OsHMA3, a P<sub>1B</sub>‐type of ATPase affects root‐to‐shoot cadmium translocation in rice by mediating efflux into vacuoles

Miyadate, Hidenori; Adachi, Saki; Hiraizumi, Aya; Tezuka, Kazuhiko; Nakazawa, Nobushige; Kawamoto, Tomohiko; Katou, Kazunao; Kodama, Ikuko; Sakurai, Kazuo; Takahashi, Hidekazu; Satoh-Nagasawa, Namiko; Watanabe, Akio; Fujimura, Tatsuhito; Akagi, Hiromori

doi:10.1111/j.1469-8137.2010.03459.x

Cited by 521 publications

(388 citation statements)

References 35 publications

(60 reference statements)

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“…QTL analyses, including ours, identified major QTLs responsible for the high-Cd trait of these three cultivars in almost identical regions on chromosome 7 (Tezuka et al 2010, Ueno et al 2009). Very recently, it has been revealed that OsHMA3, a P 1B -type ATPase, is encoded by a gene within the QTL region on chromosome 7 and plays an important role in controlling shoot Cd accumulation in rice (Miyadate et al 2011, Ueno et al 2010. Functional assays by heterologous expression of OsHMA3 in yeast showed that low-Cd cultivars contain a functional version of this gene, which is involved in Cd storage in root vacuoles.…”

Section: Discussionmentioning

confidence: 99%

Detection of a QTL for accumulating Cd in rice that enables efficient Cd phytoextraction from soil

et al. 2011

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Phytoextraction by high-cadmium (Cd)-accumulating rice (Oryza sativa L.) cultivars has been proposed as an attractive technique for cleaning up Cd-contaminated paddy field soil. To breed rice cultivars useful for Cd phytoextraction, it is necessary to understand the genetic basis of Cd accumulation in aerial parts. We developed backcross inbred lines (BILs) derived from a cross between a low-Cd-accumulating cultivar, Koshihikari (japonica), and a relatively high-Cd-accumulating cultivar, Jarjan (indica). The BILs were grown in fields containing two low levels of Cd and in pots of soil containing a moderate level of Cd. A quantitative trait locus (QTL) analysis revealed that a major QTL, qCdp7 (QTL potentially useful for Cdphytoextraction on chromosome 7) contributed to accumulation of Cd in both brown rice and straw of plants grown in any of the three soils, and it accounted for 31% to 54% of the phenotypic variance. To confirm the phytoextraction-promotion ability of qCdp7, we grew BILs carrying the Jarjan allele of qCdp7 in Cdcontaminated soil, and confirmed the reduction of the Cd concentration in the shoots of Koshihikari subsequently grown in the phytoextracted soil. These results demonstrate that the Jarjan qCdp7 allele is effective at phytoextracting Cd from the soil.

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Section: Discussionmentioning

confidence: 99%

Detection of a QTL for accumulating Cd in rice that enables efficient Cd phytoextraction from soil

et al. 2011

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“…Good evidence was presented for the involvement of Ni-histidine complexes in the vacuolar compartmentation of Ni and as a consequence in the retention of this heavy metal in roots [59]. A heavy metal ATPase was suggested to be involved in Cd accumulation in vacuoles of root cells causing Cd retention in roots and decreasing the transport to the shoot [66].…”

Section: Transport With the Transpiration Stream In The Xylemmentioning

confidence: 99%

“…After the release into the root xylem, free or chelated ions flow with the xylem sap upwards (Figure 2). Important for the concentration of heavy metals in the transpiration stream are xylem loading in the roots, interactions with cell walls during acropetal transport and selective removal from the xylem sap [65,66,68,69]. If there would be no further redistribution, the heavy metals would accumulate primarily in photosynthetically active (transpiring) leaves.…”

Section: Transport With the Transpiration Stream In The Xylemmentioning

confidence: 99%

Heavy Metals in Crop Plants: Transport and Redistribution Processes on the Whole Plant Level

2015

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Abstract:Copper, zinc, manganese, iron, nickel and molybdenum are essential micronutrients for plants. However, when present in excess they may damage the plant or decrease the quality of harvested plant products. Some other heavy metals such as cadmium, lead or mercury are not needed by plants and represent pollutants. The uptake into the roots, the loading into the xylem, the acropetal transport to the shoot with the transpiration stream and the further redistribution in the phloem are crucial for the distribution in aerial plant parts. This review is focused on long-distance transport of heavy metals via xylem and phloem and on interactions between the two transport systems. Phloem transport is the basis for the redistribution within the shoot and for the accumulation in fruits and seeds. Solutes may be transferred from the xylem to the phloem (e.g., in the small bundles in stems of cereals, in minor leaf veins). Nickel is highly phloem-mobile and directed to expanding plant parts. Zinc and to a lesser degree also cadmium are also mobile in the phloem and accumulate in meristems (root tips, shoot apex, axillary buds). Iron and manganese are characterized by poor phloem mobility and are retained in older leaves.

