Intravitreal Gene Therapy Reduces Lysosomal Storage in Specific Areas of the CNS in Mucopolysaccharidosis VII Mice

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The Journal of Neuroscience, April 15, 2003, 23(8):3302

Intravitreal Gene Therapy Reduces Lysosomal Storage in Specific Areas of the CNS in Mucopolysaccharidosis VII Mice
Anne K. Hennig¹, Beth Levy⁴, Judith Mosinger Ogilvie²^,⁵, Carole A. Vogler⁴, Nancy Galvin⁴, Steven Bassnett², and Mark S. Sands¹^,³
¹ Department of Internal Medicine, Division of Stem Cell Biology, and Departments of ² Ophthalmology and Visual Sciences and ³ Genetics, Washington University School of Medicine, St. Louis, Missouri 63110, ⁴ Department of Pathology, St. Louis University School of Medicine, St. Louis, Missouri 63107, and ⁵ Fay and Carl Simons Center for the Biology of Hearing and Deafness, Central Institute for the Deaf, St. Louis, Missouri 63110

  ABSTRACT

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ABSTRACT
Introduction
Materials and Methods
Results
Discussion
REFERENCES

The mucopolysaccharidoses (MPSs) are lysosomal storage diseases resulting from impaired catabolism of sulfated glycosaminoglycans.MPS VII mice lack lysosomal $beta$ -glucuronidase (GUSB) activity, leadingto the accumulation of partially degraded chondroitin, dermatan,and heparan sulfates in most tissues. Consequently, these micedevelop most of the symptoms exhibited by human MPS VII patients,including progressive visual and cognitive deficits. To investigatethe effects of reducing lysosomal storage in nervous tissues,we injected recombinant adeno-associated virus encoding GUSB directlyinto the vitreous humor of young adult mice. Interestingly, GUSBactivity was subsequently detected in the brains of the recipients.At 8-12 weeks after treatment, increased GUSB activity and reducedlysosomal distension were found in regions of the thalamus andtectum that received inputs from the injected eye. Lysosomal storagewas also reduced in adjacent nonvisual regions, including thehippocampus, as well as in the visual cortex. The findings suggestthat both diffusion and trans-synaptic transfer contribute tothe dissemination of enzyme activity within the CNS. Intravitrealinjection may thus provide a means of delivering certain therapeuticgene products to specific areas within theCNS.

Key words: CNS; gene therapy; genetic diseases; inborn errors of metabolism; axonal transport; lysosomal storage reduction

  Introduction

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ABSTRACT
Introduction
Materials and Methods
Results
Discussion
REFERENCES

Lysosomal storage diseases are inherited disorders that are usually caused by decreased activity of one of the lysosomal acidhydrolases. Incompletely degraded substrate accumulates withinlysosomes, interfering with cellular metabolism and eventuallyimpairing the function of various organ systems. Progressive mentalretardation, retinal degeneration, and other nervous system dysfunctionsare common clinical features of many of these diseases in humans.Mice with mucopolysaccharidosis (MPS) type VII have a single base-pairdeletion in exon 10 of the $beta$ -glucuronidase (GUSB) gene and consequentlyhave no detectable GUSB (EC 3.2.1.31) activity (Birkenmeieret al., 1989; Sands and Birkenmeier, 1993). These mice show progressiveimpairment of most of the organ systems involved in human MPSVII (Vogler et al., 1990). Nervous system involvement includesprogressive retinal degeneration with an accompanying decreasein electroretinogram amplitudes (Ohlemiller et al., 2000). Cognitivedeficits likely result, at least in part, from lysosomal storagewithin the hippocampus and neocortex (Levy et al., 1996; O'Connoret al., 1998).

