成骨细胞特异性表达Cre重组酶转基因小鼠的建立

构建了含有骨钙素基因启动子、Cre重组酶基因和人生长激素基因polyA的转基因载体pOC-Cre, 以显微注射的方法将4.6 kb的转基因片段OC-Cre导入小鼠受精卵。16只子代小鼠中经PCR和Southern杂交鉴定, 有2只小鼠携带外源基因, 整合率为12.5%。为了检测OC-Cre在转基因小鼠中表达的组织特异性, 将转基因首建者小鼠与基因组上携带有LoxP位点的条件性Smad4基因敲除小鼠交配, PCR结果显示, 仅在子代纯合型小鼠骨组织基因组中扩增出了Cre介导重组后的片段。将OC-Cre转基因小鼠与ROSA26报告小鼠交配, 利用LacZ染色对双转基因阳性子代小鼠进行检测, 结果显示Cre重组酶在成骨细胞中特异性表达并介导ROSA基因座LoxP位点间的重组。所有这些结果说明：所建立的OC-Cre转基因小鼠在成骨细胞中特异性表达Cre重组酶, 并能在体内介导成骨细胞基因组上LoxP位点间的重组, 是一种理想的研制成骨细胞特异性基因敲除小鼠的工具小鼠。     

血管内皮细胞特异表达Cre重组酶转基因小鼠的建立

血管内皮细胞参与血管形成、血管稳态维持、血栓形成、炎症和血管重建等生理和病理过程。为了便于通过Cre-LoxP系统研究相关基因在血管内皮细胞中的功能,创建了Tie2-Cre转基因小鼠,利用Tie2基因的启动子驱动Cre重组酶基因在血管内皮细胞中表达。经基因组PCR和Southern Blot鉴定有6只小鼠在基因组上整合有Cre基因,整合率为11％。为了验证Cre重组酶的剪切活性和表达组织分布,我们将Tie2-Cre转基因小鼠分别与Smad4条件基因打靶小鼠和报告小鼠ROSA26交配。Tie2-Cre;Smad4^co/＋小鼠的多个组织的基因组DNA的PCR结果显示,Cre重组酶在所有包含血管内皮细胞的组织中表达并能介导LoxP间的重组。Tie2-Cre;ROSA26双转基因胚胎LacZ染色结果显示,Cre重组酶在所有被检测组织的血管内皮细胞中特异性表达。因此．Tie2-Cre转基因小鼠可作血管内皮细胞谱系分析和在血管内皮细胞进行条件基因打靶的理想工具小鼠。     

心脏和软骨细胞特异性表达Cre重组酶转基因小鼠的基因型鉴定

我们曾经报道了分别在心脏(α—MHC—Cre)和软骨细胞(Col2A1-Cre)特异性表达Cre重组酶转基因小鼠的成功研制。为了对这2种转基因小鼠进行特异性的基因型鉴定,设计了2对特异性PCR引物,其中一条引物分别位于α-肌球蛋白重链基因(α-MHC)启动子和Ⅱ型胶原(Col2Al)启动子上。以6种不同组织特异性Cre重组酶转基因小鼠基因组DNA为模板,利用设计的特异性引物以及位于Cre编码区的通用引物进行PCR反应。结果显示,2对特异性引物可以分别将心肌细胞特异性和软骨细胞特异性Cre重组酶转基因小鼠与其他组织特异性Cre重组酶转基因小鼠有效区分开来。     

角质细胞特异性表达Cre重组酶转基因小鼠的建立

构建了含有角质细胞特异性角质素5启动子、Cre重组酶基因和人生长激素基因plyA的转基因载体pK5-Cre-hGH。以显微注射的方法将4．2kb的转基因片段K5-Cre-hGH引入小鼠基因组,共注射720枚受精卵,其中龄5枚移植至29只假孕母鼠的输卵管中发育,获得子代小鼠48只,经基因型鉴定有12只小鼠在其基因组上整合有Cre基因,整合率为25％。将带有cre重组酶基因的小鼠与基因组上携带loxP位点的smad4条件基因打靶小鼠杂交以检测Cre重组酶组织特异性表达情况以及介导重组的功能。结果表明,K5-Cre转基因小鼠只在皮肤组织中表达Cre重组酶并能在体内成功地介导loxP位点的重组。     

