Contemporary Models in Ectodermal Organ Development, Maintenance and Regeneration

Developing murine tooth germ with invading vasculature in red.

Editorial

24 September 2021

Editorial: Contemporary Models in Ectodermal Organ Development, Maintenance and Regeneration

Abigail Saffron Tucker

and

Maisa Hanna-Maija Seppala

1,561 views

1 citations

Editors

Isabelle Miletich

King's College London

Abigail Saffron Tucker

King's College London

Maisa Hanna-Maija Seppala

King's College London

Impact

Original Research

04 May 2021

Tooth Removal in the Leopard Gecko and the de novo Formation of Replacement Teeth

Kirstin S. Brink

, 4 more and

Joy M. Richman

Proliferation in the dental lamina following a pulse-chase. (A) The incorporation of BrdU +/- PCNA relative to the total number of cells in the dental lamina was significantly higher in the treated and sham control compared to the non-manipulated controls at time 0. At 1 month there were no significant differences between the types of manipulation. In addition, the number of labeled cells was the same in controls as at time zero. (B) PCNA labeling was significantly higher in the time 0 relative to the 1-month post-surgery dental lamina with the exception of control dental laminae. (C) At time 0, dual labeled cells were present in significantly higher proportions between the controls and all experimentally treated tissues. There was no significant difference between the percentage of dual labeled cells at time 0 and 1 month in the controls. Other treated tissues had significantly lower labeling at 1 month compared to time 0. (D) The proportion of BrdU + PCNA/PCNA cells was very high in the treated tissues at time 0 compared to controls. In addition, there were higher numbers of labeled cells in controls at time 0 compared to 1 month post-chase. Asterisks: *P < 0.05, **P < 0.01, ***P < 0.001, ****P < 0.0001.

Many reptiles are able to continuously replace their teeth through life, an ability attributed to the existence of epithelial stem cells. Tooth replacement occurs in a spatially and temporally regulated manner, suggesting the involvement of diffusible factors, potentially over long distances. Here, we locally disrupted tooth replacement in the leopard gecko (Eublepharis macularius) and followed the recovery of the dentition. We looked at the effects on local patterning and functionally tested whether putative epithelial stem cells can give rise to multiple cell types in the enamel organs of new teeth. Second generation teeth with enamel and dentine were removed from adult geckos. The dental lamina was either left intact or disrupted in order to interfere with local patterning cues. The dentition began to reform by 1 month and was nearly recovered by 2–3 months as shown in μCT scans and eruption of teeth labeled with fluorescent markers. Microscopic analysis showed that the dental lamina was fully healed by 1 month. The deepest parts of the dental lamina retained odontogenic identity as shown by PITX2 staining. A pulse-chase was carried out to label cells that were stimulated to enter the cell cycle and then would carry BrdU forward into subsequent tooth generations. Initially we labeled 70–78% of PCNA cells with BrdU. After a 1-month chase, the percentage of BrdU + PCNA labeled cells in the dental lamina had dropped to 10%, consistent with the dilution of the label. There was also a population of single, BrdU-labeled cells present up to 2 months post surgery. These BrdU-labeled cells were almost entirely located in the dental lamina and were the likely progenitor/stem cells because they had not entered the cell cycle. In contrast fragmented BrdU was seen in the PCNA-positive, proliferating enamel organs. Homeostasis and recovery of the gecko dentition was therefore mediated by a stable population of epithelial stem cells in the dental lamina.

7,019 views

11 citations

Incisor developmental defects in the Pax9+/–Eda–/– compound mutant embryos. Hematoxylin and eosin-stained (HE) sagittal sections through the developing incisor tooth germs. The Pax9+/–Eda+/+, Pax9+/+Eda–/–, and Pax9+/–Eda–/– compound mutants at E13.5 (A,E,I), E14.5 (B,F,J), E17.5 (C,G,K), and P0 (D,H,L), respectively, are shown. Scale bar presented 100 μm, * indicates the region of missing incisor. lcl, lower cervical loop; mc, Meckel’s cartilage; mxi, maxillary incisor; tb, tooth bud; ucl, upper cervical loop, vl, vestibular lamina.

