Characterization of patients with glycerol kinase deficiency utilizing cDNA probes for the Duchenne muscular dystrophy locus

Summary Genomic DNA from five previously unreported patients with glycerol kinase deficiency (GKD), dystrophic myopathy, and adrenal insufficiency were studied with genomic probes and cDNA probes for the Duchenne muscular dystrophy (DMD) locus. These individuals, together with those reported by ourselves and others, show that patients with a contigous gene syndrome involving the DMD, GK, and adrenal hypoplasia congenita (AHC) loci have a broader distribution of microdeletion breakpoints than those observed among patients with classical DMD. This study demonstrates the use of the DMD cDNA probes to delineate the centromeric deletion breakpoints for patients with Xp21 microdeletions extending beyond the DMD locus. It also shows the practical diagnostic application of the DMD cDNA probes when the diagnosis of GKD is entertained in a patient with known DMD and only DNA is available for study.     

Congenital adrenal hypoplasia, myopathy, and glycerol kinase deficiency: Molecular genetic evidence for deletions

Glycerol kinase deficiency (GKD) is an X-linked recessive trait that occurs in association with congenital adrenal hypoplasia (AH) and developmental delay with or without congenital dystrophic myopathy. Several such patients have recently been reported to have cytological deletions of chromosome region Xp21 and/or of DNA markers that map near the locus for Duchenne muscular dystrophy (DMD) in band Xp21. We have examined the initial family reported in the literature and, using prometaphase chromosome studies and Southern blot analysis with 13 different DNA probes derived from band Xp21, have found no deletions within this region of the X chromosome. When DNA samples from six other unrelated affected males were analyzed, four of them were found to have different-size deletions within Xp21. Thus, the form of GKD associated with AH and dystrophic myopathy exhibits significant genetic heterogeneity at the DNA level. No deletions were detected in two patients with isolated GK deficiency. Comparison of our molecular studies of unrelated patients with deletions of DNA segments allows us to define the region of Xp21 (between probes J-Bir and L1.4) that most likely contains the genes for GKD and AH. This location is distal to the DMD locus. The patients with progressive muscular dystrophy tended to have larger deletions that include markers known to derive from the DMD locus, while GKD/AH/dystrophic-myopathy patients without current evidence of deletion seemed to have a milder, nonprogressive form of congenital myopathy.     

Characterisation of a Xp21 microdeletion syndrome in a 2-year-old boy with muscular dystrophy,glycerol kinase deficiency and adrenal hypoplasia congenita

Summary We report a 2-year-old boy with Duchenne muscular dystrophy (DMD), glycerol kinase deficiency (GK) and adrenal hypoplasia congenita (AHC). At three weeks of age, the patient was hospitalized for the first time with symptoms of hypotone dehydration because of AHC, At present, he shows severe muscular hypotonia and developmental delay. The patient and his family were referred to us for prenatal diagnosis and carrier testing in the mother of the patient and the mother's sister, respectively. The patient's DNA was examined by Southern blot and polymerase chain reaction analyses, using cDNA and genomic probes within and around the dystrophin (DYS) locus. A deletion was revealed, spanning DXS28, the whole dystrophin locus, DXS84 and DXS148, whereas DXS67, DXS68 (pter) and OTC (cen) were found to be retained. The cytogenetically visible microdeletion was also seen in the patient's mother, but not in the mother's sister or the patient's maternal grandmother. Our findings support the locus order pter-DXS67-DXS68-DXS28-AHC-GK-DMD-cen.     

DXS28 (C7) maps centromeric to DXS68 (L1-4) and DXS67 (B24) by deletion analysis

Complex glycerol kinase deficiency (CGKD) is a contiguous gene syndrome consisting of glycerol kinase deficiency together with Duchenne muscular dystrophy (DMD), congenital adrenal hypoplasia, and/or Aland Island eye disease. Deletion mapping of genomic DNA from patients with CGKD was carried out and allowed definitive ordering of loci DXS28 (C7), DXS68 (L1-4), and DXS67 (B24). Most reports have placed DXS68 centromeric to DXS28 and DXS67 on the basis of the initial mapping of the Iowa patient 3, but others have presented evidence consistent with the placement of DXS28 telomeric to DXS68 and DXS67. Through the use of DNA from CGKD patients with a variety of genomic deletions, this controversy is resolved and the order Xcen...DMD-DXS28-DXS68-DXS67...pter is definitively demonstrated.     

