Paola Di Natale

Gene therapy augments the efficacy of hematopoietic cell transplantation and fully corrects mucopolysaccharidosis type I phenotype in the mouse model

Type I mucopolysaccharidosis (MPS I) is a lysosomal storage disorder caused by the deficiency of α-L-iduronidase, which results in glycosaminoglycan accumulation in tissues. Clinical manifestations include skeletal dysplasia, joint stiffness, visual and auditory defects, cardiac insufficiency, hepatosplenomegaly, and mental retardation (the last being present exclusively in the severe Hurler variant). The available treatments, enzyme-replacement therapy and hematopoietic stem cell (HSC) transplantation, can ameliorate most disease manifestations, but their outcome on skeletal and brain disease could be further improved. We demonstrate here that HSC gene therapy, based on lentiviral vectors, completely corrects disease manifestations in the mouse model. Of note, the therapeutic benefit provided by gene therapy on critical MPS I manifestations, such as neurologic and skeletal disease, greatly exceeds that exerted by HSC transplantation, the standard of care treatment for Hurler patients. Interestingly, therapeutic efficacy of HSC gene therapy is strictly dependent on the achievement of supranormal enzyme activity in the hematopoietic system of transplanted mice, which allows enzyme delivery to the brain and skeleton for disease correction. Overall, our data provide evidence of an efficacious treatment for MPS I Hurler patients, warranting future development toward clinical testing.

Cytokines, neurotrophins, and oxidative stress in brain disease from mucopolysaccharidosis IIIB.

Mucopolysaccharidosis IIIB (MPS IIIB; Sanfilippo syndrome type B) is characterized by profound neurological deterioration. Because a murine model of MPS IIIB disease is available, we focused on analysis of gene expression in the brain and cerebellum of 7‐month‐old MPS IIIB mice by pathway‐specific filter microarrays designed to probe apoptotic‐related, neurotrophic signalling molecules and inflammatory cytokines and receptors. Moreover, we extended the analysis with real‐time PCR performed at 1, 3, 7 months after birth. Bdnf was down‐regulated in the brain but up‐regulated in the cerebellum at 7 months of age, both at RNA and at protein levels. Cbln1 presented a threefold increase in the oldest brains while remaining unaltered in the cerebellum. Ccl3, Casp11, gp91phox, p67phox, and p47phox showed an increased expression in both brain and cerebellum at each examined time point. Ccl3, in particular, exhibited in both organs and at all times tested approximately a tenfold increase in its expression. Insofar as p47phox, p67phox, and gp91phox are all components of the phagocyte NADPH oxidase, our results suggest the possible involvement of the reactive oxygen species in the genesis of neurodegeneration in MPS IIIB disease.

Treatment of the mouse model of mucopolysaccharidosis type IIIB with lentiviral-NAGLU vector.

The Sanfilippo syndrome type B (mucopolysaccharidosis IIIB) is an autosomal recessive disorder due to mutations in the gene encoding NAGLU (alpha-N-acetylglucosaminidase), one of the enzymes required for the degradation of the GAG (glycosaminoglycan) heparan sulphate. No therapy exists for affected patients. We have shown previously the efficacy of lentiviral-NAGLU-mediated gene transfer in correcting in vitro the defect on fibroblasts of patients. In the present study, we tested the therapy in vivo on a knockout mouse model using intravenous injections. Mice (8-10 weeks old) were injected with one of the lentiviral doses through the tail vein and analysed 1 month after treatment. A single injection of lentiviral-NAGLU vector resulted in transgene expression in liver, spleen, lung and heart of treated mice, with the highest level reached in liver and spleen. Expression of 1% normal NAGLU activity in liver resulted in a 77% decrease in the GAG content; more remarkably, an expression of 0.16% normal activity in lung was capable of decreasing the GAG level by 29%. Long-term (6 months) follow up of the gene therapy revealed that the viral genome integration persisted in the target tissues, although the real-time PCR analysis showed a decrease in the vector DNA content with time. Interestingly, the decrease in GAG levels was maintained in liver, spleen, lung and heart of treated mice. These results show the promising potential and the limitations of lentiviral-NAGLU vector to deliver the human NAGLU gene in vivo.

