Rhizosphere mycoflora of wheat after foliar application of chlorocholine chloride,urea and 4-chloro-2-methylphenoxyacetic acid

A single-step spraying of wheat during shooting under field conditions with solutions of CCC (chlorocholine chloride), CCC and urea, CCC and Aminex (ammonium salt of 4-chloro-2-methylphenoxyacetic acid), or CCC, urea and Aminex caused changes both in numbers and composition of the rhizosphere mycoflora. The numbers both in the rhizosphere of differently treated plants and in the free soil decreased during vegetation. A more pronounced effect in the number of fungi was demonstrated in plants treated only with CCC. The difference was more considerable during first 10 days after the spray. As far as the relative occurrence of individual genera in the rhizosphere soil is concerned, fungi of the generaPenicillium Link ex Fr.,Fusarium Link ex Fr.,Verticillium Nees andTrichoderma Pers were most influenced after the treatment with the used agents.     

脲酶抑制剂氢醌对土壤脲酶活性,氨挥发和硝化的抑制动态

1.氢醌对土壤脲酶活性的抑制率及其持续的时间同氢醌浓度成正相关,与土壤脲酶活性成负相关。2.氢醌能有效地抑制施入土壤中尿素氨的挥发,而对铵盐和尿素的硝化强度产生强烈抑制。3.在麦秸还田土壤中,由于脲酶活性增高而提高了施入尿素的水解速度,故需提高氢醌用量;但由于麦秸的“氮因子效应”又固定了尿素分解产物及其氧化产物,从而弥补了氢醌失效后可能造成氮素的继续损失。     

套作棉根际与非根际土壤酶活性和养分的变化

在棉麦两熟双高产条件下研究了棉花根际与非根际土壤酶活性和养分含量的变化.结果表明,套作棉土壤脲酶、蔗糖酶、蛋白酶及过氧化氢酶活性随生育进程的变化趋势与单作棉表现一致,但整个生育期套作棉根际与非根际土壤各种酶活性均明显高于单作棉.套作棉根际与非根际土壤养分含量在麦棉共生期低于单作棉或差异较小,而在麦收后则显著高于单作棉.套作棉土壤养分含量随生育进程的变化趋势与单作棉大体相同,但一些养分的吸收高峰晚于单作棉.无论套作棉还是单作棉,根际土壤酶活性和养分含量高于非根际.土壤各养分含量与土壤脲酶、蔗糖酶和蛋白酶活性呈显著(P=0.0,n=32)或极显著(P=0.01,n=32)相关,与土壤过氧化氢酶活性相关不显著.     

脲酶抑制剂/硝化抑制剂对植稻土壤中尿素N行为的影响

采用自制根盒试验,主要研究了脲酶抑制剂氢醌（HQ）,硝化抑制剂双氰胺（DCD）及二者组合对离水稻根际不同距离处NH4^--N和NO3^-N分布的影响,结果表明,DCD及其与HQ组合均能显著促进稻株地上部分生长,始终显著降低水稻根际与近根际土中NH4^ -N含量直至施肥后60d,施肥后20d时,DCD及其与HQ组合可使非根际土中NH4^ -N含量显著增加,随后,却出现相反现象,施肥后20d时,距根际不同距离的土壤中,配施DCD或DCD＋HQ处理均能显著降低NO3^-N含量,随后,近根际和非根际仍保持上述现象直至施肥后40d;同未施DCD处理相比,根际土壤却较早出现NO3^--N含量高峰,正好与水稻N营养需求时期相一致,因此,DCD及其与HQ组合可减少水稻根际环境下尿素N损失潜势,通过不种稻土壤和距根际3cm处的土壤中尿素无机氮形态分布的差异,充分显示了研究水稻根际土壤氮素转化及相关抑制剂对其影响时,以取离根际3cm外的土壤作为非根际明显优于不种稻土壤。     

