首页 | 本学科首页   官方微博 | 高级检索  
相似文献
 共查询到17条相似文献,搜索用时 125 毫秒
1.
程思  王超  沈仁芳 《土壤》2020,52(6):1158-1163
微生物菌株RS1是从江西鹰潭油茶酸性土壤中筛选获得的一株高耐铝红酵母,能够忍耐高达200 mmol/L以上的铝浓度。前期研究表明RS1可以把铝固定在细胞表面,阻挡其进入细胞内部,但是细胞表面何种基团参与铝的固定并不清楚。本文综合采用傅里叶红外光谱和拉曼光谱技术研究了铝胁迫下红酵母RS1细胞表面官能团变化,以期从光谱学角度来探索RS1的高耐铝机制。研究发现,70 mmol/L铝处理24小时后RS1红外光谱中1403 1/cm 处的吸收峰红移到1397 1/cm处,这可能是羧基峰;在1706 1/cm处出现新的吸收峰,这可能是羰基峰;多糖、β-1,3-葡聚糖、酰胺I带、脂肪酸对应的吸收峰强度均显著减弱,且甘露聚糖的吸收峰消失。拉曼光谱在779 1/cm 、856 1/cm处和1270 1/cm处出现新的吸收峰,可能分别为核糖核酸、酪氨酸和酰胺Ш带的吸收峰。综合结果表明,RS1细胞表面与铝吸附相关的物质主要是细胞壁多糖和蛋白质,主要涉及到的官能团包括羧基、羰基和酰胺基。这些细胞表面官能团对铝的固定作用可能是红酵母RS1高耐铝的一个重要机制。  相似文献   

2.
高耐铝红酵母RS1耐铝特性初步研究   总被引:1,自引:1,他引:0       下载免费PDF全文
王超  赵学强  沈仁芳 《土壤》2013,45(3):501-505
红酵母RS1是从酸性土壤中筛选出的一株高耐铝微生物,本文对其耐铝特性进行了初步研究.结果发现,RS1可以在pH 2.5的培养基中生长,50 ~ 200 mmol/L A13+处理对RS1产生了毒害作用,其毒害并未对细胞表面形态产生影响.RS1对Al2(SO4)3的忍耐能力高于AlCl3,这种高的忍耐能力是遗传固有的,并不被诱导产生.此外,RS1可以增加体内蛋白含量来适应高的铝毒,其中蛋白型巯基可能在耐铝中表现重要作用.  相似文献   

3.
用一氧化氮供体硝普钠(sodium nitroprusside,SNP)处理铝胁迫下的黑麦和小麦幼苗,探讨铝胁迫和铝胁迫下外源NO对黑麦和小麦根尖细胞壁铝吸附的影响。结果表明:铝显著抑制黑麦和小麦根的伸长生长,小麦受抑制更为严重;SNP处理可缓解铝对黑麦和小麦根伸长生长的抑制作用,1 mmol/L SNP处理最有效。小麦根尖对铝的吸附量和吸附速率显著高于黑麦的,1 mmol/L SNP处理显著降低小麦和黑麦细胞壁对铝的吸附量,使根尖铝含量显著下降。铝与根尖细胞壁的结合是导致植物铝毒害的重要原因,而降低根尖细胞壁对铝的吸附是外源NO缓解铝毒害的重要机制。  相似文献   

