DNA sequence recognition by an isopropyl substituted thiazole polyamide

We have used DNA footprinting and fluorescence melting experiments to study the sequence-specific binding of a novel minor groove binding ligand (thiazotropsin A), containing an isopropyl substituted thiazole polyamide, to DNA. In one fragment, which contains every tetranucleotide sequence, sub-micromolar concentrations of the ligand generate a single footprint at the sequence ACTAGT. This sequence preference is confirmed in melting experiments with fluorescently labelled oligonucleotides. Experiments with DNA fragments that contain variants of this sequence suggest that the ligand also binds, with slightly lower affinity, to sequences of the type XCYRGZ, where X is any base except C, and Z is any base except G.     

The MyoD DNA binding domain contains a recognition code for muscle-specific gene activation

A 60 amino acid domain of the myogenic determination gene MyoD is necessary and sufficient for sequence-specific DNA binding in vitro and myogenic conversion of transfected C3H10T1/2 cells. We show that a highly basic region, immediately upstream of the helix-loop-helix (HLH) oligomerization motif, is required for MyoD DNA binding in vitro. Replacing helix1, helix2, or the loop of MyoD with the analogous sequence of the Drosophila T4 achaete-scute protein (required for peripheral neurogenesis) has no substantial effect on DNA binding in vitro or muscle-specific gene activation in transfected C3H10T1/2 cells. However, replacing the basic region of MyoD with the analogous sequence of other HLH proteins (the immunoglobulin enhancer binding E12 protein or T4 achaete scute protein) allows DNA binding in vitro, yet abolishes muscle-specific gene activation. These findings suggest that a recognition code that determines muscle-specific gene activation lies within the MyoD basic region and that the capacity for specific DNA binding is insufficient to activate the muscle program.     

Head-to-head bis-hairpin polyamide minor groove binders and their conjugates with triplex-forming oligonucleotides: studies of interaction with target double-stranded DNA

Two hairpin hexa(N-methylpyrrole)carboxamide DNA minor groove binders (MGB) were linked together via their N-termini in head-to-head orientation. Complex formation between these bis-MGB conjugates and target DNA has been studied using DNase I footprinting, circular dichroism, thermal dissociation, and molecular modeling. DNase I footprint revealed binding of these conjugates to all the sites of 492 b.p. DNA fragment containing (A/T)(n)X(m)(A/T)(p) sequences, where n>3, p>3; m=1,2; X = A,T,G, or C. Binding affinity depended on the sequence context of the target. CD experiments and molecular modeling showed that oligo(N-methylpyrrole)carboxamide moieties in the complex form two short antiparallel hairpins rather than a long parallel head-to-head hairpin. Binding of bis-MGB also stabilized a target duplex thermodynamically. Sequence specificity of bis-MGB/DNA binding was validated using bis-conjugates of sequence-specific hairpin (N-methylpyrrole)/(N-methylimidazole) carboxamides. In order to increase the size of recognition sequence, the conjugates of bis-MGB with triplex-forming oligonucleotides (TFO) were synthesized and compared to TFO conjugated with single MGB hairpin unit. Bis-MGB-oligonucleotide conjugates also bind to two blocks of three and more A.T/T.A pairs similarly to bis-MGB alone, independently of the oligonucleotide moiety, but with lower affinity. However, the role of TFO in DNA recognition was demonstrated for mono-MGB-TFO conjugate where the binding was detected mainly in the area of the target sequence consisting of both MGB and TFO recognition sites. Basing on the molecular modeling, three-dimensional models of both target DNA/bis-MGB and target DNA/TFO-bis-MGB complexes were built, where bis-MGB forms two antiparallel hairpins. According to the second model, one MGB hairpin is in the minor groove of 5'-adjacent A/T sequence next to the triplex-forming region, whereas the other one occupies the minor groove of the TFO binding polypurine tract. All these data together give a key information for the construction of MGB-MGB and MGB-oligonucleotide conjugates possessing high specificity and affinity for the target double-stranded DNA.     

