The 43 residue DNA binding domain of gamma delta resolvase binds adjacent major and minor grooves of DNA.

The carboxyl-terminal domain of gamma delta resolvase binds to each half of the three resolvase binding sites that constitute the recombination site, res. Ethylation inhibition experiments show that the phosphate contacts made by the C-terminal DNA binding domain are similar to those made by intact resolvase, with the exception of a single phosphate at the inside end of each contact region which is contacted solely by the intact resolvase. The DNA binding domain makes essentially identical contacts to all 6 half sites, whereas the intact resolvase makes slightly different contacts to each binding site. Despite its small size, only 43 amino acid residues, the resolvase C-terminal domain interacts with an unusually large segment of DNA. Phosphate contacts extend across an adjacent major and minor groove of DNA and about one third of the circumference around the helix. The minimal binding segment, determined experimentally, is a 12 bp sequence that includes the 9 base pair inverted repeat (common to all half sites), the adjacent 3 base pairs (towards the center of the intact resolvase binding site), and phosphates at both ends.     

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.     

Binding of the IS903 transposase to its inverted repeat in vitro.

We have purified the transposase of IS903 in three different ways. We find that transposase expressed as a fusion protein with either glutathione-S-transferase or maltose-binding protein is soluble and can be purified rapidly using affinity chromatography. The third purification requires extracting the native transposase from an insoluble pellet using an alkaline pH buffer. All three proteins bind specifically to the ends of IS903 and give identical patterns of protection when challenged with DNase I. We have used the more stable fusion proteins to examine transposase--DNA interactions in vitro. Methylation interference experiments have identified critical bases for transposase binding; methylated purines that inhibit binding all lie within the inner part of the 18 bp inverted repeat (bp 7-16). Moreover, the positions and identities of these purines suggest that the transposase interacts with base pairs in adjacent major and minor grooves. Binding assays with mutant inverted repeats confirm that transposase binding is sensitive to sequence changes only within this inner region. We propose that the transposase binding site is limited to this domain of the inverted repeat. These data are consistent with our previous analysis of the behaviour of mutant ends in vivo, from which we postulated that the inverted repeat was composed of two functional domains; an inner binding domain (bp 6-18), which included a region of minor groove interactions, and an outer domain that was involved in a step subsequent to transposase binding.     

Contacts between gamma delta resolvase and the gamma delta res site.

We have investigated the interaction between resolvase and the res site of the transposon gamma delta by methylation and ethylation interference experiments. We have examined the effect of these DNA modifications both on binding and resolution in vitro. Major groove methylations within a 9 bp sequence that borders each site inhibit binding of resolvase to that site. Ethylation of certain phosphates within, and adjacent to, this border sequence inhibits binding. Together, these interference points define a contact region, present at all three res sites. In vitro resolution is inhibited only by modifications within site I. Inhibition of resolution by methylation of adenines at the center of site I suggests that minor groove contacts near the crossover may be required for resolution activity.     

The organization of the outside end of transposon Tn5.

The end sequences of the IS50 insertion sequence are known as the outside end (OE) and inside end. These complex ends are related but nonidentical 19-bp sequences that serve as substrates for the activity of the Tn5 transposase. Besides providing the binding site of the transposase, the end sequences of a transposon contain additional types of information necessary for transposition. These additional properties include but are not limited to host protein interaction sites and sites that program synapsis and cleavage events. In order to delineate the properties of the IS50 ends,the base pairs involved in the transposase binding site have been defined. This has been approached through performing a variety of in vitro analyses: a ++hydroxyl radical missing-nucleoside interference experiment, a dimethyl sulfate interference experiment, and an examination of the relative binding affinities of single-site end substitutions. These approaches have led to the conclusion that the transposase binds to two nonsymmetrical regions of the OE, including positions 6 to 9 and 13 to 19. Proper binding occurs along one face of the helix, over two major and minor grooves, and appears to result in a significant bending of the DNA centered approximately 3 bp from the donor DNA-OE junction.     

