丛枝菌根真菌对黄瓜枯萎病的影响

盆栽条件下播种黄瓜Cucumis sativus同时接种丛枝菌根真菌Glomus etunicatum,4周后对接种处理和对照黄瓜苗分别浇灌Fusairum oxysporum f.sp.cucumerinum分生孢子悬液,2周后测定幼苗生物量、根内丙二醛、可溶性糖与游离脯氨酸含量及根围真菌和细菌数量。结果表明:接种Glomus etunicatum根系干重增加了9.3%,提高了根内可溶性糖和游离脯氨酸含量,显著减少了根围真菌数量,降低了黄瓜枯萎病的发病率和病情指数。而不接种Glomus etunicatum的黄瓜苗根系干重减少了28.0%。研究认为AM真菌Glomus etunicatum对黄瓜枯萎病具有一定的生防价值。     

苗期紫花苜蓿株体对不同地区垂穗披碱草种子萌发生长的化感作用

以发芽率、苗长、根长、苗干重、根干重变化为种子萌发和幼苗生长参数,研究苗期紫花苜蓿(Medicago sativa)植株浸提液对不同地区垂穗披碱草(Elymus nutans)种子萌发生长的化感作用。结果表明:地上部浸提液对LS、DX垂穗披碱草种子发芽率具有明显的促进作用,而对GS、KMX、LKZ、LZ地区垂穗披碱草种子发芽率均表现为抑制作用,其中对GS垂穗披碱草种子发芽率的抑制作用最强,在14.5%和5.5%浓度处理时抑制率分别为57.89%、55.26%;苗长方面,浸提液5.5%浓度对垂穗披碱草苗长的抑制率顺序为:LZNQDXLSKMXQHGSLKZ,14.5%处理时抑制率顺序为:LZKMXLKZNQGSQHDXLS,其中抑制率最高的为LZ垂穗披碱草,在14.5%和5.5%浓度处理时抑制率分别为33.03%、28.97%;根长方面,5.5%处理对垂穗披碱草根长的抑制率顺序为:QHNQLZKMX、GSLKZDX、LS,14.5%处理时抑制率顺序为:GSQH、NQLZLSKMXDXLKZ,其中在高浓度下抑制率最高的为GS垂穗披碱草,抑制率为57.69%;地上部浸提液对LKZ、LZ垂穗披碱草苗干重均具有促进作用,高浓度浸提液对NQ垂穗披碱草苗干重产生促进作用(RI0),而对KMX、DX垂穗披碱草苗干重均表现为抑制作用;根干重方面,浸提液对LS、QH、GS、NQ、LKZ垂穗披碱草根干重均有明显的抑制作用,而对KMX、DX垂穗披碱草根干重产生促进作用,高浓度浸提液对LZ垂穗披碱草的根干重产生促进作用。从根浸提液的作用来看,根浸提液除对LS、DX垂穗披碱草种子发芽率和根干重、GS垂穗披碱草种子发芽率和苗干重及NQ垂穗披碱草根干重具有促进作用外(P 0.05),对其余地区垂穗披碱草的各项指标均有明显的抑制作用(RI0)。所有以上结果表明,紫花苜蓿植株浸提液对垂穗披碱草种子萌发生长的作用具有一定的浓度效应。不同地区垂穗披碱草对紫花苜蓿地上部浸提液的敏感性趋势总体为:GSQHLSKMXNQLKZLZ,最不敏感或有促进作用的是DX垂穗披碱草;对根浸提液的敏感性趋势总体为:QHNQLZKMX,根浸提液对LS、GS、LKZ、DX垂穗披碱草种子萌发生长具有促进作用。紫花苜蓿植株不同部位浸提液对垂穗披碱草种子萌发生长的化感效应顺序为:地上部根。     

三十烷醇磷酸酯钾对水稻幼苗生长的影响(简报)

