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.     

Genetic and Molecular Analysis of the Proximal Region of the Mouse T-Complex Using New Molecular Probes and Partial T-Haplotypes

The t-complex is located on the proximal third of chromosome 17 in the house mouse. Naturally occurring variant forms of the t-complex, known as complete t-haplotypes, are found in wild mouse populations. The t-haplotypes contain at least four nonoverlapping inversions that suppress recombination with the wild-type chromosome, and lock into strong linkage disequilibrium loci affecting normal transmission of the chromosome, male gametogenesis and embryonic development. Partial t-haplotypes derived through rare recombination between t-haplotypes and wild-type homologs have been critical in the analysis of these properties. Utilizing two new DNA probes. Au3 and Au9, and several previously described probes, we have analyzed the genetic structure of several partial t-haplotypes that have arisen in our laboratory, as well as several wild-type chromosomes deleted for loci in this region. With this approach we have been able to further our understanding of the structural and dynamic characteristics of the proximal region of the t-complex. Specifically, we have localized the D17Tul locus as most proximal known in t-haplotypes, achieved a better structural analysis of the partial t-haplotype t6, and defined the structure and lethal gene content of partial t-haplotypes derived from the lethal tw73 haplotype.     

Genetic analysis of fertility of male mice with various t-haplotypes

Fertility of 47 mouse males carrying various combinations of lethal, t-haplotypes (t6/tw18, t12/tw18, Tw73/tw12, tw5/tw18, t6/dt5, t12/tw12, tw5/twPa-1, tw18/twPa-1, tw5/tw12) was studied in crosses with females of different genotypes. The t-haplotypes studied belong to 7 main groups of complementation. The presence of at least two factors of fertility in the t-complex was revealed. The influence of female genotype on the degree of male fertility was also demonstrated. The data presented confirm that different combinations of lethal complete t-haplotypes exhibit sterility, with the exception of t8/tw18 compound.     

Limits of the distal inversion in the t complex of the house mouse: Evidence from linkage disequilibria

The suppression of crossing-over and the consequent linkage disequilibrium of genetic markers within the t complex of the house mouse is caused by two large and two short inversions. The inversions encompass a region that is some 15 centiMorgans (cM) long in the homologous wild-type chromosome. The limits of the proximal inversions are reasonably welldefined, those of the distal inversions much less so. We have recently obtained seven new DNA markers (D17Tu) which in wild-type chromosomes map into the region presumably involved in the distal inversions of the t chromosomes. To find out whether the corresponding loci do indeed reside within the inversions, we have determined their variability among 26 complete and 12 partial t haplotypes. In addition, we also tested the same collection of t haplotypes for their variability at five D17Leh, Hba-ps4, Pim-1, and Crya-1 loci. The results suggest that the distal end of the most distal inversion lies between the loci D17Leh467 and D17Tu26. The proximal end of the large distal inversion was mapped to the region between the D17Tu43 and Hba-ps4 loci, but this assignment is rather ambiguous. The loci Pim-1, Crya-1, and the H-2 complex, which have been mapped between the Hba-sp4 and Grr within the large distal inversion, behave as if they recombine from time to time with their wildtype homologs.     

Polymorphism and Linkage of the αa-Crystallin Gene in t-Haplotypes of the Mouse

Restriction fragment polymorphisms were used to order the alpha A-crystallin locus (Crya-1) relative to other genes in mouse t-chromatin and to investigate the relatedness of alpha-A-crystallin sequences among different t-haplotypes. Analysis of DNA from t-recombinant mice mapped Crya-1 to the K end of the H-2 complex and within the distal inverted region characteristic of t-haplotypes. Hybridization with Crya-1 cDNA revealed three distinct phenotypic groups among the 17 different t-haplotypes studied. A majority (9 of 17) of the t-haplotypes were classified into a novel group (Crya-1t) characterized by restriction fragments apparently unique to t-chromosomes and therefore thought to contain alpha A-crystallin sequences descended from the original t-chromosome. A second group of t-haplotypes had restriction fragment patterns indistinguishable from those observed among many common inbred strains of mice of the Crya-1a type, and a third restriction fragment pattern, observed only in the tw121 haplotype, was indistinguishable from the fragment pattern for C3H/DiSn (Crya-1b) and several other inbred strains of mice. Thus, with respect to sequences around the Crya-1 locus, different t-haplotypes show restriction fragment polymorphisms, some of which are comparable to those found in wild-type chromosomes and provide further evidence for genetic heterogeneity in DNA from the distal region of t-haplotypes.     

