Five polymorphic microsatellite VNTRs on the human X chromosome

The human genome contains approximately 50,000 copies of an interspersed repeat with the sequence (dT.dG/dA.dC)n, where n = approximately 10-60. We and others have found that several of these repeats have variable lengths in different individuals, with allelic fragments varying in size by multiples of 2 bp. These "microsatellite" variable number of tandem repeats (VNTRs) may be scored by PCR, using unique flanking primers to amplify the repeat-containing regions and resolving the products on DNA sequencing gels. Since few VNTRs have been found on the X chromosome, we screened a flow-sorted X chromosome-specific genomic library for microsatellites. Approximately 25% of the phage clones hybridized to a poly (dT-dG).poly(dA-dC) probe. Of seven X-linked microsatellites present in positive phages, five are polymorphic and three have both eight or more alleles and heterozygosities exceeding 75%. Using PCR to amplify genomic DNAs from hybrid cell panels, we confirmed the X localization of these VNTRs and regionally mapped four of them. The fifth VNTR was regionally mapped by virtue of its tight linkage to DXS87 in Centre du Polymorphisme Humain families. We conclude that whatever factors limit the occurrence of "classical" VNTRs and RFLPs on the X chromosome do not appear to operate in the case of microsatellite VNTRs.     

VNTR and microsatellite polymorphisms within the subtelomeric region of 7q.

The molecular basis of a highly polymorphic RFLP marker, HTY146c3 (D7S591), within the subtelomeric region of human chromosome 7q was determined by restriction-fragment and DNA sequence analysis. Two polymorphic systems were found--a simple base-substitution polymorphism and a GC-rich VNTR element with a core structure of C3AG2C2. In addition, a compound-imperfect CA dinucleotide-repeat element was identified approximately 10-20 kb from the telomeric sequence repeat (T2AG3), demonstrating that microsatellites can extend essentially to the ends of human chromosomes. The microsatellite marker, sAVH-6 (D7S594), is highly polymorphic, with 10 alleles and an observed heterozygosity of 84% found with the CEPH (Centre d'Etude du Polymorphisme Humain) reference pedigree collection. In combination with the RFLPs, the informativeness of the markers contained within 240 kb at the telomere approaches 100%. A unique genetic and physical STS marker, sAVH-6, defines the endpoint of the long arm of human chromosome 7.     

Linkage mapping of human chromosome 10 microsatellite polymorphisms.

Ten microsatellite DNA polymorphisms located on human chromosome 10 were regionally mapped using subchromosomal somatic cell hybrids and linkage analysis. The resulting order of the markers from pter-qter was [D10S89, D10S111], D10S107, D10S109, [D10S91, D10S110, D10S108, D10S88, D10S168], and D10S169. Order of the markers within brackets was uncertain, although the order given was most likely. The microsatellites were distributed along the chromosome from the proximal p arm to near qter, with an unlinked gap between D10S168 and D10S169.     

Linkage map of human chromosome 9 microsatellite polymorphisms.

Ten microsatellite markers composed of polymorphic (CA)n or (AAAT)n repeats were mapped to chromosome 9. PIC values for these markers ranged from 0.46 to 0.82. The marker at the D9S54 locus was localized to 9pter-p22 by means of a somatic cell hybrid; another marker at D9S103 was similarly localized to 9q34-qter. Two-point lod scores and individual meiotic recombination events were used to position the 10 markers relative to each other. The best order resulting from these analyses was D9S54-D9S104-[D9S52-D9S43-D9S50]-D9S53+ ++- [D9S106-D9S105]-D9S51-D9S103, with order of the loci within brackets uncertain. Two-point linkage analysis was also used to approximate the positions of the microsatellite markers relative to those of 33 markers contained in the public CEPH database (v.3) and to one other available microsatellite marker at the D9S15 locus.     

Regional localization of the LCA oncogene to human chromosome region 2q14----q21

A novel human oncogene, LCA, was assigned to region 2q14----q21 by in situ molecular hybridization. The present regional mapping substantiates the previous assignment that was performed by Southern blot analyses of DNAs from flow-sorted human chromosomes and human-mouse somatic cell hybrids.     

Mapping of human chromosome 5 microsatellite DNA polymorphisms.

