Genetic mapping of thet-complex region on mouse chromosome 17 including theHybrid sterility-1 gene

t-haplotypes occupy a region on chromosome (Chr) 17 which slightly overlaps the ends of theT-H-2 interval. The wild-type form of this 14 centi-Morgan (cM) region was mapped in a multilocus backcross (C57BL/10-T×C3H)F₁×C57BL/10 using 15 DNA probes on Southern blots of the DNA extracted from 53 animals which were recombinants in theT-H-2 interval. Each recombinant was also progenytested to ascertain itsHybrid sterility-1 (Hst-1) genotype by crossing to PWB/Ph, aMus musculus-derived inbred strain. The limit of resolution of the cross was 0.27 cM. The map distances have been determined for the DNA loci in theT-H-2 interval and theHst-1 gene was mapped in close vicinity to theD17Rp17 locus.     

The achondroplasia gene is not linked to the locus for neurofibromatosis 1 on chromosome 17

Summary We have investigated genetic linkage of von Recklinghausen neurofibromatosis (NF1) and achondroplasia (ACH) using chromosome-17 markers that are known to be linked to NF1. Physical proximity of the two loci was suggested by the report of a patient with mental retardation and the de novo occurrence of both NF1 and ACH. Since the chance of de novo occurrence of these two disorders in one individual is 1 in 600 million, this suggested a chromosomal deletion as a single unifying molecular event and also that the ACH and NF1 loci might be physically close. To test this, we performed linkage analysis on a three-generation family with ACH. We used seven DNA probes that are tightly linked to the NF1 locus, including DNA sequences that are known to flank the NF1 locus on the centromeric and telomeric side. We detected two recombinants between the ACH trait and markers flanking the NF1 locus. In one recombinant, the flanking markers themselves were nonrecombinant. Multi-point linkage analysis excluded the ACH locus from a region surrounding the NF1 locus that spans more than 15cM (lod score < -2). Therefore, analysis of this ACH pedigree suggests that the ACH locus is not linked to the NF1 locus on chromosome 17.     

Obesity QTLs on Mouse Chromosomes 2 and 17

The inheritance of obesity has been analyzed in an intercross between the mouse strains AKR/J and C57L/J. Two novel obesity quantitative trait loci (QTLs) have been identified using the strategy of selective DNA pooling. One QTL affecting adiposity,Obq3,was mapped to a 39-cM segment near the middle of Chromosome 2, with a peak lod score (5.1) just distal to theD2Mit15locus. The AKR/JObq3allele confers increased adiposity in a nearly additive manner, and males are more affected than females. A second obesity QTL (Obq4) maps to the centromeric end of Chromosome 17, with a lod score peak of 4.6 atD17Mit143.The obesity-conferring allele is contributed by C57L/J and acts in a recessive or an additive manner.Obq4also has more influence in males and affects the inguinal fat depot differentially.Obq3andObq4account for 7.0 and 6.1% of the phenotypic variance in adiposity (gender-merged data), respectively. The possible relationships between these QTLs and previously described obesity QTLs and candidate genes are discussed. The large number of different obesity QTLs that have been described in mice and the relatively small effects contributed by individual loci suggest considerable genetic complexity.     

Viral sequences are associated with many histocompatibility genes

A C57BL/6By 5.5 kb Pvu II polymorphic restriction fragment which hybridizes with a spleen focus-forming env probe and maps in the H-30 region has been cloned, and a 358 by subfragment subcloned. Hybridization and sequencing studies show that the 358 by fragment is encoded by the region of the pol gene of murine retrovirus which codes for an endonuclease critical for viral integration. Hybridizations of digested murine genomic DNAs with the 358 by probe generate 31 restriction fragment length polymorphisms (RFLPs); 16 of these can be placed near the following 15 minor histocompatibility (H) loci: H-3, H-4, H-7, H-13, H-15, H-16, H-17, H-19, H-22, H-24, H-27, H-30, H-34, H-36, and H-38. We suggest that the proximity of viral sequences to H loci is probably evolutionarily and functionally significant and that the closeness of viral sequences and minor H loci can probably be utilized to facilitate the cloning of minor H genes. During the course of these studies, it has become possible to tentatively assign H-17, H-34, and H-38 to chromosome 12. In addition, it was observed that several H-2 congenic strains retain portions of chromosome 12 from the parental donor strains used in their derivation.     