Several therapeutic strategies can prevent, delay, or decrease the severity of many of these symptoms in the MPS VII mouse(Vogler et al., 1998). Virus-mediated gene transfer therapy initiatedat birth is both effective and long lasting (Daly et al., 1999b,2001; Frisella et al., 2001). However, because therapy is usuallynot initiated until after disease-related symptoms appear, wewanted to investigate whether reducing lysosomal storage actuallyimproved function of nervous tissue or merely arrested progressionof the dysfunction. Specifically, we injected an adeno-associatedvirus (AAV)-based gene therapy vector directly into the vitreoushumor of young adult MPS VII mice with established lysosomal storagedisease (A. K. Hennig, unpublished observations). One surprisingfinding with important therapeutic implications was that highlevels of GUSB activity were detected in the optic nerve and tract.This activity decreased lysosomal storage within the thalamus,tectum, visual cortex, and neighboring brain areas, includingthe hippocampus. Therefore, this mode of administration mightprovide a means of delivering therapeutic agents to certain siteswithin theCNS.

  Materials and Methods

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ABSTRACT
Introduction
Materials and Methods
Results
Discussion
REFERENCES

Experimental animals and viral injections. MPS VII (mps/mps) and control (mps/+ or +/+) mice were produced by heterozygousmatings of B6.C-H-2^bm1/ByBir-gus^mps/+ mice, identified biochemically at birth, and genotyped at weaningas described previously (Sands et al., 1993; Wolfe and Sands,1996). Mice at either 4 or 6 weeks of age were anesthetized with80 mg/kg ketamine/15 mg/kg xylazine. A 32 ga needle was insertedthrough the sclera just posterior to the ora serrata in the superotemporalquadrant. Three microliters of either recombinant AAV (AAV $beta$ GEnh)or sterile tissue culture medium (Opti-MEM; Invitrogen) were slowlyinjected into the posterior chamber of the left eye. Antibioticophthalmic cream (Vetropolycin; Pharmaderm, Melville, NY) wasapplied to the eye after theinjection.

The AAV $beta$ GEnh vector consists of the human GUSB cDNA driven by a cytomegalovirus enhancer/chicken $beta$ -actin promoter cassette(Daly et al., 1999a). Viral stocks were prepared by the Gene TherapyVector Core Facility of the University of Florida, as describedpreviously (Zolotukhin et al., 1999). Particle number and infectiousunits were determined by slot-blot analysis and infectious centerassay, respectively. Each 3 µl injection contained 1.5 × 10⁷ infectiousparticles.

Biochemical, histological, and molecular analyses. Mice were killed by ketamine overdose 8 (n = 6) or 12 (n = 20) weeks aftertreatment, and eyes, optic nerves, brain, and other tissues wereharvested. Homogenates were prepared from whole optic nerves orserial 2-mm-thick coronal sections of brains from four AAV $beta$ GEnh-treatedand two Opti-MEM-treated MPS VII mice 12 weeks after treatment,and four untreated MPS VII and four untreated normal littermates.GUSB activity was quantified as described by Wolfe and Sands (1996),and specific activity was expressed as nanomoles fluorescent 4-methylumbelliferonereleased per hour per milligram of totalprotein.

For GUSB histochemical localization, tissue samples were immersed in OCT compound (Sakura Finetek USA, Torrance, CA) and frozenon dry ice. GUSB activity was localized in 16 µm (eye) or 40 µm(brain) cryostat sections using the naphthol-ASBI- $beta$ -D-glucuronide/hexazotizedpararosaniline histochemical stain as described by Wolfe and Sands(1996). Three-dimensional reconstruction of GUSB staining wasperformed on the brain of a 16-week-old MPS VII mouse that hadreceived a single intravitreal injection of AAV $beta$ GEnh in the lefteye at 4 weeks of age. A contiguous series of 60-µm-thick coronalcryostat sections through the entire brain was stained for GUSBactivity. Images were digitally captured, and a three-dimensionalimage was reconstructed using Vox Blast software (VayTek, Fairfield,CA).

Lysosomal storage in the CNS was evaluated at 8 (n = 1) or 12 (n = 2) weeks after treatment, corresponding to 14 or 16 weeksof age, respectively. One of the 12 week postinjection mice receivedbilateral intravitreal injections. Brains were immersion-fixedfor at least 24 hr in fresh 4% paraformaldehyde/2% glutaraldehydein PBS and divided along the midsagittal fissure, and the righthalves were cut in coronal slices (see Table 2). The slices werepostfixed in osmium tetroxide and embedded in Spurr's resin. Toluidineblue-stained 0.5-µm-thick sections were evaluated for evidenceof lysosomal storage in leptomeninges (pia-arachnoid), intraparenchymalperivascular cells, neurons, and microglial cells. Lysosomal storagewas evaluated in the visual and nonvisual inferolateral parietallobe and frontal lobe of the neocortex, hippocampal areas CA1through CA4, dorsal brainstem, and the dorsolateral central graymatter. Reduction of storage was determined by comparison withage-matched untreated and Opti-MEM-treated normal and MPS VIIbrains. A brain from a normal AAV $beta$ GEnh-treated littermate wasalsoexamined.

