Dissection of the ATP-driven reaction cycle of the bacteriophage T4 DNA replication processivity clamp loading system.

Processive DNA replication requires the loading of a multisubunit ring-shaped protein complex, known as a sliding or processivity clamp, onto the primer-template (p/t) DNA. This clamp then binds to the replication polymerase to form a processive polymerase holoenzyme. The processivity of the holoenzyme derives from the topological properties of the clamp, which encircles the DNA without actually binding to it. Multisubunit complexes known as clamp-loaders utilize ATP to drive the placement of this ring around the DNA. To further understand the role of ATP binding and hydrolysis in driving clamp-loading in the DNA replication system of bacteriophage T4, we report the results of a series of presteady-state and steady-state kinetic ATPase experiments involving the various components of the reconstituted system. The results obtained are consistent with a mechanism in which a slow step, which involves the binary ATP-bound clamp-clamp loader complex, activates this complex and permits p/t DNA to bind and stimulate ATP hydrolysis. ATP hydrolysis itself, as well as the subsequent (after clamp-loading) dissociation of the clamp-loader and the slippage of the loaded clamp from the p/t DNA construct, are shown to be fast steps. A second slow step occurs after ATP hydrolysis. This step involves the dissociated clamp loader complex and may reflect ADP release. Only one molecule of ATP is hydrolyzed per clamp-loading event. Rate constants for each step, and an overall reaction mechanism for the T4 clamp-loading system, are derived from these data and from other results in the literature. The principles that emerge fit into a general framework that can apply to many biological processes involving ATP-driven reaction cycles.

Molecular mechanisms of the functional coupling of the helicase (gp41) and polymerase (gp43) of bacteriophage T4 within the DNA replication fork.

Processive strand-displacement DNA synthesis with the T4 replication system requires functional "coupling" between the DNA polymerase (gp43) and the helicase (gp41). To define the physical basis of this functional coupling, we have used analytical ultracentrifugation to show that gp43 is a monomeric species at physiological protein concentrations and that gp41 and gp43 do not physically interact in the absence of DNA, suggesting that the functional coupling between gp41 and gp43 depends significantly on interactions modulated by the replication fork DNA. Results from strand-displacement DNA synthesis show that a minimal gp41-gp43 replication complex can perform strand-displacement synthesis at approximately 90 nts/s in a solution containing poly(ethylene glycol) to drive helicase loading. In contrast, neither the Klenow fragment of Escherichia coli DNA polymerase I nor the T7 DNA polymerase, both of which are nonprocessive polymerases, can carry out strand-displacement DNA synthesis with gp41, suggesting that the functional helicase-polymerase coupling may require the homologous system. However, we show that a heterologous helicase-polymerase pair can work if the polymerase is processive. Strand-displacement DNA synthesis using the gp41 helicase with the T4 DNA polymerase holoenzyme or the phage T7 DNA polymerase-thioredoxin complex, both of which are processive, proceeds at the rate of approximately 250 nts/s. However, replication fork assembly is less efficient with the heterologous helicase-polymerase pair. Therefore, a processive (homologous or heterologous) "trailing" DNA polymerase is sufficient to improve gp41 processivity and unwinding activity in the elongation stage of the helicase reaction, and specific T4 helicase-polymerase coupling becomes significant only in the assembly (or initiation) stage.

Regulation of rho-dependent transcription termination by NusG is specific to the Escherichia coli elongation complex.

