Your search keyword '"Croese, E."' showing total 11 results

1. Transcriptomics as a Tool to Monitor and Predict the Behaviour of the Microbiome in an Industrial Salt Waste Water Treatment Plant

Author

Euverink, G.J.W., primary, Geurkink, A.K., additional, Faber, G., additional, Rijks, V., additional, Croese, E., additional, Dinkla, I., additional, van der Marel, P., additional, Krooneman, J., additional, and Jayawardhana, B., additional

Published

2017

2. Ecophysiology of microorganisms in microbial elctrolysis cells

Author

Croese, E., Wageningen University, Fons Stams, G.J.W. Euverink, and J.S. Geelhoed

Subjects

microbiële brandstofcellen, WIMEK, microbial fuel cells, microbiële fysiologie, Microbiologie, ecophysiology, electrolysis, Microbiology, microbial physiology, elektrolyse, ecofysiologie

Abstract

One of the main challenges for improvement of the microbial electrolysis cell (MEC) has been the reduction of the cost of the cathode catalyst. As catalyst at the cathode, microorganisms offer great possibilities. Previous research has shown the principle possibilities for the biocathode for H2 production with mixed microbial communities. In this thesis we analyzed the microbial communities from several biocathodes for H2 production. The microbial population of the very first MEC biocathode for H2 production (Chapter 2) showed a dominant population of Desulfovibrio spp.. A member of those dominant species, Desulfovibrio strain G11 was reinoculated in a biocathode and produced current and H2. On basis of previous knowledge of known Desulfovibrio spp., the molecular mechanism of electron uptake from a cathode with H2 production was proposed to have similarities to mechanisms that have been proposed for syntrophic growth. In Chapter 3 the microbial population of 5 more MEC biocathodes was analyzed. Those MECs were fed with either acetate or bicarbonate and consisted of two different designs. The results showed that the microbial communities from the same setup design are more similar than fed with the same carbon source. Furthermore, ribotypes from the phyla, Firmicutes, Proteobacteria, Bacteroidetes and Actinobacteria were found to be dominant. To understand more on the mechanisms of H2 production in the MEC, a hydrogenase gene microarray was used to analyze the hydrogenase genes present in 3 of the cathode samples. Those results showed that genes coding for bidirection NAD(P) dependent hydrogenases were mostly present in the MEC biocathode. Those results suggest a mechanisms involving cytoplasmatic NAD(P) dependent hydrogenases rather than energy converting hydrogenases as proposed before. To understand the molecular mechanisms it is important to obtain pure cultures from the MEC biocathode and test them for biocathode activity. In chapter 4 we describe a Citrobacter species strain PS2 which was isolated from the MEC biocathode. PS2 was very similar to other Citrobacter spp. able to produce fermentative H2 from a diversity of carbon sources. When inoculated in the MEC biocathode fed with pyruvate, current increased and H2 was produced with comparable efficiencies and production rates as mixed cultures biocathodes. Addition of membrane potential uncouplers nigericin and monensin showed no change in current and H2 production rates, suggesting that the molecular mechanism does not involve membrane potential driven processes. Finally, in chapter 5, we explored the usefulness of statistical methods to pinpoint which species are most important for MEC performance. We analyzed DGGE profiles from 5 different MEC anodes using two distinct statistical techniques, Radundacy analysis (RDA) and QR factorization (QRE), and tried to link those profiles to experimental data current, resistance, potential and overpotential. The results showed that current was mostly related to species composition and we were able to pinpoint a few band from DGGE that were influencing changes in experimental parameters most. The results showed that both RDA and QRE are useful methods, of which RDA takes all bands into account, but is therefore less precise; QRE is numerical precise but by eliminating bands that explain least of the variation and therefore using QRE might neglect effect of those bands. Altogether, RDA with additional QRE is useful to give an indication of which species from a mixed community are most likely important for MEC performance and can be used to find a focus in mixed community analysis. From our results we conclude that a large diversity of bacteria is able to catalyze the biocathodes reaction for H2 production. The species that develop at a cathode might be largely influenced by the design of the used setup, which has to be considered when comparing different experiments. In addition, our results suggest that a general mechanism, present in many different bacterial species, is involved in MEC H2 production. We propose a molecular mechanism involving a series of cytochromes and cytoplasmatic H2 production by NAD(P)+ dependent bidirectional hydrogenases that use energy from electrons derived from the cathode. The biocathode is a promising technology for application in the MEC, although to date the chemical cathodes still outcompete the biocathode, the biocathode offers great possibilities for future applications including production of other products such as ethanol, methane, succinate or acetate.

