AI Article Synopsis
- Functional and physiological traits are key factors driving niche differentiation among terrestrial prokaryotes, focusing on growth strategies like copiotrophy (rapid growth) and oligotrophy (stress tolerance).
- A study analyzing 175 prokaryotic taxa across 11 Phyla and 35 Families found significant relationships between traits and taxonomic groups, indicating non-random distributions and increased trait similarity within related taxa.
- The research highlights complex clade formations and suggests a more detailed approach is needed to understand how these traits influence resource utilization and niche prediction in terrestrial environments.
Article Abstract
Functional, physiological traits are the underlying drivers of niche differentiation. A common framework related to niches occupied by terrestrial prokaryotes is based on copiotrophy or oligotrophy, where resource investment is primarily in either rapid growth or stress tolerance, respectively. A quantitative trait-based approach sought relationships between taxa, traits and niche in terrestrial prokaryotes. With 175 taxa from 11 Phyla and 35 Families (n = 5 per Family), traits were considered as discrete counts of shared genome-encoded proteins. Trait composition strongly supported non-random functional distributions as preferential clustering of related taxa via unweighted pair-group method with arithmetic mean. Trait similarity between taxa increased as taxonomic rank decreased. A suite of Random Forest models identified traits significantly enriched or depleted in taxonomic groups. These traits conveyed functions related to rapid growth, nutrient acquisition and stress tolerance consistent with their presence in copiotroph-oligotroph niches. Hierarchical clustering of traits identified a clade of competitive, copiotrophic Families resilient to oxidative stress versus glycosyltransferase-enriched oligotrophic Families resistant to antimicrobials and environmental stress. However, the formation of five clades suggested a more nuanced view to describe niche differentiation in terrestrial systems is necessary. We suggest considering traits involved in both resource investment and acquisition when predicting niche.
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| http://dx.doi.org/10.1093/femsec/fiab068 | DOI Listing |
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