New control elements of bacteriophage T4 pre-replicative transcription

Systemic Expression, Purification, and Initial Structural Characterization of Bacteriophage T4 Proteins Without Known Structure Homologs

Bacteriophage T4 of Escherichia coli is one of the most studied phages. Research into it has led to numerous contributions to phage biology and biochemistry. Coding about 300 gene products, this double-stranded DNA virus is the best-understood model in phage study and modern genomics and proteomics. Ranging from viral RNA polymerase, commonly found in phages, to thymidylate synthase, whose mRNA requires eukaryotic-like self-splicing, its gene products provide a pool of fine examples for phage research. However, there are still up to 130 gene products that remain poorly characterized despite being one of the most-studied model phages. With the recent advancement of cryo-electron microscopy, we have a glimpse of the virion and the structural proteins that present in the final assembly. Unfortunately, proteins participating in other stages of phage development are absent. Here, we report our systemic analysis on 22 of these structurally uncharacterized proteins, of which none has a known homologous structure due to the low sequence homology to published structures and does not belong to the category of viral structural protein. Using NMR spectroscopy and cryo-EM, we provided a set of preliminary structural information for some of these proteins including NMR backbone assignment for Cef. Our findings pave the way for structural determination for the phage proteins, whose sequences are mainly conserved among phages. While this work provides the foundation for structural determinations of proteins like Gp57B, Cef, Y04L, and Mrh, other in vitro studies would also benefit from the high yield expression of these proteins.

Overexpression of the Bacteriophage T4 motB Gene Alters H-NS Dependent Repression of Specific Host DNA

The bacteriophage T4 early gene product MotB binds tightly but nonspecifically to DNA, copurifies with the host Nucleoid Associated Protein (NAP) H-NS in the presence of DNA and improves T4 fitness. However, the T4 transcriptome is not significantly affected by a motB knockdown. Here we have investigated the phylogeny of MotB and its predicted domains, how MotB and H-NS together interact with DNA, and how heterologous overexpression of motB impacts host gene expression. We find that motB is highly conserved among Tevenvirinae. Although the MotB sequence has no homology to proteins of known function, predicted structure homology searches suggest that MotB is composed of an N-terminal Kyprides-Onzonis-Woese (KOW) motif and a C-terminal DNA-binding domain of oligonucleotide/oligosaccharide (OB)-fold; either of which could provide MotB’s ability to bind DNA. DNase I footprinting demonstrates that MotB dramatically alters the interaction of H-NS with DNA in vitro. RNA-seq analyses indicate that expression of plasmid-borne motB up-regulates 75 host genes; no host genes are down-regulated. Approximately 1/3 of the up-regulated genes have previously been shown to be part of the H-NS regulon. Our results indicate that MotB provides a conserved function for Tevenvirinae and suggest a model in which MotB functions to alter the host transcriptome, possibly by changing the association of H-NS with the host DNA, which then leads to conditions that are more favorable for infection.

The Bacteriophage T4 MotB Protein, a DNA-Binding Protein, Improves Phage Fitness

The lytic bacteriophage T4 employs multiple phage-encoded early proteins to takeover the Escherichia coli host. However, the functions of many of these proteins are not known. In this study, we have characterized the T4 early gene motB, located in a dispensable region of the T4 genome. We show that heterologous production of MotB is highly toxic to E. coli, resulting in cell death or growth arrest depending on the strain and that the presence of motB increases T4 burst size 2-fold. Previous work suggested that motB affects middle gene expression, but our transcriptome analyses of T4 motB^am vs. T4 wt infections reveal that only a few late genes are mildly impaired at 5 min post-infection, and expression of early and middle genes is unaffected. We find that MotB is a DNA-binding protein that binds both unmodified host and T4 modified [(glucosylated, hydroxymethylated-5 cytosine, (GHme-C)] DNA with no detectable sequence specificity. Interestingly, MotB copurifies with the host histone-like proteins, H-NS and StpA, either directly or through cobinding to DNA. We show that H-NS also binds modified T4 DNA and speculate that MotB may alter how H-NS interacts with T4 DNA, host DNA, or both, thereby improving the growth of the phage.

