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The book inculcates a holistic approach to improve crop productivity and quality for ensuring food security and nutrition to all. This warrants to identify various stress conditions prevalent globally and tailor crop adaptability and productivity to the maximum accordingly, employing physio-molecular modern tools and techniques with judicious amalgamation with conventional crop husbandry. As a result, the book chapters encompass diverse environmental factors, internal physio-molecular processes and their modulations with a final goal of expanding area under cultivation by utilization of constraint terrains of poor site quality and augmenting sustainable crop productivity and quality on the face of rapidly changing climate. The book includes role of plant hormones, nano-sensors, nanomaterials etc. in stress tolerance responses, capturing recent advancement in the field of stress tolerance, enlarging scope of coverage by gleaning modern literature and providing glimpses of futuristic scenario of agriculture practices that can render ‘balance staple food rich in nutrition, vitamins and minerals’ to teeming billions of global human populations. Thus, the book provides a comprehensive overview of the role of stress environment and understanding stress physiology for developing stress tolerant crops. The book covers current knowledge and future prospects to achieve enhanced food security under stress environment of crops. The renowned contributors elegantly crafted each chapter, suited alike to both classroom texts for graduate students and reference material for researchers. The language and style are simple and lucid with liberal use of illustrations. This book should be on the shelf of university/ personal libraries for inquisitive students and enlightened researchers.
Global demand for wheat, rice, corn, and other essential grains is expected to steadily rise over the next twenty years. Meeting this demand by increasing production through increased land use is not very likely; and while better crop management may make a marginal difference, most agriculture experts agree that this anticipated deficit must be made up through increased crop yields. The first resource of its kind, Physiology and Biotechnology Integration for Plant Breeding assembles current research in crop plant physiology, plant biotechnology, and plant breeding that is aimed toward improving crop plants genetically while supporting a productive agriculture ecosystem. Highly comprehensive, this reference provides access to the most innovative perspectives in crop physiology – with a special emphasis on molecular approaches – aimed at the formulation of those crop cultivars that offer the greatest potential to increase crop yields in stress environments. Surveys the current state of the field, as well as modern options and avenues for plant breeders and biotechnologists interested in augmenting crop yield and stability With the contributions of plant scientists from all corners of the globe who are actively involved in meeting this important challenge, Physiology and Biotechnology Integration for Plant Breeding provides readers with the background information needed to understand this cutting-edge work, as well as detailed information on present and potential applications. While the first half of the book establishes and fully explains the link between crop physiology and molecular biology, the second part explores the application of biotechnology in the effective delivery of the high yield and environmentally stable crop plants needed to avert the very real possibility of worldwide hunger.
This book covers different physiological processes, tools, and their application in crop breeding. Each chapter emphasizes on a specific trait/physiological process and its importance in crop, their phenotyping information and how best it can be employed for crop improvement by projecting on success stories in different crops. It covers wide range of physiological topics including advances in field phenotyping, role of endophytic fungi, metabolomics, application of stable isotopes, high throughput phenomics, transpiration efficiency, root phenotyping and root exudates for improved resource use efficiency, cuticular wax and its application, advances in photosynthetic studies, leaf spectral reflectance and physiological breeding in hardy crops like millets. This book also covers the futuristic research areas like artificial intelligence and machine learning. This contributed volume compiles all application parts of physiological tools along with their advanced research in these areas, which is very much need of the hour for both academics and researchers for ready reference. This book will be of interest to teachers, researchers, climate change scientists, capacity builders, and policy makers. Also, the book serves as additional reading material for undergraduate and graduate students of agriculture, physiology, botany, ecology, and environmental sciences. National and international agricultural scientists will also find this a useful resource.
Plants and the soil they grow in, are confronted with severe biotic and abiotic stresses viz. nutrient starvation, salt stress, drought, flooding, xenobiotic contamination, in order to sustain in an ecosystem. They also shape the microbial composition in their vicinity by modulating their secretions. This book discusses the pressing demand for novel and potential microorganisms to support an environment-friendly and cost-effective way of stress management in the plants. The book summarizes the processes and mechanisms involved in microbe-assisted plant and soil stress management. It discusses the challenges and opportunities in the application of microbial interactions in plant health. It describes in detail the nutrient dynamics of different soil systems. It includes important topics like agriculturally important genes and enzymes, rhizosphere modeling & engineering, genetically engineered bio-inoculants etc. It also talks about the application of next-generation technologies, omics and nano-based technologies. In the recent years, more than 50% of agricultural production relies on chemical fertilizers, leading to serious health issues and environmental concerns. This book provides natural solutions to these environmental concerns. This book is useful for researchers and students in the field of microbiology, agriculture, soil biology and plant sciences.
