A single residue in leucyl-tRNA synthetase affecting amino acid specificity and tRNA aminoacylation

Human mitochondrial leucyl-tRNA synthetase (hs mt LeuRS) achieves high aminoacylation fidelity without a functional editing active site, representing a rare example of a class I aminoacyl-tRNA synthetase (aaRS) that does not proofread its products. Previous studies demonstrated that the enzyme achieves high selectivity by using a more specific synthetic active site that is not prone to errors under physiological conditions. Interestingly, the synthetic active site of hs mt LeuRS displays a high degree of homology with prokaryotic, lower eukaryotic, and other mitochondrial LeuRSs that are less specific. However, there is one residue that differs between hs mt and Escherichia coli LeuRSs located on a flexible closing loop near the signature KMSKS motif. Here we describe studies indicating that this particular residue (K600 in hs mt LeuRS and L570 in E. coli LeuRS) strongly impacts aminoacylation in two ways: it affects both amino acid discrimination and transfer RNA (tRNA) binding. While this residue may not be in direct contact with the amino acid or tRNA substrate, substitutions of this position in both enzymes lead to altered catalytic efficiency and perturbations to the discrimination of leucine and isoleucine. In addition, tRNA recognition and aminoacylation is affected. These findings indicate that the conformation of the synthetic active site, modulated by this residue, may be coupled to specificity and provide new insights into the origins of selectivity without editing.     

The ''polysemous'' codon--a codon with multiple amino acid assignment caused by dual specificity of tRNA identity.

In some Candida species, the universal CUG leucine codon is translated as serine. However, in most cases, the serine tRNAs responsible for this non-universal decoding (tRNA(Ser)CAG) accept in vitro not only serine, but also, to some extent, leucine. Nucleotide replacement experiments indicated that m1G37 is critical for leucylation activity. This finding was supported by the fact that the tRNA(Ser)CAGs possessing the leucylation activity always have m1G37, whereas that of Candida cylindracea, which possesses no leucylation activity, has A37. Quantification of defined aminoacetylated tRNAs in cells demonstrated that 3% of the tRNA(Ser)CAGs possessing m1G37 were, in fact, charged with leucine in vivo. A genetic approach using an auxotroph mutant of C.maltosa possessing this type of tRNA(Ser)CAG also suggested that the URA3 gene inactivated due to the translation of CUG as serine was rescued by a slight incorporation of leucine into the polypeptide, which demonstrated that the tRNA charged with multiple amino acids could participate in the translation. These findings provide the first evidence that two distinct amino acids are assigned by a single codon, which occurs naturally in the translation process of certain Candida species. We term this novel type of codon a 'polysemous codon'.     

Human trans-editing enzyme displays tRNA acceptor-stem specificity and relaxed amino acid selectivity

Accurate translation of genetic information into proteins is vital for cell sustainability. ProXp-ala prevents proteome-wide Pro-to-Ala mutations by hydrolyzing misacylated Ala-tRNA^Pro, which is synthesized by prolyl-tRNA synthetase. Bacterial ProXp-ala was previously shown to combine a size-based exclusion mechanism with conformational and chemical selection for the recognition of the alanyl moiety, whereas tRNA^Pro is selected via recognition of tRNA acceptor-stem elements G72 and A73. The identity of these critical bases changed during evolution with eukaryotic cytosolic tRNA^Pro possessing a cytosine at the corresponding positions. The mechanism by which eukaryotic ProXp-ala adapted to these changes remains unknown. In this work, recognition of the aminoacyl moiety and tRNA acceptor stem by human (Homo sapiens, or Hs) ProXp-ala was examined. Enzymatic assays revealed that Hs ProXp-ala requires C72 and C73 in the context of Hs cytosolic tRNA^Pro for efficient deacylation of mischarged Ala-tRNA^Pro. The strong dependence on these bases prevents cross-species deacylation of bacterial Ala-tRNA^Pro or of Hs mitochondrial Ala-tRNA^Pro by the human enzyme. Similar to the bacterial enzyme, Hs ProXp-ala showed strong tRNA acceptor-stem recognition but differed in its amino acid specificity profile relative to bacterial ProXp-ala. Changes at conserved residues in both the Hs and bacterial ProXp-ala substrate-binding pockets modulated this specificity. These results illustrate how the mechanism of substrate selection diverged during the evolution of the ProXp-ala family, providing the first example of a trans-editing domain whose specificity evolved to adapt to changes in its tRNA substrate.     

A partial amino acid sequence for sheep haemoglobin A

Amino acid analysis and terminal-group analysis of tryptic and chymotryptic peptides from sheep haemoglobin A have enabled a partial amino acid sequence to be worked out. By comparing this partial sequence with the known amino acid sequences of human haemoglobins A and F as well as horse slow haemoglobin the most probable sequence of sheep haemoglobin has been deduced.     

A statistical theory of amino acid mutation

Assuming that the observed mutation frequency of an amino acid depends on two factors. The first is mutation coefficient which describes the rate of the nucleotide substitution stochastically and the second is the similarity of amino acids which represents the fitness of a mutant under the selective pressure. A statistical theory is proposed and 380 mutation frequencies are calculated, only 10 of which disagree obviously with the observed data.The Project Supported by NSFC.     

