转Bt基因抗虫棉叶面可培养微生物多样性的变化

在大田栽培条件下,以转Bt基因抗虫棉GK-12和常规棉泗棉3号为材料,在棉花的苗期、现蕾期、花铃期和吐絮期分别测定棉花叶面细菌、真菌和放线菌的数量变化,并在花铃期和吐絮期对叶面细菌生理群的数量和多样性进行分析.结果表明：棉花叶面可培养微生物数量与其生长发育呈正相关,叶面可培养微生物的数量一般由苗期开始增多,到花铃期达最高峰,吐絮期明显减少;花铃期转Bt基因抗虫棉叶面细菌生理群Simpson指数、Shannon-Wiener指数和均匀度比常规棉升高,吐絮期比常规棉下降.     

转Bt+CpTI基因棉花对根际土壤细菌及氨氧化细菌数量的影响

转基因棉花对根际土壤微生物的影响在转基因作物风险评估中具有重要意义。【目的】通过研究转基因棉花根际微生物群落变化来评估转基因棉花的生态风险。【方法】以转Bt+CpTI基因抗虫棉(SGK321)及非转基因亲本棉花石远321(SY321)根际土壤总细菌和氨氧化细菌为研究对象,分别在种植前和棉花的不同生长时期(蕾期、花期、铃期和絮期)取样。采用微滴数码PCR方法对土壤中总细菌16S rRNA和氨氧化细菌的功能基因amoA基因进行定量分析。【结果】结果发现两种棉花根际土壤中的总细菌数量随棉花生长的不同时期没有显著差异。但是对氨氧化细菌的定量结果表明随棉花不同生长时期,两种棉花根际土壤中的氨氧化细菌数量均发生显著变化,但变化趋势不同:在蕾期,SY321和SGK321根际土壤中的氨氧化细菌数量分别增加了4倍和2倍;在花期,SY321根际氨氧化细菌与蕾期相比显著降低至5.96×105copies/g dry soil,而SGK321根际氨氧化细菌则显著增加至1.25×106copies/g dry soil;在铃期,SY321根际氨氧化细菌显著增加至1.49×106copies/g dry soil,而SGK321根际土壤中氨氧化细菌数量没有发生显著变化;絮期两者均表现为降低,但差异显著。与非转基因棉花相比,转基因棉花根际土壤中的氨氧化细菌变化相对较为平缓。【结论】这表明氨氧化细菌数量既受棉花生长时期的影响,同时也受转基因棉花的影响,转基因棉花通过影响氨氧化细菌的数量减缓氨的转化速度,这在一定程度上有利于植物生长。     

不同生育期转Bt基因棉种植对根际土壤微生物的影响

 在盆栽种植条件下,比较研究了两个转Bt基因棉(Gossypium hirsutum)与对照棉对根际土壤细菌、放线菌、真菌和主要功能类群及多样性的影 响差异。结果表明：两个转Bt基因棉根际土壤均可检测到Bt蛋白,且不同转Bt基因棉根系分泌Bt蛋白量以及Bt蛋白在根际土壤中的降解率不同 。与各自对照相比,转Bt基因棉对细菌和真菌生长繁殖有促进作用,对放线菌、好气固氮菌和钾细菌数量没有显著影响。苗期和花期转Bt基因 棉均可显著提高氨化细菌、显著降低无机溶磷菌数量,花期均可显著提高好气纤维分解菌、显著降低有机溶磷菌数量,‘Bt冀668’苗期也可显 著提高好气纤维分解菌数量。转Bt基因棉根际土壤好气纤维分解菌、有机和无机溶磷菌多度发生了变化。尽管功能类群总数转Bt基因棉高于各 自对照常规棉,但群落多样性和均匀度都有所下降,优势集中性表现明显,且花期转Bt基因棉多样性参数值以及功能类群数量的变化幅度大于 苗期。     

