Thermochemistry of aqueous solutions of alkylated nucleic acid bases. I. Apparent molar heat capacities of uracil, thymine and their derivatives

Apparent molar heat capacities phiC(p(1,3)) of uracil, thymine and a series of their alkylated derivatives: m(1)Ura,m(1,3)(2) Ura, m(1,3)(2)Thy, mi(1,3,6)(3)Ura, m(1,3)(2),e(5)Ura and e(1,3)(2)Thy in dilute aqueous solutions were measured in the temperature range of 293.15-388.15 K, using a differential adiabatic scanning microcalorimeter. They were found to lie (i) much higher than the estimated heat capacities C(p)(s) of solid compounds, (ii) comparable with the respective partial molar heat capacities at infinite dilution, C(o)(p2), and (iii) linearly related to the number nH of hydrogen atoms covalenuy bound to the solute molecules. The increment thus obtained DeltaC(o)(p2)=42.8 J mole(-1) K(-1)n(-1)(H) per each hydrogen atom at 298.15 K proved (i) to coincide closely with those found previously for homologous series of aliphatic amides and hydrocarbons, and (ii) to decrease with a rise of temperature. These findings imply the involvement of hydrophobic hydration of the solutes.     

Thermochemistry of aqueous solutions of alkylated nucleic acid bases. IV. Enthalpies of hydration of 5-alkyluracils

Enthalpies of sublimation, DeltaH degrees (subl) and of solution in water, DeltaH degrees (sol) were determined for a series of crystalline 1,3-dimethyl-uracil derivatives substituted at the C5-ring carbon atom with alkyl groups (-C(n)H(2n+1), n = 2-4) and some of their C(5.6)-cyclooligomethylene analogues (-(CH2)(n)-, n = 3-5). From these data. enthalpies of hydration DeltaH degrees (hydr)= DeltaH degrees (sol) - DeltaH degrees (subl) were calculated and corrected for energies of cavity formation in pure liquid water in order to obtain enthalpies of interaction, DeltaH degrees (int) of the solutes with their hydration shells. The latter are discussed together with the recalculated DeltaH degrees (int) for variously methylated uracils, obtained previously according to a simplified correction procedure, in terms of perturbations in the energy and scheme of hydration of the diketopyrimidine ring brought about by alkyl substitution. It was found that each -CH2-group added with an alkyl substitution contributes favorably about -20 kJ mol(-1) toDeltaH degrees (int).This contribution is partially cancelled by the unfavorable contribution to DeltaH degrees (int) connected with removal of some water molecules bound in the first and subsequent hydration layers by an alkyl substituent. This is particularly evident on substitution at the polar side of the diketopyrimidine ring on which water molecules are expected to be bound specifically.     

Thermochemistry of aqueous solutions of alkylated nucleic acid bases. II. Apparent molar relative enthalpies of dilution of solutions containing uracil and thymine derivatives

Apparent molar relative enthalpies of dilution φ_Lof aqueous solutions of a series of alkylated diketopyrimidines: m¹Ura, m^1,3₂Ura, m^1,3₂Thy, m^1,3,6₃Ura and e^1,3₂Thy were measured as a function of concentration of the solutes at three temperatures 298.15, 308.15 and 318.15 K. Dilution proved to be an endothermic process over the whole range of molalities m and temperatures studied for all compounds except the e^1,3₂Thy solution, the dilution of which, with the exception of the lowest concentrations (m > 0.2–0.3) was an exothermic process. Partial molar relative enthalpies of dilution -L₂(m) derived from φ_L(m) functions were analysed as if they were composed of two additive contributions: an endothermic one -L₂, (m₁) and an exothermic one 1.2, (m_as0), owing to the presence in the solutions of a free monomer m₁ or associated species m_as, respectively. Partial molar heat capacities of the solutes, evaluated by differentiation of -L₂(m) functions in respect to temperature, decreased with the rise of concentration in the order of the tendency of the solutes to stacking association. Changes in heat content and in heat capacity of solutions upon their dilution are interpreted in terms of involvement of hydrophobic hydration and association of the solutes.     

