Nils U. Bosshard

A founder mutation in the GK1 gene is responsible for galactokinase deficiency in Roma (Gypsies).

Galactokinase deficiency is an inborn error in the first step of galactose metabolism. Its major clinical manifestation is the development of cataracts in the first weeks of life. It has also been suggested that carriers of the deficiency are predisposed to presenile cataracts developing at age 20-50 years. Newborn screening data suggest that the gene frequency is very low worldwide but is higher among the Roma in Europe. Since the cloning of the galactokinase gene (GK1) in 1995, only two disease-causing mutations, both confined to single families, have been identified. Here we present the results of a study of six affected Romani families from Bulgaria, where index patients with galactokinase deficiency have been detected by the mass screening. Genetic linkage mapping placed the disease locus on 17q, and haplotype analysis revealed a small conserved region of homozygosity. Using radiation hybrid mapping, we have shown that GK1 is located in this region. The founder Romani mutation identified in this study is a single nucleotide substitution in GK1 resulting in the replacement of the conserved proline residue at amino acid position 28 with threonine (P28T). The P28T carrier rate in this endogamous population is approximately 5%, suggesting that the mutation may be an important cause of early childhood blindness in countries with a sizeable Roma minority.

Missense mutations in SGLT1 cause glucose–galactose malabsorption by trafficking defects

Glucose-galactose malabsorption (GGM) is an autosomal recessive disorder caused by defects in the Na+/glucose cotransporter (SGLT1). Neonates present with severe diarrhea while on any diet containing glucose and/or galactose [1]. This study focuses on a patient of Swiss and Dominican descent. All 15 exons of SGLT1 were screened using single stranded conformational polymorphism analyses, and aberrant PCR products were sequenced. Two missense mutations, Gly318Arg and Ala468Val, were identified. SGLT1 mutants were expressed in Xenopus laevis oocytes for radiotracer uptake, electrophysiological experiments, and Western blotting. Uptakes of [14C]alpha-methyl-d-glucoside by the mutants were 5% or less than that of wild-type. Two-electrode voltage-clamp experiments confirmed the transport defects, as no noticeable sugar-induced current could be elicited from either mutant [2]. Western blots of cell protein showed levels of each SGLT1 mutant protein comparable to that of wild-type, and that both were core-glycosylated. Presteady-state current measurements indicated an absence of SGLT1 in the plasma membrane. We suggest that the compound heterozygote missense mutations G318R and A468V lead to GGM in this patient by defective trafficking of mutant proteins from the endoplasmic reticulum to the plasma membrane.

Familial X-linked cardiomyopathy (Danon disease): diagnostic confirmation by mutation analysis of the LAMP2gene.

A boy presented at age 2.5 years with mild left ventricular hypertrophy and mild myopathy. Hypertrophic cardiomyopathy progressed relentlessly, leading to death at age 16 years shortly before planned heart transplantation. During the course of the disease, his mother developed severe dilated cardiomyopathy and died of its complications at 46 years of age. The combination of myopathy and cardiomyopathy, the biochemical and electron microscopy findings in a muscle biopsy, and the pedigree suggested Danon disease (MIM 300257), an X-linked lysosomal storage disorder caused by deficiency of lysosome-associated membrane protein-2 (LAMP2). The diagnosis was confirmed by the identification of a novel mutation, G138A, in the LAMP2gene, leading to the premature stop codon W46X. Conclusion:Early diagnosis of Danon disease is important for genetic counselling and timely cardiac transplantation, the only effective therapeutic option.

Severe Lymphatic Microangiopathy in Fabry Disease

BACKGROUND Lymphedema has been described in a few cases of Fabry disease. The etiology of lymphedema in Fabry disease is unknown. The aim of the study was to evaluate morphology and function of lymphatic microvessels in this disease. METHODS AND RESULTS In five male patients with Fabry disease, the initial lymphatic microvessels of the skin were studied in vivo, using a nearly atraumatic technique of fluorescence microlymphography and measurement of lymph capillary pressure. In addition, five female patients heterozygous for Fabry disease and 12 healthy controls were studied. The maximum spread of the fluorescent macromolecular dye into the network of superficial skin lymphatics was increased in the three male patients presenting with lymphedema (25, 26, and 45 mm, respectively). In the two male patients without swollen legs, the maximum spread of the dye was 3 and 7 mm, respectively, and in the female patients 8.8 mm (range, 4-17 mm), whereas in the healthy controls it reached only 4.3 mm (range, 1-7 mm). Fragmentation of the microlymphatic network was found in all patients, but not in controls. In controls, the diameter of the microvessels varied in a very narrow range (45-75 microm); in patients, the range was 15-150 microm. In patients with lymphedema, microlymphatic hypertension was present. CONCLUSION In patients with Fabry disease severe structural and functional changes of the initial lymphatics of the skin are present.

A splicing mutation in the α/β GlcNAc-1-phosphotransferase gene results in an adult onset form of mucolipidosis III associated with sensory neuropathy and cardiomyopathy†

A 47‐year‐old female who presented with a dilated cardiomyopathy and mild neuropathy was found to have pseudoHurler polydystrophy (mucolipidosis III). The serum lysosomal enzymes were strikingly elevated and GlcNAc‐1‐phosphotransferase activity in the patients fibroblasts was 3% of normal. Sequence analysis of the patients genomic DNA revealed a homozygous mutation of the last nucleotide of the 135‐bp exon 7 of the phosphotransferase gene encoding the α/β subunits, resulting in aberrant splicing and skipping of this exon. Remarkably, none of the skeletal and connective tissue anomalies characteristic of the disease were present. This case is the first example of mucolipidosis III presenting in an adult patient and further broadens the clinical spectrum of the disease.

