Single mutations in a gene for a tail fiber component of an Escherichia coli phage can cause an extension from a protein to a carbohydrate as a receptor

The T-even type Escherichia coli phage Ox2 recognizes the outer membrane protein OmpA as a receptor. This recognition is accomplished by the 266 residue protein 38, which is located at the free ends of the virion's long tail fibers. Host-range mutants had been isolated in three consecutive steps: Ox2----Ox2h5----Ox2h10----Ox2h12, with Ox2h12 recognizing the outer membrane protein OmpC efficiently and having lost some affinity for OmpA. Protein 38 consists, in comparison with these proteins of other phages, of two constant and one contiguous array of four hypervariable regions; the alterations leading to Ox2h12 were all found within the latter area. Starting with Ox2h12, further host-range mutants could be isolated on strains resistant to the respective phage: Ox2h12----h12h1----h12h1.1----h12h1.11----h12 h1.111. It was found that Ox2h12h1.1 (and a derivative of Ox2h10, h10h4) probably uses, instead of OmpA or OmpC, yet another outer membrane protein, designated OmpX. Ox2h12h1.11 was obtained on a strain lacking OmpA, -C and -X. This phage could not grow on a mutant of E. coli B, possessing a lipopolysaccharide (LPS) with a defective core oligosaccharide; Ox2h12h1.111 was obtained from this strain. It turned out that the latter two mutants used LPS as a receptor, most likely via its glucose residues. Selection for resistance to them in E. coli B (ompA+, ompC-, ompX-) yielded exclusively LPS mutants, and in another strain, possessing OmpA, C and X, the majority of resistant mutants were of this type. Isolated LPS inactivated the mutant phages very well and was inactive towards Ox2h12. By recombining the genes of mutant phages into the genome of parental phages it could be shown that the phenotypes were associated with gene 38. All mutant alterations (mostly single amino acid substitutions) were found within the hypervariable regions of protein 38. In particular, a substitution leading to Ox2h12h1.11 (Arg170----Ser) had occurred at the same site that led to Ox2h10 (His170----Arg), which binds to OmpC in addition to OmpA. It is concluded that not only can protein 38 gain the ability to switch from a protein to a carbohydrate as a receptor but can do so using the same domain of the polypeptide.     

Interconversion of Type C and D Strains of Clostridium botulinum by Specific Bacteriophages

These studies show that Clostridium botulinum types C and D cultures can be cured of their prophages and converted to either type C or D depending on the specific phage used. Strains of types C and D were cured of their prophages and simultaneously ceased to produce their dominant toxins designated as C(1) and D, respectively. Cured nontoxigenic cultures derived from type C strain 162 were sensitive to the phages from the toxigenic type C strain 162 and type D strain South African. When cured nontoxigenic cultures derived from strain 162 were infected with the tox(+) phages from the 162 strain of type C and the South African strain of type D, they then produced toxin neutralized by types C and D antisera, respectively. Cured nontoxigenic cultures isolated from the type D South African strain were only sensitive to the parent phage, and, when reinfected with the tox(+) phage, they produced toxin neutralized by type D antiserum. Type C strain 153 and type D strain 1873, when cured of their respective prophages, also ceased to produce toxins C(1) and D, but, unlike strain 162 and the South African strain, they continued to produce a toxin designated as C(2). When the cured cultures from strains 153 and 1873 were infected with the tox(+) phage from type D strain 1873, the cultures simultaneously produced toxin that was neutralized by type D antiserum. When these cured cultures were infected with the tox(+) phage from type C strain 153, the cultures produced toxin that was neutralized by type C antiserum. These studies with the four strains of C. botulinum confirm that the toxigenicity of types C and D strains requires the continued participation of tox(+) phages. Evidence is presented that types C and D cultures may arise from a common nontoxigenic strain.     

Escherichia coli mutants with an altered sensitivity to cecropin D.

