Primary structure of the immI immunity region of bacteriophage P22

Bacterial resistance to temperate phage is influenced by the frequency of lysogenic establishment

Temperate phages can shape bacterial community dynamics and evolution through lytic and lysogenic life cycles. In response, bacteria that resist phage infection can emerge. This study explores phage-based factors that influence bacterial resistance using a model system of temperate P22 phage and Salmonella both inside and outside the mammalian host. Phages that remained functional despite gene deletions had minimal impact on lysogeny and phage resistance except for deletions in the immI region that substantially reduced lysogeny and increased phage resistance to levels comparable to that observed with an obligately lytic P22. This immI deletion does not make the lysogen less competitive but instead increases the frequency of bacterial lysis. Thus, subtle changes in the balance between lysis and lysogeny during the initial stages of infection can significantly influence the extent of phage resistance in the bacterial population. Our work highlights the complex nature of the phage-bacteria-mammalian host triad.

Essential gene knockdowns reveal genetic vulnerabilities and antibiotic sensitivities in Acinetobacter baumannii

The emergence of multidrug-resistant Gram-negative bacteria underscores the need to define genetic vulnerabilities that can be therapeutically exploited. The Gram-negative pathogen, Acinetobacter baumannii, is considered an urgent threat due to its propensity to evade antibiotic treatments. Essential cellular processes are the target of existing antibiotics and a likely source of new vulnerabilities. Although A. baumannii essential genes have been identified by transposon sequencing, they have not been prioritized by sensitivity to knockdown or antibiotics. Here, we take a systems biology approach to comprehensively characterize A. baumannii essential genes using CRISPR interference (CRISPRi). We show that certain essential genes and pathways are acutely sensitive to knockdown, providing a set of vulnerable targets for future therapeutic investigation. Screening our CRISPRi library against last-resort antibiotics uncovered genes and pathways that modulate beta-lactam sensitivity, an unexpected link between NADH dehydrogenase activity and growth inhibition by polymyxins, and anticorrelated phenotypes that may explain synergy between polymyxins and rifamycins. Our study demonstrates the power of systematic genetic approaches to identify vulnerabilities in Gram-negative pathogens and uncovers antibiotic-essential gene interactions that better inform combination therapies.IMPORTANCEAcinetobacter baumannii is a hospital-acquired pathogen that is resistant to many common antibiotic treatments. To combat resistant A. baumannii infections, we need to identify promising therapeutic targets and effective antibiotic combinations. In this study, we comprehensively characterize the genes and pathways that are critical for A. baumannii viability. We show that genes involved in aerobic metabolism are central to A. baumannii physiology and may represent appealing drug targets. We also find antibiotic-gene interactions that may impact the efficacy of carbapenems, rifamycins, and polymyxins, providing a new window into how these antibiotics function in mono- and combination therapies. Our studies offer a useful approach for characterizing interactions between drugs and essential genes in pathogens to inform future therapies.

Essential Gene Knockdowns Reveal Genetic Vulnerabilities and Antibiotic Sensitivities in Acinetobacter baumannii

The emergence of multidrug-resistant Gram-negative bacteria underscores the need to define genetic vulnerabilities that can be therapeutically exploited. The Gram-negative pathogen, Acinetobacter baumannii, is considered an urgent threat due to its propensity to evade antibiotic treatments. Essential cellular processes are the target of existing antibiotics and a likely source of new vulnerabilities. Although A. baumannii essential genes have been identified by transposon sequencing (Tn-seq), they have not been prioritized by sensitivity to knockdown or antibiotics. Here, we take a systems biology approach to comprehensively characterize A. baumannii essential genes using CRISPR interference (CRISPRi). We show that certain essential genes and pathways are acutely sensitive to knockdown, providing a set of vulnerable targets for future therapeutic investigation. Screening our CRISPRi library against last-resort antibiotics uncovered genes and pathways that modulate beta-lactam sensitivity, an unexpected link between NADH dehydrogenase activity and growth inhibition by polymyxins, and anticorrelated phenotypes that underpin synergy between polymyxins and rifamycins. Our study demonstrates the power of systematic genetic approaches to identify vulnerabilities in Gram-negative pathogens and uncovers antibiotic-essential gene interactions that better inform combination therapies.

Genome analysis of Salmonella enterica serovar Typhimurium bacteriophage L, indicator for StySA (StyLT2III) restriction-modification system action

Bacteriophage L, a P22-like phage of Salmonella enterica sv Typhimurium LT2, was important for definition of mosaic organization of the lambdoid phage family and for characterization of restriction-modification systems of Salmonella. We report the complete genome sequences of bacteriophage L cI^–40 13^–am43 and L cII^–101; the deduced sequence of wildtype L is 40,633 bp long with a 47.5% GC content. We compare this sequence with those of P22 and ST64T, and predict 72 Coding Sequences, 2 tRNA genes and 14 intergenic rho-independent transcription terminators. The overall genome organization of L agrees with earlier genetic and physical evidence; for example, no secondary immunity region (immI: ant, arc) or known genes for superinfection exclusion (sieA and sieB) are present. Proteomic analysis confirmed identification of virion proteins, along with low levels of assembly intermediates and host cell envelope proteins. The genome of L is 99.9% identical at the nucleotide level to that reported for phage ST64T, despite isolation on different continents ∼35 years apart. DNA modification by the epigenetic regulator Dam is generally incomplete. Dam modification is also selectively missing in one location, corresponding to the P22 phase-variation-sensitive promoter region of the serotype-converting gtrABC operon. The number of sites for SenLTIII (StySA) action may account for stronger restriction of L (13 sites) than of P22 (3 sites).

