利用多重荧光STR技术分析上海地区7品系常用近交系小鼠核心群的遗传特性

目的比较上海地区7品系常用近交系小鼠核心群的遗传特性。方法将筛选到的48对多态性丰富的微卫星引物组合优化,形成11组多重荧光PCR引物混合体系,对来自上海地区两大实验小鼠供应商的7品系近交系小鼠核心群的DNA样进行分型检测。利用遗传分析软件进行数据分析。结果来自两大供应商的7品系近交系小鼠在48个微卫星位点上都为纯合子。同一种群内小鼠的STR位点结果均一致;不同种群小鼠无论品系是否相同,相互间均存在STR位点差异。但相同品系不同种群近交系小鼠间的遗传距离与不同品系小鼠种群间的遗传距离相比均较近。在UPGMA聚类树中,相同品系的不同种群均首先两两聚成一类。C57BL/6小鼠与其他6品系小鼠的亲缘关系均较远。结论上海地区不同供应商的7品系近交系小鼠核心群间均存在STR位点差异。     

小鼠39个微卫星的PCR条件及其运用

目的探索小鼠基因组39个微卫星的PCR条件,评价微卫星在小鼠遗传检测中的运用.方法采用梯度法探索39个微卫星的PCR条件;选择本中心不同来源及引种时间的C57BL/6、BALB/c、DBA/2J、CBA/N、FVB/NJ、ICR共6个品系(8个组)小鼠,每组采用10只个体的鼠尾,提取DNA并混合成DNA池,用39个微卫星扩增后电泳观察、比较种系纯度.结果小鼠微卫星的PCR条件差异较大,Mg2+浓度多数在1.5 mmol/L左右,退火温度多数在59℃左右.在6个品系小鼠的39个微卫星位点中,C57BL/6、BALB/c、DBA/2J都是纯合的; 其余品系有1～3个杂合位点. BALB/c在D5Mitl68、D8Mit320、D13Mit262三个位点,DBA/2J在D14Mit205位点与数据库记录有差异.结论本研究为小鼠39个微卫星提供了候选的PCR条件,并对6个品系小鼠的微卫星概貌及微卫星的运用价值进行了探讨.     

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。     

微卫星DNA标记在近交系大鼠HFJ和MIJ遗传监测中的应用

目的 用24对引物对近交系HFJ和MIJ大鼠的微卫星位点进行多态性分析,并选用近交系Lewis和F344大鼠作为对照,进行比较分析.方法 用传统的酚-氯仿法分别提取4个近交系大鼠MIJ、HFJ、Lewis和F344 的基因组DNA,选取大鼠24个微卫星位点,通过PCR扩增,扩增产物经过非变性聚丙烯酰胺凝胶电泳和银染,根据电泳结果,比较分析4种品系近交系大鼠之间微卫星多态性.结果 4种品系及品系内不同个体的近交系大鼠在24个微卫星位点上的扩增产物均出现一个条带,MIJ和HFJ大鼠在品系间和品系内均表现为单态性,同Lewis 和F344的扩增结果比较,14个位点显示多态性,有10个位点显示单态性.结论 两个近交系大鼠品系MIJ和HFJ符合近交系要求,筛选出的14个多态性微卫星位点可用于有关近交系大鼠的遗传背景监测.     

多重PCR在几个近交系小鼠遗传检测中的应用初探

目的　探讨多重PCR方法在小鼠微卫星检测中的应用。方法　用 34对特异性引物对AKR、BALB c、C57 BL、DBA 2、CBA、A WY、6 15、T739、BALB cJ和AKR J 10个品系的近交系小鼠用PCR方法进行遗传检测 ,并从中选用 4对引物 ,对这些品系小鼠进行二重和多重PCR检测。结果　二重PCR在与单一PCR相同的反应条件下 ,扩增出两条与预期条带相同的带 ,而三重PCR则没有得到三条预期的条带 ,出现了干扰现象。结论　通过二条条带的距离可以鉴别出不同的近交系小鼠 ,二重PCR可应用于近交系小鼠的遗传检测 ,具有方便简单、省时的优点     

应用40对微卫星引物对6种近交系小鼠遗传背景进行监测的研究

采用40对引物的微卫星DNA PCR遗传质量符合要求的BALB／C－nu0nu-,DBA/2,SCID,T739,TA2,615等6种近交系小鼠进行遗传监测,结果26对引物有稳定的扩增结果,5对引物表现为单态性,21对引物表现出多态性,其中D2Nds3,D3Mitl5,D3Mitl7,D3Mit18,D16Mit7等6对引物表现出显著的多态性,反映了各品系小鼠独特的遗传背景,可应用于区别小鼠品系,监测系间的遗传污染,为有关小鼠品系积累了遗传背景资料,有助于将实验动物的遗传监测从表墼这度到DNA水平。     

