Localization of Fe(2+) at an RTGR sequence within a DNA duplex explains preferential cleavage by Fe(2+) and H2O2

Nicking of duplex DNA by the iron-mediated Fenton reaction occurs preferentially at a limited number of sequences. Of these, purine-T-G-purine (RTGR) is of particular interest because it is a required element in the upstream regulatory regions of many genes involved in iron and oxidative-stress responses. In order to study the basis of this preferential nicking, NMR studies were undertaken on the RTGR-containing duplex oligonucleotide, d(CGCGATATGACACTAG)/d(CTAGTGTCATATCGCG). One-dimensional and two-dimensional 1H NMR measurements show that Fe(2+) interacts preferentially and reversibly at the ATGA site within the duplex at a rate that is rapid relative to the chemical-shift timescale, while selective paramagnetic NMR line-broadening of the ATGA guanine H8 suggests that Fe(2+) interacts with the guanine N7 moiety. Localization at this site is supported by Fe(2+) titrations of a duplex containing a 7-deazaguanine substitution in place of the guanine in the ATGA sequence. The addition of a 100-fold excess of Mg(2+) over Fe(2+) does not affect the Fe(2+)-dependent broadening. When the ATGA site in the duplex is replaced by ATGT, an RTGR site (GTGA) is created on the opposite strand. Preferential iron localization then takes place at the 3' guanine in GTGA but no longer at the guanine in ATGT, consistent with the lack of preferential cleavage of ATGT sites relative to ATGA sites.     

Sequence composition effects on the stabilities of triple helix formation by oligonucleotides containing N7-deoxyguanosine.

A nonnatural nucleoside, 7-(2-deoxy-beta-D-erythro-pento-furanosyl)-guanine (d7G), mimics protonated cytosine and specifically binds GC base pairs within a pyrimidine - purine - pyrimidine triple helix. The differences in association constants (KT) determined by quantitative footprint titration experiments at neutral pH reveal dramatic sequence composition effects on the energetics of triple helix formation by oligonucleotides containing d7G. Purine tracts of sequence composition 5'-d(AAAAAGAGAGAGAGA)-3' are bound by oligonucleotide 5'-d(TTTTT7GT7GT7GT7GT7GT)-3' three orders of magnitude less strongly than by 5'-d(TTTTTmCTmCTmCTmCTmCT)-3' (KT = 1.5 x 10(6) M(-1) and KT > or = 3 x 10(9) M(-1) respectively). Conversely, purine tracts of sequence composition 5'-d(AAAAGAAAAGGGGGGA)-3' are bound by oligonucleotide 5'-d(TTTTmCTTTT7G7G7G7G7G7GT)-3' five orders of magnitude more strongly than by 5'-d(TTTTmCTTTTmCmCmCmCmCT)-3' (KT > or = 3 x 10(9) M(-1) and KT < 5 x 10(4) M(-1) respectively). The complementary nature of d7G and mC expands the repertoire of G-rich sequences which may be targeted by triple helix formation.     

Sequence-specific binding of the influenza virus RNA polymerase to sequences located at the 5' ends of the viral RNAs.

The enzymatic activity of recombinant influenza virus RNA polymerase is strictly dependent on the addition of a template RNA containing 5' and 3' viral sequences. Here we report the analysis of the binding specificity and physical characterization of the complex by using gel shift, modification interference, and density gradient techniques. The 13S complex binds specifically to short synthetic RNAs that mimic the partially double stranded panhandle structures found at the termini of both viral RNA and cRNA. The polymerase will also bind independently to the single-stranded 5' or 3' ends of viral RNA. It binds most strongly to specific sequences within the 5' end but is unable to bind these sequences in the context of a completely double stranded structure. Modification interference analysis identified the short sequence motifs at the 5' ends of the viral RNA and cRNA templates that are critical for binding.     

Nonidentical DNA-binding sites of endonuclease NaeI recognize different families of sequences flanking the recognition site.

