Structural polymorphism of d(GA.TC)n DNA sequences. Intramolecular and intermolecular associations of the individual strands

Revealing structural peculiarities of homopurine GA repetition stuck by i-motif clip

Non-canonical forms of nucleic acids represent challenging objects for both structure-determination and investigation of their potential role in living systems. In this work, we uncover a structure adopted by GA repetition locked in a parallel homoduplex by an i-motif. A series of DNA oligonucleotides comprising GAGA segment and C3 clip is analyzed by NMR and CD spectroscopies to understand the sequence-structure-stability relationships. We demonstrate how the relative position of the homopurine GAGA segment and the C3 clip as well as single-base mutations (guanine deamination and cytosine methylation) affect base pairing arrangement of purines, i-motif topology and overall stability. We focus on oligonucleotides C3GAGA and methylated GAGAC3 exhibiting the highest stability and structural uniformity which allowed determination of high-resolution structures further analyzed by unbiased molecular dynamics simulation. We describe sequence-specific supramolecular interactions on the junction between homoduplex and i-motif blocks that contribute to the overall stability of the structures. The results show that the distinct structural motifs can not only coexist in the tight neighborhood within the same molecule but even mutually support their formation. Our findings are expected to have general validity and could serve as guides in future structure and stability investigations of nucleic acids.

Distinct mutational behaviors differentiate short tandem repeats from microsatellites in the human genome

A tandem repeat's (TR) propensity to mutate increases with repeat number, and can become very pronounced beyond a critical boundary, transforming it into a microsatellite (MS). However, a clear understanding of the mutational behavior of different TR classes and motifs and related mechanisms is lacking, as is a consensus on the existence of a boundary separating short TRs (STRs) from MSs. This hinders our understanding of MSs' mutational properties and their effective use as genetic markers. Using indel calls for 179 individuals from 1000 Genomes Pilot-1 Project, we determined polymorphism incidence for four major TR classes, and formalized its varying relationship with repeat number using segmented regression. We observed a biphasic regime with a transition from a faster to a slower exponential growth at 9, 5, 4, and 4 repeats for mono-, di-, tri-, and tetranucleotide TRs, respectively. We used an in vitro mutagenesis assay to evaluate the contribution of strand slippage errors to mutability. STRs and MSs differ in their absolute polymorphism levels, but more importantly in their rates of mutability growth. Although strand slippage is a major factor driving mononucleotide polymorphism incidence, dinucleotide polymorphism incidence is greater than that expected due to strand slippage alone, indicating that additional cellular factors might be driving dinucleotide mutability in the human genome. Leveraging on hundreds of human genomes, we present the first comprehensive, genome-wide analysis of TR mutational behavior, encompassing several motif sizes and compositions.

Circular dichroism and conformational polymorphism of DNA

Here we review studies that provided important information about conformational properties of DNA using circular dichroic (CD) spectroscopy. The conformational properties include the B-family of structures, A-form, Z-form, guanine quadruplexes, cytosine quadruplexes, triplexes and other less characterized structures. CD spectroscopy is extremely sensitive and relatively inexpensive. This fast and simple method can be used at low- as well as high-DNA concentrations and with short- as well as long-DNA molecules. The samples can easily be titrated with various agents to cause conformational isomerizations of DNA. The course of detected CD spectral changes makes possible to distinguish between gradual changes within a single DNA conformation and cooperative isomerizations between discrete structural states. It enables measuring kinetics of the appearance of particular conformers and determination of their thermodynamic parameters. In careful hands, CD spectroscopy is a valuable tool for mapping conformational properties of particular DNA molecules. Due to its numerous advantages, CD spectroscopy significantly participated in all basic conformational findings on DNA.

