Edited by: Hui Y. Lan, The Chinese University of Hong Kong, China
Reviewed by: Zhanjun Jia, University of Utah, USA; Xiao-Ming Meng, Anhui Medical University, China
*Correspondence: Sydney C. W. Tang, Division of Nephrology, Department of Medicine, The University of Hong Kong, Rm 415 Professorial Block, Queen Mary Hospital, 102 Pokfulam Road, Hong Kong, China
This article was submitted to Renal and Epithelial Physiology, a section of the journal Frontiers in Physiology
This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) or licensor are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.
Renal fibrosis is final common pathway of end stage renal disease. Irrespective of the primary cause, renal fibrogenesis is a dynamic process which involves a large network of cellular and molecular interaction, including pro-inflammatory cell infiltration and activation, matrix-producing cell accumulation and activation, and secretion of profibrogenic factors that modulate extracellular matrix (ECM) formation and cell-cell interaction. Bone morphogenetic protein-7 is a protein of the TGF-β super family and increasingly regarded as a counteracting molecule against TGF-β. A large variety of evidence shows an anti-fibrotic role of BMP-7 in chronic kidney disease, and this effect is largely mediated via counterbalancing the profibrotic effect of TGF-β. Besides, BMP-7 reduced ECM formation by inactivating matrix-producing cells and promoting mesenchymal-to-epithelial transition (MET). BMP-7 also increased ECM degradation. Despite these observations, the anti-fibrotic effect of BMP-7 is still controversial such that fine regulation of BMP-7 expression
Renal fibrosis, which characterized as glomerulosclerosis and tubulointerstitial fibrosis, is considered the hallmark of progressive renal injury and the final common pathway of multiple chronic renal diseases. Regardless of the primary causes, appearance of most “end stage kidney” manifested as extensive scar formation (fibrotic tubules and sclerotic glomeruli), thickened arteries, and infiltrated chronic inflammatory cells. Process of renal fibrosis involved activation of intrinsic kidney cells, infiltrated cells, and led to excessive accumulation and deposition of extracellular matrix and finally the loss of kidney function. TGF-β has been known as the key modulator of kidney (and that of other organs) fibrosis, and the role of TGF-β in renal fibrosis has been extensively studied. In recent years, another protein, BMP-7, that belongs to the TGF-β superfamily, has drawn great attention for its function in counteracting pro-fibrotic effects of TGF-β. BMP-7 is a homodimeric protein that with cysteine-knot. It plays an crucial role in renal development and only selectively expressed in several adult organs including the kidney. It is a natural negative regulator of nephrotic TGF-β/Smad signaling pathway. The fact that renal BMP-7 disappears during renal fibrogenesis (Wang et al.,
Fibrosis can be considered as ineffective wound healing process, in which excessive progression of scarring rather than resolution occurs. Fibroblasts play a pivotal role in the process, which is modulated by multiple cell types and molecules. In this respect, the cellular and molecular response of the damaged kidney attempted to prevent renal damage and preserve renal function, and as a matter of fact, almost all cell types of the kidney and a series of infiltrating cells are involved in the development of renal fibrosis, indicating the complexity of this process.
