Peroxisome biogenesis disorders in the Zellweger spectrum: An overview of current diagnosis, clinical manifestations, and treatment guidelines

Peroxisome biogenesis disorders in the Zellweger spectrum (PBD-ZSD) are a heterogeneous group of genetic disorders caused by mutations in PEX genes responsible for normal peroxisome assembly and functions. As a result of impaired peroxisomal activities, individuals with PBD-ZSD can manifest a complex spectrum of clinical phenotypes that typically result in shortened life spans. The extreme variability in disease manifestation ranging from onset of profound neurologic symptoms in newborns to progressive degenerative disease in adults presents practical challenges in disease diagnosis and medical management. Recent advances in biochemical methods for newborn screening and genetic testing have provided unprecedented opportunities for identifying patients at the earliest possible time and defining the molecular bases for their diseases. Here, we provide an overview of current clinical approaches for the diagnosis of PBD-ZSD and provide broad guidelines for the treatment of disease in its wide variety of forms. Although we anticipate future progress in the development of more effective targeted interventions, the current guidelines are meant to provide a starting point for the management of these complex conditions in the context of personalized health care.

Peroxisomal disorders in neurology

Although peroxisomes were initially believed to play only a minor role in mammalian metabolism, it is now clear that they catalyse essential reactions in a number of different metabolic pathways and thus play an indispensable role in intermediary metabolism. The metabolic pathways in which peroxisomes are involved include the biosynthesis of ether phospholipids and bile acids, the oxidation of very long chain fatty acids, prostaglandins and unsaturated long chain fatty acids and the catabolism of phytanate and (in man) pipecolate and glyoxylate. The importance of peroxisomes in cellular metabolism is stressed by the existence of a group of inherited diseases, the peroxisomal disorders, caused by an impairment in one or more peroxisomal functions. In the last decade our knowledge about peroxisomes and peroxisomal disorders has progressed enormously and has been the subject of several reviews. New developments include the identification of several additional peroxisomal disorders, the discovery of the primary defect in several of these peroxisomal disorders, the recognition of novel peroxisomal functions and the application of complementation analysis to obtain information on the genetic relationship between the different peroxisomal disorders. The peroxisomal disorders recognized at present comprise 12 different diseases, with neurological involvement in 10 of them. These diseases include: (1) those in which peroxisomes are virtually absent leading to a generalized impairment of peroxisomal functions (the cerebro-hepato-renal syndrome of Zellweger, neonatal adrenoleukodystrophy, infantile Refsum disease and hyperpipecolic acidaemia); (2) those in which peroxisomes are present and several peroxisomal functions are impaired (the rhizomelic form of chondrodysplasia punctata, combined peroxisomal beta-oxidation enzyme protein deficiency); and (3) those in which peroxisomes are present and only a single peroxisomal function is impaired (X-linked adrenoleukodystrophy, peroxisomal thiolase deficiency (pseudo-Zellweger syndrome), acyl-CoA oxidase deficiency (pseudo-neonatal adrenoleukodystrophy) and probably, the classic form of Refsum disease.

Analysis of very long-chain fatty acids using electrospray ionization mass spectrometry

Elevated levels of very long-chain fatty acids (VLCFA) in plasma and tissues are the biochemical hallmark for patients with X-linked adrenoleukodystrophy (X-ALD). Current methods for the determination of VLCFA levels are laborious and time-consuming. We describe a rapid and easy method using electrospray ionization mass spectrometry (ESI-MS) with deuterated internal standards. VLCFA are hydrolyzed, extracted, and quantified in less than 4h. This includes 2h of hydrolysis and 4min of quantification. We validated the method by analyzing 60 plasma samples from controls and patients with X-ALD or Zellweger syndrome using both the ESI-MS protocol and an established method for VLCFA analysis using gas chromatography (GC). The C26:0 concentrations determined with ESI-MS in plasma and fibroblasts of X-ALD patients are in good agreement with those reported previously for GC and GC-MS. Besides saturated straight chain VLCFA, we also determined the concentrations of the mono-unsaturated VLCFA C24:1 and C26:1 and established that while C24:1 levels are not elevated, C26:1 levels are elevated in both plasma and fibroblasts from X-ALD patients.

