Nucleotide dependent structural and kinetic changes in Xenopus rad51.1-DNA complex stimulating the strand exchange reaction: destacking of DNA bases and restriction of their local motion

Linear Dichroism Measurements for the Study of Protein-DNA Interactions

Linear dichroism (LD) is a differential polarized light absorption spectroscopy used for studying filamentous molecules such as DNA and protein filaments. In this study, we review the applications of LD for the analysis of DNA-protein interactions. LD signals can be measured in a solution by aligning the sample using flow-induced shear force or a strong electric field. The signal generated is related to the local orientation of chromophores, such as DNA bases, relative to the filament axis. LD can thus assess the tilt and roll of DNA bases and distinguish intercalating from groove-binding ligands. The intensity of the LD signal depends upon the degree of macroscopic orientation. Therefore, DNA shortening and bending can be detected by a decrease in LD signal intensity. As examples of LD applications, we present a kinetic study of DNA digestion by restriction enzymes and structural analyses of homologous recombination intermediates, i.e., RecA and Rad51 recombinase complexes with single-stranded DNA. LD shows that the DNA bases in these complexes are preferentially oriented perpendicular to the filament axis only in the presence of activators, suggesting the importance of organized base orientation for the reaction. LD measurements detect DNA bending by the CRP transcription activator protein, as well as by the UvrB DNA repair protein. LD can thus provide information about the structures of protein-DNA complexes under various conditions and in real time.

Structural analysis of the human Rad51 protein-DNA complex filament by tryptophan fluorescence scanning analysis: transmission of allosteric effects between ATP binding and DNA binding

Human Rad51 (HsRad51) catalyzes the strand exchange reaction, a crucial step in homologous recombination, by forming a filamentous complex with DNA. The structure of this filament is modified by ATP, which is required and hydrolyzed for the reaction. We analyzed the structure and the ATP-promoted conformational change of this filament. We systematically replaced aromatic residues in the protein, one at a time, with tryptophan, a fluorescent probe, and examined its effect on the activities (DNA binding, ATPase, ATP-promoted conformational change, and strand exchange reaction) and the fluorescence changes upon binding of ATP and DNA. Some residues were also replaced with alanine. We thus obtained structural information about various positions of the protein in solution. All the proteins conserved, at least partially, their activities. However, the replacement of histidine at position 294 (H294) and phenylalanine at 129 (F129) affected the ATP-induced conformational change of the DNA-HsRad51 filament, although it did not prevent DNA binding. F129 is considered to be close to the ATP-binding site and to H294 of a neighboring subunit. ATP probably modifies the structure around F129 and affects the subunit/subunit contact around H294 and the structure of the DNA-binding site. The replacement also reduced the DNA-dependent ATPase activity, suggesting that these residues are also involved in the transmission of the allosteric effect of DNA to the ATP-binding site, which is required for the stimulation of ATPase activity by DNA. The fluorescence analyses supported the structural change of the DNA-binding site by ATP and that of the ATP-binding site by DNA. This information will be useful to build a molecular model of the Rad51-DNA complex and to understand the mechanism of activation of Rad51 by ATP and that of the Rad51-promoted strand exchange reaction.

Roles of the human Rad51 L1 and L2 loops in DNA binding

The human Rad51 protein, a eukaryotic ortholog of the bacterial RecA protein, is a key enzyme that functions in homologous recombination and recombinational repair of double strand breaks. The Rad51 protein contains two flexible loops, L1 and L2, which are proposed to be sites for DNA binding, based on a structural comparison with RecA. In the present study, we performed mutational and fluorescent spectroscopic analyses on the L1 and L2 loops to examine their role in DNA binding. Gel retardation and DNA-dependent ATP hydrolysis measurements revealed that the substitution of the tyrosine residue at position 232 (Tyr232) within the L1 loop with alanine, a short side chain amino acid, significantly decreased the DNA-binding ability of human Rad51, without affecting the protein folding or the salt-induced, DNA-independent ATP hydrolysis. Even the conservative replacement with tryptophan affected the DNA binding, indicating that Tyr232 is involved in DNA binding. The importance of the L1 loop was confirmed by the fluorescence change of a tryptophan residue, replacing the Asp231, Ser233, or Gly236 residue, upon DNA binding. The alanine replacement of phenylalanine at position 279 (Phe279) within the L2 loop did not affect the DNA-binding ability of human Rad51, unlike the Phe203 mutation of the RecA L2 loop. The Phe279 side chain may not be directly involved in the interaction with DNA. However, the fluorescence intensity of the tryptophan replacing the Rad51-Phe279 residue was strongly reduced upon DNA binding, indicating that the L2 loop is also close to the DNA-binding site.

Identification of the subunit-subunit interface of Xenopus Rad51.1 protein: similarity to RecA

Rad51, like its prokaryotic homolog RecA, forms a helical filament for homologous DNA recombination and recombinational DNA repair. Comparison of the three-dimensional structures of human Rad51 and Escherichia coli RecA indicated that the tyrosine residue at position 191 in human Rad51 lies at the centre of a putative subunit-subunit contact interface. We inserted a tryptophan residue as a fluorescent probe at the corresponding position in Xenopus Rad51.1 and found that its fluorescence depended upon the protein concentration, indicating that the residue is truly in the subunit-subunit interface. We also found that 3 M urea, which promoted the dissociation of Rad51 filament without complete unfolding of the protein, exposed the tryptophan residue to solvent. The fluorescence was not modified by binding to DNA and only slightly modified by ATP, indicating that the same site is used for formation of the active ATP-Rad51-DNA filament. The slight changes in fluorescence caused by ATP and ADP suggest that the subunit-subunit contact is altered, leading to the elongation of the filament by these nucleotides, as with the RecA filament. Thus, Rad51 forms filaments by subunit-subunit contact much like RecA does.

