Neurocognitive testing in a murine model of mucopolysaccharidosis type IIIA.

Mucopolysaccharidosis type IIIA (MPS IIIA) is an inherited metabolic disorder caused by a lysosomal enzyme deficiency resulting in heparan sulphate (HS) accumulation and manifests with a progressive neurodegenerative phenotype. A naturally occurring MPS IIIA mouse model is invaluable for preclinical evaluation of potential treatments but the ability to effectively assess neurological function has proved challenging. Here, the aim was to evaluate a set of behaviour tests for their reliability in assessing disease progression in the MPS IIIA mouse model. Compared to wild-type (WT) mice, MPS IIIA mice displayed memory and learning deficits in the water crossmaze from mid-stage disease and locomotor impairment in the hind-limb gait assessment at late-stage disease, supporting previous findings. Declined wellbeing was also observed in the MPS IIIA mice via burrowing and nest building evaluation at late-stage disease compared to WT mice, mirroring the progressive nature of neurological disease. Excessive HS accumulation observed in the MPS IIIA mouse brain from 1 month of age did not appear to manifest as abnormal behaviours until at least 6 months of age suggesting there may be a threshold of HS accumulation before measurable neurocognitive decline. Results obtained from the open field and three-chamber sociability test are inconsistent with previous studies and do not reflect MPS IIIA patient disease progression, suggesting these assessments are not reliable. In conclusion, water cross-maze, hind-limb gait, nest building and burrowing, are promising assessments in the MPS IIIA mouse model, which produce consistent results that mimic the human disease.

Systemic scAAV9.U1a.hSGSH Delivery Corrects Brain Biochemistry in Mucopolysaccharidosis Type IIIA at Early and Later Stages of Disease.

Mucopolysaccharidosis type IIIA (MPS IIIA, Sanfilippo A syndrome) is a single gene (SGSH) childhood onset neurodegenerative disease for which gene therapy is in clinical trial. Theoretically, the transfer of a working gene should enable functional expression of the defective protein and rescue the phenotype when administered before the onset of irreversible disease. Recombinant adeno-associated virus (AAV) is being used as a vehicle for a number of gene therapy applications and the neurotropism of serotype 9 affords utility for monogenetic neurological disorders. To assess the efficacy of restoring the underlying biochemistry in the MPS IIIA brain, tail vein injections of self-complementary AAV9 human N-sulfoglucosamine sulfohydrolase (scAAV9.U1A.hSGSH) at 3 × 1013 vg/kg were administered to 6- and 16-week-old MPS IIIA mice. Heparan sulfate (HS) and GM2 and GM3 gangliosides were cleared from the cortex, hippocampus and subcortex with residual storage remaining in the brain stem and cerebellum. SGSH activity increased in the brain of the MPS IIIA-treated mice, but remained significantly reduced compared with wild-type. Motor activity as assessed in an open-field arena, and gait length, improved in MPS IIIA mice treated at both 6 and 16 weeks of age. However, functional assessment of cognition in the water cross-maze test, as well as gait width, normalized in mice treated at 6 weeks of age only, with mice treated at 16 weeks performing similar to untreated MPS IIIA mice. Astrogliosis was reduced in mice treated at 6 and 16 weeks of age compared to untreated MPS IIIA mice. These results demonstrate that the gene product is actively clearing primary HS and secondary ganglioside accumulation in MPS IIIA mice, but in older mice, neurocognitive impairments remain. This is likely due to secondary downstream consequences of HS affecting neurological functions that are not reversible upon substrate clearance.

Phenotypic Characterization and Comparison of Cystic Fibrosis Rat Models Generated Using CRISPR/Cas9 Gene Editing.

Animal models of cystic fibrosis (CF) are essential for investigating disease mechanisms and trialing potential therapeutics. This study generated two CF rat models using clustered regularly interspaced short palindromic repeats/clustered regularly interspaced short palindromic repeats-associated protein 9 gene editing. One rat model carries the common human Phe508del (ΔF508) CF transmembrane conductance regulator (CFTR) mutation, whereas the second is a CFTR knockout model. Phenotype was characterized using a range of functional and histologic assessments, including nasal potential difference to measure electrophysiological function in the upper airways, RNAscope in situ hybridization and quantitative PCR to assess CFTR mRNA expression in the lungs, immunohistochemistry to localize CFTR protein in the airways, and histopathologic assessments in a range of tissues. Both rat models revealed a range of CF manifestations, including reduced survival, intestinal obstruction, bioelectric defects in the nasal epithelium, histopathologic changes in the trachea, large intestine, and pancreas, and abnormalities in the development of the male reproductive tract. The CF rat models presented herein will prove useful for longitudinal assessments of pathophysiology and therapeutics.

