A rice ABC transporter, OsABCC1, reduces arsenic accumulation in the grain

Song, Won Yong; Yamaki, Tomohiro; Yamaji, Naoki; Ko, Donghwi; Jung, Ki‐Hong; Fujii‐Kashino, Miho; An, Gynheung; Martinoia, Enrico; Lee, Youngsook; eng, Jian F

doi:10.1073/pnas.1414968111

Cited by 411 publications

(280 citation statements)

References 34 publications

Supporting

Mentioning

261

Contrasting

Order By: Relevance

“…Recently, identification of mineral nutrient transporters in node and physiological studies shed a new light on the importance of node for preferential distribution of mineral nutrients to developing and reproductive organs (2,14,(18)(19)(20)(21)(22)(23). The xylem flow in EVBs and DVBs, which are connected by nodal vascular anastomosis (NVA) at the base of the node, are simply divided following the transpiration rate of each upper organ.…”

Section: Discussionmentioning

confidence: 99%

Orchestration of three transporters and distinct vascular structures in node for intervascular transfer of silicon in rice

Yamaji

Sakurai

Mitani‐Ueno

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

Self Cite

175

122

View full text Add to dashboard Cite

Requirement of mineral elements in different plant tissues is not often consistent with their transpiration rate; therefore, plants have developed systems for preferential distribution of mineral elements to the developing tissues with low transpiration. Here we took silicon (Si) as an example and revealed an efficient system for preferential distribution of Si in the node of rice (Oryza sativa). Rice is able to accumulate more than 10% Si of the dry weight in the husk, which is required for protecting the grains from water loss and pathogen infection. However, it has been unknown for a long time how this hyperaccumulation is achieved. We found that three transporters (Lsi2, Lsi3, and Lsi6) located at the node are involved in the intervascular transfer, which is required for the preferential distribution of Si. Lsi2 was polarly localized to the bundle sheath cell layer around the enlarged vascular bundles, which is next to the xylem transfer cell layer where Lsi6 is localized. Lsi3 was located in the parenchyma tissues between enlarged vascular bundles and diffuse vascular bundles. Similar to Lsi6, knockout of Lsi2 and Lsi3 also resulted in decreased distribution of Si to the panicles but increased Si to the flag leaf. Furthermore, we constructed a mathematical model for Si distribution and revealed that in addition to cooperation of three transporters, an apoplastic barrier localized at the bundle sheath cells and development of the enlarged vascular bundles in node are also required for the hyperaccumulation of Si in rice husk.node | rice transporter | apoplastic barrier | silicon distribution | mathematical model

show abstract

Section: Discussionmentioning

confidence: 99%

Orchestration of three transporters and distinct vascular structures in node for intervascular transfer of silicon in rice

Yamaji

Sakurai

Mitani‐Ueno

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

Self Cite

175

122

View full text Add to dashboard Cite

show abstract

“…Besides arsenate reduction, phytochelatin-arsenite complexation and subsequent sequestration into the vacuoles constitute another important pathway of arsenic detoxification in plants [58]. Being the precursor compound of phytochelatin (PC) synthesis, glutathione (GSH) plays a crucial role in arsenic tolerance.…”

Section: Accumulation Of Arsenic In Rice Grainmentioning

confidence: 99%

“…The presence of a tonoplast transporter in phloem companion cells (OsABCC1) increase the arsenic sequestration in vacuoles, which help in reduced arsenic translocation into rice grains [58]. However, methylated arsenic species, especially DMA is mobilized at a higher rate than inorganic species [55,61] and its redemption in aleurone, endosperm, and embryo may reduce the seed setting rate and induce spikelet sterility and a reduced yield [62].…”

