Models of triple-stranded polynucleotides with optimised stereochemistry

Triple helix structures: sequence dependence, flexibility and mismatch effects

By means of molecular modelling, electrostatic interactions are shown to play an important role in the sequence-dependent structure of triple helices formed by a homopyrimidine oligonucleotide bound to a homopurine. homopyrimidine sequence on DNA. This is caused by the presence of positive charges due to the protonation of cytosines in the Hoogsteen-bonded strand, required in order to form C.GxC+ triplets. Energetic and conformational characteristics of triple helices with different sequences are analyzed and discussed. The effects of duplex mismatches on the triple helix stability are investigated via thermal dissociation using UV absorption.

Theoretical study of ethidium intercalation in triple-stranded DNA and at triplex-duplex junctions

The contribution of different factors in the interaction of ethidium intercalated into various sequences of a triple helix, or in the region of the junction between the double- and triple-stranded DNA has been studied by energy minimization. It is found that in the total energy of the ethidium- triple helix complexes, a particular electrostatic contribution emerges due to the presence of protonated cytosines in the triple helix. This parameters is determinant in the sequence-specificity of ethidium binding to the triple helix. The preferred intercalation sites of ethidium in the triple helix are proposed. The interaction of ethidium at the triplex-duplex junction, and its effects are also discussed. This study is aimed at searching for new drugs specific for the triple helix, or for the triplex-duplex junctions.

Specificity and stringency in DNA triplex formation

Triple-helix formation can in principle serve as a general method for sequence-specific recognition and physical separation of duplex DNA molecules. Realization of this goal depends on how much the triplex is destabilized by mismatches and other defects (specificity) and on finding conditions in which perfect complexes are stable and defect complexes are not (stringency). We have addressed the question of specificity by determining the difference in free energy between perfect and defect complexes by using UV melting curves and equilibrium competition experiments. We find that third strands that bind with either single-base bulges or single mismatches are destabilized relative to the perfect triplex by 2.5-2.9 and 3.2-4.0 kcal/mol (1 cal = 4.184 J), respectively, essentially equivalent to the corresponding values determined for duplex DNA and RNA. Also, we present a method, referred to as stringency clamping, which maintains specific binding under conditions far from normal stringency. To do this, we provide for the formation of a competing structure involving the third strand with stability between that of the perfect and imperfect complexes; the competitive interaction effectively prevents triplex formation at imperfect sites even far below their melting temperature. We illustrate the phenomenon with three different stringency clamps, two of which compete for the all-pyrimidine third strand through Watson-Crick pairing and one that competes through all-pyrimidine pairing at acidic pH. We demonstrate physical separation of two duplex DNA molecules differing by a single base pair in their target sequence for triple-helix formation.

Sequence specificity in triple-helix formation: experimental and theoretical studies of the effect of mismatches on triplex stability

The specificity of a homopyrimidine oligonucleotide binding to a homopurine-homopyrimidine sequence on double-stranded DNA was investigated by both molecular modeling and thermal dissociation experiments. The presence of a single mismatched triplet at the center of the triplex was shown to destabilize the triple helix, leading to a lower melting temperature and a less favorable energy of interaction. A terminal mismatch was less destabilizing than a central mismatch. The extent of destabilization was shown to be dependent on the nature of the mismatch. Both single base-pair substitution and deletion in the duplex DNA target were investigated. When a homopurine stretch was interrupted by one thymine, guanine was the least destabilizing base on the third strand. However, G in the third strand did not discriminate between a C.G and an A.T base pair. If the stretch of purines was interrupted by a cytosine, the presence of pyrimidines (C or T) in the third strand yielded a less destabilizing effect than purines. This study shows that oligonucleotides forming triple helices can discriminate between duplex DNA sequences that differ by one base pair. It provides a basis for the choice of antigene oligonucleotide sequences targeted to selected sequences on duplex DNA.