Classification of Myoviridae bacteriophages using protein sequence similarity

Background

We advocate unifying classical and genomic classification of bacteriophages by integration of proteomic data and physicochemical parameters. Our previous application of this approach to the entirely sequenced members of the Podoviridae fully supported the current phage classification of the International Committee on Taxonomy of Viruses (ICTV). It appears that horizontal gene transfer generally does not totally obliterate evolutionary relationships between phages.

Results

CoreGenes/CoreExtractor proteome comparison techniques applied to 102 Myoviridae suggest the establishment of three subfamilies (Peduovirinae, Teequatrovirinae, the Spounavirinae) and eight new independent genera (Bcep781, BcepMu, FelixO1, HAP1, Bzx1, PB1, phiCD119, and phiKZ-like viruses). The Peduovirinae subfamily, derived from the P2-related phages, is composed of two distinct genera: the "P2-like viruses", and the "HP1-like viruses". At present, the more complex Teequatrovirinae subfamily has two genera, the "T4-like" and "KVP40-like viruses". In the genus "T4-like viruses" proper, four groups sharing >70% proteins are distinguished: T4-type, 44RR-type, RB43-type, and RB49-type viruses. The Spounavirinae contain the "SPO1-"and "Twort-like viruses."

Conclusion

The hierarchical clustering of these groupings provide biologically significant subdivisions, which are consistent with our previous analysis of the Podoviridae.

RNA processing and decay in bacteriophage T4

Bacteriophage T4 is the archetype of virulent phage. It has evolved very efficient strategies to subvert host functions to its benefit and to impose the expression of its genome. T4 utilizes a combination of host and phage-encoded RNases and factors to degrade its mRNAs in a stage-dependent manner. The host endonuclease RNase E is used throughout the phage development. The sequence-specific, T4-encoded RegB endoribonuclease functions in association with the ribosomal protein S1 to functionally inactivate early transcripts and expedite their degradation. T4 polynucleotide kinase plays a role in this process. Later, the viral factor Dmd protects middle and late mRNAs from degradation by the host RNase LS. T4 codes for a set of eight tRNAs and two small, stable RNA of unknown function that may contribute to phage virulence. Their maturation is assured by host enzymes, but one phage factor, Cef, is required for the biogenesis of some of them. The tRNA gene cluster also codes for a homing DNA endonuclease, SegB, responsible for spreading the tRNA genes to other T4-related phage.

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.

Recognition and specific degradation of bacteriophage T4 mRNAs

Gene 61.5 of bacteriophage T4 has a unique role in gene expression. When this gene is mutated, mRNAs of many late genes are rapidly degraded, resulting in late-gene silencing. Here, we characterize an extragenic suppressor, ssf5, of a gene 61.5 mutation. ssf5 was found to be an amber mutation in motA, which encodes a transcription activator for T4 middle genes. When this gene is mutated, both degradation and specific cleavage of late-gene mRNA is induced after a delay, as exemplified by soc mRNA. Consequently, partial late-gene expression occurs. In an ssf5 genetic background, a gene 61.5 mutation exhibits a novel phenotype: in contrast to late-gene mRNA, middle-gene mRNA is stabilized and the expression of middle genes is prolonged. This is attributable to an activity of gene 61.5 specific for degradation of middle-gene mRNA. The degradation of middle-gene mRNA in the presence of a normal gene 61.5 appears in parallel with the degradation of late-gene mRNA in its absence. This observation suggests that the mRNA-degrading activity that silences late genes in cells infected with a gene 61.5 mutant is targeted to middle-gene mRNA when gene 61.5 is wild type. These results and the results obtained in the presence of a normal motA gene suggest that gene 61.5 protein functions to discriminate mRNAs for degradation in a stage-dependent manner.

