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This book is an elaborate account of the effects of abiotic stressors on cereals crops. It not only discusses the impacts of abiotic stress on the crops but also the physiological, biochemical, and molecular strategies applied in plant of cereal crops to alleviate the detrimental effects of abiotic stressors. The book also elaborates on various molecular response to the abiotic stress. It is a knowledgebase providing readers latest updates on development of high-performance diagnostics, stress induced responses, genomics, phenomics and metabolomics involved in abiotic stress tolerance of cereal food crops. The book is useful for plant scientists and research scholars. Post graduate students of agriculture sciences, plant physiology, botany and biochemistry also benefit from this compilation.
Advances in Rice Research for Abiotic Stress Tolerance provides an important guide to recognizing, assessing and addressing the broad range of environmental factors that can inhibit rice yield. As a staple food for nearly half of the world's population, and in light of projected population growth, improving and increasing rice yield is imperative. This book presents current research on abiotic stresses including extreme temperature variance, drought, hypoxia, salinity, heavy metal, nutrient deficiency and toxicity stresses. Going further, it identifies a variety of approaches to alleviate the damaging effects and improving the stress tolerance of rice. Advances in Rice Research for Abiotic Stress Tolerance provides an important reference for those ensuring optimal yields from this globally important food crop. - Covers aspects of abiotic stress, from research, history, practical field problems faced by rice, and the possible remedies to the adverse effects of abiotic stresses - Provides practical insights into a wide range of management and crop improvement practices - Presents a valuable, single-volume sourcebook for rice scientists dealing with agronomy, physiology, molecular biology and biotechnology
Biochar for Mitigating Abiotic Stress in Plants provides a unique and leading resource for utilizing biochar to address specific plant health challenges, including osmotic, ionic, and oxidative stress. With a focus on crop yielding plants, the book provides targeted application insights to improve plant health, and resulting crop production. Readers will find important tools toward the identification, treatment, and management of a variety of abiotic stressors through the effective and appropriate application of biochar. This is an important reference for those seeking to apply current knowledge and an inspiration for further research in the area. Biochar is a carbon-rich organic substance produced by the pyrolysis of organic materials in the absence or presence of oxygen. It is an organic matter conditioner that can boost carbon sequestration and organic and inorganic pollutant immobilization. It is a crucial method for soil regeneration. Additionally, biochar facilitates increasing mineral supply and soil organic matter, resulting in soils with increased nutritional content. - Covers the latest evidence-based approach in the diagnosis and management of plants under abiotic stress - Includes easy-to-follow algorithms and key points - Proposes options for sustaining crop production under the effects of climate change
In recent decades, agrochemicals have enhanced crop productivity to meet increasing global food requirements. However, prolonged and extensive use of agrochemicals has resulted in contamination that persists in the soil system which can be biomagnified in the food chain. Furthermore, toxic chemicals adversely affect important soil microbial biota, the key drivers of biogeochemical cycles. This concern has raised the need to develop environmentally friendly and cost-effective nano- and micro-biotechnology strategies to minimize the adverse impact of agrochemicals and pesticide residues on soil microbiota, soil fertility, and their biomagnification in food crops. Nano-bioinoculants - the combination of nano-compounds and bioinoculants - have been increasingly used as soil amendments. They can improve agri-potential and soil health by maintaining soil physico- and biological properties, microbial diversity, and the nutrient-solubilizing microbial population. They also aid in improving crop yields and reducing agrochemical and pesticide residues. Nano-bioinoculants are more efficient than other methods for removing contaminants due to their small size, high reactivity, and catalytic activities. Several types of nano-compounds (chitosan, zeolite, gypsum, and silicon dioxide) have been used in conjunction with beneficial microbes (bacteria fungi, actinomycetes & endophytic bacteria) as nano-bioinoculants.
The emergence of a plethora of water contaminants as a result of industrialization has introduced complexity to water treatment processes. Such complexity may not be easily resolved using deterministic approaches. Artificial intelligence (AI) has found relevance and applications in almost all sectors and academic disciplines, including water treatment and management. AI provides dependable solutions in the areas of optimization, suspect screening or forensics, classification, regression, and forecasting, all of which are relevant for water research and management. Artificial Intelligence Applications in Water Treatment and Water Resource Management explores the different AI techniques and their applications in wastewater treatment and water management. The book also considers the benefits, challenges, and opportunities for future research. Covering key topics such as water wastage, irrigation, and energy consumption, this premier reference source is ideal for computer scientists, industry professionals, researchers, academicians, scholars, practitioners, instructors, and students.
