Andrzej Paszczynski

Manganese peroxidase of Phanerochaete chrysosporium: Purification☆

Publisher Summary This chapter discusses a method for purification of the manganese peroxidase of P. chrysosporium. It discusses assay methods for manganese. Manganese peroxidase may be assayed using a variety of aromatic substrates, particularly those that are employed for assays of common peroxidascs such as horseradish peroxidase. Reaction mixtures, however, must be supplemented with Mn(II) ions. A very convenient assay of manganese peroxidase activity involves monitoring the enzymes oxidation of Mn(II) to Mn(III). This assay is best used with purified preparations of the peroxidase, as contaminating metals such as iron and copper inhibit the reaction. The most convenient assay for ligninase is a spectrophotometric assay that monitors the oxidation of veratryl alcohol to veratryl aldehyde.

Degradation of azo compounds by ligninase from Phanerochaete chrysosporium: Involvement of veratryl alcohol☆

Phanerochaete chrysosporium decolorized several polyaromatic azo dyes in ligninolytic culture. The oxidation rates of individual dyes depended on their structures. Veratryl alcohol stimulated azo dye oxidation by pure lignin peroxidase (ligninase, LiP) in vitro. Accumulation of compound II of lignin peroxidase, an oxidized form of the enzyme, was observed after short incubations with these azo substrates. When veratryl alcohol was also present, only the native form of lignin peroxidase was observed. Azo dyes acted as inhibitors of veratryl alcohol oxidation. After an azo dye had been degraded, the oxidation rates of veratryl alcohol recovered, confirming that these two compounds competed for ligninase during the catalytic cycle. Veratryl alcohol acts as a third substrate (with H2O2 and the azo dye) in the lignin peroxidase cycle during oxidations of azo dyes.

Antimicrobial properties of pyridine-2,6-dithiocarboxylic acid, a metal chelator produced by Pseudomonas spp

ABSTRACT Pyridine-2,6-dithiocarboxylic acid (pdtc) is a metal chelator produced by Pseudomonas spp. It has been shown to be involved in the biodegradation of carbon tetrachloride; however, little is known about its biological function. In this study, we examined the antimicrobial properties of pdtc and the mechanism of its antibiotic activity. The growth of Pseudomonas stutzeri strain KC, a pdtc-producing strain, was significantly enhanced by 32 μM pdtc. All nonpseudomonads and two strains of P. stutzeri were sensitive to 16 to 32 μM pdtc. In general, fluorescent pseudomonads were resistant to all concentrations tested. In competition experiments, strain KC demonstrated antagonism toward Escherichia coli. This effect was partially alleviated by 100 μM FeCl3. Less antagonism was observed in mutant derivatives of strain KC (CTN1 and KC657) which lack the ability to produce pdtc. A competitive advantage was restored to strain CTN1 by cosmid pT31, which restores pdtc production. pT31 also enhanced the pdtc resistance of all pdtc-sensitive strains, indicating that this plasmid contains elements responsible for resistance to pdtc. The antimicrobial effect of pdtc was reduced by the addition of Fe(III), Co(III), and Cu(II) and enhanced by Zn(II). Analyses by mass spectrometry determined that Cu(I):pdtc and Co(III):pdtc2 form immediately under our experimental conditions. Our results suggest that pdtc is an antagonist and that metal sequestration is the primary mechanism of its antimicrobial activity. It is also possible that Zn(II), if present, may play a role in pdtc toxicity.

Pyridine-2,6-Bis(Thiocarboxylic Acid) Produced by Pseudomonas stutzeri KC Reduces and Precipitates Selenium and Tellurium Oxyanions

ABSTRACT The siderophore of Pseudomonas stutzeri KC, pyridine-2,6-bis(thiocarboxylic acid) (pdtc), is shown to detoxify selenium and tellurium oxyanions in bacterial cultures. A mechanism for pdtcs detoxification of tellurite and selenite is proposed. The mechanism is based upon determination using mass spectrometry and energy-dispersive X-ray spectrometry of the chemical structures of compounds formed during initial reactions of tellurite and selenite with pdtc. Selenite and tellurite are reduced by pdtc or its hydrolysis product H2S, forming zero-valent pdtc selenides and pdtc tellurides that precipitate from solution. These insoluble compounds then hydrolyze, releasing nanometer-sized particles of elemental selenium or tellurium. Electron microscopy studies showed both extracellular precipitation and internal deposition of these metalloids by bacterial cells. The precipitates formed with synthetic pdtc were similar to those formed in pdtc-producing cultures of P. stutzeri KC. Culture filtrates of P. stutzeri KC containing pdtc were also active in removing selenite and precipitating elemental selenium and tellurium. The pdtc-producing wild-type strain KC conferred higher tolerance against selenite and tellurite toxicity than a pdtc-negative mutant strain, CTN1. These observations support the hypothesis that pdtc not only functions as a siderophore but also is involved in an initial line of defense against toxicity from various metals and metalloids.

