Bystrík Polek

Production of catalases by Aspergillus niger isolates as a response to pollutant stress by heavy metals.

Isolates of Aspergillus niger, selected from the coal dust of a mine containing arsenic (As; 400 mg/kg) and from the river sediment of mine surroundings (As, 1651 mg/kg, Sb, 362 mg/kg), growing in minimal nitrate medium in the phase of hyphal development and spore formation, exhibited much higher levels of total catalase activity than the same species from the culture collection or a culture adapted to soil contaminated with As (5 mg/L). Electrophoretic resolution of catalases in cell-free extracts revealed three isozymes of catalases and production of individual isozymes was not significantly affected by stress environments. Exogenously added stressors (As5+, Cd2+, Cu2+) at final concentrations of 25 and 50 mg/L and H2O2 (20 or 40 mM) mostly stimulated production of catalases only in isolates from mines surroundings, and H2O2 and Hg2+ caused the disappearance of the smallest catalase I. Isolates exhibited a higher tolerance of the toxic effects of heavy metals and H2O2, as monitored by growth, than did the strain from the culture collection.

Diversity and PAH growth abilities of bacterial strains isolated from a contaminated soil in Slovakia

Different abandoned industrial areas contaminated by polycyclic aromatic hydrocarbons (PAHs) are present in Slovakia. These environmental burdens are very dangerous to the health of human and environment. The bioremediation, based on the use of hydrocarbons degrading microorganisms, is a promising strategy to sanitize these polluted sites. The aim of this investigation was to assess the bacterial diversity of a PAHs-contaminated soil and to select the potential hydrocarbonoclastic bacteria which can be used for different bioremediation approaches. The bacterial strains were isolated on minimal medium agar supplemented with a mixture of PAHs. Seventy-three isolated strains were grouped by ribosomal interspacer analysis in 15 different clusters and representatives of each cluster were identified by 16S rRNA sequencing. The PAHs degradation abilities of all bacterial isolates were estimated by the 2,6-dichlorophenol indophenol assay and by their growth on minimal broth amended with a mixture of PAHs. Different kinds of strains, members of the genus Pseudomonas, Enterobacter, Bacillus, Arthrobacter, Acinetobacter and Sphingomonas, were isolated from the contaminated soil. Four isolates (Pseudomonas putida, Arthrobacter oxydans, Sphingomonas sp. and S. paucimobilis) showed promising PAHs-degrading abilities and therefore their possible employing in bioremediation strategies.

Production of Catalases by Comamonas spp. and Resistance to Oxidative Stress

Bacterial isolatesComamonas terrigena N3H (from soil contaminated with crude oil) andC. testosteroni (isolated from the sludge of a wastewater treatment plant), exhibit much higher total catalase activity than the same species from laboratory collection cultures. Electrophoretic resolution of catalases revealed only one corresponding band in cell-free extracts of bothC. testosteroni cultures. Isolates ofC. terrigena N3H exhibited catalase-1 and catalase-2 activity, whereas in the collection cultureC. terrigena ATCC 8461 only catalase-1 was detected. The environmental isolates exhibited much higher resistance to exogenous H2O2 (20, 40 mmol/L) than collection cultures, mainly in the middle and late exponential growth phases. The stepwise H2O2-adapted culture ofC. terrigena N3H, which was more resistant to oxidative stress than the original isolate, exhibited an increase of catalase and peroxidase activity represented by catalase-1. Pretreatment of cells with 0.5 mmol/L H2O2 followed by an application of the oxidative agent in toxic concentrations (up to 40 mmol/L) increased the rate of cell survival in the original isolate, but not in the H2O2-adapted variant. The protection of bacteria caused by such pretreatment corresponded with stimulation of catalase activity in pretreated culture.

Lag period of 14CO2 evolution from dioctyl sulpho[2,3-14C]succinate in relation to adaptation of bacterium, Comamonas terrigena, to dialkyl esters of sulphosuccinate

Comamonas terrigena, strain N3H, which was isolated from soil polluted with crude oil products, degraded dioctyl sulphosuccinate, a synthetic commercial surfactant. The primary degradation of this compound, the cleavage of ester bonds between octyl groups and sulphosuccinate, lasted significantly shorter time than the subsequent breakdown of the sulphosuccinate moiety of dioctyl sulpho[2,3-14C]succinate. 14CO2 evolution had a significant shorter lag period with cells in Tris/phosphate medium, without inorganic sulphate and adapted to surfactant, than unadapted cells. The acceleration of the primary degradation by adapted cells also suggest that some enzymes involved in surfactant degradation are inducible. The bacterium may be useful for bioremediation.

