Cloning and expression of plasmid DNA sequences involved in Salmonella serotype Typhimurium virulence

A 22kb region of the 90kb virulence-associated plasmid, pIP1350, of Typhimurium strain C52 was cloned into the mobilizable vector pSUP202, yielding plasmid pIP1352. This recombinant plasmid restored full virulence to plasmidless strain C53 in a mouse model. Transposon Tn5 insertion mutagenesis demonstrated the existence of two DNA sequences in pIP1352 designated VirA and VirB, both of which are essential for the expression of virulence. A recombinant plasmid containing only the VirA and VirB regions markedly increased the virulence of the plasmidless strain C53, but did not confer full virulence. These results suggested that a third virulence-associated region might be present on pIP1352. Eleven proteins encoded by the 22kb insert sequence of pIP1352 were identified in Escherichia coli SE5000 maxicells. The VirA region encoded at least two proteins with apparent molecular weights of 71,000 and 28,000 and the VirB region encoded two proteins of 43,000 and 38,000.     

Virulent mutants of temperate phage Mu-1

Summary Virulent mutants of phage Mu have been isolated after mutagenesis. The virulent phenotype results from most probably 2 mutations located in the c-A region of the Mu genome.Vir mutants are trans-dominant; they induce the resident prophage upon infection in broth of any Mu lysogen. They however form plaques only on certain lysogens, that are monolysogenic for a mutant prophage. We further isolated secondary mutations in Mu Vir which suppress the virulent phenotype.     

Construction of plasmids that produce phage P22 repressor

In a series of plasmid constructions, the c2 (repressor) gene of phage P22 was cloned in a multicopy plasmid and expressed at increasing level. The final result of these constructions is a plasmid that maintains a level of approx. 200 times as much repressor as is found in a lysogen. A series of increasingly virulent phage mutants was isolated by plating sequentially on host cells with increasing levels of repressor. The methods used in the constructions should be applicable to obtaining elevated expression of cloned genes in other systems.     

Superinfection Exclusion by P22 Prophage and the Replication Complex

Wild-type sie(+) P22 prophage converted Salmonella typhimurium lysogens to exclude deoxyribonucleic acid (DNA) injected by superinfecting phage. DNA from a P22 superinfecting virulent phage associated with the replication complex in a sie(-) lysogen but not in a sie(+) lysogen.     

Role of bacterial virulence proteins in Agrobacterium-mediated transformation of Aspergillus awamori

The Agrobacterium-mediated transformation of Aspergillus awamori was optimized using defined co-cultivation conditions, which resulted in a reproducible and efficient transformation system. Optimal co-cultivation conditions were used to study the role of Agrobacterium tumefaciens virulence proteins in T-DNA transfer. This study revealed that inactivation of either of the regulatory proteins (VirA, VirG), any of the transport pore proteins (VirB), proteins involved in generation of the T-strand (VirD, VirC) or T-strand protection and targeting (VirE2) abolishes or severely reduces the formation of transformants. The results indicate that the Agrobacterium-mediated transformation of A. awamori requires an intact T-DNA machinery for efficient transformation; however, the plant host range factors, like VirE3, VirH, and VirF, are not important.     

Phosphotransferase-mediated regulation of carbohydrate utilization in Escherichia coli K12: location of the gsr (tgs) and iex (crr) genes by specialized transduction

A lysogen of Escherichia coli K12 with lambda cI857 S7 xis6 nin5 b515 b519 integrated into ptsI was induced and the lysates plated on a Pel- host [on which lambda strains with less than the wild-type amount of DNA form plaques at low frequency (Cameron et al., 1977)]. All of the 40 plaques examined contained phage able to transduce at least two of the genes known from bacteriophage P1 transduction experiments to be closely linked to ptsI. Assuming that each specialized transducing phage arose by a single illegitimate recombination event, the distribution of phage types showed that the gene order is cysA gsr ptsI (ptsH, iex) cysZ lig; both gsr+ and iex+ were dominant. Analysis of restriction endonuclease digests of the transducing phage confirmed that no unexpected DNA rearrangements had taken place and allowed the construction of a map of the sites of action of the restriction endonucleases EcoRI, HindIII, BamI and Kpn for over 20 kilobases of E. coli DNA. In an Appendix, we show cysA and cysZ mutants to be deficient in sulphate assimilation.     

Mutant of Salmonella typhimurium That Channels Infecting Bacteriophage P22 Toward Lysogenization

A slowly growing, polymyxin-sensitive mutant of Salmonella typhimurium was isolated. Wild-type phage P22 form plaques on the mutant at 5 x 10(-4), the frequency observed on wild-type hosts. All P22 clear mutants form plaques with near normal frequency. The inability of the mutant to form plaques is correlated with an increase in lysogenization frequency. The cause of the increased lysogenization frequency is not known, but it is not the result of overproduction of cyclic adenosine 5'-monophosphate.     

