A scanning electron microscope study of fetal eyelid closure accelerated by cortisone in SWV/Bc mice

Eyelid closure occurs earlier in SWV/Bc and CBA/J mouse fetuses whose mothers were treated with cortisone on day 14 of gestation than it does in fetuses from untreated mothers. Similar treatment prevents the open-eyes defect of lidgap-Miller mutant mice, but examination by scanning electron microscope (SEM) has shown differences in the periderm of the closing eyelids of the cortisone-treated mutant compared with those of untreated genetically normal fetuses. (Untreated mutant eyelids remain wide open and very abnormal). The present study has examined at the SEM level the accelerated eyelid closure of cortisone-treated normal strain, SWV/Bc, fetuses to investigate whether the differences from normal in the eyelids of treated lidgap-Miller fetuses are part of the mechanism of the cortisone "cure." At the SEM level, cortisone-accelerated eyelid closure of SWV/Bc fetuses is indistinguishable from that in untreated fetuses. This suggests that the early eyelid closure induced by cortisone in normal strain fetuses represents acceleration of the normal coordinated sequence of events that leads to closure, rather than an abnormality that fortuitously leads to closure. The data also indicate that the cellular abnormalities seen previously in treated lidgap-Miller mutant fetuses are a combination of 1) abnormalities due to the mutation that are not completely reversed by cortisone and 2) normal developmental stages that have become concurrent with the cortisone-induced late closure in lidgap-Miller mutant fetuses.     

The lidgap-Gates (lg Ga) mutation for open eyelids at birth maps to mouse Chromosome 13

Complex nonadditive interactions between specific alleles at multiple loci may underlie many so-called multifactorial threshold birth defects. The open-eyelids-at-birth defect in mice is a good model for these defects, and an understanding of its genetic complexity begins with mapping the participating loci. The open-eyelids defect can be part of a syndrome or can occur with no other obvious phenotypic effects. Of the latter nonsyndromic forms, the lidgap series includes four extant mutations that are considered to be alleles based on complementation tests. All show genetic complexity in segregation ratios. None has been mapped previously. On the basis of a strategy of mapping the mutation with the simplest inheritance pattern first, we generated an extensive exclusion map for lidgap-Gates, lg ^Ga , using morphological and protein polymorphisms. We then screened the non-excluded regions in a congenic strain, AEJ.LGG—lg ^Ga , for SSLP markers and located the differential chromosome segment containing the lg ^Ga locus in a region near the distal end of mouse Chromosome (Chr) 13. This linkage was confirmed and refined by typing SSLPs in 64 F₂ and 74 BC₁ progeny of a cross of LGG/Bc (lg ^Ga /lg ^Ga ) to SWV/Bc. The lg ^Ga mutation maps to a 1- to 2-cM region between D13Mit76 and D13Mit53. Integrin alpha 1 and integrin alpha 2, which map to the same general region, are possible candidate loci, based on their embryonic expression and cellular function. Evidence is also presented for a common unlinked recessive suppressor of the open eyelids trait caused by lg ^Ga . Received: 3 February 1995 / Accepted: 19 February 1996     

Genetic resistance of CBA and a mice to transplanted lymphoid and hemopoietic cells of CBA.M523 mutants and their F1 hybrids

(CBA × M523)F₁, (A × M523)F₁ and M523 lymphocytes grafted into lethally irradiated CBA or A mice temporarily lose their capacity to respond to test antigens (SRBC, Vi-antigenS. typhi). Immunoresponsiveness of F₁ cells is affected to a lesser degree in lethally irradiated M523 mice. Depression of response is absent in the CBA F₁ combination, in the syngeneic combination and in CBA mice which have received transplanted cells from F₁ hybrids which do not share theM523 mutation. The number of hemopoietic (CBA × M523)F₁ colonies was also reduced in CBA mice. Resistance of CBA mice to lymphoid (CBA × M523)F₁ cells develops 18 days after birth. It can be reduced by additional recipient preirradiation or preinoculation with (CBA × M523)F₁ spleen cells. The abrogated resistance can be partially restored by CBA spleen cells. The activity of (CBA × M523)F₁ lymphocytes passaged through CBA spleen is restored in syngeneic F₁ secondary recipients but inhibited again in the CBA secondary recipients. These results are consistent with the suggestion that resistance of lethally irradiated CBA mice to hemopoietic and lymphoid (CBA × M523)F₁ cells is mediated by immunologically competent, radioresistant recipient cells rapidly reacting to transplantation antigens coded by the mutantH-2K ^ka allele. These cells temporarily suppress the functional activity of transplanted cells but do not eliminate them.     

