Structural insight into the recognition of amino-acylated initiator tRNA by eIF5B in the 80S initiation complex

A novel folding motif has been observed in four different proteins which bind oligonucleotides or oligosaccharides: staphylococcal nuclease, anticodon binding domain of asp-tRNA synthetase and B-subunits of heat-labile enterotoxin and verotoxin-1. The common fold of the four proteins, which we call the OB-fold, has a five-stranded beta-sheet coiled to form a closed beta-barrel. This barrel is capped by an alpha-helix located between the third and fourth strands. The barrel-helix frameworks can be superimposed with r.m.s. deviations of 1.4-2.2 A, but no similarities can be observed in the corresponding alignment of the four sequences. The nucleotide or sugar binding sites, known for three of the four proteins, are located in nearly the same position in each protein: on the side surface of the beta-barrel, where three loops come together. Here we describe the determinants of the OB-fold, based on an analysis of all four structures. These proposed determinants explain how very different sequences adopt the OB-fold. They also suggest a reinterpretation of the controversial structure of gene 5 ssDNA binding protein, which exhibits some topological and functional similarities with the OB-fold proteins.

The OB-fold domain is a compact structural motif frequently used for nucleic acid recognition. Structural comparison of all OB-fold/nucleic acid complexes solved to date confirms the low degree of sequence similarity among members of this family while highlighting several structural sequence determinants common to most of these OB-folds. Loops connecting the secondary structural elements in the OB-fold core are extremely variable in length and in functional detail. However, certain features of ligand binding are conserved among OB-fold complexes, including the location of the binding surface, the polarity of the nucleic acid with respect to the OB-fold, and particular nucleic acid-protein interactions commonly used for recognition of single-stranded and unusually structured nucleic acids. Intriguingly, the observation of shared nucleic acid polarity may shed light on the longstanding question concerning OB-fold origins, indicating that it is unlikely that members of this family arose via convergent evolution.

In experiments modeling volcanic or hydrothermal settings amino acids were converted into their peptides by use of coprecipitated (Ni,Fe)S and CO in conjunction with H2S (or CH3SH) as a catalyst and condensation agent at 100 degreesC and pH 7 to 10 under anaerobic, aqueous conditions. These results demonstrate that amino acids can be activated under geochemically relevant conditions. They support a thermophilic origin of life and an early appearance of peptides in the evolution of a primordial metabolism.