Confirmation and high resolution mapping of an atherosclerosis susceptibility gene in mice on Chromosome 1

Previously, we demonstrated that Ath1 is a quantitative trait locus for aortic fatty streak formation, located on Chromosome (chr) 1, with susceptibility in C57BL/6J mice and resistance in C3H/HeJ and BALB/cJ mice fed an atherogenic diet. In this study, we find an atherosclerosis susceptibility locus in the same region of Chr 1 by constructing two congenic strains with the resistance phenotype transferred from different resistant strains, PERA/EiJ or SPRETUS/EiJ. By backcrossing one congenic strain to C57BL/6J and testing recombinant animals, we reduced the distance of the atherosclerosis susceptibility region to 2.3 cM between D1Mit14 and D1Mit10. Further testing of nine recombinant animals showed that eight of the nine were consistent with a further narrowing between D1Mit159 and D1Mit398 a distance of 0.66 cM. This region encompasses a number of potential candidate genes including the thiol-specific antioxidant gene Aop2, also known as peroxiredoxin 5 (Prdx5). AOP2 is capable of reducing hydroperoxides and lipid peroxides in the cell. To investigate Aop2 as a potential candidate, we mapped Aop2 in our backcross and localized it to the atherosclerosis susceptibility interval. We determined that Aop2 is highly expressed in atherosclerosis-related tissues including liver and heart. We also found an inverse correlation between Aop2 mRNA in liver and atherosclerosis phenotype for strains C57BL/6 and the resistant congenic derived from SPRETUS/EiJ. Since LDL oxidation has been implicated in the pathogenesis of this disease, and AOP2 possesses antioxidant activity, we suggest the role of Aop2 in atherosclerosis susceptibility needs to be further explored.     

Localization of Idd11 using NOD congenic mouse strains: elimination of Slc9a1 as a candidate gene

 Type 1 diabetes is a multigenic autoimmune disease, the genetic basis for which is perhaps best characterized in the nonobese diabetic (NOD) mouse model. We previously located a NOD diabetes susceptibility locus, designated Idd11, on mouse Chromosome (Chr) 4 by analyzing diabetic backcross mice produced after crossing NOD/Lt with the nondiabetic resistant strain C57BL/6 (B6) strain. In order to confirm Idd11 and further refine its location, three NOD congenic mouse strains with different B6 derived intervals within Chr 4 were generated. Two of the congenic strains had a significant decrease in the cumulative incidence of diabetes compared with NOD/Lt control mice. The third NOD congenic strain, containing a B6 interval surrounding the Slc9a1 locus, was not protected against diabetes. These results define a new distal boundary for Idd11 and eliminate the Slc9a1 gene as a candidate. The Idd11 locus has now been definitively mapped to a 13cM interval on mouse Chr 4. Received: 15 May 1999 / Revised: 25 September 1999     

Linkage of the Fv-2 gene to a newly reinserted ecotropic retrovirus in Fv-2 congenic mice

Restriction enzyme and Southern gel analyses were used to determine the number and location of endogenous ecotropic retroviruses in the germ line of several mouse strains congenic at the Fv-2 gene locus. A new endogenous ecotropic provirus was observed in the germ line of B6.S (Fv-2ss) mice, in addition to the resident provirus found in its congenic partner C57BL/6 (Fv-2rr). This new provirus was similar in structure to the C57BL provirus. The SIM strain of mice, the donors of the Fv-2s allele in B6.S mice, does not contain ecotropic proviruses, suggesting that the new provirus in the B6.S mouse strain arose by germ-line reintegration during the construction of this strain. Mendelian segregation analysis indicated that this new provirus was linked to the Fv-2 gene locus on chromosome 9. In three other Fv-2s congenic mouse strains--B10.C (47N), B6.C (H-7b), and C57BL/6J Trfa, Bgsd--no additional ecotropic endogenous viruses were detected, suggesting that the reinsertion event that occurred during the construction of B6.S is not essential for the acquisition of the Fv-2s phenotype in the C57BL genetic background. Although numerous reports of germ-line reinsertions of ecotropic virus in high-virus mouse strains have been received, the present results provide definitive evidence that similar germ-line amplifications of endogenous ecotropic virus can occur in a low-virus mouse strain.     