Collection of cerebrospinal fluid from murine lateral ventricles for biomarker determination in mucopolysaccharidosis type IIIA.

BACKGROUND: Cerebrospinal fluid (CSF) collection is currently the only feasible means to obtain biological fluid for the quantitative determination of biomarkers that may reflect disease activity within the brain. Studies in mouse models of human neurological disease benefit from ascertainment and subsequent analysis of brain tissue that is not afforded in human patients. The CSF provides a translational forum, however, due to the practical constraints presented by the mouse's small size, CSF is often ignored in experimental mouse models. NEW METHOD: Here we report a method for the controlled, precise and predictable collection of 10 µL of CSF from the lateral ventricles of adult mice using stereotaxic equipment and a micro-syringe pump. RESULTS: Collected CSF was clear and manifested the consistency of water and moreover, quantification of a disease-specific biomarker for the neurodegenerative disorder, mucopolysaccharidosis type IIIA (MPS IIIA) was possible in this small volume of CSF. In the naturally occurring mouse model of MPS IIIA, that faithfully recapitulates the human form of the disease, this biomarker was present at concentrations of >100 pmol/mL and undetectable in wild-type mice. COMPARISON WITH EXISTING METHOD: Advantages of this method over the most commonly used cisterna magna collection technique include increased CSF sample volume (10 µL) and reduced blood contamination. CONCLUSION: The ability to collect CSF from mouse models of neurological disease enables a forum for translating research outcomes in experimental models to the human equivalent in which CSF collection is also possible.

Transient Lentiviral Vector Production Using a Packed-Bed Bioreactor System.

Scalable lentiviral vector (LV) manufacturing is vital for successful commercialization of LV-based gene and cell therapy products. Accordingly, efforts are currently focused on developing and adapting technologies to address both upstream and downstream production bottlenecks. To overcome the limitations of current upstream processes, researchers are now favoring the use of bioreactors over traditional two-dimensional culture platforms. Bioreactors provide many advantages for manufacturing biomolecules, including process automation, tight regulation of production conditions, reduced labor input, and higher productivity potential. This study describes a transient LV production strategy employing a single-use, packed-bed bioreactor vessel. Functional LV titers in the 106 TU/mL range were achieved, and after concentration yields of up to 109 TU/mL were attained. This proof of principle study demonstrates that LV can be successfully produced in a packed-bed system. With further optimization, a packed-bed bioreactor could offer a potential scale-out solution for LV manufacturing.

Lobe-Specific Gene Vector Delivery to Rat Lungs Using a Miniature Bronchoscope.

For respiratory research utilizing gene vector delivery to the lung, the size of rodent models has typically necessitated relatively "blind" dosing via the nose, via an endotracheal tube, or through a surgical incision into the trachea. This commonly results in a limited ability to dose specific small regions of the lung reliably, and contributes to high levels of transduction variability between animals. The resultant poor reliability, reproducibility, and high variability compromises statistical capability, and so demands greater animal sample sizes than should be feasible. The first reliable targeted gene vector dosing of small regions in rat lungs has been designed and successfully implemented using a miniature rigid bronchoscope containing a working channel. Using this setup, this technique can currently access airway branches down to at least the fourth generation in the lungs of rats >200 g in body weight, allowing dosing and re-dosing of specific lobes via airway branch points in the lung tree. Here, the protocol for performing this minimally invasive technique is reported, along with the effect of delivering vesicular stomatitis virus G pseudotyped lentivirus to selected lung lobes. Examples of other applications, such as delivery of agar beads, are also shown. It is expected that the availability of this technique will substantially enhance gene vector studies in rat models for a range of lung diseases.

Large-scale production of lentiviral vectors using multilayer cell factories.

