不同胁迫条件下化感与非化感水稻PAL多基因家族的差异表达

水稻苯丙氨酸解氨酶(PAL)调控酚酸类化感物质的合成代谢。编码PAL的基因是一个基因家族,包含至少11个基因成员,并受不同环境条件的调控。为了明确PAL基因家族中调控水稻化感作用的特定基因成员,本研究运用实时荧光定量PCR技术分析了低氮及稗草胁迫条件下强化感水稻PI312777与非化感水稻Lemont中根系的11个PAL成员基因的表达差异。结果表明,低氮和稗草胁迫条件下,PI312777和Lemont中的 PAL4和PAL10均不表达,其余9个PAL基因成员发生了不同程度的表达变化。其中,PAL11均上调表达,其分别在低氮处理和稗草胁迫的PI312777中上调3.29倍和1.07倍,而在相同处理下的Lemont中上调3.92倍和1.08倍;PAL3和PAL9则仅在低氮和稗草胁迫条件下的PI312777中上调表达,低氮胁迫分别为1.83倍和2.66倍,稗草胁迫为1.46倍和2.65倍;而这两个基因在相同处理下的Lemont中表达下调,低氮胁迫下调1.05和1.24倍,稗草胁迫下调1.14和1.16倍,推测PAL3和PAL9可能与胁迫初期调控水稻化感作用有关。     

低钾胁迫对水稻(Oryza sativa L.)化感潜力变化的影响

研究以国际公认的化感水稻P1312777和非化感水稻Lemont为供体,稗草（Echinochloa cru-galli L.）为受体,采用稻／稗共培体系,研究低钾胁迫对水稻化感潜力变化的影响及其机制。受体稗草的形态指标分析结果表明,低钾胁迫促使化感水稻P1312777对共培稗草的根长、株高和干重的抑制率均升高,增幅远大于非化感水稻Lemont。受体稗草生理生化指标分析结果表明,低钾胁迫下化感与非化感水稻对受体稗草保护酶系（SOD、POD、CAT）及根系活力的抑制作用增强,但化感水稻P1312777比非化感水稻Lemont的抑制程度大,且达极显著差异。实时荧光定量PCR分析结果表明,低钾胁迫下,化感水稻P1312777根部与叶部中酚类代谢的关键酶——苯丙氨酸解氨酶、肉桂酸-4-羟化酶、羟化酶、O-甲基转移酶的基因均上调表达,而非化感水稻根部相应酶均下调表达,叶部除苯丙氨酸解氨酶上调,其余酶也下调表达。而萜类代谢途径关键酶——HMG—CoA还原酶、角鲨烯合酶、单萜烯环化酶、倍半萜烯环化酶、二萜烯环化酶的基因,在两种水稻根部中呈现出相同或相似的表达方式（上调或下调）,即HMG—CoA还原酶上调表达,角鲨烯合酶、单萜烯环化酶、倍半萜烯环化酶、二萜烯环化酶下调表达;而在水稻叶部,非化感水稻Lmont相应酶基因表达方式仍然不变,化感水稻P1312777除了角鲨烯合酶下调表达,其余4个酶均上调表达。水稻根系分泌物中酚类物质的HPLC分析结果表明,低钾胁迫下,化感水稻P1312777根系分泌物中,所检出的酚酸类物质总量是正常营养条件下的2．30倍,而非化感水稻Lemont则是正常营养条件下的0．91倍。综合分析认为低钾胁迫下,化感水稻P1312777抑草能力增强主要是由于酚类代谢途径关键酶基因表达上调,导致酚类代谢途径旺盛,分泌出更多的酚类物质,进而破坏受体稗草保护酶系统,抑制了稗草的正常生长。     

水稻化感生物测试方法的比较及应用

选用8个化感作用潜力各异的水稻品种(系)：PI312777、Lemont、Moroberekan、IAC25、IACA7、IAC120、Batatais、Iguape Cateto为供试材料,以田间伴生稗草为受体材料,比较分析了目前较为通用的3种生物测试方法：琼脂迟播共培法(RSA)、石英砂迟播共培法(RSS)和根系分泌物培养法(SRE)对水稻化感潜力的测试效果．结果表明,RSA法应用于测试水稻化感作用潜力的效果最好,RSS法和SRE法的测试结果虽较为一致,但两者都存在不足．据此,运用RSA法对57个水稻材料进行了化感抗草种质资源的初步筛选,从中获得5个强化感作用潜力的水稻材料：Iguape Cateto、PI312777、Azucena、Taichung Native 1和IAC25．     

