Determination of the chelatable iron pool of isolated rat hepatocytes by digital fluorescence microscopy using the fluorescent probe, phen green SK.
about
The iron metallome in eukaryotic organismsReduction of Fe(III) ions complexed to physiological ligands by lipoyl dehydrogenase and other flavoenzymes in vitro: implications for an enzymatic reduction of Fe(III) ions of the labile iron poolSubcellular distribution of chelatable iron: a laser scanning microscopic study in isolated hepatocytes and liver endothelial cellsApoptosis induced by exposure to a low steady-state concentration of H2O2 is a consequence of lysosomal ruptureChemical tools for detecting Fe ionsSelective determination of mitochondrial chelatable iron in viable cells with a new fluorescent sensor.Chelation of cellular calcium modulates hypoxia-inducible gene expression through activation of hypoxia-inducible factor-1alpha.No evidence for protective erythropoietin alpha signalling in rat hepatocytes.Determination of the labile iron pool of human lymphocytes using the fluorescent probe, CP655.Carbonic anhydrase II-based metal ion sensing: Advances and new perspectives.Fluorescent sensors for measuring metal ions in living systemsThe chelatable iron pool in living cells: a methodically defined quantity.Synthetic fluorescent sensors for studying the cell biology of metals.Malfunctioning of the iron-sulfur cluster assembly machinery in Saccharomyces cerevisiae produces oxidative stress via an iron-dependent mechanism, causing dysfunction in respiratory complexes.A Cell-Permeable Fluorescent Prochelator Responds to Hydrogen Peroxide and Metal Ions by Decreasing Fluorescence.Lipocalin-2 induces cardiomyocyte apoptosis by increasing intracellular iron accumulation.Prooxidant and antioxidant properties of salicylaldehyde isonicotinoyl hydrazone iron chelators in HepG2 cellsChanging iron content of the mouse brain during developmentSubstrate profile and metal-ion selectivity of human divalent metal-ion transporter-1.Role of labile iron in the toxicity of pharmacological ascorbateProbing oxidative stress: Small molecule fluorescent sensors of metal ions, reactive oxygen species, and thiolsImaging beyond the proteomeRole of citrate and phosphate anions in the mechanism of iron(III) sequestration by ferric binding protein: kinetic studies of the formation of the holoprotein of wild-type FbpA and its engineered mutantsA reactivity-based probe of the intracellular labile ferrous iron pool.Steap4 plays a critical role in osteoclastogenesis in vitro by regulating cellular iron/reactive oxygen species (ROS) levels and cAMP response element-binding protein (CREB) activation.Molecular imaging of labile iron(II) pools in living cells with a turn-on fluorescent probe.Iron-sensitive fluorescent probes: monitoring intracellular iron pools.Statin-induced inhibition of breast cancer proliferation and invasion involves attenuation of iron transport: intermediacy of nitric oxide and antioxidant defence mechanisms.Analytical Methods for Imaging Metals in Biology: From Transition Metal Metabolism to Transition Metal Signaling.A turn-on fluorescent sensor for imaging labile Fe(3+) in live neuronal cells at subcellular resolution.A new ratiometric fluorescent probe for detection of Fe(2+) with high sensitivity and its intracellular imaging applications.TonB is required for intracellular growth and virulence of Shigella dysenteriae.A novel strategy to selectively detect Fe(III) in aqueous media driven by hydrolysis of a rhodamine 6G Schiff base.Chelation and determination of labile iron in primary hepatocytes by pyridinone fluorescent probesLysosomal iron modulates NMDA receptor-mediated excitation via small GTPase, Dexras1.Characterization of injury in isolated rat proximal tubules during cold incubation and rewarming.Phytoestrogens modulate hepcidin expression by Nrf2: Implications for dietary control of iron absorption.Enhancement of iron toxicity in L929 cells by D-glucose: accelerated(re-)reduction.Exogenous ferrous iron is required for the nitric oxide-catalysed destruction of the iron-sulphur centre in adrenodoxin.Transferrin-iron routing to the cytosol and mitochondria as studied by live and real-time fluorescence.
