Jan Rezek

Phytoremediation: biological cleaning of a polluted environment.

Phytoremediation is the direct use of living green plants to degrade, contain, or render harmless various environmental contaminants, including recalcitrant organic compounds or heavy metals. The methods involved include phytoextraction, direct phytodegradation, rhizofiltration, phytovolatilization or formation of artificial wetlands, and lagoon systems. More research background and the development of plants tailored for remediation purposes, using genetic engineering and deeper understanding of plant cooperation with microorganisms is needed. This approach is illustrated by our studies of heavy metal uptake improvement or studies of the PCB conversion, which include in-vitro screening of plant species, analysis of the products, evaluation of their toxicity and field plots, and also studies of enzymes and cloning of foreign genes into plants.

Phytoremediation of Polychlorinated Biphenyls

MARTINA MACKOVA, DIANE BARRIAULT, KATERINA FRANCOVA, MICHEL SYLVESTRE, MONIKA MODER, BLANKA VRCHOTOVA, PETRA LOVECKA, JITKA NAJMANOVA, KATERINA DEMNEROVA, MARTINA NOVAKOVA, JAN REZEK AND TOMAS MACEK 1 Dept. Biochemistry and Microbiology., Faculty of Food and Biochemical Technology, ICT Prague, Technicka 3, Prague, 166 28 Czech Republic, 2 Dept. of Natural Products, Institute of Organic Chemistry and Biochemistry, Academy of Science of the Czech Republic, Flemingovo n. 2, 166 10 Prague, Czech Republic, E-mail: tom.macek@uochb.cas.cz Institut National de la Recherche Scientifique, INRS-IAF, 245 Boul. Hymus, Pointe-Claire, Quebec, Canada, H9R 1G6, 4 Laboratory of Analytical Chemistry, UFZ Leipzig-Halle, Permoserstrasse 17, Leipzig, Germany, 4

Advances in Phytoremediation and Rhizoremediation

Phytoremediation, with the associated role of rhizospheric microorganisms, is an important tool in bioremediation processes. Plants have an inherent ability to detoxify some xenobiotics and remove compounds from soil by direct uptake of the contaminants followed by subsequent transformation, transport and product accumulation, using enzymes similar to detoxification enzymes in mammals. Being autotrophic organisms, plants do not utilize organic compounds for their energy and carbon metabolism. As a consequence, they usually lack the catabolic enzymes necessary to achieve full mineralization of organic molecules. Plants can be used for removal of both inorganic and organic xenobiotics present in the soil, water and air. The chapter summarizes the classical approaches and possibilities for increasing effectiveness of phyto-and rhizo-remediation using genetically modified organisms. Perspectives are presented related to the use of molecular methods, including metagenomics and stable isotope probing, for obtaining deeper knowledge with a view to influencing the composition of consortia of organisms living in the contaminated environment.

BIODEGRADATION OF PAHS IN LONG-TERM CONTAMINATED SOIL CULTIVATED WITH EUROPEAN WHITE BIRCH (BETULA PENDULA) AND RED MULBERRY (MORUS RUBRA) TREE

The ability of birch (Betula pendula) and mulberry (Morus rubra), cultivated either separately or together with perennial ryegrass (Lolium perenne), to enhance the biodegradation of 15 selected polycyclic aromatic hydrocarbons (PAHs) in long-term contaminated soil was studied in a greenhouse experiment. The microecosystems (MESs) were cultivated for either 12 or 18 months at a natural photoperiod. The fact that the soil chosen for cultivation had been contaminated for over 50 years was expected to be the main factor limiting biodegradation. Extracts of both planted and unplanted soil were analyzed using HPLC. After 1 year of cultivation, the overall content of the investigated compounds had declined to 50%. The concentrations of fluoranthene and pyrene, the PAHs originally present in the soil in the highest concentrations (103.5 and 83.3 mg/kg, respectively), had decreased to 28.0 and 18.0 mg/kg, respectively. In addition, other compounds were successfully degraded, including even benzo[a]pyrene. Benzo[ghi]perylene and indeno[1,2,3-cd]pyrene were the only PAHs remaining and were almost entirely undegraded. Because few significant differences were found between the various types of MESs studied, degradation can primarily be attributed to the presence of degrading microorganisms in the soil.

Trade-off among different anti-herbivore defence strategies along an altitudinal gradient

We found that Salvia nubicola distributed along a broad altitudinal gradient developed a range of defence strategies against insect herbivores. The strategies, however, do not seem to be used simultaneously in all populations even though most of them are correlated with the altitudinal gradient along which herbivore pressure is decreasing. Our study thus shows the importance of simultaneous study of different defence strategies since understanding trade-offs among them could be necessary for detecting the mechanisms by which plants are able to cope with changes in plant-herbivore interactions as a consequence of future climate change.

Preliminary study of phytoremediation of brownfield soil contaminated by PAHs

Our project was aimed at improving a brownfield in the city of Kladno, where an old steel producing facility used to be in operation. Ecological risk is mainly caused by the processing of co-products during coal production (tars, oils). Knowledge of toxicology and environmental aspects can help us protect human health and the environment. Primarily, we focused on soil sampling and identification of pollutants. Results showed that organic contamination on the site is very high. Average concentration of total petroleum carbon in the soil was about 13g/kg DW, which is much more than the maximum allowed concentration. For selection of suitable plant species for phytoremediation at the site, experiments were conducted in a greenhouse. Biomass growth, root morphology, and pigment content in the leaves of Brassica napus var. Opus-C1 and Sorghum×drummondii var. Honey Graze BMR plants were studied. Plant analysis confirmed that polyaromatic hydrocarbons (PAHs) accumulated in the shoots of both plant species. B. napus plants grown on Poldi soil in a greenhouse were able to survive the toxicity of PAHs in soil, and their ability to accumulate PAHs from soil was evident. However, more studies are needed to decide if the plants are usable for phytoremediation of this brownfield.

Myrica rubra leaves as a potential source of a dual 5-LOX/COX inhibitor

ABSTRACT Myrica rubra Sieb. et Zucc. is a valuable fruit tree that is used in Chinese, Japanese and Taiwanese traditional medicine. We investigated the anti-inflammatory activity of M. rubra leaves extracted with four different solvents. Total phenolics were determined using the Folin–Ciocalteu method. Extracts were investigated for their inhibitory activity toward the pro-inflammatory enzymes cyclooxygenase-1 and -2 (COX-1, COX-2) and 5-lipoxygenase (5-LOX). The ethanol extract of M. rubra leaves demonstrated a strong inhibition of prostaglandin E2 (PGE2) biosynthesis catalyzed by both COX-1 (93.42%) and COX-2 (75.71%) and leukotriene B4 (LTB4) formation catalyzed by 5-LOX (82.72%). Further we identified selective COX-1 inhibition by the n-butanol and aqueous fractions of the ethanol extract (with an IC50 for COX-1 inhibition of 1.07 and 0.71 µg mL−1 , respectively) and dual 5-LOX/COX inhibition by the ethyl acetate fraction (with an IC50 of 3.29 for COX-1, 2.54 for COX-2 and 8.30 µg mL−1 for 5-LOX).