From swamp to field: how genes from mangroves and its associates can enhance crop salinity tolerance.

Salinity stress is a critical challenge in crop production and requires innovative strategies to enhance the salt tolerance of plants. Insights from mangrove species, which are renowned for their adaptability to high-salinity environments, provides valuable genetic targets and resources for improving crops. A significant hurdle in salinity stress is the excessive uptake of sodium ions (Na+) by plant roots, causing disruptions in cellular balance, nutrient deficiencies, and hampered growth. Specific ion transporters and channels play crucial roles in maintaining a low Na+/K+ ratio in root cells which is pivotal for salt tolerance. The family of high-affinity potassium transporters, recently characterized in Avicennia officinalis, contributes to K+ homeostasis in transgenic Arabidopsis plants even under high-salt conditions. The salt overly sensitive pathway and genes related to vacuolar-type H+-ATPases hold promise for expelling cytosolic Na+ and sequestering Na+ in transgenic plants, respectively. Aquaporins contribute to mangroves' adaptation to saline environments by regulating water uptake, transpiration, and osmotic balance. Antioxidant enzymes mitigate oxidative damage, whereas genes regulating osmolytes, such as glycine betaine and proline, provide osmoprotection. Mangroves exhibit increased expression of stress-responsive transcription factors such as MYB, NAC, and CBFs under high salinity. Moreover, genes involved in various metabolic pathways, including jasmonate synthesis, triterpenoid production, and protein stability under salt stress, have been identified. This review highlights the potential of mangrove genes to enhance salt tolerance of crops. Further research is imperative to fully comprehend and apply these genes to crop breeding to improve salinity resilience.

The complete chloroplast genome of Ocimum tenuiflorum L. subtype Rama Tulsi and its phylogenetic analysis.

Ocimum tenuiflorum L. subtype Rama Tulsi is an important aromatic perennial herb. It belongs to the family of Lamiaceae. In this study, the complete chloroplast genome sequence of O. tenuiflorum subtype Rama Tulsi was assembled and annotated using Illumina paired-end sequencing data. The length of the complete circular chloroplast genome was 151,722 bp. It comprises an inverted repeat (IR) region with a repeat length of 25,677 bp, a large single-copy (LSC) region of 82,781 bp, and a small single-copy (SSC) region of 17,587 bp. The GC content of complete chloroplast genome, LSC, SSC, IR regions is 37.9%, 36.0%, 31.8%, and 43.1%, respectively. The chloroplast genome contains 134 genes, including 88 protein-coding genes, 38 transfer RNA genes, and eight ribosomal RNA genes. Phylogenetic analysis with the complete chloroplast genomes of other related species revealed that the O. tenuiflorum L. subtype Rama Tulsi is fully resolved in a clade with other Ocimum species classified under the Lamiaceae family.