[Construction of an adenoassociated, viral derived, expression vector to correct the genetic defect in Morquio A disease]. / Construcción de un vector de expresión derivado de virus adenoasociados para corregir in vitro el defecto genético de la enfermedad de Morquio A.

INTRODUCTION: Mucopolysaccharidosis IVA (Morquio A) is caused by a deficiency of N-acetylgalactosamine-6-sulphate-sulphatase, a lysosomal enzyme required for the stepwise degradation of keratan-sulfate and chondroitin-6-sulfate. A deficiency in this enzyme results in an accumulation of glycosaminoglycans in several tissues. Currently, no effective therapies exist and only supportive measures are used to treat some manifestations of the disease. An ideal therapy is one that can be administrated early in life, has low mortality, and leads to long-term expression of the enzyme. Gene therapy emerges as a potential alternative to correct the genetic defect in MPS IVA. OBJECTIVE: Adenoassociated virus-derived expression vectors (AAV) were constructed to correct in vitro the enzyme deficiency in mucopolysaccharidosis IVA. MATERIALS AND METHODS: Adenoasociated virus-derived vectors containing the human GALNS gene and driven by the citomegalivirus immedited-early promoter were constructed using a free-adenoviral protocol. HEK293 cells and human skin Morquio A fibroblasts were transfected with the recombinat vectors. Enzyme activity was measured in cells 24 and 48 hours post-transfection. RESULTS: Free-adenovirus recombinant AAV vectors were obtained with titres up to 2.08x1010 capsids/mL. HEK293 cells and Morquio A fibroblasts transfected with vectors showed GALNS activity up to 3.05 nmoles/mg/h 48 hours post-transfection. CONCLUSION: The AAV mediated the in vitro expression of GALNS enzyme in the transfected cells. These results are the first step towards a gene therapy alternative to Morquio A disease using adenoassociated virus-derived vectors.

Construcción de un vector de expresión derivado de virus adenoasociados para corregir in vitro el defecto genético de la enfermedad de Morquio A / Construction of an adenoassociated, viral derived, expression vector to correct the genetic defect in Morquio A disease

Introducción. La mucopolisacaridosis IV A (Morquio A) es una enfermedad de depósito lisosómico causada por la deficiencia en la actividad de la enzima N-acetil-galactosamina- 6-sulfato-sulfatasa que produce la acumulación intralisosómica de queratán y condroitín-6-sulfato. Hasta el momento, su manejo es paliativo, por lo que las investigaciones se han enfocado en establecer una terapia que pueda aplicarse tempranamente y garantice la expresión estable de la enzima. En este sentido, la terapia génica se presenta como una de las potenciales alternativas terapéuticas para corregir el defecto genético en la mucopolisacaridosis IV A. Objetivo. Construir vectores de expresión derivados de virus adenoasociados para corregir in vitro la deficiencia enzimática en la mucopolisacaridosis IV A. Materiales y métodos. Se produjeron vectores derivados de virus adenoasociados que portaban el gen humano de la enzima N-acetil-galactosamina-6-sulfato-sulfatasa dirigido por el promotor temprano del citomegalovirus humano, empleando un sistema libre de adenovirus. Se transfectaron células HEK293 y fibroblastos humanos Morquio A con los virus recombinantes, y se determinó la actividad enzimática en el lisado celular a las 24 y 48 horas después de la transfección. Resultados. Se obtuvieron virus adenoasociados recombinantes, libres de adenovirus, con títulos hasta de 2,08 x 1010 cápsides/ml. Tanto en células HEK293 como en fibroblastos Morquio A transfectados, se obtuvieron actividades enzimáticas hasta de 3,05 nmoles/mg por hora, 48 horas después de la transfección. Conclusión. Los virus recombinantes producidos expresaron in vitro la enzima GALNS en las células transfectadas. Estos resultados constituyen el paso inicial para el desarrollo de una terapia génica para la enfermedad de Morquio A empleando vectores derivados de virus adenoasociados.

Acidic amino acid tag enhances response to enzyme replacement in mucopolysaccharidosis type VII mice.

