Human and rat chromosomal localization of two genes for 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase by analysis of somatic cell hybrids and in situ hybridization.

Two genes encoding 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase were localized in human and rat chromosomes. PFKFB1 (previously PFRX), which encodes the liver and muscle isozymes, was assigned to Xq22-q31 in the rat and to Xq27-q28 in the human by in situ hybridization using probes generated by the polymerase chain reaction. PFKFB2, which encodes the heart isozyme of 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase, was assigned to chromosome 13 in the rat and to chromosome 1 in the human by hybridization of DNA from somatic cell hybrids. By in situ hybridization, this gene was localized to the regions 13q24-25 in the rat and 1q31 in the human.     

Human and rat chromosomal localization of two genes for 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase by analysis of somatic cell hybrids and in situ hybridization

Two genes encoding 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase were localized in human and rat chromosomes. PFKFB1 (previously PFRX), which encodes the liver and muscle isozymes, was assigned to Xq22-q31 in the rat and to Xq27–q28 in the human by in situ hybridization using probes generated by the polymerase chain reaction. PFKFB2, which encodes the heart isozyme of 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase, was assigned to chromosome 13 in the rat and to chromosome 1 in the human by hybridization of DNA from somatic cell hybrids. By in situ hybridization, this gene was localized to the regions 13q24–25 in the rat and 1q31 in the human.     

Physical mapping of the factor VIII gene proximal to two polymorphic DNA probes in human chromosome band Xq28: implications for factor VIII gene segregation analysis

Genomic DNA segments for the coagulation factor VIIIc gene (F8C), which exhibits only limited restriction length polymorphism, map to the proximal region of band Xq28 by somatic cell hybridization analysis and in situ hybridization. Using somatic cell hybrids, we have obtained data which place probes DX13 (used to detect locus DXS15) and St14 (used to detect DXS52) distal to F8C, within band Xq28. Previous studies have mapped the factor IX gene (F9) and probe 52A (used to detect DXS51) proximal to F8C, in Xq26----q27 and Xq27, respectively (Camerino et al., 1984; Drayna et al., 1984; Mattei et al., 1985). Thus, the relative order of genetic marker loci in the Xq27----qter region is most likely cen-F9-DXS51-F8C-(DXS15, DXS52)-Xqter. The collection of these molecular probes is thus potentially useful in three-factor crosses of factor VIII gene segregation.     

Chromosomal localization of DBL oncogene sequences

The DBL oncogene was generated by rearrangements involving three discontinuous regions of the human genome. Analyses of panels of human X rodent somatic cell hybrids demonstrated that the DBL proto-oncogene located on the X chromosome (just proximal or distal to bands q26-27.2) underwent recombination at its 5' and 3' ends with sequences derived from chromosomes 3 (p13q-ter) and 16 (p13-q22), respectively. DBL was localized to chromosome Xq27-q28 by in situ hybridization. Another oncogene, MCF2, was previously shown to contain sequences derived from Xq27 as well. Comparison of the restriction maps and nucleotide sequences of genomic and cDNA clones representing the chromosome X-specific sequences of the DBL oncogene and MCF2, taken together with their chromosomal localization, indicates that these oncogenes were derived from the same genetic locus.     

Precise localization of the human thyroxine-binding globulin gene to chromosome Xq22.2 by fluorescence in situ hybridization

The human thyroxine-binding globulin (TBG) gene has been localized to X chromosome (Xq22.2) by in situ hybridization using a biotinylated gDNA probe. This is consistent with previous mapping of the TBG gene to chromosome Xq21-q22.     

