Comparative DNA sequence features in two long Escherichia coli contigs

Structures of RecBCD in complex with phage-encoded inhibitor proteins reveal distinctive strategies for evasion of a bacterial immunity hub

Following infection of bacterial cells, bacteriophage modulate double-stranded DNA break repair pathways to protect themselves from host immunity systems and prioritise their own recombinases. Here, we present biochemical and structural analysis of two phage proteins, gp5.9 and Abc2, which target the DNA break resection complex RecBCD. These exemplify two contrasting mechanisms for control of DNA break repair in which the RecBCD complex is either inhibited or co-opted for the benefit of the invading phage. Gp5.9 completely inhibits RecBCD by preventing it from binding to DNA. The RecBCD-gp5.9 structure shows that gp5.9 acts by substrate mimicry, binding predominantly to the RecB arm domain and competing sterically for the DNA binding site. Gp5.9 adopts a parallel coiled-coil architecture that is unprecedented for a natural DNA mimic protein. In contrast, binding of Abc2 does not substantially affect the biochemical activities of isolated RecBCD. The RecBCD-Abc2 structure shows that Abc2 binds to the Chi-recognition domains of the RecC subunit in a position that might enable it to mediate the loading of phage recombinases onto its single-stranded DNA products.

Life After USA300: The Rise and Fall of a Superbug

The community-associated methicillin-resistant Staphylococcus aureus (CA-MRSA) epidemic in the United States is largely attributable to the meteoric rise of a single clone, referred to as USA300. This strain not only spread across the United States in just a few years to become the predominant cause of staphylococcal disease, but it also appears to have increased the overall number of skin and soft-tissue infections (SSTIs), increasing the overall disease burden. While USA300 still constitutes a major public health burden, its prevalence may be decreasing in some parts of the United States. Other than an epidemic in South America due to a closely related strain, USA300 also seems to have been largely unable to establish itself as an endemic infection in other geographic locations. While there have been several hypotheses put forward to explain the enormous success of USA300, the reasons for its failures and its potential fall remain obscure. Far from being unique to USA300, the rise and fall of specific clones of S. aureus in human populations seems to be a common process that has occurred multiple times and in multiple locations. This review charts the rise of USA300 and the evidence that suggests that it may be in decline, and it considers how best to understand the future spread, containment, and possible extinction of CA-MRSA.

Finding sequence motifs in prokaryotic genomes--a brief practical guide for a microbiologist

Finding significant nucleotide sequence motifs in prokaryotic genomes can be divided into three types of tasks: (1) supervised motif finding, where a sample of motif sequences is used to find other similar sequences in genomes; (2) unsupervised motif finding, which typically relates to the task of finding regulatory motifs and protein binding sites and (3) exploratory motif finding, which aims to identify potential functionally significant sequence motifs as those that are unusual in some statistical sense. This article provides a conceptual overview for each type of task, a brief description of basic algorithms used in their solution, and a review of selected relevant software available online.

Analysis of distribution indicates diverse functions of simple sequence repeats in Mycoplasma genomes

Simple sequence repeats (SSRs) composed of extensive tandem iterations of a single nucleotide or a short oligonucleotide are rare in most bacterial genomes, but they are common among Mycoplasma. Some of these repeats act as contingency loci in association with families of surface antigens. By contraction or expansion during replication, these SSRs increase genetic variance of the population and facilitate avoidance of the immune response of the host. Occurrence and distribution of SSRs are analyzed in complete genomes of 11 Mycoplasma and 3 related Mollicutes in order to gain insights into functional and evolutionary diversity of the SSRs in Mycoplasma. The results revealed an unexpected variety of SSRs with respect to their distribution and composition and suggest that it is unlikely that all SSRs function as contingency loci or recombination hot spots. Various types of SSRs are most abundant in Mycoplasma hyopneumoniae, whereas Mycoplasma penetrans, Mycoplasma mobile, and Mycoplasma synoviae do not contain unusually long SSRs. Mycoplasma hyopneumoniae and Mycoplasma pulmonis feature abundant short adenine and thymine runs periodically spaced at 11 and 12 bp, respectively, which likely affect the supercoiling propensities of the DNA molecule. Physiological roles of long adenine and thymine runs in M. hyopneumoniae appear independent of location upstream or downstream of genes, unlike contingency loci that are typically located in protein-coding regions or upstream regulatory regions. Comparisons among 3 M. hyopneumoniae strains suggest that the adenine and thymine runs are rarely involved in genome rearrangements. The results indicate that the SSRs in the Mycoplasma genomes play diverse roles, including modulating gene expression as contingency loci, facilitating genome rearrangements via recombination, affecting protein structure and possibly protein-protein interactions, and contributing to the organization of the DNA molecule in the cell.