中枢神经系统特异性表达Cre重组酶的转基因小鼠

利用从129sv小鼠基因组文库克隆得到的1．8kb的胶质细胞原纤维酸性蛋白(GFAP)基因的5′端调控序列,构建了含有2个β—珠蛋白绝缘子、GFAP5′端调控区、Cre基因和人生长激素基因(hGH)polyA的转基因载体pGFAP—Cre—hGH。以显微注射的方法将7．6kb的转基因片段pGFAP—Cre—hGH引入191枚小鼠基因组受精卵,其中176枚分别移植至8只假孕母鼠的输卵管中使其发育,共获得子代小鼠25只。经PCR和Southern杂交鉴定其中7只小鼠基因组上整合有Cre基因,整合率为28％。用整合有Cre基因的转基因小鼠与基因组上整合有LoxP位点和LacZ表达框的ROSA26鼠杂交,以检测Cre酶的活性、组织特异性及其介导的两个LoxP位点间的重组。LacZ染色结果表明,GFAP—Cre转基因小鼠只在中枢神经系统中表达Cre重组酶并能在体内成功介导LoxP位点间的重组。     

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。     

特异性检测胰腺组织表达Cre重组酶转基因小鼠的方法

利用组织特异性分子标志物启动子调控Cre重组酶,研制了6种在不同组织中特异性表达Cre重组酶的转基因小鼠.这些转基因小鼠的基因型鉴定均使用设计在Cre基因编码区的通用引物.为了特异性检测胰腺组织表达Cre重组酶的转基因小鼠,在大鼠胰岛素RIP启动子上和Cre基因上设计1对引物进行PCR扩增,并通过凝胶电泳进行分析.PCR结果显示,设计在Cre基因上的通用引物可以从6种不同组织特异性Cre重组酶转基因小鼠基因组DNA中扩增获得480 bp产物;利用本研究设计的特异性引物可以从胰腺组织表达Cre重组酶转基因小鼠基因组DNA中扩增200 bp的目的条带.这一结果表明,利用特异性引物进行PCR反应,可有效地将胰腺组织表达Cre重组酶转基因小鼠与其他多种组织的Cm重组酶转基因小鼠鉴别开来.     

消化道细胞表达Cre重组酶转基因小鼠的功能鉴定

目的:检测白蛋白启动子介导的Cre重组酶转基因小鼠Alb-Cre-2中Cre重组酶的组织分布及其在体内介导基因重组的作用。方法:将Alb-Cre小鼠与Smad4条件基因打靶小鼠交配,利用PCR对Cre重组酶介导重组的组织特异性进行检测;然后,将Alb-Cre-2转基因小鼠与ROSA26报告小鼠交配,利用LacZ染色对双转基因阳性子代小鼠进行检测。结果:PCR结果显示心、肺、胰、脑及消化道中Cre重组酶介导的Smad4基因发生重组;LacZ染色进一步表明Cre重组酶在肝细胞、胃壁细胞、空肠潘氏细胞、回肠杯状细胞、大肠杯状细胞、大肠柱状细胞及空泡细胞中特异性表达,并介导ROSA位点LoxP序列间的重组。结论:Alb-Cre-2转基因小鼠在消化道中具有一定的组织特异性,只在胃壁细胞、空肠潘氏细胞、回肠杯状细胞、大肠杯状细胞,大肠柱状细胞及空泡细胞等细胞类型中特异性表达,并能在体内成功地介导这些消化道上皮细胞基因组上LoxP位点间的重组,是一种研制在消化道特定细胞中特异性基因剔除小鼠的良好工具小鼠。     

胰腺组织表达Cre重组酶转基因小鼠的建立及鉴定

组织特异性表达Cre重组酶的转基因小鼠是进行组织特异性基因剔除研究的重要工具。为了建立胰腺组织特异性Cre转基因小鼠,我们通过PCR克隆了大鼠胰岛素基因启动子,并用它指导Cre基因在胰岛细胞中的特异性表达。在Cre重组酶基因5′端添加了真核核糖体结合序列和核定位序列以使Cre重组酶能穿越核膜在细胞核中发挥功能;同时,在Cre基因3′端添加了含内含子的3′端人生长激素基因。表达载体经显微注射导入小鼠受精卵以建立转基因小鼠。PCR检测显示共获得7只Cre整合阳性的转基因首建者小鼠;RTPCR结果表明其中1只首建者小鼠的子代鼠在胰腺中转录了外源基因,进一步的Southern杂交结果表明,该转基因小鼠能够在胰腺中表达有功能的Cre重组酶。      