Chromosomal location of the genes encoding complement components C5 and factor H in the mouse

Complementary DNA probes corresponding to the factor H and C5 polypeptides have been used to determine the chromosomal localizations of these two complement components. Both probes revealed complex and polymorphic arrays of DNA fragments in Southern blot analysis of mouse genomic DNA. Following the distribution of these bands in panels of somatic cell hybrids carrying various combinations of mouse chromosomes on a constant rat or Chinese hamster background allowed the localization of the C5-associated fragments to proximal chromosome 2 and the localization of the factor H-associated fragments to chromosome 1 or chromosome 3. Following the inheritance of DNA restriction fragment-length polymorphisms revealed by the probes in recombinant inbred mouse strains allowed the factor H-associated fragments to be mapped to Sas-1 on chromosome 1, and the C5-associated fragments to be mapped to Hc. Analysis of three-point crosses, in turn, placed the latter locus 19 cM distal to Sd on chromosome 2. We have designated the two loci Cfh and C5, respectively. This genetic analysis raises the possibility that C5 and factor H are both encoded by complex loci composed of distinct structural and regulatory genes.     

Genetic and molecular mapping of the Hmt region of mouse.

We have mapped a new region of the mouse major histocompatibility complex (MHC) that contains the nuclear gene, Hmt, for the maternally transmitted antigen, Mta. The Hmt region of chromosome 17 lies between a recombinational breakpoint distal to Tla and another proximal to Tpx-1, thus including Pgk-2. A novel MHC class I gene fragment, R4B2, was cloned and mapped to this region as was another new class I gene, Thy19.4. Both lie proximal to Pgk-2, within the distal inversion in t-haplotypes. The presence of several other MHC class I genes in the Hmt region is predicted from analysis of the recombinants that define the region.     

Linkage analysis of the Bcg gene on mouse chromosome 1. Identification of a tightly linked marker

We have mapped and determined the gene order of five cloned genes in the vicinity of the murine host resistance gene Bcg on mouse chromosome 1. For this, we have used a RFLP-type analysis in panels of 43 recombinant inbred strains, 3 congenic mouse strains, and 186 segregating backcross progeny derived from inbred strains of Bcgr and Bcgs genotypes. The Bcg alleles of segregating animals were established by in vivo infection with Mycobacterium bovis (Bacillus Calmette-Guérin) strain Montreal. Genomic DNA prepared from progenitor mouse strains was isolated, digested with restriction endonucleases, and analyzed by Southern blotting to identify strain-specific RFLP for each DNA marker tested. Among a number of DNA markers tested, Len2, Fn, Vil, Alpi, and Achrg were found to co-segregate with Bcg in mouse strains congenic for this locus. Detailed segregation analysis of the five markers and Bcg showed that Vil was extremely close to Bcg with no recombinant identified, whereas Fn and Len2 were located 4.5 and 9 cM proximal of Bcg, respectively. Alpi and Achrg mapped 5 and 5.5 cM distal from Bcg, respectively. Pedigree analysis in the recombinant inbred strains and backcross animals indicated the gene order: centromere-Len2-Fn-Vil,Bcg-Alpi-Achrg. The tightly linked Vil marker can now be used as an entry point in recombinant genomic DNA libraries to clone sequences overlapping Bcg. This group of five genes flanking Bcg on mouse chromosome 1 is precisely conserved on the telomeric end of the long arm of human chromosome 2q. Our results suggest that a likely location for a putative human homologue to the murine host resistance gene Bcg is the long arm of human chromosome 2 (2q32-qter).     

A t(4;22) in a meningioma points to the localization of a putative tumor-suppressor gene.

