Front. Cell. Neurosci.Frontiers in Cellular NeuroscienceFront. Cell. Neurosci.1662-5102Frontiers Media S.A.10.3389/fncel.2014.00219NeuroscienceReview ArticleInfluence of the extracellular matrix on endogenous and transplanted stem cells after brain damageRollLars12FaissnerAndreas12*1Department of Cell Morphology and Molecular Neurobiology, Ruhr-University BochumBochum, Germany2International Graduate School of Neuroscience, Ruhr-University BochumBochum, Germany
Edited by: Thorsten Doeppner, University of Duisburg-Essen, Germany
Reviewed by: Ayman ElAli, CHU de Québec Research Center (CHUL), Canada; Luca Peruzzotti-Jametti, University of Cambridge, UK
*Correspondence: Andreas Faissner, Department of Cell Morphology and Molecular Neurobiology, Ruhr-University Bochum, Universitätsstraße 150, Bochum 44780, Germany e-mail: andreas.faissner@rub.de
This article was submitted to the journal Frontiers in Cellular Neuroscience.
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The limited regeneration capacity of the adult central nervous system (CNS) requires strategies to improve recovery of patients. In this context, the interaction of endogenous as well as transplanted stem cells with their environment is crucial. An understanding of the molecular mechanisms could help to improve regeneration by targeted manipulation. In the course of reactive gliosis, astrocytes upregulate Glial fibrillary acidic protein (GFAP) and start, in many cases, to proliferate. Beside GFAP, subpopulations of these astroglial cells coexpress neural progenitor markers like Nestin. Although cells express these markers, the proportion of cells that eventually give rise to neurons is limited in many cases in vivo compared to the situation in vitro. In the first section, we present the characteristics of endogenous progenitor-like cells and discuss the differences in their neurogenic potential in vitro and in vivo. As the environment plays an important role for survival, proliferation, migration, and other processes, the second section of the review describes changes in the extracellular matrix (ECM), a complex network that contains numerous signaling molecules. It appears that signals in the damaged CNS lead to an activation and de-differentiation of astrocytes, but do not effectively promote neuronal differentiation of these cells. Factors that influence stem cells during development are upregulated in the damaged brain as part of an environment resembling a stem cell niche. We give a general description of the ECM composition, with focus on stem cell-associated factors like the glycoprotein Tenascin-C (TN-C). Stem cell transplantation is considered as potential treatment strategy. Interaction of transplanted stem cells with the host environment is critical for the outcome of stem cell-based therapies. Possible mechanisms involving the ECM by which transplanted stem cells might improve recovery are discussed in the last section.
Regeneration of the adult central nervous system (CNS) after damage is limited in mammals. This causes severe problems for patients who suffer from CNS lesions or stroke. Regeneration of the peripheral nervous system is more effective, differences in the cellular response are attributed to this discrepancy (Brosius Lutz and Barres, 2014). Several approaches have been tested in animal models to improve functional recovery of patients, for instance neutralization of inhibitory factors by injection of blocking antibodies or by enzymatic degradation (Zhao et al., 2013). Transplantation of stem cells are another promising strategy and effort is made to examine their effect on regeneration in clinical trials (Savitz et al., 2014). For an efficient treatment, an understanding of the cellular and molecular mechanisms underlying the observed limitations is of interest.
In the first section we describe the effect of CNS damage on astrocytes that become reactive and in many cases start to re-express neural progenitor markers. The second section is focused on the extracellular matrix (ECM) and factors in this matrix expressed by these astrocytes and other cell types. The third section is dedicated to the question how transplanted stem cells can interact with the host and by which mechanisms they might improve regeneration.
Lesions of the central nervous system activate endogenous progenitor-like cells
After stroke or lesion, astrocytes, microglia, and other cell types of the immune system are activated in a process called reactive gliosis (reviewed by Donnelly and Popovich, 2008; Burda and Sofroniew, 2014). Astrocytes change their morphology and subpopulations of them upregulate markers typical of immature neural progenitors during development (Figure 1). In severe cases, a glial scar is formed by astrocytes that intermingle with fibroblasts before they segregate (Bundesen et al., 2003). In the following first section of the review, we want to give a short overview of the markers these astroglial subtypes express, of their spatial distribution and origin, and of the neurogenic potential these cells might have in vivo.
Subtypes of reactive astroglia. (A, B) Astrocytes become reactive following CNS damage. In addition to GFAP upregulation, some of the cells start to express progenitor markers like Vimentin and Nestin. The position of the cells in relation to the lesion determines the expression pattern with Nestin near the lesion, Vimentin in a broader area and GFAP with a widespread upregulation. (C) Immunohistochemical staining of GFAP (red), Vimentin (green), and Nestin (blue, in an adjacent slice) expression after focal laser lesion of the mouse visual cortex. The dashed line depicts the border to the lesion core; * lesion core.
Progenitor marker expression after CNS damage
Astrocytes become reactive after CNS damage and typically express the intermediate filament Glial fibrillary acidic protein (GFAP). In addition, other markers like the intermediate filaments Vimentin and Nestin are coexpressed (Pekny and Nilsson, 2005). Vimentin is expressed in radial glia during development (Bignami et al., 1982), whereas Nestin is the prototypical neural stem/progenitor cell marker (Lendahl et al., 1990). Depending on the time point after lesion, additional markers for immature glia like Brain lipid-binding protein (BLBP), the DSD-1 epitope on members of the receptor protein tyrosine phosphatase (RPTP) β family, and Tenascin-C (TN-C) are expressed (Robel et al., 2011).
The function of GFAP and Vimentin in regeneration is discussed (Brenner, 2014). For example, knockout mice deficient for GFAP and Vimentin showed reduced hypertrophy of astrocytes, improved synaptic restoration after entorhinal cortex lesion (Wilhelmsson et al., 2004), and supported integration of cells transplanted into the retina (Kinouchi et al., 2003) or into the hippocampus (Widestrand et al., 2007). In contrast, an increased lesion volume was found in GFAP/Vimentin double knockout mice after stroke, whereas single knockouts had no effect on the lesion volume (Li et al., 2008). Different GFAP isoforms are described for human and mice, but especially for mice there is no clear correlation of certain isoforms with stem/progenitor cells (Kamphuis et al., 2012). The role of TN-C and other ECM components in regeneration is discussed in the second section.
Astroglial subtypes are arranged in distinct areas
The different markers mentioned above are not uniformly expressed by all astrocytes. Instead, subpopulations express different combinations. Here it was observed that the cells show a specific spatial distribution. For example, focal laser lesions in the adult mouse visual cortex (Roll et al., 2012) induce GFAP upregulation in a wide area, whereas the progenitor markers Vimentin and even more extremely Nestin are restricted to an area near the lesion core (Figure 1). Interestingly, astrocytes (type B cells) are the stem cells of the subventricular zone (SVZ) and are also positive for Nestin and Vimentin (Doetsch et al., 1997, 1999). Differences in marker expression may reflect the potential of the cells to form other neural cell types. It was described that multipotent neural stem/progenitor cells that give rise to neurons, astrocytes, and oligodendrocytes in vitro appear in the brain following stab wound (Buffo et al., 2008), laser lesion (Sirko et al., 2009), and in other lesion models (Sirko et al., 2013). As shown by differential marker expression, reactive astrocytes are a heterogeneous population with respect to the distance of a cell to the lesion. Additionally, astrocytes are also heterogeneous regarding morphology, function, CNS region, and severity of the lesion (reviewed by Anderson et al., 2014).
Different origins of multipotent cells after CNS damage
An obvious question regarding multipotent stem/progenitor cells in the damaged adult brain is the origin of those cells. Are adult stem cells attracted from the stem cells niches like the SVZ and migrate to the lesion site, or are local astrocytes induced to de-differentiate on-site? An argument for activation of local cells in focal laser lesions of the visual mouse cortex is the distinct spatial distribution of markers like GFAP, Vimentin, and Nestin. A similar finding of Nestin-expressing cells in a distinct pattern was made in the spinal cord after hemitransection and was also interpreted as local activation (Lang et al., 2004). Re-expression of the ECM molecule TN-C, which is expressed during development and later downregulated in the adult cortex, is also restricted to astrocytes located near the lesion (McKeon et al., 1991; Roll et al., 2012). It can be assumed that gradients of signaling molecules with high concentrations near the lesion and decreasing levels in the periphery influence the cell fate and result in the observed regional differences. Indeed, fate mapping studies by Buffo et al. (2008) showed that stab wounds activate local astrocytes in the cortex that are multipotent in vitro. Multipotent cells that give rise to neurons, astrocytes, or oligodendrocytes can be found in the developing nervous system. Different tripotential, but also subtypes of bipotential glial precursors have been described there. For example, glial restricted precursors (GRPs) that produce oligodendrocytes and astrocytes, O2A cells that give rise to oligodendrocytes and type-2 astrocytes, and others are distinguished according to their potential in vivo and in vitro and to their marker expression (Liu and Rao, 2004). The proteoglycan Neuron-glial antigen 2 (NG2) is associated with glial precursors during development, therefore the contribution of NG2-positive cells present in the adult CNS after damage is discussed (Han et al., 2004; Komitova et al., 2011). In the spinal cord, it has been shown that ependymal cells contribute significantly to newly formed astrocytes and show multilineage potential (Barnabé-Heider et al., 2010). To what extent cells after damage only share similarities or if they acquire a cell fate that is indeed identical to those developmental populations is hard to determine. Depending on the severity, in addition to a local response cells from the adult stem cell niches are activated (Shimada et al., 2010). A stem cell response in terms of an increased SVZ size (Thored et al., 2006) and attraction of neuroblasts from the SVZ to the striatum after stroke was reported (Arvidsson et al., 2002; Yamashita et al., 2006). Regional differences in the potential of SVZ cells are described, such as dorsolateral prevalence of oligodendroglial cells and neuronal and astroglial fates in the ventrolateral area (reviewed by Maki et al., 2013). In some cases, attraction of cells from the SVZ could not be shown by cell tracing experiments (Shimada et al., 2012) or fate mapping (Buffo et al., 2008). In contrast to the described promoting effects of stroke on the adult stem cell niche, chronic inflammation reduces proliferation and impairs migration of neuroblasts (Pluchino et al., 2008). So in general, local activation as well as an influence on the existing adult stem cell niches are conceivable and may take place in parallel. Certainly, this depends on the type, severity, and localization of the damage and further studies are needed to determine the contribution of both mechanisms in different lesion paradigms.
Differences of the neurogenic potential in vivo and in vitro
In many cases, the neurogenic potential of the cells in vivo is more restricted compared to the situation in vitro. So reactive astrocyte-derived cells appear to be multipotent in culture, but fail to form neurons after transplantation in vivo (Shimada et al., 2012). An approach to promote the neuronal fate of reactive astrocytes is retroviral expression of the proneural transcription factor NeuroD1, allowing astrocytes to differentiate into glutamatergic neurons (Guo et al., 2014). Another transcription factor, Sox2, was able to convert spinal cord astrocytes into neurons (Su et al., 2014). A further strategy is the administration of neurogenesis-promoting factors, as shown for Galectin-1 after stroke (Ishibashi et al., 2007). More strategies have been summarized by Obermair et al. (2008).
The main difference between endogenous stem/progenitor cells in situ and their isolated and cultured counterparts is the completely changed environment, where signals from other cell types are lost. Among them are several neurogenesis-inhibiting factors (Seidenfaden et al., 2006; Buddensiek et al., 2009), one of the candidates is Notch (Aruga et al., 2002). Stress during isolation, high concentrations of growth factors in the medium, and the oxygen and energy supply are additional factors that may influence the cells’ potential. This shows that both, multipotent cells combined with a permissive environment, are necessary for the formation of neurons after lesion. The ECM contains a tremendous variety of signaling molecules and with regard to its importance for regeneration it is the topic of the next section.
Extracellular signals influence regeneration and stem/progenitor cells
The ECM is a complex network of interacting molecules that are secreted by the cells into the extracellular space. Depending on the tissue, it functions as a scaffold for the cells and provides mechanical stability, for example in cartilage (Treilleux et al., 1992), but also in all other tissues. The ECM in the CNS is free of fibrillar elements, except after lesion (Heck et al., 2007). It contains glycoproteins like TN-C, TN-R, and proteoglycans (PG; Zimmermann and Dours-Zimmermann, 2008). PGs consist of a core protein and covalently attached carbohydrate (glycosaminoglycan, GAG) chains. Important Chondroitin sulfate proteoglycans (CSPGs) are molecules of the Lectican family and members of the RPTPβ family, whereas the Heparan sulfate proteoglycans (HSPGs) Syndecan and Glypican are other prominent constituents. Interactions of PGs with other molecules can be mediated by the core protein or by the carbohydrate structures. The ECM is able to bind growth factors and to present them to the cells (Clark, 2008; Brizzi et al., 2012). This allows the extracellular signals to regulate processes like cell survival, proliferation, and differentiation as well as migration or axon growth. According to changing requirements during development, the ECM composition is variable. After CNS lesions, the ECM is altered again. For example, reactive gliosis can lead to a glial scar that has a beneficial effect as it provides a barrier for healthy tissue from the environment (Pekny et al., 2014). At the same time, it is the major obstacle for axonal regrowth (Silver and Miller, 2004; Rolls et al., 2009). But the ECM is more than one constituent of the glial scar. It is involved in synaptic plasticity in many ways, for example in long term potentiation (LTP; Dityatev and Schachner, 2003). As mentioned above, the ECM contains signals regulating processes that are critical for regeneration and therefore this second section of the review is dedicated to details regarding the ECM composition and associated factors after CNS damage.
Extracellular matrix after CNS damage
After lesion, several aspects of extracellular signals are critical: (i) barriers like the glial scar are important to protect the healthy tissue from the environment, but they also prevent axonal regrowth or cell migration; (ii) plasticity-limiting factors stabilize neuronal networks in the healthy brain but exacerbate reorganization in case of damage; and (iii) the balance between de-differentiation and re-differentiation. If cells are induced by the extracellular signals to de-differentiate, but get no signal for proper differentiation, they will stay in an undifferentiated state and cannot replace lost tissue. For example, TN-C, which is also present in the adult stem cell niche, may inhibit differentiation of an astrocyte-derived progenitor cell into a functional neuron or oligodendrocyte. This could be mediated by repression of the RNA-binding molecule Sam68 (Moritz et al., 2008; Czopka et al., 2010).
Extracellular matrix under different pathological conditions
Changes in the ECM composition differ depending on the type of CNS damage. As a disease-specific description is not the aim of this review, we recommend the following publications: stroke-induced effects were reviewed by Ellison et al. (1999), with focus on the blood-brain barrier by Baeten and Akassoglou (2011). Reports are also available for brain tumors (Gladson, 1999; Wade et al., 2013), spinal cord injuries (Condic and Lemons, 2002), neurodegenerative diseases like Alzheimer’s (Morawski et al., 2012), and for autoimmune disorders like multiple sclerosis (Sobel, 1998; van Horssen et al., 2007).
Sources of extracellular matrix and associated signaling molecules
In response to damage, a number of cell types react and communicate via extracellular signals. The main sources of ECM and related important signaling molecules in the matrix are summarized in this paragraph. Important sources of extracellular molecules are listed in Table 1.
Important sources of extracellular signaling molecules after CNS lesion.
Cell type
Extracellular matrix-related molecule
Endothelial cells
Brain-derived neurotrophic factor (BDNF)
Fibroblast growth factor 2 (FGF-2)
Leukaemia inhibitory factor (LIF)
Pleiotrophin
Vascular endothelial growth factor (VEGF)
Fibrinogen [blood-derived]
Pericytes
Fibronectin
Astrocytes
Agrin
Brevican
Collagen IV, VIII
Decorin
Fibronectin
Glypican
Laminin
Neurocan
Phosphacan
Syndecan
Tenascin-C
Thombospondin
Versican
Oligodendrocytes/Precursors
Matrix metalloproteinase 9 (MMP-9)
Neurocan
Neuron-glial antigen 2 (NG2)
Nogo-A
Versican
Neurons
Chemokines
Cytokines
Sonic hedgehog (SHH)
Microglia/Macrophages
Cytokines
Neuron-glial antigen 2 (NG2)
Neurotrophic fawsctors
As the origin of secreted molecules is often difficult to determine by immunological studies, more molecules are expressed that have not yet been allocated. References are given in the text.
Vasculature
Blood vessels are an important signal source, as reviewed by Gattazzo et al. (2014). As part of the neurovascular niche they are also thought to be crucial for the residing stem/progenitor cells in the adult stem cell niches (Shen et al., 2008). Endothelial cells produce a number of factors that act on neural cells. Among others, Pleiotrophin, Leukaemia inhibitory factor (LIF), Brain-derived neurotrophic factor (BDNF), and Fibroblast growth factor (FGF) 2 influence differentiation (Carmeliet, 2003; Dugas et al., 2008). Vascular endothelial growth factor (VEGF) is an important regulator of angiogenesis and neurogenesis (Jin et al., 2002; Nag et al., 2002). Angiogenesis is increased in the damaged CNS and therefore more cells get in contact with the perivascular niche (Arai et al., 2009). Hypoxia supports stemness during development, but also under pathological conditions like stroke (Panchision, 2009). This is mediated by Hypoxia-inducible factor (HIF) I α, which facilitates Notch signaling and inhibits factors responsible for differentiation, for example Bone morphogenetic proteins (BMPs). The blood-brain barrier is disrupted in many cases as result of mechanical damage or chemokines (Dimitrijevic et al., 2006), which allows cells like T lymphocytes and additional factors from the blood to enter the CNS that are retained under normal conditions. When Fibrinogen from the blood crosses the disturbed blood-brain barrier, it activates astrocytes by providing Transforming growth factor β (TGF-β; Schachtrup et al., 2010). Pericytes are involved in the production of the glial scar, including Fibronectin (FN; Göritz et al., 2011). In addition, vessels are used as guiding structures by migrating neural progenitors in the healthy and diseased brain (Massouh and Saghatelyan, 2010).
