Hidden evolutionary constraints dictate the retention of coronavirus accessory genes.

Stephen A Goldstein, Teagan M Feeley, Kristina M Babler, Zoë A Hilbert, Diane M Downhour, Niema Moshiri, Nels C Elde
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Abstract

Coronaviruses exhibit many mechanisms of genetic innovation, including the acquisition of accessory genes that originate by capture of cellular genes or through duplication of existing viral genes. Accessory genes influence viral host range and cellular tropism, but little is known about how selection acts on these variable regions of virus genomes. We used experimental evolution of mouse hepatitis virus (MHV) encoding a cellular AKAP7 phosphodiesterase and an inactive native phosphodiesterase, NS2 to model the evolutionary fate of accessory genes. After courses of serial infection, the gene encoding inactive NS2, ORF2, unexpectedly remained intact, suggesting it is under cryptic constraint uncoupled from the function of NS2. In contrast, AKAP7 was retained under strong selection but rapidly lost under relaxed selection. Experimental evolution also led to altered viral replication in a cell type-specific manner and changed the relative proportions of subgenomic viral RNA in plaque-purified viral isolates, revealing additional mechanisms of adaptation. Guided by the retention of ORF2 and similar patterns in related betacoronaviruses, we analyzed ORF8 of SARS-CoV-2, which arose via gene duplication and contains premature stop codons in several globally successful lineages. As with MHV ORF2, the coding-defective SARS-CoV-2 ORF8 gene remains largely intact, mirroring patterns observed during MHV experimental evolution, challenging assumptions on the dynamics of gene loss in virus genomes and extending these findings to viruses currently adapting to humans.

隐藏的进化限制决定了冠状病毒附属基因的保留。
基因创新是病毒在宿主免疫面前适应能力的基础。鉴于基因组组成相对于大多数RNA病毒家族1-5具有灵活性,冠状病毒表现出许多创新机制。实例包括通过捕获细胞基因或通过复制和分化现有病毒基因6,7来获得独特的附属基因。附属基因可能对决定病毒宿主范围和细胞嗜性有影响,但对选择如何作用于病毒基因组的这些可变区域知之甚少。我们使用小鼠肝炎病毒(MHV)与编码互补细胞AKAP7基因9的非活性天然磷酸二酯酶NS2的实验进化来模拟宿主基因的捕获,并发现了决定冠状病毒附属基因命运的隐藏限制模式。连续感染后,AKAP7在强选择下被保留,但在放松选择下迅速丢失。相反,编码无活性NS2的基因ORF2保持完整,这表明它受到了神秘的进化限制。在ORF2的保留和相关β冠状病毒中类似模式的提示的指导下,我们分析了严重急性呼吸系统综合征冠状病毒2型ORF8的进化,该病毒通过基因重复6产生,在几个全球成功的谱系中包含过早终止密码子。与MHV ORF2一样,编码缺陷的SARS-CoV-2 ORF8基因基本上保持完整,反映了MHV实验进化过程中观察到的模式,并将这些发现扩展到目前适应人类的病毒。非活性基因的保留挑战了对病毒基因组中基因丢失动态的假设,并有助于指导新出现和大流行性冠状病毒的进化分析。
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