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The Lysosome and lysosomal storage disorders (LSD) Part 2A Clinical profile of the LSDs Serge Melançon, MD February 2010 SYNOPSIS • • • • • • • Introduction History of the LSDs LSD Sub-Categories Biochemical and Cellular basis of LSD Prevalence Presentation and progression Management Introduction • Tay-Sachs disease was the first lysosomal storage disorder (LSD) described, in 1881 • Gaucher disease was the second, in 1882 • The first link between an enzyme deficiency and a LSD (-glucosidase and Pompe disease) was published in 1963 by Hers • The successful treatment of a LSD, Gaucher disease with β-glucosidase, became available in the early 1990s Introduction • It is now recognized that LSDs are not simply a consequence of pure storage, but result from perturbation of complex cell signaling mechanisms • These in turn give rise to secondary structural and biochemical changes, which have important implications for disease progression and therapy. • Significant challenges remain, particularly targetting treatment to the central nervous and skeletal systems. HISTORY OF THE LSDs Gaucher cell 1882 Ernest GAUCHER (1854-1919) History of the LSDs • Symptoms of some LSDs were described as early as the 1880s, • Many had been described and classified before the lysosome was discovered in 1955 and before their biochemical and genetic basis was fully understood • This is why they received common names (i.e.: Gaucher disease, name of discovering physician). • Later, an additional, more clinically descriptive name often came into use (glucocerebrosidase deficiency) History of the LSDs • By the 1960s the role of lysosomes in cellular digestion and substrate management was well understood, • Pompe became the first disease formally recognized as a lysosomal storage disorder. • By the 1970s scientists had recognized many more LSDs as such and had begun identifying and classifying the specific enzymatic problems. LSD Sub-Categories LSD Sub-Categories • Every LSD results from a problem with the lysosomal process by which enzymes rid cells of substrate. • Lysosomes contain about 50 different hydrolytic enzymes, produced in cell cytoplasm and each responsible for breaking down a particular substrate. LSD Sub-Categories • When a lysosomal enzyme (or another protein that directs it) is deficient or malfunctioning, the substrate it targets accumulates, interfering with normal cellular activity. Healthy cell vs. LSD cell with accumulated substrate LSD Sub-Categories • Sub-categories are based on the type of enzymatic defect and/or stored substrate product. • For example, the mucopolysaccharidoses (MPS) are grouped together because each results from an enzyme deficiency that causes accumulation of particular glycosaminoglycan (GAG) substrates. and diseases that fall under them I - Defective metabolism of glycosaminoglycans " the mucopolysaccharidoses" MPS I (Hurler, Hurler-Scheie, Scheie) MPS II (Hunter) MPS III (San filipo Types A,B,C and D) MPS IV (Morquio type A and B) MPS VI (Maroteaux-Lamy) MPS VII (Sly) MPS IX (Hyaluronidase deficiency) Multiple Sulfatase deficiency II - Defective degradation of glycan portion of glycoproteins Aspartylglucosaminuria Fucosidosis, type I and II Mannosidosis Sialidosis, type I and II III - Defective degradation of glycogen Pompe disease IV - Defective degradation of sphingolipid components Acid sphingomyelinase deficiency (Niemann-Pick A & B) Fabry disease Farber disease Gaucher disease, type I, II and III GM1 gangliosidosis, type I, II and III GM2 gangliosidosis (Tay-Sachs type I, II, III and Sandhoff Krabbe disease Metachromatic leukodystrophy, type I, II and III V - Defective degradation of polypeptides Pycnodysostosis VI - Defective degradation or transport of cholesterol, cholesterol esters, or other complex lipids Neuronal ceroid lipofuscinosis, type I, II, III and IV VII - Multiple deficiencies of lysosomal enzymes Galactosialidosis Mucolipidosis, type II and III VIII - Transport and trafficking defects Cystinosis Danon disease Mucolipidosis type IV Niemann-Pick type C Infantile sialic acid storage disease Salla disease Biochemical and Cellular basis of lysosomal storage disorders Biochemical and Cellular basis of lysosomal storage disorders 1. Most mutations result in the delivery of a defective enzyme with a reduced catalytic activity to lysosomes 2. Another (activator) protein required for optimal hydrolase activity is defective or absent 3. A mutation that causes misfolding results in defective transport of a lysosomal hydrolase out of the endoplasmic reticulum 4. Alternatively, defective transport of a lysosomal hydrolase out of the ER occurs because a multienzyme complex that is required for transport cannot form (Cathepsin A / sialidase / -galactosidase ) Biochemical and Cellular basis of LSDs… 5 In the Golgi, defective glycosylation could result in an enzyme with reduced catalytic activity 6 Alternatively, defective glycosylation with mannose6-phosphate in the Golgi could produce an enzyme that cannot reach lysosomes 7 Defects in other transport steps from the Golgi could also lead to an LSD 8 Defects in integral lysosomal membrane proteins with transporter roles 9 Defects in proteins that are involved in other vital regulatory events of lysosomal function (LAMP2, lysosomal associated membrane protein 2) Biochemical and Cellular basis of LSDs 1 catalytic activity 2 activator 3 misfolding 4 multienzyme complex 5 glycosylation 6 M-6-P targetting 7 other transport steps 8 membrane transporters 9 membrane regulators Futerman AH & van Meer G (2004) 5:554-565