Development of a SNP genotyping panel for genetic monitoring of the laboratory mouse

We have developed a genotyping system for detecting genetic contamination in the laboratory mouse based on assaying single-nucleotide polymorphism (SNP) markers positioned on all autosomes and the X chromosome. This system provides a fast, reliable, and cost-effective way for genetic monitoring, while maintaining a very high degree of confidence. We describe the allelic distribution of 235 SNPs in 48 mouse strains, thereby creating a database of polymorphisms useful for genotyping purposes. The SNP markers used in this study were chosen from publicly available SNP databases. Four genotyping methods were evaluated, and dynamic two-tube allele-specific PCR assays were developed for each marker and tested on a set of 48 inbred mouse strains. The minimal number of assays sufficient to distinguish groups consisting of different numbers of mouse strains was estimated, and a panel of 28 SNPs sufficient to distinguish virtually all of the inbred strains tested was selected. Amplifluor SNP detection assays were developed for these markers and tested on an extended list of 96 strains. This panel was used as a genetic quality control approach to monitor the genotypes of nearly 300 inbred, wild-derived, congenic, consomic, and recombinant inbred strains maintained at The Jackson Laboratory. We have concluded that this marker panel is sufficient for genetic contamination monitoring in colonies containing a large number of genetically diverse mouse strains and that reduced versions of the panel could be implemented in facilities housing a lower number of strains.     

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。     

Inbred mouse strains and genetic stability: a review

Inbred mice were essential animal models for scientific research during the 20th century and will contribute decisive results in the current and next centuries. Far from becoming an obsolete research tool, the generation of new inbred strains is continuing and such strains are being used in many research fields. However, their genetic properties have been overlooked for decades, although recent research has revealed new insights into their genetic fragility and relative instability. Contrary to what we usually assume, inbred mice are far from being completely isogenic and both single-gene major mutations and polygenic mutational variability are continuously uploading into inbred populations as new sources of genetic polymorphisms. Note that several inbred strains from new major mutations are released every year, whereas small mutations can accumulate up to accounting for a significant percentage of the phenotypic variance (e.g. 4.5% in a recent study on C57BL/6J mice). Moreover, this genetic heterogeneity can be maintained for several generations by heterozygote selection and, if fixed instead of dropping off, genetic drift must be anticipated. The contribution of accidental genetic contamination in inbred strains must also be considered, although its incidence in current breeding stocks should be minimal, or even negligible. This review revisits several relevant topics for current inbred strains, discussing the latest cutting-edge results within the context of the genetic homogeneity and stability of laboratory mice. Inbred mice can no longer be considered as completely isogenic, but provide a remarkably homogeneous animal model with an inevitable moderate-to-low degree of genetic variability. Despite a certain degree of genetic heterogeneity becoming inescapable, inbred mice still provide very useful animal models with evident advantages when compared with outbred, that is, highly variable, populations.     

Functional polymorphisms in inbred rat strains and their allele frequencies in commercially available outbred stocks.

Polymorphisms that have been proven to influence gene functions are called functional polymorphisms. It is significant to know the distribution of functional polymorphisms in the rat, widely used in animal models for human diseases. In this study, we assessed 16 functional polymorphisms consisting of 3 coat color and 13 disease-associated genes in 136 rat strains, as a part of the genetic profiling program of the National Bio Resource Project for the Rat (NBRP-Rat). Polymorphisms of Cdkn1a, Fcgr3, Grp10, Lss, and Fdft1, which were proven to function in prostate tumorigenesis, glomerulonephritis, hyperphagia, and cholesterol biosynthesis, were shared among various inbred strains. These findings indicated that most rat strains harbored the disease-associated alleles and suggested that many unidentified functional polymorphisms might exist in inbred rat strains. The functional polymorphisms shared in inbred strains were also observed within outbred stocks available commercially. Therefore, this implies that experimental plans based on either rat inbred strains or outbred stocks need to be carefully designed with a full understanding of the genetic characteristics of the animals. To select the most suitable strains for experiments, the NBRP-Rat will periodically improve and update the genetic profiles of rat strains.     

Use of simple sequence length polymorphisms for genetic characterization of rat inbred strains

Genetic monitoring is an essential component of colony management and for the rat has been accomplished primarily by using immunological and biochemical markers. Here, we report that simple sequence length polymorphisms (SSLPs) are a faster and more economical way of monitoring inbred strains of rats. We characterized 61 inbred strains of rats, using primer pairs for 37 SSLPs. Each of these loci appeared to be highly polymorphic, with the number of alleles per locus ranging between 3 and 14 and, as a result, all the 61 inbred strains tested in this study could be provided with a unique strain profile. These strain profiles are also used for estimating the degree of similarity between strains. This information may provide the rationale in selecting strains for genetic crosses or for other specific purposes.     

