Your search keyword '"Wunder, Tobias"' showing total 17 results

1. The structural basis of Rubisco phase separation in the pyrenoid

Author

He, Shan, Chou, Hui-Ting, Matthies, Doreen, Wunder, Tobias, Meyer, Moritz T., Atkinson, Nicky, Martinez-Sanchez, Antonio, Jeffrey, Philip D., Port, Sarah A., Patena, Weronika, He, Guanhua, Chen, Vivian K., Hughson, Frederick M., McCormick, Alistair J., Mueller-Cajar, Oliver, Engel, Benjamin D., Yu, Zhiheng, and Jonikas, Martin C.

Published

2020

2. Structural insights into the LCIB protein family reveals a new group of β-carbonic anhydrases

Author

Jin, Shengyang, Sun, Jian, Wunder, Tobias, Tang, Desong, Cousins, Asaph B., Sze, Siu Kwan, Mueller-Cajar, Oliver, and Gao, Yong-Gui

Published

2016

3. A linker protein from a red-type pyrenoid phase separates with Rubisco via oligomerizing sticker motifs.

Author

Zhen Guo Oh, Shou Leong Ang, Warren, Cheng Wei Poh, Soak-Kuan Lai, Siu Kwan Sze, Hoi-Yeung Li, Bhushan, Shashi, Wunder, Tobias, and Mueller-Cajar, Oliver

Subjects

PHAEODACTYLUM tricornutum, STICKERS, TANDEM repeats, PHASE separation, ELECTRON microscopy

Abstract

The slow kinetics and poor substrate specificity of the key photosynthetic CO2-fixing enzyme Rubisco have prompted the repeated evolution of Rubisco-containing biomolecular condensates known as pyrenoids in the majority of eukaryotic microalgae. Diatoms dominate marine photosynthesis, but the interactions underlying their pyrenoids are unknown. Here, we identify and characterize the Rubisco linker protein PYCO1 from Phaeodactylum tricornutum. PYCO 1 is a tandem repeat protein containing prion-like domains that localizes to the pyrenoid. It undergoes homotypic liquid-liquid phase separation (LLPS) to form condensates that specifically partition diatom Rubisco. Saturation of PYCO 1 condensates with Rubisco greatly reduces the mobility of droplet components. Cryo--electron microscopy and mutagenesis data revealed the sticker motifs required for homotypic and heterotypic phase separation. Our data indicate that the PYCO 1--Rubisco network is cross-linked by PYCO 1 stickers that oligomerize to bind to the small subunits lining the central solvent channel of the Rubisco holoenzyme. A second sticker motif binds to the large subunit. Pyrenoidal Rubisco condensates are highly diverse and tractable models of functional LLPS. [ABSTRACT FROM AUTHOR]

Published

2023

4. Control of STN7 transcript abundance and transient STN7 dimerisation are involved in the regulation of STN7 activity

Author

Wunder, Tobias, Liu, Qiuping, Aseeva, Elena, Bonardi, Vera, Leister, Dario, and Pribil, Mathias

Published

2013

5. The invariant phenylalanine of precursor proteins discloses the importance of Omp85 for protein translocation into cyanelles

Author

Schleiff Enrico, Löffelhardt Wolfgang, Martin Roman, Wunder Tobias, and Steiner Jürgen M

Subjects

Evolution, QH359-425

Abstract

Abstract Background Today it is widely accepted that plastids are of cyanobacterial origin. During their evolutionary integration into the metabolic and regulatory networks of the host cell the engulfed cyanobacteria lost their independency. This process was paralleled by a massive gene transfer from symbiont to the host nucleus challenging the development of a retrograde protein translocation system to ensure plastid functionality. Such a system includes specific targeting signals of the proteins needed for the function of the plastid and membrane-bound machineries performing the transfer of these proteins across the envelope membranes. At present, most information on protein translocation is obtained by the analysis of land plants. However, the analysis of protein import into the primitive plastids of glaucocystophyte algae, revealed distinct features placing this system as a tool to understand the evolutionary development of translocation systems. Here, bacterial outer membrane proteins of the Omp85 family have recently been discussed as evolutionary seeds for the development of translocation systems. Results To further explore the initial mode of protein translocation, the observed phenylalanine dependence for protein translocation into glaucophyte plastids was pursued in detail. We document that indeed the phenylalanine has an impact on both, lipid binding and binding to proteoliposomes hosting an Omp85 homologue. Comparison to established import experiments, however, unveiled a major importance of the phenylalanine for recognition by Omp85. This finding is placed into the context of the evolutionary development of the plastid translocon. Conclusion The phenylalanine in the N-terminal domain signs as a prerequisite for protein translocation across the outer membrane assisted by a "primitive" translocon. This amino acid appears to be optimized for specifically targeting the Omp85 protein without enforcing aggregation on the membrane surface. The phenylalanine has subsequently been lost in the transit sequence, but can be found at the C-terminal position of the translocating pore. Thereby, the current hypothesis of Omp85 being the prokaryotic contribution to the ancestral Toc translocon can be supported.