NaeI endonuclease uses a two-site binding mechanism to cleave substrate DNA: reaction-rate studies imply that occupancy of the second DNA site causes an allosteric change in the protein that enables DNA cleavage at the first site [Conrad, M., & Topal, M. D. (1989) Proc. Natl. Acad. Sci. U.S.A. 86, 9707-9711]. Measurements of relative binding affinities for 14-base-pair DNA fragments containing the NaeI recognition sequence GCCGGC and various flanking sequences showed that the two DNA-binding sites are not identical. G.C-rich flanking sequences were preferred by the activator binding site, whereas A.T-rich flanking sequences were preferred by the substrate binding site: GGGTGCCGGCAGGG was preferred 8-fold more by the activator site but 14-fold less by the substrate site than TTTCGCCGGCGTTT. Substitution of pyrimidine or 7-deazapurine for purine immediately 3' to GCCGGC reduced DNA affinity for only the activator site by up to 26-fold, implying that the activator DNA-binding site requires N-7 base contacts immediately flanking GCCGGC. The implications of nonidentical DNA-binding sites, one of which binds a specific DNA site to allosterically activate the other, are discussed.     

Locations and contexts of sequences that hybridize to poly(dG-dT).(dC-dA) in mammalian ribosomal DNAs and two X-linked genes.

Sequences located several kilobases both 5' and 3' of the stably transcribed portion of several genes hybridize to radio-labeled pure fragments of the alternating sequence poly (dG-dT) (dC-dA) ["poly(GT)"]. The genes include the ribosomal DNA of mouse, rat, and human, and also human glucose-6-phosphate dehydrogenase (G6PD) and mouse hypoxanthine-guanine phosphoribosyl transferase (HPRT). HPRT has additional hybridizing sequences in introns. Fragments that include the hybridizing sequences and up to 300 bp of adjoining DNA show perfect runs of poly(GT) (greater than 30bp) in all but the human 5' region of rDNA, which shows a somewhat different alternating purine:pyrimidine sequence, poly(GTAT) (36bp). Within 150 bp of these sequences in various instances are found a number of other sequences reported to affect DNA conformation in model systems. Most marked is an enhancement of sequences matching at least 67% to the consensus binding sequence for topoisomerase II. Two to ten-fold less of such sequences were found in other sequenced portions of the nontranscribed spacer or in the transcribed portion of rDNA. The conservation of the locations of tracts of alternating purine:pyrimidine between evolutionarily diverse species is consistent with a possible functional role for these sequences.     

Hydroxylation of deoxyguanosine at 5' site of GG and GGG sequences in double-stranded DNA induced by carbamoyl radicals

Free radicals generated by chemicals can cause sequence-specific DNA damage and play important roles in mutagenesis and carcinogenesis. Carbamoyl group (CONH 2 ) and its derived groups (CONR 2 ) occur as natural products and synthetic chemical compounds. We have investigated the DNA damage by carbamoyl radicals · (CONH 2 ), one of carbon-centered radicals. Electron spin resonance (ESR) spectroscopic study has demonstrated that carbamoyl radicals were generated from formamide by treatment with H 2 O 2 plus Cu(II), and from azodicarbonamide by treatment with Cu(II). We have investigated sequence specificity of DNA damage induced by carbamoyl radicals using 32 P-labeled DNA fragments obtained from the human c-Ha- ras -1 and p 53 genes. Treatment of double-stranded DNA with carbamoyl radicals induced an alteration of guanine residues, and subsequent treatment with piperidine or Fpg protein led to chain cleavages at 5'-G of GG and GGG sequences. Carbamoyl radicals enhanced Cu(II)/H 2 O 2 -mediated formation of 8-oxo-7,8-dihydro-2'-deoxyguanosine (8-oxodG) in double-stranded DNA more efficiently than that in single-stranded DNA. These results shows that carbamoyl radicals specifically induce hydroxylation of deoxyguanosine at 5' site of GG and GGG sequences in double-stranded DNA.     

