RecA protein mediates homologous recognition via non-Watson-Crick bonds in base triplets

Mechanisms of Bacteroides fragilis resistance to metronidazole

Metronidazole-resistant Bacteroides fragilis (B. fragilis) have been reported worldwide. Several mechanisms contribute to B. fragilis resistance to metronidazole. In some cases, the mechanisms of metronidazole resistance are unknown. Understanding the mechanisms of resistance is important for therapy, the design of new alternative drugs, and control of resistant strains. In this study, a comprehensive review of the B. fragilis resistance mechanisms to metronidazole was prepared. The rate of metronidazole-resistant B. fragilis has been reported as ranging from 0.5% to 7.8% in many surveys. According to CLSI, isolates with MICs ≥32 μg/mL are considered to be metronidazole-resistant. In the majority of cases, metronidazole resistance in B. fragilis is coupled with the existence of nim genes. Metronidazole resistance could be induced in nim-negative strains by exposure to sub-MIC levels of metronidazole. There are multi-drug efflux pumps in B. fragilis which can pump out a variety of substrates such as metronidazole. The recA overexpression and deficiency of feoAB are other reported metronidazole resistance mechanisms in this bacterium.

A model for the effect of homologous recombination on microbial diversification

The effect of homologous recombination (HR) on the evolution of microbial genomes remains contentious as competing hypotheses seek to explain the evolutionary dynamics of microbial species. Evidence for HR between microbial genomes is widespread, and this process has been proposed to act as a cohesive force that can constrain the diversification of microbial lineages. We seek to characterize the evolutionary dynamics of sympatric populations to explore the impact of HR on microbial speciation. We describe a simple equation for quantifying the cohesive effect of HR on microbial populations as a function of their nucleotide divergence, μ/ρ = π_g10 ^{− 20 π_g}. The model was verified using a forward-time microbial population simulator that can explore the evolutionary dynamics of sympatric populations in nonoverlapping niche space. The model was also evaluated using multilocus sequence data from a range of microbial species, providing criteria for dividing them into either cohesively recombining or clonally diverging lineages. We conclude that models of microbial diversification that appear contradictory can be explained in a unified manner as the natural and predictable consequence of variation in a small number of population parameters.

Acinetobacter baumannii RecA protein in repair of DNA damage, antimicrobial resistance, general stress response, and virulence

RecA is the major enzyme involved in homologous recombination and plays a central role in SOS mutagenesis. In Acinetobacter spp., including Acinetobacter baumannii , a multidrug-resistant bacterium responsible for nosocomial infections worldwide, DNA repair responses differ in many ways from those of other bacterial species. In this work, the function of A. baumannii RecA was examined by constructing a recA mutant. Alteration of this single gene had a pleiotropic effect, showing the involvement of RecA in DNA damage repair and consequently in cellular protection against stresses induced by DNA damaging agents, several classes of antibiotics, and oxidative agents. In addition, the absence of RecA decreased survival in response to both heat shock and desiccation. Virulence assays in vitro (with macrophages) and in vivo (using a mouse model) similarly implicated RecA in the pathogenicity of A. baumannii . Thus, the data strongly suggest a protective role for RecA in the bacterium and indicate that inactivation of the protein can contribute to a combined therapeutic approach to controlling A. baumannii infections.

DNA double-strand break repair by homologous recombination

DNA double-strand breaks (DSB) are presumed to be the most deleterious DNA lesions as they disrupt both DNA strands. Homologous recombination (HR), single-strand annealing, and non-homologous end-joining are considered to be the pathways for repairing DSB. In this review, we focus on DSB repair by HR. The proteins involved in this process as well as the interactions among them are summarized and characterized. The main emphasis is on eukaryotic cells, particularly the budding yeast Saccharomyces cerevisiae and mammals. Only the RAD52 epistasis group proteins are included.

Protein-free parallel triple-stranded DNA complex formation

A 14 nt DNA sequence 5'-AGAATGTGGCAAAG-3' from the zinc finger repeat of the human KRAB zinc finger protein gene ZNF91 bearing the intercalator 2-methoxy,6-chloro,9-amino acridine (Acr) attached to the sugar-phosphate backbone in various positions has been shown to form a specific triple helix (triplex) with a 16 bp hairpin (intramolecular) or a two-stranded (intermolecular) duplex having the identical sequence in the same (parallel) orientation. Intramolecular targets with the identical sequence in the antiparallel orientation and a non-specific target sequence were tested as controls. Apparent binding constants for formation of the triplex were determined by quantitating electrophoretic band shifts. Binding of the single-stranded oligonucleotide probe sequence to the target led to an increase in the fluorescence anisotropy of acridine. The parallel orientation of the two identical sequence segments was confirmed by measurement of fluorescence resonance energy transfer between the acridine on the 5'-end of the probe strand as donor and BODIPY-Texas Red on the 3'-amino group of either strand of the target duplex as acceptor. There was full protection from OsO(4)-bipyridine modification of thymines in the probe strand of the triplex, in accordance with the presumed triplex formation, which excluded displacement of the homologous duplex strand by the probe-intercalator conjugate. The implications of these results for the existence of protein-independent parallel triplexes are discussed.

Radioprobing of a RecA-three-stranded DNA complex with iodine 125: evidence for recognition of homology in the major groove of the target duplex

A fundamental problem in homologous recombination is how homology between DNAs is recognized. In all current models, a recombination protein loads onto a single strand of DNA and scans another duplex for homology. When homology is found, a synaptic complex is formed, leading to strand exchange and a heteroduplex. A novel technique based on strand cleavage by the Auger radiodecay of iodine 125, allows us to determine the distances between (125)I on the incoming strand and the target sugars of the duplex DNA strands in an Escherichia coli RecA protein-mediated synaptic complex. Analysis of these distances shows that the complex represents a post-strand exchange intermediate in which the heteroduplex is located in the center, while the outgoing strand forms a relatively wide helix intertwined with the heteroduplex and located in its minor groove. The structure implies that homology is recognized in the major groove of the duplex.

Dissociation kinetics of RecA protein-three-stranded DNA complexes reveals a low fidelity of RecA-assisted recognition of homology

We determined that the incorporation of one mismatch into RecA mediated synaptic complexes between oligonucleotide single-stranded DNAs and target duplex DNAs destabilizes the complex by 0.8 to 1.9 kcal/mol. This finding supports our previous result, that RecA binding per se can significantly decrease the loss in free energy associated with mismatch incorporation even in the absence of ATP hydrolysis. We show that the specificity is mostly driven by the dissociation process. We found that the relative destabilization induced by different mismatches depends on their position. Thus, while there is a good correlation between the ranking order of mismatches at the 5' end of synaptic complexes and mismatches in heteroduplexes (D-loops), there is no correlation between the ranking order for mismatches at the 3' end and mismatches in various DNA structures. This difference between the 5' and 3' ends of synaptic complexes agrees well with the established 5' to 3' polarity of the strand exchange promoted by RecA protein. The lack of a correlation between mismatches at the 3' end of synaptic complexes and mismatches in D-loops suggests the intermediate is probably not a canonical protein-free D-loop.