Levels of organic compounds, number of microorganisms and cadmium accumulation in Festuca ovina hydroponic culture

• Autorzy: Majewska M. , Slomka A.
• Języki publikacji: EN

Abstrakty

EN

Understanding the microbiological, biochemical and physiological aspects of phytoremediation of soil and water environments polluted to different degrees with heavy metals has very important theoretical and practical implications. In this study, a comparison was made between total cadmium concentration in root and shoot tissues as well as concentrations of particular fractions of Cd immobilized by roots of Festuca ovina (Sheep’s fescue) hydroponically cultivated in nutrient solutions supplemented with 1 μg Cd ml⁻¹ and those cultivated at 10 μg Cd ml⁻¹. After three weeks of F. ovina cultivation, the number of bacterial CFU and the amounts of organic chelators, siderophores, proteins and reducing sugars in the growth medium and on the root surface were higher at 10 than at 1 μg Cd ml⁻¹. The grass also reacted to the high Cd concentration by a decrease in plant growth and dehydrogenase activity in root tissues. The concentration of Cd determined in fractions bound with different strength in roots was significantly dependent on Cd concentration in the growth medium. When the plants were grown at 1 μg Cd ml⁻¹, 9% of the immobilized cadmium was loosely bound to the root surface, 20% was exchangeable adsorbed, and 28% was bound by chelation; at 10 μg Cd ml⁻¹, the respective values were 12%, 25%, and 20%. About 43% of the immobilized cadmium remained in roots after sequential extraction, and bioaccumulation factors in shoots had the same values independently of Cd concentration. At both Cd concentrations, the cadmium translocation index for F. ovina was low (< 1), which is why this grass can be recommended for phytostabilization of the metal under study.

• Wydawca: -
• Czasopismo: Polish Journal of Microbiology
• Rocznik: 2016
• Tom: 65
• Numer: 2
• Opis fizyczny: p.191-200,fig.,ref.

Twórcy

autor

Majewska M.

• Department of Environmental Microbiology, Institute of Microbiology and Biotechnology, Maria Curie-Sklodowska University, Lublin, Poland

autor

Slomka A.

• Department of Environmental Microbiology, Institute of Microbiology and Biotechnology, Maria Curie-Sklodowska University, Lublin, Poland

