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。     

Bt玉米丛枝菌根真菌侵染率与养分含量的变化研究

本文对比了两个不同转化事件的Bt玉米品种"5422Bt1"和"5422CBCL"及其同源常规玉米"5422"丛枝菌根真菌侵染率和叶片及根系氮、磷、钾养分含量的变化,并分析了丛枝菌根真菌侵染率和养分含量的相关性。结果表明,在观测期间,两个Bt玉米品种与常规玉米之间根系丛枝菌根真菌侵染率均无显著差异,但氮、磷、钾养分含量则明显不同,丛枝菌根真菌侵染率与养分含量之间的相关性也有所改变,其变化随玉米品种、生育期以及器官不同而不同。Bt玉米"5422Bt1"在大喇叭口期叶片全钾和根系全磷、开花授粉期叶片全磷和根系全氮、乳熟期叶片全钾以及成熟期叶片全磷和根系全氮、全钾含量均显著高于常规玉米"5422",而大喇叭口期和开花授粉期叶片全氮、开花授粉期根系全磷和全钾以及乳熟期根系全钾含量则低于常规玉米"5422"。Bt玉米"5422CBCL"在大喇叭口期叶片全钾和根系全氮及全钾、开花授粉期叶片全磷以及成熟期根系全氮和全钾含量显著大于常规玉米"5422",而开花授粉期根系全磷、乳熟期根系全磷和全钾以及成熟期叶片全磷含量则小于常规玉米"5422"。相关分析表明,常规玉米"5422"和Bt玉米"5422CBCL"的丛枝菌根真菌侵染率与根系全氮含量及叶片全钾含量之间均呈显著正相关(P0.05),而Bt玉米"5422Bt1"则无显著相关性(P0.05)。可见,与常规玉米"5422"相比,Bt玉米养分含量以及丛枝菌根真菌侵染率与养分含量之间相关关系与不同转化事件所形成的品种特性有关。     

VA菌根菌丝对土壤磷锌的吸收

利用隔网分室盆栽方法,将土壤分为根系吸收区和菌丝吸收区,以白三叶草为供试作物,定量测定了VA菌根菌丝对土壤璘和锌的吸收量及磷锌在植物体内的分布。结果表明,菌根的侵染率显著提高了植物磷锌含量。根外菌丝吸磷量随菌丝吸收区施磷量上升而迅速增加,但锌的吸收量变化不大,说明菌丝对磷和锌吸收之间无密切关系。     

不同磷肥水平下丛枝菌根菌对玉米修复芘污染土壤的影响

盆栽试验研究了不同磷肥水平下接种丛枝菌根菌（Arbuscular mycorrizal fungi,AMF）对玉米修复芘污染土壤的影响。结果表明,在施磷水平为20和80 mg/kg条件下,50 mg/kg芘处理土壤中丛枝菌根菌能够正常侵染玉米根系,侵染率没有显著变化;土壤芘污染对玉米的生长有抑制作用,缺磷土壤中施磷能够缓解土壤芘对玉米生长的抑制作用。培养60 d后,高磷（80 mg/kg）和低磷（20 mg/kg）条件下,玉米接种AMF处理土壤芘残留浓度分别比相应的不接种处理降低了38%和35%,比相应无玉米的对照处理降低了53%和58%。表明玉米接种混合AMF能够显著降低土壤芘残留浓度,促进土壤芘的去除。与P 20 mg/kg处理相比,P 80 mg/kg处理玉米接种及不接种AMF的土壤芘残留浓度分别降低了16%和19%,表明缺磷土壤中施磷对玉米及菌根玉米去除土壤芘均有一定促进作用。土壤微生物碳量与土壤芘的去除率显著正相关,接种AMF和P 80 mg/kg处理均能够显著增加土壤微生物碳量,因此土壤微生物数量的增加可能是其促进土壤芘的去除的重要原因。     

