A pseudoknot-compatible universal site is located in the large ribosomal RNA in the peptidyltransferase center.

The RNA secondary structure is not confined to a system of the hairpins and can contain pseudoknots as well as topologically equivalent slipped-loop structure (SLS) conformations. A specific primary structure that directs folding to the pseudoknot or SLS is called SL-palindrome (SLP). Using a computer program for searching the SLP in the genomic sequences, 419 primary structures of large ribosomal RNAs from different kingdoms (prokaryota, eukaryota, archaebacteria) as well as plastids and mitochondria were analyzed. A universal site was found in the peptidyltransferase center (PTC) capable of folding to a pseudoknot of 48 nucleotides in length. Phylogenetic conservation of its helices (concurrent replacements with no violation of base pairing, covariation) has been demonstrated. We suggest the reversible folding-unfolding of the pseudoknot for certain stages of the ribosome functioning.

A pseudosquare knot structure of DNA in solution.

We report a high-resolution NMR structure of a homodimer formed by a synthetic 25 residue DNA oligonucleotide GCTCCCATGGTTTTTGTGCACGAGC. This structure presents a novel structural motif for single-stranded nucleic acids, called a pseudosquare knot (PSQ). The oligonucleotide was originally designed to mimic a slipped-loop structure (SLS), another "unusual" DNA structure postulated as an alternative conformation for short direct repeats in double-stranded DNA. The design of the sequence is compatible with both SLS and PSQ structures, both of which possess identical sets of base-paired and unpaired nucleotides but different tertiary folds. We used deuteration of the H8 positions of purines to ascertain that the PSQ is actually formed under the conditions used. The PSQ structure was solved based on homonuclear proton nuclear Overhauser effect data using complete relaxation matrix methods. The structure essentially consists of two side-by-side helices connected by single-stranded loops. Each of the helices is well-defined; however, the relative orientation of the two remains undetermined by the NMR data. The sequences compatible with the PSQ formation are frequent in single-stranded genomes; this structure may play a role as a dimerization motif.

Distamycin-stabilized antiparallel-parallel combination (APC) DNA.

The formation of Antiparallel-Parallel-Combination (APC) DNA, a liner duplex with a segment of parallel-stranded (ps) helix flanked by conventional B-DNA, was tested with a number of synthetic oligonucleotides. The groove-binding ligand distamycin A (DstA) was used to stabilize the ps segment comprising five A x T base pairs. Two drug molecules bound per APC, one in each of the two equivalent grooves characteristic of ps-DNA. APC-DNA, reference molecules and their complexes with DstA were analysed by several methods: circular dichroism and absorption spectroscopy, thermal denaturation, chemical modification, and molecular modeling. The dye binding stoichiometry differed significantly due to inherent structural differences in the groove geometries of ps-DNA (trans base pairs, similar grooves) and conventional antiparallel-stranded (aps) B-DNA (cis base pairs, distinct major and minor grooves). The data support the existence of APC folding in solution.

Slipped loop structure of DNA: a specific nucleotide sequence forms only one unique conformer.

Earlier with some DNA sequences we were able to prove the existence of a new polynucleotide chain folding named slipped loop structure, or SLS [1,2]. However, the possibility of the presence of two SLS isomers in equilibrium was not excluded in the experiments. Here we are dealing with a specially designed structure formed by two short oligonucleotides intended for avoiding such a situation. To minimize the possibility of alternative structure formation and stabilize the conformation under investigation, the oligonucleotide sequences were designed in such a way that the bimolecular structure SLS31 would have two binding sites for antibiotic distamycin A. The sample was exposed to chemical probing both in the presence of distamycin A and without the ligand and the accessible nucleotides were mapped. The results do not suggest the presence in the solution of two isomers with different types of loop slippage without interloop interactions and strongly support the formation of a unique slipped loop conformation stabilized by an additional interloop helix, or slipped loop structure.

Fidelity of binding of the guanidinium nucleic acid (DNG) d(Tg)4-T-azido with short strand DNA oligomers (A5G3A5, GA4G3A4G, G2A3G3A3G2, G2A2G5A2G2). A kinetic and thermodynamic study.

