具ACC脱氨酶活性大豆根瘤内生菌的筛选、抗性及促生作用北大核心CSCD

【目的】从大豆根瘤中筛选具ACC(1-氨基环丙烷-1-羧基)脱氨酶活性的内生细菌,对活性菌株的抗盐碱性、系统分类地位以及代表菌株的促生长作用进行研究,为发掘和应用抗逆、促生优良菌种资源提供理论基础。【方法】以ACC作为唯一氮源测定菌株产ACC脱氨酶特性,采用标准曲线法测定α-丁酮酸含量,比色法定量测定ACC脱氨酶活力,固体平板筛选法对活性菌株进行抗性分析,通过菌体形态及生理生化特性测定、16S rRNA基因序列同源性分析鉴定菌株分类地位,采用盆栽试验验证代表菌株的促生作用。【结果】从河南省13个市(地区)36个点采集的大豆根瘤中筛选出8株ACC脱氨酶内生细菌,其中菌株DD132的酶活性最高(15.712 U/mg)。筛选菌株可耐受4%–6%NaCl,其中菌株DD165、DD132可耐受9%NaCl盐浓度。在pH 11时5株(DD14、DD132、DD67、DD141、DD131)生长良好,说明这些菌株有较强耐碱性。8株产ACC脱氨酶菌株分属于4属,即芽孢杆菌属(Bacillus)、肠杆菌属(Enterobacter)、寡养单胞菌属(Stenotrophomonas)和泛菌属(Pantoea)。接种试验表明内生菌DD132对小麦幼苗生长具有明显促生长作用。【结论】大豆根瘤内具ACC脱氨酶高活性菌株有较强耐盐碱性,其中菌株DD132对小麦幼苗生长有明显促生长作用。为发掘和应用抗逆、促生的优良菌种资源提供理论基础。     

具有ACC脱氨酶活性的绞股蓝内生细菌的分离鉴定及其抑菌促生作用

采用富集筛选法从绞股蓝根中筛选得到6株具有ACC脱氨活性的细菌,其中菌株JDG-6、JDG-7、JDG-14、JDG-16、JDG-23均具有较强的分泌铁载体能力,但菌株JDG-32没有产铁载体能力。抑菌试验结果显示,菌株JDG-6、JDG-7、JDG-14和JDG16对一种或多种供试菌有抑菌作用,其中菌株JDG-14能抑制大肠埃希菌、藤黄八叠球菌和白色念球菌的生长。促生试验表明,菌株JDG-6、JDG-7和JDG-14均能促进水稻幼苗根的伸长,其中菌株JDG-14的促生作用最为明显,与对照组相比水稻幼苗的根长和根鲜重分别增长了26%和21%。通过形态特征观察、生理生化试验以及16S rDNA序列分析,菌株JDG-6、JDG-7、JDG-16和JDG-23属于假单胞杆菌属（Pseudomonas）,菌株JDG-14为木糖葡萄球菌（Staphylococcus xylosus）,而菌株JDG-32为枯草芽胞杆菌（Bacillus subtilis）。菌株JDG-6、JDG-7和JDG-14均具有ACC脱氨酶活性和抑菌活性的促生菌,具有农业应用潜力。     

芽孢杆菌对桉树幼苗的促生效果及其ACC脱氨酶活性的研究

【目的】筛选出能显著促进桉树幼苗生长的芽孢杆菌菌株,探究酶活性与桉树幼苗生长的相关性,初步揭示芽孢杆菌对桉树幼苗的促生机制。【方法】以分离自广东广州、阳江桉树林地土壤的32个芽孢杆菌菌株为研究对象,测定桉树幼苗接种盆栽试验以及菌株ACC脱氨酶活性与幼苗N、P养分。【结果】接种菌株2306、2403、2301能够显著促进桉树幼苗高生长和生物量积累,尤以菌株2306的促生效果最佳,其苗高、生物量分别比对照增加53.1%和190.2%。【结论】芽孢杆菌的ACC脱氨酶活性与桉树幼苗高生长相关极显著,与生物量相关显著;而且上述3个菌株均能提高桉树幼苗的N、P含量。研究结果将进一步丰富桉树促生菌资源,促进桉树微生物肥料的开发。     