4.
  【目的】  比较加硼和不加硼条件下豌豆根尖细胞壁组分对铝的吸附解吸特征的差异,探讨硼对植物铝胁迫的缓解机制。  【方法】  以中豌6号豌豆(Pisum Sativum)为试验材料,在硼(0.6 μmol/L)水平下水培6天,提取豌豆根尖1 cm段细胞壁各组分并进行铝吸附解吸试验,根尖细胞壁各组分分别为螯合态果胶(果胶1),碱溶态果胶(果胶2),半纤维素和纤维素,并分析3个不同硼处理 (无硼、50 μmol/L H3BO3和 50 μmol/L 3-硝基苯硼酸) 条件下各组分对铝吸附解吸的影响。  【结果】  豌豆根尖细胞壁各组分含量为:纤维素>半纤维素>果胶2>果胶1。硼能够与果胶1和果胶2发生络合反应,与半纤维素也可能发生络合反应,从而影响果胶1、果胶2和半纤维素对铝的吸附解吸。在铝胁迫下,根尖细胞壁中的果胶是主要的铝结合位点,以果胶2结合最多。与对照比,硼处理显著提高了果胶2对铝的吸附量,但解吸量变化不显著。pH 3.5条件下,硼酸与3-硝基苯硼酸处理相比,更能有效地影响果胶对铝的吸附解吸。因此将铝固定在细胞壁的果胶2内,可能是硼酸缓解铝毒的重要机制之一。  【结论】  细胞壁是铝的主要结合部位,细胞壁果胶2是根尖细胞壁主要的铝结合位点,硼与果胶2的结合可能是硼缓解铝毒的重要机制之一。  相似文献   

5.
铝毒胁迫下磷对荞麦根系铝形态和分布的影响   总被引:4,自引:1,他引:3  
以2个荞麦(Fagopyrum esculentum Moench)品种"江西荞麦"(铝耐性)和"内蒙荞麦"(铝敏感)为材料,采用水培法,研究铝毒胁迫下磷对荞麦根系总铝和单核2种形态以及Al在根尖和细胞壁中的分布情况的影响。结果表明,与200μmol/L Al处理相比,1.0mmol/L磷预处理分别使江西荞麦和内蒙荞麦的相对根长增加了24.4%和35.9%,根系总Al含量分别降低了18.2%和22.5%,根系单核Al含量分别降低了95%和63.2%。根尖细胞壁荧光检测结果为在单Al胁迫下细胞壁的荧光强度最大,1.0mmol/L磷预处理大幅度减弱细胞壁的荧光强度。表明外源磷供应可降低根系总Al和单核Al含量,使毒性形态的铝转化为无毒形态,以及减少Al在根尖以及细胞壁的积累,以缓解Al对根伸长的抑制,提高荞麦根系的抗铝毒害能力。  相似文献   

6.
  【目的】  磷富集植物对高磷具有良好的耐性是其应用于植物修复的前提。本研究探讨磷富集植物矿山生态型水蓼根系对高磷的耐受能力,为后期利用其修复环境中的过量磷提供一定的理论依据。  【方法】  采用矿山生态型和非矿山生态型水蓼(ME和NME)进行了水培试验,营养液中设置无机磷2、4、8、16 mmol/L 4个高浓度处理,以正常磷0.5 mmol/L浓度为对照,分析对比了两种生态型水蓼根系对高磷的耐受特征。  【结果】  随着磷浓度的增加,ME地上部和根系生物量和磷积累量均先显著增加后降低,在磷浓度4 mmol/L时出现峰值,而NME则大体呈降低趋势。高磷处理ME地上部和根系生物量分别为NME的1.35~2.56和1.18~1.86倍,除磷浓度16 mmol/L处理外,ME地上部和根系磷积累量分别为NME的1.35~2.58和1.36~1.96倍,磷积累能力更强。ME根系质膜开始受到明显损伤的营养液磷浓度是8 mmol/L,而NME是磷浓度4 mmol/L。随着磷浓度的增加,ME根系中H2O2、MDA和NME根系中的MDA含量均表现为先稳定后显著增加,而NME根系中的H2O2含量则持续增加;两种生态型水蓼根系SOD、POD和CAT活性均先显著增高后降低,分别在磷浓度4和2 mmol/L时显著高于对照。与NME相比,ME根系抗氧化酶活性更高,对H2O2和MDA的清除能力更强。两种生态型水蓼根系亚细胞组分磷含量均表现为可溶部分(含液泡)>细胞壁>细胞器。随着磷浓度的增加,两种生态型水蓼各亚细胞组分磷含量均显著增加,且在磷浓度2和4 mmol/L处理下,根系可溶部分(含液泡)磷分配比例明显高于对照,液泡是其磷素储存的重要场所。  【结论】  矿山生态型水蓼对高磷的耐受能力和磷积累能力均强于非矿山生态型水蓼。高磷处理下矿山生态型水蓼存在根系自由基和保护酶动态平衡、细胞壁固持和可溶部分的液泡区隔化现象,这是其根系的重要耐受特征。  相似文献   

