胸腺肽基因对樱桃番茄的遗传转化

胸腺肽基因是一343bp的小肽基因,是从动物中克隆得到的。本文以“美味樱桃”番茄为植物材料,用农杆菌侵染法进行了胸腺肽基因的遗传转化。对所得再生植株进行了PCR和Southern blot检测及RT-PCR检测,34棵Kam抗性株通过目的基因PCR检测,4棵为阳性株,阳性株率为11．8%。实验中还对目的基因之后的Nos终止序列区进行了扩增,通过Nos Ter．引物对4株目的基因PCR阳性株作PCR检测．只有1株为阳性株,该植株经Southern blot检测和RT-PCR检测,均为阳性。这些检测结果说明胸腺肽基因成功地整合到番茄基因组中,并在转录水平上得以表达。     

反义磷脂酶Dγ基因转化小麦的研究

目的:获得抗寒、耐盐等能力增强的小麦新种质或新品种。方法:利用穗茎注射法将含有反义磷脂酶Dγ基因(PLDγ)的根癌农杆菌菌液注入到春小麦富硒乌麦旗叶鞘内,T1代经田间表型选择筛选到10株变异株,通过特异PCR扩增和Southern杂交技术对获得的变异株进行分子检测,并对转基因植株进行耐盐性鉴定。结果:变异株均扩增出大小为430bp的目的片段,Southern印迹结果与其一致,证实反义PLDγ基因已经整合到小麦的核基因组中;6株转基因植株的抗寒力比对照显著增强,4株的熟期提早3～4d;在室内耐盐性筛选中,2株变异植株耐NaCl的能力比对照有不同程度的提高。结论:反义PLDγ基因在提高小麦的抗寒、耐盐性上具有很大的应用价值。     

小黑杨转双价抗虫基因的研究

用根癌农杆菌介导的叶盘法,将蜘蛛杀虫肽与Bt基因C肽序列的融合基因导入小黑杨(Populus simonii×P.nigra),所获得的3株卡那霉素抗性再生植株进行PCR和PCR-Southern杂交检测的结果均为阳性,Southern杂交检测的结果2株为阳性.抗虫试验结果显示,3个转基因株系均具有明显的抗虫效果,能显著抑制舞毒蛾幼虫的生长发育,表现出强烈的抗虫作用.     

梅PGIP基因超表达载体的构建及遗传转化

运用已克隆的梅PGIP基因构建植物超表达载体,将PGIP插入带有启动子super-promoter和终止子nos的中间载体P-Super1300 中,酶切鉴定表明,目的基因已正确地插入载体中.用根癌农杆菌介导法将其转入烟草中,共获得25株潮霉素抗性苗,对其中的13株进行PCR检测,有12株扩增出了目的条带;进一步对其中的7株进行Southern杂交检测和RT-PCR检测,发现7个株系均有杂交带出现,且均发生了基因转录,说明已成功获得了能够表达PGIP基因的转基因烟草.     

外源超氧化物歧化酶基因MnSOD在玉米中的过量表达及抗逆性的提高

为研究过量表达的超氧化物歧化酶基因MnSOD对玉米抗逆性的作用,构建了小麦来源MnSOD基因的单子叶植物高效表达载体,用基因枪法转化优良玉米自交系胚性愈伤组织。经潮霉素梯度浓度培养基筛选,从阳性愈伤组织再生获得9个正常结实的植株。其中5株经PCR和Southern印迹检测表现为阳性,表明外源基因己整合到玉米基因组中。提取SOD酶液,非变性聚肉烯酰胺浓度梯度凝胶电泳分离,用H2O2 5mmol／L抑制FeSOD和CU／ZnSOD活性,氯化硝基四氮唑蓝染色检测MnSOD酶活性。Southern印迹呈阳性的5个植株,MnSOD酶活性均高于未转基因的对照。甲基紫精氧化损伤处理后,用电解质渗漏率法测定阳性株系的叶片渗透液的电导率。结果表明,转基因株系的抗氧化损伤能力显著高于对照。     

