Reprint
Molecular Genetics and Plant Breeding 2.0
Edited by
July 2024
538 pages
- ISBN978-3-7258-1498-5 (Hardback)
- ISBN978-3-7258-1497-8 (PDF)
https://doi.org/10.3390/books978-3-7258-1497-8 (registering)
This book is a reprint of the Special Issue Molecular Genetics and Plant Breeding 2.0 that was published in
Biology & Life Sciences
Chemistry & Materials Science
Medicine & Pharmacology
Summary
Global food production is in jeopardy as potential yields are reaching saturation and biotic and abiotic pressures proliferate both spatially and temporally, unable to keep pace with population growth. In order to address the climate crisis and the loss of agrobiodiversity while ensuring sustainable food security, it has become essential to mobilize trans-disciplinary enterprises that promote integrative agendas amongst the otherwise fragmented fields of molecular genetics, plant breeding, genetic conservation, physiology, ecology, seed delivery, and food policy.
Format
- Hardback
License and Copyright
© 2024 by the authors; CC BY-NC-ND license
Keywords
QTL mapping; spike-layer uniformity; kompetitive allele-specific PCR marker; yield traits; recombinant inbred lines; wheat; pitaya; genome-wide analysis; NAC gene family; cold stress; genetic transformation; Kompetitive Allele-Specific PCR; soybean; pod shattering tolerance; single nucleotide polymorphism; insertion/deletion; candidate gene; molecular marker; comparative study; cytosolic starch phosphorylase; plastidial starch phosphorylase; starch phosphorylase; Brassica napus; NRT2; gene family; evolution; nitrate; expression profile; microspore culture; DNA methylation; small RNA; differentially expressed genes; M. × piperita L.; M. spicata; RNA-Seq; comparative transcriptomics; crop biodiversity; heat stress; PIF4; thermotolerance; HSFA2; wheat; E3 ligases; Ariadne (ARI) proteins; ubiquitination; AtARI8; phylogenetic analysis; association mapping analysis; agronomic traits; B. napus; low-temperature; seed germination; Cheongcheong Nagdong double haploid; quantitative trait locus; viviparous germination; marker-assisted breeding; Glycine max; virus-induced gene silencing (VIGS); receptor-like kinases; immune responses; BIR1; salicylic acid; breeding; seed storage proteins; mRNA secondary structure; microRNA; processing quality; Myrothamnus flabellifolia; drought tolerance; salinity tolerance; WRKY; zinc finger; ABA; transcription factor; EAR motif-containing protein; AtEAUs; Arabidopsis; MYB transcription factors; plant roots; development; biotic and abiotic stresses; miR393; target gene; plant development; stress response; auxin; BRV infection; biotic stress; blackcurrant; defense response; RNA-Seq; de novo transcriptome; Plukenetia volubilis; transcriptome; proteomics; ribosome-inactivating proteins; physicochemical property; expression pattern; Capsicum annuum; pepper; RNA sequencing; virome; virus; wheat quality; agronomic trait; mutation; breeding; soybean; drought; RIL; resequencing; QTLs; artificial intelligence (AI); crop breeding; genomics; phenomics; envirotyping; big data; rice (Oryza sativa L.); sorghum (Sorghum bicolor (L.) Moench); distant species; genome; heat tolerance; new germplasm; sorghum (Sorghum bicolor L.); SbDof21; starch biosynthesis; transcriptional regulation; carotenoid; BrGOLDEN; Brassica rapa; spatiotemporal expression; Y2H; genome-wide association study; wheat hybrid breeding; trihelix; transcription factor; brassica; evolution; abiotic stress; drought; γ-TMT; α-tocopherol; fatty acids; seed germination; salt stress; soybean mosaic virus; genome; evolution; phylogeny; diversity; clubroot disease; Plasmodiophora brassicae; R gene; sesame; genome resequencing; lignan; genomic signatures; NST1; GWAS; n/a