A model for the abrogation of the SOS response by an SOS protein: a negatively charged helix in DinI mimics DNA in its interaction with RecA.

DinI is a recently described negative regulator of the SOS response in Escherichia coli. Here we show that it physically interacts with RecA and prevents the binding of single-stranded DNA to RecA, which is required for the activation of the latter. DinI also displaces ssDNA from a stable RecA-DNA cofilament, thus eliminating the SOS signal. In addition, DinI inhibits RecA-mediated homologous DNA pairing, but has no effect on actively proceeding strand exchange. Biochemical data, together with the molecular structure, define the C-terminal alpha-helix in DinI as the active site of the protein. In an unusual example of molecular mimicry, a negatively charged surface on this alpha-helix, by imitating single-stranded DNA, interacts with the loop L2 homologous pairing region of RecA and interferes with the activation of RecA.

The homologous pairing domain of RecA also mediates the allosteric regulation of DNA binding and ATP hydrolysis: a remarkable concentration of functional residues.

Switching between the active (ATP and DNA bound) and inactive conformations of the homologous recombination RecA protein is regulated by ATP hydrolysis. First, we use the homologous pairing domain of RecA derived from its mobile loop L2 to show that the interaction of this random coil peptide with the gamma-phosphate of ATP results in a peptide beta-conformation similar to that previously shown to be induced by DNA binding. Next, we show that in the whole RecA protein two residues in this L2 domain, Gln194 and Arg196, are catalytic amino acid residues for ATP hydrolysis and functionally resemble the corresponding residues engaged in GTP hydrolysis by two distinct classes of G proteins. Finally, we show that the role of DNA and high salt in the stimulation of the ATPase of RecA is to stabilize this highly mobile region involved in hydrolysis. This is a role similar to that described for RGSs in the activation of the GTPase of heterotrimeric G proteins. Therefore, (i) a prototypical DNA-dependent ATPase and ATP-stimulated DNA-binding protein, RecA, and eukaryotic signaling proteins share common stereochemical regulatory mechanisms; and (ii) in a remarkable example of parsimony, loop L2 is a molecular switch that controls both ATP promoted DNA binding and pairing reactions and DNA stimulated ATP hydrolysis.

Solution structure of DinI provides insight into its mode of RecA inactivation.

The Escherichia coli RecA protein triggers both DNA repair and mutagenesis in a process known as the SOS response. The 81-residue E. coli protein DinI inhibits activity of RecA in vivo. The solution structure of DinI has been determined by multidimensional triple resonance NMR spectroscopy, using restraints derived from two sets of residual dipolar couplings, obtained in bicelle and phage media, supplemented with J couplings and a moderate number of NOE restraints. DinI has an alpha/beta fold comprised of a three-stranded beta-sheet and two alpha-helices. The beta-sheet topology is unusual: the central strand is flanked by a parallel and an antiparallel strand and the sheet is remarkably flat. The structure of DinI shows that six negatively charged Glu and Asp residues on DinI's kinked C-terminal alpha-helix form an extended, negatively charged ridge. We propose that this ridge mimics the electrostatic character of the DNA phospodiester backbone, thereby enabling DinI to compete with single-stranded DNA for RecA binding. Biochemical data confirm that DinI is able to displace ssDNA from RecA.

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.

Saturation mutagenesis of the E. coli RecA loop L2 homologous DNA pairing region reveals residues essential for recombination and recombinational repair.

The disordered mobile loop L2 of the Escherichia coli RecA protein is known to play a central role in DNA binding and pairing. To investigate the local chemical environment in relation to function we performed saturation mutagenesis of the loop L2 region (amino acid positions 193-212) using a site-directed mutagenesis procedure, and determined the recombinational proficiency of the 380 mutants using genetic assays for homologous recombination and recombinational repair. Residues Asn193, Gln194, Arg196, Glu207, Thr209, Gly211, and Gly212 were identified as stringently required for recombinational events in bacterial cells. In addition, our findings suggest the involvement of loop L2 in the ATPase activity of RecA, and a role for residues Gln194, Arg196, Lys198 and Thr209 in the DNA-dependent hydrolysis of ATP. Finally, since 20 residue peptides that comprise this region can pair homologous DNAs by forming filamentous beta-structures, we propose how the information from the mutant analysis might facilitate the use of a simplified amino acid alphabet to design beta-structure forming L2 peptides with improved RecA-like activities.

Homologous DNA pairing domain peptides of RecA protein: intrinsic propensity to form beta-structures and filaments.

