Distinct MutS DNA-binding modes that are differentially modulated by ATP binding and hydrolysis

The role of MutS ATPase in mismatch repair is controversial. To clarify further the function of this activity, we have examined adenine nucleotide effects on interactions of Escherichia coli MutS with homoduplex and heteroduplex DNAs. In contrast to previous results with human MutS alpha, we find that a physical block at one end of a linear heteroduplex is sufficient to support stable MutS complex formation in the presence of ATP.Mg(2+). Surface plasmon resonance analysis at low ionic strength indicates that the lifetime of MutS complexes with heteroduplex DNA depends on the nature of the nucleotide present when MutS binds. Whereas complexes prepared in the absence of nucleotide or in the presence of ADP undergo rapid dissociation upon challenge with ATP x Mg(2+), complexes produced in the presence of ATP x Mg(2+), adenosine 5'-(beta,gamma-imino)triphosphate (AMPPNP) x Mg(2+), or ATP (no Mg(2+)) are resistant to dissociation upon ATP challenge. AMPPNP x Mg(2+) and ATP (no Mg(2+)) reduce MutS affinity for heteroduplex but have little effect on homoduplex affinity, resulting in abolition of specificity for mispaired DNA at physiological salt concentrations. Conversely, the highest mismatch specificity is observed in the absence of nucleotide or in the presence of ADP. ADP has only a limited effect on heteroduplex affinity but reduces MutS affinity for homoduplex DNA.

Modulation of MutS ATP hydrolysis by DNA cofactors

Escherichia coli MutS protein, which is required for mismatch repair, has a slow ATPase activity that obeys Michalelis-Menten kinetics. At 37 degrees C, the steady-state turnover rate for ATP hydrolysis is 1.0 +/- 0.3 min(-1) per monomer equivalent with a K(m) of 33 +/- 6 microM. Hydrolysis is competitively inhibited by the ATP analogues AMPPNP and ATPgammaS, with K(i) values of 4 microM in both cases, and by ADP with a K(i) of 40 microM. The rate of ATP hydrolysis is stimulated 2-5-fold by short hetero- and homoduplex DNAs. The concentration of DNA cofactor that yields half-maximal stimulation is lowest for oligodeoxynucleotide duplexes that contain a mismatched base pair. Pre-steady-state chemical quench analysis has demonstrated a substoichiometric initial burst of ADP formation by free MutS that is governed by a rate constant of 78 min(-1), indicating that the rate-limiting step for the steady-state reaction occurs after hydrolysis. Prebinding of MutS to homoduplex DNA does not alter the burst kinetics or amplitude but only increases the steady-state rate. In contrast, binding of the protein to heteroduplex DNA abolishes the burst of ADP formation, indicating that the rate-limiting step now occurs before hydrolysis. Gel filtration analysis indicates that the MutS dimer assembles into higher order oligomers in a concentration-dependent manner, and that ATP binding shifts this equilibrium to favor assembly. These results, together with kinetic findings, indicate nonequivalence of subunits within a MutS oligomer with respect to ATP hydrolysis and DNA binding.

Nucleotide-promoted release of hMutSalpha from heteroduplex DNA is consistent with an ATP-dependent translocation mechanism

ATP hydrolysis by bacterial and eukaryotic MutS activities is required for their function in mismatch correction, and two different models for the role of ATP in MutS function have been proposed. In the translocation model, based on study of bacterial MutS, ATP binding reduces affinity of the protein for a mismatch and activates secondary DNA binding sites that are subsequently used for movement of the protein along the helix contour in a reaction dependent on nucleotide hydrolysis (Allen, D. J., Makhov, A., Grilley, M., Taylor, J., Thresher, R., Modrich, P., and Griffith, J. D. (1997) EMBO J. 16, 4467-4476). The molecular switch model, based on study of human MutSalpha, invokes mismatch recognition by the MutSalpha.ADP complex. After recruitment of downstream repair activities to the MutSalpha.mismatch complex, ATP binding results in release of MutSalpha from the heteroduplex (Gradia, S., Acharya, S., and Fishel, R.(1997) Cell 91, 995-1005). To further clarify the function of ATP binding and hydrolysis in human MutSalpha action, we evaluated the effects of ATP, ADP, and nonhydrolyzable ATP analogs on the lifetime of protein.DNA complexes. All of these nucleotides were found to increase the rate of dissociation of MutSalpha from oligonucleotide heteroduplexes. These experiments also showed that ADP is not required for mismatch recognition by MutSalpha, but that the nucleotide alters the dynamics of formation and dissociation of specific complexes. Analysis of the mechanism of ATP-promoted dissociation of MutSalpha from a 200-base pair heteroduplex demonstrated that dissociation occurs at DNA ends in a reaction dependent on ATP hydrolysis, implying that release from this molecule involves movement of the protein along the helix contour as predicted for a translocation mechanism. In order to reconcile the relatively large rate of movement of MutS homologs along the helix with their modest rate of ATP hydrolysis, we propose a novel mechanism for protein translocation along DNA that supports directional movement over long distances with minimal energy input.

