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1.
本研究采用Gus 基因标记技术和常规方法跟踪考察了恶臭假单胞菌P861(Gus) 在缩影系统油菜根圈的定殖情况,以及缩影系统内土壤类型、土壤含水量对根部定殖的影响。土壤含水量分别为60% FC和75% FC时,P861(Gus) 在砂姜黑土中的定殖水平高于50% FC的,不但能散布至种子下8cm 以内的根段部位,且定殖水平分别为7.5102和2.8103cfug-1。在灰潮土缩影中,P861(Gus) 在油菜根圈的定殖动态表现为在油菜播种后3 ~6 天,定殖密度可达最高水平(5.5106cfug-1) ,然后急速下降,最后保持在一个相对稳定的较低水平(7.6102cfug-1) 。P861(Gus) 在不同根段部位的定殖密度并无从上到下逐渐递减的规律。  相似文献   

2.
恶臭假单胞菌P861(Gus)在油菜根部定殖的生态研究   总被引:3,自引:0,他引:3  
本研究采用Gus 基因标记技术和常规方法跟踪考察了恶臭假单胞菌P861(Gus) 在缩影系统油菜根圈的定殖情况,以及缩影系统内土壤类型、土壤含水量对根部定殖的影响。土壤含水量分别为60% FC和75% FC时,P861(Gus) 在砂姜黑土中的定殖水平高于50% FC的,不但能散布至种子下8cm 以内的根段部位,且定殖水平分别为7.5×102和2.8×103cfu·g-1。在灰潮土缩影中,P861(Gus) 在油菜根圈的定殖动态表现为在油菜播种后3 ~6 天,定殖密度可达最高水平(5.5×106cfu·g-1) ,然后急速下降,最后保持在一个相对稳定的较低水平(7.6×102cfu·g-1) 。P861(Gus) 在不同根段部位的定殖密度并无从上到下逐渐递减的规律。  相似文献   

3.
为研究短小芽孢杆菌BX-4在作物根际的定殖及防病效果,通过浓度梯度法用氨苄青霉素对其进行了抗性标记,并通过番茄盆栽试验研究了其在根际土壤中的定殖规律。结果表明,筛选出的突变体菌株BX-4'能够耐受浓度为200 μg·mL^-1的氨苄青霉素,并且具有耐药和遗传双重稳定性;应用试验显示该突变体菌株能成功在番茄根际定殖,接种20 d后根际土壤中存活数量达到最高值1.34×10^8 cfu·g^-1干土,以后逐渐下降,到50 d时趋于稳定;筛选的突变体菌株对番茄青枯病具有明显的防治效果,防效达37.9%-50.9%。短小芽孢杆菌BX-4在作物根部的定殖规律为揭示其生防机理及应用该菌提供了科学根据。  相似文献   

4.
解磷菌(phosphate solubilizing bacteria,PSB)可以通过提高土壤有效磷含量而增加作物产量,目前已有许多解磷菌被分离并应用于农业生产中,但关于解磷菌在植物根际中的定殖情况仍缺乏系统性的研究.WY4为本实验室前期从小白菜(Brassica chinensis)根际分离得到的一株高效解磷菌,本研究利用绿色荧光蛋白(green fluorescent protein,GFP)标记技术研究了WY4在小白菜根际及土壤中的定殖规律.与原菌株相比,GFP标记对菌株WY4-GFP生长及解磷活性具有较小影响,同时在促进小白菜生长上WY4-GFP与WY4无显著性差异;WY4-GFP具有持久的定殖能力(接种21d的自然土及30 d的小白菜根际土中,WY4-GFP的定殖数量分别为105和104 CFU/g左右),同时随时间的增加WY4-GFP在土壤中定殖数量逐渐减少;WY4-GFP在小白菜根冠及分生区大量定殖,在伸长区及侧根根毛处数量较少,同时表皮细胞间隙上也有较多的标记菌株.研究结果表明,WY4-GFP在小白菜根际及土壤中具有良好的定殖能力,这为后期深入研究解磷菌与植物间的关系提供了重要参考.  相似文献   

