Sulfatide Analysis by Mass Spectrometry for Screening of Metachromatic Leukodystrophy in Dried Blood and Urine Samples.

BACKGROUND: Metachromatic leukodystrophy (MLD) is an autosomal recessive disorder caused by deficiency in arylsulfatase A activity, leading to accumulation of sulfatide substrates. Diagnostic and monitoring procedures include demonstration of reduced arylsulfatase A activity in peripheral blood leukocytes or detection of sulfatides in urine. However, the development of a screening test is challenging because of instability of the enzyme in dried blood spots (DBS), the widespread occurrence of pseudodeficiency alleles, and the lack of available urine samples from newborn screening programs. METHODS: We measured individual sulfatide profiles in DBS and dried urine spots (DUS) from MLD patients with LC-MS/MS to identify markers with the discriminatory power to differentiate affected individuals from controls. We also developed a method for converting all sulfatide molecular species into a single species, allowing quantification in positive-ion mode upon derivatization. RESULTS: In DBS from MLD patients, we found up to 23.2-fold and 5.1-fold differences in total sulfatide concentrations for early- and late-onset MLD, respectively, compared with controls and pseudodeficiencies. Corresponding DUS revealed up to 164-fold and 78-fold differences for early- and late-onset MLD patient samples compared with controls. The use of sulfatides converted to a single species simplified the analysis and increased detection sensitivity in positive-ion mode, providing a second option for sulfatide analysis. CONCLUSIONS: This study of sulfatides in DBS and DUS suggests the feasibility of the mass spectrometry method for newborn screening of MLD and sets the stage for a larger-scale newborn screening pilot study.

Quantification of sulfatides and lysosulfatides in tissues and body fluids by liquid chromatography-tandem mass spectrometry.

Sulfatides are found in brain as components of myelin, oligodendrocytes, and neurons but are also present in various visceral tissues. Metachromatic leukodystrophy (MLD) is an inherited lysosomal storage disorder caused by a deficiency of arylsulfatase A, leading to severe white matter disease due to the accumulation of sulfatides and lysosulfatides. To study the physiological role of sulfatides, accessible and sensitive quantitative methods are required. We developed a sensitive LC/MS/MS method to quantify total sulfatide and lysosulfatide content as well as individual molecular species in urine and plasma from MLD patients and plasma and tissues from an MLD mouse model. Our results demonstrate that the method can quantify a wide range of sulfatide concentrations and can be used to quantify total sulfatide content and levels of individual molecular species of sulfatides in tissues, cells, and body fluids. Even though plasma sulfatides and lysosulfatides would seem attractive candidate biomarkers that could possibly correlate with the severity of MLD and be of use to monitor the effects of therapeutic intervention, our results indicate that it is unlikely that the determination of these storage products in plasma will be useful in this respect.

Quantification of sulfatides in dried blood and urine spots from metachromatic leukodystrophy patients by liquid chromatography/electrospray tandem mass spectrometry.

BACKGROUND: Treatments are being developed for metachromatic leukodystrophy (MLD), suggesting the need for eventual newborn screening. Previous studies have shown that sulfatide molecular species are increased in the urine of MLD patients compared to samples from non-MLD individuals, but there is no data using dried blood spots (DBS), the most common sample available for newborn screening laboratories. METHODS: We used ultra-high performance liquid chromatography/tandem mass spectrometry (UHPLC/MS/MS) to quantify sulfatides in DBS and dried urine spots from 14 MLD patients and 50 non-MLD individuals. RESULTS: Several sulfatide molecular species were increased in dried urine samples from all MLD samples compared to non-MLD samples. Sulfatides, especially low molecular species, were increased in DBS from MLD patients, but the sulfatide levels were relatively low. There was good separation in sulfatide levels between MLD and non-MLD samples when dried urine spots were used, but not with DBS, because DBS from non-MLD individuals have measurable levels of sulfatides. CONCLUSION: Sulfatide accumulation studies in urine, but not in DBS, emerges as the method of choice if newborn screening is to be proposed for MLD.

Direct tandem mass spectrometric profiling of sulfatides in dry urinary samples for screening of metachromatic leukodystrophy.

