Lu M, Miller C, Habener J F
Laboratory of Molecular endocrinology, Massachusetts General Hospital, Boston, Massachusetts 02114, USA.
Endocrinology. 1996 Jul;137(7):2959-67. doi: 10.1210/endo.137.7.8770920.
The insulin-, glucagon- and somatostatin-producing cells (beta, alpha, and delta, respectively) in the pancreatic islets derive from a common precursor stem cell and differentiate sequentially during embryonic development. The homeodomain protein islet duodenum HOX (IDX)-1 [insulin promoter factor (IPF)-1/somatostatin transactivating factor (STF)-1)] is a transcription factor critically required for both the development of the pancreas and the transcriptional expression of the insulin gene. IDX-1 may also act to determine the differentiation of the common pancreatic precursor to beta, alpha, and delta cells. Although IDX-1 is detected in most adult mouse islet beta-cells and regulates insulin gene transcription, it is also found in 15% of the delta-cells and transactivates the rat somatostatin gene. The roles of different domains of IDX-1 involved in the transactivation of the somatostatin gene are unclear. In this study, we have created a series of amino- and carboxy-terminal deletions, as well as point substitution mutations to delineate functional domains within the IDX-1 protein. We find that deletions amino-proximal to the homeodomain enhance DNA-binding to the TAAT-1 transcriptional control element within the somatostatin gene promoter. However, these amino-terminal deletions result in substantial decreases in transactivation of a transcriptional reporter containing the TAAT-1 element. Paradoxically, coexpression of the transcriptionally inactive, amino-terminally deleted IDX-1 mutant proteins, either with the wild-type IDX-1 or with themselves, results in a marked enhancement of transactivation of the transcriptional TAAT-1 element reporter. We provide evidence that this synergistic enhancement of transactivation is mediated by protein-protein interactions among the regions of IDX-1 located carboxyl-proximal to the homeodomain. Although successive deletions into the carboxy-terminal region do not alter DNA-binding, these deletions result in a biphasic enhancement and diminution of transactivation. The IDX-1 homeodomain mediates sequence- specific DNA-binding because substitution mutations within this region abolish DNA-binding. All of the amino- and carboxy-terminal deletion proteins were present in nuclear extracts of transfected cells, suggesting that nuclear localization signals reside within the IDX-1 homeodomain. The mapping of the functional domains of IDX-1 may facilitate understanding of IDX-1-mediated gene regulation and islet cell development.
胰岛中产生胰岛素、胰高血糖素和生长抑素的细胞(分别为β细胞、α细胞和δ细胞)源自共同的前体干细胞,并在胚胎发育过程中依次分化。同源结构域蛋白胰岛十二指肠HOX(IDX)-1[胰岛素启动子因子(IPF)-1/生长抑素反式激活因子(STF)-1]是胰腺发育和胰岛素基因转录表达所必需的关键转录因子。IDX-1也可能参与决定胰腺共同前体向β细胞、α细胞和δ细胞的分化。尽管在大多数成年小鼠胰岛β细胞中可检测到IDX-1并调节胰岛素基因转录,但在15%的δ细胞中也能发现它,并且它可反式激活大鼠生长抑素基因。IDX-1不同结构域在生长抑素基因反式激活中所起的作用尚不清楚。在本研究中,我们构建了一系列氨基末端和羧基末端缺失以及点替代突变体,以描绘IDX-1蛋白内的功能结构域。我们发现,同源结构域氨基近端的缺失增强了与生长抑素基因启动子内TAAT-1转录控制元件的DNA结合。然而,这些氨基末端缺失导致含有TAAT-1元件的转录报告基因的反式激活大幅降低。矛盾的是,转录无活性的氨基末端缺失的IDX-1突变蛋白与野生型IDX-1或其自身共表达时,会导致转录TAAT-1元件报告基因的反式激活显著增强。我们提供的证据表明,这种反式激活的协同增强是由同源结构域羧基近端的IDX-1区域之间的蛋白质-蛋白质相互作用介导的。尽管向羧基末端区域的连续缺失不会改变DNA结合,但这些缺失会导致反式激活出现双相增强和减弱。IDX-1同源结构域介导序列特异性DNA结合,因为该区域内的替代突变会消除DNA结合。所有氨基末端和羧基末端缺失蛋白均存在于转染细胞的核提取物中,这表明核定位信号位于IDX-1同源结构域内。IDX-1功能结构域的定位可能有助于理解IDX-1介导的基因调控和胰岛细胞发育。