Transduction by bacteriophage P22 in nonsmooth mutants of Salmonella typhimurium

The general transducing phage P22 attacks only smooth (S) Salmonella with O antigen 12, determined by the oligosaccharide repeating unit constituting the distal part of the somatic lipopolysaccharide (LPS) side chain; non-S mutants, whose LPS contain few or no O repeating units, appear to be resistant. Auxotrophic non-S mutants of Salmonella typhimurium LT2 were tested as transductional recipients. Some transductants (0.5 to 5% as many as from S recipients) were obtained from most semirough recipients, either of class D (presumed leaky rouA mutants) or of a class due to mutation near his (presumed leaky rouB mutants), and from recipients lacking uridine diphosphogalactose epimerase or phosphomannose isomerase. Transductants were not obtained from several rouA, rouB, "heptose-negative," and glucose-1-transferase mutants, nor from most semirough class C mutants, whose LPS side chains each bear a single O oligosaccharide unit. Most transductants evoked from non-S recipients by temperate (c(+)) phage P22 were nonlysogenic, and virulent P22.c2 phage was about as effective as P22.c(+) in transduction to non-S recipients; probably all P22 transducing particles neither lysogenize nor kill. The extended-host-range mutant P22h gave qualitatively similar results,but evoked 5- to 30-fold more transductants from some non-S recipients than did P22. Probably, the LPS of non-S mutants susceptible to transduction contains a few O-specific oligosaccharide units, conferring a slight ability to adsorb P22 and a greater ability to adsorb P22h.     

Genomic Investigation of Lysogen Formation and Host Lysis Systems of the Salmonella Temperate Bacteriophage SPN9CC

To understand phage infection and host cell lysis mechanisms in pathogenic Salmonella, a novel Salmonella enterica serovar Typhimurium-targeting bacteriophage, SPN9CC, belonging to the Podoviridae family was isolated and characterized. The phage infects S. Typhimurium via the O antigen of lipopolysaccharide (LPS) and forms clear plaques with cloudy centers due to lysogen formation. Phylogenetic analysis of phage major capsid proteins revealed that this phage is a member of the lysogen-forming P22-like phage group. However, comparative genomic analysis of SPN9CC with P22-like phages indicated that their lysogeny control regions and host cell lysis gene clusters show very low levels of identity, suggesting that lysogen formation and host cell lysis mechanisms may be diverse among phages in this group. Analysis of the expression of SPN9CC host cell lysis genes encoding holin, endolysin, and Rz/Rz1-like proteins individually or in combinations in S. Typhimurium and Escherichia coli hosts revealed that collaboration of these lysis proteins is important for the lysis of both hosts and that holin is a key protein. To further investigate the role of the lysogeny control region in phage SPN9CC, a ΔcI mutant (SPN9CCM) of phage SPN9CC was constructed. The mutant does not produce a cloudy center in the plaques, suggesting that this mutant phage is virulent and no longer temperate. Subsequent comparative one-step growth analysis and challenge assays revealed that SPN9CCM has shorter eclipse/latency periods and a larger burst size, as well as higher host cell lysis activity, than SPN9CC. The present work indicates the possibility of engineering temperate phages as promising biocontrol agents similar to virulent phages.     

Agrobacterium ParA/MinD-like VirC1 spatially coordinates early conjugative DNA transfer reactions

Agrobacterium tumefaciens translocates T-DNA through a polar VirB/D4 type IV secretion (T4S) system. VirC1, a factor required for efficient T-DNA transfer, bears a deviant Walker A and other sequence motifs characteristic of ParA and MinD ATPases. Here, we show that VirC1 promotes conjugative T-DNA transfer by stimulating generation of multiple copies per cell of the T-DNA substrate (T-complex) through pairwise interactions with the processing factors VirD2 relaxase, VirC2, and VirD1. VirC1 also associates with the polar membrane and recruits T-complexes to cell poles, the site of VirB/D4 T4S machine assembly. VirC1 Walker A mutations abrogate T-complex generation and polar recruitment, whereas the native protein recruits T-complexes to cell poles independently of other polar processing factors (VirC2, VirD1) or T4S components (VirD4 substrate receptor, VirB channel subunits). We propose that A. tumefaciens has appropriated a progenitor ParA/MinD-like ATPase to promote conjugative DNA transfer by: (i) nucleating relaxosome assembly at oriT-like T-DNA border sequences and (ii) spatially positioning the transfer intermediate at the cell pole to coordinate substrate-T4S channel docking.     

ssrA (tmRNA) plays a role in Salmonella enterica serovar Typhimurium pathogenesis

