"uuid","repository link","title","author","contributor","publication year","abstract","subject topic","language","publication type","publisher","isbn","issn","patent","patent status","bibliographic note","access restriction","embargo date","faculty","department","research group","programme","project","coordinates"
"uuid:3270ca70-354f-4122-8e4d-079d294aa2bd","http://resolver.tudelft.nl/uuid:3270ca70-354f-4122-8e4d-079d294aa2bd","Trichlorobacter ammonificans, a dedicated acetate-dependent ammonifier with a novel module for dissimilatory nitrate reduction to ammonia","Sorokin, Dimitry Y. (TU Delft BT/Environmental Biotechnology; Russian Academy of Sciences); Tikhonova, Tamara V. (Russian Academy of Sciences); Koch, Hanna (Radboud Universiteit Nijmegen); van den Berg, E.M. (TU Delft BT/Industriele Microbiologie); Hinderks, Renske S. (Student TU Delft); Pabst, Martin (TU Delft BT/Environmental Biotechnology); Kuenen, J.G. (TU Delft BT/Environmental Biotechnology); van Loosdrecht, Mark C.M. (TU Delft BT/Environmental Biotechnology); Lücker, Sebastian (Radboud Universiteit Nijmegen)","","2023","Dissimilatory nitrate reduction to ammonia (DNRA) is a common biochemical process in the nitrogen cycle in natural and man-made habitats, but its significance in wastewater treatment plants is not well understood. Several ammonifying Trichlorobacter strains (former Geobacter) were previously enriched from activated sludge in nitrate-limited chemostats with acetate as electron (e) donor, demonstrating their presence in these systems. Here, we isolated and characterized the new species Trichlorobacter ammonificans strain G1 using a combination of low redox potential and copper-depleted conditions. This allowed purification of this DNRA organism from competing denitrifiers. T. ammonificans is an extremely specialized ammonifier, actively growing only with acetate as e-donor and carbon source and nitrate as e-acceptor, but H2 can be used as an additional e-donor. The genome of G1 does not encode the classical ammonifying modules NrfAH/NrfABCD. Instead, we identified a locus encoding a periplasmic nitrate reductase immediately followed by an octaheme cytochrome c that is conserved in many Geobacteraceae species. We purified this octaheme cytochrome c protein (TaNiR), which is a highly active dissimilatory ammonifying nitrite reductase loosely associated with the cytoplasmic membrane. It presumably interacts with two ferredoxin subunits (NapGH) that donate electrons from the menaquinol pool to the periplasmic nitrate reductase (NapAB) and TaNiR. Thus, the Nap-TaNiR complex represents a novel type of highly functional DNRA module. Our results indicate that DNRA catalyzed by octaheme nitrite reductases is a metabolic feature of many Geobacteraceae, representing important community members in various anaerobic systems, such as rice paddy soil and wastewater treatment facilities.","","en","journal article","","","","","","Green Open Access added to TU Delft Institutional Repository ‘You share, we take care!’ – Taverne project https://www.openaccess.nl/en/you-share-we-take-care Otherwise as indicated in the copyright section: the publisher is the copyright holder of this work and the author uses the Dutch legislation to make this work public.","","2024-01-14","","","BT/Environmental Biotechnology","","",""
"uuid:a2e0de1e-eca2-4b8c-9bd9-bc7e8425704d","http://resolver.tudelft.nl/uuid:a2e0de1e-eca2-4b8c-9bd9-bc7e8425704d","Serpentinimonas gen. Nov., serpentinimonas raichei sp. nov., serpentinimonas barnesii sp. nov. and serpentinimonas maccroryi sp. nov., hyperalkaliphilic and facultative autotrophic bacteria isolated from terrestrial serpentinizing springs","Bird, Lina J. (Naval Research Laboratory; University of Southern California); Kuenen, J.G. (TU Delft BT/Environmental Biotechnology; University of Southern California); Osburn, Magdalena R. (Northwestern University); Tomioka, Naotaka (Japan Agency for Marine-Earth Science and Technologies (JAMSTEC)); Ishii, Shun’Ichi (Japan Agency for Marine-Earth Science and Technologies (JAMSTEC); Institute for Extra-cutting- edge Science and Technology Avant-garde Research (X-star)); Barr, Casey (University of Southern California); Nealson, Kenneth H. (University of Southern California); Suzuki, Shino (Japan Agency for Marine-Earth Science and Technologies (JAMSTEC); Institute of Space and Astronautical Science (ISAS)/JAXA; Institute for Extra-cutting- edge Science and Technology Avant-garde Research (X-star))","","2021","Three highly alkaliphilic bacterial strains designated as A1T, H1T and B1T were isolated from two highly alkaline springs at The Cedars, a terrestrial serpentinizing site. Cells from all strains were motile, Gram-negative and rod-shaped. Strains A1T, H1T and B1T were mesophilic (optimum, 30 °C), highly alkaliphilic (optimum, pH 11) and facultatively autotrophic. Major cellular fatty acids were saturated and monounsaturated hexadecenoic and octadecanoic acids. The genome size of strains A1T, H1T and B1T was 2574013, 2475906 and 2623236 bp, and the G+C content was 66.0, 66.2 and 66.1mol%, respectively. Analysis of the 16S rRNA genes showed the highest similarity to the genera Malikia (95.1–96.4%), Macromonas (93.0–93.6%) and Hydrogenophaga (93.0–96.6%) in the family Comamonadaceae. Phylogenetic analysis based on 16S rRNA gene and phylogenomic analysis based on core gene sequences revealed that the isolated strains diverged from the related species, forming a distinct branch. Average amino acid identity values of strains A1T, H1T and B1T against the genomes of related members in this family were below 67%, which is below the suggested threshold for genera boundaries. Average nucleotide identity by blast values and digital DNA– DNA hybridization among the three strains were below 92.0 and 46.6% respectively, which are below the suggested thresholds for species boundaries. Based on phylogenetic, genomic and phenotypic characterization, we propose Serpentinimonas gen. nov., Serpentinimonas raichei sp. nov. (type strain A1T=NBRC 111848T=DSM 103917T), Serpentinimonas barnesii sp. nov. (type strain H1T= NBRC 111849T=DSM 103920T) and Serpentinimonas maccroryi sp. nov. (type strain B1T=NBRC 111850T=DSM 103919T) belonging to the family Comamonadaceae. We have designated Serpentinimonas raichei the type species for the genus because it is the dominant species in The Cedars springs.","Alkaliphile; Autotrophic growth; Serpentinization; Serpentinomonas/Serpentinimonas","en","journal article","","","","","","","","","","","BT/Environmental Biotechnology","","",""
"uuid:0c597325-8bd6-4068-be5b-8f3981c33e78","http://resolver.tudelft.nl/uuid:0c597325-8bd6-4068-be5b-8f3981c33e78","Anammox and beyond","Kuenen, J.G. (TU Delft BT/Environmental Biotechnology)","","2019","When looking back and wonder how we did it, I became even more aware of how my wanderings in microbiology are all linked, from the start of my PhD with Hans Veldkamp on sulphur-oxidizing bacteria in chemostats. My interests broadened from obligate chemolithoautotrophic bacteria to facultative organisms and the question about the ecological niches of these different metabolic types. The sulphide oxidizing bacteria also may be used to produce elemental sulphur, which can easily be removed from wastewater. This fitted in a long-standing collaboration with Dimitry Sorokin on the ecophysiology and application of alkaliphilic sulphur bacteria. Then came the denitrifying sulphur-oxidizing bacteria and their application to remove sulphide from wastewater, which lead to our interest in nitrate, nitrite and ammonium removal in general. The big surprise was the serendipitous discovery of the ‘anammox’-process, whereby ammonium is anaerobically oxidized to dinitrogen gas with nitrite as electron acceptor. The early days of our anammox research are the main focus of this article, which describes the struggle of growing and identifying the most peculiar bacteria we ever came across. A specialized organelle, the anammoxosome was shown to be responsible for the key ammonium oxidation, whereby a rocket fuel, hydrazine, turned out to be an intermediate. Soon after we became aware that anammox is everywhere and in the marine environment makes up a major portion of the nitrogen cycle. The intense scientific collaboration with Mike Jetten and Mark van Loosdrecht and colleagues led to our further understanding and application of this fascinating process, which is briefly summarized in this article. My broader interest in environmental microbiology and microbial ecology has been a regularly returning theme, taking me all over the world to great collaborations lasting to this very day.","","en","journal article","","","","","","","","","","","BT/Environmental Biotechnology","","",""
"uuid:f8a9dbb5-4f2c-4d16-abba-1037f6789941","http://resolver.tudelft.nl/uuid:f8a9dbb5-4f2c-4d16-abba-1037f6789941","Life on N2O: deciphering the ecophysiology of N2O respiring bacterial communities in a continuous culture","Conthe Calvo, M. (TU Delft BT/Environmental Biotechnology); Wittorf, Lea (Swedish University of Agricultural Sciences); Kuenen, J.G. (TU Delft BT/Environmental Biotechnology); Kleerebezem, R. (TU Delft BT/Environmental Biotechnology); van Loosdrecht, Mark C.M. (TU Delft BT/Environmental Biotechnology); Hallin, Sara (Swedish University of Agricultural Sciences)","","2018","Reduction of the greenhouse gas N2O to N2 is a trait among denitrifying and non-denitrifying microorganisms having an N2O reductase, encoded by nosZ. The nosZ phylogeny has two major clades, I and II, and physiological differences among organisms within the clades may affect N2O emissions from ecosystems. To increase our understanding of the ecophysiology of N2O reducers, we determined the thermodynamic growth efficiency of N2O reduction and the selection of N2O reducers under N2O- or acetate-limiting conditions in a continuous culture enriched from a natural community with N2O as electron acceptor and acetate as electron donor. The biomass yields were higher during N2O limitation, irrespective of dilution rate and community composition. The former was corroborated in a continuous culture of Pseudomonas stutzeri and was potentially due to cytotoxic effects of surplus N2O. Denitrifiers were favored over non-denitrifying N2O reducers under all conditions and Proteobacteria harboring clade I nosZ dominated. The abundance of nosZ clade II increased when allowing for lower growth rates, but bacteria with nosZ clade I had a higher affinity for N2O, as defined by μmax/Ks. Thus, the specific growth rate is likely a key factor determining the composition of communities living on N2O respiration under growth-limited conditions.","","en","journal article","","","","","","","","","","","BT/Environmental Biotechnology","","",""
"uuid:6c730dce-d335-4f3d-8e57-370617f520f3","http://resolver.tudelft.nl/uuid:6c730dce-d335-4f3d-8e57-370617f520f3","Growth yield and selection of nosZ clade II types in a continuous enrichment culture of N2O respiring bacteria","Conthe Calvo, M. (TU Delft BT/Environmental Biotechnology); Wittorf, Lea (Swedish University of Agricultural Sciences); Kuenen, J.G. (TU Delft BT/Environmental Biotechnology); Kleerebezem, R. (TU Delft BT/Environmental Biotechnology); Hallin, Sara (Swedish University of Agricultural Sciences); van Loosdrecht, Mark C.M. (TU Delft BT/Environmental Biotechnology)","","2018","Nitrous oxide (N2O) reducing microorganisms may be key in the mitigation of N2O emissions from managed ecosystems. However, there is still no clear understanding of the physiological and bioenergetic implications of microorganisms possessing either of the two N2O reductase genes (nosZ), clade I and the more recently described clade II type nosZ. It has been suggested that organisms with nosZ clade II have higher growth yields and a lower affinity constant (Ks) for N2O. We compared N2O reducing communities with different nosZI/nosZII ratios selected in chemostat enrichment cultures, inoculated with activated sludge, fed with N2O as a sole electron acceptor and growth limiting factor and acetate as electron donor. From the sequencing of the 16S rRNA gene, FISH and quantitative PCR of nosZ and nir genes, we concluded that betaproteobacterial denitrifying organisms dominated the enrichments with members within the family Rhodocyclaceae being highly abundant. When comparing cultures with different nosZI/nosZII ratios, we did not find support for (i) a more energy conserving N2O respiration pathway in nosZ clade II systems, as reflected in the growth yield per mole of substrate, or (ii) a higher affinity for N2O, defined by μmax/Ks, in organisms with nosZ clade II.","","en","journal article","","","","","","","","","","","BT/Environmental Biotechnology","","",""
"uuid:e676e9ee-3822-404c-ba02-e7f5a5a29f4c","http://resolver.tudelft.nl/uuid:e676e9ee-3822-404c-ba02-e7f5a5a29f4c","Fermentative Bacteria Influence the Competition between Denitrifiers and DNRA Bacteria","van den Berg, E.M. (TU Delft BT/Industriele Microbiologie); Perdigão Elisiário, M. (TU Delft BT/Bioprocess Engineering); Kuenen, J.G. (TU Delft BT/Environmental Biotechnology); Kleerebezem, R. (TU Delft BT/Environmental Biotechnology); van Loosdrecht, Mark C.M. (TU Delft BT/Environmental Biotechnology)","","2017","Denitrification and dissimilatory reduction to ammonium (DNRA) are competing nitrate-reduction processes that entail important biogeochemical consequences for nitrogen retention/removal in natural and man-made ecosystems. The nature of the available carbon source and electron donor have been suggested to play an important role on the outcome of this microbial competition. In this study, the influence of lactate as fermentable carbon source on the competition for nitrate was investigated for varying ratios of lactate and nitrate in the influent (Lac/N ratio). The study was conducted in an open chemostat culture, enriched from activated sludge, under strict anoxia. The mechanistic explanation of the conversions observed was based on integration of results from specific batch tests with biomass from the chemostat, molecular analysis of the biomass enriched, and a computational model. At high Lac/N ratio (2.97 mol/mol) both fermentative and respiratory nitrate reduction to ammonium occurred, coupled to partial oxidation of lactate to acetate, and to acetate oxidation respectively. Remaining lactate was fermented to propionate and acetate. At a decreased Lac/N ratio (1.15 mol/mol), the molar percentage of nitrate reduced to ammonium decreased to 58%, even though lactate was supplied in adequate amounts for full ammonification and nitrate remained the growth limiting compound. Data evaluation at this Lac/N ratio suggested conversions were comparable to the higher Lac/N ratio, except for lactate oxidation to acetate that was coupled to denitrification instead of ammonification. Respiratory DNRA on acetate was likely catalyzed by two Geobacter species related to G. luticola and G. lovleyi. Two Clostridiales members were likely responsible for lactate fermentation and partial lactate fermentation to acetate coupled to fermentative DNRA. An organism related to Propionivibrio militaris was identified as the organism likely responsible for denitrification. The results of this study clearly show that not only the ratio of available substrates, but also the nature of the electron donor influences the outcome of competition between DNRA and denitrification. Apparently, fermentative bacteria are competitive for the electron donor and thereby alter the ratio of available substrates for nitrate reduction.","chemostat; denitrification; dissimilatory nitrate reduction; DNRA; Lac/N-ratio; OA-Fund TU Delft","en","journal article","","","","","","","","","","","BT/Industriele Microbiologie","","",""
