Regulation of the synthesis of bacteriophage T4 gene 32 protein

The synthesis of T4 gene 32 product (P32) has been followed by gel electrophoresis of infected cell lysates. In wild-type infections, its synthesis starts soon after infection and begins to diminish about the time late gene expression commences. The absence of functional P32 results in a marked increase in the amount of the non-functional P32 synthesized. For example, infections of T4 mutants which contain a nonsense mutation in gene 32 produce the nonsense fragment at more than ten times the maximum rate of synthesis of the gene product observed in wild-type infections. All of the temperature-sensitive mutants in gene 32 that were tested also overproduce this product at the non-permissive temperature. This increased synthesis of the non-functional product is recessive, since mixed infections (wild-type, gene 32 nonsense mutant) fail to overproduce the nonsense fragment.Mutations in genes required for late gene expression (genes 33 and 53) as well as some genes required for normal DNA synthesis also result in increased production of P32. The overproduction in such infections is dependent on DNA synthesis; in the absence of DNA synthesis no overproduction occurs. This contrasts with the overproduction resulting from the absence of functional P32 which is not dependent on DNA synthesis.These results are compatible with a model for the regulation of expression of gene 32 in which the synthesis of P32 is either directly or indirectly controlled by its own function. Thus, in the absence of P32 function the expression of this gene is increased as is manifest by the high rate of P32 synthesis. It is further suggested that in infections defective in late gene expression and consequently in the maturation of replicated DNA, the increased P32 production is caused by the large expansion of the DNA pool. This DNA is presumed to compete for active P32 by binding it non-specifically to single-stranded regions, thus reducing the amount of P32 free to block gene 32 expression. Similarly, the aberrant DNA synthesized following infections with mutants in genes 41, 56, 58, 60 and 30, although quantitatively less than that produced in the maturation defective infections, can probably bind large quantities of P32 to single-stranded regions resulting in increased P32 synthesis.     

The role of the bacteriophage T4 gene 32 protein in homologous pairing

The gene 32 protein of the bacteriophage T4 is required for efficient genetic recombination in infected Eschericia coli cells and strongly stimulates in vitro pairing catalyzed by the phage uvsX protein, a RecA-like strand transferase. This helix-destabilizing factor is known to bind tightly and cooperatively to single-stranded DNA and to interact specifically with the uvsX protein as well as other phage gene products. However, its detailed role in homologous pairing is not well understood. I show here that when the efficiency of uvsX protein-mediated pairing is examined at different gene 32 protein and duplex DNA concentrations, a correlation between the two is found, suggesting that the two interact in a functionally important manner during the reaction. These and other data are consistent with a model in which the gene 32 protein binds to the strand displaced from the recipient duplex during pairing, thereby stabilizing the heteroduplex product. An alternative model in which the gene 32 protein replaces UvsX on the invading strand, thereby freeing the strand transferase to bind to the displaced strand, is also considered.     

Photoaffinity labeling of T4 bacteriophage 32 protein

With a view toward the determination of nucleic acid binding domains and sites on nucleic acid helix-destabilizing (single strand-specific) proteins (HDPs), we have studied the interactions of the copolymer polynucleotide photoaffinity label, poly(adenylic, 8-azidoadenylic acid), (poly(A,8-N3A] with the T4 bacteriophage HDP, 32 protein. Poly(A,8-N3A) quenched the intrinsic tryptophan fluorescence of 32 protein in a manner similar to that observed with other polynucleotides, and the effect could be reversed by addition of sufficient NaCl. The binding affinity and site size of this noncovalent interaction of poly(A,8-N3A) with 32 protein are similar to the values obtained for poly(A) and this protein. When [3H]poly(A,8-N3A)/32 protein mixtures were irradiated at 254 nm, fluorescence quenching was not reversed by NaCl, suggesting that the label was covalently bound to the protein. Mixtures of photolabel and protein subjected to short periods of irradiation (generally 1 min, 2000 erg mm-2) formed high molecular weight complexes, which when electrophoresed on sodium dodecyl sulfate (SDS)-polyacrylamide gels were radioactive and stained with Coomassie Blue R. Under the same conditions, [3H]poly(A) failed to label 32 protein. The radioactivity of [3H]poly(A,8-N3A)-labeled complexes subjected to micrococcal nuclease after irradiation was seen to migrate just behind the free 32 protein monomer on SDS-polyacrylamide gels, indicating that portions of the photolabel not in direct contact with protein were accessible to this enzyme. By several criteria, we conclude that 32 protein was photolabeled specifically at its single-stranded nucleic acid binding site. Single-stranded nucleic acids with affinities for protein greater than that of poly(A,8-N3A) effectively inhibited photolabeling. The [NaCl] dependence of photolabeling monitored on SDS gels paralleled the NaCl reversal of (noncovalent) poly(A,8-N3A)-32 protein binding. Photolabeling reached a plateau after 1-2 min. The formation of high molecular weight complexes with increasing [poly(A,8-N3A)] paralleled the disappearance of free protein on SDS gels, and reached a saturation level of about 75% labeling. Several chromatographic procedures appear to be useful for the separation of the photolabeled complexes from free protein and photolabel. Limited trypsin hydrolysis of photolabeled 32 protein indicated that all the label was within the central ("III") portion of the protein. This approach should have general applicability to the identification of nucleic acid binding sites on helix-destabilizing proteins.     

