Study of the interaction between bacteriophage T4 asiA and Escherichia coli sigma(70), using the yeast two-hybrid system: neutralization of asiA toxicity to E. coli cells by coexpression of a truncated sigma(70) fragment

Improving furfural tolerance of Zymomonas mobilis by rewiring a sigma factor RpoD protein

Furfural from lignocellulosic hydrolysates is the key inhibitor for bio-ethanol fermentation. In this study, we report a strategy of improving the furfural tolerance in Zymomonas mobilis on the transcriptional level by engineering its global transcription sigma factor (σ(70), RpoD) protein. Three furfural tolerance RpoD mutants (ZM4-MF1, ZM4-MF2, and ZM4-MF3) were identified from error-prone PCR libraries. The best furfural-tolerance strain ZM4-MF2 reached to the maximal cell density (OD600) about 2.0 after approximately 30 h, while control strain ZM4-rpoD reached its highest cell density of about 1.3 under the same conditions. ZM4-MF2 also consumed glucose faster and yield higher ethanol; expression levels and key Entner-Doudoroff (ED) pathway enzymatic activities were also compared to control strain under furfural stress condition. Our results suggest that global transcription machinery engineering could potentially be used to improve stress tolerance and ethanol production in Z. mobilis.

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.

A procedure for systematic identification of bacteriophage-host interactions of P. aeruginosa phages

Immediately after bacteriophage infection, phage early proteins establish optimal conditions for phage infection, often through a direct interaction with host-cell proteins. We implemented a yeast two-hybrid approach for Pseudomonas aeruginosa phages as a first step in the analysis of these - often uncharacterized - proteins. A 24-fold redundant prey library of P. aeruginosa PAO1 (7.32x10(6) independent clones), was screened against early proteins (gp1 to 9) of phiKMV, a P. aeruginosa-infecting member of the Podoviridae; interactions were verified using an independent in vitro assay. None resembles previously known bacteriophage-host interactions, as the three identified target malate synthase G, a regulator of a secretion system and a regulator of nitrogen assimilation. Although at least two-bacteriophage infections are non-essential to phiKMV infection, their disruption has an influence on infection efficiency. This methodology allows systematic analysis of phage proteins and is applicable as an interaction analysis tool for P. aeruginosa.

Differential mechanisms of binding of anti-sigma factors Escherichia coli Rsd and bacteriophage T4 AsiA to E. coli RNA polymerase lead to diverse physiological consequences

Anti-sigma factors Escherichia coli Rsd and bacteriophage T4 AsiA bind to the essential housekeeping sigma factor, sigma(70), of E. coli. Though both factors are known to interact with the C-terminal region of sigma(70), the physiological consequences of these interactions are very different. This study was undertaken for the purpose of deciphering the mechanisms by which E. coli Rsd and bacteriophage T4 AsiA inhibit or modulate the activity of E. coli RNA polymerase, which leads to the inhibition of E. coli cell growth to different amounts. It was found that AsiA is the more potent inhibitor of in vivo transcription and thus causes higher inhibition of E. coli cell growth. Measurements of affinity constants by surface plasmon resonance experiments showed that Rsd and AsiA bind to sigma(70) with similar affinity. Data obtained from in vivo and in vitro binding experiments clearly demonstrated that the major difference between AsiA and Rsd is the ability of AsiA to form a stable ternary complex with RNA polymerase. The binding patterns of AsiA and Rsd with sigma(70) studied by using the yeast two-hybrid system revealed that region 4 of sigma(70) is involved in binding to both of these anti-sigma factors; however, Rsd interacts with other regions of sigma(70) as well. Taken together, these results suggest that the higher inhibition of E. coli growth by AsiA expression is probably due to the ability of the AsiA protein to trap the holoenzyme RNA polymerase rather than its higher binding affinity to sigma(70).

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.

