A primary genetic map of the pericentromeric region of the human X chromosome

We report a genetic linkage map of the pericentromeric region of the human X chromosome, extending from Xp11 to Xq13. Genetic analysis with five polymorphic markers, including centromeric alpha satellite DNA, spanned a distance of approximately 38 cM. Significant lod scores were obtained with linkage analysis in 26 families from the Centre d'Etude du Polymorphisme Humain, establishing estimates of genetic distances between these markers and across the centromere. Physical mapping experiments, using a panel of somatic cell hybrids segregating portions of the X chromosome due to translocations or deletions, are in agreement with the multilocus linkage analysis and indicate the order Xp11 . . . DXS7(L1.28)-TIMP- DXZ1(alpha satellite, cen)- DXS159(cpX73)-PGK1 . . . Xq13. The frequency of recombination in the two approximately 20-cM intervals flanking alpha satellite on either chromosome arm was roughly proportional to the estimated physical distance between markers; no evidence for a reduced crossover frequency was found in the intervals adjacent to the centromere. However, significant interfamilial variations in recombination rates were noted in this region. This primary map should be useful both as a foundation for a higher resolution centromere-based linkage map of the X chromosome and in the localization of genes to the pericentromeric region.     

Alphoid DNA polymorphisms for chromosome 21 can be distinguished from those of chromosome 13 using probes homologous to both.

Although alphoid DNA sequences shared among acrocentric chromosomes have been identified, no human chromosome 21-specific sequence has been isolated from the centromeric region. To identify alphoid DNA restriction fragment length polymorphisms (RFLPs) specific for chromosome 21, we hybridized human genomic DNA with alphoid DNA probes [L1.26; aRI(680),21-208] shared by chromosomes 13 and 21. We detected RFLPs with restriction enzymes ECoRI, HaeIII, MboI,StuI, and TaqI. The segregation of these RFLPs was analyzed in the 40 CEPH families. Linkage analysis between these RFLPs and loci previously mapped to either chromosome 13 or 21 revealed RFLPs that appear to be specific to chromosome 21. These polymorphisms may be useful as genetic markers of the centromeric region of chromosome 21. Different alphoid loci within the centromeric region of chromosome 13 were identified.     

A refined linkage map for DNA markers around the pericentromeric region of chromosome 10

A refined genetic linkage map for the pericentromeric region of human chromosome 10 has been constructed from data on 12 distinct polymorphic DNA loci as well as the locus for multiple endocrine neoplasia type 2A (MEN 2A), a dominantly inherited cancer syndrome. The map extends from D10S24 (at 10p13-p12.2) to D10S3 (at 10q21-q23) and is about 70 cM long. Overall, higher female than male recombination frequencies were observed for this region, with the most remarkable female excess in the immediate vicinity of the centromere, as previously reported. Most of the DNA markers in this map are highly informative for linkage and the majority of the interlocus intervals are no more than 6 cM apart. Thus this map should provide a fine framework for future efforts in more detailed mapping studies around the centromeric area. A set of ordered cross-overs identified in this work is a valuable resource for rapidly and accurately localizing new DNA clones isolated from the pericentromeric region.     

Flanking markers for the gene causing von Recklinghausen neurofibromatosis (NF1)

The defective gene causing von Recklinghausen neurofibromatosis (NF1), one of the most common inherited disorders affecting the human nervous system, was recently mapped to chromosome 17. We have used additional DNA markers to further narrow and bracket the NF1 defect. A multipoint linkage analysis suggests that the NF1 gene is flanked by D17Z1 on the centromeric side and by EW 207 on the telomeric side of the long arm of chromosome 17. The identification of closely linked flanking markers should allow us to develop a reliable prenatal and presymptomatic diagnostic test for this serious neurological disorder and provides the basis for applying chromosome-specific cloning techniques for the isolation and characterization of the mutant gene.     