Bile acid analysis in human disorders of bile acid biosynthesis

Bile acids facilitate the absorption of lipids in the gut, but are also needed to maintain cholesterol homeostasis, induce bile flow, excrete toxic substances and regulate energy metabolism by acting as signaling molecules. Bile acid biosynthesis is a complex process distributed across many cellular organelles and requires at least 17 enzymes in addition to different metabolite transport proteins to synthesize the two primary bile acids, cholic acid and chenodeoxycholic acid. Disorders of bile acid synthesis can present from the neonatal period to adulthood and have very diverse clinical symptoms ranging from cholestatic liver disease to neuropsychiatric symptoms and spastic paraplegias. This review describes the different bile acid synthesis pathways followed by a summary of the current knowledge on hereditary disorders of human bile acid biosynthesis with a special focus on diagnostic bile acid profiling using mass spectrometry.

Newborn screening for X-linked adrenoleukodystrophy in New York State: diagnostic protocol, surveillance protocol and treatment guidelines

PURPOSE

To describe a diagnostic protocol, surveillance and treatment guidelines, genetic counseling considerations and long-term follow-up data elements developed in preparation for X-linked adrenoleukodystrophy (X-ALD) newborn screening in New York State.

METHODS

A group including the director from each regional NYS inherited metabolic disorder center, personnel from the NYS Newborn Screening Program, and others prepared a follow-up plan for X-ALD NBS. Over the months preceding the start of screening, a series of conference calls took place to develop and refine a complete newborn screening system from initial positive screen results to long-term follow-up.

RESULTS

A diagnostic protocol was developed to determine for each newborn with a positive screen whether the final diagnosis is X-ALD, carrier of X-ALD, Zellweger spectrum disorder, acyl CoA oxidase deficiency or D-bifunctional protein deficiency. For asymptomatic males with X-ALD, surveillance protocols were developed for use at the time of diagnosis, during childhood and during adulthood. Considerations for timing of treatment of adrenal and cerebral disease were developed.

CONCLUSION

Because New York was the first newborn screening laboratory to include X-ALD on its panel, and symptoms may not develop for years, long-term follow-up is needed to evaluate the presented guidelines.

Gas chromatography/mass spectrometry analysis of very long chain fatty acids, docosahexaenoic acid, phytanic acid and plasmalogen for the screening of peroxisomal disorders

Very long chain fatty acids (VLCFAs) and docosahexaenoic acid (DHA), phytanic acid, and plasmalogens are usually measured individually. A novel method for the screening of peroxisomal disorders, using gas chromatography/mass spectrometry (GC/MS), was developed. Saturated and unsaturated fatty acids, including VLCFAs and DHA, phytanic acid, and plasmalogen were detected by a selected ion monitoring-electron impact method, using 100 microl of serum or plasma. Methyl-esterification and extraction could be done in one tube, and data were obtained within 4 h. All patients with Zellweger syndrome (ZS), X-linked adrenoleukodystrophy (ALD), isolated deficiency of peroxisomal beta-oxidation enzyme, and most ALD carriers showed increased VLCFA ratios, including C24:0/C22:0, C25:0/C22:0 and C26:0/C22:0. The ratio of DHA to palmitic acid (C16:0) and plasmalogen (measured as hexadecanal dimethyl acetal) to C16:0 in ZS patients was significantly lower than for the controls (P<0.001 for healthy high school students, P<0.05 for infants with other disorders). Plasmalogen was also decreased in patients with isolated deficiency of plasmalogen biosynthesis. Two of eight patients with ZS, two of four with RCDP, and all of three classical Refsum patients showed increased levels of phytanic acid. This method will simplify the screening for peroxisomal disorders.

