Your search keyword '"carboxysome"' showing total 798 results

1. Corrigendum: Atypical carboxysome loci: JEEPs or junk?

Author

Sutter, Markus, Kerfeld, Cheryl, and Scott, Kathleen

Subjects

autotroph, carbon dioxide fixation, carbonic anhydrase, carboxysome, microcompartment

Abstract

[This corrects the article DOI: 10.3389/fmicb.2022.872708.].

Published

2024

2. A new type of carboxysomal carbonic anhydrase in sulfur chemolithoautotrophs from alkaline environments.

Author

Wieschollek, Jana, Fuller, Daniella, Gahramanova, Arin, Millen, Terrence, Mislay, Ashianna J., Payne, Ren R., Walsh, Daniel P., YuXuan Zhao, Carney, Madilyn, Cross, Jaden, Kashem, John, Korde, Ruchi, Lacy, Christine, Lyons, Noah, Mason, Tori, Torres-Betancourt, Kayla, Trapnell, Tyler, Dennison, Clare L., Chaput, Dale, and Scott, Kathleen M.

Subjects

*CARBONIC anhydrase, *AUTOTROPHIC bacteria, *CARBON dioxide, *ESCHERICHIA coli, *ENZYMES

Abstract

Autotrophic bacteria are able to fix CO2 in a great diversity of habitats, even though this dissolved gas is relatively scarce at neutral pH and above. As many of these bacteria rely on CO2 fixation by ribulose 1,5-bisphospate carboxylase/oxygenase (RubisCO) for biomass generation, they must compensate for the catalytical constraints of this enzyme with CO2-concentrating mechanisms (CCMs). CCMs consist of CO2 and HCO3- transporters and carboxysomes. Carboxysomes encapsulate RubisCO and carbonic anhydrase (CA) within a protein shell and are essential for the operation of a CCM in autotrophic Bacteria that use the Calvin-Benson-Basham cycle. Members of the genus Thiomicrospira lack genes homologous to those encoding previously described CA, and prior to this work, the mechanism of function for their carboxysomes was unclear. In this paper, we provide evidence that a member of the recently discovered iota family of carbonic anhydrase enzymes (ιCA) plays a role in CO2 fixation by carboxysomes from members of Thiomicrospira and potentially other Bacteria. Carboxysome enrichments from Thiomicrospira pelophila and Thiomicrospira aerophila were found to have CA activity and contain ιCA, which is encoded in their carboxysome loci. When the gene encoding ιCA was interrupted in T. pelophila, cells could no longer grow under low-CO2 conditions, and CA activity was no longer detectable in their carboxysomes. When T. pelophila ιCA was expressed in a strain of Escherichia coli lacking native CA activity, this strain recovered an ability to grow under low CO2 conditions, and CA activity was present in crude cell extracts prepared from this strain. [ABSTRACT FROM AUTHOR]

Published

2024

3. Identification of a carbonic anhydrase-Rubisco complex within the alpha-carboxysome.

Author

Blikstad, Cecilia, Dugan, Eli, Laughlin, Thomas, Turnšek, Julia, Liu, Mira, Shoemaker, Sophie, Vogiatzi, Nikoleta, Savage, David, and Remis, .

Subjects

CO2 fixation, carbonic anhydrase, carboxysome, cryoelectron microscopy, protein–protein interactions, Ribulose-Bisphosphate Carboxylase, Carbonic Anhydrases, Carbon Dioxide, Cryoelectron Microscopy, Organelles, Bacterial Proteins