A molecular genetic linkage map of mouse chromosome 13 anchored by the beige (bg) and satin (sa) loci

A molecular genetic linkage map of mouse chromosome 13 was constructed using cloned DNA markers and interspecific backcross mice from two independent crosses. The map locations of Ctla-3, Dhfr, Fim-1, 4/12, Hexb, Hilda, Inhba, Lamb-1.13, Ral, Rrm2-ps3, and Tcrg were determined with respect to the beige (bg) and satin (sa) loci. The map locations of these genes confirm and extend regions of homology between mouse chromosome 13 and human chromosomes 5 and 7, and identify a region of homology between mouse chromosome 13 and human chromosome 6. The molecular genetic linkage map of chromosome 13 provides a framework for establishing linkage relationships between cloned DNA markers and known mouse mutations and for identifying homologous genes in mice and humans that may be involved in disease processes.     

A radiation hybrid map of 48 loci including the clouston hidrotic ectodermal dysplasia locus in the pericentromeric region of chromosome 13q

To facilitate the identification of the gene responsible for Clouston hidrotic ectodermal dysplasia (HED), we used a chromosome 13-specific radiation hybrid panel to map 54 loci in the HED candidate region. The marker retention data were analyzed using RHMAP version 3. The 54 markers have an average retention frequency of 31.6% with decreasing retention as a function of distance from the centromere. Two-point analysis identified three linkage groups with a threshold lod score of 4.00; one linkage group consisted of 49 loci including the centromeric marker D13Z1 and the telomeric flanking marker for the HED candidate region D13S143. Assuming a centromeric retention model, multipoint maximum likelihood analysis of these 49 loci except D13Z1 provided a 1000:1 framework map ordering 29 loci with 21 unique map positions and approximately 2000 times more likely than the next order. Loci that could not be ordered with this level of support were positioned within a range of adjacent intervals. This map spans 347 cR9000, has an average resolution of 17.3 cR9000, and includes 3 genes (TUBA2, GJbeta2, and FGF-9), 18 ESTs, 19 polymorphic loci, and 8 single-copy DNA segments. Comparison of our RH map to a YAC contig showed an inconsistency in order involving a reversed interval of 6 loci. Fiber-FISH and FISH on interphase nuclei analyses with PACs isolated from this region supported our order. We also describe the isolation of 8 new chromosome 13q polymorphic (CA)n markers that have an average PIC value of 0.67. These data and mapping reagents will facilitate the isolation of disease genes from this region.     

Genetic linkage map of human chromosome 21

Two of the most common disorders affecting the human nervous system, Down syndrome and Alzheimer's disease, involve genes residing on human chromosome 21. A genetic linkage map of human chromosome 21 has been constructed using 13 anonymous DNA markers and cDNAs encoding the genes for superoxide dismutase 1 (SOD1) and the precursor of Alzheimer's amyloid beta peptide (APP). Segregation of restriction fragment length polymorphisms (RFLPs) for these genes and DNA markers was traced in a large Venezuelan kindred established as a "reference" pedigree for human linkage analysis. The 15 loci form a single linkage group spanning 81 cM on the long arm of chromosome 21, with a markedly increased frequency of recombination occurring toward the telomere. Consequently, 40% of the genetic length of the long arm corresponds to less than 10% of its cytogenetic length, represented by the terminal half of 21q22.3. Females displayed greater recombination than males throughout the linkage group, with the difference being most striking for markers just below the centromere. Definition of the linkage relationships for these chromosome 21 markers will help refine the map position of the familial Alzheimer's disease gene and facilitate investigation of the role of recombination in nondisjunction associated with Down syndrome.     

Isolation of a polymorphic genomic clone from chromosome 7

Summary A peptide prepared from purified factor 13B (F13B) was sequenced, and a single, long oligonucleotide corresponding to its cognate DNA sequence was constructed and used to screen a chromosome 7 specific genomic library. The positive clone isolated, designated pKV13, was only related to F13B at the oligonucleotide region, but has proved to be a valuable chromosome 7 marker. pKV13 maps to 7pter-q22 in hybrid cell lines, and is present in a chromosome-mediated gene transfer (CMGT) cell line that also contains met and other 7q probes. pKV13 defines a common MspI restriction fragment length polymorphism (RFLP), and is genetically linked to two markers on the long arm of chromosome 7, B79a and COL1A2, both themselves linked to the cystic fibrosis locus. Multipoint linkage analysis demonstrates that KV13 maps centromeric to both B79a and COLIA2. pKV13 has been used to demonstrate the existence of rearrangements within CMGT hybrisd, and will also prove valuable in multipoint linkage studies of other 7q markers. Finally, pKV13 provides a new polymorphic locus for the characterisation of 7q deletions in myeloid disorders such as myelodysplastic syndrome.     