低磷营养胁迫下水稻化感抑草潜力的变化特性及其作用机理

在低磷(0.5 mg·L^-1) 营养胁迫下,运用生理生化方法分析了化感水稻PI312777（PI）与非化感水稻Lemont (Le) 对稗草抑制作用潜力的变化特性及其内在机理.结果表明,在低磷营养胁迫下,化感水稻品种PI对受体稗草根干重的抑制能力明显提高,在处理后的5 、10和15 d,其对稗草地下部干重的抑制率分别增加了5.64%、3.89%和12.13%,增加幅度比非化感水稻品种Le显著.生理生化分析结果表明,与正常营养条件相比,用低磷营养下生长的化感水稻PI的根系分泌物处理稗草5、10和15 d,受体稗草叶片中POD活性的促进率分别提高了20.19%、15.47%和6.68%,吲哚乙酸氧化酶活性的促进率分别提高了18.08%、17.71%和12.50%,硝酸还原酶活性的抑制率分别增加了13.89%、18.60%和2.10%. 在低磷营养胁迫下,化感水稻通过抑制受体植物的硝酸还原酶活性,影响其对氮营养的吸收,同时显著提高了吲哚乙酸氧化酶活性,减缓了受体稗草的生长速度,提高了其抑草作用潜力.     

不同供氮条件下水稻的化感抑草作用与资源竞争分析

为探讨化感水稻在不同氮素水平下的生物干扰现象,提出了一种新的测试方法———化感竞争分离法(allelopathyandcompetitionseparation basedbioassay,ACS),成功地区分了在稻/稗共生系统中水稻化感作用与资源竞争及其在不同N条件下的反应特性.结果表明,水稻PI312777具有较强的生物干扰能力.在不同N水平下,其资源竞争能力较强且表现稳定,但化感作用潜力则随供N水平的下降而明显增强.水稻Lemont不具化感作用潜力,在供N水平正常或充足条件下,其资源竞争能力减弱,但在N胁迫下却明显增强.这是在环境资源贫乏时,稻/稗共生系统中生态位竞争加剧的结果.     

苗期化感水稻对根际土壤微生物群落及其功能多样性的影响

水稻化感潜力的田间表现受根际微生物间接调控。以不种水稻的土壤为对照,通过平板计数法、氯仿熏蒸法和BIOLOG分析,探讨了水稻PI312777、IAC47Iguape Cateto和Lemont苗期根际土壤微生物的群落特征及其功能多样性。结果表明,水稻品种显著地影响其根际微生物生物量碳,不同品种水稻根际微生物生物量碳大小为:Iguape Cateto(441.0mg.kg-1)>IAC47(389.7mg.kg-1)>PI312777(333.2mg.kg-1)>Lemont(283.8mg.kg-1),对照土壤为129.3mg.kg-1;PI312777、IguapeCateto、IAC47、Lemont土壤的呼吸作用强度依次为1.404、1.019、0.671、0.488μgC.g-.1h-1,对照土壤仅为0.304μgC.g-.1h-1。不同品种水稻根际土壤微生物均以细菌占优势,占微生物总数的58.4%~65.6%,放线菌占32.2%~39.4%,占2.2%~2.8%。BIOLOG分析显示,不同水稻根际土壤的平均颜色变化率(AWCD)显著不同,总以强化感水稻PI312777最高,弱化感水稻Lemont最小,各土壤的AWCD值在培养144h时均达到最大值,此时PI312777、IAC47、Iguape Cateto和Lemont的AWCD值依次为对照土壤的1.89、1.79、1.60倍和1.43倍。主成分分析表明,从31个因素中提取的与碳源利用相关的主成分1、主成分2和主成分3依次能够解释变量方差的70.08%、11.33%和7.02%;与3个主成分显著正相关的碳源有19种,其中与主成分1显著相关的是酚酸、糖类、氨基酸和胺类,与主成分2显著相关的是酚酸、糖类和脂肪酸类,而与主成分3显著相关的是糖类和羟基酸,对各主成分起分异作用的主要碳源分别是胺类和氨基酸。相关分析表明,土壤微生物总量与细菌数量、莴苣根长抑制率IR、AWCD、MBC、MBR及Shannon指数间存在显著的正相关;土壤微生物总量与莴苣根长抑制率IR间的显著正相关与水稻品种有关。可见,水稻根际土壤微生物群落、活性和功能多样性与水稻品种密切相关,这些变化可能对水稻田间化感潜力起到重要的调节作用。     