转几丁质酶和葡聚糖酶双价基因棉花对土壤细菌种群多样性的影响

以转几丁质酶和葡聚糖酶双价基因棉花为研究对象,非转基因受体棉花为对照,通过比较可培养细菌数量和基于16S rRNA克隆文库细菌种群分析,评价外源双价基因的导入在苗期、蕾期、花铃期和吐絮期对棉花根际细菌群落多样性的影响。结果表明,可培养细菌的数量不受外源双价基因的影响,随着棉花生育期的交替而变化,以代谢旺盛的花铃期最多。构建的转基因和非转基因不同生育期根际土壤细菌16S rRNA文库容量为2400个克隆,涵盖了细菌的283个属。其中,Acidobacterium是最大优势类群,共包括624个克隆,其次为未知细菌种群和Flavisolibacter。比较转基因和非转基因棉花根际土壤细菌的种群结构,结果显示,同一生育期内前者种群的多样性显著低于后者,二者的共有类群随着生长发育的进行而增多。研究结果说明几丁质酶基因和葡聚糖酶基因对棉花根际细菌种群多样性有着不同程度的削减作用,但是随着种植时间的延长,该差异呈现逐渐缩小的趋势。     

转Bt + CpTI基因棉花对根际土壤细菌及氨氧化细菌数量的影响

摘要:转基因棉花对根际土壤微生物的影响在转基因作物风险评估中具有重要意义。【目的】通过研究转基因棉花根际微生物群落变化来评估转基因棉花的生态风险。【方法】以转Bt + CpTI基因抗虫棉(SGK321)及非转基因亲本棉花石远321(SY321)根际土壤总细菌和氨氧化细菌为研究对象,分别在种植前和棉花的不同生长时期(蕾期、花期、铃期和絮期)取样。采用微滴数码PCR方法对土壤中总细菌16S rRNA和氨氧化细菌的功能基因amoA基因进行定量分析。【结果】结果发现两种棉花根际土壤中的总细菌数量随棉花生长的不同时期没有显著差异。但是对氨氧化细菌的定量结果表明随棉花不同生长时期,两种棉花根际土壤中的氨氧化细菌数量均发生显著变化,但变化趋势不同:在蕾期,SY321和SGK321根际土壤中的氨氧化细菌数量分别增加了4倍和2倍;在花期,SY321根际氨氧化细菌与蕾期相比显著降低至5.96×105 copies/g dry soil,而SGK321根际氨氧化细菌则显著增加至1.25×106 copies/g dry soil;在铃期,SY321根际氨氧化细菌显著增加至1.49×106 copies/g dry soil,而SGK321根际土壤中氨氧化细菌数量没有发生显著变化;絮期两者均表现为降低,但差异显著。与非转基因棉花相比,转基因棉花根际土壤中的氨氧化细菌变化相对较为平缓。【结论】这表明氨氧化细菌数量既受棉花生长时期的影响,同时也受转基因棉花的影响,转基因棉花通过影响氨氧化细菌的数量减缓氨的转化速度,这在一定程度上有利于植物生长。     

转基因棉花种植对根际土壤微生物群落功能多样性的影响

应用Biolog方法对两种转基因棉花及其亲本非转基因棉花根际土壤微生物的单一碳源利用水平进行了比较分析,探讨转基因棉花种植对其根际土壤微生物群落功能多样性的影响.结果表明：与非转基因亲本相比,在苗期、蕾期、吐絮期、衰老期转基因棉花种植对根际土壤微生物群落碳源利用能力、Shannon功能多样性指数和均匀度指数的影响均不显著,而在花铃期根际土壤微生物群落碳源利用能力和Shannon功能多样性指数显著降低.主成分分析表明,花铃期转基因棉花与非转基因棉花根际土壤微生物碳源利用在两主成分轴上的分异较大,碳源利用模式差异显著.     

种植转Bt基因抗虫棉对土壤生物学活性的影响

采用温室盆栽实验,研究了种植转Bt基因棉（苏抗103）和同源常规棉（苏棉12）对根际土壤生物学活性的影响。结果表明：与对照常规棉相比,种植转Bt基因棉对根际土壤脱氢酶、碱性磷酸酶、蔗糖酶和土壤呼吸的影响因生育期而异,土壤脲酶、蛋白酶和微生物量C在各生育期均没有显著差异;土壤蔗糖酶、土壤脱氢酶和土壤呼吸分别只在苗期（苏抗103〉苏棉12,增幅为25．5％）、花铃期（苏抗103〉苏棉12,增幅为21．6％）、花铃期（苏抗103〉苏棉12,增幅为36．1％）存在显著差异;土壤磷酸酶在花铃期和吐絮期活性显著下降（降幅分别为22．1％和32．9％）。     

