Thiomonas Intermedia Research Articles

Characterization of sulfur oxidizing bacteria related to biogenic sulfuric acid corrosion in sludge digesters

BackgroundBiogenic sulfuric acid (BSA) corrosion damages sewerage and wastewater treatment facilities but is not well investigated in sludge digesters. Sulfur/sulfide oxidizing bacteria (SOB) oxidize sulfur compounds to sulfuric acid, inducing BSA corrosion. To obtain more information on BSA corrosion in sludge digesters, microbial communities from six different, BSA-damaged, digesters were analyzed using culture dependent methods and subsequent polymerase chain reaction denaturing gradient gel electrophoresis (PCR-DGGE). BSA production was determined in laboratory scale systems with mixed and pure cultures, and in-situ with concrete specimens from the digester headspace and sludge zones.ResultsThe SOB Acidithiobacillus thiooxidans, Thiomonas intermedia, and Thiomonas perometabolis were cultivated and compared to PCR-DGGE results, revealing the presence of additional acidophilic and neutrophilic SOB. Sulfate concentrations of 10–87 mmol/L after 6–21 days of incubation (final pH 1.0–2.0) in mixed cultures, and up to 433 mmol/L after 42 days (final pH <1.0) in pure A. thiooxidans cultures showed huge sulfuric acid production potentials. Additionally, elevated sulfate concentrations in the corroded concrete of the digester headspace in contrast to the concrete of the sludge zone indicated biological sulfur/sulfide oxidation.ConclusionsThe presence of SOB and confirmation of their sulfuric acid production under laboratory conditions reveal that these organisms might contribute to BSA corrosion within sludge digesters. Elevated sulfate concentrations on the corroded concrete wall in the digester headspace (compared to the sludge zone) further indicate biological sulfur/sulfide oxidation in-situ. For the first time, SOB presence and activity is directly relatable to BSA corrosion in sludge digesters.

Monitoring sulfide-oxidizing biofilm activity on cement surfaces using non-invasive self-referencing microsensors

Microbially influenced corrosion (MIC) in concrete results in significant cost for infrastructure maintenance. Prior studies have employed molecular techniques to identify microbial community species in corroded concrete, but failed to explore bacterial activity and functionality during deterioration. In this study, biofilms of different sulfur-oxidizing bacteria compositions were developed on the surface of cement paste samples to simulate the natural ecological succession of microbial communities during MIC processes. Noninvasive, self-referencing (SR) microsensors were used to quantify real time changes of oxygen, hydrogen ion and calcium ion flux for the biofilm to provide more information about bacterial behavior during deterioration. Results showed higher transport rates in oxygen consumption, and hydrogen ion at 4 weeks than 2 weeks, indicating increased bacterial activity over time. Samples with five species biofilm had the highest hydrogen ion and calcium ion transport rates, confirming attribution of acidophilic sulfur-oxidizing microorganisms (ASOM). Differences in transport rates between three species samples and two species samples confirmed the diversity between Thiomonas intermedia and Starkeya novella. The limitations of SR sensors in corrosion application could be improved in future studies when combined with molecular techniques to identify the roles of major bacterial species in the deterioration process.

Revealing biogenic sulfuric acid corrosion in sludge digesters: detection of sulfur-oxidizing bacteria within full-scale digesters.

Biogenic sulfuric acid corrosion (BSA) is a costly problem affecting both sewerage infrastructure and sludge handling facilities such as digesters. The aim of this study was to verify BSA in full-scale digesters by identifying the microorganisms involved in the concrete corrosion process, that is, sulfate-reducing (SRB) and sulfur-oxidizing bacteria (SOB). To investigate the SRB and SOB communities, digester sludge and biofilm samples were collected. SRB diversity within digester sludge was studied by applying polymerase chain reaction-denaturing gradient gel electrophoresis (PCR-DGGE) targeting the dsrB-gene (dissimilatory sulfite reductase beta subunit). To reveal SOB diversity, cultivation dependent and independent techniques were applied. The SRB diversity studies revealed different uncultured SRB, confirming SRB activity and H2S production. Comparable DGGE profiles were obtained from the different sludges, demonstrating the presence of similar SRB species. By cultivation, three pure SOB strains from the digester headspace were obtained including Acidithiobacillus thiooxidans, Thiomonas intermedia and Thiomonas perometabolis. These organisms were also detected with PCR-DGGE in addition to two new SOB: Thiobacillus thioparus and Paracoccus solventivorans. The SRB and SOB responsible for BSA were identified within five different digesters, demonstrating that BSA is a problem occurring not only in sewer systems but also in sludge digesters. In addition, the presence of different SOB species was successfully associated with the progression of microbial corrosion.

