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.     

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.     

Hydration pattern of A4T4 and T4A4 DNA: a molecular dynamics study

Hydration pattern and energetics of 'A-tract' containing duplexes have been studied using molecular dynamics on 12-mer self-complementary sequences 5'-d(GCA4T4GC)-3' and 5'-d(CGT4A4CG)-3'. The structural features for the simulated duplexes showed correlation with the corresponding experimental structures. Analysis of the hydration pattern confirmed that water network around the simulated duplexes is more conformation specific rather than sequence specific. The calculated heat capacity change upon duplex formation showed that the process is entropically driven for both the sequences. Furthermore, the theoretical free energy estimates calculated using MMPBSA approach showed a higher net electrostatic contribution for A4T4 duplex formation than for T4A4, however, energetically both the duplexes are observed to be equally stable.     

Crystalline T4 bacteriophage

Concentrated suspensions of T4 phage crystallize spontaneously in the absence of tryptophan. The crystals, in one plane, contain repeated bilayers of phage in head to head and tail to tail contact, probably with tail fibers retracted. In the plane of each layer there is hexagonal packing of the phage.     

Partial exclusion of genes of bacteriophage T2 with T4-glucosylated DNA in crosses with bacteriophage T4

A recombinant strain (D41) between phage T2 and T4 was isolated which possessed the T2 region of the genome between genes 32 and 39 and both the T4 genesgt ⁺ andgt ⁺ for glucosyltransferase. D41 was crossed with T4amber mutants in the genes for early functions and in some genes for late funcitions. The progeny of the crosses was examined for the frequency of theam ⁺ markers from D41. Genes 32, 60 and 39 in the T2 region of the recombinant strain were as sensitive to exclusion as those in standard-type T2. The T4 glucosylation of the DNA of these T2 genes did not protect them against partial exclusion by T4. However, genes in the region from gene 56 to 55 in the recombinant were resistent to exclusion. In standard-type T2 this region of the genome is sensitive to partial exclusion by T4. There are at least four exclusion sensitive sites in T2: one near gene 32, one near gene 60, one linked to gene 56 and one between genes 42 and 55.This investigation was carried out partially within the frame of the Association between Euratom and the University of Leiden, contract nr. 052-64-1-BIAN.     

The T4 molecule differentially regulating the activation of subpopulations of T4+ cells

It has been demonstrated that the T4+2H4+ subset functioned as a suppressor inducer cell, whereas the reciprocal T4+2H4- subset provided help for B cell Ig production. In the present studies, a series of monoclonal antibodies to cell surface structures expressed on these subsets of cells were examined for their effects on the proliferative and immunoregulatory functions generated in AMLR. We demonstrated that anti-T4 antibody preferentially inhibited the proliferative response of the T4+2H4+ but not T4+2H4- cells against self-MHC antigens. In contrast, anti-T3 and anti-Ia antibodies inhibited the response of both subsets of cells. This subset preference of anti-T4 antibody was not attributable to either the isolation procedures used or a shift in the kinetics of proliferation to autologous self-MHC antigens. Moreover, both IL 2 production and the immunoregulatory function of the T4+2H4+ subset was profoundly inhibited by anti-T4 antibody, whereas the T4+2H4- subset was minimally influenced. In the absence of Ia molecules, T4+2H4+ but not T4+2H4- cell proliferation was inhibited with anti-T4 antibody. Together, these results suggest that the T4 molecule plays a distinct functional role in the differential triggering of subsets of T4+ cells.     

Fate of cloned bacteriophage T4 DNA after phage T4 infection of clone-bearing cells

Plasmid pBR322 replication is inhibited after bacteriophage T4 infection. If no T4 DNA had been cloned into this plasmid vector, the kinetics of inhibition are similar to those observed for the inhibition of Escherichia coli chromosomal DNA. However, if T4 DNA has been cloned into pBR322, plasmid DNA synthesis is initially inhibited but then resumes approximately at the time that phage DNA replication begins. The T4 insert-dependent synthesis of pBR322 DNA is not observed if the infecting phage are deleted for the T4 DNA cloned in the plasmid. Thus, this T4 homology-dependent synthesis of plasmid DNA probably reflects recombination between plasmids and infecting phage genomes. However, this recombination-dependent synthesis of pBR322 DNA does not require the T4 gene 46 product, which is essential for T4 generalized recombination. The effect of T4 infection on the degradation of plasmid DNA is also examined. Plasmid DNA degradation, like E. coli chromosomal DNA degradation, occurs in wild-type and denB mutant infections. However, neither plasmid or chromosomal degradation can be detected in denA mutant infections by the method of DNA--DNA hybridization on nitrocellulose filters.     