Cecropins are a family of small, basic antibacterial polypeptides which can be isolated from pupae of immunized Lepidoptera. They are active against both gram-negative and gram-positive bacteria. We studied a mutant of Escherichia coli, strain SB1004, which is more sensitive to cecropin D than is the parental strain. The mutant was selected as resistant to a host range mutant of a Serratia marcescens phage. When the protein composition of the outer membrane was examined, strain SB1004 and some other phage-resistant mutants were found to be deficient in the OmpC protein. It was concluded that the OmpC protein is the receptor of the phage. Strain SB1004 was found to differ from other ompC mutants in being especially sensitive to hydrophobic antibiotics and to cecropin D. Furthermore, strain SB1004 has a tendency for spontaneous autolysis. A genetic analysis showed the mutations in strain SB1004 and a suppressor mutant to map in the ompC region. The activity of cecropin D against different strains of E. coli was specifically enhanced when divalent cations were absent. No such effect was found with cecropins A and B, which are less hydrophobic than the D form.     

Characteristics of phages-transposons of Pseudomonas aeruginosa belonging to 2 groups distinguished by DNA-DNA homology

14 new transposable phages (TP) were isolated from approx. 200 clinical isolates of Pseudomonas aeruginosa. The frequent occurrence of TP of P. aeruginosa has been confirmed. There are at least two different groups of TP, namely, the group of D3112 and that of B3. The distinctive features of phages belonging to the groups are as follows: 1) low level of DNA-DNA homology (less than 10%), the whole region of homology in phage genomes of different groups being located on right genome end (29-38 kb); only one of phages of the B3 group shows an additional homology with D3112 DNA outside the above mentioned region; 2) a variable DNA is observed on the left end of the B3 group phage genomes and no such DNA is revealed on the left end of genomes of the D3112 group phages; 3) all phages of the B3 group have specific type of interaction with RPL11 plasmid, which distinguish them from phages of the D3112 group; 4) phages belonging to the two groups differ greatly in their growth in cells harbouring pMG7 plasmid which mediates production of PaeR7 endonuclease and in the number of DNA sites sensitive to SalGI, PstI, BglII endonucleases. Since some of the B3 group phage genomes possess BamH1 sites, resistance to this enzyme cannot be regarded as a general characteristics for all TP of P. aeruginosa, as it was earlier proposed. Some aspects of modular hypothesis of bacteriophage evolution concerning, in particular, the ways of module formation are discussed.     

Copper sensitivity in an envelope mutant of Escherichia coli and its suppression by ColV, I-K94

A phage K3-resistant isolate from Escherichia coli P678-54 was devoid of both the OmpA and OmpC proteins but had high levels of the OmpF protein. Associated with these changes, the strain showed increased sensitivity to inhibition by detergents and greatly increased sensitivity to Cu²⁺. Introduction of the ColV, I-K94 plasmid into this mutant produced a derivative with markedly increased resistance to Cu²⁺ ions but unchanged detergent sensitivity. Analysis of membranes showed that the ColV, I-K94⁺ derivative had essentially no OmpF protein in its outer membrane. A ca 36 K outer membrane protein was present which resembled the OmpC protein in size and failure to dissociate in SDS at low temperature. It was distinct from the OmpC protein, however, in failing to allow either tetracycline uptake or the adsorption of T4-type phages. The possible significance of OmpF porin derepression (and its reversal by ColV, I-K94) for enterobacterial survival in aquatic situations is discussed.     

Bacteriophages drive strain diversification in a marine Flavobacterium: implications for phage resistance and physiological properties

