Substrate-dependent control of MAPK phosphorylation in vivo
about
Pseudophosphatase STYX modulates cell-fate decisions and cell migration by spatiotemporal regulation of ERK1/2Control theory meets synthetic biologyStructural Mechanisms of Allostery and Autoinhibition in JNK Family KinasesSegregation and crosstalk of D1 receptor-mediated activation of ERK in striatal medium spiny neurons upon acute administration of psychostimulantsSwitches, excitable responses and oscillations in the Ring1B/Bmi1 ubiquitination systemRetroactive signaling in short signaling pathwaysReceptor tyrosine kinases fall into distinct classes based on their inferred signaling networksLoads bias genetic and signaling switches in synthetic and natural systemsFrequency-modulated pulses of ERK activity transmit quantitative proliferation signals.Data-driven modeling reconciles kinetics of ERK phosphorylation, localization, and activity states.Paradoxical results in perturbation-based signaling network reconstructionThe coupling of pathways and processes through shared components.ERK as a model for systems biology of enzyme kinetics in cells.Kinase inhibitors can produce off-target effects and activate linked pathways by retroactivity.Determinants of cell-to-cell variability in protein kinase signaling.Modular composition of gene transcription networks.Substrate-dependent control of ERK phosphorylation can lead to oscillationsEvaluating the Drosophila Bicoid morphogen gradient system through dissecting the noise in transcriptional burstsMapping the binding interface of ERK and transcriptional repressor Capicua using photocrosslinking.The Capicua repressor--a general sensor of RTK signaling in development and disease.Signaling cascades transmit information downstream and upstream but unlikely simultaneously.Torso RTK controls Capicua degradation by changing its subcellular localizationPrediction of functional phosphorylation sites by incorporating evolutionary informationLong-term dynamics of multisite phosphorylationMinibrain and Wings apart control organ growth and tissue patterning through down-regulation of CapicuaLack of tailless leads to an increase in expression variability in Drosophila embryos.A load driver device for engineering modularity in biological networks.Long signaling cascades tend to attenuate retroactivity.Crosstalk and competition in signaling networksA technique for determining the signs of sensitivities of steady states in chemical reaction networks.Biphasic responses in multi-site phosphorylation systems.Intrinsic feedbacks in MAPK signaling cascades lead to bistability and oscillations.Signaling Architectures that Transmit Unidirectional Information Despite Retroactivity.A double-edged sword: The world according to Capicua in cancer.In silico evolution of gene cooption in pattern-forming gene networks.Load-induced modulation of signal transduction networks.When More Is Less: Dual Phosphorylation Protects Signaling Off State against Overexpression
P2860
Q24307792-E3EAFC4F-4223-44CE-AA99-24F58705C5D9Q26738651-5549EDD5-8A64-4363-97EC-E74BB4F70947Q27675044-A870B9FB-BEBD-4938-8833-578B1B4A02A2Q28395155-3891B575-400A-4899-871C-0043407BEA47Q28478440-2A4FB516-61DF-42FF-B7EA-150E896F4B46Q28481588-A0108FD1-EADE-4ADE-BCF3-7186B55F67FEQ28537891-C559C6DF-C793-42DF-82AD-D5F1143B0B13Q28541592-2918831B-49D6-4EE9-BA6B-D08C73AA5FDAQ30586789-14943C3C-AB8E-4D75-835B-00B834562335Q30746989-9AD3DCAF-EB1B-4CE9-8D40-67D25C3741B9Q33803292-BBD908C6-99CB-4E4C-9B96-E06E19ABFD46Q33945915-00D76EEF-5ECC-455D-9458-F427E92DB480Q34038931-D17EA601-3170-424A-81A0-3AB4D68A7DF7Q34039761-069A96FD-1DA9-4271-A32A-DBE95FD0AA41Q35067163-F4971826-270E-4780-96F7-3896C83AF753Q35120083-312D63AF-9551-4362-A23A-5FC2F356A4FDQ35815838-BDCC5778-C1F7-4966-9F96-A801ED7ACB7EQ35861631-EB193D68-E09A-4DE6-AB73-FBFC7A19A835Q35865554-EE6848F6-92AA-45B9-B513-E018EA619972Q35912432-B7EEEF84-F209-433A-A4A7-DCBFAA80E4A7Q36113381-7E7B2A19-665E-4EB3-8F4F-A2866123820FQ36321316-40FB82F7-BCAE-4EFC-94C5-B3FC874DFFEFQ36922913-2A42EAA7-D10C-4065-BD06-2FE46CA56EFEQ37095279-B8874266-F87D-493F-BFE4-D2109B9389ACQ37281524-5F107DE3-844C-4AE1-9DF0-9429A59D996FQ40070747-42D9862F-1B44-4768-9032-94AEC98196FAQ42106139-47B78D2D-8BE4-4059-89BE-654EEBD0BA32Q42161982-3758BEF9-BA20-43F8-B4E5-E508E34C5EFFQ42265191-6C4CABB6-F981-441A-8EFE-04A499B5FDB4Q42644192-072E32CC-6267-42A7-8EDA-A3A267A1C4E8Q42934167-B781EB28-ECCC-4EC2-A54F-4642276EF58BQ44591569-57322BCB-4EF1-437B-87FE-F4F509C0030CQ46323399-35F6CF64-4015-4424-A211-37B56A26E380Q47114454-B0DFB49F-2D7A-474E-AD3B-57926DFD38EDQ51272308-92F2A06B-05E2-4B67-A8EF-5E0DA0233BE0Q54351000-4883BD75-5700-4BE6-BF1A-D4271F7E2A17Q57044303-346E9991-9100-4A1C-AC1C-DD766E168DD2
P2860
Substrate-dependent control of MAPK phosphorylation in vivo
description
2011 nî lūn-bûn
@nan
2011年の論文
@ja
2011年論文
@yue
2011年論文
@zh-hant
2011年論文
@zh-hk
2011年論文
@zh-mo
2011年論文
@zh-tw
2011年论文
@wuu
2011年论文
@zh
2011年论文
@zh-cn
name
Substrate-dependent control of MAPK phosphorylation in vivo
@en
Substrate-dependent control of MAPK phosphorylation in vivo
@nl
type
label
Substrate-dependent control of MAPK phosphorylation in vivo
@en
Substrate-dependent control of MAPK phosphorylation in vivo
@nl
prefLabel
Substrate-dependent control of MAPK phosphorylation in vivo
@en
Substrate-dependent control of MAPK phosphorylation in vivo
@nl
P2093
P2860
P356
P1476
Substrate-dependent control of MAPK phosphorylation in vivo
@en
P2093
Ernst Hafen
Knud Nairz
Stanislav Y Shvartsman
Yoosik Kim
Ze'ev Paroush
P2860
P356
10.1038/MSB.2010.121
P577
2011-02-01T00:00:00Z