Molecular analysis of the UV protection and mutation genes carried by the I incompatibility group plasmid TP110.

The abortive infection of bacteriophage T7 in Shigella sonnei D2 371-48 is characterized by a premature inhibition of phage DNA replication and nucleolytic breakdown of all phage DNA. Mutations in T7 gene 10 which are recessive to the presence of the wild-type allele can alleviate the restriction of phage growth. Phage T3 productively infects S. sonnei D2 371-48, as does a T7-T3 hybrid phage that contains, in particular, a gene 10 of T7 origin. It is the presence of T3 DNA ligase that allows phage growth on S. sonnei D2 371-48, and this enzyme can also rescue wild-type T7 from the abortive infection. T7+ is therefore functionally ligase deficient during the infection of S. sonnei D2 371-48; this deficiency is a result of the expression of the phage capsid protein, but it is independent of the assembly of the protein into a procapsid or other morphogenetic structure.     

A single-base change in gene 10 of bacteriophage T7 permits growth on Shigella sonnei.

Bacteriophage T7 can extend its host range to include Shigella sonnei D2 371-48 by a mutation called ss found in the T7 major capsid protein, the gene 10 product. We show that a single A-to-C transversion at position 23150 in the T7 genome is responsible for the T7 ss mutant phenotype that allows the phage to avoid DNA degradation and undergo productive infection. The ss mutation causes an amino acid substitution of proline for glutamine at position 61 of the 344-amino-acid T7 major capsid protein.     

Physiological and Genetic Aspects of Abortive Infection of a Shigella sonnei Strain by Coliphage T7

Phage T7 adsorbed to and lysed cells of Shigella sonnei D(2) 371-48, although the average burst size was only 0.1 phage per cell (abortive infection). No mechanism of host-controlled modification was involved. Upon infection, T7 rapidly degraded host deoxyribonucleic acid (DNA) to acid-soluble material. Phage-directed DNA synthesis was initiated normally, but after a few minutes the pool of phage DNA, including the parental DNA, was degraded. Addition of chloramphenicol, at the time of phage infection, prevented both the initiation of phage-directed DNA synthesis and the degradation of parental phage DNA. Addition of chloramphenicol 4.5 min after phage was added permitted the onset of phage-directed DNA synthesis but prevented breakdown of phage DNA. Mutants of T7 (ss(-) mutants) have been isolated which show normal growth in strain D(2) 371-48. Upon mixed infection of this strain with T7 wild type and an ss(-) mutant, infection was abortive; no complementation occurred. The DNA of the ss(-) mutants was degraded in mixed infection like that of the wild type. Revertant mutants which have lost their ability to grow on D(2) 371-48 were isolated from ss(-) mutants; they are, in essence, phenotypically like T7 wild type. Independently isolated revertants of ss(-) mutants did not produce ss(-) recombinants when they were crossed among themselves. When independently isolated ss(-) mutants were crossed with each other, wild-type recombinants were found; ss(-) mutants could then be mapped in a cluster compatible with the length of one cistron. We concluded that T7 codes for an active, chloramphenicol-sensitive function [ss(+) function (for suicide in Shigella)] which leads to the breakdown of phage DNA in the Shigella host.     

Complete genomic sequence of the lytic bacteriophage phiYeO3-12 of Yersinia enterocolitica serotype O:3

phiYeO3-12 is a T3-related lytic bacteriophage of Yersinia enterocolitica serotype O:3. The nucleotide sequence of the 39,600-bp linear double-stranded DNA (dsDNA) genome was determined. The phage genome has direct terminal repeats of 232 bp, a GC content of 50.6%, and 54 putative genes, which are all transcribed from the same DNA strand. Functions were assigned to 30 genes based on the similarity of the predicted products to known proteins. A striking feature of the phiYeO3-12 genome is its extensive similarity to the coliphage T3 and T7 genomes; most of the predicted phiYeO3-12 gene products were >70% identical to those of T3, and the overall organizations of the genomes were similar. In addition to an identical promoter specificity, phiYeO3-12 shares several common features with T3, nonsubjectibility to F exclusion and growth on Shigella sonnei D(2)371-48 (M. Pajunen, S. Kiljunen, and M. Skurnik, J. Bacteriol. 182:5114-5120, 2000). These findings indicate that phiYeO3-12 is a T3-like phage that has adapted to Y. enterocolitica O:3 or vice versa. This is the first dsDNA yersiniophage genome sequence to be reported.     

