Abstract
Mycorrhizae are mutual symbiosis (associations) between plant roots and a wide group of soil-inhabiting, filamentous fungi. Both partners exchange essential nutrients required for their growth and survival. The fungal partner acquires nitrogen, phosphorus, and other nutrients from the soil environment and exchanges them with the plant partner for photosynthetically derived carbon compounds that are essential for its metabolism. Primary function of mycorrhizal fungi is nutrient exchange. In light of growing urbanization, industrialization, and greater environmental disturbances, much effort is being directed toward friendly interaction of man and the environment. As such, considering the new technological and biotechnological advances in the field of ecology and environmental studies, from a management perspective, the genetic potential to mediate virtually any biogeochemical reaction and the habitat needed to support it exist in most soils which with developing specialized capabilities could be investigated further. When mycorrhizae are present in the soil, even under suboptimal conditions, the rhizosphere is more metabolically active. Fungal metabolic activities produce organic acids that percolate with rainwater down through the soil profile and contribute to accelerated weathering of mineral of the soil, and this provides an opportunity for mycorrhizal propagules to adsorb and/or to interact with metal ions under proper matrix potential of the soil. Recent studies have shown that ecosystems are constantly contaminated through wet and dry deposition of atmospheric pollutants such as gases, heavy metals, and radioactive isotopes. Mycorrrhizal fungi have been used as biotracers, bioaccumulators, and biodegraders of toxic compounds. For example, adsorption of radioactive isotopes and heavy metals has been demonstrated in Caspian (Hyrcanian) deciduous forests of Iran. Spore surface and ornamentation contributed to metal adsorption capability of AM fungal spores, with larger and highly ornamented spores demonstrating the highest adsorption readings of many cations. However, adsorbing range of heavy and radioactive metals may be species specific and within a certain range of tolerance.
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References
Agerer R (ed) (1987–2002) Colour atlas of ectomycorrhizae. Einhorn-Verlag Eduard Dietenberger, Schwäbisch Gmünd
Agerer R (2001) Exploration types of ectomycorrhizae: a proposal to classify ectomycorrhizal mycelial systems according to their patterns of differentiation and putative ecological importance. Mycorrhiza 11:107–114
Akbarloo S (1994) Mycorrhizal distribution in Kheiroud Kenar Forest Research Station. MSc thesis, Tarbiat Modarres University, Tehran (In Persian)
Allen MF, Swenson W, Querejeta JI, Egerton-Warburton LM, Treseder KK (2003) Ecology of mycorrhizae: a conceptual framework for complex interactions among plants and fungi. Annu Rev Phytopathol 41:271–303
Assadi M (1984) Plant sociology of Kheiroud Kenar. MSc thesis, Tehran University, Iran (In Persian)
Baes CF III, McLaughlin SB (1987) Trace metal uptake and accumulation in trees as affected by environmental pollution. In: Hutchinson TC, Meems KM (eds) Effects of atmospheric pollutants on forests, wetlands and agricultural ecosystems, vol G16, NATO ASI series. Springer, Berlin, pp 307–319
Baghvardani M (1997) Determining adsorption of radioactive and heavy metals by mycorrhizal fungi in Ramsar Forests. MSc thesis, Tarbiat Modares University, Tehran (in Farsi with English Abstract)
