三裂叶豚草的化感作用研究

 本文研究了在我国东北地区广泛蔓延的菊科杂草—三裂叶豚草(Ambrosia trifida)对大豆、玉米、小麦、水稻的化感作用(Allelopathy)。通过对三裂叶豚草的不同部位(挥发物、茎叶、根、根区土壤)的化感活性的研究,发现三裂叶豚草的挥发物和根区土壤对作物无明显的作用;茎叶部分的水浸液对实验作物的种子萌发和幼苗的幼根伸长有明显的抑制作用,同时使根系形态发生较大的变化;根的水浸液对作物的幼芽伸长有一定的促进作用。在上述的研究基础上,对不同的活性组分进行了GC、GC/MS分析．结果表明主要的化感成分可能为α-蒎烯、β-蒎烯、2-冰片烯、里那醇、冰片、4-萜品醇、樟脑、α-萜品醇、马鞭烯酮、橙花叔醇、法尼烯、勺叶桉醇等。由此我们分析三裂叶豚草主要是通过雨水淋溶的方式向周围环境释放化感物质,从而对其它植物产生影响,加强自身在自然界的竞争力。     

三裂叶豚草雄花序分化的气候效应分析

【背景】三裂叶豚草是一种外来恶性杂草,它的入侵不仅影响当地的生物多样性和生态系统,而且给农牧业造成巨大的经济损失。此外,其花粉量大,是引起人体一系列过敏反应的致敏源。【方法】通过对2008～2010年三裂叶豚草分化时期和气象因素进行调查,以当年分化开始前一个月至分化结束的日最高气温、日最低气温、日平均气温、相对湿度、日照时间等数据,分析影响三裂叶豚草雄花序分化的气象因子。【结果】雄花序从未分化期至成熟期平均需26d。三裂叶豚草营养生长后期,较短的日照时间和日平均气温、较高的相对湿度和较大的温差等环境条件有利于三裂叶豚草雄花序较早地开始分化。而在分化早期,长时间较高的相对湿度不利于雄花序的分化。【结论与意义】外界环境的变化能够影响三裂叶豚草雄花序的分化,对其分化开始时间起决定性作用。本研究为制定合理的三裂叶豚草防治措施提供了理论依据,同时为进一步研究其生物安全性提供了参考。     

豚草的化感作用研究

本文研究了在我国东北地区广泛蔓延的菊科杂草－－豚草对大豆、玉米、小麦、水稻的化感作用,实验针对豚草的挥发物、茎叶和根的淋溶物、根区土壤水浸液等的化感活性进行了研究,研究发现豚草的挥发物对大豆和玉米的种子萌发有一定抑制作用,根区土壤对农作物无明显的作用;茎叶部分的水浸液对几种农作物的种子萌发和幼苗的幼根伸长有明显的抑制作用,同时使根系形态发生较大的变化,根系的水浸液对作物的幼芽伸长有一定的促进作用。     

三裂叶豚草锈菌侵染寄主叶片的显微和超微观察

【背景】三裂叶豚草是我国重要的外来入侵植物之一,其传播速度快,已给我国造成巨大的经济损失。近年来发现的三裂叶豚草锈菌是一种对其具有生物防治潜力的病原菌。【方法】本文利用显微技术研究了三裂叶豚草锈菌的侵染过程及其对寄主结构的影响。【结果】三裂叶豚草锈菌菌丝可从多处侵入同一个叶肉细胞,胞间菌丝与叶肉细胞相接触可使部分细胞壁增厚。锈菌侵染使三裂叶豚草叶脉末梢导管分枝增多,造成三裂叶豚草水分代谢失调;叶片细胞内膜系统破碎化,细胞器结构受到不同程度的破坏,导致细胞内膜系统紊乱,细胞器结构稳定性降低。【结论与意义】豚草锈菌侵染破坏了三裂叶豚草叶片的细胞结构。本研究为深入研究豚草锈菌的致病机理奠定了基础。     

三裂叶豚草锈病发生和流行规律的研究

通过田间调查与定点系统观察,结合沈阳地区的气象条件,对三裂叶豚草锈病在沈阳地区的发生和流行规律进行了研究。结果表明：三裂叶豚草锈病属于喜高温、高湿型病害;该病于6月初在沈阳地区开始发病,可持续至9月,以7～8月发病最重。人工接种试验结果表明：在30℃和相对湿度96．9％条件下接种锈菌冬孢子,4d后三裂叶豚草即可发病;冷冻保藏（-20℃）可打破冬孢子休眠,在沈阳地区冬孢子是第二年锈病发生的初侵染菌源。苍耳柄锈菌三裂叶豚草专化型对三裂叶豚草表现出了显著的致病性、致死性及专一性,证明是防治三裂叶豚草的理想生防菌。     