Astrocytes
Astrocytes are extremely heterogeneous in their expression profile, as described in the first section. Depending on the type of damage, the time point after lesion, and the position, reactive astrocytes are responsible for TN-C expression in many lesion models (McKeon et al., 1991; Roll et al., 2012) and also express Brevican, Versican (Beggah et al., 2005), Neurocan (Haas et al., 1999), Phosphacan (McKeon et al., 1999), Decorin (Stichel et al., 1995), Laminin, and FN (Gris et al., 2007). HSPGs expressed by reactive astrocytes are Glypican, Syndecan, and Agrin (Iseki et al., 2002; Hagino et al., 2003; Falo et al., 2008). Collagen expression, which is involved in glial scar formation, was also shown for reactive astrocytes. The basement membrane-associated type IV (Liesi and Kauppila, 2002) and type VIII (Hirano et al., 2004) Collagens were detected. Astrocytes are also a source of Thrombospondins (TSPs; Lin et al., 2003) (reviewed by Sofroniew, 2009). Astrocytic expression of TN-C, Neurocan, and Phosphacan is increased by presence of meningeal fibroblasts in vitro (Wanner et al., 2008). Activation of astrocytes is mediated by pro-inflammatory cytokines like Interleukin (IL)-1β, IL-6, and Tumor necrosis factor α (TNF-α). They are secreted by microglia, in part by the astrocytes themselves, or by other cell types (Buffo et al., 2010).
Oligodendrocytes
Oligodendrocytes produce Nogo-A, an inhibitor of neurite outgrowth (Chen et al., 2000). Oligodendrocyte precursors express the CSPGs Neurocan and NG2 (Levine, 1994; Asher et al., 2000) and oligodendrocyte lineage cells secrete Versican under pathological conditions (Asher et al., 2002). Matrix metalloproteinase 9 (MMP-9) produced by oligodendrocyte precursors leads to blood-brain barrier leakage (Seo et al., 2013).
Neurons
Neurons start to express numerous chemokines like Chemokine (C-C motif) ligand 20 (CCL20), CCL21, CXC chemokine ligand 12 (CXCL12/SDF-1), and CXCL14/BRAK under pathological conditions (Das et al., 2012). They are primarily involved in immunomodulation, but additional functions as neuromodulators are assumed (Rostène et al., 2011).
Microglia
Microglia, the macrophages of the CNS, are activated by several mechanisms after injury. For example, they can detect reduced neuronal activity by alterations in neurotransmitter concentration and become activated (Biber et al., 2007; Kettenmann et al., 2011). Chemokines expressed after lesion can induce migration of microglia, for example Cysteine-cysteine (CC) chemokines (Carbonell et al., 2005). The consequence of microglial activation is the upregulation of cytokines and neurotrophic factors (Donnelly and Popovich, 2008). Increased levels of cytokines can induce remodeling of the ECM, for example by inducing the expression of MMPs (Gottschall and Yu, 1995) and of matrix molecules like TN-C by reactive astrocytes. Activated microglia also express ECM molecules themselves, for example NG2 (Sugimoto et al., 2014).
Classes of extracellular matrix molecules in the postlesional CNS
Important classes of extracellular signaling molecules that are typically present after CNS damage are described below. In many cases, components typical of the stem cell niches are re-expressed and provide an environment that resembles—in part—a neural stem cell niche like the SVZ. That niche is formed by signals from the vasculature, cerebrospinal fluid, and a complex set of extracellular molecules secreted by the cells in the niche (reviewed by Kazanis and ffrench-Constant, 2011). The situation after lesion with upregulated ECM molecules and the niche-like environment is summarized in Figure 2. As described above, major sources of the signals are reactive astrocytes, microglia, and the vasculature. Important functions regulated by ECM molecules and associated factors are listed in Table 2.
The extracellular matrix after CNS damage. (A, B) After lesion, cells start to produce an altered extracellular matrix (ECM). One major source are reactive astrocytes (B) that express CSPGs and other ECM molecules. (C) Signals come from astrocytes (orange), the vasculature (red), immune cells/microglia (green), and additional sources (blue, for a detailed list see Table 1). This environment can promote, but also inhibit regeneration by affecting neurons, astrocytes, and oligodendrocytes.
Parameters modulated by extracellular signals after lesion.
Parameter
Modulating factor in the extracellular matrix
Cell survival, proliferation
Neurotrophic factors*
Cytokines*
Growth factors*
Differentiation, axon growth, synaptic plasticity
Agrin
Brevican
Collagen
Decorin
Glypican
Laminin
Neurocan
Neuron-glial antigen 2 (NG2)
Nogo-A
Phosphacan; with attached DSD-1 epitope
Pleiotrophin
Syndecan
Tenascin-C
Tenascin-R
Thrombospondins
Versican
Migration
CXC chemokine ligand 12 (CXCL12)
Fibronectin
Laminin
Tenascin-C
Thrombospondins
Many molecules regulate several aspects, only main functions are listed here. References are given in the text.
* signaling is modulated by the extracellular matrix.
Chondroitin sulfate proteoglycans
CSPGs act as barrier after CNS damage and contribute to the axonal growth-inhibitory environment including the glial scar (Brown et al., 2012). CSPGs are mainly expressed by reactive astrocytes. Their effect can be mediated by members of the Leukocyte common antigen-related (LAR) family of RPTPs that comprises for example LAR, RPTPδ, RPTPσ, and the Nogo receptors NgR1 and NgR3 (reviewed by Cregg et al., 2014). LARs are involved in β-Catenin recruitment, leading to changes in the Actin cytoskeleton, which in turn affects axon growth and synaptic organization (Um and Ko, 2013). The Actin cytoskeleton is also targeted by NgR1 and coreceptors, in this case via the small GTPase RhoA and Rho-associated kinase (ROCK; Fournier et al., 2003; Schwab and Strittmatter, 2014). In addition to the above mentioned receptors, CSPGs can bind to specific receptors like Integrins, a family of heterodimeric transmembrane receptors (see the detailed Integrin description below). CSPGs can also act indirectly, when they intensify growth factor-induced signaling by presenting a growth factor to its receptor, or conversely, block signaling by sequestering growth factors like Pleiotrophin (Deepa et al., 2002) from their receptors (reviewed by Carulli et al., 2005; Sharma et al., 2012b). Neurocan, Brevican, and Versican levels are increased after lesion (Jones et al., 2003; Beggah et al., 2005) as well as Biglycan, Decorin (Stichel et al., 1995), and NG2 (Levine, 1994). NG2 inhibits neurite outgrowth, consequently its neutralization improves recovery (Dou and Levine, 1994; Petrosyan et al., 2013). It is produced by oligodendrocyte progenitors, but not by GFAP-positive astrocytes. This is in line with reports that NG2-positive progenitors are not an important source of astrocytes after brain injury (Komitova et al., 2011). Macrophages and microglia are additional sources of NG2 (Jones et al., 2002; Sugimoto et al., 2014). Decorin antagonizes scar formation as it is able to reduce the expression of Neurocan, Brevican, NG2, and Phosphacan, probably by inhibiting TGF-β and antagonizing the Epidermal growth factor (EGF) receptor (Davies et al., 2004). The RPTPβ (or “RPTPβ/ζ“) family comprises four isoforms. Alternative splicing of a single gene and proteolytic processing result in two transmembrane receptor forms (RPTPβ long and RPTPβ short) and two secreted molecules (Phosphacan and Phosphacan short isoform (PSI; Garwood et al., 2003; Chow et al., 2008)). The receptor forms contain two cytoplasmic tyrosine phosphatase domains, of which only one is catalytically active (Krueger and Saito, 1992). Substrates for this domain are β-Catenin, which is related to the Actin cytoskeleton and Wnt signaling (Meng et al., 2000), Fyn kinase (Pariser et al., 2005a), and others. Dimerization following Pleiotrophin binding inactivates the phosphatase domains and thereby increases the phosphorylation state of downstream factors like Adducin, a cytoskeletal protein (Pariser et al., 2005b). Other extracellular interaction partners are TN-C, Contactin/F3/F11, the cell adhesion molecules L1CAM and NCAM (Klausmeyer et al., 2007), and FGF (Milev et al., 1998b). RPTPβ isoforms are regulated after knife lesion of the cerebral cortex (Dobbertin et al., 2003), striatal stab wound (Barker et al., 1996), and after retinal laser lesion (Besser et al., 2009) and are critical for recovery (Harroch et al., 2002). PSI as the smallest member of the RPTPβ family promotes axon growth (Garwood et al., 2003). Two isoforms (RPTPβ long and Phosphacan) can be decorated with Chondroitin sulfate GAG chains. These chains regulate the affinity to binding partners, for example to Contactin/F3/F11 (Milev et al., 1998a). A specific Chondroitin sulfate structure, the “DSD-1” epitope, is recognized by the monoclonal antibody 473HD (Faissner et al., 1994; Gates et al., 1995). This epitope is expressed on neural stem cells during development (von Holst et al., 2006) and it has been shown that blocking of this epitope impairs neurosphere formation in vitro. Subpopulations of reactive astrocytes after laser lesion in the visual cortex of rats and mice express the DSD-1 epitope (Sirko et al., 2009; Roll et al., 2012). As mentioned above, this might reflect the immature characteristics of some reactive astrocytes and at the same time a neurogenic niche-like signal after CNS damage.
Collagens
Collagens comprise 28 members and can be divided into fibril-forming and network-forming Collagens (Ricard-Blum, 2011). In the CNS, Collagens are associated with the vasculature. Integrins are important Collagen receptors: the Integrin subunits α1, α2, α10, α11, and β1 interact with different Collagens. Additional receptors are members of the Discoidin domain receptors (DDRs), a subfamily of receptor tyrosine kinases (Leitinger and Hohenester, 2007). In addition to cell adhesion, Collagens are able to activate intracellular pathways and can induce proliferation (Pozzi et al., 1998). Collagens are expressed by astrocytes after lesion. Type IV and type VIII Collagens, both network-forming and associated with the basement membrane, have been found upregulated in the CNS (Liesi and Kauppila, 2002; Hirano et al., 2004). In general, Collagen expression is suppressed via EGF signaling (Heck et al., 2007).
Fibronectin
FN is a secreted glycoprotein that forms dimers via disulfide bonds near the C terminus. FN interacts with ECM molecules like Collagens, HSPGs, and TN-C and acts as ligand for Integrin receptors (Singh et al., 2010). FN is expressed by astrocytes and microglia/macrophages after CNS damage, also liver-derived plasma FN has a neuroprotective function in CNS repair (Tate et al., 2007a; Kim et al., 2013). FN activates microglia through binding to Integrin α5β1 (Milner et al., 2007) and has a neurite growth-promoting effect in vitro (Tom et al., 2004).
Heparan sulfate proteoglycans
HSPGs are, in contrast to the inhibitory CSPGs, ascribed to the neurite outgrowth-promoting factors (Yamaguchi, 2001). It is assumed that HSPGs can interfere with CSPG signaling by interacting with the same receptors, for example RPTPσ (Coles et al., 2011). Accordingly, downstream factors like N-Cadherin (Siu et al., 2007) might be regulated. The HSPG Glypican is expressed by reactive astrocytes (Hagino et al., 2003). It is involved in Hedgehog signaling (Filmus and Capurro, 2014) and as a HSPG it also regulates FGF signaling (Gordon et al., 1989; Rapraeger et al., 1991; Yayon et al., 1991). Syndecan, which is also able to modulate FGF signaling (Filla et al., 1998), is produced by astrocytes after brain injury (Iseki et al., 2002). Important for axonal growth and cell migration could be the interaction of Glypican-1 with repellent Slit proteins (Ronca et al., 2001). Slit is expressed by reactive astrocytes (Hagino et al., 2003), treatment with specific inhibitors of this interaction is owing (Lau and Margolis, 2010). The Drosophila homolog of Syndecan is involved in Slit signaling (Steigemann et al., 2004), suggesting a similar effect in the mammalian CNS. The HSPG Agrin is also expressed by reactive astrocytes. It has functions in the immune system and in neuromuscular synapse formation and may additionally play a role in CNS synapse formation during regeneration (Falo et al., 2008). Perlecan, which is associated with the vascular basement membrane, is a secreted HSPG that is upregulated following damage. After stroke, a neuroprotective effect was shown after administration of Perlecan domain V. An Integrin-mediated upregulation of VEGF in endothelial cells was attributed to the beneficial function (Lee et al., 2011).
Laminins
Laminins are trimeric glycoproteins and a crucial component of the basement membrane. Different isoforms of α, β, and γ chains are combined to at least 16 Laminins and interaction with other extracellular molecules like Agrin, Collagen IV, Nidogen, and Perlecan leads to formation of complex networks (Domogatskaya et al., 2012). Laminins signal through different Integrins (Belkin and Stepp, 2000) and promote cell adhesion, migration, and axon growth during development (Calof et al., 1994). Laminins are upregulated in the glial scar by astrocytes (Liesi et al., 1984; McKeon et al., 1995) and in vessels after lesion (Tate et al., 2007b; Sarkar et al., 2012). CSPG-mediated inhibition of neurite growth in the scar interferes with Laminin-induced promoting effects (McKeon et al., 1995). Migration of activated neural stem cells along vessels after injury seems to involve Laminin (Kokovay et al., 2010). This could be mediated by α6β1 Integrin, which is a well-known Laminin receptor and is expressed on neural stem cells (Shen et al., 2008).
Tenascins
The TN family comprises four members in vertebrates, namely TN-C, TN-R, TN-W, and TN-X (Chiquet-Ehrismann et al., 2014). In the nervous system, TN-C and TN-R are expressed (Joester and Faissner, 2001). TN-C is a glycoprotein that is expressed by astrocytes during development and in adult stem cell niches (Garcion et al., 2004; von Holst, 2008). It has a modular structure including EGF-like repeats and, as a result of alternative splicing, a variable number of FN Type III-like domains (Joester and Faissner, 1999, 2001; von Holst et al., 2007). As each domain is responsible for specific interactions with other extracellular molecules, TN-C isoforms have diverse functions. Six TN-C monomers form a hexamer, called “hexabrachion”. Expression of different TN-C isoforms is regulated by the transcription factor Pax6 (von Holst et al., 2007). TN-C interacts with CSPGs, for example with Neurocan (Rauch et al., 1997), members of the RPTPβ family (Barnea et al., 1994), as well as with Integrins (Yokosaki et al., 1998) and Contactin/F3/F11 (Rigato et al., 2002). Via its EGF-like repeats, TN-C also binds to the EGF receptor (Swindle et al., 2001). Interaction of TN-C has been shown for a number of Integrins, including αvβ3 (Jones and Jones, 2000a). TN-C-induced pathways include RhoA signaling and a Contactin-dependent inhibition of Fyn kinase. A model is proposed where inactive Fyn in turn prevents expression of the splicing factor Sam68 and thereby impairs oligodendrocyte differentiation (Czopka et al., 2010). TN-C blocks FN-dependent cell migration by interacting with Syndecan-4 (Chiquet-Ehrismann and Chiquet, 2003) and regulates axon growth (Faissner, 1997). During development, maintenance of oligodendrocyte precursors (Czopka et al., 2010) and astrocytic lineage progression depend on TN-C (Karus et al., 2011). After lesion, TN-C is re-expressed and it contributes to the glial scar as barrier (McKeon et al., 1991; Deckner et al., 2000). TN-C is detected in different regions of the lesioned CNS, for example in the hippocampus (Niquet et al., 1995; Nakic et al., 1996), cerebellum, and cortex (Laywell et al., 1992). TN-C expression was also reported in the human brain after traumatic brain injury (Hausmann and Betz, 2001). TGF-β and FGF2 stimulate TN-C expression (Smith and Hale, 1997). After lesion, TN-C isoforms containing the FN Type III-like domains B and D are strongly upregulated (Dobbertin et al., 2010). After spinal cord injury, TN-C has a beneficial effect on spinal cord recovery (Chen et al., 2010). An overview of the different functions of TN-C is given by Chiquet-Ehrismann et al. (2014). TN-R has also a modular structure like TN-C, but forms trimers instead of hexamers (Joester and Faissner, 2001). TN-R interacts with Integrins, for example β1 Integrins (Xu et al., 2014), Contactin/F3/F11, Phosphacan (Jones and Jones, 2000a), and Myelin-associated glycoprotein (MAG; Yang et al., 1999). TN-R is expressed after spinal cord injury (Apostolova et al., 2006) and in the lesioned optic nerve by an increased number of cells (Becker et al., 2000). TN-R is part of perineuronal nets (PNNs) that limit synaptic plasticity in the adult. After damage, this property seems to inhibit synaptic remodeling and thereby affects regeneration.