To terminate transcription in E. coli, Rho protein binds an RNA loading site on the nascent transcript, translocates 5'--> 3' along the RNA in an ATP-driven process, and, upon reaching the transcription elongation complex, brings about RNA release. Thus, the Rho-dependent termination process can be viewed, in part, as a kinetic competition between the rate of transcript elongation by RNA polymerase (RNAP) and the rate of Rho translocation along the nascent transcript. In the context of this model, NusG, which is an essential E. coli protein, regulates Rho-dependent termination in an apparently paradoxical way, increasing the rate of transcription elongation of E. coli RNAP in the absence of Rho while also shifting the sites of Rho-dependent termination upstream on the template. Here we investigate the regulation of Rho-dependent termination by NusG. Analytical ultracentrifugation was used to establish the existence of a stable complex of NusG and Rho and to demonstrate a stoichiometry of one NusG monomer per Rho hexamer. Surface plasmon resonance was used to examine the kinetics of the formation and dissociation of the NusG-Rho complex, yielding an association rate constant (k(on)) of 2.8 (+/-0.8) x 10(5) M(-)(1) s(-)(1), a dissociation rate constant (k(off)) of 3.9 (+/-0.7) x 10(-)(3) s(-)(1), and a calculated equilibrium (dissociation) constant (K(d)) of 1.5 (+/-0.3) x 10(-)(8) M. The apparent stability of the NusG-Rho complex is insensitive to changes in salt (potassium acetate) concentration between 0.05 and 0.15 M. The translocation and transcription termination activities of Rho at saturating NusG concentrations were, however, both sensitive to salt concentration over this range, suggesting that these activities do not directly reflect the stability of the NusG-Rho complex. Rho-dependent termination could be demonstrated for transcription complexes in which E. coli RNAP had been substituted by either bacteriophage SP6 or T7 RNAP. NusG, however, was not active in transcription termination assays with either of these phage RNAPs. Thus, we conclude that NusG modulates Rho-dependent termination by interacting specifically with the RNAP of the E. coli elongation complex to render the complex more susceptible to the termination activity of Rho.

Opening of a monomer-monomer interface of the trimeric bacteriophage T4-coded GP45 sliding clamp is required for clamp loading onto DNA.

The replication system of bacteriophage T4 uses a trimeric ring-shaped processivity clamp (gp45) to tether the replication polymerase (gp43) to the template-primer DNA. This ring is placed onto the DNA by an ATPase-driven clamp-loading complex (gp44/62) where it then transfers, in closed form, to the polymerase. It generally has been assumed that one of the functions of the loading machinery is to open the clamp to place it around the DNA. However, the mechanism by which this occurs has not been fully defined. In this study we design and characterize a double-mutant gp45 protein that contains pairs of cysteine residues located at each monomer-monomer interface of the trimeric clamp. This mutant protein is functionally equivalent to wild-type gp45. However, when all three monomer-monomer interfaces are tethered by covalent crosslinks formed (reversibly or irreversibly) between the cysteine pairs these closed clamps can no longer be loaded onto the DNA nor onto the polymerase, effectively eliminating processive strand-displacement DNA synthesis. Analysis of the individual steps of the clamp-loading process shows that the ATPase-dependent interactions between the clamp and the clamp loader that precede DNA binding are hyperstimulated by the covalently crosslinked ring, suggesting that binding of the closed ring induces a futile, ATP-driven, ring-opening cycle. These findings and others permit further characterization and ordering of the steps involved in the T4 clamp-loading process.

Interactions of bacteriophage T4-coded primase (gp61) with the T4 replication helicase (gp41) and DNA in primosome formation.

One primase (gp61) and six helicase (gp41) subunits interact to form the bacteriophage T4-coded primosome at the DNA replication fork. In order to map some of the detailed interactions of the primase within the primosome, we have constructed and characterized variants of the gp61 primase that carry kinase tags at either the N or the C terminus of the polypeptide chain. These tagged gp61 constructs have been probed using several analytical methods. Proteolytic digestion and protein kinase protection experiments show that specific interactions with single-stranded DNA and the T4 helicase hexamer significantly protect both the N- and the C-terminal regions of the T4 primase polypeptide chain against modification by these procedures and that this protection becomes more pronounced when the primase is assembled within the complete ternary primosome complex. Additional discrete sites of both protection and apparent hypersensitivity along the gp61 polypeptide chain have also been mapped by proteolytic footprinting reactions for the binary helicase-primase complex and in the three component primosome. These studies provide a detailed map of a number of gp61 contact positions within the primosome and reveal interactions that may be important in the structure and function of this central component of the T4 DNA replication complex.

