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In vivo analysis of interactions between GFP-labeled microfilaments and plastid stromules.A minus-end-directed kinesin with plus-end tracking protein activity is involved in spindle morphogenesisDevelopment and evaluation of a Gal4-mediated LUC/GFP/GUS enhancer trap system in ArabidopsisGetting Down to Specifics: Profiling Gene Expression and Protein-DNA Interactions in a Cell Type-Specific MannerArabidopsis thaliana GLN2-encoded glutamine synthetase is dual targeted to leaf mitochondria and chloroplasts.Arabidopsis thaliana outer ovule integument morphogenesis: ectopic expression of KNAT1 reveals a compensation mechanism.Diphtheria toxin-mediated cell ablation reveals interregional communication during Arabidopsis seed development.WUSCHEL induces shoot stem cell activity and developmental plasticity in the root meristem.Efficient virus-induced gene silencing in roots using a modified tobacco rattle virus vector.Organ boundary1 defines a gene expressed at the junction between the shoot apical meristem and lateral organs.Arabidopsis KANADI1 acts as a transcriptional repressor by interacting with a specific cis-element and regulates auxin biosynthesis, transport, and signaling in opposition to HD-ZIPIII factors.Molecular Characterization of Arabidopsis GAL4/UAS Enhancer Trap Lines Identifies Novel Cell-Type-Specific Promoters.miRNA-dependent translational repression in the Drosophila ovaryThe MED12-MED13 module of Mediator regulates the timing of embryo patterning in ArabidopsisBREs mediate both repression and activation of oskar mRNA translation and act in transDecoding the role of chromatin architecture in development: coming closer to the end of the tunnel.Fluorescence-activated cell sorting for analysis of cell type-specific responses to salinity stress in Arabidopsis and rice.Spatiotemporal regulation of cell-cycle genes by SHORTROOT links patterning and growth.An epifluorescent attachment improves whole-plant digital photography of Arabidopsis thaliana expressing red-shifted green fluorescent protein.Fluorescent in situ folding control for rapid optimization of cell-free membrane protein synthesisPhenyl-adenine, identified in a LIGHT-DEPENDENT SHORT HYPOCOTYLS4-assisted chemical screen, is a potent compound for shoot regeneration through the inhibition of CYTOKININ OXIDASE/DEHYDROGENASE activity.Bile Acid Sodium Symporter BASS6 Can Transport Glycolate and Is Involved in Photorespiratory Metabolism in Arabidopsis thaliana.Nodule inception directly targets NF-Y subunit genes to regulate essential processes of root nodule development in Lotus japonicusRegion-specific activation of oskar mRNA translation by inhibition of Bruno-mediated repression.Gateway-compatible tissue-specific vectors for plant transformation.Translational activation of oskar mRNA: reevaluation of the role and importance of a 5' regulatory element [corrected].oskar RNA plays multiple noncoding roles to support oogenesis and maintain integrity of the germline/soma distinction.Using transgenic modulation of protein synthesis and accumulation to probe protein signaling networks in Arabidopsis thaliana.C2H2 zinc finger-SET histone methyltransferase is a plant-specific chromatin modifierNeurl4 contributes to germ cell formation and integrity in Drosophila.D-type cyclins control cell division and developmental