Genetic control of neutrophil superoxide production in diabetes-resistant ALR/Lt mice

The neutrophil oxidative burst reaction differentiates ALR/Lt mice, known for an unusual systemic elevation of antioxidant defenses, from ALS/Lt mice, a related strain known for reduced ability to withstand oxidative stress. Neutrophils from marrow of ALS mice produced a normal neutrophil oxidative burst following phorbol ester stimulation. In contrast, ALR mice exhibited a markedly suppressed superoxide burst. F1 progeny from reciprocal outcrosses between ALR and ALS mice exhibited an intermediate burst level, higher than ALR but significantly lower than ALS. To elucidate the genetic basis for this strain difference, F1 mice were backcrossed to ALS mice, and marrow neutrophils isolated from the progeny were phenotyped for oxidative burst capacity. A genome-wide sweep using polymorphic markers distinguishing the two parental strains was performed to map the trait. A 1:1 phenotypic distribution was observed, and a locus (Suppressor of superoxide production, Susp) controlling this phenotype was mapped to Chromosome 3 near D3Mit241 at 33.1 cM. This locus probably represents an important regulatory element in the overall ALR strain resistance to oxidative stress, since diminished ability to mount a neutrophil burst in backcross segregants correlated with elevated hepatic superoxide dismutase 1 (SOD1) activity, an ALR strain characteristic.     

Constitutive differences in antioxidant defense status distinguish alloxan-resistant and alloxan-susceptible mice.

Alloxan (AL), a potent generator of superoxide and hydroxyl radicals, selectively destroys rodent pancreatic beta-cells. Alloxan-susceptible (ALS/Lt) and AL-resistant (ALR/Lt) are inbred mouse strains derived in Japan by inbreeding CD-1 (ICR) mice with concomitant selection for high or low sensitivity to a relatively low AL dose. The present study was undertaken to examine whether resistance was mediated by differences in either systemic or beta-cell antioxidant defense status. Superoxide dismutase (SOD), catalase (CAT), glutathione reductase (GR), and glutathione peroxidase (GPX) activities were determined in tissues of AL-untreated ALR/Lt and ALS/Lt male mice at 7 weeks of age. Specific activities of pancreatic SOD1, GR, and GPX were significantly increased in ALR/Lt mice compared with ALS/Lt mice. ALR/Lt mice further exhibited higher levels of glutathione in plasma, blood, pancreas, and liver combined with lower constitutive lipid peroxides in serum, liver, and pancreas. These results support the hypothesis that the selection process leading to the development of an AL-resistant mouse strain entailed accumulation of a gene or genes contributing to upregulated antioxidant status.     

Selection of mouse strains showing high and low incidences of alloxan-induced diabetes

To produce an experimental model of diabetes in animals, ICR mice were inbred until the 20th generation by two-way selection toward the high- and low-incidences of alloxan-induced diabetes. Changes in successive generations in the incidence of such diabetes, in blood glucose levels, growth patterns and reproductive performance were studied. The incidence of alloxan-induced diabetes was 41.1% in the basal population; in the high-incidence strain, it was 98.7% in F13, ranging between 90 and 99% in later generations; and in the low-incidence strain, it reached 0% in F7, remaining near that level in later generations. The heritability of the incidence of alloxan-induced diabetes determined at the beginning of selection was 50-60%. The blood glucose level was 251 +/- 19 mg/dl in the basal population; in the high-incidence strain, it was 423 +/- 11 mg/dl in F13, ranging thereafter between 340 and 455 mg/dl; and in the low-incidence strain, it was 128 +/- 4 mg/dl in F7, then varying from 120 to 140 mg/dl in following generations. The heritability of the blood glucose level determined at the beginning of selection was 40-60%. No marked decrease in growth or reproductive performance accompanied successive selections. Successive generations of the high-incidence mice, however, tended to become heavier than the low-incidence animals. The high- and low-incidence strains, established in the 20th generation, were named the ALS (alloxan-induced diabetes-susceptible) and ALR (alloxan-induced diabetes-resistant) strains, respectively.     

