New small polypeptides associated with DNA-dependent RNA polymerase of Escherichia coli after infection with bacteriophage T4

Programmable CRISPR-Cas transcriptional activation in bacteria

Programmable gene activation enables fine-tuned regulation of endogenous and synthetic gene circuits to control cellular behavior. While CRISPR-Cas-mediated gene activation has been extensively developed for eukaryotic systems, similar strategies have been difficult to implement in bacteria. Here, we present a generalizable platform for screening and selection of functional bacterial CRISPR-Cas transcription activators. Using this platform, we identified a novel CRISPR activator, dCas9-AsiA, that could activate gene expression by more than 200-fold across genomic and plasmid targets with diverse promoters after directed evolution. The evolved dCas9-AsiA can simultaneously mediate activation and repression of bacterial regulons in E. coli. We further identified hundreds of promoters with varying basal expression that could be induced by dCas9-AsiA, which provides a rich resource of genetic parts for inducible gene activation. Finally, we show that dCas9-AsiA can be ported to other bacteria of clinical and bioindustrial relevance, thus enabling bacterial CRISPRa in more application areas. This work expands the toolbox for programmable gene regulation in bacteria and provides a useful resource for future engineering of other bacterial CRISPR-based gene regulators.

Transcriptional control in the prereplicative phase of T4 development

Control of transcription is crucial for correct gene expression and orderly development. For many years, bacteriophage T4 has provided a simple model system to investigate mechanisms that regulate this process. Development of T4 requires the transcription of early, middle and late RNAs. Because T4 does not encode its own RNA polymerase, it must redirect the polymerase of its host, E. coli, to the correct class of genes at the correct time. T4 accomplishes this through the action of phage-encoded factors. Here I review recent studies investigating the transcription of T4 prereplicative genes, which are expressed as early and middle transcripts. Early RNAs are generated immediately after infection from T4 promoters that contain excellent recognition sequences for host polymerase. Consequently, the early promoters compete extremely well with host promoters for the available polymerase. T4 early promoter activity is further enhanced by the action of the T4 Alt protein, a component of the phage head that is injected into E. coli along with the phage DNA. Alt modifies Arg265 on one of the two α subunits of RNA polymerase. Although work with host promoters predicts that this modification should decrease promoter activity, transcription from some T4 early promoters increases when RNA polymerase is modified by Alt. Transcription of T4 middle genes begins about 1 minute after infection and proceeds by two pathways: 1) extension of early transcripts into downstream middle genes and 2) activation of T4 middle promoters through a process called sigma appropriation. In this activation, the T4 co-activator AsiA binds to Region 4 of σ⁷⁰, the specificity subunit of RNA polymerase. This binding dramatically remodels this portion of σ⁷⁰, which then allows the T4 activator MotA to also interact with σ⁷⁰. In addition, AsiA restructuring of σ⁷⁰ prevents Region 4 from forming its normal contacts with the -35 region of promoter DNA, which in turn allows MotA to interact with its DNA binding site, a MotA box, centered at the -30 region of middle promoter DNA. T4 sigma appropriation reveals how a specific domain within RNA polymerase can be remolded and then exploited to alter promoter specificity.

Determinants of affinity and activity of the anti-sigma factor AsiA

The AsiA protein is a T4 bacteriophage early gene product that regulates transcription of host and viral genes. Monomeric AsiA binds tightly to the sigma(70) subunit of Escherichia coli RNA polymerase, thereby inhibiting transcription from bacterial promoters and phage early promoters and coactivating transcription from phage middle promoters. Results of structural studies have identified amino acids at the protomer-protomer interface in dimeric AsiA and at the monomeric AsiA-sigma(70) interface and demonstrated substantial overlap in the sets of residues that comprise each. Here we evaluate the contributions of individual interfacial amino acid side chains to protomer-protomer affinity in AsiA homodimers, to monomeric AsiA affinity for sigma(70), and to AsiA function in transcription. Sedimentation equilibrium, dynamic light scattering, electrophoretic mobility shift, and transcription activity measurements were used to assess affinity and function of site-specific AsiA mutants. Alanine substitutions for solvent-inaccessible residues positioned centrally in the protomer-protomer interface of the AsiA homodimer, V14, I17, and I40, resulted in the largest changes in free energy of dimer association, whereas alanine substitutions at other interfacial positions had little effect. These residues also contribute significantly to AsiA-dependent regulation of RNA polymerase activity, as do additional residues positioned at the periphery of the interface (K20 and F21). Notably, the relative contributions of a given amino acid side chain to RNA polymerase inhibition and activation (MotA-independent) by AsiA are very similar in most cases. The mainstay for intermolecular affinity and AsiA function appears to be I17. Our results define the core interfacial residues of AsiA, establish roles for many of the interfacial amino acids, are in agreement with the tenets underlying protein-protein interactions and interfaces, and will be beneficial for a general, comprehensive understanding of the mechanistic underpinnings of bacterial RNA polymerase regulation.

