Biodegradation of Phenol: Mechanisms and Applications

Phenol, or hydroxybenzene, is both a synthetically and naturally produced aromatic compound. Microorganisms capable of degrading phenol are common and include both aerobes and anaerobes. Many aerobic phenol-degrading microorganisms have been isolated and the pathways for the aerobic degradation of phenol are now firmly established. The first steps include oxygenation of phenol by phenol hydroxylase enzymes to form catechol, followed by ring cleavage adjacent to or in between the two hydroxyl groups of catechol. Phenol hydroxylases ranging from simple flavoprotein monooxygenases to multicomponent hydroxylases, as well as the genes coding for these enzymes, have been described for a number of aerobic phenol-degrading microorganisms. Phenol can also be degraded in the absence of oxygen. Our knowledge of this process is less advanced than that of the aerobic process, and only a few anaerobic phenol-degrading bacteria have been isolated to date. Convincing evidence from both pure culture studies with the denitrifying organism Thauera aromatica K172 and with two Clostridium species, as well as from mixed culture studies, indicates that the first step in anaerobic phenol degradation is carboxylation in the para-position to form 4-hydroxybenzoate. Following para-carboxylation, thioesterification of 4-hydroxybenzoate to co-enzyme A allows subsequent ring reduction, hydration, and fission. Para-carboxylation appears to be involved in the anaerobic degradation of a number of aromatic compounds. Numerous practical applications exist for microbial phenol degradation. These include the exploitation of indigenous anaerobic phenol-degrading bacteria in the in situ bioremediation of creosote-contaminated subsurface environments, and the use of phenol as a co-substrate for indigenous aerobic phenol-degrading bacteria to enhance in situ biodegradation of chlorinated solvents.     

Hydroxylation of phenol to catechol by Candida tropicalis: involvement of cytochrome P450

Microsomal preparations isolated from yeast Candida tropicalis (C. tropicalis) grown on three different media with or without phenol were isolated and characterized for the content of cytochrome P450 (CYP) (EC 1.14.15.1). While no CYP was detected in microsomes of C. tropicalis grown on glucose as the carbon source, evidence was obtained for the presence of the enzyme in the microsomes of C. tropicalis grown on media containing phenol. Furthermore, the activity of NADPH: CYP reductase, another enzyme of the microsomal CYP-dependent system, was markedly higher in cells grown on phenol. Microsomes of these cells oxidized phenol. The major metabolite formed from phenol by microsomes of C. tropicalis was characterized by UV/vis absorbance and mass spectroscopy as well as by the chromatographic properties on HPLC. The characteristics are identical to those of catechol. The formation of catechol was inhibited by CO, the inhibitor of CYP, and correlated with the content of cytochrome P450 in microsomes. These results, the first report showing the ring hydroxylation of phenol to catechol with the microsomal enzyme system of C. tropicalis, strongly suggest that CYP-catalyzed reactions are responsible for this hydroxylation. The data demonstrate the progress in resolving the enzymes responsible for the first step of phenol degradation by the C. tropicalis strain.     

Phenol utilisation by fungi isolated from activated sludge

The paper presents the efficiency of phenol removal (concentrations from 500 to 2000 mg/l) by fungi isolated from activated sludge purifying wastewater with high phenol concentration. Five fungal strains were isolated and identified. All isolated strains appeared to be Moniliales from the class of Fungi Imperfecti (Candida sp., Monosporium sp., Trichosporon sp.) Stationary cultures of the individual strains and their mixtures were maintained in Czapek medium containing phenol in concentration from 500 to 2000 mg/l. All isolated strains (except one) were capable of utilising phenol up to a concentration of 1500 mg/l. Depending on investigated strain, phenol in concentration of 500 mg/l was decomposed during 4-25 days, 750 mg/l during 4-14 days. After 20 days, a phenol decline of 1000 mg/l was observed. After 16 days, the phenol decline was 1500 mg/l. Higher phenol concentrations (1500 mg/l) were utilised only by a mixture of two strains. The investigated fungal strains showed good efficiency of phenol removal from high phenol concentration in wastewater and they may be proposed for use in the process of purifying wastewater of this type.     