Conformations of DNA strands containing GAGT, GACA, or GAGC tetranucleotide repeats

The (GA)(n) microsatellite has been known from previous studies to adopt unusual, ordered, cooperatively melting secondary structures in neutral aqueous solutions containing physiological concentrations of salts, at acid pH values or in aqueous ethanol solutions. To find more about the primary structure specificity of these structures, we performed parallel comparative studies of related tetranucleotide repeats (GAGC)(5), (GAGT)(5), and (GACA)(5). The general conclusion following from these comparative studies is that the primary structure specificity is fairly high, indicating that not only guanines but also adenines play a significant role in the stabilization of these unusual structures. (GAGC)(5) is a hairpin or a duplex depending on DNA concentration. Neither acid pH nor ionic strength or the presence of ethanol changed the secondary structure of (GAGC)(5) in a significant way. (GACA)(5) forms a weakly stable hairpin in neutral aqueous solutions but forms a duplex at acid pH where cytosine is protonated. (GAGT)(5) behaves most similar to (GAGA)(5). Salt induces its hairpin to duplex transition at neutral pH and an isomerization into another, probably parallel stranded, duplex takes place at acid pH. (GAGT)(5) is the only of the three present 20-mers that responds to ethanol like (GAGA)(5).

The genome-wide determinants of human and chimpanzee microsatellite evolution

Mutation rates of microsatellites vary greatly among loci. The causes of this heterogeneity remain largely enigmatic yet are crucial for understanding numerous human neurological diseases and genetic instability in cancer. In this first genome-wide study, the relative contributions of intrinsic features and regional genomic factors to the variation in mutability among orthologous human-chimpanzee microsatellites are investigated with resampling and regression techniques. As a result, we uncover the intricacies of microsatellite mutagenesis as follows. First, intrinsic features (repeat number, length, and motif size), which all influence the probability and rate of slippage, are the strongest predictors of mutability. Second, mutability increases nonuniformly with length, suggesting that processes additional to slippage, such as faulty repair, contribute to mutations. Third, mutability varies among microsatellites with different motif composition likely due to dissimilarities in secondary DNA structure formed by their slippage intermediates. Fourth, mutability of mononucleotide microsatellites is impacted by their location on sex chromosomes vs. autosomes and inside vs. outside of Alu repeats, the former confirming the importance of replication and the latter suggesting a role for gene conversion. Fifth, transcription status and location in a particular isochore do not influence microsatellite mutability. Sixth, compared with intrinsic features, regional genomic factors have only minor effects. Finally, our regression models explain approximately 90% of variation in microsatellite mutability and can generate useful predictions for the studies of human diseases, forensics, and conservation genetics.

Stabilization of the non-canonical adenine–adeninium base pair by N(7) coordination of Zn(II)

A new zinc (II) compound with 9-ethyladenine (9-EtA) of formula [Zn(9-EtA-N7)Cl(3)](9-EtAH) has been synthesized and characterized by X-ray diffraction. Its X-structure consists of an Zn(II) anionic complex and 9-ethyladeninium as counteranion. The Zn(II) complex shows a distorted tetrahedral geometry in which three Cl and an 9-EtA coordinates through N(7) position are the ligands. An indirect chelation via intramolecular H-bond between N(6)H and an Cl ligand is present in the complex. The network of [Zn(9-EtA-N7)Cl(3)](9-EtAH) shows interesting features. Thus, self-association of coordinated adenine-adeninium takes place by H-bonding of N(6)-H...N(1) and N(6)-H...N(7), leading to a polymeric ribbon-like 1D supramolecular arrangement. Ab initio calculations have been applied in order to study the stability of the adenine-adeninium interaction due to the coordination of the Zn(II) to the N(7) position and to compare experimental and theoretical structural data.

