转基因水稻秸秆还田对土壤硝化反硝化微生物群落的影响

转基因作物可能通过根系分泌物和植株残体组成的改变及外源基因的转移释放令土壤微生物群落产生变化,影响土壤微生物的生态功能。氨氧化细菌和反硝化细菌是驱动土壤硝化和反硝化过程的关键微生物,其群落结构的变化直接关系土壤氮素的转化与利用。本研究利用荧光定量PCR和PCR-DGGE技术分析了转cry1Ac/cpti双价抗虫基因水稻‘Kf8’秸秆还田降解过程中,土壤氨氧化细菌和反硝化细菌群落丰度与组成的变化,探讨转基因水稻是否存在影响稻田土壤氮素转化与N2O排放的可能。结果显示:无论是氨氧化细菌amo A基因还是反硝化细菌nirS基因,其丰度在转基因水稻‘Kf8’与非转基因水稻‘Mh86’的秸秆还田土壤中都没有显著差异;转基因水稻‘Kf8’和非转基因水稻‘Mh86’秸秆还田降解过程中0~10 cm土层中的amo A基因丰度均显著高于10~20 cm及20~30 cm土层(P0.05);各深度土层中的nirS基因丰度均存在随秸秆还田时间延长而增加的趋势。水稻秸秆还田降解过程中,转基因水稻‘Kf8’的土壤氨氧化细菌和反硝化细菌的群落多样性指数及组成,均与非转基因水稻‘Mh86’没有显著差异。相关分析结果表明土壤氨氧化细菌和反硝化细菌群落组成均与水稻秸秆还田时间存在显著相关性(P=0.002),反硝化细菌群落组成还与土层深度显著相关(P=0.024)。本研究表明转cry1Ac/cpti抗虫基因水稻秸秆还田对稻田土壤硝化和反硝化关键微生物群落不会产生明显影响。就土壤微生物群落而言,转cry1Ac/cpti抗虫基因水稻秸秆还田不存在影响土壤氮素转化与N2O排放的可能。     

种植转双价抗真菌基因水稻对根际微生物群落及酶活性的影响

对转几丁质酶和葡聚糖酶双价抗真菌基因抗病水稻七转39种植后的根际土壤微生物群落和酶活性进行了分析。研究结果表明,七转39根内生真菌和细菌数量显著低于非转基因阴性对照七丝软粘和常规水稻竹籼B,根际土壤中真菌和细菌数量也少于七丝软粘,与竹籼B数量接近。在水稻抽穗期测定,转基因水稻根际土壤过氧化氢酶、多酚氧化酶、蔗糖酶和脲酶活性以及可溶性有机质、氮、磷含量均与对照无显著差异。转基因水稻残体腐解过程中土壤腐殖酸含量变化与七丝软粘一致。与对照相比, 种植七转39未对下茬水稻的生长产生显著影响。     

水稻和小麦根际效应及细菌群落特征的比较研究

稻麦轮作是我国重要的农业生产方式,但水稻和小麦的根际效应及其对土壤功能的相对贡献仍不清楚。利用中国科学院常熟农业生态试验站典型乌栅土壤,同时分别设置种植水稻和小麦的盆栽试验,通过比较根际和非根际土壤中活性组分含量、脱氢酶活性、细菌群落多样性等指标的差异,研究植稻和植麦土壤根际效应及细菌群落特征。结果表明：水稻和小麦根际和非根际土壤的养分含量、微生物活性和细菌群落多样性以及主要细菌种类均具有显著性差异;根际土壤可溶性有机碳（DOC）、微生物生物量碳（MBC）含量和脱氢酶活性（DHA）均高于非根际土壤,而土壤可溶性有机氮（DON）含量及细菌阿尔法（Alpha）多样性均低于非根际土壤;水稻各指标根际效应（DOC：2.07%,MBC：8.61%,DHA：41.11%,DON：61.07%, Chao1指数：7.62%）均小于小麦对应指标的根际效应（DOC：3.37%,MBC：22.62%,DHA：44.48%,DON：71.43%,Chao1指数：16.59%）;小麦根际和非根际细菌群落分布之间的差异显著大于水稻。以上结果表明,与旱作小麦相比,水稻根际土壤与非根际土壤的差异较小,水稻根际效应较小,有利于光合碳及土壤养分的运移,有利于土壤微生物尤其是非根际微生物的生长。这些结果从新的角度阐释了根际效应及其对稻麦轮作土壤可持续性发展的作用机制。     

