Rapid isolation of DNA probes within specific chromosome regions by interspersed repetitive sequence polymerase chain reaction

A method was recently developed for the specific amplification of human DNA sequences from interspecific somatic cell hybrids by the polymerase chain reaction (PCR) using primers directed to Alu, a short interspersed repeat element (SINE). We now show human-specific amplification using a primer to the 3' end of the human long interspersed repeat element L1Hs (LINE). A monochromosomal hybrid containing an intact human X chromosome yielded approximately 25 discrete products, ranging in size from 800 to 4500 bp. Combination of a single Alu primer and the L1Hs primer yielded a large number of smaller products (300-1000 bp) distinct from those observed with either primer alone. Inspection of ethidium bromide-stained gels showed one Alu-Alu and three Alu-L1Hs products which were present in an intact X chromosome but absent in a hybrid containing an X chromosome deleted for the single metaphase band q28. These four fragments were isolated from the gel and used as probes on Southern blots which confirmed their localization to Xq28. These results demonstrate that primers can be constructed to a variety of interspersed repetitive sequences (IRS) and used individually or in combination for the rapid isolation of DNA fragments from defined chromosomal regions by IRS-PCR.     

The construction of human somatic cell hybrids containing portions of the mouse X chromosome and their use to generate DNA probes via interspersed repetitive sequence polymerase chain reaction

Interspersed repetitive sequence polymerase chain reaction (IRS-PCR) has become a powerful tool for the rapid generation of DNA probes from human chromosomes present in rodent somatic cell hybrids. We have constructed a somatic cell hybrid containing a major portion of the mouse X chromosome in a human background (clone 8.0). IRS-PCR was developed for the specific amplification of mouse DNA using either of two primers from the rodent-specific portion of the murine B1 repeat. Amplification was subsequently performed with clone 8.0 and a subclone, 8.1/1, which retains a small murine X-chromosomal fragment including Hprt and the Gdx locus. A total of 15-20 discrete PCR products ranging in size from less than 500 to greater than 3000 bp were obtained from clone 8.0 with each primer. In clone 8.1/1, a subset of these bands plus some additional bands were observed. Nine bands amplified from clone 8.1/1 have been excised from gels and used as probes on Southern blots. All of the fragments behaved as single-copy probes and detected domesticus/spretus variation. They have been regionally mapped using an interspecific backcross. The probe locations are compatible with those of markers known to be present in clone 8.1/1. These results demonstrate the feasibility of this method as applied to the mouse genome and the high likelihood of generating useful DNA probes from a targeted region.     

Isolation of DNA markers from a region between incontinentia pigmenti 1 (IP1) X-chromosomal translocation breakpoints by a comparative PCR analysis of a radiation hybrid subclone mapping panel.

A strategy based on the use of human-specific interspersed repetitive sequence (IRS)-PCR amplification was used to isolate regional DNA markers in the vicinity of the incontinentia pigmenti 1 (IP1) locus. A radiation hybrid (RH) resulting from a fusion of an irradiated X-only somatic cell hybrid (C12D) and a thymidine kinase deficient (TK-) hamster cell line (a23) was identified as containing multiple X chromosome fragments, including DNA markers spanning IP1 X-chromosomal translocation breakpoints within region Xp11.21. From this RH, a panel of subclones was constructed and analyzed by IRS-PCR amplification to (a) identify subclones containing a reduced number of X chromosome fragments spanning the IP1 breakpoints and (b) construct a mapping panel to assist in identifying regional DNA markers in the vicinity of the IP1 locus. By using this strategy, we have isolated three different IRS-PCR amplification products that map to a region between IP1 X chromosome translocation breakpoints. A total of nine DNA sequences have now been mapped to this region; using these DNA markers for PFGE analyses, we obtained a probe order DXS14-DXS422-MTHFDL1-DXS705. These DNA markers provide a starting point for identifying overlapping genomic sequences spanning the IP1 translocation breakpoints; the availability of IP1 translocation breakpoints should assist the molecular analysis of this locus.     

