Rbt (rabo torcido), a new mouse skeletal mutation involved in anteroposterior patterning of the axial skeleton,maps close to the ts (tail-short) locus and distal to the sox9 locus on chromosome 11

Rbt (Rabo torcido) is a new semidominant mouse mutant with a variety of skeletal abnormalities. Heterozygous Rbt mutants display homeotic anteroposterior patterning problems along the axial skeleton that resemble Polycomb group and trithorax gene mutations. In addition, the Rbt mutant displays strong similarities to the phenotype observed in Ts (Tail-short), indicating also a homeotically transformed phenotype in these mice. We have mapped the Rbt locus to an interval of approximately 6 cM on mouse Chromosome (Chr) 11 between microsatellite markers D11Mit128 and D11Mit103. The Ts locus was mapped within a shorter interval of approximately 3 cM between D11Mit128 and D11Mit203. This indicates that Rbt and Ts may be allelic mutations. Sox9, the human homolog of which is responsible for the skeletal malformation syndrome campomelic dysplasia, was mapped proximal to D11Mit128. It is, therefore, unlikely that Ts and Rbt are mouse models for this human skeletal disorder. Received: 14 April 1996 / Accepted: 22 July 1996     

Maternal methionine supplementation promotes the remediation of axial defects in Axd mouse neural tube mutants.

The Axd (axial defects) mouse model system (Essien et al., Teratology 42:183-194, '90) is characterized by a dominant mutation which causes posterior open neural tube defects (NTD) and a variety of tail anomalies (curly tails, or CT). Repeated backcrosses to BALB/cByJ mice have resulted in a 50% increase in Axd penetrance among neonates of heterozygous matings and loss of a correlation with maternal tail phenotype. Analysis of D12-D18 embryos from Axd/+ x Axd/+ matings indicates that soft tissues can superficially heal over some lesions from open NTD and that some curly tails can straighten (macroscopically) as gestation proceeds. Similarly, in embryos of Axd/+ x BALB crosses, there is remediation of approximately 33% of the tail flexion defects by birth. Numerous studies show that maternal nutritional status can affect the development of the neural tube and related axial structures. One nutrient of special interest is methionine, which is required for neurulation in cultured rat embryos (Coelho et al., J. Nutr. 119:1716, '89). Thus, the major question addressed by this study was whether supplemental methionine administered to Axd/+ dams crossed to Axd/+ males would alter the prenatal expression of the gene. When given IP (70 mg/kg) on D8 and D9, methionine resulted in a 41% reduction (from 29% to 17%) in the incidence of NTD in D 14 embryos (P less than 0.01).     

Mapping of jog locus to the region between D6Mit104 and D6Mit336 on mouse chromosome 6.

The joggle mouse is a recessive ataxic mutant carrying an unknown mutation in a C3H/He (C3H)-derived chromosomal segment. Taking advantage of the mouse genome database, we selected 127 DNA microsatellite markers showing heterozygosity between C3H and C57BL/6J (B6) and a first round of screening for the joggle mutation was performed on B6-jog/+ partial congenic mice (N4). We identified 4 chromosomal regions in which 13 microsatellite markers show heterozygosity between C3H and B6. Then, we analyzed the genotype of these 4 chromosomal regions in mice that showed the joggle phenotype and mapped the jog locus between markers D6Mit104 (111.4 Mb) and D6Mit336 (125.1 Mb) (an interval of 13.7 Mb) on chromosome 6. By using a partial congenic strain together with the mouse genome database, we successfully mapped the chromosomal localization of the jog locus much more efficiently than by conventional linkage analysis.     

