Expression of the cloned subunits of bacterial luciferase from separate replicons

The lux A and lux B genes of Vibrio harveyi, encoding the alpha and beta subunits of bacterial luciferase, were cloned individually into Escherichia coli in two different compatible plasmids. Active luciferase was formed in an amount equal to that produced in cells carrying a plasmid with the cloned genes on a single fragment.     

Stable co-existence of separate replicons in Escherichia coli is dependent on once-per-cell-cycle initiation

DNA replication in most organisms is regulated such that all chromosomes are replicated once, and only once, per cell cycle. In rapidly growing Escherichia coli, replication of eight identical chromosomes is initiated essentially simultanously, each from the same origin, oriC. Plasmid-borne oriC sequences (minichromosomes) are also initiated in synchrony with the eight chromosomal origins. We demonstrate that specific inactivation of newly formed, hemimethylated origins (sequestration) was required for the stable co-existence of oriC-dependent replicons. Cells in which initiations were not confined to a short interval in the cell cycle (carrying mutations in sequestration or initiation genes or expressing excess initiator protein) could not support stable co-existence of several oriC-dependent replicons. The results show that such stable co-existence of oriC-dependent replicons is dependent on both a period of sequestration that is longer than the initiation interval and a reduction of the initiation potential during the sequestration period. These regulatory requirements are the same as those required to confine initiation of each replicon to once, and only once, per cell cycle.     

Expression of pyruvate formate-lyase of Escherichia coli from the cloned structural gene

It is shown here that a plasmid (p29) derived from the transducing phage aspC2 (Christiansen and Pedersen 1981) codes for pyruvate formate-lyase. The identity of the 80 kilodaltons (kd) gene product of plasmid p29 with the pyruvate formate-lyase polypeptide was proven (i) by comigration of the gene product expressed in the maxicell system with purified enzyme on O'Farrell gels, and (ii) by comparison of the peptide maps obtained from limited proteolysis. In vivo the 80 kd form of the enzyme was proteolytically converted to a 78 kd polypeptide. The two polypeptides (80 kd and 78 kd) and their charge isomers present in purified enzyme preparations are therefore products of a single gene.Aerobically grown cells of Escherichia coli contained a basal level of pyruvate formate-lyase which was derepressed 5-to 10-fold under anaerobiosis. Derepression also occurred during anaerobic growth on glycerol plus fumarate. Presence of plasmid p29 caused overproduction of pyruvate formatelyase, 11-fold upon anaerobic growth on glucose, 14-fold upon aerobic growth on glucose and 33-fold upon aerobic growth at the expense of D-lactate.Non-Standard Abbreviation MOPS 4-morpholine-propane sulfonic     

Expression of cloned monkey metallothionein in Escherichia coli

Expression vectors were constructed in which a cDNA specifying the monkey kidney metallothionein-II (MT-II) was linked directly to the lambda PR promoter. Enhanced expression of MT-II in Escherichia coli was observed when two initiation signals were tandemly linked to the MT-II gene and the lambda cI+ host cells were induced by nalidixic acid.     

Expression of cloned monkey metallothionein in Escherichia coli.

Expression vectors were constructed in which a cDNA specifying the monkey kidney metallothionein-II (MT-II) was linked directly to the lambda PR promoter. Enhanced expression of MT-II in Escherichia coli was observed when two initiation signals were tandemly linked to the MT-II gene and the lambda cI+ host cells were induced by nalidixic acid.     

Nucleotide binding affinities of the intact proton-translocating transhydrogenase from Escherichia coli

Transhydrogenase (E.C. 1.6.1.1) couples the redox reaction between NAD(H) and NADP(H) to the transport of protons across a membrane. The enzyme is composed of three components. The dI and dIII components, which house the binding site for NAD(H) and NADP(H), respectively, are peripheral to the membrane, and dII spans the membrane. We have estimated dissociation constants (K(d) values) for NADPH (0.87 microM), NADP(+) (16 microM), NADH (50 microM), and NAD(+) (100-500 microM) for intact, detergent-dispersed transhydrogenase from Escherichia coli using micro-calorimetry. This is the first complete set of dissociation constants of the physiological nucleotides for any intact transhydrogenase. The K(d) values for NAD(+) and NADH are similar to those previously reported with isolated dI, but the K(d) values for NADP(+) and NADPH are much larger than those previously reported with isolated dIII. There is negative co-operativity between the binding sites of the intact, detergent-dispersed transhydrogenase when both nucleotides are reduced or both are oxidized.     

Expression of cloned calf prochymosin gene sequence in Escherichia coli

An expression plasmid for calf prochymosin (prorennin) cDNA was constructed. The plasmid (pCR301) contains the lacUV5 promoter in front of the fused gene in which the codons for the N-terminal four amino acids of prochymosin cDNA were replaced with those for the N-terminal ten amino acids of beta-galactosidase. Synthesis of the fused protein with the expected Mr was detected immunologically in Escherichia coli harboring pCR301. The product seemed to be localized in the cell membrane of the bacterial host.     

