New Molecular Markers for the Distal End of the T-Complex and Their Relationships to Mutations Affecting Mouse Development

Many mutations affecting mouse development have been mapped to the t-complex of mouse chromosome 17. We have obtained 17 cosmid clones as molecular markers for this region by screening a hamster-mouse chromosome 17 and 18 cell hybrid cosmid library with mouse-specific repetitive elements and mapping positive clones via t-haplotype vs. C3H restriction fragment length polymorphism (RFLP) analysis. Twelve of the clones mapping distal to Leh66B in t-haplotypes are described here. Using standard RFLP analysis or simple sequence length polymorphism between t-haplotypes, exceptional partial t-haplotypes and nested sets of inter-t-haplotype recombinants, five cosmids have been mapped in or around In(17)3 and seven in the most distal inversion In17(4). More precise mapping of four of the cosmids from In(17)4 shows that they will be useful in the molecular identification of some of the recessive lethals mapped to the t-complex: two cosmids map between H-2K and Crya-1, setting a distal limit in t-haplotypes for the position of the tw5 lethal, one is inseparable from the tw12 lethal, and one maps distal to tf near the t0(t6) lethal and cld.     

Polymorphism of Unique Noncoding DNA Sequences in Wild and Laboratory Mice

Two DNA probes, D17Tu1 and D17Tu2, were isolated from a genomic DNA library containing only two mouse chromosomes, one of which is chromosome 17, carrying the major histocompatibility complex (H-2), as well as the t complex genes. The D17Tu1 probe was mapped to the centromeric region of chromosome 17 and the D17Tu2 probe to the S region of the H-2 complex. Neither of the two probes appeared to detect any genes, but both contained unique, nonrepetitive sequences. Typing of DNA obtained from a large panel of mice revealed the presence of four D17Tu1 patterns in inbred mouse strains, one very common, one less common, and two present in one strain each. The two common patterns could not be detected in appreciable frequencies in the European wild mice tested (one of the two patterns was, however, found in Australian wild mice). Conversely, the patterns found frequently in European wild mice are absent in the laboratory mice. We therefore conclude that wild mice from the sampled regions of Europe could not have provided the ancestral stocks from which inbred strains were derived. Only one D17Tu1 pattern was found in all the populations of Mus musculus tested, while eight patterns were found in Mus domesticus, with virtually all the populations being polymorphic. We suggest that this difference reflects different modes in which the two species colonized Europe. The distribution of the D17Tu2 patterns in inbred strains correlates with the distribution of H-2 haplotypes.     

The Locus Encoding αa-Crystallin Is Closely Linked to H-2K on Mouse Chromosome 17

We have used a complementary DNA (cDNA) for mouse alpha A-crystallin to probe genomic DNA for restriction fragment length polymorphisms which could be used to map the alpha A-crystallin gene locus (Acry-1) in the mouse genome. Ten of 12 restriction endonucleases produced fragment polymorphism among various inbred strains of mice. A comprehensive strain survey conducted with six endonucleases resulted in the discovery of six allelic forms of Acry-1. Linkage analysis was conducted on DNA from three sets of recombinant inbred strains of mice and demonstrated close linkage of Acry-1 with the major histocompatibility complex (H-2) on chromosome 17. Analysis of congenic and recombinant congenic strains of mice confirmed the linkage of Acry-1 and H-2 and located the alpha A gene to the region between glyoxylase (Glo-1) and H-2K.     

Genetic Analysis of a Mouse t Complex Locus That Is Homologous to a Kidney Cdna Clone

A mouse kidney cDNA clone, pMK174, identifies restriction fragment length polymorphisms (RFLPs) that map to two unlinked loci. One, designated D17Rp17, has been mapped near quaking, (qk), on chromosome 17 using three sets of recombinant inbred (RI) strains. A study of several t haplotypes resulted in the identification of t-specific alleles of D17Rp17 that map to the proximal half of the t complex. Neither t-specific nor wild-type D17Rp17 alleles are present in chromosomes carrying either the T Orleans (TtOrl) or the T hairpin tail (Thp) deletions. Comparison with other molecular markers indicates that pMK174 identifies a new proximal t complex locus, Rp17. The second locus identified by pMK174, termed D4Rp18, is tentatively assigned to chromosome 4 by mouse-Chinese hamster somatic cell hybrid analysis.     

