Your search keyword '"Ochromonas metabolism"' showing total 14 results

1. Mixotrophic cultivation of microalgae-bacteria consortia enhances dark fermentation effluent treatment.

Author

Lacroux J, Mahieux M, Llamas M, Bonnafous A, Trably E, Steyer JP, and van Lis R

Subjects

Bacteria metabolism, Microbial Consortia physiology, Butyrates metabolism, Chlorella growth & development, Chlorella metabolism, Waste Disposal, Fluid methods, Darkness, Ochromonas metabolism, Ochromonas growth & development, Euglena gracilis metabolism, Euglena gracilis growth & development, Water Purification methods, Fatty Acids, Volatile metabolism, Microalgae metabolism, Microalgae growth & development, Fermentation, Biomass

Abstract

Dark fermentation (DF) is a waste treatment bioprocess which produces biohydrogen and volatile fatty acids (VFAs) such as acetate or butyrate. DF can be coupled with microalgae cultivation, allowing VFA conversion into valuable biomass. Nevertheless, the process is hindered by slow butyrate consumption. In this study, novel artificial microalgae-bacteria consortia were used as a strategy to accelerate butyrate removal. Three microalgal strains with various trophic metabolisms, Chlorella sorokiniana, Euglena gracilis and Ochromonas danica, were cultivated on DF effluent that was either sterile or contained endogenous bacteria. Bacteria did not impact microalgal biomass production of C. sorokiniana or E. gracilis while accelerating butyrate removal rates 2 to 10-fold. O. danica greatly impacted microbial diversity, probably due to its phagotrophic metabolism. These results show that bacteria in organic rich effluents can greatly aid in substrate removal while allowing microalgal growth, inspiring bioprocesses coupling raw fermentation effluents with microalgae biomass production and valorization., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 The Author(s). Published by Elsevier Ltd.. All rights reserved.)

Published

2024

2. Environment-dependent metabolic investments in the mixotrophic chrysophyte Ochromonas.

Author

Barbaglia GS, Paight C, Honig M, Johnson MD, Marczak R, Lepori-Bui M, and Moeller HV

Subjects

Photosynthesis, Light, Chlorophyll metabolism, Ochromonas metabolism, Chrysophyta

Abstract

Mixotrophic protists combine photosynthesis and phagotrophy to obtain energy and nutrients. Because mixotrophs can act as either primary producers or consumers, they have a complex role in marine food webs and biogeochemical cycles. Many mixotrophs are also phenotypically plastic and can adjust their metabolic investments in response to resource availability. Thus, a single species's ecological role may vary with environmental conditions. Here, we quantified how light and food availability impacted the growth rates, energy acquisition rates, and metabolic investment strategies of eight strains of the mixotrophic chrysophyte, Ochromonas. All eight Ochromonas strains photoacclimated by decreasing chlorophyll content as light intensity increased. Some strains were obligate phototrophs that required light for growth, while other strains showed stronger metabolic responses to prey availability. When prey availability was high, all eight strains exhibited accelerated growth rates and decreased their investments in both photosynthesis and phagotrophy. Photosynthesis and phagotrophy generally produced additive benefits: In low-prey environments, Ochromonas growth rates increased to maximum, light-saturated rates with increasing light but increased further with the addition of abundant bacterial prey. The additive benefits observed between photosynthesis and phagotrophy in Ochromonas suggest that the two metabolic modes provide nonsubstitutable resources, which may explain why a tradeoff between phagotrophic and phototrophic investments emerged in some but not all strains., (© 2023 The Authors. Journal of Phycology published by Wiley Periodicals LLC on behalf of Phycological Society of America.)

