Presence of potentially pathogenic heterotrophic plate count (HPC) bacteria occurring in a drinking water distribution system in the North-West Province, South Africa / by Leandra Venter

Venter, Leandra

January 2010

There is currently growing concern about the presence of heterotrophic plate count (HPC) bacteria in drinking water. These HPC may have potential pathogenic features, enabling them to cause disease. It is especially alarming amongst individuals with a weakened immune system. South Africa, the country with the highest incidents of HIV positive individuals in the world, mainly uses these counts to assess the quality of drinking water in terms of the number of micro-organisms present in the water. These micro-organisms may be present in the bulk water or as biofilms adhered to the surfaces of a drinking water distribution system. The current study investigated the pathogenic potential of HPC bacteria occurring as biofilms within a drinking water distribution system and determined the possible presence of these micro-organims within the bulk water. Biofilm samples were taken from five sites within a drinking water distribution system. Fifty six bacterial colonies were selected based on morphotypes and isolated for the screening of potential pathogenic features. Haemolysin production was tested for using sheep-blood agar plates. Of the 56, 31 isolates were ?-haemolytic. Among the 31 ?-haemolytic positive isolates 87.1% were positive for lecithinase, 41.9% for proteinase, 19.4% for chondroitinase, 9.7% for DNase and 6.5% for hyaluronidase. All of the ?-haemolytic isolates were resistant to oxytetracycline 30 ?g, trimethoprim 2.5 ?g and penicillin G10 units, 96.8% were resistant to vancomycin 30 ?g and ampicillin 10 ?g, 93.5% to kanamycin 30 ?g, 74.2% to chloramphenicol 30 ?g, 54.8% to ciprofloxacin 5 ?g, 22.6% to streptomycin 300 ?g and 16.1% to erythromycin 15 ?g. Nineteen isolates producing two or more enzymes were subjected to Gram staining. The nineteen isolates were all Gram-positive. These isolates were then identified using the BD BBL CRYSTALTM Gram-positive (GP) identification (ID) system. Isolates were identified as Bacillus cereus, Bacillus licheniformis, Bacillus subtilis, Bacillus megaterium, Bacillus pumilus and Kocuria rosea. 16S rRNA gene sequencing was performed to confirm these results and to obtain identifications for the bacteria not identified with the BD BBL CRYSTALTM GP ID system. Additionally identified bacteria included Bacillus thuringiensis, Arthrobacter oxydans and Exiguobacterium acetylicum. Morphological properties of the different species were studied with transmission electron microscopy (TEM) to confirm sequencing results. All the isolates displayed rod shaped cells with the exception of Arthrobacter oxydans being spherical in the stationary phase of their life cycle. Bulk water samples were taken at two sites in close proximity with the biofilm sampling sites. The DNA was extracted directly from the water samples and the 16S rRNA gene region was amplified. Denaturing gradient gel electrophoresis (DGGE) was performed to confirm the presence of the isolates from the biofilm samples in the bulk water samples. The presence of Bacillus pumilus and Arthrobacter oxydans could be confirmed with DGGE. This study demonstrated the presence of potentially pathogenic HPC bacteria within biofilms in a drinking water distribution system. It also confirmed the probable presence of two of these biofilm based bacteria in the bulk water. / Thesis (M.Sc. (Microbiology))--North-West University, Potchefstroom Campus, 2010.

Biofilms

HPC

Drinking water distribution system

DGGE

Denaturing gradient gel electrophoresis

Functional and structural diversity of the microbial communities associated with the use of Fischer–Tropsch GTL Primary Column Bottoms as process cooling water / van Niekerk B.F.

