The brain, a complex network
The human brain is composed of 100 billion individual nerve cells which communicate with each other via a complex network of connections. Errors in communications of these cells are often at the basis of brain and nerve diseases such as Alzheimer's and multiple sclerosis. In the search for possible solutions to these diseases, one important aspect is to understand how the connections between nerve cells develop.
Drosophila as a model organism
The fruit fly, Drosophila melanogaster, is an important, low-cost model organism with 60% genetic similarity with humans. The fruit fly plays a significant role in clarifying various neurological processes such as the way our memory works and our sense of smell and in studying particular neurodegenerative diseases. The team headed by Bassem Hassan uses the fruit fly as a model to study brain development.
DenMark, the missing key
Though Drosophila has long been used to study the connections between nerve cells, one specific marker was still missing. To understand the whole circuit between nerve cells, markers are needed for the different compartments of nerve cells (presynaptic or output cells and postsynaptic or input cells).
Under the direction of Bassem Hassan and in collaboration with Wim Annaert, Laura Nicolaï, Ariane Ramaekers and their colleagues have identified the missing marker, DenMark (Dendritic Marker), a hybrid of a mouse protein and a fluorescent protein. The high specificity of such a marker for the input compartment of the nerve cells in Drosophila gives rise to hope that it can also be used in other model organisms.
What is a synapse?
Nerve cells communicate via a synapse. A synapse is a space in the connection between nerve cells, more specifically the space between the presynaptic membrane (of an axon) and the postsynaptic membrane (of a dendrite). Axons conduct away from the cell, dendrites (usually) to it. The "message is transmitted" via the synapse by neurotransmitters.