Genetic mapping in the region of the mouse X-inactivation center

The mouse X-inactivation center lies just distal to the T16H breakpoint. Utilizing pedigree analysis of backcross progeny from a Mus domesticus/Mus spretus interspecific cross, we have mapped a number of genetic loci, gene probes, microclones, and EagI linking clones distal to the T16H breakpoint. The genetic analysis provides a detailed genetic map in the vicinity of the mouse X-inactivation center. Comparative mapping data from the human X chromosome indicate that the most probable location of the mouse X-inactivation center is distal to Ccg-1 and in the region of the Pgk-1 locus. We report the assignment of two new loci, EM13 and DXSmh44, to the Ccg-1/Pgk-1 interval.     

Replication timing in a single human chromosome 11 transferred into the Chinese hamster ovary (CHO) cell line

DNA replication in eukaryotes initiates from discrete genomic regions, termed origins, according to a strict and often tissue-specific temporal program. However, the genetic program that controls activation of replication origins has still not been fully elucidated in mammalian cells. Previously, we measured replication timing at the sequence level along human chromosomes 11q and 21q. In the present study, we sought to obtain a greater understanding of the relationship between replication timing programs and human chromosomes by analysis of the timing of replication of a single human chromosome 11 that had been transferred into the Chinese hamster ovary (CHO) cell line by chromosome engineering. Timing of replication was compared for three 11q chromosomal regions in the transformed CHO cell line (CHO(h11)) and the original human fibroblast cell line, namely, the R/G-band boundary at 11q13.5/q14.1, the centromere and the distal telomere. We found that the pattern of replication timing in and around the R/G band boundary at 11q13.5/q14.1 was similar in CHO(h11) cells and fibroblasts. The 11q centromeric region, which replicates late in human fibroblasts, replicated in the second half of S phase in CHO(h11) cells. By contrast, however, the telomeric region at 11q25, which is late replicating in fibroblasts (and in several other human cell lines), replicated in the first half of S phase or in very early S phase in CHO(h11) cells. Our observations suggest that the replication timing programs of the R/G-band boundary and the centromeric region of human chromosome 11q are maintained in CHO(h11) cells, whereas that for the telomeric region is altered. The replication timing program of telomeric regions on human chromosomes might be regulated by specific mechanisms that differ from those for other chromosomal regions.     

Replication timing properties within the mouse distal chromosome 7 imprinting cluster

Genomic imprinting is characterized by allele-specific expression of genes within chromosomal domains. Here we show, using fluorescence in situ hybridization (FISH) analysis, that the large chromosomal domain of the mouse distal chromosome 7 imprinting cluster, approximately 1 Mb in length between p57Kip2 and H19 genes, replicates asynchronously between the two alleles during S-phase. At the telomeric side of this domain, we found a transition from asynchronous replication at the imprinted p57Kip2 gene to synchronous replication at the Nap2 gene. Two-color FISH suggested that the paternal allele of this whole domain replicates earlier than its maternal allele. Treatment of the cells with a histone deacetylase inhibitor abolished this allele-specific feature accompanied with accelerated replication of the later-replicating allele at a domain level. Allele-specific asynchronous replication was observed even in ES cells. These results suggest that this imprinting cluster consists of a large replication domain which is already found at the early stage in development.     

Replication of human chromosomes in human-mouse hybrids: evidence that the timing of DNA synthesis is determined independently in each human chromosome.

The terminal phase of DNA replication was studied by autoradiography in hybrids between human lymphocytes and mouse fibroblasts. The hybrids contained on the average only 11 human chromosomes. It was found that the sequence of terminal DNA replication for the human chromosomes in the hybrids was the same as the sequence of terminal replication for the corresponding chromosomes in the human lymphocytes. Furthermore, it was shown that the maintenance of the normal terminal replication sequence of the human chromosomes in the hybrids was not dependent on the presence of any specific human chromosome. The results suggest that the timing of terminal DNA replication is determined independently in each human chromosome.     

Replication timing properties across the pseudoautosomal region boundary and cytogenetic band boundaries on human distal Xp

The establishment of human chromosomal regions as distinct and characteristic domains has been demonstrated by the reproducible banding patterns observed on metaphase chromosomes as a result of various staining techniques. Although the exact molecular properties responsible for the patterns are not well understood, a general correlation has been established between the time of replication of a particular region of DNA and its banding characteristics. Using a replication timing assay based on fluorescence in situ hybridization patterns, we investigated replication timing properties across chromosomal regions with potentially distinct chromatin properties. Relative replication timing values were determined using cosmid DNA probes around the pseudoautosomal region boundary in Xp22.3 and the cytogenetic band boundary regions surrounding Xp22.2. Although we observed replication timing domains that were generally consistent with cytogenetic banding patterns, we did not find sharp replication timing boundaries at either the pseudoautosomal region boundary or at the cytogenetic band boundaries. Received: 6 September 1997; in revised form: 16 December 1997 / Accepted: 5 January 1998     

