应用荧光原位杂交技术检测人类APPSWE基因在转基因小鼠染色体上的定位及位置效应

应用荧光原位杂交技术研究了人类淀粉样前体蛋白基因瑞典型突变（APPSWE）在转基因小鼠首建、F1及F2代小鼠染色体上的整合及定位,结果在2只首建转基因小鼠中,分别观察80个分裂相,出现杂交信号的核型分别为34及36个,检出率为42.5%和45%;1只F1及1只F2代转基因小鼠中,分别观察100个分裂相,出现杂交信号的核型分别为33及30个,检出率为33%和30%。转基因分别整合在8号、1号、17号和2号染色体上,提示转基因APPSWE已稳定整合到转基因小鼠的染色体上,并通过生殖细胞遗传给予子代,证实转基因在小鼠染色上的整合可能是随机的多点整合,同时,对不同整合位点的转基因小鼠进行了表型研究,结果发现不同整合位点对表型具明显影响。     

应用反向PCR克隆慢病毒介导的转基因小鼠整合位点序列

目的：为分析慢病毒介导的转基因小鼠中外源基因整合位点的信息,应用反向PCR克隆整合位点序列。方法：小鼠基因组总DNA酶解和自连接后,针对慢病毒载体的特点在LTR附近设计一组特异的PCR引物,优化半巢式PCR的各种参数,提高整合位点序列克隆的效率。结果：克隆了分别携带绿色荧光蛋白（GFP）和转铁蛋白（TF）基因的慢病毒介导的转基因小鼠家系7只小鼠中10个外源基因整合位点序列。结论：本方法可用于慢病毒介导的转基因小鼠整合位点序列的克隆,为分析整合位点与外源基因表达之间的关系等提供了科学依据。     

血管内皮生长因子 (VEGF1 83)转基因小鼠的建立(英文)

采用显微注射法 ,将一个由 1.3kb人感光细胞间维生素A类结合蛋白 (hIRBP)启动子区和人血管内皮生长因子 (hVEGF183)cDNA所构成的融合基因片段HIRV183导入 2 89枚ICR小鼠受精卵的雄性原核 .制备当代 (G0 )转基因小鼠 ,共得G0 代小鼠 17只 .经PCR和PCR Southern方法筛选得到 1只为hVEGF183转基因阳性小鼠 ,整合率为 5 9%,转基因总效率为 0 3%.将其与正常ICR小鼠交配 ,经PCR和dot blot杂交鉴定后代 (F1)小鼠阳性整合率为 4 5 9%.F1代兄妹之间进行交配 ,后代 (F2 )小鼠阳性整合率为 6 7 6 %.结果表明 ,外源基因hVEGF183整合在小鼠染色体的单一位点 ,为以后利用转基因动物的方法对VEGF这个新型异构体VEGF183进行深入研究打下了基础     

应用荧光原位杂交检测人凝血因子Ⅸ在转基因小鼠染色体上的整合

应用荧光原位杂交（FISH）技术检测两个转基因小鼠家系从F1到F4代的整合情况。阳性转基因小鼠98%~100%的中期分裂相,85%~94%的间期核出现杂交信号;阴性对照小鼠100%的中期分裂相、95%~96%的间期核未出现杂交信号。结果表明,该FISH实验条件能对转基因整合位点进行高效特异检测。本文分析的两家系转基因小鼠均为单位点整合, 但整合位点不同。各家系内F1到F4代的转基因小鼠均可检出整合染色体,且整合位点相同,表明外源基因稳定整合并遗传给后代。 Abstract:Fluorescence in situ hybridization （FISH） was used to detect the integration of hFⅨ on chromosomes of transgenic mice from F1 to F4 generation in two strains.For transgenic mice,98%~100% of metaphases and 85%~94% of interphases showed hybridization signal.For negative control mice,100% of metaphases and 95%~96% of interphases showed no hybridization signal.The results demonstrated that FISH developed to detect the integration sites of hFⅨ was high efficient and specific.The integration sites of the transgenic mice analyzed were both single but different between the two strains.The integration chromosomes can be found in the transgenic mice from F1 to F4 generation and the integration sites were the same as each of the strains,which indicated that the transgene was stably integrated and transmitted to offspring.     

