Renal stem cell

Renal stem cell
Renal stem cell
Details
Precursor	Metanephric blastema
Location	Kidney
Function	Stem cell
Identifiers
Latin	ansa nephroni
	Anatomical terms of microanatomy [edit on Wikidata]

Renal stem cells are self-renewing, multipotent stem cells which are able to give rise to all the cell types of the kidney. It is involved in the homeostasis and repair of the kidney, and holds therapeutic potential for treatment of kidney failure.^[1]

Structure[edit]

Strong evidence suggests that renal stem cells are located in the renal papilla.^[2] Using stain-retaining assay (with bromodeoxyuridine, or BrdU), a low-cycling cell population was found in the papillary region, which was able to divide rapidly to repair the damage caused by transcient renal ischemia.^[2] These cells are able to incorporate into other renal tissues, and was able to repeatedly form spheres in 3D cultures, and clonal analysis also exhibited its multipotency.^[2]

Other reports have suggested the renal tubule and renal capsule to be the site of stem cells. The renal capsule contain stain-retaining cells which exhibited markers for mesenchymal stem cells; after their removal, recovery was significantly slower post-ischemic injury. These evidence suggests a stem cell population exists within the renal capsule.^[3]

Development[edit]

Using in vivo lineage tracing techniques, Lgr5⁺ cells were found to contribute to the nephron, specifically to the ascending limb of the loop of Henle and the distal convoluted tubule. Thus, Lgr5⁺ cells can potentially be a marker for renal stem and/or progenitor cells.^[4]

Clinical significance[edit]

There is much debate regarding the cells involved in repair after injury; while some suggests that stem cells are the sole driving force of repair, others suggests that cells dedifferentiate after damage to act like stem cells.^[5] Alternately, it was also reported that differentiated tubular epithelial cells are the driving mechanism for regeneration after injury, using proliferative expansion as the mechanism.^[6]

Multipotent mouse kidney progenitor cells (MKPC) were obtained from Myh9 targeted mutant mice. Injection of MKPC into mice post-ischemic injury saw the MKPC regenerating different cell lineages and was able to regenerate renal function and enhanced survival.^[7]

Renal induced pluripotent stem cells[edit]

It has been reported that endogenous kidney tubular renal epithelial cells can be dedifferentiated into induced pluripotent stem cells by the treatment of only two factors - Oct4 and Sox2.^[8]

References[edit]

^ Brodie, J. C.; Humes, HD (2005). "Stem Cell Approaches for the Treatment of Renal Failure". Pharmacological Reviews. 57 (3): 299–313. doi:10.1124/pr.57.3.3. PMID 16109837. S2CID 13937248.
^ ^a ^b ^c Oliver, Juan A.; Maarouf, Omar; Cheema, Faisal H.; Martens, Timothy P.; Al-Awqati, Qais (2004). "The renal papilla is a niche for adult kidney stem cells". Journal of Clinical Investigation. 114 (6): 795–804. doi:10.1172/JCI20921. PMC 516259. PMID 15372103.
^ Park, H. C.; Yasuda, K.; Kuo, M. C.; Ni, J.; Ratliff, B.; Chander, P.; Goligorsky, M. S. (2010). "Renal capsule as a stem cell niche". AJP: Renal Physiology. 298 (5): F1254–F1262. doi:10.1152/ajprenal.00406.2009. PMC 2867407. PMID 20200095.
^ Barker, Nick; Rookmaaker, Maarten B.; Kujala, Pekka; Ng, Annie; Leushacke, Marc; Snippert, Hugo; Van De Wetering, Marc; Tan, Shawna; et al. (2012). "Lgr5+ve Stem/Progenitor Cells Contribute to Nephron Formation during Kidney Development". Cell Reports. 2 (3): 540–52. doi:10.1016/j.celrep.2012.08.018. PMID 22999937.
^ Humphreys, BD; Duffield, JS; Bonventre, JV (2006). "Renal stem cells in recovery from acute kidney injury". Minerva Urologica e Nefrologica. 58 (4): 329–37. PMID 17268398.
^ Humphreys, Benjamin D.; Valerius, M. Todd; Kobayashi, Akio; Mugford, Joshua W.; Soeung, Savuth; Duffield, Jeremy S.; McMahon, Andrew P.; Bonventre, Joseph V. (2008). "Intrinsic Epithelial Cells Repair the Kidney after Injury". Cell Stem Cell. 2 (3): 284–91. doi:10.1016/j.stem.2008.01.014. PMID 18371453.
^ Lee, PT; Lin, HH; Jiang, ST; Lu, PJ; Chou, KJ; Fang, HC; Chiou, YY; Tang, MJ (2010). "Mouse kidney progenitor cells accelerate renal regeneration and prolong survival after ischemic injury". Stem Cells. 28 (3): 573–84. doi:10.1002/stem.310. PMID 20099318. S2CID 30290648.
^ Montserrat, N.; Ramirez-Bajo, M. J.; Xia, Y.; Sancho-Martinez, I.; Moya-Rull, D.; Miquel-Serra, L.; Yang, S.; Nivet, E.; et al. (2012). "Generation of Induced Pluripotent Stem Cells from Human Renal Proximal Tubular Cells with Only Two Transcription Factors, Oct4 and Sox2". Journal of Biological Chemistry. 287 (29): 24131–8. doi:10.1074/jbc.M112.350413. PMC 3397840. PMID 22613719.