Escherichia coli ssrA encodes a small stable RNA molecule, tmRNA, that has many diverse functions, including tagging abnormal proteins for degradation, supporting phage growth, and modulating the activity of DNA binding proteins. Here we show that ssrA plays a role in Salmonella enterica serovar Typhimurium pathogenesis and in the expression of several genes known to be induced during infection. Moreover, the phage-like attachment site, attL, encoded within ssrA, serves as the site of integration of a region of Salmonella-specific sequence; adjacent to the 5' end of ssrA is another region of Salmonella-specific sequence with extensive homology to predicted proteins encoded within the unlinked Salmonella pathogenicity island SPI4. S. enterica serovar Typhimurium ssrA mutants fail to support the growth of phage P22 and are delayed in their ability to form viable phage particles following induction of a phage P22 lysogen. These data indicate that ssrA plays a role in the pathogenesis of Salmonella, serves as an attachment site for Salmonella-specific sequences, and is required for the growth of phage P22.     

The Salmonella typbimurium RecJ function permits growth of P22 abc phage on recBCD+ hosts

Summary We describe recJ mutants of Salmonella typhimurium. The recJ gene maps between sufD and serA (min 62) and is transcribed counterclockwise. Unlike recJ mutants of Escherichia coli, recJ strains of S. typhimurium are sensitive to irradiation with UV light. This sensitivity is equivalent to or greater that that displayed by recBCD mutant strains. The residual ability of phage P22 abc (anti-recBCD) mutants to form plaques on recBCD ⁺ strains is eliminated in recJ hosts. Thus host RecJ function appears to substitute for the anti-RecBCD functions of phage P22 and may serve to limit RecBCD activity.     

A novel antivirulence element in the temperate bacteriophage HK022.

Lysogens of the temperate lambdoid phage HK022 are immune to superinfection by HK022. Superinfection immunity is conferred in part by the action of the HK022 CI repressor at the O.R operators. In this work, we have identified an additional regulatory element involved in immunity. This site, termed OFR (operator far right), is located just downstream of the cro gene, more than 250 nucleotides distant from OR. The behavior of phage containing a mutation in OFR suggests that the wild-type site functions as an antivirulence element. HK022 OFR- mutants were able to form turbid plaques indistinguishable from those of the wild type. However, they gave rise to virulent derivatives at a far higher frequency than the wild type (approximately 10(-5) for OFR- versus about 10(-9) for the wild type). This frequency was so high that cultures of HK022 OFR- lysogens were rapidly overgrown by virulent derivatives. Whereas virulent mutants arising from a wild-type OFR+ background contained mutations in both OR1 and OR2, virulent derivatives of the OFR- mutant phage contained a single mutation in either OR1 or OR2. We conclude that the wild-type OFR site functions to prevent single mutations in OR from conferring virulence. The mechanism by which OFR acts is not yet clear. Both CI and Cro bound to OFR and repressed a very weak rightward promoter (PFR). It is unlikely that repression of PFR by CI or Cro binding to OFR can account in full for the antivirulence phenotype conferred by this element, since PFR is such a weak promoter. Other models for the possible action of OFR are discussed.     

A membrane protein is required for bacteriophage c2 infection of Lactococcus lactis subsp. lactis C2.

Phage-resistant mutants, isolated from cultures of Lactococcus lactis subsp. lactis C2 infected with phage c2, did not form plaques but bound phage normally. The mutants were sensitive to another phage, sk1, although the number of plaques was reduced approximately 56% and the plaques were four times smaller. Binding to phage sk1 was reduced about 10%. Another group of phage-resistant mutants, isolated from cultures infected with phage sk1, bound normally to both phages c2 and sk1 but did not form plaques with either phage. Carbohydrate analyses by gas chromatography of the cell walls showed no significant differences in saccharide compositions between the wild-type and phage-resistant cells. However, a difference was observed in the interactions of the phage with the cytoplasmic membranes. Membranes from the wild-type cells, but not mutant cells, inactivated phage c2. Phage sk1 was not inactivated by membrane from either strain. Treatment of wild-type membranes with proteinase K eliminated the ability of the membrane to inactivate the phage, whereas treatment with mutanolysin had no effect. On the basis of this ability to inactivate the phage, a membrane protein was partially purified by gel filtration and ion-exchange chromatography. Under nondenaturing conditions, the phage-inactivating protein has an apparent Mr of approximately 350,000. The protein has an apparent subunit size of 32 kDa, which suggests that it normally exists as a multimer with 10 to 12 subunits or in association with other membrane components. It is proposed that this protein is required for phage c2 infection.     

