驶过停止标志:预测停止密码子重配可改进噬菌体的功能注释。

IF 5.1 Q1 ECOLOGY ISME communications Pub Date : 2024-06-19 eCollection Date: 2024-01-01 DOI:10.1093/ismeco/ycae079
Ryan Cook, Andrea Telatin, George Bouras, Antonio Pedro Camargo, Martin Larralde, Robert A Edwards, Evelien M Adriaenssens
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引用次数: 0

摘要

噬菌体的多样性大多仍未定性,其生物学机制也在不断被描述。一些噬菌体品系的成员,如 Crassvirales,通过使用替代遗传密码重新利用终止密码子来编码氨基酸。在这里,我们研究了噬菌体基因组中终止密码子重配的普遍性及其对功能注释的影响。我们预测了 INPHARED 中的 76 个基因组和《人类肠道病毒组统一目录》(UHGV)中的 712 个 vOTU,这些基因组重新使用了终止密码子来编码氨基酸。我们使用改进版的 Pharokka 和 Prokka(称为 Pharokka-gv 和 Prokka-gv)对这些序列进行了重新注释,以便在注释前自动预测终止密码子的重新分配。这两种工具都大大提高了注释的质量,其中 Pharokka-gv 的效果最好。对于预测将 TAG 改为谷氨酰胺的序列(翻译表 15),Pharokka-gv 将 UHGV 序列的基因长度中位数(每个基因组中位数的中位数)从 287 bp 增加到 481 bp(增加了 67.8%),将 INPHARED 序列的基因长度中位数从 318 bp 增加到 550 bp(增加了 72.9%)。重新注释后,预测使用翻译表 15 的 UHGV 和 INPHARED 序列的中位编码能力分别从 66.8% 和 69.0% 提高到 90.0% 和 89.8%。此外,可进行功能注释的基因比例也有所增加,包括可鉴定的主要囊膜蛋白数量也有所增加。我们建议,在注释前自动预测终止密码子的重新配置有利于下游的病毒基因组和元基因组分析。
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Driving through stop signs: predicting stop codon reassignment improves functional annotation of bacteriophages.

The majority of bacteriophage diversity remains uncharacterized, and new intriguing mechanisms of their biology are being continually described. Members of some phage lineages, such as the Crassvirales, repurpose stop codons to encode an amino acid by using alternate genetic codes. Here, we investigated the prevalence of stop codon reassignment in phage genomes and its subsequent impacts on functional annotation. We predicted 76 genomes within INPHARED and 712 vOTUs from the Unified Human Gut Virome Catalogue (UHGV) that repurpose a stop codon to encode an amino acid. We re-annotated these sequences with modified versions of Pharokka and Prokka, called Pharokka-gv and Prokka-gv, to automatically predict stop codon reassignment prior to annotation. Both tools significantly improved the quality of annotations, with Pharokka-gv performing best. For sequences predicted to repurpose TAG to glutamine (translation table 15), Pharokka-gv increased the median gene length (median of per genome median) from 287 to 481 bp for UHGV sequences (67.8% increase) and from 318 to 550 bp for INPHARED sequences (72.9% increase). The re-annotation increased median coding capacity from 66.8% to 90.0% and from 69.0% to 89.8% for UHGV and INPHARED sequences predicted to use translation table 15. Furthermore, the proportion of genes that could be assigned functional annotation increased, including an increase in the number of major capsid proteins that could be identified. We propose that automatic prediction of stop codon reassignment before annotation is beneficial to downstream viral genomic and metagenomic analyses.

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