烟草抗黑胫病突变体的细胞筛选

经实验我们成功地建立了在细胞水平上筛选烟草抗黑胫病突变体的筛选体系。该体系的主要内容为:γ-射线500—2000拉德诱变高度感病品种的花药后用50—80％的黑胫病菌粗毒素为选择压力,筛选出抗毒素花粉植株,用离体叶片法测定选出抗病植株,再从后代鉴定中选出抗病性能够稳定遗传的突变系。γ-射线及高浓度毒素处理均能得到抗病植株。选自感病品种的花粉植株中约有9—50％是真正抗病的。这些抗病植株中有一部分的抗病性能够稳定遗传。用该法已从感病优质品种小黄金1025及乔庄黑苗中选出6个突变系。并自N.C.628(抗)×小黄金1025(感)及N.C.628(抗)×庆胜2号(感)的F_1花粉植株中选出4个抗病系。所有的抗病系经3—4代后均表现出稳定抗性。其中一个突变体(R400)的抗性似由不完全显性多基因控制。     

诱发玉米抗小斑病突变体的研究——Ⅳ.从玉米单倍体胚性细胞无性系筛选抗玉米小斑病突变体

将经γ射线和EMS诱变处理的玉米八趟白单倍体胚性细胞无性系为试验材料,以玉米小斑病菌Helminthosporium maydis单胞系342号菌株产生的致病毒素为选择剂,采用正选择法进行筛选,已获得抗玉米小斑病的突梦体。这个突变体脱离选择剂5代(5个月)后性状稳定,用小斑病菌的分生孢于直接接种鉴定仍具有很强的抗病力。过氧化物酶同工酶的分析,抗病突变体与不抗病对照间出现明显差异。     

通过组织培养筛选小麦抗赤霉病突变体的研究

选用中抗赤霉病的春小麦品种和品系的花药进行离体培养,以小麦赤霉病29号菌株产生的致病培养滤液为选择剂,结合物理诱变处理,进行抗病鉴定,用赤霉病菌分生孢子直接接种在愈伤组织和再生植株筛选抗病突变体。在83块愈伤中有53块抗病。在11株的再生植株中有9株均比未经培养滤液处理的对照提高了抗病性,从中选出4株抗病性接近或超过“苏麦3号”品种。     

辽宁地区水稻资源抗稻瘟病基因的检测分析

为了明确辽宁地区水稻资源中抗稻瘟病基因的分布情况及抗病效应,选取辽宁地区水稻资源176份,鉴定了抗稻瘟病基因pi21、Pi36、Pi37、Pita、Pid2、Pid3、Pi5及Pib在这些材料中的分布情况,并接种鉴定了这些材料对稻瘟病的抗性。结果表明:176份供试材料中,83份对稻瘟病表现抗病,栽培稻、杂草稻及农家种中抗病品种所占的比率分别为41.48%、1.14%及4.54%。抗稻瘟病基因pi21、Pi36和Pi37在所有参试材料中均未检测到,且分别有74份、49份、47份、52份及89份材料携带Pita、Pid2、Pid3、Pi5及Pib的抗病等位基因。抗病基因绝大部分分布在栽培种中,农家种和杂草稻中分布较少。不含有抗稻瘟病基因和只携带单个抗病基因的材料对稻瘟病的抗性均较差,而抗病基因聚合可不同程度提高材料的抗性。经检测,不含有本试验鉴定的pi21等8个已克隆抗病基因的材料共32份,其中表现抗病的占21.87%;只携带1个抗稻瘟病基因的材料为52份,表现抗病的占17.31%;携带2个抗稻瘟病基因的材料为39份,表现抗病的占69.23%,其中以携带Pita+Pi5的材料最多(14份),且均表现抗病;携带3个抗稻瘟病基因的材料为31份,表现抗病的占77.42%,以携带Pita+Pid3+Pi5的材料抗性最强;携带4个抗稻瘟病基因的水稻材料22份,表现抗病的占72.73%,携带5个抗病基因的水稻材料未检测到。     