转Bt基因棉花根际细菌与古菌群落结构分析

在一年内棉花的四个生长时期（苗期,蕾期,花铃期,吐絮期）分别采集转Bt基因抗虫棉GK12和非转基因亲本棉花泗棉3号根际土壤,以及未种植棉花的背景土壤,利用末端标记限制性片段长度多态性（T-RFLP）分析技术,分析三种土壤中细菌和古菌的16S rRNA基因片段多态性,结合克隆文库建立和测序,研究了土壤中细菌和古菌群落结构的变化.结果表明：在棉花生长的各个时期,背景土壤中细菌群落结构发生了明显的变化,生物多样性指数明显降低,古菌群落结构也有一定的变化,说明季节性变化对土壤中微生物群落产生了明显的影响.与背景土壤相比,棉花种植后根际土壤中细菌和古菌群落发生显著的变化.转基因棉花与非转基因棉花相比,根际土壤细菌和古菌的种类和种群大小的分布也发生了明显的改变.克隆文库和测序结果表明土壤中主体微生物为目前未培养的、功能特性未知的细菌和古菌,转基因棉花种植对这些细菌和古菌影响的原因、环境危害和生态风险目前尚不清楚.与古菌群落相比,棉花种植对细菌群落结构的影响较小.     

转基因作物对土壤微生物群落的影响及主要研究策略

土壤生态系统是农业生态系统安全和农业可持续发展的重要载体,也是人类赖以生存的基础。随着基因工程技术的应用和转基因作物大量种植,在带来重大经济效益的同时,也可能会引发一定的生态风险,包括会对农田土壤生态系统尤其是微生物群落结构和功能产生难以预测的复杂影响。目前这些研究方向已成为土壤生物安全的研究热点。本文简要分析了近年来转基因作物对土壤微生物群落的影响,着重介绍了转基因作物种植影响根际土壤微生物群落多样性的研究进展、土壤微生物群落多样性的研究方法及其评估研究的主要策略等。     

不同种植年限宁夏枸杞根际微生物多样性变化

为了解长期人工种植枸杞根际土壤微生物的种群结构变化特征,利用Illumina Mi Seq测序平台分别对种植5 a、10 a和15 a宁夏枸杞根际土壤微生物基因组总DNA中16S和18S r DNA基因的部分区域进行测序,经UPARSE pipeline和RDP classifier软件进行聚类分析和物种注释。结果表明,长期种植宁夏枸杞不会改变其根际土壤p H,但会导致根际土壤全磷、有效磷、全盐含量和电导率升高。测序结果表明,不同种植年限枸杞根际土壤细菌群落α多样性无显著变化,但真菌群落多样性在种植10 a枸杞中较种植5 a时显著降低(p0.05),表明根际细菌群落多样性受种植年限影响较小。从门的分类水平看,酸杆菌门、放线菌门、拟杆菌门、厚壁菌门、绿弯菌门、泉古菌门、蓝菌门、芽单胞菌门、变形菌门以及真菌子囊菌门、担子菌门、接合菌门的比例在不同种植年限的枸杞根际土壤中显著改变(p0.05)。属水平的分析也表明,共有27个细菌属和16个真菌属的比例发生改变(p0.05),这些结果表明枸杞根际土壤微生物群落组成受种植年限的影响更大。相关性分析结果表明,种植年限、土壤全磷及有效磷含量是影响枸杞根际微生物群落结构的主要因子。     

Bt水稻杀虫蛋白时空变化及秸秆还田后在土壤中的持留规律

以Bt抗虫水稻华池B6、TT51及其非转基因水稻亲本嘉早935、明恢63,以及与它们亲缘较远但农艺性状相近的水稻品种中九B、R9311为试验材料,研究了田间种植条件下Bt抗虫水稻杀虫蛋白的时空变化及其在根际土中的持留规律,同时,还研究了秸秆还田后Bt蛋白在土壤中的持留规律。结果表明：1）Bt抗虫水稻华池B6植株各个部位...     