Both regions 4.1 and 4.2 of E. coli sigma(70) are together required for binding to bacteriophage T4 AsiA in vivo

The T4 AsiA is an anti-sigma factor encoded by one of the early genes of Bacteriophage T4. It has been shown that AsiA inhibits transcription from promoters containing -10 and -35 consensus sequence by binding to sigma(70) of E. coli. Binding of AsiA to sigma(70) in vivo, in E. coli, leads to inhibition of transcription of essential genes resulting in killing of the organism. By using various in vitro methods, the region of sigma(70) binding to AsiA have been mapped to domain 4.2. Additionally, mutational analysis of sigma(70) has also identified amino acid residues in domain 4.1 which are critical for interaction with AsiA. Based on NMR studies it has been suggested that either of these regions can bind to AsiA, a conclusion which was supported by high degree of amino acid homology between domain 4.1 and 4.2. However, it is not clear whether under in vivo conditions, AsiA exerts its transcription inhibitory effect by binding to one of these regions or both the regions together. In order to understand the mechanism of AsiA mediated inhibition of E. coli transcription in vivo, in terms of specific binding requirements to region 4.1 and/or 4.2, we have studied the interaction of these sub-domains with AsiA by Yeast two hybrid system as well as by co-expressing and affinity purification of the interacting partners in vivo in E. coli. It was observed that minimum fragment of sigma(70) showing observable binding to AsiA, must possess sub-domains 4.1 and 4.2 together. No binding could be detected in sigma(70) fragments lacking a part of either domain 4.1 or 4.2, in any of the assays. This data was also supported by in vitro binding studies wherein only sigma(70) fragments carrying both region 4.1 and 4.2 showed binding to AsiA. Co-expression of region 4.1 and 4.2 fragments together also did not show any interaction with AsiA. The results presented here suggest that binding of AsiA to sigma(70), in vivo, requires the presence of both sub-domains of region 4 of sigma(70).

An artificial activator that contacts a normally occluded surface of the RNA polymerase holoenzyme

Many activators of transcription are sequence-specific DNA-binding proteins that stimulate transcription initiation through interaction with RNA polymerase (RNAP). Such activators can be constructed artificially by fusing a DNA-binding protein to a protein domain that can interact with an accessible surface of RNAP. In these cases, the artificial activator is directed to a target promoter bearing a recognition site for the DNA-binding protein. Here we describe an artificial activator that functions by contacting a normally occluded surface of promoter-bound RNAP holoenzyme. This artificial activator consists of a DNA-binding protein fused to the bacteriophage T4-encoded transcription regulator AsiA. On its own, AsiA inhibits transcription by Escherichia coli RNAP because it remodels the holoenzyme, disrupting an intersubunit interaction that is required for recognition of the major class of bacterial promoters. However, when tethered to the DNA via a DNA-binding protein, AsiA can exert a strong stimulatory effect on transcription by disrupting the same intersubunit interaction, contacting an otherwise occluded surface of the holoenzyme. We show that mutations that affect the intersubunit interaction targeted by AsiA modulate the stimulatory effect of this artificial activator. Our results thus demonstrate that changes in the accessibility of a normally occluded surface of the RNAP holoenzyme can modulate the activity of a gene-specific regulator of transcription.

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.

An altered-specificity DNA-binding mutant of Escherichia coliσ70 facilitates the analysis of σ70 function in vivo

The sigma subunit of bacterial RNA polymerase is strictly required for promoter recognition. The primary (housekeeping) sigma factor of Escherichia coli, sigma(70), is responsible for most of the gene expression in exponentially growing cells. The fact that sigma(70) is an essential protein has complicated efforts to genetically dissect the functions of sigma(70). To facilitate the analysis of sigma(70) function in vivo, we isolated an altered-specificity DNA-binding mutant of sigma(70), sigma(70) R584A, which preferentially recognizes a mutant promoter that is not efficiently recognized by wild-type sigma(70). Exploiting this sigma(70) mutant as a genetic tool, we establish an in vivo assay for the inhibitory effect of the bacteriophage T4-encoded anti-sigma factor AsiA on sigma(70)-dependent transcription. Our results demonstrate the utility of this altered-specificity system for genetically dissecting sigma(70) and its interactions with transcription regulators.

