Structural comparison of the B-DNA dodecamers d(CGCGTTAACGCG) and d(CGCGAATTCGCG) with T2A2 and A2T2 tracts.

The x-ray structure of the deoxy oligonucleotide dodecamer d(CGCGTTAACGCG) recently determined in our laboratory shows that the helical parameters of the central TTAA segment are significantly different compared to the central AATT in d(CGCGAATTCGCG). The roll in the central TA step of the T2A2 dodecamer opens towards the minor groove while the AT step of the A2T2 dodecamer opens towards the major groove. Also, the roll angles at the steps 4 and 8 (GT and AC in T2A2) and (GA and TC in A2T2) are in opposite directions. The high cup and helical twist angles at the central base-pair of T2A2 decreases the base stacking interactions compared to A2T2. Tilt angles within the tetranucleotide segments TTAA and AATT have opposite signs. In spite of the local differences caused by the sequence inversion (TTAA----AATT), the two dodecamers exhibit similar overall bending. The top third is more bent than the bottom third relative to the central segment. This asymmetric bending in the two dodecamers is mainly due to crystal packing interactions.     

Sequence-dependent anisotropic flexibility of B-DNA. A conformational study

Bending flexibility of the six tetrameric duplexes was investigated d(AAAA):d(TTTT), d(AATT)2, d(TTAA)2, d(GGGG):d(CCCC), d(GGCC)2 and d(CCGG)2,. The tetramers were extended in the both directions by regular double helices. The stiffness of the B-DNA double helix when bent into the both grooves proved to be less than that in the perpendicular direction by an order of magnitude. Such an anisotropy is a property of the sugar-phosphate backbone structure. The calculated fluctuations of the DNA bending along the dyad axis, 5-7 degree, are in agreement with experimental value of the DNA persistence length. Anisotropy of the double helix is sequence-dependent: most easily bent into the minor groove are the tetramers with purine-pyrimidine dimer (RY) in the middle. In contrast, YR dinucleotides prefer bending into the major groove. Moreover, they have an equilibrium bend of 6-12 degree into this groove. The above inequality is caused by stacking interaction of the bases. The bend in the central dimer is distributed to some extent between the adjacent links, though the main fraction of the bend remains within the central link. Variation of the sugar-phosphate geometry in the bent helix is inessential, so that DNA remains within the B-family of forms: namely, when the helical axis is bent by 20 degree. the backbone dihedral angles vary by no more than 15 degree. The obtained results are in accord with x-ray structure of the B-DNA dodecamer; they further substantiate our early model of DNA wrapping in the nucleosome by means of "mini-kinks" separated by a half-pitch of the double helix, i.e. by 5-6 b.p. Sequence-dependent anisotropy of DNA presumably dictates the three-dimensional structure of DNA in solution as well. We have found that nonrandom allocation of YR dimers leads to the systematic bends in equilibrium structure of certain DNA fragments.     

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.     

Ordered distribution of modified bases in the DNA of a dinoflagellate.

In DNA of the dinoflagellate Crypthecodinium cohnii, 38% of the thymine is replaced by the modified base 5-hydroxymethyluracil, and approximately 3% of the cytosine is replaced by 5-methylcytosine. Both of the modified bases are non-randomly distributed in the DNA. Determinations of 3' nearest neighbors show that HOMeU is preferentially located in the dinucleotides HOMeUpA and HOMeUpC. Pyrimidine tract analysis shows that HOMeU is also greatly enriched in the trinucleotide purine-HOMeU-purine. As in other eukaryotes, methylcytosine in C. cohnii DNA occurs predominantly in the dinucleotide MeCpG. By analysis of restriction endonuclease digestion patterns of C. cohnii total DNA and ribosomal DNA, we have found that the central CpG dinucleotides in the sites for the enzymes Hpa II (CCGG) and Hha I (GCGC) are extensively methylated in both total DNA and ribosomal DNA. Results of digestion with Ava I, however, indicated that not all CpG dinucleotides in the sequence CCTCGGAG are methylated in C. cohnii DNA.     