Circular dichroism spectroscopy of conformers of (guanine + adenine) repeat strands of DNA

(Guanine+adenine) strands of DNA are known to associate into guanine tetraplexes, homodimerize into parallel or antiparallel duplexes, and fold into a cooperatively melting single strand resembling the protein alpha helix. Using CD spectroscopy and other methods, we studied how this conformational polymorphism depended on the primary structure of DNA. The study showed that d(GGGA)(5) and d(GGA)(7) associated into homoduplexes at low salt or in the presence of LiCl but were prone to guanine tetraplex formation, especially in the presence of KCl. In addition, they yielded essentially the same CD spectrum in the presence of ethanol as observed with the ordered single strand of d(GA)(10). Strands of d(GA)(10), d(GGAA)(5), d(GAA)(7), and d(GAAA)(5) associated into homoduplexes in both LiCl and KCl solutions, but not into guanine tetraplexes. d(GAAA)(5) and d(GAA)(7) further failed to form the single-stranded conformer in aqueous ethanol. Adenine protonation, however, stabilized the single-stranded conformer even in these adenine-rich fragments. The ordered single strands, homoduplexes as well as the guanine tetraplexes, all provided strikingly similar CD spectra, indicating that all of the conformers shared similar base stacking geometries. The increasing adenine content only decreased the conformer thermostability.

DNA homoduplexes containing no pyrimidine nucleotide

We show using polyacrylamide gel electrophoresis that guanine+adenine repeat strands of DNA associate into homoduplexes at neutral pH and moderate ionic strength. The homoduplexes melt in a cooperative way like the Watson-Crick duplex, although they contain no Watson-Crick base pair. Guanine is absolutely needed for the homoduplex formation and the homoduplex stability increases with the guanine content of the repeat. The present results have implications for the nature of the first replicators, as well as regarding forces stabilizing the duplexes of DNA.

Identification and characterization of an angiogenin-binding DNA sequence that stimulates luciferase reporter gene expression

Angiogenin undergoes nuclear translocation in endothelial and smooth muscle cells where it accumulates in the nucleolus and binds to DNA. Nuclear translocation of angiogenin is necessary for its biological activity and is mediated by an endocytotic pathway that is independent of the microtubule system and lysosomal processing. Because the nucleolus is a subnuclear organelle containing clusters of transcriptionally active ribosomal RNA genes, we studied the binding of angiogenin to the intergenic spacer of the ribosomal RNA gene where many of the transcription regulatory elements are located. Here we report that angiogenin binds to CT repeats that are abundant in the nontranscribed region of the ribosomal RNA gene. An angiogenin-binding DNA sequence (CTCTCTCTCTCTCTCTCCCTC) has been identified and designated angiogenin-binding element (ABE). ABE binds angiogenin specifically and exhibits angiogenin-dependent promoter activity in a luciferase reporter system. CT repeats, or inverted GA box, which are abundantly distributed in the eukaryotic genome and are often located in the 5'-flanking region, have been implicated in regulating gene expression. We have previously shown that angiogenin stimulates rRNA synthesis. The present results suggest that the nuclear function of angiogenin may not only be related to rRNA production but also play a role in regulating expression of genes containing CT repeats.

Simultaneous N7,O6-binding of guanine to two zinc centers and its possible biological significance

The reaction of ZnCl(2) with 9-ethylguanine (9-EtGH) produced a novel dinuclear Zn(II) complex, [Zn(2)Cl(4)(H(2)O)(mu-9-EtGH-N7,O6)(9-EtGH-N7), 1. The X-ray structure analysis (monoclinic, P2(1) (No. 4), a = 11.0636(6) A, b = 6.6546(4) A, c = 15.9630(9) A, beta = 101.069(1) degrees, V = 1153.4(1) A(3), Z = 2) revealed that one of the tetrahedrally coordinated Zn(II) atoms binds to the N7 site of 9-EtGH and to the exocyclic O6 atom of another 9-EtGH molecule. The remaining Zn(II) atom binds to the N7 site of the second 9-EtGH moiety.