Dimerization properties of TraM, the antiactivator that modulates TraR-mediated quorum-dependent expression of the Ti plasmid tra genes

TraM, an 11.2 kDa antiactivator, modulates the acyl-homoserine lactone-mediated autoinduction of Ti plasmid conjugative transfer by interacting directly with TraR, the quorum-sensing transcriptional activator. Most antiactivators and antisigma factors examined to date act in dimer form. However, whether, and if so, how TraM dimerizes is unknown. Analyses based on a genetic assay using fusions of TraM to the lambda cI DNA binding domain, and biochemical assays using chemical crosslinking and gel filtration chromatography showed that TraM forms homodimers. Although SDS-PAGE studies suggested that the lone cysteine residue at position 71 was involved in interprotomer disulfide-bridging in TraM, altering Cys-71 to a serine did not significantly affect dimerization or the antiactivator activity of this mutant protein when expressed at wild-type levels in vivo. Analysis of N-terminal, C-terminal, and internal deletion mutants of TraM identified two regions of the protein involved in dimerization; one located within a segment between residues 20 and 50, and the other located to a segment between residues 67 and 96. Both regions are required for formation of fully stable dimers. Analysis of the activity of these deletion mutants in vivo, and their ability to bind TraR and to disrupt TraR-DNA complexes in vitro, suggests that while the internal segment of the protein is required for dimerization, determinants located at the far C-terminus and beginning at between residues 10 and 20 at the N-terminus play a role in TraR binding and antiactivator function. When co-expressed with lambda cI'::TraR fusions, wild-type TraM mediated quormone-independent dimerization of the transcriptional activator, suggesting that dimers of TraM can multimerize TraR.

A family of anti-sigma70 proteins in T4-type phages and bacteria that are similar to AsiA, a Transcription inhibitor and co-activator of bacteriophage T4

Anti-sigma70 factors interact with sigma70 proteins, the specificity subunits of prokaryotic RNA polymerase. The bacteriophage T4 anti-sigma70 protein, AsiA, binds tightly to regions 4.1 and 4.2 of the sigma70 subunit of Escherichia coli RNA polymerase and inhibits transcription from sigma70 promoters that require recognition of the canonical sigma70 -35 DNA sequence. In the presence of the T4 transcription activator MotA, AsiA also functions as a co-activator of transcription from T4 middle promoters, which retain the canonical sigma70 -10 consensus sequence but have a MotA box sequence centered at -30 rather than the sigma70 -35 sequence. The E.coli anti-sigma70 protein Rsd also interacts with region 4.2 of sigma70 and inhibits transcription from sigma70 promoters. Our sequence comparisons of T4 AsiA with Rsd, with the predicted AsiA orthologs of the T4-type phages RB69, 44RR, KVP40, and Aeh1, and with AlgQ, a regulator of alginate production in Pseudomonas aeruginosa indicate that these proteins share conserved amino acid residues at positions known to be important for the binding of T4 AsiA to sigma70 region 4. We show that, like T4 AsiA, Rsd binds to sigma70 in a native protein gel and, as with T4 AsiA, a L18S substitution in Rsd disrupts this complex. Previous work has assigned sigma70 amino acid F563, within region 4.1, as a critical determinant for AsiA binding. This residue is also involved in the binding of sigma70 to the beta-flap of core, suggesting that AsiA inhibits transcription by disrupting the interaction between sigma70 region 4.1 and the beta-flap. We find that as with T4 AsiA, the interaction of KVP40 AsiA, Rsd, or AlgQ with sigma70 region 4 is diminished by the substitution F563Y. We also demonstrate that like T4 AsiA and Rsd, KVP40 AsiA inhibits transcription from sigma70-dependent promoters. We speculate that the phage AsiA orthologs, Rsd, and AlgQ are members of a related family in T4-type phage and bacteria, which interact similarly with primary sigma factors. In addition, we show that even though a clear MotA ortholog has not been identified in the KVP40 genome and the phage genome appears to lack typical middle promoter sequences, KVP40 AsiA activates transcription from T4 middle promoters in the presence of T4 MotA. We speculate that KVP40 encodes a protein that is dissimilar in sequence, but functionally equivalent, to T4 MotA.

A single in vivo-selected point mutation in the active center ofToxoplasma gondiiferredoxin-NADP+reductase leads to an inactive enzyme with greatly enhanced affinity for ferredoxin

Electron transfer between plant-type [2Fe-2S] ferredoxin (Fd) and ferredoxin-NADP+ reductase (FNR) depends on the physical interaction between both proteins. We have applied a random mutagenesis approach with subsequent in vivo selection using the yeast two-hybrid system to obtain mutants of Toxoplasma gondii FNR with higher affinity for Fd. One mutant showed a 10-fold enhanced binding using affinity chromatography on immobilized Fd. A single serine-to-arginine exchange in the active site was responsible for its increased affinity. The mutant reductase was also enzymatically inactive. Homology modeling of the mutant FNR-Fd complex predicts substantial alterations of protein-FAD interactions in the active site of the enzyme with subsequent structural changes. Collectively, for the first time a point mutation in this important class of enzymes is described which leads to greatly enhanced affinity for its protein ligand.