Genetic, structural and physiological differences between strains of the marine bacterium Cellulophaga baltica MM#3 (Flavobacteriaceae) developing in response to the activity of two virulent bacteriophages, ΦS_M and ΦS_T, was investigated during 3 weeks incubation in chemostat cultures. A distinct strain succession towards increased phage resistance and a diversification of the metabolic properties was observed. During the incubation the bacterial population diversified from a single strain, which was sensitive to 24 tested Cellulophaga phages, into a multistrain and multiresistant population, where the dominant strains had lost susceptibility to up to 22 of the tested phages. By the end of the experiment the cultures reached a quasi steady state dominated by ΦS_T‐resistant and ΦS_M + ΦS_T‐resistant strains coexisting with small populations of phage‐sensitive strains sustaining both phages at densities of > 10⁶ plaque forming units (pfu) ml^?1. Loss of susceptibility to phage infection was associated with a reduction in the strains' ability to metabolize various carbon sources as demonstrated by BIOLOG assays. This suggested a cost of resistance in terms of reduced physiological capacity. However, there was no direct correlation between the degree of resistance and the loss of metabolic properties, suggesting either the occurrence of compensatory mutations in successful strains or that the cost of resistance in some strains was associated with properties not resolved by the BIOLOG assay. The study represents the first direct demonstration of phage‐driven generation of functional diversity within a marine bacterial host population with significant implications for both phage susceptibility and physiological properties. We propose, therefore, that phage‐mediated selection for resistant strains contributes significantly to the extensive microdiversity observed within specific bacterial species in marine environments.     

Coliphage which requires either the LamB protein or the OmpC protein for adsorption to Escherichia coli K-12.

Either of two different proteins in the outer membrane of Escherichia coli K-12 (LamB and OmpC) can function in the constitution of receptor activity for a newly isolated T-even bacteriophage. This bacteriophage (SSI) differs from other T-even phages which use the OmpC protein as their receptors. The simple procedure used to isolate phage SSI may be suitable for the detection of bacteriophages with novel outer membrane receptor requirements.     

Differentiation of methicillin-resistant strains of Staphylococcus aureus by prophage specificity]

By inducing with mitomycin C the following phages were isolated from all the tested 32 methicillin resistant strains of S. aureus: the serogroup B phage was isolated from 2 strains, the serogroup B and F phages were isolated from 5 strains and the serogroup F phage was isolated from 25 strains. The phages were divided into 5 groups by the antiphage immunity. In group 1 of the phages 4 additional phages were specified. By the specificity of the prophages in the cultures all the strains were divided into 5 groups. Group 1 of the cultures was divided into 5 subgroups (A, B, C, D and E).     

Porins and lipopolysaccharide of Escherichia coli ATCC 25922 and isogenic rough mutants

Abstract The lipopolysaccharide and porin profile of Escherichia coli ATCC 25922, a smooth strain commonly used in antibiotic susceptibility testing, and five isogenic rough mutants was examined. The lipopolysaccharide of the parent strain had the characteristic ladder pattern on polyacrylamide gels, while that of the mutants appeared similar to chemotypes Ra and Rc of Salmonella typhimurium with some changes in chemical composition. Of the porins, OmpC appeared markedly reduced in the parent strain while OmpF appeared markedly reduced in the mutants. In addition, a new outer-membrane protein of size intermediate to that of OmpC and OmpF was detected in all mutants. Neither parent nor mutants were susceptible to the LPS core-specific P1 phage or the porin-specific PA2 and K20 phages.     

Bacteriophage host range evolution through engineered enrichment bias,exploiting heterologous surface receptor expression

Research on the initial phage–host interaction has been conducted on a limited repertoire of phages and their cognate receptors, such as phage λ and the Escherichia coli LamB (EcLamB) protein. Apart from phage λ, little is known about other phages that target EcLamB. Here, we developed a simple method for isolating novel environmental phages in a predictable way, i.e. isolating phages that target a particular receptor(s) of a bacterium, in this case, the EcLamB protein. A plasmid (pMUT13) encoding the EcLamB porin was transferred into three different enterobacterial genera. By enrichment with these engineered bacteria, a number of phages (ZZ phages) that targeted EcLamB were easily isolated from the environment. Interestingly, although EcLamB-dependent in their recombinant heterologous hosts, these newly isolated ZZ phages also targeted OmpC as an alternative receptor when infecting E. coli. Moreover, the phage host range was readily extended within three different bacterial genera with heterologously expressed EcLamB. Unlike phage λ, which is a member of the Siphoviridae family, these newly isolated EcLamB-dependent phages were more commonly members of the Myoviridae family, based on transmission electron microscopy and genomic sequences. Modifications of this convenient and efficient phage enrichment method could be useful for the discovery of novel phages.     