Construction of a trivalent candidate vaccine against Shigella species with DNA recombination

In this work asd gene of Shigella flexneri 2a strain T32 was replaced by Vibrio cholerae toxin B subunit (ctxB) gene with DNA recombination in vivo and in vitro. The resulting derivative of T32, designed as FWL01, could stably express CtxB, but its growth in LB medium depended on the presence of diaminopimelic acid (DAP). Then form I plasmid of Shigella sonnei strain S7 was labeled with strain T32 asd gene and mobilized into FWL01. Thus a trivalent candidate oral vaccine strain, designed as FSW01, was constructed. In this candidate strain, a balanced-lethal system was constituted between the host strain and the form I plasmid expressing S, sonnei O antigen. Therefore the candidate strain can express stably not only its own O antigen but also CtxB and O antigen of S. sonnei in the absence of any antibiotic. Experiments showed that FSW01 did not invade HeLa cells or cause keratoconjunctivitis in guinea pigs. However, rabbits immunized FSW01 can elicit significant immune responses. In mice and rhesus monkey     

Acid tolerance of Shigella sonnei and Shigella flexneri

AIMS: Determination of the behaviour of Shigella sonnei and Sh. flexneri under acid conditions. METHODS AND RESULTS: The growth and survival of Shigella spp. (9 isolates) in acidified Brain Heart Infusion (BHI) (pH 5.0-3.25 with pH intervals of 0.25) was determined after 6, 24 and 30 h incubation at 37 degrees C. Subsequently, survival of shigellae was studied in apple juice and tomato juice stored at 7 degrees C and 22 degrees C for up to 14 days and in strawberries and a fresh fruit salad, kept at 4 degrees C for 4 and 48 h. CONCLUSIONS: The minimum pH for growth in acidified BHI for Sh. flexneri and Sh. sonnei was, respectively, pH 4.75 and pH 4.50. Survival in fruit juices and fresh fruits depended upon their pH, the type of strain and the incubation temperature. Shigella spp. Survived for up to 14 days in tomato juice and apple juice stored at 7 degrees C. The shortest survival time (2-8 d) was observed in apple juice at 22 degrees C. Sh. sonnei but not Sh. flexneri was recovered after 48 h from strawberries and fruit salad kept at 4 degrees C. SIGNIFICANCE AND IMPACT OF THE STUDY: Acid foods, especially if kept at refrigeration temperatures, support survival of Shigella spp. and may cause Shigella food poisoning.     

稳定、无抗药的痢疾福氏2a和宋内双价菌苗候选株的构建

通过体内外基因重组,将大肠杆菌粘附因子cs3基因定位整合到痢疾杆菌福氏2a疫苗株T32菌染色体的asd基因内,使asd基因灭活;将来内O抗原基因克隆至无抗药性表达载体pXL378,获得重组质粒pXL390,将其转化asd-的T32受体菌,构建成福氏2a和宋内双价苗苗株FS01。实验表明:重组质粒pXL390在不带任何抗菌素基因的情况下,在asd-的T32受体菌内是稳定的。FS01株遗传稳定,能表达两种痢疾菌的PLS-O抗原,无明显毒性作用。动物试验表明,以FS01株皮下免疫的小鼠对福氏2a和宋内有毒株的腹腔攻击有100％的保护。     

Differentiation of Shigella strains by plasmid profile analysis, serotyping and phage typing