Mapping of PCR-based markers for mouse Chromosome 4 on a backcross penetrant for the misty (m) mutation

A genetic linkage map for mouse Chromosome (Chr) 4 (MMU 4) has been constructed with an intersubspecific backcross between the C57BL/KsJ strain homozygous for the misty (m) coat color locus and the inbred Mus musculus musculus Czech II strain. Several recently developed PCR-based simple sequence length polymorphism (SSLP) markers have been intercalated among genebased markers including six anchor loci on mouse Chr 4 to assemble this map. Marker order and genetic distances are similar to the composite genetic linkage map compiled from crosses between a variety of other inbred and feral mouse strains. Transmission ratio distortion in favor of feral alleles is apparent for a region of distal MMU 4. In addition, the misty phenotype is more fully penetrant in the present backcross than in other reported interspecific and intersubspecific crosses. Backcrosses employing inbred Mus musculus musculus strains may allow reliable phenotyping and mapping of mouse mutations displaying complex phenotypes with incomplete and/or ambigious penetrance on other feral genetic backgrounds.     

Identification of a 118-kb DNA fragment containing the locus of blast resistance gene Pi-2(t) in rice

Rice blast disease, caused by the fungal pathogen Pyricularia grisea Sacc., is one of the most devastating crop diseases worldwide. Previous studies have shown that the dominant blast resistance gene Pi-2(t) confers resistance to a broad spectrum of pathogenic strains. Using a population of 292 recombinant inbred lines combined with bioinformatic analysis, we mapped Pi-2(t) between the SSR (simple-sequence repeat) marker SSR140 and the RFLP (restriction fragment length polymorphism) marker JSH12, 0.9 cM from both SSR140 and JSH12. A physical map consisting of six overlapping BAC (bacterial artificial chromosome) clones was anchored to the region containing the Pi-2(t) locus. By analyzing recombination events in this region, the Pi-2(t) locus was localized to a DNA fragment of 118 kb in length. The detailed genetic and physical maps of the Pi-2(t) locus will facilitate both molecular isolation of the gene and marker-assisted transfer of the gene in breeding programs.     

Targeting of marker loci to chicken chromosome 16 by representational difference analysis

Representational difference analysis (RDA) was initially used to identify differences between two inbred lines of chickens, line N and line 15I, on which the Compton mapping reference population is based. RDA was subsequently used to identify marker loci targeted specifically to chicken chromosome 16. Chromosome 16 contains the major histocompatibility complex (MHC), nucleolar organiser region (NOR) and Rfp-Y complex. To generate markers specific for this chromosome a bird was selected from the Compton mapping reference population which had inherited N line alleles for the MHC, NOR and Rfp-Y regions on this chromosome. DNA from this bird was compared with pooled DNA from 16 of its siblings, all of which had inherited line 15I alleles for the MHC, NOR and Rfp-Y regions. Initially amplicons were derived from Bam HI digested samples, RDA products were cloned after the first round of hybridisation and 113 clones were investigated: 45 of these identified Bam HI polymorphisms in this population. Of the 45 polymorphic clones, 17 have been mapped in the reference population so far, and these have identified seven new loci on chromosome 16. Interestingly a group of 16 other loci were linked on chromosome 4. The same birds were also compared by RDA following digestion with Taq I. Again large numbers of clones were generated of which 65 were investigated. Of these 17 clones were polymorphic and of five clones mapped so far three lie on chromosome 16. Two of the loci mapped to chromosome 16 have been used to identify yeast artificial chromosome (YAC) clones (GenBank accession numbers: AF057302, AF057303, AF057304, AF063218, AF06347, AF06348, AF06349, AF06350, AF063#51, AF06353, AF06354, AF06355, AF06356).     

Selection of human chromosome 21-specific DNA probes for genetic analysis in Alzheimer's dementia and Down syndrome

Summary We used a mouse-human somatic cell hybrid to construct a chromosome 21-enriched library in phage vector EMBL4. In all, 35 phage clones containing human inserts were identified by differential screening with total human and mouse DNA. Whole recombinant phages were regionally mapped on chromosome 21 by Southern blot analysis using competitive hybridisation conditions to block repetitive sequences. Ten phage clones mapped proximal to a translocation breakpoint in band 21q21.2, while 25 mapped distal to this point. Three of the phage clones identify restriction fragment length polymorphisms. Polymorphic chromosome 21 markers may be useful in the genetic analysis of Alzheimer's dementia and Down syndrome.     

Mapping of the L-methylmalonyl-CoA mutase gene to mouse chromosome 17

In humans, methylmalonyl acidemia is caused by a deficiency of L-methylmalonyl-CoA mutase (MUT) controlled by a gene that has been mapped to chromosome 6. The mouse homolog of this gene has now been mapped to mouse chromosome 17. Recombinant inbred and congenic strains place the mouse Mut locus 1.06 cM distal to H-2, between Pgk-2 and Ce-2. The relative order of syntenic probes flanking H-2 on mouse chromosome 17 and HLA on human chromosome 6 is shown to be different.     

