Abstract
Arsenic (As) accumulation in rice owing to uptake from the soil is a critical human health issue. Here, we studied the chemical properties of As-treated soils, growth inhibition patterns of As-stressed rice plants, changes in the As content of soil and soil solutions, and the relationship between As accumulation and As transfer factor from the soil to the rice organs. Rice plants were cultivated in a greenhouse under four concentrations of As: 0 (control), 25, 50, and 75 mg kg−1. A significant positive correlation was found between available P2O5 and exchangeable K and between As concentration and available P2O5 or exchangeable K. The As concentration for 50% shoot growth inhibition was 50 mg kg−1. As levels in roots and shoots were positively correlated with the growth stages of rice. The transfer factor (TF)root/soil increased with As concentration at the tillering stage but decreased at the heading stage. TFroot/soil and TFshoot/soil were higher at the heading stage than at the tillering stage. As accumulation in the 25 mg kg−1 treatment was higher during the heading stage, whereas no difference was found at the tillering stage. As accumulation was related to plant biomass and soil As concentration. We found that As accumulation was greater at As concentrations that allowed for plant growth and development. Thus, species-specific threshold concentrations must be determined based on As phytotoxicity for the phytoremediation of As-contaminated soils. Hence, developing practical approaches for managing safe crop production in farmlands with an As contamination of 25 mg kg−1 or less is necessary.
Similar content being viewed by others
Avoid common mistakes on your manuscript.
Introduction
Environmental toxicity owing to arsenic (As) contamination in arable lands causes major problems worldwide. Over the past few decades, millions of people in Southeast Asia have experienced As poisoning owing to consumption of contaminated rice (Bhattacharya et al. 2007; Mondal and Polya 2008; Phan et al. 2014). Environmental pollution, which is rapidly increasing owing to industrialization and urbanization, adversely affects human health. Anthropogenic activities, such as mining and smelting, have resulted in the contamination of agricultural irrigation water and the release of large amounts of As into paddy soils (Khan et al. 2010; Kim et al. 2016; Zhu et al. 2008). The primary determinant of As distribution is its naturally occurring concentration, but social and industrial activities play a primary role in the aggressive expansion of contaminated regions. Since the As contamination of rice has adverse long-term effects on health, rising levels of contamination are a matter of considerable importance (Chowdhury et al. 1999; Roychowdhury et al. 2002; Williams et al. 2005). In Korea, as well as in the rest of Southeast Asia, rice has been a dietary staple for millennia. This region not only accounts for 95% of the global rice production, but also has the highest level of rice consumption (Akinbile et al. 2011; Akinbile and Haque 2012; Kim et al. 2016). Thus, As contamination in rice is a critical issue for human health.
In comparison to other cereal crops (Sharma et al. 2016; Su et al. 2010; Williams et al. 2007), rice is cultivated in the reducing, anaerobic conditions of paddy soil, which results in more efficient absorption of As. Furthermore, when rice is grown in As-contaminated paddy soils, a high concentration of As accumulates in the plants and is transported to edible parts, such as the seeds, or to inedible organs, such as the root, stem, and leaf. This accumulation can result in serious health risks to the end consumer (Abedin et al. 2002; Jung et al. 2015; Xie and Huang 1998). Numerous studies have shown that the absorption, transport, and accumulation of As in rice plants differ depending on the rice cultivar and soil type (Ahmed et al. 2011; Chen et al. 2015; Liu et al. 2005; Norton et al. 2009; Ye et al. 2012). Moreover, using correlation studies, several researchers have clearly demonstrated an antagonistic interaction between As and phosphorus (P), which is one of the three major constituents of fertilizers (Cao et al. 2003; Gunes et al. 2009; Jiang et al. 2014; Meharg et al. 1994; Meharg and Macnair 1992). However, fewer studies have examined the interaction between As and potassium (K) (Carbonell et al. 1998; Tu and Ma 2005; Umar et al. 2013). Therefore, information on the interactions between As and K in rice is essential to further elucidating the effects of increased As on rice plants.
