The dnaC protein of Escherichia coli. Purification, physical properties and interaction with dnaB protein.

E.coli dnaC protein was purified to near-homogeneity in using a dnaC complementation assay [S.Wickner, I.Berkower, M.Wright, and J.Hurwitz (1973) Proc. Natl. Acad. Sci. USA 70, 2369-2373]. Purification was achieved by taking advantage of the hydrophobic interaction of dnaC protein with aliphatic and aromatic matrixes and with Brij58 as stabilizing agent. A sedimentation coefficient for the dnaC protein of 2.6 S corresponding to a molecular weight of approximately 26,000 was estimated from glycerol gradient centrifugation. A polypeptide molecular weight of 28,000 was determined by densitometry on a denaturing gel. In the presence of ATP the dnaC protein forms a complex with dnaB protein [S.Wickner and J.Hurwitz (1975) Proc.Natl.Acad.Sci. USA 72, 921-925]. For the dnaB . dnaC complex a sedimentation coefficient of 14.5 S was measured by glycerol gradient centrifugation, indicating a molecular weight of about 400,000. The ratio of the dnaC and dnaB polypeptides in the complex is approximately 1, as determined on a denaturing gel. It is suggested that the complex consists of the dnaB protein hexamer and six dnaC polypeptides amounting to a calculated molecular weight of about 450,000.     

Replication of bacteriophage phiK duplex replicative-form DNA in dnaB and dnaC mutants of Escherichia coli.

We have directly tested the effects of host cell DNA synthesis mutations on bacteriophage phiK replicative-form (RF) DNA replication in vivo. We observed that phiK RF DNA replication continued at normal rates in both dnaB and dnaC mutant hosts under conditions in which the activities of the dnaB and dnaC gene products were shown to be markedly reduced. This suggests that these two host proteins are not essential for normal phiK RF DNA replication. In control experiments we observed markedly reduced rates of phiK RF DNA replication in temperature-sensitive dnaG and dnaE host mutants, indicating that the products of these genes are essential. Thus, the mechanism of DNA chain initiation in vivo on the duplex RF DNA templates of isometric phages such as phiK apparently is different from that on the similar templates of isometric phages such as phiX174. The implications of this difference are discussed in the text.     

The dnaB protein of Escherichia coli: mechanism of nucleotide binding, hydrolysis, and modulation by dnaC protein

The mechanism of nucleotide binding and hydrolysis by dnaB protein and dnaB X dnaC protein complex has been studied by using fluorescent nucleotide analogues. Binding of trinitrophenyladenosine triphosphate (TNP-ATP) or the corresponding diphosphate (TNP-ADP) results in a blue shift of the emission maximum and a severalfold amplification of the fluorescence emission of the nucleotide analogues. Scatchard analysis of TNP-ATP binding indicates that TNP-ATP binds with a high affinity (Kd = 0.87 microM) and a 8.5-fold enhancement of fluorescence emission of the nucleotide. Only three molecules of TNP-ATP or TNP-ADP bind per hexamer of dnaB protein in contrast to six molecules of ATP or ADP binding to a dnaB hexamer. TNP-ATP and TNP-ADP are both competitive inhibitors of single-stranded (SS) DNA-dependent ATPase activity of dnaB protein. TNP-AMP neither binds to dnaB protein nor inhibits the ATPase activity. Formation of dnaB X dnaC complex by dnaC protein results in diminution of the TNP-ATP fluorescence enhancement and a concomitant decrease in the SS DNA-dependent ATPase activity. Kinetic analysis of the ATPase activity of dnaB X dnaC complex indicates that the decrease in the ATPase activity on complex formation is due to a reduction of the maximal velocity (Vmax). The dnaB protein hydrolyzes both TNP-ATP and dATP, however, with an extremely slow rate in the presence of single-stranded M13 DNA. The 2'-OH group of the nucleotide most likely plays an important role in the hydrolysis reaction but not in the nucleotide binding.     

Identification of a cysteine residue at the active site of Escherichia coli isocitrate lyase.