The identification of nuclear proteins that bind the homopyrimidine strand of d(GA.TC)n DNA sequences, but not the homopurine strand

Alternating d(GA.TC)(n)DNA sequences, which are abundant in eukaryotic genomes, can form altered DNA structures. Depending on the environmental conditions, the formation of (GA.GA) hairpins or [C+T(GA.TC)] and [GA(GA.TC)] intramolecular triplexes was observed in vitro. In vivo, the formation of these non-B-DNA structures would likely require the contribution of specific stabilizing factors. Here, we show that Friend's nuclear extracts are rich in proteins which bind the pyrimidine d(TC)(n)strand but not the purine d(GA)n strand (NOGA proteins). Upon chromatographic fractionation, four major proteins were detected (NOGA1-4) that have been purified and characterized. Purified NOGAs bind single-stranded d(TC)n with high affinity and specificity, showing no significant affinity for either d(GA)n or d(GA.TC)nDNA sequences. We also show that NOGA1, -2 and -3, which constitute the three most abundant and specific NOGA proteins, correspond to the single-stranded nucleic acid binding proteins hnRNP-L, -K and -I, respectively. These results are discussed in the context of the possible contribution of the NOGA proteins to the stabilization of the (GA.GA) and [GA(GA.TC)] conformers of the d(GA.TC)n DNA sequences.

Dimerization of the guanine-adenine repeat strands of DNA

Jovin and co-workers have demonstrated that DNA strands containing guanine-adenine repeats generate a parallel-stranded homoduplex. Here we propose that the homoduplex is a dimer of the ordered single strand discovered by Fresco and co-workers at acid pH. The Fresco single strand is shown here to be stabilized in aqueous ethanol where adenine is not protonated. Furthermore, we demonstrate that the strands dimerize at higher salt concentrations without significantly changing their conformation, so that the dimerization is non-cooperative. Hence, the Jovin homoduplex can form through a non-cooperative dimerization of two cooperatively melting single strands. The available data indicate that the guanines stabilize the Fresco single strand whereas the adenines cause dimerization owing to their known intercalation or clustering tendency. The guanine-adenine repeat dimer seems to be a DNA analog of the leucine zipper causing dimerization of proteins.

Triple helix formation by (G,A)-containing oligonucleotides: asymmetric sequence effect

Sequence effects on the stability of purine-motif (also called (G, A)-motif) triple helix have been investigated through two symmetry-related systems: one of them had a 5'(GGA)43' core sequence of triplex-forming oligonucleotides (TFOs), whereas the other one had a reversed 5'(AGG)43' core sequence. These (G,A)-containing TFOs were prone to self-associate into intermolecular complexes at room temperature. The competition of TFOs' self-association with triple helix formation was assessed, and minimized. By varying the lengths and the terminal base sequences of TFOs, the following were found that (1) The stability of two triple helices with identical length and base composition but reverse strand orientation may be significantly different (up to a factor of 6). (2) When the 5'(GGA)43' core sequence was extended at the 3'-end by a G, the 13-nt TFO exhibited 3- and 5-fold higher affinity toward the target double-stranded DNA (dsDNA) than the longer 14-nt and 15-nt TFOs in which one and two A(s) were added at the 3'-end of the 13-nt TFO, respectively. In contrast, when the similar extensions occurred at the 5'-end of the 5'(AGG)43' core sequence, the length increase provided a higher binding affinity of TFOs toward the target duplex. (3) The nature of the base triplets involved at the ends of triple helices may have great influence on triplex stability. The observed asymmetric sequence effect of the (G,A)-motif triple helix formation is discussed in terms of the binding strength of the first base triplet(s) at the 3' end which seems to be deeply involved in the nucleation step of triple helix formation and therefore to be a determining factor for triplex stability.

