The structural basis of rubisco phase separation in the pyrenoid

Approximately one-third of global CO2 fixation occurs in a phase-separated algal organelle called the pyrenoid. The existing data suggest that the pyrenoid forms by the phase separation of the CO2-fixing enzyme Rubisco with a linker protein; however, the molecular interactions underlying this phase separation remain unknown. Here we present the structural basis of the interactions between Rubisco and its intrinsically disordered linker protein Essential Pyrenoid Component 1 (EPYC1) in the model alga Chlamydomonas reinhardtii. We find that EPYC1 consists of five evenly spaced Rubisco-binding regions that share sequence similarity. Single-particle cryo-electron microscopy of these regions in complex with Rubisco indicates that each Rubisco holoenzyme has eight binding sites for EPYC1, one on each Rubisco small subunit. Interface mutations disrupt binding, phase separation and pyrenoid formation. Cryo-electron tomography supports a model in which EPYC1 and Rubisco form a codependent multivalent network of specific low-affinity bonds, giving the matrix liquid-like properties. Our results advance the structural and functional understanding of the phase separation underlying the pyrenoid, an organelle that plays a fundamental role in the global carbon cycle

Directing the evolution of Rubisco and Rubisco activase: first impressions of a new tool for photosynthesis research

During the last decade the practice of laboratory-directed protein evolution has become firmly established as a versatile tool in biochemical research by enabling molecular evolution toward desirable phenotypes or detection of novel structure–function interactions. Applications of this technique in the field of photosynthesis research are still in their infancy, but recently first steps have been reported in the directed evolution of the CO2-fixing enzyme Rubisco and its helper protein Rubisco activase. Here we summarize directed protein evolution strategies and review the progressive advances that have been made to develop and apply suitable selection systems for screening mutant forms of these enzymes that improve the fitness of the host organism. The goal of increasing photosynthetic efficiency of plants by improving the kinetics of Rubisco has been a long-term goal scoring modest successes. We discuss how directed evolution methodologies may one day be able to circumvent the problems encountered during this venture

Evolving improved Synechococcus Rubisco functional expression in Escherichia coli

The photosynthetic CO2-fixing enzyme Rubisco [ribulose-P2 (D-ribulose-1, 5-bisphosphate) carboxylase/ oxygenase] has long been a target for engineering kinetic improvements. Towards this goal we used an RDE (Rubisco-dependent Escherichia coli) selection system to evolve Synechococcus PCC6301 Form I Rubisco under different selection pressures. In the fastest growing colonies, the Rubisco L (large) subunit substitutions 1174V, Q212L, M262T, F345L or F345I were repeatedly selected and shown to increase functional Rubisco expression 4- to 7-fold in the RDE and 5- to 17-fold when expressed in XLI-Blue E. coli. Introducing the F345I L-subunit substitution into Synechococcus PCC7002 Rubisco improved its functional expression 11-fold in XL1-Blue cells but could not elicit functional Arabidopsis Rubisco expression in the bacterium. The L subunit substitutions L161M and M169L were complementary in improving Rubisco yield 11-fold, whereas individually they improved yield ε15-fold. In XL1-Blue cells, additional GroE chaperonin enhanced expression of the I174V, Q212L and M262T mutant Rubiscos but engendered little change in the yield of the more assembly-competent F345I or F345L mutants. In contrast, the Rubisco chaperone RbcX stimulated functional assembly of wild-type and mutant Rubiscos. The kinetic properties of the mutated Rubiscos varied with noticeable reductions in carboxylation and oxygenation efficiency accompanying the Q212L mutation and a 2-fold increase in Kribulose-P2 (KM for the substrate ribulose-P2) for the F345L mutant, which was contrary to the ∼30% reductions in Kribulose-P2 for the other mutants. These results confirm the RDE systems versatility for identifying mutations that improve functional Rubisco expression in E. coli and provide an impetus for developing the system to screen for kinetic improvements

New roads lead to Rubisco in Archaebacteria

The discovery of the CO2-fixing enzyme Rubisco in the Archaebacteria has presented a conundrum in that they apparently lack the gene for phosphoribulokinase, which is required to generate Rubisco's substrate ribulose 1,5-bisphosphate (RuBP). However, tw

In Vitro Characterization of Thermostable CAM Rubisco Activase Reveals a Rubisco Interacting Surface Loop