Intracellular targeting of ascomycetous catalase-peroxidases (KatG1s)

Bifunctional catalase-peroxidases (KatGs) are heme oxidoreductases widely spread among bacteria, archaea and among lower eukaryotes. In fungi, two KatG groups with different localization have evolved, intracellular (KatG1) and extracellular (KatG2) proteins. Here, the cloning, expression analysis and subcellular localization of two novel katG1 genes from the soil fungi Chaetomium globosum and Chaetomium cochliodes are reported. Whereas, the metalloenzyme from Ch. globosum is expressed constitutively, Ch. cochliodes KatG1 reveals a slight increase in expression after induction of oxidative stress by cadmium ions and hydrogen peroxide. The intronless open reading frames of both Sordariomycetes katG1 genes as well as of almost all fungal katG1s possess two peroxisomal targeting signals (PTS1 and PTS2). Peroxisomal localization of intracellular eukaryotic catalase-peroxidases was verified by organelle separation and immunofluorescence microscopy. Co-localization with the peroxisomal enzyme 3-ketoacyl-CoA-thiolase was demonstrated for KatGs from Magnaporthe grisea, Chaetomium globosum and Chaetomium cochliodes. The physiological role of fungal catalase-peroxidases is discussed.

Molecular diversity of katG genes in the soil bacteria Comamonas

Three complete katG genes coding for bifunctional catalase-peroxidases (KatGs) from the β-proteobacterium Comamonas terrigena and two related strains of Comamonas testosteroni have been cloned and sequenced. Catalase-peroxidases are unique bifunctional enzymes known to be expressed in these soil bacteria in response to environmental and/or oxidative stress. The evolutionary and structural diversity of these enzymes is investigated based on multiple sequence alignment and comprehensive phylogenetic analysis. The reconstructed phylogenetic tree and well-known structure–function relationships were applied to inspect the conservation of essential residues. Observed diversity is discussed with respect to the fact that KatGs are distinctive gene-duplicated peroxidases comprising a N-terminal (enzymatically active) and a C-terminal (heme-less) domain. The unique promoter motifs regulating katG transcription in four strains of Comamonas were detected and compared with E. coli katG promoter. The relationship between the promoter sequences and the corresponding expression levels was analyzed. A significant difference in heat shock-inducible catalatic and peroxidatic activities between E. coli K12 and Comamonas terrigena & testosteroni strains was observed. The peculiar variability in gene-coding sequences appears to be more significant for such activity output among Comamonas strains than differences in their promoter regions. The functional role of observed increased diversity in the C-terminal domain is discussed with respect to potential modification of catalytic features at the N-terminal domain that could be relevant for these soil bacteria to cope with stressors.

Oxidative Stress-Induced Expression of Catalases in Comamonas terrigena

When grown under oxidative stress, catalatic as well as peroxidatic activity is increased in the Gram-negative bacteriumComamonas terrigena N3H. Two distinct hydroperoxidases were demonstrated by a specific staining. Based on their molar masses and their sensitivity toward 3-amino-1,2,4-triazole and high temperatures, they were identified as dimeric catalase-1 (Cat-1; 150 kDa), and as a tetrameric catalase-2 (Cat-2; 240 kDa) with enhanced peroxidatic activity, respectively. These two catalases differ in their expression during the bacterial growth; whereas the expression of the smaller enzyme (Cat-1) is induced by 0.5 mmol/L peroxides in the medium, and to a lesser degree by 25 mg/L Cd2+, Cat-2 (typical catalase) is almost specifically induced with cadmium ions.

Metabolic activity of cadmium-stressed and/or starvedVibrio sp.

Starvation ofVibrio sp. strain S14 cells for at least 2.5 h induced an enhanced resistance to subsequently applied cadmium stress. Bacterial cultures starved for a shorter time (0–2 h) exhibited a decreased ability to incorporate glucose when exposed to Cd2+. Cyclic increase and decrease in protein synthetic activity of stressed vibrios reflect stages of starvation-induced protiens expression. Vibrio cells pre-stressed by Cd2+ addition or by starvation responded in many aspects similarly to the next stress challenge. The presence of 100 mg/L chloramphenicol significantly lowered cell resistance against the secondary stress. Proteins synthesized due to the primary stress provideVibrio S14 with an enhanced probability to survive in unfavourable environment.

Protein expression in the stressed Vibrio strains.

In a conjunction process using Escherichia coli SM10 (pLOF) KmR APR as donor and Vibrio S141 SmR as recipient, several mutants were constructed: Vibrio PH 101, V. PH 106, and V. PH 109 with lowered ability to synthesize poly-beta-hydroxybutyrate. The survival and metabolic activities of parent and mutant strains were estimated when they were subjected to stress conditions (starvation of carbon and energy sources and/or cadmium treatment). Using two-dimensional electrophoresis, the synthesis of stress proteins was demonstrated. Vibrio cultures consecutively exposed to CdCl2 and then to starvation or vice versa responded similarly metabolically. These results show increased proteosynthetic activity of the stressed Vibrio cells, indicating that the primary cadmium treatment induced the expression and synthesis of the protective proteins, enabling the cells to cope with the secondary stress.