Interactions of Escherichia coli sigma(70) within the transcription elongation complex.

A functional transcription elongation complex can be formed without passing through a promoter by adding a complementary RNA primer and core Escherichia coli RNA polymerase in trans to an RNA-primed synthetic bubble-duplex DNA framework. This framework consists of a double-stranded DNA sequence with an internal noncomplementary DNA "bubble" containing a hybridized RNA primer. On addition of core polymerase and the requisite NTPs, the RNA primer is extended in a process that manifests most of the properties of in vitro transcription elongation. This synthetic elongation complex can also be assembled by using holo rather than core RNA polymerase, and in this study we examine the interactions and fate of the sigma(70) specificity subunit of the holopolymerase in the assembly process. We show that the addition of holopolymerase to the bubble-duplex construct triggers the dissociation of the sigma factor from some complexes, whereas in others the RNA oligomer is released into solution instead. These results are consistent with an allosteric competition between sigma(70) and the nascent RNA strand within the elongation complex and suggest that both cannot be bound to the core polymerase simultaneously. However, the dissociation of sigma(70) from the complex can also be stimulated by binding of the holopolymerase to the DNA bubble duplex in the absence of a hybridized RNA primer, suggesting that the binding of the core polymerase to the bubble-duplex construct also triggers a conformational change that additionally weakens the sigma-core interaction.

Determinants of the stability of transcription elongation complexes: interactions of the nascent RNA with the DNA template and the RNA polymerase.

We use a synthetic "primed bubble-duplex" model elongation complex developed previously to examine certain structural and thermodynamic features of the transcription elongation complex of Escherichia coli. The nucleic acid framework of this model complex consists of a linear base-paired DNA molecule with a central "bubble" of non-complementary nucleotide residues, together with a single-stranded RNA molecule that is complementary (at its 3'-end) to three to 12 nucleotide residues of one of the DNA strands within the bubble. RNA polymerase is added to this framework in trans, and on addition of rNTPs the resulting complex can elongate the 3'-end of the RNA primer in a template-dependent manner with functional properties that are indistinguishable from those of a "natural" promoter-initiated transcription elongation complex operating under the same conditions. In this study we use this model system to show that the formation of a stable elongation complex at any particular template position can be treated as an equilibrium process, and that semi-quantitative dissociation constants can be estimated for the complex by using a gel band-shift assay to monitor the binding of the RNA oligomer to the complex. We then show that the formation of a stable complex depends on the presence of a complementary RNA-DNA hybrid that is at least 9 bp in length, and in addition that several nucleotide residues of non-complementary RNA located upstream of the RNA-DNA hybrid bind strongly to the putative single-stranded RNA binding site of the polymerase and significantly enhance the stability of the resulting elongation complex. Finally, we demonstrate that the measured stabilities of the model constructs in which the length of the RNA-DNA hybrid is varied correlate well with the transcriptional processivity of the functioning complex that results when rNTPs are added. These findings are discussed in the context of related studies of both model systems and natural elongation complexes. The general concepts that emerge are used to define some central structural and functional features of the transcription complex.

Rho-dependent termination within the trp t' terminator. I. Effects of rho loading and template sequence.