Dominant Lethality of the Mouse Skeletal Mutation Tail-short (Ts) Is Determined by theTsAllele from Mating Partners

Mice with the Tail-short (Ts) mutation have a short, kinky tail and numerous skeletal abnormalities, including a homeotic anteroposterior patterning problem involving the axial skeleton. The viability ofTsheterozygotes varies dramatically, depending on the mouse strain crossed with the mutant strain. At the extremes, the heterozygotes are viable or lethal prenatally. In this study, we found that laboratory mouse strains could be divided into two groups. A cross with strains from the first group yielded viableTsheterozygotes, whereas a cross with the second group resulted in dominant lethalityin utero.We planned to map the gene(s) that controls strain differences in the viability of theTsheterozygotes. The result clearly indicated that a single chromosomal region, genetically inseparable from theTslocus, is responsible for these differences. This suggests that allelism at theTslocus generates variable manifestation of the mutant phenotype. Morphological and histological analyses indicated that embryos from the lethal cross exhibit severe developmental defects from the gastrulation stage through the early fetal stage. In particular, the umbilical vein does not develop properly. All of these results suggest that the phenotype of theTsmutant is modified by theTsalleles of the mating partners.     

Uncv (uncovered): a new mutation causing hairloss on mouse chromosome 11.

A pair of mutant mice with a first sparse coat appeared spontaneously in the production stock of BALB/c mice with a normal coat. After being sib-mated, they produced three phenotypes in their progeny: mice with normal hair, mice with a first sparse coat and then a fuzzy coat, and uncovered mice. Genetic studies revealed the mutants had inherited an autosomal monogene that was semi-dominant. By using 11 biochemical loci--Idh, Car2, Mup1, Pgm1, Hbb, Es1, Es10, Gdc, Ce2, Mod1 and Es3--as genetic markers, two-point linkage tests were made. The results showed the gene was assigned to chromosome 11. The result of a three-point test with Es3 and D11Mit8 (microsatellite DNA) as markers showed that the mutation was linked to Es3 with the recombination fraction 7.89 +/- 2.19%, and linked to D11Mit8 with the recombination fraction 26.30 +/- 3.57%. The recombination fraction between Es3 and D11Mit8 was 32.90 +/- 3.81%. It is suggested that the mutation is a new genetic locus that affected the skin and hair structure of the mouse. The mutation was named uncovered, with the symbol Uncv. Further studies showed the mutation affected not only the histology of skin and hair but also the growth and reproductive performance of the mice. The molecular characterization of the Uncv locus needs to be further studied.     

BALB/c alleles at modifier loci increase the severity of the maternal effect of the "DDK syndrome"

The Om locus was first described in the DDK inbred mouse strain: DDK mice carry a mutation at Om resulting in a parental effect lethality of F(1) embryos. When DDK females are mated with males of other (non-DDK) inbred strains, e.g., BALB/c, they exhibit a low fertility, whereas the reciprocal cross, non-DDK females x DDK males, is fertile (as is the DDK intrastrain cross). The low fertility is due to the death of (DDK x non-DDK)F(1) embryos at the late-morula to blastocyst stage, which is referred to as the "DDK syndrome." The death of these F(1) embryos is caused by an incompatibility between a DDK maternal factor and the non-DDK paternal pronucleus. Previous genetic studies showed that F(1) mice have an intermediate phenotype compared to parental strains: crosses between F(1) females and non-DDK males are semisterile, as are crosses between DDK females and F(1) males. In the present studies, we have examined the properties of mice heterozygous for BALB/c and DDK Om alleles on an essentially BALB/c genetic background. Surprisingly, we found that the females are quasi-sterile when mated with BALB/c males and, thus, present a phenotype similar to DDK females. These results indicate that BALB/c alleles at modifier loci increase the severity of the DDK syndrome.     

Fine localization of a new cataract locus, Kec, on mouse chromosome 14 and exclusion of candidate genes as the gene that causes cataract in the Kec mouse

A mouse with cataract, Kec, was generated from N-ethyl-N-nitrosourea (ENU) mutagenesis. Cataract in the Kec mouse was observable at about 5 weeks after birth and this gradually progressed to become completely opaque by 12 weeks. Dissection microscopy revealed that vacuoles with a radial or irregular shape were located primarily in the cortex of the posterior and equatorial regions of the lens. At the late stage, the lens structure was distorted, but not ruptured. This cataract phenotype was inherited in an autosomal recessive manner. We performed a genetic linkage analysis using 133 mutant and 67 normal mice produced by mating Kec mutant (BALB/c) and F1 (C57BL/6 x Kec) mice. The Kec locus was mapped to the 3 cM region encompassed by D14Mit34 and D14Mit69. In addition we excluded coding sequences of 9 genes including Rcbtb2, P2ry5, Itm2b, Med4, Nudt15, Esd, Lcp1, Slc25a30, and 2810032E02Rik as the candidate gene that causes cataract in the Kec mouse.     

