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| Catalog | Product Name | EC No. | CAS No. | Source | Price |
|---|---|---|---|---|---|
| NATE-0463 | Native Bovine Mucopolysaccharidase | 9031-30-5 | Bovine testes | Inquiry |
Mucopolysaccharidases (MPS) are a group of enzymes responsible for the degradation of GAG in the lysosome. Each type of GAG requires a specific MPS enzyme for degradation. For example, heparan sulfate requires alpha-urea sulfate lyase (IDS) for degradation, while dermatan sulfate requires beta-galactosidase (GLB1). Deficiency of any of the MPS enzymes leads to accumulation of the corresponding GAG, resulting in the clinical manifestations of MPS. the severity of MPS depends on the degree of enzyme deficiency and the degree of GAG accumulation. The onset of symptoms varies depending on the type of MPS, but most types are diagnosed in early childhood.
Mucopolysaccharidase deficiency is one of the main causes of mucopolysaccharide metabolism disorders and related diseases. In the presence of mucopolysaccharidase deficiency, mucopolysaccharide molecules cannot be completely degraded and accumulate in tissues and cells, leading to damage and dysfunction. These disorders include mucopolysaccharidoses (MPS) and mucus-forming diseases (mucolipidoses), which are distinctly hereditary and lack effective treatments. Each type of MPS is caused by a specific enzyme deficiency that leads to the accumulation of a particular type of GAG.
Mucopolysaccharidoses are a group of inherited metabolic diseases characterized by the accumulation of glycosaminoglycans (GAGs) in lysosomes due to the lack of an enzyme required for the degradation of mucopolysaccharides.The accumulation of GAGs leads to cellular dysfunction, tissue damage and organ failure, resulting in a wide range of clinical manifestations involving the skeletal, cardiovascular, respiratory, neurological and gastrointestinal systems.
In ERT, patients are given intravenous injections of purified recombinant mucopolysaccharidase to replace the missing enzyme and degrade the accumulated mucopolysaccharide molecules in the body.ERT has become the standard of care for the treatment of MPS and has been remarkably successful in improving patient survival and clinical outcomes. For MPS types I, II, IV, VI and VII, ERT has proven to be a very effective treatment. However, in some cases, ERT may not be effective enough, such as MPS III (Sanfilippo syndrome). In such cases, other treatment modalities may be more appropriate, such as gene therapy and gene repair techniques. These emerging treatments use biotechnology and genetic engineering to introduce normal mucopolysaccharidase genes or produce the correct active enzyme to remedy or restore normal mucopolysaccharide metabolism.
In addition, a number of other therapeutic approaches may help to improve the symptoms and treatment outcome of MPS. For example, normal mucopolysaccharidase genes can be introduced into patients through stem cell transplantation (SCT) to enable long-term enzyme replacement therapy. Substrate reduction therapy may also be used to reduce mucopolysaccharide synthesis and slow the progression of MPS symptoms.
In conclusion, mucopolysaccharidases are an important class of lysosomal enzymes involved in maintaining the normal metabolism and physiological processes of mucopolysaccharides in the body. Mucopolysaccharidase deficiency is one of the major causes of MPS and other mucus-forming disorders.ERT has become the standard of care for MPS and has been remarkably successful in improving patient survival and clinical outcomes. In addition, emerging therapies, such as gene therapy, stem cell transplantation, and substrate reduction therapies, may also help to improve MPS treatment outcomes and improve patient prognosis.
