Neuronal Ceroid Lipofuscinosis: An Ultrastructural,Genetic, and Clinical Study Report

The term "neuronal ceroid lipofuscinosis" (NCL) describes a complex of inherited neurodegenerative conditions associated with storage of lipopigments in brain tissue. In 1989 Dyken proposed a classification of NCL based on the age, clinical symptoms, and ultrastructural aspects of the lipopigments. At the ultrastructural level it is possible to distinguish 5 different patterns of osmiophilic lipopigments: usual lipofuscin, fingerprint deposits, granular profiles, curvilinear bodies, and microtubular aggregates. The concept that each ultrastructural pattern was the counterpart of a specific clinical type has been proved not to be true. Advances in molecular genetic techniques have allowed the identification of defective genes and their protein products in several NCL clinical forms. Ceroid lipofuscin deposits may be ultrastructurally observed not only in neuronal cells, but also in several other sites, such as trophoblastic cells, thus permitting prenatal diagnosis. In spite of recent advances in immunohistochemical identification of biochemical markers, the ultrastructural identification of lipofuscinic pigments remains the gold standard to identify NCL, together with clinical aspects and respective gene defects. This study describes the ultrastructural aspects observed in 8 cases of NCL syndromes (3 juvenile, 3 infantile, 1 late infantile, and 1 congenital clinical form). In these patients, genetic analysis was also performed.     

Neuronal ceroid lipofuscinosis: an ultrastructural, genetic, and clinical study report

The term "neuronal ceroid lipofuscinosis" (NCL) describes a complex of inherited neurodegenerative conditions associated with storage of lipopigments in brain tissue. In 1989 Dyken proposed a classification of NCL based on the age, clinical symptoms, and ultrastructural aspects of the lipopigments. At the ultrastructural level it is possible to distinguish 5 different patterns of osmiophilic lipopigments: usual lipofuscin, fingerprint deposits, granular profiles, curvilinear bodies, and microtubular aggregates. The concept that each ultrastructural pattern was the counterpart of a specific clinical type has been proved not to be true. Advances in molecular genetic techniques have allowed the identification of defective genes and their protein products in several NCL clinical forms. Ceroid lipofuscin deposits may be ultrastructurally observed not only in neuronal cells, but also in several other sites, such as trophoblastic cells, thus permitting prenatal diagnosis. In spite of recent advances in immunohistochemical identification of biochemical markers, the ultrastructural identification of lipofuscinic pigments remains the gold standard to identify NCL, together with clinical aspects and respective gene defects. This study describes the ultrastructural aspects observed in 8 cases of NCL syndromes (3 juvenile, 3 infantile, 1 late infantile, and 1 congenital clinical form). In these patients, genetic analysis was also performed.     

Diagnosis of Neuronal Ceroid Lipofuscinosis (Batten Disease) by Electron Microscopy in Peripheral Blood Specimens

Neuronal ceroid lipopofuscinosis (Batten disease, NCL) represents a group of common childhood neurodegenerative diseases with a shared feature of deposition of abnormal metabolic products in neurons and other tissues, including peripheral blood lymphocytes. In most forms of NCL no specific enzyme defect is known and the diagnosis relies primarily on ultrastructural identification of characteristic membrane-bound inclusions containing the abnormal metabolic product. All buffy-coat specimens examined during a 7-year period (1997–2004) for the exclusion or confirmation of the diagnosis NCL were reviewed. From a total of 265 samples, 9 were inadequate and NCL was diagnosed in 56. Five showed granular osmophilic deposits of infantile Batten disease (NCL1), 10 showed curvilinear profiles of classical late infantile Batten disease (NCL2), and 17 showed vacuolated lymphocytes with fingerprint profiles, indicating classical juvenile Batten disease (NCL3). 24 samples (43%) demonstrated compact electron-dense deposits with fingerprint profiles in the absence of vacuolated lymphocytes, indicative of variant forms NCL. Ultrastructual examination of peripheral blood allows reliable and specific diagnosis of subtypes of Batten disease, including variants, and is a useful, minimally invasive test for the diagnosis of NCL in childhood.     