The Plant Hormone Ethylene: Stress Acclimation and Agricultural Applications presents current knowledge on our understanding of ethylene perception and signaling, its role in the regulation of plant physiological processes, and its contribution to acclimation in stressful environments. Plants regularly face environmental constraints due to their immobile nature. In persistently changing environmental conditions, several stress factors influence cellular metabolism, ultimately causing reduced plant growth and development with a significant loss in agricultural productivity. Sustainable agriculture depends on the acclimation of plant processes to the changing environment through altered physiological and molecular responses, which are controlled by plant hormones, including ethylene. Ethylene interacts with other plant hormones and signaling molecules to regulate several cellular processes, plant growth and development, and, ultimately, crop productivity. This book begins with an introduction to ethylene before providing a detailed study of the latest findings on the role of ethylene in plants, including its role in photosynthetic processes, flower development, leaf senescence, nutrients acquisition, and regulation of abiotic stress responses as well as its application in agriculture. The book is an ideal guide for researchers exploring plant physiology and biochemistry as well as for those investigating the use of ethylene knowledge in agriculture in persistently changing environmental conditions. - Provides state-of-the art insights into ethylene-regulated photosynthesis, growth, and productivity in crop plants - Presents regulatory mechanisms of ethylene action - Assists in developing physiomolecular strategies for augmenting crop performance in persistently changing environmental conditions
Currently, agriculture is at a crossroads similar to that experienced at the beginning of the last century. The growing need to supply food to global markets and the incipient climate is expected to jeopardize the current agricultural systems. This situation requires a rethinking of agricultural production systems, and it is clearly necessary to incorporate new tools and agronomic practices that improve efficiency and sustainability. A key factor can be identified in using resources or the competition of crops to resist biotic and abiotic stresses. Plant growth-promoting bacteria (PGPB) are of outstanding utility due to the multiple mechanisms with which they influence plant development. It is fundamental, at these crossroads, to delve deeper into the mechanisms by which PGPB can improve the development of plants in the soil at the phenotypic level. Biochemical methods, incorporating genomic, transcriptomic, proteomic, and metabolomic analyses, can help us understand these interactions. In addition, omics techniques will make it possible to create a complete and complex vision using big data technologies, spurring new strategies to achieve an agriculture with a greater degree of integration of the environment, and greater efficiency of production with reduced risk to human.
Microorganisms are a good indicator of soil health. Plant growth-promoting microorganisms protect plants from the stresses of water, salt, metal, biotic, and so on, and are well known for strategically modulating the plant mechanisms to defend and mitigate environmental stresses. Taking a multidisciplinary approach, this volume explores the role of plant microorganisms in ecological and agricultural revitalization beyond normal agriculture practices and offers practical and applied solutions for the restoration of degraded lands to fulfill human needs with food, fodder, fuel, and fiber. It also provides a single comprehensive platform for soil scientists, agriculture specialists, ecologists, and those in related disciplines. Features • Presents cutting-edge microbial biotechnology as a tool for restoring degraded lands • Explores the aspects of sustainable development of degraded lands using microorganism-inspired land remediation • Highlights sustainable food production intensification in nutrient-poor lands through innovative use of microbial inoculants • Explains the remediation of polluted land for regaining biodiversity and achieving United Nations Sustainable Development Goals • Includes many real-life applications from South Asia offering solutions to today’s agricultural problems This book will be of interest to professionals, researchers, and students in environmental, soil, and agricultural sciences as well as stakeholders, policy makers, and practitioners with an interest in this field.
Zusammenfassung: The book "Plant Adaptation to Abiotic Stress: From Signaling Pathways and Microbiomes to Molecular Mechanisms" comprehensively examines abiotic stressors--cold, heat, light, salinity, and water scarcity--across its 18 chapters. Focusing particularly on Arabidopsis thaliana, it investigates abiotic stresses, adaptation strategies, and molecular pathways. Furthermore, it addresses broader issues, including climate challenges, food security, water scarcity, and agricultural concerns such as soil acidity and aluminum stress. It proposes adaptive measures for cultivating stress-resistant crops and sheds light on genetic modification methods such as CRISPR-Cas9, integrating nanotechnology in plant breeding. Emphasizing transcription factors, post-translational protein modifications, and diverse noncoding RNAs (long noncoding RNAs, circular RNAs, microRNAs, and small interfering RNAs), the book highlights their role in regulating gene expression during stress responses. It specifically underscores secondary messengers, plant hormones, and MAPK cascades within intracellular signaling pathways. Additionally, it discusses the roles of endophytic bacteria and microbial interactions in bolstering stress resilience. The book explores state-of-the-art research methodologies in plant breeding, omics approaches, and nanotechnology integration for developing stress-resistant crop varieties, advocating for agricultural sustainability. Tailored for plant physiology scientists, academics, and postgraduate students, it amalgamates diverse research findings, serving as a pivotal resource to comprehend intricate plant responses to environmental challenges
Plant Life under Changing Environment: Responses and Management presents the latest insights, reflecting the significant progress that has been made in understanding plant responses to various changing environmental impacts, as well as strategies for alleviating their adverse effects, including abiotic stresses. Growing from a focus on plants and their ability to respond, adapt, and survive, Plant Life under Changing Environment: Responses and Management addresses options for mitigating those responses to ensure maximum health and growth. Researchers and advanced students in environmental sciences, plant ecophysiology, biochemistry, molecular biology, nano-pollution climate change, and soil pollution will find this an important foundational resource. - Covers both responses and adaptation of plants to altered environmental states - Illustrates the current impact of climate change on plant productivity, along with mitigation strategies - Includes transcriptomic, proteomic, metabolomic and ionomic approaches
Microbial Biostimulants for Plant Growth, Development and Abiotic Stress Amelioration provides readers with insights into the major role of biostimulants in plant growth and development while under abiotic stress. The term biostimulants is broadly used to reference a group of diverse substances and microorganisms that stimulate life or that promote favorable plant responses. They stimulate natural processes to enhance/benefit nutrient uptake, nutrient efficiency, tolerance to abiotic stress, and crop quality. Many biostimulants improve nutrition and they do so regardless of their own nutrient contents. Further, recently microbe-based biostimulants have emerged as important plant protectors under a range of adverse conditions. Microbial Biostimulants for Plant Growth, Development and Abiotic Stress Amelioration is the latest volume in the Biostimulants and Protective Biochemical Agents series. Presents the potential for more environmentally sustainable interventions against abiotic stresses Highlights the variety of applications for which biostimulants are proving effective Includes coverage of commercialization and role in addressing Sustainability Development Goals