P2860
Q28109405-F5648586-5F58-49E8-A4BF-FF20C94C1D54Q28205831-7EB0BDC4-575B-431D-9A60-8DD011F14F75Q28364228-4F742F2D-77DB-442F-87A0-6E6512E1F418Q28365604-5405D1CA-C078-4239-AEF5-875EFC8014E1Q28817879-2D00D06E-1D7A-4DC1-B183-B8FA2B1F98C0Q31037490-2EB4DAA0-8C4E-432C-A4FF-C23105369040Q33206141-3FAB921B-A8D4-4400-BCFE-6439C4697209Q33433206-F9BA16C9-BE5D-407B-919D-E60294585890Q33491551-5933A41F-2BE7-435F-BD6D-9D060F51D404Q33637489-23CDD3B6-4719-4033-8104-838F1D18DD0AQ33896372-09357C83-47C3-4292-A578-9F9ADC9E6748Q34658929-88E3C7A5-8070-4088-B4FC-3A5006949196Q34750478-AB8BC8EC-4610-4ED9-AE2E-A4E139BB019CQ35377490-FCBE0D3B-4240-436B-8590-003E79DE4B6FQ35696303-0712BA93-4E45-414B-AC38-4F62998D8CA9Q35763055-B9692FA9-F55D-493A-875B-D3846EDB9DBBQ36103810-5D095324-D277-4F74-A36D-9CDF32657E66Q36126297-F30AD0CE-0376-4DB7-B2E3-39CB878CFBDBQ36216669-3707F2ED-2D50-41D8-868F-2300B969B08FQ36539039-755EF1AF-C5C6-4F17-B8FC-D6E00A056537Q36630737-1F1EA131-D14B-4733-AA32-A43EC80A925BQ36862717-E6E97A24-E6EF-4189-BE48-9215F121DE9DQ36908340-CD0417E1-7E42-4B13-BF2E-DB6A004E2687Q37187937-3765C528-1806-436C-BCF3-83415A8ACB9DQ37233966-CE9C3FCA-DA93-48F2-B316-B881FB63DFB4Q37336347-6A1E2730-81CB-460C-AE35-038D8A66619FQ38260227-7B7CACB5-7AF2-429B-9B42-AAEE15664C47Q38981350-47CE0756-ADA6-4535-8E3B-B27DDBD30FE7Q39038980-54D1F59D-D4DA-4838-A0CB-057C57D4E209Q39324534-DEDF8FC6-AEC4-4E8B-BA10-3E634AF346BEQ39488680-04BBF50F-C22C-4F51-B435-3E241143DDBCQ39516873-52787267-0693-4EE2-937C-4B76F6480374Q39738516-D868669E-B4AC-4C34-A2C6-EE1EB349E826Q39738784-C0F42784-A122-47EE-9797-F22FE2E15945Q39849726-8AA93341-9518-4C66-8BE4-C973AC377259Q40149191-F601BDE1-78B2-4B5B-A341-F2A9351120ABQ40346229-F164DF4A-AF70-48C2-A223-DF66BD3AE166Q42132917-82675236-D17D-4720-87D6-4198C5C6ADEFQ43002415-D6AE6324-9212-4EE2-BF83-DC5FEF16A511Q43090551-89B2B26F-9980-45B8-954D-EE59CF6F6CB3
P2860
Determination of the chelatable iron pool of isolated rat hepatocytes by digital fluorescence microscopy using the fluorescent probe, phen green SK.
description
1999 nî lūn-bûn
@nan
1999年の論文
@ja
1999年学术文章
@wuu
1999年学术文章
@zh-cn
1999年学术文章
@zh-hans
1999年学术文章
@zh-my
1999年学术文章
@zh-sg
1999年學術文章
@yue
1999年學術文章
@zh
1999年學術文章
@zh-hant
name
Determination of the chelatabl ...... orescent probe, phen green SK.
@en
Determination of the chelatabl ...... orescent probe, phen green SK.
@nl
type
label
Determination of the chelatabl ...... orescent probe, phen green SK.
@en
Determination of the chelatabl ...... orescent probe, phen green SK.
@nl
prefLabel
Determination of the chelatabl ...... orescent probe, phen green SK.
@en
Determination of the chelatabl ...... orescent probe, phen green SK.
@nl
P2093
P356
P1433
P1476
Determination of the chelatabl ...... orescent probe, phen green SK.
@en
P2093
P304
P356
10.1002/HEP.510290435
P407
P577
1999-04-01T00:00:00Z