The absorption, translocation, and bioavailability of As in paddy soil have been reported to be closely related to pH, organic matter (OM), redox potential, and clay content. Therefore, these are important factors in predicting changes in the accumulation of As in rice (Bhattacharya et al. 2010; Meharg and Rahman 2003; Ye et al. 2012). However, there is a lack of standardization in the quantitative level of growth inhibition relative to the extent of As contamination. Similarly, the level of As accumulation and transport rate of As from the soil to the rice tissues at each stage of plant growth are uncertain. Research on the relationship between As concentration and the transfer factor and comparisons of changes in the soil based on soil As concentration are scarce. Quantifying the inhibition of growth as a result of different As concentrations and comparisons of the As transfer rate to different plant parts would enable predictions of As accumulation and would contribute to the production management and provision of safe agricultural products from As-contaminated farmlands.
Therefore, the present study was conducted with the following objectives: (1) to quantify the inhibition of plant growth relative to As concentration, (2) to examine the associations of soil As concentration with P and K, (3) to verify changes in As content in the soil solution relative to soil As concentrations, and (4) to evaluate the relationship between the As transfer factor and As accumulation from the soil to the different parts of the rice plant.
Materials and methods
Plant material and growth conditions
Rice (Oryza sativa L. “Dasan”) seeds were surface-sterilized in 0.2% Agri-Mycin solution (commercial bactericide, 8% ipconazole; Farm Hannong Co., Ltd. Seoul, Republic of Korea) for 48 h at ambient temperature and rinsed thoroughly with water. The surface-sterilized seeds were germinated under moist conditions (i.e., seeds were covered with two layers of moist paper towel) at 33 °C for 48 h. The germinated seeds were sown in trays (60 cm × 30 cm × 3 cm) filled with commercial potting soil (Pungnong Co., Ltd. Seoul, Republic of Korea) and grown in a greenhouse (National Institute of Agricultural Science, Wanju, Republic of Korea) during the rice-growing season (mid-June to late September) with natural sunlight and day/night temperatures of 30/25 °C with relative humidity of 60/80%, respectively. After 25 days, the seedlings were transplanted into Wagner pots (0.02-m2 surface area) filled with 3.5 kg of air-dried paddy soil and grown under flooded conditions (i.e., 3–4 cm of water above the soil surface).
Experimental design
The pots were arranged in the greenhouse in a randomized complete block design with three replicates. Urea fertilizer was applied at 110 kg N ha−1, split into two applications: 50% pre-plant-incorporated (PPI) and 50% at the five-leaf stage. Phosphorus (45 kg ha−1) and potassium (57 kg ha−1) fertilizers were applied at PPI. The four levels of As applied were 0 (control), 25, 50, and 75 mg kg−1. According to Korean soil contamination criteria, As levels exceeding 25 and 75 mg kg−1 are the warning and action criteria, respectively. High As-contaminated soil (1050 mg As kg−1) was thoroughly mixed with the paddy soil to achieve the required As concentrations. The chemical properties of the soils are listed in Table 1.
Sampling of soil, soil solutions, and rice plants
Approximately 200 g of soil from each pot was collected before transplanting rice seedlings and after harvesting rice plants at the heading stage. The soil samples were air-dried, homogenized, sieved through a 2-mm mesh sieve, and stored at ambient temperature until further analyses of chemical properties. For collecting soil solution samples from the pots, soil moisture samplers (diameter 2.5 mm, membrane pore size 0.12–0.15 μm, and porous section 10 cm; Rhizosphere Research Products, Wageningen, The Netherlands) were vertically inserted to a 10-cm depth in the pots. Soil solution samples were collected using a syringe before transplanting rice seedlings and at the rice heading stage. The samples were stored in 50-mL polypropylene tubes at 4 °C until further As analyses. For each treatment, three pots were destructively harvested at the rice tillering and heading stages. The harvested root and shoot samples were first thoroughly washed with tap water and then with deionized water to remove dust and adhering soil particles. The washed samples were then dried at 60 °C for 72 h in an oven and subsequently powdered. The powder was stored in 50-mL polypropylene tubes at ambient temperature until As analysis.
