Prereplicative complexes of components of DNA polymerase III holoenzyme of Escherichia coli

RNA polymerase and the ribosome: the close relationship

In bacteria transcription and translation are linked in time and space. When coupled to RNA polymerase (RNAP), the translating ribosome ensures transcriptional processivity by preventing RNAP backtracking. Recent advances in the field have characterized important linker proteins that bridge the gap between transcription and translation: In particular, the NusE(S10):NusG complex and the NusG homolog, RfaH. The direct link between the moving ribosome and RNAP provides a basis for maintaining genomic integrity while enabling efficient transcription and timely translation of various genes within the bacterial cell.

Selective inhibition of DNA replicase assembly by a non-natural nucleotide: exploiting the structural diversity of ATP-binding sites

DNA synthesis is catalyzed by an ensemble of proteins designated the replicase. The efficient assembly of this multiprotein complex is essential for the continuity of DNA replication and is mediated by clamp-loading accessory proteins that use ATP binding and hydrolysis to coordinate these events. As a consequence, the ability to selectively inhibit the activity of these accessory proteins provides a rational approach to regulate DNA synthesis. Toward this goal, we tested the ability of several non-natural nucleotides to inhibit ATP-dependent enzymes associated with DNA replicase assembly. Kinetic and biophysical studies identified 5-nitro-indolyl-2'-deoxyribose-5'-triphosphate as a unique non-natural nucleotide capable of selectively inhibiting the bacteriophage T4 clamp loader versus the homologous enzyme from Escherichia coli. Modeling studies highlight the structural diversity between the ATP-binding site of each enzyme and provide a mechanism accounting for the differences in potencies for various substituted indolyl-2'-deoxyribose-5'-triphosphates. An in vivo assay measuring plaque formation demonstrates the efficacy and selectivity of 5-nitro-indolyl-2'-deoxyribose as a cytostatic agent against T4 bacteriophage while leaving viability of the E. coli host unaffected. This strategy provides a novel approach to develop agents that selectively inhibit ATP-dependent enzymes that are required for efficient DNA replication.

Motion of a DNA sliding clamp observed by single molecule fluorescence spectroscopy

DNA sliding clamps attach to polymerases and slide along DNA to allow rapid, processive replication of DNA. These clamps contain many positively charged residues that could curtail the sliding due to attractive interactions with the negatively charged DNA. By single-molecule spectroscopy we have observed a fluorescently labeled sliding clamp (polymerase III beta subunit or beta clamp) loaded onto freely diffusing, single-stranded M13 circular DNA annealed with fluorescently labeled DNA oligomers of up to 90 bases. We find that the diffusion constant for the beta clamp diffusing along DNA is on the order of 10(-14) m(2)/s, at least 3 orders of magnitude less than that for diffusion through water alone. We also find evidence that the beta clamp remains at the 3' end in the presence of Escherichia coli single-stranded-binding protein. These results may imply that the clamp not only acts to hold the polymerase on the DNA but also prevents excessive drifting along the DNA.

Escherichia coli DNA polymerase III tau- and gamma-subunit conserved residues required for activity in vivo and in vitro

The Escherichia coli DNA polymerase III tau and gamma subunits are single-strand DNA-dependent ATPases (the latter requires the delta and delta' subunits for significant ATPase activity) involved in loading processivity clamp beta. They are homologous to clamp-loading proteins of many organisms from phages to humans. Alignment of 27 prokaryotic tau/gamma homologs and 1 eukaryotic tau/gamma homolog has refined the sequences of nine previously defined identity and functional motifs. Mutational analysis has defined highly conserved residues required for activity in vivo and in vitro. Specifically, mutations introduced into highly conserved residues within three of those motifs, the P loop, the DExx region, and the SRC region, inactivated complementing activity in vivo and clamp loading in vitro and reduced ATPase catalytic efficiency in vitro. Mutation of a highly conserved residue within a fourth motif, VIc, inactivated clamp-loading activity and reduced ATPase activity in vitro, but the mutant gene, on a multicopy plasmid, retained complementing activity in vivo and the mutant gene also supported apparently normal replication and growth as a haploid, chromosomal allele.