Escherichia coli isocitrate lyase was inactivated by iodacetate in a pseudo-first-order process. Complete inactivation was associated with the incorporation of only one carboxymethyl group per enzyme subunit. The substrate and products of the enzyme protected against inactivation, suggesting that the reactive group may be located at the active site. Isolation and sequencing of a carboxymethylated peptide showed that the modified residue was a cysteine, in the sequence Cys-Gly-His-Met-Gly-Gly-Lys. The reactivity of isocitrate lyase to iodoacetate declined with pH, following a titration curve for a group of pKa 7.1. The Km of the enzyme for isocritrate declined over the same pH range.     

Identification of a major facilitator protein from Escherichia coli involved in efflux of metabolites of the cysteine pathway

A chromosomal fragment has been identified in a gene bank from Escherichia coli, which augmented the yield of cysteine in an industrial production strain. Subcloning and genetic analysis showed that an open reading frame coding for a product of 299 amino acids (Orf299) was responsible. Orf299 was synthesized in the T7 polymerase/promoter system and exhibited the properties of an integral membrane protein. Mutational interruption of orf299 did not cause a distinct phenotype; however, transformants overexpressing orf299 had lost the ability to grow in minimal medium unless it was supplemented with a source of reduced sulphur compounds, and they excreted considerable amounts of cysteine and O-acetyl-L-serine, especially in the presence of thiosulphate. Most of the cysteine was found to be masked in 2-methyl-2,4-thiazolidinedicarboxylic acid. N-acetyl-L-serine was also present in the medium, but it is open to question whether it represents a primary excretion product. Measurement of the induction status of the cysteine regulon by means of a cysK'-'lacZ gene fusion demonstrated that the regulon is not induced upon growth in the presence of a poor sulphur source and that the introduction of a constitutive cysB allele alleviates this deficiency. The results indicate that orf299 codes for an export pump for different metabolites of the cysteine pathway. Its relation to other efflux systems and the physiological role are discussed.     

Regulation of dnaB function in DNA replication in Escherichia coli by dnaC and lambda P gene products

The dnaB protein of Escherichia coli, a multifunctional DNA-dependent ribonucleotide triphosphatase and dATPase, cross-links to ATP on ultraviolet irradiation under conditions that support rNTPase and dATPase activities of dnaB protein. The covalent cross-linking to ATP is specifically inhibited by ribonucleotides and dATP. Tryptic peptide mapping demonstrates that ATP cross-links to only the 33-kDa tryptic fragment (Fragment II) of dnaB protein. The presence of single-stranded DNA alters the covalent labeling of dnaB protein by ATP, suggesting a possible role of DNA on the mode of nucleotide binding by dnaB protein. Present studies demonstrate that the dnaC gene product binds ribonucleotides independent of dnaB protein. On dnaB-dnaC protein complex formation, covalent incorporation of ATP to dnaB protein decreases approximately 70% with a concomitant increase of ATP incorporation to dnaC protein by approximately 3-fold. The mechanism of this phenomenon has been analyzed in detail by titrating dnaB protein with increasing amounts of dnaC protein. The binding of dnaC protein to dnaB protein appears to be a noncooperative process. The lambda P protein, which interacts with dnaB protein in the bacteriophage lambda DNA replication, does not bind ATP in the presence or absence of dnaB protein. However, lambda P protein enhances the covalent incorporation of ATP to dnaB protein approximately 4-fold, suggesting a direct physical interaction between lambda P and dnaB proteins with a probable change in the modes of nucleotide binding to dnaB protein. The lambda P protein likely forms a lambda P-dnaB-ATP dead-end ternary complex. The implications of these results in the E. coli and bacteriophage lambda chromosomal DNA replication are discussed.     

Replication of small plasmids in extracts of Escherichia coli: involvement of the dnaB and dnaC protein in the replication of early replicative intermediates.

Summary The role of E. coli dnaB and dnaC protein in the replication of plasmid ColE1 and RSF1030 DNA was investigated in a soluble in vitro system (Staudenbauer, 1976a). Extracts from dnaB and dnaC mutants which are phenotypically DNA initiationor DNA elongation-defective were examined for their replicative capacity. It was found that all mutants tested are deficient in the synthesis of supercoiled plasmid DNA. Deficient extracts of dnaB mutants could be partially complemented by purified dnaB wild type protein but required for full complementation dnaC wild type protein as well. The dnaB wild type protein could be replaced by a P1dnaB analog (ban) protein complexed with a dnaB ts protein. Deficient extracts of dnaC mutants were complemented by purified dnaC wild type protein alone.The in vitro plasmid replication cycle had been separated into an early and late stage (Staudenbauer, 1977). Analysis by CsCl velocity centrifugation of the plasmid DNA synthesized in mutant extracts indicates that the early stage, namely the synthesis of early replicative intermediates, proceeds in all dnaB and dnaC mutants tested. However, replication of the early intermediates during the late stage depends on both the dnaB and dnaC protein. These conclusions were confirmed using inhibitors of DNA synthesis.     