We have tested an acidic oligopeptide-based targeting system for delivery of enzymes to tissues, especially bone and brain, in a murine mucopolysaccharidosis type VII (MPS VII) model. This strategy is based upon tagging a short peptide consisting of acidic amino acids (AAA) to N terminus of human beta-glucuronidase (GUS). The pharmacokinetics, biodistribution, and the pathological effect on MPS VII mouse after 12 weekly infusions were determined for recombinant human untagged and tagged GUS. The tagged GUS was taken up by MPS VII fibroblasts in a mannose 6-phosphate receptor-dependent manner. Intravenously injected AAA-tagged enzyme had five times more prolonged blood clearance compared with the untagged enzyme. The tagged enzyme was delivered effectively to bone, bone marrow, and brain in MPS VII mice and was effective in reversing the storage pathology. The storage in osteoblasts was cleared similarly with both enzyme types. However, cartilage showed a little response to any of the enzymes. The tagged enzyme reduced storage in cortical neurons, hippocampus, and glia cells. A highly sensitive method of tandem mass spectrometry on serum indicated that the concentration of serum dermatan sulfate and heparan sulfate in mice treated with the tagged enzyme decreased more than the untagged enzyme. These preclinical studies suggest that this AAA-based targeting system may enhance enzyme-replacement therapy.

Enzyme replacement therapy in a murine model of Morquio A syndrome.

Mucopolysaccharidosis IVA (MPS IVA) is an autosomal recessive disorder caused by a deficiency of N-acetylgalactosamine-6-sulfate sulfatase (GALNS), leading to accumulation of keratan sulfate (KS) and chrondroitin-6-sulfate. The pharmacokinetics and biodistributions were determined for two recombinant human GALNSs produced in CHO cell lines: native GALNS and sulfatase-modifier-factor 1 (SUMF1) modified GALNS. Preclinical studies of enzyme replacement therapy (ERT) by using two GALNS enzymes were performed on MPS IVA mice. The half-lives in blood circulation of two phosphorylated GALNS enzymes were similar (native, 2.4 min; SUMF1, 3.3 min). After intravenous doses of 250 units/g body weight were administered, each enzyme was primarily recovered in liver and spleen, with detectable activity in other tissues including bone and bone marrow. At 4 h post-injection, enzyme activity was retained in the liver, spleen, bone and bone marrow at levels that were 20-850% of enzyme activity in the wild-type mice. After intravenous doses of 250 units/g of native GALNS, and 250, 600 or 1000 units/g of SUMF1-GALNS were administered weekly for 12 weeks, MPS IVA mice showed marked reduction of storage in visceral organs, sinus lining cells in bone marrow, heart valves, ligaments and connective tissues. A dose-dependent clearance of storage material was observed in brain. The blood KS level assayed by tandem mass spectrometry was reduced nearly to normal level. These preclinical studies demonstrate the clearance of tissue and blood KS by administered GALNS, providing the in vivo rationale for the design of ERT trials in MPS IVA.

Determinant factors of spectrum of missense variants in mucopolysaccharidosis IVA gene.

Design of efficient treatment strategies for diseases requires clarification of the nature of each mutation causing the disease. In this study, we have investigated three factors to correctly predict the correlation between genotype and phenotype on N-acetylgalactosamine-6-sulfate sulfatase (GALNS) gene responsible for one of lysosomal storage diseases, known as mucopolysaccharidosis IVA (MPS IVA); (i) evolutionary conservation of amino acid residues among family proteins, (ii) conservativeness of amino acid changes in GALNS, and (iii) structural conservation of amino acid residue. The results showed that (i) the likelihood of a missense variant causing MPS IVA was directly correlated with the level of evolutionary conservation and inversely correlated with conservativeness but not correlated with the structural conservation, (ii) the disease-causative mutations were 9 times more likely to be located on the 'highly conserved' residues than the polymorphisms, (iii) the likelihood of 'non-conservative' amino acid changes in missense mutations was 6.8 times higher than those in the polymorphisms, (iv) the degree of evolutionary conservation was nearly as predictive in phenotype as that of conservativeness of amino acid changes, and (v) the combination of the two factors, evolutionary conservation and conservativeness, provides a better association between missense variants and clinical severity with higher sensitivity (83.5-88.9%) and specificity (71.4-88.3%), than that obtained by either factor alone. These findings suggest that the combination of evolutionary conservation and conservativeness is a useful tool to predict the effect of each mutation on the clinical phenotype and can be applied to the analysis of phenotype/genotype relation in other genetic diseases.