PCR analysis was performed on cryostat sections from three 16-week-old, unilaterally treated MPS VII mice, using primers specificfor exons 6 and 7 (Daly et al., 1999a). These primers amplifya 240 bp fragment from the human GUSB cDNA and, less efficiently,a 454 bp fragment from the mouse GUSB gene. The sensitivity ofthis assay was determined by titering mouse fibroblasts (3521cells) (Sands and Birkenmeier, 1993), which contain a single retrovirallyinserted copy of the human GUSB cDNA with nontransduced 3521 cells.Cell pellets containing 4 × 10⁶ cells were prepared and tested the same as cryostatsections.

  Results

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ABSTRACT
Introduction
Materials and Methods
Results
Discussion
REFERENCES

After intravitreal injection of AAV $beta$ GEnh, GUSB enzyme activity was noted in the optic nerve, chiasm, and tract, the lateralgeniculate nucleus (LGN) of the thalamus, and the superior colliculus(SC) contralateral to the injected eye of treated MPS VII mice(Fig. 1). Mice that received bilateral injections of virus showedsymmetrical distributions of enzyme activity. GUSB activity withinthe entire brain of one randomly chosen, unilaterally AAV $beta$ GEnh-treatedMPS VII mouse was visualized by three-dimensional reconstructionof images from serial cryostat sections (Fig. 2). Posterior tothe optic chiasm, GUSB activity extends dorsally around the lateraledges of the thalamus, where axons of the optic tract travel toreach the LGN. On the side of the brain contralateral to the injectedeye, enzyme activity continues dorsally and posteriorly throughthe LGN and then medially to the SC in the dorsal brainstem betweenthe cortex and the cerebellum. Similar enzyme activity patternswere seen in all brains examined from AAV $beta$ GEnh-treated MPS VIImice 4 weeks (n = 3), 8 weeks (n = 4), or 12 weeks (n = 5) afterinjection. No enzyme activity was found in brains from MPS VIImice injected with culture medium.

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Figure 1. GUSB activity is present in the brain along the visual pathway. A, An oblique coronal section through the brain of an MPS VII mouse that received a unilateral intravitreal injection of AAV $beta$ GEnh. GUSB activity (red) is present in the optic nerve (ON) from the mouse's left (injected) eye but not in the ON from the untreated right eye. B, An adjacent section stained with cresyl violet shows the cellular architecture. C, A parallel section through the optic chiasm (OC) and tract (OT), lateral geniculate nucleus (LGN), and superior colliculus (SC) of the same brain shows prominent GUSB activity on the side contralateral to the injected eye, as well as a lower level of activity in the ipsilateral LGN. This pattern of enzyme activity was seen in all brains from MPS VII mice that received unilateral intravitreal AAV $beta$ GEnh. D, A section adjacent to that in C, stained with cresyl violet. E, A coronal section through the brain of an MPS VII mouse that received bilateral intravitreal AAV $beta$ GEnh shows a symmetrical pattern of high-level enzyme activity. F, A parallel section from the same brain as E shows high-level activity in both SCs. L, Mouse's left; R, mouse's right. Sections stained for GUSB activity are counterstained with methyl green.

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Figure 2. The distribution of GUSB activity throughout the brain is seen in a three-dimensional reconstruction from another 16-week-old MPS VII mouse treated unilaterally with intravitreal AAV $beta$ GEnh at 4 weeks of age. A, Lateral view of the reconstructed image shows surface contours of the cerebral hemisphere, cerebellum, and brainstem, from anterior (ant.) to posterior (post.). B, Rendering the image transparent shows the pattern of GUSB activity along the visual pathway. C, Frontal view, showing the surface contours of the reconstruction. The right (blue) and left (red) optic nerves (ON) can be seen entering the brain. Right and left indicate the right and left sides of the mouse. D, In the transparent image, GUSB activity is most prominent in the optic nerve and tract, lateral geniculate nucleus (LGN), and superior colliculus (SC) on the right side, contralateral to the injected eye. Lower levels of activity can also be seen in the ipsilateral optic pathway.