"uuid:88eab238-008c-4717-81e6-64db21b640cc","http://resolver.tudelft.nl/uuid:88eab238-008c-4717-81e6-64db21b640cc","Role of nitrite in the competition between denitrification and DNRA in a chemostat enrichment culture","van den Berg, E.M. (TU Delft BT/Environmental Biotechnology); Rombouts, J.L. (TU Delft BT/Environmental Biotechnology); Kuenen, J.G. (TU Delft BT/Environmental Biotechnology); Kleerebezem, R. (TU Delft BT/Environmental Biotechnology); van Loosdrecht, Mark C.M. (TU Delft BT/Environmental Biotechnology)","","2017","Denitrification and dissimilatory nitrate reduction to ammonium (DNRA) are two microbial processes that compete for oxidized nitrogen compounds in the environment. The objective of this work was to determine the role of nitrite versus nitrate as terminal electron acceptor on the competition between DNRA and denitrification. Initially, a mixed culture chemostat was operated under nitrate limitation and performed DNRA. Stepwise, the influent nitrate was replaced with nitrite until nitrite was the sole electron acceptor and N-source present. Despite changing the electron acceptor from nitrate to nitrite, the dominant process remained DNRA and the same dominant organism closely related to Geobacter lovleyi was identified. Contrary to previous studies conducted with a complex substrate in marine microbial communities, the conclusion of this work is that nitrate versus nitrite as electron acceptor does not generally control the competition between DNRA and denitrification. Our results show that the effect of this ratio must be interpreted in combination with other environmental factors, such as the type and complexity of the electron donor, pH, or sulfide concentrations.","chemostat; enrichment; DNRA; dissimilatory nitrate reduction; denitrification","en","journal article","","","","","","","","","","","BT/Environmental Biotechnology","","",""
"uuid:96040c15-2f38-41fb-bf64-4a669ca47cfa","http://resolver.tudelft.nl/uuid:96040c15-2f38-41fb-bf64-4a669ca47cfa","DNRA and Denitrification Coexist over a Broad Range of Acetate/N-NO3− Ratios, in a Chemostat Enrichment Culture","van den Berg, E.M. (TU Delft BT/Environmental Biotechnology); Boleij, M. (TU Delft BT/Environmental Biotechnology); Kuenen, J.G. (TU Delft BT/Environmental Biotechnology); Kleerebezem, R. (TU Delft BT/Environmental Biotechnology); van Loosdrecht, Mark C.M. (TU Delft BT/Environmental Biotechnology)","","2016","Denitrification and dissimilatory nitrate reduction to ammonium (DNRA) compete for nitrate in natural and engineered environments. A known important factor in this microbial competition is the ratio of available electron donor and elector acceptor, here expressed as Ac/N ratio (acetate/nitrate-nitrogen). We studied the impact of the Ac/N ratio on the nitrate reduction pathways in chemostat enrichment cultures, grown on acetate mineral medium. Stepwise, conditions were changed from nitrate limitation to nitrate excess in the system by applying a variable Ac/N ratio in the feed. We observed a clear correlation between Ac/N ratio and DNRA activity and the DNRA population in our reactor. The DNRA bacteria dominated under nitrate limiting conditions in the reactor and were outcompeted by denitrifiers under limitation of acetate. Interestingly, in a broad range of Ac/N ratios a dual limitation of acetate and nitrate occurred with co-occurrence of DNRA bacteria and denitrifiers. To explain these observations, the system was described using a kinetic model. The model illustrates that the Ac/N effect and concomitant broad dual limitation range related to the difference in stoichiometry between both processes, as well as the differences in electron donor and acceptor affinities. Population analysis showed that the presumed DRNA-performing bacteria were the same under nitrate limitation and under dual limiting conditions, whereas the presumed denitrifying population changed under single and dual limitation conditions.","chemostat; denitrification; dissimilatory nitrate reduction; DNRA; Ac/N-ratio; OA-Fund TU Delft","en","journal article","","","","","","","","","","","BT/Environmental Biotechnology","","",""
"uuid:973ebd51-3fd7-43ba-b976-6bcb447b0c34","http://resolver.tudelft.nl/uuid:973ebd51-3fd7-43ba-b976-6bcb447b0c34","Physiological and genomic features of highly alkaliphilic hydrogen-utilizing Betaproteobacteria from a continental serpentinizing site","Suzuki, S.; Kuenen, J.G.; Schipper, K.; Van der Velde, S.; Ishii, S.; Wu, A.; Sorokin, D.Y.; Tenney, A.; Meng, X.Y.; Morrill, P.L.; Kamagata, Y.; Muyzer, G.; Nealson, K.H.","","2014","Serpentinization, or the aqueous alteration of ultramafic rocks, results in challenging environments for life in continental sites due to the combination of extremely high pH, low salinity and lack of obvious electron acceptors and carbon sources. Nevertheless, certain Betaproteobacteria have been frequently observed in such environments. Here we describe physiological and genomic features of three related Betaproteobacterial strains isolated from highly alkaline (pH 11.6) serpentinizing springs at The Cedars, California. All three strains are obligate alkaliphiles with an optimum for growth at pH 11 and are capable of autotrophic growth with hydrogen, calcium carbonate and oxygen. The three strains exhibit differences, however, regarding the utilization of organic carbon and electron acceptors. Their global distribution and physiological, genomic and transcriptomic characteristics indicate that the strains are adapted to the alkaline and calcium-rich environments represented by the terrestrial serpentinizing ecosystems. We propose placing these strains in a new genus ‘Serpentinomonas’.","","en","journal article","Nature Publishing Group","","","","","","","","Applied Sciences","BT/Biotechnology","","","",""
"uuid:744a0377-b8f0-461a-a591-803ac94f85c8","http://resolver.tudelft.nl/uuid:744a0377-b8f0-461a-a591-803ac94f85c8","Mariprofundus ferrooxydans PV-1 the First Genome of a Marine Fe(II) Oxidizing Zetaproteobacterium","Singer, E.; Emerson, D.; Webb, E.A.; Barco, R.A.; Kuenen, J.G.; Nelson, W.C.; Chan, C.S.; Comolli, L.R.; Ferriera, S.","","2011","Mariprofundus ferrooxydans PV-1 has provided the first genome of the recently discovered Zetaproteobacteria subdivision. Genome analysis reveals a complete TCA cycle, the ability to fix CO2, carbon-storage proteins and a sugar phosphotransferase system (PTS). The latter could facilitate the transport of carbohydrates across the cell membrane and possibly aid in stalk formation, a matrix composed of exopolymers and/or exopolysaccharides, which is used to store oxidized iron minerals outside the cell. Two-component signal transduction system genes, including histidine kinases, GGDEF domain genes, and response regulators containing CheY-like receivers, are abundant and widely distributed across the genome. Most of these are located in close proximity to genes required for cell division, phosphate uptake and transport, exopolymer and heavy metal secretion, flagellar biosynthesis and pilus assembly suggesting that these functions are highly regulated. Similar to many other motile, microaerophilic bacteria, genes encoding aerotaxis as well as antioxidant functionality (e.g., superoxide dismutases and peroxidases) are predicted to sense and respond to oxygen gradients, as would be required to maintain cellular redox balance in the specialized habitat where M. ferrooxydans resides. Comparative genomics with other Fe(II) oxidizing bacteria residing in freshwater and marine environments revealed similar content, synteny, and amino acid similarity of coding sequences potentially involved in Fe(II) oxidation, signal transduction and response regulation, oxygen sensation and detoxification, and heavy metal resistance. This study has provided novel insights into the molecular nature of Zetaproteobacteria.","","en","journal article","Public Library of Science","","","","","","","","Applied Sciences","Biotechnology","","","",""
"uuid:38e974ed-81d4-47b8-a290-a7f5723bd00e","http://resolver.tudelft.nl/uuid:38e974ed-81d4-47b8-a290-a7f5723bd00e","The microbial sulfur cycle at extremely haloalkaline conditions of soda lakes","Sorokin, D.Y.; Kuenen, J.G.; Muyzer, G.","","2011","Soda lakes represent a unique ecosystem with extremely high pH (up to 11) and salinity (up to saturation) due to the presence of high concentrations of sodium carbonate in brines. Despite these double extreme conditions, most of the lakes are highly productive and contain a fully functional microbial system. The microbial sulfur cycle is among the most active in soda lakes. One of the explanations for that is high-energy efficiency of dissimilatory conversions of inorganic sulfur compounds, both oxidative and reductive, sufficient to cope with costly life at double extreme conditions. The oxidative part of the sulfur cycle is driven by chemolithoautotrophic haloalkaliphilic sulfur-oxidizing bacteria (SOB), which are unique for soda lakes. The haloalkaliphilic SOB are present in the surface sediment layer of various soda lakes at high numbers of up to 106 viable cells/cm3. The culturable forms are so far represented by four novel genera within the Gammaproteobacteria, including the genera Thioalkalivibrio, Thioalkalimicrobium, Thioalkalispira, and Thioalkalibacter. The latter two were only found occasionally and each includes a single species, while the former two are widely distributed in various soda lakes over the world. The genus Thioalkalivibrio is the most physiologically diverse and covers the whole spectrum of salt/pH conditions present in soda lakes. Most importantly, the dominant subgroup of this genus is able to grow in saturated soda brines containing 4 M total Na+ – a so far unique property for any known aerobic chemolithoautotroph. Furthermore, some species can use thiocyanate as a sole energy source and three out of nine species can grow anaerobically with nitrogen oxides as electron acceptor. The reductive part of the sulfur cycle is active in the anoxic layers of the sediments of soda lakes. The in situ measurements of sulfate reduction rates and laboratory experiments with sediment slurries using sulfate, thiosulfate, or elemental sulfur as electron acceptors demonstrated relatively high sulfate reduction rates only hampered by salt-saturated conditions. However, the highest rates of sulfidogenesis were observed not with sulfate, but with elemental sulfur followed by thiosulfate. Formate, but not hydrogen, was the most efficient electron donor with all three sulfur electron acceptors, while acetate was only utilized as an electron donor under sulfur-reducing conditions. The native sulfidogenic populations of soda lakes showed a typical obligately alkaliphilic pH response, which corresponded well to the in situ pH conditions. Microbiological analysis indicated a domination of three groups of haloalkaliphilic autotrophic sulfate-reducing bacteria belonging to the order Desulfovibrionales (genera Desulfonatronovibrio, Desulfonatronum, and Desulfonatronospira) with a clear tendency to grow by thiosulfate disproportionation in the absence of external electron donor even at salt-saturating conditions. Few novel representatives of the order Desulfobacterales capable of heterotrophic growth with volatile fatty acids and alcohols at high pH and moderate salinity have also been found, while acetate oxidation was a function of a specialized group of haloalkaliphilic sulfur-reducing bacteria, which belong to the phylum Chrysiogenetes.","sulfur-oxidizing bacteria; sulfidogenesis; sulfate-reducing bacteria; sulfur reduction; thiosulfate reduction; soda lakes","en","journal article","Frontiers","","","","","","","","Applied Sciences","Biotechnology","","","",""
"uuid:00eb56c7-f39f-49e3-8576-8e75b70ef473","http://resolver.tudelft.nl/uuid:00eb56c7-f39f-49e3-8576-8e75b70ef473","The importance of cooling of urine samples for doping analysis","Kuenen, J.G.; Konings, W.N.","","2009","Storing and transporting of urine samples for doping analysis, as performed by the anti-doping organizations associated with the World Anti-Doping Agency, does not include a specific protocol for cooled transport from the place of urine sampling to the doping laboratory, although low cost cooling facilities can easily be made available. As a result, microbial and thermal degradation of the chemical substances in the urine may occur, which may lead to false negative or false positive results in the subsequent doping analysis. This scientifically and morally unacceptable practice is still maintained in spite of publications demonstrating that immediate cooling is an absolute requirement. Given the enormous societal consequences of positive tests, the lack of a controllable chain of custody during transport should be outlawed. This paper proposes a simple method, based on immediate cooling and cooled transport, which can easily be implemented in developed countries at low cost.","Urine analysis; Bacterial contamination; Doping analysis; Anti-doping organization","en","journal article","Springer","","","","","","","","Applied Sciences","Biotechnology","","","",""
