稻曲病菌PMK1类同源基因克隆及在稻瘟病菌遗传互补中的功能验证

[目的]克隆稻曲病菌PMK1类MAPK(Mitogen-activated protein kinase)同源基因.[方法]根据丝状真菌MAPK蛋白保守性设计简并引物扩增稻曲病菌MAPK基因部分片段,进而利用TAIL-PCR进行染色体步移和RT-PCR获得UVMK1基因全长和cDNA全长.构建互补载体,交叉互补稻瘟病菌APMK1突变体菌株nn78进行功能验证,包括附着胞分化和致病性测定.[结果]UVMK1基因全长1435 bp,包含3个内含子,编码355氨基酸的蛋白.UVMK1推导蛋白与丝状真菌Magnaporthe grisea PMK1,Fusarium oxysporum FMK1,Fusarium solani FSMAPK,Colletotrichumlagenarium CMK1,Botrytis cinerea BMK1,Claviceps purpurea CMPK1等编码蛋白高度同源.转化稻瘟病菌菌株nn78,获得5个转化子.其中选取的转化子恢复了稻瘟病菌正常的附着胞分化和对大麦叶片的致病能力.[结论]本研究成功分离了首个稻曲病菌MAPK基因,而且UVMK1基因是稻瘟病菌PMK1的同源基因.     

农杆菌介导的玉米遗传转化

用带有质粒pGIH(35S-intron-GUS/ Hptr)的根癌农杆菌EHA101转化玉米愈伤组织,获得潮霉素抗性植株,再生性好的苏玉1 图7 Southern blot分析HpaII消化的质粒pGIH 和gusA基因沉默的愈伤组织的总DNA Fig.7 Southern blot analysis of plasmid pGIH(P) and plant genomic DNA of gusA gene si- lence callus(T)digested with HpaII号转化率可以达到8.1%。对转化植株进行GUS染色分析及PCR和Southern杂交检测证明外源基因已经整合,并能够稳定表达。反向PCR分析的三个转化植株,T-DNA插入片段均为单拷贝。部分失去分化能力的抗性愈伤组织,Southern blot分析发现其基因组中有gusA基因插入,但X-gluc染色呈阴性,经HpaII酶切分析发现整合的gusA基因发生了高度甲基化。     

带有报告基因的板栗疫病菌寄生隐赤壳分泌表达突变体库的构建及分泌缺陷突变体的筛选

丝状真菌分泌蛋白与其致病性密切相关,目前对于病原真菌的蛋白胞外分泌途径及其调控机制的报道不多。为建立一个方便高效的真菌分泌蛋白调控途径的遗传研究体系,本研究以植物病原丝状真菌——板栗疫病菌寄生隐赤壳Cryphonectria parasitica为对象,选取分泌表达量最高的两个分泌蛋白的信号肽SP1和SP2,分别构建带有GUS报告基因的分泌蛋白表达载体pCPXBle-SP1-GUS和pCPXBle-SP2-GUS并用于转化板栗疫病菌。选择高效分泌GUS蛋白的转化株SP1-9为出发菌株,利用农杆菌介导的遗传转化技术构建了T-DNA插入突变体库,从576个突变体中筛选到2株GUS分泌表达明显降低的突变体。本研究成功构建了可用于研究丝状真菌蛋白分泌的遗传研究体系,并筛选获得了分泌蛋白缺陷突变体,为深入研究丝状真菌分泌途径及其调控机制奠定了基础。     

农杆菌介导的获取疏绵状嗜热丝孢菌插入突变体体系的建立

[目的]建立疏绵状嗜热丝孢菌的稳定遗传转化体系并获得插入突变体.[方法]利用农杆菌介导的方法建立疏绵状嗜热丝孢菌的遗传转化体系 ;分别通过Southern杂交、克隆转移DNA(T-DNA)侧翼序列来确定T-DNA在疏绵状嗜热丝孢菌基因组中的拷贝数和插入位点.[结果]成功建立了可靠的疏绵状嗜热丝孢菌的遗传转化体系.共培养过程中使用萌发孢子是成功建立疏绵状嗜热丝孢菌遗传转化体系的必要条件.疏绵状嗜热丝孢菌萌发的孢子与农杆菌在28℃共培养48h时,转化效率最高.乙酰丁香酮(AS)在农杆菌预培养及疏绵状嗜热丝孢菌萌发的孢子与农杆菌的共培养阶段都是必需的,且在共培养阶段当AS浓度为500 μM时转化效率最高.Southern杂交验证表明,79.2％的转化子为T-DNA单拷贝插入,且通过热不对称PCR (TAIL-PCR)分析得出T-DNA在该菌基因组中的插入位点是随机的.通过该转化系统筛选到部分表型突变体.[结论]我们首次报道了利用ATMT技术成功转化嗜热真菌-疏绵状嗜热丝孢菌,证明了该方法是一种简单有效的获得插入突变体的方法,并为该嗜热真菌进行基因定位提供了工具.     