用０．０１ｍｇ·Ｌ~（－１）三十烷醇磷酸酯钾或０．１ｍｇ·Ｌ~（－１）三十烷醇溶液培养的水稻幼苗,生长加速,苗高、苗鲜重、苗干重、苗粗壮度、根鲜重和根干重均增高。在幼苗生长后期,两者还可提高幼苗存活率。     

东北地区不同小麦品种对黑麦草的化感作用

以东北地区33个不同来源的小麦品种为研究对象,采用琼脂共培法,评价了不同小麦品种对黑麦草所产生的化感作用.通过分析不同小麦品种对黑麦草根长、苗高、根干重及苗干重的影响,探讨不同小麦品种对黑麦草化感作用的差异,从而筛选出具有较强化感潜力的小麦品种.结果表明,不同小麦品种对黑麦草根长、苗高、根干重及苗干重的影响存在显著差异.利用RI值作为化感作用的指标,结合聚类分析方法,可将这33个小麦品种按化感能力的强、中、弱分成3类;其中龙幅麦9号、龙幅麦13号、锦麦2003和小冰麦33号为化感能力较强的品种.     

布洛芬对菊花插条生根、菊苗质量的影响

研究了布洛芬对菊花插条生根、茎叶生长和菊苗质量的影响。结果表明,将菊花插条束蘸1000mg.L^-1布洛芬液5g然后扦插,能有效地促进菊花插条生根,显著增加平均每插条的生根数、最长根长度和根干重;并能促进菊苗生长,增加茎叶鲜重;菊苗的质量明显提高。     

促肝细胞生长素对肝损伤小鼠脂质过氧化的影响

将脱毒甘薯叶节苗基端于布洛芬液浸10min然后扦插,能有效地促使薯苗生根,增加根数和根干重,提高根系活力;并能促使薯苗生长,茎叶干重和腋芽发育成的枝数增加,茎节繁殖系数提高。布洛芬的最适作用浓度为1000mg·L-1。     

不同栽培基质对浙江楠和闽楠容器苗生长和根系发育的影响

按体积比5∶5、6∶4、7∶3和8∶2分别将泥炭与珍珠岩、谷壳、树皮粉和香菇废料混合制成16种栽培基质,研究了不同基质组成和配比对浙江楠(Phoebe chekiangensisC.B.Shang)和闽楠[P.bournei (Hemsl.) Yang]容器苗生长状况(包括苗高、地径、总干质量和根冠比4个指标)以及根系发育状况(包括根总长、根表面积和根体积3个指标)的影响.结果表明:采用不同基质,浙江楠和闽楠容器苗的各项指标间均有差异,其中部分指标有显著差异.从基质组成看,使用泥炭-珍珠岩、泥炭-谷壳和泥炭-树皮粉3类基质,浙江楠和闽楠容器苗的生长和根系发育的各项指标均优于使用泥炭-香菇废料基质,表明前3种基质组成更有利于浙江楠和闽楠容器苗的生长和根系发育.从基质配比看,当基质中泥炭体积分数达到70％时,浙江楠和闽楠容器苗的苗高和地径最大;而当基质中泥炭体积分数达到50％时,其根总长、根表面积和根体积较大;但基质中泥炭比例对容器苗总干质量的影响无明显规律.除闽楠容器苗的地径外,基质组成与基质配比的交互作用对浙江楠和闽楠容器苗的生长和根系发育指标均有显著影响.综合分析结果表明:选用泥炭-谷壳或泥炭-树皮粉基质,按体积比7∶3配制,适用于浙江楠容器苗的培育;按体积比8∶2配制,适用于闽楠容器苗的培育.     

