Electrooptical analysis of the Escherichia coli-phage interaction

This article describes electrooptical (EO) characterization of biospecific binding between the bacterium Escherichia coli XL-1 and the phage M13K07. The electrooptical analyzer (ELUS EO), which has been developed at the State Research Center for Applied Microbiology, Obolensk, Russia, was used as the basic instrument for EO measurements. The operating principle of the analyzer is based on the polarizability of microorganisms, which depends strongly on their composition, morphology, and phenotype. The principle of analysis of the interaction of E. coli with the phage M13K07 is based on registration of changes of optical parameters of bacterial suspensions. The phage-cell interaction includes the following stages: phage adsorption on the cell surface, entry of viral DNA into the bacterial cell, amplification of phage within infected host, and phage ejection from the cell. In this work, we used M13K07, a filamentous phage of the family Inoviridae. Preliminary study had shown that combination of the EO approach with a phage as a recognition element has an excellent potential for mediator-less detection of phage-bacteria complex formation. The interaction of E. coli with phage M13K07 induces a strong and specific EO signal as a result of substantial changes of the EO properties of the E. coli XL-1 suspension infected by the phage M13K07. The signal was specific in the presence of foreign microflora (E. coli K-12 and Azospirillum brasilense Sp7). Integration of the EO approach with a phage has the following advantages: (1) bacteria from biological samples need not be purified, (2) the infection of phage to bacteria is specific, (3) exogenous substrates and mediators are not required for detection, and (4) it is suitable for any phage-bacterium system when bacteria-specific phages are available.     

利用重组噬菌体诱导表达的大肠杆菌表达系统

将编码噬菌体T7RNA聚合酶的基因克隆至噬菌体M13mpl8RFDNA中,置于lac启动子的控制之下,得到了可表达T7 RNA聚合酶的重组噬菌体M13HEP。利用该噬菌体感染含T7启动子表达质粒的宿主菌以提供T7RNA聚合酶,可以诱导T7启动子控制下的外源基因的表达。该噬茵体诱导表达系统已成功地表达了多种外源基因,特别是一些表达产物对宿主菌有毒性的基因。同时,通过细菌接合将F',因子从大脑杆菌XL1-blue转至大肠杆菌HMS174,构建了新的大脑杆菌菌株HMSl74F,,使得T7表达质粒构建、表达及单链制备可以在同一菌株中完成,得到了一个完整的T7表达系统。     

The SOS and catabolytic repression systems can play a key role in the regulation of infection of Escherichia coli cells with F-specific filamentous phages M13, f1 and fd

Theoretical analysis of DNA sequences revealed recognition sites for two global E. coli cellular regulons in M13, fd and fl phage's genomes. Both Px and Pv promoters have SOS operator sequences and therefore must be repressed by the lexA protein. PIII and PIV contains CRP-cAMP recognition sequences in activating positions and hence will be activated by the cAMP receptor protein. The model is proposed for the phage life cycle's control in the persistent infection of E. coli cells by F-specific filamentous phages.     

M13-oriC cloning vehicles: use for amplification of high copy lethal (HCL) genetic elements

M13 cloning vehicles have been constructed which contain the Escherichia coli origin for DNA replication (oriC), with and without selectable antibiotic-resistance genes. Since the M13 viral strand origin requires a functional rep gene product, using oriC these vehicles propagate as low-copy-number plasmids in E. coli rep mutants. This property is exploited to amplify cloned "high copy lethal" (HCL) DNA fragments, those containing genetic elements which kill the E. coli host when present at multiple copies in the cell. Following cloning of such fragments in these vehicles and initial selection in E. coli rep cells, the M13-oriC chimeric plasmid DNA is used to transfect appropriate E. coli rep+ cells. The chimeric DNA propagates as M13 viral DNA, yielding double-stranded and single-stranded DNA products and phage particles prior to killing of the host via expression of the HCL element; these events mimic a lytic phage infection. Such amplification will greatly facilitate both DNA "library" constructions (HCL elements are absent a priori from libraries using high-copy-number cloning vehicles) and studies of HCL elements including restriction mapping, DNA sequencing, and physiological studies.     

