Posterior stripe expression of hunchback is driven from two promoters by a common enhancer element.
about
The Drosophila gap gene network is composed of two parallel toggle switchesSpatial bistability generates hunchback expression sharpness in the Drosophila embryoTranscriptional control in the segmentation gene network of DrosophilaA common set of DNA regulatory elements shapes Drosophila appendagesPre-steady-state decoding of the Bicoid morphogen gradient.Enhancer responses to similarly distributed antagonistic gradients in developmentRapid detection and curation of conserved DNA via enhanced-BLAT and EvoPrinterHD analysis.Gene circuit analysis of the terminal gap gene huckebein.A comparison of in vivo and in vitro DNA-binding specificities suggests a new model for homeoprotein DNA binding in Drosophila embryos.Shaping a morphogen gradient for positional precisionSpatiotemporal network motif reveals the biological traits of developmental gene regulatory networks in Drosophila melanogasterEfficient reverse-engineering of a developmental gene regulatory network.Precise developmental gene expression arises from globally stochastic transcriptional activityModeling of gap gene expression in Drosophila Kruppel mutantsThe tailless nuclear receptor acts as a dedicated repressor in the early Drosophila embryoPrecision of hunchback expression in the Drosophila embryo.Uncovering a dynamic feature of the transcriptional regulatory network for anterior-posterior patterning in the Drosophila embryo.Whole-embryo modeling of early segmentation in Drosophila identifies robust and fragile expression domains.Multiple enhancers ensure precision of gap gene-expression patterns in the Drosophila embryo.Sequence-based model of gap gene regulatory network.Mid-embryo patterning and precision in Drosophila segmentation: Krüppel dual regulation of hunchback.Conserved and divergent aspects of terminal patterning in the beetle Tribolium castaneum.Stability-driven nonnegative matrix factorization to interpret spatial gene expression and build local gene networksThe role of Bicoid cooperative binding in the patterning of sharp borders in Drosophila melanogaster.Modulation of temporal dynamics of gene transcription by activator potency in the Drosophila embryo.Dual regulation by the Hunchback gradient in the Drosophila embryoGene regulation by MAPK substrate competition.Precise registration of gene expression boundaries by a repressive morphogen in Drosophila.Using synthetic biology to make cells tomorrow's test tubesCellular resolution models for even skipped regulation in the entire Drosophila embryoQuantitative imaging of transcription in living Drosophila embryos links polymerase activity to patterning.The C. elegans tailless/Tlx homolog nhr-67 regulates a stage-specific program of linker cell migration in male gonadogenesis.Dampened regulates the activating potency of Bicoid and the embryonic patterning outcome in DrosophilaThe gap gene network.Time to move on: Modeling transcription dynamics during an embryonic transition away from maternal control.Lack of tailless leads to an increase in expression variability in Drosophila embryos.Identification of hunchback cis-regulatory DNA conferring temporal expression in neuroblasts and neurons.In silico evolution of the hunchback gene indicates redundancy in cis-regulatory organization and spatial gene expression.Probing the impact of temperature on molecular events in a developmental system.Probing the limits to positional information.
P2860
Q21089954-4C436AC7-D722-49C2-A06D-CADDFB12D0F0Q21145368-AB73D5F7-490A-42C9-9E1D-E71BFAA15C19Q24803742-D435445D-CBE9-487F-AA5C-52D29B7368C8Q28661061-15BF1A75-6668-4F00-94EA-28435F4CCEFDQ33273624-7483EFD9-F7DB-4453-8120-8ED70263FAEBQ33284529-E68D85A2-9A2F-48C3-9E58-71F15EC19AF4Q33321703-F6C6A408-62E8-4410-9139-7B947E1282D1Q33513960-CB0FC6F2-C0FF-4AE0-980B-8DC62CD87DD2Q33890600-AF84F476-C688-488F-A558-447810A40827Q34032641-3BF52E64-BEA3-4D21-A026-171147178E68Q34252823-378BFADD-C016-4F82-B557-A65F65FEE957Q34341320-65D5AF33-6241-4E9E-80B0-A6FDC4865037Q34364634-0FD9BFB7-9805-404C-A296-08C95E230308Q34395206-E7B0BE18-9EC5-4EEF-998A-DDBFFBB17965Q34564826-8B1D44BB-F9BA-47AA-B7E5-6AE9513CC332Q34639257-9D4B80AF-11C3-40AB-A72A-A232A146F9B3Q34706799-34BF3FD7-8C96-48CC-91EF-570DF20755CCQ35106698-B8B46FE9-8762-45EF-A80E-2C6314AD3CFDQ35170843-809C69AF-3232-45F1-B961-DF74B0C77C9EQ35539101-FE9E1D59-A16F-4FA4-AD63-9D7D08D12164Q35582148-79BE02F0-2D39-4233-8D58-166191D33EAAQ35787885-47A0C363-4685-44FC-AFF4-88FCAFE3EA30Q35987459-DFC51607-931D-4EC1-A678-01D8AA9CDC0AQ36236771-E5883C1B-9DCC-4A15-9E5E-80B878D4960EQ36285886-1E4A9114-0251-4D78-BAE0-B112E77D7F9AQ36498398-7154FED8-7834-48A8-8D5F-E93E8A6D4549Q36632159-9BA24DBB-DD6D-41C6-A704-786DD07D8535Q36786731-2209DD6B-D769-41C5-B8DD-6431D0651F5DQ36813978-71B886E5-A584-4643-A1F0-263434DB03B5Q37077899-8957BCFA-ECE9-491D-9F20-D6E68067BAF1Q37308421-FFBEAFAB-F705-4E5C-AEC5-01684C128217Q37424516-7C92DCDF-2998-4AD1-B6FB-73C5DAA0FA58Q37518108-9DE92188-150A-456E-A41C-8ADDA77932DDQ37798472-BEF00670-CE27-4CC4-A2AD-0B602D44FCB6Q39771923-0B1EC007-766B-4FFA-9E3C-AB98CB6787BCQ40070747-6B5B6B7A-F08F-4DF1-9025-EAA61BBF9EA4Q40843905-75C0DA18-5469-4B93-AB57-6CB625C821CAQ41066253-C90B3B5B-9969-4589-94B9-1CE726EE155DQ41833800-E6963F71-F221-46E4-AC38-4BFEC3DD1462Q42078954-680CC1F5-DC2E-498C-AB70-8CF9C314E473
P2860
Posterior stripe expression of hunchback is driven from two promoters by a common enhancer element.
description
1995 nî lūn-bûn
@nan
1995年の論文
@ja
1995年学术文章
@wuu
1995年学术文章
@zh
1995年学术文章
@zh-cn
1995年学术文章
@zh-hans
1995年学术文章
@zh-my
1995年学术文章
@zh-sg
1995年學術文章
@yue
1995年學術文章
@zh-hant
name
Posterior stripe expression of ...... by a common enhancer element.
@en
Posterior stripe expression of ...... by a common enhancer element.
@nl
type
label
Posterior stripe expression of ...... by a common enhancer element.
@en
Posterior stripe expression of ...... by a common enhancer element.
@nl
prefLabel
Posterior stripe expression of ...... by a common enhancer element.
@en
Posterior stripe expression of ...... by a common enhancer element.
@nl
P2093
P1433
P1476
Posterior stripe expression of ...... s by a common enhancer element
@en
P2093
E Steingrímsson
J A Lengyel
J S Margolis
J W Posakony
M L Borowsky
P304
P407
P577
1995-09-01T00:00:00Z