Repressor structure and the mechanism of positive control

The status of emotional labour and its influence on job burnout among village doctors during the COVID-19 pandemic in China: a cross-sectional study

BACKGROUND

Village doctors in China are not only the gatekeepers of rural residents' health but also the net bottom of the medical security system. However, emotional labour is increasingly threatening the stability of the rural primary medical system. In addition, the ongoing coronavirus disease 2019 (COVID-19) pandemic has further exposed the vulnerability of human resources in China's rural health system. This study aims to evaluate the current situation of emotional labour among village doctors and explore the impact of emotional labour on job burnout during the COVID-19 pandemic in China.

METHODS

A cross-sectional survey was conducted in December 2021 in Shandong Province. We used structured questionnaires to collect data, including sociodemographic characteristics, emotional labour, and job burnout. Data were analysed by t test, analysis of variance (ANOVA), Pearson correlation analysis, and hierarchical multiple linear regression.

RESULTS

A total of 1,093 village doctors from Shandong Province participated in the study. More than half of the participants were male (62.40%) and were between 41 and 50 years old (53.43%). The total mean score of emotional labour was 3.17 ± 0.67, of which the surface acting (SA) score was 2.28 ± 0.90, and the deep acting (DA) score was 3.91 ± 0.93. There were significant differences in SA according to gender and work content (P < 0.05) and in DA according to gender, age, education level, and work content (P < 0.05). Pearson correlation analysis showed that SA was positively correlated with job burnout (P < 0.001), and DA was negatively correlated with job burnout (P < 0.001). Hierarchical multiple linear regression analysis revealed that 29% of the variance in job burnout is attributable to SA (β = 0.530, P < 0.001) and DA (β = -0.154, P < 0.001).

CONCLUSION

Village doctors in Shandong Province performed moderate levels of emotional labour during the COVID-19 pandemic. SA had a significant positive effect on job burnout, while DA had a significant negative effect on job burnout among village doctors. Administrators should enhance training on emotional labour for village doctors to play a positive role in alleviating their job burnout.

Mechanism underlying the DNA-binding preferences of the Vibrio cholerae and vibriophage VP882 VqmA quorum-sensing receptors

Quorum sensing is a chemical communication process that bacteria use to coordinate group behaviors. In the global pathogen Vibrio cholerae, one quorum-sensing receptor and transcription factor, called VqmA (VqmA_Vc), activates expression of the vqmR gene encoding the small regulatory RNA VqmR, which represses genes involved in virulence and biofilm formation. Vibriophage VP882 encodes a VqmA homolog called VqmA_Phage that activates transcription of the phage gene qtip, and Qtip launches the phage lytic program. Curiously, VqmA_Phage can activate vqmR expression but VqmA_Vc cannot activate expression of qtip. Here, we investigate the mechanism underlying this asymmetry. We find that promoter selectivity is driven by each VqmA DNA-binding domain and key DNA sequences in the vqmR and qtip promoters are required to maintain specificity. A protein sequence-guided mutagenesis approach revealed that the residue E194 of VqmA_Phage and A192, the equivalent residue in VqmA_Vc, in the helix-turn-helix motifs contribute to promoter-binding specificity. A genetic screen to identify VqmA_Phage mutants that are incapable of binding the qtip promoter but maintain binding to the vqmR promoter delivered additional VqmA_Phage residues located immediately C-terminal to the helix-turn-helix motif as required for binding the qtip promoter. Surprisingly, these residues are conserved between VqmA_Phage and VqmA_Vc. A second, targeted genetic screen revealed a region located in the VqmA_Vc DNA-binding domain that is necessary to prevent VqmA_Vc from binding the qtip promoter, thus restricting DNA binding to the vqmR promoter. We propose that the VqmA_Vc helix-turn-helix motif and the C-terminal flanking residues function together to prohibit VqmA_Vc from binding the qtip promoter.

Bacteria use a chemical communication process called quorum sensing (QS) to orchestrate collective behaviors. Recent studies demonstrate that bacteria-infecting viruses, called phages, also employ chemical communication to regulate collective activities. Phages can encode virus-specific QS-like systems, or they can harbor genes encoding QS components resembling those of bacteria. The latter arrangement suggests the potential for chemical communication across domains, i.e., between bacteria and phages. Ramifications stemming from such cross-domain communication are not understood. Phage VP882 infects the global pathogen Vibrio cholerae, and “eavesdrops” on V. cholerae QS to optimize the timing of its transition from existing as a parasite to killing the host, and moreover, to manipulate V. cholerae biology. To accomplish these feats, phage VP882 relies on VqmA_Phage, the phage-encoded homolog of the V. cholerae VqmA_Vc QS receptor and transcription factor. VqmA_Vc, by contrast, is constrained to the control of only V. cholerae genes and is incapable of regulating phage biology. Here, we discover the molecular mechanism underpinning the asymmetric transcriptional preferences of the phage-encoded and bacteria-encoded VqmA proteins. We demonstrate how VqmA transcriptional regulation is crucial to the survival and persistence of both the pathogen V. cholerae, and the phage that preys on it.

How Does Emotional Labor Impact Employees’ Perceptions of Well-Being? Examining the Mediating Role of Emotional Disorder

Since bank employees are prone to high psychological pressure, it is key to explore the influencing mechanism of their emotional labor so as to relieve their pressure, as well as improve organizational performance and service quality. This study aimed to investigate the effects of emotional labor on bank employees’ well-being and to determine the mediating role of emotional disorder in this relationship. Employees responded to a survey regarding their use of emotional labor as well as perceptions of their well-being and emotional disorder. The results showed that employees’ use of emotional labor was related to their perceptions of well-being and confirmed the mediating role of emotional disorder in this relationship. The results indicated that surface acting has a significant negative impact on employee well-being, while deep acting has a significant positive impact. Moreover, emotional disorder played a role in mediating emotional labor and employee well-being, and emotional disorder was positively correlated with surface acting and negatively correlated with deep acting. The results revealed that developing deep-acting skills is important for increasing front-line bank staff’s well-being in China, who are accustomed to repressing their emotions, and emotional disorder might occur more often than has been previously believed, which worsens their well-being.