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.     

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.     

Histone gene expression and chromatin structure in mammalian cell hybrids

DNA isolated from mammalian cell nuclear reveals discrete size patterns when partially digested with micrococcal nuclease. The DNA repeat lengths from different tissues within a species or from different species may vary. These differences have been attributed to the presence of different species of histone H1. To examine the nature of regulation of DNA repeat lengths and their possible relationship to histone H1, we have selected several mouse and human cell lines that differ in their DNA repeat lengths and examined them and their cell hybrids. 24 mouse X human and five mouse X mouse hybrid cell lines were analyzed. All the interspecific hybrids exhibited the repeat pattern characteristic of the murine parent. The mouse intraspecific hybrids had a repeat pattern of only one of the parents. We conclude that the partial human chromosome complements retained in the hybrids assume the repeat lengths exhibited by the mouse cells. Because H1 histones have been implicated in the determination of DNA repeat lengths, we also investigated the regulation of H1 histone expression in these cell hybrids. Purified H1 histones were radioactively labeled in vitro, and individual subfractions were subjected to proteolysis followed by gel electrophoresis. The resulting partial peptide maps off H1 histone subfractions A and B were distinguishable from one another and from different cell lines. In the mouse X human hybrids analyzed, only the mouse H1 histones were detected. These observations were extended to H2b by analysis of the hybrid cell histone by Triton-acid-urea gels. Neither the DNA repeat length nor histone expression is affected by the presence of any specific human chromosome. The fact that human genes are expressed in these hybrids suggests that the H1 histones of one species is able to interact with the chromatin of another species in a biologically funtional conformation. Analysis of the intraspecific PG19 X B82 (mouse X mouse) hybrids reveals the presence of H1 histone subfractions of the B82 mouse cells. Because these hybrids exhibit the nucleosome repeat length only of the PG19 cells, it appears that if histone H1 plays a role in determining the repeat length it does so in consort with other nonhistone chromosomal proteins.     

DNA-mediated transfer of the mouse gene for hypoxanthine phosphoribosyltransferase into cultured mouse cells: No integration of the transferred gene at its homologous site in the host genome

Summary An established Chinese hamster cell line was fused with microcells isolated from phenotypically stable transferent mouse cells which contained a mouse transgenome coding for an abnormal form of mouse hypoxanthine phosphoribosyltransferase (HPRT, EC. No. 2.4.2.8) (Willecke et al. 1979). Two hybrids were isolated which expressed the abnormal form of mouse HPRT but no mouse -galactosidase (GALA, EC. No. 3.2.1.22). In one of these microcell hybrids the abnormal HPRT activity segregated under counter-selective conditions with mouse chromosome 3. No mouse chromosome or additional mouse gene marker was found in the second microcell hybrid, possibly because of breakage and/or rearrangement of the integrated transgenome during the isolation of this hybrid. We conclude from these results that the transferred mouse HPRT gene in a phenotypically stable clone is not integrated at its homologous site on the host X chromosome. Rather, the transgenome is probably integrated into mouse chromosome 3, possibly due to homologies in repeated DNA sequences which may occur in the transgenome and which are interspersed at many sites in the host genome.     

Mouse chromosome-specific markers generated by PCR and their mapping through interspecific backcrosses.

We have utilized an oligonucleotide primer from the 3' end of the mouse L1 repeat element for amplification of mouse-specific inter-repeat PCR products from Chinese hamster/mouse somatic cell hybrids. PCR of a Chinese hamster/mouse somatic cell hybrid (96AZ2), containing only mouse chromosome 16, produced a range of mouse-specific bands. Two of the mouse-specific PCR products, of 250 and 580 bp, have been confirmed as originating from mouse chromosome 16 by somatic cell hybrid analysis. Both the 250- and 580-bp PCR products have been sequenced and demonstrate the expected sequence organization. Furthermore, both the 250- and 580-bp markers have been genetically mapped in detail to mouse chromosome 16 by direct hybridization to inter-repeat PCR products of progeny DNAs from Mus domesticus/Mus spretus interspecific backcrosses.     