DNA-dependent activation of the hMutSalpha ATPase

ATP hydrolysis by MutS homologs is required for function of these proteins in mismatch repair. However, the function of ATP hydrolysis in the repair reaction is controversial. In this paper we describe a steady-state kinetic analysis of the DNA-activated ATPase of human MutSalpha. Comparison of salt concentration effects on mismatch repair and mismatch-provoked excision in HeLa nuclear extracts with salt effects on the DNA-activated ATPase suggests that ATP hydrolysis by MutSalpha is involved in the rate determining step in the repair pathway. While the ATPase is activated by homoduplex and heteroduplex DNA, the half-maximal concentration for activation by heteroduplex DNA is significantly lower under physiological salt concentrations. Furthermore, at optimal salt concentration, heteroduplex DNA increases the kcat for ATP hydrolysis to a greater extent than does homoduplex DNA. We also demonstrate that the degree of ATPase activation is dependent on DNA chain length, with the kcat for hydrolysis increasing significantly with chain length of the DNA cofactor. These results are discussed in terms of the translocation (Allen, D. J., Makhov, A., Grilley, M., Taylor, J., Thresher, R., Modrich, P., and Griffith, J. D. (1997) EMBO J. 16, 4467-4476) and the molecular switch (Gradia, S., Acharya, S., and Fishel, R. (1997) Cell 91, 995-1005) models that invoke distinct roles for ATP hydrolysis in MutS homolog function.

Kinetic mechanism for the sequential binding of two single-stranded oligodeoxynucleotides to the Escherichia coli Rep helicase dimer

Escherichia coli Rep helicase is a DNA motor protein that unwinds duplex DNA as a dimeric enzyme. Using fluorescence probes positioned asymmetrically within a series of single-stranded (ss) oligodeoxynucleotides, we show that ss-DNA binds with a defined polarity to Rep monomers and to individual subunits of the Rep dimer. Using fluorescence resonance energy transfer and stopped-flow techniques, we have examined the mechanism of ss-oligodeoxynucleotide binding to preformed Rep dimers in which one binding site is occupied by a single-stranded oligodeoxynucleotide, while the other site is free (P2S dimer). We show that ss-DNA binding to the P2S Rep dimer to form the doubly ligated P2S2 dimer occurs by a multistep process with the initial binding step occurring relatively rapidly with a bimolecular rate constant of k1 = approximately 2 x 10(6) M-1 s-1 [20 mM Tris (pH 7.5), 6 mM NaCl, 5 mM MgCl2, 5 mM 2-mercaptoethanol, and 10% (v/v) glycerol, 4 degrees C]. A minimal kinetic mechanism is proposed which suggests that the two strands of ss-DNA bound to the Rep homodimer are kinetically distinct even within the P2S2 Rep dimer, indicating that this dimer is functionally asymmetric. The implications of these results for the mechanisms of DNA unwinding and translocation by the functional Rep dimer are discussed.

