Effects of poly[d(pGpT).d(pApC)] and poly[d(pCpG).d(pCpG)] repeats on homologous recombination in somatic cells.

Sequencing studies have shown that in somatic cells alternating runs of purines and pyrimidines are frequently associated with recombination crossover points. To test whether such sequences actually promote recombination, we have examined the effects of poly[d(pGpT).d(pApC)] and poly[d(pCpG).d(pCpG)] repeats on a homologous recombination event. The parental molecule used in this study, pSVLD, is capable of generating wild-type simian virus 40 DNA via recombination across two 751-base-pair regions of homology and has been described previously (Miller et al., Proc. Natl. Acad. Sci. USA 81:7534-7538, 1984). Single inserts of either a poly[d(pGpT).d(pApC)] repeat or a poly[d(pCpG).d(pCpG)] repeat were positioned adjacent to one region of homology in such a way that the recombination product, wild-type simian virus 40 DNA, could be formed only by recombination within the homologies and not by recombination across the alternating purine-pyrimidine repeats. We have found that upon transfection of test DNAs into simian cells, a poly[d(pCpG).d(pCpG)] repeat enhanced homologous recombination 10- to 15-fold, whereas a poly[d(pGpT).d(pApC)] repeat had less effect. These results are discussed in terms of the features of these repeats that might be responsible for promoting homologous recombination.     

Characterization of a multisubunit human protein which selectively binds single stranded d(GA)n and d(GT)n sequence repeats in DNA.

A protein which selectively binds d(GA)n and d(GT)n sequence repeats in single stranded DNA has been identified in human fibroblasts. This protein, designated PGB, has been purified at least 500-fold by ammonium sulfate precipitation followed by DEAE-Sepharose column chromatography and affinity chromatography in a column of d(GA)-Sepharose. Electrophoretic mobility shift assays revealed that the PGB protein bound most avidly d(GA)n and d(GT)n tracts of n > 5. It also bound other G-rich DNA sequence repeats, including dGn tracts, with lower affinities. It did not manifest significant binding affinities to single stranded M13 DNA, or to the homopolynucleotides poly dA, poly dC and poly dT, or to various DNA sequence repeats which do not contain G residues, such as d(A-C)n and d(TC)n. It did not bind double stranded d(T-C)n.d(GA)n tracts or other double stranded DNA sequences. In glycerol gradient centrifugation assays the d(GA)n- and the d(GT)n-binding activities cosedimented as a homogeneous protein species having an S20,w = 9.4 +/- 0.7 and an estimated native molecular weight of 190,000 +/- 7,000. UV crosslinking assays revealed that the protein contains 33.6 +/- 2.1 kd subunits which bind d(GA)n and d(GT)n sequences. However, SDS-polyacrylamide gel electrophoresis of the purified protein followed by silver staining indicated that it may also contain other subunits that do not contact the DNA. It is proposed that binding of the PGB protein to single stranded d(GA)n or d(GT)n tracts in double stranded topologically restricted DNA may stimulate strand separation and formation of triple helices or other unusual DNA structures.     

Proton and phosphorus NMR studies of d-CpG(pCpG)n duplexes in solution. Helix-coil transition and complex formation with actinomycin-D.