Published

2007

6. Biomolecular condensates in photosynthesis and metabolism.

Author

Wunder, Tobias and Mueller-Cajar, Oliver

Subjects

*COENZYMES, *CARBON dioxide, *CONCEPTS, *PHOTOSYNTHESIS, *PHASE separation, *GAS exchange in plants

Abstract

The transient assembly or sequestration of enzymes into clusters permits the channeling of metabolites, but requires spatiotemporal control. Liquid liquid phase separation (LLPS) has recently emerged as a fundamental concept enabling formation of such assemblies into non-membrane bound organelles. The role of LLPS in the formation of condensates containing the CO 2 -fixing enzyme Rubisco has recently become appreciated. Both prokaryotic carboxysomes and eukaryotic pyrenoids enhance the carboxylation reaction by enabling the saturation of the enzyme with CO 2 gas. Biochemical reconstitution and structural biology are revealing the mechanistic basis of these photosynthetic condensates. At the same time other enzyme clusters, such as purinosomes for de-novo purine biosynthesis and G-bodies containing glycolytic enzymes, are emerging to behave like phase-separated systems. In the near future we anticipate details of many more such metabolic condensates to be revealed, deeply informing our ability to influence metabolic fluxes. [ABSTRACT FROM AUTHOR]

Published

2020

7. The pyrenoidal linker protein EPYC1 phase separates with hybrid Arabidopsis–Chlamydomonas Rubisco through interactions with the algal Rubisco small subunit.

Author

Atkinson, Nicky, Velanis, Christos N, Wunder, Tobias, Clarke, David J, Mueller-Cajar, Oliver, and McCormick, Alistair J

Subjects

CHLAMYDOMONAS reinhardtii, PROTEOLYSIS, CHLAMYDOMONAS, NICOTIANA benthamiana, PROTEIN-protein interactions, GREEN algae, CHLOROPHYLL spectra

Abstract

Photosynthetic efficiencies in plants are restricted by the CO2-fixing enzyme Rubisco but could be enhanced by introducing a CO2-concentrating mechanism (CCM) from green algae, such as Chlamydomonas reinhardtii (hereafter Chlamydomonas). A key feature of the algal CCM is aggregation of Rubisco in the pyrenoid, a liquid-like organelle in the chloroplast. Here we have used a yeast two-hybrid system and higher plants to investigate the protein–protein interaction between Rubisco and essential pyrenoid component 1 (EPYC1), a linker protein required for Rubisco aggregation. We showed that EPYC1 interacts with the small subunit of Rubisco (SSU) from Chlamydomonas and that EPYC1 has at least five SSU interaction sites. Interaction is crucially dependent on the two surface-exposed α-helices of the Chlamydomonas SSU. EPYC1 could be localized to the chloroplast in higher plants and was not detrimental to growth when expressed stably in Arabidopsis with or without a Chlamydomonas SSU. Although EPYC1 interacted with Rubisco in planta , EPYC1 was a target for proteolytic degradation. Plants expressing EPYC1 did not show obvious evidence of Rubisco aggregation. Nevertheless, hybrid Arabidopsis Rubisco containing the Chlamydomonas SSU could phase separate into liquid droplets with purified EPYC1 in vitro , providing the first evidence of pyrenoid-like aggregation for Rubisco derived from a higher plant. [ABSTRACT FROM AUTHOR]

Published

2019

8. CO2‐fixing liquid droplets: Towards a dissection of the microalgal pyrenoid.

Author

Wunder, Tobias, Oh, Zhen Guo, and Mueller‐Cajar, Oliver

Subjects

*CHLAMYDOMONAS reinhardtii, *GREEN algae, *PHASE separation, *PROTEIN-protein interactions, *SYNTHETIC biology, *DROPLETS

