DNA-binding activity of the Streptococcus thermophilus phage Sfi21 repressor

The cloned Streptococcus thermophilus phage Sfi21 repressor open reading frame (orf) 127 gp protects a cell against superinfection with the homologous temperate, but not against virulent phages. As demonstrated by DNase protection assay and gel shift experiments, the repressor binds to a 25-bp operator site located upstream of the repressor gene. A second sequence-related operator was identified 265 bp apart at the 3'-end of orf 75, the topological equivalent of a cro repressor gene. The replacement of a bp at the middle or at the right side of the operator decreased substantially the affinity of the repressor for the operator. In gel shift assays, the 75 gp did not bind DNA from the genetic switch region. However, when increasing amounts of orf 75 gp containing cell extracts were added to orf 127 gp containing cell extracts, the repressor could no longer bind its operator site.     

Complete genomic sequence of the lytic bacteriophage DT1 of Streptococcus thermophilus

Streptococcus thermophilus lytic bacteriophage DT1, isolated from a mozzarella whey, was characterized at the microbiological and molecular levels. Phage DT1 had an isometric head of 60 nm and a noncontractile tail of 260 x 8 nm, two major structural proteins of 26 and 32 kDa, and a linear double-stranded DNA genome with cohesive ends at its extremities. The host range of phage DT1 was limited to 5 of the 21 S. thermophilus strains tested. Using S. thermophilus SMQ-301 as a host, phage DT1 had a burst size of 276 +/- 36 and a latent period of 25 min. The genome of phage DT1 contained 34,820 bp with a GC content of 39.1%. Forty-six open reading frames (ORFs) of more than 40 codons were found and putative functions were assigned to 20 ORFs, mostly in the late region of phage DT1. Comparative genomic analysis of DT1 with the completely sequenced S. thermophilus temperate phage O1205 revealed two large homologous regions interspersed by two heterologous segments. The homologous regions consisted of the early replication genes, the late morphogenesis genes, and the lysis cassette. The divergent segments contained the DNA packaging machinery, the major structural proteins, and remnants of a lysogeny module.     

Biology of the temperate Streptococcus thermophilus bacteriophage TP-J34 and physical characterization of the phage genome

The temperate Streptococcus thermophilus bacteriophage TP-J34 was identified in the lysogenic host strain J34. The majority of phage particles produced upon induction was defective and noninfectious, consisting of DNA-filled heads lacking tails. A physical map (45.6 kb) was established. Analysis of minor restriction bands of the DNA isolated from phage particles as well as the analysis of the protein pattern indicated that phage TP-J34 is a pac-type phage. This was confirmed by immunoelectron microscopy using antisera raised against virulent cos- and pac-type S. thermophilus phages. The lysogenic host J34 but not its noninducible derivate J34-12 contained phage DNA in the nonintegrated state and exhibited autolysis at elevated temperatures. Prophage-carrying strains grew homogeneously while 16 of 20 prophage-cured derivatives aggregated and sedimented rapidly. When phage TP-J34 was propagated lytically on a prophage-cured host strain, a 2.7-kb site-specific deletion occurred in the phage genome. This deletion was also identified in the prophage DNAs of relysogenized strains.     

Nucleotide sequence of the bacteriophage P22 genes required for DNA packaging.

The mechanism of DNA packaging by dsDNA viruses is not well understood in any system. In bacteriophage P22 only five genes are required for successful condensation of DNA within the capsid. The products of three of these genes, the portal, scaffolding, and coat proteins, are structural components of the precursor particle, and two, the products of genes 2 and 3, are not. The scaffolding protein is lost from the structure during packaging, and only the portal and coat proteins are present in the mature virus particle. These five genes map in a contiguous cluster at the left end of the P22 genetic map. Three additional genes, 4, 10, and 26, are required for stabilizing of the condensed DNA within the capsid. In this report we present the nucleotide sequence of 7461 bp of P22 DNA that contains the five genes required for DNA condensation, as well as a nonessential open reading frame (ORF109), gene 4, and a portion of gene 10. N-terminal amino acid sequencing of the encoded proteins accurately located the translation starts of six genes in the sequence. Despite the fact that most of these proteins have striking analogs in the other dsDNA bacteriophage groups, which perform highly analogous functions, no amino acid sequence similarity between these analogous proteins has been found, indicating either that they diverged a very long time ago or that they are the products of spectacular convergent evolution.     

