大肠杆菌VT2噬菌体的分离与溶源转染

本试验利用指示菌MC1061。经双层琼脂法纯化和PCR扩增vt2基因,分别从大肠杆菌0157菌株、牛粪、鸡粪和污水中分离获得5株含vt2基因的噬菌体。这些噬菌斑透明,直径为0．5-2min,对指示菌的感染效价均在10^9PFU／mL以上,抵抗氯仿和56℃30min的作用。将噬菌体分离株SHφWl感染MC1061后。经PCR鉴定获得一株溶源菌株(MC1061／SHφW1)。溶源株的LB培养滤液对Vero细胞产生了显著的病变效应,而MC1061在同等条件下培养的滤液无细胞病变,表明VT2噬菌体通过溶源将vt2毒力基因水平转移,证实了VT2噬菌体的转染与细菌毒力相关。     

大肠杆菌VT2噬菌体的分离与溶源转染

本试验利用指示菌MC1061,经双层琼脂法纯化和PCR扩增vt2基因,分别从大肠杆菌O157菌株、牛粪、鸡粪和污水中分离获得5株含vt2基因的噬菌体.这些噬菌斑透明,直径为0.5-2 mm,对指示菌的感染效价均在109PFU/mL以上,抵抗氯仿和56℃C30min的作用.将噬菌体分离株SHφW1感染MC1061后,经PCR鉴定获得一株溶源菌株(MC1061/SHφW1).溶源株的LB培养滤液对Vero细胞产生了显著的病变效应,而MC1061在同等条件下培养的滤液无细胞病变,表明VT2噬菌体通过溶源将vt2毒力基因水平转移,证实了VT2噬菌体的转染与细菌毒力相关.     

Lysogenic Conversion of Pasteurella by Escherichia coli Bacteriophage P1 CM

Bacteriophage P1 CM can convert Pasteurella pestis or P. pseudotuberculosis to chloramphenicol resistance and phage restriction, but no viable phage was induced from converted Pasteurella strains.     

Lytic and lysogenic infection of diverse Escherichia coli and Shigella strains with a verocytotoxigenic bacteriophage

A verocytotoxigenic bacteriophage isolated from a strain of enterohemorrhagic Escherichia coli O157, into which a kanamycin resistance gene (aph3) had been inserted to inactivate the verocytotoxin gene (vt2), was used to infect Enterobacteriaceae strains. A number of Shigella and E. coli strains were susceptible to lysogenic infection, and a smooth E. coli isolate (O107) was also susceptible to lytic infection. The lysogenized strains included different smooth E. coli serotypes of both human and animal origin, indicating that this bacteriophage has a substantial capacity to disseminate verocytotoxin genes. A novel indirect plaque assay utilizing an E. coli recA441 mutant in which phage-infected cells can enter only the lytic cycle, enabling detection of all infective phage, was developed.     

Infection of Actinomycin-Permeable Mutants of Escherichia coli with Urea-Disrupted Bacteriophage

Intact cells of actinomycin-permeable mutants of Escherichia coli could be infected with urea-disrupted phage T4 (designated as T4pi). The parental strains and the revertants, which are impermeable to actinomycin, were not susceptible to T4pi unless they had been treated with agents which altered their permeability. The permeable mutants developed competence for pi infection during the growth cycle; cells in the early stationary phase produced 10- to 100-fold more plaques on plating with T4pi than did exponentially growing cells. Colistin (polymyxin E) was effective in converting noncompetent cells of either permeable or nonpermeable strains to the competent state. Treatment with lysozyme resulted in a considerable increase in susceptibility to T4pi of permeable mutants but not of nonpermeable cells. It appears that development of competence for pi infection is mainly due to alterations in the permeability barriers of the cell.     

Increased Fragility of Escherichia coli After Infection with Bacteriophage M13

Male strains of Escherichia coli infected with filamentous phage M13 released the progeny phage particles from intact cells. At the same time, the cells continued to grow and multiply at a slightly lower rate than the uninfected cells. Concomitant with the phage release, lipopolysaccharide from the cell wall of the infected cells was also released. The buoyant density of E. coli HfrC in diaginol, 1.25 g/cc, did not change as a result of infection. Detergents like sodium dodecyl sulfate and Sarkosyl specifically lysed the infected cells. The infected cells showed enhanced fragility as indicated by inactivation by various stresses, namely heat, osmotic shock, and freezing and thawing. It is concluded that the infection with M13 causes certain alterations in the surface structure of E. coli, thus making the cells more fragile.     

