Groove selectivity in the interaction of 9-aminoacridine-4-carboxamide antitumor agents with DNA

Theoretical quantitative evaluation of the intercalative binding to DNA of the new antitumor drug 9-aminoacridine-4-carboxamide indicates that, in contradiction with a recently proposed model, the compound should show specificity for interaction with the major (and not minor) groove of GC sequences.     

Drug-DNA sequence-dependent interactions analysed by electric linear dichroism.

The interactions between 20 drugs and a variety of synthetic DNA polymers and natural DNAs were studied by electric linear dichroism (ELD). All compounds tested, including several clinically used antitumour agents, are thought to exert their biological activities mainly by virtue of their abilities to bind to DNA. The selected drugs include intercalating agents with fused and unfused aromatic structures and several groove binders. To examine the role of base composition and base sequence in the binding of these drugs to DNA, ELD experiments were carried out with natural DNAs of widely differing base composition as well as with polynucleotides containing defined alternating and non-alternating repeating sequences, poly(dA).poly(dT), poly(dA-dT).poly(dA-dT),poly(dG).poly(dC) and poly(dG-dC).poly(dG-dC). Among intercalating agents, actinomycin D was found to be by far the most GC-selective. GC selectivity was also observed with an amsacrine-4-carboxamide derivative and to a lesser extent with methylene blue. In contrast, the binding of amsacrine and 9-aminoacridine was practically unaffected by varying the GC content of the DNAs. Ethidium bromide, proflavine, mitoxantrone, daunomycin and an ellipticine derivative were found to bind best to alternating purine-pyrimidine sequences regardless of their nature. ELD measurements provided evidence for non-specific intercalation of amiloride. A significant AT selectivity was observed with hycanthone and lucanthone. The triphenyl methane dye methyl green was found to exhibit positive and negative dichroism signals at AT and GC sites, respectively, showing that the mode of binding of a drug can change markedly with the DNA base composition. Among minor groove binders, the N-methylpyrrole carboxamide-containing antibiotics netropsin and distamycin bound to DNA with very pronounced AT specificity, as expected. More interestingly the dye Hoechst 33258, berenil and a thiazole-containing lexitropsin elicited negative reduced dichroism in the presence of GC-rich DNA which is totally inconsistent with a groove binding process. We postulate that these three drugs share with the trypanocide 4',6-diamidino-2-phenylindole (DAPI) the property of intercalating at GC-rich sites and binding to the minor groove of DNA at other sites. Replacement of guanines by inosines (i.e., removal of the protruding exocyclic C-2 amino group of guanine) restored minor groove binding of DAPI, Hoechst 33258 and berenil. Thus there are several cases where the mode of binding to DNA is directly dependent on the base composition of the polymer. Consequently the ELD technique appears uniquely valuable as a means of investigating the possibility of sequence-dependent recognition of DNA by drugs.     

The interaction of DNA-targeted 9-aminoacridine-4-carboxamide platinum complexes with DNA in intact human cells

As part of an ongoing drug development programme, this paper describes the sequence specificity and time course of DNA adduct formation for a series of novel DNA-targeted analogues of cis-diaminedichloroplatinum(II) (cisplatin) (9-aminoacridine-4-carboxamide Pt complexes) in intact HeLa cells. The sequence specificity of DNA damage caused by cisplatin and analogues in human (HeLa) cells was studied using Taq DNA polymerase and a linear amplification/polymerase stop assay. Primer extension is inhibited by a Pt-DNA adduct, and hence the sites of these lesions can be analysed on DNA sequencing gels. The repetitive alphoid DNA sequence was used as the target DNA in human cells. The 9-aminoacridine-4-carboxamide Pt complexes exhibited a markedly different sequence specificity relative to cisplatin and other analogues. The sequence specificity of the 9-aminoacridine-4-carboxamide Pt complexes is shifted away from a preference for runs of guanines. The 9-aminoacridine-4-carboxamide Pt complexes have an enhanced preference for GA dinucleotides. This is the first occasion that an altered DNA sequence specificity has been demonstrated for a cisplatin analogue in human cells. A time course of DNA damage revealed that the DNA-targeted Pt complexes, consisting of four 9-aminoacridine-4-carboxamide Pt complexes and one acridine-4-carboxamide Pt complex, damaged DNA more rapidly compared to cisplatin and non-targeted analogues. A comparison of the time taken to reach half the maximum relative intensity indicated that the DNA-targeted Pt complexes reacted approximately 4-fold faster than cisplatin and the non-targeted analogues.     

