Linkage relationships of the insulin receptor gene with the complement component 3, LDL receptor,apolipoprotein C2 and myotonic dystrophy loci on chromosome 19

Summary Myotonic dystrophy is associated with disturbances in the insulin response, possibly due to an abnormality of the insulin receptor. Both the myotonic dystrophy (DM) and insulin receptor (INSR) genes are on chromosome 19. Using a cloned gene probe for INSR, we have studied its linkage relationships with the DM locus and other chromosome 19 markers. The results show that INSR is not closely linked to DM, but is located very close to C3, in the region 19pter-19p13.2. This implies that the basic genetic defect which causes DM is not directly responsible for the disturbed insulin response in these patients.     

The locus for apolipoprotein CII is closely linked to the apolipoprotein E locus on chromosome 19 in man

Summary We have demonstrated close linkage between the genes for apolipoprotein E (apoE) and apolipoprotein CII (apoCII). Families segregating for apoE protein variants were screened for a DNA restriction fragment length polymorphism close to the apoCII gene by using an apoCII cDNA clone. The maximum lod score is 4.52 (sexes combined) at a recombination frequency of zero. Given linkage, it may be assumed that no recombinations have happened in altogether 33 observed meioses. It is therefore evident that the apoCII gene is situated on chromosome 19, close to the apoE gene.     

DNA polymorphism and linkage disequilibrium within the apolipoprotein CII locus on human chromosome 19.

The gene for human apolipoprotein CII (APOCII) is located on the proximal long arm of chromosome 19. It has been established as a closely linked marker for myotonic dystrophy (DM), the most common form of adult muscular dystrophy. In the present linkage study, we have analysed 6 APOCII RFLPs in 213 haplotypes: TaqI, 3.8/3.5 kb; BgII, 12.0/9.0 kb; BanI, 2.5/1.6 kb; BamHI, 6.0/4.9 kb; NcoI, 14.5/11.5 kb, and AvaII, 0.6/0.4 kb. The polymorphic enzyme sites were determined to be present at the following frequencies: TaqI, 0.43; BglI, 0.51; BanI, 0.25; BamHI, 0.99; NcoI, 0.51, and AvaII, 0.52. Ordering of the polymorphic sites, 5'----3', has been determined to be (NcoI-BglI)-AvaII-BanI-TaqI. Significant disequilibrium was seen between 5 of the APOCII RFLPs.     

Dimorphic markers for the human apolipoprotein CII gene locus

Two restriction-site polymorphisms (RSP) have been detected when using a human apolipoprotein CII (apoCII) cDNA clone as a hybridization probe. These include a BanI and a TaqI RSP. Frequencies of the more common allele have been determined in a German population of 100 individuals and are 0.66 (BanI RSP) and 0.56 (TaqI RSP). Corresponding polymorphic information content (PIC) values are 0.36 and 0.37 for individual sites, and 0.58 for the BanI-TaqI pair of sites, making this locus a very informative (PIC-rich) marker for this region of chromosome 19. Haplotype studies also indicate the presence of allelic association (linkage disequilibrium) at the human apoCII gene locus.     

The gene for human apolipoprotein CI is located 4.3 kilobases away from the apolipoprotein E gene on chromosome 19

Summary We have isolated a cDNA clone for apolipoprotein CI and a genomic clone for apolipoprotein E, and by hybridisation and mapping experiments found the gene for apoCI to be located on the genomic apoE clone. The distance between the loci was 4.3 kb.     

A physical map of the apolipoprotein gene cluster on human chromosome 19

Summary We have generated a restriction map around the cloned genes for human apolipoproteins CI, CII, and E by pulsed-field gel analysis. We show that the genes are clustered within an area of about 50 kb on chromosome 19. The genes are all oriented in the same direction, head to tail.     

Linkage disequilibrium of three polymorphic RFLP markers in the apolipoprotein AI-CIII gene cluster on chromosome 11

A panel of glial tumors consisting of 11 low grade gliomas, 9 anaplastic gliomas, and 29 glioblastomas were analyzed for loss of heterozygosity by examining at least one locus for each chromosome. The frequency of allele loss was highest among the glioblastomas, suggesting that genetic alterations accumulate during glial tumor development. The most common genetic alteration detected involved allele losses of chromosome 10 loci; these losses were observed in all glioblastomas and in three of the anaplastic gliomas. In order to delineate which chromosome 10 region or regions were deleted in association with glial tumor development, a deletion mapping analysis was performed, and this revealed the partial loss of chromosome 10 in eight glioblastomas and two of the anaplastic gliomas. Among these cases, three distinct regions of chromosome 10 were indicated as being targeted for deletion: one telomeric region on 10p and both telomeric and centromeric locations on 10q. These data suggest the existence of multiple chromosome 10 tumor suppressor gene loci whose inactivation is involved in the malignant progression of glioma.     

Linkage analysis of the apolipoprotein C2 gene and myotonic dystrophy on human chromosome 19 reveals linkage disequilibrium in a French-Canadian population.

