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This book deliberates on the concept, strategies, tools, and techniques of allele mining in oilseed crops and its application potential in genome elucidation and improvement, including studying allele evolution, discovery of superior alleles, discerning new haplotypes, assessment of intra- and interspecific similarity, and studies of gene expression and gene prediction. Available gene pools in global germplasm collections, specifically consisting of wild allied species and local landraces for almost all major crops, have facilitated allele mining. The development of advanced genomic techniques, including PCR-based allele priming and Eco-TILLING-based allele mining, is now widely used for mining superior alleles. Allele's discovery has become more relevant now for employing molecular breeding to develop designed crop varieties matching consumer needs and with genome plasticity to adapt to climate change scenarios. All these concepts and strategies, along with precise success stories, are presented in the chapters dedicated to the major oilseed crops. 1. This is the first book on the novel strategy of allele mining in oilseed crops for precise breeding. 2. This book presents genomic strategies for mining superior alleles underlying agronomic traits from genomic resources. 3. This book depicts case studies of PCR-based allele priming and Eco-TILLING based allele mining. 4. This book elaborates on gene discovery and gene prediction in major oilseed crops. This book will be useful to students and faculties in various plant science disciplines, including genetics, genomics, molecular breeding, agronomy, and bioinformatics; scientists in seed industries; and policymakers and funding agencies interested in crop improvement.
This edited book covers the application of modern genomics tools for developing climate-smart oilseed cultivars. The book's prime focus is on utilizing available oilseed genomic resources and application of next-generation genetics and breeding tools, viz. genome-wise association mapping, genomic selection, genome editing and accelerated breeding pipelines and their efficacy for rapid development and delivery of stress-resilient oilseeds cultivars. Oilseeds are crucial for human and animal nutrition and cater to diverse industrial applications. Besides oil content, the oilseed meal possesses proteins and a higher proportion of essential amino acids, which benefit human well-being. Additionally, the contribution of oilseeds towards renewable energy mitigates the risk of climate change by reducing carbon footprint. Hence, it is imperative to enhance oilseeds production from the current 178 to 282 million tons by 2050 to meet the demands of both the population and the environment. The current genomics era delivered various genomic resources in oilseed crops, which resulted in the discovery of genes for several agronomic and stress-resilience traits and resistance to pests and diseases. Further, the availability of next-generation plant breeding tools, such as genomic selection, genome editing, and speed breeding, are being implemented along with traditional and marked assisted selection. Thus, the book is framed to compile the importance and utility of next-generation breeding tools for enhancing stress resilience in oilseed crops in the climate change era. The book is exciting and valuable to national and international agricultural scientists, scholars and graduate students associated with oilseed crops improvement in specific and field crops in generic. The book also serves as reference in formulating various oilseed improvement programs for policymakers and research grant managers.
Genetically engineered (GE) crops were first introduced commercially in the 1990s. After two decades of production, some groups and individuals remain critical of the technology based on their concerns about possible adverse effects on human health, the environment, and ethical considerations. At the same time, others are concerned that the technology is not reaching its potential to improve human health and the environment because of stringent regulations and reduced public funding to develop products offering more benefits to society. While the debate about these and other questions related to the genetic engineering techniques of the first 20 years goes on, emerging genetic-engineering technologies are adding new complexities to the conversation. Genetically Engineered Crops builds on previous related Academies reports published between 1987 and 2010 by undertaking a retrospective examination of the purported positive and adverse effects of GE crops and to anticipate what emerging genetic-engineering technologies hold for the future. This report indicates where there are uncertainties about the economic, agronomic, health, safety, or other impacts of GE crops and food, and makes recommendations to fill gaps in safety assessments, increase regulatory clarity, and improve innovations in and access to GE technology.
Speed breeding systems for sustainable food production offer a promising solution to address food security and environmental sustainability. Speed breeding technologies allow accelerating generation of new plant varieties with desired traits in a short period. These systems include genetic selection, vertical hydroponics and data-driven smart sensor applications. Quick generation of plant varieties is achieved by manipulating photoperiods of a native plant with extended light periods in a controlled environment to fasten the crop cycle. This allows for multiple plant generations to be grown and harvested in a single year rather than the typical one to two generations in traditional field-based breeding. The application of molecular markers in the analysis of crop genomes enables the identification and characterization of genetic variation within a crop species. This, in turn, helps breeders in identifying and selecting plants with desirable traits, such as resistance to pests or diseases, or improved yield. Marker-assisted selection (MAS) and genomic selection (GS) are two recent methods that revolutionized plant breeding to improve the efficiency and accuracy of selecting desirable traits. MAS allows breeders to identify desirable traits earlier in the breeding process, without having to wait for the traits to be phenotypically expressed. On the other hand, GS allows breeders to predict the performance of a plant before it is even grown and can help speed up the breeding process by allowing breeders to select plants with desirable traits much earlier in the breeding process.