Inhibitory Effect of Bacteriophage P22 Infection on Host Cell Deoxyribonuclease Activity

Infection of Salmonella typhimurium with phage P22 causes a decrease in the activity of host deoxyribonuclease which degrades single-stranded deoxyribonucleic acid (DNA). This decrease is reversed when the infecting phage is P22c(+); it is not reversed if the infecting phage kills the cell. The decrease does not occur in infections with P22ts25.1 (which only adsorbs and injects DNA) or in infections of a lysogen by a nonvirulent phage. It does occur, however, after infections with other phages which are blocked in phage DNA synthesis. Inhibiting protein synthesis with chloramphenicol does not in itself cause the decrease in uninfected cells, but it does prevent infected cells from showing this effect.     

Isolation and preliminary characterisation of twenty-five temperature-sensitive mutants of mouse cytomegalovirus

Abstract To study the pathogenicity of mouse cytomegalovirus (MCMV) and to identify virulence determinants, we have isolated and phenotypically characterised 25 temperature-sensitive ( ts ) mutants. Six of these ( tsm 9, tsm 13, tsm 20, tsm 22, tsm 28 and tsm 30) failed to replicate in mice and were avirulent. Five mutants ( tsm 14, tsm 18, tsm 19, tsm 25 and tsm27 ) were to similar virulence to the parenthal wild-type ( wt ) virus, five ( tsm 7, tsm 15, tsm 24, tsm31 ) were 12–100 fold less virulent, five ( tsm 8, tsm 12, tsm 16, tsm 23 and tsm 29) were 150–1500 fold less virulent and four ( tsm 10, tsm 11, tsm 17 and tsm 21) were between 2,000 and 85,000 fold less virulent than wt . One mutant ( tsm 28) did not plaque or replicate at 39°C while 5 other mutants ( tsm 7, tsm 9, tsm 23, tsm 24 and tsm 27) also failed to plaque at 39°C but only failed to replicate or replicated poorly at 40°C. A further two mutants ( tsm 10 and tsm 13) were able to plaque and replicate at 39°C but not 40°C. Six other mutants ( tsm 14, tsm 15, tsm 16, tsm21 , tsm 22 and tsm 30) failed to form plaques at 40°C and were severely restricted in their replication at 40°C. The remaining 11 mutants exhibited varying degrees of restriction in ability to plaque and/or replicate at non-permissive temperatures. These 25 mutants, together with 6 isolated previously, comprise at least 24 complementation groups.     

Control of lysogenization by phage P22 I. The P22 cro gene

P22 cro^? mutants were isolated as one class of phage P22 mutants (cly mutants) that have a very high frequeney of lysogeny relative to wild-type P22. These mutants: (1) do not form plaques and over-lysogenize relative to wild-type P22 after infection of a wild-type Salmonella host; (2) are defective in anti-immunity; and (3) fail to turn off high-level synthesis of P22 c2-repressor after infection.P22 cro^? mutations are recessive and map between the P22 c2 and c1 genes. P22 cro^? mutations are suppressed by clear-plaque mutations in the c1 gene, one of which is simultaneously cy^?. They are also suppressed, but incompletely, by mutations in the c2 (repressor) gene, especially those that do not completely abolish c2 gene function.Salmonella host mutants have been isolated that are permissive for the lytic growth of the P22 cro^? mutants.     

Method for isolating restriction- and modificationless mutants of Escherichia coli K-12.

A simple method is described for the selection and isolation of restriction- and modificationless mutants in Escherichia coli K-12 by using the following properties: (i) the temperature-sensitive repressor activity of phage lambdacI857; (ii) a mutant of lambda phage defective in integration and the establishment of repression (lambdab2cI); (iii) a virulent lambda phage insensitive to the repressor activity. The final yield of spontaneously arising rk-mk+ and rk-mk- mutants from stationary-phase cultures was about 5% of the surviving cells.     

Specific Lysogenicity in Streptomyces azureus

Slope (or plate) cultures of thiostrepton-producing Streptomyces azureus (ATCC 14921) often showed spontaneously developing plaques. Plaques increased in number during serial subcultures. The production of aerial mycelia and sporulating aerial hyphae was interrupted by the overlapping plaques, whereas the growth of substrate mycelia continued in the plaques. These abnormal (eroded) cultures were easily restored to their normal conditions once they were passed through liquid cultures under shaking conditions. A few phage particles were found in the plaques, together with some headless tails and numerous tail tips which formed a hexagonal crystal or a large crystal mass when viewed in an electron microscope. No lytic phenomenon and no phage production were found in the liquid cultures, although all mycelia and spores harbored phage-producing abilities. It was also found that the propagation of phages was successful in solid culture, but not in liquid culture. The whole phage was named SAt2, which belongs to group B of Bradley's morphological classification. From these results, it is considered that S. azureus is lysogenic with temperate phage SAt2, of which virulent mutants are able to infect the aerial mycelia and sporulating hyphae of their lysogenic host.