Boron is an essential micronutrient not only for plants but also for many other organisms. The excess of boron causes toxicity and the mechanism of this toxicity is not known. The yeast Saccharomyces cerevisiae was used as a model system in this study. In order to reveal boron metabolism related genes, a genome-wide screen has been conducted. Among the identified mutants, six boron resistant and eight boron sensitive mutants were chosen for further investigation to understand how cells cope with boron stress. Boron resistant mutants were found to have increased levels of boron efflux pump ATR1 and its transcription activator Gcn4. The sensitive mutants were lacking the genes that are involved in different cellular pathways. They were found to accumulate higher amounts of boron inside the cells upon boron treatment. To reveal how boron stress is conducted to Gcn4 transcription factor, the deletion mutants of transcription factors that are known to regulate GCN4 were investigated in terms of their effects on Gcn4 and ATR1 expression. Additionally, signaling cascades that converge on Gcn4 transcription factor such as TOR, PKA, and SNF1 pathways were analyzed for their roles in boron stress response mechanism. We found that the Gcn system is activated by the uncharged tRNA stress in response to boron treatment and that GCN1, which plays a role in transferring uncharged tRNAs to Gcn2, was necessary for the kinase activity of Gcn2. Additionally, boron treatment caused the phosphorylation of eIF2α in mammalian cells, in a similar manner to that of yeast cells, which suggested that boron toxicity and tolerance mechanisms were conserved between yeast and mammals