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NF-E4蛋白短异构体对人类γ-珠蛋白基因表达的抑制与NF-E2缺失以及RNA聚合酶II募集至启动子有关。

Repression of human gamma-globin gene expression by a short isoform of the NF-E4 protein is associated with loss of NF-E2 and RNA polymerase II recruitment to the promoter.

作者信息

Zhao Quan, Zhou Wenlai, Rank Gerhard, Sutton Rosemary, Wang Xi, Cumming Helen, Cerruti Loretta, Cunningham John M, Jane Stephen M

机构信息

Rotary Bone Marrow Research Laboratory, Royal Melbourne Hospital Research Foundation, Parkville, Australia.

出版信息

Blood. 2006 Mar 1;107(5):2138-45. doi: 10.1182/blood-2005-06-2497. Epub 2005 Nov 1.

DOI:10.1182/blood-2005-06-2497
PMID:16263792
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1895715/
Abstract

Binding of the stage selector protein (SSP) to the stage selector element (SSE) in the human gamma-globin promoter contributes to the preferential expression of the gamma-gene in fetal erythroid cells. The SSP contains the transcription factor CP2 and an erythroid-specific partner, NF-E4. The NF-E4 gene encodes a 22-kDa polypeptide employing a non-AUG initiation codon. Antisera specific to NF-E4 detects this species and an additional 14 kDa protein, which initiates from an internal methionine. Enforced expression of p14 NF-E4 in the K562 fetal/erythroid cell line, and in primary erythroid cord blood progenitors, results in repression of gamma-gene expression. Biochemical studies reveal that p14 NF-E4 interacts with CP2, resulting in diminished association of CP2 with the SSE in chromatin immunoprecipitation assays. p45 NF-E2 recruitment to the gamma-promoter is also lost, resulting in a reduction in RNA polymerase II and TBP binding and a fall in promoter transcriptional activity. This effect is specific, as enforced expression of a mutant form of p14 NF-E4, which fails to interact with CP2, also fails to repress gamma-gene expression in K562 cells. These findings provide one potential mechanism that could contribute to the autonomous silencing of the human gamma-genes in adult erythroid cells.

摘要

阶段选择蛋白(SSP)与人γ-珠蛋白启动子中的阶段选择元件(SSE)结合,有助于γ基因在胎儿红细胞中的优先表达。SSP包含转录因子CP2和一个红细胞特异性伴侣NF-E4。NF-E4基因编码一种采用非AUG起始密码子的22 kDa多肽。针对NF-E4的抗血清可检测到该蛋白以及另一种从内部甲硫氨酸起始的14 kDa蛋白。在K562胎儿/红细胞系和原代红细胞脐带血祖细胞中强制表达p14 NF-E4,会导致γ基因表达受到抑制。生化研究表明,p14 NF-E4与CP2相互作用,在染色质免疫沉淀试验中导致CP2与SSE的结合减少。p45 NF-E2募集到γ启动子的过程也会丧失,导致RNA聚合酶II和TBP结合减少,启动子转录活性下降。这种效应具有特异性,因为强制表达不能与CP2相互作用的p14 NF-E4突变体形式,在K562细胞中也不能抑制γ基因表达。这些发现提供了一种可能有助于人类γ基因在成人红细胞中自主沉默的潜在机制。

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