Growth of Bacteriophage H on Male and Female Strains of Escherichia coli

Phage H propagated on Yersinia pestis was reported by Molnar and Lawton to be rapidly adsorbed to female but not to male strains of Escherichia coli. In contrast, we find phage H adsorbs to all E. coli strains tested (both male and female) and forms plaques on a wide variety of male strains. Phage H appears to be related to the T3-T7 group of coliphages.     

Inhibitory Effects of Gynostemma Pentaphyllum on the UV Induction of Bacteriophage λ in Lysogenic Escherichia coli

Effects of gynostemma pentaphyllum (GP) on the bacteriophage λ induced by ultraviolet (UV) irradiation have been studied. The results showed that GP could inhibit the UV induction of bacteriophage λ in lysogenic cells. The inhibitory effects were dependent on the concentration and the reaction time of GP, and were efficient at 40∼125 μg ml⁻¹ for 10 min. The inhibitory rate was higher than 70% when the GP concentration was 50 μg ml⁻¹. By electron spin resonance (ESR) and spin-trapping techniques, the signals of free radicals were detected in the suspension of the λ lysogenic bacteria induced by ultraviolet irradiation, but after the addition of GP the signals were decreased. These results indicate that gynostemma pentaphyllum not only is a scavenger of free radicals, but also possesses the biological function of anti-irradiation, and that there is a close relation between the UV irradiation of the bacteriaphage λ and free radicals. Received: 18 December 2000 / Accepted: 9 March 2001     

Cation Fluxes and Permeability Changes Accompanying Bacteriophage Infection of Escherichia coli

Infection of Escherichia coli by bacteriophage T2 was accompanied by a rapid but transient increase in the rate of loss of small molecules from the bacterial cells. This transient leakage was studied with radioactive labels such as (42)K and (28)Mg. Bacteriophage-induced leakage was dependent on the ratio of phage to bacteria: the higher the multiplicity of infection, the greater the leakage. No leakage occurred at 4 C [when adsorption proceeds but injection of phage deoxyribonucleic acid (DNA) is blocked]. Leakage was caused by heavily irradiated phage as well as by normal phage; therefore, the intracellular functioning of the bacteriophage DNA was not required. This conclusion was supported by experiments which showed phage-induced leakage in the presence of chloramphenicol or sodium cyanide. Leakage could be prevented by infecting the bacteria with phage in the presence of high magnesium concentrations. Phage-induced leakage was terminated by a "sealing" reaction, after which potassium turnover by infected and uninfected cells was very similar. The sealing reaction occurred even in the presence of chloramphenicol, suggesting that the sealing is controlled by bacterial and not bacteriophage genes. We were not able to detect any effect of normal bacteriophage infection on the influx (active transport) of potassium and magnesium into the cells.     

Characteristics of a Lytic Enzyme Induced by Bacteriophage Infection of Micrococcus lysodeikticus

A lytic enzyme induced in Micrococcus lysodeikticus strain 1 by infection with N1 bacteriophage was purified 45- to 50-fold by ammonium sulfate precipitation, acid precipitation, and selective adsorption of contaminating proteins with calcium phosphate gel. The optimal pH for activity of the enzyme was 6.5 to 7.0. Maximal activity occurred at 45 to 50 C and at an ionic strength of 0.06. The enzyme had a limited specificity and lysed cell walls of M. lysodeikticus with the release of dinitrofluorobenzene reactive groups. Living cells were lysed in the absence of phage; however, the rate of lysis increased when phage was present in excess of 10 particles per bacterial cell. Young cells were most sensitive, and the sensitivity decreased to a minimum with stationary-phase cells. Acting synergistically, lysozyme and the N1-induced lysin caused lysis of cells which were resistant to either enzyme acting independently. The N1 lysin did not exhibit proteolytic activity.     