Section: Accumulation Of Arsenic In Rice Grainmentioning

confidence: 99%

Arsenic Accumulation in Rice and Probable Mitigation Approaches: A Review

Mitra¹,

et al. 2017

View full text Add to dashboard Cite

According to recent reports, millions of people across the globe are suffering from arsenic (As) toxicity. Arsenic is present in different oxidative states in the environment and enters in the food chain through soil and water. In the agricultural field, irrigation with arsenic contaminated water, that is, having a higher level of arsenic contamination on the top soil, which may affects the quality of crop production. The major crop like rice (Oryza sativa L.) requires a considerable amount of water to complete its lifecycle. Rice plants potentially accumulate arsenic, particularly inorganic arsenic (iAs) from the field, in different body parts including grains. Different transporters have been reported in assisting the accumulation of arsenic in plant cells; for example, arsenate (As V ) is absorbed with the help of phosphate transporters, and arsenite (As III ) through nodulin 26-like intrinsic protein (NIP) by the silicon transport pathway and plasma membrane intrinsic protein aquaporins. Researchers and practitioners are trying their level best to mitigate the problem of As contamination in rice. However, the solution strategies vary considerably with various factors, such as cultural practices, soil, water, and environmental/economic conditions, etc. The contemporary work on rice to explain arsenic uptake, transport, and metabolism processes at rhizosphere, may help to formulate better plans. Common agronomical practices like rain water harvesting for crop irrigation, use of natural components that help in arsenic methylation, and biotechnological approaches may explore how to reduce arsenic uptake by food crops. This review will encompass the research advances and practical agronomic strategies on arsenic contamination in rice crop.

show abstract

“…In contrast to Lsi2, Lsi1 is a bidirectional channel, and a portion of As(III) taken up by Lsi1 is released back into the rhizosphere (Zhao et al 2010a), while the remaining As(III) is sequestered into root vacuoles or translocated into different plant organs (Zhao et al 2010b). Recently, a rice ABC transporter (OsABCC1) was identified that limits the As transport to the grains by sequestering As into the vacuoles of the phloem companion cells of the nodes in the rice (Song et al 2014). In the paddy soil solution, the coexistence of As(III) and As(V) with more ratio of As (III) has been shown (Panaullah et al 2009).…”

Section: Introductionmentioning

confidence: 99%

A natural rice rhizospheric bacterium abates arsenic accumulation in rice (Oryza sativa L.)

Lakshmanan

Shantharaj

et al. 2015

Planta

View full text Add to dashboard Cite

A natural rice rhizospheric isolate abates arsenic uptake in rice by increasing Fe plaque formation on rice roots. Rice (Oryza sativa L.) is the staple food for over half of the world's population, but its quality and yield are impacted by arsenic (As) in some regions of the world. Bacterial inoculants may be able to mitigate the negative impacts of arsenic assimilation in rice, and we identified a nonpathogenic, naturally occurring rice rhizospheric bacterium that decreases As accumulation in rice shoots in laboratory experiments. We isolated several proteobacterial strains from a rice rhizosphere that promote rice growth and enhance the oxidizing environment surrounding rice root. One Pantoea sp. strain (EA106) also demonstrated increased iron (Fe)-siderophore in culture. We evaluated EA106's ability to impact rice growth in the presence of arsenic, by inoculation of plants with EA106 (or control), subsequently grew the plants in As-supplemented medium, and quantified the resulting plant biomass, Fe and As concentrations, localization of Fe and As, and Fe plaque formation in EA106-treated and control plants. These results show that both arsenic and iron concentrations in rice can be altered by inoculation with the soil microbe EA106. The enhanced accumulation of Fe in the roots and in root plaques suggests that EA106 inoculation improves Fe uptake by the root and promotes the formation of a more oxidative environment in the rhizosphere, thereby allowing more expansive plaque formation. Therefore, this microbe may have the potential to increase food quality through a reduction in accumulation of toxic As species within the aerial portions of the plant.

show abstract

A rice ABC transporter, OsABCC1, reduces arsenic accumulation in the grain

Cited by 411 publications

References 34 publications

Orchestration of three transporters and distinct vascular structures in node for intervascular transfer of silicon in rice

Orchestration of three transporters and distinct vascular structures in node for intervascular transfer of silicon in rice

Arsenic Accumulation in Rice and Probable Mitigation Approaches: A Review

A natural rice rhizospheric bacterium abates arsenic accumulation in rice (Oryza sativa L.)

Contact Info

Product

Resources

About