The impact of customer incivility and verbal aggression on service providers: A systematic review

BACKGROUND

Working in direct contact with the public may involve psycho-social hazards for employees who are frequently exposed to rude or verbally aggressive customers. Negative encounters may undermine employees' well-being and job performance, impairing the quality of the service provided with tangible costs for organizations.

OBJECTIVE

The paper provides a systematic review of research on customer incivility and verbal aggression in service settings using the following framework 1) antecedents of customer misbehavior as reflected in worker perceptions, customer reasons and environmental factors; 2) maladaptive and adaptive coping strategies used by service providers in response to customer incivility and verbal aggression; 3) effects of customer incivility and verbal aggression on service providers' well-being and work-related outcomes; and 4) practical implications for the management. We present a model of the relationships between these four areas.

METHODS

A systematic review was conducted using PsychINFO and Scopus.

RESULTS

Fifty-three papers (20 pertaining to customer incivility and 33 pertaining to customer verbal aggression) were included.

CONCLUSION

Both customer incivility and verbal aggression may impair employees' well-being and job outcomes. Current gaps, practical implications, and directions for future research are discussed.

The Impact of Perceived Corporate Social Responsibility on Frontline Employee’s Emotional Labor Strategies

This study explores the relationship between corporate social responsibility and emotional labor strategies of frontline employees. In particular, the research focuses on the impact of perceived motives of corporate social responsibility on the cynicism, authenticity, and subsequently, the effect of cynicism and authenticity on surface acting and deep acting of frontline employees. Based on the online survey of 258 frontline employees in South Korea and structural equation modeling of the data, the findings show that the selfish motives of corporate social responsibility (CSR) increase cynicism whereas the altruistic motives of corporate social responsibility increase authenticity and decrease cynicism of frontline employees. In addition, this study reveals that CSR-cynicism leads to surface acting and reduces deep acting whereas CSR-authenticity increases deep acting and does not significantly affect surface acting of frontline employees.

Avaliação de efeito de uma intervenção para a Síndrome de Burnout em professores

Resumo A Síndrome de Burnout é caracterizada como um estresse crônico que impacta o trabalhador na sua saúde mental e física e requer ações de prevenção e intervenção. Assim, o estudo objetivou avaliar o efeito de uma intervenção para SB em professores. Foi utilizado delineamento pré-experimental com pré e pós-teste. Participaram da intervenção 20 professoras que atuam em uma escola municipal de ensino fundamental da região metropolitana de Porto Alegre, RS. A intervenção constitui-se de seis encontros que abordaram os seguintes temas: autodiagnóstico, estratégias de enfrentamento, manejo de problemas e emoções, gestão do tempo/família x trabalho e expectativas profissionais realísticas no trabalho. Os resultados evidenciaram que as dimensões de ilusão pelo trabalho, coping focado no problema e variabilidade de emoções no trabalho foram as variáveis que obtiveram aumento significativo quando comparados os tempos 1 e 2 de aplicação dos testes.

Viral communities of the human gut: metagenomic analysis of composition and dynamics

Background

The numerically most abundant biological entities on Earth are viruses. Vast populations prey on the cellular microbiota in all habitats, including the human gut.

Main body

Here we review approaches for studying the human virome, and some recent results on movement of viral sequences between bacterial cells and eukaryotic hosts. We first overview biochemical and bioinformatic methods, emphasizing that specific choices in the methods used can have strong effects on the results obtained. We then review studies characterizing the virome of the healthy human gut, which reveal that most of the viruses detected are typically uncharacterized phage - the viral dark matter - and that viruses that infect human cells are encountered only rarely. We then review movement of phage between bacterial cells during antibiotic treatment. Here a radical proposal for extensive movement of antibiotic genes on phage has been challenged by a careful reanalysis of the metagenomic annotation methods used. We then review two recent studies of movement of whole phage communities between human individuals during fecal microbial transplantation, which emphasize the possible role of lysogeny in dispersal.

Short conclusion

Methods for studying the human gut virome are improving, yielding interesting data on movement of phage genes between cells and mammalian host organisms. However, viral populations are vast, and studies of their composition and function are just beginning.

Modulation of Lactobacillus casei bacteriophage A2 lytic/lysogenic cycles by binding of Gp25 to the early lytic mRNA

The genetic switch of Lactobacillus casei bacteriophage A2 is regulated by the CI protein, which represses the early lytic promoter PR and Cro that abolishes expression from the lysogenic promoter PL . Lysogens contain equivalent cI and cro-gp25 mRNA concentrations, i.e., CI only partially represses P(R), predicting a lytic cycle dominance. However, A2 generates stable lysogens. This may be due to Gp25 binding to the cro-gp25 mRNA between the ribosomal binding site and the cro start codon, which abolishes its translation. Upon lytic cycle induction, CI is partially degraded, cro-gp25 mRNA levels increase, and Cro accumulates, launching viral progeny production. The concomitant concentration increase of Gp25 restricts cro mRNA translation, which, together with the low but detectable levels of CI late during the lytic cycle, promotes reentry of part of the cell population into the lysogenic cycle, thus explaining the low proportion of L. casei lysogens that become lysed (∼ 1%). A2 shares its genetic switch structure with many other Firmicutes phages. The data presented may constitute a model of how these phages make the decision for lysis versus lysogeny.

Transition Experiences of Stroke Survivors Following Discharge Home

BACKGROUND

Little is known about the transition experiences of stroke survivors after discharge home.

PURPOSE

The purpose of this article is to describe three domains of psychosocial experiences of stroke survivors during the first month following discharge for acute stroke.

METHOD

Data were collected from 125 stroke survivors interviewed at 1 month following discharge home.

RESULTS

Findings indicate that changes in sense of self, connectedness with others, and community integration presented the major challenges.