湖南桃江病圃稻瘟病菌的无毒基因及水稻抗瘟单基因联合抗性分析

【目的】鉴定湖南省桃江病圃稻瘟病菌无毒基因型,为合理搭配种植湖南省水稻抗瘟品种和抗病育种提供依据。【方法】在湖南桃江病圃采集水稻品种"丽江新团黑谷"(LTH)稻瘟菌病样,用单孢分离法分离稻瘟病菌单孢并纯化获得单孢菌株,用针刺离体法将菌株接种到以"LTH"为轮回亲本培育而成的24个含单抗瘟基因的水稻5叶期第5叶片上,对供试菌株进行无毒基因鉴定,并应用联合致病性系数和联合抗病性系数分析抗瘟基因组合间的互作。【结果】供试92个稻瘟病单孢菌株含有全部的24个无毒基因,对24个已知含单抗瘟基因的水稻材料表现出不同程度的毒力水平,含水稻抗瘟基因Pi-20对供试菌株抗菌频率最高,达54.35%;通过联合致病性系数和联合抗病性系数分析抗瘟基因组合间的互作,结果表明最佳搭配组合为Pi-20×Pi-k~s(RAC=0.28,PAC=0.23)。【结论】湖南省桃江病圃稻瘟病菌致病力较强,24个抗瘟基因多已感病化,含抗性基因Pi-20与Pi-k、Pi-k~s、Pi-3组合的水稻品种目前可在湖南省推广利用,但需研究引进新的抗瘟基因。     

广东高州普通野生稻稻瘟病抗性鉴定

在苗期采用人工接种稻瘟病混合菌株对108份高州普通野生稻样本进行了稻瘟病抗性鉴定,经过初鉴和复鉴,筛选出抗级为2—3级的抗病样本3份;利用我国稻瘟病菌5个菌群7个生理小种22个菌株对初鉴表现中抗的2份种茎样本B35和C1的各2个F1单株进行苗期抗谱测定,获得全群抗性频率分别达到86．36％和81．82％的材料各1份。本鉴定结果可供高州野生稻资源的进一步深入研究和开发利用参考。     

运用植物毒素离体筛选水稻抗胡麻叶斑病种质的研究

以胡麻叶斑病病原菌的毒素配制的培养基,培养水稻的体细胞愈伤组织,在其再分化第一代(R_1)植株群体中,发现3株(其中IR_5 2株经25％毒素处理,IR_(54) 1株未经毒素处理)抗胡麻叶斑病的突变。在这3个抗性系统的R_2(R_2植株的种子后代)群体中,均观察到对胡麻叶斑病病原菌的敏感与抗性的分离。本文是以植物毒素作为筛选因子,运用组织培养技术,在水稻上成功地筛选出抗病植株的首次报道。     

‘巴斗’杏再生体系的建立与耐盐突变体的筛选

以‘巴斗’杏试管苗茎段为外植体,研究其再生体系的建立以及在含不同浓度NaCl培养基上诱导耐盐愈伤组织,筛选耐盐突变体。结果显示：茎段在MS＋6-BA1．5mg·L^-1＋IBA0．5mg·L^-1培养基上诱导愈伤组织效果最好,芽的分化率可达88％;将出芽愈伤组织块接种到附加IBA0．5mg·L^-1＋KT2．0mg·L^-1的MS分化培养基上效果最佳,芽的分化系数最高为12．7;较理想的生根培养基为MS＋NAA0．1mg·L^-1。＋IBA0．2mg·L^-1,生根率在46．3％以上;在含0．8％NaCl的愈伤组织诱导培养基中,连续继代筛选2代,转入不含NaCl的分化培养基中,分化出了完整植株。经继代培养筛选,测定发现获得的耐盐植株比正常培养植株的游离脯氨酸含量高。     

