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Neurotransmission is a multicomponent process. Transmitters, released by neuronal activity, act on pre- and postsynaptic receptors, and many books detail advances in the receptor field. In addition, after their release from nerve endings, transmitters are removed from the neuronal vicinity by uptake into neuronal or glial cells by specific tra- porter proteins that have been studied intensely over the last 30 years; this information is scattered throughout numerous publishing vehicles. Therefore, the primary aim of this second edition of N- rotransmitter Transporters: Structure, Function, and Regulation is to offer a comprehensive picture of the characterization of neurotransmitter transporters and their biological roles. The transporter field has moved forward in stages. In the first phase, progress came from the use of substrate or blocker ligands selectively targeting transporters, the application of model systems allowing the study of transmitter tra- port shielded from storage, and the development of mathematical models for describing transport phenomena. In the second phase, roughly covering the last decade, advances in DNA techniques allowed the cloning of numerous genes coding for different transporter proteins. In the current, third stage, a wealth of information is being accumulated in studies relating transporter structure with function, experiments addressing regulation by posttranslational transfor- tion, investigations into transport modulation by trafficking processes and genomic influences, characterization of channel properties of tra- porters by electrophysiological approaches, and the creation of transgenic animals under- or overexpressing a given transporter protein.
List of contents
1 - Regulation of Monoamine Transporters: Regulated Phosphorylation, Dephosphorylation, and Trafficking.- 2 - Mechanisms of Biogenic Amine Neurotransmitter Transporters.- 3 - Structure-Function Relationships for Biogenic Amine Neurotransmitter Transporters.- 4 - Gene Organization and Polymorphisms of Monoamine Transporters: Relationship to Psychiatric and Other Complex Diseases.- 5 - Monoamine Transporters: Their Role in Maintaining Neuronal Homeostasis.- 6 - Family of Sodium-Coupled Transporters for GABA, Glycine, Proline, Betaine, Taurine, and Creatine: Pharmacology, Physiology, and Regulation.- 7 - Sodium-Coupled GABA and Glutamate Transporters: Structure and Function.- 8 - The High-Affinity Glutamate and Neutral Amino-Acid Transporter Family: Structure, Function, and Physiological Relevance.- 9 - Vesicular Neurotransmitter Transporters: Pharmacology, Biochemistry, and Molecular Analysis.- 10 - Neurotransmitter-Transporter Proteins: Post-Translational Modifications.- 11 - Dopamine-Transporter Uptake Blockers: Structure-Activity Relationships.- 12 - Imaging the Brain Dopamine Transporter Using PET and SPECT.- 13 - In Vitro and In Vivo Imaging of the Human Dopamine Transporter in Cocaine Abusers.
Summary
Neurotransmission is a multicomponent process. Transmitters, released by neuronal activity, act on pre- and postsynaptic receptors, and many books detail advances in the receptor field. In addition, after their release from nerve endings, transmitters are removed from the neuronal vicinity by uptake into neuronal or glial cells by specific tra- porter proteins that have been studied intensely over the last 30 years; this information is scattered throughout numerous publishing vehicles. Therefore, the primary aim of this second edition of N- rotransmitter Transporters: Structure, Function, and Regulation is to offer a comprehensive picture of the characterization of neurotransmitter transporters and their biological roles. The transporter field has moved forward in stages. In the first phase, progress came from the use of substrate or blocker ligands selectively targeting transporters, the application of model systems allowing the study of transmitter tra- port shielded from storage, and the development of mathematical models for describing transport phenomena. In the second phase, roughly covering the last decade, advances in DNA techniques allowed the cloning of numerous genes coding for different transporter proteins. In the current, third stage, a wealth of information is being accumulated in studies relating transporter structure with function, experiments addressing regulation by posttranslational transfor- tion, investigations into transport modulation by trafficking processes and genomic influences, characterization of channel properties of tra- porters by electrophysiological approaches, and the creation of transgenic animals under- or overexpressing a given transporter protein.
Additional text
From Reviews of the first edition...
"...highly informative and useful..."-Trends in Neurosciences
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From Reviews of the first edition...
"...highly informative and useful..."-Trends in Neurosciences