The MR spectrum of peroxisomal disorders

In the last decade an increasing number of peroxisomal disorders has been recognized. Almost all peroxisomal disorders affect the central nervous system. Many of them lead to demyelination, some of them lead to migrational disturbances. The MR pattern of X-linked adrenoleukodystrophy is well known, but the pattern of the other peroxisomal disorders is less well known. We evaluated the gray and white matter abnormalities of 20 patients on 32 occasions. We compared the results with histological data and in this way came to the description of a number of characteristic MR patterns occurring in peroxisomal disorders: (1) Neuronal migrational disturbances in combination with hypomyelination, dysmyelination or demyelination. (2) Symmetrical demyelination of posterior limb of the internal capsule, cerebellar white matter and brain stem tracts with a variable affection of cerebral hemispheres. (3) Symmetrical demyelination, exhibiting two zones, starting in the occipital area and spreading outwards and forwards; affection of brain stem tracts. (4) Less characteristic patterns of demyelination. The patterns are illustrated and differentiation from other disorders is discussed.

Additional congenital defects in anorectal malformations

From 1974 until 1995 a total of 264 (141 male, 123 female) patients born with an anorectal malformation (ARM) were referred to the University Hospital Nijmegen in the Netherlands. All additional congenital defects (ACDs) were registered. Special attention was paid to whether the ACDs take part in associations, syndromes, or sequences. One or more ACDs were observed in 67% of the patients. In decreasing order the defects concerned the uro-genital tract (43%), skeleton (38%), gastrointestinal tract (24%), circulation (21%), extremities (16%), face (16%), central nervous system (15%), respiratory tract (5%), and remaining defects (5%). Associations were observed in 49% of the patients mostly (in 44%) the Vertebral, Anorectal, Cardial, Tracheo-Esophageal, Renal and Limb association. In 5% of the patients syndromes were recognized. Sequences were seen in 2% of the patients. Remarkable is the combination of trisomy 21 and ARM without a fistula. The combination of ARM and the Zellweger syndrome has not been reported before.

CONCLUSION

Almost all combinations of ARM and ACDs can be classified as an association, syndrome or sequence. ARM-causing agents affect males and females in equal numbers but lead to different expression in the sexes. The origin of the Omphalocele, Extrophia of the bladder, Imperforate anus, Sacral anomalies complex probably differs from that of other forms of ARM.

Peroxisomal disorders. Neurodevelopmental and biochemical aspects

The peroxisomal disorders represent a group of inherited metabolic disorders that derive from defects of peroxisomal biogenesis and/or from dysfunction of single or multiple peroxisomal enzymes. Because peroxisomes are involved in the metabolism of lipids critical to the functioning of the nervous system, many of the peroxisomal disorders manifest with significant degrees of progressive psychomotor dysfunction. These disorders should be considered in the differential diagnosis of the infant with hypotonia and psychomotor delay (especially if accompanied by facial dysmorphisms, hepatomegaly, cataracts and/or retinitis, calcific stippling, short limbs, or combinations of these features), in the school-aged child with progressive neurologic dysfunction, and in adults with slowly progressive motor dysfunction. Current knowledge of peroxisomal biochemical and enzymatic processes permits precise identification of particular disorders within the peroxisomal disorder grouping. An effort should be made to identify the specific peroxisomal disorder to provide a precise explanation for neurodevelopmental deficits, to potentially prevent recurrence through genetic counseling, and to provide appropriate therapies when available.

Postnatal diagnosis of peroxisomal disorders: a biochemical approach

In recent years an increasing number of inherited decreases in man has been identified in which there is an impairment of one or more peroxisomal functions. Sofar 15 different peroxisomal disorders have been identified which can be subdivided into three distinct groups depending upon whether there is a generalized (group A), multiple (group B) or single (group C) loss of peroxisomal functions. In this paper we will briefly describe the functions of peroxisomes in man which are of direct relevance for the peroxisomal disorders known up to now. Based upon the biochemical characteristics of the different peroxisomal disorders, we well describe a straightforward approach for the postnatal identification of patients suspected to suffer from a peroxisomal disorder. Furthermore, a detailed analysis of the biochemical procedures which should be used preferably, is given.