NMR structural studies of intramolecular (Y+)n.(R+)n(Y-)nDNA triplexes in solution: imino and amino proton and nitrogen markers of G.TA base triple formation

We reported previously on NMR studies of (Y+)n.(R+)n(Y-)n DNA triple helices containing one oligopurine strand (R)n and two oligopyrimidine strands (Y)n stabilized by T.AT and C+.GC base triples [de los Santos, C., Rosen, M., & Patel, D. J. (1989) Biochemistry 28, 7282-7289]. Recently, it has been established that guanosine can recognize a thymidine.adenosine base pair to form a G.TA triple in an otherwise (Y+)n.(R+)n(Y-)n triple-helix motif. [Griffin, L. C., & Dervan, P. B. (1989) Science 245, 967-971]. The present study extends the NMR research to the characterization of structural features of a 31-mer deoxyoligonucleotide that folds intramolecularly into a 7-mer (Y+)n.(R+)n(Y-)n triplex with the strands linked through two T5 loops and that contains a central G.TA triple flanked by T.AT triples. The G.TA triplex exhibits an unusually well resolved and narrow imino and amino exchangeable proton and nonexchangeable proton spectrum in H2O solution, pH 4.85, at 5 degrees C. We have assigned the imino protons of thymidine and amino protons of adenosine involved in Watson-Crick and Hoogsteen pairing in T.AT triples, as well as the guanosine imino and cytidine amino protons involved in Watson-Crick pairing and the protonated cytidine imino and amino protons involved in Hoogsteen pairing in C+.GC triples in the NOESY spectrum of the G.TA triplex. The NMR data are consistent with the proposed pairing alignment for the G.TA triple where the guanosine in an anti orientation pairs through a single hydrogen bond from one of its 2-amino protons to the 4-carbonyl group of thymidine in the Watson-Crick TA pair.(ABSTRACT TRUNCATED AT 250 WORDS)

Structure, stability, and thermodynamics of a short intermolecular purine-purine-pyrimidine triple helix

We have investigated the structure and physical chemistry of the d(C3T4C3).2[d(G3A4G3)] triple helix by polyacrylamide gel electrophoresis (PAGE), 1H NMR, and ultraviolet (UV) absorption spectroscopy. The triplex was stabilized with MgCl2 at neutral pH. PAGE studies verify the stoichiometry of the strands comprising the triplex and indicate that the orientation of the third strand in purine-purine-pyrimidine (pur-pur-pyr) triplexes is antiparallel with respect to the purine strand of the underlying duplex. Imino proton NMR spectra provide evidence for the existence of new purine-purine (pur.pur) hydrogen bonds, in addition to those of the Watson-Crick (W-C) base pairs, in the triplex structure. These new hydrogen bonds are likely to correspond to the interaction between third-strand guanine NH1 imino protons and the N7 atoms of guanine residues on the purine strand of the underlying duplex. Thermal denaturation of the triplex proceeds to single strands in one step, under the conditions used in this study. Binding of the third strand appears to enhance the thermal stability of the duplex by 1-3 degrees C, depending on the DNA concentration. The free energy of triplex formation (-26.0 +/- 0.5 kcal/mol) is approximately twice that of duplex formation (-12.6 +/- 0.7 kcal/mol), suggesting that the overall stability of the pur.pur base pairs is similar to that of the W-C base pairs.(ABSTRACT TRUNCATED AT 250 WORDS)

Vacuum UV CD spectra of homopolymer duplexes and triplexes containing A.T or A.U base pairs

Vacuum UV circular dichroism (CD) spectra were measured down to 174 nm for five homopolymers, five duplexes, and four triplexes containing adenine, uracil, and thymine. Near 190 nm, the CD bands of poly[d(A)] and poly[r(A)] were larger than the CD bands of the polypyrimidines, poly[d(T)], poly[d(U)], and poly[r(U)]. Little change was observed in the 190 nm region upon formation of the duplexes (poly[d(A).d(T)], poly[d(A).d(U)], poly[r(A).d(T)], poly[r(A).d(U)], and poly[r(A).r(U)]) or upon formation of two of the triplexes (poly[d(T).d(A).d(T)] and poly[d(U).d(A).d(U)]). This showed that the purine strand had the same or a similar structure in these duplexes and triplexes as when free in solution. Both A.U and A.T base pairing induced positive bands at 177 and 202 nm. For three triplexes containing poly[d(A)], the formation of a triplex from a duplex and a free pyrimidine strand induced a negative band centered between 210 and 215 nm. The induction of a band between 210 and 215 nm indicated that these triplexes had aspects of the A conformation.

Mung bean nuclease cleavage pattern at a polypurine.polypyrimidine sequence upstream from the mouse metallothionein-I gene

Mung bean nuclease, an enzyme specific for single-stranded DNA, was used to probe a non-B DNA structure present in the mouse metallothionein-I gene. The region sensitive to the enzyme was constituted by a 128 base-pair long polypurine.polypyrimidine sequence located at 1.2-kb from the start of transcription. A detailed analysis of the mung bean nuclease cleavage pattern revealed that: (i) under conditions of supercoiling and low pH a triplex structure was formed, (ii) the triplex was flanked by a sequence with the potential of forming a Z-DNA structure, (iii) most of the enzymatic activity was localized at some of the junctions between double-stranded and triple-stranded DNA and at mismatches in the triplex, (iv) no unpaired bases were observed in the loop or outside the triplex, and (v) the triplex was present in more than one configuration.