十字花科黑腐病菌中影响致病相关基因XC3814表达的基因鉴定

十字花科黑腐病菌8004菌株的XC3814基因与致病性和胞外多糖合成有关。文章将XC3814的启动子与报告基因sacB融合, 构建了XC3814的表达报告质粒pL3814sac。将该质粒导入野生型菌株8004, 获得了报告菌株8004/pL3814sac。利用转座子EZ::Tn5对报告菌株的基因组进行随机诱变, 分离到3株耐蔗糖的突变体。分析发现其中的1株突变体是由EZ::Tn5插入到编号为XC3882的未知功能的基因所产生的。将由XC3814启动子与报告基因gusA融合得到的报告质粒pGUS3814分别导入8004菌株和XC3882的转座子Tn5gusA5插入突变体, 测定比较pGUS3814的GUS表达水平, 结果显示在XC3882突变体背景下GUS的表达水平比在野生型背景下降低81.3%, 表明XC3814基因的表达水平受XC3882基因的影响。     

稻瘟病菌中甘油激酶基因在碳源代谢途径中的功能分析

作为引起水稻病害的主要病菌之一,稻瘟病菌是一种重要的模式生物,对于研究植物与病原菌之间的互作起着极其重要的作用。甘油激酶在体内可以催化甘油转化为甘油3-磷酸,对甘油的分解代谢起着重要的作用。在稻瘟病菌基因组中有两个编码甘油激酶的基因,分别为Mogly1和Mogly2。我们通过体内同源重组的基因敲除技术,获得两个基因的基因缺失突变体ΔMogly1和ΔMogly2,以及两个基因的双敲突变体ΔMogly1ΔMogly2。表型分析发现这些突变体在生长,产孢,致病性等方面相对于野生型均没有明显变化,但是ΔMogly1和ΔMogly1ΔMogly2在完全培养基上面的气生菌丝减少,菌落颜色变白。通过测量这些突变体在不同碳源培养基上的生长,发现ΔMogly1和ΔMogly1ΔMogly2在以山梨醇、葡萄糖、甘油和蔗糖为唯一碳源的培养基上生长速率均减慢。而在以甘油为唯一碳源的培养基上生长速度被抑制的最为显著。这说明Mogly1和Mogly2在碳源代谢中的作用是不同的,Mogly1基因可能在碳源代谢中扮演着重要的角色,而Mogly2可能是功能冗余的基因。     

niaD基因与uidA基因共转化糖化酶高产菌株Aspergillus niger T21

从AspergillusnigerT21分离到自发性的氯酸盐抗性株,再经氮源生长试验获得硝酸盐还原酶缺陷的niaD突变体N44。用含有niaD的质粒pSTA10转化N44,转化频率为5个／μg（转化子／DNA）。转化子的Southern印迹分析表明niaD基因同源整合到N44的染色体DNA中。pSTA10与含葡糖苷酸酶基因（uidA）的质粒pNOM102共转化N44,共转化频率为40％。共转化子的GUS（葡糖苷酸酶）活力测定结果表明uidA基因已在N44中表达。由此可知,以niaD为选择标记,uidA为报告基因,以N44为受体的转化系统可用于丝状真菌启动子功能检测和已知调控序列的功能分析。     

过氧化物酶体增殖剂对稻瘟病菌生长发育及致病性的影响

【目的】探索过氧化物酶体增殖剂(Peroxisome proliferators,PPs)对稻瘟病菌生长发育及致病性的影响。【方法】在6种不同的PPs诱导下,观察比较稻瘟病菌过氧化物酶体数量及相关基因表达、生长速率、孢子萌发、附着胞形成与致病性的差异。【结果】在不同的PPs诱导下,稻瘟病菌过氧化物酶体数量均呈现明显的增加,同时过氧化物酶体形成相关基因PEX8、PEX11、PEX14的表达量升高;PPs影响病菌菌丝生长、分生孢子萌发及附着孢形成,并导致致病性的减弱。其中,2,4-D与阿司匹林的抑制效果最为显著。同时,2,4-D与ASA对稻瘟病菌过氧化物酶体形成突变体Δpex5和Δpex7的生长抑制效果与野生菌株相比明显增加。【结论】首次将PPs类化合物用于模式丝状病原真菌稻瘟病菌的研究。研究发现6种PPs均能够引起过氧化物酶体的增殖,并可抑制稻瘟病菌生长发育,降低致病性。     