DNA-binding activities of the Drosophila melanogaster even-skipped protein are mediated by its homeo domain and influenced by protein context.

The homeo box gene even-skipped (eve) encodes a 376-amino-acid protein that binds with high affinity to sequences located near the 5' termini of the eve and en genes. The 5' en sites are A + T rich and contain copies of the 10-base-pair (bp) consensus sequence T-C-A-A-T-T-A-A-A-T. In contrast, the 5' eve sites are G + C rich and contain the 9-bp sequence T-C-A-G-C-A-C-C-G. Among the five different homeo box proteins that have been tested for binding, eve is unique in that it shows virtually equal preference for the A + T-rich 5' en binding sites and the G + C-rich 5' eve sites. Most of the other proteins bind with a relatively higher affinity to the en sites than to the eve sites. In an effort to identify the regions of the eve protein that are responsible for its efficient binding to both classes of recognition sequences, we analyzed the DNA-binding properties of various mutant eve proteins. These studies suggest that the homeo domain of the eve protein is responsible for both binding activities. However, mutations in distant regions of the protein influenced the binding behavior of the eve homeo domain and caused a reduction in binding to the G + C class of recognition sites. We propose that the protein context of the homeo domain can influence its DNA-binding properties.     

Sequence-specific DNA cleavage by dipeptides disubstituted with chlorambucil and 2,6-dimethoxyhydroquinone-3-mercaptoacetic acid.

Two dipeptides, each containing a lysyl residue, were disubstituted with chlorambucil (CLB) and 2,6-dimethoxyhydroquinone-3-mercaptoacetic acid (DMQ-MA): DMQ-MA-Lys(CLB)-Gly-NH2 (DM-KCG) and DMQ-MA-beta-Ala-Lys(CLB)-NH2 (DM-BKC). These peptide-drug conjugates were designed to investigate sequence-specificity of DNA cleavage directed by the proximity effect of the DNA cleavage chromophore (DMQ-MA) situated close to the alkylating agent (CLB) inside a dipeptide moiety. Agarose electrophoresis studies showed that DM-KCG and DM-BKC possess significant DNA nicking activity toward supercoiled DNA whereas CLB and its dipeptide conjugate Boc-Lys(CLB)-Gly-NH2 display little DNA nicking activity. ESR studies of DMQ-MA and DM-KCG both showed five hyperfine signals centered at g = 2.0052 and are assigned to four radical forms at equilibrium, which may give rise to a semiquinone radical responsible for DNA cleavage. Thermal cleavage studies at 90 degrees C on a 265-mer test DNA fragment showed that besides alkylation and cleavage at G residues, reactions with DM-KCG and DM-BKC show a preference for A residues with the sequence pattern: 5'-G-(A)n-Pur-3' > 5'-Pyr-(A)n-Pyr-3' (where n = 2-4). By contrast, DNA alkylation and cleavage by CLB occurs at most G and A residues with less sequence selectivity than seen with DM-KCG and DM-BKC. Thermal cleavage studies using N7-deazaG and N7-deazaA-substituted DNA showed that strong alkylation and cleavage at A residues by DM-KCG and DM-BKC is usually flanked on the 3' side by a G residue whereas strong cleavage at G residues is flanked by at least one purine residue on either the 5' or 3' side. At 65 degrees C, it is notable that the preferred DNA cleavage by DM-KCG and DM-BKC at A residues is significantly more marked than for G residues in the 265-mer DNA; the strongest sites of A-specific reaction occur within the sequences 5'-Pyr-(A)n-Pyr-3'; 5'-Pur-(A)n-G-3' and 5'-Pyr-(A)n-G-3'. In pG4 DNA, cleavage by DM-KCG and DM-BKC is much greater than that by CLB at room temperature and at 65 degrees C. It was also observed that DM-KCG and DM-BKC cleaved at certain pyrimidine residues: C40, T66, C32, T34, and C36. These cleavages were also sequence selective since the susceptible pyrimidine residues were flanked by two purine residues on both the 5' and 3' sides or by a guanine residue on the 5' side. These findings strongly support the proposal that once the drug molecule is positioned so as to permit alkylation by the CLB moiety, the DMQ-MA moiety is held close to the alkylation site, resulting in markedly enhanced sequence-specific cleavage.     

