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1.
Seventeen soybean cultivars were screened to discern differences in aluminum (Al) sensitivity. The Sowon (Al-tolerant) and Poongsan (Al-sensitive) cultivars were selected for further study by simple growth measurement. Aluminum-induced root growth inhibition was significantly higher in the Poongsan cultivar than in the Sowon cultivar, although the differences depended on the Al concentration (0, 25, 50, 75 or 100 μmol L–1) and the amount of exposure (0, 3, 6, 12 or 24 h). Damage occurred preferentially in the root apex. High-sensitivity growth measurements using India ink implicated the central elongation zone located 2–3 mm from the root apex. The Al content was lower 0–5 mm from the root apices in the Sowon cultivar than in the apices of the Poongsan cultivar when exposed to 50 μmol L–1 Al for 12 h. Furthermore, the citric acid exudation rate was more than twofold higher in the Sowon cultivar. Protein production of plasma membrane (PM) H+-ATPase from the root apices (0–5 mm) was upregulated in the presence of Al for 24 h in both cultivars. This activity, however, decreased in both cultivars treated with Al and the Poongsan cultivar was more severely affected. We propose that Al-induced growth inhibition is correlated with changes in PM H+-ATPase activity, which is linked to the exudation of citric acid in the root apex.  相似文献   

2.
Pineapple (Ananas comosus [L.] Merrill) is one of the economically cultivated crops in Taiwan, which is grown mostly on acid soil. Aluminum (Al) is phytotoxic and sometimes inhibits root growth of crops in strongly acid soils. This study was conducted to evaluate the role in Al resistance of root‐apex cell walls of four important pineapple cultivars (Cayenne, Tainung No. 6, Tainung No. 13, and Tainung No. 17). The cell‐wall characteristics of root apices were determined using Fourier transform infrared spectroscopy (FTIR) and solid‐state 13C‐nuclear–magnetic resonance spectroscopy (13C‐NMR). The results show that the carboxylic and phenolic groups were highest in the cell wall of Tainung No.17 and lowest in that of Cayenne. Aluminum adsorption by cell wall could be described by Freundlich equation. The adsorption of Al by the cell wall of root apices was highest in Tainung No.17 and lowest in Cayenne. Tainung No.17 contained more carboxylic and phenolic groups in its cell wall of the root apices, causing more Al adsorption and so more damage to its root apices than that of the other three pineapple cultivars.  相似文献   

3.
Abstract

Aluminum (Al) is biotoxic, often active in acid soil and retards the growth of crop roots. Cayenne is a type of pineapple cultivar that can be well cultivated in a strongly acid environment containing AlCl3 concentrations up to 300?μmol?L?1. In addition to organic acids, variations in the proteins in root apices are regarded as the mechanism involved in Al resistance. The objective of the present study was to explore the responsive proteins of Al stress in a known Al-resistant pineapple cultivar (i.e. Cayenne). After root emergence, pineapple seedlings were exposed to hydroponic solutions each containing 0 and 300?μmol?L?1 AlCl3 for 4?weeks. The total proteins in the root apices were separated using 2-D electrophoresis and a total of 17 apparently differential spots were identified by mass spectrometry, with 10 upregulated and seven downregulated proteins. The root apices of Cayenne under Al stress could be characterized by cellular activities involved in, for example, carbohydrate metabolism, organic acid production, energy metabolism, alleviating redox damage and root phenotypical change, which are critical for plant survival under Al toxicity. In contrast, there are one hypothetical and three unknown proteins that play unknown roles in Al resistance and warrant further investigation. The present study may provide an important clue to future proteomic research on Al-resistant mechanisms in pineapple.  相似文献   

4.
The objectives were to determine whether two peanut cultivars show different tolerance to calcium (Ca) deficiency. The seedlings of cultivars LH11 and YZ9102 at first trifoliate leaf stage were transplanted in nutrient solution for 28 days with 0.01 and 2.0 mmol/L Ca treatments. Low Ca supply did not affect plant growth, root length and surface area of YZ9102, whereas decreased plant biomass, root length and surface area of LH11 seedlings that appeared necrosis in shoot tip. YZ9102 plant had higher Ca concentration and more Ca distribution to leaves than LH11. Under limited Ca condition, LH11 appeared net Ca2+ effluxes in the zones of 0.2 ~ 1.5 mm from root apex, while YZ9102 roots maintained net Ca2+ influxes. Peanut cultivar YZ9102 seedlings had longer roots and higher capacities of Ca uptake and Ca translocation to shoots than LH11, which might be account for higher tolerance to Ca deficiency compared with LH11.  相似文献   