7.
研究了耐铝性明显差异的2个小麦基因型西矮麦1号(耐性)和辐84系(敏感)根系对铝毒胁迫的反应与根尖细胞壁组分以及细胞壁对铝的吸附和解吸的关系。结果表明,30mol/L.AlCl3可迅速抑制小麦根系伸长,但对辐84系根系伸长的抑制更为明显,且小麦根系相对伸长率随着铝浓度的提高而急剧降低。在30mol/L.AlCl3处理24h后,西矮麦1号根系伸长的抑制率为33.3%,而辐84系根系伸长的抑制率高达70.9%。小麦距根尖0~10.mm根段的铝含量和细胞壁中果胶糖醛酸含量显著高于10~20.mm根段,且前者对铝的累积吸附量明显大于后者;在0~10.mm根段,敏感基因型果胶含量高于耐性基因型,其根尖含铝量及根尖细胞壁对铝的吸附量都要大于后者。采用1.0.mol/L.NH3.H2O对细胞壁预处理2.h降低果胶甲基酯化程度后,耐性和敏感基因型根尖细胞壁对铝的累积吸附量分别降低了17.1%和20.9%,但对铝的累积解吸率没有影响。由此可见,小麦根尖是铝毒的主要位点,细胞壁果胶含量和果胶甲基酯化程度可能是导致不同小麦基因型根尖细胞壁对铝吸附量、铝积累量的差异及其对铝毒胁迫反应的差异的重要原因。  相似文献   

8.
蜈蚣草的超微结构和砷、钙的亚细胞分布   总被引:1,自引:1,他引:0  
本文对砷和钙处理下蜈蚣草羽叶中砷、钙的亚细胞分布、超微结构变化及钙定位进行了研究。无砷处理下,各亚细胞组分中砷的分布为:细胞壁>胞质>细胞器。0.2.mmol/L砷处理下,羽叶各亚细胞组分中砷的分布为:胞质>>细胞壁>细胞器。不同处理下,各亚细胞组分中钙含量变化规律相似:细胞壁最高,胞质其次,而细胞器远低于前两者。5.mmol/L钙处理对蜈蚣草羽叶细胞超微结构产生破坏,使细胞出现明显的质壁分离。在高砷高钙环境中,钙可能会增强砷对蜈蚣草的毒害效应,导致羽叶细胞的超微结构受到破坏。  相似文献   

9.
低分子量有机酸对土壤磷活化影响的研究   总被引:14,自引:3,他引:11  
研究两种低分子量有机酸(柠檬酸和苹果酸)对土壤磷活化影响,并用修正的Hedley法测定土壤磷活化前后磷组分的变化。结果表明,低分子量有机酸能持续活化土壤磷,活化强度随低分子量有机酸浓度的增大而增强,并且柠檬酸活化土壤磷的能力强于苹果酸。低分子量有机酸能促进作物有效态无机磷组分(H2O-P和NaHCO3-Pi)的释放;同时还促进有机磷组分(NaHCO3-Po和NaOH-Po)的矿化。在低分子量有机酸浓度达到0.5 mmol/L以上时,其对土壤磷组分的活化量的顺序为:NaOH-Pi HCl-P NaHCO3-Pi H2O-P,即铁铝结合态磷 钙结合态磷 作物有效态磷。低分子量有机酸活化土壤磷的过程中伴有大量铁、铝释放,且铁或铝的释放量与磷活化量之间显著正相关(P0.05)。说明铁、铝结合态磷是低分子量有机酸活化土壤磷的主要磷源,并且其活化机制可能与铁、铝结合态磷的螯合溶解有关。  相似文献   

