Mapping of the familial Mediterranean fever gene to chromosome 16.

Familial Mediterranean fever (FMF) is an autosomal recessive disease characterized by recurrent attacks of fever, synovitis, peritonitis, or pleurisy. Some patients eventually develop systemic amyloidosis. The biochemical cause of the disease is unknown. We have conducted a genome-wide search for the FMF locus using 125 different DNA markers and mapped the FMF gene to the short arm of chromosome 16. The study was performed on 35 Israeli families primarily of North African and Iraqi origin. For the five markers D16S82 (p41-1 Sacl), D16S80 (24-1 Taq1), D16S84 (pCMM65 Taq1), D16S83 (pEKMDA2-1 Rsal), and HBA (5'HVR Rsal) we obtained maximum lod scores of 2.72 (theta = 0.08), 10.34 (theta = 0.04), 9.66 (theta = 0.050, 9.35 (theta = 0.03), and 14.31 (theta = 0.08), respectively. Multipoint analysis with HBA and D16S84 defined as a fixed loci gave a maximum lod score of 19.86 centromeric to D16S84. Crossovers defined by these markers place the FMF gene in an area of approximately 5 cM between D16S80 and D16S84. Other genes mapped to this area (16p13.3) include phosphodiesterase IB (PDE1B), hydroxyacyl-glutathione hydrolase (HAGH), phosphoglycolate phosphatase (PGP), and the gene that causes adult polycystic kidney disease (PKD1). None of these genes bear an obvious pathophysiological relationship to FMF. Using additional markers from this region we hope to localize more precisely the FMF gene and to offer the possibility of prenatal diagnosis in selected cases. Our ultimate goal is to isolate and characterize the FMF gene.     

Mapping the gene for juvenile onset neuronal ceroid lipofuscinosis to chromosome 16 by linkage analysis.

The ceroid-lipofuscinoses are a group of inherited neurodegenerative disorders characterised by the accumulation of autofluorescent lipopigment in neurones and other cell types. The underlying biochemical defect is unknown. Juvenile onset neuronal ceroid lipofuscinosis (Batten disease; Spielmeyer-Vogt disease) is an autosomal recessive trait. Linkage studies were undertaken to determine the location of the Batten disease (CLN3) mutation. Studies were carried out on 205 members of 42 families in which there were 76 affected individuals. Families originated from 7 North European countries and Canada. Serum samples from 23 families, including a total of 48 affected children, were tested for a set of "classical markers." A positive lod score was found with the haptoglobin (Hp) system. The combined male and female maximum lod score was 3.00 at theta = 0.00 and theta = 0.26, respectively. This provided an indication of localisation to the long arm of chromosome 16. Linkage analysis was then carried out in 42 families using DNA markers for loci on human chromosome 16. The maximal lod score between Batten disease and the locus D16S148 calculated for combined sexes was 6.05. No recombinants were observed. Multilocus analysis using 5 loci indicated the most likely order to be HP-D16S151-D16S150-CLN3-D16S148-D16S147. Work is in progress to refine the genetic and physical localisation of the Batten disease gene using additional markers in this region and a panel of somatic cell hybrids. Methods are now available which should allow the gene to be isolated and characterised.     

Mapping a gene for familial hypertrophic cardiomyopathy to chromosome 14q1

To identify the chromosomal location of a gene responsible for familial hypertrophic cardiomyopathy, we used clinical and molecular genetic techniques to evaluate the members of a large kindred. Twenty surviving and 24 deceased family members had hypertrophic cardiomyopathy; 58 surviving members were unaffected. Genetic-linkage analyses were performed with polymorphic DNA loci dispersed throughout the entire genome, to identify a locus that was inherited with hypertrophic cardiomyopathy in family members. The significance of the linkage detected between the disease locus and polymorphic loci was assessed by calculating a lod score (the logarithm of the probability of observing coinheritance of two loci, assuming that they are genetically linked, divided by the probability of detecting coinheritance if they are unlinked). A DNA locus (D14S26), previously mapped to chromosome 14 and of unknown function, was found to be coinherited with the disease in this family. No instances of recombination were observed between the locus for familial hypertrophic cardiomyopathy and D14S26, yielding a lod score of +9.37 (theta = 0). These data indicate that in this kindred, the odds are greater than 2,000,000,000:1 that the gene responsible for familial hypertrophic cardiomyopathy is located on chromosome 14 (band q1).     