Generation of novel sequence tagged sites (STSs) from discrete chromosomal regions using Alu-PCR

Human DNA segments from discrete chromosomal regions were generated by utilizing Alu-element-based polymerase chain reaction (Alu-PCR) of an irradiation-fusion hybrid containing approximately 10 to 15 Mb of human DNA. Following cloning into a plasmid vector, a subset of the clones was used to generate sequence tagged sites (STSs) de novo. By means of a panel of hybrids containing portions of the human X chromosome, the STSs were shown to localize to two chromosomal regions, Xq24-Xq26 and Xcen-Xq13, reflecting the presence in the irradiation-fusion hybrid of two human chromosome fragments. These results demonstrate that high densities of STSs can be rapidly and efficiently generated from defined regions of the human genome using Alu-PCR.     

"PCR-karyotype" of human chromosomes in somatic cell hybrids

Amplification of human DNA sequences in 16 monochromosomal somatic cell hybrids containing different human chromosomes were performed by the polymerase chain reaction (PCR) using primer directed at human-specific regions of Alu or L1, the two major classes of interspersed repetitive sequences (IRS-PCR). A chromosome-specific pattern of amplification products was observed on agarose gels run with ethidium bromide, producing a "PCR-karyotype." This simple gel analysis provides a rapid method for identifying and monitoring the human chromosomal content of monochromosomal somatic cell hybrids without conventional cytogenetic analysis. Hybrids containing multiple human chromosome produce complex gel patterns, but identification of chromosome content can be achieved by hybridization of PCR products against a reference panel of monochromosomal or highly reduced hybrids representing each human chromosome. This dot-blot method also enables identification of human marker chromosomes or translocated pieces in hybrids that are not identifiable by cytogenetic methods. These IRS-PCR methods should greatly reduce the need for more laborious cytogenetic, isozyme, and Southern blot characterizations of human-rodent cell hybrids.     

Painting of human chromosomes with probes generated from hybrid cell lines by PCR with Alu and L1 primers

Summary Specific amplification of human sequences of up to several kb length has recently been accomplished in man-hamster and man-mouse somatic hybrid cell DNA by IRS-PCR (interspersed repetitive sequence — polymerase chain reaction). This approach is based on oligonucleotide primers that anneal specifically to human Alu- or L1-sequences and allows the amplification of any human sequences located between adequately spaced, inverted Alu- or L1-blocks. Here, we demonstrate that probe pools generated from two somatic hybrid cell lines by Alu- and L1-PCR can be used for chromosome painting in normal human lymphocyte metaphase spreads by chromosomal in situ suppression (CISS-) hybridization. The painted chromosomes and chromosome subregions directly represent the content of normal and deleted human chromosomes in the two somatic hybrid cell lines. The combination of IRS-PCR and CISS-hybridization will facilitate and improve the cytogenetic analysis of somatic hybrid cell panels, in particular, in cases where structurally aberrant human chromosomes or human chromosome segments involved in interspecies translocations cannot be unequivocally identified by classical banding techniques. Moreover, this new approach will help to generate probe pools for the specific delineation of human chromosome subregions for use in cytogenetic diagnostics and research without the necessity of cloning.     