Bacteriophage T4 DNA primase-helicase. Characterization of oligomer synthesis by T4 61 protein alone and in conjunction with T4 41 protein

The bacteriophage T4 41 and 61 proteins function as a primase-helicase which in vitro both unwinds double-stranded DNA and synthesizes the pentaribonucleotides used to initiate DNA synthesis on the lagging strand. We demonstrate that 61 protein alone possesses a weak DNA template-dependent oligomer synthesizing activity, whose products differ in size and nucleotide specificity from those made by the 61 and 41 proteins together. We have previously shown that the 61 and 41 proteins make primarily ribonucleotide pentamers of the sequence pppApC(pN)3, although some pentamers beginning with G were also detected on phi X174 single-stranded DNA. The pentamers pppApC(pN)3 have also been shown to initiate T4 DNA chains in vivo (Kurosawa, Y., and Okazaki, T. (1979) J. Mol. Biol. 135, 841-861). We now show that in contrast, the major products made by 61 protein alone on phi X174 DNA with [alpha-32P]CTP and the other three ribonucleoside triphosphates are not pentamers, but the dimers pppApC and pppGpC. In addition, minor amounts of products from 3 to approximately 45 nucleotides in length are also synthesized. Unlike the 61/41 protein reaction, 61 protein alone can substitute dATP or dGTP for ATP or GTP. Addition of 41 protein greatly stimulates oligomer synthesis, especially the synthesis of products made with ATP and CTP and products 5 nucleotides in length. Thus, both 61 and 41 proteins are needed to obtain efficient synthesis of the biologically relevant pentamers pppApC(pN)3. We demonstrate that the glucosylated hydroxymethylcytosines present in T4 DNA do not support the initiation of primer synthesis by the 61 protein on this template. With glycosylated hydroxymethyl T4 DNA, pppApC but not pppGpC oligomers are detected. If the T4 DNA is modified by hydroxymethylation but not glucosylation, pppApC and only a trace of pppGpC products are seen. In the accompanying paper (Nossal, N.G., and Hinton, D.M. (1987) J. Biol. Chem. 262, 10879-10885), we examine DNA synthesis primed by 61 protein in the absence of 41 protein.     

Studies of viable T4 bacteriophage containing cytosine-substituted DNA (T4dC phage)

Summary Digestion of non-glucosylated and cytosine-substituted T4 phage (T4dC) DNA with SalI restriction endonuclease showed that the DNA had nine SalI-sensitive sites. There were eight SalI sites in DNA from a strain which had a deletion in the rII-denB-ndd region. The comparison of two digestion patterns indicated that one of the SalI-sensitive sites was present in the deleted region and that the SalI-F fragment (8.4x10⁶ daltons) was located adjacent to the SalI-C or SalI-D fragment (15.5x10⁶ daltons) on the T4 chromosome. The DNA gave no detectable cleavage product when digested with BamHI endonuclease alone, while, when digested successively with BamHI and SalI, the DNA yielded two new digestion products in place of one fragment formed by SalI alone. The BamHI-sensitive site was in the SalI-A fragment (25.2x10⁶ daltons). The usefulness of this information for making cleavage maps of T4 phage chromosome is discussed.     

Bacteriophage T4 DNA primase-helicase. Characterization of the DNA synthesis primed by T4 61 protein in the absence of T4 41 protein

The bacteriophage T4 61/41 protein primase-helicase is part of a seven T4 protein system needed for DNA synthesis in vitro. Although both 41 and 61 proteins are required for the synthesis and utilization of the normal pppApC(pN)3 pentanucleotide primer, we show in the accompanying paper (Hinton, D. M., and Nossal, N. G. (1987) J. Biol. Chem. 262, 10873-10878) that high concentrations of 61 protein alone carry out a limited, template-dependent oligonucleotide synthesis with the dimers pppApC and pppGpC as the major products labeled with [alpha-32P]CTP. At these high concentrations, 61 protein alone primes DNA synthesis by T4 DNA polymerase and the T4 genes 44/62 and 45 polymerase accessory proteins, or by Escherichia coli DNA polymerase I. The addition of T4 replication proteins other than 41 protein does not change the size distribution of oligonucleotides made by 61 protein. However, the primers used for DNA synthesis in the absence of 41 protein are not dimers, but rather trace quantities of longer oligonucleotides (5 to about 45 bases) which begin predominantly with pppGpC. These results show that 41 protein is required to prime with oligonucleotides beginning with pppApC and suggest that 41 protein, either alone or in conjunction with 61 protein, helps to stabilize the usual short pentamer primers on the template until they are elongated by the DNA polymerase. Moreover, since 61 protein by itself can only initiate DNA synthesis with primers beginning with pppGpC, but cannot make oligonucleotides starting with pppGpC on T4 DNA in which all the C is glucosylated and hydroxymethylated, both the T4 41 and 61 proteins are essential to prime DNA synthesis on their normal template. In our analysis of RNA-primed DNA, we demonstrate that although RNA primers at the 5' ends of DNA chains are relatively resistant to the 3' to 5' exonuclease of T4 DNA polymerase (Kurosawa, Y., and Okazaki, T. (1979) J. Mol. Biol. 135, 841-861), pppNpNpNpNpN oligomers are digested to a greater extent than the dephosphorylated pentamers NpNpNpNpN.