Recognition of chemically damaged DNA by the gene 32 protein from bacteriophage T4

We have used fluorescence spectroscopy to investigate the binding of gene 32 protein from bacteriophage T4 to DNA which has been chemically modified with carcinogens or antitumor drugs. This protein exhibits a high specificity for single-stranded nucleic acids and binds more efficiently to DNA modified either with cis-diaminodichloroplatinum(II) or with aminofluorene derivatives than to native DNA. This increased affinity is related to the formation of locally unpaired regions which are strong binding sites for the single-strand binding protein. In contrast, gene 32 protein has the same affinity for native DNA, DNA containing methylated purines and DNA that has reacted with trans-diaminodichloroplatinum(II) or with chlorodiethylenetriaminoplatinum(II) chloride. These types of damage do not induce a sufficient structural change to allow gene 32 protein binding. Depurination of DNA does not create binding sites for the T4 gene 32 protein but nicked apurinic sites are strong ligands for the protein. This T4 single-strand binding protein does not exhibit a significantly increased affinity for nicked DNA as compared with native DNA. These results are discussed with respect to the recognition of DNA damage by proteins involved in DNA repair and to the possible role of single-strand binding proteins in DNA repair mechanisms.     

Mutator mutations in bacteriophage T4 gene 32 (DNA unwinding protein).

Bacteriophage T4 gene 32 encodes a DNA unwinding protein required for DNA replication, repair, and recombination. Gene 32 temperature-sensitive mutations enhance virtually all base pair substitution mutation rates.     

Studies of the self-association of bacteriophage T4 gene 32 protein by equilibrium sedimentation.

The self-association of the bacteriophage T4 gene 32 protein has been examined in the analytical ultracentrifuge under varying conditions to determine the nature of the process. The process is not a simple indefinite association with one association constant (monomer

dimer

trimer

etc.). The complexity of the process is shown by (1) peculiarities in the molecular weight versus concentration curves, in the region of the dimer (observed with increasing ionic strength, at pH 10, in 0.04 m-MgCl₂, with aged preparations, at 19 °C and in the presence of the oligonucleotide d(pT)₁₀), (2) the increased sigmoidicity of the association curve in the presence of glycerol or oligo[d(pT)₄], and (3) the discontinuity in the association curve at the tetramer at a pH value of approximately 9.4. A model with two association constants which could vary independently (monomer

dimer

tetramer

etc.) explained many of the findings. However, a more complex model was required to explain curves which had a plateau at the dimer with increased association at higher protein concentrations. Thus, under all conditions examined there is evidence for more than one type of protein-protein interaction. These different interactions may be involved in a physiological function such as recombination.     