Ninety-one Shigella flexneri and 29 Shigella sonnei strains isolated during 1994 from sporadic cases of shigellosis and healthy carriers were analyzed for plasmid profile in order to compare the discriminating ability of this method with that of serotyping and phage typing. Our study revealed 10 plasmid profiles (PP) among S. sonnei strains. A total of 26 out of 29 (89%) S. sonnei isolates could be placed into two phage types (type 1 and 20) comprising four PP for phage type 1 and seven PP for type 20, respectively. Twenty-three different PP were identified among S. flexneri strains. Each serotype was associated with a specific predominant plasmid profile, except serotype 2a. This serotype, the most frequently isolated in Romania, was still rather homogeneous: 33 out of 39 isolates belonged to phage type 125, 27 of which could be placed into two related PP (F10 and F17). Comparison of plasmid patterns of epidemiologically independent S. flexneri serotype 2a isolates with those exhibited by 45 serotype 2a isolates associated to six independent outbreaks revealed the same homogeneity. Thirty-eight strains, representing 4 of 6 outbreaks, had F10 and F17 plasmid patterns. The discrimination indices (D) for plasmid profile analysis alone (D = 0.890) and for the combination of serotyping and phage typing (D = 0.841) indicate that both typing systems have a nearly similar ability of discriminating among S. flexneri strains. By combining the results of the three typing methods, a total of 42 types are distinguished and the D value is 0.942. Our data suggest that plasmid profile analysis can complement phenotyping methods resulting in a degree of discrimination that cannot be achieved by either system alone.     

Bacteriophage Tail Components V. Complementation of T4D Gene 28?-Infected Bacterial Extracts with Pteroyl Hexaglutamate

Synthetic pteroyl hexaglutamate (9 x 10(-6) M) stimulated the formation of new T4D particles in vitro in extracts of Escherichia coli B infected with T4D gene 28(-). The stimulation was specific for this form of folic acid since neither pteroyl pentaglutamate nor pteroyl heptaglutamate stimulated phage formation. T4D formation in vitro in E. coli B extracts prepared after infection with 11 other phage mutants known to be involved in phage tail plate formation (5(-), 6(-), 7(-), 8(-), 10(-), 25(-), 26(-), 27(-), 29(-), 51(-), 53(-)) was not stimulated by the addition of pteroyl hexaglutamate. It can be concluded that the T4D gene 28 product is involved in the formation of the phage tail plate pteroyl hexaglutamate.     

Construction of a trivalent candidate Shigella vaccine strain with host-vector balanced-lethal system

A trivalent live Shigella vaccine candidate FSD01 against S. flexneri 2a, S. sonnei and S. dysen-teriae I was constructed. This candidate strain was based on the S. flexneri 2a vaccine T32. By homologous recombi-nation exchange, the chromosomal asd gene of T32 was site-specifically inactivated, resulting in the strain unable to grow normally in LB broth, while another asd gene of S. mutans was employed to construct an Asd complementary vector. This combination of asd 'host/ Asd vector formed a balanced-lethal expression system in T32 strain. By use of this system, two important protective antigen genes coding for S. sonnei Form I antigen and Shiga toxin B subunit were cloned and expressed in T32, which led to the construction of trivalent candidate vaccine FSD01. Experimental results showed that this strain was genetically stable, but its recombinant plasmid was non-resistant. Moreover, it was able to effectively express trivalent antigens in one host and induce protective responses in mice against the     

Functional interactions of the genomes of Shigella sonnei phages and Escherichia coli phage T4 in mixed infection]

A comparative study of Shigella sonnei phages U and G and Escherichia coli phage T4 has shown that enzymes coded for by the Sh. sonnei phages can functionally substitute for some T4-coded products. This finding in indicative of an evolutionary relationship between T-even phages and disenteric phages U and G. The U phage is uncapable to compensate amber mutants for the genes that control the conversion of cytosine into 5-hydroxymethyl cytosine (5-HMC) and the glucosylation of the latter, which agrees with our earlier finding that the U phage DNA contains no 5-HMC. U and G phages are also found to exclude the T4 phage in the course of mixed infection.     

Study of the methylation process and DNA methylase specificity in Shigella]

The nature and content of minor bases in DNA of 3 Shigella strains are investigated. DNAs from Shigella stutzeri 2, Sh. sonnei 1188 and Sh. sonnei 311 are found to contain 0.43, 0.56 and 0.45 mol.% of N6-methyladenine respectively. 5-methylcytosine (0.16 mol.%) is discovered in Sh. sonnei 311. Substrate specificity of adenine methylase from Sh. sonnei 1188 with respect to phage DNAs of different host modification is investigated. Recognition sites for guanine methylase of DDVI phage and for adenine methylase of Sh. sonnei 1188 turned to be different. DNA of DDII phage grown in Sh. stutzeri 2 cells does not accept methyl groups under the treatment with Sh. sonnei 1188 extracts, but it is methylated by Escherichia coli extract. Adenine methylases of Sh. sonnei 1188 and Sh. stutzeri 2 are suggested to be either the same enzyme, or enzymes, which recognition sites are partially overlapped.     