Thermochemistry of aqueous solutions of alkylated nucleic acid bases. VI. Enthalpies of hydration of 2-alkyl-9-methyladenines

Enthalpies of solution in water, delta H0sol, and vant'Hoff enthalpies of sublimation, delta H0subl, were determined experimentally for a number of crystalline 2-alkyl derivatives of 9-methyladenine: m2(2,9)Ade, e2m9Ade, pr2m9Ade and but2m9Ade. Standard enthalpies of hydration, delta H0hydr derived from these data were corrected for the calculated cavity terms, delta H0cav, to yield enthalpies of interaction, delta H0int, of the solutes with their hydration shells. The apparent residual contribution of alkyl groups, R, to the enthalpy of interaction delta delta H0int (R) was found to increase linearly with the number of CH2 groups added upon alkyl substitution, whereas this contribution calculated per unit area of the water-accessible molecular surface, SB, of alkyl residues delta delta H0int (R): delta SB(R) appeared constant over the whole series of the compounds investigated. This indicates that alkyl groups substituted at the C(2) carbon atom of the adenine contribute additively to the van der Waals' part of the enthalpy of interaction and do not affect the electrostatic part of the energy of interaction of the solutes with their hydration shells.     

Thermodynamics of some nucleic acid bases and nucleosides in water, and their transfer to aqueous glucose and sucrose solutions at 298.15 K

The partial molar heat capacities and volumes of some of the constituents of nucleic acids have been determined in water and 1 molal aqueous glucose and sucrose solutions in order to elucidate the nature of interactions occurring between various nucleic acid bases, nucleosides and the sugar (glucose and sucrose) molecules. The results have been explained in terms of the contributions from hydrophobic interactions, hydrophilic interactions and the hydrogen bonding between the solute and solvent molecules. The results have also been compared with those of amino acids and peptides in aqueous glucose and sucrose solutions.     

A study of the hydration of deoxydinucleoside monophosphates containing thymine, uracil and its 5-halogen derivatives: Monte Carlo simulation.

An extensive Monte Carlo simulation of hydration of various conformations of the dinucleoside monophosphates (DNP), containing thymine, uracil and its 5-halogen derivatives has been performed. An anti-anti conformation is the most energetically stable one for each of the DNPs. In the majority of cases the energy preference is determined by water-water interaction. For other dimers conformational energy is the most important factor, or both the factors are of nearly equal importance. The introduction of the methyl group into the 5-position of uracil ring most noticeably influences the conformational energy and leads to the decrease of its stabilizing contribution to the total interaction energy. The introduction of halogen atoms increases the relative content of anti-syn and syn-anti conformations of DNPs as compared to the parent ones due to the formation of an energetically more favorable water structure around these conformations. A correlation is observed between the Monte Carlo results for the halogenated DNPs and their experimental photoproduct distribution. The data obtained demonstrates a sequence dependence in the photochemistry of the halogenated dinucleoside monophosphates.     

Study of the hydration characteristics of nucleic acid bases and their complementary pairs using the Monte-Carlo method

To elucidate the role of certain atomic groups in the formation of the nucleic acid hydrate shell, we simulated the systems involving a base or a complementary pair (the base molecules are methylated in N9 of purines and in N1 of pyrimidines) and 25 water molecules using the Monte-Carlo method. All hydrophilic centers, except for N1 purines and N3 pyrimidines in complementary pairs, form hydrogen bonds (H-bonds) with water molecules. The mean numbers of H-bonds formed by different centers, and distributions of the geometric characteristics of these bonds, which appeared similar to those in crystals, have been calculated. The formation of bridges of one, two of three water molecules between hydrophilic centers was shown. The probabilities of formation of these bridges have been calculated.     