5.
粪产碱菌与水稻根的联合过程   总被引:2,自引:2,他引:0  
应用~(15)N同位素标记菌体和Tn5转座子诱变的突变株研究固氮粪产碱菌对宿主水稻的联合进程,结果表明,粘附作用是结合过程的第一步,接种3h后粘附在根表的菌体数量达最大值,约占接种量的3.7%。粘附的菌体易脱离根表,表明粘附作用是细菌与宿主植物间的弱的相互作用。在根表定位是结合过程的第二步。接种15h后,定位菌体数量达最大值,约占接种量的21%。经振荡处理不能使定位菌体脱离根表。定殖是结合过程的第三步,接种20h后定殖菌体紧密结合于根表,剧烈振荡亦不易使其脱离根表。定殖后菌体开始出现果胶酶活性。采用趋化(Che)和胞外多糖(Exo)突变株研究表明,趋化性和胞外多糖的合成是影响细菌在根表结合的重要因素。粪产碱菌在水稻根表没有专一的粘附部位,但粪产碱菌的定位和定殖主要发生在主根根表,尤其是主、侧根交接处。  相似文献   

6.
王平  冯新梅  李阜棣 《土壤学报》2001,38(2):265-270
在土壤一盒栽、盆栽微宇宙系统(Microcosm)中和田间条件下,研究了发光酶基因(luxAB)标记的华癸根瘤菌JS5A16L在紫云英根圈的定殖动态、分布范围及结瘤情况。在盒栽系统中,JS5A16L的定殖密度在紫云英出苗2天后达到最高水平(7.88 lpg cfu/克根)(cfu为colony forming unit的缩写),然后开始下降,并保持在一个相对稳定的水平;58天后又有所回升,且能散布至种子下方22cm处的根段部位。盆栽条件下的定殖动态与盒栽系统中的相似,紫云英播种3天后,JS5A16L可达最高定殖水平(6.92 log cfu/株根系),随后开始缓慢下降,直至32天时仍维持在一个相对稳定水平。JS5A16L在田间条件的定殖动态则不同,播种后30天时定殖密度达到最大值(7 .03 log cfu/克根),90天后降到最低值(5. 24 log cfu/克根),然后又开始上升,160天时为7.87 log cfu/克根,甚至在地上部植株收割后20天仍可维持在7.89 log cfu/克根。接种该菌株可显著提高紫云英的生物学产量。  相似文献   

7.
内生菌YN201728的定殖能力及其防治烟草白粉病的效果研究   总被引:2,自引:0,他引:2  
为研究生防菌YN201728在烟草体内的定殖规律及防病机制,本研究利用其绿色荧光标记菌株YN28-P43GFPmut3a实时动态观测标记菌的定殖部位及密度,并探究其对温室烟草白粉病的盆栽防效与定殖的关系。结果表明,YN28-P43GFPmut3a发酵液处理烟草种子和幼苗后,种子内的标记菌含量可达2.18×106 CFU·g-1,在幼苗的根表土、根际土、根、茎、叶等组织中均能检测到标记菌,且其定殖密度表现为根表土>根际土>根>茎>叶。激光共聚焦显微镜观察显示,标记菌主要聚集在烟草根表皮、木质部导管、茎表皮、韧皮部及维管束组织、叶片表面和叶肉细胞间隙以及种皮与胚等部位。盆栽防效试验结果表明,YN201728野生型和标记菌株对烟草白粉病均有较好的保护和治疗效果,持效期长达21 d。此外,烟草叶片中内生菌的定殖量与其防效呈正相关。本研究结果表明,内生菌YN201728在烟草体内有良好的定殖和防治白粉病效果,具很好的开发潜力,为烟草病害的生物防治提供了一定的理论基础。  相似文献   