DNA-binding activity of the A-factor receptor protein and its recognition DNA sequences

The A-factor receptor protein (ArpA) containing an α-helix-turn-α-helix DNA-binding consensus sequence at its N-terminal portion plays a key role in the regulation of secondary metabolism and cell differentiation in Streptomyces griseus . A binding site forming a palindrome 24 bp in length was initially recovered from a pool of random-sequence oligonucleotides by rounds of a binding/immunoprecipitation/amplification procedure with histidine-tagged ArpA and anti-ArpA antibody. By means of further binding/gel retardation/amplification experiments on the basis of the recovered sequence, a 22 bp palindromic binding site with the sequence 5'-GG(T/C)CGGT(A/T)(T/C)-G(T/G)-3' as one half of the palindrome was deduced as a consensus sequence recognized and bound by ArpA. ArpA did not bind to the binding site in the presence of its ligand, A-factor. In addition, exogenous addition of A-factor to the ArpA–DNA complex induced immediate release of ArpA from the DNA. All of these data are consistent with the idea, obtained from previous genetic studies, that ArpA acts as a repressor-type regulator for secondary metabolism and cellular differentiation by preventing the expression of a certain key gene(s) during the early growth phase. A-factor, produced in a growth-dependent manner, releases ArpA from the DNA, thus switching on the expression of the key gene(s), leading to the onset of secondary metabolism and aerial mycelium formation.     

HU binding to bent DNA: a fluorescence resonance energy transfer and anisotropy study

HU, an architectural DNA-binding protein, either stabilizes DNA in a bent conformation or induces a bend upon binding to give other proteins access to the DNA. In this study, HU binding affinity for a bent DNA sequence relative to a linear sequence was investigated using fluorescence anisotropy measurements. A static bend was achieved by the introduction of two phased A4T4 tracts in a 20 bp duplex. Binding affinity for 20 bp duplexes containing two phased A-tracts in either a 5'-3' or 3'-5' orientation was found to be almost 10-fold higher than HU binding to a random sequence 20 bp duplex (6.1 vs 0.68 microM(-1)). The fluorescence technique of resonance energy transfer was used to quantitatively determine the static bend of the DNA duplexes and the HU-induced bend. DNA molecules were 5'-end labeled with fluorescein as the donor or rhodamine as the acceptor. From the efficiency of energy transfer, the end-to-end distance of the DNA duplexes was calculated. The end-to-end distance relative to DNA contour length (R/R(C)) yields a bend angle for the A-tract duplex of 45 +/- 7 degrees in the absence of HU and 70 +/- 3 degrees in the presence of HU. The bend angle calculated for the T4A4 tract duplex was 62 +/- 4 degrees after binding two HU dimers. Fluorescence anisotropy measurements reveal that HU binds in a 1:1 stoichiometry to the A4T4 tract duplex but a 2:1 stoichiometry to the T4A4 tract and random sequence duplex. These findings suggest that HU binding and recognition of DNA may be governed by a structural mechanism.     

Substrate specificity and sequence-dependent activity of the Saccharomyces cerevisiae 3-methyladenine DNA glycosylase (Mag)

DNA glycosylases initiate base excision repair by first binding, then excising aberrant DNA bases. Saccharomyces cerevisiae encodes a 3-methyladenine (3MeA) DNA glycosylase, Mag, that recognizes 3MeA and various other DNA lesions including 1,N6-ethenoadenine (epsilon A), hypoxanthine (Hx) and abasic (AP) sites. In the present study, we explore the relative substrate specificity of Mag for these lesions and in addition, show that Mag also recognizes cisplatin cross-linked adducts, but does not catalyze their excision. Through competition binding and activity studies, we show that in the context of a random DNA sequence Mag binds epsilon A and AP-sites the most tightly, followed by the cross-linked 1,2-d(ApG) cisplatin adduct. While epsilon A binding and excision by Mag was robust in this sequence context, binding and excision of Hx was extremely poor. We further studied the recognition of epsilon A and Hx by Mag, when these lesions are present at different positions within A:T and G:C tracts. Overall, epsilon A was slightly less well excised from each position within the A:T and G:C tracts compared to excision from the random sequence, whereas Hx excision was greatly increased in these sequence contexts (by up to 7-fold) compared to the random sequence. However, given most sequence contexts, Mag had a clear preference for epsilon A relative to Hx, except in the TTXTT (X=epsilon A or Hx) sequence context from which Mag removed both lesions with almost equal efficiency. We discuss how DNA sequence context affects base excision by various 3MeA DNA glycosylases.     