Thirteen moderately to highly informative microsatellite DNA polymorphisms based on (dC-dA)n.(dG-dT)n repeats were mapped to segments of human chromosome 5 using both linkage analysis and a panel of somatic cell hybrids which contained rearranged chromosomes. The markers were distributed throughout most of the length of the chromosome from the regions p15.3-p15.1 to q33.3-qter. Maps of the sites of meiotic recombination within the reference families proved particularly useful for the purpose of integrating new polymorphisms into the existing linkage map.     

Identification of a haplosufficient 3.6-Mb region in human chromosome 11q14.3-->q21

Cytogenetic deletions are almost always associated with phenotypic abnormality and are very rarely transmitted. We have located a hitherto undescribed, familial deletion involving the region 11q14.3-->q21 in five individuals in a three-generation kindred. Four of the deletion carriers show no phenotypic abnormality; the other, who is the proband, was investigated for short stature and poor academic progress. In view of the apparent innocuous nature of this genetic imbalance, the deletion was investigated in detail to determine its size (3.6 Mb) and location with reference to molecular markers and genetic content. The deleted region is described by a contig of 37 BACS including the flanking regions, which we have assembled. Several possible contributory factors are considered, which might explain the lack of clinical significance of this large deletion. It is notable that there are few genes in this region and none have known functions. All most likely have copies elsewhere in the genome and a number of other hypothetical genes appear to be members of certain gene families, i.e. none is unique. Part of the region (1 Mb) is also duplicated at the pericentromeric region 11p11. Given the very low proportion of the genome occupied by single copy genes and their uneven distribution, regions such as this, which appear to be functionally haplosufficient, may be more common than hitherto recognised.     

Bovine Y chromosome microsatellite polymorphisms

Thirty-eight bovine Y chromosome (BTAY) microsatellites (MS) were assessed for polymorphisms in DNA samples obtained from 17 unrelated bulls. Thirty-three of these microsatellites are new and were used for the construction of a first generation radiation hybrid map for BTAY (Liu et al., 2002). Five MS had been previously reported and were used as positive controls. Fourteen out of 38 MS were found to be polymorphic; the remaining 24 were uninformative among the animals tested. The number of hemizygous loci per MS within individual ranged from two to over 20. Seven MS presented smear- or ladder-like bands, a unique feature for Y chromosome multi-copy hemizygous MS loci. The locus length variance, within individual, ranged from 2 to 42 bp corresponding to the MS with the minimum and maximum number of loci observed, respectively. Within the 14 polymorphic MS, the five pseudoautosomal MS, on average, were more polymorphic (35.3%) than the nine Y-specific MS (19.6%). Haplotypes resulting from combinations of these polymorphic loci will provide a powerful tool for future studies on the origin of domestic cattle and the evolution of bovid species.     

Evidence for a new Graves disease susceptibility locus at chromosome 18q21

Graves disease (GD) is a common autoimmune thyroid disorder that is inherited as a complex multigenic trait. By using a single microsatellite marker at each locus, we screened the type 1 diabetes loci IDDM4, IDDM5, IDDM6, IDDM8, and IDDM10 and the fucosyltransferase-2 locus for linkage in sib pairs with GD. This showed a two-point nonparametric linkage (NPL) score of 1.57 (P=.06) at the IDDM6 marker D18S41, but NPL scores were <1.0 at the other five loci. Thus, the investigation of the IDDM6 locus was extended by genotyping 11 microsatellite markers spanning 48 cM across chromosome 18q12-q22 in 81 sib pairs affected with autoimmune thyroid disease (AITD). Multipoint analysis, designating all AITD sib pairs as affected, showed a peak NPL score of 3.46 (P=.0003), at the marker D18S487. Designation of only GD cases as affected (74 sib pairs) showed a peak NPL score of 3.09 (P=.001). Linkage to this region has been demonstrated in type 1 diabetes (IDDM6), rheumatoid arthritis, and systemic lupus erythematosus, which suggests that this locus may have a role in several forms of autoimmunity.     

