通过农杆菌介导法将免防御麦NP—1基因导入毛白杨（P.tomentosa）

采用叶盘法将兔将御素ＮＰ－１基因导入毛白杨后,经ＰＣＲ分析、Ｓｏｕｔｈｅｒｎ杂交检测与筛获得了转基因植株,并经体外抑菌实验表明,转ＮＰ－１基因毛白杨植株组织提取物对某些微生物的生长具有明显的抑制作用。     

通过根癌农杆菌介导法获得菊花转基因植株

以带叶茎段为外植体,通过根癌农杆菌介导法,将兔防御ＮＰ－１基因导入菊花品种“００１”中。经梯度卡那霉素（ｋａｎａｍｙｃｉｎ,Ｋｍ）筛选,获得了大量Ｋｍ抗性植株,其中部分Ｋｍ抗性植株经Ｓｏｕｔｈｅｒｎ杂交鉴定为转基因植株。从而成功地建立了菊花遗传转化系统,为菊花分子育种奠定了基础。     

通过农杆菌介导法将兔防御素NP-1基因导入毛白杨(P.tomentosa)

采用叶盘法将兔防御素NP－1基因导入毛白杨后,经PCR分析、Southern杂交检测与筛选获得了转基因植株。并经体外抑菌实验表明,转NP－1基因毛白杨植株组织提取物对某些微生物的生长具有明显的抑制作用。     

通过根瘤农杆菌介导法获得菊花转基因植株

以带叶茎段为外植体,通过根癌农杆菌介导法,将兔防御素NP－1基因导入菊花品种“001”中。经梯度卡那霉素（kanamycin,Km）筛选,获得了大量Km抗性植株,其中部分Km抗性植株经Southem杂交鉴定为转基因植株。从而成功地建立了菊花遗传转化系统,为菊花分子育种奠定了基础。     

小麦中外源基因瞬间表达调控研究及兔防御素（NP—1）基因的转化

将不同５上游调控序列驱动下的ＧＵＳ基因用基因枪法导入小麦幼胚和胚性愈伤组织,通过组织化学分析法和荧光分析法对ＧＵＳ基因的表达进行定量检测,比较了几种烟草花叶病毒（ＴＭＶ）Ω增强子序列对小麦中外源基因瞬间表达的调控作用;然后将其中效率最高的玉米Ｕｂｉｌ启动子与兔防御素（ＮＰ－１）连接起来,并加上Ｎｏｓ终止子,构民ＮＰ－１基因小麦表达载体,并转化小麦幼胚,经ＰＣＲ－Ｓｕｔｈｅｒｎ ｂｌｏｔ分析,初步确     

IPsaur-ipt基因转化番茄的过氧化物酶同工酶分析

将整合在Ｔｉ质粒上的Ｐｓａｕｒ基因（生长素调节基因和细胞激动素合成酶基因的融合基因）通过花粉管通道法导入番茄品种中蔬四号、强力米寿、粉红甜肉、ＵＳ—Ⅰ、ＵＳ—Ⅱ中。对Ｄ１代转基因番茄用聚丙稀酰凝胶电泳方法进行过氧化物酶同工分析。结果表明,转基因番茄与对照植株的过氧化物酶同工酶谱带有明显差异,谱带多少和强弱都有所不同,而且相应地出现了植株形态学上的差异。间接验证了外源ＤＮＡ的导入。说明同工酶分析方法和田间形态学检测可作为转基因植株早期筛选的有效方法     

马铃薯Y病毒外壳蛋白基因在转基因马铃薯中的表达

ＰＶＹ是马铃薯Ｙ病毒组的典型成员,主要感染马铃薯、番茄、辣椒和烟草等。近年来,利用植物基因工程手段获得了不少抗病毒转基因工程植物,为培育抗病毒作物新品种提供了新途径［１］。病毒外壳蛋白基因导入并使之在植物中表达可获得抗相应病毒的转基因植物,已在烟草、番茄、马铃薯、苜蓿、黄瓜和番木瓜等植物中获得成功［１～３］。本室已成功地对在我国流行的ＰＶＹＮ株系外壳蛋白基因进行了克隆及序列测定［４］,在此基础上,我们构建了植物表达中间载体,通过土壤农杆菌介导的叶盘法转化马铃薯,获得了大量转基因植株。分子检测证明…     

