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。     

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。     

肥大软骨细胞特异性表达Cre重组酶转基因小鼠的建立

肥大软骨细胞是软骨细胞的终末分化形式,在软骨内成骨过程中发挥十分关键的作用。为了研究肥大软骨细胞在骨骼发育过程中的功能,我们构建了在8.2 kb小鼠X型胶原基因（Col10a1）启动子控制下表达Cre重组酶的转基因小鼠品系（Col10a1-8.2-Cre）。采用显微注射法将11.5 kb的转基因片段引入小鼠基因组,共注射受精卵328枚,获得子代鼠51只,经PCR基因型鉴定有3只在基因组上整合有Cre重组酶基因。PCR检测发现Col10a1-8.2-Cre转基因在含有肥大软骨细胞的组织中表达。为了检测Cre重组酶表达的强度和组织特异性,转基因小鼠与ROSA26报告小鼠交配。子代ROSA26;Col10a1-8.2-Cre双转基因小鼠LacZ染色检测的结果显示,Cre重组酶在所有的肥大软骨细胞中表达。原位杂交的结果验证Col10a1-8.2-Cre转基因表达在肥大区的上端。以上结果表明,我们建立的肥大软骨细胞特异性表达Cre重组酶的转基因小鼠品系可以作为一种遗传学工具,介导目的基因在肥大软骨细胞中的敲除。     

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。     

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。     

平滑肌细胞特异表达Cre重组酶转基因小鼠Cre重组酶的表达分布

利用转基因技术构建了平滑肌细胞特异表达Cre重组酶的转基因小鼠（SMA-Cre）,将该小鼠与基因组上携带LoxP位点的ROSA26小鼠杂交,通过LacZ染色检测Cre重组酶介导重组的功能以及表达的组织特异性。结果显示,在气管C形软骨连接处平滑肌、细支气管壁平滑肌、食道壁平滑肌、胃壁平滑肌、小肠壁平滑肌、子宫壁平滑肌、膀胱壁平滑肌、血管壁平滑肌、心肌及骨骼肌中检测到Cre重组酶活性。表明SMA—Cre转基因小鼠在所有平滑肌细胞中表达Cre重组酶,并且有很好的组织特异性。     

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。     

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。     

干扰素诱导Mx—Cre转基因小鼠表达的重组酶活性的体外检测

利用PCR、Western blot、免疫组化、免疫金标电镜、Southern blot从DNA水平,蛋白水平分析干扰素诱导后Mx-Cre转基因小鼠肝组织中Cre重组酶的表达及其表达产物的活性,在对Mx-Cre转基因小鼠基因组中整合有cre基因进行确定后,通过干扰素诱导Mx-Cre转基因小鼠表达Cre重组酶,结果表明转基因小鼠肝细胞核和细胞质中均有Cre重组酶的表达,并在超微水平进一步证实,将含表达的Cre重组酶的肝细胞核抽提液加入到带有loxP位点的DNA中进行重组,分析证明Mx-Cre转基因小鼠表达的Cre重组酶具有重组活性,从而建立了体外检测Mx-Cre转基因re重组酶活性的方法。     

软骨组织特异性表达Cre重组酶转基因小鼠的研制和鉴定

构建了含有软骨组织特异性Ⅱ型胶原A1启动子和Cre重组酶基因的转基因载体pcol2Al-Cre。323枚小鼠受精卵经显微注射引入转基因片段后,分别移植至14只假孕母鼠的输卵管使其发育。共得到仔鼠52只,PCR结果显示其中10只小鼠基因组上有Cre基因的整合,整合率为19．2％。用整合有Cre基因的转基因小鼠与基因组上携带LoxP位点的条件基因打靶小鼠交配,以检测Cre酶介导的重组及其组织特异性。PCR结果表明：col2Al-Cre转基因小鼠软骨组织中表达的Cre重组酶成功地介导了LoxP之间的重组。此结果通过Southern杂交得到了进一步的证实。     

Tie2-Cre transgenic mice: a new model for endothelial cell-lineage analysis in vivo

Endocardial cells are thought to contribute at least in part to the formation of the endocardial cushion mesenchyme. Here, we created Tie2-Cre transgenic mice, in which expression of Cre recombinase is driven by an endothelial-specific promoter/enhancer. To analyze the lineage of Cre expressing cells, we used CAG-CAT-Z transgenic mice, in which expression of lacZ is activated only after Cre-mediated recombination. We detected pan-endothelial expression of the Cre transgene in Tie2-Cre;CAG-CAT-Z double-transgenic mice. This expression pattern is almost identical to Tie2-lacZ transgenic mice. However, interestingly, we observed strong and uniform lacZ expression in mesenchymal cells of the atrioventricular canal of Tie2-Cre;CAG-CAT-Z double-transgenic mice. We also detected lacZ expression in the mesenchymal cells in part of the proximal cardiac outflow tract, but not in the mesenchymal cells of the distal outflow tract and branchial arch arteries. LacZ staining in Tie2-Cre;CAG-CAT-Z embryos is consistent with endocardial-mesenchymal transformation in the atrioventricular canal and outflow tract regions. Our observations are consistent with previously reported results from Cx43-lacZ, Wnt1-Cre;R26R, and Pax3-Cre;R26R transgenic mice, in which lacZ expression in the cardiac outflow tract identified contributions in part from the cardiac neural crest. Tie2-Cre transgenic mice are a new genetic tool for the analyses of endothelial cell-lineage and endothelial cell-specific gene targeting.     