Physical mapping distal to the DMD locus

We report a new locus, designated JC-1, which maps between the gene responsible for adrenal hypoplasia (AHC) and the gene that encodes glycerol kinase (GK) in Xp21.2-21.3. The probe identifying this locus was obtained by cloning the distal sequence of a junction fragment from a Duchenne muscular dystrophy (DMD) patient with a large deletion. Pulsed-field gel electrophoresis analysis shows that a region of at least 4 Mb separates the 3' end of the dystrophin gene and the closest distal marker to AHC, DXS28. This region of the human genome contains few genes whose deletion results in a clinical phenotype. JC-1 is a useful probe from which to initiate strategies directed at cloning the AHC and GK loci.     

Isolation of a random cosmid clone,cX5, which defines a new polymorphic locus DXS148 near the locus for Duchenne muscular dystrophy

Summary We have isolated a random cosmid cX5 (DXS148), which maps into a small Xp21 deletion associated with Duchenne muscular dystrophy (DMD), chronic granulomatous disease (CGD), retinitis pigmentosa (RP) and McLeod syndrome. cX5 maps proximally outside several other deletions associated with DMD, glycerol kinase deficiency (GK) and adrenal hypoplasia (AHC). The following order of loci is proposed: centromere-OTC-cX5 (DXS148)-754 (DXS84)-PERT87 (DXS164)/DMD-telomere. A subclone cX5.7, isolated from this cosmid, identifies an MspI RFLP, with a minor allele frequency of 35%. This probe forms an important adjunct to the existing RFLPs for family studies in Duchenne muscular dystrophy.     

Detection of gene deletions in Chinese patients with Duchenne/Becker muscular dystrophy using CDNA probes and the polymerase chain reaction method.

One hundred thirty-eight patients with Duchenne/Becker muscular dystrophy (DMD/BMD) were screened with complete cDNA probes and the multiplex polymerase chain reaction (mPCR) amplification of 18 pairs of oligonucleotide primers. Eighty-six deletions and 4 duplications were detected, the deletion frequency being 62.3%. Eighty-two deletions were detected with the two sets of primers described by Chamberlain et al. and Beggs et al, which was 95.4% of deletions detected by complete cDNA probes. Consistent with the deletion locations described previously, the deletions of dystrophin gene in Chinese individuals are clustered mainly in two high-frequency deletion regions of exons 44-52 (68.6%) of 3' side of the gene central regions and exons 1-19 (26.7%) in the 5' side. The distribution of deletions in dystrophin gene is associated with the phenotype of DMD/BMD. In the 25 cases with in-frame deletions, 15 deletions located in the region of exons 2-47 were milder BMD and intermediate patients, as the location of deletions was not the important region of the dystrophin gene.     

Topography of the Duchenne muscular dystrophy (DMD) gene: FIGE and cDNA analysis of 194 cases reveals 115 deletions and 13 duplications.

We have studied 34 Becker and 160 Duchenne muscular dystrophy (DMD) patients with the dystrophin cDNA, using conventional blots and FIGE analysis. One hundred twenty-eight mutations (65%) were found, 115 deletions and 13 duplications, of which 106 deletions and 11 duplications could be precisely mapped in relation to both the mRNA and the major and minor mutation hot spots. Junction fragments, ideal markers for carrier detection, were found in 23 (17%) of the 128 cases. We identified eight new cDNA RFLPs within the DMD gene. With the use of cDNA probes we have completed the long-range map of the DMD gene, by the identification of a 680-kb SfiI fragment containing the gene's 3' end. The size of the DMD gene is now determined to be about 2.3 million basepairs. The combination of cDNA hybridizations with long-range analysis of deletion and duplication patients yields a global picture of the exon spacing within the dystrophin gene. The gene shows a large variability of intron size, ranging from only a few kilobases to 160-180 kb for the P20 intron.     

Molecular and phenotypic analysis of patients with deletions within the deletion-rich region of the Duchenne muscular dystrophy (DMD) gene