表面活性蛋白A启动子指导Cre重组酶在转基因小鼠Ⅱ型肺上皮细胞中表达

Ⅱ型肺上支细胞合成和分泌肺表面活性物质（PS）,与肺损伤后的修复有关,很多肺相关疾病的发生伴随有Ⅱ型肺上皮细胞功能不全及PS系统缺陷。Ⅱ型肺上皮细胞在肺的发育、机体免疫及疾病的发生发展过程中的具体功能尚不明确．对调控Ⅱ型肺上皮细胞功能的遗传机制也知之甚少。为了利用Cre-loxP系统研究调节Ⅱ型肺上皮细胞功能的遗传机制,研制了表面活性蛋白A（SP—A）启动子指导Cre重组酶基因在转基因小鼠Ⅱ型肺上皮细胞中表达的转基因小鼠。将整合有Cre重组酶基因的首建者小鼠与Smad4条件基因打靶小鼠及ROSA26报告小鼠交配,利用基因组PCR和LacZ染色检测Cre重组酶表达的组织分布及其钵内介导loxP位点间重组的活性。多组织基因组PCR显示Cre重组酶在转基因小鼠肺、脑和消化道组织中表达。LacZ染色显示仅在Ⅱ型肺上皮细胞中检测到Cre重组酶的活性。以上结果表明本研究研制的pSP—A—Cre转基因小鼠可用于在Ⅱ型肺上皮细胞中进行条件基因打靶和细胞谱系分析。     

Transgenic mice that express Cre recombinase in hypertrophic chondrocytes

In order to investigate the physiological control of hypertrophic chondrocytes which present the terminally differentiated form of chondrocytes, we generated a mouse line expressing the Cre recombinase under the control of the mouse type X collagen (Col10a1) promoter. In situ hybridization analysis demonstrated the expression of Col10a1-Cre transgene in hypertrophic chondrocytes of femur at postnatal day 2 (P2). In order to test the excision activity of the Cre recombinase, the Col10a1-Cre transgenic line was crossed with the mouse strain carrying the Smad4 conditional alleles (Smad4co/co) and the reporter line ROSA26. Multiple tissue PCR of Col10a1-Cre;Smad4co/+ mice revealed the restricted Cre activity in tissues containing hypertrophic chondrocytes. LacZ staining revealed that the Cre activity was observed in the cartilage primordia of ribs at E14.5 and only detected in the lower hypertrophic region of ribs at P1. These data suggest that the Col10a1-Cre mouse line described here could be used to achieve conditional gene targeting in hypertrophic chondrocytes.     

Collagen1alpha1 promoter drives the expression of Cre recombinase in osteoblasts of transgenic mice

Osteoblasts participate in bone formation, bone mineralization, osteoclast differentiation and many pathological processes. To study the function of genes in osteoblasts using Cre-LoxP system, we generated a mouse line expressing the Cre recombinase under the control of the rat Collagen1alpha1 (Col1alpha1) promoter (Col1alpha1-Cre). Two founders were identified by genomic PCR from 16 offsprings, and the integration efficiency is 12.5%. In order to determine the tissue distribution and the activity of Cre recombinase in the transgenic mice, the Col1alpha1-Cre transgenic mice were bred with the ROSA26 reporter strain and a mouse strain that carries Smad4 conditional alleles (Smad4(Co/Co)). Multiple tissue PCR of Col1alpha1-Cre;Smad4(Co/+)mice revealed the restricted Cre activity in bone tissues containing osteoblasts and tendon. LacZ staining in the Col1alpha1-Cre;ROSA26 double transgenic mice revealed that the Cre recombinase began to express in the osteoblasts of calvaria at E14.5. Cre activity was observed in the osteoblasts and osteocytes of P10 double transgenic mice. All these data indicated that the Col1alpha1-Cre transgenic mice could serve as a valuable tool for osteoblast lineage analysis and conditional gene knockout in osteoblasts.     

Expression and activity of osteoblast-targeted Cre recombinase transgenes in murine skeletal tissues