Mapping of 262 DNA markers into 24 intervals on human chromosome 11.

We have extended our mapping effort on human chromosome 11 to encompass a total of 262 DNA markers, which have been mapped into 24 intervals on chromosome 11; 123 of the markers reveal RFLPs. These clones are scattered throughout the chromosome, although some clustering occurs in R-positive bands (p15.1, p11.2, q13, and q23.3). Fifty-two of the markers were found to contain DNA sequences conserved in Chinese hamster, and some of these 52 also cross-hybridized with DNA from other mammals and/or chicken. As the length of chromosome 11 is estimated at nearly 130 cM, the average distance between RFLP markers is roughly 1 cM. The large panel of DNA markers on our map should contribute to investigations of hereditary diseases on this chromosome, and it will also provide reagents for constructing either fine-scale linkage and physical maps or contig maps of cosmids or yeast artificial chromosomes.     

Isolation and analysis of DNA markers specific to human chromosome 15.

Chromosome-specific DNA markers provide a powerful approach for studying complex problems in human genetics and offer an opportunity to begin understanding the human genome at the molecular level. The approach described here for isolating and characterizing DNA markers specific to human chromosome 15 involved construction of a partial chromosome-15 phage library from a human/Chinese hamster cell hybrid with a single human chromosome 15. Restriction fragments that identified unique- and low-copy loci on chromosome 15 were isolated from the phage inserts. These fragments were regionally mapped to the chromosome by three methods, including Southern analysis with a mapping panel of cell hybrids, in situ hybridization to metaphase chromosomes, and quantitative hybridization or dosage analysis. A total of 42 restriction fragments of unique- and low-copy sequences were identified in 14 phage. The majority of the fragments that have been characterized so far exhibited the hybridization pattern of a unique locus on chromosome 15. Regional mapping assigned these markers to specific locations on chromosome 15, including q24-25, q21-23, q13-14, q11-12, and q11. RFLP analysis revealed that several markers displayed polymorphisms at frequencies useful for genetic linkage analysis. The markers mapped to the proximal long arm of chromosome 15 are particularly valuable for the molecular analysis of Prader-Willi syndrome, which maps to this region. Polymorphic markers in this region may also be useful for definitively establishing linkage with one form of dyslexia. DNA probes in this chromosomal region should facilitate molecular structural analysis for elucidation of the nature of instability in this region, which is frequently associated with chromosomal aberrations.     

Isolation and mapping of 88 new RFLP markers on human chromosome 8.

To obtain new RFLP markers for construction of a high-resolution map of human chromosome 8, a cosmid library was constructed from a somatic hybrid cell that contained chromosome 8 as the only human component in mouse genomic background. Eighty-eight new RFLP markers were isolated and characterized, and 71 of them were sublocalized to chromosomal bands by fluorescent in situ hybridization (FISH). Of these, 36 were localized to the short arm, 34 to the long arm, and 1 to the centromeric region. Five markers defined VNTR loci. This work represents the first extensive isolation and physical mapping of RFLP markers on human chromosome 8. These new markers will serve as useful resources for linkage mapping of loci for inherited diseases and for efforts to identify a putative tumor suppressor gene(s) on chromosome 8.     

Assignment of autosomal dominant spinocerebellar ataxia (SCA1) centromeric to the HLA region on the short arm of chromosome 6, using multilocus linkage analysis.

A 7-generation kindred with the HLA-linked form of spinocerebellar ataxia (SCA1) was studied to determine whether the SCA1 gene maps centromeric or telomeric to the HLA loci. The DNA markers flanking the HLA-(A-B) region were used for polymorphism studies and multilocus linkage analysis. These two markers are the cDNA for the beta-subunit of HLA-DP, which is centromeric to HLA-(A-B), and the cDNA for coagulation factor XIIIa (F13A), which is telomeric to HLA-(A-B). Haplotypes were constructed using multiple polymorphisms for these two DNA markers, and pairwise linkage analysis revealed a maximum lod score of 2.18 for SCA1 versus HLA-DP at a recombination fraction of .05 and a maximum lod score of 0 for SCA1 versus F13A at a recombination fraction of .50. A possible crossover between HLA-(A-B) and HLA-DP was identified, but lack of samples from key individuals hampered the analysis. To clarify the phase and improve the analysis, the two chromosomes 6 for the crossover individual were separated in somatic cell hybrids. The results strongly favored the probability that the crossover occurred between HLA-(A-B-DR) and HLA-DP with SCA1 segregating with HLA-DP, consistent with a location centromeric to HLA-(A-B). Multilocus linkage analysis was used to evaluate further the location of SCA1 relative to F13A, HLA-(A-B), and HLA-DP; the results indicated that the SCA1 gene locus is centromeric to HLA-DP with odds of 46:1 favoring this most likely location over the second most likely location, i.e., telomeric to HLA-(A-B) between the HLA complex and F13A.     