Anaerobic degradation of phenol by pure cultures of newly isolated denitrifying pseudomonads

From various oxic or anoxic habitats several strains of bacteria were isolated which in the absence of molecular oxygen oxidized phenol to CO₂ with nitrate as the terminal electron acceptor. All strains grew in defined mineral salts medium; two of them were further characterized. The bacteria were facultatively anaerobic Gramnegative rods; metabolism was strictly oxidative with molecular oxygen, nitrate, or nitrite as electron acceptor. The isolates were tentatively identified as pseudomonads. Besides phenol many other benzene derivatives like cresols or aromatic acids were anaerobically oxidized in the presence of nitrate. While benzoate or 4-hydroxybenzoate was degraded both anaerobically and aerobically, phenol was oxidized under anaerobic conditions only. Reduced alicyclic compounds were not degraded. Preliminary evidence is presented that the first reaction in anaerobic phenol oxidation is phenol carboxylation to 4-hydroxybenzoate.     

一株耐高盐热带假丝酵母菌降解苯酚的研究

从含酚废水处理池污泥中驯化分离得到一株能以苯酚为唯一碳源的菌株FD-1。经18SrDNA和ITS序列的BLAST比对及系统发育分析,鉴定FD-1为热带假丝酵母(Candida tropicalis)的近缘种。FD-1对苯酚的降解能力较强,能够完全降解浓度为1 000mg·L-1的苯酚溶液。初步确定了FD-1在降解苯酚溶液时的最适温度为30~35℃,pH为6.0~7.0,并且通过探讨加入无机盐、培养基原料以及改变接种量三个因素对苯酚降解的影响,其耐受盐的浓度可达5%,对实践中应用微生物降解含酚废水具有积极的意义。     

Isolation of the <Emphasis Type="Italic">phe</Emphasis>-operon from <Emphasis Type="Italic">G. stearothermophilus</Emphasis> comprising the phenol degradative <Emphasis Type="Italic">meta</Emphasis>-pathway genes and a novel transcriptional regulator

Background  

Geobacillus stearothermophilus is able to utilize phenol as a sole carbon source. A DNA fragment encoding a phenol hydroxylase catalyzing the first step in the meta-pathway has been isolated previously. Based on these findings a PCR-based DNA walk was performed initially to isolate a catechol 2,3-dioxygenase for biosensoric applications but was continued to elucidate the organisation of the genes encoding the proteins for the metabolization of phenol.     

Metabolism of compounds with nitro-functions by Klebsiella pnuemoniae isolated from a regional wetland

Metabolism of nitroaromatic compounds by a Klebsiella pneumoniae isolated from a regional wetland was studied. When it was grown with nitrophenol as the sole nitrogen source, the isolate had the metabolic capability of transforming nitrophenol to phenol; however, it did not use nitrophenol as the sole carbon source. The metabolic pathway showed that the K. pneumoniae reduced the nitro group to an amino group forming aminophenol as a major metabolite. This aminophenol was oxidatively deaminated to phenol. For every mole of nitrophenol metabolized, 1 mol of phenol was produced and the phenol did not undergo further metabolism. The isolate also used several other nitroaromatic compounds including nitrotoluenes and nitrobenzenes as its nitrogen source. Even though this organism did not degrade the nitroaromatics completely, it may be useful in degrading nitroaromatics in contaminated soil and water containing other aromatic degraders in a syntrophic condition in nature.     

Metabolism of phenol,chloro- and nitrophenols by the Penicillium strain Bi 7/2 isolated from a contaminated soil

The Penicillium strain Bi 7/2 able to grow on phenol as sole source of carbon and energy was isolated from a contaminated soil in Bitterfeld (East Germany). The strain is adapted to high phenol concentrations. Spores germinated still at a phenol concentration of 1.5 g/l. Phenol is degraded by the ortho-pathway with catechol as first intermediary product. The Penicillium strain metabolizes 4-, 3- and 2-chlorophenol with decreasing rates with phenol or glucose as cosubstrate. In the case of 4-chlorophenol 4-chlorocatechol was detected as intermediary product, further degraded as indicated by release of about 35% of the bound chlorine of the aromatic molecule. The strain also cometabolically metabolizes 4-, 3- and 2-nitrophenol. The final product of 3- and 4-nitrophenol is 4-nitrocatechol.     

