Transcriptome-wide characterization of alternative splicing regulation in Najran wheat (<em>Triticum aestivum</em>) under salt stress

\ua9 2024The process of alternative splicing (AS) has emerged as a crucial mechanism in plant responses to environmental stresses, contributing to the enhancement of the required transcriptome and proteome complexity. Despite the importance of AS, there remains a paucity of studies on the regulatory implications of AS in the responses of wheat to salt stress. In the current study, transcriptome-wide changes in AS profiles were established in roots and shoots of Najran wheat treated with 200 mM NaCl. Salt stress induced AS events increasing the complexity of the transcriptome; out of all expressed genes in all samples, 32,268 genes (22.5% of expressed genes) in the roots and 31,941 genes (23.1% of expressed genes) in the shoots were subjected to AS with 3’ Alternative splice site (A3) being the most frequent AS event and mutually exclusive exon (MX) being the least common event. Moreover, the results revealed that salt stress modulates AS patterns in a tissue-specific way where 82% of AS events were differentially expressed in either root or shoot tissues, participating in organ differentiation. In Total, 423 Differential AS events associated with cytoskeletal-related categories such as microtubule-based processes, actin filament-based movements, and cytoskeletal motor activity were identified in the roots. In contrast, 393 Differential AS events associated with biological categories related to metabolic and signalling processes such as catabolic processes, and response to gibberellin were identified in the shoots. The results presented in this study enhance our understanding of salt tolerance mechanisms in wheat and provide promising insights for future functional investigations and crop improvement efforts

Management of pregnant women infected with Ebola virus in a treatment centre in Guinea, June 2014

We report two cases of confirmed Ebola virus disease in pregnant women, who presented at the Médecins Sans Frontières Ebola treatment centre in Guéckédou. Despite the very high risk of death, both pregnant women survived. In both cases the critical decision was made to induce vaginal delivery. We raise a number of considerations regarding the management of Ebola virus-infected pregnant women, including the place of amniocentesis and induced delivery, and whether certain invasive medical acts are justified

Environmental regulation of carbon isotope composition and crassulacean acid metabolism in three plant communities along a water availability gradient

Expression of crassulacean acid metabolism (CAM) is characterized by extreme variability within and between taxa and its sensitivity to environmental variation. In this study, we determined seasonal fluctuations in CAM photosynthesis with measurements of nocturnal tissue acidification and carbon isotopic composition (δ13C) of bulk tissue and extracted sugars in three plant communities along a precipitation gradient (500, 700, and 1,000 mm year−1) on the Yucatan Peninsula. We also related the degree of CAM to light habitat and relative abundance of species in the three sites. For all species, the greatest tissue acid accumulation occurred during the rainy season. In the 500 mm site, tissue acidification was greater for the species growing at 30% of daily total photon flux density (PFD) than species growing at 80% PFD. Whereas in the two wetter sites, the species growing at 80% total PFD had greater tissue acidification. All species had values of bulk tissue δ13C less negative than −20‰, indicating strong CAM activity. The bulk tissue δ13C values in plants from the 500 mm site were 2‰ less negative than in plants from the wetter sites, and the only species growing in the three communities, Acanthocereus tetragonus (Cactaceae), showed a significant negative relationship between both bulk tissue and sugar δ13C values and annual rainfall, consistent with greater CO2 assimilation through the CAM pathway with decreasing water availability. Overall, variation in the use of CAM photosynthesis was related to water and light availability and CAM appeared to be more ecologically important in the tropical dry forests than in the coastal dune

Expression of phosphoenolpyruvate carboxylase and phosphoenolpyruvate carboxylase kinase genes. Implications for genotypic capacity and phenotypic plasticity in the expression of crassulacean acid metabolism

In plants with crassulacean acid metabolism (CAM), dark CO2 uptake is mediated by phosphoenolpyruvate carboxylase (PEPC), an enzyme that can be regulated at transcriptional and posttranslational levels. Reversible phosphorylation of PEPC is catalyzed by a dedicated PEPC kinase, which in turn is regulated at the transcriptional level over the 24-h cycle in CAM plants. PEPC kinase controls the day/night regulation of PEPC during the CAM cycle, thus facilitating plasticity for optimizing CO2 uptake under different environmental conditions. To understand the importance of PEPC kinase in relation to its target PEPC in terms of CAM performance, the expression of the genes encoding the two enzymes was investigated in four species of Clusia that have photosynthetic patterns ranging from C3 photosynthesis to constitutive CAM. By linking changes in the expression of PEPC and PEPC kinase to day/night patterns of leaf gas exchange, organic acid, and soluble sugar contents under different environmental conditions, the genetic and metabolic limitations to CAM plasticity were assessed. The results indicate that PEPC expression is a major factor underpinning the genotypic capacity for CAM and that PEPC kinase expression does not appear to limit CAM. The day/night regulation of Ppck transcript abundance was found to be a consequence of CAM and the day/night cycling of associated metabolites, rather than the primary controlling factor for the temporal separation of carboxylation processes