小麦与蚕豆间作体系根系形态与磷吸收的定量解析

豆科与禾本科作物间作能够改变作物根系生长,但不同施磷水平下间作-根系形态-磷吸收之间的关系尚未明确。本研究通过田间定位试验和根箱模拟试验,研究不同种植模式(小麦单作、蚕豆单作和小麦-蚕豆间作)和不同磷水平下小麦和蚕豆的产量、生物量、磷吸收及根系形态特征,分析探讨不同施磷条件下小麦-蚕豆间作对根系形态和磷吸收的影响。结果表明: 根箱试验中,与单作相比,间作小麦的根干重、根冠比分别增加21.2%、61.5%,地上部干重降低14.6%,根系磷含量和总吸磷量分别提高23.8%和12.1%;间作蚕豆的地上部干重、根干重、根冠比、总根长和根体积分别增加16.5%、47.3%、24.0%、3.5%和8.4%,间作蚕豆地上部磷含量、根系磷含量和总吸磷量分别提高14.7%、26.2%和21.5%。田间试验中,与单作相比,分蘖期间作小麦地上部磷吸收量降低8.7%,而在拔节期、抽穗期、灌浆期和成熟期分别提高40.6%、19.7%、7.8%和12.4%;但种间互作导致开花期、结荚期和成熟期间作蚕豆的地上部磷吸收量分别降低9.8%、9.0%和5.2%。偏最小二乘法(PLS)回归分析表明,小麦的根表面积和根体积、蚕豆的根表面积对作物磷吸收的贡献最大,在低磷胁迫条件下,间作同时提高了小麦和蚕豆的根体积和根表面积,促进了磷的吸收。总之,在缺磷或低磷条件下,种间互作扩大了小麦和蚕豆根土接触面积,促进了苗期磷的吸收,为后期间作优势的形成奠定了基础。     

布洛芬对脱毒甘薯叶节苗生根和生长的影响

将脱毒甘薯叶节苗基端于布洛芬液浸 1 0min然后扦插 ,能有效地促使薯苗生根 ,增加根数和根干重 ,提高根系活力 ;并能促使薯苗生长 ,茎叶干重和腋芽发育成的枝数增加 ,茎节繁殖系数提高。布洛芬的最适作用浓度为 1 0 0 0mg·L-1 。     

不同育苗方式对移栽后侧柏和白榆幼苗根系生长的影响

不同类型苗木,具有不同的根系结构特征,其根系结构也将影响林木的生长和恢复生态系统的稳定性。以侧柏和白榆为研究对象,对移栽18个月后的种基盘苗与营养钵苗根系的生长进行了调查。结果表明:侧柏种基盘苗的总根长和平均直径比营养钵苗分别增加了316.20 cm和0.05mm,白榆苗则分别增加了651.54 cm和0.88mm。侧柏和白榆种基盘苗的根系表面积比营养钵苗分别增加了40.05%和73.04%。侧柏种基盘苗的根系总体积与营养钵苗的差异不显著,而白榆种基盘苗的根系总体积则比营养钵苗增加了54.70%。侧柏和白榆营养钵苗的一级侧根数量大于种基盘苗,增幅分别为42.31%和30.65%。对于侧柏来说,营养钵苗的根尖总数比种基盘苗的增加324个,但白榆苗差异不显著。各种处理的幼苗总根长与根系表面积都有显著相关性,但与根体积不具有显著相关性。营养钵苗的根系平均直径和根尖数量具有相对独立性,而种基盘的根系平均直径与总根长以及根体积均表现为显著相关。种基盘苗能提高侧柏、白榆幼苗的根冠比,促进幼苗株高、地径和主根的生长。采用种基盘苗进行植被恢复,由于其具有较大的根表面积和根长度,林木便具有了较大的吸收水分和营养的能力,以及较高的固结表层土壤能力。     