Proton NMR and optical spectroscopic studies on the DNA triplex formed by d-A-(G-A)7-G and d-C-(T-C)7-T

Triplex and duplex formation of two deoxyribohexadecamers d-A-(G-A)-G (a) and d-C-(T-C)-T (b) have been studied by UV, CD, fluorescence, and proton NMR spectroscopy. Optical studies of a and b at dilute concentrations (microM range) yielded results similar to those seen for polymers of the same sequence, indicating that these hexadecamers have properties similar to the polymers in regard to triplex formation. The CD spectra of concentrated NMR samples (mM range) are similar to those observed at optical concentrations at both low and high pH, making possible a correlation between CD and NMR studies. In NMR spectra, two imido NH-N hydrogen bonded resonance envelopes at 12.6 and 13.7 ppm indicate that only the duplex conformation is present at pH greater than 7.7. Four new NH-N hydrogen-bonded resonance envelopes at 12.7, 13.5, 14.2, and 14.9 ppm are observed under acidic conditions (pH 5.6) and the two original NH-N resonances gradually disappear as the pH is lowered. Assignment of these four peaks to Watson-Crick G.C. Hoogsteen T.A Watson-Crick A.T, and Hoogsteen C+.G hydrogen-bonded imidos, respectively, confirm the formation of triple-stranded DNA NMR results also show that triplex is more stable than duplex at the same salt condition and that triplex melts to single strands directly without going through a duplex intermediate. However, in the melting studies, a structural change within the triple-stranded complex is evident at temperatures significantly below the major helix-to-coil transition. These studies demonstrate the feasibility of using NMR spectroscopy and oligonucleotide model compounds a and b for the study of DNA triplex formation.

Local supercoil-stabilized DNA structures

The DNA double helix exhibits local sequence-dependent polymorphism at the level of the single base pair and dinucleotide step. Curvature of the DNA molecule occurs in DNA regions with a specific type of nucleotide sequence periodicities. Negative supercoiling induces in vitro local nucleotide sequence-dependent DNA structures such as cruciforms, left-handed DNA, multistranded structures, etc. Techniques based on chemical probes have been proposed that make it possible to study DNA local structures in cells. Recent results suggest that the local DNA structures observed in vitro exist in the cell, but their occurrence and structural details are dependent on the DNA superhelical density in the cell and can be related to some cellular processes.

Thermodynamic characterization of the stability and the melting behavior of a DNA triplex: a spectroscopic and calorimetric study

We report a complete thermodynamic characterization of the stability and the melting behavior of an oligomeric DNA triplex. The triplex chosen for study forms by way of major-groove Hoogsteen association of an all-pyrimidine 15-mer single strand (termed y15) with a Watson-Crick 21-mer duplex composed of one purine-rich strand (termed u21) and one pyrimidine-rich strand (termed y21). We find that the near-UV CD spectrum of the triplex can be duplicated by the addition of the B-like CD spectrum of the isolated 21-mer duplex and the CD spectrum of the 15-mer single strand. Spectroscopic and calorimetric measurements show that the triplex (y15.u21.y21) melts by two well-resolved sequential transitions. The first transition (melting temperature, Tm, approximately 30 degrees C) is pH-dependent and involves the thermal expulsion of the 15-mer strand to form the free duplex u21.y21 and the free single strand y15. The second transition (Tm approximately 65 degrees C) is pH-independent between pH 6 and 7 and reflects the thermal disruption of the u21.y21 Watson-Crick duplex to form the component single strands. The thermal stability of the y15.u21.y21 triplex increases with increasing Na+ concentration but is nearly independent of DNA strand concentration. Differential scanning calorimetric measurements at pH 6.5 show the triplex to be enthalpically stabilized by only 2.0 +/- 0.1 kcal/mol of base triplets (1 cal = 4.184 J), whereas the duplex is stabilized by 6.3 +/- 0.3 kcal/mol of base pairs. From the calorimetric data, we calculate that at 25 degrees C the y15.u21.y21 triplex is stabilized by a free energy of only 1.3 +/- 0.1 kcal/mol relative to its component u21.y21 duplex and y15 single strand, whereas the 21-mer duplex is stabilized by a free energy of 17.2 +/- 1.2 kcal/mol relative to its component single strands. The y15 single strand modified by methylation of cytosine at the C-5 position forms a triplex with the u21.y21 duplex, which exhibits enhanced thermal stability. The spectroscopic and calorimetric data reported here provide a quantitative measure of the influence of salt, temperature, pH, strand concentration, and base modification on the stability and the melting behavior of a DNA triplex. Such information should prove useful in designing third-strand oligonucleotides and in defining solution conditions for the effective use of triplex structure formation as a tool for modulating biochemical events.

