Birth of a metabolic gene cluster in yeast by adaptive gene relocation. - Wikidata - awgldk - TriplyDB

Birth of a metabolic gene cluster in yeast by adaptive gene relocation.

Birth of a metabolic gene cluster in yeast by adaptive gene relocation.

http://www.wikidata.org/entity/Q46542404

about

A test of the coordinated expression hypothesis for the origin and maintenance of the GAL cluster in yeast Additions, losses, and rearrangements on the evolutionary route from a reconstructed ancestor to the modern Saccharomyces cerevisiae genome Gene functionalities and genome structure in Bathycoccus prasinos reflect cellular specializations at the base of the green lineage The determinants of gene order conservation in yeasts Comparative genomics of emerging pathogens in the Candida glabrata clade Two unlike cousins: Candida albicans and C. glabrata infection strategies Constraints and plasticity in genome and molecular-phenome evolution Unusual linkage patterns of ligands and their cognate receptors indicate a novel reason for non-random gene order in the human genome Logical identification of an allantoinase analog (puuE) recruited from polysaccharide deacetylases The evolution of fungal metabolic pathways Clade- and species-specific features of genome evolution in the Saccharomycetaceae Transposable elements re-wire and fine-tune the transcriptome Comparative genomics and genome evolution in yeasts The biosynthetic gene cluster for the cyanogenic glucoside dhurrin in Sorghum bicolor contains its co-expressed vacuolar MATE transporter Genomic analysis and D-xylose fermentation of three novel Spathaspora species: Spathaspora girioi sp. nov., Spathaspora hagerdaliae f. a., sp. nov. and Spathaspora gorwiae f. a., sp. nov.Adaptive evolution of chloroplast genome structure inferred using a parametric bootstrap approach.Non-random clustering of stress-related genes during evolution of the S. cerevisiae genome Recombination hotspots flank the Cryptococcus mating-type locus: implications for the evolution of a fungal sex chromosome.Gene duplication, modularity and adaptation in the evolution of the aflatoxin gene cluster.Origin and distribution of epipolythiodioxopiperazine (ETP) gene clusters in filamentous ascomycetes.Horizontal transfer of a nitrate assimilation gene cluster and ecological transitions in fungi: a phylogenetic study.The repertoire and dynamics of evolutionary adaptations to controlled nutrient-limited environments in yeast Recurring cluster and operon assembly for Phenylacetate degradation genes.Systematic identification of balanced transposition polymorphisms in Saccharomyces cerevisiae Properties of untranslated regions of the S. cerevisiae genome.Gene responses to oxygen availability in Kluyveromyces lactis: an insight on the evolution of the oxygen-responding system in yeast.The Sir2-Sum1 complex represses transcription using both promoter-specific and long-range mechanisms to regulate cell identity and sexual cycle in the yeast Kluyveromyces lactis Analysis of gene evolution and metabolic pathways using the Candida Gene Order Browser Analysis of gene order conservation in eukaryotes identifies transcriptionally and functionally linked genes.The evolutionary life cycle of the polysaccharide biosynthetic gene cluster based on the Sphingomonadaceae Relocation of genes generates non-conserved chromosomal segments in Fusarium graminearum that show distinct and co-regulated gene expression patterns.Plant metabolic clusters - from genetics to genomics.Genome urbanization: clusters of topologically co-regulated genes delineate functional compartments in the genome of Saccharomyces cerevisiae.Multiple GAL pathway gene clusters evolved independently and by different mechanisms in fungi Fragile regions and not functional constraints predominate in shaping gene organization in the genus Drosophila.Genome structure and dynamics of the yeast pathogen Candida glabrata.Gene clusters for secondary metabolic pathways: an emerging theme in plant biology.Formation of plant metabolic gene clusters within dynamic chromosomal regions.Two different secondary metabolism gene clusters occupied the same ancestral locus in fungal dermatophytes of the arthrodermataceae Impact of chromosomal inversions on the yeast DAL cluster.

