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Conditional Myh9 and Myh10 inactivation in adult mouse renal epithelium results in progressive kidney disease
Karla L. Otterpohl, Brook W. Busselman, Ishara Ratnayake, Ryan G. Hart, Kimberly R. Hart, Claire M. Evans, Carrie L. Phillips, Jordan R. Beach, Phil Ahrenkiel, Bruce A. Molitoris, Kameswaran Surendran, Indra Chandrasekar
Karla L. Otterpohl, Brook W. Busselman, Ishara Ratnayake, Ryan G. Hart, Kimberly R. Hart, Claire M. Evans, Carrie L. Phillips, Jordan R. Beach, Phil Ahrenkiel, Bruce A. Molitoris, Kameswaran Surendran, Indra Chandrasekar
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Research Article Cell biology Nephrology

Conditional Myh9 and Myh10 inactivation in adult mouse renal epithelium results in progressive kidney disease

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Abstract

Actin-associated nonmuscle myosin II (NM2) motor proteins play critical roles in a myriad of cellular functions, including endocytosis and organelle transport pathways. Cell type–specific expression and unique subcellular localization of the NM2 proteins, encoded by the Myh9 and Myh10 genes, in the mouse kidney tubules led us to hypothesize that these proteins have specialized functional roles within the renal epithelium. Inducible conditional knockout (cKO) of Myh9 and Myh10 in the renal tubules of adult mice resulted in progressive kidney disease. Prior to overt renal tubular injury, we observed intracellular accumulation of the glycosylphosphatidylinositol-anchored protein uromodulin (UMOD) and gradual loss of Na+ K+ 2Cl– cotransporter from the apical membrane of the thick ascending limb epithelia. The UMOD accumulation coincided with expansion of endoplasmic reticulum (ER) tubules and activation of ER stress and unfolded protein response pathways in Myh9&10-cKO kidneys. We conclude that NM2 proteins are required for localization and transport of UMOD and loss of function results in accumulation of UMOD and ER stress–mediated progressive renal tubulointerstitial disease. These observations establish cell type–specific role(s) for NM2 proteins in regulation of specialized renal epithelial transport pathways and reveal the possibility that human kidney disease associated with MYH9 mutations could be of renal epithelial origin.

Authors

Karla L. Otterpohl, Brook W. Busselman, Ishara Ratnayake, Ryan G. Hart, Kimberly R. Hart, Claire M. Evans, Carrie L. Phillips, Jordan R. Beach, Phil Ahrenkiel, Bruce A. Molitoris, Kameswaran Surendran, Indra Chandrasekar

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Figure 6

Expansion of RTN4 positive ER tubules is observed in the Myh9&10-cKO mouse kidneys.

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Expansion of RTN4 positive ER tubules is observed in the Myh9&10-cKO...
(A–F) Images represent paraformaldehyde-fixed (PFA-fixed) 9-week-old control and cKO kidney sections stained to visualize ER tubule–associated protein RTN4 along with UMOD and DAPI in the TAL tubules. (A) Control kidney section stained for RTN4 and UMOD showing discrete RTN4 staining (red) in the TAL tubules that also express UMOD (green) along the apical membrane. (B) Region of interest (ROI) images from a control TAL tubule in A (white box) indicate that UMOD localizes to the apical membrane (white arrowhead), while RTN4 appears as very thin filaments that run from the apical membrane to the basolateral membrane. (C and E) cKO kidney sections show increased intensity of RTN4 staining in the cKO TAL cells that partially colocalized with UMOD in several regions of the cell. UMOD accumulation within the cells is apparent. (D and F) ROI images of cKO TAL tubules represented in C and E (white box) show changes in RTN4 and UMOD expression and localization. Gray scale and merged images show the increase in RTN4 and UMOD intracellular staining in the cKO TAL tubule, as well as regions of colocalization along the membrane and inside the cell. Asterisks (*) in all images denote the lumen, and white arrowhead marks the apical membrane. Scale bar: 10 μm. Images are representative of analysis of sections from 3 control and cKO kidneys (n = 3).

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