Effect of selective cytosine methylation and hydration on the conformations of DNA triple helices containing a TTTT loop structure by FT-IR spectroscopy

Human epigenome data reveal increased CpG methylation in alternatively spliced sites and putative exonic splicing enhancers

The role of gene body methylation, which represents a major part of methylation in DNA, remains mostly unknown. Evidence based on the CpG distribution associates its presence with nucleosome positioning and alternative splicing. Recently, it was also shown that cytosine methylation influences splicing. However, to date, there is no methylation-based data on the association of methylation with alternative splicing and the distribution in exonic splicing enhancers (ESEs). We presently report that, based on the computational analysis of the Human Epigenome Project data, CpG hypermethylation (>80%) is frequent in alternatively spliced sites (particularly in noncanonical) but not in alternate promoters. The methylation frequency increases in sequences containing multiple putative ESEs. However, significant differences in the extent of methylation are observed among different ESEs. Specifically, moderate levels of methylation, ranging from 20% to 80%, are frequent in SRp55-binding elements, which are associated with response to extracellular conditions, but not in SF2/ASF, primarily responsible for alternative splicing, or in CpG islands. Finally, methylation is more frequent in the presence of AT repeats and CpGs separated by 10 nucleotides and lower in adjacent CpGs, probably indicating its dependence on helical formations and on the presence of nucleosome positioning-related sequences. In conclusion, our results show the regulation of methylation in ESEs and support its involvement in alternative splicing.

The effect of structural water molecules on the normal mode spectrum of dTn . dAn x dTn DNA

In this paper we present a theoretical treatment of triplex B type DNA hydration using normal mode calculation techniques. Discrete solvent is added as spines of hydration in the Watson-Crick and Crick-Hoogsteen grooves as well as water bridges between the Phosphate groups. The effect of binding the discrete structural waters on the normal mode of vibration of the system was studied by introducing a parameter, Xw, that is proportional to the degree of water binding and inversely proportional to the relative humidity (RH) of the system. We examined the variation of the dipole moments of characteristic modes with Xw. The results show that there is a direct relationship between the degree of binding of the water molecules to the atoms in the triple helix, the relative humidity of the system and the conformation and stability of the triple helix. At high RH and Xw = 0:0 the triple helix has mostly B type conformation characteristics, with C'2 -endo sugars. The emergence of normal modes of vibration characteristic to the A type conformation (C'3 - endo sugars) at Xw = 0:4 and 60% RH indicates a conformational shift towards A-type for some of the sugars between Xw = 0.2 (80% RH) and Xw = 0.4 (60% RH). These results are in agreement with the "economy of hydration hypothesis" of Saenger (Saenger et al., 1986) which maintains that the main difference in the hydration of A- and B- forms of DNA is the presence of water bridges between adjacent Phosphate groups in the low-hydration A-form but not in the B- form. Free energy calculations for the triplex DNA with structural waters show that there is a minimum of the free energy at Xw = 0.2 and the free energy increases with Xw and becomes larger than the free energy of the B conformation without structural waters for Xw equal to and larger than 0.4. This result indicates that the B conformation is more stable with bound structural water molecules (for degrees of water binding that are not over 20% higher than the degree of binding between bulk water molecules). The structural water molecules are bound much tighter in the A conformation than in the B conformation. The model predicts that the B to A transition occurs at higher relative humidities in D2O than in H2O. Part of these results (Dadarlat, 1997) have been subsequently confirmed by the experimental work and MD simulations of Ouali (Ouali et al., 1997). The experimental results showed that the N-type sugars corresponding to the A conformation are clearly detected below 75% RH.

Influence of 5-bromodeoxycytosine substitution on triplex DNA stability and conformation

Three triple-helical hairpin DNAs with substitution of 5-bromocytosine for cytosine in different strands have been investigated by molecular mechanics and Raman spectroscopy. The stability of the three substituted triplexes were compared with the corresponding unsubstituted triplex DNA by the molecular mechanics method. Base stacking interactions and strand--strand interactions of each triplex were analyzed in detail. Sugar conformations in these triplexes have been determined by both vibrational spectroscopy and molecular dynamics simulation. The hairpin triplexes with substitution occurring in strand I or both in strands I and III have the main sugar conformation of C3'-endo, while the triplex with substitution occurring in strand III is the combination of C3'-endo and C2'-endo sugar conformation. Theoretical results are basically in agreement with experiments.

