About Leigh Syndrome
The New York Center for Rare Diseases supports the mission and guidelines of the Genetic and Rare Diseases Information Center (GARD). The following information is provided by the NIH.
Summary
Leigh syndrome is a rare, inherited neurodegenerative condition. It usually becomes apparent in infancy, often after a viral infection. Signs and symptoms usually progress rapidly. Early symptoms may include poor sucking ability; loss of head control and motor skills; loss of appetite; vomiting; and seizures. As the condition progresses, symptoms may include weakness and lack of muscle tone; spasticity; movement disorders; cerebellar ataxia; and peripheral neuropathy. Complications can lead to impairment of respiratory, heart and kidney function. The term "Leigh-like syndrome" is often used for people with features that are strongly suggestive of Leigh syndrome but who do not meet the diagnostic criteria. The inheritance of Leigh syndrome depends on where the responsible gene is located in each case. This is because it can be due to genetic changes in either mitochondrial DNA or nuclear DNA: Mitochondrial DNA-associated Leigh syndrome follows a mitochondrial inheritance pattern (also called maternal inheritance). Nuclear gene-encoded Leigh syndrome may be inherited in an autosomal recessive or X-linked manner.
Causes
What Causes This Disease?
Genetic Mutations: Leigh syndrome is caused by genetic mutations, also known as pathogenic variants. Genetic mutations can be hereditary, when parents pass them down to their children, or they may occur randomly when cells are dividing. Genetic mutations may also result from contracted viruses, environmental factors, such as UV radiation from sunlight exposure, or a combination of any of these.
If you suspect you may have this disease, you may want to start collecting your family health history. Information such as other family members who have had similar symptoms, when their/your symptoms first appeared, or exposures to any potential disease-causing environmental factors should be discussed with your medical team.
Disruption in Metabolism: Leigh syndrome is caused by a disruption in a person's metabolism. Metabolism is the series of chemical reactions in our body that turns the food we eat into energy and removes toxins. Hormones and specific proteins, called enzymes, help make the right chemical reactions happen in the right order. However, genetic changes can prevent hormones or enzymes from working properly, which can lead to a disruption in metabolism such as energy not being created for the body or toxins not being removed from the body.
Impaired Mitochondrial Function: Leigh syndrome is caused by an impairment, or issue, in mitochondrial function. Mitochondria make the energy needed for cells to work properly. When mitochondria are unable to produce enough energy for a cell, the cell can become damaged or can die. Depending on the location and number of damaged cells, different organs and body systems can be affected.
Can This Disease Be Passed Down From Parent to Child?
Yes. It is possible for a biological parent to pass down genetic mutations that cause or increase the chances of getting this disease to their child. This is known as inheritance. Knowing whether other family members have previously had this disease, also known as family health history, can be very important information for your medical team.
There are multiple ways, or patterns, a disease can be inherited depending on the gene(s) involved. Based on GARD's current data, this disease can be inherited in the following pattern(s):
Mitochondrial Inheritance: Mitochondrial inheritance means the genetic mutation is located in a specific type of DNA, called mtDNA. mtDNA is found within the cell's mitochondria. Mitochondria are tiny structures that produce energy for the body. Genetic mutations within mtDNA can prevent the mitochondria from working properly.
During human conception, egg cells, or the cells that come from the female parent, provide mitochondria. If a female parent is affected by a mitochondrial genetic mutation, there is a 100% chance their child inherits the mutated gene. However, the child may or may not be affected by the disease. A male parent cannot pass mitochondrial genetic mutations to their children.
Autosomal Recessive: Autosomal means the gene involved is located on one of the numbered chromosomes. Recessive means that a child must inherit two copies of the mutated gene, one from each biological parent, to be affected by the disease. A carrier is a person who only has one copy of the genetic mutation. A carrier usually doesn't show any symptoms of the disease.
If both biological parents are carriers, there is a 25% chance their child inherits both copies of the mutated gene and is affected by the disease. Additionally, there is a 50% chance their child inherits only one copy of the mutated gene and is a carrier.
X-Linked: X-linked inheritance means the genetic mutation is located on the X chromosome, one of the sex chromosomes. The male sex chromosome pair consists of one X and one Y chromosome (XY). The female sex chromosome pair consists of two X chromosomes (XX). Because males have just one X chromosome, it takes only one copy of the mutated gene to cause the disease. Females that have one copy of the mutated gene may have symptoms similar to those experienced by affected males, but usually have less severe symptoms, or no symptoms at all.
Female parents with one X-linked mutated gene have a 50% chance of passing on the mutation to each of their biological children. Male parents with an X-linked mutated gene will pass on the mutation to all their female children but cannot pass the mutation on to their male children.