The Spike Protein of SARS-coV2 19B (S) Clade Mirrors Critical Features of Viral Adaptation and Coevolution

Overview

Journal Microorganisms

Specialty Microbiology

Date 2022 Oct 27

PMID 36296293

Authors

Bidour K Hussein

Omnia M Ibrahium

Marwa F Alamin

Lamees A M Ahmed

Safa A E Abuswar

Mohammed H Abdelraheem

Muntaser E Ibrahim

Affiliations

Soon will be listed here.

Abstract

Pathogens including viruses evolve in tandem with diversity in their animal and human hosts. For , the focus is generally for understanding such coevolution on the virus spike protein, since it demonstrates high mutation rates compared to other genome regions, particularly in the receptor-binding domain (RBD). Viral sequences of the 19B (S) clade and variants of concern from different continents were investigated, with a focus on the A.29 lineage, which presented with different mutational patterns within the 19B (S) lineages in order to learn more about how may have evolved and adapted to widely diverse populations globally. Results indicated that went through evolutionary constrains and intense selective pressure, particularly in Africa. This was manifested in a departure from neutrality with excess nonsynonymous mutations and a negative Tajima D consistent with rapid expansion and directional selection as well as deletion and deletion-frameshifts in the N-terminal domain (NTD region) of the spike protein. In conclusion, we hypothesize that viral transmission during epidemics through populations of diverse genomic structures and marked complexity may be a significant factor for the virus to acquire distinct patterns of mutations within these populations in order to ensure its survival and fitness, explaining the emergence of novel variants and strains.

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