Contiguous and complete assemblies of gut microbiome-associated protists reveal evolutionary diversification to host ecology.

, an obligate host-associated protist, is the most common microbial eukaryote in the human gut, and is widely distributed across vertebrate hosts. The evolutionary transition of from its free-living stramenopile ancestors to a radiation of host-associated organisms is poorly understood. To explore this, we cultured and sequenced eight strains representing the significant phylogenetic diversity of the genus using long-read, short-read, and Hi-C DNA sequencing, alongside gene annotation and RNA sequencing. Comparative genomic analyses reveal significant variation in gene content and genome structure across Notably, three strains from herbivorous tortoises, phylogenetically distant from human subtypes, have markedly larger genomes with longer introns and intergenic regions, and retain canonical stop codons absent in the human-associated strains. Despite these genetic differences, all eight isolates exhibit gene losses linked to the reduced cellular complexity of , including losses of cilia and flagella genes, microtubule motor genes, and signal transduction genes. Isolates from herbivorous tortoises contain higher numbers of plant carbohydrate-metabolizing enzymes, suggesting that, like gut bacteria, these protists ferment plant material in the host gut. We find evidence that some of these carbohydrate-metabolizing enzymes were horizontally acquired from bacteria, indicating that horizontal gene transfer is an ongoing process in that has contributed to host-related adaptation. Together, these results highlight substantial genetic and metabolic diversity within the genus, indicating that different lineages of have varied ecological roles in the host gut.