内含子中正筛选标记neo基因在转录中的剪切研究

目的:研究插入内含子中的正筛选标记基因neo在转录中的剪切情况。方法:克隆了猪血清白蛋白基因5'端调控序列,以猪基因组DNA为模板,P10/P11为引物,PCR扩增猪血清白蛋白基因翻译终止密码子后2.9kb的3'端调控序列;以pEGFP-1为模板,P400/P401为引物PCR扩增绿色荧光蛋白(EGFP)基因,插入猪血清白蛋白基因5'端调控区之后,在3'端调控序列的内含子中靠近N端的序列中插入正筛选标记基因neo,构建了表达EGFP的真核表达载体pEXp11。转染人肝癌细胞系HepG2,通过G418药物筛选获得稳定转染的抗药性细胞克隆。提取抗性细胞克隆基因组RNA并进行反转录,获得cDNA序列。结果:用引物D400/D401及分别位于neo基因和3'端调控序列上的一对引物D394/D357进行PCR检测,其中D394/D357并未扩增出目的条带。结论:插入内含子中的neo基因在转录过程中可随内含子一起被剪切。     

Myostatin基因打靶载体的构建及猪胎儿成纤维细胞Myostatin基因的敲除

目的:用缺口修复等技术构建Myostatin(肌肉生长抑制素,MSTN)基因打靶载体,并对大白猪胎儿成纤维体细胞进行转染,获得基因敲除细胞。方法与结果:首先构建用于MSTN基因同源长臂(LA)的抓捕载体,然后在大肠杆菌内利用Red同源重组系统介导的缺口修复,从含大白猪MSTN基因座的细菌人工染色体上亚克隆9.9 kb的LA到抓捕载体上,经过部分序列测定,同源性为100%;通过PCR获得1.4 kb的同源短臂(SA);将LA和SA连入载体pLOXP,构建含有neo和tk正负筛选标记基因的MSTN基因打靶载体pLOXP-MSTN-KO;将线性化的pLOXP-MSTN-KO通过电转染整合到大白猪胎儿成纤维细胞基因组中,利用G418和丙氧鸟苷进行药物筛选,获得抗性细胞克隆890个,通过PCR和DNA测序鉴定获得基因敲除的细胞克隆4个。结论:构建了有效的MSTN基因打靶载体,通过转染获得基因敲除细胞,为利用体细胞核移植制备MSTN基因敲除猪奠定了基础。     

构建LEF1基因毛囊特异表达载体并稳定转染胎儿成纤维细胞

旨在构建内蒙古白绒山羊(Capra hircus)淋巴样增强因子-1(Lymphoid enhancer factor,LEF1)基因真核表达载体并转染胎儿成纤维细胞,获得稳定表达红色荧光蛋白及毛囊特异性表达LEF1的转基因细胞克隆。以pCDsRed2载体为基本骨架将LEF1基因亚克隆到KAP6-1启动子下游,连接红色荧光蛋白表达元件,构建LEF1基因毛囊特异表达载体pCDsRed-KL。外源表达载体以lipofectamineTM2000介导转染胎儿成纤维细胞,通过G418筛选获得稳定转染的细胞克隆。PCR鉴定外源基因在细胞基因组中的整合。测序显示构建的表达载体pCDsRed-KL序列中,LEF1基因正确连接在KAP6-1启动子下游,顺序连接CMV启动子和红色荧光蛋白基因,载体构建正确。脂质体介导的稳定转染效率约为14.0%,经G418筛选得到高效表达红色荧光蛋白转基因细胞克隆。PCR检测显示外源KAP6-1启动子和LEF1基因整合到胎儿成纤维细胞基因组中。     

猪α-1,3-半乳糖转移酶基因打靶载体的构建

目的:构建猪α-1,3-半乳糖转移酶(GGTA1)基因的正负筛选打靶载体。方法:以原代猪胚胎成纤维细胞基因组DNA为模板,采用长程PCR方法扩增出GGTA1基因的2条片段;以长约2kb包含部分第9外显子的片段为同源短臂,在XbaⅠ和ClaⅠ位点插入pLoxP质粒正筛选标记neo基因的3'端;以长约5.4kb包括部分第8外显子、全部第8内含子及部分第9外显子的片段为同源长臂,于NotⅠ位点插入该质粒中neo基因的5'端;2.7kb的负筛选标记tk基因位于载体中同源短臂的3'端外侧。结果与结论:酶切、PCR及测序结果表明,同源臂被正确连接至质粒pLoxP,成功构建了猪GGTA1基因正负筛选打靶载体pSL/GT。     

