Abstract
The high potency of clostridial neurotoxins relies predominantly on their neurospecific binding and specific hydrolysis of SNARE proteins. Their multi-step mode of mechanism can be ascribed to their multi-domain three-dimensional structure. The C-terminal H(CC)-domain interacts subsequently with complex polysialo-gangliosides such as GT1b and a synaptic vesicle protein receptor via two neighbouring binding sites, resulting in highly specific uptake of the neurotoxins at synapses of cholinergic motoneurons. After its translocation the enzymatically active light chain specifically hydrolyses specific SNARE proteins, preventing SNARE complex assembly and thereby blocking exocytosis of neurotransmitter.
MeSH terms
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Animals
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Botulinum Toxins / chemistry
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Botulinum Toxins / metabolism*
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Botulinum Toxins / pharmacology
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Cholinergic Fibers / drug effects
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Cholinergic Fibers / metabolism
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Gangliosides / metabolism*
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Humans
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Motor Neurons / drug effects*
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Motor Neurons / metabolism
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Neurotoxins / chemistry
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Neurotoxins / metabolism
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Neurotoxins / pharmacology
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Protein Binding
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SNARE Proteins / drug effects*
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SNARE Proteins / metabolism
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Structure-Activity Relationship
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Synaptic Membranes / drug effects
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Synaptic Membranes / metabolism
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Synaptotagmins / drug effects
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Synaptotagmins / metabolism
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Tetanus Toxin / chemistry
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Tetanus Toxin / metabolism*
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Tetanus Toxin / pharmacology
Substances
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Gangliosides
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Neurotoxins
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SNARE Proteins
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Tetanus Toxin
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Synaptotagmins
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Botulinum Toxins