Site-specific DNA damage at GGG sequence by oxidative stress may accelerate telomere shortening.

Telomere shortening during human aging has been reported to be accelerated by oxidative stress. We investigated the mechanism of telomere shortening by oxidative stress. H2O2 plus Cu(II) caused predominant DNA damage at the 5' site of 5'-GGG-3' in the telomere sequence. Furthermore, H2O2 plus Cu(II) induced 8-oxo-7,8-dihydro-2'-deoxyguanosine (8-oxodG) formation in telomere sequences more efficiently than that in non-telomere sequences. NO plus O2- efficiently caused base alteration at the 5' site of 5'-GGG-3' in the telomere sequence. It is concluded that the site-specific DNA damage at the GGG sequence by oxidative stress may play an important role in increasing the rate of telomere shortening with aging.     

Binding site of Fe3+ at purine of ATP as studied by NMR

The binding site of Fe3+ in the purine base of adenosine 5'-triphosphate (ATP) was studied by nuclear magnetic resonance (NMR). The NMR relaxation rates (R1) of 1H and 31P in ATP solutions free of and containing ferric ions were measured in the pH range of 3-10. It was found that Fe3+ selectively enhanced the relaxation rate of protons. In the presence of Fe3+, the R1 of H2 was much bigger than that of H8 at a lower pH (3-4.5), while at a higher pH (5.5-7.5) the R1 of H8 was more enhanced than H2. At a pH of around 5, both H2 and H8, as well as all three phosphorous, showed a sudden jump in R1. When pH>8, Fe3+ failed to show appreciable enhancement of R1 to all protons and phosphorous. The quantitative data of relaxation rate enhancements suggest that the binding site of Fe3+ in ATP is strongly dependent on pH. At lower pH values, Fe3+ binds N1 but at higher pH it binds to N7. When pH is around 5, the whole purine base donates the aromatic pi-electrons to the ferric ion, forming a ferrocene-like complex, while when pH>8, ATP could not form complexes with Fe3+.     

Endonuclease G: a (dG)n X (dC)n-specific DNase from higher eukaryotes.

An endonuclease activity (termed endonuclease G) that selectively cleaves DNA at (dG)n X (dC)n tracts has been partially purified from immature chicken erythrocyte nuclei. Sites where n greater than or equal to 9 are cleaved in a manner that resembles types II and III restriction nucleases. The nicking rate of the G-strand is 4- to 10-fold higher than that of the C-strand depending on the length of the (dG)n X (dC)n tract and/or nucleotide composition of the flanking sequences. Endonuclease G hydrolyzes (dG)24 X (dC)24 of supercoiled DNA in a bimodal way every 9-11 nucleotides, the maxima in one strand corresponding to minima in the opposite, suggesting that it binds preferentially to one side of the double helix. The nuclease produces 5' phosphomonoester ends and its activity is dependent on Mg2+ or Mn2+. The wide distribution and high relative activity of endonuclease G in a variety of tissues and species argues for a general role of the enzyme. The striking correlation between genetic instability and poly(dG) X poly(dC) tracts in DNA suggests that these sequences and endonuclease G are involved in recombination processes.     

5' terminal nucleotide sequences of the messenger RNA's of Dictyostelium discoideum.