5.
小麦的铝毒及耐性   总被引:11,自引:2,他引:11  
为探明Al的毒性和忍耐机理 ,比较了Scout 66和Atlas 66Al敏感和抗性的 2个小麦品种的根对Al的积累模式、根细胞壁对Al的吸附以及Al诱导的有机酸的分泌。结果表明 ,Al对Scout 6 6根伸长的抑制作用较Atlas 66明显。根系吸收的Al主要积累于 0至 5mm根尖处。Scout 6 6的根尖及Al处理后分离的根尖细胞壁对Al的积累量大于Atlas 6 6。但是 ,Al处理前分离根尖细胞壁 ,Al处理后细胞壁对Al的吸附量两品种间无显著差异。Al可诱导Atlas 6 6的根系分泌苹果酸 ,而Scout 6 6的分泌物中未发现Al诱导的有机酸。这些结果表明 ,Atlas 6 6的根尖及其细胞壁较Scout 66积累较少的Al,这种差异与Al诱导的有机酸分泌有关 ,而与根尖细胞壁固有的吸附Al的能力无关  相似文献   

6.
《Journal of plant nutrition》2013,36(11):2047-2066
Abstract

Eighteen soybean genotypes differing in aluminum (Al) tolerance were used to investigate genotypic differences in Al-induced citrate exudation and its role in Al tolerance. Aluminum accumulation and localization in soybean roots were examined by analysis of total Al and hematoxylin staining. Soybean genotypes exhibited a wide range of Al tolerance. Based on relative root elongation, several Al-tolerant genotypes from Brazil such as B1, B10, and B15 were more tolerant than the Al-tolerant PI 416937 (PI) and Perry. All soybeans exuded citrate in response to Al stress, and some Al-sensitive genotypes secreted more citrate than tolerant ones, showing no correlation between the Al tolerance and Al-induced citrate exudation. Further study found that both copper (Cu) and cadmium (Cd) stimulated citrate and malate exudation in soybean, indicating that organic acid secretion is not specifically induced by Al. Aluminum concentrations were significantly higher in 2–3 and 3–4 cm of segments than that in 0–1 and 1–2 cm segments under 15 μM AlCl3. Both the root mature zone and apex were heavily stained by hematoxylin after exposure to 10, 15, or 20 μM AlCl3 (24 h), whereas root elongation zone was not stained. After exposure to 50 μM AlCl3 for 20 min, the Al-tolerant PI was less stained by hematoxylin than the Al-sensitive Young, suggesting that Al accumulation in root apices seem to be an immediate response to Al stress, and related to differential Al sensitivity. Present results suggest that citrate secretion induced by Al stress may not be a key mechanism responsible for the differential Al tolerance of some soybean genotypes and other mechanism(s) conferring Al exclusion should exist and operate immediately after exposure to Al stress.  相似文献   

7.
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   

8.
Nitrogen (N), ammonium (NH4+) and nitrate (NO3?), is one of the key determinants for plant growth. The interaction of both ions displays a significant effect on their uptake in some species. In the current study, net fluxes of NH4+ and NO3? along the roots of Picea asperata were determined using a Non-invasive Micro-test Technology (NMT). Besides, we examined the interaction of NH4+ and NO3? on the fluxes of both ions, and the plasma membrane (PM) H+-ATPases and nitrate reductase (NR) were taken into account as well. The results demonstrated that the maximal net NH4+ and NO3? influxes were detected at 13–15?mm and 8–10.5?mm from the root apex, respectively. Net NH4+ influx was significantly stimulated with the presence of NO3?, whereas NH4+ exhibited a markedly negative effect on NO3? uptake in the roots of P. asperata. Also, our results indicated that PM H+-ATPases and NR play a key role in the control of N uptake.  相似文献   

