The COOH-terminal domain of the RNA polymerase alpha subunit in transcriptional enhancement and deactivation at the bacteriophage T4 late promoter

Transcription activation by a sliding clamp

Transcription activation of bacteriophage T4 late genes is accomplished by a transcription activation complex containing RNA polymerase (RNAP), the promoter specificity factor gp55, the coactivator gp33, and a universal component of cellular DNA replication, the sliding clamp gp45. Although genetic and biochemical studies have elucidated many aspects of T4 late gene transcription, no precise structure of the transcription machinery in the process is available. Here, we report the cryo-EM structures of a gp55-dependent RNAP-promoter open complex and an intact gp45-dependent transcription activation complex. The structures reveal the interactions between gp55 and the promoter DNA that mediate the recognition of T4 late promoters. In addition to the σR2 homology domain, gp55 has a helix-loop-helix motif that chaperons the template-strand single-stranded DNA of the transcription bubble. Gp33 contacts both RNAP and the upstream double-stranded DNA. Gp45 encircles the DNA and tethers RNAP to it, supporting the idea that gp45 switches the promoter search from three-dimensional diffusion mode to one-dimensional scanning mode.

Transcription activation of late genes in T4 bacteriophage requires the promoter specificity factor gp55, the coactivator gp33 and the sliding clamp gp45. Here, the authors provide structural insights into gp45- dependent transcription activation by determining the cryo-EM structures of a gp55-dependent RNA polymerase (RNAP)-promoter open complex and of an intact gp45-dependent transcription activation complex.

Crystal structure of the bacteriophage T4 late-transcription coactivator gp33 with the β-subunit flap domain of Escherichia coli RNA polymerase

Activated transcription of the bacteriophage T4 late genes, which is coupled to concurrent DNA replication, is accomplished by an initiation complex containing the host RNA polymerase associated with two phage-encoded proteins, gp55 (the basal promoter specificity factor) and gp33 (the coactivator), as well as the DNA-mounted sliding-clamp processivity factor of the phage T4 replisome (gp45, the activator). We have determined the 3.0 Å-resolution X-ray crystal structure of gp33 complexed with its RNA polymerase binding determinant, the β-flap domain. Like domain 4 of the promoter specificity σ factor (σ(4)), gp33 interacts with RNA polymerase primarily by clamping onto the helix at the tip of the β-flap domain. Nevertheless, gp33 and σ(4) are not structurally related. The gp33/β-flap structure, combined with biochemical, biophysical, and structural information, allows us to generate a structural model of the T4 late promoter initiation complex. The model predicts protein/protein interactions within the complex that explain the presence of conserved patches of surface-exposed residues on gp33, and provides a structural framework for interpreting and designing future experiments to functionally characterize the complex.

Transcription of the T4 late genes

This article reviews the current state of understanding of the regulated transcription of the bacteriophage T4 late genes, with a focus on the underlying biochemical mechanisms, which turn out to be unique to the T4-related family of phages or significantly different from other bacterial systems. The activator of T4 late transcription is the gene 45 protein (gp45), the sliding clamp of the T4 replisome. Gp45 becomes topologically linked to DNA through the action of its clamp-loader, but it is not site-specifically DNA-bound, as other transcriptional activators are. Gp45 facilitates RNA polymerase recruitment to late promoters by interacting with two phage-encoded polymerase subunits: gp33, the co-activator of T4 late transcription; and gp55, the T4 late promoter recognition protein. The emphasis of this account is on the sites and mechanisms of actions of these three proteins, and on their roles in the formation of transcription-ready open T4 late promoter complexes.

Dissection of the bacteriophage T4 late promoter complex

Activated transcription of the bacteriophage T4 late genes is generated by a mechanism that stands apart from the common modalities of transcriptional regulation: the activator is gp45, the viral replisome's sliding clamp; two sliding-clamp-binding proteins, gp33 and gp55, replace the host RNA polymerase (RNAP) sigma subunit. We have mutagenized, reconfigured and selectively disrupted individual interactions of the sliding clamp with gp33 and gp55 and have monitored effects on transcription. The C-terminal sliding-clamp-binding epitopes of gp33 and gp55 are perfectly interchangeable, but the functions of these two RNAP-sliding clamp connections differ: only the gp33-gp45 linkage is essential for activation, while loss of the gp55-gp45 linkage impairs but does not abolish activation. Formation of transcription-ready promoter complexes by the sliding-clamp-activated wild-type T4 RNAP resists competition by high concentrations of the polyanion heparin. This avid formation of promoter complexes requires both linkages of the T4 late RNAP to the sliding clamp. Preopening the promoter compensates for loss of the gp55-gp45 but not the gp33-gp45 linkage. We interpret the relationship of these findings and our prior analysis to the common model of transcriptional initiation in bacteria in terms of two parallel pathways, with two RNAP holoenzymes and two DNA templates: (1) gp55-RNAP and the T4 late promoter execute basal transcription; (2) gp55-gp33-RNAP and the T4 late promoter with its mobile enhancer, the T4 sliding clamp, execute activated transcription. gp55 and gp33 perform sigma-like functions, gp55 in promoter recognition and gp33 (as well as gp55) in enhancer recognition. gp33 operates the switch between these two pathways by repressing basal transcription.

Bacteriophage-induced modifications of host RNA polymerase

Bacteriophages have developed an impressive array of ingenious mechanisms to modify bacterial host RNA polymerase to make it serve viral needs. In this review we summarize the current knowledge about two types of host RNA polymerase modifications induced by double-stranded DNA phages: covalent modifications and modifications through RNA polymerase-binding proteins. We interpret the biochemical and genetic data within the framework of a structure-function model of bacterial RNA polymerase and viral biology.