10.
黑麦品种间耐铝差异性机制研究   总被引:1,自引:0,他引:1  
采用室内模拟方法,研究了铝诱导黑麦根系分泌有机酸、根尖磷对铝的固定作用。结果表明,在铝胁迫下冬牧品种(Win)相对根伸长率高于King品种。在铝胁迫下,经磷预处理的根尖铝和磷含量增加,且以Win品种根尖中的Al、P含量较高,说明根尖磷对铝的固定是黑麦耐铝机制之一。另一方面,在铝胁迫下,两品种根系均分泌柠檬酸和苹果酸,且Win的分泌速率较高。有机酸的分泌随着铝处理浓度(10、30、50 mol/L)和时间(0.5、3、6、9、12 h)的增加而增加,但在低温(4C)下柠檬酸分泌量显著减少。Al处理0.5 h后苹果酸已明显分泌,而柠檬酸的分泌在铝处理6 h后才明显增加。在铝处理前,进行缺磷预处理(3 d)不能增加有机酸的分泌,10 mol/L的La3+、Cu2+、Ni3+也不能诱导根系分泌有机酸。说明铝诱导根系专一性分泌有机酸也是黑麦品种间耐铝性差异的机制。  相似文献   

11.
Aluminum (Al) is very toxic to many living organisms, including plants, animals and microorganisms. However, despite many studies on Al tolerance in plants, little has been reported concerning these mechanisms in microorganisms. In this study, a red yeast, which could tolerate Al 3+ concentrations as high as 200 mmol L-1 , was isolated from acidic soils, identified as Rhodotorula sp. and designated as RS1. As the medium compositions can greatly affect the responses of microorganisms to Al, two culture mediums, glucose medium (GM) and lysogeny broth medium containing soil extract (S-LBM), were used. During growth of RS1, the pH of medium decreased in GM but increased in S-LBM. These changes in the pH of the media were not induced by Al addition. No or little secretion of organic acids was observed in RS1 growth media. Importantly, the thickness of the cell walls and the ratio of cell wall to biomass of RS1 significantly increased in GM with high Al 3+ concentrations. In the presence of 100 mmol Al L-1 , 78.0% of the total Al of whole cells was present in the thickened cell walls. The Al in cell walls was mostly bound to OH, amide and CO groups of polysaccharides. These results suggest that thickening of the cell wall in response to the high Al 3+ concentrations may play an important role in the high tolerance of RS1 to Al and that pH increase of the medium and chelation of Al ions are not involved in Al tolerance of this organism.  相似文献   

12.
玉米、小麦细胞磷、锌营养及交互作用的研究   总被引:12,自引:0,他引:12  
采用溶液培养研究玉米、小麦在不同磷、锌浓度下细胞磷、锌营养及交互作用。结果表明,随着外界磷浓度(0,0.12,0.6,3.0mmol/L)的提高,玉米、小麦根系和叶片细胞壁、细胞质和液泡中磷含量也随之增高,但细胞壁和液泡中磷的含量高于细胞质中的含量。介质中磷浓度的提高使根细胞壁中锌的含量增加,但高磷(3.0mmol/L)处理使细胞质、液泡中锌的含量下降。高磷处理抑制了两种作物的锌由根系向地上部的转运,同时叶片中大部分锌被结合在细胞壁中,因而叶细胞中的细胞质和液泡处于相对的低锌状态。与足量锌(2.0mol/L)供应比较,低锌(0.1mol/L)处理使玉米、小麦根系和叶细胞壁、细胞质和液泡中磷的浓度增高。低锌和过量磷的供给抑制了植株的生长,最终使干物质的积累下降。  相似文献   