Published

2024

3. On the power per mitochondrion and the number of associated active ATP synthases.

Author

Fahimi P and Matta CF

Subjects

Amoeba metabolism, Ciliophora metabolism, Energy Metabolism, Euglena metabolism, Mitochondria metabolism, Mitochondrial Proton-Translocating ATPases metabolism, Ochromonas metabolism

Abstract

Recent experiments and thermodynamic arguments suggest that mitochondrial temperatures are higher than those of the cytoplasm. A "hot mitochondrion" calls for a closer examination of the energy balance that endows it with these claimed elevated temperatures. As a first step in this effort, we present here a semi-quantitative bookkeeping whereby, in one stroke, a formula is proposed that yields the rate of heat production in a typical mitochondrion and a formula for estimating the number of " active " ATP synthase molecules per mitochondrion. The number of active ATP synthase molecules is the equivalent number of ATP synthases operating at 100% capacity to maintain the rate of mitochondrial heat generation. Scaling laws are shown to determine the number of active ATP synthase molecules in a mitochondrion and mitochondrial rate of heat production, whereby both appear to scale with cell volume. Four heterotrophic protozoan cell types are considered in this study. The studied cells, selected to cover a wide range of sizes (volumes) from ca. 100 μ m 3 to 1 million μ m 3 , are estimated to exhibit a power per mitochondrion ranging from ca. 1 pW to 0.03 pW. In these cells, the corresponding number of active ATP synthases per mitochondrion ranges from 5000 to just about a hundred. The absolute total number of ATP synthase molecules per mitochondrion, regardless of their activity status, can be up to two orders of magnitudes higher., (© 2021 IOP Publishing Ltd.)

Published

2021

4. Conversion of wastewater-originated waste grease to polyunsaturated fatty acid-rich algae with phagotrophic capability.

Author

Xiao S and Ju LK

Subjects

Biotransformation, Triglycerides metabolism, Fatty Acids, Unsaturated metabolism, Ochromonas growth & development, Ochromonas metabolism, Wastewater microbiology, Water Pollutants, Chemical metabolism

Abstract

Grease balls collected from a municipal wastewater treatment plant were melt-screened and used for cultivation of microalga Ochromonas danica, which could phagocytize droplets and particles as food. After autoclaving, the waste grease (WG) separated into two (upper and lower) phases. O. danica grew well on both, accumulating 48-79% (w/w) intracellular lipids. Initial WG contained approximately 50:50 triglycerides and free fatty acids (FFAs); over time, almost only FFAs remained in the extracellular WG presumably due to hydrolysis by algal lipase. PUFAs, mainly C18:2n6, C18:3n3, C18:3n6, C20:4n6, and C22:5n6, were synthesized and enriched to up to 67% of intracellular FAs, from the original 15% PUFA content in WG. The study showed feasibility of converting wastewater-originated WG to PUFA-rich O. danica algae culture, possibly as aquaculture/animal feed. WG dispersion was identified as a major processing factor to further improve for optimal WG conversion rate and cell and FA yields.

Published

2019

5. Evolution of heterotrophy in chrysophytes as reflected by comparative transcriptomics.

Author

Graupner N, Jensen M, Bock C, Marks S, Rahmann S, Beisser D, and Boenigk J

Subjects

Energy Metabolism genetics, Heterotrophic Processes genetics, Ochromonas genetics, Ochromonas growth & development, Photosynthesis genetics, Phototrophic Processes genetics, Plastids genetics, Energy Metabolism physiology, Heterotrophic Processes physiology, Ochromonas metabolism, Photosynthesis physiology, Phototrophic Processes physiology

Abstract

Shifts in the nutritional mode between phototrophy, mixotrophy and heterotrophy are a widespread phenomenon in the evolution of eukaryotic diversity. The transition between nutritional modes is particularly pronounced in chrysophytes and occurred independently several times through parallel evolution. Thus, chrysophytes provide a unique opportunity for studying the molecular basis of nutritional diversification and of the accompanying pathway reduction and degradation of plastid structures. In order to analyze the succession in switching the nutritional mode from mixotrophy to heterotrophy, we compared the transcriptome of the mixotrophic Poterioochromonas malhamensis with the transcriptomes of three obligate heterotrophic species of Ochromonadales. We used the transcriptome of P. malhamensis as a reference for plastid reduction in the heterotrophic taxa. The analyzed heterotrophic taxa were in different stages of plastid reduction. We investigated the reduction of several photosynthesis related pathways e.g. the xanthophyll cycle, the mevalonate pathway, the shikimate pathway and the tryptophan biosynthesis as well as the reduction of plastid structures and postulate a presumable succession of pathway reduction and degradation of accompanying structures.

