Cloacimonadota metabolisms include adaptations for engineered environments that are reflected in the evolutionary history of the phylum

Phylum Cloacimonadota (previously Cloacimonetes, WWE1) is an understudied bacterial lineage frequently associated with engineered and wastewater systems. Cloacimonadota members were abundant and diverse in metagenomic datasets from a municipal landfill, prompting an examination of phylogenetic relationships, metabolic diversity, and pangenomic dynamics across the phylum, based on 22 publicly available genomes and 24 from landfill samples. Cloacimonadota formed two discrete clades, with one clade's genomes principally deriving from engineered systems. A few more-divergent genomes were placed basal in the tree, and not associated with either clade. Metabolic reconstructions for metagenome-assembled genomes predict an anaerobic, acetogenic, and fermentative lifestyle for the majority of Cloacimonadota surveyed. Genomes from engineered ecosystems (first clade) encode a unique suite of genes not typically found in genomes from natural environments (second clade). These encoded functions include acetate kinase, the enzyme responsible for the formation of acetate from acetyl phosphate, and carbon utilization enzymes, suggesting different substrate degradation and energy generation strategies in these ecologically and phylogenetically distinct lineages.

Genomic analysis of family UBA6911 (Group 18 Acidobacteria) expands the metabolic capacities of the phylum and highlights adaptations to terrestrial habitats

Approaches for recovering and analyzing genomes belonging to novel, hitherto unexplored bacterial lineages have provided invaluable insights into the metabolic capabilities and ecological roles of yet-uncultured taxa. The phylum Acidobacteria is one of the most prevalent and ecologically successful lineages on earth yet, currently, multiple lineages within this phylum remain unexplored. Here, we utilize genomes recovered from Zodletone spring, an anaerobic sulfide and sulfur-rich spring in southwestern Oklahoma, as well as from multiple disparate soil and non-soil habitats, to examine the metabolic capabilities and ecological role of members of the family UBA6911 (group18) Acidobacteria. The analyzed genomes clustered into five distinct genera, with genera Gp18_AA60 and QHZH01 recovered from soils, genus Ga0209509 from anaerobic digestors, and genera Ga0212092 and UBA6911 from freshwater habitats. All genomes analyzed suggested that members of Acidobacteria group 18 are metabolically versatile heterotrophs capable of utilizing a wide range of proteins, amino acids, and sugars as carbon sources, possess respiratory and fermentative capacities, and display few auxotrophies. Soil-dwelling genera were characterized by larger genome sizes, higher number of CRISPR loci, an expanded carbohydrate active enzyme (CAZyme) machinery enabling de-branching of specific sugars from polymers, possession of a C1 (methanol and methylamine) degradation machinery, and a sole dependence on aerobic respiration. In contrast, non-soil genomes encoded a more versatile respiratory capacity for oxygen, nitrite, sulfate, trimethylamine N-oxide (TMAO) respiration, as well as the potential for utilizing the Wood Ljungdahl (WL) pathway as an electron sink during heterotrophic growth. Our results not only expand our knowledge of the metabolism of a yet-uncultured bacterial lineage, but also provide interesting clues on how terrestrialization and niche adaptation drives metabolic specialization within the Acidobacteria.

Oxidation of trimethylamine to trimethylamine N-oxide facilitates high hydrostatic pressure tolerance in a generalist bacterial lineage

High hydrostatic pressure (HHP) is a characteristic environmental factor of the deep ocean. However, it remains unclear how piezotolerant bacteria adapt to HHP. Here, we identify a two-step metabolic pathway to cope with HHP stress in a piezotolerant bacterium. Myroides profundi D25T, obtained from a deep-sea sediment, can take up trimethylamine (TMA) through a previously unidentified TMA transporter, TmaT, and oxidize intracellular TMA into trimethylamine N-oxide (TMAO) by a TMA monooxygenase, MpTmm. The produced TMAO is accumulated in the cell, functioning as a piezolyte, improving both growth and survival at HHP. The function of the TmaT-MpTmm pathway was further confirmed by introducing it into Escherichia coli and Bacillus subtilis. Encoded TmaT-like and MpTmm-like sequences extensively exist in marine metagenomes, and other marine Bacteroidetes bacteria containing genes encoding TmaT-like and MpTmm-like proteins also have improved HHP tolerance in the presence of TMA, implying the universality of this HHP tolerance strategy in marine Bacteroidetes.