攀枝花市麻疯树根际土壤内生菌根菌分布特征

【目的】研究天然麻疯树根际土壤中内生菌根菌孢子果密度,揭示麻疯树根际土壤中内生菌根菌的分布特征,为麻疯树育苗繁殖和栽植推广提供科学依据。【方法】采用随机采样的方法对攀枝花市仁和区天然麻疯树根际土壤中内生菌根菌孢子果数量进行调查,确定了20个采样点,采集了20个土根混合样,利用解剖镜测定其孢子果密度,再根据1999年林业行标测定样品中的水分含量,养分含量等。【结果】天然麻疯树根际土壤采样从海拔1025m开始,直到1500m。土壤样品中均含有AM菌根菌孢子果,且数量丰富的,含量最高的土壤样品中AM菌根菌孢子果密度为236个/g干土,最小的密度为9个/g干土,平均密度为80个/g干土。土样含水量在4.01%-13.39%之间,平均值为6.79%,与AM菌根菌孢子果含量正相关。有机质平均含量为3.80g/kg,与AM菌根菌孢子果含量正相关。【结论】天然麻疯树根际土壤中均能检测出AM菌根菌孢子果,且含量高,但分布不均。它的密度随着海拔高度的升高逐渐降低,随土壤含水量的增加而增加,随土壤有机质含量的增加而增加。     

麻疯树根的化学成分研究

从麻疯树（Ｊａｔｒｏｐｈａ ｃｕｒｃａｓ Ｌ．）的根中分离到１３ 个化合物,经理化常数和波谱鉴定（ＩＲ、１Ｈ－ＮＭＲ、１３Ｃ－ＮＭＲ、ＥＩＭＳ和ＦＡＢＭＳ）分别为∶５α－豆甾烷－３,６－二酮（１）、川皮甙（２）、β－谷甾醇（３）、蒲公英脑（４）、２Ｓ－正二十四饱和脂肪酸甘油酯－１（５）、５－羟基－６,７－二甲氧基香豆素（６）、麻疯树酚酮Ａ（７）、麻疯树酚酮Ｂ（８）、６－甲氧基－７－羟基香豆素（９）、ｃａｎｉｏｊａｎｅ （１０）、３－羟基－４－甲氧基－苯甲醛（１１）、３－甲氧基－４－羟基苯甲酸（１２）和胡萝卜甙（１３）． 其中,化合物５ 为未见报道的新化合物,化合物１、２、９、１０、１１、１２ 为首次从该植物中分得,１０ 为含有过氧基团的二萜化合物． ７ 和８ 为一对四环二萜的立体异构体,并在碱中相互转化     

石油污染土壤中植物根际促生菌的筛选及特性分析

以1-氨基环丙烷-1-羧酸(ACC)为唯一氮源,从黑龙江省大庆地区石油污染土壤的狼尾草根际土壤中分离筛选出2株产ACC脱氨酶的细菌,F4-1和F4-2。对分离的菌株进行生理生化和16S rDNA序列鉴定,确定F4-1为肠杆菌属(Enterobactersp.),F4-2为克雷伯菌属(Klebsiellasp.)。菌株F4-1的ACC脱氨酶活性为(1.40±0.17)μmolα-KA.(mg Pr.h)-1,高于F4-2的(1.03±0.03)μmolα-KA.(mg Pr.h)-1。随着L-Trp浓度的增加,菌株F4-1和F4-2的吲哚乙酸(IAA)合成量相应增加,总体上看F4-1的IAA合成能力高于F4-2。F4-1合成嗜铁素的能力也高于F4-2。     

