DNA sequence determinant for Flp-induced DNA bending

The Flp site-specific recombinase from Saccharomyces cerevisiae induces DNA bending upon interaction with the Flp recognition target (FRT) site. The minimal FRT site comprises the inverted a and b binding elements, which flank a central 8 bp core region. The DNA bend in a complex of two Flp monomers bound to the FRT site is located in the middle of the core region. When the central AT basepair was replaced with a CG, the DNA bend was positioned at the outside end of the core region adjacent to the a binding element. The other basepairs surrounding the central AT basepair were not important to the position of Flp-induced bends. The change also decreased Flp-mediated cleavage of the top strand of the FRT site and increased Flp-mediated cleavage of the bottom strand. The overall recombination proficiency of the site was impaired. We conclude that the central AT basepair provides a point of flexure in the FRT site, which Flp uses to position the bend in dimeric Flp–DNA complexes, and that the structure of the core DNA influences the functionality of the site.     

Lock and key binding of the HOX YPWM peptide to the PBX homeodomain

HOX homeodomain proteins bind short core DNA sequences to control very specific developmental processes. DNA binding affinity and sequence selectivity are increased by the formation of cooperative complexes with the PBX homeodomain protein. A conserved YPWM motif in the HOX protein is necessary for cooperative binding with PBX. We have determined the structure of a PBX homeodomain bound to a 14-mer DNA duplex. A relaxation-optimized procedure was developed to measure DNA residual dipolar couplings at natural abundance in the 20-kDa binary complex. When the PBX homeodomain binds to DNA, a fourth alpha-helix is formed in the homeodomain. This helix rigidifies the DNA recognition helix of PBX and forms a hydrophobic binding site for the HOX YPWM peptide. The HOX peptide itself shows some structure in solution and suggests that the interaction between PBX and HOX is an example of "lock and key" binding. The NMR structure explains the requirement of DNA for the PBX-HOX interaction and the increased affinity of DNA binding.     

Contacts between 5 S DNA and Xenopus TFIIIA identified using 5-azido-2'-deoxyuridine-substituted DNA

A highly photosensitive analogue of thymidine, 5-azidodeoxyuridine 5'-triphosphate, has been incorporated into 61-base pair (bp) DNA fragments corresponding to the central region of Xenopus somatic-type 5 S RNA genes such that 5-azidodeoxyuridine replaces some or all T residues in either the coding or noncoding strand of the TFIIIA binding site. Photolysis of TFIIIA.DNA complexes formed with these probes results in efficient, sequence-specific cross-linking to the Zn-finger protein providing direct evidence that this class of proteins have contacts in the major groove of their target sequence. Of the 20 T residues present in the 61-bp probes, greater than 90% of the cross-linking occurs from two sites in the 5 S RNA gene corresponding to T residues at positions 84 and 88 in the noncoding and coding strands, respectively. Digestion by V8 protease of the complex formed with the noncoding strand probe releases peptides not bound to the DNA. Amino acid sequence analysis of the remaining, cross-linked peptides indicates the region including zinc-finger 2 plus the finger 2-3 linker is in contact with position 84. The linker region between fingers 5 and 6 is also in close proximity to the major groove somewhere upstream from position 84.     

Crystal structures of I-SceI complexed to nicked DNA substrates: snapshots of intermediates along the DNA cleavage reaction pathway

I-SceI is a homing endonuclease that specifically cleaves an 18-bp double-stranded DNA. I-SceI exhibits a strong preference for cleaving the bottom strand DNA. The published structure of I-SceI bound to an uncleaved DNA substrate provided a mechanism for bottom strand cleavage but not for top strand cleavage. To more fully elucidate the I-SceI catalytic mechanism, we determined the X-ray structures of I-SceI in complex with DNA substrates that are nicked in either the top or bottom strands. The structures resemble intermediates along the DNA cleavage reaction. In a structure containing a nick in the top strand, the spatial arrangement of metal ions is similar to that observed in the structure that contains uncleaved DNA, suggesting that cleavage of the bottom strand occurs by a common mechanism regardless of whether this strand is cleaved first or second. In the structure containing a nick in the bottom strand, a new metal binding site is present in the active site that cleaves the top strand. This new metal and a candidate nucleophilic water molecule are correctly positioned to cleave the top strand following bottom strand cleavage, providing a plausible mechanism for top strand cleavage.     

