The CACNA1C gene provides instructions for making one of several calcium channels. Calcium channels, which transport positively charged calcium atoms (calcium ions) into cells, play a key role in a cell's ability to generate electrical signals. Calcium ions are important for many cellular functions, including regulating the electrical activity of cells, cell-to-cell communication, the tensing of muscle fibers (muscle contraction), and the regulation of certain genes, particularly those involved in the development of the brain and bones before birth.~The calcium channel produced from the CACNA1C gene is known as CaV1.2. These channels are found in many types of cells, although they appear to be particularly important for the function of heart cells (cardiomyocytes) and nerve cells (neurons) in the brain. In the heart, CaV1.2 channels open and close at specific times to control the flow of calcium ions into cardiomyocytes at each heartbeat. How long the channels are open and closed is regulated to maintain normal heart function. In the brain, CaV1.2 channels are thought to be involved in memory, the fear response, and the rapid transmission of nerve signals; however, the role of these channels in the brain and other tissues is not completely understood.~Researchers have discovered that many different versions (isoforms) of the CaV1.2 channel can be produced from the CACNA1C gene by a mechanism called alternative splicing. This mechanism produces different versions of the channel by cutting and rearranging the genetic instructions in different ways. Some versions of the CaV1.2 channel are more common than others in certain parts of the body. For example, in the heart and brain, about 80 percent of CaV1.2 channels are made with a particular segment known as exon 8. The other 20 percent of CaV1.2 channels contain a slightly different version of this segment, known as exon 8A. This difference becomes important when researchers are studying the effects of CACNA1C mutations in various tissues.