Brief Research Report

26 November 2020

Pax9’s Interaction With the Ectodysplasin Signaling Pathway During the Patterning of Dentition

Shihai Jia

, 5 more and

Rena N. D’Souza

4,559 views

7 citations

Family pedigrees and genetic variants. Arrow indicates the proband. Tooth phenotypes of the participants were determined either by the dentist or reported by the participants. W+/+, homozygous WNT10A variant; W+/-, heterozygous WNT10A variant; W+/+, wild-type WNT10A variant; E+/+, homozygous EDARADD variant; E+/-, heterozygous EDARADD variant; E+/+, wild-type EDARADD variant.

Original Research

19 November 2020

Phenotypic and Genotypic Features of Thai Patients With Nonsyndromic Tooth Agenesis and WNT10A Variants

Charinya Kanchanasevee

, 5 more and

Vorasuk Shotelersuk

4,349 views

13 citations

Loss of function of Msx2 and Sp6 in LS8 ameloblast-derived cells: (A) Both LS8 and G5 cells were overexpressed with Msx2 over-expression plasmid. Representative RT-PCR showing Sp6 is upregulated whereas Fst is downregulated in both cell lines after Msx2 overexpression. Bottom panel shows densitometric quantification of the bands. (B) The knockdown of Msx2 with siRNA relative to scrambled control shows downregulation of Msx2 and Sp6 and upregulation of Fst, in 48 and 72 h. RT-PCR results were normalized to Gapdh that served as an internal control and expression levels were relative to scrambled controls. **P < 0.01. Bottom panel shows a graph describing the trend of genes’ expression. (C) Lentiviral (ShRNA) gene knockdown assay, where Msx2-shRNA and Sp6-shRNA, and non-target-shRNA infected LS8 cells further confirm the siRNA results. qPCR results were normalized to Gapdh. Bottom panel shows densitometric quantification of the bands. Experiments were done in triplicates. **p ≤ 0.005; ***p ≤ 0.0001.

Original Research

26 October 2020

An Msx2-Sp6-Follistatin Pathway Operates During Late Stages of Tooth Development to Control Amelogenesis

Intan Ruspita

, 7 more and

Marianna Bei

4,393 views

12 citations

SEM observation of mouse nasal septum explants. (A) A schematic of the removal of the explants from the right palatal shelf from each maxilla. (B–G) Occlusal views of the WT mouse nasal septum at E14.5 (B,E), after 12 h of culture (C,F), and after 24 h of culture (D,G). (E–G) Higher magnification views in the region indicated by white boxes in B–D. No protrusion of epithelial cells of the nasal septum occurred (red arrowheads). (H–M) Occlusal views of the WT mouse nasal septum at E15.0 (H,K), after 12 h of culture (I,L), and after 24 h of culture (J,M). (K–M) Higher magnification views in the region indicated by white boxes in H–J. Protrusion of epithelial cells of the nasal septum occurred (red area, red arrowheads). Black dotted lines in B–D and H–J indicate the posterior border of the primary palate. A, anterior; P, posterior; PP, primary palate; PS, secondary palate; NS, nasal septum. Scale bars: B 100 μm (B–D same magnification); E 50 μm (E–G same magnification); H 100 μm (H–J same magnification); K 20 μm (K–M same magnification).

Original Research

02 October 2020

Observation of the Epithelial Cell Behavior in the Nasal Septum During Primary Palate Closure in Mice

Sayuri Yamamoto

, 9 more and

Takashi Yamashiro

4,068 views

4 citations

Original Research

03 September 2020

Expression Profiles of CircRNA and mRNA in Lacrimal Glands of AQP5–/– Mice With Primary Dry Eye

Yaning Liu

, 5 more and

Peng Chen

Purpose: This work aimed to identify differentially expressed circular RNAs (circRNAs) and elucidate their potential function in aquaporin 5 (AQP5) knockout (AQP5^–/–) mice with the primary dry eye phenotype.