Published

2012

3. Hydrogen producing microbial communities of the biocathode in a microbial electrolysis cell

Author

Croese, E., Pereira, M. A., Euverink, G., Stams, Alfons Johannes Maria, Geelhoed, J., and Universidade do Minho

Abstract

In the search for alternatives for fossil fuels and the reuse of the energy from waste streams, the microbial electrolysis cell is a promising technique. The microbial electrolysis cell is a two electrode system in which at the anode organic substances, including waste water, are used by microorganisms that release the terminal electrons to the electrode. These electrons are subsequently used at the cathode resulting in the production of a current. By addition of a small voltage, hydrogen gas can be produced by combining electrons and protons at the cathode. To catalyse the hydrogen evolution reaction at the cathode, expensive catalysts such as platinum are required. Recently, the use of biocathodes has shown great potential as an alternative for platinum. The microbial community responsible for the hydrogen evolution in such systems is, however, not well understood. In this study we focused on the characterization of the microbial communities of the microbial electrolysis cell biocathode using molecular techniques. The results show that the microbial community consists of 44% Proteobacteria, 27% Firmicutes, 18% Bacteriodetes and 12% related to other phyla. Within the major phylogenetic groups we found several clusters of uncultured species belonging to novel taxonomic groups at genus level. These novel taxonomic groups developed under environmentally unusual conditions and might have properties that have not been described before. Therefore it is of great interest to study those novel groups further. Within the Proteobacteria a major cluster belonged to the Deltaproteobacteria and based on the known characteristics of the closest related cultured species, we suggest a mechanism for microbial electron transfer for the production of hydrogen at the cathode.

Published

2010

4. Ecophysiology of microorganisms in microbial elctrolysis cells

Author

Stams, Fons, Euverink, G.J.W., Geelhoed, J.S., Croese, E., Stams, Fons, Euverink, G.J.W., Geelhoed, J.S., and Croese, E.

Abstract

One of the main challenges for improvement of the microbial electrolysis cell (MEC) has been the reduction of the cost of the cathode catalyst. As catalyst at the cathode, microorganisms offer great possibilities. Previous research has shown the principle possibilities for the biocathode for H2 production with mixed microbial communities. In this thesis we analyzed the microbial communities from several biocathodes for H2 production. The microbial population of the very first MEC biocathode for H2 production (Chapter 2) showed a dominant population of Desulfovibrio spp.. A member of those dominant species, Desulfovibrio strain G11 was reinoculated in a biocathode and produced current and H2. On basis of previous knowledge of known Desulfovibrio spp., the molecular mechanism of electron uptake from a cathode with H2 production was proposed to have similarities to mechanisms that have been proposed for syntrophic growth. In Chapter 3 the microbial population of 5 more MEC biocathodes was analyzed. Those MECs were fed with either acetate or bicarbonate and consisted of two different designs. The results showed that the microbial communities from the same setup design are more similar than fed with the same carbon source. Furthermore, ribotypes from the phyla, Firmicutes, Proteobacteria, Bacteroidetes and Actinobacteria were found to be dominant. To understand more on the mechanisms of H2 production in the MEC, a hydrogenase gene microarray was used to analyze the hydrogenase genes present in 3 of the cathode samples. Those results showed that genes coding for bidirection NAD(P) dependent hydrogenases were mostly present in the MEC biocathode. Those results suggest a mechanisms involving cytoplasmatic NAD(P) dependent hydrogenases rather than energy converting hydrogenases as proposed before. To understand the molecular mechanisms it is important to obtain pure cultures from the MEC biocathode and test them for biocathode activity. In chapter 4 we describe a Citrobacter

Published

2012

5. Analysis of the microbial community of the biocathode of a hydrogen-producing microbial electrolysis cell

Author

Croese, E., Pereira, M.A., Euverink, G.J.W., Stams, A.J.M., Geelhoed, J.S., Croese, E., Pereira, M.A., Euverink, G.J.W., Stams, A.J.M., and Geelhoed, J.S.