Commonalities of genetic resistance to spontaneous autoimmune and free radical--mediated diabetes

ALR/Lt, a NOD-related mouse strain, was selected for resistance to alloxan free radical-mediated diabetes (ALD). Despite extensive genomic identity with NOD (>70%), ALR mice display strong resistance to autoimmune type 1 diabetes (T1D) due to both an unusual elevation in systemic antioxidant defenses and a reduction in cellular ROS production that extends to the beta cell level. Reciprocal backcross to NOD previously linked the ALR-derived T1D resistance to Chr. 3, 8, and 17 as well as to the ALR mt-Nd2(a) allele encoded by the mitochondrial genome (mtDNA). To determine whether any of the ALR-derived loci protecting against T1D also protected against ALD, 296 six-week-old F2 mice from reciprocal outcrosses were alloxan-treated and assessed for diabetes onset, and a genome-wide scan (GWS) was conducted. GWS linked mt-Nd2 as well as three nuclear loci with alloxan-induced diabetes. A dominant ALR-derived ALD resistance locus on Chr. 8 colocalized with the ALR-derived T1D resistance locus identified in the previous backcross analysis. In contrast, whereas ALR contributed a novel T1D resistance locus on Chr. 3 marked by Susp, a more proximal ALR-derived region marked by Il-2 contributed ALD susceptibility, not resistance. In addition, a locus was mapped on Chr. 2, where heterozygosity provided heightened susceptibility. Tests for alloxan sensitivity in ALR conplastic mice encoding the NOD mt-Nd2(c) allele and NOD mice congenic for the protective Chr. 8 locus supported our mapping results. Alloxan sensitivity was increased in ALR.mt(NOD) mice, whereas it was decreased by congenic introduction of ALR genome on Chr. 8 into NOD. These data demonstrate both similarities and differences in the genetic control of T1D versus ROS-induced diabetes.     

Further genetic studies of the cause of exencephaly in SELH mice.

We have developed an inbred stock of mice called SELH that has a high frequency of the neural tube defect exencephaly at birth. A previous genetic study indicated that the exencephaly is due to two to three additive loci differing between SELH and a closely related normal strain, ICR/Bc, but this analysis was not designed to detect genetic maternal effects. Recently, we demonstrated that there is genetic polymorphism among normal mouse strains leading to differences in site of initiation of closure of the cranial neural tube. In the present study, an inbred substrain of SELH mice, with 24% exencephaly among embryos, was crossed with an unrelated normal strain, SWV/Bc, and the frequency of exencephaly in subsequent generations used to extend our understanding of the genetic cause of exencephaly in SELH mice. The purposes of the genetic studies reported here were twofold. First, based on the influence of genetic maternal effects on other genetically complex birth defects in mice, we hypothesized that the exencephaly of SELH mice would exhibit strong genetic maternal effects. This hypothesis was tested by comparisons among the four possible reciprocal backcrosses to SELH. The result was an overall frequency of 2.3% exencephaly in first backcross embryos with no difference among the four crosses and no evidence of genetic maternal effects. Second, the frequency of exencephaly recovered in the backcross and F1 embryos was compared with the previous genetic study and with various genetic models. The frequencies were similar to those obtained from the cross to ICR/Bc mice and were compatible with a hypothesis of additive gene action at a few loci.(ABSTRACT TRUNCATED AT 250 WORDS)     

