The defective proton-ATPase of uncD mutants of Escherichia coli. Identification by DNA sequencing of residues in the beta-subunit which are essential for catalysis or normal assembly

Six mutant uncD alleles, affecting essential residues of the beta-subunit of Escherichia coli proton-ATPase, have been identified by intragenic complementation mapping, cloning, and DNA sequencing. Five of the mutations impair catalysis but do not cause structural perturbation of F1-ATPase. The amino acid substitutions found were as follows: uncD412, Gly-142----Ser; uncD430 and uncD431, both Arg-246----Cys; uncD478, Ser-174----Phe; and uncD484, Met-209----Ile. Kinetic characteristics of each corresponding mutant F1-ATPase are described or reviewed. In each case, the major determinant of impaired catalysis appears to be an attenuation of positive catalytic site cooperativity. Additionally, each mutation affects intrinsic properties of the catalytic site, including affinity for ATP, the ratio between unisite-bound substrate and products, and the rate of release of product inorganic phosphate under unisite ATP hydrolysis conditions. These effects are discussed in terms of a structural model of the catalytic nucleotide-binding domain of beta-subunit proposed recently (Duncan, T.M., Parsonage, D., and Senior, A.E. (1986) FEBS Lett. 208, 1-6). Each of the mutations lies within that domain. The uncD409 allele abolishes normal assembly of F1-ATPase. The amino acid substitution is Gly-214----Arg, which is suggested to affect a beta-turn connecting a beta-strand and an alpha-helix in the predicted nucleotide-binding domain of the beta-subunit.     

The defective proton-ATPase of uncA mutants of Escherichia coli: ATP-binding and ATP-induced conformational change in mutant alpha-subunits

Mutations in the uncA gene of Escherichia coli cause loss of both oxidative phosphorylation and ATP-driven generation of the transmembrane proton gradient. The uncA gene encodes the alpha-subunit of the F1-sector of the E. coli membrane proton-ATPase. F1-alpha-subunit from normal (unc+) E. coli binds ATP tightly (KD = 0.1 microM) and undergoes a large ATP-induced conformational change, but the functional role of the ATP-binding site is currently unknown. There is disagreement in the literature as to whether the ATP-binding site is present or lacking in F1-alpha-subunit from uncA mutant strains. One obstacle in studying this question is the difficulty of purifying mutant alpha-subunits in native form. In order to circumvent this difficulty we have studied ATP binding and ATP-induced conformational changes in mixtures of F1 subunits obtained by dissociating uncA mutant F1. Anti-alpha antibody was used in conjunction with immunoblotting to identify the alpha-subunits in the mixtures. Retention of native conformation by the alpha-subunits was demonstrated by the fact that the dissociated alpha-subunits were fully competent to repolymerize with other F1 subunits to yield intact F1 aggregate. The results show that, contrary to previous reports, alpha-subunits from three catalytically defective uncA mutants do indeed bind ATP and do undergo an ATP-induced conformational change. The binding affinity of alpha-subunit for ATP was lower than normal in each of the three mutants, but this is not likely to be a significant factor under physiological conditions.     

The defective proton-ATPase of uncD mutants of Escherichia coli. Two mutations which affect the catalytic mechanism

The catalytic characteristics of F1-ATPases from uncD412 and uncD484 mutant strains of Escherichia coli were studied in order to understand how these beta-subunit mutations cause defective catalysis. Both mutant enzymes showed reduced affinity for ATP at the first catalytic site. While uncD412 F1 was similar to normal in other aspects of single site catalysis, uncD484 F1 showed a Keq of bound reactants greatly biased toward bound substrate ATP and an abnormally fast rate of Pi release. Impairment of productive catalytic cooperativity was the major cause of the reduced steady state ("multisite") catalytic rate in both mutant enzymes. Addition of excess ATP to saturate second and/or third catalytic sites did promote ATP hydrolysis and product release at the first catalytic site of uncD412 F1, but the multisite turnover rate was significantly slower than normal. In contrast, with uncD484 F1, addition of excess ATP induced rapid release of ATP from the first catalytic site and so productive catalytic cooperativity was almost completely absent. The results show that both mutations affect properties of the catalytic site and catalytic site cooperativity and further that the relatively more severe uncD484 mutation affects a residue which acts as a determinant of the fate of bound substrate ATP during promotion of catalysis. Taken together with previous studies of uncA mutant F1-ATPases (Wise, J. G., Latchney, L. R., Ferguson, A. M., and Senior, A. E. (1984) Biochemistry 23, 1426-1432) the results indicate that catalytic site cooperativity in F1-ATPases involves concerted beta-alpha-beta intersubunit communication between catalytic sites on the beta-subunits.     

