TRANSCRIPTOMIC ANALYSIS OF THE GLYCOPHYTIC CROP Ipomoea aquatica UNDER SALINITY CONDITIONS COMPARED TO ITS WILD HALOPHYTE RELATIVE Ipomoea pes-caprae

This study focuses on the glycophytic crop Ipomoea Aquatica (commonly known as water spinach) and its wild halophytic relative Ipomoea pes-caprae. I. Aquatica is a crop with economic value; however, it is unable to tolerate high levels of salinity. Whereas its relative Ipomoea pes-caprae is able to grow and thrive in the harsh environment of the UAE. The main aim of this study is to analyze the genetic differences underlying the variation in the two plants’ response to salinity and determine the genetic components that can be used to enhance I. Aquatica\u27s tolerance to salinity. Accordingly, the plants were subjected to salinity stress to measure physiological responses, and the two plants\u27 transcriptomes were analyzed for mRNAs, miRNAs, and pathway enrichment. The analysis determined several crucial genetic differences between me. Aquatica and I. pes-caprae during salinity stress. Many differences in the genetic responses were observed between these two plants, including the upregulation of High-affinity Potassium Transporter (HKT) in I. pes-caprae and the upregulation of a NAC3-like transcription factor. These differences can be used to genetically modify I. Aquatica in order to enhance its salt tolerance levels

Transcriptome Profiling and Functional Validation of RING-Type E3 Ligases in Halophyte Sesuvium verrucosum under Salinity Stress

Owing to their sessile nature, plants have developed a tapestry of molecular and physiological mechanisms to overcome diverse environmental challenges, including abiotic stresses. Adaptive radiation in certain lineages, such as Aizoaceae, enable their success in colonizing arid regions and is driven by evolutionary selection. Sesuvium verrucosum (commonly known as Western sea-purslane) is a highly salt-tolerant succulent halophyte belonging to the Aizoaceae family; thus, it provides us with the model-platform for studying plant adaptation to salt stress. Various transcriptional and translational mechanisms are employed by plants to cope with salt stress. One of the systems, namely, ubiquitin-mediated post-translational modification, plays a vital role in plant tolerance to abiotic stress and other biological process. E3 ligase plays a central role in target recognition and protein specificity in ubiquitin-mediated protein degradation. Here, we characterize E3 ligases in Sesuvium verrucosum from transcriptome analysis of roots in response to salinity stress. Our de novo transcriptome assembly results in 131,454 transcripts, and the completeness of transcriptome was confirmed by BUSCO analysis (99.3% of predicted plant-specific ortholog genes). Positive selection analysis shows 101 gene families under selection; these families are enriched for abiotic stress (e.g., osmotic and salt) responses and proteasomal ubiquitin-dependent protein catabolic processes. In total, 433 E3 ligase transcripts were identified in S. verrucosum; among these transcripts, single RING-type classes were more abundant compared to multi-subunit RING-type E3 ligases. Additionally, we compared the number of single RING-finger E3 ligases with ten different plant species, which confirmed the abundance of single RING-type E3 ligases in different plant species. In addition, differential expression analysis showed significant changes in 13 single RING-type E3 ligases (p-value < 0.05) under salinity stress. Furthermore, the functions of the selected E3 ligases genes (12 genes) were confirmed by yeast assay. Among them, nine genes conferred salt tolerance in transgenic yeast. This functional assay supports the possible involvement of these E3 ligase in salinity stress. Our results lay a foundation for translational research in glycophytes to develop stress tolerant crops