抗真菌转基因水稻根际土壤真菌群落结构的动态变化

以非转基因水稻"七丝软粘"为对照,采用传统平板计数法和变性梯度凝胶电泳技术,研究了抗真菌转基因水稻"转品1"和"转品8"生长周期内对根际土壤中可培养真菌数和真菌群落结构的影响。结果显示,相同生育期转基因水稻根际土壤可培养真菌数量与其非转基因对照水稻相比较无显著性差异,表明转基因水稻的种植没有对根际土壤真菌数量产生明显影响;18S rRNA真菌群落DGGE图谱分析显示,相同生育期转基因水稻与其非转基因对照水稻的根际土壤真菌DGGE条带数量和条带位置均无显著性差异,表明转基因水稻的种植没有对根际土壤真菌群落结构产生明显影响。进一步分析相同生育期转基因水稻与其非转基因对照水稻的根际土壤真菌群落香农多样性指数(Shannon diversity index)和均匀度指数(Evenness index)的动态变化,发现两者均没有显著性差异。以上研究结果表明,外源抗真菌基因的导入对水稻根际土壤中真菌群落数量和群落结构均没有明显影响。此外,将不同位置的真菌DGGE条带切胶回收,克隆、测序后,进行系统进化树分析,结果表明根际土壤真菌群落主要归属为子囊菌门(Ascomycota)、担子菌门(Basidiomycota)、壶菌门(Chytridiomycota)、接合菌门(Zygomycota)和未知真菌(unknown fungi)5个类群。     

玉米?水稻轮作和水稻连作土壤根际和非根际氮含量及酶活性

【目的】以水稻连作为对照,研究玉米?水稻水旱轮作模式对稻田作物根际和非根际土壤氮素含量及酶活性的影响,为稻田系统玉米?水稻轮作对土壤氮素转化与稻田土壤质量的影响提供科学依据。【方法】利用根际袋盆栽试验进行水稻连作与玉米?水稻轮作,在玉米喇叭口期、抽穗期及成熟期,水稻分蘖期、孕穗期及成熟期分别采取根际与非根际土样,测定土壤铵态氮、硝态氮、全氮含量与脲酶、硝酸还原酶活性变化。【结果】两种种植模式及作物生育期对土壤氮素含量和酶活性均有显著影响。不同种植模式下土壤酶活性变化趋势基本相同。与水稻连作相比,玉米?水稻轮作土壤铵态氮减少了24.7%;土壤硝态氮含量增加了153.4%,主要表现在第一季。与水稻连作相比,玉米?水稻轮作条件下两季作物成熟期土壤全氮含量降低,土壤脲酶活性整体提高24.3%,土壤硝酸还原酶活性整体降低34.6%。水旱轮作对各个指标的影响可持续到第二季。根际土壤铵态氮含量及脲酶活性整体低于非根际土壤,玉米根际土壤硝态氮含量低于非根际,水稻根际土壤硝态氮含量高于非根际土壤,根际土壤硝酸还原酶活性高于非根际土壤。【结论】在本试验中,轮作在第一季对土壤氮素及酶活性的影响可持续至第二季。与水稻连作相比,玉米?水稻轮作可以提高作物根际与非根际土壤的脲酶活性及硝态氮含量,有利于氮素有效性的提高。     