Mutations in the alpha8 loop of human APE1 alter binding and cleavage of DNA containing an abasic site

Recent crystallographic studies reveal loops in human AP endonuclease 1 (APE1) that interact with the major and minor grooves of DNA containing apurinic/apyrimidinic (AP) sites. These loops are postulated to stabilize the DNA helix and the flipped out AP residue. The loop alpha8 interacts with the major groove on the 3' side of the AP site. To determine the essentiality of the amino acids that constitute the alpha8 loop, we created a mutant library containing random nucleotides at codons 222-229 that, in wild-type APE1, specify the sequence NPKGNKKN. Upon expression of the library (2 x 10(6) different clones) in Escherichia coli and multiple rounds of selection with the alkylating agent methyl-methane sulfonate (MMS), we obtained approximately 2 x 10(5) active mutants that complemented the MMS sensitivity of AP endonuclease-deficient E. coli. DNA sequencing showed that active mutants tolerated amino acid substitutions at all eight randomized positions. Basic and uncharged polar amino acids together comprised the majority of substitutions, reflecting the positively charged, polar character of the wild-type loop. Asn-222, Asn-226, and Asn-229 exhibited the least mutability, consistent with x-ray data showing that each asparagine contacts a DNA phosphate. Substitutions at residues 226-229, located nearer to the AP site, that reduced basicity or hydrogen bonding potential, increased Km 2- to 6-fold and decreased AP site binding; substitutions at residues 222-225 exhibited lesser effects. This initial mutational analysis of the alpha8 loop supports and extends the conclusion of crystallographic studies that the loop is important for binding of AP.DNA and AP site incision.     

Sequence-specific and 3'-end selective single-strand DNA binding by the Oxytricha nova telomere end binding protein alpha subunit

Oxytricha nova telomere end binding protein (OnTEBP) specifically recognizes and caps single-strand (T(4)G(4))(2) telomeric DNA at the very 3'-ends of O. nova macronuclear chromosomes. The discovery of proteins homologous to the N-terminal domain of the OnTEBP alpha subunit in Euplotes crassus, Schizosaccharomyces pombe, and Homo sapiens suggests that related proteins are widely distributed in eukaryotes. Previously reported crystal structures of the ssDNA binding domain of the OnTEBP alpha subunit both uncomplexed and complexed with telomeric ssDNA have suggested specific mechanisms for sequence-specific and 3'-end selective recognition of the single-strand telomeric DNA. We now describe comparative binding studies of ssDNA recognition by the N-terminal domain of the OnTEBP alpha subunit. Addition of nucleotides to the 3'-end of the TTTTGGGG telomere repeat decreases the level of alpha binding by up to 7-fold, revealing a modest specificity for a 3'-terminus relative to an internal DNA binding site. Nucleotide substitutions at specific positions within the t(1)t(2)t(3)T(4)G(5)G(6)G(7)G(8) repeat show that base substitutions at some sites do not substantially decrease the binding affinity (<2-fold for lowercase letters), while substitutions at other sites dramatically reduce the binding affinity (>20-fold decrease for the uppercase bold letter). Comparison of the structural and binding data provides unique insights into the ways in which proteins recognize and bind single-stranded DNA.     

DNA binding activities of the Caenorhabditis elegans Tc3 transposase.

Tc3 is a member of the Tc1/mariner family of transposable elements. All these elements have terminal inverted repeats, encode related transposases and insert exclusively into TA dinucleotides. We have studied the DNA binding properties of Tc3 transposase and found that an N-terminal domain of 65 amino acids binds specifically to two regions within the 462 bp Tc3 inverted repeat; one region is located at the end of the inverted repeat, the other is located approximately 180 bp from the end. Methylation interference experiments indicate that this N-terminal DNA binding domain of the Tc3 transposase interacts with nucleotides on one face of the DNA helix over adjacent major and minor grooves.     

Highly tolerated amino acid substitutions increase the fidelity of Escherichia coli DNA polymerase I

Fidelity of DNA synthesis, catalyzed by DNA polymerases, is critical for the maintenance of the integrity of the genome. Mutant polymerases with elevated accuracy (antimutators) have been observed, but these mainly involve increased exonuclease proofreading or large decreases in polymerase activity. We have determined the tolerance of DNA polymerase for amino acid substitutions in the active site and in different segments of E. coli DNA polymerase I and have determined the effects of these substitutions on the fidelity of DNA synthesis. We established a DNA polymerase I mutant library, with random substitutions throughout the polymerase domain. This random library was first selected for activity. The essentiality of DNA polymerases and their sequence and structural conservation suggests that few amino acid substitutions would be tolerated. However, we report that two-thirds of single base substitutions were tolerated without loss of activity, and plasticity often occurs at evolutionarily conserved regions. We screened 408 members of the active library for alterations in fidelity of DNA synthesis in Escherichia coli expressing the mutant polymerases and carrying a second plasmid containing a beta-lactamase reporter. Mutation frequencies varied from 1/1000- to 1000-fold greater compared with wild type. Mutations that produced an antimutator phenotype were distributed throughout the polymerase domain, with 12% clustered in the M-helix. We confirmed that a single mutation in this segment results in increased base discrimination. Thus, this work identifies the M-helix as a determinant of fidelity and suggests that polymerases can tolerate many substitutions that alter fidelity without incurring major changes in activity.     