(GTG)5探针产生的DNA指纹图在近交系小鼠遗传检测中的应用

目的探讨用非放射性标记的寡聚核苷酸探针(GTG)5进行近交系小鼠的DNA指纹分析。方法用非放射性标记的寡聚核苷酸探针(GTG)5制作BALB/c、C57BL/6J、DBA/2、C3H近交系小鼠的DNA指纹图,对这四个品系的小鼠进行遗传检测,分析各品系内和品系间的遗传变异性。结果(GTG)5探针可产生具有良好多态性的DNA指纹图,平均图带数为8~12条。各品系内的DNA指纹图平均相似系数(-x)在0.96~1.00的范围内,具有相同指纹图的概率(P)均在3.1×10-1以上,极显著地高于品系间的相似系数(0.22~0.39)和相同指纹图的概率(P<1.07×10-4)。结论(GTG)5可用于制作近交系小鼠的DNA指纹图以对其进行遗传检测。     

近交系小鼠线粒体DNA多态性的研究

目的　分析BALB/c等八个近交系小鼠线粒体DNA(mtDNA)的多态性 ,探讨近交系小鼠的遗传监测方法。方法　PCR -RFLP技术 ,即PCR技术结合限制性内切酶片段长度多态分析 (restrictionfragmentlengthPolymorphism ,RFLP)。结果　mtDNAD -Loop、tR NAIle GIN Met、ND3基因片段经HaeⅢ、HinfⅠ、EcoRV、HindⅢ、HpaⅠ、BamHⅠ、ApaⅠ、NdeⅡ、XhoⅠ、XbaⅠ、AluⅠ、RsaⅠ、StuⅠ、DraⅠ、AvaⅠ、HaeⅡ 16种内切酶分别消化后 ,BALB/c、C3H、C57BL/ 6J、T739、DBA/ 2、TA2、6 15、BALB/c -nu/nu等小鼠均表现出相同的酶切格局 ,未发现多态性。结论　BALB/c、C3H、C57BL/ 6J、T739、DBA/ 2、TA2、6 15、BALB/c -nu/nu等近交系小鼠遗传背景较为狭窄 ,不同品系小鼠间遗传背景的差异远远低于动物种属间的差异     

PCR扩增近交系大鼠微卫星位点DNA多态性的研究

本实验选取大鼠7条染色体上的微卫星位点合成了10对引物,利用聚合酶链反应（PCR）扩增技术对国内北京和哈尔滨等4家单位提供伯6个品系（SHR、SHRSP、LEW、RCS、WKY和F344）的8个近交系大鼠群体进行了DNA多态性分析的研究。结果表明：9个微卫星位点具有显多态性;不同品系个体之间具有多态性;同一群体不同个体之间除SHR（哈）的SMST位点和WKY（哈）的AGT位点出现一定的差异,其他均没有差异;不同地区同一品系的不同个体之间也存在一定的差异。该方法能有效地对近交系与杂交系、品系与品系、品系与亚系加以区分。因此,本实验为开展近交系大鼠遗传作图、基因定位和为实验动物的遗传背景监测提供可靠的信息,为大鼠遗传基因的研究提供了一个快速简例、特异准确的方法。     

BALB/c小鼠遗传质量检测的新方法

目的比较随即扩增多态性方法（RAPD）、微卫星方法（STR）与生化标记方法对近交系小鼠遗传质量检测的差异,为近交系动物遗传质量控制提供一种分子生物学方法。方法提取近交系小鼠BALB/c基因组DNA,用6条RAPD引物和20对STR引物对其进行PCR扩增,用生化标记法检测13个位点。结果在6条RAPD引物中,引物2（p2）、引物3（p3）、引物5（p5）和引物6（p6）这四条引物扩增的条带出现差异,表现为不同的RAPD图谱;在20对STR引物中,引物2、4、10和11,这四对引物扩增的条带出现差异,表现为不同的STR图谱;13个生化标记位点中,过氧化氢酶-2（Ce-2）等6个生化位点发现杂合基因。结论RAPD和STR可用于验证生化标记方法的实验结果,并用于保证近交系动物的遗传质量。     

PCR-analyzed microsatellites: Data concerning laboratory and wild-derived mouse inbred strains

We have investigated 67 primers designed by Dr. J. Todd and co-workers to amplify microsatellites sequences in the mouse. We report on additional polymorphisms concerning seven laboratory inbred strains, complementary to those already published. We include the survey of three independently derived strains of Mus spretus: SPE/Pas, SEG/Pas and SPR/Smh. SPE/Pas and SEG/Pas are very close (3% polymorphism), whereas the third one, (SPR/Smh), is very different from the other two strains (33% polymorphism). Seventy-four to 84% of the microsatellites analyzed in this study are polymorphic between C57BL/6Pas and Mus spretus strains. By comparison, 36–46% are polymorphic between laboratory inbred strains involved in established sets of recombinant inbred strains. A strain derived from Mus musculus musculus (PWK/Pas) was found to be very different from both C57BL/6Pas (70% polymorphism) and SPE/Pas (82% polymorphism). These results emphasize the interest of using Mus musculus musculus inbred strains to establish interspecific crosses, particularly when considering their breeding performances.     

