Information flow in cells relies on calcium as a key agent in several signalling pathways. Calcium dependent signalling is crucial in nearly every aspect of life - muscle movement, immune reactions, nerve function, light sensing and many such processes. In fact, one could consider any cellular function, and calcium signalling is probably involved in it in some way. Now, researchers from the National Centre for Biological Sciences (NCBS), Bangalore have discovered a new player in calcium signalling pathways - a protein named Septin 7 that functions as a 'molecular brake' to Orai activation.

As calcium ions cannot cross cell membranes freely, the rise and fall of calcium levels within a cell are controlled through a set of proteins that act as channels for calcium ions. One such protein is Orai, that forms pores or channels in cell membranes and allows calcium ions to move through them in a regulated fashion.

Since these proteins can be likened to 'gatekeepers' of the calcium entryways into cells, they are named after the mythological Greek Orai, also known as Horae or the gatekeepers of heaven. Researchers now have discovered that another protein known as Septin 7 acts as a 'guard' of the Orai proteins by regulating their activity.

Previous work from this group had established the critical role of calcium signalling and Orai for maintaining dopamine levels in flight circuit neurons in fruit fly (Drosophila) brains. Using this system as a platform, the team investigated and established the role of Septin 7 as a 'molecular brake' of Orai in the neurons of these flies. This means that when Septin 7 levels are decreased in a cell, calcium entry via Orai goes up, leading to higher calcium concentrations within cells. The discovery has been published as a paper in the journal Nature Communications.

The negative nature of Orai regulation by Septin 7 could be a therapeutically important one. "Most drugs work by inhibiting the function of a protein, and inhibiting most proteins causes the processes they are involved in to be reduced. In this case, inhibiting Septin 7 can actually raise intracellular calcium levels," says the lead author of the paper.

"In the context of neural function, we know that under some conditions, reduced calcium signalling can lead to neurodegeneration. Rare genetic disorders such as spinocerebellar ataxias are thought to be caused by calcium signalling dysregulations. Future therapies for certain classes of such disorders could focus on Septin 7 as a therapeutic target," adds the researcher.

http://www.nature.com/ncomms/2016/160526/ncomms11751/full/ncomms11751.html