Molecular characterization of a novel Na+/H+ antiporter cDNA from Eucalyptus globulus

Environmental stress factors such as salt, drought and heat are known to affect plant productivity. However, high salinity is spreading throughout the world, currently affecting more than 45 million ha. One of the mechanisms that allow plants to withstand salt stress consists on vacuolar sequestration of Na⁺, through a Na⁺/H⁺ antiporter. We isolated a new vacuolar Na⁺/H⁺ antiporter from Eucalyptus globulus from a cDNA library. The cDNA had a 1626 bp open reading frame encoding a predicted protein of 542 amino acids with a deduced molecular weight of 59.1 KDa. Phylogenetic and bioinformatic analyses indicated that EgNHX1 localized in the vacuole. To assess its role in Na⁺ exchange, we performed complementation studies using the Na⁺ sensitive yeast mutant strain Δnhx1. The results showed that EgNHX1 partially restored the salt sensitive phenotype of the yeast Δnhx1 strain. However, its overexpression in transgenic Arabidopsis confers tolerance in the presence of increasing NaCl concentrations while the wild type plants exhibited growth retardation. Expression profiles of Eucalyptus seedlings subjected to salt, drought, heat and ABA treatment were established. The results revealed that Egnhx1 was induced significantly only by drought. Together, these results suggest that the product of Egnhx1 from E. globulus is a functional vacuolar Na⁺/H⁺ antiporter.     

Ontogeny of in vitro rooting processes in Eucalyptus globulus

Summary In the present work, histological changes observed at the base of Eucalyptus globulus shoots in in vitro culture are described. Shoots were placed on solidified Murashige and Skoog medium containing half the original salt concentration, the complete vitamin composition, 9.8 μM indolebutyric acid (IBA), and 30 gI⁻¹ agar, and were incubated in the dark for the first 7 d, followed by a 16-h photoperiod. In vitro-generated roots could be originated either from old vascular tissue or from newly formed xylem. The influence of the preexistent tissues on the neoformation process appeared to be varied. The medulla did not intervene directly, although there were abundant cellular divisions in response to the induction medium. On the other hand, the interruptions observed in the vascular cylinder of the stem suggested an influence of the interfascicular parenchyma, and therefore the medulla could have participated in the differentiation process. However, the cortical parenchyma showed most of the changes that lead to the formation of adventitious roots of E. globulus growing in vitro. Histological analysis suggests that vascular rays can also be formed in direct contact with the central cylinder of the stem, although they mainly originate from the cortical parenchyma.