Genetic control of capsid length in bacteriophage T4: clustering of ptg mutations in gene 23.

Fifty-two new bacteriophage T4 ptg mutations have been isolated by selecting for the giant-capsid phenotype they display. Genetic mapping placed all of them at eight sites, all located in gene 23. These sites were clustered in three locations, one near amber B17 (gene 23 nucleotide [NT] 268), another centrally placed between amE506 (NT 706) and amE1270 (NT 925), and the third between amC208 (NT 1297) and amE1236 (NT 1489). The lack of a selective system for identifying recombinant genotypes when dealing with the very close linkages found within these clusters opens the possibility that more than eight sites are represented in this set of mutations. Since one site was represented by only one mutation, it seems likely that further searching might uncover additional sites. It is suggested that the clustering of mutations observed here identifies regions of the gene 23 product that play a role in regulating the capsid length of T4.     

Genetic control of capsid length in bacteriophage T4: DNA sequence analysis of petite and petite/giant mutants

The T4 gene 23 product (gp23) encodes the major structural protein of the mature capsid. Mutations in this gene have been described which disrupt the normal length-determining mechanism (A.H. Doermann, F.A. Eiserling, and L. Boehner, J. Virol. 12:374-385, 1973). Mutants which produce high levels of petite and giant phage (ptg) are restricted to three tight clusters in gene 23 (A.H. Doermann, A. Pao, and P. Jackson, J. Virol. 61:2823-2827, 1987). Twenty-six of these ptg mutations were cloned, and their DNA sequence alterations were determined. Each member of this set of ptg mutants arose from a single mutation, and the set defined 10 different sites at which ptg mutations can occur in gene 23. Two petite (pt) mutations in gene 23 (pt21-34 and ptE920g), which produce high frequencies of petite particles but no giants, were also sequenced. Both pt21-34 and ptE920g were shown to include multiple mutations. The phenotypes attributed to both pt and ptg mutations are discussed relative to the mechanism of capsid morphogenesis. A site-directed mutation (SD-1E) was created at the ptgNg191 site, and its phenotypic consequences were examined. Plaque morphology revertants arising from a gene 23 mutant derivative of pt21-34 and from SD-1E were isolated. A preliminary mapping of the mutation(s) responsible for their revertant phenotypes suggested that both intra- and extragenic suppressors of the petite phenotype can be isolated by this method.     

Genetic control of capsid length in bacteriophage T4 VII. A model of length regulation based on DNA size

Four models for head length regulation in bacteriophage T4 are described and discussed. Several length mutants in the major capsid protein gene (23) were studied by sucrose gradient analysis, rotating gel analysis of DNA length, and by mixed infection gene dosage experiments with T4 amber mutants in gene 24. The results show that head length variation is quantized and highly specific, in that certain amino acid changes in gp23 results in reproducible and well-defined head length phenotypes. These data are presented as being most consistent with a vernier-type of head length control mechanism.     

Genetic mapping of regA mutants of bacteriophage T4D.

SP62, a mutant of bacteriophage T4 shown by Wiberg et al. (1973) to be defective in regulation of T4 protein synthesis, was shown by complementation tests to define a new gene, regA, and by intergenic mapping to lie between genes 43 and 62. The mapping involved crossing SP62 with a quadruple amber mutant defective in genes 42, 43, 62, and 44, selecting all six classes of amber-containing recombinants caused by single crossover events, and then scoring the presence or absence of SP62 in these recombinants. In addition, 15 new, spontaneous regA mutants were isolated, and 13 of these were mapped against each other; a total of eight different mutation sites were thus defined. Most of the new mutants were isolated as pseudorevertants of a leaky amber mutant in gene 62, according to Karam and Bowles (1974), whereas one was identified by virtue of the "white ring" around its plaque, a phenotype possessed by all the regA mutants at high temperature, SP62 was renamed regA1, and the new mutants were named regA2, regA3, etc.     