驱除痢疾杆菌侵袭大质粒的新方法

用质粒不相容性原理驱除痢疾杆菌福氏 2a 2 4 5 7T和宋内S7的侵袭大质粒 ,先从福氏2a侵袭大质粒分别扩增ori和inc基因 ,将它们克隆至 pMD18 T载体 ,得重组质粒pMDori和 pMDinc ,然后转化 2 4 5 7T和S7,不管是pMDori还是 pMDinc都能竞争驱除痢疾杆菌福氏 2a 2 4 5 7T和宋内S7的侵袭大质粒。     

类志贺邻单胞菌7-63-5株及其多糖的研究

类志贺邻单胞菌O17血清型与宋内氏痢疾志贺氏菌的脂多糖结构一致,类志贺邻单胞菌7-63-5株属于O17血清型。实验中通过对该菌株培养特性、生化特征、免疫学特性的研究,证明其完全符合类志贺邻单胞菌特性。多糖的研究证明,类志贺邻单胞菌7-63-5株的O-特异性多糖无论从化学结构,还是免疫学特性上,都与宋内氏I相菌的一致。因此,类志贺邻单胞菌7-63-5株可以用以研究宋内氏痢疾多糖蛋白质结合疫苗。     

Detecting low concentrations of Shigella sonnei in environmental water samples by PCR

Outbreaks of Shigella sonnei associated with contaminated water have been reported and methods for the simultaneous detection of Shigellae and enteroinvasive Escherichia coli in water samples have been developed with detection limits of 10(1)-10(2) CFU mL(-1) of water. Because 10(1)-10(2)Shigellae can cause disease, a more sensitive detection method as an addition to the existing methods for detection of Shigella sonnei in water samples is reported here. Initially, 33 Shigella sonnei and 72 non-Shigella sonnei isolates were tested and one primer pair was found capable of specifically amplifying a 369-bp insertion sequence 1 (IS1) fragment from all 33 Shigella sonnei isolates and one Shigella dysenteriae ATCC isolate by PCR. The detection method was developed, which included filtration of 50 mL of water through a membrane and application of PCR to the membrane using this primer pair. Environmental water samples with total bacterial numbers of 384-2.84 x 10(7) CFU L(-1) were collected and seeded with 13 Shigella sonnei and the Shigella dysenteriae ATCC isolates. Detection limits were determined as 1.7-24.7 and 270-8000 CFU per 50 mL of water, respectively, using this detection method.     

Possible mechanisms underlying the slow lactose fermentation phenotype in Shigella spp.

A Southern hybridization analysis revealed that the region homologous to Escherichia coli lacZ was present on the chromosomal DNAs of beta-galactosidase-positive Shigella strains, such as Shigella dysenteriae serovar 1 and Shigella sonnei strains, whereas this region was absent from chromosomal DNAs of beta-galactosidase-negative strains of Shigella flexneri and Shigella boydii. We found that the lacY-A region was deficient in S. dysenteriae serovar 1 and believe that this is the reason for the slow fermentation of lactose by this strain. S. sonnei strains possessed the region which hybridized with E. coli lacY-A despite their slow hydrolysis of lactose. The whole lactose-fermenting region was cloned from S. sonnei and compared with the cloned lac operon of E. coli K-12. Both clones directed the synthesis of beta-galactosidase in an E. coli K-12 strain lacking indigenous beta-galactosidase activity (strain JM109-1), and we observed no difference in the expression of beta-galactosidase activity in S. sonnei and E. coli. However, E. coli JM109-1 harboring the lactose-fermenting genes of S. sonnei exhibited the slow lactose fermentation phenotype like the parental strain. S. sonnei strains had no detectable lactose permease activities. E. coli JM109-1 harboring the lactose-fermenting genes of S. sonnei had a detectable permease activity, possibly because of the multicopy nature of the cloned genes, but this permease activity was much lower than that of strain JM109-1 harboring the lac operon of E. coli K-12. From these results we concluded that slow lactose fermentation by S. sonnei is due to weak lactose permease activity.     