Abstract

Carboxysomes are proteinaceous organelles that encapsulate key enzymes of CO2 fixation-Rubisco and carbonic anhydrase-and are the centerpiece of the bacterial CO2 concentrating mechanism (CCM). In the CCM, actively accumulated cytosolic bicarbonate diffuses into the carboxysome and is converted to CO2 by carbonic anhydrase, producing a high CO2 concentration near Rubisco and ensuring efficient carboxylation. Self-assembly of the α-carboxysome is orchestrated by the intrinsically disordered scaffolding protein, CsoS2, which interacts with both Rubisco and carboxysomal shell proteins, but it is unknown how the carbonic anhydrase, CsoSCA, is incorporated into the α-carboxysome. Here, we present the structural basis of carbonic anhydrase encapsulation into α-carboxysomes from Halothiobacillus neapolitanus. We find that CsoSCA interacts directly with Rubisco via an intrinsically disordered N-terminal domain. A 1.98 Å single-particle cryoelectron microscopy structure of Rubisco in complex with this peptide reveals that CsoSCA binding is predominantly mediated by a network of hydrogen bonds. CsoSCAs binding site overlaps with that of CsoS2, but the two proteins utilize substantially different motifs and modes of binding, revealing a plasticity of the Rubisco binding site. Our results advance the understanding of carboxysome biogenesis and highlight the importance of Rubisco, not only as an enzyme but also as a central hub for mediating assembly through protein interactions.

Published

2023

4. A systematic exploration of bacterial form I rubisco maximal carboxylation rates.

Author

de Pins, Benoit, Greenspoon, Lior, Bar-On, Yinon M, Shamshoum, Melina, Ben-Nissan, Roee, Milshtein, Eliya, Davidi, Dan, Sharon, Itai, Mueller-Cajar, Oliver, Noor, Elad, and Milo, Ron

Subjects

*CARBON fixation, *BACTERIAL enzymes, *ECOLOGICAL niche, *BACTERIAL diversity, *GENETIC variation, *AUTOTROPHIC bacteria, *CARBOXYLATION

Abstract

Autotrophy is the basis for complex life on Earth. Central to this process is rubisco—the enzyme that catalyzes almost all carbon fixation on the planet. Yet, with only a small fraction of rubisco diversity kinetically characterized so far, the underlying biological factors driving the evolution of fast rubiscos in nature remain unclear. We conducted a high-throughput kinetic characterization of over 100 bacterial form I rubiscos, the most ubiquitous group of rubisco sequences in nature, to uncover the determinants of rubisco's carboxylation velocity. We show that the presence of a carboxysome CO2 concentrating mechanism correlates with faster rubiscos with a median fivefold higher rate. In contrast to prior studies, we find that rubiscos originating from α-cyanobacteria exhibit the highest carboxylation rates among form I enzymes (≈10 s−1 median versus <7 s−1 in other groups). Our study systematically reveals biological and environmental properties associated with kinetic variation across rubiscos from nature. Synopsis: Form I rubisco, known for its slow kinetics in plants and algae, exhibits a great unexplored diversity in autotrophic bacteria. This article represents the first large-scale survey of bacterial form I rubisco kinetics and reveals unifying features of fast carboxylating rubiscos. Over 100 homologs were systematically screened, spanning the wide genetic diversity of form I rubisco enzymes across a variety of ecological niches and metabolic profiles. Phototrophy and carboxysome association are correlated with fast-carboxylating rubiscos. α-cyanobacteria emerges as the bacterial clade expressing the fastest form I rubiscos on Earth. Bacterial rubisco enzymes associated with carboxysomes have the fastest CO2-fixing rates. [ABSTRACT FROM AUTHOR]

Published

2024

5. A carboxysome‐based CO2 concentrating mechanism for C3 crop chloroplasts: advances and the road ahead.

Author

Nguyen, Nghiem D., Pulsford, Sacha B., Förster, Britta, Rottet, Sarah, Rourke, Loraine, Long, Benedict M., and Price, G. Dean

Subjects

*CHLOROPLASTS, *CROPS, *CROP yields, *FOOD security, *CARBON dioxide, *SYNTHETIC biology