DNA Packaging and Genomics of the Salmonella 9NA-Like Phages

We present the genome sequences of Salmonella enterica tailed phages Sasha, Sergei, and Solent. These phages, along with Salmonella phages 9NA, FSL_SP-062, and FSL_SP-069 and the more distantly related Proteus phage PmiS-Isfahan, have similarly sized genomes of between 52 and 57 kbp in length that are largely syntenic. Their genomes also show substantial genome mosaicism relative to one another, which is common within tailed phage clusters. Their gene content ranges from 80 to 99 predicted genes, of which 40 are common to all seven and form the core genome, which includes all identifiable virion assembly and DNA replication genes. The total number of gene types (pangenome) in the seven phages is 176, and 59 of these are unique to individual phages. Their core genomes are much more closely related to one another than to the genome of any other known phage, and they comprise a well-defined cluster within the family Siphoviridae To begin to characterize this group of phages in more experimental detail, we identified the genes that encode the major virion proteins and examined the DNA packaging of the prototypic member, phage 9NA. We show that it uses a pac site-directed headful packaging mechanism that results in virion chromosomes that are circularly permuted and about 13% terminally redundant. We also show that its packaging series initiates with double-stranded DNA cleavages that are scattered across a 170-bp region and that its headful measuring device has a precision of ±1.8%.IMPORTANCE The 9NA-like phages are clearly highly related to each other but are not closely related to any other known phage type. This work describes the genomes of three new 9NA-like phages and the results of experimental analysis of the proteome of the 9NA virion and DNA packaging into the 9NA phage head. There is increasing interest in the biology of phages because of their potential for use as antibacterial agents and for their ecological roles in bacterial communities. 9NA-like phages that infect two bacterial genera have been identified to date, and related phages infecting additional Gram-negative bacterial hosts are likely to be found in the future. This work provides a foundation for the study of these phages, which will facilitate their study and potential use.

Mutagenic dissection of the sequence determinants of protein folding, recognition, and machine function

Understanding the relationship between the amino-acid sequence of a protein and its ability to fold and to function is one of the major challenges of protein science. Here, cases are reviewed in which mutagenesis, biochemistry, structure determination, protein engineering, and single-molecule biophysics have illuminated the sequence determinants of folding, binding specificity, and biological function for DNA-binding proteins and ATP-fueled machines that forcibly unfold native proteins as a prelude to degradation. In addition to structure-function relationships, these studies provide information about folding intermediates, mutations that accelerate folding, slow unfolding, and stabilize proteins against denaturation, show how new binding specificities and folds can evolve, and reveal strategies that proteolytic machines use to recognize, unfold, and degrade thousands of distinct substrates.

Genomic analysis of bacteriophage epsilon 34 of Salmonella enterica serovar Anatum (15+)

Background

The presence of prophages has been an important variable in genetic exchange and divergence in most bacteria. This study reports the determination of the genomic sequence of Salmonella phage ε³⁴, a temperate bacteriophage that was important in the early study of prophages that modify their hosts' cell surface and is of a type (P22-like) that is common in Salmonella genomes.

Results

The sequence shows that ε³⁴ is a mosaically related member of the P22 branch of the lambdoid phages. Its sequence is compared with the known P22-like phages and several related but previously unanalyzed prophage sequences in reported bacterial genome sequences.

Conclusion

These comparisons indicate that there has been little if any genetic exchange within the procapsid assembly gene cluster with P22-like E. coli/Shigella phages that are have orthologous but divergent genes in this region. Presumably this observation reflects the fact that virion assembly proteins interact intimately and divergent proteins can no longer interact. On the other hand, non-assembly genes in the "ant moron" appear to be in a state of rapid flux, and regulatory genes outside the assembly gene cluster have clearly enjoyed numerous and recent horizontal exchanges with phages outside the P22-like group. The present analysis also shows that ε³⁴ harbors a gtrABC gene cluster which should encode the enzymatic machinery to chemically modify the host O antigen polysaccharide, thus explaining its ability to alter its host's serotype. A comprehensive comparative analysis of the known phage gtrABC gene clusters shows that they are highly mobile, having been exchanged even between phage types, and that most "bacterial" gtrABC genes lie in prophages that vary from being largely intact to highly degraded. Clearly, temperate phages are very major contributors to the O-antigen serotype of their Salmonella hosts.

Ribbon-helix-helix transcription factors: variations on a theme

The ribbon-helix-helix (RHH) superfamily of transcription factors uses a conserved three-dimensional structural motif to bind to DNA in a sequence-specific manner. This functionally diverse protein superfamily regulates the transcription of genes that are involved in the uptake of metals, amino-acid biosynthesis, cell division, the control of plasmid copy number, the lytic cycle of bacteriophages and, perhaps, many other cellular processes. In this Analysis, the structures of different RHH transcription factors are compared in order to evaluate the sequence motifs that are required for RHH-domain folding and DNA binding, as well as to identify conserved protein-DNA interactions in this superfamily.

Corrected sequence of the bacteriophage p22 genome

We report the first accurate genome sequence for bacteriophage P22, correcting a 0.14% error rate in previously determined sequences. DNA sequencing technology is now good enough that genomes of important model systems like P22 can be sequenced with essentially 100% accuracy with minimal investment of time and resources.

Extensive domain shuffling in transcription regulators of DNA viruses and implications for the origin of fungal APSES transcription factors

BACKGROUND

Viral DNA-binding proteins have served as good models to study the biochemistry of transcription regulation and chromatin dynamics. Computational analysis of viral DNA-binding regulatory proteins and identification of their previously undetected homologs encoded by cellular genomes might lead to a better understanding of their function and evolution in both viral and cellular systems.