Structure of d(GT)n.d(GA)n sequences: formation of parallel stranded duplex DNA

Alternating polypurine sequences exhibit remarkable polymorphism. In this study, we report that dGA.dGT sequences form parallel stranded duplex DNA at neutral pH. Using two model hairpins, 3'-d(GT)3-5'5'-T4(AG)3-3' (I) and 3'-d(GT)4-5'5'-T4(AG)4-3' (II), containing 5'5' linkages which direct parallel strand formation, we systematically explored the spectroscopic and thermodynamic properties of parallel stranded d(GA)n.d(GT)n. The parallel stranded hairpins are remarkably stable structures with TM's of 41.5 and 47.5 degreesC (in 0.4 M NaCl) for the shorter and longer hairpins, respectively. The van't Hoff enthalpies of 80.7 and 114 kJ mol-1 are relatively low but are comparable to a parallel stranded d(GA)n duplex. On the basis of the spectroscopic and electrophoretic characteristics, we conclude that parallel strand formation is not restricted to hairpin systems, but also readily occurs in unconstrained dimeric duplexes with the appropriate sequence homologies. Both melting curves and electrophoretic analyses of parallel stranded heteroduplexes in which the sequence enforces specific base pairing demonstrate that G-G and A-T base pairs are formed in d(GA)n.d(GT)n segments.

Antiparallel DNA duplex formation between alternating alpha d(GA)n and beta d(GA)n sequences

Alternating polypurine d(GA)n, sequences exhibit a considerable polymorphism. Here we report that alpha d(GA) x d(GA) sequences form an antiparallel stranded duplex DNA at neutral pH. The spectroscopic, electrophoretic and thermodynamic properties of the alpha/beta chimeric oligodeoxynucleotide, 5'-d(GA)4(T)4 alpha d(AG)4T-3', support the formation of a hairpin structure with antiparallel strands in the stem. The optical properties of this novel antiparallel structure are different from the parallel stranded homoduplex formed by d(GA)G7. This alpha/beta hairpin has a remarkably high Tm of 44.5 degrees C in 0.4 M NaCl with a van't Hoff enthalpy comparable to that of a parallel d(GA)n duplex. Base pairing was confirmed by T4 polynucleotide ligase catalyzed joining of the alpha/beta hairpin to an antiparallel bimolecular duplex and by non-denaturing gel electrophoresis using duplexes containing sequence constraints. Both support the presence of alphaG-G and alphaA-A base pairing in the antiparallel 5'-d(GA)4(T)4 alpha d(AG)4T-3' intramolecular duplex. This study adds to the polymorphic nature of alternating d(GA)n sequences as well as providing novel homopurine base pairing approaches for probing polypurine polypyrimidine sequences.

Conformational properties of DNA strands containing guanine-adenine and thymine-adenine repeats

CD spectroscopy and PAGE were used to cooperatively analyze melting conformers of DNA strands containing GA and TA dinucleotide repeats. The 20mer (GA)10 formed a homoduplex in neutral solutions containing physiological concentrations of salts and this homoduplex was not destabilized even in the terminal (GA)3 hexamers of (GA)3(TA)4(GA)3, although the central (TA)4 portion of this oligonucleotide preserved the conformation adopted by (TA)10. This observation demonstrates that homoduplexes of alternating GA and TA sequences can co-exist in a single DNA molecule. Another 20mer, (GATA)5, adopted as a whole either the AT duplex, like (TA)10, or the GA duplex, like (GA)10, and switched between them reversibly. The concentration of salt controlled the conformational switching. Hence, guanine and thymine share significant properties regarding complementarity to adenine, while the TA and GA sequences can stack in at least two mutually compatible ways within the DNA duplexes analyzed here. These properties extend our knowledge of non-canonical structures of DNA.

Thermodynamic and spectral properties of DNA miniduplexes with the terminal G x A mispairs and 3' or 5' dangling bases

The tetradeoxyribonucleotide pAGCG in 1 M NaCl forms duplexes with terminal non-canonical pA x G pairs with stability significantly exceeding that for the duplex (pAGCT)2 and lower than that for the duplex (pCGCG)2. The deoxyriboduplex (pAGCG)2 is considerably stabilized by 3'-Y and slightly by 5'-X dangling bases. Therefore, the stability of duplexes with 3' dangling bases decreases in the order (pAGCGY)2 > (pCGCGA)2 > (pAGCTA)2. The sum of the independent stabilizing effect of the of 5'-pG and 3'-A dangling bases on the (pAGCG)2 core duplex is higher than that of the additional terminal pG x A pair in pG-A-/-G-A tandem of the duplex (pGAGCGA)2.