Bioremediation of phenol by alkaliphilic bacteria isolated from alkaline lake of Lonar, India

Phenol is an industrially important compound which has a wide range of applications. Being highly soluble in water, it appears as the major pollutant in waste waters arising from both phenol manufacturing and from industrial units that utilise phenol. Because of its toxicity, bioremediation of phenol is necessary. Since some of the phenol-bearing industrial waste waters are alkaline in nature, use of alkaliphilic bacteria for bioremediation of phenol was investigated. Alkaliphilic bacteria were isolated from sediments of an alkaline lake in Lonar, Dist. Buldhana, Maharashtra State, India, by phenol enrichment at pH 10.0 and phenol concentration of 500 mg/l. The lake (lat. 19°58'45", long. 76°34') is known to be a unique inland saline lake in Asia. It has a circular periphery and diameter of 2 km around the top of the banks and 1.2 km at the bottom. The lake has a high saline level (～ 2649 mg/l sodium chloride) and a high level of alkalinity (～ 2605 mg/l calcium carbonate). Alkaliphilic strains of Arthrobacter spp., Bacillus cereus, Citrobacter freundii, Micrococcus agilis and Pseudomonas putida biovar B were capable of removing phenol from waste waters arising from industries manufacturing methyl violet (using phenol as one of the major raw materials) and cumene-phenol. The waste waters from both these units were alkaline in nature (pH ～ 9.95-10.1) and had a high phenol content (368-660 mg/l). The alkaliphilic bacteria being studied removed 100% of the phenol from the industrial waste waters within 48 h of incubation under shake culture conditions and at an ambient temperature of 28 ± 2 °C. Bioremediation of phenol by alkaliphilic strains of Arthrobacter spp., B. cereus, C. freundii and M. agilis seems to be the first report.     

Proteomic insight into phenolic adaptation of a moderately halophilic Halomonas sp. strain AAD12

A gram-negative, moderately halophilic bacterium was isolated from ?amalt? Saltern area, located in the Aegean Region of Turkey. Analysis of its 16S rRNA gene sequence and physiological characteristics showed that this strain belonged to the genus Halomonas ; hence, it was designated as Halomonas sp. strain AAD12. The isolate tolerated up to 800 mg?L(-1) phenol; however, at elevated concentrations, phenol severely retarded cell growth. The increase in lag phase with increasing phenol concentrations indicated that the microorganism was undergoing serious adaptative changes. To understand the physiological responses of Halomonas sp. strain AAD12 to phenol, a 2-dimensional electrophoresis approach combined with mass spectrometric analysis was used. This approach showed that the expression of 14 protein spots were altered as phenol concentration increased from 200 to 800 mg?L(-1). Among the identified proteins were those involved in protein biosynthesis, energy, transport, and stress metabolism. So far, this is the first study on phenolic adaptation of a gram-negative, moderately halophilic bacteria using proteomic tools. The results provided new insights for understanding the general mechanism used by moderately halophilic bacteria to tolerate phenol and suggested the potential for using these microorganisms in bioremediation.     

Rhizoremediation of phenol and chromium by the synergistic combination of a native bacterial strain and Brassica napus hairy roots

A bacterial strain resistant to phenol and Cr (VI) was isolated from an industrial polluted soil of Córdoba province (Argentina), which was identified as Pantoea sp. FC 1. This microorganism was able to use phenol as sole carbon source. In addition it was capable of reducing Cr (VI) to Cr (III) in mineral and nutrient media. The isolated strain exhibited some properties as plant-growth promoting bacterium (PGPB), such as production of Indole Acetic Acid (IAA) and synthesis of siderophores, as well as being capable of solubilizing inorganic phosphates. A rhizoremediation system using the association Pantoea sp. FC 1-Brassica napus hairy roots (HRs) was tested for phenol and Cr (VI) removal in a hydroponic system. Microbial inoculation improved both phenol removal and chromium accumulation efficiency by HRs, showing a significant increase in Cr (III) accumulation compared to non-inoculated HRs, exceeding 1000 mg kg⁻¹. Cr (III) was detected in HR biomass and supernatants, suggesting a possible Cr (VI) reducing activity of B. napus HRs. Basic studies in plant model systems, such as HRs, provide additional useful information that could facilitate the transition of this technology into plants suitable for practical rhizoremediation applications.     

