Aluminum-Induced 1→3-β-<scp>d</scp>-Glucan Inhibits Cell-to-Cell Trafficking of Molecules through Plasmodesmata. A New Mechanism of Aluminum Toxicity in Plants

Sivaguru, Mayandi; Fujiwara, Toru; Šamaj, Josef; Baluška, Frantǐsek; Yang, Zhenming; Osawa, Hiroki; Maeda, Takanori; Mori, Tomoko; Volkmann, Dieter; Matsumoto, Hideaki

doi:10.1104/pp.124.3.991

Cited by 244 publications

(156 citation statements)

References 76 publications

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“…Callose formation has been induced in the apical root cells of aluminum-sensitive maize cultivars (Sivaguru et al, 1999) and Arabidopsis mutants with increased sensitivity to aluminum (Larsen et al, 1996). A study using immuno-fluorescence and immuno-electron microscopic techniques combined with monoclonal antibodies against callose (Sivaguru et al, 2000) showed that aluminum-sensitive wheat root growth inhibition was closely associated with the blockage of plasmodesmata (cytoplasmic channels responsible for the intercellular movement of water, nutrients and for signaling) by callose deposition under aluminum stress, which could effectively block symplastic transport and communication in higher plants. One of the key enzymes acting in callose formation is callose synthase, which showed high similarity with genes in the SUCEST database.…”

Section: Discussionmentioning

confidence: 99%

Prospecting sugarcane genes involved in aluminum tolerance

et al. 2001

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Aluminum is one of the major factors that affect plant development in acid soils, causing a substantial reduction in yield in many crops. In South America, about 66% of the land surface is made up of acid soils where high aluminum saturation is one of the main limiting factors for agriculture. The biochemical and molecular basis of aluminum tolerance in plants is far from being completely understood despite a growing number of studies, and in the specific case of sugarcane there are virtually no reports on the effects of gene regulation on aluminum stress. The objective of the work presented in this paper was to prospect the sugarcane expressed sequence tag (SUCEST) data bank for sugarcane genes related to several biochemical pathways known to be involved in the responses to aluminum toxicity in other plant species and yeast. Sugarcane genes similar to most of these genes were found, including those coding for enzymes that alleviate oxidative stress or combat infection by pathogens and those which code for proteins responsible for the release of organic acids and signal transducers. The role of these genes in aluminum tolerance mechanisms is reviewed. Due to the high level of genomic conservation in related grasses such as maize, barley, sorghum and sugarcane, these genes may be valuable tools which will help us to better understand and to manipulate aluminum tolerance in these species.

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Section: Discussionmentioning

confidence: 99%

Prospecting sugarcane genes involved in aluminum tolerance

et al. 2001

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“…In this respect, the formation of callose deposits at the neck region of PD leading to reduced size exclusion limits or PD closure has frequently been described as a specific response of plants to different abiotic and biotic stresses, including wounding, metal toxicity, and microbial infection (Enkerli et al, 1997;Iglesias and Meins, 2000;Sivaguru et al, 2000;Roberts and Oparka, 2003). For instance, enhanced callose accumulation was observed in membranes and PD of pea roots in response to aluminum treatment, leading to the blockage of symplastic transport and inhibition of root elongation (Sivaguru et al, 2000). Interestingly, callose formation was strongly correlated with aluminuminduced oxidative damage to membrane lipids and changes in intracellular calcium homeostasis, suggesting a mechanistic link between lipid peroxidation and callose synthesis (Jones et al, 1998;Yamamoto et al, 2001).…”