Cytogenetic analysis of meningioma cells from one particular patient (MN32) displayed the stem-line karyo-type 45, XY, -1, 4p+, 22q-, 22q+, which thus had rearrangements of both chromosomes 22. The 22q+ marker appeared as a dicentric: 22 pter----q11::1p11----qter. The reciprocal product of this translocation has presumably been lost because it lacked a centromere. The 22q- chromosome also appeared to have lost sequences distal to band q11. We assumed that this marker could have been the result of a reciprocal translocation between chromosomes 4 and 22. To investigate the 4p+ and 22q- chromosomes in more detail, human-hamster somatic cell hybrids were constructed that segregated the 22q- and 4p+ chromosomes. Southern blot analysis with DNA from these hybrids showed that sequences from 22q were indeed translocated to 4p+ and that reciprocally sequences from 4p were translocated to 22q-, demonstrating a balanced t(4;22)(p16;q11). On the basis of these results we presume that in this tumor a tumor-suppressor gene is deleted in the case of the 22q+ marker and that the t(4;22) disrupts the second allele of this gene. The latter translocation was mapped between D22S1 and D22S15, a distance of 1 cM on the linkage map of this chromosome. The area in which we have located the translocation is within the region where the gene predisposing to neurofibromatosis 2 has been mapped.     

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.     

The Putative Oncogene Pim-1 in the Mouse: Its Linkage and Variation among t Haplotypes

Pim-1, a putative oncogene involved in T-cell lymphomagenesis, was mapped between the pseudo-alpha globin gene Hba-4ps and the alpha-crystallin gene Crya-1 on mouse chromosome 17 and therefore within the t complex. Pim-1 restriction fragment variants were identified among t haplotypes. Analysis of restriction fragment sizes obtained with 12 endonucleases demonstrated that the Pim-1 genes in some t haplotypes were indistinguishable from the sizes for the Pim-1b allele in BALB/c inbred mice. There are now three genes, Pim-1, Crya-1 and H-2 I-E, that vary among independently derived t haplotypes and that have indistinguishable alleles in t haplotypes and inbred strains. These genes are closely linked within the distal inversion of the t complex. Because it is unlikely that these variants arose independently in t haplotypes and their wild-type homologues, we propose that an exchange of chromosomal segments, probably through double crossingover, was responsible for indistinguishable Pim-1 genes shared by certain t haplotypes and their wild-type homologues. There was, however, no apparent association between variant alleles of these three genes among t haplotypes as would be expected if a single exchange introduced these alleles into t haplotypes. If these variant alleles can be shown to be identical to the wild-type allele, then lack of association suggests that multiple exchanges have occurred during the evolution of the t complex.     

The L-isoaspartyl/D-aspartyl protein methyltransferase gene (PCMT1) maps to human chromosome 6q22.3-6q24 and the syntenic region of mouse chromosome 10.

We have mapped the genes for the human and mouse L-isoaspartyl/D-aspartyl protein carboxyl methyltransferase (EC 2.1.1.77) using cDNA probes. We determined that the human gene is present in chromosome 6 by Southern blot analysis of DNA from a panel of mouse-human somatic cell hybrids. In situ hybridization studies allowed us to confirm this identification and further localize the human gene (PCMT1) to the 6q22.3-6q24 region. By analyzing the presence of an EcoRI polymorphism in DNA from backcrosses of C57BL/6J and Mus spretus strains of mice, we localized the mouse gene (Pcmt-1) to chromosome 10, at a position 8.2 +/- 3.5 cM proximal to the Myb locus. This region of the mouse chromosome is homologous to the human 6q24 region.     

Genetic analysis of complementation of t-haplotypes in mice

Complementation for viability of the compounds tx/ty in complete lethal haplotypes t6, t12, tw5, tw12, tw18, tw73, twPa-1 belonging to the seven basic complementation groups was studied. In the overwhelming majority of crosses a lack of tx/ty offspring was revealed but there is also evidence of non-complete complementation of the tx/ty haplotypes, except for T/tw73XT/tw12, T/tw18XT/t12, T/tw73XT/tw18 crosses in which the level of complementation for viability exceeds 100%. The maternal effect for compound variability was significantly revealed in 9 out of the 19 matings. In addition, reciprocal matings of heterozygotes T/txXT/ty were tested for fertility. In two cases, the maternal effect was also revealed for this character. Comparison of data on viability of the compounds and the fertility of the original strains gives grounds to believe that the tx/ty haplotypes are not completely recessive and partially manifest themselves in the heterozygotes, decreasing fertility in a number of matings. In some cases, these t-haplotypes yield an effect, close to negative complementation, which may be associated with the interaction of the proteins of t-haplotypes.     