Parallel-stranded linear homoduplexes of d(A+-G)n > 10 and d(A-G)n > 10 manifesting the contrasting ionic strength sensitivities of poly(A+.A+) and DNA

In contrast to shorter homologs which only form a single-stranded nucleic acid alpha-helix in acid solution at [Na+]</=0.02 M Na+, d(A-G)20,30 form in addition a parallel-stranded duplex with (A+.A+) and (G.G) base pairs and interstrand dA+...PO2-ionic and dA+NH2... O=P H-bonds. Under conditions where duplex prevails over alpha-helix, the contribution of the base-backbone interactions to stability varies directly with [H+] and inversely with [Na+], just as in poly(A+.A+). These duplexes are characterized by intense circular dichroism and a large cooperative thermally-induced hyperchromic transition that is dependent on oligomer concentration. Dimethylsulfate reactivity of the dG residues indicates G.G and therefore dA+.dA+rather than dA+.G base pairs. At much higher ionic strength (Na+>/=0.2 M) the protonated base-backbone interactions are so weakened that duplex stability becomes increasingly dependent upon H-bonded base pairing and stacking and almost independent of pH. Between pH 6 and 8 this duplex structure is devoid of protonated dA residues and shows positive dependence of T m on ionic strength similar to that of DNA.

Duplex-tetraplex equilibrium between a hairpin and two interacting hairpins of d(A-G)10 at neutral pH

d(A-G)10 forms two helical structures at neutrality, at low ionic strength a single-hairpin duplex, and at higher ionic strength a double-hairpin tetraplex. An ionic strength-dependent equilibrium between these forms is indicated by native PAGE, which also reveals additional single-stranded species below 0.3 M Na+, probably corresponding to partially denatured states. The equilibrium also depends upon oligomer concentration: at very low concentrations, d(A-G)10 migrates faster than the random coil d(C-T)10, probably because it is a more compact single hairpin; at high concentrations, it co-migrates with the linear duplex d(A-G)10 x d(C-T)10, probably because it is a two-hairpin tetraplex. Molecular weights measured by equilibrium sedimentation in 0.1 M Na+, pH 7, reveal a mixture of monomer and dimer species at 1 degree C, but only a monomer at 40 degrees C; in 0.6 M Na+, pH 7, only a dimer species is observed at 4 degrees C. That the single- and double-stranded species are hairpin helices, is indicated by preferential S1 nuclease cleavage at the center of the oligomer(s), i.e., the loop of the hairpin(s). The UV melting transition below 0.3 M Na+ or K+, exhibits a dTm/dlog[Na+/K+] of 33 or 36 degrees C, respectively, consistent with conversion of a two-hairpin tetraplex to a single-hairpin duplex with extrahelical residues. When [Na+/K+] > or = 0.3 M, dTm/dlog [Na+/K+] is 19 or 17 degrees C, respectively, consistent with conversion of a two-hairpin tetraplex directly to single strands. A two-hairpin structure stabilized by G-tetrads is indicated by differential scanning calorimetry in 0.15 M Na+/5 mM Mg2+, with deltaH of formation per mole of the two-hairpin tetraplex of -116.9 kcal or -29.2 kcal/mol of G-tetrad.

