Omics strategies for crop improvement in response to climate change‐imposed abiotic stress

Omics strategies for crop improvement in response to climate change‐imposed abiotic stress

Given the current status of climate change and its impact on global food security, it is imperative to improve the abiotic stress tolerance of crop plants to enhance productivity. Traditional plant breeding methods have been widely employed to develop climate‐resilient crops; however, their success...

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Bibliographic Details
Main Authors: Abhilasha Shourie, Nishtha Madaan, Paridhi Saini
Format: Article
Language:English
Published: Universitas Gadjah Mada, Yogyakarta 2024-12-01
Series:Indonesian Journal of Biotechnology
Subjects:
crispr
gene function identification
gene‐trait relationships
genome editing
gwas
high throughput genomic technologies
Online Access:https://jurnal.ugm.ac.id/ijbiotech/article/view/94026
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Summary:Given the current status of climate change and its impact on global food security, it is imperative to improve the abiotic stress tolerance of crop plants to enhance productivity. Traditional plant breeding methods have been widely employed to develop climate‐resilient crops; however, their success has been limited due to the lack of understanding of the complex relationships between genes and stress‐related phenotypes. The advent of modern genomics has enabled the expression analysis of stress genes in plants, as genome‐wide information is readily accessible and can be utilized to assign and validate the gene functions. This article highlights the potential applications and limitations of present‐day genomic technologies based on genome mapping, gain or loss‐of‐function analysis for identification of the role of a particular gene in abiotic stress response in plants. Such technologies are highly efficient in candidate gene identification; gene‐trait relationships establishment; functional elucidation of genes; and stress genes modification in crop plants. Modern high throughput genomic technologies offer wide scope for deciphering the complexities of genetic regulation of stress in plants; modulating stress responses; and developing stress tolerance in crop plants against drought, temperature, salinity, osmotic imbalance, herbicides and heavy metal toxicity.
ISSN:0853-8654
2089-2241

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