Structural and functional characterization of Pseudomonas aeruginosa global regulator AmpR

Pseudomonas aeruginosa is a dreaded pathogen in many clinical settings. Its inherent and acquired antibiotic resistance thwarts therapy. In particular, derepression of the AmpC β-lactamase is a common mechanism of β-lactam resistance among clinical isolates. The inducible expression of ampC is controlled by the global LysR-type transcriptional regulator (LTTR) AmpR. In the present study, we investigated the genetic and structural elements that are important for ampC induction. Specifically, the ampC (PampC) and ampR (PampR) promoters and the AmpR protein were characterized. The transcription start sites (TSSs) of the divergent transcripts were mapped using 5' rapid amplification of cDNA ends-PCR (RACE-PCR), and strong σ(54) and σ(70) consensus sequences were identified at PampR and PampC, respectively. Sigma factor RpoN was found to negatively regulate ampR expression, possibly through promoter blocking. Deletion mapping revealed that the minimal PampC extends 98 bp upstream of the TSS. Gel shifts using membrane fractions showed that AmpR binds to PampC in vitro whereas in vivo binding was demonstrated using chromatin immunoprecipitation-quantitative PCR (ChIP-qPCR). Additionally, site-directed mutagenesis of the AmpR helix-turn-helix (HTH) motif identified residues critical for binding and function (Ser38 and Lys42) and critical for function but not binding (His39). Amino acids Gly102 and Asp135, previously implicated in the repression state of AmpR in the enterobacteria, were also shown to play a structural role in P. aeruginosa AmpR. Alkaline phosphatase fusion and shaving experiments suggest that AmpR is likely to be membrane associated. Lastly, an in vivo cross-linking study shows that AmpR dimerizes. In conclusion, a potential membrane-associated AmpR dimer regulates ampC expression by direct binding.

Point mutations in Helicobacter pylori's fur regulatory gene that alter resistance to metronidazole, a prodrug activated by chemical reduction

Background

Helicobacter pylori's Fur regulatory protein controls transcription of dozens of genes in response to iron availability, acidity and oxidative stress, and affects the vigor of infection and severity of disease. It is unusual among Fur family proteins in being active both when iron-loaded and iron-free.

Metholodolgy/Principal Findings

We tested if H. pylori fur mutations could affect resistance to metronidazole (Mtz), an anti-H. pylori prodrug rendered bactericidal by chemical reduction. Point mutations were made by PCR in DNA containing fur and a downstream chloramphenicol resistance gene, and were placed in the H. pylori chromosome by transformation of a fur-deletion (Δfur) strain. Several substitutions affecting H. pylori Fur's ∼10 residue N terminal arm, which has no counterpart in prototype (E. coli-type) Fur proteins, increased Mtz resistance, as did mutations affecting the region between DNA binding and dimerization domains. Three types of mutations decreased resistance more than did Δfur: substitutions affecting the N-terminal arm; substitutions affecting the metal binding pocket; and nonsense mutations that resulted in a truncated Fur protein with no C-terminal dimerization domain. Most metal binding pocket mutations were obtained only in fur genes with additional inactivating mutations, and thus seemed deleterious or lethal because they.

Conclusions/Significance

These results establish that H. pylori Fur's distinctive N terminal arm is functional, and more generally illustrate that point mutations can confer informative phenotypes, distinct from those conferred by null mutations. We propose that fur mutations can affect Mtz susceptibility by altering the balance among Fur's several competing activities, and thereby the expression of genes that control cellular redox potential or elimination of bactericidal Mtz activation products. Further analyses of selected mutants should provide insights into Fur interactions with other cellular components, metabolic circuitry, and how H. pylori thrives in its special gastric niche.

Evolution of complex gene regulatory circuits by addition of refinements

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

Model of transcriptional activation by MarA in Escherichia coli

The AraC family transcription factor MarA activates ∼40 genes (the marA/soxS/rob regulon) of the Escherichia coli chromosome resulting in different levels of resistance to a wide array of antibiotics and to superoxides. Activation of marA/soxS/rob regulon promoters occurs in a well-defined order with respect to the level of MarA; however, the order of activation does not parallel the strength of MarA binding to promoter sequences. To understand this lack of correspondence, we developed a computational model of transcriptional activation in which a transcription factor either increases or decreases RNA polymerase binding, and either accelerates or retards post-binding events associated with transcription initiation. We used the model to analyze data characterizing MarA regulation of promoter activity. The model clearly explains the lack of correspondence between the order of activation and the MarA-DNA affinity and indicates that the order of activation can only be predicted using information about the strength of the full MarA-polymerase-DNA interaction. The analysis further suggests that MarA can activate without increasing polymerase binding and that activation can even involve a decrease in polymerase binding, which is opposite to the textbook model of activation by recruitment. These findings are consistent with published chromatin immunoprecipitation assays of interactions between polymerase and the E. coli chromosome. We find that activation involving decreased polymerase binding yields lower latency in gene regulation and therefore might confer a competitive advantage to cells. Our model yields insights into requirements for predicting the order of activation of a regulon and enables us to suggest that activation might involve a decrease in polymerase binding which we expect to be an important theme of gene regulation in E. coli and beyond.

When environmental conditions change, cell survival can depend on sudden production of proteins that are normally in low demand. Protein production is controlled by transcription factors which bind to DNA near genes and either increase or decrease RNA production. Many puzzles remain concerning the ways transcription factors do this. Recently we collected data relating the intracellular level of a single transcription factor, MarA, to the increase in expression of several genes related to antibiotic and superoxide resistance in Escherichia coli. These data indicated that target genes are turned on in a well-defined order with respect to the level of MarA, enabling cells to mount a response that is commensurate to the level of threat detected in the environment. Here we develop a computational model to yield insight into how MarA turns on its target genes. The modeling suggests that MarA can increase the frequency with which a transcript is made while decreasing the overall presence of the transcription machinery at the start of a gene. This mechanism is opposite to the textbook model of transcriptional activation; nevertheless it enables cells to respond quickly to environmental challenges and is likely of general importance for gene regulation in E. coli and beyond.

The C-terminal domain of the Escherichia coli RNA polymerase alpha subunit plays a role in the CI-dependent activation of the bacteriophage lambda pM promoter

The bacteriophage lambda p(M) promoter is required for maintenance of the lambda prophage in Escherichia coli, as it facilitates transcription of the cI gene, encoding the lambda repressor (CI). CI levels are maintained through a transcriptional feedback mechanism whereby CI can serve as an activator or a repressor of p(M). CI activates p(M) through cooperative binding to the O(R)1 and O(R)2 sites within the O(R) operator, with the O(R)2-bound CI dimer making contact with domain 4 of the RNA polymerase sigma subunit (sigma(4)). Here we demonstrate that the 261 and 287 determinants of the C-terminal domain of the RNA polymerase alpha subunit (alphaCTD), as well as the DNA-binding determinant, are important for CI-dependent activation of p(M). We also show that the location of alphaCTD at the p(M) promoter changes in the presence of CI. Thus, in the absence of CI, one alphaCTD is located on the DNA at position -44 relative to the transcription start site, whereas in the presence of CI, alphaCTD is located at position -54, between the CI-binding sites at O(R)1 and O(R)2. These results suggest that contacts between CI and both alphaCTD and sigma are required for efficient CI-dependent activation of p(M).