Effect of Bacteriophage Ghost Infection on Protein Synthesis in Escherichia coli

The rate of protein synthesis by Escherichia coli markedly decreased within 1 min after phage T4 infection, whereas a complete cessation of protein synthesis was observed within at least 25 sec after T4 ghost infection. The cellular level of amino acids and aminoacyl-transfer ribonucleic acid (tRNA) did not change drastically upon infection with ghosts, indicating that the inhibition of protein synthesis took place at a step(s) beyond aminoacyl-tRNA formation. The host messenger RNA remained intact and still bound to ribosomes shortly after ghost infection. Kinetic studies of the effect of ghosts on host protein synthesis revealed that nascent peptide chains on ribosomes were not released upon ghost infection.     

Enlargement of Escherichia coli After Bacteriophage Infection II. Proposed Mechanism

Division of Escherichia coli was stopped and mean cellular volume was increased after infection with T-even phage. This host cell enlargement was temperature-dependent, cyanide-sensitive, and stable in the presence of hypertonic medium. Enlargement ceased at about the same time that energy metabolism ceased. Initially, enlargement was accompanied by a decrease in mean cell density. Tritiated 2, 6-diaminopimelic acid was accumulated and incorporated into cold acid-insoluble material at the preinfection rate. These findings suggest that the effect on host cell size is only in part an osmotic phenomenon and that it also reflects continued growth of the surface of the infected cell in the absence of cell division.     

Unfolding of the Host Genome After Infection of Escherichia coli with Bacteriophage T4

The folded genome of Escherichia coli is converted to a slower-sedimenting form within 5 min after infection with bacteriophage T4 or T4nd28(den A)-amN82(44). Chloramphenicol sensitivity and response to UV-irradiation of the phage suggest participation of viral-induced functions.     

Shigella Strains Are Not Clones of Escherichia coli but Sister Species in the Genus Escherichia

Shigella species and Escherichia coli are closely related organisms. Early phenotyping experiments and several recent molecular studies put Shigella within the species E. coli. However, the whole-genome-based, alignment-free and parameter-free CVTree approach shows convincingly that four established Shigella species, Shigella boydii, Shigella sonnei, Shigella felxneri and Shigella dysenteriae, are distinct from E. coli strains, and form sister species to E. coli within the genus Escherichia. In view of the overall success and high resolution power of the CVTree approach, this result should be taken seriously. We hope that the present report may promote further in-depth study of the Shigella-E. coli relationship.     

Degradation of Escherichia coli Chromosome After Infection by Bacteriophage T4: Role of Bacteriophage Gene D2a

Mutations in the D2a gene of bacteriophage T4 have recently been shown to result in the stabilization of cytosine-containing phage deoxyribonucleic acid (DNA) made after infection by phage gene 56 (deoxycytidine triphosphatase) mutants. In the experiments reported here, we investigate the role of the D2a gene in the degradation of the host chromosome. We find that if T4 endonuclease II, a product of the phage gene denA, is active, host chromosome degradation appears normal, regardless of the presence of the D2a gene product. However, if T4 endonuclease II is absent, a small amount of host chromosome degradation occurs, but only if the D2a product is present. These results are interpreted in terms of the hypothesis that D2a controls a nuclease which degrades cytosine-containing DNA. Neither D2a nor denA mutations affect the shut-off of host DNA synthesis.     

Prophage Induction in Lysogenic Escherichia coli with N-Nitroso Compounds and Derivatives

Prophage induction in lysogenic Escherichia coli W1709 (iota) was determined for 29 N-nitroso compounds, 13 of their denitrosated derivatives, and 7 hydroxylamino and hydrazino analogues of nitrosamines. Minimal inducing concentrations of 0.1 to 2.0 mug/ml were demonstrated for eight nitrosamidines, and concentrations of 0.5 to 25.0 mug/ml were shown for six nitrosamides. Weak inducing activities were found with N,N-diethylhydroxylamine oxalate and N-methyl-N-phenylhydrazine sulfate, derivatives of inactive N-nitrosodiethylamine and N-nitrosomethylphenylamine, respectively. Inactive compounds including N-methyl-N-nitroso-p-toluenesulfonamide, 11 nitrosamines, 3 N, N'-dialkyl substituted-N-nitrosoureas, 13 denitrosated derivatives, and 5 hydroxylamino and hydrazino analogues of nitrosamines are listed. Since 7 of the 14 prophage-inducing nitrosamidines and nitrosamides reported thus far have carcinostatic activity in rodent tumor systems, it is concluded that the induction test may provide a useful screen for the detection of potential antitumor compounds. The induction test may also be useful for the detection of responsive N-nitroso compounds which may be potential toxicological hazards in the environment since, of the six active nitrosamides, five have already been reported to produce mutagenic and carcinogenic effects, four produce chromosomedamaging effects, and two produce teratogenic effects. Use of the prophage induction system for detection of biologically active intermediates formed by N-nitroso compounds under physiological conditions is considered.     