The 20 amino acid residue peptides derived from RecA loop L2 have been shown to be the pairing domain of RecA. The peptides bind to ss- and dsDNA, unstack ssDNA, and pair the ssDNA to its homologous target in a duplex DNA. As shown by circular dichroism, upon binding to DNA the disordered peptides adopt a beta-structure conformation. Here we show that the conformational change of the peptide from random coil to beta-structure is important in binding ss- and dsDNA. The beta-structure in the DNA pairing peptides can be induced by many environmental conditions such as high pH, high concentration, and non-micellar sodium dodecyl sulfate (6 mM). This behavior indicates an intrinsic property of these peptides to form a beta-structure. A beta-structure model for the loop L2 of RecA protein when bound to DNA is thus proposed. The fact that aromatic residues at the central position 203 strongly modulate the peptide binding to DNA and subsequent biochemical activities can be accounted for by the direct effect of the aromatic amino acids on the peptide conformational change. The DNA-pairing domain of RecA visualized by electron microscopy self-assembles into a filamentous structure like RecA. The relevance of such a peptide filamentous structure to the structure of RecA when bound to DNA is discussed.

The duplex DNA is very underwound in the three-stranded RecA protein-mediated synaptic complex.

BACKGROUND: The RecA protein is a central player in bacterial homologous recombination. It promotes two key events: the search for homology between two DNA molecules and the subsequent formation of the synaptic complex composed of RecA and three DNA strands (two from one duplex and one single strand). In spite of numerous studies, the architecture of the synaptic complex is still far from clear. RESULTS: We have exploited two approaches to study the structure of Escherichia coli RecA protein-mediated DNA synapsis: chemical modification with potassium permanganate and treatment of synaptic complexes of different lengths with topoisomerase I. The linking number difference values, obtained after separation of the individual sets of topoisomers in an agarose gel, were used to determine the number of bases per helical turn. We were able to show that the topology of the three-stranded complexes containing RecA is quite different from that expected for deproteinized D-loops. The original duplex in the synaptic complex is unwound, but not necessarily unpaired, to a structure topologically equivalent to DNA with approximately 27 bp per turn. Despite the fact that the patterns of reactivity towards potassium permanganate cannot be interpreted unambiguously, the results of chemical footprinting can be explained in terms of a synaptic complex as an extended and unwound three-stranded helical structure. CONCLUSIONS: This work provides the first quantitative topological parameters for the RecA protein-mediated three-stranded synaptic complex. Furthermore, the structure of synaptic complexes is different from that of a simple D-loop.

Homologous DNA pairing promoted by a 20-amino acid peptide derived from RecA.

The molecular structure of the Escherichia coli RecA protein in the absence of DNA revealed two disordered or mobile loops that were proposed to be DNA binding sites. A short peptide spanning one of these loops was shown to carry out the key reaction mediated by the whole RecA protein: pairing (targeting) of a single-stranded DNA to its homologous site on a duplex DNA. In the course of the reaction the peptide bound to both substrate DNAs, unstacked the single-stranded DNA, and assumed a beta structure. These events probably recapitulate the underlying molecular pathway or mechanism used by homologous recombination proteins.

The identification of the single-stranded DNA-binding domain of the Escherichia coli RecA protein.

To identify the ssDNA-binding domain of Escherichia coli RecA protein, we examined the ssDNA-binding capabilities of synthetic peptides, the sequences of which were derived from the C- and N-termini and from sequences within loops L1 and L2 of the RecA molecule identified from the crystal structure. Synthetic peptides derived from amino acid residues 185-219 of several bacterial RecA proteins, which include loop L2 of RecA, bound to ssDNA in filter-binding assays, whereas three separate synthetic peptides corresponding to single point mutants of E. coli RecA in this region did not. The binding of RecA to ssDNA examined using a gel-shift assay was inhibited by a synthetic peptide derived from this ssDNA-binding region, but not by synthetic peptides derived from amino acid residues 301-329 of the C-terminus or from N-terminal residues 6-39. A peptide corresponding to amino acid positions 152-169 of the RecA molecule and spanning loop L1 and its flanking regions did not bind ssDNA at peptide concentrations up to 250 microM. We have also defined a synthetic 20-amino-acid peptide that comprises amino acid residues 193-212 and includes loop L2 of RecA as the minimum unit that can bind to ssDNA from this region of RecA. Finally, two maltose-binding protein-RecA fusion proteins were made, one containing amino acid residues 185-224 of RecA and the other the last 51 C-terminal residues of RecA (amino acid residues 303-353). In contrast to the C-terminus-derived fusion protein, the fusion protein containing the putative DNA-binding site demonstrated significant binding to single-stranded oligonucleotides in both filter-binding and gel-shift assays. These findings suggest that a portion of the region extending from amino acid residues 193-212 is either part of or the whole ssDNA-binding domain of the RecA protein.

