[Niemann-Pick disease (Crocker's type C): ultrastructural study of a case (author's transl)]

A Drosophila model of the Niemann-Pick type C lysosome storage disease: dnpc1a is required for molting and sterol homeostasis

Niemann-Pick type C (NPC) disease is a fatal autosomal-recessive neurodegenerative disorder characterized by the inappropriate accumulation of unesterified cholesterol in aberrant organelles. The disease is due to mutations in either of two genes, NPC1, which encodes a transmembrane protein related to the Hedgehog receptor Patched, and NPC2, which encodes a secreted cholesterol-binding protein. Npc1 mutant mice can be partially rescued by treatment with specific steroids. We have created a Drosophila NPC model by mutating dnpc1a, one of two Drosophila genes related to mammalian NPC1. Cells throughout the bodies of dnpc1a mutants accumulated sterol in a punctate pattern, as in individuals with NPC1 mutations. The mutants developed only to the first larval stage and were unable to molt. Molting after the normal first instar period was restored to various degrees by feeding the mutants the steroid molting hormone 20-hydroxyecdysone, or the precursors of ecdysone biosynthesis, cholesterol and 7-dehydrocholesterol. dnpc1a is normally highly expressed in the ecdysone-producing ring gland. Ring gland-specific expression of dnpc1a in otherwise mutant flies allowed development to adulthood, suggesting that the lack of ecdysone in the mutants is the cause of death. We propose that dnpc1a mutants have sterols trapped in aberrant organelles, leading to a shortage of sterol in the endoplasmic reticulum and/or mitochondria of ring gland cells, and, consequently, inadequate ecdysone synthesis.

A Riddle Wrapped in a Mystery: Understanding Niemann-Pick Disease, Type C

BACKGROUND

Niemann-Pick disease, type C (NPC), is a lipid storage disease that may present at any age from fetal life to the seventh decade. Its protean manifestations include hepatic and pulmonary failure, as well as a range of progressive neuropsychiatric phenotypes. Late onset disease has been increasingly recognized as the biochemical diagnosis of NPC has been more widely applied.

REVIEW SUMMARY

The phenotypes, biochemical, and molecular bases of NPC are reviewed. Indistinguishable phenotypes are produced by mutations in two distinct genes, designated NPC 1 and NPC 2, that play key roles in the intracellular trafficking of lipids. The diagnosis of NPC is challenging as the characteristic vertical supranuclear gaze palsy is difficult to recognize, organomegaly is often absent, and standard biochemical screening studies are usually normal. Definitive diagnosis requires demonstration of the trafficking defect in cultured fibroblasts, supplemented in selected cases by genotyping. Animal studies have shown that inhibition of glycosphingolipid synthesis may delay the onset of disease and prolong survival; a human trial of this approach is underway.

CONCLUSIONS

NPC is a model for inborn errors of metabolism whose gene product mediates molecular trafficking rather than catabolizing macromolecules, as in classic lipid storage diseases. NPC should be considered in the differential diagnosis of progressive neurodegenerative disorders at any age. The astute clinician can provide great comfort to families afflicted by NPC by making an accurate diagnosis, notwithstanding the absence of definitive treatment.

Fetal Niemann-Pick disease type C: ultrastructural and lipid findings in liver and spleen

We present the first ultrastructural study of liver and spleen from a 20-week fetus with Niemann-Pick disease type C in correlation with lipid studies of these tissues. The lipid storage pattern was characteristic of the disease and although the distribution of the lipid storage was similar to that of affected children, ultrastructural studies emphasized that many inclusions were qualitatively different. These are discussed. Concomitant with this complex lipid storage, ultrastructural evidence of cholestasis was observed and the early hyperplasia of pericanalicular microfilaments leads us to question the presence of a toxic metabolite which might induce cholestasis by acting upon microfilaments.

Feline sphingolipidosis resembling Niemann-Pick disease type C

A 9-week old domestic short-hair kitten with progressive neurological dysfunction had histopathological lesions consistent with a lysosomal storage disease. Light microscopy of the brain, spinal cord, and ganglia revealed distention and vacuolation of many neuronal populations, and extensive neuroaxonal dystrophy. Large numbers of foamy macrophages were observed in the liver, spleen, lymph nodes, and lung. Hepatocytes appeared pale and swollen. Ultrastructural examination of all affected tissues and organs revealed heterogeneous membranous inclusions. Lipid analysis of liver revealed an excess of cholesterol, glucosylceramide, lactosylceramide and phospholipids including sphingomyelin. There was some increase in the levels of brain GM2 and GM3 gangliosides. Sphingomyelinase activity in liver was partially deficient or low normal. Skin fibroblasts were cultured from two affected cats from the colony established with littermates of the subject of this report. The cultured skin fibroblasts had partially decreased sphingomyelinase activity and a greatly decreased ability to esterify exogenous cholesterol. Clinical, morphological, and biochemical findings suggest that this cat had sphingolipidosis similar to human Niemann-Pick disease type C, a disease not previously described in the cat. The feline form of this storage disease may provide a useful model for studies on the human disease.