ACS和ACO基因克隆及植物转化

根据已知序列设计PCR引物,分别扩增氨基环丙烷羧酸合酶（ACS）和氨基环丙烷羧酸氧化酶（ACO）基因并克隆到中间载体,经限制性内切酶酶切图谱分析、部分序列分析以及Southern印迹鉴定后,将两个基因单个或相互串联后反向亚克隆至植物表达载体pBI121。经农杆菌LBA4404转化番茄子叶,在抗性培养基上得到8株ACS基因反义转化的生根小苗以ACS基因的酶切小片段作为探针,经Southern印迹分析,证明获得了两株阳性转化株。     

转拟南芥AtKup1基因高含钾量烟草获得

提取拟南芥幼根总RNA,进行RTPCR逆转录,产物测序,将其构建到含Km(带内含子)筛选标记的植物双元表达载体上,根癌农杆菌介导法将AtKup1基因导入烟草,对转化子进行PCR扩增、GUS染色、Southern杂交和AtKup1基因mRNA荧光定量PCR分析,并进行烟叶内在成分化验分析。PCR获得2100bp左右扩增产物,测序结果证实扩增产物序列与拟南芥AtKup1基因(GenbankNo:AF029876)一致;得到GUS染色阳性的AtKup1基因转化烟草材料29株。经PCR扩增、分子杂交检测证实AtKup1基因已整合到转基因烟草的基因组,荧光定量PCR分析可以在幼根中检测到AtKup1基因的mRNA转录。烟叶含钾量化验结果表明导入的AtKup1基因在转化材料中成功表达,使烟叶含钾量提高约45%。     

根癌农杆菌介导的高羊茅遗传转化研究

采用携带卡那霉素抗性基因nptⅡ和Na^ ／H^ 反向运输AtNHX1基因的表达载体pROK2／AtNHX1(带有35S启动子)和pROK2U／AtNHX1(带有ubi1启动子)的根癌农杆菌AGL1和GV3101,对4个品种高羊茅下胚轴来源的胚性愈伤组织进行了遗传转化。胚性愈伤组织经根癌农杆菌感染和共培养后,用50～150mg／L巴龙霉素筛选抗性愈伤组织,获得1126棵再生植株,用10～20mg／L卡那霉素进一步筛选再生植株,总共得到525棵绿色抗性植株。抗性植株的总DNA用AtNHX1基因的特异引物进行PCR检测,其中21棵为PCR阳性,最高转化频率为1．77％。Southern杂交结果证实,外源基因以低拷贝整合到高羊茅的基因组中,实验发现,在不同品种之间转化效率有所差异。     

激发子基因peaT1转化三生烟及其对TMV抗性的提高

通过根癌农杆菌(Agrobactrium tumefaciens)介导转化法,将含有激发子基因peaT1的植物表达载体pCAM-BIA2300-G4AS-peaT1转化三生烟,获得了转基因烟草植株。用PCR检测确认了阳性转化株,用Southern杂交、RT-PCR和Western杂交进一步证实了peaT1基因的整合、转录和表达。对T1代转基因阳性株进行TMV接种试验,结果显示,与非转基因对照相比,表达peaT1的烟草叶片枯斑数量减少,表明蛋白激发子基因peaT1的表达提高了转基因烟草对TMV的抗性。     

超声波介导铁蛋白基因转化苹果的研究

以嘎拉苹果的叶片为转化受体,应用超声波法将菜豆铁蛋白基因导入受体中.实验表明,以0.5 W/cm2的声强、25℃、20 min超声波处理的转化效果最佳,抗性愈伤组织的比例高达24%.抗性愈伤组织经诱导获得了16个苹果抗性植株,有11株表现出GUS阳性,阳性比率为2.75%.经PCR检测,11株GUS阳性植株中有6株能扩增出目的条带;而Southern blotting实验表明,菜豆铁蛋白基因仅在2个苹果转基因株系的基因组中实现了完整插入,并且杂交的信号较强;进一步RT-PCR检测实验显示,外源菜豆铁蛋白基因在上述2株转基因植株中并未转录,发生了基因沉默.     

