Access the full text.
Sign up today, get DeepDyve free for 14 days.
AYu Muratova, TV Dmitrieva, LV Panchenko, OV Turkovskaya (2008)
Phytoremediation of oilsludge-contaminated soilInt. J. Phytoremed., 10
LY Hong, MK Banks, AP Schwab (2008)
Removal of cyanide contaminants from rhizosphere soilBioremed. J., 12
MP Maila, TE Cloete (2002)
Germination of Lepidium sativum as a method to evaluate polycyclic aromatic hydrocarbons (PAHs) removal from contaminated soilInt. Biodeteriorat. Biodegrad., 50
XD Huang, BJ McConcey, ST Babu, DG Dixon, BM Greenberg (1997)
Mechanisms of photoinduced toxicity modified anthracene to plants. Inhibition of photosynthesis in the aquatic higher plants Lemna gibbaEnviron. Toxicol. Chem., 16
CC Wiltse, WL Rooney, Z Chen, AP Schwab, MK Banks (1998)
Greenhouse evaluation of agronomic and crude oil-phytoremediation potential among alfalfa genotypesJ. Environ. Qual., 27
S Criquet, E Joner, P Leglize, C Leyval (2000)
Anthracene and mycorrhiza affect the activity of oxidoreductases in the roots and the rhizosphere of lucerne (Medicago sativa L.)Biotechnol. Lett., 22
GV Zaalishvili, GA Khatisashvili, DSh Ugrekhelidze, MSh Gordeziani, GI Kvesitadze (2000)
Plant potential for detoxification (Review)Prikl. Biokhim. Mikrobiol., 36
GI Kvesitadze, GA Khatisashvili, TA Sadunishvili, ZG Evstigneeva (2005)
Metabolizm antropogennykh toksikantov v vysshikh rasteniyakh
AP Statsenko, LI Tuzhilova, AA V’yugovskii (2008)
Vestn. Orenburg. Gos. Univ.
SL Liu, YM Luo, ZH Cao, LH Wu, KQ Ding, P Christie (2004)
Degradation of benzo[a]pyrene in soil with arbuscular mycorrhizal alfalfaEnviron. Geochem. Health, 26
C Collins, M Fryer, A Grosso (2006)
Plant uptake of non-ionic organic chemicalsEnviron. Sci. Technol., 40
JH Kang, Y Katayama, F Kondo (2006)
Biodegradation or metabolism of bisphenol A: from microorganisms to mammalsToxicology, 217
E Kvesitadze, T Sadunishvili, G Kvesitadze (2009)
Mechanisms of organic contaminants uptake and degradation in plantsWorld Acad. Sci. Engineer. Technol., 55
A Muratova, S Golubev, L Wittenmayer, T Dmitrieva, A Bondarenkova, F Hirche, W Merbach, O Turkovskaya (2009)
Effect of the polycyclic aromatic hydrocarbon phenanthrene on root exudation of Sorghum bicolor (L.) MoenchEnviron. Exp. Bot., 66
A Schaffner, B Massner, C Langebartels, H Sandermann (2002)
Genes and enzymes for in-planta phytoremediation of air, water and soilActa Biotechnol., 22
GS Smith, CM Jonston, IS Cornforth (1983)
Comparison of nutrient solution for growth of plant in sand cultureNew Phytol., 94
VF Gavrilenko, ME Ladygina, MM Khandobina (1975)
Bol’shoi praktikum po fiziologii rastenii
MM Bradford (1976)
A rapid and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein-dye bindingAnal. Biochem., 72
KL Njoku, MO Akinila, OB Oboh (2008)
Growth and performance of Glicine max L. (Merrill) grown in crude oil contaminated soil augmented with cow dungNat. Sci., 6
J Fismes, C Perrin-Ganier, P Empereur-Bissonnet, JL Morel (2002)
Soil-to-root transfer and translocation of polycyclic aromatic hydrocarbons by vegetables grown on industrial contaminated soilsJ. Environ. Qual., 31
CM Frick, RE Farrell, JJ Germida (1999)
Report prepared for the Petroleum Technology Alliance Canada (PTAC)
UK Laemmli (1970)
Cleavage of structural proteins during the assembly of the head of bacteriophageNature, 4
B Peretieno-Clarke, F Achuba (2007)
Phytochemical effect of petroleum on peanut (Arachis hypogea) seedlingsPlant Pathol. J., 6
N Duran, E Esposito (2000)
Potential applications of oxidative enzymes and phenoloxidase-like compounds and soil treatment: a reviewAppl. Catalysis B: Environmental, 28
Y Xu, N Yamaji, R Shen, JF Ma (2007)
Sorghum roots are inefficient in uptake of EDTA-chelated leadAnn. Bot., 99
MK Banks, P Kulakow, AP Schwab, Z Chen, K Rathbone (2003)
Degradation of crude oil in the rhizosphere of Sorghum bicolorInt. J. Phytoremed., 5
Y Gao, XZ Yu, SC Wu, KC Cheung, NFY Tam, PY Qian, MH Wong (2006)
Interactions of rice (Oryza sativa L.) and PAH-degrading bacteria (Acinetobacter sp.) on enhanced dissipation of spiked phenanthrene and pyrene in waterlogged soilSci. Total Environ., 372
A Leonowicz, K Grzywnowicz (1981)
Quantitative estimation of laccase forms in some white-rot fungi using syringaldazine as a substrateEnzyme Microb. Technol., 3
P Schroder (2008)
Phytoremediation: Methods and Reviews
M Kummerova, J Krulova, S Zezulka, J Tpiska (2006)
Evaluation of fluoranthene phytotoxicity in pea plants by Hill reaction and chlorophyll fluorescenceChemosphere, 65
Physiological, biochemical, and growth parameters of sorghum (Sorghum bicolor (L.) Moench) plants grown in the presence of phenantrene (10 and 100 mg/kg soil) were examined. Activities of intracellular tyrosinases, peroxidases, and laccase-like oxidases were analyzed in 1 and 2 months after planting. The tyrosinase activity in root and leaf tissues correlated positively throughout the experiment with the level of soil pollution. The oxidase activity was apparent only in the first month; it also correlated positively with the concentration of phenanthrene. Intracellular peroxidases exhibited the highest activity; positive correlation of this activity with the level of soil contamination was observed in the first period of observations. The soil pollutant had a negative impact on growth characteristics (germination capacity, survival rate, and accumulation of plant biomass). In addition, soil contamination with phenanthrene reduced the total content of photosynthetic pigments and changed their ratio. The maximum extent of phenanthrene elimination in soil was found to occur in the root zone of sorghum plants at high-level contamination, which indicates a significant contribution of plants to the decomposition (binding) of this xenobiotic.
Russian Journal of Plant Physiology – Springer Journals
Published: Jun 24, 2014
Access the full text.
Sign up today, get DeepDyve free for 14 days.