RESULTS

The phyletic range and the conserved DNA-binding domains of the viral regulatory proteins of the poxvirus D6R/N1R and baculoviral Bro protein families have not been previously defined. Using computational analysis, we show that the amino-terminal module of the D6R/N1R proteins defines a novel, conserved DNA-binding domain (the KilA-N domain) that is found in a wide range of proteins of large bacterial and eukaryotic DNA viruses. The KilA-N domain is suggested to be homologous to the fungal DNA-binding APSES domain. We provide evidence for the KilA-N and APSES domains sharing a common fold with the nucleic acid-binding modules of the LAGLIDADG nucleases and the amino-terminal domains of the tRNA endonuclease. The amino-terminal module of the Bro proteins is another, distinct DNA-binding domain (the Bro-N domain) that is present in proteins whose domain architectures parallel those of the KilA-N domain-containing proteins. A detailed analysis of the KilA-N and Bro-N domains and the associated domains points to extensive domain shuffling and lineage-specific gene family expansion within DNA virus genomes.

CONCLUSIONS

We define a large class of novel viral DNA-binding proteins and their cellular homologs and identify their domain architectures. On the basis of phyletic pattern analysis we present evidence for a probable viral origin of the fungus-specific cell-cycle regulatory transcription factors containing the APSES DNA-binding domain. We also demonstrate the extensive role of lineage-specific gene expansion and domain shuffling, within a limited set of approximately 24 domains, in the generation of the diversity of virus-specific regulatory proteins.

Non-independence of Mnt repressor-operator interaction determined by a new quantitative multiple fluorescence relative affinity (QuMFRA) assay

Salmonella bacteriophage repressor Mnt belongs to the ribbon-helix-helix class of transcription factors. Previous SELEX results suggested that interactions of Mnt with positions 16 and 17 of the operator DNA are not independent. Using a newly developed high-throughput quantitative multiple fluorescence relative affinity (QuMFRA) assay, we directly quantified the relative equilibrium binding constants (K(ref)) of Mnt to operators carrying all the possible dinucleotide combinations at these two positions. Results show that Mnt prefers binding to C, instead of wild-type A, at position 16 when wild-type C at position 17 is changed to other bases. The measured K(ref) values of double mutants were also higher than the values predicted from single mutants, demonstrating the non-independence of these two positions. The ability to produce a large number of quantitative binding data simultaneously and the potential to scale up makes QuMFRA a valuable tool for the large-scale study of macromolecular interaction.

Complete nucleotide sequence of the prophage VT2-Sakai carrying the verotoxin 2 genes of the enterohemorrhagic Escherichia coli O157:H7 derived from the Sakai outbreak

The enterohemorrhagic Escherichia coli (EHEC) O157:H7 strain RIMD 0509952, derived from an outbreak in Sakai city, Japan, in 1996, produces two kinds of verotoxins, VT1 and VT2, encoded by the stx1 and stx2 genes. In the EHEC strains, as well as in other VT-producing E. coli strains, the toxins are encoded by lysogenic bacteriophages. The EHEC O157:H7 strain RIMD 0509952 did not produce plaque-forming phage particles upon inducing treatments. We have determined the complete nucleotide sequence of a prophage, VT2-Sakai, carrying the stx2A and stx2B genes on the chromosome, and presumed the putative functions of the encoded proteins and the cis-acting DNA elements based on sequence homology data. To our surprise, the sequences in the regions of VT2-Sakai corresponding to the early gene regulators and replication proteins, and the DNA sequences recognized by the regulators share very limited homology to those of the VT2-encoding 933W phage carried by the EHEC O157:H7 strain EDL933 reported by Plunkett et al. (J. Bacteriol., p1767-1778, 181, 1999), although the sequences corresponding to the structural components are almost identical. These data suggest that these two phages were derived from a common ancestral phage and that either or both of them underwent multiple genetic rearrangements. An IS629 insertion was found downstream of the stx2B gene and upstream of the lysis gene S, and this might be responsible for the absence of plaque-forming activity in the lysate obtained after inducing treatments.

Translationally repressive RNA structures monitored in vivo using temperate DNA bacteriophages

The RNA challenge phage system enables genetic selection of proteins with RNA-binding activity in bacteria. These phages are modified versions of the temperate DNA bacteriophage P22 in which post-transcriptional regulatory events control the developmental fate of the phage. The system was originally developed to identify novel RNA ligands that display reduced affinity for the R17/MS2 coat protein, as well as to select for suppressor coat proteins that recognize mutant RNA ligands. During the course of evaluating whether the HIV-1 Rev protein could direct lysogen development for bacteriophage derivatives that encode Rev response element (RRE) RNA sequences, two examples of RRE RNA ligands that interfere with challenge phage development were identified. In the phage examples described, RRE RNA secondary structure prevents Ant protein biosynthesis and lytic development. Phage lysogen formation occurs efficiently in recipient cells, independent of the expression status of the Rev protein or trans-acting competitor RRE RNA ligands. These studies provide the first example whereby RNA challenge phages may be applied to study RNA folding events and RNA structural interactions in an in vivo context.

Functional recognition of fragmented operator sites by R17/MS2 coat protein, a translational repressor

The R17/MS2 coat protein serves as a translational repressor of replicase by binding to a 19 nt RNA hairpin containing the Shine-Dalgarno sequence and the initiation codon of the replicase gene. We have explored the structural features of the RNA operator site that are necessary for efficient translational repression by the R17/MS2 coat protein in vivo . The R17/MS2 coat protein efficiently directs lysogen formation for P22 R17 , a bacteriophage P22 derivative that carries the R17/MS2 RNA operator site within the P22 phage ant mRNA. Phages were constructed that contain fragmented operator sites such that the Shine-Dalgarno sequence and the initiation codon of the affected gene are not located within the RNA hairpin. The wild-type coat protein directs efficient lysogen formation for P22 phages that carry several fragmented RNA operator sites, including one in which the Shine-Dalgarno sequence is positioned 4 nt outside the coat protein binding site. Neither the wild-type R17/MS2 coat protein nor super-repressor mutants induce lysogen formation for a P22 phage encoding an RNA hairpin at a distance of 9 nt from the Shine-Dalgarno sequence, implying that a discrete region of biological repression is defined by the coat protein-RNA hairpin interaction. The assembly of RNA species into capsid structures is not an efficient means whereby the coat protein achieves translational repression of target mRNA transcripts. The R17/MS2 coat protein exerts translational regulation that extends considerably beyond the natural biological RNA operator site structure; however, the coat protein still mediates repression in these constructs by preventing ribosome access to linear sequence determinants of the translational initiation region by the formation of a stable RNA secondary structure. An efficient translational regulatory mechanism in bacteria appears to reside in the ability of proteins to regulate RNA folding states for host cell and phage mRNAs.

