The effects of symmetrical recombination site hixC on Hin recombinase function.

An artificial recombination site hixC composed of two identical half-sites that bind the Hin recombinase served as a better operator in vivo than the wild type site hixL (Hughes, K. T., Youderian, P., and Simon, M. I (1988) Genes & Dev. 2, 937-948). In vitro binding assays such as gel retardation assay and methylation protection assay demonstrated that Hin binds to hixC as tightly as it binds to hixL, even when the sites are located in negatively supercoiled plasmids. However, hixC served as a poor recombination site when it was subjected to the standard inversion assay in vitro. hixC showed a 16-fold slower inversion rate than the wild type. A series of biochemical assays designed to probe different stages of the Hin-mediated inversion reaction, demonstrated that Hin dimers bound to hixC have difficulty in forming paired hix site intermediates. KMnO4 and S1 nuclease assays detected an anomalous structure of the center of hixC only when the site was in negatively supercoiled plasmids. Mutational analysis in the central region of hixC and assays of paired hix site formation with topoisomers of the hixC substrate plasmid suggested that Hin is not able to pair hixC sites because of the presence of the anomalous structure in the center of the site. The structure does not behave like a DNA "cruciform" since Hin dimers still bind efficiently to the site. It is thought to consist of a short denatured "bubble" encompassing 2 base pairs. During the study of mutations in the center of hixC, it was found that Hin is not able to cleave DNA if a guanine residue is one of the two central nucleotides close to the cleavage site. Furthermore, Hin acts in a concerted fashion and cannot cleave any DNA strand if one of the four strands in the inversion intermediate is not cleavable.     

Orientation of the putative recognition helix in the DNA-binding domain of Hin recombinase complexed with the hix site

On the basis of sequence similarity with other known DNA-binding proteins, the DNA-binding domain of Hin recombinase, residues 139-190, is thought to bind DNA by a helix-turn-helix motif. Two models can be considered that differ in the orientation of the recognition helix in the major groove of DNA. One is based on the orientation of the recognition helix found in the 434 repressor (1-69) and lambda repressor-DNA cocrystals, and the other is based on the NMR studies of lac repressor headpiece. Cleavage by EDTA.Fe attached to a lysine side chain (Ser183----Lys183) near the COOH terminus of Hin(139-184) reveals that the putative recognition helix is oriented toward the center of the inverted repeats in a manner similar to that seen in the 434 and lambda repressor-DNA cocrystals.     

Sequence-specific interaction of the Salmonella Hin recombinase in both major and minor grooves of DNA.

The Hin recombinase of Salmonella catalyzes a site-specific recombination event which leads to flagellar phase variation. Starting with a fully symmetrical recombination site, hixC, a set of 40 recombination sites which vary by pairs of single base substitutions was constructed. This set was incorporated into the Salmonella-specific bacteriophage P22 based challenge phage selection and used to define the DNA sequence determinants for the binding of Hin to DNA in vivo. The critical sequence-specific contacts between a Hin monomer and a 13 bp hix half-site are at two T:A base pairs in the major groove of the DNA which are separated by one base pair, and two consecutive A:T contacts in the minor groove. The base substitutions in the major groove recognition portion which were defective in binding Hin still retained residual binding capability in vivo, while the base pair substitutions affecting the minor groove recognition region lost all in vivo binding. Using in vitro binding assays, Hin was found to bind to hix symmetrical sites with A:T base pairs or I:C base pairs in the minor groove recognition sequences, but not to G:C base pairs. In separate in vitro binding assays, Hin was equally defective in binding to either a G:C or a I:C contact in a major groove recognition sequence. Results from in vitro binding assays to hix sites in which 3-deazaadenine was substituted for adenine are consistent with Hin making a specific contact to either the N3 of adenine or O2 of thymine in the minor groove within the hix recombination site on each symmetric half-site. These results taken with the results of previous studies on the DNA binding domain of Hin suggest a sequence-specific minor groove DNA binding motif.     

Participation of water in Hin recombinase--DNA recognition.