Identification of molecular defects in Italian Sanfilippo A patients including 13 novel mutations

Sanfilippo syndrome type A or mucopolysaccharidosis IIIA (MPS IIIA) is a lysosomal storage disorder caused by the deficiency of the enzyme heparin sulfamidase (EC 3.10.1.1), required for the degradation of the mucopolysaccharide heparan sulfate. Patients develop central nervous system degeneration resulting in progressive dementia, developmental delay, hyperactivity, and aggressive behaviour; subjects may present a wide spectrum of clinical severity. Here, we report the results from molecular analysis of 24 Italian MPS IIIA patients diagnosed over the last 15 years in our laboratory. Altogether, we were able to characterize 38 out of the 48 (79%) pathogenic alleles. We identified 16 molecular defects, 13 novel. The majority of alterations were missense mutations: on exon two (Y40N; A44T; S66W; R74C), on exon four (G122R; P128L; L146P; R150Q), on exon five (D179N; R182C), on exon six (P227R) and on exon eight (E369K; R377C). Single base pair deletions: on exon two (A52nt‐1) and on exon eight (T360nt‐1) and one base pair insertion on exon eight (V361nt + 1) were also identified. Restriction enzyme or ARMS analyses were used to confirm each alteration. S66W represents the most common alteration in our patients population accounting for 33% of the total alleles. Interestingly, all six patients from Sardinia present this mutation, and five of them are homozygous for this change, suggesting that these subjects may have been derived from a common founder. Hum Mutat 11:313–320, 1998.

Sulphatase activities are regulated by the interaction of sulphatase-modifying factor 1 with SUMF2

Sulphatases undergo a unique post‐translational modification that converts a highly conserved cysteine located within their active site into formylglycine. This modification is necessary for the catalytic activities of the sulphatases, and it is generated by the protein product of sulphatase‐modifying factor 1 (SUMF1), the gene mutated in multiple sulphatase deficiency (MSD). A paralogous gene, SUMF2, was discovered through its sequence similarity to SUMF1. We present evidence that SUMF2 colocalizes with SUMF1 within the endoplasmic reticulum and that the two proteins form heterodimers. SUMF1 and SUMF2 also form homodimers. In addition, SUMF2 is able to associate with the sulphatases with and without SUMF1. We have previously shown that co‐transfection of SUMF1 with the sulphatase complementary DNAs greatly enhances the activities of the overexpressed sulphatases. Here, we show that SUMF2 inhibits the enhancing effects of SUMF1 on sulphatases, suggesting that the SUMF1–SUMF2 interaction represents a further level of control of these sulphatase activities.

Mucopolysaccharidosis IIIB: oxidative damage and cytotoxic cell involvement in the neuronal pathogenesis.

Sanfilippo B syndrome (Mucopolysaccharidosis IIIB, MPS IIIB) is a lysosomal storage disease due to mutations in the gene encoding alpha-N-acetylglucosaminidase and is characterized by a severe neurological disorder. Although several studies have been reported for the murine model of the disease, the molecular basis and the sequence of events leading to neurodegeneration remain to be clarified. We previously suggested the possible involvement of the reactive oxygen species in the disease pathogenesis. In the present paper we extended the analysis of oxidative stress by evaluating the production of superoxide ions throughout the CNS and by evaluating the effect of the stress on the cellular macromolecules. These approaches applied to one-month-old, three-month-old and six-month-old mice revealed that oxidative stress is present in the affected cerebrum and cerebellum tissues from one month from birth, and that it results primarily in protein oxidation, both in the cerebrum and cerebellum, with lipid peroxidation, and especially DNA oxidation, appearing milder and restricted essentially to the cerebellum. We also identified additional genes possibly associated with the neuropathology of MPS IIIB disease. Real time RT-PCR analysis revealed an altered expression of the Sod1, Ret, Bmp4, Tgfb, Gzmb and Prf1 genes. Since Gzmb and Prf1 are proteins secreted by NK/cytotoxic T-cells, these data suggest the involvement of cytotoxic cells in the neuronal pathogenesis. Extending our previous study, findings reported in the present paper show that oxidative stress and all the analyzed stress-related pathological changes occur very early in the disease course, most likely before one month of age.

Heparan N-sulfatase gene: two novel mutations and transient expression of 15 defects.

