Difference between revisions of "Gaucher Disease"
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+ | The autosomal recessive disease, Gaucher's disease, caused by a defect protein (glucocerebrosidase) in the lipid metabolism. Through this sphingolipidosis (lysosomal storage disease) there can be found an accumulation of sphingolipids in cells, that leads to a morbid impact on the body. The disease was first described in 1882 by a French doctor Philippe Gaucher, after whom it is named. |
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− | '''Note:''' this page is not finished yet! :) |
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+ | <figure id="t1" > |
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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 an accumulation of sphingolipids in cells, that leads to a morbid impact on the body. The disease was first described in 1882 by a French doctor Philippe Gaucher, after whom it is named. |
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+ | [[File:gaucher_disease.gif|thumb|500px|'''<caption>''' Symptoms of type I Gaucher's disease (source [http://drugline.org/medic/term/gaucher-disease/ drugline.org])</caption>]] |
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+ | </figure> |
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− | == |
+ | ==Phenotypic Description of the Disease== |
− | There exist three phenotypic expressions of the Gaucher's disease. Dependent |
+ | There exist three main phenotypic expressions of the Gaucher's disease (in <xr id="type"/>). Dependent on the severeness of the disease, different symptoms may occur (<xr id="t1"/>). Moreover, the age at which the first symptoms appear, is in connection with the degree of illness. |
+ | ===Classification of Types and Symptoms=== |
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+ | <figure id="type" > |
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− | === Classification of types and symptoms === |
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+ | [[Image:gaucher-types-002.gif|thumb|550px|'''<caption>''' Phenotypes of Gaucher types (source: [http://www.childrensgaucher.org/about-gaucher/gaucher-basics/ Children's Gaucher Research Fund]) </caption>]] |
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+ | </figure> |
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+ | ====Type I: Non-Neuropathic==== |
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− | [[Image:gaucher-types-002.gif|thumb|550px|Phenotypes of Gaucher types (source: [http://www.childrensgaucher.org/about-gaucher/gaucher-basics/ Children's Gaucher Research Fund]) ]] |
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+ | The most common type of the Gaucher's disease has also the mildest illness degree. It mostly occurs the first time in adulthood. |
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− | ==== Type I: non-neuropathic ==== |
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− | |||
− | The most common type of the Gaucher's disease has also the mildest illnes degree. It mostly occurs the first time in adulthood. |
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Symptoms, that may occur in type I: |
Symptoms, that may occur in type I: |
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* '''skeletal abnormalities''' (osteopenia, bone pain/fractures) |
* '''skeletal abnormalities''' (osteopenia, bone pain/fractures) |
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* '''hepatomegaly''' (enlarged liver) |
* '''hepatomegaly''' (enlarged liver) |
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− | * '''splenomegaly''' (enlarged spleen) that causes '''anemia''' ( |
+ | * '''splenomegaly''' (enlarged spleen) that causes '''anemia''' (decreased amount of healthy red blood cells) and can result in '''thrombocytopenia''' (faster bruising, because of the low number of blood platelets) as well as '''nosebleeds''' |
− | * '''pingueculae''' (yellow spots in |
+ | * '''pingueculae''' (yellow spots in the eyes) |
* '''delayed puberty''' |
* '''delayed puberty''' |
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+ | ====Type II: Acute Infantile Neuropathic==== |
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+ | The second disease form starts at the infant stage and has the severest degree of illness. Most children with this type of Gaucher do not reach the age of five. |
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− | ==== Type II: acute infantile neuropathic ==== |
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− | |||
− | 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. |
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Symptoms, that may occur in type II: |
Symptoms, that may occur in type II: |
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* '''type I symptoms''' |
* '''type I symptoms''' |
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* rapidly process of '''brain damage''' (mental retardation, dementia) |
* rapidly process of '''brain damage''' (mental retardation, dementia) |
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− | * ''' |
+ | * '''rigidity''' |
− | * ''' |
+ | * '''seizures''' |
+ | ====Type III: Chronic Neuropathic==== |
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− | |||
− | ==== Type III: chronic neuropathic ==== |
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The Type III of Gaucher’s disease begins in childhood or adolescence. |
The Type III of Gaucher’s disease begins in childhood or adolescence. |
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* slow '''brain damage''' (mental retardation, dementia) |
* slow '''brain damage''' (mental retardation, dementia) |
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− | === |
+ | ===References=== |
− | |||
