Linkage analyses of five chromosome 4 markers localizes the facioscapulohumeral muscular dystrophy (FSHD) gene to distal 4q35

The genetic locus for facioscapulohumeral muscular dystrophy (FSHD) has been mapped to chromosome 4. We have examined linkage to five chromosome 4q DNA markers in 22 multigenerational FSHD families. Multipoint linkage analyses of the segregation of four markers in the FSHD families and in 40 multigenerational mapping families from the Centre d'Etude du Polymorphisme Humaine enabled these loci and FSHD to be placed in the following order: cen-D4S171-factor XI-D4S163-D4S139-FSHD-qter. One interval, D4S171-FSHD, showed significant sex-specific differences in recombination. Homogeneity tests supported linkage of FSHD to these 4q DNA markers in all of the families we studied. The position of FSHD is consistent with that generated by other groups as members of an international FSHD consortium.     

Mapping of facioscapulohumeral muscular dystrophy gene to chromosome 4q35-qter by multipoint linkage analysis and in situ hybridization

We have recently assigned the facioscapulohumeral muscular dystrophy (FSHD) gene to chromome 4 by linkage to the microsatellite marker Mfd 22 (locus D4S171). We now report that D4S139, a VNTR locus, is much more closely linked to FSHD. Two-point linkage analysis between FSHD and D4S139 in nine informative families showed a maximum combined lod score (Zmax) of 17.28 at a recombination fraction theta of 0.027. Multipoint linkage analysis between FSHD and the loci D4S139 and D4S171 resulted in a peak lod score of 20.21 at 2.7 cM from D4S139. Due to the small number of recombinants found with D4S139, the position of the FSHD gene relative to that of D4S139 could not be established with certainty. D4S139 was mapped to chromosome 4q35-qter by in situ hybridization, thus firmly establishing the location of the FSHD gene in the subtelomeric region of chromosome 4q. One small family yielded a negative lod score for D4S139. In the other families no significant evidence for genetic heterogeneity was obtained. Studies of additional markers and new families will improve the map of the FSHD region, reveal possible genetic heterogeneity, and allow better diagnostic reliability.     

The human skeletal muscle adenine nucleotide translocator gene maps to chromosome 4q35 in the region of the facioscapulohumeral muscular dystrophy locus

Facioscapulohumeral muscular dystrophy (FSHD) is a relatively common autosomal dominant neuromuscular disorder. The gene for FSHD has recently been assigned to chromosome 4q35. Although abnormal mitochondrial and biochemical changes have been observed in FSHD, the molecular defect is unknown. In addition to the FSHD gene, the human muscle adenine nucleotide translocator gene (ANT1) is located on chromosome 4. Interestingly, biochemical studies recently showed a possible defect of ANT1. In order to evaluate the potential role of ANT1 in the etiology of FSHD, the human ANT1 gene was isolated by cosmid cloning and localized to 4q35, in the region containing the FSHD gene. However, in situ hybridization and physical mapping of somatic cell hybrids localized the ANT1 gene proximal to the FSHD gene. In addition, a polymorphic CA-repeat 5 kb upsstream of the ANT1 gene was used as a marker in FSHD and Centre d'Etude du Polymorphisme Humain families to perform linkage analysis. These data together exclude ANT1 as the primary candidate gene for FSHD. The most likely order of the loci on chromosome 4q35 is cen-ANT1-D4S171-F11-D4S187-D4S163-D4S139-FSHD-tel.     

Mapping of facioscapulohumeral muscular dystrophy gene to chromosome 4q35-qter by multipoint linkage analysis and in situ hybridization

We have recently assigned the facioscapulohumeral muscular dystrophy (FSHD) gene to chromosome 4 by linkage to the microsatellite marker Mfd 22 (locus D4S171). We now report that D4S139, a VNTR locus, is much more closely linked to FSHD. Two-point linkage analysis between FSHD and D4S139 in nine informative families showed a maximum combined lod score (Z_max) of 17.28 at a recombination fraction θ of 0.027. Multipoint linkage analysis between FSHD and the loci D4S139 and D4S171 resulted in a peak lod score of 20.21 at 2.7 cM from D4S139. Due to the small number of recombinants found with D4S139, the position of the FSHD gene relative to that of D4S139 could not be established with certainty. D4S139 was mapped to chromosome 4q35-qter by in situ hybridization, thus firmly establishing the location of the FSHD gene in the subtelomeric region of chromosome 4q. One small family yielded a negative lod score for D4S139. In the other families no significant evidence for genetic heterogeneity was obtained. Studies of additional markers and new families will improve the map of the FSHD region, reveal possible genetic heterogeneity, and allow better diagnostic reliability.     