抗鳗弧菌独特型单克隆抗体dsFv的构建及其噬菌体表面呈现

抗鳗弧菌独特型单克隆抗体 1E10是能够模拟鳗弧菌的保护性表位 ,可以作为疫苗使用的一种单克隆抗体 .利用基因工程抗体技术从抗鳗弧菌独特型单克隆抗体杂交瘤细胞株 1E10中克隆出抗体的重链及轻链可变区基因 (VH 和VL) .通过定点突变技术将VH4 4和VL10 5突变为半胱氨酸并且连接到噬菌体表达载体pCANTAB5E中 ,突变后的VH 和VL 基因位于cpⅢ先导序列和cpⅢ基因之间 ,在LacZ启动子调控之下 ,以融合蛋白的形式被导入细胞间隙 ,依靠链间二硫键组装成二硫键稳定型Fv抗体 (dsFv) .加入辅助噬菌体M13K0 7后 ,dsFv以融合蛋白的形式表达在噬菌体表面 .ELISA测定显示 :dsFv噬菌体能够与抗原结合并且这种结合呈噬菌体浓度依赖 .结果表明 :成功构建出了抗鳗弧菌独特型单克隆抗体dsFv基因并使其在噬菌体表面获得了正确呈现 .该dsFv噬菌体有望成为新一代基因工程疫苗用于预防鱼类鳗弧菌感染     

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.     

SOS induction in Escherichia coli by infection with mutant filamentous phage that are defective in initiation of complementary-strand DNA synthesis.

We report that the SOS response is induced in Escherichia coli by infection with mutant filamentous phage that are defective in initiation of the complementary (minus)-strand synthesis. One such mutant, R377, which lacks the entire region of the minus-strand origin, failed to synthesize any detectable amount of primer RNA for minus-strand synthesis. In addition, the rate of conversion of parental single-stranded DNA of the mutant to the double-stranded replicative form in infected cells was extremely slow. Upon infection, R377 induced the SOS response in the cell, whereas the wild-type phage did not. The SOS induction was monitored by (i) induction of beta-galactosidase in a strain carrying a dinD::lacZ fusion and (ii) increased levels of RecA protein. In addition, cells infected with R377 formed filaments. Another deletion mutant of the minus-strand origin, M13 delta E101 (M. H. Kim, J. C. Hines, and D. S. Ray, Proc. Natl. Acad. Sci. USA 78:6784-6788, 1981), also induced the SOS response in E. coli. M13Gori101 (D. S. Ray, J. C. Hines, M. H. Kim, R. Imber, and N. Nomura, Gene 18:231-238, 1982), which is a derivative of M13 delta E101 carrying the primase-dependent minus-strand origin of phage G4, did not induce the SOS response. These observations indicate that single-stranded DNA by itself induces the SOS response in vivo.     

A visualization method of filamentous phage infection and phage-derived proteins in Escherichia coli using biotinylated phages.

Direct visualization of filamentous phage infection in Escherichia coli (E. coli) was attempted using biotinylated phages (BIO-phages). The biotinylation of the phages did not influence their infectivity into E. coli. E. coli infected with BIO-phages could be detected by using fluorescein-conjugated avidin with confocal laser scanning microscopy, and BIO-phages and BIO-phage-derived proteins in E. coli could be directly observed by using the avidin-biotin-peroxidase complex method with electron microscopy. This is the first report of direct visualization of phage infection and phage-derived proteins in the host cell using a biotin-avidin interaction. This simple and powerful method is applicable to the study of infection by various viruses.     

Bacteriophage T4 Inhibits Colicin E2-Induced Degradation of Escherichia coli Deoxyribonucleic Acid I. Protein Synthesis-Dependent Inhibition