Published

2018

6. A tale of two mixotrophic chrysophytes: Insights into the metabolisms of two Ochromonas species (Chrysophyceae) through a comparison of gene expression.

Author

Lie AAY, Liu Z, Terrado R, Tatters AO, Heidelberg KB, and Caron DA

Subjects

Amino Acids metabolism, Bacteria, Carbon metabolism, Chlorophyll metabolism, Chlorophyll A, Citric Acid Cycle, Glycolysis, Light, Nitrogen metabolism, Ochromonas genetics, Ochromonas physiology, Phylogeny, Transcriptome, Gene Expression, Ochromonas metabolism

Abstract

Ochromonas spp. strains CCMP1393 and BG-1 are phagotrophic phytoflagellates with different nutritional strategies. Strain CCMP1393 is an obligate phototroph while strain BG-1 readily grows in continuous darkness in the presence of bacterial prey. Growth and gene expression of strain CCMP1393 were investigated under conditions allowing phagotrophic, mixotrophic, or phototrophic nutrition. The availability of light and bacterial prey led to the differential expression of 42% or 45-59% of all genes, respectively. Data from strain CCMP1393 were compared to those from a study conducted previously on strain BG-1, and revealed notable differences in carbon and nitrogen metabolism between the 2 congeners under similar environmental conditions. Strain BG-1 utilized bacterial carbon and amino acids through glycolysis and the tricarboxylic acid cycle, while downregulating light harvesting and carbon fixation in the Calvin cycle when both light and bacteria were available. In contrast, the upregulation of genes related to photosynthesis, light harvesting, chlorophyll synthesis, and carbon fixation in the presence of light and prey for strain CCMP1393 implied that this species is more phototrophic than strain BG-1, and that phagotrophy may have enhanced phototrophy. Cellular chlorophyll a content was also significantly higher in strain CCMP1393 supplied with bacteria compared to those without prey. Our results thus point to very different physiological strategies for mixotrophic nutrition in these closely related chrysophyte species.

Published

2018

7. Autotrophic and heterotrophic acquisition of carbon and nitrogen by a mixotrophic chrysophyte established through stable isotope analysis.

Author

Terrado R, Pasulka AL, Lie AA, Orphan VJ, Heidelberg KB, and Caron DA

Subjects

Autotrophic Processes, Bacteria classification, Bacteria genetics, Bacteria isolation & purification, Carbon Isotopes analysis, Carbon Isotopes metabolism, Heterotrophic Processes, Nitrogen Isotopes analysis, Nitrogen Isotopes metabolism, Ochromonas genetics, Ochromonas isolation & purification, Photosynthesis, Bacteria metabolism, Carbon metabolism, Nitrogen metabolism, Ochromonas metabolism, Ochromonas microbiology

Abstract

Collectively, phagotrophic algae (mixotrophs) form a functional continuum of nutritional modes between autotrophy and heterotrophy, but the specific physiological benefits of mixotrophic nutrition differ among taxa. Ochromonas spp. are ubiquitous chrysophytes that exhibit high nutritional flexibility, although most species generally fall towards the heterotrophic end of the mixotrophy spectrum. We assessed the sources of carbon and nitrogen in Ochromonas sp. strain BG-1 growing mixotrophically via short-term stable isotope probing. An axenic culture was grown in the presence of either heat-killed bacteria enriched with 15 N and 13 C, or unlabeled heat-killed bacteria and labeled inorganic substrates ( 13 C-bicarbonate and 15 N-ammonium). The alga exhibited high growth rates (up to 2 divisions per day) only until heat-killed bacteria were depleted. NanoSIMS and bulk IRMS isotope analyses revealed that Ochromonas obtained 84-99% of its carbon and 88-95% of its nitrogen from consumed bacteria. The chrysophyte assimilated inorganic 13 C-carbon and 15 N-nitrogen when bacterial abundances were very low, but autotrophic (photosynthetic) activity was insufficient to support net population growth of the alga. Our use of nanoSIMS represents its first application towards the study of a mixotrophic alga, enabling a better understanding and quantitative assessment of carbon and nutrient acquisition by this species.