Regional mapping of facioscapulohumeral muscular dystrophy gene on 4q35: Combined analysis of an international consortium

Members of an international consortium for linkage analysis of the facioscapulohumeral muscular dystrophy (FSHD) gene have pooled data for joint analyses, in an attempt to determine the precise location of the FSHD gene and the order of four DNA markers on 4q35 region. Six laboratories determined a total of 3,078 genotypes in 65 families, consisting of a total of 504 affected subjects and 559 unaffected subjects. For each marker, a mean of 648 meioses were informative. D4S139 and D4S163 were identified as the closest linked markers to the FSHD locus, with 99% upper confidence intervals of recombination fractions of .08 and .10, respectively. We have used the CRI-MAP program to construct the most likely order of cen-D4S171-F11-D4S163-D4S139-FSHD-tel, with favorable odds of 10(8)-10(114) over all other orders except that in which F11 and D4S171 are reversed, for which the odds ratio was 191:1. With this order, the genetic map of this region extends 25.5 cM in males and 13.8 cM in females (averaging 19.5 cM for sexes combined); the sex difference was statistically significant (P = .0013). Comparison between families for the two-point and multipoint lod scores involving FSHD showed no evidence for heterogeneity of this disorder. However, after the completion of this analysis, one large family which might show heterogeneity was identified. In view of this and the fact that all of the linked markers reside on the same side of the FSHD locus, the clinical application of these markers is not recommended at this time.     

Linkage localization of facioscapulohumeral muscular dystrophy (FSHD) in 4q35.

Fasioscapulohumeral muscular dystrophy (FSHD) has recently been localized to 4q35. We have studied four families with FSHD. Linkage to the 4q35 probes D4S163, D4S139, and D4S171 was confirmed. We found no recombinants helpful in detailed localization of the FSHD gene. Two of our families include males with a rapidly progressive muscle disease that had been diagnosed, on the basis of clinical features, as Duchenne muscular dystrophy. One of these males is available for linkage study and shares the haplotype of his FSHD-affected aunt and cousin.     

Genetic and physical mapping on chromosome 4 narrows the localization of the gene for facioscapulohumeral muscular dystrophy (FSHD).

We have used a combination of classical RFLPs and PCR-based polymorphisms including CA repeats and single-strand conformation polymorphisms to generate a fine-structure genetic map of the distal long arm of chromosome 4q. This map is now genetically linked to the pre-existing anchor map of 4pter-4q31 and generates, for the first time, a complete linkage map of this chromosome. The map consists of 32 anchor loci placed with odds of greater than 1,000:1. The high-resolution map in the cytogenetic region surrounding 4q35 provides the order 4cen-D4S171-F11-D4S187-D4S163-D4S139-4q ter. When we used somatic cell hybrids from a t(X;4)(p21;q35) translocation, these five markers fell into three groups consistent with the genetic map-D4S171 and F11 in 4pter-4q35, D4S163 and D4S139 in 4q35-4qter, and D4S187 as a junction fragment between these two regions. These markers are in tight linkage to the gene for facioscapulo-humeral muscular dystrophy (FSHD) mapped to this region by several collaborating investigators and provide a framework for further detailed analysis of this region.     

Chromosome 4q35 haplotypes and DNA rearrangements segregating in affected subjects of 19 Italian families with facioscapulohumeral musculatur dystrophy (FSHD)

Four DNA markers on the distal long arm of chromosome 4 have been analyzed for their linkage to facioscapulohumeral muscular dystrophy locus (FSHD) in a series of 16 Italian families. We found that, in two families, the disease is not linked to the 4q35 markers, indicating the presence of genetic heterogeneity among Italian FSHD families. Linkage analysis in the remaining families supports the order cen-D4S171-D4S163-D4S139-D4S810-FSHD-qter, in agreement with the physical map from the literature. EcoRI digestion and hybridization with the distal marker p13E-11 (D4S810) detected DNA rearrangements in the affected members of both sporadic and familial cases of FSHD, with family-specific fragments ranging in size between 15 kb and 28 kb. In three sporadic FSHD cases, the appearance of a new small fragment not present in either parent was clearly associated with the development of FSHD disease. However, in the familial cases analyzed, we observed two recombinations between all four 4q35 markers and the disease locus in apparently normal subjects, leaving open the possibility of nonpenetrance of the FSHD mutation.

