Overexpression of the activated form of the AtAREB1 gene (AtAREB1ΔQT) improves soybean responses to water deficit.

Abscisic acid-responsive element binding protein (AREB1) is a basic domain/leucine zipper transcription factor that binds to the abscisic acid (ABA)-responsive element motif in the promoter region of ABA-inducible genes. Because AREB1 is not sufficient to direct the expression of downstream genes under non-stress conditions, an activated form of AREB1 (AREB1ΔQT) was created. Several reports claim that plants overexpressing AREB1 or AREB1ΔQT show improved drought tolerance. In our studies, soybean plants overexpressing AREB1ΔQT were characterized molecularly, and the phenotype and drought response of three lines were accessed under greenhouse conditions. Under conditions of water deficit, the transformed plants presented a higher survival rate (100%) than those of their isoline, cultivar BR 16 (40%). Moreover, the transformed plants displayed better water use efficiency and had a higher number of leaves than their isoline. Because the transgenic plants had higher stomatal conductance than its isoline under well-watered conditions, it was suggested that the enhanced drought response of AREB1ΔQT soybean plants might not be associated with altered transpiration rates mediated by ABA-dependent stomatal closure. However, it is possible that the smaller leaf area of the transgenic plants reduced their transpiration and water use, causing delayed stress onset. The difference in the degree of wilting and percentage of survival between the 35S-AREB1ΔQT and wildtype plants may also be related to the regulation of genes that protect against dehydration because metabolic impairment of photosynthesis, deduced by an increasing internal CO2 concentration, was not observed in the transgenic plants.

Multiple horizontally acquired genes from fungal and prokaryotic donors encode cellulolytic enzymes in the bdelloid rotifer Adineta ricciae.

The bdelloid rotifer, Adineta ricciae, an anhydrobiotic microinvertebrate, exhibits a high rate of horizontal gene transfer (HGT), with as much as 10% of its transcriptome being of foreign origin. Approximately 80% of these foreign transcripts are involved in metabolic processes, and therefore bdelloids represent a useful model for assessing the contribution of HGT to biochemical diversity. To validate this concept, we focused on cellulose digestion, an unusual activity in animals, which is represented by at least 16 genes encoding cellulolytic enzymes in A. ricciae. These genes have been acquired from a variety of different donor organisms among the bacteria and fungi, demonstrating that bdelloids use diverse genetic resources to construct a novel biochemical pathway. A variable complement of the cellulolytic gene set was found in five other bdelloid species, indicating a dynamic process of gene acquisition, duplication and loss during bdelloid evolution. For example, in A. ricciae, gene duplications have led to the formation of three copies of a gene encoding a GH45 family glycoside hydrolase, at least one of which encodes a functional enzyme; all three of these gene copies are present in a close relative, Adineta vaga, but only one copy was found in each of four Rotaria species. Furthermore, analysis of expression levels of the cellulolytic genes suggests that a bacterial-origin cellobiase is upregulated upon desiccation. In summary, bdelloid rotifers have apparently developed cellulolytic functions by the acquisition and domestication of multiple foreign genes.