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A bidirectional YAC walk from the Norrie disease (NDP) locus.
The region of Xp between DXS7 and the centromere contains the gene for Norrie disease in addition to the genes for several other ophthalmic disorders. A 650-kb YAC containing the loci MAOA, MAOB, and NDP has been used as the starting point for a bidirectional chromosomal walk. A contig of 16 YACs covering between 2 and 3 Mb has been developed in which the following markers/genes are located (in physical order): Xpter--DXS1201 (256ze5)--DXS6668--DXS228--DXS77--MAOA--++ +MAOB--FR12 (pseudogene)--NDP--DXS6670--RRM2P3--DXS6671--DXS742 --Xcen. Seven new STSs are described both for end clones and for internal Alu PCR products from the contig. The contig contains the breakpoint of the t75-2ma-1b (t75) translocation, close to the 5' end of the MAOB gene.
Trinucleotide repeat expansion in the FRAXE locus is not common among institutionalized individuals with non-specific developmental disabilities.
Expansion of a polymorphic GCC-repeat at the FRAXE locus has been associated with expression of chromosome fragility at this site and cognitive impairment in some individuals previously testing negative for CGG-repeat expansion in the fragile X mental retardation-1 (FMR1) gene. To determine the frequency of FRAXE triplet repeat expansion among persons with developmental disability, 396 individuals from two institutions were studied, all of whom were negative for FMR1 repeat expansion. Clinically, there was a wide range of mental impairment, with the majority (61.1%) being severely to profoundly affected. The distribution of FRAXE GCC-repeat numbers in the study population was 5-38: 28 (5.6%) with 10-14 repeats; 366 (73.8%) with 15-19 repeats; 74 (14.9%) with 20-24 repeats; 20 (4.0%) with 25-29 repeats; and 5 (1.0%) with 30-38 repeats, with no individuals demonstrating repeat expansion. One profoundly retarded male was found to have a deletion of about 40 bp. Southern blots of HindIII-digested DNAs from individuals with > or = 26 repeats all showed normal patterns. These results suggest that FRAXE GCC-repeat expansion is not a common cause of developmental disability in institutionalized persons with mild to profound mental retardation.
The mapping of a cDNA from the human X-linked Duchenne muscular dystrophy gene to the mouse X chromosome.
The recent discovery of sequences at the site of the Duchenne muscular dystrophy (DMD) gene in humans has opened up the possibility of a detailed molecular analysis of the genes in humans and in related mammalian species. Until relatively recently, there was no obvious mouse model of this genetic disease for the development of therapeutic strategies. The identification of a mouse X-linked mutant showing muscular dystrophy, mdx, has provided a candidate mouse genetic homologue to the DMD locus; the relatively mild pathological features of mdx suggest it may have more in common with mutations of the Becker muscular dystrophy type at the same human locus, however. But the close genetic linkage of mdx to G6PD and Hprt on the mouse X chromosome, coupled with its comparatively mild pathology, have suggested that the mdx mutation may instead correspond to Emery Dreifuss muscular dystrophy which itself is closely linked to DNA markers at Xq28-qter in the region of G6PD on the human X chromosome. Using an interspecific mouse domesticus/spretus cross, segregating for a variety of markers on the mouse X chromosome, we have positioned on the mouse X chromosome sequences homologous to a DMD cDNA clone. These sequences map provocatively close to the mdx mutation and unexpectedly distant from sparse fur, spf, the mouse homologue of OTC (ornithine transcarbamylase) which is closely linked to DMD on the human X chromosome.
A new DNA marker tightly linked to the fragile X locus (FRAXA).
The fragile X syndrome is the most common cause of familial mental retardation. Genetic counseling and gene isolation are hampered by a lack of DNA markers close to the disease locus. Two somatic cell hybrids that each contain a human X chromosome with a breakpoint close to the fragile X locus have been characterized. A new DNA marker (DXS296) lies between the chromosome breakpoints and is the closest marker to the fragile X locus yet reported. The Hunter syndrome gene, which causes iduronate sulfatase deficiency, is located at the X chromosome breakpoint that is distal to this new marker, thus localizing the Hunter gene distal to the fragile X locus.
Efficient utrophin expression following adenovirus gene transfer in dystrophic muscle.
Utrophin is a homologue of dystrophin, the protein whose absence is responsible for Duchenne muscular dystrophy (DMD). As a first step toward clarifying if adenovirus (AV)-mediated utrophin transfer is a possible option to treat DMD, we have constructed an AV expressing utrophin (AdCMV-Utr) and studied utrophin expression after intramuscular injection of mdx mice, the mouse DMD model. Overexpression of utrophin by AdCMV-Utr was marked and nontoxic. The recombinant utrophin was distributed homogeneously at the surface of the muscle fibers. Its expression was sufficient to restore the normal histochemical pattern of alpha-sarcoglycan and beta-dystroglycan at this site. These two proteins are members of the dystrophin associated protein complex whose distribution is greatly reduced at the surface of the DMD muscle. These data indicate that AV-mediated utrophin transfer is an efficient way of utrophin upregulation in muscle and has the potential of becoming a treatment for DMD.
Genomic organization and chromosomal localization of a member of the MAP kinase phosphatase gene family to human chromosome 11p15.5 and a pseudogene to 10q11.2.