RASA4 undergoes DNA hypermethylation in resistant juvenile myelomonocytic leukemia

Aberrant DNA methylation at specific genetic loci is a key molecular feature of juvenile myelomonocytic leukemia (JMML) with poor prognosis. Using quantitative high-resolution mass spectrometry, we identified RASA4 isoform 2, which maps to chromosome 7 and encodes a member of the GAP1 family of GTPase-activating proteins for small G proteins, as a recurrent target of isoform-specific DNA hypermethylation in JMML (51% of 125 patients analyzed). RASA4 isoform 2 promoter methylation correlated with clinical parameters predicting poor prognosis (older age, elevated fetal hemoglobin), with higher risk of relapse after hematopoietic stem cell transplantation, and with PTPN11 mutation. The level of isoform 2 methylation increased in relapsed cases after transplantation. Interestingly, most JMML cases with monosomy 7 exhibited hypermethylation on the remaining RASA4 allele. The results corroborate the significance of epigenetic modifications in the phenotype of aggressive JMML.     

The genetic control of liver cAMP levels in mice

Steady-state level of liver 3,5-cyclic monophosphate, cAMP, has been shown to be under genetic control linked to the mouseH-2 complex. Liver cAMP levels are associated withH-2 haplotype in fully segregating crosses of strains C3H and C57BL/10. In crosses involving strain A, other loci have an effect that swamps that ofH-2. Results withH-2 recombinants indicate that liver cAMP levels are affected by more than oneH-2-linked locus.     

Linkage map of mouse chromosome 17: localization of 27 new DNA markers

Chromosome 17 of the laboratory variant of the house mouse (Mus musculus L.), MMU17, has been studied extensively, largely because of its involvement in the control of immune response and embryonic as well as male germ cell differentiation. A detailed linkage map of this chromosome is therefore a highly desired goal. As the first step toward achieving this goal, we have isolated, using a LINE 1 repetitive sequence as a probe, 52 anonymous DNA clones from MMU17. Twenty-seven repetitive sequence-free probes isolated from these clones displayed restriction fragment length variation among common inbred strains and could be mapped with the help of recombinant inbred strains, congenic strains, F2 segregants, or intra-t recombinants. Together with markers identified previously, the new markers can be used to construct a map of MMU17 that contains 125 DNA loci. The markers are distributed over a length of approximately 71 cM, which probably represents the entire length of MMU17. Most of the markers reside in the proximal portion of the chromosome, which contains the t and H-2 complexes; this chromosomal region is now fairly well mapped. The distal region of MMU17, on the other hand, is populated by only a few, rather imprecisely mapped markers. Molecular maps are available for most of the H-2 complex and for parts of the t complex.     

Glucocorticoid-induced cleft palate genes in chromosome 17: Genetic linkage and mapping analyses

Genes that influence susceptibility to dexamethasone-induced cleft palate and tentatively designated Dcp are linked to the major histocompatibility complex H-2 in chromosome 17 of the mouse. Experiments presented refine the map of genes. The results show two or three Dcp loci. The two-locus model maps Dcp genes to the class II gene E and to the chromosomal region between the S and D genes. The three-locus model maps the Dcp genes to the chromosomal regions from the centromere to E , from E to S, and from D to Pgk-2. Experiments were done by comparing the dexamethasone-induced cleft palate dose response of congenic strains with H-2 haplotypes that are recombinants of H-2 ^aand H-2 ^b. The analysis of genetic linkage between H-2 and Dcp was expanded to include reciprocal backcrosses. A maternal factor was found to influence the frequency of dexamethasone-induced cleft palate in the backcross fetuses. The factor's origin is associated with the H-2 haplotype of the outcross mother, so the effect is actually a grandmother effect that probably is transmitted horizontally. Finally, the sexes were distributed unevenly between the fetuses with cleft palate in two of the congenic strains. This suggests interaction between the H-2-linked Dcp genes and a Dcp sex-associated gene that modulates susceptibility to dexamethasone-induced cleft palate.     

Eyespot resistance gene Pch-1 in H-93 wheat lines. Evidence of linkage to markers of chromosome group 7 and resolution from the endopeptidase locus Ep-D1b

Summary Gene Pch1, which confers resistance to eyespot disease (Pseudocercosporella herpotrichoides Fron), has been located on chromosome 7D in the H-93 wheat-Aegilops ventricosa transfer lines using isozyme markers and DNA probes corresponding to group 7 chromosomes. Previous experiments had failed to ascertain this location. The lack of segregation of the resistance trait in progeny from reciprocal crosses between lines H-93-70 and VPM1 indicates that their respective resistance factors are allelic. Line H-93-51 carries the endopeptidase allele Ep-D1b but is susceptible to eyespot, which indicates that resistance to eyespot is not a product of the Ep-D locus, as had been proposed in a previous hypohesis.     

