Amity F. Eaton, Elizabeth C Danielson, Diane Capen, M. Merkulova, Dennis Brown
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We, therefore, hypothesized that Dmxl1 is a mammalian V-ATPase assembly factor. Here, we generated kidney IC-specific Dmxl1 knockout (KO) mice, which had high urine pH, like B1 V-ATPase KO mice, suggesting impaired V-ATPase function. Western blotting showed decreased B1 expression and B1 (V1) and a4 (VO) subunits were more intracellular and less colocalized in Dmxl1 KO ICs. In parallel, subcellular fractionation revealed less V1 associated B1 in the membrane fraction of KO cells relative to the cytosol. Furthermore, a Proximity Ligation Assay (PLA) performed using probes against B1 and a4 V-ATPase subunits also revealed decreased association. We propose that loss of Dmxl1 reduces V-ATPase holoenzyme assembly, thereby inhibiting proton pumping function. Dmxl1 may recruit the V1 domain to the membrane and facilitate assembly with the VO domain and in its absence V1 may be targeted for degradation. 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引用次数: 0
摘要
质子泵 V-ATP 酶驱动着重要的生物过程,如细胞内细胞器的酸化。重要的是,V-ATPase 的 V1 和 VO 结构域必须组装成一个功能性全酶。V-ATPase 功能障碍会导致癌症、神经变性和糖尿病,以及因分泌质子的肾脏间质细胞(IC)活性降低而引起的全身性酸中毒。然而,人们对哺乳动物体内 V-ATP 酶的分子调控知之甚少。我们发现了哺乳动物 V-ATP 酶的一种新型互作因子--黑腹果蝇 X 染色体基因样 1(Dmxl1),又名 Rabconnectin-3A。Dmxl1 的酵母同源物 Rav1p 是催化结构域可逆组装的复合体的一部分。因此,我们推测 Dmxl1 是哺乳动物的 V-ATPase 组装因子。在这里,我们产生了肾脏IC特异性Dmxl1基因敲除(KO)小鼠,它们的尿液pH值很高,就像B1 V-ATP酶KO小鼠一样,表明V-ATP酶功能受损。Western 印迹显示,在 Dmxl1 KO IC 中,B1 表达减少,B1(V1)和 a4(VO)亚基在细胞内的分布更多,共定位更少。同时,亚细胞分馏显示,相对于细胞质,KO 细胞膜分馏中与 V1 相关的 B1 更少。此外,使用针对 B1 和 a4 V-ATPase 亚基的探针进行的邻近连接测定(PLA)也显示出关联性降低。我们认为,Dmxl1 的缺失减少了 V-ATPase 全酶的组装,从而抑制了质子泵功能。Dmxl1 可能会将 V1 结构域募集到膜上,并促进其与 VO 结构域的组装。我们的结论是,Dmxl1是哺乳动物V-ATP酶的真正组装因子。
Dmxl1 is an Essential Mammalian Gene that is Required for V-ATPase Assembly and Function In Vivo
The proton pumping V-ATPase drives essential biological processes, such as acidification of intracellular organelles. Critically, the V-ATPase domains, V1 and VO, must assemble to produce a functional holoenzyme. V-ATPase dysfunction results in cancer, neurodegeneration, and diabetes, as well as systemic acidosis caused by reduced activity of proton-secreting kidney intercalated cells (ICs). However, little is known about the molecular regulation of V-ATPase in mammals. We identified a novel interactor of the mammalian V-ATPase, Drosophila melanogaster X chromosomal gene-like 1 (Dmxl1), aka Rabconnectin-3A. The yeast homologue of Dmxl1, Rav1p, is part of a complex that catalyzes the reversible assembly of the domains. We, therefore, hypothesized that Dmxl1 is a mammalian V-ATPase assembly factor. Here, we generated kidney IC-specific Dmxl1 knockout (KO) mice, which had high urine pH, like B1 V-ATPase KO mice, suggesting impaired V-ATPase function. Western blotting showed decreased B1 expression and B1 (V1) and a4 (VO) subunits were more intracellular and less colocalized in Dmxl1 KO ICs. In parallel, subcellular fractionation revealed less V1 associated B1 in the membrane fraction of KO cells relative to the cytosol. Furthermore, a Proximity Ligation Assay (PLA) performed using probes against B1 and a4 V-ATPase subunits also revealed decreased association. We propose that loss of Dmxl1 reduces V-ATPase holoenzyme assembly, thereby inhibiting proton pumping function. Dmxl1 may recruit the V1 domain to the membrane and facilitate assembly with the VO domain and in its absence V1 may be targeted for degradation. We conclude that Dmxl1 is a bona-fide mammalian V-ATPase assembly factor.