Adeno-associated virus vector gene transfer and sarcolemmal expression of a 144 kDa micro-dystrophin effectively restores the dystrophin-associated protein complex and inhibits myofibre degeneration in nude/mdx mice

Duchenne muscular dystrophy is a severe life-threatening X-linked recessive disorder, caused by mutations in the dystrophin gene, for which currently there is no effective treatment. Because of the large size of the dystrophin cDNA (14 kb) this precluded it from being used in early adenovirus- or retrovirus-based gene therapy vectors. However, some therapeutic success has been achieved in mdx mice using adenovirus- and retrovirus-mediated transfer of a 6.3 kb recombinant mini-dystrophin cDNA. Despite this, problems with immunogenicity and inefficient transduction of mature myofibres make these vectors less than ideal for gene transfer to skeletal muscle. Adeno-associated viral (AAV) vectors overcome many of the problems associated with other vector systems. However, AAV vectors can only accommodate <5 kb of foreign DNA. For this reason we have produced a micro-dystrophin cDNA gene construct that is <3.8 kb. This construct, driven by a CMV promoter, was introduced into the skeletal muscle of 12-day-old nude/mdx mice using an AAV vector, resulting in specific sarcolemmal expression of micro-dystrophin in >50% of myofibres up to 20 weeks of age, and effective restoration of the dystrophin-associated protein (DAP) complex components. Additionally, evaluation of central nucleation indicated a significant inhibition of degenerative dystrophic muscle pathology. We have therefore shown that the current micro-dystrophin gene delivered in vivo using an AAV vector is not only capable of restoring sarcolemmal DAP complexes, but can also ameliorate dystrophic pathology at the cellular level.     

Rapid neurofibrillary tangle formation after localized gene transfer of mutated tau

Neurofibrillary pathology was produced in the brains of adult rats after localized gene transfer of human tau carrying the P301L mutation, which is associated with frontotemporal dementia with parkinsonism. Within 1 month of in situ transfection of the basal forebrain region of normal rats, tau-immunoreactive and argyrophilic neuronal lesions formed. The fibrillar lesions had features of neurofibrillary tangles and tau immunoreactivity at light and electron microscopic levels. In addition to neurofibrillary tangles, other tau pathology, including pretangles and neuropil threads, was abundant and widespread. Tau gene transfer to the hippocampal region of amyloid-depositing transgenic mice produced pretangles and threads, as well as intensely tau-immunoreactive neurites in amyloid plaques. The ability to produce neurofibrillary pathology in adult rodents makes this a useful method to study tau-related neurodegeneration.     

Filamentous tau in oligodendrocytes and astrocytes of transgenic mice expressing the human tau isoform with the P301L mutation

We recently reported a transgenic mouse line (JNPL3) that expresses mutant (P301L) tau and develops neurofibrillary tangles composed of filamentous tau aggregates. Here we show that these mice have abnormal tau filaments not only in neurons, but also in oligodendrocytes and astrocytes. Similar results were detected in another transgenic line (JNPL2+3+) that expresses the longest human tau isoform with the P301L mutation. The ultrastructure of the tau filaments and immunoreactivity with tau and ubiquitin antibodies were similar in glia and neurons. Given similarities of the lesions in the mice to human neuronal and glial inclusions, these transgenic mice appear to be a valuable model to study pathogenesis of the neurodegenerative tauopathies.     

Amplified region of chromosome band 11q13 in breast and squamous cell carcinomas encompasses three CpG islands telomeric of FGF3, including the expressed gene EMS1

DNA markers that map within the karyotypically defined band q13 on human chromosome 11 are amplified in a subset of mammary and squamous cell carcinomas. It is assumed that the amplified DNA includes a critical gene (or genes) whose overexpression provides a selective force in the development of the tumor. To help identify such genes, we have begun to construct a physical map of CpG islands in the region, making use of a squamous cell carcinoma cell line (UMSCC2) in which the 11q13 region is amplified 11-fold. We previously described the proximal end of this amplicon and the order of markers extending ～800 kb centromeric of the FGF3 locus (formerly INT2). We now report the use of chromosome jumping techniques to define additional CpG islands that lie distal to FGF3. These map within the amplified region in UMSCC2 cells and the most telomeric corresponds to the EMS1 gene. The data imply that the amplified DNA in UMSCC2 cells extends for over 1,500 kb and includes at least 7 potential genes. EMS1 and CCND1 (formerly PRAD1), the best candidates for the key gene on the 11q13 amplicon, are ≥800 kb apart. © 1993 Wiley-Liss, Inc.     