Deletion Mapping of Four Loci Defined by N-Ethyl-N-Nitrosourea-Induced Postimplantation-Lethal Mutations within the Pid-Hbb Region of Mouse Chromosome 7

As part of a long-term effort to refine the physical and functional maps of the Fes-Hbb region of mouse chromosome 7, four loci [l(7)1Rn, l(7)2Rn, l(7)3Rn, l(7)4Rn] defined by N-ethyl-N-nitrosourea (ENU)-induced, prenatally lethal mutations were mapped by means of trans complementation crosses to mice carrying lethal deletions of the mouse chromosome-7 albino (c) locus. Each locus was assigned to a defined subregion of the deletion map at the distal end of the Fes-Hbb interval. Of particular use for this mapping were preimplantation-lethal deletions having distal breakpoints localized between pid and Omp. Hemizygosity or homozygosity for each of the ENU-induced lethals was found to arrest development after uterine implantation; the specific time of postimplantation death varied, and depended on both the mutation itself and on whether it was hemizygous or homozygous. Based on their map positions outside of and distal to deletions that cause death at preimplantation stages, these ENU-induced mutations identify loci, necessary for postimplantation development, that could not have been discovered by phenotypic analyses of mice homozygous for any albino deletion. The mapping of these loci to specific genetic intervals defined by deletion breakpoints suggests a number of positional-cloning strategies for the molecular isolation of these genes. Phenotypic and genetic analyses of these mutations should provide useful information on the functional composition of the corresponding segment of the human genome (perhaps human 11q13.5).     

Definitive chromosomal location of the H-2 complex by in situ hybridization to pachytene chromosomes

Chromosome 17 of the mouse carries the H-2 complex and the T/t complex. An understanding of the organization of this region and an accurate genetic map of chromosome 17 would be of great value for both immunologists and developmental biologists. Until now the only maps available have been derived solely from recombinational studies using several translocations, an inherently inaccurate method. We have found the definitive location of the H-2 complex by the use of in situ hybridization. Our results show that both the T/t complex and the H-2 complex map to positions far more distal than the generally accepted map positions. This proves that recombination in Robertsonian chromosomes underestimates physical map distances on chromosome 17.     

Localization and cloning of Xp21 deletion breakpoints involved in muscular dystrophy

Summary Twenty-nine deletion breakpoints were mapped in 220 kb of the DXS164 locus relative to potential exons of the Duchenne and Becker muscular dystrophy gene. Four deletion junction fragments were isolated to acquire outlying Xp21 loci on both the terminal and centromere side of the DXS164 locus. The junction loci were used for chromosome walking, searches for DNA polymorphisms, and mapping against deletion and translocation breakpoints. Forty-four unrelated deletions were analyzed using the junction loci as hybridization probes to map the endpoints between cloned Xp21 loci. DNA polymorphisms from the DXS164 and junction loci were used to follow the segregation of a mutation in a family that represents a recombinant. Both the physical and genetic data point to a very large size for this X-linked muscular dystrophy locus.     

Diploid state of phenotypically recombinant progeny arising after protoplast fusion in Bacillus subtilis

Summary After fusion of Bacillus subtilis protoplasts the phenotypically recombinant clones isolated, whether immediately or as segregants of complementing diploid clones, have in common the following properties. They appear independently of the recN ⁺ gene, most often as the result of apparently non-reciprocal recombination occurring in genetic intervals encompassing the origin and the terminus of replication. First indicated by reciprocal fusion crosses between 105-lysogenic and 105-sensitive strains, the diploidy of the recombinants was confirmed by studying the transforming activities of their DNA. These experiments establish heterozygosity at eight loci scattered on the chromosome map. By revealing the presence of the rpF ⁺ allele in trpF7 recombinants, the results also strongly suggest that stable phenotypic recombinants may arise by genetic inactivation. Two possible genetic structures for these recombinants are discussed, one implying total inactivation of one recombinant chromosome, the other a segmentary inactivation of one unrecombined chromosome. Whatever the structure, genetic stability is not a reliable sign of haploidy in bacterial clones produced after protoplast fusion.     

