On the basis of chemical considerations and model building, the Watson-Crick concept of complementary base pairing is extended to a wider range of DNA pairs that A-T and G-C (including A-C, G-T, A-A, G-G and G-A) by invoking imino or enol tautomers (or protonated species) and synisomers. The virtual absence of these additional base pairs from DNA is explained in terms of the low frequency with which these unfavoured forms occur and the two-step mechanism of DNA synthesis, whereby residues are first incorporated by the DNA polymerase and then checked. This base-pairing hypothesis is used to explain the origin, nature and level of spontaneous substitution mutations, their enhancement by base analogues, and the unique effects of certain mutator alleles.
To understand more fully how amino acid composition of proteins has changed over the course of evolution, a method has been developed for estimating the composition of proteins in an ancestral genome. Estimates are based upon the composition of conserved residues in descendant sequences and empirical knowledge of the relative probability of conservation of various amino acids. Simulations are used to model and correct for errors in the estimates. The method was used to infer the amino acid composition of a large protein set in the Last Universal Ancestor (LUA) of all extant species. Relative to the modern protein set, LUA proteins were found to be generally richer in those amino acids that are believed to have been most abundant in the prebiotic environment and poorer in those amino acids that are believed to have been unavailable or scarce. It is proposed that the inferred amino acid composition of proteins in the LUA probably reflects historical events in the establishment of the genetic code.
Base pairing in codon-anticodon interaction has been investigated in order to understand the basis on which particular base pairs have been selected for or against participation at the wobble position and the basis for codon-anticodon infidelity.
The structural integrity and biological activity of many proteins are known to depend on their content of one or a very few tightly bound low-molecular-weight moieties, often metal ions. There is a growing appreciation of a strong analogy between the factors that determine and affect the molecular structure of proteins and the corresponding factors for nucleic acids. Thus, despite wide differences in the chemical nature of the monomers of which they are formed, the major determinant of their native conformation is their primary structure.1-3 The bonding forces and environmental factors on which depend the integrity of their conformations also appear to be the same, and they are responsive to similar denaturants.4 The analogy is particularly striking in the case of sRNA,5 whose small size is conducive to a unique macromolecular architecture containing elements of both secondary and tertiary structure6' 7(rather than to the constellation of statistical structures likely for ribosomal, viral, and messenger RNA's). The finding reported here, that several sRNA's (when prepared by conventional methods involving denaturing steps) require the incorporation of site-bound Mg++ or some other divalent cation in order to be able to express their amino acid acceptor activities, makes the analogy seem even more plausible.While the involvement of Mg++ in the structure and function of sRNA has been
Near-UV difference spectral analysis of the triplex formed from d(C-T)6 and d(A-G)6.d(C-T)6 in neutral and acidic solution shows that the third strand dC residues are protonated at pH 7.0, far above their intrinsic pKa. Additional support for ion-dipole interactions between the third strand dC residues and the G.C target base pairs comes from reduced positive dependence of triplet stability on ionic strength below 0.9 M Na+, inverse dependence above 0.9 M Na+ and strong positive dependence on hydrogen ion concentration. Molecular modeling (AMBER) of C:G.C and C+:G.C base triplets with the third strand base bound in the Hoogsteen geometry shows that only the C+:G.C triplet is energetically feasible. van't Hoff analysis of the melting of the triplex and target duplex shows that between pH 5.0 and 8.5 in 0.15 M NaCl/0.005 M MgCl2 the enthalpy of melting (delta H degree obs) varies from 5.7 to 6.6 kcal.mol-1 for the duplex in a duplex mixture and from 7.3 to 9.7 kcal.mol-1 for third strand dissociation in the triplex mixture. We have extended the condensation-screening theory of Manning to pH-dependent third strand binding. In this development we explicitly include the H+ contribution to the electrostatic free energy and obtain [formula: see text]. The number of protons released in the dissociation of the third strand from the target duplex at pH 7.0, delta n2, is thereby calculated to be 5.5, in good agreement with approximately six third strand dc residues per mole of triplex. This work shows that when third strand binding requires protonated residues that would otherwise be neutral, triplex formation and dissociation are mediated by proton uptake and release, i.e., a proton switch. As a by-product of this study, we have found that at low pH the Watson-Crick duplex d(A-G)6.d(C-T)6 undergoes a transition to a parallel Hoogsteen duplex d(A-G)6.d(C(+)-T)6.
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