Van Niekerk, Bertina Freda

January 2011

Despite emerging water shortages, most water is only used once, and often with low efficiency. However, with appropriate treatment, water can be re–used to reduce the demand on freshwater sources. The Department of Water Affairs, South Africa, promotes industries to reduce discharges into water resources in order to sustain an overall good water quality of all water systems. All of this ultimately leads to industries striving towards zero effluent discharge. Primary Column Bottoms (PCBs) is a wastewater stream derived from the Fischer–Tropsch Gas to Liquid process and consists mainly of organic acids, but no nitrogen or phosphorous, which by implication excludes possible biodegradation. In the operation of cooling towers in industrial processes, cooling water quality has a direct impact on the cooling performance of the system, where nutrient levels may affect fouling, scaling and corrosion observed in the cooling towers. Fouling, scaling and corrosion affect the operating efficiency of cooling water systems and may necessitate the addition of chemical agents to control these phenomena. This has a financial and labour time impact on the operation of these systems. In this study a mini cooling tower test rig was operated with a synthetic PCB effluent as cooling water and various cycles of concentration, pH and linear flow velocities (LFVs). A constant delta temperature of 10 °C was maintained. Cycles of concentration (COC) evaluated included 2, 4 and 6 cycles of concentration and linear flow velocities evaluated was 0.6 m/s, 0.9 m/s and 1.2 m/s. Fouling, scaling and corrosion rates were determined using corrosion coupons and heat exchanger tubes for mild steel and stainless steel. Besides the evaluation of the various operational parameters for fouling, scaling and corrosion, the possibility for chemical oxygen demand (COD) removal by operating the cooling tower as a bioreactor was also evaluated. To this end nutrient correction was applied to the reactor to allow for a CNP ratio of 100:10:1. With regard to fouling, scaling and corrosion, mild steel was more affected by fouling, scaling and corrosion compared to stainless steel where almost no fouling, scaling and corrosion was observed. Overall increased linear flow velocities resulted in higher fouling and scaling rates, whereas lower linear flow velocities resulted in decreased corrosion rates. In terms of cycles of concentration, increased COC resulted in higher fouling, scaling and corrosion rates. Despite the high nutrient removal levels, the accompanying fouling, scaling and corrosion was still below the particular industry’s guidelines. Besides physical–chemical evaluation of the towers under the various operational conditions, culture–dependent and culture–independent methods were also employed. Concerning culture–dependent approaches the study demonstrated that aerobic and anaerobic organisms are present in both the planktonic and sessile phase of the cooling tower reactors. Heterotrophic aerobes were found to be the most abundant under all the operating conditions. Sulphate reducing bacteria were more abundant in the sessile phase of the cooling towers, and the presence of high sulphate levels in the experiments could be indicative of the sulphate reducing bacteria actively participating in the microbial community. Lower than expected corrosion levels, however, suggest that a combination of the organisms in the biofilm rather than sulphate reducing bacteria alone, contributed to the corrosion rates observed. Culture–independent methods, specifically phospholipid fatty acid analysis supported the results from the culture–dependent methods. Furthermore results demonstrated that linear flow velocity had a greater effect on the community structure than cycles of concentration. Finally molecular methods, specifically denaturing gradient gel electrophoresis, found that increasing cycles of concentration resulted in increased microbial community diversity, while increasing linear flow velocity resulted in decreased microbial community diversity. Regarding COD removal, nutrient correction of the synthetic PCB effluent achieved 89.35 % COD removal at 2 COC and 1.2 m/s LFV, while 80.85 % COD removal was achieved at 4 COC at 1.2 m/s LFV. From these results it was recommended that the operation of the cooling tower should be at 4 COC and 1.2 m/s, which despite slightly lower % COD removal, were characterised by fouling, scaling and corrosion rates well within guidelines. / Thesis (M. Environmental Science)--North-West University, Potchefstroom Campus, 2012.

Cooling towers

Bioreactor

Fouling

Scaling

Corrosion

Denaturing gradient gel electrophoresis

Phospholipid fatty acid analysis

Presence of potentially pathogenic heterotrophic plate count (HPC) bacteria occurring in a drinking water distribution system in the North-West Province, South Africa / by Leandra Venter