Structural polymorphism of homopurine DNA sequences. d(GGA)n and d(GGGA)n repeats form intramolecular hairpins stabilized by different base-pairing interactions

DNA sequences containing homopurine d(G1-3A)n tracts are known to be capable of adopting non-B-DNA conformations. The structural polymorphism of these sequences is a direct consequence of the structural properties of the homopurine d(G1-3A)n tracts. Depending on the conditions, d(GA)n DNA sequences can form antiparallel-and parallel-stranded homoduplexes, multistranded complexes, and ordered single-stranded conformations. On the other hand, much less is known about the structural properties of d(GGA)n and d(GGGA)n sequences. In this paper, we show that d(GGA)n and d(GGGA)n repeats form antiparallel-stranded, intramolecular hairpins. Under physiological salt and pH conditions, the thermal stability of these hairpin forms is high, showing, at 50 mM NaCl, melting temperatures in the range of 40-50 degrees C. The base-pairing interactions involved in the formation of the d(GGA)n and d(GGGA)n hairpins are different. G.A pairs importantly contribute to the stability of the d(GGA)n hairpins. On the other hand, the d(GGGA)n hairpins are stabilized by the formation of G.G and A.A, but not G.A pairs. Homopurine d(G1-3A)n tracts are frequently found at genomic locations performing specialized chromosomal functions (i.e. telomeres, centromeres, and recombination "hot-spots"). The molecular interactions described here are relevant for the understanding of the peculiar structural and biological properties of DNA sequences containing homopurine tracts.

The unusual X-form DNA in oligodeoxynucleotides: dependence of stability on the base sequence and length

X-form is an unusual double helix of DNA adopted by poly(dA-dT) or (dT-dA)4 at high concentrations of CsF. On the other hand, poly(dA), poly(dT), (dA-dT)4 and most other DNAs do not adopt this conformer. Here we demonstrate that the X-form is strongly destabilized by GC pairs or even minute perturbations of the alternating pyrimidinepurine sequence. For example, the 30-mer d(TATAAT)5, containing five tandem repeats of the Pribnow box, fails to isomerize into the X-form. After (dT-dA)4, the 16-mer (dT-dA)8 is shown to be the second most predisposed oligodeoxynucleotide in the (dT-dA)n series to isomerize into the X-form while the duplex lengths corresponding to n = 3,5,6,7,9,12 and 20 make the X-form unstable even in the strictly alternating (dT-dA)n sequence. Consequently, the (dT-dA)n duplex length is also a crucial factor of the X-form stability on the oligodeoxynucleotide level. We discuss a possibility that the X-form is a solution counterpart of the D-form adopted in dehydrated poly(dA-dT) fibers because properties of these two conformers are remarkably similar in many respects.

A molecular mechanics and dynamics study of alternate triple-helices involving the integrase-binding site of the HIV-1 virus and oligonucleotides having a 3'-3' internucleotide junction

Triple helix formation by oligonucleotides can be extended beyond polypurine tracts with the help of specially designed linkers. In this paper we focus our attention on the integrase-binding site of the HIV-1 virus located on the U5 LTR end which contains two adjacent purine tracts on opposite strands. Two alternate triple helices with a 3'-3' junction in the third strand are considered: 5'-GGTTTTp3'-3'pTGTGT-5' and 5'-GGAAAAp3'-3'pAGAGA-5' The structural plausibility of these triplexes is investigated using molecular mechanics and dynamics simulations, both in vacuo and in aqua. The non-isomorphism of the triplets in the GpT steps in the first sequence, gives rise to non canonical conformations in the torsion angles, hydration appears to be crucial for this triplex. Sugar puckers are predominantly South during in vacuo simulations while they turn East in aqua. In the simulation in aqua the triplexes are shrouded by an hydration shell, however, we have not been able to detect any permanent hydrogen bond bridge between DNA and water. The solvation of ions as well as their radial distribution, appear to be relatively well behaved despite the artifacts known to be generated by the simulation procedure. The experimental feasibility of these structures is discussed.