利用马铃薯晚疫病菌粗毒素离体筛选马铃薯抗晚疫病无性系

以3个马铃薯品种叶片外植体的愈伤组织为材料、马铃薯晚疫病病菌培养粗毒素为筛选压力进行马铃薯抗晚疫病细胞变异无性系筛选。结果表明,不同品种的叶片、愈伤组织对毒素有不同的忍耐力。“费乌瑞它”最大忍耐的粗毒素浓度为40％,“东农303”、“早大白”则为50％。马铃薯晚疫病病原菌粗毒素对愈伤组织的诱导、生长、不定芽的分化及再生苗生根有显著的抑制作用,而且浓度越大,抑制作用越强。筛选结果抗性鉴定表明,经过粗毒素筛选的细胞无性系及其再生植株对高浓度粗毒素的抗性能力显著高于对照。     

离体筛选抗枯萎病辣椒新种质

以2个辣椒(Capsicum annuum L.)自交系子叶诱导产生的愈伤组织为材料,辣椒枯萎菌粗毒素为选择剂,筛选抗枯萎病辣椒新种质.结果表明,枯萎菌粗毒素对辣椒子叶愈伤组织诱导、生长及不定芽分化具有明显的抑制作用,且随着粗毒素浓度的增加,抑制作用增强;在枯萎菌粗毒素质量浓度为0.60 g·L-1条件下,筛选、鉴定并获得了抗枯萎病辣椒体细胞变异无性系,且成功再生抗性植株.从而证明,离体筛选抗枯萎病辣椒新种质的方法是可行的.     

药用野生稻TAC克隆转化籼稻的体系初探

采用已构建的药用野生稻TAC文库,比较研究4个籼稻品种在不同培养基的诱导率及愈伤组织对潮霉素抗性。通过2种不同诱导方法产生的愈伤组织,将携带药用野生稻大片段DNA的TAC克隆转化到籼稻品种中的结果表明,除了‘粤香占’以外,其它3个品种在心诱导培养基中添加微量B,后,其愈伤诱导率最高。不同品种的潮霉素筛选适合浓度存在差异,其中‘华粳籼74’的适合筛选浓度为50mg．L-1,‘粤香占’为40mg．L-1。用预培养5d的愈伤组织进行遗传转化,在潮霉素筛选之前先以头孢拉定抑菌处理的,容易获得转基因植株。4个品种中以‘粤香占’的抗性愈伤组织筛选率和分化率最高,分别为22．58％和14．86％。分子检测11株转基因水稻的结果表明,其中8株含有抗性标记基因。据此认为,药用野生稻TAC文库在水稻创新育种中可能有一定的利用前景。     

多年生黑麦草成熟胚再生体系的建立及基因枪转化

目的:建立以多年生黑麦草成熟胚为起始材料的再生体系,用于基因枪转化。方法:多年生黑麦草成熟种子在附加 5mg L 2,4 D的MS培养基上诱导愈伤组织,转至新继代培养基上产生胚性愈伤组织。分化培养基为无激素MS培养基。再生植株在培养基成分减半的无激素MS培养基生根,之后移栽至土壤。基于这一再生体系,用含有水稻几丁质酶基因RC2 4的质粒pARN6和含有草丁膦乙酰转移酶基因Bar的质粒pDB1,通过基因枪轰击胚性愈伤组织。用附加PPT的继代培养基进行转化植株的抗性筛选。结果:共获得 2 4 3株再生植株。通过PCR进行检测,获得1 8株整合有RC2 4基因的植株,1 5株整合有Bar基因的植株,同时转入 2个基因的植株 2株。     

表达反义核酶RNA的转基因水稻对矮缩病毒复制和症状的抑制作用

用基因枪法将含有ＲＤＶ第五片段反义核酶序列基因的植物表达载体ｐＲＯＫＩＩ转化水稻幼胚,在Ｇ４１８存在的条件下,约２～３个月可筛选出抗性愈伤,转入分化培养基中培养可分化出幼苗。经Ｓｏｕｔｈｅｒｎ杂交法检测为阳性的水稻幼苗进行抗病性测定显示,转ＲＤＶ反义核酶基因的水稻植株对ＲＤＶ的复制和症状有显著抑制作用。转基因植株发病较轻,并能部分结实,而对照植株则明显矮化且大多不能抽穗。     