The ?35 sequence location and the Fis?sigma factor interface determine ?Sselectivity of the proP (P2) promoter in Escherichia coli

The P2 promoter of proP, encoding a transporter for proline and glycine betaine in Escherichia coli, is a unique paradigm, where master regulators of different growth stages, Fis and sigma(S) (RpoS), collaborate to achieve promoter activation. It is also the only case described where Fis functions as class II transcriptional activator (centred at -41). Here we show that the degenerate -35 sequence, and the location of the Fis binding site, which forces a suboptimal 16 bp spacing between the -35 and -10 elements, allow only sigma(S) but not sigma(70) to function at proP (P2). Moreover, the interface between Fis and sigma(S) seems better suited to sigma(S), due to a single residue difference between sigma(S) and sigma(70). Nevertheless, Fis can activate RNA polymerase containing sigma(70) at a proP (P2) promoter variant, in which a typical sigma(70)-35 recognition sequence has been introduced at a 17 bp distance from the -10 hexamer. In summary, we elucidate the rules that govern sigma factor selectivity in the presence of a class II activator, provide new insight into transcriptional activation by Fis from this position, and clarify, why the proP (P2) promoter is precisely activated during a short time window of the growth cycle, when Fis and sigma(S) are both present.

The structural basis of cooperative regulation at an alternate genetic switch

Bacteriophage lambda is a paradigm for understanding the role of cooperativity in gene regulation. Comparison of the regulatory regions of lambda and the unrelated temperate bacteriophage 186 provides insight into alternate ways to assemble functional genetic switches. The structure of the C-terminal domain of the 186 repressor, determined at 2.7 A resolution, reveals an unusual heptamer of dimers, consistent with presented genetic studies. In addition, the structure of a cooperativity mutant of the full-length 186 repressor, identified by genetic screens, was solved to 1.95 A resolution. These structures provide a molecular basis for understanding lysogenic regulation in 186. Whereas the overall fold of the 186 and lambda repressor monomers is remarkably similar, the way the two repressors cooperatively assemble is quite different and explains in part the differences in their regulatory activity.

Crystal structure of the restriction-modification system control element C.Bcll and mapping of its binding site

Protection from DNA invasion is afforded by restriction-modification systems in many bacteria. The efficiency of protection depends crucially on the relative expression levels of restriction versus methytransferase genes. This regulation is provided by a controller protein, named C protein. Studies of the Bcll system in E. coli suggest that C.Bcll functions as a negative regulator for M.Bcll expression, implying that it plays a role in defense against foreign DNA during virus infection. C.Bcll binds (Kd = 14.3 nM) to a 2-fold symmetric C box DNA sequence that overlaps with the putative -35 promoter region upstream of the bcllM and bcllC genes. The C.Bcll fold comprises five alpha helices: two helices form a helix-turn-helix motif, and the remaining three helices form the extensive dimer interface. The C.Bcll-DNA model proposed suggests that DNA bending might play an important role in gene regulation, and that Glu27 and Asp31 in C.Bcll might function critically in the regulation.

Positive autoregulation of cI is a dispensable feature of the phage lambda gene regulatory circuitry

Complex gene regulatory circuits contain many features that are likely to contribute to their operation. It is unclear, however, whether all these features are necessary for proper circuit behavior or whether certain ones are refinements that make the circuit work better but are dispensable for qualitatively normal behavior. We have addressed this question using the phage lambda regulatory circuit, which can persist in two stable states, the lytic state and the lysogenic state. In the lysogenic state, the CI repressor positively regulates its own expression by stimulating transcription from the P(RM) promoter. We tested whether this feature is an essential part of the regulatory circuitry. Several phages with a cI mutation preventing positive autoregulation and an up mutation in the P(RM) promoter showed near-normal behavior. We conclude that positive autoregulation is not necessary for proper operation of the lambda circuitry and speculate that it serves a partially redundant function of stabilizing a bistable circuit, a form of redundancy we term "circuit-level redundancy." We discuss our findings in the context of a two-stage model for evolution and elaboration of regulatory circuits from simpler to more complex forms.

Purification and characterization of the repressor of the shiga toxin-encoding bacteriophage 933W: DNA binding, gene regulation, and autocleavage

The genes encoding Shiga toxin (stx), the major virulence factor of Shiga toxin-encoding Escherichia coli (STEC) strains, are carried on lambdoid prophages resident in all known STEC strains. The stx genes are expressed only during lytic growth of these temperate bacteriophages. We cloned the gene encoding the repressor of the Shiga toxin-encoding bacteriophage 933W and examined the DNA binding and transcriptional regulatory activities of the overexpressed, purified protein. Typical of nearly all lambdoid phage repressors, 933W repressor binds to three sites in 933W right operator (OR). Also typical, when bound at OR, 933W repressor functions as an activator at the PRM promoter and a repressor at the PR promoter. In contrast to other lambdoid bacteriophages, 933W left operator (OL) contains only two repressor binding sites, but the OL-bound repressor still efficiently represses PL transcription. Lambdoid prophage induction requires inactivation of the repressor's DNA binding activity. In all phages examined thus far, this inactivation requires a RecA-stimulated repressor autoproteolysis event, with cleavage occurring precisely in an Ala-Gly dipeptide sequence that is found within a "linker " region that joins the two domains of these proteins. However, 933W repressor protein contains neither an Ala-Gly nor an alternative Cys-Gly dipeptide cleavage site anywhere in its linker sequence. We show here that the autocleavage occurs at a Leu-Gly dipeptide. Thus, the specificity of the repressor autocleavage site is more variable than thought previously.

