Ali Ahmed, Rahimi Ryan, Mahmoud Motamed Elsayed, Shalaby Adel A, Gallardo Rodrigo A, Abdul-Careem Mohamed Faizal
Faculty of Veterinary Medicine, University of Calgary, Calgary, AB T2N 4N1, Canada.
Department of Pathology, Faculty of Veterinary Medicine, Beni-Suef University, Beni Suef 62511, Egypt.
Viruses. 2025 Apr 4;17(4):527. doi: 10.3390/v17040527.
Infectious bronchitis virus (IBV) commonly produces a range of genetic sequences during replication, particularly in the spike 1 (S1)-coding portion of the S gene, leading to distinct subpopulations within the broader viral population. It has been shown that certain microenvironments exert selective pressure on the S1-coding sequences and their encoded proteins, influencing the selection of viral subpopulations in these environments. In this study, high-throughput next-generation sequencing (NGS) was used to analyze the S1-coding sequences from tissues of the respiratory, digestive, renal, and reproductive systems of specific pathogen-free (SPF) laying hens. These tissues were collected nine days after infection with the California 1737/04 (CA1737/04) IBV strain, which is known to cause varying degrees of pathology in these tissues. Using a specific bioinformatics pipeline, 27 single nucleotide variants (SNVs) were detected in the S1-coding sequences derived from different tissues. These SNVs shaped multiple subpopulations (SP1-SP15), with SP1 being the core subpopulation present in all tissues, while others were tissue-specific. The IBV RNA loads in the tissues were negatively correlated with the number of SNVs or the Shannon entropy values, and phylogenetic analysis revealed a genetic divergence in the S1-coding sequences from certain tissues with lower viral RNA loads, particularly those from the trachea and ovary. Furthermore, the SNVs were associated with nonsynonymous mutations, primarily located in hypervariable region 2 (HVR 2) within the N-terminal domain of S1 (S1-NTD), except for those in SP7, which was exclusive to the trachea and contained changes in HVR 3 in the C-terminal domain of S1 (S1-CTD). Overall, this study adds to the existing knowledge about IBV evolution by highlighting the role of tissue-specific environments in shaping viral genetic diversity.
传染性支气管炎病毒(IBV)在复制过程中通常会产生一系列基因序列,尤其是在S基因的刺突1(S1)编码部分,从而在更广泛的病毒群体中形成不同的亚群。研究表明,某些微环境对S1编码序列及其编码蛋白施加选择压力,影响这些环境中病毒亚群的选择。在本研究中,使用高通量下一代测序(NGS)分析特定病原体-free(SPF)蛋鸡的呼吸、消化、肾脏和生殖系统组织中的S1编码序列。这些组织在感染加利福尼亚1737/04(CA1737/04)IBV毒株九天后采集,已知该毒株会在这些组织中引起不同程度的病变。使用特定的生物信息学流程,在来自不同组织的S1编码序列中检测到27个单核苷酸变体(SNV)。这些SNV形成了多个亚群(SP1-SP15),其中SP1是所有组织中都存在的核心亚群,而其他亚群则是组织特异性的。组织中的IBV RNA载量与SNV数量或香农熵值呈负相关,系统发育分析显示,某些病毒RNA载量较低的组织(尤其是气管和卵巢组织)的S1编码序列存在遗传差异。此外,SNV与非同义突变相关,主要位于S1(S1-NTD)N端结构域的高变区2(HVR 2),但SP7中的SNV除外,SP7是气管特有的,其S1(S1-CTD)C端结构域的HVR 3发生了变化。总体而言,本研究通过强调组织特异性环境在塑造病毒遗传多样性中的作用,增加了关于IBV进化的现有知识。