外源水杨酸调控水稻化感抑草作用及其分子生理特性

为了探讨外源水杨酸（SA）调控水稻化感抑草效应的可行性,研究了不同浓度的外源SA对强化感水稻PI312777抑草效应的影响及其生理生化特性,并运用实时定量RT-PCR(FQ-PCR)技术检测SA介导的关键酶苯丙氨酸解氨酶基因（ZB8）的相对表达量.结果表明：外源SA能够诱导水稻化感抑草效应增强,而且这种诱导效应与SA的浓度和处理时间相关.叶面喷施SA后,PI312777对稗草的抑制率显著提高,其根系活力、超氧化物歧化酶（SOD）和过氧化物酶（POD）活性增强,过氧化氢酶（CAT）活性降低;而伴生杂草稗草的相应生理指标的变化趋势则相反.PI312777植株中的苯丙氨酸解氨酶（PAL）活性增强,总酚含量升高.0.2 mmol·L^-1的SA诱导水稻化感抑草效应最显著,该浓度下目的基因ZB8的相对表达丰度随处理时间先上调后下调,在24 h达到表达高峰.     

不同氮素供应下水稻酚类物质代谢关键酶基因差异表达

运用实时荧光定量PCR技术探讨了不同供氮条件下强化感与弱化感水稻苯丙烷代谢途径中9个关键酶基因的表达差异。结果表明,与正常氮素供应相比,低氮胁迫引起强化感水稻‘P1312777’中与酚类代谢途径相关的9个关键酶基因表达量均上调,表达量增幅在1.9～5.4倍之间,且以PAL基因上调倍数最大。而弱化感水稻‘Lemont’则相反,只有2个基因(苯丙氨酸裂解酶基因和肉桂酰CoA基因)表达上调,但上调倍数分别是强化感水稻对应的基因的22%和74%,其余的7个基因表达均下调,降幅在29%～72%之间,表明低氮胁迫诱发的水稻化感抑草能力增强与其体内酚类物质合成代谢增强有关。     

水稻根系响应镉胁迫的蛋白质差异表达

为探讨水稻根系对镉胁迫的分子生理响应,以抗镉水稻PI312777和镉敏感水稻IR24为材料,设置Cd~(2+)浓度为0、50和100μmol/L的水培试验,处理7 d后分析了水稻根系的蛋白质差异表达。结果表明,在镉胁迫下水稻PI312777和IR24根系有18个蛋白质发生了差异表达,其中的12个得到MALDI-TOF/MS鉴定。这些鉴定的蛋白功能可分四类:(1)与活性氧(ROS)胁迫相关的过氧化物酶(POD)、蛋氨酸腺苷转移酶(MAT)、类萌发素蛋白前体;(2)与谷胱甘肽(GSH)合成相关的S-腺苷甲硫氨酸合成酶(SAMS)、谷氨酰胺合成酶(GS)和谷氨酸脱氢酶(GDH);(3)与逆境胁迫相关的ABA胁迫诱导蛋白含HVA22域蛋白、ABA-胁迫-成熟诱导蛋白5(ASR5);(4)与细胞分裂调控相关的GTP结合核蛋白Ran-2。镉胁迫下SAMS和GTP结合核蛋白Ran-2在两种水稻根系均发生上调表达;MAT、POD、类萌发素蛋白前体和GS发生下调表达;依赖NADP-GDH、GDH和磷酸甘油酸变位酶在IR24根部均发生下调表达,在PI312777根部仅在100μmol/L Cd~(2+)处理发生下调表达;含HVA22域蛋白在PI312777根部上调表达,在IR24根部发生下调表达;ASR5在PI312777根部上调表达,在IR24根部的表达无显著差异;100μmol/L Cd~(2+)胁迫下60S酸性核糖体蛋白P0在水稻PI312777根部表达下调,在IR24根部表达上调。可见,镉胁迫使水稻根部ROS增加,形成氧化胁迫反应,造成毒害作用,而水稻根通过调节SAMS和GS提高GSH合成降低镉毒害。ASR5和HVA22蛋白等逆境胁迫蛋白的表达差异则是水稻品种间抗性差异的重要原因之一。     