Panoramic Insights into the Microevolution and Macroevolution of Prevotella copri-containing Lineage in Primate Guts

Prevotella copri and related taxa are widely detected in mammalian gut microbiomes and have been linked with one human enterotype. However, their microevolution and macroevolution among hosts are poorly characterized. In this study, extensively collected marker genes and genomes were analyzed to trace their evolutionary history, host specificity, and biogeographic distribution. Investigations based on 16S rRNA gene, gyrB, and genomes suggested that a multi-specific P. copri-containing lineage (PCL) harbors diverse species in higher primates. Firstly, P. copri is the dominant species of PCL in the human gut and consists of multiple groups exhibiting high genomic divergence and conspicuous but non-strict biogeographic pattern. Most African strains with high genomic divergence from other strains were phylogenetically placed near the species root, indicating the co-evolutionary history of P. copri and Homo sapiens. Secondly, although long-term co-evolution between PCL and higher primates was revealed, sporadic signals of co-speciation and extensive host jumping of PCL members were observed among higher primates. Metagenomic and phylogenetic analyses indicated that P. copri and other PCL species found in captive mammals have been recently transmitted from humans. Thirdly, strong evidence was found on the extensively horizontal transfer of genes (e.g., carbohydrate-active enzyme encoding genes) among sympatric P. copri groups and PCL species in the same primate host. Our study provides panoramic insights into the complex effects of vertical and horizontal transmission, and potential niche adaption on speciation, host, and biogeographical distribution spanning microevolutionary and macroevolutionary history for a certain gut bacterial lineage.ImportancePrevotella copri and its related taxa, which we designated as Prevotella copri-containing lineage (PCL) in the present study, are widely detected in guts of human, non-human primates and many captive mammals, showing positive or negative correlation to some human diseases. However, a comprehensive understanding on its microevolutionary (within P. copri) and macroevolutionary (among PCL members) history across host species and host biogeography is still lacking. According to our analysis based on 16S rRNA gene, gyrB and genomes, we provided the panoramic insights into the putative effects of vertical transfer, horizontal transmission and potential niche selection on host and biogeographical distribution of this gut bacterial lineage and P. copri. To our knowledge, it is the first time that a gut bacterial lineage was studied at both micro- and macroevolutionary levels, which can aid our systematic understanding on the host-microbe co-evolutionary interactions.

Heme A-containing oxidases evolved in the ancestors of iron oxidizing bacteria

The origin of oxygen respiration in bacteria has long intrigued biochemists, microbiologists and evolutionary biologists. The earliest enzymes that consume oxygen to extract energy did not evolve in the same lineages of photosynthetic bacteria that released oxygen on primordial earth, leading to the great oxygenation event (GOE). A widespread type of such enzymes is proton pumping cytochrome c oxidase (COX) that contains heme A, a unique prosthetic group for these oxidases. Here we show that the most ancestral proteins for the biosynthesis of heme A are present in extant acidophilic Fe2+-oxidizing Proteobacteria. Acidophilic Fe2+-oxidizers lived on emerged land around the time of the GOE, as suggested by the earliest geochemical evidence for aerobic respiration on paleoproterozoic earth. The gene for heme A synthase in acidophilic Fe2+-oxidizing Proteobacteria is associated with the COX gene cluster for iron oxidation. Compared to many other soil bacteria, the COX subunits encoded by this gene cluster are early diverging. Our data suggest that the ancient bacterial lineage which first evolved heme A-containing COX was related to the ancestors of present acidophilic Fe2+-oxidizers such as Acidiferrobacter and Acidithiobacillus spp. The copper leaching activity of such bacteria might have constituted a key ecological factor to promote COX evolution.

Comparative Genomics Guides Elucidation of Vitamin B12 Biosynthesis in Novel Human-Associated Akkermansia Strains