To maintain metabolic flux through the Calvin-Benson-Bassham cycle in higher plants, dead-end inhibited complexes of Rubisco must constantly be engaged and remodeled by the molecular chaperone Rubisco activase (Rca). In C3 plants, the thermolability of Rca is responsible for the deactivation of Rubisco and reduction of photosynthesis at moderately elevated temperatures. We reasoned that crassulacean acid metabolism (CAM) plants must possess thermostable Rca to support Calvin-Benson-Bassham cycle flux during the day when stomata are closed. A comparative biochemical characterization of rice (Oryza sativa) and Agave tequilana Rca isoforms demonstrated that the CAM Rca isoforms are approximately10°C more thermostable than the C3 isoforms. Agave Rca also possessed a much higher in vitro biochemical activity, even at low assay temperatures. Mixtures of rice and agave Rca form functional hetero-oligomers in vitro, but only the rice isoforms denature at nonpermissive temperatures. The high thermostability and activity of agave Rca mapped to the N-terminal 244 residues. A Glu-217-Gln amino acid substitution was found to confer high Rca activity to rice Rca. Further mutational analysis suggested that Glu-217 restricts the flexibility of the α4-β4 surface loop that interacts with Rubisco via Lys-216. CAM plants thus promise to be a source of highly functional, thermostable Rca candidates for thermal fortification of crop photosynthesis. Careful characterization of their properties will likely reveal further protein-protein interaction motifs to enrich our mechanistic model of Rca function.MOE (Min. of Education, S’pore)Published versio

Biomolecular condensates in photosynthesis and metabolism

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 CO2-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 CO2 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.Ministry of Education (MOE)Accepted versionOur research on microalgal metabolic condensates is supported by the Ministry of Education, Singapore, under its Academic Research Fund (AcRF) Tier 2 programme (MOE2018-T2-2-059). We apologize to colleagues whose important work was not cited due to brevity of this format, with priority given to papers published in the last two years

Directed Evolution of Rubisco in Escherichia coli Reveals a Specificity-Determining Hydrogen Bond in the Form 11 Enzyme

Ribulose 1,5-bisphosphate carboxylase/oxygenase (Rubisco) occupies a critical position in photosynthetic CO2-fixation and consequently has been the focus of intense study. Crystal-structure-guided site-directed mutagenesis studies have met with limited success in engineering kinetic improvements to Rubisco, highlighting our inadequate understanding of structural constraints at the atomic level that dictate the enzyme's catalytic chemistry. Bioselection provides an alternative random mutagenic approach that is useful for identifying and elucidating imperceptible structure - function relationships. Using the dimeric Form II Rubisco from Rhodospirillum rubrum, its gene (rbcM) was randomly mutated and introduced under positive selection into Escherichia coli cells metabolically engineered to be dependent on Rubisco to detoxify its substrate ribulose 1,5-bisphosphate. Thirteen colonies displaying improved fitness were isolated, and all were found to harbor mutations in rbcM at one of two codons, histidine-44 or aspartate-117, that are structurally adjacent amino acids located about 10 Å from the active site. Biochemical characterization of the mutant enzymes showed the mutations reduced their CO2/O2 specificity by 40% and decreased their carboxylation turnover rate by 20-40%. Structural analyses showed histidine-44 and aspartate-117 form a hydrogen bond in R. rubrum Rubisco and that the residues are conserved among other Form II Rubiscos. This study demonstrated the utility of directed evolution in E. coli for identifying catalytically relevant residues (in particular nonobvious residues disconnected from active site residues) and their potential molecular interactions that influence Rubisco's catalytic chemistry

Rubisco activase requires residues in the large subunit N terminus to remodel inhibited plant Rubisco

The photosynthetic CO2 fixing enzyme ribulose 1,5-bisphosphate carboxylase/oxygenase (Rubisco) forms dead-end inhibited complexes while binding multiple sugar phosphates, including its substrate ribulose 1,5-bisphosphate. Rubisco can be rescued from this inhibited form by molecular chaperones belonging to the ATPases associated with diverse cellular activities (AAA+ proteins) termed Rubisco activases (Rcas). The mechanism of green-type Rca found in higher plants has proved elusive, in part because until recently higher-plant Rubiscos could not be expressed recombinantly. Identifying the interaction sites between Rubisco and Rca is critical to formulate mechanistic hypotheses. Toward that end here we purify and characterize a suite of 33 Arabidopsis Rubisco mutants for their ability to be activated by Rca. Mutation of 17 surface-exposed large subunit residues did not yield variants that were perturbed in their interaction with Rca. In contrast, we find that Rca activity is highly sensitive to truncations and mutations in the conserved N terminus of the Rubisco large subunit. Large subunits lacking residues 1-4 are functional Rubiscos but cannot be activated. Both T5A and T7A substitutions result in functional carboxylases that are poorly activated by Rca, indicating the side chains of these residues form a critical interaction with the chaperone. Many other AAA+ proteins function by threading macromolecules through a central pore of a disc-shaped hexamer. Our results are consistent with a model in which Rca transiently threads the Rubisco large subunit N terminus through the axial pore of the AAA+ hexamer.Ministry of Education (MOE)National Research Foundation (NRF)Published versionThis work was funded by Grant MOE2016-T2-2-088 from the Ministry of Education of Singapore and Grant NRF2017-NRF-ISF002-2667 from the National Research Foundation of Singapore (to O. M.-C.)