Spectroscopic determination of open complex formation at promoters for Escherichia coli RNA polymerase

A considerable amount of effort has been expended studying the kinetics of association of Escherichia coli RNA polymerase with promoter DNA in forming the open complex. Strand separation occurs over about 12 base pairs and includes the transcription start site. However, these efforts have been significantly hampered by the lack of a sensitive, real time method by which formation of an open complex could be assayed. Here, we employ short (86 bp) synthetic promoters with 2-aminopurine (2-AP) substitutions in the region that becomes single-stranded to spectroscopically monitor open complex formation. We demonstrate that promoters bearing the substitutions behave in a manner similar to that of those containing only the four common bases with respect to both the region of strand separation and start site selection. Open complex formation was found to yield an increased fluorescence signal with an emission maximum characteristic of 2-aminopurine. This spectroscopic assay for open complex formation was found to be well-suited to the investigation of a strong promoter, allowing open complex formation to be followed over a time scale of seconds with a stopped flow apparatus. The introduction of two additional nonconsensus base pairs in the -35 region resulted in a promoter for which open complex formation was 100-fold slower. The same substrates were also used to monitor the promoter re-annealing that ensues upon initiation of RNA synthesis. Similar rates for this process were observed for the two promoter variants employed in this study.

ATP hydrolysis stimulates binding and release of single stranded DNA from alternating subunits of the dimeric E. coli Rep helicase: implications for ATP-driven helicase translocation

DNA helicases are motor proteins that unwind duplex DNA during DNA replication, recombination and repair in reactions that are coupled to ATP binding and hydrolysis. In the process of unwinding duplex DNA processively, DNA helicases must also translocate along the DNA filament. To probe the mechanism of ATP-driven translocation by the dimeric E. coli Rep helicase along single stranded (ss) DNA, we examined the effects of ATP on the dissociation kinetics of ssDNA from the Rep dimer. Stopped-flow experiments show that the dissociation rate of a fluorescent ss oligodeoxynucleotide bound to one subunit of the dimeric Rep helicase is stimulated by ssDNA binding to the other subunit, and that the rate of this ssDNA exchange reaction is further stimulated approximately 60-fold upon ATP hydrolysis. This ssDNA exchange process occurs via an intermediate in which ssDNA is transiently bound to both subunits of the Rep dimer. These results suggest a rolling or subunit switching mechanism for processive ATP-driven translocation of the dimeric Rep helicase along ssDNA. Such a mechanism requires the extreme negative cooperativity for DNA binding to the second subunit of the Rep dimer, which insures that the doubly DNA-ligated Rep (P2S2) dimer is formed only transiently and relaxes back to the singly ligated Rep (P2S) dimer. The fact that other oligomeric DNA helicases share many functional features with the dimeric Rep helicase suggests that similar mechanisms for translocation and DNA unwinding may apply to other dimeric as well as hexameric DNA helicases.

Mechanisms of helicase-catalyzed DNA unwinding

DNA helicases are essential motor proteins that function to unwind duplex DNA to yield the transient single-stranded DNA intermediates required for replication, recombination, and repair. These enzymes unwind duplex DNA and translocate along DNA in reactions that are coupled to the binding and hydrolysis of 5'-nucleoside triphosphates (NTP). Although these enzymes are essential for DNA metabolism, the molecular details of their mechanisms are only beginning to emerge. This review discusses mechanistic aspects of helicase-catalyzed DNA unwinding and translocation with a focus on energetic (thermodynamic), kinetic, and structural studies of the few DNA helicases for which such information is available. Recent studies of DNA and NTP binding and DNA unwinding by the Escherichia coli (E. coli) Rep helicase suggest that the Rep helicase dimer unwinds DNA by an active, rolling mechanism. In fact, DNA helicases appear to be generally oligomeric (usually dimers or hexamers), which provides the helicase with multiple DNA binding sites. The apparent mechanistic similarities and differences among these DNA helicases are discussed.

ATPase activity of Escherichia coli Rep helicase is dramatically dependent on DNA ligation and protein oligomeric states