rate during Arabidopsis seed development.Ectopic divisions in vascular and ground tissues of Arabidopsis thaliana result in distinct leaf venation defects.RNA sequences required for the noncoding function of oskar RNA also mediate regulation of Oskar protein expression by Bicoid Stability Factor.Redirecting the Cyanobacterial Bicarbonate Transporters BicA and SbtA to the Chloroplast Envelope: Soluble and Membrane Cargos Need Different Chloroplast Targeting Signals in Plants.Community effects in regulation of translation.Global analysis of cell type-specific gene expression.HKT transporters--state of the artGeneration of active pools of abscisic acid revealed by in vivo imaging of water-stressed Arabidopsis.Red fluorescent protein (DsRed) as a reporter in Saccharomyces cerevisiae.Expression of the Arabidopsis Sigma Factor SIG5 Is Photoreceptor and Photosynthesis Controlled
P2860
Q21261977-C44AACA3-624C-4A34-B2D4-448FD55EFF6BQ24521334-266CFC3B-49C8-4E95-850C-89181268C08EQ24814315-D202F21F-0B25-4E72-A0F9-DEFEAB8955CBQ26786615-7F3E71D0-6372-4D5E-AD31-E8C46D750997Q31098979-ABA397BA-764F-479F-8E85-933B0C95E41EQ33328123-D98E64BA-67D2-472E-B8B0-727E07F2746AQ33339385-56F5034F-EFD3-41D1-9CD8-DA06FFA3A258Q33339772-29C34278-92D4-4233-8642-7BDBB0BD92FFQ33340656-A6F0479F-A543-49E2-BED1-B213175D70E3Q33350484-593EF32A-4D98-4C29-B0C4-6E878A50376EQ33357634-DE24FC9F-3F35-4416-BA48-90BD46D57D98Q33363178-77B29024-BCD5-400E-A50C-6D327FF41829Q33413758-FA5DFC2F-D2E1-49AA-A32C-E567C0BB2D70Q33552385-7F34917D-442D-4A10-8985-53A34FC6279AQ33738174-6822D05F-585B-41BD-8FE2-3D8C2A704514Q34073499-77DB4B8B-12D0-4A54-A87F-894146AF7939Q34181578-C2838DAA-96C5-4059-BBCF-405D0DDA2430Q34259625-867D0B5D-66E0-4699-B1D9-C3B3E1AD3C61Q34266234-AC77EFAA-19A4-4FCA-9756-40AF049C497CQ34359630-5C15153A-315B-4ED0-99DC-42F90ED3E311Q34536456-EC25DF05-49C6-4FAA-B6B9-DCBC9D56B303Q34554302-107A4FDE-E1A2-4BDB-9150-9115549934A0Q34649811-629C446D-F4C5-47C9-9BD0-33C994B16506Q35130479-7B4695D6-7796-4FB1-9D0C-5AE6733B7D3AQ35155545-14ABE08D-A7C5-4963-9D9F-BD602CCCC77EQ35565930-02356902-E42E-45B1-8F8E-3F63A4320593Q35621431-214D8EC0-BFA6-4BEB-90B1-C3D384E5F80CQ35672005-066076B8-1210-48DF-B534-161E1B231B2FQ35697322-39E7BB77-38E1-4052-9A10-B72849F340D3Q35973330-3609823E-FE45-47E1-B6AE-D5ACCBE4F655Q36073523-B0B3DCC0-EFEB-4D84-ADF0-52608B32C096Q36199709-3C6BC01A-8E80-4366-8430-5C8C1A773555Q36328490-0F61A7F9-B5A5-4EB7-99A4-E3A211FF78D6Q36627419-07429AF0-3B02-43A2-947A-FC6EC3EDAD71Q36839590-9327C19B-2643-49DA-901B-B4A1D4537F3AQ37217291-83131831-EF9C-4DC4-98FE-D3D6B0498AD0Q38152924-2FD0FA05-0996-48D5-80F7-DF377CF57C89Q38946590-13C0536A-CA3A-4620-A0A2-34CF65DAB127Q39503833-64A808FA-1C7E-42EA-A6EB-9474F32E5E48Q40605531-396664CC-DF19-4CE5-A49A-262442C53577
P2860
description
im Januar 1999 veröffentlichter wissenschaftlicher Artikel
@de
wetenschappelijk artikel
@nl
наукова стаття, опублікована в 1999
@uk
name
GFP variants for multispectral imaging of living cells
@en
GFP variants for multispectral imaging of living cells
@nl
type
label
GFP variants for multispectral imaging of living cells
@en
GFP variants for multispectral imaging of living cells
@nl
prefLabel
GFP variants for multispectral imaging of living cells
@en
GFP variants for multispectral imaging of living cells
@nl
P1476
GFP variants for multispectral imaging of living cells
@en
P2093
J Haseloff
P304
P407
P577
1999-01-01T00:00:00Z