Influence of compound structure on affinity, sequence selectivity, and mode of binding to DNA for unfused aromatic dications related to furamidine

In the course of a program aimed at developing sequence-specific gene-regulatory small organic molecules, we have investigated the DNA interactions of a new series of nine diphenylfuran dications related to the antiparasitic drug furamidine (DB75). Two types of structural modifications were tested: the terminal amidine groups of DB75 were shifted from the para to the meta position, and the amidines were replaced with imidazoline or dimethyl-imidazoline groups, to test the importance of both the position and nature of positively charged groups on DNA interactions. The interactions of these compounds with DNA and oligonucleotides were studied by a combination of biochemical and biophysical techniques. Absorption and CD measurements suggested that the drugs bind differently to AT and GC sequences in DNA. The para-para dications, like DB75, bind into the minor groove of poly(dAT)(2) and intercalate between the base pairs of poly(dGC)(2), as revealed by electric linear dichroism experiments. In contrast, the meta-meta compounds exhibit a high tendency to intercalate into DNA whatever the target sequence. The lack of sequence selectivity of the meta-meta compounds containing amidines or dimethyl-imidazoline groups was also evident from DNase I footprinting and surface plasmon resonance (SPR) experiments. Accurate binding measurements using the BIAcore SPR method revealed that all nine compounds bind with similar affinity to an immobilized GC sequence DNA hairpin but exhibit very distinct affinities for the corresponding AT hairpin oligonucleotide. The minor groove-binding para-para compounds have a high specificity for AT sequences. The biophysical data clearly indicate that shifting the cationic substituents from the para to the meta position results in a loss of specificity and change in binding mode. The strong AT selectivity of the para-para compounds was independently confirmed by DNase I footprinting experiments performed with a range of DNA restrictions fragments. In terms of AT selectivity, the compounds rank in the order para-para > para-meta > meta-meta. The para dications bind preferentially to sequences containing four contiguous AT base pairs. Additional footprinting experiments with substrates containing the 16 possible [A.T](4) blocks indicated that the presence of a TpA step within an [A.T] (4) block generally reduces the extent of binding. The diverse methods, from footprinting to SPR to dichroism, provide a consistent model for the interactions of the diphenylfuran dications with DNA of different sequences. Altogether, the results attest unequivocally that the binding mode for unfused aromatic cations can change completely depending on substituent position and DNA sequence. These data provide a rationale to explain the relationships between sequence selectivity and mode of binding to DNA for unfused aromatic dications related to furamidine.     

Use of Electric Linear Dichroism and Competition Experiments with Intercalating Drugs to Investigate the Mode of Binding of Hoechst 33258, Berenil and DAPI to GC Sequences