Replication variants of the human inactive X chromosome

Replication variants of the inactive X chromosome were investigated in lymphocytes from six donors by means of terminal BrdU or thymidine incorporation. There were interindividual differences in the incidence of particular variants. In endoreduplicated and tetraploid cells both allocyclic X chromosomes showed the same replication sequence. The Xp22 band of the allocyclic X chromosome seemed to replicate later than the homologous material in some cells. Initiation time of DNA synthesis within the inactive X chromosome was found to be stable; termination time, however, varied greatly relative to the other chromosomes. Early completion of replication within the heterochromatic X chromosome could be demonstrated preferentially for the Xq25–27 terminal sequence, but other variants expressed the phenomenon also. A variable replication rate of the inactive X chromosome is believed to be responsible for its asynchronous, independent replication. The biological significance of the phenomenon is discussed with respect to cell differentiation.     

Replication variants of the human inactive X chromosome

The sequence of DNA replication was studied within the inactive X chromosome in human lymphocytes, by means of the FPG method. Several variants of the replication sequence were found. The number of variants in the cells of a single donor exceeded 2 in each of the 4 normal individuals studied. The phenomenon is discussed with respect to the regulation of DNA synthesis and to the cell differentiation process.     

Two extra euchromatic bands in the qh region of chromosome 9

Chromosome analysis in a fetus revealed an abnormal appearance of chromosome 9. The secondary constriction region of chromosome 9 was very large and two separate G+ bands were observed within this region with GTG banding. Parents' karyotypes showed maternal inheritance of this variant chromosome 9. Two G+ bands were stained negative with C banding both in the fetus and in the mother. The mother was phenotypically normal. Regarding phenotypically normal mother, normal fetal ultrasonographic findings and the similar cases described before in the literature it was considered that the fetus would be normal. Physical examination of the baby was normal after birth as expected. The existence of two G+ bands in 9qh was considered to be a normal variant in humans.     

Methylation patterns at the hypervariable X-chromosome locus DXS255 (M27 beta): correlation with X-inactivation status.

Methylation patterns surrounding a hypervariable X-chromosome locus, DXS255, have been analyzed with the restriction enzyme MspI and its methylation-sensitive isoschizomer HpaII. HpaII sites flanking the hypervariable region were found to be methylated on 41 active X chromosomes and unmethylated on 11 inactive X chromosomes present in a range of male, female, and hybrid cells and tissues. This differential methylation pattern coupled with the previously described high level (greater than 90%) of heterozygosity at the DXS255 locus can therefore be applied to determine the inactivation status of X chromosomes in females heterozygous for X-linked disease and in tumor clonality studies.     

Replication timing of DNA sequences associated with human centromeres and telomeres.

The timing of replication of centromere-associated human alpha satellite DNA from chromosomes X, 17, and 7 as well as of human telomeric sequences was determined by using density-labeling methods and fluorescence-activated cell sorting. Alpha satellite sequences replicated late in S phase; however, the alpha satellite sequences of the three chromosomes studied replicated at slightly different times. Human telomeres were found to replicate throughout most of S phase. These results are consistent with a model in which multiple initiations of replication occur at a characteristic time within the alpha satellite repeats of a particular chromosome, while the replication timing of telomeric sequences is determined by either telomeric origins that can initiate at different times during S phase or by replication origins within the flanking chromosomal DNA sequences.     

Assignment of the human myeloperoxidase gene (MPO) to bands q21.3----q23 of chromosome 17

Using a human myeloperoxidase cDNA, we have mapped the human myeloperoxidase gene to chromosome 17 at q21.3----q23 by in situ hybridization to metaphase chromosomes from human lymphocyte preparations.     

Bends in human mitotic metaphase chromosomes, including a bend marking the X-inactivation center.