A genetic linkage map of the rat derived from recombinant inbred strains

We have constructed a genetic linkage map in the rat by analyzing the strain distribution patterns of 500 genetic markers in a large set of recombinant inbred strains derived from the spontaneously hypertensive rat and the Brown-Norway rat (HXB and BXH recombinant inbred strains). 454 of the markers could be assigned to specific chromosomes, and the amount of genome covered by the mapped markers was estimated to be 1151 centimorgans. By including a variety of morphologic, biochemical, immunogenetic, and molecular markers, the current map integrates and extends existing linkage data and should facilitate rat gene mapping and genetic studies of hypertension and other complex phenotypes of interest in the HXB and BXH recombinant inbred strains. Received: 21 June 1995 / Accepted: 11 September 1995     

A Linkage Map of Endogenous Murine Leukemia Proviruses

Thirty endogenous proviruses belonging to the modified polytropic (Mpmv) class of murine leukemia virus (MLV) were identified by proviral-cellular DNA junction fragment segregation in several sets of recombinant inbred mice. Twenty-six Mpmv loci were mapped to chromosomal regions by matching proviral strain distribution patterns to those of previously assigned genes. Like other endogenous nonecotropic MLVs, Mpmv loci were present on several chromosomes in all strains examined. We pooled recombinant inbred strain linkage data from 110 MLV loci and selected marker genes in order to construct a chromosomal linkage map. Every mouse chromosome was found to harbor at least one proviral insertion, and several regions contained multiple integrations. However, the overall distribution of the 110 mapped proviruses did not deviate significantly from a random distribution. Because of their polymorphism in inbred strains of mice, and the ability to score as many as 57 proviruses per strain using only three hybridization probes, the nonecotropic MLVs mapped in common strains of mice offer a significant advantage over older methods (e.g., biochemical or individual restriction fragment polymorphisms) as genetic markers. These endogenous insertion elements should also be useful for assessing strain purity, and for studying the relatedness of common and not-so-common inbred strains.     

Polymorphic microsatellite markers in the outbred CFW and ICR stocks for the generation of speed congenic mice on C57BL/6 background

Reliable definition of the phenotype of particular alleles is carried out in the genetic background of inbred strains. Appearance of mutations in outbred mice therefore requires the generation of congenic mice. The aim of this study was the establishment of a list of polymorphic microsatellite markers which can be used in a polymerase chain reaction (PCR)-based marker-assisted selection protocol (MASP) to allow the use of the two common outbred stocks, CFW and ICR, as donor animals for the fast generation of congenic C57BL/6 mice. The selection of informative microsatellite markers was carried out to provide a simple evaluation of the PCR products by conventional agarose gel electrophoresis. Outbred mice from three suppliers were examined. In total, 153 microsatellite loci were analysed. Here we present 76 and 70 microsatellite markers polymorphic for the outbred ICR and CFW stocks compared to C57BL/6. At least three microsatellite loci per chromosome were chosen as informative markers for the autosomal genome, giving rise to a maximum marker distance of 58 cM. Thus, additional individual markers have to be selected for the respective outbred mouse which is chosen as a donor animal.     

Importance of biochemical marker genes in inbred strains of mice. Some problems on checking genetic purity of inbred strains (author's transl)

In order to check genetic purity of inbred strains of mice, we surveyed five biochemical variants in certain 69 strains, some of which had established from Japanese fancy mice. The loci examined were Hemoglobin beta-chain, Malic enzyme (supernatant form), Isocitrate dehydrogenase (supernatant form), Serum esterase-1, and Serum esterase-2. These loci were all in homozygous states as far as examined, however some subline divergences were found in a few strains, that is to say, sublines were found to be fixed with different alleles as some loci, Important of biochemical marker genes to check genetic purity of strains and several derived problems are mentioned.     