Short strand DNA oligomers (A5G3A5, GA4G3A4G, G2A3G3A3G2, and G2A2G5A2G2) and the guanidinium (g) linked thymidyl nucleoside d(Tg)4-T-azido associate as triplexes. The melting temperatures, Tm, the association and dissociation kinetic and thermodynamic parameters and activation energies for the triplexes were determined by UV thermal analysis. The hypochromic shift and Tm for triplex formation increases with increase in concentration and decreases with the number of mismatches. The melting temperatures are between 35 and 55 degrees C in the range of ionic strength of 0.06-0.24 and decrease with increase in ionic strength at 100 deg/(ionic strength unit). The melting and cooling curves exhibit hysteresis behavior in the temperature range 5-95 degrees C at 0.2 deg/min thermal rate. From these curves, the rate constants and the energies of activation for association (k(on), E(on)) and dissociation (k(off), E(off)) processes were obtained. The second-order rate constants, k(on), for the triplex formation at 288 K are between 10 and 500 M(-2) s(-1). Values of k(on) increase with the decrease in the ionic strength. The first order rate constants for the dissociation, k(off), at 288 K are between 10(-6) and 40 x 10(-6) s(-1) and increase with increase in ionic strength. The energies of activation for the association and dissociation processes are in the range -22 to -9 kcal/mol and 8 to 29 kcal/mol, respectively. At 6.3 x 10(-5) M/base and at the physiological ionic strength (0.15-0.30) and below, the triplex structures formed with d(Tg)4-T-azido and A5G3A5 and GA4G3A4G have well-defined Tm values. The melting curves with G2A3G3A3G2 and G2A2G5A2G2 are very shallow with small hypochromic shifts denoting negligible binding at physiological ionic strength. Therefore, with the increase in the G content (mismatched base pairs) at a certain concentration (e.g., 6.3 x 10(-5) M/base), discrimination (change in fidelity) occurs in the formation and strength of binding of d(Tg)4-T-azido to d(pAn pGm) oligomers. The standard molar enthalpies for triplex formation have in general larger negative values at low ionic strength than at high ionic strength, indicating that at lower mu values the formation of triplexes of d(Tg)4-T-azido with d(pAn pGm) are more favorable. The values of deltaH(standard)(288) calculated from the activation parameters are between -17 and -49 kcal/mol, and the values of deltaG(standard)(288) are between -7.5 and -11.8 kcal/mol for A5G3A5, GA4G3A4G, G2A3G3A3G2, and G2A2G5A2G2, respectively. There is a linear relationship in the enthalpy-entropy compensation for the triplex melting thermodynamics.

Experimental evidence for slipped loop DNA, a novel folding type for polynucleotide chain.

DNA regions with short direct repeats (5-7bp) with a spacer in between, when under super-helical stress, are known to become susceptible to single-strand specific nuclease S1. This is in accord with formation of two shifted loops protruding from the opposite chains. Such type of folding could have been additionally stabilized by base pairing between the complementary parts of the loops that explains existence of the protected from S1 moieties of the loops. To test this possibility we designed and synthesized an oligonucleotide of 56 bases, so that it forms a hairpin with a stem which fails to acquire a traditional helix due to a special sequence but may favor the formation of the proposed Slipped Loop Structure (SLS). The oligonucleotide folding was studied by a chemical modification method at one nucleotide level resolution. Three zones, protected from the used probes were found: the one that forms the stem, and the others that are located within the two by-loops in those moieties which have the base pairing potential. Proceeding from the data obtained and stereochemical analysis a 3-D scheme for the SLS form of DNA is suggested.

Parallel purine-pyrimidine-purine triplex: experimental evidence for existence.

Oligonucleotides 5'-d(CT)5-L-d(AG)5-L-d(GA)5-3' and 5'-d(GA)5-L-d(TC)5-L-d(GA)5-3' [L = pO(CH2CH2O)3p] were studied by thermal denaturation, chemical modification and binding of fluorescent dyes. Both oligonucleotides are shown to fold back on itself twice forming at pH 7 a sufficiently stable triplex ether with antiparallel-oriented oligopurine strands (the first compound) or parallel-oriented oligopurine strands (the second compounds). The parallel triplex is significantly less stable than the antiparallel one. On the basis of conformational modeling, possible types of base tripling in the triplets are proposed. Thus our data provide the first convincingly evidence for the existence of a purine-pyrimidine-purine triplex with parallel orientation of identical strands.

The R-form of DNA does exist.