As content of soil, soil solutions, and rice tissues
All samples used in this study were analyzed based on the established protocols for soil and plant analyses (NAAS (National Academy of Agricultural Science) 2011). Soil pH and electrical conductivity (EC) were measured using a 1:5 mixture of soil and distilled water. OM content was determined using a wet digestion method, available phosphate (Av. P2O5) was calibrated using the Lancaster method (Cox 2001), and exchangeable cations were determined using 1 M ammonium acetate (pH 7).
The chemical properties of the soil analyzed before transplantation of rice seedlings and after harvesting of rice plants at the heading stage are listed in Table 1. The As content of the soil was analyzed using an inductively coupled plasma-optical emission spectrometer (ICP-OES; GBC AU/Integra XL, GBC Scientific Equipment Ltd., Melbourne, Australia). The homogenized soil (3 g) was digested using a Gerhardt trace metal digestion system (SMA-20A, Gerhardt Co., Ltd. Königswinter, Germany), cooled to ambient temperature, diluted to 100 mL with ultrapure water, and filtered through Whatman No. 40 filter paper (Whatman, Buckinghamshire, UK) into a 100-mL volumetric flask. This filtrate was used for ICP-OES spectrometry.
Inductively coupled plasma-mass spectroscopy (ICP-MS; Agilent 7900, Agilent Technologies Inc., Santa Clara, USA) was used to analyze As content in soil solutions. The soil solution (10 mL) was digested using a graphite block acid digestion system (ODLAB Co., Ltd. Seoul, Republic of Korea). After digestion, the solution was cooled to ambient temperature and diluted to 50 mL with ultrapure water. This diluent was used for the ICP-MS spectrometry.
For measuring As content in the roots and shoots of rice plants, 200 mg of powdered sample was digested using the graphite block acid digestion system. After digestion, the solutions were cooled to ambient temperature, diluted to 100 mL with ultrapure water, and filtered through Whatman No. 40 filter papers. This filtrate was used for ICP-MS spectrometry.
Plant growth response and analysis
The effects of As on plant height, tiller number, shoot dry weight (DW), and shoot water content (WC) of rice plants were measured at the tillering and heading stages (Table 2). The plants were cut at the soil surface, and shoot fresh weights were recorded immediately for calculating shoot water content. The shoots were then dried at 60 °C for 72 h and weighed again to obtain the shoot dry weight.
Data analysis
The relationships between As concentrations and Av. P2O5 (Fig. 1a) and exchangeable (Ex.) K (Fig. 1b) and between Av. P2O5 and Ex. K (Fig. S1) were evaluated by linear regression analyses after harvesting rice plants at the heading stage.
For the evaluation of growth inhibition, data were expressed as the percentage of the mean growth of untreated rice plants in order to standardize comparisons between the As treatments. A linear regression was used to describe growth inhibition at the heading stage. The quantity of As that would reduce shoot dry weight by 50% (GR50) was calculated from the regression equation (Fig. 1c).
To evaluate the relationship between the As contents of the roots and shoot As content of rice plants at tillering (Fig. 3c) and heading (Fig. 3d) stages, a linear regression was performed on the data obtained from the four As treatments.
The soil to root (Fig. 4a) or shoot (Fig. 4b) transfer factor (TF) was calculated as follows:
where Ca is the As concentration of the root or shoot and Cb is the As concentration of the soil.
To elucidate the physiological responses of rice plants to varying levels of As, a principal component analysis (PCA) and a correlation coefficient analysis were performed using MetaboAnalyst 3.0 (www.metaboanalyst.ca) for cluster analysis and heat map generation. Ward’s clustering algorithm and Pearson’s distance were applied for cluster analysis.
