11/53. Identification of a new complementation group of the peroxisome biogenesis disorders and PEX14 as the mutated gene. Peroxisome biogenesis disorders (PBD) are lethal hereditary diseases caused by abnormalities in the biogenesis of peroxisomes. At present, 12 different complementation groups have been identified and to date, all genes responsible for each of these complementation groups have been identified. The peroxisomal membrane protein PEX14 is a key component of the peroxisomal import machinery and may be the initial docking site for the two import receptors PEX5 and PEX7. Although PEX14 mutants have been identified in yeasts and CHO-cells, human PEX14 deficiency has apparently not been documented. We now report the identification of a new complementation group of the peroxisome biogenesis disorders with PEX14 as the defective gene. Indeed, human PEX14 rescues the import of a PTS1-dependent as well as a PTS2-dependent protein into the peroxisomes in fibroblasts from a patient with zellweger syndrome belonging to the new complementation group. This patient was homozygous for a nonsense mutation in a putative coiled-coil region of PEX14, c.553C>T (p.Q185X). Furthermore, we showed that the patient's fibroblasts lacked PEX14 as determined by immunocytochemical analysis. These findings indicate that there are 13 genotypes in PBD and that the role of PEX14 is also essential in humans. ( info) |
12/53. A human gene responsible for zellweger syndrome that affects peroxisome assembly. The primary defect arising from zellweger syndrome appears to be linked to impaired assembly of peroxisomes. A human complementary dna has been cloned that complements the disease's symptoms (including defective peroxisome assembly) in fibroblasts from a patient with zellweger syndrome. The cause of the syndrome in this patient was a point mutation that resulted in the premature termination of peroxisome assembly factor-1. The homozygous patient apparently inherited the mutation from her parents, each of whom was heterozygous for that mutation. ( info) |
| A preterm (gestational age 34 weeks), small for gestational age infant (birth weight less than P2,3) is described. Because of unexplained slightly disturbed liver function tests at age 2 months, extensive metabolic examinations were performed. Elevated blood levels of very long-chain fatty acids, pipecolic acid and abnormal levels of bile acid intermediates were detected, suggesting a peroxisomal disorder. The plasmalogen content of erythrocytes was decreased. Morphologically distinct peroxisomes were absent in the liver. In fibroblasts an accumulation of very long-chain fatty acids, decreased activity of acyl-CoA:dihydroxyacetone phosphate acyltransferase and impaired de novo biosynthesis of plasmalogens was found. In summary, a mild variant of the classical cerebro-hepato-renal syndrome of Zellweger was found without the characteristic clinical facial signs. ( info) |
14/53. Proton NMR spectroscopy of cerebral metabolic alterations in infantile peroxisomal disorders. Noninvasive studies of cerebral metabolism were performed with use of localized proton MR spectroscopy (MRS) in both healthy controls (n = 4, age 6 weeks to 2 years) and infants (n = 4, age 3-15 months) who had impaired peroxisomal functions classified as variants of zellweger syndrome. All patients revealed a marked decrease of N-acetylaspartate in white and gray matter, thalamus, and cerebellum, indicating impairment of normal neuronal development as well as neuronal loss. In two cases an increase of cerebral glutamine and a decrease of the cytosolic polyol myo-inositol in gray matter and striatum reflected the impact of a concomitant effect on hepatic function. Two cases 3 and 6 months of age exhibited a notable elevation of mobile lipids and/or cholesterol in white matter. These patients with severe disease died within 4 weeks after the MRS examination. While an increase of free fatty acids generally associated with a lysosomal storage disease was not consistently observed by proton MRS of brain, this technique provides a convenient and safe tool for the direct assessment of neuropathologic aspects of zellweger syndrome such as neuronal degeneration, demyelination, and consequences of compromised liver function. ( info) |
| The cerebro-hepato-renal syndrome of Zellweger is the most severe peroxisome biogenesis disorder. zellweger syndrome is caused by a disturbance in the peroxisomal protein import machinery and leads to multiple organ defects and death usually within the first year of life. Here we report a 3-month-old girl with zellweger syndrome who was found to have cysts in the caudothalamic groove on cranial magnetic resonance imaging. ( info) |