A mutation within the β subunit of Escherichia coli RNA polymerase impairs transcription from bacteriophage T4 middle promoters

During infection of Escherichia coli, bacteriophage T4 usurps the host transcriptional machinery, redirecting it to the expression of early, middle, and late phage genes. Middle genes, whose expression begins about 1 min postinfection, are transcribed both from the extension of early RNA into middle genes and by the activation of T4 middle promoters. Middle-promoter activation requires the T4 transcriptional activator MotA and coactivator AsiA, which are known to interact with σ(70), the specificity subunit of RNA polymerase. T4 motA amber [motA(Am)] or asiA(Am) phage grows poorly in wild-type E. coli. However, previous work has found that T4 motA(Am)does not grow in the E. coli mutant strain TabG. We show here that the RNA polymerase in TabG contains two mutations within its β-subunit gene: rpoB(E835K) and rpoB(G1249D). We find that the G1249D mutation is responsible for restricting the growth of either T4 motA(Am)or asiA(Am) and for impairing transcription from MotA/AsiA-activated middle promoters in vivo. With one exception, transcription from tested T4 early promoters is either unaffected or, in some cases, even increases, and there is no significant growth phenotype for the rpoB(E835K G1249D) strain in the absence of T4 infection. In reported structures of thermophilic RNA polymerase, the G1249 residue is located immediately adjacent to a hydrophobic pocket, called the switch 3 loop. This loop is thought to aid in the separation of the RNA from the DNA-RNA hybrid as RNA enters the RNA exit channel. Our results suggest that the presence of MotA and AsiA may impair the function of this loop or that this portion of the β subunit may influence interactions among MotA, AsiA, and RNA polymerase.

New Late Gene, dar, Involved in DNA Replication of Bacteriophage T4 I. Isolation, Characterization, and Genetic Location

Suppressors of gene 59-defective mutants were isolated by screening spontaneous, temperature-sensitive (ts) revertants of the amber mutant, amC5, in gene 59. Six ts revertants were isolated. No gene 59-defective ts recombinant was obtained by crossing each ts revertant with the wild type, T4D. However, suppressors of gene 59-defective mutants were obtained from two of these ts revertants. These suppressor mutants are referred to as dar (DNA arrested restoration). dar mutants specifically restored the abnormalities, both in DNA synthesis and burst size, caused by gene 59-defective mutants to normal levels. It is unlikely that dar mutants are nonsense suppressors since theý failed to suppress amber mutations in 11 other genes investigated. The genetic expression of dar is controlled by gene 55; therefore, dar is a late gene. The genetic location of dar has been mapped between genes 24 and 25, a region contiguous to late genes. dar appears to be another nonessential gene of T4 since burst sizes of dar were almost identical to those of the wild type. Mutations in dar did not affect genetic recombination and repair of UV-damaged DNA, but caused a sensitivity to hydroxyurea in progeny formation. The effect of the dar mutation on host DNA degradation cannot account for its hydroxyurea sensitivity. dar mutant alleles were recessive to the wild-type allele as judged by restoration of arrested DNA synthesis. The possible mechanisms for the suppression of defects in gene 59 are discussed.

Middle promoters constitute the most abundant and diverse class of promoters in bacteriophage T4

The temporally regulated transcription program of bacteriophage T4 relies upon the sequential utilization of three classes of promoters: early, middle and late. Here we show that middle promoters constitute perhaps the largest and the most diverse class of T4 promoters. In addition to 45 T4 middle promoters known to date, we mapped 13 new promoters, 10 of which deviate from the consensus MotA box, with some of them having no obvious match to it. So, 30 promoters of 58 identified now deviate from the consensus sequence deduced previously. In spite of the differences in their sequences, the in vivo activities of these T4 middle promoters were demonstrated to be dependent on both activators, MotA and AsiA. Traditionally, the MotA box was restricted to a 9 bp sequence with the highly conserved motif TGCTT. New logo based on the sequences of currently known middle promoters supports the conclusion that the consensus MotA box is comprised of 10 bp with the highly conserved central motif GCT. However, some apparently good matches to the consensus of middle promoters do not produce transcripts either in vivo or in vitro, indicating that the consensus sequence alone does not fully define a middle promoter.

Bacillus subtilis RNA polymerase and its modification in sporulating and phage-infected bacteria

Bacillus subtilis RNA polymerase holoenzyme consists of the subunits beta', beta, sigma, alpha, delta, and omega. In sporulating bacteria and in bacteria infected with phages SP01 and SP82, this enzyme undergoes changes in subunit composition and transcriptional specificity that could play a regulatory role in gene transcription. Sporulating bacteria may contain a specific component that inhibits the activity of the sigma subunit of polymerase probably by interfering with the binding of sigma-polypeptide to core enzyme. The hypothetical inhibitor may be metabolically unstable, since its activity is rapidly depleted from sporulating cells in the presence of chloramphenicol. Inhibition of sigma-polypeptide activity may restrict the transcription of phage DNA an infected sporulating cells. Although lacking the sigma-subunit, RNA polymerase purified from sporulating cells contains sporulation-specific subunits of 85,000 and 27,000 daltons. In SP01-infected bacteria, the sigma-subunit is replaced by phage-induced subunits. Purified enzyme containing the protein product of SP01 regulatory gene 28 directs the transcription of phage middle genes in vitro, while enzyme containing phage-induced polypeptides V and VI preferentially copies late genes. Accurate transcription of middle and late genes in vitro requires the host delta-subunit of polymerase (or high ionic strength) but not sigma-subunit. Phage PBS2 induces an entirely new multisubunit RNA polymerase that specifically transcribes PBS2 DNA in vitro. This enzyme is synthesized de novo after infection and does not arise by modification of the B. subtilis holoenzyme.