In situ hybridization to cytogenetic bands of yeast artificial chromosomes covering 50% of human Xq24-Xq28 DNA

From the collection described by Abidi et al., 102 yeast artificial chromosomes (YACs) with human DNA inserts more than 300 kb in length were assigned to chromosomal band positions on early metaphase chromosomes by in situ hybridization using the biotin-avidin method. All the YACs hybridized within the Xq24-Xqter region, supporting the origin of the vast majority of the YACs from single human X-chromosomal sites. With assignments precise to +/- 0.5 bands, YACs were distributed among cytogenetic bands to roughly equal extents. Thus, there is no gross bias in the cloning of DNA from different bands into large YACs. To test band assignments further, hybridizations were carried out blind, and band positions were then compared with (1) probe localizations in cases in which a reported location was present in one of the YACs; (2) cross-hybridization of a labeled YAC with others in the collection; and (3) hybridization to a panel of DNAs from a series of hybrid cells containing Xq DNA truncated at various regions. Of 31 cases in which YACs contained a probe with a previously reported location, 28 in situ assignments were in agreement, and 14 other assignments, including one of the three discordant with probe localization, were confirmed by YAC cross-hybridization studies. Results with a group of nine YACs were further confirmed with a panel of somatic cell hybrid DNAs from that region. Five YACs hybridized both to Xq25 and to a second site (four in Xq27 and one in Xq28), suggestive of some duplication of DNA of the hybrid cell and perhaps in normal X chromosomes. The in situ assignments are thus sufficient to place YACs easily and systematically within bins of about 7-10 Mb and to detect some possible anomalies. Furthermore, on the basis of expectations for random cloning of DNA in YACs, the assigned YACs probably cover more than 50% of the total Xq24-Xq28 region. This provides one way to initiate the assembly of YAC contigs over extended chromosomal regions.     

Regional localization on the human X of DNA segments cloned from flow sorted chromosomes.

Fluorescence activated sorting of chromosomes from 49,XXXXY human lymphoblasts has been used to obtain DNA enriched for the human X. This DNA was cloned in lambda phage Charon 21A to obtain a library of approximately 60,000 pfu. Phage inserts free of human highly repeated DNA sequences are localized to different regions of the human X by two independent hybridization analyses. The first utilized comparative hybridization to rodent-human hybrid cell DNA samples containing all or known portions of the human X, while the second was based on hybridization dosage to DNA samples from human cell lines differing in the number of X chromosomes or X chromosome segments. Of five unique sequence inserts tested, three were X chromosome specific and were localized to regions Xpter leads to Xcen, Xql leads to Xq22 and Xq24 leads to Xqter, respectively. The library presented here represents a highly enriched source of human X chromosome-specific DNA sequences.     

Localization of the human thyroxine-binding globulin gene to the long arm of the X chromosome (Xq21-22).

Thyroxine-binding globulin (TBG) is the major thyroid-hormone transport protein in the plasma of most vertebrate species. A recombinant phage (lambda cTBG8) containing a cDNA insert of human TBG recently has been described. With the cDNA insert from lambda cTBG8 used as a radiolabeled probe, DNA from a series of somatic-cell hybrids containing deletions of the X chromosome was analyzed by means of blot hybridization. The results indicated that the TBG gene is located in the midportion of the long arm of the X chromosome between bands Xq11 and Xq23. The gene then was mapped to band region Xq21-22 by means of in situ hybridization to metaphase chromosomes. Sequences on the X chromosome that are homologous to the cDNA probe are contained within a single EcoRI restriction fragment of 12.5 kb in human DNA. On the basis of the intensity of the hybridization signal on Southern blots, it was determined that the human TBG cDNA probe used in the present study shares significant homology with hamster and mouse sequences. A single EcoRI restriction fragment was recognized in both hamster (8.0-kb) and mouse (5.1-kb) DNA.     

Localization by in situ hybridization of the coagulation factor IX gene and of two polymorphic DNA probes with respect to the fragile X site

Summary The coagulation factor IX gene and two other polymorphic loci corresponding to DNA probes 52 A and St 14 have been previously localized in the q27 to qter region of the human X chromosome. In order to study their localization with respect to the fragile site at Xq27-28, we have hybridized the three DNA probes to metaphase chromosomes of a boy with fragile X mental retardation. We show that probe 52A is located in the proximal part of the Xq27 band, while the coagulation factor IX gene is on the distal part of this band, but proximal to the fragile site. The very polymorphic St 14 probe is located in the distal part of the Xq28 band, on the other side of the fragile site.     