Eighty unrelated individuals with Duchenne muscular dystrophy (DMD) or Becker muscular dystrophy (BMD) were found to have deletions in the major deletion-rich region of the DMD locus. This region includes the last five exons detected by cDNA5b-7, all exons detected by cDNA8, and the first two exons detected by cDNA9. These 80 individuals account for approximately 75% of 109 deletions of the gene, detected among 181 patients analyzed with the entire dystrophin cDNA. Endpoints for many of these deletions were further characterized using two genomic probes, p20 (DXS269; Wapenaar et al.) and GMGX11 (DXS239; present paper). Clinical findings are presented for all 80 patients allowing a correlation of phenotypic severity with the genotype. Thirty-eight independent patients were old enough to be classified as DMD, BMD, or intermediate phenotype and had deletions of exons with sequenced intron/exon boundaries. Of these, eight BMD patients and one intermediate patient had gene deletions predicted to leave the reading frame intact, while 21 DMD patients, 7 intermediate patients, and 1 BMD patient had gene deletions predicted to disrupt the reading frame. Thus, with two exceptions, frameshift deletions of the gene resulted in more severe phenotype than did in-frame deletions. This is in agreement with recent findings by Baumbach et al. and Koenig et al. but is in contrast to findings, by Malhotra et al., at the 5' end of the gene.     

An error in dystrophin mRNA processing in golden retriever muscular dystrophy, an animal homologue of Duchenne muscular dystrophy.

Golden retriever muscular dystrophy (GRMD) is a spontaneous, X-linked, progressively fatal disease of dogs and is also a homologue of Duchenne muscular dystrophy (DMD). Two-thirds of DMD patients carry detectable deletions in their dystrophin gene. The defect underlying the remaining one-third of DMD patients is undetermined. Analysis of the canine dystrophin gene in normal and GRMD dogs has failed to demonstrate any detectable loss of exons. Here, we have demonstrated a RNA processing error in GRMD that results from a single base change in the 3' consensus splice site of intron 6. The seventh exon is then skipped, which predicts a termination of the dystrophin reading frame within its N-terminal domain in exon 8. This is the first example of dystrophin deficiency caused by a splice-site mutation.     

Deletion mapping of Aland Island eye disease to Xp21 between DXS67 (B24) and Duchenne muscular dystrophy.

Aland Island Eye Disease (AIED) is an X-linked form of ocular hypopigmentation--also known as Forsius-Eriksson, or type 2, ocular albinism--in which affected males demonstrate subnormal visual acuity, protanomalous red-green colorblindness, axial myopia, astigmatism, hypoplasia of the fovea, and hypopigmentation of the fundus. A patient has previously been described who, in addition to AIED, manifested a contiguous gene syndrome which included congenital adrenal hypoplasia (AHC), glycerol kinase deficiency (GKD), and Duchenne muscular dystrophy (DMD). In the present paper report we report the molecular genetic analysis of his deletion. Initially, multiplex polymerase-chain-reaction amplification was used to screen for a DMD-locus deletion which was then further characterized, using DMD cDNA and genomic probes, via Southern blot analysis. The deletion includes the region encompassed by probes C7 (DXS28) and DMD cDNA 8. Probes B24 (DXS67) and DMD cDNA 5b-7 show normal hybridization patterns and appear to flank the deletion, while the DMD cDNA 8 detects a junction fragment. Molecular genetic techniques have mapped the deletion in this patient to the subbands Xp21.3-21.2, between DXS67 and DMD.     

Detection of New Paternal Dystrophin Gene Mutations in Isolated Cases of Dystrophinopathy in Females

Duchenne muscular dystrophy is one of the most common lethal monogenic disorders and is caused by dystrophin deficiency. The disease is transmitted as an X-linked recessive trait; however, recent biochemical and clinical studies have shown that many girls and women with a primary myopathy have an underlying dystrophinopathy, despite a negative family history for Duchenne dystrophy. These isolated female dystrophinopathy patients carried ambiguous diagnoses with presumed autosomal recessive inheritance (limbgirdle muscular dystrophy) prior to biochemical detection of dystrophin abnormalities in their muscle biopsy. It has been assumed that these female dystrophinopathy patients are heterozygous carriers who show preferential inactivation of the X chromosome harboring the normal dystrophin gene, although this has been shown for only a few X:autosome translocations and for two cases of discordant monozygotic twin female carriers. Here we study X-inactivation patterns of 13 female dystrophinopathy patients—10 isolated cases and 3 cases with a positive family history for Duchenne dystrophy in males. We show that all cases have skewed X-inactivation patterns in peripheral blood DNA. Of the nine isolated cases informative in our assay, eight showed inheritance of the dystrophin gene mutation from the paternal germ line. Only a single case showed maternal inheritance. The 10-fold higher incidence of paternal transmission of dystrophin gene mutations in these cases is at 30-fold variance with Bayesian predictions and gene mutation rates. Thus, our results suggest some mechanistic interaction between new dystrophin gene mutations, paternal inheritance, and skewed X inactivation. Our results provide both empirical risk data and a molecular diagnostic test method, which permit genetic counseling and prenatal diagnosis of this new category of patients.     

