%D8%A5%D8%B1%D9%81%D9%8A%D9%86_%D9%86%D9%8A%D9%87%D8%B1%D8%A7%D8%B1%D9%88%DB%8C%D9%86_%D9%86%DB%8C%DB%8C%D8%B1%D0%AD%D1%80%D0%B2%D1%96%D0%BD_%D0%9D%D0%B5%D0%B5%D1%80Erwin_NeherCategory:Erwin_NeherErwin_NeherErwin_NeherErwin_NeherErwin_NeherErwin_NeherErwin_Neher%D8%A7%D8%B1%D9%88%DB%8C%D9%86_%D9%86%DB%8C%DB%8C%D8%B1Erwin_NeherErwin_Neher%D7%90%D7%A8%D7%95%D7%95%D7%99%D7%9F_%D7%A0%D7%94%D7%A8Erwin_NeherErwin_NeherErwin_NeherErwin_NeherErwin_Neher%E3%82%A8%E3%83%AB%E3%83%B4%E3%82%A3%E3%83%B3%E3%83%BB%E3%83%8D%E3%83%BC%E3%82%A2%E3%83%BC%D0%AD%D1%80%D0%B2%D0%B8%D0%BD_%D0%9D%D0%B5%D0%B5%D1%80%EC%97%90%EB%A5%B4%EB%B9%88_%EB%84%A4%EC%96%B4Erwin_Neher%E0%B4%8E%E0%B5%BC%E0%B4%B5%E0%B4%BF%E0%B5%BB_%E0%B4%A8%E0%B5%86%E0%B4%B9%E0%B5%86%E0%B5%BCErwin_NeherErwin_NeherErwin_NeherErwin_NeherErwin_Neher%D8%A7%D8%B1%D9%88%D9%86_%D9%86%DB%8C%DB%81%D8%B1Erwin_Neher%D0%9D%D0%B5%D1%8D%D1%80,_%D0%AD%D1%80%D0%B2%D0%B8%D0%BDErwin_NeherErwin_NeherErwin_NeherErwin_Neher%E0%AE%8E%E0%AE%B0%E0%AF%8D%E0%AE%B5%E0%AE%BF%E0%AE%A9%E0%AF%8D_%E0%AE%A8%E0%AF%87%E0%AE%AF%E0%AF%86%E0%AE%B0%E0%AF%8D%E0%B0%8E%E0%B0%B0%E0%B1%8D%E0%B0%B5%E0%B0%BF%E0%B0%A8%E0%B1%8D_%E0%B0%A8%E0%B1%86%E0%B0%B9%E0%B1%86%E0%B0%B0%E0%B1%8DErwin_Neher
about
The Patch Clamp TechniqueImproved patch-clamp techniques for high-resolution current recording from cells and cell-free membrane patchesHow frequent are correlated changes in families of protein sequences?Examining synaptotagmin 1 function in dense core vesicle exocytosis under direct control of Ca2+Intracellular calcium dependence of large dense-core vesicle exocytosis in the absence of synaptotagmin IMerits and Limitations of Vesicle Pool Models in View of Heterogeneous Populations of Synaptic VesiclesThe influence of phospholipid polar groups on gramicidin channelsTransmitter release modulation by intracellular Ca2+ buffers in facilitating and depressing nerve terminals of pyramidal cells in layer 2/3 of the rat neocortex indicates a target cell-specific difference in presynaptic calcium dynamicsSuperpriming of synaptic vesicles as a common basis for intersynapse variability and modulation of synaptic strength.A special pair of phytohormones controls excitability, slow closure, and external stomach formation in the Venus flytrapThe coupling between synaptic vesicles and Ca2+ channels determines fast neurotransmitter release.The SNARE protein SNAP-25 is linked to fast calcium triggering of exocytosisThe Venus Flytrap Dionaea muscipula Counts Prey-Induced Action Potentials to Induce Sodium UptakeThe extracellular patch clamp: a method for resolving currents through individual open channels in biological membranes.Heterodimerization of serotonin receptors 5-HT1A and 5-HT7 differentially regulates receptor signalling and trafficking.The timing of phasic transmitter release is Ca2+-dependent and lacks a direct influence of presynaptic membrane potentialSpecificity emerges in the dissection of diacylglycerol- and protein kinase C-mediated signalling pathwaysVesicle pools and short-term synaptic depression: lessons from a large synapse.Application of an Epac activator enhances neurotransmitter release at excitatory central synapses.Emerging roles of presynaptic proteins in Ca++-triggered exocytosis.Estimation of quantal parameters at the calyx of Held synapse.The reserve pool of synaptic vesicles acts as a buffer for proteins involved in synaptic vesicle recycling.A small pool of vesicles maintains synaptic activity in vivo.Combining deconvolution and fluctuation analysis to determine quantal parameters and release rates.Calcium sensor kinase activates potassium uptake systems in gland cells of Venus flytrapsReduced endogenous Ca2+ buffering speeds active zone Ca2+ signalingPresynaptic calcium and control of vesicle fusion.Estimation of mean exocytic vesicle capacitance in mouse adrenal chromaffin cells.A comparison between exocytic control mechanisms in adrenal chromaffin cells and a glutamatergic synapse.Superpriming of synaptic vesicles after their recruitment to the readily releasable pool.Blind source separation techniques for the decomposition of multiply labeled fluorescence images.Multiple roles of calcium ions in the regulation of neurotransmitter release.Protein scaffolds in the coupling of synaptic exocytosis and endocytosis.Quantitative intensity-based FRET approaches--a comparative snapshot.Transients in global Ca2+ concentration induced by electrical activity in a giant nerve terminal.Neurosecretion: what can we learn from chromaffin cells.Insect haptoelectrical stimulation of Venus flytrap triggers exocytosis in gland cells.Venus Flytrap HKT1-Type Channel Provides for Prey Sodium Uptake into Carnivorous Plant Without Conflicting with Electrical Excitability.Some Subtle Lessons from the Calyx of Held Synapse.Calcium gradients and buffers in bovine chromaffin cells.