The Escherichia coli Rep helicase catalyzes the unwinding of duplex DNA using the energy derived from ATP binding and hydrolysis. Rep functions as a dimer but assembles to its active dimeric form only on binding DNA. Each promoter of a dimer contains a DNA binding site that can bind either single-stranded (S) or duplex (D) DNA. The dimer can bind up to two oligodeoxynucleotides in five DNA-ligation states: two half-ligated states, P2S and P2D, and three fully-ligated states, P2S2, P2D2, and P2SD. We have previously shown that the relative stabilities of these ligation states are allosterically regulated by the binding and hydrolysis of ATP and have proposed an "active rolling" model for DNA unwinding where the enzyme cycles through a series of these ligation states in a process that is coupled to the catalytic cycle of ATP hydrolysis [Wong, I., & Lohman, T.M., (1992), Science 256, 350-355]. THe basal ATPase activity of Rep protein is stimulated by ss DNA binding and by protein dimerization. We have measured the steady-state ATPase activities of Rep bound to dT(pT)15 in each distinct ss DNA ligation state (PS, P2S, and P2S2) to compare with our previous measurements with unligated Rep monomer (P) [Moore, K.J.M., & Lohman, T.M. (1994) Biochemistry 33, 14550]. We find the ATPase activity of Rep is influenced dramatically by both dimerization and ss DNA ligation state, with the following kcat values for ATP hydrolysis increasing by over 4 orders of magnitude: 2.1 x 10(-3) s(-1) for P, 2.17 +/- 0.04 s(-1) for PS, 16.5 +/- 0.2 s(-1) for P2S, and 71 +/- 2.5 s(-1) for P2S2 (20 mM Tris-HCl, pH 7.5, 6mM NaCl, 5 mM MgCl2, 10% glycerol, 4 degrees C). The apparent KM's for ATP hydrolysis are 2.05 +/- 0.1 microM for PS and 2.7 +/- 0.2 microM for P2S. These widely different ATPase activities reflect the allosteric effects of DNA ligation and demonstrate that cooperative communication occurs between the ATP and DNA site of both subunits of the Rep dimer. These results further emphasize the need to explicitly consider the population distribution of oligomerization and DNA ligation states of the helicase when attempting to infer information about elementary processes such as helicase translocation based solely on macroscopic steady-state ATPase measurements.

Kinetic mechanism of DNA binding and DNA-induced dimerization of the Escherichia coli Rep helicase

The monomeric Escherichia coli Rep protein undergoes a DNA-induced dimerization upon binding either single-stranded (ss) or duplex DNA with the dimer being the active form of the Rep helicase. Using stopped-flow fluorescence, we have determined a minimal kinetic mechanism for this reaction in which Rep monomer (P) binds to ss oligodeoxynucleotides (dN(pN)15) (S) by a two-step mechanism to form PS*, which can then dimerize with P to form P2S as indicated: [reaction in text]. This minimal mechanism is supported by four independent studies in which the kinetics were monitored by changes in fluorescence intensity of three different probes: the intrinsic Rep tryptophan fluorescence, the fluorescence of d(T5(2-AP)T4(2-AP)T5), containing the fluorescent base, 2-aminopurine (2-AP), and dT(pT)15 labeled at its 3'-end with fluorescein (3'-F-dT(pT)15). Simultaneous (global) analysis of the time courses of d(T5(2-AP)T4(2-AP)T5) (100 nM) binding to a range of Rep monomer concentrations (25-400 nM) yields the following rate constants: k1 = (3.3 +/- 0.5) x 10(7) M-1 s-1; k-1 = 1.4 +/- 0.4 s-1; k2 = 2.7 +/- 0.9 s-1; k-2 = 0.21 +/- 0.06 s-1; k3 = (4.5 +/- 0.3) x 10(5) M-1 s-1; k-3 = 0.0027 +/- 0.0008 s-1 [20 mM Tris-HCl, pH 7.5, 6 mM NaCl, 5 mM MgCl2, 5 mM 2-mercaptoethanol, and 10% (v/v) glycerol, 4.0 degrees C]. This mechanism provides direct evidence that Rep monomers can bind ss DNA and that ss DNA binding induces a conformational change in the Rep monomer that is probably required for Rep dimerization. This conformational change is likely to be large and global since it is detected by all three fluorescence probes. The apparent bimolecular rate constant for Rep monomer binding to 3'-F-dT(pT)15 [k1(app) = (6.0 +/- 0.7) x 10(7) M-1 s-1] is slightly larger than measured with d(T5(2-AP)T4(2-AP)T5) binding. The apparent rate constant for dissociation of d(T5(2-AP)T4(2-AP)T5) (S) from the half-ligated Rep dimer, P2S, increases with increasing concentration of a nonfluorescent competitor ss DNA (d(T5-AT4AT5)) (C), indicating transient formation of a doubly ligated P2SC intermediate. However, the apparent bimolecular rate constant for binding of C to P2S is extremely slow (> or = 250 M-1 s-1), suggesting the occurrence of a multistep process before dissociation of ss DNA. In the absence of competitor DNA, dissociation of ss DNA from P2S occurs only after slow dissociation of the Rep dimer to form PS* + P. The implications of these results for Rep-catalyzed DNA unwinding are discussed.

