Rosella Tomanin

Genistein reduces glycosaminoglycan levels in a mouse model of mucopolysaccharidosis type II.

Background and purpose:  Mucopolysaccharidoses (MPS) are lysosomal storage disorders resulting from a deficit of specific lysosomal enzymes catalysing glycosaminoglycan (GAG) degradation. The typical pathology involves most of the organ systems, including the brain, in its severe forms. The soy isoflavone genistein has recently attracted considerable attention as it can reduce GAG synthesis in vitro. Furthermore, genistein is able to cross the blood–brain barrier in the rat. The present study was undertaken to assess the ability of genistein to reduce urinary and tissue GAG levels in vivo.

Reduction of GAG storage in MPS II mouse model following implantation of encapsulated recombinant myoblasts.

Hunter syndrome, mucopolysaccharidosis type II (MPS II), is a X‐linked inherited disorder caused by the deficiency of the enzyme iduronate‐2‐sulfatase (IDS), involved in the lysosomal catabolism of the glycosaminoglycans (GAG) dermatan and heparan sulfate. Such a deficiency leads to the intracellular accumulation of undegraded GAG and eventually to a progressive severe clinical pattern. Many attempts have been made in the last two to three decades to identify possible therapeutic strategies for the disorder, including gene therapy and somatic cell therapy.

Human amniotic fluid stem cells protect rat lungs exposed to moderate hyperoxia.

Treatment of bronchopulmonary dysplasia (BPD) remains as yet an unmet clinical need and recently stem cells have been proposed as a therapeutic tool in animal models. We investigated the role of amniotic fluid stem cells (AFS) in an adult rat model of hyperoxia lung injury.

Rapid diagnostic testing procedures for lysosomal storage disorders : α-glucosidase and β-galactosidase assays on dried blood spots

BACKGROUND Lysosomal storage disorders (LSDs) are pathologies caused by the deficit of lysosomal enzymes; late diagnosis may render therapeutic programs less effective. As early, pre-symptomatic detection could change the natural history of the disease, we are setting up rapid microassays using dried blood spots (DBS) on filter paper. Here we report alpha-glucosidase and beta-galactosidase assays. METHODS Enzymatic activities were evaluated on DBS from five different groups of subjects including healthy controls and patients affected with an LSD. A 260-day monitoring of DBS preservation at five different temperatures and a comparison of the enzymatic activities measured in DBS obtained from a single (sDBS) or a double (dDBS) blood drop were performed as well. RESULTS Both assays could clearly distinguish the affected patients from the other subjects analyzed. Storage of DBS at 4 degrees C and below allowed a longer preservation of the enzymatic activities. No significant differences were detected between sDBS and dDBS. CONCLUSIONS DBS can be used for non-invasive, easy, inexpensive lysosomal enzyme assays. Reliability of assays on DBS needs to be checked using a control enzyme such as beta-galactosidase. DBS can be still reliably analyzed even if generated incidentally by two overlapped drops.

Non‐viral transfer approaches for the gene therapy of mucopolysaccharidosis type II (Hunter syndrome)

Aims: Hunter syndrome is a rare X‐linked lysosomal storage disorder caused by the deficiency of the housekeeping enzyme iduronate‐2‐sulphatase (IDS). Deficiency of IDS causes accumulation of undegraded dermatan and heparan‐sulphate in various tissues and organs. Approaches have been proposed for the symptomatic therapy of the disease, including bone marrow transplantation and, very recently, enzyme replacement. To date, gene therapy strategies have considered mainly retroviral and adenoviral transduction of the correct cDNA. In this paper, two non‐viral somatic gene therapy approaches are proposed: encapsulated heterologous cells and muscle electro‐gene transfer (EGT). Methods: Hunter primary fibroblasts were co‐cultured with either cell clones over‐expressing the lacking enzyme or with the same incorporated in alginate microcapsules. For EGT, plasmid vector was injected into mouse quadriceps muscle, which was then immediately electro‐stimulated. Results: Co‐culturing Hunter primary fibroblasts with cells over‐expressing IDS resulted in a three‐ to fourfold increase in fibroblast enzyme activity with respect to control cells. Fibroblast IDS activity was also increased after co‐culture with encapsulated cells. EGT was able to transduce genes in mouse muscle, resulting in at least a tenfold increase in IDS activity 1–5 weeks after treatment.

Uptake of recombinant iduronate-2-sulfatase into neuronal and glial cells in vitro

Mucopolysaccharidosis type II (MPS II, Hunter syndrome) is a congenital storage disorder resulting from mutations on the iduronate-2-sulfatase (IDS) gene. The disease shows variable clinical phenotypes from severe to mild with progressive neurological dysfunction. The therapeutic options for treatment of MPS II are limited and currently no specific therapies are available; the problem is further compounded by difficulties in delivering therapeutic agents to the central nervous system (CNS). In this work, as a potential treatment for this disease, the transfer of the recombinant IDS enzyme into brain cells has been studied in vitro. Two different approaches to obtain recombinant IDS have been utilized: production of the recombinant enzyme by a transfected human clone (Bosc 23 cells); production of the recombinant enzyme by adenoviral transduction of neuronal (SK-N-BE) or glial (C6) cells. Our data indicate that the transfected as well as the infected cells produce a large amount of the IDS enzyme, which is efficiently endocytosed into neuronal and glial cells through the mannose 6-phosphate (M6P) receptor system. Somatic gene therapy appears therefore to be suitable to correct IDS deficiency in brain cells.

