褐飞虱喂养试验显示表达GNA的转基因水稻纯系抗褐飞虱

利用基因枪法将含有3个不同基因（hpt,gus和gna）的质粒pWRG1515和pRSSGNA1共同转化粳稻品种鄂晚5号成熟胚诱导的愈伤组织。共再生出35株独立转基因植株。PCR／Southern印迹法分析发现,83％的转基因植株含有所有3个外源基因。Western印迹法分析发现79％的含gna基因的转基因植株以不同水平表达GNA。遗传分析证实外源基因在转基因植株后代中以孟德尔方式遗传。从其R1代亲本为孟德尔3：1方式遗传的R2代中,鉴定出2个含有所有3个外源基因的独立转基因植株纯系。这些纯系具有相似的外源基因表达量。褐飞虱喂养试验表明,这些纯系对褐飞虱具有显著的抑制作用。这些褐飞虱抗性提高的转基因纯系将应用于水稻抗虫育种中。实验证明,通过遗传转化和筛选可获得含在农业上有应用价值基因的转基因水稻纯系。     

转基因水稻纯系对褐飞虱的抗性研究

利用基因枪法将含潮霉素抗性基因、ＧＵＳ报告基因和雪花莲凝集基因的２个质粒ｐＷＲＧ１５１５和ｐＲＳＳＧＡ１共同转化粳稻品种鄂宜１０５的成熟胚诱导的愈伤组织,从轰击的１５２块愈伤组织中共再生出２６株独立转基因植株,ＰＣＲ／Ｓｏｕｔｈｅｒｎ印迹法分析发现,７３％的转基因植株含有所有３个外源基因,遗传分析证实外泊基因在转基因植株后代中以孟德尔方式遗传,从其Ｒ１代亲本为孟德尔３：１方式遗传的Ｒ２代中,鉴定出     

通过遗传转化获得含多基因的水稻转基因纯合植株

利用基因枪法将含有4个不同基因的3个质粒共转化由粳稻品种鄂宜105号和鄂晚5号种子胚诱导的愈伤组织（5－10d龄）。从轰击的986块愈合组织中共再生出169株独立的转基因水稻植株（转化率为17％）。PCR／Southern blot分析显示70％以上的转基因植株含有所有4个基因。GUS组织化学分析、Western blot和或RT－PCR分析表明所有4个基因的共表达率为70％。未观察到任何质粒在整合中存在优势,转基因拷贝数也与基因表达量无关。遗传分析证实外源基因在后代植株中大多以孟德尔方式遗传。从其R1代为3：1孟德尔方式遗传的后代R2代植株中,鉴定含有3个或4个不同基因的转基因纯合植株系。PCR／Southern blot分析证实了这些转基因纯合植株系。这些系的植株具有相似的外源基因表达量。我们证实通过基因枪介导的共转化,结合常规育种方法筛选可以获得含多基因的转基因水稻纯合植株。这项技术为利用基因同时改良作用多个性状提供了一种途径。     

外源基因（bar）在转基因燕麦（AvenasativaL.）后代中的遗传与表达

通过微弹轰击获得的含有ｂａｒ基因的转基因燕麦植株自交产生转基因后代。利用ＰＣＲ方法检测ｂａｒ基因在后代中的传递情况。     

表达雪花莲外源凝集素基因的油菜转基因植株的获得

利用农杆菌素LBA4404（pCAMBIA3300RG)转化优良甘蓝型油菜恢复系W723的下胚轴节段.pCAM-BIA3300RG含有Rssl启动子引导的雪花莲外源凝集素基因（gna）和CaMV-35S启动子引导的除草剂抗性基因（bar）。经过两轮除草剂（2.5mg/L bialaphos）筛选（两周/轮）,除草剂抗性再生芽被传入生根培养基中生根,对根系旺盛生长的植株中所含gna基因进行PCR分析,PCR分析证实了这些植株确为转基因植株,利用Western印迹法对随机选择的5株含gna基因的转基因植株的分析发现,其中4株表达了gna基因。目前正对这些表达gna基因的转基因植株进行后代遗传分离分析。     