Multipoint mapping of adult onset polycystic kidney disease (PKD1) on chromosome 16.

Analysis of genetic linkage data in 33 adult onset polycystic kidney (ADPKD) families was carried out using probes for the D16S85, D16S84, and D16S94 loci. The data set of 33 families shows no evidence of genetic heterogeneity since one unlinked family was previously excluded. Two point linkage analysis showed maximum likelihood values of the recombination fraction of 0.07 for ADPKD and D16S85 (lod score 18.78), 0.02 for ADPKD and D16S84 (lod score 7.55), and 0.00 for ADPKD and D16S94 (lod score 6.73). Multipoint analysis showed a maximum likelihood order of tel-D16S85-0.06-D16S84-0.02-(PKD1, D16S94)-cen with a multipoint lod score of 32.16. Analysis of rare recombinants lying close to PKD1 gave results consistent with this order.     

Susceptibility gene for familial acute myeloid leukemia associated with loss of 5q and/or 7q is not localized on the commonly deleted portion of 5q

The molecular mechanism for the occurrence of leukemia in multiple members of a family has not been fully elucidated but data support the contribution of highly penetrant mutations in leukemia susceptibility genes. We have investigated the genetic etiology of an unusual three-generation family with apparent autosomal dominant transmission of acute myeloid leukemia (AML) and myelodysplastic syndrome (MDS) accompanied by somatic loss of the long arm of chromosome 5 and/or loss of heterozygosity (LOH) analysis and fluorescence in situ hybridization (FISH) of leukemia cells have been performed, confirming acquired hemi- and homozygous deletion of the long arm of chromosome 5. However, the chromosome lost in the observed LOH event is from the affected parent, in contradiction to the expectation for a two-hit hypothesis involving a tumor suppressor gene. Furthermore, genetic linkage has been performed at 5q31-33 as well as other loci (21q22 and 16q21-23.2) previously implicated in familial leukemia. In this family, linkage analysis excludes loci at 5q31-33 and 21q22, but localization to 16q21-23.2 cannot be excluded. We observed a maximum multipoint LOD score of 1.19 between marker D16S265 and D16S503 at 16q22 (P = 0.03), suggesting possible linkage to this locus. Considering this family and the previous 16q-linked family together, the linkage of a leukemia susceptibility gene to 16q22 achieved an LOD score of 3.63 at D16S265 with theta = 0. Thus, somatic deletion of the long arm of chromosome 5 appears as a necessary but surprisingly noncausative event for onset of AML and MDS in this family, thereby confirming a multistep etiology in which chromosome 5 plays an important secondary role.     

Linkage and association studies with C8A and C8B RFLPs on chromosome 1

Linkage relations for the C8A and C8B Bam HI RFLPs have been investigated. A peak lod score of 4·52 at recombination fraction zero was obtained between the two C8 genes. Combined with our previously obtained linkage data (Rogde et al. 1986) the maximum lod score is 7·53 at recombination fraction zero. The compiled C8-PGM1 linkage data from this and the previous study gave a maximum lod score of 22·02 at recombination fraction 0·11 (0·07–0·16) with no sex difference. A chromosome 1p reference marker, D1S57 , has been applied in this linkage study. A maximum lod score of 5·06 between the C8 cluster and D1S57 at θ= 0·18 (0·11–0·28) was recorded. The linkage analyses and triply informative families gave evidence that the C8 loci are situated about halfway between PGM1 and D1S57 on the short arm of chromosome 1. There was no evidence of allelic association between the C8A and C8B Bam HI RFLPs in 62 unrelated haplotypes.     