提高水稻耐盐能力的根际核心菌株筛选及应用

根际微生物能通过多种途径增强作物对盐胁迫的适应性。为获得能显著提高水稻耐盐性的根际促生菌并探究其应用效果,选择耐盐品种湖南籼和盐敏感品种南粳46两个水稻品种,分别比较了耐盐水稻和盐敏感水稻在自然盐土和灭菌盐土中的生理指标,然后基于16S rRNA基因扩增子测序,通过根系细菌群落差异分析和共现网络分析,鉴定了在耐盐水稻根际富集且与耐盐性相关的关键类群。随后,采用根际微生物宏培养方法从耐盐水稻根际筛选出关键细菌类群的可培养菌株。最后通过盆栽试验评估了菌株增强盐敏感水稻耐盐能力的作用效果。结果表明,自然盐土中耐盐水稻株高和根长均显著高于灭菌土壤中的植株,而脯氨酸含量则显著低于灭菌土壤中的植株,表明耐盐水稻品种根际的微生物群落在增强水稻耐盐能力中具有重要作用。扩增子测序分析发现耐盐水稻品种和盐敏感水稻品种根际微生物群落差异显著,差异分析明确黄杆菌科（Flavobacteriaceae）和假单胞菌科（Pseudomonadaceae）为耐盐水稻根际富集的关键细菌类群。通过设置盐胁迫下盐敏感水稻发芽试验和苗期水培试验,筛选出普氏假单胞菌P34和大安金黄杆菌C18两株功能菌。最后通过盆栽试验证明C18和P34作为直接接种剂或种子包衣剂均能在盐胁迫下显著促进盐敏感水稻生长。综上,C18和P34具有良好的增强水稻耐盐能力的潜力,可作为开发盐碱地专用的种子包衣及微生物肥料的候选菌剂。     

Two-year field study shows little evidence that PPO-transgenic rice affects the structure of soil microbial communities

There is global concern about the environmental consequences associated with transgenic crops. Their effects on the soil ecosystem are of special interest when assessing ecological safety and integrity. Although many efforts have been made to develop crops genetically modified to have resistance to protoporphyrin oxidase (PPO)-inhibiting herbicides, little is known about their influence on soil microbial communities. We conducted a 2-year field study and an analysis via terminal restriction fragment length polymorphism (T-RFLP) to assess the impacts of PPO-transgenic rice on bacterial and fungal communities. In the first year we sampled the rhizosphere and surrounding bulk soil, while in the second year we sampled rhizosphere soil only. No differences were observed in the diversity indices and community composition of microbial communities between transgenic rice and its parental non-transgenic counterpart (cultivar Dongjin). Instead, community variation was strongly dependent on growth stage and year. Therefore, we observed no adverse effects by these crops of modified rice on the microbial community composition in paddy soils.     

Assessment of microbial activity and bacterial community composition in the rhizosphere of a copper accumulator and a non-accumulator

Soil microorganisms may play an important role in the uptake of heavy metals from soils. However, assessments of bacterial activity and community composition in the rhizosphere of accumulators have been largely ignored. We studied potential effects of a copper (Cu)-accumulator, Elsholtzia splendens, and a non-Cu-accumulator plant, Trifolium repens, on soil microbial activity and community composition with increasing Cu addition. The results showed that concentrations of Cu in the shoots of E. splendens were 2.1, 2.2 and 2.4 times those of T. repens under the treatment of different Cu concentrations. Soil microbial biomass and phosphatase activity in the rhizosphere of E. splendens were higher than those of T.repens. PCR-denaturing gradient gel electrophoresis (PCR-DGGE) fingerprint analysis revealed that addition of Cu decreased the number of bands in bare soil and soil with T. repens. However, there was a significant increase in the number of bands in soil with E. splendens incorporated with either 200 or 500 mg kg⁻¹ Cu. The abundances of five phylogenetic groups related most closely to -, β-, γ-proteobacteria, Gram-positive bacteria and CFB group, respectively, were determined in the rhizosphere of plants. Some specific clone such as E13 (metal-contaminated soil clone K20-64) was found in the rhizosphere of E. splendens. Results indicated that E. splendens, as a Cu-accumulator, played an important role in governing soil microbial activity and bacterial community composition in the rhizosphere in response to Cu stress.     