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.

Building a replisome from interacting pieces: sliding clamp complexed to a peptide from DNA polymerase and a polymerase editing complex

We have solved the crystal structures of the bacteriophage RB69 sliding clamp, its complex with a peptide essential for DNA polymerase interactions, and the DNA polymerase complexed with primer-template DNA. The editing complex structure shows a partially melted duplex DNA exiting from the exonuclease domain at an unexpected angle and significant changes in the protein structure. The clamp complex shows the C-terminal 11 residues of polymerase bound in a hydrophobic pocket, and it allows docking of the editing and clamp structures together. The peptide binds to the sliding clamp at a position identical to that of a replication inhibitor peptide bound to PCNA, suggesting that the replication inhibitor protein p21CIP1 functions by competing with eukaryotic polymerases for the same binding pocket on the clamp.

Sigma competition: the contest between bacteriophage T4 middle and late transcription

In bacterial transcription, diverse sigma-family promoter recognition proteins compete for a common RNA polymerase core. Bacteriophage T4 infection ultimately reduces this competition to a duel between activated viral middle and enhanced late transcription, involving two sigma proteins, two phage-encoded activator proteins and two phage-specific co-activators. This competition has been analyzed in vitro, and the relative abundances in T4-infected Escherichia coli of the participating proteins have been measured. Activated late transcription holds an advantage over activated middle transcription, especially at higher ionic strength. This advantage is further compounded by ADP-ribosylation of the RNA polymerase alpha subunits, and by the phage-specific, RNA polymerase core-bound RpbA subunit. The largest contribution to the middle-late competition is made by gp55, the late sigma factor, but not enough of gp55 is produced during T4 infection to shut off middle transcription by direct competition with sigma(70). AsiA, the originally identified anti-sigma protein is not a major determinant of middle-late competition.

Abortive initiation of transcription at a hybrid promoter. An analysis of the sliding clamp activator of bacteriophage T4 late transcription, and a comparison of the sigma70 and T4 gp55 promoter recognition proteins

Bacteriophage T4 late promoters are transcribed by an RNA polymerase holoenzyme comprising the Escherichia coli core, E, the phage gene 55-encoded promoter recognition subunit, gp55, and the gene 33-encoded co-activator, gp33. Transcriptional initiation is activated by the T4 gene 45-encoded sliding clamp, which is loaded on to DNA at enhancer-like sites by its clamp-loader. Correct initiation of transcription at late promoters in basal mode requires only RNA polymerase core and gp55 (E.gp55). Dinucleotide-primed abortive initiation of basal and activated T4 late transcription has been compared. Only the trinucleotide non-productive transcript is made at a high rate; all other short transcripts are made at rates of less than one molecule per productive transcript. Gp45 increases abortive trinucleotide synthesis along with productive transcription, although the proportion of productive transcripts is also elevated. Nevertheless, this increase accounts for only a small part of the activation of T4 late transcription that is generated by its activator and co-activator. The pattern of production of short transcripts differs subtly between basal and enhanced transcription, indicating that linking the RNA polymerase with its sliding clamp activator only generates minor changes in the transition from abortive to productive RNA chain elongation. The T4 late promoter is converted to a strong sigma70 promoter by inserting an appropriate -35 promoter element. A direct comparison at such a hybrid promoter shows sigma70 and gp55 generating qualitatively and quantitative different patterns of abortive initiation at the same start site.

Dual targets of a transcriptional activator that tracks on DNA

The sliding clamp of the bacteriophage T4 DNA polymerase, gp45, is also the proximal effector for activation of transcription of T4 late genes. We have identified the phage T4-encoded sigma factor gp55 and the co-activator gp33 as targets of gp45 in promoter complexes, and have shown that a conserved carboxy-terminal amino acid sequence of gp55 and gp33 is required for interaction with gp45. The respective contribution of each target-gp45 interaction to activation of transcription has been assessed by measuring promoter opening rates. The opening rate supported by interaction with both targets is far greater than the arithmetical sum of the separate contributions of each target, implying a synergistic activation of transcription through at least two separate interactions of the trimeric gp45.

The carboxyl terminus of the bacteriophage T4 DNA polymerase is required for holoenzyme complex formation

To further elucidate the mechanism and dynamics of bacteriophage T4 holoenzyme formation, a mutant polymerase in which the last six carboxyl-terminal amino acids are deleted, was constructed, overexpressed, and purified to homogeneity. The mutant polymerase, designated delta C6 exo-, is identical to wild-type exo- polymerase with respect to kcat, kpol, and dissociation constants for nucleotide and DNA substrate. However, unlike wild-type exo- polymerase, the delta C6 exo- polymerase is unable to interact with the 45 protein to form the stable holoenzyme. A synthetic polypeptide corresponding to the carboxyl terminus of the wild-type exo- polymerase was tested as an in vitro inhibitor of bacteriophage T4 DNA replication. Surprisingly, the peptide does not directly inhibit holoenzyme complex formation by disrupting the interaction of the polymerase with the 45 protein. On the contrary, the peptide appears to disrupt the interaction of the 44/62 protein with the 45 protein, suggesting that the 44/62 protein and the polymerase use the same site on the 45 protein for functional interactions. Data presented are discussed in terms of a model correlating the functionality of the carboxyl terminus of the polymerase for productive interactions with the 45 protein as well as in terms of the 45 protein concomitantly interacting with the 44/62 protein and polymerase.