Isolation and Characterization of High-Strength Phenol-Degrading Novel Bacterium of the Pantoea Genus

A new indigenous soil bacterium Pantoea strain NII-153 utilizing phenol as a sole carbon source was isolated and characterized. Phylogenetic analysis suggested its classification to the Enterobacteriaceae family, with 95.0% gene sequence similarity to Pantoea ananatis ATCC 33244. Biodegradation rates of phenol by NII-153 were found to be more effective at 64 h with initial concentration of 600 mg L^{? 1} of phenol and this is the first report of such activity in Pantoea species. Strain NII-153 has showed high tolerance to phenol concentration (900 mg L^{? 1}). Therefore, strain NII-153 could be used for biotreatment of high-strength phenol-containing industrial effluents and for bioremediation of phenol-contaminated soils.     

Isolation and characterization of polyphenols-degrading bacteria from olive-mill wastewaters polluted soil

In this study 28 bacterial strains, isolated from greenwaters-polluted-soil, were investigated for their ability to grow in presence of phenols added to Mineral Basal Medium (MBM) in aerobic conditions. In particular, three of them were found to be able to use as sole carbon source phenol, cathecol, caffeic acid and ferulic acid with efficiency ranging from 76% (phenol in 5 days, millimolar concentration from 3.7 10^?2 to 9 10^?3) to 95% (ferulic acid in 2 days millimolar concentration from 6.8 10^?1 to 3 10^?2). For these strains the taxonomic position was studied by amplification and sequencing of 16S rRNA genes. The isolated strains were classified belonging to Arthrobacter sulfureus, Pseudomonas synxantha and Pseudomonas oryzihabitans. Noteworthy, for the first time such Pseudomonas strains have been shown to be able to use polyphenols as the only carbon source in vitro. In fact, to the best of our knowledge, this kind of study were not done on Ps. Synxantha, while it was recently shown the ability of P. oryzihabitans to degrade catechol. These findings may open to new biotechnological applications for the degradation of polyphenols.     

Synergistic relationships in algal-bacterial microcosms for the treatment of aromatic pollutants

The potential of algal-bacterial microcosms was studied for the biodegradation of salicylate, phenol and phenanthrene. The isolation and characterization of aerobic bacterial strains capable of mineralizing each pollutant were first conducted. Ralstonia basilensis was isolated for salicylate degradation, Acinetobacter haemolyticus for phenol and Pseudomonas migulae and Sphingomonas yanoikuyae for phenanthrene. The green alga Chlorella sorokiniana was then cultivated in the presence of the pollutants at different concentrations, showing increasing inhibitory effects in the following order: salicylate < phenol < phenanthrene. The synergistic relationships in the algal-bacterial microcosms were clearly demonstrated, since for the three contaminants tested, a substantial removal (>85%) was recorded only in the systems inoculated with both algae and bacteria and incubated under continuous lighting. This study presents, to our knowledge, the first reported case of photosynthesis-enhanced biodegradation of toxic aromatic pollutants by algal-bacterial microcosms in a one-stage treatment.     

Engineering of solvent-tolerant Pseudomonas putida S12 for bioproduction of phenol from glucose

Efficient bioconversion of glucose to phenol via the central metabolite tyrosine was achieved in the solvent-tolerant strain Pseudomonas putida S12. The tpl gene from Pantoea agglomerans, encoding tyrosine phenol lyase, was introduced into P. putida S12 to enable phenol production. Tyrosine availability was a bottleneck for efficient production. The production host was optimized by overexpressing the aroF-1 gene, which codes for the first enzyme in the tyrosine biosynthetic pathway, and by random mutagenesis procedures involving selection with the toxic antimetabolites m-fluoro-dl-phenylalanine and m-fluoro-l-tyrosine. High-throughput screening of analogue-resistant mutants obtained in this way yielded a P. putida S12 derivative capable of producing 1.5 mM phenol in a shake flask culture with a yield of 6.7% (mol/mol). In a fed-batch process, the productivity was limited by accumulation of 5 mM phenol in the medium. This toxicity was overcome by use of octanol as an extractant for phenol in a biphasic medium-octanol system. This approach resulted in accumulation of 58 mM phenol in the octanol phase, and there was a twofold increase in the overall production compared to a single-phase fed batch.     

