Perinuclear biogenesis of mutant torsin-A inclusions in cultured cells infected with tetracycline-regulated herpes simplex virus type 1 amplicon vectors.

TorsinA is a novel protein identified in the search for mutations underlying the human neurologic movement disorder, early onset torsion dystonia. Relatively little is understood about the normal function of torsinA or the physiological effects of the codon deletion associated with most cases of disease. Overexpression of wild-type torsinA in cultured cells by DNA transfection results in a reticular distribution of immunoreactive protein that co-localizes with endoplasmic reticulum resident chaperones, while the dystonia-related mutant form accumulates within concentric membrane whorls and nuclear-associated membrane stacks. In this study we examined the biogenesis of mutant torsinA-positive membrane inclusions using tetracycline-regulated herpes simplex virus amplicon vectors. At low expression levels, mutant torsinA was localized predominantly around the nucleus, while at high levels it was also concentrated within cytosolic spheroid inclusions. In contrast, the distribution of wild-type torsinA did not vary, appearing diffuse and reticular at all expression levels. These observations are consistent with descriptions of inducible membrane synthesis in other systems in which cytosolic membrane whorls are derived from multilayered membrane stacks that first form around the nuclear envelope. These results also suggest that formation of mutant torsinA-positive inclusions occurs at high expression levels in culture, whereas the perinuclear accumulation of the mutant protein is present even at low expression levels that are more likely to resemble those of the endogenous protein. These nuclear-associated membrane structures enriched in mutant torsinA may therefore be of greater relevance to understanding how the dystonia-related mutation compromises cellular physiology.

HSV-1 Vectors for Gene Therapy of Experimental CNS Tumors.

Gliomas account for about 60% of all primary CNS tumors; two-thirds of all gliomas comprise the most malignant form, glioblastoma multiforme, or glioma grade IV. Although much progress has been achieved in the treatment of other solid tumors over the last few decades, the median survival of patients with glioblastoma remains at around 12 mo after standard treatment, which includes bulk resection and irradiation, as well as chemotherapy in some cases (1). Essentially, no patient can expect to survive 5 yr. New treatment modalities like immunotherapy have been applied so far with only limited success (2). With the improvement of methods for in vivo and ex vivo gene delivery, gene therapy became a new, promising approach to glioma therapy. Gliomas appear to be a particularly good target for a gene therapy approach using locally applied vectors, as the growth of gliomas is restricted to the brain. Clinical trials are under way using retrovirus and adenovirus vectors which carry the herpes simplex virus type-1 (HSV-1) thymidine kinase gene (HSV-tk). This gene encodes a prodrug-activating enzyme, which in infected cells converts the nontoxic prodrug, ganciclovir (GCV), to its cytotoxic phosphorylated form (3-5). There is an ever-increasing list of other prodrug-activation systems that showed efficacy in culture and in preclinical studies using rodent glioma models. These include, for example, cytosine deaminase converting 5-fluorocytosine to 5-fluoro-uracil (6), cytochrome P450-2B1 converting cyclophosphamide to phosphoramide mustard (7), deoxycytidine kinase phosphorylating cytosine arabinoside (8), and the Escherichia coli guanine phosphoribosyl transferase (gpt) metabolizing 6-thioxanthine and 6-thioguanine to toxic nucleoside analogs (9). Moreover, gene therapy approaches to brain tumors include the viral transfer of immune-enhancing cytokines, particularly granulocyte/macrophage colony-stimulating factor (10), or antisense to TGF-ß to glioma cells (11) used for vaccination purposes. Other approaches use the transfer of genes that modulate angiogenesis (12,13) or are involved in apoptosis like p53 (14). All aforementioned gene-transfer methods use nonreplicative viral vectors.

Selective delivery of herpes virus vectors to experimental brain tumors using RMP-7.

RMP-7, a bradykinin analog, has been shown to selectively open the blood-tumor barrier for the delivery of chemotherapeutic drugs to brain tumors. In contrast to bradykinin, RMP-7 has no hypotensive effects and has been approved for human use. This study was initiated to determine whether RMP-7 would open the blood-tumor barrier to virus vectors encoding tumor-killing genes in an experimental model. The herpes virus vector used, hrR3, which encodes virus thymidine kinase gene and the lacZ reporter gene, is defective in a gene encoding ribonucleotide reductase, replicates selectively in dividing tumor cells and not in postmitotic neural cells. It was determined that an optimum dose of RMP-7 (1.5-3.0 microg/kg over 10-15 minutes) enhanced viral delivery to brain tumors in rats bearing intracranial 9 L gliosarcomas when infused through the carotid artery immediately prior to virus vector application. Maximum expression of the lacZ reporter gene occurred at 3 days after intracarotid infusion. By 8 days, transgene expression was largely confined to tumor foci away from the main tumor mass. Viral delivery was essentially specific to tumor cells, with little transgene expression elsewhere in the brain. Minimal uptake and pathology was noted in the kidney, spleen, and liver. These findings indicate that intracarotid delivery of RMP-7 can augment the selective delivery of virus vectors to brain tumors in an experimental rat model, with the potential for application to human brain tumors.