Production of small molecular weight catalysts and the mechanism of trinitrotoluene degradation by several Gloeophyllum species

The ability of Gloeophyllum species to produce dimethoxybenzoquinones (DMBQ), particularly 2,5-dimethoxyhydroquinone (2,5DMHQ), and oxalic acid was investigated. The involvement of these compounds, along with hydrogen peroxide and Fe(III), in 2,4,6trinitrotoluene (TNT) degradation was examined. Salicylic acid (SA) and phenol (PH) were used as probes to trap Fenton process-produced hydroxyl radicals in several of the investigated species. All the cultures degraded SA and PH readily. A low concentration of 2,3-dihydroxy benzoic acids was detected in cultures of only two Gloeophyllum species. TNT was rapidly transformed by G. trabeum, but ring-UL- 14 CTNT was not converted to 14 CO2. Mass balance studies indicated that about 74% of the radioactivity from TNT remained in the culture supernatant. Analysis of culture extracts revealed several aromatic nitro-amines and nitro-aldehydes and their oligomeric coupling products formed by Schiff base reaction mechanism. 2,2,6,6-Tetramethyl-1-piperidynyloxide (TEMPO), a stable free radical, was used as a trap in in vitro reactions containing hydrogen peroxide, 2,5-DMHQ, and TNT. The coupling products of TEMPO and 2,5-DMHQ were detected, indicating semi-dimethoxy quinone radical formation. The in vitro Fenton-like reaction containing all above reactants except methoxyquinones produced degradation products from TNT similar to those extracted from G. trabeumcultures, suggesting that reduced oxygen species produced by Fenton-like reactions are involved in the transformation of TNT by brown-rot fungi such as G. trabeum.

Pyridine-2,6-bis(thiocarboxylic acid) Produced by Pseudomonas stutzeri KC Reduces Chromium(VI) and Precipitates Mercury, Cadmium, Lead and Arsenic

Interactions of the Pseudomonas stutzeri KC siderophore pyridine-2,6-bis(thiocarboxylic acid) (pdtc) with chromium(VI), mercury(II), cadmium(II), lead(II), and arsenic(III) are described. Pdtc was found to reduce Cr(VI) to Cr(III) in both bacterial cultures and in abiotic reactions with chemically synthesized pdtc. Cr(III) subsequently formed complexes with pdtc and pdtc hydrolysis products, and their presence was confirmed using electrospray ionization-mass spectrometry (ESI-MS). Cr(III):pdtc complexes were found to slowly release Cr(III) as chromium sulfide and possibly Cr(III) oxides. Pdtc also formed poorly soluble complexes with Hg, Cd, Pb, and As(III). Hydrolysis of those complexes led to the formation of their respective metal sulfides as confirmed by energy dispersive X-ray spectroscopy (EDS) elemental analysis. The pdtc-producing strain P. stutzeri KC showed higher tolerance to most of these metals as compared to a pdtc-negative mutant. A novel role of pdtc is postulated as its involvement in providing an extracellular pool of thiols that are used for redox processes in detoxification of the bacterial extracellular environment. These redox processes can be mediated by transition metal:pdtc complexes.

Sterilization of biological pathogens using supercritical fluid carbon dioxide containing water and hydrogen peroxide.

Novel noninvasive techniques for the removal of biological contaminants to generate clean or sterile materials are in demand by the medical, pharmaceutical and food industries. The sterilization method described here uses supercritical fluid carbon dioxide (SF-CO(2)) containing 3.3% water and 0.1% hydrogen peroxide (v/v/v) to achieve from four to eight log viability reduction of all tested microbial species, including vegetative cells, spores and biofilms. The sterilization method employs moderate pressure and temperature (80 atm, 50°C) and a short (30-minute) treatment time. The procedure kills various opportunistic pathogens that often persist in biofilm structures, fungal spores commonly associated with nosocomial infections, and Bacillus pumilus SAFR-032 endospores that are notoriously hard to eradicate by conventional sterilization techniques.