表达红色荧光及转胸腺素β4基因绵羊胎儿成纤维细胞系的制备

旨在构建胸腺素β4(thymosin beta4,Tβ4)基因真核表达载体并转染绵羊胎儿成纤维细胞,获得稳定表达胸腺素β4及红色荧光蛋白的转基因细胞克隆。将克隆载体pMD19TT中的胸腺素β4基因亚克隆到表达载体pIRES2-DsRed2的多克隆位点,构建表达载体pIRES2-DsRed2-Tβ4,脂质体介导转染绵羊胎儿成纤维细胞,G418筛选获得稳定转染的细胞克隆。RT-PCR检测Tβ4基因在宿主细胞中的转录。测序结果显示,构建的表达载体pIRES2-DsRed2-Tβ4序列中,Tβ4基因正确连接在CMV启动子下游,顺序连接IRES2序列和红色荧光蛋白基因,载体构建正确。脂质体介导的稳定转染效率约为15%,经G418筛选得到转基因细胞克隆并高效表达红色荧光蛋白。RT-PCR检测显示外源Tβ4基因在绵羊胎儿成纤维细胞中得到转录。成功构建具有红色荧光蛋白和新霉素抗性双选择标记的胸腺素β4基因真核表达载体并稳定转染绵羊胎儿成纤维细胞,筛选得到的超表达胸腺素β4绵羊胎儿成纤维细胞系为下一步通过核移植和克隆技术获得转基因绵羊提供了条件。     

构建骨骼肌特异表达人FS基因载体及其稳定转染绵羊胎儿成纤维细胞

旨在构建骨骼肌特异表达人卵泡抑制素( follistatin,Fs)基因载体并得到其稳定转染的蒙古绵羊胎儿成纤维细胞系,为后期通过体细胞核移植方法制作转FS基因克隆绵羊奠定基础.首先通过RT-PCR方法克隆得到人FS基因cDNA序列,然后与猪骨骼肌特异表达启动子α-actin以及红色荧光蛋白表达元件连接,构建成FS基因骨骼肌特异表达载体pCFCDS.脂质体介导外源表达载体转染绵羊胎儿成纤维细胞,经G418筛选后得到稳定转染的绵羊转基因细胞克隆.PCR鉴定外源基因在细胞基因组中的整合,分析转基因细胞系的核型和生长状况.结果显示,成功构建得到绵羊骨骼肌特异表达人FS基因的真核表达载体,并得到其稳定转染的转基因绵羊胎儿成纤维细胞系,为后期通过体细胞核移植方法制作转FS基因克隆绵羊奠定基础.     

ht-Pam基因在山羊β-酪蛋白基因座定位整合的研究

利用体细胞基因打靶与核移植技术制备动物乳腺生物反应器是当今转基因定位整合表达的一种新技术。分别克隆山羊的β-酪蛋白基因5′调控区的6.3kb片段,外显子7、外显子8和9三个基因片段,并与克隆的人tPA突变体cDNA一起构建了含有neo和tk正负筛选标记基因的β-酪蛋白基因打靶载体P^GBC4tPA,并验证了neo基因、tk基因以及Cre-LoxP系统的有效性。将线性化的P^GBC4tPA通过电转染整合到山羊胎儿成纤维细胞基因组中,利用G418和GANC进行抗性细胞克隆的药物筛选,初步获得抗性细胞克隆244个,PCR检测后获得阳性细胞克隆31个,其中初步验证2个细胞克隆转植基因整合位点重组后的基因序列正确,并且该细胞克隆能够有效扩增。这为下一步基因打靶体细胞核移植制备山羊乳腺生物反应器奠定了基础。     

CHO/dhfr-细胞定点整合高效表达系统的建立

为了克服随机整合建立高表达细胞株时“位置效应”所带来的不可预知的后果,我们尝试建立基于定点整合的CHO高效表达系统。首先设计一个新的高效筛选载体pMCEscan。该载体含有报告基因(k2tPA)、扩增基因(dhfr)、重组酶识别序列(FRT)及筛选基因(neo),且neo基因的表达经过系统的弱化,确保能够对基因组中的整合位点进行大规模的高效筛选。然后利用该载体转染CHO/dhfr-细胞并进行大规模筛选以获得足够多的阳性克隆,并对阳性克隆进行系统分析,筛选出报告基因表达水平高、单拷贝且扩增效果好的克隆,此克隆被认为筛选载体整合入CHO细胞基因组中转录热点(Hotspot)区域,从而获得了能够实现外源基因在基因组中定点整合和有效表达的CHO/dhfr-细胞系。随后利用位点特异性重组系统(FLP-FRT)将外源基因定点整合到Hotspot区域,以实现外源基因在CHO细胞基因组中的定点整合及高效表达。并利用该细胞系实现了k2tPA的高表达,表达量达到17.1μg/106cell.24h。该研究致力于CHO细胞基因组中高表达位点的寻找和确认,建立基于定点整合的哺乳动物细胞高效表达系统。     