Site-specific cleavage of duplex DNA by a semisynthetic nuclease via triple-helix formation

A Lys-84----Cys mutant staphylococcal nuclease was selectively linked to the 5' and/or 3' terminus of a thiol-containing polypyrimidine oligonucleotide via a disulfide bond. The oligonucleotide-staphylococcal nuclease adduct is capable of binding to a homopurine-homopyrimidine region of Watson-Crick duplex DNA by the formation of a triple-helical structure. Upon the addition of Ca2+, the nuclease cleaves DNA at sites adjacent to the homopurine tract. Specific double-strand cleavage occurred predominantly at A + T-rich sites to the 5' side of the homopurine tract for both the 5'-derivatized and the 5',3'-diderivatized nucleases; the 3'-derivatized nuclease gave no cleavage. The cleavage pattern is asymmetric and consists of multiple cleavage sites shifted to the 5' side on each strand, centered at the terminal base pair of the binding site. Microgram amounts of plasmid pDP20 DNA (4433 base pairs) containing a homopurine-homopyrimidine tract were selectively cleaved by a semisynthetic nuclease with greater than 75% efficiency at room temperature within 1 hr. Cleavage reaction conditions were optimized with respect to pH, temperature, reaction times, and reaction components. Semisynthetic nucleases of this type should provide a powerful tool in chromosomal DNA manipulations.

Thermodynamics of triple helix formation: spectrophotometric studies on the d(A)10.2d(T)10 and d(C+3T4C+3).d(G3A4G3).d(C3T4C3) triple helices

We have stabilized the d(A)10.2d(T)10 and d(C+LT4C+3).d(G3A4G3).d(C3T4C3) triple helices with either NaCl or MgCl2 at pH 5.5. UV mixing curves demonstrate a 1:2 stoichiometry of purine to pyrimidine strands under the appropriate conditions of pH and ionic strength. Circular dichroic titrations suggest a possible sequence-independent spectral signature for triplex formation. Thermal denaturation profiles indicate the initial loss of the third strand followed by dissociation of the underlying duplex with increasing temperature. Depending on the base sequence and ionic conditions, the binding affinity of the third strand for the duplex at 25 degrees C is two to five orders of magnitude lower than that of the two strands forming the duplex. Thermodynamic parameters for triplex formation were determined for both sequences in the presence of 50 mM MgCl2 and/or 2.0 M NaCl. Hoogsteen base pairs are 0.22-0.64 kcal/mole less stable than Watson-Crick base pairs, depending on ionic conditions and base composition. C+.G and T.A Hoogsteen base pairs appear to have similar stability in the presence of Mg2+ ions at low pH.

Protection against UV-induced pyrimidine dimerization in DNA by triplex formation

Cyclobutane and [6-4]-pyrimidine dimers are major photoproducts of ultraviolet-irradiated DNA. The yield of these photoproducts is dependent on the sequence and structure of the DNA. By analysing the photofootprints of fragments produced by cleavage of the DNA chain near [6-4]-pyrimidine dimers, we show here that a homopurine-homopyrimidine insert (with either d(TC)x or d(C)n) in plasmid pUC19 is, as expected, a good target for UV-induced pyrimidine-dimer formation. But we find that dimerization is virtually completely suppressed when the pyrimidine oligonucleotides d(TC)y or d(C)m are added to DNA carrying d(TC)x- or d(C)n-containing inserts, respectively. This effect is dependent on the type of oligonucleotide used and is site-specific. The protection occurs under acidic conditions that favour the formation of intermolecular triplexes between the homopurine-homopyrimidine inserts and homologous oligopyrimidines. We therefore conclude that triplex formation effectively protects the DNA duplex from UV-induced damage (pyrimidine dimerization). This observation makes the photofootprinting assay a very promising method for studying intermolecular and intramolecular triplexes (H-form DNA) both in vitro and in vivo.