The Watson–Crick imino and amino exchangeable protons, the nonexchangeable base and sugar protons, and the backbone phosphates for d-CpG(pCpG)_n, n = 1 and 2, have been monitored by high-resolution nmr spectroscopy in aqueous solution over the temperature range 0°–90°C. The temperature dependence of the chemical shifts of the tetramer and hexamer resonances is consistent with the formation of stable duplexes at low temperature in solution. Comparison of the spectral characteristics of the tetranucleotide with those of the hexanucleotide with temperature permits the differentiation and assignment of the cytosine proton resonances on base pairs located at the end of the helix from those in an interior position. There is fraying at the terminal base pairs in the tetranucleotide and hexanucleotide duplexes. The Watson–Crick ring imino protons exchange at a faster rate than the Watson–Crick side-chain amino protons, with exchange occurring by transient opening of the double helix. The structure of the d-CpG(pCpG)_n double helices has been probed by proton relaxation time measurements, sugar proton coupling constants, and the proton chemical shift changes associated with the helix–coil transition. The experimental data support a structural model in solution, which incorporates an anti conformation about the glycosyl bonds, C(3) exo sugar ring pucker, and base overlap geometries similar to the B-DNA helix. Rotational correlation times of 1.7 and 0.9 × 10^?9 sec have been computed for the hexanucleotide and tetranucleotide duplexes in 0.1 M salt, D₂O, pH 6.25 at 27°C. The well-resolved ³¹P resonances for the internucleotide phosphates of the tetramer and hexamer sequences at superconducting fields shift upfield by 0.2–0.5 ppm on helix formation. These shifts reflect a conformational change about the ω,ω′ phosphodiester bonds from gauche-gauche in the duplex structure to a distribution of gauche-trans states in the coil structure. Significant differences are observed in the transition width and midpoint of the chemical shift versus temperature profiles plotted in differentiated form for the various base and sugar proton and internucleotide phosphorous resonances monitoring the d-CpG(pCpG)_n helix–coil transition. The twofold symmetry of the d-CpGpCpG duplex is removed on complex formation with the antibiotic actinomycin-D. Two phosphorous resonances are shifted downfield by ～2.6 ppm and ～1.6 ppm on formation of the 1:2 Act-D:d-CpGpCpG complex in solution. Model studies on binding of the antibiotic to dinucleotides of varying sequence indicate that intercalation of the actinomycin-D occurs at the GpC site in the d-CpGpCpG duplex and that the magnitude of the downfield shifts reflects strain at the O-P-O backbone angles and hydrogen bonding between the phenoxazone and the phosphate oxygens. Actinomycin-D is known to bind to nucleic acids that exhibit a B-DNA conformation; this suggests that the d-CpG(pCpG)_n duplexes exhibit a B-DNA conformation in solution.     

A structural transition in d(AT)n.d(AT)n inserts within superhelical DNA

We have constructed plasmids carrying d(AT)n.d(AT)n inserts of different lengths. Two-dimensional gel electrophoresis patterns show that an increase in the negative superhelicity of these DNAs brings about a structural transition within the inserts, resulting in a reduction of the superhelical stress. However, this reduction corresponds to the expected values neither for cruciform nor the Z form. Those DNA topoisomers in which the structural transition had occurred proved to be specifically recognizable by single-strand-specific endonuclease S1, with the cleavage site situated at the centre of the insert. These data, as well as kinetic studies, suggest that the cloned d(AT)n.d(AT)n sequences adopt a cruciform rather than the Z-form structure. We discuss plausible reasons of the discrepancy between the observed superhelical stress release and that expected for the transition of the insert to the cruciform state.     

Length-dependent cruciform extrusion in d(GTAC)n sequences

pBR322-derived plasmids have been constructed carrying d(GTAC)n.d(GTAC)n inserts of different lengths, in order to investigate the effect of insert size on cruciform extrusion and/or the B-Z transition. Plasmids with n ranging from 4 to 12 are hypersensitive to cleavage by the single-strand specific nucleases, S1 nuclease and Bal31 nuclease. Hypersensitive sites associated with the smaller alternating purine-pyrimidine tracts, however, coexist with the major pBR322 sites. Site-selective cleavage of these plasmids with the resolvase, T7 endonuclease I, demonstrates that all the inserts form cruciform structures when stably integrated into negatively supercoiled plasmids. An increase in the negative superhelical density of the DNA's induces cruciform formation within the insert region, resulting in a reduction in torsional stress consistent with the size of the insert. Moreover, as n decreases, the superhelical density required to stabilise the cruciform state increases. Therefore, the cruciform geometry is the favoured conformation of these d(GTAC)n.d(GTAC)n sequences under torsional stress. The stability of these cruciforms increases as n increases, with cruciformation occurring at lower superhelical densities and to the exclusion of the other pBR322 cruciforms.     

