Your search keyword '"Sporre, Emil"' showing total 14 results

1. Metabolite interactions in the bacterial Calvin cycle and implications for flux regulation

Author

Sporre, Emil, Karlsen, Jan, Schriever, Karen, Asplund-Samuelsson, Johannes, Janasch, Markus, Strandberg, Linnéa, Karlsson, Anna, Kotol, David, Zeckey, Luise, Piazza, Ilaria, Syrén, Per-Olof, Edfors, Fredrik, and Hudson, Elton P.

Published

2023

2. Thermodynamic limitations of PHB production from formate and fructose in Cupriavidus necator

Author

Janasch, Markus, Crang, Nick, Asplund-Samuelsson, Johannes, Sporre, Emil, Bruch, Manuel, Gynnå, Arvid, Jahn, Michael, and Hudson, Elton P.

Published

2022

3. Synthetic metabolic pathways for conversion of CO2 into secreted short-to medium-chain hydrocarbons using cyanobacteria

Author

Yunus, Ian S., Anfelt, Josefine, Sporre, Emil, Miao, Rui, Hudson, Elton P., and Jones, Patrik R.

Published

2022

4. Cycling between growth and production phases increases cyanobacteria bioproduction of lactate

Author

Shabestary, Kiyan, Hernández, Hugo Pineda, Miao, Rui, Ljungqvist, Emil, Hallman, Olivia, Sporre, Emil, Branco dos Santos, Filipe, and Hudson, Elton P.

Published

2021

5. Metabolite interactions in the bacterial Calvin cycle and implications for flux regulation

Author

Sporre, Emil, Karlsen, Jan, Schriever, Karen, Asplund-Samuelsson, Johannes, Janasch, Markus, Strandberg, Linnéa, Kotol, David, Zeckey, Luise, Piazza, Ilaria, Syrén, Per-Olof, Edfors, Fredrik, Hudson, Elton P., Sporre, Emil, Karlsen, Jan, Schriever, Karen, Asplund-Samuelsson, Johannes, Janasch, Markus, Strandberg, Linnéa, Kotol, David, Zeckey, Luise, Piazza, Ilaria, Syrén, Per-Olof, Edfors, Fredrik, and Hudson, Elton P.

Abstract

Metabolite-level regulation of enzyme activity is important for microbes to cope with environmental shifts. Knowledge of such regulations can also guide strain engineering to improve industrial phenotypes. Recently developed chemoproteomics workflows allow for genome-wide detection of metabolite-protein interactions that may regulate pathway activity. We applied limited proteolysis small molecule mapping (LiP-SMap) to identify and compare metabolite-protein interactions in the proteomes of two cyanobacteria and two lithoautotrophic bacteria that fix CO2 using the Calvin cycle. Clustering analysis of the hundreds of detected interactions showed that some metabolites interacted in a species-specific manner, such as interactions of glucose-6-phosphate in Cupriavidus necator and of glyoxylate in Synechocystis sp PCC 6803. These are interpreted in light of the different central carbon conversion pathways present. Metabolites interacting with the Calvin cycle enzymes fructose-1,6/sedoheptulose-1,7-bisphosphatase (F/SBPase) and transketolase were tested for effects on catalytic activity in vitro. The Calvin cycle intermediate glyceraldehyde-3-phosphate activated both Synechocystis and Cupriavidus F/SBPase, which suggests a feed-forward activation of the cycle in both photoautotrophs and chemolithoautotrophs. In contrast to the stimulating effect in reduced conditions, glyceraldehyde-3-phosphate inactivated the Synechocystis F/SBPase in oxidized conditions by accelerating protein aggregation. Thus, metabolite-level regulation of the Calvin cycle is more prevalent than previously appreciated and may act in addition to redox regulation., Not duplicate with DiVA 1608437QC 20230307

Published

2022

6. Metabolite interactions in the bacterial Calvin cycle and implications for flux regulation

Author

Sporre, Emil, primary, Karlsen, Jan, additional, Schriever, Karen, additional, Samuelsson, Johannes Asplund, additional, Janasch, Markus, additional, Strandberg, Linnéa, additional, Kotol, David, additional, Zeckey, Luise, additional, Piazza, Ilaria, additional, Syrén, Per-Olof, additional, Edfors, Fredrik, additional, and Hudson, Elton P., additional

Published

2022

7. Identification of metabolite-protein interactions among enzymes of the Calvin Cycle in a CO2-fixing bacterium

Author

Sporre, Emil

Subjects

chemolithoautotroph, Calvin Cycle, proteomics, carbon fixation, Medical Biotechnology, Medicinsk bioteknologi, Cupriavidus necator, allosteric regulation, limited proteolysis, metabolite-protein interactions