Isomerase-Independent Chaperone Function of Cyclophilin Ensures Aggregation Prevention of Adenosine Kinase Both in vitro and under in vivo Conditions

Using inactive aggregates of adenosine kinase (AdK) from Leishmania donovani as the model substrate, we recently demonstrated that a cyclophilin (LdCyP) from the same source in an isomerase-independent fashion reactivated the enzyme in vitro by disaggregating its inactive oligomers [Chakraborty et al. (2002) J. Biol. Chem. 277, 47451-47460]. Besides disrupting preformed aggregates, LdCyP also prevents reaggregation of the newly formed active protein that is generated after productive refolding from its urea-denatured state. To investigate possible physiological implications of such phenomena, a unique expression system that simultaneously induces both AdK and LdCyP in naturally AdK-deficient Escherichia coli, was developed. Both in vitro and in vivo experiments revealed that oligomerization is an inherent property of this particular enzyme. In vivo protein cross-linking studies, activity determination analysis and Ado phosphorylation experiments carried out in cells coexpressing both the proteins unequivocally demonstrated that, similar to the phenomena observed in vitro, aggregates of the enzyme formed in vivo are able to interact with both LdCyP and its N-terminal truncated form (N(22-88)DEL LdCyP) in a crowded intracellular environment, resulting in aggregation prevention and reactivation of the enzyme. Our results indicate that the isomerase-independent chaperone function of LdCyP, detected in vitro, participates in vivo as well to keep aggregation-prone proteins in a monomeric state. Furthermore, analogous to yeast/bacterial two-hybrid systems, development of this simple coexpression system may help in the confirmation of interaction of two proteins under simulated in vivo conditions.

Characterization of the interactions between the bacteriophage T4 AsiA protein and RNA polymerase

The anti-sigma factor AsiA effects a change in promoter specificity of the Escherichia coli RNA polymerase via interactions with two conserved regions of the sigma(70) subunit, denoted 4.1 and 4.2. Free AsiA is a symmetrical homodimer. Here, we show that AsiA is monomeric when bound to sigma(70) and that a subset of the residues that contribute to the homodimer interface also contributes to the interface with sigma(70). AsiA interacts primarily with C-terminal sections of regions 4.1 and 4.2, which show remarkable sequence similarity. An AsiA monomer can simultaneously, and apparently cooperatively, bind both isolated regions 4.1 and 4.2 at preferred, distinct subsites, whereas region 4.1 alone or region 4.2 alone can interact with either subsite. These results suggest structural and functional plasticity in the interaction of AsiA with sigma(70) and support the notion of discrete roles for regions 4.1 and 4.2 in transcription regulation by AsiA. Furthermore, we show that AsiA inhibits recognition of the -35 consensus promoter element by region 4 of sigma(70) indirectly, as the residues on region 4 responsible for AsiA binding are distinct from those involved in DNA binding. Finally, we show that AsiA must directly disrupt the interaction of region 4 with the RNA polymerase beta subunit flap domain, resulting in a distance change between region 2 and region 4 of sigma(70). Thus, a new paradigm for transcription regulation by AsiA is emerging, whereby the distance between the DNA binding domains in sigma(70) is regulated, and promoter recognition specificity is modulated, by mediating the interactions of the sigma region 4 with the beta subunit flap domain.

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.

Mutational analysis of bacteriophage T4 AsiA: involvement of N- and C-terminal regions in binding to sigma(70) of Escherichia coli in vivo

