Underexplored viral auxiliary metabolic genes in soil: Diversity and eco-evolutionary significance.

Abstract

Bacterial viruses are the most abundant biological entities in soil ecosystems. Owing to the advent of metagenomics and viromics approaches, an ever-increasing diversity of virus-encoded auxiliary metabolic genes (AMGs) have been identified in soils, including those involved in the transformation of carbon, phosphorus, and sulfur, degradation of organic pollutants, and antibiotic resistance, among other processes. These viral AMGs can alter soil biogeochemical processes and metabolic activities by interfering with bacterial host metabolism. It is recognized that viral AMGs compensate for host bacterial metabolism outputs by encoding accessory functional genes and are favourable for the hosts' adaptation to stressed soil environments. The eco-evolutionary mechanisms behind this fascinating diversity of viral AMGs in soil microbiomes have begun to emerge, such as horizontal gene transfer, lytic-lysogenic conversion, and single-nucleotide polymorphisms. In this mini-review, we summarize recent advances in the diversity and function of virus-encoded AMGs in the soil environment, especially focusing on the evolutionary significance of AMGs involved in virus-host interactions. This mini-review also sheds light on the existing gaps and future perspectives that could have major significance for viral AMGs research in soils.