共查询到16条相似文献,搜索用时 921 毫秒
1.
为了构建荷包猪SLA-3-HB01基因四聚体前体链原核表达载体,并获得SLA-3-HB01表达蛋白,试验以SLA-3-HB01/pMD18-T为模板进行PCR扩增四聚体前体链SLA-3-HB01-BSP,并克隆至pMD19-T载体中,经NdeⅠ和XhoⅠ双酶切筛选阳性克隆并测序,目的基因连接至表达载体pET-21a(+),转化大肠杆菌BL21(DE3)感受态细胞,经IPTG诱导表达,SDS-PAGE检测目的蛋白大小及表达情况,提取包涵体并进行检测。结果显示,PCR成功扩增得到SLA-3-HB01-BSP,大小为896 bp左右。酶切鉴定证实,目的基因成功克隆至pMD19-T载体中,插入片段大小为876 bp,阳性克隆经测序后所获序列与原序列一致,并在3'端带有BSP标签序列。酶切鉴定进一步证实成功构建SLA-3-HB01-BSP/pET-21a(+)重组表达载体,经转化及诱导表达,SDS-PAGE检测显示目的蛋白分子质量在33.5 ku左右。包涵体蛋白分子质量约33.5 ku,与菌体中目的蛋白大小一致,经凝胶成像系统UVP扫描分析,包涵体蛋白纯度接近于90%,符合进行相关结构和功能研究的要求。本研究成功构建了荷包猪SLA-3-HB01基因四聚体前体链的pET-21a(+)重组表达系统,并获得了一定纯度的包涵体蛋白。 相似文献
2.
为了构建荷包猪SLA-3-HB01基因四聚体前体链原核表达载体,并获得SLA-3-HB01表达蛋白,试验以SLA-3-HB01/pMD18-T为模板进行PCR扩增四聚体前体链SLA-3-HB01-BSP,并克隆至pMD19-T载体中,经NdeⅠ和XhoⅠ双酶切筛选阳性克隆并测序,目的基因连接至表达载体pET-21a(+),转化大肠杆菌BL21(DE3)感受态细胞,经IPTG诱导表达,SDS-PAGE检测目的蛋白大小及表达情况,提取包涵体并进行检测。结果显示,PCR成功扩增得到SLA-3-HB01-BSP,大小为896bp左右。酶切鉴定证实,目的基因成功克隆至pMD19-T载体中,插入片段大小为876bp,阳性克隆经测序后所获序列与原序列一致,并在3′端带有BSP标签序列。酶切鉴定进一步证实成功构建SLA-3-HB01-BSP/pET-21a(+)重组表达载体,经转化及诱导表达,SDS-PAGE检测显示目的蛋白分子质量在33.5ku左右。包涵体蛋白分子质量约33.5ku,与菌体中目的蛋白大小一致,经凝胶成像系统UVP扫描分析,包涵体蛋白纯度接近于90%,符合进行相关结构和功能研究的要求。本研究成功构建了荷包猪SLA-3-HB01基因四聚体前体链的pET-21a(+)重组表达系统,并获得了一定纯度的包涵体蛋白。 相似文献
3.
为构建大约克猪SLA-1胞外区的原核表达载体及表达目的蛋白,试验设计1对引物,经PCR扩增获得大约克猪SLA-1胞外区基因(命名为SLA-1-DYKe),将此片段克隆至pMD®19-T Simple Vector,转化大肠杆菌TOP10感受态细胞,经Nde Ⅰ和Xho Ⅰ双酶切筛选阳性克隆菌并测序,将目的基因插入到原核表达载体pET-28a(+)中,转化至宿主菌BL21(DE3)进行诱导表达,用SDS-PAGE检测目的蛋白的表达情况,大量诱导提取包涵体并检测。结果显示,PCR成功扩增SLA-1-DYKe的胞外区,得到大小为837 bp的目的基因,目的基因成功克隆至pMD®19-T Simple Vector,并获得序列正确的重组质粒。以得到的重组质粒成功构建了SLA-1-DYKe/pET-28a(+)表达载体,目的蛋白大小约为34 ku。本研究成功构建了大约克猪SLA-1原核表达载体,获得了表达蛋白,为今后研究大约克猪SLA-1的空间结构和基因功能奠定了基础。 相似文献
4.