In early phase of renal injury, damage cells release cytokines and chemokines, which attract inflammatory cells infiltrated into injured sites (You and Kruse,
The sustained increase of profibrotic cytokines in microenvironment after renal injury inevitably leads to activation of matrix-producing cells, which plays a central role in renal fibrosis. Fibroblasts are considered as the major source of ECM in the kindney, besides, other cell types in renal tubulointerstitium such as tubular epithelial cells, vascular smooth muscle cells and macrophages are also capable of producing ECM. Myofibroblasts are terminally differentiated cells that rarely found in normal renal tissue. It functions for interstitial ECM synthesis and accumulation including collagen I, collagen III, fibronectin during wound healing or scar forming at injured sites. There are at least five source of myofibroblasts have been proposed in experimental kidney models or disease kidneys, including activation of endogenous fibroblasts (which was regarded as classical source of myofibroblasts), differentiation of pericytes, tubular epithelial to mesenchymal transition, bone marrow fibroblast infiltration or endothelial phenotypic transition (Duffield,
Activated fibroblasts from all sources produce large amounts of ECM components, leading to excessive accumulation and deposition of interstitial matrix, which is predominantly composed of collagen I, III, and fibronectin. In the physiological condition, the production and degradation of ECM is intensely regulated under a dynamic balance. Under the profibrotic state, this delicate balance is interrupted. Activation of profibrotic factors and inactivation of antifibrotic factors tilt the balance, increasing ECM formation while reducing their degradation, finally leading to excessive accumulation of ECM. Key fibrogenic factors include TGF-β1, connective tissue growth factor (CTGF), angiotensin II, platelet-derived growth factor (PDGF) and fibroblast growth factor (FGF)2, among which, TGF-β1 has been regarded as key modulator of renal fibrosis (Bottinger,
Transforming growth factor-β (TGF-β) is a multifunctional cytokine, functioned through its cognate receptors (type II and I) to activate a variety of canonical and non-canonical signaling pathways with large amount of profibrotic target genes (Bottinger,
CTGF is a cytokine with a molecular weight around 36–38 kD, it is thought to be an prominent profibrotic downstream modulator of TGF-β (Leask and Abraham,
BMP-7, formerly called osteogenic protein-1/OP-1, is a member of the BMP-subfamily within the transforming growth factor β (TGF-β) superfamily. BMP-7 expression in normal kidney has the highest expression level in adult organs (Dudley et al.,
Shortly after this observation, researchers sought to explore the role of BMP-7 in a rat model of STZ-induced diabetes, which resembles human type 1 diabetes. BMP-7 was given exogenously through i.v. injection. In this model, it was found that BMP-7 administration delayed the onset of diabetic nephropathy and prevented glomerulosclerosis; and even partially reversed diabetic kidney hypertrophy and restored GFR in the progression stage of DN (Wang et al.,
The beneficial effects of BMP-7 are not just restricted to DN. In MRL/MpJ background and autoimmune disease-prone MRL/MpJ
Among these studies, a prominent anti-fibrotic effect of BMP-7 in both glomerulus and tubulointerstitium was observed. Nevertheless, considering that BMP-7 was first discovered as growth factor that facilitated bone formation, concerns about ectopic bone formation and vascular calcification of using BMP-7 systemically seem reasonable. To date, no reports suggested these potential complications in their rodent models. Furthermore, there was evidence that BMP-7 even prevented vascular calcification (Davies et al.,
However, BMP-7 was not always effective and promising. For example, BMP-7 conferred no benefits in a rat protein-overload model (Ikeda et al.,
| IRI | Rat | Acute tubular necrosis | Preserved kidney function, increase survival rate | Vukicevic et al., |
| UUO | Rat | Obstructive nephropathy | Preserved renal blood flow, prevent tubular atrophy, reduced tubulointerstitial and fibrosis | Hruska et al., |
| MRL/MpJ |
Mouse | Lupus nephritis | Inhibited tubular atrophy and interstitial fibrosis | Zeisberg et al., |