Thrombospondins
TSPs are secreted glycoproteins that form trimers (members of subgroup A) or pentamers (subgroup B) (Adams and Lawler, 2011). Interaction partners include ECM molecules like Laminins, Collagens, and PGs, growth factors like FGF2, and Integrin receptors that eventually trigger intracellular signaling cascades (Resovi et al., 2014). Thrombospondins are also involved in Notch signaling, which regulates astrocytic differentiation after lesion (Benner et al., 2013). TSPs are expressed by reactive astrocytes and microglia (Möller et al., 1996; Lin et al., 2003), for example they are upregulated after spinal cord injury (Wang et al., 2009b). TSPs are involved in oligodendrocyte precursor migration (Scott-Drew and ffrench-Constant, 1997), synapse formation (Christopherson et al., 2005), and angiogenesis inhibition (Armstrong and Bornstein, 2003).
Cell adhesion molecules
Cell adhesion molecules of the Immunoglobulin superfamily (IgSF CAMs) are membrane-bound receptors that mediate contact to the ECM and cell-cell interactions. Axon guidance is one important function of CAMs. Among them, Neural CAM (NCAM) is upregulated after CNS lesion and promotes spinal cord recovery (Zhang et al., 2010). Accordingly, recovery in NCAM knockout mice is affected. The polysialylated form of NCAM (PSA-NCAM) is associated with plasticity and is expressed during development, in the adult stem cell niche, and after CNS damage (Emery et al., 2003). NCAM can modulate GDNF and BDNF signaling (Vutskits et al., 2001; Nielsen et al., 2009) and interacts with the CSPG Neurocan (Friedlander et al., 1994). NCAM can activate a number of intracellular cascades, for example the mitogen-activated protein (MAP) kinase pathway via a complex of Spectrin, RPTPα, Fyn kinase and Focal adhesion kinase (FAK; Budinich et al., 2012). L1CAM, another member of IgSF CAMs, is also an important regulator of axon growth during development. It is again upregulated after lesions, where it limits corticospinal tract sprouting (Jakeman et al., 2006). L1CAM activates, in part together with Integrins, MAP kinase signaling via Src kinase and Phosphoinositide 3-kinase (PI3K). It also modulates the Actin cytoskeleton through Ankyrin and Spectrin and can recruit microtubules via Doublecortin (Maness and Schachner, 2007).
Integrins
Integrins, a group of heterodimer transmembrane receptors for ECM molecules, are involved in cell adhesion, axon growth, and numerous other processes. Each Integrin heterodimer consists of one α and one β subunit. Eighteen α and eight β subunits are described, leading to 24 confirmed Integrin heterodimers. Integrins connect ECM and the cytoskeleton via adapters like Talin and activate intracellular pathways that regulate gene expression. The classical downstream cascade of Integrins leads to activation of FAK and subsequent activation of Akt and MAP kinases (Guan, 1997; Guo and Giancotti, 2004). A FAK-independent activation of Src kinase also exists (Arias-Salgado et al., 2003). Some Integrins, including the subunits αv, β1, β4, and β7, can crosstalk with growth factor receptors like EGFR (Brizzi et al., 2012). The β1 subunit is important in stem cell biology (Campos, 2005). As already mentioned, Integrins bind a huge number of ECM molecules. For example, Integrin α6β1 binds Laminin (Shen et al., 2008) and αvβ3 binds TN-C (Jones and Jones, 2000b). In addition to these outside-in signaling pathways, Integrins can transduce inside-out signals. They are mediated by the cytoskeletal protein Talin and increase the affinity of Integrin for extracellular ligands (Anthis et al., 2009). Like their ligands, Integrins are regulated under pathological conditions and contribute to postlesional changes (Ellison et al., 1999).
Matrix metalloproteinases
MMPs are able to modulate the ECM by specific proteolytic cleavage (Candelario-Jalil et al., 2009). This function is important in the damaged CNS when the cells’ environment needs to be adjusted, for example to increase plasticity. MMP upregulation following injury is described for blood vessels, astrocytes, and microglia (Noble et al., 2002). MMPs degrade defined matrix components. So different TN-C isoforms are cleaved by specific MMPs (Siri et al., 1995), MMP-3 degrades the CSPGs Neurocan, Brevican, and Phosphacan (Muir et al., 2002). Effects of MMPs on regeneration have been described, for example of MMP-9 (Hsu et al., 2008). Here, migration of MMP-9-deficient astrocytes was reduced in vitro. MMP-9 is also involved in blood-brain barrier opening in the diseased CNS (Seo et al., 2013). The expression of MMPs in astrocytes can be regulated by the cytokines IL-1 and TNF-α (Gottschall and Yu, 1995). But not only migration is affected by MMPs: MMP-3 and MMP-9 play a role in neuronal differentiation in response to cytokines in vitro (Barkho et al., 2008).
Perineuronal nets
A specialized form of ECM are PNNs. They consist of Hyaluronan, TN-R, the CSPGs Aggrecan, Neurocan, and Brevican, and link proteins (Faissner et al., 2010; Ye and Miao, 2013). PNNs surround subpopulations of neurons, mostly Parvalbumin-positive GABAergic inhibitory interneurons, and are thought to stabilize synapses. Therefore their appearance is correlated with the end of a critical period during development. It has been shown that astrocytes play an important role in PNN formation, as they secrete components of the PNNs (Pyka et al., 2011). In line with this, the quadruple knockout of TN-C, TN-R, Neurocan, and Brevican either in astrocytes or hippocampal neurons leads to reduced PNN formation, accompanied by impaired synaptogenesis, synapse stability, and altered synaptic activity in vitro (Geissler et al., 2013). PNN degradation with the bacterial enzyme Chondroitinase ABC restored synaptic plasticity in the visual cortex after the critical period (Pizzorusso et al., 2002). Although single components like Neurocan can be upregulated after damage (Kwok et al., 2011), reduction of PNNs has been described, which is in line with the fact that plasticity is increased under this condition (Karetko-Sysa et al., 2011). This shows that not only the presence of molecules as such is important, but also the spatial distribution and the interaction of different factors.
Growth factors and other signaling molecules in the matrixEphrins and Eph receptors
Ephrins and their counterparts, the Eph receptors, are potent regulators of neurite growth, as they are able to induce growth cone collapse. Activation of an Eph receptor tyrosine kinase following Ephrin binding leads to RhoA- and ROCK-induced changes of the Actin cytoskeleton (Wahl et al., 2000). Also bidirectional signaling is described, in this case Ephrins can activate RhoA and other pathways (Daar, 2012). Many Ephrins and Eph receptors are upregulated after CNS damage, as reviewed by Goldshmit et al. (2006). Ephrin-B2 and Eph-B2 seem to be involved in segregating invading fibroblasts at the glial scar (Bundesen et al., 2003).
Nogo-A
Nogo-A is a potent inhibitor of neurite outgrowth and interacts with a complex of receptors, including NgR1, that results in activation of ROCK signaling (reviewed by Schmandke et al., 2014). Nogo-A is produced by oligodendrocytes and is part of the myelin in the CNS. It is one important inhibitor of axonal regeneration (Chen et al., 2000). Interestingly, Nogo-A and NgR1 are also involved in the homeostasis of the adult SVZ. Here, proliferation and differentiation of neural stem cells are restricted by Nogo-A-expressing neuroblasts via NgR1. In addition, neuroblast migration is regulated by Nogo-A in an NgR1-independent mechanism that acts on ROCK (Rolando et al., 2012). Nogo-A and its receptor have been a target for several blocking experiments after stroke (Lee et al., 2004), spinal cord injury (Liebscher et al., 2005), and in other lesion models that showed beneficial effects of Nogo-A inactivation (reviewed by Overman and Carmichael, 2014; Schwab and Strittmatter, 2014). In intact animals, Nogo-A blocking showed no obvious side effects on cognitive function (Craveiro et al., 2013), although the Nogo-A receptor NgR1 is involved in memory formation (Karlén et al., 2009) and mice with downregulated Nogo-A show subtle cognitive deficits (Petrasek et al., 2014).
Semaphorins
Twenty Semaphorins are found in vertebrates, all of them contain a characteristic extracellular Sema domain. The most prominent function of Semaphorins is the regulation of axon growth and their ability to induce growth cone collapse. Semaphorins bind to Plexin and Neuropilin receptors. Different intracellular cascades eventually affect the cytoskeleton and, in many cases, induce growth cone collapse. Microtubule and Actin filament stability can be modified as well as gene expression (Neufeld and Kessler, 2008), pathways that depend on protein synthesis and independent mechanisms coexist (Manns et al., 2012). Sema3A is expressed by fibroblast-like cells after CNS injury (Pasterkamp et al., 1999) and in line with this, meningeal fibroblasts inhibit neurite outgrowth in vitro (Niclou et al., 2003). After optic nerve crush, short-term Sema3A upregulation was observed, whereas other class 3 Semaphorins were upregulated for days (Sharma et al., 2012a). L1CAMFc chimeric molecules can reverse the repellent effect of Sema3A, which shows that the combination of different factors is important rather than a single factor (Castellani et al., 2000).
Sonic hedgehog
Sonic hedgehog (SHH) is a signaling molecule that is able to regulate gene expression as well as the cytoskeleton. During development, it serves as morphogen and is involved in dorsoventral patterning. Binding of SHH to its receptor Patched relieves the repression of the seven-transmembrane receptor Smoothened. As a consequence, Gli transcription factors are activated and accumulate in the nucleus. This results in repression or activation of other transcription factors and altered gene expression (Fuccillo et al., 2006). Via a Gli-independent mechanism that involves a guanine nucleotide exchange factor (Tiam1) for the GTPase Rac1, SHH acts on the cytoskeleton during dendritic spine formation (Sasaki et al., 2010). SHH is secreted by neurons, endothelial cells (Sirko et al., 2013), and also by reactive astrocytes (Amankulor et al., 2009). This upregulation can only be observed under certain pathological conditions in the CNS. The expression differs depending on the type of damage. So it is detected after stab wound and stroke, but not in a murine Alzheimer’s model (Sirko et al., 2013). In this study, it was shown that SHH expression is necessary for multipotency of endogenous neural stem/progenitor cells. The HSPG Glypican, itself upregulated after damage, is involved in Hedgehog signaling (Filmus and Capurro, 2014).
Wnts
Secreted Wnt proteins influence gene expression and the cytoskeleton. The canonical Wnt pathway starts with binding of Wnt to Frizzled receptor and to the coreceptor LRP. Subsequently, a β-Catenin-degrading complex is inactivated and β-Catenin accumulates in the cell. It enters the nucleus, where it interacts with transcription factors and activates Wnt target genes (Reya and Clevers, 2005). Non-canonical Wnt pathways also affect the cytoskeleton (Semenov et al., 2007). Wnt proteins are upregulated after lesion and influence regeneration in different ways. It was shown that repulsive Wnts inhibit axonal growth in the spinal cord (Liu et al., 2008), on the other hand Wnt signaling is involved in symmetrical cell division of SVZ cells after stroke (Piccin and Morshead, 2011).
Notch
Notch is a transmembrane receptor that plays an important role in neural cell fate determination. After binding of its ligand, Jagged or Delta-like, the Notch intracellular domain (NICD) is cleaved by γ-Secretase. NICD translocates to the nucleus, where it interacts with transcription factors and allows target gene expression (Kopan and Ilagan, 2009). Notch is upregulated and activated after CNS lesion or stroke (Yamamoto et al., 2001; Xiao et al., 2009). Notch and its interaction with TSP 4 after cortical lesion are necessary for the differentiation of SVZ-derived astrocytes (Givogri et al., 2006; Benner et al., 2013). In another study, astrogliosis was promoted by the Notch ligand Jagged, produced by transplanted endothelial progenitor cells (Kamei et al., 2012).
Cytokines
Cytokines induce diverse cellular responses by activation of specific receptors. Examples for signaling cascades are reviewed by Leonard and Lin (2000) and Schlessinger and Ullrich (1992). Important cytokines expressed by activated microglia and macrophages are Interleukin-1 (IL-1), IL-6, Interferon, and TNF-α (Smith and Hale, 1997). TGF-β is increased in microglia under pathological conditions in the brain (Morgan et al., 1993) and the spinal cord (McTigue et al., 2000). They influence the expression levels of MMPs (see above) and activate astrocytes, IL-6 for example promotes EGF-induced astrocyte proliferation (Levison et al., 2000). Astrocytes are another major cytokine source (reviewed by Eddleston and Mucke, 1993; Wiese et al., 2012). BMPs and their inhibitor Noggin regulate neurogenesis in the adult stem cell niche (Lim et al., 2000). BMPs and Noggin are upregulated after brain and spinal cord injury (Hampton et al., 2007) and regulate astrocytic vs. neuronal and oligodendrocytic differentiation (Xiao et al., 2010). By driving the differentiation of astrocytes and CSPG production, BMPs are involved in glial scar formation (Fuller et al., 2007).
Neurotrophic factors
Neurotrophic factors and growth factors signal via specific transmembrane receptors. Depending on the class of growth factors, receptor tyrosine kinases (e.g., EGF receptor) or serine/threonine receptor kinases (e.g., TGFβ receptor) induce intracellular signaling cascades (Schlessinger and Ullrich, 1992). Neurotrophins like NT3 bind to Trk (Tropomyosin-related kinase) receptors (Hetman and Xia, 2000). Neurotrophic factors expressed by activated microglia and macrophages are BDNF, Ciliary neurotrophic factor (CNTF), Glial cell line-derived neurotrophic factor (GDNF), Hepatocyte growth factor (HGF), Insulin-like growth factor (IGF), Nerve growth factor (NGF), Neurotrophin (NT)-3 and Platelet-derived growth factor (PDGF; reviewed by Donnelly and Popovich, 2008). Microglia-produced neurotrophic factors can act in an autocrine way, for example BDNF and NT-3 increase microglia proliferation (Elkabes et al., 1996). In the adult spinal cord, high levels of CNTF are expressed following injury (Nakamura and Bregman, 2001). VEGF is secreted by endothelial cells and after damage also by astrocytes (Nag et al., 2002). It increases neurogenesis and plasticity (Jin et al., 2002; Licht et al., 2011). FGF and EGF increase levels of TGF-β (Lindholm et al., 1992), which is responsible for astrocyte activation and Neurocan expression (Asher et al., 2000). TGF-β increases NGF levels (Lindholm et al., 1990). NGF in turn induces microglial migration via the TrkA receptor, when combined with low concentrations of TGF-β (De Simone et al., 2007).
Chemokines
Chemokines are secreted signaling molecules that bind to G protein-coupled, seven-transmembrane receptors (Salanga et al., 2009). Activation of a receptor induces a cascade including second messengers like cAMP or IP3 that can mediate diverse cellular responses (Patel et al., 2013). The chemokine stromal-derived factor 1 (SDF-1/CXCL12) is expressed by astrocytes after stroke and mediates attraction of cells by binding to its receptor, CXCR4. This system is involved in attraction of bone marrow stem cells (Hill et al., 2004), transplanted umbilical cord blood cells (Rosenkranz et al., 2010), and neural stem cells (Imitola et al., 2004). Two isoforms, SDF-1α and SDF-1β, have distinct expression patterns in the lesioned CNS. Neurons express SDF-1α, whereas SDF-1β is expressed by endothelial cells (Stumm et al., 2002). Hence, a dual function of SDF-1-mediated modulation of the immune response and neurotransmission is discussed.
Regeneration in ECM knockout (KO) models
The effect of ECM molecules on regeneration was examined in different knockout models. Double knockout of Neurocan and Brevican in mice does not obviously affect recovery after spinal cord injury (Quaglia et al., 2008). In a more sophisticated model with an additional priming lesion in the sensory nerve 7 days after spinal cord injury, only in KO animals axons crossed the dorsal root entry zone. This uncovered the growth-inhibiting effect of Neurocan and Brevican in the wild-type situation. TN-C KO mice have a mild phenotype, but recover worse after spinal cord injury (Chen et al., 2010). In contrast, deficiency of TN-R improves functional recovery of mice after spinal cord injury (Apostolova et al., 2006). TN-R seems to restrict synaptic reorganization after injury, which is in line with the role of TN-R in PNNs. EphA4 KO mice exhibit reduced gliosis and improved functional recovery after spinal cord injury (Goldshmit et al., 2004). Therefore, EphA4 seems to regulate two important aspects in regeneration.
Extracellular matrix as target for improved recovery
Inhibitory matrix was the target of different approaches so far, a number of studies have been reviewed by Soleman et al. (2013). The function can be blocked with antibodies, specific inhibitors, by knockdown, or already synthetized ECM can proteolytically be degraded, for example by ADAM proteases (reviewed by Burnside and Bradbury, 2014). Inhibition of proteoglycan synthesis by β-D-Xylosides and sodium chlorate eliminates the inhibitory effect of astrocytic matrix on neurite growth in vitro (Smith-Thomas et al., 1995). Treatment with the Chondroitin sulfate-degrading enzyme Chondroitinase ABC (ChABC) revealed a recovery-promoting effect after spinal cord injury (Bradbury et al., 2002) and had neuroprotective effects (Chen et al., 2014). Although ChABC treatment is effective in many cases, ChABC-resistant inhibitory matrix also remains (Siddiqui et al., 2009) that needs to be addressed by other strategies. These inhibitory signals can be ascribed to the core protein part of PGs or to other molecules in the matrix. Treatment with antibodies directed against an extracellular factor relies on blocking its function. Studies using antibodies against Nogo-A (Zhao et al., 2013) and TN-R (You et al., 2012) have shown improved recovery from spinal cord injury. In addition to the aforementioned strategies that rely on the elimination of ECM function, delivery of regeneration-promoting ECM-related molecules is possible. For example, transplantation of L1CAM-overexpressing neural aggregates improved regeneration more effectively than those with normal L1CAM expression levels (Cui et al., 2011).