Biochemical genetic variants in mice selectively bred for sensitivity or resistance to ethanol-induced sedation

The distribution of biochemical genetic variants was examined among eight inbred strains of mice, which served as contributors to a heterogeneous stock of mice (HS), and in short-sleep (SS) and long-sleep (LS) mice, selectively bred from the HS stock for differential ethanol sensitivity. Fifteen loci for enzymes of alcohol and aldehyde metabolism, as well as 12 other biochemical loci, were investigated. Thirteen of these loci exhibited allelic variation between strains, of which six were separately fixed in the SS and LS mice. Comparisons of genetic similarity coefficients, based upon the distributions of allelic variants for the loci examined, with behavioural sensitivities (sleep-time) to an acute dose of ethanol for the inbred and selected strains of mice, indicated no correlations between these data. This suggests that this collective group of loci are not useful indicators of the genes selectively bred in the SS and LS strains, which are responsible for the differential sensitivities to acute doses of ethanol.     

Laboratory and wild-derived mice with multiple loci for production of xenotropic murine leukemia virus.

Mendelian segregation analysis was used to define genetic loci for the induction of infectious xenotropic murine leukemia virus in several laboratory and wild-derived mice. MA/My mice contain two loci for xenotropic virus inducibility, one of which, Bxv -1, is the only induction locus carried by five other inbred strains. The second, novel MA/My locus, designated Mxv -1, is unlinked to Bxv -1 and shows a lower efficiency of virus induction. The NZB mouse carries two induction loci; both are distinct from Bxv -1 since neither is linked to the Pep-3 locus on chromosome 1. Finally, one partially inbred strain derived from the wild Japanese mouse, Mus musculus molossinus, carries multiple (at least three) unlinked loci for induction of xenotropic virus. Although it is probable that inbred strains inherited xenotropic virus inducibility from Japanese mice, our data suggest that none of the induction loci carried by this particular M. m. molossinus strain are allelic with Bxv -1.     

Provisional QTL for circadian period of wheel running in laboratory mice: quantitative genetics of period in RI mice.

Wheel running was monitored in B x D recombinant inbred (RI) mice under dark-dark (DD) conditions, and the mean circadian period was calculated for each strain. There were significant differences for this trait among B x D recombinant inbred strains (p < .0001) and a narrow-sense heritability of 21%. Analysis of strain means and variances indicates that at least four segregating loci contribute to the genetic variance for the free-running circadian period in this population. Correlation of the strain means for the circadian period of wheel running for each RI strain against the distribution of markers at over 1500 loci along the mouse genome identified a number of provisional quantitative trait loci (QTL). There were provisional QTL for wheel running at p < .001 on chromosome 11 and at p < .01 on chromosomes 1, 6, 9, 17, and 19. Most were in agreement with a second analysis done under similar conditions.     

A common polygenic basis for quinine and PROP avoidance in mice

Inbred strains of mice (Mus musculus) differ greatly in ability to taste various bitter compounds. For some compounds, the differences result from allelic variation at a single locus. However, segregation patterns incompatible with monogenic inheritance have been found for quinine avoidance. The Soa bitter sensitivity locus exerts some influence on this phenotype, but an unknown number of other loci also contribute. Relative avoidance patterns for quinine sulfate in panels of naive inbred strains resembled avoidance patterns for 6-n-propyl-2- thiouracil (PROP), suggesting a common genetic basis. In particular, C57BL/6J mice strongly avoided both 0.1 mM quinine sulfate and 1 mM PROP in two-bottle preference tests, whereas C3H/HeJ mice were indifferent to both. Therefore, 12 BXH/Ty recombinant inbred strains, derived from these strains, were tested with both solutions to begin identification of the unknown bitter loci. Naive mice were tested for four consecutive days with each compound (order counterbalanced). Some BXH/Ty strain means resembled those of the parent strains, but others were intermediate. This indicated recombination among loci affecting avoidance, and therefore polygenic inheritance. The strain means were highly correlated across compounds (r = 0.98), suggesting that the same polygenes controlled both phenotypes. The BXH/Ty means for both compounds were then compared with the strain genotypes at 212 chromosome position markers distributed throughout the genome. Eight markers on five chromosomes (3, 6, 7, 8 and 9) yielded significant correlations. Six of the markers were correlated with both phenotypes, again suggesting common polygenic inheritance. The marker with the highest correlation was Prp, tightly linked to Soa on chromosome 6. The correlated marker regions likely contain quantitative trait loci affecting bitter avoidance. The phenotypic similarity of PROP to quinine, rather than to phenylthiourea, apparently stemming from a common polygenic basis, indicates a difference between mice and humans in gustatory organization related to bitters.      