Stability of triple-helical poly(dT)-poly(dA)-poly(dT) DNA with counterions

Structural conformation of triple-helical poly(dT)-poly(dA)-poly(dT) has been a very controversial issue recently. Earlier investigations, based on fiber diffraction data and molecular modeling, indicated an A-form conformation with C'3-endo sugar pucker. On the other hand, Raman, solution infrared spectral, and NMR studies show a B-form structure with C'2-endo sugars. In accordance with these experimental results, a theoretical model with B-form, C'2-endo sugars was proposed in 1993. In the present work we investigate the dynamics and stability of the two conformations within the effective local field approach applied to the normal mode calculations for the system. The presence of counterions was explicitly taken into account. Stable equilibrium positions for the counterions were calculated by analyzing the normal mode dynamics and free energy of the system. The breathing modes of the triple helix are shifted to higher frequencies over those of the double helix by 4-16 cm-1. The characteristic marker band for the B conformation at 835 cm-1 is split up into two marker bands at 830 and 835 cm-1. A detailed comparison of the normal modes and the free energies indicates that the B-form structure, with C'2-endo sugar pucker, is more stable than the A-form structure. The normal modes and the corresponding dipole moments are found to be in close agreement with recent spectroscopic findings.

Effect of selective substitution of 5-bromocytosine on conformation of DNA triple helices

Three triplex DNAs containing 5-bromocytosine[BrC] were studied by vibrational spectroscopy and molecular modelling. Firstly, three oligodeoxypyrimidines of 5'-(TC)3-T4-(BrCT)3 [CBrC], 5'-(TBrC)3-T4-(CT)3 [BrCC] and 5'-(TBrC)3-T4-(BrCT)3 [BrCBrC] were synthesized and then reacted with an oligodeoxypurine of 5'-(AG)3 at pH=4.5 in phosphate buffer respectively to form three comparative hairpin triplex named CY,YC and YY. The results of FT-Raman and IR revealed that YY is almost in A-like form, CY and YC are combinations of A-like form and B-like form, but A-form dominates in CY while B-form is equivalent as A-form in YC. The result is consistent with the theoretical analysis.

Biphasic transitions of a hairpin hexanucleotide triplex DNA

The conformational transitions (helix-coil transitions) of three hairpin triple helices, models 5'-(A-G)(3) + 5'-(T-C)(3)-T(4)-((br)C-T)(3) [CY], 5'-(A-G)(3) + 5'-(T-(br)C)(3)-T(4)-(C-T)(3) [YC] and 5'-(A-G)(3) + 5'-(T-(br)C)(3)-T(4)-((br)C-T)(3) [YY], are characterized in this work by UV spectroscopy. Melting of these triplexes is biphasic, and the profiles are used to obtain the thermodynamic parameters. The thermodynamic properties of the hairpin triplex are T(m) = 19.45 degrees C and DeltaH(vH) = 293.12 kJ mol(-1) for CY, T(m) = 22.85 degrees C and DeltaH(vH) = 256.63 kJ mol(-1) for YC and T(m) = 28.47 degrees C and DeltaH(vH) = 234.68 kJ mol(-1) for YY at pH 4.4. Those of the duplex are T(m) = 30.50 degrees C and DeltaH(vH) = 427.09 kJ mol(-1) for CY, T(m) = 32.96 degrees C and DeltaH(vH) = 374.47 kJ mol(-1) for YC and T(m) = 33.24 degrees C and DeltaH(vH) = 329.67 kJ mol(-1) for YY at pH 4.4. The distinct transitions of triplex to duplex and duplex to single strands are analyzed using the nearest-neighbor Ising model. Electrostatic effects on each conformation are also analyzed.

Hydrated water molecules of pyrimidine/purine/pyrimidine DNA triple helices as revealed by FT-IR spectroscopy: a role of cytosine methylation

Hydrated water molecules of pyrimidine/purine/pyrimidine DNA hairpin triplex was studied by a comparison of triplex (CC.AG6) formed by a host oligodeoxypyrimidine of 5'-d(TC)3T4(CT)3(CC) with a target hexadeoxypurine 5'-d(AG)3(AG6) strand and by triplexes (MM.AG6, MC.AG6, and CM.AG6) formed by oligonucleotides with the exact sequences as above except 5-methylcytosine replaced all (MM), 5' end half (MC), and 3' end half (CM) cytosine bases in CC via FT-IR spectroscopy in hydrated film. Results revealed that: (i) all these triplexes have a similar hydration pattern, in which water molecules probably bound in the N7 sites of adenines and guanines in the Crick-Hoogsteen groove, and to the methyl group of thymidines in the Watson-Hoogsteen groove. There are also some bound water molecules found at the O2 sites of thymines in both Watson-Crick and Crick-Hoogsteen grooves. (ii) In the CC.AG6 triplex the S-type sugars are always dominant in all hydrated states, whereas in MM.AG6 triplex the relative population of the N-type sugars is very close to that of the S-type between 86% and 66% of humidity. Furthermore, the sugar conformation in two partially modified triplexes (CM.AG6, and MC.AG6) are dominant by the N-type at lower humidity. This phenomenon might reflect that the degree of bound water varies among the binding sites of bases. (iii) The effect of introducing a methyl group on cytosine is to generate a spine of hydrophobic region in MM (MC and MC). The enlarging hydrophobic area not only increase the stability in solution, and also the stability in sodium hydrated films of the pyrimidine/purine/pyrimidine hairpin triplexes.