Major proteins of the outer cell envelope membrane of Escherichia coli K12: multiple species of protein I differ in primary structure.

Summary Protein I, one of the major outer membrane proteins of E. coli in most K12 strains is represented by two very similar polypeptides Ia and Ib. Sequential mutations (involving selections for phage resistance) can lead to loss of proteins Ia and Ib. Among revertants of such Ia^- Ib^- mutants clones exist that instead of Ia or Ib produce a third species of protein I, polypeptide Ic.Ichihara and Mizushima [J. Biochem. 83, 1095–1100 (1978)] have shown that proteins Ia and Ib exhibit differences in primary structure. Here evidence is presented indicating that protein Ic also is not identical in primary structure with Ia or Ib. Thus, 3 very similar structural genes appear to exist for the protein I species known to date, and that for Ic normally is silent. Introduction of a functional Ic locus into a Ia⁺ Ib⁺ strain caused expression of all three proteins with a reduced rate of synthesis of protein Ia.     

Functions related to the receptor protein specified by the tsx gene of Escherichia coli

The receptor protein for the phage T6 and colicin K, coded by the tsx gene, facilitated the diffusion of all nucleosides and deoxynucleosides except cytidine and deoxcytidine through the outer membrane of Escherichia coli K-12 and Escherichia coli B. The tsx protein was coregulated with the nucleoside uptake system. Constitutive cytR and deoR mutants contained higher amounts of this protein than wild type strains. There was a good correlation between the initial rate of nucleoside uptake and the adsorption rate of phage T6. From the observation that nucleosides did not compete with each other in the translocation across the outer membrane and that they did not inhibit T6 adsorption it was concluded that the tsx protein forms a pore to which nucleosides have only little if any binding affinity.A major outer membrane protein specified by the ompA gene influenced the function of the tsx protein. Outer membranes of ompA mutants showed an enhanced binding of colicin K but the strains were colicin K insensitive (tolerant). The T6 phage adsorbed at the same rate and plated with the same efficiency as to ompA ⁺ strains. The uptake rate of thymidine and of adenosine was reduced by 16–33% in ompA mutants.The adsorption rate of phage T6 on mutants with altered lipopolysaccharide was the same or even higher than on wild type strains. However the plating efficiency was reduced ranging from 0–46%. Lipopolysaccharide plays no role in the primary adsorption of phage T6 but it is apparently required in a later step of the infection process.Non Standard Abbreviations LPS lipopolysaccharide - cAMP-CRP complex of cyclic adenosine 3,5-monophosphate (cAMP) and its receptor protein (CRP)     

Major proteins of the outer cell envelope membrane of Escherichia coli K-12: multiple species of protein I.

Summary Protein I, one of the major outer membrane proteins ofE. coli, in a number of strains exists as two electrophoretically separable species Ia and Ib. Two phages, TuIa and TuIb, have been found which use, as receptors, proteins Ia and Ib, respectively. Selection for resistance to phage TuIb yielded mutants still possessing protein Ia and missing protein Ib (Ia⁺ Ib^-). Selection in this background, for resistance to phage TuIa yielded one class of mutants missing both species of protein I and another synthesizing a new species of protein I, polypeptide Ic.Tryptic fingerprints of Ia and Ic are very similar and the sequence of 8 N-terminal amino acids is identical for Ia and Ic. Yet, Ic showed an entirely different pattern of cyanogen bromide fragments than that of protein Ia. With another example (cyanogen bromide fragments of protein II^*, with and without performic acid oxidation) it is shown that protein modification can lead to gross changes of the electrophoretic mobility of cyanogen bromide fragments. It is not unlikely that all protein I species observed so far represent in vivo modifications of one and the same polypeptide chain.A genetic analysis together with data from other laboratories revealed that at least 4 widely separated chromosomal loci are involved in the expression of the protein I species known to date.     

Lysis protein T of bacteriophage T4

Summary Lysis protein T of phage T4 is required to allow the phage's lysozyme to reach the murein layer of the cell envelope and cause lysis. Using fusions of the cloned gene t with that of the Escherichia coli alkaline phosphatase or a fragment of the gene for the outer membrane protein OmpA, it was possible to identify T as an integral protein of the plasma membrane. The protein was present in the membrane as a homooligomer and was active at very low cellular concentrations. Expression of the cloned gene t was lethal without causing gross leakiness of the membrane. The functional equivalent of T in phage is protein S. An amber mutant of gene S can be complemented by gene t, although neither protein R of (the functional equivalent of T4 lysozyme) nor S possess any sequence similarity with their T4 counterparts. The murein-degrading enzymes (including that of phage P22) have in common a relatively small size (molecular masses of ca. 18 000) and a rather basic nature not exhibited by other E. coli cystosolic proteins. The results suggest that T acts as a pore that is specific for this type of enzyme.     