X-linked myotubular myopathy: a linkage study

Two families with the congenital X-linked infantile form of myotubular myopathy have been investigated by linkage analysis using markers from the X-chromosome. Linkage was found at the locus Xq28 (with DXS52). The analysis gave a peak lod score of 2.41 at the recombination fraction zero. Free recombinations (theta = 0.50) were seen using the markers DXS84, DXS14 and DXS146 from the p arm of the X-chromosome. Since the disorder is very rare, it is important to add cumulative linkage data from the few families that do exist.     

Bridging markers defining the map position of X linked hypophosphataemic rickets.

Hypophosphataemic rickets is commonly an X linked dominant hereditary disorder associated with a renal tubular defect in phosphate transport and bone deformities. The gene causing this disorder has been mapped to Xp22.31----p21.3 by using cloned human X chromosome sequences identifying restriction fragment length polymorphisms (RFLPs) in linkage studies of affected families. The hypophosphataemic rickets gene locus (HPDR) was previously mapped distal to the X linked polymorphic locus DXS41 (99.6) but its position in relation to the distal loci DXS43 (D2) and DXS85 (782) was not established. In order to obtain a precise mapping of the disease locus in relation to these genetic loci, additional affected families informative for these X linked markers have been investigated. The combined results from the two studies have established linkage with the loci DXS41 (99.6) and DXS43 (D2); peak lod score for DXS41 (99.6) = 7.35, theta = 0.09, and peak lod score for DXS43 (D2) = 4.77, theta = 0.16. Multilocus linkage analysis mapped the hypophosphataemic rickets gene distal to the DXS41 (99.6) locus and proximal to the DXS43 (D2) locus, thereby revealing two bridging genetic markers for the disease.     

Linkage of X-linked myopathy with excessive autophagy (XMEA) to Xq28

X-linked myopathy with excessive autophagy (XMEA, MIM 310440) is a rare inherited mild myopathy. We have used 32 polymorphic markers spanning the entire X chromosome to exclude most of the chromosome except the Xq28 region in a large XMEA family. Using three additional families for linkage analysis, we have obtained a significant two-point lod score with marker DXS1183 (Z = 2.69 at theta = 0). Multipoint linkage analysis confirmed the assignment of the disease locus with a maximal lod score of 2.74 obtained at recombination fraction zero. Linkage of XMEA to the Xq28 region is thus firmly established. In addition, we have ruled out the Emery-Dreifuss muscular dystrophy to be allelic with XMEA by direct sequencing of the emerin gene in three of our families.     

Autosomal dominant branchio-oto-renal syndrome--localization of a disease gene to chromosome 8q by linkage in a Dutch family.

Branchio-oto-renal syndrome (BOR) is an autosomal dominant disorder with variable clinical manifestations affecting branchial, renal and auditory development. Varying clinical expression of the disease between different families suggests that multiple loci may be involved. However, the possibility of genetic heterogeneity as the cause of clinical variability cannot be resolved until the gene(s) causing BOR syndrome are mapped. DNA from four generations of a family with autosomal dominant BOR syndrome have been typed with a series of genetic markers on the long arm of chromosome 8. Using two point linkage analysis, a significant lod score of Z = 4.0 at theta = 0.05 was obtained with the D8S165 microsatellite marker. Multipoint analyses with 8q markers place the gene for BOR between the markers D8S87 and D8S165.     

Linkage analysis of two Canadian families segregating for X linked spondyloepiphyseal dysplasia.

X linked spondyloepiphyseal dysplasia (SED) is caused by a growth defect of the vertebral bodies leading to characteristic changes in the vertebral bodies and a short trunk. The gene responsible for this disorder has previously been mapped to Xp22, with a maximum likelihood location between markers DXS16 and DXS92. We present linkage data using microsatellite markers on two Canadian X linked SED families, one of Norwegian descent and the other from Great Britain. In the Xp22 region, three recombination events have occurred in these families, two between markers DXS996 and DXS1043 and one between DXS999 and DXS989. One family shows a maximal lod score of 3.0 at theta = 0 with marker DXS1043 and the other family has a maximal lod score of 1.2 at theta = 0 with markers DXS1224 and DXS418. Both families therefore support the previously reported gene localisation.     