The amount of GUSB enzyme activity present 12 weeks after treatment was quantified in 2-mm-thick coronal slices from rightor left half-brains (Table 1). Although the specific activitylevels varied among the AAV $beta$ GEnh-treated mice, all showed substantialincreases in GUSB activity in the contralateral brain slices betweenthe optic chiasm and the posterior end of the superior colliculuscompared with untreated MPS VII littermates. The treated mousewith the highest contralateral activity levels also had a detectableincrease in GUSB activity on the ipsilateral side of the brain.Specific activity levels ranged from 2.3 to 17% of normal levels,substantially lower than those of normal littermates. This isconsistent with the localization of enzyme activity to discretesubregions of the brain seen histochemically.

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Histopathologic examination was performed to assess lysosomal storage in the brains of treated and untreated mice (Table 2,Fig. 3). In the central gray (thalamic) and dorsal brainstem (tectal)nuclei of untreated MPS VII mice, lysosomal distension in neuronalsomata was slight, whereas storage in glial cells was more prominent(Fig. 3). In the treated mice, storage was reduced in areas correspondingto both the LGN and the SC (Table 2). In the visual cortex, lysosomalstorage was reduced in both neurons and microglia in the moreposterior sections examined. In contrast, in the more anteriorvisual cortex and the adjacent inferolateral parietal cortex,no reduction in storage was apparent at the light microscopiclevel. In general, although the decrease in storage was more conspicuousin glial cells than in neurons, both cell populations showed similarresponses in each area examined.

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Figure 3. Intravitreal AAV $beta$ GEnh decreases lysosomal storage in hippocampus and visual cortex as well as LGN. Pairs of toluidine blue-stained, 0.5-µm-thick sections from the CA1 and CA4 regions of the hippocampus, visual cortex (VC), nonvisual cortex (NVC), and lateral geniculate nucleus (LGN) are from two 16-week-old MPS VII mice. The sections indicated by " $-$ " are from the mouse that received no treatment. The sections indicated by "+" are from a littermate that received unilateral intravitreal AAV $beta$ GEnh at 4 weeks of age. Black arrows indicate distended vacuoles in neurons; white arrows indicate storage in microglia and other nonneuronal cells. The approximate sites of the respective histologic samples are indicated on the GUSB-stained cryostat section.

In the hippocampus of treated mice, the CA3-CA4 regions, which are in dorsal proximity to the LGN, had reduced neuronal andmicroglial storage more frequently than the CA1-CA2 regions, whichare farther from the visual pathway (Fig. 3). Only the bilaterallyinjected MPS VII mouse showed improvement in the CA1-CA2 regions.Storage was reduced in the leptomeninges (pia-arachnoid) in bothof the 12 week postinjection mice examined, but perivascular cellswere cleared only in the mouse that received bilateral injections.No reduction in storage was seen in theependyma.

Spheroids are morphologic alterations in neuronal processes indicative of axonal degeneration. They have previously been describedin animal models of several lysosomal storage diseases includingMPS VII (Levy et al., 1996; Walkley, 1998). All of the AAV $beta$ GEnh-treatedmice that were examined had spheroids in the central white matter,neocortex, central gray matter, and hippocampal pyramidal celllayer. The distribution patterns were similar to those seen inuntreated and saline-treated MPS VII control mice. Thus, MPS VIImice that received intravitreal AAV $beta$ GEnh treatment showed lesslysosomal storage than untreated MPS VII mice of the same age,but they still had other morphologic alterations associated withMPS VII. The functional significance of this finding isunclear.