Lentiviral-mediated gene therapy has been proposed for the treatment of a range of diseases, and due to its genome integration properties, it offers the potential for long-lasting benefit from a once-off treatment. Production methods for pre-clinical studies in animal models, and ultimately for human clinical trials, must be capable of producing large quantities of high-quality lentiviral vector in an efficient and cost-effective manner. We report here a medium-scale method (from 1.5 L to 6 L of vector supernatant) for lentiviral vector production in adherent cell cultures using the NUNC™ EasyFill™ Cell Factory™ from Thermo Fisher Scientific. Downstream purification uses a Mustang Q XT5 anion exchange capsule from Pall, and an ultracentrifugation step to concentrate the vector. This method is capable of producing lentiviral vector with concentrated titres of 108-109 TU/ml, with reduced manual handling compared to single monolayer flask methods.

Role of Basal Cells in Producing Persistent Lentivirus-Mediated Airway Gene Expression.

Cystic fibrosis (CF) lung disease is an ideal candidate for a genetic therapy. It has been shown previously that preconditioning with lysophosphatidylcholine (LPC) prior to lentiviral (LV) vector delivery results in long-term in vivo gene expression in the airway epithelium of CF mice. It was hypothesized that this outcome is largely due to transduction of airway basal cells that in turn pass the transgene onto their progeny. The aim of these studies was to confirm if the in vivo delivery of a human immunodeficiency virus type 1 (HIV-1) vesicular stomatitis virus envelope glycoprotein (VSV-G) pseudotyped LV vector following LPC airway conditioning results in transduction of mouse airway basal cells in situ and if the transgene is passed onto their progeny. Additionally, the study sought to determine the efficiency of in vitro transduction of human airway basal cells. First, normal mouse nasal airways were pretreated with LPC prior to delivery of a HIV-1 VSV-G pseudotyped LV vector carrying a LacZ marker gene (LV-LacZ). An epithelial ablation model utilizing polidocanol was then used to demonstrate that clonal outgrowth of linear and spotted clusters of transgene expressing ciliated, basal, and goblet cells occurs following transduction of basal cells. Second, human basal cells were cultured from primary bronchial epithelial cells, with identity confirmed by keratin 5 staining. High levels of transgene expression were found following LV-LacZ transduction. This study demonstrates the ability of the vector delivery protocol to transduce mouse airway basal cells, the LV vector to transduce human basal cells, and the likely role of these cells in maintaining long-term gene expression. These findings support and further develop the potential of LV gene transfer for persistent correction of CF airway disease.

Challenges of up-scaling lentivirus production and processing.

Lentiviruses are becoming an increasingly popular choice of gene transfer vehicle for use in the treatment of a variety of genetic and acquired human diseases. As research progresses from basic studies into pre-clinical and clinical phases, there is a growing demand for large volumes of high purity, concentrated vector, and accordingly, the means to produce such quantities. Unlike other viral vectors, lentiviruses are difficult to produce using stable cell lines, therefore transient transfection of adherent cell lines is conventionally used, and this method has proven challenging to up-scale. Furthermore, with the required increases in the volume of vector needed for larger animal and human use, comes the need for more efficient and sophisticated supernatant purification and concentration techniques. This review presents the challenges of up-scaling lentivirus production and processing approaches, novel systems for overcoming these issues, and the quality assessments recommended for producing a clinical grade lentiviral gene therapy product.

Transduction of ferret airway epithelia using a pre-treatment and lentiviral gene vector.

BACKGROUND: The safety and efficiency of gene therapies for cystic fibrosis (CF) need to be assessed in pre-clinical models. Using the normal ferret, this study sought to determine whether ferret airway epithelia could be transduced with a lysophosphatidylcholine (LPC) pre-treatment followed by a VSV-G pseudotyped HIV-1 based lentiviral (LV) vector, in preparation for future studies in CF ferrets. METHODS: Six normal ferrets (7 -8 weeks old) were treated with a 150 µL LPC pre-treatment, followed one hour later by a 500 µL LV vector dose containing the LacZ transgene. LacZ gene expression in the conducting airways and lung was assessed by X-gal staining after 7 days. The presence of transduction in the lung, as well as off-target transduction in the liver, spleen and gonads, were assessed by qPCR. The levels of LV vector p24 protein bio-distribution in blood sera were assessed by ELISA at 0, 1, 3, 5 and 7 days. RESULTS: The dosing protocol was well tolerated. LacZ gene expression was observed en face in the trachea of all animals. Histology showed that ciliated and basal cells were transduced in the trachea, with rare LacZ transduced single cells noted in lung. p24 levels was not detectable in the sera of 5 of the 6 animals. The LacZ gene was not detected in the lung tissue and no off-target transduction was detected by qPCR. CONCLUSIONS: This study shows that ferret airway epithelia are transducible using our unique two-step pre-treatment and LV vector dosing protocol. We have identified a number of unusual anatomical factors that are likely to influence the level of transduction that can be achieved in ferret airways. The ability to transduce ferret airway epithelium is a promising step towards therapeutic LV-CFTR testing in a CF ferret model.