Partition of distinct chromosomal regions: negotiable border and fixed border

Chromosomes are partitioned into distinct functional regions. For example, heterochromatin regions consist of condensed chromatin and contain few transcriptionally active genes, whereas euchromatin regions are less condensed and majority of active genes reside in the euchromatin regions. Because distinct regions reside in each chromosome, borders are accordingly established between these regions. A prevailing view of the borders is that they are 'walls' that actively inhibit communication between distinct regions on chromosomes. Although little is known about the molecular bases of these walls, specific DNA elements are considered to recruit these walls to define the positions of the borders. We call the borders established with this mechanism as 'fixed borders'. Past studies have identified various insulators (boundary DNA elements) that have been suggested to recruit fixed borders to them. Another mechanism, which we introduce and focus on in this review, does not require walls recruited by specific DNA elements at the chromosomal borders. Instead, the borders are defined by a balance of opposing enzymatic activities located at the opposite sides of the resultant borders. We name these borders 'negotiable borders'. Here we review some of the recent progress in the field that offer valuable insight into mechanisms of establishing structural and functional borders on chromosomes.

Structure of a ternary transcription activation complex

The cI protein of bacteriophage lambda (lambdacI) activates transcription by binding a DNA operator just upstream of the promoter and interacting with the RNA polymerase sigma subunit domain 4 (sigma(4)). We determined the crystal structure of the lambdacI/sigma(4)/DNA ternary complex at 2.3 A resolution. There are no conformational changes in either protein, which interact through an extremely small interface involving at most 6 amino acid residues. The interactions of the two proteins stabilize the binding of each protein to the DNA. The results provide insight into how activators can operate through a simple cooperative binding mechanism but affect different steps of the transcription initiation process.

DNA binding and ToxR responsiveness by the wing domain of TcpP, an activator of virulence gene expression in Vibrio cholerae

Virulence in Vibrio cholerae requires activation of toxT by two membrane-localized activators, TcpP and ToxR. We isolated 12 tcpP activation mutants that fell into two classes: class I mutants were inactive irrespective of the presence of ToxR, and class II mutants exhibited near wild-type activity when coexpressed with ToxR. Most class I mutants had lesions in the wing domain predicted by homology with the winged helix-turn-helix family of activators. Class I mutants bound promoter DNA poorly and were largely unable to interact with ToxR in a crosslinking assay, whereas class II mutants retained physical interaction with ToxR. One mutant constructed in vitro bound DNA poorly but nevertheless responded to ToxR by activating toxT and also maintained ToxR interaction. We propose that ToxR interaction, but not DNA binding, is essential for TcpP function and that the wing domain of TcpP enables contact with ToxR required for productive TcpP-RNA polymerase association.

Region 4 of sigma as a target for transcription regulation

Bacterial sigma factors play a key role in promoter recognition, making direct contact with conserved promoter elements. Most sigma factors belong to the sigma70 family, named for the primary sigma factor in Escherichia coli. Members of the sigma70 family typically share four conserved regions and, here, we focus on region 4, which is directly involved in promoter recognition and serves as a target for a variety of regulators of transcription initiation. We review recent advances in the understanding of the mechanism of action of regulators that target region 4 of sigma.

Transcriptional activities of the zinc finger protein Zac are differentially controlled by DNA binding

Zac encodes a zinc finger protein that promotes apoptosis and cell cycle arrest and is maternally imprinted. Here, we show that Zac contains transactivation and repressor activities and that these transcriptional activities are differentially controlled by DNA binding. Zac transactivation mapped to two distinct domains. One of these contained multiple repeats of the peptide PLE, which behaved as an autonomous activation unit. More importantly, we identified two related high-affinity DNA-binding sites which were differentially bound by seven Zac C(2)H(2) zinc fingers. Zac bound as a monomer through zinc fingers 6 and 7 to the palindromic DNA element to confer transactivation. In contrast, binding as a monomer to one half-site of the repeat element turned Zac into a repressor. Conversely, Zac dimerization at properly spaced direct and reverse repeat elements enabled transactivation, which strictly correlated with DNA-dependent and -independent contacts of key residues within the recognition helix of zinc finger 7. The later ones support specific functional connections between Zac DNA binding and transcriptional-regulatory surfaces. Both classes of DNA elements were identified in a new Zac target gene and confirmed that the zinc fingers communicate with the transactivation function. Together, our data demonstrate a role for Zac as a transcription factor in addition to its role as coactivator for nuclear receptors and p53.

Protein-protein and protein-DNA interactions of sigma70 region 4 involved in transcription activation by lambdacI

The cI protein of bacteriophage lambda (lambdacI) activates transcription from promoter P(RM) through an acidic patch on the surface of its DNA-binding domain. Genetic evidence suggests that this acidic patch stimulates transcription from P(RM) through contact with the C-terminal domain (region 4) of the sigma(70) subunit of Escherichia coli RNA polymerase. Here, we identify two basic residues in region 4 of sigma(70) that are critical for lambdacI-mediated activation of transcription from P(RM). On the basis of structural modeling, we propose that one of these sigma(70) residues, K593, facilitates the interaction between lambdacI and region 4 of sigma(70) by inducing a bend in the DNA upstream of the -35 element, whereas the other, R588, interacts directly with a critical acidic residue within the activating patch of lambdacI. Residue R588 of sigma(70) has been shown to play an important role in promoter recognition; our findings suggest that the R588 side-chain has a dual function at P(RM), facilitating the interaction of region 4 with the promoter -35 element and participating directly in the protein-protein interaction with lambdacI.

Flipping a genetic switch by subunit exchange

The bacteriophage T4 AsiA protein is a multifunctional protein that simultaneously acts as both a repressor and activator of gene expression during the phage life cycle. These dual roles with opposing transcriptional consequences are achieved by modification of the host RNA polymerase in which AsiA binds to conserved region 4 (SR4) of sigma(70), altering the pathway of promoter selection by the holoenzyme. The mechanism by which AsiA flips this genetic switch has now been revealed, in part, from the three-dimensional structure of AsiA and the elucidation of its interaction with SR4. The structure of AsiA is that of a novel homodimer in which each monomer is constructed as a seven-helix bundle arranged in four overlapping helix-loop-helix elements. Identification of the protein interfaces for both the AsiA homodimer and the AsiA-sigma(70) complex reveals that these interfaces are coincident. Thus, the AsiA interaction with sigma(70) necessitates that the AsiA homodimer dissociate to form an AsiA-SR4 heterodimer, exchanging one protein subunit for another to alter promoter choice by RNA polymerase.