BACKGROUND: Prediagnostic steps in suspected metachromatic leukodystrophy (MLD) rely on clinical chemical methods other than enzyme assays. We report a new diagnostic method which evaluates changes in the spectrum of molecular types of sulfatides (3-O-sulfogalactosyl ceramides) in MLD urine. METHODS: The procedure allows isolation of urinary sulfatides by solid-phase extraction on DEAE-cellulose membranes, transportation of a dry membrane followed by elution and tandem mass spectrometry (MS/MS) analysis in the clinical laboratory. Major sulfatide isoforms are normalized to the least variable component of the spectrum, which is the indigenous C18:0 isoform. This procedure does not require the use of specific internal standards and minimizes errors caused by sample preparation and measurement. RESULTS: Urinary sulfatides were analyzed in a set of 21 samples from patients affected by sulfatidosis. The combined abundance of the five most elevated isoforms, C22:0, C22:0-OH, C24:0, C24:1-OH, and C24:0-OH sulfatides, was found to give the greatest distinction between MLD-affected patients and a control group. CONCLUSIONS: The method avoids transportation of liquid urine samples and generates stable membrane-bound sulfatide samples that can be stored at ambient temperature. MS/MS sulfatide profiling targeted on the most MLD-representative isoforms is simple with robust results and is suitable for screening.

Biochemical profiling to predict disease severity in metachromatic leukodystrophy.

Metachromatic leukodystrophy is a neurodegenerative disease that is characterized by a deficiency of arylsulfatase A, resulting in the accumulation of sulfatide and other lipids in the lysosomal network of affected cells. Accumulation of sulfatide in the nervous system leads to severe impairment of neurological function with a fatal outcome. Prognosis is often poor unless treatment is carried out before the onset of clinical symptoms. Pre-symptomatic detection of affected individuals may be possible with the introduction of newborn screening programs. The ability to accurately predict clinical phenotype and rate of disease progression in asymptomatic individuals will be essential to assist selection of the most appropriate treatment strategy. Biochemical profiling, incorporating the determination of residual enzyme protein/activity using immune-based assays, and metabolite profiling using electrospray ionization-tandem mass spectrometry, was performed on urine and cultured skin fibroblasts from a cohort of patients representing the clinical spectrum of metachromatic leukodystrophy and on unaffected controls. Residual enzyme protein/activity in fibroblasts was able to differentiate unaffected controls, arylsulfatase A pseudo-deficient individuals, pseudo-deficient compound heterozygotes and affected patients. Metachromatic leukodystrophy phenotypes were distinguished by quantification of sulfatide and other secondarily altered lipids in urine and skin fibroblasts; this enabled further differentiation of the late-infantile form of the disorder from the juvenile and adult forms. Prediction of the rate of disease progression for metachromatic leukodystrophy requires a combination of information on genotype, residual arylsulfatase A protein and activity and the measurement of sulfatide and other lipids in urine and cultured skin fibroblasts.

Synthetic sulfogalactosylceramide (sulfatide) and its use for the mass spectrometric quantitative urinary determination in metachromatic leukodystrophies.

3-O-Sulfogalactosylceramides (sulfatides) accumulate in the genetic disease metachromatic leukodystrophy which is due to a defect in the catabolic enzyme, arylsulfatase A. Clinical diagnosis is usually confirmed by in vitro enzymatic deficiency of arylsulfatase A activity. The diagnosis may be complicated because of arylsulfatase A pseudo-deficiencies and another cause of MLD, sphingolipid activator B deficiency. As large quantities of sulfatides can be found in the urine in this disease, sulfatiduria appears as an extremely useful test. As recently enzyme replacement is underway, the quantitative determination, using an internal standard, appears particularly useful as a follow-up. Thus a non-physiological sulfatide was synthesized for this purpose, i.e. 3-O-sulfo-beta-D-C17 galactosylceramide (3-O-Sulfo-D: -Galactosyl-beta1'-->1-N-Heptadecanoyl-D-erythro-Sphingosine). It has been prepared through condensation of an azidosphingosine derivative with a protected D-galactopyranosyltrichloroacetimidate. Reduction of the azide was followed by acylation of a C-17 fatty acid. The key step was achieved by selective sulfation of the desired hydroxyl group on the sugar residue of the galactosylceramide using the stannylene methodology to give a 3'-sulfated beta-galactosyl C-17 ceramide.