The participation of water molecules in the interaction between the Hin recombinase and its operator DNA has been detected by analysis of the dissociation constant in the presence of varying concentrations of neutral solutes and cosolvents. The dissociation constant as measured by gel mobility shift assays increased as the concentration of dimethyl sulfoxide, glycerol, sucrose, or polyethylene glycol was increased. Osmotic pressure is the only property that correlates with the change in the dissociation constant for all compounds. This data indicates that binding of a small population of water molecules accompanies formation of the Hin-DNA complex, and points to a novel role for solvent molecules in assisting site specific interaction between DNA-binding proteins and their cognate DNA sequence.     

A model for histone H5-DNA interaction: simultaneous minor and major groove binding.

Using the tertiary structure of the globular domain of H5 (GH5) and based on an alternative sequence homology between GH5 and DNA-binding proteins containing the helix-turn-helix motif, a model for H5-DNA interaction is proposed. From molecular graphics it follows that helix II recognizes the major groove of the DNA, as does the second helix of the helix-turn-helix motif, while helix III makes minor groove contacts, in agreement with the hypothesis of Turnell et al. (FEBS letters 232, 263-268). In the resulting model GH5 makes contact with a full turn of DNA.     

Synthesis of nonlinear DNA-binding peptide with binding specificity determinants close to those of 434 Cro-repressor

Design, synthesis and DNA binding activity of a nonlinear 102 residue peptide are reported. The peptide contains four sequence-specific DNA binding domains of 434 Cro protein. These four domains were linked covalently to a symmetrical carboxyterminal crosslinker that contains four arms each ending with an aliphatic aminogroup. From CD studies we have found that in aqueous buffer in the presence of 20% trifluoroethanol the peptide residues assume alpha helical, beta-sheet and random coiled conformations with an alpha helical content of about 16% at room temperature. The alpha helicity is increased up to 40% in the presence of 40% trifluoroethanol. Upon complex formation between the peptide and DNA a change in the peptide conformation takes place which is consistent with an alpha-beta transition in the DNA binding, helix-turn-helix motif of 434 Cro repressor. Evidently residues present in helices alpha(2) and alpha(3) form a beta hairpin which is inserted in the minor DNA groove. The latter inference is supported by our observations that the peptide can displace minor groove binding antibiotic distamycin A from a complex with poly(dA).poly(dT). As revealed from DNase protection studies the peptide exhibits preferences for binding to operator and pseudooperator sites recognized by 434 Cro repressor. It binds strongly to operator sites OR1, OR2 and OR3 and exhibits a greater affinity for pseudooperator site Op1. From analysis of nucleotide sequences in the strong affinity binding sites for the peptide on DNA a conclusion is drawn that it binds to pseudosymmetrical nucleotide sequences 5'-ACAA(W)nCTGT-3', where W is an arbitrary nucleotide. n is equal to six or seven. In the strongest affinity binding site for the peptide on DNA (Op1) motif 5'-ACAA-3' is replaced by sequence 5'-ACCA-3'. A difference in binding specificity shown by the peptide and 434 Cro protein could be attributed to a flexibility of the connecting chains between DNA-binding domains in the peptide molecule as well as to a replacement of Thr - Ala in the alpha 2 helix. Removal of two residues from the N-terminal end of helix alpha 2 in each of the four DNA binding domains of 434 Cro present in the peptide leads to a loss of binding specificity, although the modified peptide binds to DNA unspecifically.     

Sequence-specific oxidative cleavage of DNA by a designed metalloprotein, Ni(II).GGH(Hin139-190).