水分和氮源类型对小麦根际土壤酶活性和氮素利用效率的影响

本研究以‘郑麦366'(强筋)和‘百农207'(中筋)两个小麦品种为试验材料,分别在全生育期不灌水(W₁)和拔节+抽穗灌两水(W₂)条件下,研究了氯化铵(NT₁)、硝酸钙(NT₂)、尿素(NT₃)和硝酸铵钙(NT₄)4种氮源类型对小麦土壤供氮能力、产量和氮素利用效率的影响,以期为小麦高产高效生产提供理论和技术支撑。结果表明: 1)随着土层深度的增加,开花期土壤中铵态氮和硝态氮含量呈下降趋势。在W₂条件下,0～60 cm土层铵态氮、硝态氮含量,根际土壤脲酶、蔗糖酶和过氧化氢酶活性均低于相应W₁条件下,其中强筋小麦郑麦366平均分别下降10.0%、13.3%、7.5%、2.8%和3.9%。2)两个小麦品种0～60 cm土层铵态氮含量均表现为在NT₁和NT₃处理下显著高于其他处理;而硝态氮含量则在NT₂和NT₃处理下显著高于其他处理。与NT₁和NT₂处理相比,NT₃和NT₄提高了灌浆中、后期土壤脲酶和蔗糖酶活性。3)两个小麦品种在NT₃和NT₄处理下籽粒产量和氮素利用效率较高;其中在W₂条件下,郑麦366在NT₃和NT₄处理下的产量较NT₁处理分别增加14.9%和20.7%,NUE分别增加25.6%和13.9%。4)相关分析结果表明, 0～20 cm土壤硝态氮含量、20～40 cm土壤铵态氮含量分别与小麦产量、氮素利用效率呈显著正相关。两种水分条件下,施用尿素和硝酸铵钙均提高了灌浆中、后期根际土壤酶活性,有利于籽粒产量和氮素利用效率的提高。     

The rhizosphere microflora of wheat grown under controlled conditions II. Influence of the stage of growth of the plant,soil fertility and leaf treatment with urea on the rhizosphere soil microflora

Summary The rhizosphere effect of seminal roots of seedlings and of nodal roots of tillering plants of spring wheat ‘Kaspar’ was investigated under controlled conditions. The total number of micro-organisms recorded in the rhizosphere soil were significantly higher than for the non-rooted soil when investigated with the soil dilution plate method, but lower when fluorescence microscopy was used. Additions of inorganic fertilizer (NPK) decreased their numbers especially in rhizosphere soil of seminal roots and in non-rhizosphere soil, but did not change the ratio between bacteria and actinomycetes (B/A). In the rhizosphere soil the B/A ratio was higher than in the non-rhizosphere soil. An effect of urea leaf treatment was found with the dilution-plate method only in the rhizosphere soil of nodal roots, 3 to 7 days after the first treatment. Increased numbers of actinomycetes were found in this period in NPK fertilized soil, whereas increased numbers of bacteria were found at both fertility levels.     

Leaf urea metabolism in potato. Urease activity profile and patterns of recovery and distribution of (15)N after foliar urea application in wild-type and urease-antisense transgenics

The influence of urease activity on N distribution and losses after foliar urea application was investigated using wild-type and transgenic potato (Solanum tuberosum cv Désirée) plants in which urease activity was down-regulated. A good correlation between urease activity and (15)N urea metabolism (NH(3) accumulation) was found. The general accumulation of ammonium in leaves treated with urea indicated that urease activity is not rate limiting, at least initially, for the assimilation of urea N by the plant. It is surprising that there was no effect of urease activity on either N losses or (15)N distribution in the plants after foliar urea application. Experiments with wild-type plants in the field using foliar-applied (15)N urea demonstrated an initial rapid export of N from urea-treated leaves to the tubers within 48 h, followed by a more gradual redistribution during the subsequent days. Only 10% to 18% of urea N applied was lost (presumably because of NH(3) volatilization) in contrast to far greater losses reported in several other studies. The pattern of urease activity in the canopy was investigated during plant development. The activity per unit protein increased up to 10-fold with leaf and plant age, suggesting a correlation with increased N recycling in senescing tissues. Whereas several reports have claimed that plant urease is inducible by urea, no evidence for urease induction could be found in potato.     

Growth of Phaseolus vulgaris on Various Nitrogen Sources: The Importance of Urease

Rhizobium-inoculatcd plants of Phaseolus vulgaris L. were grownwith different N-sources (nitrate, ammonium, urea) and differentconcentrations of urea. The distribution of growth between plantparts varied with N-sources. Nitrate and ammonium were moreinhibitory to nodulation than urea, which at 40 mol m^–3N had no effect. Urease activity varied in amount and locationover a range of urea concentrations. At higher concentrations,more urea was transported to and increased urease activity wasfound in the shoot Lower levels of activity in plants relianton N₂-fixation were consistent with a ureide-degradation pathwaynot involving urea. Moderate doses of urea could be assimilatedconcomitantly with N₂-fixation. At higher levels of appliedurea, nodulation and ureide transport to the shoots were reduced,although increased growth could not be maintained at concentrationsof applied urea greater than 6.0 mol m^–3 urea N. Key words: Phaseolus vulgaris, growth, nitrogen source, urease     

Respiration and microflora of the rhizosphere soil of wheat influenced by foliar application of urea