Screen for MAOA mutations in target human groups.

Brunner et al. [1993: Am J Hum Genet 52: 1032-1039; 1993: Science 262:578-580] described males with an MAO-A deficiency state resulting from a premature stop codon in the coding region of the MAOA gene. This deficiency state was associated with abnormal levels of amines and amine metabolites in urine and plasma of affected males, as well as low normal intelligence and apparent difficulty in impulse control, including inappropriate sexual behavior. In the present study, disruption of the MAOA gene was evaluated in males with mental retardation with and without a history of sexually deviant behavior, as well as normal controls, healthy males, and patients with other diseases (Parkinson disease, Lesch-Nyhan syndrome). When available, plasma samples were evaluated first for levels of 3-methoxy, 4-hydroxyphenolglycol (MHPG), a metabolite of norepinephrine which serves as the most sensitive index of MAO-A activity in humans. Blood DNA from individuals with abnormally low MHPG, and from other individuals for whom metabolite levels were not available, were screened for nucleotide variations in the coding region of the MAOA gene by single-strand conformational polymorphism (SSCP) analysis across all 15 exons and splice junctions, and by sequencing, when indicated by either altered metabolites or SSCP shifts. No evidence for mutations disrupting the MAOA gene was found in 398 samples from the target populations, including institutionalized mentally retarded males (N = 352) and males participating in a sexual disorders clinic (N = 46), as well as control groups (N = 75). These studies indicate that MAOA deficiency states are not common in humans.

Mutational analysis of the human MAOA gene.

The monoamine oxidases (MAO-A and MAO-B) are the enzymes primarily responsible for the degradation of amine neurotransmitters, such as dopamine, norepinephrine, and serotonin. Wide variations in activity of these isozymes have been reported in control humans. The MAOA and MAOB genes are located next to each other in the p11.3-11.4 region of the human X chromosome. Our recent documentation of an MAO-A-deficiency state, apparently associated with impulsive aggressive behavior in males, has focused attention of genetic variations in the MAOA gene. In the present study variations in the coding sequence of the MAOA gene were evaluated by RT-PCR, SSCP, and sequencing a mRNA or genomic DNA in 40 control males with > 100-fold variations of MAO-A activity, as measured in cultured skin fibroblasts. Remarkable conservation of the coding sequence was found with only 5 polymorphisms observed. All but one of these were in the third codon position and thus did not alter the deduced amino acid sequence. The one amino acid alteration observed, lys --> arg, was neutral and should not affect the structure of the protein. This study demonstrates high conservation of coding sequence in the human MAOA gene in control males, and provides primer sets which can be used to search genomic DNA for mutations in this gene in males with neuropsychiatric conditions.

Gene therapy for brain tumors.

Gene therapy has opened new doors for treatment of neoplastic diseases. This new approach seems very attractive, especially for glioblastomas, since treatment of these brain tumors has failed using conventional therapy regimens. Many different modes of gene therapy for brain tumors have been tested in culture and in vivo. Many of these approaches are based on previously established anti-neoplastic principles, like prodrug activating enzymes, inhibition of tumor neovascularization, and enhancement of the normally weak anti-tumor immune response. Delivery of genes to tumor cells has been mediated by a number of viral and synthetic vectors. The most widely used paradigm is based on the activation of ganciclovir to a cytotoxic compound by a viral enzyme, thymidine kinase, which is expressed by tumor cells, after the gene has been introduced by a retroviral vector. This paradigm has proven to be a potent therapy with minimal side effects in several rodent brain tumor models, and has proceeded to phase 1 clinical trials. In this review, current gene therapy strategies and vector systems for treatment of brain tumors will be described and discussed in light of further developments needed to make this new treatment modality clinically efficacious.

Mutations in the Norrie disease gene.