Possible mechanisms by which transplanted stem cells can promote regeneration in the context of ECM are discussed in the following third section.
Potential effects of endogenous and transplanted stem cells on regeneration
As described in the first section, endogenous progenitor-like cells appear in the damaged CNS. If a subset of astroglial cells starts to de-differentiate anyway, what could be the benefit of additional, transplanted stem cells? It is clear that in many cases positive effects are not due to cell replacement (Chopp et al., 2009). The last section of this review gives an overview of the different strategies behind stem cell therapies.
What are potential mechanisms by which transplanted stem cells support regeneration? Several strategies to improve recovery have been pursued so far (Burda and Sofroniew, 2014). Roughly the effects can be divided into three main aspects: (i) immune modulation; (ii) support of cell survival, differentiation, or axonal growth; and (iii) cell replacement (summarized in Figure 3A). Examples for factors that are produced by stem cells and their potential effects on regeneration are listed in Table 3. With regard to the phases of regeneration, where a first phase of cell death and inflammation (ca. 2 weeks) is followed by a phase of tissue replacement (days to weeks) and finally by tissue remodeling (months to years), at each time point different mechanisms have priority. This limits the time frame for efficient stem cell treatment (Figure 3B). Depending on the desired effect, stem cells of different origin and of different potential are the first choice.
Stem cell treatment and time line after CNS damage. (A) Stem cell transplantation can promote recovery by different mechanisms. Modulation of (i) the immune response; (ii) production of factors that regulate survival, differentiation, or axon growth; and (iii) cell replacement are possible mechanisms. (B) In a first phase, cell death and inflammation (ca. 2 weeks) predominate, followed by a phase of tissue replacement (days to weeks) and tissue remodeling (months to years). This limits the time frame for efficient stem cell treatment, as shown for different aspects involved in regeneration. (B) Modified from Burda and Sofroniew (2014).
Aspects potentially influenced by transplanted stem cells.
The following aspects may account for differences of cultured and transplanted cells in comparison to the endogenous stem/progenitor pool: (i) the cell number of stem/progenitor cells may be higher when additional cells are transplanted; (ii) the potential of the cultured cells may differ from their endogenous counterparts due to the treatment (stress, addition of factors to the medium, etc.); (iii) not only the potential to differentiate may be changed during culture, but also the factors these cells secrete could differ depending on the pretreatment, the origin, or the differentiation state; (iv) transplantation of stem cells could modulate the immune system and therefore act indirectly on the CNS; and (v) stem cells can also be used as vehicle: for example, genetically modified stem cells stably deliver neurotrophic or other factors to damaged tissue, e.g., CNTF (Jung et al., 2013).
Interaction of stem cells and the immune system
Immune cells can have both, positive and detrimental effects on regeneration, but also on the fate of endogenous and transplanted stem cells (reviewed by Martino et al., 2011; Kokaia et al., 2012). On the other hand, stem cells can modulate the immune response. For example, it has been shown that neurosphere-derived multipotent progenitors have a neuroprotective effect by immune modulation (Pluchino et al., 2005). Systemically transplanted NSCs improved recovery in a stroke model and reduced the expression of inflammation-associated genes (Bacigaluppi et al., 2009). Stem cells can also suppress T lymphocytes via increased nitric oxide and Prostaglandin E levels (Wang et al., 2009a).
In addition to the typical immune modulators mentioned above, molecules of the ECM can also influence the immune system: CSPGs do not only regulate axon growth, they are also able to modulate the immune response by binding to cytokines and Cluster of differentiation 44 (CD44; reviewed by Haylock-Jacobs et al., 2011). TN-C, a glycoprotein that is secreted by neural stem/progenitor cells in vitro (von Holst et al., 2007), can influence the immune system via Toll-like receptor (TLR) 4 (Midwood et al., 2009). TN-C and the immune system influence each other reciprocally: TN-C modulates the immune response, but is itself regulated by cytokines during inflammation. A detailed description is given in the review by Jakovcevski et al. (2013). Not only neural stem/progenitor cells can be utilized to improve recovery. For example, bone marrow stromal cells/mesenchymal stem cells (MSCs) reduce microglial activation (Yan et al., 2013). In addition to secreted factors, in the last years the role of exosomes in intercellular communication is being discussed (Ludwig and Giebel, 2012). These small vesicles loaded with lipids, proteins, and RNAs are released by MSCs and other cell types and might represent a mechanism by which transplanted cells can influence the immune system (Kordelas et al., 2014).
Production of neurotrophic factors and regulation of plasticity
As described, stem cells can support neuronal survival by modulating the immune response, but they can also have a direct neuroprotective effect. Stem cells produce neurotrophic factors like GDNF and NGF (Lladó et al., 2004). Furthermore, they express a number of ECM molecules that are present in the developing nervous system. Among them are CSPGs like Neurocan, Phosphacan carrying the DSD-1 epitope (Ida et al., 2006; von Holst et al., 2006) and, as already mentioned, the glycoprotein TN-C. Some of these factors are well-known for their impact on cell differentiation, migration, and axon growth. If these factors are able to influence regeneration after transplantation will mostly depend on the number of surviving cells. A positive effect of human neural progenitor cells on axonal transport and plasticity after stroke was in part attributed to VEGF, TSP and Slit expression (Andres et al., 2011). Transplanted cells that express MMPs or they counterparts, the Tissue inhibitors of metalloproteinases (TIMPs), can control the ECM composition. Also non-neural cells can affect plasticity. So expression of MMPs and TIMPs was shown in MSCs, with differences in the expression profile depending on the origin of the cells (Lozito et al., 2014). MSCs induce SHH expression in host astrocytes that increases plasticity in conjunction with tissue-type plasminogen activator (tPA; Samson and Medcalf, 2006; Ding et al., 2013).
Plasticity can be induced not only on the molecular level. Neural precursors transplanted into the visual cortex differentiated into inhibitory neurons and formed synapses to host cortical neurons, thereby promoting plasticity after the critical period (Southwell et al., 2010).
Neural differentiation and cell replacement by transplanted stem cells
Embryonic stem (ES) cells provide a source for the different cell types, because as pluripotent cells they can give rise to all cell types of the body, including neurons, astrocytes, and oligodendrocytes (Fraichard et al., 1995). To avoid the ethically problematic use of the embryo-derived ES cells, alternative sources for pluripotent cells were investigated. A promising alternative was described in 2006, when fibroblasts were reprogrammed to induced pluripotent stem cells (iPSCs; Takahashi and Yamanaka, 2006). The “Yamanaka cocktail” contains the four factors Oct3/4, Sox2, c-Myc, and Klf4. Subsequently, the number of factors could be reduced to two when adult neural stem cells were reprogrammed to iPSCs (Kim et al., 2008). Meanwhile, direct conversion of fibroblasts to induced neural stem cells (iNSCs) without a pluripotent state has been described (Han et al., 2012; Thier et al., 2012), reducing the risk of tumor induction by undifferentiated cells.
Cell fate decisions can be regulated, so astrocytic differentiation of transplanted NSCs is reduced when the CNTF is neutralized (Ishii et al., 2006). Astrocytes can be driven to a glutamatergic, NG2 glia to a glutamatergic and GABAergic neuronal cell fate by retroviral expression of the transcription factor NeuroD1 (Guo et al., 2014). Procedures for the directed differentiation into distinct neuronal subtypes exist, where cells are exposed to defined soluble and surface-bound factors. For example, glutamatergic (Zeng et al., 2010) and GABAergic (Maroof et al., 2013) neurons can be derived from ESCs or iPSCs. Also regional identities like retinal progenitors (Lamba et al., 2006) and subsequently photoreceptors can be produced (Lamba et al., 2010). But not only neurons, also oligodendrocytes as the myelinating cells of the CNS are important for regeneration and protocols are described that promote this cell fate (Neman and de Vellis, 2012). Functional integration of such cells was already shown, also for human cells (Tornero et al., 2013). A combined approach of stem cell-based treatment and manipulation of the ECM is the injection of neural stem cells with Chondroitinase ABC into the lesioned spinal cord (Ikegami et al., 2005). Axonal regrowth was significantly increased by the combined application.
Summary/Outlook
As shown in this review, the CNS reacts to damage by upregulation of numerous extracellular signaling molecules that in part resemble the neurogenic stem cell niche. In line with this, endogenous stem/progenitor-like cells can be observed in many lesion models. The ECM contains important regulators of cell survival, differentiation, migration, or neurite outgrowth and is able to modulate signaling of associated molecules, for example of growth factors. These signals and the intrinsic properties of the cells present in the lesioned CNS are responsible for the outcome after regeneration. Stem cell transplantation now aims to influence this system or to add cells that replace lost tissue to a certain degree. Some approaches exploit neuroprotective effects by the stem cells, whereas others depend on cell replacement after differentiation and functional integration of the cells. The latter requires a carefully orchestrated sequence of complex actions and therefore seems to be harder to achieve. Stem cell transplantation experiments in animals will help to learn more about the molecular mechanisms that influence regeneration, as they allow to manipulate specific aspects in this complex interplay.
Conflict of interest statement
The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.
We thank the International Graduate School of Neuroscience (IGSN), the RUB Research School of the Ruhr-University Bochum, and the German Research Foundation (DFG SFB 509, Fa 159/16-1) for financial support. In particular, we want to thank Prof. Dr. Ulf T. Eysel for performing the laser lesions in the mouse visual cortex (Figure 1).
ReferencesAdamsJ. C.LawlerJ. (2011). The thrombospondins. 3:a009712. 10.1101/cshperspect.a00971221875984AmankulorN. M.HambardzumyanD.PyonteckS. M.BecherO. J.JoyceJ. A.HollandE. C. (2009). Sonic hedgehog pathway activation is induced by acute brain injury and regulated by injury-related inflammation. 29, 10299–10308. 10.1523/jneurosci.2500-09.200919692604AndersonM. A.AoY.SofroniewM. V. (2014). Heterogeneity of reactive astrocytes. 565C, 23–29. 10.1016/j.neulet.2013.12.03024361547AndresR. H.HorieN.SlikkerW.Keren-GillH.ZhanK.SunG.. (2011). Human neural stem cells enhance structural plasticity and axonal transport in the ischaemic brain. 134, 1777–1789. 10.1093/brain/awr09421616972AnthisN. J.WegenerK. L.YeF.KimC.GoultB. T.LoweE. D.. (2009). The structure of an integrin/talin complex reveals the basis of inside-out signal transduction. 28, 3623–3632. 10.1038/emboj.2009.28719798053ApostolovaI.IrintchevA.SchachnerM. (2006). Tenascin-R restricts posttraumatic remodeling of motoneuron innervation and functional recovery after spinal cord injury in adult mice. 26, 7849–7859. 10.1523/jneurosci.1526-06.200616870730AraiK.JinG.NavaratnaD.LoE. H. (2009). Brain angiogenesis in developmental and pathological processes: neurovascular injury and angiogenic recovery after stroke. 276, 4644–4652. 10.1111/j.1742-4658.2009.07176.x19664070Arias-SalgadoE. G.LizanoS.SarkarS.BruggeJ. S.GinsbergM. H.ShattilS. J. (2003). Src kinase activation by direct interaction with the integrin beta cytoplasmic domain. 100, 13298–13302. 10.1073/pnas.233614910014593208ArmstrongL. C.BornsteinP. (2003). Thrombospondins 1 and 2 function as inhibitors of angiogenesis. 22, 63–71. 10.1016/s0945-053x(03)00005-212714043ArugaJ.TohmondaT.HommaS.MikoshibaK. (2002). Zic1 promotes the expansion of dorsal neural progenitors in spinal cord by inhibiting neuronal differentiation. 244, 329–341. 10.1006/dbio.2002.059811944941ArvidssonA.CollinT.KirikD.KokaiaZ.LindvallO. (2002). Neuronal replacement from endogenous precursors in the adult brain after stroke. 8, 963–970. 10.1038/nm74712161747AsherR. A.MorgensternD. A.FidlerP. S.AdcockK. H.OohiraA.BraisteadJ. E.. (2000). Neurocan is upregulated in injured brain and in cytokine-treated astrocytes. 20, 2427–2438. 10729323AsherR. A.MorgensternD. A.ShearerM. C.AdcockK. H.PeshevaP.FawcettJ. W. (2002). Versican is upregulated in CNS injury and is a product of oligodendrocyte lineage cells. 22, 2225–2236. 11896162BacigaluppiM.PluchinoS.Peruzzotti-JamettiL.KilicE.KilicU.SalaniG.. (2009). Delayed post-ischaemic neuroprotection following systemic neural stem cell transplantation involves multiple mechanisms. 132, 2239–2251. 10.1093/brain/awp17419617198BaetenK. M.AkassoglouK. (2011). Extracellular matrix and matrix receptors in blood-brain barrier formation and stroke. 71, 1018–1039. 10.1002/dneu.2095421780303BarkerR. A.DunnettS. B.FaissnerA.FawcettJ. W. (1996). The time course of loss of dopaminergic neurons and the gliotic reaction surrounding grafts of embryonic mesencephalon to the striatum. 141, 79–93. 10.1006/exnr.1996.01418797670BarkhoB. Z.MunozA. E.LiX.LiL.CunninghamL. A.ZhaoX. (2008). Endogenous matrix metalloproteinase (MMP)-3 and MMP-9 promote the differentiation and migration of adult neural progenitor cells in response to chemokines. 26, 3139–3149. 10.1634/stemcells.2008-051918818437Barnabé-HeiderF.GöritzC.SabelströmH.TakebayashiH.PfriegerF. W.MeletisK.. (2010). Origin of new glial cells in intact and injured adult spinal cord. 7, 470–482. 10.1016/j.stem.2010.07.01420887953BarneaG.GrumetM.MilevP.SilvennoinenO.LevyJ. B.SapJ.. (1994). Receptor tyrosine phosphatase beta is expressed in the form of proteoglycan and binds to the extracellular matrix protein tenascin. 269, 14349–14352. 7514167BeckerT.AnlikerB.BeckerC. G.TaylorJ.SchachnerM.MeyerR. L.. (2000). Tenascin-R inhibits regrowth of optic fibers in vitro and persists in the optic nerve of mice after injury. 