To investigate whether the GUSB activity present in the brains of the treated mice was being produced locally, PCR amplificationof GUSB sequences was performed on DNA extracted from cryostatsections adjacent to those stained for enzyme activity. The primerspreferentially amplify a 240 bp fragment from the human cDNA presentin the AAV genome, but they also produce a 454 bp fragment fromthe endogenous mouse GUSB gene. When tissue from a representativeinjected animal was examined, the 240 bp AAV genome-specific fragmentwas amplified only from DNA obtained from tissue sections throughtreated eyes (Fig. 4A). The 454 bp mouse genomic GUSB product,but no AAV genome-specific fragment, was amplified from the untreatedright eye, the optic nerve exiting the treated eye, and braincoronal sections through the optic chiasm, LGN, or SC. Similarresults were obtained from two additional injected animals analyzedin the identical manner. This assay as performed detects as littleas one copy of the human cDNA in ~2,000-10,000 haploid mouse genomes(Fig. 4B).

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Figure 4. PCR reveals AAV $beta$ GEnh DNA in the injected eyes of treated mice, but not in brain samples. A, DNA from the right optic nerve (lane 1), left (injected) eye (lane 2), left optic nerve (lane 3), optic chiasm (lane 4), right LGN (lane 5), posterior LGN + anterior SC (lane 6), and SC (lane 7) of a 14-week-old MPS VII mouse that received an intravitreal injection at 6 weeks of age. Primers amplified a fragment of 240 bp from the human GUSB cDNA sequence encoded by AAV $beta$ GEnh as well as a 454 bp fragment from the endogenous mouse GUSB gene. B, Murine fibroblasts (3521 cells) containing one retroviral hGUSB cDNA insert per cell (lane 1) were titered with untransduced 3521 cells (lane 7). Cell mixtures contained one copy of hGUSB per 100 haploid genomes (lane 2), one per 1 × 10³ (lane 3), one per 2 × 10³ (lane 4), one per 10⁴ (lane 5), and one per 2 × 10⁴ (lane 6). Fragment sizes are given in base pairs.

  Discussion

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ABSTRACT
Introduction
Materials and Methods
Results
Discussion
REFERENCES

The retina is a readily accessible CNS structure containing neurons that project to the thalamus and tectum. Many substancesincluding proteins, chemical tracers, and small precursor moleculesare transported along these projections when injected into theposterior chamber of the eye (Grafstein and Forman, 1980). Ina recent study, green fluorescent protein (GFP), a cytoplasmicmarker, was transported in an anterograde direction after AAV-mediatedgene transfer to the eye (Dudus et al., 1999). The findings presentedhere demonstrate that retinal expression of a noncytoplasmic protein(a lysosomal enzyme) results in enzyme activity appearing in thethalamus and tectum in levels sufficient to reduce disease pathologyin these and adjacent areas. The unequal distribution of enzymeactivity between the two hemispheres in unilaterally injectedanimals is consistent with the low percentage of retinotectalfibers that innervate the ipsilateral primary visual nuclei inmice (Drager, 1985). Axonal transport of the protein rather thanthe virus seems to account for most of the activity in the brain,because the amount of vector genome in the CNS areas with thehighest amounts of enzyme activity was at most extremely low.Because of the limitations of the PCR assay, however, small amountsof AAV might also be transported to the brain and could accountfor some of theactivity.

Substantial clearance of lysosomal storage was observed in the LGN and SC of all AAV $beta$ GEnh-treated mice that were examined.The visual cortex also showed some reduction in neuronal storageat the later survival times. This suggests that therapeutic enzymeactivity can be transported across synapses in the LGN, becausethere are no direct axonal connections from the retina to thevisual cortex. Interestingly, adjacent nonvisual regions of thethalamus and tectum also showed a marked decrease in lysosomalstorage. Furthermore, the hippocampus, which does not receivedirect visual input, showed consistent decreases in lysosomalstorage in the CA3-CA4 regions, which are in dorsal proximityto the LGN. The CA1-CA2 regions (which are farther from the visualpathway) also showed decreases in lysosomal storage in the mousethat received bilateral gene therapy. Taken together, these findingssuggest that GUSB enzyme activity spreads within the brain byboth neuronal transport anddiffusion.

