Animals harbor diverse gut microorganisms that influence host health and fitness. Synthetic microbial communities have been instrumental in enabling reductionist studies of host-microbiome interactions, but some questions require microbial communities with more natural-like complexity while preserving experimental tractability, in vivo monitoring, and quantitative analysis. Here, we describe a method optimized for longitudinal studies of host-microbiome-environment interactions in the nematode Caenorhabditis elegans. In this approach, complex microbial extracts (CMEs) are generated from environmental samples and applied to worm culture plates, providing a diverse yet experimentally convenient microbial environment. We show that CME composition remains stable during cold storage, enabling reproducible longitudinal experiments while minimizing confounding environmental drift over time. As a proof of principle, we apply this method to examine age-dependent changes in the worm gut microbiome, providing support for previous reports of age-dependent increase in the abundance of gut Enterobacteriaceae. CMEs provide a practical and reproducible framework that complements experiments using monocultures or synthetic communities, enabling longitudinal studies of host-microbiome interactions under conditions that better approximate natural microbial complexity.
Bodkhe, R., Choi, R., Shapira, M.
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