大豆/玉米间作体系中接种AM真菌和根瘤菌对氮素吸收的促进作用

利用大豆和玉米之间根系不同分隔方式的盆栽试验,研究了在玉米/大豆间作体系中接种大豆根瘤菌、AM真菌Glomus mosseae和双接种对间作体系氮素吸收的促进作用。结果表明,双接种处理显著提高了大豆及与其间作玉米的生物量、氮含量,双接种大豆/玉米间作体系总吸氮量比单接AM菌根、根瘤菌和不接种对照平均分别增加22.6%、24.0%和54.9%。大豆促进了与其间作玉米对氮素的吸收作用,在接种AM真菌和双接种条件,间作玉米的AM真菌侵染率提高,大豆根瘤数增加; 接种AM真菌处理,不分隔和尼龙网分隔比完全分隔玉米吸氮量的净增加量是未接种对照的1.8、2.6倍,双接种处理分别是对照的1.3和1.7倍。说明在间作体系中进行有效的根瘤菌和AM真菌接种,发挥两者的协同作用对提高间作体系土壤养分利用效率,进一步提高间作体系的生产力有重要的意义。     

接种根瘤菌对蚕豆/玉米间作系统产量及结瘤作用的影响

通过田间试验,研究了不同施氮水平下蚕豆接种根瘤菌GS374对蚕豆/玉米间作系统产量及蚕豆结瘤作用的影响。结果表明,不施氮处理接种根瘤菌所获得的单作或间作系统产量与不接种但施N225kghm-2的相应系统产量相当,且施N225kghm-2处理接种仍能促进蚕豆的结瘤作用。统计分析表明,与不接种根瘤菌、蚕豆单作、不施氮相比,接种、蚕豆/玉米间作、施氮均极显著地提高了蚕豆生物学产量,但只有间作能显著增加其籽粒产量;施氮显著增加玉米生物量和籽粒产量。施N225kghm-2后,蚕豆接种、间作对玉米生物量无显著影响;但不施氮时蚕豆接种显著提高了与之间作的玉米籽粒和生物学产量,增幅分别为34.3%和25.6%。接种根瘤菌显著提高了不同氮处理以籽粒产量为基础计算的土地当量比和不施氮处理以生物学产量为基础计算的土地当量比。蚕豆接种根瘤菌与不接种相比,其单株根瘤数和根瘤干重均显著增加;间作与蚕豆单作相比对根瘤数的影响较小,但显著促进了蚕豆单株根瘤干重的增加。因此,本研究认为豆科作物接种合适的根瘤菌,是进一步提高豆科/禾本科作物间作系统间作优势的又一重要途径。     

丛枝菌根真菌与根瘤菌接种对大豆根瘤分布及磷素吸收的影响

在温室条件下,采用石英砂盆栽试验研究了大豆(冀豆6号)接种丛枝菌根真菌（Glomous mosseae）与根瘤菌 （Bradyrhizobium japonicum）对根瘤的形成、分布以及磷素吸收效率的影响。结果表明,大豆生长至开花期（接种后56 d）,与单接种根瘤菌处理相比,双接种AM真菌和根瘤菌显著增加大豆生物量、氮、磷含量、根系上的总根瘤数。单接种根瘤菌条件下,总根瘤数的48.4%分布在主根上,51.6%分布在侧根上;根瘤菌与AM真菌双接种时,总根瘤数的32.5%分布在主根上,67.5%分布在侧根上。双接种处理的侧根根瘤的固氮酶活性显著高于单接种处理的。双接种条件下大豆侧根中AMF侵染增强,尤其是结根瘤侧根上的AM真菌的侵染率高于未结瘤的侧根的菌根侵染率。接种后28 d单接种菌根真菌处理显著高于双接种处理的植株磷的吸收效率;而56 d 时趋势相反。以上结果表明,AM真菌侵染改变根瘤在大豆根系上的分布,根瘤数量、分布与结根瘤侧根上AM真菌的侵染强度存在正相关关系。     