Microbiome Nano-Cross-Talk presents a comprehensive overview of the functional aspects of multiphasic microbial and nanotechnological interactions within and between plants and their ecosystem. Recognizing that beneficial microbes are involved in plant growth promotion, this book highlights their mechanism and regulation to enhance plant's yield and development even under stressed conditions. The merging of nanotechnology with microbiology is an essential aspect of this book. Various nanomaterials, their synthesis approaches as well as applications in agriculture have been studied extensively in past years. However, there is still a lack of information available on the synergism between nanomaterials and microbes towards increased plant growth as well as reducing stress. Microbiome Nano-Cross-Talk, provides detailed insights into these environmental and agricultural perspectives of plant-microbe-nano interaction. With a focus on focus the morphological, anatomical, biochemical, molecular and gene expression levels of plant growth promotion, the book is the first of its kind to enable scientists to unravel the different pathways and signaling cascades involved in response to this interaction and to understanding how nanomaterials regulate the plant-microbe associations. It critically examines the role of beneficial microbes in conjunction with nanoparticles in plants and the mechanisms adopted by the plants at the biochemical and molecular levels to enhance plant growth and mitigate various stresses. - Presents a logistic approach to nanotechnology and microbiology in the plant sciences - Explores multiple nanomaterials and their interactions for improved plant health and yield - Enables the reader to devise strategies for engineering stress-tolerant plants and increased plant productivity
Biostimulants in Alleviation of Metal Toxicity in Plants: Emerging Trends and Opportunities focuses on the role of substances or micro-organisms whose presence can address issues of metal contamination in soils, seeds and plants. Including a range of biostimulant tools, the book highlights both endogenous and exogenous application. Written and edited by a global team of experts, this book presents an overview on biostimulants in determining metal toxicity. As plants encounter a wide range of environmental challenges during their lifecycle, among which metal toxicity is a common form of abiotic stress, this book thoroughly covers important topics on the subject matter. Once inside a plant system, toxic metals may initiate a variety of physiological alterations in plants, including adversely impacted seed germination, root and shoot growth, chloroplasts ultrastructure and photosynthesis, nutrients assimilation, carbohydrates metabolism, and plant hormonal status which, collectively, results in reduced plants yields. In addition to several naturally occurring physiological and metabolic re-programing responses, plants may also modify their root and shoot systems in order to dilute entered amount of toxic metals. As an additional tool biostimulants have emerged as one of the important plant protectors under adverse conditions. - Includes endogenous and exogenous application of biostimulants - Focuses on use based on specific metal contamination - Presents forward-looking prospects for the use of biostimulants in plant health protection
Crop improvement using classically induced mutagenesis is now well standardized. Many new promising varieties of different crops have been successfully developed worldwide using both physical and chemical mutagens. Voluminous literature is now available on basic and applied aspects of mutagenesis. The mutation technique has been refined and holds the promise of generating much wider and more desirable variability than classical breeding. Recent advances in technology combined with classical mutation breeding offer new and exciting challenges for the development of new varieties. A global inventory of induced mutagenesis activities for crop improvement is requried. This book covers both basic and applied aspects of mutation and its impact on various crops: it is extremely well prepared and contains a huge volume of information accumulated using classically induced mutagenesis on different crops in different countries. Three key features: Describes the importance of induced mutation in crop plant research and its application to production Highlights new advances in the understanding of plant mutagenesis in crop improvement Contains contributions from major leaders in the field of plant mutation research This volume brings together all the important and relevant literature in the field. It provides a complete account of the mutation breeding of crops, presenting conclusions about the value of the method, its possibilities, limitations, and shortcomings, and the possible difficulties of further application in various crops. The initial chapters deal with the interactions between mutagenic treatment and plant material, such as aspects of mutagenic treatment, postirradiation behavior of shoot apices, and adventitious bud techniques. All available literature is then discussed crop by crop and critically evaluated. This will serve as an extremely comprehensive guide for researchers, teachers, students, and individuals who are interested in using induced mutagenesis as a tool for crop improvement.
Improving Stress Resilience in Plants: Physiological and Biochemical Basis and Utilization in Breeding addresses the urgent need for improved understanding of major plant stress tolerance mechanisms, the identification of the genes and gene products that are key to improving those mechanisms and means of optimizing those genes through molecular approaches. With a focus on plant physiological and biochemical attributes at both cellular and whole plant levels, this book includes the latest information on crosstalk between the various signaling molecules and quantitative trait locus (QTL). Further, it explores the extension of these mechanisms to breeding approaches, confirming overall understanding and inspiring further research. Written by a team of global experts, and presented in three thematic sections, the book provides insights into physical adaptations, metabolism and pathways, and breeding techniques including CRISPR and conventional approaches to reduce the negative effects of stresses and improve crop yield even under stress conditions. Improving Stress Resilience in Plants: Physiological and Biochemical Basis and Utilization in Breeding is ideal for researchers, academics and advanced students seeking to improve stress tolerance among crop plants and developing key future strategies for sustainable food production. - Explores key strategies, including signaling molecules and Quantitative Trait Locus (QTLs) - Highlights stress mitigating agents for improved crop yield - Provides an integrated and holistic overview, enabling and inspiring further research toward improved food security