[http://en.wikipedia.org/wiki/Gaucher%27s_disease http://en.wikipedia.org/wiki/Gaucher%27s_disease] |
[http://en.wikipedia.org/wiki/Gaucher%27s_disease http://en.wikipedia.org/wiki/Gaucher%27s_disease] |
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[http://www.mayoclinic.com/health/gauchers-disease/DS00972/DSECTION=symptoms http://www.mayoclinic.com/health/gauchers-disease/DS00972/DSECTION=symptoms] |
[http://www.mayoclinic.com/health/gauchers-disease/DS00972/DSECTION=symptoms http://www.mayoclinic.com/health/gauchers-disease/DS00972/DSECTION=symptoms] |
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+ | ==Gene and Protein Causing the Disease== |
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− | == Biochemical disease mechanism == |
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+ | <figure id="chr" > |
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+ | [[File:chromosome_band_1q22.JPG|thumb|100px|'''<caption>''' Chromosome 1, band 1q22 (source: [http://fmp-8.cit.nih.gov/hembase/detail.php?chrb=1q22 Hembase Search])</caption>]] |
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+ | </figure> |
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+ | <figure id="comp" > |
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+ | [[File:Acid_beta_glucosidase.png|thumb|'''<caption>''' Structure of lysosomal glucocerebrosidase (source: [http://en.wikipedia.org/wiki/Gaucher%27s_disease Wikipedia, Gaucher's disease])</caption>]] |
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+ | </figure> |
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+ | <figure id="ca" > |
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+ | [[File:1ogs_bio_r_500.jpeg|thumb|'''<caption>''' Structure of lysosomal glucocerebrosidase chain A (source: [http://www.rcsb.org/pdb/explore/explore.do?structureId=1OGS PDB])</caption>]] |
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+ | </figure> |
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+ | The cause of Gaucher's disease is a recessive mutation in a houskeeping gene lysosomal glucocerebrosidase (acid beta-glucosidase, glucosylceramidase) on chromosome 1 (<xr id="chr"/>), coding for an enzyme. |
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− | [[Image:pathway_bearbeitet.jpg|thumb|400px|Sphingolipid Metabolism (source: [http://www.genome.jp/kegg-bin/show_pathway?ec00600+3.2.1.45 KEGG]) ]] |
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+ | Some information about the defect gene/protein is presented in the following table. |
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+ | {| border="1" |
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− | 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. |
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+ | !colspan="2"|''Defect Enzyme in Gaucher's Disease'' |
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+ | |- |
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+ | |Gene symbol || GBA |
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+ | |- |
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+ | |Cytogenetic location || 1q22 |
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+ | |- |
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+ | |Genomic coordinates || 1-155,204,238-155,214,652 |
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+ | |- |
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+ | |Number of exons || 11 |
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+ | |- |
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+ | | EC number || 3.2.1.45 |
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+ | |- |
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+ | | Names || |
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+ | * glucocerebrosidase |
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+ | * beta-glucocerebrosidase |
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+ | * beta-D-glucocerebrosidase |
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+ | * glucosylcerebrosidase |
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+ | * acid beta-glucosidase |
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+ | * GlcCer-beta-glucosidase |
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+ | * ceramide glucosidase |
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+ | * glucosylsphingosine beta-glucosidase |
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+ | * glucosylsphingosine beta-D-glucosidase |
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+ | * glucosylceramidase |
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+ | * beta-glucosylceramidase |
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+ | * alglucerase |
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+ | * imiglucerase |
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+ | * psychosine hydrolase |
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+ | * glucosphingosine glucosylhydrolase |
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+ | * D-glucosyl-N-acylsphingosine glucohydrolase |
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+ | |- |
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+ | | PDB || |
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+ | * structure: 1OGS |
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+ | * molecular weight: 55.6 KD |
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+ | * length: 497 amino acids |
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+ | |- |
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+ | | UniProt || |
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+ | * entry: P04062 |
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+ | * molecular weight: 59.716 KD |
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+ | * length: 536 amino acids |
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+ | |} |