Abstract

The drugs Hoechst 33258, berenil and DAPI bind preferentially to the minor groove of AT sequences in DNA Despite a strong selectivity for AT sites, they can interact with GC sequences by a mechanism which remains so far controversial. The 2-amino group of guanosine represents a steric hindrance to the entry of the drugs in the minor groove of GC sequences. Intercalation and major groove binding to GC sites of GC-rich DNA and polynucleotides have been proposed for these drugs. To investigate further the mode of binding of Hoechst 33258, berenil and DAPI to GC sequences, we studied by electric linear dichroism the mutual interference in the DNA binding reaction between these compounds and a classical intercalator, proflavine, or a DNA-threading intercalating drug, the amsacrine-4-carboxamide derivative SN16713. The results of the competition experiments show that the two acridine intercalators markedly affect the binding of Hoechst 33258, berenil and DAPI to GC polynucleotides but not to DNA containing AT/GC mixed sequences such as calf thymus DNA Proflavine and SN16713 exert dissimilar effects on the binding of Hoechst 33258, berenil and DAPI to GC sites. The structural changes in DNA induced upon intercalation of the acridine drugs into GC sites are not identically perceived by the test compounds. The electric linear dichroism data support the hypothesis that Hoechst 33258, berenil and DAPI interact with GC sites via a non-classical intercalation process.     

cis-Dichloroplatinum(II) complexes tethered to 9-aminoacridine-4-carboxamides: synthesis and action in resistant cell lines in vitro.

A series of intercalator-tethered platinum(II) complexes PtLCl(2) have been prepared where L are the diamine ligands N-[2-[(aminoethyl)amino]ethyl]-9-aminoacridine-4-carboxamide, N-[3-[(2-aminoethyl)amino]propyl]-9-aminoacridine-4-carboxamide, N-[4-[(2-aminoethyl)amino]butyl]-9-aminoacridine-4-carboxamide and N-[5-[(aminoethyl)amino]pentyl]-9-aminoacridine-4-carboxamide and N-[6-[(aminoethyl)amino]hexyl]-9-aminoacridine-4-carboxamide. The activity of the complexes was assessed in the CH-1, CH-1cisR, 41M, 41McisR and SKOV-3 cell lines. The compounds with the shorter linker chain lengths are generally the most active against these cell lines and are much more toxic than Pt(en)C1(2). For example, for the n=2 compound the IC(50) values are 0.017 microM (CH-1), 1.7 microM (41M), 1.4 microM (SKOV-3) and the resistance ratios are 51 (CH-1cisR) and 1.6 (41McisR). For the untethered analogue Pt(en)C1(2) the IC(50) values are 2.5 microM (CH-1), 2.9 microM (41M), 45 microM (SKOV-3) and the resistance ratios are 2.8 (CH-1cisR) and 4.1 (41McisR). The very large differential in IC(50) values between the CH-1 and CH-1cisR pair of cell lines for the 9-aminoacridine-4-carboxamide tethered platinum complexes indicates that repair of platinum-induced DNA damage may be a major determinant of the activity of these compounds.     

DNA sequence recognition by the antitumor drug ditercalinium

The antitumor drug ditercalinium is a rare example of a noncovalent DNA-binding ligand that forms bisintercalation complexes via the major groove of the double helix. Previous structural studies have revealed that the two connected pyridocarbazolium chromophores intercalate into DNA with the positively charged bis(ethylpiperidinium) linking chain oriented to the wide groove side of the helix. Although the interaction of ditercalinium with short oligonucleotides containing 4-6 contiguous GC base pairs has been examined in detail by biophysical and theoretical approaches, the sequence preference for ditercalinium binding to long DNA fragments that offer a wide variety of binding sites has been investigated only superficially. Here we have investigated both sequence preferences and possible molecular determinants of selectivity in the binding of ditercalinium to DNA, primarily using methods based upon DNase I footprinting. A range of multisite DNA substrates, including several natural restriction fragments and different PCR-generated fragments containing unconventional bases (2,6-diaminopurine, inosine, uridine, 5-fluoro- and 5-methylcytosine, 7-deazaguanine, 7-deazaadenine, and N(7)-cyanoboranoguanine), have been employed to show that ditercalinium selectively recognizes certain GC-rich sequences in DNA and to identify some of the factors which affect its DNA-binding sequence selectivity. Specifically, the footprinting data have revealed that the 2-amino group on the purines or the 5-methyl group on the pyrimidines is not essential for the formation of ditercalinium-DNA complexes whereas the major groove-oriented N(7) of guanine does appear as a key element in the molecular recognition process. The loss of N(7) at guanines but not adenines is sufficient to practically abolish sequence-selective binding of ditercalinium to DNA. Thus, as expected for a major groove binding drug, the N(7) of guanine is normally required for effective complex formation with GC base pairs, but interestingly the substitution of the N(7) with a relatively bulky cyanoborane group does not markedly affect the sequence recognition process. Therefore, the hydrogen bond accepting capability at N(7) of guanines is not sufficient to explain the GC-selective drug-DNA association, and the implications of these findings are considered.     