ACC脱氨酶活性菌株ACC 30的分离、 鉴定及其促生作用

【目的】筛选具有1-氨基环丙烷-1-羧酸(简称ACC)脱氨酶活性的菌株,并探索该类菌的促生作用,有助于研发微生物肥料,实现农业增产。【方法】以ACC为唯一氮源,从土壤中富集和分离ACC脱氨酶产生菌;测定ACC脱氨酶的比活力,对酶活性最强的菌株根据形态和培养特征、生理生化特征及16S rDNA序列进行分类鉴定;分别采用菌液培养接种法与菌液浸种接种法初步研究该菌株对紫花苜蓿幼苗生长的促生作用。【结果】筛选得到6株ACC脱氨酶阳性细菌,其中菌株ACC 30酶活性最高,为0.217 U/mg,根据培养特征观察和生理生化指标测定结果,结合16S rDNA序列比对分析,确定ACC 30为产气肠杆菌(Enterobacter aerogenes)。促生试验表明,ACC 30可促进紫花苜蓿幼苗根伸长,菌液培养接种法与菌液浸种接种法两种处理方法下ACC 30分别使幼苗根相对伸长135%、136%,促生作用均明显且基本一致。但是,两种方法处理下ACC 30均抑制幼苗下胚轴伸长。【结论】筛选获得ACC脱氨酶活性菌株ACC 30,其酶活性较高且促生作用明显,有望进一步研发成为微生物肥料。     

具有ACC脱氨酶活性的细菌的分离和鉴定

在以ＡＣＣ（α－氨基环丙烷梭酸）为唯一氮源的选择性培养基上,对土壤来源的细菌菌株进行了筛选。通过生长测定、对ＡＣＣ降解的分析,确定了菌株ＡＣＣ脱氨酶的活性,并对菌株进行了系统鉴定。     

中华补血草内生与根际具ACC脱氨酶活性细菌的筛选及其生物多样性

【目的】获得江苏沿海滩涂盐生药用植物中华补血草内生及根际具有1-氨基环丙烷-1-羧酸(ACC)脱氨酶活性的细菌,研究其遗传多样性和潜在促生活性。【方法】从中华补血草和根际土壤分离筛选具有ACC脱氨酶活性的菌株,对其ACC脱氨酶活性定量检测,通过16S r RNA基因序列分析确定菌株系统发育地位。同时研究其固氮、溶磷、产植物生长素吲哚乙酸(IAA)及耐盐能力。【结果】分离筛选获得18株具有ACC脱氨酶活性的内生与根际细菌,定量检测发现其中有13株菌的ACC脱氨酶含量在20 nmolα-KA/(mg Pr·h)以上,有11株菌可以固氮,7株菌能够解磷,9株菌产生IAA。菌株的Na Cl盐耐受范围多数在0–13%之间。16S r RNA基因测序表明,活性菌株分属于7个属,多样性丰富,节杆菌属(Arthrobacter)为优势类群。其中菌株KLBMP 5180为节杆菌属的潜在新种。【结论】江苏沿海滩涂盐生药用植物中华补血草共生环境中具有丰富多样的具ACC脱氨酶活性的菌株,并存在潜在新物种资源,具有进一步研究价值。     

具有ACC脱氨酶活性的杜仲内生细菌的分离鉴定及其抗菌活性

采用富集筛选法从杜仲根中分离到5株具有ACC脱氨酶活性的内生细菌, 利用纸片法测定它们的抑菌活性, 通过形态特征、生理生化试验和16S rRNA序列分析对分离菌株进行鉴定。结果显示, 5株杜仲内生细菌均具有较高的ACC脱氨酶活性, 其中4株菌对大肠杆菌CGMCC1.1103和枯草芽孢杆菌CGMCC1.769均有较好的抑菌活性, 通过生理生化试验和16S rRNA序列分析, 将菌株JDM-2、JDM-8、JDM-11、JDM-14和JDM-19分别鉴定为Pseudomonas koreensis、肺炎克雷伯氏菌(Klebsiella pneumoniae)、路德维希肠杆菌(Enterobacter ludwigii)、变栖克雷伯氏菌(Klebsiella variicola)和阿氏肠杆菌(Enterobacter asburiae)。     

Perspective of plant growth promoting rhizobacteria (PGPR) containing ACC deaminase in stress agriculture