Solution structure of the K50 class homeodomain PITX2 bound to DNA and implications for mutations that cause Rieger syndrome

We have determined the solution structure of a complex containing the K50 class homeodomain Pituitary homeobox protein 2 (PITX2) bound to its consensus DNA site (TAATCC). Previous studies have suggested that residue 50 is an important determinant of differential DNA-binding specificity among homeodomains. Although structures of several homeodomain-DNA complexes have been determined, this is the first structure of a native K50 class homeodomain. The only K50 homeodomain structure determined previously is an X-ray crystal structure of an altered specificity mutant, Engrailed Q50K (EnQ50K). Analysis of the NMR structure of the PITX2 homeodomain indicates that the lysine at position 50 makes contacts with two guanines on the antisense strand of the DNA, adjacent to the TAAT core DNA sequence, consistent with the structure of EnQ50K. Our evidence suggests that this side chain may make fluctuating interactions with the DNA, which is complementary to the crystal data for EnQ50K. There are differences in the tertiary structure between the native K50 structure and that of EnQ50K, which may explain differences in affinity and specificity between these proteins. Mutations in the human PITX2 gene are responsible for Rieger syndrome, an autosomal dominant disorder. Analysis of the residues mutated in Rieger syndrome indicates that many of these residues are involved in DNA binding, while others are involved in formation of the hydrophobic core of the protein. Overall, the role of K50 in homeodomain recognition is further clarified, and the results indicate that native K50 homeodomains may exhibit differences from altered specificity mutants.     

Conformational changes in the PBX homeodomain and C-terminal extension upon binding DNA and HOX-derived YPWM peptides

PBX is a member of the three amino acid loop extension (TALE) class of homeodomains. PBX binds DNA cooperatively with HOX homeodomain proteins that contain a conserved YPWM motif. The amino acids immediately C-terminal to the PBX homeodomain increase the affinity of the homeodomain for its DNA site and HOX proteins. We have determined the structure of the free PBX homeodomain using NMR spectroscopy. Both the PBX homeodomain and the extended PBX homeodomain make identical contacts with a 5'-TGAT-3' DNA site and a YPWM peptide. A fourth alpha-helix, which forms upon binding to DNA, stabilizes the extended PBX structure. Variations in DNA sequence selectivity of heterodimeric PBX-HOX complexes depend on the HOX partner; however, a comparison of five different HOX-derived YPWM peptides showed that each bound to PBX in the same way, differing only in the strength of the association.     

DNA strand arrangement within the SfiI-DNA complex: atomic force microscopy analysis

The SfiI restriction enzyme binds to DNA as a tetramer holding two usually distant DNA recognition sites together before cleavage of the four DNA strands. To elucidate structural properties of the SfiI-DNA complex, atomic force microscopy (AFM) imaging of the complexes under noncleaving conditions (Ca2+ instead of Mg2+ in the reaction buffer) was performed. Intramolecular complexes formed by protein interaction between two binding sites in one DNA molecule (cis interaction) as well as complexes formed by the interaction of two sites in different molecules (trans interaction) were analyzed. Complexes were identified unambiguously by the presence of a tall spherical blob at the DNA intersections. To characterize the path of DNA within the complex, the angles between the DNA helices in the proximity of the complex were systematically analyzed. All the data show clear-cut bimodal distributions centered around peak values corresponding to 60 degrees and 120 degrees. To unambiguously distinguish between the crossed and bent models for the DNA orientation within the complex, DNA molecules with different arm lengths flanking the SfiI binding site were designed. The analysis of the AFM images for complexes of this type led to the conclusion that the DNA recognition sites within the complex are crossed. The angles of 60 degrees or 120 degrees between the DNA helices correspond to a complex in which one of the helices is flipped with respect to the orientation of the other. Complexes formed by five different recognition sequences (5'-GGCCNNNNNGGCC-3'), with different central base pairs, were also analyzed. Our results showed that complexes containing the two possible orientations of the helices were formed almost equally. This suggests no preferential orientation of the DNA cognate site within the complex, suggesting that the central part of the DNA binding site does not form strong sequence specific contacts with the protein.     