Abstract

CO2 enters the biosphere via the slow, oxygen‐sensitive carboxylase, Rubisco. To compensate, most microalgae saturate Rubisco with its substrate gas through a carbon dioxide concentrating mechanism. This strategy frequently involves compartmentalization of the enzyme in the pyrenoid, a non‐membrane enclosed compartment of the chloroplast stroma. Recently, tremendous advances have been achieved concerning the structure, physical properties, composition and in vitro reconstitution of the pyrenoid matrix from the green alga Chlamydomonas reinhardtii. The discovery of the intrinsically disordered multivalent Rubisco linker protein EPYC1 provided a biochemical framework to explain the subsequent finding that the pyrenoid resembles a liquid droplet in vivo. Reconstitution of the corresponding liquid‐liquid phase separation using pure Rubisco and EPYC1 allowed a detailed characterization of this process. Finally, a large high‐quality dataset of pyrenoidal protein‐protein interactions inclusive of spatial information provides ample substrate for rapid further functional dissection of the pyrenoid. Integrating and extending recent advances will inform synthetic biology efforts towards enhancing plant photosynthesis as well as contribute a versatile model towards experimentally dissecting the biochemistry of enzyme‐containing membraneless organelles. [ABSTRACT FROM AUTHOR]

Published

2019

9. Structural insights into the LCIB protein family reveals a new group of β-carbonic anhydrases.

Author

Shengyang Jin, Jian Sun, Wunder, Tobias, Desong Tang, Cousins, Asaph B., Siu Kwan Sze, Mueller-Cajar, Oliver, and Yong-Gui Gao

Subjects

MICROALGAE cultures & culture media, STAPHYLOCOCCAL protein A, ENZYME activation, CHLAMYDOMONAS reinhardtii, BIOCHEMISTRY, CARBOXYLASES

Abstract

Aquatic microalgae have evolved diverse CO2-concentrating mechanisms (CCMs) to saturate the carboxylase with its substrate, to compensate for the slow kinetics and competing oxygenation reaction of the key photosynthetic CO2-fixing enzyme rubisco. The limiting CO2-inducible B protein (LCIB) is known to be essential for CCM function in Chlamydomonas reinhardtii. To assign a function to this previously uncharacterized protein family, we purified and characterized a phylogenetically diverse set of LCIB homologs. Three of the six homologs are functional carbonic anhydrases (CAs). We determined the crystal structures of LCIB and limiting CO2-inducible C protein (LCIC) from C. reinhardtii and a CA-functional homolog from Phaeodactylum tricornutum, all of which harbor motifs bearing close resemblance to the active site of canonical β-CAs. Our results identify the LCIB family as a previously unidentified group of β-CAs, and provide a biochemical foundation for their function in the microalgal CCMs. [ABSTRACT FROM AUTHOR]

Published

2016

10. The major thylakoid protein kinases STN7 and STN8 revisited: effects of altered STN8 levels and regulatory specificities of the STN kinases.

Author

Wunder, Tobias, Wenteng Xu, Qiuping Liu, Wanner, Gerhard, Leister, Dario, and Pribil, Mathias

Subjects

PROTEIN kinases, THYLAKOIDS, PHOTOSYSTEMS, PHOSPHORYLATION, ARABIDOPSIS thaliana, SPATIAL distribution (Quantum optics)

Abstract

Thylakoid phosphorylation is predominantly mediated by the protein kinases STN7 and STN8. While STN7 primarily catalyzes LHCII phosphorylation, which enables LHCII to migrate from photosystem (PS) II to PSI, STN8 mainly phosphorylates PSII core proteins. The reversible phosphorylation of PSII core proteins is thought to regulate the PSII repair cycle and PSII supercomplex stability, and play a role in modulating the folding of thylakoid membranes. Earlier studies clearly demonstrated a considerable substrate overlap between the two STN kinases, raising the possibility of a balanced interdependence between them at either the protein or activity level. Here, we show that such an interdependence of the STN kinases on protein level does not seem to exist as neither knock-out nor overexpression of STN7 or STN8 affects accumulation of the other. STN7 and STN8 are both shown to be integral thylakoid proteins that form part of molecular supercomplexes, but exhibit different spatial distributions and are subject to different modes of regulation. Evidence is presented for the existence of a second redox-sensitive motif in STN7, which seems to be targeted by thioredoxin f. Effects of altered STN8 levels on PSII core phosphorylation, supercomplex formation, photosynthetic performance and thylakoid ultrastructure were analyzed in planta Arabidopsis thaliana using STN8-overexpressing plants (oeSTN8). In general, oeSTN8 plants were less sensitive to intense light and exhibited changes in thylakoid ultrastructure, with grana stacks containing more layers and reduced amounts of PSII supercomplexes. Hence, we conclude that STN8 and STN7 both acts in an a dosage- amount-dependent t manner, similar to what was shown for STN7 in previous studies. although However, their modes of regulation of the STN kinases appear to differ significantly. [ABSTRACT FROM AUTHOR]