The numbers of micromycetes and bacteria were investigated with respect to oxygen consumption in the rhizosphere soil of wheat and in non-rhizosphere soil. Plants after foliar application of urea (2 % solution) and non-treated plants were cultivated in degraded chernozem and garden soil in a green-house. Changes in oxygen consumption by the suspensions of rhizosphere and non-rhizosphere soils corresponded to changes in the number of bacteria designated as the rhizosphere effect (R/S). Values of R/S depended on the presence of organic substrates. Changes in oxygen consumption by the soil suspension from the rhizosphere of wheat occurring due to foliar application of urea corresponded to changes in the amount of microflora. The results obtained are discussed with respect to a possible utilization of the data to follow metabolic activity of soils in a natural environment (in situ) determined according to oxygen consumption by a soil suspension, and to assess changes in the microflora of rhizosphere and non-rhizosphere soil.     

接种内生降解菌Stenotrophomonas pavanii DJL-M3对多菌灵胁迫下水稻根际微生态的影响

内生降解菌定殖可促进水稻中农药等有机污染物的降解代谢,研究功能内生菌对农药暴露下水稻根际微生态的影响,可为利用植物-微生物互作调控农作物农药残留及修复农田生态环境污染提供科学依据。以水稻根际土壤中的蚯蚓、土壤酶和微生物群落为研究对象,分析接种内生菌Stenotrophomonas pavanii DJL-M3对水稻根际微生态响应多菌灵胁迫的影响。结果表明：多菌灵暴露导致水稻根际土壤过氧化氢酶活性增强,脲酶和蔗糖酶活性被抑制;多菌灵污染可对水稻根际周围的蚯蚓造成氧化损伤,致使其体内丙二醛累积并诱导超氧化物歧化酶和乙酰胆碱酯酶过表达;多菌灵残留显著降低水稻根际土壤微生物群落的多样性与碳源代谢活性。接种内生降解菌S.pavanii DJL-M3促进了水稻根际残留多菌灵的降解,缓解根际土壤微生物与蚯蚓所受胁迫压力,显著提高了土壤脲酶、蔗糖酶活力以及蚯蚓的存活率,并有效提升了水稻根际微生物群落的代谢活性与多样性。因此,接种内生降解菌S.pavanii DJL-M3有助于多菌灵残留污染下稻田土壤生态环境的恢复。     

Microbial changes in clover rhizosphere after foliar and soil application of cobalt

Application of cobalt(II) nitrate to the leaves of red clover (Trifolium pratense L.) resulted in a pronounced increase of dry weight and the number of root nodules. Counts of bacteria in the rhizosphere, content of ammonia and production of carbon dioxide m rhizosphere soil were also higher, whereas the content of nitrates decreased Differences m the counts of bacteria, aotmomycetes, Azotobaoter, anaerobic bacteria and cellulose decomposing bacteria m the rhizosphere of control and treated plants were not directly related to the way of application of cobalt. GeneraPenicillium, Fusarium andTrichoderma predominated among fungi. The relative occurrence of pemcillia was higher after the application of cobalt, the incidence of fusaria was lower. The effects of foliar and soil application of cobalt on rhizosphere microflora were not identical.     

Influence of fertilizers on nitrogen mineralization and utilization in the rhizosphere of wheat

Plant roots and microorganisms play an important role in the soil N cycle and plant N nutrition through the release of extracellular enzymes. In the present greenhouse pot experiment, wheat (Triticum aestivum) seedlings were grown in a fluvo-aquic soil (Udifluvent) to investigate N mineralization and utilization in the rhizosphere of wheat. The soil received chemical fertilizer (¹⁵N-labeled urea), chemical fertilizer plus manure (common urea + ¹⁵N-labeled swine manure) or no N. Plant roots were separated from the soil with a nylon cloth, and 1-mm increments of soil moving laterally away from roots were analyzed for N, microbial C, and the activities of invertase, urease and protease. Chemical fertilizer plus manure promoted wheat growth and N absorption significantly compared with chemical fertilizer. ¹⁵N from both chemical fertilizer and swine manure accumulated significantly in the rhizosphere soil within 5 mm of the roots. Fertilized N could thus move easily laterally towards roots and there was no indication that movement through the soil limited plant N supply. A large proportion of fertilizer N was lost from the soil during the wheat growing period, and N utilization efficiency was 24% for chemical fertilizer and 30% for swine manure. In addition, faster rates of N mineralization, larger amounts of microbial C, and increased activities of invertase, urease and protease occurred in the rhizosphere compared with other parts of the soil. There was a significant correlation between microbial C and N mineralization rate (r?=?0.968, P?<?0.01) in the whole soil. Microbial C also showed significant positive correlations with activities of invertase (r?=?0.892, P?<?0.01) and protease (r?=?0.933, P?<?0.01). Further study showed that adding manure into soil increased microbial C and the activities of invertase and protease; adding urea stimulated urease activity in the same soil. Changes in soil enzyme activities in response to N fertilizers could be considered indicators for different fertilizer managements.     