In vivo assessment of the Z-DNA-forming potential of d(CA.GT)n and d(CG.GC)n sequences cloned into SV40 minichromosomes

Alternating repeated d(CA.GT)n and d(CG.GC)n sequences constitute a significant proportion of the simple repeating elements found in eukaryotic genomic DNA. These sequences are known to form left-handed Z-DNA in vitro. In this paper, we have addressed the question of the in vivo determination of the Z-DNA-forming potential of such sequences in eukaryotic chromatin. For this purpose, we have investigated the ability of a d(CA.GT)30 sequence and a d(CG.GC)5 sequence to form left-handed Z-DNA when cloned into simian virus 40 (SV40) minichromosomes at two different positions: the TaqI site, which occurs in the intron of the T-antigen gene, and the HpaII site, which is located in the late promoter region within the SV40 control region. Formation of Z-DNA at the inserted repeated sequences was analyzed through the change in DNA linkage associated with the B to Z transition. Our results indicate that regardless of: (1) the site of insertion (either TaqI or HpaII), (2) the precise moment of the viral lytic cycle (from 12 h to 48 h postinfection) and (3) the condition of incorporation of the SV40 recombinants to the host cells (either as minichromosomes or as naked DNA, relaxed or negatively supercoiled), neither the d(CA.GT)30 nor the d(CG.GC)5 sequence are stable in the left-handed Z-DNA conformation in the SV40 minichromosome. The biological relevance of these results is discussed.     

Binding of actinomycin D to single-stranded DNA of sequence motifs d(TGTCT(n)G) and d(TGT(n)GTCT)

Our recent binding studies with oligomers derived from base replacements on d(CGTCGTCG) had led to the finding that actinomycin D (ACTD) binds strongly to d(TGTCATTG) of apparent single-stranded conformation without GpC sequence. A fold-back binding model was speculated in which the planar phenoxazone inserts at the GTC site with a loop-out T base whereas the G base at the 3'-terminus folds back to form a basepair with the internal C and stacks on the opposite face of the chromophore. To provide a more concrete support for such a model, ACTD equilibrium binding studies were carried out and the results are reported herein on oligomers of sequence motifs d(TGTCT(n)G) and d(TGT(n)GTC). These oligomers are not expected to form dimeric duplexes and contain no canonical GpC sequences. It was found that ACTD binds strongly to d(TGTCTTTTG), d(TGTTTTGTC), and d(TGTTTTTGTC), all exhibiting 1:1 drug/strand binding stoichiometry. The fold-back binding model with displaced T base is further supported by the finding that appending TC and TCA at the 3'-terminus of d(TGTCTTTTG) results in oligomers that exhibit enhanced ACTD affinities, consequence of the added basepairing to facilitate the hairpin formation of d(TGTCTTTTGTC) and d(TGTCTTTTGTCA) in stabilizing the GTC/GTC binding site for juxtaposing the two G bases for easy stacking on both faces of the phenoxazone chromophore. Further support comes from the observation of considerable reduction in ACTD affinity when GTC is replaced by GTTC in an oligomer, in line with the reasoning that displacing two T bases to form a bulge for ACTD binding is more difficult than displacing a single base. Based on the elucidated binding principle of phenoxazone ring requiring its opposite faces to be stacked by the 3'-sides of two G bases for tight ACTD binding, several oligonucleotide sequences have been designed and found to bind well.     

Synthesis and proton-NMR studies of oligonucleotides containing an apurinic (AP) site

In order to elucidate the conformational properties of base-deleted oligodeoxyribonucleotides, the molecules d-CpS(pCpG)n (n = 1,2; S = sugar) were synthesized by the phosphotriester method and characterized by 1H-NMR spectroscopy. Complete assignment of all non-exchangeable proton resonances of both compounds was obtained by 1D- and 2D-NMR techniques. In combination with computer simulation, these spectra yielded proton-proton and proton-phosphorus coupling constants of high accuracy. These data provide valuable information about the sugar and the backbone conformation. It appears that d-Cp1Sp2Cp3G4 does not form a duplex under any of the conditions studied. On the contrary, the base-deleted hexamer d-Cp1Sp2Cp3Gp4Cp5G6 occurs as a right-handed' staggered' DNA duplex at 280 K: the core of this duplex is formed by the residues C(3)-G(6); two 'dangling' residues C(1) and S(2) are located at the two 5'-ends of the duplex. The assignment of the corresponding imino proton resonances for [d-CpS(pCpG)2]2 was based on their thermal behavior: the line broadening of these resonances was studied as a function of temperature. The chemical shift and the number of imino proton resonances accord well with the number and type of Watson-Crick base pairs which can be formed in the staggered duplex described above. Thermodynamic parameters of duplex formation were obtained from an analysis of the chemical shift versus temperature profiles of aromatic base and H-1' protons. It is suggested that the cytosine ring of C(1) stacks, at least part of the time, with the guanine ring on the nucleotide residue, G(6), situated in the complementary strand. The binding of Lys-Trp-Lys to [d-CpS(pCpG)2]2 as well as to [d-CpGpCpG]1 was investigated. It is concluded that the indole ring of the tryptophan residue probably stacks on top of the 3'-terminal guanine base of both duplexes, but not on the nucleic acid bases next to the apurinic (AP) site.     