Although lysosomal storage was reduced in MPS VII mouse brains after intravitreal injection of an AAV vector, the reductionwas limited to specific regions. This may be somewhat surprising,because previous reports have shown that a single intracranialinjection of vector will reduce storage throughout most of thetreated hemisphere and partially correct the contralateral hemisphere(Ghodsi et al., 1998; Skorupa et al., 1999; Bosch et al., 2000;Sferra et al., 2000). This difference may be attributable to thefact that higher levels of enzyme activity are delivered to thebrain by direct intracranial injection compared with transportfrom the eye. It is possible that the mechanism responsible fortransport from the retina has a limited capacity, resulting ina lower steady-state level of enzyme activity in the brain. Anotherfactor that may contribute to the difference could be that themyelin sheaths surrounding the ganglion cell axons may limit thediffusion of GUSB, thereby limiting the area ofcorrection.

It has previously been shown that lysosomal storage reduction correlates both with the prevention of cognitive deficits afterneonatal gene therapy and with the reversal of established CNSdeficits after gene therapy in adult animals. The Morris watermaze was used to correlate the reduction of lysosomal distensionin the CNS with improved cognitive function in MPS VII mice treatedat birth with intracranial gene therapy (Frisella et al., 2001).In addition, Brooks et al. (2002) have used a repeated acquisitionperformance chamber to demonstrate that after lentiviral-mediatedgene therapy into the CNS of adult MPS VII mice, the reductionof lysosomal storage in the brain leads to improvements in cognitivefunction. Although in the current study lysosomal storage wasreduced in several areas of the brain including the hippocampus,it was unclear whether cognitive functions were improved. Theprogression of systemic disease in the MPS VII mice at the endpointof this study precluded behavioral testing. However, it will becritical to determine the extent of cognitive recovery after intravitrealgenedelivery.

Therapies directed to the CNS are usually delivered by direct injection. Intracranial injections of adenoviral (Ghodsi etal., 1998; Stein et al., 1999), AAV (Skorupa et al., 1999; Sferraet al., 2000; Frisella et al., 2001; Fu et al., 2002), and lentiviral(Bosch et al., 2000; Brooks et al., 2002) vectors have been usedfor treating CNS lysosomal storage disease. Two recent studieshave addressed transport of gene products within the CNS afterAAV-mediated gene transfer to specific brain nuclei. Chamberlinet al. (1998) found robust anterograde labeling of transducedneurons, but essentially no retrograde transport after injectingan AAV construct encoding GFP into the parabrachial nucleus inthe brainstem. Passini et al. (2002) injected AAV encoding GUSBinto the hippocampus or the striatum of MPS VII brains and reportedenzyme transport throughout the septohippocampal and nigrostriatalsystems with concomitant reversal of lysosomal storage. Here weshow that intravitreal injection also results in targeting oftherapeutic gene product to specific subregions of the brain.Axonal transport of the GUSB gene product is likely involved atleast in the correction of the visual cortex, because no ASBIreactivity, indicating transduced cells producing high levelsof enzyme, were ever seen in this area in any of the brainsexamined.

Successful axonal transport of therapeutic gene products from a remote administration site into the CNS requires that thegene product be recognized as suitable cargo, released from thetransporting cell at axon terminals, and taken up and used correctlyby adjacent, affected cells. Soluble lysosomal enzymes are ideallysuited for this approach because all cells possess mechanismsfor exchanging these enzymes in a receptor-dependent manner througha process referred to as "cross-correction" (Neufeld and Fratantoni,1970; Kornfeld, 1992). Other gene products that might be appropriatefor this delivery system include secreted growth factors and othercytokines.

The findings presented here show that axonal transport from the retina can be used to deliver therapeutic agents into thebrain. If these findings hold true in larger animals, this routeof entry into the CNS may provide a less invasive delivery methodfor certain therapeutic gene products. Such a treatment strategymight be particularly attractive for lysosomal storage diseases,during which both visual and cognitive deficits occur, and mayreduce the number of intracranial injections required for widespreadCNStherapy.

  FOOTNOTES

Received Sept. 9, 2002; revised Jan. 17, 2003; accepted Jan. 24, 2003.

This work was funded by National Institutes of Health Grants 1RO3 DC04946-01 (A.K.H.), DC 04665 (J.M.O.), EY 12260 (S.B.),DK 57586, and NS 044520 (M.S.S.) and by the National MPS Society(A.K.H.), the Foundation Fighting Blindness (J.M.O.), and GenzymeCorporation (M.S.S.).