High-resolution linkage map in the vicinity of the Lp locus

Looptail (Lp) is a mutation that profoundly affects neurulation in mouse and is characterized by craniorachischisis, an open neural tube extending from the midbrain to the tail in embryos homozygous for the mutation. Lp maps to the distal portion of mouse chromosome 1, and as part of a positional cloning approach, we have generated a high-resolution linkage map of the Lp chromosomal region. For this, we have carried out extensive segregation analysis in a total of 706 backcross mice informative for Lp and derived from two crosses, (Lp/ + X SJL/J)F1 X SJL/J and (Lp/ + X SWR/J)F1 X SWR/J. In addition, 269 mice from a (Mus spretus X C57BL/6J)F1 X C57BL/6J interspecific backcross were also used to order marker loci and calculate intergene distances for this region. With these mice, a total of 28 DNA markers corresponding to either cloned genes or anonymous markers of the SSLP or SSCP-types were mapped within a 5-cM interval overlapping the Lp region, with the following locus order and interlocus distances (in cM): centromere-D1Mit110 / Atp1β1 / Cd3ζ / Cd3η / D1Mit145 — D1Hun14 / D1Mit15 — D1Mit111 / D1Mit112 — D1Mit114 — D1Mit148 / D1Mit205/ D1Mit36 / D1Mit146 / D1Mit147 / D1Mit270 / D1Hun13 — Fcgr2 — Mpp — Apoa2/Fcer1γ - Lp - D1Mit149 / Spna1/Fcer1α-Eph1-Hlx1/D1Mit62. These studies have allowed the delineation of a maximum genetic interval for Lp of 0.5 cM, a size amenable to physical mapping techniques.     

Exclusion of Sox9 as a candidate for the mouse mutant Tail-short

The Sry-related gene Sox9 has been proposed as the gene responsible for the mouse skeletal mutant Tail-short (Ts), on the basis of its expression in skeletogenic mesenchymal condensations in the mouse embryo and its chromosomal location in the region of Ts on distal Chromosome (Chr) 11. We present here detailed mapping of Ts locus relative to the Sox9, using an intersubspecific cross. Among 521 backcross progeny, 16 recombinants were detected between Sox9 and Ts, suggesting a separation of 3.5 ± 0.01 cM, and excluding Sox9 as a candidate for Ts. A further nine recombinants were detected between Ts and the polycomb-like gene M33, suggesting that these loci are separated by 1.8 ± 0.011 cM. Six microsatellite markers were co-localized to the Ts locus, providing reagents for positional cloning of Ts. Received: 13 December 1995 / Accepted: 3 March 1996     

Expression of a new mutation (Axd) causing axial defects in mice correlates with maternal phenotype and age

A new autosomal mutation, Axd (axial defects), is described. Axd segregates in a simple Mendelian fashion, and it is dominant with incomplete penetrance and variable expressivity. The phenotype of Axd heterozygotes ranges from a variety of tail anomalies to visibly normal tails. Approximately 12% of neonates from curly-tail (CT) F1 (Axd/+) x F1 (Axd/+) matings exhibit open neural tube defects (NTD) in the lumbosacral region and 16% have curly tails. Mean litter sizes and resorption rates comparable to wild type indicate that homozygosity for Axd is not obligately lethal. Genetic background plays a major role in Axd expression. Strains such as BALB/cByJ allow the highest penetrance of the mutation in single dose (46%), whereas, in CF-1 mice Axd is recessive. The tail phenotype of heterozygous Axd/+ dams, in part reflective of their genetic background, correlates with the incidence of NTD in F2 offspring: CT mothers produce significantly more neonates with frank NTD than normal tail mothers. At the one embryonic period examined for this study (D13/D14 post-coitus), an 85% higher incidence of total axial defects is observed than among the F2 at birth. Unchanging litter size and the relative increase in phenotypically normal offspring by birth suggest that Axd acts by delaying posterior neural tube closure. One of the most significant findings in this study is that maternal age influences the survival of Axd embryos in utero. Axd/+ dams older than 8 months yield fewer mean implants, higher resorption rates, and fewer viable embryos with axial defects than do Axd/+ dams younger than 8 months. Axd is not allelic to nor linked to the Sp (splotch) gene which also affects neurulation.     

