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

Building capacity for implementation-the KT Challenge

BACKGROUND

The KT Challenge program supports health care professionals to effectively implement evidence-based practices. Unlike other knowledge translation (KT) programs, this program is grounded in capacity building, focuses on health care professionals (HCPs), and uses a multi-component intervention. This study presents the evaluation of the KT Challenge program to assess the impact on uptake, KT capacity, and practice change.

METHODS

The evaluation used a mixed-methods retrospective pre-post design involving surveys and review of documents such as teams' final reports. Online surveys collecting both quantitative and qualitative data were deployed at four time points (after both workshops, 6 months into implementation, and at the end of the 2-year funded projects) to measure KT capacity (knowledge, skills, and confidence) and impact on practice change. Qualitative data was analyzed using a general inductive approach and quantitative data was analyzed using non-parametric statistics.

RESULTS

Participants reported statistically significant increases in knowledge and confidence across both workshops, at the 6-month mark of their projects, and at the end of their projects. In addition, at the 6-month check-in, practitioners reported statistically significant improvements in their ability to implement practice changes. In the first cohort of the program, of the teams who were able to complete their projects, half were able to show demonstrable practice changes.

CONCLUSIONS

The KT Challenge was successful in improving the capacity of HCPs to implement evidence-based practice changes and has begun to show demonstrable improvements in a number of practice areas. The program is relevant to a variety of HCPs working in diverse practice settings and is relatively inexpensive to implement. Like all practice improvement programs in health care settings, a number of challenges emerged stemming from the high turnover of staff and the limited capacity of some practitioners to take on anything beyond direct patient care. Efforts to address these challenges have been added to subsequent cohorts of the program and ongoing evaluation will examine if they are successful. The KT Challenge program has continued to garner great interest among practitioners, even in the midst of dealing with the COVID-19 pandemic, and shows promise for organizations looking for better ways to mobilize knowledge to improve patient care and empower staff. This study contributes to the implementation science literature by providing a description and evaluation of a new model for embedding KT practice skills in health care settings.

Introducing differential RNA-seq mapping to track the early infection phase for Pseudomonas phage ɸKZ

As part of the ongoing renaissance of phage biology, more phage genomes are becoming available through DNA sequencing. However, our understanding of the transcriptome architecture that allows these genomes to be expressed during host infection is generally poor. Transcription start sites (TSSs) and operons have been mapped for very few phages, and an annotated global RNA map of a phage – alone or together with its infected host – is not available at all. Here, we applied differential RNA-seq (dRNA-seq) to study the early, host takeover phase of infection by assessing the transcriptome structure of Pseudomonas aeruginosa jumbo phage ɸKZ, a model phage for viral genetics and structural research. This map substantially expands the number of early expressed viral genes, defining TSSs that are active ten minutes after ɸKZ infection. Simultaneously, we record gene expression changes in the host transcriptome during this critical metabolism conversion. In addition to previously reported upregulation of genes associated with amino acid metabolism, we observe strong activation of genes with functions in biofilm formation (cdrAB) and iron storage (bfrB), as well as an activation of the antitoxin ParD. Conversely, ɸKZ infection rapidly down-regulates complexes IV and V of oxidative phosphorylation (atpCDGHF and cyoABCDE). Taken together, our data provide new insights into the transcriptional organization and infection process of the giant bacteriophage ɸKZ and adds a framework for the genome-wide transcriptomic analysis of phage–host interactions.

Structural basis of σ appropriation

Bacteriophage T4 middle promoters are activated through a process called σ appropriation, which requires the concerted effort of two T4-encoded transcription factors: AsiA and MotA. Despite extensive biochemical and genetic analyses, puzzle remains, in part, because of a lack of precise structural information for σ appropriation complex. Here, we report a single-particle cryo-electron microscopy (cryo-EM) structure of an intact σ appropriation complex, comprising AsiA, MotA, Escherichia coli RNA polymerase (RNAP), σ70 and a T4 middle promoter. As expected, AsiA binds to and remodels σ region 4 to prevent its contact with host promoters. Unexpectedly, AsiA undergoes a large conformational change, takes over the job of σ region 4 and provides an anchor point for the upstream double-stranded DNA. Because σ region 4 is conserved among bacteria, other transcription factors may use the same strategy to alter the landscape of transcription immediately. Together, the structure provides a foundation for understanding σ appropriation and transcription activation.