[1] Brodie, J. C.; Humes, HD (2005). "Stem Cell Approaches for the Treatment of Renal Failure". Pharmacological Reviews. 57 (3): 299–313. doi:10.1124/pr.57.3.3. PMID 16109837. S2CID 13937248.

[DoiJCI-2] Oliver, Juan A.; Maarouf, Omar; Cheema, Faisal H.; Martens, Timothy P.; Al-Awqati, Qais (2004). "The renal papilla is a niche for adult kidney stem cells". Journal of Clinical Investigation. 114 (6): 795–804. doi:10.1172/JCI20921. PMC 516259. PMID 15372103.

[3] Park, H. C.; Yasuda, K.; Kuo, M. C.; Ni, J.; Ratliff, B.; Chander, P.; Goligorsky, M. S. (2010). "Renal capsule as a stem cell niche". AJP: Renal Physiology. 298 (5): F1254–F1262. doi:10.1152/ajprenal.00406.2009. PMC 2867407. PMID 20200095.

[4] Barker, Nick; Rookmaaker, Maarten B.; Kujala, Pekka; Ng, Annie; Leushacke, Marc; Snippert, Hugo; Van De Wetering, Marc; Tan, Shawna; et al. (2012). "Lgr5+ve Stem/Progenitor Cells Contribute to Nephron Formation during Kidney Development". Cell Reports. 2 (3): 540–52. doi:10.1016/j.celrep.2012.08.018. PMID 22999937.

[5] Humphreys, BD; Duffield, JS; Bonventre, JV (2006). "Renal stem cells in recovery from acute kidney injury". Minerva Urologica e Nefrologica. 58 (4): 329–37. PMID 17268398.

[6] Humphreys, Benjamin D.; Valerius, M. Todd; Kobayashi, Akio; Mugford, Joshua W.; Soeung, Savuth; Duffield, Jeremy S.; McMahon, Andrew P.; Bonventre, Joseph V. (2008). "Intrinsic Epithelial Cells Repair the Kidney after Injury". Cell Stem Cell. 2 (3): 284–91. doi:10.1016/j.stem.2008.01.014. PMID 18371453.

[7] Lee, PT; Lin, HH; Jiang, ST; Lu, PJ; Chou, KJ; Fang, HC; Chiou, YY; Tang, MJ (2010). "Mouse kidney progenitor cells accelerate renal regeneration and prolong survival after ischemic injury". Stem Cells. 28 (3): 573–84. doi:10.1002/stem.310. PMID 20099318. S2CID 30290648.

[8] Montserrat, N.; Ramirez-Bajo, M. J.; Xia, Y.; Sancho-Martinez, I.; Moya-Rull, D.; Miquel-Serra, L.; Yang, S.; Nivet, E.; et al. (2012). "Generation of Induced Pluripotent Stem Cells from Human Renal Proximal Tubular Cells with Only Two Transcription Factors, Oct4 and Sox2". Journal of Biological Chemistry. 287 (29): 24131–8. doi:10.1074/jbc.M112.350413. PMC 3397840. PMID 22613719.

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v t e Stem cells
Sources/types	Embryonic stem cells Adult stem cells Cancer stem cells Induced pluripotent stem cells Induced stem cells
Cell potency	Totipotent Zygote Spore Morula Pluripotent Embryonic stem cell Callus Multipotent Progenitor cell: Endothelial stem cell Hematopoietic stem cell Mesenchymal stem cell Neural stem cell Unipotent Precursor cell
Related articles	Cellular differentiation Stem cell therapy Stem cell controversy Stem cell line Stem cell laws Stem cell laws and policy in the United States Epigenetics in stem cell differentiation
Category

Structure[edit]

Development[edit]

Clinical significance[edit]

Renal induced pluripotent stem cells[edit]

See also[edit]

References[edit]