利用椭圆小球藻硝酸还原酶缺失突变体为生物反应器表达兔防御素NP-1蛋白

利用转基因小球藻为生物反应器生产兔防御素NP-1蛋白具有重要的应用价值。本研究利用椭圆小球藻(Chlorella ellipsoidea)硝酸还原酶(nitrate reductase)缺失突变体为受体, 构建了包含NPTII基因和硝酸还原酶基因两个筛选标记的兔防御素蛋白表达载体, 采用电激法将目的基因转入椭圆小球藻硝酸还原酶缺失突变体nrm-4, 获得了正确表达防御素蛋白的转基因藻, 从而表明通过硝酸还原酶作为筛选标记基因并结合硝酸还原酶缺失突变体可作为较好的小球藻生物反应器生产模式。     

口蹄疫病毒结构蛋白P1-2A及蛋白酶3C基因的转基因番茄对豚鼠免疫反应的初步研究

构建了O型口蹄疫病毒China99株结构蛋白P1-2A、非结构蛋白3C以及部分2B基因(P1-2X3C)的植物双元表达载体pBin438/P1-2X3C,通过农杆菌介导法转化番茄子叶,经卡那霉素抗性筛选,获得40余株抗性植株,对得到的抗性植株进行分子生物学检测,65%的再生植株PCR检测阳性;RT-PCR结果证实P1-2X3C基因在转基因番茄中能够有效转录;ELISA和Western blot检测表明转基因植株中表达的目的蛋白具有免疫反应性。转基因番茄叶片蛋白粗提液经肌肉途径免疫豚鼠,于第3次免疫后28d用100ID50/0.2mL的同源强毒攻击,结果表明口蹄疫病毒P1-2X3C基因的转基因番茄表达产物具有良好的免疫原性,豚鼠3免后血清效价可达1:64~1:128,攻毒后两组免疫豚鼠保护率分别达3/5和5/5。     

番茄ACC合成酶cDNA克隆及其对果实成熟的反义抑制

利用RT—PcR技术克隆了ACC合成酶多基因家族成员之－LE-ACC2编码区约1．7kb的cDNA,经酶切图谱和序列分析鉴定无误后,反向插入到植物表达载体pBin437中,构建了表达Acc合成酶反望RNA的二元载体。经农杆菌途径转化番茄“丽春”品种后,通过PCR检测从抗卡那霉素再生植株中筛选到6株转基因植株,Southern杂交确证了外源基因是以单拷贝插入到番茄染色体中;对果实乙烯释放的测定结果表明转基因番茄果实的乙烯释放量仅为对照的30％左右,在室温下转基因番茄果实采后保存60 d以上仍然没有变红、软化。以上结果表明其反义RNA在转基因番茄中的表达能有效地抑制乙烯的生物合成从而延缓果实成熟,表现出良好的耐储保鲜特性。对转基因植株子一代(T1)的分析结果进一步表明反义ACC合成酶基因以典型的单基因方式传到子代。通过对子二代的分析已初步筛选到一 个耐储藏的转基因番茄纯合品系。     

番茄多蛋白桥梁因子基因LeMBF1的克隆及抗病性分析

采用同源序列克隆法,从番茄中克隆了多蛋白桥梁因子基因LeMBF1,该基因包含一个完整的420 bp的开放阅读框,编码139个氨基酸,具有MBF1保守结构域.LeMBF1氨基酸序列与马铃薯StMBF1、烟草NtMBF1和葡萄VvMBF1的氨基酸序列相似度分别是99.3%、91.4%和84.2%.为了研究番茄多蛋白桥梁因子LeMBF1在植物抗病性中的作用,以LeMBF1超表达转基因番茄和野生型番茄为材料,对其进行接种病原细菌Pst.DC3000和尖孢镰刀菌Fusarium.oxysporum的生物胁迫实验.抗菌表型分析发现,LeMBF1超表达转基因番茄叶片上的菌斑数明显少于对照植株;实时定量PCR分析表明,LeMBF1超表达番茄植株中防卫基因PR1、PR6的表达水平明显增强.由此可见,LeMBF1可能通过激活部分PRs基因的表达提高了植物的抗病性.     