Structural analysis of the (dA)10.2(dT)10 triple helix

The existence of DNA triple helices in vitro has been known for some time. Recent evidence suggesting that DNA triplexes exist in vivo and showing their potential for chemotherapeutic applications has renewed interest in these triple-strand conformations. However, little structural information is currently known about these unusual nucleic acid forms. We have induced and stabilized triple-helical (dA)10.2(dT)10 with MgCl2 at neutral pH. UV mixing curves demonstrate a 1:2 (dA)10 to (dT)10 stoichiometry at suitable MgCl2 concentrations. Thermal denaturation profiles establish a melting mechanism characterized by the initial loss of the third strand, followed by dissociation of the remaining duplex. The circular dichroic spectrum of the triplex form is distinct from that of a duplex equimolar in (dA)10. NMR studies show that magnesium-induced triplex formation is accompanied by an upfield shift of several imino proton resonances present before stabilization of the triplex form with MgCl2 and the induction of new upfield imino proton resonances. Nuclear Overhauser effect spectroscopy measurements on both undeuterated and C8--H-deuterated (dA)10.2(dT)10 triplexes demonstrate dipolar contacts between resolvable imino proteins and both adenine C8--H and C2--H aromatic protons. Hence, MgCl2 stabilizes a triplex structure in which thymine N3--H imino protons are involved in both Watson-Crick and Hoogsteen base pairing.

A study of model energetics and conformational properties of polynucleotide triplexes

The formation of triple-stranded nucleic acid helices is studied by molecular mechanics and molecular dynamics calculations. Using standard TAT and CGG homopolymers, single, triple, and quintuple molecular replacements are made. Some of these replacements are expected to form Hoogsteen bonds and some are not. While the electrostatic and total energetic differences for base triplet mismatches were dependent on the electrostatic model chosen, clear trends in the local geometric distortions were apparent. Relationships between these model-built strand geometries and chemical probe experiments are discussed.

Recognition of thymine adenine.base pairs by guanine in a pyrimidine triple helix motif

Oligonucleotide recognition offers a powerful chemical approach for the sequence-specific binding of double-helical DNA. In the pyrimidine-Hoogsteen model, a binding size of greater than 15 homopurine base pairs affords greater than 30 discrete sequence-specific hydrogen bonds to duplex DNA. Because pyrimidine oligonucleotides limit triple helix formation to homopurine tracts, it is desirable to determine whether oligonucleotides can be used to bind all four base pairs of DNA. A general solution would allow targeting of oligonucleotides (or their analogs) to any given sequence in the human genome. A study of 20 base triplets reveals that the triple helix can be extended from homopurine to mixed sequences. Guanine contained within a pyrimidine oligonucleotide specifically recognizes thymine.adenine base pairs in duplex DNA. Such specificity allows binding at mixed sites in DNA from simian virus 40 and human immunodeficiency virus.

Specificity in formation of triple-stranded nucleic acid helical complexes: studies with agarose-linked polyribonucleotide affinity columns

The binding of a variety of deoxyribo and ribo homo- and copolynucleotide complementary duplexes to agarose-linked homopolynucleotide affinity columns has been studied. The results provide information concerning the specificity of recognition of complementary base pairs of nucleic acids through a mechanism that involves triple-helix formation under physiological conditions of ionic strength, pH, and temperature. The method employed made it possible, for the first time, to survey the full range of base triplets conceivable from the canonical nucleic acid bases and, in addition, hypoxanthine and thereby to differentiate between those triplets which can and cannot form. Certain previously observed features of the stereochemistry of double-helical targets for third-strand binding are confirmed, and some unrecognized features are elaborated. These include a general requirement for clusters of purine residues in one strand, protonation of third-strand C residues, the ability of natural third-strand residues to distinguish between A.T/U and G.C base pairs, and a capacity of third-strand (unnatural) I residues to recognize all base pairs within such clusters. Thus, the basis for a third-strand binding code is demonstrated.