苹果树腐烂病菌细胞色素P450基因Vmcyp5的功能

【目的】研究表明,细胞色素P450(CYP)在死体营养型真菌的毒素合成代谢中发挥重要作用,预测可能与病原菌致病相关。论文对苹果树腐烂病菌(Valsa mali)毒素合成基因簇中的1个上调表达的CYP基因Vmcyp5进行生物学功能研究,明确CYP基因对病原菌致病力影响,为细胞色素P450基因家族对苹果树腐烂病菌致病机理的进一步研究提供依据。【方法】通过Double-joint PCR和PEG介导的原生质体转化技术获得具有G418抗性的突变体,并对突变体进行PCR检测及Southern blotting验证得到单拷贝敲除突变体。将目的基因片段重新导入敲除突变体,筛选获得互补突变体。最终对野生型菌株及敲除突变体、互补突变体进行菌落、产孢及致病力观察,利用SPSS软件对数据进行差异显著性分析,并利用q RT-PCR技术分析突变体黑色素基因簇的表达水平。【结果】通过基因敲除技术获得1个Vmcyp5基因的敲除突变体。与野生型菌株相比,Vmcyp5基因的敲除突变体菌落呈白色,产孢量减少51.3%。q RT-PCR分析发现敲除突变体黑色素基因簇基因表达量降低。重要的是,敲除突变体致病力较野生型菌株降低24.5%。互补突变体菌落颜色、产孢及致病力近似恢复至野生型菌株水平。【结论】Vmcyp5基因与病原菌黑色素合成、子实体的产生和致病力相关。     

一种有效的嗜热真菌杜邦嗜热菌靶向基因替代系统

以嗜热真菌杜邦嗜热菌Thermomyces dupontii NRRL 2155为研究材料,利用同源重组原理和真菌原生质体转化方法,以潮霉素抗性基因替换嗜热真菌目标基因,获得抗潮霉素的靶向基因敲除突变菌株。优化的遗传转化体系为：用15mg/mL裂解酶,在28℃下酶解2g杜邦嗜热菌菌丝5.5h以获得原生质体,经STC缓冲液洗涤重悬后,利用PEG（polyethylene glycol）介导的遗传转化方式,将10μg线性敲除全长片段转化至杜邦嗜热菌原生质体中,通过潮霉素筛选及PCR验证得到基因替换突变菌株,同源重组率达到20%。本研究首次将原生质体转化方法应用在杜邦嗜热菌,并成功建立稳定高效的基因替换体系,为快速构建杜邦嗜热菌的遗传转化体系和研究该嗜热真菌的基因功能提供有效方法。     

The GUS gene fusion system (Escherichia coli beta-D-glucuronidase gene), a useful tool in studies of root colonization by Fusarium oxysporum.

The plant-pathogenic fungus Fusarium oxysporum was successfully transformed with the beta-D-glucuronidase gene from Escherichia coli (gusA) (GUS system) in combination with the gene for nitrate reductase (niaD) as the selectable marker. The frequency of cotransformation, as determined by GUS expression on plates containing medium supplemented with 5-bromo-4-chloro-3-indolyl glucuronide (GUS+), was very high (up to 75%). Southern hybridization analyses of GUS+ transformants revealed that single or multiple copies of the gusA gene were integrated into the genomes. High levels of GUS activity are expressed in some transformants, but activity in F. oxysporum does not appear to be correlated with the copy number of the gusA gene. Since the highest activity was found in a transformant with a single copy, it can be assumed that sequence elements of F. oxysporum integrated upstream of the gene can act as a promoter or enhancer. Expression of the gusA gene was also detected during growth of the fungus in plants, indicating that the GUS system can be used as a sensitive and easy reporter gene assay in F. oxysporum.     

Transformation of Montmorency sour cherry (Prunus cerasus L.) and Gisela 6 (P. cerasus × P. canescens) cherry rootstock mediated by Agrobacterium tumefaciens

Sour cherry (Prunus cerasus L.) scion cv. Montmorency and rootstock cv. Gisela 6 (P. cerasus x P. canescens) were transformed using Agrobacterium tumefaciens strain EHA105:pBISN1 carrying the neomycin phosphotransferase gene (nptII) and an intron interrupted ss-glucuronidase (GUS) reporter gene (gusA). Whole leaf explants were co-cultivated with A. tumefaciens, and selection and regeneration of transformed cells and shoots of both cultivars was carried out for 12 weeks on selection medium containing 50 mg l(-1) kanamycin (Km) and 250 mg l(-1) timentin. These media were [Quoirin and Lepoivre (Acta Hortic 78:437-442, 1977)] supplemented with 0.5 mg l(-1) benzylaminopurine (BA) + 0.05 mg l(-1) indole-3-butyric acid (IBA), and woody plant medium [Lloyd and McCown (Proc Int Plant Prop Soc 30:421-427, 1980)] containing 2.0 mg l(-1) BA + 1.0 mg l(-1) IBA for cv. Montmorency and cv. Gisela 6, respectively. Seven out of 226 (3.1%) explants of cv. Montmorency and five out of 152 (3.9%) explants of cv. Gisela 6 produced 30/39 GUS- and PCR-positive shoots from the cut midribs via an intermediate callus. Southern analysis of the GUS- and PCR-positive transformants confirmed stable integration of the transgenes with 1-3 copy numbers in the genomes of seven lines of cv. Montmorency and five of cv. Gisela 6. The selected transformants have a normal phenotype in vitro.     