Oxidation of phenol by Bacillus stearothermophilus strains]

The assimilation of phenol as a sole source of carbon and energy was studied with the thermophilic bacillus isolated from the geothermal zones in the South Ural. This ability was displayed by 11 strains of Bacillus stearothermophilus among 26 studied strains. The most active strains oxidized all phenol, when its content in the medium was 0.1--0.2%, during two days, at 56--58 degrees C, with aeration; a considerable amount of biomass was accumulated and the medium was acidified. The maximum concentration of phenol, which did not suppress the bacterial growth, was 0.3%. The majority of the strains of Bac. stearothermophilus capable of phenol oxidation were isolated from the regions heated with parothermal gases which contained phenols.     

Comparison between entrapment methods for phenol removal and operation of bioreactor packed with co-entrapped activated carbon and Pseudomonas fluorescence KNU417

A microorganism capable of degrading phenol was isolated from crude oil contaminated soil and identified as Pseudomonas fluorescence. A porous polymer bead of polyvinyl alcohol (PVA) and Xanthan gum was found to be the best entrapment for phenol degradation in terms of bead shape (spherical form), bead strength, non-agglomeration, phenol degradation rate, and cell holding inside the bead. Activated carbon was co-immobilized with the microorganism in the bead, which readily adsorbed phenol to decrease initial phenol concentration. Due to the decreased phenol concentration, the cells needed shorter adaptation time after which the microorganism stably degraded phenol. When the bead containing microorganism with 1% of activated carbon was packed in a packed-bed bioreactor, the start-up period was shortened by 40 h and the removal efficiency of phenol during the period was increased by 28% than the case with only microorganism.     

Extracellular degradation of phenol by the cyanobacterium Synechococcus PCC 7002

Investigations of the unicellular marine cyanobacterium Synechococcus PCC 7002 revealed its ability to metabolize phenol under non-photosynthetic conditions up to 100 mg L^–1. Under continuous light, photoautotrophic growth was reduced only slightly in the presence of this phenol concentration, but no transformation was observed. However neither under photoautotrophic nor heterotrophic conditions were the cells able to use phenol for growth. During the degradation of phenol in the dark cis,cis-muconic acid was produced as the major product, which was identified by gas chromatography/mass spectrometry. This result was confirmed by an identical absorption spectrum and an identical retention time in high performance liquid chromatographic analysis with authentic muconic acid as standard. This provides the first record for an ortho-fission of a phenolic substance by cyanobacteria. Further investigations of the breakdown mechanism of phenol have shown that the transformation is an extracellular process inhibited by heat, proteases and metal ions and is probably catalyzed by a protein.     

Growth of moderately halophilic bacteria isolated from sea water using phenol as the sole carbon source

Moderately halophilic bacteria utilizing phenol as the sole carbon source were isolated by selective enrichment from sea water. The isolate (Gram-negative motile rods) was identified asDeleya venusta. It grew well in the presence of up to 1600 mg/L of phenol and 8% NaCl under aerobic conditions. When the cells were treated with chloramphenicol prior to the addition of phenol they did not utilize added phenol, even after prolonged incubation. Thus, the enzymes necessary for phenol metabolism appeared to be inducible.     

Phenol degradation by yeasts isolated from industrial effluents

Yeast strains of the genera Aureobasidium, Rhodotorula and Trichosporon were isolated from stainless steel effluents and tested for their ability to utilize phenol as the sole carbon source. Fourteen strains grew in the presence of up to 10 mm phenol. Only the strain Trichosporon sp. LE3 was able to grow in the presence of up to 20 mm phenol. An inhibitory effect was observed at concentrations higher than 11 mm, resulting in reduction of specific growth rates. Phenol degradation was a function of strain, time of incubation and initial phenol concentration. All strains exhibited activity of catechol 1,2-dioxygenase and phenol hydroxylase in free cell extracts from cells grown on phenol, suggesting that catechol was oxidized by the ortho type of ring fission. Addition of glucose and benzoate reduced the phenol consumption rate, and both substrates were used simultaneously. Glucose concentrations higher than 0.25% inhibited the induction of phenol oxidation by non-proliferating cells and inhibited phenol oxidation by pre-induced cells.