About one-half of the terminators of the Escherichia coli genome require transcription termination factor rho to function. Here we use the very "diffuse" trp t' terminator of E. coli to show that both template sequence and transcript secondary structure are involved in controlling the template positions and efficiencies of rho-dependent termination. Termination begins in the wild-type trp t' terminator sequence approximately 97 bps downstream of the promoter under our standard reaction conditions, and termination efficiencies for individual positions on three related templates have been determined in the form of quantitative patterns of rho-dependent RNA release. Comparison of these patterns shows that the rho-dependent termination efficiency at individual template positions depends primarily on the nucleotide sequence at and near the putative 3' end of the transcript, although these efficiencies can also be influenced by RNA sequence elements located further upstream. The amplitudes of the peaks of the RNA release patterns at specific template positions are controlled primarily by the effectiveness of the binding of the rho hexamer to the "rho loading site" of the transcript. Introduction of a stable element of secondary structure into the nascent RNA within the loading site both shifts the position of initial rho-dependent termination downstream and decreases the amplitudes of the peaks of the RNA release pattern at the corresponding sequences. These results and others are consistent with the view that rho-dependent terminators contain two essential components: (i) an upstream rho loading site on the RNA that is 70-80 nucleotide residues in length, essentially devoid of secondary structure, and which contains sufficient numbers of rC residues to activate the RNA-dependent ATPase of rho; and (ii) a downstream sequence within which termination actually occurs. In this study we use the trp t' terminator to characterize the involvement of each of these sequence components in detail in order to provide the parameters required to define a quantitative mechanistic model for the function of rho in transcript termination.

Rho-dependent termination within the trp t' terminator. II. Effects of kinetic competition and rho processivity.

Continuing our quantitative analysis of rho-dependent termination at the trp t ' terminator, we here present evidence that the position of rho-dependent terminators along the template is strongly regulated by the secondary structure of the nascent RNA transcript, and that the prerequisite for establishing an effective kinetic competition between elongation and rho-dependent RNA release at a particular termination position is an upstream rho hexamer properly bound to a rho loading site on the nascent transcript. As a consequence kinetic competition regulates termination efficiency at individual positions downstream of the rho loading site, but does not control the position of the termination zone. Conditions that favor the formation of stable secondary structure on the RNA shift the initial rho-dependent termination position downstream. These results are consistent with a model that states that the rho protein requires approximately 70-80 nucleotide residues of unstructured RNA to load onto the transcript and cause termination, and that stable RNA secondary structures are effectively "looped out" to avoid interaction with rho, meaning that more RNA must be synthesized before rho-dependent termination can begin. Thus, although the rate of transcript elongation is important in determining termination efficiency at specific template positions, the process of loading of the rho hexamer onto the nascent transcript plays an overriding role in determining the template positions of rho-dependent terminators. We also show that at high salt concentrations, which have virtually no effect on the rate of transcript elongation, rho-dependent transcript termination is more directly dependent on the efficiency of rho loading, since the processivity of translocation of rho along the nascent transcript to "catch up with" the polymerase is much more limited under these conditions. A quantitative model for rho-dependent transcript termination is developed to account for all these interacting effects of rho on the efficiency of RNA release from actively transcribing elongation complexes.

An integrated model of the transcription complex in elongation, termination, and editing.

Recent findings now allow the development of an integrated model of the thermodynamic, kinetic, and structural properties of the transcription complex in the elongation, termination, and editing phases of transcript formation. This model provides an operational framework for placing known facts and can be extended and modified to incorporate new advances. The most complete information about transcriptional mechanisms and their control continues to come from the Escherichia coli system, upon which most of the explicit descriptions provided here are based. The transcriptional machinery of higher organisms, despite its greater inherent complexity, appears to use many of the same general principles. Thus, the lessons of E. coli continue to be relevant.

Effects of reaction conditions on RNA secondary structure and on the helicase activity of Escherichia coli transcription termination factor Rho.