The effect of quinoid and phenolic compounds on urease and dehydrogenase activity and nitrification in soil

Summary 1,4-Naphthoquinone; 2-methyl-1,4-napthoquinone; 2,3-dichlorohydroquinone; 4,6-di-tert.butyl-o-benzoquinone; 4,6-di-tert.butylpyrocatechol and 4-tert.butylpyrocatechol at concentrations of 10 and 20 ppm inhibit mineralization of urea N by reducing urease activity and/or nitrification in soils. Coating of urea with these chemicals was more effective than direct application to the soil. There was no adverse effect of any of the chemicals either on germination or on the growth of wheat plants at concentrations of 20 and 50 ppm added to soil.     

Artificial carbon dioxide source to attract lesser cornstalk borer (Lepidoptera: Pyralidae) larvae

Different combinations of urea, urease (in jack bean meal, Canavalia DC.), and water were tested as carbon dioxide sources to attract larvae of lesser cornstalk borer, Elasmopalus lignosellus (Zeller), by using olfactory bioassays with an olfactometer and infrared gas analysis. A combination of urea, jack bean meal, and water was necessary to release a high level of carbon dioxide to attract the larvae. Different proportions of the three ingredients had different carbon dioxide release rates and exhibited different levels of attraction to the larvae. When carbon dioxide concentration was too high, attractiveness declined. Combinations with different amounts of water remained attractive for a period of up to 3 d, depending on the moisture of the samples. When Zonolite was used to simulate the soil conditions in the olfactometer, significantly more larvae located the area near the artificial carbon dioxide sources compared with the control. When combined with the artificial carbon dioxide sources, three insecticides (Lorsban, Temik, and Force) did not obviously affect the release rates of carbon dioxide, and more larvae were attracted to samples with the carbon dioxide source than to the samples without carbon dioxide.     

Effect of nickel deficiency in soybeans on the phytotoxicity of foliar-applied urea

The leaf-tip necrosis commonly observed after foliar fertilization of soybean [Glycine max (L.) Merr.] plants with urea is usually attributed to ammonia formed through hydrolysis of urea by plant urease. We recently found, however, that although addition of a urease inhibitor (phenylphosphorodiamidate) to foliar-applied urea increased the urea content and decreased the ammonia content and urease activity of soybean leaves, it increased the leaf-tip necrosis observed after foliar fertilization. We concluded that this necrosis was due to accumulation of toxic amounts of urea rather than formation of toxic amounts of ammonia. To confirm this conclusion, we measured the urea content, urease activity, and leaf-tep necrosis of leaves of soybean plants treated with urea after growth of the plants in nutrient solutions containing different amounts of nickel (Ni), which is an essential component of urease. We found that the urease activity of these leaves decreased, and that their urea content and leaf-tip necrosis increased, with decrease in the Ni content of the nutrient solution. Besides supporting the conclusion that the leaf-tip necrosis observed after foliar fertilization of soybean with urea is due to accumulation of toxic amounts of urea in the soybean leaves, these observations indicate that Ni-deficient plants may have a lower urease activity than plants that are not deficient in Ni and may therefore be more susceptible to leaf burn when foliar-fertilized with urea.     

施氮量对冬小麦根际土壤酶活性的影响

在大田高产条件下,研究了不同施氮水平对大穗型小麦品种兰考矮早八和多穗型小麦品种豫麦49-198根际土壤酶活性的影响.结果表明:两种穗型冬小麦品种根际土壤酶活性随生育进程的变化趋势一致,即蛋白酶、脲酶及脱氢酶活性均呈先升后降的变化趋势;过氧化氢酶活性随生育进程的推进逐渐增加,在成熟期达到最大值.在同生育时期内,随着施氮水平的提高,土壤蛋白酶、过氧化氢酶及脱氢酶活性均呈先增后降的变化趋势,以180 kg N·hm-2施氮水平的活性最高;脲酶活性则随施氮水平的提高而上升,在360 kg N·hm-2施氮水平下达到最高.     

