Using chemical, fluorescent indicators of cytosolic calcium in analyses of cell populations as well as single cells, in combination with an analysis of which genes are expressed in human astrocytes, we have characterised which subtypes of purinergic receptors are functionally expressed in human astrocytes. The results, indicating that only two types of receptors are functionally expressed, and that this expression profile differs from the one expected from previous analyses, are currently under review at an international peer-reviewed journal.
Using chemical, fluorescent indicators of cytosolic calcium in analyses of astrocytic cell populations and specific inhibitors of different ATP-providing pathways, we determined that only two sources of cellular ATP provision appear to affect a certain type of calcium signals in human astrocytes, evoked by the receptor PAR1. This indicates that micro domains of cellular ATP might exists in these cells, locally supporting energy-demanding signalling processes. We are currently continuing this project to analyse which steps in the PAR1-evoked signalling cascade are dependent on local provision of ATP.
We have obtained evidence that supports our hypothesis of a previously unknown pathway for subcellular glucose compartmentalization inside astrocytes. We have used advanced optical imaging techniques, such as total internal reflection fluorescence microscopy and confocal imaging, that allow visualization of sub-cellular processes with the aid of fluorescent biosensors. Using a sub-cellularly targeted fluorescent biosensor for glucose we found indications for a dynamic pathway for glucose uptake and glucose distribution inside astrocytes. We also establisehd a protocol that allows astrocytes to be grown inside microfluidic chambers, which permit fluidic isolation of cell body from cell extensions. This protocol enables to selectively change the chemical environment of cell body and cell extensions, mimicking conditions inside the body, where cell extensions will be exposed to different chemical signals than the cell body of brain cells. The results of this work are currently being finalized, and will be presented at the International Society for Neurochemistry Conference in Paris in August 2017. In addition the results will, upon completion within the next few months, be submitted to an international peer-reviewed journal.
All publications from this project will be open access, allowing members of the public to access the articles.