Energetics of the B-H transition in supercoiled DNA carrying d(CT)x.d(AG)x and d(C)n.d(G)n inserts.

We have studied the B-H transition in the d(AG)x inserts of varying length under superhelical stress. The new data and previously published results for the d(G)31 insert are treated within a phenomenological model of the B-H transition, making it possible to obtain, for the first time, the energy parameters of the B-H transition in the d(AG)x and d(G)n sequences.     

Structure of d(GT)n repeating sequences with parallel and antiparallel chains]

The ability of oligonucleotides 3'-d(GT)5pO(CH2)5Opd(GT)5-5' (anti[d(GT)]) and 3'-d(GT)5pO(CH2)6Opd(GT)5-3' (par[d(GT)]) to form hairpins and higher associates is studied. Optical methods of thermal denaturation and circular dichroism as well as the fluorescence of ethidium bromide and acridine orange bound to oligonucleotides were used. At room temperatures the formation of hairpin structure with parallel and antiparallel strands is possible. Thermodynamic parameters of par[d(GT)] and anti[d(GT)] are similar and equal to delta H = -15 kcal/mol, delta S = -50 cal/mol. deg. In the temperature range 3-10 degrees C par[d(GT)] and anti[d(GT)] form four-stranded structures with parallel chains, in which layers of four G-residues alternate with unpaired T-residues being bulged out easily. On comparison of occurrence of alternating (GT)n, (GC)n and (G)n sequences in genome it can be stated that (GT)n biological functions could be connected with conformational possibilities of the four-stranded parallel structures with unpaired T-residues.     

UV-induced interstrand cross-linking of d(GT)n.d(CA)n is facilitated by a structural transition

Photochemical alterations following ultraviolet irradiation of the alternating copolymer d(GT)n.d(CA)n were studied. We found that in solution conditions which produced circular dichroism spectra compatible with B-form or A-form DNA, no interstrand cross-linking or photoproduct formation could be demonstrated. Zimmer et al. (Zimmer, C., Tymen, S., Marck, C., and Guschlbaumer, W. (1982) Nucleic Acids Res. 10, 1081-1091) and Vorlickova et al. (Vorlickova, M., Kypr, J., Sotkrova, S., Sponar, J. (1982) Nucleic Acids Res. 10, 1071-1080) have reported a number of solution conditions which produce a structural transition of this polymer characterized by a negative deviation of the circular dichroism spectrum in the region of 280 nm. The nature of this transition has not yet been elucidated. Following ultraviolet irradiation of d(GT)n.d(CA)n under two conditions which produce this transition (manganese solution or ethanol plus trace salts solution) we found ultraviolet dose-dependent interstrand cross-linking as well as dose-dependent formation of thymine-containing photoproduct. Interstrand cross-linking is demonstrated by two criteria: increase in polymer size as detected by alkaline agarose gel electrophoresis, and generation of intermediate density material in alkaline cesium sulfate isopycnic gradients. The thymine-containing photo-product was demonstrated by thin layer chromatography of acid hydrolysates of the polymer. The photo-product is at least partially photoreversible. These findings suggest that the geometry of the alternative conformation is such that pyrimidines from different strands are closely approximated, allowing for photodimerization.     