为构建烟台黑猪SLA-2-YTH基因原核表达载体,本研究设计引物PCR扩增SLA-2-YTH胞外区,将其克隆至pMD 19-T Simple 载体,筛选阳性克隆。阳性克隆经酶切后,进一步与表达载体pET-28a(+)连接,转化BL21(Rosseta)感受态细胞并进行诱导表达,SDS-PAGE检测蛋白表达情况。结果显示,SLA-2-YTH胞外区亚克隆大小为834 bp,酶切鉴定证实其成功插入pET-28a(+)表达载体。SDS-PAGE结果显示,SLA-2-YTH基因导入宿主菌后成功表达,蛋白大小约31.0 ku,与预期结果相符,优化后蛋白相对表达量达25%以上。本研究成功构建了烟台黑猪SLA-2-YTH原核表达载体,获得了表达蛋白,为今后进一步的结构和功能研究奠定基础。 相似文献
5.
为提高托佩克猪SLA-2-TPK基因胞外区在pET-21a的表达量,对其5′端进行密码子优化,并设计表达引物,PCR扩增SLA-2-TPK胞外区,然后克隆入pMD○R19-T Simple Vector,经酶切鉴定后连接至pET-21a载体,转化BL21(Rosseta)进行诱导表达,SDS-PAGE检测目的蛋白。PCR结果显示,SLA-2-TPKe大小约为850bp,并成功克隆入pMD○R19-T Simple Vector,双酶切后大小为834bp。酶切后的SLA-2-TPKe成功与pET-21a链接,重组菌经诱导后目的蛋白大小为30.9ku,与密码子优化前重组菌相比,目的蛋白相对表达含量提高约40%。研究证明,密码子优化可明显提高蛋白的表达量,为进行其他蛋白表达研究提供了参考。 相似文献
6.
试验旨在构建荷包猪猪白细胞抗原1(swine lymphocyte antigen 1,SLA-1)重链四聚体前体链并研究其在表达载体pET-21a(+)中蛋白的表达情况。以SLA-1全基因序列为模板,结合表达载体的特点设计引物,利用PCR扩增技术在SLA-1-HB01胞外区序列C-末端加载上可生物素酰化序列(BirA substrate peptide,BSP)。将PCR扩增产物SLA-1-HB01-BSP克隆到pEASY T1载体上,筛选出阳性克隆菌SLA-1-HB01-BSP/pEASY T1,经双酶切后进一步与表达载体pET-21a(+)连接,再转化到E.coli BL21感受态细胞中构建pET-21a(+)/SLA-1-HB01-BSP重组表达菌,通过IPTG诱导蛋白表达,SDS-PAGE检测蛋白的大小及表达情况,提取包涵体检测蛋白的纯度。PCR扩增结果显示,SLA-1-HB01-BSP大小为898 bp,与理论值相符,扩增片段成功克隆至pEASY T1载体构建克隆菌,经Nde Ⅰ和Xho Ⅰ双酶切筛选及测序,成功获得阳性克隆菌株SLA-1-HB01-BSP/pEASY T1,插入的目的基因片段大小为876 bp。阳性克隆菌株与pET-21a(+)表达载体经Nde Ⅰ和Xho Ⅰ双酶切后进行连接,转化E coli BL21感受态细胞后获得pET-21a(+)/SLA-1-HB01-BSP重组表达菌,经IPTG诱导表达,SDS-PAGE检测目的蛋白大小为31.4 ku。进一步检测分析发现,目的蛋白以包涵体形式存在,且蛋白纯度达到80%以上。本研究成功构建了荷包猪SLA-1-HB01重链四聚体前体链的pET-21a(+)重组表达体系,为下一步进行猪SLA Ⅰ类分子四聚体的检测奠定基础。 相似文献
7.
《中国兽医学报》2016,(7):1178-1182
用real-time PCR方法扩增家兔PepTⅠmRNA序列,通过原核表达体外获得家兔PepTⅠ蛋白,旨在制备多克隆抗体。试验通过RT-PCR方法成功扩增出2 001bp的家兔PepTI基因片段,设计特异性引物成功扩增出抗原表位相对集中的1 071bp大小的片段,构建重组表达质粒,获得融合蛋白。结果显示:家兔PepTⅠ基因片段成功的连接到pMD18-T载体上,重组克隆载体双酶切后回收目的片段分别连接到原核表达载体pET-32a、pET-28a,经转化提取质粒测序验证后表明,成功构建原核表达载体pET-32a-P、pET-28a-P,将重组质粒转化至感受态细胞BL21(DE3)后IPTG诱导,成功表达出PepTⅠ融合蛋白,目的蛋白相对分子质量大小约为44 000,与预期试验结果相符。结果表明:本试验成功扩增出家兔PepTⅠmRNA序列,并且通过原核表达获得家兔PepTI融合蛋白。 相似文献
8.
