Brain's 'molecular memory switch' identified

Scientists have identified a key molecule responsible for triggering the chemical processes in the brain linked to formation of memories.

The research, led by scientists at the University of Bristol, reveals a new target for therapeutic interventions to reverse the devastating effects of memory loss.

Previous studies have shown that our ability to learn and form memories is due to an increase in synaptic communication called Long Term Potentiation (LTP).

This communication is initiated through a chemical process triggered by calcium entering brain cells and activating a key enzyme called 'Ca2+ responsive kinase' (CaMKII).

Once this protein is activated by calcium it triggers a switch in its own activity enabling it to remain active even after the calcium has gone. This special ability of CaMKII to maintain its own activity has been termed 'the molecular memory switch'.

Until now, the question still remained as to what triggers this chemical process in our brain that allows us to learn and form long-term memories.

The research team, comprising scientists from the University's School of Physiology and Pharmacology, conducted experiments using the common fruit fly [Drosophila] to analyse and identify the molecular mechanisms behind this switch.

Using advanced molecular genetic techniques that allowed them to temporarily inhibit the flies' memory the team were able to identify a gene called CASK as the synaptic molecule regulating this 'memory switch'.

"In experiments whereby we tested the flies' learning and memory ability, involving two odours presented to the flies with one associated with a mild shock, we found that around 90 per cent were able to learn the correct choice remembering