Bibliografia

• Adeniji B.A., M.T. Budimir-Hussey and S.M. Macfie. 2010. Production of organic acids and adsorption of Cd on roots of durum wheat (Triticum turgidum L. var. durum). Acta Physiol. Plant. 32: 1063–1072.
• Alef K. and P. Nannipieri. 1995. Methods in applied soil microbiology and biotechnology. Academic Press, London.
• Alvarenga P., A.P. Gonçalves, R.M. Fernandes, A. de Varennes, G. Vallini, E. Duarte and A.C. Cunha-Queda. 2008. Evaluation of composts and liming materials in the phytostabilization of a mine soil using perennial ryegrass. Sci. Total Environ. 406: 43–56.
• An L., Y. Pan, Z. Wang and C. Zhu. 2011. Heavy metal absorption status of five plant species in monoculture and intercropping. Plant Soil 345: 237–245.
• Arnow L.E. 1937. Colorimetric determination of the components of 3,4-dihydroksyphenylalanine-tyrosine mixtures. J. Biol. Chem. 228: 531–537.
• Atkin C.L., J.B. Neilands and H. Phaff. 1970. Rhodotorulic acid from species of Rhodospirillum, Rhodotorula, Sporidiobolus and Sporobolomyces. J. Bacteriol. 103: 722–733.
• Atkinson N.J. and P.E. Urwin. 2012. The interaction of plant biotic and abiotic stresses: from genes to the field. J. Exp. Bot. 63(10): 3523–3544.
• Atlas R.M. 1995. Handbook Media for Environmental Microbiology. CRC Press, Boca Raton.
• Bradford M.M. 1976. A rapid and sensitive method for quantification of microgram quantities of proteins utilizing the principle of protein-dye binding. Anal. Biochem. 72: 248–254.
• Brandt S. 1999. Date analysis. Statistical and computational me-thods for scientist and engineers, 3th ed. Springer-Verlang, NewYork.
• Chen G., Y. Liu, R. Wang, J. Zhang and G. Owens. 2013. Cadmium adsorption by willow root: the role of cell walls and their subfractions. Environ. Sci. Pollut. Res. 20: 5665–5672.
• Chen L., S. Luo, X. Xiao, H. Guo, J. Chen, Y. Wan, B. Li, T. Xu, Q. Xi, C. Rao and others. 2010. Application of plant growth-promoting endophytes (PGPE) isolated from Solanum nigrum L. for phytoextraction of Cd-polluted soils. Appl. Soil Ecol. 46: 383–389.
• Cheraghi M., B. Lorestani, N. Khorasani, N. Yusefi and M. Karami. 2011. Finding on the phytoextraction and phytostabilization of soils contaminated with heavy metals. Biol. Trace Elem. Res. 144: 1133–1141.
• Comas L.H., D.M. Eissenstat and A.N. Lakso. 2000. Assessing root death and root system dynamic in a study of grape canopy pruning. New Phytol. 47: 171–178.
• Csaky T.Z. 1948. On the estimation of bound hydroxylamine in biological materials. Acta Chem. Scand. 2: 370–386.
• de Ascencao A.R.F.D.C. and I.A. Dubery. 2003. Soluble and wall-bound phenolics and phenolic polymers in Musa acuminataroots exposed to elicitors from Fusarium oxysporum f.sp. cubense. Phytochemistry 63: 679–686.
• dell’Amico E., L. Cavalca and V. Andreoni. 2005. Analysis of rhizobacterial communities in perennial Gramicaceae from polluted water meadow soil, and screening of metal-resistant, potentially plant growth-promoting bacteria. FEMS Microbiol. Ecol. 52: 153–162.
• Elobeid M., C., Göbel, I. Feussner and A. Polle. 2012. Cadmium interferens with auxin physiology and lignification in poplar. J. Exp. Bot. 63(3): 1413–1421.
• Fiedler H.D., J.L. Westrup, A.J. Souza, A.D. Pavei, C.U. Chagas and F. Nome. 2004. Cd (II) determination in the presence of aqueous micellar solutions. Talanta 64: 190–195.
• Ganesan V. 2012. Rhizoremediation: a pragmatic approach for remediation of heavy metal-contaminated soil, pp. 147–162. In: Zaidi A., P.A. Wani and M.S. Khan (eds). Toxicity of heavy metals to legumes and bioremediation. Springer-Verlag Wien.
• Gerhardt K.E., X.-D. Huang, B.R. Glick and B.M. Greenberg. 2009. Phytoremediation and rhizoremediation of organic soil contaminants: Potential and challenges. Plant Sci. 176: 20–30.
• Grodzińska K. and G. Szarek-Łukaszewska. 2009. Heavy metal vegetation in the Olkusz region (Southern Poland) – preliminary studies. Pol. Bot. J. 54(1): 105–112.
• Haoliang L., Y. Chongling and L. Jingchum. 2007. Low-molecular-weight organic acids exuded by mangrove (Kandelia candel (L.) Druce) roots and their effect on cadmium species change in the rhizosphere. Environ. Exp. Bot. 61: 159–166.
• Huang P.M. and J.J. Germina. 2002. Chemical and biological processes in the rhizosphere: metal pollutants, pp. 381–438. In: Huang P.M., J.-M. Bollag and N. Senesi (eds). Interaction between soil particle and microorganisms. Impact on the terrestrial ecosystem. IUPAC series on analytical and physical chemistry of environmental systems, vol. 8. John Wiley & Sons LTD, Chichester.
• Jha P.N., G. Gupta, P. Jha and R. Mehrotra. 2013. Association of rhizospheric/endophytic bacteria with plants: a potential gateway to sustainable agriculture. Greener J. Agric. Sci. 3(2): 73–84.
• Kacálková L., P. Tlustoš and J. Száková. 2014. Chromium, nickel, cadmium, and lead accumulation in maize, sunflower, willow, and poplar. Pol. J. Environ. Stud. 23 (3): 753–761.
• Kamaludeen S.P.B. and K. Ramasamy. 2008. Rhizoremediation of metals: harnessing microbial communities. Indian J. Microbiol. 48: 80–88.