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+ | ===Reference Sequence=== |
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+ | Sequence of Glucosylceramidase (source: [http://www.uniprot.org/uniprot/P04062.fasta Uniprot]): |
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− | [[Image:gaucher-cell.gif|thumb|300px|Development of a Gaucher cell (source: [http://www.childrensgaucher.org/about-gaucher/gaucher-basics/ Children's Gaucher Research Fund]) ]] |
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+ | >sp|P04062|GLCM_HUMAN Glucosylceramidase OS=Homo sapiens GN=GBA PE=1 SV=3 |
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+ | MEFSSPSREECPKPLSRVSIMAGSLTGLLLLQAVSWASGARPCIPKSFGYSSVVCVCNAT |
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+ | YCDSFDPPTFPALGTFSRYESTRSGRRMELSMGPIQANHTGTGLLLTLQPEQKFQKVKGF |
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+ | GGAMTDAAALNILALSPPAQNLLLKSYFSEEGIGYNIIRVPMASCDFSIRTYTYADTPDD |
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+ | FQLHNFSLPEEDTKLKIPLIHRALQLAQRPVSLLASPWTSPTWLKTNGAVNGKGSLKGQP |
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+ | GDIYHQTWARYFVKFLDAYAEHKLQFWAVTAENEPSAGLLSGYPFQCLGFTPEHQRDFIA |
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+ | RDLGPTLANSTHHNVRLLMLDDQRLLLPHWAKVVLTDPEAAKYVHGIAVHWYLDFLAPAK |
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+ | ATLGETHRLFPNTMLFASEACVGSKFWEQSVRLGSWDRGMQYSHSIITNLLYHVVGWTDW |
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+ | NLALNPEGGPNWVRNFVDSPIIVDITKDTFYKQPMFYHLGHFSKFIPEGSQRVGLVASQK |
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+ | NDLDAVALMHPDGSAVVVVLNRSSKDVPLTIKDPAVGFLETISPGYSIHTYLWRRQ |
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===References=== |
===References=== |
||
[http://en.wikipedia.org/wiki/Gaucher%27s_disease Wikipedia, Gaucher's disease] |
[http://en.wikipedia.org/wiki/Gaucher%27s_disease Wikipedia, Gaucher's disease] |
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+ | [http://en.wikipedia.org/wiki/Glucocerebrosidase Wikipedia, Glucocerebrosidase] |
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− | [http://www.childrensgaucher.org/about-gaucher/gaucher-basics/ Children's Gaucher Research Fund] |
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+ | [http://www.rcsb.org/pdb/explore/explore.do?structureId=1OGS PDB database, structure ID 1OGS] |
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− | == Inheritance and Incidence == |
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− | |||
− | * 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. |
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− | |||
− | [[File:gaucher_inheritance.gif|thumb|Autosomal recessive inheritance [http://www.childrensgaucher.org/about-gaucher/gaucher-basics/ Children's Gaucher Research Fund]]] |
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+ | [http://www.uniprot.org/uniprot/P04062 UniProt, entry P04062] |
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− | * According to National Gaucher Foundation (USA) nearly 1 person in 20,000 has Gaucher's disease. |
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+ | |||
− | * 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. |
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+ | [http://www.genome.jp/dbget-bin/www_bget?3.2.1.45 KEGG, Enzyme: 3.2.1.45] |
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− | * '''Type II''' Gaucher's disease does not seem to be preferentially represented by a specific ethnic group. |
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+ | |||
− | * '''Type III''' Gaucher's disease occurs most frequently in the northern Swedish region of Norrbotten. The incidence is 1 in 50,000 there. |
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+ | [http://omim.org/entry/606463 OMIM, entry 606463] |
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+ | |||
+ | ==Biochemical Disease Mechanism== |
||
+ | <figure id="pathway" > |
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+ | [[Image:pathway_bearbeitet.jpg|thumb|400px|'''<caption>''' Sphingolipid Metabolism (source: [http://www.genome.jp/kegg-bin/show_pathway?ec00600+3.2.1.45 KEGG]) </caption>]] |
||
+ | </figure> |
||
+ | |||
+ | 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 glucosylceramide accumulates. The macrophages that are affected by such an accumulation are called Gaucher cells (<xr id="cell"/>). |
||
+ | |||
+ | <figure id="cell" > |
||
+ | [[Image:gaucher-cell.gif|thumb|300px|'''<caption>'''Development of a Gaucher cell (source: [http://www.childrensgaucher.org/about-gaucher/gaucher-basics/ Children's Gaucher Research Fund])</caption> ]] |
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+ | </figure> |
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===References=== |
===References=== |
||
+ | [http://en.wikipedia.org/wiki/Gaucher%27s_disease Wikipedia, Gaucher's disease] |
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+ | |||
[http://www.childrensgaucher.org/about-gaucher/gaucher-basics/ Children's Gaucher Research Fund] |
[http://www.childrensgaucher.org/about-gaucher/gaucher-basics/ Children's Gaucher Research Fund] |
||
+ | ==Mutations Associated with the Disease== |
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− | [http://en.wikipedia.org/wiki/Gaucher%27s_disease Wikipedia, Gaucher's disease] |
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+ | * The phenotype may depend on the activity of acid beta-glucosidase, which is determined by the different mutations. |
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− | == Gene and mutations associated with the disease == |