The bacteriophage T4 anti-sigma factor AsiA is not necessary for the inhibition of early promoters in vivo

Bacteriophage T4 early promoters are utilized immediately after infection and are abruptly turned off 2-3 min later (at 30 degrees C) when the middle promoters are activated. The viral early protein AsiA has been suspected to bring about this transcriptional switch: not only does it activate transcription at middle promoters in vivo and in vitro but it also shows potent anti-sigma70 activity in vitro, suggesting that it is responsible for the shut-off of early transcription. We show here that after infection with a phage deleted for the asiA gene the inhibition of early transcription occurs to the same extent and with the same kinetics as in a wild-type infection. Thus, another AsiA-independent circuit efficiently turns off early transcription. The association of a mutation in asiA with a mutation in mod, rpbA, motA or motB has no effect on the inhibition of early promoters, showing that none of these phage-encoded transcriptional regulators is necessary for AsiA-independent shut-off. It is not known whether AsiA is able to inhibit early promoters in vivo, but host transcription is strongly inhibited in vivo upon induction of AsiA from a multicopy plasmid.

Characterisation of the bacteriophage T4 comC alpha 55.6 and comCJ mutants. A possible role in an antitermination process

We have performed a new screen for T4 mutants (comC) that overcome the phage growth restriction caused by the Escherichia coli rho/tabC mutants. We show that one such mutant (comCJ) identifies a different gene from that identified by canonical comC mutants. We compare the regulation of T4 prereplicative transcription in a rho/tabC mutant infected by T4 wild-type, by a canonical comC mutant (comC alpha 55.6) and by comCJ. The transcription rates of the two prereplicative genes 39 and 43 is depressed in a T4 wild-type infected tabC host mutant. When comC alpha 55.6 and/or comCJ single and double mutants are the infecting phages, transcription of genes 39 and 43 is resumed to different extents; in particular, in the double mutant infections there appears to be a synergistic effect on transcription. Furthermore, we find that the comC alpha 55.6 phage mutant affects the transcription rate of the gene rIIA in a wild-type host.

Role of MotA transcription factor in bacteriophage T4 DNA replication

At least two bacteriophage T4 replication origins, ori(uvsY) and ori(34), contain a T4 middle-mode promoter that is necessary for origin function. We wanted to analyze the requirement of these two replication origins for the MotA protein, which is the phage-encoded activator of middle-mode promoters. To ensure the complete absence of MotA protein, we deleted the motA gene from the T4 genome. Unexpectedly, the deletion mutant was not viable unless the MotA protein was provided from a recombinant plasmid. Therefore, MotA is an essential protein for T4 growth. The motA delta mutation reduced the synthesis of several proteins that are encoded by genes with middle-mode promoters, delayed and reduced the synthesis of late proteins, and substantially reduced phage genomic replication. The motA delta mutation also reduced the replication of an ori(uvsY)-containing plasmid and virtually abolished replication of an ori(34)-containing plasmid. The replication defects of the two origins correlated with transcriptional defects: the motA delta mutation modestly reduced transcription from the plasmid-borne ori(uvsY) promoter and strongly reduced transcription from the ori(34) promoter. These results provide strong evidence that MotA protein is normally involved in origin-dependent replication. However, MotA is not required for origin-directed replication as long as transcription can occur from the origin promoter.

Sequence and characterization of the bacteriophage T4 comC alpha gene product, a possible transcription antitermination factor

We have sequenced a 1,340-bp region of the bacteriophage T4 DNA spanning the comC alpha gene, a gene which has been implicated in transcription antitermination. We show that comC alpha, identified unambiguously by sequencing several missense and nonsense mutations within the gene, codes for an acidic polypeptide of 141 residues, with a predicted molecular weight of 16,680. We have identified its product on one- and two-dimensional gel systems and found that it migrates abnormally as a protein with a molecular weight of 22,000. One of the missense mutations (comC alpha 803) is a glycine-to-arginine change, and the resulting protein exhibits a substantially faster electrophoretic mobility. The ComC alpha protein appears immediately after infection. Its rate of synthesis is maximum around 2 to 3 min postinfection (at 37 degrees C) and then starts to decrease slowly. Some residual biosynthesis is still detectable during the late period of phage development.

