Capsid size determination in the P2-P4 bacteriophage system: suppression of sir mutations in P2's capsid gene N by supersid mutations in P4's external scaffold gene sid.

The sid gene of the P2-dependent phage P4 provides an external scaffold so P2 N gene encoded protomers assemble as T = 4 capsids rather than as P2's T = 7 capsids. Mutations (sir) in the middle of N interfere with Sid's function. We describe a new P4 mutant class, nms ("supersid") mutations, which direct also P2 sir to provide small capsids. Three different nms mutations were located near the sid end, commingled with sid(-) mutations. Suppression of sir by nms is not allele-specific. Our results favor this interpretation of capsid size control: (i) sir mutations reduce pN protomer flexibility and thereby interfere with the generation of T = 4 compatible hexons; (ii) the C-termini of Sid molecules link up when forming the scaffold; nms mutations strengthen these Sid-Sid contacts and thus allow the scaffold to force even sir-type protomers to form T = 4 compatible hexons. Some related findings concern suppression of N ts mutations by P4.

Translation of two nested genes in bacteriophage P4 controls immunity-specific transcription termination.

In phage P4, transcription of the left operon may occur from both the constitutive PLE promoter and the regulated PLL promoter, about 400 nucleotides upstream of PLE. A strong Rho-dependent termination site, timm, is located downstream of both promoters. When P4 immunity is expressed, transcription starting at PLE is efficiently terminated at timm, whereas transcription from PLL is immunity insensitive and reads through timm. We report the identification of two nested genes, kil and eta, located in the P4 left operon. The P4 kil gene, which encodes a 65-amino-acid polypeptide, is the first translated gene downstream of the PLE promoter, and its expression is controlled by P4 immunity. Overexpression of kil causes cell killing. This gene is the terminal part of a longer open reading frame, eta, which begins upstream of PLE. The eta gene is expressed when transcription starts from the PLL promoter. Three likely start codons predict a size between 197 and 199 amino acids for the Eta gene product. Both kil and eta overlap the timm site. By cloning kil upstream of a tRNA reporter gene, we demonstrated that translation of the kil region prevents premature transcription termination at timm. This suggests that P4 immunity might negatively control kil translation, thus enabling transcription termination at timm. Transcription starting from PL proceeds through timm. Mutations that create nonsense codons in eta caused premature termination of transcription starting from PLL. Suppression of the nonsense mutation restored transcription readthrough at timm. Thus, termination of transcription from PLL is prevented by translation of eta.

Mutational analysis of the bacteriophage P4 capsid-size-determining gene.

Satellite phage P4 (11,624 bp) depends on the morphopoietic genes (capsid, tail) and lysis genes of its helper phage P2 (33.5 kb) for its lytic development. In the morphopoietic process, P4 redirects the assembly pathway of large, P2 size, capsids (diameter = 60 nm) to yield smaller, P4 size, capsids (diameter = 45 nm), 1/3 in volume of that of its helper. The P4-specified capsid size determination is dependent on the function of the 27-kDa gpSid. To study the capsid size-determining function, we carried out a mutational analysis of the P4 sid gene. Use of a P4-derived genome of 29.1 kb (P461), which can be packaged only into large, P2 size, capsids allowed us to select P4 Sid- mutants. By DNA sequencing we characterized 25 P4 Sid- mutants, of which 10 contain base pair substitutions and 15 contain deletions. Both types of mutations are clustered in separate locations within the sid gene. Our results suggest that the Sid polypeptide contains three distinct functional domains.

Bacteriophage P2: genes involved in baseplate assembly.

The sequences of two previously defined tail genes, V and J, of the temperate bacteriophage P2, and those of two new essential tail genes, W and I, were determined. Their order is the late gene promoter, VWJI, followed by the tail fiber genes H and G, and a transcription terminator. The V gene product is the small spike at the tip of the tail, and the J gene product lies at the edge of the baseplate. The W gene product may be homologous to the product of gene 25 of T4 phage, which is part of the T4 baseplate. A temperature-sensitive mutation in gene V affects satellite phage P4 production more than it affects the production of P2 helper phage. P4 mutations that partially compensate for this defect of gene V lie in the P4 capsid size determination gene, sid.