Stable isotope dilution analysis of very long chain fatty acids in plasma, urine and amniotic fluid by electron capture negative ion mass fragmentography

A sensitive and selective stable isotope dilution electron capture negative ion chemical ionization mass fragmentography method applying pentafluorobenzyl derivatives was developed for the accurate quantitation of very long chain fatty acids. This technique allowed detection of 1-5 pg of each compound and was applied to plasma (100 microliters), amniotic fluid (1 ml) and urine (1 ml). Normal concentrations were established and the concentrations in samples of selected patients with classified peroxisomal disorders were determined. In plasma samples of all patients the C26:0/C22:0 ratios were elevated (range 0.03-0.43), compared to the control ratios (range 0.003-0.021). The ratio C26:0/C22:0 was elevated in four of five amniotic fluid samples from fetuses with peroxisomal disorders (range 0.18-0.54) when compared with controls (range 0.05-0.25). An elevation of the ratio C26:1/C22:0 was observed in all five amniotic fluid samples (range 0.22-0.60 vs. 0-0.08 in controls). Urinary C26:0 concentrations were lower than in plasma and amniotic fluid and diagnostic ratios were not elevated in patients with peroxisomal disorders.

Specific and rapid quantification of 8-iso-prostaglandin F2alpha in urine of healthy humans and patients with Zellweger syndrome by gas chromatography-tandem mass spectrometry

8-iso-Prostaglandin F2alpha (8-iso-PGF2alpha) is currently discussed as a potential index parameter of oxidative stress in vivo. We describe in this article a fully validated gas chromatographic-tandem mass spectrometric method for the quantitative determination of 8-iso-PGF2alpha in human urine. The method is highly specific and requires a single thin-layer chromatographic step for sample purification. Inter- and intraday imprecision were below 8%. Mean inaccuracy was 5.3% for added levels of 8-iso-PGF2alpha up to 2000 pg/ml of urine. We measured highly elevated excretion of 8-iso-PGF2alpha in the urine of children with peroxisomal beta-oxidation deficiency, i.e. Zellweger syndrome, (63.3+/-16.6 ng/mg creatinine) compared to that of healthy children (0.51+/-0.16 ng/mg creatinine) (mean+/-S.D., both n=5). The method could be useful for diagnosing Zellweger syndrome and for investigating the utility of 8-iso-PGF2alpha as a novel marker for oxidative stress in vivo in man.

Peroxisomal assembly defects: clinical, pathologic, and biochemical findings in two patients in a newly identified complementation group

We describe the clinical, pathologic, and biochemical findings for two peroxisome-deficient patients in a newly identified complementation group. Both patients had biochemical findings typical of patients with peroxisome biogenesis disorders. However, whereas one patient had the typical clinicopathologic features of Zellweger syndrome, the other patient's phenotype was atypical.

Effects of sodium 2-[5-(4-chlorophenyl)pentyl]-oxirane-2-carboxylate (POCA) on fatty acid oxidation in fibroblasts from patients with peroxisomal diseases

The effects of sodium 2-[5-(4-chlorophenyl)pentyl]oxirane-2-carboxylate (POCA), a potent inhibitor of carnitine palmitoyltransferase I, on fatty acid oxidation were investigated using fibroblasts from control subjects and from patients with peroxisomal disorders. [1-14C]Palmitate oxidation was inhibited by 8% of the control value when 15 microM POCA was added to the medium. The inhibition by POCA was significantly (P less than 0.05) stronger in fibroblasts from patients with Zellweger syndrome or with neonatal adrenoleukodystrophy, in which peroxisomes and peroxisomal beta-oxidation enzymes were absent. However, the inhibition in fibroblasts from patients with X-linked adrenoleukodystrophy, in which a specific defect of peroxisomal lignoceroyl-CoA synthetase was speculated, was similar to that in the controls. [1-14C]Lignocerate oxidation was not influenced by the addition of POCA, in samples from the controls and from the patients. These results indicate that peroxisomes account for a small but demonstrable proportion of palmitate oxidation, and add new evidence to the concept that lignocerate is oxidized exclusively in the peroxisomes. Our findings also support the hypotheses that the activity of palmitoyl-CoA synthetase and the enzymes of beta-oxidation cycle in peroxisomes are normal in patients with X-linked adrenoleukodystrophy and that a specific defect of lignoceroyl-CoA synthetase is responsible for the accumulation of very long chain fatty acids in these patients.