The phage T4 MotA transcription factor contains a novel DNA binding motif that specifically recognizes modified DNA

During infection, bacteriophage T4 produces the MotA transcription factor that redirects the host RNA polymerase to the expression of T4 middle genes. The C-terminal 'double-wing' domain of MotA binds specifically to the MotA box motif of middle T4 promoters. We report the crystal structure of this complex, which reveals a new mode of protein-DNA interaction. The domain binds DNA mostly via interactions with the DNA backbone, but the binding is enhanced in the specific cognate structure by additional interactions with the MotA box motif in both the major and minor grooves. The linker connecting the two MotA domains plays a key role in stabilizing the complex via minor groove interactions. The structure is consistent with our previous model derived from chemical cleavage experiments using the entire transcription complex. α- and β-d-glucosyl-5-hydroxymethyl-deoxycytosine replace cytosine in T4 DNA, and docking simulations indicate that a cavity in the cognate structure can accommodate the modified cytosine. Binding studies confirm that the modification significantly enhances the binding affinity of MotA for the DNA. Consequently, our work reveals how a DNA modification can extend the uniqueness of small DNA motifs to facilitate the specificity of protein-DNA interactions.

Tetramethylpyrazine-Inducible Promoter Region from Rhodococcus jostii TMP1

An inducible promoter region, P_TTMP (tetramethylpyrazine [TTMP]), has been identified upstream of the tpdABC operon, which contains the genes required for the initial degradation of 2,3,5,6-tetramethylpyrazine in Rhodococcus jostii TMP1 bacteria. In this work, the promoter region was fused with the gene for the enhanced green fluorescent protein (EGFP) to investigate the activity of P_TTMP by measuring the fluorescence of bacteria. The highest promoter activity was observed when bacteria were grown in a nutrient broth (NB) medium supplemented with 5 mM 2,3,5,6-tetramethylpyrazine for 48 h. Using a primer extension reaction, two transcriptional start sites for tpdA were identified, and the putative −35 and −10 promoter motifs were determined. The minimal promoter along with two 15 bp long direct repeats and two 7 bp inverted sequences were identified. Also, the influence of the promoter elements on the activity of P_TTMP were determined using site-directed mutagenesis. Furthermore, P_TTMP was shown to be induced by pyrazine derivatives containing methyl groups in the 2- and 5-positions of the heterocyclic ring, in the presence of the LuxR family transcriptional activator TpdR.

The E. coli Global Regulator DksA Reduces Transcription during T4 Infection

Bacteriophage T4 relies on host RNA polymerase to transcribe three promoter classes: early (Pe, requires no viral factors), middle (Pm, requires early proteins MotA and AsiA), and late (Pl, requires middle proteins gp55, gp33, and gp45). Using primer extension, RNA-seq, RT-qPCR, single bursts, and a semi-automated method to document plaque size, we investigated how deletion of DksA or ppGpp, two E. coli global transcription regulators, affects T4 infection. Both ppGpp⁰ and ΔdksA increase T4 wild type (wt) plaque size. However, ppGpp⁰ does not significantly alter burst size or latent period, and only modestly affects T4 transcript abundance, while ΔdksA increases burst size (2-fold) without affecting latent period and increases the levels of several Pe transcripts at 5 min post-infection. In a T4motA^am infection, ΔdksA increases plaque size and shortens latent period, and the levels of specific middle RNAs increase due to more transcription from Pe’s that extend into these middle genes. We conclude that DksA lowers T4 early gene expression. Consequently, ΔdksA results in a more productive wt infection and ameliorates the poor expression of middle genes in a T4motA^am infection. As DksA does not inhibit Pe transcription in vitro, regulation may be indirect or perhaps requires additional factors.

Transcription regulation mechanisms of bacteriophages: recent advances and future prospects

Phage diversity significantly contributes to ecology and evolution of new bacterial species through horizontal gene transfer. Therefore, it is essential to understand the mechanisms underlying phage-host interactions. After initial infection, the phage utilizes the transcriptional machinery of the host to direct the expression of its own genes. This review presents a view on the transcriptional regulation mechanisms of bacteriophages, and its contribution to phage diversity and classification. Through this review, we aim to broaden the understanding of phage-host interactions while providing a reference source for researchers studying the regulation of phage transcription.

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

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

Direct activator/co-activator interaction is essential for bacteriophage T4 middle gene expression

The bacteriophage T4 AsiA protein is a bifunctional regulator that inhibits transcription from the major class of bacterial promoters and also serves as an essential co-activator of transcription from T4 middle promoters. AsiA binds the primary s factor in Escherichia coli, sigma(70), and modifies the promoter recognition properties of the sigma(70)-containing RNA polymerase(RNAP) holoenzyme. In its role as co-activator, AsiA directs RNAP to T4 middle promoters in the presence of the T4-encoded activator MotA. According to the current model for T4 middle promoter activation, AsiA plays an indirect role in stabilizing the activation complex by facilitating interaction between DNA-bound MotA and sigma(70). Here we show that AsiA also plays a direct role in T4 middle promoter activation by contacting the MotA activation domain. Furthermore,we show that interaction between AsiA and the beta-flap domain of RNAP is important for co-activation. Based on our findings, we propose a revised model for T4 middle promoter activation, with AsiA organizing the activation complex via three distinct protein-protein interactions.