Methods: A slit lamp examination was performed on AQP5^–/– mice to assess corneal epithelial defects using fluorescein sodium staining. Hematoxylin–eosin staining and transmission electron microscopy analysis were performed to identify structural changes in lacrimal gland epithelial cells due to AQP5 deficiency. The expression profiles of circRNA and messenger RNA (mRNA) were determined by a microarray analysis. The selected circRNA was verified by quantitative real-time reverse transcription-polymerase chain reaction (qRT-PCR). Gene Ontology and Kyoto Encyclopedia of Genes and Genomes (KEGG) pathway enrichment analyses were performed to predict the biological functions and the potential pathways of parental genes involved in lacrimal gland epithelial cell changes. According to the bioinformatics analysis of identified circRNAs, we predicted a circRNA–miRNA–mRNA network of phagosomes.

Results: The AQP5^–/– mice spontaneously exhibit dry eye symptoms, wherein the AQP5 deficiency changes the structure of lacrimal gland epithelial cells. The analysis revealed that, compared to AQP5^+/+ mice, 30 circRNAs in the lacrimal glands of AQP5^–/– mice were differentially expressed (fold change ≥ 2.0, p < 0.05). Nine upregulated circRNAs were identified using qRT-PCR, and nine upregulated validated circRNAs, 40 altered microRNAs (miRNAs), and nine upregulated mRNAs were identified through a network analysis. The KEGG analysis showed that these nine target genes were expressed in phagosomes.

Conclusion: The AQP5^–/– mice have primary and stable dry eye phenotypes from birth. We identified differently expressed circRNAs in the lacrimal glands of AQP5^–/– and AQP5^+/+ mice, predicting a circRNA–miRNA–mRNA network of phagosomes. CircRNA likely plays an important role in lacrimal gland epithelial cell pathogenesis. Therefore, it is reasonable to use circRNA as a potential therapeutic agent for the treatment of dry eyes.

3,745 views

24 citations

Original Research

24 August 2020

Balance Between Tooth Size and Tooth Number Is Controlled by Hyaluronan

Natalia Sánchez

, 8 more and

Marcia Gaete

3,303 views

10 citations

Original Research

31 July 2020

Action of Actomyosin Contraction With Shh Modulation Drive Epithelial Folding in the Circumvallate Papilla

Sushan Zhang

, 2 more and

Han-Sung Jung

3,513 views

9 citations

The potential cross-talk between SOCE and the circadian clock in ameloblasts. Schematic representation summarizing how SOCE can potentially influence the ameloblasts’ circadian clock based on our findings. Upon Ca2+ depletion in the ER, STIM1 binds to ORAI to facilitate Ca2+ entry and activate Ca2+-dependent signal transduction. Calcium induces the activity of Ca2+/calmodulin-dependent protein kinases which activate PKA and PKC that phosphorylate CREB in a circadian manner. The phosphorylated CREB translocate to the nucleus where it recognizes the cAMP Response Element in the promoter region of Per1 & 2 and serves as a transcription factor. PER1 & 2 are core regulators of the mammalian circadian clock and participate in forming the autoregulatory TTFL. Disruption of SOCE in Stim1 cKO ameloblasts resulted in dysregulated expression of Per2 that disrupts the TTFLs leading to abnormal circadian patterns including an upregulated Bmal1 expression that maybe involved in the development of SOCE mediated AI. iCa2+, intracellular calcium; TTFL, transcription translation feedback loop; PKA, protein Kinase A; PKC, protein Kinase C; CREB, cAMP response element-binding protein; STIM1, Stromal interaction molecule 1; P, Phosphate group. This figure was created with images adapted from Servier Medical Art by Servier. Original images are licensed under a Creative Commons Attribution 3.0 Unported License.