DNA Minor Groove Induced Dimerization of Heterocyclic Cations: Compound Structure, Binding Affinity, and Specificity for a TTAA Site

With the increasing number and variations of genome sequences available, control of gene expression with synthetic, cell-permeable molecules is within reach. The variety of sequence-specific binding agents is, however, still quite limited. Many minor groove binding agents selectivity recognize AT over GC sequences but have less ability to distinguish among different AT sequences. The goal with this article is to develop compounds that can bind selectively to different AT sequences. A number of studies indicate that AATT and TTAA sequences have significantly different physical and interaction properties and different requirements for minor groove recognition. Although it has been difficult to get minor groove binding at TTAA, DB293, a phenyl-furan-benzimidazole diamidine, was found to bind as a strong, cooperative dimer at TTAA but with no selectivity over AATT. In order to improve selectivity, we made modifications to each unit of DB293. Binding affinities and stoichiometries obtained from biosensor-surface plasmon resonance experiments show that DB1003, a furan-furan-benzimidazole diamidine, binds strongly to TTAA as a dimer and has selectivity (K_TTAA/K_AATT = 6). CD and DNase I footprinting studies confirmed the preference of this compound for TTAA. In summary, (i) a favorable stacking surface provided by the pi system, (ii) H-bond donors to interact with TA base pairs at the floor of the groove provided by a benzimidazole (or indole) -NH and amidines, and (iii) appropriate curvature of the dimer complex to match the curvature of the minor groove play important roles in differentiating the TTAA and AATT minor grooves.     

Isolation of altered specificity mutants of the single-chain 434 repressor that recognize asymmetric DNA sequences containing the TTAA and TTAC subsites.

A novel single-chain (sc) protein framework containing covalently dimerized DNA-binding domains (DBD) of the phage 434 repressor was used to construct combinatorial mutant libraries in order to isolate mutant DBDs with altered specificities. The library members contain one wild-type DBD and one mutant domain with randomized amino acids in the DNA-contacting region. Based on previous studies, the mutant sc derivatives are expected to recognize a general ACAA-6 bp-NNNN sequence, where ACAA is contacted by the wild-type and NNNN by the mutant domain. In principle, any sequence can stand for NNNN and serve as a selection target. Here an in vivo library screening method was used to isolate mutant sc repressors that interact with an asymmetric operator containing the TTAA target. Several mutants showed high affinity in vitro binding to operators containing the target and strong (up to 80-fold) preference for the TTAA target over the wild-type TTGT. Specificity studies revealed that certain mutants bound with substantially higher affinities (K(d) approximately 10(-11)M) to operators containing the TTAC sequence, a close homolog of the TTAA target. Thus, we have fortuitously isolated mutant sc repressors that show up to a several hundred-fold preference for TTAC over TTGT.     

Sequence-Dependent Anisotropic Flexibility of B-DNA A Conformational Study

Abstract

Bending flexibility of the six tetrameric duplexes was investigated d(AAAA):d(TTTT), d(AATT)₂, d(TTAA) ₂, d(GGGG):d(CCCC), d(GGCC) ₂ and d(CCGG) ₂. The tetramers were extended in the both directions by regular double helices. The stiffness of the B-DNA double helix when bent into the both grooves proved to be less than that in the perpendicular direction by an order of magnitude. Such an anisotropy is a property of the sugar-phosphate backbone structure. The calculated fluctuations of the DNA bending along the dyad axis, 5–7°, are in agreement with experimental value of the DNA persistence length.

Anisotropy of the double helix is sequence-dependent: most easily bent into the minor groove are the tetramers with purine-pyrimidine dimer (RY) in the middle. In contrast, YR dinucleotides prefer bending into the major groove. Moreover, they have an equilibrium bend of 6–12° into this groove. The above inequality is caused by stacking interaction of the bases.

