Molecular identification of a major quantitative trait locus, qLTG3-1, controlling low-temperature germinability in rice.
about
The Nipponbare genome and the next-generation of rice genomics research in JapanRice and cold stress: methods for its evaluation and summary of cold tolerance-related quantitative trait lociFine definition of the pedigree haplotypes of closely related rice cultivars by means of genome-wide discovery of single-nucleotide polymorphismsAssessment of Five Chilling Tolerance Traits and GWAS Mapping in Rice Using the USDA Mini-Core Collection.Molecular cloning of Sdr4, a regulator involved in seed dormancy and domestication of rice.Detection of quantitative trait loci controlling pre-harvest sprouting resistance by using backcrossed populations of japonica rice cultivars.Diversification of the plant-specific hybrid glycine-rich protein (HyGRP) genes in cerealsQuantitative trait loci analysis for rice seed vigor during the germination stage.Colinearity and similar expression pattern of rice DREB1s reveal their functional conservation in the cold-responsive pathway.Combining association mapping and transcriptomics identify HD2B histone deacetylase as a genetic factor associated with seed dormancy in Arabidopsis thaliana.Genotyping of endosperms to determine seed dormancy genes regulating germination through embryonic, endospermic, or maternal tissues in riceGenetic analysis of cold tolerance at the germination and booting stages in rice by association mappingLoss of floral repressor function adapts rice to higher latitudes in EuropeDynamic quantitative trait locus analysis of seed vigor at three maturity stages in riceNew insights into the genetic basis of natural chilling and cold shock tolerance in rice by genome-wide association analysis.Transcriptome profiling and validation of gene based single nucleotide polymorphisms (SNPs) in sorghum genotypes with contrasting responses to cold stressIdentification and Fine Mapping of a Stably Expressed QTL for Cold Tolerance at the Booting Stage Using an Interconnected Breeding Population in Rice.Shared Genomic Regions Between Derivatives of a Large Segregating Population of Maize Identified Using Bulked Segregant Analysis Sequencing and Traditional Linkage Analysis.Overexpression of cold-inducible wheat galactinol synthase confers tolerance to chilling stress in transgenic rice.Genome-wide association mapping focusing on a rice population derived from rice breeding programs in a regionMapping QTLs for cold tolerance at germination and the early seedling stage in rice (Oryza sativa L.).Variation in heading date conceals quantitative trait loci for other traits of importance in breeding selection of rice.Towards the understanding of complex traits in rice: substantially or superficially?Genome-wide Association Mapping of Cold Tolerance Genes at the Seedling Stage in RiceWhat has natural variation taught us about plant development, physiology, and adaptation?Natural variation in CTB4a enhances rice adaptation to cold habitatsMolecular mechanisms of seed dormancy.Early seedling vigour, an imperative trait for direct-seeded rice: an overview on physio-morphological parameters and molecular markers.Genome wide association analysis of cold tolerance at germination in temperate japonica rice (Oryza sativa L.) varieties.Proteomic approach to address low seed germination in Cyclobalnopsis gilva.Breeding approaches and genomics technologies to increase crop yield under low-temperature stress.Genetic shift in local rice populations during rice breeding programs in the northern limit of rice cultivation in the world.Rice LTG1 is involved in adaptive growth and fitness under low ambient temperature.Mapping QTL for Seed Germinability under Low Temperature Using a New High-Density Genetic Map of Rice.Improvement of seed shattering and dormancy in Oryza sativa L. 'Hokuriku 193' based on genetic information.Genetic analysis for rice seedling vigor and fine mapping of a major QTL qSSL1b for seedling shoot length.New Genetic Loci Associated with Preharvest Sprouting and Its Evaluation Based on the Model Equation in Rice.Dynamic quantitative trait loci analysis of seed reserve utilization during three germination stages in rice.Natural variation reveals that OsSAP16 controls low-temperature germination in rice.QTL Mapping in Three Connected Populations Reveals a Set of Consensus Genomic Regions for Low Temperature Germination Ability in Zea mays L.