Biocatalytic Hydrogen Sulphide Removal from Gaseous Streams

Hydrogen sulphide is one of the most important substances responsible for unpleasant odour emissions in gas phase. It is often formed in higher concentration beyond other sulphur containing volatile compounds like methane thiol (MT), dimethyl sulphide (DMS) and dimethyl disulphide (DMDS). Removal of hydrogen sulphide is usually carried out by physical-chemical methods (e.g. adsorption), but nowadays some bio-processes may be considered as promising alternatives. Certain sulphur oxidising thiobacteria can be successfully applied for hydrogen sulphide conversion from gaseous streams like biogas. Various strains have been applied so far for degradation of hydrogen sulphide, they belong mostly to the group of Thiobacillus, which are autotrophic microorganisms. These autotrophic bacteria have the drawback in application that they grow slower than the heterotrophic ones and it is more difficult to control their growth. A number of chemotrophs are suitable for the biodegradation of H2S. These bacteria grow and produce new cell material by using inorganic carbon (CO2) as a carbon source and chemical energy from the oxidation of reduced inorganic compounds such as H2S.The objective of the work described here was to study the ability of elimination of hydrogen sulphide by two chemotrophic microorganisms (Thiomonas intermedia, Thiobacillus thioparus) in a batch bioreactor. The other aim was the study of the immobilization of these bacteria to different supports.

Microbial mediated deterioration of reinforced concrete structures

Biogenic sulfuric acid corrosion is often a problem in sewer pipelines, compromising the structural integrity by degrading the pipeline’s concrete components. We investigated the microbial populations in deteriorated bridge concrete, with samples taken from bridge concrete both above the water level and in adjacent soils. Total counts of microbial cells indicated a range of 5.3 ± 0.9 × 10 6 to 3.6 ± 0.3 × 10 7 per gram of concrete. These values represent the range from slightly to severely deteriorated concrete. From severely deteriorated concrete samples, we successfully enriched and isolated one sulfur-oxidizing bacterium, designated strain CBC3. This strain exhibited strong acid-producing properties. The pH of the pure culture of CBC3 reached as low as 2.0 when thiosulfate was used as the sole energy source. 16S rDNA sequence analysis revealed that the isolated strain CBC3 was close to members of Thiomonas perometablis with 99.3% identity. Fluorescent In Situ Hybridization (FISH) analysis of significant numbers of sulfur-oxidizing bacteria from deteriorated concrete indicated that T. perometablis was the dominant acidophilic bacterium, comprising 32.0% of the total active bacteria in the severely deteriorated concrete. Semi-continuous cultures of T. perometablis CBC3 and Thiomonas intermedia were used to evaluate the biodegradation of cement samples. A weight loss of up to 5.7% was observed after 3 months, compared with a weight loss of 0.3% in non-inoculated control.

Succession of Sulfur-Oxidizing Bacteria in the Microbial Community on Corroding Concrete in Sewer Systems

Microbially induced concrete corrosion (MICC) in sewer systems has been a serious problem for a long time. A better understanding of the succession of microbial community members responsible for the production of sulfuric acid is essential for the efficient control of MICC. In this study, the succession of sulfur-oxidizing bacteria (SOB) in the bacterial community on corroding concrete in a sewer system in situ was investigated over 1 year by culture-independent 16S rRNA gene-based molecular techniques. Results revealed that at least six phylotypes of SOB species were involved in the MICC process, and the predominant SOB species shifted in the following order: Thiothrix sp., Thiobacillus plumbophilus, Thiomonas intermedia, Halothiobacillus neapolitanus, Acidiphilium acidophilum, and Acidithiobacillus thiooxidans. A. thiooxidans, a hyperacidophilic SOB, was the most dominant (accounting for 70% of EUB338-mixed probe-hybridized cells) in the heavily corroded concrete after 1 year. This succession of SOB species could be dependent on the pH of the concrete surface as well as on trophic properties (e.g., autotrophic or mixotrophic) and on the ability of the SOB to utilize different sulfur compounds (e.g., H2S, S0, and S2O3(2-)). In addition, diverse heterotrophic bacterial species (e.g., halo-tolerant, neutrophilic, and acidophilic bacteria) were associated with these SOB. The microbial succession of these microorganisms was involved in the colonization of the concrete and the production of sulfuric acid. Furthermore, the vertical distribution of microbial community members revealed that A. thiooxidans was the most dominant throughout the heavily corroded concrete (gypsum) layer and that A. thiooxidans was most abundant at the highest surface (1.5-mm) layer and decreased logarithmically with depth because of oxygen and H2S transport limitations. This suggested that the production of sulfuric acid by A. thiooxidans occurred mainly on the concrete surface and the sulfuric acid produced penetrated through the corroded concrete layer and reacted with the sound concrete below.