P2860

Q21089931-B9992C93-162D-4A81-BCA8-B30A2E56B6EA Q21092460-A1B1FEDD-31F2-460D-981B-1E7816210362 Q21183998-25249011-DF81-40C7-95A4-207B0D9979B0 Q21184135-DA42ED77-69E7-4907-A56B-DC8CF6252A73 Q21266666-32454DDE-53E0-45F7-A4C7-D30BDD7DF7BF Q21999041-651196C2-5A8D-48A2-892C-84392827AAC5 Q24594789-732DFFAA-B4AA-429B-B9CF-01DF98498B79 Q24815834-62D4641A-ECBD-40B3-B91D-5BC504B9FFD1 Q27650820-71B98ABC-747E-49E4-A388-849919253550 Q28542493-12DDC7B3-DE5A-45A0-9E4C-4CB826B95B64 Q28608178-B98931A4-967B-4277-9C04-5C32BBAC7DCC Q28709521-8FB641F9-4A00-4D33-846C-D990EBD45C32 Q28767111-D83CB671-BD9D-4EA8-8F51-C778F781C87A Q28821493-023DCB5F-50BD-44DC-BDF2-A3953D5DDF51 Q31096857-4435B45D-080B-43C9-A951-FA2809C312C5 Q33233546-79424C3D-EB3D-4742-9825-9342F8B29784 Q33251346-D513FDCA-9307-416A-BBD4-32A6D12DACDA Q33262629-0A683967-3016-4DA8-8E3E-F0A4C0AF997A Q33290337-4BC17431-506D-4EAC-949E-79A3195C5FD1 Q33300473-3ECB6B42-4F1E-4EAA-A1AC-A8769E6B2B5E Q33304438-2DC6A355-975D-4D00-B7C0-7FAFED73606F Q33392677-7BE5A923-6E35-4194-B84C-3FB7FA31E764 Q33408037-AB890A2A-2A5B-4BF8-97B9-5A93721636BD Q33463258-428C347B-3AF2-4AD3-BD55-7840302255DB Q33495709-6802A37C-1002-417F-B18C-ED36CEDFF063 Q33512530-6FCA8C0B-B0F2-4851-9641-6531ABF8A527 Q33515250-65EF1517-BA5B-40C8-80A8-0DD5ECEDF869 Q33575349-2F76D931-5A4D-4D54-81FA-303E930C4986 Q33586232-EB7549D5-7DC3-4CBE-9D67-58041E6F3877 Q33587309-6435A366-4510-428B-A0C8-3EB9EB7B63EB Q33616403-62200D85-E08A-412A-B695-225B02C6B913 Q33740016-C5D8BB63-880A-4994-92E1-49DBA8D6599F Q33741032-0870BBAE-D8A4-45B7-B982-3A89BA7C28D9 Q33933343-5E0BD89A-CE4B-4E12-A169-B69EDC04D81B Q34018323-78365331-551B-48B0-90D7-00EF90795DCB Q34039890-A7663D6D-3F69-4772-B1D0-68BA4910B404 Q34141744-4D3F0D6F-7A79-4A23-BAAB-FFFD9A58D15D Q34211703-CF240D60-BBAF-49FF-ABBB-31FD4B8520BF Q34364283-10F7F2CD-E534-426A-808B-C542B2410B82 Q34390777-5BD07B2B-B917-41FA-8801-1D267D30E046

P2860

Birth of a metabolic gene cluster in yeast by adaptive gene relocation.

http://www.wikidata.org/entity/Q46542404

description

2005 nî lūn-bûn

@nan

2005年の論文

@ja

2005年学术文章

@wuu

2005年学术文章

@zh

2005年学术文章

@zh-cn

2005年学术文章

@zh-hans

2005年学术文章

@zh-my

2005年学术文章

@zh-sg

2005年學術文章

@yue

2005年學術文章

@zh-hant

name

Birth of a metabolic gene cluster in yeast by adaptive gene relocation.

@en

Birth of a metabolic gene cluster in yeast by adaptive gene relocation.

@nl

type

label

Birth of a metabolic gene cluster in yeast by adaptive gene relocation.

@en

Birth of a metabolic gene cluster in yeast by adaptive gene relocation.

