MicroRNA-21 promotes fibrosis of the kidney by silencing metabolic pathways

BN Chau, C Xin, J Hartner, S Ren… - Science translational …, 2012 - science.org
BN Chau, C Xin, J Hartner, S Ren, AP Castano, G Linn, J Li, PT Tran, V Kaimal, X Huang…
Science translational medicine, 2012science.org
Scarring of the kidney is a major public health concern, directly promoting loss of kidney
function. To understand the role of microRNA (miRNA) in the progression of kidney scarring
in response to injury, we investigated changes in miRNA expression in two kidney fibrosis
models and identified 24 commonly up-regulated miRNAs. Among them, miR-21 was highly
elevated in both animal models and in human transplanted kidneys with nephropathy.
Deletion of miR-21 in mice resulted in no overt abnormality. However, miR-21−/− mice …
Scarring of the kidney is a major public health concern, directly promoting loss of kidney function. To understand the role of microRNA (miRNA) in the progression of kidney scarring in response to injury, we investigated changes in miRNA expression in two kidney fibrosis models and identified 24 commonly up-regulated miRNAs. Among them, miR-21 was highly elevated in both animal models and in human transplanted kidneys with nephropathy. Deletion of miR-21 in mice resulted in no overt abnormality. However, miR-21−/− mice suffered far less interstitial fibrosis in response to kidney injury, a phenotype duplicated in wild-type mice treated with anti–miR-21 oligonucleotides. Global derepression of miR-21 target mRNAs was readily detectable in miR-21−/− kidneys after injury. Analysis of gene expression profiles up-regulated in the absence of miR-21 identified groups of genes involved in metabolic pathways, including the lipid metabolism pathway regulated by peroxisome proliferator–activated receptor-α (Pparα), a direct miR-21 target. Overexpression of Pparα prevented ureteral obstruction–induced injury and fibrosis. Pparα deficiency abrogated the antifibrotic effect of anti–miR-21 oligonucleotides. miR-21 also regulated the redox metabolic pathway. The mitochondrial inhibitor of reactive oxygen species generation Mpv17l was repressed by miR-21, correlating closely with enhanced oxidative kidney damage. These studies demonstrate that miR-21 contributes to fibrogenesis and epithelial injury in the kidney in two mouse models and is a candidate target for antifibrotic therapies.
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