Mutational analysis of sigma70 region 4 needed for appropriation by the bacteriophage T4 transcription factors AsiA and MotA

Transcriptional activation of bacteriophage T4 middle promoters requires sigma70-containing Escherichia coli RNA polymerase, the T4 activator MotA, and the T4 co-activator AsiA. T4 middle promoters contain the sigma70 -10 DNA element. However, these promoters lack the sigma70 -35 element, having instead a MotA box centered at -30, which is bound by MotA. Previous work has indicated that AsiA and MotA interact with region 4 of sigma70, the C-terminal portion that normally contacts -35 DNA and the beta-flap structure in core. AsiA binding prevents the sigma70/beta-flap and sigma70/-35 DNA interactions, inhibiting transcription from promoters that require a -35 element. To test the importance of residues within sigma70 region 4 for MotA and AsiA function, we investigated how sigma70 region 4 mutants interact with AsiA, MotA, and the beta-flap and function in transcription assays in vitro. We find that alanine substitutions at residues 584-588 (region 4.2) do not impair the interaction of region 4 with the beta-flap or MotA, but they eliminate the interaction with AsiA and prevent AsiA inhibition and MotA/AsiA activation. In contrast, alanine substitutions at 551-552, 554-555 (region 4.1) eliminate the region 4/beta-flap interaction, significantly impair the AsiA/sigma70 interaction, and eliminate AsiA inhibition. However, the 4.1 mutant sigma70 is still fully competent for activation if both MotA and AsiA are present. A previous NMR structure shows AsiA binding to sigma70 region 4, dramatically distorting regions 4.1 and 4.2 and indirectly changing the conformation of the MotA interaction site at the sigma70 C terminus. Our analyses provide biochemical relevance for the sigma70 residues identified in the structure, indicate that the interaction of AsiA with sigma70 region 4.2 is crucial for activation, and support the idea that AsiA binding facilitates an interaction between MotA and the far C terminus of sigma70.

Transcriptional takeover by σ appropriation: remodelling of the σ 70 subunit of Escherichia coli RNA polymerase by the bacteriophage T4 activator MotA and co-activator AsiA

Activation of bacteriophage T4 middle promoters, which occurs about 1 min after infection, uses two phage-encoded factors that change the promoter specificity of the host RNA polymerase. These phage factors, the MotA activator and the AsiA co-activator, interact with theσ70specificity subunit ofEscherichia coliRNA polymerase, which normally contacts the −10 and −35 regions of host promoter DNA. Like host promoters, T4 middle promoters have a good match to the canonicalσ70DNA element located in the −10 region. However, instead of theσ70DNA recognition element in the promoter's −35 region, they have a 9 bp sequence (a MotA box) centred at −30, which is bound by MotA. Recent work has begun to provide information about the MotA/AsiA system at a detailed molecular level. Accumulated evidence suggests that the presence of MotA and AsiA reconfigures protein–DNA contacts in the upstream promoter sequences, without significantly affecting the contacts ofσ70with the −10 region. This type of activation, which is called ‘σappropriation’, is fundamentally different from other well-characterized models of prokaryotic activation in which an activator frequently serves to forceσ70to contact a less than ideal −35 DNA element. This review summarizes the interactions of AsiA and MotA withσ70, and discusses how these interactions accomplish the switch to T4 middle promoters by inhibiting the typical contacts of the C-terminal region ofσ70, region 4, with the host −35 DNA element and with other subunits of polymerase.

Transcription regulation by bacteriophage T4 AsiA

Bacteriophage T4 AsiA, a strong inhibitor of bacterial RNA polymerase, was the first antisigma protein to be discovered. Recent advances that made it possible to purify large amounts of this highly toxic protein led to an increased understanding of AsiA function and structure. In this review, we discuss how the small 10-KDa AsiA protein plays a key role in T4 development through its ability to both inhibit and activate bacterial RNA polymerase transcription.

Twelve new MotA-dependent middle promoters of bacteriophage T4: consensus sequence revised

Bacteriophage T4 middle-mode transcription requires Escherichia coli RNA polymerase, phage-encoded transcriptional activator MotA and co-activator AsiA that form a complex at a middle promoter DNA. T4 middle promoters have been defined by a consensus sequence deduced from the list of 14 middle promoters identified in earlier studies. To date, 33 middle promoters have been mapped on the T4 genome. Of these, 12 contain differences even at the highly conserved positions of the consensus sequence. In the T4 prereplicative gene cluster between genes e and rpbA, we have identified 12 new middle promoters, most of which contain differences from the consensus sequence deduced previously. Analysis of base conservation in the different sequence positions of new middle promoters, as well as those identified previously, revealed some new features of middle T4 promoters. We propose to define these promoters by a MotA box (a/t)(a/t)(a/t)TGCTTtA centred at the position -30, the sequence TAtaAT centred at -10 relative to the transcriptional start site, and the spacer region of 12(+/-1) base-pairs between them.

Bacteriophage T4 genome

Phage T4 has provided countless contributions to the paradigms of genetics and biochemistry. Its complete genome sequence of 168,903 bp encodes about 300 gene products. T4 biology and its genomic sequence provide the best-understood model for modern functional genomics and proteomics. Variations on gene expression, including overlapping genes, internal translation initiation, spliced genes, translational bypassing, and RNA processing, alert us to the caveats of purely computational methods. The T4 transcriptional pattern reflects its dependence on the host RNA polymerase and the use of phage-encoded proteins that sequentially modify RNA polymerase; transcriptional activator proteins, a phage sigma factor, anti-sigma, and sigma decoy proteins also act to specify early, middle, and late promoter recognition. Posttranscriptional controls by T4 provide excellent systems for the study of RNA-dependent processes, particularly at the structural level. The redundancy of DNA replication and recombination systems of T4 reveals how phage and other genomes are stably replicated and repaired in different environments, providing insight into genome evolution and adaptations to new hosts and growth environments. Moreover, genomic sequence analysis has provided new insights into tail fiber variation, lysis, gene duplications, and membrane localization of proteins, while high-resolution structural determination of the "cell-puncturing device," combined with the three-dimensional image reconstruction of the baseplate, has revealed the mechanism of penetration during infection. Despite these advances, nearly 130 potential T4 genes remain uncharacterized. Current phage-sequencing initiatives are now revealing the similarities and differences among members of the T4 family, including those that infect bacteria other than Escherichia coli. T4 functional genomics will aid in the interpretation of these newly sequenced T4-related genomes and in broadening our understanding of the complex evolution and ecology of phages-the most abundant and among the most ancient biological entities on Earth.

