Expression of Arabidopsis thaliana mitochondrial alanyl-tRNA synthetase is not sufficient to trigger mitochondrial import of tRNAAla in yeast.

It has often been suggested that precursors to mitochondrial aminoacyl-tRNA synthetases are likely carriers for mitochondrial import of tRNAs in those organisms where this process occurs. In plants, it has been shown that mutation of U(70) to C(70) in Arabidopsis thaliana tRNA(Ala)(UGC) blocks aminoacylation and also prevents import of the tRNA into mitochondria. This suggests that interaction of tRNA(Ala) with alanyl-tRNA synthetase (AlaRS) is necessary for import to occur. To test whether this interaction is sufficient to drive import, we co-expressed A. thaliana tRNA(Ala)(UGC) and the precursor to the A. thaliana mitochondrial AlaRS in Saccharomyces cerevisiae. The A. thaliana enzyme and its cognate tRNA were correctly expressed in yeast in vivo. However, although the plant AlaRS was efficiently imported into mitochondria in the transformed strains, we found no evidence for import of the A. thaliana tRNA(Ala) nor of the endogenous cytosolic tRNA(Ala) isoacceptors. We conclude that at least one other factor besides the mitochondrial AlaRS precursor must be involved in mitochondrial import of tRNA(Ala) in plants.

The same Arabidopsis gene encodes both cytosolic and mitochondrial alanyl-tRNA synthetases.

In plants, all aminoacyl-tRNA synthetases are nuclearly encoded, despite the fact that their activities are required in the three protein-synthesizing cell compartments (cytosol, mitochondria, and chloroplasts). To investigate targeting of these enzymes, we cloned cDNAs encoding alanyl-tRNA synthetase (AlaRS) and the corresponding nuclear gene, ALATS, from Arabidopsis by using degenerate polymerase chain reaction primers based on highly conserved regions shared between known AlaRSs from other organisms. Analysis of the transcription of the gene showed the presence of two potential translation initiation codons in some ALATS mRNAs. Translation from the upstream AUG would generate an N-terminal extension with features characteristic of mitochondrial targeting peptides. A polyclonal antibody raised against part of the Arabidopsis AlaRS revealed that the Arabidopsis cytosolic and mitochondrial AlaRSs are immunologically similar, suggesting that both isoforms are encoded by the ALATS gene. In vitro experiments confirmed that two polypeptides can be translated from AlATS transcripts, with most ribosomes initiating on the downstream AUG to give the shorter polypeptide corresponding in size to the cytosolic enzyme. The ability of the presequence encoded between the two initiation codons to direct polypeptides to mitochondria was demonstrated by expression of fusion proteins in tobacco protoplasts and in yeast. We conclude that the ALATS gene encodes both the cytosolic and the mitochondrial forms of AlaRS, depending on which of the two AUG codons is used to initiate translation.

Cell growth inhibition by sequence-specific RNA minihelices.

RNA minihelices which reconstruct the 12 base pair acceptor-T psi C domains of transfer RNAs interact with their cognate tRNA synthetases. These substrates lack the anticodons of the genetic code and, therefore, cannot participate in steps of protein synthesis subsequent to aminoacylation. We report here that expression in Escherichia coli of either of two minihelices, each specific for a different amino acid, inhibited cell growth. Inhibition appears to be due to direct competition between the minihelix and its related tRNA for binding to their common synthetase. This competition, in turn, sharply lowers the pool of the specific charged tRNA for protein synthesis. Inhibition is relieved by single nucleotide changes which disrupt the minihelix-synthetase interaction. The results suggest that sequence-specific RNA minihelix substrates bind to cognate synthetases in vivo and can, in principle, act as cell growth regulators. Naturally occurring non-tRNA substrates for aminoacylation may serve a similar purpose.

Region of a conserved sequence motif in a class II tRNA synthetase needed for transfer of an activated amino acid to an RNA substrate.

The class II Escherichia coli alanine tRNA synthetase aminoacylates RNA miniduplexes, which reconstruct the acceptor end of alanine tRNA with the critical G3:U70 base pair. A benzophenone photoaffinity label attached adjacent to G3:U70 in a miniduplex substrate was previously cross-linked to a long enzyme peptide that begins at Gly161 between the class-defining motifs 2 and 3 [Musier-Forsyth, K., & Schimmel, P. (1994) Biochemistry 33, 773-779]. To identify side chains in this peptide that potentially contribute hydrogen bonding or catalytic determinants for the RNA-dependent step of the aminoacylation reaction, peptide functional side chains that are conserved among sequenced alanine enzymes (Asp, Asn, Arg, Glu, Gln, and Tyr) were individually replaced. Of the 21 mutant proteins so generated, one was identified that was not viable even though it accumulated in vivo. This Asp235-->Ala mutant enzyme is defective in the rate of transfer of the activated amino acid to the 3'-end of the RNA substrate. The conserved Asp235 is at the beginning of motif 3. By comparison with the crystal structure of the related class II yeast aspartate tRNA synthetase complexed with tRNA(Asp) (Cavarelli et al., 1993), we suggest that D235 is not in direct contact with acceptor helix base pairs such as G3:U70. Instead, we propose that D235 contributes to transfer-step interactions at the 3'-end of alanine tRNA. Because D235 in alanine tRNA synthetase is at the beginning of one of the conserved motifs that define class II tRNA synthetases, this region of the structure may in general be important for the transfer step.