The use of DNA hybridization in situ for identifying chromosomal rearrangements in the karyotyping of cell lines]

A complex karyological analysis of three human cell lines (PLC-PRF-5, MT-4 and U937) was carried out that involved traditional methods of G-, C-banding and silver staining, in addition to the in situ hybridization technique using 4 alpha-satellite DNA probes: DNA specific for centromeric regions of chromosome 11, 6, 13, and 21, and 14 and 22. The application of this additional method allowed to identify, prove or detalize the structure of 13 markers in PLC-PRF-5 cells, 1 marker in MT-4 cells, and 3 markers in U937 cells. The results show that the in situ hybridization method would be successful in cell line karyotyping for a more objective identification of some markers difficult for analysis.     

Localization of new, microdissection- generated, anonymous markers and of the genes Pcsk1, Dhfr, Ndub13, and Ccnb1 to rat chromosome region 2q1

The centromeric region of rat chromosome 2 (2q1) harbors unidentified quantitative trait loci of genes that control tumor growth or development. To improve the mapping of this chromosome region, we microdissected it and generated 10 new microsatellite markers, which we included in the linkage map and/or radiation hybrid map of 2q1, together with other known markers, including four genes: Pcsk1 (protein convertase 1), Dhfr (dihydrofolate reductase), Ndub13 (NADH ubiquinone oxidoreductase subunit b13), and Ccnb1 (cyclin B1). To generate anchor points between the different maps, the gene Ndub13 and the microsatellite markers D2Ulb25 and D2Mit1 were also localized cytogenetically. The radiation map generated in region 2q1 extends its centromeric end of about 150 cR.     

A high-resolution comparative radiation hybrid map of ovine chromosomal regions that are homologous to human chromosome 6 (HSA6)

In this study, we constructed high-resolution radiation hybrid (RH) and comparative maps of ovine chromosomes or chromosomal segments that are homologous to human chromosome 6 (HSA6). A total of 251 markers were successfully genotyped across the recently developed USUoRH5000 whole-genome panel; 208 of these markers were assigned to five RH linkage groups distributed on three ovine chromosomes (OAR8, 9 and 20). The RH maps have good correspondence with previous chromosome painting data, although a small centromeric region on OAR9 that is homologous to HSA6 had not been previously detected using human chromosome paints on ovine chromosomal spreads. High percentages of the ovine markers were identified as orthologues in the bovine (86.3%), dog (85.8%), horse (69.3%) and human (88.7%) genomes. These maps contribute to investigations in mammalian chromosome evolution and the search for economic trait loci in sheep.     

Structural organization and polymorphism of the alpha satellite DNA sequences of chromosomes 13 and 21 as revealed by pulse field gel electrophoresis

Summary More than 30 unrelated individuals were analysed by pulse field gel electrophoresis for the alphoid centromeric sequences of chromosomes 13 and 21. These individuals had DNA patterns all different from each other and were most probably heterozygous at both loci. When several nuclear families were analysed in this manner, segregation was shown to be Mendelian, and no recombination event was detected over the 150 meioses scored in this study. Alphoid DNA sequences, therefore, constitute highly polymorphic centromeric markers, which can be used in linkage analysis for loci close to the centromeres of chromosomes 13 and 21.     