昆明小鼠4个可能近交系的基因分型验证

在我国,昆明小鼠作为一种实验动物广泛应用于药理和遗传学相关的研究领域。但由于昆明小鼠属于远交群,而且不同地区的种群间已经出现了严重分化,缺乏具有显著特征的近交系,这使得它在生物学上的应用受到了很大的限制。研究人员已经以昆明小鼠为背景培育出了几个可能的近交系,但由于缺乏可靠的遗传检测,至今未得到广泛的认可和应用。文章收集昆明小鼠的4个已经60代以上兄妹交配繁殖的可能近交系,并以两个标准近交系BALB/c和C57BL/6为参照,利用30个微卫星标记对每个品系的5只小鼠进行了微卫星基因分型,进而分析其遗传纯度。结果发现,品系A1和品系N4在本研究所用的30个位点均呈纯合状态;而T2和N2均在D15Mit16位点呈杂合状态。本研究第一次为我国昆明小鼠近交系的遗传学纯度提供了可靠的分子水平证据。今后应当加强昆明小鼠近交系的标准化,以扩大其在遗传学方面的应用。     

Characterization of temperature-sensitive strains of Neospora caninum in mice

Temperature-sensitive (ts) strains of the Neospora caninum tachyzoites were selected by chemical mutagenesis and selection for growth at 32 C. Three ts strains and the parental, N. caninum wild-type strain, NC-1, were examined in the present study for their ability to cause disease in inbred BALB/c mice, outbred ICR mice, and chemically immunosuppressed ICR mice. In BALB/c mice, all 3 strains failed to induce clinical disease, whereas infection with the NC-1 strain caused central nervous system disease and death in some mice. No disease was observed in ICR mice inoculated with the 3 ts strains or the NC-1 strain. All immunosuppressed ICR mice inoculated with the NC-1 strain died, whereas no immunosuppressed mice inoculated with the NCts-4 strain and only 1 of 5 mice inoculated with the NCts-8 and NCts-12 strains died. The NCts-4 and NCts-12 strains reverted to a wild-type phenotype when grown at 37 C. Vaccination of BALB/c mice with live, but not frozen NCts-8 strain tachyzoites induced significant (P < 0.05) protection following NC-1 strain challenge.     

Effects of Se-enriched polysaccharides produced by Enterobacter cloacae Z0206 on alloxan-induced diabetic mice

In this study, the water-soluble selenium-enriched exopolysaccharides (Se-ECZ-EPS) were isolated from submerged culture broth of Enterobacter cloacae Z0206 through fermentation, ethanol precipitation and deproteinization. The protective effects of Se-ECZ-EPS on alloxan-induced diabetic mice were investigated. Diabetes was induced in ICR (Institute of Cancer Research) mice by administration of single doses of alloxan intraperitoneally (190 mg/kg body weight). Se-ECZ-EPS at a dose of 200 mg/kg body weight were administered per os (p.o.) as single dose per day to diabetes-induced mice for a period of 42 days. The decrease in body weight, serum insulin level, and the increase in blood glucose level, glycosylated serum protein (GSP), total cholesterol (TC) and triglycerides (TG) in liver were observed in diabetic mice. On the other hand, oral administration of Se-ECZ-EPS resulted in a significant reduction in fasting blood glucose levels, GSP, TC and TG contents in liver coupled with improvement of body weight and serum insulin level in comparison with diabetic control group. These results suggest that Se-ECZ-EPS possess significant protective and anti-diabetic effects in alloxan-induced diabetic mice.     