DNA structure requirements for the Escherichia coli gamma complex clamp loader and DNA polymerase III holoenzyme

The Escherichia coli chromosomal replicase, DNA polymerase III holoenzyme, is highly processive during DNA synthesis. Underlying high processivity is a ring-shaped protein, the beta clamp, that encircles DNA and slides along it, thereby tethering the enzyme to the template. The beta clamp is assembled onto DNA by the multiprotein gamma complex clamp loader that opens and closes the beta ring around DNA in an ATP-dependent manner. This study examines the DNA structure required for clamp loading action. We found that the gamma complex assembles beta onto supercoiled DNA (replicative form I), but only at very low ionic strength, where regions of unwound DNA may exist in the duplex. Consistent with this, the gamma complex does not assemble beta onto relaxed closed circular DNA even at low ionic strength. Hence, a 3'-end is not required for clamp loading, but a single-stranded DNA (ssDNA)/double-stranded DNA (dsDNA) junction can be utilized as a substrate, a result confirmed using synthetic oligonucleotides that form forked ssDNA/dsDNA junctions on M13 ssDNA. On a flush primed template, the gamma complex exhibits polarity; it acts specifically at the 3'-ssDNA/dsDNA junction to assemble beta onto the DNA. The gamma complex can assemble beta onto a primed site as short as 10 nucleotides, corresponding to the width of the beta ring. However, a protein block placed closer than 14 base pairs (bp) upstream from the primer 3' terminus prevents the clamp loading reaction, indicating that the gamma complex and its associated beta clamp interact with approximately 14-16 bp at a ssDNA/dsDNA junction during the clamp loading operation. A protein block positioned closer than 20-22 bp from the 3' terminus prevents use of the clamp by the polymerase in chain elongation, indicating that the polymerase has an even greater spatial requirement than the gamma complex on the duplex portion of the primed site for function with beta. Interestingly, DNA secondary structure elements placed near the 3' terminus impose similar steric limits on the gamma complex and polymerase action with beta. The possible biological significance of these structural constraints is discussed.

The chi psi subunits of DNA polymerase III holoenzyme bind to single-stranded DNA-binding protein (SSB) and facilitate replication of an SSB-coated template

A complex of the chi and psi proteins is required to confer resistance to high levels of glutamate on the DNA polymerase III holoenzyme-catalyzed reaction (Olson, M., Dallmann, H. G., and McHenry, C. (1995) J. Biol. Chem. 270, 29570-29577). We demonstrate that this salt resistance also requires templates to be coated with the Escherichia coli single-stranded DNA-binding protein (SSB). We show that this is the result of a direct chipsi-SSB interaction that is strengthened approximately 1000-fold when SSB is bound to DNA. On model oligonucleotide templates, DNA polymerase III core is inhibited by SSB. We show that the minimal polymerase assembly that will synthesize DNA on SSB-coated templates is polymerase III-tau-psi chi. gamma, the alternative product of the dnaX gene, will not replace tau in this reaction, indicating that tau's unique ability to bind to DNA polymerase III holding chipsi in the same complex is essential. All of our findings are consistent with chipsi strengthening DNA polymerase III holoenzyme interactions with the SSB-coated lagging strand at the replication fork, facilitating complex assembly and elongation.

Conservation of the Escherichia coli dnaX programmed ribosomal frameshift signal in Salmonella typhimurium

Escherichia coli DNA polymerase III subunits tau and gamma are produced from one gene, dnaX, by a programmed ribosomal frameshift which generates the C terminal of gamma within the tau reading frame. To help evaluate the role of the dispensable gamma, the distribution of tau and gamma homologs in several other species and the sequence of the Salmonella typhimurium dnaX were determined. All four enterobacteria tested produce tau and gamma homologs. S. typhimurium dnaX is 83% identical to E. coli dnaX, but all four components of the frameshift signal are 100% conserved.