Diagnosis of neuronal ceroid lipofuscinosis (Batten disease) by electron microscopy in peripheral blood specimens

Neuronal ceroid lipopofuscinosis (Batten disease, NCL) represents a group of common childhood neurodegenerative diseases with a shared feature of deposition of abnormal metabolic products in neurons and other tissues, including peripheral blood lymphocytes. In most forms of NCL no specific enzyme defect is known and the diagnosis relies primarily on ultrastructural identification of characteristic membrane-bound inclusions containing the abnormal metabolic product. All buffy-coat specimens examined during a 7-year period (1997-2004) for the exclusion or confirmation of the diagnosis NCL were reviewed. From a total of 265 samples, 9 were inadequate and NCL was diagnosed in 56. Five showed granular osmophilic deposits of infantile Batten disease (NCL1), 10 showed curvilinear profiles of classical late infantile Batten disease (NCL2), and 17 showed vacuolated lymphocytes with fingerprint profiles, indicating classical juvenile Batten disease (NCL3). 24 samples (43%) demonstrated compact electron-dense deposits with fingerprint profiles in the absence of vacuolated lymphocytes, indicative of variant forms NCL. Ultrastructual examination of peripheral blood allows reliable and specific diagnosis of subtypes of Batten disease, including variants, and is a useful, minimally invasive test for the diagnosis of NCL in childhood.     

Neuronal ceroid lipofuscinosis. Closing chapter of a long story

Neuronal ceroid lipofuscinoses represent a group of diseases which has until quite recently resisted definite elucidation of the underlying defect(s) on the molecular level. The common feature of all the NCLs is a serious and progressive neurological disorder, accompanied, with only few exceptions, by retinal degeneration. Visceral symptoms, despite the presence of the storage process, are absent, or minimal. There are many clinical variants of the disease process, among which a set of standard, historical phenotypes exists found to be linked to specific genotypes. The disorder is inherited and transmitted as an autosomal recessive trait. At the cellular level, it is featured by lyzosomal storage of autofluorescent hydrophobic material, the substantial part of which consists of hydrophobic proteins and esterified dolichol. The dominant protein is the subunit c of mitochondria ATP synthase. In one NCL type (NCL1) the dominant proteins are saposins A and D. Ultrastructural appearance is membranous with several relatively specific patterns with some tendency to condensation or, namely in NCL3 to vacuolar distension. Amorphous appearance is associated with NCL1. The impact of the disease process on the cell biology differs substantially depending on the cell type. The brain neurons are most seriously affected and degenerate, whereas other cell types mostly survive without detectable deterioration. Pathogenesis at the molecular level is now being elucidated using the modern molecular biology techniques, which have already enabled unravelling of a set of genes controlling majority of the standard historical phenotypes. The original infantile form of NCL (NCL1) is now defined as palmitoyl protein thioesterase deficiency (gen at the 1p32 locus), the late infantile form (NCL2) as pepstatin resistant proteinase deficiency (gen at the 11p15.5 locus) and the original juvenile form (NCL3) as a defect of the specific gene (locus 16p11.2-12.3), the product of which, the NCL3 protein, still lacks functional characterization. Two gene loci have been identified in the so-called early juvenile, or variant late infantile NCL. One of them is in the 13q21 locus (NCL5 or Finnish variant late infantile form), the second is in the 15q21-23 one (NCL6). Kufs form remains the least defined form of NCL. Recently two novel NCL variants were described with specific loci. Thanks to introduction of molecular genetic based diagnosis it was possible to recognize, besides the standard phenotype, existence of further phenotypic variants. The phenotype based scheme of NCL has thus been definitely substituted by classification based on genotype and biochemistry.     