Bipolar DNA Translocation Contributes to Highly Processive DNA Unwinding by RecBCD Enzyme

We recently demonstrated that the RecBCD enzyme is a bipolar DNA helicase that employs two single-stranded DNA motors of opposite polarity to drive translocation and unwinding of duplex DNA. We hypothesized that this organization may explain the exceptionally high rate and processivity of DNA unwinding catalyzed by the RecBCD enzyme. Using a stopped-flow dye displacement assay for unwinding activity, we test this idea by analyzing mutant RecBCD enzymes in which either of the two helicase motors is inactivated by mutagenesis. Like the wild-type RecBCD enzyme, the two mutant proteins maintain the ability to bind tightly to blunt duplex DNA ends in the absence of ATP. However, the rate of forward translocation for the RecB motor-defective enzyme is only approximately 30% of the wild-type rate, whereas for the RecD motor-defective enzyme, it is approximately 50%. More significantly, the processivity of translocation is substantially reduced by approximately 25- and 6-fold for each mutant enzyme, respectively. Despite retaining the capacity to bind blunt dsDNA, the RecB-mutant enzyme has lost the ability to unwind DNA unless the substrate contains a short 5'-terminated single-stranded DNA overhang. The consequences of this observation for the architecture of the single-stranded DNA motors in the initiation complex are discussed.

A single nuclease active site of the Escherichia coli RecBCD enzyme catalyzes single-stranded DNA degradation in both directions

The RecBCD enzyme of Escherichia coli is an ATP-dependent DNA exonuclease and a helicase. Its exonuclease activity is subject to regulation by an octameric nucleotide sequence called chi. In this study, site-directed mutations were made in the carboxyl-terminal nuclease domain of the RecB subunit, and their effects on RecBCD's enzymatic activities were investigated. Mutation of two amino acid residues, Asp(1067) and Lys(1082), abolished nuclease activity on both single- and double-stranded DNA. Together with Asp(1080), these residues compose a motif that is similar to one shown to form the active site of several restriction endonucleases. The nuclease reactions catalyzed by the RecBCD enzyme should therefore follow the same mechanism as these restriction endonucleases. Furthermore, the mutant enzymes were unable to produce chi-specific fragments that are thought to result from the 3'-5' and 5'-3' single-stranded exonuclease activities of the enzyme during its reaction with chi-containing double-stranded DNA. The results show that the nuclease active site in the RecB C-terminal 30-kDa domain is the universal nuclease active site of RecBCD that is responsible for DNA degradation in both directions during the reaction with double-stranded DNA. A novel explanation for the observed nuclease polarity switch and RecBCD-DNA interaction is offered.

Identification of the nuclease active site in the multifunctional RecBCD enzyme by creation of a chimeric enzyme

The recombinational hot spot chi modulates the nuclease and helicase activities of the RecBCD enzyme, leading to generation of an early DNA intermediate for homologous recombination. Here we identify the subunit location of the nuclease active site in RecBCD. The isolated RecB protein cleaves circular single-stranded M13 phage DNA, but RecB1-929, comprising only the 100 kDa N-terminal domain of RecB, does not. We reported previously that the reconstituted RecB1-929CD enzyme also is not a nuclease, suggesting that the C-terminal 30 kDa domain of RecB is a non-specific ssDNA endonuclease. However, we were unable to detect nuclease activity with the subtilisin-generated C-terminal 30 kDa fragment of RecB. Since the subtilisin-generated fragment did not bind to a ssDNA-agarose column, we designed a chimeric enzyme by attaching the C-terminal 30 kDa domain of RecB to the gene 32 protein of T4 phage, a ssDNA binding protein that does not have strand scission ability. In addition, Asp427 in the chimeric enzyme (Asp1080 in RecB), a residue that is conserved among several RecB homologs, was substituted to alanine (the D427A mutant). The wild-type chimeric enzyme cleaves the M13 DNA and the D427A mutation abolishes the endonuclease activity of the chimeric enzyme but does not affect its DNA binding ability. This finding indicates an unusual bipartite nature in the structural organization of RecB, in which the DNA-binding function is located in the N-terminal 100 kDa domain and the nuclease catalytic domain is located in the C-terminal 30 kDa domain. The purified RecBD1080ACD mutant is a processive helicase but not a nuclease, demonstrating that RecBCD has a single nuclease active site in the C-terminal 30 kDa domain of RecB.