Molecular mapping of the centromeres of tomato chromosomes 7 and 9

The centromeres of two tomato chromosomes have been precisely localized on the molecular linkage map through dosage analysis of trisomic stocks. To map the centromeres of chromosomes 7 and 9, complementary telo-, secondary, and tertiary trisomic stocks were used to assign DNA markers to their respective chromosome arms and thus to localize the centromere at the junction of the short and long arms. It was found that both centromeres are situated within a cluster of cosegregating markers. In an attempt to order the markers within the centric clusters, genetic maps of the centromeric regions of chromosomes 7 and 9 were constructed from F₂ populations of 1620Lycopersicon esculentum × L. pennellii (E × P) plants and 1640L. esculentum × L. pimpinellifolium (E × PM) plants. Despite the large number of plants analyzed, very few recombination events were detected in the centric regions, indicating a significant suppression of recombination at this region of the chromosome. The fact that recombination suppression is equally strong in crosses between closely related (E × PM) and remotely related (E × P) parents suggests that centromeric suppression is not due to DNA sequence mismatches but to some other mechanism. The greatest number of centromeric markers was resolved in theL. esculentum × L. pennellii F₂ population. The centromere of chromosome 7 is surrounded by eight cosegregating markers: three on the short arm, five on the long arm. Similarly, the centric region of chromosome 9 contains ten cosegregating markers including one short arm marker and nine long arm markers. The localization of centromeres to precise intervals on the molecular linkage map represents the first step towards the characterization and ultimate isolation of tomato centromeres.     

Extensive sequence polymorphisms associated with chromosome 10 alpha satellite DNA and its close linkage to markers from the pericentromeric region

Summary Extensive sequence polymorphisms exist in the chromosome 10 alpha satellite DNA (the D10Z1 locus). Polymorphic morphs revealed by the enzymes PstI, EcoRV, and HincII, can be unambiguously scored and make this centromeric region an excellent genetic marker for the study of multiple endocrine neoplasia, type 2A (MEN2A), as well as for chromosome 10 linkage studies in general. Strong positive lod scores and linkage distance relationships between D10Z1 and DNA markers from the chromosome 10 pericentromeric region, especially FNRB and RBP3, known to be on either side of the centromere, provide independent support for mapping of all these loci.     

A degenerate alpha satellite probe, detecting a centromeric deletion on chromosome 21 in an apparently normal human male, shows limitations of the use of satellite DNA probes for interphase ploidy analysis.

A degenerate alpha satellite DNA probe specific for a repeated sequence on human chromosomes 13 and 21 was synthesized using the polymerase chain reaction (PCR). Fluorescence in situ hybridization (FISH) with this probe to normal metaphase spreads revealed strong probe binding to the centromeric regions of human chromosomes 13 and 21 with negligible cross-hybridization with other chromosomes. FISH to normal interphase cell nuclei showed four distinct domains of probe binding. However, hybridization with probe to interphase and metaphase preparations from one apparently normal human male resulted in only three major binding domains. Metaphase chromosome analysis revealed a centromeric deletion on one chromosome 21 that caused greatly reduced probe binding. The result suggest caution in the interpretation of interphase ploidy studies performed with chromosome-specific alphoid DNA probes.     

PCR amplification of chromosome-specific alpha satellite DNA: definition of centromeric STS markers and polymorphic analysis.

Alpha satellite DNA is a tandemly repetitive DNA family found at the centromere of every human chromosome. Chromosome-specific subsets have been isolated for over half the chromosomes and have prove useful as markers for both genetic and physical mapping. We have developed specific oligonucleotide primer sets for polymerase chain reaction (PCR) amplification of alpha satellite DNA from chromosomes 3, 7, 13/21, 17, X, and Y. For each set of primers, PCR products amplified from human genomic DNA are specific for the centromere of the target chromosome(s), as shown by somatic cell hybrid mapping and by fluorescence in situ hybridization. These six subsets represent several evolutionarily related alpha satellite subfamilies, suggesting that specific primer pairs can be designed for most or all chromosomal subsets in the genome. The PCR products from chromosome 17 directly reveal the polymorphic nature of this subset, and a new DraI polymorphism is described. The PCR products from chromosome 13 are also polymorphic, allowing in informative cases genetic analysis of this centromeric subset distinguished from the highly homologous chromosome 21 subset. These primer sets should allow placement of individual centromeres on the proposed STS map of the human genome and may be useful for somatic cell hybrid characterization and for making in situ probes. In addition, the ability to amplify chromosome-specific repetitive DNA families directly will contribute to the structural and functional analysis of these abundant classes of DNA.