Phage-Encoded Colanic Acid-Degrading Enzyme Permits Lytic Phage Infection of a Capsule-Forming Resistant Mutant Escherichia coli Strain

In this study, we isolated a bacteriophage T7-resistant mutant strain of Escherichia coli (named S3) and then proceeded to characterize it. The mutant bacterial colonies appeared to be mucoid. Microarray analysis revealed that genes related to colanic acid production were upregulated in the mutant. Increases in colanic acid production by the mutant bacteria were observed when l-fucose was measured biochemically, and protective capsule formation was observed under an electron microscope. We found a point mutation in the lon gene promoter in S3, the mutant bacterium. Overproduction of colanic acid was observed in some phage-resistant mutant bacteria after infection with other bacteriophages, T4 and lambda. Colanic acid overproduction was also observed in clinical isolates of E. coli upon phage infection. The overproduction of colanic acid resulted in the inhibition of bacteriophage adsorption to the host. Biofilm formation initially decreased shortly after infection but eventually increased after 48 h of incubation due to the emergence of the mutant bacteria. Bacteriophage PBECO4 was shown to infect the colanic acid-overproducing mutant strains of E. coli. We confirmed that the gene product of open reading frame 547 (ORF547) of PBECO4 harbored colanic acid-degrading enzymatic (CAE) activity. Treatment of the T7-resistant bacteria with both T7 and PBECO4 or its purified enzyme (CAE) led to successful T7 infection. Biofilm formation decreased with the mixed infection, too. This procedure, using a phage cocktail different from those exploiting solely receptor differences, represents a novel strategy for overcoming phage resistance in mutant bacteria.     

Replication of Bacteriophage ST-1 in Escherichia coli Strains Temperature Sensitive in DNA Synthesis

Bacteriophage ST-1 replication requires DNA polymerase III (dnaE) but not DNA polymerases I or II, DNA ligase, or the products of dnaA, B, or C-D. It was not certain whether dnaG was required. These results differ considerably from those reported for X-174.     

Enlargement of Escherichia coli After Bacteriophage Infection I. Description of the Phenomenon

Cycloheximide addition at various times from 24 to 36 hr after virus infection markedly inhibits the rate of simian virus 40 (SV40) deoxyribonucleic acid (DNA) synthesis in monkey kidney (CV-1) cultures. To determine whether superhelical (form I) SV40 DNA was synthesized in the cycloheximide-inhibited cultures, extracts were prepared by the method of Hirt from cultures labeled with (3)H-thymidine ((3)H-dT) and were analyzed by cesium chloride-ethidium bromide (CsCl-EtBr) equilibrium centrifugation and by velocity sedimentation in neutral sucrose gradients. When control or cycloheximide-treated cultures were labeled for 2 or 4 hr with (3)H-dT at 36 or 37 hr after infection, 71 to 83% of the radioactivity soluble in 1 m NaCl was detected in closed-circular SV40 DNA (form I). Cycloheximide treatment did not generate an increase of higher multiple circular forms of SV40 DNA. In pulse-chase experiments with or without cycloheximide treatment, radioactivity first appeared in nicked molecular forms sedimenting faster than open-circular SV40 DNA (form II), and then was chased into superhelical form I SV40 DNA. These results suggest that in cycloheximide-treated SV40-infected cultures: (i) polynucleotide ligase concentrations are adequate, and (ii) duplication errors causing formation of circular oligomers of SV40 DNA are not enhanced.