The deoxyribonucleic acid (DNA) of Escherichia coli B is converted by colicin E2 to products soluble in cold trichloroacetic acid; we show that this DNA degradation (hereafter termed solubilization) is subject to inhibition by infection with bacteriophage T4. At least two modes of inhibition may be differentiated on the basis of their sensitivity to chloramphenicol. The following observations on the inhibition of E2 by phage T4 in the absence of chloramphenicol are described: (i) Simultaneous addition to E. coli B of E2 and a phage mutated in genes 42, 46, and 47 results in a virtually complete block of the DNA solubilization normally induced by E2; the mutation in gene 42 prevents phage DNA synthesis, and the mutations in genes 46 and 47 block a late stage of phage-induced solubilization of host DNA. (ii) This triple mutant inhibits equally well when added at any time during the E2-induced solubilization. (iii) Simultaneous addition to E. coli B of E2 and a phage mutated only in gene 42 results in extensive DNA solubilization, but the amount of residual acid-insoluble DNA (20 to 25%) is more characteristic of phage infection than of E2 addition (5% or less). (iv) denA mutants of phage T4 are blocked in an early stage (endonuclease II) of degradation of host DNA; when E2 and a phage mutated in both genes 42 and denA are added to E. coli B, extensive solubilization of DNA occurs with a pattern identical to that observed upon simultaneous addition of E2 and the gene 42 mutant. (v) However, delaying E2 addition for 10 min after infection by this double mutant allows the phage to develop considerable inhibition of E2. (vi) Adsorption of E2 to E. coli B is not impaired by infection with phage mutated in genes 42, 46, and 47. In the presence of chloramphenicol, the inhibition of E2 by the triple-mutant (genes 42, 46, and 47) still occurs, but to a lesser extent.     

Escherichia coli mutT mutator effect during in vitro DNA synthesis. Enhanced A.G replicational errors

The mechanism of the Escherichia coli mutT mutator effect was investigated using single-stranded phage as a mutational target. In vivo experiments showed that two M13mp2 lacZ alpha nonsense mutants reverted at a higher rate on a mutT1 host than on the wild-type host. The specificity of this mutator effect was identical to that observed for E. coli genes: A.T----C.G transversions. The mutT effect was subsequently demonstrated in vitro during DNA replication of M13mp2 DNA in cell-free extracts of E. coli. Replication (the single-stranded----replicative form conversion) in mutT1 extracts proceeded with a higher error rate than in wild-type extracts, and DNA sequence analysis of the in vitro revertants revealed the specific induction of A.T----C.G transversions. On the basis of the template specificity of the mutT effect in vitro, we conclude that the mutT effect involves the aberrant processing of A.G rather than T.C mispairs.     

Identification of Yersinia enterocolitica genes affecting survival in an animal host using signature-tagged transposon mutagenesis

Pathogenic Yersinia species are associated with both localized and systemic infections in mammalian hosts. In this study, signature-tagged transposon mutagenesis was used to identify Yersinia enterocolitica genes required for survival in a mouse model of infection. Approximately 2000 transposon insertion mutants were screened for attenuation. This led to the identification of 55 mutants defective for survival in the animal host, as judged by their ability to compete with the wild-type strain in mixed infections. A total of 28 mutants had transposon insertions in the virulence plasmid, validating the screen. Two of the plasmid mutants with severe virulence defects had insertions in an uncharacterized region. Several of the chromosomal insertions were in a gene cluster involved in O-antigen biosynthesis. Other chromosomal insertions identified genes not previously demonstrated as being required for in vivo survival of Y. enterocolitica. These include genes involved in the synthesis of outer membrane components, stress response and nutrient acquisition. One severely attenuated mutant had an insertion in a homologue of the pspC gene (phage shock protein C) of Escherichia coli. The phage shock protein operon has no known biochemical or physiological function in E. coli, but is apparently essential for the survival of Y. enterocolitica during infection.     

Identification of Avian pathogenic Escherichia coli genes that are induced in vivo during infection in chickens

Avian pathogenic Escherichia coli (APEC) is associated with extraintestinal infections in poultry causing a variety of diseases collectively known as colibacillosis. The host and bacterial factors influencing and/or responsible for carriage and systemic translocation of APEC inside the host are poorly understood. Identification of such factors could help in the understanding of its pathogenesis and in the subsequent development of control strategies. Recombination-based in vivo expression technology (RIVET) was used to identify APEC genes specifically expressed during infection in chickens. A total of 21 clones with in vivo-induced promoters were isolated from chicken livers and spleens, indicative of systemic infection. DNA sequencing of the cloned fragments revealed that 12 of the genes were conserved E. coli genes (metH, lysA, pntA, purL, serS, ybjE, ycdK [rutC], wcaJ, gspL, sdsR, ylbE, and yjiY), 6 of the genes were phage related/associated, and 3 genes were pathogen specific (tkt1, irp2, and eitD). These genes are involved in various cellular functions, such as metabolism, cell envelope and integrity, transport systems, and virulence. Others were phage related or have yet-unknown functions.