Differences in methylation patterns in the methylation boundary region of IDS gene in Hunter syndrome patients: implications for CpG hot spot mutations.

Hunter syndrome, an X-linked disorder, results from deficiency of iduronate-2-sulfatase (IDS). Around 40% of independent point mutations at IDS were found at CpG sites as transitional events. The 15 CpG sites in the coding sequences of exons 1 and 2, which are normally hypomethylated, account for very few of transitional mutations. By contrast, the CpG sites in the coding sequences of exon 3, though also normally hypomethylated, account for much higher fraction of transitional mutations. To better understand relationship between methylation status and CpG transitional mutations in this region, the methylation patterns of 11 Hunter patients with transitional mutations at CpG sites were investigated using bisulfite genomic sequencing. The patient cohort mutation spectrum is composed of one mutation in exon 1 (one patient) and three different mutations in exon 3 (10 patients). We confirmed that in normal males, cytosines at the CpG sites from the promoter region to a portion of intron 3 were hypomethylated. However, specific CpG sites in this area were more highly methylated in patients. The patients with p.R8X (exon 1), p.P86L (exon 3), and p.R88H (exon 3) mutations had a hypermethylated condition in exon 2 to intron 3 but retained hypomethylation in exon 1. The same trend was found in four patients with p.A85T (exon 3), although the degree of hypermethylation was less. These findings suggest methylation patterns in the beginning of IDS genomic region are polymorphic in humans and that hypermethylation in this region in some individuals predisposes them to CpG mutations resulting in Hunter syndrome.

Enhancement of drug delivery to bone: characterization of human tissue-nonspecific alkaline phosphatase tagged with an acidic oligopeptide.

Hypophosphatasia is caused by deficiency of activity of the tissue-nonspecific alkaline phosphatase (TNSALP), resulting in a defect of bone mineralization. Enzyme replacement therapy (ERT) with partially purified plasma enzyme was attempted but with little clinical improvement. Attaining clinical effectiveness with ERT for hypophosphatasia may require delivering functional TNSALP enzyme to bone. We tagged the C-terminal-anchorless TNSALP enzyme with an acidic oligopeptide (a six or eight residue stretch of L-Asp), and compared the biochemical properties of the purified tagged and untagged enzymes derived from Chinese hamster ovary cell lines. The specific activities of the purified enzymes tagged with the acidic oligopeptide were the same as the untagged enzyme. In vitro affinity experiments showed the tagged enzymes had 30-fold higher affinity for hydroxyapatite than the untagged enzyme. Lectin affinity chromatography for carbohydrate structure showed little difference among the three enzymes. Biodistribution pattern from single infusion of the fluorescence-labeled enzymes into mice showed delayed clearance from the plasma up to 18 h post infusion and the amount of tagged enzyme retained in bone was 4-fold greater than that of the untagged enzyme. In vitro mineralization assays with the bone marrow from a hypophosphatasia patient using each of the three enzymes in the presence of high concentrations of pyrophosphate provided evidence of bone mineralization. These results show the anchorless enzymes tagged with an acidic oligopeptide are delivered efficiently to bone and function bioactively in bone mineralization, at least in vitro. They suggest potential advantages for use of these tagged enzymes in ERT for hypophosphatasia, which should be explored.

Mutation and polymorphism spectrum of the GALNS gene in mucopolysaccharidosis IVA (Morquio A).

