由剪接因子基因PRPF31中的错义突变引起的视网膜色素变性（RP11）的疾病机制。

Disease mechanism for retinitis pigmentosa (RP11) caused by missense mutations in the splicing factor gene PRPF31.

作者信息

Wilkie Susan E, Vaclavik Veronika, Wu Huimin, Bujakowska Kinga, Chakarova Christina F, Bhattacharya Shomi S, Warren Martin J, Hunt David M

机构信息

University College London Institute of Ophthalmology, London, United Kingdom.

出版信息

Mol Vis. 2008 Apr 18;14:683-90.

PMID:18431455

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2324120/

Abstract

PURPOSE

Missense mutations in the splicing factor gene PRPF31 cause a dominant form of retinitis pigmentosa (RP11) with reduced penetrance. Missense mutations in PRPF31 have previously been shown to cause reduced protein solubility, suggesting insufficiency of functional protein as the disease mechanism. Here we examine in further detail the effect of the A216P mutation on splicing function.

METHODS

Splicing activity was assayed using an in vivo assay in transfected mammalian cells with rhodopsin (RHO) and transducin (GNAT1) splicing templates. Pull-down assays were used to study the interaction between PRPF31 and one of its cognate partners in the spliceosome, PRPF6.

RESULTS

Splicing of RHO intron 3 and GNAT1 introns 3-5 mini-gene templates was inefficient with both spliced and unspliced products clearly detected. Assays using the RHO minigene template revealed a direct negative effect on splicing efficiency of the mutant. However, no effect of the mutation on splicing efficiency could be detected using the longer GNAT1 minigene template or using a full-length RHO transcript, splicing of which had an efficiency of 100%. No unspliced RHO transcripts could be detected in RNA from human retina. Pull-down assays between PRPF31 and PRPF6 proteins showed a stronger interaction for the mutant than wild type, suggesting a mechanism for the negative effect.

CONCLUSIONS

Splicing of full-length RHO is more efficient than splicing of the minigene, and assays using a full-length template more accurately mimic splicing in photoreceptors. The RP11 missense mutations exert their pathology mainly via a mechanism based on protein insufficiency due to protein insolubility, but there is also a minor direct negative effect on function.

摘要

目的

剪接因子基因PRPF31中的错义突变会导致显性遗传性视网膜色素变性（RP11），其外显率降低。此前已表明PRPF31中的错义突变会导致蛋白质溶解度降低，提示功能性蛋白质不足是疾病机制。在此，我们更详细地研究A216P突变对剪接功能的影响。

方法

使用视紫红质（RHO）和转导蛋白（GNAT1）剪接模板，在转染的哺乳动物细胞中进行体内实验来测定剪接活性。采用下拉实验研究PRPF31与其在剪接体中的一个同源伴侣PRPF6之间的相互作用。

结果

RHO内含子3以及GNAT1内含子3 - 5小基因模板的剪接效率低下，剪接和未剪接产物均能清晰检测到。使用RHO小基因模板的实验揭示了该突变对剪接效率有直接负面影响。然而，使用更长的GNAT1小基因模板或全长RHO转录本时，未检测到该突变对剪接效率有影响，全长RHO转录本的剪接效率为100%。在人类视网膜RNA中未检测到未剪接的RHO转录本。PRPF31和PRPF6蛋白之间的下拉实验表明，突变体的相互作用比野生型更强，提示了产生负面影响的一种机制。

结论

全长RHO的剪接比小基因的剪接更高效，使用全长模板的实验能更准确地模拟光感受器中的剪接情况。RP11错义突变主要通过基于蛋白质不溶性导致的蛋白质不足机制发挥其病理作用，但也存在对功能的轻微直接负面影响。

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由剪接因子基因PRPF31中的错义突变引起的视网膜色素变性（RP11）的疾病机制。

Disease mechanism for retinitis pigmentosa (RP11) caused by missense mutations in the splicing factor gene PRPF31.

作者信息

机构信息

出版信息

PURPOSE

METHODS

RESULTS

CONCLUSIONS

目的

方法

结果

结论

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