Section: Callose Deposition In the Vascular Tissue Correlates With Tomentioning

confidence: 99%

RNAi-Mediated Tocopherol Deficiency Impairs Photoassimilate Export in Transgenic Potato Plants

et al. 2004

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Tocopherols (vitamin E) are lipophilic antioxidants presumed to play a key role in protecting chloroplast membranes and the photosynthetic apparatus from photooxidative damage. Additional nonantioxidant functions of tocopherols have been proposed after the recent finding that the Suc export defective1 maize (Zea mays) mutant (sxd1) carries a defect in tocopherol cyclase (TC) and thus is devoid of tocopherols. However, the corresponding vitamin E deficient1 Arabidopsis mutant (vte1) lacks a phenotype analogous to sxd1, suggesting differences in tocopherol function between C4 and C3 plants. Therefore, in this study, the potato (Solanum tuberosum) ortholog of SXD1 was isolated and functionally characterized. StSXD1 encoded a protein with high TC activity in vitro, and chloroplastic localization was demonstrated by transient expression of green fluorescent protein-tagged fusion constructs. RNAi-mediated silencing of StSXD1 in transgenic potato plants resulted in the disruption of TC activity and severe tocopherol deficiency similar to the orthologous sxd1 and vte1 mutants. The nearly complete absence of tocopherols caused a characteristic photoassimilate export-defective phenotype comparable to sxd1, which appeared to be a consequence of vascular-specific callose deposition observed in source leaves. CO 2 assimilation rates and photosynthetic gene expression were decreased in source leaves in close correlation with excess sugar accumulation, suggesting a carbohydrate-mediated feedback inhibition rather than a direct impact of tocopherol deficiency on photosynthetic capacity. This conclusion is further supported by an increased photosynthetic capacity of young leaves regardless of decreased tocopherol levels. Our data provide evidence that tocopherol deficiency leads to impaired photoassimilate export from source leaves in both monocot and dicot plant species and suggest significant differences among C3 plants in response to tocopherol reduction.

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“…Callose deposition at Pds is stimulated by physical and physiological stresses (Hughes and Gunning, 1980;Beffa and Meins, 1996;Iglesias and Meins, 2000;Sivaguru et al, 2000;Rinne et al, 2005;Ueki and Citovsky, 2005;Maeda et al, 2006) and is proposed to provide a mechanism for regulating Pd flux (Botha and Cross, 2000;Iglesias and Meins, 2000;Levy et al, 2007a). Hence, for example, plants with reduced accumulation of the glycolytic enzyme 1,3-b-glucanase had increased callose accumulation and a reduction in the experimental molecular size exclusion limit.…”

Section: Introductionmentioning

confidence: 99%

AnArabidopsisGPI-Anchor Plasmodesmal Neck Protein with Callose Binding Activity and Potential to Regulate Cell-to-Cell Trafficking

et al. 2009

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Plasmodesmata (Pds) traverse the cell wall to establish a symplastic continuum through most of the plant. Rapid and reversible deposition of callose in the cell wall surrounding the Pd apertures is proposed to provide a regulatory process through physical constriction of the symplastic channel. We identified members within a larger family of X8 domaincontaining proteins that targeted to Pds. This subgroup of proteins contains signal sequences for a glycosylphosphatidylinositol linkage to the extracellular face of the plasma membrane. We focused our attention on three closely related members of this family, two of which specifically bind to 1,3-b-glucans (callose) in vitro. We named this family of proteins Pd callose binding proteins (PDCBs). Yellow fluorescent protein-PDCB1 was found to localize to the neck region of Pds with potential to provide a structural anchor between the plasma membrane component of Pds and the cell wall. PDCB1, PDCB2, and PDCB3 had overlapping and widespread patterns of expression, but neither single nor combined insertional mutants for PDCB2 and PDCB3 showed any visible phenotype. However, increased expression of PDCB1 led to an increase in callose accumulation and a reduction of green fluorescent protein (GFP) movement in a GFP diffusion assay, identifying a potential association between PDCB-mediated callose deposition and plant cell-to-cell communication.

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Aluminum-Induced 1→3-β-d-Glucan Inhibits Cell-to-Cell Trafficking of Molecules through Plasmodesmata. A New Mechanism of Aluminum Toxicity in Plants

Cited by 244 publications

References 76 publications

Prospecting sugarcane genes involved in aluminum tolerance

Prospecting sugarcane genes involved in aluminum tolerance

RNAi-Mediated Tocopherol Deficiency Impairs Photoassimilate Export in Transgenic Potato Plants

AnArabidopsisGPI-Anchor Plasmodesmal Neck Protein with Callose Binding Activity and Potential to Regulate Cell-to-Cell Trafficking

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