Helicobacter pylori Infection Modulates Host Cell Metabolism through VacA-Dependent Inhibition of mTORC1.

Helicobacter pylori (Hp) vacuolating cytotoxin (VacA) is a bacterial exotoxin that enters host cells and induces mitochondrial dysfunction. However, the extent to which VacA-dependent mitochondrial perturbations affect overall cellular metabolism is poorly understood. We report that VacA perturbations in mitochondria are linked to alterations in cellular amino acid homeostasis, which results in the inhibition of mammalian target of rapamycin complex 1 (mTORC1) and subsequent autophagy. mTORC1, which regulates cellular metabolism during nutrient stress, is inhibited during Hp infection by a VacA-dependent mechanism. This VacA-dependent inhibition of mTORC1 signaling is linked to the dissociation of mTORC1 from the lysosomal surface and results in activation of cellular autophagy through the Unc 51-like kinase 1 (Ulk1) complex. VacA intoxication results in reduced cellular amino acids, and bolstering amino acid pools prevents VacA-mediated mTORC1 inhibition. Overall, these studies support a model that Hp modulate host cell metabolism through the action of VacA at mitochondria.

Patterns of gene flow define species of thermophilic Archaea.

Despite a growing appreciation of their vast diversity in nature, mechanisms of speciation are poorly understood in Bacteria and Archaea. Here we use high-throughput genome sequencing to identify ongoing speciation in the thermoacidophilic Archaeon Sulfolobus islandicus. Patterns of homologous gene flow among genomes of 12 strains from a single hot spring in Kamchatka, Russia, demonstrate higher levels of gene flow within than between two persistent, coexisting groups, demonstrating that these microorganisms fit the biological species concept. Furthermore, rates of gene flow between two species are decreasing over time in a manner consistent with incipient speciation. Unlike other microorganisms investigated, we do not observe a relationship between genetic divergence and frequency of recombination along a chromosome, or other physical mechanisms that would reduce gene flow between lineages. Each species has its own genetic island encoding unique physiological functions and a unique growth phenotype that may be indicative of ecological specialization. Genetic differentiation between these coexisting groups occurs in large genomic "continents," indicating the topology of genomic divergence during speciation is not uniform and is not associated with a single locus under strong diversifying selection. These data support a model where species do not require physical barriers to gene flow but are maintained by ecological differentiation.

Biogeography of the Sulfolobus islandicus pan-genome.

Variation in gene content has been hypothesized to be the primary mode of adaptive evolution in microorganisms; however, very little is known about the spatial and temporal distribution of variable genes. Through population-scale comparative genomics of 7 Sulfolobus islandicus genomes from 3 locations, we demonstrate the biogeographical structure of the pan-genome of this species, with no evidence of gene flow between geographically isolated populations. The evolutionary independence of each population allowed us to assess genome dynamics over very recent evolutionary time, beginning approximately 910,000 years ago. On this time scale, genome variation largely consists of recent strain-specific integration of mobile elements. Localized sectors of parallel gene loss are identified; however, the balance between the gain and loss of genetic material suggests that S. islandicus genomes acquire material slowly over time, primarily from closely related Sulfolobus species. Examination of the genome dynamics through population genomics in S. islandicus exposes the process of allopatric speciation in thermophilic Archaea and brings us closer to a generalized framework for understanding microbial genome evolution in a spatial context.

Pliocene colonization and adaptive radiations in Australia and New Guinea (Sahul): multilocus systematics of the old endemic rodents (Muroidea: Murinae).

The old endemic rodents of Australia and New Guinea (Sahul) represent one or more large adaptive radiations including novel morphological adaptations to aquatic, arboreal, hopping, and arid ecologies. Four tribes recognized among the Sahulian old endemics (Hydromini, Conilurini, Anisomyini, and Uromyini) reflect distinct biogeographic and ecomorphological hypotheses about diversification within the Old Endemics. We present the first character-based phylogeny of the Sahulian Old Endemic rodents with broad sampling, nested within a broader phylogeny of the Murinae. We estimated phylogenies from >2,500 nucleotides of mtDNA sequence and >9,500 nucleotides from six autosomal nuclear loci, for individual genes and for the full concatenated data using parsimony, likelihood, and Bayesian methods. Our results strongly supported monophyly of the group and its sister relationship to the Philippine old endemics of the Chrotomys division. Most striking was the rapid diversification after the Late Miocene or Early Pliocene colonization of New Guinea from the west, consistent with a single colonization of the Sahulian continent. That was followed 2-3 My later by a second adaptive radiation resulting from one or more colonizations of Australia. Monophyly was not supported for the Anisomyini or the Conilurini but was for the Uromyini nested within the Conilurini and for the Hydromyini. Conflict among gene phylogenies was weak, and support for the consensus topology increased with more (even conflicting) data.