Vilse, a conserved Rac/Cdc42 GAP mediating Robo repulsion in tracheal cells and axons

Slit proteins steer the migration of many cell types through their binding to Robo receptors, but how Robo controls cell motility is not clear. We describe the functional analysis of vilse, a Drosophila gene required for Robo repulsion in epithelial cells and axons. Vilse defines a conserved family of RhoGAPs (Rho GTPase-activating proteins), with representatives in flies and vertebrates. The phenotypes of vilse mutants resemble the tracheal and axonal phenotypes of Slit and Robo mutants at the CNS midline. Dosage-sensitive genetic interactions between vilse, slit, and robo mutants suggest that vilse is a component of robo signaling. Moreover, overexpression of Vilse in the trachea of robo mutants ameliorates the phenotypes of robo, indicating that Vilse acts downstream of Robo to mediate midline repulsion. Vilse and its human homolog bind directly to the intracellular domains of the corresponding Robo receptors and promote the hydrolysis of RacGTP and, less efficiently, of Cdc42GTP. These results together with genetic interaction experiments with robo, vilse, and rac mutants suggest a mechanism whereby Robo repulsion is mediated by the localized inactivation of Rac through Vilse.     

Genetic linkage of the tricho-dento-osseous syndrome to chromosome 17q21

Tricho-dento-osseous syndrome (TDO), MIM# 190320, is transmitted as a highly penetrant autosomal dominant trait that is characterized by variable clinical expression. The principal clinical features include kinky/curly hair in infancy, enamel hypoplasia, taurodontism, as well as increased thickness and density of cranial bones. Possible genetic linkage has been reported for TDO with the ABO blood group locus, but the gene defect remains unknown. We have identified four multiplex families (n = 63, 39 affected, 24 unaffected) from North Carolina segregating TDO. We previously have excluded a major locus for TDO in the ABO region for these families. Utilizing a genome-wide search strategy, we obtained conclusive evidence for linkage of the TDO syndrome locus to markers on chromosome 17q21 (D17S791, Z max = 10.54, Theta = 0.00) with no indication of genetic heterogeneity. Multipoint analysis suggests the TDO locus is located in a 7 cM chromosomal segment flanked by D17S932 and D17S941. This finding represents the first step towards isolation and cloning of the TDO gene. Identification of this gene has important implications for understanding normal and abnormal craniofacial development of hair, teeth and bone.      

Pseudotypes of vesicular stomatitis virus with envelope antigens provided by murine mammary tumor virus.

Infection of two mouse mammary carcinoma cell lines with vesicular stomatitis virus (VSV) resulted in the formation of at least two types of particles containing the VSV genome but expressing different envelope characteristics (VSV pseudotypes). One of these VSV pseudotypes was infectious for a cell line derived from normal mouse mammary epithelial cells and mouse embryo cells but noninfectious for 3T3 cells, mink lung cells, and Vero cells. If mouse mammary tumor cells were treated with dexamethason some days prior to infection with VSV, the titer of this pseudotype was significantly increased. In contrast, the second pseudotype was infectious for mink cells, but not for the other cell lines tested, and the titer of this second pseudotype was unaffected by the presence of dexamethasone. The first pseudotype was found to be almost completely neutralized by anti-murine mammary tumor virus (MuMTV) serum whereas the second pseudotype was only partially neutralized at a higher antiserum concentration. Neither pseudotype showed the neutralization, host range, or interference properties of either ecotropic or xenotropic murine C-type viruses. These results suggest that the first pseudotype is VSV(MuMTV). The other pseudotype is less well defined but conceivably may represent a xenotropic MuMTV. In the course of these studies, a filterable agent was observed in GR mammary carcinoma cultures that reactivated the infectivity of VSV neutralized by antiserum. This agent was transmissible to mink cells.     

Penetration, diffusion, and uptake of recombinant human alpha-L-iduronidase after intraventricular injection into the rat brain

Central nervous system disease can have devastating consequences in the severe or Hurler form of mucopolysaccharisosis I (MPS I). Intravenously administered recombinant human alpha-L-iduronidase (rhIDU) is not expected to reach and treat the brain disease due to the blood-brain barrier. To determine whether administration of rhIDU into the cerebrospinal fluid could successfully treat the brain, we studied intraventricular administration of rhIDU in rats. RhIDU was stereotactically administered directly to the lateral ventricle of the intact rat brain and the brain tissues assessed by enzyme assays, immunofluorescence and confocal microscopy 30 min, 24 h, or 7 days later. Quantitation of activity revealed that rhIDU was widely distributed throughout the brain following injection into the lateral ventricle, with activities increased by a factor of 3.3 higher than control in most samples 30 min-24 h after injection and highest levels on the side of injection. The enzyme crossed the ependymal lining of the ventricle and entered neurons into lysosomal-like vesicles. The enzyme was able to diffuse through brain tissue as demonstrated by a decreasing signal gradient from 0.2 to 4.8 mm from the ventricle surface. The largest amount of rhIDU, as detected by immunostaining, was observed 24 h after injection and decreased approximately 50% during the first 7 days. Although the immunostaining decreased with time, specific vesicular staining was still detectable 28 days after injection. The data suggest that rhIDU given into the ventricle can diffuse, penetrate at least several millimeters of brain tissue and be taken up into neurons and glial cells.