8.
GFP标记的植物促生菌B96-Ⅱ-gfp的定殖能力研究   总被引:1,自引:0,他引:1       下载免费PDF全文
采用绿色荧光蛋白基因标记技术研究了植物促生菌B96-Ⅱ的标记菌B96-Ⅱ-gfp在盆栽黄瓜土壤中的时间、空间定殖动态以及在黄瓜植株上的分布。研究表明: B96-Ⅱ-gfp在土壤中具有持久的定殖能力, 接种180 d时在自然土和黄瓜枯萎菌病土中的定殖数量分别为2.7×104 cfu·g-1和6.6×104 cfu·g-1, 360 d时在土壤中仍可检测到B96-Ⅱ-gfp的存在。B96-Ⅱ-gfp可在盆栽植株生长土壤的表层(0~4 cm)、中层(4~8 cm)和底层(8~12 cm)定殖, 定殖数量随土壤深度的增加而增加。此外, B96-Ⅱ-gfp还可在黄瓜的根、茎和叶上定殖, 根部定殖的数量(7.2×104 cfu·g-1)显著高于茎部和叶部定殖的数量; 黄瓜植株体内定殖的数量多于体表定殖的数量。对土壤中可培养的3大微生物类群影响的研究表明: B96-Ⅱ-gfp对土壤中真菌数量具有显著抑制作用, 而对细菌和放线菌数量则没有明显影响。防病促生试验表明: B96-Ⅱ-gfp可增加黄瓜株高、鲜重和干重, 对黄瓜枯萎病有一定的防治效果, 且与未标记菌株B96-Ⅱ的防病促生作用无显著差异。  相似文献   

9.
本研究将2株香蕉枯萎病拮抗细菌0202和1112分别涂布于含有不同浓度的利福平培养基上,筛选出抗药性标记菌株0202-r和1112-r。将香蕉枯萎病菌Foc4接种于香蕉植株根部,3d后再将抗药性标记菌株接种在同一部位或位点,于不同时间测定拮抗细菌在根际、根内、球茎和假茎的定殖情况。研究结果显示,将拮抗细菌接种香蕉根部1~3d后,在植株根际土壤内存在大量拮抗细菌,而根内、球茎和假茎内存在少量拮抗细菌;接种7~14d后,在植株根内、球茎和假茎内定殖的拮抗细菌增多,并达到最大量;在接种14~21d后,在植株根内、球茎和假茎内定殖的拮抗细菌量急剧下降;在接种28~35d后,在植株根内、球茎和假茎内定殖的拮抗细菌量稍有回升。  相似文献   

10.
印度梨形孢诱导油菜抗旱性机理的初步研究   总被引:5,自引:0,他引:5  
印度梨形孢(Piriformospora indica)是一种根部内生真菌,能够促进许多植物的生长,提高作物的产量,而且还能诱导植物产生对生物或非生物胁迫的抗性.为了研究印度梨形孢对油菜(Brassica napus L.)抗旱性的影响,本研究用20%的聚乙二醇6000(PEG)对有印度梨形孢定殖和无印度梨形孢定殖的油菜植株进行模拟干旱胁迫处理,分析两者在受干旱胁迫后丙二醛(MDA)含量、相对电导率大小、脯氨酸(Pro)含量、抗氧化酶(超氧化物歧化酶(SOD)、过氧化物酶(POD)和过氧化氢酶(CAT))活性以及干旱相关基因表达水平的差异.结果表明,接种印度梨形孢的油菜植株叶片中MDA含量和相对电导率均显著低于未接种印度梨形孢的油菜植株;Pro含量显著高于未接种印度梨形孢的油菜植株,在PEG处理后的第72小时,接种印度梨形孢的油菜叶片中Pro含量是未接种印度梨形孢的油菜的1.3倍;SOD、POD和CAT活性明显高于未接种印度梨形孢的油菜植株,PEG处理后的第24小时SOD、POD和CAT活性分别是对照油菜的1.17、1.38和1.27倍.RT-PCR分析表明,干旱胁迫下有印度梨形孢定殖的油菜叶片中编码合成脂质转运蛋白的基因575表达上调,PEG处理后的第9小时其表达量是对照的3.2倍.本研究研究结果表明印度梨形孢提高油菜对干旱胁迫的抗性与MDA含量、质膜透性、Pro含量、抗氧化酶活性和干旱相关基因的表达相关,印度梨形孢可能是通过提高油菜整体抗氧化能力、维持细胞生物膜完整性和细胞内渗透压以及降低膜脂的过氧化水平,从而增强了油菜对干旱胁迫的抗性.本研究初步明确了印度梨形孢提高油菜抗旱性的作用与部分机理,为深入研究印度梨形孢提高油菜的抗逆性作用及其机理提供基础资料.  相似文献   