The Escherichia coli dnaB replication protein is a DNA helicase

Genetic and biochemical analyses indicate that the Escherichia coli dnaB replication protein functions in the propagation of replication forks in the bacterial chromosome. We have found that the dnaB protein is a DNA helicase that is capable of unwinding extensive stretches of double-stranded DNA. We constructed a partially duplex DNA substrate, containing two preformed forks of single-stranded DNA, which was used to characterize this helicase activity. The dnaB helicase depends on the presence of a hydrolyzable ribonucleoside triphosphate, is maximally stimulated by a combination of E. coli single-stranded DNA-binding protein and E. coli primase, is inhibited by antibody directed against dnaB protein, and is inhibited by prior coating of the single-stranded regions of the helicase substrate with the E. coli single-stranded DNA-binding protein. It was determined that the dnaB protein moves 5' to 3' along single-stranded DNA, apparently in a processive fashion. To invade the duplex portion of the helicase substrate, the dnaB protein requires a 3'-terminal extension of single-stranded DNA in the strand to which it is not bound. Under optimal conditions at 30 degrees C, greater than 1 kilobase pair of duplex DNA can be unwound within 30 s. Based on these findings and other available data, we propose that the dnaB protein is the primary replicative helicase of E. coli and that it actively and processively migrates along the lagging strand template, serving both to unwind the DNA duplex in advance of the leading strand and to potentiate synthesis by the bacterial primase of RNA primers for the nascent (Okazaki) fragments of the lagging strand.     

Escherichia coli dnaB protein. Affinity chromatography on immobilized nucleotides.

The purification of the Escherichia coli dnaB protein by affinity chromatography on nucleotides bound to agarose is described. The dnaB protein, which contains an associated ribonucleoside triphosphatase activity (Wickner, S., Wright, M., and Hurwitz, J. (1974) Proc. Natl. Acad. Sci. U. S. A. 71, 783-787) binds to immobilized ATP, ADP, and UDP, but not to AMP. The type of linkage of ATP to agarose influences the adsorption, elution, and purification of the enzyme. Optimal purification is achieved using ATP bound to agarose via its oxidized ribose moiety. By this means, the dnaB protein can be obtained at least 95% electrophoretically pure after only three purification steps. The enzyme can be eluted from immobilized nucleoside-5'-di- and -triphosphates by ATP, ADP, and pyrophosphate, but not by AMP or orthophosphate. ADP and pyrophosphate, as well as the substrate ATP in high concentration are at the same time inhibitors of the ribonucleoside triphosphatase. The dnaB complementing and ribonucleoside triphosphatase activities could not be separated from each other by affinity chromatography, supporting the finding of others that they both reside on the same protein complex, namely a dnaB multimer. The results indicate that the dnaB protein binds to immobilized nucleotides by means of its ribonucleoside triphosphatase, and that at least the pyrophosphate moiety is essential for adsorption as well as elution of the enzyme.     

Mechanism of dnaB protein action. I. Crystallization and properties of dnaB protein, an essential replication protein in Escherichia coli

Purification and crystallization of dnaB protein from Escherichia coli was performed on a large scale by a simple procedure. From 1.5 kg of cells, 520 mg of dnaB protein were obtained in a 58% yield with a purity greater than 99%. The E. coli cells harbor a high copy-number plasmid carrying the dnaB gene and overproduce the enzyme over 200-fold. The subunit molecular weight determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis is 50,000. Based on a native Mr = 290,000 and cross-linking studies that yielded six bands, dnaB protein is judged to be a hexamer, confirming the results of Reha-Krantz, L. J., and Hurwitz, J. (1978) J. Biol. Chem. 253, 4043-4050.     

Thymineless death in Escherichia coli dnaB mutants and in a dnaB dnaG double mutant.