The Neuronal Ceroid-Lipofuscinoses. Recent Advances

The neuronal ceroid lipofuscinoses (NCLs) represent a group of neurodegenerative disorders characterised by progressive visual failure, neurodegeneration, epilepsy and the accumulation of an autofluorescent lipopigment in neurons and other cells. The main childhood subtypes are infantile (INCL; CLN1 ), classical late infantile (LINCL; CLN2 ) and juvenile NCL (J NCL; CLN3 ), distinguished on the basis of age of onset, clinical course and ultrastructural morphology, and recently genetic analysis. In addition several variant forms of the disease complex have been described as well as a rare adult onset form. Advances in both genetics and biochemistry have led to the identification of the genes for the three main subtypes of childhood NCL and their corresponding protein products and to mapping of two additional genes for two variant forms. The disease causing genes in both INCL and classical LINCL have been shown to encode lysosomal enzymes whilst the JNCL gene codes for a protein whose function is as yet unknown.     

Neuronal ceroid-lipofuscinoses in Italy: An epidemiological study

To establish the incidence of neuronal ceroid-lipofuscinoses (NCL) in Italy, we sent a questionnaire to all Neuropediatric and Child Neuropsychiatric Departments (answer rate 15/34 = 44%). Diagnoses were accepted only when based on firm clinical and/or electron microscopic criteria. We collected 58 cases born between 1966–1991 (2 infantile NCL, 37 late infantile NCL, and 19 juvenile NCL). The incidence was calculated only on patients born between 1974–1984. In this period, the incidence of overall NCL in the Italian population was calculated to be 0.56 per 100,000 live births (0.36 for late infantile NCL, and 0.20 for juvenile NCL). Our data show that infantile NCL is very rare in Italy, and that late infantile seems to be the most frequent form of NCL. © 1995 Wiley-Liss, Inc.     

Protease inhibitors as a model for NCL disease, with special emphasis on the infantile and adult forms.

An animal model of NCL disease has been developed with the use of protease inhibitors. Young rats received a continuous infusion of various specific protease inhibitors or of physiological saline into the lateral ventricle of the brain using osmotic mini-pumps. Treatment lasted for 2 weeks, at which time animals were sacrificed and the brains were removed and processed for light or electron microscopic analysis. The thiol protease inhibitors leupeptin and E64C, but not saline or the serine protease inhibitor aprotinin, caused a massive accumulation of ceroid-lipofuscin (CL) in brain cells that bore a strong morphological resemblance to the CL in the infantile and adult forms of NCL disease, and bore similarity to the CL of the late infantile and juvenile forms. Leupeptin also caused the death of cerebellar Purkinje cells, as is seen in the infantile and adult forms of NCL. Further evidence is presented in support of the hypothesis (Ivy et al.: Science 226:985-987, 1984) that decreased or defective lysosomal thiol proteases or their substrates may underly the pathogenesis of at least the infantile and adult forms of NCL disease. Administration of protease inhibitors to the brains of young rats provides an important model for studying the cellular mechanisms of ceroid-lipofuscino-genesis.     

Variability in the clinical and pathological findings in the neuronal ceroid lipofuscinoses: review of data and observations.

We reviewed the clinical and pathological data on 319 neuronal ceroid lipofuscinosis (NCL) cases to determine the degree of variability within the different forms and among and within families. Thirty-six cases (11.3%) were the infantile form; 116 cases (36.3%), late infantile; 163 cases (51.1%), juvenile; and four cases (1.3%), the adult form (Kufs disease). Clinical variability was found in all forms studied, but was most striking in the juvenile and late infantile forms of NCL. The expected initial findings of seizures, dementia, blindness, or motor impairment were evident in 255 cases (80%), and rarer, less typical initial neurological symptoms were seen mainly in the 64 cases (20%) of the juvenile form: behavior abnormalities (18/64), psychoses (12/64), neuropathy (2/64), involuntary movements (15/64), ataxia (9/64). Six juvenile and two adult cases had no detectable impairment of vision. All 319 NCL cases had skin or conjunctive biopsies or buffy coats that showed the characteristic ultrastructural abnormalities of NCL. Variability was evident in 16.7% in that a combination of fingerprint, curvilinear, and membranous profile inclusion bodies was observed in storage lysosomes, although one type of inclusion was distinctly predominant for each form. Postmortem examination of brains of 19 NCL cases (three with the infantile form, six with the late infantile form, nine with the juvenile form, and one with the adult form) revealed characteristic changes. Sixteen of the 19 NCL brains (84%) showed pathological variability in that they contained more than one kind of characteristic inclusion body in the neuronal lysosomal storage compartment. In all 19 NCL brains, small amounts of aging lipofuscin were also found.(ABSTRACT TRUNCATED AT 250 WORDS)     