Dramatic changes in DNA-binding specificity caused by single residue substitutions in an Arc/Mnt hybrid repressor

Arc and Mnt are homologous repressors which recognize operator sequences that differ at 8-10 important positions. Nevertheless, single residue changes in an Arc/Mnt hybrid protein can switch DNA-binding specificity between the two operators and even allow one particular hybrid to bind strongly to both operators. The ability of single residue changes to radically alter binding specificity involves: 'master' residues that mediate some base contacts directly and some base contacts indirectly through residue-residue hydrogen bonds; identical residues which can make alternative sets of DNA contacts in the two operators; and amplification of the effect of each mutation because the proteins bind operator DNA as tetramers.

The superinfection exclusion gene (sieA) of bacteriophage P22: identification and overexpression of the gene and localization of the gene product

Previous work has shown that the sieA gene of Salmonella bacteriophage P22 is located between the genes mnt and 16. We cloned DNA fragments of the region into multicopy vectors and tested the transformants for mediating superinfection exclusion. Subcloning, phenotypical tests, and DNA sequencing resulted in the identification of the sieA gene. There are two possible initiation codons within one open reading frame of 492 or 480 bp. The deduced amino acid sequence leads to a hypothetical polypeptide with a calculated molecular mass of 18.8 or 18.3 kDa, respectively. According to three hydrophobic regions, all of which are long enough to span the membrane, the product of sieA should be a protein of the inner membrane of a P22-lysogenic cell of Salmonella typhimurium. The SieA protein was moderately overproduced from an expression vector in cultures of Escherichia coli and could be recovered from the membrane fraction.

Hydrogen exchange studies of the Arc repressor: evidence for a monomeric folding intermediate

The hydrogen exchange rates of the backbone amide and labile side-chain protons of the dimeric Arc repressor have been measured. For the slowly exchanging amides in the alpha-helical regions, these rates show a concentration dependence. To account for this dependence, the role of the monomer-dimer equilibrium was considered. Extrapolating the observed exchange rates to zero dimer concentration provides estimates of these rates in the monomer and shows that they are significantly retarded compared to those of an unfolded polypeptide. This suggests that the monomer is in a structured "molten globule" like state. In particular, the two helices of Arc retain a high degree of their secondary structure and it is proposed that the two amphiphilic helices are packed together with their hydrophobic faces. Evidence for a partially folded structure in the Arc monomer was reported earlier in two other studies [J. L. Silva, C. F. Silveira, A. Correia, Jr., and L. Pontes (1992) Journal of Molecular Biology, Vol. 223, pp. 545-555; X. Peng, J. Jonas, and J. L. Silva (1993) Proceedings of the National Academy of Science USA, Vol. 90, pp. 1776-1780]. By combining the results of these studies and ours, a folding pathway of the dimeric Arc repressor involving four different stages is proposed. Due to the low concentration of Arc repressor in the cell, the protein is present either as a free monomer or it is bound to DNA presumably as a tetramer. Therefore the folding pathway can be regarded as an integral part of the overall DNA binding process.

MLH1, PMS1, and MSH2 interactions during the initiation of DNA mismatch repair in yeast

The discovery that mutations in DNA mismatch repair genes can cause hereditary nonpolyposis colorectal cancer has stimulated interest in understanding the mechanism of DNA mismatch repair in eukaryotes. In the yeast Saccharomyces cerevisiae, DNA mismatch repair requires the MSH2, MLH1, and PMS1 proteins. Experiments revealed that the yeast MLH1 and PMS1 proteins physically associate, possibly forming a heterodimer, and that MLH1 and PMS1 act in concert to bind a MSH2-heteroduplex complex containing a G-T mismatch. Thus, MSH2, MLH1, and PMS1 are likely to form a ternary complex during the initiation of eukaryotic DNA mismatch repair.

Cold denaturation of a repressor-operator complex: the role of entropy in protein-DNA recognition

The mechanisms by which regulatory proteins recognize specific DNA sequences are not fully understood. Here we examine the basis for the stability of a protein-DNA complex, using hydrostatic pressure and low temperature. Pressure converts the DNA-binding Arc repressor protein from a native state to a denatured, molten-globule state. Our data show that the folding and dimerization of Arc repressor in the temperature range 0-20 degrees C are favored by a large positive entropy value, so that the reaction proceeds in spite of an unfavorable positive enthalpy. On binding operator DNA, Arc repressor becomes extremely stable against denaturation. However, the Arc repressor-operator DNA complex is cold-denatured at subzero temperatures under pressure, demonstrating that the favorable entropy increases greatly when Arc repressor binds tightly to its operator sequence but not a nonspecific sequence. We show how an increase in entropy may operate to provide the protein with a mechanism to distinguish between a specific and a nonspecific DNA sequence. It is postulated that the formation of the Arc-operator DNA complex is followed by an increase in apolar interactions and release of solvent which would explain its entropy-driven character, whereas this solvent would not be displaced in nonspecific complexes.