Abstract

The Calvin – Benson cycle is the most widespread metabolic pathway capable of fixing CO2 in nature and a target of very high interest to metabolic engineers worldwide. In this study, 12 metabolites (ATP, AMP, NADP, NADPH, 2PG, 3PGA, FBP, RuBP, PEP, AKG, Ac-CoA and phenylalanine) were tested for protein – metabolite interactions against the proteome of Cupriavidus necator (previously Ralstonia eutropha) in the hopes of finding potential examples of allosteric regulation of the Calvin – Benson cycle. This is accomplished through the use of the LiP-SMap method, a recently developed shotgun proteomics method described by Piazza et al. capable of testing a metabolite of interest for interactions with the entire proteome of an organism at once. A functional protocol was developed and 234 protein – metabolite interactions between ATP and the proteome of C. necator are identified, 103 of which are potentially novel. Due to time constraints and setbacks in the lab, significant results were not produced for the other 11 metabolites tested. C. necator is an industrially relevant chemolithoautotroph that can be engineered to produce many valuable products and is capable of growth on CO2 and hydrogen gas. The bacteria were grown in continuous cultures after which the proteome was extracted while retaining its native state. Subsequently, the proteome was incubated with a metabolite of interest and subjected to limited, non-specific proteolysis. The resulting peptide mix was analyzed by liquid chromatography coupled tandem mass spectrometry (LC – MS/MS). Calvin-Benson-cykeln är den mest utbredda metaboliska processen i naturen med vilken det är möjligt att fixera CO2 och en måltavla av högsta intresse för bioteknologer världen över. I den här studien testades 12 metaboliter (ATP, AMP, NADP, NADPH, 2PG, 3PGA, FBP, RuBP, PEP, AKG, Ac-CoA and phenylalanine) för interaktioner mot proteomet från Cupriavidus necator (tidigare Ralstonia eutropha) i hopp om att hitta potentiella exempel på allosterisk reglering av Calvin-Benson-cykeln. Detta uppnåddes genom användning av LiP-SMap-metoden, en nyligen utvecklad proteomikmetod beskriven av Piazza et al. kapabel av att testa en metabolit av intresse mot en organisms hela proteom simultant. Ett funktionellt protokoll utvecklades och 234 interaktioner mellan ATP och proteomet av C. necator identifierades, varav 103 potentiellt är nyupptäckta. På grund av tidsbrist och motgångar i labbet producerades inga signifikanta resultat för de resterande 11 metaboliterna som testades. C. necator är en industriellt relevant kemolitoautotrof som kan växa på CO2 och vätgas, samt manipuleras till att producera många värdefulla produkter. Bakterierna odlades i kemostater varefter proteomet extraherades i sitt naturliga tillstånd. Sedan inkuberades proteomet med en metabolit av intresse och utsattes för begränsad, icke-specifik proteolys. Den resulterande peptidblandningen analyserades via tandem masspektrometri kopplad till vätskekromatografi (LC – MS/MS).

Published

2020

8. A chemostat- and enzyme-constrained model-based analysis of the exceptionally high substrate consumption rate and respiratory capacity of Geobacillus sp. LC300

Author

Ljungqvist, Emil E., Sporre, Emil, Hudson, Paul, Kerkhoven, Eduard, van Maris, Antonius J. A., Gustavsson, Martin, Ljungqvist, Emil E., Sporre, Emil, Hudson, Paul, Kerkhoven, Eduard, van Maris, Antonius J. A., and Gustavsson, Martin

Abstract

Geobacillus LC300 is a thermophilic bacterium displaying exceptionally fast growth and substrate utilization rates. Despite its potential, fundamental understanding of its metabolism and fast growth is lacking. Here, the metabolism of G. sp. LC300 was studied through a combination of chemostat cultivations, proteomics, and enzyme-constrained modeling. Glucose-limited chemostat cultivations revealed an unprecedented respiratory capacity of 48 mmolO2 gDW-1 h-1 and concomitant complete respiratory metabolism until very high growth rates. Respiro-fermentative metabolism, i.e. formation of acetate in addition to respiration, only occurred at growth rates above 1.7 h-1 and above glucose uptake rates of 23 mmolglc gDW-1 h-. Proteome analysis of batch cultures showed an optimization of central carbon metabolism, with high apparent catalytic rates allowing a redistribution of protein resources to respiration and biosynthetic pathways. An enzyme-constrained genome-scale model was constructed, able to accurately simulate chemostat and batch growth. Proteome allocation analysis at varying growth rates was studied in the model, and the overflow metabolism observed at growth rates above 1.7 h-1 was explained by a limited protein supply causing a downregulation of large respiratory enzymes in favor of ATP generation through acetate formation. These insights into G. sp. LC300’s metabolic capabilities enhance our understanding of fast-growing thermophilic microorganisms, which also paves the way for more efficient biomanufacturing applications., QC 20240814