DNA dynamics in RecA-DNA filaments: ATP hydrolysis-related flexibility in DNA

RecA-catalyzed DNA recombination is initiated by a mandatory, high-energy form of DNA in RecA-nucleoprotein filaments, where bases are highly unstacked and the backbone is highly unwound. Interestingly, only the energetics consequent to adenosine triphosphate (ATP) binding, rather than its hydrolysis, seems sufficient to mediate such a high-energy structural hallmark of a recombination filament. The structural consequence of ATP hydrolysis on the DNA part of the filament thus remains largely unknown. We report time-resolved fluorescence dynamics of bases in RecA-DNA complexes and demonstrate that DNA bases in the same exhibit novel, motional dynamics with a rotational correlation time of 7-10 ns, specifically in the presence of ATP hydrolysis. When the ongoing ATP hydrolysis of RecA-DNA filament is "poisoned" by a nonhydrolyzable form of ATP (ATPgammaS), the motional dynamics cease and reveal a global motion with a rotational correlation time of >20 ns. Such ATP hydrolysis-induced flexibility ensues in single-stranded as well as double-stranded bases of RecA-DNA filaments. These results suggest that the role of ATP hydrolysis is to induce a high level of backbone flexibility in RecA-DNA filament, a dynamic property that is likely to be important for efficient strand exchanges in ATP hydrolysis specific RecA reactions. It is the absence of these motions that may cause high rigidity in RecA-DNA filaments in ATPgammaS. Dynamic light scattering measurement comparisons of RecA-ss-DNA filaments formed in ATPgammaS vs that of ATP confirmed such an interpretation, where the former showed a complex of larger (30 nm) hydrodynamic radius than that of latter (12-15 nm). Taken together, these results reveal a more dynamic state of DNA in RecA-DNA filament that is hydrolyzing ATP, which encourage us to model the role of ATP hydrolysis in RecA-mediated DNA transactions.

ADP stabilizes the human Rad51-single stranded DNA complex and promotes its DNA annealing activity

BACKGROUND

Human Rad51 protein (HsRad51) is a homologue of Escherichia coli RecA protein, and involved in homologous recombination. These eukaryotic and bacterial proteins catalyse strand exchange between two homologous DNA molecules, each forming a complex with single-stranded DNA (ssDNA) and ATP as the initial step. Both proteins hydrolyse ATP; however, the role of ATP hydrolysis appears to vary between the two proteins.

RESULTS

Measurements using the fluorescence ssDNA analogue, poly(1,N6-etheno-deoxyadenosine), indicate that ATP affects the HsRad51-ssDNA complex, promoting two conformational states: one transient, rather rigid transition state and a final more flexible state. While ADP lowers the affinity of RecA protein to ssDNA, it is found to rather stabilize the HsRad51-ssDNA complex. ADP does not activate the strand exchange by HsRad51 but instead stimulates annealing between complementary ssDNAs.

CONCLUSIONS

The hydrolysis of ATP promotes a transition of the HsRad51-ssDNA complex from a stiff state to less stiff state. The first state may be important for the strand separation of dsDNA in the initial step of strand exchange, while the second state may be important for annealing in the next step. However, hydrolysis does not dissociate HsRad51 from DNA as a component step of its recycling.

Difference between active and inactive nucleotide cofactors in the effect on the DNA binding and the helical structure of RecA filament dissociation of RecA--DNA complex by inactive nucleotides

The RecA protein requires ATP or dATP for its coprotease and strand exchange activities. Other natural nucleotides, such as ADP, CTP, GTP, UTP and TTP, have little or no activation effect on RecA for these activities. We have investigated the activation mechanism, and the selectivity for ATP, by studying the effect of various nucleotides on the DNA binding and the helical structure of the RecA filament. The interaction with DNA was investigated via fluorescence measurements with a fluorescent DNA analog and fluorescein-labeled oligonucleotides, assisted by linear dichroism. Filament structure was investigated via small-angle neutron scattering. There is no simple correlation between filament elongation, DNA binding affinity of RecA, and DNA structure in the RecA complex. There may be multiple conformations of RecA. Both coprotease and strand exchange activities require formation of a rigid and well organized complex. The triphosphate nucleotides which do not activate RecA, destabilize the RecA-DNA complex, indicating that the chemical nature of the nucleotide nucleobase is very important for the stability of RecA-DNA complex. Higher stability of the RecA-DNA complex in the presence of adenosine 5'-O-3-thiotriphosphate or guanosine 5'-O-3-thiotriphosphate than ATP or GTP indicates that contact between the protein and the chemical group at the gamma position of the nucleotide also affects the stability of the RecA-DNA complex. This contact appears also important for the rigid organization of DNA because ADP strongly decreases the rigidity of the complex.

The L2 loop peptide of RecA stiffens and restricts base motions of single-stranded DNA similar to the intact protein

The L2 loop in the RecA protein is the catalytic center for DNA strand exchange. Here we investigate the DNA binding properties of the L2 loop peptide using optical spectroscopy with polarized light. Both fluorescence intensity and anisotropy of an etheno-modified poly(dA) increase upon peptide binding, indicate that the base motions of single-stranded DNA are restricted in the complex. In agreement with this conclusion, the peptide-poly(dT) complex exhibits a significant linear dichroism signal. The peptide is also found to modify the structure of double-stranded DNA, but does not denature it. It is inferred that strand separation may not be required for the formation of a joint molecule.