Heterotrophic Thaumarchaeota with ultrasmall genomes are widespread in the ocean

Abstract

AbstractThe Thaumarchaeota comprise a diverse archaeal phylum including numerous lineages that play key roles in global biogeochemical cycling, particularly in the ocean. To date, all genomically-characterized marine Thaumarchaeota are reported to be chemolithoautotrophic ammonia-oxidizers. In this study, we report a group of heterotrophic marine Thaumarchaeota (HMT) with ultrasmall genome sizes that is globally abundant in deep ocean waters, apparently lacking the ability to oxidize ammonia. We assemble five HMT genomes from metagenomic data derived from both the Atlantic and Pacific Oceans, including two that are >95% complete, and show that they form a deeply-branching lineage sister to the ammonia-oxidizing archaea (AOA). Metagenomic read mapping demonstrates the presence of this group in mesopelagic samples from all major ocean basins, with abundances reaching up to 6% that of AOA. Surprisingly, the predicted sizes of complete HMT genomes are only 837-908 Kbp, and our ancestral state reconstruction indicates this lineage has undergone substantial genome reduction compared to other related archaea. The genomic repertoire of HMT indicates a highly reduced metabolism for aerobic heterotrophy that, although lacking the carbon fixation pathway typical of AOA, includes a divergent form III-a RuBisCO that potentially functions in a nucleotide scavenging pathway. Despite the small genome size of this group, we identify 13 encoded pyrroloquinoline quinone (PQQ)-dependent dehydrogenases that are predicted to shuttle reducing equivalents to the electron transport chain, suggesting these enzymes play an important role in the physiology of this group. Our results suggest that heterotrophic Thaumarchaeota are widespread in the ocean and potentially play key roles in global chemical transformations.ImportanceIt has been known for many years that marine Thaumarchaeota are abundant constituents of dark ocean microbial communities, where their ability to couple ammonia oxidation and carbon fixation plays a critical role in nutrient dynamics. In this study we describe an abundant group of heterotrophic marine Thaumarchaeota (HMT) in the ocean with physiology distinct from their ammonia-oxidizing relatives. HMT lack the ability to oxidize ammonia and fix carbon via the 3-hydroxypropionate/4-hydroxybutyrate pathway, but instead encode a form III-a RuBisCO and diverse PQQ-dependent dehydrogenases that are likely used to generate energy in the dark ocean. Our work expands the scope of known diversity of Thaumarchaeota in the ocean and provides important insight into a widespread marine lineage.