The effects of local DNA sequence on the interaction of ligands with their preferred binding sites

We have examined the effects of local DNA sequence on the interaction of distamycin, Hoechst 33258, echinomycin, actinomycin and mithramycin with their preferred binding sites using a series of DNA fragments that contain every symmetrical hexanucleotide sequence. In several instances we find that the affinity for the ligands' preferred binding sites is affected by the hexanucleotide context in which they are located. The AT-selective minor groove binding ligand Hoechst 33258 shows a 200-fold difference in binding to the 16 different X(A/T)(4)Y sites; the strongest binding is to AAATTT and the weakest is to (G/C)TTAA(C/G). Although TTAA is generally a poor binding site, ATTAAT is better than TTTAAA and they are both much better than GTTAAC and CTTAAG. Similarly, TTATAA and ATATAT are better binding sites than GTATAC and CTATAG. In contrast, distamycin shows less discrimination between the various X(A/T)(4)Y sites, with a 20-fold difference between the best [(A/T)AATT(T/A)] and worst [GATATC and (G/C)TTAA(C/G)] sites. Although actinomycin binds to GpC it shows little or no interaction with any of the GGCC sites, yet shows only a six-fold variation in affinities for the other XYGCXY sites. Echinomycin binds to CpG yet shows no binding to TTCGAA, TGCGCA and AGCGCT, while the best binding is to AACGTT. The tetranucleotides CCGG and ACGT produce consistently good binding sites, irrespective of the surrounding sequences, while the interaction with TCGA and GCGC is sensitive to the hexanucleotide context. Hexanucleotides with a central GCGC, flanked by A and T are weaker echinomycin sites than those flanked by G and C, especially CGCGCG. The best X(G/C)(4)Y binding sites for mithramycin were located at AGCGCT and GGGCCC, and the worst at CCCGGG and TCCGGA. These footprinting fragments are valuable tools for comparing the binding of ligands to all the potential symmetrical hexanucleotides and provide insights into the effects of local DNA sequence on ligand-DNA interactions.     

DNA binding properties of the Saccharomyces cerevisiae DAT1 gene product.

The DAT1 gene of Saccharomyces cerevisiae encodes a DNA binding protein (Dat1p) that specifically recognizes the minor groove of non-alternating oligo(A).oligo(T) tracts. Sequence-specific recognition requires arginine residues found within three perfectly repeated pentads (G-R-K-P-G) of the Dat1p DNA binding domain [Reardon, B. J., Winters, R. S., Gordon, D., and Winter, E. (1993) Proc. Natl. Acad. Sci. USA 90, 11327-1131]. This report describes a rapid and simple method for purifying the Dat1p DNA binding domain and the biochemical characterization of its interaction with oligo(A).oligo(T) tracts. Oligonucleotide binding experiments and the characterization of yeast genomic Dat1p binding sites show that Dat1p specifically binds to any 11 base sequence in which 10 bases conform to an oligo(A).oligo(T) tract. Binding studies of different sized Dat1p derivatives show that the Dat1p DNA binding domain can function as a monomer. Competition DNA binding assays using poly(I).poly(C), demonstrate that the minor groove oligo(A).oligo(T) constituents are not sufficient for high specificity DNA binding. These data constrain the possible models for Dat1p/oligo(A).oligo(T) complexes, suggest that the DNA binding domain is in an extended structure when complexed to its cognate DNA, and show that Dat1p binding sites are more prevalent than previously thought.     

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.     

Simian virus 40 and polyomavirus large tumor antigens have different requirements for high-affinity sequence-specific DNA binding.

By using a DNA fragment immunoassay, the binding of simian virus 40 (SV40) and polyomavirus (Py) large tumor (T) antigens to regulatory regions at both viral origins of replication was examined. Although both Py T antigen and SV40 T antigen bind to multiple discrete regions on their proper origins and the reciprocal origin, several striking differences were observed. Py T antigen bound efficiently to three regions on Py DNA centered around an MboII site at nucleotide 45 (region A), a BglI site at nucleotide 92 (region B), and another MboII site at nucleotide 132 (region C). Region A is adjacent to the viral replication origin, and region C coincides with the major early mRNA cap site. Weak binding by Py T antigen to the origin palindrome centered at nucleotide 3 also was observed. SV40 T antigen binds strongly to Py regions A and B but only weakly to region C. This weak binding on region C was surprising because this region contains four tandem repeats of GPuGGC, the canonical pentanucleotide sequence thought to be involved in specific binding by T antigens. On SV40 DNA, SV40 T antigen displayed its characteristic hierarchy of affinities, binding most efficiently to site 1 and less efficiently to site 2. Binding to site 3 was undetectable under these conditions. In contrast, Py T antigen, despite an overall relative reduction of affinity for SV40 DNA, binds equally to fragments containing each of the three SV40 binding sites. Py T antigen, but not SV40 T antigen, also bound specifically to a region of human Alu DNA which bears a remarkable homology to SV40 site 1. However, both tumor antigens fail to precipitate DNA from the same region which has two direct repeats of GAGGC. These results indicate that despite similarities in protein structure and DNA sequence, requirements of the two T antigens for pentanucleotide configuration and neighboring sequence environment are different.     