Separation of purine derivatives by polymer-bound nucleic acid bases

Separation of a variety of purine bases, which include 7-methyl derivatives, was studied by using polyethyleneimine-coated silicagel which bound hypoxanthine, cytosine or guanine moieties. The separation behavior seems to be related to the interaction of imidazole part of purine derivatives with the resins through hydrogen bonding.     

Reaction of nucleic acids bases and their derivatives with peroxodisulfate ion

Reaction with peroxodisulfate ion was investigated, that is, reaction of 1,3-dimethyluracil, 1,3-dimethylthymine, and caffeine with carbon radicals formed from decarboxylation of carboxylic acids, oxidation of the methyl group at 5-position of thymines, and halogenation of nucleic acids bases and their derivatives with alkali halides.     

Degradation of the pyrimidine bases uracil and thymine by Escherichia coli B

Degradation of the pyrimidine bases uracil and thymine by Escherichia coli B was investigated. The known products of the reductive pathway of pyrimidine base catabolism were tested to determine if they could support the growth of E. coli B cells as sole sources of nitrogen or carbon. As might be expected if the reductive pathway was present, it was found that dihydrouracil, N-carbamoyl-beta-alanine, beta-alanine, dihydrothymine and beta-aminoisobutyric acid could sustain the growth of the bacterial cells as sole nitrogen sources by at least a fourteen-fold greater level than that observed if they were included as sole carbon sources. The existence of the reductive pathway of pyrimidine base degradation was confirmed in this micro-organism, since dihydrouracil, N-carbamoyl-beta-alanine and beta-alanine were detected following thin-layer chromatographic separation of the catabolic products of uracil and dihydrouracil.     

Affinity chromatography of nucleosides and nucleic acid base derivatives with nucleic acid bases or nitrobenzeneboronic acid substituted silicas

Nucleic acid bases such as adenine and uracil, and nitrobenzeneboronic acid substituted silicas were prepared by the reaction of chloromethylbenzene substituted silica with adenine sodium salt and trimethylsilylated uracil, and nitration of benzeneboronic acid substituted silica, respectively. From the results of HPLC of nucleosides and N-ethyl derivatives of nucleic acid bases using modified silicas, hydrophobic base stacking interaction, selective hydrogen bonding interaction between purine and pyrimidine bases, and reversible cyclic boronate ester formation between diols of nucleosides with boronic acid were effective for the separation of nucleic acid related compounds. Moreover, association constants for hydrogen bonding formation of nucleic acid bases were estimated.     

Alkylation of nucleic acid components by ethyleneimine derivatives. I. Alkylation of bases

In the course of investigating the reaction conditions of the nucleic acid components alcylation, the interaction of thioTEPA (N,N',N'-triethylenethiophosphoamide) with hydrochloric and perchloric acids was studied, perchloric acid increasing the alkylation products yield. HPLC and UV spectroscopy were used to isolate and identify products of nucleic bases alkylation by ethylenimine and its derivatives (thioTEPA and monoaziridinediethylphosphate). It is shown that under neutral conditions phosphoaminoethylation takes place, whereas under slightly acidic conditions products of aminoethylation are formed.     

Quantitative changes in the content of nucleic acid bases and their derivatives in a culture ofPenicillium sizowi

Acid-soluble (“free”) nucleotides, nucleosides and bases were analyzed in the mycelium and in the culture filtrate of the fungusPenicillium sizowi, using micro-thin-layer chromatography on alumina and densitometry of the zones of the individual components. It was found that the levels of the various components underwent complicated changes, the corresponding curves exhibiting from one to three maxima which occur at different periods of cultivation. It was observed that a substantial amount of nucleotides, nucleosides and bases occurs in the medium as early as at the beginning of the exponential phase of growth. An attempt was made to elucidate some peculiarities of the nucleotide pool ofPenicillium species, using enzymes responsible for the individual transformations of nucleotides, nucleosides and bases.