Genetic structure and origin of t haplotypes of mice, analyzed with H-2 cDNA probes

We investigated the genetic organization and evolutionary origin of t chromosomes of mice by examining the restriction fragment patterns of DNA from t haplotypes and normal chromosomes with cDNA probes to H-2 class I genes. On genomic DNA blots, the restriction fragments containing H-2-related sequences were highly variable among different inbred strains of mice, whereas they were very similar among different t haplotypes even when the t haplotypes carried serologically different H-2 haplotypes. These observations suggest that all t haplotypes have a common origin and are not products of independent mutational events. We also mapped the position of several restriction fragments characteristic of t DNA by using a battery of recombinant t haplotypes, defined with respect to their t-lethal factors and H-2 haplotypes. We thus show that restriction fragments containing H-2-related sequences map to the left of the H-2 class I genes in t chromosomes, a region in which the tw32 b-lethal factor also maps. The cloning of these fragments can be expected to provide an entry for the structural analysis of t DNA.     

A BAC contig map over the proximal approximately 3.3 Mb region of horse chromosome 21

A total of 207 BAC clones containing 155 loci were isolated and arranged into a map of linearly ordered overlapping clones over the proximal part of horse chromosome 21 (ECA21), which corresponds to the proximal half of the short arm of human chromosome 19 (HSA19p) and part of HSA5. The clones form two contigs - each corresponding to the respective human chromosomes - that are estimated to be separated by a gap of approximately 200 kb. Of the 155 markers present in the two contigs, 141 (33 genes and 108 STS) were generated and mapped in this study. The BACs provide a 4-5x coverage of the region and span an estimated length of approximately 3.3 Mb. The region presently contains one mapped marker per 22 kb on average, which represents a major improvement over the previous resolution of one marker per 380 kb obtained through the generation of a dense RH map for this segment. Dual color fluorescence in situ hybridization on metaphase and interphase chromosomes verified the relative order of some of the BACs and helped to orient them accurately in the contigs. Despite having similar gene order and content, the equine region covered by the contigs appears to be distinctly smaller than the corresponding region in human (3.3 Mb vs. 5.5-6 Mb) because the latter harbors a host of repetitive elements and gene families unique to humans/primates. Considering limited representation of the region in the latest version of the horse whole genome sequence EquCab2, the dense map developed in this study will prove useful for the assembly and annotation of the sequence data on ECA21 and will be instrumental in rapid search and isolation of candidate genes for traits mapped to this region.     

Characterization ofH-2 congenic strains using DNA markers

Congenic mouse strains are widely used in mapping traits to specific loci or short chromosomal regions. The precision of the mapping depends on the information available about the length of the differential segment—the segment introduced from the donor into the background strain. Until recently, very few markers flanking the differential locus were known and consequently the length of the foreign segment could only be determined imprecisely. Now, in an attempt to construct a map of the mouse chromosome 17, we have produced a set of DNA markers distributed along the chromosome. These markers provide a new opportunity to measure the length of the differential segment of the congenic strains and thus increase their usefulness for gene mapping. Here we examined the DNA of 96H-2 congenic strains using 30 DNA markers; of these, the most proximal is located roughly 1.5 centiMorgans (cM) from the centromere and the most distal is about 20 cM telomeric from theH-2 complex (the complex itself being some 20 cM from the centromere). The mapping depends on polymorphism among the input strains and can therefore establish only the minimal length of the differential segment. This point is emphasized by the fact that the average observed length of the differential segment is only about one half of the expected values. Offprint requests to: V. Vincek.     

TheD17Tu5 locus in thet complex: implications for the origin oft haplotypes and inbred strains

The mouse × Chinese hamster cell line R4 4-1 contains only one mouse chromosome, the bulk of which corresponds toMus musculus chromosomes 17 and 18 (MMU17 and MMU18, respectively). A genomic library was prepared from the R4 4-1 DNA, and a mouse clone was isolated from the library, which—with the help of somatic cell hybrids-could be mapped to the MMU17. A locus defined by a 2.7-kb longBam HI probe from this clone was designatedD17Tu5 (Tu for Tübingen). The locus proved to be polymorphic among inbred strains and wild mice. By testing of recombinant inbred strains and partialt haplotypes, theD17Tu5 locus could be mapped to a position between theD17Leh66E andD17Rp17 loci within thet complex. Two alleles were found at this locus,D17Tu5 ^a andD17Tu5 ^b , defined byTaq I restriction fragment length polymorphism. Both alleles are present among inbred strains and wild mice of the speciesM. domesticus. All completet haplotypes tested carry theD17Tu5 ^a allele and all tested wild mice of the speciesM. musculus, with the exception of those bearingt haplotypes, carry theD17Tu5 ^b allele. Additional alleles are found in some populations of wild mice and in other species of the genusMus. The distribution of the two alleles among the inbred strains correlates well with their known or postulated genealogy. Their distribution between the two species ofMus and among the mice withT haplotypes suggests a relatively recent origin of thet haplotypes.     