Generation and characterization of the binding epitope of a novel monoclonal antibody to sulfatide (sulfogalactosylceramide) OL-2: applications of antigen immunodetections in brain tissues and urinary samples.

An IgM monoclonal antibody, OL-2, was produced by immunizing Lou rats with crude cerebellar membrane fraction. Splenocytes from the rats were fused with a rat myeloma cell line. An antibody secreted by one hybridoma was found to bind to sulfated glycolipids, i.e. sulfatide, seminolipid, sulfolactosylceramide, lysosulfatide and evidenced no binding to neutral sphingoglycolipids such as galactosylceramide, and lactosylceramide, as shown by immunodetection by thin-layer chromatography. In tissue sections, cerebellar white matter and oligodendrocytes were strongly labeled while live; immunocytofluorescence detected both immature and fully mature oligodendrocyte in tissue cultures. The antibody was successfully used to detect urinary sulfatides in metachromatic leukodystrophy and distinguish them from closely migrating other lipids from patients with other neurological diseases.

Characterization of urinary sulfatides in metachromatic leukodystrophy using electrospray ionization-tandem mass spectrometry.

Metachromatic leukodystrophy is an inherited disorder characterized by a deficiency of the lysosomal enzyme arylsulfatase A and the subsequent accumulation of sulfatide in neural and visceral tissues. Clinical diagnosis is usually confirmed by in vitro analysis of arylsulfatase A activity, but may be complicated in cases of arylsulfatase A pseudodeficiency and sphingolipid activator protein deficiency. Large quantities of sulfatide can be detected in the urinary sediment of affected individuals and its measurement can aid in diagnosis. A number of complex methods have been described for the measurement of urinary sulfatide excretion. We have developed a rapid, sensitive, and specific mass spectrometric method for determining urinary sulfatide concentration of metachromatic leukodystrophy patients. Sulfatides are extracted from urine and then directly analyzed using electrospray ionization-tandem mass spectrometry. A sulfatide internal standard has been employed for quantification. The assay has demonstrated significant elevations in the concentrations of several hydroxy and nonhydroxy molecular species of sulfatide in the urine of metachromatic leukodystrophy patients compared to age-matched controls. Analysis of urinary sulfatides in arylsulfatase A pseudodeficiency patients showed a mild elevation in some individuals when related to urinary phosphatidylcholine.

Determination of urinary sulfatides and other lipids by combination of reversed-phase and thin-layer chromatographies.

A fast and simple method for determination of sulfatides in the urine of patients with metachromatic leukodystrophy (MLD, arylsulfatase A deficiency) has been developed. The procedure consists of two steps: extraction of total urinary lipids by reversed-phase chromatography and their HPTLC separation. Two types of sorbents based on different matrixes were compared, of which the hydroxyethyl methacrylate C-18 type sorbent was found to be superior. Twenty-milliliter aliquots of urine are sufficient for the analysis. The technique is appropriate for simultaneous qualitative identification and semiquantitative densitometric determination and is suitable for routine work. The amount of sulfatides is expressed in relation to sphingomyelin, which copurifies with sulfatides and better reflects the level of membrane lipids in urine than commonly used parameters (creatinine, urine volume, etc.). The ranges were found to be 0.15-0.68 nmol sulfatide/nmol sphingomyelin for control individuals and 3.5-27.2 nmol sulfatide/nmol sphingomyelin for MLD patients. The excretion of sulfatides is pathonognomic for true MLD (due to the accumulation in kidney) and therefore its analysis is important for evaluation of suspected MLD cases including clinically and enzymatically atypical cases. The method is also useful as a complementary analysis for other lipidoses with high excretion of sphingolipids in urine (e.g., Fabry disease).

Coincidence of two novel arylsulfatase A alleles and mutation 459+1G>A within a family with metachromatic leukodystrophy: molecular basis of phenotypic heterogeneity.