Length-Dependent Cruciform Extrusion in d(GTAC)n Sequences

Abstract

pBR322-derived plasmids have been constructed carrying d(GTAC)_n·d(GTAC)_n inserts of different lengths, in order to investigate the effect of insert size on cruciform extrusion and/or the B-Z transition. Plasmids with n ranging from 4 to 12 are hypersensitive to cleavage by the single-strand specific nucleases, S1 nuclease and Bal31 nuclease. Hypersensitive sites associated with the smaller alternating purine-pyrimidine tracts, however, coexist with the major pBR322 sites. Site-selective cleavage of these plasmids with the resolvase, T7 endonuclease I, demonstrates that all the inserts form cruciform structures when stably integrated into negatively supercoiled plasmids. An increase in the negative superhelical density of the DNA's induces cruciform formation within the insert region, resulting in a reduction in torsional stress consistent with the size of the insert. Moreover, as n decreases, the superhelical density required to stabilise the cruciform state increases. Therefore, the cruciform geometry is the favoured conformation of these d(GTAC)_n·d(GTAC)_n sequences under torsional stress. The stability of these cruciforms increases as n increases, with cruciformation occurring at lower superhelical densities and to the exclusion of the other pBR322 cruciforms.     

Structure of d(T)n.d(A)n.d(T)n: the DNA triple helix has B-form geometry with C2'-endo sugar pucker.

The polynucleotide helix d(T)n.d(A)n.d(T)n is the only deoxypolynucleotide triple helix for which a structure has been published, and it is generally assumed as the structural basis for studies of DNA triplexes. The helix has been assigned to an A-form conformation with C3'-endo sugar pucker by Arnott and Selsing [1974; cf. Arnott et al. (1976)]. We show here by infrared spectroscopy in D2O solution that the helix is instead B-form and that the sugar pucker is in the C2'-endo region. Distamycin A, which binds only to B-form and not to A-form helices, binds to the triple helix without displacement of the third strand, as demonstrated by CD spectroscopy and gel electrophoresis. Molecular modeling shows that a stereochemically satisfactory structure can be build using C2'-endo sugars and a displacement of the Watson-Crick base-pair center from the helix axis of 2.5 A. Helical constraints of rise per residue (h = 3.26 A) and residues per turn (n = 12) were taken from fiber diffraction experiments of Arnott and Selsing (1974). The conformational torsion angles are in the standard B-form range, and there are no short contacts. In contrast, we were unable to construct a stereochemically allowed model with A-form geometry and C3'-endo sugars. Arnott et al. (1976) observed that their model had short contacts (e.g., 2.3 A between the phosphate-dependent oxygen on the A strand and O2 in the Hoogsteen-paired thymine strand) which are generally known to be outside the allowed range.(ABSTRACT TRUNCATED AT 250 WORDS)     

Dispersion of meso-tetrakis(N-methylpyridinium-4-yl)porphyrin on [d(A-T)n]2 oligonucleotides

The binding modes of the free-base meso-tetrakis(N-methylpyridinium-4-yl)porphyrin (TMPyP) complexed with [d(AT)n]2 oligonucleotides (where n=3-8, corresponding to 6 to 16 AT base pairs) were studied by circular dichroism (CD). When associated with the shortest oligonucleotide, ([d(AT)3]2), a bisignate CD spectrum was produced in the Soret absorption region at the mixing ratio between 2.0 and 0.25, corresponding to one TMPyP per 0.5 to 4 oligonucleotides. Apparent bisignate CD was attributed to a stacked TMPyP along the DNA. On the other hand, when the oligonucleotide length reaches one helical turn or longer, ([d(AT)n]2, n=6,7,8), TMPyP exhibited a positive CD signal, that corresponds to the monomeric groove binding mode, at the mixing ratio below 1.0 (one TMPyP per oligonucleotide). As the mixing ratio increases, the CD signal was best accounted for by the sum of the stacked and groove-binding TMPyP. At the intermediate oligonucleotide length ([d(AT)n]2, n=4,5), the CD spectrum appeared to be the sum of the stacked and groove binding TMPyP at all mixing ratios. Therefore, it is conclusive that the full dispersion of TMPyP requires at least one helical turn of the AT sequence at a mixing ratio below 1.0. Further increase of the mixing ratio resulted in the stacking of TMPyP even at the long oligonucleotides.     