11.
Pot experiments were carried out over two growing periods to assay the biocontrol efficacy and rhizosphere colonization of Trichoderma harzianum SQR-T037 (SQR-T037) applied as SQR-T037 conidia suspension (TCS), SQR-T037 conidia suspension blended with organic fertilizer (TBF), or SQR-T037 fermented organic fertilizer (TFF). Each formulation had three T. harzianum numbers. In two experiments, Percent Disease Indexes (PDIs) decreased with the increase of SQR-T037 number added to soils. The TFF treatment consistently exhibited the lowest PDIs at same amendment rate of SQR-T037 and 0–8.9%, 25.6–78.9%, and 4.4–50.0% of PDIs were found in TFF, TCS, and TBF treatment, respectively. Soils treated with TFF showed the highest SQR-T037 population in rhizosphere and bulk soil. Decrease of Fusarium oxysporum population in both bulk and rhizosphere soils occurred in the treatment SQR-T037 at 105 and 106 cfug−1 soil rate. The TFF treatment at the SQR-T037 rate of 103 cfug−1 soil significantly (p < 0.05) increased SQR-T037 population within the rhizoplane but had no effect on F. oxysporum population when compared to TCS and TBF. Generally, TFF treatments were superior to TCS and TBF treatments on disease control by sustaining colonization of SQR-T037 and decreasing F. oxysporum abundance in the rhizosphere soil. We propose that TFF treatment at SQR-T037 rate of 107 cfug−1 (i.e., 105 cfug−1 soil after applied to soil) was the best formulation for controlling Fusarium wilt of cucumber.  相似文献   

12.
The intimate relationships between plant roots, rhizosphere, and soil are fostered by the release of organic compounds from the plant into soil through various forms of rhizodeposition and the simultaneous harvesting of nutrients from the soil to the plant. Here we present a method to spatially track and map the migration of plant‐derived carbon (C) through roots into the rhizosphere and surrounding soil using laser ablation‐isotope ratio mass spectrometry (LA‐IRMS). We used switchgrass microcosms containing soil from field plots at the Kellogg Biological Station (Hickory Corners, Michigan, USA) which have been cropped with switchgrass since 2008. We used a 13CO2 tracer to isotopically label switchgrass plants for two diel cycles and tracked subsequent movement of labeled C using the spatially specific (< 100 µm resolution) δ13C analysis enabled by LA‐IRMS. This approach permitted assessment of variable C flow through different roots and enabled mapping of spatial variability of C allocation to the rhizosphere. Highly 13C‐enriched C (consistent with production during the 13CO2 application period) extended ≈ 0.5–1 mm from the root into the soil, suggesting that the majority of recent plant‐derived C was within this distance of the root after 48 h. Tracking the physical extent of root exudation into the rhizosphere can help evaluate the localization of plant‐microbe interactions in highly variable subsurface environments, and the use of the isotopic label can differentiate freshly fixed C (presumably from root exudates) from other types of subsurface C (e.g., plant necromass and microbial turnover). The LA‐IRMS technique may also serve as a valuable screening technique to identify areas of high activity for additional microbial or geochemical assays.  相似文献   