Mass Spectrometric Analysis of Human Transferrin in Different Body Fluids

Abstract In this study, we present a versatile new procedure for the analysis of transferrin and its isoforms isolated from human body fluids such as serum, plasma, and cerebrospinal fluid. This method is based on a three-step procedure: (i) isolation of transferrins using anion-exchange chromatography with UV detection; (ii) concentration of the transferrin fraction; (iii) detection of the transferrins with liquid chromatography-electrospray mass spectrometry. Pre-analytical sample procedures can be omitted and no immunoaffinity columns or transferrin-specific immunoassays were used. Anticoagulants such as heparin, EDTA, citrate, and oxalate do not interfere with our analysis. According to their respective molecular masses, up to ten different isoforms of transferrin could be identified in a serum sample from a patient with a congenital disorder of glycosylation type Ia (CDG-Ia). The method was successfully applied to different pathological samples from patients with CDG-Ia, CDG-Ib, CDG-Ic, CDG-Ie, CDG-If, and CDG-IIa. Additionally, samples from alcohol consumers that were found with turbidimetric immunoassay to contain increased levels of carbohydrate-deficient transferrin were analyzed.

Low β-glucuronidase enzyme activity and mutations in the human β-glucuronidase gene in mild mucopolysaccharidosis type VII, pseudodeficiency and a heterozygote

Abstract Deficiency of β-glucuronidase is the cause of the human lysosomal storage disorder mucopolysaccharidosis type VII (MPS VII). The wide interfamilial variation in the presentation of this disorder complicates clinical diagnosis. Since greatly reduced β-glucuronidase enzyme activity may also be found in healthy individuals (pseudodeficiency), diagnosis based on the biochemical phenotype is also difficult. This is illustrated by the patients studied here, who had extremely mild symptoms confined to the spine, or tachycardia, or upper respiratory infection, and who had low β-glucuronidase activity, and excessive granulation of granulocytes and monocytes on routine blood smears. Low enzyme activity was caused by mutations in the β-glucuronidase gene in all cases. One patient was homozygous for the previously described D152N allele. Family information and 35SO4-uptake studies clearly demonstrated that he was pseudodeficient, with symptoms unrelated to his low β-glucuronidase activity. Two patients of another family were compound heterozygotes for a C38G and a Y626H allele, and were probably extremely mild MPS VII patients. The low β-glucuronidase activity in another mild MPS VII patient was due to reduced biosynthesis of stable mRNA from one allele, and a W446X mutation on the second. Extremely low β-glucuronidase enzyme activity was also found in the serum of a carrier of a 1801ΔT allele, possibly as a consequence of a dominant-negative effect. A combination of investigations is necessary in order to differentiate between mild disease and pseudodeficiency in individuals with enzyme activities close to the threshold.

Molecular diagnosis of type 1c glycogen storage disease

Abstract Glycogen storage disease type 1 (GSD 1) results from deficiency of the microsomal multicomponent glucose-6-phosphatase system. Malfunction of the catalytic subunit characterises GSD 1a. GSD 1b and GSD 1c are characterised by defective microsomal glucose-6-phosphate or pyrophosphate/phosphate transport, respectively. Recently, a gene encoding a microsomal transporter protein has been found to be mutated in GSD 1b and 1c patients. Here, we report the genomic sequence of the transporter gene and the detection of a homozygous 2-bp deletion (1211delCT) and a homozygous donor splice site mutation (317+1G→T) in two GSD 1c patients, confirming that GSD 1c is allelic to GSD 1b.

Clinical, biochemical and molecular findings in a patient with X-linked liver glycogenosis followed for 40 years

Abstract Phosphorylase kinase (PHK) is a regulatory enzyme in glycogen metabolism. Mutations in the gene encoding the α subunit of PHK (PHKA2) have been shown to be responsible for X-linked liver glycogenosis (XLG). XLG, a frequent type of glycogen storage disease, is characterised by hepatomegaly and growth retardation. Two subtypes of XLG have been described: XLG type I patients have a clear-cut PHK deficiency in liver and blood cells, whereas XLG type II patients have a normal or residual activity. Here, we present clinical, biochemical and molecular findings on a liver glycogenosis patient in whom the diagnosis XLG II only became clear after enzyme assays in the liver and identification of the disease-causing mutation. A missense mutation replacing arginine at amino acid position 186 by histidine (R186H) was identified in the PHKA2 gene. Mutations of the same arginine residue have been previously found in at least four other unrelated XLG II patients. Conclusion Arginine at position 186 of the α subunit seems to play an important role in the structure or the regulation of PHK. In patients with XLG having normal or residual PHK activity where XLG II is suspected, the identification of mutations in PHKA2 leads to the final classification.

Enzymes and Metabolites of Carbohydrate Metabolism

This chapter deals with the assays used for the diagnosis of three groups of inborn errors of metabolism of carbohydrates, i.e.: