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| Author | : Margarita Mauro Herrera |
| Publisher | : |
| Total Pages | : 302 |
| Release | : 2003 |
| Genre | : |
| ISBN | : |
| Author | : Paul Gepts |
| Publisher | : Springer Science & Business Media |
| Total Pages | : 609 |
| Release | : 2012-12-06 |
| Genre | : Science |
| ISBN | : 940092786X |
The period following the second world war has witnessed an expanding commitment to incr~ased food production in tropical countries. Public and private initiatives at the national and international levels have led to the creation of programs geared specifically towards the improvement of food crops in tropical conditions. Examples of this increased commitment are the network of international agricultural research centers and numerous bilateral aid projects. As a consequence, crop improvement has become a truly worldwide endeavor, relying on an international network of institutions and collaborators. This holds also for Phaseolus beans. Following the discovery of the Americas, Phaseolus beans became distributed on all six continents. Yet, until not so long ago, most of the research on Phaseolus improvement took place in developed countries. In recognition of the nutritional importance of Phaseolus beans in developing countries, this has changed considerably in the last years, principally perhaps through the activities of the Centro Internacional de Agricultura Tropical (CIAT) and the International Board for Plant Genetic Resources (IBPGR). Consequently, the scope of the research on Phaseolus has broadened considerably and the number of Phaseolus researchers is larger than ever before.
| Author | : S.P. Singh |
| Publisher | : Springer Science & Business Media |
| Total Pages | : 413 |
| Release | : 2013-11-09 |
| Genre | : Science |
| ISBN | : 940159211X |
The common bean (Phaseolus vulgaris L. ) is the most important pulse crop in the world. It is an important source of calories, proteins, dietary fibers, minerals, and vitamins for millions of people in both developing and developed countries worldwide. It complements cereals and other carbohydrate-rich foods in providing near-perfect nutrition to people of all ages. Moreover, a regular intake ofbeans helps lower cholesterol and cancer risks. Despite the fact that per capita consumption of common bean in some developed countries (e. g. , the U. S. A. ) has been increasing over the last several years, in general, the average global per capita consumption is declining because production is unable to keep up with the population growth. Moreover, increasing demand for pesticide-free food products, concern for natural resources conservation, and the need to reduce production costs offer daunting challenges to the twenty-first century policy makers, bean growers, and researchers alike. High yielding, high quality bean cultivars that require less water, fertilizers, pesticides, and manual labor combined with integrated management of abiotic and biotic stresses will have to be developed. Eminent bean researchers were invited to contemplate these issues, prepare a state-of-the-art account on most relevant topics, and offer their insight into research directions into the twenty-first century. Four excellent books have been published covering various aspects ofthe common bean since 1980. These books are: I) Bean Production Problems nd in the Tropics (l SI ed. 1980, 2 ed. 1989), H. F. Schwartz & M. A.
| Author | : Tamara Iva Miller |
| Publisher | : |
| Total Pages | : |
| Release | : 2019 |
| Genre | : |
| ISBN | : 9781085732857 |
The common bean (Phaseolus vulgaris L.) is consumed by millions of people worldwide and is a staple source of protein, starch and micronutrients. Common bean production across the world is affected by abiotic and biotic stresses that limit the growth and yield of this important crop. Efforts to breed improved common bean for dissemination to farmers and consumers in East Africa is underway in several breeding programs worldwide. Improvement on agronomic and consumer traits such as disease resistance can be greatly aided by the application of next generation sequencing technologies. With the decreasing cost of DNA sequencing, genomic re-sequencing of diverse common bean accessions facilitates marker- assisted breeding that can be used to speed the creation of new common bean cultivars. Marker-assisted selection (MAS) is an important aspect of modern bean breeding that seeks to utilize genetic markers to select individuals with improved agronomic and consumer traits. For example, breeders in the African Bean Consortium seek to introgress known genetic loci conferring resistance to multiple diseases into bean genetic backgrounds with preferred seed and agronomic characteristics. However, the usefulness of markers is dependent on whether they are polymorphic in the specific parents of the breeding program. Often genetic markers identified in a specific plant population are not useful for marker assisted selection among