Selectivity and affinity of triplex-forming oligonucleotides containing 2'-aminoethoxy-5-(3-aminoprop-1-ynyl)uridine for recognizing AT base pairs in duplex DNA

We have used DNase I footprinting, fluorescence and ultraviolet (UV) melting experiments and circular dichroism to demonstrate that, in the parallel triplex binding motif, 2′-aminoethoxy-5-(3-aminoprop-1-ynyl)uridine (bis-amino-U, BAU) has very high affinity for AT relative to all other Watson–Crick base pairs in DNA. Complexes containing two or more substitutions with this nucleotide analogue are stable at pH 7.0, even though they contain several C.GC base triplets. These modified triplex-forming oligonucleotides retain exquisite sequence specificity, with enhanced discrimination against YR base pairs (especially CG). These properties make BAU a useful base analogue for the sequence-specific creation of stable triple helices at pH 7.0.     

Energetics and stereochemistry of DNA complexation with the antitumor AT specific intercalators tilorone and m-AMSA.

Computations by the SIBFA method on the intercalative interaction energies of tilorone and m-AMSA with B-DNA representative oligonucleotides account for the specificity of these antitumor drugs for AT sites and minor groove intercalation. In tilorone this specificity is due to the strong preference of the side chains for the minor groove, which overcomes the preference of the chromophore for a GC intercalation site. In m-AMSA the specificity is due to the combined preference of both the chromophore and the anilino side chain for AT intercalation site and minor groove, respectively. o-AMSA is shown to manifest a similar (although significantly less pronounced specificity) as m-AMSA but a higher affinity for DNA. A comparison of the energetics and stereochemistry of intercalative binding to DNA of m-AMSA (AT minor groove specific) and 9-aminoacridine-4-carboxamide (GC major groove specific), which possess the same chromophore and differ only by the nature and position of the side chains, shows the possibility of important variations in the intercalative behaviour of chromophoric drugs as a function of the substituent groups attached to them.     

Site and sequence specificity of the daunomycin-DNA interaction

The site and sequence specificity of the daunomycin-DNA interaction was examined by equilibrium binding methods, by deoxyribonuclease I footprinting studies, and by examination of the effect of the antibiotic on the cleavage of linearized pBR322 DNA by restriction endonucleases PvuI and EcoRI. These three experimental approaches provide mutually consistent results showing that daunomycin indeed recognizes specific sites along the DNA lattice. The affinity of daunomycin toward natural DNA increases with increasing GC content. The quantitative results are most readily explained by binding models in which daunomycin interacts with sites containing two adjacent GC base pairs, possibly occurring as part of a triplet recognition sequence. Deoxyribonuclease I footprinting studies utilizing the 160 base pair (bp) tyrT DNA fragment and 61 and 53 bp restriction fragments isolated from pBR322 DNA further define the sequence specificity of daunomycin binding. Specific, reproducible protection patterns were obtained for each DNA fragment at 4 degrees C. Seven protected sequences, ranging in size from 4 to 14 bp, were identified within the tyrT fragment. Relative to the overall tyrT sequence, these protected sequences were GC rich and contained a more limited and distinct distribution of di- and trinucleotides. Within all of the protected sequences, a triplet containing adjacent GC base pairs flanked by an AT base pair could be found in one or more copies. Nowhere in the tyrT fragment did that triplet occur outside a protected sequence. The same triplet occurred within seven out of nine protected sequences observed in the fragments isolated from pBR322 DNA. In the two remaining cases, three contiguous GC base pairs were found. We conclude that the preferred daunomycin triplet binding site contains adjacent GC base pairs, of variable sequence, flanked by an AT base pair. This conclusion is consistent with the results of a recent theoretical study of daunomycin sequence specificity [Chen, K.-X., Gresh, N., & Pullman, B. (1985) J. Biomol. Struct. Dyn. 3, 445-466]. Adriamycin and the beta-anomer of adriamycin produce the same qualitative pattern of protection as daunomycin with the tyrT fragment. Daunomycin inhibits the rate of digestion of pBR322 DNA by PvuI (recognition sequence 5'-CGATCG-3') to a greater extent than it does EcoRI (recognition sequence 5'-GAATTC-3'), a finding consistent with the conclusions derived from our footprinting studies. Our results, as a whole, are the clearest indication to date that daunomycin recognizes a specific DNA sequence as a preferred binding site.     