As in the mRNA from all other eucaryotic cells examined, the 5' nucleotide in messenger RNA from Dictyostelium discoideum is linked by a 5'-5' triphosphate bridge to the unusual nucleoside 7-methyl guanosine. In mammalian cellular mRNA, the 5' terminal sequences have the general formula m7GpppXmpYp(m), where X and Y can be either purine or pyrimidine nucleotides and Y, as well as X, may contain a 2'0-methylated ribose. Although at least 32 5' terminal sequences are possible in cellular mRNA, only four are present in Dictyostelum mRNA. They are (I) m7GppppAp (65%); (II) m7GpppGp (10%); (III) m7GpppAmpAp (10%); (IV m7GpppAp (65%); (II) m7gpppGp (10%); (III) m7GpppAmpAp (10%); (IV) m7GpppAmpUp (10%). Sequences I and II are simpler than those previously reported for mammalian cells because they lack 2'0-methylated nucleosides. Another difference is that in all Dictyostelium mRNAs. the nucleoside X is a purine. The nucleoside 6-methyl adenosine which is found internal to the 5' end of the mRNA of mammalian cells is not detectable in Dictyostelium mRNA. Thus neither 2'0-methylated nucleotides nor 6-methyl adenosine can represent sites for processing of a primary nuclear transript to yield mRNA.     

Studies on the base pair binding specificity of CC-1065 to oligomer duplexes

In this paper, we report on the base pair binding specificity of CC-1065 to oligomer duplexes of several lengths and base composition as determined by circular dichroism (CD) methods. The oligomers are synthesized using the phosphoramidite triester coupling approach and purified by either polyacrylamide gel electrophoresis or anion-exchange HPLC. CC-1065 binds by two different mechanisms to form a reversibly bound species and an irreversibly bound species, both of which show intense induced CD bands. The reversible to irreversible binding transition is characterized by a shift of the CD band to shorter wavelength (392----371 nm) characteristic of the reaction between the cyclopropyl group of CC-1065 and the N-3 of adenine. The induced CD acquired by the CC-1065 chromophore increases with increasing oligomer chain length and with an increase in the number of bases to the 5' end of the site of attachment whether a purine or a pyrimidine is at position 5 (or 4) from the site of attachment at the 3' end is not crucial for binding. The binding sequences 5'-GATAT and 5'-GTATA show a slower conversion to an irreversibly bound species relative to the preferred sequences 5'-AAA and 5'-TTA. A G base pair at position 3 in 5'-AAGAA hinders the formation of the irreversibly bound species relative to the 5'-GAAAA and 5'-AGAAA sequences. Very stable reversible binding is observed with the sequences 5'-GAATT and 5'-AAGAA. The sequences 5'-GCGAA and 5'-AGAG also show reversible binding but are characterized by a relatively small induced molar ellipticity which decreases with time. These binding characteristics signify weaker binding for these sequences. Overall, these binding studies agree with earlier sequence studies which found two preferred binding sequences, 5'-AAAAA and 5'-PuNTTA, with CC-1065 attached to the 3' end of the binding site. Furthermore, according to studies of the oligomer 5'-CGCGAATTCGCG-3' under different experimental conditions, the annealing conditions of this work produced oligomer duplex structures, not hairpin structures. In these studies, we found that CC-1065 binds very little or not at all to hairpin structures.     

Multiple sequence-specific DNA binding activities are eluted from chicken nuclei at low ionic strengths.

DNA sequence-specific binding proteins eluted from chicken erythrocyte and thymus nuclei, and fractionated as described by Emerson and Felsenfeld (19), have been investigated by filter binding and footprint analyses. The erythrocyte nuclear protein fraction specifically binds to at least two sites within the 5' flanking chromatin hypersensitive site of the chicken beta A-globin gene, and to a site 5' to the human beta-globin gene. The major chicken beta A globin gene binding site [G)18CGGGTGG) and the human beta-globin gene binding site [TA)6(T)8C(T)4) occur at or near sequences which are hypersensitive to S1 nuclease cleavage in supercoiled plasmids. Downstream, the second chicken beta A-globin gene binding site includes the beta-globin gene CACCC consensus sequence. Filter binding studies also show other sequence specific binding activities to human N-ras and human (but not chicken) c-myc gene sequences.     