All data obtained were subjected to an analysis of variance (ANOVA). To identify significant differences between treatments, Fisher’s least significant difference (LSD) tests were performed with a statistical analysis software (SAS ver. 9.2, SAS Institute Inc., Cary, NC, USA). Differences at P < 0.05 were considered significant. Data in figures are expressed as mean values ± standard deviations (SD).
Results and discussion
Changes in the chemical properties of As-treated soils
The chemical properties of the potting soil treated with 0, 25, 50, or 75 mg As kg−1 were analyzed from the samples collected immediately before transplanting (pre-experiment) and at the heading stage (post-experiment) (Table 1). No significant differences were noted in the chemical properties between the pre- and post-experimental periods, with the exception of Av. P2O5 and Ex. K. Although no significant differences between treatments were observed before the experiment, the concentrations of Av. P2O5 and Ex. K were significantly different after the experiment (Table 1).
As the concentration of As increased, Av. P2O5 (Fig. 1a) and Ex. K (Fig. 1b) increased proportionally in soil, where significant positive correlations between As concentration and Av. P2O5 (Fig. 1a) and Ex. K (Fig. 1b), as well as between Av. P2O5 and Ex. K (Online Resource 1), were observed. To the best of our knowledge, this is the first result to demonstrate the association of As with K in soil. Although the result of the plant analysis showed the association of As with K and P, Liu et al. (2008) reported significant decreases in total K and P concentrations in As treatments of both the shoots and roots of Triticum aestivum under hydroponic conditions. P can affect As uptake by rice, which can be explained by the effect of P on the adsorption of As onto soil particles and the subsequent solubility and bioavailability of As for uptake by rice (Gupta and Ahmad 2014; Islam et al. 2016; Panda et al. 2010). Meharg and Macnair (1992) reported a negative relationship between P and arsenate uptakes by Holcus lanatus roots. Our results were similar to those of Umar et al. (2013), who reported low As uptake by garden cress when low concentrations of K were applied (20–40 mg L−1) but high As uptake when higher concentrations of K were applied (60–100 mg L−1) under hydroponic growth conditions. In addition, Carbonell et al. (1998) and Tu and Ma (2005) showed that K competes with As for uptake by plants. These results show that P and K fertilizers can act as important factors in the growth and development of crops cultivated in fields contaminated with relatively low As concentrations (25 mg kg−1 and lower) and suggest that the management of P and K fertilizations can be used to control As absorption and reduce plant toxicity.
Growth inhibition patterns in As-stressed rice
As toxicity adversely affects photosynthesis by reducing chlorophyll content, thereby negatively affecting overall growth, vital metabolic processes, and crop yields (Gupta and Ahmad 2014; Panda et al. 2010). In the present study, we found that rice plants exhibited an As concentration-dependent inhibition of growth and development. Excluding shoot water content, the presence of As resulted in a reduction in plant height, number of tillers, and shoot dry weight at both the tillering and heading stages in rice plants. Although shoot water content did not differ between the tested As levels at the tillering stage, shoot water content was higher at 50 and 75 mg As kg−1 than at 0 and 25 mg As kg−1 at the heading stage (Table 2). To quantify growth inhibition in relation to As levels, shoot dry weight, a parameter that shows growth inhibition proportional to As concentration, was used in a regression analysis (Fig. 1c). Plant growth decreased linearly with increased As concentrations, and emergence and heading were essentially inhibited at As levels higher than 50 mg kg−1 (Fig. 1d). Thus, an As concentration of 50 mg kg−1 caused a 50% inhibition in growth owing to plant toxicity. The regression analysis showed that a 1% inhibition in rice growth was inversely proportional to a 1 mg As kg−1 increase in As concentration (Fig. 1c).