Correspondence should be addressed to Dr. Mark S. Sands, Departments of Internal Medicine and Genetics, Washington UniversitySchool of Medicine, Box 8007, 660 South Euclid Avenue, St. Louis,MO 63110. E-mail: msands{at}imgate.wustl.edu.

  References

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ABSTRACT
Introduction
Materials and Methods
Results
Discussion
REFERENCES

Birkenmeier EH, Davisson MT, Beamer WG, Ganschow RE, Vogler CA, Gwynn B, Lyford KA, Maltais LM, Wawrzyniak CJ (1989) Murine mucopolysaccharidosis type VII: characterization of a mouse with $beta$ -glucuronidase deficiency. J Clin Invest 83:1258-1266.
Bosch A, Ferret E, Desmaris N, Trono D, Heard JM (2000) Reversal of pathology in the entire brain of mucopolysaccharidosis type VII mice after lentivirus-mediated gene transfer. Hum Gene Ther 11:1139-1150[Web of Science][Medline].
Brooks AI, Stein CS, Hughes SM, Heth J, McCray Jr PM, Sauter SL, Johnston JC, Cory-Slechta DA, Federoff HJ, Davidson BL (2002) Functional correction of established central nervous system deficits in an animal model of lysosomal storage disease with feline immunodeficiency virus-based vectors. Proc Natl Acad Sci USA 99:6216-6221[Abstract/Free Full Text].
Chamberlin NL, Du B, de Lacalle S, Saper CB (1998) Recombinant adeno-associated virus vector: use for transgene expression and anterograde tract tracing in the CNS. Brain Res 793:169-175[Web of Science][Medline].
Daly T, Okuyama T, Vogler C, Haskins M, Muzyczka N, Sands MS (1999a) Neonatal intramuscular injection with recombinant adeno-associated virus results in prolonged $beta$ -glucuronidase expression in situ and correction of liver pathology in mucopolysaccharidosis type VII mice. Hum Gene Ther 10:85-94[Web of Science][Medline].
Daly TM, Vogler C, Levy B, Haskins ME, Sands MS (1999b) Neonatal gene transfer leads to widespread correction of pathology in a murine model of lysosomal storage disease. Proc Natl Acad Sci USA 96:2296-2300[Abstract/Free Full Text].
Daly TM, Ohlemiller KK, Roberts MS, Vogler CA, Sands MS (2001) Prevention of systemic clinical disease in MPS VII mice following AAV-mediated neonatal gene transfer. Gene Ther 8:1291-1298[Web of Science][Medline].
Drager UC (1985) Birth dates of retinal ganglion cells giving rise to the crossed and uncrossed optic projections in the mouse. Proc R Soc Lond B Biol Sci 224:57-77[Medline].
Dudus L, Anand V, Acland GM, Chen S-J, Wilson JM, Fisher KJ, Maguire AM, Bennett J (1999) Persistent transgene product in retina, optic nerve and brain after intraocular injection of rAAV. Vision Res 39:2545-2553[Web of Science][Medline].
Frisella WA, O'Connor LH, Vogler CA, Roberts M, Walkley S, Levy B, Daly TM, Sands MS (2001) Intracranial injection of recombinant adeno-associated virus improves cognitive function in a murine model of mucopolysaccharidosis Type VII. Mol Ther 3:351-358[Web of Science][Medline].
Fu H, Samulski RJ, McCown TJ, Picornell YJ, Fletcher D, Muenzer J (2002) Neurological correction of lysosomal storage in a mucopolysaccharidosis IIIB mouse model by adeno-associated virus-mediated gene delivery. Mol Ther 5:42-49[Web of Science][Medline].
Ghodsi A, Stein C, Derksen T, Yang G, Anderson RD, Davidson BL (1998) Extensive $beta$ -glucuronidase activity in murine central nervous system after adenovirus-mediated gene transfer to the brain. Hum Gene Ther 9:2331-2340[Web of Science][Medline].
Grafstein B, Forman DS (1980) Intracellular transport in neurons. Physiol Rev 60:1167-1283[Free Full Text].