Direct genetic selection for a specific RNA-protein interaction

The decision between lytic and lysogenic development of temperate DNA bacteriophages is determined largely by transcriptional regulation through DNA-binding proteins. To determine whether a heterologous RNA-binding activity could control the developmental fate of a DNA bacteriophage, a derivative of P22 was constructed in which the chosen developmental pathway is regulated by an RNA-binding molecule interacting with its RNA target site located in a phage mRNA. In the example presented, lysogenic development of the phage relies upon R17 coat protein expression in the susceptible host cell and the availability of a suitable coat protein binding site encoded by the phage genome. Through the analysis of phage mutants that are able to grow lytically in susceptible cells that express the coat protein, additional insights were obtained regarding the specific interaction of the R17 coat protein with its RNA binding site. This study also suggests a novel and extremely sensitive strategy for selecting RNA-binding activities in vivo.

P22 Arc repressor: enhanced expression of unstable mutants by addition of polar C-terminal sequences

Many mutant variants of the P22 Arc repressor are subject to intracellular proteolysis in Escherichia coli, which precludes their expression at levels sufficient for purification and subsequent biochemical characterization. Here we examine the effects of several different C-terminal extension sequences on the expression and activity of a set of Arc mutants. We show that two tail sequences, KNQHE (st5) and H6KNQHE (st11), increase the expression levels of most mutants from 10- to 20-fold and, in some cases, result in restoration of biological activity in the cell. A third tail sequence, HHHHHH (st6), was not as effective in increasing mutant expression levels. All three tail sequences are functionally and structurally silent, as judged by their lack of effects on the DNA binding activity and stability of otherwise wild-type Arc. The properties of the st11 tail sequence make it an efficient system for the expression and purification of mutant Arc proteins, both because mutant expression levels are increased and because the proteins can be rapidly purified using nickel-chelate affinity chromatography. Arc mutants containing the EA28, RL31, and SA32 mutations were purified in the st11 background. The thermodynamic stability of the EA28 mutant (delta delta Gu approximately -0.4 kcal/mol) is reduced modestly compared to the st11 parent, whereas the RL31 mutant (delta delta Gu approximately -3.0 kcal/mol) and SA32 mutant (delta delta Gu approximately -3.3 kcal/mol) are substantially less stable.

The antirepressor of phage P1. Isolation and interaction with the C1 repressor of P1 and P7

Two antirepressor proteins, Ant1 and Ant2, of molecular weight 42 and 32 kDa, respectively, are encoded by P1 as a single open reading frame, with the smaller protein initiating at an in-frame start codon. Another open reading frame, icd, 5' upstream of and overlapping ant1 is required for ant1 expression. Using appropriate ant gene-carrying plasmids we have overproduced and purified Ant1/2 in the form of a protein complex and Ant2 as a single protein. Sequence analysis confirmed the N-terminal amino acids predicted from the DNA sequence of ant1/ant2, except that the N-terminal methionine is missing in the Ant2 protein. Under appropriate conditions the C1 repressors of phages P1 and P7 specifically co-precipitate with the Ant1/2 complex but not with Ant2 protein alone. The results suggest that the antirepressor may exert its C1-inactivating function by a direct protein-protein interaction.

Energy coupling between DNA binding and subunit association is responsible for the specificity of DNA-Arc interaction

The effects of several DNA molecules on the free energy of subunit association of Arc repressor were measured. The association studies under equilibrium conditions were performed by the dissociating perturbation of hydrostatic pressure. The magnitude of stabilization of the subunit interaction was determined by the specificity of the protein-DNA interaction. Operator DNA stabilized the free energy of association by about 2.2 kcal/mol of monomeric unit, whereas poly(dG-dC) stabilized the subunit interaction by only 0.26 kcal. Measurements of the stabilizing free energy at different DNA concentrations revealed a stoichiometry of two dimers per 21 bp for the operator DNA sequence and for the nonspecific DNA poly(dA-dT). However, the maximum stabilization was much larger for operator sequence (delta p = 1,750 bar) as compared for poly(dA-dT) (delta p = 750 bar). The importance of the free-energy linkage for the recognition process was corroborated by its absence in a mutant Arc protein (PL8) that binds to operator and nonspecific DNA sequences with equal, low affinity. We conclude that the coupling accounts for the high specificity of the Arc-operator DNA interaction. We hypothesize a mutual coupling between the protein subunits and the two DNA strands, in which the much higher persistency of the associated form when Arc is bound to operator would stabilize the interactions between the two DNA strands.

Conjugative transfer of Enterococcus faecalis plasmid pAD1: nucleotide sequence and transcriptional fusion analysis of a region involved in positive regulation

The Enterococcus faecalis plasmid pAD1 undergoes conjugative transfer in response to cAD1, a peptide sex pheromone emitted by potential bacterial recipients. Regulation of pAD1 transfer involves a number of plasmid-encoded determinants:iad, which determines a peptide-competitive inhibitor iAD1; signal sensing and transducing elements; and negative and positive regulators. The key positive regulator(s) of the pheromone response is believed to be encoded within a segment designated the E region of the plasmid. In this study, we analyzed the nucleotide sequence and transcription within the E region. An open reading frame designated traE1 was identified; its inferred protein consists of 118 amino acids. Insertional mutagenesis of traE1 resulted in a complete loss in plasmid transfer capability. Analysis of Tn917-lac insertions giving rise to transcriptional lacZ fusions showed that traE1 is transcribed only under cAD1 inducing conditions. Analysis of additional lacZ fusions within the region provided some insight into the roles of potential regulatory signals within and around the nucleotide sequences reported here. A regulatory role appearing to involve read-through of certain key transcription termination sequences seemed evident.

