Metachromatic leukodystrophy

From Bioinformatikpedia
Revision as of 14:35, 10 April 2012 by Andrea (talk | contribs) (Biochemical disease mechanism)
(diff) ← Older revision | Latest revision (diff) | Newer revision → (diff)

Summary

Metachromatic leukodystrophy (MLD) is a genetic disorder that affects nerves, muscles, other organs, and behavior. It slowly gets worse over time.

MLD is a lysosomal storage disease that is caused by a deficiency in Arylsulfatase A, leading to an accumulation of the sulfolipid sulfatide . This affects the growth and/or development of myelin. The myelin covering acts as an insulator around nerve fibers throughout the central and peripheral nervous systems.

Phenotype

The disease leads to a toxic buildup of lipids in cells in the nervous system, liver, and kidneys (see below for mechanism). This impairs the function of the cells of the brain and spinal cord as well as the nerves connecting the brain and spinal cord to muscles and sensory cells. This affects the muscle tone, leading to abnormally high muscle tone as well as decreased muscle tone. This in turn leads to walking and feeding difficulties, frequent falls, incontinence, speech difficulties with slurring, etc. It can also effect nerve function and lead to decreased mental function, personality changes, etc. (see PubMed Health).

There are three forms of MLD: late infantile, juvenile, and adult. (see e.g. National Institute of Neurological Disorders and Stroke).

  • The late infantile form is most common (50 to 60 per cent of patients). It sets in between 12 and 20 months following birth. Affected children have difficulty walking after the first year of life and subsequently show muscle wasting leading to paralysis, loss of vision leading to blindness, and dementia. Most children with this form of MLD die by age 5.
  • The juvenile form sets in between 3-10 years of age. It usually begins with impaired school performance. Subsequently symptoms similar to the late infantile form occur, but with slower progression. Death occurs 10 to 20 years following the onset of the disease.
  • The adult form commonly begins after age 16. It is first seen as a psychiatric disorder or progressive dementia. Symptoms include impaired concentration, ataxia, seizures, dementia, and tremor. Death occurs 20 (or 6 according to other sources) to 30 years following the onset of the disease.

Metachromatic leukodystrophy gets its name from the microscopic appearance of cells with the sulfatide (lipid) accumulation that occurs in this disorder. The sulfatides form granules which are metachromatic, which means they pick up color differently than surrounding cellular material when stained for microscopic examination.

Cross-references

See also description of this disease in

Biochemical disease mechanism

  • The symptoms of MLD are caused by the gradual degradation of the myelin sheaths that act as insulators around nerve fibers throughout the central and peripheral nervous systems.
  • The reason for the degradation is the accumulation of sulfatides (sulfated glycosphingolipids), which gradually destroys the cells forming the myelin sheath.
    galactosylceramide sulfate; source: http://www.ebi.ac.uk/chebi
  • The sulfatides accumulate in the lysosome when the enzyme Arylsulfatase A responsible for breaking up sulfatides, is not working. Hence the disease is called a "lysosomal storage disease".
    Lysosome pathways from KEGG
    Sphingolipid metabolism in homo sapiens from KEGG, highlighting Arylsulfatase A
  • The protein Arylsulfatase A
    • has a sequence length of 507 aa,
    • is located in the lysosome,
    • has a Ca cofactor
    • is encoded by the Gene ARSA (see #Genomic information) on chromosome 22.
  • In cells from patients with juvenile and adult forms of MLD, von Figura et al. (1983) found severe deficiency in the arylsulfatase polypeptide, because the mutant enzyme was rapidly degraded upon transport into lysosomes.
  • Some patients with clinical metachromatic leukodystrophy have normal arylsulfatase A activity but lack an activator protein that is involved in sulfatide degradation. (These pages will focus only on mutations in the original Aryslulfatase A.)
  • The fold of the ARS A monomer has significant structural analogy to another hydrolytic enzyme, the alkaline phosphatase. (The active centers are located in largely identical positions.) The functionally essential formylglycine is located in a positively charged pocket and acts as ligand to an octahedrally coordinated metal ion. In the proposed catalytic mechanism, the aldehyde accepts a water molecule to form a hydrate. One of the two hydroxyl groups hydrolyzes the substrate sulfate ester via a transesterification step, resulting in a covalent intermediate. The second hydroxyl serves to eliminate sulfate under inversion of configuration through C-O cleavage and reformation of the aldehyde. (see mechanism graphics in publication based on the first crystal structure)

Cross-references


Treatment

  • Bone marrow and umbilical cord blood transplantation to replace the defective enzyme may slow down the progression.
  • Gene therapy is under development as a possible solution to correct the underlying genetic abnormality.
  • In Europe, ongoing clinical trials are evaluating the safety and efficacy of a recombinant human arylsulfatase A (rhARSA) enzyme, metazym.
  • Physical, occupational and speech therapy to maintain the range of motion.


References

Genomic information

The gene for ARS A lies on chromosome 22.

Chromosome 22 with ARS A gene highlighted, source: http://www.ensembl.org/

MLD shows autosomal recessive inheritance. Only the ASA-/ASA- genotype was is associated with the development of both early- and late-onset MLD, including neuropsychiatric symptoms. Variations in the phenotype can be attributed to different mutations of the ARSA gene that affect the protein activity differently.

Cross-references


Reference sequence, mutations and sequence features

The Uniprot entry for ARS A P15289 gives the protein sequence used as reference in this practical:

>sp|P15289|ARSA_HUMAN Arylsulfatase A OS=Homo sapiens GN=ARSA PE=1 SV=3 
MGAPRSLLLALAAGLAVARPPNIVLIFADDLGYGDLGCYGHPSSTTPNLDQLAAGGLRFT
DFYVPVSLCTPSRAALLTGRLPVRMGMYPGVLVPSSRGGLPLEEVTVAEVLAARGYLTGM
AGKWHLGVGPEGAFLPPHQGFHRFLGIPYSHDQGPCQNLTCFPPATPCDGGCDQGLVPIP
LLANLSVEAQPPWLPGLEARYMAFAHDLMADAQRQDRPFFLYYASHHTHYPQFSGQSFAE
RSGRGPFGDSLMELDAAVGTLMTAIGDLGLLEETLVIFTADNGPETMRMSRGGCSGLLRC 
GKGTTYEGGVREPALAFWPGHIAPGVTHELASSLDLLPTLAALAGAPLPNVTLDGFDLSP
LLLGTGKSPRQSLFFYPSYPDEVRGVFAVRTGKYKAHFFTQGSAHSDTTADPACHASSSL
TAHEPPLLYDLSKDPGENYNLLGGVAGATPEVLQALKQLQLLKAQLDAAVTFGPSQVARG
EDPALQICCHPGCTPRPACCHCPDPHA


Human lysosomal arylsulfatase A (ARS A) requires the posttranslational oxidation of the -CH2SH group of a conserved cysteine to an aldehyde, yielding a formylglycine. Without this modification sulfatases are catalytically inactive (one cause of the disease!).

ARS A exists both as a single chain of 58 kDa (component A) or as a chain of 50 kDa (component B) linked by disulfide bond(s) to a 7 kDa chain (component C).

ARS A binds a Ca-ion that is important for function.