Echinomycin binding to alternating AT.

We have studied the binding of echinomycin to DNA fragments containing GC-rich regions flanked by blocks of alternating AT by DNase I footprinting and diethylpyrocarbonate modification. Regions of alternating AT flanking the sequences CCCG, CCGC, CGGC and GG show a four base pair DNase I cleavage pattern and reaction of alternate adenines with diethylpyrocarbonate. This pattern is strongest when the AT-block is immediately adjacent to the CpG ligand binding site. We explain these phenomena by suggesting that echinomycin binds to the dinucleotide step ApT in a cooperative fashion. The cooperative effects can be transmitted through the dinucleotide step GC but not CC or AA. No such repetitive patterns are seen with surrounding regions of (ATT).(AAT). Evidence is presented for secondary drug binding sites at CpC and TpG with weaker interaction at the CpG site within the hexanucleotide TTCGAA.     

The effects of actinomycin on the structure of dAn.dTn and (dA-dT)n regions surrounding its GC binding site. A footprinting study.

The effect of actinomycin on the structure of DNA fragments containing the sequences (AT)5GC(AT)5, (TA)5GC(TA)5, A9GCT9, and T9GCA9, cloned into the SmaI site of pUC19, has been studied by footprinting analysis using a variety of probes known to be sensitive to DNA structure. In each case clear footprints are found around the central GC sites. DNase I cleavage of fragments containing alternating AT shows much greater cutting at ApT than TpA; in the presence of actinomycin, although this preference is retained, there is a large increase in the cutting efficiency at the closest TpA steps. DNase I cleavage in homopolymeric regions of A and T, which is normally very poor, is greatly enhanced by drug binding. With T9GCA9 the enhancements are propagated in both directions, whereas changes are only found to the 5'-side of the GC site in A9GCT9. The results are confirmed by similar experiments with micrococcal nuclease and DNase II. Small increases in sensitivity to diethylpyrocarbonate are found at adenines proximal to GC. Experiments performed at 4 degrees C suggest that conformational changes are a necessary consequence of drug binding.     

Combinatorial determination of sequence specificity for nanomolar DNA-binding hairpin polyamides

