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The genetic disease, Gaucher's disease, causes a disorder of the lipid metabolism. Through this sphingolipidosis (lysosomal storage disease) there can be found a accumulation of sphingolipids in cells, that leads to a morbid impact on the body.
- 1 Phenotypic description of the disease
- 2 Biochemical disease mechanism
- 3 Inheritance and incidence
- 4 Gene and mutations associated with the disease
- 5 Diagnosis
- 6 Treatment
Phenotypic description of the disease
There exist three phenotypic expressions of the Gaucher's disease. Dependent of the severe of the disease, the disease shows different symptoms. Also, the age at which the first symptoms appear, is in connection with the degree of illness.
Classification of types and symptoms
Type I: non-neuropathic
The most common type of the Gaucher's disease has also the mildest illnes degree. It mostly occurs the first time in adulthood. Symptoms, that may occur in type I:
- skeletal abnormalities (osteopenia, bone pain/fractures)
- hepatomegaly (enlarged liver)
- splenomegaly (enlarged spleen) that causes anemia (decrease in healthy red blood cells) and can result in thrombocytopenia (greater susceptibility to bruising, which may mean you have a low number of blood platelets) as well as nosebleeds
- pingueculae (yellow spots in your eyes)
- delayed puberty
Type II: acute infantile neuropathic
The second disease form starts at the infant stage and has the severest degree of illness. Most children with this type of Gaucher won't reach the age of five. Symptoms, that may occur in type II:
- type I symptoms
- rapidly process of brain damage (mental retardation, dementia)
Type III: chronic neuropathic
The Type III of Gaucher’s disease begins in childhood or adolescence. Symptoms, that may occur in type III:
- type I symptoms especially liver and spleen enlargement are more intense than in the other Gaucher types
- slow brain damage (mental retardation, dementia)
Biochemical disease mechanism
Old or other disused red/white blood cells are processed in the macrophages. In these Immunocells, the lysosomal glucocerebrosidase acts on the fatty acids of the cell membrane. In the lysosome the glucocerebrosidase cleaves the glucosylceramide into ceramide and glucose. After the breakdown of the cell membrane, the macrophage is able to degrade the blood cell. A defect on the glycocerebrosidase enzyme prohibits this fatty acid degradation, so that the fatty acid is stored in the lysosome. Without the enzyme, the glucosylceramide cannot be processed anymore. As macrophages are not able to process the fatty acids of the cell membranes, they cannot eliminate the waste products of the blood cells and the glucosylceramid accumulates. The Macrophages that are affected by such a accumulation are called Gaucher cells. 
Inheritance and incidence
- The disease befalls both females and males and is inherited in autosomal recessive manner. That means that if both parents carry the defect gene, their child (in each pregnancy) will be affected (i.e. become the disease) with 1:4 chance.
- According to National Gaucher Foundation (USA) nearly 1 person in 20,000 has Gaucher's disease.
- About 1 in 100 humans in general population of USA is a carrier of Gaucher's most common type - type I, which gives a prevalence of 1 in 40,000. The carrier rate is much higher among Ashkenazi Jews: around 1 in 15, with birth incidence 1 in 450.
- Type II Gaucher's disease does not seem to be preferentially represented by a specific ethnic group.
- Type III Gaucher's disease occurs most frequently in the northern Swedish region of Norrbotten. The incidence is 1 in 50,000 there.
Gene and mutations associated with the disease
- The cause of Gaucher disease is a recessive mutation in a houskeeping gene lysosomal glucocerebrosidase (beta-glucosidase, glucosylceramidase) on chromosome 1 (1q21).
- The defect protein is an enzyme with the following properties:
- EC number 126.96.36.199
- PDB structure 1OGS. The molecular weight of the determined structure is 55.6 KD and length 497 amino acids.
- UniProt entry P04062. The molecolar weight of the native protein is 59.716 KD and length 536 amino acids.
- The phenotype depends on the activity of the beta-glucosidase, which is determined by the different mutations.
- There are about 80 known mutations causing Gaucher's disease, divided into three main groups, according to the Goucher's types they cause:
- Type I: N370S homozygote (2 copies)
- Type II: 1-2 copies of L444P
- Type III: 1-2 copies of L444P possibly delayed by protective polymorphisms
- Interesting is that heterozygote individuals for certain acid mutations in the enzyme carry approx. a 5-fold risk to develop Parkinson's disease, which is the highest known risk-factor.
- Moreover, a study in USA showed that among 1525 Gaucher patients the diseases non-Hodgkin lymphoma, melanoma and pancreatic cancer occurred at a 2-3 times higher rate.
Diagnosis of Gaucher’s disease is possible. Two possibilities exist:
- Blood test: tests the activity of beta-glococerebrosidase.
- DNA analysis (genotyping): examination of the gene for typical mutations (N370S, L444P).
There does not exist a cure for this disease yet. But several different treatments and therapies were developed to treat patients with Gaucher's disease.
The treatments used today can be divided into to different groups:
- Enzyme replacement treatment: the enzyme, recombinant glucocerebrosidase (imiglucerase), is biotechnological produced and intravenous applied to the body. It decreases the size of liver and spleen. (t1+t3) [wie diabetes]
- Substrate reduction therapie: inhibits the development of the substrate glucosylceramide, so that the small amount of Glucocerebrosidase suffices to process the substrate.
- Symptomatic therapie: This therapy doesn't cure the disease but eases the symptoms by using organ transplantation/removal, pain medication, blood transfusion or bone marrow transplantation.
A Gene therapie is still not developed, but scientists are researching to find a treatment to treat the disease on the gene level. The idea behind this is a once applied therapie to fix the defect by mutating the disease causing SNP back to "normal", so that it does not influence the protein product anymore. This futuristic idea raise questions such as technical as well as a ethic and moral questions.