Bacteriophage T4 late gene expression: overlapping promoters direct divergent transcription of the base plate gene cluster

A dual-signal regulatory circuit activates transcription of a set of divergent operons in Salmonella typhimurium

We present a molecular mechanism for signal transduction that activates transcription of the SlyA regulon in Salmonella typhimurium. We demonstrate that SlyA mediates transcriptional activation in response to guanosine tetraphosphate, ppGpp, according to the following observations: (i) in vivo transcription of SlyA-dependent genes is repressed when ppGpp is absent; this transcription can be restored by overproducing SlyA; (ii) in vivo dimerization and binding of SlyA to the target promoter are facilitated in the presence of ppGpp; and (iii) in vitro SlyA binding to the target promoter is enhanced when ppGpp is supplemented. Thus, ppGpp must be the cytoplasmic component that stimulates SlyA regulatory function by interacting directly with this regulator in Salmonella. This signaling domain, integrated by the PhoP/PhoQ 2-component system that activates slyA transcription by sensing Mg(2+), forms feedforward loops that regulate chromosomal loci identified through a motif search over the S. typhimurium genome. Many such loci are divergent operons, each formed by 2 neighboring genes in which transcription of these 2 loci proceeds in opposite directions. Both genes, however, are controlled by PhoP and SlyA through a single shared PhoP box and SlyA box present in their intergenic regions. A substitution in either box sequence causes a simultaneous cessation of transcription of a divergent operon, pagD-pagC, equivalent to the phenotype in a phoP or slyA mutant. We also identified several chromosomal loci that possess pagC-type genes without the cognate pagD-type genes. Therefore, our results provide a molecular basis for the understanding of SlyA-dependent phenotypes associated with Salmonella virulence.

Post-transcriptional control of bacteriophage T4 gene 25 expression: mRNA secondary structure that enhances translational initiation

Secondary structure of the mRNA in the translational initiation region is an important determinant of translation efficiency. However, the secondary structures that enhance or facilitate translation initiation are rare. We have previously proposed that such structure may exist in the case of bacteriophage T4 gene 25 translational initiation region, which contains three potential Shine-Dalgarno sequences (SD1, SD2, and SD3) with a spacing of 8, 17, and 27 nucleotides from the initiation codon of this gene, respectively. We now present results that clearly demonstrate the existence of a hairpin structure that includes SD1 and SD2 sequences and brings the SD3, the most typical of these Shine-Dalgarno sequences, to a favourable spacing with the initiation codon of gene 25. Using a phage T7 expression system, we show that mutations that prevent the formation of hairpin structure or eliminate the SD3 sequence result in a decreased level of gp25 synthesis. Double mutation in base-pair V restores the level of gene 25 expression that was decreased by either of the two mutations (C-to-G and G-to-C) alone, as predicted by an effect attributable to mRNA secondary structure. We introduced the mutations into the bacteriophage T4 by plasmid-phage recombination. Changes in the plaque and burst sizes of T4 mutants, carrying single and double mutations in the translational initiation region of gene 25, strongly suggest that the predicted mRNA secondary structure controls (enhances) the level of gene 25 expression in vivo. Hybridization of total cellular RNA with a gene 25 specific probe indicated that secondary structure or mutations in the translational initiation region do not notably affect the 25 mRNA stability. Immunoblot analysis of gp25 in Escherichia coli cells infected by T4 mutants showed that mRNA secondary structure increases the level of gp25 synthesis by three- to fourfold. Since the secondary structure increases the level of gp25 synthesis and does not affect mRNA stability, we conclude that this structure enhances translation initiation. We discuss some features of two secondary structures in the translational initiation regions of T4 genes 25 and 38.

Bacteriophage T4 gene 28

The complete nucleotide sequence of bacteriophage T4D gene 28 has been determined. Gene 28 product is a structural component of the viral baseplate for which an enzymatic activity has also been proposed.