Niemann-Pick disease

Results of the investigation carried out during this decade brought unambigous evidence of biochemical heterogeneity inside the complex of Niemann-Pick disease according to which two entirely different metabolic disorders can be recognized. 1. Niemann-Pick sphingomyelinosis, a clear-cut enzymopathy, the pivotal lesion of which is the deficiency of lysosomal spingomyelinase leading to widespread lysosomal deposition of sphingomyelin liquid crystals. Two main allelic variants are known. The first one, neuronopathic (former type A) known as infantile with rapid course, may also manifest considerably prolonged course or an atypical course with predominantly visceral symptomatology. Patients with the second, visceral, variant (former type B), display mainly slow clinical course and often reach adulthood. With rare exceptions the neuronopathic variant can be biochemically recognized from the visceral one by much lower values of the in vivo sphingomyelin degradation test in the former. 2. The rest of the complex comprising types C-D differs substantially from the sphingomyelinase deficiency group by the remarkable heterogeneity in the lysosomal stored lipid pattern given by differences among the affected cell populations. Sphingomyelin storage could be proved histochemically solely in the histiocytic population together with cholesterol, neutral glycosphingolipids and lysobisphosphatidic acid, whereas the brain neurons displayed only neutral glycosphingolipid storage. There is an increasing evidence of the crucial biochemical lesion in this group being an altered intracellular traffic of exogenously derived cholesterol caused probably by its deficient translocation from lysosomes to other intracellular membrane sites. This leads to decreased cholesterol esterification rate which is the basis of the newly developed diagnostic test. Inconstant depression of sphingomyelinase activity is considered to be a secondary phenomenon. The so-called lactosylceramidosis is a rare variant pertinent to this group. The biochemical nature of type E still awaits clarification. Both groups of Niemann-Pick disease display clinical and especially histochemical features which allows to establish diagnosis in a highly efficient way already at the clinicopathological level.

Diagnosis of juvenile-adult form of neuroaxonal dystrophy by electron microscopy of rectum and skin biopsy

Images

Niemann-Pick disease type C. Study on the nature of the cerebral storage process

A complex neuropathological study of two cases of Niemann-Pick disease (NPD) type C (NPDC) revealed some novel features in the chemical pathology of the neuronal storage. Lipid histochemistry showed the presence of a lipid which met the criteria of a neuronal glycosphingolipid. Sphingomyelin (SM) was not detected in the neurones in any of the regions examined. Lipid chemical analysis of total extracts and of partially purified lysosomal fraction of the brain cortex showed markedly increased levels of neutral ceramide hexosides especially of glucosylceramide and ceramide dihexoside (mostly of its slower band). Phospholipids were not significantly increased. Monosialogangliosides GM2 and GM3 were increased only slightly. The storage process displayed the well known fine structure and was accompanied by a marked secondary increase in some lysosomal enzyme activities. There was neuroaxonal dystrophy (NAD) of considerable intensity and extent. Many spheroids contained masses of degenerated organelles and neurofilaments in various proportions and displayed variable activities of acid phosphatase, nonspecific esterase and dehydrogenases. There was marked brain atrophy accompanied in one case by severe demyelination. Enzyme studies revealed partial decrease of sphingomyelinase (SMase) and beta-glucosidase activities in cultured fibroblasts, as well as lack of cathodic SMase activity on isoelectric focusing. No defects of these enzymes were found in the brain samples. The findings are regarded as significant since they indicate a biochemical defect in which SM is not primarily involved and which may thus be fundamentally different from that in type A of NPD.

Niemann-Pick disease: lipid storage in bone marrow macrophages

A histochemical study of lipids in bone marrow smears was performed in a series of 15 cases of Niemann-Pick disease (NPD). It revealed significant differences in the amount of lipids stored in macrophages of sphingomyelinase (SMase) deficiency (types A, B) and type C. Early deposition of uniform, anisotropic droplets of sphingomyelin (Maltese-cross birefringence) in lysosomes was a feature of a 9-member group of SMase deficiency (types A, B). The type C group (six cases) was characterized by a remarkable difference in the degree of phospholipid, mainly sphingomyelin, deposition. The total amount of phospholipids was small on average, and very often inversely proportional to pronounced structural storage changes. This indirect relationship was most prominent in the early phase of the disease and grew less prominent as the disease progressed further. The stored lipid was primarily isotropic. In longer lasting cases of both categories (SMase deficiency and type C) a considerable part of the storage cell population displayed ceroid deposition giving the appearance of a 'sea-blue histiocyte' independent of the type of NPD, but with definite predominance in SMase deficiency. The diagnostic value of the findings is discussed, and some pathogenetic conclusions suggested, particularly as regards type C. Lipid histochemistry of bone marrow smears is highly recommended as it represents a simple but highly efficient approach, capable of yielding valuable diagnostic information.

Adult neurovisceral lipidosis compatible with Niemann-Pick disease type C

The authors present a case of neurovisceral storage disease with the whole of its clinical course confined to adult life (symptoms from 26 to 46 years of age) and marked by mainly neurological symptomatology with dystonia, vertical supranuclear ophthalmoplegia and progressive mental deterioration as the dominant features. From the results of postmortem structural histochemical and chemical analysis the case was diagnosed as Niemann-Pick disease type C. This case, together with sporadic observations reported by other authors, represents a significant shift in our view of the incidence of NPD type C in older age groups.

Retinal abnormalities in ophthalmoplegic lipidosis

Images