Transformation of Aspergillus sp. and Trichoderma reesei using the pyrithiamine resistance gene (ptrA) of Aspergillus oryzae

A pyrithiamine (PT) resistance gene (ptrA) was cloned from a PT resistant mutant of Aspergillus oryzae and was useful as a dominant selectable marker for transformation of all A. oryzae wild type strain as well as A. nidulans. For further study, we examined whether or not ptrA could be used as the transformation marker in other species of filamentous fungi. Two types of plasmid, which contain ptrA as a selectable marker, were constructed, and the transformation experiments were done with them. One is an integrative plasmid, pPTRI, and another is the autonomously replicating plasmid pPTRII, which contains AMA1. PT-resistant transformants were obtained in the cases of A. kawachii, A. terreus, A. fumigatus, and Trichoderma reesei as hosts with pPTRI and pPTRII. Furthermore, a beta-glucuronidase (GUS) gene was introduced into A. kawachii and A. fumigatus using pPTRII. Almost all the transformants turned blue on GUS assay plates. These results indicate that ptrA can also be used for some other filamentous fungi besides A. oryzae and A. nidulans.     

农杆菌介导的玉米遗传转化

Several maize inbreds were transformed with Agrobacterium tumefaciens EHA101 (pGIH). Transgenic maize plants were obtained. Frequency of transformation of maize inbred Suyu No. 1 can reach 8.1%. Results of PCR and Southern blot analysis proved that T-DNA was stably integrated into the genome of maize. Staining with X-gluc confirmed the expression of GUS gene in maize cells. The band amplified by inverse PCR showed that the copy number of transgene in three transformants was single. After long term of subculture, some hygromycin resistant calli lost their regeneration ability. Although Southern blot probed the integration of gusA gene in their genome, GUS activity cannot be detected in those calli. Southern blot analysis of HpaII digest DNA showed that transgenic gusA gene was highly methylated.     

Agrobacterium tumefaciens-mediated transformation of the plant pathogenic fungus, Magnaporthe grisea.

An effective way to study the infection mechanisms of fungal pathogens is to disrupt their genes via transformation in both targeted and random manners. This isolates the mutants that exhibit altered virulence. In this paper, we report the successful transformation of Magnaporthe grisea, the causal agent for rice blast, that is mediated by Agrobacterium tumefaciens. Employing the binary vector pBHt2, which carries the bacterial hygromycin B phosphotransferase gene under the control of the Aspergillus nidulans trpC promoter as a selectable marker, led to the production of 500 to > 1,000 hygromycin B-resistant transformants per 1 x 10(6) conidia of M. grisea. The transformation efficiency is correlated with the number of A. tumefaciens cells used, pre-treating bacterial cells with acetosyringone prior to co-cultivation with fungal spores, and the duration of co-cultivation. All of the transformants tested remained mitotically stable, maintaining their hygromycin B resistance after several generations of growth in the absence of hygromycin B. A genomic Southern blot analysis showed that over 60% of the transformants contained a single T-DNA insert on their genome. Considering the efficiency and flexibility of A. tumefaciens-mediated transformation (ATMT), this technique offers highly efficient means for characterizing the genes that are important for the pathogenicity of M. grisea.     

Agrobacterium -mediated transformation of embryogenic cell suspensions of the banana cultivar Rasthali (AAB)

 A protocol was developed for establishing embryogenic suspension cultures from in vitro-grown, thin shoot-tip sections of the banana cultivar Rasthali. The best medium for callus induction was an MS-based medium supplemented with 2 mg/l 2,4-D and 0.2 mg/l zeatin. The callus was transferred to liquid medium to establish embryogenic cell suspensions. These cultures were subsequently used for Agrobacterium-mediated transformation. The Agrobacterium tumefaciens strain EHA105 containing the binary vector pVGSUN with the als gene as a selectable marker and an intron-containing the gusA gene as a reporter gene was used for transformations. The herbicide Glean was used as a selection agent. Two hundred putative transformants were recovered, of which a set of 16 was tested by histochemical analysis for GUS expression and by Southern blot analysis with a probe for the gusA gene. The plants were positive for GUS expression and integration of the gusA gene. Two of the transformants were grown to maturity under greenhouse conditions. Bananas were harvested to test GUS expression by histochemical analysis. The fruit from both transgenics tested positive for GUS expression. Received: 22 February 2000 / Revision received: 2 October 2000 / Accepted: 5 October 2000