A pseudogene homologous to mouse transplantation antigens: Transplantation antigens are encoded by eight exons that correlate with protein domains

We have isolated about 30 to 40 different BALB/c mouse sperm DNA genomic clones that hybridize to cDNA clones encoding proteins homologous to transplantation antigens. One of these clones (27.1) was selected for sequence analysis because it was polymorphic in Southern blot analyses of the DNAs from BALB/c and CBA mice. A fragment of 5.7 kilobases of this clone was completely sequenced and found to contain a pseudogene whose sequence is highly homologous to the sequences of known transplantation antigens. Pseudogene 27.1 is split into eight exons that correlate with the structurally defined protein domains of transplantation antigens. Using Southern blot hybridization on the DNAs of different inbred mouse strains, we mapped the pseudogene to the Qa-2,3 region, a part of the Tla complex on chromosome 17 that is adjacent to the major histocompatibility complex. The Qa-2,3 region encodes lymphoid differentiation antigens homologous to the transplantation antigens in size, in peptide map profiles and in their association with β2-microglobulin. These mapping studies suggest that gene 27.1 may be a pseudogene for either a Qa antigen or an as yet undefined transplantation antigen. Accordingly, we may have isolated genes encoding lymphoid differentiation antigens of the Tla complex as well as those encoding transplantation antigens among the 30 to 40 different genomic clones isolated from our sperm library.     

Human chromosome 17 NotI linking clones and their use in long-range restriction mapping of the Miller-Dieker chromosome region (MDCR) in 17p13.3

A NotI linking library constructed from flow-sorted human chromosome 17 material was screened to aid in construction of a long-range restriction map of the Miller-Dieker chromosome region (MDCR) in 17p13.3. A total of 66 clones were mapped to one of eight regions of chromosome 17 using a somatic cell hybrid panel, and 44/66 (67%) of these clones cross-hybridized to rodent DNA on Southern blots. Of these, 24 clones were tested and all mapped to mouse chromosome 11, the homolog of human chromosome 17. Four linking clones mapped to 17p13.3 and were used for pulsed-field gel electrophoresis studies along with six other anonymous probes previously mapped to this region. Clone L132 was found to be deleted in all Miller-Dieker patients tested (n = 15) and therefore lies within the critical region for this disorder. It detects two NotI fragments (180 and 320 kb), one of which (320 kb) was shared by YNZ22 and YNH37, two probes previously shown to be co-deleted in all patients with the Miller-Dieker syndrome (MDS). These results indicate that all MDS patients share a minimum deletion region of greater than 370 kb. Two other NotI clones, L53 and L125, mapped telomeric to the MDS critical region and share a 600-kb MluI fragment with each other and with YNZ22/YNH37. This provides a 930-kb MluI map that encompasses the distal boundary of the MDS critical region but does not include the proximal boundary. A total of over 2 Mbp is represented in the MluI fragments by probes in subband p13.3, a cytogenetic region estimated to be 3-4 Mbp.     

Mapping and cloning of a fla-che region of the Rhizobium meliloti chromosome.

We constructed a genetic map of the fla-che region of the Rhizobium meliloti chromosome using cotransduction with bacteriophage phi M12. Several other chromosomal markers located in the general area are included in the map. We isolated plasmids carrying wild-type DNA inserts that complement the mapped mutations from a genomic library carried in the broad-host-range vector pLAFR1. The complementation data obtained from the clones confirmed the contransduction map and clarified the exact order of several of the behavioral genes. A restriction map of this area was developed by using the cloned DNA. One of the five individual EcoRI fragments subcloned from the original clones complemented two of the behavioral mutations.     