13.
豌豆不同耐铝品种根尖细胞壁果胶及其甲基酯化度的差异   总被引:1,自引:0,他引:1  
【目的】研究豌豆不同品种耐铝性和根尖根段耐铝性与果胶及其甲基酯化间的关系,为进一步揭示植物耐铝机理以及耐铝性状的遗传改良提供依据。【方法】以豌豆品种Hyogo和Alaska为试验材料,采用Hoagland培养方式,测定了不同品种不同根段果胶含量、 果胶甲基酯化度和果胶甲酯酶活性,研究了其差异及原因。【结果】在15和30 μmol/L铝浓度胁迫条件下,豌豆品种Alaska根相对伸长率均显著高于品种Hyogo,同时有根尖0~5 mm和5~10 mm段有更少的胼胝质生成和累积,在30 μmol/L浓度下不同根段间均达到显著差异,同时品种Hyogo根尖0~2.5 mm和2.5~5.0 mm段铝含量均显著高于品种Alaska,说明品种Alaska和品种Hyogo间存在耐铝性差异,其中品种Alaska耐铝性高于品种Hyogo,即品种Hyogo为铝敏感品种,品种Alaska是耐铝品种。比较两者不同根段(0~2.5 mm、 2.5~5.0 mm和5.0~10.0 mm)的铝含量与果胶含量、 果胶甲基酯化度、 PME活性间的关系,发现耐铝品种不同根段中的铝含量均小于敏感品种,并且在0~2.5 mm和2.5~5.0 mm段间达到显著性差异; 根尖不同根段果胶糖醛酸含量大小依次为0~2.5>2.5~5.0>5.0~10.0 mm,耐铝品种Alaska根尖细胞壁果胶和未甲酯化果胶含量均显著低于Hyogo,并且0~2.5 mm根段差异最大。根尖不同根段果胶甲基酯化度从根尖向上逐渐降低,并且耐铝品种Alaska高于铝敏感品种Hyogo,其中0~2.5 mm段间的差异达到显著水平;在对两个品种果胶甲基酯化酶(PME)活性进一步分析发现,PME活性大小依次为0~2.5>2.5~5.0>5.0~10.0 mm,两品种0~2.5 mm和2.5~5.0 mm根段间均达到显著差异。【结论】铝敏感品种Hyogo在0~2.5 mm和2.5~5.0 mm根段具有较高 PME活性和较低果胶甲基酯化程度。豌豆根尖果胶含量和甲基酯化度尤其是0~2.5 mm根段是豌豆耐铝性差异的重要原因;Alaska根尖细胞壁的果胶含量低和果胶甲基酯化度高(尤其是0~2.5 mm段)是其耐铝的重要机制。  相似文献   

14.
Corn and wheat plants were grown in a nutrient culture solution at four levels of phosphorus (0,0.12,0.60 and 3.0mmol L^-1) and two levels of cadmium(0 and 4.0umol L^-1) in greenhouse for a 18-day period.The concentrations of phosphorus and cadmium in cell wall,cytoplasm and vacuoles of roots and leaves were examined by cell fractionation techniques.With increasing phosphorus in medium,the contents of P in cell wall,cytoplasm and vacuoles of corn and wheat roots and leaves increased.The highest content of P was observed in cell wall,next in vacuoles,and the lowest in cytoplasm.The wheat subcellular fractions in both roots and leaves hab higher concentrations of phosphorus than those of corn.Increasing phosphorus in medium significantly inhibited the intracellular Cd accumulation in both species,However,at P concentration up to 3.0mmol L^-1,the Cd content in cell wall was increased.Increasing phosphorus resulted in reduction of the subcellular Cd content in cell wall was increased.Increasing phosphorus resulted in reduction of the subcellualr Cd content in corn and wheat leaves.Compared with corn,the wheat roots had a higher Cd content in the cell wall and vacuoles and a lower in cytoplasm,while in leaf subcellular fractions the wheat cell had a higher Cd content in its vacuoles and a lower one in its cytoplasm,The results indicate that phosphorus may be involved in sequestration of Cd ionic activity in both cell wall and vaculoes by forming insoluble Cd phosphate.  相似文献   