人t-PA突变体cDNA打靶敲入小鼠ES细胞β-酪蛋白位点的研究

应用克隆的基因组序列作为同源臂 ,构建了小鼠 β 酪蛋白基因定位敲入打靶载体。短臂长 2 7kb ,包括小鼠 β 酪蛋白基因 5′端侧翼区、第 1外显子、第 1内含子、部分第 2外显子。长臂包括小鼠 β 酪蛋白基因部分第 2内含子、第 3～ 7外显子、第 3～ 6内含子、部分第 7内含子 ,长 3 4kb。人t PA突变体cDNA在第 2外显子中与小鼠 β 酪蛋白信号肽序列融合。正筛选标记neo放置在 β 酪蛋白基因第 2内含子中部 ,负筛选标记tk位于短臂外侧。ES细胞株TC 1在滋养层上培养扩增。处理ES细胞使其密度达到 2× 10 7个 /mL后 ,将 4 5 μg线性化的打靶载体DNA与 1mL细胞混匀后电击。转染的细胞在含G4 18和Gancyclovir的选择培养基中培养 ,7d后挑取 192个抗性克隆 ,扩增、提取基因组DNA ,EcoRⅠ酶切后 ,用打靶载体 5′端内侧探针进行Southern杂交 ,野生型出现 9 8kb ,而中靶的 β 酪蛋白基因由于敲入的人t PA突变体携带一个EcoRⅠ位点 ,中靶等位基因出现 6 6kb。从 78株ES细胞株中获得 1株发生正确同源重组的中靶ES细胞。     

CHO/dhfr-细胞定点整合高效表达系统的建立

为了克服随机整合建立高表达细胞株时“位置效应”所带来的不可预知的后果,我们尝试建立基于定点整合的CHO高效表达系统。首先设计一个新的高效筛选载体pMCEscan。该载体含有报告基因（k2tPA）、扩增基因（dhfr）、重组酶识别序列（FRT）及筛选基因（neo）,且neo基因的表达经过系统的弱化,确保能够对基因组中的整合位点进行大规模的高效筛选。然后利用该载体转染CHO／dhfr^-细胞并进行大规模筛选以获得足够多的阳性克隆,并对阳性克隆进行系统分析,筛选出报告基因表达水平高、单拷贝且扩增效果好的克隆,此克隆被认为筛选载体整合入CHO细胞基因组中转录热点（Hotspot）区域,从而获得了能够实现外源基因在基因组中定点整合和有效表达的CHO／dhfr-细胞系。随后利用位点特异性重组系统（FLP-FRT）将外源基因定点整合到Hotspot区域,以实现外源基因在CHO细胞基因组中的定点整合及高效表达。并利用该细胞系实现了k2tPA的高表达,表达量达到17．1μg／10^6cell·24h。该研究致力于CHO细胞基因组中高表达位点的寻找和确认,建立基于定点整合的哺乳动物细胞高效表达系统。     

Expression of human serum albumin in the milk of transgenic mice

We have tested the feasibility of producing large quantities of human serum albumin (HSA) in the milk of transgenic livestock by generating transgenic mice as a model system. The sheep β-lactoglobulin (BLG) 5′-regulatory promoter sequences were used to support expression of BLG or HSA in transgenic mice. Transgenic animals generated from the entire BLG gene including 3, 5.5 or 10.8 kb of 5′-sequences demonstrated that 3 kb of 5′-sequences were sufficient to support high levels of expression of BLG, and that the longer 5′-sequences did not improve upon the levels of expression. As such, the 3 kb 5′-sequences were used to drive expression of HSA in BLG-HSA constructs. HSA was not detectably expressed in eight transgenic lines generated from a BLG-HSA construct containing the HSA cDNA. Two transgenic lines of 26 generated, using five different constructs, with an HSA minigene possessing the first intron expressed HSA in their milk. One of these expressed HSA at high levels (2.5 mg ml⁻¹) and has stably transmitted this ability to its progeny. A high percentage of transgenic mouse lines (four of six) generated from a vector containing an HSA minigene possessing introns 1 and 2 expressed HSA in their milk at levels which ranged from 1 to 35 μg ml⁻¹. In a similar trend, levels of expression of HSA by transfected tissue culture cells from BLG-HSA vectors containing an introduced SV40 enhancer were low with the HSA cDNA, increased with the HSA minigene with intron 1 and increased further with the minigene containing introns 1 and 2. This study demonstrates that high levels of HSA can be expressed in the milk of transgenic animals, that introns of the HSA gene play a role in its expression and that transfected cell lines may be used to quickly evaluate the relative expression efficiencies of various vector constructs intended for future transgenic evaluation.     

A potato Sus3 sucrose synthase gene contains a context-dependent 3' element and a leader intron with both positive and negative tissue-specific effects.

