Interaction of tyrosine 65 of RecA protein with the first and second DNA strands

Structural, thermodynamic, and kinetic basis for the activities of some nucleic acid repair enzymes

X-ray structural analysis provides no quantitative estimate of the relative contribution of specific and nonspecific or strong and weak interactions to the total affinity of enzymes for nucleic acids. We have shown that the interaction between enzymes and long nucleic acids at the molecular level can be successfully analyzed by the method of stepwise increase in ligand complexity (SILC). In the present review we summarize our studies of human uracil DNA glycosylase and apurinic/apyrimidinic endonuclease, E. coli 8-oxoguanine DNA glycosylase and RecA protein using the SILC approach. The relative contribution of structural (X-ray analysis data), thermodynamic, and catalytic factors to the discrimination of specific and nonspecific DNA by these enzymes at the stages of complex formation, the following changes in DNA and enzyme conformations and especially the catalysis of the reactions is discussed.

Conserved Conformation of RecA Protein after Executing the DNA Strand-Exchange Reaction. A Site-Specific Linear Dichroism Structure Study

RecA protein and its eukaryotic homologue Rad51 protein catalyzes the DNA strand exchange, which is a key reaction of homologous recombination. At the initial step of the reaction, RecA proteins form a helical filament on a single-stranded DNA (ssDNA). Binding of double-stranded DNA (dsDNA) to the filament triggers the homology search; as homology is found, the exchange of strands occurs, and the displaced DNA is released. These are the principal steps of genetic recombination; however, despite many years of extensive study of RecA activities, the details of the mechanism are still obscure. A high-resolution structure of the active nucleoprotein filament could provide information to help understand this process. Using a linear dichroism polarized-light spectroscopy technique, in combination with protein engineering (the site-specific linear dichroism method), we have previously studied the arrangement of RecA in complex with ssDNA. In the present study, we have used this approach to search for structural variations of RecA at the atomic level as the DNA in the complex is changed from ssDNA to dsDNA. The structural data of the RecA-dsDNA filament are found to be very similar to the data previously obtained for the RecA-ssDNA complex, indicating that the overall orientation and also the internal structure of RecA in the active filament are not markedly altered when the bound DNA changes from single- to double-stranded. The implications of the structural similarities as well as the significance of some conformational variations observed for a few amino acid residues that may be involved in interactions with DNA are discussed.

Formation of nucleoprotein RecA filament on single-stranded DNA. Analysis by stepwise increase in ligand complexity

RecA protein plays a pivotal role in homologous recombination in Escherichia coli. RecA polymerizes on single-stranded (ss) DNA forming a nucleoprotein filament. Then double-stranded (ds) DNA is bound and searched for segments homologous to the ssDNA. Finally, homologous strands are exchanged, a new DNA duplex is formed, and ssDNA is displaced. We report a quantitative analysis of RecA interactions with ss d(pN)n of various structures and lengths using these oligonucleotides as inhibitors of RecA filamentation on d(pT)20. DNA recognition appears to be mediated by weak interactions between its structural elements and RecA monomers within a filament. Orthophosphate and dNMP are minimal inhibitors of RecA filamentation (I50 = 12-20 mM). An increase in homo-d(pN)2-40 length by one unit improves their affinity for RecA (f factor) approximately twofold through electrostatic contacts of RecA with internucleoside phosphate DNA moieties (f approximately = 1.56) and specific interactions with T or C bases (f approximately = 1.32); interactions with adenine bases are negligible. RecA affinity for d(pN)n containing normal or modified nucleobases depends on the nature of the base, features of the DNA structure. The affinity considerably increases if exocyclic hydrogen bond acceptor moieties are present in the bases. We analyze possible reasons underlying RecA preferences for DNA sequence and length and propose a model for recognition of ssDNA by RecA.

Location of tyrosine 315, a target for phosphorylation by cAbl tyrosine kinase, at the edge of the subunit-subunit interface of the human Rad51 filament

