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Chickpea is an important protein-rich crop with considerable diversity present among 44 annual Cicer species. A large collection of chickpea germplasm including wild Cicer species has been conserved in different gene banks globally. However, the effective and efficient utilization of these resources is required to develop new cultivars with a broad genetic base. Using core and mini-core collections, chickpea researchers have identified diverse germplasm possessing various beneficial traits that are now being used in chickpea breeding. Further, for chickpea improvement, the genus Cicer harbours alleles/genes for tolerance/resistance to various abiotic and biotic stresses as well as for agronomic and nutrition-related traits. Recent advances in plant biotechnology have resulted in developing large number of markers specific to chickpea in addition to technological breakthrough in developing high-throughput genotyping platforms for unlocking the genetic potential available in germplasm collections.
This anchor volume to the series Managing Global Genetic Resources examines the structure that underlies efforts to preserve genetic material, including the worldwide network of genetic collections; the role of biotechnology; and a host of issues that surround management and use. Among the topics explored are in situ versus ex situ conservation, management of very large collections of genetic material, problems of quarantine, the controversy over ownership or copyright of genetic material, and more.
Genetic diversity is the key to crop improvement and food security. There are more than 1500 gene banks around the world, and genetic resources are maintained in nature reserves and on farms. Genetic diversity serves as the starting point for breeding crops with improved nutritional quality, higher yields, and better tolerance to abiotic and biotic stresses. However, genetic diversity also provides opportunities for diversifying farm and food systems. Utilization depends on access to material and information. However, many gene banks experience backlogs in characterization, evaluation, regeneration, viability tests, plant health monitoring, and information sharing. This research topic focuses on advances in plant genetic resource conservation and utilization.
As per the reports of FAO, the human population will rise to 9 billion by the end of 2050 and 70% of more food must be produced over the next three decades to feed the additional population. The breeding approaches for crop improvement programs are dependent on the availability and accessibility of genetic variation, either spontaneous or induced by the mutagens. Plant breeders, agronomists, and geneticists are under constant pressure to expand food production by employing innovative breeding strategies to enhance yield, adaptability, nutrition, resistance to biotic and abiotic stresses. In conventional breeding approaches, introgression of genes in crop varieties is laborious and time-consuming. Nowadays, new innovative plant breeding techniques such as molecular breeding and plant biotechnology, supplement the traditional breeding approaches to achieve the desired goals of enhanced food production. With the advent of recent molecular tools like genomics, transgenics, molecular marker-assisted back-crossing, TILLING, Eco-TILLING, gene editing, CRISPR CAS, non-targeted protein abundant comparative proteomics, genome wide association studies have made possible mapping of important QTLs, insertion of transgenes, reduction of linkage drags, and manipulation of genome. In general, conventional and modern plant breeding approaches would be strategically ideal for developing new elite crop varieties to meet the feeding requirement of the increasing world population. This book highlights the latest progress in the field of plant breeding, and their applicability in crop improvement. The basic concept of this 2-volume work is to assess the use of modern breeding strategies in supplementing the conventional breeding toward the development of elite crop varieties, for obtaining desired goals of food production.
Genetic and Genomic Resources For Cereals Improvement is the first book to bring together the latest available genetic resources and genomics to facilitate the identification of specific germplasm, trait mapping, and allele mining that are needed to more effectively develop biotic and abiotic-stress-resistant grains. As grain cereals, including rice, wheat, maize, barley, sorghum, and millets constitute the bulk of global diets, both of vegetarian and non-vegetarian, there is a greater need for further genetic improvement, breeding, and plant genetic resources to secure the future food supply. This book is an invaluable resource for researchers, crop biologists, and students working with crop development and the changes in environmental climate that have had significant impact on crop production. It includes the latest information on tactics that ensure that environmentally robust genes and crops resilient to climate change are identified and preserved. Provides a single-volume resource on the global research work on grain cereals genetics and genomics Presents information for effectively managing and utilizing the genetic resources of this core food supply source Includes coverage of rice, wheat, maize, barley, sorghum, and pearl, finger and foxtail millets
Genetic resources of vegetable crops in Poland; ERGE: A microcumputer program for genetic resources of cereals database management; The Center for genetic resources, the Netherlands (CGN); Multivariate analysis of variation among hops (Humulus lupulus L.) accessions; Avena germplasm, its collection, use and distribution; Grain legume crops - present situation and possibilities of germplasm conservation in Yugoslavia; International wheat database; Studies on genetic shift in rye seeds after long term storage in seed bank; The Czechoslovak programme on plant genetic resources of cultivated plants; The Netherlands, a leader in horticultural seeds; The historical development of international collaboration in plant genetic resources; Actual and future concepts for collaboration in crop genetic resources; In situ conservation at the interface between crop genetic resources and nature conservation; Intellectual property protection and genetic resources; Central crop detabases in collaborative genetic resources management; The core collection concept; The role of the Commission of the European Communities in germplasm conservation; The role of ICARDA in genetic resources conservation; The CGIAR collaborative system on plant genetic resources; The VIR network: problems of mobilization and conservation of plant genetic resources; the concept of international collaboration; The NGB system; Plant genetic resources conservation programme in Poland, a multi-institucional collabotration.
The 6th session of the FAO Commission on Plant Genetic Resources requested that IPGRI study the feasibility of possible systems for the exchange of plant genetic resources for food and agriculture (PGRFA)1 and the equitable sharing of benefits. The following report is the result of that study. It seeks to provide the Commission with a set of options and their implications and thus to inform international negotiationsconncerning the revision of the International Undertaking on Plant Genetic Tesources. As part of the study process a wide series of consultations was held with major stakeholder groups. A fundamental justification for conserving and characterizing PGRFA is their potential for use in the development of improved crop varieties. These improved varieties are necessary to meet the food needs of a growing population and the demands of changing agro-ecological and social conditions.