Abstract

The microbial electrolysis cell (MEC) is a promising system for hydrogen production. Still, expensive catalysts such as platinum are needed for efficient hydrogen evolution at the cathode. Recently, the possibility to use a biocathode as an alternative for platinum was shown. The microorganisms involved in hydrogen evolution in such systems are not yet identified. We analyzed the microbial community of a mixed culture biocathode that was enriched in an MEC bioanode. This biocathode produced 1.1 A m(-2) and 0.63 m3 H2 m(-3) cathode liquid volume per day. The bacterial population consisted of 46% Proteobacteria, 25% Firmicutes, 17% Bacteroidetes, and 12% related to other phyla. The dominant ribotype belonged to the species Desulfovibrio vulgaris. The second major ribotype cluster constituted a novel taxonomic group at the genus level, clustering within uncultured Firmicutes. The third cluster belonged to uncultured Bacteroidetes and grouped in a taxonomic group from which only clones were described before; most of these clones originated from soil samples. The identified novel taxonomic groups developed under environmentally unusual conditions, and this may point to properties that have not been considered before. A pure culture of Desulfovibrio strain G11 inoculated in a cathode of an MEC led to a current development from 0.17 to 0.76 A m(-2) in 9 days, and hydrogen gas formation was observed. On the basis of the known characteristics of Desulfovibrio spp., including its ability to produce hydrogen, we propose a mechanism for hydrogen evolution through Desulfovibrio spp. in a biocathode system

Published

2011

6. Praktijkervaringen met waterberging in natuur(ontwikkelings)gebieden : hoofdrapport pilotprogramma waterberging en natuur

Author

Stuijfzand, S., van Ek, R., Belien, E., Beumer, V., Croese, E., Diggelen, R., Eigenhuijsen, E., Goeij, S., Grotenboer, A., Hommel, P.W.F.M., Jong, H., Klein, J., Kruit, L., van Manen, H., Medenblik, J., Mouissie, M., Olsthoorn, A.F.M., den Ouden, J., Pelsma, T., Pol, J., Riksen, M.J.P.M., de Rooij, S., Sass-Klaassen, U., Sival, F.P., Vegter, U., Verbeek, L., Voorde, L., de Waal, R.W., Wessels, Y., Zierfuss, S., Stuijfzand, S., van Ek, R., Belien, E., Beumer, V., Croese, E., Diggelen, R., Eigenhuijsen, E., Goeij, S., Grotenboer, A., Hommel, P.W.F.M., Jong, H., Klein, J., Kruit, L., van Manen, H., Medenblik, J., Mouissie, M., Olsthoorn, A.F.M., den Ouden, J., Pelsma, T., Pol, J., Riksen, M.J.P.M., de Rooij, S., Sass-Klaassen, U., Sival, F.P., Vegter, U., Verbeek, L., Voorde, L., de Waal, R.W., Wessels, Y., and Zierfuss, S.

Abstract

In 2002 is het “Pilotprogramma Waterberging-Natuur”gestart. Het hoofddoel van het pilotprogramma was waterbeheerders, terreinbeherende instanties en provincies te ondersteunen in het koppelen van de functies waterberging en natuur. Daarbij is het pilotprogramma primair gericht geweest op het opdoen en verspreiden van ervaringskennis. Dit rapport geeft een overzicht van de belangrijkste resultaten van het pilotprogramma waterberging-natuur. Naast dit hoofdrapport is er per pilot een achtergrondrapport beschikbaar waar in meer detail wordt ingegaan op aanpak van de monitoring en de resultaten. Een samenwerking tussen vele partijen: WUR, Deltares, Natuurmonumenten, Staatsbosbeheer, RU Groningen, Twentse Vogelwerkgroep, waterschappen, Rijkswaterstaat en LNV (Natuur, Kennis)