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Linkage studies in facioscapulohumeral muscular dystrophy (FSHD)

Facioscapulohumeral muscular dystrophy (FSHD) has been localized to the 4q35-qter region of chromosome 4. Linkage analyses of two polymorphic markers from the region, D4S139 and D4S163, have been carried out using four large multigenerational FSHD families. The results indicate that both markers are closely linked to FSHD, with D4S139 being the closest proximal marker to FSHD.     

Localization of the gene for the nevoid basal cell carcinoma syndrome.

The nevoid basal cell carcinoma syndrome (NBCC) is an autosomal dominant multisystem disorder characterized by multiple basal cell carcinomas, jaw cysts, pits of the palms and/or soles, ectopic calcification, and skeletal malformations. The NBCC gene has recently been mapped to chromosome 9q22.3-9q31. In order to further define the region containing the NBCC gene, we have analyzed 137 individuals from eight families for linkage, using 11 markers from the region. Eight markers showed statistically significant evidence for linkage to NBCC. Three markers (D9S180, ALDOB, and D9S173) showed no definite recombination with the disease locus. All families showed some evidence for linkage to markers in this region. On the basis of the inspection of individual recombinants and previously published information about map location, we suggest the following order for the markers: D9S119-D9S12-D9S197-D9S196-(NBCC,D9S180 -D9S173,ALDOB)-D9S109- D9S127-(D9S53,D9S29). We are currently developing YAC contigs for the most closely linked markers, to further refine the location of the NBCC gene.     

Evidence for heterogeneity in facioscapulohumeral muscular dystrophy (FSHD)

Facioscapulohumeral muscular dystrophy (FSHD) is a slowly progressive primary disease of muscle which is usually inherited as an autosomal dominant disorder. FSHD has been localized to the long arm of chromosome 4, specifically to the 4q3.5-qter region. Initially published linkage studies showed no evidence for heterogeneity in FSHD. In the present study we have examined individuals in seven FSHD families. Two-point lod scores show significant evidence for linkage for D4S163 (lod score 3.04 at recombination fraction .21) and D4S139 (lod score 3.84 at recombination fraction .20). D4S171 also gave a positive score (lod score 2.56 at recombination fraction .24). Significant evidence for heterogeneity was found for each of the three markers. Multipoint linkage analysis in this region resulted in a peak multipoint lod score of 6.47. The multipoint analysis supported the two-point studies with odds of 20:1 showing linkage and heterogeneity over linkage and homogeneity. Five of the seven families gave a posterior probability of >95% of being of the linked type, while two families appeared unlinked to this region of 4q (P < .01%). Individuals in the two unlinked families met the clinical criteria for the diagnosis of FSHD, including facial weakness, clavicular flattening, scapula winging, proximal muscle weakness, and myopathic changes on muscle biopsies without inflammatory or mitochondrial pathology. This study demonstrates genetic heterogeneity in FSHD and has important implications for both genetic counseling and the elucidation of the etiology of FSHD.     

Genetic heterogeneity of polycystic kidney disease in Bulgaria

Linkage analysis was performed on 22 Bulgarian families with polycystic kidney disease (PKD) ascertained through the hemodialysis centers of two medical schools. A total of 128 affected and 59 unaffected individuals, and 54 spouses have been investigated using eight polymorphic markers linked to PKD1 and nine markers to PKD2. The results demonstrate locus heterogeneity with 0.67 as the maximum likelihood value of alpha, i.e., the proportion of families linked to PKD1. In five families, the results suggest linkage to PKD2, and observed recombinants place the gene between loci D4S1544 and D4S1542. In one family, two double recombinants for closely linked markers on chromosome 16 and on chromosome 4 give evidence for the lack of link-age to either PKD1 or PKD2, thus suggesting the involvement of a third locus. Analysis of clinical data in the PKD1 group versus the unlinked group shows no significant differences in the severity of the disease.     