Mitogen-activated protein kinase phosphatases (MKPs) play a central role in a variety of signaling pathways. We recently described a novel murine MKP, M3/6, which is uniquely specific for c-Jun N-terminal kinase/stress-activated protein kinase and p38 kinase. Here we report the localization of the human orthologue of this gene, HB5, to within 150 kb of H19 on human chromosome 11p15.5. The gene consists of six exons. Two of the introns in HB5 are not found in other genes of this family, suggesting an evolutionary split between MKPs displaying specificity toward different MAP kinases. An intronless pseudogene is present on chromosome 10q11.2. Although 11p15.5 is an imprinted region, HB5 is almost entirely unmethylated on both alleles in lymphocytes. Chromosome 11p15 has been implicated in the development of a number of tumor types, including lung, a tissue known to express this gene. Loss of heterozygosity was found in one of eight informative lung tumors studied.
A novel gene, DXS8237E, lies within 20 kb upstream of UBE1 in Xp11.23 and has a different X inactivation status.
A novel X-linked gene, DXS8237E, was isolated from human fetal brain cDNA, and its 3' end was mapped to within 20 kb upstream of UBE1 in Xp11.23. A 1.3-kb cDNA for DXS8237E detects homologous sequences in other mammals and a 3-kb mRNA that is widely expressed in human cell lines and mouse tissues. Sequence analysis indicated that the 1.3-kb cDNA contains the 3' end of the DXS8237E gene, but the sequence shows no significant homology to known genes. DXS8237E was shown to be subject to X inactivation in five somatic cell hybrids that contain an inactive human X chromosome but no active homologue. Since UBE1 escapes X inactivation, DXS8237E and UBE1 are the closest mapped genes with discordant X inactivation profiles. Sequences in the vicinity of these two genes may be important determinants of X inactivation status.
Rescue of a single yeast artificial chromosome from a cotransformation event utilizing segregation at meiosis
During the construction of yeast artificial chromosome (YAC) libraries to facilitate mapping of the human genome, two YACs may be cotransformed into the same yeast cell, making further analysis very difficult. We present a simple method to rescue the required YAC that utilizes the segregation of chromosomes at meiosis. In brief, we crossed the cotransformed yeast cell with a non-YAC-containing strain and induced the resulting diploid to sporulate and undergo meiosis. The new haploid generation included some yeast cells that contained only the desired YAC. These YACs were analyzed by conventional methods. To exclude the possibility that major rearrangement occurred during the procedure, we analyzed the YACs with restriction enzymes that cut only rarely. We conclude that this is a useful technique to rescue cotransformed YACs. © 1993.
Genetic and physical mapping around the properdin P gene
A CA repeat has been found on the human X chromosome within 16 kb of the gene encoding properdin P factor (PFC) and has been shown to be a highly informative marker. Two more polymorphic CA repeats were found in a cosmid containing DXS228. The CA repeats, and other markers from proximal Xp, were mapped genetically in CEPH families and the likely order of markers was established as Xpter-(DXS7, MAO-A, DXS228)-(PFC, DXS426)-(TIMP, OATL1)-DXS255-Xcen. This places PFC in the region Xp11.3-Xp11.23, thus refining previous in situ hybridization data. Two yeast artificial chromosomes (YACs) (440 and 390 kb) contain both PFC and DXS426, and one of them (440 kb) also contains TIMP. This confirms the genetic order TIMP-(PFC, DXS426). PFC and TIMP are located on the same 100-kb SalI PvuI fragment of the 440-kb YAC. Given the genetic orientation of TIMP and (PFC, DXS426), this YAC can now serve as a starting point for directional walking toward disease genes located in Xp11.3-Xp11.2 such as retinitis pigmentosa (RP2) and Wiskott-Aldrich syndrome. © 1991.
Neuronal over-expression of Oxr1 is protective against ALS-associated mutant TDP-43 mislocalisation in motor neurons and neuromuscular defects in vivo.
A common pathological hallmark of amyotrophic lateral sclerosis (ALS) and the related neurodegenerative disorder frontotemporal dementia, is the cellular mislocalization of transactive response DNA-binding protein 43 kDa (TDP-43). Additionally, multiple mutations in the TARDBP gene (encoding TDP-43) are associated with familial forms of ALS. While the exact role for TDP-43 in the onset and progression of ALS remains unclear, the identification of factors that can prevent aberrant TDP-43 localization and function could be clinically beneficial. Previously, we discovered that the oxidation resistance 1 (Oxr1) protein could alleviate cellular mislocalization phenotypes associated with TDP-43 mutations, and that over-expression of Oxr1 was able to delay neuromuscular abnormalities in the hSOD1G93A ALS mouse model. Here, to determine whether Oxr1 can protect against TDP-43-associated phenotypes in vitro and in vivo, we used the same genetic approach in a newly described transgenic mouse expressing the human TDP-43 locus harbouring an ALS disease mutation (TDP-43M337V). We show in primary motor neurons from TDP-43M337V mice that genetically-driven Oxr1 over-expression significantly alleviates cytoplasmic mislocalization of mutant TDP-43. We also further quantified newly-identified, late-onset neuromuscular phenotypes of this mutant line, and demonstrate that neuronal Oxr1 over-expression causes a significant reduction in muscle denervation and neuromuscular junction degeneration in homozygous mutants in parallel with improved motor function and a reduction in neuroinflammation. Together these data support the application of Oxr1 as a viable and safe modifier of TDP-43-associated ALS phenotypes.