The Cre/loxP recombination system can be used to circumvent many of the limitations of generalized gene ablation in mice. Here we present the development and characterization of transgenic mice in which Cre recombinase has been targeted to cells of the osteoblast lineage with 2.3 kb (Col 2.3-Cre) and 3.6 kb (Col 3.6-Cre) fragments of the rat Col1a1 promoter. Cre mRNA was detected in calvaria and long bone of adult Col 2.3-Cre and Col 3.6-Cre mice, as well as in tendon and skin of Col 3.6-Cre mice. To obtain a historical marking of the temporal and spatial pattern of Cre-mediated gene rearrangement, Col-Cre mice were bred with ROSA26 (R26R) mice in which Cre-mediated excision of a floxed cassette results in LacZ expression. In Col 2.3-Cre;R26R and Col 3.6-Cre;R26R progeny, calvarial and long bone osteoblasts showed intense beta-gal staining at embryonic day 18 and postnatal day 5. The spatial pattern of beta-gal staining was more restricted in bone and in bone marrow stromal cultures established from Col 2.3-Cre;R26R mice. Similar differences in the spatial patterns of expression were seen in transgenic bone carrying Col1a1-GFP visual reporters. Our data suggest that Col 2.3-Cre and Col 3.6-Cre transgenic mice may be useful for conditional gene targeting in vivo or for obtaining osteoblast populations for in vitro culture in which a gene of interest has been inactivated.     

Transgenic mice that express Cre recombinase in osteoclasts

To study the physiological control of osteoclasts, the bone resorbing cells, we generated transgenic mice carrying the Cre recombinase gene driven by either the tartrate-resistant acid phosphatase (TRAP) or cathepsin K (Ctsk) promoters. TRAP-Cre and Ctsk-Cre transgenic mouse lines were characterized by breeding with LacZ ROSA 26 (R26R) reporter mice and immunohistochemistry for Cre recombinase. The Cre transgene was functional in all lines, with Cre-mediated recombination occurring primarily in the long bones, vertebrae, ribs, and calvaria. Histological analyses of the bones demonstrated that functional Cre protein was present in 1) osteoclasts (Ctsk-Cre); 2) osteoclasts, columnar proliferating, and hypertrophic chondrocytes (TRAP-Cre line 4); and 3) round proliferating chondrocytes (TRAP-Cre line 3). In conclusion, we generated transgenic mouse lines that will enable the deletion of floxed target genes in osteoclasts, which will be valuable tools for studying the regulation of osteoclast function.     

骨形成蛋白4条件性RNA干扰小鼠的建立

为研究骨形成蛋白4(Bone morphogenetic protein 4, BMP4)在骨骼发育中的作用, 我们以含有LoxPneo的pBSK/U6载体为骨架, 构建小鼠BMP4条件性RNAi(conditional RNA interference), CRNA; 载体(BMP4CRNAi), 经KpnⅠ和AflⅢ双酶切获取针对bmp4并含neo基因的目的干扰片段, 纯化后的目的片段显微注射入0.5 d的FVB/NJ小鼠受精卵, 并植入同期发情的假孕母鼠中, 获取G0代转基因小鼠; 利用PCR对G0代转基因小鼠基因型进行鉴定, PCR阳性的小鼠与FVB/NJ小鼠交配, 最终获取稳定传代的BMP4CRNAi小鼠。稳定传代的BMP4^CRNAi小鼠与成骨和软骨前体细胞表达Cre的转基因小鼠(Col2a1-Cre)交配, 获取BMP4^Col2a1-CRNAi小鼠。分离BMP4Col2a1-CRNAi小鼠原代软骨细胞, 提取总RNA, 利用半定量RT-PCR检测RNA干扰效率。小鼠基因型鉴定结果表明：成功获得条件性RNAi转基因小鼠; BMP4干扰效率检测结果表明：在软骨细胞中BMP4的干扰效率为81％。以上结果表明, 我们成功制备了BMP4^CRNAi小鼠和BMP4^Col2a1-CRNAi小鼠, BMP4^CRNAi小鼠与不同Cre转基因小鼠交配, 可以研究BMP4在不同细胞、组织和器官的功能, BMP4^Col2a1-CRNAi小鼠的获得为研究BMP4在软骨发育中的作用提供了合适的动物模型。     

Rearrangement of a conditional allele regardless of inheritance of a Cre recombinase transgene

To generate conditional gene knockouts in osteoblasts, we previously developed transgenic mice in which Cre recombinase cDNA was cloned downstream of a 3.6 or 2.3 kb fragment of the rat Col1a1 promoter (Col3.6-Cre and Col2.3-Cre, respectively). Col-Cre mice were bred with mice in which exon 4 of the Igf1 gene is flanked by loxP sites. Mating units were arranged such that either the male or the female breeder transmitted the Col-Cre transgenes. Progeny were evaluated for Cre-mediated Igf1 gene rearrangement. We found that the loxP-flanked Igf1 locus was rearranged in the absence of inheritance of the Cre transgene. The incidence was 50 and 28% with Col2.3-Cre and Col3.6-Cre females, respectively, and 15 and 18% with Col2.3-Cre and Col3.6-Cre males, respectively.