about
The voltage-gated potassium channels and their relativesQuantitative two-photon imaging of fluorescent biosensorsKetogenic diet metabolites reduce firing in central neurons by opening K(ATP) channelsImaging intracellular pH in live cells with a genetically encoded red fluorescent protein sensor.Quantitative determinants of aerobic glycolysis identify flux through the enzyme GAPDH as a limiting step.A perturbation-based method for calculating explicit likelihood of evolutionary co-variance in multiple sequence alignments.Intracellular gate opening in Shaker K+ channels defined by high-affinity metal bridges.Metabolism regulates the spontaneous firing of substantia nigra pars reticulata neurons via KATP and nonselective cation channels.Imaging cytosolic NADH-NAD(+) redox state with a genetically encoded fluorescent biosensorStatus of the intracellular gate in the activated-not-open state of shaker K+ channelsCytosolic NADH-NAD(+) Redox Visualized in Brain Slices by Two-Photon Fluorescence Lifetime Biosensor Imaging.Structural changes during HCN channel gating defined by high affinity metal bridges.Charge movement in gating-locked HCN channels reveals weak coupling of voltage sensors and gate.Trapping of organic blockers by closing of voltage-dependent K+ channels: evidence for a trap door mechanism of activation gating.Blocker state dependence and trapping in hyperpolarization-activated cation channels: evidence for an intracellular activation gateMovements near the gate of a hyperpolarization-activated cation channelTwo functionally distinct subsites for the binding of internal blockers to the pore of voltage-activated K+ channelsThe leak channel NALCN controls tonic firing and glycolytic sensitivity of substantia nigra pars reticulata neurons.A PKA activity sensor for quantitative analysis of endogenous GPCR signaling via 2-photon FRET-FLIM imagingOptogenetic reporters: Fluorescent protein-based genetically encoded indicators of signaling and metabolism in the brainModulation of K+ current by frequency and external [K+]: a tale of two inactivation mechanisms.Imaging changes in the cytosolic ATP-to-ADP ratio.A genetically encoded fluorescent reporter of ATP:ADP ratio.Expression of Torpedo nicotinic acetylcholine receptor subunits in yeast is enhanced by use of yeast signal sequences.Akt regulation of glycolysis mediates bioenergetic stability in epithelial cells.BAD knockout provides metabolic seizure resistance in a genetic model of epilepsy with sudden unexplained death in epilepsy.Live cell imaging of cytosolic NADH/NAD+ ratio in hepatocytes and liver slices.BAD and KATP channels regulate neuron excitability and epileptiform activity.Neuronal Stimulation Triggers Neuronal Glycolysis and Not Lactate Uptake.Structure and selectivityQuantitative in vivo imaging of neuronal glucose concentrations with a genetically encoded fluorescence lifetime sensor.Alternative mechanism for pathogenesis of an inherited epilepsy by a nicotinic AChR mutationBlocker protection in the pore of a voltage-gated K+ channel and its structural implicationsGated access to the pore of a voltage-dependent K+ channelDimers among friends: ion channel regulation by dimerization of tail domainsKeeping K+ completely comfortableFueling thought: Management of glycolysis and oxidative phosphorylation in neuronal metabolismNeurons rely on glucose rather than astrocytic lactate during stimulationHepatic NADH reductive stress underlies common variation in metabolic traits
P50
Q22337264-63A7074E-4515-4958-9083-E318874FD703Q28083052-4F384B48-5ECD-407B-8F12-9203F5B48375Q28296513-08D75334-C5EE-42DD-872A-9CBC098E25FAQ30403328-A837118C-039B-4161-8B54-91123DA627F3Q33987684-727C278C-481F-44AF-B555-D142B18F9099Q34298639-86AD8560-A6DE-446E-A5DA-A97162F8E4AFQ34315701-0511B198-08B6-4D78-937E-89B8FBFC4FA4Q34614572-96E6F174-9D85-4CD5-A145-8254B8C2C10AQ35302804-938370EB-0EF6-46FD-AFFC-47F8A469E6A2Q35629078-E3B20CE0-5039-4B36-BB66-B4E21C302672Q35917671-B4C8D24F-2883-49CF-84D0-951975AD3656Q36209612-DACB2CE8-6F0B-4A50-9A8E-92CC647E3C74Q36353443-18534106-F429-4A53-BC8F-C0BD3D899E93Q36411850-1D8A6B2D-E930-4FD1-A3DC-E5CC73979F47Q36412287-FD260C94-47E0-4E22-944D-94BF3473DBE1Q36436615-897759BC-F250-419B-957B-C086F7C456DAQ36694932-BAD012F0-8F4D-4017-B4CD-150C8DBA2D3CQ36993657-1AD20C30-9122-4B36-A166-47B1FD4D9030Q37692939-D08BCEE0-CB19-42CF-9627-5EDA1F6B714FQ37985027-52DBB779-A790-41C0-A0CD-DDBC538B588CQ41290065-7AC24F8C-5E7C-4FCA-9058-36CF3E81D540Q43141583-AD8E9CA0-F0FA-4C01-B56C-363CA90A661AQ43190761-D049F8BC-D45D-4C9E-9779-B2E9D8EA75DCQ43987203-84F58207-5C10-4D8B-82F1-EFEF27CC8F1CQ46492675-A4B2AC41-B4EF-4697-8ECF-48472E5FC2D1Q47368974-849B4B04-8D14-46CD-8CBB-630AA2ED4288Q47615003-5710B8A3-D29C-4D55-9FCB-64A31342C02CQ47840670-F63E654F-66AD-40C8-BEAA-85B5EF2878E4Q48169378-2145C6C2-674B-40FD-866D-E6BCE2A6C699Q59032137-3E6AA5A1-141A-4173-B302-67640B6C3286Q67403863-1A0E9778-27FF-4457-9841-0C466A73EBB7Q71230087-F0332A2C-56B7-4393-8BF1-A44794627B56Q73412357-760C0C54-ABD3-425D-BD94-CB65F0CC1975Q73564876-00357083-BC12-46A8-AFCF-1E0885A8C326Q74480708-31C4F8CB-AF00-4DC9-9FAF-ABA710900D31Q77293050-54B46223-1548-4B36-831B-0ADC74FBC151Q88645870-EDA96EB8-B8E6-44F5-8F2B-F284534A09FDQ90690062-2C4F9472-890D-400F-9269-CEBD706502C8Q95934146-F85CCDCE-DD3B-413D-8B5E-224235761268
P50
description
hulumtues
@sq
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
Gary Yellen
@ast
Gary Yellen
@en
Gary Yellen
@es
Gary Yellen
@nl
Gary Yellen
@sl
type
label
Gary Yellen
@ast
Gary Yellen
@en
Gary Yellen
@es
Gary Yellen
@nl
Gary Yellen
@sl
altLabel
Yellen G
@en
prefLabel
Gary Yellen
@ast
Gary Yellen
@en
Gary Yellen
@es
Gary Yellen
@nl
Gary Yellen
@sl
P106
P1153
7005147521
P21
P31
P4012
P496
0000-0003-4228-7866