Arbuscular mycorrhizal fungi enhance cadmium uptake of wetland plants in contaminated water

doi:10.13287/j.1001-9332.201906.019

Abstract

Abstract: Arbuscular mycorrhizal fungi (AMF) play an important role in plant growth enhancement, tolerance to heavy metal toxicity, and rehabilitation of contaminated ecosystems. An experiment was carried out with Phragmites communis and Pennisetum alopecuroides inoculated with or without Funneliformis mosseae (Fm), or Rhizophagus intraradices (Ri) under the simulated wetland system with Cd polluted water (0, 5, 10 or 20 mg·L^-1). The results showed that Cd addition significantly decreased mycorrhizal colonization. AMF increased plant height, dry mass, leaf chlorophyll, N and Cd contents in shoot and root of P. communis and P. alopecuroides, enhanced Cd enrichment capability by roots, and decreased Cd transfer coefficient. Under Cd 5 mg·L^-1 treatment, all of the indices in Fm + P. communis combination treatment were higher than those of other treatments, with 60.6% of AMF colonization, and the entry points and vesicles per mm root length were 2.3 and 3.7, respectively. Under the inoculation treatment, dry mass of shoot and root was improved by 69.1%, and 75.0%, nitrogen contents in shoot and root were increased by 38.7% and 27.8%, and the chlorophyll content and plant height were increased by 3.8% and 11.1%, respectively. There was a significant positive correlation between Cd concentration in wetland system and Cd content in shoot and root. Under Cd 20 mg·L^-1 treatment, Fm + P. communis combination had the maximum Cd contents of 182.4 mg·kg^-1 and 663.3 mg·kg^-1 in shoot and root, respectively, the lowest Cd transfer coefficient (0.27), and the highest enrichment coefficient (0.55). In conclusion, Fm + P. communis was the best combination for absorbing Cd in polluted water.

NING Chu-han, LI Wen-bin, XU Qi-kai, LI Min, GUO Shao-xia. Arbuscular mycorrhizal fungi enhance cadmium uptake of wetland plants in contaminated water[J]. Chinese Journal of Applied Ecology, 2019, 30(6): 2063-2071.