In a family with three siblings, one developed classical late infantile metachromatic leukodystrophy (MLD), fatal at age 5 years, with deficient arylsulfatase A (ARSA) activity and increased galactosylsulfatide (GS) excretion. The two other siblings, apparently healthy at 12(1/2) and 15 years, respectively, and their father, apparently healthy as well, presented ARSA and GS values within the range of MLD patients. Mutation screening and sequence analysis disclosed the involvement of three different ARSA mutations being the molecular basis of intrafamilial phenotypic heterogeneity. The late infantile patient inherited from his mother the frequent 0-type mutation 459+1G>A, and from his father a novel, single basepair microdeletion of guanine at nucleotide 7 in exon 1 (7delG). The two clinically unaffected siblings carried the maternal mutation 459+1G>A and, on their paternal allele, a novel cytosine to thymidine transition at nucleotide 2435 in exon 8, resulting in substitution of alanine 464 by valine (A464V). The fathers genotype thus was 7delG/A464V. Mutation A464V was not found in 18 unrelated MLD patients and 50 controls. A464V, although clearly modifying ARSA and GS levels, apparently bears little significance for clinical manifestation of MLD, mimicking the frequent ARSA pseudodeficiency allele. Our results demonstrate that in certain genetic conditions MLD-like ARSA and GS values need not be paralleled by clinical disease, a finding with serious diagnostic and prognostic implications. Moreover, further ARSA alleles functionally similar to A464V might exist which, together with 0-type mutations, may cause pathological ARSA and GS levels, but not clinical outbreak of the disease.

Urine sulfatides and the diagnosis of metachromatic leukodystrophy.

A deficiency of the lysosomal enzyme arylsulfatase A (ASA) causes the lysosomal storage disorder metachromatic leukodystrophy (MLD). The diagnosis of MLD is straightforward in cases with deficient leukocyte or fibroblast ASA activity and a typical clinical history. However, several atypical and late-onset forms of MLD have been described. The diagnosis is also complicated by the high frequency of presumably benign polymorphisms at the ASA gene locus that are associated with markedly diminished in vitro ASA activity. Additional diagnostic tools are needed in the clinically and (or) enzymatically atypical cases. Although analyses of urinary sulfatides have been reported to be helpful in the diagnosis of MLD, previously described methods are complex and incompletely characterized and validated. We developed an improved method for determining urinary sulfatides and applied it to a cohort of individuals with MLD. The sulfatides are extracted from urine, separated from glycerol-based lipids by alkaline hydrolysis, isolated by ion-exchange chromatography, and hydrolyzed to galactosylceramide, which is then perbenzoylated and quantified by HPLC. This assay provides excellent resolution of sulfatides from other lipids and good analytical precision. In addition, the urinary sulfatide concentrations of healthy controls (mean +offSD: 0.16 +/- 0.07 nmol/mg creatinine; range: 0.07-0.34; n = 18) are clearly distinguished from those of individuals with MLD (7.6 +/- 6.1 nmol/mg creatine; 1.2-24.2; n = 20).

Elevated sulfatide excretion in heterozygotes of metachromatic leukodystrophy: dependence on reduction of arylsulfatase A activity.

Sulfatide excretion in urine and arylsulfatase A (ASA) activity in leukocytes were determined in 10 homozygotes of metachromatic leukodystrophy (MLD), 7 obligate and 5 facultative MLD heterozygotes, 6 low ASA subjects (not related to MLD homozygotes), and in 9 controls. As compared to controls (sulfatides: 0-2 nmol/mg lipid; ASA: 101-287 nmol p-nitrocatechol/mg protein/hr), MLD homozygotes displayed highly increased sulfatide excretions (27-280 nmol) and low residual ASA activities (0-13 nmol). Of 12 MLD heterozygotes (ASA: 18-87 nmol) 10 showed increased sulfatides (3-24 nmol). All heterozygotes with ASA activity < 60 nmol (n = 8) had elevated sulfatide excretions (4-24 nmol). Thus, reduction of ASA activity below 40% of the mean value of controls seems to be the critical threshold for elevated sulfatide excretion in MLD heterozygotes. The low ASA subjects (ASA in the heterozygote range) excreted sulfatides in the control range, even those with ASA activities < 60 nmoles (n = 3; including a definite homozygote for ASA-pseudodeficiency; ASA:25 nmol). Statistical evaluation of sulfatide excretion and ASA activity in all subjects (n = 37) revealed a significant inverse relation (Spearman rank correlation; R = 0.8278, P < 0.001). The finding of elevated sulfatide excretion in certain MLD heterozygotes might point to increase of sulfatides also in the nervous system.