Enzyme markers in inbred rat strains: Genetics of new markers and strain profiles

Twenty-six inbred strains of the laboratory rat (Rattus norvegicus) were examined for electrophoretic variation at an estimated 97 genetic loci. In addition to previously documented markers, variation was observed for the enzymes aconitase, aldehyde dehydrogenase, and alkaline phosphatase. The genetic basis of these markers (Acon-1, Ahd-2, and Akp-1) was confirmed. Linkage analysis between 35 pairwise comparisons revealed that the markers Fh-1 and Pep-3 are linked. The strain profiles of the 25 inbred strains at 11 electrophoretic markers are given.     

Mating preferences of F2 segregants of crosses between MHC-congenic mouse strains

Male and female F₂ homozygotes from crosses between MHC-congenic inbred mouse strains were tested for MHC-associated mating preference. In three instances, of the four genotypic combinations so tested, marked MHC-associated mating preference was observed. This result greatly reduces the possibility that the observed mating preferences of MHC-congenic inbred strains can be explained wholly in terms of non-MHC genetic drift, or of residual non-MHC genetic disparity, or of fortuitous acquired strain characteristics unrelated to MHC. In two of the four combinations investigated, the MHC-related mating bias of F₂ segregants was similar to that of the genotypically similar inbred parent strains. In a third combination, F² segregants did not show the mating bias exhibited by the corresponding parent strains. In a fourth combination, F₂ segregants displayed an MHC-related mating bias that was evident in the corresponding parental inbred strains only when the colonies of the parent strains had been maintained in isolation from other strains. While the exhibition of mating preference by mice of the same genotypes may differ according to circumstances, as indicated, in no instance was preference reversed. Mating preference in a given combination of MHC genotypes, whenever it was observed, always favored the same MHC haplotype of the two alternative haplotypes represented. It appears that the familial MHC genotypes of mice and the environment in which the colonies are maintained influence their MHC-related mating preference, but it has yet to be decided whether these factors operate by determining exposure to particular MHC haplotypes.Abbreviations used in this paper are as follows B6 C57BL/6 - B10 C57BL/10 - BALE BALB/c - BALB.B BALB.B10 - INB inbred - MHC major histocompatibility complex See also Figure 1     

三个近交系C57BL/6J小鼠群体微卫星遗传变异分析(英文）

应用微卫星遗传标记对近交系C57BL/6J(B6)小鼠遗传稳定性进行分析。用FAM标记的引物PCR扩增了来自北京和上海三个实验动物生产单位提供的三个B6小鼠群体共15个微卫星位点并进行分型。结果显示,所有位点均处于纯合状态,其中7个位点为多态位点。研究表明各B6群体虽然为高度近交群体,但不同生产单位维持的B6群体之间存在遗传分化。     

Behavior-genetic analysis of the paradise fish (Macropodus opercularis). IV. Behavioral unit analysis of the response to novelty using recombinant inbred strains

Frequencies and relative durations of eleven ethologically defined behavioral units were measured on paradise fish of two inbred strains and 9 recombinant inbred lines derived from their cross and then maintained under inbreeding. Significant genotype-dependent differences were found in all but one behavior units. Strain distribution patterns showed polygenic genetic determination of all units, and in several cases non-allelic genic interactions seem to contribute to the variation. Additive and interaction components of the progenitor means and minimal number of effective factors were estimated for each behavior unit.     

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.     

Genetic background determines metabolic phenotypes in the mouse

To evaluate the contribution of genetic background to phenotypic variation, we compared a large range of biochemical and metabolic parameters at different ages of four inbred mice strains, C57BL/6J, 129SvPas, C3HeB/FeJ, and Balb/cByJ. Our results demonstrate that important metabolic, hematologic, and biochemical differences exist between these different inbred strains. Most of these differences are gender independent and are maintained or accentuated throughout life. It is therefore imperative that the genetic background is carefully defined in phenotypic studies. Our results also argue that certain backgrounds are more suited to study a given physiologic phenomenon, as distinct mouse strains have a different propensity to develop particular biochemical, hematologic, and metabolic abnormalities. These genetic differences can furthermore be exploited to identify new genes/proteins that contribute to phenotypic abnormalities. The choice of the genetic background in which to generate and analyze genetically engineered mutant mice is important as it is, together with environmental factors, one of the most important contributors to the variability of phenotypic results.     