Published

2007

7. Influence of setup and carbon source on the bacterial community of biocathodes in microbial electrolysis cells.

Author

Croese E, Jeremiasse AW, Marshall IP, Spormann AM, Euverink GJ, Geelhoed JS, Stams AJ, and Plugge CM

Subjects

Bacteria classification, Bacteria genetics, Bacteria metabolism, Bacterial Proteins genetics, Bacterial Proteins metabolism, Biodiversity, Carbon, Electrodes, Electrolysis, Genes, Bacterial, Hydrogen metabolism, Hydrogenase genetics, Hydrogenase metabolism, Industrial Microbiology, Microscopy, Electron, Scanning, Bioelectric Energy Sources microbiology

Abstract

The microbial electrolysis cell (MEC) biocathode has shown great potential as alternative for expensive metals as catalyst for H2 synthesis. Here, the bacterial communities at the biocathode of five hydrogen producing MECs using molecular techniques were characterized. The setups differed in design (large versus small) including electrode material and flow path and in carbon source provided at the cathode (bicarbonate or acetate). A hydrogenase gene-based DNA microarray (Hydrogenase Chip) was used to analyze hydrogenase genes present in the three large setups. The small setups showed dominant groups of Firmicutes and two of the large setups showed dominant groups of Proteobacteria and Bacteroidetes. The third large setup received acetate but no sulfate (no sulfur source). In this setup an almost pure culture of a Promicromonospora sp. developed. Most of the hydrogenase genes detected were coding for bidirectional Hox-type hydrogenases, which have shown to be involved in cytoplasmatic H2 production., (Copyright © 2014 Elsevier Inc. All rights reserved.)

Published

2014

8. Relating MEC population dynamics to anode performance from DGGE and electrical data.

Author

Croese E, Keesman KJ, Widjaja-Greefkes AH, Geelhoed JS, Plugge CM, Sleutels TH, Stams AJ, and Euverink GJ

Subjects

Archaea genetics, Archaea growth & development, Bacteria genetics, Bacteria growth & development, Denaturing Gradient Gel Electrophoresis, Molecular Sequence Data, Population Dynamics, Sequence Analysis, DNA, Archaea classification, Bacteria classification, Biodiversity, Bioelectric Energy Sources microbiology, Electricity, Electrodes microbiology

Abstract

The microbial electrolysis cell (MEC) is a promising system for H2 production, but little is known about the active microbial population in MEC systems. Therefore, the microbial community of five different MEC graphite felt anodes was analyzed using denaturing gradient gel electrophoresis (DGGE) profiling. The results showed that the bacterial population was very diverse and there were substantial differences between microorganisms in anolyte and anode samples. The archaeal population in the anolyte and at the anodes, and between the different MEC anodes, was very similar. SEM and FISH imaging showed that Archaea were mainly present in the spaces between the electrode fibers and Bacteria were present at the fiber surface, which suggested that Bacteria were the main microorganisms involved in MEC electrochemical activity. Redundancy analysis (RDA) and QR factorization-based estimation (QRE) were used to link the composition of the bacterial community to electrochemical performance of the MEC. The operational mode of the MECs and their consequent effects on current density and anode resistance on the populations were significant. The results showed that the community composition was most strongly correlated with current density. The DGGE band mostly correlated with current represented a Clostridium sticklandii strain, suggesting that this species had a major role in current from acetate generation at the MEC anodes. The combination of RDA and QRE seemed especially promising for obtaining an insight into the part of the microbial population actively involved in electrode interaction in the MEC., (Copyright © 2013 Elsevier GmbH. All rights reserved.)

Published

2013

9. Acetate enhances startup of a H₂-producing microbial biocathode.

Author

Jeremiasse AW, Hamelers HV, Croese E, and Buisman CJ

Subjects

Bicarbonates metabolism, Carbon metabolism, Electrolysis, Acetates metabolism, Bioelectric Energy Sources, Electrodes microbiology, Hydrogen metabolism