Brief Research Report

31 July 2020

Calcium Sets the Clock in Ameloblasts

Raed Said

, 2 more and

Petros Papagerakis

4,674 views

9 citations

Lingual/buccal differences in VL epithelium. (A,D) Histological frontal sections through the upper canine. (B,C,E–K) Immunofluorescence. DAPI shows nuclei in white. (A–C) CS23. Box in (A) highlights regions in (B,C). The buccal side of the cheek furrow comprises cells with (B) limited Keratin 14 (K14; Green) and Keratin 10 (K10; red), and (C) high levels of Keratin 5 (K5; blue). (D–F) 9 weeks. Box in (D) highlights regions in (E,F). The buccal side of the cheek furrow comprises cells with (E) robust K14 in the basal layer (Green), with K10 turning on in the overlying suprabasal layer (red), and (F) high levels of K5 (blue). (G–K) 11 weeks. Box in (G) highlights regions in (J,K). (G) K14 (green) is robustly expressed around the edges of the VL, with K10 (red) observed at high levels mainly on the buccal side only. (H–K) High power of the buccal side (H,I) and lingual (J,K) side of the VL comparing the expression of K5 (blue) and K14 (green) in the basal layer and overlying layer, and K10 (red) in the suprabasal layer. Yellow lines outline the basement membrane separating the epithelial and mesenchymal cells in (B,C,E,F,H–K). Scale bars in (A) = 500 μm, same scale in (D). Scales bars in (B,H) = 10 μm, same scale in (C,E,F,I–K). Scale bar in (G) = 100 μm.

Original Research

16 July 2020

Development of the Vestibular Lamina in Human Embryos: Morphogenesis and Vestibule Formation

Tengyang Qiu

, 2 more and

Abigail S. Tucker

6,648 views

4 citations

Mammalian early embryonic hair development, a model for cellular mechanisms driving ectodermal organogenesis. (A) Mice have four different hair types that arise in three successive waves of hair follicle induction. The first wave of embryonic development of hair follicles in the mouse back skin starts with the establishment of a pre-pattern around embryonic day 13.5 (E13.5) creating the spacing of the hair follicles by a reaction-diffusion type signaling system. At E14.5 the initial thickening of the epidermis, the epithelial placode, is induced by a signal from the mesenchymal compartment the dermis. The epithelium of the hair germ polarizes, and at the same time mesenchymal cells start forming a dermal condensate. The epithelium then buds by cell proliferation invaginating into the dermis to form the hair peg and the condensed mesenchyme engulfed by the epithelium becomes the dermal papilla. This is followed by further differentiation in a mature hair follicle. The second wave of hair morphogenesis takes place around E16–E17 and third at E18- postnatal day 1 (P1) with specific molecular patterning mechanisms for each. The mature hair follicle cycles producing new hairs throughout the adult life. (B) The hair has been one of first ectodermal model organs in which live imaging approaches have brought understanding of the cellular dynamics of the morphogenesis and patterning especially in the early stages of morphogenesis: during the first wave of hair follicle induction the cellular events start with a cell fate commitment and cell cycle exit in the prospective placode cells at E13.5. These cells then intercalate and migrate centripetally to condense into a placode thickening at E14.5. The placode signals to the mesenchymal compartment and the dermal cells commit to dermal condensate fate, exit the cell cycle and migrate to form the dermal condensate. The epithelial compartment concomitantly polarizes. The cellular mechanisms of hair follicle polarization have been studied during the second wave of hair follicle induction (E15.5–E17.5). The polarization takes place through planar cell polarity mediated mechanisms and the cells acquire specific fates and collectively actively redistribute into a polarized structure (Duverger and Morasso, 2009; Ahtiainen et al., 2014; Biggs and Mikkola, 2014; Biggs et al., 2018; Cetera et al., 2018).