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+ | * According to OMIM, round 200 mutations have been found in patients with all types of the Gaucher's disease. According to Wikipedia, there are about 80 known mutations causing Gaucher's disease. The mutations can be divided into three main groups, according to the prevalence in the Goucher's types. |
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− | * The cause of Gaucher disease is a recessive mutation in a houskeeping gene lysosomal glucocerebrosidase (beta-glucosidase, glucosylceramidase) on chromosome 1 (1q21). |
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+ | ===Gaucher Type I=== |
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− | * The defect protein is an enzyme with the following properties: |
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+ | Gaucher disease type I is caused by homozygous or compound heterozygous mutation in the gene encoding acid beta-glucosidase. |
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− | ** EC number 3.2.1.45 |
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+ | Mutations: |
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− | ** PDB structure 1OGS. The molecular weight of the determined structure is 55.6 KD and length 497 amino acids. |
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+ | * '''L444P''' substitution on a single allele (compound heterozygous with e.g. N370S mutation) |
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− | ** UniProt entry P04062. The molecular weight of the native protein is 59.716 KD and length 536 amino acids. |
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+ | * '''N370S''' substitution, cases among Ashkenazi Jews, homozygous or on a single allele (Zimran et al.(1991) found that among 62 Ashkenazi Jewish patients with type I Gaucher disease, N370S appeared in 73% of the 124 mutant alleles.) |
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+ | ===Gaucher Type II=== |
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+ | Mutations: |
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+ | * '''L444P''' substitution, homozygous or on a single allele (Wigderson et al. (1989) reported a case of compound heterozygous with L444P and P415R.) |
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+ | |||
+ | ===Gaucher Type III=== |
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+ | Mutations: |
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+ | * '''L444P''' substitution, homozygous (Dahl et al.(1990) showed that the Norrbottnian form of Gaucher's disease is caused by a homozygous L444P mutation and Koprivica et al.(2000) approved that the homozygosity for L444P is associated with type III Gaucher's disease.) |
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+ | * Park et al. (2003) studied 16 patients from a rare subgroup (IIIA) of Gaucher's disease type III with progressive myoclonic epilepsy. They detected 14 different genotypes with several shared alleles, including '''V394L''', '''G377S''', and '''N188S'''. Some of the shared alleles in these subtype IIIA patients had previously been associated with non-neuronopathic Gaucher disease (type I). According to other studies, these patients lacked the processed 56-kD enzyme isoform which usually indicates neuronopathic disease. The genotypes differed from those found in most type III patients. Nevertheless, Park et al. (2003) concluded that "lack of a specific shared genotype and the variability of clinical presentations indicated a contribution by other genetic and environmental modifiers"[http://omim.org/entry/231000]. |
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+ | * Also according to Wikidepia, the L444P mutation, homozygous or on a single allele, is possibly delayed by protective polymorphisms among type III patients. |
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+ | ===Cross risk-factors=== |
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− | {{Infobox Defect Enzyme in Gaucher's Disease |
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+ | * Interesting is that heterozygous 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. |
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− | | EC number 3.2.1.45 |
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+ | |||
− | | Names = * glucosylceramidase |
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+ | * 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. |
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− | * psychosine hydrolase |
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− | * glucosphingosine glucosylhydrolase |
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− | * GlcCer-beta-glucosidase |
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− | * beta-D-glucocerebrosidase |
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− | * glucosylcerebrosidase |
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− | * beta-glucosylceramidase |
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− | * ceramide glucosidase |
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− | * glucocerebrosidase |
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− | * glucosylsphingosine beta-glucosidase |
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− | * glucosylsphingosine beta-D-glucosidase |
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− | | Structure = [[File:Acid_beta_glucosidase.png|thumb|Structure of lysosomal glucocerebrosidase (source: [http://en.wikipedia.org/wiki/Gaucher%27s_disease Wikipedia, Gaucher's disease])]] |
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− | | PDB = * structure: 1OGS |
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− | * molecular weight: 55.6 KD |
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− | *length: 497 amino acids |
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− | | UniProt = * entry: P04062 |
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− | * molecular weight: 59.716 KD |