The T4 AsiA is an anti-sigma factor encoded by an early gene of bacteriophage T4. AsiA has been shown to inhibit T4 early promoters in vitro and expression of this protein from a plasmid causes transcriptional shut off in the host cells leading to cell death. By reasoning that mutant AsiA expression in Escherichia coli will not inhibit the host transcription and hence lead to healthy colony formation, a strategy was developed wherein inactive or partially active mutants of AsiA could be isolated. These mutants were tested for their ability to bind to sigma(70) in vivo in E. coli, monitored as a relative toxicity assay, co-purification of sigma(70), inhibition of [3H-uridine] incorporation and also in the yeast two hybrid system. A good correlation was found between the loss of toxicity of AsiA to E. coli cells and the inability of mutant AsiAs to bind to sigma(70) It was observed that deletion of C-terminal 17 amino acid residues of AsiA did not affect the activity whereas a mutant asiA lacking C-terminal 28 amino acid residues had the toxicity reduced to a large extent, suggesting that amino acid residues between 64 and 73 played a role in binding to AsiA. A mutant with a deletion of 34 amino acids in the C-terminus did not show any toxicity to E. coli cells. In the N-terminal region, deletion of five amino acid residues was tolerated but extending the deletion to ten amino acids abolished the AsiA activity completely. The conversion of glutamic acid (E10) to either leucine, serine, glutamine, tyrosine or alanine did not affect the toxicity to a great extent suggesting that a negative charge at E10 is not critical for interaction with sigma(70). The results of our in vivo studies suggest that the primary sigma(70) binding site of AsiA is in N-terminus, but, it requires the presence of C-terminal 64-73 amino acid residues for effective binding in vivo.

Functional interaction of region 4 of the extracytoplasmic function sigma factor FecI with the cytoplasmic portion of the FecR transmembrane protein of the Escherichia coli ferric citrate transport system

Transcriptional regulation of the ferric citrate transport genes of Escherichia coli is initiated by the binding of ferric citrate to the outer membrane protein FecA. This binding elicits a signal that is transmitted by FecR across the cytoplasmic membrane into the cytoplasm, where the sigma factor FecI directs the RNA polymerase to the promoter upstream of the fecABCDE genes. An in vivo deletion analysis using a bacterial two-hybrid system assigned the interaction of the FecR and FecI proteins to the cytoplasmic portion of the FecR transmembrane protein and region 4 of FecI. Missense mutations randomly generated by PCR were localized to region 4 of FecI, and the mutants were impaired with regard to the interaction of FecR with FecI and fecB-lacZ transcription. The cloned region 4 of FecI interfered with fecB-lacZ transcription. Interaction of N-proximal regions of predicted FecR homologs with region 4 of predicted FecI homologs of Pseudomonas aeruginosa was demonstrated. The interaction was specific in that only cognate protein pairs interacted with each other; no interactions occurred between heterologous combinations of the P. aeruginosa proteins and between a P. aeruginosa FecI homolog and E. coli FecR. The results demonstrate that region 4 of FecI specifically binds FecR and that this binding is necessary for FecI to function as a sigma factor.

The bacteriophage T4 transcription activator MotA interacts with the far-C-terminal region of the sigma70 subunit of Escherichia coli RNA polymerase

Transcription from bacteriophage T4 middle promoters uses Escherichia coli RNA polymerase together with the T4 transcriptional activator MotA and the T4 coactivator AsiA. AsiA binds tightly within the C-terminal portion of the sigma70 subunit of RNA polymerase, while MotA binds to the 9-bp MotA box motif, which is centered at -30, and also interacts with sigma70. We show here that the N-terminal half of MotA (MotA(NTD)), which is thought to include the activation domain, interacts with the C-terminal region of sigma70 in an E. coli two-hybrid assay. Replacement of the C-terminal 17 residues of sigma70 with comparable sigma38 residues abolishes the interaction with MotA(NTD) in this assay, as does the introduction of the amino acid substitution R608C. Furthermore, in vitro transcription experiments indicate that a polymerase reconstituted with a sigma70 that lacks C-terminal amino acids 604 to 613 or 608 to 613 is defective for MotA-dependent activation. We also show that a proteolyzed fragment of MotA that contains the C-terminal half (MotA(CTD)) binds DNA with a K(D(app)) that is similar to that of full-length MotA. Our results support a model for MotA-dependent activation in which protein-protein contact between DNA-bound MotA and the far-C-terminal region of sigma70 helps to substitute functionally for an interaction between sigma70 and a promoter -35 element.

