The role of plant e IF5 A proteins in multiple biological processes, such as protein synthesis regulation,translation elongation, m RNA turnover, programmed cell death and stress tolerance is well known. Toward using these powerful proteins to increase stress tolerance in agricultural plants, in the present study, we cloned and characterized Psne IF5A2 and Psne IF5A4 from young poplar(P. simonii 9 P. nigra) leaves. The deduced amino acid sequences of Psne IF5A2 and Psne IF5A4 were 98 %similar to each other, and they are orthologs of e IF5A1 in Arabidopsis. In a subcellular localization analysis,Psne IF5A2 and Psne IF5A4 proteins were localized in the nucleus and cytoplasm. q RT-PCR analysis showed that Psne IF5A2 and Psne IF5A4 were transcribed in poplar flowers, stem, leaves, and roots. In addition, they were also induced by abiotic stresses. Transgenic yeast expressing Psne IF5A2 and Psne IF5A4 had increased salt, heavy metal, osmotic, oxidative tolerance. Our results suggest that Psne IF5A2 and Psne IF5A4 are excellent candidates for genetic engineering to improve salt and heavy metal tolerance in agricultural plants. The role of plant e IF5 A proteins in multiple biological processes, such as protein synthesis regulation, translation elongation, m RNA turnover, programmed cell death and stress tolerance is well known. Toward using these powerful proteins to increase stress tolerance in agricultural plants, in the present study, we cloned and characterized Psne IF5A2 and Psne IF5A4 from young poplar (P. simonii 9 P. nigra) leaves. The deduced amino acid sequences of Psne IF5A2 and Psne IF5A4 were 98% similar to each other, and they are orthologs of e IF5A1 in Arabidopsis. In a subcellular localization analysis, Psne IF5A2 and Psne IF5A4 proteins were localized in the nucleus and cytoplasm. q RT-PCR analysis showed that Psne IF5A2 and Psne IF5A4 were transcribed in poplar flowers, stems, leaves, and roots . In addition, they were also induced by abiotic stresses. Transgenic yeast expressing Psne IF5A2 and Psne IF5A4 had increased salt, heavy metal, osmotic, oxidative tolerance. Our results suggest that Ps ne IF5A2 and Psne IF5A4 are excellent candidates for genetic engineering to improve salt and heavy metal tolerance in agricultural plants.