Transgenic Bt rice does not affect enzyme activities and microbial composition in the rhizosphere during crop development

Use of transgenic crops, including those expressing the insecticidal Cry protein from Bt, is increasing at a rapid rate in worldwide. Field and laboratory studies of transgenic Bt crops have been carried out to detect the persistence and activity of the Cry protein in soil and its effect on soil microorganisms to assess their risks to environment. However, there were few studies that evaluate the seasonal effects of Bt rice on rhizosphere soil microbial communities compared to those of insecticides commonly applied in paddy soil for the control of lepidopteran insects. In this study, seasonal effects of transgenic rice expressing the Cry1Ab insecticidal protein active against lepidoperan pests and the insecticide triazophos [3-(o,o-diethyl)-1-phenyl thiophosphoryl-1,2,4-triazol] on soil enzyme activities and microbial communities were compared under field conditions. During a 2-year field study, rhizosphere soil samples of transgenic-Bt rice (Bt), non-Bt parental rice (Ck) and non-Bt parental rice with triazophos (Ckp) applied were taken at four stages in the rice developmental cycle: seedling, booting, heading and maturing. Microbial processes were investigated by measuring different biochemical activities including those involved in C and P cycling. Denaturing gradient gel electrophoresis (DGGE) and terminal-restriction fragment length polymorphism (T-RFLP) analyses were used to compare rhizosphere microbial compositions. Some occasional and inconsistent effects of the application of triazophos on the bacterial composition in the rhizosphere soil of rice plant were found at the booting and heading stages as compared with that of transgenic-Bt rice. There were no statistically significant differences (P>0.05) in phosphatase activity, dehydrogenase activity, respiration, methanogenesis or fungal community composition in rhizosphere soil between Bt, Ck and Ckp over the rice cropping cycle. However, seasonal variations in the selected enzyme activities and microbial community composition in the rhizosphere soil of Bt, Ck and Ckp were clearly detected. These results suggested that the changes in rhizophere soil microbial community composition associated with the crop growth stage overweighed the application of triazophos and the cry1Ab gene transformation. KMD1 (Bt) rice expressing the cry1Ab gene had no measurable adverse effect on the key microbial processes or microbial community composition in rhizophere soil over 2 years of rice cropping.     

化肥配施有机肥对花生根际细菌群落结构及共存网络的影响

为评估化肥配施有机肥对花生根际细菌群落的影响，田间试验条件下研究了不施肥(CK)、施化学氮磷钾肥(NPK)和化学氮磷钾肥+有机肥配施(NPKM)对花生根际细菌群落多样性、结构和共存网络的影响。结果表明：NPKM处理下花生根际土养分状况明显改善，特别是有效磷的含量，较CK和NPK处理分别提高了5.31倍～12.16倍和3.24倍～6.50倍；而NPK处理下花生根际土养分状况并没有明显提升；Source Tracker分析显示，NPKM处理下根际细菌群落中只有2.1%～5.5%的物种来源于有机肥自身，但其花生根际细菌群落多样性在生育期前期要明显高于CK和NPK处理，而CK和NPK处理下根际细菌群落多样性差异不大；限制性主成分分析(CAP)显示，施肥措施和生育期均对根际细菌群落结构产生了显著影响，NPKM处理下花生根际土中富集了属于根瘤菌目(Rhizobiales)、梭菌目(Clostridiales)和芽孢杆菌目(Bacillales)这一类根际促生菌，根际细菌共存网络结构更加复杂，且网络中重要连接点的比例要也明显高于CK和NPK处理网络。可见，化肥配施有机肥有助于构建一个健康稳定的根际细...     

向日葵对土壤中铜的积累作用研究

温室内不同Cu浓度添加土壤的向日葵盆栽试验表明,向日葵植株的部分生物学性状如地上部干物质量、地下部干物质量、最大单叶面积随土壤中Cu浓度的增加而降低,土壤中添加20mg/kgCu对向日葵根部生长抑制作用最大,而植物高度在添加100mg/kgCu浓度时最高。且不同Cu浓度处理下向日葵对Cu的积累能力不同,但植物各部分Cu含量均随土壤中添加Cu浓度的增加而增加,但在100mg/kgCu浓度处理下,向日葵对Cu的积累主要集中在根部,地上部分Cu含量很低,在200mg/kgCu浓度处理下,向日葵叶中Cu含量超过根部,达857±297mg/kg干重,Cu积累的叶根比达1.27,说明当土壤Cu浓度较高时,Cu在向日葵地上部有较高的Cu积累,集中收获植株地上部分,可移出土壤中的过多有效铜,但生长受到抑制。使用向日葵修复高浓度Cu污染土壤时,还需考虑采用其他手段接种根际微生物、转基因、设施农业环境工程技术等来增加其生物产量。     

