X linked myotubular myopathy (MTM1) maps between DXS304 and DXS305, closely linked to the DXS455 VNTR and a new, highly informative microsatellite marker (DXS1684)

The locus for X linked recessive myotubular myopathy (MTM1) has previously been mapped to Xq28 by linkage analysis. We report two new families that show recombination between MTM1 and either DXS304 or DXS52. These families and a third previously described recombinant family were analysed with two highly polymorphic markers in the DXS304-DXS52 interval, the DXS455 VNTR and a newly characterised microsatellite, DXS1684 (82% heterozygosity). These markers did not recombine with MTM1 in the three families. Together with the recent mapping of an interstitial X chromosome deletion in a female patient with moderate signs of myotubular myopathy, our data suggest the following order of loci in Xq28: cen-DXS304-(DXS455, MTM1)-DXS1684-DXS305-DXS52-tel. This considerably refined localisation of the MTM1 locus should facilitate positional cloning of the gene. The availability of highly polymorphic and very closely linked markers will markedly improve carrier and prenatal diagnosis of MTM1.

Identification of mutations in the putative ATP-binding domain of the adrenoleukodystrophy gene

The recently identified adrenoleukodystrophy (ALD) gene is predicted to encode a peroxisomal protein of 745 amino acids that includes one domain for ATP-binding, termed nucleotide-binding fold (NBF). To determine whether mutations occur in the putative NBF of ALD protein, we analyzed by denaturing gradient gel electrophoresis (DGGE) exon 6 and 8 that encode most part of this domain in 50 ALD patients. Four amino acid substitutions, three frameshift mutations leading to premature termination signal, and a splicing mutation were identified. These amino acid substitutions occurred at residues highly conserved in other ATP-binding cassette (ABC) proteins. In addition, a nonsense mutation was detected in exon 4.

Identification of a two base pair deletion in five unrelated families with adrenoleukodystrophy: a possible hot spot for mutations

The gene for X-linked adrenoleukodystrophy (ALD) was recently identified. Intragenic deletions of several kilobases were found in about 7% of patients. Point mutations, expected to be very heterogeneous, were identified so far in only two patients. We report the identification of a two base pair deletion at position 1801-1802 of the ALD cDNA, located within the fifth exon of the ALD gene, which precedes the two consensus motives for ATP-binding. This microdeletion was found in five out of 40 unrelated ALD kindreds, indicating that this position is a hot spot for mutations. The mutation was observed both in patients with childhood cerebral ALD (CCALD) and in patients with adrenomyeloneuropathy (AMN).

Male with typical fragile X phenotype is deleted for part of the FMR1 gene and for about 100 kb of upstream region

We report on a patient with moderate mental retardation and a typical fragile X phenotype, with no family history and no fragile X site on cytogenetic analysis. The patient was found to have a deletion encompassing part of the FMR1 gene and a 70-100 kb region upstream of the FMR1 promotor region. This deletion is smaller than those previously reported and confirms that FMR1 is the major and probably the only gene implicated in the phenotype of the fragile X syndrome.

A new human gene (DXS1357E) with ubiquitous expression, located in Xq28 adjacent to the adrenoleukodystrophy gene

We have isolated a new human gene (DXS1357E; laboratory name: CDM) localized in Xq28. This gene is transcribed from the same CpG island as the adrenoleukodystrophy gene (ALD) and oriented in the opposite direction. It encodes a 1.5-kb transcript that exhibits ubiquitous expression and contains a single open reading frame. The 246 deduced amino acid sequence suggests the presence of membrane-associated segments and a weak similarity with the rod-like tail portion of heavy chain myosins from different species. The DXS1357E gene may be a candidate for one of the many diseases mapping to this region. A preliminary analysis did not show rearrangements of the gene in 19 independent patients with Emery-Dreifuss muscular dystrophy.