转水稻NibT基因玉米植株的获得及抗病性研究

以玉米(Zea mays L.)自交系'金黄96B'为受体材料,供体为质粒pWM101并携带有水稻矮缩病病毒复制酶基因Nib的提前终止突变体基因NibT,采用超声波处理花粉介导植物基因转化方法将NibT基因导入受体,经PCR检测和Southern杂交分析证实获得转基因植株,进而对T1～T3代转基因植株(株系)进行分子分析、田间抗病鉴定和农艺性状调查.逐代分子检测分析结果证明,目的基因可稳定遗传.抗病鉴定结果证明转基因植株(株系)各代抗病水平基本一致,抗病性比对照提高3级.农艺性状调查分析表明,与对照比较,转基因植株株高增加7～18 cm、穗位高增高0～13 cm、穗长增加0.7～2.1 cm、穗粒数多8～35粒、百粒重增加1.1～2.6 g,转基因株系与阴性对照间、各代转基因株系相互间都差异显著(P＜0.05);调查还发现转基因植株的株高和穗位高随着世代的增加,与对照间的差异逐代减少.研究也说明,超声波处理花粉介导植物基因转化方法是一种简捷、快速和有效的植物转化工具.     

以胆碱脱氢酶基因对小黑杨花粉植株的遗传转化

以小黑杨（Populus simoniixP．nigra）花粉植株叶片为外植体,用根癌农杆菌介导法将胆碱脱氢酶基因（betA）导入其中,将获得的4株卡那霉素抗性转基因株系进行PCR检测,结果均为阳性。用荧光定量PCR对转基因株系的betA基因转录结果检测表明,4个转基因株系均已表达外源基因,但表达量有差异。对获得的4株转基因株系及对照进行NaCl胁迫处理,当NaCl浓度为0．55％时,非转基因小黑杨花粉植株生根率为0,转基因株系生根率为80％～100％;在NaCl为0．70％～0.80％时,则转基因株系生根率也为0。4个转基因株系的甜菜碱含量显著高于未转基因对照,说明抛融基因的导入提高了转基因株系的耐盐性。     

Bioinformatics Analysis of Disease Resistance Gene <i>PR1</i> and Its Genetic Transformation in Soybeans and Cultivation of Multi-resistant Materials

In agricultural production, a single insect-resistant and disease-resistant variety can no longer meet the demand. In this study, the expression vector pCAMBIA-3301-PR1 containing the disease-resistant gene PR1 was constructed by means of genetic engineering, and the PR1 gene was genetically transformed to contain the PR1 gene through the pollen tube method. In CryAb-8Like transgenic high-generation T₇ receptor soybean, a new material that is resistant to insects and diseases is obtained. For T₂ transformed plants, routine PCR detection, Southern Blot hybridization, fluorescence quantitative PCR detection, indoor and outdoor pest resistance identification and indoor disease resistance identification were performed. The results showed that there were 9 positive plants in the routine PCR test of T₂ generation. In Southern Blot hybridization, both PR1 and CryAb-8Like genes are integrated in soybeans in the form of single copies. Fluorescence quantitative PCR showed that the expression levels of PR1 and CryAb-8Like genes are different in different tissues. The average expression levels of PR1 gene in plant roots, stems, and leaves are 2.88, 1.54, and 5.26, respectively. CryAb-8Like genes are found in roots, stems, and leaves. The average expression levels were 1.36, 1.39, and 4.25, respectively. The insectivorous rate of the CryAb-8Like gene in outdoor plants with positive insect resistance identification was 3.78%. The disc partition method was used indoors for pest resistance identification, and the bud length of transformed plants increased significantly. The average mortality rate of untransformed plants in indoor disease resistance identification was as high as 56.66%, and the average mortality rate of plants transformed with PR1 gene was 10.00%, and disease resistance was significantly improved. Therefore, a new material with resistance to diseases and insects is obtained.     

转水稻粗缩病毒运动蛋白缺陷型基因玉米的二重PCR检测研究

本研究以外源基因（RDV MP-）和玉米内源基因Zein作为PCR扩增对象,旨在建立一种简便有效的转基因玉米及其产品的二重PCR检测技术。转外源基因（RDV MP-）材料的常规PCR检测结果证明外源基因在转基因材料中可稳定遗传;对常规PCR检测的阴性结果材料进行二重PCR检测,扩增结果除进一步证实常规PCR检测的阴性结果结论外,还证明提取的植物总DNA质量符合试验要求,进而从二重PCR检测结果还得出常规PCR检测的阴性结果出错率为1.4%。此方法简单,实用,结果可靠,可适用于转基因植物及产品的检测。     