Isolation and characterization of sulphur-oxidizing Thiomonas sp. and its potential application in biological deodorization

To isolate and characterize a sulphur-oxidizing bacterial strain from activated sludge and to evaluate its potential application in biological deodorization. A dominant sulphur-oxidizing bacterial strain, designated as strain SS, was isolated from an enrichment culture using thiosulphate as a sole energy source and CO2 as a sole carbon source. The cells of this organism were aerobic, rod-shaped, Gram-negative and motile. Strain SS could grow autotrophically, heterotrophically as well as mixotrophically. Autotrophic growth was observed at pH values ranging from 2.3 to 9.0. Phylogenetic analyses revealed that strain SS belonged to Group 1 of the genus Thiomonas, closely related to Thiomonas perometabolis and Thiomonas intermedia. The thiosulphate oxidation rates of strain SS at different pH values were evaluated in terms of oxygen uptake using a Micro-Oxymax respirometer. The results showed that the maximum oxidation rate of 5.65 mg l(-1) h(-1) occurred at 56 h of growth and pH 6.0. Continuous H2S removal study demonstrated that strain SS could remove more than 99% of H2S when the inlet concentration was below 58.6 ppm. Further increase of the inlet concentration to 118 ppm gave rise to a decline in the removal efficiency to ca 90%. The strong acidification of the culture medium during the later period could result in the deterioration of the growth activity and the metabolism activity of strain SS. In practical application, the problems caused by the end-product inhibition and the acidification can be alleviated by periodical replacement of culture medium with fresh medium. Given the physiological flexibility and the ability to remove H2S rapidly and efficiently, strain SS could be a good 'deodorizing' candidate. This is the first time that Thiomonas species has been reported for biological deodorization application.

Carboxysome genomics: a status report.

Carboxysomes, microcompartments that enhance the fixation of carbon dioxide by Rubisco, are found in several chemoautotrophs and in all cyanobacteria thus far examined. The genes for Rubisco large (cbbL) and small (cbbS) subunits (cbb for Calvin-Benson-Bassham), along with the genes (csoS) for the carboxysome shell peptides, are organized in a putative operon in Halothiobacillus neapolitanus in the following order: cbbL,cbbS, csoS2, csoS3, orfA, orfB, csoS1C, csoS1A, and csoS1B. DNA sequencing has revealed essentially the same operon in three other thiobacilli, Acidithiobacillus ferrooxidans, Thiomonas intermedia, and Thiobacillus denitrificans. The carboxysome genes are also clustered inSynechococcus sp. and Synechocystis sp., although in some cases certain genes lie outside the cluster. The genes, labelled ccm for CO2 concentrating mechanism, exist in Synechococcus PCC7942 in the order ccmK, ccmL, ccmM, ccmN, and ccmO, and are located upstream of the Rubisco genes. ccmO is absent, and multiple copies of ccmK exist in some species. The ccmK/ccmO and ccmL genes are homologues of csoS1CAB andorfAB, respectively. The ccmM and ccmN genes have no apparent counterpart in the thiobacilli. More recently, the genome sequence of four additional cyanobacteria has become available. The carboxysome genes in Nostoc punctiforme are clustered like, and are similar to, the genes of the earlier mentioned cyanobacteria. However, the three marine organisms Prochlorococcus marinus MIT9313, P. marinus MED4, and Synechococcus WH8102, possess an operon nearly identical to that found in thiobacilli. Furthermore, the genes exhibit surprising sequence identity to the carboxysome genes of the thiobacilli.