Of "mice" and mammals: utilizing classical inbred mice to study the genetic architecture of function and performance in mammals

The house mouse is one of the most successful mammals and the premier research animal in mammalian biology. The classical inbred strains of house mice have been artificially modified to facilitate identification of the genetic factors underlying phenotypic variation among these strains. Despite their widespread use in basic and biomedical research, functional and evolutionary morphologists have not taken full advantage of inbred mice as a model for studying the genetic architecture of form, function, and performance in mammals. We illustrate the potential of inbred mice as a model for mammalian functional morphology by examining the genetic architecture of maximum jaw-opening performance, or maximum gape, across 21 classical inbred strains. We find that variation in maximum gape among these strains is heritable, providing the first evidence of a genetic contribution to maximum jaw-opening performance in mammals. Maximum gape exhibits a significant genetic correlation with body size across strains, raising the possibility that evolutionary increases in size frequently resulted in correlated increases in maximum gape (within the constraints of existing craniofacial form) during mammalian evolution. Several craniofacial features that influence maximum gape share significant phenotypic and genetic correlations with jaw-opening ability across these inbred strains. The significant genetic correlations indicate the potential for coordinated evolution of craniofacial form and jaw-opening performance, as hypothesized in several comparative analyses of mammals linking skull form to variation in jaw-opening ability. Functional studies of mammalian locomotion and feeding have only rarely examined the genetic basis of functional and performance traits. The classical inbred strains of house mice offer a powerful tool for exploring this genetic architecture and furthering our understanding of how form, function, and performance have evolved in mammals.     

Genetic variables that influence phenotype

Characterization of genetically engineered mice requires consideration of the gene of interest and the genetic background on which the mutation is maintained. A fundamental prerequisite to deciphering the genetic factors that influence the phenotype of a mutant mouse is an understanding of genetic nomenclature. Mutations and transgenes are often maintained on segregating or mixed backgrounds of often-unspecified origin. Minimizing the importance of strain and substrain differences, especially among 129 strains, can lead to poor experimental design or faulty interpretations of data. Genetic factors that influence phenotype can be categorized as traits that are unique to the background strain, unique to the gene of interest, or an interaction of both the background strain and the gene of interest. The commonly used inbred strains are generally well characterized and understood; however, specific genetic alterations combined with genes unique to the background inbred strain may lead to unexpected results. Genetic background effects can be analyzed and controlled for by using specific targeting and breeding strategies. Selection of appropriate experimental controls is critical. Ideally, mutations or transgenes should be characterized on more than one genetic background and in hybrids of the two progenitor strains. This approach may lead to the identification of novel genetic modifiers of the "gene of interest." Conditional mutagenesis technologies increase the options for controlling genetic background effects in addition to permitting the study of developmental and temporal changes in gene and protein expression and thus phenotype.     

EPISTASIS AND THE EVOLUTION OF ADDITIVE GENETIC VARIANCE IN POPULATIONS THAT PASS THROUGH A BOTTLENECK

Traditional models of genetic drift predict a linear decrease in additive genetic variance for populations passing through a bottleneck. This perceived lack of heritable variance limits the scope of founder-effect models of speciation. We produced 55 replicate bottleneck populations maintained at two male-female pairs through four generations of inbreeding (average F = 0.39). These populations were formed from an F₂ intercross of the LG/J and SM/J inbred mouse strains. Two contemporaneous control strains maintained with more than 60 mating pairs per generation were formed from this same source population. The average level of within-strain additive genetic variance for adult body weight was compared between the control and experimental lines. Additive genetic variance for adult body weight within experimental bottleneck strains was significantly higher than expected under an additive genetic model This enhancement of additive genetic variance under inbreeding is likely to be due to epistasis, which retards or reverses the loss of additive genetic variance under inbreeding for adult body weight in this population. Therefore, founder-effect speciation processes may not be constrained by a loss of heritable variance due to population bottlenecks.     

Quantitative PCR assays for mouse enteric flora reveal strain-dependent differences in composition that are influenced by the microenvironment

The mammalian gastrointestinal (GI) tract is inhabited by over a hundred species of symbiotic bacteria. Differences among individuals in the composition of the GI flora may contribute to variation in in vivo experimental analyses and disease susceptibility. To investigate potential interindividual differences in GI flora composition, we developed real-time quantitative PCR-based assays for the detection of the eight members of the Altered Schaedler Flora (ASF) as representative members of different bacterial niches within the mammalian GI tract. Quantitative and reproducible strain-specific variations in the numbers of the ASF members were observed across 23 different barrier-housed inbred mouse strains, suggesting that the ASF assays can be used as sentinels for changes in GI flora composition. A significant cage effect was also detected. Isogenic mice that cohabited at weaning, whether from the same or different litters, showed little variation in ASF profiles. Conversely, litters split among different cages at weaning showed divergence in ASF profiles after three weeks. Individual ASF profiles, once established, were highly stable over time in the absence of environmental perturbation. Furthermore, cohabitation of different inbred strains maintained most of the interstrain variation in the GI flora, supporting a role of host genetics in determining GI flora composition.     

