Abstract
The acyl-coenzyme A oxidase 3 (ACX3) gene involved in the β-oxidation pathway plays a critical role in plant growth and development as well as stress response. Earlier on, studies focused primarily on the role of β-oxidation limited to fatty acid breakdown. However, ACX3 peroxisomal β-oxidation pathways result in a downstream cascade of events that act as a transduction of biochemical and physiological responses to stress. A role that is yet to be studied extensively. In this study, we identified 20, 18, 22, 23, 20, 11, and 9 proteins in Gossypium hirsutum, G. barbadense, G. tomentosum, G. mustelinum, G. darwinii, G. arboretum, and G. raimondii genomes, respectively. The tetraploid cotton genome had protein ranging between 18 and 22, while diploids had between 9 and 11. After analyzing the gene family evolution or selection pressure, we found that this gene family undergoes purely segmental duplication both in diploids and tetraploids. W-Box (WRKY-binding site), ABRE, CAAT–Box, TATA-box, MYB, MBS, LTR, TGACG, and CGTCA-motif are abiotic stress cis-regulatory elements identified in this gene family. All these are the binding sites for abiotic stress transcription factors, indicating that this gene is essential. Genes found in G. hirsutum showed a clear response to drought and salinity stress, with higher expression under drought and salt stress, particularly in the leaf and root, according to expression analysis. We selected Gh_DO1GO186, one of the highly expressed genes, for functional characterization. We functionally characterized the GhACX3 gene through overexpression and virus-induced gene silencing (VIGS). Overexpression of this gene enhanced tolerance under stress, which was exhibited by the germination assay. The overexpressed seed growth rate was faster relative to control under drought and salt stress conditions. The survival rate was also higher in overexpressed plants relative to control plants under stress. In contrast, the silencing of the GhACX3 gene in cotton plants resulted in plants showing the stress susceptibility phenotype and reduced root length compared to control. Biochemical analysis also demonstrated that GhACX3-silenced plants experienced oxidative stress while the overexpressed plants did not. This study has revealed the importance of the ACX3 family during stress tolerance and can breed stress-resilient cultivar.
Highlights
Drought and salt stresses are environmental factors that affect plant growth and development (Su et al, 2020), reproduction, and reduce crop yield
In G. hirsutum (AD) 1, we identified 20 proteins, in G. barbadense (AD) 2, 18 proteins, in G. tomentosum (AD) 3, proteins, G. mustelinum (AD) 4, proteins, G. darwinii (AD) 5, 20 proteins, in G. arboreum A2, 11 proteins, and G. raimondii D5, nine (9) proteins
We further evaluated various physiological parameters such as the excised leaf water loss (ELWL), relative leaf water content (RLWC), and cell membrane stability (CMS) in Virus-Induced Gene Silencing (VIGS) plants and WT
Summary
Drought and salt stresses are environmental factors that affect plant growth and development (Su et al, 2020), reproduction, and reduce crop yield. The acyl coenzyme A oxidase (ACX) gene family is a diverse family of enzymes involved in the β- oxidation pathway of fatty acids (Graham and Eastmond, 2002). Hydrogen peroxide produced in this process serves as a stress signal molecule (Kindl, 1993) Another scientist found that genes encoding ACXs are distributed in most plant tissues, including leaves, roots, inflorescence, and bolts; this is because β-oxidation of fatty acid occurs throughout plants’ life cycles (Eastmond et al, 2000). ACXs genes are critical in the production of energy under aerobic conditions, gene epigenetic modification, and transcription of stress-responsive genes
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