Differences in host controlled reactivation of lambdoid and T phages

Summary Phages 434, T4, T5 and T7 are studied with regard to host controlled reactivation of damage produced by UV or photodynamic action sensitized by thiopyronine. Repair of 434 phages proceeds under control of both hcr and rec genes. UV irradiated T5 and T7 phages are reactivated under control of the host's hcr genes only. If these phages are inactivated by photodynamic action they are reactivated not at all. T4 phages inactivated by both treatments are also refractory to host controlled reactivation. These differences might reflect different degrees of autarchy and different abilities of phage DNAs to serve as substrate for recombination enzymes of the host.These results were presented in an abstracted version at the V. International UV colloquium Grundlagen der UV-Wirkung, Kühlungsborn, DDR, in October 1969. The experiments with T5 were done by Mrs. E. Marx.     

Characterization of a phage specific to hemorrhagicEscherichia coli O157:H7 and disclosure of variations in host outer membrane protein OmpC

Phage AR1, previously known to infectEscherichia coli O157:H7 with high specificity, was further characterized for its genetic properties. The phage DNA sequences including capsid genes and a putative -glucosyltransferase gene(-gt) have been deduced. These sequences are conservative but not identical to those of T4 phage. However, a nonessential gene,SegD, organized within the capsid gene cluster of T4 is missing in the corresponding region of AR1 genome, and this characteristic has not been observed among T-even related phages. The difference between AR1 and T4 was further exemplified by their distinct host ranges. Strains ofE. coli O157:H7 collected from different sources were permissive to AR1 but resistant to T4 that normally infects K-12 strains ofE. coli through contact with the outer membrane protein OmpC. Thus, the O157:H7 strains must have a varied OmpC. Indeed, the OmpC sequence of O157:H7 strains was proved to differ from that of K-12 strains by a total of 15 amino acid substitutions and two gaps (a five-residue deletion and a four-residue insertion). The OmpC molecules are relatively conserved across the gram-negative bacteria, and this is the first time OmpC divergence has been found within the sameE. coli species. Since OmpC is located in the outer membrane and its expression is regulated by environmental conditions, alteration of the structure in pathogenic O157:H7 strains may have biological significance.     

Stimulation of T7 DNA polymerase by a new phage-coded protein

Summary A bacteriophage-induced DNA-binding protein was purified from T7 infected E. coli. The protein has a molecular weight of about 25000, as judged by SDS-polyacrylamide gel electrophoresis. The purified protein binds to single-stranded but not to native T7 DNA. Like the T4 gene-32 protein and the 22000-dalton unwinding protein of E. coli, the T7 25000 protein lowers the melting temperature of poly d(A-T). Using partially single-stranded T7 DNA as template-primer, the protein stimulates in vitro DNA synthesis by T7 DNA polymerase about five-fold. It was also found that the DNA-unwinding protein of E. coli stimulates T7 DNA polymerase to approximately the same extent. However, neither of the unwinding proteins stimulate DNA polymerase I of E. coli.     

meoA is the structural gene for outer membrane protein c of Escherichia coli K12

Summary The isolation and characterization of two mutants of Escherichia coli K12 with an altered outer membrane protein c is described. The first mutant, strain CE1151, was isolated as a bacteriophage Mel resistant strain which contains normal levels of protein c. Mutant cells adsorbed the phage with a strongly decreased rate. Complexes of purified nonheat modified wild type protein c and wild type lipopolysaccharide inactivated phage Me1, indicating that these components are required for receptor activity for phage Me1. When wild type protein c was replaced by protein c of strain CE1151, the receptorcomplex was far less active, showing that protein c of strain CE1151 is altered. The second mutant produces a protein c with a decreased electrophoretic mobility, designated as protein c^*. An altered apparent molecular weight was also observed for one or more fragments obtained after fragmentation of the mutant protein with cyanogen bromide, trypsin and chymotrypsin. Alteration of protein c was not accompanied by a detectable alteration in protein b or its fragments. Both mutations are located at minute 48 of the Escherichia coli K12 linkage map. The results strongly suggest that meoA is the structural gene for protein c.     