Kinetic mechanism of the 3'-->5' proofreading exonuclease of DNA polymerase III. Analysis by steady state and pre-steady state methods

DNA polymerase III holoenzyme is the major replicative enzyme in Escherichia coli. An important component of the high-fidelity DNA synthesis that is characteristic of DNA polymerase III holoenzyme is the 3'-->5' proofreading exonuclease activity resident in the epsilon subunit. Steady state and pre-steady state conditions have been used to determine equilibrium and Michaelis constants for substrate binding and the rate constant for cleavage by purified epsilon subunit. The steady state kinetic constants are K(m) = 16 +/- 6 microM and kcat = 210 +/- 23 s-1 for degradation of single-stranded DNA by epsilon. These steady state values are in agreement with the rate constants determined for excision of the 3' nucleotide of a dT10 oligomer under pre-steady state conditions. Using a simple two-step model, E + Dn reversible E.Dn-->E + Dn-1, we find K = 12 microM and kf = 280 s-1 for the dT10 substrate. In these experiments, epsilon subunit acts in a distributive manner and product release is not the rate-limiting step. Activity of the epsilon subunit on paired DNA oligonucleotides with zero to three mismatches at the 3' terminus indicates that an additional step is required in the mechanism. In the scheme Dn reversible Dn* + E reversible E.Dn*-->E + Dn-1, the 3' terminus undergoes a conformational change or "melts" before the DNA is a substrate for epsilon subunit. With this additional step, the values for binding of activated substrate and cleavage are the same as those for single-stranded DNA. The kinetics for exonucleolytic degradation of single-stranded, paired, and mispaired oligonucleotides support the model that the rate-limiting step in exonucleolytic proofreading of DNA by epsilon subunit is the DNA-melting step.

Assembly of a chromosomal replication machine: two DNA polymerases, a clamp loader, and sliding clamps in one holoenzyme particle. V. Four different polymerase-clamp complexes on DNA

Several different subassemblies of DNA polymerase III holoenzyme can be purified from Escherichia coli. Toward the goal of understanding the functional significance of these subassemblies, we have used the gamma complex clamp loader and the beta ring to assemble each different polymerase onto DNA. Through use of radioactive labeled proteins, the subunit structure of each resulting processive polymerase has been determined. Use of DNA polymerase III core, the gamma complex, and beta results in a core-beta complex on DNA; the gamma complex is not incorporated into the structure. The addition of tau to the assembly reaction to form either core1-tau 2 or core2-tau 2 results in a more efficient polymerase and more stabile association of core-tau beta on DNA, although the gamma complex still does not remain on DNA. The gamma complex clamp loader was retained on DNA with the other subunits only if it was first assembled into the polymerase (Pol) III* structure. The clamp loader within Pol III* appeared to be capable of loading two beta clamps onto DNA for both core polymerases within Pol III*, consistent with the hypothesis that one replicase can simultaneously replicate both strands of a duplex chromosome. These findings extend those of an earlier study showing that distinctive polymerases can be assembled depending on the presence or absence of tau (Maki, S., and Kornberg, A. (1988) J. Biol. Chem. 263, 6561-6569). The significance of these distinct polymerases in separate paths of DNA metabolism is discussed.

Mutations in Escherichia coli dnaA which suppress a dnaX(Ts) polymerization mutation and are dominant when located in the chromosomal allele and recessive on plasmids