Introduction of antisensewaxy gene into main parent lines ofindica hybrid rice

Amylose content in rice endosperm is one of the key determinants of rice eating and cooking quality, and the poor quality ofindica hybrid rice is closely related to the high amylose level in rice grains. In order to improve the grain quality of theindica hybrid rice by genetic engineering, an antisense fragment of ricewaxy gene, driven by the 5′-franking sequences of the ricewaxy gene, was successfully introduced into three major parent lines ofindica hybrid rice, all contain a high amylose level in the grains, viaAgrobacterium, and more than 100 hygromycinresistant plants were regenerated. The analysis of PCR amplification and Southern blots indicated that the T-DNA containing the antisensewaxy gene had been integrated into the genome of transgenic rice plants. Most of the primary transgenic rice plants grew normally, and the mature seeds from these transgenic plants were performed for analysis of the amylose content. The results showed that the amylose content in the endosperm of some grains was reduced and the lowest reached 7.02% in one homozygous transgenic line, 72.4% lower than that of the wild type. The influence of the altered amylose content on the gelatinization temperature and gel consistency was also observed in several homozygous transgenic rice plants. The two authors contributed equally to this work.     

Inheritance and expression of multiple disease and insect resistance genes in transgenic rice

2—3 anti-fungal disease genes are coinserted with hygromycin phosphotransferase in the same vector. Two insecticidal genes and PPT acetyl transferase genes are placed in another one. The vectors are co-delivered to rice embryonic cellus tissue at a molar ratio of 1︰1 using the particle gun method. 55 independent regenerated lines have been obtained through screening for hygromycin resistance. Of these, 70% transgenic plants harbor 6—7 foreign genes. The genes on the same vectors are always co-delivered to rice plant. Northern blot analysis has indicated that the multiple foreign genes give stable expression. In the 6 transgenic plants carrying 6—7 foreign genes, multiple foreign genes tend to integrate in 1 or 2 genetic loci. Progeny segregation is consistent with Mendel’s 3︰1 segregation law. 8 homozygous R₁ transgenic plants harboring 2—3 anti-fungal and 2 insecticidal genes are selected from large number of transgenic progeny screening for hygromycin and Basta resistance.     

抗除草剂旱稻转基因植株的获得

以旱稻丹粳旱５－５５、６－２４、６－３７的悬浮细胞及未成熟胚为受体材料，采用基因枪法将含ＢＡＲ基因的ｐＤＭ３０２质粒ＤＮＡ导入旱稻细胞中，经ＰＰＴ筛选获得抗性愈伤组织，筛选出的愈伤组织在分化培养基上再生出完整的旱稻转基因植株。Ｓｏｕｔｈｅｒｎ分子杂交分析表明，外源ＢＡＲ基因已整合到水稻基因组内，抗除草剂试验结果表明，转化植株对０．０１％Ｂａｓｔａ（有效成分为ＰＰＴ）有一定程度的抗性，说明外源ＢＡＲ     

Introduction of antisense waxy gene into main parent lines of indica hybrid rice

Amylose content in rice endosperm is one of thekey determinants of rice eating and cooking quality, and thepoor quality of indica hybrid rice is closely related to thehigh amylose level in rice grains. In order to improve thegrain quality of the indica hybrid rice by genetic engineering,an antisense fragment of rice waxy gene, driven by theintroduced into three major parent lines of indica hybrid rice,all contain a high amylose level in the grains, via Agrobacte-rium, and more than 100 hygromycin-resistant plants wereregenerated. The analysis of PCR amplification and South-ern blots indicated that the T-DNA containing the antisensewaxy gene had been integrated into the genome of transgenicrice plants. Most of the primary transgenic rice plants grewnormally, and the mature seeds from these transgenic plantswere performed for analysis of the amylose content. Theresults showed that the amylose content in the endosperm ofsome grains was reduced and the lowest reached 7.02% inone homozygous transgenic line, 72.4% lower than that ofthe wild type. The influence of the altered amylose contenton the gelatinization temperature and gel consistency wasalso observed in several homozygous transgenic rice plants.     