Properties of a proton-translocating nicotinamide nucleotide transhydrogenase from Escherichia coli with alpha and beta subunits linked through fused transmembrane helices.

Proton-translocating nicotinamide nucleotide transhydrogenase from Escherichia coli is composed of an alpha and a beta subunit, whereas the homologues mitochondrial enzyme contains a single polypeptide. As compared to the latter transhydrogenase, using a 14-helix model for its membrane topology, the point of fusion is between the transmembrane helices 4 and 6 where the fusion linker provides the extra transmembrane helix 5. In order to clarify the potential role of this extra helix/linker, the alpha and the beta subunits were fused using three connecting peptides of different lengths, one (pAX9) involving essentially a direct coupling, a second (pKM) with a linking peptide of 18 residues, and a third (pKMII) with a linking peptide of 32 residues, as compared to the mitochondrial extra peptide of 27 residues. The results demonstrate that the plasma membrane-bound and purified pAX9 enzyme with the short linker was partly misfolded and strongly inhibited with regard to both catalytic activities and proton translocation, whereas the properties of pKM and pKMII with longer linkers were similar to those of wild-type E. coli transhydrogenase but partly different from those of the mitochondrial enzyme although pKMII generally gave higher activities. It is concluded that a mitochondrial-like linking peptide is required for proper folding and activity of the E. coli fused transhydrogenase, and that differences between the catalytic properties of the E. coli and the mitochondrial enzymes are unrelated to the linking peptide. This is the first time that larger subunits of a membrane protein with multiple transmembrane helices have been fused with retained activity.     

Essential glycine in the proton channel of Escherichia coli transhydrogenase

The nicotinamide nucleotide transhydrogenases of mitochondria and bacteria are proton pumps that couple hydride ion transfer between NAD(H) and NADP(H) bound, respectively, to extramembranous domains I and III, to proton translocation by the membrane-intercalated domain II. Previous experiments have established the involvement of three conserved domain II residues in the proton pumping function of the enzyme: His91, Ser139, and Asn222, located on helices 9, 10, and 13, respectively. Eight highly conserved domain II glycines in helices 9, 10, 13, and 14 were mutated to alanine, and the mutant enzymes were assayed for hydride transfer between domains I and III and for proton translocation by domain II. One of the glycines on helix 14, Gly252, was further mutated to Cys, Ser, Thr, and Val, expression levels of the mutant enzymes were evaluated, and each was purified and assayed. The results show that Gly252 is essential for function and support a model for the proton channel composed of helices 9, 10, 13, and 14. Gly252 would allow spatial proximity of His91, Ser139, and Asn222 for proton conductance within the channel. Gly252 mutants are distinguished by high levels of cyclic transhydrogenation activity in the absence of added NADP(H) and by complete loss of proton pumping activity. The purified G252A mutant has <1% proton translocation and reverse transhydrogenation activity, retains 0.9 mol of NADP(H) per domain III, and has 96% intrinsic cyclic transhydrogenation activity, which does not exceed 100% upon the addition of NADP(H). These properties imply that Gly252 mutants exhibit a native-like domain II conformation while blocking proton translocation and coupled exchange of NADP(H) in domain III.     

Overexpression and biochemical characterization of soluble pyridine nucleotide transhydrogenase from Escherichia coli

The soluble pyridine nucleotide transhydrogenase (STH) is an energy-independent flavoprotein that directly catalyzes hydride transfer between NAD(H) and NADP(H) to maintain homeostasis of these two redox cofactors. The sth gene in Escherichia coli was cloned and expressed as a fused protein (EcSTH). The purified EcSTH displayed maximal activity at 35 °C, pH 7.5. Heat-inactivation studies showed that EcSTH retains 50% activity after 5 h at 50 °C. The enzyme was stable at 4 °C for 25 days. The apparent K(m) values of EcSTH were 68.29 μM for NADPH and 133.2 μM for thio-NAD(+) . The k(cat) /K(m) ratios showed that EcSTH had a 1.25-fold preference for NADPH over thio-NAD(+) . Product inhibition studies showed that EcSTH activity was strongly inhibited by excess NADPH, but not by thio-NAD(+) . EcSTH activity was enhanced by 2 mM adenine nucleotide and inhibited by divalent metal ions: Mn(2+) , Co(2+) , Zn(2+) , Ni(2+) and Cu(2+) . However, after preincubation for 30 min, most divalent metal ions had little effect on EcSTH activity, except Zn(2+) , Ni(2+) and Cu(2+) . The enzymatic analysis could provide the important basic knowledge for EcSTH utilizations.     