Published

2017

8. Effect of light and prey availability on gene expression of the mixotrophic chrysophyte, Ochromonas sp.

Author

Lie AA, Liu Z, Terrado R, Tatters AO, Heidelberg KB, and Caron DA

Subjects

Carbon metabolism, Energy Metabolism genetics, Gene Expression Profiling, Light, Nitrogen metabolism, Ochromonas metabolism, Transcriptome, Gene Expression Regulation radiation effects, Ochromonas genetics, Photosynthesis genetics

Abstract

Background: Ochromonas is a genus of mixotrophic chrysophytes that is found ubiquitously in many aquatic environments. Species in this genus can be important consumers of bacteria but vary in their ability to perform photosynthesis. We studied the effect of light and bacteria on growth and gene expression of a predominantly phagotrophic Ochromonas species. Axenic cultures of Ochromonas sp. were fed with heat-killed bacteria (HKB) and grown in constant light or darkness. RNA was extracted from cultures in the light or in the dark with HKB present (Light + HKB; Dark + HKB), and in the light after HKB were depleted (Light + depleted HKB)., Results: There were no significant differences in the growth or bacterial ingestion rates between algae grown in light or dark conditions. The availability of light led to a differential expression of only 8% of genes in the transcriptome. A number of genes associated with photosynthesis, phagotrophy, and tetrapyrrole synthesis was upregulated in the Light + HKB treatment compared to Dark + HKB. Conversely, the comparison between the Light + HKB and Light + depleted HKB treatments revealed that the presence of HKB led to differential expression of 59% of genes, including the majority of genes involved in major carbon and nitrogen metabolic pathways. Genes coding for unidirectional enzymes for the utilization of glucose were upregulated in the presence of HKB, implying increased glycolytic activities during phagotrophy. Algae without HKB upregulated their expression of genes coding for ammonium transporters, implying uptake of inorganic nitrogen from the culture medium when prey were unavailable., Conclusions: Transcriptomic results agreed with previous observations that light had minimal effect on the population growth of Ochromonas sp. However, light led to the upregulation of a number of phototrophy- and phagotrophy-related genes, while the availability of bacterial prey led to prominent changes in major carbon and nitrogen metabolic pathways. Our study demonstrated the potential of transcriptomic approaches to improve our understanding of the trophic physiologies of complex mixotrophs, and revealed responses in Ochromonas sp. not apparent from traditional culture studies.

Published

2017

9. Cultivation of phagotrophic algae with waste activated sludge as a fast approach to reclaim waste organics.

Author

Li C, Xiao S, and Ju LK

Subjects

Anaerobiosis, Biomass, Bioreactors, Sewage analysis, Ochromonas growth & development, Ochromonas metabolism, Recycling, Waste Disposal, Fluid methods, Water Pollutants, Chemical metabolism

Abstract

Substantial energy is reserved in waste activated sludge (WAS) organics but much of it is difficult to recover because the solid organics require long time to solubilize. In this work we introduced the new approach of recovering WAS organics into the biomass of phagotrophic algae. Phagotrophic algae have the unique ability to grow by ingesting insoluble organic particles including microbial cells. This phagotrophic ability renders the solubilization of WAS organics unnecessary and makes this approach remarkably fast. The approach consists of two stages: a short anaerobic digestion treatment followed by the algal growth on treated WAS. The short anaerobic digestion was exploited to release discrete bacteria from WAS flocs. Phagotrophic algae could then grow rapidly with the released bacteria as well as the solubilized nutrients in the treated WAS. The results showed that WAS organics could be quickly consumed by phagotrophic algae. Among all studied conditions the highest WAS volatile solids (VS) reduction was achieved with 72 h anaerobic digestion and 24 h algal growth. In this optimal process, 28% of WAS VS was reduced, and 41% and 20% of the reduced VS were converted into algal biomass and lipids, respectively. In comparison, only 18% WAS VS were reduced after the same time of aerobic digestion without algae addition. Through this approach, the amount of WAS organics requiring further treatment for final disposal is significantly reduced. With the production of significant amounts of algal biomass and lipids, WAS treatment is expected to be more economical and sustainable in material recycling., (Copyright © 2016 Elsevier Ltd. All rights reserved.)

Published

2016

10. Extracellular secretion of free fatty acids by the chrysophyte Ochromonas danica under photoautotrophic and mixotrophic growth.