Neuromuscular ataxia: a new spontaneous mutation in the mouse

Neuromuscular ataxia, nma, is a new autosomal recessive mutation that arose spontaneously in CBA/J inbred mice at The Jackson Laboratory. The mutation, now maintained on the B6C3FeF₁ hybrid background, when homozygous, causes small size, uncoordinated gait, dysmetria, dystonia, general weakness, and death shortly after weaning. No biochemical or morphological abnormalities have been detected. We used an intercross between the B6C3FeF₁ mutant and CAST/Ei to map the nma mutation to the proximal end of Chr 12. The most likely gene order places the mutation between D12Mit270 and D12Mit54, non-recombinant with D12Mit2 in 96 tested meioses. Received: 27 March 2000 / Accepted: 17 May 2000     

Whiskers amiss, a new vibrissae and hair mutation near the Krt1 cluster on mouse Chromosome 11

Whiskers amiss (wam) is a new spontaneous recessive mutation in the SELH/Bc strain of mice that causes a phenotype of askew, sometimes kinked or curled, breakable whiskers and disheveled-appearing body hair, apparently owing to disoriented guard hairs. Heterozygotes on three genetic backgrounds are indistinguishable from normal. Using informative SSLPs in the F₂ generation after crosses to two normal strains, we have mapped wam to the region of the type I keratin cluster on Chromosome (Chr) 11, within an approximately 6-cM segment according to the current Mouse Genome Database (MGD) map position of flanking SSLPs. Although several other hair mutations also map to the Krt1 region (Re, Rim3, Bda, Bsk), none has a hair and whisker phenotype similar to that of wam, and, because all are transmitted as dominants, interpretable complementation tests could not be done. Scabbing and tissue loss occur on the rims of the pinnae and tail tip in some aging wam homozygotes, suggesting that wam may be an animal model of a genetic ectodermal disorder. The SELH/Bc strain background appears to have an unusually high rate of spontaneous mutation; wam is the sixth mutation to be described. Received: 13 October 1999 / accepted: 7 December 1999     

An interstitial telomere array proximal to the distal telomere of mouse chromosome 13

Lambda clones of mouse DNA from BALB/c and C57BL/10, each containing an array of telomere hexamers, were localized by FISH to a region close to the telomere of Chr 13. Amplification of mouse genomic DNA with primers flanking SSRs within the cloned DNA showed several alleles, which were used to type eight sets of RI strains. The two lambda clones contained allelic versions of the interstitial telomere array, Tel-rs4, which is 495 bp in C57BL/10 and which includes a variety of sequence changes from the consensus telomere hexamer. Comparison of the segregation of the amplification products of the SSRs with the segregation of other loci in an interspecies backcross (C57BL/6JEi × SPRET/Ei) F₁× SPRET/Ei shows recombination suppression, possibly associated with ribosomal DNA sequences present on distal Chr 13 in Mus spretus, when compared with recombination in an interstrain backcross, (C57BL/6J × DBA/J) F₁× C57BL/6J, and with the MIT F₂ intercross. Analysis of recombination in females using a second interstrain backcross, (ICR/Ha × C57BL/6Ha) F₁× C57BL/6Ha, also indicates recombination suppression when compared with recombination in males of the same strains, using backcross C57BL/6Ha × (ICR/Ha × C57BL/6Ha) F₁. Thus, more than one cause may contribute to recombination suppression in this region. The combined order of the loci typed was D13Mit37–D13Mit30–D13Mit148–(D13Rp1, 2, 3, 4, Tel-rs4)–D13Mit53–D13Mit196–D13Mit77–(D13Mit78, 35). Data from crosses where apparently normal frequencies of recombination occur suggest that the telomere array is about 6 map units proximal to the most distal loci on Chr 13. This distance is consistent with evidence from markers identified in two YAC clones obtained from the region. Received: 24 September 1996/Accepted: 20 January 1997     

Quantitative trait loci affecting the behavior of A/J and CBA/J intercross mice in the elevated plus maze