Rad51 is a key element of recombinational DNA repair and its activity is regulated by phosphorylation of the tyrosine residue at position 315 by cAbl kinase. This phosphorylation could be involved in the resistance of cancer cells to chemotherapy. We have investigated the role of this residue by comparing the three-dimensional structures of human Rad51 and its prokaryotic homologue, Escherichia coli RecA. The residue appeared to be on the edge of the subunit-subunit interacting site. The fluorescence intensity of the tryptophan residue inserted at position 315 of human Rad51 in the place of tyrosine was decreased by adding 3 M urea, although the protein was not unfolded as there was no large change in the fluorescence peak position or circular dichroism signal. This change in fluorescence occurred at a lower urea concentration when the protein was diluted, which favours dissociation. These results indicate that the change is related to the dissociation of Rad51 polymer and that residue 315 is close to the subunit-subunit interacting site. ATP and ADP, which affect the filament structure, caused a blue shift in the fluorescence peak. These nucleotides probably altered the subunit-subunit contacts and may thus affect the filament structure. Phosphorylation of this residue could therefore affect the formation and structure of the Rad51 filament. Correct prediction of subunit-subunit interface of Rad51 by simple comparison of structures of Rad51 and RecA supports the idea that Rad51 forms the filament in a similar way as does RecA.

Direct evaluation of a mechanism for activation of the RecA nucleoprotein filament

The RecA protein of Escherichia coli controls the SOS response for DNA damage tolerance and plays a crucial role in recombinational DNA repair. The formation of a RecA.ATP.ssDNA complex initiates all RecA activities, and yet this process is not understood at the molecular level. An analysis of RecA.DNA interactions was performed using both a mutant RecA protein containing a tryptophan (Trp) reporter and oligodeoxyribonucleotides (ODNs) containing a fluorescent guanine analogue, 6-methylisoxanthopterin (6MI). Experiments using fluorescent ODNs allowed structurally distinct nucleoprotein filaments, formed in the absence and presence of ATPgammaS (a slowly hydrolyzed analogue of ATP), to be differentiated directly. Stopped-flow spectrofluorometry, combined with presteady-state kinetic analyses, revealed unexpected differences in the rates of RecA.ODN and RecA.ATPgammaS.ODN complex assembly. This is the first demonstration that such intrinsically fluorescent synthetic DNAs can be used to characterize definitively the real-time assembly and activation of RecA.ssDNA complexes. Surprisingly, the ssDNA binding event is almost 50-fold slower in the presence of the activating ATPgammaS cofactor. Furthermore, a combination of time-dependent emission changes from 6MI and Trp allowed the first direct chemical test of whether an inactive filament can isomerize to the active state. The results revealed that, unlike the hexameric motor proteins, the inactive RecA filament cannot directly convert to the active state upon ATPgammaS binding. These results have implications for understanding how a coincidence of functions--an ATP-communicated signal-like activity and an ATP-driven motorlike activity--are resolved within a single protein molecule.

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.

Arrangement of RecA protein in its active filament determined by polarized-light spectroscopy

Linear dichroism (LD) polarized-light spectroscopy is used to determine the arrangement of RecA in its large filamentous complex with DNA, active in homologous recombination. Angular orientation data for two tryptophan and seven tyrosine residues, deduced from differential LD of wild-type RecA vs. mutants that were engineered to attenuate the UV absorption of selected residues, revealed a rotation by some 40 degrees of the RecA subunits relative to the arrangement in crystal without DNA. In addition, conformational changes are observed for tyrosine residues assigned to be involved in DNA binding and in RecA-RecA contacts, thus potentially related to the global structure of the filament and its biological function. The presented spectroscopic approach, called "Site-Specific Linear Dichroism" (SSLD), may find forceful applications also to other biologically important fibrous complexes not amenable to x-ray crystallographic or NMR structural analysis.

Design and evaluation of a tryptophanless RecA protein with wild type activity

The C-terminal domain of the Escherichia coli RecA protein contains two tryptophan residues whose native fluorescence emission provides an interfering background signal when other fluorophores such as 1,N(6)-ethenoadenine, 2-aminopurine and other tryptophan residues are used to probe the protein's activities. Replacement of the wild type tryptophans with nonfluorescent residues is not trivial because one tryptophan is highly conserved and the C-terminal domain functions in both DNA binding as well as interfilament protein-protein contact. We undertook the task of creating a tryptophanless RecA protein with WT RecA activity by selecting suitable amino acid replacements for Trp290 and Trp308. Mutant proteins were screened in vivo using assays of SOS induction and cell survival following UV irradiation. Based on its activity in these assays, the W290H-W308F W-less RecA was purified for in vitro characterization and functioned like WT RecA in DNA-dependent ATPase and DNA strand exchange assays. Spectrofluorometry indicates that the W290H-W308F RecA protein generates no significant emission when excited with 295-nm light. Based on its ability to function as wild type protein in vivo and in vitro, this dark RecA protein will be useful for future fluorescence experiments.