Lu Q, Wallrath L L, Granok H, Elgin S C
Department of Biology, Washington University, St. Louis, Missouri 63130.
Mol Cell Biol. 1993 May;13(5):2802-14. doi: 10.1128/mcb.13.5.2802-2814.1993.
Previous analysis of the hsp26 gene of Drosophila melanogaster has shown that in addition to the TATA box and the proximal and distal heat shock elements (HSEs) (centered at -59 and -340, relative to the start site of transcription), a segment of (CT)n repeats at -135 to -85 is required for full heat shock inducibility (R.L. Glaser, G.H. Thomas, E.S. Siegfried, S.C.R. Elgin, and J.T. Lis, J. Mol. Biol. 211:751-761, 1990). This (CT)n element appears to contribute to formation of the wild-type chromatin structure of hsp26, an organized nucleosome array that leaves the HSEs in nucleosome-free, DNase I-hypersensitive (DH) sites (Q. Lu, L.L. Wallrath, B.D. Allan, R.L. Glaser, J.T. Lis, and S.C.R. Elgin, J. Mol. Biol. 225:985-998, 1992). Inspection of the sequences upstream of hsp26 has revealed an additional (CT)n element at -347 to -341, adjacent to the distal HSE. We have analyzed the contribution of this distal (CT)n element (-347 to -341), the proximal (CT)n element (-135 to -85), and the two HSEs both to the formation of the chromatin structure and to heat shock inducibility. hsp26 constructs containing site-directed mutations, deletions, substitutions, or rearrangements of these sequence elements have been fused in frame to the Escherichia coli lacZ gene and reintroduced into the D. melanogaster genome by P-element-mediated germ line transformation. Chromatin structure of the transgenes was analyzed (prior to gene activation) by DNase I or restriction enzyme treatment of isolated nuclei, and heat-inducible expression was monitored by measuring beta-galactosidase activity. The results indicate that mutations, deletions, or substitutions of either the distal or the proximal (CT)n element affect the chromatin structure and heat-inducible expression of the transgenes. These (CT)n repeats are associated with a nonhistone protein(s) in vivo and are bound by a purified Drosophila protein, the GAGA factor, in vitro. In contrast, the HSEs are required for heat-inducible expression but play only a minor role in establishing the chromatin structure of the transgenes. Previous analysis indicates that prior to heat shock, these HSEs appear to be free of protein. Our results suggest that GAGA factor, an abundant protein factor required for normal expression of many Drosophila genes, and heat shock factor, a specific transcription factor activated upon heat shock, play distinct roles in gene regulation: the GAGA factor establishes and/or maintains the DH sites prior to heat shock induction, while the activated heat shock factor recognizes and binds HSEs located within the DH sites to trigger transcription.
先前对黑腹果蝇hsp26基因的分析表明,除了TATA框以及近端和远端热休克元件(HSEs)(相对于转录起始位点,分别位于-59和-340处)外,位于-135至-85处的一段(CT)n重复序列对于热休克的充分诱导是必需的(R.L.格拉泽、G.H.托马斯、E.S.西格弗里德、S.C.R.埃尔金和J.T.利斯,《分子生物学杂志》211:751 - 761,1990年)。这个(CT)n元件似乎有助于hsp26野生型染色质结构的形成,即一种有组织的核小体阵列,使HSEs处于无核小体、对DNase I敏感(DH)的位点(Q.陆、L.L.沃尔拉斯、B.D.艾伦、R.L.格拉泽、J.T.利斯和S.C.R.埃尔金,《分子生物学杂志》225:985 - 998,1992年)。对hsp26上游序列的检查揭示了在-347至-341处有一个额外的(CT)n元件,与远端HSE相邻。我们分析了这个远端(CT)n元件(-347至-341)、近端(CT)n元件(-135至-85)以及两个HSEs对染色质结构形成和热休克诱导的贡献。含有这些序列元件的定点突变、缺失、替换或重排的hsp26构建体已与大肠杆菌lacZ基因读框融合,并通过P元件介导的种系转化重新引入黑腹果蝇基因组。通过对分离的细胞核进行DNase I或限制性内切酶处理来分析转基因的染色质结构(在基因激活之前),并通过测量β-半乳糖苷酶活性来监测热诱导表达。结果表明,远端或近端(CT)n元件的突变、缺失或替换会影响转基因的染色质结构和热诱导表达。这些(CT)n重复序列在体内与一种或多种非组蛋白相关联,并且在体外被一种纯化的果蝇蛋白GAGA因子结合。相比之下,HSEs是热诱导表达所必需的,但在建立转基因染色质结构方面仅起次要作用。先前的分析表明,在热休克之前,这些HSEs似乎没有蛋白质结合。我们的结果表明,GAGA因子是许多果蝇基因正常表达所需的一种丰富的蛋白质因子,而热休克因子是热休克时激活的一种特异性转录因子,它们在基因调控中发挥不同的作用:GAGA因子在热休克诱导之前建立和/或维持DH位点,而激活的热休克因子识别并结合位于DH位点内的HSEs以触发转录。