Transcriptional analysis of the Chlamydia trachomatis plasmid pCT identifies temporally regulated transcripts, anti-sense RNA and sigma 70-selected promoters

We analysed transcription of the DNA region immediately downstream of the origin of replication in the chlamydial plasmid pCT. This region comprises two convergent open reading frames (ORF7, ORF8), encoding putative polypeptides that are homologous to each other and with C-terminal domains typical of the phage integrase family of proteins. Northern blot and RNA 5' end mapping analyses indicated that both ORFs were transcribed in the late phase of the chlamydial replicative cycle. RNA mapping showed the presence of a transcript starting 31 nucleotides (nt) before the ATG start codon of ORF7, and two temporally regulated transcripts starting 59 and 89 nt upstream of the ATG start codon of ORF8. Two abundant RNA species of 225 and 415 nt were also identified as overlapping anti-sense transcripts (AS-RNAs), complementary to the 3' end of ORF8 mRNA, with identical 5' ends but different 3' ends. In vitro and in vivo experiments in Escherichia coli showed that the sigma 70-RNA polymerase complex was capable of initiating RNA synthesis at the same sites as observed in Chlamydia trachomatis for ORF7 and AS-RNA transcripts, but was not able to transcribe ORF8. In accord with this, sequences at -10 and -35 nt upstream of the RNA 5' ends resemble sigma 70 consensus promoters in the case of ORF7 and AS, but not in the case of the two ORF8 transcripts. Therefore, transcription of ORF7 and ORF8 is controlled by different types of promoters.(ABSTRACT TRUNCATED AT 250 WORDS)

Cloning, sequence, and overexpression of bacteriophage T4 gene 51

The nucleotide sequence of the 907-bp XbaI-EcoRV T4 DNA fragment containing gene 51 is presented. The sequence of gene 51 predicts a 249 amino acid peptide with an M(r) of 29387 and a pl of 6.34. We have cloned and overexpressed this gene in the T7 RNA polymerase system. The observed molecular mass of gp51 is in agreement with the sequence data. We also show that the low level of gene 51 expression usually seen is caused by an RNA stem-loop structure in the region between genes 26 and 51. In addition, discrepancies with the sequence published by other authors are indicated.

A transcriptional enhancer whose function imposes a requirement that proteins track along DNA

Transcriptional regulation of the bacteriophage T4 late genes requires the participation of three DNA polymerase accessory proteins that are encoded by T4 genes 44, 62, and 45, and that act at an enhancer-like site. Transcriptional activation by these DNA replication proteins also requires the function of an RNA polymerase-bound coactivator protein that is encoded by T4 gene 33 and a promoter recognition protein that is encoded by T4 gene 55. Transcriptional activation in DNA constructs, in which the enhancer and a T4 late promoter can be segregated on two rings of a DNA catenane, has now been analyzed. The ability of an interposed DNA-binding protein to affect communication between the enhancer and the promoter was also examined. Together, these experiments demonstrate that this transcription-activating signal is conveyed between its enhancer and a T4 late promoter by a DNA-tracking mechanism. Alternative activation mechanisms relying entirely on through-space interactions of enhancer-bound and promoter-bound proteins are excluded.

An internal AUU codon initiates a smaller peptide encoded by bacteriophage T4 baseplate gene 26

Bacteriophage T4 baseplate gene 26 codes for two in-frame overlapping peptides with identical C-terminal regions. By site-directed mutagenesis we have now determined that an internal AUU, codon 114 of gene 26, is used as the initiation codon for the synthesis of a smaller peptide (gp26*). Thus gene 26* gives rise to a peptide of 95 amino acid residues with an Mr of 10,873, while the complete gene 26 encodes a peptide of 208 amino acid residues of M(r) 23,880. Expression of gene 26* is shown to depend on the RNA secondary structure in the translational initiation region of this gene.