Head morphogenesis of bacteriophage T4 III. The role of gene 20 in DNA packaging

The product of gene 20 plays two important roles in bacteriophage T4 head formation: first, in the formation of the prehead assembly initiation complex, second, in the packaging of DNA into the cleaved head. The second function was revealed after the isolation of a cold-sensitive (cs) mutant of gene 20. Empty, fully cleaved heads accumulating in 20cs-infected cells can be packaged with DNA to form mature phage after shift up to 42°. The accumulation of 200 S DNA and the formation of empty phages (ghosts) in the 20cs-infected cells suggest that 20cs empty heads are not attached to concatemeric DNA inside the cell. The phenotype of the 20cs mutation resembles that of 17ts or 17am mutations and a second site suppressor mutation in gene 17 was found which overcomes the 20cs mutation. These results suggest an intimate relationship between these two gene products which probably interact directly during DNA packaging. Both p17 and p20 also appear to be involved in collar and whisker assembly, suggesting location of p20 at the head-tail juuction.     

Complete genomic nucleotide sequence and analysis of the temperate bacteriophage VWB

The entire double-stranded DNA genome of the Streptomyces venezuelae bacteriophage VWB was sequenced and analyzed. Its size is 49,220 bp with an overall molar G + C content of 71.2 mol%. Sixty-one potential open reading frames were identified and annotated using several complementary bioinformatics tools. Clusters of functionally related putative genes were defined, supporting a refined version of the modular theory of phage evolution.     

Maturation of the head of bacteriophage T4: 9-aminoacridine blocks a late step in DNA packaging.

9-Aminoacridine (9AA) reversibly inhibits bacteriophage T4 maturation. In the presence of 9AA, cells infected with bacteriophage T4 accumulate an intermediate similar to prohead III on the maturation pathway described by Laenmmli and Favre (J. Mol. Biol., 80, 575–599, 1973). This particle sediments at 550 S if cells are lysed under conditions that help to preserve fragile intermediates. This particle contains about half the normal complement of DBA and is bound to the replicative DNA. The completion of the DNA packaging process occurs following removal of 9AA. This was demonstrated by estimating the amount of newly synthesized DNA packaged into these particles after 9AA removal, using 5-bromo-2′-deoxyuridine as a label. Light inactivation studies showed that 75% of the particles packaged an average of at least 12% of their DNA after 9AA removal. Cleavage of the various head proteins that normally occur during maturation is not affected by 9AA, and the particles which accumulate in cells blocked with 9AA contain the same proteins found in mature heads.     

Nucleotide sequence of the genes encoding the major tail sheath and tail tube proteins of bacteriophage P2.

The major structural components of the contractile tail of bacteriophage P2 are proteins FI and FII, which are believed to be the tail sheath and tube proteins, respectively. Both proteins were mapped previously to the P2 late gene F, based on the pattern of protein synthesis in various P2 amber mutants. In order to clarify the gene arrangement and to provide a basis for structural comparisons with other contractile phage tails, we have determined the nucleotide sequence of the region of the P2 genome encoding these two proteins. The coding regions were confirmed by location of the Fam4 mutation and by N-terminal amino acid sequencing of both proteins. The molecular weight and amino acid composition predicted by each of the coding regions correspond well to those determined experimentally for each protein. FII is encoded by a newly identified P2 late gene. These proteins bear little resemblance to their functional homologues in bacteriophage T4.     