Rho1 has distinct functions in morphogenesis, cell wall biosynthesis and virulence of Fusarium oxysporum

Rho-type GTPases regulate polarized growth in yeast by reorganization of the actin cytoskeleton and through signalling pathways that control the expression of cell wall biosynthetic genes. We report the cloning and functional analysis of rho1 from Fusarium oxysporum, a soilborne fungal pathogen causing vascular wilt on plants and opportunistic infections in humans. F. oxysporum strains carrying either a Deltarho1 loss-of-function mutation or a rho1(G14V) gain-of-function allele were viable, but displayed a severely restricted colony phenotype which was partially relieved by the osmotic stabilizer sorbitol, indicating structural alterations in the cell wall. Consistent with this hypothesis, Deltarho1 strains showed increased resistance to cell wall-degrading enzymes and staining with Calcofluor white, as well as changes in chitin and glucan synthase gene expression and enzymatic activity. Re-introduction of a functional rho1 allele into the Deltarho1 mutant fully restored the wild-type phenotype. The Deltarho1 strain had dramatically reduced virulence on tomato plants, but was as virulent as the wild type on immunodepressed mice. Thus, Rho1 plays a key role during fungal infection of plants, but not of mammalian hosts.     

转番茄几丁质酶基因西瓜植株的获得及其抗病性研究

构建了以CaMV35s启动子驱动的含有番茄几丁质酶基因（Chi3）的植物表达载体,通过冻融法导入根癌农杆菌（Agrobacterium tumefaciens）菌株EHAl05中。用叶盘法转化西瓜（Citrullus lanatus）栽培种“中育1号”,通过PCR、Southern blot和RT-PCR鉴定,表明外源基因已成功整合到西瓜基闪组中,并获得表达。利用尖孢镰刀菌西瓜专化型进行的转基因植株叶片粗提液抑菌效果检测,表明转基因植株的抗病性均有一定程度的增强。     

Role of ethylene in the protection of tomato plants against soil-borne fungal pathogens conferred by an endophytic Fusarium solani strain

An endophytic fungal isolate (Fs-K), identified as a Fusarium solani strain, was obtained from root tissues of tomato plants grown on a compost which suppressed soil and foliar pathogens. Strain Fs-K was able to colonize root tissues and subsequently protect plants against the root pathogen Fusarium oxysporum f.sp. radicis-lycopersici (FORL), and elicit induced systemic resistance against the tomato foliar pathogen Septoria lycopersici. Interestingly, attenuated expression of certain pathogenesis-related genes, i.e. PR5 and PR7, was detected in tomato roots inoculated with strain Fs-K compared with non-inoculated plants. The expression pattern of PR genes was either not affected or aberrant in leaves. A genetic approach, using mutant tomato plant lines, was used to determine the role of ethylene and jasmonic acid in the plant's response to infection by the soil-borne pathogen F. oxysporum f.sp. radicis-lycopersici (FORL), in the presence or absence of isolate Fs-K. Mutant tomato lines Never ripe (Nr) and epinastic (epi1), both impaired in ethylene-mediated plant responses, inoculated with FORL are not protected by isolate Fs-K, indicating that the ethylene signalling pathway is required for the mode of action used by the endophyte to confer resistance. On the contrary, def1 mutants, affected in jasmonate biosynthesis, show reduced susceptibility to FORL, in the presence Fs-K, which suggests that jasmonic acid is not essential for the mediation of biocontrol activity of isolate Fs-K.     