• Kao P.-H., C.-C. Huang and Z.-Y. Hseu. 2006. Response of microbial activities to heavy metals in a neutral loamy soil treated with biosolid. Chemosphere 64: 63–70.
• Khan M.I.R., M. Fatma, T.S. Per, N.A. Anjum and N.A. Khan. 2015. Salicylic acid-induced abiotic stress tolerance and underlying mechanisms in plants. Front. Plant Sci. 6: 462–478.
• Kim K.-R., G. Owens, R. Naidu and S.-I. Kwon. 2010. Influence of plant roots on rhizosphere soil solution composition of long-term contaminated soils. Geoderma 155: 86–92.
• Kurek E. and M. Majewska. 2004. In vitro remobilization of Cd immobilized by fungal biomass. Geoderma 122: 235–246.
• Kurek E. and M. Majewska. 2012. Microbially mediated transformations of heavy metals in rhizosphere, pp. 129–146. In: Zaidi A., P.A. Wani and M.S. Khan (eds). Toxicity of heavy metals to legumes and bioremediation, Springer-Verlag Wien.
• Li Y., L. Wang, L. Yang and H. Li. 2014. Dynamics of rhizosphere properties and antioxidative responses in wheat (Triticum aestivum L.) under cadmium stress. Ecotox. Environ. Safe 102: 55–61.
• Lou Y., H. Luo, T. Hu, H. Li and J. Fu. 2013. Toxic effects, uptake, and translocation of Cd and Pb in perennial ryegrass. Ecotoxicology 22: 207–214.
• Madhaiyan M., S. Poonguzhali and S. Tongmin. 2007. Metal tolerating methylotrophic bacteria reduces nickel and cadmium toxicity and promotes plant growth of tomato (Lycopersicon esculentum L.). Chemosphere 69: 220–228.
• Majewska M., E. Kurek and D. Szlachetka. 2006. Microbial activity – factor increasing retention of Cd added to soil. Pol. J. Environ. Stud. 15(2a): 127–134.
• Majewska M. and E. Kurek. 2011. Effect of Cd concentration in growth media on Secale cereale roots and Cd interaction with rhizosphere microorganisms originating from different parts of the grain. Eur. J. Soil. Biol. 47: 95–101.
• Majewska M., E. Kurek and A. Słomka. 2011. Effect of plant growth on total concentrations of Zn, Pb, and Cd, and their distribution between operational fractions in the upper layer of a 100-year-old zinc-lead waste heap. Pol. J. Environ. Stud. 20(3): 591–297.
• Martin J.P. 1950. Use of acid, rose bengal and streptomycin in the plate method for estimating soil fungi. Soil Sci. 38: 215–220.
• Mendez M.O. and R.M. Maier. 2008. Phytostabilization of mine tailing in arid and semiarid environments – an emerging remediation technology. Environ. Health Persp. 116(3): 278–283.
• Philippot L., J.M. Raaijmakers, P. Lemanceau and W.H. van der Putten. 2013. Going back to the roots: the microbial ecology of the rhizosphere. Nat. Rev. Microbiol. 11: 789–799.
• Renella G., L. Landi and P. Nannipieri. 2004. Degradation of low molecular weight organic acids complexed with heavy metals in soil. Geoderma 122: 311–315.
• Schützendübel A., P. Schwanz, T. Teichmann, K. Gross, R. Langenfeld-Heyser, D.L. Godbold and A. Polle. 2001. Cadmium-induced changes in antioxidative systems, hydrogen peroxide content, and differentiation in scots pine roots. Plant Physiol. 127: 887–898.
• Šćiban M.B., M.T. Klašnja and M.G. Antov. 2011. Study of the biosorption of different heavy metal ions onto Kraft lignin. Ecol. Eng. 37: 2092–2095.
• Semenov V.M., A.S. Tulina, N.A. Semenova and L.A. Ivannikova. 2013. Humification and nonhumification pathways of the organic matter stabilization in soil: A review. Eurasian Soil Sci. 46(4): 355–368.
• Sipos G., Á. Solti, V. Czech, I. Vashegyi, B. Tóth, E. Cseh and F. Fodor. 2013. Heavy metals accumulation and tolerance of energy grass (Elymus elongates subsp. ponticus cv. Szavasi-1) grown in hydroponic culture. Plant Physiol. Bioch. 68: 96–103.
• Soleimani M., H.A. Hajabbasi, M. Afyuni, A. Mirlohi, O.K. Borggaard and P.E. Holm. 2010. Effect of endophytic fungi on cadmium tolerance and bioaccumulation by Festuca arundinacea and Festuca pratensis. Int. J. Phytoremediat. 12: 535–549.
• Van der Perk M. 2006. Soil and Water Contamination from Molecular to Catchment Scale. Taylor & Francis/Balkema, Leiden.
• Xu Y. and F.M.M. Morel. 2013. Cadmium in Marine Phytoplankton, pp. 509–528. In: Sigiel A., Sigiel, H. and R.K.O. Sigiel, (eds). Cadmium: From Toxicity to Essentiality, Metal Ions in Life Sciences. Springer Sciences + Business Media, Dordrecht.
• Yin Y., Y. Wang, Y. Liu, G. Zeng, X. Hu, X. Hu, L. Zhou, Y. Guo and J. Li. 2015. Cadmium accumulation and apoplastic and symplastic transport in Boehmeria nivea (L.) Gaudich on cadmium-contaminated soil with the addition of EDTA or NTA. RSC Advances 5: 47584–47591.
• Zhang S., T. Li, H. Huang, Z. Zou, X. Zhang, H. Yu, Z. Zheng and Y. Wang. 2012. Cd accumulation and phytostabilization potential of dominant plants surrounding mining tailings. Environ. Sci. Pollut. Res. 19: 3879–3888.
• Zhang Y., S. Xu, S. Yang and Y. Chen. 2015. Salicylic acid alleviates cadmium-induced inhibition of growth and photosynthesis through upregulating antioxidant defense system in two melon cultivars (Cucumis melo L.). Protoplasma 252: 911–924.

Identyfikatory

DOI

10.5604/17331331.1204479