This volume will be the only existing single-authored book offering a science-based breeder’s manual directed at breeding for water-limited environments. Plant breeding is characterized by the need to integrate information from diverse disciplines towards the development and delivery of a product defines as a new cultivar. Conventional breeding draws information from disciplines such as genetics, plant physiology, plant pathology, entomology, food technology and statistics. Plant breeding for water-limited environments and the development of drought resistant crop cultivars is considered as one of the more difficult areas in plant breeding while at the same time it is becoming a very pressing issue. This volume is unique and timely in that it develops realistic solutions and protocols towards the breeding of drought resistant cultivars by integrating knowledge from environmental science, plant physiology, genetics and molecular biology.
Understand the impact of climate change on plant growth with this timely introduction Climate change has had unprecedented consequences for plant metabolism and plant growth. In botany, adverse effects of this kind are called plant stress conditions; in recent years, the plant stress conditions generated by climate change have been the subject of considerable study. Plants have exhibited increased photosynthesis, increased water requirements, and more. There is an urgent need to understand and address these changes as we adapt to drastic changes in the global climate. Global Climate Change and Plant Stress Management presents a comprehensive guide to the effects of global climate change on plants and plant metabolism. It introduces and describes each climate change-related condition and its components, offering a detailed analysis of the resulting stress conditions, the environmental factors which ameliorate or exacerbate them, and possible solutions. The result is a thorough, rigorous introduction to this critical subject for the future of our biome. Readers will also find: Analysis of global climate change impact on various agricultural practices Socio-economic consequences of climate change and plant stress conditions, and possible solutions Strategies for sustainable agriculture Global Climate Change and Plant Stress Management is essential for researchers, scientists, and industry professionals working in the life sciences, as well as for advanced graduate students.
Crops experience an assortment of environmental stresses which include abiotic viz., drought, water logging, salinity, extremes of temperature, high variability in radiation, subtle but perceptible changes in atmospheric gases and biotic viz., insects, birds, other pests, weeds, pathogens (viruses and other microbes). The ability to tolerate or adapt and overwinter by effectively countering these stresses is a very multifaceted phenomenon. In addition, the inability to do so which renders the crops susceptible is again the result of various exogenous and endogenous interactions in the ecosystem. Both biotic and abiotic stresses occur at various stages of plant development and frequently more than one stress concurrently affects the crop. Stresses result in both universal and definite effects on plant growth and development. One of the imposing tasks for the crop researchers globally is to distinguish and to diminish effects of these stress factors on the performance of crop plants, especially with respect to yield and quality of harvested products. This is of special significance in view of the impending climate change, with complex consequences for economically profitable and ecologically and environmentally sound global agriculture. The challenge at the hands of the crop scientist in such a scenario is to promote a competitive and multifunctional agriculture, leading to the production of highly nourishing, healthy and secure food and animal feed as well as raw materials for a wide variety of industrial applications. In order to successfully meet this challenge researchers have to understand the various aspects of these stresses in view of the current development from molecules to ecosystems. The book will focus on broad research areas in relation to these stresses which are in the forefront in contemporary crop stress research.
This publication demonstrates the benefits of neglected and underutilized species, including amaranth, sorghum and cowpea, and their potential contribution to achieving Zero Hunger in South and Southeast Asia.
Cover crops slow erosion, improve soil, smother weeds, enhance nutrient and moisture availability, help control many pests and bring a host of other benefits to your farm. At the same time, they can reduce costs, increase profits and even create new sources of income. You¿ll reap dividends on your cover crop investments for years, since their benefits accumulate over the long term. This book will help you find which ones are right for you. Captures farmer and other research results from the past ten years. The authors verified the info. from the 2nd ed., added new results and updated farmer profiles and research data, and added 2 chap. Includes maps and charts, detailed narratives about individual cover crop species, and chap. about aspects of cover cropping.