How allelic diversity affects neural mechanisms to produce behavioral variation is largely unknown. The elevated plus maze, consisting of open and closed arms, has been used as a model of behavioral variation in rodent exploration. Under dim illumination the nature of the sensory stimuli that influence arm choice is uncertain. Two inbred mouse strains, A/J (Tyr ^c /Tyr ^c , the albino phenotype, mutation in tyrosinase) with a strong preference for closed arm entry, and CBA/J (Pdeb ^rdl /Pdeb ^rdl , the retinal degeneration phenotype, mutation in the β-subunit of rod cGMP phosphodiesterase), with a weak preference for open arm entry, were studied under varying light. Because behavioral differences persist under red light, variation in light perception is not likely to fully account for variation in arm choice. To identify genetic factors influencing arm choice (100 × Open arm entries/Total arm entries) quantitative trait loci analyses (QTL) were performed on (A/J × CBA/J)F₂ mice. Two QTLs, one of which includes PDEB, were identified on Chr 5 (LOD > 10) and account for > 30% of the behavioral variation in arm preference. Tyr (Chr 7, 44 cM) was linked to closed arm entries but not arm preference, and is unlikely to be acting through a direct effect on light perception, because A/J arm entries were not affected by red light and there was no interaction with PDEB in the (A/J × CBA/J)F₂ mice. Whether the candidate QTLs on Chr 5 affect arm choice through an effect on light perception is unknown, but phenotypic differences between F₂ mice with retinal degeneration and CBA/J mice and F₂ mice with albinism and A/J mice suggest that factors other than light sensitivity contribute to arm preference in these two strains. Received: 11 January 2001 / Accepted: 22 March 2001     

Mapping murine loci for seizure response to kainic acid

Mature DBA/2J (D2) mice are very sensitive to seizures induced by various chemical and physical stimuli, whereas C57BL/6J (B6) mice are relatively seizure resistant. We have conducted a genome-wide search for quantitative trait loci (QTLs) influencing the differential sensitivity of these strains to kainic acid (KA)-induced seizures by studying an F₂ intercross population. Parental, F₁, and F₂ mice (8–10 weeks of age) were injected subcutaneously with 25 mg/kg of KA and observed for 3 h. Latencies to focal and generalized seizures and status epilepticus were recorded and used to calculate an overall seizure score. Results of seizure testing indicated that the difference in susceptibility to KA-induced seizures between D2 and B6 mice is a polygenic phenomenon with at least 65% of the variance due to genetic factors. First-pass genome screening (10-cM marker intervals) in F₂ progeny (n = 257) documented a QTL of moderate effect on Chromosome (Chr) 1 with a peak LOD score of 5.5 (17% of genetic variance explained) localized between D1Mit30 and D1Mit16. Provisional QTLs of small effect were detected on Chr 11 (D11Mit224–D11Mit14), 15 (D15Mit6–D15Mit46) and 18 (D18Mit9–D18Mit144). Multiple locus models generally confirmed the Mapmaker/QTL results and also provided evidence for another QTL on Chr 4 (D4Mit9). Multilocus analysis of seizure severity suggested that additional loci on Chrs 5 (D5Mit11), 7 (D7Mit66), and 15 (D15Nds2) might also contribute to KA-induced seizure response. Overall, our results document a complex genetic determinism for KA-induced seizures in these mouse strains with contributions from as many as eight QTLs. Received: 16 April 1996 / Accepted: 21 October 1996     

Genetic mapping of the whirler mutation

The whirler (wi) mutation on mouse Chromosome (Chr) 4 results in an autosomal recessive neuroepithelial deafness and vestibular dysfunction exhibited as a characteristic shaker-waltzer behavior (deafness, circling, and head-bobbing). We have constructed a genetic linkage map across the wi region in both an interspecific [(wi/wi× CAST/Ei)F₁×wi/wi] backcross (n = 817) and an intraspecific [(wi/wi× CBA/Ca)F₁×wi/wi)] backcross (n = 335). In the interspecific backcross, wi was found to be non-recombinant with Orm1, 0.12 cM distal of D4Mit87 and Ambp, and 0.12 cM proximal of CD301. In the intraspecific backcross, wi was found to be non-recombinant with Orm1 and D4Mit244, 0.3 cM distal of Mup1, and 0.6 cM proximal of Tnc. We also report a family from the interspecific backcross that shows evidence of multiple recombinations across the region of mouse Chr 4 around the wi locus. These rearrangements appear specific to both the region and the family. Received: 10 July 1998 / Accepted: 19 January 1999     

A rat homolog of the mouse deafness mutant jerker (je)