References

[1] Huang Y, Chen Q, Deng M, et al. Heavy metal pollution and health risk assessment of agricultural soils in a typical peri-urban area in southeast China. Journal of Environmental Management, 2018, 207: 159-168
[2] Liu J, Wang P, Wang C, et al. Heavy metal pollution status and ecological risks of sediments under the influence of water transfers in Taihu Lake, China. Environmental Science & Pollution Research, 2017, 24: 1-14
[3] Maieryemu Y (麦尔耶姆·亚森), Mamat S (买买提·沙吾提), Nigela T (尼格拉·塔什甫拉提), et al. Distribution of heavy metal pollution and assessment of its potential ecological risks in Ugan-Kuqa River Delta of Xinjiang. Transactions of the Chinese Society of Agricultural Engineering (农业工程学报), 2017, 33(20): 226-233 (in Chinese)
[4] Olaniran AO, Adhika B, Balakrishna P. Bioavailability of heavy metals in soil: Impact on microbial biodegradation of organic compounds and possible improvement strategies. International Journal of Molecular Sciences, 2013, 14: 10197-10228
[5] Yabanli^. M, Yozukmaz A, Sel F. Heavy metal accumulation in the leaves, stem and root of the invasive submerged macrophyte Myriophyllum spicatum L. (Halora-gaceae): An example of Kadin Creek (Mugla, Turkey). Brazilian Archives of Biology & Technology, 2014, 57: 47-52
[6] Wang X, Li X, Ma R, et al. Quadratic discriminant analysis model for assessing the risk of cadmium pollution for paddy fields in a county in China. Environmental Pollution, 2018, 236: 366-372
[7] Zhang X, Li X, Yang H, et al. Biochemical mechanism of phytoremediation process of lead and cadmium pollution with Mucor circinelloides, and Trichoderma asperellum. Ecotoxicology & Environmental Safety, 2018, 157: 21-28
[8] Vaario LM, Pennanen T, Lu J, et al. Tricholoma matsutake can absorb and accumulate trace elements directly from rock fragments in the shiro. Mycorrhiza, 2015, 25: 325-334
[9] Wu J-T (吴洁婷). Remediation Potential and Mechanism of Copper Pollution in Phragmites australis-AMF Symbiosis System. PhD Thesis. Harbin: Harbin Institute of Technology, 2015 (in Chinese)
[10] Shi ZY, Mickan B, Feng G, Chene YL. Arbuscular mycorrhizal fungi improved plant growth and nutrient acquisition of desert ephemeral Plantago minuta under variable soil water conditions. Journal of Arid Land, 2015, 7: 414-420
[11] Carrenho R, Alves LDJ, Santos IDS. Arbuscular Mycorrhizal Fungi, Interactions with Heavy Metals and Rehabilitation of Abandoned Mine Lands. Amsterdam, the Netherland: Elsevier, 2018
[12] Chaturvedi R, Favas P, Pratas J, et al. Assessment of edibility and effect of arbuscular mycorrhizal fungi on Solanum melongena L. grown under heavy metal(loid) contaminated soil. Ecotoxicology & Environmental Safety, 2018, 148: 318-326
[13] Bissonnette L, Starnaud M, Labrecque M. Phytoextraction of heavy metals by two Salicaceae clones in symbiosis with arbuscular mycorrhizal fungi during the second year of a field trial. Plant and Soil, 2010, 332: 55-67
[14] Zhang Y, Hu J, Bai J, et al. Arbuscular mycorrhizal fungi alleviate the heavy metal toxicity on sunflower (Helianthus annuus L.) plants cultivated on a heavily contaminated field soil at a WEEE-recycling site. Science of the Total Environment, 2018b, 628: 282-290
[15] Sun H, Xie Y, Zheng Y, et al. The enhancement by arbuscular mycorrhizal fungi of the Cd remediation ability and bioenergy quality-related factors of five switchgrass cultivars in Cd-contaminated soil. PeerJ, 2018, 6: 4414-4425
[16] Ren J (任珺), Tao L (陶玲), Yang Q (杨倩), et al. Accumulation ability of Cd in water for Phragmites australis, Acorus calamus and Scirpus tabernaemontani. Journal of Agro-Environment Science (农业环境科学学报), 2010, 29(9): 1757-1762 (in Chinese)
[17] Wang Q-H (王庆海), Duan L-S (段留生), Wu J-Y (武菊英), et al. Growth vitality and pollutants-removal ability of plants in constructed wetland in Beijing region. Chinese Journal of Applied Ecology (应用生态学报), 2008, 19(5): 1131-1137 (in Chinese)
[18] Akmukhanova NR, Zayadan BK, Sadvakasova AK, et al. Consortium of higher aquatic plants and microalgae designed to purify sewage of heavy metal ions. Russian Journal of Plant Physiology, 2018, 65: 143-149
[19] Zhong Z-M (钟珍梅), He B-L (何波澜), Huang Q-L (黄勤楼), et al. Response of P. americanum × P. purpureum to Cd content in slurry and the Cd accumulation. Journal of Safety and Environment (安全与环境学报), 2016, 16(1): 245-249 (in Chinese)
[20] Lin H (林海), Liu J-F (刘俊飞), Liu L-L (刘璐璐), et al. Physiological responses of Acorus calamus and reed under composite heavy metal stress and their enrichment ability. Chinese Journal of Engineering (工程科学学报), 2017, 39(7): 1123-1128 (in Chinese)
[21] Liu R-J (刘润进), Chen Y-L (陈应龙). Mycorrhizo-logy. Beijing: Science Press, 2007 (in Chinese)
[22] Baker AJM, Brooks RR. Terrestrial higher plants which hyperaccumulated metallic elements: A review of their distribution, ecology and phytochemistry. Biorecovery, 1989, 1: 81-126
[23] Nayuki K, Chen B, Ohtomo R, et al. Cellular imaging of cadmium in resin sections of arbuscular mycorrhizas using synchrotron micro X-ray fluorescence. Microbes & Environments, 2014, 29: 60-66
[24] Joner EJ, Briones RR, Leyval C, et al. Metal-binding capacity of arbuscular mycorrhizal mycelium. Plant and Soil, 2000, 226: 227-234
[25] Chen B-D (陈保冬), Sun Y-Q (孙玉青), Zhang X (张莘), et al. Underlying mechanisms of the heavy metal tolerance of mycorrhizal fungi. Environmental Science (环境科学), 2015, 3(1): 1123-1132 (in Chinese)
[26] Wu S, Zhang X, Sun Y, et al. Chromium immobilization by extra- and intraradical fungal structures of arbuscular mycorrhizal symbioses. Journal of Hazardous Materials, 2016, 316: 34-42
[27] Li Q-L (李秋玲), Ling W-T (凌婉婷), Gao Y-Z (高彦征), et al. Arbuscular mycorrhizal bioremediation and its mechanisms of organic pollutants-contaminated soils. Chinese Journal of Applied Ecology (应用生态学报), 2006, 17(11): 2217-2221 (in Chinese)
[28] Zu Y-Q (祖艳群), Lu X (卢鑫), Zhan F-D (湛方栋), et al. Research progress on the function and mecha-nism of arbuscular mycorrhizal fungi in phytoremediation of heavy metal contaminated soil. Plant Physiology Journal (植物生理学报), 2015, 10(1): 1538-1548 (in Chinese)