Correction of murine mucopolysaccharidosis type IIIA central nervous system pathology by intracerebroventricular lentiviral-mediated gene delivery.

BACKGROUND: Mucopolysaccharidoses (MPS) are inborn metabolic disorders caused by a deficiency of glycosaminoglycan degrading enzymes. Although intravenous enzyme replacement therapy is a viable approach for the treatment of non-neuronopathic forms of MPS, its effectiveness in the central nervous system (CNS) is limited by the blood-brain barrier. Alternatively, enzyme replacement therapies and other therapies that directly target the brain represent approaches that circumvent the blood-brain barrier and, in the case of gene therapies, are intended to negate the need for repetitive dosing. METHODS: In the present study, gene therapy was targeted to the brains of young adult mice affected by mucopolysaccharidosis type IIIA (MPS IIIA) by bilateral delivery of two different therapeutic lentivirus vectors to the cerebral lateral ventricles. One vector expressed codon optimised murine sulphamidase, whereas the other co-expressed sulphamidase and sulfatase modifying factor-1. RESULTS: Six months after gene delivery, bladder distension was prevented in all treated animals, and behavioural deficits were improved. Therapeutic enzyme activity from the most efficacious vector, which was also the simpler vector, ranged from 0.5- to four-fold normal within the brains of treated animals, and the average amount of integrated vector ranged from 0.1-1 gene copies per cell. Consequently, levels of ganglioside and lysosomal ß-hexosaminidase, both of which are characteristically elevated in MPS IIIA, were significantly reduced, or were normalised. CONCLUSIONS: The present study demonstrates the efficacy of the intraventricular injection as a tool to target the brain with therapeutic genes in adult MPS IIIA mice, and provides evidence supporting this approach as a potentially effective means of treating CNS pathology in MPS IIIA patients.

Correction of methylmalonic aciduria in vivo using a codon-optimized lentiviral vector.

Methylmalonic aciduria is a rare disorder of organic acid metabolism with limited therapeutic options, resulting in high morbidity and mortality. Positive results from combined liver/kidney transplantation suggest, however, that metabolic sink therapy may be efficacious. Gene therapy offers a more accessible approach for the treatment of methylmalonic aciduria than organ transplantation. Accordingly, we have evaluated a lentiviral vector-mediated gene transfer approach in an in vivo mouse model of methylmalonic aciduria. A mouse model of methylmalonic aciduria (Mut(-/-)MUT(h2)) was injected intravenously at 8 weeks of age with a lentiviral vector that expressed a codon-optimized human methylmalonyl coenzyme A mutase transgene, HIV-1SDmEF1αmurSigHutMCM. Untreated Mut(-/-)MUT(h2) and normal mice were used as controls. HIV-1SDmEF1αmurSigHutMCM-treated mice achieved near-normal weight for age, and Western blot analysis demonstrated significant methylmalonyl coenzyme A enzyme expression in their livers. Normalization of liver methylmalonyl coenzyme A enzyme activity in the treated group was associated with a reduction in plasma and urine methylmalonic acid levels, and a reduction in the hepatic methylmalonic acid concentration. Administration of the HIV-1SDmEF1αmurSigHutMCM vector provided significant, although incomplete, biochemical correction of methylmalonic aciduria in a mouse model, suggesting that gene therapy is a potential treatment for this disorder.

Skeletal response to lentiviral mediated gene therapy in a mouse model of MPS VII.