旱直播条件下强弱化感潜力水稻根际微生物的群落结构

运用末端限制性片段长度多态性(T-RFLP)技术,以强化感水稻品种PI312777和弱化感水稻品种Lemont为材料,研究了旱直播模式下5叶期和7叶期化感水稻根际土壤微生物的组成和结构。结果显示:HaeⅢ和MspⅠ2种内切酶分别检测到9—87个TRFs、15—89个TRFs,各个样本的TRFs排序间存在极显著差异,表明各样本的微生物的相对丰富度存在极显著差异。用物种丰富度(S)、香隆指数(H)、Simpson多样性指数(D)、均匀度指数(E)评价了6个样本中TRFs的多样性,香隆指数最能体现2个酶切片断中TRFs的多样性,PI7中TRFs多样性最高。聚类分析和主成分分析表明旱作条件下强弱化感潜力水稻在生育前期(5叶期以前)根际微生物群落的组成与结构相似性较大,而7叶期强弱化感水稻及对照之间微生物群落差异较大,表明水稻根际微生物的组成既受生育期的影响又受水稻品种的影响。7叶期的化感水稻根际微生物呈现最大物种丰富度和香隆-威尔指数多样性,在其特有的34个菌中有7个属于粘细菌目,另外还有一些滑行菌和一些与氮循环相关的细菌等。粘细菌可能通过次生代谢产物抑制伴生杂草种子的萌发,降低杂草的密度从而提高化感水稻的化感作用潜力。     

Analysis of gene expressions associated with increased allelopathy in rice (Oryza sativa L.) induced by exogenous salicylic acid

The defense characteristics of allelopathic rice accession PI312777 and its counterpart Lemont induced by exogenous salicylic acid (SA) to suppress troublesome weed barnyardgrass (BYG) were investigated using the methods of suppression subtractive hybridization (SSH) and real-time fluorescence quantitative PCR (qRT-PCR). The results showed that exogenous SA could induce the allelopathic effect of rice on BYG and this inducible defense was SA dose-respondent and treatment time-dependent. PI312777 exhibited higher inhibitory effect than Lemont on BYG after treated with different concentrations of SA. The activities of cell protective enzymes including SOD, POD and CAT in the BYG plants co-cultured with PI312777 treated by SA were highly depressed compared with the control (co-cultured with rice without SA-treatment). Similar but lower depression on these enzymes except for CAT was also observed in the BYG plants when co-cultured with Lemont treated by SA. It is therefore suggested that allelopathic rice should be more sensitive than non-allelopathic rice to exogenous SA. Seventeen genes induced by SA were obtained by SSH analysis from PI312777. These genes encode receptor-kinase proteins, ubiquitin carrier proteins, proteins related to phenylpropanoid metabolism, antioxidant related proteins and some growth-mediating proteins. The differential expressions of these genes were validated in part by qRT-PCR in the two rice accessions. Our work elucidated that allelopathic rice possesses an active chemical defense and auto-detoxifying enzyme system such as the up-regulated enzymes involved in de novo biosynthesis of phenolic allelochemicals and the glutathione-S-transferase (GST) associated with xenobiotic detoxification.     

Genomic analysis of allelopathic response to low nitrogen and barnyardgrass competition in rice (<Emphasis Type="Italic">Oryza sativa</Emphasis> L.)

To explore the molecular mechanism of allelopathic rice in response to low nitrogen (N) supply or accompanying weed stress, allelopathic rice PI 312777 and its counterpart Lemont were grown under low N supply or co-cultured with barnyardgrass [Echinochloa crus-galli (L.) Beauv.] in hydroponics. The suppression subtractive hybridization (SSH) technique was employed to isolate the up-regulated genes in the treated rice accession. The results indicated that the expression of the genes associated with N utilization was significantly up-regulated in allelopathic rice PI 312777, and the higher efficiency of N uptake and its utilization were also detected in PI 312777 than that in Lemont when the two rice accessions were exposed to low N supply. This result suggested that the allelopathic rice had higher ability to adapt to low N stress than its non-allelopathic counterpart. However, a different response was observed when the allelopathic rice was exposed to accompanying weed (barnyardgrass) co-cultured in full Hoagland solution (normal N supply). It showed that the expression of the genes associated with allelochemical synthesis and its detoxification were all up-regulated in the allelopathic rice when co-cultured with the target weed under normal N supply. The results suggested that the allelopathic rice should be a better competitor in the rice-weed co-culture system, which could be attributed to increasing de novo biosynthesis and detoxification of allelochemicals in rice, consequently resulting in enhanced allelopathic effect on the target and preventing the autotoxicity in this process. These findings suggested that the accompanying weed, barnyardgrass is not only the stressful factor, but also one of the triggers in activating allelopathy in rice. This implies that the allelopathic rice is sensible of the existing target in chemical communication.     