Venter, Leandra

January 2010

There is currently growing concern about the presence of heterotrophic plate count (HPC) bacteria in drinking water. These HPC may have potential pathogenic features, enabling them to cause disease. It is especially alarming amongst individuals with a weakened immune system. South Africa, the country with the highest incidents of HIV positive individuals in the world, mainly uses these counts to assess the quality of drinking water in terms of the number of micro-organisms present in the water. These micro-organisms may be present in the bulk water or as biofilms adhered to the surfaces of a drinking water distribution system. The current study investigated the pathogenic potential of HPC bacteria occurring as biofilms within a drinking water distribution system and determined the possible presence of these micro-organims within the bulk water. Biofilm samples were taken from five sites within a drinking water distribution system. Fifty six bacterial colonies were selected based on morphotypes and isolated for the screening of potential pathogenic features. Haemolysin production was tested for using sheep-blood agar plates. Of the 56, 31 isolates were ?-haemolytic. Among the 31 ?-haemolytic positive isolates 87.1% were positive for lecithinase, 41.9% for proteinase, 19.4% for chondroitinase, 9.7% for DNase and 6.5% for hyaluronidase. All of the ?-haemolytic isolates were resistant to oxytetracycline 30 ?g, trimethoprim 2.5 ?g and penicillin G10 units, 96.8% were resistant to vancomycin 30 ?g and ampicillin 10 ?g, 93.5% to kanamycin 30 ?g, 74.2% to chloramphenicol 30 ?g, 54.8% to ciprofloxacin 5 ?g, 22.6% to streptomycin 300 ?g and 16.1% to erythromycin 15 ?g. Nineteen isolates producing two or more enzymes were subjected to Gram staining. The nineteen isolates were all Gram-positive. These isolates were then identified using the BD BBL CRYSTALTM Gram-positive (GP) identification (ID) system. Isolates were identified as Bacillus cereus, Bacillus licheniformis, Bacillus subtilis, Bacillus megaterium, Bacillus pumilus and Kocuria rosea. 16S rRNA gene sequencing was performed to confirm these results and to obtain identifications for the bacteria not identified with the BD BBL CRYSTALTM GP ID system. Additionally identified bacteria included Bacillus thuringiensis, Arthrobacter oxydans and Exiguobacterium acetylicum. Morphological properties of the different species were studied with transmission electron microscopy (TEM) to confirm sequencing results. All the isolates displayed rod shaped cells with the exception of Arthrobacter oxydans being spherical in the stationary phase of their life cycle. Bulk water samples were taken at two sites in close proximity with the biofilm sampling sites. The DNA was extracted directly from the water samples and the 16S rRNA gene region was amplified. Denaturing gradient gel electrophoresis (DGGE) was performed to confirm the presence of the isolates from the biofilm samples in the bulk water samples. The presence of Bacillus pumilus and Arthrobacter oxydans could be confirmed with DGGE. This study demonstrated the presence of potentially pathogenic HPC bacteria within biofilms in a drinking water distribution system. It also confirmed the probable presence of two of these biofilm based bacteria in the bulk water. / Thesis (M.Sc. (Microbiology))--North-West University, Potchefstroom Campus, 2010.

Biofilms

HPC

Drinking water distribution system

DGGE

Denaturing gradient gel electrophoresis

Functional and structural diversity of the microbial communities associated with the use of Fischer–Tropsch GTL Primary Column Bottoms as process cooling water / van Niekerk B.F.