Probing the structure of gal operator-repressor complexes. Conformation change in DNA

The gal operon is regulated by binding of Gal repressor to two operator loci, OE and OI, which are separated by 114 base pairs (bp). We have probed the actual operator DNA segments with and without Gal repressor occupation by characterizing the regions protected by repressor from DNase I digestion and dimethyl sulfate methylation. The segments which are protected from DNase I digestion in both OE and OI are about 22 bp long and seem to include 2-3 extra bp on either side of a 16-bp similar sequence containing an approximate dyad symmetry, with a consensus half-symmetry sequence GTG(G/T)AA-C. Repressor occupation hinders the reactivity of the consensus guanines in the four half-symmetry sequences, as shown by retardation of methylation at the N-7 positions by dimethyl sulfate owing to repressor binding. The protected guanines are symmetrically located. Since a dimeric Gal repressor affects symmetrically located bases, it is consistent with the notion that each half-operator is occupied by a repressor subunit. Because the N-7 positions of methylation of guanines lie in the major grooves and the protected guanines are located at positions 1, 3, 8 and the rotational 1', 3', and 8' in the 16-bp dyad symmetry, we suggest that Gal repressor establishes direct contacts with bases at 1, 3, 1', and 3' through two major grooves lying on one face of an operator helix and prevents reactivity of the guanines at 8 and 8' of a third major groove on the opposite face by changing the DNA helical structure at this position. Contacts at other positions are also discussed.     

The novel Mrf-2 DNA-binding domain recognizes a five-base core sequence through major and minor-groove contacts.

Recent NMR studies of the purified Mrf-2 DNA-binding domain peptide have shown that its structure differs significantly from previously characterized classes of DNA-binding domains. Here we report biochemical studies of the DNA-binding properties of this peptide. Binding interference and binding site selection assays indicated that Mrf-2 requires the core sequence AATA(C/T) for high affinity binding. Kinetic analyses of several selected sequences indicated that the core sequence alone is not sufficient for high affinity binding, however. Kinetic analyses were also performed using a series of synthetic oligonucleotides with single base analogues at each position in the core sequence. Base analogues that altered the major groove structure reduced or eliminated Mrf-2 binding when present in the second, third, and fourth base-pairs of the core sequence, but had little or no effect in the first and fifth positions. These results suggest that Mrf-2 contacts both the major and minor grooves of its target sequences.     

Characterization of the herpes simplex virus origin binding protein interaction with OriS.

The origin binding protein (OBP) of herpes simplex virus (HSV), which is essential for viral DNA replication, binds specifically to sequences within the viral replication origin(s) (for a review, see Challberg, M.D., and Kelly, T. J. (1989) Annu. Rev. Biochem. 58, 671-717). Using either a COOH-terminal OBP protein A fusion or the full-length protein, each expressed in Escherichia coli, we investigated the interaction of OBP with one HSV origin, OriS. Binding of OBP to a set of binding site variant sequences demonstrates that the 10-base pair sequence, 5' CGTTCGCACT 3', comprises the OBP-binding site. This sequence must be presented in the context of at least 15 total base pairs for high affinity binding, Ka = approximately 0.3 nM. Single base pair mutations in the central CGC sequence lower the affinity by several orders of magnitude, whereas a substitution at any of the other seven positions reduces the affinity by 10-fold or less. OBP binds with high affinity to duplex DNA containing mismatched base pairs. This property is exploited to analyze OBP binding to DNA heteroduplexes containing singly substituted mutant and wild-type DNA strands. For positions 2, 3, 5, 6, 7, 8, and 9, substitutions are tolerated on one or the other DNA strand, indicating that base-mediated interactions are limited to one base of each pair. For both Boxes I and II, these interactions are localized to one face of the DNA helix, forming a recognition surface in the major groove. In OriS, the 31 base pairs which separate Boxes I and II orient the two interaction surfaces to the same side of the DNA.     

Activity and Specificity of the Bacterial PD-(D/E)XK Homing Endonuclease I-Ssp6803I

The restriction endonuclease fold [a three-layer α-β sandwich containing variations of the PD-(D/E)XK nuclease motif] has been greatly diversified during evolution, facilitating its use for many biological functions. Here we characterize DNA binding and cleavage by the PD-(D/E)XK homing endonuclease I-Ssp6803I. Unlike most restriction endonucleases harboring the same core fold, the specificity profile of this enzyme extends over a long (17 bp) target site. The DNA binding and cleavage specificity profiles of this enzyme were independently determined and found to be highly correlated. However, the DNA target sequence contains several positions where binding and cleavage activities are not tightly coupled: individual DNA base-pair substitutions at those positions that significantly decrease cleavage activity have minor effects on binding affinity. These changes in the DNA target sequence appear to correspond to substitutions that uniquely increase the free energy change between the ground state and the transition state, rather than simply decreasing the overall DNA binding affinity. The specificity of the enzyme reflects constraints on its host gene and limitations imposed by the enzyme's quaternary structure and illustrate the highly diverse repertoire of DNA recognition specificities that can be adopted by the related folds surrounding the PD-(D/E)XK nuclease motif.     