Author

Abomohra Ael-F, El-Sheekh M, and Hanelt D

Subjects

Biomass, Carbon metabolism, Culture Media chemistry, Cytosol chemistry, Fatty Acids, Nonesterified metabolism, Ochromonas growth & development, Ochromonas metabolism

Abstract

Recently, microalgae have gained a lot of attention because of their ability to produce fatty acids in their surrounding environments. The present paper describes the influence of organic carbon on the different fatty acid pools including esterified fatty acids, intracellular free fatty acids and extracellular free fatty acids in Ochromonas danica. It also throws light on the ability of O. danica to secrete free fatty acids in the growth medium under photoautotrophic and mixotrophic conditions. Biomass production of photoautotrophically grown O. danica was higher than that of mixotrophically grown, where a cellular biomass formation of 1.8 g L(-1) was observed under photoautotrophic condition which was about five folds higher than that under mixotrophic conditions. Contrary, the esterified fatty acid content reached up to 99 mg g(-1) CDW under photoautotrophic conditions at the late exponential phase, while during mixotrophic conditions a maximum of 212 mg g(-1) CDW was observed at the stationary phase. Furthermore, O. danica cells grown under mixotrophic conditions showed higher intracellular free fatty acid and extracellular free fatty acid contents (up to 51 and 20 mg g(-1) CDW, respectively) than cells grown under photoautotrophic conditions (up to 26 and 4 mg g(-1) CDW, respectively). The intra- and extracellular free fatty acids consisted of a high proportion of polyunsaturated fatty acids, mainly C18:2n-6, C18:3n-3 and C20:4n-6.

Published

2014

11. Bioaccumulation of CdTe quantum dots in a freshwater alga Ochromonas danica: a kinetics study.

Author

Wang Y, Miao AJ, Luo J, Wei ZB, Zhu JJ, and Yang LY

Subjects

Cadmium Compounds chemistry, Cadmium Compounds toxicity, Fresh Water, Kinetics, Luminescent Measurements, Models, Biological, Ochromonas drug effects, Ochromonas growth & development, Quantum Dots chemistry, Quantum Dots toxicity, Tellurium chemistry, Tellurium toxicity, Thioglycolates chemistry, Cadmium Compounds metabolism, Ochromonas metabolism, Quantum Dots metabolism, Tellurium metabolism

Abstract

The bioaccumulation kinetics of thioglycolic acid stabilized CdTe quantum dots (TGA-CdTe-QDs) in a freshwater alga Ochromonas danica was comprehensively investigated. Their photoluminescence (PL) was determined by flow cytometry. Its cellular intensity increased hyperbolically with exposure time suggesting real internalization of TGA-CdTe-QDs. This hypothesis was evidenced by the nanoparticle uptake experiment with heat-killed or cold-treated cells and by their localization in the vacuoles. TGA-CdTe-QD accumulation could further be well simulated by a biokinetic model used previously for conventional pollutants. Moreover, macropinocytosis was the main route for their internalization. As limited by their diffusion from the bulk medium to the cell surface, TGA-CdTe-QD uptake rate increased proportionally with their ambient concentration. Quick elimination in the PL of cellular TGA-CdTe-QDs was also observed. Such diminishment resulted mainly from their surface modification by vacuolar biomolecules, considering that these nanoparticles remained mostly undissolved and their expulsion out of the cells was slow. Despite the significant uptake of TGA-CdTe-QDs, they had no direct acute effects on O. danica. Overall, the above research shed new light on nanoparticle bioaccumulation study and would further improve our understanding about their environmental behavior, effects and fate.

Published

2013

12. A simple defined medium for growth and maintenance of the mixotrophic protist Ochromonas danica.

Author

Foster BL and Chrzanowski TH

Subjects

Cell Proliferation drug effects, Culture Media pharmacology, Hydrogen-Ion Concentration, Ochromonas drug effects, Ochromonas metabolism, Cell Culture Techniques methods, Culture Media chemistry, Ochromonas growth & development

Abstract

A simple-defined medium was formulated that allows robust axenic-growth of the model mixotrophic protist Ochromonas danica at a neutral pH. This new defined medium, with a minimum number of constituents, facilitates more highly controlled studies of mixotrophic metabolism and nutrient regeneration than have previously been possible., (Copyright © 2012 Elsevier B.V. All rights reserved.)