An autosomal recessive deafness mutant was discovered in our colony of Zucker (ZUC) rats. These mutants behave like shaker-waltzer deafness mutants, and their inner ear pathology classifies them among neuroepithelial degeneration type of deafness mutants. To determine whether this rat deafness mutation (−) defines a unique locus or one that has been previously described, we mapped its chromosomal location. F₂ progeny of (Pbrc:ZUC × BN/Crl) A/a B/b H/h+/− F₁ rats were scored for coat color and behavioral phenotypes. Segregation analysis indicated that the deafness locus might be loosely linked with B on rat Chromosome (Chr) 5 (RNO5). Therefore, 40 −/− rats were scored for BN and ZUC alleles at four additional loci, D5Mit11, D5Mit13, Oprd1, and Gnb1, known to map to RNO5 or its homolog, mouse Chr 4 (MMU4). Linkage analysis established the gene order (cM distance) as D5Mit11–(19.3)–B–(17.9)–D5Mit13–(19.2)–Oprd1–(21.5) − (1.2) Gnb1, placing the deafness locus on distal RNO5. The position of the deafness locus on RNO5 is similar to that ofjerker (je) on MMU4; the phenotypes and patterns of inheritance of the deafness mutation and je are also similar. It seems likely that the mutation affects the rat homolog of je. The rat deafness locus should, therefore, be named jerker and assigned the gene symbol Je. Received: 13 June 1995 / Accepted: 4 January 1996     

Hemifacial deficiency induced by a shift in dominance of the mouse mutation far: a possible genetic model for hemifacial microsomia

Hemifacial deficiency appeared in 10% of juvenile mice when BALB/cGaBc mice carrying the recessive lethal mutation far were crossed with ICR/Bc. The hemifacial deficiency increased to 15-20% after one backcross to ICR/Bc and then remained at that level for 11 additional generations of backcrossing of far into ICR/Bc. Neither the ICR/Bc strain nor BALB/cGaBc (+/far) produces hemifacial deficiency. Genetic and anatomical studies of adults and fetuses showed that the hemifacial deficiency was due to +/far in the ICR/Bc strain genome; that is, far becomes an incomplete dominant in the ICR/Bc strain background. The hemifacial deficiency (38% of +/far) is probably caused by premature synostosis of the maxilla and premaxilla, observable on day 16 of gestation. An additional 20% of +/far in ICR/Bc have cleft palate and die at birth. Most +/far in both strains have a hidden anomaly, bilateral splitting of the maxillary branch of the trigeminal nerve. far/far homozygotes of both strain backgrounds have a syndrome of severe bilateral deficiency of the derivatives of the maxillary prominence. In human pedigrees, where the equivalents of the dominance modifiers in BALB/cGaBc and ICR/Bc would segregate within families, it would be difficult to recognize that sporadic hemifacial deficiency and severe bilateral maxillary deficiency were due to the same gene. We suggest that human bilateral and unilateral abnormalities of tissue derived from the first branchial arch should be analyzed with the awareness that, in mice, at least, the two kinds of syndrome are due to the same mutant gene.     

Unravelling the complex genetics of cleft lip in the mouse model

Nonsyndromic cleft lip in ``A' strain mice and humans is genetically complex and is distinct from isolated cleft palate. Cleft lip embryos recovered in 2.4% of 1485 first backcross (BC₁) segregants from a cross of A/WySnJ (24% cleft lip) and C57BL/6J (no cleft lip) in A/WySnJ mothers, and in testcrosses of 10 recombinant inbred (RI) strains (AXB/Pgn or BXA/Pgn), were used for gene mapping and for inference of genetic architecture. The A/WySnJ maternal genotype increased cleft lip risk in reciprocal crosses; the relevant genetic difference between AXB-6/Pgn (8%) and A/WySnJ (24%) is entirely maternal. A combination of new mapping panels (325 meioses), new markers, and a recombinant cleft lip embryo redefined the location of a recessive factor essential to cleft lip risk, clf1, and candidate genes Itgb3 and Crhr, to between D11Mit146/360 and D11Mit166/147. A screen of 54 YACs for 46 genes and SSLP loci located Wnt15, Wnt3, Crhr, Mtapt, Itgb3, Dlx3, and Dlx7 within the clf1 candidate region. The clf2 locus was newly mapped to Chromosome (Chr) 13 by a genome screen of BC₁ segregants, and further defined to a 4-cM region between D13Mit13/54 and D13Mit231 by strain distribution patterns of cleft lip liability and markers in testcrossed RI strains. Specific combinations of marker genotypes associated with cleft lip risk indicated that high risk in A/WySnJ mice is caused by epistatic interaction between clf1 and clf2 in the context of a genetic maternal effect. Human homologs of clf1 and clf2 are expected to be on 17q and 5q/9q. Received: 17 May 2000 / Accepted: 30 November 2000     