Abstract

H(2) can be produced from organic matter with a microbial electrolysis cell (MEC). To decrease MEC capital costs, a cathode is needed that is made of low-cost material and produces H(2) at high rate. A microbial biocathode is a low-cost candidate, but suffers from a long startup and a low H(2) production rate. In this study, the effects of cathode potential and carbon source on microbial biocathode startup were investigated. Application of a more negative cathode potential did not decrease the startup time of the biocathode. If acetate instead of bicarbonate was used as carbon source, the biocathode started up more than two times faster. The faster startup was likely caused by a higher biomass yield for acetate than for bicarbonate, which was supported by thermodynamic calculations. To increase the H(2) production rate, a flow through biocathode fed with acetate was investigated. This biocathode produced 2.2 m(3) H(2) m(-3)  reactor day(-1) at a cathode potential of -0.7 V versus NHE, which was seven times that of a parallel flow biocathode of a previous study., (Copyright © 2011 Wiley Periodicals, Inc.)

Published

2012

10. Analysis of the microbial community of the biocathode of a hydrogen-producing microbial electrolysis cell.

Author

Croese E, Pereira MA, Euverink GJ, Stams AJ, and Geelhoed JS

Subjects

Bacteria chemistry, Bacteria classification, Bioreactors microbiology, Electrodes microbiology, Electrolysis, Molecular Sequence Data, Phylogeny, Bacteria isolation & purification, Bacteria metabolism, Bioelectric Energy Sources microbiology, Hydrogen metabolism

Abstract

The microbial electrolysis cell (MEC) is a promising system for hydrogen production. Still, expensive catalysts such as platinum are needed for efficient hydrogen evolution at the cathode. Recently, the possibility to use a biocathode as an alternative for platinum was shown. The microorganisms involved in hydrogen evolution in such systems are not yet identified. We analyzed the microbial community of a mixed culture biocathode that was enriched in an MEC bioanode. This biocathode produced 1.1 A m(-2) and 0.63 m3 H2 m(-3) cathode liquid volume per day. The bacterial population consisted of 46% Proteobacteria, 25% Firmicutes, 17% Bacteroidetes, and 12% related to other phyla. The dominant ribotype belonged to the species Desulfovibrio vulgaris. The second major ribotype cluster constituted a novel taxonomic group at the genus level, clustering within uncultured Firmicutes. The third cluster belonged to uncultured Bacteroidetes and grouped in a taxonomic group from which only clones were described before; most of these clones originated from soil samples. The identified novel taxonomic groups developed under environmentally unusual conditions, and this may point to properties that have not been considered before. A pure culture of Desulfovibrio strain G11 inoculated in a cathode of an MEC led to a current development from 0.17 to 0.76 A m(-2) in 9 days, and hydrogen gas formation was observed. On the basis of the known characteristics of Desulfovibrio spp., including its ability to produce hydrogen, we propose a mechanism for hydrogen evolution through Desulfovibrio spp. in a biocathode system.

Published

2011

11. Repeatability and individual correlates of microbicidal capacity of bird blood.

Author

Tieleman BI, Croese E, Helm B, and Versteegh MA

Subjects

Aging blood, Aging immunology, Animals, Female, Male, Sex Characteristics, Species Specificity, Blood Bactericidal Activity, Candida albicans immunology, Escherichia coli immunology, Songbirds blood, Songbirds immunology

Abstract

With the rapid development of the field of ecological and evolutionary immunology, a series of new techniques to measure different components of immune function is becoming commonplace. An important step for the interpretation of these new measures is to understand the kind of information about the animal that they convey. We showed that the microbicidal capacity of Stonechat (Saxicola torquata) blood, an integrative measure of constitutive immune function, is highly repeatable when tested against Escherichia coli and not significantly repeatable when tested against Candida albicans. The low repeatability against C. albicans results from relatively low variation among individuals, providing only low resolution to identify if this interindividual variation is consistent. In addition, we explored the effect of sex and age on microbicidal capacity, and found that over a range of ages from 1 to 7 years the blood of older birds had a better capacity to kill microbes. We concluded that, over a time period of weeks, microbicidal capacity of avian blood is an individual-bound trait, that shows consistent interindividual variation partly related to age, and unaffected by sex. This knowledge is important when interpreting the possible evolutionary mechanism underlying immunological differences, for example among individuals, environments and seasons., (Copyright (c) 2010 Elsevier Inc. All rights reserved.)

Published

2010