Improvement of rice transformation using bombardment of scutellum-derived calli

Although several reports on rice transformation have been published, producing transgenic plants ofIndica rice varieties is still problematic. We report an improved protocol for transformingIndica rice genotypes. An important agronomic MexicanIndica rice variety, Morelos A-92, was used. Calli derived from scutellum seeds were produced by using auxins and bombarded with 2 vectors, one harboring the reporteruidA gene and the other with thehptII gene conferring hygromycin resistance. The influence of the molar relation of these vectors (uidA-hptIII) in generating callus and plants expressing theuidA reporter gene was analyzed. Selection of bombarded calli was performed under 2 conditions: 50 mg/L of hygromycin with 3 subcultures and 80 mg/L of hygromycin with no subcultures. The best conditions were a 20∶1uidA-hptII molar vector relationship and selection at 80 mg/L of hygromycin, producing 14% of calli expressing GUS. The minimal callus size in regenerating plants was 3 mm. Transformed rice plants were generated with 4.6% efficiency, considering the initial number of bombarded calli. Heredity of theuidA gene behaved as a single locus in transformed rice plants. Homozygous plants were identified in the T₁ generation by means of pollen staining.     

Identification of rice genes induced in a rice blast-resistant mutant

To clarify mechanisms of rice blast resistance in rice plants we used suppression subtractive hybridization (SSH) to isolate genes induced upon rice blast inoculation in a rice blast-resistant mutant. A total of 26 rice cDNAs were isolated and found to have elevated expression upon rice blast infection in a rice blast-resistant derivative, SHM-11, of the rice cultivar, Sanghaehyanghyella. Sequencing of the cDNAs revealed that many of the proteins they encoded had been previously described as involved in plant responses against pathogen attack. Two interesting groups of the defense-related proteins consisted of three different PR5 homologues and four different protease inhibitors, all highly expressed in the rice blast mutant. Genes encoding proteins involved in signal transduction and regulation were also identified, including translation initiation factor eIF5A, C2 domain DNA binding protein, putative rice EDS and putative receptor like kinase. Most of the identified cDNAs were highly expressed 24 h after blast inoculation. Our results suggest that a pathway regulating defense gene expression may be altered in the mutant, resulting in early induction of the defense genes upon fungal infection.     

Agrobacterium tumefaciens－mediated transformation of rice with the spider insecticidal gene conferring resistance to leaffolder and striped stem borer

Immature embryos of rice varieties "Xiushuill" and "Chunjiang 11" precultured for 4d were infected and transformed by Agrobacterium tumefaciens strain EHA101/pExT7 (containing the spider insecticidal gene). The resistant calli were transferred onto the differentiation medium and plants were regenerated. The transformation frequency reached 56% approximately 72% measured as numbers of Geneticin (G418)-resistant calli produced and 36% approximately 60% measured as numbers of transgenic plants regenerated, respectively. PCR and Southern blot analysis of transgenic plants confirmed that the T-DNA had been integrated into the rice genome. Insect bioassays using T1 transgenic plants indicated that the mortality of the leaffolder (Cnaphalocrasis medinalis) after 7d of leaf feeding reached 38% approximately 61% and the corrected mortality of the striped stem borer (Chilo suppressalis) after 7d of leaf feeding reached 16% approximately 75%. The insect bioassay results demonstrated that the transgenic plants expressing the spider insecticidal protein conferred enhanced resistance to these pests.     