Xid-defective male (CBA/N x C57BL/6)F1 accessory cells present bovine insulin to long-term cultured F1-restricted T-cells

The reactivity of H-2^b-restricted murine T cells towards bovine insulin was reported to depend on the expression of Ia.W39, a private specificity of I-A^b, on antigen-presenting cells. Cells of male (CBA/N x B6)F₁ mice carrying the mutation xid on the X chromosome lack Ia.W39 on the cell surface. These cells are unable to present bovine insulin to primed T cells derived from female (CBA/N x B6)F₁ mice. We show here that spleen cells of male (CBA/N x B6)F₁ hybrids served perfectly as accessory cells for the insulin-dependent induction of a proliferative response of long-term cultured T cells with (B10 x B10.BR)F₁ genotype, restricted to recognizing insulin in the context of F₁-unique I-A determinants. The epitope on the insulin molecule essential for stimulation was determined to depend on the glutamic acid residue in position 4 of the A chain of insulin. This contrasts with the H-2^b-restricted response of B6 mice to bovine insulin, which appears to be directed at the A chain loop determinant (amino acids A8 and A10). These data suggest that distinct I-A^b-encoded structures, the expression of which is regulated independently, may serve as components of restriction elements for H-2^b and (H-2^b x H-2^k)F₁ restricted T cells, which are specific for different epitopes of bovine insulin.     

Strain distribution pattern in AXB and BXA recombinant inbred strains for loci on murine Chromosomes 10, 13, 17, and 18

Strain distribution patterns (SDPs) of selected loci previously mapped to murine Chromosomes (Chrs) 10, 13, 17, and 18 are reported for the AXB, BXA recombinant inbred (RI) strain set derived from the progenitor strains A/J (A) and C57BL/6J (B). The loci included the simple sequence length polymorphisms (D10Nds1, D10Mit2, D10Mit10, D10Mit14, D13Mit3, D13Nds1, D13Mit10, D13Mit13, D13Mit7, D13Mit11, D17Mit18, D17Mit10, D17Mit20, D17Mit3, D17Mit2, D18Mit17, D18Mit9, and D18Mit4), the restriction fragment length polymorphisms Pdea and Csfmr, and the biochemical marker AS-1. These loci were chosen because they map to genomic regions that had few or no genetic markers in the AXB, BXA RI set. Several of these loci also were typed in backcross progeny of matings of the (AXB)F₁ to strain A or B. The strain distribution patterns for chromosomes 10, 13, 17, and 18 are reported, and the gene order and map distances determined from the backcross data. The addition of these markers to the AXB, BXA RI strain set increases the genomic region over which linkage for new markers can be detected.     

Fine Genetic Map of Mouse Chromosome 10 around the Polycystic Kidney Disease Gene,jcpk,and Ankyrin 3

A chlorambucil (CHL)-induced mutation of thejcpk(juvenile congenital polycystic kidney disease) gene causes a severe early onset polycystic kidney disease. In an intercross involvingMus musculus castaneus, jcpkwas precisely mapped 0.2 cM distal toD10Mit115and 0.8 cM proximal toD10Mit173.In addition, five genes,Cdc2a, Col6a1, Col6a2, Bcr,andAnk3were mapped in both thisjcpkintercross and a (BALB/c × CAST/Ei)F₁× BALB/c backcross. All five genes were eliminated as possible candidates forjcpkbased on the mapping data. Thejcpkintercross allowed the orientation of theAnk3gene relative to the centromere to be determined.D10Mit115, D10Mit173, D10Mit199,andD10Mit200were separated genetically in this cross. The order and genetic distances of all markers and gene loci mapped in thejcpkintercross were consistent with those derived from the BALB/c backcross, indicating that the CHL-induced lesion has not generated any gross chromosomal abnormalities detectable in these studies.     

Tcrb-V3+3T-cell deletion and a new mouse mammary tumor provirus,Mtv-44

Genes encoding endogenous superantigens causing Tcrb-V3⁺ T-cell deletion co-segregate with mouse mammary tumor proviruses (Mtv),Mtv-3, Mtv-6, andMtv-13. In additionMtv-1 has been implicated in deletion of these T cells. We have examined levels of Tcrb-V3⁺ T cells andMtv integrations in the following off-spring and their parental strains, [(CBA-T6 × NZW)F₁ × CBA], [(CBA × C3H/He)F₁ × CBA], and [(B10.S (9R) × NOD]F₁ mice. We show that a newMtv (Mtv-44) from NZW mice andMtv-1 from C3H/He mice cosegregate with genes encoding ligands for partial deletion of Tcrb-V3^s+ T cells and that some NOD mice have an additionalMtv (Mtv-45) which is closely linked toMtv-3. Address correspondence and offprint requests to: K. Tomonari.     