Non-specific X-linked mental retardation: linkage analysis in MRX2 and MRX4 families revisited

We have previously reported linkage analysis in 3 families with non-specific X-linked mental retardation (XLMR). This used RFLPs and was limited by the relatively low informativeness and density of markers available. We have performed a new linkage analysis using microsatellites (including new Genethon markers) in the two most informative families. In the MRX2 family, a lod score of 2.61 at theta = 0.05 had previously been obtained with DXS85 in Xp22.2. We now report a tighter linkage with AFM 135xe7 (DXS989, z = 4.62 at theta = 0.00) and established the order DXS85-DXS207-DXS999 (AFM234 y12)-MRX2, DXS365, DXS1052 (AFM 163yh2), DXS989-DXS1065 (AFM224zf2), DMD 3'. The localization of MRX2 in Xp22.2-p22.1 is thus clearly different from the more distal MRX gene defined by patients with contiguous gene syndromes. In the MRX4 family, a maximum lod score of 2.53 at theta = 0.00 had been obtained with DXS159 in Xq13. Our present study did not show recombination from ALAS2 in Xp11.21 to DXS441 in Xq13.3 (z = 3.38 at theta = 0.00 for the latter marker) and the closest flanking markers are DXS255 in Xp11.22 and DXYS1 in Xq21.3. Reduced recombination around the centromere prevents precise mapping. The localisation of MRX4 overlaps with that of several other MRX families.

Towards identification of X-linked mental retardation genes: a proposal

Identification of X linked mental retardation (XLMR) genes that can only be broadly localised by linkage analysis will ultimately depend on systematic screening of many probands for mutations in many candidate genes. This would be more efficiently performed by analysis of mRNA (or illegitimate transcripts) by reverse transcriptase-polymerase chain reaction (RT-PCR). A scheme is proposed that associates standardized reporting of XLMR families, including small families that would not by themselves yield statistically significant linkage information, and deposit of a lymphoblastoid cell line for one proband of each family to an accessible repository.

Genomic organization of the adrenoleukodystrophy gene

Adrenoleukodystrophy (ALD), the most frequent peroxisomal disorder, is a severe neurodegenerative disease associated with an impairment of very long chain fatty acids beta-oxidation. We have recently identified by positional cloning the gene responsible for ALD, located in Xq28. It encodes a new member of the "ABC" superfamily of membrane-associated transporters that shows, in particular, significant homology to the 70-kDa peroxisomal membrane protein (PMP70). We report here a detailed characterization of the ALD gene structure. It extends over 21 kb and consists of 10 exons. To facilitate the detection of mutations in ALD patients, we have determined the intronic sequences flanking the exons as well as the sequence of the 3' untranslated region and of the immediate 5' promoter region. Sequences present in distal exons cross-hybridize strongly to additional sequences in the human genome. The ALD gene has been positioned on a pulsed-field map between DXS15 and the L1CAM gene, about 650 kb upstream from the color pigment genes. The frequent occurrence of color vision anomalies observed in patients with adrenomyeloneuropathy (the adult onset form of ALD) thus does not represent a contiguous gene syndrome but a secondary manifestation of ALD.

The Friedreich ataxia region: characterization of two novel genes and reduction of the critical region to 300 kb

Friedreich ataxia is a severe neurodegenerative autosomal recessive disorder of unknown biochemical defect. The Friedreich ataxia locus (FRDA) is tightly linked to the centromeric side of the D9S5 locus. We have used 'exon-trapping' to identify two new genes, approximately 100 and 200 kb centromeric to D9S5, respectively. One gene appears ubiquitously expressed while the other is prominently expressed in muscle. The ubiquitous transcript codes for a protein containing a 20 aa repeat reminiscent of simple repeats found in several ribonucleoproteins. Using the single-strand conformation polymorphism (SSCP) procedure, we searched for mutations in affected patients in the coding sequence of the two genes, as well as in a gene that we had previously identified in the same region. Eight polymorphic DNA changes but no causative mutations were found, suggesting that the genes are not candidates for Friedreich ataxia. The discovery of a simple sequence repeat polymorphism in the most centromeric gene allowed the localization within that gene of the breakpoint of a previously described recombination in a Friedreich ataxia family, therefore excluding the two distal genes from the FRDA region. The lack of causative mutations in the three genes and the position of the recombination further delineate the FRDA locus to a 300 kb interval.