Van Niekerk, Bertina Freda

January 2011

Despite emerging water shortages, most water is only used once, and often with low efficiency. However, with appropriate treatment, water can be re–used to reduce the demand on freshwater sources. The Department of Water Affairs, South Africa, promotes industries to reduce discharges into water resources in order to sustain an overall good water quality of all water systems. All of this ultimately leads to industries striving towards zero effluent discharge. Primary Column Bottoms (PCBs) is a wastewater stream derived from the Fischer–Tropsch Gas to Liquid process and consists mainly of organic acids, but no nitrogen or phosphorous, which by implication excludes possible biodegradation. In the operation of cooling towers in industrial processes, cooling water quality has a direct impact on the cooling performance of the system, where nutrient levels may affect fouling, scaling and corrosion observed in the cooling towers. Fouling, scaling and corrosion affect the operating efficiency of cooling water systems and may necessitate the addition of chemical agents to control these phenomena. This has a financial and labour time impact on the operation of these systems. In this study a mini cooling tower test rig was operated with a synthetic PCB effluent as cooling water and various cycles of concentration, pH and linear flow velocities (LFVs). A constant delta temperature of 10 °C was maintained. Cycles of concentration (COC) evaluated included 2, 4 and 6 cycles of concentration and linear flow velocities evaluated was 0.6 m/s, 0.9 m/s and 1.2 m/s. Fouling, scaling and corrosion rates were determined using corrosion coupons and heat exchanger tubes for mild steel and stainless steel. Besides the evaluation of the various operational parameters for fouling, scaling and corrosion, the possibility for chemical oxygen demand (COD) removal by operating the cooling tower as a bioreactor was also evaluated. To this end nutrient correction was applied to the reactor to allow for a CNP ratio of 100:10:1. With regard to fouling, scaling and corrosion, mild steel was more affected by fouling, scaling and corrosion compared to stainless steel where almost no fouling, scaling and corrosion was observed. Overall increased linear flow velocities resulted in higher fouling and scaling rates, whereas lower linear flow velocities resulted in decreased corrosion rates. In terms of cycles of concentration, increased COC resulted in higher fouling, scaling and corrosion rates. Despite the high nutrient removal levels, the accompanying fouling, scaling and corrosion was still below the particular industry’s guidelines. Besides physical–chemical evaluation of the towers under the various operational conditions, culture–dependent and culture–independent methods were also employed. Concerning culture–dependent approaches the study demonstrated that aerobic and anaerobic organisms are present in both the planktonic and sessile phase of the cooling tower reactors. Heterotrophic aerobes were found to be the most abundant under all the operating conditions. Sulphate reducing bacteria were more abundant in the sessile phase of the cooling towers, and the presence of high sulphate levels in the experiments could be indicative of the sulphate reducing bacteria actively participating in the microbial community. Lower than expected corrosion levels, however, suggest that a combination of the organisms in the biofilm rather than sulphate reducing bacteria alone, contributed to the corrosion rates observed. Culture–independent methods, specifically phospholipid fatty acid analysis supported the results from the culture–dependent methods. Furthermore results demonstrated that linear flow velocity had a greater effect on the community structure than cycles of concentration. Finally molecular methods, specifically denaturing gradient gel electrophoresis, found that increasing cycles of concentration resulted in increased microbial community diversity, while increasing linear flow velocity resulted in decreased microbial community diversity. Regarding COD removal, nutrient correction of the synthetic PCB effluent achieved 89.35 % COD removal at 2 COC and 1.2 m/s LFV, while 80.85 % COD removal was achieved at 4 COC at 1.2 m/s LFV. From these results it was recommended that the operation of the cooling tower should be at 4 COC and 1.2 m/s, which despite slightly lower % COD removal, were characterised by fouling, scaling and corrosion rates well within guidelines. / Thesis (M. Environmental Science)--North-West University, Potchefstroom Campus, 2012.

Cooling towers

Bioreactor

Fouling

Scaling

Corrosion

Denaturing gradient gel electrophoresis

Phospholipid fatty acid analysis

Diversity and Distribution of Diatom Endosymbionts in <i>Amphistegina</i> spp. (Foraminifera) Based on Molecular and Morphological Techniques

Barnes, Kwasi H.