Neural expression of alpha-internexin promoter in vitro and in vivo

alpha-Internexin is a 66 kDa neuronal intermediate filament protein found most abundantly in the neurons of the nervous systems during early development. To characterize the function of mouse alpha-internexin promoter, we designed two different expression constructs driven by 0.7 kb or 1.3 kb of mouse alpha-internexin 5'-flanking sequences; one was the enhanced green fluorescent protein (EGFP) reporter for monitoring specific expression in vitro, and the other was the cre for studying the functional DNA recombinase in transgenic mice. After introducing DNA constructs into non-neuronal 3T3 fibroblasts and a neuronal Neuro2A cell line by lipofectamine transfection, we observed that the expression of EGFP with 1.3 kb mouse alpha-internexin promoter was in a neuron-dominant manner. To establish a tissue-specific pattern in the nervous system, we generated a transgenic mouse line expressing Cre DNA recombinase under the control of 1.3 kb alpha-Internexin promoter. The activity of the Cre recombinase at postnatal day 1 was examined by mating the cre transgenic mice to ROSA26 reporter (R26R) mice with knock-in Cre-mediated recombination. Analyses of postnatal day 1 (P1) newborns showed that beta-galactosidase activity was detected in the peripheral nervous system (PNS), such as cranial nerves innervating the tongue and the skin as well as spinal nerves to the body trunk. Furthermore, X-gal-labeled dorsal root ganglionic (DRG) neurons showed positive for alpha-Internexin in cell bodies but negative in their spinal nerves. The motor neurons in the spinal cord did not exhibit any beta-galactosidase activity. Therefore, the cre transgene driven by mouse alpha-internexin promoter, described here, provides a useful animal model to specifically manipulate genes in the developing nervous system.     

Cre-conditional expression of constitutively active Notch1 in transgenic mice

The Notch signaling pathway plays a critical role during mammalian development. To bypass embryonic lethality associated with constitutive Notch1 signaling, we created transgenic mice with a floxed beta-geo/stop signal between a cytomegalo virus promoter and the constitutively active intracellular domain of Notch1 (IC-Notch1). IC-Notch1 is activated upon introduction of Cre recombinase and it is coexpressed with an enhanced green fluorescent protein or human placental alkaline phosphatase reporter. We created three IC-Notch1 transgenic mouse lines and crossed them to a general Cre deletor mouse line, pCX-Cre. The double transgenic IC-Notch1/pCX-Cre embryos have widespread expression of IC-Notch1 and reporters and die before 10.5 days of gestation. Morphological and histological analysis of the double transgenic embryos indicated growth arrest and various developmental defects, including lack of neural tube closure, disorganized somites, and disrupted vasculature. The conditional IC-Notch1 expressing transgenic mice provide a unique tool to investigate the Notch pathway using tissue-specific Cre mice and inducible Cre systems.     

Generation of a transgenic mouse model with chondrocyte-specific and tamoxifen-inducible expression of Cre recombinase

Postnatal cartilage development and growth are regulated by key growth factors and signaling molecules. To fully understand the function of these regulators, an inducible and chondrocyte-specific gene deletion system needs to be established to circumvent the perinatal lethality. In this report, we have generated a transgenic mouse model (Col2a1-CreER(T2)) in which expression of the Cre recombinase is driven by the chondrocyte-specific col2a1 promoter in a tamoxifen-inducible manner. To determine the specificity and efficiency of the Cre recombination, we have bred Col2a1-CreER(T2) mice with Rosa26R reporter mice. The X-Gal staining showed that the Cre recombination is specifically achieved in cartilage tissues with tamoxifen-induction. In vitro experiments of chondrocyte cell culture also demonstrate the 4-hydroxy tamoxifen-induced Cre recombination. These results demonstrate that Col2a1-CreER(T2) transgenic mice can be used as a valuable tool for an inducible and chondrocyte-specific gene deletion approach.     