Ribonuclease Fl1 from Fusarium lateriticum. Isolation, substrate specificity and amino acid sequence

Extracellular RNase Fl1 has been purified from the culture filtrate of Fusarium lateritium. The enzyme has been obtained in the electrophoretically homogeneous state with the yield about 90% and 300 fdd degree of purification. RNase Fl1 is a guanyl specific enzyme (EC 3.1.27.3) with the specific activity on RNA 1420 units/mg of protein. The total primary structure of the RNase has been determined by the automated Edman degradation of two non-fractionated peptide hydrolysates produced by trypsin and Staphylococcus aureus protease and of the hydroxylamine cleavage products of the protein. It was shown that hydroxylamine converts the RNase Fl1 N-terminal residue, pyroglutamic acid, into the hydroxyamic acid derivative sensitive to Edman degradation. RNase Fl1 consists of 105 amino acid residues (Mr 10,852) and is a structural homologue of the Fus. moniliforme RNase F1, differing from the latter by 15 amino acid substitutions outside the enzyme active site.     

A new method for the purification of DNA-binding proteins with sequence specificity

We describe a technique for a rapid and efficient isolation and purification of proteins binding to defined DNA sequences. Cloned double-stranded DNA was covalently coupled to m-aminobenzyloximethylcellulose in order to purify proteins which recognize and bind to specific sequences on the DNA. The purification of two DNA-binding proteins from Drosophila melanogaster is demonstrated using the respective cloned DNA sequences.     

Structure-specific tRNA determinants for editing a mischarged amino acid

Alanyl-tRNA synthetase efficiently aminoacylates tRNAAla and an RNA minihelix that comprises just one domain of the two-domain L-shaped tRNA structure. It also clears mischarged tRNAAla using a specialized domain in its C-terminal half. In contrast to full-length tRNAAla, minihelixAla was robustly mischarged and could not be edited. Addition in trans of the missing anticodon-containing domain did not activate editing of mischarged minihelixAla. To understand these differences between minihelixAla and tRNAAla, several chimeric full tRNAs were constructed. These had the acceptor stem of a non-cognate tRNA replaced with the stem of tRNAAla. The chimeric tRNAs collectively introduced multiple sequence changes in all parts but the acceptor stem. However, although the acceptor stem in isolation (as the minihelix) lacked determinants for editing, alanyl-tRNA synthetase effectively cleared a mischarged amino acid from each chimeric tRNA. Thus, a covalently continuous two-domain structure per se, not sequence, is a major determinant for clearance of errors of aminoacylation by alanyl-tRNA synthetase. Because errors of aminoacylation are known to be deleterious to cell growth, structure-specific determinants constitute a powerful selective pressure to retain the format of the two-domain L-shaped tRNA.     

A method for the analysis of tRNA patterns in Drosophila melanogaster using an amino acid analyser

Using tRNA and aminoacyl-tRNA synthetase preparations from Drosophila melanogaster, a method has been developed for simultaneously estimating levels of at least 15 different species of aminoacyl-tRNA. ¹⁴C-labeled aminoacyl-tRNA, which is formed during a single incubation of tRNA with a mixture of 15 ¹⁴C-labeled amino acids, is purified, hydrolysed, and the composition of the mixture of ¹⁴C-labeled amino acids so obtained is determined using an Amino Acid Analyser.The sensitivity of the method and the reproducibility of the results obtained are such that it is suitable for detecting changes in tRNA patterns in comparative studies.     

The amino acid sequence specificity of a protease from spores of Bacillus megaterium

Previous work has shown that the degradation of 20% of total protein which occurs early in germination of Bacillus megaterium spores is initiated by an endoprotease. This enzyme is found only in the spore and is active only on the spore proteins degraded during germination. Action of the spore protease in vitro on the three major proteins (Proteins A, B, and C) which are degraded in vivo during germination results in cleavage of one (A and C protein) or two (B protein) peptide bonds. The sequences surrounding the cleavage sites are -Tyr-Glu- Ile-Ala-Ser-Glu-Phe- in the A protein, -Phe-Glu- Ile-Ala-Ser-Glu-Phe- in the C protein, and -Thr-Glu- Phe-Gly-Ser-Glu-Thr-, and -Thr-Glu- Phe-Ala-Ser-Glu-Thr- in the B protein, with cleavage taking place at the glutamyl bond noted by the arrow. The similarity of these four sequences suggests the possibility that the specificity of the spore protease may be due to its requirement for a specific pentapeptide sequence of the type -R-Glu-(Phe or Ile)-(Gly or Ala)-Ser-Glu-R- for recognition and cleavage. However, it is also possible that it is the conformation of the A, B, and C proteins which determines their site of cleavage by the spore protease.     

Epitope mapping by a method that requires no amino acid sequence information.

A simple, rapid method of epitope mapping has been developed that avoids the often cumbersome requirement of obtaining amino acid sequence information. The protein antigen is digested with various concentrations of carboxypeptidase into a nearly continuous series of polypeptides of different molecular weights, all containing a common N-terminus. The peptides are separated by polyacrylamide gel electrophoresis and then transferred to nitrocellulose paper. After developing the blot with the antibody to be mapped, a nearly continuous stain is observed extending from the position of the intact antigen to the molecular weight of the smallest N-terminal fragment still containing the antibody's epitope. By noting the molecular weight where the stain terminates, the position of the epitope relative to the N-terminus can be determined. Using this methodology, and taking special precautions to inhibit all endoproteinases in the carboxypeptidase preparation, the previously mapped epitopes of six nonoverlapping antibodies to the erythrocyte anion transporter were confirmed.