氮、磷供给水平对丛枝菌根真菌生长发育的影响

为了研究营养元素氮、磷对丛枝菌根真菌（arbuscular mycorrhizal fungus）生长发育的影响,以黄瓜、番茄为宿主植物,采用半液培的方式,在LAN营养液的基础上,设置不同氮、磷供给水平的处理。结果显示,同一N、P处理水平条件下,接种处理对黄瓜植株地上部和根系的生物量未产生显著影响。不同N、P供应水平对菌根生长发育显著影响。提高供氮水平显著增加了菌根结构的数量,同时降低了植株地上部的磷含量;而磷处理对侵染结构的影响因不同供氮水平而有所差异,供N 0.3 mmol/L时,提高磷供给水平显著降低了侵染结构的数量,而当把供氮水平提高到N 3 mmol/L时,随着供磷水平的增加,菌根侵染结构数量显著增加。在此条件下,基于氮对菌根真菌和植株磷营养状况的影响的一致性,氮对菌根结构的作用可能源于氮、磷之间的交互作用。     

钼污染对丛枝菌根和球囊霉素的影响

丛枝菌根作为地球上最广泛的共生体,在各种逆境环境中发挥着重要作用.基于不同钼污染程度的钼矿区,分析了钼污染对丛枝菌根真菌侵染、繁殖及其分泌球囊霉素能力的影响.结果 表明,在4个不同钼污染级别的土壤中,丛枝菌根真菌与植物共生关系的形成未受到钼污染的影响,平均菌根侵染频度为50.64％.洛阳钼矿区土壤的平均孢子密度为19....     

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。      

Bt基因导入对侵染丛枝菌根真菌的玉米生长生理及磷转运基因表达的影响

为了分析Bt玉米与常规玉米对接种丛枝菌根真菌响应的异同,本文在接种摩西球囊霉(Funneliformis mosseae)和不接种的条件下,对比分析了两个Bt玉米品种‘5422Bt1’(Bt11)和‘5422CBCL’(Mon810)以及同源常规玉米品种‘5422’根系中丛枝菌根真菌侵染率、磷转运基因的表达量、生长和养分利用状况。结果表明:生长50 d和80 d时,Bt玉米‘5422Bt1’和‘5422CBCL’根系丛枝菌根真菌侵染率显著高于常规玉米‘5422’,分别比‘5422’高13.54%、11.24%和9.83%、6.70%;50 d取样时,接菌和不接菌处理玉米‘5422Bt1’、‘5422CBCL’和‘5422’根系内的磷转运基因表达量均没有显著差异;接菌和不接菌处理下玉米‘5422Bt1’的干重显著高于‘5422CBCL’相应的处理,而与‘5422’没有显著差异;80 d取样时,不接菌处理玉米‘5422Bt1’的根长、根表面积和根体积显著高于‘5422’和‘5422CBCL’不接菌处理。Bt基因的导入主要影响了两个Bt玉米品种(‘5422Bt1’和‘5422CBCL’)苗期(50 d)和成熟期(80 d)的氮素吸收利用,与常规玉米品种‘5422’相比,合成Bt蛋白消耗了部分氮素和磷;3个玉米品种对接种AMF的响应不同,接菌处理提高了‘5422Bt1’和‘5422CBCL’苗期(50 d)和成熟期(80 d)的氮素吸收利用。在磷养分条件满足玉米生长需要的条件下,接种丛枝菌根真菌对Bt玉米磷转运基因表达量和磷的吸收利用没有显著影响。Bt基因的导入以及接种F.mosseae对Bt玉米生长和养分利用的影响与不同转化事件形成的品种特性相关。     