a different set of bean parents, which necessitates identification of novel markers linked to the genes of interest that are polymorphic among breeding parents. One disease that greatly affects common bean production in humid tropical and sub-tropical growing regions is Angular Leaf Spot (ALS; caused by the foliar fungus Pseudocercospora griseola Sacc.). Marker assisted breeding is being used in multiple different bean breeding programs to improve the resistance of adapted cultivars to ALS. The ALS resistance locus, Phg-2, is an important resistance locus used to improve plant resistance to Angular Leaf Spot in South America and Pan Africa, however in the case of the African Bean Consortium breeding programs in East Africa, certain bean parents used for breeding were monomorphic for the original marker used to perform marker assisted selection of Phg-2. In order to facilitate marker assisted selection of Phg-2 in specific breeding parents used in the Uganda bean improvement program, an alternative, co-dominant, marker linked to the Phg-2 ALS resistance locus was developed (Chapter 1). A new marker, g796, was identified which is polymorphic among the breeding parents; its co-segregation was confirmed in a segregating F2 population derived from the cross between French bean variety Amy and the ALS resistance donor, Mexico 54. This work was conducted in collaboration with Stephen Kimno and Esther Arunga at Embu University, Kenya, as well as other members of the African Bean Consortium bean breeding programs in Tanzania, Uganda, and Ethiopia. The application of DNA sequencing to marker-assisted breeding and crop improvement is rapidly becoming common in the development of improved bean varieties. A nearly complete reference genome and transcriptome for Phaseolus vulgaris was released in 2014 and newly resequenced genomes of diverse bean accessions are being developed for the purpose of marker assisted breeding. In Chapter 2, whole-genome resequencing of 29 bean accessions, including accessions commonly used as breeding parents, was carried out in collaboration with the Ratz lab at the International Center for Tropical Agriculture (CIAT, Colombia). Genetic diversity analysis was performed in order to access the evolutionary relationships between the sequenced bean genomes. Data generated by this work was made available to the larger bean research community and will be used by breeders and geneticists to perform marker-assisted selection and genetic analysis in the future. Angular leaf spot (ALS) occurs throughout Eastern and Southern Africa (as well as other parts of the world) and can cause yield losses up to 80% in environments that favor the disease. ALS is caused by the fungal pathogen, Pseudocercospora griseola, a highly diverse pathogen with many different races that infect diverse types of bean hosts. Growing crop cultivars with genetic resistance to the disease is one of the most effective measures for farmers to reduce crop losses due to ALS. The landrace Mexico 54 is used as a donor for ALS resistance in East Africa and marker-assisted selection of the Phg-2 ALS resistance locus from Mexico 54 is underway in multiple breeding programs in order to increase the resistance of adapted bean germplasm in East Africa and Brazil. Previous allelism tests between different ALS resistance donors suggested additional resistance loci exist in Mexico 54 besides the Phg-2 locus and were named Phg-5 and Phg-6. The genomic locations of the proposed Phg-5 and Phg-6 resistance genes in Mexico 54 have never been investigated, however, the existence of multiple resistance loci in Mexico 54 is likely the cause of its high level of resistance to ALS on multiple continents. In Chapter 3, a biparental mapping population consisting of 167 F8 recombinant inbred lines (RIL) was derived from a cross between Kablanketi, a preferred bean market type in Tanzania, and Mexico 54 in order to map additional quantitative trait loci that confer resistance to ALS in Mexico 54. The identification of novel ALS resistance loci will aid breeders to develop resistant cultivars as well as provide a greater understanding of the genetic diversity that influences resistance to ALS.
| Author | : Petr Smýkal |
| Publisher | : Frontiers Media SA |
| Total Pages | : 281 |
| Release | : 2020-12-02 |
| Genre | : Science |
| ISBN | : 2889661431 |
This eBook is a collection of articles from a Frontiers Research Topic. Frontiers Research Topics are very popular trademarks of the Frontiers Journals Series: they are collections of at least ten articles, all centered on a particular subject. With their unique mix of varied contributions from Original Research to Review Articles, Frontiers Research Topics unify the most influential researchers, the latest key findings and historical advances in a hot research area! Find out more on how to host your own Frontiers Research Topic or contribute to one as an author by contacting the Frontiers Editorial Office: frontiersin.org/about/contact.