Characterization of the DNA binding activity of stable RecA-DNA complexes. Interaction between the two DNA binding sites within RecA helical filaments

The DNA-binding, annealing and recombinational activities of purified RecA-DNA complexes stabilized by ATP gamma S (a slowly hydrolysable analog of ATP) are described. Electrophoretic analysis, DNase protection experiments and observations by electron microscopy suggest that saturated RecA complexes formed with single- or double-stranded DNA are able to accommodate an additional single strand of DNA with a stoichiometry of about one nucleotide of added single-stranded DNA per nucleotide or base-pair, respectively, of DNA resident in the complex. This strand uptake is independent of complementarity or homology between the added and resident DNA molecules. In the complex, the incoming and resident single-stranded DNA molecules are in close proximity as the two strands can anneal in case of their complementarity. Stable RecA complexes formed with single-stranded DNA bind double-stranded DNA efficiently when the added DNA is homologous to the complexed strand and then initiate a strand exchange reaction between the partner DNA molecules. Electron microscopy of the RecA-single-stranded DNA complexes associated with homologous double-stranded DNA suggests that a portion of duplex DNA is taken into the complex and placed in register with the resident single strand. Our experiments indicate that both DNA binding sites within RecA helical filaments can be occupied by either single- or double-stranded DNA. Presumably, the same first DNA binding site is used by RecA during its polymerization on single- or double-stranded DNA and the second DNA binding site becomes available for subsequent interaction of the protein-saturated complexes with naked DNA. The way by which additional DNA is taken into RecA-DNA complexes shows co-operative character and this helps to explain how topological problems are avoided during RecA-mediated homologous recombination.     

Role of DNA conformation & energetic insights in Msx-1-DNA recognition as revealed by molecular dynamics studies on specific and nonspecific complexes

In most of homeodomain–DNA complexes, glutamine or lysine is present at 50th position and interacts with 5th and 6th nucleotide of core recognition region. Molecular dynamics simulations of Msx-1–DNA complex (Q50-TG) and its variant complexes, that is specific (Q50K-CC), nonspecific (Q50-CC) having mutation in DNA and (Q50K-TG) in protein, have been carried out. Analysis of protein–DNA interactions and structure of DNA in specific and nonspecific complexes show that amino acid residues use sequence-dependent shape of DNA to interact. The binding free energies of all four complexes were analysed to define role of amino acid residue at 50th position in terms of binding strength considering the variation in DNA on stability of protein–DNA complexes. The order of stability of protein–DNA complexes shows that specific complexes are more stable than nonspecific ones. Decomposition analysis shows that N-terminal amino acid residues have been found to contribute maximally in binding free energy of protein–DNA complexes. Among specific protein–DNA complexes, K50 contributes more as compared to Q50 towards binding free energy in respective complexes. The sequence dependence of local conformation of DNA enables Q50/Q50K to make hydrogen bond with nucleotide(s) of DNA. The changes in amino acid sequence of protein are accommodated and stabilized around TAAT core region of DNA having variation in nucleotides.     

The Athb-1 and -2 HD-Zip domains homodimerize forming complexes of different DNA binding specificities.

The Arabidopsis Athb-1 and -2 proteins are characterized by the presence of a homeodomain (HD) with a closely linked leucine zipper motif (Zip). We have suggested that the HD-Zip motif could, via dimerization of the leucine zippers, recognize dyad-symmetric DNA sequences. Here we report an analysis of the DNA binding properties of the Athb-1 homeodomain-leucine zipper (HD-Zip-1) domain in vitro. DNA binding analysis performed using random-sequence DNA templates showed that the HD-Zip-1 domain, but not the Athb-1 HD alone, binds to DNA. The HD-Zip-1 domain recognizes a 9 bp dyad-symmetric sequence [CAAT(A/T)ATTG], as determined by selecting high-affinity binding sites from random-sequence DNA. Gel retardation assays demonstrated that the HD-Zip-1 domain binds to DNA as a dimer. Moreover, the analysis of the DNA binding activity of Athb-1 derivatives indicated that a correct spatial relationship between the HD and the Zip is essential for DNA binding. Finally, we determined that the Athb-2 HD-Zip domain recognizes a distinct 9 bp dyad-symmetric sequence [CAAT(G/C)ATTG]. A model of DNA binding by the HD-Zip proteins is proposed.     