Genetic polymorphisms among C57BL/6 mouse inbred strains

Mice from the inbred C57BL/6 strain have been commonly used for the generation and analysis of transgenic and knockout animal models. However, several C57BL/6 substrains exist, and these are genetically and phenotypically different. In addition, each of these substrains can be purchased from different animal providers and, in some cases, they have maintained their breeding stocks separated for a long time, allowing genetic differences to accumulate due to individual variability and genetic drift. With the aim of describing the differences in the genotype of several C57BL/6 substrains, we applied the Illumina^® Mouse Medium Density Linkage Mapping panel, with 1,449 single nucleotide polymorphisms (SNPs), to individuals from ten C57BL/6-related strains: C57BL/6JArc, C57BL/6J from The Jackson Lab, C57BL/6J from Crl, C57BL6/JRccHsd, C57BL/6JOlaHsd, C57BL/6JBomTac, B6(Cg)-Tyr ^c?2j /J, C57BL/6NCrl, C57BL/6NHsd and C57BL/6NTac. Twelve SNPs were found informative to discriminate among the mouse strains considered. Mice derived from the original C57BL/6J: C57BL/6JArc, C57BL/6J from The Jackson Lab and C57BL/6J from Crl, were indistinguishable. Similarly, all C57BL/6N substrains displayed the same genotype, whereas the additional substrains showed intermediate cases with substrain-specific polymorphisms. These results will be instrumental for the correct genetic monitoring and appropriate mouse colony handling of different transgenic and knockout mice produced in distinct C57BL/6 inbred substrains.     

Mouse microsatellites from a flow-sorted 4:6 Robertsonian chromosome

Twenty microsatellites were generated from a previously characterized gt10 library containing C57BL/6J mouse DNA from a flow-sorted 4:6 Robertsonian chromosome. These sequences were analyzed for size variation between different strains of mice with the polymerase chain reaction (PCR) and mapped by use of either strain distribution patterns (SDPs) in recombinant inbred (RI) strains, or intra- and interspecific backcrosses. Eighty-five percent of the sequences showed allelic variations between different inbred strains of mice and the wild mouse, Mus spretus, and 70% were variant between inbred strains. Eight (62%) of the 13 repeats that have been mapped lie on Chromosomes (Chr) 4 and 6. This approach is an effective way of generating informative markers on specific chromosomes.     

Genes regulating testis size.

The studies described here provide information about the genetic and morphological bases for the significant differences in testis size among three closely related C57BL mouse substrains: C57BL/6J, C57BL/6ByJ, and C57BL/10J. C57BL/6J mice have normal-size testes while the other two substrains have small-size testes. Genes controlling testis size are postulated to be among the estimated forty genes that differ between the C57BL/6J and C57BL/6ByJ substrains. The number of genes involved in testis size regulation was examined using recombinant inbred mouse strains. An investigation of the role of Y chromosome genes was performed by completing molecular analyses with a mouse Y chromosome-specific probe. Sertoli and germ cell counts provided insight into the morphological basis for the different testis sizes. The experimental results suggest that there are at least two autosomal testis-size genes and that they control testis size by regulating the number of Sertoli cells.     

Development of SNP markers for C57BL/6N-derived mouse inbred strains

C57BL/6N inbred mice are used as the genetic background for producing knockout mice in large-scale projects worldwide; however, the genetic divergence among C57BL/6N-derived substrains has not been verified. Here, we identified novel single nucleotide polymorphisms (SNPs) specific to the C57BL/6NJ strain and selected useful SNPs for the genetic monitoring of C57BL/6N-derived substrains. Informative SNPs were selected from the public SNP database at the Wellcome Trust Sanger Institute by comparing sequence data from C57BL/6NJ and C57BL/6J mice. A total of 1,361 candidate SNPs from the SNP database could distinguish the C57BL/6NJ strain from 12 other inbred strains. We confirmed 277 C57BL/6NJ-specific SNPs including 10 nonsynonymous SNPs by direct sequencing, and selected 100 useful SNPs that cover all of the chromosomes except Y. Genotyping of 11 C57BL/6N-derived substrains at these 100 SNP loci demonstrated genetic differences among the substrains. This information will be useful for accurate genetic monitoring of mouse strains with a C57BL/6N-derived background.     