Dissociation of a native dimer to a molten globule monomer. Effects of pressure and dilution on the association equilibrium of arc repressor

The monomer-dimer association reaction of Arc repressor was studied by pressure-induced dissociation and by dilution. The dissociation was measured by the decrease (red shift) in the average energy of emission of the tryptophan fluorescence. Pressure dissociation also promoted a decrease in the excited-state lifetime of the single tryptophanyl residue, Trp14. These observations suggest that Trp14 becomes exposed to an aqueous environment following dissociation. The pressure-dissociation curves were concentration dependent, with p1/2 (half-dissociation pressure) shifting to higher pressures as the concentration increased. The dissociation constant (KdO) obtained by extrapolating the pressure-dissociation curves to atmospheric pressure was similar to that determined from the dilution curve (KdO = 30 nM). An anomalous steepness of dissociation in response to dilution was observed, suggesting that conformational changes occur as a result of dissociation of Arc repressor. Binding of bis(8-anilinonaphthalene-1-sulfonate) to Arc repressor was not significantly affected by pressure dissociation, whereas thermal or urea denaturation was accompanied by a dramatic decrease in binding. These results suggest that the conformational changes that follow dissociation induced by pressure are more limited than those following denaturation. The tryptophan anisotropy decreased by about one-half, suggesting the dissociation of a globular dimer to a compact monomer. On the other hand, denaturation by urea promoted an increase in anisotropy, as expected for a random-coil conformation. Dissociated Arc has the hydrodynamic properties of a folded monomer. On the other hand, dissociated Arc has a high degree of exposure of hydrophobic side-chains, and the distribution of conformations is much broader than that in the folded dimer. These features suggest that the dissociated subunit is a molten globule. The subunit interaction was substantially increased by a single amino acid substitution (Pro8----Leu), and the free energy of stabilization amounted to -2.9 kcal/mol. This increased stability suggests that residue 8 is located in the dimer interface and that part of the tertiary and most of the quaternary structure constraints result from the interaction between the intersubunit beta-strands.

RNA polymerase bound to the PR promoter of bacteriophage lambda inhibits open complex formation at the divergently transcribed PRM promoter. Implications for an indirect mechanism of transcriptional activation by lambda repressor

We demonstrate that RNA polymerase bound at the PR promoter of bacteriophage lambda can repress transcription initiation from the divergently transcribed PRM promoter in vitro. Using abortive initiation and run-off transcription experiments we show that inactivating mutations introduced into either the -10 or -35 regions of PR result in a significant increase in the rate of formation of transcriptionally competent complexes at the PRM promoter. This is due primarily to an increase in the rate constant for the isomerization of closed to open complexes. Gel shift and DNase I footprinting experiments were employed to further define the mechanism by which PR sequences mediate PRM repression. From these assays we were able to conclude that the formation of an open complex at the PR promoter did not exclude RNA polymerase from binding at PRM. Rather, initiation at PRM was impaired because closed complexes must isomerize in the presence of an open complex already situated at the PR promoter. Extensive evidence has been obtained previously indicating that lambda repressor activates transcription directly by contacting RNA polymerase situated at the PRM promoter. Results presented here raise the possibility that an additional mechanism could be operative, whereby lambda repressor indirectly activates PRM transcription by excluding RNA polymerase from the PR promoter.

Hierarchies of base pair preferences in the P22 ant promoter

Oligonucleotide-directed mutagenesis was used to complete a collection of mutations in the -35 and -10 hexamers of the ant promoter of Salmonella phage P22. The effects of all 36 single-base-pair substitutions on promoter strength in vivo were measured in strains carrying the mutant promoters fused to an ant-lacZ gene on a single-copy prophage. The results of these assays show that certain consensus base pairs are more important than others; in general, the least-critical positions are among the most poorly conserved. Some mutations within the hexamers have smaller effects on promoter strength than certain mutations outside the hexamers in this and other promoters. Several different patterns of base pair preferences are observed. These hierarchies of base pair preferences correlate well (but not perfectly) with the hierarchies defined by the frequency distribution of base pairs at each position among wild-type promoters. The hierarchies observed in the ant promoter also agree well with most of the available information on base pair preferences in other promoters.

Structure of Arc repressor in solution: evidence for a family of beta-sheet DNA-binding proteins

The Arc repressor, which is involved in the switch between lysis and lysogeny of Salmonella bacteriophage P22, does not belong to any of the known classes of DNA-binding proteins. Mutagenesis studies show that the DNA-binding region is located in the 15 N-terminal amino-acid residues. We have now determined the three-dimensional structure of the Arc dimer from an extensive set of interproton-distance data obtained from 1H NMR spectroscopy. A priori, intra- and inter-monomer nuclear Overhauser effects (NOEs) cannot be distinguished for a symmetric dimer. But by using the homology with the Escherichia coli Met repressor we could interpret the NOEs unambiguously in an iterative structure refinement procedure. The final structure satisfies a large set of NOE constraints (1,352 for the dimer). It shows a strongly intertwined dimer, in which residues 8-14 of different monomers form an antiparallel beta-sheet. A model for the Arc repressor-operator complex can account for all available biochemical and genetic data. In this model two Arc dimers bind with their beta-sheet regions in successive major grooves on one side of the DNA helix, similar to the Met repressor interaction. Thus, Arc and Met repressors are members of the same family of proteins, which contain an antiparallel beta-sheet as the DNA-binding motif.

A mutant Escherichia coli sigma 70 subunit of RNA polymerase with altered promoter specificity

A mutation is described that alters the promoter specificity of sigma 70, the primary sigma factor of Escherichia coli RNA polymerase. In strains carrying both the mutant and wild-type sigma gene (rpoD), the mutant sigma causes a large increase in the activity of mutant P22 ant promoters with A.T or C.G instead of the wild-type, consensus G.C base-pair at position -33, the third position of the consensus -35 hexamer 5'-TTGACA-3'. There is little or no effect on the activities of the wild-type and 23 other mutant ant promoters, including one with T.A at -33. The mutant sigma also activates E. coli lac promoters with A.T or C.G, but not T.A, at the corresponding position. The rpoD mutation (rpoD-RH588) changes a CGT codon to CAT. The corresponding change in sigma 70 is Arg588----His. This residue is in a region that is conserved among most sigma factors, a region that is also homologous with the helix-turn-helix motif of DNA-binding proteins. These results suggest that this region of sigma 70 is directly involved in recognition of the -35 hexamer.