种植转Bt基因棉土壤中Bt蛋白的分布

采用盆栽试验结合酶联免疫法(ELISA)测定了转Bt基因抗虫棉及常规棉花不同生育期根际及非根际土壤中的Bt蛋白含量.结果表明:红壤、黄棕壤及黄褐土种植转Bt基因棉花后根际土中Bt蛋白含量显著高于非根际土,而种植常规棉花的根际土与非根际土中Bt蛋白含量差异不显著.在初蕾期转Bt基因棉根际土中的Bt蛋白含量为黄褐土＞黄棕壤＞红壤,分别为常规棉根际土的144%、121%和238%;而在盛花期为黄棕壤＞黄褐土＞红壤,分别为常规棉根际土的156%、116%和197%.无论种植转Bt基因棉还是常规棉,供试土壤的根际和非根际土中Bt蛋白含量都随棉花生育期的推进先增加后减少,在盛花期达最大值.整个生育期内,转Bt基因棉根际土中的Bt蛋白含量大于其非根际土;种植转Bt基因棉土壤中Bt蛋白含量高于常规棉,说明转Bt基因棉花的Bt蛋白可释放到根际土中.     

麦棉套作棉花根际非根际土壤微生物和土壤养分

在麦棉套作栽培模式下,设置不隔根、纱网隔根和塑膜隔根3种麦棉套种方式,研究麦棉套作对棉花根际和非根际土壤微生物数量、活性和土壤养分（全氮、有效磷和速效钾）含量的影响,结果表明：麦棉套作有利于棉花根际与非根际土壤细菌的增殖,盛蕾期不隔根处理棉花根际土壤与非根际土壤细菌数量分别是塑膜隔根处理的2.57和2.81倍.但麦棉套作不利于土壤真菌和放线菌的增殖.细菌在土壤微生物区系中占99.9%.所以,麦棉套作显著提高了棉花土壤微生物数量,同时也增强了微生物活性.麦棉共处期纱网隔根处理棉花土壤全氮、有效磷、速效钾含量显著高于不隔根处理和塑膜隔根处理,证明麦棉套作系统中小麦根系分泌物与脱落物的存在对棉花土壤养分含量的增加有明显的促进作用,即存在种间营养补偿效应.而共处期不隔根处理套作棉土壤养分含量总体上显著低于隔根处理的现象则反映出小麦根系对棉花土壤养分的竞争作用大于其对棉花土壤养分的促进作用.小麦收获后,小麦根系对棉花养分的竞争作用解除,不隔根处理棉花土壤养分含量显著高于塑膜隔根和纱网隔根处理.     

Bt棉与常规棉根际土壤Bt毒蛋白和植物激素变化动态

通过ELISA法对常规棉（石远321）和转基因抗虫棉（99B、SGK321）根际土壤苏云金芽孢杆菌（Bt）毒蛋白和植物激素含量进行了分析,结果表明抗虫棉根际土壤Bt毒蛋白含量显著高于常规棉,特别是从苗期到盛花期抗虫棉根际土壤Bt毒蛋白含量高出常规棉200-300ng／g。抗虫棉根际土壤中脱落酸（ABA）和生长素吲哚乙酸（IAA）含量变化趋势与常规棉相比表现出较大差异。常规棉与抗虫棉根际土壤中ABA变化趋势表现为相似的单峰曲线,而抗虫棉根际土壤中ABA含量变化幅度明显小于常规棉。在棉花生长发育后期抗虫棉根际土壤中赤霉酸（GA3）含量较高,而常规棉根际土壤中GA,含量升高较抗虫棉早且变化幅度大,在高峰处常规棉高于抗虫棉,低谷时抗虫棉高于常规棉。7月17日常规棉根际土壤IAA含量显著高于抗虫棉,8月27日抗虫棉又大大高于常规棉,其他时期变化不大。上述结果表明,外源Bt基因的插入或表达能引起棉花根际土壤中Bt毒蛋白和植物激素含量的较大改变,这种改变可能会影响到抗虫棉的生长发育,并对环境产生影响。     

Effects of repeated cultivation of transgenic Bt cotton on functional bacterial populations in rhizosphere soil

The impact of multiple-year (0–5 years) cultivation of transgenic Bacillus thuringiensis (Bt) cotton on the functional bacterial populations in rhizosphere soil was investigated. The transgenic Bt + CpTI cotton line SGK321 and a non-Bt cotton line Shiyuan321 were planted in four fields in which Bt cotton had been continuously cultivated for 0, 1, 3, and 5 years. Rhizosphere soil samples were collected at the seedling, squaring, flower and boll, and boll-opening stages of cotton. Numbers of bacteria involved in nitrogen-fixing, organic phosphate-dissolving, inorganic phosphate-dissolving, and potassium-dissolving were measured with cultivation-dependent approaches. The data presented here showed no consistent statistically significant differences in the numbers of different groups of functional bacteria between rhizosphere soil of Bt and non-Bt cotton in the same field, and no obvious trends in the numbers of the various group of functional bacteria with the increasing duration of Bt cotton cultivation. These studies suggest that multiple-year cultivation of transgenic Bt cotton may not affect the functional bacterial populations in rhizosphere soil.     

