两个 IDD14 转录因子的剪接变体竞争性地形成非功能异二聚体，可能调节淀粉代谢。

Two splice variants of the IDD14 transcription factor competitively form nonfunctional heterodimers which may regulate starch metabolism.

机构信息

Department of Chemistry, Seoul National University, Seoul 151-742, Korea.

出版信息

Nat Commun. 2011;2:303. doi: 10.1038/ncomms1303.

Abstract

Alternative splicing of primary gene transcripts provides eukaryotic cells, with a critical scheme for enriching transcriptome and proteome diversity. Here we report that alternative splicing of the Arabidopsis INDERMINATE DOMAIN 14 (IDD14) transcription factor gene generates a competitive inhibitor in regulating starch metabolism. An alternatively spliced IDD14 form (IDD14β), which is produced predominantly under cold conditions, lacks functional DNA-binding domain but is able to form heterodimers with the functional IDD14 form (IDD14α). IDD14α-IDD14β heterodimers have reduced binding activity to the promoter of Qua-Quine Starch (QQS) gene that regulates starch accumulation. Transgenic Arabidopsis plants overproducing IDD14α (35S:IDD14α) exhibited retarded growth with pale green leaves as appeared on QQS-overexpressing plants. Notably, IDD14β overproduction rescued the 35S:IDD14α phenotypes. We propose that alternative splicing of the IDD14 gene generates a self-controlled regulatory loop that may modulate starch accumulation in response to cold.

摘要

初级基因转录本的选择性剪接为真核细胞提供了一种丰富转录组和蛋白质组多样性的关键方案。在这里，我们报告说，拟南芥不定域 14（IDD14）转录因子基因的选择性剪接产生了一种竞争性抑制剂，调节淀粉代谢。一种替代性剪接的 IDD14 形式（IDD14β），主要在低温条件下产生，缺乏功能性 DNA 结合域，但能够与功能性 IDD14 形式（IDD14α）形成异源二聚体。IDD14α-IDD14β 异源二聚体与调节淀粉积累的 Qua-Quine Starch（QQS）基因启动子的结合活性降低。过表达 IDD14α 的转基因拟南芥植株（35S:IDD14α）表现出生长迟缓，叶片呈浅绿色，类似于 QQS 过表达植株。值得注意的是，IDD14β 的过度表达挽救了 35S:IDD14α 的表型。我们提出，IDD14 基因的选择性剪接产生了一个自我控制的调节环，可能会根据温度的变化调节淀粉的积累。

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两个 IDD14 转录因子的剪接变体竞争性地形成非功能异二聚体，可能调节淀粉代谢。

Two splice variants of the IDD14 transcription factor competitively form nonfunctional heterodimers which may regulate starch metabolism.

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