Oligonucleotide 5'-d(CATGCTAACT)-L-d(AGTTAGCATG)-L-d(CATGCTAACT)-3' [L = pO(CH2CH2O)3p] is shown to fold back on itself twice forming at pH 7 a sufficiently stable triplex (Tm is about 30 degrees C) with parallel-orientated identical strands (the recombinant or R-form of DNA). Experimental evidence was obtained by studying thermal denaturation, chemical modification and binding of fluorescent probes. The stability of the R-triplex increases in the presence of divalent ions or spermidine. Its structure is characterized by a certain heterogeneity that causes the cooperativity of a triplex-to-duplex transition to decrease. On the basis of conformational modeling, the possible types of base tripling in all four triplets are proposed. The experimental data as well as the molecular mechanic calculations indicate that the stabilities of triplets in the R-triplex decrease in the order: G:C-G = A:T-A >> T:A-T > C:G-C.

Thermodynamics of B-Z transition of poly[d(G-C)] in a water-ethanol solution. The "tie calorimetry".

Poly[d(G-C)] in a 55% ethanol solution undergoes a transition from the Z form to the B form when the temperature is increased from 20 degrees to 50 degrees C. The enthalpy of the transition, delta HBA = -1.4 kcal/mol, has been determined with a "tie" polyamine which stabilizes the Z conformation. This value has been shown to be practically independent of ionic strength within the range of 5 X 10(-4) M - 2 X 10(-3) M NaCl.

Three-state diagram for DNA.

Experimental phase diagrams (A form, B form, Coil) were built in the coordinates (a, alcohol fraction: T, temperature) for the natural DNAs and poly d(A-T). The main parameter of the B-A transition,-cooperativity length, nu o, was estimated by the slopes of the branches A-B, A-Coil, B-Coil in the vicinity of the triple point: nu o = 10-20 base pairs, which corresponds to the energy for the B/A junction of 1.2-1.8 kcal/mol. We discovered two new effects which are due to the coexistence of the three different conformations in one polymeric molecule: an increase in the melting temperature above that for the 'ideal' triple point (i.e. for the case of the ideal phase transitions); a widening of the melting curve within the B-A transition range.

Increase in temperature induces the Z to B transition of poly[d(G-C)] in water-ethanol solution.

An increase in temperature from 20 to 50 degrees C results in the complete transition from the Z to B form of poly[d(G-C)], dissolved in a 55% ethanol-water solution. The transition is fully reversible and displays a slow kinetics. The transition profiles for the free polynucleotide and for that in the presence of ethidium bromide, which is known to stabilize the B form, are obtained by circular dichroism. Based on these data the enthalpy value for the B-Z transition in our conditions is estimated to be delta HBZ = -0.7 kcal/mol.

B-A transition in DNA.

The B-A transition is characterized by two main physical parameters which might be biologically important: the cooperativity length and free energy difference between the B and A states under physiological conditions. Earlier these values were determined by us in an experiment over the B-A shift in water-non-electrolyte solutions in the presence of small molecules ("ties") affecting the B-A equilibrium. Now we report a new method of determining the cooperativity length which utilizes a phase diagram (B,A, coil). The coordinates are the fraction of non-electrolytes and temperature. Application of the Ising model for joint description of the B-A and helix-coil transitions makes possible to find the cooperativity length using the known thermodynamic parameters of the DNA melting and the appearance of the phase diagram near the triple point (A,B,coil). The value thus found (approximately 10(1) base pairs) is in accord with the values obtained with ties. In the new method the junctions between the A and B segments actually play the role of ties, stabilizing the double-stranded state. A considerable effect of the melting curve widening within the B-A transition range was discovered. A possible explanation suggests the presence of the A-philic sequences in the natural DNA. The A-phility of the oligo G oligo C sequence was estimated from the B-A transition curves of the synthetic decanucleotide duplexes.

The transitions between left- and right-handed forms of poly(dG-dC).

The circular dichroism study of water/trifluoroethanol (TFE) solutions of poly(dG-dC) has revealed the following: The polynucleotide is present as a B form up to a TFE content of 60% (v/v) or less. Then, a cooperative transition into a left-handed Z form occurs. Within the region of 66-78% TFE, a continuous non-cooperative change is going on which can be attributed to an intrafamily transition within the family of Z forms. At last, in the interval of 80-84% TFE, a second cooperative transition, probably, Z - A is realized. Both transitions, Z - A and Z - B, show slow kinetics (10-60 min) while the direct transitions from the A to B form taking less than 10 sec. The length of cooperativity for the B - Z transition, Vo = 25 base pairs was estimated using spermine molecules. Spermine was found to induce the B to Z transition in the (dG-dC) sequences even in the absence of TFE which might be biologically interesting.