Published

2013

11. The Omp85 proteins of Anabaena sp. PCC 7120 and E. coli are functionally distinct.

Author

Wunder, Tobias, Bredemeier, Rolf, Ruprecht, Maike, and Schleiff, Enrico

Subjects

*PROTEINS, *PROKARYOTES, *ENDOSYMBIOSIS, *CHLOROPLASTS, *PLANT organelles, *PLANT proteins, *ANABAENA, *ESCHERICHIA coli, *PLANT membranes

Abstract

Proteins of the Omp85 family are considered as very ancient and can be found in almost all prokaryotic species with an outer membrane and in the outer membrane of the endosymbiotic organelles mitochondrion and chloroplast. They are involved in the protein translocation across or the insertion of proteins into the membrane. In all species analyzed so far the protein signs essential for the biogenesis of the outer membrane or, in chloroplasts, of the organelle. Therefore, this protein family is an interesting indicator for both, the evolutionary development of organelles as well as proteins. Recent studies have emphasized differences between Omp85 proteins from cyanobacteria and proteobacteria. Here we challenge the observation by the comparison of the functionality in the native context of a bamA mutant of Escherichia coli. We demonstrate that Omp85 from Anabaena sp. PCC 7120 inserted into the outer membrane of E. coli does not complement the mutant strain but in contrast appears to be lethal for the proteobacterial cells. Possible explanations for this are discussed. [ABSTRACT FROM AUTHOR]

Published

2009

12. The invariant phenylalanine of precursor proteins discloses the importance of Omp85 for protein translocation into cyanelles.

Author

Wunder, Tobias, Martin, Roman, Löffelhardt, Wolfgang, Schleiff, Enrico, and Steiner, Jürgen M.

Subjects

*PLASTIDS, *PHENYLALANINE, *CYANOBACTERIA, *GENETIC transformation, *PROTEINS, *BIOLOGICAL membranes

Abstract

Background: Today it is widely accepted that plastids are of cyanobacterial origin. During their evolutionary integration into the metabolic and regulatory networks of the host cell the engulfed cyanobacteria lost their independency. This process was paralleled by a massive gene transfer from symbiont to the host nucleus challenging the development of a retrograde protein translocation system to ensure plastid functionality. Such a system includes specific targeting signals of the proteins needed for the function of the plastid and membrane-bound machineries performing the transfer of these proteins across the envelope membranes. At present, most information on protein translocation is obtained by the analysis of land plants. However, the analysis of protein import into the primitive plastids of glaucocystophyte algae, revealed distinct features placing this system as a tool to understand the evolutionary development of translocation systems. Here, bacterial outer membrane proteins of the Omp85 family have recently been discussed as evolutionary seeds for the development of translocation systems. Results: To further explore the initial mode of protein translocation, the observed phenylalanine dependence for protein translocation into glaucophyte plastids was pursued in detail. We document that indeed the phenylalanine has an impact on both, lipid binding and binding to proteoliposomes hosting an Omp85 homologue. Comparison to established import experiments, however, unveiled a major importance of the phenylalanine for recognition by Omp85. This finding is placed into the context of the evolutionary development of the plastid translocon. Conclusion: The phenylalanine in the N-terminal domain signs as a prerequisite for protein translocation across the outer membrane assisted by a "primitive" translocon. This amino acid appears to be optimized for specifically targeting the Omp85 protein without enforcing aggregation on the membrane surface. The phenylalanine has subsequently been lost in the transit sequence, but can be found at the C-terminal position of the translocating pore. Thereby, the current hypothesis of Omp85 being the prokaryotic contribution to the ancestral Toc translocon can be supported. [ABSTRACT FROM AUTHOR]