Chromosomal localization of the loci responsible for dystrophic cardiac calcinosis in DBA/2 mice.

Dystrophic cardiac calcinosis (DCC) occurs in certain inbred strains of mice, including DBA/2 and C3H/He, and is generally found as an incidental lesion in adult animals at necropsy. Preliminary genetic studies into the cause of DCC have been performed in DBA/2 mice and suggest that DCC is inherited as an autosomal recessive trait involving three or four unlinked genes. To investigate the genetics of DCC further, we produced myocardial cell death by freeze-thaw injury to induce DCC. Experiments were conducted with three F1 hybrids made using three inbred strains of mice (DBA/2J and C3H/HeJ, DCC-susceptible strains; C57BL/6J, DCC-resistant strain) to compare the genetic factors in the development of DCC. We found that DBA/2 and C3H/He mice share the same gene pattern(s) that is responsible for DCC. We determined by backcross linkage analysis in DBA/2 and C57BL/6 mice that at least one recessive locus is responsible for DCC. A haplotype analysis of the backcross data demonstrated that the recessive locus, designated dyscalc1, is located on Chromosome 7, 20.5 cM distal to the centromere. The likely candidate genes for dyscalc1 are discussed. Further understanding of the structure and function of these mutant genes will be beneficial in explaining the molecular pathogenesis of DCC.     

Genetic characterization of the Dyscalc locus

Calcification occurs frequently in the development of atherosclerotic lesions, and studies in mice have indicated a genetic contribution. We now show that one genetic factor contributing to aortic calcification is the Dyscalc locus, previously shown to contribute to myocardial calcification. Thus, the Dyscalc locus, on proximal mouse Chromosome (Chr) 7, segregated with vascular calcification in a large cross between susceptible strain DBA/2J and resistant strain C57BL/6J. Further evidence was observed by analysis of recombinant inbred strains derived from various susceptible and resistant parental strains. Myocardial and vascular calcifications are importantly influenced by multiple modifier loci as well as the Dyscalc gene, making fine mapping of Dyscalc difficult. In order to allow more detailed genetic and biochemical characterization of Dyscalc, we have identified congenic strains containing the Dyscalc locus from resistant strain C57BL/10 on the background of susceptible strain C3H/DiSnA. The congenic strains exhibit little or no myocardial or vascular calcification, unlike the background HcB C3H strain, and the calcification segregated as a Mendelian factor, allowing finer mapping of Dyscalc.     

Spontaneous autoimmunity in 129 and C57BL/6 mice-implications for autoimmunity described in gene-targeted mice

Systemic lupus erythematosus (SLE) is a multisystem autoimmune disorder in which complex genetic factors play an important role. Several strains of gene-targeted mice have been reported to develop SLE, implicating the null genes in the causation of disease. However, hybrid strains between 129 and C57BL/6 mice, widely used in the generation of gene-targeted mice, develop spontaneous autoimmunity. Furthermore, the genetic background markedly influences the autoimmune phenotype of SLE in gene-targeted mice. This suggests an important role in the expression of autoimmunity of as-yet-uncharacterised background genes originating from these parental mouse strains. Using genome-wide linkage analysis, we identified several susceptibility loci, derived from 129 and C57BL/6 mice, mapped in the lupus-prone hybrid (129 × C57BL/6) model. By creating a C57BL/6 congenic strain carrying a 129-derived Chromosome 1 segment, we found that this 129 interval was sufficient to mediate the loss of tolerance to nuclear antigens, which had previously been attributed to a disrupted gene. These results demonstrate important epistatic modifiers of autoimmunity in 129 and C57BL/6 mouse strains, widely used in gene targeting. These background gene influences may account for some, or even all, of the autoimmune traits described in some gene-targeted models of SLE.     