外源基因在转基因小鼠中遗传和表达的稳定性

通过显微注射将外源构件λ１０６（年α－Ｓ１酪蛋白基因调控区指导的乙肝病毒表面抗原基因表达构件）导入小鼠受精卵中,用ＰＣＲ－Ｓｏｕｔｈｅｍ方法进行外源基因的整合检测、ＥＬＩＳＡ法进行外源基因的表达检测,对４代转基因小鼠进行了跟踪测定,结果表明：的代转基因小鼠的整合率为５６％,原代雌鼠乳汁中转基因产物的表达率为１００％;传代跟踪基因的整合率不符合“单一位点随机整合”的假说,家系分析推测外源基因在受精卵     

应用荧光原位杂交技术检测人β^E珠蛋白基因小鼠染色体上的整合状态

为将荧光原位杂交技术应用于基因定位研究中,探讨一种能有效地检测转基因动物染色体上外源基因整合状态的实验方法,对小鼠腹腔注射秋水仙素后,取转基因小鼠骨髓制备中期染色体,将传统的FISH方法加以改进,检测外源基因在转基因小鼠染色体上的整合状态。检测结果表明,外源人β^E珠蛋白基因已稳定地整合于小鼠染色体上,FISH能直观地反映外源基因在转基因动物染色体上的整合状态,该方法可对转基因动物及基因转移研究中的外源基因整合反进行染色体定位检测。     

TIMP-1转基因小鼠纯合子的建立及建系

采用遗传学育种方法 ,使外源基因整合位点随机的基质金属蛋白酶抑制剂 1(TIMP 1)转基因小鼠成为单一整合位点的纯合子转基因小鼠而建立TIMP 1转基因小鼠品系 .通过受精卵原核显微注射方法 ,获得带有人TIMP 1基因的Founder小鼠 .将转基因小鼠与正常小鼠交配 ,得到子代小鼠 .通过PCR及Southern印迹等方法 ,检测TIMP 1DNA在转基因小鼠体内的整合情况 ,阳性率达5 0 %后 ,进行近亲交配 .提取小鼠组织总RNA ,Northern印迹分析阳性小鼠各组织外源性TIMP 1mRNA表达情况 ,以正常NIH小鼠做对照 .获得了 6代小鼠共 4 2 4只 ,其中PCR阳性鼠 2 72只 ,Southern阳性鼠 2 2 6只 ,纯合子转基因小鼠 12 8只 ;F4代后阳性率达到 95 %以上 .转基因小鼠TIMP 1基因表达情况在肾脏的丰度明显高于肝脏和脾脏 (P <0 0 1) ,而肝和脾之间并没有显著差异 (P>0 0 5 ) .外源基因在转基因小鼠体内可以稳定遗传 ,并得到了整合有TIMP 1基因的纯合子转基因小鼠 ,且在阳性的转基因小鼠体内在肾脏中特异性表达 ,为以后开展TIMP 1的肾脏病理生理研究提供了有用的手段     

应用接头PCR克隆慢病毒介导的转基因小鼠整合位点旁侧序列

目的为鉴定慢病毒介导的转基因小鼠中外源基因的整合位点信息,应用接头PCR克隆整合位点旁侧序列。方法小鼠基因组总DNA酶解后与设计的接头片段连接,根据慢病毒的LTR序列设计巢式PCR引物,克隆转基因小鼠整合位点旁侧序列。结果成功克隆到转基因小鼠整合位点的旁侧序列,经过测序定位于小鼠染色体上。结论作为反向PCR的改进,本方法可用于转基因小鼠整合位点旁侧序列的克隆,为分析整合位点与外源基因表达之间的关系等提供了科学依据。     

应用荧光原位杂交技术检测人βE珠蛋白基因在转基因小鼠染色体上的整合状态

为将荧光原位杂交技术应用于基因定位研究中,探讨一种能有效地检测转基因动物染色体上外源基因整合状态的实验方法,对小鼠腹腔注射秋水仙素后,取转基因小鼠骨髓制备中期染色体,将传统的FISH方法加以改进,检测外源基因在转基因小鼠染色体上的整合状态.检测结果表明,外源人βE珠蛋白基因已稳定地整合于小鼠染色体上.FISH能直观地反映外源基因在转基因动物染色体上的整合状态,该方法可对转基因动物及基因转移研究中的外源基因整合后进行染色体定位检测。 Abstract:To determine the integration site of human βE globin gene in the chromosomes of transgenic mice, transgenic mice carrying human βE globin gene were injected intraperitoneally with colchicines, then, bone marrow cells wereisolated and metaphase chromosomes were prepared, the traditional FISH method was improved to detect the integration site of humanβE globin gene in transgenic mice when combined with G-banding. Human t3E globin gene can bedetected in different position of different chromosomes in transgenic mice and FISH signals showed that two mice were heterozygous of human 13E globin gene and one was homozygous. Human t3E globin gene was integrated into thechromosomes of transgenic mice in a random pattern and the results demonstrated that FISH can be used to investigate the integration site of foreign genes in transgenic mice.     