豚草锈菌对三裂叶豚草光合生理特性的影响

【背景】外来人侵恶性杂草——三裂叶豚草在我国迅速蔓延,并对我国经济、人民健康、生态等方面造成巨大影响。【方法】本文运用光合仪（CIRAS-1）测定豚草锈菌侵染后的三裂叶豚草叶片的光合效率、蒸腾速率、叶表面蒸汽压差、胞间CO2浓度、气孔导度等指标,以探讨豚草锈菌影响三裂叶豚草光合作用的机制。【结果】豚草锈菌侵染三裂叶豚草叶片后,对叶片水分代谢与光合代谢有明显影响,从而影响叶片有机物质的合成。豚草锈菌侵染显症1—4d后,受侵染叶片蒸腾速率与气孔导度下降,光合作用有所加强,导致胞间CO2浓度下降,进而使叶片细胞水分代谢与光合代谢加强。显症4d后,随着叶片发病程度增加（4～5级）,胞间CO2浓度增加,蒸腾速率与气孔导度大幅降低,光合速率下降。【结论与意义】豚草锈菌能干扰三裂叶豚草叶片的光合生理活动。该结果可为防治三裂叶豚草提供参考。     

烟草水浸提液对葡萄根瘤蚜侵染危害的控制效应

【目的】检疫害虫葡萄根瘤蚜Daktulosphaira vitifoliae已经在我国多个地区葡萄园发现为害, 直接影响葡萄生长; 前期实验发现烟草水浸提液可有效控制离体根上根瘤蚜的存活率, 本研究进一步开展盆栽验证, 探讨烟草水浸提液对葡萄根瘤蚜侵染的控制效应及葡萄植株生长抑制的缓解作用。【方法】以两年生温室盆栽‘巨峰’自根苗为实验材料, 接种根瘤蚜虫卵35 d后进行烟草水浸提液处理, 处理后测定供试植株的根结数、生长量、根系活力、叶片光合速率及叶绿素荧光等指标。【结果】20 mg/mL和50 mg/mL的烟草水浸提液对根瘤蚜均有一定程度的抑制作用, 施药21 d后, 葡萄根部的新增根结数分别比侵染对照下降了42.9%和52.8%。烟草水浸提液处理还在一定程度上缓解了根瘤蚜侵染对植株的光合能力和荧光的抑制作用。20 mg/mL和50 mg/mL烟草水浸提液处理的株高分别比侵染对照提高了57.1%和7.7%; 根瘤蚜侵染降低了土壤中真菌、细菌和放线菌的数量, 烟草水浸提液处理进一步降低了真菌和放线菌的数量, 降低了由微生物带来的次生侵染几率。【结论】烟草水浸提液对葡萄根瘤蚜的侵染具有控制效果, 并可对葡萄根瘤蚜侵染已造成的寄主危害有一定的缓解作用。     

基于ISSR的豚草和三裂叶豚草遗传多样性研究

[目的]研究不同地理种群的豚草和三裂叶豚草的遗传多样性水平和遗传结构。[方法]应用筛选的13条ISSR引物对8个豚草居群和7个三裂叶豚草居群共240个样品进行分子标记。[结果]8个豚草居群128个样品,共扩增出304条带,多态性位点比率为98.68%;Shannon''s信息指数为0.6716,Nei''s基因多样性指数为0.4788。7个三裂叶豚草居群112个样品,共扩增出266条带,多态性位点比率为95.86%;Shannon''s信息指数为0.6593,Nei''s基因多样性指数为0.4670。豚草和三裂叶豚草各居群遗传距离较近。[结论]豚草和三裂叶豚草在居群间具有一定的遗传稳定性;居群内具有丰富的遗传多样性。豚草和三裂叶豚草遗传变异主要来源于居群内部。豚草各居群遗传距离和地理距离有显著相关性,三裂叶豚草各居群遗传距离和地理距离无显著相关性。     