为研究引起奶牛乳房炎的病原菌停乳链球菌、无乳链球菌和乳房链球菌的gapC基因工程疫苗及其生物免疫活性,试验采用PCR方法扩增出停乳链球菌、无乳链球菌和乳房链球菌的gapC基因cDNA序列,克隆到pMD18-T载体上,将重组质粒pMD18-T-TRgapC、pMD18-T-WRgapC和pMD18-T-RFgapC经双酶切鉴定、测序及序列分析后,再将gapC基因亚克隆到pET-28a(+)原核表达载体上,构建停乳链球菌、无乳链球菌和乳房链球菌的gapC基因原核表达质粒pET-28-TRgapC、pET-28-WRgapC和pET-28-RFgapC;将构建好的原核表达质粒转化至宿主菌BL21(DH3)中,诱导表达目的蛋白。表达产物经SDS-PAGE电泳、纯化、复性后经Western blot检测,得到了约38 ku的条带,与预期大小相符。说明这3种蛋白有一定的免疫原性。 相似文献
9.
为了克隆羊传染性脓疱病毒CEV112基因并对其进行原核表达,根据GenBank中CEV112基因序列信息设计1对引物,以CEV基因组为模板,采用PCR扩增出1条大小为867bp的CEV112基因,将其连接到pMD20-T载体上,构建pMD20-T-CEV112重组质粒,转化到大肠埃希菌(E.coli)DH5α感受态细胞中,提取质粒进行酶切鉴定。鉴定正确后构建重组质粒pET28a-CEV112,转化到E.coli BL21(DE3)感受态细胞中。经IPTG诱导表达,表达产物用SDS-PAGE和Western blot进行分析。结果表明,成功构建了pET-28a-CEV112原核表达载体,并在E.coli BL21(DE3)中表达了CEV112基因,表达的融合蛋白大小约36ku,且主要以包涵体形式存在,为后续开展CEV112基因的功能研究奠定了基础。 相似文献
10.
新城疫病毒F基因在大肠埃希菌中的表达及其抗原性分析 总被引:2,自引:0,他引:2
构建新城疫病毒融合蛋白F基因的原核表达载体,并将其在宿主菌BL21(DE3)感受细胞中表达.以含有融合蛋白F基因的重组质粒pMD19T-F为模板,设计特异性引物,应用PCR技术扩增获得F基因的F1片段,定向插入原核表达载体pET-28a,构建重组质粒pET-F1,将构建成功的重组质粒pET-F1转化宿主菌BL21(DE3)感受态细胞经IPTG诱导,将其在宿主菌细胞中表达,表达产物用SDS-PAGE和Western blot方法检测.结果显示,成功克隆出了新城疫病毒F1基因片段序列852 bp.构建的pET-F1载体经PCR、双酶切、测序鉴定均无误,转化表达宿主菌后经SDS-PAGE和Western blot检测结果显示,目的基因被成功表达,并具有良好的反应原性.成功构建了新城疫病毒的融合蛋白F基因原核表达载体,转化宿主细胞后成功表达了融合蛋白F1重组蛋白片段. 相似文献
11.
