Calcium Transport Elements in Plants discusses the role of calcium in plant development and stress signaling, the mechanism of Ca2+ homeostasis across plant membranes, and the evolution of Ca2+/cation antiporter (CaCA) superfamily proteins. Additional sections cover genome-wide analysis of Annexins and their roles in plants, the roles of calmodulin in abiotic stress responses, calcium transport in relation to plant nutrition/biofortification, and much more. Written by leading experts in the field, this title is an essential resource for students and researchers that need all of the information on calcium transport elements in one place. Calcium transport elements are involved in various structural, physiological and biochemical processes or signal transduction pathways in response to various abiotic and biotic stimuli. Development of high throughput sequencing technology has favored the identification and characterization of numerous gene families in plants in recent years, including the calcium transport elements.

The growth of human population has increased the demand for improved yield and quality of crops and horticultural plants. However, plant productivity continues to be threatened by stresses such as heat, cold, drought, heavy metals, UV radiations, bacterial and fungal pathogens, and insect pests. Long noncoding RNAs are associated with various developmental pathways, regulatory systems, abiotic and biotic stress responses and signaling, and can provide an alternative strategy for stress management in plants. Long Noncoding RNAs in Plants: Roles in development and stress provides the most recent advances in LncRNAs, including identification, characterization, and their potential applications and uses. Introductory chapters include the basic features and brief history of development of lncRNAs studies in plants. The book then provides the knowledge about the lncRNAs in various important agricultural and horticultural crops such as cereals, legumes, fruits, vegetables, and fiber crop cotton, and their roles and applications in abiotic and biotic stress management.

Understand the keys to creating the food of the future Genome engineering in plants is a field that has made enormous strides in recent years. In particular, the CRISPR-Cas system has been used in a number of crop species to make significant leaps forward in nutritional improvement, stress tolerance, crop yield, and more. As scientists work to meet global food needs and foster sustainable agriculture in a changing world, genome engineering promises only to become more important. Applications of Genome Engineering in Plants details the history of, and recent developments in, this essential area of biotechnology. It describes advances enabling nutritional improvement, nutraceuticals improvement, flavonoid enrichment, and many more crop enhancements, as well as subjects such as biosafety and regulatory mechanisms. The result is a thorough and essential overview for researchers and biotech professionals. Applications of Genome Engineering in Plants readers will also find: Chapters on trans-gene free editing or non-transgenic approaches to plant genomes Detailed discussion of topics including nanotechnology-facilitated genome editing, engineering for virus resistance in plants, and more Applications of genome editing in oil seed crops, vegetables, ornamental plants, and many others Applications of Genome Engineering in Plants is ideal for academics, scientists, and industry professionals working in biotechnology, agriculture, food science, and related subjects.

Microbial Bioreactors for Industrial Molecules Harness the planet’s most numerous resources with this comprehensive guide Microorganisms constitute the invisible majority of all living creatures on Earth. They are found virtually everywhere on the planet, including in environments too extreme for any larger organisms to exist. They form a hugely significant resource whose potential value for human society cannot be overlooked. The creation of microorganism- based bioreactors for the industrial production of valuable biomolecules has the potential to revolutionize a range of industries and fields. Microbial Bioreactors for Industrial Molecules provides a comprehensive introduction to these bioresources. It covers all potential approaches to the use of microbial technology and the production of high-value biomolecules for the pharmaceutical, cosmetic, and agricultural industries, among others. The book’s rigorous detail and global, holistic approach to harnessing the power of the planetary microbiome make it an invaluable introduction to this growing area of research and production. Readers will also find: Detailed coverage of basic, applied, biosynthetic, and translational approaches to the use of microbial technology Discussion of industrially produced microbe-borne enzymes including invertase, lipase, keratinase, protease, and more Approaches for using microbial bioreactors to generate biofuels Microbial Bioreactors for Industrial Molecules is essential for scientists and researchers in microbiology and biotechnology, as well as for professionals in the biotech industries and graduate students studying the applications of the life sciences.

Plant Transcription Factors: Contribution in Development, Metabolism, and Environmental Stress provides comprehensive coverage of plant TFs and their various functions, evaluating their crucial role in growth and development, signaling, stress management and other key plant processes. Sections cover the significance of plant TFs in functional genomics, the influence of phyto-hormones on the modulation of plant TFs, plant development and metabolism, including shoot development, flowering development and alkaloid biosynthesis. The book's final section reviews the role of TFs in various plant stresses, including temperature, water and heavy metal stress. Written by leading experts around the globe, this book is an essential read to researchers interested in plant signaling and plant genomics.

Plant Receptor-like Kinases: Role in Development and Stress presents the latest research in receptor-like kinases (RLKs), a class of development and defense-response proteins in plants. As one of the largest protein families, with roles ranging from growth and development to stress response, RLKs are involved in every aspect of the plant life cycle, including growth and development, reproduction, and immunity. Development of high throughput sequencing technology has improved the identification and characterization of numerous gene families in plants in the recent years, allowing researchers to identify and characterize numerous RLK sub-families in model plant species and agro-economically important crop plants like rice, wheat, sorghum, tomatoes, and more. This book provides foundational knowledge on the classification of RLKs, their mechanism of action and their roles in the plant life cycle, as well as the most up-to-date advances in the applications of RLKs. It is an essential read for researchers interested in plant signaling and plant genomics.

Cation Transporters in Plants presents expert information on the major cation transporters, along with developments of various new strategies to cope with the adverse effects of abiotic and biotic stresses. The book will serve as a very important repository for the scientist, researcher, academician and industrialist to enhance their knowledge about cation transport in plants. Further, applications listed in the book will facilitate future developments in crop designing strategies. This comprehensive resource provides an alternative strategy for abiotic and biotic stress management in agricultural and horticultural crops. In addition, it will further improve basic knowledge om the origin and mechanism of cation homeostasis and their role in developmental transition and stress regulation.

This book discusses molecular approaches in plant as response to environmental factors, such as variations in temperature, water availability, salinity, and metal stress. The book also covers the impact of increasing global population, urbanization, and industrialization on these molecular behaviors. It covers the natural tolerance mechanism which plants adopt to cope with adverse environments, as well as the novel molecular strategies for engineering the plants in human interest. This book will be of interest to researchers working on the impact of the changing environment on plant ecology, issues of crop yield, and nutrient quantity and quality in agricultural crops. The book will be of interest to researchers as well as policy makers in the environmental and agricultural domains.

This book discusses molecular approaches in plant as response to environmental factors, such as variations in temperature, water availability, salinity, and metal stress. The book also covers the impact of increasing global population, urbanization, and industrialization on these molecular behaviors. It covers the natural tolerance mechanism which plants adopt to cope with adverse environments, as well as the novel molecular strategies for engineering the plants in human interest. This book will be of interest to researchers working on the impact of the changing environment on plant ecology, issues of crop yield, and nutrient quantity and quality in agricultural crops. The book will be of interest to researchers as well as policy makers in the environmental and agricultural domains.