Micrococcal nuclease as a DNA structural probe: its recognition sequences, their genomic distribution and correlation with DNA structure determinants

We have analyzed micrococcal nuclease (MNase) DNA cleavage patterns at the sequence level by examining 2.3 X 10(3) base-pairs of data derived from the Drosophila melanogaster 44D larval cuticle locus. Within this region, MNase preferentially cleaved 140 sites. Clusters of these sites appear to generate the preferential MNase eukaryotic DNA cleavage sites seen on agarose gels at roughly 100 to 300 base-pair intervals. These clusters of preferential cleavage sites rarely occur within gene coding regions. The analysis revealed that duplex DNA sequences preferentially cleaved by MNase are generally determined by a single strand sequence: d(A-T)n, where n greater than or equal to 1, flanked by a 5' dC or dG. Cleavage of the other strand is generally staggered 5' by several nucleotides and occurs even if such sequences are absent on that strand. An empirical predictive DNA cleavage model derived from a statistical analysis of the sequence level data was applied to seven eukaryotic gene loci of known sequence. The predicted patterns were in good general agreement with the previously observed eukaryotic gene/spacer cleavage pattern. Statistical analysis also revealed that sites of predicted preferential DNA cleavage occur less frequently in protein coding regions than for randomized sequences of the same length and nucleotide content. Comparison of the MNase cleavage patterns to the sequence-dependent pattern of binding energies between duplex DNA strands indicates that MNase preferentially cleaves sequences with low helix stability.     

Preferential binding to DNA sequences of peptides related to a novel XPRK motif

Two dodecapeptide amines: (WPRK)(3)NH(2)[WR-12] and (YPRK)(3)NH(2)[YR-12], and a 30-mer polypeptide amide (SP-30) were synthesized by solid-phase peptide methodology. DNase I footprinting studies on a 117-mer DNA showed that WR-12 and YR-12 bind selectively to DNA sequences in a manner similar to SP-30 which has a repeating SPK(R)K sequence. The most distinctive blockages seen with all three peptides occur at positions 26-30, 21-24 and 38-45 around sequences 5'-GAATT-3', 5'-TAAT-3' and 5'-AAAACGAC-3', respectively. However, it appears that YR-12 is better able to extend its recognition site to include CG pairs than is SP-30. At low concentrations YR-12 was able to induce enhanced rates of DNase I cleavage at regions surrounding some of its binding sites. To obtain further quantitative data supplementary to the footprinting work, equilibrium binding experiments were performed in which the binding of the two peptides to six decanucleotide duplexes was compared. Scatchard analyses indicated that WR-12 may be more selective for oligomers containing runs of consecutive purines or pyrimidines. On the other hand, YR-12 binds better to d(CTTAGACGTC)- d(GACGTCTAAG) than to the other oligomer duplexes, denoting selectivity for evenly distributed C/G and A/T sequences.     

Identification of nucleotide preferences in DNA sequences recognised specifically by c-Ets-1 protein.

The protooncogene Ets-1 is a member of the c-Ets family of genes originally identified through their sequence homology to the v-ets gene of the avian erythroblastosis virus E26. Ets-like factors are characterised by a conserved 85 amino acid domain which appears to be essential for binding to purine rich DNA sequences. Sequences binding to Ets-1 were selected from a random oligonucleotide pool by immunoprecipitation and amplified using the Polymerase Chain Reaction. Oligonucleotides enriched by this procedure were cloned in plasmids and sequenced. Alignment of DNA sequences revealed GGAA and GGAT cores at about a 1.4:1 ratio. Preferred sequences were identified both 5' and 3' of the GGAW core, extending the binding site to ACMGGAWRTT. Analysis of the flanking sequences associated with GGAA and GGAT cores revealed differences which may have compensated for the generally lower affinity of binding sites containing a GGAT core. Lastly mutational analysis of one particular Ets-1 binding site was used to establish the relative importance for binding of some nucleotides within the core and to show that Ets-1 and the closely related Ets-2 proteins bind to similar sequences.