Transgenic Bt cotton has no apparent effect on enzymatic activities or functional diversity of microbial communities in rhizosphere soil

A transgenic Bt cotton (Sukang-103) and its non-Bt cotton counterpart (Sumian-12) were investigated to evaluate the potential risk of transgenes on the soil ecosystem. The activities of urease, phosphatase, dehydrogenase, phenol oxidase, and protease in cotton rhizosphere were assayed during the vegetative, reproductive, and senescing stages of cotton growth and after harvest. A Biolog system was used to evaluate the functional diversity of microbial communities in soils after a complete cotton growth cycle. Enzymatic activities in soils amended with cotton biomass were also assayed. Results showed that there were few significant differences in enzyme activities between Bt and non-Bt cottons at any of the growth stages and after harvest; amendment with cotton biomass to soil enhanced soil enzyme activities, but there were no significant difference between Bt and non-Bt cotton; the richness of the microbial communities in rhizosphere soil did not differ between Bt and the non-Bt cotton, and close to that of control soil; the functional diversity of microbial communities were not different in rhizosphere soils between Bt and non-Bt cotton. All results suggested that there was no evidence to indicate any adverse effects of Bt cotton on the soil ecosystem in this study.     

番茄根际微生物种群动态变化及多样性

采用盆栽试验的方法对番茄根际主要微生物种群在不同生育期的动态变化进行了跟踪研究.结果表明,在番茄整个生育期内,可培养细菌数量在初花期和初果期时最多;放线菌数量从苗期到末期逐渐减少;真菌数量逐渐增多.番茄对细菌根际效应明显.DGGE图谱显示不同生育期番茄根际均具有较高的细菌多样性.根际细菌种类和数量在初花期发生较为显著的变化,初果期根际群落多样性指数(H)和物种丰度(S)值都达到最高,微生物最丰富,是筛选拮抗菌的较好时期.     

Effects of proportion and configuration of Bacillus thuringiensis cotton on pest abundance, damage, and yield

Bacillus thuringiensis (Bt) transgenic cotton, Gossypium hirsutum L., kills several economically important pests, reducing injury and increasing yields. Refuges of non-Bt cotton are currently planted with Bt cotton in different designs to slow pest resistance evolution. To compare the effects of differences in Bt/non-Bt plant heterogeneity found in different refuge designs on square (flower bud) damage, abscissions, sap-feeding herbivore densities, and yield in cotton, four types of 24-row cotton plots were planted in 2001 and 2002: 1) seed mixtures of Bt and non-Bt varieties, 2) 12-row strips of Bt and non-Bt, 3) solid Bt, and 4) solid non-Bt. For both years cotton bollworm, Helicoverpa zea (Boddie), damage was less in solid Bt plots than strips and mixtures and all were less than solid non-Bt plots. Cotton fleahopper, Pseudatomoscelis seriatus (Reuter), damage was affected by refuge, but only in 2002 when damage was greater in solid Bt plots than all other plots and greater in strips than solid non-Bt plots. Abscissions were least in solid non-Bt plots, and less in mixtures and strips than solid Bt plots. In 2001, western flower thrips, Frankliniella occidentalis (Pergande), density was greatest in mixtures, whereas sweetpotato whitefly, Bemisia tabaci (Gennadius), was greatest in solid Bt plots, and greater in mixtures than solid non-Bt plots. Yield also was affected by refuge, it was greater for solid Bt plots than for solid non-Bt plots and mixtures in 2001, but the reverse was true in 2002.     