9. Metabolite interactions in the bacterial Calvin cycle and implications for flux regulation

Author

Sporre, Emil, Karlsen, Jan, Schriever, Karen, Asplund-Samuelsson, Johannes, Janasch, Markus, Kotol, David, Strandberg, Linnéa, Zeckey, Luise, Piazza, Ilaria, Syrén, Per-Olof, Edfors, Fredrik, Hudson, Elton Paul, Sporre, Emil, Karlsen, Jan, Schriever, Karen, Asplund-Samuelsson, Johannes, Janasch, Markus, Kotol, David, Strandberg, Linnéa, Zeckey, Luise, Piazza, Ilaria, Syrén, Per-Olof, Edfors, Fredrik, and Hudson, Elton Paul

Abstract

Metabolite-level regulation of enzyme activity is important for coping with environmental shifts. Recently developed proteomics methodologies allow for mapping of post-translational interactions, including metabolite-protein interactions, that may be relevant for quickly regulating pathway activity. While feedback and feedforward regulation in glycolysis has been investigated, there is relatively little study of metabolite-level regulation in the Calvin cycle, particularly in bacteria. Here, we applied limited proteolysis small molecule mapping (LiP-SMap) to identify metabolite-protein interactions in four Calvin-cycle harboring bacteria, including two cyanobacteria and two chemolithoautotrophs. We identified widespread protein interactions with the metabolites GAP, ATP, and AcCoA in all strains. Some species-specific interactions were also observed, such as sugar phosphates in Cupravidus necator and glyoxylate in Synechocystis sp. PCC 6803. We screened some metabolites with LiP interactions for their effects on kinetics of the enzymes F/SBPase and transketolase, two enzymatic steps of the Calvin cycle. For both Synechocystis and Cupriavidus F/SBPase, GAP showed an activating effect that may be part of feed-forward regulation in the Calvin cycle. While we verified multiple enzyme inhibitors on transketolase, the effect on kinetics was often small. Incorporation of F/SBPase and transketolase regulations into a kinetic metabolic model of Synechocystis central metabolism resulted in a general decreased stability of the network, and altered flux control coefficients of transketolase as well as other reactions. The LiP-SMap methodology is promising for uncovering new modes of metabolic regulation, but will benefit from improved peptide quantification and higher peptide coverage of enzymes, as known interactions are often not detected for low-coverage proteins. . Furthermore, not all LiP interactions appear to be relevant for catalysis, as 4/8 (transketolase) and 5/6 (F/S, QC 20211117

10. Metabolite-level enzyme regulation in and around the bacterial Calvin cycle revealed by interaction proteomics

Author

Sporre, Emil, Karlsen, Jan, Schriever, Karen, Asplund-Samuelsson, Johannes, Janasch, Markus, Kotol, David, Strandberg, Linnéa, Zeckey, Luise, Piazza, Ilaria, Syrén, Per-Olof, Edfors, Fredrik, Hudson, Paul, Sporre, Emil, Karlsen, Jan, Schriever, Karen, Asplund-Samuelsson, Johannes, Janasch, Markus, Kotol, David, Strandberg, Linnéa, Zeckey, Luise, Piazza, Ilaria, Syrén, Per-Olof, Edfors, Fredrik, and Hudson, Paul

Abstract

QC 20211125

11. Metabolite interactions in the bacterial Calvin cycle and implications for flux regulation

Author

Sporre, Emil, Karlsen, Jan, Schriever, Karen, Asplund-Samuelsson, Johannes, Janasch, Markus, Kotol, David, Strandberg, Linnéa, Zeckey, Luise, Piazza, Ilaria, Syrén, Per-Olof, Edfors, Fredrik, Hudson, Elton Paul, Sporre, Emil, Karlsen, Jan, Schriever, Karen, Asplund-Samuelsson, Johannes, Janasch, Markus, Kotol, David, Strandberg, Linnéa, Zeckey, Luise, Piazza, Ilaria, Syrén, Per-Olof, Edfors, Fredrik, and Hudson, Elton Paul