| COL4A3−/− | Mouse | Alport syndrome | Inhibited tubular atrophy and interstitial fibrosis | Zeisberg et al., |
| Nephrotoxic serum nephritis | CD1 Mouse | Acute glomerulonephritis | Induced MET, decreased ECM secretion | Zeisberg et al., |
| STZ induced diabetes | Rat | Type 1 diabetic nephropathy | Reversed kidney hypertrophy, restored GFR, reduced albumin excretion | Wang et al., |
| Kidney Cx or 5/6 Nx (RRKM) | SD rat | CKD | Increased tubular regeneration in early stage of repair process | Dube et al., |
| STZ induced diabetes | CD1 Mouse | Type 1 diabetic nephropathy | Inhibit glomerular lesion, and tubulointerstitial fibrosis | Sugimoto et al., |
| STZ induced diabetes | FVB/N Mouse | Type 1 diabetic nephropathy | Reduced podocytes dropout, glomerular fibrosis and interstitial collagen accumulation | Wang et al., |
| LDLR−/− | Mouse | CKD/VC/Atherosclerosis/ | Down regulated osteocalcin expression | Davies et al., |
| Unx + kidney partial ablation LDLR−/− | Mouse | Metabolic syndrome/Insulin resistance | Corrected hyperphosphatemia, osteodystrophy, and prevent VC, but no improvement of renal function | Davies et al., |
| STZ induced diabetes | Rat | Type 1 diabetic nephropathy | Reduced urine protein excretion, preserved podocyte number and nephrin expression | Xiao et al., |
| Protein overload | Rat | Kidney disease | Failed to reduced proteinuria and even showed increase of ECM gene expression | Ikeda et al., |
TGF-β has been known as the key modulator of kidney (and that of other organs) fibrosis. TGF-β acts on multiple cell types in the kidney, including podocytes, mesangial cells, renal proximal tubular epithelial cells and interstitial fibroblasts. TGF-β induces pro-fibrotic gene transcription, and finally leads to the overexpression of extracellular matrix proteins, reduction of cell proliferation and differentiation, and elevation of resident epithelial cell apoptosis. Moreover, although evidence of epithelial-to-mesenchymal transition (EMT) in human kidney remains insufficient, TGF-β have been shown to super-induce fibrotic progression in dozens of
Besides the anti-fibrotic effect of BMP-7 in all the animal models mentioned above, a variety of
TGF-β induced extracellular matrix and other pro-fibrotic gene overexpression in mesangial cells. Although mesangial cells did not express BMP-7, BMP receptors were detectable on mesangial cells with active signals. Co-incubating murine mesangial cells with TGF-β and BMP-7 reduced TGF-β-stimulated collagen IV, fibronectin and CTGF overexpression. It is worth mentioning that BMP-7 reduces ECM accumulation without concomitant changes of their mRNA levels, suggesting that BMP-7 might act through affecting ECM protein degradation. Besides, TGF-β stimulation decreased matrix metalloprotease (MMP)-2 expression and this action could be abolished by BMP-7, possibly via reducing the activation of the plasminogen activator inhibitor (PAI-1) (Wang and Hirschberg,
The effects of BMP-7 on tubular epithelial cells have also been extensively studied. The emerging importance of tubular epithelial cells (the most abundant cell type in the kidney) in kidney diseases cannot be overemphasized. Most studies in the animal models stated above mainly focused on tubulointerstitial damage, fueling attention of how BMP-7 functions on TECs.
Like mesangial cells, proximal tubular epithelial cells showed no expression of BMP-7, but constitutively express BMP receptors as described in the previously section. On the other hand, distal tubular cells express both BMP-7 and BMP receptors.
In a setting that study of BMP-7 on NP-1 cell (mouse distal tubule cell line) which stimulated with TGF-β (Zeisberg et al.,
Researches have also been done in human proximal tubular epithelial cell line (HK2). BMP-7 dose dependently reduced TGF-β-induced overexpression of a-SMA, fibronectin, collagen I and CTGF in HK2 cells (Xu et al.,
Cyclosporine A (CsA) has been reported to induce EMT in HK2 cells with involvement of TGF-β and CTGF (McMorrow et al.,
However, not all the studies with BMP-7 in TGF-β-induced fibrosis showed a positive result. Dudas et al., used TGF-β as a stimulant to study the role of BMP-7 in both human and murine tubular epithelial cells. Contrary to the other results listed above, they failed to demonstrate an anti-fibrotic role of BMP-7 in human tubular cells (both primary cell and immortalized cell line). BMP-7