砷胁迫条件下接种丛枝菌根真菌对番茄生长和磷吸收的影响

采用盆栽法研究了砷(As)污染条件下(As 0,50,100和200 mg·kg-14个水平)丛枝菌根真菌(AMF)接种对全生育期番茄植株生长及其磷(P)营养的影响。试验中各接种处理均成功侵染,侵染率在11.79%~34.36%之间。砷胁迫显著影响番茄植株的生物量,植株生长过程中各个时期地上部和根系干重均随As添加水平的升高而显著下降。本试验同时发现As 50 mg·kg-1是不接种番茄植株忍受砷毒害的上限,而接种丛枝菌根真菌后,番茄忍受砷毒害的上限上调到100 mg·kg-1;但200 mg·kg-1已达番茄忍受砷毒害的极限。基质中添加砷对番茄植株不同生长时期地上部和根部磷含量有显著影响。除开花期地上部与其不接种处理根部磷含量外,幼苗期和坐果期植株地上部磷含量与根部磷含量均随着砷添加量的增加而呈大致递增趋势。番茄植株生长的各个时期(幼苗期、开花期和坐果期)地上部和根部磷吸收量随砷添加水平的增加呈明显下降趋势。砷污染条件下,接种丛枝菌根在一定程度上促进了植株生长及其对磷的吸收,缓解了砷对植株生长的胁迫。     

菌根化育苗对玉米生长和养分吸收的影响

【目的】丛枝菌根真菌(arbuscular mycorrhizal fungi,AMF)侵染作物根系形成菌根共生体系对于作物吸收磷具有重要作用,但该结果大多来源于室内受控试验,有限的田间试验因环境条件、试验材料与接种技术等差异致使AMF菌剂应用效果不一。本研究通过玉米菌根化育苗和田间移栽,分析了接种AMF对玉米生长、养分吸收、籽粒产量及养分含量的影响,以期推进菌根技术的实际生产应用。【方法】以自交品系玉米B73为供试作物,于2018年5月至10月在北京市延庆区进行了田间试验。田间小区设置基施磷(+P)和不施磷(–P)处理。供试AMF为Rhizophagus irregularis Schenck&Smith BGC AH01。玉米种子催芽后,分别播入加入AMF菌剂(+M)和菌剂过滤液(–M)的育苗钵内,培养两周后移栽至田间。玉米在田间条件下生长至拔节期时,使用便携式光合仪测定叶片光合速率与气孔导度,取样测定地上部与根部干重和养分元素含量,同时测定菌根侵染率;在玉米完熟期取样,测定籽粒百粒重、籽粒产量及养分含量。【结果】无论田间施磷与否,接菌植株根系的菌根侵染强度和丛枝丰度均显著高于不接菌植株。不施磷情况下,+M处理显著提高了玉米根系干重,玉米生长的菌根依赖性(163.7%)显著高于施磷情形(124.1%)。–P–M处理玉米叶片的光合速率和气孔导度显著低于其他3个处理。–P+M处理玉米叶片的光合参数、玉米地上部和根部磷含量与+P+M均无显著差异。与–P–M处理相比,–P+M显著提高了玉米籽粒产量和百粒重,同时也提高了籽粒中锌、锰、镁等矿质养分的含量,且与+P+M处理相比均无显著差异。【结论】玉米幼苗接种AMF后再移栽到田间,可以显著提高拔节期玉米根系的菌根侵染率,促进玉米地上部和根部对磷及锌、锰和镁的吸收,进而促进玉米的生长,提高籽粒产量和养分含量。本试验条件下,菌根化育苗可以达到与施磷同样的效果,在保障作物不减产的前提下减少磷肥施用量。     

Effects of phosphorus application and vesicular arbuscular mycorrhizal inoculation on the growth and phosphorus nutrition of maize

The growth and nutrition of maize (Zea mays L.) grown with and without the soil application of phosphorus (P) fertilizer and/or mycorrhizal inoculum was studied in pots placed under field environments. Inoculation enhanced the growth of maize significantly (up to 81.8%) during the early stages but response gradually disappeared during the later stages of growth. Addition of phosphate increased plant growth, but suppressed mycorrhizal infection. In the first half of the season, the stimulation in plant growth was related to higher rates of P uptake by the inoculated plants, but later a decline of growth in these treatments was most probably due to fungal parasitism as a result of high root densities.     