Tumor formation in Nicotiana: Auxin levels and auxin inhibitors in normal and tumor-prone genotypes

Summary Auxin and auxin-inhibitors from acidic ether extracts of normal stem tissue of Nicotiana longiflora, N. debneyi-tabacum, their tumor producing F ₁ hybrid and non-tumor and tumor-prone segregants were separated by thin-layer chromatography and measured by an Avena curvature test. A significantly higher amount of auxin, very likely IAA, was found in the F ₁ hybrid and the tumor-prone segregants as compared to the non-tumor tissues. Inhibitory substances appeared at different R_f's but generally in low amounts. One inhibitor seems to be identical with the inhibitor . In general, the results indicate that higher levels of auxin are associated with tumor-prone tissues in the F ₁ hybrid and the segregants of a later generation carrying an alien longiflora chromosome on a debneyi-tabacum background. The role of this growth-regulating substance as related to tumor formation in Nicotiana is discussed.This paper is delicated to Professor Dr. Hans Söding, Hamburg, Germany, in commemoration of his 70th birthday and in recognition of his pioneering work in thefield of plant growth-hormone research.     

Mapping of new recessive cataract gene (itIr2) in the mouse

A new strain of mice with cataracts was developed in BALB/cHeA and STS/A recombinant inbred strain, CXS4 (D). In this study the mapping of spontaneous autosomal recessive cataract mutation is described. This mutation was characterized by ruptures of the lens nucleus, vitreous chamber through the posterior capsule, and the vacuolization of the lens. For the linkage analysis, we produced two kinds of backcross progenies, (BALB/cHeA × D)F₁ and (STS/A × D)F₁ females crossed to D male mice. The gene (lr2, lens rupture2) was mapped to the central part of Chromosome(Chr) 14, 0.7 ± 0.7cM from the micosatellite marker D14Mit28. Received: 13 October 1996 / Accepted: 22 July 1997     

Genetic resistance to fowl cholera is linked to the major histocompatibility complex

Chickens of the Iowa State S1 line have been selected for ability to regress Rous sarcoma virus-induced (RSV) tumors, humoral immune response to GAT (Ir-GAT), and erythrocyte antigen B. Sublines homozygous at the major histocompatibility complex (MHC), as well as F₁ heterozygotes and F₂ segregants, were tested for resistance to fowl cholera by challenge with Pasteurella multocida strain X73. Control of the response at high doses was associated in a preliminary study with Ir-GAT and response to RSV tumors. Genetic control of resistance to low doses of P. multocida was demonstrated via sublines and F₂ segregants to be linked with genes of the B-G region. Thus, genetic control of resistance to fowl cholera in chickens after exposure to Pasteurella multocida was shown to be linked to the major histocompatibility B complex, in this first demonstration of MHC-linked resistance to bacterial disease challenge.     

Jumbled spine and ribs (Jsr): a new mutation on mouse Chromosome 5

Jumbled spine and ribs (Jsr) is an autosomal dominant mutation that results in malformation of the axial skeleton. The vertebrae of mutant mice (Jsr/+) are all shorter than those of normal mice (+/+) in the inbred line and show various abnormalities. In addition, several ribs are fused at their proximal region because of fusion of thoracic vertebrae. In this study, we localized the Jsr mutation on distal Chromosome (Chr) 5 and constructed a high-resolution map. Chromosomal mapping was performed with an inter-subspecific backcross of (CKH-Jsr/+× MOG) F₁ carrying the Jsr allele and CKH-+/+. The predicted gene order around Jsr was determined to be cen–(Epo, Pdgfa, D5Mit31, D5Mit374)–(Jsr, Nfe2u, D5Mit99, D5Mit247, D5Mit284, D5Mit292, D5Mit327)–D5Mit328–tel. Subsequently, high-resolution mapping concluded the Jsr localization to be cen–Nfe2u–1.0cM–Jsr–0.2cM–D5Mit247,292–tel. Jsr/Jsr homozygotes are alive, as the mutation is not lethal. Based on histological analysis of mutant embryos, Jsr is hypothesized to be caused by abnormal development of primordial cells in the axial skeleton. Received: 1 June 1998 / Accepted: 15 October 1998