Abstract

SUMMARY: The introduction of the carboxysome‐based CO2 concentrating mechanism (CCM) into crop plants has been modelled to significantly increase crop yields. This projection serves as motivation for pursuing this strategy to contribute to global food security. The successful implementation of this engineering challenge is reliant upon the transfer of a microcompartment that encapsulates cyanobacterial Rubisco, known as the carboxysome, alongside active bicarbonate transporters. To date, significant progress has been achieved with respect to understanding various aspects of the cyanobacterial CCM, and more recently, different components of the carboxysome have been successfully introduced into plant chloroplasts. In this Perspective piece, we summarise recent findings and offer new research avenues that will accelerate research in this field to ultimately and successfully introduce the carboxysome into crop plants for increased crop yields. Significance Statement: The efficacy of the cyanobacterial CO2‐concentrating mechanism (CCM) relies on its ability to concentrate CO2 around the Rubisco enzyme, which is natively encapsulated within a carboxysome. As our understanding of carboxysome biogenesis and functionality grows, there is optimism that this microcompartment and the cyanobacterial CCM as a whole, can contribute to addressing global food security. [ABSTRACT FROM AUTHOR]

Published

2024

6. Uncovering the roles of the scaffolding protein CsoS2 in mediating the assembly and shape of the α-carboxysome shell

Author

Tianpei Li, Taiyu Chen, Ping Chang, Xingwu Ge, Vincent Chriscoli, Gregory F. Dykes, Qiang Wang, and Lu-Ning Liu

Subjects

bacterial microcompartment, carboxysome, self-assembly, encapsulation, structurally disordered protein, Microbiology, QR1-502

Abstract

ABSTRACT Carboxysomes are proteinaceous organelles featuring icosahedral protein shells that enclose the carbon-fixing enzymes, ribulose-1,5-bisphosphate carboxylase oxygenase (Rubisco), along with carbonic anhydrase. The intrinsically disordered scaffolding protein CsoS2 plays a vital role in the construction of α-carboxysomes through bridging the shell and cargo enzymes. The N-terminal domain of CsoS2 binds Rubisco and facilitates Rubisco packaging within the α-carboxysome, whereas the C-terminal domain of CsoS2 (CsoS2-C) anchors to the shell and promotes shell assembly. However, the role of the middle region of CsoS2 (CsoS2-M) has remained elusive. Here, we conducted in-depth examinations on the function of CsoS2-M in the assembly of the α-carboxysome shell by generating a series of recombinant shell variants in the absence of cargos. Our results reveal that CsoS2-M assists CsoS2-C in the assembly of the α-carboxysome shell and plays an important role in shaping the α-carboxysome shell through enhancing the association of shell proteins on both the facet-facet interfaces and flat shell facets. Moreover, CsoS2-M is responsible for recruiting the C-terminal truncated isoform of CsoS2, CsoS2A, into α-carboxysomes, which is crucial for Rubisco encapsulation and packaging. This study not only deepens our knowledge of how the carboxysome shell is constructed and regulated but also lays the groundwork for engineering and repurposing carboxysome-based nanostructures for diverse biotechnological purposes.IMPORTANCECarboxysomes are a paradigm of organelle-like structures in cyanobacteria and many proteobacteria. These nanoscale compartments enclose Rubisco and carbonic anhydrase within an icosahedral virus-like shell to improve CO2 fixation, playing a vital role in the global carbon cycle. Understanding how the carboxysomes are formed is not only important for basic research studies but also holds promise for repurposing carboxysomes in bioengineering applications. In this study, we focuses on a specific scaffolding protein called CsoS2, which is involved in facilitating the assembly of α-type carboxysomes. By deciphering the functions of different parts of CsoS2, especially its middle region, we provide new insights into how CsoS2 drives the stepwise assembly of the carboxysome at the molecular level. This knowledge will guide the rational design and reprogramming of carboxysome nanostructures for many biotechnological applications.

