A novel antivirulence element in the temperate bacteriophage HK022

The loopometer: a quantitative in vivo assay for DNA-looping proteins

Proteins that can bring together separate DNA sites, either on the same or on different DNA molecules, are critical for a variety of DNA-based processes. However, there are no general and technically simple assays to detect proteins capable of DNA looping in vivo nor to quantitate their in vivo looping efficiency. Here, we develop a quantitative in vivo assay for DNA-looping proteins in Escherichia coli that requires only basic DNA cloning techniques and a LacZ assay. The assay is based on loop assistance, where two binding sites for the candidate looping protein are inserted internally to a pair of operators for the E. coli LacI repressor. DNA looping between the sites shortens the effective distance between the lac operators, increasing LacI looping and strengthening its repression of a lacZ reporter gene. Analysis based on a general model for loop assistance enables quantitation of the strength of looping conferred by the protein and its binding sites. We use this ‘loopometer’ assay to measure DNA looping for a variety of bacterial and phage proteins.

Evolution of complex gene regulatory circuits by addition of refinements

How do complex gene regulatory circuits evolve? These circuits involve many interacting components, which work together to specify patterns of gene expression. They typically include many subtle mechanistic features, but in most cases it is unclear whether these features are essential for the circuit to work at all, or if instead they make a functional circuit work better. In the latter case, such a feature is here termed 'dispensable', and it is plausible that the feature has been added at a late stage in the evolution of the circuit. This review describes experimental tests of this question, using the phage λ gene regulatory circuit. Several features of this circuit are found to be dispensable, in the sense that the circuitry works without these features, though not as well as the wild type. In some cases, second-site suppressor mutations are needed to confer near-normal behavior in the absence of such a feature. These findings are discussed here in the context of a two-stage model for evolution of gene regulatory circuits. In this model, a circuit evolves by assembly of a primitive or basic form, followed by adjustment of parameters and addition of qualitatively new features. Pathways are suggested for the addition of such features to a more basic form. Selected examples in other systems are described. Some of the dispensable features of phage λ may be evolutionary refinements. Finding that a feature is dispensable, however, does not prove that it is a late addition - it is possible that it was essential early in evolution, and became dispensable as the circuit evolved. Conversely, a late addition might have become essential. As ongoing work provides additional examples of dispensable features, it may become clearer how often they represent refinements.

Isolation and characterization of bacteriophages infecting Staphylococcus epidermidis

Bacteriophages infecting Staphylococcus epidermidis were isolated by mitomycin C induction. Three distinct phages (vB_SepiS-phiIPLA5, vB_SepiS-phiIPLA6, and vB_SepiS-phiIPLA7)-defined by plaque morphology, structure, virion proteins pattern, DNA restriction bands, and host range-were obtained. One-step growth curves of bacteriophages under optimal growth conditions for S. epidermidis F12 revealed eclipse and latent periods of 5-10 and 10-15 min, respectively, with burst sizes of about 5 to 30 PFU per infected cell. Transmission electron microscopy revealed that the phages were of similar size and belonged to the Siphoviridae family. Phage phi-IPLA7 had the broadest host range infecting 21 out of 65 S. epidermidis isolates. Phage phi-IPLA5 seemed to be a virulent phage probably derived from phi-IPLA6. Phages phi-IPLA5 and phi-IPLA7 exhibited increasing plaques surrounded by a halo that could be indicative of a polysaccharide depolymerase activity. Viable counts, determined during the infection of S. epidermidis F12, confirmed that phi-IPLA5 had a potent lytic capability and reduced S. epidermidis population by 5.67 log units in 8 h of incubation; in the presence of the mixture of phi-IPLA6 and phi-IPLA7, however, a reduction of 2.27 log units was detected.

Conservation and diversity in the immunity regions of wild phages with the immunity specificity of phage lambda

The gene regulatory circuitry of phage lambda is among the best-understood circuits. Much of the circuitry centres around the immunity region, which includes genes for two repressors, CI and Cro, and their cis-acting sites. Related phages, termed lambdoid phages, have different immunity regions, but similar regulatory circuitry and genome organization to that of lambda, and show a mosaic organization, arising by recombination between lambdoid phages. We sequenced the immunity regions of several wild phages with the immunity specificity of lambda, both to determine whether natural variation exists in regulation, and to analyse conservation and variability in a region rich in well-studied regulatory elements. CI, Cro and their cis-acting sites are almost identical to those in lambda, implying that regulatory mechanisms controlled by the immunity region are conserved. A segment adjacent to one of the operator regions is also conserved, and may be a novel regulatory element. In most isolates, different alleles of two regulatory proteins (N and CII) flank the immunity region; possibly the lysis-lysogeny decision is more variable among isolates. Extensive mosaicism was observed for several elements flanking the immunity region. Very short sequence elements or microhomologies were also identified. Our findings suggest mechanisms by which fine-scale mosaicism arises.