Different mechanisms of Trichoderma virens‐mediated resistance in tomato against Fusarium wilt involve the jasmonic and salicylic acid pathways

In the present study, we investigated the role of Trichoderma virens (TriV_JSB100) spores or cell‐free culture filtrate in the regulation of growth and activation of the defence responses of tomato (Solanum lycopersicum) plants against Fusarium oxysporum f. sp. lycopersici by the development of a biocontrol–plant–pathogen interaction system. Two‐week‐old tomato seedlings primed with TriV_JSB100 spores cultured on barley grains (BGS) or with cell‐free culture filtrate (CF) were inoculated with Fusarium pathogen under glasshouse conditions; this resulted in significantly lower disease incidence in tomato Oogata‐Fukuju plants treated with BGS than in those treated with CF. To dissect the pathways associated with this response, jasmonic acid (JA) and salicylic acid (SA) signalling in BGS‐ and CF‐induced resistance was evaluated using JA‐ and SA‐impaired tomato lines. We observed that JA‐deficient mutant def1 plants were susceptible to Fusarium pathogen when they were treated with BGS. However, wild‐type (WT) BGS‐treated tomato plants showed a higher JA level and significantly lower disease incidence. SA‐deficient mutant NahG plants treated with CF were also found to be susceptible to Fusarium pathogen and displayed low SA levels, whereas WT CF‐treated tomato plants exhibited moderately lower disease levels and substantially higher SA levels. Expression of the JA‐responsive defensin gene PDF1 was induced in WT tomato plants treated with BGS, whereas the SA‐inducible pathogenesis‐related protein 1 acidic (PR1a) gene was up‐regulated in WT tomato plants treated with CF. These results suggest that TriV_JSB100 BGS and CF differentially induce JA and SA signalling cascades for the elicitation of Fusarium oxysporum resistance in tomato.     

黄瓜转新型抗菌蛋白基因GNK2-1及其抗枯萎病的研究

GNK2-1为一种来自银杏(Ginkgo biloba)种仁的新型抗真菌蛋白, 具有较强的真菌抗性且性质稳定。序列分析表明,其结构与所有已知的抗真菌蛋白不同, 而与富含半胱氨酸的植物类受体激酶的胞外结构域相似。为探索GNK2-1基因在黄瓜(Cucumis sativus)抗病反应中的作用, 利用基因重组技术构建了GNK2-1的高效组成型表达载体, 并利用根癌农杆菌(Agrobacterium tumefaciens)介导转入黄瓜栽培品种农城3号(Cucumis sativus ‘Nongcheng No.3’)基因组中。通过对获得的抗性植株进行PCR、RT-PCR和Western blot检测分析, 结果表明GNK2-1基因可在T₀代转基因植株中转录表达, 并能在T₁代转基因黄瓜中稳定遗传。离体枯萎病抗性鉴定结果表明, 转GNK2-1基因的黄瓜对枯萎病的抗性增强, GNK2-1可以作为黄瓜抗病性改良的潜在基因资源。     

黄瓜转新型抗菌蛋白基因GNK2-1及其抗枯萎病的研究

GNK2-1为一种来自银杏（Ginkgo biloba）种仁的新型抗真菌蛋白,具有较强的真菌抗性且性质稳定。序列分析表明,其结构与所有已知的抗真菌蛋白不同,而与富含半胱氨酸的植物类受体激酶的胞外结构域相似。为探索GNK2-1基因在黄瓜（Cucumis sativus）抗病反应中的作用,利用基因重组技术构建了GNK2-1的高效组成型表达载体,并利用根癌农杆菌（Agrobacterium tumefaciens）介导转入黄瓜栽培品种农城3号（Cucumis sativus＇ Nongcheng No.3＇）基因组中。通过对获得的抗性植株进行PCR、RT-PCR和Western blot检测分析,结果表明GNK2-1基因可在T0代转基因植株中转录表达,并能在T1代转基因黄瓜中稳定遗传。离体枯萎病抗性鉴定结果表明,转GNK2-1基因的黄瓜对枯萎病的抗性增强,GNK2-1可以作为黄瓜抗病性改良的潜在基因资源。