High-resolution timing of cell cycle-regulated gene expression
about
The transcriptional network activated by Cln3 cyclin at the G1-to-S transition of the yeast cell cycleModel-based deconvolution of cell cycle time-series data reveals gene expression details at high resolutionXbp1 directs global repression of budding yeast transcription during the transition to quiescence and is important for the longevity and reversibility of the quiescent stateProbabilistic approach to predicting substrate specificity of methyltransferasesEvolution and regulation of cellular periodic processes: a role for paraloguesStatistical significance of variables driving systematic variation in high-dimensional data.Systematic identification of yeast cell cycle transcription factors using multiple data sources.Characterizing regulatory path motifs in integrated networks using perturbational data.Missing value imputation for microarray data: a comprehensive comparison study and a web tool.Shrinkage regression-based methods for microarray missing value imputation.TF-Cluster: a pipeline for identifying functionally coordinated transcription factors via network decomposition of the shared coexpression connectivity matrix (SCCM)Reverse engineering dynamic temporal models of biological processes and their relationships.Attributes of short linear motifs.Evaluation of gene association methods for coexpression network construction and biological knowledge discovery.The 3D organization of the yeast genome correlates with co-expression and reflects functional relations between genes.A PREVIOUSLY UNKNOWN UNIQUE CHALLENGE FOR INHIBITORS OF SYK ATP-BINDING SITE: ROLE OF SYK AS A CELL CYCLE CHECKPOINT REGULATORIdentification of yeast cell cycle regulated genes based on genomic features.Acetyl-CoA induces cell growth and proliferation by promoting the acetylation of histones at growth genes.Rotavirus replication is correlated with S/G2 interphase arrest of the host cell cycleBranching process deconvolution algorithm reveals a detailed cell-cycle transcription programAcetyl-CoA induces transcription of the key G1 cyclin CLN3 to promote entry into the cell division cycle in Saccharomyces cerevisiaePrincipal component analysis based unsupervised feature extraction applied to budding yeast temporally periodic gene expression.Influence of metabolism on epigenetics and disease.Transcriptional analysis of the Candida albicans cell cycleEvidence of carbon monoxide-mediated phase advancement of the yeast metabolic cycleTopology and control of the cell-cycle-regulated transcriptional circuitry.Systems approaches for the study of metabolic cycles in yeast.Periodic mRNA synthesis and degradation co-operate during cell cycle gene expressionA Computational Method for Identifying Yeast Cell Cycle Transcription Factors.Establishment of a promoter-based chromatin architecture on recently replicated DNA can accommodate variable inter-nucleosome spacing.A stochastic model dissects cell states in biological transition processes.The precise timeline of transcriptional regulation reveals causation in mouse somitogenesis network.Deconvolution of isotope signals from bundles of multiple hairs.Architecture and dynamics of overlapped RNA regulatory networks.Predicting proteome dynamics using gene expression data
P2860
Q21184036-DB3E275A-4135-4E6B-B944-9BEAC7A06102Q27335491-5650311F-F2BC-40DB-B032-9341D6973AFEQ27938875-11E08B95-7DDA-4088-A662-8975CAED6F79Q27940324-8A42F1D8-76E9-40C7-A626-7BAB3733094EQ30002382-12FF0E50-9D0D-4A69-82EC-44B4906F0A3BQ30863598-92CEB512-6FE6-4D3A-920D-1E73BBE65195Q33390479-23BE5148-56AC-423F-B536-2F107C7FD199Q33540857-0F42D3F0-5D77-4A80-A3DF-133E2D50759AQ33640883-E2C046CD-6C61-4885-9177-BFD6399423F8Q33641285-8BB99CA0-D1B9-4ED9-A8E9-8228C9A2AC71Q33874302-67BF85D4-892C-4B24-A7C2-8575D57C24E6Q34005135-5124D4A5-53CE-45A3-B45A-87AF4F09B40DQ34215453-29F2C589-CE8C-47A8-AA81-0F25351F455CQ34505364-7783F2C5-37F0-4700-B181-39868754A0FDQ34575600-BC24F0E3-13BA-413B-8466-B6C3D14A0B38Q34653474-E2CBE7D5-F9A3-493C-B144-D313522D8900Q34877882-3C9E209E-0723-481D-9FBA-1E072405DC87Q35027765-4EC8E877-17DA-4BEA-8410-B0DA6BB97B70Q36407402-C1BBA5AB-CC7A-4BE1-A23A-80E671EF839FQ36673033-B9572AE8-E682-4047-BD8D-8C6E0515118FQ36820004-2EE8F3E1-1BB2-4C11-A342-B507E54BE35FQ37054889-AAFF296A-B8F8-4645-BFA4-97776A50211CQ37177814-0B7ADFF1-4D80-43E8-9D87-264A76384A37Q37262209-A1A91FF3-EF28-4EFD-A60B-4DEE09003AB2Q37321193-CA15B1B7-7AEA-49E1-AB09-97EA79DDD01CQ37412791-7761AA0B-E8CE-40C5-A41E-15C01E722D42Q37807174-B679EE71-5810-40BF-A941-2893D62C5E3FQ39674822-768A10B0-90FF-47E6-9F07-67BCD292A399Q40645488-6622F59D-DF2F-4091-8172-30E4C5F1A76EQ41005325-51A55E7F-EC86-4912-B321-443BE5094E1EQ41876823-18AC1DFA-889A-406B-8BF6-7E43DEF9B431Q43010260-4DCF15FB-245F-43C0-A482-9C67E7AB6ABDQ43493376-C96AC92F-F22C-4B9A-89BA-229FC9A95474Q47998890-0E6C19D9-ECC3-4E80-BFCC-83867B38A279Q58740967-A14FBE54-4D6B-4B90-9B97-A989899D3ACB
P2860
High-resolution timing of cell cycle-regulated gene expression
description
2007 nî lūn-bûn
@nan
2007年の論文
@ja
2007年論文
@yue
2007年論文
@zh-hant
2007年論文
@zh-hk
2007年論文
@zh-mo
2007年論文
@zh-tw
2007年论文
@wuu
2007年论文
@zh
2007年论文
@zh-cn
name
High-resolution timing of cell cycle-regulated gene expression
@ast
High-resolution timing of cell cycle-regulated gene expression
@en
type
label
High-resolution timing of cell cycle-regulated gene expression
@ast
High-resolution timing of cell cycle-regulated gene expression
@en
prefLabel
High-resolution timing of cell cycle-regulated gene expression
@ast
High-resolution timing of cell cycle-regulated gene expression
@en
P2860
P356
P1476
High-resolution timing of cell cycle-regulated gene expression
@en
P2093
Andrzej Kudlicki
Benjamin P Tu
P2860
P304
16892-16897
P356
10.1073/PNAS.0706022104
P407
P577
2007-09-07T00:00:00Z