Confirmation of genetic linkage between atopic IgE responses and chromosome 11q13.

Genetic linkage between atopic IgE responses and chromosome 11q13 (D11S97) has been previously reported in a limited number of extended families. Difficulties of phenotyping in the older family members, poor family structure in some families, and genetic heterogeneity were proposed as possible explanations for the variability in lod scores. To test this finding a second linkage study of 64 young nuclear families was undertaken and gave a two point lod score of 3.8 at theta = 0.07 (assuming theta m = theta f). A test of genetic heterogeneity in the nuclear families shows that atopic IgE responses are linked to this locus in 60 to 100% of families (approximate 95% confidence limits).     

Linkage studies of Best''s macular dystrophy

Genetic linkage studies are presented for nine kindreds with Best's vitelliform macular dystrophy (BVMD). This condition is an autosomal dominant macular dystrophy with reduced penetrance and highly variable expressivity. Asymptomatic carriers were identified with electro-oculography, fundus photographs and fluorescein angiography. Blood and saliva specimens were obtained from informative family members and genotyped for 26 polymorphic genetic traits. No firm evidence was found for linkage between BVMD and 18 informative markers; the highest positive lod score was z = 0.57 for GPT1 at a recombination fraction of theta = 0.30. An atypical form of vitelliform macular dystrophy (VMD-1) is linked to GPT1 (theta less than 0.05) and is provisionally assigned to chromosome 16pter-p11. Our data are not sufficient to rule out loose linkage for GPT1 and BVMD. Thus we were not able to determine whether BVMD and VMD-1 are allelic mutations or separate genetic disorders. Additional linkage and gene mapping studies of these loci and BVMD (as well as other atypical forms of macular dystrophy) would be useful to further delineate these disorders.     

Linkage studies with the gene for an X-linked syndrome of mental retardation, microcephaly and spastic diplegia (MRX2)

A family in which a gene (MRX2) is segregating for an X-linked syndrome of mental retardation, short stature, microcephaly, brachycephaly, spastic diplegia, small testes and possible intra-uterine growth retardation is described. There are 7 clearly affected males and one possibly affected infant in the family. The obligate carriers are normal. Linkage studies show a suggestion of linkage to loci near the centromere. The maximum lod score was 2.10 at theta = 0.11 for DXYS1, assuming the possibly affected male carried the MRX2 gene. There were lower lod scores suggestive of linkage with DXS7 (theta = 0.14; z = 1.29) and DXS94 (theta = 0.11; z = 1.22).     

Linkage data for Marfan syndrome and markers on chromosomes 1 and 11.

Six large families with classical Marfan syndrome were studied using markers on chromosomes 1 and 11. Two of three families tested showed negative scores using D1S7 but a third family gave a positive score (0.92) at theta = 0.1. The other chromosome 1 markers typed (MUCI, NGFB, D1S8) excluded close linkage. Negative lod scores with two chromosome 11q22 markers (D11S84, D11S148) excluded at least 20 cM in this area (Z = less than -2), which was chosen for study as two enzymes responsible for collagen degradation (collagenase and stromelysin) are localised to this region.     

Mapping the gene for juvenile onset neuronal ceroid lipofuscinosis to chromosome 16 by linkage analysis