Published

2012

13. Utilizing the effective xanthophyll cycle for blooming of Ochromonas smithii and O. itoi (Chrysophyceae) on the snow surface.

Author

Tanabe Y, Shitara T, Kashino Y, Hara Y, and Kudoh S

Subjects

Chrysophyta growth & development, Chrysophyta metabolism, Chrysophyta physiology, Cold Temperature, Light, Models, Biological, Ochromonas growth & development, Photosynthesis physiology, Eutrophication physiology, Ochromonas metabolism, Ochromonas physiology, Snow, Xanthophylls metabolism

Abstract

Snow algae inhabit unique environments such as alpine and high latitudes, and can grow and bloom with visualizing on snow or glacier during spring-summer. The chrysophytes Ochromonas smithii and Ochromonas itoi are dominant in yellow-colored snow patches in mountainous heavy snow areas from late May to early June. It is considered to be effective utilizing the xanthophyll cycle and holding sunscreen pigments as protective system for snow algae blooming in the vulnerable environment such as low temperature and nutrients, and strong light, however the study on the photoprotection of chrysophytes snow algae has not been shown. To dissolve how the chrysophytes snow algae can grow and bloom under such an extreme environment, we studied with the object of light which is one point of significance to this problem. We collected the yellow snows and measured photosynthetically active radiation at Mt. Gassan in May 2008 when the bloom occurred, then tried to establish unialgal cultures of O. smithii and O. itoi, and examined their photosynthetic properties by a PAM chlorophyll fluorometer and analyzed the pigment compositions before and after illumination with high-light intensities to investigate the working xanthophyll cycle. This experimental study using unialgal cultures revealed that both O. smithii and O. itoi utilize only the efficient violaxanthin cycle for photoprotection as a dissipation system of surplus energy under prolonged high-light stress, although they possess chlorophyll c with diadinoxanthin.

Published

2011

14. Analysis of a chlorosulfolipid from Ochromonas danica by matrix-assisted laser desorption/ionization quadrupole ion trap time-of-flight mass spectrometry.

Author

Darsow KH, Lange HA, Resch M, Walter C, and Buchholz R

Subjects

Chlorine Compounds analysis, Lipids analysis, Reproducibility of Results, Sensitivity and Specificity, Sulfur Compounds analysis, Chlorine Compounds chemistry, Lipids chemistry, Ochromonas metabolism, Spectrometry, Mass, Electrospray Ionization methods, Spectrometry, Mass, Matrix-Assisted Laser Desorption-Ionization methods, Sulfur Compounds chemistry

Abstract

Matrix-assisted laser desorption/ionization (MALDI) time-of-flight (ToF) mass spectrometry (MS) is an established tool for analyzing high mass molecules, such as proteins, whereas it attracts far less interest in the field of lipid analysis. In the study reported here a new chlorosulfolipid (CSL), 3,8,12,15-tetrachloroeicosane-1,17,18-triyl tris(hydrogen sulfate), was identified from the alga Ochromonas danica and de novo characterized by matrix-assisted laser desorption/ionization quadrupole ion trap time-of-flight (MALDI-QIT-ToF) MS in negative ion mode. This method provides an effective alternative for the analysis of compounds directly derived from organic cell extracts. For MALDI analyses several frequently used solid MALDI matrices as well as some ionic liquid matrices (ILMs) were tested to enhance the analyte response to UV-laser and its ionization. The molecular weight of the observed compound could be determined as Li-, Na- and K-adducts [M+Me-2H]-. The characteristic isotopic patterns of the measured ions and the well-allocated molecular fragments by MS1, MS2 and MS3 indicate the fourfold chlorination and threefold sulfation of the investigated compound. The MS fragmentation alongside of the chlorine-bearing C-atoms is accompanied by the generation of a double bond at the opposite fragment in MS1. This obtained fragmentation pattern provides an insight into the allocation of the chlorine-bearing C-atoms along the carbon chain., (Copyright 2007 John Wiley & Sons, Ltd.)

Published

2007