@nl

prefLabel

Birth of a metabolic gene cluster in yeast by adaptive gene relocation.

@en

Birth of a metabolic gene cluster in yeast by adaptive gene relocation.

@nl

P1433

Q46542404-8921507F-81A2-4F79-A423-66D0D146DA3D

P1476

Q46542404-1AE78F4A-BBD4-4DE5-B164-C08311CC0B55

P2093

Q46542404-4EA89A0A-5569-4F5D-AC1D-B3D036E2EE2B

P2860

Q46542404-05553454-F0B2-4743-ABBD-A0AF15E7DF73

Q46542404-06DD0DDF-4123-4B80-853C-6B21C291F445

Q46542404-2C8282E8-2F91-43AE-829C-F3B969A54BBA

Q46542404-3225946C-77CE-4686-917E-F67D0B735B05

Q46542404-3BF150B2-5E20-4B12-9FBF-9E5A833FA36E

Q46542404-508A2F57-3C6B-45E1-A702-C4029416CA5C

Q46542404-53C8FDC2-AD17-441A-85C5-370DA2A38A76

Q46542404-61569F9D-2817-4816-9713-9080208B76B2

Q46542404-6DEACA4A-DA74-4712-AC5E-9CBF83BD2507

Q46542404-7203400D-56CB-4C6F-A74E-156D782588E6

P2888

Q46542404-34CBDBB7-22E7-4D7E-84BB-3B5334CB4445

P304

Q46542404-0B260F83-6AD7-41FD-9276-48E0956CBC4E

P31

Q46542404-81E18105-3D6D-4619-9FF5-559F0210B825

P356

Q46542404-685214ED-A34D-4449-9FCA-100B88A84E15

P407

Q46542404-9D89FFB0-54CF-47CC-9394-ADA4BB739B3D

P433

Q46542404-9560542F-5117-4686-AB71-52EC5A6DFDF3

P478

Q46542404-F499DBA5-4961-4CBE-9A64-1D174A2A3309

P50

Q46542404-CCD69EE9-B147-48A8-A8FA-C979A0572B97

P577

Q46542404-94325EE6-B2A4-40DB-92B7-577D056E337A

P5875

Q46542404-3819CE38-CBA9-4AB0-BE79-AE4CBA23CFBF

P698

Q46542404-4CE0E0F0-0123-49C6-9B05-1F473A33CD5A

P356

P1433

Nature Genetics

P1476

Birth of a metabolic gene cluster in yeast by adaptive gene relocation.

@en

P2093

Simon Wong

http://www.w3.org/2001/XMLSchema#string

P2860

Sequencing and comparison of yeast species to identify genes and regulatory elements

Genomic gene clustering analysis of pathways in eukaryotes

Microarray deacetylation maps determine genome-wide functions for yeast histone deacetylases.

Sum1 and Ndt80 proteins compete for binding to middle sporulation element sequences that control meiotic gene expression.

A Snf2 family ATPase complex required for recruitment of the histone H2A variant Htz1.

Proof and evolutionary analysis of ancient genome duplication in the yeast Saccharomyces cerevisiae

A computational analysis of whole-genome expression data reveals chromosomal domains of gene expression.

Evidence for co-evolution of gene order and recombination rate.

Genomic analyses of anaerobically induced genes in Saccharomyces cerevisiae: functional roles of Rox1 and other factors in mediating the anoxic response.

The evolutionary dynamics of eukaryotic gene order.

P2888

P304

777-782

http://www.w3.org/2001/XMLSchema#string

P31

scholarly article

P356

10.1038/NG1584

http://www.w3.org/2001/XMLSchema#string

P407

P433

7

http://www.w3.org/2001/XMLSchema#string

P478

37

http://www.w3.org/2001/XMLSchema#string

P50

Kenneth H. Wolfe

P577

2005-06-12T00:00:00Z

http://www.w3.org/2001/XMLSchema#dateTime

P5875

7790522

http://www.w3.org/2001/XMLSchema#string

P698

15951822

http://www.w3.org/2001/XMLSchema#string