Development of sequence-specific DNA-binding drugs is an important pharmacological goal, given the fact that numerous existing DNA-directed chemotherapeutic drugs rely on the strength and selectivity of their DNA interactions for therapeutic activity. Among the DNA-binding antibiotics, hairpin polyamides represent the only class of small molecules that can practically bind any predetermined DNA sequence. DNA recognition by these ligands depends on their side-by-side amino acid pairings in the DNA minor groove. Extensive studies have revealed that these molecules show extremely high affinity for sequence-directed, minor groove interaction. However, the specificity of such interactions in the presence of a large selection of sequences such as the human genome is not known. We used the combinatorial selection method restriction endonuclease protection, selection, and amplification (REPSA) to determine the DNA binding specificity of two hairpin polyamides, ImPyPyPy-gamma-PyPyPyPy-beta-Dp and ImPyPyPy-gamma-ImPyPyPy-beta-Dp, in the presence of more than 134 million different sequences. These were verified by restriction endonuclease protection assays and DNase I footprinting analysis. Our data showed that both hairpin polyamides preferentially selected DNA sequences having consensus recognition sites as defined by the Dervan pairing rules. These consensus sequences were rather degenerate, as expected, given that the stacked pyrrole-pyrrole amino acid pairs present in both polyamides are unable to discriminate between A.T and T.A base pairs. However, no individual sequence within these degenerate consensus sequences was preferentially selected by REPSA, indicating that these hairpin polyamides are truly consensus-specific DNA-binding ligands. We also discovered a preference for overlapping consensus binding sites among the sequences selected by the hairpin polyamide ImPyPyPy-gamma-PyPyPyPy-beta-Dp, and confirmed by DNase I footprinting that these complex sites provide higher binding affinity. These data suggest that multiple hairpin polyamides can cooperatively bind to their highest-affinity sites.     

Two nearby sites bind zen protein independently

Summary The region upstream from the zerknullt (zen) gene contains three sites that specifically bind the zen protein product of the gene. Evidence for these binding sites was obtained by the filter binding technique and the DNase footprinting technique. The filter binding technique was used to scan various segments of DNA for the presence of possible specific binding sites. Segments that were selectively retained by the filter binding technique invariably contained one or more specific binding sites according to the DNase footprinting technique. Two of the zen protein binding sites were spaced only 30 base pairs apart. These sites could be separated without any loss in their specific binding properties. It is concluded that these two sites function independently in the binding of zen protein.     

Synthesis and evaluation of 9-aminoacridines derived from benzyne click chemistry

A small set of 9-aminoacridine-3- and 4-carboxamides were synthesized efficiently using the benzyne/azide click chemistry. The products bind to duplex DNA but have different antitumour activity in the HL60 cell line.     

DNA sequence dependent binding modes of 4',6-diamidino-2-phenylindole (DAPI)

The interactions of DAPI with natural DNA and synthetic polymers have been investigated by hydrodynamic, DNase I footprinting, spectroscopic, binding, and kinetic methods. Footprinting results at low ratios (compound to base pair) are similar for DAPI and distamycin. At high ratios, however, GC regions are blocked from enzyme cleavage by DAPI but not by distamycin. Both poly[d(G-C)]2 and poly[d(A-T)]2 induce hypochromism and shifts of the DAPI absorption band to longer wavelengths, but the effects are larger with the GC polymer. NMR shifts of DAPI protons in the presence of excess AT and GC polymers are significantly different, upfield for GC and mixed small shifts for AT. The dissociation rate constants and effects of salt concentration on the rate constants are also quite different for the AT and the GC polymer complexes. The DAPI dissociation rate constant is larger with the GC polymer but is less sensitive to changes in salt concentration than with the AT complex. Binding of DAPI to the GC polymer and to poly[d(A-C)].poly[d(G-T)] exhibits slight negative cooperativity, characteristic of a neighbor-exclusion binding mode. DAPI binding to the AT polymer is unusually strong and exhibits significant positive cooperativity. DAPI has very different effects on the bleomycin-catalyzed cleavage of the AT and GC polymers, a strong inhibition with the AT polymer but enhanced cleavage with the GC polymer. All of these results are consistent with two totally different DNA binding modes for DAPI in regions containing consecutive AT base pairs versus regions containing GC or mixed GC and AT base pair sequences. The binding mode at AT sites has characteristics which are similar to those of the distamycin-AT complex, and all results are consistent with a cooperative, very strong minor groove binding mode. In GC and mixed-sequence regions the results are very similar to those observed with classical intercalators such as ethidium and indicate that DAPI intercalates in DNA sequences which do not contain at least three consecutive AT base pairs.     