13.
根际促生菌Bacillus subtilisY-IVI在香草兰上的应用效果研究   总被引:4,自引:1,他引:3  
【目的】香草兰为多年生热带经济作物,随着种植年限的增加,植株长势弱,土壤有益微生物减少,土壤微生物区系失衡,严重制约了香草兰产业的可持续发展。枯草芽孢杆菌作为一种根际促生菌,被广泛应用于促进作物生长,改善土壤微生物环境。本文将枯草芽孢杆菌Y-IVI接种在有机肥上,生产了生物有机肥,并就该生物有机肥对香草兰生长的影响进行了研究。【方法】采用温室盆栽试验,调查施用根际促生菌枯草芽孢杆菌(Bacillus subtilis)Y-IVI及其经固体发酵制得的微生物有机肥料(Y-IVI:3×108cfu/g)后,香草兰植株地上部及根系的生长状况,采用选择性培养基方法研究了Y-IVI在香草兰根际土壤中的定殖能力及对香草兰根茎腐病致病菌-尖孢镰刀菌数量的影响。【结果】施用Y-IVI及BIO 4个月后,香草兰根际土壤Y-IVI数量仍可达到106cfu/g土,二者无显著差异,在处理OF和对照中未检测到菌株Y-IVI。施用生物有机肥香草兰地上部干重和根系干重均显著高于对照,分别增加了63.1%和59.4%,与不接种Y-IVI的有机肥处理(OF)相比,地上部干重显著提高了43.2%,根系干重提高了18%,差异不显著;施用Y-IVI菌液的处理植株地上部干重和根系干重均高于对照,但无显著性差异;处理BIO根系直径、根系表面积和总体积与对照相比分别增加了41.9%、88.9%和80.4%,均显著高于对照,总根长与对照差异不显著;处理BIO根系表面积和总体积与有机肥处理OF相比分别显著增加了41.9%和30.8%,根系直径与OF相比增加了10.1%,差异不显著;处理Y-IVI根系直径与对照相比显著增加了25.5%,但根系表面积和总体积与对照差异不显著;与对照相比,施用BIO及Y-IVI的处理根际土壤尖孢镰刀菌数量分别明显降低了52.2%和41.8%,施用有机肥OF的处理降低了10%,差异不显著。【结论】Y-IVI可稳定定殖于香草兰根际土壤对其生长起有益作用,含促生菌Y-IVI的生物有机肥料比单独使用促生菌菌液可以更有效地减少根际土壤中尖孢镰刀菌数量,降低连作生物障碍。施用生物有机肥料比施用化肥和有机肥更有效地促进香草兰地上部及根系生长,因此,施用由根际促生菌枯草芽孢杆菌(Bacillus subtilis)Y-IVI制得的生物有机肥是解决香草兰连作生物障碍和提高收益的有效手段。  相似文献   

14.
RHIZOSPHERE MICROBIAL POPULATIONS IN CONTAMINATED SOILS   总被引:2,自引:0,他引:2  
Rhizosphere microbial populations may increase bioremediation of soil contaminated with organic chemicals. A growth chamber study was conducted to evaluate rhizosphere microbial populations in contaminated and non-contaminated soil. Alfalfa (Medicago sativa L.) and alpine bluegrass (Poa alpina L.) were grown in soil containing a mixture of organic chemicals for 14 weeks. The equal millimolar mixture of hexadecane, (2,2-dimethylpropyl)benzene, cis-decahydronaphthalene (decalin), benzoic acid, phenanthrene, and pyrene was added at levels of 0 and 2000 mg/kg. Organic chemical degrader (OCD) populations were assessed by a Most-Probable-Number technique, and bacteria and fungi were enumerated by plate count methods. Different methods for expressing OCD rhizosphere populations were investigated to determine the effect it had on interpretation of the results. At 9 weeks, the OCD numbers were significantly higher in rhizosphere and contaminated soils than in bulk and non-contaminated soils, respectively. Alfalfa rhizosphere OCD levels were 4 × 107/g for contaminated and 6 × 106/g for non-contaminated soils. Bluegrass rhizosphere OCD levels were 1 × 107/g and 1 × 106/g in contaminated and non-contaminated soils, respectively. Selective enrichment of OCD populations was observed in contaminated rhizosphere soil. Higher numbers of OCD in contaminated rhizospheres suggest potential stimulation of bioremediation around plant roots.  相似文献   