P2860
Q26742016-417A8465-20C7-4878-B4B1-0A6C843263CFQ26866411-3378C0F2-027D-43D7-980C-AD48C09E04FDQ33566193-99AB6150-5040-445B-B8F6-CCAC98153EBAQ33776079-CD69EB0F-8047-48E9-9BD1-D57C1CCAFF0AQ33778334-8F26C89E-56A0-49FF-BEBC-FB6C22CB48B9Q33808748-837D3DFD-E258-4FD8-BE40-E0D30C94539EQ34239368-7D347EFB-8F5B-41F3-957F-72F264335DB5Q34381949-F0C6D65B-728A-4B5D-85EB-E3C9A7A855C9Q34450698-189A43C3-5765-4637-A41F-9B8E22523313Q34610036-7C1608B5-7961-4939-83F8-A449F2CA3E41Q35061921-504BFFC9-485F-4EC8-ACEF-299CCA5EA0E8Q35195685-CA1312A2-1C07-49A5-9108-4302D340C49FQ35230157-BCFBE4E8-DCD5-4F48-AEF9-224696058A7FQ35533311-79DC64EA-DDB6-49AA-9809-1A3560328DD7Q35779550-792449F2-A8C6-49B0-8B1A-4490A75EA54BQ35863282-39963012-01BB-4A87-B113-A685C12587D3Q35880568-6102A33E-C157-4411-8176-90F62E3A3E28Q35926385-4FC7C371-F03A-492C-8306-FEC3CCD55572Q36352004-EF35200F-6F8A-41F9-B3BB-3DF1248188C7Q36352033-987AA098-15A1-4EE1-8BD6-E94EB1426EE6Q36384237-7D223B46-9F7D-4257-A8F3-14E1C08EFD96Q36410905-AEEE9F13-4F3B-493F-8A25-2139BC40A20CQ37225927-BB96094A-04C9-447F-B942-EC60A73481D5Q37415913-AC9548B4-DEB1-4938-8F57-CE64E1033588Q37539483-C560AAF7-B1E4-4DAC-A658-63627B82A7B1Q37733823-3BD3BF05-5CFA-4CD3-9E7D-472643BC2CACQ38012481-CF111A2A-9FAC-4703-999A-73D256BA01DDQ38389643-EFA5BDFE-3DAD-4747-A4D6-CDFA97670BFCQ38619827-CD5AA0AA-9A79-4D0A-839C-28D8CD90CF77Q38670975-480ABA33-3793-4D51-82D3-ED1D699623CBQ38791768-538953C9-9947-4B77-88B0-13DDF9A3E45BQ39013651-DFACC6D0-0075-4311-96F8-DBEEE1170728Q39191830-C3DD87DF-C929-44FD-8201-15302AF6C3BDQ40986575-FD6F1DCB-5EE3-4709-96C6-3A3343505C37Q41046885-9AAEC273-6C01-4A27-AF90-81767E403BC9Q41046975-1F0D6749-7B3F-4A7D-B839-C36553D51465Q41333683-9497A837-C3A6-486D-A10C-788EBCE18AFDQ42913148-5521DC80-E724-4F33-8334-EA714061F28AQ47297421-285E6410-E6EE-4E1A-97EF-7E92ED6CB031Q49310417-9B2A3887-ECA8-41A5-A4F1-900D810013F1
P2860
Molecular identification of a major quantitative trait locus, qLTG3-1, controlling low-temperature germinability in rice.
description
2008 nî lūn-bûn
@nan
2008年の論文
@ja
2008年論文
@yue
2008年論文
@zh-hant
2008年論文
@zh-hk
2008年論文
@zh-mo
2008年論文
@zh-tw
2008年论文
@wuu
2008年论文
@zh
2008年论文
@zh-cn
name
Molecular identification of a ...... erature germinability in rice.
@en
type
label
Molecular identification of a ...... erature germinability in rice.
@en
prefLabel
Molecular identification of a ...... erature germinability in rice.
@en
P2093
P2860
P356
P1476
Molecular identification of a ...... erature germinability in rice.
@en
P2093
Hiroshi Sekiguchi
Kazuhiko Sugimoto
Kazuko Ono
Masahiro Yano
Yasuyuki Matsuda
P2860
P304
12623-12628
P356
10.1073/PNAS.0805303105
P407
P50
P577
2008-08-21T00:00:00Z