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“…Among rice P-type ATPases characterized, OsHMA2 transports Zn and Cd (Satoh-Nagasawa et al, 2012;Takahashi et al, 2012;Yamaji et al, 2013), OsHMA3 is involved in Cd accumulation (Ueno et al, 2010;Miyadate et al, 2011), and OsHMA9 is responsible for the transport of Zn, Cu, Pb, and Cd (Lee et al, 2007). Knockout of OsHMA5 only resulted in altered Cu concentration, but not other metals, including Zn, Fe, and Mn (Fig.…”

Section: Transport Activity Of Oshma5 In Yeastmentioning

confidence: 99%

“…Furthermore, OsHMA2 at the node is required for preferential distribution of Zn to young leaves and panicles (Yamaji et al, 2013). OsHMA3 is localized to the tonoplast of the root cells and responsible for the sequestration of Cd into the vacuoles (Ueno et al, 2010;Miyadate et al, 2011). On the other hand, OsHMA9 was mainly expressed in vascular tissues, including the xylem and phloem (Lee et al, 2007).…”

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A Member of the Heavy Metal P-Type ATPase OsHMA5 Is Involved in Xylem Loading of Copper in Rice

et al. 2013

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ORCID ID: 0000-0003-3411-827X (J.F.M.).Heavy metal-transporting P-type ATPase (HMA) has been implicated in the transport of heavy metals in plants. Here, we report the function and role of an uncharacterized member of HMA, OsHMA5 in rice (Oryza sativa). Knockout of OsHMA5 resulted in a decreased copper (Cu) concentration in the shoots but an increased Cu concentration in the roots at the vegetative stage. At the reproductive stage, the concentration of Cu in the brown rice was significantly lower in the mutants than in the wild-type rice; however, there was no difference in the concentrations of iron, manganese, and zinc between two independent mutants and the wild type. The Cu concentration of xylem sap was lower in the mutants than in the wild-type rice. OsHMA5 was mainly expressed in the roots at the vegetative stage but also in nodes, peduncle, rachis, and husk at the reproductive stage. The expression was up-regulated by excess Cu but not by the deficiency of Cu and other metals, including zinc, iron, and manganese, at the vegetative stage. Analysis of the transgenic rice carrying the OsHMA5 promoter fused with green fluorescent protein revealed that it was localized at the root pericycle cells and xylem region of diffuse vascular bundles in node I, vascular tissues of peduncle, rachis, and husk. Furthermore, immunostaining with an antibody against OsHMA5 revealed that it was localized to the plasma membrane. Expression of OsHMA5 in a Cu transport-defective mutant yeast (Saccharomyces cerevisiae) strain restored the growth. Taken together, OsHMA5 is involved in loading Cu to the xylem of the roots and other organs.

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OsHMA3, a P_1B‐type of ATPase affects root‐to‐shoot cadmium translocation in rice by mediating efflux into vacuoles

Cited by 521 publications

References 35 publications

Detection of a QTL for accumulating Cd in rice that enables efficient Cd phytoextraction from soil

Detection of a QTL for accumulating Cd in rice that enables efficient Cd phytoextraction from soil

Heavy Metals in Crop Plants: Transport and Redistribution Processes on the Whole Plant Level

A Member of the Heavy Metal P-Type ATPase OsHMA5 Is Involved in Xylem Loading of Copper in Rice

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OsHMA3, a P1B‐type of ATPase affects root‐to‐shoot cadmium translocation in rice by mediating efflux into vacuoles

Cited by 521 publications

References 35 publications

Detection of a QTL for accumulating Cd in rice that enables efficient Cd phytoextraction from soil

Detection of a QTL for accumulating Cd in rice that enables efficient Cd phytoextraction from soil

Heavy Metals in Crop Plants: Transport and Redistribution Processes on the Whole Plant Level

A Member of the Heavy Metal P-Type ATPase OsHMA5 Is Involved in Xylem Loading of Copper in Rice

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OsHMA3, a P_1B‐type of ATPase affects root‐to‐shoot cadmium translocation in rice by mediating efflux into vacuoles