新开垦土壤上构建玉米/蚕豆-根瘤菌高效固氮模式

为了在新开垦土壤上构建高效种植模式,本文采用温室盆栽和大田试验相结合的方法,选用4种根瘤菌接种方式(保水剂拌种、清水拌种、三叶期灌根和种子丸衣化)接种4种不同蚕豆根瘤菌(NM353、CCBAU、G254和QH258),分析接菌后新开垦土壤上玉米/蚕豆间作体系的生产潜力、地上部氮素吸收和结瘤特性以及生物固氮等方面的优势,拟为该体系筛选出高效的根瘤菌及其接种技术。结果表明:接种NM353后,玉米/蚕豆间作体系中蚕豆籽粒产量比单作平均增加152.84%,而玉米保持相对稳产;以保水剂拌种的方式接种NM353的间作蚕豆地上部氮素积累量最高,蚕豆结瘤数、瘤重、固氮比例和固氮量均高于本试验中其他3种方式接种的根瘤菌。在盛花期和盛花鼓粒期,接种NM353蚕豆的固氮比例比接种CCBAU的分别高19.1%和11.1%,在各个生育时期两者固氮量之间差异均达显著水平;接种NM353与接种其他菌种间固氮量和固氮比例差异更显著。因此,在新开垦土壤上,用保水剂拌种的方式对间作蚕豆接种NM353根瘤菌,构建玉米/蚕豆-根瘤菌高效固氮体系,为新开垦土壤合理开发利用的可持续发展模式。     

丛枝菌根真菌和根瘤菌对连作花生养分吸收及土壤微生物特性的影响

探讨接种丛枝菌根(AM)真菌和根瘤菌对连作花生作用效果及可能机制,有益于缓解花生连作障碍,促进花生养分高效和持续高产。在花生典型种植区,选择有代表性的酸性砂姜黑土,设置不接种(CK)、接种AM真菌(AM)、接种根瘤菌(Rb)、双接种(AM+Rb)4个处理,采用微区试验,研究AM真菌与根瘤菌对花生生长、根系形态、养分吸收及土壤微生物特性的影响。结果表明:接种处理增加了花生第一侧枝长和分枝数,显著提高了花生根和地上部生物量、荚果重和根瘤数,其中AM+Rb处理提高效果最显著。同时AM+Rb处理的花生根系总根长、总表面积、总体积分别显著提高30.1%、20.2%和59.7%,土壤微生物总量、细菌/真菌、放线菌/真菌明显提高,不同部位氮、磷、钾、钙、镁积累量显著增加,效果优于单接种。比较AM真菌和根瘤菌2种接种方式,Rb处理的花生不同部位氮积累量较高,而AM处理的根系形态状况较好,且花生不同部位磷、钾、钙、镁吸收量较高。可见,在酸性砂姜黑土区,接种AM真菌和根瘤菌尤其是双接种有益于改善根系形态状况和根际微生物环境,增强花生养分吸收能力,从而促进花生的生长及产量的提高。     

间作小麦和接种AM真菌协同提高蚕豆抗枯萎病能力和根际微生物碳代谢活性

【目的】接种丛枝菌根 (arbuscular mycorrhizal,AM) 真菌和间作均是防治蚕豆枯萎病的有效方法,从土壤微生物学角度研究两者协同减轻蚕豆枯萎病的机理,对控制蚕豆枯萎病传播具有重要意义。【方法】利用盆栽试验方法,进行了间作和接种AM真菌摩西管柄囊霉 (Funneliformis mosseae,Fm) 和扭形球囊霉 (Glomus tortuosum,Gt) 试验。设蚕豆单作对照 (MF)、蚕豆小麦间作 (IF)、蚕豆单作接种Fm (MFFm)、蚕豆小麦间作接种Fm (IFFm)、蚕豆单作接种Gt (MFGt)、蚕豆小麦间作接种Gt (IFGt) 6个处理。于蚕豆开花期 (生长70天) 取土壤样品,测定蚕豆幼苗生长、枯萎病发生、根际镰刀菌数量和微生物碳代谢活性。【结果】间作显著增加蚕豆幼苗干重93.0%、降低蚕豆枯萎病病情指数71.4%,接菌显著增加蚕豆幼苗干重55.3%、降低病情指数76.6%,其中接种Fm真菌对蚕豆幼苗干重的影响更大,对病情指数的抑制效果更好。间作接菌显著增加蚕豆幼苗干重100%、降低病情指数89.8%。Biolog微平板测试结果显示,间作提高根际微生物碳代谢活性32.3%;接菌提高微生物活性85.4%;间作接菌提高微生物活性122%。主成分分析结果表明,间作和接菌均明显改变了根际微生物的群落结构,并主要改变了对碳水化合物类、氨基酸和羧酸类碳源的利用。相关性分析结果显示,枯萎病发病率和病情指数与根际镰刀菌数量呈极显著正相关关系,与AWCD值、Shannon多样性指数和丰富度指数均呈极显著负相关。【结论】蚕豆与小麦间作和接菌对抑制蚕豆枯萎病和促进蚕豆生长均具有积极效应,间作显著提高了AM真菌的定殖率,二者协同提高了根际微生物活性,改变了微生物群落结构,并抑制了病原菌增殖,进而控制蚕豆枯萎病发生。     