A chromosomal translocation causing multiple abnormalities including open eyelids at birth and glomerulonephritis

We have characterized the phenotype of a mouse with a t(2;13) reciprocal translocation induced by chlorambucil. It results in abnormal eyelid formation as well as a series of neurological, physiological, and immunological abnormalities. This mutant has been termed T(2;13)1Fla/+. T(2;13)1Fla/+ mice exhibit open eyelids at birth, a dilute coat color, hyperactivity, and occasional circling and stargazing activity. At 1-6 months, T(2;13)1Fla/+ mice show signs of immune complex-mediated glomerulonephritis and die prematurely. Additionally, double-stranded DNA autoantibodies have been found in sera of T(2;13)1Fla/+ mice. Cytogenetic analysis situated the translocation breakpoint at the proximal end of Chromosome (chr) 2 at band A2, and on Chr 13 at band A4. The mutant phenotype completely correlated with the presence of the translocation. Additional genetic studies have mapped the mutation and translocation breakpoint to Chr 13 between D13Mit16 and D13Mit64, and to Chr 2 proximal to D2Mit5. By fluorescent in situ hybridization (FISH), the position of this mutation/translocation on Chr 13 has been mapped to a region less than 1cM from D13Mit61.     

Identification of quantitative trait loci that regulate obesity and serum lipid levels in MRL/MpJ x SJL/J inbred mice

The total body fat mass and serum concentration of total cholesterol, HDL cholesterol, and triglyceride (TG) differ between standard diet-fed female inbred mouse strains MRL/MpJ (MRL) and SJL/J (SJL) by 38-120% (P < 0.01). To investigate genetic regulation of obesity and serum lipid levels, we performed a genome-wide linkage analysis in 621 MRLx SJL F2 female mice. Fat mass was affected by two significant loci, D11Mit36 [43.7 cM, logarithm of the odds ratio (LOD) 11.2] and D16Mit51 (50.3 cM, LOD 3.9), and one suggestive locus at D7Mit44 (50 cM, LOD 2.4). TG levels were affected by two novel loci at D1Mit43 (76 cM, LOD 3.8) and D12Mit201 (26 cM, LOD 4.1), and two suggestive loci on chromosomes 5 and 17. HDL and cholesterol concentrations were influenced by significant loci on chromosomes 1, 3, 5, 7, and 17 that were in the regions identified earlier for other strains of mice, except for a suggestive locus on chromosome 14 that was specific to the MRL x SJL cross. In summary, linkage analysis in MRL x SJL F2 mice disclosed novel loci affecting TG, HDL, and fat mass, a measure of obesity. Knowledge of the genes in these quantitative trait loci will enhance our understanding of obesity and lipid metabolism.     

A gene(s) for all-trans-retinoic acid-induced forelimb defects mapped and confirmed to murine chromosome 11

All-trans-retinoic acid (RA) induces various anatomical limb dysmorphologies in mice dependent on the time of exposure. During early limb development, RA induces forelimb ectrodactyly (digital absence) with varying susceptibilities for different inbred mouse strains; C57BL/6N are highly susceptible while SWV are resistant. To isolate the genetic basis of this defect, a full-genome scan was performed in 406 backcross fetuses of F(1) males to C57BL/6N females. Fetuses were exposed via a maternal injection of 75 mg of RA per kilogram of body weight on gestational day 9.25. The genome-wide analysis revealed significant linkage to a chromosome 11 locus near D11Mit39 with a maximum LOD score of 9.0 and to a chromosome 4 locus near D4Mit170. An epistatic interaction was detected between loci on chromosome 11 (D11Mit39) and chromosome 18 (D18Mit64). Linkage to the chromosome 11 locus (D11Mit39) was confirmed in RA-treated backcross fetuses of F(1) females to C57BL/6N males. Loci associated with bone density/mass in both human and mouse were previously detected in the same region, suggesting a mechanistic linkage with bone homeostasis. The human syntenic region of this locus has been previously linked to Meckel syndrome; the phenotype includes postaxial polydactyly, an ectopic digital defect hypothesized to be induced by a common molecular pathway with ectrodactyly.     