Late onset white matter disease in peroxisome biogenesis disorder

OBJECTIVE

To report late onset cerebral white matter disease as a distinctive phenotype in peroxisome biogenesis disorder (PBD).

BACKGROUND

There is phenotypic and genetic overlap among the PBD known as Zellweger syndrome (ZS), infantile Refsum disease (IRD), and neonatal adrenoleukodystrophy (NALD). Distinctive external features are variable among these three disorders, and neurologic deficit has its onset at birth or in infancy. In a structured follow-up cohort of 25 patients with PBD, not including ZS, three patients had an unusual pattern of cerebral white matter disease with onset past the age of 1, not conforming to any of the classic PBD phenotypes.

METHODS

Clinical phenotyping and follow-up, peroxisomal biochemical determinations in body fluids and fibroblasts, identification of affected PEX gene by genetic complementation in fibroblasts, and MRI studies.

RESULTS

Two unrelated patients with PBD without distinctive external features had normal neurodevelopmental milestones during their first year, followed by rapid deterioration including severe hypotonic pareses, seizures, retinopathy, and deafness. A third patient initially diagnosed with IRD developed cerebral white matter degeneration in the third year of life, complicating the original diagnosis. MRI in all three patients showed cerebral demyelination with sparing of subcortical fibers and pronounced central cerebellar demyelination.

CONCLUSIONS

Late-onset cerebral white matter disease may occur in PBD, either following IRD or following normal early development and in the absence of distinctive external features. Peroxisome biogenesis disorder should be included in the differential diagnosis of post-infantile onset of cerebral white matter disease

Human peroxisomal disorders

Peroxisomes are single membrane-bound cell organelles performing numerous metabolic functions. The present article aims to give an overview of our current knowledge about inherited peroxisomal disorders in which these organelles are lacking or one or more of their functions are impaired. They are multiorgan disorders and the nervous system is implicated in most. After a summary of the historical names and categories, each having distinct symptoms and prognosis, microscopic pathology is reviewed in detail. Data from the literature are added to experience in the authors' laboratory with 167 liver biopsy and autopsy samples from peroxisomal patients, and with a smaller number of chorion samples for prenatal diagnosis, adrenal-, kidney-, and brain samples. Various light and electron microscopic methods are used including enzyme- and immunocytochemistry, polarizing microscopy, and morphometry. Together with other laboratory investigations and clinical data, this approach continues to contribute to the diagnosis and further characterization of peroxisomal disorders, and the discovery of novel variants. When liver specimens are examined, three main groups including 9 novel variants (33 patients) are distinguished: (1) absence or (2) presence of peroxisomes, and (3) mosaic distribution of cells with and without peroxisomes (10 patients). Renal microcysts, polarizing trilamellar inclusions, and insoluble lipid in macrophages in liver, adrenal cortex, brain, and in interstitial cells of kidney are also valuable for classification. On a genetic basis, complementation of fibroblasts has classified peroxisome biogenesis disorders into 12 complementation groups. Peroxisome biogenesis genes (PEX), knock-out-mice, and induction of redundant genes are briefly reviewed, including some recent results with 4-phenylbutyrate. Finally, regulation of peroxisome expression during development and in cell cultures, and by physiological factors is discussed.

Ether lipid synthesis and its deficiency in peroxisomal disorders

This paper deals with the discovery of plasmalogen deficiency in the cerebro-hepato-renal (Zellweger) syndrome and discusses how this has led to the development of postnatal and prenatal diagnostic procedures for this and a number of related peroxisomal disorders in man that show a general impairment in the biosynthesis of ether glycerophospholipids. The results have clearly shown an indispensable role for peroxisomes in the total process of ether lipid synthesis as evidenced by a description of the cellular topography of this process. Platelet-activating factor is a bioactive phospholipid in which the glycero-ether linkage is essential for its biological activities. The deficient formation of this lipid mediator can be correlated to the residual amounts of ether phospholipids found in patients with impaired ether lipid production. Evidence is provided to demonstrate that the extent to which cells upon stimulation produce platelet-activating factor and its 1-acyl counterpart is not caused by enzyme selectivities for ether-linked versus ester-linked phospholipid species. Rather, the relative production of these compounds appears to be mainly governed by the relative abundance of ether-linked and ester-linked precursor molecules and the activity of cellular enzymes, such as lysophospholipases, that catabolize the acyl analog of platelet-activating factor through deacylation.