低磷土壤接种菌根真菌和解磷细菌对大田玉米生长和磷吸收的影响

丛枝菌根真菌(Arbuscular mycorrhizal fungi,AMF)能与多数陆生植物共生,促进植物吸收养分尤其是磷。解磷细菌(Phosphate-solubilizing bacteria,PSB)可以活化土壤中难溶性无机磷和有机磷。本研究采用苯菌灵对田间低磷土壤中土著AM真菌进行灭菌,并接种外源AM真菌(Glomusversiforme,G.v)和PSB(Pseudomonassp.),研究AM真菌和PSB接种对不同生育期玉米生长、磷养分吸收和产量的影响。结果表明,施用苯菌灵能够有效地抑制土著AM真菌对玉米根系的侵染,未施用苯菌灵处理中土著AM真菌促进了玉米前期和收获期的生长,提高了玉米吸磷量;接种Pseudomonas sp.促进了玉米六叶期根系的生长;接种外源AM真菌G.v促进了玉米六叶期和收获期地上部的生长,但降低了玉米产量。双接种Pseudomonas sp.和G.v对玉米生长、吸磷量和产量未表现出显著的协同效应。     

根瘤菌菌株NM353对小麦/蚕豆间作体系中作物生长及养分吸收的影响

采用不同根系分隔方式(小麦与蚕豆根系完全分隔、尼龙网分隔和不分隔)研究了间作蚕豆接种根瘤菌菌株NM353,在施氮和不施氮情况下,蚕豆和小麦的生长和养分吸收状况。结果表明,无论何种分隔方式和施氮与否,接种根瘤菌菌株NM353对蚕豆的生长都好于不接种;同时,间作小麦也通过根系的相互作用受益。在施氮情况下,接种与不接种处理相比,蚕豆生物量在三种分隔方式中依次增加了15%、16%和5%;吸氮量依次增加了17%、9%和12%;而根系不分隔并接种根瘤菌NM353还改善间作小麦的生长,其生物量、吸氮量比不接种时分别增加了13%和22%。因此,小麦/蚕豆间作中通过选择合适的菌株进行接种,并配合适当的氮肥施用,可以充分发挥豆科生物固氮作用,并改善与之间作的作物氮素营养。     