Phenotypic reversions at the W/Kit locus mediated by mitotic recombination in mice.

The mouse W locus encodes Kit, the receptor tyrosine kinase for stem cell factor (SCF). Kit is required for several developmental processes, including the proliferation and survival of melanoblasts. Because of the nearly complete failure of Wrio/+ melanoblasts to colonize the skin, the costs of Wrio/+ mice are characterized by a majority of white hairs interspersed among pigmented hairs, giving a roan effect. However, 3.6% of Wrio/+ mice exhibit phenotypic reversions, i.e., spots of wild-type color on their coats with an otherwise mutant phenotype. Melanocyte cell lines were derived from each of six independent reversion spots on the skin of (C57BL/6 x DBA/2)F1 Wrio/+ mice. All six melanocyte cell lines exhibited the general characteristics common to normal, nonimmortal mouse melanocytes. Of these, three revertant cell lines had lost the dominant-negative Wrio allele following mitotic recombination between the centromere and the W locus. One of the cell lines remained Wrio/+ but showed (i) stimulation in response to SCF and (ii) increased Kit expression, suggesting that the Wrio mutation can be rescued by increased endogenous expression of the c-kit proto-oncogene. Finally, two cell lines showed no detectable genetic change at the W/Kit locus and failed to respond to SCF stimulation in vitro. These results demonstrate that mitotic recombination can create large patches of wild-type hair on the coats of Wrio/+ mutant mice. This shows that mitotic recombination occurs spontaneously in normal healthy tissue in vivo. Moreover, these experiments confirm that other mechanisms, not associated with loss of heterozygosity, may account for the coat color reversion phenotype.     

Wnt9b is the mutated gene involved in multifactorial nonsyndromic cleft lip with or without cleft palate in A/WySn mice, as confirmed by a genetic complementation test

BACKGROUND: Nonsyndromic cleft lip (CL) with or without cleft palate (CLP) is a common human birth defect with complex genetic etiology. One of the unidentified genes maps to chromosome 17q21. A mouse strain, A/WySn, has CLP with complex genetic etiology that models the human defect, and 1 of its causative genes, clf1, maps to a region homologous to human 17q21. Extensive studies of the candidate region pointed to a novel insertion of an IAP transposon 3' from the gene Wnt9b as the clf1 mutation. Independently a recessive knockout mutation of Wnt9b (Wnt9b-) was reported to cause a lethal syndrome that includes some CLP. METHODS: A standard genetic test of allelism between clf1 and the Wnt9b- mutation was done. A total of 83 F1 embryos at gestation day 14 (GD 14) from Wnt9b-/+ males crossed with A/WySn females, and 79 BC1 GD 14 embryos from F1 Wnt9b-/clf1 males back-crossed to A/WySn females were observed for CL. Embryo genotypes at clf1 and Wnt9b were obtained from DNA markers. Genotypes for a second unlinked modifier locus from A/WySn, clf2, were similarly obtained. RESULTS: The compound mutant embryos (Wnt9b-/clf1) had high frequencies of CL: 27% in the F1 and 63% in the BC1. The clf2 modifier gene was found to have 3 alleles segregating in this study and to strongly influence the penetrance of CL in the compound mutant. CONCLUSIONS: The noncomplementation of clf1 and Wnt9b- confirms that clf1 is a mutation of the Wnt9b gene. The homologous human WNT9B gene and 3' conserved noncoding region should be examined for a role in human nonsyndromic CLP.     