Binding of the Bacillus subtilis LexA protein to the SOS operator

The Bacillus subtilis LexA protein represses the SOS response to DNA damage by binding as a dimer to the consensus operator sequence 5′-CGAACN₄GTTCG-3′. To characterize the requirements for LexA binding to SOS operators, we determined the operator bases needed for site-specific binding as well as the LexA amino acids required for operator recognition. Using mobility shift assays to determine equilibrium constants for B.subtilis LexA binding to recA operator mutants, we found that several single base substitutions within the 14 bp recA operator sequence destabilized binding enough to abolish site-specific binding. Our results show that the AT base pairs at the third and fourth positions from the 5′ end of a 7 bp half-site are essential and that the preferred binding site for a LexA dimer is 5′-CGAACATATGTTCG-3′. Binding studies with LexA mutants, in which the solvent accessible amino acid residues in the putative DNA binding domain were mutated, indicate that Arg-49 and His-46 are essential for binding and that Lys-53 and Ala-48 are also involved in operator recognition. Guided by our mutational analyses as well as hydroxyl radical footprinting studies of the dinC and recA operators we docked a computer model of B.subtilis LexA on the preferred operator sequence in silico. Our model suggests that binding by a LexA dimer involves bending of the DNA helix within the internal 4 bp of the operator.     

The gamma delta resolvase bends the res site into a recombinogenic complex.

We have characterized complexes between the gamma delta resolvase and its recombination site, res, using both a gel retardation assay and DNase I cleavage. The mobility of resolvase-res complexes in polyacrylamide gels is sensitive to the location of res within the DNA fragment and is at a minimum when res is at its center. This behavior is characteristic of a protein-dependent bend. By the same assay we have found that bends are induced upon the binding of resolvase to each of the three individual binding sites that constitute res. In the wild-type res, the centers of binding sites I and II are 53 bp apart and the central section of the intersite DNA is sensitive to DNase I cleavage. We find that insertions of 10 or 21 bp (one or two turns of the DNA helix) have no discernible effect on the ability of res to recombine or to form complexes with resolvase. However, insertions of short segment (e.g. 6 or 17 bp) equivalent to nonintegral numbers of helical turns, inhibit recombination and prevent the formation of the normally compact resolvase-res complex. Complexes of resolvase with res containing 10 or 21 bp insertions exhibit a pattern of enhanced and suppressed DNase I cleavages that suggest that the intersite segment is curved. This curvature requires both that site I and II are appropriately spaced, and that site III is also present and occupied.     

DNA sequence determinants for binding of the Escherichia coli catabolite gene activator protein.

The consensus DNA site for binding of the Escherichia coli catabolite gene activator protein (CAP) is 22 base pairs in length and is 2-fold symmetric: 5'-AAATGTGATCTAGATCACATTT-3'. Positions 4 to 8 of each half of the consensus DNA half-site are the most strongly conserved. In this report, we analyze the effects of substitution of DNA base pairs at positions 4 to 8, the effects of substitution of thymine by uracil and by 5-methylcytosine at positions 4, 6, and 8, and the effect of dam methylation of the 5'-GATC-3' sequence at positions 7 to 10. All DNA sites having substitutions of DNA base pairs at positions 4 to 8 exhibit lower affinities for CAP than does the consensus DNA site, consistent with the proposal that the consensus DNA site is the ideal DNA site for CAP. Specificity for T:A at position 4 appears to be determined solely by the thymine 5-methyl group. Specificity for T:A at position 6 and specificity for A:T at position 8 appear to be determined in part, but not solely, by the thymine 5-methyl group. dam methylation has little effect on CAP.DNA complex formation. The thermodynamically defined consensus DNA site spans 28 base pairs. All, or nearly all, DNA determinants required for maximal affinity for CAP and for maximal thermodynamically defined CAP.DNA ion pair formation are contained within a 28-base pair DNA fragment that has the 22-base pair consensus DNA site at its center. The quantitative data in this report provide base-line thermodynamic data required for detailed investigations of amino acid-base pair and amino acid-phosphate contacts in this protein-DNA complex.