粗升肢Myh9和Myh10肌球蛋白马达的特异性失活导致渐进性肾病,并驱动远端肾小球和集合管的性别特异性细胞适应。

IF 5.1 Q2 CELL BIOLOGY Function (Oxford, England) Pub Date : 2024-11-05 DOI:10.1093/function/zqae048
Karla L Otterpohl, Brook W Busselman, Jenna L Zimmerman, Malini Mukherjee, Claire Evans, Kelly Graber, Vedant P Thakkar, Jermaine G Johnston, Arooba Ilyas, Michelle L Gumz, Douglas C Eaton, Jeff M Sands, Kameswaran Surendran, Indra Chandrasekar
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引用次数: 0

摘要

我们之前的工作确定了肌动蛋白相关肌球蛋白马达蛋白MYH9和MYH10在厚上升肢(TAL)特异性货物、尿调节蛋白(UMOD)和Na + K + 2Cl- 共转运体(NKCC2)的转运中的作用。在这里,我们建立了一个TAL特异性Myh9&10条件性基因敲除(Myh9&10 TAL-cKO)小鼠模型,以确定MYH9&10蛋白在TAL货物运输中的细胞自主作用,并了解TAL功能障碍在成人肾脏中的后果。Myh9&10 TAL-cKO 小鼠会出现进行性肾病,并伴有组织学变化、肾小管损伤标记物、ER 应激/折叠蛋白反应途径上调、血尿素氮和血清肌酐升高等证实的病理性肾小管损伤。然而,雄性小鼠的存活时间是雌性小鼠的两倍。我们确定,发病率的性别双态性是由于远端肾小球和集合管对 TAL 功能障碍的适应以及 NKCC2 表达的显著降低。我们证明,这引发了一种代偿机制,涉及远端肾小管和集合管内特定性别的细胞适应,以促进钠的重吸收。虽然雌雄小鼠都会通过激活髓质集合管中ENaC的表达来过度补偿,从而导致高钠血症,但在雄性Myh9&10 TAL-cKO小鼠中,这种情况会被抑制,因为它们最初会促进远端肾小管中氯化钠共转运体(NCC)的更高表达。我们的研究结果表明,TAL 功能受损会导致髓质集合管细胞适应不良,从而获得类似皮质的特性,包括 ENaC 表达。这项工作进一步证实了肌球蛋白运动蛋白 MYH9&10 在维持 TAL 中 NKCC2 表达方面的细胞自主作用,并揭示了远端肾小球和集合管段对 TAL 功能障碍的适应机制。
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Thick Ascending Limb Specific Inactivation of Myh9 and Myh10 Myosin Motors Results in Progressive Kidney Disease and Drives Sex-specific Cellular Adaptation in the Distal Nephron and Collecting Duct.

Our previous work established a role for actin associated myosin motor proteins MYH9 and MYH10 in the trafficking of thick ascending limb (TAL) specific cargoes, uromodulin (UMOD) and Na + K + 2Cl- cotransporter (NKCC2). Here, we have generated a TAL-specific Myh9&10 conditional knockout (Myh9&10 TAL-cKO) mouse model to determine the cell autonomous roles for MYH9&10 proteins in TAL cargo transport and to understand the consequence of TAL dysfunction in the adult kidney. Myh9&10 TAL-cKO mice develop progressive kidney disease with pathological tubular injury confirmed by histological changes, tubular injury markers, upregulation of ER stress/unfolded protein response pathway, and higher blood urea nitrogen and serum creatinine. However, male mice survive twice as long as female mice. We determined that the sexual dimorphism in morbidity is due to adaptation of the distal nephron and the collecting ducts in response to TAL dysfunction and significantly lower NKCC2 expression. We demonstrate that this triggers a compensatory mechanism involving sex-specific cellular adaptation within the distal tubules and collecting ducts to boost sodium reabsorption. While both sexes overcompensate by activating ENaC expression in the medullary collecting ducts resulting in hypernatremia, this is subdued in male Myh9&10 TAL-cKO mice as they initially promote higher sodium chloride cotransporter (NCC) expression within the distal nephron. Our results indicate that compromised TAL function results in maladaptation of medullary collecting duct cells, which acquire cortical-like properties, including ENaC expression. This work further confirms a cell autonomous role for myosin motor proteins MYH9&10 in the maintenance of NKCC2 expression in the TAL and uncover adaptive mechanisms of the distal nephron and the collecting duct segments in response to TAL dysfunction.

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