根际通气状况对盐胁迫下棉花幼苗生长的影响

以溶液培养的棉花(Gossypium hirsutum)幼苗为材料,测定了不同盐胁迫程度和不同通气状况下棉花幼苗株高、根系体积、根系和茎叶生物量以及灰分含量的变化,以探索根际通气状况对盐胁迫下棉花生长的影响。结果表明,盐胁迫抑制棉花植株生长,表现为植株变矮、叶面积减小和干物质积累下降;根际环境通气不良也会导致棉花幼苗生长受抑制、干物质积累下降和矿质元素吸收减少等。进一步比较盐胁迫和根际通气状况及两者组合作用对棉苗生长的影响,发现盐胁迫对株高和总生物量的影响较大,而根际通气状况对根系体积、根系生物量、根冠比和矿质元素吸收的影响较大。总体表现为:盐胁迫对茎叶生长的不利影响较大,而根际通气状况对根系生长的不利影响较大。同时,在根际环境通气良好的条件下,不同程度盐胁迫导致的棉花幼苗株高、根系体积、叶面积、根系生物量和总生物量的变化程度远小于根际环境通气不良条件下的变化程度。实验结果表明,根际环境通气良好可以减弱盐胁迫对棉花生长发育的抑制作用,而根际环境通气不良则会加重盐胁迫的不利影响。     

Depletion of macro-nutrients from rhizosphere soil solution by juvenile corn, cottonwood, and switchgrass plants

In situ sampling of rhizosphere solution chemistry is an important step in improving our understanding of soil solution nutrient dynamics. Improved understanding will enhance our ability to model nutrient dynamics and on a broader scale, to develop effective buffers to minimize nutrient movement to surface waters. However, only limited attention has been focused on the spatial heterogeneity and temporal dynamics of rhizosphere solution, and still less is known about how rhizosphere solution chemistry varies among plant species. Nutrients in rhizosphere soil solution and changes in root morphology of juvenile corn (Zea mays L. cv. Stine 2250), cottonwood (Populus deltoids L.), and switchgrass (Panicum virgatum L.) were monitored using mini-rhizotron technology. Plants were grown for 10 days in a fine-silty, mixed, superactive, mesic Cumulic Hapludoll (Kennebec series). Micro-samples (100–200 μL) of rhizosphere and bulk soil solution were collected at 24-h intervals at a tension of ?100 kPa and analyzed for P, K, Ca, and Mg concentration using Capillary Electrophoresis techniques. Plants were harvested at the end of the 10-day period, and tissue digests analyzed for nutrient content by Inductively Coupled Plasma Spectroscopy. Corn plants produced roots that were 1.3 times longer than those of cottonwood, and 11.7 times longer than those of switchgrass. Similar trends were observed in number of root tips and root surface area. At the end of 10 days, rhizosphere solution P and K concentrations in the immediate vicinity of the roots (<1 mm) decreased by approximating 24 and 8% for corn, and 15 and 5% for cottonwood. A rhizosphere effect was not found for switchgrass. After correction for initial plant nutrient content, corn shoot P, K, and Mg were respectively 385, 132, and 163% higher than cottonwood and 66, 37, and 10% higher than switchgrass. Cottonwood shoot Ca concentration, however, was 68 to 133% higher than that of corn or switchgrass. There was no difference in root P concentration among the three species. Nutrient accumulation efficiency (μg nutrient mm^?1 root length) of cottonwood was 26 to 242% higher for P, 25 to 325% higher for Ca, and 41 to 253% higher for Mg than those of corn and switchgrass. However, K accumulation efficiency of corn was four to five times higher than that of the cottonwood and switchgrass. Nutrient utilization efficiency (mg of dry weight produced per mg nutrient uptake) of P, K, and Mg was higher in cottonwood than in corn and switchgrass. These differences are element-specific and depend on root production and morphology as well as plant nutrient status. From a practical perspective, the results of this study indicate that potentially significant differences in rhizosphere solution chemistry can develop quickly. Results also indicate that cottonwood would be an effective species to slow the loss of nutrients in buffer settings.     

Citric acid excretion and precipitation of calcium citrate in the rhizosphere of white lupin (Lupinus albus L.)