The uncA gene codes for the alpha-subunit of the adenosine triphosphatase of Escherichia coli. Electrophoretic analysis of uncA mutant strains.

Four mutant strains of Escherichia coli which lack membrane-bound adenosine triphosphatase activity were shown by genetic-complementation tests to carry mutations in the uncA gene. A soluble inactive F1-ATPase aggregate was released from the membranes of three of the uncA mutant strains by low-ionic-strength washing, and purified by procedures developed for the purification of F1-ATPase from normal strains. Analysis of the subunit structure by two-dimensional gel electrophoresis indicated that the F1-ATPase in strains carrying the uncA401 or uncA453 alleles had a subunit structure indistinguishable from normal F1-ATPase. In contrast, the F1-ATPase from the strain carrying the uncA447 allele contained an alpha-subunit of normal molecular weight, but abnormal net charge. Membranes from strains carrying the uncA450 allele did not have F1-ATPase aggregates that could be solubilized by low-ionic-strength washing. However, a partial dipolid strain carrying both the uncA+ and uncA450 alleles formed an active F1-ATPase aggregate which could be solubilized by low-ionic-strength washing of the membranes and which contained two types of alpha-subunit, one of which was normal and the other had abnormal net charge. It is concluded that the uncA gene codes for the alpha-subunit of the adenosine triphosphatase.     

Identification of catalytically essential residues in Escherichia coli esterase by site-directed mutagenesis.

Escherichia coli esterase (EcE) is a member of the hormone-sensitive lipase family. We have analyzed the roles of the conserved residues in this enzyme (His103, Glu128, Gly163, Asp164, Ser165, Gly167, Asp262, Asp266 and His292) by site-directed mutagenesis. Among them, Gly163, Asp164, Ser165, and Gly167 are the components of a G-D/E-S-A-G motif. We showed that Ser165, Asp262, and His292 are the active-site residues of the enzyme. We also showed that none of the other residues, except for Asp164, is critical for the enzymatic activity. The mutation of Asp164 to Ala dramatically reduced the catalytic efficiency of the enzyme by the factor of 10(4) without seriously affecting the substrate binding. This residue is probably structurally important to make the conformation of the active-site functional.     

Escherichia coli mutants defective in the uncH gene.

Plasmids carrying cloned segments of the unc operon of Escherichia coli have been used in genetic complementation analyses to identify three independent mutants defective in the uncH gene, which codes for the delta subunit of the ATP synthetase. Mutations in other unc genes have also been mapped by this technique. ATPase activity was present in extracts of the uncH mutants, but the enzyme was not as tightly bound to the membrane as it was in the parental strain. ATP-dependent membrane energization was absent in membranes isolated from the uncH mutants and could not be restored by adding normal F1 ATPase from the wild-type strain. F1 ATPase prepared from uncH mutants could not restore ATP-dependent membrane energization when added to wild-type membranes depleted of F1. Membranes of the uncH mutants were not rendered proton permeable as a result of washing with low-ionic-strength buffer.     

Identification and characterization of gyrB mutants of Escherichia coli that are defective in partitioning of mini-F plasmids.

hopA mutants, which have been suggested to be defective in mini-F plasmid partitioning (H. Niki, C. Ichinose, T. Ogura, H. Mori, M. Morita, M. Hasegawa, N. Kusukawa, and S. Hiraga, J. Bacteriol. 170:5272-5278, 1988), were found to carry mutations in the gyrB gene, coding for the B subunit of DNA gyrase. In gyrB(HopA) mutants, relaxation of the superhelicity of plasmids, increased IncG incompatibility, and increased SopB protein production were observed. It is suggested that altered expression of the sop genes, which is due to relaxation of the mini-F plasmid DNA, causes both defective partitioning of the mini-F plasmids and increased IncG incompatibility in gyrB(HopA) mutants.     