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− | *length: 536 amino acids |
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− | }} |
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+ | ===References=== |
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− | * The phenotype depends on the activity of the beta-glucosidase, which is determined by the different mutations. |
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+ | [http://en.wikipedia.org/wiki/Gaucher%27s_disease Wikipedia, Gaucher's disease] |
||
+ | [http://omim.org/entry/606463 OMIM, entry 606463 - GBA] |
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− | * There are about 80 known mutations causing Gaucher's disease, divided into three main groups, according to the Goucher's types they cause: |
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− | ** '''Type I:''' N370S homozygote (2 copies) |
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− | ** '''Type II:''' 1-2 copies of L444P |
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− | ** '''Type III:''' 1-2 copies of L444P possibly delayed by protective polymorphisms |
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+ | [http://omim.org/entry/230800 OMIM, entry 230800 - Gaucher type I] |
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− | * 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. |
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+ | |||
+ | [http://omim.org/entry/230900 OMIM, entry 230900 - Gaucher type II] |
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+ | |||
+ | [http://omim.org/entry/231000 OMIM, entry 231000 - Gaucher type III] |
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+ | |||
+ | ==Inheritance and Incidence== |
||
+ | |||
+ | <figure id="auto" > |
||
+ | [[File:gaucher_inheritance.gif|thumb|'''<caption>''' Autosomal recessive inheritance (source: [http://www.childrensgaucher.org/about-gaucher/gaucher-basics/ Children's Gaucher Research Fund])</caption>]] |
||
+ | </figure> |
||
+ | |||
+ | * The disease befalls both females and males. It is inherited in autosomal recessive manner (<xr id="auto"/>). 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. |
||
− | * 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. |
||
+ | |||
+ | * '''Type III''' Gaucher's disease occurs most frequently in the northern Swedish region of Norrbotten. The incidence is 1 in 50,000 there. |
||
− | === |
+ | ===References=== |
+ | [http://www.childrensgaucher.org/about-gaucher/gaucher-basics/ Children's Gaucher Research Fund] |
||
[http://en.wikipedia.org/wiki/Gaucher%27s_disease Wikipedia, Gaucher's disease] |
[http://en.wikipedia.org/wiki/Gaucher%27s_disease Wikipedia, Gaucher's disease] |
||
+ | ==Diagnosis== |
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− | [http://en.wikipedia.org/wiki/Glucocerebrosidase Wikipedia, Glucocerebrosidase] |
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+ | <figure id="gc" > |
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− | [http://www.rcsb.org/pdb/explore/explore.do?structureId=1OGS PDB database, structure ID 1OGS] |
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+ | [[File:gaucher_cells.gif|thumb|300px|'''<caption>''' Gaucher cells (source: [http://www.makethediagnosis.com/hem/mtd_hem_opportunities.asp makethediagnosis.com])</caption>]] |
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+ | </figure> |
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− | [http://www.uniprot.org/uniprot/P04062 UniProt, entry P04062] |
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+ | A diagnosis of Gaucher’s disease is possible. There exist a number of possibilities. |
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− | == Diagnosis == |
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+ | * The first diagnosis of the disease was done by Desnick et al. (1971), who demonstrated that homozygote as well as heterozygote defected alleles could be identified by chemical analysis of the '''sediment from a 24-hour urine collection'''. Individual neutral glycosphingolipids were separated by thin-layer chromatography and quantitatively estimated by gas-liquid chromatography, as recorded in OMIM. |
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− | Diagnosis of Gaucher’s disease is possible. Two possibilities exist: |
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+ | |||
− | * '''Blood test:''' tests the activity of beta-glococerebrosidase. |
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+ | * '''Genetic testing (DNA analysis, genotyping)''' is done by sequencing the beta-glucocerebrosidase gene and checking for the known mutations. This may be done prenatally, if there is a known genetic risk factor for the disease. It is one of the most reliable ways to confirm the diagnosis of the disease as well as to detect if the person is a carrier. |
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− | * '''DNA analysis (genotyping):''' examination of the gene for typical mutations (N370S, L444P). |
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+ | |||
+ | * Reliable diagnosis is possible today with a simple blood test where the '''activity of beta-glucocerebrosidase''' is determined. A very deficient enzyme activity indicates Gaucher's disease. The test is done in special laboratories. |
||
+ | |||
+ | * Certain '''nonspecific abnormalities''' in patients with type I Gaucher's disease can also be identified with blood examinations, for example: |
||
+ | ** high levels of glucosylceramide, angiotensin-converting enzyme (ACE), TRAP, ferritin levels, chitotriosidase, alkaline phosphatase and gamma globulins |
||
+ | ** low levels of LDL and HDL cholesterol, B12 and clotting factors |
||
+ | |||
+ | * '''Cell analysis''' can detect "crinkled paper" macrophages (also called Gaucher cells, <xr id="gc"/>). |