成都平原蚕豆高效根瘤菌的筛选及其促生功能初步评价

[目的]筛选适用于成都平原的高效广谱蚕豆根瘤菌,并对其相关促生功能进行初步评价,为成都平原高效蚕豆根瘤菌剂的研制与应用提供科学依据。[方法]供试6株根瘤菌由课题组前期分离自成都平原,其与四川主栽蚕豆‘大白蚕豆’匹配良好,采用常规方法测定了这6个菌株分泌生长素及溶磷能力。菌株与蚕豆品种匹配试验采用低氮砂培法,供试蚕豆品种为成都平原主栽品种‘成胡14’、‘成胡15’;两个品种的蚕豆种子播种后,分别接种6个菌株,以不接种为对照(CK),光照(控温22~25℃、光照强度2800 lx左右、日照时间14 h)下培养41天后收获,测定植株生物量和根瘤数。然后,对匹配性试验筛到的两株高效广谱根瘤菌进行田间验证,供试蚕豆品种为成胡15,将2个根瘤菌制备的菌剂(活菌数5.0×10^8 CFU/g以上,载体为泥炭)进行拌种,以不接菌处理的灭菌泥炭为对照。在盛花期(生育期105 d)采样测定株高、根瘤数、地上部分植株干重;收获期(生育期200 d)采样测产;测定两个时期植株样品氮、磷、钾含量。盛花期采用BOX-PCR分子标记法测定接种根瘤菌占瘤率,同时提取接种菌株SCAUf73、SCAUf76的总DNA,比较接种菌株及相应根瘤类菌体根瘤菌DNA的BOX-PCR分子指纹图谱。用多位点基因序列分析法对田间验证的优良菌株SCAU73进行分类地位研究。[结果]1)通过匹配性砂培试验,筛选到2株与2个成都平原主栽蚕豆品种均高效匹配的根瘤菌SCAUf73、SCAUf76。SCAUf76、SCAUf73能使‘成胡14’、‘成胡15’植株干重较CK显著增加40.5%~61.6%。2)通过两株菌田间接种试验发现,接种SCAUf76处理的蚕豆产量与CK差异不显著;接种SCAUf73处理蚕豆植株干重、全氮含量等指标均高于CK,籽粒鲜产比CK显著增加25.0%,并显著高于SCAUf76,其占瘤率达到33%。3)多位点基因序列分析表明,SCAUf73可能是Rhizobium的一个新类群。4)促生性试验表明,6株菌都能分泌生长素(IAA),最大分泌量为21.0 mg/L(SCAUf76);供试菌株的溶磷能力不明显。[结论]从成都平原上筛选的6个菌株中,SCAUf73具有分泌IAA能力,与蚕豆接种后,占瘤率达33%,可显著促进蚕豆氮素吸收积累,提高蚕豆籽粒产量。与成都平原的主栽蚕豆品种匹配的高效广谱根瘤菌SCAUf73,适用于成都平原的蚕豆生产。     

氮肥和接种根瘤菌对豌豆/玉米间作产量和水分利用效率的影响

豌豆/玉米间作是河西绿洲灌区面积最大的间作模式,也是当地重要的高产高效种植模式之一。针对目前氮肥过量施用和豆科作物生物固氮被忽视的实际,2011年和2012年在甘肃省武威市凉州区进行了豌豆/玉米间作大田试验,研究不同施氮量下,豌豆接种根瘤菌对豌豆/玉米间作体系作物籽粒产量和水分利用效率的影响,旨在为河西绿洲灌区豌豆/玉米间作体系节肥、高产的氮肥用量和接菌增产作用提供理论依据。结果表明:施用氮肥对豌豆产量影响不显著。接种根瘤菌后单作豌豆比不接菌处理两年平均增产12.7%,间作豌豆产量比单作两年平均增产61.1%,间作豌豆接种根瘤菌比不接菌两年平均增产4.8%。单作豌豆以施氮量75 kg(N)·hm-2接菌处理的产量最高,达到2 735 kg·hm-2;而且在此施氮量下接菌比不接菌两年平均增产达22.8%。施用氮肥对玉米的增产效果显著,施氮量在300 kg(N)·hm-2时单作玉米产量为14 394 kg·hm-2,间作比单作两年平均增产61.8%;间作豌豆带接菌较不接菌玉米两年平均增产3.3%。土地当量比在不同施氮量和接种根瘤菌的条件下都大于1。豌豆水分利用效率随施氮量增加而减小,最大值为不施氮的12.9 kg·mm-1·hm-2;玉米水分利用效率随施氮量增加先增大后减小,以施氮量300 kg(N)·hm-2处理为最高,达25.0 kg·mm-1·hm-2。综上所述,在豌豆/玉米间作体系中,玉米高产、高水分利用效率的施氮量为300 kg(N)·hm-2,豌豆高产高效的施氮量为75 kg(N)·hm-2。在大田生产中,接种根瘤菌对豌豆和玉米增产作用明显。     

Effects of epigeic earthworm (Eisenia fetida) and arbuscular mycorrhizal fungus (Glomus intraradices) on enzyme activities of a sterilized soil–sand mixture and nutrient uptake by maize