多样化培肥模式调控丛枝菌根真菌促进玉米磷素吸收

利用丛枝菌根真菌（Arbuscular mycorrhizal fungi，AMF）从农田生态系统获取养分，是红壤作物吸收土壤磷（P）素的有效途径。针对我国南方红壤生物功能退化、P素生物有效性低、作物产量低等问题，如何调控作物根际AMF群落，优化其与宿主的互惠共生关系，是打破红壤区作物P摄取瓶颈的关键。本研究结合红壤旱地生态间作与有机（秸秆、猪粪、生物肥）无机肥料配施的4种多样化培肥措施，基于作物产量和红壤磷素活化水平，筛选最优培肥模式。进一步利用扩增子高通量测序和显微观察等技术，解析红壤旱地最优培肥措施调控AMF群落组成，揭示优化的AMF群落激发宿主玉米P素摄取机理。结果表明，花生/玉米间作结合秸秆/生物肥的有机无机配施（In+NPKSB）相较于其他培肥方式使红壤旱地全磷（TP）提高29.07%、有效磷（AP）提升1.35倍，且增强了玉米根内AMF群落科水平间的联系。该措施AMF定殖率是传统培肥措施的2.24倍，提高玉米根际酸/碱性磷酸酶（ACP/ALP）活性32.18%和41.66%，玉米生物量提高34.98%，产量提高67.27%。本研究证实红壤旱地花生/玉米生态间作结合秸秆/生物肥有机无机配施的培肥措施可通过优化玉米根内AMF群落组成，促进土壤P素活化，为在红壤旱地因地制宜推广可持续农业发展的集成应用提供理论依据。     

Response of maize to mycorrhizal colonization at varying levels of zinc and phosphorus

A greenhouse experiment was conducted in a red sandy loam soil (Alfisol) to study the responses of arbuscular mycorrhizal (AM) fungus Glomus intraradices Schenck & Smith inoculated (M+) and uninoculated (M−) maize (Zea mays L) plants exposed to various levels of P (15 and 30 mg kg⁻¹) and Zn (0, 1.25, and 2.5 mg kg⁻¹). Roots and shoots were sampled at 55 and 75 days after sowing and assessed for their nutritional status, root morphology, and root cation exchange capacity (CEC) besides grain quality. Mycorrhizal plants had longer and more extensive root systems than nonmycorrhizal plants, indicating that M+ plants are nutritionally rich, especially with P, which directly assisted in the proliferation of roots. Further, root CEC of M+ plants were consistently higher than those of M− plants, suggesting that mycorrhizal colonization assists in the acquisition of nutrients from soil solution. Mycorrhizal inoculated plants had significantly (P ≤ 0.01) higher P and Zn concentrations in roots, shoots, and grains, regardless of P or Zn levels. The available Zn and P status of AM fungus-inoculated soils were higher than unioculated soils. The data suggest that mycorrhizal symbiosis improves root morphology and CEC and nutritional status of maize plants by orchestrating the synergistic interaction between Zn and P besides enhancing soil available nutrient status that enables the host plant to sustain zinc-deficient conditions.     

低磷环境下接种丛枝菌根真菌促进紫花苜蓿生长和磷素吸收的机理

[目的]磷极易被土壤吸附和固定,导致土壤中磷有效性较低.研究接种丛枝菌根真菌(arbuscular mycorrhizal fungi,AMF)和低磷处理两者交互对紫花苜蓿生长和磷吸收的影响,为提高碱性土壤中磷肥利用率提供理论依据.[方法]以黄绵土和紫花苜蓿(Medicago sativa)为试验材料进行盆栽试验.在施...     

Effect of arbuscular mycorrhizal colonization of four species of glomus on physiological responses of maize

