tRNA 赖氨酸化对恶性疟原虫细胞质中的最小翻译系统至关重要

Rubayet Elahi, Sean T Prigge
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摘要

数十年来,研究人员一直试图确定最小基因组,以阐明生命的基本原理并推动生物技术的发展。tRNA 是这一机制的重要组成部分,它将 mRNA 密码子解码为氨基酸。疟原虫的细胞质在其细胞器基因组中编码了 25 种 tRNA 异型,这是已知翻译系统中最少的。这种最小系统的高效翻译在很大程度上取决于转录后 tRNA 的修饰,尤其是在摇摆反密码子位置的修饰。tRNACAU 的摆动位置(C34)上的赖氨酸修饰可区分蛋氨酸(AUG)和异亮氨酸(AUA)密码子,改变该 tRNA 提供的氨基酸,确保蛋白质的准确合成。赖氨酸由 tRNA 异亮氨酸赖氨酸合成酶(TilS)形成,在细菌中几乎无处不在,是细胞存活所必需的。我们在恶性疟原虫寄生虫的 apicoplast 中发现了一种 TilS 同源物(PfTilS)。通过将 PfTilS 与细菌的直向同源物互补,我们证明了 PfTilS 的赖氨酰化活性对寄生虫的存活和 apicoplast 的维持至关重要,这可能是由于它对 apicoplast 蛋白质翻译的影响。我们的发现代表了 TilS 在内生细胞器中的首次表征,推动了真核生物细胞器研究和我们对最小翻译机制的理解。由于人类体内不存在赖氨酸修饰,这项研究还揭示了疟原虫的一个潜在弱点,可作为抗疟策略的目标。
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tRNA lysidinylation is essential for the minimal translation system found in the apicoplast of Plasmodium falciparum
For decades, researchers have sought to define minimal genomes to elucidate the fundamental principles of life and advance biotechnology. tRNAs, essential components of this machinery, decode mRNA codons into amino acids. The apicoplast of malaria parasites encodes 25 tRNA isotypes in its organellar genome - the lowest number found in known translation systems. Efficient translation in such minimal systems depends heavily on post-transcriptional tRNA modifications, especially at the wobble anticodon position. Lysidine modification at the wobble position (C34) of tRNACAU distinguishes between methionine (AUG) and isoleucine (AUA) codons, altering the amino acid delivered by this tRNA and ensuring accurate protein synthesis. Lysidine is formed by the enzyme tRNA isoleucine lysidine synthetase (TilS) and is nearly ubiquitous in bacteria and essential for cellular viability. We identified a TilS ortholog (PfTilS) located in the apicoplast of Plasmodium falciparum parasites. By complementing PfTilS with a bacterial ortholog, we demonstrated that the lysidinylation activity of PfTilS is critical for parasite survival and apicoplast maintenance, likely due to its impact on apicoplast protein translation. Our findings represent the first characterization of TilS in an endosymbiotic organelle, advancing eukaryotic organelle research and our understanding of minimal translational machinery. Due to the absence of lysidine modifications in humans, this research also exposes a potential vulnerability in malaria parasites that could be targeted by antimalarial strategies.
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