Glucosamine-labelled envelope proteins of Escherichia coli K-12 II. Location in inner and outer membranes

Hydrophobic envelope proteins were extracted by phenol from a glucosamine- and leucine-requiring mutant of Escherichia coli K-12 (E-110). Three protein fractions labelled with D-[1-^{1 4}C]glucosamine and L-[4,5-³H]leucine were obtained by electrophoretic separation. Envelope were isolated from cells labeleed with D-[1-^{1 4}C]glucosamine—HCL and acid hydrolyzed. At least 68% of the radioactivity was recovered as glucosamine and glucose with no random distribution of label. Fingerprinting of pronase digests of glucosamine-labelled proteins showed four radioactive spots associated with peptides. Te glycoproteins were pronase- and trypsin-sensitive and had apparent molecular weights of 11 000 (fast mobility), 35 000 (intermediate mobility) and 62 000 (slow mobility) as estimated by sodium dodecyl sulfate-polyacrylamide disc electrophoresis. The two heavier fractions were labelled with meso-diamino[1,7-^{1 4}C₂]pimelic acid, while ortho[^{3 2}P]phosphate was not incorporated into any fraction. The glucosamine radioactivity of the fast fraction underwent rapid changes upon a chase with non-radioactive glucosamine. Using a Sephadex LH-20 column, the radioactive proteins were separated from the phenol and subsequently fractionated on a DEAS-cellulose column. The DEAE-cellulose fractions were distinct from each other in the number and composition of protein bands, when analyzed by sodium dodecyl sulfate-polyacrylamide disc electrophoresis. Radioactive bands with intermediate and fast electrophoretic mobilities were found in separate DEAE-cellulose fractions.     

Single-stranded conjugation in Escherichia coli K-12

Summary The mutation BT43 in the gene dnaB leads to the inhibition of vegetative and conjugational DNA synthesis at 42°. The consequences in case of conjugation are very unusual. The fragment of donor DNA tramsmitted to the recipient cell remains single-stranded and is integrated as such into the recipient chromosome similar to the main events during transformation. We call this process single-stranded (SS) conjugation.The evidence for this statement comes from the measurement of the time of expression of the gene tsx, containing the genetic information for the receptor of phage T6. The gene tsx is introduced into a dnaBT43 recipient cell alternatively by two different donors Hfr H and Hfr C, which are characterized by opposite directions of transfer. Therefore both donors introduce into the recipient cell alternatively the informational or noninformational DNA strand. If conjugation is performed at a nonpermissive temperature, the transferred DNA piece remains single-stranded and is integrated as such into the recipient chromosome. If it is the informational strand (case of Hfr H), it is transcribed very fast and yields the protein in question in about 20 min. If the noninformational strand is integrated (Hfr C) about 40 min additional time is required to effect cell division.SS-conjugation is very sensitive to the action of exonucleases Exo I and Exo V and is much enhanced in the absence of both nucleases in the recipient.The exogenous DNA pieces are integrated as short insertions, this leads to the disjoining of linked markers and to a very short scale of the genetic map. Because the donor DNA undergoes recombination in the single-stranded state heteroduplex regions originate which are subsequently corrected by the enzymes of the recipient cell. The situation leads to a very special but predictable heterogeneity of the progeny of transconjugants.The fact of the existence of this special process, SS-conjugation, drastically different from common conjugation in many respects, suggests that common conjugation leads to the integration of double-stranded DNA pieces into the recipient chromosome.     

Cloned structural gene (ompA) for an integral outer membrane protein of Escherichia coli K-12

Summary pTU 100 is a hybrid plasmid constructed by cloning a 7.5 Kb EcoRI fragment (carrying the wildtype ompA gene) onto pSC 101 (Henning et al., 1979). This plasmid confers sensitivity to phages Tull^* and K3h1 when present in an ompA host strain, due to the expression of the phage receptor protein II^* from the plasmid ompA ⁺ gene. Plasmid mutants have been isolated that have become resistant to one or both of these phages. Restriction endonuclease analysis and DNA-sequencing studies in these plasmids demonstrate that a BamHI site and two PvuII sites are located within the ompA gene. BamHI cuts the gene at a site corresponding to residue 227 within a total of 325 amino acid residues.Neither the wildtype ompA gene nor the BamHI fragment encoding the NH₂-terminal part of the protein (residues 1–227) could be transferred to a high copy number plasmid, presumably due to lethal overproduction of the protein or its NH₂-terminal fragment. However, the NH₂-terminal fragment derived from one of the ompA mutants of pTU100 could be transferred to the high copy number plasmid pBR322, and was expressed in the presence of the amber suppressors supD or supF. Under these conditions two new envelope proteins with apparent molecular weights of 30,000 and 24,000 were synthesized, and the cells became sensitive to phage TuII^*, indicating the presence of phage receptor activity in the outer membrane. The major, 24,000 dalton protein has the molecular weight expected of a protein comprising residues 1–227 of protein II^*. DNA-sequencing studies demonstrated that no termination codons are present in the DNA region immediately downstream from the BamHI site at residue 227 in this hybrid plasmid, and it is therefore likely that the 24,000-dalton protein arises from the posttranslational proteolytic cleavage of a larger polypeptide. The 30,000-dalton protein is a likely candidate for such a larger polypeptide. These results also demonstrate that the 98 CO₂H-terminal residues of wildtype protein II^* (resisdues 228–325) are not required either for the activity of the protein as a phage receptor or for its incorporation into the outer membrane.     

