The DNA-binding domain of the MotA transcription factor from bacteriophage T4 shows structural similarity to the TATA-binding protein

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.

Solution NMR and X-ray crystal structures of Pseudomonas syringae Pspto_3016 from protein domain family PF04237 (DUF419) adopt a "double wing" DNA binding motif

The protein Pspto_3016 is a 117-residue member of the protein domain family PF04237 (DUF419), which is to date a functionally uncharacterized family of proteins. In this report, we describe the structure of Pspto_3016 from Pseudomonas syringae solved by both solution NMR and X-ray crystallography at 2.5 Å resolution. In both cases, the structure of Pspto_3016 adopts a "double wing" α/β sandwich fold similar to that of protein YjbR from Escherichia coli and to the C-terminal DNA binding domain of the MotA transcription factor (MotCF) from T4 bacteriophage, along with other uncharacterized proteins. Pspto_3016 was selected by the Protein Structure Initiative of the National Institutes of Health and the Northeast Structural Genomics Consortium (NESG ID PsR293).

A basic/hydrophobic cleft of the T4 activator MotA interacts with the C-terminus of E.coli sigma70 to activate middle gene transcription

Transcriptional activation often employs a direct interaction between an activator and RNA polymerase. For activation of its middle genes, bacteriophage T4 appropriates Escherichia coli RNA polymerase through the action of two phage-encoded proteins, MotA and AsiA. Alone, AsiA inhibits transcription from a large class of host promoters by structurally remodelling region 4 of sigma(70), the primary specificity subunit of E. coli RNA polymerase. MotA interacts both with sigma(70) region 4 and with a DNA element present in T4 middle promoters. AsiA-induced remodelling is proposed to make the far C-terminus of sigma(70) region 4 accessible for MotA binding. Here, NMR chemical shift analysis indicates that MotA uses a 'basic/hydrophobic' cleft to interact with the C-terminus of AsiA-remodelled sigma(70), but MotA does not interact with AsiA itself. Mutations within this cleft, at residues K3, K28 and Q76, both impair the interaction of MotA with sigma(70) region 4 and MotA-dependent activation. Furthermore, mutations at these residues greatly decrease phage viability. Most previously described activators that target sigma(70) directly use acidic residues to engage a basic surface of region 4. Our work supports accumulated evidence indicating that 'sigma appropriation' by MotA and AsiA uses a fundamentally different mechanism to activate transcription.

Transcription regulation by bacteriophage T4 AsiA

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

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

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

Bacteriophage T4 genome

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

The MotA transcription factor from bacteriophage T4 contains a novel DNA-binding domain: the 'double wing' motif

MotA is a transcription factor from bacteriophage T4 that helps adapt the host Escherichia coli transcription apparatus to T4 middle promoters. We have determined the crystal structure of the C-terminal DNA-binding domain of MotA (MotCF) to 1.6 A resolution using multiwavelength, anomalous diffraction methods. The structure reveals a novel DNA-binding alpha/beta motif that contains an exposed beta-sheet surface that mediates interactions with the DNA. Independent biochemical experiments have shown that MotCF binds to one surface of a single turn of DNA through interactions in adjacent major and minor grooves. We present a model of the interaction in which beta-ribbons at opposite corners of the six-stranded beta-sheet penetrate the DNA grooves, and call the motif a 'double wing' to emphasize similarities to the 'winged-helix' motif. The model is consistent with data on how MotA functions at middle promoters, and provides an explanation for why MotA can form non-specific multimers on DNA.

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.

Binding of the bacteriophage T4 transcriptional activator, MotA, to T4 middle promoter DNA: evidence for both major and minor groove contacts

During infection, the bacteriophage T4 transcriptional activator MotA, the co-activator AsiA, and host RNA polymerase are needed to transcribe from T4 middle promoters. Middle promoters contain a -10 region recognized by the sigma(70)subunit of RNA polymerase and a MotA box centered at -30 that is bound by MotA. We have investigated how the loss or modification of base determinants within the MotA box sequence 5'TTTGCTTTA3' (positions -34 to -26 of a middle promoter) affects MotA function. Gel retardation assays with mutant MotA boxes are consistent with the idea that MotA uses minor groove contacts upstream and major groove contacts downstream of the center GC, and does not require any specific base feature at the C.G base-pair at position -30. In particular, the 5-methyl residue on the thymine residue at position -29, a major groove contact, contributes to MotA binding, while converting the T.A at -32 to a C. I base-pair, a change that affects the major but nor the minor groove, yields a MotA box that is similar to wild-type. However, methylation interference analyses indicate that neither the binding of MotA nor the binding of polymerase/MotA/AsiA to the middle promoter PuvsXis inhibited by premethylation of guanine and adenine residues, suggesting that binding does not require minor groove contact with any specific T.A base-pair. Using gel retardation analyses, we calculate an apparent dissociation constant of 130 nM for MotA binding to the wild-type MotA box. Previous work has shown that the N-terminal region of MotA is needed for an interaction between MotA and sigma(70). We suggest that this MotA-sigma(70)interaction helps to stabilize the relatively weak interaction of MotA with the -30 region of middle promoter DNA.

