High-density molecular map of the central span of the mouse X chromosome.

A total of 17 linking clones previously sublocalized to the central span of the mouse X chromosome have been ordered by detailed analysis through interspecific Mus spretus/Mus musculus domesticus backcross progeny. These probes have been positioned with respect to existing DNA markers utilizing a new interspecific backcross segregating for the Tabby (Ta) locus. The density of clones within this 11.5-cM interval is now, on average, one clone every 1000 kb. This high-density map provides probes in the vicinity of a number of important genetic loci in this region which include the X-inactivation center, the Ta locus, and the mottled (Mo) locus, and therefore provides a molecular framework for identification of the genes encoded at these loci.     

Construction and characterization of a NotI linking library of human chromosome 21

Effective procedures have been developed for constructing NotI linking libraries starting from chromosome-specific genomic libraries. Fifteen different single copy and two rDNA NotI linking clones from human chromosome 21 were identified in two libraries. Their chromosomal origin was confirmed, and regional location established using hybrid cell panels. Hybridization experiments with these probes revealed pairs of genomic NotI fragments, each ranging in size from less than 0.05 to 4.0 Mb. Many fragments displayed cell type variation. The total size of the NotI fragments detected in a human fibroblast cell line (GM6167) and mouse hybrid cell containing chromosome 21 as its only human component (WAV17) were approximately 32 and 34 Mb, respectively. If these fragments were all non-overlapping, this would correspond to about 70% of the 50-Mb content estimated for the whole chromosome. The linking clones will be enormously useful in the subsequent construction of a NotI restriction map of this chromosome. Characterization of these clones indicates the presence of numerous additional sites for other enzymes that recognize sequences containing CpG. Thus most NotI linking clones appear to derive from CpG islands and probably identify the 5' end of genes.     

Construction of a detailed molecular map of the mouse X chromosome by microcloning and interspecific crosses.

A large number of microclones obtained by microdissection of the mouse X chromosome have been mapped using an interspecific Mus domesticus/Mus spretus cross. Clones displaying close linkage to a number of loci of known phenotype but unknown gene product, such as mdx (X-linked muscular dystrophy), have been obtained. Over a central 30 cM span of the mouse X chromosome, 17 clones have been mapped and ordered at a sufficient density to contemplate the complete physical mapping of this region that will aid in the isolation of a number of unidentified genes. Some of the mapped microclones detect moderately repetitive sequences that were clustered in several discrete regions of the mouse X chromosome.     

Construction of a human chromosome 3 specific NotI linking library using a novel cloning procedure.

Two new diphasmid vectors (lambda SK17 and SK22) and a novel procedure to construct linking libraries are described. A partial filling-in reaction provides counter-selection against false linking clones in the library, and obviates the need for supF selection. The diphasmid vectors, in combination with the novel selection procedure, have been used to construct a chromosome 3 specific NotI linking library from a human chromosome 3/mouse microcell hybrid cell line. The application of the new vectors and the strong biochemical and biological selections resulted in a library of 60,000 NotI linking clones. As practically all of them are real NotI linking clones (no false recombinants) the library represents approximately 3,000 human recombinants (equal to 10-15 genomic equivalents of chromosome 3). Previously published methods for construction of linking libraries are compared with the procedure described in the present paper. The advantages of the new vectors and the novel protocol are discussed.     

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.     

Assignment of the gene for adenosine kinase to chromosome 14 in Mus musculus by somatic cell hybridization.

Evidence is presented for the assignment of the gene for adenosine kinase to Mus musculus chromosome 14 by synteny testing and karyotypic analysis of mouse X Chinese hamster somatic cell hybrid clones. ADOK and two enzymes previously mapped to mouse chromosome 14, NP and ES-10, were expressed concordantly in 29 hybrid clones. Chromosome analysis confirmed this assignment. Syntenic evidence is also presented using several clones of a gene transfer system in which the gene for human HPRT had integrated into modified mouse chromosome 14's.     

Mapping of the mouse X chromosome using random genomic probes and an interspecific mouse cross.

Two libraries enriched in murine X chromosome material have been constructed in the lambda vector NM 1149 from flow-sorted chromosomes. Inserts of unique genomic sequence DNA were purified and their X chromosome specificity characterised by hybridisation to a panel of somatic cell hybrid lines. Of the first five such X chromosome-specific probes characterised, all detect restriction fragment length polymorphisms (RFLPs) between inbred mouse laboratory strains such as C57BL/6 and BALB/c and the SPE/Pas mouse strain established from a wild Mus spretus mouse, when their DNAs are digested with the restriction enzyme TaqI. Taking advantage of these RFLPs, all five probes have been localised on the X chromosome using an interspecific backcross between the B6CBARI and SPE/Pas mouse strains segregating the X chromosome markers hypoxanthine phosphoribosyl transferase (Hprt) and Tabby (Ta). Three of the probes map to the region between the centromere and Hprt, and two distal to Ta. Since such X-specific sequence probes detect RFLPs between M. spretus and M. musculus domesticus DNAs with high frequency, a large panel of well localised probes should soon be available for studies of biological problems associated with the X chromosome which can best be approached using the murine species.     

