Development of a core RFLP map in maize using an immortalized F2 population.
about
Molecular genetic maps in wild emmer wheat, Triticum dicoccoides: genome-wide coverage, massive negative interference, and putative quasi-linkageA high-density genetic recombination map of sequence-tagged sites for sorghum, as a framework for comparative structural and evolutionary genomics of tropical grains and grassesA maize map standard with sequenced core markers, grass genome reference points and 932 expressed sequence tagged sites (ESTs) in a 1736-locus map.A single molecule scaffold for the maize genome.MaizeGDB update: new tools, data and interface for the maize model organism databaseCharacterization of a maize chromosome 4 centromeric sequence: evidence for an evolutionary relationship with the B chromosome centromere.Characterization of three maize bacterial artificial chromosome libraries toward anchoring of the physical map to the genetic map using high-density bacterial artificial chromosome filter hybridization.Identification of candidate genes associated with cell wall digestibility and eQTL (expression quantitative trait loci) analysis in a Flint x Flint maize recombinant inbred line population.QTL Mapping for Yield and Resistance against Mediterranean Corn Borer in Maize.EST-derived SSR markers used as anchor loci for the construction of a consensus linkage map in ryegrass (Lolium spp.).Quantitative trait loci underlying gene product variation: a novel perspective for analyzing regulation of genome expression.Relationship between chromosome 9 of maize and wheat homeologous group 7 chromosomes.teosinte branched1 and the origin of maize: evidence for epistasis and the evolution of dominance.RFLP mapping in cultivated sugarcane (Saccharum spp.): genome organization in a highly polyploid and aneuploid interspecific hybridPhysical and genetic mapping of chromosome 9S in maize using mutations with terminal deficienciesThe type of ploidy of chrysanthemum is not black or white: a comparison of a molecular approach to published cytological methods.MaizeGDB becomes 'sequence-centric'Gene-based SNP discovery and genetic mapping in pea.Identification of maize genes associated with host plant resistance or susceptibility to Aspergillus flavus infection and aflatoxin accumulation.Development of an ultra-dense genetic map of the sunflower genome based on single-feature polymorphismsLinkage mapping of 1454 new maize candidate gene LociMaize adaptation to temperate climate: relationship between population structure and polymorphism in the Dwarf8 gene.Molecular mapping of segregation distortion loci in Aegilops tauschiiGenetic mechanisms underlying apimaysin and maysin synthesis and corn earworm antibiosis in maize (Zea mays L.).Multiple interval QTL mapping and searching for PSTOL1 homologs associated with root morphology, biomass accumulation and phosphorus content in maize seedlings under low-P.New insights into the genetics of in vivo induction of maternal haploids, the backbone of doubled haploid technology in maize.Identification of QTL for resistance to Mediterranean corn borer in a maize tropical line to improve temperate germplasm.Quantitative trait loci and metabolic pathways.Development of pachytene FISH maps for six maize chromosomes and their integration with other maize maps for insights into genome structure variation.Oat-maize chromosome addition lines: a new system for mapping the maize genomeEvidence for a common sex determination mechanism for pistil abortion in maize and in its wild relative Tripsacum.Advances in maize genomics and their value for enhancing genetic gains from breeding.Quantitative trait loci and metabolic