Analysis of regions within the bacteriophage T4 AsiA protein involved in its binding to the sigma70 subunit of E. coli RNA polymerase and its role as a transcriptional inhibitor and co-activator

Bacteriophage T4 AsiA, a protein of 90 amino acid residues, binds to the sigma(70) subunit of Escherichia coli RNA polymerase and inhibits host or T4 early transcription or, together with the T4 MotA protein, activates T4 middle transcription. To investigate which regions within AsiA are involved in forming a complex with sigma(70) and in providing transcriptional functions we generated random mutations throughout AsiA and targeted mutations within the C-terminal region. We tested mutant proteins for their ability to complement the growth of T4 asiA am phage under non-suppressing conditions, to inhibit E. coli growth, to interact with sigma(70) region 4 in a two-hybrid assay, to bind to sigma(70) in a native protein gel, and to inhibit or activate transcription in vitro using a T4 middle promoter that is active with RNA polymerase alone, is inhibited by AsiA, and is activated by MotA/AsiA. We find that substitutions within the N-terminal half of AsiA, at amino acid residues V14, L18, and I40, rendered the protein defective for binding to sigma(70). These residues reside at the monomer-monomer interface in recent NMR structures of the AsiA dimer. In contrast, AsiA missing the C-terminal 44 amino acid residues interacted well with sigma(70) region 4 in the two-hybrid assay, and AsiA missing the C-terminal 17 amino acid residues (Delta74-90) bound to sigma(70) and was fully competent in standard in vitro transcription assays. However, the presence of the C-terminal region delayed formation of transcriptionally competent species when the AsiA/polymerase complex was pre-incubated with the promoter in the absence of MotA. Our results suggest that amino acid residues within the N-terminal half of AsiA are involved in forming or maintaining the AsiA/sigma(70) complex. The C-terminal region of AsiA, while not absolutely required for inhibition or co-activation, aids inhibition by slowing the formation of transcription complexes between a promoter and the AsiA/polymerase complex.

Identification of two middle promoters upstream DNA ligase gene 30 of bacteriophage T4

Bacteriophage T4 DNA ligase gene 30 lies in the cluster of prereplicative genes located counterclockwise from map units 149 to 121. Based on the early transcription studies this gene has been considered as a typical early gene of bacteriophage T4. In agreement with this assignment, two strong T4 early promoters, P(E )30.8 (128.6) and P(E )30.7 (128.2), located about 3.1 and 2.7 kb upstream from gene 30 have been revealed by promoter mapping and sequence analysis. In addition, the existence of a putative early promoter just upstream of gene 30 was proposed from the sequence data. However, here we show that the putative early promoter just upstream of gene 30 is, in fact, a T4 middle promoter. Furthermore, we detected one more middle promoter located in the genomic region between early promoter P(E )30.7 (128.2) and DNA ligase gene 30 in the coding region of gene 30.3. Both new middle promoters have differences from the consensus MotA box, while their -10 regions match the sigma(70) consensus sequence very well. The 5' ends of MotA-dependent transcripts directed from these promoters, as well as the kinetics of 5' end accumulation in the cells, have been determined by primer extension analysis. The results of these analyses indicate that both MotA-dependent and MotA-independent promoters control the transcription of T4 DNA ligase gene 30 in vivo. Moreover, we show that the first transcripts for gene 30 are directed from its own middle promoter, P(M)30.

Solution structure and stability of the anti-sigma factor AsiA: implications for novel functions

Anti-sigma factors regulate prokaryotic gene expression through interactions with specific sigma factors. The bacteriophage T4 anti-sigma factor AsiA is a molecular switch that both inhibits transcription from bacterial promoters and phage early promoters and promotes transcription at phage middle promoters through its interaction with the primary sigma factor of Escherichia coli, sigma(70). AsiA is an all-helical, symmetric dimer in solution. The solution structure of the AsiA dimer reveals a novel helical fold for the protomer. Furthermore, the AsiA protomer, surprisingly, contains a helix-turn-helix DNA binding motif, predicting a potential new role for AsiA. The AsiA dimer interface includes a substantial hydrophobic component, and results of hydrogen/deuterium exchange studies suggest that the dimer interface is the most stable region of the AsiA dimer. In addition, the residues that form the dimer interface are those that are involved in binding to sigma(70). The results promote a model whereby the AsiA dimer maintains the active hydrophobic surfaces and delivers them to sigma(70), where an AsiA protomer is displaced from the dimer via the interaction of sigma(70) with the same residues in AsiA that constitute the dimer interface.

Recognition and specific degradation of bacteriophage T4 mRNAs

Gene 61.5 of bacteriophage T4 has a unique role in gene expression. When this gene is mutated, mRNAs of many late genes are rapidly degraded, resulting in late-gene silencing. Here, we characterize an extragenic suppressor, ssf5, of a gene 61.5 mutation. ssf5 was found to be an amber mutation in motA, which encodes a transcription activator for T4 middle genes. When this gene is mutated, both degradation and specific cleavage of late-gene mRNA is induced after a delay, as exemplified by soc mRNA. Consequently, partial late-gene expression occurs. In an ssf5 genetic background, a gene 61.5 mutation exhibits a novel phenotype: in contrast to late-gene mRNA, middle-gene mRNA is stabilized and the expression of middle genes is prolonged. This is attributable to an activity of gene 61.5 specific for degradation of middle-gene mRNA. The degradation of middle-gene mRNA in the presence of a normal gene 61.5 appears in parallel with the degradation of late-gene mRNA in its absence. This observation suggests that the mRNA-degrading activity that silences late genes in cells infected with a gene 61.5 mutant is targeted to middle-gene mRNA when gene 61.5 is wild type. These results and the results obtained in the presence of a normal motA gene suggest that gene 61.5 protein functions to discriminate mRNAs for degradation in a stage-dependent manner.