Identification of novel mutations of the DAX-1 gene in patients with X-linked adrenal hypoplasia congenita

OBJECTIVE: X-linked adrenal hypoplasia congenita (AHC) is a condition clinically featuring adrenal insufficiency and hypogonadotropic hypogonadism caused by mutations of DAX-1. This study was undertaken to characterize the molecular defects of DAX-1 in 3 unrelated Korean patients with AHC. PATIENTS AND METHODS: Patient 1 is a 6-year-old boy who presented with a salt-losing adrenal crisis in the neonatal period. Patient 2 is a 3-year-old boy who manifested aspiration pneumonia and adrenal insufficiency at the age of 1 month. Patient 3 is a 7-year-old boy who developed an adrenal crisis at the age of 3 days. In each of these patients, DAX-1 was analyzed by direct DNA sequencing after polymerase chain reaction amplification of the entire coding region. RESULTS: Direct sequencing of DAX-1 revealed two novel mutations, 1156_1157delCT in patient 1 and another novel nonsense mutation W105X in patient 2. Patient 3 had complete deletion of DAX-1. In patient 3, serum transaminases and creatine kinase levels were elevated while the glycerol kinase activity of leukocytes was decreased. Markedly elevated glycerol excretion was detected by urine organic acid analysis. Patient 3 was diagnosed as Xp21 contiguous gene syndrome associated with deletions of the entire IL1RAPL, GK genes and the C-terminal region of DMD gene. CONCLUSIONS: Two novel mutations of DAX-1 were detected in 2 unrelated patients with AHC, and complete deletion of DAX-1 in a patient with Xp21 contiguous gene syndrome who also presented with glycerol kinase deficiency, Duchenne muscular dystrophy, and AHC.     

Molecular analysis of the Duchenne muscular dystrophy region using pulsed field gel electrophoresis

Genetic and molecular studies show that the Duchenne muscular dystrophy (DMD) locus at Xp21 is large and complex. We have analyzed this region using pulsed field gel electrophoresis (PFGE) and have determined physical distances between Xp21 probes. The sum of the sizes of the Sfil restriction fragments detected by these probes is greater than 4000 kb. The deletion endpoints in two DMD patients were detected by observing changes in these restriction fragments. In addition, the Xp21 breakpoint for the X;1 translocation in an affected female was mapped. These results demonstrate the applicability of PFGE for analysis of Xp21, and should facilitate the mapping of other translocations and deletions in this region, some of which lead to glycerol kinase deficiency and adrenal hypoplasia as well as DMD.     

Brother/sister pairs affected with early-onset, progressive muscular dystrophy: molecular studies reveal etiologic heterogeneity.

An autosomal recessive (AR) form of muscular dystrophy that clinically resembles Duchenne/Becker types exists, but its frequency is unknown. We have studied three unrelated affected brother/sister pairs and their families for deletions and polymorphisms with the entire dystrophin cDNA and other DNA probes from the Xp21 region to test for involvement of the DMD locus. In family 1 a large intragenic deletion was found in the affected male. The affected sister was heterozygous for this deletion, but the mother was not, implying germinal mosaicism. In family 2, no deletion was detected in the affected male. RFLP analysis revealed that the affected male and an unaffected sister shared a complete Xp21 haplotype while the affected sister had inherited a recombinant Xp21 region resulting from a crossover between pERT 87-15 and J-Bir. Only the 5' region of the dystrophin gene was shared with the affected boy. X-inactivation studies using a polymorphism in the 5'-flanking region of the HPRT gene, in conjunction with methylation-sensitive enzymes, revealed random X inactivation in the affected girl's leukocytes. In a muscle biopsy from the affected male, the dystrophin protein was present in normal amount and size. Family 3 was informative for four RFLPs detected with dystrophin cDNA probes which span the entire gene. The affected male was found to share the complete dystrophin RFLP haplotype with his unaffected brother, while his affected sister had inherited the other maternal haplotype. It is concluded that the clinical presentation of early-onset, progressive muscular dystrophy in a male and in his karyotypically normal sister can be caused by mutations at different loci. While in family 1 a deletion in the dystrophin gene is responsible, this gene does not appear to be involved in families 2 and 3.     

