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果蝇MSL蛋白形成复合物:MSL2环状结构域在蛋白质复合物组装中的作用

Complex formation by the Drosophila MSL proteins: role of the MSL2 RING finger in protein complex assembly.

作者信息

Copps K, Richman R, Lyman L M, Chang K A, Rampersad-Ammons J, Kuroda M I

机构信息

Program in Cell and Molecular Biology, Baylor College of Medicine, Houston, TX 77030, USA.

出版信息

EMBO J. 1998 Sep 15;17(18):5409-17. doi: 10.1093/emboj/17.18.5409.

DOI:10.1093/emboj/17.18.5409
PMID:9736618
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1170866/
Abstract

Drosophila MSL proteins are thought to act within a complex to elevate transcription from the male X chromosome. We found that the MSL1, MSL2 and MSL3 proteins are associated in immunoprecipitations, chromatographic steps and in the yeast two-hybrid system, but that the MLE protein is not tightly complexed in these assays. We focused our analysis on the MSL2-MSL1 interaction, which is postulated to play a critical role in MSL complex association with the X chromosome. Using a modified two-hybrid assay, we isolated missense mutations in MSL2 that disrupt its interaction with MSL1. Eleven out of 12 mutated residues clustered around the first zinc-binding site of the RING finger domain were conserved in a Drosophila virilis MSL2 homolog. Two pre-existing msl2 alleles, which fail to support male viability in vivo, have lesions in the same region of the RING finger. We tested these in the two-hybrid system and found that they are also defective in interaction with MSL1. Mutation of the second zinc-binding site had little effect on MSL1 binding, suggesting that this portion of the RING finger may have a distinct function. Our data support a model in which MSL2-MSL1 interaction nucleates assembly of an MSL complex, with which MLE is weakly or transiently associated.

摘要

果蝇MSL蛋白被认为在一个复合物中发挥作用,以提高雄性X染色体的转录水平。我们发现,MSL1、MSL2和MSL3蛋白在免疫沉淀、色谱步骤以及酵母双杂交系统中相互关联,但在这些实验中,MLE蛋白并未紧密结合形成复合物。我们将分析重点放在MSL2-MSL1相互作用上,该相互作用被认为在MSL复合物与X染色体的结合中起关键作用。通过改良的双杂交实验,我们分离出了MSL2中的错义突变,这些突变破坏了它与MSL1的相互作用。在12个突变残基中,有11个聚集在RING指结构域的第一个锌结合位点周围,在果蝇的MSL2同源物中是保守的。两个现有的msl2等位基因在体内无法支持雄性存活,它们在RING指的同一区域存在损伤。我们在双杂交系统中对其进行了测试,发现它们与MSL1的相互作用也存在缺陷。第二个锌结合位点的突变对MSL1的结合影响很小,这表明RING指的这一部分可能具有不同的功能。我们的数据支持一个模型,即MSL2-MSL1相互作用促使MSL复合物的组装,而MLE与该复合物存在弱或瞬时的关联。

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