A 55-residue protein containing the DNA binding domain of Hin recombinase, residues 139-190, with the tripeptide Gly-Gly-His (GGH) at the NH2 terminus was synthesized by stepwise solid-phase methods. GGH(Hin139-190) binds sequence specifically to DNA at four 13 base pair sites (termed hixL and secondary) and, in the presence of Ni(OAc)2 and monoperoxyphthalic acid, reacts predominantly at a single deoxyribose position on one strand of each binding site [Mack, D.P., & Dervan, P.B. (1990) J. Am. Chem. Soc. 112, 4604]. We find that, upon treatment with n-butylamine, the DNA termini at the cleavage site are 3'- and 5'-phosphate, consistent with oxidative degradation of the deoxyribose backbone. The nickel-mediated oxidation can be activated with peracid, iodosylbenzene, or hydrogen peroxide. The sequence specificity of the reaction is not dependent on oxidant, but the rates of cleavage differ, decreasing in the order peracid greater than iodosylbenzene greater than hydrogen peroxide. Optimal cleavage conditions for a 1 microM concentration of protein are 50 microM peracid, pH 8.0, and 1 equiv of Ni(OAc)2. The preferential cleavage at a single base pair position on one strand of the minor groove indicates a nondiffusible oxidizing species. A change of absolute configuration in the GGH metal binding domain from L-His to D-His [Ni(II).GG-(-D-)H(Hin139-190)] affords cleavage at similar base pair locations but opposite with regard to strand specificity.     

Protein--DNA contacts in the structure of a homeodomain--DNA complex determined by nuclear magnetic resonance spectroscopy in solution.

The 1:1 complex of the mutant Antp(C39----S) homeodomain with a 14 bp DNA fragment corresponding to the BS2 binding site was studied by nuclear magnetic resonance (NMR) spectroscopy in aqueous solution. The complex has a molecular weight of 17,800 and its lifetime is long compared with the NMR chemical shift time scale. Investigations of the three-dimensional structure were based on the use of the fully 15N-labelled protein, two-dimensional homonuclear proton NOESY with 15N(omega 2) half-filter, and heteronuclear three-dimensional NMR experiments. Based on nearly complete sequence-specific resonance assignments, both the protein and the DNA were found to have similar conformations in the free form and in the complex. A sufficient number of intermolecular 1H-1H Overhauser effects (NOE) could be identified to enable a unique docking of the protein on the DNA, which was achieved with the use of an ellipsoid algorithm. In the complex there are intermolecular NOEs between the elongated second helix in the helix-turn-helix motif of the homeodomain and the major groove of the DNA. Additional NOE contacts with the DNA involve the polypeptide loop immediately preceding the helix-turn-helix segment, and Arg5. This latter contact is of special interest, both because Arg5 reaches into the minor groove and because in the free Antp(C39----S) homeodomain no defined spatial structure could be found for the apparently flexible N-terminal segment comprising residues 0-6.     

Effects of dimer interface mutations in Hin recombinase on DNA binding and recombination

Previous biochemical assays and a structural model of the protein have indicated that the dimer interface of the Hin recombinase is composed of two alpha-helices. To elucidate the structure and function of the helix, amino acids at the N-terminal end of the helix, where the two helices make their most extensive contact, were randomized, and inversion-incompetent mutants were selected. To investigate why the mutants lost their inversion activities, the DNA binding, hix pairing, invertasome formation, and DNA cleavage activities were assayed using in vivo and in vitro methodologies. The results indicated that the mutants could be divided into four classes based on their DNA binding activity. We propose that the alpha-helices might serve to place a DNA binding motif of Hin in the correct spatial relationship to the minor groove of the recombination site. All the mutants except those that failed to bind DNA were able to perform hix pairing and invertasome formation, suggesting that the dimer interface is not involved in either of these processes. The inversion-incompetent phenotype of the binders was caused by the inability of mutants to perform DNA cleavage. The mutants that showed less binding ability than the wild type nevertheless exhibited a wild-type level of hix pairing activity, because the hix pairing activity overcomes the defect in DNA binding. This phenotype of the mutants that are impaired in DNA binding suggests that the binding domains of Hin may mediate Hin-Hin interaction during hix pairing.     

