My journey into the world of sphingolipids and sphingolipidoses.
(20/29)
Analysis of lipid storage in postmortem brains of patients with amaurotic idiocy led to the recognition of five lysosomal ganglioside storage diseases and identification of their inherited metabolic blocks. Purification of lysosomal acid sphingomyelinase and ceramidase and analysis of their gene structures were the prerequisites for the clarification of Niemann-Pick and Farber disease. For lipid catabolism, intraendosomal vesicles are formed during the endocytotic pathway. They are subjected to lipid sorting processes and were identified as luminal platforms for cellular lipid and membrane degradation. Lipid binding glycoproteins solubilize lipids from these cholesterol poor membranes and present them to water-soluble hydrolases for digestion. Biosynthesis and intracellular trafficking of lysosomal hydrolases (hexosaminidases, acid sphingomyelinase and ceramidase) and lipid binding and transfer proteins (GM2 activator, saposins) were analyzed to identify the molecular and metabolic basis of several sphingolipidoses. Studies on the biosynthesis of glycosphingolipids yielded the scheme of Combinatorial Ganglioside Biosynthesis involving promiscuous glycosyltransferases. Their defects in mutagenized mice impair brain development and function. (+info)
Sustained activation of sphingomyelin synthase by 2-hydroxyoleic acid induces sphingolipidosis in tumor cells.
(21/29)
Concentrations of an activator protein for sphingolipid hydrolysis in liver and brain samples from patients with lysosomal storage diseases.
(22/29)
The hydrolysis of sphingolipids by lysosomal enzymes requires the presence of additional proteins, which have been called activator proteins. The number of activator proteins, their specificity, exact mechanism of action, and response to a storage process all remain to be determined. In this study, antibodies to an activator protein known to bind sphingolipids and activate the enzymatic hydrolysis of GM1 ganglioside and sulfatide were used to estimate the concentration of this activator protein in small samples of liver and brain from patients with lysosomal storage diseases. By using rocket immunoelectrophoresis, the concentration of cross-reacting material (CRM) was determined. Control livers had an average of 0.95 +/- 0.18 (mean +/- 1 SD) microgram CRM/mg protein in the extracts, and control brains had an average of 0.25 +/- 0.14 microgram CRM/mg protein. Extremely high levels of CRM were found in extracts of livers from patients with type 1 GM1 gangliosidosis (15.1 and 16.9), and type A Niemann-Pick disease (10.7). Extracts of brain samples revealed a large amount of CRM in type 1 GM1 gangliosidosis (14.8), Tay-Sachs disease (5.3 and 8.7), and Sandhoff disease (13.5). Significantly elevated CRM was also measured in brain samples from patients with type 2 GM1 gangliosidosis, type A Niemann-Pick disease, metachromatic leukodystrophy, and Krabbe disease. The highest levels are found in those genetic diseases where the lipids stored, primarily or secondarily to the genetic defect, bind to this activator protein. This activator protein may have an important function in regulating intralysosomal lipid catabolism, and changes in its concentration in certain genetic diseases may be the cause of clinical, biochemical, and pathological heterogeneity found in the patients. (+info)
Basilar artery aneurysm and Anderson-Fabry disease.
(23/29)
A case of basilar artery aneurysm is described. The patient had a family history of similar aneurysms and also of a rare spingolipidosis, Anderson-Fabry disease. (+info)
Diagnosis of metachromatic leukodystrophy, Krabbe disease, and Farber disease after uptake of fatty acid-labeled cerebroside sulfate into cultured skin fibroblasts.
(24/29)
[(14)C]Stearic acid-labeled cerebroside sulfate (CS) was presented to cultured skin fibroblasts in the media. After endocytosis into control cells 86% was readily metabolized to galactosylceramide, ceramide, and stearic acid, which was reutilized in the synthesis of the major lipids found in cultured fibroblasts. Uptake and metabolism of the [(14)C]CS into cells from typical and atypical patients and carriers of metachromatic leukodystrophy (MLD), Krabbe disease, and Farber disease were observed. Cells from patients with late infantile MLD could not metabolize the CS at all, while cells from an adult MLD patient and from a variant MLD patient could metabolize approximately 40 and 15%, respectively, of the CS taken up. These results are in contrast to the in vitro results that demonstrated a severe deficiency of arylsulfatase A in the late infantile and adult patient and a partial deficiency (21-27% of controls) in the variant MLD patient. Patients with Krabbe disease could metabolize nearly 40% of the galactosylceramide produced in the lysosomes from the CS. This is in contrast to the near zero activity for galactosylceramidase measured in vitro. Carriers of Krabbe disease with galactosylceramidase activity near half normal in vitro and those with under 10% of normal activity were found to metabolize galactosylceramide in cells significantly slower than controls. This provides a method for differentiating affected patients from carriers with low enzyme activity in vitro. Cells from patients with Farber disease could catabolize only approximately 15% of the ceramide produced from galactosylceramide. This technique provides a method for the identification of typical and atypical patients and carriers of three genetic diseases using one substrate. (+info)