Mucopolysaccharidosis IVA (MPS IVA; Morquio A disease) is an autosomal-recessive disorder caused by a deficiency of lysosomal N-acetylgalactosamine-6-sulfate sulfatase (GALNS; E.C.3.1.6.4). GALNS is required to degrade glycosaminoglycans, keratan sulfate (KS), and chondroitin-6-sulfate. Accumulation of undegraded substrates in lysosomes of the affected tissues leads to a systemic bone dysplasia. We summarize information on 148 unique mutations determined to date in the GALNS gene, including 26 novel mutations (19 missense, four small deletions, one splice-site, and two insertions). This heterogeneity in GALNS gene mutations accounts for an extensive clinical variability within MPS IVA. Seven polymorphisms that cause an amino acid change, and nine silent variants in the coding region are also described. Of the analyzed mutant alleles, missense mutations accounted for 78.4%; small deletions, 9.2%; nonsense mutation, 5.0%; large deletion, 2.4%; and insertions, 1.6%. Transitional mutations at CpG dinucleotides accounted for 26.4% of all the described mutations. The importance of the relationship between methylation status and distribution of transitional mutations at CpG sites at the GALNS gene locus was elucidated. The three most frequent mutations (over 5% of all mutations) were represented by missense mutations (p.R386C, p.G301C, and p.I113F). A genotype/phenotype correlation was defined in some mutations. Missense mutations associated with a certain phenotype were studied for their effects on enzyme activity and stability, the levels of blood and urine KS, the location of mutations with regard to the tertiary structure, and the loci of the altered amino acid residues among sulfatase proteins.

Identification of a common mutation in mucopolysaccharidosis IVA: correlation among genotype, phenotype, and keratan sulfate.

Mucopolysaccharidosis IVA (MPS IVA) is a lysosomal storage disorder caused by the deficiency of N-acetylgalactosamine-6-sulfate sulfatase (GALNS). Mutation screening of the GALNS was performed by genomic PCR and direct sequence analyses in 20 MPS IVA patients from Latin America. In this study, 12 different gene mutations including nine unreported ones were identified in 16 severe and four attenuated patients and accounted for 90.0% of the unrelated mutant alleles. The gene alterations were missense mutations except one insertion. Six recurrent mutations, p.A75G, p.G116S, p.G139S, p.N164T, p.R380S, and p.R386C, accounted for 5.0, 10.0, 5.0, 7.5, 5.0, and 32.5% of the unrelated mutant alleles, respectively. The p.R386C mutation was identified in all Latin American populations studied. Eleven mutations correlated with a severe form, while one mutation, p.R380S, was associated with an attenuated form. MPS IVA patients had an elevation of urine and plasma keratan sulfate (KS) concentrations compared with those of the age-matched control. KS concentrations in severe patients were higher than those in attenuated patients. These data provide evidence for extensive allelic heterogeneity and presence of a common mutation in Latin American patients. Accumulation of mutations with clinical description and KS concentration will lead us to predict clinical severity of the patient more precisely.

Mucopolysaccharidosis IVA (Morquio A): identification of novel common mutations in the N-acetylgalactosamine-6-sulfate sulfatase (GALNS) gene in Italian patients.

Mucopolysaccharidosis IVA (MPS IVA) is a lysosomal storage disorder caused by the deficiency of N-acetylgalactosamine-6-sulfate sulfatase (GALNS). Mutation screening of the GALNS gene was performed by RT-PCR with one amplicon and direct sequence analyses using cDNA samples from 15 Italian MPS IVA patients. Each mutation was confirmed at the genomic level. In this study, 13 different gene mutations with four common mutations (over 10% of mutant alleles) were identified in 12 severe and three milder (attenuated) MPS IVA patients. The gene alterations in 12 out of 13 were found to be point mutations and only one mutation was deletion. Ten of 13 mutations were novel. The c.1070C>T (p.Pro357Leu) mutation coexisted with c.1156C>T (p.Arg386Cys) mutation on the same allele. Together they accounted for 100% of the 30 disease alleles of the patients investigated. Four common mutations accounted for 70% of mutant alleles investigated. Urine keratan sulfate (KS) concentrations were elevated in all patients investigated. These data provide further evidence for extensive allelic heterogeneity and importance of relation among genotype, phenotype, and urine KS excretion as a biomarker in MPS IVA.

General implications for CpG hot spot mutations: methylation patterns of the human iduronate-2-sulfatase gene locus.