Mycobacterium tuberculosis WhiB3 interacts with RpoV to affect host survival but is dispensable for in vivo growth

Previous work established that the principal sigma factor (RpoV) of virulent Mycobacterium bovis, a member of the Mycobacterium tuberculosis complex, restores virulence to an attenuated strain containing a point mutation (Arg-515-->His) in the 4.2 domain of RpoV. We used the 4.2 domain of RpoV as bait in a yeast two-hybrid screen of an M. tuberculosis H37Rv library and identified a putative transcription factor, WhiB3, which selectively interacts with the 4.2 domain of RpoV in virulent strains but not with the mutated (Arg-515-->His) allele. Infection of mice and guinea pigs with a M. tuberculosis H37Rv whiB3 deletion mutant strain showed that whiB3 is not necessary for in vivo bacterial replication in either animal model. In contrast, an M. bovis whiB3 deletion mutant was completely attenuated for growth in guinea pigs. However, we found that immunocompetent mice infected with the M. tuberculosis H37Rv whiB3 mutant strain had significantly longer mean survival times as compared with mice challenged with wild-type M. tuberculosis. Remarkably, the bacterial organ burdens of both mutant and wild-type infected mice were identical during the acute and persistent phases of infection. Our results imply that M. tuberculosis replication per se is not a sufficient condition for virulence in vivo. They also indicate a different role for M. bovis and M. tuberculosis whiB3 genes in pathogenesis generated in different animal models. We propose that M. tuberculosis WhiB3 functions as a transcription factor regulating genes that influence the immune response of the host.

Conserved regions 4.1 and 4.2 of sigma(70) constitute the recognition sites for the anti-sigma factor AsiA, and AsiA is a dimer free in solution

The association of the bacteriophage T4-encoded AsiA protein with the final sigma(70) subunit of the Escherichia coli RNA polymerase is one of the principal events governing transcription of the T4 genome. Analytical ultracentrifugation and NMR studies indicate that free AsiA is a symmetric dimer and the dimers can exchange subunits. Using NMR, the mutual recognition sites on AsiA and final sigma(70) have been elucidated. Residues throughout the N-terminal half of AsiA are involved either directly or indirectly in binding to final sigma(70) whereas the two highly conserved C-terminal regions of final sigma(70), denoted 4.1 and 4.2, constitute the entire AsiA binding domain. Peptides corresponding to these regions bind tightly to AsiA individually and simultaneously. Simultaneous binding promotes structural changes in AsiA that mimic interaction with the complete AsiA binding determinant of final sigma(70). Moreover, the results suggest that a significant rearrangement of the dimer accompanies peptide binding. Thus, both conserved regions 4.1 and 4.2 are intimately involved in recognition of AsiA by final sigma(70). The interaction of AsiA with 4.1 provides a potential explanation of the differential abilities of DNA and AsiA to bind to free final sigma(70) and a mechanistic alternative to models of AsiA function that rely on binding to a single site on final sigma(70).

The Escherichia coli RNA polymerase.anti-sigma 70 AsiA complex utilizes alpha-carboxyl-terminal domain upstream promoter contacts to transcribe from a -10/-35 promoter

During infection of Escherichia coli, the phage T4 early protein AsiA inhibits open complex formation by the RNA polymerase holoenzyme Efinal sigma(70) at -10/-35 bacterial promoters through binding to region 4.2 of the final sigma(70) subunit. We used the -10/-35 lacUV5 promoter to study the properties of the Efinal sigma(70). AsiA complex in the presence of the glutamate anion. Under these experimental conditions, inhibition by AsiA was significantly decreased. KMnO(4) probing showed that the observed residual transcriptional activity was due to the slow transformation of the ternary complex Efinal sigma(70). AsiA.lacUV5 into an open complex. In agreement with this observation, affinity of the enzyme for the promoter was 10-fold lower in the ternary complex than in the binary complex Efinal sigma(70).lacUV5. A tau plot analysis of abortive transcription reactions showed that AsiA binding to Efinal sigma(70) resulted in a 120-fold decrease in the second-order on-rate constant of the reaction of Efinal sigma(70) with lacUV5 and a 55-fold decrease in the rate constant of the isomerization step leading to the open complex. This ternary complex still responded to activation by the cAMP.catabolite activator protein complex. We show that compensatory Efinal sigma(70)/promoter upstream contacts involving the C-terminal domains of alpha subunits in Efinal sigma(70) become essential for the binding of Efinal sigma(70). AsiA to the lacUV5 promoter.

