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This volume looks at the latest techniques used by researchers to help them understand the biology of various cellular processes and agronomic traits, and come up with better strategies to improve legume crops. The chapters in this book cover topics such as legume genomic resources; legume pangenome and organelle genome construction; transcriptome analysis; DNA methylation analysis; double-digest restriction site-associated DNA sequencing; target enrichment sequencing via probe capture; genomic selection and transformation methods; prediction of long non-coding RNAs and secondary structures; genome-wide mining of disease resistance gene analogs; genome editing, and bioactive compound and phosphoproteome analysis. Written in the highly successful Methods in Molecular Biology series format, chapters include introductions to their respective topics, lists of the necessary materials and reagents, step-by-step, readily reproducible laboratory protocols, and tips on troubleshooting and avoiding known pitfalls. Cutting-edge and informative, Legume Genomics: Methods and Protocols is a useful reference for genomicists, molecular breeders, plant molecular biologists, biotechnologists, computational biologists, and developmental biologists. This book is also an excellent resource for any novice and expert researcher involved in various molecular aspects of legume biology or general plant studies.
Botany. --- Plant genetics. --- Plant Science. --- Plant Genetics. --- Plants --- Genetics --- Botanical science --- Floristic botany --- Phytobiology --- Phytography --- Phytology --- Plant biology --- Plant science --- Biology --- Natural history
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Abiotic stresses are the major cause that limits productivity of crop plants worldwide. Plants have developed intricate machinery to respond and adapt over these adverse environmental conditions both at physiological and molecular levels. Due to increasing problems of abiotic stresses, plant biotechnologists and breeders need to employ new approaches to improve abiotic stress tolerance in crop plants. Although current research has divulged several key genes, gene regulatory networks and quantitative trait loci that mediate plant responses to various abiotic stresses, the comprehensive understanding of this complex trait is still not available. This topic is focused on molecular genetics and genomics approaches to understand the plant response/adaptation to various abiotic stresses. We welcome all types of articles (original research, method, opinion and review) that provide new insights into different aspects of plant responses and adaptation to abiotic stresses. Articles describing genome analysis to identify key candidate genes, regulatory network analysis, epigenetic regulation, discovery of novel genetic variations, QTL identification using linkage mapping and association mapping approaches, genetic engineering, molecular breeding and novel approaches for understanding and manipulation of abiotic stress response, are welcome.
Molecular genetics. --- Plants, Cultivated --- Botany --- Botany, Economic. --- Crops, Agricultural --- Genetics. --- Molecular aspects. --- microbiology. --- molecular genetics --- signal transduction --- transcriptional regulatory network --- functional genomics --- virus-induced gene silencing --- abiotic stress
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Abiotic stresses are the major cause that limits productivity of crop plants worldwide. Plants have developed intricate machinery to respond and adapt over these adverse environmental conditions both at physiological and molecular levels. Due to increasing problems of abiotic stresses, plant biotechnologists and breeders need to employ new approaches to improve abiotic stress tolerance in crop plants. Although current research has divulged several key genes, gene regulatory networks and quantitative trait loci that mediate plant responses to various abiotic stresses, the comprehensive understanding of this complex trait is still not available. This topic is focused on molecular genetics and genomics approaches to understand the plant response/adaptation to various abiotic stresses. We welcome all types of articles (original research, method, opinion and review) that provide new insights into different aspects of plant responses and adaptation to abiotic stresses. Articles describing genome analysis to identify key candidate genes, regulatory network analysis, epigenetic regulation, discovery of novel genetic variations, QTL identification using linkage mapping and association mapping approaches, genetic engineering, molecular breeding and novel approaches for understanding and manipulation of abiotic stress response, are welcome.
Molecular genetics. --- Plants, Cultivated --- Botany --- Botany, Economic. --- Crops, Agricultural --- Genetics. --- Molecular aspects. --- microbiology. --- molecular genetics --- signal transduction --- transcriptional regulatory network --- functional genomics --- virus-induced gene silencing --- abiotic stress
Choose an application
Abiotic stresses are the major cause that limits productivity of crop plants worldwide. Plants have developed intricate machinery to respond and adapt over these adverse environmental conditions both at physiological and molecular levels. Due to increasing problems of abiotic stresses, plant biotechnologists and breeders need to employ new approaches to improve abiotic stress tolerance in crop plants. Although current research has divulged several key genes, gene regulatory networks and quantitative trait loci that mediate plant responses to various abiotic stresses, the comprehensive understanding of this complex trait is still not available. This topic is focused on molecular genetics and genomics approaches to understand the plant response/adaptation to various abiotic stresses. We welcome all types of articles (original research, method, opinion and review) that provide new insights into different aspects of plant responses and adaptation to abiotic stresses. Articles describing genome analysis to identify key candidate genes, regulatory network analysis, epigenetic regulation, discovery of novel genetic variations, QTL identification using linkage mapping and association mapping approaches, genetic engineering, molecular breeding and novel approaches for understanding and manipulation of abiotic stress response, are welcome.
Molecular genetics. --- Plants, Cultivated --- Botany --- Botany, Economic. --- Crops, Agricultural --- molecular genetics --- signal transduction --- transcriptional regulatory network --- functional genomics --- virus-induced gene silencing --- abiotic stress --- Genetics. --- Molecular aspects. --- microbiology. --- molecular genetics --- signal transduction --- transcriptional regulatory network --- functional genomics --- virus-induced gene silencing --- abiotic stress
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