"uuid:8e0a0d21-6a70-48f4-b744-9d6ae39d3c83","http://resolver.tudelft.nl/uuid:8e0a0d21-6a70-48f4-b744-9d6ae39d3c83","Influence of salts and pH on growth and activity of a novel facultatively alkaliphilic, extremely salt-tolerant, obligately chemolithoautotrophic sufur-oxidizing Gammaproteobacterium Thioalkalibacter halophilus gen. nov., sp. nov. from South-Western Siberian soda lakes","Banciu, H.L.; Sorokin, D.Y.; Tourova, T.P.; Galinski, E.A.; Muntyan, M.S.; Kuenen, J.G.; Muyzer, G.","","2008","A chemolithoautotrophic sulfur-oxidizing bacterium (SOB) strain ALCO 1 capable of growing at both near-neutral and extremely alkaline pH was isolated from hypersaline soda lakes in S-W Siberia (Altai, Russia). Strain ALCO 1 represents a novel separate branch within the halothiobacilli in the Gammaproteobacteria, which, so far, contained only neutro-halophilic SOB. On the basis of its unique phenotypic properties and distant phylogeny, strain ALCO 1 is proposed as a new genus and species Thioalkalibacter halophilus gen. nov. sp. nov. ALCO 1 was able to grow within a broad range of salinity (0.5–3.5 M of total sodium) with an optimum at around 1 M Na+, and pH (7.2–10.2, pHopt at around 8.5). Na+ was required for sulfur-dependent respiration in ALCO 1. The neutral (NaCl)-grown chemostat culture had a much lower maximum growth rate (?max), respiratory activity and total cytochrome c content than its alkaline-grown counterpart. The specific concentration of osmolytes (ectoine and glycine-betaine) produced at neutral pH and 3 M NaCl was roughly two times higher than at pH 10 in soda. Altogether, strain ALCO 1 represents an interesting chemolithoautotrophic model organism for comparative investigations of bacterial adaptations to high salinity and pH.","Haloalkaliphilic; Halothiobacillus; Soda lakes; Sulfur-oxidizing bacteria; Thioalkalibacter halophilus","en","journal article","Springer","","","","","","","","Applied Sciences","Department of Biotechnology","","","",""
"uuid:aeafde1b-658d-4b27-87f8-8f8f0913373b","http://resolver.tudelft.nl/uuid:aeafde1b-658d-4b27-87f8-8f8f0913373b","Competition and coexistence of sulfate-reducing bacteria, acetogens and methanogens in a lab-scale anaerobic bioreactor as affected by changing substrate to sulfate ratio","Dar, S.A.; Kleerebezem, R.; Stams, A.J.M.; Kuenen, J.G.; Muyzer, G.","","2008","The microbial population structure and function of natural anaerobic communities maintained in lab-scale continuously stirred tank reactors at different lactate to sulfate ratios and in the absence of sulfate were analyzed using an integrated approach of molecular techniques and chemical analysis. The population structure, determined by denaturing gradient gel electrophoresis and by the use of oligonucleotide probes, was linked to the functional changes in the reactors. At the influent lactate to sulfate molar ratio of 0.35 mol mol?1, i.e., electron donor limitation, lactate oxidation was mainly carried out by incompletely oxidizing sulfate-reducing bacteria, which formed 80–85% of the total bacterial population. Desulfomicrobium- and Desulfovibriolike species were the most abundant sulfate-reducing bacteria. Acetogens and methanogenic Archaea were mostly outcompeted, although less than 2% of an acetogenic population could still be observed at this limiting concentration of lactate. In the near absence of sulfate (i.e., at very high lactate/sulfate ratio), acetogens and methanogenic Archaea were the dominant microbial communities. Acetogenic bacteria represented by Dendrosporobacter quercicolus-like species formed more than 70% of the population, while methanogenic bacteria related to uncultured Archaea comprising about 10–15% of the microbial community. At an influent lactate to sulfate molar ratio of 2 mol mol?1, i.e., under sulfate-limiting conditions, a different metabolic route was followed by the mixed anaerobic community. Apparently, lactate was fermented to acetate and propionate, while the majority of sulfidogenesis and methanogenesis were dependent on these fermentation products. This was consistent with the presence of significant levels (40–45% of total bacteria) of D.quercicolus-like heteroacetogens and a corresponding increase of propionate-oxidizing Desulfobulbus-like sulfate-reducing bacteria (20% of the total bacteria). Methanogenic Archaea accounted for 10% of the total microbial community.","anaerobic consortia; DGGE; FISH; acetogens; methanogens; sulfate-reducing bacteria","en","journal article","Springer","","","","","","","","Applied Sciences","Biotechnology","","","",""
"uuid:23f0e500-f62d-4a84-b58a-781fb4da4721","http://resolver.tudelft.nl/uuid:23f0e500-f62d-4a84-b58a-781fb4da4721","Effects of Deposition of Heavy-Metal-Polluted Harbor Mud on Microbial Diversity and Metal Resistance in Sandy Marine Sediments","Toes, A.C.M.; Finke, N.; Kuenen, J.G.; Muyzer, G.","","2008","Deposition of dredged harbor sediments in relatively undisturbed ecosystems is often considered a viable option for confinement of pollutants and possible natural attenuation. This study investigated the effects of deposition of heavy-metal-polluted sludge on the microbial diversity of sandy sediments during 12 months of mesocosm incubation. Geochemical analyses showed an initial increase in pore-water metal concentrations, which subsided after 3 months of incubation. No influence of the deposited sediment was observed in denaturing gradient gel electrophoresis (DGGE) profiles of bacterial 16S rRNA genes, whereas a minor, transient impact on the archaeal community was revealed. Phylogenetic analyses of bacterial 16S rRNA clone libraries showed an abundance of members of the Flavobacteriaceae, the ?- and ?-Proteobacteria, in both the muddy and the sandy sediments. Despite the finding that some groups of clones were shared between the metal-impacted sandy sediment and the harbor control, comparative analyses showed that the two sediments were significantly different in community composition. Consequences of redeposition of metal-polluted sediment were primarily underlined with cultivation-dependent techniques. Toxicity tests showed that the percentage of Cd- and Cu-tolerant aerobic heterotrophs was highest among isolates from the sandy sediment with metal-polluted mud on top.","","en","journal article","Springer","","","","","","","","Applied Sciences","Biotechnology","","","",""
"uuid:50f77f09-958a-431c-84fd-f2b1aa3bd7fd","http://resolver.tudelft.nl/uuid:50f77f09-958a-431c-84fd-f2b1aa3bd7fd","Bacterial diversity and activity along a salinity gradient in soda lakes of the Kulunda Steppe (Altai, Russia)","Foti, M.J.; Sorokin, D.Y.; Zacharova, E.E.; Pimenov, N.V.; Kuenen, J.G.; Muyzer, G.","","2007","Here we describe the diversity and activity of sulfate reducing bacteria along a salinity gradient in four different soda lakes from the Kulunda Steppe (South East Siberia, Russia). For this purpose, a combination of culture-dependent and independent techniques was applied. The general bacterial and SRB diversity were analyzed by denaturing gradient gel electrophoresis (DGGE) targeting the 16S rDNA gene. DNA was used to detect the microbial populations that were present in the soda lake sediments, whereas ribosomal RNA was used as a template to obtain information on those that were active. Individual DGGE bands were sequenced and a phylogenetic analysis was performed. In addition, the overall activity of SRB was obtained by measuring the sulfate reduction rates (SRR) and their abundance was estimated by serial dilution. Our results showed the presence of minor, but highly active microbial populations, mostly represented by members of the Proteobacteria. Remarkably high SRR were measured at hypersaline conditions (200 g L-1). A relatively high viable count indicated that sulfate reducing bacteria could be highly active in hypersaline soda lakes. Furthermore, the increase of sodium carbonate/bicarbonate seemed to affect the composition of the microbial community in soda lakes, but not the rate of sulfate reduction.","","en","journal article","Springer","","","","","","","","Applied Sciences","Biotechnology","","","",""
"uuid:00b6c1be-422a-4077-83af-95771ec20116","http://resolver.tudelft.nl/uuid:00b6c1be-422a-4077-83af-95771ec20116","Co-existence of physiologically similar sulfate-reducing bacteria in a full-scale sulfidogenic bioreactor fed with a single organic electron donor","Dar, S.A.; Stams, A.J.M.; Kuenen, J.G.; Muyzer, G.","","2007","","Sulfate-reducing bacteria; Microbial ecology; Ecological niches","en","journal article","Springer","","","","","","","","Applied Sciences","","","","",""
"uuid:a1ad4ed0-cb0b-4c7f-b211-d8642dfeddbf","http://resolver.tudelft.nl/uuid:a1ad4ed0-cb0b-4c7f-b211-d8642dfeddbf","Microbiologie is mijn hobby","Kuenen, J.G.","","2005","","Uittreerede","nl","public lecture","","","","","","","","","","","","","",""
"uuid:c91b2d73-75ae-4b98-81eb-dae2ef236282","http://resolver.tudelft.nl/uuid:c91b2d73-75ae-4b98-81eb-dae2ef236282","Nested PCR-Denaturing Gradient Gel Electrophoresis Approach To Determine the Diversity of Sulfate-Reducing Bacteria in Complex Microbial Communities","Dar, S.A.; Kuenen, J.G.; Muyzer, G.","","2005","","","en","journal article","American Society for Microbiology","","","","","","","","","","","","",""
"uuid:1a357676-ecac-4780-a10a-b7e7c4c223d5","http://resolver.tudelft.nl/uuid:1a357676-ecac-4780-a10a-b7e7c4c223d5","Biomarkers for In Situ Detection of Anaerobic Ammonium-Oxidizing (Anammox) Bacteria","Schmid, M.C.; Maas, B.; Dapena, A.; van de Pas-Schoonen, K.; van de Vossenberg, J.; Kartal, B.; van Niftrik, L.; Schmid, I.; Cirpus, I.; Kuenen, J.G.; Wagner, M.; Sinninghe Damste, J.S.; Kuypers, M.; Revsbech, N.P.; Mendez, R.; Jetten, M.S.M.; Strous, M.","","2005","","","en","journal article","American Society for Microbiology","","","","","","","","","","","","",""
"uuid:9986086d-04d7-48b7-af28-063486e24dee","http://resolver.tudelft.nl/uuid:9986086d-04d7-48b7-af28-063486e24dee","Anaerobic growth of the haloalkaliphilic denitrifying sulfur-oxidizing bacterium Thialkalivibrio thiocyanodenitrificans sp. nov. with thiocyanate","Sorokin, D.Yu.; Tourova, T.P.; Antipov, A.N.; Muyzer, G.; Kuenen, J.G.","","2004","","","en","journal article","General Society for Microbiology","","","","","","","","Applied Sciences","","","","",""
"uuid:be8bd50d-8280-4f5d-ab48-5d71463a0a01","http://resolver.tudelft.nl/uuid:be8bd50d-8280-4f5d-ab48-5d71463a0a01","Thialkalivibrio nitratireducens sp. nov., a nitrate-reducing member of an autotrophic denitrifying consortium from a soda lake","Sorokin, D.Yu.; Tourova, T.P.; Sjollema, K.A.; Kuenen, J.G.","","2003","","","en","journal article","Society for General Microbiology","","","","","","","","","","","","",""
"uuid:b6029079-baf9-4bff-a08d-7f7249a1bcda","http://resolver.tudelft.nl/uuid:b6029079-baf9-4bff-a08d-7f7249a1bcda","Thioalkalimicrobium aerophilum gen. nov., sp. nov. and Thioalkalimicrobium sibericum sp. nov., and Thioalkalivibrio versutus gen. nov., sp. nov., Thioalkalivibrio nitratis sp. nov. and Thioalkalivibrio denitrificans sp. nov., novel obligately alkaliphilic and obligately chemolithoautotrophic sulfur-oxidizing bacteria from soda lakes","Sorokin, D.Yu.; Lysenko, A.M.; Mityushina, L.L.; Tourova, T.P.; Jones, B.E.; Rainey, F.A.; Robertson, L.A.; Kuenen, G.J.","","2001","","","en","journal article","Society for General Microbiology","","","","","","","","","","","","",""
"uuid:25102210-b8f6-4c0e-8629-be17b45f7459","http://resolver.tudelft.nl/uuid:25102210-b8f6-4c0e-8629-be17b45f7459","Over leven en technologie","Kuenen, J.G.","","2000","","158ste Dies Natalis 2000","nl","public lecture","","","","","","","","","","","","","",""
"uuid:a39a72a0-e44b-4eb2-ad30-e1bafeaef61a","http://resolver.tudelft.nl/uuid:a39a72a0-e44b-4eb2-ad30-e1bafeaef61a","Key Physiology of Anaerobic Ammonium Oxidation","Strous, M.; Kuenen, J.G.; Jetten, M.S.","","1999","","","en","journal article","American Society for Microbiology","","","","","","","","","","","","",""
"uuid:e2a3db86-75ed-41c1-8ef5-60fb3a26790b","http://resolver.tudelft.nl/uuid:e2a3db86-75ed-41c1-8ef5-60fb3a26790b","Nitrogen, Carbon, and Sulfur Metabolism in Natural Thioploca Samples","Otte, S.; Kuenen, J.G.; Nielsen, L.P.; Paerl, H.W.; Zopfi, J.; Schulz, H.N.; Teske, A.; Strotmann, B.; Gallardo, V.A.; Jorgensen, B.B.","","1999","","","en","journal article","American Society for Microbiology","","","","","","","","","","","","",""
"uuid:b74dd5d2-0437-48ef-9596-e4120c58f579","http://resolver.tudelft.nl/uuid:b74dd5d2-0437-48ef-9596-e4120c58f579","A Design Strategy for Low-Power Low-Voltage Integrated Transconductance Amplifiers","Kuenen, J.C.","Davidse, J. (promotor)","1997","","analog amplifiers; low power; structured electronic design","en","doctoral thesis","Delft University Press","","","","","","","","Electrical Engineering, Mathematics and Computer Science","","","","",""
"uuid:16bc55b9-68ef-4a83-8559-338687f51f69","http://resolver.tudelft.nl/uuid:16bc55b9-68ef-4a83-8559-338687f51f69","Metabolic pathway of anaerobic ammonium oxidation on the basis of 15N studies in a fluidized bed reactor","Van de Graaf, A.A.; De Bruijn, P.; Robertson, L.A.; Jetten, M.S.M.; Kuenen, J.G.","","1997","","Microbial activity Ammonium Oxidation Anaerobiosis Metabolic pathway Nitrites Hydroxylamine Hydrazine Bioreactor Fluidized bed reactor Batchwise Activite microbienne Ammonium Oxydation Anaerobiose Voie metabolique Nitrite Hydroxylamine Hydrazine Bioreacte; oxidation","en","journal article","","","","","","","","","","","","","",""
"uuid:76a10663-8374-487b-8313-50054a86ddc6","http://resolver.tudelft.nl/uuid:76a10663-8374-487b-8313-50054a86ddc6","Ammonium removal from concentrated waste streams with the anaerobic ammonium oxidation (Anammox) process in different reactor configurations","Strous, M.; Van Gerven, E.; Zheng, P.; Kuenen, J.G.; Jetten, M.S.M.","","1997","","nitrogen removal nitrite nitrate wastewater fluidised bed fixed bed nitrogen removal water; oxidation","en","journal article","","","","","","","","","","","","","",""
