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Pamela Peeke, M. Views Total views. Actions Shares. No notes for slide. Liquid Chromatography [] Database wur. CoxPathDB kazusa. Browse the tomato genome, Sol Genomics http: Biology , 8, 90 13 of 19 Conclusions Abiotic stress is one of the major limiting factors in plant growth and yield.
Various omics tools and techniques have been developed to understand the molecular mechanisms of plants responses in abiotic stress conditions.
Under stress conditions, plants modulate themselves to adopt the existing stresses by controlling gene regulation, proteins, and metabolites. It is essential to elucidate the functions of newly identified stress-responsive genes to understand the abiotic stress responses of plants. To identify changes by various tools and techniques like genomics, transcriptomics, metabolomics, ionmics, and phenomics have been devised to allow the understanding of genetic makeup in depth, their signaling cascade, and their adaptability under stress conditions.
In tomato, genomics, ionomics, and transcriptomics have been developed for abiotic stress, but the other major branches like metabolomics, proteomics, and phenomics are as of yet lingering behind. Diverse study of omics tools and integrated approaches discussed in this review tell us about the current situations and future points for successful management of abiotic stress in tomato. Author Contributions: J.
All authors contributed to finalizing the manuscript. All authors read and approved the final manuscript. Conflicts of Interest: The authors declare no conflict of interest. References 1. Chaudhary, J. Plants , 8, Patil, G. Genomic-assisted haplotype analysis and the development of high-throughput SNP markers for salinity tolerance in soybean. Rizhsky, L. When Defense Pathways Collide. Plant Physiol. Lin, T. Genomic analyses provide insights into the history of tomato breeding. Plant Sci.
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