Variability in the clinical and pathological findings in the neuronal ceroid lipofuscinoses: Review of data and observations

We reviewed the clinical and pathological data on 319 neuronal ceroid lipofuscinosis (NCL) cases to determine the degree of variability within the different forms and among and within families. Thirty-six cases (11.3%) were the infantile form; 116 cases (36.3%), late infantile, 163 cases (51.1%), juvenile; and four cases (1.3%), the adult form (Kufs disease). Clinical variability was found in all forms studied, but was most striking in the juvenile and late infantile forms of NCL. The expected initial findings of seizures, dementia, blindness, or motor impairment were evident in 255 cases (80%), and rarer, less typical initial neurological symptoms were seen mainly in the 64 cases (20%) of the juvenile form: behavior abnormalities (18/64), psychoses (12/64), neuropathy (2/64), involuntary movements (15/64), ataxia (9/64), Six juvenile and two adult cases had no detectable impairment of vision. All 319 NCL cases had skin or conjunctiva biopsies or buffy that showed the characteristic ultrastructural abnormalities of NCL. Variability was evident in 16.7% in that a combination of fingerprint, curvilinear, and membranous profile inclusion bodies was observed in storage lysosomes, although one type of inclusion was distinctly predominant for each form. Postmortem examination of brains of 19 NCL cases (three with the infantile form, six with the late infantile form, nine with the juvenile form, and one with the adult form) revealed characteristic changes, Sixteen of the 19 NCL brains (84%) showed pathological variability in that they contained more than one kind of characteristic inclusion body in the neuronal lysosomal storage compartment. In all 19 NCL brains, small amounts of aging lipofuscin were also found. In three late infantile cases, neuronal cytoplasmic inclusion bodies were found mainly in the basal ganglia, midbrain, and cerebellar (BG), At the ultrastructural level, theses inclusions were found to be large lysosomes filled with very densely packed curvilinear profiles. Histological and immunocytochemical staining properties of these basal ganglial, midbrain, and cerebellar neurons were found to be different from those storage neurons of other brain regions in this subform and other NCL forms. Therefore, we conclude that these cases represent a distinct NCL subtype. More confounding was the discovery of several neuritic plaques in the fronto-temporal lobes of a 53-year-old female with the adult form. Our present results reveal theat not all epitopes of amyloid β-precursor protein (APP) can be detected in the NCL brain, and moreover, their distribution and intensity of immunostaining vary, not only among different NCL forms but in some instances with the same forms. The significance of high levels of epitope expression of certain APP domains in NCL brains is still unknown and needs further biochemical studies.     

Linkage analysis of late-infantile neuronal ceroid-lipofuscinosis

The neuronal ceroid-lipofuscinoses (NCL) are a group of neurodegenerative disorders with an autosomal-recessive pattern of inheritance. There are 3 main categories of childhood NCL, namely, infantile, late-infantile, and juvenile NCL. These can be distinguished on the basis of age of onset, clinical course, and histopathology. A number of variant forms of NCL have also been described, and these show symptoms intermediary between the main classical forms. The genes for both the infantile and juvenile forms of NCL have previously been mapped to chromosome areas 1p32 and 16p12, respectively. The gene for late-infantile NCL (LINCL), CLN2, has been excluded from both these loci, but its location is as yet unknown. Recently, CLN5, the gene for the Finnish variant form of LINCL, was mapped to 13q21.1–32. Using the 3 microsatellite markers which were most tightly linked to CLN5, we have excluded CLN2 from this region using a subset of 17 families. Thus, CLN2 represents a fourth distinct genetic locus involved in the pathogenesis of NCL. © 1995 Wiley-Liss, Inc.     