This greenhouse study aimed to analyze the impact of arbuscular mycorrhizal (AM) fungal associations on maize (Zea mays L. hybrid Pioneer 3905) in order to compare their functional compatibility and efficiency. The AM fungus species used for this study were Glomus aggregatum, G. etunicatum, G. mosseae, and G. versiforme. Shoot and leaf masses, chlorophyll, soluble protein, total and reducing sugar, carbon (C), and nitrogen (N) concentrations, and glutamine synthetase (GS) activity in the maize leaves were analyzed. The root colonization ranged from 26% to 72% depending on the AM fungus species. Leaf mass was significantly higher when maize plants were colonized with G. etunicatum in comparison to the non‐AM control. The mycorrhizal effect on dry leaf mass ranged from 15.9% to 23.9% depending on the AM species. However, the total shoot mass did not differ significantly among the treatments. The mycorrhizal treatment had a marginally significant effect on the chlorophyll concentrations in maize leaves. The protein concentration was the highest in the plants colonized with G. etunicatum and the N percentage was significantly higher in the leaves of plants colonized by G. versiforme or G. aggregatum than those with G. mosseae. However, the AM colonization did not significantly alter the GS activity among the treatments. The highest sugar concentrations were detected in the leaves of plants colonized by G. versiforme. The sugar concentrations as well as the C percentage were lower in the leaves of plants colonized by G. etunicatum compared to the other mycorrhizal treatments but the values were comparable to the non‐AM control. Our overall results suggest that the expression of the mycorrhizal potential in the maize host plants varies among AM fungal species.     

Arbuscular mycorrhizal colonization and phosphorus acquisition of plants: effects of coexisting plant species

Arbuscular mycorrhizal (AM) fungi influence interactions among plant species through enhancing nutrient uptake and possibly facilitating nutrient transport among plants. However, the effects of one plant species on coexisting plant species with regard to mycorrhizal colonization are not well understood. We examined root mycorrhizal colonization and phosphorus (P) acquisition of plants in a highly P-limiting soil in Lanxi city, Zhejiang, China from the year 2000 to 2002. Three dominant native plant species with different mycorrhizal properties, Digitaria ciliaris (poorly mycorrhizal species), Ixeris denticulate (moderately mycorrhizal species) and Kummerowia striata (highly mycorrhizal species), were planted in experimental plots. In the monocultures, K. striata was found to have the highest infection and D. ciliaris the lowest mycorrhizal infection, but shoot P-concentration was higher in both I. denticulate and D. ciliaris than that in K. striata. In the mixtures, D. ciliaris and I. denticulate did not significantly affect the mycorrhizal colonization, spore production and shoot P-concentration of K. striata plants, but K. striata and I. denticulate significantly increased root mycorrhizal colonization and shoot P-concentration of D. ciliaris. K. striata enhanced but D. ciliaris reduced mycorrhizal infection and shoot P-concentration of I. denticulate. These results suggested that highly mycorrhizal plant species may positively impact coexisting species with respect to mycorrhizal colonization and P acquisition, but the effects on poorly mycorrhizal species are less predictable.     

玉米丛枝菌根真菌根外菌丝表面定殖细菌解磷功能鉴定

【目的】在田间原位条件下研究丛枝菌根(Arbuscular mycorrhizal, AM)真菌根外菌丝表面有无解磷细菌定殖,并对存在的解磷细菌的种类进行鉴定,对其活化有机磷的能力进行检测,从而为更好地认识菌丝际土壤有机磷的周转和磷的生物地球化学循环过程提供依据。【方法】利用河北省曲周县中国农业大学实验站的玉米长期定位试验,采用田间埋膜方式从玉米根系周围收集AM真菌的根外菌丝,用蒙金娜有机磷固体培养基筛选菌丝表面具有矿化植酸钙能力的细菌,对筛选出的细菌进行分离、 培养,然后提取细菌DNA,通过16S rDNA测序分析来确定解磷细菌的种类。分离鉴定的菌株先用蒙金娜有机磷固体培养基通过测定菌落直径(d)及溶磷圈直径(D)初步鉴定其活化植酸钙的能力,再用无菌的蒙金娜有机磷液体培养基确定每株解磷细菌矿化植酸磷的能力,并对溶液的pH进行测定,每个菌株重复3次。最后采用两室隔网根盒将分离纯化的解磷细菌回接至AM真菌根外菌丝,鉴定回接成功率,确定分离出的解磷细菌能否成功定殖于菌丝表面。【结果】从AM真菌根外菌丝表面分离得到了29株具有活化有机磷能力的细菌,分属于芽胞杆菌、 假单胞菌、 沙雷氏菌、 葡萄球菌和肠杆菌5个不同的属。通过有机磷液体培养进一步检测这些菌株活化植酸磷的能力,发现它们对植酸磷的矿化率为1.9%~21.9%。其中假单胞菌属细菌的解磷能力相对较强,对植酸磷的矿化率达14%以上,液体培养基的pH值下降2~4个单位。将分离纯化的细菌回接至两室隔网根盒的菌丝室,培养30 d后,从菌丝表面再次检测到除假单胞菌属外的芽胞杆菌属(Bacillus)、 沙雷氏菌属(Serratia)、 葡萄球菌属(Staphylococcus)和肠杆菌属(Enterobacter)细菌,另外还检测到贪铜菌属(Cupriavidus)细菌。【结论】在田间原位条件下,与玉米共生的AM真菌的根外菌丝表面有多种解磷细菌定殖,它们活化有机磷能力存在差异,其中以假单胞菌属细菌的解磷能力相对较强。     