Sterilization of Bacillus pumilus spores using supercritical fluid carbon dioxide containing various modifier solutions

Supercritical fluid carbon dioxide (SF-CO(2)) with small amounts of chemical modifier(s) provides a very effective sterilization technique that should be useful for destroying microorganism on heat-sensitive devices such as instruments flown on planetary-bound spacecraft. Under a moderate temperature (50 degrees C) and pressure (100 atm), spores of Bacillus pumilus strains ATCC 7061 and SAFR 032 can be effectively inactivated/eliminated from metal surfaces and small electronic devices in only 45 min using optimized modifier concentrations. Modifiers explored in this study included hydrogen peroxide (H(2)O(2)), tert-butyl hydroperoxide, formic acid, and Triton X-100. During sterilization procedure the modifiers were continuously added to SF-CO(2) in either methanol or water at controlled concentrations. The lowest effective concentrations were established for each modifier. Complete elimination of both types of B. pumilus endospores occurred with an optimal modifier addition of either or 10% methanol containing 12% H(2)O(2) or 12% tert-butyl hydroperoxide in SF-CO(2), or a mixture of 6% H(2)O(2) and 6% tert-butyl hydroperoxide. Using water as the carrier of SF-CO(2) modifier, the complete elimination of spores viability of both B. pumilus strains occurred with an addition of either 3.3% water containing 3% H(2)O(2), or 3.3% water containing 10% methanol and 0.5% formic acid, or 3.3% water containing 10% methanol, 1% formic acid and 2% H(2)O(2).

Metal binding by pyridine-2,6-bis(monothiocarboxylic acid), a biochelator produced by Pseudomonas stutzeri and Pseudomonas putida

Pyridine-2,6-bis(monothiocarboxylic acid) (pdtc),a natural metal chelator produced by Pseudomonas stutzeri and Pseudomonas putidathat promotes the degradation of carbon tetrachloride, was synthesized and studiedby potentiometric and spectrophotometric techniques. The first two stepwise protonationconstants (pK) for successive proton addition to pdtc were found to be 5.48 and2.58. The third stepwise protonation constant was estimated to be 1.3. The stability (affinity)constants for iron(III), nickel(II), and cobalt(III) were determined by potentiometric orspectrophotometric titration. The results show that pdtc has strong affinity for Fe(III)and comparable affinities for various other metals. The stability constants (log K) are 33.93 for Co(pdtc)21-; 33.36 for Fe(pdtc)21-; and 33.28 for Ni(pdtc)22-. These protonationconstants and high affinity constants show that over a physiological pH range theferric pdtc complex has one of the highest effective stability constants for ironbinding among known bacterial chelators.

Proteogenomic and functional analysis of chromate reduction in Acidiphilium cryptum JF-5, an Fe(III)-respiring acidophile.

Acidiphilium cryptum JF-5, an acidophilic iron-respiring Alphaproteobacterium, has the ability to reduce chromate under aerobic and anaerobic conditions, making it an intriguing and useful model organism for the study of extremophilic bacteria in bioremediation applications. Genome sequence annotation suggested two potential mechanisms of Cr(VI) reduction, namely, a number of c-type cytochromes, and a predicted NADPH-dependent Cr(VI) reductase. In laboratory studies using pure cultures of JF-5, an NADPH-dependent chromate reductase activity was detected primarily in soluble protein fractions, and a periplasmic c-type cytochrome (ApcA) was also present, representing two potential means of Cr(VI) reduction. Upon further examination, it was determined that the NADPH-dependent activity was not specific for Cr(VI), and the predicted proteins were not detected in Cr(VI)-grown cultures. Proteomic data did show measureable amounts of ApcA in cells grown with Cr(VI). Purified ApcA is reducible by menadiol, and in turn can reduce Cr(VI), suggesting a means to obtain electrons from the respiratory chain and divert them to Cr(VI). Electrochemical measurements confirm that Cr reduction by ApcA is pH dependent, with low pH being favored. Homology modeling of ApcA and comparison to a known Cr(VI)-reducing c-type cytochrome structure revealed basic amino acids which could interact with chromate ion. From these studies, it can be concluded that A. cryptum has the physiologic and genomic capability to reduce Cr(VI) to the less toxic Cr(III). However, the expected chromate reductase mechanism may not be the primary means of Cr(VI) reduction in this organism.