Genetic mapping of Prm-1, Igl-1, Smst, Mtv-6, Sod-1, and Ets-2 and localization of the Down syndrome region on mouse chromosome 16

Molecular probes were used as markers in the backcross (Czech II X BALB/cPt) X Czech II to determine the positions of six genes on mouse chromosome 16 (MMU 16). The order of the genes mapped is (centromere), protamine-1 (Prm-1), immunoglobulin lambda 1 light chain (Igl-1), preprosomatostatin (Smst), an endogenous mouse mammary tumor virus locus (Mtv-6), and two more distal sequences, superoxide dismutase, cytoplasmic form (Sod-1), and the proto-oncogene sequence Ets-2. The largest recombination frequency between any two adjacent markers is 24 cM, and thus the position of any marker on MMU 16 that is polymorphic between these two strains can be readily determined in this backcross. A region of MMU 16 which corresponds to the Down syndrome region of human chromosome 21 is located near the distal end of the chromosome.     

Chromosome 16-specific repetitive DNA sequences that map to chromosomal regions known to undergo breakage/rearrangement in leukemia cells.

Human chromosome 16-specific low-abundance repetitive (CH16LAR) DNA sequences have been identified during the course of constructing a physical map of this chromosome. At least three CH16LAR sequences exist and they are interspersed, in small clusters, over four regions that constitute more than 5% of the chromosome. CH16LAR sequences were observed in one unusually large cosmid contig (number 55), where the ordering of clones was difficult because these sequences led to false overlaps between noncontiguous clones. Contig 55 contains 78 clones, or approximately 2% of all the clones contained within the present cosmid contig physical map. Fluorescent in situ hybridization of multiple clones, including cosmid and YAC contig 55 clones, mapped the four CH16LAR-rich regions to bands p13, p12, p11, and q22. These regions are of biological interest since the pericentric inversion and the interhomologue translocation breakpoints commonly found in acute nonlymphocytic leukemia (ANLL) subtype M4 fall within these bands. Sequence analysis of a 2.2-kb HindIII fragment from a cosmid containing a CH16LAR sequence indicated that one of the CH16LAR elements is similar to a minisatellite sequence in that the core repeat is only 40 bp in length. Additional characterization of other repetitive elements is in progress.     

A high-resolution comparative RH map of the proximal part of bovine chromosome 1

Current comparative maps between human chromosome 21 and the proximal part of cattle chromosome 1 are insufficient to define chromosomal rearrangements because of the low density of mapped genes in the bovine genome. The recently completed sequence of human chromosome 21 facilitates the detailed comparative analysis of corresponding segments on BTA1. In this study eight bovine bacterial artificial chromosome (BAC) clones containing bovine orthologues of human chromosome 21 genes, i.e. GRIK1, CLDN8, TIAM1, HUNK, SYNJ1, OLIG2, IL10RB, and KCNE2 were physically assigned by fluorescence in situ hybridization (FISH) to BTA1q12.1-q12.2. Sequence tagged site (STS) markers derived from these clones were mapped on the 3000 rad Roslin/Cambridge bovine radiation hybrid (RH) panel. In addition to these eight novel markers, 17 known markers from previously published BTA1 linkage or RH maps were also mapped on the Roslin/Cambridge bovine RH panel resulting in an integrated map with 25 markers of 355.4 cR(3000) length. The human-cattle genome comparison revealed the existence of three chromosomal breakpoints and two probable inversions in this region.     

Genetic map of nine polymorphic loci comprising a single linkage group on rat chromosome 10: evidence for linkage conservation with human chromosome 17 and mouse chromosome 11.

Seven genes and two anonymous markers were mapped to a single linkage group on rat chromosome 10 using progeny of an F2 intercross of Fischer (F344/N) and Lewis (LEW/N) inbred rats. Two genes, the neu oncogene or cellular homologue of the viral oncogene erbb2 (ERBB2) and growth hormone (GH) were mapped by Southern blot analysis of restriction fragment length polymorphisms. Five genes, embryonic skeletal myosin heavy chain (MYH3), androgen binding protein/sex hormone binding globulin (SHBG), asialoglycoprotein receptor (hepatic lectin)-1 (ASGR1), ATP citrate lysase (CLATP), and pancreatic polypeptide (PPY), and two anonymous markers, F16F2 and F10F1, were mapped using PCR amplification techniques. The PCR-typable polymorphic markers for the five genes were also highly polymorphic in 10 other inbred rat strains (SHR/N, WKY/N, MNR/N, MR/N, LOU/MN, BN/SsN, BUF/N, WBB1/N, WBB2/N, and ACI/N). These markers should be useful in genetic analysis of traits described in inbred rat strains, as well as in genetic monitoring of such strains. The loci in this linkage group covered 50 cM of rat chromosome 10 with the following order: MYH3, SHBG/ASGR1 (no recombinants detected), F16F2, ERBB2, CLATP, PPY, GH, and F10F1. Comparative gene mapping analysis indicated that this region of rat chromosome 10 exhibits linkage conservation with regions of human chromosome 17 and mouse chromosome 11.