We report our experience to date in mutation identification in the Norrie disease (ND) gene. We carried out mutational analysis in 26 kindreds in an attempt to identify regions presumed critical to protein function and potentially correlated with generation of the disease phenotype. All coding exons, as well as noncoding regions of exons 1 and 2, 636 nucleotides in the noncoding region of exon 3, and 197 nucleotides of 5' flanking sequence, were analyzed for single-strand conformation polymorphisms (SSCP) by polymerase chain reaction (PCR) amplification of genomic DNA. DNA fragments that showed altered SSCP band mobilities were sequenced to locate the specific mutations. In addition to three previously described submicroscopic deletions encompassing the entire ND gene, we have now identified 6 intragenic deletions, 8 missense (seven point mutations, one 9-bp deletion), 6 nonsense (three point mutations, three single bp deletions/frameshift) and one 10-bp insertion, creating an expanded repeat in the 5' noncoding region of exon 1. Thus, mutations have been identified in a total of 24 of 26 (92%) of the kindreds we have studied to date. With the exception of two different mutations, each found in two apparently unrelated kindreds, these mutations are unique and expand the genotype database. Localization of the majority of point mutations at or near cysteine residues, potentially critical in protein tertiary structure, supports a previous protein model for norrin as member of a cystine knot growth factor family (Meitinger et al., 1993). Genotype-phenotype correlations were not evident with the limited clinical data available, except in the cases of larger submicroscopic deletions associated with a more severe neurologic syndrome.(ABSTRACT TRUNCATED AT 250 WORDS)

A genetic linkage map of human chromosome 9q.

A genetic linkage map of human chromosome 9q, spanning a sex-equal distance of 125 cM, has been developed by genotyping 26 loci in the Venezuelan Reference Pedigree. The loci include 12 anonymous microsatellite markers reported by Kwiatkowski et al. (1992), several classical systems previously assigned to chromosome 9q, and polymorphisms for the genes tenacin (HXB), gelsolin (GSN), adenylate kinase 1 (AK1), arginosuccinate synthetase (ASS), ABL oncogene (ABL1), ABO blood group (ABO), and dopamine beta-hydroxylase (DBH). Only a marginally significant sex difference is found along the entire length of the map and results from one interval, between D9S58 and D9S59, that displays an excess of female recombination. A comparison of the genetic map to the existing physical data suggests that there is increased recombination in the 9q34 region with a recombination event occurring every 125-400 kb. This map should be useful in further characterizing the relationship between physical distance and genetic distance, as well as for genetic linkage studies of diseases that map to chromosome 9q, including multiple self-healing squamous epithelioma (MSSE), Gorlin syndrome (NBCCS), xeroderma pigmentosum (XPA), nail-patella syndrome (NPS1), torsion dystonia (DYT1), and tuberous sclerosis (TSC1).

Strong allelic association between the torsion dystonia gene (DYT1) andloci on chromosome 9q34 in Ashkenazi Jews.

The DYT1 gene responsible for early-onset, idiopathic torsion dystonia (ITD) in the Ashkenazi Jewish population, as well as in one large non-Jewish family, has been mapped to chromosome 9q32-34. Using (GT)n and RFLP markers in this region, we have identified obligate recombination events in some of these Jewish families, which further delineate the area containing the DYT1 gene to a 6-cM region bounded by loci AK1 and ASS. In 52 unrelated, affected Ashkenazi Jewish individuals, we have found highly significant linkage disequilibrium between a particular extended haplotype at the ABL-ASS loci and the DYT1 gene. The 4/A12 haplotype for ABL-ASS is present on 69% of the disease-bearing chromosomes among affected Jewish individuals and on only 1% of control Jewish chromosomes (chi 2 = 91.07, P much less than .001). The allelic association between this extended haplotype and DYT1 predicts that these three genes lie within 1-2 cM of each other; on the basis of obligate recombination events, the DYT1 gene is centromeric to ASS. Furthermore, this allelic association supports the idea that a single mutation event is responsible for most hereditary cases of dystonia in the Jewish population. Of the 53 definitely affected typed, 13 appear to be sporadic, with no family history of dystonia. However, the proportion of sporadic cases which potentially carry the A12 haplotype at ASS (8/13 [62%]) is similar to the proportion of familial cases with A12 (28/40 [70%]). This suggests that many sporadic cases are hereditary, that the disease gene frequency is greater than 1/15,000, and that the penetrance is lower than 30%, as previously estimated in this population. Most affected individuals were heterozygous for the ABL-ASS haplotype, a finding supporting autosomal dominant inheritance of the DYT1 gene. The ABL-ASS extended-haplotype status will provide predictive value for carrier status in Jewish individuals. This information can be used for molecular diagnosis, evaluation of subclinical expression of the disease, and elucidation of environmental factors which may modify clinical symptoms.

