T-type calcium channel
T-type calcium channels are low voltage activated calcium channels that become inactivated during cell membrane hyperpolarization but then open to depolarization. The entry of calcium into various cells has many different physiological responses associated with it. Within cardiac muscle cell and smooth muscle cells voltage-gated calcium channel activation initiates contraction directly by allowing the cytosolic concentration to increase. Not only are T-type calcium channels known to be present within cardiac and smooth muscle, but they also are present in many neuronal cells within the central nervous system. Different experimental studies within the 1970s allowed for the distinction of T-type calcium channels from the already well-known L-type calcium channels . The new T-type channels were much different from the L-type calcium channels due to their ability to be activated by more negative membrane potentials, had small single channel conductance, and also were unresponsive to calcium antagonist drugs that were present. These distinct calcium channels are generally located within the brain, peripheral nervous system, heart, smooth muscle, bone, and endocrine system.
The distinct structures of T-type calcium channels are what allow them to conduct in these manners, consisting of a primary α1 subunit. The α1 subunit of T-type channels is the primary subunit that forms the pore of the channel, and allows for entry of calcium.
T-type calcium channels function to control the pace-making activity of the SA Node within the heart and relay rapid action potentials within the thalamus. These channels allow for continuous rhythmic bursts that control the SA Node of the heart.
Pharmacological evidence of T-type calcium channels suggest that they play a role in several forms of cancer, absence epilepsy, pain, and Parkinson's disease. Further research is continuously occurring to better understand these distinct channels, as well as to create drugs to selectively target these channels.
Function
Like any other channel in a cell membrane, the primary function of the T-type voltage gated calcium channel is to allow passage of ions, in this case calcium, through the membrane when the channel is activated. When membrane depolarization occurs in a cell membrane where these channels are embedded, they open and allow calcium to enter the cell, which leads to several different cellular events depending on where in the body the cell is found. As a member of the Cav3 subfamily of voltage-gated calcium channels, the function of the T-type channel is important for the repetitive firing of action potentials in cells with rhythmic firing patterns such as cardiac muscle cells and neurons in the thalamus of the brain. T-type calcium channels are activated in the same range as voltage-gated sodium channels, which is at about -55 mV. Because of this very negative value at which these channels are active, there is a large driving force for calcium going into the cell. The T-type channel is regulated by both dopamine and other neurotransmitters, which inhibit T-type currents. Additionally, in certain cells angiotensin II enhances the activation of T-type channels.Heart
This is important in the aforementioned depolarization events in the pace-making activity of the sinoatrial (SA) Node in the heart and in the neuron relays of the thalamus so that quick transmission of action potentials can occur. This is very important for the heart when stimulated by the sympathetic nervous system that causes the heart rate to increase, in that not only does the T-type calcium channel provide an extra depolarization punch in addition to the voltage gated sodium channels to cause a stronger depolarization, but it also helps provide a quicker depolarization of the cardiac cells.Fast-acting
Another important facet of the T-type voltage gated calcium channel is its fast voltage-dependent inactivation compared to that of other calcium channels. Therefore, while they help provide stronger and quicker depolarization of cardiac muscle cells and thalamus nerve cells, T-type channels also allow for more frequent depolarization events. This is very important in the heart in the simple fact that the heart is better apt to increase its rate of firing when stimulated by the sympathetic nervous system innervating its tissues. Although all of these functions of the T-type voltage gated calcium channel are important, quite possibly the most important of its functions is its ability to generate potentials that allow for rhythmic bursts of action potentials in cardiac cells of the sinoatrial node of the heart and in the thalamus of the brain. Because the T-type channels are voltage dependent, hyperpolarization of the cell past its inactivation voltage will close the channels throughout the SA node, and allow for another depolarizing event to occur. The voltage dependency of the T-type channel contributes to the rhythmic beating of the heart.Structure
Voltage-gated calcium channels are made up of several subunits. The α1 subunit is the primary subunit that forms the transmembrane pore of the channel. The α1 subunit also determines the type of calcium channel. The β, α2δ, and γ subunits, present in only some types of calcium channels, are auxiliary subunits that play secondary roles in the channel.α1 Subunit
The α1 subunit of T-type calcium channels is similar in structure to the α subunits of K+ channels, Na+ channels, and other Ca2+ channels. The α1 subunit is composed of four domains, with each domain containing 6 transmembrane segments. The hydrophobic loops between the S5 and S6 segments of each domain form the pore of the channel. The S4 segment contains a high quantity of positively charged residues and functions as the voltage sensor of the channel opening or closing based on the membrane potential. The exact method by which the S4 segment controls the opening and closing of the channel is currently unknown.Auxiliary subunits
The β, α2δ, and γ subunits are auxiliary subunits that affect channel properties in some calcium channels. The α2δ subunit is a dimer with an extracellular α2 portion linked to a transmembrane δ portion. The β subunit is an intracellular membrane protein. The α2δ and β subunits have an effect on the conductance and kinetics of the channel. The γ subunit is a membrane protein that has an effect on the voltage sensitivity of the channel. Current evidence shows that isolated T-type α1 subunits have similar behavior to natural T-type channels, suggesting that the β, α2δ, and γ subunits are absent from T-type calcium channels and the channels are made up of only an α1 subunit.Variation
There are three known types of T-type calcium channels, each associated with a specific α1 subunit.| Designation | α1 Subunit | Gene |
| Cav3.1 | α1G | |
| Cav3.2 | α1H | |
| Cav3.3 | α1I |
Pathology
When these channels are not functioning correctly, or are absent from their usual domains, several issues can result.Cancer
T-type Calcium channels are expressed in different human cancers such as breast, colon, prostate, insulinoma, retinoblastoma, leukemia, ovarian, and melanoma, and they also play key roles in proliferation, survival, and the regulation of cell cycle progression in these forms of cancer. This was demonstrated through studies that showed that down regulating T-type channel isoforms, or just blocking the T-type calcium channels caused cytostatic effects in cancer cells such as gliomas, breast, melanomas, and ovarian, esophageal, and colorectal cancers.Some of the most notorious forms of cancer tumors contain cancer stem cells, which makes them particularly resistant to any cancer therapy. Furthermore, there is evidence that suggests that the presence of the CSC in human tumors may be associated with the expression of T-type calcium channels in the tumors.