Review

16 July 2020

Live Tissue Imaging Sheds Light on Cell Level Events During Ectodermal Organ Development

Isabel Mogollón

and

Laura Ahtiainen

5,756 views

6 citations

Original Research

03 July 2020

Mesenchymal Bmp7 Controls Onset of Tooth Mineralization: A Novel Way to Regulate Molar Cusp Shape

Zeba Malik

, 3 more and

Daniel Graf

Bmp7 expression in odontoblasts correlates with onset of mineralization. Sagittal sections of molars from Bmp7LacZ reporter mice (A) at P0 Bmp7 is expressed in a subset of odontoblasts at the crown region in the cusps of the 1st maxillary molar. (A’,A”) Magnified view of (A). (B) At P2 Bmp7 expression is restricted to the 2nd molar and is not visibly noticed in 1st mandibular molars. (B’) Magnified view of 2nd molars shown in (B). (C) At P6 expression is lost in both 1st and 2nd molars. (D,E) At P14 Bmp7 expression is dynamic and Bmp7 appears in the 3rd molar and is re-expressed in some lateral areas of the 1st/2nd molars. Expression of Bmp7 in ameloblasts is dynamic and can be observed at various stages. Scale bars: (A–E): 250 μm, (A’): 100 μm, (A”,B’): 50 μm.

Investigating the molecular basis for tooth shape variation provides an important glimpse into the evolution of tooth function. We recently showed that loss of mesenchymal BMP7 is sufficient to alter morphology and function of the toothrow. Here we report on the underlying mechanism. Expression of mesenchymal Bmp7 is observed at sites where mineralization is initiated, in tooth cusps of developing molars. Neural crest-specific deletion of Bmp7 (Bmp7^ncko) resulted in a complete lack of dentin/enamel formation at birth, the time when mineralization is normally initiated in the upper molars, similar to what was observed in Bmp2^ncko mice. Unlike loss of Bmp2, loss of Bmp7 did not affect odontoblast polarization and did not significantly alter the levels of pSmad1/5/8, but almost completely abolished canonical Wnt signaling in (pre)-ameloblasts. Tooth mineralization resumed with a 48-h delay allowing for additional mesenchymal proliferation. Enamel volume was still reduced at P4 and P8, but was comparable in erupted teeth, which were broader and had altered cusp shapes. Tooth eruption was also delayed. Overall, enamel appeared inconspicuous, although some structural changes along with reduced mineral density could be observed. Loss of Bmp7 led to an increase in mesenchymal Bmp6 suggesting an interplay between Bmp6 and Bmp7 in the regulation of mineralization initiation. Our findings show that regulation of the onset of tooth mineralization is a hitherto unsuspected mechanism controlling tooth shape variation. Initiation of tooth mineralization is regulated by a complex epithelial-mesenchymal Bmp/Wnt-signaling network to which Bmp7 contributes. This network is separate and independent of the Bmp2-signaling network regulating odontoblast cell polarization. From an evolutionary perspective, addition of Bmp7 as initiator of tooth mineralization might be akin to an upgrade of an existing computer operating system. While not essential, it provides obviously sufficient advantage warranting its evolutionary incorporation.

4,117 views

26 citations

Comparison of the COEL, COEL/miR-26b rescue and WT mice demonstrating normal incisor development in the rescued mice. (A) Mice heads with incisor phenotypes are shown, (B) μCT head images comparing the COEL, COEL/miR-26b rescue, and Cre negative control mice bone and tooth development. (C) Sagittal sections of P2 lower incisors of the three mice showing the COEL extra stem cell compartment and rescue by miR-26b, H&E staining; Ki67 staining shows that cell proliferation in the rescue mice is similar to WT mice; and Amelogenin expression is similar in the rescue mice as observed in WT mice. The boxed region is shown for comparison. (D) P0 mandibles were processed for RNA and analyzed for Lef-1 and miR-26b expression from WT, COEL, and COEL miR-26b± mice. (N = 3, *p < 0.05). Labial cervical loop, LaCL; Ameloblasts, Am.