ABSTRACT Akkermansia muciniphila is a mucin-degrading bacterium found in the gut of most humans and is considered a “next-generation probiotic.” However, knowledge of the genomic and physiological diversity of human-associated Akkermansia sp. strains is limited. Here, we reconstructed 35 metagenome-assembled genomes and combined them with 40 publicly available genomes for comparative genomic analysis. We identified at least four species-level phylogroups (AmI to AmIV), with distinct functional potentials. Most notably, we identified genes for cobalamin (vitamin B12) biosynthesis within the AmII and AmIII phylogroups. To verify these predictions, 10 Akkermansia strains were isolated from adults and screened for vitamin B12 biosynthesis genes via PCR. Two AmII strains were positive for the presence of cobalamin biosynthesis genes, while all 9 AmI strains tested were negative. To demonstrate vitamin B12 biosynthesis, we measured the production of acetate, succinate, and propionate in the presence and absence of vitamin supplementation in representative strains of the AmI and AmII phylogroups, since cobalamin is an essential cofactor in propionate metabolism. Results showed that the AmII strain produced acetate and propionate in the absence of supplementation, which is indicative of vitamin B12 biosynthesis. In contrast, acetate and succinate were the main fermentation products for the AmI strains when vitamin B12 was not supplied in the culture medium. Lastly, two bioassays were used to confirm vitamin B12 production by the AmII phylogroup. This novel physiological trait of human-associated Akkermansia strains may affect how these bacteria interact with the human host and other members of the human gut microbiome. IMPORTANCE There is significant interest in the therapeutic and probiotic potential of the common gut bacterium Akkermansia muciniphila. However, knowledge of both the genomic and physiological diversity of this bacterial lineage is limited. Using a combination of genomic, molecular biological, and traditional microbiological approaches, we identified at least four species-level phylogroups with differing functional potentials that affect how these bacteria interact with both their human host and other members of the human gut microbiome. Specifically, we identified and isolated Akkermansia strains that were able to synthesize vitamin B12. The ability to synthesize this important cofactor broadens the physiological capabilities of human-associated Akkermansia strains, fundamentally altering our understanding of how this important bacterial lineage may affect human health.

Genetically Related Mycobacterium bovis Strains Displayed Differential Intracellular Growth in Bovine Macrophages

Molecular typing of bacterial isolates provides a powerful approach for distinguishing Mycobacterium bovis (M. bovis) genotypes. It is known that M. bovis strain virulence plays a role in prevalence and spread of the disease, suggesting that strain virulence and prevailing genotypes are associated. However, it is not well understood whether strain virulence correlates with particular genotypes. In this study, we assessed the in vitro intracellular growth of 18 M. bovis isolates in bovine macrophages as an indicator of bacterial virulence and sought a relationship with the genotype identified by spoligotyping. We found 14 different spoligotypes—11 were already known and three spoligotypes had never been reported before. We identified 2 clusters that were phylogenetically related, containing 10 and 6 strains, respectively, and 2 orphan strains. Intracellular growth and phagocytic rates of 18 M. bovis strains were heterogeneous. Our results suggest that M. bovis intracellular growth and phagocytosis are independent of the bacterial lineage identified by spoligotyping.

The speciation and hybridization history of the genusSalmonella

Bacteria and archaea make up most of natural diversity but the mechanisms that underlie the origin and maintenance of prokaryotic species are poorly understood. We investigated the speciation history of the genusSalmonella, an ecologically diverse bacterial lineage, within whichS. entericasubsp.entericais responsible for important human food-borne infections. We performed a survey of diversity across a large reference collection using multilocus sequence typing, followed by genome sequencing of distinct lineages. We identified eleven distinct phylogroups, three of which were previously undescribed. Strains assigned toS. entericasubsp.salamaeare polyphyletic, with two distinct lineages that we designate Salamae A and Salamae B. Strains of subspecieshoutenaeare subdivided into two groups, Houtenae A and B and are both related to Selander’s group VII. A phylogroup we designate VIII was previously unknown. A simple binary fission model of speciation cannot explain observed patterns of sequence diversity. In the recent past, there have been large scale hybridization events involving an unsampled ancestral lineage and three distantly related lineages of the genus that have given rise to Houtenae A, Houtenae B and VII. We found no evidence for ongoing hybridization in the other eight lineages but detected more subtle signals of ancient recombination events. We are unable to fully resolve the speciation history of the genus, which might have involved additional speciation-by-hybridization or multi-way speciation events. Our results imply that traditional models of speciation by binary fission and divergence may not apply inSalmonella.Data summaryIllumina sequence data were submitted to the European Nucleotide Archive under project number PRJEB2099 and are available from INSDC (NCBI/ENA/DDBJ) under accession numbers ERS011101 to ERS011146. The MLST sequence and profile data generated in this study have been publicly available on theSalmonellaMLST web site between 2010 and the migration of theSalmonellaMLST website to EnteroBase (https://enterobase.warwick.ac.uk/), and subsequently from there.