expA: A conditional mutation affecting the expression of a group of exported proteins in Escherichia coli K-12

Summary A mutant of Escherichia coli K-12 was isolated as conditionally deficient in the expression of two exported proteins simultaneously (i.e. two acid phosphatases) The mutant was found to be thermosensitive on minimal medium at 37°C and above, but grew normally on rich media at these temperatures. The mutation, named expA and located at 22 min on the recalibrated linkage map, depressed the levels of six periplasmic enzymatic activities in bacteria grown at 37°C. At least ten proteins were greatly reduced in the periplasm under these conditions. The mutation also affected some outer membrane proteins, among which were the ompF protein and a protein which may be protein III, but had little effect on cytoplasmic membrane proteins. The gel patterns of the soluble cytoplasmic proteins were not modified except for one major protein of MW 47,000. The activities of -galactosidase and of aspartate transcarbamylase were unmodified. After growth at 30°C no difference was observed between expA and expA ⁺ isogenic strains. The results are discussed with respect to the mechanism of protein export.Enzymes E.C. 3.1.3.2 Acid phosphatase (optimum pH 2.5) - E.C. 3.1.3.2 Acid phosphatase (optimum pH 4.5) - E.C. 3.1.3.1 Alkaline phosphatase - E.C. 3.4.11 Aminopeptidase-N - E.C. 2.1.3.2 Aspartate transcarbamylase - E.C. 3.2.1.23 -galactosidase - E.C. 3.1.27.1 RNase I Abbreviations PNP-OH Para-nitro-phenol - PNA Para-nitro-anilide - PNP-P Para-nitro-phenyl-phosphate - Bis-PNP-P Bis-para-nitro-phenyl-phosphate - IPTG Isopropyl--thiogalactopyranoside, Nitrosoguanidine N-methyl, N'-nitro, N, Nitrosoguanidine, Tris Tris (hydromethyl) aminomethane     

Deletion map of the Escherichia coli K-12 dnaB gene

Summary Acid phosphatase isoenzymes of Chlamydomonas reinhardii were investigated by isoelectric focusing in polyacrylamide gel systems. In this paper we describe in detail an original method for isoelectric focusing of acid phosphatases extracted from wildtype and acid phosphatase-lacking mutant algae, obtained from Laboratoire de Génetique of University of Liège. Three isoenzymes can be separated from the buffer-soluble components of these cells. An additional isoenzyme type can be visualized using the nonionic detergent NP40 as solubilizer. We conclude that these four isoenzymes are releated to the structural gene of the soluble constitutive acid phosphatase, which was shown by their appearance in P ₂ and their total absence in mutant P _a. The pl values of soluble constitutive acid phosphatase isoenzymes range between pH 5.2 and 6.2. As a result of treatment with NP40 the extracts from both wild-type and mutant lines contain two additional active phosphatase forms which can be characterized by their high heat resistance and low pI values. These enzymes are fully active using either -naphthyl phosphate or different acetate esters as substrates.     

Interplasmidic and intraplasmidic recombination in Escherichia coli K-12

Summary The construction of plasmids which facilitate the study of interplasmidic and intraplasmidic recombination is described. In this system, a single recombination event between two mutated Te^r genes on separate plasmids or on one plasmid leads to a change in the host phenotype from sensitivity to resistance to tetracycline.Recombination proficiencies have been determined for different E. coli K-12 strains: both interplasmidic and intraplasmidic recombination are independent of the recBC gene product. RecA mutations decrease the proficiency of plasmidic recombination 40–100 fold. Intraplasmidic and interplasmidic recombination via the recE pathway are more efficient than via the recBC pathway. Intraplasmidic recombination, but not interplasmidic recombination via the recE pathway is independent of a functional recA product.     