New strategy for mapping the human genome based on a novel procedure for construction of jumping libraries

A novel procedure for construction of jumping libraries is described. The essential features of this procedure are as follows: (1) two diphasmid vectors (lambda SK17 and lambda SK22) are simultaneously used in the library construction to improve representativity, (2) a partial filling-in reaction is used to eliminate cloning of artifactual jumping clones and to obviate the need for a selectable marker. The procedure has been used to construct a representative human NotI jumping library (220,000 independent recombinant clones) from the lymphoblastoid cell line CBMI-Ral-STO, which features a low level of methylation of its resident EBV genomes. A human chromosome 3-specific NotI jumping library (500,000 independent recombinant clones) from the human chromosome 3 x mouse hybrid cell line MCH 903.1 has also been constructed. Of these recombinant clones 50-80% represent jumps to the neighboring cleavable NotI site. With our previously published method for construction of linking libraries this procedure makes a new genome mapping strategy feasible. This strategy includes the determination of tagging sequences adjacent to NotI sites in random linking and jumping clones. Special features of the lambda SK17 and lambda SK22 vectors facilitate such sequencing. The STS (sequence tagged site) information obtained can be assembled by computer into a map representing the linear order of the NotI sites for a chromosome or for the entire genome. The computerized mapping data can be used to retrieve clones near a region of interest. The corresponding clones can be obtained from the panel of original clones, or necessary probes can be made from genomic DNA by PCR.     

Assignment of the genes for triose phosphate isomerase to chromosome 6 and tripeptidase-1 to chromosome 10 in Mus musculus by somatic cell hybridization

Evidence is presented for the assignment of the gene for triose phosphate isomerase to Mus musculus chromosome 6 and tripeptidase-1 to chromosome 10 by synteny testing and chromosome assignment in Chinese hamster X mouse somatic cell hybrid clones. Neither TPI nor TRIP-1 were expressed concordantly with any known isozyme markers in 45 hybrid clones (13 primary and 32 secondary). Karyotypic analysis of 21 clones showed that the expression of TPI and chromosome 6 were concordant in all cases as was expressed of TRIP-1 and chromosome 10. Both chromosomes were previously unmarked by isozymes.     

Genetic mapping on the mouse X chromosome of human cDNA clones for the fragile X and Hunter syndromes.

Murine X-linked genes corresponding to the human Fragile X (FMR1) and Hunter syndrome (IDS) loci have been mapped in an interspecific backcross between B6CBA-Aw-J/A-Bpa and Mus spretus using human cDNA clones. Pedigree analysis of recombinants from a total of 248 backcross progeny favors a gene order of (Cf-9, Mcf-2)-(Fmr-1)-Ids-Gabra3-Rsvp. Gene order is conserved between the species, although no fragile site has been detected in the mouse in this region of the murine X chromosome.     

The T cell receptor beta chain genes are located on chromosome 6 in mice and chromosome 7 in humans

Homologous clones that encode the beta chain of the T cell antigen receptor have been isolated recently from both murine and human cDNA libraries. These cDNA clones have been used in connection with interspecies hybrid cell lines to determine that the murine T cell receptor gene is located on chromosome 6 and the human gene on chromosome 7. In situ hybridization confirms these data and further localizes these genes to band B of chromosome 6 in the mouse and bands 7p13-21 in the human genome. The organization of the T cell antigen receptor J beta gene segments and C beta genes appears to be conserved, since very few intraspecies polymorphisms of restriction fragment length have been detected in either mouse or human DNA.     

Characterization of the Xp21-23 region in the wood lemming, a region involved in XY sex reversal.

The wood lemming (Myopus schisticolor) harbors two types of X chromosome, a normal X and a variant X, designated X*. The X* chromosome contains a mutation that causes XY sex reversal. We have previously demonstrated that the Xp21-23 region is deleted from X* and is associated with XY sex reversal. To further analyze the deleted region, we have constructed and characterized seven X chromosome- and region-specific recombinant DNA libraries. Further, we have screened mouse fetal gonad cDNA libraries with the microdissected Xp21-23 DNA as a probe in an attempt to identify homologous and expressed sequences from the deletion. Fourteen positive clones were isolated, and sequence analyses showed that ten of these contained identical sequences homologous to mouse gamma-satellite sequences. One of the remaining four was perfectly homologous to the mouse gene Ccth (chaperonin containing t-complex polypeptide 1, eta subunit). Southern blot indicated that the Ccth cDNA was located on the X chromosome, not deleted from the X* but closely linked to the deletion region. Although the role of the Ccth containing region in sex determination of the wood lemming requires additional studies, the isolation of the mouse Ccth gene by the deletion Xp21-23 probe could be important since this gene is mainly expressed in testis.     

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.     