| Author | : Epimaki Mennas Kimolo Koinange |
| Publisher | : |
| Total Pages | : 306 |
| Release | : 1992 |
| Genre | : |
| ISBN | : |
| Author | : Jorge Carlos Berny Mier y Teran |
| Publisher | : |
| Total Pages | : |
| Release | : 2018 |
| Genre | : |
| ISBN | : 9780355967524 |
Drought is the main constraint in common bean (Phaseolus vulgaris) production. Although breeding efforts to increase drought resistance have shown gains in productivity, their full potential remains untapped. Improvements have been limited by the complexity of the trait involved, limited germplasm recombination, and most importantly, the poorly understood genetic basis of tolerance. To gain information about the genetics and mechanism(s) of drought adaptation, I explored the genetic diversity of wild and domesticated Mesoamerican gene pool of the species through genetic analyses in natural, bi-parental, and multi-parental populations. In the first chapter, I evaluated root and shoot traits in a large panel of wild accessions and reference domesticated cultivars, both from the Mesoamerican distribution of common bean, in a greenhouse tube experiment. The domesticated beans were, in general, more vigorous and deeper-rooted than wild beans. Nevertheless, some wild beans were outstanding in their productivity and rooting capacity. A comparison of the measured phenotypic traits with the climatic and soil characteristics of the location of origin of the individual wild bean accessions showed that most traits were significantly associated with mean annual temperature and aridity. The most deeply rooted and productive accessions originated from the driest regions. Each wild accession was genotyped with both a SNP array and a GBS platform; three populations of wild bean accessions were identified, of which the most productive, deeply rooted, and more drought-tolerant population, originating from Central and North-West Mexico and Oaxaca. Through genome-wide association analyses, genomic regions associated with productivity, root depth, and drought adaptation were identified. Some co-located with regions showing signals of selection suggesting that drought stress is a driver of local adaptation in wild common beans.In the second chapter, I investigated the effects of drought stress on the genetic architecture of photosynthate allocation and remobilization in pods, one of the main mechanisms of drought resistance and overall productivity. A bi-parental recombinant inbred line (RIL) population of the Mesoamerican gene pool was evaluated in field conditions under well-watered conditions and terminal and intermittent drought stress in two years. There was a significant effect of the water regime and year on pod harvest index (PHI), a measure of the partition of seed biomass to pod biomass, its components, phenology and grain yield at the phenotypic and QTL level. QTLs for pod harvest index, including a major, stable QTL on chromosome Pv07 was detected. For grain yield, the QTLs were not stable; however, three were detected for the overall mean across environments. There was differential co-localization of the components of PHI, co-localizing mainly with either the pod wall, seed mass, or both. Three of the eight yield QTLs co-localized with PHI QTLs, underlying the importance of photosynthate remobilization in productivity. Epistasis explained a considerable part of the variation, especially for PHI and yield. In the third chapter, to further test the value of wild variation as compared with the domesticated forms, joint linkage mapping of nested populations was carried out in three newly develop domesticated by wild backcrossed recombinant inbred line populations. The populations were developed by crossing three wild accessions representing the extreme range of rainfall of the Mesoamerican wild bean distribution to an elite drought resistant domesticated parent. Grain yield was evaluated under field conditions in two fully irrigated trials in two seasons and a simulated terminal drought in the second season. The highest yielding populations were the populations from the lower part of the rainfall distribution. The populations were genotyped and a consensus map was developed containing 721 SNP markers. Twenty QTLs were found in 13 unique regions on eight chromosomes. At least one wild allele with a significant positive additive effect was found in five of these regions. The additive effects of all the QTLs ranged from -164 to 277 kg ha−1, with some evidence of allelic series. The variation explained by these QTLs ranged from 0.6 to 5.4 % of the total variation. These results underlie the potential of wild variation for bean crop improvement as well the identification of regions for efficient marker-assisted introgression and candidate genes.