Tracing the interaction of bacteriophage with bacterial biofilms using fluorescent and chromogenic probes

Phages T4 and E79 were fluorescently-labeled with rhodamine isothiocyanate (RITC), fluoroscein isothiccyanate (FITC), and by the addition of 46-diamidino-2-phenylindole (DAPI) to phage-infected host cells ofEscherichia coli andPseudomonas aeruginosa. Comparisons of electron micrographs with scanning confocal laser microscope (SCLM) images indicated that single RITC-labeled phage particles could be visualized. Biofilms of each bacterium were infected by labeled phage. SCLM and epifluorescence microscopy were used to observe adsorption of phage to single-layer surface-attached bacteria and thicker biofilms. The spread of the recombinant T4 phage, YZA1 (containing an rll-LacZ fusion), within alac E. coli biofilm could be detected in the presence of chromogenic and fluorogenic homologs of galactose. Infected cells exhibited blue pigmentation and fluorescence from the cleavage products produced by the phage-encoded -galactosidase activity. Fluorescent antibodies were used to detect nonlabeled progeny phage. Phage T4 infected both surface-attached and surface-associatedE. coli while phage E79 adsorbed toP. aeruginosa cells on the surface of the biofilm, but access to cells deep in biofilms was somewhat restricted. Temperature and nutrient concentration did not affect susceptibility to phage infection, but lower temperature and low nutrients extended the time-to-lysis and slowed the spread of infection within the biofilm.     

Marker rescue of the adsorption properties of bacteriophage T 4 by bacteriophage T 2

Rescue of adsorption properties from UV-irradiated T4 by T2 as a helper phage, revealed progeny phage with intermediate properties. Fourteen independent progeny phages, plating onE. coli B/2, were plated on several indicator strains and their adsorption properties were also studied with specific T4 antibodies. Two of these, plating onE. coli KS/4, were not inactivated by the T4 antiserum, and were T2h without apparent T4 properties. The other 12 progeny phages did not plate on KS/4, and were inactivated, but at a slower rate than the parental T4. Their mean efficiency of plating onE. coli B/2 (0.83) was significantly lower than that of the parental T4. The efficiency of plating was positively correlated with the velocity of inactivation by T4 antiserum. The observations were explained by assuming that the progeny phages were recombinants of T4 and T2 loci for adsorption sites. Plating of these 12 progeny phages on several indicator strains showed that they were allrII mutants and all, except one, wererI mutants too. In addition, two weretu andh ⁴, respectively. The condition for the appearance of multiple mutants might be a complementation by T2 of UV-damaged functions, which otherwise fail to induce the completion of the lytic cycle in monocomplexes of extracellularly irradiated T4.     

Colicin Ib does not cause plasmid-promoted abortive phage infection of Escherichia coli K-12

Summary A 2.2 kilobase (kb) fragment of ColIdrd-1 cloned in pBR325 causes phage T5 and BF23 infections of Escherichia coli K-12 to abort. This abortive infection is associated with leakage of -galactosidase from the cell. A recombinant plasmid containing a 2.8 kb fragment of ColIdrd-1 encodes colicin Ib but fails to cause abortive infection. Tn5 and Tn10 insertions into ColIdrd-1 that abolish colicin Ib production have no effect on the abortive infection phenotype. These findings are inconsistent with a previously proposed role for colicin Ib in causing phage infections to abort.     

The host specificity system inEscherichia coli SK

E. coli SK has its own enzyme system providing DNA host specificity which differs from the known types of specificity inE. coli K12 andE. coli B. Modification and restriction are observed when the PBVI or PBV3 phages are transferred fromE. coli SK toE. coli B or K12 (and back).A methylase has been isolated fromE. coli SK cells and partly purified. This methylase catalyzesin vitro transfer of the labelled methyl groups from S-adenosylmethionine (SAM) to DNA of both phage and tissue origin which gives rise to 5-methylcytosine (5MC) and 6-methylaminopurine (6MAP). The methylase preparations isolated from the cells at the stationary growth have proved to be 1.5–1.7 times as active as the enzyme from the cells at the logarithmic growth stage. The extract ofE. coli SK cells infected with the phage S_D cannot methylate DNAin vitro. This fact is due tode novo synthesis of the enzyme which disintegrates SAM down to 5-methylthioadenosine (5MTA) and homoserine (HS). This enzyme is not found in the cells infected with the S_D phage in the presence of chloroamphenicole. The activity of the enzyme which disintegrates SAM is the highest between the 4th and the 5th minutes of infection. Thus it may be assumed that this enzyme, most probably, is an early virus specific protein and preventsin vivo methylation of the phage DNA.     

