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克洛什突变斑马鱼的视网膜发育异常。

Abnormal retinal development in Cloche mutant zebrafish.

作者信息

Dhakal Susov, Stevens Craig B, Sebbagh Meyrav, Weiss Omri, Frey Ruth A, Adamson Seth, Shelden Eric A, Inbal Adi, Stenkamp Deborah L

机构信息

Department of Biological Sciences, University of Idaho, Moscow, ID USA.

Neuroscience Graduate Program, University of Idaho, Moscow, ID USA.

出版信息

Dev Dyn. 2015 Nov;244(11):1439-1455. doi: 10.1002/dvdy.24322. Epub 2015 Sep 2.

DOI:10.1002/dvdy.24322
PMID:26283463
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4619121/
Abstract

BACKGROUND

Functions for the early embryonic vasculature in regulating development of central nervous system tissues, such as the retina, have been suggested by in vitro studies and by in vivo manipulations that caused additional ocular vessels to develop. Here, we use an avascular zebrafish embryo, cloche-/- (clo-/-), to begin to identify necessary developmental functions of the ocular vasculature in regulating development and patterning of the neural retina, in vivo. These studies are possible in zebrafish embryos, which do not yet rely upon the vasculature for tissue oxygenation.

RESULTS

clo-/- embryos lacked early ocular vasculature and were microphthalmic, with reduced retinal cell proliferation and cell survival. Retinas of clo mutants were disorganized, with irregular synaptic layers, mispatterned expression domains of retinal transcription factors, morphologically abnormal Müller glia, reduced differentiation of specific retinal cell types, and sporadically distributed cone photoreceptors. Blockade of p53-mediated cell death did not completely rescue this phenotype and revealed ectopic cones in the inner nuclear layer. clo-/- embryos did not upregulate a molecular marker for hypoxia.

CONCLUSIONS

The disorganized retinal phenotype of clo-/- embryos is consistent with a neural and glial developmental patterning role for the early ocular vasculature that is independent of its eventual function in gas exchange.

摘要

背景

体外研究和导致额外眼血管发育的体内操作表明,早期胚胎血管系统在调节中枢神经系统组织(如视网膜)发育方面具有功能。在这里,我们使用无血管的斑马鱼胚胎cloche-/-(clo-/-),在体内开始确定眼血管系统在调节神经视网膜发育和模式形成中的必要发育功能。这些研究在斑马鱼胚胎中是可行的,因为它们尚未依赖血管系统进行组织氧合。

结果

clo-/-胚胎缺乏早期眼血管系统,眼睛小,视网膜细胞增殖和细胞存活减少。clo突变体的视网膜结构紊乱,突触层不规则,视网膜转录因子的表达域模式错误,Müller胶质细胞形态异常,特定视网膜细胞类型的分化减少,视锥光感受器散在分布。阻断p53介导的细胞死亡并不能完全挽救这种表型,并且在内核层中发现了异位视锥。clo-/-胚胎没有上调缺氧分子标记。

结论

clo-/-胚胎视网膜结构紊乱的表型与早期眼血管系统在神经和胶质发育模式形成中的作用一致,这与其最终在气体交换中的功能无关。

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