| zellweger syndrome (ZS), or cerebrohepatorenal syndrome, was the first described peroxisomal biogenesis disorder. It represents the most severe phenotype, and some of its multiple congenital anomalies can manifest prenatally. Fetal hypokinesia, renal hyperechogenicity, and cerebral ventricular enlargement are the most common reported fetal features. Single and/or late detectable manifestations account for most of the difficulties of prenatal diagnosis, as well as the limitations of ultrasonography itself. prenatal diagnosis, however, can be achieved through (1) assays of concentrations of peroxisomal metabolites (very-long-chain fatty acids, bile acids, intermediates, plasmalogens), (2) activities of peroxisomal enzymes (dihydroacetone-phosphate acyltransferase), or (3) molecular screening techniques, if available. We report on the contribution of MR imaging to the diagnosis of ZS in 2 unrelated fetuses. MR imaging was performed in the third trimester because of cerebral ventricular enlargement diagnosed on routine sonography examinations. In both cases, MR imaging revealed ZS-characteristic abnormal cortical gyral patterns, impaired myelination, and cerebral periventricular pseudocysts. In addition, MR imaging revealed renal microcysts and hepatosplenomegaly in one case. The high level of resolution of MR imaging, which allows analysis of cerebral gyration and myelination, facilitates the prenatal diagnosis of complex polymalformative syndromes such as ZS. ( info) |
| The morphology of hepatic peroxisomes in five patients with metabolic disorders believed to be due to inherited defects of peroxisomal function or biogenesis is described. Electron microscopy and cytochemical staining for catalase were used to identify peroxisomes in two boys with infantile Refsum's disease (IRD), a girl with autopsy confirmed neonatal adrenoleukodystrophy (NALD), and two boys with pseudo-zellweger syndrome (PZS). In the patients with IRD and NALD hepatic peroxisomes were significantly reduced in size and number and contained electron dense centres. In the liver of the patients with PZS the peroxisomes were enlarged. Morphologically abnormal peroxisomes were also detected in autopsy tissue from one boy with PZS using electron microscopy. Lamellar-lipid inclusions and mitochondria with crystalline inclusions and/or abnormal cristae are also described in two patients, one with IRD, the other with NALD. ( info) |
| 1-O-Alkyl and 1-O-alk-1-enyl (plasmalogens) glyceryl ether lipid levels were measured in post-mortem brain and/or liver biopsies from 7 patients with ultrastructural and biochemical evidence of a defect in peroxisomal biogenesis and/or enzymological evidence of a disturbance in ether lipid synthesis. Near normal levels of both species of glyceryl ether lipids were found in neonatal adrenoleukodystrophy and infantile Refsum's disease but marked deficiencies were found in Zellweger's syndrome and rhizomelic chondrodysplasia punctata, the latter manifesting the most profound reduction in ether lipid levels. These observations suggest that little ether lipid biosynthesis occurs in vivo in rhizomelic chondrodysplasia punctata or Zellweger's syndrome. However, in some phenotypes with apparently gross reductions in peroxisomal numbers, e.g. neonatal adrenoleukodystrophy and infantile Refsom's disease, there is significant ether lipid synthesis in liver and brain. ( info) |
19/53. zellweger syndrome: a histochemical diagnosis of two cases. Until 17 years ago the diagnosis of the cerebrohepatorenal zellweger syndrome (ZS) rested largely on clinical grounds confirmed by pathologic findings at autopsy. The observation that peroxisomes are not detectable morphologically or histochemically in liver or kidney of patients with this syndrome gave histopathologists the opportunity to make the diagnosis of this complex syndrome at biopsy. catalase reaction of the peroxisomes can be used as a rapid and accurate method to differentiate between ZS and other clinical conditions in which the peroxisomes are present in normal or reduced number. We describe two patients in whom the diagnosis of ZS was made by the absence of histochemical staining for catalase in a liver biopsy. The findings were subsequently confirmed using standard biochemical tests. ( info) |
20/53. Cortical cytoarchitectural and immunohistochemical studies on zellweger syndrome. In two cases of zellweger syndrome, Golgi studies revealed an irregular neuronal arrangement, the presence of immature neurons, poor dendritic arborization and poor spine development, all of which suggest abnormal morphogenesis and delayed maturation. In immunohistochemical studies with antisera against human catalase, negative staining of neurons suggested a decrease of catalase due to defects of microperoxisomes, and positive staining of myelination glia only in the internal capsule may have been related to delayed myelination. Abnormal peroxisomal membrane or its related metabolites may cause a migration disorder in intrauterine development and myelination disturbance in perinatal maturation. ( info) |