An aminoacyl tRNA synthetase whose sequence fits into neither of the two known classes.

Aminoacyl transfer RNA synthetases catalyse the first step of protein synthesis and establish the rules of the genetic code through the aminoacylation of tRNAs. There is a distinct synthetase for each of the 20 amino acids and throughout evolution these enzymes have been divided into two classes of ten enzymes each. These classes are defined by the distinct architectures of their active sites, which are associated with specific and universal sequence motifs. Because the synthesis of aminoacyl-tRNAs containing each of the twenty amino acids is a universally conserved, essential reaction, the absence of a recognizable gene for cysteinyl tRNA synthetase in the genomes of Archae such as Methanococcus jannaschii and Methanobacterium thermoautotrophicum has been difficult to interpret. Here we describe a different cysteinyl-tRNA synthetase from M. jannaschii and Deinococcus radiodurans and its characterization in vitro and in vivo. This protein lacks the characteristic sequence motifs seen in the more than 700 known members of the two canonical classes of tRNA synthetase and may be of ancient origin. The existence of this protein contrasts with proposals that aminoacylation with cysteine in M. jannaschii is an auxiliary function of a canonical prolyl-tRNA synthetase.

Editing by a tRNA synthetase: DNA aptamer-induced translocation and hydrolysis of a misactivated amino acid.

Aminoacyl-tRNA synthetases establish the rules of the genetic code by aminoacylation reactions. Occasional activation of the wrong amino acid can lead to errors of protein synthesis. For isoleucyl-tRNA synthetase, these errors are reduced by tRNA-dependent hydrolytic editing reactions that occur at a site 25 A from the active site. These reactions require that the misactivated amino acid be translocated from the active site to the center for editing. One mechanism describes translocation as requiring the mischarging of tRNA followed by a conformational change in the tRNA that moves the amino acid from one site to the other. Here a specific DNA aptamer is investigated. The aptamer can stimulate amino acid-specific editing but cannot be aminoacylated. Although the aptamer could in principle stimulate hydrolysis of a misactivated amino acid by an idiosyncratic mechanism, the aptamer is shown here to induce translocation and hydrolysis of misactivated aminoacyl adenylate at the same site as that seen with the tRNA cofactor. Thus, translocation to the site for editing does not require joining of the amino acid to the nucleic acid. Further experiments demonstrated that aptamer-induced editing is sensitive to aptamer sequence and that the aptamer is directed to a site other than the active site or tRNA binding site of the enzyme.

Nucleotide determinants for tRNA-dependent amino acid discrimination by a class I tRNA synthetase.

The high accuracy of the genetic code relies on the ability of tRNA synthetases to discriminate rigorously between closely similar amino acids. While the enzymes can detect differences between closely similar amino acids at an accuracy of about 1 part in 100-200, a finer discrimination requires the presence of the cognate tRNA. The role of the tRNA is to direct the misactivated amino acid to a distinct catalytic site for editing where hydrolysis occurs. Previous work showed that three nucleotides at the corner of the L-shaped tRNA were collectively required. Here we show that each of these nucleotides individually contributes to the efficiency of editing. However, all are dispensable for the chemical step of hydrolysis. Instead, these nucleotides are required for translocation of a misactivated amino acid from the active site to the center for editing.

Site-specific cross-linking of amino acids in the basic region of human immunodeficiency virus type 1 Tat peptide to chemically modified TAR RNA duplexes.

The Human Immunodeficiency Virus type 1 Tat protein interacts specifically with a U-rich bulge within an RNA stem-loop known as the trans-activation responsive region (TAR) that occurs in all viral transcripts. We have photochemically cross-linked to Tat peptide (37-72), a model TAR duplex substituted at U23 in the bulge by 4-thioU. We have identified the cross-linked amino acid as Arg55 in the basic region of the Tat peptide by use of a combination of proteolytic digestions and MALDI-TOF mass spectrometric analysis. The identification also required use of a synthetic Tat peptide containing a site-specific, uniformly 13C and 15N isotopically labeled arginine. We also describe a new chemical procedure for obtaining site-specific cross-links to Tat via the use of 2'-beta-alanyl U-substituted TAR and the amino-specific reagent dithiobis(succinimidyl propionate). U23-2'-functionalized TAR was shown to cross-link uniquely to Lys51 in the basic region of Tat, whereas other sites in the upper and lower stems of TAR (U35, U38, and U42) showed cross-linking only to the N-terminus of Tat peptide (37-72). U40 cross-linked to both Lys51 and the N-terminus of the peptide. The results help to establish a preliminary model of the binding of Tat peptide to the major groove of TAR RNA.

Chemical cross-linking of the human immunodeficiency virus type 1 Tat protein to synthetic models of the RNA recognition sequence TAR containing site-specific trisubstituted pyrophosphate analogues.

A chemical ligation procedure has been developed for the synthesis of oligoribonucleotides carrying a trisubstituted pyrophosphate (tsp) linkage in place of a single phosphodiester. Good yields of tsp were obtained when a single 2'-deoxynucleoside 5' to the tsp was used in the ligation reaction. A tsp linkage was found to be reasonably stable to hydrolysis but cleaved by treatment with ethylenediamine or lysine to give phosphoamidate adducts. A model human immunodeficiency virus type 1 (HIV-1) TAR RNA duplex containing an activated tsp was able to bind to HIV-1 Tat protein with only 3-fold reduced affinity and to a Tat peptide (residues 37-72) with identical affinity compared to that of an unmodified duplex. Tsps incorporated at sites previously identified as being in close proximity to Tat protein were able to cross-link to Tat peptide (37-72) to form a covalent phosphoamidate conjugate. Endopeptidase cleavage followed by MALDI-TOF (matrix-assisted laser desorption ionization time of flight) mass spectrometric analysis provided strong evidence that a TAR duplex containing a tsp replacing the phosphate at 38-39 had reacted specifically with Lys51 in the basic region of Tat peptide (37-72). The new chemical cross-linking method may be generally useful for identifying lysines in close proximity to phosphates in basic RNA-binding domains of proteins.