A new erythrocytic antigen of C57BL/10 (B10) mice

A new antigen, detectable on murine erythrocytes by hemagglutination assay with a (BALB/cCrl X SWR/J)F1 anti-B10.D2n/Sn alloantiserum, is described. Among the inbred and congenic mouse strains tested for reactivity with the antiserum, only the immunizing strain, B10.D2, and its congenic resistant partner, C57BL/10 (B10), reacted. Three other C57 strains, C57BL/6J, C57BL/6By, and C57L, were negative for the antigen. F1 hybrids between B10 and BALB/c, an antigen-negative strain, were positive for the antigen indicating that its expression is dominant. Typing of 39 (BALB/c X (BALB/c X B10)F1) and 62 [BALB/c X B10)F1 X BALB/c) backcross mice revealed that a single gene controls expression of the antigen. The gene is autosomal and not linked to H-2, Ly-4, or the c (albino) or b coat color genes.     

Dissection of multigenic obesity traits in congenic mouse strains

Previous quantitative trait locus mapping (QTL) identified multigenic obesity (MOB) loci on mouse Chromosome (Chr) 2 that influence the interrelated phenotypes of obesity, insulin resistance, and dyslipidemia. To better localize and characterize the MOB locus, three congenic mouse strains were created. Overlapping genomic intervals from the lean CAST/Ei (CAST) strain were introgressed onto an obesity-susceptible C57BL/6 (BL6) background to create proximal (15 Mb–73 Mb), middle (63 Mb–165 Mb), and distal (83 Mb–182 Mb) congenic strains. The congenic strains showed differences in obesity, insulin, and lipid traits consistent with the original QTL analysis for the locus. Importantly, characterization of the MOB congenics localized the effects of genes that underlie obesity-related traits to an introgressed interval (73–83 Mb) unique to the middle MOB congenic. Conversely, significant differences between the lipid and insulin profiles of the middle and distal MOB congenics implicated the presence of at least two genes that underlie these traits. When fed an atherogenic diet, several traits associated with metabolic syndrome were observed in the distal MOB congenic, while alterations in plasma lipoproteins were observed in the middle MOB congenic strain.     

Spontaneous Autoimmunity in 129 and C57BL/6 Mice—Implications for Autoimmunity Described in Gene-Targeted Mice

Systemic lupus erythematosus (SLE) is a multisystem autoimmune disorder in which complex genetic factors play an important role. Several strains of gene-targeted mice have been reported to develop SLE, implicating the null genes in the causation of disease. However, hybrid strains between 129 and C57BL/6 mice, widely used in the generation of gene-targeted mice, develop spontaneous autoimmunity. Furthermore, the genetic background markedly influences the autoimmune phenotype of SLE in gene-targeted mice. This suggests an important role in the expression of autoimmunity of as-yet-uncharacterised background genes originating from these parental mouse strains. Using genome-wide linkage analysis, we identified several susceptibility loci, derived from 129 and C57BL/6 mice, mapped in the lupus-prone hybrid (129 × C57BL/6) model. By creating a C57BL/6 congenic strain carrying a 129-derived Chromosome 1 segment, we found that this 129 interval was sufficient to mediate the loss of tolerance to nuclear antigens, which had previously been attributed to a disrupted gene. These results demonstrate important epistatic modifiers of autoimmunity in 129 and C57BL/6 mouse strains, widely used in gene targeting. These background gene influences may account for some, or even all, of the autoimmune traits described in some gene-targeted models of SLE.     

Mapping of a Chromosome 12 Region Associated with Airway Hyperresponsiveness in a Recombinant Congenic Mouse Strain and Selection of Potential Candidate Genes by Expression and Sequence Variation Analyses