The bacteriophage T4 anti-sigma factor AsiA is not necessary for the inhibition of early promoters in vivo

Bacteriophage T4 early promoters are utilized immediately after infection and are abruptly turned off 2-3 min later (at 30 degrees C) when the middle promoters are activated. The viral early protein AsiA has been suspected to bring about this transcriptional switch: not only does it activate transcription at middle promoters in vivo and in vitro but it also shows potent anti-sigma70 activity in vitro, suggesting that it is responsible for the shut-off of early transcription. We show here that after infection with a phage deleted for the asiA gene the inhibition of early transcription occurs to the same extent and with the same kinetics as in a wild-type infection. Thus, another AsiA-independent circuit efficiently turns off early transcription. The association of a mutation in asiA with a mutation in mod, rpbA, motA or motB has no effect on the inhibition of early promoters, showing that none of these phage-encoded transcriptional regulators is necessary for AsiA-independent shut-off. It is not known whether AsiA is able to inhibit early promoters in vivo, but host transcription is strongly inhibited in vivo upon induction of AsiA from a multicopy plasmid.

The bacteriophage T4 transcriptional activator MotA accepts various base-pair changes within its binding sequence

During infection, bacteriophage T4 regulates three sets of genes: early, middle, and late. The host RNA polymerase is capable of transcribing early genes, but middle transcription requires the T4-encoded transcriptional activator, MotA protein, and the T4 co-activator, AsiA protein, both of which bind to the sigma 70 (sigma70) subunit of RNA polymerase. MotA also binds a DNA sequence (a MotA box), centered at position -30. The identification of more than 20 middle promoters suggested that a strong match to the MotA box consensus sequence (t/a)(t/a)TGCTT(t/c)A was critical for MotA activation. We have investigated how specific base changes within the MotA box sequence affect MotA binding and activation in vitro, and we have identified seven new middle promoters in vivo. We find that an excellent match to the sigma70 -10 consensus sequence, rather than an excellent match to the MotA box consensus sequence, is an invariant feature of MotA-dependent promoters. Many single base changes in the MotA box are tolerated in binding and activation assays, indicating that there is more flexibility in the sequence requirements for MotA than was previously appreciated. We also find that using the natural T4 DNA, which contains glucosylated, 5-hydoxymethylated cytosine residues, affects the ability of particular MotA box sequences to activate transcription. We suggest that MotA and AsiA may function like certain eukaryotic TAFs (TATA binding protein (TBP) associated factors) whose binding to TBP results in transcription from new core promoter sequences.

The anti-sigma factors

A mechanism for regulating gene expression at the level of transcription utilizes an antagonist of the sigma transcription factor known as the anti-sigma (anti-sigma) factor. The cytoplasmic class of anti-sigma factors has been well characterized. The class includes AsiA form bacteriophage T4, which inhibits Escherichia coli sigma 70; FlgM, present in both gram-positive and gram-negative bacteria, which inhibits the flagella sigma factor sigma 28; SpoIIAB, which inhibits the sporulation-specific sigma factor, sigma F and sigma G, of Bacillus subtilis; RbsW of B. subtilis, which inhibits stress response sigma factor sigma B; and DnaK, a general regulator of the heat shock response, which in bacteria inhibits the heat shock sigma factor sigma 32. In addition to this class of well-characterized cytoplasmic anti-sigma factors, a new class of homologous, inner-membrane-bound anti-sigma factors has recently been discovered in a variety of eubacteria. This new class of anti-sigma factors regulates the expression of so-called extracytoplasmic functions, and hence is known as the ECF subfamily of anti-sigma factors. The range of cell processes regulated by anti-sigma factors is highly varied and includes bacteriophage phage growth, sporulation, stress response, flagellar biosynthesis, pigment production, ion transport, and virulence.

Studies on the omega subunit of Escherichia coli RNA polymerase--its role in the recovery of denatured enzyme activity

Highly purified Escherichia coli RNA polymerase contains a small subunit termed omega that has a molecular mass of 10,105 Da and is comprised of 91 amino acids. To elucidate the function of omega, whose role is as yet undefined, the subunit was purified to over 95% purity from an overproducing strain [BL21 (pGP1-2, pE3C-2)]. Purified omega was then reconstituted with RNA polymerase isolated from an omega-less mutant. Externally added omega inhibited promoter-specific transcriptional activity at all promoters tested. Renaturation of fully denatured omega-less RNA polymerase in the presence of excess omega yielded maximum recovery of activity suggesting a structural rather than functional role for omega.

An N-terminal mutation in the bacteriophage T4 motA gene yields a protein that binds DNA but is defective for activation of transcription

The bacteriophage T4 MotA protein is a transcriptional activator of T4-modified host RNA polymerase and is required for activation of the middle class of T4 promoters. MotA alone binds to the -30 region of T4 middle promoters, a region that contains the MotA box consensus sequence [(t/a)(t/a)TGCTT(t/c)A]. We report the isolation and characterization of a protein designated Mot21, in which the first 8 codons of the wild-type motA sequence have been replaced with 11 different codons. In gel retardation assays, Mot21 and MotA bind DNA containing the T4 middle promoter P(uvsX) similarly, and the proteins yield similar footprints on P(uvsX). However, Mot21 is severely defective in the activation of transcription. On native protein gels, a new protein species is seen after incubation of the sigma70 subunit of RNA polymerase and wild-type MotA protein, suggesting a direct protein-protein contact between MotA and sigma70. Mot21 fails to form this complex, suggesting that this interaction is necessary for transcriptional activation and that the Mot21 defect arises because Mot21 cannot form this contact like the wild-type activator.