三裂叶豚草雄花序分化期ABA、GAs和IAA的含量动态

【背景】三裂叶豚草为我国外来入侵有害植物,是世界公认的危害性杂草,不仅影响农牧业的生产,而且其花粉含有致敏蛋白,能引起人体一系列的过敏反应,危害人类健康。植物内源激素与植物生长发育的基本规律和代谢过程的调节控制密切相关。【方法】本文利用高效液相色谱法,研究了三裂叶豚草雄花序分化过程中3种内源激素的含量动态。【结果】在三裂叶豚草雄花芽分化过程中,赤霉素(GAs)的含量在分化初期比较平稳,从花蕾分化期开始急剧下降,雄蕊分化期又上升;吲哚乙酸(IAA)的含量始终处于缓慢上升的趋势;脱落酸(ABA)在花瓣分化期出现且迅速上升,在雄蕊分化末期达到峰值。3种激素中,ABA含量与三裂叶豚草花芽分化的相关性较明显。【结论与意义】ABA的出现及其含量是决定三裂叶豚草雄花序分化能否完成的一个关键因素。本研究为利用化学方法防治三裂叶豚草提供了依据。     

豚草和三裂叶豚草种子休眠规律研究

豚草和三裂叶豚草是菊科豚草属一年生草本植物,其种子休眠程度随生育地的纬度不同而有变化,纬度越高,种子成熟后进入休眠状态的比例越大,解除休眠所需的低温层积时间也越长。在高纬度的牡丹江市,成熟的豚草和三裂叶豚草种子全部进入休眠状态,低温层积１２周时萌发率达９５％以上,而在低纬度的南昌市,有１０％左右的豚草和三裂叶豚草种子没有进入休眠状态,低温层积８周时,萌发率即可达９５％以上。进入休眠状态的豚草和三裂叶豚草种子,不经过低温层积处理,在１５℃的室温下保存半年以上,也有一定比例的种子可以解除休眠。豚草和三裂叶豚草种子休眠机制可能是由抑制物质和促进物质复合体所控制,休眠种子含有高水平的抑制剂和低水平的促进剂,非休眠种子这种平衡转向有利于促进剂,不同纬度地区的温度差异和低温层积以及长期室温贮藏的呼吸代谢过程,可能对这种平衡产生影响,改变种子的休眠状态     

Soybean Seedling Extracts Inhibit Supernodulation

When soybean (Glycine max ) nodulation mutant nts 382 was inoculated with Bradyrhizobium japonicum, these plants nodulated significantly more than the parental type Bragg. Nts 382 seedlings displayed wild-type nodulation pattern when aqueous extracts of young Bragg shoots were applied to the cultural medium together with nutrient solution. Application of young nts 382 shoot extracts to Bragg seedlings did not result in any apparent increase in nodule number. In graft experiments, young shoots from mutant nts 382 induced supernodulation on Bragg root stocks, while no supernodulation was observed when Bragg seedlings were used as scion and grafted onto nts 382 root stocks. Further, the effectiveness of Bragg plant extracts to suppress supernodulation on nts 382 seedlings was found to depend on the age of the plant material used, being very ineffective with extracts from 60-day-old plants. The age effect was not observed in graft experiments. These findings suggest that soybean supernodulation phenomenon may be controlled by one or a few unknown chemicals or plant hormones.     

Degradation and utilization of exogenous allantoin by intact soybean root

Allantoin is produced by soybean [ Glycine max (L.) Merr. cv. Harper] nodules during nitrogen fixation. Decomposed nodules, therefore, may release allantoin into the surrounding soil. If the released allantoin were to be taken up by the plant without degradation, it is possible that the exogenous allantoin might repress subsequent nodulation. Using a hydroponic growth system, degradation of exogenous allantoin by soybean root was studied. In the presence of intact soybean root exogenous allantoin was rapidly degraded, yielding ca 2 mmol of urea per mmol of allantoin. Hydrolysis of urea to ammonia proceeded very slowly. Instead, the urea seemed to be taken up by the intact soybean root. The enzyme(s) required for the production of urea from exogenous allantoin could not be detected in the aqueous rooting medium. Therefore, these enzymes seem to be attached to the exterior surface of the intact soybean root. This study shows that exogenous allantoin can be readily degraded and assimilated by the growing soybean plant.     

