Decoding RNA Editing Sites Through Transcriptome Analysis in Rice Under Alkaline Stress

Abstract: Ribonucleic acid editing (RE) is a post-transcriptional process that altered the genetics of RNA which provide the extra level of gene expression through insertion, deletions, and substitutions. In animals, it converts nucleotide residues C-U. Similarly in plants, the role of RNA editing sites (RES) in rice under alkaline stress is not fully studied. Rice is a staple food for most of the world population. Alkaline stress cause reduction in yield. Here, we explored the effect of alkaline stress on RES in the wh… Show more

“…Alkalinity induced higher expression of GmABF4, GmAAO3, GmABI5, GmNCED5, and GmNCED9 genes in soybean [62]; however, ribonucleic acid editing in rice chloroplast and mitochondria mRNA increased under alkaline stress; four types of RNA editing were notable-A-G (A-I), C-T (C-U), G-A, and T-C. Pentatricopeptide repeats (PPR) and organelle zinc-fingers (OZI) are involved in various biological functions and molecular processes. This phenomenon may contribute to amino acid changes in genes, which could lead to tolerance to this type of stress [94].…”

Underlying Mechanisms of Action to Improve Plant Growth and Fruit Quality in Crops under Alkaline Stress

“…Alkalinity induced higher expression of GmABF4, GmAAO3, GmABI5, GmNCED5, and GmNCED9 genes in soybean [62]; however, ribonucleic acid editing in rice chloroplast and mitochondria mRNA increased under alkaline stress; four types of RNA editing were notable-A-G (A-I), C-T (C-U), G-A, and T-C. Pentatricopeptide repeats (PPR) and organelle zinc-fingers (OZI) are involved in various biological functions and molecular processes. This phenomenon may contribute to amino acid changes in genes, which could lead to tolerance to this type of stress [94].…”

Underlying Mechanisms of Action to Improve Plant Growth and Fruit Quality in Crops under Alkaline Stress

The emerging role of epitranscriptome in shaping stress responses in plants

Prediction of RNA editing sites in maize under salt stress through transcriptomic approaches