||
+ | |||
+ | Even though reliable diagnostic methods exist, it is difficult to detect Gaucher's disease. Hematologists may not immediately suspect this rare disease, because the patients have symptoms analogous to other diverse diseases (among them Acute lymphocytic leukemia, Acute myelogenous leukemia, Multiple myeloma, Lymphoma and ITP). |
||
+ | |||
+ | ===References=== |
||
+ | [http://omim.org/entry/230800 OMIM, entry 230800 - Gaucher type I] |
||
− | === References === |
||
[http://www.gaucher.de/diagnose/wie-wird-diagnostiziert.html www.gaucher.de] |
[http://www.gaucher.de/diagnose/wie-wird-diagnostiziert.html www.gaucher.de] |
||
+ | [http://en.wikipedia.org/wiki/Gaucher%27s_disease#Diagnosis Wikipedia, Gaucher's disease] |
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− | == Treatment == |
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+ | |||
− | 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. |
||
+ | [http://www.makethediagnosis.com/hem/mtd_hem_opportunities.asp www.makethediagnosis.com] |
||
+ | |||
+ | ==Treatment== |
||
+ | |||
+ | 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. |
||
+ | |||
===Applied treatments=== |
===Applied treatments=== |
||
− | * '''Enzyme replacement treatment:''' To compensate for the missing amount of glucocerebrosidase a biotechnological produced protein is used. This recombinant glucocerebrosidase (imiglucerase), is intravenous applied to the body. It decreases the size of liver and spleen as well as it reduces skeletal abnormalities. The treatment mechanism is comparable with the procedure of an insulin therapie used of diabetes patient. (t1+t3) [wie diabetes] |
||
− | * '''Substrate reduction therapie:''' The 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. |
||
+ | * '''Enzyme replacement treatment (ERT):''' To compensate for the missing amount of glucocerebrosidase a biotechnological produced protein is used. This recombinant glucocerebrosidase (imiglucerase) is intravenous applied to the body. It decreases the size of liver and spleen as well as it reduces skeletal abnormalities. The treatment mechanism is comparable with the procedure of an insulin therapie used of diabetes patient. |
||
− | ===Future Treatments=== |
||
+ | * '''Substrate reduction therapie (SRT):''' The therapie inhibits the development of the substrate glucosylceramide, e.g. by using miglustat[http://informahealthcare.com/doi/abs/10.1517/13543784.12.2.273], to minimize the accumulation of the waste products. Thereby the small amount of glucocerebrosidase suffices to process the substrate. |
||
− | 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. |
||
+ | * '''Symptomatic therapie:''' This therapy eases the symptoms by using organ transplantation or removal, pain medication, blood transfusion or bone marrow transplantation. |
||
+ | The treatments differ in their acting. While the symptomatic therapie only treats the phenotypes of the disease, the other treatments act into the metabolic pathways and try to avoid the development of the phenotypes of the Gaucher's disease. Which of these two treatments is applied depends on the Gaucher type. The enzyme replacement treatment is mostly used for patients of Gaucher's disease of all types. In some cases of Gaucher's disease type I the ERT is not applicable. The substrate reduction therapie is an option for those patients. The ERT and SRT have to be applied regularly for a lifetime. |
||
+ | ===Future Treatments=== |
||
− | compensate for the missing amount of proteins |
||
+ | 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 ones. |
||
===References=== |
===References=== |
||
− | |||
[http://www.gaucher.de/behandlung/enzymersatztherapie.html www.gaucher.de] |
[http://www.gaucher.de/behandlung/enzymersatztherapie.html www.gaucher.de] |
||
Line 162: | Line 261: | ||
[http://www.gauchercare.com/healthcare/TreatmentOptions.aspx www.gauchercare.com] |
[http://www.gauchercare.com/healthcare/TreatmentOptions.aspx www.gauchercare.com] |
||
+ | |||
+ | ==Tasks== |
||
+ | * Link to Task 02: [[Gaucher_Disease:_Task_02_-_Alignments|Alignments]] |
||
+ | * Link to Task 03: [[Gaucher_Disease:_Task_03_-_Sequence-based_predictions|Sequence-based predictions]] |
||
+ | * Link to Task 04: [[Gaucher_Disease:_Task_04_-_Structural Alignment|Structural Alignment]] |
||
+ | * Link to Task 05: [[Gaucher_Disease:_Task_05_-_Homology Modelling|Homology Modelling]] |
||
+ | * Link to Task 06: [[Gaucher_Disease:_Task_06_-_Protein structure prediction from evolutionary sequence variation|Protein structure prediction from evolutionary sequence variation]] |
||
+ | * Link to Task 07: [[Gaucher_Disease:_Task_07_-_Research SNPs|Research SNPs]] |
||
+ | * Link to Task 08: [[Gaucher_Disease:_Task_08_-_Sequence-based mutation analysis|Sequence-based mutation analysis]] |
||
+ | * Link to Task 09: [[Gaucher_Disease:_Task_09_-_Structure-based mutation analysis|Structure-based mutation analysis]] |
||
+ | * Link to Task 10: [[Gaucher_Disease:_Task_10_-_Normal mode analysis|Normal mode analysis]] |
Latest revision as of 23:06, 4 September 2013
The autosomal recessive disease, Gaucher's disease, caused by a defect protein (glucocerebrosidase) in the lipid metabolism. Through this sphingolipidosis (lysosomal storage disease) there can be found an accumulation of sphingolipids in cells, that leads to a morbid impact on the body. The disease was first described in 1882 by a French doctor Philippe Gaucher, after whom it is named.
<figure id="t1" >
</figure>
Contents
Phenotypic Description of the Disease
There exist three main phenotypic expressions of the Gaucher's disease (in <xr id="type"/>). Dependent on the severeness of the disease, different symptoms may occur (<xr id="t1"/>). Moreover, the age at which the first symptoms appear, is in connection with the degree of illness.