Ethylene is a gaseous plant growth hormone produced endogenously by almost all plants. It is also produced in soil through a variety of biotic and abiotic mechanisms, and plays a key role in inducing multifarious physiological changes in plants at molecular level. Apart from being a plant growth regulator, ethylene has also been established as a stress hormone. Under stress conditions like those generated by salinity, drought, waterlogging, heavy metals and pathogenicity, the endogenous production of ethylene is accelerated substantially which adversely affects the root growth and consequently the growth of the plant as a whole. Certain plant growth promoting rhizobacteria (PGPR) contain a vital enzyme, 1-aminocyclopropane-1-carboxylate (ACC) deaminase, which regulates ethylene production by metabolizing ACC (an immediate precursor of ethylene biosynthesis in higher plants) into α-ketobutyrate and ammonia. Inoculation with PGPR containing ACC deaminase activity could be helpful in sustaining plant growth and development under stress conditions by reducing stress-induced ethylene production. Lately, efforts have been made to introduce ACC deaminase genes into plants to regulate ethylene level in the plants for optimum growth, particularly under stressed conditions. In this review, the primary focus is on giving account of all aspects of PGPR containing ACC deaminase regarding alleviation of impact of both biotic and abiotic stresses onto plants and of recent trends in terms of introduction of ACC deaminase genes into plant and microbial species.     

木本油料植物麻疯树的研究进展

近来,麻疯树(Jatropha curcas L.)因可以作为生物柴油的原料而受到广泛关注。虽然麻疯树具有含油量高且可在边际土地种植的优势,但同时存在理想品种缺乏、种植面积限制、基础研究薄弱等方面的问题。为了使常规育种和生物技术改良工作者更好地了解麻疯树的研究进展,确定日后麻疯树育种和遗传改良的方向,综述了麻疯树种质资源与遗传多样性分析、生理及对环境适应性、组学研究、油脂合成功能基因研究、育种等方面国内外的最新进展。     

生物柴油植物黑皂树开发利用研究

能源短缺和环境污染是当前人类社会所面临的巨大挑战,生物柴油的推广和应用是现阶段解决替代燃油的重要途径之一。黑皂树种子油是很好的生物柴油原料,目前在许多热带地区大力种植黑皂树。我国华南、西南地区的一些干旱荒地可以种植黑皂树。我们对黑皂树油在柴油机上的应用研究证明:黑皂树油在气温35℃条件下,可以直接在各种柴油机上起动和应用;黑皂树油中掺入20%的轻柴油,其黏度大大降低,冷机起动性能和热效率等均与轻柴油相当。因此,黑皂树油的应用比目前国外使用的生物柴油更经济,是一种很有发展前途的能源植物。     

麻疯树皮的化学成分研究

从麻疯树(Jatrophac curcus L.)的树皮中分离得到12个化合物,经理化常数和波谱鉴定(IR,1H NMR,13C NMR,EI-MS)分别为二十六酸甲酯(1),β-谷甾醇(2),蒲公英萜醇(3),蒲公英甾醇(4),伪蒲公英甾醇(5),curcusones A(6),curcusones B(7),jatropholone A(8),jatropholone B(9),3,3′,4-三甲氧基鞣花酸(10),胡萝卜甙(11),蔗糖(12)。其中化合物1,4,5,10,12为首次从该植物中分离得到。     

小桐子愈伤组织的诱导

本文以小桐子的叶片、叶柄、茎段及下胚轴和子叶作为外植体,研究不同外植体类型对愈伤组织诱导的影响,结果表明叶柄的诱导率最高,其次为茎段的诱导率。同时以小桐子的下胚轴作为外植体,研究植物生长调节剂种类及浓度配比对愈伤组织诱导的影响,结果显示6-BA与2,4-D的组合更适宜小桐子愈伤组织的诱导,MS+6-BA0.5mg/L+2,4-D0.1mg/L为小桐子愈伤组织诱导的最佳培养基,其愈伤组织诱导率高达96.7%。本研究为小桐子愈伤组织的分化、植株再生及相关的遗传转化研究提供了参考。     

