05785nam 2201585z- 450 991055767200332120231214133338.0(CKB)5400000000044785(oapen)https://directory.doabooks.org/handle/20.500.12854/69169(EXLCZ)99540000000004478520202105d2020 |y 0engurmn|---annantxtrdacontentcrdamediacrrdacarrierMolecular Research in RiceAgronomically Important TraitsBasel, SwitzerlandMDPI - Multidisciplinary Digital Publishing Institute20201 electronic resource (378 p.)3-03943-238-9 3-03943-239-7 This volume presents recent research achievements concerning the molecular genetic basis of agronomic traits in rice. Rice (Oryza sativa L.) is the most important food crop in the world, being a staple food for more than half of the world’s population. Recent improvements in living standards have increased the worldwide demand for high-yielding and high-quality rice cultivars. To achieve improved agricultural performance in rice, while overcoming the challenges presented by climate change, it is essential to understand the molecular basis of agronomically important traits. Recently developed techniques in molecular biology, especially in genomics and other related omics fields, can reveal the complex molecular mechanisms involved in the control of agronomic traits. As rice was the first crop genome to be sequenced, in 2004, molecular research tools for rice are well-established, and further molecular studies will enable the development of novel rice cultivars with superior agronomic performance.Molecular Research in Rice Research & information: generalbicsscBiology, life sciencesbicsscTechnology, engineering, agriculturebicsscchloroplast RNA splicing and ribosome maturation (CRM) domainintron splicingchloroplast developmentricerice (Oryza sativa L.), grain size and weightInsertion/Deletion (InDel) markersmulti-gene allele contributionsgenetic variationrice germplasmdisease resistancemicrobe-associated molecular pattern (MAMP)Pyricularia oryzae (formerly Magnaporthe oryzae)Oryza sativa (rice)receptor-like cytoplasmic kinase (RLCK)reactive oxygen species (ROS)salinityosmotic stresscombined stressGABAphenolic metabolismCIPKs genesshoot apical meristemtranscriptomic analysisco-expression networktillernitrogen raterice (Oryza sativa L.)quantitative trait locusgrain protein contentsingle nucleotide polymorphismresidual heterozygoterice (Oryza sativa)specific length amplified fragment sequencingKjeldahl nitrogen determinationnear infrared reflectance spectroscopyheterosisyield componentshigh-throughput sequenceFW2.2-like genetiller numbergrain yieldCRISPR/Cas9genome editingoff-target effectheat stresstranscriptomeantheranthesispyramidingbacterial blightmarker-assisted selectionforeground selectionbackground selectionjaponica ricecold stressgerminabilityhigh-density linkage mapQTLsseed dormancyABAseed germinationchromosome segment substitution lineslinkage mappingOryza sativa L.chilling stresschlorophyll biosynthesischloroplast biogenesisepidermal characteristicsAAA-ATPasesalicylic acidfatty acidMagnaporthe oryzaeleaf senescencequantitative trait locitranscriptome analysisgeneticepigeneticglobal methylationtransgenicphenotypeOsNAR2.1dwarfismOsCYP96B4metabolomicsNMRqRT-PCRbHLH transcription factorlamina jointleaf anglelong grainbrassinosteroid signalingblast diseasepartial resistancepi21haplotypehigh night temperaturewet seasondry seasonResearch & information: generalBiology, life sciencesTechnology, engineering, agricultureHori Kiyosumiedt1295504Shenton MatthewedtHori KiyosumiothShenton MatthewothBOOK9910557672003321Molecular Research in Rice3023548UNINA