CTGF is considered as inhibitor of BMP-7 signaling. In diabetic CTGF+/+ mice, phosphorylation of smad1/5, expression of BMP-7 target gene Id1 and MMP activity was significantly lower than in CTGF+/− mice (Nguyen et al.,
Another possible hypothesis is that BMP-7 exerts anti-fibrotic effect by affecting ECM formation and degradation. BMP-7 reduced TGF-β induced overexpression of ECM proteins in mesangial cells without affecting their gene levels, besides, BMP-7 preserves MMP2 activity and blocks PAI-1 promoter activation in TGF-β-stimulated mesangial cells (Wang and Hirschberg,
Inflammatory response can be considered as the onset of wound healing, while non-resolution inflammation is a relentless driver of fibrogenesis that forms a vicious cycle to finally lead to irreversible fibrosis. Anti-inflammatory treatment on the onset and progression stage of renal fibrosis also attracted highly attention. Current studies of BMP-7 in the kidney mainly focused on its anti-fibrotic role, though many studies have suggested the possible anti-inflammatory effect of BMP-7. In the IRI model, BMP-7 reduced ICAM-1 expression and accumulation and activity of neutrophils (Vukicevic et al.,
| Murine podocyte | HG 25 mM TGF-β 100 pM | Reduced capase-3 activity, reduced apoptosis | Mitu et al., |
| Murine podocyte | HG | Restored synaptopodin and podocin | De Petris et al., |
| Rat mesangial cell | HG 30 nM | Decreased ROS and TGF-β | Yeh et al., |
| Mesangial cell | polymeric IgA | Reduced expression of TNF-α, IL-6, TGF-β, fibronectin | Chan et al., |
| Mesangial cell | TGF-β 50–200 pM | Reduced ECM accumulation, maintained activity of MMP2 | Wang and Hirschberg, |
| Mesangial cell | TGF-β 12.5–200 pM | BMP-7-induced opposition to TGF-β required Smad5 | Wang and Hirschberg, |
| Human PTECs | HSA 5 mg/ml | Repressed NIK dependent chemokine synthesis | Lim et al., |
| HK2 cell | AA 30, 60, 120 umol/L | Preserved cell phenotype and cell viability, reduced TGF-β and collagen 3 secretion | Wang et al., |
| HK2 cell | TGF-β1 ng/ml | Suppressed PAI-1, CTGF and TGF-β expression, preserved SnoN expression | Luo et al., |
| HK2 cell | CsA 4.2 μM | Preserved epithelial cell phenotype, restored E-cadherin and decreased ECM secretion | Xu et al., |
| HK2 cell | TGF-β3 ng/ml | Reversed EMT decreased ECM expression | Xu et al., |
| HK2 cell and RPTEC and TCMK-1 cells | TGF-β 10 ng/ml (RPTEC); 3 ng/ml (HK2) | Failed to attenuate EMT in RPTEC or HK-2 cells, BMP-7 alone decreased E-cadherin expression and increased vimentin, CTGF and TGF-β1 expression; Preserved E-cadherin in TCMK-1 cells | Dudas et al., |
| HK2 cell | MCP-1 0.1, 1, 10, 50 ng/ml | Inhibited MCP-1 induced EMT through TGF-β-Smad 3 pathways | Tan et al., |
| TK173 | N/A | Increased fibroblast E-cadherin, Pax2, Wnt4 expression and E-cadherin promoter activity (MET) | Zeisberg et al., |
| HK2 cell | U937 cell condition media TNF-a 10 ng/ml | Reduced U937-dependent TGF-β promoter activity and TGF-β synthesis through interaction with cell surface hyaluronan; | Zhang et al., |
| NP-1 cell | TGF-β 3 ng/ml | Preserved E-cadherin and ZO-1 expression | Zeisberg et al., |
Role of oxidative stress in tissue fibrogenesis has been discussed extensively (Poli,
Increasing evidence from different independent experiments has approved the anti-fibrotic effect of BMP-7 in renal fibrotic disease regardless of its primary causes. BMP-7 exerts anti-inflammatory, anti-fibrotic and anti-oxidative responses caused by various stimuli, reduces ECM production by suppressing matrix-producing cell activity and inducing MET, enhances ECM degradation by increasing the activity of MMP and reducing activation of PAI-1. Clinical trials have also been launched to investigate the efficacy of BMP-7 (analog) in both acute and chronic kidney disease. However, despite the increasing understanding of BMP-7 signaling transduction and regulation, there are also controversial results in its efficacy. For instance, there was no effect of BMP-7 in skin, lung or renal fibrosis, and some studies even showed that BMP-7 is a promoter of fibrosis. Based on the overall results from all
Rui Xi Li, Wai Han Yiu and Sydney C. W. Tang designed the study. Rui Xi Li and Wai Han Yiu carried out the experiments. Rui Xi Li analyzed the data and wrote the manuscript. Wai Han Yiu provided technical support. Sydney C. W. Tang edited the manuscript.
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.