Spinocerebellar ataxia type 6 (SCA6) is a condition characterized by progressive problems with movement. People with this condition initially experience problems with coordination and balance (ataxia). Other early signs and symptoms of SCA6 include speech difficulties, involuntary eye movements (nystagmus), and double vision. Over time, individuals with SCA6 may develop loss of coordination in their arms, tremors, and uncontrolled muscle tensing (dystonia).

Signs and symptoms of SCA6 typically begin in a person's forties or fifties but can appear anytime from childhood to late adulthood. People with this disorder may require walking or mobility assistance later in life.

Variants (also known as mutations) in the CACNA1A gene cause SCA6. The CACNA1A gene provides instructions for making a protein that forms a part of some calcium channels. These channels transport positively charged calcium atoms (calcium ions) across cell membranes. The movement of these ions is critical for normal signaling between nerve cells (neurons) in the brain and other parts of the nervous system. The CACNA1A gene provides instructions for making one part (the alpha-1 subunit) of a calcium channel called CaV2.1. CaV2.1 channels play an essential role in communication between neurons in the brain.

The CACNA1A gene variants that cause SCA6 involve a DNA segment known as a CAG trinucleotide repeat. This segment is made up of a series of three DNA building blocks (cytosine, adenine, and guanine) that appear multiple times in a row. Normally, the CAG segment is repeated 4 to 18 times within the gene. In people with SCA6, the CAG segment is repeated 20 to 33 times. People with 20 repeats tend to experience signs and symptoms of SCA6 beginning in late adulthood, while people with a larger number of repeats usually have signs and symptoms from mid-adulthood.

An increase in the length of the CAG segment leads to the production of an abnormally long version of the alpha-1 subunit. This version of the subunit alters the location and function of the CaV2.1 channels. Normally the alpha-1 subunit is located within the cell membrane; the abnormal subunit is found in the cell membrane as well as in the fluid inside cells (cytoplasm), where it clusters together and forms clumps (aggregates). The effect these aggregates have on cell functioning is unknown. The lack of normal calcium channels in the cell membrane impairs cell communication between neurons in the brain. Diminished cell communication leads to cell death. Cells within the cerebellum, which is the part of the brain that coordinates movement, are particularly sensitive to the accumulation of these aggregates. Over time, a loss of cells in the cerebellum causes the movement problems characteristic of SCA6.

Normal Function

The CACNA1A gene belongs to a family of genes that provide instructions for making calcium channels. These channels, which transport positively charged calcium atoms (calcium ions) across cell membranes, play a key role in a cell's ability to generate and transmit electrical signals. Calcium ions are involved in many different cellular functions, including cell-to-cell communication, the tensing of muscle fibers (muscle contraction), and the regulation of certain genes.

The CACNA1A gene provides instructions for making one part (the alpha-1 subunit) of a calcium channel called CaV2.1. This subunit forms the hole (pore) through which calcium ions can flow. CaV2.1 channels play an essential role in communication between nerve cells (neurons) in the brain. These channels are especially abundant in neurons called Purkinje cells and granule cells. These neurons are found in the part of the brain that coordinates movement (the cerebellum) .

CaV2.1 channels help control the release of neurotransmitters, which are chemicals that relay signals from one neuron to another. Researchers believe that CaV2.1 channels are also involved in the survival of neurons and the ability of these cells to change and adapt over time (plasticity).

The CACNA1A gene also provides instructions for making another protein called alpha1-ACT (α1ACT). This protein acts as a transcription factor, which means it attaches (binds) to specific regions of DNA and helps control the activity of particular genes. The α1ACT protein is important for the development of neurons, especially Purkinje cells.

Near the tail end of the CACNA1A gene, a segment of three DNA building blocks (nucleotides) is repeated multiple times. This sequence, which is written as CAG, is called a triplet or trinucleotide repeat. The number of CAG repeats in this gene typically ranges from 4 to 18.

Health Conditions Related to Genetic Changes

Episodic ataxia

Many variants (also called mutations) in the CACNA1A gene have been found to cause episodic ataxia type 2 (EA2), the most common form of episodic ataxia. EA2 is associated with episodes of poor coordination and balance (ataxia) and involuntary eye movements called nystagmus.

The CACNA1A variants that cause EA2 are known as loss-of-function variants because they reduce the function of CaV2.1 channels. The changes can impair the production of functional CaV2.1 channels; prevent the channels from reaching the cell membrane, where they are needed to transport calcium ions; or reduce the flow of calcium through the channels. A decrease in the total flow of calcium ions into neurons disrupts the release of neurotransmitters in the brain. Studies show that changes in CaV2.1 channels can disrupt the normal signaling of Purkinje cells. Changes in the chemical signals between neurons cause the episodes of uncoordinated movement seen in people with episodic ataxia.

Familial hemiplegic migraine

Several variants in the CACNA1A gene have been identified in people with familial hemiplegic migraine type 1 (FHM1). This condition is characterized by migraines with a pattern of neurological symptoms known as aura. In FHM1, the aura includes temporary numbness or weakness on one side of the body (hemiparesis). Like EA2 (described above), FHM1 is commonly associated with ataxia and nystagmus. Most of the variants that cause FHM1 change single protein building blocks (amino acids) in the CaV2.1 channel. The most common variant, known as Thr666Met or T666M, replaces the amino acid threonine with the amino acid methionine at a specific location in the CaV2.1 channel. This variant has been found in more than a dozen families.