The bend in the central dimer is distributed to some extent between the adjacent links, though the main fraction of the bend remains within the central link. Variation of the sugar-phosphate geometry in the bent helix is inessential, so that DNA remains within the B-family of forms: namely, when the helical axis is bent by 20°, the backbone dihedral angles vary by no more than 15°.

The obtained results are in accord with x-ray structure of the B-DNA dodecamer; they further substantiate our early model of DNA wrapping in the nucleosome by means of “mini-kinks” separated by a half-pitch of the double helix, i.e. by 5–6 b.p. Sequence-dependent anisotropy of DNA presumably dictates the three-dimentional structure of DNA in solution as well. We have found that nonrandom allocation of YR dimers leads to the systematic bends in equilibrium structure of certain DNA fragments.     

Functional homology between the sequence-specific DNA-binding proteins nuclear factor I from HeLa cells and the TGGCA protein from chicken liver.

Nuclear factor I from HeLa cells, a protein with enhancing function in adenovirus DNA replication, and the chicken TGGCA protein are specific DNA-binding proteins that were first detected by independent methods and that appeared to have similar DNA sequence specificity. To test whether they are homologous proteins from different species we have compared (i) their DNA binding properties and (ii) their function in reconstituted adenovirus DNA replication systems. Using deletion and substitution mutants derived from the DNA binding site on the adenovirus 2 inverted terminal repeat, it was found that the two proteins protect the same 24-nucleotide region of both strands against DNase I digestion and that they have identical minimal recognition sequences of 15 bp containing dyad symmetry. Like nuclear factor I, the TGGCA protein enhances the initiation reaction of adenovirus 2 DNA replication in vitro in a DNA recognition site-dependent manner.     

Site-specific DNA binding of nuclear factor I: analyses of cellular binding sites.

Nuclear factor I is a cellular site-specific DNA-binding protein required for the efficient in vitro replication of adenovirus DNA. We have characterized human DNA sequences to which nuclear factor I binds. Three nuclear factor I binding sites (FIB sites), isolated from HeLa cell DNA, each contain the sequence TGG(N)6-7GCCAA. Comparison with other known and putative FIB sites suggests that this sequence is important for the binding of nuclear factor I. Nuclear factor I protects a 25- to 30-base-pair region surrounding this sequence from digestion by DNase I. Methylation protection studies suggest that nuclear factor I interacts with guanine residues within the TGG(N)6-7GCCAA consensus sequence. One binding site (FIB-2) contained a restriction endonuclease HaeIII cleavage site (GGCC) at the 5' end of the GCCAA motif. Digestion of FIB-2 with HaeIII abolished the binding of nuclear factor I. Southern blot analyses indicate that the cellular FIB sites described here are present within single-copy DNA in the HeLa cell genome.     

Single‐chain 434 repressors with altered DNA‐binding specificities

Combinatorial mutant libraries of the single-chain 434 repressor were used to discover novel DNA-binding specificities. Members of the library contain one wild type domain and one mutant domain which are connected by a recombinant peptide linker. The mutant domain contains randomized amino acids in place of the DNA-contacting residues. The single-chain derivatives are expected to recognize artificial operators containing the DNA sequence of ACAA — 6 base-pairs — NNNN, where ACAA is bound by the wild-type and NNNN by the mutant domain. An invivo library screening method was used to isolate mutant DNA-binding domains which recognize the TTAA site of an asymmetric operator. Several mutants showed high affinity binding to the selection target and also strong (up to 80 fold) preference for TTAA over the wild type TTGT sequence. Some of the isolated mutants bound with very high affinities (10–50 pM) to operators containing the TTAC sequence, a close homologue of the TTAA selection target.This revised version was published online in October 2005 with corrections to the Cover Date.     

Determination and analysis of the primary structure of the nerve terminal specific phosphoprotein, synapsin I.