Structure of Bacterial Transcription Factor SpoIIID and Evidence for a Novel Mode of DNA Binding

SpoIIID is evolutionarily conserved in endospore-forming bacteria, and it activates or represses many genes during sporulation of Bacillus subtilis. An SpoIIID monomer binds DNA with high affinity and moderate sequence specificity. In addition to a predicted helix-turn-helix motif, SpoIIID has a C-terminal basic region that contributes to DNA binding. The nuclear magnetic resonance (NMR) solution structure of SpoIIID in complex with DNA revealed that SpoIIID does indeed have a helix-turn-helix domain and that it has a novel C-terminal helical extension. Residues in both of these regions interact with DNA, based on the NMR data and on the effects on DNA binding in vitro of SpoIIID with single-alanine substitutions. These data, as well as sequence conservation in SpoIIID binding sites, were used for information-driven docking to model the SpoIIID-DNA complex. The modeling resulted in a single cluster of models in which the recognition helix of the helix-turn-helix domain interacts with the major groove of DNA, as expected. Interestingly, the C-terminal extension, which includes two helices connected by a kink, interacts with the adjacent minor groove of DNA in the models. This predicted novel mode of binding is proposed to explain how a monomer of SpoIIID achieves high-affinity DNA binding. Since SpoIIID is conserved only in endospore-forming bacteria, which include important pathogenic Bacilli and Clostridia, whose ability to sporulate contributes to their environmental persistence, the interaction of the C-terminal extension of SpoIIID with DNA is a potential target for development of sporulation inhibitors.     

Proposed structure for the DNA-binding domain of the Myb oncoprotein based on model building and mutational analysis

Myb-related proteins from plants to humans are characterized by a DNA-binding domain which contains two to three imperfect repeats of approximately 50 amino acids each. Based on the evolutionary conservation of specific residues, secondary structural predictions suggest an arrangement of alpha helices homologous to that seen in the homeodomains, members of the helix-turn-helix family of DNA-binding proteins. We have used molecular modelling in conjunction with site-directed mutagenesis to test the feasibility of this structure. We propose that each Myb repeat consists of three alpha helices packed over a hydrophobic core which is built around the three highly conserved tryptophan residues. The C-terminal helix forms part of the helix-turn-helix motif and can be positioned into the major groove of B-form DNA, allowing prediction of residues critical for specificity of interaction. Modelling also allowed positioning of adjacent repeats around the major groove over an 8 bp binding site.     

Design and synthesis of peptides capable of specific binding to DNA

In the present communication, design, synthesis and DNA binding activities of the following two peptides are reported: Dns-Gly-Ala-Gln-Lys-Leu-Ala-Cly-Lys-Val-Gly-Thr-Lys-Val-Lys-Val-Gl y-Thr-Lys-Thr - Val-OH (I) and [(H-Ala-Lys-Leu-Ala-Thr-Lys-Ala-Gly-Val-Lys-Gln-Gln-Ser-Ile-Gln-Leu-Ile- Thr- Ala-Aca-Lys-Aca)2Lys-Aca]2Lys-Val-OH (II), where Aca = NH(CH2)5CO--; Dns is a residue of 5-dimethylaminonaphtalene-1-sulfonic acid. Peptide I contains a large fraction (ca.30%) of valyl and threonyl residues, which possess a high potential for beta structure formation. Peptide II contains four repeats of the amino acid sequence present in the presumed DNA binding helix-turn-helix unit of 434 Cro repressor. These four domains are linked in such a way that two domains can interact with two halves a 14 base pair long operator site on DNA. From CD studies we have found that peptide I is in a random coil conformation in the aqueous solution in the presence of 20% trifluoroethanol. By contrast, amino acid residues of peptide II assume alpha helical, beta and random coiled conformations under the same conditions. A change in the secondary structure of the two peptides upon binding to DNA is observed. The difference CD spectra obtained by subtracting the spectra of free DNA from the spectra of peptide I--DNA complexes gives rise to a beta-like pattern. The difference CD spectra obtained for complexes of peptide II with various natural and synthetic DNAs suggest that alpha-beta-transition takes place in the presumed helix-turn-helix repeat units of peptide II upon binding to DNA. Peptide I binds more strongly to poly(dG).poly(dC) than to poly(dA).poly(dT) and poly[d(GC)].poly[d(GC)]. The binding takes place in the minor DNA groove because minor groove binding antibiotic sibiromycin can displace peptide I from a complex with poly(dG).poly(dC). Analysis of footprinting diagramms shows that peptide I specifically protects phosphodiester bonds within operator sites OR1 and OR2 of phage lambda from nuclease cleavage. By contrast, peptide II does not react specifically with operators OR1, OR2 and OR3 of phage 434 although it forms very tight complexes with DNA which are stable in the presence of 1M NH4F.     