Autogenous regulatory site on the bacteriophage T4 gene 32 messenger RNA

We have identified the binding site on the bacteriophage T4 gene 32 mRNA responsible for autogenous translational regulation. We demonstrate that this site is largely unstructured and overlaps the initiation codon of gene 32 as previously predicted. Co-operative binding of gene 32 protein to this site specifically blocks the formation of 30 S-tRNA(fMet)-gene 32 mRNA ternary complexes and initiation of translation. The translational operator is bound co-operatively by gene 32 protein and this binding is facilitated by a nucleation site far upstream from the initiation codon. A similar unstructured mRNA lacking this nucleation site is also bound co-operatively, but only at concentrations of gene 32 protein higher than those needed to repress binding of ribosomes to the gene 32 mRNA. Some sequence-specific interactions may also influence this binding. Comparison of the bacteriophage T2, T4 and T6 gene 32 operator sequences leads us to propose that the nucleation site is a pseudoknot.     

Purification and properties of the bacteriophage T4 gene 61 RNA priming protein

The bacteriophage T4 gene 61 protein is required, together with the gene 41 protein and single-stranded DNA, for the synthesis of the pentaribonucleotides that are used as primers for the start of each new Okazaki DNA fragment during T4 DNA replication. Using this priming activity as an assay, we have purified the 61 protein to essential homogeneity in milligram amounts. The priming activity was identified with the product of T4 gene 61 by using two-dimensional polyacrylamide gel electrophoresis to compare all of the T4-induced proteins in wild-type and mutant infections; the purified protein co-migrates with the only detectable protein missing in a 61- mutant infection. The purified 61 protein is shown to bind to the T4 helix-destabilizing protein (gene 32 protein) and to both single-stranded and double-stranded DNA. We have failed to detect any ribonucleotide polymerizing activity in either the 61 protein or the 41 protein alone; both the 61 and 41 proteins must be present to observe any synthesis of oligoribonucleotides.     

Construction and properties of a recombinant plasmid containing gene 32 of bacteriophage T4D

This paper describes the construction and characterization of a chimeric plasmid that encodes the single-stranded DNA-binding protein of bacteriophage T4D (the product of gene 32). The plasmid contains a 2·6 × 10³ base HindIII segment of T4 DNA that includes genes 59 and 32 as well as a portion of gene 33. Isolation of bacteria carrying the recombinant plasmid became possible when the segment of phage DNA contained an amber mutation in gene 32. This suggests that a functional gene 32 is deleterious to the cell. Using antibody to gene 32 protein, we have been able to demonstrate expression of the plasmid-borne gene 32 in uninfected bacteria. Deletion variants of the gene 32 plasmid have been constructed in vitro. These have been used to align the genetic map of the region with the restriction map and to study phage gene expression from the plasmid in both infected and uninfected cells. In phage-infected cells the level of functional gene 32 product regulates the efficiency of translation of its own messenger RNA. We also observe such self-regulation for gene 32 present on the plasmid.     

Interaction between bacteriophage T4 coded gene 32 protein and poly(rA)

The cooperative binding of T4 gene 32 protein with polynucleotides, of which the quantitative aspects in the literature have not satisfied the requirements of thermodynamics, is studied by adopting a modified formula of the lattice theory. A moderate value is found for the cooperativity parameter (q approximately 200 at 0.2 M NaCl), which is weakly dependent on salt concentration. The cation effect on the binding suggests that the shielding of negative charges of the protein or a loose cation bridge between the bound protein molecules plays a role in the cooperative binding process.     

Immunoprecipitation of SV40 replicating minichromosomes complexed with bacteriophage T4 gene 32 protein.

Simian Virus 40 (SV40) DNA replication is a useful model to study eukaryotic cell DNA replication because it encodes only one replication protein and its genome has a nucleoprotein structure ('minichromosome') indistinguishable from cellular chromatin. Late after infection SV40 replicating DNA molecules represent about 5% of total viral minichromosomes. Since gene 32 protein (P32) from bacteriophage T4 interacts with single-stranded DNA and SV40 replication complexes are expected to contain single-stranded regions at the replication forks, we asked whether P32 might be used to isolate replicating SV40 minichromosomes. When nuclear extracts from SV40 infected cells were treated sequentially with P32 and anti-P32 antibodies, pulse-labeled minichromosomes were selectively immunoprecipitated. Agarose gel electrophoresis analysis confirmed that immunoprecipitated material corresponded to SV40 replicative intermediates. Protein analysis of the pelleted material revealed several proteins of viral and cellular origin. Among them, T antigen and histones were found to be complexed with at least other three proteins from cellular origin, to the replicative complexes. Additionally, anti-P32 antibodies were able to detect three cellular proteins of approximately 70, 32 and 13 kDa in western blots. These proteins could correspond to those found as part of an eukaryotic multisubunit single-stranded DNA binding protein. The use of P32 and anti-P32 antibodies thus allows the separation of replicating from mature SV40 minichromosomes and can constitute a novel method to enrich and to study replicative active chromatin.     