Mutations in alpha-subunit of Escherichia coli F1-ATPase obtained by hydroxylamine-mutagenesis of plasmids carrying the uncA gene

In order to generate mutants randomly in the Escherichia coli uncA gene (encoding the alpha-subunit of F1-ATPase), plasmids carrying uncA were treated in vitro with hydroxylamine. Restriction fragments of the mutated uncA gene were then reconstructed into plasmid pDP34, which expresses all of the F1F0 structural genes, and the reconstructed mutant plasmids were expressed in a strain carrying a deletion of chromosomal uncA. Each of the mutations was characterized by DNA sequencing, growth assays, and biochemical assays of membrane preparations. Three nonsense and one frameshift mutation were identified and their properties were studied briefly. Eight new missense mutations were identified and characterization of their properties is described. These eight mutations were R139H, A177V, R210C, R303C, A306V, T343I, G351S, and P370L.     

Molecular cloning, DNA sequencing, and enzymatic analyses of two Escherichia coli pyruvate oxidase mutants defective in activation by lipids.

Two Escherichia coli pyruvate oxidase (EC 1.2.2.2) mutant genes, poxB3 and poxB4, were cloned on plasmid pBR322. The poxB3 mutant oxidase which was described previously (Y. Y. Chang and J. E. Cronan, Jr., Proc. Natl. Acad. Sci. USA 81:4348-4352, 1984) was deficient in lipid activation but retained full catalytic activity. The poxB3 mutation was located in the C-terminal half of the gene, and the nucleotide alteration has been determined by DNA sequencing of this part of the gene and by comparing the sequence with that of the wild-type strain (C. Grabau and J. E. Cronan, Jr., submitted for publication). The poxB3 oxidase mutation is the substitution of a serine residue for Pro-536. poxB4, another pyruvate oxidase mutant gene, was also deficient in lipid activation. The major difference between the poxB3 and poxB4 oxidase was in the binding of Triton detergents. The poxB4 mutation was also located in the C-terminal half of the gene, and sequence analysis has shown that only one nucleotide base was altered, which resulted in Ala-467 being converted to a threonine residue. The results of the amino acid substitutions in the mutant proteins, leading to the functional alteration of the enzyme, are discussed.     

Conserved and nonconserved residues in the substrate binding site of 7,8-diaminopelargonic acid synthase from Escherichia coli are essential for catalysis

The vitamin B(6)-dependent enzyme 7,8-diaminopelargonic acid (DAPA) synthase catalyzes the antepenultimate step in the synthesis of biotin, the transfer of the alpha-amino group of S-adenosyl-l-methionine (SAM) to 7-keto-8-aminopelargonic acid (KAPA) to form DAPA. The Y17F, Y144F, and D147N mutations in the active site were constructed independently. The k(max)/K(m)(app) values for the half-reaction with DAPA of the Y17F and Y144F mutants are reduced by 1300- and 2900-fold, respectively, compared to the WT enzyme. Crystallographic analyses of these mutants do not show significant changes in the structure of the active site. The kinetic deficiencies, together with a structural model of the enzyme-PLP/DAPA Michaelis complex, point to a role of these two residues in recognition of the DAPA/KAPA substrates and in catalysis. The k(max)/K(m)(app) values for the half-reaction with SAM are similar to that of the WT enzyme, showing that the two tyrosine residues are not involved in this half-reaction. Mutations of the conserved Arg253 uniquely affect the SAM kinetics, thus establishing this position as part of the SAM binding site. The D147N mutant is catalytically inactive in both half-reactions. The structure of this mutant exhibits significant changes in the active site, indicating that this residue plays an important structural role. Of the four residues examined, only Tyr144 and Arg253 are strictly conserved in the available amino acid sequences of DAPA synthases. This enzyme thus provides an illustrative example that active site residues essential for catalysis are not necessarily conserved, i.e., that during evolution alternative solutions for efficient catalysis by the same enzyme arose. Decarboxylated SAM [S-adenosyl-(5')-3-methylthiopropylamine] reacts nearly as well as SAM and cannot be eliminated as a putative in vivo amino donor.     

Blue ghosts: a new method for isolating amber mutants defective in essential genes of Escherichia coli.

We describe a technique which permits an easy screening for amber mutants defective in essential genes of Escherichia coli. Using this approach, we have isolated three amber mutants defective in the rho gene. An extension of the technique allows the detection of ochre mutants and transposon insertions in essential genes.     

ATPase-deficient mutants of the Escherichia coli DNA replication protein PriA are capable of catalyzing the assembly of active primosomes.