Influence of Nematodes and Light Sources on Growth and Nodulation of Soybean

The influence of nematodes on nodulation of soybean varied according to their modes of parasitism. In the greenhouse, nodule formation was stimulated by the endoparasites, Meloidogyne hapla and Pratylenchus penetrans, but was inhibited slightly by the ectoparasite, Belonolaimus longicaudatus. In an experiment under controlled conditions in a phytotron, Heterodera glycines severely inhibited nodule formation, whereas plants inoculated with B. longicaudatus and P. penetrans had more nodules per g root than nematode-free plants. Nitrogen-fixing capacity, however, was inhibited by all three nematode species. Different light sources used in the phytotron experiment also influenced growth and nodulation of soybean. A fluorescent plus incandescent light regime resulted in plants with the greatest shoot weight, pod number, and nodules per g root. Plants grown under Lucalox lamps had excessive stem elongation.     

Regulation of nodulation in the soybean-Rhizobium symbiosis : strain and cultivar variability

Double inoculation (15 h apart) of the soybean cultivar Williams with Bradyrhizobium japonicum I-110ARS reveals a rapid regulatory plant response that inhibits nodulation of distal portions of the primary root (M Pierce, WD Bauer 1984 Plant Physiol 73: 286-290). Only living, homologous rhizobia elicit the response. We conducted similar double inoculation experiments to test the hypothesis that this is a universal phenomenon in soybean symbioses. We investigated interactions of the cultivar McCall with the slow-growing strain Bradyrhizobium sp. 3185 (=3G4b16) and strains of the fast-growing soybean symbiont, Rhizobium fredii (USDA191 [Nod⁺ on McCall] and USDA257 [Nod⁻ on McCall]). Nodulation was not detectably inhibited when USDA257 was included in various combinations with an inoculum of USDA191. Strain USDA257 cohabited nodules with strain USDA191 when plants were inoculated sequentially with both strains, but USDA257 did not nodulate McCall when a sterile culture filtrate of USDA191 was added to USDA257 inoculum. There was only a slight inhibition of nodulation of distal portions of the primary root in double inoculation experiments with McCall and strain 3185. Because these results were unexpected, we repeated the experiments with Williams and strain I-110ARS. The response was similar to that observed in the McCall × 3185 interaction. Regulation of nodulation on the primary root thus appears to be variable and depend on strain X cultivar interactions.     

脲酶抑制剂氢醌对大豆结瘤、固氮和木质部溶质氮形态的影响

首次报导了在白浆土和砂壤土上使用氢醌(HQ)抑制土壤脲酶活性,有效地缓解尿素分解产物及其随后的氧化产物对大豆结瘤和固氮活性的抑制效应,结果表明:1.HQ浓度在40PPM以内对大豆幼苗生长及初生结瘤表现促进作用;进一步提高HQ浓度将使大豆根系生长受阻变态而阻止结瘤。2.HQ(10—50PPM)提高了离体活性大豆根瘤类苗体悬液的耗氧量(79.4—86.1％)和琥珀酸脱氢酶活性(124.7—138.4％)。3.盆栽和田间试验证实,由于HQ缓解了尿素的分解,从而颇大减轻了尿素对大豆结瘤和固氮(乙炔还原活性)的抑制效应;通过大豆木质部中溶质氮形态(酰胺、酰脲和硝酸盐)的分析进一步证实了,大豆植株从根部向地上部运输的氮素形态同土壤氮转化强度和根瘤固氮强度(酰脲相对丰度)之间的紧密联系。4.由于麦秸还田土壤脲酶活性提高,故应提高HQ剂量;与此同时,通过麦秸的“氮因子效应”便能完全解除尿素对大豆结瘤固氮的抑制,并为大豆籽实发育提供了丰富的土壤氮源。     

氮肥和水分条件对长喙田菁生长、结瘤和固氮的影响

 盆栽试验研究了长喙田菁(Sesbania rostrata) 茎瘤固氮根瘤菌（Azorhizobium caulinodans）共生体系在不同水分和无机氮肥条件下的生长、结瘤和氮积累。水分处理为: 不浸水、浅浸水(土壤水分为田间持水量)和深浸水, 氮肥处理分别为每千克土施加无机氮肥10 mg、20 mg和40 mg。结果表明,水分条件对共生体系有较大影响, 浸水环境虽然抑制了根瘤的形成, 却促进了茎瘤的结瘤作用和长喙田菁根系的生长, 田间持水量状态下共生体系能获得最大的生物量和氮累积量; 无机氮肥对共生体系的影响受水分供应的影响较大,实验氮肥施用浓度范围内,长喙田菁的结瘤作用对复合态氮无负敏感反应,明显有别于一般根瘤体系的复合态氮反应。     