Abstract

Metabolite-level regulation of enzyme activity is important for coping with environmental shifts. Recently developed proteomics methodologies allow for mapping of post-translational interactions, including metabolite-protein interactions, that may be relevant for quickly regulating pathway activity. While feedback and feedforward regulation in glycolysis has been investigated, there is relatively little study of metabolite-level regulation in the Calvin cycle, particularly in bacteria. Here, we applied limited proteolysis small molecule mapping (LiP-SMap) to identify metabolite-protein interactions in four Calvin-cycle harboring bacteria, including two cyanobacteria and two chemolithoautotrophs. We identified widespread protein interactions with the metabolites GAP, ATP, and AcCoA in all strains. Some species-specific interactions were also observed, such as sugar phosphates in Cupravidus necator and glyoxylate in Synechocystis sp. PCC 6803. We screened some metabolites with LiP interactions for their effects on kinetics of the enzymes F/SBPase and transketolase, two enzymatic steps of the Calvin cycle. For both Synechocystis and Cupriavidus F/SBPase, GAP showed an activating effect that may be part of feed-forward regulation in the Calvin cycle. While we verified multiple enzyme inhibitors on transketolase, the effect on kinetics was often small. Incorporation of F/SBPase and transketolase regulations into a kinetic metabolic model of Synechocystis central metabolism resulted in a general decreased stability of the network, and altered flux control coefficients of transketolase as well as other reactions. The LiP-SMap methodology is promising for uncovering new modes of metabolic regulation, but will benefit from improved peptide quantification and higher peptide coverage of enzymes, as known interactions are often not detected for low-coverage proteins. . Furthermore, not all LiP interactions appear to be relevant for catalysis, as 4/8 (transketolase) and 5/6 (F/S, QC 20211117

12. Metabolite interactions in the bacterial Calvin cycle and implications for flux regulation

Author

Sporre, Emil, Karlsen, Jan, Schriever, Karen, Asplund-Samuelsson, Johannes, Janasch, Markus, Kotol, David, Strandberg, Linnéa, Zeckey, Luise, Piazza, Ilaria, Syrén, Per-Olof, Edfors, Fredrik, Hudson, Elton Paul, Sporre, Emil, Karlsen, Jan, Schriever, Karen, Asplund-Samuelsson, Johannes, Janasch, Markus, Kotol, David, Strandberg, Linnéa, Zeckey, Luise, Piazza, Ilaria, Syrén, Per-Olof, Edfors, Fredrik, and Hudson, Elton Paul

Abstract

Metabolite-level regulation of enzyme activity is important for coping with environmental shifts. Recently developed proteomics methodologies allow for mapping of post-translational interactions, including metabolite-protein interactions, that may be relevant for quickly regulating pathway activity. While feedback and feedforward regulation in glycolysis has been investigated, there is relatively little study of metabolite-level regulation in the Calvin cycle, particularly in bacteria. Here, we applied limited proteolysis small molecule mapping (LiP-SMap) to identify metabolite-protein interactions in four Calvin-cycle harboring bacteria, including two cyanobacteria and two chemolithoautotrophs. We identified widespread protein interactions with the metabolites GAP, ATP, and AcCoA in all strains. Some species-specific interactions were also observed, such as sugar phosphates in Cupravidus necator and glyoxylate in Synechocystis sp. PCC 6803. We screened some metabolites with LiP interactions for their effects on kinetics of the enzymes F/SBPase and transketolase, two enzymatic steps of the Calvin cycle. For both Synechocystis and Cupriavidus F/SBPase, GAP showed an activating effect that may be part of feed-forward regulation in the Calvin cycle. While we verified multiple enzyme inhibitors on transketolase, the effect on kinetics was often small. Incorporation of F/SBPase and transketolase regulations into a kinetic metabolic model of Synechocystis central metabolism resulted in a general decreased stability of the network, and altered flux control coefficients of transketolase as well as other reactions. The LiP-SMap methodology is promising for uncovering new modes of metabolic regulation, but will benefit from improved peptide quantification and higher peptide coverage of enzymes, as known interactions are often not detected for low-coverage proteins. . Furthermore, not all LiP interactions appear to be relevant for catalysis, as 4/8 (transketolase) and 5/6 (F/S, QC 20211117

13. Metabolite interactions in the bacterial Calvin cycle and implications for flux regulation

Author

Sporre, Emil, Karlsen, Jan, Schriever, Karen, Asplund-Samuelsson, Johannes, Janasch, Markus, Kotol, David, Strandberg, Linnéa, Zeckey, Luise, Piazza, Ilaria, Syrén, Per-Olof, Edfors, Fredrik, Hudson, Elton Paul, Sporre, Emil, Karlsen, Jan, Schriever, Karen, Asplund-Samuelsson, Johannes, Janasch, Markus, Kotol, David, Strandberg, Linnéa, Zeckey, Luise, Piazza, Ilaria, Syrén, Per-Olof, Edfors, Fredrik, and Hudson, Elton Paul

