Proliferation of Bone Marrow-Derived Cells Contributes to Regeneration after Folic Acid-Induced Acute Tubular Injury

Fang, Te Chao; Alison, Malcolm R.; Cook, H. Terence; Jeffery, Rosemary; Wright, Nicholas; Poulsom, Richard

doi:10.1681/asn.2004121089

Cited by 144 publications

(120 citation statements)

References 46 publications

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“…Furthermore, ex vivo manipulation of macrophages using specific cytokines confirmed that classically activated, M1 macrophages worsen chronic inflammatory adriamycin nephropathy, whereas alternatively activated M2 macrophages reduce histological disruption and functional injury [36]. Of note, in the heart Camargo et al [37] have [39] Glycerol-induced ARF (mouse) MSCs Enhanced tubular proliferation [68] IR (rat) Papilla LRCs Proliferation and incorporation [149] IR (mouse) Bone marrow No functional improvement, intrarenal cells are the main source of repopulating cell during repair [22] Folic acid-induced acute tubular injury (mouse) Bone marrow Intrinsic tubular cell proliferation accounts for repair after damage [150] Folic acid-induced acute tubular injury (mouse) Bone marrow 10% incorporation in tubules and G-CSF doubles this rate [151] IR (rat) MSCs Improved renal function and less injury [152] Cisplatin-induced renal failure (mouse) MSCs Accelerated tubular proliferation [153] UUO (mouse) Bone marrow macrophages Reduced renal fibrosis [41] IR (rat) MSCs Improved renal function, increased proliferation and decreased apoptosis [84] IR (rat) rKS56 (S3 segment outgrowth) Replace tubular and improve function [80] Glycerol-induced tubulonecrosis (mouse) Human CD133 + cells Homing and tubular integration [66] UUO (rat) Label-retaining cells (LRC) Proliferates, migrates and transdifferentiates into fibroblast-like cells [27] Cisplatin-induced renal failure (mouse) G-CSF ± M-CSF Improvement in renal function and prevention of renal tubular injury [154] Anti-Thy1.1 GN (rat) MSCs Increased glomerular proliferation and reduction in proteinuria [53] Col4α3 deficiency (mouse) MSCs Prevented loss of peritubular capillaries and reduced fibrosis but no increase in function or survival [24] Col4α3 deficiency (mouse) Bone marrow Partial restoration of expression of the type IV collagen α3 chain, improved histology and function [25] Col4α3 deficiency (mouse) MSCs Improved function and glomerular scarring and interstitial fibrosis reduced [155] UUO (mouse) BM Instertitial BM-derived cells do not contribute significantly to collagen synthesis after damage [74] Adriamycin-nephropathy (mouse) Renal side population Functional amprovement but very low rate of engraftment. [78] IR (rat) Multipotent renal progenitor cells In vivo epithelial differentiation, no difference on renal function [67] Cultured met...…”

Section: Bone Marrow-derived Cellsmentioning

confidence: 99%

Stem cell options for kidney disease

Hopkins

Rae

et al. 2008

The Journal of Pathology

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Chronic kidney disease (CKD) is increasing at the rate of 6-8% per annum in the US alone. At present, dialysis and transplantation remain the only treatment options. However, there is hope that stem cells and regenerative medicine may provide additional regenerative options for kidney disease. Such new treatments might involve induction of repair using endogenous or exogenous stem cells or the reprogramming of the organ to reinitiate development. This review addresses the current state of understanding with respect to the ability of non-renal stem cell sources to influence renal repair, the existence of endogenous renal stem cells and the biology of normal renal repair in response to damage. Understanding repair options via an understanding of renal developmentThe prevalence and incidence of chronic kidney disease (CKD) is increasing at 6-8% per annum in the USA alone, largely as a result of increased prevalence of diabetes and obesity [1]. To understand what might be possible with respect to cellular therapies or regenerative medicine for the kidney, one first needs to consider what is understood about normal renal development and response to injury. The kidney has been classically regarded as an organ with minimal cellular turnover and no capacity for regeneration. The subsequent identification of stem cells in a number of such organs, including the brain, has challenged this view. However, the dogma remains that the kidney reaches a maximal complement of nephrons and then loses these over time [2]. This dogma is drawn from our understanding of the development of this organ. The progenitor population during developmentThe kidney is mesodermal in origin and develops from two populations derived from intermediate mesoderm, the ureteric bud (UB) and the metanephric mesenchyme (MM). While an even broader potential had been proposed [3], genetic and lineage analyses have confirmed that the MM gives rise to all portions of the nephron other than the collecting ducts and also gives rise to elements of the renal interstitium [4][5][6]. The UB gives rise to the ureter and collecting ducts only. The MM is apparently not homogeneous but forms condensed mesenchyme around the tips of the branching UB. This cap mesenchyme (CM) contains self-renewing progenitors capable of generating all cells of the nephron other than the collecting ducts via an initial mesenchyme-epithelial transition (MET) event throughout the prenatal developmental period [6]. The continued expression of the transcription factor Six2 in CM is required for maintenance of this stem cell population during kidney development [5]. As the UB branches and extends through the MM, individual MET events occur at the underside of each tip to form a new nephron [2]. This nephron endowment therefore proceeds from the centre of the kidney out to the periphery, with the CM stem cell field remaining on the outer edge of the expanding organ. Endowment of new nephrons is restricted to prenatal development in humans, while in rodents it persists only until the imm...