Integron integrase binds to bulged hairpin DNA

Gene cassettes are short, monogenic DNA elements that translocate between integrons through site-specific excision and integration. These events require that an integron-coded tyrosine recombinase forms a reactive complex with two sites, at least one of which belongs to the attC class. An attC site can be divided into two pairs of short repeats flanking a palindromic central region. The nucleotide sequence of attC among different cassettes varies extensively, implying that the site contains a structural recognition determinant with low sequence constraints. Oligonucleotides representing many different sequence modifications in either strand of the site were examined for integrase binding by using an electrophoresis mobility shift assay. The inner repeats, a central triplet and two single-nucleotide asymmetries in the site had the strongest influence on binding strength and strand choice. Our data show that the recombinase binds to a bulged hairpin in attC and that the hairpin distortion due to bulging could define the appropriate orientation of the otherwise symmetrical site. This is consistent with the strong bias for binding of recombinase to the bottom-strand oligonucleotides in vitro. Moreover, it was observed that the mobility-shifted complexes persisted under protein-denaturing assay conditions, indicating that a covalent link is indeed formed between integrase and DNA. Upon substitution of the presumed DNA-attacking residue, Y312, with a phenylalanine, DNA binding remained but there was no covalent linkage.     

Targeting individual subunits of the FokI restriction endonuclease to specific DNA strands

Many restriction endonucleases are dimers that act symmetrically at palindromic DNA sequences, with each active site cutting one strand. In contrast, FokI acts asymmetrically at a non-palindromic sequence, cutting ‘top’ and ‘bottom’ strands 9 and 13 nucleotides downstream of the site. FokI is a monomeric protein with one active site and a single monomer covers the entire recognition sequence. To cut both strands, the monomer at the site recruits a second monomer from solution, but it is not yet known which DNA strand is cut by the monomer bound to the site and which by the recruited monomer. In this work, mutants of FokI were used to show that the monomer bound to the site made the distal cut in the bottom strand, whilst the recruited monomer made in parallel the proximal cut in the top strand. Procedures were also established to direct FokI activity, either preferentially to the bottom strand or exclusively to the top strand. The latter extends the range of enzymes for nicking specified strands at specific sequences, and may facilitate further applications of FokI in gene targeting.     

Chemical probe and missing nucleoside analysis of Flp recombinase bound to the recombination target sequence.

The Flp protein catalyzes a site-specific recombination reaction between two 47 bp DNA sites without the assistance of any other protein or cofactor. The Flp recognition target (FRT) site consists of three nearly identical sequences, two of which are separated by an 8 bp spacer sequence. In order to gain insight into this remarkable protein-DNA interaction we used a variety of chemical probe methods and the missing nucleoside experiment to examine Flp binding. Hydroxyl radical footprints of Flp bound to a recombinationally-competent site fall on opposite faces of canonical B-DNA. The 8 bp spacer region between the two Flp binding sites becomes reactive towards 5-phenyl-1,10-phenanthroline.copper upon Flp binding, indicating that once bound by Flp, this segment of DNA is not in the B-form. Missing nucleoside analysis reveals that within each binding site the presence of two nucleosides on the top strand and four on the bottom, are required for formation of a fully-occupied FRT site. In contrast, loss of any nucleoside in the three binding sites in the FRT interferes with formation of lower-occupancy complexes. DNA molecules with gaps in the 8 bp spacer region are over-represented in complexes with either two or three binding sites occupied by Flp, evidence that DNA flexibility facilitates the cooperative interaction of Flp protomers bound to a recombinationally-active site.     

Interaction of the BELL-like protein ATH1 with DNA: role of homeodomain residue 54 in specifying the different binding properties of BELL and KNOX proteins

We have studied the interaction of the BELL-like Arabidopsis homeodomain protein ATH1 with DNA. Analysis of oligonucleotides selected by the ATH1 homeodomain from a random mixture suggests that ATH1 preferentially binds the sequence TGACAGGT. Single nucleotide replacements at positions 2 or 3 of this sequence abolish binding, while changes at position 4 are more tolerated. Changes outside this core differentially affect binding, depending on the position. Hydroxyl radical footprinting and missing nucleoside experiments showed that ATH1 interacts with a 7-bp region of the strand carrying the GAC core. On the other strand, protection was observed over a 7-bp region, comprising one additional nucleotide complementary to T in position 1. A comparative analysis of the binding preferences of the homeodomains of ATH1 and STM (a KNOX homeodomain protein) indicated that they bind similar sequences, but with differences in affinity and specificity. The decreased affinity displayed by the ATH1 homeodomain correlates with the presence of valine (instead of lysine as in STM) at position 54. This difference also explains the decreased and increased selectivities, respectively, at positions 4 and 5. Our results point to an essential role of residue 54 in determining the different binding properties of BELL and KNOX homeodomains.