Changes in the As content of soil and soil solutions
The As content of the soil samples treated with 25, 50, and 75 mg As kg−1 decreased by 28, 18, and 4%, respectively (Fig. 2a), and those of the soil solutions were reduced by 91, 86, and 76%, respectively (Fig. 2b). In addition, the rate of decrease in As content was the highest at 25 mg As kg−1, followed by 50 and 75 mg As kg−1 (Fig. 2a, b). This could be because the maximum limit of As absorption varies with plant species, cultivars, growth stages, and environmental conditions. When the As concentration is higher than the maximum absorption limit, As absorption decreases owing to overall growth inhibition in plants (Panda et al. 2010; Warren et al. 2003).
Relationship between As contents in different organs
The As content in roots and shoots increased proportionally with As concentration at both the tillering and heading stages, where As levels were higher in the roots than in shoots (Fig. 3a, b). The results showed a positive correlation between As content in roots or shoots and the growth stages of rice. The root/shoot ratio at the tillering stage was 63 (Fig. 3c), which was higher than the ratio of 50 observed at the heading stage (Fig. 3d). Thus, a relatively greater amount of As was absorbed and sequestered in the roots at the tillering stage than at the heading stage. Subsequently, as plant biomass increased, an increase in the transfer of As to the shoot occurred.
As transfer-factor profile and accumulation in As-stressed rice
In contrast to the increase in TFroot/soil observed with increasing As treatment at the tillering stage, a decreasing trend was observed at the heading stage (Fig. 4a) (Gupta and Ahmad 2014). The TFroot/soil at the heading stage was significantly higher than that at the tillering stage (Fig. 4a). However, no significant differences were observed for TFshoot/soil between As treatments at the different growth stages of rice (Fig. 4b). TFshoot/soil was higher at the heading stage than at the tillering stage (Fig. 4b). These results are similar to those of Williams et al. (2007), who reported 50-fold higher values for wheat and barley. The TFroot/soil increased as the As content of the soil increased. In contrast, TFshoot/root decreased with increasing As levels in the soil. Similarly, all other TFs (grain/soil, grain/root, and shoot/soil) either remained unchanged or decreased with increasing soil As levels (Batista et al. 2014). Overall, these results clearly show (1) that the shoot transfer rate of As was maintained at a constant value, regardless of the As level, and (2) that the growth stage of the plant and not the As concentration of the soil affected the TF values (Batista et al. 2014; da Silva et al. 2016; Gupta and Ahmad 2014).
Since the estimation of As accumulation in the shoot at different growth stages was based on biomass, As accumulation was significantly higher at the heading stage, when the plants have undergone considerable growth, in comparison to plants in the tillering stage, which experienced a relatively short As exposure period. Furthermore, As accumulation in rice plants was found to be the highest at the lowest As treatment concentration of 25 mg As kg−1, where no significant differences were observed between the higher treatments at 50 and 75 mg As kg−1 (Fig. 4c). These results indicate that As accumulation was highly dependent upon plant biomass and not dependent on As concentration in the soil. Thus, it can be concluded that As accumulation by the rice plants was more efficient when the As concentration in the soil allowed better plant growth and development.
Principal component analysis of the physiological responses of rice plants
A principal component analysis (PCA) score plot was used to evaluate overall responses of rice plants to various levels of As at the tillering and heading stages (Fig. 5a). The PCA score plot accounted for 49.5 and 38.1% of the variance of principal component 1 (PC-1) and principal component 2 (PC-2), respectively. These results indicated that plant physiological responses to treatment with different As levels varied at both growth stages. A comparison of the physiological responses at these two growth stages showed that they were considerably different at the lower levels (0 and 25 mg kg−1) of applied As than at the higher levels (50 and 75 mg kg−1). Furthermore, this result showed that the heading stage was more responsive to As application than the tillering stage, as the response variables in the PCA score plot were much wider and more extensive at the heading stage than at the tillering stage.
At the tillering stage, As shoot/soil ratio, As accumulation, root As, shoot As, and As root/soil ratio were positively correlated with each other but were negatively correlated with tiller number, plant height, and shoot DW (Fig. 5b). At the heading stage, three large positive correlation clusters were identified: (1) tillers, plant height, and shoot DW; (2) As shoot/soil ratio, As root/soil ratio, and As accumulation; and (3) shoot WC, root As, and shoot As. Furthermore, tillers, plant height, and shoot DW were negatively correlated with the other variables (Fig. 5c). Therefore, these results indicate that plant growth stages would be highly affected by the application of As.