Complete genomic sequence analysis of the temperate bacteriophage phiSASD1 of Streptomyces avermitilis

The bacteriophage phiSASD1, isolated from a failed industrial avermectin fermentation, belongs to the Siphoviridae family. Its four predominant structural proteins, which include the major capsid, portal and two tail-related proteins, were separated and identified by SDS-PAGE and N-terminal sequence analysis. The entire double-stranded DNA genome of phiSASD1 consists of 37,068 bp, with 3'-protruding cohesive ends of nine nucleotides. Putative biological functions have been assigned to 24 of the 43 potential open reading frames. Comparative analysis shows perfect assembly of three “core” gene modules: the morphogenesis and head module, the tail module and the right arm gene module, which displays obvious similarity to the right arm genes of Streptomyces phage phiC31 in function and arrangement. Meanwhile, structural module flexibility within phiSASD1 suggests that assignment of phage taxonomy based on comparative genomics of structural genes will be more complex than expected due to the exchangeability of functional genetic elements.     

Comparative Sequence Analysis of the DNA Packaging, Head, and Tail Morphogenesis Modules in the Temperate cos-Site Streptococcus thermophilus Bacteriophage Sfi21

The temperate Streptococcus thermophilus bacteriophage Sfi21 possesses 15-nucleotide-long cohesive ends with a 3′ overhang that reconstitutes a cos-site with twofold hyphenated rotational symmetry. Over the DNA packaging, head and tail morphogenesis modules, the Sfi21 sequence predicts a gene map that is strikingly similar to that of lambdoid coliphages in the absence of any sequence similarity. A nearly one to one gene correlation was found with the phage lambda genes Nu1 to H, except for gene B-to-E complex, where the Sfi21 map resembled that of coliphage HK97. The similarity between Sfi21 and HK97 was striking: both major head proteins showed an N-terminal coiled-coil structure, the mature major head proteins started at amino acid positions 105 and 104, respectively, and both major head genes were preceded by genes encoding a possible protease and portal protein. The purported Sfi21 protease is the first viral member of the ClpP protease family. The prediction of Sfi21 gene functions by reference to the gene map of intensively investigated coliphages was experimentally confirmed for the major head and tail gene. Phage Sfi21 shows nucleotide sequence similarity with Lactococcus phage BK5-T and a lactococcal prophage and amino acid sequence similarity with the Lactobacillus phage A2 and the Staphylococcus phage PVL. PVL is a missing link that connects the portal proteins from Sfi21 and HK97 with respect to sequence similarity. These observations and database searches, which demonstrate sequence similarity between proteins of phage from gram-positive bacteria, proteobacteria, and Archaea, constrain models of phage evolution.     

Analysis of the complete DNA sequence of the temperate bacteriophage TP901-1: evolution, structure, and genome organization of lactococcal bacteriophages

A complete analysis of the entire genome of the temperate lactococcal bacteriophage TP901-1 has been performed and the function of 21 of 56 TP901-1-encoded ORFs has been assigned. This knowledge has been used to propose 10 functional modules each responsible for specific functions during bacteriophage TP901-1 proliferation. Short regions of microhomology in intergenic regions present in several lactococcal bacteriophages and chromosomal fragments of Lactococcus lactis are suggested to be points of exchange of genetic material through homologous recombination. Our results indicate that TP901-1 may have evolved by homologous recombination between the host chromosome and a mother phage and support the observation that phage remnants as well as prophages located in the Lactococcus chromosome contribute significantly to bacteriophage evolution. Some proteins encoded in the early transcribed region of the TP901-1 genome were more homologous to proteins encoded by phages infecting gram-positive hosts other than L. lactis. This protein homology argues for the occurrence of horizontal genetic exchange among these bacteriophages and indicates that they have access to a common gene pool.     

