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超越 GWAS-同种异体移植排斥途径内的遗传分化能否塑造对 COVID-19 的天然免疫?

Beyond GWAS-Could Genetic Differentiation within the Allograft Rejection Pathway Shape Natural Immunity to COVID-19?

机构信息

Biostatistics Group, Department of Genetics, Wrocław University of Environmental and Life Sciences, 51-631 Wroclaw, Poland.

Department of Cattle Breeding, National Research Institute of Animal Production, Krakowska 1, 32-083 Balice, Poland.

出版信息

Int J Mol Sci. 2022 Jun 3;23(11):6272. doi: 10.3390/ijms23116272.

DOI:10.3390/ijms23116272
PMID:35682950
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9181155/
Abstract

COVID-19 infections pose a serious global health concern so it is crucial to identify the biomarkers for the susceptibility to and resistance against this disease that could help in a rapid risk assessment and reliable decisions being made on patients' treatment and their potential hospitalisation. Several studies investigated the factors associated with severe COVID-19 outcomes that can be either environmental, population based, or genetic. It was demonstrated that the genetics of the host plays an important role in the various immune responses and, therefore, there are different clinical presentations of COVID-19 infection. In this study, we aimed to use variant descriptive statistics from GWAS (Genome-Wide Association Study) and variant genomic annotations to identify metabolic pathways that are associated with a severe COVID-19 infection as well as pathways related to resistance to COVID-19. For this purpose, we applied a custom-designed mixed linear model implemented into custom-written software. Our analysis of more than 12.5 million SNPs did not indicate any pathway that was significant for a severe COVID-19 infection. However, the Allograft rejection pathway (hsa05330) was significant ( = 0.01087) for resistance to the infection. The majority of the 27 SNP marking genes constituting the Allograft rejection pathway were located on chromosome 6 (19 SNPs) and the remainder were mapped to chromosomes 2, 3, 10, 12, 20, and X. This pathway comprises several immune system components crucial for the self versus non-self recognition, but also the components of antiviral immunity. Our study demonstrated that not only single variants are important for resistance to COVID-19, but also the cumulative impact of several SNPs within the same pathway matters.

摘要

COVID-19 感染构成了严重的全球健康威胁,因此确定对这种疾病的易感性和抵抗力的生物标志物至关重要,这有助于快速进行风险评估,并对患者的治疗和潜在住院做出可靠的决策。几项研究调查了与严重 COVID-19 结果相关的因素,这些因素可能是环境、基于人群的或遗传的。研究表明,宿主的遗传学在各种免疫反应中起着重要作用,因此 COVID-19 感染有不同的临床表现。在这项研究中,我们旨在使用 GWAS(全基因组关联研究)的变异描述性统计数据和变异基因组注释来识别与严重 COVID-19 感染相关的代谢途径,以及与 COVID-19 抵抗力相关的途径。为此,我们应用了一个定制的混合线性模型,该模型实现于定制编写的软件中。我们对超过 1250 万个 SNP 的分析并未表明任何与严重 COVID-19 感染相关的途径具有统计学意义。然而,同种异体移植排斥途径(hsa05330)对于感染的抵抗力是显著的(=0.01087)。构成同种异体移植排斥途径的 27 个标记基因中的大多数 SNP 位于 6 号染色体上(19 个 SNP),其余的 SNP 映射到 2、3、10、12、20 和 X 号染色体上。该途径包含几个对自我与非自我识别至关重要的免疫系统成分,以及抗病毒免疫的成分。我们的研究表明,不仅单个变体对 COVID-19 的抵抗力很重要,而且同一途径中的几个 SNP 的累积影响也很重要。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/ae63/9181155/21187e5fd788/ijms-23-06272-g004.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/ae63/9181155/fe19118e7899/ijms-23-06272-g001.jpg
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