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

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

A chimeric activator of transcription that uses two DNA-binding domains to make simultaneous contact with pairs of recognition sites

Many well-known transcriptional regulatory proteins are composed of at least two independently folding domains and, typically, only one of these is a DNA-binding domain. However, some transcriptional regulators have been described that have more than one DNA-binding domain. Regulators with a single DNA-binding domain often bind co-operatively to the DNA in homotypic or heterotypic combinations, and two or more DNA-binding domains of a single regulatory protein can also bind co-operatively to suitably positioned recognition sequences. Here, we examine the behaviour of a chimeric activator of transcription with two different DNA-binding domains, that of the bacteriophage lambda cI protein and that of the Escherichia coli cyclic AMP receptor protein. We show that these two DNA-binding moieties, when present in the same molecule, can bind co-operatively to a pair of cognate recognition sites located upstream of a test promoter, thereby permitting the chimera to function as a particularly strong activator of transcription from this promoter. Our results show how such a bivalent DNA-binding protein can be used to regulate transcription differentially from promoters that bear either one or both recognition sites.

Analyses of the effects that disease-causing missense mutations have on the structure and function of the winged-helix protein FOXC1

Five missense mutations of the winged-helix FOXC1 transcription factor, found in patients with Axenfeld-Rieger (AR) malformations, were investigated for their effects on FOXC1 structure and function. Molecular modeling of the FOXC1 forkhead domain predicted that the missense mutations did not alter FOXC1 structure. Biochemical analyses indicated that, whereas all mutant proteins correctly localize to the cell nucleus, the I87M mutation reduced FOXC1-protein levels. DNA-binding experiments revealed that, although the S82T and S131L mutations decreased DNA binding, the F112S and I126M mutations did not. However, the F112S and I126M mutations decrease the transactivation ability of FOXC1. All the FOXC1 mutations had the net effect of reducing FOXC1 transactivation ability. These results indicate that the FOXC1 forkhead domain contains separable DNA-binding and transactivation functions. In addition, these findings demonstrate that reduced stability, DNA binding, or transactivation, all causing a decrease in the ability of FOXC1 to transactivate genes, can underlie AR malformations.

Quorum sensing in Vibrio fischeri: analysis of the LuxR DNA binding region by alanine-scanning mutagenesis

LuxR is the transcriptional activator for quorum-sensing control of luminescence in Vibrio fischeri. A series of alanine-scanning mutants spanning a predicted helix-turn-helix region in the DNA binding domain of LuxR was constructed, and the activity of each of the LuxR mutant proteins in recombinant Escherichia coli was investigated. The region covered by the mutagenesis spanned residues 190 to 224. About half of the alanine-scanning mutants showed activities similar to that of the wild-type LuxR: at least two were positive-control mutants, four appeared to be defective in DNA binding, and several others were characterized as DNA binding affinity mutants. This analysis, taken together with information about other bacterial transcription factors, provides insights into amino acid residues in LuxR that are involved in DNA binding and transcriptional activation.

Mechanism for a transcriptional activator that works at the isomerization step

Transcriptional activators in prokaryotes have been shown to stimulate different steps in the initiation process including the initial binding of RNA polymerase (RNAP) to the promoter and a postbinding step known as the isomerization step. Evidence suggests that activators that affect initial binding can work by a cooperative binding mechanism by making energetically favorable contacts with RNAP, but the mechanism by which activators affect the isomerization step is unclear. A well-studied example of an activator that normally exerts its effect exclusively on the isomerization step is the bacteriophage lambda cI protein (lambdacI), which has been shown genetically to interact with the C-terminal region of the final sigma(70) subunit of RNAP. We show here that the interaction between lambdacI and final sigma can stimulate transcription even when the relevant portion of final sigma is transplanted to another subunit of RNAP. This activation depends on the ability of lambdacI to stabilize the binding of the transplanted final sigma moiety to an ectopic -35 element. Based on these and previous findings, we discuss a simple model that explains how an activator's ability to stabilize the binding of an RNAP subdomain to the DNA can account for its effect on either the initial binding of RNAP to a promoter or the isomerization step.

DNA sequence requirements for the activation of 434 P(RM) transcription by 434 repressor

A dimer of the 434 repressor bound at O(R)2 activated transcription initiation from P(RM) by contacting RNA polymerase. Although DNA-binding site mutations at either end of O(R)2 decreased the ability of the repressor to activate P(RM) transcription, mutations proximal to the promoter had a greater effect on transcription activation. Orienting a repressor subunit bearing the altered specificity Gln-28 --> Ala mutation to the halfsite of O(R)2 proximal to the P(RM) promoter decreased the repressor's ability to activate transcription initiation at 434 P(RM) to a much greater extent than if this subunit was placed in the O(R)2 half-site distal to P(RM). In addition to showing that the downstream (promoter proximal) subunit of the O(R)2-bound 434 repressor functions in activating 434 P(RM), the results indicated that DNA sequence-dependent conformational changes alter the efficiency with which the repressor activates P(RM) transcription. These unexpected findings highlight the importance of the structure of the repressor-DNA interface in activating transcription from P(RM).

Prolonged stationary-phase incubation selects for lrp mutations in Escherichia coli K-12

Evolution by natural selection occurs in cultures of Escherichia coli maintained under carbon starvation stress. Mutants of increased fitness express a growth advantage in stationary phase (GASP) phenotype, enabling them to grow and displace the parent as the majority population. The first GASP mutation was identified as a loss-of-function allele of rpoS, encoding the stationary-phase global regulator, sigma(S) (M. M. Zambrano, D. A. Siegele, M. A. Almirón, A. Tormo, and R. Kolter, Science 259:1757-1760, 1993). We now report that a second global regulator, Lrp, can also play a role in stationary-phase competition. We found that a mutant that took over an aged culture of an rpoS strain had acquired a GASP mutation in lrp. This GASP allele, lrp-1141, encodes a mutant protein lacking the critical glycine in the turn of the helix-turn-helix DNA-binding domain. The lrp-1141 allele behaves as a null mutation when in single copy and is dominant negative when overexpressed. Hence, the mutant protein appears to retain stability and the ability to dimerize but lacks DNA-binding activity. We also demonstrated that a lrp null allele generated by a transposon insertion has a fitness gain identical to that of the lrp-1141 allele, verifying that cells lacking Lrp activity have a competitive advantage during prolonged starvation. Finally, we tested by genetic analysis the hypothesis that the lrp-1141 GASP mutation confers a fitness gain by enhancing amino acid catabolism during carbon starvation. We found that while amino acid catabolism may play a role, it is not necessary for the lrp GASP phenotype, and hence the lrp GASP phenotype is due to more global physiological changes.