Germline mosaicism in 4q35 facioscapulohumeral muscular dystrophy (FSHD1A) occurring predominantly in oogenesis

Facioscapulohumeral muscular dystrophy (FSHD) is an autosomal dominantly inherited neuromuscular disorder affecting facial and shoulder girdle muscles with subsequent progression to the pelvic girdle and lower extremities. The major gene involved has been localized to chromosome 4q35 (FSHD1A). The 4q35 DNA marker p13E-11 (D4F104S1) detects a de novo EcoRI DNA rearrangement of < 30 kb in isolated and familial cases. The intrafamilial size of the fragment is constant, inversely correlated with the severity, and directly correlated with the age of onset of the condition. There has been evidence of parental mosaicism in FSHD1A for the D4F104S1 locus. Four female and three male clinically unaffected parents have been described to be carriers of EcoRI fragments of the same size as their affected offspring, but with a markedly less intensive hybridization signal (semi-quantitative evidence). In our total sample of 42 FSHD1A families, we found semi-quantitative evidence of parental D4F104S1 mosaicism in 11 families (EcoRI fragment size range: 12–27 kb). On analysis with adjacent 4q35 probes (D4S163, D4S139), additional qualitative evidence of germline mosaicism could be obtained in two families. In our mosaic families and in the families reported in the literature, a female predominance of mosaicism carriers (13 females versus 5 males) could be noted. In our sample, mosaicism was observed in multigeneration families, in families with isolated cases, and in families with two and three affected children from seemingly unaffected parents. A short EcoRI fragment once having emerged in a mosaicism carrier was found to be transmitted autosomal dominantly to subsequent generations. Of all reported sporadic patients, 19% have a mosaic parent. Finding evidence of parental mosaicism in all our families with more than one affected child of seemingly unaffected parents suggests that there is no autosomal recessively inherited form of FSHD1A. Received: 5 March 1996 / Revised: 14 May 1996     

A linkage group of five DNA markers on human chromosome 10

Five chromosome 10 DNA markers (D10S1, D10S3, D10S4, D10S5, and RBP3) were typed in five large pedigrees with multiple endocrine neoplasia type 2A (MEN-2A) and in five non-MEN-2A pedigrees. Linkage analyses showed that these loci and the locus for MEN-2A (MEN2A) are in one linkage group spanning at least 70 cM. The order of the marker loci is RBP3-D10S5-D10S3-D10S1-D10S4, with interlocus recombination frequencies of 7, 13-19, 19, and 19%, respectively, all on the same side of MEN2A. Analyses of sex-specific recombination frequencies indicated no significant differences between males and females for any of the map intervals studied. Previous localization of D10S5 and RBP3 to the proximal region of the long arm and the pericentric region, respectively, comparison of results with other studies, and our preliminary results with other chromosome 10 markers suggest that the D10S4 end of the map extends into the long arm. Our linkage map has been constructed using only two- and three-locus analyses. It will be possible to combine our results with those of other groups to construct a more detailed and accurate genetic map of chromosome 10.     

Evidence from family studies that the gene causing Huntington disease is telomeric to D4S95 and D4S90.

A DNA probe (D4S95) that detects a variable number of tandem repeats and a single-site-variation polymorphism after digestion with a single restriction enzyme, AccI, has previously been described. The order of this probe relative to the gene for Huntington disease (HD) and other previously described markers has not been established. Analysis of 24 affected families with HD has shown that D4S95 is in tight linkage with the gene causing HD, with a maximal Lod score of 12.489 at a theta of .03. D4S90 is a probe which maps to 4p16.3, telomeric to D4S95, and detects polymorphisms with HincII and other enzymes. In one affected person, recombination has occurred between D4S10 and HD, between D4S95 and HD, and in all likelihood also between D4S90 and HD, which strongly suggests that the gene for HD is telomeric to all these DNA probes. This suggests that the gene causing HD is located in the most distal region of the short arm of chromosome 4, flanked by D4S90 and the telomere, and supports the locus order D4S10-D4S95-D4S90-HD-telomere. D4S95 is a most useful DNA marker for predictive testing programs, while D4S90 will serve as a useful starting point for identifying DNA fragments closer to the gene for HD.     