Genetic control of whisker antigen of bacteriophage T4D

An antigenic component of T4 whiskers (short fibrils located in the region of the head—tail junction) has been reported to be under the control of gene 49 (Yanagida & Ahmad-Zadeh, 1970; Yanagida, 1972). This was based on immunological evidence using antiserum to particles of T4D adsorbed with gene 49-defective extract made with the mutant amE727. The latter phage, however, is shown here to be a double mutant bearing amber mutations in gene 49 and another gene, herein referred to as wac (whisker antigen control gene). Gene wac maps in the general region of gene 16. Evidence is presented indicating that the whisker antigen is under the control of wac and not gene 49. In wac-defective infections phage are produced that lack a protein. This protein appears by electrophoretic analysis in sodium dodecyl sulfate-polyacrylamide gels to be the major component of the antigen.The tail fibers of wac-defective bacteriophage are in an open configuration under conditions in which those of wild-type phage are folded alongside the tail. Thus, the wac gene may have a role in the regulation of tail-fiber configuration.     

Isolation of bacteriophage T4 DNA polymerase mutator mutants

More than 20 new bacteriophage T4 DNA polymerase mutants have been isolated by a procedure designed to select mutants with high spontaneous mutation rates. Some of the mutants produce the highest mutation frequencies that have been observed in T4 thus far. The design of the selection procedure allows for the isolation of mutator mutants that preferentially induce certain types of replication errors, and some of the mutator mutants have mutational specificities different from wild-type. The new mutants are clustered at just two sites in the DNA polymerase gene, and this result confirms an earlier observation.     

Chaperonin-mediated folding of bacteriophage T4 major capsid protein. II. Production of gene product 23 deletion mutants

Folding of bacteriophage T4 major capsid protein, gene product 23 (534 a.a.), is aided by two proteins: E. coli GroEL chaperonin and viral gp31 co-chaperonin. In the present work a set of mutants with extensive deletions inside gene 23 using controlled digestion with Bal31 nuclease has been constructed. Proteins with deletions were co-expressed from plasmid vectors with phage gp31 co-chaperonin. Deletions from 8 to 33 a.a. in the N-terminal region of the gp23 molecule covering the protein proteolytic cleavage site during capsid maturation have no influence on the mutants' ability to produce in E. coli cells proteins which form regular structures—polyheads. Deletions in other regions of the polypeptide chain (187-203 and 367-476 a.a.) disturb the correct folding and subsequent assembly of gp23 into polyheads.     

Proteolytic cleavage and structural transformation: Their relationship in bacteriophage T4 capsid maturation

Giant T4 phage capsoids formed in canavanine-treated cultures infected by phage mutants in genes 21 and 17, respectively, differ with regard to cleavage of the major capsid protein, gp 23, and in the fine structure of their hexagonal surface lattices. Quantitative computer processing of electron micrographs shows that the significant differences in capsomer morphology amount to six symmetrically placed features present in the uncleaved hexamer but absent after cleavage. These features may be related with the N-terminal portions of gp 23 monomers excised by phage-specific proteolysis. Cleaved 17^? giants can be induced to undergo a further structural transformation (expansion). Structural characteristics of partially transformed giant particles give clues about the dynamics of the cleavage and expansion transformations. Both processes appear to be polar, initiating in one cap and propagating along the particle. The transition zone of partial cleavage is diffuse, whereas the transition between unexpanded and expanded areas is confined to a narrow band of some 20 nm width.     

Nonsense mutants in the bacteriophage T4D v gene

Ten UV-sensitive mutants of T4D with the v phenotype were isolated. Of these ten mutants, two are amber and two opal. In UV curves and in photoreactivation and multiplicity reactivation (MR) experiments the nonsense mutants show the v phenotype in su⁻ hosts and almost the T4+ phenotype in su⁺ hosts. The mutations are located between rI and e and are alleles of v₁. In crosses with irradiated and non-irradiated phages the recombinant frequency is not reduced by uvs5.Amber uvs5 propagated in CR63 su⁺ is with B su⁻ just as sensitive to UV as uvs5 propagated in B su⁻, which permits the conclusion that the capsid of T4 phage particles does not contain the v gene product.In addition, four mutants with a relative UV sensitivity equal to that of T4x were isolated. These are discussed in the next paper³³.     

Genetic complementation by cloned bacteriophage T4 late genes.