Classification of Types and Symptoms
<figure id="type" >
</figure>
Type I: Non-Neuropathic
The most common type of the Gaucher's disease has also the mildest illness 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 (decreased amount of healthy red blood cells) and can result in thrombocytopenia (faster bruising, because of the low number of blood platelets) as well as nosebleeds
- pingueculae (yellow spots in the 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 do not reach the age of five. Symptoms, that may occur in type II:
- type I symptoms
- rapidly process of brain damage (mental retardation, dementia)
- rigidity
- seizures
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)
References
http://en.wikipedia.org/wiki/Gaucher%27s_disease
http://www.mayoclinic.com/health/gauchers-disease/DS00972/DSECTION=symptoms
Gene and Protein Causing the Disease
<figure id="chr" >
</figure> <figure id="comp" >
</figure> <figure id="ca" >
</figure>
The cause of Gaucher's disease is a recessive mutation in a houskeeping gene lysosomal glucocerebrosidase (acid beta-glucosidase, glucosylceramidase) on chromosome 1 (<xr id="chr"/>), coding for an enzyme.
Some information about the defect gene/protein is presented in the following table.
Defect Enzyme in Gaucher's Disease | |
---|---|
Gene symbol | GBA |
Cytogenetic location | 1q22 |
Genomic coordinates | 1-155,204,238-155,214,652 |
Number of exons | 11 |
EC number | 3.2.1.45 |
Names |
|
PDB |
|
UniProt |
|
Reference Sequence
Sequence of Glucosylceramidase (source: Uniprot):
>sp|P04062|GLCM_HUMAN Glucosylceramidase OS=Homo sapiens GN=GBA PE=1 SV=3 MEFSSPSREECPKPLSRVSIMAGSLTGLLLLQAVSWASGARPCIPKSFGYSSVVCVCNAT YCDSFDPPTFPALGTFSRYESTRSGRRMELSMGPIQANHTGTGLLLTLQPEQKFQKVKGF GGAMTDAAALNILALSPPAQNLLLKSYFSEEGIGYNIIRVPMASCDFSIRTYTYADTPDD FQLHNFSLPEEDTKLKIPLIHRALQLAQRPVSLLASPWTSPTWLKTNGAVNGKGSLKGQP GDIYHQTWARYFVKFLDAYAEHKLQFWAVTAENEPSAGLLSGYPFQCLGFTPEHQRDFIA RDLGPTLANSTHHNVRLLMLDDQRLLLPHWAKVVLTDPEAAKYVHGIAVHWYLDFLAPAK ATLGETHRLFPNTMLFASEACVGSKFWEQSVRLGSWDRGMQYSHSIITNLLYHVVGWTDW NLALNPEGGPNWVRNFVDSPIIVDITKDTFYKQPMFYHLGHFSKFIPEGSQRVGLVASQK NDLDAVALMHPDGSAVVVVLNRSSKDVPLTIKDPAVGFLETISPGYSIHTYLWRRQ
References
PDB database, structure ID 1OGS
Biochemical Disease Mechanism
<figure id="pathway" >
</figure>
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 glucosylceramide accumulates. The macrophages that are affected by such an accumulation are called Gaucher cells (<xr id="cell"/>).
<figure id="cell" >
</figure>
References
Children's Gaucher Research Fund
Mutations Associated with the Disease
- The phenotype may depend on the activity of acid beta-glucosidase, which is determined by the different mutations.
- According to OMIM, round 200 mutations have been found in patients with all types of the Gaucher's disease. According to Wikipedia, there are about 80 known mutations causing Gaucher's disease. The mutations can be divided into three main groups, according to the prevalence in the Goucher's types.
Gaucher Type I
Gaucher disease type I is caused by homozygous or compound heterozygous mutation in the gene encoding acid beta-glucosidase. Mutations:
- L444P substitution on a single allele (compound heterozygous with e.g. N370S mutation)
- N370S substitution, cases among Ashkenazi Jews, homozygous or on a single allele (Zimran et al.(1991) found that among 62 Ashkenazi Jewish patients with type I Gaucher disease, N370S appeared in 73% of the 124 mutant alleles.)
Gaucher Type II
Mutations:
- L444P substitution, homozygous or on a single allele (Wigderson et al. (1989) reported a case of compound heterozygous with L444P and P415R.)
Gaucher Type III
Mutations:
- L444P substitution, homozygous (Dahl et al.(1990) showed that the Norrbottnian form of Gaucher's disease is caused by a homozygous L444P mutation and Koprivica et al.(2000) approved that the homozygosity for L444P is associated with type III Gaucher's disease.)