Selective binding of specific mouse genomic DNA fragments by mouse vimentin filaments in vitro

Mouse vimentin intermediate filaments (IFs) reconstituted in vitro were analyzed for their capacity to select certain DNA sequences from a mixture of about 500-bp-long fragments of total mouse genomic DNA. The fragments preferentially bound by the IFs and enriched by several cycles of affinity binding and polymerase chain reaction (PCR) amplification were cloned and sequenced. In general, they were G-rich and highly repetitive in that they often contained Gn, (GT)n, and (GA)n repeat elements. Other, more complex repeat sequences were identified as well. Apart from the capacity to adopt a Z-DNA and triple helix configuration under superhelical tension, many fragments were potentially able to form cruciform structures and contained consensus binding sites for various transcription factors. All of these sequence elements are known to occur in introns and 5'/3'-flanking regions of genes and to play roles in DNA transcription, recombination and replication. A FASTA search of the EMBL data bank indeed revealed that sequences homologous to the mouse repetitive DNA fragments are commonly associated with gene-regulatory elements. Unexpectedly, vimentin IFs also bound a large number of apparently overlapping, AT-rich DNA fragments that could be aligned into a composite sequence highly homologous to the 234-bp consensus centromere repeat sequence of gamma-satellite DNA. Previous experiments have shown a high affinity of vimentin for G-rich, repetitive telomere DNA sequences, superhelical DNA, and core histones. Taken together, these data support the hypothesis that, after penetration of the double nuclear membrane via an as yet unidentified mechanism, vimentin IFs cooperatively fix repetitive DNA sequence elements in a differentiation-specific manner in the nuclear periphery subjacent to the nuclear lamina and thus participate in the organization of chromatin and in the control of transcription, replication, and recombination processes. This includes aspects of global regulation of gene expression such as the position effects associated with translocation of genes to heterochromatic centromere and telomere regions of the chromosomes.

Centromeric dodeca-satellite DNA sequences form fold-back structures

The evolutionarily conserved centromeric dodeca-satellite DNA has an asymmetric distribution of guanine and cytosine residues resulting in one strand being relatively G-rich. This dodeca-satellite G-strand contains a GGGA-tract that is similar to the homopurine tracts found in most telomeric DNA sequences. Here, we show that the dodeca-satellite G-strand forms intramolecular hairpin structures that are stabilized by the formation of non-Watson-Crick G.A pairs as well as regular Watson-Crick G.C pairs. Special stacking interactions are also likely to contribute significantly to the stability of this structure. This hairpin conformation melts at relatively high temperature, around 75 degrees C, and is detected under many different ionic and pH conditions. As judged by electron microscopy visualization, these structures can be formed in a B-DNA environment. Under the same experimental conditions, neither the C-strand nor the double-stranded dodeca-satellite DNA were found to form any unusual DNA structure. A protein activity has been detected that preferentially binds to the single-stranded dodeca-satellite C-strand. The biological relevance of these results is discussed in view of the similarities to telomeric DNA.

Calorimetric and spectroscopic studies on the poly[d(GA).d(CT)] structural polymorphism induced by zinc

The interaction of zinc (II) with poly[d(GA).d(CT)] and salmon testes DNA has been investigated by Differential Scanning Calorimetry (DSC) and Circular Dichroism (CD). We have detected and energetically characterized the existence of two different structural forms in poly[d(GA).d(CT)] which behave differently during a DSC experiment. The overall melting of DNA shows two calorimetric transitions at different temperatures. Moreover, the presence of zinc, at an input ratio of ion to nucleotide (r) above two, renders a complex DSC profile which is characterized by a negative enthalpy transition. Besides, the low-temperature transition observed in the presence of zinc is practically reversible after re-cooling/re-heating cycles. Nevertheless, the high-temperature transition characterized by a negative delta H degree cal does not appear in re-heating experiments, and remains stable below 100 degrees C. A calorimetric negative enthalpy transition is also found using salmon DNA in the presence of zinc ions. It seems that the combination of a temperature effect and zinc binding might induce the production of a stable metal-DNA complex, which can also be detected by changes in some bands in the CD profiles. The experimental results show that the presence of DNA structures and binding processes involving a negative calorimetric enthalpy contribution might be more widespread than previously reckoned.