Baghvardani M, Zare-maivan H (1998) Determining adsorption of radioactive and heavy metals by mycorrhizal fungi. In: 13th Iranian plant pathology congress (abstract)
Baghvardani M, Zare-maivan H (2000) Determining adsorption capacity of radioactive and heavy metals by mycorrhizal fungi. Iran J Plant Pathol 36:1–5
Baker AJM, Brooks RR (1989) Terrestrial higher plants which hyperaccumulate metallic elements: a review of their distribution, ecology and phytochemistry. Biorecovery 1:81–126
Barbour M, Burk JH, Pitts DW, Gilliam FS, Schwartz MW (1999) Terrestrial plant ecology. Addison-Wesley Longman, New York, 678 p
Bargagli R, Baldi F (1984) Mercury and methyl mercury in higher fungi and their relation with sulfur in a Cinnabar mining area. Chemosphere 13:1059
Bradley R, Burt AJ, Read DJ (1982) The biology of mycorrhiza in the Ericaceae. VIII. The role of mycorrhizal infection in heavy metal resistance. New Phytol 91:197–209
Brown MT, Wilkins DA (1985) Zinc tolerance of mycorrhizal Betula. New Phytol 99:101–106
Brundrett M (1991) Mycorrhizas in natural ecosystems. In: Begon M, Fitter AH, MacFayden A (eds) Advances in ecological research, vol 21. Academic, Harcourt Brace Jovanovich, New York, pp 171–313
Bruns TD (1995) Thoughts on the processes that maintain local species diversity of ectomycorrhizal fungi. Plant Soil 170:63–73
Cairney JWG (1999) Intraspecific physiological variation: implications for understanding functional diversity in ectomycorrhizal fungi. Mycorrhiza 9:125–135
Cairney JWG (2000) Evolution of mycorrhiza systems. Naturwissenschaften 87:467–475
Chan WK, Griffith DA (1991) The induction of mycorrhizas in Eucalyptus microcorys and E. torrelliana grown in Hong Kong. Forest Ecol Manag 43:15–24
Denny HJ, Wilkins DA (1987a) Zinc tolerance in Betula spp. II. Microanalytical studies of zinc uptake into root tissues. New Phytol 106:525–534
Denny HJ, Wilkins DA (1987b) Zinc tolerance in Betula spp. IV. The mechanism of ectomycorrhizal amelioration of zinc toxicity. New Phytol 106:546–553
Diaz E (2004) Bacterial degradation of aromatic pollutants: a paradigm of metabolic versatility. Int Microbiol 7:173–180
Hibbett DS, Gilbert L-B, Donoghue MJ (2000) Evolutionary instability of ectomycorrhizal symbioses in basidiomycetes. Nature 407:506–508
Horton TR, Bruns TD (2001) The molecular revolution in ectomycorrhizal ecology: peeking into the black box. Mol Ecol 10:1855–1871
Korury SAA, Teimuri M, Khoshnevis M, Salehi P, Salahi A, Matinzadeh M (1999) Determining heavy metal accumulation in Ziziphus spina-christi using Peroxidase analysis. Iranian Forest and Rangeland Institute Report. Ministry of Jihad-Agriculture, Tehran (In Farsi)
Linderman RG (1988) Mycorrhizal interactions with the rhizosphere microflora: the mycorrhizosphere effect. Phytopathology 78:366–371
Marshner H, Dell B (1994) Nutrient uptake in mycorrhizal symbiosis. Plant Soil 159:89–102
Marx DH, Artman JD (1979) Pisolithus tinctorius ectomycorrhizae improve survival and growth of pine seedlings on acid coal soils in Kentucky and Virginia. Reclam Rev 2:23–31
Mc Kenny MC, Donald DL (1987) Improved method for quantifying endomycorrhizal fungi: spores from soil. Mycologia 79:179–187
McGrath SP, Zhao FJ (2003) Phytoremediation of metals and metalloids from soils. Curr Opin Biotechnol 14:277–282
Molina R, Massiocotte H, Trappe JM (1992) Specificity phenomena in mycorrhizal symbioses: community-ecological consequences and practical implications. In: Allen MF (ed) Mycorrhizal functioning: an integrative plant-fungal process. Chapman and Hall, New York, pp 357–423
