A novel form of RNA polymerase from Escherichia coli

Enzymology of DNA in replication in prokaryotes

This review stresses recent developments in the in vitro study of DNA replication in prokaryotes. New insights into the enzymological mechanisms of initiation and elongation of leading and lagging strand DNA synthesis in ongoing studies are emphasized. Data from newly developed systems, such as those replicating oriC containing DNA or which are dependent on the lambda, O, and P proteins, are presented and the information compared to existing mechanisms. Evidence bearing on the coupling of DNA synthesis on both parental strands through protein-protein interactions and on the turnover of the elongation systems are analyzed. The structure of replication origins, and how their tertiary structure affects recognition and interaction with the various replication proteins is discussed.

Replication of duplex DNA of phage phi X174 reconstituted with purified enzymes

Replication of the covalently closed duplex replicative form (RF) of phage phi X174 DNA has been achieved by coupling two known enzyme systems: (i) synthesis of viral strand circles (SS) from RF, and (ii) conversion of SS to nearly complete RF (RF II). In this coupled system, activated RF (gene A . RF II complex) was a more efficient template and generated as many as 10 RF II molecules per RF input, at a rate commensurate with SS synthesis. The 11 proteins required for the two component systems were all needed in the coupled RF duplication system; no new factors were required. Single-stranded DNA binding protein was needed for RF duplication at only 4% the level needed in its stoichiometric participation in SS synthesis. In addition to RF II, more complex replicative forms appeared late in the reaction, and their possible origin is discussed.

Analysis of in vitro replication of different DNAs

The conversion of single-stranded circular DNA to duplex DNA in vitro occurs by at least three different mechanisms. These differences reside in the manner of priming of these DNAs. In contrast, the elongation of primed DNA templates is a general reaction. A number of these proteins have been isolated and further characterized. In addition, cell-free preparations capable of supporting phi X RFI DNA replication as well as the synthesis of progeny viral phi X174 single-stranded circular DNA have been prepared.

Gene expression in Escherichia coli B/r during partial rifampicin-mediated restrictions of transcription initiation

The antibiotic rifampicin inhibits transcription initiation, but not the elongation and completion of nascent RNA transcripts. Addition of low concentrations of rifampicin only partially blocks initiation but at the same time specifically alters the general pattern of transcription in the culture. The transcription of genes specifying the beta and beta' subunits of RNA polymerase, and to a lesser extent of the genes specifying the RNA and protein components of the ribosome, was specifically stimulated relative to total transcription. In contrast, the transcription of the lactose operon was selectively reduced. These results are consistent with the ideas that the level of expression of the genes specifying the beta and beta' subunits is sensitive to the general rate of RNA synthesis in the culture, and that the expression of the beta and beta' RNA polymerase genes is related to the expression of ribosome component genes.

The firA gene, a locus involved in the expression of rifampicin resistance in Escherichia coli. I. Characterisation of lambdafirA transducing phages constructed in vitro

The firA200 mutation of E. coli not only renders RNA synthesis thermosensitive but also eliminates the high-level resistance to rifampicin associated with certain mutations in the beta subunit of the RNA polymerase. A priori, the firA gene is likely to code for an essential component of the transcription apparatus. The isolation is reported of transducing phages for the firA gene, constructed in vitro by fusing fragments of the E. coli chromosomes into a lambdoid bacteriophage. Such phages carry at least two essential genes and are able to suppress both the thermosensitivity and abnormal rifampicin sensitivity associated with the firA200 allele. The finding that some, but not all, of the lambdafirA phages have a temperature dependent growth defect is discussed.