Purification and some properties of presumptive tof gene product of Coli phage 434.

Summary The presumptive tof gene product of Coli phage 434 has been purified from cells carrying imm–⁴³⁴ cIdv plasmid known to contain only some of the early genes of phage 434 and . It was detected and tentatively identified as tof protein primarily by its ability to specifically bind to phage 434 DNA. The protein has a molecular weight of about 11,000 and requires Mg²⁺ for specific DNA binding, unlike 434 cI-repressor.     

Isolation and characterization of a temperature-sensitive amber suppressor mutant of Escherichia coli K12

Summary By mutagenizing an E. coli strain carrying an amber suppressor supD ^- (or su _I ⁺), we isolated a mutant whose amber suppressor activity was now temperature-sensitive. The mutant suppressor gene was named sup-126, which was found to be cotransduced with the his gene by phage P1vir at the frequency of ca. 20%. At 30° C it suppresses many amber mutations of E. coli, phage T4, and phage . At 42° C, however, it can suppress none of over 30 amber mutations tested so far. The sup-126 mutation is unambiguous and stable enough to be useful for making production of an amber protein temperature-sensitive.     

Identification of a New Site for Ferrichrome Transport by Comparison of the FhuA Proteins of Escherichia coli, Salmonella paratyphi B, Salmonella typhimurium, and Pantoea agglomerans

The fhuA genes of Salmonella paratyphi B, Salmonella typhimurium, and Pantoea agglomerans were sequenced and compared with the known fhuA sequence of Escherichia coli. The highly similar FhuA proteins displayed the largest difference in the predicted gating loop, which in E. coli controls the permeability of the FhuA channel and serves as the principal binding site for the phages T1, T5, and 80. All the FhuA proteins contained the region in the gating loops required in E. coli for ferrichrome and albomycin transport. The three subdomains required for phage binding were contained in the gating loop of S. paratyphi B which is infected by the E. coli phages, whereas two of the subdomains were deleted in S. typhimurium and P. agglomerans which are resistant to the E. coli phages. Small deletions in a surface loop adjacent to the gating loop, residues 236 to 243 and 236 to 248, inactivated E. coli FhuA with regard to transport of ferrichrome and albomycin, but sensitivity to T1 and T5 was fully retained and sensitivity to 80 and colicin M was reduced 10-fold. Full-size FhuA hybrid proteins of S. paratyphi B and S. typhimurium displayed S. paratyphi B FhuA activity when the hybrids contained two-thirds of either the N- or the C-terminal portions of S. paratyphi B and displayed S. typhimurium FhuA activity to phage ES18 when the hybrid contained two-thirds of the N-terminal region of the S. typhimurium FhuA. The central segment of the S. paratyphi B FhuA flanked on both sides by S. typhimurium FhuA regions conferred full sensitivity only to phage T5. The data support the essential role of the gating loop for the transport of ferrichrome and albomycin, identified an additional loop for ferrichrome and albomycin uptake, and suggest that several segments and their proper conformation, determined by the entire FhuA protein, contribute to the multiple FhuA activities.     

Inhibition of modification and restriction for phages lambda and T-1 by co-infecting T3

Summary The host controlled modifications of phage -DNA byEscherichia coli B, K, and C (P1) can be suppressed by preinfecting the bacteria with UV-irradiated phage T3. Since UV-irradiated T3 induces an enzyme which cleaves S-adenosylmethionine into homoserine and thiomethyl adenosine, and since S-adenosylmethionine is the only methyl group donor for DNA methylation, we conclude that methylation is a required step in the host controlled modification of -DNA.T3 itself successfully infectsE. coli K and B with its nonmethylated DNA. Also, restricted phage or T1 will be accepted by the restrictive hostsE. coli B, K, and C(P1) if these are preinfected with UV-T3. It thus appears that T3 is capable of blocking the restriction mechanisms in these hosts.The inability of T3 to grow on C(P1) is not understood. Since T3-DNA is restricted but not degraded into nucleotides byE. coli C(P1) we presume that degradation is not the initial step in restriction.Supported by Grant No. GB 1033 R of the National Science Foundation.Postdoctoral fellow of the Deutsche Forschungsgemeinschaft.     

