Aluminium rhizotoxicity in maize grown in solutions with Al3+ or Al(OH)4- as predominant solution Al species

Staß, Angelika; Wang, Y; Eticha, Dejene; Horst, W. J.

doi:10.1093/jxb/erl174

Cited by 36 publications

(25 citation statements)

References 47 publications

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“…Stass et al (2006) found that Al mainly existed as biologically toxic Al 3+ at rhizosphere pH < 4.3. Contents of active Al 3+ were decreased when the rhizosphere pH was increased from 4.0 to 5.0 (Zhu et al 2005).…”

Section: Resultsmentioning

confidence: 96%

Rhizosphere pH difference regulated by plasma membrane H+-ATPase is related to differential Al tolerance of two wheat cultivars

Yang¹,

Wang²,

Geng³

et al. 2011

PLANT SOIL ENVIRON

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Aluminum (Al)-tolerance of different cultivars shows considerable differences. Elevation of rhizosphere pH is an external Al-resistant mechanism of plants. To elucidate the correlation between Al tolerance and the capacity of plants to modify the rhizosphere pH at different Al-tolerant levels, a comparative study on the wheat (Triticum aestivum L.) cultivars ET8 (Al-tolerant) and ES8 (Al-sensitive) was performed. Rhizosphere pH of ET8 was much higher than that of ES8 under the same treatment, significant correlations were obtained among all the data of rhizosphere pH and relative root elongation (R2 = 0.9209**), or Al content in root apex (R2 = 0.9321**), which indicated that Al tolerance may be related to pH changes in the rhizosphere. The elevation of rhizosphere pH was inhibited by H+-ATPase specific inhibitor DCCD (dicylcohexylcarbodiimide, 25 mmol). Relative PM (plasma membrane) H+-ATPase activity of ET8 was significantly higher than that of ES8 under the same treatment. Significant correlation between all the data of relative PM H+-ATPase activity and rhizosphere pH (R2 = 0.8319**) were obtained. Taken together, these results suggest that PM H+-ATPase was involved in regulating rhizosphere pH. Under Al stress, the Al-tolerant line showed a stronger capacity of up-regulating rhizosphere pH by PM H+-ATPase than the Al-sensitive line, which may explain the observed differences in Al tolerance between the two wheat cultivars.

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Section: Resultsmentioning

confidence: 96%

Rhizosphere pH difference regulated by plasma membrane H+-ATPase is related to differential Al tolerance of two wheat cultivars

Yang¹,

Wang²,

Geng³

et al. 2011

PLANT SOIL ENVIRON

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“…It functions as a physical barrier against many stress factors, which may threaten to penetrate the protoplast, e.g., biotic threats such as fungal pathogens (Bolwell et al 2002), or abiotic threats including wounding (Jacobs et al 2003) and TM stress (e.g., Hématy et al 2009). Callose appearance under TM stress has been observed in the response of a range of plant species, e.g., in response to Pb in Lemna minor (Samardakiewicz et al 1996) and F. hygrometrica protonemata (Krzesłowska et al 2009a), and to Al in Triticum aestivum (Sivaguru et al 2000), A. thaliana (de Cnodder et al 2005) and Zea mays (Stass et al 2006). In plants exposed to Al, it has been shown that callose deposition was inducted by the appearance of ROS in the CW and alteration of calcium homeostasis, mainly its increase within protoplast caused by the metal (Sivaguru et al 2000;Jones et al 2006).…”

Section: Detection Of Tms In Plant Cell Wallmentioning

confidence: 99%

The cell wall in plant cell response to trace metals: polysaccharide remodeling and its role in defense strategy

2010

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This review paper is focused predominantly on the role of the cell wall in the defense response of plants to trace metals. It is generally known that this compartment accumulates toxic divalent and trivalent metal cations both during their uptake by the cell from the environment and at the final stage of their sequestration from the protoplast. However, from results obtained in recent years, our understanding of the role played by the cell wall in plant defense response to toxic metals has markedly altered. It has been shown that this compartment may function not only as a sink for toxic trace metal accumulation, but that it is also actively modified under trace metal stress. These modifications lead to an increase in the capacity of the cell wall to accumulate trace metals and a decrease of its permeability for trace metal migration into the protoplast. One of the most striking alterations is the enhancement of the level of low-methylesterified pectins: the polysaccharides able to bind divalent and trivalent metal ions. This review paper will present the most recent results, especially those that are concerned with polysaccharide level, composition and distribution under trace metal stress, and describe in detail the polysaccharides responsible for metal binding and immobilization in different groups of plants (algae and higher plants). The review also contains information related to the entry pathways of trace metals into the cell wall and their detection methods.

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“…It was recognized that significant accumulation of Al in the cell walls may alter their structural and mechanical properties, and thus affect the root growth (Wang et al 2004). The Al binding to sensitive binding sites in the apoplast of the epidermis and the outer cortex of roots has been shown to inhibit root growth in maize (Stass et al 2006). The Al binding to these negatively charged sites can lead to displacement of Ca 2+ , fundamental for cell-wall stability (Rincon & Gonzales 1992;Tabuchi & Matsumoto 2001).…”

Section: Aluminum Toxicity In Maize Rootsmentioning

confidence: 99%

Changes induced by aluminum stress in the organic acid content of maize seedlings: The crucial role of exogenous citrate in enhancing seedling growth

Chaffai

Seybou

Marzouk³

et al. 2009

Biologia

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Abstract:We have studied the effect of Al on growth and morphology of maize seedlings (Zea mays L.), the changes in organic acid content as well as the role of application of exogenous citrate in enhancing the Al tolerance. Al treatment induced inhibition of root growth, causing morphological symptoms of Al toxicity. Al decreased significantly the malate content in roots compared to control plants. However, the citrate and total organic acids did not show any change, indicating that one mechanism underlying plant defense may involve the maintenance a normal levels of organic acids in roots. The succinate content increased in roots at 1000 µmol L −1 Al, while that of lactate decreased. However, 500 and 1000 µmol L −1 Al significantly increased the total organic acid in shoots, due to an increase in the succinate and malate contents. By contrast, the citrate and lactate levels decreased at 250 and 500 µmol L −1 Al. To investigate the role of citrate in enhancing the plant growth, citrate was supplied to nutrient medium containing 500 µmol L −1 Al at different Al:Citrate ratios (1:1, 1:2 and 1:3). The addition of citrate in the nutrient solution resulted in an alleviation of Al toxicity, with the maximal effect obtained at Al:Citrate ratio of 1:2. These data provide evidence that in maize, the organic acids, mainly citrate play an important role in enabling the plant to tolerate elevated exposure to Al concentration.

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Aluminium rhizotoxicity in maize grown in solutions with Al3+ or Al(OH)4- as predominant solution Al species

Cited by 36 publications

References 47 publications

Rhizosphere pH difference regulated by plasma membrane H<sup>+</sup>-ATPase is related to differential Al tolerance of two wheat cultivars

Rhizosphere pH difference regulated by plasma membrane H<sup>+</sup>-ATPase is related to differential Al tolerance of two wheat cultivars

The cell wall in plant cell response to trace metals: polysaccharide remodeling and its role in defense strategy

Changes induced by aluminum stress in the organic acid content of maize seedlings: The crucial role of exogenous citrate in enhancing seedling growth

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