To construct tetramer precursor chain of swine lymphocyte antigen 1 (SLA-1) heavy chain in Hebao pig and study its protein expression in the pET-21a (+) vector,the SLA-1 complete genome sequence was referenced with the characteristics of the expression vector,and a pair of primers was designed to integrate the BirA substrate peptide (BSP) sequence at the C-terminus of the SLA-1-HB01 and the SLA-1-HB01-BSP was amplified by PCR. Then,the products were cloned into the pEASY T1 vector and the positive clones of SLA-1-HB01-BSP/pEASY T1 was selected. After the double digestion,the interest of the gene in positive clone was further ligated into the pET-21a (+) expression vector and transformed into E.coli BL21 to construct the recombinant strain of pET-21a (+)/SLA-1-HB01-BSP. After induction with IPTG,the target protein were detected by SDS-PAGE. Finally,the inclusion body of the SLA-1-HB01-BSP was isolated and detected to evaluate its purity. The PCR results showed that the length of SLA-1-HB01-BSP was about 898 bp,which was consistent with the theoretical value. The amplified fragment was successfully cloned into pEASY T1 vector, and the positive clones were identified by Nde Ⅰ and Xho Ⅰ digestion. The size of inserted fragment was 876 bp. The interest of gene was also inserted into pET-21a (+) and transformed into E.coil BL21 successfully. After induction,SDS-PAGE detection results showed that the target protein was 31.4 ku. Further detection showed that the target protein was mainly expressed as inclusion bodies,and the purity of the protein was about 80%. In this study,the recombinant tetramer precursor of SLA-1-HB01 heavy chain was constructed in pET-21a (+) expression line successfully, which would lay a foundation to detect the tetramer of SLA class Ⅰ molecular. 相似文献
12.
In order to construct the prokaryotic expressing vector of SLA-1 derived form Yorkshire pig and express the interest of protein, a pair of primers was designed to amplify the extracellular domain of SLA-1 gene from Yorkshire pig (named SLA-1-DYKe) by PCR. Then the PCR product was cloned into pMD®19-T Simple Vector and transformed into Escherichia coli TOP10. After cleaved by Nde Ⅰ and Xho Ⅰ, the positive clones were selected to be sequenced. Analyzing by biological soft, the fragment from positive clone with correct sequence was inserted into pET-28a (+) and transformed into E.coli BL21(DE3). After induction and expression, the interest of protein was detected by SDS-PAGE. The results showed that the extracellular domain of SLA-1-DYKe was successfully amplified with the fragment length of 837 bp. The interest of SLA-1 gene was successfully cloned into pMD®19-T Simple Vector and the positive recombinant plasmids with correct sequences were obtained. The SLA-1-DYKe from positive recombinant plasmids was further inserted into pET-28a(+). After transformed into E.coli BL21(DE3) and induction, the SLA-1-DYKe was successfully expressed. The molecular weight of the protein was about 34 ku. It was concluded that the prokaryotic expressing vector of SLA-1 was constructed successfully from Yorkshire pigs and then the expressed protein was obtained, which would lay a base for studying on the structure and function of SLA-1 from Yorkshire pig in the future. 相似文献
13.
The swine leukocyte antigen (SLA) genes in pigs were the important immune gene group in antigen presentation, and studing on SLA could provide the references for the prevention of some infectious diseases. Earlier studies found that SLA-1-632-TPK gene in ToPigs pig had a deleted base in its coding sequence (a single base "C" was lost in 632 bp from the 5' end of the SLA-1-632-TPK gene), which lead to frameshift mutation. In order to correct the SLA-1-632-TPK gene, two pairs of gene-correction's primers were designed to correct the gene by the splicing overlap extension PCR (SOE-PCR) in template of recombinant plasmid of SLA-1-632-TPK/pMD18-T. Firstly,the 5'and 3'ends of SLA-1-632-TPK gene were amplified, respectively, then both of them were spliced and amplified to form an intact SLA-1-632-TPK gene. After detected by agarose electrophoresis, the interest of the product was further cloned into pMD19-T Simple vector. The positive clones were screened by colony PCR and then sequenced. The result showed that the 5'and 3' ends of the SLA-1-632-TPK gene were all amplified successfully by SOE-PCR, with the products of about 650 and 590 bp, which were consistent with the theoretical value of 648 and 585 bp, respectively. After spliced, the intact sequence of SLA-1-632-TPK gene was obtained with the product of about 1 200 bp, which was close to the theoretical value of 1 223 bp. The colony PCR result showed that the corrected gene was successfully inserted into pMD19-T Simple vector . After the sequence was analyzed by GENETYX version 9.0, it was shown that the nucleotide "C" in 632 bp numbered from the 5'end of the gene was added and the SLA-1-632-TPK gene was coded correctly. In this study, the SLA-1-632-TPK was corrected successfully, and the recombinant plasmid SLA-1-TPK/pMD19-T was constructed, which would lay a foundation to further study the protein expression and associated function of SLA-1-TPK. 相似文献
14.