"uuid:59af4dad-c9ea-4030-8596-73c0d5614968","http://resolver.tudelft.nl/uuid:59af4dad-c9ea-4030-8596-73c0d5614968","Low-power MOS integrated filter with transconductors with spoilt current sources","van de Gevel, M.; Kuenen, J.C.; Davidse, J.; Roermund, A.H.M.","","1997","","","en","journal article","IEEE","","","","","","","","","","","","",""
"uuid:889aa8f5-961f-46ce-ade3-f3404628c3bb","http://resolver.tudelft.nl/uuid:889aa8f5-961f-46ce-ade3-f3404628c3bb","Hydroxylamine metabolism in Pseudomonas PB16: Involvement of a novel hydroxylamine oxidoreductase","Jetten, M.S.M.; De Bruijn, P.; Kuenen, J.G.","","1997","","hydroxylamine nitrification aerobic denitrification Pseudomonas heterotrophic nitrification aerobic denitrification thiosphaera-pantotropha nitrosomonas-europaea heme","en","journal article","","","","","","","","","","","","","",""
"uuid:d4bb4d84-242a-48dc-bdcc-32ad40e0dbe7","http://resolver.tudelft.nl/uuid:d4bb4d84-242a-48dc-bdcc-32ad40e0dbe7","Sulfur production by obligately chemolithoautotrophic Thiobacillus species","Visser, J.M.; Robertson, L.A.; Van Varseveld, H.W.; Kuenen, J.G.","","1997","","hydrogen-sulfide oxidation bacteria removal oxygen; oxidation","en","journal article","","","","","","","","","","","","","",""
"uuid:4235f1a6-1bb8-4c10-9acb-2e78208badd7","http://resolver.tudelft.nl/uuid:4235f1a6-1bb8-4c10-9acb-2e78208badd7","Isolation of the tetrathionate hydrolase from Thiobacillus acidophilus","De Jong, G.A.H.; Hazeu, W.; Bos, P.; Kuenen, J.G.","","1997","","tetrathionate hydrolase Thiobacillus acidophilus sulfur metabolism polythionate reduced sulfur-compounds purification oxidation ferrooxidans thiosulfate proteins","en","journal article","","","","","","","","","","","","","",""
"uuid:3115f09d-467b-4b19-8b41-d883f9da2a9b","http://resolver.tudelft.nl/uuid:3115f09d-467b-4b19-8b41-d883f9da2a9b","Thiobacillus sp. W5, the dominant autotroph oxidizing sulfide to sulfur in a reactor for aerobic treatment of sulfidic wastes","Visser, J.M.; Stefess, G.C.; Robertson, L.A.; Kuenen, J.G.","","1997","","chemolithoautotrophic floating filters sulfide sulfur thiobacilli quantitative measurement bacteria cultures","en","journal article","","","","","","","","","","","","","",""
"uuid:4e4866f2-a0ec-4dcc-9a4b-fc827e486517","http://resolver.tudelft.nl/uuid:4e4866f2-a0ec-4dcc-9a4b-fc827e486517","Process for the purification of gases containing hydrogen sulfide","Buisman, C.J.N.; Sorokin, D.Y.; Kuenen, J.G.; Janssen, J.H.; Robertson, L.A.","","1997","","hydrogen sulfide removal gas bacteria","en","patent","","","","","","","","","","","","","",""
"uuid:f0a9c689-5068-4cf9-8b1d-f6ce8f3f6991","http://resolver.tudelft.nl/uuid:f0a9c689-5068-4cf9-8b1d-f6ce8f3f6991","Polythionate degradation by tetrathionate hydrolase of Thiobacillus ferrooxidans","De Jong, G.A.H.; Hazeu, W.; Bos, P.; Kuenen, J.G.","","1997","","Thiobacillus ferrooxidans polythionates tetrathionate hydrolase acidophilic bacteria sulfur metabolism reduced sulfur-compounds molecular composition oxidation acidophilus thiosulfate purification tepidarius metabolism cultures proteins","en","journal article","","","","","","","","","","","","","",""
"uuid:7e0a7f2b-e6f9-42cc-8c2a-33ef2a0d9a1f","http://resolver.tudelft.nl/uuid:7e0a7f2b-e6f9-42cc-8c2a-33ef2a0d9a1f","cbb(3)-type cytochrome oxidase in the obligately chemolithoautotrophic Thiobacillus sp. W5","Visser, J.M.; De Jong, G.A.H.; De Vries, S.; Robertson, L.A.; Kuenen, J.G.","","1997","","Thiobacillus Autotrophy Chemolithotrophy Respiratory chain Cytochrome c oxidase Thiobacillus Autotrophie Chimiolithotrophie Chaine respiratoire Cytochrome c oxidase Cytochrome cbb3 Thiobacillus Autotrofia Quimiolitotrofia Cadena respiratoria Cy","en","journal article","","","","","","","","","","","","","",""
"uuid:1b14f1b4-70c1-40b4-86e2-b8d9655dc68a","http://resolver.tudelft.nl/uuid:1b14f1b4-70c1-40b4-86e2-b8d9655dc68a","Effects of aerobic and microaerobic conditions on anaerobic ammonium-oxidizing (Anammox) sludge","Strous, M.; Van Gerven, E.; Kuenen, J.G.; Jetten, M.","","1997","","oxidation","en","journal article","","","","","","","","","","","","","",""
"uuid:8b0b8f77-6655-4bfc-aa14-62687ebb19e1","http://resolver.tudelft.nl/uuid:8b0b8f77-6655-4bfc-aa14-62687ebb19e1","Novel principles in the microbial conversion of nitrogen compounds","Jetten, M.S.M.; Logemann, S.; Muyzer, G.; Robertson, L.A.; De Vries, S.; Van Loosdrecht, M.C.M.; Kuenen, J.G.","","1997","","hydroxylamine anaerobic ammonium oxidation nitrification denitrification periplasmic nitrate reductase nitric-oxide reductase cytochrome-c-oxidase ammonium-oxidizing bacteria 16s ribosomal-rna thiosphaera-pantotropha nitrosomonas-europaea pseudomonas-stut","en","journal article","","","","","","","","","","","","","",""
"uuid:a180c59d-ca97-476c-a891-0fc4f64ced85","http://resolver.tudelft.nl/uuid:a180c59d-ca97-476c-a891-0fc4f64ced85","Competition for dimethyl sulfide and hydrogen sulfide by Methylophaga sulfidovorans and Thiobacillus thioparus T5 in continuous cultures","De Zwart, J.M.M.; Sluis, J.M.R.; Kuenen, J.G.","","1997","","microbial mats phytoplankton sulfur","en","journal article","","","","","","","","","","","","","",""
"uuid:97635cbf-d9d7-4053-9fe4-c15182e0dddb","http://resolver.tudelft.nl/uuid:97635cbf-d9d7-4053-9fe4-c15182e0dddb","Aerobic conversion of dimethyl sulfide and hydrogen sulfide by Methylophaga sulfidovorans: Implications for modeling DMS conversion in a microbial mat","De Zwart, J.M.M.; Kuenen, J.G.","","1997","","microbial mat dimethyl sulfide oxidation hydrogen sulfide oxidation compartment model Methylophaga sulfidovorans methylated sulfur-compounds dimethylsulfoniopropionate transformations consumption metabolism","en","journal article","","","","","","","","","","","","","",""
"uuid:7a7e6869-ee65-4187-b65d-cd045126ef02","http://resolver.tudelft.nl/uuid:7a7e6869-ee65-4187-b65d-cd045126ef02","A novel membrane-bound flavocytochrome c sulfide dehydrogenase from the colourless sulfur bacterium Thiobacillus sp. W5","Visser, J.M.; De Jong, G.A.H.; Robertson, L.A.; Kuenen, J.G.","","1997","","Thiobacillus sp W5; sulfide oxidation; sulfur formation; flavocytochrome c; Chlorobium limicola; Chromatium vinosum; Thiobacilli","en","journal article","","","","","","","","","","","","","",""
"uuid:fd4a0685-4292-4498-911f-9f85302e3291","http://resolver.tudelft.nl/uuid:fd4a0685-4292-4498-911f-9f85302e3291","Autotrophic growth of anaerobic ammonium-oxidizing microorganisms in a fluidized bed reactor","Van de Graaf, A.A.; De Bruijn, P.; Robertson, L.A.; Jetten, M.S.M.; Kuenen, J.G.","","1996","","ammonium oxidn microorganism growth","en","journal article","","","","","","","","","","","","","",""
"uuid:f41d4cf4-9008-4353-b418-90f5ab168c0a","http://resolver.tudelft.nl/uuid:f41d4cf4-9008-4353-b418-90f5ab168c0a","Isolation and characterization of Methylophaga sulfidovorans sp nov: An obligately methylotrophic, aerobic, dimethylsulfide oxidizing bacterium from a microbial mat","De Zwart, J.M.M.; Nelisse, P.N.; Kuenen, J.G.","","1996","","microbial mat dimethylsulfide oxidation Methylophaga sulfidovorans methylated sulfur-compounds salt-marsh sediments marine bacterium gen-nov sulfide dimethylsulfoniopropionate dehydrogenase metabolism methanol demethylation","en","journal article","","","","","","","","","","","","","",""
"uuid:f47a8adc-4e70-4f97-bedb-1a736e35a09e","http://resolver.tudelft.nl/uuid:f47a8adc-4e70-4f97-bedb-1a736e35a09e","Quantitative measurement of sulphur formation by steady-state and transient-state continuous cultures of autotrophic Thiobacillus species","Stefess, G.C.; Torremans, R.A.M.; De Schrijver, R.; Robertson, L.A.; Kuenen, J.G.","","1996","","oxidation; Thiobacillus Production Thiobacillus neapolitanus Application Waste water purification Sulfur Metabolism Sulfides Thiosulfates Oxidation Steady state Microorganism culture Performance evaluation Chemostat Environmental factor Continuous process Oxygen Com","en","journal article","","","","","","","","","","","","","",""
"uuid:1ed8dbc6-7635-4364-9cf1-84e428969da1","http://resolver.tudelft.nl/uuid:1ed8dbc6-7635-4364-9cf1-84e428969da1","Heat flux measurements for the fast monitoring of dynamic responses to glucose additions by yeasts that were subjected to different feeding regimes in continuous culture","Van Kleeff, B.H.A.; Kuenen, J.G.; Heijnen, J.J.","","1996","","glucose; saccharomyces-cerevisiae energy balances candida-utilis growth limitation substrate acid","en","journal article","","","","","","","","","","","","","",""
"uuid:9e6333c7-b3d2-4798-801c-9d3b8b2540dd","http://resolver.tudelft.nl/uuid:9e6333c7-b3d2-4798-801c-9d3b8b2540dd","Aerobic DMS degradation in microbial mats: The use of a newly isolated species Methylophaga sulfidovorans in the mathematical description of sulfur fluxes in mats","De Zwart, J.M.M.; Kuenen, J.G.","","1996","","dimethylsulfide degrdn Methyophaga","en","conference paper","","","","","","","","","","","","","",""
"uuid:fc7f1463-94f0-49c3-83d0-44081a473048","http://resolver.tudelft.nl/uuid:fc7f1463-94f0-49c3-83d0-44081a473048","Nitrous oxide production by Alcaligenes faecalis under transient and dynamic aerobic and anaerobic conditions","Otte, S.; Grobben, N.G.; Robertson, L.A.; Jetten, M.S.M.; Kuenen, J.G.","","1996","","heterotrophic nitrification paracoccus-denitrificans denitrifying bacteria continuous culture nitric-oxide oxygen transport reduction nitrate enzymes","en","journal article","","","","","","","","","","","","","",""
"uuid:72add51e-ac5f-4640-a7df-c20ce04c0519","http://resolver.tudelft.nl/uuid:72add51e-ac5f-4640-a7df-c20ce04c0519","Sulfur cycling in Catenococcus thiocyclus","Sorokin, D.Y.; Robertson, L.A.; Kuenen, J.G.","","1996","","oxidation; sulfur cycle Catenococcus thiocyclus thiosulfate tetrathionate sulfide heterotrophic bacteria thiosulfate oxidation growth","en","journal article","","","","","","","","","","","","","",""
"uuid:aaa95caf-7ac1-4261-986c-955935492ea8","http://resolver.tudelft.nl/uuid:aaa95caf-7ac1-4261-986c-955935492ea8","Purification and characterization of a periplasmic thiosulfate dehydrogenase from the obligately autotrophic Thiobacillus sp W5","Visser, J.M.; De Jong, G.A.H.; Robertson, L.A.; Kuenen, J.G.","","1996","","oxidation; Thiobacilli chemolithoautotrophy thiosulfate dehydrogenase thiosulfate tetrathionate cytochrome c respiratory chain oxidizing enzyme oxidation novellus growth resolution tepidarius proteins system cells","en","journal article","","","","","","","","","","","","","",""
"uuid:91ed5f4e-9aab-4209-9d2a-05698f73c515","http://resolver.tudelft.nl/uuid:91ed5f4e-9aab-4209-9d2a-05698f73c515","Nitrous oxide production by Alcaligenes faecalis under transient and dynamic aerobic and anaerobic conditions","Otte, S.; Grobben, N.G.; Robertson, L.A.; Jetten, M.S.; Kuenen, J.G.","","1996","","","en","journal article","American Society for Microbiology","","","","","","","","","","","","",""
"uuid:c0de7bca-2668-480c-934d-65d8904e1d03","http://resolver.tudelft.nl/uuid:c0de7bca-2668-480c-934d-65d8904e1d03","Nitrification, Denitrification and Growth in Artificial Thiosphaera-Pantotropha Biofilms as Measured with a Combined Microsensor for Oxygen and Nitrous-Oxide","Dalsgaard, T.; De Zwart, J.; Robertson, L.A.; Kuenen, J.G.; Revsbech, N.P.","","1995","","thiosphaera pantotropha heterotrophic nitrification denitrification growth biofilm immobilized cells heterotrophic nitrification aerobic denitrification acetylene sediments reduction water inhibition solubility diffusion seawater","en","journal article","","","","","","","","","","","","","",""
"uuid:fb0d838d-b6b9-464f-acdb-07c9f0b2ff21","http://resolver.tudelft.nl/uuid:fb0d838d-b6b9-464f-acdb-07c9f0b2ff21","Nitrification and denitrification by Thiosphaera pantotropha in aerobic chemostat cultures","Arts, P.A.M.; Robertson, L.A.; Kuenen, J.G.","","1995","","aerobic denitrification; heterotrophic nitrification; Thiosphaera pantotropha nitrogen; balance mass spectrometry; periplasmic nitrate; reductase paracoccus-denitrificans; bacterial denitrification; heterotrophic nitrifiers","en","journal article","Elsevier","","","","","","","","","","","","",""
"uuid:2fa4e9ca-24f0-4907-91da-7ba52fe13702","http://resolver.tudelft.nl/uuid:2fa4e9ca-24f0-4907-91da-7ba52fe13702","Confirmation of 'aerobic denitrification' in batch cultures, using gas chromatography and 15N mass spectrometry","Robertson, L.A.; Dalsgaard, T.; Revsbech, N.P.; Kuenen, J.G.","","1995","","Paracoccus denitrificans Alcaligenes faecalis Pseudomonas denitrificans Nitrogen Metabolism Aerobiosis Heterotrophy Denitrification Nitrification Mass spectrometry Gas chromatography Paracoccus denitrificans Alcaligenes faecalis Pseudomonas denitrificans","en","journal article","","","","","","","","","","","","","",""
"uuid:c31559ca-5786-41cb-a1fd-e51cd6a81185","http://resolver.tudelft.nl/uuid:c31559ca-5786-41cb-a1fd-e51cd6a81185","Growth of Nitrosomonas-Europaea on Hydroxylamine","De Bruijn, P.; Van de Graaf, A.A.; Jetten, M.S.M.; Robertson, L.A.; Kuenen, J.G.","","1995","","nitrosomonas europaea hydroxylamine growth yield nitrous oxide anaerobic growth nitrifying bacteria nitric-oxide impact no2 n2o","en","journal article","","","","","","","","","","","","","",""
"uuid:7f4eeacc-43e4-4392-8298-0953688dcb45","http://resolver.tudelft.nl/uuid:7f4eeacc-43e4-4392-8298-0953688dcb45","Effects of growth conditions on mitochondrial morphology in Saccharomyces cerevisiae","Visser, W.; Van Spronsen, E.A.; Nanninga, N.; Pronk, J.T.; Kuenen, J.G.; Van Dijken, J.P.","","1995","","Saccharomyces cerevisiae Mitochondria Morphology Metabolism Cell respiration Fermentation Environmental factor Ethanol Glucose Oxygen Yeast Saccharomyces cerevisiae Mitochondrie Morphologie Metabolisme Respiration cellulaire Fermentation Facteur milieu Et","en","journal article","","","","","","","","","","","","","",""
"uuid:4396f5f0-7944-41b6-92d4-5780247959ea","http://resolver.tudelft.nl/uuid:4396f5f0-7944-41b6-92d4-5780247959ea","Compartment Model for Biological Conversions of Dms in a Microbial Mat - Effect of pH on DMS Fluxes","De Zwart, J.M.M.; Kuenen, J.G.","","1995","","microbial mat mathematical model dimethylsulfide fluxes sulfur phytoplankton biofilms gases","en","journal article","","","","","","","","","","","","","",""