The CACNA1A variants that cause familial hemiplegic migraine are called gain-of-function variants, because they increase the activity of Cav2.1 channels. The variants change the structure of the CaV2.1 channels. The altered channels open more easily than usual, which increases the inward flow of calcium ions. A greater influx of calcium ions through CaV2.1 channels increases the cell's release of neurotransmitters. The resulting changes in signaling between neurons lead to the development of severe headaches in people with familial hemiplegic migraine.

In some children with FHM1 or sporadic hemiplegic migraine (described below), minor head trauma can cause life-threatening brain swelling (cerebral edema) and coma. One of the CACNA1A gene variants, known as S218L, replaces the amino acid serine with the amino acid leucine at a specific location within the CaV2.1 channel. Channels with this altered subunit open even more easily than channels altered by other CACNA1A gene variants and take longer to close. Researchers suspect that the prolonged channel activity may lead to cellular changes that cause swelling and coma.

Spinocerebellar ataxia type 6

Spinocerebellar ataxia type 6 (SCA6) is another disorder caused by CACNA1A gene variants. The major features of this condition include progressive ataxia, nystagmus, and impaired speech (dysarthria), most often beginning in a person's forties or fifties. SCA6 results from an increased number of copies (expansion) of the CAG trinucleotide repeat in the CACNA1A gene. In people with this condition, the number of CAG repeats ranges from 20 to more than 30.

An increase in the length of the CAG segment impairs the function of the α1ACT transcription factor. As a result, genes that direct the development of Purkinje cells in the cerebellum are not turned on when they should be, and the cells cannot survive. Over time, the loss of cells in the cerebellum leads to the movement problems characteristic of SCA6.

Sporadic hemiplegic migraine

Several variants in the CACNA1A gene have been found in individuals with sporadic hemiplegic migraine. The signs and symptoms of this condition are identical to those of FHM1 (described above); however, sporadic hemiplegic migraine occurs in people with no family history of the condition. As in FHM1, sporadic hemiplegic migraine caused by CACNA1A gene variants is commonly associated with migraines with auras, ataxia, and nystagmus.

CACNA1A gene variants that cause sporadic hemiplegic migraine are acquired during a person's lifetime and are not inherited. The variants change single amino acids in the CaV2.1 channel. Many of these variants are also found in families with FHM1. The altered channels are more active than usual, which increases the release of neurotransmitters. The abnormal signaling between neurons caused by these changes leads to the headaches and auras characteristic of sporadic hemiplegic migraine.

19p13.13 deletion syndrome

The CACNA1A gene is located in a region of chromosome 19 that is missing in most people with 19p13.13 deletion syndrome. As a result of this deletion, many affected individuals are missing one copy of CACNA1A and several other genes in each cell. Features associated with 19p13.13 deletion syndrome include an unusually large head size (macrocephaly), tall stature, intellectual disability, seizures, ataxia, and other health problems. Researchers are working to determine which missing genes contribute to the specific features of the disorder. Studies suggest that the loss of one copy of the CACNA1A gene may cause the seizures and ataxia seen in affected individuals. The deletion reduces the number of CaV2.1 channels produced within cells, although it is unclear exactly how a shortage of these channels is related to seizures and ataxia in people with 19p13.13 deletion syndrome.

Other disorders

Variants in the CACNA1A gene can also cause a form of developmental and epileptic encephalopathy, which is a group of conditions characterized by repeated seizures (epilepsy) and developmental delays. People with developmental and epileptic encephalopathy caused by CACNA1A gene variants often experience intellectual disability, ataxia, nystagmus, and weak muscle tone (hypotonia).

Studies suggest that some variants involved in the condition increase the activity of the CaV2.1 channels, while others reduce the activity. Researchers are working to understand how both types of changes can lead to developmental and epileptic encephalopathy.

Other Names for This Gene

• APCA
• brain calcium channel 1
• CAC1A_HUMAN
• CACNL1A4
• calcium channel, alpha 1A subunit
• calcium channel, L type, alpha-1 polypeptide, isoform 4
• calcium channel, voltage-dependent, P/Q type, alpha 1A subunit
• CAV2.1
• HPCA
• SCA6
• Voltage-gated calcium channel subunit alpha Cav2.1

Genomic Location

This condition is inherited in an autosomal dominant pattern, which means one copy of the altered gene in each cell is sufficient to cause the disorder. In most cases, an affected person has one parent with the condition.

As the altered CACNA1A gene is passed down from one generation to the next, the length of the CAG trinucleotide repeat often slightly increases. A larger number of repeats is usually associated with an earlier onset of signs and symptoms. This phenomenon is called anticipation.

While there is no specific treatment which can prevent of slow the progression of SCA6, there are therapies available to help manage the symptoms. For instance:

• Episodes of ataxia, vertigo, and sleep disorders can be treated with medication,
• Home modifications may be made for safety and convenience,
• Canes and walkers can allow for continued mobility,
• Speech therapy and communication devices may help with dysarthria, and
• Weighted eating utensils and dressing hooks can help patients maintain independence.

Affected individuals should be followed annually or semiannually by a neurologist, with consultations as needed with other specialists.

The worldwide prevalence of SCA6 is estimated to be less than 1 in 100,000 individuals.