Cheng Christina N, Wingert Rebecca A
Department of Biological Sciences and Center for Zebrafish Research, University of Notre Dame, 100 Galvin Life Sciences, Notre Dame, IN 46556, USA.
Department of Biological Sciences and Center for Zebrafish Research, University of Notre Dame, 100 Galvin Life Sciences, Notre Dame, IN 46556, USA.
Dev Biol. 2015 Mar 1;399(1):100-116. doi: 10.1016/j.ydbio.2014.12.020. Epub 2014 Dec 25.
The mechanisms that establish nephron segments are poorly understood. The zebrafish embryonic kidney, or pronephros, is a simplified yet conserved genetic model to study this renal development process because its nephrons contain segments akin to other vertebrates, including the proximal convoluted and straight tubules (PCT, PST). The zebrafish pronephros is also associated with the corpuscles of Stannius (CS), endocrine glands that regulate calcium and phosphate homeostasis, but whose ontogeny from renal progenitors is largely mysterious. Initial patterning of zebrafish renal progenitors in the intermediate mesoderm (IM) involves the formation of rostral and caudal domains, the former being reliant on retinoic acid (RA) signaling, and the latter being repressed by elevated RA levels. Here, using expression profiling to gain new insights into nephrogenesis, we discovered that the gene single minded family bHLH transcription factor 1a (sim1a) is dynamically expressed in the renal progenitors-first marking the caudal domain, then becoming restricted to the proximal segments, and finally exhibiting specific CS expression. In loss of function studies, sim1a knockdown expanded the PCT and abrogated both the PST and CS populations. Conversely, overexpression of sim1a modestly expanded the PST and CS, while it reduced the PCT. These results show that sim1a activity is necessary and partially sufficient to induce PST and CS fates, and suggest that sim1a may inhibit PCT fate and/or negotiate the PCT/PST boundary. Interestingly, the sim1a expression domain in renal progenitors is responsive to altered levels of RA, suggesting that RA regulates sim1a, directly or indirectly, during nephrogenesis. sim1a deficient embryos treated with exogenous RA formed nephrons that were predominantly composed of PCT segments, but lacked the enlarged PST observed in RA treated wild-types, indicating that RA is not sufficient to rescue the PST in the absence of sim1a expression. Alternately, when sim1a knockdowns were exposed to the RA inhibitor diethylaminobenzaldehyde (DEAB), the CS was abrogated rather than expanded as seen in DEAB treated wild-types, revealing that CS formation in the absence of sim1a cannot be rescued by RA biosynthesis abrogation. Taken together, these data reveal previously unappreciated roles for sim1a in zebrafish pronephric proximal tubule and CS patterning, and are consistent with the model that sim1a acts downstream of RA to mitigate the formation of these lineages. These findings provide new insights into the genetic pathways that direct nephron development, and may have implications for understanding renal birth defects and kidney reprogramming.
建立肾单位节段的机制目前还知之甚少。斑马鱼胚胎肾脏,即前肾,是研究这一肾脏发育过程的一个简化但保守的遗传模型,因为其肾单位包含与其他脊椎动物类似的节段,包括近端曲管和直小管(PCT、PST)。斑马鱼前肾还与斯坦尼氏小体(CS)相关,CS是调节钙和磷稳态的内分泌腺,但其从肾祖细胞的个体发生过程在很大程度上仍是个谜。斑马鱼肾祖细胞在中间中胚层(IM)中的初始模式形成涉及头侧和尾侧区域的形成,前者依赖视黄酸(RA)信号,而后者受到升高的RA水平的抑制。在这里,我们利用表达谱分析来深入了解肾发生,发现基因单 minded家族bHLH转录因子1a(sim1a)在肾祖细胞中动态表达——首先标记尾侧区域,然后局限于近端节段,最后在CS中特异性表达。在功能丧失研究中,sim1a敲低扩大了PCT,并消除了PST和CS群体。相反,sim1a的过表达适度扩大了PST和CS,同时减少了PCT。这些结果表明,sim1a的活性对于诱导PST和CS命运是必要的且部分是充分的,并表明sim1a可能抑制PCT命运和/或调节PCT/PST边界。有趣的是,肾祖细胞中sim1a的表达域对RA水平的改变有反应,这表明RA在肾发生过程中直接或间接调节sim1a。用外源性RA处理的sim1a缺陷胚胎形成的肾单位主要由PCT节段组成,但缺乏在RA处理的野生型中观察到的扩大的PST,这表明在没有sim1a表达的情况下,RA不足以挽救PST。或者,当sim1a敲低的胚胎暴露于RA抑制剂二乙氨基苯甲醛(DEAB)时,CS被消除而不是像在DEAB处理的野生型中那样扩大,这表明在没有sim1a的情况下,RA生物合成的消除不能挽救CS的形成。综上所述,这些数据揭示了sim1a在斑马鱼前肾近端小管和CS模式形成中以前未被认识到的作用,并且与sim1a在RA下游起作用以减轻这些谱系形成的模型一致。这些发现为指导肾单位发育的遗传途径提供了新的见解,并且可能对理解肾脏出生缺陷和肾脏重编程有启示意义。