他莫昔芬诱导的Cre重组酶在hGfapCreERT2转基因鼠小脑中的表达研究

目的探讨他莫昔芬诱导的hGfapCreERT2转基因鼠小脑中表达Cre重组酶的细胞类型。方法 hGfapCre-ERT2/Rosa26R转基因小鼠在胚胎晚期和出生早期用他莫昔芬诱导Cre重组酶表达,对小脑组织切片行X-gal染色,然后用细胞种类特异性抗体进行免疫组织化学染色,并和X-gal染色双重标记。结果在出生后第7天(P7)、第14天(P14)和第60天(P60),X-gal阳性染色和胶质细胞抗体Blbp阳性染色共标记,和神经元抗体Neun、浦肯野细胞抗体Calbindin及少突胶质细胞前体细胞抗体NG2不共标。结论自胚胎晚期第17.5天(E17.5)后用他莫昔芬诱导hGfapCreERT2转基因鼠,发现Cre重组酶特异性在小脑星形胶质细胞中表达,不在神经元、浦肯野细胞、少突胶质细胞前体细胞中表达。     

精子特异性 Sleeping Beauty 转座酶转基因小鼠模型的建立

目的：建立精子特异性表达Sleeping Beauty （ SB）转座酶转基因小鼠模型,为研究SB转座子在小鼠中的应用提供工具。方法克隆精子特异性启动子用以驱动SB转座酶基因的表达,建立精子特异性表达SB转座酶的载体,利用显微注射方法建立以C57BL/6J为背景的精子特异性表达SB转座酶的转基因小鼠。 PCR鉴定首建鼠的基因型,western blot（WB）和免疫组织化学（IHC）检测SB转座酶基因在小鼠生殖腺睾丸中的表达情况,筛选睾丸中高表达SB转座酶的转基因小鼠。结果显微注射方式获得了5只首建小鼠,其中3只能稳定传代,利用WB和IHC成功的筛选出一株在精子中高表达SB转座酶的转基因小鼠。结论成功建立了精子特异性高表达SB转座酶转基因小鼠模型,为将SB转座子作为一种基因工程工具应用于小鼠基因修饰模型的建立提供非常重要的工具资源。     

Characterization of a novel transgenic mouse line expressing Cre recombinase under the control of the Cdx2 neural specific enhancer

Several genetically modified mouse models have been generated in order to drive expression of the Cre recombinase in the neuroectoderm. However, none of them specifically targets the posterior neural plate during neurulation. To fill this gap, we have generated a new transgenic mouse line in which Cre expression is controlled by a neural specific enhancer (NSE) from the Caudal‐related homeobox 2 (Cdx2) locus. Analyses of Cre activity via breeding with R26R‐YFP reporter mice have indicated that the Cdx2NSE‐Cre mouse line allows for recombination of LoxP sites in most cells of the posterior neural plate as soon as from the head fold stage. Detailed examination of double‐transgenic embryos has revealed that this novel Cre‐driver line allows targeting the entire posterior neural tube with an anterior limit in the caudal hindbrain. Of note, the Cdx2NSE regulatory sequences direct Cre expression along the whole dorso‐ventral axis (including pre‐migratory neural crest cells) and, accordingly, YFP fluorescence has been also observed in multiple non‐cranial neural crest derivatives of double‐transgenic embryos. Therefore, we believe that the Cdx2NSE‐Cre mouse line represents an important novel genetic tool for the study of early events occurring in the caudal neuroectoderm during the formation of both the central and the peripheral nervous systems. genesis 51:777–784. © 2013 Wiley Periodicals, Inc.     

乙型肝炎病毒蛋白和绿色荧光蛋白的共表达研究

目的：构建增强型绿色荧光蛋白（EGFP）标记的乙型肝炎病毒（HBV）真核表达载体,并研究其在真核细胞和小鼠体内的共表达。方法：以质粒pBR322-HBVadr2．0和pCX-EGFP为基础,构建含有双拷贝HBV全基因组DNA和EGFP基因的真核表达载体pCX-EGFP-HBVadr2．0,分别转染真核细胞和小鼠肝组织,建立体外、体内表达系统,研究GFP和HBV基因的表达。结果：构建了真核表达载体pCX-EGFP-HBVadr2．0,EGFP和HBV病毒蛋白在体内和体外均可表达。结论：构建的pCX-EGFP-HBVadr2．0真核表达载体可以GFP作为HBV存在与否的报告基因,提高了培育检测转基因小鼠的效率,为转基因小鼠的制备及后续研究奠定了基础。     

Foxl1-Cre BAC transgenic mice: a new tool for gene ablation in the gastrointestinal mesenchyme

The use of Cre-loxP technology for the purpose of cell type-specific gene ablation has revolutionized developmental biology and biomedicine. Several transgenic mouse lines have been developed for the analysis of gene function in the gastrointestinal tract, but in all of these the expression of Cre is limited to the epithelial cell layer. No Cre- expressing transgenic mouse lines ("Cre lines") exist for the deletion of loxP-flanked genes specifically in gut mesoderm. To address this deficiency, we have derived a bacterial artificial chromosome based transgenic mouse line in which the Cre gene is controlled by the Foxl1 promoter and enhancer elements. X-Gal staining of Foxl1-Cre; Rosa26R bi-transgenic lines confirm that Foxl1-Cre results in recombination specifically in the gastrointestinal mesenchyme. The Foxl1-Cre line will facilitate the dissection of mesenchymal to epithelial signaling that is known to play a major role in the patterning and function of the gastrointestinal tract.