New pore protein produced in cells lysogenic for Escherichia coli phage HK253hrk

Outer membrane pore protein OmpC was identified as the receptor for the temperate Escherichia coli phage HK253hrk. The part of OmpC protein recognized by the phage was identified by using hybrid proteins in which parts of OmpC protein are replaced by the corresponding parts of the related PhoE protein. In contrast to other OmpC-specific phages, HK253hrk recognizes a part of OmpC within the C-terminal 50 amino acids of the protein. E. coli strains lysogenic for HK253hrk produce reduced amounts of OmpC protein, and produce a new pore protein instead. Expression of this new protein was temperature-dependent, i.e. low at 30 degrees C. The functioning of this new pore protein was characterized both in vivo by studying the uptake of beta-lactam antibodies and in vitro after reconstitution of the protein in black lipid films. Its effective pore size was larger than that of the OmpF pores of E. coli B. The new porin appears to be cation-selective. A comparison with the selectivity of the known OmpC and OmpF pores of E. coli showed that the new pore has a higher selectivity than OmpF but is less selective than OmpC. The new pore protein appears to function in E. coli K12 lysogens as the receptor for the phages HK187, HK189 and HK332.     

Analysis of Lactobacillus phages and bacteriocins in American dairy products and characterization of a phage isolated from yogurt.

Yogurt and acidophilus milk that contain Lactobacillus acidophilus could promote human health because L. acidophilus can inhibit enteric and food-borne microbial pathogens. To evaluate the stability of diary L. acidophilus cultures, we studied whether some diary lactobacilli could be inhibited by phages or bacteriocins released by other dairy lactobacilli. From 20 yogurts and two acidophilus milks purchased at local food markets, 38 Lactobacillus strains were isolated. Eight Lactobacillus type strains were used as controls. With mitomycin induction and agar spot assay, phages and bacteriocins were isolated from these strains and their activities were analyzed. Lactobacillus strains from 11 yogurts released phages, while the strains from most of the remaining products released bacteriocins. One phage, designated phi y8, was characterized. It was spontaneously released from its host strain L. acidophilus Y8, at a rate of about 10(4)/ml. This phage lysed nine other dairy Lactobacillus strains tested. It had a burst size of 100, an elongated prolate head of 39 by 130 nm, a long, flexible but noncontractile tail of 300 nm, and a 54.3-kb linear double-stranded DNA. DNA fingerprinting analysis indicated that L. acidophilus phages of nine yogurts in this study belonged to the same type as phi y8. Although they may be sensitive to bacteriocins, all lysogens resisted further phage attacks, whereas most nonlysogens were sensitive to both phages and bacteriocins. Therefore, Lacotbacillus cultures of some American yogurts and acidophilus milks may be unstable or unsafe because they can either be inhibited by phages or bacteriocins or release them to inhibit lactobacilli or other diary products.     

Specific phages used for differentiation of the entomopathogenic bacterium Bacillus thuringiensis]

The sensitivity to specific phages and morphological, physiological, and antigenic properties were compared among several strains of Bacillus thuringiensis isolated from insects inhabiting various geographical zones. All 43 cultures assigned to Bac. thuringiensis var. sotto and 198 among 170 cultures classed as Bac. thuringiensis var. dendrolimus were found to belong to Bac. thuringiensis var. dendrolimus. None of these cultures was resistant to its specific phage. The same was true of 22 studied cultures of Bac. thuringiensis var. galleriae. Only two among studied 45 cultures of Bac. thuringiensis var. thuringiensis were resistant to phages specific for this variety. Therefore, the abundance of variants resistant to specific phages in natural conditions differs among the varieties of Bac. thuringiensis. In most cases, cultures of the same variety of Bac. thuringiensis isolated from various insects inhabiting different geographical zones are identical by their sensitivity to specific phages and by other important characteristics.     