The asiA gene of bacteriophage T4 codes for the anti-sigma 70 protein

The anti-sigma 70 factor of bacteriophage T4 is a 10-kDa (10K) protein which inhibits the sigma 70-directed initiation of transcription by Escherichia coli RNA polymerase holoenzyme. We have partially purified the anti-sigma 70 factor and obtained the sequence of a C-terminal peptide of this protein. Using reverse genetics, we have identified, at the end of the lysis gene t and downstream of an as yet unassigned phage T4 early promoter, an open reading frame encoding a 90-amino-acid protein with a predicted molecular weight of 10,590. This protein has been overproduced in a phage T7 expression system and partially purified. It shows a strong inhibitory activity towards sigma 70-directed transcription (by RNA polymerase holoenzyme), whereas it has no significant effect on sigma 70-independent transcription (by RNA polymerase core enzyme). At high ionic strength, this inhibition is fully antagonized by the neutral detergent Triton X-100. Our results corroborate the initial observations on the properties of the phage T4 10K anti-sigma 70 factor, and we therefore propose that the gene which we call asiA, identified in the present study, corresponds to the gene encoding this T4 transcriptional inhibitor.

Gene product dsbA of bacteriophage T4 binds to late promoters and enhances late transcription

Gene product 33 of phage T4 is known to be essential in late transcription. Upstream from gene 33 and overlapping its 5' terminal sequence by 20 bp, we identified an open reading frame coding for a binding protein for double-stranded DNA (DsbA). Gene product DsbA is composed of 89 amino acid residues with a Mr of 10376 kDa. We purified this protein to homogeneity from over-expressing cells. Gel retardation assays reveal that it binds to DNA and footprint analyses disclose that it interacts preferentially with T4 late promoter regions. At the sites of binding the protein introduces nicks in double-stranded DNA. In vitro transcription assays performed with T4 late modified RNA polymerase on restriction fragments harbouring a T4 late promoter region prove that gene product DsbA enhances transcription from these promoter regions in the presence of gene product 33. Gene dsbA is distinct from gene das which maps close to this genomic region.

Inhibition of transcription of cytosine-containing DNA in vitro by the alc gene product of bacteriophage T4

The alc gene product (gpalc) of bacteriophage T4 inhibits the transcription of cytosine-containing DNA in vivo. We examined its effect on transcription in vitro by comparing RNA polymerase isolated from Escherichia coli infected with either wild-type T4D+ or alc mutants. A 50 to 60% decline in RNA polymerase activity, measured on phage T7 DNA, was observed by 1 min after infection with either T4D+ or alc mutants; this did not occur when the infecting phage lacked gpalt. In the case of the T4D+ strain but not alc mutants, this was followed by a further decrease. By 5 min after infection the activity of alc mutants was 1.5 to 2.5 times greater than that of the wild type on various cytosine-containing DNA templates, whereas there was little or no difference in activity on T4 HMdC-DNA, in agreement with the in vivo specificity. Effects on transcript initiation and elongation were distinguished by using a T7 phage DNA template. Rifampin challenge, end-labeling with [gamma-32P]ATP, and selective initiation with a dinucleotide all indicate that the decreased in vitro activity of the wild-type polymerase relative to that of the alc mutants was due to inhibition of elongation, not to any difference in initiation rates. Wild-type (but not mutated) gpalc copurified with RNA polymerase on heparin agarose but not in subsequent steps. Immunoprecipitation of modified RNA polymerase also indicated that gpalc was not tightly bound to RNA polymerase intracellularly. It thus appears likely that gpalc inhibits transcript elongation on cytosine-containing DNA by interacting with actively transcribing core polymerase as a complex with the enzyme and cytosine-rich stretches of the template.

Overproduced bacteriophage T4 gene 33 protein binds RNA polymerase

Bacteriophage T4 gene 33 protein (gp33), which is required for viral late transcription, has been overproduced. The purified gp33 binds to RNA polymerase core from uninfected or T4-infected Escherichia coli, but the major E. coli transcription initiation factor, sigma 70, competed effectively for this binding.

Escherichia coli mutations that prevent the action of the T4 unf/alc protein map in an RNA polymerase gene

Bacteriophage T4 has the substituted base hydroxymethylcytosine in its DNA and presumably shuts off host transcription by specifically blocking transcription of cytosine-containing DNA. When T4 incorporates cytosine into its own DNA, the shutoff mechanism is directed back at T4, blocking its late gene expression and phage production. Mutations which permit T4 multiplication with cytosine DNA should be in genes required for host shutoff. The only such mutations characterized thus far have been in the phage unf/alc gene. The product of this gene is also required for the unfolding of the host nucleoid after infection, hence its dual name unf/alc. As part of our investigation of the mechanism of action of unf/alc, we have isolated Escherichia coli mutants which propagate cytosine T4 even if the phage are genotypically alc+. These same E. coli mutants are delayed in the T4-induced unfolding of their nucleoid, lending strong support to the conclusion that blocking transcription and unfolding the host nucleoid are but different manifestations of the same activity. We have mapped two of the mutations, called paf mutations for prevent alc function. They both map at about 90 min, probably in the rpoB gene encoding a subunit of RNA polymerase. From the behavior of Paf mutants, we hypothesize that the unf/alc gene product of T4 interacts somehow with the host RNA polymerase to block transcription of cytosine DNA and unfold the host nucleoid.

Identification of the gene encoding an RNA polymerase-binding protein of bacteriophage T4

One of five bacteriophage T4-specified proteins that bind to host RNA polymerase core has been purified and partially sequenced. A mixed oligonucleotide, based on the amino acid sequence, was used to probe genomic restriction fragments. The gene for this protein, previously designated the 15K protein, has been located between T4 genes 45 and 46 and designated rpbA.