9.
High‐performance liquid chromatography (HPLC) was used to determine aluminum (Al)‐induced changes in organic acid (OA) concentrations of Al‐tolerant ‘Dade’ and Al‐sensitive ‘Romano’ snapbean cultivars. Two week old ‘Dade’ and ‘Romano’ snapbean were grown in 1/5‐strength Steinberg nutrient solution for 10 days and then subjected to 0, 2, 4, 6, and 8 mg L‐1 Al treatments at pH 4.5 for an additional 3–15 days. Current studies confirmed earlier findings that the Dade cultivar was significantly more tolerant to Al than the Romano variety. Organic acid analyses were performed on extracts of root and leaf, and on stem exudates. The organic acids were separated on an ion exclusion column using a mobile phase of 0.01 N H3PO4. Individual OA were quantified with a variable wavelength detector operating at 210 nm. Aluminum stress tended to reduce the concentrations of citric, malonlc, malic, glycolic, fumaric, and acetic acids in the roots and increased the OA concentrations in stem exudates. In the presence or absence of Al stress, the Al tolerant Dade cultivar contained higher OA concentrations than did the Al‐sensitlve Romano. Aluminum stress reduced total OA levels in root extracts from Al‐sensltive Romano plants to a greater extent than in those of the Al‐tolerant Dade. Malic and citric acid concentrations were decreased more than those of the other organic acids examined. Results indicate that the Al‐tolerant Dade snapbean cultivar has a higher potential for Al‐chelation and detoxification than does the Al‐sensitive Romano. Hence, an Al‐chelation mechansism may be involved in differential Al tolerance within this species.  相似文献   

10.
Cultivated tea (Camellia sinensis) plants acidify the rhizosphere, and Aluminum (Al) toxicity is recognized as a major limiting factor for plant growth in acidic soils. However, the mechanisms responsible for rhizosphere acidification associated with Al have not been fully elucidated. The present study examined the effect of Al on root-induced rhizosphere acidification, plasma membrane H+-adenosine triphosphatase (H+-ATPase) activity, and cation-anion balance in tea plant roots. The exudation of H+ from tea plant roots with or without Al treatment was visualized using an agar sheet with bromocresol purple. The H+-ATPase activity of plasma membranes isolated from the roots was measured after hydrolysis using the two-phase partition system. The Al treatment strongly enhanced the exudation of H+, and the acidification of tea plant roots by Al was closely associated with plasma membrane H+-ATPase activity. The root plasma membrane H+-ATPase activity increased with Al concentration. The Al content, amount of protons released, and H+-ATPase activity were significantly higher in roots treated with Al than in those untreated. The results of the cation-anion balance in roots showed an excess of cations relative to anions, with the amount of excess cation uptake increasing with increasing Al concentrations. These suggest that Al-enhanced proton release is associated with plasma membrane H+-ATPase activity and excess cation uptake. Findings of this study would provide insights into the contributing factors of soil acidification in tea plantations.  相似文献   

11.
《Journal of plant nutrition》2013,36(12):2677-2688
ABSTRACT

Under field conditions, wheat cultivar PBW 343 produced 1.5 times higher grain yield than PDW 233, when grown on low manganese (Mn) soil. To explain the differences in Mn efficiency a pot experiment was conducted using Mn deficient Typic ustochrept loamy sand soil treated with 0, 50, and 100?mg?Mn?kg?1 soil. In no-Mn treatment, both the wheat cultivars showed Mn deficiency symptoms and cultivar PBW 343 produced 30% of the maximum dry matter yield (DMY) attained at high Mn supply, while PDW 233 produced only 18% of its maximum DMY after 40 days of growth. With application of 50?mg?Mn?kg?1 soil, the DMY significantly increased to 87% and 50% of the maximum for PBW 343 and PDW 233, respectively. These results indicate that aestivum cultivar PBW 343 was more Mn efficient than durum cultivar PDW 233. Manganese efficient cultivar PBW 343 had a lower internal Mn requirement than PDW 233 because at the same shoot Mn concentration PBW 343 produced more DMY. The root growth of both wheat cultivars was similar at sufficient Mn supply, the root length (RL)?:?DMY ratio being equal. At decreasing Mn supply root growth was depressed more strongly than shoot growth, the inhibition being more severe in Mn inefficient cultivar PDW 233, indicating the importance of root system size for Mn efficiency between these two wheat cultivars. A nutrient uptake model closely described Mn influx in both the cultivars, indicating that calculated concentration profiles were realistic and that chemical mobilization of Mn in the rhizosphere was not responsible for higher Mn efficiency of PBW 343. Calculated concentration profiles showed that in soil not fertilized with Mn, initial soil solution Mn concentration of 0.23?µM decreased to only 0.21?µM at the root surface after 27 days of uptake. This 7.4% decrease in Mn concentration at the root surface indicated that roots could not decrease Mn concentration to a lower value which would have caused higher transport of Mn to root surface and hence resulted in higher Mn influx.  相似文献   