从噬菌体展示随机12肽库中筛选与IRS-1PH结构域相结合的多肽模体

将胰岛素受体底物-1(IRS-1)的PH结构域(pleckstrin homology domain)编码序列克隆到融合表达载体pRSETA中,阳性克隆经IPTG诱导,表达出氨基端带6个连续组氨酸残基的融合蛋白。经检测,表达的目的蛋白一部分以可溶形式存在。利用Ni-NTA金属螯合亲和层析法在非变性条件下对表达的目的蛋白进行纯化,纯度大于98％。将纯化的目的蛋白包被于聚苯乙烯平皿上作为靶蛋白,经过4轮淘筛,得到能够与IRS-1的PH结构域相结合的重组噬菌体克隆;从中随机挑选出50个克隆进行DNA序列测定,对获得的短肽序列进行了分析。并通过ELISA检测了这些克隆与IRS-1的PH结构域的结合活性。     

Shigella viruses Sf22 and KRT47 require outer membrane protein C for infection

Viruses rely on hosts for their replication: thus, a critical step in the infection process is identifying a suitable host cell. Bacterial viruses, known as bacteriophages or phages, often use receptor binding proteins to discriminate between susceptible and non-susceptible hosts. By being able to evade predation, bacteria with modified or deleted receptor-encoding genes often undergo positive selection during growth in the presence of phage. Depending on the specific receptor(s) a phage uses, this may subsequently affect the bacteria's ability to form biofilms, its resistance to antibiotics, pathogenicity, or its phenotype in various environments. In this study, we characterize the interactions between two T4-like phages, Sf22 and KRT47, and their host receptor S. flexneri outer membrane protein C (OmpC). Results indicate that these phages use a variety of surface features on the protein, and that complete resistance most frequently occurs when hosts delete the ompC gene in full, encode premature stop codons to prevent OmpC synthesis, or eliminate specific regions encoding exterior loops.     

Alteration of Host Specificity to Lytic Bacteriophages in Streptococcus cremoris

A mutant of Streptococcus cremoris strain ML1 was isolated based on its resistance to acriflavine. The mutant strain showed resistance to the growth of virulent bacteriophages to which the parental strain was sensitive whereas it became sensitive to a number of other virulent phages to which the parental strain was resistant. At the same time, infection of the mutant strain by another bacteriophage sc607 resulted in killing of cells without production of progeny phages. The phage adsorption appeared normal, suggesting that the killing was a postadsorption event. Such killing of bacterial cells was prevented by chloramphenicol treatment, indicating that involvement of some protein either synthesized by phage or phage-induced cellular protein. Synthesis of ribonucleic acid was abruptly terminated after infection of the mutant strain by phage sc607 but not of the parental strain. The alteration of host specificity in the mutant to different lytic bacteriophages and especially abortive infection by phage sc607 resembles the prophage-mediated interference observed in other bacteria.     

Lactococcal Bacteriophages Require a Host Cell Wall Carbohydrate and a Plasma Membrane Protein for Adsorption and Ejection of DNA

The mechanism of the initial steps of bacteriophage infection in Lactococcus lactis subsp. lactis C2 was investigated by using phages c2, ml3, kh, l, h, 5, and 13. All seven phages adsorbed to the same sites on the host cell wall that are composed, in part, of rhamnose. This was suggested by rhamnose inhibition of phage adsorption to cells, competition between phage c2 and the other phages for adsorption to cells, and rhamnose inhibition of lysis of phage-inoculated cultures. The adsorption to the cell wall was found to be reversible upon dilution of the cell wall-adsorbed phage. In a reaction step that apparently follows adsorption to the cell wall, all seven phages adsorbed to a host membrane protein named PIP. This was indicated by the inability of all seven phages to infect a strain selected for resistance to phage c2 and known to have a defective PIP protein. All seven phages were inactivated in vitro by membranes from wild-type cells but not by membranes from the PIP-defective, phage c2-resistant strain. The mechanism of membrane inactivation was an irreversible adsorption of the phage to PIP, as indicated by adsorption of [³⁵S] methionine-labeled phage c2 to purified membranes from phage-sensitive cells but not to membranes from the resistant strain, elimination of adsorption by pretreatment of the membranes with proteinase K, and lack of dissociation of ³⁵S from the membranes upon dilution. Following membrane adsorption, ejection of phage DNA occurred rapidly at 30°C but not at 4°C. These results suggest that many lactococcal phages adsorb initially to the cell wall and subsequently to host cell membrane protein PIP, which leads to ejection of the phage genome.     