Kornfeld S (1992) Structure and function of the mannose 6-phosphate/insulin-like growth factor II receptors. Annu Rev Biochem 61:307-330[Web of Science][Medline].
Levy B, Galvin N, Vogler C, Birkenmeier EH, Sly WS (1996) Neuropathology of murine mucopolysaccharidosis type VII. Acta Neuropathol 92:562-568[Medline].
Neufeld E, Fratantoni J (1970) Inborn errors of mucopolysaccharide metabolism. Science 169:141-146[Free Full Text].
O'Connor LH, Erway LC, Vogler CA, Sly WS, Nicholes A, Grubb J, Holmberg SW, Levy B, Sands MS (1998) Enzyme replacement therapy for murine mucopolysaccharidosis type VII leads to improvements in behavior and auditory function. J Clin Invest 101:1394-1400[Web of Science][Medline].
Ohlemiller KK, Vogler CA, Roberts M, Galvin N, Sands MS (2000) Retinal function is improved in a murine model of a lysosomal storage disease following bone marrow transplantation. Exp Eye Res 71:469-481[Web of Science][Medline].
Passini MA, Lee EB, Heuer GG, Wolfe JH (2002) Distribution of a lysosomal enzyme in the adult brain by axonal transport and by cells of the rostral migratory stream. J Neurosci 22:6437-6446[Abstract/Free Full Text].
Sands MS, Birkenmeier EH (1993) A single-base-pair deletion in the $beta$ -glucuronidase gene accounts for the phenotype of murine mucopolysaccharidosis type VII. Proc Natl Acad Sci USA 90:6567-6571[Abstract/Free Full Text].
Sands MS, Barker J, Vogler C, Levy B, Gwynn B, Galvin N, Birkenmeier EH (1993) Treatment of murine mucopolysaccharidosis type VII by syngeneic bone marrow transplantation in neonates. Lab Invest 68:676-686[Web of Science][Medline].
Sferra TJ, Qu G, McNeely D, Rennard R, Clark KR, Lo WD, Johnson PR (2000) Recombinant adeno-associated virus-mediated correction of lysosomal storage within the central nervous system of the adult mucopolysaccharidosis type VII mouse. Hum Gene Ther 11:507-519[Web of Science][Medline].
Skorupa AF, Fisher KJ, Wilson JM, Parente MK, Wolfe JH (1999) Sustained production of $beta$ -glucuronidase from localized sites after AAV vector gene transfer results in widespread distribution of enzyme and reversal of lysosomal storage lesions in a large volume of brain in mucopolysaccharidosis VII mice. Exp Neurol 160:17-27[Web of Science][Medline].
Stein CS, Ghodsi A, Derksen T, Davidson BL (1999) Systemic and central nervous system correction of lysosomal storage in mucopolysaccharidosis type VII mice. J Virol 73:3423-3429.
Vogler C, Birkenmeier EH, Sly WS, Levy B, Pegors C, Kyle JW, Beamer WG (1990) A murine model of mucopolysaccharidosis VII: gross and microscopic findings in beta-glucuronidase-deficient mice. Am J Pathol 136:207-217[Abstract].
Vogler C, Sands MS, Galvin N, Levy B, Thorpe C, Barker J, Sly WS (1998) Murine mucopolysaccharidosis type VII: the impact of therapies on the clinical course and pathology in a murine model of lysosomal storage disease. J Inher Metab Dis 21:575-586[Medline].
Walkley SU (1998) Cellular pathology of lysosomal storage disorders. Brain Pathol 8:175-193[Web of Science][Medline].
Wolfe JH, Sands MS (1996) Murine mucopolysaccharidosis type VII: a model system for somatic gene therapy of the central nervous system. In: Gene transfer into neurones: towards gene therapy of neurological disorders (Lowenstein P, Enquist L, eds), pp 263-274. Essex, UK: Wiley.
Zolotukhin S, Byrne BJ, Mason E, Zolotukhin I, Potter M, Chesnut K, Summerford C, Samulski RJ, Muzyczka N (1999) Recombinant adeno-associated virus purification using novel methods improves infectious titer and yield. Gene Ther 6:973-985[Web of Science][Medline].

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