外来入侵植物的氮代谢及其土壤氮特征

研究了4种外来入侵植物(五爪金龙、南美蟛蜞菊、金腰箭和马缨丹)和1种本地植物鸡矢藤(对照)的氮代谢及其土壤氮特征.结果表明:外来人侵植物的组织硝酸还原酶活性、根际土壤NH4-N、NO3-N含量、蛋白酶活性和脲酶活性均较高,分别为鸡矢藤的1.65～4.34、1.56～2.15、1.72～3.11、1.43～3.23和1.41～3.33倍,而植物组织硝态氮含量则较低,仅为鸡矢藤的17.5%～50.6%.相关分析表明:植物组织硝酸还原酶活性与根际土壤总氮、NH4-N、NO3-N含量呈显著正相关(P<0.05),与蛋白酶活性和脲酶活性呈极显著正相关(P<0.01).这说明,外来植物入侵使土壤氮代谢加快,氮的生物有效性增强,氮同化能力提高,并且较好地将植物体氮素代谢与土壤氮素代谢协调起来.因此,较强的氮素同化能力与加速土壤氮素的转化可能是植物成功入侵的重要机制之一.     

生物有机肥对连作当归根际土壤细菌群落结构和根腐病的影响

研究生物有机肥料DZF-363对当归生长、根腐病的发病情况及土壤微生物群落结构和功能的影响,可为其对连作当归根际土壤环境的调节和改善提供理论依据.本研究以连作2年的当归及其根际土壤为对象,设置对照(不施农药和微生物肥料,CK)、农药(15%的阿维毒死蜱乳油+50%多菌灵可湿性粉剂,N)和生物有机肥DZF-363(DZF)处理,利用高通量测序和比色的方法,研究施用DZF-363对当归根际土壤微生物群落结构和土壤脲酶、磷酸酶活性的影响.结果表明:施用DZF-363比对照和农药处理分别增产18.8%和6.8%.施用DZF-363使当归根腐病病情指数显著降低,对根腐病防效达52.0%;整个生育期当归根际土壤的脲酶、中性磷酸酶、碱性磷酸酶活性显著提高,苗期、生长中期及收获期脲酶活性分别提高52.4%、13.9%、10.3%,中性磷酸酶活性分别提高15.5%、10.2%、10.3%,碱性磷酸酶活性分别提高10.3%、4.4%、4.0%,酸性磷酸酶活性在当归生长中期及收获期分别提高15.6%、8.2%.放线菌门在CK、N和DZF处理中的占比分别为11.3%、10%和20%,未知的放线菌纲和芽孢杆菌纲在DZF处理中的占比显著高于CK和N处理.施用DZF-363能显著增加当归根际土壤Shannon指数,且Shannon指数和Simpson指数与当归产量呈正相关,与根腐病呈负相关.表明施用DZF-363能显著增加当归根际土壤细菌多样性,改变当归根际土壤细菌群落结构,提高根际土壤脲酶和磷酸酶活性,减轻当归根腐病的发生,显著提高当归产量.     

控释掺混尿素对稻、麦土壤氮与酶活性的影响

通过大田试验,共设7个处理,即不施氮、常规施肥以及掺混控释氮肥10%、20%、40%、80%、100%处理,探讨了不同施肥处理对土壤中4种形态氮(全氮、铵态氮、硝态氮、微生物生物量氮)和3种氮功能性酶(脲酶、蛋白酶、硝酸还原酶)活性的影响,以探究控释掺混尿素对稻、麦土壤肥力和环境的影响.结果表明: 土壤全氮在稻、麦全生育期内趋于稳定,且掺混比例20%以上各控释氮肥处理在稻、麦季均无显著差异;掺混40%以上控释氮肥能有效促进稻、麦生育中后期土壤无机氮水平;随稻、麦生育期推进,掺混40%以上控释氮肥处理可显著提高土壤微生物生物量氮,但常规施肥处理的微生物生物量氮整体呈明显下降趋势;掺混40%以上控释氮肥能明显提升稻、麦生育中后期土壤酶活性,土壤蛋白酶与硝酸还原酶活性在作物生育后期均随掺混比例增加而提高,以100%控释氮肥处理土壤酶活性最高.掺混20%以上控释氮肥处理能明显降低水稻季分蘖期脲酶活性,推迟铵态氮峰值期,有利于减少氮损失;掺混40%以上控释氮肥处理均可保障稻、麦生育中后期的氮素供应,刺激土壤脲酶与蛋白酶参与氮素转换,促进了土壤氮素有效性;100%控释氮肥处理对稻、麦生育后期土壤硝酸还原酶活性增加最明显,与掺混40%～80%控释氮肥处理相比,可显著减少小麦季20～40 cm土壤硝态氮残留量,在减少氮素损失方面的效果明显.