The complete genome sequence of Escherichia coli K-12

The 4,639,221-base pair sequence of Escherichia coli K-12 is presented. Of 4288 protein-coding genes annotated, 38 percent have no attributed function. Comparison with five other sequenced microbes reveals ubiquitous as well as narrowly distributed gene families; many families of similar genes within E. coli are also evident. The largest family of paralogous proteins contains 80 ABC transporters. The genome as a whole is strikingly organized with respect to the local direction of replication; guanines, oligonucleotides possibly related to replication and recombination, and most genes are so oriented. The genome also contains insertion sequence (IS) elements, phage remnants, and many other patches of unusual composition indicating genome plasticity through horizontal transfer.

Characteristic enrichment of DNA repeats in different genomes

Using computer programs developed for this purpose, we searched for various repeated sequences including inverted, direct tandem, and homopurine-homopyrimidine mirror repeats in various prokaryotes, eukaryotes, and an archaebacterium. Comparison of observed frequencies with expectations revealed that in bacterial genomes and organelles the frequency of different repeats is either random or enriched for inverted and/or direct tandem repeats. By contrast, in all eukaryotic genomes studied, we observed an overrepresentation of all repeats, especially homopurine-homopyrimidine mirror repeats. Analysis of the genomic distribution of all abundant repeats showed that they are virtually excluded from coding sequences. Unexpectedly, the frequencies of abundant repeats normalized for their expectations were almost perfect exponential functions of their size, and for a given repeat this function was indistinguishable between different genomes.

In vitro selection of preferred DNA pairing sequences by the Escherichia coli RecA protein

The RecA protein and other DNA strand exchange proteins are characterized by their ability to bind and pair DNA in a sequence-independent manner. In vitro selection experiments demonstrate, unexpectedly, that RecA protein has a preferential affinity for DNA sequences rich in GT composition. Such GT-rich sequences are present in loci that display increased recombinational activity in both eukaryotes and prokaryotes, including the Escherichia coli recombination hotspot, chi (5'-GCTGGTGG-3'). Interestingly, these selected sequences, or chi-containing substrates, display both an enhanced rate and extent of homologous pairing in RecA protein-dependent homologous pairing reactions. Thus, the binding and pairing of DNA by RecA protein is composition-dependent, suggesting that a component of the elevated recombinational activity of chi and increased genomic rearrangements at certain DNA sequences in eukaryotes is contributed by enhanced DNA pairing activity.

Conserved sequence patterns in phages Mu and lambda DNA

The genetic maps of bacteriophages Mu and lambda can be aligned with respect to the functions of their genes. We were interested to ascertain whether the congruence of gene order is reflected at the nucleotide sequence level. A sliding window analysis of sequences from the early regions of both phages revealed a substantial degree of similarity. Equally high scores, however, were found when the early region of Mu was compared to the late region of lambda and in self-comparisons of either Mu or lambda. Hence, the similarity is due to a common pattern of nucleotides rather than to sequence similarities between functionally related genes. Employing degenerated scoring matrices we could show that primarily adenine and thymine residues contribute to the high scores and that a specific clustering of these residues is the basis for the conserved pattern. Since such a similarity was not observed with control sequences of other phages. Escherichia coli or eukaryotic viruses, the data support the notion that Mu and lambda have diverged from a common phage module. In general, our approach could offer a simple and sensitive way to trace distant relationships.