The methylation pattern at CpG sites of a housekeeping gene correlates with the likelihood of mutation. Mucopolysaccharidosis (MPS) type II, an X-linked disorder, results from the deficiency of iduronate-2-sulfatase (IDS). In these patients, over 35% of independent point mutations at the IDS gene locus were found at CpG sites as transitional events. To gain insight into the relationship between methylation status and CpG hot spot mutations, we investigated patterns of cytosine methylation in the entire IDS gene, except for introns 4-8. Bisulfite genomic sequencing was performed on the normal leukocyte DNA. Our data show that: 1) cytosine methylation at the CpG sites was extensive, except for those present from the promoter region to a portion of intron 3; 2) a sharp boundary of methylated-nonmethylated regions was observed at the 5'-flanking region, whereas a gradual change in methylation was observed in the 2.0-kb segment in the 3'-flanking region; 3) the boundary of the 5'-flanking region contained multiple Sp1 sites and the TATA box; 4) the CpG sites in exons 1 and 2 were hypomethylated and were associated only with rare transitional mutations, while the CpG sites in exon 3 were also hypomethylated, yet were associated with a high rate of transitional mutations; 5) there was no striking sex difference in the methylation patterns in active alleles; and, 6) the methylation in both strands was symmetrical, except at the boundary of methylated-unmethylated regions.

Development and testing of new screening method for keratan sulfate in mucopolysaccharidosis IVA.

Mucopolysaccharidosis IVA (MPS IVA), a progressive lysosomal storage disease, causes skeletal dysplasia through excessive storage of keratan sulfate (KS). We developed an ELISA-sandwich assay that used a MAb specific to KS. Forty-five blood and 59 urine specimens from MPS IVA patients (ages 1-65 y) were analyzed to determine whether KS concentration is a suitable marker for early diagnosis and longitudinal assessment of disease severity. Blood specimens were obtained from patients categorized as phenotypically severe (n = 36) and milder (n = 9). Urine specimens were also analyzed from patients categorized as severe (n = 56) and milder (n = 12), respectively. Blood KS levels (101-1525 ng/mL) in MPS IVA patients were two to eight times higher than those in age-matched controls (15-323 ng/mL). It was found that blood KS level varied with age and clinical severity. Blood KS levels in both MPS IVA and controls peaked between 5 and 10 y of age (mean, 776 versus 234 ng/mL, respectively). Blood levels in severe MPS IVA were 1.5 times higher than in the milder form. In contrast to blood, urine KS levels in both MPS IVA and controls peaked between 1 and 5 y (15.3 versus 0.26 mg/g creatinine), and thereafter declined with age. Urine KS level also varied with age and clinical severity, and the severe MPS IVA phenotype was associated with 6.7 times greater urine KS excretion than the milder one. These findings indicate that the new assay for blood or urine KS may be suitable for early diagnosis and longitudinal assessment of disease severity in MPS IVA.

Contribution of the H63D mutation in HFE to murine hereditary hemochromatosis.

Hereditary hemochromatosis (HH) is an autosomal recessive disease characterized by iron accumulation in several organs, followed by organ damage and failure. The C282Y mutation in the HFE gene explains 80-90% of all diagnosed cases of HH in populations of northwestern European ancestry. Targeted disruption of the mouse Hfe gene (or introduction of the murine mutation analogous to the C282Y human mutation) produces a murine model of HH. Another mutation in the HFE gene, H63D, is more prevalent than C282Y. However, the physiological consequences of the H63D mutation (as well as C282Y/H63D compound heterozygosity) on iron homeostasis are less well established. To evaluate the phenotypic consequences of the C282Y/H63D and H63D/H63D genotypes, we produced H67D (corresponding to H63D in humans) and C294Y (corresponding to C282Y in humans) knock-in mice. H67D homozygous mice, C294Y homozygous mice, and H67D/C294Y compound heterozygous mice each demonstrated hepatic iron loading. Even on a standard diet, by 10 weeks of age, hepatic iron levels in mice of these three genotypes were significantly higher than those of wild-type littermates. The relative severity of hepatic iron loading was C294Y/C294Y > C294Y/H67D > H67D/H67D. We conclude that the H67D allele, when homozygous or combined with a more consequential mutation like C294Y, leads to hepatic iron loading. These observations indicate that the H67D mutation leads to partial loss of Hfe function and can contribute to murine HH.