New regulatory mutations affecting the expression of the threonine operon in Escherichia coli K-12

Summary The promoter of the threonine operon was joined to the structural genes of the lac operon in Escherichia coli K12. The synthesis of -galactosidase was thus repressed by threonine plus isoleucine in the fusion strains. To isolate mutations which affect the expression of the threonine operon, alterations in the level of expression of the lacZ gene were selected. A new type of regulatory mutation was discovered.This paper is part of a thesis presented by Isabelle Saint-Girons in partial fulfillment of the requirements for the Dr. Sc. degree from the University of Paris     

DNA degradation in minicells of Escherichia coli K-12

Summary The properties of minicell producing mutants of Escherichia coli deficient in gentic recombination were examined. Experiments were designed to test recombinant formation in conjugal crosses, survival following UV-irradiation in cells, and the state of DNA metabolism in minicells. The REC^- phenotypes are unaffected by min ⁺/^- genotypes in whole cells. In contrast to minicells produced by rec ⁺ parental cells, minicells from a recB21 strain have limited capacity to degrade linear, Hfr transferred DNA. The lack of a functional recA gene product, presumably involved in inhibiting the recBC nuclease action(s), permits unrestricted Hfr DNA breakdown in minicells produced by a recA1 strain. This results in an increase in TCA soluble products and in the formation of small DNA molecules that sediment near the top of an alkaline sucrose gradient. Unlike the linear DNA, circular duplex DNA from plasmids R64-11 or dv, segregated into the minicells, is resistant to breakdown. By using in vitro criteria, and [³²P]-labelled linear DNA from bacteriophage T₇ for substrate, we found that the ATP-dependent exonuclease of the recBC complex (exo V) is present in rec ⁺ and recA^- minicells, and is lacking in the recB21 mutant. In fact, the absence of a functional exo V in recBC^- minicells results in isolation of larger than average Hfr DNA from minicells. We suggest that recombination (REC) enzymes segregate into the polar minicells at the time of minicell biogenesis. This system should be useful for studies on DNA metabolism and functions of the recBC and recA gene products.Paper 1 in series, see Khachatourians et al., 1974.     

Hyper-recombination in dam mutants of Escherichia coli K-12

Summary F-prime heterogenotes of dam-3 bacteria segregate F-prime homogenotes at a frequency 30–200 times higher than the isogenic dam ⁺ strain. A hyperrecombination mutant which shows increased recombination between chromosomal duplications was characterized as a dam mutant. The dam-3 allele causes a reduction in linkage of proximal unselected markers in transconjugants and increases the recombination frequency between a pair of closely linked markers. It is concluded that dam mutations confer a hyperrecombination phenotype to the cell.     

Hyper-recombination in uvrD mutants of Escherichia coli K-12

Summary A mutant strain of E. coli which was isolated initially because of its strong hyper-recombination phenotype was shown to carry a lesion in uvrD. The presence of this mutation, designated uvrD210, increased the frequency of recombination between chromosomal duplications in F-prime repliconant cells and reduced linkage between closely linked markers in crosses with Hfr donors. A comparable hyper-rec phenotype was demonstrated in strains carrying other alleles of uvrD previously referred to as mutU4, uvr502 and recL152. The recombination activity of a uvrD210 strain was abolished by mutation of recA but the mutator activity associated with this allele proved to be independent of recA. It is suggested that uvrD mutations reduce the fidelity of DNA replication and that the accumulation of lesions in the newly synthesized strand provides additional sites for initiating recombination.     

Ribosomal mutation in Escherichia coli affecting membrane stability

Summary Mutations in ribosomal protein L6 cause (i) loss of viability of cells at 0° C, which can be prevented by the presence of sodium chloride or 20% sucrose in the medium, (ii) influx of compounds at low temperature that normally cannot penetrate, and (iii) a defective assembly and maturation of 30S and 50S subunits at low temperature. It is proposed that abnormal interaction of immature subunits (or mutant 70S ribosomes) with the cytoplasmic membrane is responsible for triggering breakdown of membrane stability during cold shock.     

Membrane topology and assembly of the outer membrane protein OmpA of Escherichia coli K12

The 325-residue outer membrane protein OmpA of Escherichia coli has been proposed to consist of a membrane-embedded moiety (residues 1 to about 170) and a C-terminal periplasmic region. The former is thought to comprise eight transmembrane segments in the form of antiparallel -strands, forming an amphiphilic connected by exposed turns. Several questions concerning this model were addressed. Thus no experimental evidence had been presented for the turns at the inner leaflet of the membrane and it was not known whether or not the periplasmic part of the polypeptide plays a role in the process of membrane incorporation. Oligonucleotides encoding trypsin cleavage sites were inserted at the predicted turn sites of the ompA gene and it was shown that the encoded proteins indeed become accessible to trypsin at the modified sites. Together with previous results, these data also show that the turns on both sides of the membrane do not possess specifically topogenic information. In two cases one of the two expected tryptic fragments was lost and could be detected at low concentration in only one case. Therefore, bilateral proteolytic digestion of outer membranes can cause loss of -strands and does not necessarily produce a reliable picture of protein topology. When ompA genes were constructed coding for proteins ending at residue 228 or 274, the membrane assembly of these proteins was shown to be partially defective with about 20% of the proteins not being assembled. No such defect was observed when, following the introduction of a premature stop codon, a truncated protein was produced ending with residue 171. It is concluded that (1) the proposed -barrel structure is essentially correct and (2) the periplasmic part of OmpA does not play an active role in, but can, when present in mutant form, interfere with membrane assembly.     