Extragenic suppressor mutations which had the ability to suppress a dnaX2016(Ts) DNA polymerization defect and which concomitantly caused cold sensitivity have been characterized within the dnaA initiation gene. When these alleles (designated Cs, Sx) were moved into dnaX+ strains, the new mutants became cold sensitive and phenotypically were initiation defective at 20 degrees C (J.R. Walker, J.A. Ramsey, and W.G. Haldenwang, Proc. Natl. Acad. Sci. USA 79:3340-3344, 1982). Detailed localization by marker rescue and DNA sequencing are reported here. One mutation changed codon 213 from Ala to Asp, the second changed Arg-432 to Leu, and the third changed codon 435 from Thr to Lys. It is striking that two of the three spontaneous mutations occurred in codons 432 and 435; these codons are within a very highly conserved, 12-residue region (K. Skarstad and E. Boye, Biochim. Biophys. Acta 1217:111-130, 1994; W. Messer and C. Weigel, submitted for publication) which must be critical for one of the DnaA activities. The dominance of wild-type and mutant alleles in both initiation and suppression activities was studied. First, in initiation function, the wild-type allele was dominant over the Cs, Sx alleles, and this dominance was independent of location. That is, the dnaA+ allele restored growth to dnaA (Cs, Sx) strains at 20 degrees C independently of which allele was present on the plasmid. The dnaA (Cs, Sx) alleles provided initiator function at 39 degrees C and were dominant in a dnaA(Ts) host at that temperature. On the other hand, suppression was dominant when the suppressor allele was chromosomal but recessive when it was plasmid borne. Furthermore, suppression was not observed when the suppressor allele was present on a plasmid and the chromosomal dnaA was a null allele. These data suggest that the suppressor allele must be integrated into the chromosome, perhaps at the normal dnaA location. Suppression by dnaA (Cs, Sx) did not require initiation at oriC; it was observed in strains deleted of oriC and which initiated at an integrated plasmid origin.

DNA replication: enzymology and mechanisms

Research into the enzymology of DNA replication has seen a multitude of highly significant advances during the past year, in both prokaryotic and eukaryotic systems. The scope of this article is limited to chromosomal replicases and origins of initiation. The multiprotein chromosomal replicases of prokaryotes and eukaryotes appear to be strikingly similar in structure and function, although future work may reveal their differences. Recent developments, elaborating the activation of origins in several systems, have begun to uncover mechanisms of regulation. The enzymology of eukaryotic origins has, until now, been limited to viral systems, but over the past few years, enzymology has caught a grip on the cellular origins of yeast.

SOS mutagenesis

In Escherichia coli, UV and many chemicals appear to cause mutagenesis by a process of translesion synthesis that requires some form of DNA polymerase III and the SOS-regulated proteins UmuD, UmuC and RecA. An analysis of SOS mutagenesis offers insights into the molecular basis of induced mutagenesis and into mechanisms of DNA damage tolerance.

The Escherichia coli DNA polymerase III holoenzyme contains both products of the dnaX gene, tau and gamma, but only tau is essential

The replicative polymerase of Escherichia coli, DNA polymerase III, consists of a three-subunit core polymerase plus seven accessory subunits. Of these seven, tau and gamma are products of one replication gene, dnaX. The shorter gamma is created from within the tau reading frame by a programmed ribosomal -1 frameshift over codons 428 and 429 followed by a stop codon in the new frame. Two temperature-sensitive mutations are available in dnaX. The 2016(Ts) mutation altered both tau and gamma by changing codon 118 from glycine to aspartate; the 36(Ts) mutation affected the activity only of tau because it altered codon 601 (from glutamate to lysine). Evidence which indicates that, of these two proteins, only the longer tau is essential includes the following. (i) The 36(Ts) mutation is a temperature-sensitive lethal allele, and overproduction of wild-type gamma cannot restore its growth. (ii) An allele which produced tau only could be substituted for the wild-type chromosomal gene, but a gamma-only allele could not substitute for the wild-type dnaX in the haploid state. Thus, the shorter subunit gamma is not essential, suggesting that tau can be substitute for the usual function(s) of gamma. Consistent with these results, we found that a functional polymerase was assembled from nine pure subunits in the absence of the gamma subunit. However, the possibility that, in cells growing without gamma, proteolysis of tau to form a gamma-like product in amounts below the Western blot (immunoblot) sensitivity level cannot be excluded.