Project description:Eukaryotes have occasionally acquired genetic material through horizontal gene transfer (HGT). However, little is known about the evolutionary and functional significance of such acquisitions. Lysozymes are ubiquitous enzymes that degrade bacterial cell walls. Here, we provide evidence that two subclasses of bivalves (Heterodonta and Palaeoheterodonta) acquired a lysozyme gene via HGT, building on earlier findings. Phylogenetic analyses place the bivalve lysozyme genes within the clade of bacteriophage lysozyme genes, indicating that the bivalves acquired the phage-type lysozyme genes from bacteriophages, either directly or through intermediate hosts. These bivalve lysozyme genes underwent dramatic structural changes after their co-option, including intron gain and fusion with other genes. Moreover, evidence suggests that recurrent gene duplication occurred in the bivalve lysozyme genes. Finally, we show the co-opted lysozymes exhibit a capacity for antibacterial action, potentially augmenting the immune function of related bivalves. This represents an intriguing evolutionary strategy in the eukaryote-microbe arms race, in which the genetic materials of bacteriophages are co-opted by eukaryotes, and then used by eukaryotes to combat bacteria, using a shared weapon against a common enemy.

Project description:The mature virion of the tailed bacteriophage ϕ29 is an ~33 MDa complex that contains more than 450 subunits of seven structural proteins assembling into a prolate head and a short non-contractile tail. Here, we report the near-atomic structures of the ϕ29 pre-genome packaging head (prohead), the mature virion and the genome-emptied virion. Structural comparisons suggest local rotation or oscillation of the head-tail connector upon DNA packaging and release. Termination of the DNA packaging occurs through pressure-dependent correlative positional and conformational changes in the connector. The funnel-shaped tail lower collar attaches the expanded narrow end of the connector and has a 180-Å long, 24-strand β barrel narrow stem tube that undergoes conformational changes upon genome release. The appendages form an interlocked assembly attaching the tail around the collar. The membrane active long loops at the distal end of the tail knob exit during the late stage of infection and form the cone-shaped tip of a largely hydrophobic helix barrel, prepared for membrane penetration.

Project description:Vessel co-option is an alternative mode of tumor vascularization, which contributes to resistance to anti-angiogenic therapy (AAT). In contrast to vessel sprouting (angiogenesis), knowledge about the mechanisms underlying vessel co-option is minimal, precluding therapeutic strategies. We therefore single-cell RNA-sequenced 31,964 cells from a murine lung metastasis model with vessel co-option, characterized by resistance to AAT. Unexpectedly, co-opted endothelial cells (ECs) were transcriptomically indistinguishable from healthy ECs and lacked an activation signature, while co-opted pericytes expressed a quiescence signature, in contrast to activated pericytes during angiogenesis. Compared with cancer cells during angiogenesis, co-opting cancer cells were phenotypically more diverse and enriched in invasive subpopulations. Together, these data reveal new insight into vessel co-option, with possible implications for the development of therapeutic targets.

Project description:A surprising example of interspecies competition is the production by certain bacteria of hydrogen peroxide at concentrations that are lethal for others. A case in point is the displacement of Staphylococcus aureus by Streptococcus pneumoniae in the nasopharynx, which is of considerable clinical significance. How it is accomplished, however, has been a great mystery, because H(2)O(2) is a very well known disinfectant whose lethality is largely due to the production of hyperoxides through the abiological Fenton reaction. In this report, we have solved the mystery by showing that H(2)O(2) at the concentrations typically produced by pneumococci kills lysogenic but not nonlysogenic staphylococci by inducing the SOS response. The SOS response, a stress response to DNA damage, not only invokes DNA repair mechanisms but also induces resident prophages, and the resulting lysis is responsible for H(2)O(2) lethality. Because the vast majority of S. aureus strains are lysogenic, the production of H(2)O(2) is a very widely effective antistaphylococcal strategy. Pneumococci, however, which are also commonly lysogenic and undergo SOS induction in response to DNA-damaging agents such as mitomycin C, are not SOS-induced on exposure to H(2)O(2). This is apparently because they are resistant to the DNA-damaging effects of the Fenton reaction. The production of an SOS-inducing signal to activate prophages in neighboring organisms is thus a rather unique competitive strategy, which we suggest may be in widespread use for bacterial interference. However, this strategy has as a by-product the release of active phage, which can potentially spread mobile genetic elements carrying virulence genes.