Recombinant adenoviral vector-lipofectAMINE complex for gene transduction into human T lymphocytes.

We have evaluated, as a vector for gene transfer into human T lymphocytes, a recombinant adenovirus (rAd-MFG-AP) carrying a modified, membrane-exposed, alkaline phosphatase (AP) as reporter gene. CD3+ cells were selected from the buffy coat of healthy donors by the immunomagnetic technique. The positive cell population, comprising 96+/-2% CD3+ cells, was cultured with clinical-grade cytokine(s) for 3-7 days prior to rAd-MFG-AP transduction and the transgene expression was evaluated 48 hr later by indirect immunofluorescence flow cytometry assay with an anti-alkaline phosphatase antibody. The best efficiency of transduction was achieved on incubation of CD3+ cells with IL-2 plus either IL-12 (AP+ cells, 12+/-3%) or IL-7 (AP+ cells, 11+/-3%). To increase further the efficiency of transduction, we have combined LipofectAMINE and rAd-MFG-AP with the aim to enhance the uptake of viral particles into the target cells. The percentage of CD3+ cells transduced by rAd-MFG-AP-LipofectAMINE complex was 24+/-4% (range, 20-35%) after incubation with IL-2 plus IL-7 and 22+/-4% (range, 18-32%) after incubation with II-2 plus IL-12. Forty-eight hours after the incubation with rAd-MFG-AP, the transduced T lymphocytes were subjected to fluorescence-activated cell sorting and fractionated into AP+ and AP- cell subpopulations. The AP+ cell fraction, comprising 96.8% of AP+ cells, was evaluated by FACScan analysis for T lymphocyte surface antigens. The immunophenotyping of the transduced T lymphocytes has shown that there was not a particular subtype of T lymphocytes more susceptible to rAd-MFG-AP transduction. In addition, the transgene expression did not modify T lymphocyte functions, as demonstrated by results obtained by cytotoxicity assay before and after rAd-MFG-AP-LipofectAMINE complex transduction. In conclusion, human T lymphocytes can be efficiently transduced, under clinically applicable conditions, by adenovirus-LipofectAMINE complex after 7 days of culture with IL-2 and IL-12 or IL-7.

In vitro correction of iduronate-2-sulfatase deficiency by adenovirus-mediated gene transfer.

Hunter syndrome is a lethal lysosomal storage disorder caused by the deficiency of iduronate-2-sulfatase and characterized by severe skeletal and neurological symptoms. Only symptomatic treatments are available and, although bone marrow transplantation has been suggested, no encouraging results have been obtained so far. Therefore, gene therapy might be a route to be pursued for treatment of the disease. In this respect, one major goal to achieve is the generation of an overexpressing vector able to correct, in particular, central nervous system (CNS) cells. Adenoviruses have been shown to infect CNS cells efficiently with minor or even absent immunological response. We describe the generation of a replication-defective adenoviral vector, AdRSVIDS, which is able to express in vitro high levels of iduronate-2-sulfatase. After infection, accumulation of mucopolysaccharides in treated Hunter cells was normalized. Furthermore, endocytosis of the transduced IDS did occur via the mannose-6-phosphate (M6P) receptor. Since no animal model for the disease is available, we developed a system based on the generation of derma-equivalents which enabled us to verify the expression of high levels of sulfatase up to 30 days after infection.

A novel functional role of iduronate-2-sulfatase in zebrafish early development

Sulfated glycosaminoglycan chains of extracellular matrix and cell membrane-tethered proteoglycans exert specific cellular functions by interacting with a broad spectrum of morphogens and growth factors. In humans, a congenital impaired catabolism of sulfated glycosaminoglycans is associated with severe metabolic disorders. Here, we report on the identification and characterization of a zebrafish iduronate sulfatase orthologue. By knocking down its function with antisense morpholino oligos, we demonstrate that iduronate sulfatase plays a critical role during early vertebrate development and its downregulation may be responsible for severe developmental defects, including a misshapen trunk and abnormal craniofacial cartilages. We show that the altered cartilage patterning is mediated by depauperation of sox10-expressing neural crest cell precursors. Through the application of a transactivation reporter assay, we also provide a molecular proof that increased TGFbeta (Transforming Growth Factor beta) signalling is tightly associated with downregulation of iduronate sulfatase function. Our results provide an insight into the early biological impairments underlying the Hunter syndrome and suggest the use of zebrafish as a novel tool to better understand lysosomal storage disorder pathogenesis.

Gene therapy approaches for lysosomal storage disorders, a good model for the treatment of mendelian diseases

This review describes the different gene therapy technologies applied to approach lysosomal storage disorders, monogenic conditions, with known genetic and biochemical defects, for many of which animal models are available. Both viral and nonviral procedures are described, underlying the specific needs that the treatment of genetic disorders requires.