A pot experiment was conducted to investigate the effect of epigeic earthworm (Eisenia fetida) and arbuscular mycorrhizal (AM) fungi (Glomus intraradices) on soil enzyme activities and nutrient uptake by maize, which was grown on a mixture of sterilized soil and sand. Maize plants were grown in pots inoculated or not inoculated with AMF, treated or not treated with earthworms. Wheat straw was added as a feed source for earthworms. Mycorrhizal colonization of maize was markedly increased in AM fungi inoculated pots and further increased by addition of epigeic earthworms. AM fungi and epigeic earthworms increased maize shoot and root biomass, respectively. Soil acid phosphatase activity was increased by both earthworms and mycorrhiza, while urease and cellulase activities were only affected by earthworms. Inoculation with AM fungi significantly (p?<?0.001) increased the activity of soil acid phosphatase but decreased soil available phosphorus (P) and potassium (K) concentrations at harvest. Addition of earthworms alone significantly (p?<?0.05) increased soil ammonium-N content, but decreased soil available P and K contents. AM fungi increased maize shoot weight and root P content, while earthworms improved N, P, and K contents in shoots. AM fungi and earthworm interactively increased maize shoot and root biomass through their regulation of soil enzyme activities and on the content of available soil N, P, and K.     

丛枝菌根真菌对玉米锌、磷拮抗作用的影响

【目的】 利用丛枝菌根 (arbuscular mycorrhizal fungi,AM) 真菌与作物互利共生的关系来提高作物对锌的吸收是缓解锌、磷拮抗作用的途径之一,本试验在不同锌、磷浓度条件下,研究了接种AM真菌对玉米侵染和锌、磷吸收的影响,以期为揭示AM真菌影响锌、磷拮抗作用的机理提供理论依据。 【方法】 采用盆栽试验,设置三个施磷水平 (0、200 、400 mg/kg),两个施锌水平 (0、5 mg/kg),2个接菌水平[接菌 (+AM)和不接菌 (–AM)],共12个处理,每个处理4次重复。利用生物镝灯补充光照,在人工光照植物培养室内植株生长50天后,地上部与根部分别收获,测定其生物量、锌磷的含量和吸收量。 【结果】 施磷和接种AM真菌都显著提高了玉米植株生物量,不施锌条件下,施磷从0 mg/kg增加到400 mg/kg,玉米植株地下部和地上部生物量分别提高6.67倍、9.30倍。接种处理对玉米植株生物量的影响也有相同的趋势。在锌水平为5 mg/kg、磷水平为200 mg/kg的条件下,接种AM真菌玉米植株地下部磷的吸收量和含量分别增加了110%、55%;在同一锌、磷供给条件下,接种AM真菌显著提高了玉米对锌的吸收量,地下部和地上部分别是未接种处理的1.71倍和1.68倍。随着施磷水平的不断提高,玉米植株的锌含量会逐渐下降。不施锌条件下,施磷从0 mg/kg增加到200 mg/kg,玉米植株地上部锌含量降低36%,与之相反,接种AM真菌后地上部锌含量增加35%。但在高磷条件 (400 mg/kg) 下,接种AM真菌对玉米植株锌磷含量和吸收量影响均不显著。 【结论】 在本试验条件下,施磷抑制玉米对锌的吸收,接种AM真菌可提高玉米锌磷的含量和吸收量,有效缓解玉米锌磷拮抗作用,改善玉米的锌营养状况。      

地下部分隔对蚕豆/玉米间作氮素吸收和土壤硝态氮残留影响

利用田间试验,探讨了地下部分隔对蚕豆/玉米间作氮素吸收和土壤硝态氮残留的影响,结果表明:蚕豆/玉米间作,蚕豆不分隔条件下籽粒和秸秆吸氮量比分隔分别增加20 10%,34 43%;玉米不分隔条件下籽粒吸氮量与分隔近似,但秸秆吸氮量比分隔减少13 04%;蚕豆和玉米不分隔条件下土壤硝态氮累积量都高于分隔。蚕豆/空带间作,蚕豆不分隔籽粒吸氮量高于分隔,但土壤硝态氮累积量没有差异。空带/玉米间作,地下部分隔与否,作物吸氮量和土壤硝态氮累积量都没有差异。     