PCR amplification and analysis of yeast artificial chromosomes

A strategy for the analysis of yeast artificial chromosome (YAC) clones that relies on polymerase chain reaction (PCR) amplification of small restriction fragments from isolated YACs following adapter ligation was developed. Using this method, termed YACadapt, we have amplified several YACs from a human Xq24-qter library and have used the PCR products for physical mapping by somatic cell hybrid deletion analysis and fluorescent in situ hybridization. One YAC, RS46, was mapped to band Xq27.3, near the fragile X mutation. The PCR product is an excellent renewable source of YAC DNA for analyses involving hybridization of YAC inserts to a variety of DNA/RNA sources.     

Probes for CpG islands on the distal long arm of the human X chromosome are clustered in Xq24 and Xq28

We have isolated and characterized 55 EagI-containing genomic DNA clones from the distal long arm of the human X chromosome. The presence of additional sites for rare-cutter restriction enzymes and the demethylation of the corresponding genomic DNA demonstrate that at least 30 clones correspond to CpG islands of the Xq24-Xqter region. All clones were regionally mapped with a hybrid panel. The majority are in Xq28 and Xq24 (18 and 14 clones, respectively), 15 are in the Xq26-Xq27 interval, and none is in Xq25. This analysis demonstrates a nonuniform distribution of CpG islands that may reflect the distribution of coding regions in this part of the genome.     

Repeated DNA sequences in the distal long arm of the human X chromosome

Summary Two DNA probes from within a single large insert from a recombinant phage-DNA library that was constructed from flow-sorted chromosomes enriched for the human X chromosome were shown to hybridize with repeated X-specific and autosomal DNA sequences. The X-chromosomal repeated sequences were assigned to the distal long arm of the X chromosome by both hybrid mapping and in situ hybridization. Fine mapping places these repeats in a region of Xq28 between DX13 (DXS15, in distal Xq28) and factor VIII (F8C, in proximal Xq28). The location of the X-specific repeats makes them potentially useful for future investigations of discases mapping to the distal long arm of the X chromosome, such as the fragile X syndrome.     

Assignment of the human connexin 32 gene (GJB1) to band Xq13.

The chromosomal localization of the human gene coding for connexin 32 (GJB1) was determined by in situ suppression hybridization (ISSH). The results allowed assignment of the gene to band Xq13, thus refining previous localization data obtained by means of somatic cell hybrid analysis.     

Distribution of moderately repetitive sequences pTR5 and LF1 in Xq24-q28 human DNA and their use in assembling YAC contigs.

Xq24-q28 DNA, from a hamster/human hybrid cell containing only that portion of the human X chromosome, was found to contain 56 TaqI restriction fragments that hybridized to the moderately repetitive sequence pTR5. Using the pTR5 sequence as a probe in colony hybridization, 136 cognate yeast artificial chromosome (YAC) clones were detected among a collection of 820 containing about three genomic equivalents of the Xq24-q28 DNA. The YACs were then grouped into 48 contigs and single clones containing one or more of the TaqI fragments. Overlaps were confirmed both by fingerprinting YACs with AluI and L1 probes and by additional information. A less complete analysis was also carried out with a second moderately repetitive sequence, LF1, and some smaller contigs were merged into larger ones. Moderately repetitive sequences can thus be used as probes for multiple loci in single hybridization experiments and can help to organize and confirm YAC overlaps during the development of maps with long-range contiguity.     

Human Xq24-Xq28: approaches to mapping with yeast artificial chromosomes.