Cation and sequence effects on stability of intermolecular pyrimidine-purine-purine triplex.

A differential effect is found of various bivalent cations (Ba2+, Ca2+, Mg2+, Cd2+, Co2+, Mn2+, Ni2+, Zn2+ and Hg2+) on stability of intermolecular Py-Pu-Pu triplex with different sequence of base triads. Ca2+, Mg2+, Cd2+, Co2+, Mn2+, Ni2+ and Zn2+ do stabilize the d(C)n d(G)n d(G)n triplex whereas Ba2+ and Hg2+ do not. Ba2+, Ca2+, Mg2+ and Hg2+ destabilize the d(TC)n d(GA)n d(AG)n triplex whereas Cd2+, Co2+, Mn2+, Ni2+ and Zn2+ stabilize it. The complexes we observe are rather stable because they do not dissociate during time of gel electrophoresis in the co-migration experiments. Chemical probing experiments with dimethyl sulfate as a probe indicate that an arbitrary homopurine-homopyrimidine sequence forms triplex with corresponding purine oligonucleotide in the presence of Mn2+ or Zn2+, but not Mg2+. In the complex the purine oligonucleotide has antiparallel orientation with respect to the purine strand of the duplex. Specifically, we have shown the formation of the Py-Pu-Pu triplex in a fragment of human papilloma virus HPV-16 in the presence of Mn2+.

Protonated pyrimidine-purine-purine triplex.

We have studied a protonated pyrimidine-purine-purine (Py-Pu-Pu) triplex, which is formed between the d(C)nd(G)n duplex and the d(AG)m oligonucleotide as the third strand and carries the CG*A+ protonated base-triads. We have observed such an intermolecular complex between a plasmid carrying the d(C)18 d(G)18 insert and the d(AG)5 oligonucleotide without bivalent cations in 200 mM of Na+ at pH4.0. Bivalent cations additionally stabilize the complex. We propose the structures for nearly isomorphous base-triads TA*A, CG*G and CG*A+. To identify the H-DNA-like structure, which includes the triplex between d(C)n d(G)n duplex and the AG-strand, we have cloned in a superhelical plasmid the insert: G10TTAA(AG)5. The data on photofootprinting and chemical modification with diethyl pyrocarbonate, potassium permanganate and dimethyl sulfate demonstrate that the H-like structure with triplex carrying CG*G and CG*A+ base triads is actually formed under acid conditions. In the course of this study we have come across unexpected results on probing of Py-Pu-Pu triplexes by dimethyl sulfate (DMS): the protection effect is observed not only for guanines entering the duplex but also for guanines in the third strand lying in the major groove. We have demonstrated this effect not only for the case the novel protonated Py-Pu-Pu triplex but also for the traditional non-protonated Py-Pu-Pu intramolecular triplex (H*-DNA) formed by the d(C)37 d(G)37 insert in supercoiled plasmid in the presence of Mg2+ ions.

An eclectic DNA structure adopted by human telomeric sequence under superhelical stress and low pH.

We have found, with the aid of 2-D gel electrophoresis, that double-stranded human telomeric repeat, (T2AG3)12.(C3TA2)12, being cloned within a plasmid, forms a protonated superhelically-induced structure. Experiments on chemical and enzymatic probing also indicate that the human telomeric repeats adopt an unusual structure. We have proposed an eclectic model for this structure in which four different elements coexist: a non-orthodox intramolecular triplex stabilized by the canonical protonated C.G*C+ base-triads and highly enriched by noncanonical base-triads; the intramolecular quadruplex formed by a portion of the G-rich strand; the single-stranded region encompassing a portion of the G-rich strand and, probably, the (C,A)-hairpin formed by a portion of the C-rich strand.

Photofootprinting of DNA triplexes.