Separation of allelopathy from resource competition using rice/barnyardgrass mixed-cultures

Plant-plant interference is the combined effect of allelopathy, resource competition, and many other factors. Separating allelopathy from resource competition is almost impossible in natural systems but it is important to evaluate the relative contribution of each of the two mechanisms on plant interference. Research on allelopathy in natural and cultivated plant communities has been hindered in the absence of a reliable method that can separate allelopathic effect from resource competition. In this paper, the interactions between allelopathic rice accession PI312777, non-allelopathic rice accession Lemont and barnyardgrass were explored respectively by using a target (rice)-neighbor (barnyardgrass) mixed-culture in hydroponic system. The relative competitive intensity (RCI), the relative neighbor effect (RNE) and the competitive ratio (CR) were used to quantify the intensity of competition between each of the two different potentially allelopathic rice accessions and barnyardgrass. Use of hydroponic culture system enabled us to exclude any uncontrolled factors that might operate in the soil and we were able to separate allelopathy from resource competition between each rice accession and barnyardgrass. The RCI and RNE values showed that the plant-plant interaction was positive (facilitation) for PI312777 but that was negative (competition) for Lemont and barnyardgrass in rice/barnyardgrass mixed-cultures. The CR values showed that one PI312777 plant was more competitive than 2 barnyardgrass plants. The allelopathic effects of PI312777 were much more intense than the resource competition in rice/barnyardgrass mixed cultures. The reverse was true for Lemont. These results demonstrate that the allelopathic effect of PI312777 was predominant in rice/barnyardgrass mixed-cultures. The most significant result of our study is the discovery of an experimental design, target-neighbor mixed-culture in combination with competition indices, can successfully separate allelopathic effects from competition.     

化感水稻根际微生物类群及酶活性变化

以化感水稻PI312777（PI）和非化感水稻Lemont（LE）为材料,分别测定不同水稻叶龄期（3～7叶期）根际微生物区系变化及根际土壤酶活性.结果表明,化感水稻明显影响土壤根际微生物类群及相关酶活性.化感水稻PI根际细菌、放线菌、固氮菌的数量高于非化感水稻LE,增幅分别在11.2%～28.3%、40%～78.6%和111.5%～173.9%之间,而真菌数量低于非化感水稻LE,最高仅为其值的25.5％,说明化感水稻PI对绝大多数细菌、放线菌、固氮菌生长有促进作用,对一些真菌生长有抑制作用.进一步分析表明,化感水稻PI对氨化细菌、亚硝酸细菌、硝酸细菌、好气性固氮菌、好气性纤维素分解菌、硫化细菌的生长具有促进作用,其中以氨化细菌、好气性固氮菌的更为明显,最低增幅分别为53.7％和57.6％;而对反硫化细菌、反硝化细菌生长有抑制作用,其值最高分别为非化感水稻的54.2％和50.6％.此外,化感水稻PI根系分泌物对脲酶、磷酸酶、蔗糖酶的活性具有促进作用,而对过氧化氢酶则呈抑制作用.     

水稻和稗草共生土壤微生物生物量碳及酶活性的变化

以稻田稗草、化感水稻PI312777和普通水稻辽粳9为试材,研究了田间稗草和水稻1∶1共生条件下,土壤微生物生物量碳及脱氢酶、脲酶和转化酶活性的变化.结果表明：在稗草 的干扰下,化感水稻PI312777根区土壤微生物生物量碳含量比单作减少了 50.52％（P<0.01）,而行间土壤微生物生物量碳含量增加;普通水稻辽粳9根区土壤 微生物生物量碳含量比单作减少了38.99％（P<0.01）,但其行间土壤微生物生物量碳含量无明显变化.两个水稻品种根区土壤脱氢酶活性均被显著抑制（P<0.05）,下降率都在20％以上;PI312777根区土壤脲酶和转化酶活性均被显著促进（P<0.01）;而辽粳9根区土壤转化酶活性也被显著抑制（P<0.01）,但脲酶活性无明显变化.化感水稻根区土壤微生物生物量碳含量的显著减少及脲酶、转化酶活性的增加是其化感特性的表现,表明土壤微生物和酶均参与了水稻和稗草的种间作用,化感水稻具有抗稗草干扰的明显优势.