about
Validation of rice genome sequence by optical mapping.The Selaginella genome identifies genetic changes associated with the evolution of vascular plantsBrachypodium distachyon. A new model system for functional genomics in grassesComparative genetics in the grassesComparative genomics of Arabidopsis and maize: prospects and limitations.Genome, functional gene annotation, and nuclear transformation of the heterokont oleaginous alga Nannochloropsis oceanica CCMP1779Repertoire of SSRs in the Castor Bean Genome and Their Utilization in Genetic Diversity Analysis in Jatropha curcasCharacterization of ten novel Ty1/copia-like retrotransposon families of the grapevine genomeUnravelling the genome of Holy basil: an "incomparable" "elixir of life" of traditional Indian medicine.Integration of Cot analysis, DNA cloning, and high-throughput sequencing facilitates genome characterization and gene discoveryIdentification, analysis, and utilization of conserved ortholog set markers for comparative genomics in higher plants.A single molecule scaffold for the maize genome.An integrated physical and genetic map of the rice genome.Comparative genomics in the grass family: molecular characterization of grass genome structure and evolution.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.Discovery and assembly of repeat family pseudomolecules from sparse genomic sequence data using the Assisted Automated Assembler of Repeat Families (AAARF) algorithmTargeting the aluminum tolerance gene Alt3 region in rye, using rice/rye micro-colinearity.A BAC pooling strategy combined with PCR-based screenings in a large, highly repetitive genome enables integration of the maize genetic and physical mapsSmall RNAs, DNA methylation and transposable elements in wheat.Plant genomics.Sequence-Based Analysis of Structural Organization and Composition of the Cultivated Sunflower (Helianthus annuus L.) Genome.Comparative genome organization in plants: from sequence and markers to chromatin and chromosomes.Transposons and genome evolution in plantsComparative sequence analysis of plant nuclear genomes:m microcolinearity and its many exceptions.Comparative genomics of plant chromosomes.The WRKY transcription factor family in Brachypodium distachyon.A 2600-locus chromosome bin map of wheat homoeologous group 2 reveals interstitial gene-rich islands and colinearity with rice.Deletion mapping of homoeologous group 6-specific wheat expressed sequence tagsGenome mapping in capsicum and the evolution of genome structure in the solanaceae.De novo evolution of satellite DNA on the rye B chromosome.Comparative genetics of disease resistance within the solanaceae.Retrotransposon evolution in diverse plant genomesIdentification and physical localization of useful genes and markers to a major gene-rich region on wheat group 1S chromosomes.Gene conversion within regulatory sequences generates maize r alleles with altered gene expressionIs "junk" DNA mostly intron DNA?Analyses of synteny between Arabidopsis thaliana and species in the Asteraceae reveal a complex network of small syntenic segments and major chromosomal rearrangements.A GeneTrek analysis of the maize genomeLTR retrotransposons and flowering plant genome size: emergence of the increase/decrease model.High gene density is conserved at syntenic loci of small and large grass genomes.An overview of plant chromosome structure.
P2860
Q21266561-6EEFA270-E404-41E5-BCC0-2034997D9CFBQ22065618-B051BDBC-A29F-49A2-99D2-AC0F0118CEC4Q24537141-B60F8E04-7630-4CF5-91DA-72BE82CAB6BFQ24599160-59FF5CBC-040A-4262-8D08-5390171E1A27Q24791057-E9322E65-7A0B-41C6-9C35-44E1EB1C9290Q28485189-A9D6620E-9EE4-430E-A619-EBF28B61042EQ28743623-9B4031FD-D5DA-47E0-9578-72F70F42EA60Q28756687-A8075B52-9D09-46CE-879A-CD92F81AFC73Q30410813-1DE6BFBD-4445-4286-90A6-D572A4525C63Q30706610-397EBF3C-6A30-4579-B2EA-C45029C08380Q30837046-7049E7C9-8CB9-41CC-892B-16B544C22DFBQ30912396-4B9E3178-5D79-410A-9879-5E9E2711ACBCQ31044538-3D384C44-CC20-4C0E-AC25-E3AFB2443C44Q31092756-DD0810E8-0915-4C6D-95C1-BF9522764DB4Q31121405-2C456DD4-F48D-4EA9-BDB3-13B8A3637474Q31155225-5CA8B19F-012B-4D39-A4A3-EF95F9F665BDQ33211427-3B465F16-3FDA-4DFD-95A0-F16559C07BE0Q33273059-42199BD0-95D5-49F8-BDAF-287463FD8B28Q33618598-6F7AD7A2-E84C-41D6-8F28-AF6EE70760DBQ33665518-6BE0E5D8-7E4E-446C-8DA6-C254FE3C26BBQ33858692-D95F5B15-886A-40FC-8464-5F38E6C39B37Q33917910-E7EDCF6B-0E14-4128-A414-6BF5C8F9917BQ33946983-2F2FA34D-A269-494A-88EB-6B7723569307Q33971721-B658B438-FD71-47D7-ADB5-548D27A52187Q34046146-521DD479-C0F0-4796-836A-5CDD20EA987DQ34314777-2A073557-D39C-431F-A2B4-063ACADF7673Q34569797-36FA586E-2440-49D8-988A-A2CD4236564FQ34569818-E615275C-0109-43DD-AF9A-5E161DB79EB2Q34607169-C517D48D-5700-4735-B39E-5A39F8637EDFQ34608761-1B618A30-5CD8-4F18-8034-D7B0FFB85706Q34609765-57812468-BAF9-417C-9E6B-82E6A94DB80DQ34610398-5F907801-452E-4151-AD2B-14DF17E4F7CBQ34612334-E9EC113F-E5D6-4FA5-A6CD-DA2E414AC9C7Q34613934-B2F92C99-7E5D-4197-A097-BC78FFC9E749Q35030102-BC2DA973-1D1E-4169-914E-40D30C0AF47BQ35038452-38EF3625-F8BB-4324-B477-D0F3CD164B70Q35880341-C52957F7-8AF5-4A12-BC9C-713EDF9D8BDDQ36225278-11365000-2C33-4CD6-9FE6-962699E46D61Q36419430-A8CABDAD-AFC5-4651-A1EE-6DB0BE03EAE6Q37173628-C4C895BB-B0D7-4C71-AEF9-4F6433FA6940
P2860
description
1998 nî lūn-bûn
@nan
1998年の論文
@ja
1998年論文
@yue
1998年論文
@zh-hant
1998年論文
@zh-hk
1998年論文
@zh-mo
1998年論文
@zh-tw
1998年论文
@wuu
1998年论文
@zh
1998年论文
@zh-cn
name
Grass genomes
@ast
Grass genomes
@en
type
label
Grass genomes
@ast
Grass genomes
@en
prefLabel
Grass genomes
@ast
Grass genomes
@en
P2093
P2860
P356
P1476
Grass genomes
@en
P2093
J L Bennetzen
P SanMiguel
Z Avramova
P2860
P304
P356
10.1073/PNAS.95.5.1975
P407
P577
1998-03-01T00:00:00Z