The ceroid-lipofuscinoses are a group of inherited neurodegenerative disorders characterised by the accumulation of autofluorescent lipopigment in neurones and other cell types. The underlying biochemical defect is unknown. Juvenile onset neuronal ceroidlipofuscinosis (Batten disease; Spielmeyer-Vogt disease) is an autosomal recessive trait. Linkage studies were undertaken to determine the location of the Batten disease (CLN3) mutation. Studies were carried out on 205 members of 42 families in which there were 76 affected individuals. Families originated from 7 North European countries and Canada. Serum samples from 23 families, including a total of 48 affected children, were tested for a set of “classical markers.” A positive lod score was found with the haptoglobin (Hp) system. The combined male and female maximum lod score was 3.00 at θ = 0.00 and θ = 0.26, respectively. This provided an indication of localisation to the long arm of chromosome 16. Linkage analysis was then carried out in 42 families using DNA markers for loci on human chromosome 16. The maximal lod score between Batten disease and the locus D16S148 calculated for combined sexes was 6.05. No recombinants were observed. Multilocus analysis using 5 loci indicated the most likely order to be HP–D16S151–D16S150–CLN3–D16S148–D16S147. Work is in progress to refine the genetic and physical localisation of the Batten disease gene using additional markers in this region and a panel of somatic cell hybrids. Methods are now available which should allow the gene to be isolated and characterised.     

Linkage analysis of neurofibromatosis (von Recklinghausen disease).

Linkage analysis of 28 genetic markers was undertaken in 108 subjects from 11 families with well-documented, classic, peripheral neurofibromatosis. Fifty-four persons were affected in one four-generation family, seven three-generation families, and three two-generation families. Lod scores were calculated using the standard LIPED programme for 49 combinations of theta male and theta female from 0.01 to 0.50. Lod scores excluded close linkage with 16 markers, including most tested on chromosome 1 and HLA on chromosome 6, and were inconclusive for 12 markers, including the secretor locus, closely linked to myotonic dystrophy. Analysis of five informative families resulted in a lod score of +2.2 for close linkage with GC on chromosome 4. However, the lod score for GC in the one additional informative family was negative, so that the final interpolated maximum was Z = 0.89 for theta male = 0.03, theta female = 0.28. Further studies are needed to evaluate this suggestion of linkage and possible genetic heterogeneity.     

Search for linkage to schizophrenia on the X and Y chromosomes

Markers for X chromosome loci were used in linkage studies of a large group of small families (n = 126) with at least two schizophrenic members in one sibship. Based on the hypothesis that a gene for schizophrenia could be X-Y linked, with homologous loci on both X and Y, our analyses included all families regardless of the pattern of familial inheritance. Lod scores were computed with both standard X-linked and a novel X-Y model, and sibpair analyses were performed for all markers examining the sharing of maternal alleles. Small positive lod scores were obtained for loci pericentromeric, from Xp11.4 to Xq12. Lod scores were also computed separately in families selected for evidence of maternal inheritance and absence of male to male transmission of psychosis. The lod score for linkage to the locus DXS7 reached a maximum of 1.83 at 0.08% recombination, assuming dominant inheritance on the X chromosome in these families (n = 34). Further investigation of the X-Y homologous gene hypothesis focussing on this region is warranted. © 1994 Wiley-Liss, Inc.     

Localization of the gene for progressive bifocal chorioretinal atrophy (PBCRA) to chromosome 6q

Progressive bifocal chorioretinal atrophy (PBCRA) is a rare,autosomal dominant congenital chorioretinal dystrophy. We haveperformed genetic linkage analysis on a five-generation BritishPedigree. Twopoint linkage analysis showed significant linkagewith nine microsatellite marker loci mapping to chromosome 6q.Multipoint analysis gave a maximum lod score of 11. 8 (     

Linkage studies in Duchenne and Becker muscular dystrophies.

We have studied the inheritance of four cloned DNA sequences which recognise restriction fragment length polymorphisms on the short arm of the X chromosome in families with Becker and Duchenne muscular dystrophy. We have confirmed linkage of two probe loci to the disease loci and have combined our results with those previously published to give a maximum lod score of 11.642 at a recombination fraction of 0.15 for DXS41 (probe 99.6), and a maximum lod of 15.84 at a recombination fraction of 0.15 for DXS84 (probe 754). Linkage of these diseases to the loci defined by the pERT87 probes and probe pXJ1.1 has also been studied, giving maximum lod scores of 8.634 and 5.118 at recombination fractions of 0.02 and 0.00 respectively. The information obtained using these polymorphic DNA markers, combined with pedigree and CK data, can be used to give more accurate genetic counselling to women at risk in Becker and Duchenne families.