Three-dimensional structure prediction of the NAD binding site of proton-pumping transhydrogenase from Escherichia coli

A three-dimensional structure of the NAD site of Escerichia coli transhydrogenase has been predicted. The model is based on analysis of conserved residues among the transhydrogenases from five different sources, homologies with enzymes using NAD as cofactors or substrates, hydrophilicity profiles, and secondary structure predictions. The present model supports the hypothesis that there is one binding site, located relatively close to the N-terminus of the α-subunit. The proposed structure spans residues α145 to α287, and it includes five β-strands and five α-helices oriented in a typical open twisted α/β conformation. The amino acid sequence following the GXGXXG dinucleotide binding consensus sequence (residues α172 to α177) correlates exactly to a typical fingerprint region for ADP binding βαβ folds in dinucleotide binding enzymes. In the model, aspartic acid α195 forms hydrogen bonds to one or both hydroxyl groups on the adenosine ribose sugar moiety. Threonine α196 and alanine α256, located at the end of βB and βD, respectively, create a hydrophobic sandwich with the adenine part of NAD buried inside. The nicotinamide part is located in a hydrophobic cleft between αA and βE. Mutagenesis work has been carried out in order to test the predicted model and to determine whether residues within this domain are important for proton pumping directly. All data support the predicted structure, and no residue crucial for proton pumping Was detected. Since no three-dimensional structure of transhydrogenase has been solved, a well based tertiary structure prediction is of great value for further experimental design in trying to elucidate the mechanism of the energy-linked proton pump. © 1995 Wiley-Liss, Inc.     

X-ray structure of domain I of the proton-pumping membrane protein transhydrogenase from Escherichia coli

The dimeric integral membrane protein nicotinamide nucleotide transhydrogenase is required for cellular regeneration of NADPH in mitochondria and prokaryotes, for detoxification and biosynthesis purposes. Under physiological conditions, transhydrogenase couples the reversible reduction of NADP+ by NADH to an inward proton translocation across the membrane. Here, we present crystal structures of the NAD(H)-binding domain I of transhydrogenase from Escherichia coli, in the absence as well as in the presence of oxidized and reduced substrate. The structures were determined at 1.9-2.0 A resolution. Overall, the structures are highly similar to the crystal structure of a previously published NAD(H)-binding domain, from Rhodospirillum rubrum transhydrogenase. However, this particular domain is unique, since it is covalently connected to the integral-membrane part of transhydrogenase. Comparative studies between the structures of the two species reveal extensively differing surface properties and point to the possible importance of a rigid peptide (PAPP) in the connecting linker for conformational coupling. Further, the kinetic analysis of a deletion mutant, from which the protruding beta-hairpin was removed, indicates that this structural element is important for catalytic activity, but not for domain I:domain III interaction or dimer formation. Taken together, these results have important implications for the enzyme mechanism of the large group of transhydrogenases, including mammalian enzymes, which contain a connecting linker between domains I and II.     

Expression and regulation of the penicillin G acylase gene from Proteus rettgeri cloned in Escherichia coli.

The penicillin G acylase genes from the Proteus rettgeri wild type and from a hyperproducing mutant which is resistant to succinate repression were cloned in Escherichia coli K-12. Expression of both wild-type and mutant P. rettgeri acylase genes in E. coli K-12 was independent of orientation in the cloning vehicle and apparently resulted from recognition in E. coli of the P. rettgeri promoter sequences. The P. rettgeri acylase was secreted into the E. coli periplasmic space and was composed of subunits electrophoretically identical to those made in P. rettgeri. Expression of these genes in E. coli K-12 was not repressed by succinate as it is in P. rettgeri. Instead, expression of the enzymes was regulated by glucose catabolite repression.     

Expression of the cloned ColE1 kil gene in normal and Kilr Escherichia coli

The kil gene of the ColE1 plasmid was cloned under control of the lac promoter. Its expression under this promoter gave rise to the same pattern of bacterial cell damage and lethality as that which accompanies induction of the kil gene in the colicin operon by mitomycin C. This confirms that cell damage after induction is solely due to expression of kil and is independent of the cea or imm gene products. Escherichia coli derivatives resistant to the lethal effects of kil gene expression under either the normal or the lac promoter were isolated and found to fall into several classes, some of which were altered in sensitivity to agents that affect the bacterial envelope.     

Characterization of the cloned Escherichia coli dihydrofolate reductase

Dihydrofolate reductase (5,6,7,8-tetrahydrofolate: NADP+ oxidoreductase, EC 1.5.1.3) was purified from Escherichia coli strains that carried derivatives of the multicopy recombinant plasmid, pJFM8. The results of enzyme kinetic and two-dimensional gel electrophoresis experiments showed that the cloned enzyme is indistinguishable from the chromosomal enzyme. Therefore it can be concluded that these strains are ideal for use as a source of enzyme for further studies on the biochemistry and regulation of this important enzyme. The plasmid derivatives were constructed by recloning experiments that utilized several restriction endonucleases. From the analysis both of these plasmids and the purified dihydrofolate reductase enzymes it was possible to deduce the location and orientation of the dihydrofolate reductase structural gene on the parent plasmid, pJFM8.