Thermodynamics of specific and nonspecific DNA binding by two DNA-binding domains conjugated to fluorescent probes

The complexes designed in this work combine the sequence-specific binding properties of helix-turn-helix DNA-binding motifs with intercalating cyanine dyes. Thermodynamics of the Hin recombinase and Tc3 transposase DNA-binding domains with and without the conjugated dyes were studied by fluorescence techniques to determine the contributions to specific and nonspecific binding in terms of the polyelectrolyte and hydrophobic effects. The roles of the electrostatic interactions in binding to the cognate and noncognate sequences indicate that nonspecific binding is more sensitive to changes in salt concentration, whereas the change in the heat capacity shows a greater sensitivity to temperature for the sequence-specific complexes in each case. The conjugated dyes affect the Hin DNA-binding domain by acting to anchor a short stretch of amino acids at the N-terminal end into the minor groove. In contrast, the N-terminal end of the Tc3 DNA-binding domain is bound in a well-ordered fashion to the DNA even in the absence of the conjugated dye. The conjugated dye and the DNA-binding domain portions of each conjugate bind noncooperatively to the DNA. The characteristic thermodynamic parameters of specific and nonspecific DNA binding by each of the DNA-binding domains and their respective conjugates are presented.     

Sequence-specific DNA binding determined by contacts outside the helix-turn-helix motif of the ParB homolog KorB

The KorB protein of the broad-host-range plasmid RP4 acts as a multifunctional regulator of plasmid housekeeping genes, including those responsible for replication, maintenance and conjugation. Additionally, KorB functions as the ParB analog of the plasmid's partitioning system. The protein structure consists of eight helices, two of which belong to a predicted helix-turn-helix motif. Each half-site of the palindromic operator DNA binds one copy of the protein in the major groove. As confirmed by mutagenesis, recognition specificity is based mainly on two side chain interactions outside the helix-turn-helix motif with two bases next to the central base pair of the 13-base pair operator sequence. The surface of the KorB DNA-binding domain mirrors the overall acidity of KorB, whereas DNA binding occurs via a basic interaction surface. We present a model of KorB, including the structure of its dimerization domain, and discuss its interactions with the highly basic ParA homolog IncC.     

Crystal structure of the specific DNA-binding domain of Tc3 transposase of C.elegans in complex with transposon DNA.

The crystal structure of the complex between the N-terminal DNA-binding domain of Tc3 transposase and an oligomer of transposon DNA has been determined. The specific DNA-binding domain contains three alpha-helices, of which two form a helix-turn-helix (HTH) motif. The recognition of transposon DNA by the transposase is mediated through base-specific contacts and complementarity between protein and sequence-dependent deformations of the DNA. The HTH motif makes four base-specific contacts with the major groove, and the N-terminus makes three base-specific contacts with the minor groove. The DNA oligomer adopts a non-linear B-DNA conformation, made possible by a stretch of seven G:C base pairs at one end and a TATA sequence towards the other end. Extensive contacts (seven salt bridges and 16 hydrogen bonds) of the protein with the DNA backbone allow the protein to probe and recognize the sequence-dependent DNA deformation. The DNA-binding domain forms a dimer in the crystals. Each monomer binds a separate transposon end, implying that the dimer plays a role in synapsis, necessary for the simultaneous cleavage of both transposon termini.     

Orientation of the Lac repressor DNA binding domain in complex with the left lac operator half site characterized by affinity cleaving.