The ATPase and helicase activities of the Escherichia coli transcription termination protein rho have been studied under a variety of reaction conditions that alter its transcription termination activity. These conditions include KCl, KOAc, or KGlu concentrations from 50 to 150 mM and Mg(OAc)2 concentrations from 1 to 5 mM (in the presence of 1 mM ATP). In higher KCl or higher Mg(OAc)2 concentrations we found that the translocation of rho hexamers along RNA was slower and less processive than the same process measured at 50 mM monovalent salt concentrations and 1 mM Mg(OAc)2. The ATPase activity of rho was also decreased under reaction conditions that slowed translocation. RNA melting experiments showed that the decreased ATPase activity of rho and the slower helicase activity at increased KCl or Mg(OAc)2 concentrations are accompanied by a concomitant increase in the secondary structure of the RNA portion of the helicase substate. In contrast, the ATPase activity of rho in the presence of poly(rC), a synthetic RNA that does not form salt-concentration-dependent secondary structure, was shown to be the same in each of the three monovalent salts. Thus, the salts do not directly affect the structure or conformation of the rho protein or the binding of rho to single-stranded RNA. However, the translocation of rho along RNA was more processive in 150 mM KOAc or KGlu than in 150 mM KCl, while the RNA secondary structure was the same in all three monovalent salts. Therefore, the monovalent salt present in the reaction may directly affect rho-RNA interactions when the RNA substrate can form secondary structure. Helicase experiments with an RNA molecule that does not contain a rho loading-site showed that rho translocates less processively along this potential helicase substrate. These results suggest that the helicase activity of rho may be significantly regulated by RNA secondary structure. In addition, one of the mechanisms to concentrate the activity of rho on transcripts containing unstructured rho loading sites may be that rho translocation along such molecules is more processive than it is along more structured RNA molecules in the cell.

A two-metal ion mechanism operates in the hammerhead ribozyme-mediated cleavage of an RNA substrate.

Evidence for a two-metal ion mechanism for cleavage of the HH16 hammerhead ribozyme is provided by monitoring the rate of cleavage of the RNA substrate as a function of La3+ concentration in the presence of a constant concentration of Mg2+. We show that a bell-shaped curve of cleavage activation is obtained as La3+ is added in micromolar concentrations in the presence of 8 mM Mg2+, with a maximal rate of cleavage being attained in the presence of 3 microM La3+. These results show that two-metal ion binding sites on the ribozyme regulate the rate of the cleavage reaction and, on the basis of earlier estimates of the Kd values for Mg2+ of 3.5 mM and > 50 mM, that these sites bind La3+ with estimated Kd values of 0.9 and > 37.5 microM, respectively. Furthermore, given the very different effects of these metal ions at the two binding sites, with displacement of Mg2+ by La3+ at the stronger (relative to Mg2+) binding site activating catalysis and displacement of Mg2+ by La3+ at the weaker (relative to Mg2+) (relative to Mg2+) binding site inhibiting catalysis, we show that the metal ions at these two sites play very different roles. We argue that the metal ion at binding site 1 coordinates the attacking 2'-oxygen species in the reaction and lowers the pKa of the attached proton, thereby increasing the concentration of the attacking alkoxide nucleophile in an equilibrium process. In contrast, the role of the metal ion at binding site 2 is to catalyze the reaction by absorbing the negative charge that accumulates at the leaving 5'-oxygen in the transition state. We suggest structural reasons why the Mg(2+)-La3+ ion combination is particularly suited to demonstrating these different roles of the two-metal ions in the ribozyme cleavage reaction.

Transcriptional activation via DNA-looping: visualization of intermediates in the activation pathway of E. coli RNA polymerase x sigma 54 holoenzyme by scanning force microscopy.

Scanning force microscopy (SFM) has been used to study transcriptional activation of Escherichia coli RNA polymerase x sigma 54 (RNAP x sigma 54) at the glnA promoter by the constitutive mutant NtrC(D54E,S160F) of the NtrC Protein (nitrogen regulatory protein C). DNA-protein complexes were deposited on mica and images were recorded in air. The DNA template was a 726 bp linear fragment with two NtrC binding sites located at the end and about 460 bp away from the RNAP x sigma 54 glnA promoter. By choosing appropriate conditions the structure of various intermediates in the transcription process could be visualized and analyzed: (1) different multimeric complexes of NtrC(D54E,S160F) dimers bound to the DNA template; (2) the closed complex of RNAP x sigma 54 at the glnA promoter; (3) association between DNA bound RNAP x sigma 54 and NtrC(D54E,S160F) with the intervening DNA looped out; and (4) the activated open promoter complex of RNAP x sigma 54. Measurements of the DNA bending angle of RNAP x sigma 54 closed promoter complexes yielded an apparent bending angle of 49(+/-24) degrees. Under conditions that allowed the formation of the open promoter complex, the distribution of bending angles displayed two peaks at 50(+/-24) degrees and 114(+/-18) degrees, suggesting that the transition from the RNAP x sigma 54 closed complex to the open complex is accompanied by an increase of the DNA bending angle.