28 June 2016

Diatoms associated with foraminifers of the genus Amphistegina were assessed using a combination of morphological and molecular techniques. These included: 1) microscopic identification of diatoms cultured from the host, 2) sequencing of portions of the small subunit of the ribosomal RNA gene (18S) and the large subunit of the ribulose-1,5-bisphosphate carboxylase/oxygenase [i.e., RubisCO] gene (rbcL) from DNA extracted directly from the Amphistegina hosts and also from diatoms cultured from these hosts, and 3) denaturing gradient gel electrophoresis (DGGE) profiles of rbcL and internal transcribed spacer 1 (ITS1) PCR amplicons from DNA extracted directly from hosts and from cultures. Consistent with previous culture studies, multiple species of pennate diatoms of the genera Nitzschia, Fragilaria (including Nanofrustulum), Amphora, and Navicula, were cultured from >900 host specimens collected from >20 sites in the western Atlantic and four sites in the Pacific. Diatoms of the genus Nitzschia grew in about half of all successful cultures. The genetic identities of selected cultures were consistent with those based on morphological taxonomy. Diatom sequences from DNA extracted directly from the cytoplasm of the Amphistegina hosts were species specific and distinct from sequences obtained from cultured diatoms and from sequences in GenBank of diatom taxa previously reported as endosymbionts. Multiple phylogenetic analyses revealed that the 18S and rbcL diatom sequences from specimens of A. gibbosa collected from the Atlantic sites and of Amphistegina spp. from Hawai’i were most similar to the 18S and rbcL sequences of an unnamed Fragilariaceae diatom in GenBank (Accession # JX413542.1 for 18S and JX413559.1 for rbcL) and other closely related diatoms in that family. Of diatom taxa previously reported as endosymbionts of larger foraminifers, Nanofrustulum shiloi was the most similar, but not identical, to the sequences from hosts collected from the Atlantic and Hawai’i. The 18S and rbcL diatom sequences from the Atlantic host species, A. gibbosa, were all nearly identical, but small intra-species differences (subclades) were observed from specimens collected from the deepest (75 m) site in the Florida Keys and also from the eastern-most site, Young Island near St. Vincent. The 18S and rbcL diatom sequences from the two host species from Hawai’i, A. lobifera and A. lessonii, were more variable but still within the family Fragilariaceae. The diatom sequences from A. radiata collected from two sites in Papua New Guinea (PNG) were most similar to diatoms of the family Plagiogrammaceae and therefore distinct from sequences obtained from other Amphistegina species in this study, as well as from all diatoms previously reported as endosymbionts. A small difference was observed between the diatom sequences from host specimens collected from a Pacific site as compared to a Bismarck Sea site. The ITS1 DGGE profiles of DNA extracted directly from A. gibbosa specimens at different depths, locations, and seasons in the western Atlantic were nearly identical. Differences were seen between rbcL DGGE profiles of DNA extracted directly from the different Amphistegina host species. The rbcL DGGE profiles directly from all hosts were clearly different from those extracted from diatoms cultured from the same host specimens, as well as from Nitzschia laevis, a commonly reported diatom endosymbiont in past culture-based studies. My findings are consistent with ultrastructural studies of endosymbionts of Amphistegina published in the early 1980s and congruent with recent molecular studies of endosymbionts in other diatom-bearing foraminifers, all of which indicate specificity. Nevertheless, the consistency with which several diatom taxa have been reported in culture studies from all oceans indicates the possibility of some relationship with Amphistegina spp., either as important food items, epiphytes, or minor opportunistic symbionts that can thrive in culture media.

DNA Extraction

Sequencing

Denaturing Gradient Gel Electrophoresis

Symbiosis

Phylogenetics

Bioinformatics

Aquaculture and Fisheries

Genetics

Systems Biology

Denaturing gradient gel electrophoresis characterisation of microbial communities in polycyclic aromatic hydrocarbon and polychlorinated biphenyl contaminated soil