Nannipieri P, Ascher J, Ceccherni MT, Landi L, Pietramellara G, Renella G (2003) Microbial diversity and soil functions. Eur J Soil Sci 54:655–670
Nourbakhsh A (1994) Succession of vegetation and mycorrhizae in Kheiroud Kenar Forest. MSc thesis, Tarbiat Modares University, Tehran (In Farsi with English abstract)
Nourbakhsh A, Zare-maivan H (1995) Succession pattern of vegetation and mycorrhizae in Kheiroud Kenar Forest. In: 11th Iranian plant pathology congress (abstract)
Perez-Moreno J, Read DJ (2000) Mobilization and transfer of nutrients from litter to tree seedlings via the vegetative mycelium of ectomycorrhizal plants. New Phytol 145:301–330
Peterson RL, Massiocotte HB, Melville LH (2004) Mycorrhizas: anatomy and cell biology. NRC Research Press, Ottawa
Pirozynski KA, Malloch DW (1975) The origin of land plants: a matter of mycotrophism. Biosystems 6:153–164
Ritchie IM, Thingvold DA (1985) Assessment of atmospheric impacts of large-scale copper-nickel development in northern Minnesota. Water Air Soil Pollut 25:145–160
Robertson SJ, Tackabery LE, Egger KN, Massiocotte HB (2006) Ectomycorrhizal fungal communities of black spruce differ between wetland and upland forests. Can J Forest Res 36:972–985
Rosling A, Landeveert R, Lindhall BD, Larsson KH, Kuyper TW, Taylor AFS, Finlay RD (2003) Vertical distribution of ectomycorrhizal fungal taxa in a podzol soil profile. New Phytol 159:775–783
Runeckles VC (1984) Impact of air pollution combinations on plants. In: Treshaw M (ed) Air pollution and plant life. Wiley, Chichester, p 239
Sapp J (2004) The dynamics of symbiosis: an historical overview. Can J Bot 82:1046–1056
Seaward MRD, Richardson DHS (1990) Atmospheric source of metal pollution and effects on vegetation. In: Shaw AJ (ed) Heavy metal tolerance in plants: evolutionary aspects. CRC, Boca Raton, FL, pp 75–92
Smith SE, Read DJ (1997) Mycorrhizal symbiosis, 2nd edn. Academic, London
Tam PCF (1995) Heavy metal tolerance by ectomycorrhizal fungi and metal amelioration by Pisolithus tinctorius. Mycorrhiza 5:181–187
Tam PCF, Griffith DA (1993) Mycorrhizal associations in Hong Kong Fagaceae. IV. The mobilization of organic and poorly soluble phosphates by ectomycorrhizal fungus Pisolithus tinctorius. Mycorrhiza 2:133–139
Turnau K, Kotke I, Oberwinkler F (1993) Element localization in mycorrhizal roots of Pteridium aquilinum (L) Kuhn collected from experimental plots treated with cadmium dust. New Phytol 123:313–324
Vare H (1990) Aluminum polyphosphate in the ectomycorrhizal fungus Suillus variegatus (Fr) O. Kunze as revealed by energy dispersive spectroscopy. New Phytol 116:663–668
Wissenhorn I, Leyval C, Berthelin J (1994) Bioavailability of heavy metals and abundance of arbuscular mycorrhizae in soil polluted by atmospheric deposition from a smelter. Biol Fertil Soils 19:22–28
Wissenhorn L, Leyval C, Belgy G, Berthelin J (1995) Arbuscular mycorrhizal contribution to heavy metal uptake by maize(Zea mays L.) in pot culture with contaminated soil. Mycorrhiza 5:245–251
Zare-maivan H (1983) Root and mycorrhizal distribution of healthy and declining English oaks (Quercus robur L.). MSc thesis, Western Illinois University, Macomb, IL
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Zare-Maivan, H. (2013). Mycorrhizae Adsorb and Bioaccumulate Heavy and Radioactive Metals. In: Goltapeh, E., Danesh, Y., Varma, A. (eds) Fungi as Bioremediators. Soil Biology, vol 32. Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-642-33811-3_12
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