Mouse ferritin H multigene family is polymorphic and contains a single multiallelic functional gene located on chromosome 19.

Multiple ferritin H subunit sequences are present in the genome of higher vertebrates, but it is not yet known with certainty if more than one is expressed. In this paper, we provide evidence that there is only one functional ferritin H gene in the mouse. We screened a mouse genomic library using a mouse ferritin H cDNA as a probe and characterized five clones. These genomic clones proved to contain three pseudogenes and two allelic forms of a unique functional gene. These two alleles differed by only two point mutations in the promoter and three in the first intron and by a 31-bp insertion in the first intron. They were equally expressed when transiently transfected in HeLa cells. These five genomic clones account for all the bands observed on a Southern blot of mouse genomic DNA hybridized with a ferritin H cDNA, and these bands present a restriction fragment length polymorphism between various representatives of the genus Mus. Using a DNA panel prepared from the backcross progeny (C57BL/6 X Mus spretus)F1 X C57BL/6, we localized the functional ferritin H gene (Fth) in region B of mouse chromosome 19 and established cen-Ly-1-Fth-Pax-2 as the most likely gene order, thus defining a conserved syntenic fragment with human chromosome 11q.     

Rapid physical mapping of cloned DNA on banded mouse chromosomes by fluorescence in situ hybridization.

Physical mapping of DNA clones by nonisotopic in situ hybridization has greatly facilitated the human genome mapping effort. Here we combine a variety of in situ hybridization techniques that make the physical mapping of DNA clones to mouse chromosomes much easier. Hybridization of probes containing the mouse long interspersed repetitive element to metaphase chromosomes produces a Giemsa-like banding pattern which can be used to identify individual Mus musculus, Mus spretus, and Mus castaneus chromosomes. The DNA binding fluorophore, DAPI, gives quinacrine-like bands that can complement the hybridization banding data. Simultaneous hybridization of a differentially labeled clone of interest with the banding probe allows the assignment of a mouse clone to a specific cytogenetic band. These methods were validated by first mapping four known genes, Cpa, Ly-2, Cck, and Igh-6, on banded chromosomes. Twenty-seven additional clones, including twenty anonymous cosmids, were then mapped in a similar fashion. Known marker clones and fractional length measurements can also provide information about chromosome assignment and clone order without the necessity of recognizing banding patterns. Clones hybridizing to each murine chromosome have been identified, thus providing a panel of marker probes to assist in chromosome identification.     

Localization of the properdin factor complement locus Pfc to band A3 on the mouse X chromosome

The locus for properdin (properdin factor complement, Pfc), a plasma glycoprotein, has been mapped to band A3 of the mouse X chromosome by in situ hybridization to metaphase spreads containing an X;2 Robertsonian translocation. The X-linkage of the locus has also been confirmed by analysis of Mus musculus x Mus spretus interspecific crosses. The XA3 localization for Pfc places it in the chromosomal segment conserved between man and mouse which is known to contain at least six other homologous loci (Cybb, Otc, Syn-1 Maoa, Araf, Timp).     

Cosmid clones derived from both euchromatic and heterochromatic regions of the human Y chromosome.

Clones containing sequences derived from the human Y chromosome have been isolated from cosmid libraries of a human-mouse hybrid cell line. These libraries were constructed in the new expression vectors Homer V and Homer VI. The collection of cosmids isolated is enriched for unique sequence DNA and only a few of the cosmids contain the tandemly repeated sequences which constitute a major portion of the Y chromosome. Three cosmids have been studied in detail. One cosmid shows extensive homology over at least 20 kb with the long arm of the X chromosome; this homology is outside the predicted homology region required for sex chromosome pairing. The other two clones contain unique sequences specific to the Y chromosome and both map to the heterochromatic region of the Y chromosome long arm.     

Methylation and sequence analysis around EagI sites: identification of 28 new CpG islands in XQ24-XQ28.

Thirty-two probes for CpG islands of the distal long arm of the human X chromosome have been identified. From a genomic library of DNA of the hamster-human cell hybrid X3000.1 digested with the rare cutter restriction enzyme EagI, 53 different human clones have been isolated and characterized by methylation and sequence analysis. The characteristic pattern of DNA methylation of CpG islands at the 5' end of genes of the X chromosome has been used to distinguish between EagI sites in CpG islands versus isolated EagI sites. The sequence analysis has confirmed and completed the characterization showing that sequences at the 5' end of known genes were among the clones defined CpG islands and that the non-CpG islands clones were mostly repetitive sequences with a non-methylated or variably methylated EagI site. Thus, since clones corresponding to repetitive sequences can be easily identified by sequencing, such libraries are a very good source of CpG islands. The methylation analysis of 28 different new probes allows to state that demethylation of CpG islands of the active X and methylation of those on the inactive X chromosome are the general rule. Moreover, the finding, in all instances, of methylation differences between male and female DNA is in very strong support of the notion that most genes of the distal long arm of the X chromosome are subject to X inactivation.