Bacteriophage T4 containing nonsense mutations in late genes was found to be genetically complemented by four conjugate T4 genes (7, 11, 23, or 24) located on plasmid or phage vectors. Complementation was at a very low level unless the infecting phage carried a denB mutation (which abolishes T4 DNA endonuclease IV activity). In most experiments, the infecting phage also had a denA mutation, which abolishes T4 DNA endonuclease II activity. Mutations in the alc/unf gene (which allow dCMP-containing T4 late genes to be expressed) further increased complementation efficiency. Most of the alc/unf mutant phage strains used for these experiments were constructed to incorporate a gene 56 mutation, which blocks dCTP breakdown and allows replication to generate dCMP-containing T4 DNA. Effects of the alc/unf:56 mutant combination on complementation efficiency varied among the different T4 late genes. Despite regions of homology, ranging from 2 to 14 kilobase pairs, between cloned T4 genes and infecting genomes, the rate of formation of recombinants after T4 den:alc phage infection was generally low (higher for two mutants in gene 23, lower for mutants in gene 7 and 11). More significantly, when gene 23 complementation had to be preceded by recombination, the complementation efficiency was drastically reduced. We conclude that high complementation efficiency of cloned T4 late genes need not depend on prior complete breakage-reunion events which transpose those genes from the resident plasmid to a late promoter on the infecting T4 genome. The presence of the intact gene 23 on plasmids reduced the yield of T4 phage. The magnitude of this negative complementation effect varied in different plasmids; in the extreme case (plasmid pLA3), an almost 10-fold reduction of yield was observed. The cells can thus be said to have been made partly nonpermissive for this lytic virus by incorporating a part of the viral genome.     

Genetic control of formation of very fast sedimenting DNA of bacteriophage T4

Summary Formation of very fast sedimenting DNA (VFS-DNA) in cells of Escherichia coli infected with phage T4 carrying a defect in gene 49 was differentially affected by a secondary mutation in gene 30 or 46; a mutation of gene 46 markedly reduced formation of VFS-DNA, whereas that of gene 30 did not.     

Suppression of temperature sensitive mutants of bacteriophage T4 by bacterial opal suppressors

Summary Some of the partial revertants from opal (UGA) mutants of bacteriophage T4 are temperature sensitive in su ^– host cells but are still temperature resistant in su ⁺ cells. Hence these revertants are missense mutants suppressible by bacterial opal suppressors. Such a suppression may be explained in terms of codon-anticodon interactions by the wobble hypothesis.     

Suppression of amber and ochre rII mutants of bacteriophage T4 by streptomycin

Orias, E. (University of California, Santa Barbara), and T. K. Gartner. Suppression of amber and ochre rII mutants of bacteriophage T4 by streptomycin. J. Bacteriol. 91:2210-2215. 1966.-Streptomycin-induced suppression of amber and ochre rII mutants of phage T4 was studied in a streptomycin-sensitive strain of Escherichia coli and four nearly isogenic streptomycin-resistant derivatives of this strain, in the presence and in the absence of an ochre suppressor. Most of the 12 rII mutants tested were suppressed by streptomycin in the streptomycin-sensitive su(-) strain. This streptomycin-induced suppression in the su(-) strain was eliminated by the independent action of at least two of the four nonidentical mutations to streptomycin resistance. In two of the su(+)str-r strains, streptomycin markedly augmented the suppression caused by the ochre suppressor. In those su(-)str-r hosts in which significant streptomycin-induced suppression could be measured, the amber mutants were more suppressible than the ochre mutants.     

Proteolysis of the major capsid protein T4 bacteriophage polyheads limited by quaternary structure.

Bacteriophage T4 carrying an amber mutation in gene 22 plus an amber mutation in gene 21 form aberrant, tubular structures termed rough polyheads, instead of complete phage when they infect Escherichia coli B. These rough polyheads consist almost entirely of the major capsid protein in its uncleaved form (gp23). When rough polyheads are treated under mild conditions with any of the five proteases, trypsin, chymotrypsin, thermolysin, pronase, or the protease from Staphylococcus aureus V8, the gp23 is rapidly hydrolyzed at a limited number of peptide bonds. In contrast, cleaved capsid protein (gp23) in mature phage capsids is completely resistant to proteolysis under the same conditions. A major project in this laboratory requires determining the primary structure of gp23, a large protein (Mr = 58,000) quite rich in those amino acids at which cleavages are achieved by conventional means. Recovery of peptides from the complex mixtures resulting from such cleavages proved to be extremely difficult. The limited proteolysis of gp23 in rough polyheads had yielded a set of large, easily purified fragments which are greatly simplifying the task of determining the primary structure of this protein.