Regulation of transcription factor rho and the alpha subunit of RNA polymerase in Escherichia coli B/r

Transcriptional termination factor rho, the alpha subunit of RNA polymerase (RNA nucleotidyltransferase nucleosidetriphosphate: RNA nucleotidyltransferase, EC 2.7.7.6), and ribosomal protein S6 were resolved from whole-cell extracts of E. coli B/r by a high-resolution, two-dimensional polyacrylamide gel electrophoretic technique, and were identified through coelectrophoresis with the purified proteins. The regulation of rho, alpha, and S6 was studied, in steady-state cultures of E. coli B/r growing at rates ranging from 0.6 to 2.1 generations per hr, through the use of this gel technique and a double radioisotope labeling procedure. The regulatory patterns of rho and alpha are distinct from, but similar to, one another. Neither rho nor alpha shows the sharply increasing levels with increasing growth rate shown by the ribosomal proteins was exemplified by S6. The difference between the levels of rho and alpha, on the one hand, and S6, on the other, is most pronounced during rapid growth. The regulatory pattern of alpha is interesting, given the recent suggestion that the gene coding for alpha is contranscribed with genes coding for ribosomal proteins.

Novel replicative properties of a capsid mutant of bacteriophage phi chi 174

A capsid mutant of bacteriophage phi chi 174 demonstrates altered requirements for the conversion of viral single-stranded DNA to double-stranded replicative form DNA. In the presence of puromycin at 42 C, wild-type phi chi 174 is unable to complete this replicative event, whereas phi chi ahb is able to do so. Furthermore, in contrast to wild-type phi chi 174, formation of phi chi ahb parental replicative form DNA is sensitive to rifampin under certain experimental conditions. These data suggest that the mutant capsid proteins of phi chi ahb influence the biosynthesis of phi chi ahb complementary strand DNA.

A bacterial RNA polymerase mutant that renders lambda growth independent of the N and cro functions at 42 degrees C

We describe a bacterial RNA polymerase mutation, rif 501, which confers rifampicin resistance and thermosensitivity to E. coli K 12. The purified RNA polymerase enzyme from rif 501 bacteria shows increased heatsensitivity in vitro at 51 degrees C. However, in vivo, at 42 degrees C the non-permissive temperature, mutant bacteria continue to grow and to synthesize RNA for 90 min. On a lawn of the mutant bacteria, at 40-41 degrees C, phage lambda forms clear plaques (LycA phenotype); this is probably due to an enhancement of cro function; we surmise that at 42 degrees C the transcription originating from the pR (but not from the pL) promoter on the lamdba genome becomes N-independent and less sensitive to the absence of the cro product. We discuss the possibility that both the N and cro proteins of phage lambda interact directly with the bacterial RNA polymerase. These observations indicate that the loss of viability of the rif 501 mutant at the restrictive temperature is not a consequence of an immediate inactivation of RNA polymerase; rather we feel it is due to a modification of the activity of RNA polymerase, leading to a disruption of the cellular regulation.

RNA polymerase mutants of Escherichia coli. III. A temperature-sensitive rifampicin-resistant mutant

Temperature-sensitive mutants of Escherichia coli that are unable to grow at high temperature can be obtained among those selected for resistance to streptovaricin or rifampicin at low temperature (Yura et al., 1973). One of these mutants (KY5323) that was supposed to carry a single mutation affecting both rifampicin resistance and temperature sensitivity was further investigated. Using purified RNA polymerase preparations obtained from the mutant and the wild type, it was found that the activity for RNA chain elongation is more sensitive to heat treatment than that for RNA chain initiation or DNA binding, and that the mutant enzyme is significantly more labile than the wild-type enzyme with respect to RNA chain elongation, when heat treatment is carried out at high salt concentration. These results, taken together with those of the enzyme reconstitution experiments, strongly suggest that the beta subunit of the polymerase is directly involved in both RNA chain initiation and elongation reactions. Enzyme reconstitution experiments using isolated subunits derived from the mutant and the wild-type polymerases demonstrate that the alteration of beta subunit is primarily responsible for both rifampicin resistance and thermolability of the mutant enzyme. In addition, the results suggested the apparent alteration of both beta and alpha subunits in this mutant. Extensive transduction experiments provided genetic evidence that are consistent with the view that the strain KY5323 carries a second mutation affecting the beta subunit, beside the primary mutation affecting the beta subunit. The hypothetical beta subunit mutation seems to modify quantitatively the rifampicin resistance caused by the beta subunit mutation.