"uuid:763a4817-056a-4942-9e86-b3eab154cdc4","http://resolver.tudelft.nl/uuid:763a4817-056a-4942-9e86-b3eab154cdc4","Anaerobic Oxidation of Ammonium Is a Biologically Mediated Process","Van de Graaf, A.A.; Mulder, A.; De Bruijn, P.; Jetten, M.S.M.; Robertson, L.A.; Kuenen, J.G.","","1995","","nitrosomonas-europaea black-sea nitrite denitrification bacteria oxide; oxidation","en","journal article","","","","","","","","","","","","","",""
"uuid:371c6121-09f2-423d-8f2c-2ba7350f00d6","http://resolver.tudelft.nl/uuid:371c6121-09f2-423d-8f2c-2ba7350f00d6","Rapid Short-Term Poly-ß-Hydroxybutyrate Production by Thiosphaera-Pantotropha in the Presence of Excess Acetate","Van Niel, E.W.J.; Robertson, L.A.; Kuenen, J.G.","","1995","","thiosphaera pantotropha poly-beta-hydroxybutyrate batch excess acetate overflow electron transport chain aerobic denitrification heterotrophic nitrification limitation","en","journal article","","","","","","","","","","","","","",""
"uuid:93952a8e-d167-49d8-b277-77e0945d9740","http://resolver.tudelft.nl/uuid:93952a8e-d167-49d8-b277-77e0945d9740","Model-Based Optimization of Equipment and Control for Heat-Flux Measurements in a Laboratory Fermenter","Van Kleeff, B.H.A.; Kuenen, J.G.; Honderd, G.; Heijnen, S.J.","","1995","","","en","journal article","","","","","","","","","","","","","",""
"uuid:f359a226-ad83-420a-b20e-fca92bdc2afc","http://resolver.tudelft.nl/uuid:f359a226-ad83-420a-b20e-fca92bdc2afc","Anaerobic Ammonium Oxidation Discovered in a Denitrifying Fluidized-Bed Reactor","Mulder, A.; Van de Graaf, A.A.; Robertson, L.A.; Kuenen, J.G.","","1995","","ammonium removal anaerobiosis denitrification waste water nitrification denitrification bacteria; oxidation","en","journal article","","","","","","","","","","","","","",""
"uuid:4efa20a5-75c2-4ea9-8855-eab15e0cc52a","http://resolver.tudelft.nl/uuid:4efa20a5-75c2-4ea9-8855-eab15e0cc52a","Anaerobic oxidation of ammonium is a biologically mediated process","van de Graaf, A.A.; Mulder, A.; de Bruijn, P.; Jetten, M.S.; Robertson, L.A.; Kuenen, J.G.","","1995","","","en","journal article","American Society for Microbiology","","","","","","","","","","","","",""
"uuid:e3e5ba1d-c927-4349-a28f-b4af253f86cd","http://resolver.tudelft.nl/uuid:e3e5ba1d-c927-4349-a28f-b4af253f86cd","Methanol oxidation in a spontaneous mutant of Thiosphaera pantotropha with a methanol-positive phenotype is catalysed by a dye-linked ethanol dehydrogenase","Ras, J.; Hazelaar, M.J.; Robertson, L.A.; Kuenen, J.G.; Van Spanning, R.J.M.; Stouthamer, A.H.; Harms, N.","","1995","","oxidation; Paracoccus denitrificans Methanol Oxidation Metabolism Enzymatic activity Paracoccus denitrificans Methanol Oxydation Metabolisme Activite enzymatique Ethanol dehydrogenase Gene mxaF Paracoccus denitrificans Metanol Oxidacion Metabolismo Actividad enzimat","en","journal article","","","","","","","","","","","","","",""
"uuid:e8c2be28-89ab-4cba-bfa4-444c7a8fd1c2","http://resolver.tudelft.nl/uuid:e8c2be28-89ab-4cba-bfa4-444c7a8fd1c2","Isolation, Sequencing and Mutational Analysis of a Gene-Cluster Involved in Nitrite Reduction in Paracoccus-Denitrificans","De Boer, A.P.N.; Reijnders, W.N.M.; Kuenen, J.G.; Stouthamer, A.H.; Van Spanning, R.J.M.","","1994","","denitrification cd(1)-type nitrite reductase cytochrome c d(1) heme biosynthesis uroporphyrinogen iii methylase paracoccus denitrificans uroporphyrinogen-iii methyltransferase adenosyl-l-methionine nitrous-oxide reductase escherichia-coli pseudomonas-stut","en","journal article","","","","","","","","","","","","","",""
"uuid:3a78abf1-e28f-468a-9b59-398cabb0342d","http://resolver.tudelft.nl/uuid:3a78abf1-e28f-468a-9b59-398cabb0342d","Heterogeneity of biofilms in rotating annular reactors: Occurrence, structure, and consequences","Gjaltema, A.; Arts, P.A.M.; Van Loosdrecht, M.C.M.; Kuenen, J.G.; Heijnen, J.J.","","1994","","Biofilms Bioreactors Morphology Cell culture Biomass Growth kinetics Mathematical models Rotating machinery Mixing Flow of fluids Biofilm reactors Heterogeneity 461.2 (Biological Materials) 802.1 (Chemical Plants and Equipment) 461.8 (Biotechnology) 921.6","en","journal article","","","","","","","","","","","","","",""
"uuid:62198786-80ab-493e-9d26-ec081d261c64","http://resolver.tudelft.nl/uuid:62198786-80ab-493e-9d26-ec081d261c64","Thiobacillus ferrooxidans, a versatile mineworker","Bos, P.; Meulenberg, R.; Pronk, J.T.; Hazeu, W.; Kuenen, J.G.","","1994","","review Thiobacillus mine worker","en","conference paper","","","","","","","","","","","","","",""
"uuid:f84100b8-a40a-4ba5-872c-b864edb4f4ee","http://resolver.tudelft.nl/uuid:f84100b8-a40a-4ba5-872c-b864edb4f4ee","Distribution of Cultivated and Uncultivated Cyanobacteria and Chloroflexus-Like Bacteria in Hot-Spring Microbial Mats","Ruffroberts, A.L.; Kuenen, J.G.; Ward, D.M.","","1994","","ribosomal-rna sequences; inhabitants; community; hybridization; probes; growth; ph","en","journal article","","","","","","","","","","","","","",""
"uuid:9d4cad0d-0833-4a71-bc56-2573c7bc17e1","http://resolver.tudelft.nl/uuid:9d4cad0d-0833-4a71-bc56-2573c7bc17e1","Nitrogen Removal from Waste-Water","Kuenen, J.G.; Robertson, L.A.","","1994","","","en","conference paper","ELSEVIER SCIENCE PUBL B V","","","","","","","","","","","","",""
"uuid:2c18dbc2-563b-4f6a-83ff-ec16e06cb71c","http://resolver.tudelft.nl/uuid:2c18dbc2-563b-4f6a-83ff-ec16e06cb71c","Combined Nitrification-Denitrification Processes","Kuenen, J.G.; Robertson, L.A.","","1994","","nitrification denitrification n2o n-2 waste-water nitrosomonas-europaea nitrifying bacteria heterotrophic nitrification nitrobacter-agilis alcaligenes sp competition nitrifier ammonia nitrite n2o","en","journal article","","","","","","","","","","","","","",""
"uuid:3bf22122-8a6f-4b4e-906a-d786160f800e","http://resolver.tudelft.nl/uuid:3bf22122-8a6f-4b4e-906a-d786160f800e","The Role of the Efb Working Party on Education in the European Network","Kuenen, J.G.; Bennett, D.J.","","1994","","","en","conference paper","ELSEVIER SCIENCE PUBL B V","","","","","","","","","","","","",""
"uuid:22875b9c-6c2c-462a-a7ba-3b055eab4f4d","http://resolver.tudelft.nl/uuid:22875b9c-6c2c-462a-a7ba-3b055eab4f4d","A Review of Bioenergetics and Enzymology of Sulfur Compound Oxidation by Acidophilic Thiobacilli","Kuenen, J.G.; Pronk, J.T.; Hazeu, W.; Meulenberg, R.; Bos, P.","","1993","","oxidation","en","conference paper","MINERALS METALS & MATERIALS SOC","","","","","","","","","","","","",""
"uuid:e8c217b9-31bc-474e-b229-ef32832cbdd8","http://resolver.tudelft.nl/uuid:e8c217b9-31bc-474e-b229-ef32832cbdd8","A mathematical description of the behaviour of mixed chemostat cultures of an autotrophic nitrifier and a heterotrophic nitrifier/aerobic denitrifier; a comparison with experimental data","Van Niel, E.W.J.; Robertson, L.A.; Kuenen, J.G.","","1993","","Chemostat Aerobiosis Mathematical model Dissolved oxygen Concentration effect Interspecific competition Mixed microorganism culture Nitrosomonas europaea Chemostat Aerobiose Modele mathematique Oxygene dissous Effet concentration Competition interspecifiq","en","journal article","","","","","","","","","","","","","",""
"uuid:c4cad9cf-c9d2-4ae4-86ee-63d41726c456","http://resolver.tudelft.nl/uuid:c4cad9cf-c9d2-4ae4-86ee-63d41726c456","Interactions among bacteria metabolizing inorganic nitrogen compounds","Kuenen, J.G.; Robertson, L.A.","","1993","","nitrification, denitrification, dissimilatory nitrate reduction","en","conference paper","SPANISH SOCIETY MICROBIOLOGY","","","","","","","","","","","","",""
"uuid:a843f451-1cd5-4c96-916c-55ede2c11d0d","http://resolver.tudelft.nl/uuid:a843f451-1cd5-4c96-916c-55ede2c11d0d","Sulfide-Oxidizing Bacteria in the Burrowing Echinoid, Echinocardium-Cordatum (Echinodermata)","Temara, A.; De Ridder, C.; Kuenen, J.G.; Robertson, L.A.","","1993","","oxidation; riftia-pachyptila jones vent tube worm sea hydrothermal vents elemental sulfur rich habitats thiothrix oxidation beggiatoa detoxification accumulation","en","journal article","","","","","","","","","","","","","",""
"uuid:e8565466-4cfb-4137-8546-d7bf736fcd70","http://resolver.tudelft.nl/uuid:e8565466-4cfb-4137-8546-d7bf736fcd70","Purification and Partial Characterization of Thiosulfate Dehydrogenase from Thiobacillus-Acidophilus","Meulenberg, R.; Pronk, J.T.; Hazeu, W.; Van Dijken, J.P.; Frank, J.; Bos, P.; Kuenen, J.G.","","1993","","oxidation; sulfur-compounds thiosulfate tepidarius oxidation proteins growth","en","journal article","","","","","","","","","","","","","",""
"uuid:c9c8d61a-e74c-4c48-a4f5-d2483ae5857b","http://resolver.tudelft.nl/uuid:c9c8d61a-e74c-4c48-a4f5-d2483ae5857b","Continuous Measurement of Microbial Heat-Production in Laboratory Fermenters","Van Kleeff, B.H.A.; Kuenen, J.G.; Heijnen, J.J.","","1993","","microbial calorimetry heat of growth balances","en","journal article","","","","","","","","","","","","","",""
"uuid:798fb629-c4df-4548-898a-fcfac5d271b5","http://resolver.tudelft.nl/uuid:798fb629-c4df-4548-898a-fcfac5d271b5","Competition between Heterotrophic and Autotrophic Nitrifiers for Ammonia in Chemostat Cultures","Van Niel, E.W.J.; Arts, P.A.M.; Wesselink, B.J.; Robertson, L.A.; Kuenen, J.G.","","1993","","aerobic denitrification thiosphaera-pantotropha nitrosomonas-europaea c/n ratio oxygen tension thiosphaera-pantotropha aerobic denitrification nitrification bacteria","en","journal article","","","","","","","","","","","","","",""
"uuid:4413b235-a782-4b18-9429-7234bfc32a1c","http://resolver.tudelft.nl/uuid:4413b235-a782-4b18-9429-7234bfc32a1c","Experimental and Theoretical Discrepancies in Growth Yields of Acinetobacter-Calcoaceticus - a Correction of Published Data","Van Schie, B.J.; Pronk, J.T.; Van Dijken, J.P.; Kuenen, J.G.","","1993","","glucose","en","journal article","","","","","","","","","","","","","",""
"uuid:0304d657-171c-4df7-a008-e290f3e11491","http://resolver.tudelft.nl/uuid:0304d657-171c-4df7-a008-e290f3e11491","Metabolism of Tetrathionate in Thiobacillus-Acidophilus","Meulenberg, R.; Scheer, E.J.; Pronk, J.T.; Hazeu, W.; Bos, P.; Kuenen, J.G.","","1993","","thiobacillus acidophilus acidophile sulfur metabolism polythionate hydrolysis tetrathionate metabolism trithionate hydrolase reduced sulfur-compounds ferrooxidans oxidation cultures","en","journal article","","","","","","","","","","","","","",""
"uuid:8aade790-0b53-4d38-8ef6-6506b54297f8","http://resolver.tudelft.nl/uuid:8aade790-0b53-4d38-8ef6-6506b54297f8","Oxidation of reduced sulphur compounds by intact cells of Thiobacillus acidophilus","Meulenberg, R.; Pronk, J.T.; Hazeu, W.; Bos, P.; Kuenen, J.G.","","1992","","Theobacillus acidophilus; acidophilis; sulphur metabolism; sulphide; elemental sulphur; thiosulphate; tetrathionate; trithionate; sulphite","en","journal article","","","","","","","","","","","","","",""
"uuid:aca7232c-b577-4dc2-bbd0-b13e55b197fa","http://resolver.tudelft.nl/uuid:aca7232c-b577-4dc2-bbd0-b13e55b197fa","Anaerobic Growth of Thiobacillus-Ferrooxidans","Pronk, J.T.; De Bruyn, J.C.; Bos, P.; Kuenen, J.G.","","1992","","ferric iron reduction sulfur oxidation bacteria; oxidation","en","journal article","","","","","","","","","","","","","",""
"uuid:c0b5054d-413d-455c-8e52-7cd0d8721a82","http://resolver.tudelft.nl/uuid:c0b5054d-413d-455c-8e52-7cd0d8721a82","Inhibition of Denitrification and Oxygen Utilization by Thiosphaera-Pantotropha","Van Niel, E.W.J.; Robertson, L.A.; Cox, R.P.; Kuenen, J.G.","","1992","","paracoccus-denitrificans; aerobic denitrification; dissolved-gases oxide","en","journal article","","","","","","","","","","","","","",""
"uuid:408e5f86-a17e-4d36-99a3-6f1c30d775df","http://resolver.tudelft.nl/uuid:408e5f86-a17e-4d36-99a3-6f1c30d775df","Microbial Aldonolactone Formation and Hydrolysis - Kinetic and Bioenergetic Aspects","Noorman, H.J.; Rakels, J.L.L.; Kuenen, J.G.; Luyben, K.; Heijnen, J.J.","","1992","","acinetobacter-calcoaceticus invivo","en","journal article","","","","","","","","","","","","","",""
"uuid:87a571e2-a46f-4472-92e0-11be9a6fce01","http://resolver.tudelft.nl/uuid:87a571e2-a46f-4472-92e0-11be9a6fce01","Nitrogen removal from water and waste","Robertson, L.A.; Kuenen, J.G.","","1992","","review nitrogen removal water wastewater","en","conference paper","","","","","","","","","","","","","",""
"uuid:74bc7046-d5be-493b-8668-dfcace61c43b","http://resolver.tudelft.nl/uuid:74bc7046-d5be-493b-8668-dfcace61c43b","HIGH YIELD METHOD OF GROWING THIOBACILLUS FERROOXIDANS ON FORMATE","Pronk, J.T.; Van Dijken, J.P.; Bos, P.; Kuenen, J.G.","","1992","","","en","patent","European Patent Office","","","","","","","","Civil Engineering and Geosciences","","","","",""
"uuid:0c80176f-e3af-4a04-b3c0-541eb9160b27","http://resolver.tudelft.nl/uuid:0c80176f-e3af-4a04-b3c0-541eb9160b27","The Effect of Electron-Acceptor Variations on the Behavior of Thiosphaera-Pantotropha and Paracoccus-Denitrificans in Pure and Mixed Cultures","Robertson, L.A.; Kuenen, J.G.","","1992","","aerobic denitrification; oxygen; nitrate; nitrite; selection","en","journal article","","","","","","","","","","","","","",""
"uuid:07227fc0-37f8-46c3-8846-c8d3d2531dec","http://resolver.tudelft.nl/uuid:07227fc0-37f8-46c3-8846-c8d3d2531dec","C1-cycle of sulfur compounds: Microbial metabolism of C1-pollutants","De Zwart, J.M.M.; Kuenen, J.G.","","1992","","C1 organic sulfides; DMS; global sulfur cycle","en","journal article","","","","","","","","","","","","","",""
"uuid:6a6a1202-5f67-4e68-a1da-233ef3276266","http://resolver.tudelft.nl/uuid:6a6a1202-5f67-4e68-a1da-233ef3276266","The use of natural bacterial popolations for the treatment of sulphur-containing wastewater","Kuenen, J.G.; Robertson, L.A.; Rosenberg, E.; Rothschild, F.","","1992","","Waste water purification Sulfur Pollution Bacteria Sulfides Desulfurization Bioreactor Epuration eau usee Soufre Pollution Bacterie Sulfure Desulfuration Bioreacteur Depuracion aguas servidas Azufre Polucion Bacteria Sulfuro Desulfuracion Biorreactor Poll","en","journal article","","","","","","","","","","","","","",""
"uuid:84e48b6f-3335-437c-8c21-d15dc3b59c08","http://resolver.tudelft.nl/uuid:84e48b6f-3335-437c-8c21-d15dc3b59c08","Anaerobic Growth of Thiobacillus ferrooxidans","Pronk, J.T.; de Bruyn, J.C.; Bos, P.; Kuenen, J.G.","","1992","","","en","journal article","American Society for Microbiology","","","","","","","","","","","","",""