15.
Glucose uptake by maize roots and its transformation in the rhizosphere   总被引:1,自引:0,他引:1  
The flow of carbon from roots into the rhizosphere represents a significant C loss from plants. However, roots have the capacity to recapture low molecular weight C from soil although this is in direct competition with soil microorganisms. The aim of this study was to investigate the behaviour of glucose in rhizosphere and non-rhizosphere soil, the plant's potential to recapture sugars from soil and translocation and utilization of the recaptured sugars. In microcosms containing maize plants we injected 14C-glucose into the rhizosphere and followed its uptake into plants, upward and downward transport in the plant and soil, evolution as 14CO2 and incorporation into the soil microbial biomass. These fluxes were compared with non-rhizosphere soil. Glucose was rapidly mineralized in soil and the rate of turnover was significantly greater in the rhizosphere in comparison to non-rhizosphere soil. The amount of glucose captured by the maize plants was low (<10% of the total 14C-glucose added) in comparison to that captured by the soil microbial biomass. Only small amounts of the 14C-glucose were transported to the shoot (0.6% of the total). The degree of glucose capture by maize roots whilst in competition with soil microorganisms was similar to similar experiments performed for amino acids. We conclude that while plant roots can recapture low molecular weight C from the rhizosphere, intense competition from soil microorganisms may reduce the efficiency of this process.  相似文献   

16.
The roots of 7-day-old hydroponically grown maize seedlings inoculated with a soil suspension 2 days after sowing are mostly inhabited by shorter rods and occasionally by actinomycete-like filaments, as seen by scanning electron microscopy. The density of the bacterial cover increases from 39 × 103 bacteria/mm2 in the region where root hairs are just emerging to 63 × 103 in the root hair zone 10 mm below the emerging secondary roots, and 188 × 103 in the oldest part 10 mm below the grain. In this region the bacterial cover can locally form a coherent multilayer. The average area covered by 1 bacterium is 1.04μm2 as measured by means of an image analyser. The percentage of the root area covered by its microflora, presuming a monolayer, is therefore 4%, 7% and 20%, respectively, of the three root zones under investigation. With an average dry weight of 0.64pg/cell all the 1.2 × 109 rhizoplane bacteria/g root dry matter only account for less than 0.1% of the root weight. The microbial population adapted to the rhizosphere has very simple nutritional demands. Whereas 65% of the soil microflora isolated on yeast extract grows on the simple aforementioned medium, the value is 92% for the rhizosphere organisms. In spite of appreciable amounts of vitamins found in the inoculated nutrient solution, the growth of vitamin requiring species is not stimulated compared to the soil population. The same is true for amino acids.  相似文献   

17.
Root-induced changes in the rhizosphere may affect mineral nutrition of plants in various ways. Examples for this are changes in rhizosphere pH in response to the source of nitrogen (NH4-N versus NO3-N), and iron and phosphorus deficiency. These pH changes can readily be demonstrated by infiltration of the soil with agar containing a pH indicator. The rhizosphere pH may be as much as 2 units higher or lower than the pH of the bulk soil. Also along the roots distinct differences in rhizosphere pH exist. In response to iron deficiency most plant species in their apical root zones increase the rate of H+ net excretion (acidification), the reducing capacity, the rate of FeIII reduction and iron uptake. Also manganese reduction and uptake is increased several-fold, leading to high manganese concentrations in iron deficient plants. Low-molecular-weight root exudates may enhance mobilization of mineral nutrients in the rhizosphere. In response to iron deficiency, roots of grass species release non-proteinogenic amino acids (?phytosiderophores”?) which dissolve inorganic iron compounds by chelation of FeIII and also mediate the plasma membrane transport of this chelated iron into the roots. A particular mechanism of mobilization of phosphorus in the rhizosphere exists in white lupin (Lupinus albus L.). In this species, phosphorus deficiency induces the formation of so-called proteoid roots. In these root zones sparingly soluble iron and aluminium phosphates are mobilized by the exudation of chelating substances (probably citrate), net excretion of H+ and increase in the reducing capacity. In mixed culture with white lupin, phosphorus uptake per unit root length of wheat (Triticum aestivum L.) plants from a soil low in available P is increased, indicating that wheat can take up phosphorus mobilized in the proteoid root zones of lupin. At the rhizoplane and in the root (root homogenates) of several plant species grown in different soils, of the total number of bacteria less than 1 % are N2-fixing (diazotrophe) bacteria, mainly Enterobacter and Klebsiella. The proportion of the diazotroph bacteria is higher in the rhizosphere soil. This discrimination of diazotroph bacteria in the rhizosphere is increased with foliar application of combined nitrogen. Inoculation with the diazotroph bacteria Azospirillum increases root length and enhances formation of lateral roots and root hairs similarly as does application of auxin (IAA). Thus rhizosphere bacteria such as Azospirillum may affect mineral nutrition and plant growth indirectly rather than by supply of nitrogen.  相似文献   