Identification of two new bacteriophage T4 genes that may have roles in transcription and DNA replication

We have identified two bacteriophage T4 genes, 45.1 and 45.2, that map in the intergenic space between phage replication genes 46 (which encodes a recombination initiation protein) and 45 (which encodes a bifunctional protein required in replication and transcription). The existence of genes 45.1 and 45.2 had not been previously recognized by mutation analysis of the T4 genome. We cloned the T4 gene 45.1/45.2 segment, determined its nucleotide sequence, and expressed its two reading frames at high levels in bacterial plasmids. The results predicted molecular weights of 11,400 (100 amino acids) for gp45.1 and 7,500 (62 amino acids) for gp45.2. We also determined that in T4-infected Escherichia coli, genes 45.1 and 45.2 are cotranscribed with their distal neighbor, gene 45, by at least one mode of transcription. In an accompanying report (K. P. Williams, G. A. Kassavetis, F. S. Esch, and E. P. Geiduschek, J. Virol. 61:600-603, 1987), it is shown that the product of gene 45.1 is the so-called T4-induced 15K protein, an RNA polymerase-binding protein of unknown role in phage development. Possibly, T4 genes 45.2, 45.1, and 45 constitute an operon for host RNA polymerase-binding phage proteins. Jointly with Williams et al., we propose the term rpb (RNA polymerase-binding) to refer to T4 genes whose products bind to the host RNA polymerase and have adopted the name rpbA for T4 gene 45.1.

The region of phage T4 genes 34, 33 and 59: primary structures and organization on the genome

The product of gene 33 is essential for the regulation of late transcription and gene product 59 is required in recombination, DNA repair and replication. The exact functions of both proteins are not known. Restriction fragments spanning the genomic area of genes 33 and 59 have been cloned into phage M13 and a 4.9 kb nucleotide sequence has been determined. Translation of the DNA sequence predicted that gp33 contains 112 amino acids with a mol.wt. of 12.816 kd while gp59 is composed of 217 amino acids adding up to a mol.wt. of 25.967 kd. The genomic area studied here also contains 3 open reading frames of genes not identified to date and it is thought to include the NH2-terminal part of g34. One of the open reading frames seems to code for the 10 kd protein, probably involved in the regulation of transcription of bacteriophage T4. This protein is predicted to consist of 89 amino acid residues with a mol.wt. of 10.376 kd. Gene 33 and the gene for the 10 kd protein were cloned separately on high expression vectors resulting in over-production of the two proteins.

The bacteriophage T4 regulatory protein gpunf/alc binds to DNA in the absence of RNA polymerase

DNA-cellulose chromatography and two-dimensional gel electrophoresis have been used to demonstrate the DNA-binding capacity of bacteriophage T4 gpunf/alc. The unf/alc protein does not bind to DNA via an association with RNA polymerase; gpunf/alc was shown to bind to DNA after separation from RNA polymerase and other large proteins by Sephadex chromatography.

Bacteriophage T4 unf (=alc) gene function is required for late replication in the presence of plasmid pR386

The bacteriophage T4 unf gene, known to be involved in the arrest of transcription from cytosine-containing DNA, is unessential except in Escherichia coli strains containing plasmid pR386. Comparative genetic and biochemical analyses of parameters of unf+ and unf- phage growth in host cells isogenic except for the presence or absence of plasmid pR386 have shown that unf gene function is required for late phage DNA synthesis in the presence of the plasmid. Shutoff of host DNA, RNA, and protein syntheses, degradation of host DNA, adsorption, injection, and early phage DNA, RNA, and protein syntheses all occurred with normal or near-normal kinetics in unf- infections, even in the presence of the plasmid. The switch from early to late protein synthesis occurred in plasmid pR386-containing cells infected with unf+ or unf- phage. However, this switchover was slow in both cases and may be slower in unf- infections than in unf+ infections. Net incorporation of [3H]thymidine terminated at about 30 min after infection of pR386-containing cells with unf- phage at 30 degrees C. Alkaline sucrose gradient studies of the intracellular pools of replicative DNA in unf-infected plasmid pR386-containing cells indicated that this DNA is not detectably nickel or cleaved at the time that DNA synthesis aborts. The addition of chloramphenicol subsequent to early enzyme synthesis prevented the arrest of DNA synthesis in plasmid-containing cells infected with unf-phage.

Bacteriophage T4 gol site: sequence analysis and effects of the site on plasmid transformation

The Escherichia coli lit gene product is required for the multiplication of bacteriophage T4 at temperatures below 34 degrees C. After infection of a lit mutant host, early gene product synthesis is normal, as is T4 DNA replication; however, the late gene products never appear, and early gene product synthesis eventually ceases. Consequently, at late times, there is no protein synthesis of any kind (W. Cooley, K. Sirotkin, R. Green, and L. Snyder, J. Bacteriol. 140:83-91, 1979; W. Champness and L. Snyder, J. Mol. Biol. 155:395-407, 1982), and no phage are produced. We have isolated T4 mutants which can multiply in lit mutant hosts. The responsible T4 mutations (called gol mutations) completely overcome the block to T4 gene expression (Cooley et al., J. Bacteriol. 140:83-91). We have proposed that gol mutations alter a cis-acting regulatory site on T4 DNA rather than a diffusible gene product and that the wild-type form of the gol site (gol+) somehow interferes with gene expression late in infection (Champness and Snyder, J. Mol. Biol. 155:395-409). In this communication, we report the sequence of the gol region of the T4 genome from five different gol mutants. The gol mutations are all single-base-pair transitions within 40 base pairs of DNA. Therefore, the gol site is at least 40 base pairs long. The sequence data confirm that the gol phenotype is not due to an altered protein. We also report that the gol+ site in plasmids prevents transformation of Lit- but not Lit+ E. coli. Thus, the gol site is at least partially active in the absence of the T4 genome.