"uuid:7e7e7ff9-16c6-418d-8396-29c8140125f6","http://resolver.tudelft.nl/uuid:7e7e7ff9-16c6-418d-8396-29c8140125f6","Purification and partial characterization of a thermostable trithionate hydrolase from the acidophilic sulphur oxidizer Thiobacillus acidophilus","Meulenberg, R.; Pronk, J.T.; Frank, J.; Hazeu, W.; Bos, P.; Kuenen, J.G.","","1992","","","en","journal article","","","","","","","","","","","","","",""
"uuid:97374190-1e9e-43dc-bfc3-2e66b01e07cd","http://resolver.tudelft.nl/uuid:97374190-1e9e-43dc-bfc3-2e66b01e07cd","Heterotrophic Nitrification and Aerobic Denitrification in Alcaligenes-Faecalis Strain TUD","Van Niel, E.W.J.; Braber, K.J.; Robertson, L.A.; Kuenen, J.G.","","1992","","alcaligenes-faecalis; aerobe; chemostat; denitrification; heterotroph; nitrification","en","journal article","","","","","","","","","","","","","",""
"uuid:06eea8b2-089e-4f13-bf52-191bea129b63","http://resolver.tudelft.nl/uuid:06eea8b2-089e-4f13-bf52-191bea129b63","Growth of Thiobacillus-Ferrooxidans on Formic-Acid","Pronk, J.T.; Meijer, W.M.; Hazeu, W.; Van Dijken, J.P.; Bos, P.; Kuenen, J.G.","","1991","","acidophilic bacteria chemostat cultures formate chemolithotroph energetics methanol sulfur; oxidation","en","journal article","","","","","","","","","","","","","",""
"uuid:a731e4a2-2da0-4098-9c5e-8023309fb0ef","http://resolver.tudelft.nl/uuid:a731e4a2-2da0-4098-9c5e-8023309fb0ef","Growth of Thiobacillus ferrooxidans on Formic Acid","Pronk, J.T.; Meijer, W.M.; Hazeu, W.; van Dijken, J.P.; Bos, P.; Kuenen, J.G.","","1991","","","en","journal article","American Society for Microbiology","","","","","","","","","","","","",""
"uuid:5384ed65-66b1-4139-9cfe-d8bc3e5d2fa3","http://resolver.tudelft.nl/uuid:5384ed65-66b1-4139-9cfe-d8bc3e5d2fa3","Energy Transduction by Anaerobic Ferric Iron Respiration in Thiobacillus-Ferrooxidans","Pronk, J.T.; Liem, K.; Bos, P.; Kuenen, J.G.","","1991","","","en","journal article","","","","","","","","","","","","","",""
"uuid:715b313a-1dfb-4f5a-82a4-316f4f85d235","http://resolver.tudelft.nl/uuid:715b313a-1dfb-4f5a-82a4-316f4f85d235","Relative contributions of biological and chemical reactions to the overall rate of pyrite oxidation at temperatures between 30C and 70C","Boogerd, F.C.; Van den Beemd, C.; Stoelwinder, T.; Bos, P.; Kuenen, J.G.","","1991","","Oxidation Pyrite Iron III Sulfides Rate constant Reaction mechanism Kinetic model Bacteria Bioreactor Oxydation Pyrite Fer III Sulfure Constante vitesse Mecanisme reaction Modele cinetique Bacterie Bioreacteur Oxidacion Pirita Hierro III Sulfuro Constante","en","journal article","","","","","","","","","","","","","",""
"uuid:f7d6dba0-3b8a-4d62-96c0-cb77d15edf6d","http://resolver.tudelft.nl/uuid:f7d6dba0-3b8a-4d62-96c0-cb77d15edf6d","Energy Transduction by Anaerobic Ferric Iron Respiration in Thiobacillus ferrooxidans","Pronk, J.T.; Liem, K.; Bos, P.; Kuenen, J.G.","","1991","","","en","journal article","American Society for Microbiology","","","","","","","","","","","","",""
"uuid:76d51dce-708b-47f7-a2e3-52b7f0c53998","http://resolver.tudelft.nl/uuid:76d51dce-708b-47f7-a2e3-52b7f0c53998","Energetics of mixotrophic and autotrophic C1-metabolism by Thiobacillus acidophilus","Pronk, J.T.; De Bruijn, P.; Van Dijken, J.P.; Bos, P.; Kuenen, J.G.","","1990","","Bacteria Mixotrophy Autotrophy Monocarbon compound Energy metabolism Enzyme Enzymatic activity Microorganism growth Bacterie Mixotrophie Autotrophie Compose monocarbone Metabolisme energetique Enzyme Activite enzymatique Multiplication microorganisme Thio","en","journal article","","","","","","","","","","","","","",""
"uuid:3b434b11-72c1-430f-9964-2e02c96bee2e","http://resolver.tudelft.nl/uuid:3b434b11-72c1-430f-9964-2e02c96bee2e","Floating Filters, a Novel Technique for Isolation and Enumeration of Fastidious, Acidophilic, Iron-Oxidizing, Autotrophic Bacteria","De Bruyn, J.C.; Boogerd, F.C.; Bos, P.; Kuenen, J.G.","","1990","","","en","journal article","","","","","","","","","","","","","",""
"uuid:78f57f7f-0431-45f1-abc3-c4da9663a897","http://resolver.tudelft.nl/uuid:78f57f7f-0431-45f1-abc3-c4da9663a897","Heterotrophic Growth of Thiobacillus-Acidophilus in Batch and Chemostat Cultures","Pronk, J.T.; Meesters, P.J.W.; Van Dijken, J.P.; Bos, P.; Kuenen, J.G.","","1990","","","en","journal article","","","","","","","","","","","","","",""
"uuid:a8d38dc4-35ef-4236-ad37-7ee51400e382","http://resolver.tudelft.nl/uuid:a8d38dc4-35ef-4236-ad37-7ee51400e382","Denitrification by obligate and facultative autotrophs","Robertson, L.A.; Kuenen, J.G.","","1990","","review denitrification autotroph bacteria","en","book chapter","","","","","","","","","","","","","",""
"uuid:4a6ff527-25f9-4825-9c24-b8d587ab2668","http://resolver.tudelft.nl/uuid:4a6ff527-25f9-4825-9c24-b8d587ab2668","Use of a metabolically structured model in the study of growth, nitrification and denitrification by Thiosphaera pantotropha","Geraats, S.G.M.; Hooijman, C.M.; Van Niel, E.W.J.; Obertson, L.A.; Heijnen, J.J.; Luyben, A.M.; Kuenen, J.G.","","1990","","","en","journal article","","","","","","","","","","","","","",""
"uuid:10025675-3315-460a-8092-3ecb530c5489","http://resolver.tudelft.nl/uuid:10025675-3315-460a-8092-3ecb530c5489","Oxygen and carbon dioxides mass transfer and the aerobic, autaotrophic cultivation of moderate and extreme thermophiles. A case study related to the microbial desulfurization of coal","Boogerd, F.C.; Bos, P.; Kuenen, J.G.; Heijnen, J.J.; Van der Lans, R.G.J.M.","","1990","","Biotechnology CELL CULTURE COAL Desulfurization OXYGEN Mass Transfer CARBON DIOXIDE Mass Transfer MICROBIOLOGY Industrial Applications Thermophiles autotrophic cultures microbial coal desulfurization 801 (Chemistry) 524 (Solid Fuels) 802 (Chemical Apparat","en","journal article","","","","","","","","","","","","","",""
"uuid:d4a1af8b-a4cd-4b98-abf6-a0fa42517dc3","http://resolver.tudelft.nl/uuid:d4a1af8b-a4cd-4b98-abf6-a0fa42517dc3","Physiological and ecological aspects of aerobic denitrification, a link with heterotrophic nitrification?","Robertson, L.A.; Kuenen, J.G.","","1990","","review denitrification aerobic ecol physiol nitrification heterotrophic ecol review","en","conference paper","","","","","","","","","","","","","",""
"uuid:10dfb6ea-8b60-4097-85cf-0f59219c2fde","http://resolver.tudelft.nl/uuid:10dfb6ea-8b60-4097-85cf-0f59219c2fde","Floating Filters, a Novel Technique for Isolation and Enumeration of Fastidious, Acidophilic, Iron-Oxidizing, Autotrophic Bacteria","de Bruyn, J.C.; Boogerd, F.C.; Bos, P.; Kuenen, J.G.","","1990","","","en","journal article","American Society for Microbiology","","","","","","","","","","","","",""
"uuid:0f87db6d-9a71-473e-91b4-f26053de1de1","http://resolver.tudelft.nl/uuid:0f87db6d-9a71-473e-91b4-f26053de1de1","Mixotrophic and Autotrophic Growth of Thiobacillus acidophilus on Glucose and Thiosulfate","Pronk, J.T.; Meulenberg, R.; van den Berg, D.J.; Batenburg-van der Vegte, W.; Bos, P.; Kuenen, J.G.","","1990","","","en","journal article","American Society for Microbiology","","","","","","","","","","","","",""
"uuid:9592868a-b999-4712-a233-191b615da6c6","http://resolver.tudelft.nl/uuid:9592868a-b999-4712-a233-191b615da6c6","Oxidation of Reduced Inorganic Sulfur-Compounds by Acidophilic Thiobacilli","Pronk, J.T.; Meulenberg, R.; Hazeu, W.; Bos, P.; Kuenen, J.G.","","1990","","oxidation","en","journal article","","","","","","","","","","","","","",""
"uuid:cf51c1c7-98ec-447d-bdce-cd5b1ac8c298","http://resolver.tudelft.nl/uuid:cf51c1c7-98ec-447d-bdce-cd5b1ac8c298","Mixotrophic and Autotrophic Growth of Thiobacillus-Acidophilus on Glucose and Thiosulfate","Pronk, J.T.; Meulenberg, R.; Van den Berg, D.J.M.; Batenburg-Van de Vegte, W.H.; Bos, P.; Kuenen, J.G.","","1990","","","en","journal article","","","","","","","","","","","","","",""
"uuid:4e5b3c2a-8229-4631-9934-820a998a8e4e","http://resolver.tudelft.nl/uuid:4e5b3c2a-8229-4631-9934-820a998a8e4e","Anoxic ammonium oxidation","Van de Graaf, A.A.; Mulder, A.; Slijkhuis, H.; Robertson, L.A.; Kuenen, J.G.","","1990","","oxidation; wastewater denitrification ammonium oxidn","en","conference paper","","","","","","","","","","","","","",""
"uuid:47bc8d25-c1e5-4917-b0e0-5e1db718a522","http://resolver.tudelft.nl/uuid:47bc8d25-c1e5-4917-b0e0-5e1db718a522","Combined Heterotrophic Nitrification and Aerobic Denitrification in Thiosphaera-Pantotropha and Other Bacteria","Robertson, L.A.; Kuenen, J.G.","","1990","","","en","journal article","","","","","","","","","","","","","",""
"uuid:52c084d7-b185-48f2-8f9f-89a8c9a041cf","http://resolver.tudelft.nl/uuid:52c084d7-b185-48f2-8f9f-89a8c9a041cf","Selection of Glucose-Assimilating Variants of Acinetobacter-Calcoaceticus Lmd-7941 in Chemostat Culture","Van Schie, B.J.; Rouwenhorst, R.J.; Van Dijken, J.P.; Kuenen, J.G.","","1989","","","en","journal article","","","","","","","","","","","","","",""
"uuid:5f3f004a-effe-41bc-a5a0-7f40a208169a","http://resolver.tudelft.nl/uuid:5f3f004a-effe-41bc-a5a0-7f40a208169a","Effects of growth rate and oxygen tension on glucose dehydrogenase activity in Acinetobacter calcoaceticus LMD 79.41","Van Schie, B.J.; Van Dijken, J.P.; Kuenen, J.G.","","1989","","glucose; glucose dehydrogenase Acinetobacter oxygen","en","journal article","","","","","","","","","","","","","",""
"uuid:cfe3e30a-7d58-47f0-a86a-ee2c8fb68d12","http://resolver.tudelft.nl/uuid:cfe3e30a-7d58-47f0-a86a-ee2c8fb68d12","The effect of thiosulphate and other inhibitors of autotrophic nitrification on heterotrophic nitrifiers","Robertson, L.A.; Cornelisse, R.; Zeng, R.; Kuenen, J.G.","","1989","","Nitrification Heterotrophy Nitrification inhibitor Thiosulfates Hydroxylamine Autotrophy Mixotrophy Microorganism culture Batch process Chemostat Pseudomonas denitrificans Nitrification Heterotrophie Inhibiteur nitrification Thiosulfate Allylthiouree Hydr","en","journal article","","","","","","","","","","","","","",""
"uuid:f83a1247-46e4-4a7a-997a-1e93a7b14c2b","http://resolver.tudelft.nl/uuid:f83a1247-46e4-4a7a-997a-1e93a7b14c2b","Aerobic Denitrification in Various Heterotrophic Nitrifiers","Robertson, L.A.; Cornelisse, R.; De Vos, P.; Hadioetomo, R.; Kuenen, J.G.","","1989","","","en","journal article","","","","","","","","","","","","","",""
"uuid:c3fd7b15-0f34-4620-b47e-7105e2ab2cb6","http://resolver.tudelft.nl/uuid:c3fd7b15-0f34-4620-b47e-7105e2ab2cb6","Carbon-Dioxide Fixation as the Initial Step in the Metabolism of Acetone by Thiosphaera-Pantotropha","Bonnet-Smits, E.M.; Robertson, L.A.; Van Dijken, J.P.; Senior, E.; Kuenen, J.G.","","1988","","","en","journal article","Cambridge University Press","","","","","","","","","","","","",""
"uuid:458733f2-8a6c-40cd-b6c7-42b1ef6fe5c6","http://resolver.tudelft.nl/uuid:458733f2-8a6c-40cd-b6c7-42b1ef6fe5c6","The Production and Utilization of Intermediary Elemental Sulfur During the Oxidation of Reduced Sulfur-Compounds by Thiobacillus-Ferrooxidans","Hazeu, W.; Batenburg-Van de Vegte, W.H.; Bos, P.; Van der Pas, R.K.; Kuenen, J.G.","","1988","","","en","journal article","","","","","","","","","","","","","",""
"uuid:605328d4-8611-40a5-9495-9cd698421171","http://resolver.tudelft.nl/uuid:605328d4-8611-40a5-9495-9cd698421171","Heterotrophic Nitrification in Thiosphaera-Pantotropha - Oxygen-Uptake and Enzyme Studies","Robertson, L.A.; Kuenen, J.G.","","1988","","","en","journal article","","","","","","","","","","","","","",""
"uuid:90977ab5-7b86-4352-99c7-9d3048ab68ea","http://resolver.tudelft.nl/uuid:90977ab5-7b86-4352-99c7-9d3048ab68ea","Simultaneous sulfide and acetate oxidation in a dentrifying fluidized bed. reactor. II: Measurements of activities and conversion","Gommers, P.J.F.; Buleveld, W.; Zuijderwijk, F.J.M.; Kuenen, J.G.","","1988","","Waste water purification Denitrification Fluidized bed reactor Organic sulfide Acetate Oxidation Performance evaluation Biological purification Epuration eau usee Denitrification Reacteur lit fluidise Sulfure organique Acetate Oxydation Evaluation perform","en","journal article","","","","","","","","","","","","","",""
"uuid:a9fb7696-fa6a-410c-abb5-c804e86c4f7e","http://resolver.tudelft.nl/uuid:a9fb7696-fa6a-410c-abb5-c804e86c4f7e","Feasibility of a Dutch process for microbial desulphurization of coal","Bos, P.; Huber, T.F.; Luyben, K.C.A.M.; Kuenen, J.G.","","1988","","Coal MICROORGANISMS Applications BIOTECHNOLOGY Research COAL PREPARATION PYRITES Removal SULFUR Removal Microbial desulfurization inorganic sulfudic minerals sink float process 524 (Solid Fuels) 802 (Chemical Apparatus and Plants, Unit Operations, Unit Pr","en","journal article","","","","","","","","","","","","","",""
"uuid:efda3b7d-3dd8-4cd8-bddd-b17a9e36acbc","http://resolver.tudelft.nl/uuid:efda3b7d-3dd8-4cd8-bddd-b17a9e36acbc","Simultaneous nitrification and denitrification in aerobic chemostat cultures of Thiosphaera pantotropha","Robertson, L.A.; Van Niel, E.W.J.; Torremans, R.A.M.; Kuenen, J.G.","","1988","","Nitrification Denitrification Simultaneous reaction Metabolism Bacteria Microorganism culture Continuous Environmental factor Dissolved oxygen Nitrogen cycle Thiosphaera pantotropha Nitrification Denitrification Reaction simultanee Metabolisme Bacterie Cu","en","journal article","","","","","","","","","","","","","",""
"uuid:97001dc4-ae34-4fb9-b94a-3833e9b4a228","http://resolver.tudelft.nl/uuid:97001dc4-ae34-4fb9-b94a-3833e9b4a228","Simultaneous Nitrification and Denitrification in Aerobic Chemostat Cultures of Thiosphaera pantotropha","Robertson, L.A.; van Niel, E.W.; Torremans, R.A.; Kuenen, J.G.","","1988","","","en","journal article","American Society for Microbiology","","","","","","","","","","","","",""
"uuid:629778f6-66f9-486a-8902-bdc3b1e67581","http://resolver.tudelft.nl/uuid:629778f6-66f9-486a-8902-bdc3b1e67581","Biochemical Limits to Microbial-Growth Yields - an Analysis of Mixed Substrate Utilization","Gommers, P.J.F.; Van Schie, B.J.; Van Dijken, J.P.; Kuenen, J.G.","","1988","","","en","journal article","","","","","","","","","","","","","",""
"uuid:4451b090-bc91-4774-9c30-34911615c86f","http://resolver.tudelft.nl/uuid:4451b090-bc91-4774-9c30-34911615c86f","Ecology of nitrification and denitrification","Kuenen, J.G.; Robertson, L.A.","","1988","","review nitrification denitrification ecol","en","conference paper","","","","","","","","","","","","","",""