12.
Root border cells are considered to contribute to aluminum (Al) resistance by protecting the root apex from Al toxicity. In the present study, the responses of root apices of pea (Pisum sativum) to Al exposure in mist culture with border cells stripped off or not were compared. Inhibition of root elongation, induction of callose synthesis, and accumulation of Al were more pronounced in root apices stripped from border cells. Aluminum application led to higher Al concentrations in border cells than in root apices. The same trend was found for Al contents in cell walls of border cells compared to root apices. The analysis of cell‐wall pectin indicated that the concentrations of total sugars, uronic acids, and 2‐keto‐3‐deoxyoctonic acid (KDO) were higher in border cells than in root apices, especially when exposed to Al. Together, these results suggest that root border cells enhance the Al resistance of root apices by immobilizing Al in their cell‐wall pectin, thus protecting the root apex.  相似文献   

13.
Abstract

Aluminum (Al) toxicity is one of the major factors limiting plant growth in acid soils. To determine the response of taro [Colocasia esculenta (L.) Schott] to Al‐toxicity, cultivars (cv.) Lehua maoli and Bun long were grown in hydroponic solution at six initial levels of Al (0, 110, 220, 440, 890, and 1330 uM Al). Increasing Al levels significantly depressed fresh and dry weights of taro leaf blades, petioles, and roots, as well as leaf areas and root lengths. No significant cultivar differences were found for plant dry weights. However, significant cultivar differences were found for expansion growth parameters, with cv. Lehua maoli exhibiting greater leaf fresh weights and root lengths in the presence of Al, compared to cv. Bun long. Apparently, differential response of taro cultivars to Al is related to the ability of the Al‐tolerant cultivar to maintain water uptake and cell expansion in the presence of Al. The initial solution Al level that resulted in the greatest separation of growth differences between taro cultivars in their response to Al was 890 μM Al.  相似文献   

14.
Using an aluminum (Al)‐sensitive maize cultivar, we investigated the influence of Al on the apoplastic solute bypass flow and its relationship with Al‐induced (1 h, 50 μM) callose formation and root growth. We selected the fluorescent probes 8‐hydroxypyrene‐1,3,6‐trisulfonic acid, trisodium salt (MW 524) (HPTS) and dextran‐Texas Red (TR) conjugates (MW 3,000, 10,000, and 40,000) to monitor their apoplastic transport. Confocal laser–scanning microscopy (CLSM) analysis and spectrofluorometric quantification showed Al‐induced callose formation in peripheral root cells within 1 h. Pretreatment of plants with the callose synthesis inhibitor 2‐deoxy‐D‐glucose (DDG) reduced the callose formation by half. Uptake experiments with both HPTS and dextrans showed uniform dye distribution in control root apices. After Al treatment for 1 or 2 h, which inhibited root growth by 32% or 50%, respectively, the dyes accumulated in the epidermal and outer cortical cell layers, especially in the 1–2 mm apical root zone. Al treatment reduced the export of the dyes out of the apical 1 cm treatment zone. This was due to strong sorption of HPTS but not of dextrans by Al‐loaded cell walls. Aluminum treatment reduced loading into the xylem sap particularly of higher–molecular weight dextrans. Pretreatment of roots with DDG and presence of 50 mM mannitol during the Al treatment partially forestalled the inhibitory effect of Al on the dye transport, but only slightly reduced the Al‐induced growth inhibition. Exudation experiments revealed that xylem water flow remained unaffected by the Al treatment of the root tips. The results with dextran suggest that Al binding in cell walls of the root apex inhibits apoplastic bypass flow of higher–molecular weight solutes, which might contribute to Al‐induced inhibition of root growth.  相似文献   