Maturation of bacteriophage T4 lagging strand fragments depends on interaction of T4 RNase H with T4 32 protein rather than the T4 gene 45 clamp

In the bacteriophage T4 DNA replication system, T4 RNase H removes the RNA primers and some adjacent DNA before the lagging strand fragments are ligated. This 5'-nuclease has strong structural and functional similarity to the FEN1 nuclease family. We have shown previously that T4 32 protein binds DNA behind the nuclease and increases its processivity. Here we show that T4 RNase H with a C-terminal deletion (residues 278-305) retains its exonuclease activity but is no longer affected by 32 protein. T4 gene 45 replication clamp stimulates T4 RNase H on nicked or gapped substrates, where it can be loaded behind the nuclease, but does not increase its processivity. An N-terminal deletion (residues 2-10) of a conserved clamp interaction motif eliminates stimulation by the clamp. In the crystal structure of T4 RNase H, the binding sites for the clamp at the N terminus and for 32 protein at the C terminus are located close together, away from the catalytic site of the enzyme. By using mutant T4 RNase H with deletions in the binding site for either the clamp or 32 protein, we show that it is the interaction of T4 RNase H with 32 protein, rather than the clamp, that most affects the maturation of lagging strand fragments in the T4 replication system in vitro and T4 phage production in vivo.     

Suppressors of gene 32 am mutants that specifically overproduce P32 (unwinding protein) in bacteriophage T4.

A gene 32 amber (am) mutant, amNG364, fails to grow on Escherichia coli Su3+ high temperatures, suggesting that the tyrosine residue inserted at the am codon by Su3+ leads to a temperature-sensitive gene 32 protein (P32). By plating amNG364 on E. coli Su3+ 45 degrees C, several pseudorevertants were found that proved to contain a suppressor (su) mutant in addition to the original am mutation. Crosses of two of these amNG364su strains to am+ phage indicated that the suppressors themselves are in or close to gene 32. Phage strains carrying either of the two su mutations, without amNG364, grew normally. When cells were infected by these su mutants and the proteins produced were examined by sodium dodecyl sulfate-gel electrophroesis, specific overproduction of P32 was found. Maximum overproduction compared to am+ phage was 6.6-fold for one su mutant and 2.4-fold for the other. Other proteins were produced in normal amounts and in normal time sequence. When amNG364su phage were allowed to infect E. coli S/6/5(Su-), the gene 32 am fragments produced were present at the same derepressed levels as in an infection by amNG364 without a suppressor. The suppressor mutations are interpreted as causing derepression of P32 by altering sites in this autogenously regulated protein involved in template recognition. Previously, specific derepression of gene 32 had only been shown using gene 32 conditional lethal mutants grown under restrictive conditions. We have shown that P32 can also be derepressed under permissive conditions, indicating that loss of P32 function is not necessary for specific derepression.     

Lysis protein T of bacteriophage T4

Summary Lysis protein T of phage T4 is required to allow the phage's lysozyme to reach the murein layer of the cell envelope and cause lysis. Using fusions of the cloned gene t with that of the Escherichia coli alkaline phosphatase or a fragment of the gene for the outer membrane protein OmpA, it was possible to identify T as an integral protein of the plasma membrane. The protein was present in the membrane as a homooligomer and was active at very low cellular concentrations. Expression of the cloned gene t was lethal without causing gross leakiness of the membrane. The functional equivalent of T in phage is protein S. An amber mutant of gene S can be complemented by gene t, although neither protein R of (the functional equivalent of T4 lysozyme) nor S possess any sequence similarity with their T4 counterparts. The murein-degrading enzymes (including that of phage P22) have in common a relatively small size (molecular masses of ca. 18 000) and a rather basic nature not exhibited by other E. coli cystosolic proteins. The results suggest that T acts as a pore that is specific for this type of enzyme.