In a previous study we determined that BcA86 mice, a strain belonging to a panel of AcB/BcA recombinant congenic strains, have an airway responsiveness phenotype resembling mice from the airway hyperresponsive A/J strain. The majority of the BcA86 genome is however from the hyporesponsive C57BL/6J strain. The aim of this study was to identify candidate regions and genes associated with airway hyperresponsiveness (AHR) by quantitative trait locus (QTL) analysis using the BcA86 strain. Airway responsiveness of 205 F2 mice generated from backcrossing BcA86 strain to C57BL/6J strain was measured and used for QTL analysis to identify genomic regions in linkage with AHR. Consomic mice for the QTL containing chromosomes were phenotyped to study the contribution of each chromosome to lung responsiveness. Candidate genes within the QTL were selected based on expression differences in mRNA from whole lungs, and the presence of coding non-synonymous mutations that were predicted to have a functional effect by amino acid substitution prediction tools. One QTL for AHR was identified on Chromosome 12 with its 95% confidence interval ranging from 54.6 to 82.6 Mbp and a maximum LOD score of 5.11 (p = 3.68×10⁻³). We confirmed that the genotype of mouse Chromosome 12 is an important determinant of lung responsiveness using a Chromosome 12 substitution strain. Mice with an A/J Chromosome 12 on a C57BL/6J background have an AHR phenotype similar to hyperresponsive strains A/J and BcA86. Within the QTL, genes with deleterious coding variants, such as Foxa1, and genes with expression differences, such as Mettl21d and Snapc1, were selected as possible candidates for the AHR phenotype. Overall, through QTL analysis of a recombinant congenic strain, microarray analysis and coding variant analysis we identified Chromosome 12 and three potential candidate genes to be in linkage with airway responsiveness.     

Genetic Determination of the Developmental Program for Mouse Liver β-GALACTOSIDASE: Involvement of Sites Proximate to and Distant from the Structural Gene

The identification and mode of action of genetic loci that program gene expression during development are important for understanding differentiation in higher organisms. Previous work from this laboratory has identified two patterns for the postnatal development of liver beta-galactosidase among inbred mouse strains: type I, where activity levels remain constant after about 30 days of age, is found in strains DBA/2J, CBA/J, and BALB/cJ, among others; type II, where activity levels increase between 25 and 50 days of age to reach a new adult level, is found in strain C57BL/6J and related strains. It has been shown that the type I vs. type II developmental difference between strains C57BL/6J and DBA/2J is due to variation at a locus, Bgl-t, that maps with the beta-galactosidase complex, [Bgl], on chromosome 9. In the present study, we have confirmed the existence of Bgl-t as a temporal locus within [Bgl] by analysis of both a congenic strain carrying the beta-galactosidase complex of strain CBA/J in the C57BL/6J genetic background and a cross of strains CBA/J and C57BL/6J. The existence of additional temporal loci for beta-galactosidase that segregate independently of the structural gene and participate in determination of the type I vs. type II difference was revealed by analysis of: (1) a congenic strain containing the beta-galactosidase complex of strain BALB/cJ in the C57BL/10Sn background; (2) recombinant inbred lines derived from progenitor strains C57BL/6ByJ and BALB/cByJ; and (3) a genetic cross between strains C57BL/6ByJ and BALB/cByJ. Thus, for these pairs of strains, the type I vs. type II developmental difference is due to variation at a temporal locus (or loci) unlinked to the enzyme structural gene, and not at Bgl-t. These facts, together with information gathered from an examination of the distribution of beta-galactosidase phenotypes among over 100 inbred strains (Breen, Lusis and Paigen 1977), have led us to conclude that the postnatal developmental pattern for liver beta-galactosidase is determined by a set of interacting temporal genes. One of these, Bgl-t, is located within [Bgl], and one or more are separable from [Bgl] by recombination. A possible mode of interaction among the temporal and instructural loci is suggested.     

Genetic regulation of early survival and cyst number after peroral Toxoplasma gondii infection of A x B/B x A recombinant inbred and B10 congenic mice

Genetics of two traits, survival and brain cyst number after peroral Toxoplasma gondii infection, were studied by using recombinant inbred strains of mice derived from resistant A/J (A) and susceptible C57BL/6J (B) progenitors, F1 progeny of crosses between A/J and C57BL/6J mice, and congenic mice (B10 background). Analysis of strain distribution pattern of survival of A x B/B x A recombinant mice indicated that survival is regulated by a minimum of five genes. One of these genes appears to be linked to the H-2 complex and another is related to an as yet unmapped gene controlling resistance to Ectromelia virus. Associations of defined traits with resistance or susceptibility to Toxoplasma cyst formation were also analyzed. Cyst number is regulated by a locus on chromosome 17 within 0 to 4 centimorgans of the H-2 complex (p = 0.001). Mice with the H-2a haplotype are resistant and those with the H-2b haplotype are susceptible. This analysis also indicated that the Bcg locus on chromosome 1 may effect cyst number (map distance = 12 centimorgans, p = 0.05). Resistance to cyst formation is a dominant trait. To analyze relative roles of H-2 and Bcg loci on cyst numbers, C57BL10 (B10)-derived congenic strains of mice with known H-2 and Bcg type were studied. These studies indicated that the H-2 complex locus has the primary effect on cyst number.     

