DNA helicases unwind duplex DNA to form the single-stranded (ss) DNA intermediates required for replication, recombination, and repair in reactions that require nucleoside 5'-triphosphate hydrolysis. Helicases generally require a ss-DNA flanking the duplex in order to initiate unwinding in vitro; however, the precise function of the ss-DNA is not understood. If a helicase unwinds DNA by a "passive" mechanism, it would bind to and translocate unidirectionally along the ss-DNA and facilitate duplex unwinding by translocating onto the ss-DNA that is formed transiently by thermal fluctuations in the duplex. We have examined the kinetics of DNA unwinding by Escherichia coli Rep protein (a 3' to 5' helicase) by rapid quench-flow methods using a series of novel, nonnatural DNA substrates possessing 3' flanking ss-DNA within which is embedded either a segment of ss-DNA possessing reversed backbone polarity or a non-DNA [poly(ethylene glycol)] spacer, either of which should block unwinding by a passive helicase. The E. coli Rep helicase effectively unwinds these DNA substrates, ruling out a passive mechanism of unwinding. Instead, the results are consistent with an "active" rolling mechanism during which Rep binds to ss-DNA and duplex DNA simultaneously.
Vitamin B12-dependent methionine synthase catalyzes the transfer of a methyl group from methyltetrahydrofolate to homocysteine via the enzyme-bound cofactor methylcobalamin. To carry out this reaction, the enzyme must alternately stabilize six-coordinate methylcobalamin and four-coordinate cob(I)alamin oxidation states. The lower axial ligand to the cobalt in free methylcobalamin is the dimethylbenzimidazole nucleotide substituent of the corrin ring; when methylcobalamin binds to methionine synthase, the ligand is replaced by histidine 759, which in turn is linked by hydrogen bonds to aspartate 757 and thence to serine 810. We have proposed that these residues control the reactivity of the enzyme-bound cofactor both by increasing the coordination strength of the imidazole ligand and by allowing stabilization of cob(I)alamin via protonation of the His-Asp-Ser triad. In this paper we report results of mutation studies focusing on these catalytic residues. We have used visible absorbance spectroscopy and electron paramagnetic resonance spectroscopy to probe the coordination state of the cofactor and have used stopped-flow kinetic measurements to explore the reactivity of each mutant. We show that mutation of histidine 759 blocks turnover, while mutations of aspartate 757 or serine 810 decrease the reactivity of the methylcobalamin cofactor. In contrast, we show that mutations of these same residues increase the rate of AdoMet-dependent reactivation of cob(II)alamin enzyme. We propose that the reaction with AdoMet proceeds via a different transition state than the reactions with homocysteine and methyltetrahydrofolate. These results provide a glimpse at how a protein can control the reactivity of methylcobalamin.
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)
Cobalamin-dependent methionine synthase from Escherichia coli is a monomeric 136 kDa protein composed of multiple functional regions. The X-ray structure of the cobalamin-binding region of methionine synthase reveals that the cofactor is sandwiched between an alpha-helical domain that contacts the upper face of the cobalamin and an alpha/beta (Rossmann) domain that interacts with the lower face. An unexpected conformational change accompanies binding of the methylcobalamin cofactor. The dimethylbenzimidazole ligand to the lower axial position of the cobalt in the free cofactor is displaced by histidine 759 from the Rossmann domain [Drennan, C. L., Huang, S., Drummond, J. T., Matthews, R. G., & Ludwig, M. L. (1994) Science 266, 1669]. In order to facilitate studies of the roles of amino acid residues in the cobalamin-binding region of methionine synthase, we have constructed a synthetic module corresponding to nucleotides (nt) 1741-2668 in the metH gene and incorporated it into the wild-type metH gene. This module contains unique restriction sites at approximately 80 base pair intervals and was synthesized by overlap extension of 22 synthetic oligonucleotides ranging in length from 70 to 105 nt and subsequent amplification using two sets of primers. Expression of methionine synthase from a plasmid containing the modified gene was shown to be unaffected by the introduction of the synthetic module. E. coli does not synthesize cobalamin, and overexpression of MetH holoenzyme requires accelerated cobalamin transport. Growth conditions are described that enable the production of holoenzyme rather than apoenzyme. We describe the construction and initial characterization of seven mutants. Four mutations (His759Gly, Asp757Glu, Asp757Asn, and Ser810Ala) alter residues in the hydrogen-bonded network His-Asp-Ser that connects the histidine ligand of the cobalt to solvent. Three mutations (Phe708Ala, Phe714Ala, and Leu715Ala) alter residues in the cap region that covers the upper face of the cobalamin. The His759Gly mutation has profound effects, essentially abolishing steady-state activity, while the Asp757, Ser810, Phe708, and Leu715 mutations lead to decreases in activity. These mutations asses the importance of individual residues in modulating cobalamin reactivity.
Optical melting transitions of the short DNA hairpins formed from the self-complementary DNA oligomers d[GGATACX4GTATCC] where X = A, T, G, or C measured in 100 mM NaCl are presented. A significant dependence of the melting transitions on loop sequence is observed and transition temperatures, tm, of the hairpins vary from 58.3 degrees C for the T4 loop hairpin to 55.3 degrees C for the A4 loop. A nearest-neighbor sequence-dependent theoretical algorithm for calculating melting curves of DNA hairpins is presented and employed to analyze the experimental melting transitions. Experimental melting curves were fit by adjustment of a single theoretical parameter, Fend(n), the weighting function for a hairpin loop comprised of n single-strand bases. Empirically determined values of Fend(n) provide an evaluation of the free-energy of hairpin loop formation and stability. Effects of heterogeneous nearest-neighbor sequence interactions in the duplex stem on hairpin loop formation were investigated by evaluating Fend(n) in individual fitting procedures using two of the published sets of nearest-neighbor stacking interactions in DNA evaluated in 100 mM NaCl and given by Wartell and Benight, 1985. In all cases, evaluated values of Fend(n) were obtained that provided exact theoretical predictions of the experimental transitions. Results of the evaluations indicate: (1) Evaluated free-energies of hairpin loop formation are only slightly dependent on loop sequences examined. At the transition temperature, Tm, the free-energy of forming a loop of four bases is approximately equal for T4, G4, or C4 loops and varies from 3.9 to 4.8 kcal/mole depending on the set of nearest-neighbor interactions employed in the evaluations. This result suggests, in light of the observed differences in stability between the T4, G4, and C4 loop hairpins, that sequence-dependent interactions between base residues of the loop are most likely not the source of the enhanced stability of a T4 loop.(ABSTRACT TRUNCATED AT 400 WORDS)
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