DNA binding specificity of the Arc and Mnt repressors is determined by a short region of N-terminal residues

The Arc and Mnt repressors of phage P22 are related proteins that bind to different operator DNA sites. By creating a hybrid Arc-Mnt protein, we show that the binding specificity of Mnt can be switched to that of Arc by replacing six residues at the N terminus of Mnt with the corresponding nine residues from Arc.

DNA binding by proteins

Study of proteins that recognize specific DNA sequences has yielded much information, but the field is still in its infancy. Already two major structural motifs have been discovered, the helix-turn-helix and zinc finger, and numerous examples of DNA-binding proteins containing either of them are known. The restriction enzyme Eco RI uses yet a different motif. Additional motifs are likely to be found as well. There is a growing understanding of some of the physical chemistry involved in protein-DNA binding, but much remains to be learned before it becomes possible to engineer a protein that binds to a specific DNA sequence.

Modulation of Escherichia coli RecBCD activity by the bacteriophage lambda Gam and P22 Abc functions

Plasmids that express the bacteriophage lambda gam gene or the P22 abc2 gene (with and without abc1) at controllable levels were placed in Escherichia coli and tested for effects on the activity of RecBCD. Like Gam, Abc2 inhibited the ATP-dependent exonuclease activity of RecBCD, apparently not by binding to DNA. However, Abc2-mediated inhibition was partial, while Gam-mediated inhibition was complete. Both Abc2 and Gam inhibited host system-mediated homologous recombination in a Chi-containing interval in the chromosome of a hybrid lambda phage; Abc2 inhibited it more strongly than Gam. Gam but not Abc2 spared a phage T4 gene 2 mutant from restriction by RecBCD; Abc2 exhibited weak sparing activity in combination with Abc1 and substantial activity in combination with both Abc1 and P22 homologous recombination function Erf. Either Gam or the combination of the lambda recombination functions Exo and Bet was sufficient to induce a mode of plasmid replication that produced linear multimers. The combination of Abc2, Abc1, and Erf also exhibited this activity. However, Erf was inactive, both by itself and in combination with Abc1; Abc2 had weak activity. These results indicate that Gam and Abc2 modulate the activity of RecBCD in significantly different ways. In comparison with lambda Gam, P22 Abc2 has a weak effect on RecBCD nuclease activity but a strong effect on its recombination-promoting activity.

The Mnt repressor of bacteriophage P22: role of C-terminal residues in operator binding and tetramer formation

A set of C-terminal deletion mutants of the Mnt repressor of bacteriophage P22 has been constructed, and the corresponding truncated proteins have been purified. A truncated protein lacking the three C-terminal residues, Lys80-Thr81-Thr82, binds operator DNA with an affinity near wild type and has a normal tetrameric structure. Loss of the next residue, Lys79, causes a 600-fold decrease in operator affinity, but the truncated protein is still tetrameric. Further sequential deletions of Tyr78 and Leu77 cause modest decreases in operator affinity, but the truncated proteins are now dimeric. These results indicate that Lys79 is an important determinant of the high affinity of Mnt repressor for operator DNA and that Tyr78 is an important determinant of tetramer formation by Mnt repressor.

Interaction of the bacteriophage P22 Arc repressor with operator DNA

Are repressor binds to a single, partially symmetric, 21 base-pair operator site that is centered between the -10 and -35 regions of the Pant promoter. Protection and interference experiments show that Arc makes contacts with the operator on one side of the DNA helix. Although Arc is a small protein (53 residues/subunit), it makes contacts that are farther from the center of the operator than those made by many larger repressors. These extended contacts include the phosphate groups at the ends of the 21 base-pair site. Under standard conditions (pH 7.5, 100 mM-KCl, 3 mM-MgCl2, 22 degrees C) half-maximal operator binding is observed at an Arc concentration of 2.5 X 10(-9) M and the protein-DNA complex is very stable (t1/2 approximately equal to 80 min).

Bacteriophage P22 Mnt repressor. DNA binding and effects on transcription in vitro

We have examined the binding of Mnt repressor to operator DNA in vitro and have determined how this binding affects the level of transcription from two nearby promoters, Pant and Pmnt. Mnt binds to a region of DNA that overlaps the startpoint of transcription of Pant and the -35 region of Pmnt. Mnt represses transcription in vitro from Pant and enhances transcription from Pmnt. Protection and interference experiments show that Mnt binds to a single, 17 base-pair operator site. The operator sequence and the protein-DNA contacts are symmetric. Mnt makes major groove contacts on both faces of the operator DNA. At pH 7.5, 200 mM-KCl, 22 degrees C, the Mnt tetramer binds operator with high affinity (Kd = 2.2 X 10(-11M) and the protein-DNA complex is quite stable (t1/2 = 48 min). Operator binding shows large dependencies on pH, salt concentration, and temperature.