A rat brain cDNA clone containing an open reading frame encoding the neuron-specific protein synapsin I has been sequenced. The sequence predicts a protein of 691 amino acids with a mol. wt of 73 kd. This is in excellent agreement with the size of rat brain synapsin Ib measured by SDS--polyacrylamide gel electrophoresis. Inspection of the predicted primary structure has revealed the probable sites for synapsin I phosphorylation by the cAMP-dependent and Ca2+/calmodulin-dependent protein kinases. All of the biochemically observed intermediates of synapsin I digestion by collagenase can be verified by inspection of the sequence, and the collagenase-resistant fragment has been defined as the amino-terminal 439 amino acids of the molecule. Predictions of sequence secondary structure and hydrophobicity suggest that a central domain of approximately 270 amino acids may exist as a folded, globular core. The carboxyl-terminal domain of the protein (the region sensitive to collagenase digestion) contains sites for Ca2+/calmodulin-dependent protein kinase phosphorylation. These sites are flanked by three regions of repeating amino acid sequence that are proposed to be the synaptic vesicle-binding domain of synapsin I. This region also shares homology with the actin-binding proteins profilin and villin. The characteristics of the synapsin I sequence do not support extensive homology with the erythrocyte cytoskeletal protein 4.1.     

Nucleosome core particle self-assembly kinetics and stability at physiological ionic strength

Micrococcal nuclease, DNase I, and trypsin have been employed to study the kinetics of core particle self-assembly by salt jump from 2.0 to 0.2 M NaCl. A few seconds after the initiation of the reassociation reaction, the bulk of core particle DNA becomes protected from digestion by micrococcal nuclease, whereas free DNA, under the same conditions, is completely hydrolyzed. The central and C-terminal regions of core histones are also protected from trypsin digestion immediately after the 2.0-0.2 M NaCl salt jump. Moreover, the extent of degradation produced by trypsin is the same for samples digested a few seconds after the salt jump and for samples digested 20 min after the salt jump. With DNase I, minor structural differences have been detected between samples obtained at different times during the reaction. However, even in this case our results indicate that many of the characteristic histone-DNA contacts within the core particle are made a few seconds after the initiation of the self-assembly reaction. Furthermore, core particles have been labeled with the fluorescent reagent N-(1-pyrenyl)maleimide (NPM), which was previously used as a sensitive probe for nucleosome conformation. Extensive DNase I or trypsin digestion of NPM-labeled core particles in 0.2 M NaCl does not produce significant changes in excimer fluorescence. This allows us to conclude that the covalent continuity of DNA is not required for the maintenance of the folded conformation of the core particle and that the trypsin-resistant domains of core histones play a fundamental role in the stabilization of this structure.     

DNA bending and its relation to nucleosome positioning

X-ray and solution studies have shown that the conformation of a DNA double helix depends strongly on its base sequence. Here we show that certain sequence-dependent modulations in structure appear to determine the rotational positioning of DNA about the nucleosome. Three different experiments are described. First, a piece of DNA of defined sequence (169 base-pairs long) is closed into a circle, and its structure examined by digestion with DNAase I: the helix adopts a highly preferred configuration, with short runs of (A, T) facing in and runs of (G, C) facing out. Secondly, the same sequence is reconstituted with a histone octamer: the angular orientation around the histone core remains conserved, apart from a small uniform increase in helix twist. Finally, it is shown that the average sequence content of DNA molecules isolated from chicken nucleosome cores is non-random, as in a reconstituted nucleosome: short runs of (A, T) are preferentially positioned with minor grooves facing in, while runs of (G, C) tend to have their minor grooves facing out. The periodicity of this modulation in sequence content (10.17 base-pairs) corresponds to the helix twist in a local frame of reference (a result that bears on the change in linking number upon nucleosome formation). The determinants of translational positioning have not been identified, but one possibility is that long runs of homopolymer (dA) X (dT) or (dG) X (dC) will be excluded from the central region of the supercoil on account of their resistance to curvature.     

