Intermediates in genetic recombination of bacteriophage T7 DNA. Biological activity and the roles of gene 3 and gene 5

When Escherichia coli cells were infected with ³²P- and 5-bromodeoxyuridine-labeled T7 bacteriophage defective in genes 1.3, 2.3, 4 and 5, doubly branched T7 DNA molecules with “H” or “X”-like configurations were found in the half-heavy density fractions. Physical study showed that they are dimeric molecules composed of two parental DNA molecules (Tsujimoto & Ogawa, 1977a). The transfection assay of these molecules revealed that they were infective. Genetic analysis of progeny in infective centers obtained by transfection of dimeric molecules formed by infection of genetically marked T7 phage showed that these dimeric molecules were genetically biparental.To elucidate the roles of the products of gene 3 (endonuclease I) and gene 5 (DNA polymerase) of phage T7 in the recombination process, the ³²P/BrdUrd hybrid DNA molecules which were formed in the infected cells in the presence of these gene products were isolated, and their structures were analyzed. The presence of T7 DNA polymerase seems to stimulate and/or stabilize the interaction of parental DNAs. At an early stage of infection few dimeric molecules were formed in the absence of T7 DNA polymerase, whereas a significant number of doubly branched molecules were formed in its presence. With increasing incubation time, the multiply branched DNA molecules with a high sedimentation velocity accumulated.In contrast to the accumulation of multiply branched molecules in phage with mutations in genes 2, 3 and 4, almost all of the ³²P/BrdUrd hybrid DNA formed in phage with mutations in genes 2 and 4 were monomeric linear molecules. Shear fragmentation of monomeric linear ³²P/BrdUrd-labeled DNA shifted the density of [³²P]DNA to almost fully light density. It was also found that approximately 50% of [³²P]DNA was linked covalently to BrdUrd-labeled DNA. These linear monomer DNA molecules had infectivity and some of those formed by infection of genetically marked parents yielded recombinant phages. Therefore the gene 3 product seems to process the branched intermediates to linear recombinant molecules by trimming the branches.     

Different restriction of bacteriophages T3 and T7 by P1-lysogenic cells and the role of the T3-coded SAMase.

The intracellular growth of the phages T3 and T7 is restricted in the presence of the Escherichia coli prophage P1. Phage T3 has a higher ability to express its genome and to damage the host cell than T7. This partial protection of T3 against P1 restriction is due to the T3-coded SAMase, an enzyme which degrades S-adenosylmethionine, the cofactor of the P1 restriction endonuclease. Since we did not observe DNA cleavage in vivo, we conclude that the in vivo action of the P1 nuclease is limited to a SAM-dependent repressor-like binding to T3 and T7 DNA, while further reactions with the DNA (modification vs cleavage) are blocked.     

Sequence and analysis of the gene for bacteriophage T3 RNA polymerase.

The RNA polymerases encoded by bacteriophages T3 and T7 have similar structures, but exhibit nearly exclusive template specificities. We have determined the nucleotide sequence of the region of T3 DNA that encodes the T3 RNA polymerase (the gene 1.0 region), and have compared this sequence with the corresponding region of T7 DNA. The predicted amino acid sequence of the T3 RNA polymerase exhibits very few changes when compared to the T7 enzyme (82% of the residues are identical). Significant differences appear to cluster in three distinct regions in the amino-terminal half of the protein. Analysis of the data from both enzymes suggests features that may be important for polymerase function. In particular, a region that differs between the T3 and T7 enzymes exhibits significant homology to the bi-helical domain that is common to many sequence-specific DNA binding proteins. The region that flanks the structural gene contains a number of regulatory elements including: a promoter for the E. coli RNA polymerase, a potential processing site for RNase III and a promoter for the T3 polymerase. The promoter for the T3 RNA polymerase is located only 12 base pairs distal to the stop codon for the structural gene.     