To examine which sequences are involved in regulating the potato sucrose synthase gene Sus3-65, we examined a series of deletion and substitution constructs in transgenic potato and tobacco plants. In a construct containing 3.9 kb of 5' flanking region, substitution of the native 3' sequence with the nopaline synthase 3' sequence and deletion of the leader intron did not significantly affect expression in vegetative tissues. However, in a construct containing only 320 bp of 5' flanking region, these changes had marked effects. Replacing the native 3' sequences with nopaline synthase 3' sequences caused a six- to 20-fold increase in expression in vascular tissue, and removing the leader intron almost completely abolished expression in potato plants. Surprisingly, removal of the leader intron from either the full-length construct or a construct containing only 320 bp of 5' flanking sequence reduced expression in vascular tissue of tobacco anthers at later stages of development but increased expression in pollen by more than 100-fold.     

The structure and expression of maize genes encoding the major heat shock protein, hsp70

We have isolated and sequenced two maize genomic clones that are homologous to the Drosophila hsp70 gene. One of the maize hsp70 clones contains the entire hsp70 coding region and 81 nucleotides of the 5' nontranslated sequence. The predicted amino acid sequence for this maize protein is 68% homologous to the hsp70 of Drosophila. The second maize hsp70 clone contains only part of the coding sequence and 1.1 kb of the 5' flanking sequence. This 5' flanking sequence contains two sequences homologous to the consensus heat-shock-element sequence. Both maize genes are thermally inducible and each contains an intron in the same position as that of the heat-shock-cognate gene, hsc1, of Drosophila. The presence of an intron in the maize genes is a distinguishing feature in that no other thermally inducible hsp70 genes described to date contain an intron. We have constructed a hybrid hsp70 gene containing the entire hsp70 coding sequence with an intron, and 1.1 kb of the 5' flanking sequence. We demonstrate that this hybrid gene is thermally inducible in a transgenic petunia plant and that the gene is expressed from its own promoter.     

Gene replacement in Dictyostelium: generation of myosin null mutants.

The eukaryotic slime mold Dictyostelium discoideum has a single conventional myosin heavy chain gene (mhcA). The elimination of the mhcA gene was achieved by homologous recombination. Two gene replacement plasmids were constructed, each carrying the G418 resistance gene as a selective marker and flanked by either 0.7 kb of 5' coding sequence and 0.9 kb of 3' coding sequence or 1.5 kb of 5' flanking sequence and 1.1 kb of 3' flanking sequence. Myosin null mutants (mhcA- cells) were obtained after transformation with either of these plasmids. The mhcA- cells are genetically stable and are capable of a variety of motile processes. Our results provide genetic proof that in Dictyostelium the conventional myosin gene is required for growth in suspension, normal cell division and sporogenesis, and illustrate how gene targeting can be used as a tool in Dictyostelium.     

Elements within the beta-lactoglobulin gene inhibit expression of human serum albumin cDNA and minigenes in transfected cells but rescue their expression in the mammary gland of transgenic mice.

Two new beta-lactoglobulin (BLG)/human serum albumin (HSA) hybrid gene vectors were constructed and tested for expression in COS-7 cells and in transgenic mice. The HSA sequences were inserted between the second and sixth BLG exons. Transient transfection experiments with these vectors as well as a series of additional vectors with either the BLG 5'- or 3'- intragenic sequences revealed that sequences within BLG exon 1/intron 1/exon 2 abrogated BLG- directed HSA expression in vitro, regardless of the presence of HSA introns or the origin of the 3' polyadenylation signal. In contrast, the same BLG expression cassette enabled the efficient expression of HSA cDNA or minigene in the mammary gland of transgenic mice with subsequent secretion of the corresponding protein into the milk of 56 and 82%, respectively of the mouse strains at levels up to 0.3 mg/ml. Previous attempts to express HSA cDNA inserted into exon 1 of the BLG gene had failed [Shani,M., Barash,I., Nathan,M., Ricca,G., Searfoss,G.H., Dekel,I., Faerman,A., Givol,D. and Hurwitz,D.R. (1992) Transgenic Res. 1, 195- 208]. The new BLG expression cassette conferred more stringent tissue specific expression than previously described BLG/HSA constructs [Barash,I, Faerman,A., Ratovitsky,T, Puzis,R., Nathan,M., Hurwitz,D.R. and Shani, M. (1994) Transgenic Res. 3, 141-151]. However, it was not able to insulate the transgenes from the surrounding host DNA sequences and did not result in copy number dependent expression in transgenics. Together, the in vitro and in vivo results suggest both positive and negative regulatory elements within the BLG intragenic sequences evaluated. The new BLG construct represents an extremely valuable vector for the efficient expression of cDNAs in the mammary gland of transgenic animals.