Intracellular morphogenesis of bacteriophage T4. I. Gene dosage effects on early functions and tail fiber assembly

Mixed infection of nonpermissive bacteria by amber mutant and wild-type T4 phage reduces the burst size in a manner that depends on the nature of the gene product eliminated by the mutation. While the genotypic proportions produced by such mixedly infected cells were directly proportional to those in the starting mixtures, the fraction of the burst size compared to wild-type-infected cells was dependent on the kind of mutant used. For example, mutants in genes 56, 42, and 43, which control catalytic functions for DNA synthesis, produced normal burst sizes even at ratios of four mutant to one wild-type phage. The multiplicity of infection in these experiments was near 20, and most cells received one wild-type phage. By contrast, infection with mutants in tail fiber structural genes gave a normal burst size with 1:1 mixtures of wild-type phage, but showed a decrease in burst size below this ratio. The conclusions drawn are that enzymes of DNA replication are present in large excess over the amount needed for phage DNA synthesis, and that tail fiber structural proteins are made in a three- to fourfold excess over the amount needed for phage maturation under normal laboratory conditions.     

Comparative DNA sequence analysis of wheat and rice genomes

The use of DNA sequence-based comparative genomics for evolutionary studies and for transferring information from model species to crop species has revolutionized molecular genetics and crop improvement strategies. This study compared 4485 expressed sequence tags (ESTs) that were physically mapped in wheat chromosome bins, to the public rice genome sequence data from 2251 ordered BAC/PAC clones using BLAST. A rice genome view of homologous wheat genome locations based on comparative sequence analysis revealed numerous chromosomal rearrangements that will significantly complicate the use of rice as a model for cross-species transfer of information in nonconserved regions.     

Role of exonuclease in the specificity of bacteriophage T7 DNA packaging

During morphogenesis in vivo, bacteriophage T7 packages and cuts to mature size an end-to-end concatemer of its nonpermuted, terminally repetitious, double-stranded, mature DNA. Efficient production (90-100%) and packaging (20-35%) of concatemers has also been demonstrated in extracts of T7-infected cells (in vitro) (Son, M., Hayes, S. J., and Serwer, P. [1988] Virology 162, 38-46). By use of both this procedure of in vitro DNA packaging and in-gel hybridization to packaged DNA fractionated by agarose gel electrophoresis, the specificity of packaging in vitro is found to depend on the presence of T7 gene 6 exonuclease (p6). In the absence of p6 in vitro, no concatemerization is detected and packaging of DNA nonhomologous to T7 DNA (bacteriophage P22 DNA) is as efficient (0.05-1.1%) as the packaging of monomeric T7 DNA. Addition of p6 in vitro both stimulates the concatemerization-packaging of T7 DNA and suppresses the packaging of P22 DNA. The packaging efficiency for concatemeric T7 DNA is 29-611 x higher than that for monomeric T7 DNA. Inhibition of the packaging of P22 DNA by p6 is correlated with the formation of single-stranded P22 DNA ends. These data are explained by the hypothesis that a DNA molecule with a single-stranded end is packaged less efficiently than the same DNA without the single-stranded end. Testing this hypothesis in vivo reveals that both p6 and gene 3 endonuclease contribute to suppressing the packaging of host DNA.     

Morphology of temperate bacteriophage SfV and characterisation of the DNA packaging and capsid genes: the structural genes evolved from two different phage families

The entire genome of SfV, a temperate serotype-converting bacteriophage of Shigella flexneri, has recently been sequenced (Allison, G.E., Angeles, D., Tran-Dinh, N., Verma, N.K. 2002, J. Bacteriol. 184, 1974-1987). Based on the sequence analysis, we further characterised the SfV virion structure and morphogenesis. Electron microscopy indicated that SfV belongs to the Myoviridae morphology family. Analysis of the proteins encoded by orf1, orf2, and orf3 revealed that they were homologous to small and large terminase subunits, and portal proteins, respectively; the protein encoded by orf5 showed homology to capsid proteins. Western immunoblot of the phage with anti-SfV sera revealed two antigenic proteins, and the N-terminal amino acid sequence of the 32-kDa protein corresponded to amino acids 116 to 125 of the ORF5 protein, suggesting that the capsid may be processed. Functional analysis of orf4 showed that it encodes the phage capsid protease. The proteins encoded by orfs1, 2, 3, 4, and 5 are homologous to similar proteins in the Siphoviridae phage family of both gram-positive and gram-negative origin. The capsid and morphogenesis genes are upstream and adjacent to the genes encoding Myoviridae (Mu-like) tail proteins. The organisation of the structural genes of SfV is therefore unique as the head and tail genes originate from different morphology groups.     