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

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

Genetic diversity among five T4-like bacteriophages

BACKGROUND

Bacteriophages are an important repository of genetic diversity. As one of the major constituents of terrestrial biomass, they exert profound effects on the earth's ecology and microbial evolution by mediating horizontal gene transfer between bacteria and controlling their growth. Only limited genomic sequence data are currently available for phages but even this reveals an overwhelming diversity in their gene sequences and genomes. The contribution of the T4-like phages to this overall phage diversity is difficult to assess, since only a few examples of complete genome sequence exist for these phages. Our analysis of five T4-like genomes represents half of the known T4-like genomes in GenBank.

RESULTS

Here, we have examined in detail the genetic diversity of the genomes of five relatives of bacteriophage T4: the Escherichia coli phages RB43, RB49 and RB69, the Aeromonas salmonicida phage 44RR2.8t (or 44RR) and the Aeromonas hydrophila phage Aeh1. Our data define a core set of conserved genes common to these genomes as well as hundreds of additional open reading frames (ORFs) that are nonconserved. Although some of these ORFs resemble known genes from bacterial hosts or other phages, most show no significant similarity to any known sequence in the databases. The five genomes analyzed here all have similarities in gene regulation to T4. Sequence motifs resembling T4 early and late consensus promoters were observed in all five genomes. In contrast, only two of these genomes, RB69 and 44RR, showed similarities to T4 middle-mode promoter sequences and to the T4 motA gene product required for their recognition. In addition, we observed that each phage differed in the number and assortment of putative genes encoding host-like metabolic enzymes, tRNA species, and homing endonucleases.

CONCLUSION

Our observations suggest that evolution of the T4-like phages has drawn on a highly diverged pool of genes in the microbial world. The T4-like phages harbour a wealth of genetic material that has not been identified previously. The mechanisms by which these genes may have arisen may differ from those previously proposed for the evolution of other bacteriophage genomes.

Transcription and RNA processing during expression of genes preceding DNA ligase gene 30 in T4-related bacteriophages

Early gene expression in bacteriophage T4 is controlled primarily by the unique early promoters, while T4-encoded RegB endoribonuclease promotes degradation of many early messages contributing to the rapid shift of gene expression from the early to middle stages. The regulatory region for the genes clustered upstream of DNA ligase gene 30 of T4 was known to carry two strong early promoters and two putative RegB sites. Here, we present the comparative analysis of the regulatory events in this region of 16 T4-type bacteriophages. The regulatory elements for control of this gene cluster, such as rho-independent terminator, at least one early promoter, the sequence for stem-loop structure, and the RegB cleavage sites have been found to be conserved in the phages studied. Also, we present experimental evidence that the initial cleavage by RegB of phages TuIa and RB69 enables degradation of early phage mRNAs by the major Escherichia coli endoribonuclease, RNase E.

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.

The sequences and activities of RegB endoribonucleases of T4-related bacteriophages

The RegB endoribonuclease encoded by bacteriophage T4 is a unique sequence-specific nuclease that cleaves in the middle of GGAG or, in a few cases, GGAU tetranucleotides, preferentially those found in the Shine-Dalgarno regions of early phage mRNAs. In this study, we examined the primary structures and functional properties of RegB ribonucleases encoded by T4-related bacteriophages. We show that all but one of 36 phages tested harbor the regB gene homologues and the similar signals for transcriptional and post-transcriptional autogenous regulation of regB expression. Phage RB49 in addition to gpRegB utilizes Escherichia coli endoribonuclease E for the degradation of its transcripts for gene regB. The deduced primary structure of RegB proteins of 32 phages studied is almost identical to that of T4, while the sequences of RegB encoded by phages RB69, TuIa and RB49 show substantial divergence from their T4 counterpart. Functional studies using plasmid-phage systems indicate that RegB nucleases of phages T4, RB69, TuIa and RB49 exhibit different activity towards GGAG and GGAU motifs in the specific locations. We expect that the availability of the different phylogenetic variants of RegB may help to localize the amino acid determinants that contribute to the specificity and cleavage efficiency of this processing enzyme.