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Serpentine soils do not limit mycorrhizal fungal diversityPotential of Penicillium species in the bioremediation fieldBiological Control of Meloidogyne incognita by Aspergillus niger F22 Producing Oxalic AcidMeasurement of cation exchange capacity (CEC) of plant cell walls by X-ray microanalysis (EDX) in the transmission electron microscope.Aquatic hyphomycete strains from metal-contaminated and reference streams might respond differently to future increase in temperature.Cunninghamella elegans biomass optimisation for textile wastewater biosorption treatment: an analytical and ecotoxicological approach.Fluoride-tolerant mutants of Aspergillus niger show enhanced phosphate solubilization capacity.The response of dark septate endophytes (DSE) to heavy metals in pure culture.Phenotypic heterogeneity is a selected trait in natural yeast populations subject to environmental stress.Biosynthesis and uptake of copper nanoparticles by dead biomass of Hypocrea lixii isolated from the metal mine in the Brazilian Amazon Region.Impact of metal pollution on fungal diversity and community structures.Ectomycorrhizal Community Structure of Salix and Betula spp. at a Saline Site in Central Poland in Relation to the Seasons and Soil Parameters.Harmful effects of silver nanoparticles on a complex detrital model system.Distribution patterns of microbial communities in ultramafic landscape: a metagenetic approach highlights the strong relationships between diversity and environmental traits.Root Fungal Endophytes Enhance Heavy-Metal Stress Tolerance of Clethra barbinervis Growing Naturally at Mining Sites via Growth Enhancement, Promotion of Nutrient Uptake and Decrease of Heavy-Metal Concentration.Role of Penicillium chrysogenum XJ-1 in the Detoxification and Bioremediation of CadmiumPretreatment hepatoprotective effect of the marine fungus derived from sponge on hepatic toxicity induced by heavy metals in rats.Molecular mechanisms of resistance to heavy metals in the protist Euglena gracilis.Bacterial and fungal geomicrobiology: a problem with communities?Biotechnological applications of serpentine soil bacteria for phytoremediation of trace metals.The effects of glyphosate on the in vitro linear growth of selected microfungi from a boreal forest soil.Mechanisms of metal resistance and homeostasis in haloarchaea.Current status of research on fungal bioluminescence: biochemistry and prospects for ecotoxicological application.Isolation and identification of nematode-antagonistic compounds from the fungus Aspergillus candidus.Model systems to unravel the molecular mechanisms of heavy metal tolerance in the ericoid mycorrhizal symbiosis.Role of Bioadsorbents in Reducing Toxic Metals.Biochemical and ecophysiological responses to manganese stress by ectomycorrhizal fungus Pisolithus tinctorius and in association with Eucalyptus grandis.Effects of sediment burial disturbance on macro and microelement dynamics in decomposing litter of Phragmites australis in the coastal marsh of the Yellow River estuary, China.Integrated bioleaching of copper metal from waste printed circuit board-a comprehensive review of approaches and challenges.Biogeochemical spatio-temporal transformation of copper in Aspergillus niger colonies grown on malachite with different inorganic nitrogen sources.The roles of magnesium in biotechnology.Phosphatase-mediated bioprecipitation of lead by soil fungi.A comprehensive study on the behavior of a novel bacterial strain Acinetobacter guillouiae for bioremediation of divalent copper.Transport of small lons and molecules through the plasma membrane of filamentous fungi.Atmospheric Deposition-Carried Zn and Cd from a Zinc Smelter and Their Effects on Soil Microflora as Revealed by 16S rDNA.Evidence of nickel (Ni) efflux in Ni-tolerant ectomycorhizal Pisolithus albus isolated from ultramafic soil.Effects of metals on growth and sporulation of aquatic fungi.Biosorption of Cr(VI) by free and immobilized Pediastrum boryanum biomass: equilibrium, kinetic, and thermodynamic studies.Biodegradation of organics in landfill leachate by immobilized white rot fungi, Trametes versicolor BCC 8725.A preliminary report of indigenous fungal isolates from contaminated municipal solid waste site in India.