Additional microsatellite markers for mouse genome mapping

Mouse sequence information from the EMBL and GenBank databases, published sequences and genomic clones have been analyzed for simple repetitive elements or microsatellites. Each microsatellite has been amplified by the polymerase chain reaction (PCR) as a single locus marker. PCR primers were designed from unique sequence flanking each repeat. Size variation of PCR products less than 750 base pairs (bp) between mouse strains has been determined using ethidium bromide-stained acrylamide or agarose gels. A further 74 newly characterized microsatellites are presented in this paper, bringing to 185 the total we have analyzed. Of these, 157/185 (85%) have more than one allele, 143/178 (80%) vary in length between C57BL/6J and Mus spretus, and 82/168 (49%) vary between DBA/2J and C57BL/6J. Microsatellites provide informative single locus probes for linkage analysis in the construction of a genetic map of the mouse genome.     

Regional linkage analysis of the dioxin-inducible P-450 gene family on mouse chromosome 9

The dioxin-inducible P-450 gene family in the C57BL/6N mouse comprises two genes, P1-450 and P3-450. Restriction endonuclease-digested genomic DNA was probed with P1-450 and P3-450 full-length cDNA clones in an attempt to find species-specific fragment length differences between mouse and hamster cell lines and any restriction fragment length polymorphism among four inbred mouse strains. With this Southern blot hybridization technique, PstI fragments were used to distinguish between the mouse and hamster P1-450/P3-450 genes, and PvuII fragments were used to distinguish P3-450 differences between the AKR/J and C57L/J inbred strains. Analysis of nineteen mouse X hamster somatic cell hybrid lines and sixteen AKXL (AKR/J X C57L/J) recombinant inbred lines showed that the P1-450/P3-450 genes are located near the Mpi-1 locus, between the Thy-1 and Pk-3 loci, in the middle portion of mouse chromosome 9.     

A catalog of nonsynonymous polymorphism on mouse Chromosome 16

Numerous phenotypic traits differ among inbred mice, and the genetic diversity of inbred strains has been exploited in studies of quantitative trait loci (QTL). Sequencing the mouse genome has resulted in improved tools for the study of QTL, but a comprehensive catalog of sequence variants between strains would be of great value in identifying and testing potentially causative alleles. A/J DNA was included in the Celera shotgun sequence of the mouse genome and C57BL/6 DNA was sequenced by an international consortium. We have resequenced A/J and B6 DNA to cover nearly all of the protein-coding portions of mouse Chromosome 16, revealing that there are 106 nonsynonymous substitutions in 74 of the 779 genes on the chromosome. The pattern of substitution is more similar to the spectrum of benign polymorphism in the human population than it is to human disease-causing mutations. In mouse, polymorphic variants tend to be associated with one another on large haplotypes; this pattern also holds true for nonsynonymous polymorphism. However, sufficient fragmentation of haplotypes is present to suggest that only a very-high-resolution haplotype map will enable effective inference of alleles in additional strains. SNP data have been submitted to dbSNP with ssid No. 46531525-46532013.     

Mouse senile amyloidosis. ASSAM amyloidosis in mice presents universally as a systemic age-associated amyloidosis.

Amyloid deposition in 11 inbred strains of mice (A/J, SJL/J, DDD, C57BL/6J, B10.BR, C57BL/10, B10A/SgSn, C3H/HeMs, B10A(5R), DBA/2 and C57BL/6Cr5/c) was studied using the peroxidase antiperoxidase (PAP) method and antisera against ASSAM and murine protein AA. Among the 170 mice examined, in 77 (45.3%) from the nine strains other than C3H/HeMs and DBA/2, there was evidence of spontaneous amyloid deposits in routine histological sections. Immunohistochemical studies using 54 mice with amyloid deposition, demonstrated ASSAM deposition in 45 mice (83.3%) in all nine strains, although the incidence and intensity of the deposition differed somewhat between strains. SJL/J and A/J had ASSAM deposits from the age of 8 months and the incidence increased with advancing age. In the other seven strains, ASSAM was first deposited at an older age than in the SJL/J and A/J strains. In A J, C57BL/6J, C57BL/10, B10.BR, B10A(5R) and C57BL/6Cr5/c, protein AA often coexisted with ASSAM. The distribution pattern of the ASSAM deposits was similar to that observed among the SAM strains. Thus, ASSAM is an ubiquitously distributed senile amyloid protein in the mouse. Determination of the molecular type of apoA-II, a serum precursor of ASSAM, among all 11 strains using the polymerase chain reaction (PCR) revealed the SAM-P/1 type apoA-II variant in SJL/J and A/J strains with a high susceptibility to ASSAM deposition. We concluded from this study that amino acid substitution in precursor apoA-II may be responsible for the early onset and severe amyloid deposition in the mouse.