A new radiation sensitive mutant of Escherichia coli K-12

Summary Streptomycin treatment of competent cultures of Bacillus subtilis kills the non competent cells. This method was used to look for mutagenic effects of Streptomyces coelicolor DNA. This DNA was found to induce a class of met⁺ clones harbouring aromatic adventitious mutations.     

Molecular characterisation of the Stc mutation of Escherichia coli K-12

The previously described Stc ^- (suppressor of TolC) mutation modifies the phenotype of tolC mutants from OmpF⁻ to OmpF⁺. Restriction mapping of chromosomal DNA from Stc ⁺ and Stc⁻ strains was performed to investigate the nature of the mutation which was shown to be a deletion, upstream of the ompC gene. DNA from the region of the deletion was cloned into pUC18 and a 650-bp PstI-EcoRI fragment was sequenced. The deletion started 49 bp upstream of the AUG start codon of the ompC gene, thus removing part of the ompC promoter and the whole of the micF gene. We suggest that the deletion of micF gives rise to the Stc⁻ phenotype since the effect of micF expression is assumed to reduce ompF expression, and the Stc⁻ phenotype involves increase in ompF expression.     

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.     

A second purine nucleoside phosphorylase in Escherichia coli K-12

Summary The presence of a second purine nucleoside phosphorylase in wild-type strains of E. coli K-12 after growth on xanthosine has been demonstrated. Like other purine nucleoside phosphorylases it is able to carry out both phosphorylosis and synthesis of purine deoxy- and ribonucleosides whilst pyrimidine nucleosides cannot act as substrates. In contrast to the well characterised purine nucleoside phosphorylase of E. coli K-12 (encoded by the deoD gene) this new enzyme could act on xanthosine and is hence called xanthosine phosphorylase. Studies of its substrate specificity showed that xanthosine phosphorylase, like the mammalian purine nucleoside phosphorylases, has no activity towards adenine and the corresponding nucleosides. Determinations of K _m and gel filtration behaviour was carried out on crude dialysed extracts. The presence of xanthosine phosphorylase enables E. coli to grow on xanthosine as carbon source. Xanthosine was the only compound found which induced xanthosine phosphorylase. No other known nucleoside catabolising enzyme was induced by xanthosine. The implications of non-linear induction kinetics of xanthosine phosphorylase is discussed.     

The process of general recombination in Escherichia coli K-12

Summary A review of the data on the genetic determination of general recombination in Escherichia coli introduces three alternative pathways of recombination, RecBC, RecF, and RecBCF. One recBC-dependent pathway is functional in recF ^– cells. An initiating endonuclease is involved, acting on the chi-sites of DNA. The second is recF-dependent, acting in the double mutant recBC sbcB. The corresponding endonuclease uses the fre-sites as a substrate. A third pathway acting in wild-type cells is mixed. Both enzymatic systems participate in the overall process. We shall call it RecBCF.Using the thermosensitive recA44 mutant it became possible to study the kinetics of integration of donor DNA into the recipient chromosome via the RecF and RecBCF pathways of recombination. The RecF pathway is characterized by delayed recombination; not less than 14 h being needed to complete the process at 35° C. By the RecBCF pathway (wild-type recipient) the reaction is fast, as described by Lloyd and Johnson (1979). The two stage nature of the RecF pathway is important. First an intermediate product is formed during a short time interval. This product is resistant to the degrading exonuclease V. Afterward the intermediate product is slowly integrated into the recipient chromosome. Autoradiography of this intermediate product, extracted from exconjugants, shows that it consists of closed DNA circles. Their length is within the limits 2–15 min on the E. coli map. Their average value is in fair agreement with genetic estimations of the integrated DNA fragments.Taking into consideration the similarity between genetic determinations of the fre-effects and the heterogeneity of the progeny, we conclude that the intermediate structures formed contribute to this heterogeneity.     

Synthesis of Escherichia coli outer membrane OmpA protein in yeasts

Saccharomyces cerevisiae was transformed with the Escherichia coli ompA gene coding for an outer membrane protein. Yeast transformants containing the pYTLJ101 plasmid, consisting of the ompA gene cloned in pSC101 and the HindIII-3 fragment of 2-μm DNA, express the foreign membrane protein. The protein synthesized in yeast has an M_r value very similar if not identical to that of the mature E. coli protein. The expressed protein is present in yeast mitochondrial and plasma membrane fractions. The yeast cell can tolerate about 250 molecules of the foreign membrane protein per cell, although the transformants show altered growth kinetics.