High resolution genetic and physical mapping of the mouse asebia locus: A key gene locus for sebaceous gland differentiation

The asebia (ab) mutation in the mouse is an autosomal recessive trait with hypoplastic sebaceous glands. As a first step toward cloning the ab gene, we report here the genetic mapping of the ab locus with respect to Chromosome 19 microsatellite markers. 644 backcross progeny were generated by mating (CAST/EiJ × DBA/1LacJ-ab^2J/ab^2J) F₁ heterozygous females and parental ab^2J/ab^2J mutant males. Our results located the ab gene to an interval of 1.6 cM on mouse Chromosome 19 defined by flanking markers D19Mit11 and D19Mit53/D19Mit27, and identified a tightly linked polymorphic marker, D19Mit67, that co-segregates with the mutation in the backcross progeny examined. This places ab locus 4 cM distal to its present position as indicated in Mouse Genome Database at The Jackson Laboratory. We have also mapped a yeast artificial chromosome (YAC) contig in this locus interval which suggests the ab interval to be less than one megabase of DNA.     

Role of the Nh (Non-hair) mutation in the development of dermatitis and hyperproduction of IgE in DS-Nh mice.

The DS-Nh (DS Non-hair) mouse is a spontaneous hairless mutant of the DS mouse. The inheritance mode of the Nh mutation is autosomal dominant, and the Nh locus is mapped to Chromosome 11. The roles of the Nh mutation in spontaneous dermatitis and IgE hyperproduction were studied using an Nh congenic strain with a genetic background from the BALB/c mouse. In contrast to DS-Nh (Nh/+) mice, BALB/c-Nh (Nh/+) mice under conventional conditions showed a marked increase in serum IgE, without the development of dermatitis. These results suggest that IgE hyperproduction is regulated by the Nh mutation, while other genetic factor(s) are also involved in the development of dermatitis.     

两例新的稀毛小鼠突变基因的染色体定位

用连锁分析法对乙烷基亚硝基脲(ENU) 诱变获得的两例被毛突变小鼠(snthr 1Bao及snthr 2Bao) 的突变基因进行定位。选择平均分布于小鼠基因组且在C57BL/6J和DBA/2 间有差异的39 个微卫星对B6D2F1 互交得到的稀毛F2 进行全基因组扫描。扫描了9个微卫星后发现snthr 1Bao突变基因与D9Mit243 的LOD值为7 73。突变基因被定位于9号染色体。在此基础上又选择了D9Mit355 和D9Mit18 两个微卫星进行检测, 并扩大F2 的数量至145只。结果发现, snthr 1Bao与D9Mit18间无1 例重组, 稀毛突变基因与该微卫星紧密连锁, 距着丝点71cM。同理, 将snthr 2Bao突变基因也定位在与snthr 1Bao相近的区域。检索发现snthr 1Bao是一尚未克隆的新基因。     

Detection of modifier loci influencing the lung phenotype of cystic fibrosis knockout mice

The variable severity of lung disease associated with cystic fibrosis (CF) cannot be explained by the genotype of the cystic fibrosis transmembrane conductance regulator (CFTR) locus alone. Lung disease has been reported in a congenic CF mouse model of C57BL/6J genetic background (B6 CF), in the absence of detectable infection, but not in CF mice of mixed genetic background, nor in wild-type animals maintained in identical environments. In this report, studies are presented to show that the same CF mutation in mice of a BALB/c background (BALB CF) results in minimal lung disease. By 12 weeks of age B6 CF mice developed a lung disease consisting of mononuclear cell interstitial infiltrate and fibrosis, and BALB CF or littermate control mice developed minimal histopathology. Therefore, it is possible to identify the chromosomal locations of genes that can contribute to the susceptibility to lung disease in B6 CF mice compared with BALB CF mice by means of a quantitative trait loci (QTL) mapping strategy based on the variable histology of the (B6 × BALB) F2 CF mice. Significant linkage of the fibrotic lung phenotype was detected for a region on Chromosome (Chr) 6, defined by markers D6Mit194 to D6Mit201, and suggestive linkage was found for regions on Chr 1, 2, 10, and 17. Additional loci, suggestive of linkage, were also detected for the interstitial thickening phenotype. Most of these putative loci are specific to the sex of the animals. These results suggest that multiple genes can influence the severity of CF lung disease in mice.