Nucleotide sequence and control of transcription of the bacteriophage T4 motA regulatory gene

A 2116bp segment of the bacteriophage T4 genome encompassing the motA regulatory gene has been sequenced. In addition to motA, five open reading frames were identified in the direction of early transcription. The motA gene encodes a basic protein of 211 amino acids with a predicted molecular weight of 23,559. Measurements of the rate of transcription of motA showed that the promoter of this gene is turned off after only 2 min of T4 development. This early promoter presents a structure which is richer in information than that of a classical constitutive Escherichia coli promoter. In addition to containing conserved sequences centred at -10 and -35, this promoter shares extensive homologies with other subgroups of early promoters in regions centred at +3 and at -55. We discuss the possible role of these different sequence determinants.

Impaired expression of certain prereplicative bacteriophage T4 genes explains impaired T4 DNA synthesis in Escherichia coli rho (nusD) mutants

The Escherichia coli rho 026 mutation that alters the transcription termination protein Rho prevents growth of wild-type bacteriophage T4. Among the consequences of this mutation are delayed and reduced T4 DNA replication. We show that these defects can be explained by defective synthesis of certain T4 replication-recombination proteins. Expression of T4 gene 41 (DNA helicase/primase) is drastically reduced, and expression of T4 genes 43 (DNA polymerase), 30 (DNA ligase), 46 (recombination nuclease), and probably 44 (DNA polymerase-associated ATPase) is reduced to a lesser extent. The compensating T4 mutation goF1 partially restores the synthesis of these proteins and, concomitantly, the synthesis of T4 DNA in the E. coli rho mutant. From analyzing DNA synthesis in wild-type and various multiply mutant T4 strains, we infer that defective or reduced synthesis of these proteins in rho 026-infected cells has several major effects on DNA replication. It impairs lagging-strand synthesis during the primary mode of DNA replication; it delays and depresses recombination-dependent (secondary mode) initiation; and it inhibits the use of tertiary origins. All three T4 genes whose expression is reduced in rho 026 cells and whose upstream sequences are known have a palindrome containing a CUUCGG sequence between the promoter(s) and ribosome-binding site. We speculate that these palindromes might be important for factor-dependent transcription termination-antitermination during normal T4 development. Our results are consistent with previous proposals that the altered Rho factor of rho 026 may cause excessive termination because the transcription complex does not interact normally with a T4 antiterminator encoded by the wild-type goF gene and that the T4 goF1 mutation restores this interaction.

Transcriptional activation of bacteriophage T4 middle promoters by the motA protein

Transcriptional activation of middle genes in bacteriophage T4 requires the phage-encoded motA protein. Many middle genes are involved in deoxyribonucleotide biosynthesis and phage DNA replication. In the absence of motA, the gene products that are required for DNA synthesis are transcribed from other, upstream promoters. Using primer extension sequencing on RNA templates isolated from T4 motA+ and motA- infected cells, we have characterized 14 motA-dependent transcripts. The T4 middle promoters have a consensus sequence of nine base-pairs, (a/t)(a/t)TGCTT(t/c)A, spaced 11 to 13 nucleotides away from the Escherichia coli--10 consensus sequence, TAnnnT. The motA protein also can act as a transcriptional repressor for at least one early gene. Furthermore, the phage-encoded motA protein can activate in trans a middle promoter resident on a plasmid.

The region of phage T4 genes 34, 33 and 59: primary structures and organization on the genome

The product of gene 33 is essential for the regulation of late transcription and gene product 59 is required in recombination, DNA repair and replication. The exact functions of both proteins are not known. Restriction fragments spanning the genomic area of genes 33 and 59 have been cloned into phage M13 and a 4.9 kb nucleotide sequence has been determined. Translation of the DNA sequence predicted that gp33 contains 112 amino acids with a mol.wt. of 12.816 kd while gp59 is composed of 217 amino acids adding up to a mol.wt. of 25.967 kd. The genomic area studied here also contains 3 open reading frames of genes not identified to date and it is thought to include the NH2-terminal part of g34. One of the open reading frames seems to code for the 10 kd protein, probably involved in the regulation of transcription of bacteriophage T4. This protein is predicted to consist of 89 amino acid residues with a mol.wt. of 10.376 kd. Gene 33 and the gene for the 10 kd protein were cloned separately on high expression vectors resulting in over-production of the two proteins.