Linkage of Nat and Es-1 in the mouse and development of strains congenic for N-acetyltransferase

The human polymorphism in the hepatic enzyme N-acetyltransferase (NAT) affects the rate at which individuals acetylate, and in many cases detoxify, aromatic amine and hydrazine drugs and xenobiotics. Differences in NAT activity are known to affect individual susceptibility to drug toxicities and are thought to play a part in some spontaneous disorders. A mouse model for the human acetylation polymorphism has been previously characterized and involves the A/J (slow acetylator) and C57BL/6J (rapid acetylator) inbred strains. Strain distribution analysis of 40 A x B and B x A recombinant inbred (RI) strains indicated linkage between the N-acetyltransferase gene (Nat) and the esterase 1 (Es-1) gene, located on mouse chromosome 8. A double backcross involving 107 animals confirmed the recombination frequency between Nat and Es-1 to be 12 +/- 3% (mean +/- SE). The information obtained in the backcross and RI studies was combined, yielding a 13 +/- 2.8% (mean +/- SD) recombination frequency. The Es-1 genotype was determined in our newly developed congenic strains A.B6-Natr and B6.A-Nats. The B6.A-Nats strain has the Es-1 genotype of its inbred partner, the B6 strain, and the A.B6-Natr strain has the Es-1 genotype of the donor strain. These congenic strains will be important in determining the role of the NAT genotype in susceptibility to arylamine-induced cancer and other disorders.     

Mapping of theLyb-4 gene to different chromosomes in DBA/2J and C3H/HeJ mice

Linkage has been established between the Lyb-4 alloantigen locus and the chromosome 4 markersLyb- 2 andMup- 1 using recombinant inbred (RI) strains. Only 2 of 24 BXD RI strains possess recombinant genotypes with respect to the B cell alloantigen lociLyb- 4 andLyb- 2, for an estimated recombination frequency of 0.024 ±0.019. One additional BXD RI strain was a recombinant with respect toLyb- 4 andMup- 1 (major urinary protein locus) for an estimated recombination frequency of 0.039 ± 0.026. These linkages were confirmed and further quantitated in a (C57BL/6J × DBA/2J)F₁ × C57BL/6J backcross population, in which the recombination frequency betweenLyb- 4 andMup- 1 was 0.049 ± 0.019. No recombination between the expression of Lyb-4.1 antigen and the ability of anti-Lyb-4.1 serum to suppress MLC reactivity was found, indicating that the genes controlling the antigenic determinant which is recognized with cytotoxic antibodies in anti-Lyb-4.1 serum is the same as, or is very closely linked to, the gene which is responsible for augmentation of the MLC response. In contrast, no linkage was observed between the gene controlling the Lyb-4.1 determinant andMup- 1 in RI strain and backcross mice derived from the cross of C3H/HeJ and C57BL/6J. Again, there was complete concordance between the serologically recognized determinant and the ability of anti-Lyb-4.1 serum to suppress the MLC response. Absorption of anti-Lyb-4.1 serum with C3H/HeJ, DBA/2J, and C57BL/6J lymphocytes, followed by the cytotoxic assay of the absorbed sera on lymphocytes of each of these three strains showed that serologically the Lyb-4.1 antigenic determinant on DBA/2 mice was indistinguishable from that on C3H/HeJ mice. Thus, both traits appear to be under the control of single genes in both DBA/2J and C3H/HeJ, but the C3H/HeJ gene appears to be nonallelic and unlinked to the DBA/2J gene.Abbreviations used in this paper LAD lymphocyte activating determinants - LPS lipopolysaccharide - MLC mixed lymphocyte culture - RI recombinant inbred     

The ter mutation responsible for germ cell deficiency but not testicular nor ovarian teratocarcinogenesis in ter / ter congenic mice