29, 330–346. 10.1002/(sici)1098-1136(20000215)29:4<330::aid-glia4>3.0.co;2-l10652443BeggahA. T.Dours-ZimmermannM. T.BarrasF. M.BrosiusA.ZimmermannD. R.ZurnA. D. (2005). Lesion-induced differential expression and cell association of Neurocan, Brevican, Versican V1 and V2 in the mouse dorsal root entry zone. 133, 749–762. 10.1016/j.neuroscience.2005.03.00515896911BelkinA. M.SteppM. A. (2000). Integrins as receptors for laminins. 51, 280–301. 10.1002/1097-0029(20001101)51:3<280::aid-jemt7>3.0.co;2-o11054877BennerE. J.LucianoD.JoR.AbdiK.Paez-GonzalezP.ShengH.. (2013). Protective astrogenesis from the SVZ niche after injury is controlled by notch modulator Thbs4. 497, 369–373. 10.1038/nature1206923615612BesserM.Horvat-BröckerA.EyselU. T.FaissnerA. (2009). Differential expression of receptor protein tyrosine phosphatases accompanies the reorganisation of the retina upon laser lesion. 198, 37–47. 10.1007/s00221-009-1932-019639307BiberK.NeumannH.InoueK.BoddekeH. W. (2007). Neuronal ‘On’ and ‘Off’ signals control microglia. 30, 596–602. 10.1016/j.tins.2007.08.00717950926BignamiA.RajuT.DahlD. (1982). Localization of vimentin, the nonspecific intermediate filament protein, in embryonal glia and in early differentiating neurons. In vivo and in vitro immunofluorescence study of the rat embryo with vimentin and neurofilament antisera. 91, 286–295. 10.1016/0012-1606(82)90035-57047260BradburyE. J.MoonL. D.PopatR. J.KingV. R.BennettG. S.PatelP. N.. (2002). Chondroitinase ABC promotes functional recovery after spinal cord injury. 416, 636–640. 10.1038/416636a11948352BrennerM. (2014). Role of GFAP in CNS injuries. 565, 7–13. 10.1016/j.neulet.2014.01.05524508671BrizziM. F.TaroneG.DefilippiP. (2012). Extracellular matrix, integrins and growth factors as tailors of the stem cell niche. 24, 645–651. 10.1016/j.ceb.2012.07.00122898530Brosius LutzA.BarresB. A. (2014). Contrasting the glial response to axon injury in the central and peripheral nervous systems. 28, 7–17. 10.1016/j.devcel.2013.12.00224434136BrownJ. M.XiaJ.ZhuangB.ChoK. S.RogersC. J.GamaC. I.. (2012). A sulfated carbohydrate epitope inhibits axon regeneration after injury. 109, 4768–4773. 10.1073/pnas.112131810922411830BuddensiekJ.DresselA.KowalskiM.StorchA.SabolekM. (2009). Adult cerebrospinal fluid inhibits neurogenesis but facilitates gliogenesis from fetal rat neural stem cells. 87, 3054–3066. 10.1002/jnr.2215019530161BudinichC. S.ChenH.LoweD.RosenbergerJ. G.BernstockJ. D.McCabeJ. T. (2012). Mouse brain PSA-NCAM levels are altered by graded-controlled cortical impact injury. 2012:378307. 10.1155/2012/37830722848850BuffoA.RiteI.TripathiP.LepierA.ColakD.HornA. P.. (2008). Origin and progeny of reactive gliosis: a source of multipotent cells in the injured brain. 105, 3581–3586. 10.1073/pnas.070900210518299565BuffoA.RolandoC.CerutiS. (2010). Astrocytes in the damaged brain: molecular and cellular insights into their reactive response and healing potential. 79, 77–89. 10.1016/j.bcp.2009.09.01419765548BundesenL. Q.ScheelT. A.BregmanB. S.KromerL. F. (2003). Ephrin-B2 and EphB2 regulation of astrocyte-meningeal fibroblast interactions in response to spinal cord lesions in adult rats. 23, 7789–7800. 12944508BurdaJ. E.SofroniewM. V. (2014). Reactive gliosis and the multicellular response to CNS damage and disease. 81, 229–248. 10.1016/j.neuron.2013.12.03424462092BurnsideE. R.BradburyE. J. (2014). Manipulating the extracellular matrix and its role in brain and spinal cord plasticity and repair. 40, 26–59. 10.1111/nan.1211424438519CalofA. L.CampaneroM. R.O’RearJ. J.YurchencoP. D.LanderA. D. (1994). Domain-specific activation of neuronal migration and neurite outgrowth-promoting activities of laminin. 13, 117–130. 10.1016/0896-6273(94)90463-48043273CamposL. S. (2005). Beta1 integrins and neural stem cells: making sense of the extracellular environment. 27, 698–707. 10.1002/bies.2025615954093Candelario-JalilE.YangY.RosenbergG. A. (2009). Diverse roles of matrix metalloproteinases and tissue inhibitors of metalloproteinases in neuroinflammation and cerebral ischemia. 158, 983–994. 10.1016/j.neuroscience.2008.06.02518621108CarbonellW. S.MuraseS.HorwitzA. F.MandellJ. W. (2005). Migration of perilesional microglia after focal brain injury and modulation by CC chemokine receptor 5: an in situ time-lapse confocal imaging study. 25, 7040–7047. 10.1523/jneurosci.5171-04.200516049180CarmelietP. (2003). Blood vessels and nerves: common signals, pathways and diseases. 4, 710–720. 10.1038/nrg115812951572CarulliD.LaabsT.GellerH. M.FawcettJ. W. (2005). Chondroitin sulfate proteoglycans in neural development and regeneration. 15, 116–120. 10.1016/j.conb.2005.03.01815721753CastellaniV.ChédotalA.SchachnerM.Faivre-SarrailhC.RougonG. (2000). Analysis of the L1-deficient mouse phenotype reveals cross-talk between Sema3A and L1 signaling pathways in axonal guidance. 27, 237–249. 10.1016/s0896-6273(00)00033-710985345ChenM. S.HuberA. B.van der HaarM. E.FrankM.SchnellL.SpillmannA. A. (2000). Nogo-A is a myelin-associated neurite outgrowth inhibitor and an antigen for monoclonal antibody IN-1. 403, 434–439. 10.1038/3500021910667796ChenJ.Joon LeeH.JakovcevskiI.ShahR.BhagatN.LoersG.. (2010). The extracellular matrix glycoprotein tenascin-C is beneficial for spinal cord regeneration. 18, 1769–1777. 10.1038/mt.2010.13320606643ChenX. R.LiaoS. J.YeL. X.GongQ.DingQ.ZengJ. S.. (2014). Neuroprotective effect of chondroitinase ABC on primary and secondary brain injury after stroke in hypertensive rats. 1543, 324–333. 10.1016/j.brainres.2013.12.00224326094Chiquet-EhrismannR.ChiquetM. (2003). Tenascins: regulation and putative functions during pathological stress. 200, 488–499. 10.1002/path.141512845616Chiquet-EhrismannR.OrendG.ChiquetM.TuckerR. P.MidwoodK. S. (2014). Tenascins in stem cell niches. [Epub ahead of print]. 10.1016/j.matbio.2014.01.00724472737ChoppM.LiY.ZhangZ. G. (2009). Mechanisms underlying improved recovery of neurological function after stroke in the rodent after treatment with neurorestorative cell-based therapies. 40, S143–S145. 10.1161/strokeaha.108.53314119064763ChowJ. P.FujikawaA.ShimizuH.SuzukiR.NodaM. (2008). Metalloproteinase- and gamma-secretase-mediated cleavage of protein-tyrosine phosphatase receptor type Z. 283, 30879–30889. 10.1074/jbc.m80297620018713734ChristophersonK. S.UllianE. M.StokesC. C.MullowneyC. E.HellJ. W.AgahA.. (2005). Thrombospondins are astrocyte-secreted proteins that promote CNS synaptogenesis. 120, 421–433. 10.1016/j.cell.2004.12.02015707899ClarkR. A. (2008). Synergistic signaling from extracellular matrix-growth factor complexes. 128, 1354–1355. 10.1038/jid.2008.7518478010ColesC. H.ShenY.TenneyA. P.SieboldC.SuttonG. C.LuW.. (2011). Proteoglycan-specific molecular switch for RPTPsigma clustering and neuronal extension. 332, 484–488. 10.1126/science.120084021454754CondicM. L.LemonsM. L. (2002). Extracellular matrix in spinal cord regeneration: getting beyond attraction and inhibition. 13, A37–A48. 10.1097/00001756-200203040-0000211930141CraveiroL. M.WeinmannO.RoschitzkiB.GonzenbachR. R.ZörnerB.MontaniL.. (2013). Infusion of anti-Nogo-A antibodies in adult rats increases growth and synapse related proteins in the absence of behavioral alterations. 250, 52–68. 10.1016/j.expneurol.2013.09.01524076004CreggJ. M.DePaulM. A.FilousA. R.LangB. T.TranA.SilverJ. (2014). Functional regeneration beyond the glial scar. 253, 197–207. 10.1016/j.expneurol.2013.12.02424424280CuiY. F.XuJ. C.HargusG.JakovcevskiI.SchachnerM.BernreutherC. (2011). Embryonic stem cell-derived L1 overexpressing neural aggregates enhance recovery after spinal cord injury in mice. 6:e17126. 10.1371/journal.pone.001712621445247CzopkaT.von HolstA.ffrench-ConstantC.FaissnerA. (2010). Regulatory mechanisms that mediate tenascin C-dependent inhibition of oligodendrocyte precursor differentiation. 30, 12310–12322. 10.1523/jneurosci.4957-09.201020844127DaarI. O. (2012). Non-SH2/PDZ reverse signaling by ephrins. 23, 65–74. 10.1016/j.semcdb.2011.10.01222040914DasM.MohapatraS.MohapatraS. S. (2012). New perspectives on central and peripheral immune responses to acute traumatic brain injury. 9:236. 10.1186/1742-2094-9-23623061919DaviesJ. E.TangX.DenningJ. W.ArchibaldS. J.DaviesS. J. (2004). Decorin suppresses neurocan, brevican, phosphacan and NG2 expression and promotes axon growth across adult rat spinal cord injuries. 19, 1226–1242. 10.1111/j.1460-9568.2004.03184.x15016081DecknerM.LindholmT.CullheimS.RislingM. (2000). Differential expression of tenascin-C, tenascin-R, tenascin/J1 and tenascin-X in spinal cord scar tissue and in the olfactory system. 166, 350–362. 10.1006/exnr.2000.754311085900DeepaS. S.UmeharaY.HigashiyamaS.ItohN.SugaharaK. (2002). Specific molecular interactions of oversulfated chondroitin sulfate E with various heparin-binding growth factors. Implications as a physiological binding partner in the brain and other tissues. 277, 43707–43716. 10.1074/jbc.m20710520012221095De SimoneR.AmbrosiniE.CarnevaleD.Ajmone-CatM. A.MinghettiL. (2007). NGF promotes microglial migration through the activation of its high affinity receptor: modulation by TGF-beta. 190, 53–60. 10.1016/j.jneuroim.2007.07.02017868907DimitrijevicO. B.StamatovicS. M.KeepR. F.AndjelkovicA. V. (2006). Effects of the chemokine CCL2 on blood-brain barrier permeability during ischemia-reperfusion injury. 26, 797–810. 10.1038/sj.jcbfm.960022916192992DingX.LiY.LiuZ.ZhangJ.CuiY.ChenX.. (2013). The sonic hedgehog pathway mediates brain plasticity and subsequent functional recovery after bone marrow stromal cell treatment of stroke in mice. 33, 1015–1024. 10.1038/jcbfm.2013.5023549381DityatevA.SchachnerM. (2003). Extracellular matrix molecules and synaptic plasticity. 4, 456–468. 10.1038/nrn111512778118DobbertinA.CzvitkovichS.TheocharidisU.GarwoodJ.AndrewsM. R.ProperziF.. (2010). Analysis of combinatorial variability reveals selective accumulation of the fibronectin type III domains B and D of tenascin-C in injured brain. 225, 60–73. 10.1016/j.expneurol.2010.04.01920451518DobbertinA.RhodesK. E.GarwoodJ.ProperziF.HeckN.RogersJ. H.. (2003). Regulation of RPTPbeta/phosphacan expression and glycosaminoglycan epitopes in injured brain and cytokine-treated glia. 24, 951–971. 10.1016/s1044-7431(03)00257-414697661DoetschF.CailléI.LimD. A.García-VerdugoJ. M.Alvarez-BuyllaA. (1999). Subventricular zone astrocytes are neural stem cells in the adult mammalian brain. 97, 703–716. 10.1016/s0092-8674(00)80783-710380923DoetschF.García-VerdugoJ. M.Alvarez-BuyllaA. (1997). Cellular composition and three-dimensional organization of the subventricular germinal zone in the adult mammalian brain. 17, 5046–5061. 9185542DomogatskayaA.RodinS.TryggvasonK. (2012). Functional diversity of laminins. 28, 523–553. 10.1146/annurev-cellbio-101011-15575023057746DonnellyD. J.PopovichP. G. (2008). Inflammation and its role in neuroprotection, axonal regeneration and functional recovery after spinal cord injury. 209, 378–388. 10.1016/j.expneurol.2007.06.00917662717DouC. L.LevineJ. M. (1994). Inhibition of neurite growth by the NG2 chondroitin sulfate proteoglycan. 14, 7616–7628. 7996200DugasJ. C.MandemakersW.RogersM.IbrahimA.DanemanR.BarresB. A. (2008). A novel purification method for CNS projection neurons leads to the identification of brain vascular cells as a source of trophic support for corticospinal motor neurons. 28, 8294–8305. 10.1523/JNEUROSCI.2010-08.200818701692EddlestonM.MuckeL. (1993). Molecular profile of reactive astrocytes—implications for their role in neurologic disease. 54, 15–36. 10.1016/0306-4522(93)90380-x8515840ElkabesS.DiCicco-BloomE. M.BlackI. B. (1996). Brain microglia/macrophages express neurotrophins that selectively regulate microglial proliferation and function. 16, 2508–2521. 8786427EllisonJ. A.BaroneF. C.FeuersteinG. Z. (1999). Matrix remodeling after stroke. De novo expression of matrix proteins and integrin receptors. 890, 204–222. 10.1111/j.1749-6632.1999.tb07996.x10668427EmeryD. L.RoyoN. C.FischerI.SaatmanK. E.McIntoshT. K. (2003). Plasticity following injury to the adult central nervous system: is recapitulation of a developmental state worth promoting?20, 1271–1292. 10.1089/08977150332268608514748977FaissnerA. (1997). The tenascin gene family in axon growth and guidance. 290, 331–341. 10.1007/978-3-642-60905-3_199321695FaissnerA.ClementA.LochterA.StreitA.MandlC.SchachnerM. (1994). Isolation of a neural chondroitin sulfate proteoglycan with neurite outgrowth promoting properties. 126, 783–799. 10.1083/jcb.126.3.7837519189FaissnerA.PykaM.GeisslerM.SobikT.FrischknechtR.GundelfingerE. D.. (2010). Contributions of astrocytes to synapse formation and maturation—Potential functions of the perisynaptic extracellular matrix. 63, 26–38. 10.1016/j.brainresrev.2010.01.00120096729FaloM. C.ReevesT. M.PhillipsL. L. (2008). Agrin expression during synaptogenesis induced by traumatic brain injury. 25, 769–783. 10.1089/neu.2008.051118627255FillaM. S.DamP.RapraegerA. C. (1998). The cell surface proteoglycan syndecan-1 mediates fibroblast growth factor-2 binding and activity. 174, 310–321. 10.1002/(sici)1097-4652(199803)174:3<310::aid-jcp5>3.0.co;2-r9462693FilmusJ.CapurroM. (2014). The role of glypicans in hedgehog signaling. 35, 248–252. 10.1016/j.matbio.2013.12.00724412155FournierA. E.TakizawaB. T.StrittmatterS. M. (2003). Rho kinase inhibition enhances axonal regeneration in the injured CNS. 23, 1416–1423. 12598630FraichardA.ChassandeO.BilbautG.DehayC.SavatierP.SamarutJ. (1995). In vitro differentiation of embryonic stem cells into glial cells and functional neurons. 108(Pt. 10), 3181–3188. 7593279FriedlanderD. R.MilevP.KarthikeyanL.MargolisR. K.MargolisR. U.GrumetM. (1994). The neuronal chondroitin sulfate proteoglycan neurocan binds to the neural cell adhesion molecules Ng-CAM/L1/NILE and N-CAM and inhibits neuronal adhesion and neurite outgrowth. 125, 669–680. 10.1083/jcb.125.3.6697513709FuccilloM.JoynerA. L.FishellG. (2006). Morphogen to mitogen: the multiple roles of hedgehog signalling in vertebrate neural development. 7, 772–783. 10.1038/nrn199016988653FullerM. L.DeChantA. K.RothsteinB.CaprarielloA.WangR.HallA. K.. (2007). Bone morphogenetic proteins promote gliosis in demyelinating spinal cord lesions. 62, 288–300. 10.1002/ana.2117917696121GarcionE.HalilagicA.FaissnerA.ffrench-ConstantC. (2004). Generation of an environmental niche for neural stem cell development by the extracellular matrix molecule tenascin C. 131, 3423–3432. 10.1242/dev.0120215226258GarwoodJ.HeckN.ReichardtF.FaissnerA. (2003). Phosphacan short isoform, a novel non-proteoglycan variant of phosphacan/receptor protein tyrosine phosphatase-beta, interacts with neuronal receptors and promotes neurite outgrowth. 278, 24164–24173. 10.1074/jbc.m21172120012700241GatesM. A.ThomasL. B.HowardE. M.LaywellE. D.SajinB.FaissnerA.. (1995). Cell and molecular analysis of the developing and adult mouse subventricular zone of the cerebral hemispheres. 