Original Research

14 July 2020

Ectodermal Organ Development Is Regulated by a microRNA-26b-Lef-1-Wnt Signaling Axis

Steve Eliason

, 3 more and

Brad A. Amendt

2,426 views

12 citations

Original Research

04 June 2020

Transforming Growth Factor-Beta and Sonic Hedgehog Signaling in Palatal Epithelium Regulate Tenascin-C Expression in Palatal Mesenchyme During Soft Palate Development

Shirabe Ohki

, 8 more and

Takayoshi Sakai

Tenascin C expression during palatal development in mice between embryonic day 13.5 (E13.5) and E15.5. (A) The mRNA expressions of tenascin-C (TNC), tenascin-X (TNX), and tenascin-W (TNW) in the anterior and posterior palatal shelves at E13.5, E14.5, and E15.5 (real-time polymerase chain reaction). The mRNA expression of TNC was greater than that of TNX or TNW and significantly higher in the posterior palate than in the anterior palate at E15.5. Data are presented as the mean ± standard deviation (n = 6). The mRNA expressions were normalized to that of glyceraldehyde 3-phosphate dehydrogenase (GAPDH). ∗P < 0.05. (B) Immunofluorescence staining of TNC protein in the middle, mid-posterior and posterior regions of the palatal shelves at E13.5, E14.0, E14.5, and E15.5. Stronger TnC expression was observed in the posterior palatal shelves than in the middle or mid-posterior regions, particularly at the later developmental stages. T, tooth germ; Pt, pterygoid process. Bar = 100 μm.

During palatogenesis, the palatal shelves first grow vertically on either side of the tongue before changing their direction of growth to horizontal. The extracellular matrix (ECM) plays an important role in these dynamic changes in palatal shelf morphology. Tenascin-C (TNC) is an ECM glycoprotein that shows unique expression in the posterior part of the palatal shelf, but little is known about the regulation of TNC expression. Since transforming growth factor-beta-3 (TGF-β3) and sonic hedgehog (SHH) signaling are known to play important roles in palatogenesis, we investigated whether TGF-β3 and SHH are involved in the regulation of TNC expression in the developing palate. TGF-β3 increased the expression of TNC mRNA and protein in primary mouse embryonic palatal mesenchymal cells (MEPM) obtained from palatal mesenchyme dissected at embryonic day 13.5–14.0. Interestingly, immunohistochemistry experiments revealed that TNC expression was diminished in K14-cre;Tgfbr2^fl/fl mice that lack the TGF-β type II receptor in palatal epithelial cells and exhibit cleft soft palate, whereas TNC expression was maintained in Wnt1-cre;Tgfbr2^fl/fl mice that lack the TGF-β type II receptor in palatal mesenchymal cells and exhibit a complete cleft palate. SHH also increased the expression of TNC mRNA and protein in MEPM cells. However, although TGF-β3 up-regulated TNC mRNA and protein expression in O9-1 cells (a cranial neural crest cell line), SHH did not. Furthermore, TGF-β inhibited the expression of osteoblastic differentiation markers (osterix and alkaline phosphatase) and induced the expression of fibroblastic markers (fibronectin and periostin) in O9-1 cells, whereas SHH did not affect the expression of osteoblastic and fibroblastic markers in O9-1 cells. However, immunohistochemistry experiments showed that TNC expression was diminished in the posterior palatal shelves of Shh^–/+;MFCS4^+/– mice, which have deficient SHH signaling in the posterior palatal epithelium. Taken together, our findings support the proposal that TGF-β and SHH signaling in palatal epithelium co-ordinate the expression of TNC in the posterior palatal mesenchyme through a paracrine mechanism. This signal cascade may work in the later stage of palatogenesis when cranial neural crest cells have differentiated into fibroblast-like cells. The spatiotemporal regulation of ECM-related proteins by TGF-β and SHH signaling may contribute not only to tissue construction but also to cell differentiation or determination along the anterior–posterior axis of the palatal shelves.