"uuid:f56a39fc-c0af-491e-a23f-fc4d6fd44367","http://resolver.tudelft.nl/uuid:f56a39fc-c0af-491e-a23f-fc4d6fd44367","Simultaneous sulfide and acetate oxidation in a denitrifying fluidized bed reactor. I: Start-up and reactor performance","Gommers, P.J.F.; Buleveld, W.; Kuenen, J.G.","","1988","","Waste water purification Denitrification Material balance Fluidized bed reactor Performance evaluation Methodology Organic sulfide Biomass Acetate Oxidation Epuration eau usee Denitrification Bilan matiere Reacteur lit fluidise Evaluation performance Meth","en","journal article","","","","","","","","","","","","","",""
"uuid:54d5fb20-3aa5-4ce0-ba42-3ccf7e3dfc87","http://resolver.tudelft.nl/uuid:54d5fb20-3aa5-4ce0-ba42-3ccf7e3dfc87","Thiobacillus strain Q, a chemolithoheterotrophic sulphur bacterium","Gommers, P.J.F.; Kuenen, J.G.","","1988","","Thiobacillus Taxonomy Description Strain Chemoheterotrophy Chemolithotrophy Thiobacillus Systematique Description Souche Chimioheterotrophie Chimiolithotrophie Thiobacillus Sistematica Descripcion Cepa Quimioheterotrofia Quimiolitotrofia Bacteriology Micr","en","journal article","","","","","","","","","","","","","",""
"uuid:b152e370-c7f6-486c-b66e-38fbe53415e8","http://resolver.tudelft.nl/uuid:b152e370-c7f6-486c-b66e-38fbe53415e8","Energetic aspects of CO2 uptake in Thiobacillus neapolitanus","Holthuijzen, Y.A.; Van Dissel Emiliani, F.M.F.; Kuenen, J.G.; Konings, W.N.","","1987","","Thiobacillus neapolitanus Carbon dioxide Energy Metabolism Thiosulfates Biosynthesis PH Electron transfer Antibiotic Antibacterial agent Thiobacillus neapolitanus Carbone dioxyde Energie Metabolisme Thiosulfate Biosynthese Valinomycine PH Transfert electr","en","journal article","","","","","","","","","","","","","",""
"uuid:119375bf-b61b-4c08-bda0-f313d8bc6165","http://resolver.tudelft.nl/uuid:119375bf-b61b-4c08-bda0-f313d8bc6165","Activity of Ribulose-1,5-Bisphosphate Carboxylase in Intact and Disrupted Carboxysomes of Thiobacillus-Neapolitanus","Holthuijzen, Y.A.; Kuenen, J.G.; Konings, W.N.","","1987","","","en","journal article","","","","","","","","","","","","","",""
"uuid:c97a442a-9f58-493b-b6e8-d6955993f9b5","http://resolver.tudelft.nl/uuid:c97a442a-9f58-493b-b6e8-d6955993f9b5","Physiology and biochemistry of autotrophic bacteria","Codd, G.A.; Kuenen, J.G.","","1987","","review autotrophic bacteria metab Calvin cycle autotrophic bacteria review","en","conference paper","","","","","","","","","","","","","",""
"uuid:ce6ff9f5-67e2-4949-b5e8-b5f258309585","http://resolver.tudelft.nl/uuid:ce6ff9f5-67e2-4949-b5e8-b5f258309585","An in vivo analysis of the energetics of aldose oxidation by Acinetobacter calcoaceticus","van Schie, B.J.; Rouwenhorst, R.J.; de Bont, J.A.M.; van Dijken, J.P.; Kuenen, J.G.","","1987","","Acinetobacter aldose oxidn energy; glucose; oxidation","en","journal article","","","","","","","","","","","","","",""
"uuid:d93eb39e-7cf5-43a4-9f6e-a5b73161ebaf","http://resolver.tudelft.nl/uuid:d93eb39e-7cf5-43a4-9f6e-a5b73161ebaf","Glucose-dehydrogenase-mediated solute transport and ATP synthesis in Acinetobacter calcoaceticus","Van Schie, B.J.; Pronk, J.T.; Hellingwerf, K.J.; Van Dijken, J.P.; Kuenen, J.G.","","1987","","Acinetobacter calcoaceticus Enzyme Glucose dehydrogenase Chemostat Limitation Carbon Conservation Energy Acinetobacter calcoaceticus Enzyme Glucose dehydrogenase Chemostat Limitation Carbone Conservation Energie Acinetobacter calcoaceticus Enzima Glucose","en","journal article","","","","","","","","","","","","","",""
"uuid:74da38df-1db6-42dd-bbd0-34cff276f2fb","http://resolver.tudelft.nl/uuid:74da38df-1db6-42dd-bbd0-34cff276f2fb","A combined immunofluorescence DNA-fluorescence staining technique for enumeration of Thiobacillus ferrooxidans in a population of acidophilic bacteria","Muyzer, G.; De Bruyn, A.C.; Schmedding, D.J.M.; Bos, P.; Westbroek, P.; Kuenen, J.G.","","1987","","Immunofluorescence Fluorescence DNA Numeration Method Bacteria Acidophily Thiobacillus ferrooxidans Immunological method Immunofluorescence Fluorescence DNA Numeration Methode Bacterie Acidophilie Thiobacillus ferrooxidans Methode immunologique Inmunofluo","en","journal article","","","","","","","","","","","","","",""
"uuid:ade158e3-709a-42a9-b41d-d5cffba0e7eb","http://resolver.tudelft.nl/uuid:ade158e3-709a-42a9-b41d-d5cffba0e7eb","Methyl mercaptan oxidase, a key enzyme in the metabolism of methylated sulphur compounds by Hyphomicrobium EG","Suylen, G.M.H.; Large, P.J.; Van Dijken, J.P.; Kuenen, J.G.","","1987","","Hyphomicrobium Enzyme Purification Characterization Oxidase Metabolism Hyphomicrobium Enzyme Purification Caracterisation Oxidase Metabolisme Methyl mercaptan oxydase Sulfuremethyl Hyphomicrobium Enzima Purificacion Caracterizacion Oxidase Metabolismo Bac","en","journal article","","","","","","","","","","","","","",""
"uuid:22e9c3ed-6de0-43ef-8d9c-1ee7989e47e3","http://resolver.tudelft.nl/uuid:22e9c3ed-6de0-43ef-8d9c-1ee7989e47e3","PQQ-Dependent Production of Gluconic Acid by Acinetobacter, Agrobacterium and Rhizobium Species","Van Schie, B.J.; De Mooy, O.H.; Linton, J.D.; Van Dijken, J.P.; Kuenen, J.G.","","1987","","","en","journal article","","","","","","","","","","","","","",""
"uuid:55ef56d2-d203-460f-b7ad-bd0e41dddc1d","http://resolver.tudelft.nl/uuid:55ef56d2-d203-460f-b7ad-bd0e41dddc1d","Microbial-Metabolism of Dimethyl Sulfide","Suylen, G.M.H.; Large, P.J.; Kuenen, J.G.","","1987","","","en","journal article","","","","","","","","","","","","","",""
"uuid:a8ee230e-1c93-435a-934b-64e725c1b41a","http://resolver.tudelft.nl/uuid:a8ee230e-1c93-435a-934b-64e725c1b41a","A Combined Immunofluorescence-DNA-Fluorescence Staining Technique for Enumeration of Thiobacillus ferrooxidans in a Population of Acidophilic Bacteria","Muyzer, G.; de Bruyn, A.C.; Schmedding, D.J.; Bos, P.; Westbroek, P.; Kuenen, G.J.","","1987","","","en","journal article","American Society for Microbiology","","","","","","","","","","","","",""
"uuid:b2da658d-69d7-4039-b2d8-1bddf38f1735","http://resolver.tudelft.nl/uuid:b2da658d-69d7-4039-b2d8-1bddf38f1735","Chemolithotrophic potential of a Hyphomicrobium species, capable of growth on methylated sulphur compounds","Suylen, G.M.H.; Stefess, G.C.; Kuenen, J.G.","","1986","","Hyphomicrobium Methylotrophy Chemolithotrophy Growth Microorganism culture Continuous Discontinuous Respiration Sulfur compound Hyphomicrobium Methylotrophie Chimiolithotrophie Croissance Culture microorganisme Continu Discontinu Respiration Soufre compos","en","journal article","","","","","","","","","","","","","",""
"uuid:97739f7c-8c1e-4990-872b-634ac58b094d","http://resolver.tudelft.nl/uuid:97739f7c-8c1e-4990-872b-634ac58b094d","Kinetics and Energetics of Reduced Sulfur Oxidation by Chemostat Cultures of Thiobacillus-Ferrooxidans","Hazeu, W.; Bijleveld, W.; Grotenhuis, J.T.C.; Kakes, E.; Kuenen, J.G.","","1986","","","en","journal article","","","","","","","","","","","","","",""
"uuid:5b0e3dab-7d16-458c-ad64-abd4e8a775bf","http://resolver.tudelft.nl/uuid:5b0e3dab-7d16-458c-ad64-abd4e8a775bf","Carboxysomes of Thiobacillus-Neapolitanus Do Not Contain Extrachromosomal DNA","Holthuijzen, Y.A.; Maathuis, F.J.M.; Kuenen, J.G.; Konings, R.N.H.; Konings, W.N.","","1986","","","en","journal article","","","","","","","","","","","","","",""
"uuid:d63a061f-5423-49e4-a791-5c0bee7af8c7","http://resolver.tudelft.nl/uuid:d63a061f-5423-49e4-a791-5c0bee7af8c7","Protein-Composition of the Carboxysomes of Thiobacillus-Neapolitanus","Holthuijzen, Y.A.; Van Breemen, J.F.L.; Kuenen, J.G.; Konings, W.N.","","1986","","","en","journal article","","","","","","","","","","","","","",""
"uuid:08397ecb-8006-47e8-951c-269af36cf61b","http://resolver.tudelft.nl/uuid:08397ecb-8006-47e8-951c-269af36cf61b","Gas-Phase Influence on the Mixing in a Fluidized-Bed Bio-Reactor","Gommers, P.J.F.; Christoffels, L.P.; Kuenen, J.G.; Luyben, K.","","1986","","","en","journal article","","","","","","","","","","","","","",""
"uuid:0b349f61-e2f5-4342-a7ff-ef052df3056b","http://resolver.tudelft.nl/uuid:0b349f61-e2f5-4342-a7ff-ef052df3056b","A Microcomputer-Based Method for Semicontinuous Monitoring of Biological-Activities","Robertson, L.A.; Van Kleeff, B.H.A.; Kuenen, J.G.","","1986","","","en","journal article","","","","","","","","","","","","","",""
"uuid:741f6c5c-9c12-47f7-8e71-5b600ba3138f","http://resolver.tudelft.nl/uuid:741f6c5c-9c12-47f7-8e71-5b600ba3138f","A Dutch feasibility study on microbial coal desulfurization","Bos, P.; Huber, T.F.; Kos, C.H.; Ras, C.; Kuenen, J.G.","","1986","","coal; desulfurization; pyrite; bacteria; economics","en","conference paper","","","","","","","","","","","","","",""
"uuid:ce8bba12-7c28-4375-95ba-dd990dabc70c","http://resolver.tudelft.nl/uuid:ce8bba12-7c28-4375-95ba-dd990dabc70c","Oxygen Microprofiles of Trickling Filter Biofilms","Kuenen, J.G.; Jorgensen, B.B.; Revsbech, N.P.","","1986","","","en","journal article","","","","","","","","","","","","","",""
"uuid:84bb3325-aade-44a6-940f-4e95bcd71f69","http://resolver.tudelft.nl/uuid:84bb3325-aade-44a6-940f-4e95bcd71f69","Chemostat enrichment and isolation of Hyphomicrobium EG, a dimethyl-sulphide oxidizing methylotroph and reevaluation of Thiobacillus MS1","Suylen, G.M.H.; Kuenen, J.G.","","1986","","Isolation Hyphomicrobium Microorganism culture Culture medium Enzyme Serine Aminoacid Aerobiosis Thiobacillus Enrichment Nutrition Metabolism Mixed microorganism culture Oxidation Chemical pollution Methylotrophy Carbon Strain Chemolithotrophy Bacteria Is","en","journal article","","","","","","","","","","","","","",""
"uuid:00e2302c-cc6a-4c8f-8c2f-c7a2ee4d4d8e","http://resolver.tudelft.nl/uuid:00e2302c-cc6a-4c8f-8c2f-c7a2ee4d4d8e","Critical Parameters in the Isolation of Mitochondria from Candida-Utilis Grown in Continuous Culture","Bruinenberg, P.M.; Van Dijken, J.P.; Kuenen, J.G.; Scheffers, W.A.","","1985","","","en","journal article","","","","","","","","","Applied Sciences","","","","",""
"uuid:90b7f836-76bf-4b65-877b-9dd667e45826","http://resolver.tudelft.nl/uuid:90b7f836-76bf-4b65-877b-9dd667e45826","Oxidation of NADH and NADPH by Mitochondria from the Yeast Candida utilis","Bruinenberg, P.M.; Van Dijken, J.P.; Kuenen, J.G.; Scheffers, W.A.","","1985","","","en","journal article","","","","","","","","","Applied Sciences","","","","",""
"uuid:7103107a-a0bc-40f7-8103-5af11ac85eac","http://resolver.tudelft.nl/uuid:7103107a-a0bc-40f7-8103-5af11ac85eac","Eenmaal, andermaal, biotechnologie!","Kuenen, J.C.","","1985","","143ste Dies Natalis 1985","nl","public lecture","Delftse Universitaire Pers","","","","","","","","","","","","",""
"uuid:4d5ea237-62e4-436a-b948-002308346b2f","http://resolver.tudelft.nl/uuid:4d5ea237-62e4-436a-b948-002308346b2f","Continuous Culture Studies on the Regulation of Pqq-Dependent Glucose-Dehydrogenase in Acinetobacter-Calcoaceticus","Visser, W.; Van Schie, B.J.; De Bont, J.A.M.; Van Dijken, J.P.; Kuenen, J.G.","","1985","","","en","journal article","","","","","","","","","","","","","",""
"uuid:576491f7-16e8-4369-ae1c-91a96668cb6c","http://resolver.tudelft.nl/uuid:576491f7-16e8-4369-ae1c-91a96668cb6c","Enrichment of Dimethyl Sulfide-Oxidizing Bacteria","Scheulderman-Suylen, G.M.H.; Verbeek, J.B.M.; Kuenen, J.G.","","1985","","","en","journal article","","","","","","","","","","","","","",""
"uuid:8b4c48a4-5ee3-48d0-a5eb-c5e5f6e54cc0","http://resolver.tudelft.nl/uuid:8b4c48a4-5ee3-48d0-a5eb-c5e5f6e54cc0","The Subtle Difference between Heterotrophic Sulfur-Oxidizing Bacteria and Chemolithoheterotrophs","Gommers, P.J.F.; Kuenen, J.G.","","1985","","","en","journal article","","","","","","","","","","","","","",""
"uuid:369ad2a6-975a-4aa5-8236-cfa9dc54e799","http://resolver.tudelft.nl/uuid:369ad2a6-975a-4aa5-8236-cfa9dc54e799","Energy transduction by electron transfer via a pyrrolo-quinoline quinone-dependent glucose dehydrogenase in Escherichia coli, Pseudomonas aeruginosa, and Acinetobacter calcoaceticus (var. lwoffi)","Van Schie, B.J.; Hellingwerf, K.J.; Van Dijken, J.P.; Elferink, M.G.L.; Van Dijl, J.M.; Kuenen, J.G.; Konings, W.N.","","1985","","","en","journal article","","","","","","","","","","","","","",""
"uuid:8f783a5a-64fd-4f59-b80f-5b5b176d89f0","http://resolver.tudelft.nl/uuid:8f783a5a-64fd-4f59-b80f-5b5b176d89f0","The Gluconic Acid-Producing Enzyme of Acinetobacters","Van Schie, B.J.; Van Dijken, J.P.; Kuenen, J.G.","","1985","","","en","journal article","","","","","","","","","","","","","",""
"uuid:c7afb6d0-4f7e-4174-a622-e55f8b9c66fb","http://resolver.tudelft.nl/uuid:c7afb6d0-4f7e-4174-a622-e55f8b9c66fb","Further Evidence for Aerobic Denitrification by Thiosphaera-Pantotropha","Robertson, L.A.; Kuenen, J.G.","","1985","","","en","journal article","","","","","","","","","","","","","",""
"uuid:0d95a8a0-915e-4fed-a4a5-e5afdf8698bd","http://resolver.tudelft.nl/uuid:0d95a8a0-915e-4fed-a4a5-e5afdf8698bd","Aerobic Denitrification and Heterotrophic Nitrification by Thiosphaera-Pantotropha","Robertson, L.A.; Kuenen, J.G.; Kleijntjens, R.","","1985","","","en","journal article","","","","","","","","","","","","","",""
"uuid:be3d7ee7-0648-4f9d-a7ec-6bc22ee1ca65","http://resolver.tudelft.nl/uuid:be3d7ee7-0648-4f9d-a7ec-6bc22ee1ca65","Energization of Solute Transport by Pqq-Dependent Glucose-Dehydrogenase in Membrane-Vesicles of Acinetobacter Species","Pronk, J.T.; Van Schie, B.J.; Van Dijken, J.P.; Kuenen, J.G.","","1985","","","en","journal article","","","","","","","","","","","","","",""
"uuid:255c6bb0-e7a9-4072-8842-6e448dd9c054","http://resolver.tudelft.nl/uuid:255c6bb0-e7a9-4072-8842-6e448dd9c054","Microbiological Aspects of Denitrifying, Desulfurizing, Waste-Water Treatment","Robertson, L.A.; Kuenen, J.G.","","1985","","","en","journal article","","","","","","","","","","","","","",""
"uuid:8fd11574-5135-426c-9098-027b3e5a6055","http://resolver.tudelft.nl/uuid:8fd11574-5135-426c-9098-027b3e5a6055","Hyphomicrobium Eg, a Dimethyl Sulfide-Utilizing Methylotroph","Scheulderman-Suylen, G.M.H.; Kuenen, J.G.","","1985","","","en","journal article","","","","","","","","","","","","","",""
"uuid:ccff39fe-5bf9-4866-ba3d-135427874d26","http://resolver.tudelft.nl/uuid:ccff39fe-5bf9-4866-ba3d-135427874d26","Microbial Activities and Chemical Gradients in the Chemocline of a Meromictic Lake in Relation to the Precision of the Sampling Procedure","Borsheim, K.Y.; Kuenen, J.G.; Gottschal, J.; Dundas, I.","","1985","","","en","journal article","","","","","","","","","","","","","",""