High-density genetic and physical bin mapping of wheat chromosome 1D reveals that the powdery mildew resistance gene <Emphasis Type="Italic">Pm24</Emphasis> is located in a highly recombinogenic region

Genetic maps of wheat chromosome 1D consisting of 57 microsatellite marker loci were constructed using Chinese Spring (CS) × Chiyacao F₂ and the International Triticeae Mapping Initiative (ITMI) recombinant inbred lines (RILs) mapping populations. Marker order was consistent, but genetic distances of neighboring markers were different in two populations. Physical bin map of 57 microsatellite marker loci was generated by means of 10 CS 1D deletion lines. The physical bin mapping indicated that microsatellite marker loci were not randomly distributed on chromosome 1D. Nineteen of the 24 (79.2%) microsatellite markers were mapped in the distal 30% genomic region of 1DS, whereas 25 of the 33 (75.8%) markers were assigned to the distal 59% region of 1DL. The powdery mildew resistance gene Pm24, originating from the Chinese wheat landrace Chiyacao, was previously mapped in the vicinity of the centromere on the short arm of chromosome 1D. A high density genetic map of chromosome 1D was constructed, consisting of 36 markers and Pm24, with a total map length of 292.7 cM. Twelve marker loci were found to be closely linked to Pm24. Pm24 was flanked by Xgwm789 (Xgwm603) and Xbarc229 with genetic distances of 2.4 and 3.6 cM, respectively, whereas a microsatellite marker Xgwm1291 co-segregated with Pm24. The microsatellite marker Xgwm1291 was assigned to the bin 1DS5-0.70-1.00 of the chromosome arm 1DS. It could be concluded that Pm24 is located in the ‘1S0.8 gene-rich region’, a highly recombinogenic region of wheat. The results presented here would provide a start point for the map-based cloning of Pm24.     

A Genetic Linkage Map of the Mouse Using Restriction Landmark Genomic Scanning (Rlgs)

We have developed a multiplex method of genome analysis, restriction landmark genomic scanning (RLGS) that has been used to construct genetic maps in mice. Restriction landmarks are end-labeled restriction fragments of genomic DNA that are separated by using high resolution, two-dimensional gel electrophoresis identifying as many as two thousand landmark loci in a single gel. Variation for several hundred of these loci has been identified between laboratory strains and between these strains and Mus spretus. The segregation of more than 1100 RLGS loci has been analyxed in recombinant inbred (RI) strains and in two separate interspecific genetic crosses. Genetic maps have been derived that link 1045 RLGS loci to reference loci on all of the autosomes and the X chromosome of the mouse genome. The RLGS method can be applied to genome analysis in many different organisms to identify genomic loci because it used end-labeling of restriction landmarks rather than probe hybridization. Different combinations of restriction enzymes yield different sets of RLGS loci providing expanded power for genetic mapping.     

Molecular Genetics of the Brown (B)-Locus Region of Mouse Chromosome 4. II. Complementation Analyses of Lethal Brown Deletions

Numerous new mutations at the brown (b) locus in mouse chromosome 4 have been recovered over the years in germ-cell mutagenesis experiments performed at the Oak Ridge National Laboratory. A large series of radiation- and chemical-induced b mutations known to be chromosomal deletions, and also known to be prenatally lethal when homozygous, were analyzed by pairwise complementation crosses as well as by pseudodominance tests involving flanking loci defined by externally visible phenotypes. These crosses were designed to determine the extent of each deletion on the genetic and phenotype map of the chromosomal region surrounding the b locus; the crosses also provided basic data that assigned deletions to complementation groups and defined four new loci associated with aberrancies in normal development. Specifically, the pseudodominance tests identified deletions that include the proximally mapping whirler (wi) and the distally mapping depilated (dep) genes, thereby bracketing these loci defined by visible developmental abnormalities with landmarks (deletion breakpoints) that are easily identified on the physical map. Furthermore, the complementation crosses, which were supplemented with additional crosses that allowed determination of the gross time of lethality of selected deletions, defined four new loci required for normal development. Homozygous deletion of one of these loci (b-associated fitness, baf) results in a runting syndrome evident during postnatal development; deletion of one locus [l(4)2Rn] causes death in the late gestation/neonatal period; and deletion of either of two loci [l(4)1Rn or l(4)3Rn] results in embryonic death, most likely in pre-, peri- or postimplantation stages. The placement of these new functionally defined loci on the evolving molecular map of the b region should be useful for continuing the analysis of the roles played in development by genes in this segment of chromosome 4.     