Possible mechanisms underlying the slow lactose fermentation phenotype in Shigella spp.

A Southern hybridization analysis revealed that the region homologous to Escherichia coli lacZ was present on the chromosomal DNAs of beta-galactosidase-positive Shigella strains, such as Shigella dysenteriae serovar 1 and Shigella sonnei strains, whereas this region was absent from chromosomal DNAs of beta-galactosidase-negative strains of Shigella flexneri and Shigella boydii. We found that the lacY-A region was deficient in S. dysenteriae serovar 1 and believe that this is the reason for the slow fermentation of lactose by this strain. S. sonnei strains possessed the region which hybridized with E. coli lacY-A despite their slow hydrolysis of lactose. The whole lactose-fermenting region was cloned from S. sonnei and compared with the cloned lac operon of E. coli K-12. Both clones directed the synthesis of beta-galactosidase in an E. coli K-12 strain lacking indigenous beta-galactosidase activity (strain JM109-1), and we observed no difference in the expression of beta-galactosidase activity in S. sonnei and E. coli. However, E. coli JM109-1 harboring the lactose-fermenting genes of S. sonnei exhibited the slow lactose fermentation phenotype like the parental strain. S. sonnei strains had no detectable lactose permease activities. E. coli JM109-1 harboring the lactose-fermenting genes of S. sonnei had a detectable permease activity, possibly because of the multicopy nature of the cloned genes, but this permease activity was much lower than that of strain JM109-1 harboring the lac operon of E. coli K-12. From these results we concluded that slow lactose fermentation by S. sonnei is due to weak lactose permease activity.     

Characterization of a bacteriophage T4 mutant lacking DNA-dependent ATPase.

A DNA-dependent ATPase has previously been purified from bacteriophage T4-infected Escherichia coli. A mutant phage strain lacking this enzyme has been isolated and characterized. Although the mutant strain produced no detectable DNA-dependent ATPase, growth properties were not affected. Burst sizes were similar for the mutant phage and T4D in polA1, recB, recC, uvrA, uvrB, uvrC, and various DNA-negative E. coli. UV sensitivity and genetic recombination were normal in a variety of E. coli hosts. Mapping data indicate that the genetic locus controlling the mutant occurs near gene 56. The nonessential nature of this gene is discussed.     

Bacteriophage T4 baseplate components. III. Location and properties of the bacteriophage structural thymidylate synthetase.

Two T4D thymidylate synthetase (td) temperature-sensitive mutants have been isolated and characterized. Both mutants produce heat-labile phage particles. This observation supports the view that this viral-induced protein is a phage structural component. Further, antiserum to td has been shown to block a specific step in tail plate morphogenesis. The results indicated that the td protein is largely covered by the T4D tail plate gene 11 protein. Since the phageinduced dihydrofolate reductase (dfr) also is partially covered by the gene 11 protein, it appears that td was adjacent to the tail plate dfr. This location has been confirmed by constructing a T4D mutant which is dfrtstdts and showing that these two tail plate constituents interact and give altered physical properties to the phage particles produced. A structural relationship for the tail plate folate, dfr, and td has been reported.     

Specificity and functions of guanine methylase of Shigella sonnei DDVI phage.

DNA methylase methylating adenine with formation of 6-methylaminopurine has been identified in Shigella sonnei 1188 cells which are the natural host of DDVI phage. At the same time, in DNA of DDVI phage replicating both in Sh. sonnei 1188 cells and in Escherichia coli B cells 7-methylguanine was found as the only minor base in amounts of 0.25 and 0.27 mol per 100 mol of nucleotides, respectively. The extract of the infected cells was found to contain both kinds of DNA methylases: virus-specific guanine methylase and cellular adenine methylase. The lack of 6-methylaminopurine in DNA of this phage is explained by reversible inhibition of the cell enzyme in the infected cells. The amount of methyl groups transferred by DDVI-specific methylase on DNA does not depend on the species of the infected cells and is similar in the case of unmodified SD phage DNA and DNA of T2 phage methylated by E. coli B enzyme. Guanine methylase has been shown to be a DDVI-induced modification enzyme and to protect against restriction of B-type. It methylates double-stranded DNAs only and is inhibited by S-adenosylhomocysteine.