Chromosomal distribution of the hamster intracisternal A-particle (IAP) retrotransposons

The retrotransposon-like elements of the intracisternal A-particle (IAP) sequences occur in about 900 copies per haploid hamster cell genome. By applying the fluorescent in situ hybridization (FISH) technique and four different, cloned segments of the IAP element as hybridization probes, these elements were found to be distributed in specific patterns over many of the 44 hamster chromosomes. The hybridization patterns were very similar regardless of whether all four probes or only the IAPI probe carrying the long terminal repeat (LTR) region were used. The IAP elements were found most abundantly, though not exclusively, on the short arms of at least 12 of the autosomes. Of the sex chromosomes, the shorter Y chromosome was stained on both arms, and the X chromosome on one arm by the IAP probes. Primary Syrian hamster cells, the established Syrian hamster cell line BHK21, and the adenovirus type 12 (Ad12)-transformed BHK21 cell line T637 yielded very similar results. In Chinese hamster ovary (CHO) or 3T3 mouse cells, signals could not be elicited by FISH using the Syrian hamster IAP probes. On Southern blots, the DNAs from these cell lines hybridized very weakly, if at all, to the IAP sequences. Thus, IAP sequences were retroposed after Syrian hamster and mouse or Syrian and Chinese hamsters had diverged in evolution.     

The human desmin and vimentin genes are located on different chromosomes

We have used somatic cell hybrids of Chinese hamster X man and mouse X man to localize the genes (des and vim) encoding the intermediate filaments desmin and vimentin in the human genome. Southern blots of DNA prepared from each cell line were screened with hamster cDNA probes specific for des and vim genes, respectively. The single-copy human des gene is located on chromosome 2, and the single-copy human vim gene is assigned to chromosome 10. Partial restriction maps of the two human genomic loci are presented. A possible correlation of the des locus with several reported hereditary myopathies is discussed.     

Normal X chromosome induced reversion in the direction of chromosome segregation in mouse-Chinese hamster somatic cell hybrids

The effect of a normal mouse X chromosome on the chromosome segregation of mouse-Chinese hamster somatic cell hybrids was determined by (i) producing hybrids between the mouse sarcoma line CMS4 and a microcell hybrid (mfe4) of the hamster line E36, containing a mouse X chromosome from a normal cell; (ii) isolating hybrids between CMS4 and a 6-thioguanine selected (X minus) mfe4 subpopulation; (iii) comparing the direction of segregation in the two sets of hybrids. It was found that the normal X chromosome, like the X chromosomes from two MCA-transformed sarcoma lines reported previously [9], has the ability to switch the chromosome segregation of mouse-Chinese hamster somatic cell hybrids. We conclude that the reversal in chromosome segregation is mediated by factors located on the X chromosome. We designate these genetic elements as segregation reversal genes or sr genes.     

Gene mapping in the rat by mouse-rat somatic cell hybridization: synteny of the albumin and alpha-fetoprotein genes and assignment to chromosome 14

The methods of somatic cell genetics and molecular hybridization were applied to a panel of mouse X rat hepatocyte hybrids segregating rat chromosomes to assign the rat genes coding for two serum proteins, albumin and alpha-fetoprotein (Alb and Afp). The molecular hybridization of DNAs from different hybrids with cloned DNA probes showed that all the hybrid clones possessing the rat Alb gene and expressing it also retained the rat Afp locus, which is not expressed in these hybrids. So the Alb and Afp genes are syntenic in the rat, as in the mouse. Furthermore, the cytogenetic analysis allowed the assignment of these two loci to rat chromosome 14.     

Variation in genomic alu repeat density as a basis for rapid construction of low resolution physical maps of human chromosomes

Human DNA restriction fragments containing high numbers of Alu repeat sequences can be preferentially detected in the presence of other human DNA restriction fragments in DNA from human:rodent somatic cell hybrids when the DNA is fragmented with enzymes that cleave mammalian DNA infrequently. This ability to lower the observed human DNA complexity allowed us to develop an approach to order rapidly somatic hybrid cell lines retaining overlapping human genomic domains. The ordering process also generates a relative physical map of the human fragments detected with Alu probe DNA. This process can generate physical mapping information for human genomic domains as large as an entire chromosome (100,000 kb). The strategy is demonstrated by ordering Alu-detected NotI fragments in a panel of mouse:human hybrid cells that span the entire long arm of human chromosome 17.by L. Manuelidis     

A highly polymorphic locus in human DNA revealed by probes from cosmid 1-5 maps to chromosome 2q35----37.