Mutations affecting two adjacent amino acid residues in the alpha subunit of RNA polymerase block transcriptional activation by the bacteriophage P2 Ogr protein.

The bacteriophage P2 ogr gene product is a positive regulator of transcription from P2 late promoters. The ogr gene was originally defined by compensatory mutations that overcame the block to P2 growth imposed by a host mutation, rpoA109, in the gene encoding the alpha subunit of RNA polymerase. DNA sequence analysis has confirmed that this mutation affects the C-terminal region of the alpha subunit, changing a leucine residue at position 290 to a histidine (rpoAL290H). We have employed a reporter plasmid system to screen other, previously described, rpoA mutants for effects on activation of a P2 late promoter and have identified a second allele, rpoA155, that blocks P2 late transcription. This mutation lies just upstream of rpoAL290H, changing the leucine residue at position 289 to a phenylalanine (rpoAL289F). The effect of the rpoAL289F mutation is not suppressed by the rpoAL290H-compensatory P2 ogr mutation. P2 ogr mutants that overcome the block imposed by rpoAL289F were isolated and characterized. Our results are consistent with a direct interaction between Ogr and the alpha subunit of RNA polymerase and support a model in which transcription factor contact sites within the C terminus of alpha are discrete and tightly clustered.

The gene fimU affects expression of Salmonella typhimurium type 1 fimbriae and is related to the Escherichia coli tRNA gene argU.

The gene fimU, located on a recombinant plasmid carrying the Salmonella typhimurium type 1 fimbrial gene cluster is closely related to the Escherichia coli tRNA gene argU. The fimU gene complements an E. coli argU mutant that is a P2 lysogen, thereby allowing the phage P4 to grow in this strain but preventing the growth of phage lambda. In addition, fimU was shown to be involved in fimbrial expression since transformants of the E. coli argU mutant could produce fimbriae only in the presence of fimU but not in its absence, whereas in an E. coli argU+ strain fimbriation did not require the fimU gene.

Retronphage phi R73: an E. coli phage that contains a retroelement and integrates into a tRNA gene.

Some strains of Escherichia coli contain retroelements (retrons) that encode genes for reverse transcriptase and branched, multicopy, single-stranded DNA (msDNA) linked to RNA. However, the origin of retrons is unknown. A P4-like cryptic prophage was found that contains a retroelement (retron Ec73) for msDNA-Ec73 in an E. coli clinical strain. The entire genome of this prophage, named phi R73, is 12.7 kilobase pairs and is flanked by 29-base pair direct repeats derived from the 3' end of the selenocystyl transfer RNA gene (selC). P2 bacteriophage caused excision of the phi R73 prophage and acted as a helper to package phi R73 DNA into an infectious virion. The newly formed phi R73 closely resembled P4 as a virion and in its lytic growth. Retronphage phi R73 lysogenized a new host strain, reintegrating its genome into the selC gene of the host chromosome and enabling the newly formed lysogens to produce msDNA-Ec73. Hence, retron Ec73 can be transferred intercellularly as part of the genome of a helper-dependent retronphage.

Morphopoietic switch mutations of bacteriophage P2.

During the growth of bacteriophage P4, for which the genome of bacteriophage P2 is needed as helper, the decision whether to make large, P2 size, heads or small, P4 size, heads depends on the size-directing function of P4's sid gene and on P2's "sid responsiveness." P2 mutants (=P2 sir) impaired in their response to P4's sid function are readily obtainable as one class of P2 plaque formers selected on certain P4 cl plasmid lysogens. We describe nine P2 sir mutants of independent origin. For eight we could assign their sir mutation to P2 gene N, which encodes the major capsid protein. DNA sequencing indicated an open reading frame of 357 codons for gene N and showed these sir mutations to affect only four codons within a 38-codon segment in the middle of N. Seven mutations are missense mutations (three of them identical); one is a deletion of one codon. There seems to be a correlation between the phenotypic "strength" of the sir mutations and the type of amino acid replacement by missense mutations. Although the weakest mutation, sir7, could not yet be assigned to any P2 gene, it appears clear from this work that P2's N gene product is the major (or only) target of P4's Sid gene function.

