Decoding post-transcriptional gene expression controls in trypanosomatids using machine learning.

Q1 Medicine

Wellcome Open Research Pub Date : 2025-07-09 eCollection Date: 2025-01-01 DOI:10.12688/wellcomeopenres.23817.2

Michele Tinti, David Horn

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引用次数: 0

Abstract

Background: We recently described a pervasive cis-regulatory role for sequences in Trypanosoma brucei mRNA untranslated regions (UTRs). Specifically, increased translation efficiency (TE) was associated with the dosage and density of A-rich tracts. This finding raised three related questions: (1) What relative contributions do UTRs and codon usage bias make to TE in T. brucei? (2) What relative contributions do these sequences make to mRNA steady-state levels in T. brucei? (3) Do these sequences make substantial contributions to TE and/or mRNA steady-state levels in the related parasitic trypanosomatids, T. cruzi and Leishmania?

Methods: To address these questions, we applied machine learning to analyze existing transcriptome, TE, and proteomics data.

Results: Our predictions indicate that both UTRs and codon usage bias impact gene expression in all three trypanosomatids, but with substantial differences. In T. brucei, TE is primarily correlated with longer A-rich and C-poor UTRs. The situation is similar in T. cruzi, but codon usage bias makes a greater contribution to TE. In Leishmania, median TE is higher and is more strongly correlated with longer (A)U-rich UTRs and with codon usage bias. Codon usage bias has a major impact on mRNA abundance in all three trypanosomatids, while analysis of T. brucei proteomics data yielded results consistent with the view that this is due to differential translation elongation rates.

Conclusions: Taken together, our findings indicate that gene expression control in trypanosomatids operates primarily at the point of translation, which is impacted by both UTRs and codon usage. We suggest a model whereby UTRs control the rate of translation initiation, while favoured codons increase the rate of translation elongation, thereby reducing mRNA turnover.

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利用机器学习解码锥虫转录后基因表达控制。

背景：我们最近描述了布鲁氏锥虫mRNA非翻译区（utr）序列普遍的顺式调控作用。具体来说，翻译效率（TE）的提高与富a束的剂量和密度有关。这一发现提出了三个相关问题：(1)utr和密码子使用偏差对布鲁氏t细胞TE的相对贡献是什么？(2)这些序列对布鲁氏体mRNA稳态水平的相对贡献是什么？(3)这些序列是否对相关的寄生锥虫、克氏锥虫和利什曼原虫的TE和/或mRNA稳态水平有实质性贡献？方法：为了解决这些问题，我们应用机器学习来分析现有的转录组、TE和蛋白质组学数据。结果：我们的预测表明，utr和密码子使用偏差都会影响所有三种锥虫的基因表达，但存在实质性差异。在T. brucei中，TE主要与较长的富含a和缺乏c的utr相关。克氏锥虫的情况类似，但密码子使用偏差对TE的贡献更大。在利什曼原虫中，TE的中位数更高，并且与更长的(A) u -富utr和密码子使用偏差密切相关。密码子使用偏差对所有三种锥虫的mRNA丰度都有重大影响，而对布氏锥虫蛋白质组学数据的分析得出的结果与这是由于不同的翻译延伸率所致的观点一致。结论：综上所述，我们的研究结果表明，锥虫的基因表达控制主要发生在翻译点，这受到utr和密码子使用的影响。我们提出一个模型，其中utr控制翻译起始率，而有利的密码子增加翻译延伸率，从而减少mRNA的周转。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Wellcome Open Research Biochemistry, Genetics and Molecular Biology-Biochemistry, Genetics and Molecular Biology (all)

CiteScore

5.50

自引率

0.00%

发文量

426

审稿时长

1 weeks

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