Control of gene expression in bacteriophage P22 by a small antisense RNA. I. Characterization in vitro of the Psar promoter and the sar RNA transcript

The characterization in vitro of a newly discovered promoter (Psar) in the bacteriophage P22 immI region is described. Psar is located within the ant gene and is directed toward the major immI promoter, Pant. The entire intercistronic region between the P22 arc and ant genes (69 bp) is transcribed. The initiation and termination of sar (small antisense regulatory) RNA transcription are unusual. Frequent abortive initiation occurs in the presence of all four NTPs; RNA products 3-13 nucleotides in length are produced in about 15- to 25-fold larger numbers than full-length transcripts. Termination of sar RNA synthesis occurs after transcription of the first and second Ts of a TTTA sequence following a region of hyphenated dyad symmetry. The effects of convergent transcription between Pant and Psar were investigated on linear and supercoiled templates. Active transcription from Pant interferes with full-length transcription from Psar; several factors that interfere with Pant initiation (e.g., Pant down-mutation, Mnt repressor protein, Arc repressor protein) result in indirect activation of sar RNA synthesis. The sar RNA pairs rapidly with ant mRNA to form a stable stoichiometric complex. The location and properties of Psar suggest an important regulatory function for sar RNA as a negative effector of ant expression. The results of Wu et al. (this issue) support this suggestion.

Control of gene expression in bacteriophage P22 by a small antisense RNA. II. Characterization of mutants defective in repression

Phage P22 produces antirepressor protein early after infection from a transcript initiated at the Pant promoter. After the first few minutes of infection, transcription from Pant is repressed by a protein encoded by the arc gene. Antirepressor is not produced late in infection, even though the antirepressor gene, ant, is transcribed from the late operon promoter Plate. We describe the isolation of P22 mutants that synthesize antirepressor from the Plate transcript. The mutations inactivate a promoter Psar, which lies within the ant coding sequence and directs the synthesis of sar RNA, a small antisense regulatory RNA complementary to the ant ribosome binding site. Characterization of the Psar down-mutants shows that transcription from Psar interferes with synthesis of antirepressor from both the Plate and Pant transcripts. Since sar RNA represses synthesis of antirepressor in trans, we propose that sar RNA base-pairs with ant mRNA to inhibit antirepressor synthesis at a post-transcriptional level. The role and importance of sar RNA in P22 biology are discussed.

The c4 gene of phage P1

The c4 gene of phage P1 has been localized to 335 bp of the P1EcoRI-9 fragment, within 50 bp of the EcoRI-9/14 junction. DNA sequence analysis of this fragment reveals a single open reading frame of 66 amino acids. The location of two c4 mutations, both of which produce changes in the predicted amino acid sequence in this reading frame, suggests that the reading frame codes for the c4 repressor. A region with high homology to the E. coli promoter consensus sequence is located approximately 50 bp upstream from the reading frame. Deletion of this potential promoter region abolishes expression of c4, as indicated by the loss of complementation of c4 mutants for lysogeny. Complementation is restored by the introduction of a heterologous promoter (the T7 phi 10 promoter), indicating that c4 expression is absolutely dependent on transcription of the 66-amino acid reading frame.

The miniF plasmid C protein: sequence, purification and DNA binding

The C (pifC) protein of miniF represses transcription of its own gene by binding to the pif operator (pifO); it is also needed for replication initiated from the miniF primary origin (ori-1). We have determined the nucleotide sequence of the C gene. The gene has been inserted into an expression vector under Ptrp control where it is expressed at high levels. The C protein has been purified from cells carrying the Ptrp-C plasmid, and a preliminary study of C protein-DNA binding properties has been carried out. C protein binds strongly to pifO, and weakly to sequences in the ori-1 region.

Isolation and analysis of arc repressor mutants: evidence for an unusual mechanism of DNA binding

We have isolated 64 different missense mutations at 36 out of 53 residue positions in the Arc repressor of bacteriophage P22. Many of the mutant proteins with substitutions in the C-terminal 40 residues of Arc have reduced intracellular levels and probably have altered structures or stabilities. Mutations in the N-terminal ten residues of Arc cause large decreases in operator DNA binding affinity without affecting the ability of Arc to fold into a stable three-dimensional structure. We argue that these N-terminal residues are important for operator recognition but that they are not part of a conventional helix-turn-helix DNA binding structure. These results suggest that Arc may use a new mechanism for sequence specific DNA binding.

Analysis of forward mutations induced by N-methyl-N'-nitro-N-nitrosoguanidine in the bacteriophage P22 mnt repressor gene

We describe the isolation and genetic characterization of N-methyl-N'-nitro-N-nitrosoguanidine (MNNG)-induced mutations in the phage P22 mnt repressor gene cloned in plasmid pBR322. Mutations in the mnt repressor gene or its operator on this plasmid, pPY98, confer a tetracycline resistance phenotype, whereas the wild-type plasmid confers tetracycline sensitivity. Cells carrying pPY98 were briefly exposed to MNNG to give 20 to 40% survival and a 50- to 100-fold increase in tetracycline-resistant cells. DNA sequence analysis showed that 29 of 30 MNNG-induced mutations were GC-to-AT transitions and one was an AT-to-GC transition. About 80% of the mutations are in three hotspots. This mutation spectrum is consistent with the proposed mechanism of mutagenic action of MNNG, which involves mispairing of an alkylated base, O6-methylguanine. The mnt gene may be a useful target for determining mutagenic specificity at the nucleotide level because forward mutations are easily isolated, the target size is small, and the DNA sequence changes of mutations can be determined rapidly.

Bacteriophage L: chromosome physical map and structural proteins

Restriction endonuclease cleavage site mapping was used to locate the regions of highest sequence homology in the chromosomes of Salmonella typhimurium bacteriophages L and P22. These lie in the DNA packaging, tail, early transcription antitermination, and perhaps integration "gene modules." Other regions of the two genomes are substantially less closely related. Phage L, which has no functional immunity I region, lacks approximately 1300 bp of DNA when compared to P22 in this section of the chromosome. At least some of the virion structural proteins are interchangeable between the two phages, which suggests that the two phage structural protein genes are very closely related. In addition, the apparent molecular weights of most P22 and L phage structural proteins are very similar. However, the phage L virion contains about 140 molecules of a 15K capsid protein which apparently has no P22 analog.