丛枝菌根真菌根内菌丝碱性磷酸酶活性与菌根共生效应的研究

试验研究 3种丛枝菌根真菌根内菌丝碱性磷酸酶活性与菌根共生效应的结果表明 ,3种丛枝菌根真菌对宿主植物的效应不同 ,与接种G .spp处理和未接种对照相比 ,接种G .m和G .i处理显著增加玉米地上部和根系干物质量、P浓度和吸P量 ,但后两者间无显著差异 ;而接种G .spp处理与对照无显著差异。播种后 35d时接种G .m和G .i处理根内菌丝碱性磷酸酶活性显著高于接种G .spp处理 ,而前二者间无显著差异 ,且随生长时间的变化趋势相似 ,35d时酶活性最高 ,35～ 5 0d呈迅速下降趋势 ,至 70d时酶活性仍下降且趋于平缓。G .spp酶活性则一直处于较低水平 ,随生长时间的延长略有起伏。即接种不同丛枝菌根真菌时 ,根内菌丝碱性磷酸酶活性高的菌根真菌对玉米生长促进作用较大 ,可提高玉米P营养状况 ;反之则对玉米生长和P营养状况无明显促进作用 ,且与对照无显著差异。出苗后 35d时根内菌丝碱性磷酸酶活性是预测丛枝菌根真菌对玉米生长效应的有效生理指标之一。     

Contribution of Roots and Mycorrhizal Hyphae on Phosphorus Efficiency of Maize (Zea mays,L.) Genotypes Grown on Calcareous Soil—A Mechanistic Modeling Approach

ABSTRACT

This work was conducted to study phosphorus (P) efficiency of two maize genotypes (Zea mays, L.) in calcareous soil grown in potted soil with two levels of P in soil by adding 40 and 270 mg P/kg soil. Half of the pots were inoculated with arbuscular mycorrhizal fungi (AMF) (Rhizoglomus irregulare). The maize genotypes were harvested two times at 35 and 50 days after transplanting. The plant dry matter, root length and Plant P uptake of maize genotype Hagen 1 without mycorrhizal fungi (AMF) increased significantly compared with Hagen 9 at a low P level. In contrast, there was no significant difference between two maize genotypes inoculated with AMF under the same P level. The predicted value increased rapidly with increasing P levels from about 70% up to 97% in both maize genotypes with and without mycorrhizal fungi. At a low P level, the mycorrhizae hyphae contributed by about 31.6% and 30.2% of the predicted total P uptake in maize genotype Hagen 1 and Hagen 9, respectively. The results of this study suggested that the P-inefficient genotype Hagen 9 improved with inoculation with mycorrhizal fungi under a low P level at the same conditions of this experiment. Also, root growth system and mycorrhizal hyphae length would be a suitable plant parameter for studying P efficient maize genotypes, especially under limited P supply. The current study clearly pointed out that the mechanistic simulation model (NST 3.0) provides useful tools for studying the role of AMF in P uptake of plant.     

Legume residue influence arbuscular mycorrhizal colonisation and P uptake by wheat

Legumes have been shown to increase growth and P uptake of the following cereal. This could, in part, be due to nutrients released by the decomposing legume residues. To investigate the effect of P added with legume residues on wheat growth, P uptake and arbuscular mycorrhizal (AM) colonisation, a number of experiments were conducted with different legume residues added to a soil with low P availability under conditions in which N was not limiting. Young and mature faba bean shoots (FYS, FMS) and mature chickpea shoots (CP) were added to soil at different rates (0.5–2%, w/w) with the P concentration being the greatest in the young faba bean shoots and least in the mature chickpea residues. Other treatments included addition of inorganic P at different rates (0–80 mg P kg⁻¹). Available P, growth and P uptake and AM colonisation of wheat were measured after 6 weeks. As expected, inorganic P addition increased growth and P uptake but decreased AM colonisation. The effect of the residues was more complex. AM colonisation was not correlated with available P in the soil amended with residues, whereas there was significant negative correlation between available P and AM colonisation in the treatments with inorganic P. Addition of FYS increased wheat shoot growth and P uptake and decreased AM colonisation. However, FMS and CP addition not only decreased wheat growth and P uptake but also AM colonisation despite low soil P availability. It is concluded that addition of some legume residues can improve the growth of subsequent cereals, but others have a negative effect on wheat growth and AM colonisation which cannot be explained solely by soil P availability.     

