Recent studies in Saccharomyces cerevisiae have shown that ALA1 (coding for alanyl-tRNA synthetase) initiates the translation of its mitochondrial isoform from two consecutive ACG triplets, with the first ACG being the more robust. In the work described here we focuse on the mechanism of non-ATG initiation in yeast. To explore if any other non-ATG triplets can serve a similar function, the first and second ACG triplets were replaced by a random triplet and ACC, respectively, and the resultant constructs were screened for candidates expressing the mitochondrial activity. We report here that, in addition to ATG, six common non-ATG initiators (ATA, ATU, ATC, GTG, UTG, and CTG) and four rare non-ATG initiators (AGC, CGC, CAT, and CAC) can each functionally substitute for the ACG initiators. Western blot analysis suggests that initiating activity of the non-ATG initiators is significantly affected by the nucleotides at their relative positions -3 ~ -1. Furthermore, a putative pseudoknot structure 17-nucleotide downstream of the non-AUG initiation site also appears to be important for the initiation activity. A second part of the thesis is focused on the valyl-tRNA synthetase (ValRS) appended domain (ad) of Saccharomyces cerevisiae. We show here that this domain is a non-specific tRNA-binding domain (Kd ~ 2 μM) that contributes significantly to the tRNA-binding activity of the valine enzyme. Thus, even a small deletion in the appended domain, such as Δ32-71, has a devastating effect on the enzyme’s tRNA-binding and aminoacylation activities. In addition we show here that the ad can deliver a green fluorescent protein in to the nucleus, further reinforcing the notion that ValRS could be involved regulation of nuclear gene.