Impact of transgenic cotton varieties on activity of enzymes in their rhizosphere

The impact of five Bacillus thuringiensis (Bt) cotton varieties and their respective isogenic non-Bt(NBt) isolines (ANKUR-2534, MECH-6304, RCH-317, ANKUR-651 and MECH-6301) was assessed on the key soil enzymes i.e., dehydrogenase, alkaline phosphatase and urease in their rhizosphere at four growth stages of the crop, namely vegetative, flowering, bolling and harvesting. These varieties were grown on farmer's field in villages 22 miles and 24 miles of Ganganagar District of Rajasthan State in India. Results showed that dehydrogenase, alkaline phosphatase and urease activities were higher in rhizosphere of Bt isolines as compared to NBt isolines of all the varieties. Except phosphatase, differences in dehydrogenase and urease activities in rhizosphere of Bt and NBt isolines of all five varieties were significant (P < 0.05). Maximum enhancement in the three enzymes activities was observed in MECH-6304 Bt isoline rhizosphere. Maximum and minimum activities of dehydrogenase and urease were observed in MECH-6304 and RCH-317 Bt isolines, respectively, whereas phosphatase activity was maximum and minimum in MECH-6304 and ANKUR-651 Bt isolines, respectively. Maximum dehydrogenase and urease activities were observed at boll formation and minimum at flowering and harvesting stage, respectively, while maximum phosphatase activity was observed at vegetative stage and minimum at harvesting stage. In conclusion, all the studied Bt isolines of cotton varieties showed no adverse effect on dehydrogenase, alkaline phosphatase and urease activities in the rhizosphere.     

Characterization of the rhizosphere microbial community from different Arabidopsis thaliana genotypes using phospholipid fatty acids (PLFA) analysis

Total and culturable rhizosphere microbial communities structure from three different genotypes of Arabidopsis thaliana growing on three different substrates was studied with phospholipid fatty acid analysis (PLFA) and multivariate statistical analyses: correspondence analysis (CA) and distance based redundancy analyses (db-RDA). In addition, microbial biomass from different groups (total bacteria, Gram+, Gram? and fungi) was calculated from biomarkers PLFA peak area, both from total and culturable microbial community. db-RDA analysis showed significant differences between soils but not between plant genotypes for culturable microbial community structure. Total microbial community was significantly different between soils, and also between plant lines in each soil. Biomass of different bacterial groups showed significant higher values in soil two rhizosphere irrespective of the plant line. In addition, significant differences between plant lines were also found for microbial biomass of different bacterial groups both in total and culturable microbial community. Throughout the work we have demonstrated that PLFA analysis has been able to show a different behaviour of total microbial community with regard to the culturable fraction analyzed in this work under the influence of plant roots. Microbial biomass of different microbial groups calculated with PLFA biomarkers was a suitable tool to detect differences between soils irrespective of the plant line, and differences in the same soil between plant lines. According to this data, a previous study should be carried out before GMPs are used in field conditions to evaluate the potential alterations that may take place on rhizosphere microbial communities structure which may further affect soil productivity. In conclusion, based on data presented in this work, GMPs alter rhizosphere microbial communities structure and this effect is different depending on the soil. Furthermore, total microbial community is affected to a greater extent than the culturable fraction analyzed.     

Changes of Bt Toxin in the Rhizosphere of Transgenic Bt Cotton and its Influence on Soil Functional Bacteria

Summary The concentrations of Bacillus thuringensis (Bt) toxin released from root exudation of Bt cotton were measured by an enzyme-linked immunosorbent assay (ELISA), and its impacts on the numbers of culturable functional bacteria in the rhizosphere were determined by cultivation. No Bt toxin was found in the rhizosphere of non-Bt cotton (SHIYUAN321), but varying levels of Bt toxin were present in the rhizosphere of two Bt cotton varieties (NuCOTN99^B and SGK321) during the entire growth period. The levels of Bt toxin in the rhizosphere of NuCOTN99^B were significantly higher (p<0.05) than those of SGK321 within all sampling dates except on June 17th in the whole growth season. Significant differences (p<0.05) were found in the numbers of the three functional bacteria between SHIYUAN321 and NuCOTN99^B within each sampling day from May 27th to October 27th. No significant differences were found in the numbers of functional bacteria among three cultivars after growth season. Fortification of pure Bt toxin into rhizospheric soil did not result in significant changes in the numbers of culturable functional bacteria, except the nitrogen-fixing bacteria when the concentration of Bt toxin was higher than 500 ng/g. The results indicated that Bt toxin was not the direct factor causing decrease of the numbers of bacteria in the rhizosphere, and other factors may be involved.