The gene for human apolipoprotein C2 (APOC2), situated on the proximal long arm of chromosome 19, is closely linked to the gene for the most common form of adult muscular dystrophy, myotonic dystrophy (DM). Six APOC2 RFLPs (TaqI, BglI, BanI, BamHI, NcoI, and AvaII) have been identified to date. We have conducted a comprehensive DM linkage study utilizing all six RFLPs and involving 50 families and 372 individuals. The most informative RFLPs are, in descending order, NcoI (lod = 6.64, theta = 0.05), BglI (lod = 6.12, theta = 0.05), AvaII (lod = 6.02, theta = 0.03), BanI (lod = 5.76, theta = 0.04), TaqI (lod = 4.29, theta = 0.06), and BamHI (lod = 1.75, theta = 0.01). A substantial increase in the lod scores over those seen with the individual RFLPs was obtained when the linkage of the entire APOC2 haplotype (composed of the six RFLPs) was studied (lod = 17.87, theta = 0.04). We have observed significant inter-APOC2 RFLP linkage disequilibrium. Consequently, the three most informative RFLPs have been found to be BanI, TaqI, and either BglI, AvaII, or NcoI polymorphisms. We also demonstrate linkage disequilibrium between DM and APOC2 in our French-Canadian population (standardized disequilibrium constant phi = .22, chi 2 = 5.12, df = 1, P less than 0.04). This represents the first evidence of linkage disequilibrium between APOC2 and the DM locus.     

Localization of the Leptospira interrogans metF gene on the CII secondary chromosome

An open reading frame of 885 nucleotides was identified as the Leptospira interrogans metF gene. The deduced amino acid sequence (294 amino acids) showed similarities with Escherichia coli methylene tetrahydrofolate reductase (MetF or MTHFR) (33% identity) and with the N-terminal part of human MTHFR (33% identity). The L. interrogans metF gene complements an E. coli metF mutant to prototrophy, suggesting the functionality of the folate branch converging to form methionine. In addition, the L. interrogans MetF was found to be thermolabile. The metF gene belonged to the CII secondary chromosome, in contrast to the previously isolated metY and metX genes, which have been localized to the CI chromosome of Leptospira sp.     

Linkage relationships of the Wiskott-Aldrich syndrome to 10 loci in the pericentromeric region of the human X chromosome

Twelve families with Wiskott-Aldrich syndrome (WAS) were studied by linkage analysis using 10 polymorphic marker loci from the X-chromosome pericentromeric region. The results confirm close linkage of WAS to the DXS14, DXS7, TIMP, and DXZ1 loci and are consistent with previous data suggesting that WAS maps to the proximal Xp and is flanked by the DXS14 and DXS7 loci. The strongest linkage (Z = 10.19 at theta = 0.00) was found to be between WAS and the hypervariable DXS255 locus, a marker locus already mapped between DXS7 and DXS14 and which was informative for all meioses included in this analysis. Linkage of the WAS to two pericentromeric Xq loci, DXS1 and PGK1, was also established. On the basis of these results, accurate predictive testing should now be feasible in the majority of WAS families.     

Linkage relationships of the human methylmalonyl CoA mutase to the HLA and D6S4 loci on chromosome 6

The human methylmalonyl CoA mutase (MCM) cDNA has been used to localize the MUT locus on the short arm of chromosome 6 proximal to the glyoxalase locus in 6p deletion cell lines. A HindIII polymorphism identified by the MCM cDNA was used to study linkage relationships of MUT to HLA (A-B-DQ-DR) and D6S4 in the reference CEPH families. The maximum lod score for MUT versus HLA was 3.04 at a recombination fraction of 0.28. The maximum lod score for MUT versus D6S4 was 22.93 at a recombination fraction of 0.01. These data suggest that MUT and D6S4 loci are tightly linked and may be used as one locus in a haplotype form for linkage studies on proximal 6p and diagnostic analysis of pedigrees with mut methylmalonic acidemia.     

Linkage relationships among the malic enzyme,hexokinase-1, and red loci on the X chromosome of Tribolium confusum

Linkage data for the sex-linked malic enzyme (Me) and hexokinase-1 (Hk-1) loci in the flour beetle, Tribolium confusum, were obtained from a three-point experiment involving the red locus. The order of the three loci was determined to be red--Hk-1-Me, with map distances of 12.4 +/- 1.8 for red to Hk-1 and 7.0 +/- 1.3 for Hk-1 to Me.     

Linkage of typical pseudoachondroplasia to chromosome 19

Pseudoachondroplasia (PSACH) is an autosomal dominant dwarfing condition associated with disproportionate short stature, marked joint deformities, and early onset osteoarthritis. Previous linkage studies have excluded linkage to cartilage and noncartilagenous extracellular matrix candidate genes. Here, we report mapping the pseudoachondroplasia gene to chromosome 19. Maximum lod scores of 4.70, 4.15, and 4.86 at θ - 0.00 were found for D19S212, D19S215, and D19S49, respectively. Multipoint analysis suggests the following order: D19S253-D19S199-(D19S212/PSACH/Dl9S215)-D19S222-D19S49.