Determination of the mouse homologous region for the rat dmy locus

The autosomal recessive mutation dmy causes neurological changes which are characterized by a severe demyelination in the spinal cord, associated with paralysis of the hind limbs. Kuramoto et al. have already mapped the mutation between Hh1ltts and Agtr1a loci on rat chromosome 17 (Kuramoto et al. 1996). Toward the identification of the dmy mutation, we determined here the corresponding genomic region on mouse chromosome 13 and constructed its fine genetic and physical maps. We are currently producing further backcross progeny to narrow down the dmy interval on the rat genome. Determination of the homologous region on the mouse genome should help identifying the causative gene.     

Molecular mapping of QTLs for Karnal bunt resistance in two recombinant inbred populations of bread wheat

Karnal bunt (KB) of wheat, caused by the fungus Tilletia indica, is a challenge to the grain industry, owing not to direct yield loss but to quarantine regulations that may restrict international movement of affected grain. Several different sources of resistance to KB have been reported. Understanding the genetics of resistance will facilitate the introgression of resistance into new wheat cultivars. The objectives of this study were to identify quantitative trait loci (QTLs) associated with KB resistance and to identify DNA markers in two recombinant inbred line populations derived from crosses of the susceptible cultivar WH542 with resistant lines HD29 and W485. Populations were evaluated for resistance against the KB pathogen for 3 years at Punjab Agricultural University, Ludhiana, India. Two new QTLs (Qkb.ksu-5BL.1 and Qkb.ksu-6BS.1) with resistance alleles from HD29 were identified and mapped in the intervals Xgdm116–Xwmc235 on chromosome 5B (deletion bin 5BL9-0.76-0.79) and Xwmc105–Xgwm88 on chromosome 6B (C-6BS5-0.76). They explained up to 19 and 13% of phenotypic variance, respectively. Another QTL (Qkb.ksu-4BL.1) with a resistance allele from W485 mapped in the interval Xgwm6–Xwmc349 on chromosome 4B (4BL5-0.86-1.00) and explained up to 15% of phenotypic variance. Qkb.ksu-6BS.1 showed pairwise interactions with loci on chromosomes 3B and 6A. Markers suitable for marker-assisted selection are available for all three QTLs. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Identification of a Novel Mouse Brachyury (<Emphasis Type="Italic">T</Emphasis>) Allele Causing a Short Tail Mutation in Mice

Mutations in T-box genes are associated with numerous disease states in humans. The objective of this paper was to characterize the T ^shao , a specific T-box mutation, in mice. T ^shao , a short-tailed mutant mouse strain in a B6 background, was obtained by ethylnitrosourea mutagenesis. Microsatellite genomic scans mapped the location of the mutation. RT–PCR was used to amplify the identified region and the product was sequenced. DNA of the region was sequenced and scanned for mutations. Tails of T ^shao mice were mostly curly with tail length ranging from less than 1 cm (tail bud) to half of the normal length. T ^shao presented single dominance gene inheritance, and homozygous mutant mice died approximately at E10. Scans of the F2 generation mapped the mutant gene to chromosome 17, near D17Mit143. The Brachyury (T) gene was identified as a potential candidate gene in this location. To confirm this, RT–PCR was performed on RNA from intercrossed 8.5-day embryos, and products were sequenced. A 67-nucleotide deletion in exon 2 of the mutant T gene was identified. Further sequencing of the genomic DNA from this region identified a T to A transversion at the 67th nucleotide of exon 2. The T ^shao mutation is a result of a deletion in exon 2 causing the early termination and loss of function of protein encoded by the T gene, manifesting as a short tail phenotype.     

Mapping of the Sod-2 locus into the t complex on mouse chromosome 17

A human DNA probe specific for the superoxide dismutase gene was used to identify the corresponding mouse gene. Under the chosen hybridizing conditions, the probe detected DNA fragments most likely carrying the mouse Sod-2 gene. Mapping studies revealed that the Sod-2 gene resides in the proximal inversion of the t complex on mouse chromosome 17. All complete t haplotypes tested showed restriction fragment length polymorphism which is distinct from that found in all wild-type chromosomes tested. The Sod-2 locus maps in the same region as some of the loci that influence segregation of t chromosomes in male gametes. The possibility that the Sod-2 locus is related to some of the t-complex distorter or responder loci is discussed. The data indicate that the human homolog of the mouse t complex has split into two regions, the distal region remaining on the p arm of human chromosome 6, while the proximal region has been transposed to the telomeric region of this chromosome's q arm.