Crystal structure of the lambda repressor C-terminal domain provides a model for cooperative operator binding

Interactions between transcription factors bound to separate operator sites commonly play an important role in gene regulation by mediating cooperative binding to the DNA. However, few detailed structural models for understanding the molecular basis of such cooperativity are available. The c1 repressor of bacteriophage lambda is a classic example of a protein that binds to its operator sites cooperatively. The C-terminal domain of the repressor mediates dimerization as well as a dimer-dimer interaction that results in the cooperative binding of two repressor dimers to adjacent operator sites. Here, we present the x-ray crystal structure of the lambda repressor C-terminal domain determined by multiwavelength anomalous diffraction. Remarkably, the interactions that mediate cooperativity are captured in the crystal, where two dimers associate about a 2-fold axis of symmetry. Based on the structure and previous genetic and biochemical data, we present a model for the cooperative binding of two lambda repressor dimers at adjacent operator sites.

Mutually exclusive utilization of P(R) and P(RM) promoters in bacteriophage 434 O(R)

Establishment and maintenance of a lysogen of the lambdoid bacteriophage 434 require that the 434 repressor both activate transcription from the P(RM) promoter and repress transcription from the divergent P(R) promoter. Several lines of evidence indicate that the 434 repressor activates initiation of P(RM) transcription by occupying a binding site adjacent to the P(RM) promoter and directly contacting RNA polymerase. The overlapping architecture of the P(RM) and P(R) promoters suggests that an RNA polymerase bound at P(R) may repress P(RM) transcription initiation. Hence, part of the stimulatory effect of the 434 repressor may be relief of interference between RNA polymerase binding to the P(RM) promoter and to the P(R) promoter. Consistent with this proposal, we show that the repressor cannot activate P(RM) transcription if RNA polymerase binds at P(R) prior to addition of the 434 repressor. However, unlike the findings with the related lambda phage, formation of RNA polymerase promoter complexes at P(RM) and at P(R) apparently are mutually exclusive. We find that the RNA polymerase-mediated inhibition of repressor-stimulated P(RM) transcription requires the presence of an open complex at P(R). Taken together, these results indicate that establishment of an open complex at P(R) directly prevents formation of an RNA polymerase-P(RM) complex.

The coiled coil dimerization element of the yeast transcriptional activator Hap1, a Gal4 family member, is dispensable for DNA binding but differentially affects transcriptional activation

The heme activator protein Hap1 is a member of the yeast Gal4 family, which consists of transcription factors with a conserved Zn(2)Cys(6) cluster that recognizes a CGG triplet. Many members of the Gal4 family contain a coiled coil dimerization element and bind symmetrically to DNA as homodimers. However, Hap1 possesses two unique properties. First, Hap1 binds asymmetrically to a direct repeat of two CGG triplets. Second, Hap1 binds to two classes of DNA elements, UAS1/CYC1 and UAS/CYC7, and permits differential transcriptional activation at these sites. Here we determined the residues of the Hap1 dimerization domain critical for DNA binding and differential transcriptional activation. We found that the Hap1 dimerization domain is composed of functionally redundant elements that can substitute each other in DNA binding and transcriptional activation. Remarkably, deletion of the coiled coil dimerization element did not severely diminish DNA binding and transcriptional activation at UAS1/CYC1 but completely abolished transcriptional activation at UAS/CYC7. Furthermore, Ala substitutions in the dimerization element selectively diminished transcriptional activation at UAS/CYC7. These results strongly suggest that the coiled coil dimerization element is responsible for differential transcriptional activation at UAS1/CYC1 and UAS/CYC7 and for making contacts with a putative coactivator or part of the transcription machinery.

Cooperative interaction of CI protein regulates lysogeny of Lactobacillus casei by bacteriophage A2

The temperate bacteriophage A2 forms stable lysogens in Lactobacillus casei. The A2-encoded cI product (CI), which is responsible for maintaining the A2 prophage in the lysogenic state, has been purified. The CI protein, which is a monomer of 25.3 kDa in solution, specifically binds to a 153-bp DNA fragment that contains two divergent promoters, PL and PR. These promoters mediate transcription from cI and a putative cro, respectively. Three similar, although not identical, 20-bp inverted repeated DNA segments (operator sites O1, O2, and O3) were found in this segment. CI selectively interacts with O1, which is placed downstream from the transcription start point of the cro gene, and with O2 and O3, which overlap with the -35 region of the two promoters. Using a heterologous RNA polymerase, we have determined the transcription start points of PL and PR. CI exerts a negative effect on the in vitro transcription of PR by repositioning the RNA polymerase in a concentration-dependent manner. CI, when bound to O1 and O2, enhances the positioning of the RNA polymerase with the PL promoter. Our data indicate that the CI protein regulates the lytic and lysogenic pathways of the A2 phage.

The Oct-1 POU domain activates snRNA gene transcription by contacting a region in the SNAPc largest subunit that bears sequence similarities to the Oct-1 coactivator OBF-1

The RNA polymerases II and III snRNA gene promoters contain an octamer sequence as part of the enhancer and a proximal sequence element (PSE) as part of the core promoter. The octamer and the PSE bind the POU domain activator Oct-1 and the basal transcription factor SNAPc, respectively. Oct-1, but not Oct-1 with a single E7R mutation within the POU domain, binds cooperatively with SNAPc and, in effect, recruits SNAPc to the PSE. Here, we show that SNAPc recruitment is mediated by an interaction between the Oct-1 POU domain and a small region of the largest subunit of SNAPc, SNAP190. This SNAP190 region is strikingly similar to a region in the B-cell-specific Oct-1 coactivator, OBF-1, that is required for interaction with octamer-bound Oct-1 POU domain. The Oct-1 POU domain-SNAP190 interaction is a direct protein-protein contact as determined by the isolation of a switched specificity SNAP190 mutant that interacts with Oct-1 POU E7R but not with wild-type Oct-1 POU. We also show that this direct protein-protein contact results in activation of transcription. Thus, we have identified an activation target of a human activator, Oct-1, within its cognate basal transcription complex.