Project description:Bacteriophages belonging to the order Caudovirales possess a tail acting as a molecular nanomachine used during infection to recognize the host cell wall, attach to it, pierce it, and ensure the high-efficiency delivery of the genomic DNA to the host cytoplasm. In this review, we provide a comprehensive analysis of the various proteins constituting tailed bacteriophages from a structural viewpoint. To this end, we had in mind to pinpoint the resemblances within and between functional modules such as capsid/tail connectors, the tails themselves, or the tail distal host recognition devices, termed baseplates. This comparison has been extended to bacterial machineries embedded in the cell wall, for which shared molecular homology with phages has been recently revealed. This is the case for the type VI secretion system (T6SS), an inverted phage tail at the bacterial surface, or bacteriocins. Gathering all these data, we propose that a unique ancestral protein fold may have given rise to a large number of bacteriophage modules as well as to some related bacterial machinery components.

Project description:UnlabelledThe field of viral metagenomics has expanded our understanding of viral diversity from all three domains of life (Archaea, Bacteria, and Eukarya). Traditionally, viral metagenomic studies provide information about viral gene content but rarely provide knowledge about virion morphology and/or cellular host identity. Here we describe a new virus, Acidianus tailed spindle virus (ATSV), initially identified by bioinformatic analysis of viral metagenomic data sets from a high-temperature (80°C) acidic (pH 2) hot spring located in Yellowstone National Park, followed by more detailed characterization using only environmental samples without dependency on culturing. Characterization included the identification of the large tailed spindle virion morphology, determination of the complete 70.8-kb circular double-stranded DNA (dsDNA) viral genome content, and identification of its cellular host. Annotation of the ATSV genome revealed a potential three-domain gene product containing an N-terminal leucine-rich repeat domain, followed by a likely posttranslation regulatory region consisting of high serine and threonine content, and a C-terminal ESCRT-III domain, suggesting interplay with the host ESCRT system. The host of ATSV, which is most closely related to Acidianus hospitalis, was determined by a combination of analysis of cellular clustered regularly interspaced short palindromic repeat (CRISPR)/Cas loci and dual viral and cellular fluorescence in situ hybridization (viral FISH) analysis of environmental samples and confirmed by culture-based infection studies. This work provides an expanded pathway for the discovery, isolation, and characterization of new viruses using culture-independent approaches and provides a platform for predicting and confirming virus hosts.ImportanceVirus discovery and characterization have been traditionally accomplished by using culture-based methods. While a valuable approach, it is limited by the availability of culturable hosts. In this research, we report a virus-centered approach to virus discovery and characterization, linking viral metagenomic sequences to a virus particle, its sequenced genome, and its host directly in environmental samples, without using culture-dependent methods. This approach provides a pathway for the discovery, isolation, and characterization of new viruses. While this study used an acidic hot spring environment to characterize a new archaeal virus, Acidianus tailed spindle virus (ATSV), the approach can be generally applied to any environment to expand knowledge of virus diversity in all three domains of life.

Project description:Multidrug-resistant bacterial pathogens are a major medical concern. E. coli, particularly the pathotype extraintestinal pathogenic E. coli (ExPEC), is a leading cause of bloodstream infections. As natural parasites of bacteria, bacteriophages are considered a possible solution to treat patients infected with antibiotic resistant strains of bacteria. However, the development of phage as an anti-infective therapeutic is hampered by limited knowledge of the physiologic factors that influence their properties in complex mammalian environments such as blood. To address this barrier, we tested the ability of phage to kill ExPEC in human blood. Phages are effective at killing ExPEC in conventional media but are substantially restricted in this ability in blood. This phage killing effect is dependent on the levels of free metals and is inhibited by the anticoagulant EDTA. The EDTA-dependent inhibition of ExPEC killing is overcome by exogenous iron, magnesium, and calcium. Metal-enhanced killing of ExPEC by phage was observed for several strains of ExPEC, suggesting a common mechanism. The addition of metals to a murine host infected with ExPEC stimulated a phage-dependent reduction in ExPEC levels. This work defines a role for circulating metals as a major factor that is essential for the phage-based killing of bacteria in blood.

Project description:Explore the genome-scale phage–host interactions across different developmental infection stages

Project description:Explore the genome-scale phage–host interactions across different developmental infection stages

Project description:We have isolated and characterized several bacteriophages infecting Pseudomonas aeruginosa distantly related to Felix O1 virus and proposed they form a new subfamily named Felixounavirinae. The infectious cycle of bacteriophages belonging to this subfamily has not been studied yet in terms of gene expression. The present study reports the RNA-Seq analysis of bacteriophage PAK_P3 infecting PAK strain of P. aeruginosa.