应用荧光原位杂交技术检测人βE珠蛋白基因在转基因小鼠染色体上的整合状态

为将荧光原位杂交技术应用于基因定位研究中,探讨一种能有效地检测转基因动物染色体上外源基因整合状态的实验方法,对小鼠腹腔注射秋水仙素后,取转基因小鼠骨髓制备中期染色体,将传统的FISH方法加以改进,检测外源基因在转基因小鼠染色体上的整合状态.检测结果表明,外源人βE珠蛋白基因已稳定地整合于小鼠染色体上.FISH能直观地反映外源基因在转基因动物染色体上的整合状态,该方法可对转基因动物及基因转移研究中的外源基因整合后进行染色体定位检测。 Abstract:To determine the integration site of human βE globin gene in the chromosomes of transgenic mice, transgenic mice carrying human βE globin gene were injected intraperitoneally with colchicines, then, bone marrow cells wereisolated and metaphase chromosomes were prepared, the traditional FISH method was improved to detect the integration site of humanβE globin gene in transgenic mice when combined with G-banding. Human t3E globin gene can bedetected in different position of different chromosomes in transgenic mice and FISH signals showed that two mice were heterozygous of human 13E globin gene and one was homozygous. Human t3E globin gene was integrated into thechromosomes of transgenic mice in a random pattern and the results demonstrated that FISH can be used to investigate the integration site of foreign genes in transgenic mice.     

Mea2/Golga3 gene is disrupted in a line of transgenic mice with a reciprocal translocation between Chromosomes 5 and 19 and is responsible for a defective spermatogenesis in homozygotes

A line of transgenic mouse T604 transmitted a transgene to progeny together with a set of chromosomes with a reciprocal translocation. The transgene was integrated at a single site in the translocated chromosomes, as revealed by fluorescence in situ hybridization. The transgenic hemizygous males, also heterozygous for the translocation of chromosomes, showed apparently normal spermatogenesis, while the males homozygous for the transgene as well as for the translocated chromosomes showed a defect in spermatogenesis. Considering that the genetic rearrangement by either insertion of the transgene or the chromosome translocation in the T604 mouse line might have caused a recessive mutation in a gene indispensable for spermatogenesis, we have mapped the transgene integration site and the translocation breakpoints in mouse chromosomes. Linkage analysis with SSLP markers showed that the loci for the transgene and the translocation breakpoints were closely located to D5Mit24 on Chromosome (Chr) 5, and to a region between D19Mit19 and D19Jpk2 on Chr 19. Mea2 gene, mapped only 2 cM from D5Mit24 and known to show male-specific enhanced expression in the testis, was analyzed as a candidate for the gene disrupted in T604 transgenic mice. Southern blot analysis revealed that Mea2 gene was indeed disrupted in T604 mice, and Northern blot analysis of the testis RNA showed that the expression of Mea2 was annihilated in the testis of T604 transgenic homozygotes. Received: 8 July 1998 / Accepted: 23 September 1998     

E1 mice epilepsy shows genetic polymorphism for S-Adenosyl-L-homocysteine hydrolase

E1 mice are an animal model of human epilepsy (idiopathic complex partial seizures). We have previously demonstrated abrupt poly(A)(+) RNA expression in liver from 1-day-old E1 mouse [Mita et al., 1991. Devl. Brain Res. 64, 27-35]. In the present study, we constructed a cDNA library of the poly(A)(+) RNA. By analyzing cDNA clones and nucleotide sequences, we found a clone that was homologous to a rat gene of S-adenosyl-L-homocysteine hydrolase (EC 3.3.1.1.) (SAHH) (a key enzyme in the active methyl transfer pathway) and showed the gene polymorphism/RFLP(PstI) between the epileptic strain, E1, and the non-epileptic mother strain, ddY, as indicated in a gel electrophoresis by cleaving 2.6 kb with PstI into 1.9 kb and 0.7 kb fragment bands. F1(E1xddY) showed the heterozygosity. An attempt to determine the mutation on the genomic SAHH gene in the E1 disclosed a single nucleotide polymorphism indicated by a C-->T transition in the 8th intron, by which the PstI site was created. SAHH enzymatic activity in the liver in 1-day-old E1 mice was slight (approximately 10%), and in fact was significantly lower than that of the control ddY. Results suggested that the abrupt primary mRNA transcribed on the SAHH gene in the liver of 1-day-old E1 mice was processed partially or incompletely because of the presence of the point mutation in the intron. Accordingly, poor energy supply by the insufficient SAHH enzymatic activity in the brain postnatally may be responsible for epileptogenesis in this animal model. It is concluded that a single nucleotide SAHH gene polymorphism may be associated with epilepsy in E1 mice.     