The ter (teratoma) gene causes germ cell deficiency and a high incidence of congenital testicular teratomas derived from primordial germ cells in 129/Sv- ter strain mice. Ovarian teratomas in LTXBJ mice originate from ovarian parthenotes. In order to study the function of the ter gene in germ cell development and teratocarcinogenesis, we examined the influence of a foreign genetic background on the ter action by introducing the ter gene of 129/Sv- ter strain mice into C57BL/6J, LTXBJ and C3H/HeJ genetic backgrounds by the backcross method and by thus establishing B6- ter , LTXBJ- ter and C3H- ter ter congenic strains, respectively. Histological analysis showed that germ cell deficiency occurred in both sexes of the ter mutants, through the fetal stages to adulthood, but that congenital testicular teratocarcinogenesis did not occur after the fifth backcross generation. The ter/ter gonads were smaller than normal (+/+ or +/ ter ). Experimental testicular teratomas never developed from intratesticular grafts of B6- ter genital ridges. LTXBJ- ter/ter females had no ovarian teratomas. It is concluded that the ter gene is solely responsible for germ cell deficiency, but not testicular teratocarcinogenesis, in ter congenic strains having background genes other than 129/Sv- ter and that the ter gene is not involved in ovarian teratocarcinogenesis.     

Genetic control of red cell osmotic fragility

Among normal mouse strains, natural genetic variation offers the potential to investigate the structure and function of cell membranes. One such polymorphism between C57BL/6J and DBA/2J is a difference in erythrocyte sensitivity to osmotic lysis. The genetic basis for erythrocyte osmotic fragility differences between mouse strains C57BL/6 and DBA/2 was examined through analyses of their serial backcross progeny, recombinant inbred (ri) strains (BXD), and congenic C57BL/6 strains with allelic differences at Hbb or Fv-2. The data indicate that the fragility difference between C57BL/6 and DBA/2 is the result of allelic differences at a minimum of two segregating loci. One of these might be linked to, but is not identical with the gene encoding the beta chain of hemoglobin (Hbb). Allelic differences at Fv-2, a gene known to control the proportion of erythroid precursors in the S phase, and at Hba, the structural locus of hemoglobin alpha chain also appear to exert no major influence on red cell osmotic fragility. Furthermore, the fact that red cells from one of the RI strans (BXD-31) are strikingly more resistant than those from the resistant parental strain DBA/2 leads to the conclusion that the degree of resistance/susceptibility for either strain is determined by the combined contributions of gene effects not all of which act in the same direction. We also found that red cells from strans C57BL/6 and DBA/2 differ in their uptake of 51Cr. This result suggests the possibility that red cell osmotic fragility differences may be due in part to differences in ion metabolism or membrane transport.     

Gene-environment interaction: a significant diet-dependent obesity locus demonstrated in a congenic segment on mouse Chromosome 7

We have previously reported suggestive evidence for a locus on Chromosome (Chr) 7 that affects adiposity in F₂ mice from a CAST/Ei × C57BL/6J intercross fed a high-fat diet. Here we characterize the effect of a high-fat (32.6 Kcal% fat) diet on male and female congenic mice with a C57BL/6J background and a CAST/Ei-derived segment on Chr 7. Adiposity index (AI) and weights of certain fat pads were approximately 50% lower in both male and female congenic mice than in control C57BL/6J mice, and carcass fat content was significantly reduced. The reduction of fat depot weights was not seen, however, in congenic animals fed a low-fat chow diet (12 Kcal% fat). The congenic segment is approximately 25 cM in length, extending from D7Mit213 to D7Mit41, and includes the tub, Ucp2, and Ucp3, genes, all of which are candidate genes for this effect. Some polymorphisms have been found on comparing c-DNA sequences of the Ucp2 gene from C57BL/6J and CAST/Ei mice. These results suggest that one or more genes present in the congenic segment modulate the susceptibility to fat deposition on feeding a high-fat diet. We were unable to show any significant difference between the energy intakes of the congenic and the control C57BL/6J mice on the high-fat diet. Also, measurements of energy expenditure in male mice at 6 weeks of age, during the first 2 weeks of exposure to the high-fat diet, failed to show any differences between control and congenic animals. Received: 30 September 1998 / Accepted: 22 December 1998     

Inheritance of susceptibility to the myeloproliferative sarcoma virus: effect of the Fv-2 locus and evidence for a myeloproliferative sarcoma virus resistance locus.