P2860
Q21136250-2085C715-BE48-4BD4-B826-9FA87DD43051Q24644814-5FAED294-DBB9-4466-942D-AFE0671DEFE3Q28552670-9619457C-FA81-4129-9D49-A579302C8382Q33291090-7F943C37-749A-4DEB-945B-5852F2C79B7CQ34085146-8D2CD1E9-33F0-4CA3-83DA-BDFC3AE6B1BEQ34153171-8B8ADDDF-B40D-4BFD-8299-0AD3259694EDQ34332281-7D2B977F-9CC2-4AAB-ACEC-6F4C415FCF9EQ34464689-1496B802-5E23-457B-9887-405672C7774AQ34507272-6880B769-18B7-4CEE-A661-D2B1460A9D96Q35055140-4F9C5C81-8A08-4D9A-BB08-893FF0F9D997Q35191731-A6AFA9AD-5B62-48CD-9CCB-FDEEE51E48C0Q35193394-793787F5-E442-4099-83F1-F402CAEA1BD7Q35860490-267C0801-EA20-4960-B503-597ACCB98131Q35963638-73BE7461-249F-476B-AFC2-7B0D934F3DB8Q36234937-52A65AE3-2791-4AAC-9394-0D9AA4BFC78CQ36387339-0EAF8625-9D9D-482D-9147-2C3A766DD254Q36635534-67843EEB-4EAC-459E-9C9D-27F31CFAFCC5Q36902947-C47D401D-ABA1-46A9-8C5E-A9E42F3014C8Q37171057-F0F605EE-AF86-40C8-A3A3-6D8654BBB756Q37514191-67F4E4E4-BEE5-4F26-BD04-11E9C0F9A14FQ37710972-7D81272C-8504-40D9-B8C5-21A30AA8565DQ38093569-02C64D5F-493C-485F-8576-D3CBF33AE05DQ38120847-A3609490-6C34-4C00-9C65-AFBE33361526Q38410384-156BC3E6-2381-4105-A041-D6B24B8D1595Q38681437-57FBC9B6-F3D6-4F23-8B47-7B60EE7F7347Q38770139-1FE3AE6F-7E2B-4656-A52A-EC991ED51B15Q38931108-2F2820F7-FC14-48CC-864E-A7915D8881EBQ38944064-5ACA93D6-420B-4EE9-85F6-5FCB60EA6D40Q38966294-99DF448B-E626-4E88-8BF6-0559E52EF7A8Q40391213-C90D6682-B914-431E-84B1-04938A4BCDB0Q40612440-04B77489-5AF9-4BCA-831D-2101289A6571Q40668352-DFCB9128-221A-4D82-B777-E6EFBAB39CF0Q40896663-A14B6214-381A-4DB7-AE30-052CDB1966FDQ41425845-798A2431-016D-4638-8C74-27918CA6E9D2Q42353550-5690F56F-250C-4E0F-A5A1-E21ABA43B2B1Q42472401-B8B5613E-B78A-4293-A631-46CACF451528Q43080215-E38E3EBB-0F81-46F0-8940-7589E9201945Q43340963-03406933-E8EA-414C-8E44-497AF2FDCAEEQ43355362-3F852275-B806-45AC-A5EF-CE6FB78B1E8AQ43359860-9D70B7E1-F8D1-4CC1-BE40-330D8F9B0B19
P2860
description
article
@en
im Mai 1993 veröffentlichter wissenschaftlicher Artikel
@de
wetenschappelijk artikel
@nl
наукова стаття, опублікована в травні 1993
@uk
ലേഖനം
@ml
name
Interactions of fungip with toxic metals
@en
Interactions of fungip with toxic metals
@nl
type
label
Interactions of fungip with toxic metals
@en
Interactions of fungip with toxic metals
@nl
prefLabel
Interactions of fungip with toxic metals
@en
Interactions of fungip with toxic metals
@nl
P2860
P1433
P1476
Interactions of fungip with toxic metals
@en
P2093
G. M. GADD
P2860
P356
10.1111/J.1469-8137.1993.TB03796.X
P407
P577
1993-05-01T00:00:00Z