Mouse model of N-acetylgalactosamine-6-sulfate sulfatase deficiency (Galns-/-) produced by targeted disruption of the gene defective in Morquio A disease.

Mucopolysaccharidosis IVA is an autosomal recessive disorder caused by a deficiency of N-acetylgalactosamine-6-sulfate sulfatase (GALNS), a lysosomal enzyme required for the stepwise degradation of keratan sulfate (KS) and chondroitin-6-sulfate (C6S). To generate a model for studies of the pathophysiology and of potential therapies, we disrupted exon 2 of Galns, the homologous murine gene. Homozygous Galns-/- mice have no detectable GALNS enzyme activity and show increased urinary glycosaminoglycan (GAGs) levels. These mice accumulate GAGs in multiple tissues including liver, kidney, spleen, heart, brain and bone marrow. At 2 months old, lysosomal storage is present primarily within reticuloendothelial cells such as Kupffer cells and cells of the sinusoidal lining of the spleen. Additionally, by 12 months old, vacuolar change is observed in the visceral epithelial cells of glomeruli and cells at the base of heart valves but it is not present in parenchymal cells such as hepatocytes and renal tubular epithelial cells. In the brain, hippocampal and neocortical neurons and meningeal cells had lysosomal storage. KS and C6S were more abundant in the cytoplasm of corneal epithelial cells of Galns-/- mice compared with wild-type mice by immunohistochemistry. Radiographs revealed no change in the skeletal bones of mice up to 12 months old. Thus, targeted disruption of the murine Galns gene has produced a murine model, which shows visceral storage of GAGs but lacks the skeletal features. The complete absence of GALNS in mutant mice makes them useful for studies of pharmacokinetics and tissue targeting of recombinant GALNS designed for enzyme replacement.

Missense models [Gustm(E536A)Sly, Gustm(E536Q)Sly, and Gustm(L175F)Sly] of murine mucopolysaccharidosis type VII produced by targeted mutagenesis.

Human mucopolysaccharidosis VII (MPS VII, Sly syndrome) results from a deficiency of beta-glucuronidase (GUS) and has been associated with a wide range in severity of clinical manifestations. To study missense mutant models of murine MPS VII with phenotypes of varying severity, we used targeted mutagenesis to produce E536A and E536Q, corresponding to active-site nucleophile replacements E540A and E540Q in human GUS, and L175F, corresponding to the most common human mutation, L176F. The E536A mouse had no GUS activity in any tissue and displayed a severe phenotype like that of the originally described MPS VII mice carrying a deletion mutation (gus(mps/mps)). E536Q and L175F mice had low levels of residual activity and milder phenotypes. All three mutant MPS models showed progressive lysosomal storage in many tissues but had different rates of accumulation. The amount of urinary glycosaminoglycan excretion paralleled the clinical severity, with urinary glycosaminoglycans remarkably higher in E536A mice than in E536Q or L175F mice. Molecular analysis showed that the Gus mRNA levels were quantitatively similar in the three mutant mouse strains and normal mice. These mouse models, which mimic different clinical phenotypes of human MPS VII, should be useful in studying pathogenesis and also provide useful models for studying enzyme replacement therapy and targeted correction of missense mutations.

Determinación de la actividad enzimática de la hexosaminidasa en fluidos biológicos / Determination of the enzimatic activity of hexosaminidase in biological fluids

Este estudio describe un método electroforético que emplea el sustrato fluorogénico 4-metilumbelliferil 2-acetamida 2-deoxi-ß-D-glucopiranosido, para determinación enzimática de la hexosaminidasa (HEX) en linfocitos de sangre períferica, líquido amniótico, suero y orina. Se propone que la electroforésis sirva como método confirmatorio del diagnóstico de la gangliosidosis GM2, ya que permite determinar la actividad enzimática de la HEX y hacer la diferenciación de las isoenzimas (HEX A y HEX B). La deficiencia de estas isoenzimas se detecta por disminución o ausencia de fluorescencia