The Genetic Divergence of Sublines as Assessed by Histocompatibility Testing

The degree of genetic divergence which has occurred between a number of inbred strains of mice and between two sublines of inbred rats was assessed by determining the fate of inter-subline skin grafts. Sublines which had been separated for 29 and 42 generations possessed no detectable incompatibility, while three combinations of sublines judged to have been maintained apart for from 123 to 129 generations showed slight degrees of histoincompatibility. One pair of sublines which had been separated for 119 generations demonstrated a marked degree of incompatibility, and an F₂ test suggested that mutations had occurred at four or five histocompatibility loci.     

近交系剑尾鱼的STR遗传检测技术

目的建立近交系实验用鱼DNA检测方法,用于遗传质量控制。方法以RR-B、RW-H、BY-F三个近交系剑尾鱼的基因组DNA为主要研究对象,并以非选育剑尾鱼作对照,采用STR（short tandem repeat）引物扩增方法检测不同品系在DNA上的异同。设计10对STR引物,优化PCR电泳条件,使用相同的实验条件进行重复,以得到可靠的扩增条带,筛选出特异性引物。结果有4对引物可扩增出稳定条带,1对引物（AY204223）的PCR扩增条带在非选育群中表现多态性,在RR-B与BY-F系表型一致,与RW-H表型不同。这些STR位点能够区分剑尾鱼三个近交系品系。结论STR检测技术可望用于近交系剑尾鱼的遗传质量监测。     

Genetic profile of alloxan-induced diabetes-susceptible mice (ALS) and-resistant mice (ALR)

Two inbred strains from a foundation stock derived from Crj: CD-1 (ICR) mice were established after more than 20 generations of full-sib mating, and by simultaneous selective breeding for developing and not developing diabetes after alloxan administration (45 mg/kg in males, 47 mg/kg in females). To elucidate the genetic background of the two inbred strains, i. e., alloxan-induced diabetes-susceptible (ALS) strain and alloxan-induced diabetes-resistant (ALR) strain, their biochemical genetic markers and immunogenetic markers were examined. 1) For both strains, investigation of biochemical genetic markers at 19 loci and immunogenetic markers at 11 loci revealed no variation in any gene within the same strain, showing to be homogeneous, thus indicating establishment of the inbred strains. 2) The two strains differed from each other at 2 loci of biochemical genetic markers and at 5 loci of immunogenetic markers. 3) The ALS and ALR strains can be regarded as new inbred strains derived from ICR mice. 4) The results show that the marker genes of the two strains are different at 7 loci, but it remains unclear whether or not these genes are involved in the difference between the two strains in susceptibility to alloxan.     

The AXB and BXA set of recombinant inbred mouse strains

The recombinant inbred (RI) set of strains, AXB and BXA, derived from C57BL/6J and A/J, originally constructed and maintained at the University of California/San Diego, have been imported into The Jackson Laboratory and are now in the 29th to 59th generation of brother-sister matings. Genetic quality control testing with 45 proviral and 11 biochemical markers previously typed in this RI set indicated that five strains had been genetically contaminated sometime in the past, so these strains have been discarded. The correct and complete strain distribution patterns for 56 genetic markers are reported for the remaining RI strain set, which consists of 31 living strains and 8 extinct strains for which DNA is available. Two additional strains, AXB 12 and BXA 17, are living and may be added to the set pending further tests of genetic purity. The progenitors of this RI set differ in susceptibility to 27 infectious diseases as well as atherosclerosis, obesity, diabetes, cancer, cleft palate, and hydrocephalus. Thus, the AXB and BXA set of RI strains will be useful in the genetic analysis of several complex diseases.     

Inbreeding and outbreeding depression in Caenorhabditis nematodes

The nematode Caenorhabditis elegans reproduces primarily by self-fertilization of hermaphrodites, yet males are present at low frequencies in natural populations (androdioecy). The ancestral state of C. elegans was probably gonochorism (separate males and females), as in its relative C. remanei. Males may be maintained in C. elegans because outcrossed individuals escape inbreeding depression. The level of inbreeding depression is, however, expected to be low in such a highly selfing species, compared with an outcrosser like C. remanei. To investigate these issues, we measured life-history traits in the progeny of inbred versus outcrossed C. elegans and C. remanei individuals derived from recently isolated natural populations. In addition, we maintained inbred lines of C. remanei through 13 generations of full-sibling mating. Highly inbred C. remanei showed dramatic reductions in brood size and relative fitness compared to outcrossed individuals, with evidence of both direct genetic and maternal-effect inbreeding depression. This decline in fitness accumulated over time, causing extinction of nearly 90% of inbred lines, with no evidence of purging of deleterious mutations from the remaining lines. In contrast, pure strains of C. elegans performed better than crosses between strains, indicating outbreeding depression. The results are discussed in relation to the evolution of androdioecy and the effect of mating system on the level of inbreeding depression.