Kinetics of the RNA-DNA helicase activity of Escherichia coli transcription termination factor rho. 1. Characterization and analysis of the reaction.

The kinetics of the ATP-dependent RNA-DNA helicase activity of Escherichia colitranscription termination factor rho have been analyzed. Helicase substrates were assembled using 255 nt and 391 nt RNA sequences from the trp t' RNA transcript of E. coli. These RNA sequences each carry a rho "loading site" at a position near the 5'-end, and a rho-dependent terminator sequence at the 3'-end to which complementary approximately 20 nt DNA oligonucleotides have been annealed. A rapid ( approximately 30 s) pre-steady-state burst of helicase activity (DNA oligomer release), followed by a slow linear phase, is observed in reactions carried out at low salt concentrations (50 mM KCl). Using poly(rC) or poly(dC) as traps for the rho that is released after one round of activity, we have shown that the first (burst) phase of the reaction represents the processive translocation of prebound rho hexamers from the rho loading site to the 3'-end of the RNA molecule. The slow phase of the reaction is complex and represents a combination of many different processes, including the slow release of RNA from rho, the reannealing of complementary DNA oligonucleotides to the RNA substrate, and the recycling of rho hexamers onto additional RNA molecules. Reactions carried out at higher salt concentrations (150 mM KCl) consist of only one phase, since under these conditions rho dissociates more rapidly from the RNA, with an amplitude corresponding to several DNA oligomers removed per rho hexamer. Thus, rho can recycle and function as a catalytic helicase under reaction conditions resembling those found in the cell.

Kinetics of the RNA-DNA helicase activity of Escherichia coli transcription termination factor rho. 2. Processivity, ATP consumption, and RNA binding.

The RNA-binding and RNA-DNA helicase activities of the Escherichia coli transcription termination factor rho have been investigated using natural RNA molecules that are 255 and 391 nucleotide residues in length and that contain the trp t' rho-dependent termination sequence of E. coli. Helicase substrates were prepared from these RNA molecules by annealing one or more DNA oligomers to complementary sequences located at or near the 3'-ends of the RNA molecules to form defined RNA-DNA hybrid sequences ranging in length from 20 to 100 bp. By comparing the fraction of the RNA molecules bound to rho with the fraction of bound DNA oligomers removed from the RNA during one round of the helicase reaction, we have shown that rho translocates processively at 37 degrees C in buffer containing 50 mM KCl. Helicase reactions and ATPase measurements were performed in parallel in the presence of RNA molecules containing RNA-DNA hybrids of various lengths, and we show that both the rate of translocation of the rho hexamer along the RNA chain and the rate of ATP consumption are similar, whether or not DNA is hybridized to the RNA transcript. By combining measurements of translocation and ATPase rates, we estimate that rho consumes approximately 1-2 ATP molecules in translocating over 1 nucleotide residue of the RNA chain at 37 degrees C in 50 mM KCl. The ATPase activity of rho remains the same after one round of the helicase reaction, indicating that rho appears to hydrolyze ATP at the same rate, whether it is translocating along the RNA, separating RNA-DNA hybrids, or bound at the 3'-end of the RNA substrate. We also show that rho binds cooperatively ( approximately 2-4 rho hexamers per RNA chain) to the RNA substrates under our standard helicase reaction conditions. However, cooperative binding is not essential for helicase activity, since this binding stoichiometry can be reduced to approximately 1.5 rho hexamers per 255-nucleotide residue RNA chain by blocking approximately 100 nt of either end of the rho binding site of the helicase substrate with complementary DNA oligonucleotides, with no change in helicase properties. The implications of these results for models of rho helicase function and for the role of rho in termination are discussed.