利用脉冲电泳技术转化玉米获得转基因植株的研究

本研究采用脉冲电泳技术将外源Bar基因和B-t基因转化玉米种胚并直接成苗,通过除草剂抗性初步筛选,再进行PCR检测、Southem杂交验证,探讨了脉冲电泳介导外源基因直接转化玉米种胚的有效性,结果表明：脉冲电泳技术介导玉米转基因是有效可行的,其T0代植株PCR阳性率与T1代植株转化率分别为11．36％和1．04％。在外源基因的转化中,处于不同启动子下的B-t基因和Bar基因共转化频率为90．9％。T1代PCR表现为阳性的植株Southem杂交结果显示脉冲电泳法介导的外源基因在受体中多为单拷贝,且已遗传给后代,并获得稳定表达。     

多个抗虫基因转化水稻两用系培矮—64S

应用基因枪法对水稻两用系培矮－64S进行了转化。质粒载体pKC-3串联了三个抗虫基因,将其转化成熟胚诱导形成的愈伤组织,共获得33株转基因植株。分别对R0代植株不同的基因进行PCR及Southern blot分析,并对R1代植株进行了PCR分析。结果表明,三个抗虫基因均已整合到水稻基因组并获得稳定遗传。     

多个抗虫基因转化水稻两用系培矮-64S

应用基因枪法对水稻两用系培矮-64S进行了转化。质粒载体pKC-3串联了三个抗虫基因,将其转化成熟胚诱导形成的愈伤组织,共获得33株转基因植株。分别对R_0代植株不同的基因进行PCR及Southern blot分析,并对R_1代植株进行了PCR分析。结果表明,三个抗虫基因均已整合到水稻基因组并获得稳定遗传。     

转Zm13_Barnase基因玉米的获得及其花粉育性研究

5 mg·L-1 Bialaphos was determined to be the adequate concentration for selection of maize (Zea mays L.) calli on herbicide resistance after evaluating three concentrations of Bialaphos in three genotypes. The chimeric gene Zm13-Barnase was transferred into the embryogenic calli of maize by particle bombardment, and 24 normal plants were regenerated from the 32 herbicide-resistant calli obtained after six cycles of continuous selection under 5 mg·L-1 Bialaphos. PCR assay showed that 18 plants were positive for Barnase gene with a frequency of 75%. I-KI staining and pollen germination revealed that five plants were partially male-sterile. Southern blot analysis indicated integration of Barnase gene into maize genome.     

Cloning and Drought Resistance Analysis of Soybean <i>GmHsps_p23-like</i> Gene

Soybean (Glycine max (L.) Merr.) is an important cultivated crop, which requires much water during its growth, and drought seriously affects soybean yields. Studies have shown that the expression of small heat shock proteins can enhance drought resistance, cold resistance and salt resistance of plants. In this experiment, soybean GmHsps_p23-like gene was successfully cloned by RT-PCR, the protein encoded by the GmHsps_p23-like gene was subjected to bioinformatics analysis, and the pCAMBIA3301-GmHsps_p23-like overexpression vector and pCBSG015-GmHsps_p23-like gene editing vector were constructed. Agrobacterium-mediated method was used to transform soybeans to obtain positive plants. RT-PCR detection, rehydration experiment and drought resistance physiological and biochemical index detection were performed on the T₂ generation positive transgenic soybean plants identified by PCR and Southern hybridization. The results showed that the overexpression vector plant GmHsps_p23-like gene expression increased. After rehydration, the transgenic overexpression plants returned to normal growth, and the damage to the plants was low. After drought stress, the SOD and POD activities and the PRO content of the transgenic overexpression plants increased, while the MDA content decreased. The reverse was true for soybean plants with genetically modified editing vectors. The drought resistance of the overexpressed soybeans under drought stress was higher than that of the control group, and had a stronger drought resistance. It showed that the expression of soybean GmHsps_p23-like gene can improve the drought resistance of soybean. The cloning and functional verification of soybean GmHsps_p23-like gene had not been reported yet. This is the first time that PCR technology has been used to amplify the soybean GmHsps_p23-like gene and construct an expression vector for this gene. This research has laid the foundation for transgenic technology to improve plant drought resistance and cultivate new drought-resistant transgenic soybean varieties.