Bends in mitotic metaphase chromosomes are not distributed randomly throughout the karyotype. The frequency of bends at centromeres is positively correlated with the relative length of the chromosomes and negatively correlated with the centromere index (more bends in metacentrics, fewer in acrocentrics). The frequency of bends in the noncentromeric regions (except at Xq13-Xq21) is positively correlated with the relative length of chromosome arms. A bend at Xq13.3 to Xq21.1 was more frequent than a bend in any other region of the karyotype, centromeric or noncentromeric. It was observed in one member of the X-chromosome pair in 63% of 46,XX cells. In contrast, it was observed in only 2% of 46,XY cells. RBG-staining showed that this specific bend is confined to the lyonized X chromosome. These observations in cells from normal subjects were confirmed using G-banding and RBG-staining on cells from nine subjects with different X-chromosome abnormalities and on metaphases from amniotic fluid cell and lymphocyte cultures. The "center for Barr body condensation" has been localized to the region between Xq11.2 and Xq21.1. The functional and structural relationship is unclear, but we believe this highly specific bend may represent a visible manifestation of the condensation process; it could represent the first folded (and last unfolded) position, upon or around which the rest of the chromosome condenses. The late replication of this region may also be a factor. The smallest region of overlap (SRO) for the X-chromosome inactivation center and the specific chromosome bend is Xq13.3 to Xq21.1.     

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.     

Replication origin region of the chromosome of alkaliphilic Bacillus halodurans C-125.

An 18.5-kb DNA fragment containing the oriC region of the chromosome of the alkaliphilic Bacillus halodurans C-125 was obtained by PCR and sequenced. Sixteen open reading frames (ORFs) were identified in this region. A sequencing similarity search using the BSORF database found that ORF1 to 13 all had significant similarities to gene products of Bacillus subtilis. Three other ORFs (ORF14-16) of unknown function were positioned down-stream of gyrB instead of rrnO, which is found in the same region in the case of B. subtilis. The ORF organization from gidA to gyrA was the same as that of B. subtilis. The gene organization and the location of the DnaA-box region were also similar to those of the chromosomes of other bacteria, such as Escherichia coli and Pseudomonas putida. There were two DnaA-box clusters (Box-region C and R) with a consensus sequence TTATCCACA on both sides of the dnaA gene but another DnaA box cluster (Box-region L) which is found in the region between thdF and jag in B. subtilis was not found in the corresponding region in the case of alkaliphilic Bacillus halodurans C-125.     

Characterization of the central region containing the X-inactivation center and terminal region of the mouse X Chromosome using irradiation and fusion gene transfer hybrids

The irradiation and fusion gene transfer (IFGT) procedure provides a means of isolating subchromosomal fragments for use in the mapping of loci and for cloning probes from a particular area of a chromosome. Using this procedure, two large panels of somatic cell hybrids that contain mouse X Chromosome (Chr) fragments have been generated. These hybrid panels were generated by irradiating the monochromosomal mouse-hamster hybrid HYBX, which retains the mouse X Chr, with either 10 K or 50 K rads of X-irradiation followed by fusion with a recipient Chinese hamster cell line. IFGT hybrids retaining mouse material were generated at high frequency. These hybrids were used to orient loci in the X-inactivation center region that had not been resolvable in our interspecies backcross panel and also to map, within the terminal region of the X Chr, repeat elements detected by the probe p15-4. These hybrids not only complement existing interspecies meiotic mapping panels for the detailed analysis of specific regions of particular chromosomes, but also provide a potential source of material for chromosome-specific probe isolation.     

Replication timing: the early bird catches the worm

Different replication origins in eukaryotes are activated at different times during S phase. New work indicates that the time at which an origin fires is related to its ability to recruit replication initiation factors that are limiting within the cell.     

Characterization of the central region containing the X-inactivation center and terminal region of the mouse X Chromosome using irradiation and fusion gene transfer hybrids

The irradiation and fusion gene transfer (IFGT) procedure provides a means of isolating subchromosomal fragments for use in the mapping of loci and for cloning probes from a particular area of a chromosome. Using this procedure, two large panels of somatic cell hybrids that contain mouse X Chromosome (Chr) fragments have been generated. These hybrid panels were generated by irradiating the monochromosomal mouse-hamster hybrid HYBX, which retains the mouse X Chr, with either 10 K or 50 K rads of X-irradiation followed by fusion with a recipient Chinese hamster cell line. IFGT hybrids retaining mouse matcrial were generated at high frequency. These hybrids were used to orient loci in the X-inactivation center region that had not been resolvable in our interspecies backcross panel and also to map, within the terminal region of the X Chr, repeat elements detected by the probe p15-4. These hybrids not only complement existing interspecies meiotic mapping panels for the detailed analysis of specific regions of particular chromosomes, but also provide a potential source of material for chromosome-specific probe isolation.     

Assignment of uroporphyrinogen decarboxylase (UROD) to the pter----p21 region of human chromosome 1

The assignment of the human gene for uroporphyrinogen decarboxylase (UROD) to chromosome 1 is confirmed and further localized to the pter----p21 region through the use of human-mouse somatic cell hybrids. Human and mouse UROD were separated by electrophoresis and identified with antibodies to the human enzyme after electrophoretic transfer to nitrocellulose membranes.