Published

2007

13. The phase separation underlying the pyrenoid-based microalgal Rubisco supercharger.

Author

Wunder, Tobias, Cheng, Steven Le Hung, Lai, Soak-Kuan, Li, Hoi-Yeung, and Mueller-Cajar, Oliver

Abstract

The slow and promiscuous properties of the CO2-fixing enzyme Rubisco constrain photosynthetic efficiency and have prompted the evolution of powerful CO2 concentrating mechanisms (CCMs). In eukaryotic microalgae a key strategy involves sequestration of the enzyme in the pyrenoid, a liquid non-membranous compartment of the chloroplast stroma. Here we show using pure components that two proteins, Rubisco and the linker protein Essential Pyrenoid Component 1 (EPYC1), are both necessary and sufficient to phase separate and form liquid droplets. The phase-separated Rubisco is functional. Droplet composition is dynamic and components rapidly exchange with the bulk solution. Heterologous and chimeric Rubiscos exhibit variability in their tendency to demix with EPYC1. The ability to dissect aspects of pyrenoid biochemistry in vitro will permit us to inform and guide synthetic biology ambitions aiming to engineer microalgal CCMs into crop plants. The microalgal pyrenoid has been reported to behave as a phase-separated liquid compartment. Here the authors demonstrate that the CO2-fixing enzyme Rubisco and the linker protein EPYC1 are necessary and sufficient to bring about a liquid-liquid phase separation that recapitulates the pyrenoid's liquid-like behavior. [ABSTRACT FROM AUTHOR]

Published

2018

14. PGRL1 Is the Elusive Ferredoxin-Plastoquinone Reductase in Photosynthetic Cyclic Electron Flow

Author

Hertle, Alexander P., Blunder, Thomas, Wunder, Tobias, Pesaresi, Paolo, Pribil, Mathias, Armbruster, Ute, and Leister, Dario

Subjects

*PLASTOQUINONES, *PHOTOSYSTEMS, *REDUCTASES, *FERREDOXINS, *ELECTRON transport, *ANGIOSPERMS

Abstract

Summary: During plant photosynthesis, photosystems I (PSI) and II (PSII), located in the thylakoid membranes of the chloroplast, use light energy to mobilize electron transport. Different modes of electron flow exist. Linear electron flow is driven by both photosystems and generates ATP and NADPH, whereas cyclic electron flow (CEF) is driven by PSI alone and generates ATP only. Two variants of CEF exist in flowering plants, of which one is sensitive to antimycin A (AA) and involves the two thylakoid proteins, PGR5 and PGRL1. However, neither the mechanism nor the site of reinjection of electrons from ferredoxin into the thylakoid electron transport chain during AA-sensitive CEF is known. Here, we show that PGRL1 accepts electrons from ferredoxin in a PGR5-dependent manner and reduces quinones in an AA-sensitive fashion. PGRL1 activity itself requires several redox-active cysteine residues and a Fe-containing cofactor. We therefore propose that PGRL1 is the elusive ferredoxin-plastoquinone reductase (FQR). [ABSTRACT FROM AUTHOR]

Published

2013

15. Dynamics of reversible protein phosphorylation in thylakoids of flowering plants: The roles of STN7, STN8 and TAP38

Author

Pesaresi, Paolo, Pribil, Mathias, Wunder, Tobias, and Leister, Dario

Subjects

*PHOSPHORYLATION, *THYLAKOIDS, *ANGIOSPERMS, *POST-translational modification, *MEMBRANE proteins, *PHOTOSYNTHESIS, *GENETIC regulation, *PROTEIN kinases

