Melting of a DNA helix terminus within the active site of a DNA polymerase.

Accurate synthesis of DNA by polymerase is due in part to the selective removal of misincorporated nucleotides by a 3'-5' exonuclease activity (proofreading). Proofreading by an exonuclease domain containing a single-stranded DNA binding site may involve local melting of a duplex DNA substrate. Here we use time-resolved fluorescence spectroscopy to analyze the local melting of a DNA duplex terminus induced by the Klenow fragment of DNA polymerase I. Four oligodeoxynucleotide primer/templates were prepared, each containing the fluorescent adenine analog 2-aminopurine (A*) at the primer 3' terminus, and one of the common DNA bases opposite the A* residue. Fluorescence decays of the duplex DNAs and the single primer oligonucleotide were jointly analyzed using global analysis procedures. Four lifetime components were resolved in the duplex DNAs, representing distinct conformational states of the terminal A* residue: paired A* bases, partially stacked A* bases, and extended A* bases. The variation of the apparent fraction of paired A* bases with temperature was in accord with optical melting data, and the extent of base pairing observed in each duplex was consistent with the base-pairing preferences of A* established in other studies. These results establish that the fluorescence decay characteristics of A* can be used to examine base-pairing interactions at a DNA duplex terminus. Since the fluorescence of A* can be observed without interference from protein amino acid residues, unlike existing methods for monitoring DNA melting transitions, this method was used to examine the extent to which Klenow fragment could induce fraying at each duplex terminus.(ABSTRACT TRUNCATED AT 250 WORDS)

Proofreading DNA: recognition of aberrant DNA termini by the Klenow fragment of DNA polymerase I.

Fluorescence depolarization decays were measured for 5-dimethylaminonaphthalene-1-sulfonyl (dansyl) probes attached internally to 17-mer.27-mer oligonucleotides bound to Klenow fragment of DNA polymerase I. The time-resolved motions of the dansyl probes were sensitive indicators of DNA-protein contacts, showing that the protein binds to DNA with two footprints, corresponding to primer termini at either the polymerase or 3'-5' exonuclease sites. We examined complexes of Klenow fragment with DNAs containing various base mismatches. Single mismatches at the primer terminus caused a 3- to 4-fold increase in the equilibrium partitioning of DNA into the exonuclease site; the largest effects were observed for purine-purine mismatches. Two or more consecutive G.G mismatches caused the DNA to bind exclusively at the exonuclease site, with a partitioning constant at least 250-fold greater than that of the corresponding matched DNA sequence. Internal single mismatches produced larger effects than the same mismatch at the primer terminus, with a delta delta G relative to the matched sequence of -1.1 to -1.3 kcal/mol for mismatches located 2, 3, or 4 bases from the primer terminus. Although part of the observed effects may be attributed to the increased melting capacity of the DNA, it appears that the polymerase site also promotes movement of DNA into the exonuclease site by rejecting aberrant primer termini. These effects suggest that the polymerase and exonuclease sites act together to recognize specific errors that distort the primer terminus, such as frameshifts, in addition to proofreading misincorporated bases.

Distance distribution in a dye-linked oligonucleotide determined by time-resolved fluorescence energy transfer.

Fluorescence energy transfer is potentially a useful technique for obtaining structural and dynamic information on duplex and branched DNA molecules suitably labeled with donor and acceptor dyes. We have assessed the accuracy and limitations of FET measurements in nucleic acids with respect to the localization of the dyes and the flexibility of the dye-DNA linkages. A nine base-pair duplex oligonucleotide was synthesized with donor and acceptor dyes linked at the opposing 5' termini by alkyl chains. A careful analysis of the fluorescence decay of the donor revealed that the donor-acceptor distance in this molecule was not well defined, but was described by a rather broad distribution. The mean donor-acceptor distance and the distribution of distances have been recovered from the donor decay. Orientational effects on energy transfer have been included in the analysis. The implications of these findings for FET measurements in nucleic acids are considered.

Interaction of DNA with the Klenow fragment of DNA polymerase I studied by time-resolved fluorescence spectroscopy.

The interaction of a fluorescent duplex DNA oligomer with the Klenow fragment of DNA polymerase I from Escherichia coli has been studied in solution by using time-resolved fluorescence spectroscopy. An aminonaphthalenesulfonate (dansyl) fluorescent probe was linked by a propyl chain to a C5-modified uridine base located at a specific site in the primer strand of the DNA oligomer. The fluorescent oligomer bound tightly to the Klenow fragment (KD = 7.9 nM), and the probe's position within the DNA-protein complex was varied by stepwise elongation of the primer strand upon addition of the appropriate deoxynucleoside triphosphates. The decay of the total fluorescence intensity and the polarization anisotropy were measured with a picosecond laser and a time-correlated single photon counting system. The fluorescence lifetimes, the correlation time for internal rotation, and the angular range of internal rotation varied according to the probe's position within the DNA-protein complex. These results showed that five or six bases of the primer strand upstream of the 3' terminus were in contact with the protein and that within this contact region there were differences in the degree of solvent accessibility and the closeness of contact. Further, a minor binding mode of the DNA-protein complex was identified, on the basis of heterogeneity of the probe environment observed when the probe was positioned seven bases upstream from the primer 3' terminus, which resulted in a distinctive "dip and rise" in the anisotropy decay. Experiments with an epoxy-terminated DNA oligomer and a site-directed mutant protein established that the labeled DNA was binding at the polymerase active site (major form) and at the spatially distinct 3'----5' exonuclease active site (minor form). The abundance of each of these distinct binding modes of the DNA-protein complex was estimated under solution conditions by analyzing the anisotropy decay of the dansyl probe. About 12% of the labeled DNA was bound at the 3'----5' exonuclease site. This method should be useful for investigating the editing mechanism of this important enzyme.

Dynamics of mismatched base pairs in DNA.

The structural dynamics of mismatched base pairs in duplex DNA have been studied by time-resolved fluorescence anisotropy decay measurements on a series of duplex oligodeoxynucleotides of the general type d[CGG(AP)GGC].d[GCCXCCG], where AP is the fluorescent adenine analogue 2-aminopurine and X = T, A, G, or C. The anisotropy decay is caused by internal rotations of AP within the duplex, which occur on the picosecond time scale, and by overall rotational diffusion of the duplex. The correlation time and angular range of internal rotation of AP vary among the series of AP.X mismatches, showing that the native DNA bases differ in their ability to influence the motion of AP. These differences are correlated with the strength of base-pairing interactions in the various AP.X mismatches. The interactions are strongest with X = T or C. The ability to discern differences in the strength of base-pairing interactions at a specific site in DNA by observing their effect on the dynamics of base motion is a novel aspect of the present study. The extent of AP stacking within the duplex is also determined in this study since it influences the excited-state quenching of AP. AP is thus shown to be extrahelical in the AP.G mismatch. The association state of the AP-containing oligodeoxynucleotide strand is determined from the temperature-dependent tumbling correlation time. An oligodeoxynucleotide triplex is formed with a particular base sequence in a pH-dependent manner.