A PEX10 defect in a patient with no detectable defect in peroxisome assembly or metabolism in cultured fibroblasts

Zellweger spectrum disorders (ZSD) are diagnosed by biochemical assay in blood, urine and cultured fibroblasts and PEX gene mutation identification. In most cases studies in fibroblasts corroborate results obtained in body fluids. In 1996 Clayton and colleagues described a 10-year old girl with evidence of a peroxisome disorder, based on elevated bile acid metabolites and phytanate. At the time it was not possible to distinguish whether she had a ZSD or a single peroxisomal protein defect. Studies in our laboratory showed that she also had elevated plasma pipecolate, supporting the former diagnosis. Despite the abnormal metabolites detected in blood (phytanate, bile acid intermediates and pipecolate), analysis of multiple peroxisomal pathways in fibroblasts yielded normal results. In addition, she had a milder clinical phenotype than usually associated with ZSD. Since complementation analysis to determine the gene defect was not possible, we screened this patient following the PEX Gene Screen algorithm (PGS). The PGS provides a template for sequencing PEX gene exons independent of complementation analysis. Two mutations in PEX10 were identified, a frameshift mutation inherited from her father and a de novo missense mutation in a conserved functional domain on the other allele. This case highlights that molecular analysis may be essential to the diagnosis of patients at the milder end of the ZSD spectrum. Furthermore, it supports the concept that some tissues are less affected by certain PEX gene defects than brain and liver.

Biochemical markers predicting survival in peroxisome biogenesis disorders

OBJECTIVE

To identify prognostic markers reflecting the extent of peroxisome dysfunction in primary skin fibroblasts from patients with peroxisome biogenesis disorders (PBD).

BACKGROUND

PBD are a genetically heterogeneous group of disorders due to defects in at least 11 distinct genes. Zellweger syndrome is the prototype of this group of disorders, with neonatal adrenoleukodystrophy and infantile Refsum disease as milder variants. Common to these three disorders are liver disease, variable neurodevelopmental delay, retinopathy, and perceptive deafness. Because genotype-phenotype studies are complicated by the genetic heterogeneity among patients with PBD, the authors evaluated a series of biochemical markers as a measure of peroxisome dysfunction in skin fibroblasts.

METHODS

Multiple peroxisomal functions including de novo plasmalogen synthesis, dihydroxyacetonephosphate acyltransferase (DHAPAT) activity, C26:0/C22:0 ratio, C26:0 and pristanic acid beta-oxidation, and phytanic acid alpha-oxidation were analyzed in fibroblasts from a series of patients with defined clinical phenotypes.

RESULTS

A poor correlation with age at death was found for de novo plasmalogen synthesis, C26:0/C22:0 ratio, and phytanic acid alpha-oxidation. A fairly good correlation was found for pristanic acid beta-oxidation, but the best correlation was found for DHAPAT activity and C26:0 beta-oxidation. A mathematic combination of DHAPAT activity and C26:0 beta-oxidation showed an even better correlation.

CONCLUSIONS

DHAPAT activity and C26:0 beta-oxidation are the best markers in predicting life expectancy of patients with PBD. Combination of both markers gives an even better prediction. These results contribute to the management of patients with PBD.

Evaluation of C26:0-lysophosphatidylcholine and C26:0-carnitine as diagnostic markers for Zellweger spectrum disorders

INTRODUCTION

Zellweger spectrum disorders (ZSD) are a group of genetic metabolic disorders caused by a defect in peroxisome biogenesis. This results in multiple metabolic abnormalities, including elevated very long-chain fatty acid (VLCFA) levels. Elevated levels of C26:0-lysophosphatidylcholine (C26:0-lysoPC) have been shown in dried blood spots (DBS) from ZSD patients. However, little is known about the sensitivity and specificity of this marker and C26:0-carnitine, another VLCFA-marker, in ZSD. We investigated C26:0-lysoPC and C26:0-carnitine as diagnostic markers for ZSD in DBS and fibroblasts.