Salt tolerance of transgenic rice (Oryza sativa L.) withmtlD gene andgutD gene

Southern blot analysis indicated thatmtlD gene (encoding mannitol-1-phosphate dehydrogenase) andgutD gene (encoding glucitol-6-phosphate dehydrogenase) had been integrated into the rice genome mediated byAgrobacterium tumefaciens LBA4404(pBIGM). The expression of the above two genes in transgenic rice plants was demonstrated by Northern blot analysis and enzymatic activity assay. Analysis of sugar alcohol showed that transgenic rice plants could produce and accumulate mannitol and sorbitol. The salt tolerance of transgenic plants was much higher than that of their controls.     

农杆菌介导GNA基因对水稻的遗传转化

在ｐＣＡＭＢＩＡ３３００质粒中插入带有ＲＳｓ－１启动子的ＧＮＡ基因,并利用农杆菌介导的遗传转化将其导入水稻的微不定芽受体,得到了再生植株。ＰＣＲ,Ｓｏｕｔｈｅｒｎ ｂｌｏｔ和Ｗｅｓｔｅｒｎ ｂｌｏｔ的检测结果初步证明ＧＮＡ基因已经整合到水稻的基因组中并得到表达。     

生物鉴定和喂养试验证明GNA赋予转基因水稻纯系对褐飞虱的抗性

参照Rao等（1998）的褐飞虱生物鉴定和喂养方法,用水稻褐飞虱生物Ⅰ型的－龄若虫食喂,用基因枪法获得2个转基因水稻纯系。这2个纯系均含有并表达潮霉素抗性基因（hpt),gusA报告基因和雪花莲凝集素基因（gna)。褐飞虱生物鉴定和喂养试验表明,水稻纯系对褐飞虱具有显著的抑制作用。具体表现为降低褐飞虱成活率和繁殖力、延缓褐虱发育以及减少褐飞虱进食是。通过褐飞虱生物鉴定和喂养试验证明,表达GNA的转基因水稻纯系对严重危害水稻生产的褐飞虱具有抗性作用。     

Transformation of japonica rice with RHL gene and salt tolerance of the transgenic rice plant

Overexpression of the yeast HAL2 gene increases salt tolerance of yeast and plant. Rice HAL2-like (RHL) gene was introduced into a japonica rice cultivar HJ19 with Agrobacterium tumefaciens-mediated transformation. Transgenic plants in R0 generation were selected on the principle of GUS-positive, RHL gene PCR-positive and normal growth. Hygromycin-resistant plants of some transgenic lines in R1 generation increased salt tolerance during the seedling and booting stage, being less damaged in the cytomembrane and stronger in leaf tissue viability under salt stress during booting period. Southern analysis of transgenic lines tolerant to salt in R1 generation showed that the RHL gene expression cassette had been successfully integrated into rice genome. Moreover, gene engineering breeding methodology and really salt-tolerant rice cultivar were discussed.     

Salt tolerance of transgenic rice (Oryza sativa L.) with mtlD gene and gutD gene

Southern blot analysis indicated that mtlD gene (encoding mannitol-1-phosphate dehydrogenase) and gutD gene (encoding glucitol-6-phosphate dehydrogenase) had been integrated into the rice genome mediated by Agrobacterium tumefaciens LBA4404(pBIGM). The expression of the above two genes in transgenic rice plants was demonstrated by Northern blot analysis and enzymatic activity assay. Analysis of sugar alcohol showed that transgenic rice plants could produce and accumulate mannitol and sorbitol. The salt tolerance of transgenic plants was much higher than that of their controls.     