| Author | : Paulo Cesar Izquierdo Romero |
| Publisher | : |
| Total Pages | : 0 |
| Release | : 2023 |
| Genre | : Electronic dissertations |
| ISBN | : |
Dry bean (Phaseolus vulgaris L.) is the most important legumes for human consumption worldwide and is an important source of protein, vitamins, and micronutrients in the human diet. This research aimed to i) uncover the genetic architecture of yield, Fe bioavailability and seed micronutrient concentration, ii) characterize the genetic control of canning quality traits, and ii) assess the accuracy of genomic prediction models for yield and end-use quality traits. The genetic architecture of yield and seed micronutrient concentration was assessed through a combination of meta-QTL analyses integrating published studies over the last two decades in dry bean. A Gaussian mixture model was used to determine the number of distinct QTL in the meta-QTL analyses. Consistent meta-QTL over different genetic backgrounds and environments were identified, reducing the confidence interval compared with initial QTL. Furthermore, a genome-wide association (GWA) study with 295 lines of the yellow bean collection and 82 yellow recombinant inbred lines identified a major QTL for Fe bioavailability related to the ground factor P gene. A black breeding panel with 415 lines was evaluated for yield and canning quality traits in two growing seasons. Consistent associations for color retention, appearance and texture of canned beans were identified across years. Genomic prediction models provided moderate to high accuracy for end-use quality traits on the yellow and black populations. The genomic prediction accuracy was related to the heritability of each trait, and improvement of accuracy was observed for complex traits when secondary traits were included in the model, while for traits with major QTL, the use of associated markers as fixed effects increased prediction ability. The use of meta-QTL analyses and GWA in this study lays a foundation of the genetic control of yield and end-use quality traits and reveals the potential of genomic prediction for these traits in dry beans.
| Author | : Rocío Campos Vega |
| Publisher | : |
| Total Pages | : 0 |
| Release | : 2018 |
| Genre | : Common bean |
| ISBN | : 9781536135466 |
The International Year of Pulses celebrated in 2016 magnified the public focus and consumer perception on human health, environmental aspects, crop production and novel product development benefits of pulses. The gluten-free and plant protein movements have also increased interest in pulse utilization. The common dry bean (Phaseolus vulgaris L.) among pulses is the most economically and widest ecologically adapted crop species used for food by large populations. Nowadays, dry beans top the list of pulse crops accounting on average for ~38 and 32% of global pulse growing area and production, respectively. Protein production from kidney beans requires about 18, 12, 10, 10 and 9 times less land, fertilizer, pesticide, water and fuel, respectively compared to producing the same amount of protein from beef.This book focuses on breeding aspects including new cultivars, production and post-harvest practices, and investigations that can lead to the development of high quality grain and functional foods, and nutraceutical products from beans. It also provides an overview of the crop management practices, technology progress and impacts favoring the best possible clean and sustainable crop production. Bean breeding is highlighted form the European perspective including the preservation/conservation of local gene pools. Bean production and quality improvement is a continuous process, particularly in major bean producing and consuming countries. The socioeconomic impact is considerable in countries where beans are traditionally part of the staple daily diet. However, application of novel technologies in improving nitrogen fixation, integrated disease management, and post-harvest storage ensures sustainable bean production and quality. The quality of bean types close to the site of its original domestication provides an outlook on their resilience and potential as a genetic resource and future food products. Current knowledge of bean health benefits, bioactive compounds, bioactive peptides and phenolics are important for development of novel functional foods. Beans can be used in many forms; as a natural coagulant, in metabolic disease prevention and other common bean-based food products, where their current market availability is explored. The multiple attributes of beans including cost, sustainability, commercial availability in varied forms and types ensure its extensive and expanding use in the development of healthy eating habits that can reduce healthcare and societal costs. This book should give plant scientists, nutritionists, health professionals, chemists and industry professionals interested in beans useful and up-to-date information to advance the field.
| Author | : Marcelino Pérez de la Vega |
| Publisher | : Springer |
| Total Pages | : 304 |
| Release | : 2017-12-20 |
| Genre | : Science |
| ISBN | : 3319635263 |
This book provides insights into the genetics and the latest advances in genomics research on the common bean, offering a timely overview of topics that are pertinent for future developments in legume genomics. The common bean (Phaseolus vulgaris L.) is the most important grain legume crop for food consumption worldwide, as well as a model for legume research, and the availability of the genome sequence has completely changed the paradigm of the ongoing research on the species. Key topics covered include the numerous genetic and genomic resources, available tools, the identified genes and quantitative trait locus (QTL) identified, and there is a particular emphasis on domestication. It is a valuable resource for students and researchers interested in the genetics and genomics of the common bean and legumes in general.