METHODS

C26:0-lysoPC levels in 91 DBS from 37 different ZSD patients were determined and compared to the levels in 209 control DBS. C26:0-carnitine levels were measured in 41 DBS from 29 ZSD patients and 97 control DBS. We measured C26:0-lysoPC levels in fibroblasts from 24 ZSD patients and 61 control individuals.

RESULTS

Elevated C26:0-lysoPC levels (>72 nmol/L) were found in 86/91 ZSD DBS (n=33/37 patients) corresponding to a sensitivity of 89.2%. Median level was 567 nmol/l (range 28-3133 nmol/l). Consistently elevated C26:0-carnitine levels (>0.077 μmol/L) in DBS were found in 16 out of 29 ZSD patients corresponding to a sensitivity of 55.2%. C26:0-lysoPC levels were elevated in 21/24 ZSD fibroblast lines.

DISCUSSION

C26:0-lysoPC in DBS is a sensitive and useful marker for VLCFA accumulation in patients with a ZSD. C26:0-carnitine in DBS is elevated in some ZSD patients, but is less useful as a diagnostic marker. Implementation of C26:0-lysoPC measurement in the diagnostic work-up when suspecting a ZSD is advised. This marker has the potential to be used for newborn screening for ZSD.

Clinical recognition of patients affected by a peroxisomal disorder: a retrospective study in 40 patients

Peroxisomal disorders are genetic diseases in which an impairment in one or more peroxisomal function(s) causes clinical and multiple biochemical abnormalities. Early recognition of the major peroxisomal disorders in which functional peroxisomes are virtually absent, leading to a generalised impairment of peroxisomal functions, is of utmost importance, as this will enable the prenatal diagnosis of these severe diseases in future pregnancies. Unfortunately, clinical recognition of these disorders can be difficult because of the aspecific and varying phenotypic presentation. We analysed the clinical characteristics in 40 patients suspected of having a peroxisomal disorder to identify specific clinical criteria for diagnosis. From this study we conclude that the combined presence of at least three major clinical characteristics (present in greater than 75% of the affected patients, including psychomotor retardation, hypotonia, impaired hearing, low/broad nasal bridge, abnormal ERG, hepatomegaly) and one or more minor characteristics (present in 50%-75% of the patients, like large fontanelles, shallow orbital ridges, epicanthus, anteverted nostrils, retinitis pigmentosa) warrants biochemical investigation of peroxisomal functions. Further prospective investigations will have to be done to evaluate these criteria.

Oxidation of pristanic acid in fibroblasts and its application to the diagnosis of peroxisomal beta-oxidation defects

Pristanic acid oxidation measurements proved a reliable tool for assessing complementation in fused heterokaryons from patients with peroxisomal biogenesis defects. We, therefore, used this method to determine the complementation groups of patients with isolated defects in peroxisomal beta-oxidation. The rate of oxidation of pristanic acid was reduced in affected cell lines from all of the families with inherited defects in peroxisomal beta-oxidation, thus excluding the possibility of a defective acyl CoA oxidase. Complementation analyses indicated that all of the patients belonged to the same complementation group, which corresponded to cell lines with bifunctional protein defects. Phytanic acid oxidation was reduced in fibroblasts from some, but not all, of the patients. Plasma samples were still available from six of the patients. The ratio of pristanic acid to phytanic acid was elevated in all of these samples, as were the levels of saturated very long chain fatty acids (VLCFA). However, the levels of bile acid intermediates, polyenoic VLCFA, and docosahexaenoic acid were abnormal in only some of the samples. Pristanic acid oxidation measurements were helpful in a prenatal assessment for one of the families where previous experience had shown that cellular VLCFA levels were not consistently elevated in affected individuals.

