依赖于帽子的翻译指导了应激诱导的弓形虫原生寄生虫的分化

Vishakha Dey, Michael J Holmes, Matheus S Bastos, Ronald C Wek, William J Sullivan
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引用次数: 0

摘要

转化控制机制调节真核病原体的微生物潜伏期,使它们能够逃避免疫和药物治疗。弓形虫原生寄生虫通过从增殖性速虫分化为潜伏的囊虫,从而在宿主体内存活下来。促进缓虫转化的转录变化是由一种名为 BFD1 的 Myb 结构域转录因子介导的,其 mRNA 存在于速虫中,但在施加压力诱导分化之前不会翻译成蛋白质。我们研究了应激诱导寄生虫分化过程中翻译控制驱动 BFD1 合成的机制。利用生化和分子方法,我们发现 BFD1 mRNA 的 5-leader 在应激时足以优先翻译。通过插入 5-近端茎环和敲除弓形虫帽结合蛋白 eIF4E1,当 5-帽附近的核糖体组装受损时,BFD1 mRNA 的翻译控制得以维持。此外,我们还发现,一种名为 BFD2/ROCY1 的反式作用 RNA 结合蛋白通过与 5-leader 结合,对 BFD1 的无帽子翻译是必要的。BFD2 mRNA 的翻译也被认为是在压力下优先被诱导的,但却是通过依赖于帽子的机制进行的。这些结果表明,除了典型的帽子依赖性翻译外,弓形虫的翻译控制和分化还通过帽子非依赖性机制进行。我们在原生动物中发现的帽子依赖性翻译强调了这种基因调控模式在细胞进化中的古老性及其在应激诱导的生命周期事件中的核心作用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Cap-independent translation directs stress-induced differentiation of the protozoan parasite Toxoplasma gondii
Translational control mechanisms modulate microbial latency of eukaryotic pathogens, enabling them to evade immunity and drug treatments. The protozoan parasite Toxoplasma gondii persists in hosts by differentiating from proliferative tachyzoites to latent bradyzoites, which are housed inside tissue cysts. Transcriptional changes facilitating bradyzoite conversion are mediated by a Myb domain transcription factor called BFD1, whose mRNA is present in tachyzoites but not translated into protein until stress is applied to induce differentiation. We addressed the mechanisms by which translational control drives BFD1 synthesis in response to stress-induced parasite differentiation. Using biochemical and molecular approaches, we show that the 5-leader of BFD1 mRNA is sufficient for preferential translation upon stress. The translational control of BFD1 mRNA is maintained when ribosome assembly near its 5-cap is impaired by insertion of a 5-proximal stem-loop and upon knockdown of the Toxoplasma cap-binding protein, eIF4E1. Moreover, we show that a trans-acting RNA-binding protein called BFD2/ROCY1 is necessary for cap-independent translation of BFD1 through its binding to the 5-leader. Translation of BFD2 mRNA is also suggested to be preferentially induced under stress, but by a cap-dependent mechanism. These results show that translational control and differentiation in Toxoplasma proceed through cap-independent mechanisms in addition to canonical cap-dependent translation. Our identification of cap-independent translation in protozoa underscores the antiquity of this mode of gene regulation in cellular evolution and its central role in stress-induced life-cycle events.
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