Tertiary structure, stabilization pairs

The base sequence and the tertiary structure of the yeast tRNA specific for phenylalanine (tRNA " ) is typical of all tRNAs. The molecule (see also p.86) contains a high proportion of unusual and modified components (shaded in dark green in Fig. 1). These include pseudouridine (T), dihydrouridine (D), thymidine (T), which otherwise only occurs in DNA, and many methylated nucleotides such as 7-methylguanidine (m G) and—in the anticodon—2 -0-methylguanidine (m G). Numerous base pairs, sometimes deviating from the usual pattern, stabilize the molecule s conformation (2). 

Another example of a quantal repeat—but with considerable variation in sequence—is seen in the keratin-associated proteins (KAPs). In sheep, these display pentapeptide and decapeptide consensus repeats of the form G—G—Q—P—S/T and C-C-Q/R—P—S/T—C/S/T—C—Q—P/T—S, respectively (Parry et al., 1979). Some of the positions, as indicated by the presence of a consensus sequence, contain residues that occur much more frequently than others, but the absolute conservation of a residue in any position is not observed. The decapeptide consists of a pair of five-residue repeats closely related, but different to that displayed by the pentapeptide. Although the repeats have an undetermined structure, the similarity of the repeat to a sequence in snake neurotoxin suggests that the pentapeptides will adopt a closed loop conformation stabilized by a disulphide bond between cysteine residues four apart (Fig. 5 Fraser et al., 1988 Parry et al, 1979). Relative freedom of rotation about the single bond connecting disulphide-bonded knots would give rise to the concept of a linear array of knots that can fold up to form a variety of tertiary structures. The KAPS display imperfect disulphide stabilization of knots and have interacting... 

Although the base triplets are of only minor importance in double-stranded nucleic acids, they have a structural role in determining and stabilizing the tertiary structure of transfer RNA, as discussed in Chapter 20. Base quadruplets where two Watson-Crick base pairs are associated as shown in Fig. 16.17 have been invoked to play a role in DNA-DNA aggregation and DNA recombination, but there is no direct evidence for their occurrence. 

Just as main-chain NH 0=C hydrogen bonds are important for the stabilization of the a-helix and / -pleated sheet secondary structures of the proteins, the Watson-Crick hydrogen bonds between the bases, which are the side-chains of the nucleic acids, are fundamental to the stabilization of the double helix secondary structure. In the tertiary structure of tRNA and of the much larger ribosomal RNA s, both Watson-Crick and non-Watson-Crick base pairs and base triplets play a role. These are also found in the two-, three-, and four-stranded helices of synthetic polynucleotides (Sect. 20.5, see Part II, Chap. 16). 

Fig. 20.8. Three-dimensional structure of phenylalanine specific tRNA from yeast. Watson-Crick type base pairs indicated by slabs, nonstandard base-base interactions that stabilize the tertiary structure are denoted a to h. Invariant and semi-invariant nucleotides are shaded, the four double helical regions are indicated by a a-(amino add) arm, Tarm, D arm, a.c. (anticodon arm [696]...

The potential for RNA to act as a catalyst is dictated by its structure as a linear polymer of the four common ribonucleotides. Like DNA, RNA can form double stranded, antiparallel helices via traditional Watson-Crick base pairing. However, the backbone of nucleic acid is highly flexible and RNA can form complex tertiary structures that often involve non-Watson-Crick base pairing to create active site crevices for catalysis. The phosphodiester backbone is charged negatively and interacts electrostatically as well as by direct coordination with solution divalent cations. Ribose, purines, and pyrimidine bases contain both H-bond donors and acceptors that help stabilize higher-order stmcture and provide for substrate positioning, as well as participate in active site interactions. 

In rat liver ADH the presence of multiple molecular forms has been correlated to disulfide bridges involving the ligands to this zinc atom (Section II,B,3). These forms are active in ethanol oxidation (62). The lobe region which binds zinc is thus, in all probability, not essential for the catalytic action of alcohol oxidation. It has been suggested (133,134) that the extra zinc atom is essential for the structural stability of the enzyme. There is no evidence in the structure that this lobe region is necessary either for tertiary or quaternary structure stabilization. From the structural point of view, this region looks much more like a second catalytic center. The zinc atom is situated in one side of an obvious cleft into which the lone pair electrons of the sulfur atom of Cys-97 project. 

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