T4 late transcripts are initiated near a conserved DNA sequence

Bacteriophage T4 late transcription is unusual, among prokaryotes, in its complexity. Late transcription requires the host RNA polymerase, the products of T4 genes, 33, 45 and 55, and other small polypeptides, the genes of which have not been identified. In addition the DNA template must be "competent' for late transcription. First the DNA must contain the substituted base 5-hydroxymethyl cytosine in place of cytosine (this requirement is eliminated by a mutation in the T4 alc gene). Second, the DNA must be replicating, although late transcription can be uncoupled from DNA replication by mutations in the T4 genes coding for DNA ligase (gene 30) and DNA exonuclease (gene 46). We report here the location of the initiation sites of the messenger RNAs (mRNAs) synthesized in vivo from four late genes (genes 21, 22, 23 and 36) by S1 nuclease mapping and we have determined the DNA sequences at these sites. We have found strong homology to the sequence TATAAATACTATT immediately upstream from the 5' ends of the late messages and we suggest that this sequence is specifically recognized by the complex responsible for late transcription. Also, we have examine gene 23 mRNA synthetized in the absence of DNA replication using the 30- 46- mutant described above and find that it is identical to the true late transcript synthesized in normal infections.

Two alternative mechanisms for initiation of DNA replication forks in bacteriophage T4: priming by RNA polymerase and by recombination

We show that bacteriophage T4 has two alternative mechanisms to initiate DNA replication; one dependent on Escherichia coli RNA polymerase (RNA nucleotidyltransferase, EC 2.7.7.6), and one dependent on general recombination. Continued DNA synthesis under recombination-defective conditions was sensitive to rifampin, an inhibitor of RNA polymerase. On the other hand, DNA synthesis accelerated in spite of the present of rifampin if recombination occurred.

Bacteriophage T4 alc gene product: general inhibitor of transcription from cytosine-containing DNA

The alc gene of bacteriophage T4 was originally defined on the basis of mutations which allow late protein synthesis directed by T4 DNA containing cytosine rather than hydroxymethylcytosine. The question remained whether the normal alc gene product (gpalc) also blocks the transcription of early genes from cytosine-containing DNA. Complementation experiments were performed between hydroxymethylcytosine-containing phage which direct gpalc synthesis but carry mutations in a given gene(s) and cytosine-containing phage carrying that gene(s). The required protein would then have to be directed by the cytosine-containing DNA: it is looked for directly on polyacrylamide gels or through its physiological effects or both. For all early proteins examined in this way, no synthesis was observed when 95 to 100% of the hydroxymethylcytosine was substituted by cytosine in the infecting DNA, whereas there was significant synthesis with 75% substitution or less. The results indicate that gpalc is carried in with the infecting DNA or is made very early to block transcription of all cytosine-containing DNA.

On the role of the Escherichia coli RNA polymerase sigma factor in T4 phage development

The rpoD800 mutation causing the temperature sensitivity of Escherichia coli RNA polymerase sigma factor has been used to demonstrate that the bacterial sigma factor is necessary throughout T4 phage development. In T4-infected RpoD800 mutant cells RNA synthesis is equally depressed at restrictive temperature at early and late stages of infection. The results show the bacterial sigma factor to be necessary for the synthesis of all RNA types in infected cells.

Control of promoter utilization by bacteriophage T4-induced modification of RNA polymerase alpha subunit

After infection of Escherichia coli cells, bacteriophage T4 induces several changes in the host DNA-dependent RNA polymerase. A well-characterized chemical change is a two-step ADP-ribosylation of the enzyme's alpha subunit (1). In order to investigate the effect of this change on RNA polymerase transcriptional properties in an in vitro system, we have reconstituted the enzyme from separated individual subunits which were obtained from normal or T4-modified RNA polymerases. It is demonstrated that the enzymes containing T4-modified alpha differ from the enzymes with normal alpha in two respects: (i) their overall activity on T4 DNA is reduced and (ii) they fail to utilize certain T4 promotors while efficiently utilizing other promoters. Among the promoters which are switched off by alpha modification are the two promoters of the D region and one of the two promoters of the T4 tRNA gene cluster. The differential effect of alpha modification on the expression of the tRNA and the D regions in vitro correlates with the previously established pattern of their transcription in vivo. It is suggested that the T4-induced ADP-ribosylation of RNA polymerase alpha subunit is involved in the shutoff of the early bacteriophage genes at the late stage of phage development.

Changes in the promoter range of RNA polymerase resulting from bacteriophage T4-induced modification of core enzyme

Primary transcripts made in vitro on bacteriophage T4 DNA by RNA polymerase isolated from normal or T4-infected Escherichia coli were compared by gel electrophoresis. Bacteriophage-modified RNA polymerase fails to initiate transcription at certain promoters recognized by unmodified enzyme. In the T4tRNA gene region, only one of the two promoters is active with the modified RNA polymerase. Reconstitution of separated RNA polymerase components demonstrates that this change in promoter site selection results from the modification of core enzyme and not sigma factor.

Postinfection control in T4 bacteriophage infection: inhibition of the rep function

We suggest that the general mechanism by which T4 phage turns off host macromolecular synthesis involves specific phage proteins which react with key components in the synthetic pathway. Support for this mechanism exists for the inhibition of host RNA synthesis. Here we note that the host rep function was inhibited after T4 phage infection. Since rep functions are known to be involved in host DNA replication, inhibition of rep might alter the course of host DNA replication.