Lac repressor (LacR) is a helix-turn-helix motif sequence-specific DNA binding protein. Based on proton NMR spectroscopic investigations, Kaptein and co-workers have proposed that the helix-turn-helix motif of LacR binds to DNA in an orientation opposite to that of the helix-turn-helix motifs of lambda repressor, lambda cro, 434 repressor, 434 cro, and CAP [Boelens, R., Scheek, R., van Boom, J. and Kaptein, R., J. Mol. Biol. 193, 1987, 213-216]. In the present work, we have determined the orientation of the helix-turn-helix motif of LacR in the LacR-DNA complex by the affinity cleaving method. The DNA cleaving moiety EDTA.Fe was attached to the N-terminus of a 56-residue synthetic protein corresponding to the DNA binding domain of LacR. We have formed the complex between the modified protein and the left DNA half site for LacR. The locations of the resulting DNA cleavage positions relative to the left DNA half site provide strong support for the proposal of Kaptein and co-workers.     

Incorporation of an EDTA-metal complex at a rationally selected site within a protein: application to EDTA-iron DNA affinity cleaving with catabolite gene activator protein (CAP) and Cro.

We have developed a simple procedure to incorporate an EDTA-metal complex at a rationally selected site within a full-length protein. Our procedure has two steps: In step 1, we use site-directed mutagenesis to introduce a unique solvent-accessible cysteine residue at the site of interest. In step 2, we derivatize the resulting protein with S-(2-pyridylthio)cysteaminyl-EDTA-metal, a novel aromatic disulfide derivative of EDTA-metal. We have used this procedure to incorporate an EDTA-iron complex at amino acid 2 of the helix-turn-helix motif of each of two helix-turn-helix motif sequence-specific DNA binding proteins, catabolite gene activator protein (CAP) and Cro, and we have analyzed EDTA-iron-mediated DNA affinity cleavage by the resulting protein derivatives. The CAP derivative cleaves DNA at base pair 2 of the DNA half-site in the protein-DNA complex, and the Cro derivative cleaves DNA at base pairs -3 to 5 of the DNA half-site in the protein-DNA complex. We infer that amino acid 2 of the helix-turn-helix motif of CAP is close to base pair 2 of the DNA half-site in the CAP-DNA complex in solution and that amino acid 2 of the helix-turn-helix motif of Cro is close to base pairs -3 to 5 of the DNA half-site in the Cro-DNA complex in solution.(ABSTRACT TRUNCATED AT 250 WORDS)     

Importance of minor-groove contacts for recognition of DNA by the binding domain of Hin recombinase

Incorporation of the DNA-cleaving moiety EDTA.Fe at discrete amino acid residues along a DNA-binding protein allows the positions of these residues relative to DNA bases, and hence the organization of the folded protein, to be mapped by high-resolution gel electrophoresis. A 52-residue protein, based on the sequence-specific DNA-binding domain of Hin recombinase (139-190), with EDTA at the NH2 terminus cleaves DNA at Hin recombination sites. The cleavage data for EDTA-Hin(139-190) reveal that the NH2 terminus of Hin(139-190) is bound in the minor groove of DNA near the symmetry axis of Hin-binding sites [Sluka, J. P., Horvath, S. J., Bruist, M. F., Simon, M. I., & Dervan, P. B. (1987) Science 238, 1129]. Six proteins, varying in length from 49 to 60 residues and corresponding to the DNA-binding domain of Hin recombinase, were synthesized by solid-phase methods: Hin(142-190), Hin(141-190), Hin(140-190), Hin(139-190), Hin(135-190), and Hin(131-190) were prepared with and without EDTA at the NH2 termini in order to test the relative importance of the residues Gly139-Arg140-Pro141-Arg142, located near the minor groove, for sequence-specific recognition at five imperfectly conserved 12-base-pair binding sites. Footprinting and affinity cleaving reveal that deletion of Gly139 results in a protein with affinity and specificity similar to those of Hin(139-190) but that deletion of Gly139-Arg140 affords a protein with altered affinities and sequence specificities for the five binding sites. It appears that Arg140 in the DNA-binding domain of Hin is important for recognition of the 5'-AAA-3' sequence in the minor groove of DNA. Our results indicate modular DNA and protein interactions with two adjacent DNA sites (major and minor grooves, respectively) bound on the same face of the helix by two separate parts of the protein.