Quantifying Microbial Guilds

Overview

Journal ISME Commun

Publisher Oxford University Press

Date 2024 May 6

PMID 38707845

Authors

Juan Rivas-Santisteban

Pablo Yubero

Semidan Robaina-Estevez

Jose M Gonzalez

Javier Tamames

Carlos Pedros-Alio

Affiliations

Soon will be listed here.

Abstract

The ecological role of microorganisms is of utmost importance due to their multiple interactions with the environment. However, assessing the contribution of individual taxonomic groups has proven difficult despite the availability of high throughput data, hindering our understanding of such complex systems. Here, we propose a quantitative definition of guild that is readily applicable to metagenomic data. Our framework focuses on the functional character of protein sequences, as well as their diversifying nature. First, we discriminate functional sequences from the whole sequence space corresponding to a gene annotation to then quantify their contribution to the guild composition across environments. In addition, we identify and distinguish functional implementations, which are sequence spaces that have different ways of carrying out the function. In contrast, we found that orthology delineation did not consistently align with ecologically (or functionally) distinct implementations of the function. We demonstrate the value of our approach with two case studies: the ammonia oxidation and polyamine uptake guilds from the Malaspina circumnavigation cruise, revealing novel ecological dynamics of the latter in marine ecosystems. Thus, the quantification of guilds helps us to assess the functional role of different taxonomic groups with profound implications on the study of microbial communities.

Citing Articles

Microbial functional guilds respond cohesively to rapidly fluctuating environments.

Crocker K, Skwara A, Kannan R, Murugan A, Kuehn S bioRxiv. 2025; .

PMID: 39974892 PMC: 11838272. DOI: 10.1101/2025.01.30.635766.

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