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.     

Ovarian teratocarcinomas in LT/Sv mice carrying t-mutations

Ovarian teratomas that result from parthenogenetic activation of oocytes provide a double tool for developmental genetics. First, they provide a way of measuring recombination between a gene and its centromere. Second, in the absence of crossing over there is the potential of producing tumors that are homozygous for genes that would be lethal in the course of in utero embryonic development. We have applied both aspects to several t-haplotypes containing different early acting t-lethal genes. In a study of 26 tumors, genotyped by Southern blot analysis of the major histocompatibility complex (MHC), we measured the distance between the centromere and the start of the t-complex as 5.6 +/- 2.3 cM. We found a marked deficiency of t-homozygous genotypes among the tumors we studied, although T/T genotypes formed teratomas at levels comparable to controls. None of the lethal t-haplotypes we studied permit homozygous embryos to develop to the primitive streak stage, while T/T embryos do develop essentially normally through that stage. Thus, although the total number of tumors observed from t-bearing mice was small, the great difference in the incidence of t/t tumors versus the incidence of T/T tumors suggests strongly that the parthenogenetic embryos that convert to teratocarcinomas must first pass through some of the stages of normal early development, including the formation of three germ layers and the primitive streak.     

Genetic mapping of the gene for a novel tyrosine kinase, Blk, to mouse chromosome 14

The gene Blk, which encodes a novel tyrosine kinase expressed preferentially in B-lymphoid cells, was mapped by Southern blot analysis of DNA from the progeny of an intersubspecific backcross. Blk maps to the proximal region of chromosome 14 with the gene order centromere--(Np-1,Tcra)-Blk-sys-Es-10.     

Gene for lymphoid enhancer-binding factor 1 (LEF1) mapped to human chromosome 4 (q23-q25) and mouse chromosome 3 near Egf.

LEF-1 is a 54-kDa nuclear protein that is expressed specifically in pre-B and T-cells. It binds to a functionally important site in the T-cell receptor alpha enhancer and contributes to maximal enhancer activity. LEF-1 is a member of a family of regulatory proteins that share homology with the high mobility group protein 1 (HMG1). The location of the LEF1 gene on human and mouse chromosomes was determined by Southern blot analysis of DNA from panels of interspecies somatic cell hybrids using a murine cDNA probe. Human-specific DNA fragments were detected in all somatic cell hybrids that retained the human chromosomal region 4cen-q31.2. Fluorescent in situ hybridization with two biotin-labeled overlapping human genomic cosmids revealed a specific hybridization signal at 4q23-q25. The homologous locus in the mouse was mapped to chromosome 3 by Southern analysis of rodent x mouse hybrid cell DNA. This chromosomal location was confirmed by the use of a restriction fragment length polymorphism (RFLP) in recombinant inbred mouse strains. The results of this RFLP analysis indicated that the mouse Lef-1 gene was closely linked to Pmv-39 and Egf and was likely placed between these loci, both of which were previously mapped to distal mouse chromosome 3. Our mapping results did not suggest involvement of this gene in previously mapped genetic disorders or in known neoplasia-associated translocation breakpoints.     

The molecular organization of the H-2K region of two t-haplotypes: implications for the evolution of genetic diversity.

The genetic diversity between the t12 and tw5 haplotype chromosomes was studied by analyzing the molecular organization of the H-2K region. Twenty-one cosmid clones spanning over 150 kb of the H-2K region of both t-haplotypes were defined, and high resolution restriction maps were determined. Detailed comparison of the t12 and tw5 restriction maps revealed the following. (i) The H-2K regions of both t-haplotypes retain a very similar molecular organization to that reported for B10, BALB/c and AKR. The nucleotide sequence diversity estimated from restriction site polymorphism is 0.68% between the t12 and tw5 haplotypes; these two t-haplotypes are no more similar to one another than BALB/c is to AKR. (ii) Genetic recombination is strongly implicated in generating H-2 polymorphism. (iii) Genetic polymorphisms, defined as small restriction fragment size differences, are observed at multiple sites along the H-2K region. An Alu-like B2 sequence and BAM5-R homologous sequence were identified as the inserted/deleted DNA segments of two of these sites, suggesting that insertion/deletion of mobile elements is a general mechanism for generating genetic diversity.