The human protein translin specifically binds single-stranded microsatellite repeats, d(GT)n, and G-strand telomeric repeats, d(TTAGGG)n: a study of the binding parameters

We have previously identified in human fibroblasts a multisubunit protein (designated PGB) that specifically bound single-stranded G-rich microsatellite DNA sequences. PGB was later found to be identical, or closely related to translin, an octameric protein that bound single-stranded DNA consisting of sequences flanking chromosomal translocations. Here, we report that recombinant translin binds single-stranded microsatellite repeats, d(GT)n, and G-strand telomeric repeats, d(TTAGGG)n, with higher affinities (Kdis approximately = 2 nM and Kdis approximately = 12.5 nM, respectively, in 100 mM NaCl and 25 degrees C) than the affinity with which it binds a prototypical sequence flanking translocation sites (Kdis approximately = 23 nM). Translin also binds d(GT)n and d(TTAGGG)n overhangs linked to double-stranded DNA with equilibrium constants in the nanomolar range. Formation of DNA quadruplexes by the d(TTAGGG)n repeats inhibits their binding to translin. A further study of the binding parameters revealed that the minimal length of d(GT)n and d(TTAGGG)n oligonucleotides that a translin octamer can bind is 11 nucleotides, but that such oligonucleotides containing up to 30 nucleotides can bind only a single translin octamer. However, the oligonucleotides d(GT)27 and d(TTAGGG)9 bind two octamers with negative cooperativity. Translin does not detectably bind single-stranded d(GT)n sequences embedded within double-stranded DNA. Based on our data, we propose that translin might be involved in the control of recombination at d(GT)n.d(AC)n microsatellites and in telomere maintenance.     

Electrophoretic behavior of d(GGAAAAAAGG)n, d(CCAAAAAACC)n, and (CCAAAAAAGG)n and implications for a DNA bending model.

Double stranded multimers (C2A6C2)n, (C2A6G2)n and (G2A6G2)n were prepared from chemically synthesized oligonucleotides to study the influence of sequences flanking the An tract on the curvature of DNA. All these duplexes, including polypurine.polypyrimidine one, exhibit strong retardation in polyacrylamide gel which is indicative of pronounced DNA curvature. It has been proposed previously that among the bends at the boundary with the oligo(A) tract two types should be distinguished: 5'-bends and 3'-bends (Koo et al., 1986) This distinction was deduced from different relative mobilities of two specially designed sequences having phased 5'-bends and 3'-bends, respectively. Our data indicate that the substitutions of nucleotides at both 5' and 3' boundaries of A6 tract result in comparable changes in relative mobility. Therefore, for B-B' bends it is important to take into account not only whether they are at the 5' or 3' end of an oligo(dA) tract, but also the particular sequences at the boundaries of this tract.     

Identification of novel single-stranded d(TC)n binding proteins in several mammalian species

A group of single-stranded d(TC)n specific binding proteins has been detected in the nuclear extracts of several mammalian species that included mouse, human, African green monkey, chimpanzee, and Chinese muntjac. Southwestern analysis of 500 mM KCI nuclear extracts has shown that these proteins cluster in a similar size range, 55.5 to 57 kD. An additional 54 kD band was present for the three primate species examined. The single-stranded d(TC)n binding activity was confirmed with bandshift assay. Specific double-stranded binding activity for duplex d(TC)n.d(GA)n or single-stranded d(GA)n was not detected. The conservation of size distribution and d(TC)n-binding activity across the species examined indicates that this class of single-stranded binding proteins may have an important biological function in vivo.     

Short oligodeoxynucleotides with d(G-C)n sequence do not assume left-handed conformation in high salt conditions

d(G-C)n oligodeoxynucleotides (with n varying from 3 to 7) were studied by the circular dichroism technique in 5 M-NaCl. Contrary to what was previously found with the d(C-G)n series in the same solvent, the left-handed double-stranded Z-conformation appears less stable than the B-form for low n values. The influence of base sequence on the relative stability of B- and Z-conformations for the two series is discussed.