15.
Abstract

Shallow rooting and susceptibility to drought are believed to be caused, at least in part, by strongly acidic (pH <5.5, 1:1 soil‐water), aluminum (Al)‐toxic subsoils. However, this hypothesis has not been clearly confirmed under field conditions. The Al toxicity hypothesis was tested on a map unit of Matawan‐Hammonton loam (0–2% slope) on unlimed and limed field plots (pH range 5.1 to 5.8) at Beltsville, MD, during 1994 to 1998. Aluminum‐tolerant and sensitive pairs of barley (Hordeum vulgare L.), wheat [Triticum aestivum (L.)], snap bean (Phaseolus vulgaris L.), and soybean [Glycine max (L.) Merr.] cultivars were used as indicator plants. Eastern gamagrass [Tripsacum dactyloides (L.) L.], cultivar ‘Pete’, reported to tolerate both chemical and physical stress factors in soils, was grown for comparison. Shoots of Al‐sensitive ‘Romano’ snap beans showed a significant response to liming of the 0–15 cm surface layer, but those of Al‐tolerant ‘Dade’ did not, indicating that Al toxicity was a growth limiting factor in this acid soil at pH 5.1. Lime response of the Al‐tolerant and sensitive cultivars of barley, wheat, and soybean were in the same direction but not significant at the 5% level. Aluminum‐tolerant and sensitive cultivars did not differ in abilities to root in the 15–30 cm soil depth. Only 9 to 25% of total roots were in this layer, and 75 to 91% were in the 0–15 cm zone. No roots were found in the 30–45 cm zone which had a pH of 4.9. Soil bulk density values of 1.44 and 1.50 g cm?3 in the 15–30 and 30–45 cm zones, respectively, indicated that mechanical impedance was a primary root barrier. Results indicated that restricted shoot growth and shallow rooting of the Al‐indicator plants studied in this acid soil were due to a combination of Al toxicity and high soil bulk density. Confounding of the two factors may have masked the expected response of indicator plants to Al. These two growth restricting factors likely occur in many, if not most acid, problem subsoils. Studies are needed to separate these factors and to develop plant genotypes that have tolerance to multiple abiotic stresses. Unlike the Al indicator cultivars, eastern gamagrass showed high tolerance to acid, compact soils in the field and did not respond to lime applications (pH 5.1–5.8).  相似文献   

16.
Seedlings of four cultivars of wheat (Triticum aestivum L.) differing in tolerance to aluminium (Al) were grown for 14 to 20 days using a split‐root sand/solution culture technique. Each culture tube was divided horizontally into two compartments by a root‐permeable paraffin wax barrier, so that phosphorus (P) and aluminium (Al) supply could be varied in the upper 0–80 mm (surface) and lower 80–180 mm (subsurface) compartments, respectively.

Root growth into the subsurface zone was enhanced by increased P supply to surface roots, but only in the absence of subsurface Al. Where subsurface Al was present, increased P supply to surface roots had no effect on the penetration of roots into the subsurface zone. Tolerance to Al in the cultivars used was therefore not related to the ability to translocate P to sites of Al injury.  相似文献   

17.
Intra-species variation in response to defoliation and soil amendment has been largely neglected in terms of the soil microbial community (SMC). The influence of defoliation and soil fertiliser amendment on the structure of the SMC was assessed with two Lolium perenne cultivars contrasting in ability to accumulate storage reserves. Plant response to defoliation was cultivar specific and depended on the nutrient amendment of the soil. Results suggested a greater ability to alter plant biomass allocation in the low carbohydrate accumulating cultivar (S23) compared to the high carbohydrate cultivar (AberDove) when grown in improved (IMP), but not in unimproved (UNI), soil. Although differences in plant growth parameters were evident, no treatment effects were detected in the size of the active microbial biomass (total phospholipid fatty acid (PLFA) 313.8 nmol g−1 soil±33.9) or proportions of PLFA signature groups. A lower average well colour development (AWCD) of Biolog sole carbon source utilisation profiles (SCSUPs) in defoliated (D) compared to non-defoliated (ND) treatments may be indicative of lower root exudation 1 week following defoliation, as a consequence of lower root non-structural carbohydrate (NSC) concentrations. Within the bacterial community the lower cyclopropyl-to-precursor ratio of PLFAs, and the trans/cis ratio of 16:1w7, in UNI relative to IMP soil treatments indicates lower physiological stress in UNI soils regardless of L. perenne cultivar. Discrimination of broad scale SMC structure, measured by PLFA analysis, revealed that soil treatment interacted strongly with cultivar and defoliation. In IMP soils the SMCs discriminated between cultivars while defoliation had little effect. Conversely, in UNI soils defoliation caused a common shift in the SMC associated with both cultivars, causing convergence of overall community structure. Separation of SMC structure along the primary canonical axis correlated most strongly (P<0.001) with root:shoot ratio (47.6%), confirming that differences in cultivar C-partitioning between treatments were influential in defining the rhizosphere microbial community.  相似文献   