Genetic typing of the Senescence-Accelerated Mouse (SAM) strains with microsatellite markers

The Senescence-Accelerated Mouse (SAM) strains constitute a murine model of accelerated senescence originating from the ancestral AKR/J strains and consist of nine senescence-prone (SAMP) strains and four senescence-resistant (SAMR) strains. The chromosomes (Chrs) of the SAM strains were typed with 581 microsatellite markers amplified by PCR, and the fundamental genetic information of the SAM strains was obtained. One-third of the examined markers displayed polymorphism among the strains, and only two alleles were detected in almost all loci among the SAM and AKR/J strains. However, in 12 loci (5.6% of total 215 polymorphic markers), the third allele was detected among the SAM strains. The genetic typing and developmental history suggested that the SAM strains were related inbred strains developed by the accidental crossing between the AKR/J strain and other unknown strain(s). Comparison of the distribution of the loci in the SAMP and the SAMR series revealed notable differences in the four regions on Chrs 4, 14, 16, and 17. This indicated that some of these chromosomal sites might contain the genes responsible for accelerated senescence in the SAMP series. Received: 17 July 1998 / Accepted: 17 November 1998     

Natural killer gene complex (Nkc) allelic variability in inbred mice: evidence for Nkc haplotypes

Allelic variability for mouse Chromosome 6 Nkc loci was assessed in 22 common laboratory strains of mice using selected natural killer gene complex (Nkc)-linked sequence tagged site markers. Most Nkc markers distinguished three or more alleles for a particular locus in the assessed mouse strains. Nkc locus alleles were highly conserved among genealogically related inbred strains, whereas far less similarity was observed among unrelated strains. Concurrent strain-to-strain comparisons for all Nkc-linked loci revealed common and uncommon Nkc haplotypes, including some that were likely recombinant. Nkc allele and haplotype assignments in inbred mouse strains and correlation with phenotypic traits should facilitate positional gene cloning strategies for unknown Nkc-linked trait modification loci.     

Genetic analysis of endogenous xenotropic murine leukemia viruses: association with two common mouse mutations and the viral restriction locus Fv-1.

We have defined 40 endogenous xenotropic virus (Xmv) loci from several common inbred strains of mice by examining provirus-cell DNA junction fragments in recombinant inbred mice. Some inbred strains carried unique proviruses, but most Xmv loci were present in several strains, indicating that many Xmv integration events preexisted modern inbreeding. It was also clear that most Xmv junction fragment variation between inbred strains resulted from independent integration events and not modification or restriction site polymorphism following integration. Chromosomal assignments were determined for 32 Xmv loci by comparing their recombinant inbred strain distribution patterns to those of known genetic markers. The Xmv loci were generally dispersed throughout the genome, but several chromosomal regions contained more than one provirus. Furthermore, several close genetic associations with cellular genes were discovered. Four Xmv loci were closely linked to Fv-1b, a dominant viral resistance gene present in C57BL/6J, BALB/cJ, A/J, and several other strains. Xmv-28 was closely linked to rd (retinal degeneration), and Xmv-10 was closely linked to a (non-agouti), both of which are old mutations as inferred from their broad distribution in mice. We suggest that Xmv integration contributed to genetic diversity in the past and that much of this diversity exists today in common laboratory strains.     

Nucleoside phosphorylase 2 (Np-2) of mice

Isozyme patterns of nucleoside phosphorylase (NP) in 16 inbred strains, two recombinant inbred, one congenic, and three species of wild mice were studied. Evidence is provided for a genetic locus, Np-2, encoding an electrophoretic variant which is expressed exclusively in erythrocytes of certain inbred strains. This finding establishes the occurrence of genetic polymorphism of NP among inbred strains of mice. In addition, the Npla allele previously reported only in inbred strains has been observed in one of the species of wild mice (Mus musculus castaneus) studied.