Abstract. White lupin ( Lupinus albus L.) was grown for 13 weeks in a phosphorus (P) deficient calcareous soil (20% CaCO₃, pH(H₂O)7.5) which had been sterilized prior to planting and fertilized with nitrate as source of nitrogen. In response to P deficiency, proteoid roots developed which accounted for about 50% of the root dry weight. In the rhizosphere soil of the proteoid root zones, the pH dropped to 4.8 and abundant white precipitates became visible. X-ray spectroscopy and chemical analysis showed that these precipitates consisted of calcium citrate. The amount of citrate released as root exudate by 13-week-old plants was about 1 g plant⁻¹, representing about 23% of the total plant dry weight at harvest. In the rhizosphere soil of the proteoid root zones the concentrations of available P decreased and of available Fe, Mn and Zn increased. The strong acidification of the rhizosphere and the cation/anion uptake ratio of the plants strongly suggests that proteoid roots of white lupin excrete citric acid, rather than citrate, into the rhizosphere leading to intensive chemical extraction of a limited soil volume. In a calcareous soil, citric acid excretion leads to dissolution of CaCO₃ and precipitation of calcium citrate in the zone of proteoid roots.     

Depletion of macro-nutrients from rhizosphere soil solution by juvenile corn,cottonwood, and switchgrass plants

In situ sampling of rhizosphere solution chemistry is an important step in improving our understanding of soil solution nutrient dynamics. Improved understanding will enhance our ability to model nutrient dynamics and on a broader scale, to develop effective buffers to minimize nutrient movement to surface waters. However, only limited attention has been focused on the spatial heterogeneity and temporal dynamics of rhizosphere solution, and still less is known about how rhizosphere solution chemistry varies among plant species. Nutrients in rhizosphere soil solution and changes in root morphology of juvenile corn (Zea mays L. cv. Stine 2250), cottonwood (Populus deltoids L.), and switchgrass (Panicum virgatum L.) were monitored using mini-rhizotron technology. Plants were grown for 10 days in a fine-silty, mixed, superactive, mesic Cumulic Hapludoll (Kennebec series). Micro-samples (100–200 μL) of rhizosphere and bulk soil solution were collected at 24-h intervals at a tension of −100 kPa and analyzed for P, K, Ca, and Mg concentration using Capillary Electrophoresis techniques. Plants were harvested at the end of the 10-day period, and tissue digests analyzed for nutrient content by Inductively Coupled Plasma Spectroscopy. Corn plants produced roots that were 1.3 times longer than those of cottonwood, and 11.7 times longer than those of switchgrass. Similar trends were observed in number of root tips and root surface area. At the end of 10 days, rhizosphere solution P and K concentrations in the immediate vicinity of the roots (<1 mm) decreased by approximating 24 and 8% for corn, and 15 and 5% for cottonwood. A rhizosphere effect was not found for switchgrass. After correction for initial plant nutrient content, corn shoot P, K, and Mg were respectively 385, 132, and 163% higher than cottonwood and 66, 37, and 10% higher than switchgrass. Cottonwood shoot Ca concentration, however, was 68 to 133% higher than that of corn or switchgrass. There was no difference in root P concentration among the three species. Nutrient accumulation efficiency (μg nutrient mm⁻¹ root length) of cottonwood was 26 to 242% higher for P, 25 to 325% higher for Ca, and 41 to 253% higher for Mg than those of corn and switchgrass. However, K accumulation efficiency of corn was four to five times higher than that of the cottonwood and switchgrass. Nutrient utilization efficiency (mg of dry weight produced per mg nutrient uptake) of P, K, and Mg was higher in cottonwood than in corn and switchgrass. These differences are element-specific and depend on root production and morphology as well as plant nutrient status. From a practical perspective, the results of this study indicate that potentially significant differences in rhizosphere solution chemistry can develop quickly. Results also indicate that cottonwood would be an effective species to slow the loss of nutrients in buffer settings. An erratum to this article can be found at     