Conclusion
Rice growth decreased linearly with As concentration, where the reduced growth inhibited the absorption of the macro-elements P and K, both of which are essential to plant growth and development. Our results clearly show that As transfer to the shoot increased with increases in the duration of As exposure and increased with plant growth and development but was not affected by the As content of the soil. Moreover, As accumulation in plants decreased when As concentrations exceeded a threshold concentration for plant growth. Therefore, for the phytoremediation of As-contaminated soils, the threshold limit concentration for plant growth and development should be determined based on As toxicity in different plant species. Furthermore, our findings highlight the need to develop management methods for safe crop production in farmlands with relatively low As contaminations levels of 25 mg kg−1 or less.
References
Abedin, M. J., Feldmann, J., & Meharg, A. A. (2002). Uptake kinetics of arsenic species in rice plants. Plant Physiology, 128(3), 1120–1128.
Ahmed, Z. U., Panaullah, G. M., Gauch, H., McCouch, S. R., Tyagi, W., Kabir, M. S., & Duxbury, J. M. (2011). Genotype and environment effects on rice (Oryza sativa L.) grain arsenic concentration in Bangladesh. Plant and Soil, 338(1–2), 367–382.
Akinbile, C. O., & Haque, A. M. M. (2012). Arsenic contamination in irrigation water for rice production in Bangladesh: a review. Trends in Applied Sciences Research, 7(5), 331–349.
Akinbile, C. O., El-Latif, K. M. A., Abdullah, R., & Yusoff, M. S. (2011). Rice production and water use efficiency for self-sufficiency in Malaysia: a review. Trends in Applied Sciences Research, 6(10), 1127–1140.
Batista, B. L., Nigar, M., Mestrot, A., Rocha, B. A., Barbosa Jr., F., Price, A. H., et al. (2014). Identification and quantification of phytochelatins in roots of rice to long-term exposure: evidence of individual role on arsenic accumulation and translocation. Journal of Experimental Botany, 65(6), 1467–1479.
Bhattacharya, P., Welch, A. H., Stollenwerk, K. G., McLaughlin, M. J., Bundschuh, J., & Panaullah, G. (2007). Arsenic in the environment: biology and chemistry. Science of the Total Environment, 379(2–3), 109–120.
Bhattacharya, P., Samal, A. C., Majumdar, J., & Santra, S. C. (2010). Accumulation of arsenic and its distribution in rice plant (Oryza sativa L.) in Gangetic West Bengal, India. Paddy and Water Environment, 8(1), 63–70.
Cao, X., Ma, L. Q., & Shiralipour, A. (2003). Effect of compost and phosphate amendments on arsenic mobility in soils and arsenic uptake by the hyperaccumulator Pteris vittata L. Environmental Pollution, 126(2), 157–167.
Carbonell, A. A., Aarabi, M. A., DeLaune, R. D., Gambrell, R. P., & Patrick Jr., W. H. (1998). Arsenic in wetland vegetation: availability, phytotoxicity, uptake and effects on plant growth and nutrition. Science of the Total Environment, 217(3), 189–199.
Chen, Y., Moore, K. L., Miller, A. J., McGrath, S. P., Ma, J. F., & Zhao, F. J. (2015). The role of nodes in arsenic storage and distribution in rice. Journal of Experimental Botany, 66(13), 3717–3724.
Chowdhury, T. R., Basu, G. K., Mandal, B. K., Biswas, B. K., Samanta, G., Chowdhury, U. K., Chanda, C. R., Lodh, D., Roy, S. L., Saha, K. C., & Roy, S. (1999). Arsenic poisoning in the Ganges delta. Nature, 401(6753), 545–546.