Clinical and molecular analysis of Japanese patients with neuronal ceroid lipofuscinosis

Neuronal ceroid lipofuscinosis (NCL) is one of the most common inherited neurological diseases in childhood. It occurs every 12,500 births in northern-European populations. Mental retardation, visual impairment, and seizures are common symptoms. The prevalence of NCL is variable depending upon the races or countries. Although a wealth information is available in Caucasian populations, there is little information about NCL in Asian people. Because a nationwide survey in Japanese patients with NCL has never been performed, we pursued an epidemiological survey. We identified 36 NCL patients in Japan. Patients with infantile, late infantile, juvenile, and adult type accounted for 2, 15, 15, and 4 cases, respectively. Seizures were a major initial symptom in the late infantile type. In the juvenile type, visual failure was present in 73% at onset. Recently, the juvenile NCL (Batten disease) gene has been isolated. Studies of the mutations in this gene demonstrated that a 1.02-kb deletion was the most prevalent mutation among Caucasian patients, accounting for 81% of total alleles. To determine the prevalence of this 1.02-kb deletion in Japanese patients, we performed a rapid allele-specific polymerase chain reaction test. No 1.02-kb major deletion was detected in 5 Japanese juvenile NCL cases. These data suggest that the distribution of NCL and clinical findings are similar to those of Caucasian subjects; however, prevalence of mutations in Japanese patients with NCL would be distinct from that observed in Caucasians.     

Neuronal ceroid lipofuscinosis (nclf), a new disorder of the mouse linked to chromosome 9

The neuronal ceroid lipofuscinoses (NCLs) comprise a set of at least 6 distinct human and an unknown number of animal diseases characterized by storage of proteolipids in lysosomes of many cell types. By unknown mechanisms, this accumulation leads to or is associated with severe neuronal and retinal degeneration. The genes for 3 human NCLs, infantile, late infantile, and juvenile, have been cloned. The first murine form of NCL, the motor neuron degeneration (mnd) mouse, has been described and mapped to proximal Chromosome 8. Here we describe a second genetic variant of NCL in the mouse, neuronal ceroid lipofuscinosis, nclf. These mice exhibited a phenotype that was almost exactly the same as that observed in mnd/mnd mice. Homozygous nclf mice developed progressive retinal atrophy early in life and become paralyzed at around 9 months of age. They accumulated luxol fast blue staining material in cytoplasm of neurons and many other cell types. Ultrastructurally, affected lysosomes had a “finger print pattern” with membranous material arranged in “pentalaminar” patterns. Affected mice developed severe cerebral gliosis in late stages of their disease. They also had severe Wallerian degeneration of long tracts in spinal cord and brain stem, lesions that accounted for the distinctive upper motor neuron signs displayed by both nclf/nclf and mnd/mnd mice. By crossing nclf/nclf mice with CAST/Ei mice, linkage analysis of nclf with respect to SSLP markers was performed, showing that nclf is located on Chromosome 9 between D9Mit164 and D9Mit165, in a region that is homologous with human Ch 15q21, where the gene for one variant of late infantile NCL, CLN6, recently has been mapped. The genes for two proteolipids known to be stored in lysosomes of animals and people with NCL were also mapped in this study and found not to map to the mnd or nclf loci nor to any mouse locus homologous to any known human NCL disease locus. Am. J. Med. Genet. 77:289–297, 1998. © 1998 Wiley-Liss, Inc.     

Update of the mutation spectrum and clinical correlations of over 360 mutations in eight genes that underlie the neuronal ceroid lipofuscinoses

The neuronal ceroid lipofuscinoses (NCLs) are clinically and genetically heterogeneous neurodegenerative disorders. Most are autosomal recessively inherited. Clinical features include a variable age of onset, motor and mental decline, epilepsy, visual loss, and premature death. Mutations in eight genes (PPT1/CLN1, TPP1/CLN2, CLN3, CLN5, CLN6, MFSD8/CLN7, CLN8) have been identified and several more are predicted to exist, including two provisionally named CLN4 and CLN9. Despite excessive in vitro and in vivo studies, the precise functions of the NCL proteins and the disease mechanisms remain elusive. To date 365 NCL-causing mutations are known, with 91 novel disease-causing mutations reported. These are reviewed with an emphasis on their complex correlation to phenotypes. Different mutations within the NCL spectrum can cause variable disease severity. The NCLs exemplify both phenotypic convergence or mimicry and phenotypic divergence. For example, mutations in CLN5, CLN6, MFSD8, or CLN8 can underlie the clinically similar late infantile variant NCL disease. Phenotypic divergence is exemplified by different CLN8 mutations giving rise to two very different diseases, the mild CLN8 disease, EPMR (progressive epilepsy with mental retardation), and the more severe CLN8 disease, late infantile variant. The increase in the genetic understanding of the NCLs has led to improved diagnostic approaches, and the recent proposal of a new nomenclature.     