The interference of dnaB mutations of Escherichia coli with thymineless death is described. All the isogenic Thy- dnaB mutants of E. coli we have tested show a remarkable immunity towards cell death induced by thymine deprivation at the nonpermissive temperature. We have also constructed and tested an isogenic double dnaB dnaG mutant. It loses its viability in the absence of thymine at both permissive and nonpermissive temperatures. The role of the dnaB gene product is discussed.     

L-threonine dehydrogenase from Escherichia coli. Identification of an active site cysteine residue and metal ion studies

Pure L-threonine dehydrogenase from Escherichia coli is a tetrameric protein (Mr = 148,000) with 6 half-cystine residues/subunit; its catalytic activity as isolated is stimulated 5-10-fold by added Mn2+ or Cd2+. The peptide containing the 1 cysteine/subunit which reacts selectively with iodoacetate, causing complete loss of enzymatic activity, has been isolated and sequenced; this cysteine residue occupies position 38. Neutron activation and atomic absorption analyses of threonine dehydrogenase as isolated in homogeneous form now show that it contains 1 mol of Zn2+/mol of enzyme subunit. Removal of the Zn2+ with 1,10-phenanthroline demonstrates a good correlation between the remaining enzymatic activity and the zinc content. Complete removal of the Zn2+ yields an unstable protein, but the native metal ion can be exchanged by either 65Zn2+, Co2+, or Cd2+ with no change in specific catalytic activity. Mn2+ added to and incubated with the native enzyme, the 65Zn2(+)-, the Co2(+)-, or the Cd2(+)- substituted form of the enzyme stimulates dehydrogenase activity to the same extent. These studies along with previously observed structural homologies further establish threonine dehydrogenase of E. coli as a member of the zinc-containing long chain alcohol/polyol dehydrogenases; it is unique among these enzymes in that its activity is stimulated by Mn2+ or Cd2+.     

Stabilization by ATP and ADP of Escherichia coli dnaB protein activity

The effect of adenine ribonucleotides on the stability of Escherichia coli dnaB protein in cellular crude extracts was studied. Stabilization of dnaB protein by ATP or ADP, but not by AMP, was manifested in that (i) the activity and yield of wild type dnaB protein is enhanced in the presence of ATP, (ii) the dnaB protein of E. coli dnaB mutants, such as groPB and dnaB252/ColE1::dnaC+, which is inactive in a dnaB complementation assay, can be isolated in active form in the presence of ATP or aDP, (iii) ATP or ADP protect the dnaB protein of an E. coli dnaBts mutant from inactivation at 37 degrees C, and (iv) inactive groPB and dnaBts protein can be reactivated partially by ATP. Thus, the stabilizing effect of ATP and ADP can be exploited for the isolated of otherwise inactive or labile mutant dnaB proteins.     

Re-examination of F plasmid replication in a dnaC mutant of Escherichia coli.

Summary The replication of an F plasmid in a dnaC mutant, thermolabile for initiation of chromosomal replication, has been re-examined using a novel DNA-DNA annealing assay. Plasmid replication ceases rapidly at non-permissive conditions, consistent with a direct role for the dnaC product in the replication of F.     

Identification of five new essential genes involved in the synthesis of a secreted protein in Escherichia coli.

To define additional components of the export machinery of Escherichia coli, I have isolated extragenic suppressors of a mutant [secA(Ts)] that is temperature sensitive for growth and secretion at 37 degrees C. Suppressors that restored growth at 37 degrees C, but that rendered the cell cold sensitive for growth at 28 degrees C, were obtained. The suppressor mutations fall into at least seven loci, two of which (prlA and secC) have been previously implicated in protein secretion. The five remaining loci (ssaD, ssaE, ssaF, ssaG, and ssaH) have been mapped by P1 transduction and appear to define new genes in E. coli. All of the suppressor mutations allow both enhanced growth and protein secretion of the secA(Ts) mutant at 37 degrees C, but not 42 degrees C, indicating a continued requirement for SecA protein. Strains carrying solely the cold-sensitive mutations show reduced levels of certain periplasmic proteins when grown at low temperatures. In at least one case, that of maltose-binding protein, this defect is at the level of synthesis of the protein. Since mutants in any of seven genes as well as secA amber mutants halt or reduce the synthesis of an exported protein, it appears that E. coli may possess a general and complex mechanism for coupling protein synthesis and secretion.