Insights into Cucumber () Genetics: Genome-wide Discovery and Computational Analysis of the Calreticulin Domain-Encoding Gene (CDEG) Family

Overview

Journal Saudi J Biol Sci

Specialty Biology

Date 2024 Feb 26

PMID 38404540

Authors

Pravej Alam

Thamer Albalawi

Affiliations

Soon will be listed here.

Abstract

Cucumber is an essential vegetable crop throughout the world. Cucumber development is vital for accomplishing both quality and productivity requirements. Meanwhile, numerous factors have resulted in substantial cucumber losses. However, the calreticulin domain-encoding genes (CDEGs) in cucumber were not well-characterized and had little function. In the genome-wide association study (GWAS), we recognized and characterized the CDEGs in (cucumber). Through a comprehensive study of , our research has unveiled the presence of three unique genes, denoted as and , unevenly distributed on three chromosomes in the genome of . In accordance to the phylogenetic investigation, these genes may be categorized into three subfamilies. Based on the resemblance with AtCDE genes, we reorganized the all genes in accordance with international nomenclature. The expression analysis and -acting components revealed that each of gene promoter region enclosed number of -elements connected with hormone and stress response. According to subcellular localization studies demonstrated that, they were found in deferent locations of the cell such as endoplasmic reticulum, plasma membrane, golgi apparatus, and vacuole, according to subcellular localization studies. Chromosomal distribution analysis and synteny analysis demonstrated the probability of segmental or tandem duplications within the cucumber CDEG gene family. Additionally, miRNAs displayed diverse modes of action, including mRNA cleavage and translational inhibition. We used the RNA seq data to analyze the expression of CDEG genes in response to cold stress and also improved cold tolerance, which was brought on by treating cucumber plants to an exogenous chitosan oligosaccharide spray. Our investigation revealed that these genes responded to this stress in a variety of ways, demonstrating that they may adapt quickly to environmental changes in cucumber plants. This study provides a base for further understanding in reference to CDE gene family and reveals that genes play significant functions in cucumber stress responses.

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