pathways: genetic control of the concentration of maysin, a corn earworm resistance factor, in maize silks.The MITE family heartbreaker (Hbr): molecular markers in maize.Selinene Volatiles Are Essential Precursors for Maize Defense Promoting Fungal Pathogen Resistance.Molecular genetics of the maize (Zea mays L.) aspartate kinase-homoserine dehydrogenase gene family.The Miniature1 Seed Locus of Maize Encodes a Cell Wall Invertase Required for Normal Development of Endosperm and Maternal Cells in the Pedicel.B73-Mo17 near-isogenic lines demonstrate dispersed structural variation in maizeConstruction of genetic linkage map and identification of QTLs related to agronomic traits in maize using DNA transposon-based markersFine analysis of a genomic region involved in resistance to Mediterranean corn borer
P2860
Q24622899-6D251990-24BD-452C-8E84-D98F933ECDF2Q28768950-EA4A7427-5C69-401A-B171-E1A2D92E3CF0Q30725861-9A79D4DF-E24F-4688-B6B8-04DF88AAA545Q30912396-24594AAE-B92D-41A3-A44C-6F9978E0FB50Q31001094-0D186D79-A9DC-40F1-9EBF-383D35039172Q31010221-49D98D8D-55F0-413B-86AF-2F0E09AF82E1Q31121405-022536D8-65F2-4D1F-8159-B95E4EA51BB7Q33269621-B8B89755-16A4-4E00-BF82-DED2546F9DFDQ33645742-96B243E2-E3CB-43A1-9D89-E7F3EB3C83A2Q33659564-D397E82A-3DFA-4968-AB59-DC3203CB12EFQ33962913-79AC0F48-54D1-49FD-867C-D8060BD402CFQ33964055-55BE0DD5-E165-459F-95EF-7877CB421C59Q33965725-4BA5D7BE-3353-4135-B193-A0343A5E76DAQ33966864-93D160F9-D02B-442D-8741-90085BB091EFQ33968179-16027E53-4635-4375-BA60-F2EEA84462C9Q34229961-3C4012D4-A3EE-4BA6-8716-97C3ACF101B4Q34240346-4C52D7FE-9E0E-4431-B64A-97471FD82E6AQ34266847-2A05A4A3-81FA-43AC-BCE0-AE0484622032Q34273757-1EAB3FE3-6A33-49F1-A444-57914C586B9FQ34531819-8D969F1E-1032-4254-9423-EB411D0DE901Q34573446-9A936CEB-2881-4208-A731-83EFCCB01B40Q34588465-16E9B0C0-ED90-4D09-9AE6-49FB8D3362D1Q34604281-01D7C538-6FFD-421A-905B-02FF90AFB8A0Q34604913-D40BB116-1832-463F-BFA8-962E80C471C1Q35684377-F89689CC-62CB-46C5-9821-8BB355B0E682Q35748186-138A5BBD-5526-470D-A160-47BF2D4695DFQ35830888-CD101390-7A22-47F1-8061-A2DD09B3EF1FQ36058196-DA8BD90D-2D6C-473B-8625-761F68C18B0CQ36080989-E1699AB6-4778-4D80-A18E-E565B8B29DACQ36101012-B267B025-54B2-4AC4-AFED-3B2F8D16DC1DQ36112301-16212CDE-5739-4DEB-AA9D-4AC94166347DQ37303967-4B3FC578-C432-4D76-B75D-34823936E0CDQ37373170-221675AB-747A-4E2E-B227-D80002FEC226Q37405532-78887190-C5D4-47D9-88DC-559E5BB2ABBCQ46078698-B3A944A9-DD3D-4980-AE8E-4F22A92C9D0EQ48077553-1152FD5C-56F3-4FB8-B5B7-17AAFE6B912AQ52201121-7F88C976-8D80-43E7-AE5A-8A4D2BB4FF3EQ53486781-B5ED9E23-C1BF-4D60-907D-FFCBE8A3267DQ58127993-8AAB6BE7-3DC5-455B-AF53-2004B6F07D31Q58777996-0F4F8240-4373-4920-A83A-F86360006111
P2860
Development of a core RFLP map in maize using an immortalized F2 population.
description
1993 nî lūn-bûn
@nan
1993 թուականի Յուլիսին հրատարակուած գիտական յօդուած
@hyw
1993 թվականի հուլիսին հրատարակված գիտական հոդված
@hy
1993年の論文
@ja
1993年論文
@yue
1993年論文
@zh-hant
1993年論文
@zh-hk
1993年論文
@zh-mo
1993年論文
@zh-tw
1993年论文
@wuu
name
Development of a core RFLP map in maize using an immortalized F2 population.
@ast
Development of a core RFLP map in maize using an immortalized F2 population.
@en
type
label
Development of a core RFLP map in maize using an immortalized F2 population.
@ast
Development of a core RFLP map in maize using an immortalized F2 population.
@en
prefLabel
Development of a core RFLP map in maize using an immortalized F2 population.
@ast
Development of a core RFLP map in maize using an immortalized F2 population.
@en
P2093
P2860
P1433
P1476
Development of a core RFLP map in maize using an immortalized F2 population
@en
P2093
Gardiner JM
Hoisington DA
Melia-Hancock S
P2860
P304
P407
P577
1993-07-01T00:00:00Z