Torsion dystonia genes in two populations confined to a small region on chromosome 9q32-34.

Idiopathic torsion dystonia (ITD) is characterized by sustained, involuntary muscle contractions, frequently causing twisting and repetitive movements or abnormal postures. Most familial forms of ITD display autosomal dominant inheritance with reduced penetrance. Linkage analysis has been previously used to localize a dystonia gene to the 9q32-34 region in a large non-Jewish family and in a group of Ashkenazi Jewish families. Utilizing GT repeat polymorphisms from this region, here we demonstrate that the gene causing dystonia in Ashkenazi Jews can be localized to the 11-cM interval between AK1 and D9S10. Linkage analysis in the non-Jewish family is also consistent with occurrence of the gene in this region, although positive lod scores extend over a greater than 20-cM interval in that family. These results set the stage for positional cloning of the dystonia gene. Currently there are no known candidate genes in this region.

Identification of a highly polymorphic microsatellite VNTR within the argininosuccinate synthetase locus: exclusion of the dystonia gene on 9q32-34 as the cause of dopa-responsive dystonia in a large kindred.

Dopa-responsive dystonia is a clinical variant of idiopathic torsion dystonia that is distinguished from other forms of dystonia by the frequent occurrence of parkinsonism, diurnal fluctuation of symptoms, and its dramatic therapeutic response to L-dopa. Linkage of a gene causing classic dystonia in a large non-Jewish kindred (DYT1) and in a group of Ashkenazi Jewish families, to the gelsolin (GSN) and arginino-succinate synthetase (ASS) loci on chromosome 9q32-34, respectively, was recently determined. Here we report the discovery of a highly informative (GT)n repeat VNTR polymorphism within the ASS locus. Analysis of a large kindred with dopa-responsive dystonia, using this new polymorphism and conventional RFLPs for the 9q32-34 region, excludes loci in this region as a cause of this form of dystonia. This provides proof of genetic heterogeneity between classic idiopathic torsion dystonia and dopa-responsive dystonia.

Dystonia gene in Ashkenazi Jewish population is located on chromosome 9q32-34.

Idiopathic torsion dystonia (ITD) is a neurological disorder characterized by sustained muscle contractions that appear as twisting movements of the limbs, trunk, and/or neck, which can progress to abnormal postures. Most familial forms of ITD follow autosomal dominant transmission with reduced penetrance. The frequency of ITD in the Ashkenazi Jewish population is five to ten times greater than that in other groups. Recently, a gene for ITD (DYT1) in a non-Jewish kindred was located on chromosome 9q32-34, with tight linkage to the gene encoding gelsolin (GSN). In the present study linkage analysis using DNA polymorphisms is used to locate a gene responsible for susceptibility to ITD in 12 Ashkenazi Jewish families. This dystonia gene exhibits close linkage with the gene encoding argininosuccinate synthetase (ASS), and appears by multipoint analysis to lie in the q32-34 region of chromosome 9, a region that also contains the loci for gelsolin and dopamine-beta-hydroxylase. The same gene may be responsible for ITD both in the non-Jewish kindred mentioned above and in the Ashkenazi Jewish families presented here. However, because there is substantial difference between the penetrance of the dominant allele in these two groups, two different mutations may be operating to produce susceptibility to this disease in the two groups.

Human gene for torsion dystonia located on chromosome 9q32-q34.

Torsion dystonia is a movement disorder of unknown etiology characterized by loss of control of voluntary movements appearing as sustained muscle contractions and/or abnormal postures. Dystonic movements can be caused by lesions in the basal ganglia, drugs, or gene defects. Several hereditary forms have been described, most of which have autosomal dominant transmission with variable expressivity. In the Ashkenazi Jewish population the defective gene frequency is about 1/10,000. Here, linkage analysis using polymorphic DNA and protein markers has been used to locate a gene responsible for susceptibility to dystonia in a large, non-Jewish kinship. Affected members of this family have a clinical syndrome similar to that found in the Jewish population. This dystonia gene (ITD1) shows tight linkage with the gene encoding gelsolin, an actin binding protein, and appears by multipoint linkage analysis to lie in the q32-q34 region of chromosome 9 between ABO and D9S26, a region that also contains the locus for dopamine-beta-hydroxylase.