Analysis of tissue-specific expression of human type II collagen cDNA driven by different sizes of the upstream region of the beta-casein promoter

To investigate the ability of 1.8 kb or 3.1 kb bovine beta-casein promoter sequences for the expression regulation of transgene in vivo, transgenic mice were produced with human type II collagen gene fused to 1.8 kb and 3.1 kb of bovine beta-casein promoter by DNA microinjection. Five and three transgenic founder mice were produced using transgene constructs with 1.8 kb and 3.1 kb of bovine beta-casein promoters respectively. Founder mice were outbred with the wild type to produce F1 and F2 progenies. Total RNAs were extracted from four tissues (mammary gland, liver, kidney, and muscle) of female F1 transgenic mice of each transgenic line following parturition. RT-PCR and Northern blot analysis revealed that the expression level of transgene was variable among the transgenic lines, but transgenic mice containing 1.8 kb of promoter sequences exhibited more leaky expression of transgene in other tissues compared to those with 3.1 kb promoter. Moreover, Western blot analysis of transgenic mouse milk showed that human type II collagen proteins secreted into the milk of lactating transgenic mice contained 1.8 kb and 3.1 kb of bovine beta-casein promoter. These results suggest that promoter sequences of 3.1 kb bovine beta-casein gene can be used for induction of mammary gland-specific expression of transgenes in transgenic animals.     

增强子驱动的Cre转基因小鼠的构建及Cre基因的表达鉴定

目的:探索将增强子应用于构建Cre转基因小鼠品系,为以条件基因敲除为基础的基因功能研究提供更多的工具。方法:通过PCR方法从小鼠的细菌人工染色体扩增UH增强子片段,构建含有Hsp68基础启动子、增强子UH、Cre重组酶基因和SV40 polyA的转基因载体pLW400,将3.3 kb的转基因片段通过显微注射导入小鼠受精卵;为了检测Cre在转基因小鼠中的表达,将转基因一代小鼠与纯合子ROSA26报告小鼠(R/R)交配,收集第14 d胚胎期(E14)的舌组织进行LacZ染色检测鉴定。结果:经鉴定,31只子代小鼠中有6只携带外源基因,整合率为19.4%;与R/+对照相比,E14期的双基因型Cre,R/+舌组织为阳性结果(蓝色)。这表明Cre基因在转基因小鼠舌组织内得到表达,并在体内介导ROSA26基因座loxP位点间的重组,且有效删除了2个loxP之间的片段,从而启动了LacZ基因的表达。结论:构建了UH增强子-Hsp68Cre的转基因小鼠,在舌肌中特异表达Cre基因,提示增强子可以被选择应用于Cre转基因小鼠的构建;为舌肌的发育和再生研究奠定了基础。     

Integration site analysis in transgenic mice by thermal asymmetric interlaced (TAIL)-PCR: segregating multiple-integrant founder lines and determining zygosity

When transgenic mice are created by microinjection of DNA into the pronucleus, the sites of DNA integration into the mouse genome cannot be predicted. Most methods based on polymerase chain reaction (PCR) that have been used for determining the integration site of foreign DNA into a genome require specific reagents and/or complicated manipulations making routine use tedious. In this report we demonstrate the use of a PCR-based method-TAIL-PCR (Thermal Asymmetric Interlaced PCR) which relies on a series of PCR amplifications with gene specific and degenerate primers to reliably amplify the integration sites. By way of example, using this approach, three separate integration sites were found (on chromosomes 8, 15 and 17) in one transgenic founder. As the sites on chromosomes 8 and 15 failed to segregate in any subsequent progeny, whole chromosome paints were done to determine if translocations involving chromosomes 8 and 15 occurred at the time of transgene integration. Whole chromosome painting could not detect translocations, suggesting that the rearrangements likely involve only small stretches of chromosomes. Site-specific primers were used to identify the progeny carrying only one integration site; these mice were then used as sub-founders for subsequent breedings. Integration site specific primers were used to distinguish homozygous progeny from heterozygotes. TAIL-PCR thus provides an easy and reliable way to (1) identify multiple integration sites in transgenic founders, (2) select breeders with one integration site, and (3) determine zygosity in subsequent progeny. Use of this strategy may also be considered to map integration sites in situations of unexpected phenotype or embryonic lethality while creating new transgenic mice.