Dynamin Inhibitors as Tools for Dissecting the Endocytic Pathway in Neurons

Funding Activity

Website
http://purl.org/au-research/grants/nhmrc/228406

Funding Status
Closed

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Funded Activity Summary

Nerve cells communicate by the release of neurotransmitters which are packaged in synaptic vesicles inside nerve endings. There is a finite number of vesicles, so they are recycled (endocytosis) for reuse. Some human neural diseases hijack the endocytic pathway for entry of pathological peptides, proteins or viruses to paralyse, kill or infect neurons. Our overall aim is to control nerve communication to ultimately allow us to treat disorders of nerve communication like epilepsy. At its most extreme, completely blocking endocytosis quickly results in a complete block in nerve communication. Therefore slowing it down (rather than blocking) might be a means to control some neural diseases. For example, a seizure is the uncontrolled firing of neurons. The main mechanisms controlling endocytosis converge on the protein dynamin. Dynamin can assemble into a tiny, tightly wound helix or spring. When energy (GTP hydrolysis) is applied to the nanospring it rapidly releases to cleave off empty recycling synaptic vesicles from the cell wall back into the neuron. Our premise is that blocking the nanospring may lead to a new generation of antiepileptic drugs. To achieve this we have already discovered the first chemical inhibitors of dynamin. In this project we will determine how they work, by showing that they target distinct sites in dynamin. We have embarked on an ambitious chemical synthesis program to greatly improve the potency and specificity of the inhibitors. We will expand this with an iterative approach using combinatorial chemistry. When applied to neurons, the drugs appear to be the first endocytosis inhibitors. Will test our proposal that they will reveal multiple points of action of dynamin in various stages of endocytosis. This project will prove the principle that the development of anti-dynamin drugs could lead to the first anti-endocytic drugs. This has the potential to lead to future development of targeted antiepileptic and anticancer drugs.

Funded Activity Details

Start Date: 01-01-2003

End Date: 01-01-2005

Funding Scheme: NHMRC Project Grants

Funding Amount: $470,250.00

Funder: National Health and Medical Research Council

Research Topics

ANZSRC Field of Research (FoR)

Cell Neurochemistry

ANZSRC Socio-Economic Objective (SEO)

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Other Keywords

antiepileptic drugs | drug discovery | dynamin | endocytosis | epilepsy | nerve terminals | neurochemistry | neuropharmacology | synaptic transmission

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