We have used a photofootprinting assay to study intermolecular and intramolecular DNA triplexes. The assay is based on the fact that the DNA duplex is protected against photodamage (specifically, against the formation of the (6-4) pyrimidine photoproducts) within a triplex structure. We have shown that this is the case for PyPuPu (YRR) as well as PyPuPy (YRY) triplexes. Using the photofootprinting assay, we have studied the triplex formation under a variety of experimentally defined conditions. At acid pH, d(C)n.d(G)n.d(C)n and d(CT)n.d(GA)n.d(CT)n triplexes are detected by this method. The d(CT)n.d(GA)n.d(CT)n triplexes are additionally stabilized by divalent cations and spermidine. PyPuPu triplexes are pH-independent and are stabilized by divalent cations, such as Mg++ and Zn++. The effect depends on the type of cation and on the DNA sequence. The d(CT)n.d(GA)n.d(GA)n triplex is stabilized by Zn++, but not by Mg++, whereas the d(C)n.d(G)n.d(G)n triplex is stabilized by Mg++. In H-DNA, virtually the entire pyrimidine chain is protected against photodimerization, whereas only half of the pyrimidine chain participating in a triplex is protected in the CGG intramolecular triplex.

Stabilization of PyPuPu triplexes with bivalent cations.

We studied the formation of stable PyPuPu intermolecular triplexes under neutral pH in the presence of bivalent cations (Mg, Ca, Mn, Co, Ni, Cu, Zn, Cd, and Ba) with the help of the photo- and DMS footprinting assays. The cations which stabilize d(C)n.d(G)n.d(G)n and d(TC)n.d(GA)n.d(AG)n triplexes were determined. Among them, Zn++ ions stabilized both triplexes, whereas Mg++ ions stabilize CGG triplexes, but do not stabilize TC.GA.AG triplexes. We have shown that an arbitrary purine sequence forms the PyPuPu triplex in the presence of Zn++ ions, and that the purine third strand is antiparallel with respect to the purine strand within the duplex.

An unusual DNA structure detected in a telomeric sequence under superhelical stress and at low pH.

Telomeric sequences of DNA, which are found at the ends of linear chromosomes, have been attracting attention as potential sites for the formation of unusual DNA structures. They consist of (GnTm) or (GnATm) motifs (n greater than or equal to m) and, in the single-stranded state, form hairpins stabilized by non-canonical G.G pairs. In the duplex state and under superhelical stress they exhibit hypersensitivity to SI nuclease which by analogy with homopurine-homopyrimidine sequences may reflect the formation of an unusual structure. To determine whether this is the case we have inserted into a plasmid the Tetrahymena telomeric motif (G4T2).(A2C4) and probed it by two-dimensional gel electrophoresis, chemical modification and oligonucleotide binding. Our data demonstrate that, under superhelical stress and at low pH, the insert does indeed adopt a novel DNA conformation. We have concluded that in this structure the C-rich strand forms a hairpin stabilized by non-Watson-Crick base pairs C.C+ and A.A+, whereas the G-rich strand remains unstructured. We term this new DNA structure the (C,A)-hairpin.

Localization of melted regions in supercoiled DNA.

Diethyl pyrocarbonate (DEPC) was used as a probe of local denatured regions in ccDNA pAO3 plasmid. It was found that in native ccDNA molecules only adenosine residues in the loop of the cruciform structure react with DEPC. Denaturation of ccDNA is accompanied by the appearance of two short regions (20 bp long) at both borders of the cruciform structure. Further increase in the denaturation process is associated with considerable expansion of the region located to the left of the cruciform, while the cruciform structure itself and the denatured region located to the right of it disappear.

[Localization of melted regions in supercoiled DNA by means of chemical modification]. / Lokalizatsiia rasplavlennykh uchastkov v sverkhspiral'noi DNK pri pomoshchi khimicheskoi modifikatsii.

Diethyl pyrocarbonate was used as a probe in mapping early melting stages in supercoiled DNA. It was shown that in the process of early melting of pAO3 DNA two denatured regions (about 15 b.p.) arouse near the left and right boundaries of the cruciform structure. In course of further melting denatured regions appeared within AT-rich stretches and the cruciform structure itself disappeared.

Chemical probing of homopurine-homopyrimidine mirror repeats in supercoiled DNA.

We have recently shown that under superhelical stress and/or acid pH the homopurine-homopyrimidine tracts conforming to the mirror symmetry (H palindromes) form a novel DNA structure, the H form. According to our model, the H form includes (1) a triplex formed by half of the purine strand and by the homopyrimidine hairpin and (2) the unstructured other half of the purine strand. We used four specially designed sequences to demonstrate that, in accordance with our model, the mirror symmetry is essential for facile formation of the H form detected by two-dimensional gel electrophoresis. Here we report that, under conditions favouring the H-form extrusion, guanines of the 3' half of the purine strand are protected against alkylation by dimethylsulphate, whereas adenines of the 5' half of the purine strand react with diethyl pyrocarbonate. These data indicate that the 3' half of the homopurine strand is within the triplex whereas the 5' half is unstructured, in full agreement with our model.