Metachromatic leukodystrophy in Greece: observations on 4 cases.

We report our findings in four cases of metachromatic leukodystrophy diagnosed in Greece during the last 4 years. The age of onset and the clinical symptoms were those described for the late infantile form of the disease. However, one patient retained his speech and mental abilities despite his pronounced motor regression and neurological involvement. This was combined with high residual arylsulphatase A activity in white blood cell homogenates even in the 0 degrees C incubation assay.

HPLC analysis of urinary sulfatide: an aid in the diagnosis of metachromatic leukodystrophy.

Metachromatic leukodystrophy (MLD) presents as six separate variant forms, four allelic and two non-allelic. It is diagnosed in the laboratory by a decrease in the fibroblast or leukocyte arylsulfatase A activity, generally against an artificial substrate. Since residual enzyme activity is not always an indicator of presence or absence of disease, it may be helpful to supplement this information with that of the presence or absence of sulfatide storage in the body. We have improved the HPLC analysis of sulfatide by the use of a sulfated internal standard, sulfatoxymonoalkylmonoacylgalactosylglycerol. Normal urines contain approximately 0 to 0.2 nmol sulfatide/mg creatinine, whereas MLD urines may contain 5 to 7.5 nmol/mg. There is no increase in plasma sulfatide compared to controls in the age group of MLD patients which we studied (up to 4 years).

Analysis of fatty acids and sphingosines from urinary sulfatides in a patient with metachromatic leukodystrophy by gas chromatography-mass spectrometry.

The urinary sulfatides in metachromatic leukodystrophy (MLD) were analyzed by gas chromatography-mass spectrometry. Fatty acids and long chain bases were obtained after methanolysis. C22:0 and C22h:0 were major components of the fatty acids distributed in the urinary sulfatides in MLD while they were only minor components of the fatty acids in the brain sulfatides in a control subject. These results were in accordance with the report of Philippart et al. It was suggested that the urinary sulfatides originated not in the brain but in other organs. The mass spectra of the trimethylsilyl derivatives of the hydroxy fatty acid methyl esters always showed peaks at m/z (M-15-28)+ and (M-59)+, indicating that the hydroxy group was on carbon 2. Two kinds of long chain base were identified: C18-sphingosine and 3-O-methyl-C18-sphingosine. The latter compound may be a by-product formed on methanolysis.

Urinary acid mucopolysaccharides in multiple sulfatase deficiency (mucosulfatidosis).

Urinary acid mucopolysaccharides (AMPS) excretion was investigated in a Japanese case with Multiple Sulfatase Deficiency (MSD) (Mucosulfatidosis). The patient excreted AMPS 4 to 5 times more (as carbazoluronic acid) than controls. The cellulose acetate gel electrophoresis clearly indicated two major AMPS which co-migrated with heparan sulfate and chondroitin sulfate A/C. Enzymic digestion with chondroitinase AC and ABC, and by testicular hyaluronidase plus amino sugar analysis also confirmed that our case excreted heparan sulfate and chondroitin sulfate A/C. These findings suggest that there are heterogeneities of urinary AMPS excretion among cases with MSD.

Metachromatic leukodystrophy without arylsulfatase A deficiency.

Two siblings of consanguinous parents were noted to have a neurologic syndrome marked by developmental delay, regression of psychomotor performance, marked spasticity and progressive central nervous system degeneration. Markedly delayed nerve conduction times and a sural nerve biopsy which demonstrated changes typical of metachromatic leukodystrophy (MLD) were evident. Impairment of sulfated glycolipid metabolism was documented by analysis of glycospingolipid in urinary sediment. In spite of these findings, activities of arylsulfatase A and cerebroside sulfatidase in white blood cells and cultured skin fibroblasts were near normal. However, when intact growing fibroblasts were loaded with 35SO4-sulfatide a clear defect in sulfatide cleavage, comparable to that seen in MLD patients, was observed. Thus, these patients represent a new form of sulfatide storage disease -- MLD characterized by intact enzyme activity in cell homogenates but defective sulfolipid metabolism in vivo and in intact fibroblasts.