The bvg-dependent promoters show similar behaviour in different Bordetella species and share sequence homologies

The expression of the virulence-associated genes in Bordetella species is co-ordinately regulated by the gene products encoded by the bvg locus. In Bordetella pertussis the expression of this locus is regulated by the P1, P2, P3 and P4 promoters which are located in a 350 bp DNA fragment also containing the PFHA promoter. Here we report the transcriptional regulation of the bvg locus and the fha gene in Bordetella parapertussis and a sequence analysis of the bvg-regulated promoters. The Pp1, Pp2, Pp4 and PpFHA promoters are indistinguishable, both in transcription initiation sites and environmental regulation, from the corresponding promoters of B. pertussis, while the Pp3 promoter is not active. Sequence homologies from nine bvg-regulated promoters show a conserved dinucleotide, 5'-TG-3', at approximately one turn of helix upstream of the -10 5'-A.AaTat-3' region, and a 5'-TTTCC-3' sequence in the -90 region. Since the nucleotide sequence of the inactive Pp3 promoter shows several base substitutions with respect to the found sequence homologies, it is likely that some of these bases play an essential role in promoter activity.

Two bacteriophage T4 base plate genes (25 and 26) and the DNA repair gene uvsY belong to spatially and temporally overlapping transcription units

The bacteriophage T4 DNA recombination-repair gene uvsY located at or near an origin of DNA replication and adjacent to the late base plate genes 25 and 26. Our present results reveal a complex transcription pattern in the region encompassing these genes. Most significantly, uvsY and two ORFs, downstream of it, all of which are transcribed from a middle promoter before the onset of DNA replication, are also part of a larger late transcription unit which includes the base plate genes 25 and 26. The late genes 25 and 26 are transcribed not only late, but also early from one or several early promoters further upstream. Translation, however, is inhibited by secondary structures which sequester the ribosome binding site in the early transcript. We discuss possible advantages of these transcriptional patterns for T4 DNA recombination, replication, and repair. The predicted and in vivo-expressed 23.9-kDa product of gene 26 is smaller than the reported size of gene 26 protein isolated from base plates, suggesting that nascent gp26 might be processed to a larger protein during assembly.

Synthesis, phosphorylation, and nuclear localization of human papillomavirus E7 protein in Schizosaccharomyces pombe

The complete E7 protein-encoding open reading frame of human papillomavirus type 16 (HPV-16) was expressed in the fission yeast Schizosaccharomyces pombe, under the control of a cloned yeast promoter. The HPV-16 E7 protein synthesized in S. pombe is a 17-kDa phosphoprotein which is recognized by anti-E7 antibodies (raised in rabbits against E7 fusion protein produced in Escherichia coli). The mobility during sodium dodecyl sulfate-polyacrylamide-gel electrophoresis of native E7 phosphoprotein synthesized in S. pombe is identical to that of the E7 phosphoprotein immunoprecipitated from human CaSki cells. Immunofluorescence staining showed that HPV-16 E7 phosphoprotein is localized in the nuclei of transformed S. pombe. These results indicate that E7 protein synthesized by S. pombe is apparently indistinguishable from HPV-16 E7 protein synthesized in higher eukaryotic cells expressing genes of HPV-16, and also that the phosphorylated, nuclear HPV-16 E7 protein is synthesized in S. pombe in a form compatible with its biological activity.

Expression and regulation of genes coding for three bacteriophage T4 tail tube-associated proteins

The assembly and length regulation of the tail tube of bacteriophage T4 requires the function of three proteins: gp29, 48, and 54. Six copies of each protein are found in the completed tail, and the genes for these proteins are adjacent on the T4 genome. Evidence is presented here that gp54 is also a tail tube-associated protein that remains bound to the tail tube after the baseplate is removed by guanidine hydrochloride, suggesting that all three proteins interact structurally. There is a strong polar effect of translation termination mutants in gene 48 upon the expression of the adjacent gene 54, in cis-trans tests. Gene dosage experiments that assay the in vivo expression of these genes show that only gene 48 is expressed at slightly higher than stoichiometric levels during T4 infection. Genes 48 and 54 were placed under the control of a T7 promoter and the corresponding proteins identified. When a frameshift mutation was introduced into gene 48, neither gp48 nor gp54 was made. Transcriptional termination was not the explanation of this result because genes distal to 48 and 54 in the plasmid were expressed. These data suggest that expression of genes 48 and 54 is translationally coupled.