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Section: Bone Marrow-derived Cellsmentioning

confidence: 99%

Stem cell options for kidney disease

Hopkins

Rae

et al. 2008

The Journal of Pathology

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“…Some experiments based on bone marrow transplantation indicated that bone marrow-derived stem cells may contribute to repopulate the injured nephrons. 10,11 MSCs were shown to localize within the injured kidneys when injected in mice with AKI. 3,5,6,12 However, several reports indicate only a transient recruitment of MSCs in the renal vasculature without a direct incorporation within the regenerating tubules.…”

mentioning

confidence: 99%

Mesenchymal Stem Cell-Derived Microvesicles Protect Against Acute Tubular Injury

Bruno¹,

Grange²,

Deregibus³

et al. 2009

Journal of the American Society of Nephrology

1,152

1,173

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Administration of mesenchymal stem cells (MSCs) improves the recovery from acute kidney injury (AKI).The mechanism may involve paracrine factors promoting proliferation of surviving intrinsic epithelial cells, but these factors remain unknown. In the current study, we found that microvesicles derived from human bone marrow MSCs stimulated proliferation in vitro and conferred resistance of tubular epithelial cells to apoptosis. The biologic action of microvesicles required their CD44-and ␤1-integrin-dependent incorporation into tubular cells. In vivo, microvesicles accelerated the morphologic and functional recovery of glycerol-induced AKI in SCID mice by inducing proliferation of tubular cells. The effect of microvesicles on the recovery of AKI was similar to the effect of human MSCs. RNase abolished the aforementioned effects of microvesicles in vitro and in vivo, suggesting RNA-dependent biologic effects. Microarray analysis and quantitative real time PCR of microvesicle-RNA extracts indicate that microvesicles shuttle a specific subset of cellular mRNA, such as mRNAs associated with the mesenchymal phenotype and with control of transcription, proliferation, and immunoregulation. These results suggest that microvesicles derived from MSCs may activate a proliferative program in surviving tubular cells after injury via a horizontal transfer of mRNA.

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“…9,10 Others used drugs such as cisplatin or folic acid to induce AKI. 11,12 Here, we used a model of nephrotoxic AKI induced by HgCl 2 , based on a standardized survival evaluation protocol already published. 13 Mercuric chloride at high doses causes an increase in serum creatinine, urea, and potassium.…”

Section: Discussionmentioning

confidence: 99%

Transplantation of Bone Marrow Mononuclear Cells Reduces Mortality and Improves Renal Function on Mercury-Induced Kidney Injury in Mice

et al. 2013

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Objective: Recent studies have demonstrated the therapeutic effects of bone marrow-derived cells in tissue regeneration. The aim of this study was to investigate the effects of bone marrow mononuclear cell (BMMC) transplantation in a mouse model of acute renal failure (ARF) induced by mercuric chloride. Methods: BMMC was isolated from male BALB/c mice and injected into female mice treated with a lethal dose (LD90) of mercuric chloride. Survival rate, histopathological analysis, and assessment of urea, creatinine, sodium, potassium, and mercury levels were carried out. Results: Cellular therapy with BMMC significantly reduced the mortality induced by mercuric chloride ( p < 0.05). This finding correlated with a decrease in serum levels of urea ( p ¼ 0.04) and potassium ( p < 0.01). However, no differences in renal morphology were observed when BMMC-treated and control group were compared. Conclusion: Transplanted BMMC improve renal function and reduce mortality and, therefore, may represent a new therapeutic alternative to treat ARF.

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Proliferation of Bone Marrow-Derived Cells Contributes to Regeneration after Folic Acid-Induced Acute Tubular Injury

Cited by 144 publications

References 46 publications

Stem cell options for kidney disease

Stem cell options for kidney disease

Mesenchymal Stem Cell-Derived Microvesicles Protect Against Acute Tubular Injury

Transplantation of Bone Marrow Mononuclear Cells Reduces Mortality and Improves Renal Function on Mercury-Induced Kidney Injury in Mice

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