One hundred twenty-seven yeast strains with artificial chromosomes containing Xq24-Xqter human DNA were obtained starting from a human/hamster somatic cell hybrid. The clones were characterized with respect to their insert size, stability, and representation of a set of Xq24-Xqter DNA probes. The inserts of the clones add up to 19.3 megabase (Mb) content, or about 0.4 genomic equivalents of that portion of the X chromosome, with a range of 40-650 kb in individual YACs. Eleven clones contained more than one YAC, the additional ones usually having hamster DNA inserts; the individual YACs could be separated by extracting the total DNA from such strains and using it to retransform yeast cells. One of the YACs, containing the probe for the DXS49 locus, was grossly unstable, throwing off smaller versions of an initial 300-kb YAC during subculture; the other YACs appeared to breed true on subculture. Of 52 probes tested, 12 found cognate YACs; the YACs included one with the glucose-6-phosphate dehydrogense gene and another containing four anonymous probe sequences (DX13, St14, cpx67, and cpx6). Xq location of YACs is being verified by in situ hybridization to metaphase chromosomes, and fingerprinting and hybridization methods are being used to detect YACs that overlap.     

New polymorphisms at the DXS98 locus and confirmation of its location proximal to FRAXA by in situ hybridization.

The locus DXS98, detected with the 1.5-kb anonymous probe p4D-8, was recently shown to be closely linked and proximal to the locus for the fragile X syndrome, with theta = .05 at lod = 3.406, by utilizing a limited number of meioses informative for a two-allele MspI RFLP. Because DXS98 may be the closest available marker to the fragile X locus (FRAXA), we sought to increase its utility for linkage studies by extending its PIC and confirming its localization to Xq27, proximal to FRAXA. We have isolated 15 kb of genomic DNA (lambda 4D8-3) from the DXS98 locus by using p4D-8 to screen a genomic phage library containing partial Sau3A-digested human DNA. Three additional RFLPs for the enzymes BglII and XmnI were found by using the entire lambda 4D8-3 as probe. Combined heterozygosity for the four RFLPs in 25 unrelated females was 48%, as compared with only 28% when the MspI RFLP alone was used. In situ hybridization of unique sequences from lambda 4D8-3 was performed on metaphase chromosomes of lymphocytes and lymphoblasts from patients with the fragile X syndrome. Grains on the X chromosome were significantly clustered at band Xq27. Following fragile site induction, all nine grains in the q27-28 region were proximal to the fragile site. Confirmation of the location of DXS98 proximal to FRAXA and the new RFLPs at this locus make DXS98 more useful for linkage analysis and physical mapping in the region of the fragile X mutation.     

Deletion (X)(q26.1-->q28) in a proband and her mother: molecular characterization and phenotypic-karyotypic deductions.

During a routine prenatal diagnosis we detected a female fetus with an apparent terminal deletion of an X chromosome with a karyotype 46,X,del(X)(q25); the mother, who later underwent premature ovarian failure, had the same Xq deletion. To further delineate this familial X deletion and to determine whether the deletion was truly terminal or, rather, interstitial (retaining a portion of the terminal Xq28), we used a combination of fluorescence in situ hybridization (FISH) and Southern analyses. RFLP analyses and dosage estimation by densitometry were performed with a panel of nine probes (DXS3, DXS17, DXS11, DXS42, DXS86, DXS144E, DXS105, DXS304, and DXS52) that span the region Xq21 to subtelomeric Xq28. We detected a deletion involving the five probes spanning Xq26-Xq28. FISH with a cosmid probe (CLH 128) that defined Xq28 provided further evidence of a deletion in that region. Analysis with the X chromosome-specific cocktail probes spanning Xpter-qter showed hybridization signal all along the abnormal X, excluding the possibility of a cryptic translocation. However, sequential FISH with the X alpha-satellite probe DXZ1 and a probe for total human telomeres showed the presence of telomeres on both the normal and deleted X chromosomes. From the molecular and FISH analyses we interpret the deletion in this family as 46,X,del(X) (pter-->q26::qter). In light of previous phenotypic-karyotypic correlations, it can be deduced that this region contains a locus responsible for ovarian maintenance.