A compositional map of the cen-q21 region of human chromosome 21

A compositional map of the centromere and of the subcentromeric region of the long arm of human chromosome 21 was established by determining the GC levels (GC is the molar fraction of guanine+cytosine in DNA) of 11 YACs (yeast artificial chromosomes) covering this 13–14 Mb region which extends from the α-satellite sequences of the C(entromeric) band qll.1, through R(everse) band q11.2, to the proximal part of G(iemsa) band q21. The entire region is made up of GC-poor, or L, isochores with only one GC-rich H1 isochore, at least 2 Mb in size, located in band q21. The almost identical GC levels of the centromeric α-satellite repeats (38.5%), of R band q11.2 (39%), and of G bands (38–40%) provide a direct demonstration that base composition cannot be the only cause of the cytogenetic differences between C, G, and the majority of R bands, namely the H3^- R bands (which do not contain the GC-richest H3 isochores). The results obtained also show that isochores may be as long as 6 Mb, at least in the GC-poor regions of the genome, and support previous observations suggesting that YACs from isochore borders are unstable and/or difficult to clone. Genes and CpG islands are very rare in the GC-poor region investigated, as expected from the fact that their concentration is proportional to the GC levels of the isochores in which they are contained.     

Large-scale mapping and chromosome jumping in the q27 region of the human X chromosome

We have used pulsed field gel electrophoresis for further physical mapping studies in the q27 region of the human X chromosome. We show that the DXS 102 locus and the F9 gene are separated by only 300 kb despite a genetic distance of 1.4 cM; this linkage orients our large-scale map and shows that the mcf.2 transforming sequence is telomeric to F9. A BssHII complete-digest jumping library was used to jump toward the DXS 105 locus; a 130-kb jump was achieved and the corresponding "linking clone" was obtained.     

Establishment of the mouse chromosome 7 region with homology to the myotonic dystrophy region of human chromosome 19q

A number of genetic markers, including ATP1A3, TGFB, CKMM, and PRKCG, define the genetic region on human chromosome 19 containing the myotonic dystrophy locus. These and a number of other DNA probes have been mapped to mouse chromosome 7 utilizing a mouse Mus domesticus/Mus spretus interspecific backcross segregating for the genetic markers pink-eye dilution (p) and chinchilla (cch). The establishment of a highly syntenic group conserved between mouse chromosome 7 and human chromosome 19q indicates the likely position of the homologous gene locus to the human myotonic dystrophy gene on proximal mouse chromosome 7. In addition, we have mapped the muscle ryanodine receptor gene (Ryr) to mouse chromosome 7 and demonstrated its close linkage to the Atpa-2, Tgfb-1, and Ckmm cluster of genes. In humans, the malignant hyperthermia susceptibility locus (MHS) also maps close to this gene cluster. The comparative mapping data support Ryr as a candidate gene for MHS.     

A new human brain cDNA molecule: assignment to chromosome 11q21-q23.1 and description of two polymorphisms studied by the polymerase chain reaction

A new human brain cDNA molecule was mapped by in situ hybridization to the 11q21-q23.1 region of the human genome, probably to the 11q22 band. An EcoRI restriction site and a (GT) _n repeat element within the gene were shown to be polymorphic. Both polymorphisms were readily studied by the polymerase chain reaction. A two-allele polymorphism was described for the EcoRI restriction site, whereas four different alleles were detected for the second genetic marker. The observed heterozygosities were 37% and 42% for the former and the latter polymorphism, respectively. The combined heterozygosity index was estimated to be 0.56. These new genetic markers will be useful for linkage analysis of neurogenetic diseases that have been mapped to this chromosomal region.     

Identification of polymorphisms by genomic denaturing gradient gel electrophoresis: application to the proximal region of human chromosome 21.

Genomic Denaturing Gradient Gel Electrophoresis (gDGGE) provides an alternative to the standard method of restriction fragment length polymorphism (RFLP) analysis for identifying polymorphic sequence variation in genomic DNA. For gDGGE, genomic DNA is cleaved by restriction enzymes, separated in a polyacrylamide gel containing a gradient of DNA denaturants, and then transferred by electroblotting to nylon membranes. Unlike other applications of DGGE, gDGGE is not limited by the size of the probe and does not require probe sequence information. gDGGE can be used in conjunction with any unique DNA probe. Here we use gDGGE with probes from the proximal region of the long arm of human chromosome 21 to identify polymorphic DNA sequence variation in this segment of the chromosome. Our screening panel consisted of DNA from nine individuals, which was cleaved with five restriction enzymes and submitted to electrophoresis in two denaturing gradient conditions. We detected at least one potential polymorphism for nine of eleven probes that were tested. Two polymorphisms, one at D21S4 and one at D21S90, were characterized in detail. Our study demonstrates that gDGGE is a fast and efficient method for identifying polymorphisms that are useful for genetic linkage analysis.