Distribution and Lateral Mobility of Voltage-dependent Sodium Channels in Neurons
نویسندگان
چکیده
Voltage-dependent sodium channels are distributed nonuniformly over the surface of nerve cells and are localized to morphologically distinct regions. Fluorescent neurotoxin probes specific for the voltagedependent sodium channel stain the axon hillock 5-10 times more intensely than the cell body and show punctate fluorescence confined to the axon hillock which can be compared with the more diffuse and uniform labeling in the cell body. Using fluorescence photobleaching recovery (FPR) we measured the lateral mobility of voltage-dependent sodium channels over specific regions of the neuron. Nearly all sodium channels labeled with specific neurotoxins are free to diffuse within the cell body with lateral diffusion coefficients on the order of 10 -9 cm2/s. In contrast, lateral diffusion of sodium channels in the axon hillock is restricted, apparently in two different ways. Not only do sodium channels in these regions diffuse more slowly (10-1°-10 -H cm2/s), but also they are prevented from diffusing between axon hillock and cell body. No regionalization or differential mobilities were observed, however, for either tetramethylrhodaminephosphatidylethanolamine, a probe of lipid diffusion, or FITC-succinyl concanavalin A, a probe for glycoproteins. During the maturation of the neuron, the plasma membrane differentiates and segregates voltagedependent sodium channels into local compartments and maintains this localization perhaps either by direct cytoskeletal attachments or by a selective barrier to
منابع مشابه
Distribution and lateral mobility of voltage-dependent sodium channels in neurons [published erratum appears in J Cell Biol 1989 May;108(5):preceding 2001]
Voltage-dependent sodium channels are distributed nonuniformly over the surface of nerve cells and are localized to morphologically distinct regions. Fluorescent neurotoxin probes specific for the voltage-dependent sodium channel stain the axon hillock 5-10 times more intensely than the cell body and show punctate fluorescence confined to the axon hillock which can be compared with the more dif...
متن کاملClustering and mobility of voltage-dependent sodium channels during myelination.
In myelinated axons, voltage-dependent sodium channels are segregated at high density at nodes of Ranvier (Rosenbluth, 1976; Waxman and Quick, 1978; Black et al., 1990; Elmer et al., 1990), a distribution that is critical for the saltatory conduction of action potentials (Huxley and Stampfli, 1949). The factors that specifically control the organization and immobilization of sodium channels at ...
متن کاملDistribution and lateral mobility of GABA/benzodiazepine receptors on nerve cells.
The distribution and mobility of GABA/benzodiazepine receptors has been examined on living nerve cells by fluorescence digital imaging and fluorescence photobleach recovery with 2 novel fluorescent derivatives of the benzodiazepines Ro7-1986 and 1012S. These fluorescent derivatives retain their high affinity for the GABA/benzodiazepine receptor complex with Ks of 79 and 85 nM, respectively. Dig...
متن کاملTemperature-dependent model of human cardiac sodium channel
Cardiac sodium channels are integral membrane proteins whose structure is not known at atomic level yet and their molecular kinetics is still being studied through mathematical modeling. This study has focused on adapting an existing model of cardiac Na channel to analyze molecular kinetics of channels at 9-37°C. Irvine et al developed a Markov model for Na channel using Neuronal Network Model ...
متن کاملTemperature-dependent model of human cardiac sodium channel
Cardiac sodium channels are integral membrane proteins whose structure is not known at atomic level yet and their molecular kinetics is still being studied through mathematical modeling. This study has focused on adapting an existing model of cardiac Na channel to analyze molecular kinetics of channels at 9-37°C. Irvine et al developed a Markov model for Na channel using Neuronal Network Model ...
متن کامل