The activation domain of the MotA transcription factor from bacteriophage T4

Bacteriophage T4 encodes a transcription factor, MotA, that binds to the -30 region of middle-mode promoters and activates transcription by host RNA polymerase. We have solved the structure of the MotA activation domain to 2.2 A by X-ray crystallography, and have also determined its secondary structure by NMR. An area on the surface of the protein has a distinctive patch that is populated with acidic and hydrophobic residues. Mutations within this patch cause a defective T4 growth phenotype, arguing that the patch is important for MotA function. One of the mutant MotA activation domains was purified and analyzed by NMR, and the spectra clearly show that the domain is properly folded. The mutant full-length protein appears to bind DNA normally but is deficient in transcriptional activation. We conclude that the acidic/hydrophobic surface patch is specifically involved in transcriptional activation, which is reminiscent of eukaryotic acidic activation domains.

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

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

Three-dimensional structure of a DNA repair enzyme, 3-methyladenine DNA glycosylase II, from Escherichia coli

The three-dimensional structure of Escherichia coli 3-methyladenine DNA glycosylase II, which removes numerous alkylated bases from DNA, was solved at 2.3 A resolution. The enzyme consists of three domains: one alpha + beta fold domain with a similarity to one-half of the eukaryotic TATA box-binding protein, and two all alpha-helical domains similar to those of Escherichia coli endonuclease III with combined N-glycosylase/abasic lyase activity. Mutagenesis and model-building studies suggest that the active site is located in a cleft between the two helical domains and that the enzyme flips the target base out of the DNA duplex into the active-site cleft. The structure of the active site implies broad substrate specificity and simple N-glycosylase activity.

PCD/DCoH: more than a second molecular saddle

Two recent crystal structures of the tetrameric pterin-4 alpha-carbinolamine dehydratase (PCD)/dimerization cofactor of HNF-1 (DCoH) protein provide fresh insights into how this multifunctional enzyme/transcriptional coactivator works.

Old phage, new insights: two recently recognized mechanisms of transcriptional regulation in bacteriophage T4 development

The regulation of bacteriophage T4 middle and late gene expression involves previously unrecognized mechanisms. Middle transcription requires a DNA-binding transcriptional activator and a sigma 70-binding co-activator. The coupling of late transcription to DNA replication is effected by a DNA-tracking protein that is loaded onto DNA by an assembly factor at enhancer-like entry sites. Late transcription also requires an RNA polymerase core-binding co-activator. The co-activators of T4 middle and late transcription share the property of depressing unactivated, basal transcription.

The bacteriophage T4 middle promoter PuvsX: analysis of regions important for binding of the T4 transcriptional activator MotA and for activation of transcription

Bacteriophage T4 middle promoters, which are transcribed using phage-modified host RNA polymerase and the T4 transcriptional activator, MotA, match the host sigma 70 consensus sequence at -10, but they have a different consensus ((t/a)(t/a)TGCTT(t/c)A) (a MotA box) at -30. While the T4 middle promoter PuvsX has these -10 and -30 motifs, it also has matches to the MotA box at -35, -51, -70, and -87. We show that MotA binds to PuvsX DNA, footprinting a region that includes the MotA boxes at -30, -35, and -51. Very high levels of MotA are required for footprinting and gel-shift experiments, and protein-DNA complexes formed in the presence of both phage-modified polymerase and MotA are more resistant to HindIII cleavage than those formed with either protein alone. These results suggest that MotA-DNA interactions may be stabilized by phage-modified polymerase. Sequences between -18 and -38 are absolutely required for MotA activation of transcription, but sequences upstream of -38 are stimulatory, particularly when chloride instead of glutamate is the major anion. Our results dissect PuvsX into a core promoter, downstream of -38, which is required for MotA activation, and an upstream region that enhances transcription especially under conditions less favourable for protein-DNA interactions.