Single-turnover kinetics of helicase-catalyzed DNA unwinding monitored continuously by fluorescence energy transfer

We describe a fluorescence assay that can be used to monitor helicase-catalyzed unwinding of duplex DNA continuously in real time. The assay is based on the observation that fluorescence resonance energy transfer (FRET) occurs between donor (fluorescein) and acceptor (hexachlorofluorescein) fluorophores that are in close proximity due to their covalent attachment to the 3' and 5' ends of the complementary strands of a duplex oligodeoxynucleotide. FRET results in a reduction in the fluorescence emission intensity of fluorescein in the duplex DNA substrate relative to that observed for fluorescein-labeled single stranded DNA. Therefore, an enhancement of fluorescein fluorescence (lambda ex = 492 nm; lambda em = 520 nm) occurs upon helicase-catalyzed unwinding of the duplex DNA and separation of the complementary strands. The fluorescence assay is extremely sensitive, allowing DNA unwinding reactions to be monitored continuously at DNA concentrations as low as 1 nM in a fluorescence stopped-flow experiment. We demonstrate the use of this DNA substrate in pre-steady state, single turnover studies of duplex DNA unwinding catalyzed by the Escherichia coli Rep helicase, monitored by fluorescence stopped flow. We show that the fluorescence enhancement monitors Rep-catalyzed DNA unwinding by comparisons with identical kinetic studies carried out using rapid chemical quench-flow techniques. Single turnover kinetic studies performed at 1 nM DNA as a function of excess Rep concentration show that Rep-catalyzed unwinding of an 18 base pair duplex containing a 3'-ss-(dT)20 tail is biphasic and can be described by the sum of two exponential terms. The observed rate constant of the first phase is independent of [Rep] (20-300 nM) and measures the rapid single turnover, unwinding of the duplex DNA by Rep dimers bound in productive complexes (1.3 +/- 0.2 s-1; 23 +/- 3 base pairs s-1 at 25.0 degrees C). The observed rate constant for the second phase increases linearly with [Rep], reflecting DNA unwinding that is limited by a Rep binding event occurring with a bimolecular rate constant of (1.8 +/- 0.1) x 10(5) M-1 s-1, which may reflect the rate constant for Rep dimerization on DNA. Kinetic competition studies indicate that both Rep subunits are bound stably to the DNA substrate in the productive complex that is unwound in the fast phase. The results of these kinetic studies are consistent with an active, rolling mechanism for Rep-catalyzed unwinding of DNA [Wong, I., & Lohman, T. M., (1992) Science 256, 350].(ABSTRACT TRUNCATED AT 400 WORDS)

Structure and assembly of the Escherichia coli transcription termination factor rho and its interactions with RNA. II. Physical chemical studies

Transcription termination factor rho from Escherichia coli is comprised of a hexamer of identical protein monomers. Hydrodynamic and light-scattering studies have shown the fully assembled rho to be a doughnut-shaped structure. Semi-denaturing gels, protein crosslinking, and spectroscopic studies, as well as other functional and binding determinations have established that the rho hexamer displays D3 symmetry (i.e. it exists as a trimer of dimers). In the accompanying paper we visualize rho directly in the absence of cofactor and show that binding of RNA it into the hexameric form. In this paper we examine the pathway and association constants involved in rho oligomer assembly. Sedimentation and fluorescence-detected size exclusion chromatography are used to demonstrate three steps in the assembly process. These steps can be differentiated by subunit association affinity and kinetic properties. The kinetics of the monomer-dimer equilibrium are fast and an apparent association constant of 1.3 x 10(6) M-1 is measured for this process. In contrast, the dimer-tetramer and tetramer-hexamer association processes appear to be slower (of the order of seconds) and to involve association constants that are smaller than that of the monomer-dimer reaction. This behaviour is consistent with a hexamer of D3 symmetry. Such a particle displays two kinds of subunit interactions; one associated with an intra-dimer A:A interface and the other with an inter-dimer B:B interface. The closure of the circular hexamer does not appear to contribute additional free energy to the assembly process. Fluorescence and sedimentation studies show the association steps to be sensitive to salt concentration. Consistent with earlier work, we find that assembly to the hexameric state is driven by RNA binding.