麻疯树花药发育过程中Ca2+的分布特征

采用超薄切片技术,在透射电镜下观察麻疯树(Jatropha curcasL.)花药发育过程中Ca2 的分布特征。在孢原细胞时期的花药中几乎看不到Ca2 沉淀,但花药维管束周围的细胞中有较多的Ca2 沉淀;到小孢子母细胞时期,细胞质中Ca2 沉淀依然较少,绒毡层壁上Ca2 沉淀明显增多;四分体形成时,小孢子细胞质和绒毡层细胞质中出现了较多的Ca2 沉淀;在小孢子发育早期,细胞质中Ca2 沉淀增加不明显,花粉壁部位累积有很多的Ca2 沉淀,绒毡层中Ca2 沉淀数量达到最多;到小孢子发育晚期,小孢子大液泡的液泡膜上有大量的Ca2 沉淀,绒毡层中Ca2 沉淀明显减少;随着二胞花粉中的大液泡消失,细胞质中积累淀粉粒以后,花粉中看到的Ca2 沉淀极少,同时,在花药维管束周围的薄壁细胞中,又出现了较多的Ca2 沉淀,表明花粉对Ca2 的需求可能降低。麻疯树花药发育过程中钙的动态分布特征暗示着钙参与了调控花粉发育过程,Ca2 的运输途径是由药隔薄壁组织运输到绒毡层,再进一步转移到小孢子表面和细胞质中,整个花药发育过程中,Ca2 沉淀表现为少—增加—减少的变化趋势。     

麻疯树小孢子发育的研究

用透射电镜观察了麻疯树(Jatropha curcas L.)小孢子发育的超微结构。小孢子母细胞时期内质网和质体较多;减数分裂和四分体时期,细胞处于明显的代谢活跃状态,细胞器丰富,主要有内质网、线粒体、质体、高尔基体和球状体;在小孢子发育早期和晚期,线粒体和内质网仍较丰富;小孢子经过高度的不对称分裂后,形成较大的营养细胞和较小的生殖细胞,营养细胞中细胞器数量明显减少,含大量的淀粉和脂类物质,生殖细胞中脂类物质丰富;表皮、药室内壁和中层细胞在小孢子母细胞和四分体时期淀粉粒丰富,小孢子时期明显减少,绒毡层从小孢子母细胞至小孢子发育晚期的细胞器都很丰富,主要为内质网、质体和线粒体,为二胞花粉发育奠定基础。     

麻疯树核糖体失活蛋白Curcin2的原核可溶性表达及其抗真菌活性研究

Curcin2是麻疯树幼苗在真菌侵染、干旱及高低温胁迫下诱导产生的一种核糖体失活蛋白.采用分子克隆的方法,从麻疯树基因组中扩增到Curcin2成熟肽编码基因,分别连接到质粒载体pGEX-6p-1、pMAL-c5E上,转化大肠杆菌最终获得重组菌PGC(pGEX-6p-1-curcin2)和PMC(pMAL-c5E-curcin2).在不同温度、IPTG浓度、时间诱导下,Curcin2在重组菌PGC中均以包涵体形式表达,在重组菌PMC中主要以可溶性融合蛋白形式表达,且蛋白质的表达量与诱导条件相关.重组菌PMC表达可溶性curcin2的优化条件为:温度28℃,IPTG 0.3mmol/L,时间8h,此条件下目的蛋白占总蛋白表达量的30.6％,1L培养物中可获得19.74mg电泳纯的重组蛋白.重组蛋白可被MBP TrapTM HP柱亲和纯化并与curcin抗体发生抗原抗体反应.体外抗真菌活性实验表明,纯化后的curcin2融合蛋白有抑制真菌生长作用,且对小麦赤霉、油菜菌核的抑制作用强于curcin.此蛋白的获得为其相关功能的研究奠定了基础.     