DNA detection system using molecularly imprinted polymer as the gel matrix in electrophoresis

To develop a simple and inexpensive method for DNA detection, we prepared a molecularly imprinted polymer (MIP) for recognizing a specific double-stranded DNA (dsDNA) sequence and used it in an electrophoretic gel matrix. The MIP gel has many binding sites that are complementary in size, shape, and arrangement of functional groups of the target dsDNA sequence. During MIP gel electrophoresis (MIPGE), migration of the target dsDNA should be hindered by the capture effect of the binding sites in the MIP gel. This was confirmed by observation of deviations from the linear relationship between the migration distances of the DNA standard size markers in the polyacrylamide gel and those in the MIP gel. The migration distances of nontarget dsDNA maintained a linear relationship, however. In addition, the sequence selectivity of dsDNA in this method was investigated by using the Ha-ras gene and its point mutants. Except for A.T to T.A base pair substitution, mutant dsDNA (for example, substitution from A.T to C.G and from G.C to T.A) could be distinguished from the target (wild-type) dsDNA. Although some improvement in A.T (T.A) base pair distinction is still needed, this study is the first to demonstrate detection of a specific dsDNA sequence with MIPs and, as such, opens up a new realm for practical applications of MIPs.     

An altered DNA conformation in origin region I is a determinant for the binding of SV40 large T antigen

Seventeen base pairs of DNA from SV40 origin region I encode a tripartite binding site for a dimeric mass of SV40 large T antigen. Two binding components are the directly repeated pentanucleotide sequences 5'-GAGGC-3'/5'-GCCTC-3'. The third component is the asymmetric sequence 5'-TTTTTTG-3'/5'-CAAAAAA-3' that separates the pentanucleotides. Nucleotide-specific features of this spacer element stabilize binding to the adjacent pentanucleotides. We report here that the spacer sequence determines a DNA conformation that correlates with high affinity binding of T antigen. The nature of the spacer sequence suggests that the DNA is bent. We propose that binding of T antigen to region I proceeds through monomer-pentanucleotide interactions and either protein-protein or protein-spacer interactions directed by the spacer-encoded structure.     

Simian virus 40 tumor antigen: isolation of the origin-specific DNA-binding domain

To localize the origin-specific DNA-binding domain on the simian virus 40 tumor (T) antigen molecule, we used limited proteolysis with trypsin to generate fractional peptides for analysis. A 17,000-Mr peptide was found to be capable of binding not only to calf thymus DNA, but also specifically to the simian virus 40 origin of DNA replication. This approximately 130-amino-acid peptide was derived from the extreme N-terminus of the T antigen and represented less than one-fifth of the entire molecule. The coding sequence for this tryptic peptide was located approximately between 0.51 and 0.67 map units (excluding the intron, which maps between 0.54 and 0.59). Since the first 82 amino acids are shared between large T and small t antigens, and since the latter does not bind DNA, it can be concluded that the sequence between isoleucine 83 and approximately arginine 130 is necessary for origin-specific binding by the T antigen. We also observed that in vivo phosphorylation of the T antigen within this region completely abolished the ability of the 17,000-Mr peptide to bind DNA. This observation is consistent with the idea that DNA binding by the T antigen is regulated by posttranslational modifications.     

IHF redistributes bound initiator protein, DnaA, on supercoiled oriC of Escherichia coli

In Escherichia coli, initiation of chromosome replication requires that DnaA binds to R boxes (9-mer repeats) in oriC, the unique chromosomal replication origin. At the time of initiation, integration host factor (IHF) also binds to a specific site in oriC. IHF stimulates open complex formation by DnaA on supercoiled oriC in cell-free replication systems, but it is unclear whether this stimulation involves specific changes in the oriC nucleoprotein complex. Using dimethylsulphate (DMS) footprinting on supercoiled oriC plasmids, we observed that IHF redistributed prebound DnaA, stimulating binding to sites R2, R3 and R5(M), as well as to three previously unidentified non-R sites with consensus sequence (A/T)G(G/C) (A/T)N(G/C)G(A/T)(A/T)(T/C)A. Redistribution was dependent on IHF binding to its cognate site and also required a functional R4 box. By reducing the DnaA level required to separate DNA strands and trigger initiation of DNA replication at each origin, IHF eliminates competition between strong and weak sites for free DnaA and enhances the precision of initiation synchrony during the cell cycle.