The highly polymorphic locus D2S3 is revealed by three single-copy probes from cosmid C1-5. These probes, 1-30, 1-32, and 2-96, collectively reveal seven restriction fragment length polymorphisms. Fifty-three of 56 unrelated individuals (93%) were heterozygous at one or more of the seven loci, making the compound locus a very useful marker for gene mapping. Chromosomal assignment of D2S3 was obtained using a panel of human X hamster and human X mouse somatic cell hybrids. Molecular hybridization of EcoRI-digested DNA from these cell lines with the DNA inserts from subclones 1-30, 1-32, and 2-96 showed that all three probes mapped to the long arm of chromosome 2. Additionally, in situ hybridization of [3H]-labeled probe 2-96 to metaphase chromosome preparations allowed more precise assignment of the locus to the region 2q35----37.     

Retrieval of human DNA from rodent-human genomic libraries by a recombination process

Human Alu repeat ("BLUR") sequences have been cloned into the mini-plasmid vector piVX. The resulting piBLUR clones have been used to rescue selectively, by recombination, bacteriophage carrying human DNA sequences from genomic libraries constructed using DNA from rodent-human somatic cell hybrids. piBLUR clones are able to retrieve human clones from such libraries because at least one Alu family repeat is present on most 15 to 20 kb fragments of human DNA and because of the relative species-specificity of the sequences comprising the Alu family. The rapid, selective plaque purification achieved results in the construction of a collection of recombinant phage carrying diverse human DNA inserts from a specific subset of the human karyotype. Subfragments of two recombinants rescued from a mouse-human somatic cell hybrid containing human chromosomes X, 10, 13, and 22 were mapped to human chromosomes X and 13, respectively, demonstrating the utility of this protocol for the isolation of human chromosome-specific DNA sequences from appropriate somatic cell hybrids.     

X chromosome-induced reversion of chromosome segregation in mouse/Chinese hamster somatic cell hybrids : Cellular recognition of native and foreign X chromosomes

The direction of chromosome loss in two sets of mouse-Chinese hamster hybrids was compared with the direction of segregation of the same hybrids, to which an additional X chromosome derived from either of the mouse sarcoma lines MethAa, MethAs, or CMS4, was introduced at the time of the fusion. The addition of the X chromosome was carried out by substituting in place of the Chinese hamster parent a mouse X containing microcell hybrid of the latter. It was found that the addition of an X chromosome reverses the direction of chromosome segregation, but it can do so only if the mouse parent in the hybridization is different from the line from which the X originated. The possible reasons for recognition by the cells of a native and a foreign X are discussed. The existence of a multigene family on the X chromosome, involved in this recognition, is proposed.     

Evidence for suppression of cellular growth in vitro and selection against the indigenous mouse X chromosome in A9 cell hybrids after microcell-mediated transfer of an X from other mammalian species

Introduction of a human or Syrian hamster X chromosome (derived from BHK-191-5C cell hybrids) into tumorigenic mouse A9 cells via microcell fusion induced changes in cellular morphology and a retardation of cellular growth. The suppression of growth of the hybrids could be abolished, however, by daily changes of medium containing 20% serum. G-banding analysis showed the absence of a single, cytogenetically identifiable, indigenous X chromosome (marker Z) in two of four hybrid clones after an X chromosome was transferred from either hamster or human cells. All hybrids were tumorigenic when tested in nude mice. Together, these data suggest that the loss of the mouse X chromosome took place probably because of growth inhibitory effects imposed on hybrid cells due to the increase in X chromosome dosage. In addition, our results show a lack of association between the phenotype of cellular growth suppression in vitro and the phenotype of suppression of tumorigenicity in vivo.