Abstract

Metabolite-level regulation of enzyme activity is important for coping with environmental shifts. Recently developed proteomics methodologies allow for mapping of post-translational interactions, including metabolite-protein interactions, that may be relevant for quickly regulating pathway activity. While feedback and feedforward regulation in glycolysis has been investigated, there is relatively little study of metabolite-level regulation in the Calvin cycle, particularly in bacteria. Here, we applied limited proteolysis small molecule mapping (LiP-SMap) to identify metabolite-protein interactions in four Calvin-cycle harboring bacteria, including two cyanobacteria and two chemolithoautotrophs. We identified widespread protein interactions with the metabolites GAP, ATP, and AcCoA in all strains. Some species-specific interactions were also observed, such as sugar phosphates in Cupravidus necator and glyoxylate in Synechocystis sp. PCC 6803. We screened some metabolites with LiP interactions for their effects on kinetics of the enzymes F/SBPase and transketolase, two enzymatic steps of the Calvin cycle. For both Synechocystis and Cupriavidus F/SBPase, GAP showed an activating effect that may be part of feed-forward regulation in the Calvin cycle. While we verified multiple enzyme inhibitors on transketolase, the effect on kinetics was often small. Incorporation of F/SBPase and transketolase regulations into a kinetic metabolic model of Synechocystis central metabolism resulted in a general decreased stability of the network, and altered flux control coefficients of transketolase as well as other reactions. The LiP-SMap methodology is promising for uncovering new modes of metabolic regulation, but will benefit from improved peptide quantification and higher peptide coverage of enzymes, as known interactions are often not detected for low-coverage proteins. . Furthermore, not all LiP interactions appear to be relevant for catalysis, as 4/8 (transketolase) and 5/6 (F/S, QC 20211117

14. Metabolite interactions in the bacterial Calvin cycle and implications for flux regulation

Author

Sporre, Emil, Karlsen, Jan, Schriever, Karen, Asplund-Samuelsson, Johannes, Janasch, Markus, Kotol, David, Strandberg, Linnéa, Zeckey, Luise, Piazza, Ilaria, Syrén, Per-Olof, Edfors, Fredrik, Hudson, Elton Paul, Sporre, Emil, Karlsen, Jan, Schriever, Karen, Asplund-Samuelsson, Johannes, Janasch, Markus, Kotol, David, Strandberg, Linnéa, Zeckey, Luise, Piazza, Ilaria, Syrén, Per-Olof, Edfors, Fredrik, and Hudson, Elton Paul

Abstract

Metabolite-level regulation of enzyme activity is important for coping with environmental shifts. Recently developed proteomics methodologies allow for mapping of post-translational interactions, including metabolite-protein interactions, that may be relevant for quickly regulating pathway activity. While feedback and feedforward regulation in glycolysis has been investigated, there is relatively little study of metabolite-level regulation in the Calvin cycle, particularly in bacteria. Here, we applied limited proteolysis small molecule mapping (LiP-SMap) to identify metabolite-protein interactions in four Calvin-cycle harboring bacteria, including two cyanobacteria and two chemolithoautotrophs. We identified widespread protein interactions with the metabolites GAP, ATP, and AcCoA in all strains. Some species-specific interactions were also observed, such as sugar phosphates in Cupravidus necator and glyoxylate in Synechocystis sp. PCC 6803. We screened some metabolites with LiP interactions for their effects on kinetics of the enzymes F/SBPase and transketolase, two enzymatic steps of the Calvin cycle. For both Synechocystis and Cupriavidus F/SBPase, GAP showed an activating effect that may be part of feed-forward regulation in the Calvin cycle. While we verified multiple enzyme inhibitors on transketolase, the effect on kinetics was often small. Incorporation of F/SBPase and transketolase regulations into a kinetic metabolic model of Synechocystis central metabolism resulted in a general decreased stability of the network, and altered flux control coefficients of transketolase as well as other reactions. The LiP-SMap methodology is promising for uncovering new modes of metabolic regulation, but will benefit from improved peptide quantification and higher peptide coverage of enzymes, as known interactions are often not detected for low-coverage proteins. . Furthermore, not all LiP interactions appear to be relevant for catalysis, as 4/8 (transketolase) and 5/6 (F/S, QC 20211117