The molecular basis for Duchenne versus Becker muscular dystrophy: Correlation of severity with type of deletion

About 60% of both Duchenne muscular dystrophy (DMD) and Becker muscular dystrophy (BMD) is due to deletions of the dystrophin gene. For cases with a deletion mutation, the "reading frame" hypothesis predicts that BMD patients produce a semifunctional, internally deleted dystrophin protein, whereas DMD patients produce a severely truncated protein that would be unstable. To test the validity of this theory, we analyzed 258 independent deletions at the DMD/BMD locus. The correlation between phenotype and type of deletion mutation is in agreement with the "reading frame" theory in 92% of cases and is of diagnostic and prognostic significance. The distribution and frequency of deletions spanning the entire locus suggests that many "in-frame" deletions of the dystrophin gene are not detected because the individuals bearing them are either asymptomatic or exhibit non-DMD/non-BMD clinical features.     

Point mutations and polymorphisms in the human dystrophin gene identified in genomic DNA sequences amplified by multiplex PCR

Summary About one third of Duchenne muscular dystrophy (DMD) patients have no gross DNA rearrangements in the dystrophin gene detectable by Southern blot analysis or multiplex exon amplification. Presumably, in these cases, the deficiency is caused by minor structural lesions of the dystrophin gene. However, to date, only a single human DMD case has been described where a point mutation, producing a stop codon, accounts for the DMD phenotype. To screen for microheterogeneities in the dystrophin gene, we applied analysis by chemical mismatch cleavage to thirteen exons amplified in multiplex sets by the polymerase chain reaction. This analysis covers approximately 20% of the dystrophin-coding sequence. Sixty DMD patients without detectable deletions or duplications were investigated, leading to the identification of two point mutations and four polymorphisms with a frequency higher than 5%. Both point mutations are frameshift mutations in exons 12 and 48, respectively, and are closely followed by stop codons, thus explaining the functional deficiency of the dystrophin gene products in both patients.     

A 10-megabase physical map of human Xp21, including the Duchenne muscular dystrophy gene

Using pulsed-field gel electrophoresis and 12 Xp21-derived DNA probes, we have constructed a continuous restriction map spanning more than 4 million base pairs (4 Mbp), including the Duchenne muscular dystrophy gene of more than 2 Mbp. This detailed map is part of a less detailed map spanning 10 Mbp, also spanning the genes for glycerol kinase and congenital adrenal hypoplasia, constructed under electrophoresis conditions which separated DNA fragments in the range 200 to 4000 kbp. DNA from three different tissues was analyzed, and differential methylation was observed.     

Molecular diagnosis of Duchenne/Becker muscular dystrophy by polymerase chain reaction and microsatellite analysis

Duchenne muscular dystrophy (DMD) and Becker muscular dystrophy (BMD) are X-linked recessive genetic disorders resulting from mutations in the dystrophin gene. About two-thirds of the affected patients have large deletions or duplications, which occur in the 5' and central region of the gene. The remaining DMD/BMD cases show no deletions, so they cannot be easily identified by current strategies. In these DMD/BMD families, a linkage analysis that involves DNA markers of the flanking and intragenic dystrophin gene are necessary for carrier and prenatal diagnosis. We analyzed eighteen deletion-prone exons of the gene by a polymerase chain reaction (PCR) in order to characterize the molecular defects of the dystrophin gene in Korean DMD/BMD families. We also performed a linkage analysis to assess the usefulness and application of six short tandem repeat markers for molecular diagnosis in the families. We observed a deletion that eliminated the exon 50. Also, a linkage analysis in the families with six short tandem repeat (STR) markers showed heterozygosity at most of the STR markers. The haplotype analysis was useful for detecting the carrier status. This study will be helpful for a molecular diagnosis of DMD/BMD families in the Korean population.     

Identification of new markers in Xp21 between DXS28 (C7) and DMD

Characterization of Xp21 distal to Duchenne muscular dystrophy (DMD) in the region containing the genes for adrenal hypoplasia congenita (AHC) and glycerol kinase deficiency (GKD) has been limited due to a paucity of probes. Two probes were localized between DXS28 (C7) and AHC, the yeast artificial chromosome insert YHX39 (DXS727) and the polymorphic phage clone QST59 (DXS319). A genomic clone, FT1 (DXS726), 3' to DMD, was also characterized. Portions of the three probes were sequenced and primer pairs were generated to amplify a sequence-tagged site within each probe. Amplification of DNA from patients confirmed the deletion results obtained by Southern blot analysis, and these three sequence-tagged sites were successfully combined for triplex PCR. In addition to facilitating molecular genetic diagnosis in Xp21, these probes can be used to identify additional YACs and other probes to further increase the genomic information and diagnostic capabilities in this region.