Surridge, Angela Karen Joanna

28 May 2007

Fossil fuels are currently the primary industrial energy source on Earth. They are principally composed of complex hydrocarbons in either long-chain or cyclic conformation. Industrial use of petroleum, diesel, oil, tar and other coal-derived products inevitably leads to pollution of the environment. The most serious pollution is caused by polycyclic aromatic hydrocarbons (PAHs) and polychlorinated biphenyls (PCBs) that are not easily removed from soil after a spill. Long-chain and cyclic conformation makes fossil fuel hydrocarbons difficult to break down. However, certain free-living soil microorganisms have adapted to utilising these PAHs/PCBs as a source of energy. In many cases, their efficacy is greatly enhanced by the presence of plants. By inhabiting the rhizosphere, microbes form a mutualistic relationship with the plant, receiving nutrients from it and in return providing a less polluted environment in which the plant can grow. The purpose of this study was to elucidate some of the microbial population diversity in PAH/PCB-polluted soils in South Africa through the use of denaturing gradient gel electrophoresis (DGGE). In an initial study, DGGE was employed to separate soil communities in polluted and unpolluted soils into a genetic fingerprint, the main bands of which were sequenced and subjected to a BLAST analysis through a database for possible identification of species present. Phylogenetic and distance studies indicated that unpolluted soils have a far greater species diversity. It thus was evident that PAH/PCB pollution of soil leads to a decrease in microbial diversity by selecting for microorganisms with the ability to activate metabolic pathways allowing them to utilise the pollutants as an alternative source of carbon. Population diversity of pro- and eukaryotes found within polluted and non-polluted soils was compared. DGGE was employed to determine the genetic fingerprint of each population. Following this, dendogram analyses based on Shannon indices were done to determine PAH breakdown potential of prokaryotic vs. eukaryotic communities. A higher diversity and better adaptation potential were evident within prokaryotic than eukaryotic communities in pollution-stressed environments, indicating that the prokaryotic component of these samples had the greatest PAH-metabolism potential. To determine the capacity for PAH/PCB metabolism by the organisms within the soil samples being studied, the presence of xylE and ndoB genes, responsible for toluene/xylene and naphthalene biodegradation, respectively, was determined. DGGE was performed to analyse genetic diversity between these two genes, based on community fingerprints. Polluted soil communities tended to have comparable community diversity within their functional genes, depending on their physical situation, plant species proximity and soil conditions. In general, soil contained indigenous microbes with a high natural potential for biodegradation of PAHs/PCBs. A portion of the 16S gene of eight bacterial isolates representing the most dominant culturable taxa in the polluted soils was sequenced and analysed for identification purposes. These identifications were conducted in conjunction with the use of the catabolic gene probes xylE and ndoB to establish the hydrocarbon degrading capacity of the isolates. Pseudomonas, from the rhizosphere of Cyperus esculentus, was the most common PAH-degrading genus found in this study. Considering the well-established rhizosphere competence and PAH-degrading capacity of Pseudomonas, this genus seems to be the best suited for bioaugmentation purposes in South Africa. The presence of the nifH gene, the general marker gene of nitrogen-fixing bacteria in communities from unpolluted and polluted soils, was determined. It was hypothesised that bioremediation could be enhanced by nitrogen addition to polluted environments. Nested-PCR of the nifH gene was conducted on a diagnostic basis and was followed by DGGE of the product to determine the functional gene diversity within pollution-dwelling, nitrogen-fixing bacterial communities. Nitrogen-fixing microorganisms were present in all the soils sampled but, in only 80% of the pure cultures isolated from polluted and unpolluted soils and rhizospheres. Although different rhizospheres and pollutants were examined, it was found that of the polluted soils studied, most nifH gene diversity of polluted soils existed within machinery oil polluted, wood chip mulched, non-rhizosphere soil. Thus, it would appear that the more polluted the soil the higher the free microbe nitrogen fixation diversity possibly due to environmental stress. / Thesis (PhD (Microbiology))--University of Pretoria, 2007. / Microbiology and Plant Pathology / unrestricted