Oligonucleotide N-alkylphosphoramidates: synthesis and binding to polynucleotides

A few different methods for the preparation of oligonucleotide N-alkylphosphoramidates were compared directly. One of these, involving the use of protected nucleoside phosphites as building blocks, provided the requisite N-alkylphosphoramidates via oxidation of the intermediate dinucleoside methyl phosphites with iodine in the presence of the appropriate alkylamine. This method was found to have several attractive features, including the use of building blocks identical with those employed for the synthesis of DNA and compatibility with procedures and instruments employed for the stepwise synthesis of oligonucleotides by solution and solid-phase methods. This procedure was used to make several di-, tri-, and tetranucleotide N-alkylphosphoramidates derived from deoxyadenosine and thymidine; alkyl substituents included N,N-dimethyl, N-butyl, N-octyl, N-dodecyl, and N-(5-aminopentyl). The aminoalkyl derivative of d(TpT) (24) was used to demonstrate the feasibility of introducing an intercalative agent to the alkylphosphoramidate moiety of such derivatives. The oligonucleotide N-alkylphosphoramidates were separated into their component diastereomers and characterized structurally by a number of techniques including circular dichroism, high-field 1H NMR spectroscopy, FAB mass spectrometry, and enzymatic digestion to authentic nucleosides and nucleotides. Physicochemical characterization of several di- and trinucleotide alkyl-phosphoramidates revealed that the adenine nucleotide analogues formed stable complexes with poly-(thymidylic acid). The stabilities of these complexes were found to increase with increasing chain length of the N-alkylphosphoramidate substituents. The finding that N-alkylphosphoramidate substituents can enhance the binding of certain oligonucleotides to their complementary polynucleotides suggests the existence of a novel source of polynucleotide affinity.

A stable complex between homopyrimidine oligomers and the homologous regions of duplex DNAs

When plasmid DNA duplexes carrying the regular homopurine-homopyrimidine inserts (dGA)n, (dTC)n and (dG)n, (dC)n are preincubated with homologous labeled oligo(dPy) ((dTC)n and (dC)n respectively) at acid pH, the label co-electrophoreses with the duplex DNA. Thus, a very strong complex is formed. Complementary oligo(dPu) does not form a complex under these conditions. No binding is observed for oligo(dPy) with non-homologous inserts as well as with vector plasmids without inserts. The complex is formed equally well with linear, nicked or superhelical DNA. The complex is not detected at pH greater than 6. Complex formation leads to very little, if any, unwinding of the duplex. The observed complex appears to be the Py.Pu.Py triplex consisting of TAT and CGC base-triads with protonated cytosines. Two-dimensional gel electrophoresis patterns show that the presence of homologous oligo(dPy) destabilizes the formation of the H form.

Sequence-specific cleavage of double helical DNA by triple helix formation

Homopyrimidine oligodeoxyribonucleotides with EDTA-Fe attached at a single position bind the corresponding homopyrimidine-homopurine tracts within large double-stranded DNA by triple helix formation and cleave at that site. Oligonucleotides with EDTA.Fe at the 5' end cause a sequence specific double strand break. The location and asymmetry of the cleavage pattern reveal that the homopyrimidine-EDTA probes bind in the major groove parallel to the homopurine strand of Watson-Crick double helical DNA. The sequence-specific recognition of double helical DNA by homopyrimidine probes is sensitive to single base mismatches. Homopyrimidine probes equipped with DNA cleaving moieties could be useful tools for mapping chromosomes.

CD of homopolymer DNA-RNA hybrid duplexes and triplexes containing A-T or A-U base pairs

CD spectra and difference-CD spectra of (a) two DNA X RNA hybrid duplexes (poly[r(A) X d(U)] and poly[r(A) X d(T)]) and (b) three hybrid triplexes (poly-[d(T) X r(A) X d(T)], poly[r(U) X d(A) X r(U)], and poly[r(T) X d(A) X r(T)]) were obtained and compared with CD spectra of six A X U- and A X T-containing duplex and triplex RNAs and DNAs. We found that the CD spectra of the homopolymer duplexes above 260 nm were correlated with the type of base pair present (A-U or A-T) and could be interpreted as the sum of the CD contributions of the single strands plus a contribution due to base pairing. The spectra of the duplexes below 235 nm were related to the polypurine strands present (poly-[r(A)] or poly[d(A)]). We interpret the CD intensity in the intermediate 255-235 nm region of these spectra to be mainly due to stacking of the constituent polypurine strands. Three of the five hybrids (poly[r(A) X d(U)], poly[r(A) X d(T)], and poly[d(T) X r(A) X d(T)]) were found to have heteronomous conformations, while poly[r(U) X d(A) X r(U)] was found to be the most A-like and poly[r(T) X d(A) X r(T)], the least A-like.