Comparative study of temperate bacteriophages isolated from Yersinia

170 Yersinia strains belonging to various species were investigated for the presence of temperate bacteriophages. By induction with mitomycin C seven phages were isolated from Y. enterocolitica strains and one phage from a Y. frederiksenii strain. The phages were characterized on the basis of their morphology, host range, genome size, DNA homology, and protein composition. They belong to different phage families and reveal narrow to moderate wide host ranges. Some of the isolated phages were able to infect pathogenic as well as nonpathogenic strains of Y. enterocolitica. The genomes of all isolated phages were found to be composed of double stranded DNA ranging from about 40 to 60 kb. In addition to the analysed phages, a number of putative phages were induced in strains of Y. frederiksenii, Y. kristensenii, Y. intermedia, and Y. mollaretii. The putative phages were identified by isolation of phage DNA from cell free lysates but could not be propagated on indicator strains. Southern hybridization experiments revealed relationships between phages belonging to different families. Moreover, DNA homologies were observed between phages isolated from nonpathogenic Yersinia strains and a phage which was isolated from a pathogenic Y. enterocolitica serogroup O:3 strain.     

Bacteriophage Typing as an Epidemiological Tool for Urinary Escherichia coli

Phage typing was used to identify strains of Escherichia coli isolated from urinary and nonurinary sources. When eight phages isolated in Pennsylvania were used to type 717 cultures from Missouri, 50.3% of 624 urinary isolates and 34.4% of 93 nonurinary isolates were typable. Strains from nonurinary sources were not found commonly in urine. When five additional phages isolated in Missouri were added to the original set of eight phages, 80.4% of 331 urinary isolates were typable. When this set of phages was used to type 552 urinary cultures isolated in California, Minnesota, Ohio, Pennsylvania, Virginia, and West Virginia, 82.0% of the cultures were typable. Some common phage types were found in high incidence among cultures from the different regions. No correlation was found between phage type and the pattern of resistance to antibiotics. Phage typing data were presented also on the number of strains in individual urine specimens and the recurrences of strains in patients with chronic bacteriuria. Of 97 fecal isolates, 75.2% of the cultures were typable, and the most common phage type was observed in high incidence among the urinary isolates from this region. When 75 cultures from nine other genera of enteric bacteria were typed, only the shigellae were lysed. In view of the information obtained by phage typing and the ease and speed with which it can be done, it is suggested that phage typing be considered a new tool in epidemiological studies of urinary tract infections by E. coli.     

The morphology and nucleotide composition of DNA of Citrobacter phages

Citrobacter phages 38/37, 31/37, 40/1 and 8/5, isolated from lysogenic cultures, were concentrated and purified by 2 cycles of differential centrifugation. Electron microscopy of the phages has shown that their particles have similar morphology and that they relate to the morphological group A1. The heads of the phages are hexagonal, 50 +/- 2 nm in diameter. The tail of the phage is straight, 112-152 nm in length, with a contracting sheath 11.5-12.5 nm wide. The tails of the phages 38/37 and 40/1 were found to be slightly longer in comparison with the phages 31/37 and 8/5. Chromatographic investigation of DNA preparations of the phages revealed the presence of 4 nitrous bases. Identification of the latter permitted us to relate them to common nitrous bases. DNA of the phages is double-stranded and belongs to a weakly expressed guanine-cytosine type. The content of guanine and cytosine in DNA of the phage 38/37 amounts to 56.68%, that of the phage 31/37 to 56.75, of the phage 40/1 to 57.36% and of the phage 8/5 to 55.58%. No substantial variations were observed in the DNA composition of the phages.