田菁根际促生菌的筛选及其促生耐盐效果

【目的】为探究盐生植物田菁及其根际功能微生物改良盐碱地的效果,本研究从黄河三角洲盐碱区田菁根际土壤中分离促生菌,并明确其耐盐促生效果。【方法】采用选择培养方法从田菁根际土壤中分离固氮菌、解磷菌以及解钾菌,并进行16S rRNA分子生物学鉴定。之后对菌株的耐盐及促生特性进行测定,筛选性状优良菌株进行玉米促生作用研究。【结果】共分离得到105株根际促生菌,其中N102兼具多种促生特性且耐盐性达15%。田菁种子发芽试验表明,N102可显著提高田菁发芽率(47%,P0.05)、芽长(48.5%,P0.05)和根长(60%,P0.05);玉米盆栽试验结果表明,N102对盐胁迫下玉米的株高、根长、叶绿素含量、地上部干重以及根干重具有显著的促进作用。经系统发育分析,N102与Enterobacter soli ATCC BAA-2102 (NR117547)序列相似度为99.30%,鉴定属于Enterobacter属。【结论】菌株N102具有多种植物促生耐盐特性,具有开发成有效促进盐碱地作物生长的微生物肥的良好前景。     

盐分胁迫对啤酒大麦幼苗生长、离子平衡和根际pH变化的影响

盐分胁迫不仅影响植物的生长,而且会影响植物根际微域环境。根际pH的改变对土壤养分的有效性和微生物群落组成的变化有重要影响。为了探究啤酒大麦幼苗对不同类型盐分胁迫的生理生态响应机制和根际pH变化影响的生理机制,采用水培法,通过不同类型盐分(对照、混合Na盐、混合Cl盐和NaCl)胁迫处理啤酒大麦幼苗,对其生长、离子平衡和根际pH变化进行了研究。结果表明,1)在3种不同类型盐分胁迫下,啤酒大麦幼苗地上部干重、含水量均有所降低,而根冠比增加,尤其在NaCl胁迫下啤酒大麦幼苗地上部干重较对照显著降低了17.88%,而根干重和根冠比则分别增加了19.12%和43.86%。不同类型盐分胁迫抑制了啤酒大麦幼苗根长的生长,尤其在混合Na盐胁迫下根长降低明显(P0.05),但促进了根表面积和根体积的增加,尤其在混合Cl盐胁迫下,根表面积和根体积分别增加了41.76%和84.38%。2)不同类型盐分胁迫下啤酒大麦幼苗地上部离子平衡发生改变,在混合Na盐和NaCl胁迫下啤酒大麦幼苗主要吸收Na~+,地上部K~+/Na~+、Ca~(2+)/Na~+和Mg~(2+)/Na~+显著降低;混合Cl盐和NaCl胁迫下则过量吸收Cl~-,抑制了H_2PO_4~-、NO_3~-和SO_4~(2-)的吸收。3)在混合Na盐、混合Cl盐和NaCl盐分胁迫下,啤酒大麦幼苗对阴离子的吸收总量高于对阳离子的吸收总量,离子平衡计算结果表明根际呈碱化现象,与原位显色结果一致,且在混合Cl盐胁迫下根际碱化程度最大。     

玉米苗期耐低铁能力的综合评价及其预测

为了筛选和鉴定耐低铁玉米品种应用于生产,本研究以23个玉米品种为材料,测定低铁胁迫和正常供铁(对照)玉米幼苗的株高、茎粗、可见叶、展叶、叶面积、根长、根体积、总干重、活性铁、含铁量、铁积累量和叶绿素含量等15个性状,以各性状的相对值作为衡量指标,利用主成分分析、隶属函数分析和聚类分析对其进行耐低铁能力的综合评价。结果表明不同玉米品种耐低铁能力存在明显的基因型差异;邡玉1号、福康玉909、正大619、正红102、福得2号、正红2号耐低铁能力较强;展叶数、叶面积、根长、根干重、铁积累量可作为玉米耐低铁品种苗期筛选指标;可利用玉米苗期耐低铁能力的回归模型:D=(-384.23+2.71X4+2.50X5+3.22X6+1.70X9+4.86X14)×10-3对玉米苗期耐低铁能力进行预测。     