Effect of site-specific endonuclease digestion on the thyP3 gene of bacteriophage phi 3T and the thyP11 gene of bacteriophage rho11.

phi 3T and rho11 are closely related bacteriophages of Bacillus subtilis which can "convent" thymine auxotrophs to thymine prototrophs upon infection or transfection. The effect of endonuclease digestion on the ability of both bacteriophage and prophage DNA from phi eT and rho11 to transform for thymine prototrophy was determined. All of the endonucleases tested: BamHI, Bg/II, BsuRI, EcoRI, HindII+ III, and HpaII reduced the efficiency of thyP transformation to an equal extent in prophage and bacteriophage DNA. Only HpaII completely abolished thyP transformation. The reduction in transformation with BamHI, Bg/II, BsuRI, EcoRI, and HpaII fragments is size related. The thyP transforming fragments generated by these endonucleases are potentially clonable.     

Sequence of bacteriophage T3 DNA from gene 2.5 through gene 9

The nucleotide sequence of bacteriophage T3 DNA, from gene 2.5 through gene 9 has been determined. In addition to regulatory sites, the sequence predicts 19 close-packed genes plus two genes that overlap, in a different reading frame, another gene. The majority of these genes are highly homologous to those in the corresponding region of bacteriophage T7. However, there are some genes that are present in one, but not the other, phage. These apparent deletions are almost exactly gene size and thus the close-packed organization of genes remains the same in T3 as in T7. The varying levels of homology between T3 and T7 DNAs, first noted by Davis and Hyman in their study of DNA heteroduplexes, are also demonstrated here by a comparison of T3 and T7 nucleotide sequences. Many regions of extremely high homology immediately abut sequences that have no apparent homology. These data suggest that bacteriophages T3 and T7 have recombined, both with each other and with other members of a pool of T7-like phages, during their co-evolution.     

Heterogeneity of the procapsid of bacteriophage T3.

Like other double-stranded DNA bacteriophages, bacteriophage T3 assembles a DNA-free procapsid that subsequently packages the bacteriophage DNA. By agarose gel electrophoresis, it has been found that the T3 procapsid has a negative electrophoretic mobility (mu) that progressively increases in magnitude by as much as 3% after assembly of the procapsid. This increase is (i) caused by an increase in the solid support-free mu (muo) of the procapsid, not a decrease in its radius, and (ii) not prevented by either genetically or chemically (use of proflavine) blocking DNA packaging. However, inhibition of the formation of high-energy compounds with a mixture of cyanide and fluoride ions does block the time-dependent increase in the magnitude of muo. This increase appears to be accompanied by addition of an unidentified T3 protein to the procapsid.     

Gamma-T4 hybrid bacteriophage carrying the thymidine kinase gene of bacteriophage T4.

Among 32 lambda-T4 recombinant phages selected for growth on a thymidylate synthetase-deficient (thyA) host, 2 were shown to carry the T4 thymidine kinase (tk) gene. The lambda-T4tk phages contain two T4 HindIII DNA fragments (2.0 and 1.5 kilobases) that hybridize to restriction fragments of T4 DNA, encompassing the tk locus at 60 kilobases on the T4 map. The T4tk insert compensates for the simultaneous host deficiencies of thymidine kinase and thymidylate synthetase in a thymidine kinase-deficient (tdk) host growing in the presence of fluorodeoxyuridine when provided with thymidine and uridine. The lambda-T4tk hybrid phages specified five polypeptides with Mrs of 22,000 (22K), 21K, 14K, 11K, and 9K.     

Gene 24-controlled osmotic shock resistance in bacteriophage T4: probable multiple gene functions.

By use of mixed infections with conditional lethal mutations in the head genes and an osmotic shock-resistant mutant we have demonstrated that osmotic shock resistance is controlled by gene 24. Using acrylamide gel electrophoresis combined with the "immune replicate" technique, we confirmed the positions of gene products 24 and 24* (P24 and P24*). In this paper we have still used the notation "P24," etc., for designating the product of gene 23, etc., although we prefer and use in general the designation "gp23" as introduced by Casjens and King (Annu. Rev. Biochem. 44:585, 1975). The reason for using the old notation is because the illustrations were prepared several years ago.) P24 ts showed a significantly slower mobility. Both osmotic shock-resistant and -sensitive mature phages contain 24*. Giants constructed with the Osr phage showed the same surface lattice as normal phage. Through temperature-shift experiments with 24(tsL90) alone and in combinations, we studied the phages which are matured after the shift to permissive temperature in the absence of new protein synthesis. Our results strongly suggest that only a fraction of the total phage complement of gene 24-controlled proteins is involved in determining the phenotype of shock resistance, and the remainder is necessary to mature the head.