Study of CaDreb2c and CaDreb2h Gene Sequences and Expression in Chickpea ( Cicer arietinum L.) Cultivars Growing in Northern Kazakhstan under Drought

Drought poses a significant challenge to plant growth and productivity, particularly in arid regions like northern Kazakhstan. Dehydration-responsive element-binding (DREB) transcription factors play an important role in plant response to drought and other abiotic stresses. In , the DREB subfamily c...

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Bibliographic Details
Published in:Plants (Basel) 2024-08, Vol.13 (15), p.2066
Main Authors: Kiselev, Konstantin V, Ogneva, Zlata V, Dubrovina, Alexandra S, Gabdola, Ademi Zh, Khassanova, Gulmira Zh, Jatayev, Satyvaldy A
Format: Article
Language:English
Subjects:
abiotic stress
Agricultural production
Amino acids
Arid regions
Arid zones
Beans
Chickpeas
crop
Crop diseases
Cultivars
Dehydration
DNA sequencing
Drought
Drought resistance
Gene expression
Gene sequencing
Genes
Genetic research
Genetically altered foods
Greenhouse gases
Heat
Legumes
Mimosaceae
Molecular interactions
Nucleotide sequence
Nucleotides
Plant growth
Potatoes
Proteins
Rankings
Regulatory sequences
Salinity
Salinity tolerance
Substitutes
tolerance
Transcription factors
Water deprivation
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Summary:Drought poses a significant challenge to plant growth and productivity, particularly in arid regions like northern Kazakhstan. Dehydration-responsive element-binding (DREB) transcription factors play an important role in plant response to drought and other abiotic stresses. In , the DREB subfamily consists of six groups, designated DREB1 to DREB6. Among these, DREB2 is primarily associated with drought and salinity tolerance. In the chickpea genome, two genes, and , have been identified, exhibiting high sequence similarity to Arabidopsis genes. We investigated the nucleotide sequences of and genes in several chickpea cultivars commonly grown in northern Kazakhstan. Interestingly, the gene sequence was identical across all varieties and corresponded to the sequence deposited in the GenBank. However, the gene sequence exhibited variations among the studied varieties, categorized into three groups: the first group (I), comprising 20 cultivars, contained a gene sequence identical to the GenBank (Indian cultivar CDC Frontier). The second group (II), consisting of 4 cultivars, had a single synonymous substitution (T to C) compared to the deposited gene sequence. The third group, encompassing 5 cultivars, displayed one synonymous substitution (C to T) and two non-synonymous substitutions (G to T and G to A). Furthermore, we assessed the gene expression patterns of and in different chickpea varieties under drought conditions. Chickpea cultivars 8 (III), 37 (I), 6 (III), and 43 (I) exhibited the highest drought resistance. Our analysis revealed a strong positive correlation between drought resistance and gene expression under drought stress. Our findings suggest that the chickpea's adaptive responses to water deprivation are associated with changes in gene expression. To further elucidate the mechanisms underlying drought tolerance, we propose future research directions that will delve into the molecular interactions and downstream targets of genes.
ISSN:2223-7747
2223-7747
DOI:10.3390/plants13152066