P50
Q22337218-6CE7B672-226A-4174-B2BE-720D6B29ED90Q22337395-50F0BC9B-D61B-4620-BCCC-DAC20058D8B6Q24562368-352AF6E7-AB28-4149-85CE-C027545EB825Q26269939-20c42093-4d0f-6be3-9716-1f9cc944835eQ26269979-8d154ed6-4911-fe21-7b91-6c1c6599eafcQ28081497-42D1BC6B-3AF5-4BF7-B8F4-7358D1CEF0C2Q28318027-2AF32FBB-720F-4737-B60B-B8C8218505A4Q28360349-2512C90D-4D7C-4204-A698-5636102F1994Q30376786-FFB15E73-EF88-4533-9DAC-73FED6B5E005Q30504421-D9AE1ADD-34DC-4075-A0B7-A6FDE7AE0460Q33273491-AB96F929-27EC-4BAE-BE78-285EC86E10DAQ34010435-2D567655-976E-4328-A90E-9AF2E8B5E30EQ34045942-4D4587D1-54B9-455D-836D-E16B49E879E6Q34237703-A21AB703-D639-4C3C-8854-9AEA9917E6BFQ34256410-A47A33C6-A4FE-471D-83F8-EA3EA5748B18Q34393072-2A8E06C9-2565-4FA1-93DC-C6EBB3A64515Q34428916-9E591E59-5623-4A3E-A8BE-FBD6FB7CA073Q34629985-A26B225C-5A52-425C-9DF0-152B061A6EAEQ34805045-1212EAA8-66FE-4CBE-AC61-5CF33F0F958CQ34979915-A2B63952-98DA-4874-A096-4F69A009D589Q35006132-BE70EC94-072E-4693-8F56-D318C4A969FAQ35344955-EAFEEC64-3464-4A64-A842-9FAF2CDA3A03Q35345585-DAAF302B-6889-4EBE-B711-59B43F973C33Q35604850-E732A454-EF6E-46C1-87B5-7576C2FBC7B2Q35740255-092F8A60-8E7C-4C16-ABB2-26DF0592F4EBQ35740458-5EF391CB-8648-4A62-86E8-F0E03D7EB99CQ36140944-EFC34F47-58DD-46A6-989E-ED8C0DB4428DQ36239491-B9541AC1-EA83-49C8-A2A1-D1E36B39D08DQ36611095-C9C8DDAD-AFD4-4E7C-A48A-BFC5448832E2Q37173048-BB5F01D6-B931-4208-BAFE-1147A392260BQ37263539-553409DA-1C9F-48C2-9B71-3D2DB30F9074Q37279408-1B3547D3-FF3D-4F32-924C-579C0DB256EBQ37838259-91228E3D-7C73-4DD5-925B-D09739BC7222Q38064051-0C1F636B-5FE2-463A-AD2E-CC996565BAFAQ38093048-DEF9F19E-4297-4721-AD8F-D8C423CA5756Q38628008-6C617A39-E13C-4E7A-B6D8-775193D4476CQ38833548-26744686-3EE6-40B8-ACDE-C811CA2453D4Q38995125-8C45F8D3-48A9-43A0-AD5E-857C3E722C31Q38999523-B8AA9A5E-1968-410B-91AA-1044E7735E3CQ39227699-6EB2E8E1-F473-43DA-AA54-C5171213F544
P50
description
German biophysicist
@en
biofysicus uit Nazi-Duitsland
@nl
deutscher Mediziner und Nobelpreisträger
@de
fisico tedesco
@it
német biofizikus
@hu
physicien allemand
@fr
professor académico alemão
@pt
tysk professor
@da
tysk professor
@sv
ביופיזיקאי גרמני, זוכה פרס נובל
@he
name
Erwin Neher
@ast
Erwin Neher
@ca
Erwin Neher
@cs
Erwin Neher
@da
Erwin Neher
@de
Erwin Neher
@en
Erwin Neher
@es
Erwin Neher
@et
Erwin Neher
@eu
Erwin Neher
@fi
type
label
Erwin Neher
@ast
Erwin Neher
@ca
Erwin Neher
@cs
Erwin Neher
@da
Erwin Neher
@de
Erwin Neher
@en
Erwin Neher
@es
Erwin Neher
@et
Erwin Neher
@eu
Erwin Neher
@fi
altLabel
E Neher
@en
E. Neher
@en
Neher E
@en
Neher E.
@en
Neher
@en
Neher
@sv
Ервін Неер
@uk
Неэр Э.
@ru
Неэр Эрвин
@ru
Неэр
@ru
prefLabel
Erwin Neher
@ast
Erwin Neher
@ca
Erwin Neher
@cs
Erwin Neher
@da
Erwin Neher
@de
Erwin Neher
@en
Erwin Neher
@es
Erwin Neher
@et
Erwin Neher
@eu
Erwin Neher
@fi