Published

2024

7. BMC Caller: a webtool to identify and analyze bacterial microcompartment types in sequence data

Author

Sutter, Markus and Kerfeld, Cheryl A

Subjects

Biochemistry and Cell Biology, Bioinformatics and Computational Biology, Genetics, Biological Sciences, Bacteria, Bacterial Proteins, Metabolic Networks and Pathways, Organelles, Phylogeny, Bacterial microcompartment, Protein HMM profile, Protein sequence analysis, Metabolosome, Carboxysome, Medical and Health Sciences, Bioinformatics, Biological sciences

Abstract

Bacterial microcompartments (BMCs) are protein-based organelles found across the bacterial tree of life. They consist of a shell, made of proteins that oligomerize into hexagonally and pentagonally shaped building blocks, that surrounds enzymes constituting a segment of a metabolic pathway. The proteins of the shell are unique to BMCs. They also provide selective permeability; this selectivity is dictated by the requirements of their cargo enzymes. We have recently surveyed the wealth of different BMC types and their occurrence in all available genome sequence data by analyzing and categorizing their components found in chromosomal loci using HMM (Hidden Markov Model) protein profiles. To make this a "do-it yourself" analysis for the public we have devised a webserver, BMC Caller ( https://bmc-caller.prl.msu.edu ), that compares user input sequences to our HMM profiles, creates a BMC locus visualization, and defines the functional type of BMC, if known. Shell proteins in the input sequence data are also classified according to our function-agnostic naming system and there are links to similar proteins in our database as well as an external link to a structure prediction website to easily generate structural models of the shell proteins, which facilitates understanding permeability properties of the shell. Additionally, the BMC Caller website contains a wealth of information on previously analyzed BMC loci with links to detailed data for each BMC protein and phylogenetic information on the BMC shell proteins. Our tools greatly facilitate BMC type identification to provide the user information about the associated organism's metabolism and enable discovery of new BMC types by providing a reference database of all currently known examples.

Published

2022

8. Atypical Carboxysome Loci: JEEPs or Junk?

Author

Sutter, Markus, Kerfeld, Cheryl A., and Scott, Kathleen M.

Subjects

LOCUS (Genetics), CARBONIC anhydrase, ACTIVE biological transport, PROTEOBACTERIA, AUTOTROPHIC bacteria, OPERONS, CARBON dioxide fixation, NUCLEOTIDE sequencing, OXYGENASES

Abstract

Carboxysomes, responsible for a substantial fraction of CO2 fixation on Earth, are proteinaceous microcompartments found in many autotrophic members of domain Bacteria, primarily from the phyla Proteobacteria and Cyanobacteria. Carboxysomes facilitate CO2 fixation by the Calvin-Benson-Bassham (CBB) cycle, particularly under conditions where the CO2 concentration is variable or low, or O2 is abundant. These microcompartments are composed of an icosahedral shell containing the enzymes ribulose 1,5-carboxylase/oxygenase (RubisCO) and carbonic anhydrase. They function as part of a CO2 concentrating mechanism, in which cells accumulate HCO3 - in the cytoplasm via active transport, HCO3 - enters the carboxysomes through pores in the carboxysomal shell proteins, and carboxysomal carbonic anhydrase facilitates the conversion of HCO3 - to CO2, which RubisCO fixes. Two forms of carboxysomes have been described: a-carboxysomes and ß-carboxysomes, which arose independently from ancestral microcompartments. The a-carboxysomes present in Proteobacteria and some Cyanobacteria have shells comprised of four types of proteins [CsoS1 hexamers, CsoS4 pentamers, CsoS2 assembly proteins, and a-carboxysomal carbonic anhydrase (CsoSCA)], and contain form IA RubisCO (CbbL and CbbS). In the majority of cases, these components are encoded in the genome near each other in a gene locus, and transcribed together as an operon. Interestingly, genome sequencing has revealed some a-carboxysome loci that are missing genes encoding one or more of these components. Some loci lack the genes encoding RubisCO, others lack a gene encoding carbonic anhydrase, some loci are missing shell protein genes, and in some organisms, genes homologous to those encoding the carboxysome-associated carbonic anhydrase are the only carboxysomerelated genes present in the genome. Given that RubisCO, assembly factors, carbonic anhydrase, and shell proteins are all essential for carboxysome function, these absences are quite intriguing. In this review, we provide an overview of the most recent studies of the structural components of carboxysomes, describe the genomic context and taxonomic distribution of atypical carboxysome loci, and propose functions for these variants. We suggest that these atypical loci are JEEPs, which have modified functions based on the presence of Just Enough Essential Parts. [ABSTRACT FROM AUTHOR]