361, 249–266. 10.1002/cne.9036102058543661GattazzoF.UrciuoloA.BonaldoP. (2014). Extracellular matrix: a dynamic microenvironment for stem cell niche. 1840, 2506–2519. 10.1016/j.bbagen.2014.01.01024418517GeisslerM.GottschlingC.AguadoA.RauchU.WetzelC. H.HattH.. (2013). Primary hippocampal neurons, which lack four crucial extracellular matrix molecules, display abnormalities of synaptic structure and function and severe deficits in perineuronal net formation. 33, 7742–7755. 10.1523/jneurosci.3275-12.201323637166GivogriM. I.de PlanellM.GalbiatiF.SuperchiD.GrittiA.VescoviA.. (2006). Notch signaling in astrocytes and neuroblasts of the adult subventricular zone in health and after cortical injury. 28, 81–91. 10.1159/00009075516508306GladsonC. L. (1999). The extracellular matrix of gliomas: modulation of cell function. 58, 1029–1040. 10.1097/00005072-199910000-0000110515226GoldshmitY.GaleaM. P.WiseG.BartlettP. F.TurnleyA. M. (2004). Axonal regeneration and lack of astrocytic gliosis in EphA4-deficient mice. 24, 10064–10073. 10.1523/JNEUROSCI.2981-04.200415537875GoldshmitY.McLenachanS.TurnleyA. (2006). Roles of Eph receptors and ephrins in the normal and damaged adult CNS. 52, 327–345. 10.1016/j.brainresrev.2006.04.00616774788GordonP. B.ChoiH. U.ConnG.AhmedA.EhrmannB.RosenbergL.. (1989). Extracellular matrix heparan sulfate proteoglycans modulate the mitogenic capacity of acidic fibroblast growth factor. 140, 584–592. 10.1002/jcp.10414003252528552GöritzC.DiasD. O.TomilinN.BarbacidM.ShupliakovO.FrisénJ. (2011). A pericyte origin of spinal cord scar tissue. 333, 238–242. 10.1126/science.120316521737741GottschallP. E.YuX. (1995). Cytokines regulate gelatinase A and B (matrix metalloproteinase 2 and 9) activity in cultured rat astrocytes. 64, 1513–1520. 10.1046/j.1471-4159.1995.64041513.x7891077GrisP.TigheA.LevinD.SharmaR.BrownA. (2007). Transcriptional regulation of scar gene expression in primary astrocytes. 55, 1145–1155. 10.1002/glia.2053717597120GuanJ. L. (1997). Focal adhesion kinase in integrin signaling. 16, 195–200. 10.1016/S0945-053X(97)90008-19402009GuoW.GiancottiF. G. (2004). Integrin signalling during tumour progression. 5, 816–826. 10.1038/nrm149015459662GuoZ.ZhangL.WuZ.ChenY.WangF.ChenG. (2014). In vivo direct reprogramming of reactive glial cells into functional neurons after brain injury and in an Alzheimer’s disease model. 14, 188–202. 10.1016/j.stem.2013.12.00124360883HaasC. A.RauchU.ThonN.MertenT.DellerT. (1999). Entorhinal cortex lesion in adult rats induces the expression of the neuronal chondroitin sulfate proteoglycan neurocan in reactive astrocytes. 19, 9953–9963. 10559403HaginoS.IsekiK.MoriT.ZhangY.HikakeT.YokoyaS.. (2003). Slit and glypican-1 mRNAs are coexpressed in the reactive astrocytes of the injured adult brain. 42, 130–138. 10.1002/glia.1020712655597HamptonD. W.AsherR. A.KondoT.SteevesJ. D.RamerM. S.FawcettJ. W. (2007). A potential role for bone morphogenetic protein signalling in glial cell fate determination following adult central nervous system injury in vivo. 26, 3024–3035. 10.1111/j.1460-9568.2007.05940.x18028109HanS. S.LiuY.Tyler-PolszC.RaoM. S.FischerI. (2004). Transplantation of glial-restricted precursor cells into the adult spinal cord: survival, glial-specific differentiation and preferential migration in white matter. 45, 1–16. 10.1002/glia.1028214648541HanD. W.TapiaN.HermannA.HemmerK.HöingS.Araúzo-BravoM. J.. (2012). Direct reprogramming of fibroblasts into neural stem cells by defined factors. 10, 465–472. 10.1016/j.stem.2012.02.02122445517HarrochS.FurtadoG. C.BrueckW.RosenbluthJ.LafailleJ.ChaoM.. (2002). A critical role for the protein tyrosine phosphatase receptor type Z in functional recovery from demyelinating lesions. 32, 411–414. 10.1038/ng100412355066HausmannR.BetzP. (2001). Course of glial immunoreactivity for vimentin, tenascin and alpha1-antichymotrypsin after traumatic injury to human brain. 114, 338–342. 10.1007/s00414000019911508799Haylock-JacobsS.KeoughM. B.LauL.YongV. W. (2011). Chondroitin sulphate proteoglycans: extracellular matrix proteins that regulate immunity of the central nervous system. 10, 766–772. 10.1016/j.autrev.2011.05.01921664302HeckN.GarwoodJ.DobbertinA.CalcoV.SirkoS.MittmannT.. (2007). Evidence for distinct leptomeningeal cell-dependent paracrine and EGF-linked autocrine regulatory pathways for suppression of fibrillar collagens in astrocytes. 36, 71–85. 10.1016/j.mcn.2007.06.00217689979HetmanM.XiaZ. (2000). Signaling pathways mediating anti-apoptotic action of neurotrophins. 60, 531–545. 11200182HillW. D.HessD. C.Martin-StuddardA.CarothersJ. J.ZhengJ.HaleD.. (2004). SDF-1 (CXCL12) is upregulated in the ischemic penumbra following stroke: association with bone marrow cell homing to injury. 63, 84–96. 14748564HiranoS.YonezawaT.HasegawaH.HattoriS.GreenhillN. S.DavisP. F.. (2004). Astrocytes express type VIII collagen during the repair process of brain cold injury. 317, 437–443. 10.1016/j.bbrc.2004.03.04915063777HsuJ. Y.BourguignonL. Y.AdamsC. M.PeyrollierK.ZhangH.FandelT.. (2008). Matrix metalloproteinase-9 facilitates glial scar formation in the injured spinal cord. 28, 13467–13477. 10.1523/jneurosci.2287-08.200819074020IdaM.ShuoT.HiranoK.TokitaY.NakanishiK.MatsuiF.. (2006). Identification and functions of chondroitin sulfate in the milieu of neural stem cells. 281, 5982–5991. 10.1074/jbc.m50713020016373347IkegamiT.NakamuraM.YamaneJ.KatohH.OkadaS.IwanamiA.. (2005). Chondroitinase ABC combined with neural stem/progenitor cell transplantation enhances graft cell migration and outgrowth of growth-associated protein-43-positive fibers after rat spinal cord injury. 22, 3036–3046. 10.1111/j.1460-9568.2005.04492.x16367770ImitolaJ.RaddassiK.ParkK. I.MuellerF. J.NietoM.TengY. D.. (2004). Directed migration of neural stem cells to sites of CNS injury by the stromal cell-derived factor 1alpha/CXC chemokine receptor 4 pathway. 101, 18117–18122. 10.1073/pnas.040825810215608062IsekiK.HaginoS.MoriT.ZhangY.YokoyaS.TakakiH.. (2002). Increased syndecan expression by pleiotrophin and FGF receptor-expressing astrocytes in injured brain tissue. 39, 1–9. 10.1002/glia.1007812112370IshibashiS.KuroiwaT.SakaguchiM.SunL.KadoyaT.OkanoH.. (2007). Galectin-1 regulates neurogenesis in the subventricular zone and promotes functional recovery after stroke. 207, 302–313. 10.1016/j.expneurol.2007.06.02417706645IshiiK.NakamuraM.DaiH.FinnT. P.OkanoH.ToyamaY.. (2006). Neutralization of ciliary neurotrophic factor reduces astrocyte production from transplanted neural stem cells and promotes regeneration of corticospinal tract fibers in spinal cord injury. 84, 1669–1681. 10.1002/jnr.2107917044031JakemanL. B.ChenY.LucinK. M.McTigueD. M. (2006). Mice lacking L1 cell adhesion molecule have deficits in locomotion and exhibit enhanced corticospinal tract sprouting following mild contusion injury to the spinal cord. 23, 1997–2011. 10.1111/j.1460-9568.2006.04721.x16630048JakovcevskiI.MiljkovicD.SchachnerM.AndjusP. R. (2013). Tenascins and inflammation in disorders of the nervous system. 44, 1115–1127. 10.1007/s00726-012-1446-023269478JinK.ZhuY.SunY.MaoX. O.XieL.GreenbergD. A. (2002). Vascular endothelial growth factor (VEGF) stimulates neurogenesis in vitro and in vivo. 99, 11946–11950. 10.1073/pnas.18229649912181492JoesterA.FaissnerA. (1999). Evidence for combinatorial variability of tenascin-C isoforms and developmental regulation in the mouse central nervous system. 274, 17144–17151. 10.1074/jbc.274.24.1714410358070JoesterA.FaissnerA. (2001). The structure and function of tenascins in the nervous system. 20, 13–22. 10.1016/s0945-053x(00)00136-011246000JonesF. S.JonesP. L. (2000a). The tenascin family of ECM glycoproteins: structure, function and regulation during embryonic development and tissue remodeling. 218, 235–259. 10.1002/(sici)1097-0177(200006)218:2<235::aid-dvdy2>3.0.co;2-g10842355JonesP. L.JonesF. S. (2000b). Tenascin-C in development and disease: gene regulation and cell function. 19, 581–596. 10.1016/s0945-053x(00)00106-211102748JonesL. L.MargolisR. U.TuszynskiM. H. (2003). The chondroitin sulfate proteoglycans neurocan, brevican, phosphacan and versican are differentially regulated following spinal cord injury. 182, 399–411. 10.1016/S0014-4886(03)00087-612895450JonesL. L.YamaguchiY.StallcupW. B.TuszynskiM. H. (2002). NG2 is a major chondroitin sulfate proteoglycan produced after spinal cord injury and is expressed by macrophages and oligodendrocyte progenitors. 22, 2792–2803. 11923444JungG.SunJ.PetrowitzB.RieckenK.KruszewskiK.JankowiakW.. (2013). Genetically modified neural stem cells for a local and sustained delivery of neuroprotective factors to the dystrophic mouse retina. 2, 1001–1010. 10.5966/sctm.2013-001324167317KameiN.KwonS. M.IshikawaM.IiM.NakanishiK.YamadaK.. (2012). Endothelial progenitor cells promote astrogliosis following spinal cord injury through Jagged1-dependent notch signaling. 29, 1758–1769. 10.1089/neu.2011.213922452482KamphuisW.MamberC.MoetonM.KooijmanL.SluijsJ. A.JansenA. H.. (2012). GFAP isoforms in adult mouse brain with a focus on neurogenic astrocytes and reactive astrogliosis in mouse models of Alzheimer disease. 7:e42823. 10.1371/journal.pone.004282322912745Karetko-SysaM.Skangiel-KramskaJ.NowickaD. (2011). Disturbance of perineuronal nets in the perilesional area after photothrombosis is not associated with neuronal death. 231, 113–126. 10.1016/j.expneurol.2011.05.02221683696KarlénA.KarlssonT. E.MattssonA.LundströmerK.CodeluppiS.PhamT. M.. (2009). Nogo receptor 1 regulates formation of lasting memories. 106, 20476–20481. 10.1073/pnas.090539010619915139KarusM.DeneckeB.ffrench-ConstantC.WieseS.FaissnerA. (2011). The extracellular matrix molecule tenascin C modulates expression levels and territories of key patterning genes during spinal cord astrocyte specification. 138, 5321–5331. 10.1242/dev.06741322071102KazanisI.ffrench-ConstantC. (2011). Extracellular matrix and the neural stem cell niche. 71, 1006–1017. 10.1002/dneu.2097021898854KettenmannH.HanischU. K.NodaM.VerkhratskyA. (2011). Physiology of microglia. 91, 461–553. 10.1152/physrev.00011.201021527731KimH.AhnM.ChoiS.KimM.SimK. B.KimJ.. (2013). Potential role of fibronectin in microglia/macrophage activation following cryoinjury in the rat brain: an immunohistochemical study. 1502, 11–19. 10.1016/j.brainres.2013.01.04323380531KimJ. B.ZaehresH.WuG.GentileL.KoK.SebastianoV.. (2008). Pluripotent stem cells induced from adult neural stem cells by reprogramming with two factors. 454, 646–650. 10.1038/nature0706118594515KinouchiR.TakedaM.YangL.WilhelmssonU.LundkvistA.PeknyM.. (2003). Robust neural integration from retinal transplants in mice deficient in GFAP and vimentin. 6, 863–868. 10.1038/nn108812845328KlausmeyerA.GarwoodJ.FaissnerA. (2007). Differential expression of phosphacan/RPTPbeta isoforms in the developing mouse visual system. 504, 659–679. 10.1002/cne.2147917722031KokaiaZ.MartinoG.SchwartzM.LindvallO. (2012). Cross-talk between neural stem cells and immune cells: the key to better brain repair?15, 1078–1087. 10.1038/nn.316322837038KokovayE.GoderieS.WangY.LotzS.LinG.SunY.. (2010). Adult SVZ lineage cells home to and leave the vascular niche via differential responses to SDF1/CXCR4 signaling. 7, 163–173. 10.1016/j.stem.2010.05.01920682445KomitovaM.SerwanskiD. R.LuQ. R.NishiyamaA. (2011). NG2 cells are not a major source of reactive astrocytes after neocortical stab wound injury. 59, 800–809. 10.1002/glia.2115221351161KopanR.IlaganM. X. (2009). The canonical notch signaling pathway: unfolding the activation mechanism. 137, 216–233. 10.1016/j.cell.2009.03.04519379690KordelasL.RebmannV.LudwigA. K.RadtkeS.RuesingJ.DoeppnerT. R.. (2014). MSC-derived exosomes: a novel tool to treat therapy-refractory graft-versus-host disease. 28, 970–973. 10.1038/leu.2014.4124445866KruegerN. X.SaitoH. (1992). A human transmembrane protein-tyrosine-phosphatase, PTP zeta, is expressed in brain and has an N-terminal receptor domain homologous to carbonic anhydrases. 89, 7417–7421. 10.1073/pnas.89.16.74171323835KwokJ. C.DickG.WangD.FawcettJ. W. (2011). Extracellular matrix and perineuronal nets in CNS repair. 71, 1073–1089. 10.1002/dneu.2097421898855LambaD. A.KarlM. O.WareC. B.RehT. A. (2006). Efficient generation of retinal progenitor cells from human embryonic stem cells. 103, 12769–12774. 10.1073/pnas.060199010316908856LambaD. A.McUsicA.HirataR. K.WangP. R.RussellD.RehT. A. (2010). Generation, purification and transplantation of photoreceptors derived from human induced pluripotent stem cells. 5:e8763. 10.1371/journal.pone.000876320098701LangB.LiuH. L.LiuR.FengG. D.JiaoX. Y.JuG. (2004). Astrocytes in injured adult rat spinal cord may acquire the potential of neural stem cells. 128, 775–783. 10.1016/j.neuroscience.2004.06.03315464285LauE.MargolisR. U. (2010). Inhibitors of slit protein interactions with the heparan sulphate proteoglycan glypican-1: potential agents for the treatment of spinal cord injury. 37, 417–421. 10.1111/j.1440-1681.2009.05318.x19843094LaywellE. D.DörriesU.BartschU.FaissnerA.SchachnerM.SteindlerD. A. (1992). Enhanced expression of the developmentally regulated extracellular matrix molecule tenascin following adult brain injury. 89, 2634–2638. 10.1073/pnas.89.7.26341372985LeeB.ClarkeD.Al AhmadA.KahleM.ParhamC.AucklandL.. (2011). Perlecan domain V is neuroprotective and proangiogenic following ischemic stroke in rodents. 121, 3005–3023. 10.1172/JCI4635821747167LeeJ. K.KimJ. E.SivulaM.StrittmatterS. M. (2004). Nogo receptor antagonism promotes stroke recovery by enhancing axonal plasticity. 24, 6209–6217. 10.1523/jneurosci.1643-04.200415240813LeitingerB.HohenesterE. (2007). Mammalian collagen receptors. 26, 146–155. 10.1016/j.matbio.2006.10.00717141492LendahlU.ZimmermanL. B.McKayR. D. (1990). CNS stem cells express a new class of intermediate filament protein. 60, 585–595. 10.1016/0092-8674(90)90662-x1689217LeonardW. J.LinJ. X. (2000). Cytokine receptor signaling pathways. 105, 877–888. 10.1067/mai.2000.10689910808165LevineJ. M. (1994). Increased expression of the NG2 chondroitin-sulfate proteoglycan after brain injury. 14, 4716–4730. 8046446LevisonS. W.JiangF. J.StoltzfusO. K.DucceschiM. H. (2000). IL-6-type cytokines enhance epidermal growth factor-stimulated astrocyte proliferation. 32, 328–337. 10.1002/1098-1136(200012)32:3<328::aid-glia110>3.0.co;2-711102972LiL.LundkvistA.AnderssonD.WilhelmssonU.NagaiN.PardoA. C.. (2008). Protective role of reactive astrocytes in brain ischemia. 28, 468–481. 10.1038/sj.jcbfm.960054617726492LichtT.GoshenI.AvitalA.KreiselT.ZubedatS.EavriR.. (2011). Reversible modulations of neuronal plasticity by VEGF. 108, 5081–5086. 10.1073/pnas.100764010821385942LiebscherT.SchnellL.SchnellD.SchollJ.SchneiderR.GulloM.. (2005). Nogo-A antibody improves regeneration and locomotion of spinal cord-injured rats. 58, 706–719. 