- Park et al. (2003) studied 16 patients from a rare subgroup (IIIA) of Gaucher's disease type III with progressive myoclonic epilepsy. They detected 14 different genotypes with several shared alleles, including V394L, G377S, and N188S. Some of the shared alleles in these subtype IIIA patients had previously been associated with non-neuronopathic Gaucher disease (type I). According to other studies, these patients lacked the processed 56-kD enzyme isoform which usually indicates neuronopathic disease. The genotypes differed from those found in most type III patients. Nevertheless, Park et al. (2003) concluded that "lack of a specific shared genotype and the variability of clinical presentations indicated a contribution by other genetic and environmental modifiers"[1].
- Also according to Wikidepia, the L444P mutation, homozygous or on a single allele, is possibly delayed by protective polymorphisms among type III patients.
Cross risk-factors
- Interesting is that heterozygous 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.
References
OMIM, entry 230800 - Gaucher type I
OMIM, entry 230900 - Gaucher type II
OMIM, entry 231000 - Gaucher type III
Inheritance and Incidence
<figure id="auto" >
</figure>
- The disease befalls both females and males. It is inherited in autosomal recessive manner (<xr id="auto"/>). 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.
References
Children's Gaucher Research Fund
Diagnosis
<figure id="gc" >
</figure>
A diagnosis of Gaucher’s disease is possible. There exist a number of possibilities.
- The first diagnosis of the disease was done by Desnick et al. (1971), who demonstrated that homozygote as well as heterozygote defected alleles could be identified by chemical analysis of the sediment from a 24-hour urine collection. Individual neutral glycosphingolipids were separated by thin-layer chromatography and quantitatively estimated by gas-liquid chromatography, as recorded in OMIM.
- Genetic testing (DNA analysis, genotyping) is done by sequencing the beta-glucocerebrosidase gene and checking for the known mutations. This may be done prenatally, if there is a known genetic risk factor for the disease. It is one of the most reliable ways to confirm the diagnosis of the disease as well as to detect if the person is a carrier.
- Reliable diagnosis is possible today with a simple blood test where the activity of beta-glucocerebrosidase is determined. A very deficient enzyme activity indicates Gaucher's disease. The test is done in special laboratories.
- Certain nonspecific abnormalities in patients with type I Gaucher's disease can also be identified with blood examinations, for example:
- high levels of glucosylceramide, angiotensin-converting enzyme (ACE), TRAP, ferritin levels, chitotriosidase, alkaline phosphatase and gamma globulins
- low levels of LDL and HDL cholesterol, B12 and clotting factors
- Cell analysis can detect "crinkled paper" macrophages (also called Gaucher cells, <xr id="gc"/>).
Even though reliable diagnostic methods exist, it is difficult to detect Gaucher's disease. Hematologists may not immediately suspect this rare disease, because the patients have symptoms analogous to other diverse diseases (among them Acute lymphocytic leukemia, Acute myelogenous leukemia, Multiple myeloma, Lymphoma and ITP).
References
OMIM, entry 230800 - Gaucher type I
Treatment
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.
Applied treatments
- Enzyme replacement treatment (ERT): To compensate for the missing amount of glucocerebrosidase a biotechnological produced protein is used. This recombinant glucocerebrosidase (imiglucerase) is intravenous applied to the body. It decreases the size of liver and spleen as well as it reduces skeletal abnormalities. The treatment mechanism is comparable with the procedure of an insulin therapie used of diabetes patient.
- Substrate reduction therapie (SRT): The therapie inhibits the development of the substrate glucosylceramide, e.g. by using miglustat[2], to minimize the accumulation of the waste products. Thereby the small amount of glucocerebrosidase suffices to process the substrate.
- Symptomatic therapie: This therapy eases the symptoms by using organ transplantation or removal, pain medication, blood transfusion or bone marrow transplantation.
The treatments differ in their acting. While the symptomatic therapie only treats the phenotypes of the disease, the other treatments act into the metabolic pathways and try to avoid the development of the phenotypes of the Gaucher's disease. Which of these two treatments is applied depends on the Gaucher type. The enzyme replacement treatment is mostly used for patients of Gaucher's disease of all types. In some cases of Gaucher's disease type I the ERT is not applicable. The substrate reduction therapie is an option for those patients. The ERT and SRT have to be applied regularly for a lifetime.
Future Treatments
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 ones.
References
Children's Gaucher Research Fund
Tasks
- Link to Task 02: Alignments
- Link to Task 03: Sequence-based predictions
- Link to Task 04: Structural Alignment
- Link to Task 05: Homology Modelling
- Link to Task 06: Protein structure prediction from evolutionary sequence variation
- Link to Task 07: Research SNPs
- Link to Task 08: Sequence-based mutation analysis
- Link to Task 09: Structure-based mutation analysis
- Link to Task 10: Normal mode analysis