18.
覆盖模式及小麦根系对土壤微生物区系的影响   总被引:7,自引:3,他引:4       下载免费PDF全文
采用平皿分离培养法研究了5种栽培模式和小麦根系对土壤细菌、真菌及放线菌数量的影响。连续2年的定位测定结果表明:覆膜有利于土壤微生物数量增加。5种栽培模式中,小麦根区、根外土壤细菌数量均以覆膜模式下最高,分别为116.8×106cfu·g-1和86.7×106cfu·g-1;土壤真菌和放线菌数量均以垄沟覆膜(垄上覆膜、垄沟播种)模式下最高,分别为3.0×103cfu·g-1、1.4×103cfu·g-1和18.9×105cfu·g-1、19.7×105cfu·g-1。不同模式下小麦根系对土壤细菌和真菌数量影响较大,表现为根区高于根外;而根系对放线菌影响较小,只有补灌和覆膜2种模式为根区高于根外。多重比较结果显示,覆膜与其他模式之间细菌数量差异极显著,根区土壤细菌和真菌数量与根外存在显著差异。覆盖和根系能大幅度增加根区细菌、真菌和放线菌的数量,强化小麦根区根外细菌和真菌的数量差异。  相似文献   

19.
The paper summarizes the results of a series of experiments on enumeration of N2-fixing bacteria (diazotrophs) and hormonal effects of Azospirillum on root development. Numbers of N2-fixing and N-heterotrophic bacteria were determined on the root (rhizoplane plus “inner” root surface) and in the rhizosphere soil (0–3 mm from the root surface) of Arrhenatherum elatius, other forage grasses and some herbaceous plant species. Pot experiments involved freshly collected soil from an unfertilized grassland area containing its natural population of N2-fixing bacteria. The MPN (most probable number) of diazotrophs in relation to the MPN of the total bacterial population was always lower on the root than in the rhizosphere soil, suggesting that diazotrophs were not selectively advantaged at the root surface. Supply of mineral nitrogen (NH4NO3) decreased the proportion of N2-fixing bacteria at the rhizoplane as well as in the rhizosphere soil. Similar results were obtained when N was supplied via the leaves. The data suggest that N2-fixing bacteria in the rhizosphere are poor competitors once they loose their competitive advantage of binding dinitrogen. Correspondingly, the increase in the MPN of the diazotrophs found during plant development was interpreted as a result of decreased available combined N in the rhizosphere. The proportion of N2-fixing bacteria relative to the total number of bacteria was generally below 1%. Considering the potential amount of substrate released from the roots and the substrate requirement of the bacterial population, N2-fixation was considered insignificant for plant growth under the given conditions. For the investigations on possible beneficial effects on plant development by bacterial hormones, Azospirillum brasilense was chosen because evidence suggests that amongst the soil bacteria releasing hormones, especially IAA, certain strains of this species are more important than other bacteria. Application of A. brasilense Cd (ATCC 29710) onto the roots of young wheat plants grown in soil increased the number of lateral roots, the total root length and the number of root hairs. Similar results were obtained after application of IAA. This suggests that IAA is an important factor responsible for the effects observed after inoculation with A. brasilense. The increase in root surface may improve acquisition of nutrients and enhance growth of plants. Another hormonal effect of A. brasilense was an increase in nodulation of Medicago sativa grown on agar. Again pure IAA resulted in a similar increase in nodule number. Increases in nodule number were only in part associated with a change in root morphology. Therefore an effect of IAA on the plant immanent regulation system for nodulation is likely.  相似文献   

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