Transformation of Jatropha curcas L. for production of larger seeds and increased amount of biodiesel

The development of green energy is important to mitigate global warming. Jatropha (Jatropha curcas L.) is a promising candidate for the production of alternative biofuel, which could reduce the burden on the Earth’s resources. Jatropha seeds contain a large quantity of lipids that can be used to produce biofuel, and the rest of the plant has many other uses. Currently, techniques for plant genetic transformation are extensively employed to study, create, and improve the specific characteristics of the target plant. Successful transformation involves the alteration of plants and their genetic materials. The aim of this study was to generate Jatropha plants that can support biofuel production by increasing their seed size using genes found via the rice FOX-hunting system. The present study improved previous protocols, enabling the production of transgenic Jatropha in two steps: the first step involved using auxins and dark incubation to promote root formation in excised shoots and the second step involved delaying the timing of antibiotic selection in the cultivation medium. Transgenic plants were subjected to PCR analysis; the transferred gene expression was confirmed via RT-PCR and the ploidy level was investigated. The results suggest that the genes associated with larger seed size in Arabidopsis thaliana, which were found using the rice FOX-hunting system, produce larger seeds in Jatropha.     

Growth promotion and yield enhancement of peanut (Arachis hypogaea L.) by application of plant growth-promoting rhizobacteria

Although plant growth-promoting rhizobacteria (PGPR) have been reported to influence plant growth, yield and nutrient uptake by an array of mechanisms, the specific traits by which PGPR promote plant growth, yield and nutrient uptake were limited to the expression of one or more of the traits expressed at a given environment of plant–microbe interaction. We selected nine different isolates of PGPR from a pool of 233 rhizobacterial isolates obtained from the peanut rhizosphere on the basis of ACC-deaminase activity. The nine isolates were selected, initially, on the basis of germinating seed bioassay in which the root length of the seedling was enhanced significantly over the untreated control. All the nine isolates were identified as Pseudomonas spp. Four of these isolates, viz. PGPR1, PGPR2, PGPR4 and PGPR7 (all fluorescent pseudomonads), were the best in producing siderophore and indole acetic acid (IAA). In addition to IAA and siderophore-producing attributes, Pseudomonas fluorescens PGPR1 also possessed the characters like tri-calcium phosphate solubilization, ammonification and inhibited Aspergillus niger and A. flavus in vitro. P. fluorescens PGPR2 differed from PGPR1 in the sense that it did not show ammonification. In addition to the traits exhibited by PGPR1, PGPR4 showed strong in vitro inhibition to Sclerotium rolfsii. The performances of these selected plant growth-promoting rhizobacterial isolates were repeatedly evaluated for 3 years in pot and field trials. Seed inoculation of these three isolates, viz. PGPR1, PGPR2 and PGPR4, resulted in a significantly higher pod yield than the control, in pots, during rainy and post-rainy seasons. The contents of nitrogen and phosphorus in soil, shoot and kernel were also enhanced significantly in treatments inoculated with these rhizobacterial isolates in pots during both the seasons. In the field trials, however, there was wide variation in the performance of the PGPR isolates in enhancing the growth and yield of peanut in different years. Plant growth-promoting fluorescent pseudomonad isolates, viz. PGPR1, PGPR2 and PGPR4, significantly enhanced pod yield (23–26%, 24–28% and 18–24%, respectively), haulm yield and nodule dry weight over the control in 3 years. Other attributes like root length, pod number, 100-kernel mass, shelling out-turn and nodule number were also enhanced. Seed bacterization with plant growth-promoting P. fluorescens isolates, viz. PGPR1, PGPR2 and PGPR4, suppressed the soil-borne fungal diseases like collar rot of peanut caused by A. niger and PGPR4 also suppressed stem rot caused by S. rolfsii. Studies on the growth patterns of PGPR isolates utilizing the seed leachate as the sole source of C and N indicated that PGPR4 isolate was the best in utilizing the seed leachate of peanut, cultivar JL24. Studies on the rhizosphere competence of the PGPR isolates, evaluated on the basis of spontaneous rifampicin resistance, indicated that PGPR7 was the best rhizoplane colonizer and PGPR1 was the best rhizosphere colonizer. Although the presence of growth-promoting traits in vitro does not guarantee that an isolate will be plant growth promoting in nature, results suggested that besides ACC-deaminase activity of the PGPR isolates, expression of one or more of the traits like suppression of phytopathogens, solubilization of tri-calcium phosphate, production of siderophore and/or nodulation promotion might have contributed to the enhancement of growth, yield and nutrient uptake of peanut.