Variable response of growth and arbuscular mycorrhizal colonization of maize plants to preceding crops in various types of soils

The effects of the preceding crops, sunflower (mycorrhizal host) and mustard (nonhost), on arbuscular mycorrhizal (AM) colonization and growth of succeeding maize were examined in 17 soils in an attempt to clarify the influence of soil characteristics on the effects of preceding crops. Shoot weight and P uptake of maize planted after sunflower were much higher than those after mustard in 14 soils, although the preceding crop had little effect on soil-P availability. AM colonization of maize after sunflower was much higher than that after mustard. The effect of the preceding crop was eliminated by soil sterilization. These results suggested that the differences in maize growth were caused by differences in the AM colonization. Correlation analysis of the effect of the preceding crop and soil properties showed that the difference in the effects on maize growth could not be explained by soil chemical properties, but only by the AM colonization of the preceding sunflower crop. In one of the 17 soils, however, the effect was not evident despite the higher AM colonization of sunflower. This soil was sterilized, and the effect of inoculation by AM fungi (AMF) on maize was examined. However, it was found that the inoculation increased AM colonization but did not improve maize growth at any P level, suggesting that the effect of AMF was unusually inhibited in this soil by unknown soil physicochemical properties. In most soils, however, the preceding mycorrhizal host crop, sunflower, improved the growth and AM colonization of maize depending on the AM colonization of sunflower.     

玉米根系对局部氮磷供应响应的基因型差异

【目的】土壤养分具有异质性,揭示不同基因型玉米根系对于养分异质性的响应规律,对提高不同玉米品种氮、磷利用效率具有重要意义。 【方法】本试验在水培条件下,利用分根系统研究3个玉米杂交种苗期根系对氮、磷两种养分局部供应响应的基因型差异。 【结果】根系对局部供氮的响应存在基因型差异,浚单20和中农玉99侧根生长对局部供氮的响应较敏感,显著提高了局部供氮（+N）一侧的侧根长,增幅达到79%、50%,而NE15无显著响应;浚单20和中农玉99主要提高了+N一侧直径大于0.12 mm的侧根长度。根系生长对于局部供磷（+P）的反应同样存在基因型差异,NE15显著提高+P一侧根系生物量和轴根长,增幅达到38%和24%,中农玉99显著提高+P一侧的侧根长达到35%;在+P侧,浚单20主要增加了直径大于0.12 mm的侧根长度,NE15主要增加直径介于0.12~0.24 mm的侧根长度,而中农玉99主要增加直径小于0.12 mm的极细侧根长度。局部供氮对3个品种侧根生长的促进作用强于局部供磷,而对缺氮一侧根系生长的抑制作用均大于缺磷一侧。不同玉米基因型苗期根系生物量、侧根长（尤其是直径>0.12 mm的侧根）对于局部供应氮、磷存在显著的互作效应,局部供氮对浚单20的侧根生长（尤其是直径>0.12 mm的侧根）的促进作用显著高于局部供磷,而NE15的根系生长（尤其是根系生物量）对局部供磷的响应强度大于局部供氮。 【结论】对于不同养分特性的玉米杂交种,苗期根系对局部供应不同种类养分的响应存在显著的基因型差异,在生产中可以针对品种特性采取不同的施肥措施,以便发挥其生物学潜力。