水分胁迫下丛枝菌根真菌对枳实生苗生长和渗透调节物质含量的影响

采用盆栽试验研究了水分胁迫下接种丛枝菌根真菌摩西球囊霉(Glomaus mosseae)对枳[Poncirustrifoliat(L.)Raf.]实生苗的生长和渗透调节物质含量的影响.结果表明,在土壤含水量为20%、16%和12%条件下,接种G.mosseae能够增加植株的生长(株高、茎粗、叶面积、地上部干重、地下部干重和植株干重),促进植株根系活跃吸收面积和根际土壤有效磷的吸收,提高叶片和根系可溶性糖含量的积累,降低叶片脯氨酸含量,增强植株的水分利用效率(达20%～40%),使枳实生苗的抗旱能力得到增强.土壤含水量为20%和16%条件下接种G.mosseae对植株的效果较土壤含水量为12%条件下更显著.12%的土壤含水量严重抑制Gmosseae的侵染,说明丛枝菌根侵染程度轻,其对植物的效果也差.     

间作对植株生长及养分吸收和根际环境的影响

通过盆栽实验研究了线辣椒和玉米间作对其植株生长、矿质养分吸收、根际环境以及铁载体分泌的影响,以探索间作促进铁、磷等养分吸收利用的可能生理机制.结果表明:(1)与单作相比,间作线辣椒地上部干重降低23.0%,根系干重增加44.2%,玉米地上部和根系的干重分别增加8.7%和22.9%;间作线辣椒根冠比和根系活力分别显著提高86.4%和29.8%;间作线辣椒、玉米叶绿素含量分别显著提高12.6%和7.8%.(2)与单作相比,间作线辣椒的铁、锌、锰含量分别增加1.50倍、1.39倍和1.34%,而间作玉米则无显著变化;间作线辣椒和玉米的钙含量都显著低于相应单作,氮含量没有显著变化,但磷、钾含量显著增加.(3)间作线辣椒和玉米的根际土、非根际土的酸性磷酸酶活性及根系酸性磷酸酶活性都显著高于相应单作,而其根际土和非根际土的pH值无显著变化;间作玉米根系的铁载体分泌比单作减少32.8%,间作线辣椒根系的铁还原酶活性是单作的1.10倍.研究发现,线辣椒/玉米间作能通过影响根际生物学特征和化学过程提高植株的铁、锌、磷和钾养分水平,缓解养分胁迫,是一种很有推广价值的种植模式.     

Phosphorus acquisition from soil by white lupin (Lupinus albus L.) and soybean (Glycine max L.), species with contrasting root development

White lupin and soybean have contrasting root morphologies: white lupin develops proteoid or cluster roots, roots with discreet clusters of short, determinate branch roots (rootlets) while soybean develops a more fibrous root system with evenly distributed, longer branch roots. Growth and P acquisition by white lupin and soybean were compared in a soil high in bound, total P, with or without additional inorganic P applied in solution. Additional P increased biomass by 25% and doubled total P in soybean. In contrast, white lupin did not respond to additional P in biomass or total P. However added P decreased cluster development on proteoid roots indicating that white lupin sensed the added P. The reduction in cluster weight per plant was exactly countered by an increase in dry weight of other roots. Soybean root development responded to P application, proliferating branch roots with active meristems in the upper portion of the soil profile where P was applied, and reducing root weight to plant weight by 13%. White lupin did not proliferate roots in response to P application. When P was not added to soil, soybean and lupin acquired similar P per unit root dry weight. However, white lupin accumulated 4.8 times more P per unit root length, suggesting that P acquisition in these plants involved other mechanisms such as the exudation of P solubilizing compounds. Soybean accessed P by developing more root length thus colonising more soil volume than white lupin and, therefore, was better able to take advantage of the added P. Pericycle and root tip meristem activities were critical to the differences in root development between white lupin and soybean, and therefore their responses to plant and soil P.