Simulation of interactions between nucleic acid bases by refined atom-atom potential functions

Energy of interaction between nitrogen bases of nucleic acid has been calculated as a function of parameters determining the mutual position of two bases. Refined atom-atom potential functions are suggested. These functions contain terms proportional to the first (electrostatics), sixth (or tenth for the atoms forming a hydrogen bond) and twelfth (repulsion of all atoms) powers of interatomic distance. Calculations have shown that there are two groups of minima of the base interaction energy. The minima of the first group correspond to coplanar arrangement of the base pairs and hydrogen bond formation. The minima of the second group correspond to the position of bases one above the other in almost parallel planes. There are 28 energy minima corresponding to the formation of coplanar pairs with two (three for the G:C pair) almost linear N-H . . . O and (or) N-H . . . N hydrogen bonds. The position of nitrogen bases paired by two such H-bonds in any crystal of nucleic acid component in polynucleotide complexes and in tRNA is close to the position in one of these minima. Besides, for each pair there are energy minima corresponding to the formation of a single N-H . . . O or N-H . . . N and one C-H . . . O or C-H . . . N hydrogen bond. The form of potential surface in the vicinity of minima has been characterized. The results of calculations agree with the experimental data and with more rigorous calculations based on quantum-mechanical approach.

The structure of triple helical poly(U).poly(A).poly(U) studied by Raman spectroscopy

Using Raman spectroscopy, we examined the ribose-phosphate backbone conformation, the hydrogen bonding interactions, and the stacking of the bases of the poly(U).poly(A).poly(U) triple helix. We compared the Raman spectra of poly(U).poly(A).poly(U) in H2O and D2O with those obtained for single-stranded poly(A) and poly(U) and for double-stranded poly(A).poly(U). The presence of a Raman band at 863 cm-1 indicated that the backbone conformations of the two poly(U) chains are different in the triple helix. The sugar conformation of the poly(U) chain held to the poly(A) by Watson-Crick base pairing is C3' endo; that of the second poly(U) chain may be C2' endo. Raman hypochromism of the bands associated with base vibrations demonstrated that uracil residues stack to the same extent in double helical poly(A).poly(U) and in the triple-stranded structure. An increase in the Raman hypochromism of the bands associated with adenine bases indicated that the stacking of adenine residues is greater in the triple helix than in the double helical form. Our data further suggest that the environment of the carbonyls of the uracil residues is different for the different strands.

Role of RecA protein spiral filaments in genetic recombination

Physical and enzymatic studies on RecA protein from Escherichia coli provide the basis for a molecular model of general genetic recombination, a novel feature of which is the role attributed to spiral filaments of RecA protein.

Molecular model for messenger RNA splicing

A molecular model is presented for a messenger RNA (mRNA) "splice region." The model requires cation coordination to reduce backbone-backbone electrostatic repulsion and it allows for every base residue on the pre-mRNA to be stacked in A-form helical geometry with a recognition element on the intron or exon (or both) sides of the splice junction. The two nucleotides involved in the initial steps of the cleavage-ligation mechanism must adopt a non-A-form geometry, which ideally positions reactive groups on the pre-mRNA for the necessary catalytic chemistry. The model is also consistent with available biochemical data on splicing reactions.

A RNA.DNA hybrid that can adopt two conformations: an x-ray diffraction study of poly(rA).poly(dT) in concentrated solution or in fibers

The RNA.DNA hybrid poly(rA).poly(dT) can adopt two conformations, depending upon its degree of hydration. Fibers yield a conventional A' RNA-like pattern at 79% relative humidity. In contrast, under highly solvated conditions this material yields an x-ray diffraction pattern with striking similarities to that of B DNA and clearly different from the RNA-like diffraction patterns previously obtained from fibers of other hybrids. A structural model is proposed for the solution form of the hybrid that has several similarities to models proposed for B DNA. The hybrid model accommodates the 2'-hydroxyl groups of the poly(rA) strand in intrachain hydrogen bonds to the adjacent ribose moieties.

Could poly(A) align the splicing sites of messenger RNA precursors?

In general, poly(A)-mRNA appears to be derived from larger nuclear RNA precursors. The maturation of these precursors involves excision of sequences of variable length from within the molecule and splicing of the remaining structural and coding sequences. The mechanism by which this process occurs is not known. It does not appear to operate solely through the recognition of a defined primary sequence or through the formation of a consistent secondary structure. We propose an alternative model in which poly(A) facilitates the splicing event by promoting the formation of triple-stranded structures within the mRNA precursor.