不同肥力红壤水稻土根际团聚体组成和碳氮分布动态

研究水稻种植期间表层土壤团聚体数量及其有机碳、全氮含量的变化,对揭示人为耕作的影响、认知土壤肥力的演变规律具有重要意义。选择两种不同肥力的红壤性水稻土进行田间根袋试验,分别于水稻插秧前、分蘖期、孕穗期和成熟期采样,分析了水稻生长过程中根际和非根际土壤团聚体组成、稳定性以及有机碳、全氮分布的动态变化。结果表明,低肥力土壤团聚体以0.25 mm大团聚体为主(56.2%~64.0%),0.25~1 mm粒级团聚体含量最高;除1~2 mm粒级外,水稻生育期内根际土壤各粒级团聚体含量均有显著变化;取样时期、根际作用与取样时期的交互效应对0.25~1 mm和0.053~0.25 mm粒级含量有显著影响。高肥力土壤中以0.25 mm微团聚体为主(59.8%~72.0%),0.053~0.25 mm粒级团聚体比例最高,取样时期显著影响0.25 mm大团聚体含量,根际作用与取样时期的交互效应对2 mm粒级含量有极显著影响。与非根际相比,根际土壤大团聚体的破坏率较低,平均重量直径(MWD)较高,种植水稻有助于提高根际土壤的稳定性。两种肥力土壤团聚体中有机碳和全氮含量均表现为1~2 mm粒级最高,0.053~0.25 mm粒级最低,大团聚体中显著高于微团聚体。根际土壤中,水稻成熟期各粒级团聚体有机碳含量与插秧前无显著差异,而分蘖期和孕穗期有明显波动;水稻的生长降低了大团聚体中的全氮含量,对高肥力土壤的影响更为显著。总体而言,低肥力土壤中,根际作用主要影响团聚体组成和稳定性,取样时期影响团聚体碳氮含量;高肥力土壤中,团聚体组成和碳氮分布受根际作用和取样时期的共同影响。     

Characterization of copper-resistant bacterial community in rhizosphere of highly copper-contaminated soil

The characteristics of copper (Cu)-resistant bacterial communities in a rhizosphere and a non-rhizosphere of the ditch reed, Phragmites, in a highly Cu-contaminated area near a copper mine were investigated. The total Cu concentration was 720 μg·g^–1 in the rhizosphere soil and 5 680 μg·g^–1 in the non-rhizosphere soil. In the rhizosphere, the multiplication of bacteria, particularly non-resistant bacteria, was promoted as compared with the non-rhizosphere. The properties of the bacterial community in the rhizosphere were quite different from those in the non-rhizosphere in terms of Cu sorption ability, growth rate and exopolymer production. Both the Cu-resistant bacteria and non-resistant bacteria in the rhizosphere grew more rapidly in media than those in the non-rhizosphere. For almost all the isolated Cu-resistant bacteria, exopolymer production was prompted by Cu stimuli especially for the isolates from the rhizosphere. The adverse effect of Cu on the growth rate was found to be small for the Cu-resistant bacteria producing exopolymers in a large quantity, suggesting the involvement of exopolymers in the detoxification of Cu. The role of Cu resistance in the bacterial chemotactic migration in the Cu-contaminated soils was not evident.     