Restriction enzyme digests of rapidly renaturing fragments of vaccinia virus DNA.

Vaccinia virus DNA fragments that have been denatured by alkali and then neutralized contain a fraction that rapidly reforms duplex structures. The fraction is enriched by fractionating on hydroxyapatite columns and serves as as substrate for digestion by two restriction endonucleases isolated from Hemophilus parainfluenzae, Hpa I and HPa II. The patterns obtained by gel electrophoresis of the digested fragments show the presence of three major bands after Hpa I digestion and four major bands after Hpa II digestion. The DNA that is isolated from some of these bands quickly reforms duplex regions after alkaline denaturation. The size of the DNA segments in the major bands has been estimated to be in the range of 0.44 X 10(6) to 3.2 X 10(6) daltons. The fragments which rapidly reform duplex chains after denaturation are sensitive to single-strand-specific nucleases. These results are consistent with a model of vaccinia virus DNA which has a covalent link connecting complementary chains.     

Studies on activities, cell uptake and DNA binding of four trans-planaramineplatinum(II) complexes of the form: trans-PtL(NH3)Cl2, where L=2-hydroxypyridine, imidazole, 3-hydroxypyridine and imidazo(1,2-alpha)pyridine

Four trans-planaramineplatinum(II) complexes code named YH9, YH10, YH11 and YH12 each of the form trans-PtL(NH(3))Cl(2), where L=2-hydroxypyridine and 3-hydroxypyridine, imidazole, and imidazo(1,2-alpha)pyridine for YH9, YH10, YH11 and YH12, respectively, have been synthesized and the activity of the compounds against human cancer cell lines, cell uptake, DNA-binding and nature of interaction with pBR322 plasmid DNA have been studied. The compound having imidazo(1,2-alpha)pyridine ligand as one the carrier ligands in the trans-configuration is found to be significantly more active than cis-platin against ovarian A2780(cisR) cancer cell line corresponding with higher Pt-DNA binding. All other compounds have resistance factors less than that for cis-platin in the A2780 and A2780(cisR) cell lines. A greater prevention of BamH1 digestion with increasing concentration of the compounds indicates that as the compounds bind with nucleobases in DNA, the DNA conformation is changed sufficiently so as to prevent BamH1 digestion at the specific GG site. Gel electrophoresis results also indicate that as the compounds bind to DNA, unwinding of supercoiled form I DNA takes place to change it from the negatively supercoiled form I through relaxed circular form I to the positively supercoiled form I.     

PspGI,a type II restriction endonuclease from the extreme thermophile Pyrococcus sp.: structural and functional studies to investigate an evolutionary relationship with several mesophilic restriction enzymes

We present here the first detailed biochemical analysis of an archaeal restriction enzyme. PspGI shows sequence similarity to SsoII, EcoRII, NgoMIV and Cfr10I, which recognize related DNA sequences. We demonstrate here that PspGI, like SsoII and unlike EcoRII or NgoMIV and Cfr10I, interacts with and cleaves DNA as a homodimer and is not stimulated by simultaneous binding to two recognition sites. PspGI and SsoII differ in their basic biochemical properties, viz. stability against chemical denaturation and proteolytic digestion, DNA binding and the pH, MgCl(2) and salt-dependence of their DNA cleavage activity. In contrast, the results of mutational analyses and cross-link experiments show that PspGI and SsoII have a very similar DNA binding site and catalytic center as NgoMIV and Cfr10I (whose crystal structures are known), and presumably also as EcoRII, in spite of the fact that these enzymes, which all recognize variants of the sequence -/CC-GG- (/ denotes the site of cleavage), are representatives of different subgroups of type II restriction endonucleases. A sequence comparison of all known restriction endonuclease sequences, furthermore, suggests that several enzymes recognizing other DNA sequences also share amino acid sequence similarities with PspGI, SsoII and EcoRII in the region of the presumptive active site. These results are discussed in an evolutionary context.     

