Applied Biotechnology Strategies to Combat Plant Abiotic Stress investigates the causal molecular factors underlying the respective mechanisms orchestrated by plants to help alleviate abiotic stress in which
Although knowledge of abiotic stresses in crop plants and high throughput tools and biotechnologies is avaiable, in this book, a systematic effort has been made for integrating omics interventions across major sorts of abiotic stresses with special emphasis to major food crops infused with detailed mechanistic understanding, which would furthermore help contribute in dissecting the interdisciplinary areas of omics-driven plant abiotic stress biology in a much better manner.
In 32 chapters Applied Biotechnology Strategies to Combat Plant Abiotic Stress focuses on the integration of multi-OMICS biotechnologies in deciphering molecular intricacies of plant abiotic stress namely drought, salt, cold, heat, heavy metals, in major C3 and C4 food crops. Together with this, the book provides updated knowledge of common and unique set of molecular intricacies playing a vital role in coping up severe abiotic stresses in plants deploying multi-OMICS approaches
This book is a valuable resource for early researchers, senior academicians, and scientists in the field of biotechnology, biochemistry, molecular biology, researchers in agriculture and, crops for human foods, and all those who wish to broaden their knowledge in the allied field.
- Describes biotechnological strategies to combat plant abiotic stress
- Covers the latest evidence based multipronged approaches in understanding omics perspective of stress tolerance
- Focuses on the integration of multi-OMICS technologies in deciphering molecular intricacies of plant abiotic stress
Reihe
Sprache
Verlagsort
Verlagsgruppe
Elsevier Science & Techn.
Dateigröße
ISBN-13
978-0-443-21624-4 (9780443216244)
Schweitzer Klassifikation
- Advancement in the understanding of the different abiotic stresses using "omics"
- Omics advancements in plant abiotic stress
- Implication of integrated multiomics approaches to decode the molecular basis of drought stress response in plants: an Omics's perspective
- Advancement in understanding cold stress tolerance using "omics" tools
- Omics-based strategies for improving salt tolerance in rice
- Master players in the chase of establishing heat tolerance: a molecular perspective
- Advancements in understanding molecular interlinkages to combat combinations of drought and salinity stresses in crops
- Integrated omics approaches for nutrient stress management in plants
- Role of omics in understanding heavy metal responses and tolerance in plants
- Physiological and genomic approaches for improving tolerance of flooding during germination and seedling establishment in rice
- Advances in understanding and engineering plant root system architecture to alleviate abiotic stress
- Role of omics in understanding signaling cascade of abiotic stress in plants
- Role of omics tools in the understanding of abiotic stress tolerance in wheat crop
- Role of omics tools in understanding the stress tolerance in legumes
- Developments in root omics in legume crops under drought stress
- Recent advances in abiotic stress tolerance in rice
- Omic tools in understanding stress tolerance in grasses
- Advances and challenges in omics approaches for alleviating abiotic stresses and improving cane yield in sugarcane crop
- Unraveling the mechanisms of various phospho-proteomics approach for crop improvement
- Impact of omics in understanding reactive oxygen species metabolism in abiotic stress
- Omics technologies: an advanced approach to understand the systems using bioinformatics tools
- Plant response to drought stress: epigenomic perspective
- Recent advancement in high-throughput "omics" technologies
- Omics approaches for exploring plant-microbe interaction combating abiotic stress
- Impact of rhizospheric endophytes in combating abiotic stress in plants
- Metagenomics for mitigation of heavy metal toxicity in plants
- Genome editing as a promising tool to dissect the stress biology
- Improving end-use quality under marginal environments employing 'omics' approach
- Emerging roles of noncoding RNAs in regulation of drought stress responses