DNA sequence recognition by the indolocarbazole antitumor antibiotic AT2433-B1 and its diastereoisomer

The antibiotic AT2433-B1 belongs to a therapeutically important class of antitumor agents. This natural product contains an indolocarbazole aglycone connected to a unique disaccharide consisting of a methoxyglucose and an amino sugar subunit, 2,4-dideoxy-4-methylamino-L-xylose. The configuration of the amino sugar distinguishes AT2433-B1 from its diastereoisomer iso-AT2433-B1. Here we have investigated the interaction of these two disaccharide indolocarbazole derivatives with different DNA sequences by means of DNase I footprinting and surface plasmon resonance (SPR). Accurate binding measurements performed at 4 and 25 degrees C using the BIAcore SPR method revealed that AT2433-B1 binds considerably more tightly to a hairpin oligomer containing a [CG](4) block than to an oligomer with a central [AT](4) tract. The kinetic analysis shows that the antibiotic dissociates much more slowly from the GC sequence compared to the AT one. Preferential binding of AT2433-B1 to GC-rich sequences in DNA was independently confirmed by DNase I footprinting experiments performed with a 117 bp DNA restriction fragment. The specific binding sequence 5'-AACGCCAG identified from the footprints was then converted into a biotin-labeled DNA hairpin duplex and compound interactions with this specific sequence were characterized by high resolution BIAcore SPR experiments. Such a combined approach provided a detailed understanding of the molecular basis of DNA recognition. The discovery that the glycosyl antibiotic AT2433-B1 preferentially recognizes defined sequences offers novel opportunities for the future design of sequence-specific DNA-reading small molecules.     

Selective binding to AT sequences in DNA by an acridine-linked peptide containing the SPKK motif.

The sequence selectivity of binding to DNA by an acridine-linked peptide ligand has been investigated by means of footprinting methodologies. The ligand conjugates an anilino-acridine intercalating chromophore with the potentially minor groove binder octapeptide SPKKSPKK. This basic peptide corresponds to a highly conserved DNA recognition motif found in histone H1 and several other nonhistone proteins. Three complementary techniques using DNase I, hydroxyl radicals and osmium tetroxide as sequencing probes have been employed to evaluate both the sequence specificity of binding and the drug-induced conformational changes in DNA. The results converge to demonstrate the AT-selectivity and support a model in which the peptide moiety lies in the minor groove. DNA-binding sites of the conjugate are restricted to a few alternating AT-sequences proximal to GC-rich regions. Binding to homooligomeric runs of A and T is clearly disfavoured by the hybrid whereas such sequences represent preferred binding sites for the unsubstituted basic peptide. These differences reflect the influence of the anilino-acridine chromophore, which evidently contributes to the DNA recognition process allowing the peptide only to contact defined DNA sequences.     

Effects of length and position of an extended linker on sequence-selective DNA recognition of zinc finger peptides

Engineered zinc finger proteins revealed that a linker sequence connecting zinc finger units has a significant effect on the DNA binding property of the protein. The recognition for a noncontiguous DNA target beyond the current recognition code of zinc finger proteins has never been determined because of the limitation of a zinc finger framework. DNA recognition of zinc finger proteins is limited only to a contiguous subset of three base pairs. We propose the recognition for a noncontiguous DNA target by inserting amino acids into the canonical linker between zinc finger units. The sequence selectivity of the new zinc finger peptides was evaluated by gel mobility shift assays. DNase I footprinting analyses clearly showed different DNA binding of various linker-extended zinc finger peptides. The application of a SPR measurement also revealed a DNA sequence selectivity of peptides. Insertion of three amino acids is enough for recognition of a noncontiguous DNA target with sequence selectivity. An extended linker will be useful for expansion of the recognition code of zinc finger proteins and for development of a new role for linker sequences in DNA binding of zinc finger proteins.