Substrate-binding ability of Escherichia coli ribonucleic acid polymerase in relation to its protein composition

Interaction between Escherichia coli RNA polymerase and its substrates, the nucleoside triphosphates, was studied by gel-filtration and dialysis-rate-measurement techniques. 2. The holoenzyme bound variable amounts of ATP and GTP. There was no correlation between substrate-binding ability and enzyme activity of different enzyme preparations. 3. The core enzyme bound a maximum of 0.1 mol of ATP/mol of enzyme. The dissociation constant of this interaction was of the order of 1 X 10(-5)M. The core enzyme did not bind GTP. 4. A protein of mol.wt. 60000, which was eluted in the first fraction during phosphocellulose column chromatography of the holoenzyme, bound appreciable amounts of ATP. The dissociation constant of this interaction was of the order of 3 X 10(-5)-5 X 10(-6)M. 5. Evidence presented shows that this protein, and not the sigma factor, is responsible for the observed variation in the ATP-binding ability of the holoenzyme.

Rifampin inhibition of bacteriophage phiX174 parental replicative-form DNA synthesis in an Escherichia coli dnaC mutant

The Escherichia coli dnaC protein is not absolutely required in vivo for bacteriophage phiX174 parental replicative-form synthesis (Kranias and Dumas, 1974). However, when rifampin is present at a concentration that inhibits DNA-dependent RNA polymerase, phiX174 parental replicative-form synthesis is dependent on the dnaC protein activity. We conclude that E. coli DNA-dependent RNA polymerase can substitute for the dnaC protein in phiX174 parental replicative-form DNA synthesis, presumably in its initiation. The implications of this result with respect to the in vitro synthesis of the complementary strand of phiX174 DNA are discussed.

Replication of bacteriophage M13 IX. Requirement of the Escherichia coli dnaG function for M13 duplex DNA replication

Temperature-shift experiments with an Escherichia coli dnaG strain indicate a requirement for the dnaG function for M13 phage production only at an early stage of infection. Mutant cells infected at nonpermissive temperature form the parental RF (SS leads to RF) but do not replicate further. A shift to nonpermissive temperature after infection inhibits RF leads to RF replication but not RF leads to SS synthesis. The synthesis of both strands of the duplex RF was inhibited equally after a temperature shift during RF leads to RF replication. We infer that the dnaG protein is required for M13 production only during RF replication and that it is required for the synthesis of both strands of the RF.

Multienzyme systems of DNA replication

Replication is accomplished by multienzyme systems whose operations are usefully considered in respect to three stages of the process: initiation, elongation, anid termination. 1) Initiation entails synthesis of a short RNA fragment that serves as primer for the elongation step of DNA synthesis. This stage, probed by SS phage DNA templates, reveals three distinctive and highly specific systems in E. coli. The Ml3 DNA utilizes RNA polymerase in a manner that may reflect how plasmid elements are replicated in the cell. The ØX174 DNA does not rely on RNA-polymerase, but requires instead five distinctive proteins which may belong to an apparatus for initiating a host chromosome replication cycle at the origin. The G4 DNA, also independent of RNA polymerase, needs simply the dnaG protein for its distinctive initiation and may thus resemble the system that initiates the replication fragments at the nascent growing fork. In each case it is essential that in vitro the DNA-unwinding protein coat the viral DNA and influence its structure. 2) Elongation is achieved in every case by the multisubunit, holoenzyme form of DNA polymerase III. Copolymerase III, which is an enzyme subunit, and adenosine triphosphate are required to form a proper complex with the primer template but appear dispensable for the ensuing chain growth by DNA polymerase (33). 3) Termination requires excision of the RNA priming fragment, filling of gaps and sealing of interruptions to produce a covalently intact phosphodiester backbone. DNA polymerase I has the capacity for excision and gapfilling and DNA ligase is required for sealing. What once appeared to be a simple DNA polymerase-mediated conversion of a single-strand to a duplex circle (34) is now seen as a complex series of events in which diverse multienzyme systems function. Annoyance with the difficulties in resolving and reconstituting these systems is tempered by the conviction that these are the very systems used ,by the cell in replicating its chromosome and extrachromosomal elements. Thus, understanding of the regulation of replication events in the cell, their localization at membrane surfaces and integration with cell division, and their coordination with phage DNA maturation and particle assembly will all be advanced by knowledge of the components of the replicative machinery.