Cerebral MRI as a valuable diagnostic tool in Zellweger spectrum patients

Patients with defects in the biogenesis of peroxisomes include those with Zellweger syndrome spectrum (ZSS), a developmental and progressive metabolic disease with a distinct dysmorphic phenotype and varying severity. The diagnosis of ZSS relies on the clinical presentation and the biochemical evaluation of peroxisomal metabolites. Mutation detection in one out of twelve genes coding for proteins involved in the biogenesis of peroxisomes confirms the diagnosis. In the absence of pronounced clinical features of ZSS, neuroradiological findings may lead the way to the diagnosis. Cerebral magnetic resonance imaging (cMRI) pathology in ZSS consists of abnormal gyration pattern including polymicrogyria and pachygyria, leukencephalopathy, germinolytic cysts and heterotopias as reported by previous systematic studies including cMRI of a total of 34 ZSS patients, only five of whom had a severe phenotype. The present study evaluated the cMRI results of additional 18 patients, 6 with a severe and 12 with a milder ZSS phenotype. It confirms and extends knowledge of the characteristic cMRI pattern in ZSS patients. Besides an abnormal gyration pattern and delayed myelination or leukencephalopathy, brain atrophy was a common finding. Polymicrogyria and pachygyria were more common in patients with severe ZSS, while leukencephalopathy increases with age in patients with longer survival. Nevertheless, an abnormal gyration pattern might be more frequent in patients with a mild ZSS than deduced from previous studies. In addition, we discuss the differential diagnosis of the ZSS cMRI pattern and review investigations on the pathogenesis of the ZSS cerebral phenotype in mouse models of the disease.

Proton magnetic resonance spectroscopy (1H-MRS) of the cerebrum in two young infants with Zellweger syndrome

Cerebral metabolic abnormalities have been previously detected by 1H-MRS in infants with the Zellweger syndrome as young as 3 months. We hypothesized that metabolic abnormalities could also be found shortly after birth. Two fullterm infants with Zellweger syndrome were studied at 12 days and two months of age, respectively, using single voxel 1H-MRS. In the first case 1H-MRS was performed using PRESS with variable TE (31, 136, 272 ms); in the second, STEAM and PRESS sequences were used with different TE (STEAM at 30 and 144 ms; PRESS at 270 ms). In both cases a significant decrease of N-acetylaspartate (NAA) and an abnormal signal at 1.33 and 0.9 ppm, consisting of lactate (Lac) and lipids (Lip) were found. The reported MRS abnormalities, although not specific for peroxisomal dysfunctions, may support the suspicion of Zellweger syndrome and may indicate direct referral to the specific laboratory and molecular studies necessary to establish the diagnosis and prognosis of this syndrome.

Peroxisomal disorders in children: immunohistochemistry and neuropathology

Immunohistochemical studies with antisera against four peroxisomal enzymes, catalase and beta-oxidation enzymes (acyl-coenzyme A oxidase, bifunctional protein, and 3-ketoacyl-CoA thiolase), were performed on brain, liver, and kidney specimens from patients with peroxisomal disorders, as well as specimens from three control subjects, by using conventional paraffin-embedded autopsy material. The patients included eight with Zellweger syndrome and one with neonatal adrenoleukodystrophy. In the liver and kidney specimens from all patients, except one with Zellweger syndrome, diffuse immunostaining with all antisera in the cytoplasm of hepatocytes and renal tubular epithelium suggested an absence of peroxisomes but the presence of peroxisomal enzymes. Examination of brain specimens indicated a weak or negative reaction of neurons in the cerebral cortex and a weak reaction of glial cells in the white matter, which suggested maturational delay compared with control subjects. The delayed immunoreactive pattern of peroxisomal enzymes in Zellweger syndrome and neonatal adrenoleukodystrophy may be related to the significant neuropathologic features of polymicrogyria and dysmyelinogenesis. One patient with Zellweger syndrome had a unique finding of a positive granular catalase reaction and a negative reaction with antisera to 3-ketoacyl-coenzyme A thiolase, which suggested a diagnosis of pseudo-Zellweger syndrome. This study validates the application of these immunohistochemical methods to the study of peroxisomal enzymes. Use of these methods improves the accuracy of diagnosis of peroxisomal disorders.