DNA-based positive control mutants in the binding site sequence of 434 repressor

As detected by chemical nuclease treatments, the conformation of the 434 repressor-DNA complex depends on the sequence of the bound DNA (Bell, A. C., and Koudelka, G. B. (1993) J. Mol. Biol. 234, 542-553). We show here that these DNA sequence-dependent conformational changes alter the efficiency with which the repressor activates transcription from 434 PRM. Several lines of evidence suggest that binding site sequence affects the repressor's ability to activate transcription by altering the accessibility of the activation surface on the repressor to RNA polymerase. The results presented here show that in addition to affecting transcription by altering the overall binding affinity of protein for DNA, DNA sequence may also modulate the activity of the DNA-bound protein.

Amino acid-amino acid contacts at the cooperativity interface of the bacteriophage lambda and P22 repressors

The bacteriophage lambda repressor and its relatives bind cooperatively to adjacent as well as artificially separated operator sites. This cooperativity is mediated by a protein-protein interaction between the DNA-bound dimers. Here we use a genetic approach to identify two pairs of amino acids that interact at the dimer-dimer interface. One of these pairs is nonconserved in the aligned sequences of the lambda and P22 repressors; we show that a lambda repressor variant bearing the P22 residues at these two positions interacts specifically with the P22 repressor. The other pair consists of a conserved ion pair; we reverse the charges at these two positions and demonstrate that, whereas the individual substitutions abolish the interaction of the DNA-bound dimers, these changes in combination restore the interaction of both lambdacI and P22c2 dimers.

Alterations in the GAL4 DNA-binding domain can affect transcriptional activation independent of DNA binding

The GAL4 protein belongs to a large class of fungal transcriptional activator proteins encoding within their DNA-binding domains (DBD) six cysteines that coordinate two atoms of zinc (the Zn2Cys6 domain). In an effort to characterize the interactions between the Zn2Cys6 class transcriptional activator proteins and their DNA-binding sites, we have replaced in the full-length GAL4 protein small regions of the Zn2Cys6 domain with the analogous regions of another Zn2Cys6 protein called PPR1 an activator of pyrimidine biosynthetic genes. Alterations between the first and third cysteines abolished binding to GAL4 (upstream activation sequence of GAL (UASG)) or PPR1 (upstream acitvation sequence of UAS) DNA-binding sites and severely reduced transcriptional activation in yeast. In contrast, alterations between the third and fourth cysteines had only minor effects on binding to UASG but led to substantial decreases in activation in both yeast and a mammalian cell line. In the crystal structure of the GAL4 DBD-UASG complex (Marmorstein, R., Carey, M., Ptashne, M., and Harrison, S. C. (1992) Nature 356, 408-414), this region is facing away from the DNA, making it likely that there exists within the GAL4 DBD an accessible domain important in activation.

FruR-mediated transcriptional activation at the ppsA promoter of Escherichia coli

The start site of transcription of the ppsA gene, whose expression is controlled by the regulatory protein FruR in Escherichia coli, was determined by primer extension of in vivo transcripts. The interactions of the ppsA promoter with either RNA polymerase or FruR factor were analysed by the base removal method. Our results indicate that: (i) the RNA polymerase binding site has a -10 extended module but lacks its -35 hexamer; (ii) FruR binds to a target DNA region centered around position -45.5 upstream of the ppsA gene. In addition, circular permutation analysis showed that, upon binding to its site, FruR induces a sharp bend of 120 degrees in the DNA helix, which suggests a crucial involvement of FruR-induced bending in ppsA promoter activation. Direct contacts between the upstream activating DNA and RNA polymerase were studied in an in vitro transcription assay by using reconstituted RNA polymerase mutants containing Ala substitutions in C-terminal domain of their alpha subunit. The alpha[L262A], alpha[R265A] and alpha[N268A] substitutions, which caused the most drastic reduction in the FruR-mediated activation of the ppsA promoter, had previously been shown to inhibit the upstream element-mediated activation at the rrnBP1 promoter.

Molecular characterization of a phage-inducible middle promoter and its transcriptional activator from the lactococcal bacteriophage phi31

An inducible middle promoter from the lactococcal bacteriophage phi31 was isolated previously by shotgun cloning an 888-bp fragment (P15A10) upstream of the beta-galactosidase (beta-Gal) gene (lacZ.st) from Streptococcus thermophilus (D. J. O'Sullivan, S. A. Walker, S. G. West, and T. R. Klaenhammer, Bio/Technology 14:82-87, 1996). The promoter showed low levels of constitutive beta-Gal activity which could be induced two- to threefold over baseline levels after phage infection. During this study, the fragment was subcloned and characterized to identify a smaller, tightly regulated promoter fragment which allowed no beta-Gal activity until after phage infection. This fragment, defined within nucleotides 566 to 888 (P(566-888); also called fragment 566-888), contained tandem, phage-inducible transcription start sites at nucleotides 703 and 744 (703/744 start sites). Consensus -10 regions were present upstream of both start sites, but no consensus -35 regions were identified for either start site. A transcriptional activator, encoded by an open reading frame (ORF2) upstream of the 703/744 start sites, was identified for P(566-888). ORF2 activated P(566-888) when provided in trans in Escherichia coli. In addition, when combined with pTRK391 (P15A10::lacZ.st) in Lactococcus lactis NCK203, an antisense ORF2 construct was able to retard induction of the phage-inducible promoter as measured by beta-Gal activity levels. Finally, gel shift assays showed that ORF2 was able to bind to promoter fragment 566-888. Deletion analysis of the region upstream from the tandem promoters identified a possible binding site for transcriptional activation of the phage promoters. The DNA-binding ability of ORF2 was eliminated upon deletion of part of this region, which lies centered approximately 35 bp upstream of start site 703. Deletion analysis and mutagenesis studies also elucidated a critical region downstream of the 703/744 start sites, where mutagenesis resulted in a two- to threefold increase in beta-Gal activity. With these improvements, the level of expression achieved by an explosive-expression strategy was elevated from 3,000 to 11,000 beta-Gal units within 120 min after induction.