Mucopolysaccharidosis VII (MPS VII) is an autosomal recessive, lysosomal storage disorder caused by ß-glucuronidase (GUSB) deficiency, resulting in the accumulation of glycosaminoglycans (GAGs), in a variety of cell types. Severe, progressive skeletal pathology, termed dysostosis multiplex, is a prominent clinical feature of MPS VII. We have evaluated a gene therapy protocol for its efficacy in preventing the development and progression of bone pathology in MPS VII mice treated with a lentiviral vector at birth or at 7 weeks. Two weeks after injections, high levels of vector expression were observed in liver, spleen and bone marrow and to a lesser extent in kidney, lung and heart. Widespread clearance of GAG storage was observed in somatic tissues of both groups and some clearance of neuronal storage was observed in mice treated from birth. Micro-CT analysis demonstrated a significant decrease in vertebral and femoral bone mineral volume, trabecular number, bone surface density and cortical bone thickness in both treatment groups. Lumbar and femoral bone lengths were significantly decreased in untreated MPS VII mice, while growth plate heights were increased and these parameters did not change upon treatment. Small improvements in performance in the open field and rotarod behaviour tests were noted. Overall, systemic lentiviral-mediated gene therapy results in a measurable improvement in parameters of bone mass and architecture as well as biochemical and enzymatic correction. Conversely, growth plate chondrocytes were not responsive to treatment, as evidenced by the lack of improvement in vertebral and femoral bone length and growth plate height.

Therapies for neurological disease in the mucopolysaccharidoses.

Intravenous enzyme replacement therapy has been developed as a viable treatment for most of the somatic pathologies associated with the mucopolysaccharide storage disorders. However, approximately two thirds of individuals affected by a mucopolysaccharide storage disorder also display neurological disease, in these instances intravenous enzyme replacement therapy is not viable as the blood-brain barrier severely limits enzyme distribution from the peripheral circulation into the central nervous system. Accordingly, much research is now focussed on developing therapies that specifically address neurological disease, or somatic and neurological disease in combination. Therapies designed to address the underlying cause of central nervous system pathology, that is the lysosomal storage itself, can be broadly divided into two groups, those that continue the rationale of enzyme replacement, and those that address the supply side of the storage equation; that is the production of storage material. Enzyme replacement can be further divided by technology (principally direct enzyme replacement, gene replacement and cell transplantation). Here we review the current state of the art for these strategies and suggest possible future directions for research in this field. In particular, we suggest that any one approach in itself is unlikely to be as efficacious as a carefully considered combination therapy, be it a combination of some sort of enzyme replacement with substrate deprivation, or a combination of two different replacement technologies or strategies.

Comparison of ventricular and intravenous lentiviral-mediated gene therapy for murine MPS VII.

Mucopolysaccharidosis type VII (MPS VII) is caused by the deficiency of the lysosomal hydrolase ß-glucuronidase. Symptoms include intellectual impairment, growth retardation, visual and hearing deficits and organ malfunction. The MPS VII mouse displays most of the symptoms variously associated with the MPS disorders, and has been widely used as a developmental paradigm for gene therapy. In this study, a lentiviral vector expressing murine ß-glucuronidase was delivered to 6-week-old MPS VII affected mice, either by intravenous injection, or by ventricular infusion. Therapeutic outcomes were assessed 7 months after gene transfer. Intravenous vector delivery restored liver ß-glucuronidase to normal levels. Consequently, most somatic pathology was corrected, and brain pathology was reduced. In mice that received ventricular vector most brain regions appeared biochemically and histologically normal. These animals showed significantly improved behavioural performance within the open-field test. An additional positive outcome of ventricular vector delivery was the significant reduction of lysosomal storage within the eye. The blood-brain barrier is not completely impervious to lysosomal enzymes, therefore, therapeutic enzyme can be distributed widely throughout the brain via the extensive cerebral vasculature. However, improvements in somatic gene delivery and expression are required for this to be completely successful. Ventricular vector delivery cleared lysosomal storage within the CNS making this a reasonable, albeit more challenging, therapeutic option for the MPS. The best therapeutic outcomes, with possible synergistic effects within the CNS, might be expected to occur when vector delivery to the brain is used in combination with somatic gene transfer.

Correction of mucopolysaccharidosis type IIIA somatic and central nervous system pathology by lentiviral-mediated gene transfer.