10.1002/ana.2062716173073LiesiP.KauppilaT. (2002). Induction of type IV collagen and other basement-membrane-associated proteins after spinal cord injury of the adult rat may participate in formation of the glial scar. 173, 31–45. 10.1006/exnr.2001.780011771937LiesiP.KaakkolaS.DahlD.VaheriA. (1984). Laminin is induced in astrocytes of adult brain by injury. 3, 683–686. 6370690LimD. A.TramontinA. D.TrevejoJ. M.HerreraD. G.García-VerdugoJ. M.Alvarez-BuyllaA. (2000). Noggin antagonizes BMP signaling to create a niche for adult neurogenesis. 28, 713–726. 10.1016/s0896-6273(00)00148-311163261LinT. N.KimG. M.ChenJ. J.CheungW. M.HeY. Y.HsuC. Y. (2003). Differential regulation of thrombospondin-1 and thrombospondin-2 after focal cerebral ischemia/reperfusion. 34, 177–186. 10.1161/01.str.0000047100.84604.ba12511771LindholmD.CastrénE.KieferR.ZafraF.ThoenenH. (1992). Transforming growth factor-beta 1 in the rat brain: increase after injury and inhibition of astrocyte proliferation. 117, 395–400. 10.1083/jcb.117.2.3951560032LindholmD.HengererB.ZafraF.ThoenenH. (1990). Transforming growth factor-beta 1 stimulates expression of nerve growth factor in the rat CNS. 1, 9–12. 10.1097/00001756-199009000-000032129862LiuY.RaoM. S. (2004). Glial progenitors in the CNS and possible lineage relationships among them. 96, 279–290. 10.1111/j.1768-322x.2004.tb01416.x15145532LiuY.WangX.LuC. C.KermanR.StewardO.XuX. M.. (2008). Repulsive Wnt signaling inhibits axon regeneration after CNS injury. 28, 8376–8382. 10.1523/JNEUROSCI.1939-08.200818701700LladóJ.HaenggeliC.MaragakisN. J.SnyderE. Y.RothsteinJ. D. (2004). Neural stem cells protect against glutamate-induced excitotoxicity and promote survival of injured motor neurons through the secretion of neurotrophic factors. 27, 322–331. 10.1016/j.mcn.2004.07.01015519246LozitoT. P.JacksonW. M.NestiL. J.TuanR. S. (2014). Human mesenchymal stem cells generate a distinct pericellular zone of MMP activities via binding of MMPs and secretion of high levels of TIMPs. 34, 132–143. 10.1016/j.matbio.2013.10.00324140982LudwigA. K.GiebelB. (2012). Exosomes: small vesicles participating in intercellular communication. 44, 11–15. 10.1016/j.biocel.2011.10.00522024155MakiT.LiangA. C.MiyamotoN.LoE. H.AraiK. (2013). Mechanisms of oligodendrocyte regeneration from ventricular-subventricular zone-derived progenitor cells in white matter diseases. 7:275. 10.3389/fncel.2013.0027524421755ManessP. F.SchachnerM. (2007). Neural recognition molecules of the immunoglobulin superfamily: signaling transducers of axon guidance and neuronal migration. 10, 19–26. 10.1038/nn182717189949MannsR. P.CookG. M.HoltC. E.KeynesR. J. (2012). Differing semaphorin 3A concentrations trigger distinct signaling mechanisms in growth cone collapse. 32, 8554–8559. 10.1523/jneurosci.5964-11.201222723695MaroofA. M.KerosS.TysonJ. A.YingS. W.GanatY. M.MerkleF. T.. (2013). Directed differentiation and functional maturation of cortical interneurons from human embryonic stem cells. 12, 559–572. 10.1016/j.stem.2013.04.00823642365MartinoG.PluchinoS.BonfantiL.SchwartzM. (2011). Brain regeneration in physiology and pathology: the immune signature driving therapeutic plasticity of neural stem cells. 91, 1281–1304. 10.1152/physrev.00032.201022013212MassouhM.SaghatelyanA. (2010). De-routing neuronal precursors in the adult brain to sites of injury: role of the vasculature. 58, 877–883. 10.1016/j.neuropharm.2009.12.02120045706McKeonR. J.HökeA.SilverJ. (1995). Injury-induced proteoglycans inhibit the potential for laminin-mediated axon growth on astrocytic scars. 136, 32–43. 10.1006/exnr.1995.10817589332McKeonR. J.JurynecM. J.BuckC. R. (1999). The chondroitin sulfate proteoglycans neurocan and phosphacan are expressed by reactive astrocytes in the chronic CNS glial scar. 19, 10778–10788. 10594061McKeonR. J.SchreiberR. C.RudgeJ. S.SilverJ. (1991). Reduction of neurite outgrowth in a model of glial scarring following CNS injury is correlated with the expression of inhibitory molecules on reactive astrocytes. 11, 3398–3411. 1719160McTigueD. M.PopovichP. G.MorganT. E.StokesB. T. (2000). Localization of transforming growth factor-beta1 and receptor mRNA after experimental spinal cord injury. 163, 220–230. 10.1006/exnr.2000.737210785461MengK.Rodriguez-PeñaA.DimitrovT.ChenW.YaminM.NodaM.. (2000). Pleiotrophin signals increased tyrosine phosphorylation of beta beta-catenin through inactivation of the intrinsic catalytic activity of the receptor-type protein tyrosine phosphatase beta/zeta. 97, 2603–2608. 10.1073/pnas.02048799710706604MidwoodK.SacreS.PiccininiA. M.InglisJ.TrebaulA.ChanE.. (2009). Tenascin-C is an endogenous activator of toll-like receptor 4 that is essential for maintaining inflammation in arthritic joint disease. 15, 774–780. 10.1038/nm.198719561617MilevP.ChibaA.HäringM.RauvalaH.SchachnerM.RanschtB.. (1998a). High affinity binding and overlapping localization of neurocan and phosphacan/protein-tyrosine phosphatase-zeta/beta with tenascin-R, amphoterin and the heparin-binding growth-associated molecule. 273, 6998–7005. 10.1074/jbc.273.12.69989507007MilevP.MonnerieH.PoppS.MargolisR. K.MargolisR. U. (1998b). The core protein of the chondroitin sulfate proteoglycan phosphacan is a high-affinity ligand of fibroblast growth factor-2 and potentiates its mitogenic activity. 273, 21439–21442. 10.1074/jbc.273.34.214399705269MilnerR.CrockerS. J.HungS.WangX.FraustoR. F.del ZoppoG. J. (2007). Fibronectin- and vitronectin-induced microglial activation and matrix metalloproteinase-9 expression is mediated by integrins alpha5beta1 and alphavbeta5. 178, 8158–8167. 10.4049/jimmunol.178.12.815817548654MöllerJ. C.KleinM. A.HaasS.JonesL. L.KreutzbergG. W.RaivichG. (1996). Regulation of thrombospondin in the regenerating mouse facial motor nucleus. 17, 121–132. 10.1002/(sici)1098-1136(199606)17:2<121::aid-glia4>3.3.co;2-b8776579MorawskiM.BrücknerG.JagerC.SeegerG.MatthewsR. T.ArendtT. (2012). Involvement of perineuronal and perisynaptic extracellular matrix in Alzheimer’s disease neuropathology. 22, 547–561. 10.1111/j.1750-3639.2011.00557.x22126211MorganT. E.NicholsN. R.PasinettiG. M.FinchC. E. (1993). TGF-beta 1 mRNA increases in macrophage/microglial cells of the hippocampus in response to deafferentation and kainic acid-induced neurodegeneration. 120, 291–301. 10.1006/exnr.1993.10638491285MoritzS.LehmannS.FaissnerA.von HolstA. (2008). An induction gene trap screen in neural stem cells reveals an instructive function of the niche and identifies the splicing regulator sam68 as a tenascin-C-regulated target gene. 26, 2321–2331. 10.1634/stemcells.2007-109518617690MuirE. M.AdcockK. H.MorgensternD. A.ClaytonR.von StillfriedN.RhodesK.. (2002). Matrix metalloproteases and their inhibitors are produced by overlapping populations of activated astrocytes. 100, 103–117. 10.1016/s0169-328x(02)00132-812008026NagS.EskandarianM. R.DavisJ.EubanksJ. H. (2002). Differential expression of vascular endothelial growth factor-A (VEGF-A) and VEGF-B after brain injury. 61, 778–788. 12230324NakamuraM.BregmanB. S. (2001). Differences in neurotrophic factor gene expression profiles between neonate and adult rat spinal cord after injury. 169, 407–415. 10.1006/exnr.2001.767011358454NakicM.MitrovicN.SperkG.SchachnerM. (1996). Kainic acid activates transient expression of tenascin-C in the adult rat hippocampus. 44, 355–362. 10.1002/(sici)1097-4547(19960515)44:4<355::aid-jnr7>3.3.co;2-h8739155NemanJ.de VellisJ. (2012). A method for deriving homogenous population of oligodendrocytes from mouse embryonic stem cells. 72, 777–788. 10.1002/dneu.2200822234971NeufeldG.KesslerO. (2008). The semaphorins: versatile regulators of tumour progression and tumour angiogenesis. 8, 632–645. 10.1038/nrc240418580951NiclouS. P.FranssenE. H.EhlertE. M.TaniguchiM.VerhaagenJ. (2003). Meningeal cell-derived semaphorin 3A inhibits neurite outgrowth. 24, 902–912. 10.1016/s1044-7431(03)00243-414697657NielsenJ.GotfrydK.LiS.KulahinN.SorokaV.RasmussenK. K.. (2009). Role of glial cell line-derived neurotrophic factor (GDNF)-neural cell adhesion molecule (NCAM) interactions in induction of neurite outgrowth and identification of a binding site for NCAM in the heel region of GDNF. 29, 11360–11376. 10.1523/JNEUROSCI.3239-09.200919741142NiquetJ.JorqueraI.FaissnerA.Ben-AriY.RepresaA. (1995). Gliosis and axonal sprouting in the hippocampus of epileptic rats are associated with an increase of tenascin-C immunoreactivity. 24, 611–624. 10.1007/bf012573767595669NobleL. J.DonovanF.IgarashiT.GoussevS.WerbZ. (2002). Matrix metalloproteinases limit functional recovery after spinal cord injury by modulation of early vascular events. 22, 7526–7535. 12196576ObermairF. J.SchröterA.ThallmairM. (2008). Endogenous neural progenitor cells as therapeutic target after spinal cord injury. 23, 296–304. 10.1152/physiol.00017.200818927205OvermanJ. J.CarmichaelS. T. (2014). Plasticity in the injured brain: more than molecules matter. 20, 15–28. 10.1177/107385841349114623757300PanchisionD. M. (2009). The role of oxygen in regulating neural stem cells in development and disease. 220, 562–568. 10.1002/jcp.2181219441077PariserH.EzquerraL.HerradonG.Perez-PineraP.DeuelT. F. (2005a). Fyn is a downstream target of the pleiotrophin/receptor protein tyrosine phosphatase beta/zeta-signaling pathway: regulation of tyrosine phosphorylation of Fyn by pleiotrophin. 332, 664–669. 10.1016/j.bbrc.2005.05.00715925565PariserH.Perez-PineraP.EzquerraL.HerradonG.DeuelT. F. (2005b). Pleiotrophin stimulates tyrosine phosphorylation of beta-adducin through inactivation of the transmembrane receptor protein tyrosine phosphatase beta/zeta. 335, 232–239. 10.1016/j.bbrc.2005.07.06016105548PasterkampR. J.GigerR. J.RuitenbergM. J.HoltmaatA. J.De WitJ.De WinterF.. (1999). Expression of the gene encoding the chemorepellent semaphorin III is induced in the fibroblast component of neural scar tissue formed following injuries of adult but not neonatal CNS. 13, 143–166. 10.1006/mcne.1999.073810192772PatelJ.ChannonK. M.McNeillE. (2013). The downstream regulation of chemokine receptor signalling: implications for atherosclerosis. 2013:459520. 10.1155/2013/45952023690662PeknyM.NilssonM. (2005). Astrocyte activation and reactive gliosis. 50, 427–434. 10.1002/glia.2020715846805PeknyM.WilhelmssonU.PeknaM. (2014). The dual role of astrocyte activation and reactive gliosis. 565C, 30–38. 10.1016/j.neulet.2013.12.07124406153PetrasekT.ProkopovaI.BahnikS.SchonigK.BergerS.ValesK.. (2014). Nogo-A downregulation impairs place avoidance in the Carousel maze but not spatial memory in the morris water maze. 107, 42–49. 10.1016/j.nlm.2013.10.01524211256PetrosyanH. A.HunanyanA. S.AlessiV.SchnellL.LevineJ.ArvanianV. L. (2013). Neutralization of inhibitory molecule NG2 improves synaptic transmission, retrograde transport and locomotor function after spinal cord injury in adult rats. 33, 4032–4043. 10.1523/JNEUROSCI.4702-12.201323447612PiccinD.MorsheadC. M. (2011). Wnt signaling regulates symmetry of division of neural stem cells in the adult brain and in response to injury. 29, 528–538. 10.1002/stem.58921425415PizzorussoT.MediniP.BerardiN.ChierziS.FawcettJ. W.MaffeiL. (2002). Reactivation of ocular dominance plasticity in the adult visual cortex. 298, 1248–1251. 10.1126/science.107269912424383PluchinoS.MuzioL.ImitolaJ.DeleidiM.Alfaro-CervelloC.SalaniG.. (2008). Persistent inflammation alters the function of the endogenous brain stem cell compartment. 131, 2564–2578. 10.1093/brain/awn19818757884PluchinoS.ZanottiL.RossiB.BrambillaE.OttoboniL.SalaniG.. (2005). Neurosphere-derived multipotent precursors promote neuroprotection by an immunomodulatory mechanism. 436, 266–271. 10.1038/nature0388916015332PozziA.WaryK. K.GiancottiF. G.GardnerH. A. (1998). Integrin alpha1beta1 mediates a unique collagen-dependent proliferation pathway in vivo. 142, 587–594. 10.1083/jcb.142.2.5879679154PykaM.WetzelC.AguadoA.GeisslerM.HattH.FaissnerA. (2011). Chondroitin sulfate proteoglycans regulate astrocyte-dependent synaptogenesis and modulate synaptic activity in primary embryonic hippocampal neurons. 33, 2187–2202. 10.1111/j.1460-9568.2011.07690.x21615557QuagliaX.BeggahA. T.SeidenbecherC.ZurnA. D. (2008). Delayed priming promotes CNS regeneration post-rhizotomy in Neurocan and Brevican-deficient mice. 131, 240–249. 10.1093/brain/awm27918065437RapraegerA. C.KrufkaA.OlwinB. B. (1991). Requirement of heparan sulfate for bFGF-mediated fibroblast growth and myoblast differentiation. 252, 1705–1708. 10.1126/science.16464841646484RauchU.ClementA.RetzlerC.FröhlichL.FässlerR.GöhringW.. (1997). Mapping of a defined neurocan binding site to distinct domains of tenascin-C. 272, 26905–26912. 10.1074/jbc.272.43.269059341124ResoviA.PinessiD.ChiorinoG.TarabolettiG. (2014). Current understanding of the thrombospondin-1 interactome. [Epub ahead of print]. 10.1016/j.matbio.2014.01.01224476925ReyaT.CleversH. (2005). Wnt signalling in stem cells and cancer. 434, 843–850. 10.1038/nature0331915829953Ricard-BlumS. (2011). The collagen family. 3:a004978. 10.1101/cshperspect.a00497821421911RigatoF.GarwoodJ.CalcoV.HeckN.Faivre-SarrailhC.FaissnerA. (2002). Tenascin-C promotes neurite outgrowth of embryonic hippocampal neurons through the alternatively spliced fibronectin type III BD domains via activation of the cell adhesion molecule F3/contactin. 22, 6596–6609. 12151539RobelS.BerningerB.GötzM. (2011). The stem cell potential of glia: lessons from reactive gliosis. 12, 88–104. 10.1038/nrn297821248788RolandoC.ParolisiR.BodaE.SchwabM. E.RossiF.BuffoA. (2012). Distinct roles of nogo-a and nogo receptor 1 in the homeostatic regulation of adult neural stem cell function and neuroblast migration. 32, 17788–17799. 10.1523/JNEUROSCI.3142-12.201223223298RollL.MittmannT.EyselU. T.FaissnerA. (2012). The laser lesion of the mouse visual cortex as a model to study neural extracellular matrix remodeling during degeneration, regeneration and plasticity of the CNS. 349, 133–145. 10.1007/s00441-011-1313-422277993RollsA.ShechterR.SchwartzM. (2009). The bright side of the glial scar in CNS repair. 10, 235–241. 10.1038/nrn259119229242RoncaF.AndersenJ. S.PaechV.MargolisR. U. (2001). Characterization of slit protein interactions with glypican-1. 276, 29141–29147. 10.1074/jbc.m10024020011375980RosenkranzK.KumbruchS.LebermannK.MarschnerK.JensenA.DermietzelR.. (2010). The chemokine SDF-1/CXCL12 contributes to the ’homing’ of umbilical cord blood cells to a hypoxic-ischemic lesion in the rat brain. 88, 1223–1233. 10.1002/jnr.2229219937807RostèneW.DansereauM. A.GodefroyD.Van SteenwinckelJ.Reaux-Le GoazigoA.Mélik-ParsadaniantzS.. (2011). Neurochemokines: a menage a trois providing new insights on the functions of chemokines in the central nervous system. 118, 680–694. 10.1111/j.1471-4159.2011.07371.x21722132SalangaC. L.O’HayreM.HandelT. (2009). Modulation of chemokine receptor activity through dimerization and crosstalk. 