红三叶草丛枝菌根对有机磷的吸收

The capacities of two arbuscular mycorrhizal (AM) fungi, Glomus mosseae and Glomus versderme, tomineralize added organic P were studied in a sterilized calcareous soil. Mycorrhizal (inoculated with either of the AM fungi) and non-mycorrhizal red clover (Trghlium pmtense L.) plants were grown for eight weeksin pots with upper root, central hyphal and lower soil compartments. The hyphal and soil compartmentsreceived either organic P (as Na-phytate) or inorganic P (as KH₂PO₄) at tbe rate of 50 mg P kg^-1. No P wasadded to the root compartments. Control pots received no added P. Yields were higher in mycorrhizal than innon-mycorrhizal clover. Mycorrhizal inoculation doubled shoot P concentration and more than doubled total P uptake of plaflts in P-amended soil, irrespective of the form of applied P. The mycorrhizal contributionto inorganic P uptake was 80% or 76% in plants inoculated with G. mosseae or G. verefforme, respectively. Corresponding values were 74% and 82% when Na-phytate was applied. In the root compartments of the mycorrhizal treatments, the proportion of root length infected, hyphal length density and phosphatase activity were all higher when organic P was applied than when inorganic P was added.     

Effect of mixing soil saprophytic fungi with organic residues on the response of Solanum lycopersicum to arbuscular mycorrhizal fungi

The effect of the dual inoculation with arbuscular mycorrhizal (AM) and saprophytic fungi and a combination of wheat straw and sewage sludge residues were studied by determining their effect on dry weight of tomato and on chemical and biochemical properties of soil. Incubation of organic residue (sewage sludge combined with wheat straw) with saprophytic fungi and plant inoculation with mycorrhizal fungi was essential to study plant growth promotion. Soil application of organic residues increased the dry weight of tomato inoculated with Rhizophagus irregularis. The greatest shoot dry mass was obtained when the organic residues were incubated with Trichoderma harzianum and applied to AM plants. However, the greatest percentage of root length colonized with AM in the presence of the organic residues was obtained with inoculation with Coriolopsis rigida. The relative chlorophyll was greatest in mycorrhizal plants regardless of the presence of either saprophytic fungus. The presence of the saprophytic fungi increased soil pH as the incubation time increased. Soil nitrogen and phosphorus contents and acid phosphatase were stimulated by the addition of organic residues, and contents of N and P. Total N and P content in soil increased when the organic residue was incubated with saprobe fungi, but this effect decreased as the incubation period of the residue with saprobe fungi increased. The same trend was observed for soil β‐glucosidase and fluorescein diacetate activities. The application of organic residues in the presence of AM and saprophytic fungi seems to be an interesting option as a biofertilizer to improve plant growth and biochemical parameters of soils.     

不同种植密度下丛枝菌根真菌对玉米磷吸收的影响

【目的】利用土著丛枝菌根真菌(arbuscular mycorrhizal fungi,AM真菌)与作物形成互惠互利的共生关系提高作物对土壤磷的利用效率是解决农业生产中磷供需矛盾的主要途径之一,本研究在大田玉米不同种植密度条件下,研究AM真菌对玉米根系的侵染及磷吸收作用,为揭示集约化玉米高效获取磷的机理提供理论依据。【方法】以大田作物玉米的两种种植密度(5104 plants/hm2和9104 plants/hm2)体系为研究对象,在田间原位埋设PVC管装置,通过测定菌丝生长室中的菌丝密度和有效磷耗竭来确定不同种植密度体系条件下AM真菌对玉米磷吸收的作用。【结果】相对于低密度种植群体,高密度群体显著降低了玉米拔节期土壤有效磷的耗竭量,同时增加了玉米地上部的磷含量,即磷吸收效率,增幅达20%; 在玉米拔节期,增加种植密度使根际的根外菌丝生物量(菌丝密度)降低了4%,而非根际土壤中的根外菌丝生物量(菌丝密度)增加了37%; 高密度玉米种植密度群体中AM真菌的根外菌丝对土壤有效磷耗竭的贡献增加了22%。【结论】集约化玉米生产中土著AM真菌依然帮助植株从土壤中吸收有效磷; 高密度体系下玉米对磷的吸收更加依赖于AM真菌。高密度种植增加AM真菌对玉米的侵染、 根外菌丝量和对土壤有效磷的吸收。