15.
Three experiments were conducted in which roots of two species of Lotus were immersed for up to 40 min in complete nutrient solutions containing 6, 15 or 25 μM Al. The two species tested were L. pedunculatus cv. Grasslands Maku (Al‐tolerant) and L. corniculatus cv. Maitland (Al‐sensitive). There was an initial rapid (< 5 min) decrease in solution Al at 25 μM Al. The effect was less marked with solution Al ≤ 15 μM. The decrease in solution Al was greater in the Al‐sensitive Maitland than in the Al‐tolerant Grasslands Maku, particularly when expressed on the basis of root fresh mass and root length. Root cation‐exchange capacity (CEC) was lower in Grasslands Maku than in Maitland, viz. 23.9 vs 36.5 mmol kg‐1 dry mass. Maitland roots removed more Al from solution than did those of Maku on the basis of total exchange capacity.

We propose a mechanism of Al tolerance on the basis of the results of this study and of other published information, viz. that differential Al tolerance results from differences in root CEC. Aluminum‐tolerant genotypes have roots with low CEC, and high Al activities (> 20 μM in the case of Grasslands Maku) are required to precipitate the relatively highly methylated pectins associated with low CEC. In contrast, relatively low activities of Al would precipitate the pectins in plants with roots of high CEC. This would decrease the protective capacity of the pectins, enabling the toxic, monomeric Al ions to come in contact with a number of Al‐sensitive compounds or processes in the cell wall, plasmalemma, or cell cytoplasm.  相似文献   

16.
钙、硅对铝胁迫下荞麦光合生理的影响   总被引:4,自引:0,他引:4  
采用营养液培养法,研究了钙、硅对荞麦根长、光合作用和叶绿素荧光的影响。结果表明,15 d时0.5 mmol/L和5 mmol/L Al3 处理降低了荞麦根长、叶绿素含量、净光合速率(Pn)、气孔导度(Ci),对叶绿素荧光Fv/Fm、Fv/Fo的影响不大,30 d后以上伤害均加重。配施钙或硅的处理,能促进根的伸长和提高叶绿素含量,并使叶片的Pn、Ci保持在较高的水平,施硅能明显提高荞麦叶片的叶绿素荧光Fv/Fm、Fv/F,而钙的影响不大。硅对铝胁迫的缓解效果好于钙。  相似文献   

17.
The effects of K and Al in K-deficient and complete nutrient solutions on the growth and nutrient uptake of rice were studied in the work.The effect of Al on the growth of roots and above-ground part of rice was associated with the concentration of Al in solution .A low level(0.1 mmol L^-1) of Al promtoed but a high level(1 mmol L^-1)of Al inhibited the growth of both the root and the aerial part of rice,and the magnitude of K concentration in the nutrient solution also had an appreciable impact on this,Thus ,in the low-Al solution,the plant treated with K2(80 mg K L^-1)produced much longer roots,showing the presence of interaction between Al and K; in the high-Al solution the K-reated plant had more and longe roots and a considerably greater dry weigh of the above-ground part compared with the plant deficient in K, showing the alleviating effect of K^ on Al toxicity.The mechanism of the Al-K interaction affecting the rice aerial part growth is not yet known,but part of the reason might be that the excessive amount of Al inhibited the uptake of some nutrients such as Ca and Mg and reduced their transfer to the plant aerial organs,whereas K showed its compensating effect on this;therefore,K could relieve Al toxicity at a high level of Al and promoted rice growth at a low level of Al.  相似文献   

设为首页 | 免责声明 | 关于勤云 | 加入收藏

Copyright©北京勤云科技发展有限公司  京ICP备09084417号