The protein coded by the X-adrenoleukodystrophy gene is a peroxisomal integral membrane protein

The gene for adrenoleukodystrophy (X-ALD), a peroxisomal disease characterized by excessive accumulation of very long-chain (VLC) fatty acids (> C22:0), has recently been identified by positional cloning, and it is predicted to encode a protein (ALD-P) of 745 amino acids [(1993) Nature 361, 726]. Using Western blot analysis of subcellular organelles purified by isopycnic density gradient centrifugation from X-ALD and control fibroblasts, we show that the monoclonal antibodies directed against ALD-P cross-react with a 75 kDa protein in intact peroxisomes and that ALD-P is an integral component of the peroxisomal membrane. Moreover, no signal for ALD-P was detected in peroxisomes from X-ALD patients with deletion of the ALD gene.

Expression of a recombinant dystrophin in mdx mice using adenovirus vector

Genetic deficiencies may be compensated by delivery of the appropriate gene to the affected tissue(s) by somatic gene transfer. In this study, recombinant adenoviruses (defective for replication) carrying a cDNA coding for a truncated dystrophin or 'minidystrophin' (Ad.dys), associated to adenoviruses carrying a beta-galactosidase reporter gene (Ad.beta gal), were administered locally to evaluate the biochemical correction of the genetic defect in mdx mice mutants. Both genes were placed under the control of muscle specific regulatory elements. Two weeks after a single intramuscular injection of Ad.dys, injected muscles showed a significant increase in the percentage of dystrophin positive fibres when compared to muscles either untreated or injected with Ad.beta gal only. Intramuscular injection of the adenoviral expression vectors elicited a local deleterious effect on muscle morphology, rarefaction of myofibres at the site of injection, calcifications and fibrosis were much more marked in comparison to control muscles injected with vehicle. beta-galactosidase was exclusively expressed within myofibres in a segmental fashion. Regional co-localization of beta-galactosidase and dystrophin expression gives further support to the demonstration of adenoviral induced expression of the recombinant genes.

Hypomagnesemia with secondary hypocalcemia in a female with balanced X;9 translocation: mapping of the Xp22 chromosome breakpoint

Magnesium-dependent hypocalcaemia (HSH), a rare inherited disease, is caused by selective disorders of magnesium absorption. Both X-linked and autosomal recessive modes of inheritance have been reported for HSH; this suggests a genetically heterogeneous condition. A balanced de novo t(X;9)(p22;q12) translocation has been reported in a female manifesting hypomagnesemia with secondary hypocalcemia. In a lymphoblastoid cell line, derived from this patient, the normal X chromosome is preferentially inactivated, suggesting that the patient's phenotype is caused by disruption of an HSH gene in Xp22. In an attempt to define more precisely the position of the X breakpoint, we have constructed a hybrid cell line retaining the der(X)(Xqter-Xp22.2::9q12-9qter) in the absence of the der(9) and the normal X chromosome. Southern blot analysis of this hybrid and in situ hybridization on metaphase chromosomes have localized the breakpoint between DXS16 and the cluster (DXS207, DXS43), in Xp22.2. Thus, if a gene involved in HSH residues at or near the translocation breakpoint, our findings should greatly facilitate its isolation.