Abstract

Abstract: Phosphorylation is the most common post-translational modification found in thylakoid membrane proteins of flowering plants, targeting more than two dozen subunits of all multiprotein complexes, including some light-harvesting proteins. Recent progress in mass spectrometry-based technologies has led to the detection of novel low-abundance thylakoid phosphoproteins and localised their phosphorylation sites. Three of the enzymes involved in phosphorylation/dephosphorylation cycles in thylakoids, the protein kinases STN7 and STN8 and the phosphatase TAP38/PPH1, have been characterised in the model species Arabidopsis thaliana. Differential protein phosphorylation is associated with changes in illumination and various other environmental parameters, and has been implicated in several acclimation responses, the molecular mechanisms of which are only partly understood. The phenomenon of State Transitions, which enables rapid adaptation to short-term changes in illumination, has recently been shown to depend on reversible phosphorylation of LHCII by STN7-TAP38/PPH1. STN7 is also necessary for long-term acclimation responses that counteract imbalances in energy distribution between PSII and PSI by changing the rates of accumulation of their reaction-centre and light-harvesting proteins. Another aspect of photosynthetic acclimation, the modulation of thylakoid ultrastructure, depends on phosphorylation of PSII core proteins, mainly executed by STN8. Here we review recent advances in the characterisation of STN7, STN8 and TAP38/PPH1, and discuss their physiological significance within the overall network of thylakoid protein phosphorylation. This article is part of a Special Issue entitled: Regulation of Electron Transport in Chloroplasts. [Copyright &y& Elsevier]

Published

2011

16. A linker protein from a red-type pyrenoid phase separates with Rubisco via oligomerizing sticker motifs.

Author

Oh ZG, Ang WSL, Poh CW, Lai SK, Sze SK, Li HY, Bhushan S, Wunder T, and Mueller-Cajar O

Subjects

Ribulose-Bisphosphate Carboxylase genetics, Cryoelectron Microscopy, Biomolecular Condensates, Prions, Diatoms genetics

Abstract

The slow kinetics and poor substrate specificity of the key photosynthetic CO 2 -fixing enzyme Rubisco have prompted the repeated evolution of Rubisco-containing biomolecular condensates known as pyrenoids in the majority of eukaryotic microalgae. Diatoms dominate marine photosynthesis, but the interactions underlying their pyrenoids are unknown. Here, we identify and characterize the Rubisco linker protein PYCO1 from Phaeodactylum tricornutum . PYCO1 is a tandem repeat protein containing prion-like domains that localizes to the pyrenoid. It undergoes homotypic liquid-liquid phase separation (LLPS) to form condensates that specifically partition diatom Rubisco. Saturation of PYCO1 condensates with Rubisco greatly reduces the mobility of droplet components. Cryo-electron microscopy and mutagenesis data revealed the sticker motifs required for homotypic and heterotypic phase separation. Our data indicate that the PYCO1-Rubisco network is cross-linked by PYCO1 stickers that oligomerize to bind to the small subunits lining the central solvent channel of the Rubisco holoenzyme. A second sticker motif binds to the large subunit. Pyrenoidal Rubisco condensates are highly diverse and tractable models of functional LLPS.

Published

2023

17. CO 2 -fixing liquid droplets: Towards a dissection of the microalgal pyrenoid.

Author

Wunder T, Oh ZG, and Mueller-Cajar O

Subjects

Intrinsically Disordered Proteins chemistry, Ribulose-Bisphosphate Carboxylase chemistry, Carbon Dioxide metabolism, Chloroplasts metabolism, Intrinsically Disordered Proteins metabolism, Microalgae metabolism, Ribulose-Bisphosphate Carboxylase metabolism

Abstract

CO 2 enters the biosphere via the slow, oxygen-sensitive carboxylase, Rubisco. To compensate, most microalgae saturate Rubisco with its substrate gas through a carbon dioxide concentrating mechanism. This strategy frequently involves compartmentalization of the enzyme in the pyrenoid, a non-membrane enclosed compartment of the chloroplast stroma. Recently, tremendous advances have been achieved concerning the structure, physical properties, composition and in vitro reconstitution of the pyrenoid matrix from the green alga Chlamydomonas reinhardtii. The discovery of the intrinsically disordered multivalent Rubisco linker protein EPYC1 provided a biochemical framework to explain the subsequent finding that the pyrenoid resembles a liquid droplet in vivo. Reconstitution of the corresponding liquid-liquid phase separation using pure Rubisco and EPYC1 allowed a detailed characterization of this process. Finally, a large high-quality dataset of pyrenoidal protein-protein interactions inclusive of spatial information provides ample substrate for rapid further functional dissection of the pyrenoid. Integrating and extending recent advances will inform synthetic biology efforts towards enhancing plant photosynthesis as well as contribute a versatile model towards experimentally dissecting the biochemistry of enzyme-containing membraneless organelles., (© 2019 John Wiley & Sons A/S. Published by John Wiley & Sons Ltd.)

Published

2019