Characterization of a recombinant that locates the hereditary hemochromatosis gene telomeric to HLA-F

The gene responsible for hereditary hemochromatosis has been shown to be closely linked to the HLA-A and D6S105 loci on the short arm of chromosome 6. Efforts at mapping the disease gene have been hindered, however, by a lack of informative recombinants in this region. We have identified two recombinant individuals in a single affected family and have confirmed recombination by analysis of 16 polymorphic markers located near HLA-A and D6S105. One of the recombinants provides evidence for the location of the hemochromatosis gene telomeric to HLA-F.     

Characterisation of wheat-rye recombinants with RFLP and PCR probes

Summary The introgression of genetic material from alien species into wheat has become an important tool in modern wheat breeding. Ideally, only the trait of interest and no flanking material should be transferred. Random recombination between the genetic material is therefore of paramount importance. In a model system, we examined 17 recombinants putatively between chromosome 1D of wheat and 1R of rye with 60 random RFLP and three PCR markers. The recombinants had been generated by removing the normal effect of the Ph1 gene in the wheat background. Amongst the nine short-arm recombinants, three breakpoints were identified but no differentiation could be made between the five proximal recombinants. For the eight long-arm recombinants analysed only two breakpoints were identified with 36 markers. However, only a single RFLP marker was able to differentiate between the recombinants. Indeed the long-arm results are consistent with the possibility that only the rye telomeric region had been transferred. These results indicate either a strong clustering of the RFLP markers near the centromere or else imply that recombination induced between wheat and rye in the absence of the normal effect of the Ph1 gene occurs at only restricted sites. The results allow new primary recombinants to be selected for intercrossing to generate secondary recombinants which are expected to have a smaller interstitial rye segment than that present in DR-A1.     

A new DNA marker (D10S94) very tightly linked to the multiple endocrine neoplasia type 2A (MEN2A) locus.

Combined somatic cell hybrid and linkage studies between D10S94 and five pericentromeric loci (FNRB, D10Z1, MEN2A, RBP3, and D10S15) have localized the new DNA sequence pcl1/A1S-6-c23 at D10S94 to 10q11.2. No recombinants were observed between D10S94 and D10Z1 or MEN2A. D10S94 maps in proximal 10q11.2 very near to MEN2A. There are three possible orders for the six loci that we investigated from the centromeric region of chromosome 10. At present the genetic data do not allow us to order MEN2A with respect to D10Z1 and D10S94. The three possible orders are FNRB-D10Z1-D10S94-MEN2A-RBP3-D10S15, FNRB-D10Z1-MEN2A-D10S94-RBP3-D10S15, and FNRB-MEN2A-D10Z1-D10S94-RBP3-D10S15. In view of the fact that no recombinants between D10S94 and MEN2A or between D10S94 and D10Z1 were observed, the combined haplotypes formed from RFLPs and D10Z1 and D10S94 will increase the informativeness and accuracy of genotype prediction for at-risk members of the families having the MEN 2A syndrome, particularly when the affected parent is female. The localization of D10S94 with respect to MEN2A will prove valuable in experiments directed toward cloning the MEN2A locus.     

Linkage analysis of neurofibromatosis type I, using chromosome 17 DNA markers.

The gene for von Recklinghausen neurofibromatosis type 1 (NF1) has recently been mapped to the pericentromeric region of human chromosome 17. To further localize the NF1 gene, linkage analysis using chromosome 17 DNA markers was performed on 11 multigeneration families with 175 individuals, 57 of whom were affected. The markers used were D17Z1 (p17H8), D17S58 (EW301), D17S54 (EW203), D17S57 (EW206), D17S73 (EW207), CRI-L946, HOX-2, and growth hormone. Tight linkage was found between NF1 and D17Z1, D17S58, and D17S57 with a recombination fraction of zero. One recombinant was detected between NF1 and D17S73, showing linkage with a 10% recombination fraction. No linkage was detected between NF1 and CRI-L946 or between HOX-2 and growth hormone. Our data are consistent with the proposed gene order pter D17S58-D17Z1-NF1-D17S57-D17S73 qter.