Instability of CAG repeats in Huntington's disease: relation to parental transmission and age of onset

Huntington's disease (HD) has recently been found to be caused by expansion of a trinucleotide (CAG) repeat within the putative coding region of a gene with an unknown function. We report here an analysis of HD mutation and the characteristics of its transmission in 36 HD families. CAG repeats on HD chromosomes were unstable when transmitted from parent to offspring. Instability appeared more frequent and stronger upon transmission from a male than from a female, with a clear tendency towards increased size. We have also found a significant inverse correlation (p = 0.0001) between the age of onset and the CAG repeat length. The observed scatter would, however, not allow an accurate individual prediction of age of onset. Three juvenile onset cases analysed had an HD mutation of paternal origin. In at least two of these cases a large expansion of the HD allele upon paternal transmission may explain the major anticipation observed. Our results suggest that several features of the expansion mutation in HD are similar to those previously observed for mutations of similar size in spinobulbar muscular atrophy and in myotonic dystrophy, and to those observed more recently in spinocerebellar ataxia type 1 and in dentatorubropallidoluysian atrophy, four diseases also caused by expansion of CAG repeats.

The gene responsible for adrenoleukodystrophy encodes a peroxisomal membrane protein

Adrenoleukodystrophy is a severe genetic demyelinating disease associated with an impairment of beta-oxidation of very long chain fatty acids (VLCFA) in peroxisomes. Earlier studies had suggested that a deficiency in VLCFA CoA synthetase was the primary defect. A candidate adrenoleukodystrophy gene has recently been cloned and was found unexpectedly to encode a putative ATP-binding cassette transporter. We have raised monoclonal antibodies against this protein, that detect a 75kDa band. This protein was absent in several patients with adrenoleukodystrophy. Immunofluorescence and immunoelectron microscopy showed that the adrenoleukodystrophy protein (ALDP) is associated with the peroxisomal membrane. Distinct immunofluorescence patterns were observed in cell lines from patients with Zellweger syndrome (a peroxisomal biogenesis disorder) belonging to different complementation groups.

X-linked adrenoleukodystrophy gene: identification of a candidate gene by positional cloning

Adrenoleukodystrophy (ALD) is an X-linked peroxisomal disorder characterized by a progressive demyelination of the central nervous system, adrenal insufficiency and impaired capacity to o-oxidase very long chain fatty acids, a metabolic process that normally takes place in peroxisomes. The ALD locus has been mapped to Xq28 and we have recently identified a patient with ALD who has a complex rearrangement in the 5' end of the red/green color pigment genes in Xq28. This rearrangement comprises two deletions separated by a large inversion. The second deletion of this key ALD patient extends 19 kb into the 3' region of an expressed gene which was found partially deleted in six of 85 independent patients with ALD. This segment thus constitutes a candidate region for the ALD gene.

Mapping the Friedreich ataxia locus (FRDA) by linkage disequilibrium analysis with highly polymorphic microsatellites

The Friedreich's ataxia locus (FRDA) is tightly linked to markers D9S5 and D9S15 located in 9q13-q21. Cumulated maximum lod scores between FRDA and D9S5 and between FRDA and D9S15 are above 36 and 61, respectively, at a recombination fraction of 0, indicating that recombination events needed to orient the search of the gene are very difficult to identify and ascertain. We have established a 1 Megabase PFGE map around D9S5 and D9S15 and isolated a corresponding 530 kb YAC contig. We found that the two markers are 260 kb apart. This result was surprising, since D9S5 and D9S15 were independently isolated, but in agreement with the strong linkage between the two loci (lod score > 35 at a recombination fraction of 0). Seven clusters of rare cutter enzyme sites (CpG islands), which are potential indicators of genes, were identified in the 1 Megabase region by PFGE analysis and YAC mapping. The search for genes around the CpG islands is in progress. To map the Friedreich ataxia locus in the absence of clearly identified recombination events, we chose an alternative approach based on haplotype analysis of patients from small populations with precise geographic and historical origins, such as the Louisiana-Acadians, deported from Nova-Scotia about 150 years ago and who remained isolated for historical and cultural reasons. In this population, a single mutation, associated with a specific haplotype may account for the majority of Friedreich ataxia cases. Haplotypes different from the major haplotype at one or the other extremity can indicate ancient recombinations.(ABSTRACT TRUNCATED AT 250 WORDS)