Formation, stability and core histone positioning of nucleosomes reassembled on bent and other nucleosome-derived DNA

DNA originating from chicken erythrocyte mononucleosomes was cloned and sequenced. The properties of nucleosome reconstruction were compared for two cloned inserts, selected on account of their interesting sequence organization, length and difference in DNA bending. Cloned fragment 223 (182 base-pairs) carries alternatively (A)3-4 and (T)4-5 runs approximately every ten base-pairs and is bent; cloned fragment 213 (182 base-pairs) contains a repeated C4-5ATAAGG consensus sequence and is apparently not bent. Our experiments indicate the preference of the bent DNA fragment 223 over fragment 213 to associate in vitro with an octamer of histones under stringent conditions. We provide evidence that the in vitro nucleosome formation is hampered in the case of fragment 213, whereas the reconstituted nucleosomes were equally stable once formed. For the correct determination of the positioning of the histone octamer with regard to the two nucleosome-derived cloned DNA sequences, the complementary use of micrococcal nuclease, exonuclease III and DNase I is a prerequisite. No unique, but rotationally related, positions of the histone octamer were found on these nucleosome-derived DNA fragments. The sequence-dependent anisotropic flexibility, as well as intrinsic bending of the DNA, resulting in a rotational setting of the DNA fragments on the histone core, seems to be a strong determinant for the allowed octamer positions, Exonuclease III digestion indicates a different histone-DNA association when oligo(d(C.G)n) stretches are involved. The apparent stagger near oligo(d(A.T)n) stretches generated by DNase I digestion on reconstituted nucleosome 223 was found to be inverted from the normal two-base 3' overhang to a two-base 5' overhang. Two possibilities of the oligo(d(A.T)n) minor groove location relative to the histone core are envisaged to explain this anomaly in stagger.     

Conformational variations in d(TGACGTCA) and its reverse sequence d(ACTGCAGT): a joint circular dichroism and nuclear magnetic resonance study

Circular dichroism (CD) and nuclear magnetic resonance (NMR) techniques have been used to characterize the structural properties of the two self-complementary DNA octamers d(TGACGTCA) (I) and d(ACTGCAGT) (II). These display as distinctive features reverse sequences and central steps CpG and GpC, respectively. CD experiments lead to B-form DNA spectra characterized by larger magnitude signals in the case of octamer (I). NMR COSY spectra indicate that in the two octamers all the residues are predominantly south, S, (2'-endo) sugar conformation. NMR NOESY spectra show most of the glycosidic angles confined in the range predicted for B-form DNA although important heterogeneity is noticed along the chains, more pronounced in the case of octamer (I). Both the increase of north, N, (3'-endo) sugar conformation and P (pseudorotation phase angle) deviation from its standard B-form DNA value (162 degrees) express local sequence dependent structure distortions, remarkably visible in CpG step of octamer (I) and agreeing with NOESY cross-peaks intensities. Results interpreted according to Calladine's rules indicate higher cross-chain strains in octamer (I) than in octamer (II). All together, we find evidence to support for octamer (I) in solution local structures with A-DNA properties likely dictated by the central CpG step. Such structures could be involved in the DNA recognition by proteins and anticancerous drugs.     

Actinomycin D induced DNase I cleavage enhancement caused by sequence specific propagation of an altered DNA structure.

Two DNA hexadecamers containing one central 5'-GC-3' base step have been examined by footprinting methodology in the presence and absence of actinomycin D. The results of these studies, coupled with imino proton NMR measurements indicate that the antitumor drug causes a change in DNA conformation at a distance from the actinomycin intercalation site in a molecule of sequence d[ATATATAGCTATATAT] that does not occur in d[AAAAAAAGCTTTTTTT]. The experiments demonstrate that DNase I rate enhancements associated with actinomycin D binding are caused by ligand alteration of equilibrium DNA structure.