Distribution of polypyrimidine . polypurine segments in DNA from diverse organisms

Polypyrimidine . polypurine segments are regions of duplex DNA which contain a highly asymmetric distribution of pyrimidine and purine nucleotides. A polypyrimidine in single-stranded DNA can be detected by its ability to form a complex and poly(A, G) which will bind to hydroxyapatite. We tested DNA from a variety of organisms and found that most contained polypyrimidines. From the shape of the curve relating DNA size to percentage bound to hydroxyapatite, we conclude that polypyrimidine . polypurine segments occur widely in DNA from higher organisms, at intervals of 6000--8000 base pairs throughout the majority of the genome. Lower levels occur in DNA from yeast and Drosophila.

A computer aided oligonucleotide analysis provides a model sequence for RNA polymerase-promoter recognition in E.coli

A novel computer procedure has been used to search for homology among 17 known procaryotic promoter sequences. A model sequence, :formula: (see text), is compatible with the properties of all known promoter and operator mutations, predicts base positions for the initiation of RNA synthesis coinciding with those determined experimentally, is compatible with current models for the regulation of transcription, suggests that RNA polymerase could recognize the DNA double helix firstly in the B conformation then in the A.

Protonated polynucleotides structures - 22.CD study of the acid-base titration of poly(dG).poly(dC)

The acid-base titration (pH 8 --> pH 2.5 --> pH 8) of eleven mixing curve samples of the poly(dG) plus poly(dC) system has been performed in 0.15 M NaCl. Upon protonation, poly(dG).poly(dC) gives rise to an acid complex, in various amounts according to the origin of the sample. We have established that the hysteresis of the acid-base titration is due to the non-reversible formation of an acid complex, and the liberation of the homopolymers at the end of the acid titration and during the base titration: the homopolymer mixtures remain stable up to pH 7. A 1G:1C stoichiometry appears to be the most probable for the acid complex, a 1G:2C stoichiometry, as found in poly(C(+)).poly(I).poly(C) or poly(C(+)).poly(G).poly(C), cannot be rejected. In the course of this study, evidence has been found that the structural consequences of protonation could be similar for both double stranded poly(dG).poly(dC) and G-C rich DNA's: 1) protonation starts near pH 6, dissociation of the acid complex of poly(dG).poly(dC) and of protonated DNA take place at pH 3; 2) the CD spectrum computed for the acid polymer complex displays a positive peak at 255 nm as found in the acid spectra of DNA's; 3) double stranded poly(dG).poly(dC) embedded in triple-stranded poly(dG).poly(dG).poly(dC) should be in the A-form and appears to be prevented from the proton induced conformational change. The neutral triple stranded poly(dG).poly(dG).poly(dC) appears therefore responsible, although indirectly, for the complexity and variability of the acid titration of poly(dG).poly(dC) samples.

Raman spectral studies of nucleic acids. XVII. Conformational structures of polyinosinic acid

Laser-Raman spectra of poly(rI) show the formation of an ordered complex in aqueous solutions of high ionic strength. This structure exhibits the A-helix geometry, contains stacked bases and is apparently stabilized by specific hydrogen bonding involving hypoxanthine C6=0 groups. Thermal dissociation of the poly(rI) complex (Tm=45 degrees C) yields single-stranded and disordered poly (RI) chains. A disordered structure also occurs for poly (rI) in aqueous solutions of low ionic strength. In oriented films, poly (rI) forms an ordered structure probably the same as that which occurs in solutions of high ionic strength. Raman intensities measured at 815 and 1100 cm-1 in spectra of poly (rI) and poly (rU)-poly (rA)-poly(rU) indicate that the correlation previously established for single- and double-stranded ribopolymer structures is valid also for these multi-stranded structures. X-ray diffraction and model-building studies confirm the A-helix structure.

RNA structure

This review is concerned primarily with the physical structure and changes in the structure of RNA molecules. It will be evident that we have not attempted comprehensive coverage of what amounts to a vast literature. We have tried to stay away from particular areas that have been recently reviewed elsewhere. Citations to and information from them are included, however, so that access to the literature is available. Much of what we treat in depth deals with the crystal structures and solution behaviour of model RNA compounds, including synthetic polymers and molecular fragments such as dinucleoside phosphates. Sequence data on natural RNA are cited, but not in detail. Similarly, apart from tRNA, natural RNAs the structural determinations of which are presently not so far advanced, are not dwelt upon. We have tried to present in detail the available structural data with scaled drawings that permit facile comparisons of molecular geometries.