The operator-early promoter regions of Shiga-toxin bearing phage H-19B

Genes (stx) encoding Shiga toxins (Stx), major virulence factors in some pathogenic strains of Escherichia coli (STEC), are located in prophages of the lambda family. Agents that induce prophages lead to high levels of Stx, suggesting a role for the prophage in stx expression. Activation of the phage regulatory cascade has been shown to contribute to Stx production and release. Therefore, repressor-operator interactions that maintain prophage repression appear important in regulating expression of a major bacterial virulence factor. To determine if the operators of an stx-bearing phage have distinctive features, we characterized the operator regions of H-19B, a lambdoid phage carrying stx1 genes. H-19B mutants that grow in the presence of repressor (classically called virulent mutants) were selected and the mutations definitively identified the operators. The H-19B operators, as those in other lambdoid phages, comprise variations of an inverted repeat. Four repeats were identified in O(R) rather than the three found in each of the operators of other lambdoid phages. Primer extensions identified the transcription start sites of P(R) and P(RM), the two promoters in O(R) regulated by repressor.

Family values in the age of genomics: comparative analyses of temperate bacteriophage HK022

HK022 is a temperate coliphage related to phage lambda. Its chromosome has been completely sequenced, and several aspects of its life cycle have been intensively studied. In the overall arrangement, expression, and function of most of its genes, HK022 broadly resembles lambda and other members of the lambda family. Upon closer view, significant differences emerge. The differences reveal alternative strategies used by related phages to cope with similar problems and illuminate previously unknown regulatory and structural motifs. HK022 prophages protect lysogens from superinfection by producing a sequence-specific RNA binding protein that prematurely terminates nascent transcripts of infecting phage. It uses a novel RNA-based mechanism to antiterminate its own early transcription. The HK022 protein shell is strengthened by a complex pattern of covalent subunit interlinking to form a unitary structure that resembles chain-mail armour. Its integrase and repressor proteins are similar to those of lambda, but the differences provide insights into the evolution of biological specificity and the elements needed for construction of a stable genetic switch.

Mutations affecting cooperative DNA binding of phage HK022 CI repressor

Cooperative protein-DNA interactions play critical roles in gene regulation in all organisms. Among the best-studied cooperative interactions is that of phage lambda repressor, which binds cooperatively to two adjacent operators. Similar cooperative interactions are also shown by several other lambdoid phage repressors, including HK022 CI repressor, which we study here. This protein has a much higher degree of cooperativity than seen with lambda repressor, and previous evidence has suggested that cooperativity may play roles in HK022 gene regulation that have no parallel in lambda. We have isolated several cooperativity or Coop- mutations in HK022 cI. These mutant proteins were partially defective in vivo for binding to two adjacent operators, but normal or nearly so for binding to a single operator. Two mutations showed mutual suppression, in that the double mutation had wild-type behavior. Analysis of several purified mutant proteins showed that they were also defective for cooperative binding in vitro. Unexpectedly, the mutant proteins showed an altered pattern of in vitro binding to DNA at non-operator sites. Several of them also increased the rate of specific repressor cleavage. We propose a conformational model in which the various functions of the wild-type protein are carried out by differing conformations; these conformations are normally in balance, and the mutations perturb this balance.

The spacing between binding sites controls the mode of cooperative DNA-protein interactions: implications for evolution of regulatory circuitry

The CI repressors of lambdoid phages bind cooperatively to adjacent binding sites. Although these binding sites are found at complex operators containing three binding sites, cooperative binding occurs only between dimers bound at two of the sites, a mode of binding termed pairwise cooperativity. At the level of regulation, pairwise cooperativity allows the proper operation of the genetic switch. At the mechanistic level, it has been proposed to result from steric distortion of the complex, such that a protein dimer bound to a central site cannot contact both flanking dimers because it "leans" towards one of the two sites. We have tested this model using the CI repressor of phage HK022. Previous work suggested that reducing the spacing between adjacent operators might allow cooperative interaction among three dimers, a mode of cooperativity we term extended. Using a set of synthetic templates, we have shown that reducing the spacing allows extended cooperativity among three binding sites. Accordingly, the mode of cooperativity changes qualitatively in response to changes in the inter-site spacing. That is, the change in spacing has major functional consequences for the properties of the complex. We suggest that such changes can play important roles in the evolution of gene regulatory circuitry and of other processes involving nucleoprotein complexes.