Function of cloned T4 recombination genes, uvsX and uvsY, in cells of Escherichia coli

Summary Genes uvsX and uvsY of bacteriophage T4 both control genetic recombination and repair of damaged DNA, and their mutant phenotypes bear a striking resemblance to each other. It has been shown recently that the uvsX gene product is analogous to the recA gene product of Escherichia coli (Yonesaki et al. 1985; Yonesaki and Minagawa 1985; Formosa and Alberts 1986), but the function of the uvsY gene is unknown. To obtain further insight into the function of these genes we introduced plasmid-borne copies of the two genes separately or together into E. coli. The uvsX gene rendered recA ^- cells more resistant to UV and raised the recombination frequency of phage and E. coli, but hampered induction of the prophage and the SOS function of E. coli. The uvsY gene had no detectable function when introduced alone into E. coli but significantly enhanced the function of the uvsX gene when the two plasmid-borne genes were introduced together.     

Molecular cloning of the genes for xylan degradation of Bacillus pumilus and their expression in Escherichia coli

Summary The 7.7 Mdal PstI fragment of Bacillus pumilus IPO containing genes for xylan degradation, xylanase, and -xylosidase was inserted at the PstI site of pBR322 and cloned in E. coli C600. The hybrid plasmid thus formed was named pOXN29. The amount of xylanase and -xylosidase expressed in E. coli harboring pOXN29 was about 6% and 20% of the activity produced by the donor, B. pumilus. The reverse orientation of the inserted fragment resulted respectively in 5 times and 50 times increases in xylanase and -xylosidase productivities. Both enzymes expressed in E. coli transformants were shown to be indistinguishable from those of B. pumilus by immunological and chemical criteria. Digestion of pOXN29 with BglII produced two fragments; one was 6.7 Mdal in size and contained the whole pBR322 and the -xylosidase gene, and the other was 3.7 Mdal and coded for xylanase. Analysis of enzymes expressed in the transformant cells indicated that neither enzyme was secreted into the culture medium, periplasm nor membrane bound, although xylanase but not -xylosidase, was secreted into the medium in a B. pumilus culture.     

β-Oxidation-mediated resistance ofEscherichia coli to inhibition by long-chain fatty acids

Decanoate exerted a stronger bactericidal action onEscherichia coli K76 (-oxidation negative) than on its -oxidation constitutive parent,E. coli K113; both strains had a normal lipopolysaccharide layer.E. coli RC59, a mutant carrying a defective lipopolysaccharide layer, was more sensitive than its parent,E. coli O111B4, to the growth inhibition by decanoate. Oleate did not affectE. coli RC59 viability, but washing of the cells rendered them sensitive.E. coli RC59 was unable to degrade decanoate and oleate. A mutant of this strain was isolated (E. coli ER20) which retained the defective lipopolysaccharide but was able to metabolize oleic acid. When the killing effect of oleate was assayed on washed cells ofE. coli O111B4, RC59, and ER20, a positive correlation between -oxidation activity and the number of surviving viable cells was found. The ability of Gram-negative organisms to withstand the toxic effect of fatty acids was attributed to the presence of a lipolysaccharide (LPS) layer in the cell envelope. An additional mechanism of resistance is suggested by the results in this report which show that the ability to oxidize fatty acids contributes to resistance.     

Purification of Lac repressor protein using polymer displacement and immobilization of the protein

Lac repressor protein was purified from E. coli BMH8117 harboring plasmid pWB1000 and E. coli K₁₂BMH 71-18 strains. Displacement of the protein with poly(ethyleneimine) (PEI) from phosphocellulose cation exchange column was shown to be an effective elution strategy. It resulted in better recoveries and sharper elution profiles than traditional salt elution without effecting the purity of the protein. The elution is assumed to proceed via displacement of bound protein by PEI when the polymer binds to the ion exchanger. The minor impurities in the protein solution were finally removed by chromatography on immobilized metal affinity column. The repressor protein undergoes distinct conformational changes upon addition of specific inducer isopropyl--D-thiogalactoside (IPTG), which is evidenced by changes in ultraviolet absorption spectrum. The protein was immobilized covalently to the Sepharose matrix. The intact biological activity of the protein after immobilization was shown by binding of genomic DNA and lac operator plasmid DNA from E. coli to the immobilized lac repressor.