66, 1370–1386. 10.1007/s00018-008-8666-119099182SamsonA. L.MedcalfR. L. (2006). Tissue-type plasminogen activator: a multifaceted modulator of neurotransmission and synaptic plasticity. 50, 673–678. 10.1016/j.neuron.2006.04.01316731507SarkarS.RaymickJ.SchmuedL. (2012). Temporal progression of kainic acid induced changes in vascular laminin expression in rat brain with neuronal and glial correlates. 9, 110–119. 10.2174/15672021280041086722475395SasakiN.KurisuJ.KengakuM. (2010). Sonic hedgehog signaling regulates actin cytoskeleton via Tiam1-Rac1 cascade during spine formation. 45, 335–344. 10.1016/j.mcn.2010.07.00620654717SavitzS. I.CramerS. C.WechslerL.ConsortiumS. (2014). Stem cells as an emerging paradigm in stroke 3: enhancing the development of clinical trials. 45, 634–639. 10.1161/STROKEAHA.113.00337924368562SchachtrupC.RyuJ. K.HelmrickM. J.VagenaE.GalanakisD. K.DegenJ. L.. (2010). Fibrinogen triggers astrocyte scar formation by promoting the availability of active TGF-beta after vascular damage. 30, 5843–5854. 10.1523/JNEUROSCI.0137-10.201020427645SchlessingerJ.UllrichA. (1992). Growth factor signaling by receptor tyrosine kinases. 9, 383–391. 10.1016/0896-6273(92)90177-F1326293SchmandkeA.SchmandkeA.SchwabM. E. (2014). Nogo-A: multiple roles in CNS development, maintenance and disease. 20, 372–386. 10.1177/107385841351680024402613SchwabM. E.StrittmatterS. M. (2014). Nogo limits neural plasticity and recovery from injury. 27C, 53–60. 10.1016/j.conb.2014.02.01124632308Scott-DrewS.ffrench-ConstantC. (1997). Expression and function of thrombospondin-1 in myelinating glial cells of the central nervous system. 50, 202–214. 10.1002/(sici)1097-4547(19971015)50:2<202::aid-jnr9>3.0.co;2-j9373030SeidenfadenR.DesoeuvreA.BosioA.VirardI.CremerH. (2006). Glial conversion of SVZ-derived committed neuronal precursors after ectopic grafting into the adult brain. 32, 187–198. 10.1016/j.mcn.2006.04.00316730456SemenovM. V.HabasR.MacdonaldB. T.HeX. (2007). SnapShot: noncanonical Wnt signaling pathways. 131, 1378.e1–1378.e2. 10.1016/j.cell.2007.12.01118160045SeoJ. H.MiyamotoN.HayakawaK.PhamL. D.MakiT.AyataC.. (2013). Oligodendrocyte precursors induce early blood-brain barrier opening after white matter injury. 123, 782–786. 10.1172/JCI6586323281396SharmaA.PollettM. A.PlantG. W.HarveyA. R. (2012a). Changes in mRNA expression of class 3 semaphorins and their receptors in the adult rat retino-collicular system after unilateral optic nerve injury. 53, 8367–8377. 10.1167/iovs.12-1079923139269SharmaK.SelzerM. E.LiS. (2012b). Scar-mediated inhibition and CSPG receptors in the CNS. 237, 370–378. 10.1016/j.expneurol.2012.07.00922836147ShenQ.WangY.KokovayE.LinG.ChuangS. M.GoderieS. K.. (2008). Adult SVZ stem cells lie in a vascular niche: a quantitative analysis of niche cell-cell interactions. 3, 289–300. 10.1016/j.stem.2008.07.02618786416ShimadaI. S.LeComteM. D.GrangerJ. C.QuinlanN. J.SpeesJ. L. (2012). Self-renewal and differentiation of reactive astrocyte-derived neural stem/progenitor cells isolated from the cortical peri-infarct area after stroke. 32, 7926–7940. 10.1523/JNEUROSCI.4303-11.201222674268ShimadaI. S.PetersonB. M.SpeesJ. L. (2010). Isolation of locally derived stem/progenitor cells from the peri-infarct area that do not migrate from the lateral ventricle after cortical stroke. 41, e552–e560. 10.1161/STROKEAHA.110.58901020671247SiddiquiS.Horvat-BroeckerA.FaissnerA. (2009). Comparative screening of glial cell types reveals extracellular matrix that inhibits retinal axon growth in a chondroitinase ABC-resistant fashion. 57, 1420–1438. 10.1002/glia.2086019243018SilverJ.MillerJ. H. (2004). Regeneration beyond the glial scar. 5, 146–156. 10.1038/nrn132614735117SinghP.CarraherC.SchwarzbauerJ. E. (2010). Assembly of fibronectin extracellular matrix. 26, 397–419. 10.1146/annurev-cellbio-100109-10402020690820SiriA.KnäuperV.VeiranaN.CaocciF.MurphyG.ZardiL. (1995). Different susceptibility of small and large human tenascin-C isoforms to degradation by matrix metalloproteinases. 270, 8650–8654. 10.1074/jbc.270.15.86507536739SirkoS.BehrendtG.JohanssonP. A.TripathiP.CostaM.BekS.. (2013). Reactive glia in the injured brain acquire stem cell properties in response to sonic hedgehog. [corrected]. 12, 426–439. 10.1016/j.stem.2013.01.01923561443SirkoS.NeitzA.MittmannT.Horvat-BröckerA.von HolstA.EyselU. T.. (2009). Focal laser-lesions activate an endogenous population of neural stem/progenitor cells in the adult visual cortex. 132, 2252–2264. 10.1093/brain/awp04319286696SiuR.FladdC.RotinD. (2007). N-cadherin is an in vivo substrate for protein tyrosine phosphatase sigma (PTPsigma) and participates in PTPsigma-mediated inhibition of axon growth. 27, 208–219. 10.1128/mcb.00707-0617060446SmithG. M.HaleJ. H. (1997). Macrophage/Microglia regulation of astrocytic tenascin: synergistic action of transforming growth factor-beta and basic fibroblast growth factor. 17, 9624–9633. 9391017Smith-ThomasL. C.StevensJ.Fok-SeangJ.FaissnerA.RogersJ. H.FawcettJ. W. (1995). Increased axon regeneration in astrocytes grown in the presence of proteoglycan synthesis inhibitors. 108(Pt. 3), 1307–1315. 7622613SobelR. A. (1998). The extracellular matrix in multiple sclerosis lesions. 57, 205–217. 10.1097/00005072-199803000-000019600212SofroniewM. V. (2009). Molecular dissection of reactive astrogliosis and glial scar formation. 32, 638–647. 10.1016/j.tins.2009.08.00219782411SolemanS.FilippovM. A.DityatevA.FawcettJ. W. (2013). Targeting the neural extracellular matrix in neurological disorders. 253, 194–213. 10.1016/j.neuroscience.2013.08.05024012743SouthwellD. G.FroemkeR. C.Alvarez-BuyllaA.StrykerM. P.GandhiS. P. (2010). Cortical plasticity induced by inhibitory neuron transplantation. 327, 1145–1148. 10.1126/science.118396220185728SteigemannP.MolitorA.FellertS.JäckleH.VorbrüggenG. (2004). Heparan sulfate proteoglycan syndecan promotes axonal and myotube guidance by slit/robo signaling. 14, 225–230. 10.1016/s0960-9822(04)00007-714761655StichelC. C.KapplerJ.JunghansU.KoopsA.KresseH.MüllerH. W. (1995). Differential expression of the small chondroitin/dermatan sulfate proteoglycans decorin and biglycan after injury of the adult rat brain. 704, 263–274. 10.1016/0006-8993(95)01131-58788923StummR. K.RummelJ.JunkerV.CulmseeC.PfeifferM.KrieglsteinJ.. (2002). A dual role for the SDF-1/CXCR4 chemokine receptor system in adult brain: isoform-selective regulation of SDF-1 expression modulates CXCR4-dependent neuronal plasticity and cerebral leukocyte recruitment after focal ischemia. 22, 5865–5878. 12122049SuZ.NiuW.LiuM. L.ZouY.ZhangC. L. (2014). In vivo conversion of astrocytes to neurons in the injured adult spinal cord. 5:3338. 10.1038/ncomms433824569435SugimotoK.NishiokaR.IkedaA.MiseA.TakahashiH.YanoH.. (2014). Activated microglia in a rat stroke model express NG2 proteoglycan in peri-infarct tissue through the involvement of TGF-β1. 62, 185–198. 10.1002/glia.2259824311432SwindleC. S.TranK. T.JohnsonT. D.BanerjeeP.MayesA. M.GriffithL.. (2001). Epidermal growth factor (EGF)-like repeats of human tenascin-C as ligands for EGF receptor. 154, 459–468. 10.1083/jcb.20010310311470832TakahashiK.YamanakaS. (2006). Induction of pluripotent stem cells from mouse embryonic and adult fibroblast cultures by defined factors. 126, 663–676. 10.1016/j.cell.2006.07.02416904174TateC. C.GarcíaA. J.LaPlacaM. C. (2007a). Plasma fibronectin is neuroprotective following traumatic brain injury. 207, 13–22. 10.1016/j.expneurol.2007.05.00817599836TateC. C.TateM. C.LaPlacaM. C. (2007b). Fibronectin and laminin increase in the mouse brain after controlled cortical impact injury. 24, 226–230. 10.1089/neu.2006.004317263686ThierM.WörsdörferP.LakesY. B.GorrisR.HermsS.OpitzT.. (2012). Direct conversion of fibroblasts into stably expandable neural stem cells. 10, 473–479. 10.1016/j.stem.2012.03.00322445518ThoredP.ArvidssonA.CacciE.AhleniusH.KallurT.DarsaliaV.. (2006). Persistent production of neurons from adult brain stem cells during recovery after stroke. 24, 739–747. 10.1634/stemcells.2005-028116210404TomV. J.DollerC. M.MaloufA. T.SilverJ. (2004). Astrocyte-associated fibronectin is critical for axonal regeneration in adult white matter. 24, 9282–9290. 10.1523/jneurosci.2120-04.200415496664TorneroD.WattananitS.Grønning MadsenM.KochP.WoodJ.TatarishviliJ.. (2013). Human induced pluripotent stem cell-derived cortical neurons integrate in stroke-injured cortex and improve functional recovery. 136, 3561–3577. 10.1093/brain/awt27824148272TreilleuxI.Mallein-GerinF.le GuellecD.HerbageD. (1992). Localization of the expression of type I, II, III collagen and aggrecan core protein genes in developing human articular cartilage. 12, 221–232. 10.1016/s0934-8832(11)80065-x1406455UmJ. W.KoJ. (2013). LAR-RPTPs: synaptic adhesion molecules that shape synapse development. 23, 465–475. 10.1016/j.tcb.2013.07.00423916315van HorssenJ.DijkstraC. D.de VriesH. E. (2007). The extracellular matrix in multiple sclerosis pathology. 103, 1293–1301. 10.1111/j.1471-4159.2007.04897.x17854386von HolstA. (2008). Tenascin C in stem cell niches: redundant, permissive or instructive?188, 170–177. 10.1159/00011284818160825von HolstA.EgbersU.ProchiantzA.FaissnerA. (2007). Neural stem/progenitor cells express 20 tenascin C isoforms that are differentially regulated by Pax6. 282, 9172–9181. 10.1074/jbc.m60806720017264084von HolstA.SirkoS.FaissnerA. (2006). The unique 473HD-Chondroitinsulfate epitope is expressed by radial glia and involved in neural precursor cell proliferation. 26, 4082–4094. 10.1523/jneurosci.0422-06.200616611825VutskitsL.Djebbara-HannasZ.ZhangH.PaccaudJ. P.DurbecP.RougonG.. (2001). PSA-NCAM modulates BDNF-dependent survival and differentiation of cortical neurons. 13, 1391–1402. 10.1046/j.0953-816x.2001.01516.x11298800WadeA.RobinsonA. E.EnglerJ. R.PetritschC.JamesC. D.PhillipsJ. J. (2013). Proteoglycans and their roles in brain cancer. 280, 2399–2417. 10.1111/febs.1210923281850WahlS.BarthH.CiossekT.AktoriesK.MuellerB. K. (2000). Ephrin-A5 induces collapse of growth cones by activating Rho and Rho kinase. 149, 263–270. 10.1083/jcb.149.2.26310769020WangX.ChenW.LiuW.WuJ.ShaoY.ZhangX. (2009b). The role of thrombospondin-1 and transforming growth factor-beta after spinal cord injury in the rat. 16, 818–821. 10.1016/j.jocn.2008.09.01419342245WangL.ShiJ.van GinkelF. W.LanL.NiemeyerG.MartinD. R.. (2009a). Neural stem/progenitor cells modulate immune responses by suppressing T lymphocytes with nitric oxide and prostaglandin E2. 216, 177–183. 10.1016/j.expneurol.2008.11.01719109951WannerI. B.DeikA.TorresM.RosendahlA.NearyJ. T.LemmonV. P.. (2008). A new in vitro model of the glial scar inhibits axon growth. 56, 1691–1709. 10.1002/glia.2072118618667WidestrandA.FaijersonJ.WilhelmssonU.SmithP. L.LiL.SihlbomC.. (2007). Increased neurogenesis and astrogenesis from neural progenitor cells grafted in the hippocampus of GFAP−/− Vim−/− mice. 25, 2619–2627. 10.1634/stemcells.2007-012217628017WieseS.KarusM.FaissnerA. (2012). Astrocytes as a source for extracellular matrix molecules and cytokines. 3:120. 10.3389/fphar.2012.0012022740833WilhelmssonU.LiL.PeknaM.BertholdC. H.BlomS.EliassonC.. (2004). Absence of glial fibrillary acidic protein and vimentin prevents hypertrophy of astrocytic processes and improves post-traumatic regeneration. 24, 5016–5021. 10.1523/jneurosci.0820-04.200415163694XiaoQ.DuY.WuW.YipH. K. (2010). Bone morphogenetic proteins mediate cellular response and, together with Noggin, regulate astrocyte differentiation after spinal cord injury. 221, 353–366. 10.1016/j.expneurol.2009.12.00320005873XiaoM. J.HanZ.ShaoB.JinK. (2009). Notch signaling and neurogenesis in normal and stroke brain. 1, 192–202. 20428478XuJ. C.XiaoM. F.JakovcevskiI.SivukhinaE.HargusG.CuiY. F.. (2014). The extracellular matrix glycoprotein tenascin-R regulates neurogenesis during development and in the adult dentate gyrus of mice. 127, 641–652. 10.1242/jcs.13761224338367YamaguchiY. (2001). Heparan sulfate proteoglycans in the nervous system: their diverse roles in neurogenesis, axon guidance and synaptogenesis. 12, 99–106. 10.1006/scdb.2000.023811292375YamamotoS.NagaoM.SugimoriM.KosakoH.NakatomiH.YamamotoN.. (2001). Transcription factor expression and notch-dependent regulation of neural progenitors in the adult rat spinal cord. 21, 9814–9823. 11739589YamashitaT.NinomiyaM.Hernández AcostaP.García-VerdugoJ. M.SunaboriT.SakaguchiM. (2006). Subventricular zone-derived neuroblasts migrate and differentiate into mature neurons in the post-stroke adult striatum. 26, 6627–6636. 10.1523/jneurosci.0149-06.200616775151YanK.ZhangR.SunC.ChenL.LiP.LiuY.. (2013). Bone marrow-derived mesenchymal stem cells maintain the resting phenotype of microglia and inhibit microglial activation. 8:e84116. 10.1371/journal.pone.008411624391898YangH.XiaoZ. C.BeckerB.HillenbrandR.RougonG.SchachnerM. (1999). Role for myelin-associated glycoprotein as a functional tenascin-R receptor. 55, 687–701. 10.1002/(sici)1097-4547(19990315)55:6<687::aid-jnr4>3.3.co;2-y10220110YayonA.KlagsbrunM.EskoJ. D.LederP.OrnitzD. M. (1991). Cell surface, heparin-like molecules are required for binding of basic fibroblast growth factor to its high affinity receptor. 64, 841–848. 10.1016/0092-8674(91)90512-w1847668YeQ.MiaoQ. L. (2013). Experience-dependent development of perineuronal nets and chondroitin sulfate proteoglycan receptors in mouse visual cortex. 32, 352–363. 10.1016/j.matbio.2013.04.00123597636YokosakiY.MatsuuraN.HigashiyamaS.MurakamiI.ObaraM.YamakidoM.. (1998). Identification of the ligand binding site for the integrin alpha9 beta1 in the third fibronectin type III repeat of tenascin-C. 273, 11423–11428. 10.1074/jbc.273.19.114239565552YouJ.HongS. Q.ZhangM. Y.ZhaoH. L.LiuT. Z.ZhouH. L.. (2012). Passive immunization with tenascin-R (TN-R) polyclonal antibody promotes axonal regeneration and functional recovery after spinal cord injury in rats. 525, 129–134. 10.1016/j.neulet.2012.08.00222902990ZengH.GuoM.Martins-TaylorK.WangX.ZhangZ.ParkJ. W.. (2010). Specification of region-specific neurons including forebrain glutamatergic neurons from human induced pluripotent stem cells. 5:e11853. 10.1371/journal.pone.001185320686615ZhangS.XiaY. Y.LimH. C.TangF. R.FengZ. W. (2010). NCAM-mediated locomotor recovery from spinal cord contusion injury involves neuroprotection, axon regeneration and synaptogenesis. 56, 919–929. 10.1016/j.neuint.2010.03.02320381564ZhaoR. R.AndrewsM. R.WangD.WarrenP.GulloM.SchnellL.. (2013). Combination treatment with anti-Nogo-A and chondroitinase ABC is more effective than single treatments at enhancing functional recovery after spinal cord injury. 38, 2946–2961. 10.1111/ejn.1227623790207ZimmermannD. R.Dours-ZimmermannM. T. (2008). Extracellular matrix of the central nervous system: from neglect to challenge. 130, 635–653. 10.1007/s00418-008-0485-918696101