BACKGROUND: The hallmark of lysosomal storage disorders (LSDs) is microscopically demonstrable lysosomal distension. In mucopolysaccharidosis type IIIA (MPS IIIA), this occurs as a result of an inherited deficiency of the lysosomal hydrolase sulphamidase. Consequently, heparan sulphate, a highly sulphated glycosaminoglycan, accumulates primarily within the cells of the reticulo-endothelial and monocyte-macrophage systems and, most importantly, neurones. Children affected by MPS IIIA experience a severe, progressive neuropathology that ultimately leads to death at around 15 years of age. METHODS: MPS IIIA pathology was addressed in a mouse model using two separate methods of therapeutic gene delivery. A lentiviral vector expressing murine sulphamidase was delivered to 6-week-old MPS IIIA affected mice either by intravenous injection, or by intraventricular infusion. Therapeutic outcomes were assessed 7 months after gene transfer. RESULTS: After intravenous gene delivery, liver sulphamidase was restored to approximately 30% of wild-type levels. The resultant widespread delivery of enzyme secreted from transduced cells to somatic tissues via the peripheral circulation corrected most somatic pathology. However, unlike an earlier study, central nervous system (CNS) pathology remained unchanged. Conversely, intraventricular gene delivery resulted in widespread sulphamidase gene delivery in (and reduced lysosomal storage throughout) the brain. Improvements in behaviour were observed in these mice, and interestingly, pathological urinary retention was prevented. CONCLUSIONS: The CNS remains the last major barrier to effective therapy for children affected by LSDs. The blood-brain barrier (BBB) limits the uptake of lysosomal enzymes from the peripheral circulation into the CNS, making direct gene delivery to the brain a reasonable, albeit more challenging, therapeutic option. Future work will further assess the relative advantages of directly targeting the brain with somatic gene delivery with sulphamidase modified to increase the efficiency of transport across the BBB.

Lentiviral-mediated gene therapy for murine mucopolysaccharidosis type IIIA.

Mucopolysaccharidosis type IIIA (MPS IIIA) is a heritable glycosaminoglycan (GAG) storage disorder which is characterised by lysosomal accumulation of heparan sulphate, secondary to a deficiency of sulphamidase (heparan-N-sulphatase, N-sulphoglucosamine sulphohydrolase, EC No. 3.10.1.1.). There is currently no treatment for affected individuals who experience progressive CNS deterioration prior to an early death. As a first step towards developing gene therapy as a treatment for MPS IIIA, an MPS IIIA mouse model was used to examine the efficacy of intravenous lentiviral-mediated gene therapy. Five-week-old mice were injected with virus expressing murine sulphamidase and analysed 6 months after treatment. Transduction by the lentiviral vector was highest in the liver and spleen of treated animals, and sulphamidase activity in these tissues averaged 68% and 186% of normal, respectively. Storage was assessed using histochemical, chemical and mass spectrometric analyses. Storage in most somatic tissues was largely normalised, although chondrocytes were an obvious exception. Histologically, improvement of lysosomal storage within the brain was variable. However, beta-hexosaminidase activity, which is abnormally elevated in MPS IIIA, was significantly reduced in every treated tissue, including the brain. Total uronic acid was also significantly reduced in the brains of treated mice. The level of a disaccharide marker (hexosamine-N-sulphate[alpha-1,4]hexuronic acid; HNS-UA) of heparan sulphate storage was also decreased in the brains of treated mice, albeit non-significantly. These results suggest that lentiviral-mediated somatic gene transfer may affect not only the somatic, but possibly also the CNS pathology, found in MPS IIIA.

Lentiviral-mediated gene correction of mucopolysaccharidosis type IIIA.

BACKGROUND: Mucopolysaccharidosis type IIIA (MPS IIIA) is the most common of the mucopolysaccharidoses. The disease is caused by a deficiency of the lysosomal enzyme sulphamidase and results in the storage of the glycosaminoglycan (GAG), heparan sulphate. MPS IIIA is characterised by widespread storage and urinary excretion of heparan sulphate, and a progressive and eventually profound neurological course. Gene therapy is one of the few avenues of treatment that hold promise of a sustainable treatment for this disorder. METHODS: The murine sulphamidase gene cDNA was cloned into a lentiviral vector and high-titre virus produced. Human MPS IIIA fibroblast cultures were transduced with the sulphamidase vector and analysed using molecular, enzymatic and metabolic assays. High-titre virus was intravenously injected into six 5-week old MPS IIIA mice. Three of these mice were pre-treated with hyperosmotic mannitol. The weight of animals was monitored and GAG content in urine samples was analysed by polyacrylamide gel electrophoresis. RESULTS: Transduction of cultured MPS IIIA fibroblasts with the sulphamidase gene corrected both the enzymatic and metabolic defects. Sulphamidase secreted by gene-corrected cells was able to cross correct untransduced MPS IIIA cells. Urinary GAG was found to be greatly reduced in samples from mice receiving the vector compared to untreated MPS IIIA controls. In addition, the weight of treated mice became progressively normalised over the 6-months post-treatment. CONCLUSION: Lentiviral vectors appear promising vehicles for the development of gene therapy for MPS IIIA.