Alexander P. Hynes scite author profile

Aerobic methanotrophic bacteria are capable of utilizing methane as their sole energy source. They are commonly found at the oxic/anoxic interfaces of environments such as wetlands, aquatic sediments, and landfills, where they feed on methane produced in anoxic zones of these environments. Until recently, all known species of aerobic methanotrophs belonged to the phylum Proteobacteria, in the classes Gammaproteobacteria and Alphaproteobacteria. However, in 2007-2008 three research groups independently described the isolation of thermoacidophilic methanotrophs that represented a distinct lineage within the bacterial phylum Verrucomicrobia. Isolates were obtained from geothermal areas in Italy, New Zealand and Russia. They are by far the most acidophilic methanotrophs known, with a lower growth limit below pH 1. Here we summarize the properties of these novel methanotrophic Verrucomicrobia, compare them with the proteobacterial methanotrophs, propose a unified taxonomic framework for them and speculate on their potential environmental significance. New genomic and physiological data are combined with existing information to allow detailed comparison of the three strains. We propose the new genus Methylacidiphilum to encompass all three newly discovered bacteria.

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Widespread anti-CRISPR proteins in virulent bacteriophages inhibit a range of Cas9 proteins

Hynes

et al. 2018

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CRISPR-Cas systems are bacterial anti-viral systems, and bacterial viruses (bacteriophages, phages) can carry anti-CRISPR (Acr) proteins to evade that immunity. Acrs can also fine-tune the activity of CRISPR-based genome-editing tools. While Acrs are prevalent in phages capable of lying dormant in a CRISPR-carrying host, their orthologs have been observed only infrequently in virulent phages. Here we identify AcrIIA6, an Acr encoded in 33% of virulent Streptococcus thermophilus phage genomes. The X-ray structure of AcrIIA6 displays some features unique to this Acr family. We compare the activity of AcrIIA6 to those of other Acrs, including AcrIIA5 (also from S. thermophilus phages), and characterize their effectiveness against a range of CRISPR-Cas systems. Finally, we demonstrate that both Acr families from S. thermophilus phages inhibit Cas9-mediated genome editing of human cells.

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An anti-CRISPR from a virulent streptococcal phage inhibits Streptococcus pyogenes Cas9

et al. 2017

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The CRISPR-Cas system owes its utility as a genome-editing tool to its origin as a prokaryotic immune system. The first demonstration of its activity against bacterial viruses (phages) is also the first record of phages evading that immunity . This evasion can be due to point mutations , large-scale deletions , DNA modifications , or phage-encoded proteins that interfere with the CRISPR-Cas system, known as anti-CRISPRs (Acrs) . The latter are of biotechnological interest, as Acrs can serve as off switches for CRISPR-based genome editing . Every Acr characterized to date originated from temperate phages, genomic islands, or prophages , and shared properties with the first Acr discovered. Here, with a phage-oriented approach, we have identified an unrelated Acr in a virulent phage of Streptococcus thermophilus. In challenging a S. thermophilus strain CRISPR-immunized against a set of virulent phages, we found one that evaded the CRISPR-encoded immunity>40,000× more often than the others. Through systematic cloning of its genes, we identified an Acr solely responsible for the abolished immunity. We extended our findings by demonstrating activity in another S. thermophilus strain, against unrelated phages, and in another bacterial genus immunized using the heterologous SpCas9 system favoured for genome editing. This Acr completely abolishes SpCas9-mediated immunity in our assays.

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DNA packaging bias and differential expression of gene transfer agent genes within a population during production and release of the Rhodobacter capsulatus gene transfer agent, RcGTA

Hynes

Mercer

Watton

et al. 2012

Molecular Microbiology

121

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SummaryRhodobacter capsulatus produces a gene transfer agent (GTA) called RcGTA. RcGTA is a phage-like particle that packages R. capsulatus DNA and transfers it to other R. capsulatus cells. We quantified the relative frequency of packaging for each gene in the genome by hybridization of DNA from RcGTA particles to an R. capsulatus microarray. All genes were found within the RcGTA particles. However, the genes encoding the RcGTA particle were under-packaged compared with other regions. Gene transfer bioassays confirmed that the transfer of genes within the RcGTA structural cluster is reduced relative to those of other genes. Single-cell expression analysis, by flow cytometry analysis of cells containing RcGTA-reporter gene fusion constructs, demonstrated that RcGTA gene expression is not uniform within a culture. This phenomenon was accentuated when the constructs were placed in a strain lacking a putative lysis gene involved in RcGTA release; a small subpopulation was found to be responsible for~95% of RcGTA activity. We propose a mechanism whereby high levels of RcGTA gene transcription in the most active RcGTAproducing cells cause a reduction in their packaging frequency. This subpopulation's role in producing and releasing the RcGTA particles explains the lack of observed cell lysis in cultures.

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