Variant late infantile neuronal ceroid lipofuscinosis in a subset of Turkish patients is allelic to Northern epilepsy

Childhood-onset neuronal ceroid lipofuscinoses (NCL) are a group of autosomal recessive progressive encephalopathies characterized by the accumulation of autofluorescent material in various tissues, notably in neurons. Based on clinical features, the country of origin of patients, and the molecular genetic background of the disorder, at least seven different forms are thought to exist. Northern epilepsy is a novel form of NCL so far described only in Finland, where all patients are homozygous for a missense mutation in the CLN8 gene. A variant form of late infantile NCL (vLINCL) present in Turkish patients has been considered a distinct clinical and genetic entity among the NCL, the underlying gene (CLN7) being unknown. Recently, we reported homozygosity over the Northern epilepsy CLN8 gene region on 8p23 in four out of five Turkish vLINCL families studied. However, no common mutation in CLN8 was found in these families. We have now extended the Turkish vLINCL family panel to 18 families, of which only one is nonconsanguineous. Nine families were excluded from CLN8 by lack of homozygosity. In the remaining families, four CLN8 gene mutations were identified indicating that in a subset of patients with Turkish vLINCL, the disorder is allelic to Northern epilepsy. There is no apparent genotype-phenotype correlation among the Turkish patients with CLN8 mutations, although their phenotype is distinct from that of Finnish Northern epilepsy patients. The molecular genetic background of the Turkish vLINCL families not linked to CLN8 remains to be clarified.     

Anomalies of mitochondrial ATP synthase regulation in four different types of neuronal ceroid lipofuscinosis

Several neuronal ceroid lipofuscinoses (NCL) show storage of subunit c of mitochondrial ATP synthase. The neurodegenerative process, however, remains obscure. We previously reported a decreased basal ATP synthase activity in fibroblasts from late-infantile NCL (CLN2) and juvenile NCL (CLN3) patients. We have now extended the study of the ATP synthase system to an ovine NCL (a model for the late-infantile NCL variant, CLN6) and the infantile NCL (CLN1). In fibroblasts from healthy sheep, active regulation of ATP synthase in response to cellular energy demand was present similar to human cells: ATP synthase was down-regulated under conditions of anoxia or functional uncoupling and was up-regulated in response to calcium. In fibroblasts from NCL sheep, basal ATP synthase activity was slightly elevated and down-regulation in response to anoxia or uncoupling of mitochondria also occurred. Calcium produced an unexpected down-regulation to 55% of basal activity. Activities of respiratory chain enzymes did not differ between healthy and NCL sheep. In fibroblasts from CLN1 patients, basal ATP synthase activity was reduced and regulation of the enzyme was absent. Activities of respiratory chain complexes II and IV were reduced. The defect of ATP synthase regulation found in fibroblasts from NCL sheep and infantile NCL patients is different from the ATP synthase deficiencies demonstrated in late-infantile and juvenile NCL, but problems of mitochondrial energy production, if also expressed in brain, would be a common feature of several NCL forms. Deficient ATP supply could result in degeneration of neurons, especially in those with high energy requirements.     

Genetic heterogeneity of neuronal ceroid lipofuscinosis in The Netherlands

An overview of patients in the Netherlands who are known to us with neuronal ceroid lipofuscinosis (NCL) is presented. Several CLN genes involved in NCL have been isolated or mapped. We have analyzed families with different types of NCL with polymorphic markers linked to CLN loci to investigate the genetic heterogeneity of NCL in the Netherlands. Haplotype analysis suggests that in addition to the CLN2 and CLN6 genes another gene is involved in at least one family with late infantile NCL in the Netherlands. The CLN2 and CLN6 loci have also been excluded in a family with protracted juvenile NCL.     

