Towards key principles of host-associated microbiome assembly

Symbiotic relationships between microbes and host organisms frequently involve the assembly of complex microbial communities (microbiomes) within hosts. Patterns at the community level influence life-history traits, the evolutionary trajectories of both microbes and their hosts, and are often critical for maintaining host health. These community-level patterns are dynamically driven by eco-evolutionary mechanisms acting at the individual level, such as microbial dispersal, host selection, and microbe-resource interactions. Critically, we still lack a clear picture of the ways in which these mechanisms interact to shape microbiome assembly. Here, we present a model of assembly to describe how distinct community structures can be characterised by underlying mechanisms. To illustrate the approach, we analyse microbiome data from marine sponges and simulate different structures of host-microbe associations, thereby bridging mechanistic models and empirical patterns. We further apply the model to human microbiome data to explore its relevance across biological systems, proposing that the combined effect of a small set of general mechanisms may govern diverse patterns of microbial diversity and abundance. Our findings advance ecological theory by linking individual-level processes to community-scale patterns, illuminating the key drivers underlying microbiome assembly.