18.
Aluminum toxicity and boron deficiency are the major factors that limit plant growth and development in acid soils and in B-deficient soils. Root growth inhibition is an early symptom of AI toxicity and B deficiency. Effects of AI and B supply and their interaction on the growth of wheat (Triticum aestivum L.) seedlings were investigated using hydroponics. Fifteen wheat cultivars commonly grown in Bangladesh were used and found to differ considerably in their tolerance to AI toxicity and B deficiency. The relative root length of all the wheat cultivars at 50 µM AI (pH 4.5) ranged from 27 to 71% relative to the control (0 µM AI). Among the cultivars, Inia66 and Kalyansona were found to be the most Al-tolerant and sensitive cultivars, respectively, based on the data of relative root length, malate exudation and AI content of roots. Malate was detected in all the cultivars in the presence of 100 µM AI (pH 4.3). Inia66 exuded a 6-fold larger amount of malate and the AI content of roots was 4 times lower than that in Kalyansona. The vigorous seedling growth was observed at 40 µM B among the series of B treatments. Considerable cultivar differences in response to 40 µM B were observed among the 15 cultivars. Kalyansona was considered to be the most sensitive and Kheri the most tolerant to B deficiency. The interaction effects of B ( 40 and 200 µM) and AI (50 µM) on seedling growth were also examined in Inia66 and Kalyansona. Root growth was inhibited in the presence of Al but B supply especially at 200 µM B in the Kalyansona cultivar caused a slight improvement.  相似文献   

19.
为探讨铝(Al)胁迫条件下脱落酸(ABA)调控植物根系有机酸分泌的机制,进行了ABA与Al诱导大豆根系柠檬酸分泌的关系试验。结果表明:1)外源ABA和ABA合成抑制剂fluridone分别提高和降低了Al诱导的大豆根尖ABA含量的增加,但对根系柠檬酸分泌量均无影响,ABA对根系内源柠檬酸含量和柠檬酸合成酶的活性也没有影响;2)分根试验表明,与Al直接接触的根部(Part A)内源ABA含量发生变化,且有柠檬酸的分泌,而不与Al直接接触的根部(Part B)内源ABA含量也发生变化,但没有柠檬酸分泌;3)Al胁迫下,大豆耐Al基因型柠檬酸分泌量远高于敏感基因型,但二者的内源ABA含量却没有差异;4)30μmol AlCl3处理,在0~12 h柠檬酸分泌速率和内源ABA含量随Al处理时间增加而增加,去除Al胁迫时(12~18 h),柠檬酸分泌速率继续增加,但内源ABA含量则迅速下降。综合以上结果,推测ABA不是通过提高Al诱导柠檬酸分泌来调控大豆耐Al性。  相似文献   

20.
Phosphate (Pi), the fully oxidized and assimilated form of phosphorus (P), influences virtually all developmental and biochemical processes in plants; however, its availability and distribution are widely heterogeneous. Paradoxically, although total P is abundant in lithosphere, elusive soil chemistry of Pi renders the element the most dilute and the least mobile in natural and agricultural ecosystems, resulting in P deprivation due to its low mobility and high fixation capacity in the soil. Nonmycorrhizal Brassica does not produce specialized cluster/dauciform roots but is an effective P user compared to other crops. Using a soil low in P (Mehlich 3–extractable P) with or without P fertilization, Brassica cultivars showed substantial genetic diversity in P-utilization efficiency (PUE), P efficiency (PE), P-efficiency ratio (PER), and P-stress factor (PSF). Cultivars producing greater root biomass accumulated greater total P contents, which in turn was related negatively to PSF and positively to shoot and total biomass. Plant survival and reproduction rely on efficient strategies in exploring culture media for P. Acquisition of orthophosphate from extracellular sparse P sources may be enhanced by biochemical rescue strategies such as copious H+ efflux and/or carboxylates exudation into rhizosphere by roots via plasmalemma H+-ATPase and anion channels triggered by P starvation. The P-starvation-induced solution pH changes due to H+ efflux, and carboxylates exudations were estimated by low-P-tolerant and low-P-sensitive cultivars in solution culture experiments. Low-P-tolerant cultivars showed more decrease in pH compared to low-P-sensitive cultivars when cultivars were grown under a P-stress environment induced by using sparingly soluble P sources (rock phosphate and tricalcium phosphate). The P contents of cultivars were inversely related to decrease in culture media pH. Low P-tolerant cultivars presented enhanced H+-efflux and total carboxylates exudations compared to low-P-sensitive cultivars, resulting in more rhizosphere acidification to scavenge Pi, evidencing their adaptability to P starvation. These elegant P-stress-induced rescue strategies by tested cultivars provided the basis of enhanced P solubilization and acquisition of P from sparingly soluble P sources to combat P-starved environments.  相似文献   

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