Effects of co-inoculation with arbuscular mycorrhizal fungi and rhizobia on soybean growth as related to root architecture and availability of N and P

Soybean plants can form tripartite symbiotic associations with rhizobia and arbuscular mycorrhizal (AM) fungi, but little is known about effects of co-inoculation with rhizobia and AM fungi on plant growth, or their relationships to root architecture as well as nitrogen (N) and phosphorus (P) availability. In the present study, two soybean genotypes contrasting in root architecture were grown in a field experiment to evaluate relationships among soybean root architecture, AMF colonization, and nodulation under natural conditions. Additionally, a soil pot experiment in greenhouse was conducted to investigate the effects of co-inoculation with rhizobia and AM fungi on soybean growth, and uptake of N and P. Our results indicated that there was a complementary relationship between root architecture and AMF colonization in the field. The deep root soybean genotype had greater AMF colonization at low P, but better nodulation with high P supply than the shallow root genotype. A synergistic relationship dependent on N and P status exists between rhizobia and AM fungi on soybean growth. Co-inoculation with rhizobia and AM fungi significantly increased soybean growth under low P and/or low N conditions as indicated by increased shoot dry weight, along with plant N and P content. There were no significant effects of inoculation under adequate N and P conditions. Furthermore, the effects of co-inoculation were related to root architecture. The deep root genotype, HN112, benefited more from co-inoculation than the shallow root genotype, HN89. Our results elucidate new insights into the relationship between rhizobia, AM fungi, and plant growth under limitation of multiple nutrients, and thereby provides a theoretical basis for application of co-inoculation in field-grown soybean.     

Autoregulation of soybean–Bradyrhizobium nodule symbiosis is controlled by shoot or/and root factors

Two strains of Bradyrhizobium japonicum were evaluated with five commercial cultivars of soybean (Clark, Crauford, Davis, Centaur, and Nessen) and one hypernodulating mutant NOD1-3. The hypernodulating NOD1-3 produced 30–50 times the number of nodules of commercial cultivars either inoculated with B. japonicum strain USDA 123 or RCR 3409. Grafting of NOD1-3 shoots to Clark and Davis roots induced hypernodulation on roots of Clark and Davis but did not enhance nodulation when grafted onto the roots of Crauford, Centaur, and Nessen. In contrast, the shoots of Clark, Davis, Centaur and Nessen significantly inhibited nodule formation on the root of NOD1-3. However, Crauford shoots did not alter nodule formation on the roots of NOD1-3 as compared with self-grafts of NOD1-3. It appears that the shoot of NOD1-3 has the ability to alter autoregulatory control of nodulation of Clark and Davis cultivars, but not of Crauford, Centaur and Nessen. The results suggest that the regulation of nodulation in soybean cultivars Clark and Davis is controlled by the shoot factors, while the Crauford was root controlled. Reciprocal grafts between NOD1-3 and Centaur or Nessen indicate that both shoot and root factors are involved in regulation of nodulation. The results suggested that the regulation of nodulation did not depend on bradyrhizobial strains. The shoot control of hypernodulation may be causally related to differential root isoflavonoid levels, which are also controlled by shoot. Application of daidzein significantly enhanced the nodulation and nitrogenase activity of soybean cv. Clark. Root control of restricted nodulation of soybean cv. Centaur did not respond to the addition of daidzein in nutrient solution indicating that this character is not related to isoflavonoids. Therefore, autoregulation in Clark and Centaur plants may be separate events in legume–rhizobia symbiosis and regulated by different kinds of signals.     

接种量对费氏中华根瘤菌HN01DL根圈定殖与结瘤的影响

在灭菌土和未灭菌土盆栽系统中 ,研究了大豆种子的表面初始接种量对费氏中华根瘤菌HN0 1DL在大豆根圈中的定殖动态与结瘤的影响。结果表明 ,与 3个接种量对应的早期根圈定殖动态和水平有明显差异 ,但随着宿主植物根系的生长其差异逐渐减小 ,整个定殖动态曲线的变化和定殖密度趋向一致 ,并且发现 3个不同的初始接种量对HN0 1DL在大豆黑农 33根系上的结瘤数量和占瘤率没有显著影响。