"uuid:249cdb4f-a613-49de-9ad5-9abf09ee18c5","http://resolver.tudelft.nl/uuid:249cdb4f-a613-49de-9ad5-9abf09ee18c5","Microbial Interactions among Aerobic and Anaerobic Sulfur-Oxidizing Bacteria","Kuenen, J.G.; Robertson, L.A.; Van Gemerden, H.","","1985","","","en","journal article","","","","","","","","","","","","","",""
"uuid:0760a3eb-21c3-4a79-9c37-9ad9656b0656","http://resolver.tudelft.nl/uuid:0760a3eb-21c3-4a79-9c37-9ad9656b0656","Structure and Function of Carboxysomes","Holthuijzen, Y.A.; Kuenen, J.G.; Konings, W.N.","","1985","","","en","journal article","","","","","","","","","","","","","",""
"uuid:d6e87c72-e76d-4584-9a10-1cfbb6056c8c","http://resolver.tudelft.nl/uuid:d6e87c72-e76d-4584-9a10-1cfbb6056c8c","Physiological-Properties of a Non-Autotrophic Sulfur-Oxidizing Bacterium","Gommers, P.J.F.; Kuenen, J.G.","","1985","","","en","journal article","","","","","","","","","","","","","",""
"uuid:82d5181b-6a63-46e7-948f-5a1abae53da6","http://resolver.tudelft.nl/uuid:82d5181b-6a63-46e7-948f-5a1abae53da6","The Carboxysome of Thiobacillus-Neapolitanus","Holthuijzen, Y.A.; Vonck, J.; Kuenen, J.G.; Konings, W.N.","","1984","","","en","journal article","","","","","","","","","","","","","",""
"uuid:62d1f704-2d18-4353-b242-81236fc8b2a2","http://resolver.tudelft.nl/uuid:62d1f704-2d18-4353-b242-81236fc8b2a2","Anaerobic treatment of 'acid water' (methane production in a sulfate-rich environment)","Hoeks, F.W.J.M.; Ten Hoopen, H.J.G.; Roels, J.A.; Kuenen, J.G.","","1984","","fatty acid wastewater anaerobic treatment sulfate reducing bacteria anaerobic treatment hydrogen sulfide fatty acid wastewater","en","journal article","","","","","","","","","","","","","",""
"uuid:38d4784c-7069-4fdf-b007-d94a20e02a87","http://resolver.tudelft.nl/uuid:38d4784c-7069-4fdf-b007-d94a20e02a87","Microbial desulfurization of industrial wastes","Kuenen, J.G.; Robertson, L.A.; Scheulderman-Suylen, G.M.H.; Gommers, P.J.F.","","1984","","biol desulfurization industrial wastewater","en","conference paper","","","","","","","","","","","","","",""
"uuid:916e66d2-64ab-4f68-8acf-50d2f0db475a","http://resolver.tudelft.nl/uuid:916e66d2-64ab-4f68-8acf-50d2f0db475a","Competition among chemolithotrophic bacteria under aerobic and anaerobic conditions","Kuenen, J.G.; Robertson, L.A.","","1984","","review chemolithotrophic bacteria competition","en","conference paper","","","","","","","","","","","","","",""
"uuid:a55e55f2-43fd-4a0c-8be5-1eaaa745cd84","http://resolver.tudelft.nl/uuid:a55e55f2-43fd-4a0c-8be5-1eaaa745cd84","Role of Quinoprotein Glucose-Dehydrogenase in Gluconic Acid Production by Acinetobacter-Calcoaceticus","De Bont, J.A.M.; Dokter, P.; Van Schie, B.J.; Van Dijken, J.P.; Frank Jzn, J.; Duine, J.; Kuenen, J.G.","","1984","","","en","journal article","","","","","","","","","","","","","",""
"uuid:ac0d1a1e-9462-4118-aeeb-fe5db9e7aa59","http://resolver.tudelft.nl/uuid:ac0d1a1e-9462-4118-aeeb-fe5db9e7aa59","Strategies for growth and evolution of microorganisms in oligotrophic habitats","Van Gemerden, H.; Kuenen, J.G.","","1984","","review evolution microorganism oligotrophic habitat bacteria oligotrophic adaptation review","en","conference paper","","","","","","","","","","","","","",""
"uuid:fabe8dee-32cc-46dd-b7d9-ca2889782f61","http://resolver.tudelft.nl/uuid:fabe8dee-32cc-46dd-b7d9-ca2889782f61","Non-Coordinated Synthesis of Glucose-Dehydrogenase and Its Prosthetic Group PQQ in Acinetobacter and Pseudomonas Species","Van Schie, B.J.; Van Dijken, J.P.; Kuenen, J.G.","","1984","","","en","journal article","","","","","","","","","","","","","",""
"uuid:64ecb695-4935-4256-a2ec-d6abdbd165ca","http://resolver.tudelft.nl/uuid:64ecb695-4935-4256-a2ec-d6abdbd165ca","Aerobic Denitrification - a Controversy Revived","Robertson, L.A.; Kuenen, J.G.","","1984","","","en","journal article","","","","","","","","","","","","","",""
"uuid:1ee1461b-bf57-45a4-be89-cd086e7269ec","http://resolver.tudelft.nl/uuid:1ee1461b-bf57-45a4-be89-cd086e7269ec","Ecology of the colorless sulfur bacteria","Kelly, D.P.; Kuenen, J.G.","","1984","","review ecol sulfur bacteria","en","conference paper","","","","","","","","","","","","","",""
"uuid:34b639c5-fd46-47e4-bf8d-5912117d505c","http://resolver.tudelft.nl/uuid:34b639c5-fd46-47e4-bf8d-5912117d505c","Aerobic Denitrification - Old Wine in New Bottles","Robertson, L.A.; Kuenen, J.G.","","1984","","","en","journal article","","","","","","","","","","","","","",""
"uuid:7182e41c-711b-4cfd-8005-3750ac7b5849","http://resolver.tudelft.nl/uuid:7182e41c-711b-4cfd-8005-3750ac7b5849","Design and scale up of a reactor for microbial desulfurization of coal: A regime analysis","Huber, T.F.; Kossen, N.W.F.; Bos, P.; Kuenen, J.G.","","1984","","coal desulfurization microbial design reactor scale up coal desulfurization microbiol","en","journal article","","","","","","","","","","","","","",""
"uuid:a0838c49-db86-429d-a310-e570d5163ac2","http://resolver.tudelft.nl/uuid:a0838c49-db86-429d-a310-e570d5163ac2","Interactions between obligately and facultatively chemolithotrophic sulfur bacteria","Kuenen, J.G.; Robertson, L.A.","","1984","","chemolithotrophic sulfur bacteria interaction","en","conference paper","","","","","","","","","","","","","",""
"uuid:ef54f957-3676-408a-9469-15dc49e78562","http://resolver.tudelft.nl/uuid:ef54f957-3676-408a-9469-15dc49e78562","Thiosphaera pantotropha gen. nov. sp. nov., a facultatively anaerobic, facultatively autotrophic sulfur bacterium","Robertson, L.A.; Kuenen, J.G.","","1983","","sulfur metab Thiosphaera taxonomy","en","journal article","","","","","","","","","","","","","",""
"uuid:a8439e1f-eef9-4963-95c8-6d57f8134247","http://resolver.tudelft.nl/uuid:a8439e1f-eef9-4963-95c8-6d57f8134247","Microbiology of sulfur-oxidizing bacteria","Bos, P.; Kuenen, J.G.","","1983","","review sulfur oxidn bacteria","en","conference paper","","","","","","","","","","","","","",""
"uuid:8d913b11-9296-44be-83cd-3d553a44533e","http://resolver.tudelft.nl/uuid:8d913b11-9296-44be-83cd-3d553a44533e","The Role of Specialists and Generalists in Microbial-Population Interactions","Kuenen, J.G.","","1983","","","en","conference paper","","","","","","","","","","","","","",""
"uuid:74f67895-71b1-49e7-8051-0a6bb08c163b","http://resolver.tudelft.nl/uuid:74f67895-71b1-49e7-8051-0a6bb08c163b","Microbiology of Thiobacilli and Other Sulfur-Oxidizing Autotrophs, Mixotrophs and Heterotrophs","Kuenen, J.G.; Beudeker, R.F.; Shively, J.M.; Codd, G.A.","","1982","","","en","journal article","","","","","","","","","","","","","",""
"uuid:e9329a08-5325-4e93-93a2-c928b36820a6","http://resolver.tudelft.nl/uuid:e9329a08-5325-4e93-93a2-c928b36820a6","Reactivity Versus Flexibility in Thiobacilli","Beudeker, R.F.; Gottschal, J.C.; Kuenen, J.G.","","1982","","","en","journal article","","","","","","","","","","","","","",""
"uuid:5754edff-2740-4402-8791-7e09ff22cde9","http://resolver.tudelft.nl/uuid:5754edff-2740-4402-8791-7e09ff22cde9","Regulation of Nitrogen Assimilation by the Obligate Chemolithotroph Thiobacillus-Neapolitanus","Beudeker, R.F.; Riegman, R.; Kuenen, J.G.","","1982","","","en","journal article","","","","","","","","","","","","","",""
"uuid:8582c2c1-dc1a-45bd-85ee-df2794939d9b","http://resolver.tudelft.nl/uuid:8582c2c1-dc1a-45bd-85ee-df2794939d9b","Van oecologie naar biotechnologie","Kuenen, J.G.","","1981","","Intreerede","nl","public lecture","Delft University Press","","","","","","","","","","","","",""
"uuid:3cddafe1-5958-4203-8f81-4c9649c9541c","http://resolver.tudelft.nl/uuid:3cddafe1-5958-4203-8f81-4c9649c9541c","Mixed Substrates and Mixed Culture","Kuenen, J.G.","","1981","","","en","journal article","","","","","","","","","","","","","",""
"uuid:94857270-15b7-4ead-a343-ab7a804e18c9","http://resolver.tudelft.nl/uuid:94857270-15b7-4ead-a343-ab7a804e18c9","Occurrence, Structure and Function of Intracellular Polyglucose in the Obligate Chemolithotroph Thiobacillus-Neapolitanus","Beudeker, R.F.; Kerver, J.W.M.; Kuenen, J.G.","","1981","","","en","journal article","","","","","","","","","","","","","",""
"uuid:10577003-48c3-4a76-afd3-aa4906e15b20","http://resolver.tudelft.nl/uuid:10577003-48c3-4a76-afd3-aa4906e15b20","Quantification and Intracellular-Distribution of Ribulose-1,5-Bisphosphate Carboxylase in Thiobacillus-Neapolitanus, as Related to Possible Functions of Carboxysomes","Beudeker, R.F.; Codd, G.A.; Kuenen, J.G.","","1981","","","en","journal article","","","","","","","","","","","","","",""
"uuid:da298fad-42b4-4a5b-a123-f6f3e7787124","http://resolver.tudelft.nl/uuid:da298fad-42b4-4a5b-a123-f6f3e7787124","Heterolactic Fermentation of Intracellular Polyglucose by the Obligate Chemolithotroph Thiobacillus-Neapolitanus under Anaerobic Conditions","Beudeker, R.F.; De Boer, W.; Kuenen, J.G.","","1981","","","en","journal article","Elsevier","","","","","","","","","","","","",""
"uuid:0f3441cc-8948-4b10-a8ae-02f87bc8b286","http://resolver.tudelft.nl/uuid:0f3441cc-8948-4b10-a8ae-02f87bc8b286","Metabolic flexibility of Thiobacillus A 2 during substrate transitions in the chemostat","Gottschal, J.C.; Pol, A.; Kuenen, J.G.","","1981","","Thiobacillus thiosulfate heterotrophy autotrophy chemostat ribulose bisphosphate carboxylase Thiobacillus carbon dioxide fixation Thiobacillus","en","journal article","","","","","","","","","","","","","",""
"uuid:42d0e480-7fd9-4579-b518-ada1fea6fb08","http://resolver.tudelft.nl/uuid:42d0e480-7fd9-4579-b518-ada1fea6fb08","Growth of Thiobacillus-A2 under Alternating Growth-Conditions in the Chemostat","Gottschal, J.C.; Nanninga, H.J.; Kuenen, J.G.","","1981","","","en","journal article","","","","","","","","","","","","","",""
"uuid:b3a27911-8bf6-435e-9454-afd106658005","http://resolver.tudelft.nl/uuid:b3a27911-8bf6-435e-9454-afd106658005","Glycolate metabolism in the obligate chemolithotroph Thiobacillus neapolitanus grown in continuous culture","Beudeker, R.F.; Kuenen, J.G.; Codd, G.A.","","1981","","Thiobacillus glycolate metab","en","journal article","Cambridge University Press","","","","","","","","","","","","",""
"uuid:94845105-f84a-4be0-a337-b3be2abf69df","http://resolver.tudelft.nl/uuid:94845105-f84a-4be0-a337-b3be2abf69df","Geochemistry of sulfides in coal and microbial leaching experiments","Kos, C.H.; Poorter, R.P.E.; Bos, P.; Kuenen, J.G.","","1981","","coal sulfide microbial leaching Thiobacillus coal sulfide leaching acidophilic bacteria coal sulfide leaching trace element coal microbial leaching","en","conference paper","","","","","","","","","","","","","",""
"uuid:c5f69047-89d8-4894-94be-643b93c9d8b4","http://resolver.tudelft.nl/uuid:c5f69047-89d8-4894-94be-643b93c9d8b4","Physiological and ecological significance of facultative chemolithotrophy and mixotrophy in chemolithotrophic bacteria","Gottschal, J.C.; Kuenen, J.G.","","1981","","bacteria chemolithotroph nutrition ecol Thiobacillus metab ecol sulfur metab Thiobacillus","en","conference paper","","","","","","","","","","","","","",""
"uuid:daf08d65-352b-4287-89e9-9e557e2fa35a","http://resolver.tudelft.nl/uuid:daf08d65-352b-4287-89e9-9e557e2fa35a","Cytochemical-Localization of Fructose-1,6-Bisphosphatase in Thiobacillus-Neapolitanus Carboxysomes","Beudeker, R.F.; Veenhuis, M.; Kuenen, J.G.","","1981","","","en","journal article","","","","","","","","","","","","","",""
"uuid:daa5d751-959f-4e8a-923b-43f6de2c13f1","http://resolver.tudelft.nl/uuid:daa5d751-959f-4e8a-923b-43f6de2c13f1","Carboxysomes: ""Calvinosomes""?","Beudeker, R.F.; Kuenen, J.G.","","1981","","","en","journal article","","","","","","","","","","","","","",""
"uuid:1257e4ae-f89a-4ec7-80d5-1a83bfe9240c","http://resolver.tudelft.nl/uuid:1257e4ae-f89a-4ec7-80d5-1a83bfe9240c","Selective Enrichment of Facultatively Chemolithotrophic Thiobacilli and Related Organisms in Continuous Culture","Gottschal, J.C.; Kuenen, J.G.","","1980","","","en","journal article","","","","","","","","","","","","","",""
"uuid:1c1d5192-7c97-4feb-9ecb-b9909a9fd06c","http://resolver.tudelft.nl/uuid:1c1d5192-7c97-4feb-9ecb-b9909a9fd06c","Mixotrophic Growth of Thiobacillus-A2 on Acetate and Thiosulfate as Growth Limiting Substrates in the Chemostat","Gottschal, J.C.; Kuenen, J.G.","","1980","","","en","journal article","","","","","","","","","","","","","",""
"uuid:c03d5f68-09f0-491d-94e4-67a086bfd9a6","http://resolver.tudelft.nl/uuid:c03d5f68-09f0-491d-94e4-67a086bfd9a6","Relations between D-Ribulose-1,5-Bis-Phosphate Carboxylase, Carboxysomes and Co2 Fixing Capacity in the Obligate Chemolithotroph Thiobacillus-Neapolitanus Grown under Different Limitations in the Chemostat","Beudeker, R.F.; Cannon, G.C.; Kuenen, J.G.; Shively, J.M.","","1980","","","en","journal article","","","","","","","","","","","","","",""
"uuid:8fa85525-26f1-4db2-8acf-b4290c6bd8c6","http://resolver.tudelft.nl/uuid:8fa85525-26f1-4db2-8acf-b4290c6bd8c6","Autotrophic Metabolism of Formate by Thiobacillus Strain-A2","Kelly, D.P.; Wood, A.P.; Gottschal, J.C.; Kuenen, J.G.","","1979","","","en","journal article","","","","","","","","","","","","","",""
"uuid:f5d2aace-8b9a-431a-a17a-246bad9c5719","http://resolver.tudelft.nl/uuid:f5d2aace-8b9a-431a-a17a-246bad9c5719","Oxygen toxicity. Group report","Kuenen, J.G.; Hassan, H.M.; Krinsky, N.I.; Morris, J.G.; Pfennig, N.; Schlegel, H.; Shilo, M.; Vogels, G.D.; Weser, U.; Wolfe, R.","","1979","","review microorganism oxygen toxicity","en","conference paper","","","","","","","","","","","","","",""
"uuid:5cd6c96e-9ddb-43be-9a27-df37664db872","http://resolver.tudelft.nl/uuid:5cd6c96e-9ddb-43be-9a27-df37664db872","Microbial Transformations of Sulfur-Compounds in a Stratified Lake (Solar Lake, Sinai)","Jorgensen, B.B.; Kuenen, J.G.; Cohen, Y.","","1979","","","en","journal article","","","","","","","","","","","","","",""
"uuid:aa7f37c0-38f4-4879-9a17-0dac9f3c7fd8","http://resolver.tudelft.nl/uuid:aa7f37c0-38f4-4879-9a17-0dac9f3c7fd8","Growth Yields and Maintenance Energy Requirement in Thiobacillus Species under Energy Limitation","Kuenen, J.G.","","1979","","","en","journal article","","","","","","","","","","","","","",""
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"uuid:70d2f5ca-c042-453d-b867-810c10122ef2","http://resolver.tudelft.nl/uuid:70d2f5ca-c042-453d-b867-810c10122ef2","Some Quantitative Aspects of Incorporation of Organic Compounds by 2 Obligately Chemolithotrophic Sulfur Bacteria","Kuenen, J.G.; Veldkamp, H.","","1971","","","en","journal article","","","","","","","","","","","","","",""
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