Cox, M. S. (2001). The Lancaster soil test method as an alternative to the Mehlich 3 soil test method. Plant and Soil, 166(7), 484–489.
da Silva, C. P., de Almeida, T. E., Zittel, R., de Oliveira Stremel, T. R., Domingues, C. E., Kordiak, J., et al. (2016). Translocation of metal ions from soil to tobacco roots and their concentration in the plant parts. Environmental Monitoring and Assessment, 188(12), 663.
Gunes, A., Pilbeam, D. J., & Inal, A. (2009). Effect of arsenic-phosphorus interaction on arsenic-induced oxidative stress in chickpea plants. Plant and Soil, 314(1–2), 211–220.
Gupta, M., & Ahmad, M. A. (2014). Arsenate induced differential response in rice genotypes. Ecotoxicology and Environmental Safety, 107, 46–54.
Islam, S., Rahman, M. M., Islam, M. R., & Naidu, R. (2016). Arsenic accumulation in rice: consequences of rice genotypes and management practices to reduce human health risk. Environment International, 96, 139–155.
Jiang, W., Hou, Q., Yang, Z., Zhong, C., Zheng, G., Yang, Z., et al. (2014). Evaluation of potential effects of soil available phosphorus on soil arsenic availability and paddy rice inorganic arsenic content. Environmental Pollution, 188, 159–165.
Jung, H. I., Chae, M. J., Kim, S. J., Kong, M., Kang, S. S., Lee, D. B., et al. (2015). Effects of cadmium and arsenic on physiological responses and copper and zinc homeostasis of rice. Korean Journal of Soil Science and Fertilizer, 48(5), 397–403.
Khan, M. A., Stroud, J. L., Zhu, Y. G., Mcgrath, S. P., & Zhao, F. J. (2010). Arsenic bioavailability to rice is elevated in Bangladeshi paddy soils. Environmental Science and Technology, 44(22), 8515–8521.
Kim, H. S., Kang, D. W., Kim, D. I., Lee, S., Park, S. W., Yoo, J. H., et al. (2016). Inorganic As concentration in rice grown around the abandoned mining areas and its health risk assessment. Korean Journal of Soil Science and Fertilizer, 49(5), 584–588.
Liu, X., Zhang, S., Shan, X., & Zhu, Y. G. (2005). Toxicity of arsenate and arsenite on germination, seedling growth and amylolytic activity of wheat. Chemosphere, 61(2), 293–301.
Liu, Q., Hu, C., Tan, Q., Sun, X., Su, J., & Liang, Y. (2008). Effects of As on As uptake, speciation, and nutrient uptake by winter wheat (Triticum aestivum L.) under hydroponic conditions. Journal of Environmental Sciences, 20(3), 326–331.
Meharg, A. A., & Macnair, M. R. (1992). Suppression of the high affinity phosphate uptake system: a mechanism of arsenate tolerance in Holcus lanatus L. Journal of Experimental Botany, 43(4), 519–524.
Meharg, A. A., & Rahman, M. M. (2003). Arsenic contamination of Bangladesh paddy field soils: implications for rice contribution to arsenic consumption. Environmental Science and Technology, 37(2), 229–234.
Meharg, A. A., Naylor, J., & Macnair, M. R. (1994). Phosphorus nutrition of arsenate-tolerant and nontolerant phenotypes of velvetgrass. Journal of Environmental Quality, 23(2), 234–238.
Mondal, D., & Polya, D. A. (2008). Rice is a major exposure route for arsenic in Chakdaha block, Nadia district, West Bengal, India: a probabilistic risk assessment. Applied Geochemistry, 23(11), 2987–2998.
NAAS (National Academy of Agricultural Science). (2011). Methods of soil and plant analysis. Suwon: RDA (In Korean).
Norton, G. J., Duan, G., Dasgupta, T., Islam, M. R., Lei, M., Zhu, Y. G., et al. (2009). Environmental and genetic control of arsenic accumulation and speciation in rice grain: comparing a range of common cultivars crown in contaminated sites across Bangladesh, China, and India. Environmental Science and Technology, 43(21), 8381–8386.