Substitutions in bacteriophage T4 AsiA and Escherichia coli sigma(70) that suppress T4 motA activation mutations

Bacteriophage T4 middle-mode transcription requires two phage-encoded proteins, the MotA transcription factor and AsiA coactivator, along with Escherichia coli RNA polymerase holoenzyme containing the sigma(70) subunit. A motA positive control (pc) mutant, motA-pc1, was used to select for suppressor mutations that alter other proteins in the transcription complex. Separate genetic selections isolated two AsiA mutants (S22F and Q51E) and five sigma(70) mutants (Y571C, Y571H, D570N, L595P, and S604P). All seven suppressor mutants gave partial suppressor phenotypes in vivo as judged by plaque morphology and burst size measurements. The S22F mutant AsiA protein and glutathione S-transferase fusions of the five mutant sigma(70) proteins were purified. All of these mutant proteins allowed normal levels of in vitro transcription when tested with wild-type MotA protein, but they failed to suppress the mutant MotA-pc1 protein in the same assay. The sigma(70) substitutions affected the 4.2 region, which binds the -35 sequence of E. coli promoters. In the presence of E. coli RNA polymerase without T4 proteins, the L595P and S604P substitutions greatly decreased transcription from standard E. coli promoters. This defect could not be explained solely by a disruption in -35 recognition since similar results were obtained with extended -10 promoters. The generalized transcriptional defect of these two mutants correlated with a defect in binding to core RNA polymerase, as judged by immunoprecipitation analysis. The L595P mutant, which was the most defective for in vitro transcription, failed to support E. coli growth.

Mapping the molecular interface between the sigma(70) subunit of E. coli RNA polymerase and T4 AsiA

Bacteriophage T4 antisigma protein AsiA (10 kDa) orchestrates a switch from the host and early viral transcription to middle viral transcription by binding to the sigma(70) subunit of E. coli RNA polymerase. The molecular determinants of sigma(70)-AsiA complex formation are not known. Here, we used combinatorial peptide chemistry, protein-protein crosslinking, and mutational analysis to study the interaction between AsiA and its target, the 33 amino acid residues-long sigma(70) peptide containing conserved region 4.2. Many region 4.2 amino acid residues contact AsiA, which likely completely occludes the DNA-binding surface of region 4.2. Though none of region 4.2 amino acid residues is singularly responsible for the very tight interaction with AsiA, sigma(70) Lys593 and Arg596 which lie outside the putative DNA recognition element of region 4.2, contribute the most. In AsiA, the first 20 amino acid residues are both necessary and sufficient for interactions with sigma(70). Our results clarify details of sigma(70)-AsiA interaction and open the way for engineering AsiA derivatives with altered specificities.

The antiactivator TraM interferes with the autoinducer-dependent binding of TraR to DNA by interacting with the C-terminal region of the quorum-sensing activator

Conjugal transfer of Agrobacterium tumefaciens Ti plasmids is regulated by quorum sensing via the transcriptional activator TraR and the acyl-homoserine lactone Agrobacterium autoinducer (AAI). Unique to this system, the activity of TraR is negatively modulated by an antiactivator called TraM. Analyses from yeast two-hybrid studies suggest that TraM directly interacts with the activator, but the conditions under which these components interact and the region of TraR responsible for this interaction are not known. Induction of traM in a strain in which TraR was activating transcription of a reporter system led to rapid cessation of gene expression. As assessed by a genetic assay that measures AAI-dependent DNA binding, TraM inhibited TraR function before and after the transcription factor had bound to its DNA recognition site. Consistent with this observation, in gel retardation assays, purified TraM abolished the DNA binding activity of TraR in a concentration-dependent manner. Such inhibition occurred independent of the order of addition of the reactants. As assessed by far Western analyses TraM interacts with TraR by directly binding the activator. TraM in its native form interacted with native TraR and also with heat-treated TraR but only when SDS was included with the denatured protein. TraM interacted with TraR on blots prepared with total lysates of cells grown in the presence and absence of AAI. Far Western analysis of N- and C-terminal deletion mutants localized a domain of TraR contributing to TraM binding to the C-terminal portion of the activator protein. Random mutagenesis by hydroxylamine treatment and error-prone polymerase chain reaction identified several residues in this region of TraR important for interacting with TraM as well as for transcriptional activation or/and DNA binding. We conclude that TraM inhibits TraR by binding to the activator at a domain within or close to the helix-turn-helix motif located at the C terminus of the protein.