Sanfilippo syndrome type A or mucopolysaccharidosis IIIA (MPS IIIA) results from the deficiency of the enzyme heparan N-sulfatase (NS, EC 3.10.1.1), required for the degradation of heparan sulfate. Molecular defects of 24 Italian MPS IIIA patients were recently reported by our group. We report here two novel mutations: 1040insT and Q365X and the expression studies on 15 of the identified defects. Transient expression of COS cells by cDNA mutagenized to correspond to heparan N-sulfatase mutations Y40N, A44T, 166delG, G122R, P128L, L146P, R150Q, D179N, R182C, R206P, P227R, 1040insT, 1093insG, E369K, R377C did not yield active enzyme, demonstrating the deleterious nature of the mutations. Western blot analysis and metabolic labeling experiments revealed, for cells transfected with wild-type enzyme, a precursor 62-kDa form and a mature 56-kDa form. Western blot resulted, for 11 mutations, in the presence of both forms, indicating a normal maturation of the mutant enzyme. Western blot, metabolic labeling and immunofluorescence experiments suggested, for mutations 166delG, L146P, 1040insT and 1093insG, an increased degradation of the mutant enzymes.

The iduronate sulfatase gene: Isolation of a 1.2-Mb YAC contig spanning the entire gene and identification of heterogeneous deletions in patients with Hunter syndrome

A recently isolated cDNA clone from the iduronate sulfatase (IDS) gene has been used both to seed a contig of overlapping yeast artificial chromosomes (YACs) and to investigate the molecular defect in patients with Hunter syndrome (MPS II). Six YAC clones were found to span the IDS gene, and those and 14 other YACs were assembled into a 1.2-Mb contig around the gene in Xq27-q28. The physical map of the region identifies several putative CpG islands, suggesting the presence of other genes in the vicinity. DNA from a patient with a translocation breakpoint in the gene also permitted the orientation of the contig in the chromosome. Southern analysis of DNA from 25 unrelated Italian Hunter syndrome patients revealed 4 with deletions or rearrangements in the IDS gene.

Fourteen novel mucopolysaccharidosis IVA producing mutations in GALNS gene

Mucopolysaccharidosis IVA (MPS IVA) is an autosomal recessive disorder caused by a deficiency of the lysosomal N‐acetylgalactosamine‐6‐sulfate sulfatase. Here, we report our analysis of data on 21 patients of diverse ethnic and geographic origins studied by SSCP and sequencing analysis. Sixteen mutations were detected, including 14 new mutations (11 missense, one premature termination, one splice site alteration, and one cryptic site alteration). The donor splice site mutation (IVS4 + 1G→A) predicts that normal splicing will be abolished and that translation would lead to an immediate premature termination (W141X). Another novel nucleotide change outside the coding sequence is an intronic alteration (IVS9‐42C→T:ggtcggtgcggttggtgc) creating a potential cryptic donor site. The nucleotide sequence surrounding this alteration is highly suggestive of a consensus donor splice site. All 12 missense and nonsense mutations were shown by transient expression to abolish or greatly reduce GALNS activity, thereby providing an explanation as to why they produce MPS IVA. All mutations were readily confirmed by restriction enzyme or by allelic specific oligonucleotide analysis (ASO). These findings, coupled with previously reported mutations, bring the total of different mutations to 41 among independent families with MPS IVA, illustrating the extensive allelic heterogeneity among mutations producing MPS IVA. Hum Mutat 10:368–375, 1997.

Intracranial gene delivery of LV-NAGLU vector corrects neuropathology in murine MPS IIIB†‡

Mucopolysacccharidosis (MPS) IIIB is an inherited lysosomal storage disorder caused by the deficiency of alpha‐N‐acetylglucosaminidase (NAGLU). The disease is characterized by mild somatic features and severe neurological involvement with high mortality. Although several therapeutic approaches have been applied to the murine model of the disease, no effective therapy is available for patients. In this study, we used the lentiviral‐NAGLU vector to deliver the functional human NAGLU gene into the brain of young adult MPS IIIB mice. We report the restoration of active enzyme with a sustained expression throughout a large portion of the brain, and a significantly improved behavioral performance of treated animals. Moreover, we analyzed the effect of therapy on the expression profile of some genes related to neurotrophic signaling molecules and inflammatory cytokines previously found altered in MPS IIIB mice. At 1 month from treatment, the level of cerebellin 1 (Cbln1) was decreased while the brain‐derived neurotrophic factor (Bdnf) expression was increased, both reaching normal values. At 6 months from treatment a significant reduction in the expression of all the inflammation‐ and oxidative stress‐related genes was observed, as well as the maintenance of the correction of the Bdnf gene expression. These results indicate that NAGLU delivery from intracerebral sources has the capacity to alleviate most disease manifestations in MPS IIIB mice; furthermore, Bdnf might be a response‐to‐therapy biomarker for MPS IIIB.