Characterisation

Communities

Aromatic

Polycyclic

Electrophoresis

Hydrocarbon

Polychlorinate

Biphenyl

Contaminated soil

Microbial

Denaturing

Gradient gel

UCTD

Actinobacterial diversity of the Ethiopian Rift Valley lakes

Du Plessis, Gerda

January 2011

>Magister Scientiae - MSc / The class Actinobacteria consists of a heterogeneous group of filamentous, Gram-positive bacteria that colonise most terrestrial and aquatic environments. The industrial and biotechnological importance of the secondary metabolites produced by members of this class has propelled it into the forefront of metagenomics studies. The Ethiopian Rift Valley lakes are characterized by several physical extremes, making it a polyextremophilic environment and a possible untapped source of novel actinobacterial species. The aims of the current study were to identify and compare the eubacterial diversity between three geographically divided soda lakes within the ERV focusing on the actinobacterial subpopulation. This was done by means of a culture-dependent (classical culturing) and culture-independent (DGGE and ARDRA) approach. The results indicate that the eubacterial 16S rRNA gene libraries were similar in composition with a predominance of α-Proteobacteria and Firmicutes in all three lakes. Conversely, the actinobacterial 16S rRNA gene libraries were significantly different and could be used to distinguish between sites. The actinobacterial OTUs detected belonged to both the Rubrobacterales and Actinomycetales orders with members of the genus Arthrobacter being found in all three lakes. Geochemical properties were significantly different between the lakes, although more than one property attributed to the variance between community compositions. The diversity detected in the culture-based study differed significantly and all isolates belonged to the genus Streptomyces. Two novel strains were characterized by means of phylogenetic (16S rRNA gene sequence), physiological, morphological and biochemical analyses. Both novel isolates were capable of growing under "extreme" conditions- pH 12, 10% NaCl and 45°C. Partial enzyme characterization revealed that both strains produced xylanase enzymes that were active at pH 6.5 and 8.5 with an increase in activity up to 45°C. The results obtained revealed a previously undetected diversity of actinobacteria in the Ethiopian Rift Valley with a potentially novel subpopulation adapted to haloalkaline conditions. The low 16S rRNA sequence similarity of a substantial proportion of the libraries suggests that culture-based isolation may play a vital role in deciphering the community fingerprint. / The National Research Foundation and the Norwegian Research Council

Actinobacteria

Ethiopian Rift Valley

Soda lakes

Denaturing Gradient Gel Electrophoresis

Contribution of Biosolids-derived Bioaerosols to the Airborne Microbial Population

Lindelof, Kara L.

09 June 2011

No description available.

Environmental Science

Microbiology

biosolids

aerosols

DGGE

denaturing gradient gel electrophoresis

bioaerosols

BIODEGRADATION OF METHYL <i>TERT</i> -BUTYL ETHER

PRUDEN, AMY J.

11 October 2002

No description available.