猪白细胞抗原(swine leukocyte antigen,SLA)在猪免疫系统中起递呈抗原作用,对其展开研究可为猪相关传染病的预防提供依据。研究发现,托佩克猪SLA-1-632-TPK基因编码序列发生碱基缺失(距离SLA-1-632-TPK基因5'端632 bp处丢失1个碱基"C"),导致移码突变。为矫正SLA-1-632-TPK基因,设计2对矫正引物,以原重组质粒SLA-1-632-TPK/pMD18-T为模板,利用剪切重叠延伸PCR(splicing overlap extention PCR,SOE-PCR)技术分别扩增SLA-1-632-TPK 5'和3'端,之后进行拼接,最后扩增全序列从而矫正目的基因,并进一步连接pMD19-T Simple载体,通过单菌落PCR筛选阳性克隆并测序,并通过GENETYX version 9.0软件对所测序列进行分析。结果显示,SOE-PCR成功扩增得到5'和3'端片段,大小约为650和590 bp,与理论设计值大小(648和585 bp)接近,经过拼接以后,得到全长约1 200 bp,与理论设计值1 223 bp接近。菌落PCR结果显示,矫正基因成功克隆入pMD19-T Simple载体。序列分析结果显示,托佩克猪SLA-1-632-TPK基因距离5'端632 bp处丢失的碱基"C"得到矫正并正确编码。本研究成功矫正了SLA-1-632-TPK基因,并构建其重组质粒SLA-1-TPK/pMD19-T,为下一步研究SLA-1-TPK蛋白表达和相关功能奠定基础。 相似文献
15.
试验旨在克隆羊种布鲁氏菌LpxB基因并进行原核表达和蛋白的生物信息学分析。以布鲁氏菌M5-90株基因组为模板,参照GenBank中M5-90株基因组DNA序列,用DNAMAN软件设计1对引物,通过聚合酶链式反应(PCR)扩增得到大小为1 188 bp的LpxB基因,将其连接入pMD20-T载体上,构建pMD20-T-LpxB重组质粒,将其转化到E.coli DH5α感受态细胞中,经BamH Ⅰ和 Xho Ⅰ双酶切鉴定正确后扩大培养。将BamH Ⅰ和 Xho Ⅰ双酶切获得的LpxB片段连接入pET-28a,构建重组质粒pET-28a-LpxB,转化到E.coli BL21(DE3)中,双酶切鉴定正确后扩大培养。经IPTG诱导其表达,用SDS-PAGE和Western blotting对蛋白进行鉴定。运用DNAMAN、BioEdit等软件对LpxB基因编码的氨基酸序列进行分析。结果表明,本研究成功克隆了LpxB基因并进行了蛋白表达,在LpxB蛋白二级结构中,α-螺旋、伸展链、β-折叠和无规卷曲分别占52.41%、14.94%、8.10%和24.55%。 相似文献
16.
NIE Xin ZHAO Tian-jing CAO Rui-yong PENG Dong-mei LI Guo-hua LI Ya-ying XU Kai-lian ZHU Hua-pei PANG Feng WANG Feng-yang DU Li 《中国畜牧兽医》2016,43(7):1681-1687
The study was aimed to clone and express LpxB gene,and perform the bioinformatics analysis of protein.The genomic DNA of Brucella melitensis M5-90 was used as template.According to the genome sequence of M5-90 on GenBank,a pair of primers was designed.LpxB gene,which was 1 188 bp,was amplified by PCR,and was ligated into pMD20-T vector.The constructed recombinant plasmid pMD20-T-LpxB was transformed into E.coli DH5α.The recombinant plasmid was confirmed by endonuclease digestion and sequencing.The coding region of LpxB from pMD20-T was digested by BamHⅠ and XhoⅠ.Then,the fragment was inserted into prokaryotic expression vector pET-28a,and the positive plasmid was named pET-28a-LpxB.The pET-28a-LpxB was transformed into E.coli BL21 (DE3).The expressed protein was identified by SDS-PAGE and Western blotting.DNAMAN and BioEdit softwares were used to analyze the sequence of amino acids encoded LpxB gene.The results showed that the CDS of LpxB was successfully cloned and expressed.The secondary structure of LpxB protein consisted structure α -helix,extended strand,β-turn and random coil which accounted for 52.41%,14.94%,8.10% and 24.55%,respectively. 相似文献