磷高效转基因水稻OsPT4对红壤无机磷组成的影响

本研究以磷高效转基因水稻OsPT4为材料,以非转基因亲本日本晴(Nipp)和磷高效突变体水稻PHO2为对照,设施磷和不施磷2个处理,利用根盒试验研究磷高效转基因水稻OsPT4的种植对根际及非根际土壤无机磷组成的影响。结果表明:(1)Os PT4和PHO2的植株干重和磷含量均显著高于Nipp,而土壤全磷和无机磷总量均低于Nipp;(2)Os PT4和PHO2水稻根际和非根际土壤无机磷组分含量均表现为O-PFe-PAl-PCa-P;(3)施磷处理时,Os PT4和PHO2的根际土壤O-P、Ca-P含量显著低于Nipp,其非根际土壤Al-P、Fe-P和O-P含量也显著低于Nipp。不施磷处理时,Os PT4和PHO2的根际土壤Fe-P含量和非根际土壤Fe-P、O-P含量均显著低于Nipp,其根际土壤Ca-P含量显著高于Nipp。说明在供磷条件下,磷高效转基因水稻对A1-P、O-P和Ca-P的吸收活化能力较强,而缺磷条件下,磷高效转基因水稻可促进其根系对Fe-P的吸收利用。     

Community structure of microeukaryotes in a rice rhizosphere revealed by DNA-based PCR-DGGE

Rice roots provide a specific habitat for microorganisms in the rhizosphere of a submerged field through supply of oxygen and organic matter. Many studies have focused on the microbial community in the rice rhizosphere, but less is still known about the microeukaryotic community structure of rice rhizosphere. This study explored the microeukaryotic community structure of a rice rhizosphere through denaturing gradient gel electrophoresis (DGGE) targeting 18S rRNA gene. The rice roots and the rhizosphere soil samples, which were collected from a field under rice-wheat rotation system, were separately analyzed. To characterize the rice rhizosphere-specific community, the bulk soil of rice field and the wheat rhizosphere samples were also examined. DGGE fingerprints showed that the microeukaryotic community of rice roots were distinct from the community of the bulk soil and showed a temporal shift with the growth stage. The rhizosphere soil community was distinct from the root and bulk soil communities, but this could be explained by that the root and bulk soil communities were shared in the rhizosphere. The rice rhizosphere community was also distinct from those in the wheat rhizosphere. Microeukaryotes that characterized the rice rhizosphere (roots and the rhizosphere soil) community could be affiliated to Polymyxa, flagellates, and oomycetes, which suggested that microeukaryotes with various ecological roles, e.g., parasites, bacterial grazers, and decomposers, inhabit the rice rhizosphere. The results showed that the rice root and its growth stages are key factors shaping the microeukaryotic community structure in the rhizosphere.     

泥鳅生长及抗氧化 解毒酶系统对水体中转Cry1Ab/Ac基因水稻残遗物的响应

在泥鳅养殖水体中添加稻秆粉模拟水稻残遗物生境,研究了泥鳅生长和肝胰脏抗氧化酶(SOD、CAT)与解毒酶(GST)活性对转Cry1Ab/Ac基因水稻‘华恢1号’(HH1)的响应。设计以HH1稻秆粉10 mg·L?1、50 mg·L?1、100 mg·L?1和200 mg·L?1 4个梯度浓度处理泥鳅为试验组,以非转Bt基因水稻‘明恢63’(MH63)稻秆粉处理组为阴性对照,不加稻秆粉的基础饲养组为空白对照。结果显示:在4种稻秆粉浓度下,HH1组与MH63对照组泥鳅的特定生长率、肥满度、内脏系数及SOD、CAT和GST酶活性均无显著差异(P0.05);与空白对照比较,稻秆粉浓度升高对泥鳅生长的抑制逐渐增强,当浓度达到200 mg·L?1时,HH1组和MH63对照组泥鳅的特定生长率、内脏系数与CAT活性降低。研究结果表明,水体中低含量的转融合基因Cry1Ab/Ac水稻HH1稻秆粉对泥鳅的生长与生理酶活性没有明显影响,高浓度HH1和MH63稻秆粉均使泥鳅的生长和生理酶活性显著降低,这可能与养殖水体中浓度较高的悬浮稻秆粉妨碍了泥鳅的呼吸和滤食,及稻秆粉的分解降低了水体p H和溶氧量有关。