The PriA replication protein of Escherichia coli (formerly replication factor Y or protein n') is multifunctional. It is a site-specific, single-stranded DNA-dependent ATPase (dATPase), a 3'----5' DNA helicase, and guides the ordered assembly of the primosome, a mobile, multiprotein DNA replication priming/helicase complex. Although PriA is not absolutely required for viability, priA null mutant cells grow very slowly, have poor viability, and form extensive filaments. In order to assess which of the multiple activities of PriA are required for normal replication and growth, site-directed mutagenesis was employed to introduce single amino acid substitutions for the invariant lysine within the consensus nucleotide-binding motif found in PriA. Biochemical characterization of the representative purified mutant PriA proteins revealed them to be completely deficient in nucleotide hydrolysis, incapable of translocation along a single-stranded DNA binding protein-coated single-stranded DNA template, and unable to manifest the 3'----5' DNA helicase activity of wild-type PriA. These mutant proteins were, however, capable of catalyzing the assembly of active primosomes in vitro. Furthermore, when supplied in trans to insertionally inactivated priA cells, plasmids containing a copy of these mutant priA genes restored the wild-type growth rate, viability, and cell morphology. Based on these results, a model for PriA function in vivo is discussed.     

Isolation of Escherichia coli mutants defective in uptake of molybdate.

For the study of molybdenum uptake by Escherichia coli, we generated Tn5lac transposition mutants, which were screened for the pleiotropic loss of molybdoenzyme activities. Three mutants A1, A4, and M22 were finally selected for further analysis. Even in the presence of 100 microM molybdate in the growth medium, no active nitrate reductase, formate dehydrogenase, and trimethylamine-N-oxide reductase were detected in these mutants, indicating that the intracellular supply of molybdenum was not sufficient. This was also supported by the observation that introduction of plasmid pWK225 carrying the complete nif regulon of Klebsiella pneumoniae did not lead to a functional expression of nitrogenase. Finally, molybdenum determination by induced coupled plasma mass spectroscopy confirmed a significant reduction of cell-bound molybdenum in the mutants compared with that in wild-type E. coli, even at high molybdate concentrations in the medium. A genomic library established with the plasmid mini-F-derived cop(ts) vector pJE258 allowed the isolation of cosmid pBK229 complementing the molybdate uptake deficiency of the chlD mutant and the Tn5lac-induced mutants. Certain subfragments of pBK229 which do not contain the chlD gene are still able to complement the Tn5lac mutants. Mapping experiments showed that the Tn5lac insertions did not occur within the chromosomal region present in pBK229 but did occur very close to that region. We assume that the Tn5lac insertions have a polar effect, thus preventing the expression of transport genes, or that a positively acting regulatory element was inactivated.     

Function of RNase H in DNA replication revealed by RNase H defective mutants of Escherichia coli

Summary Escherichia coli rnh mutants were isolated using localized mutagenesis and selective measurements of RNase H activity in mutagenized cell extracts with [³H]poly(rC)·poly(dG) as substrate. RNase H activity in extracts of one mutant, ON152 (rnh-91), was undetectable (less than 0.05% of that of wild-type cells). This mutant formed small colonies at 43 °C. At this temperature, accumulation of nascent fragments was more prominent in the rnh-91·polA4113 double mutant than in the polA4113 mutant; however, no accumulation was found in the rnh single mutant at 43° C. Unlike the 1–3 nucleotide primer RNA found on nascent fragments of polA4113 cells, primers from the rnh-91·polA4113 cells ranged from one to about ten bases. These results suggest that the 53 exonuclease activity of DNA polymerase I plays a major role in removal of primer RNA and that RNase H functions in an auxiliary role, excising the 5-portion of longer primers.The rnh mutant supports replication of ColE1-type plasmids. A possible mechanism of replication of such plasmids in rnh mutants and a role of RNase H in the initiation of chromosomal replication are discussed.     

Identification of histidyl and cysteinyl residues essential for catalysis by 5'-nucleotidase

Inactivation of both cytosolic 5'-nucleotidase and ecto-5'-nucleotidase by diethylpyrocarbonate indicated the presence of an essential histidyl residue which in the cytosolic enzyme was conclusively located at the active site. Inactivation by thiol reagents indicated the presence of an essential cysteinyl residue in both enzymes. The data suggest that both 5'-nucleotidases belong to a group of histidine phosphatases which also includes glucose-6-phosphatase and acid phosphatase. A working hypothesis for the catalytic mechanism of these enzymes is proposed.