Myeloproliferative sarcoma virus (MPSV) causes a generalized stem cell leukemia with erythroid and myeloid hyperplasia in adult mice. MPSV also transforms fibroblasts. Mice congenic for the Fv-2 locus showed marked differences in susceptibility to MPSV according to the Fv-2 genotype. MPSV was injected into C57BL/6 Fvs and C57BL/6 Fv-2r mice congenic except for the Fv-2 locus. C57BL/6 mice with the Fvs genotype were much more susceptible to MPSV than were those with the Fvr genotype. Both DDD Fv-2r mice congenic with DDD Fv-2s mice except for the Fv-2 locus and DDD Fv-2s mice, however, were sensitive to spleen focus formation by MPSV. These data indicate that at least one additional resistance locus to MPSV is present in C57BL/6 mice but not in DDD mice. Both the Fv-2 locus and the putative MSPV resistance locus (loci) Mpsvr appear to be epistatic to either of the sensitivity loci. Fibroblast focus formation by MPSV was obtained well in C57BL/6 Fv-2r and C57BL/6 Fvs fibroblasts, indicating that the genes for MPSV resistance (Fv-2r and Mpsvr) were not operating in fibroblast cells. A model is proposed which may account for the differences in response of genetically different mice to MPSV and Friend spleen focus-forming virus.     

Localization on a physical map of the NKC-linked Cmv1 locus between Ly49b and the Prp gene cluster on mouse chromosome 6.

The Cmv1 locus controls NK cell-mediated resistance to infection with murine CMV. Our recent genetic analysis of backcross mice demonstrated that the NK gene complex (NKC)-linked Cmv1 locus should reside between the Ly49 and Prp gene clusters on distal mouse chromosome 6. We have aligned yeast artificial chromosome (YAC) inserts in a contig spanning the interval between the Ly49 and Prp gene clusters. This YAC contig includes 13 overlapping YAC inserts that span more than 2 megabases (Mb) in C57BL/6 (B6) mice. Since we have identified genomic clones that span the Ly49-Prp gene region, we hypothesize that at least one should contain the Cmv1 locus. To narrow the Cmv1 critical region, we developed novel NKC genetic markers and used these to genotype informative backcross and intra-NKC recombinant congenic mouse DNA samples. These data suggest that Cmv1 resides on a single YAC insert within an interval that corresponds to a physical distance of approximately 390 kb. This high resolution, integrated physical and genetic NKC map will facilitate identification of Cmv1 and other NKC-linked loci that regulate NK cell-mediated immunity.     

Segregation of a QTL cluster for home-cage activity using a new mapping method based on regression analysis of congenic mouse strains

Recent genetic studies have shown that genetic loci with significant effects in whole-genome quantitative trait loci (QTL) analyses were lost or weakened in congenic strains. Characterisation of the genetic basis of this attenuated QTL effect is important to our understanding of the genetic mechanisms of complex traits. We previously found that a consomic strain, B6-Chr6C^MSM, which carries chromosome 6 of a wild-derived strain MSM/Ms on the genetic background of C57BL/6J, exhibited lower home-cage activity than C57BL/6J. In the present study, we conducted a composite interval QTL analysis using the F2 mice derived from a cross between C57BL/6J and B6-Chr6C^MSM. We found one QTL peak that spans 17.6 Mbp of chromosome 6. A subconsomic strain that covers the entire QTL region also showed lower home-cage activity at the same level as the consomic strain. We developed 15 congenic strains, each of which carries a shorter MSM/Ms-derived chromosomal segment from the subconsomic strain. Given that the results of home-cage activity tests on the congenic strains cannot be explained by a simple single-gene model, we applied regression analysis to segregate the multiple genetic loci. The results revealed three loci (loci 1–3) that have the effect of reducing home-cage activity and one locus (locus 4) that increases activity. We also found that the combination of loci 3 and 4 cancels out the effects of the congenic strains, which indicates the existence of a genetic mechanism related to the loss of QTLs.