Ovine neuronal ceroid lipofuscinosis: a large animal model syntenic with the human neuronal ceroid lipofuscinosis variant CLN6.

The neuronal ceroid lipofuscinoses (NCLs) are a group of inherited degenerative neurological diseases affecting children. A number of non-allelic variants have been identified within the human population and the genes for some of these have recently been identified. The underlying mechanism for the neuropathology remains an enigma; however, pioneering studies with the naturally occurring ovine model (OCL) have led to the proposal that these diseases represent lesions in specific hydrophobic protein degradation pathways. In this study, we show linkage between OCL and microsatellite markers on OAR 7q13-15. Using interspecies chromosome painting we establish that OAR 7q13-15 is syntenic with human chromosome 15q21-23, the region which was recently defined as the location of a newly identified late infantile variant (CLN6). We propose that our ovine model represents a mutation in the gene orthologous to that mutated in the human late infantile variant CLN6. The ovine linkage flock, consisting of 56 families, represents a powerful resource for positional cloning of this NCL gene. The availability of such a large animal model will have important implications for experimentation in downstream corrective therapies.     

Evidence for processing of dolichol-linked oligosaccharides in patients with neuronal ceroid-lipofuscinosis.

In agreement with reports from other laboratories, we have shown that patients with the juvenile or late infantile forms of neuronal ceroid-lipofuscinosis (NCL) have greatly increased levels (5-fold to 20-fold) of dolichyl pyrophosphoryl oligosaccharides in their cerebral gray matter. Oligosaccharides containing 2 GlcNAc residues and 3 to 9 mannose residues were liberated by mild acid hydrolysis. The oligosaccharide profile given by brain tissue from 2 patients with infantile NCL was markedly different from that of late infantile and juvenile NCL brain, with Man9GlcNAc2 as the most abundant component and decreasing amounts of Man8- Man7- and Man6GlcNAc2. By contrast, Man5GlcNAc2 was the most abundant oligosaccharide present in all juvenile NCL brain samples analyzed. Both the susceptibility of the isolated Man5GlcNAc2 to endoglucosaminidase H digestion and permethylation analysis clearly indicated that it is not an intermediate in the biosynthesis of Glc3Man9GlcNAc2-PP-dolichol but has undergone catabolism, probably either in the endoplasmic reticulum or in the Golgi apparatus. Treatment of cultured skin fibroblasts for 7 days with N-methyldeoxynojirimycin, a potent inhibitor of the endoplasmic reticulum processing enzymes glucosidase I and II, resulted in an accumulation of the same Man5GlcNAc2-PP-dolichol species that was elevated in juvenile NCL brain. The level in untreated fibroblasts was undetectable, suggesting that inhibition of processing glucosidases has interfered with the regulation and compartmentalization of lipid-linked oligosaccharides.     

Books received

Subunit c is normally present as an inner mitochondrial membrane component of the F₀ sector of the ATP synthase complex, but in the late infantile form of neuronal ceroid-lipofuscinosis (NCL) it was also found in lysosomes in high concentrations. The rate of degradation of subunit c as measured by pulse–chase and immunoprecipitation showed a marked delay of degradation in patients' fibroblasts with late infantile form of NCL. There were no significant differences between control cells and cells with disease in the degradation of cytochrome oxidase subunit IV, an inner membrane protein of mitochondria. Measurement of labeled subunit c in mitochondrial and lysosomal fractions showed that the accumulation of labeled subunit c in the mitochondrial fraction can be detected before lysosomal appearance of radioactive subunit c, suggesting that subunit c accumulated as a consequence of abnormal catabolism in the mitochondrion and is transferred to lysosomes through an autophagic process. The biosynthetic rate of subunit c and mRNA levels for P1 and P2 genes that code for it were almost the same in both control and patient cells. These findings suggest that a specific failure in the degradation of subunit c after its normal inclusion in mitochondria and its consequent accumulation in lysosomes. © 1995 Wiley-Liss, Inc.