Overexpression of glutamine synthetases confers transgenic rice herbicide resistance

Glutamine synthetase (GS, E.C.6.3.1.2) is a key enzyme involved in the assimilation of inorganic nitrogen in higher plants and gram-negative microorganisms. GS is the targeting enzyme of a herbicide phosphinothricin (PPT) or Basta. In order to generate PPT-resistant transgenic rice via overexpression of GS, we constructed a plant expression vector p2GS harboring two different isoenzymes GS1 and GS2 cDNAs under the control of constitutive promoters of rice Act1 and maize Ubiquitin(Ubi) genes. The p2GS was introduced into rice genome by Agrobacterium-mediated transformation and confirmed by PCR and Southern blot hybridization. GS-transgene expression was first detected by Northern blot analyses. Results from Basta test indicated that GS-transgenic plants can tolerate as high as 0.3% Basta solution. In addition, our results also demonstrated that GS overexpression conferred transformed rice calli PPT resistance. Thus, GS cassette can serve as a selective marker gene instead of bar cassette for selection of PPT transformants.     

Transformation of japonica rice with<Emphasis Type="Italic">RHL</Emphasis> gene and salt tolerance of the transgenic rice plant

Overexpression of the yeastHAL2 gene increases salt tolerance of yeast and plant. RiceHAL2-like (RHL) gene was introduced into ajaponica rice cultivar HJ19 withAgrobacterium tumefaciens-mediated transformation. Transgenic plants in R₀ generation were selected on the principle of GUS-positive,RHL gene PCR-positive and normal growth. Hygromycin-resistant plants of some transgenic lines in R₁ generation increased salt tolerance during the seedling and booting stage, being less damaged in the cytomembrane and stronger in leaf tissue viability under salt stress during booting period. Southern analysis of transgenic lines tolerant to salt in R₁ generation showed that theRHL gene expression cassette had been successfully integrated into rice genome. Moreover, gene engineering breeding methodology and really salt-tolerant rice cultivar were discussed.     

In situ localization of proteinase inhibitor mRNA in rice plant challenged by brown planthopper

Proteinase inhibitor (PI) mRNA was localized by in situ hybridization in tissue sections of root, stem and leaf of the resistant rice (B5) plant fed by brown planthopper nymphs. In the rice material without BPH feeding, PI gene was expressed in the root, stem and leaf, while the abundance of PI mRNA was low. In the rice material fed by BPH,PI gene was expressed substantially in the parenchyma of rice stem and leaf, but weakly in the root. The results indicated that the PI gene was up-regulated in the rice plant challenged by brown planthopper. For the first time, we reported the expression changes of proteinase inhibitor gene in plant which was infested by a piercing/sucking insect.     

含编码类铁氧还双亲性蛋白ap1基因的转基因水稻植株的获得

利用基因枪法将含有潮霉素抗性基因（hpt),gusA报告基因和ap1基因的2个质粒（pJIMB15和pBiSAP1)共同转化同转化由粳稻品种鄂宜105号种 子在胚诱导的愈伤组织（2－3周龄）。ap1基因编码一种双亲性的蛋白。该蛋白能延缓因假单孢菌感染所引起的非寄主植物中的过敏反应。经过2轮潮霉素（30mg/L)筛选,抗性愈伤组织被转入含30mg/L潮霉素的再生培养基中再生植株。从轰击的186块愈伤组织中共再生出32株独立的转基因水稻植株（转化率为17．2％）,PCR／Southern blot分析显示84％的转基因植株含有所有3个基因。     

Resistance to rice blast (Pyricularia oryzae) caused by the expression of trichosanthin gene in transgenic rice plants transferred through agrobacterium method

The gene of trichosanthin has been transferred into rice plants through agrobacterium method. The single copy insertion and the expression of foreign gene have been proved in regenerated plants. In antifungal assay the degrees of rice blast (Pyricularia oryzae) infection of the transgenic plants expressing trichosanthin and expressingGUS gene as control have been evaluated. The differences such as the time of disease symptom observed, the number of infected plants and damaged leaves, the growth of infected plants of the two transgenic plants after being inoculated by rice blast (Pyricularia oryzae) are significant. The transgenic plants with trichosanthin gene grew faster than the plants withGUS gene, even when humidity environment was removed. The results show that the transgenic plants that expressed trichosanthin are able to delay the infection of rice blast compared with the plants as control. In addition, no damage caused by the expression of trichosanthin gene in transgenic plants has been observed.