An apparent Bacillus subtilis folic acid biosynthetic operon containing pab, an amphibolic trpG gene, a third gene required for synthesis of para-aminobenzoic acid, and the dihydropteroate synthase gene.

McDonald and Burke (J. Bacteriol. 149:391-394, 1982) previously cloned a sulfanilamide-resistance gene, sul, residing on a 4.9-kb segment of Bacillus subtilis chromosomal DNA, into plasmid pUB110. In this study we determined the nucleotide sequence of the entire 4.9-kb fragment. Genes identified on the fragment include pab, trpG, pabC, sul, one complete unidentified open reading frame, and one incomplete unidentified open reading frame. The first three of these genes, pab, trpG, and pabC, are required for synthesis of p-aminobenzoic acid. The trpG gene encodes an amphibolic glutamine amidotransferase required for synthesis of both p-aminobenzoate and anthranilate, the latter an intermediate in the tryptophan biosynthetic pathway. The pabC gene may encode a B. subtilis analog of enzyme X, an enzyme needed for p-aminobenzoate synthesis in Escherichia coli. The sul gene probably encodes dihydropteroate synthase, the enzyme responsible for formation of 7,8-dihydropteroate, the immediate precursor of folic acid. All six of the cloned genes are arranged in a single operon. Since all four of the identified genes are needed for folate biosynthesis, we refer to this operon as a folic acid operon. Expression of the trpG gene is known to be negatively controlled by tryptophan. We propose that this regulation is at the level of translation. This hypothesis is supported by the finding of an apparent Mtr-binding site which overlaps with the trpG ribosome-binding site.

A mutation of the transactivation gene of satellite bacteriophage P4 that suppresses the rpoA109 mutation of Escherichia coli.

Satellite bacteriophage P4 requires the products of the late genes of a helper such as P2 in order to grow lytically. The Escherichia coli rpoA109 mutation, which alters the alpha subunit of RNA polymerase, prevents transcription of the late genes of bacteriophage P2. Suppressor mutations that define the P2 ogr gene overcome this block. We found that P4 lytic growth using a P2 ogr+ prophage helper was prevented by the rpoA109 mutation but that this block was overcome when the P2 helper carried the suppressor mutation in the ogr gene. Furthermore, we isolated and characterized four independent mutations in P4, called org, that suppress the E. coli rpoA109 mutation by allowing P4 lytic growth using a P2 ogr+ helper. DNA sequence analysis revealed that the four independent org mutations are identical and that they occur in the P4 delta gene, which codes for a factor that positively regulates the transcription of the P2 and P4 late genes. delta is predicted to code for a basic 166-amino-acid residue protein. Each 83-residue half of the predicted delta gene product is similar to the predicted 72-residue proteins encoded by the ogr gene of P2 and the B gene of phage 186.

Modifying effect of colicin on experimental Shigella keratoconjunctivitis.

The ability of colicinogenic bacteria and colicin to inhibit Shigella sonnei during the course of infection was studied. Infection of the guinea pig conjunctivae was used as the experimental model. In S. sonnei-infected guinea pig conjunctivae which were treated with a colicinogenic strain of Escherichia coli or with colicin, the number of S. sonnei cells was lower than in animals infected with S. sonnei but not treated. The decrease in the number of pathogenic organisms was associated with absence of disease. A noncolicinogenic strain of E. coli had no effect on production of disease in infected animals. Treatment with a colicinogenic strain of E. coli or colicin did not affect the production of disease or the numbers of organisms in an animal infected with a colicin-resistant strain of S. sonnei.