Environmental Sciences

methyl tert.butyl ether

fuel oxygenates

biodegradation

denaturing gradient gel electrophoresis

Evaluation of the Biodegradability of MTBE in Groundwater

Chen, Ku-Fan

24 May 2006

Methyl tert-butyl ether (MTBE) has been used as a gasoline additive to improve the combustion efficiency and to replace lead since 1978. It is the most commonly used oxygenate now due to its low cost, convenience of transfer, and ease of blending and production. MTBE has become a prevalent groundwater contaminant because it is widely used and it has been disposed inappropriately. MTBE has been demonstrated an animal carcinogen. The US Environmental Protection Agency (US EPA) has temporarily classified MTBE as a possible human carcinogen and has set its advisory level for drinking water at 20-40 &#x00B5;g/L based on taste and odor concerns. The Taiwan Environmental Protection Administration (TEPA) also classifies it as the Class IV toxic chemical substances. Currently, natural attenuation (NA) as well as natural bioremediation or enhanced bioremediation are attractive remediation options for contaminated sites due to their economic benefit and environmental friendly. In general, in situ microorganisms at the contaminated site play a very important role in site restoration. Although early studies suggested that the biodegradability of MTBE was not significant, recent laboratory and field reports reveal that MTBE can be biodegraded under aerobic and anaerobic conditions. In addition, evidences and some successful cases of MTBE attenuation have been reported that make natural attenuation a considerable remedial strategy. However, the biodegrading rate might decrease if the nutritional and physiological requirements are not met. Thus, it is important to assess the biodegradability of natural microorganisms under various site conditions to obtain optimal remedial conditions. Contributions of intrinsic biodegradation and other abiotic mechanisms to the removal and control of contaminants should also be evaluated to provide sufficient information for remedial option determination. Moreover, isolation and identification of the dominant native microorganisms will be helpful to following remediation tasks. In the first part of this study, microcosm study and microbial identification technologies (denaturing gradient gel electrophoresis, DGGE) were applied to assess the biodegradability of MTBE by indigenous microbial consortia and to identify the dominant microorganisms at a MTBE-contaminated site (Site A). In the second part of this study, thorough field investigations were performed to evaluate the occurrence of natural attenuation of MTBE at two MTBE-contaminated sites (Site A and Site B). In addition, a natural attenuation model, BIOSCREEN, was performed to assess the effectiveness of natural attenuation on MTBE containment. The main objectives of this study contained the following: (1)Evaluate MTBE biodegradability under different redox conditions by the indigenous microorganisms. (2)Determine the dominant native microorganisms in MTBE biodegradation for further application. (3)Assess the feasibility of using natural attenuation to control the MTBE plume. (4)Evaluate the contributions of intrinsic biodegradation patterns on natural attenuation processes by BIOSCREEN. Results from the microcosm study reveal that MTBE could be biodegraded by aquifer sediments without the addition of extra carbon sources under aerobic conditions. The production of tert-butyl alcohol (TBA), a degradation byproduct of MTBE, was detected. Complete removal of TBA was also observed by the end of the experiment. Results from aerobic microcosms study indicate that oxygen might be the major limiting factor of MTBE biodegradation at Site A. Thus, MTBE at this site could be removed via natural biodegradation processes with the supplement of sufficient oxygen. Microcosm study with extracted supernatant of aquifer sediments as the inocula show that the indigenous microorganisms were capable of using MTBE as the sole carbon and energy source. The calculated MTBE degradation rate was 0.597 mg/g cells/h or 0.194 nmole/mg cells/h. No MTBE removal was observed under various anaerobic conditions. Results suggest that aerobic biodegradation was the dominant degradation process and aerobic bioremediation might be a more appropriate option for the site remediation. According to the results of DGGE analysis, aerobic MTBE-biodegrading bacteria, Pseudomonas sp. and Xanthomonas sp., might exist at this site. Although results of microcosm study show that MTBE could not be degraded under anaerobic conditions, the microbial identification indicates that some novel anaerobic microbes, which could degraded MTBE, might be present at this site. In addition, anaerobic microbes caused the consumption of electron acceptors (e.g., nitrate, ferric iron) and removal of benzene, toluene, ethylbenzene, xylenes (BTEX), 1,2,4-trimethyl benzene (1,2,4-TMB), and 1,3,5-trimethyl benzene (1,3,5-TMB) (TMBs) in the anaerobic microcosms. These results also indicate that the potential of anaerobes activities was high at Site A. Based on the results from the field investigation, natural attenuation of MTBE was occurring at both sites. MTBE plume at Site B could be effectively controlled via natural attenuation processes. Nevertheless, MTBE plume at Site A has migrated to a farther downgradient area and passed the boundary of the site. Field investigation results indicate that the natural attenuation mechanisms of MTBE at both sites were occurring with the first-order attenuation rates of 0.0021 and 0.0048 1/day at Sites A and B, respectively. According to BIOSCREEN simulation, biodegradation was responsible for 78% and 59% of MTBE mass reduction at Sites A and B, respectively. The intrinsic biodegradation had significant contributions on the control of MTBE plumes. Moreover, the dilution and dispersion processes might be the major mechanisms for the attenuation of MTBE in the downgradient areas. However, results also reveal that intrinsic biological processes might still fail to contain the plume if the selected point of compliance is not appropriate. Results of this study suggest that natural attenuation might be feasible to be used as a remedial option for the remediation of MTBE-contaminated site on the premise that (1) detailed site characterization has been conducted, and (2) the occurrence and effectiveness of natural attenuation processes have been confirmed. Based on the results from the field investigation and laboratory microcosm studies, MTBE could be biodegraded by natural microbial populations at the studied sites under both aerobic and anaerobic conditions and natural attenuation would be applied as a remedial option at MTBE-contaminated sites. Results from this study would be useful in determining the favorable bioremediation conditions and designing an efficient and cost-effective bioremediation system such as monitored natural attenuation (MNA) or in situ or on-site MTBE bioremediation system for field application.

BIOSCREEN

natural attenuation

intrinsic bioremediation

MTBE (methyl tert-butyl ether)

anaerobic biodegradation