Panda, S. K., Upadhyay, R. K., & Nath, S. (2010). Arsenic stress in plants. Journal of Agronomy and Crop Science, 196(3), 161–174.
Phan, K., Phan, S., Heng, S., Huoy, L., & Kim, K. W. (2014). Assessing arsenic intake from groundwater and rice by residents in Prey Veng province, Cambodia. Environmental Pollution, 185, 84–89.
Roychowdhury, T., Uchino, T., Tokunaga, H., & Ando, M. (2002). Survey of arsenic in food composites from an arsenic-affected area of West Bengal, India. Food and Chemical Toxicology, 40(11), 1611–1621.
Sharma, S., Kaur, J., Nagpal, A. K., & Kaur, I. (2016). Quantitative assessment of possible human health risk associated with consumption of arsenic contaminated groundwater and wheat grains from Ropar Wetland and its environs. Environmental Monitoring and Assessment, 188(9), 506.
Su, Y. H., McGrath, S. P., & Zhao, F. J. (2010). Rice is more efficient in arsenite uptake and translocation than wheat and barley. Plant and Soil, 328(1–2), 27–34.
Tu, C., & Ma, L. Q. (2005). Effects of arsenic on concentration and distribution of nutrients in the fronds of the arsenic hyperaccumulator Pteris vittata L. Environmental Pollution, 135(2), 333–340.
Umar, S., Gauba, N., Anjum, N. A., & Siddiqi, T. O. (2013). Arsenic toxicity in garden cress (Lepidium sativum Linn.): significance of potassium nutrition. Environmental Science and Pollution Research, 20(9), 6039–6049.
Warren, G. P., Alloway, B. J., Lepp, N. W., Singh, B., Bochereau, F. J., & Penny, C. (2003). Field trials to assess the uptake of arsenic by vegetables from contaminated soils and soil remediation with iron oxides. Science of the Total Environment, 311(1), 19–33.
Williams, P. N., Price, A. H., Raab, A., Hossain, S. A., Feldmann, J., & Meharg, A. A. (2005). Variation in arsenic speciation and concentration in paddy rice related to dietary exposure. Environmental Science and Technology, 39(15), 5531–5540.
Williams, P. N., Villada, A., Deacon, C., Raab, A., Figuerola, J., Green, A. J., et al. (2007). Greatly enhanced arsenic shoot assimilation in rice leads to elevated grain levels compared to wheat and barley. Environmental Science and Technology, 41(19), 6854–6859.
Xie, Z. M., & Huang, C. Y. (1998). Control of arsenic toxicity in rice plants grown on an arsenic-polluted paddy soil. Communications in Soil Science and Plant Analysis, 29(15–16), 2471–2477.
Ye, X. X., Sun, B., & Yin, Y. L. (2012). Variation of As concentration between soil types and rice genotypes and the selection of cultivars for reducing As in the diet. Chemosphere, 87(4), 384–389.
Zhu, Y. G., Williams, P. N., & Meharg, A. A. (2008). Exposure to inorganic arsenic from rice: a global health issue? Environmental Pollution, 154(2), 169–171.
Acknowledgments
This work was supported by the “Cooperative Research Program for Agriculture Science & Technology Development (Project No. PJ011953),” Rural Development Administration, Republic of Korea.
Author information
Authors and Affiliations
Corresponding author
Electronic supplementary material
ESM 1
(DOCX 53 kb).
Rights and permissions
Open Access This article is distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution, and reproduction in any medium, provided you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made.
About this article
Cite this article
Jung, Hi., Lee, J., Chae, MJ. et al. Growth-inhibition patterns and transfer-factor profiles in arsenic-stressed rice (Oryza sativa L.). Environ Monit Assess 189, 638 (2017). https://doi.org/10.1007/s10661-017-6350-3
Received:
Accepted:
Published:
DOI: https://doi.org/10.1007/s10661-017-6350-3