Mutational analysis of two structural genes of the temperate lactococcal bacteriophage TP901-1 involved in tail length determination and baseplate assembly

Two putative structural genes, orf tmp (tape measure protein) and orf bpp (baseplate protein), of the temperate lactococcal phage TP901-1 were examined by introduction of specific mutations in the prophage strain Lactococcus lactic ssp. cremoris 901-1. The adsorption efficiencies of the mutated phages to the indicator strain L. lactic ssp. cremoris 3107 were determined and electron micrographs were obtained. Specific mutations in orf tmp resulted in the production of mostly phage head structures without tails and a few wild-type looking phages. Furthermore, construction of an inframe deletion or duplication of 29% in orf tmp was shown to shorten or lengthen the phage tail by approximately 30%, respectively. The orf tmp is proposed to function as a tape measure protein, TMP, important for assembly of the TP901-1 phage tail and involved in tail length determination. Specific mutations in orf bpp produced phages which were unable to adsorb to the indicator strain and electron microscopy revealed particles lacking the baseplate structure. The orf bpp is proposed to encode a highly immunogenic structural baseplate protein, BPP, important for assembly of the baseplate. Finally, an assembly pathway of the TP901-1 tail and baseplate structure is presented.     

Late stages in bacteriophage lambda head morphogenesis: in vitro studies on the action of the bacteriophage lambda D-gene and W-gene products

The in vitro maturation of bacteriophage lambda can be divided into discrete steps. Concatemers of lambda DNA bind terminase to form complex I. This DNA-terminase complex then binds a prohead to form a ternary complex (II). Complex II in turn can be converted to infectious phage by the addition of extracts containing the products of the phage genes D, W, FII, as well as phage tails. By using in vitro complementation assays gpD and gpW have been partially purified and their interactions with complex II studied. gpD can bind to complex II in vitro to form a new complex (III) which can be isolated by sedimentation on neutral sucrose gradients. This complex requires only the addition of gpW, gpFII, and phage tails to form mature phage particles. The sedimentation of complex III is virtually identical to that of complex II; however, the resistance of the former to inactivation by DNase is higher, likely due to the partial packaging of the DNA. In similar experiments it was shown that gpW cannot bind to complex II but can effectively interact with complex III. This latter reaction converts complex III to a DNase-resistant form which sediments in a manner identical to that of full phage heads (complex IV). After isolation of the complex IV only gpFII and tails are required for mature phage formation in vitro. gpW is a heat-stable protein of molecular weight approximately 10,000.     

Comparative analysis of the localization of lipoteichoic acid in Streptococcus agalactiae and Streptococcus pyogenes.

The cellular locations of deacylated lipoteichoic acid (dLTA) and lipoteichoic acid (LTA) were examined in late-exponential-phase cells of a serotype III strain of Streptococcus agalactiae (group B streptococci [GBS]) isolated from an infant with late-onset meningitis and compared with a fresh clinical isolate of Streptococcus pyogenes (group A streptococci [GAS]). LTA and dLTA were found to be associated with the protoplast membranes of both organisms, with only dLTA found in mutanolysin cell wall digests. Both organisms released dLTA during growth, but only the GAS released substantial levels of LTA into the culture medium. However, penicillin treatment (5 micrograms/ml for 60 min) of GBS resulted in the recovery of LTA in cell wall digests as well as in the culture medium. These results suggest that under normal growth conditions, the hydrophobic region (glycolipid) of LTA remains associated with the cytoplasmic membrane of GBS and unavailable for hydrophobic interactions at the cell surface with epithelial cells. In contrast, release of LTA into the environment by the GAS allows the fatty acid moieties to interact with hydrophobic domains on the surface of epithelial cells. These results may help explain the marked differences in the specificity of binding between these two major streptococcal pathogens for human fetal and adult epithelial cells.