Plant regeneration from in vitro cultures of anthers and mature seeds of rice (Oryza sativa L.) cv. Basmati-370

Pollen plants were obtained from anther-derived calli of the indica rice variety Basmati-370. Anther-response (anthers producing pollen derived calli) and plant regeneration frequency from the pollen derived calli. was very low. Donor plants which flowered at the average max/min. temperature of 34.2°/23.3°C gave a significantly higher anther-response to in vitro techniques, than did those which flowered at 29.1°/16.4°C. Somatic callus induction and subsequent plant regeneration was readily obtained from mature seed embryos. While 2,4-D or 2,4,5-T (1 or 2 mg/l) proved highly efficient for callus induction, tryptophan (50 or 100 mg/l) induced a high frequency of green plants from the calli.Abbreviations 2,4-D 2,4-dichlorophenoxyacetic acid - 2,4,5-T 2,4,5-trichlorophenoxyacetic acid - NAA naphthaleneacetic acid - IAA indoleacetic acid - K kinetin - BA benzyladenine - Trp tryptophan - CW coconut water     

A procedure for regenerating Japonica and Indica varieties of rice from protoplasts

Fertile rice plants have been regenerated from protoplasts of two japonica rice varieties (Radon and Baldo) using a protocol initially developed for plant regeneration from protoplasts of an indica rice. Embryogenic calli were developed from immature embryos of Radon and Baldo rice on a callus induction medium, and then used to establish cell suspensions. Protoplasts were isolated from the cell suspensions, and cultured on a Millipore filter placed on a Kao/agarose medium that contained cell clusters from suspensions of IR52 or IR45. The protoplasts grew vigorously on Kao medium and developed into embryogenic calli within two to three weeks. Somatic embryo development occurred during a subsequent transfer of the calli to an LS medium for two to three weeks. The calli were then transferred to MS or N6 plant regeneration medium, and within one to three weeks, plants regenerated from 21 to 32% of the Radon calli, and 33 to 35% of the Baldo calli. Based upon these results and the previous success in regenerating an indica variety from protoplasts, this procedure has great promise for regenerating a range of rice varieties, and probably for regeneration of other monocotyledonous plants from protoplasts     

Oryzacystatin Exogenously Introduced into Protoplasts and Regeneration of Transgenic Rice

Oryzacystatin (OC) is a proteinaceous cysteine proteinase inhibitor involved in the biodefense of rice seeds. To create transgenic rice plants with increased OC activity, we introduced an OC expressing vector into rice protoplasts and obtained transformed calli. The expression vector contained a bacterial inaA DNA fragment in the 3′-noncoding region as a tag to distinguish the introduced DNA from the intrinsic OC gene. The OC vector and a selection marker gene conferring hygromycin resistance were used together to transfect into rice protoplasts. A number of hygromycin-resistant calli were obtained and studied by polymerase chain reaction and genomic Southern blotting to find if the exogenous OC gene had been integrated. The calli were studied by northern blotting as well to examine mRNA expression. The results showed that integration and expression of the introduced OC gene occurred in 51% and 27%, respectively, of 156 subcultures from 15 hygromycin-resistant calli. As a final step, transgenic rice plants were regenerated from the calli expressing OC. Leaves and seeds from the plants had higher OC activities than those from nontransgenic plants.     

Transformation of cotton (Gossypium hirsutum L.) by Agrobacterium tumefaciens and regeneration of transgenic plants

Cotton (Gossypium hirsutum L.) cotyledon tissues have been efficiently transformed and plants have been regenerated. Cotyledon pieces from 12-day-old aseptically germinated seedlings were inoculated with Agrobacterium tumefaciens strains containing avirulent Ti (tumor-inducing) plasmids with a chimeric gene encoding kanamycin resistance. After three days cocultivation, the cotyledon pieces were placed on a callus initiation medium containing kanamycin for selection. High frequencies of transformed kanamycin-resistant calli were produced, more than 80% of which were induced to form somatic embryos. Somatic embryos were germinated, and plants were regenerated and transferred to soil. Transformation was confirmed by opine production, kanamycin resistance, immunoassay, and DNA blot hybridization. This process for producing transgenic cotton plants facilitates transfer of genes of economic importance to cotton.