Published

2024

9. Impact of Carbon Fixation, Distribution and Storage on the Production of Farnesene and Limonene in Synechocystis PCC 6803 and Synechococcus PCC 7002.

Author

Vincent, Marine, Blanc-Garin, Victoire, Chenebault, Célia, Cirimele, Mattia, Farci, Sandrine, Garcia-Alles, Luis Fernando, Cassier-Chauvat, Corinne, and Chauvat, Franck

Subjects

*CARBON fixation, *LIMONENE, *TERPENES, *SYNECHOCOCCUS, *SYNECHOCYSTIS, *CYANOBACTERIAL toxins, *GENETIC overexpression, *CYANOBACTERIA

Abstract

Terpenes are high-value chemicals which can be produced by engineered cyanobacteria from sustainable resources, solar energy, water and CO2. We previously reported that the euryhaline unicellular cyanobacteria Synechocystis sp. PCC 6803 (S.6803) and Synechococcus sp. PCC 7002 (S.7002) produce farnesene and limonene, respectively, more efficiently than other terpenes. In the present study, we attempted to enhance farnesene production in S.6803 and limonene production in S.7002. Practically, we tested the influence of key cyanobacterial enzymes acting in carbon fixation (RubisCO, PRK, CcmK3 and CcmK4), utilization (CrtE, CrtR and CruF) and storage (PhaA and PhaB) on terpene production in S.6803, and we compared some of the findings with the data obtained in S.7002. We report that the overproduction of RubisCO from S.7002 and PRK from Cyanothece sp. PCC 7425 increased farnesene production in S.6803, but not limonene production in S.7002. The overexpression of the crtE genes (synthesis of terpene precursors) from S.6803 or S.7002 did not increase farnesene production in S.6803. In contrast, the overexpression of the crtE gene from S.6803, but not S.7002, increased farnesene production in S.7002, emphasizing the physiological difference between these two model cyanobacteria. Furthermore, the deletion of the crtR and cruF genes (carotenoid synthesis) and phaAB genes (carbon storage) did not increase the production of farnesene in S.6803. Finally, as a containment strategy of genetically modified strains of S.6803, we report that the deletion of the ccmK3K4 genes (carboxysome for CO2 fixation) did not affect the production of limonene, but decreased the production of farnesene in S.6803. [ABSTRACT FROM AUTHOR]

Published

2024

10. Natural variation in metabolism of the Calvin-Benson cycle.

Author

Clapero, Vittoria, Arrivault, Stéphanie, and Stitt, Mark

Subjects

*CALVIN cycle, *ATMOSPHERIC carbon dioxide, *ATMOSPHERIC oxygen, *SPECIES diversity, *WATER supply

Abstract

The Calvin-Benson cycle (CBC) evolved over 2 billion years ago but has been subject to massive selection due to falling atmospheric carbon dioxide, rising atmospheric oxygen and changing nutrient and water availability. In addition, large groups of organisms have evolved carbon-concentrating mechanisms (CCMs) that operate upstream of the CBC. Most previous studies of CBC diversity focused on Rubisco kinetics and regulation. Quantitative metabolite profiling provides a top-down strategy to uncover inter-species diversity in CBC operation. CBC profiles were recently published for twenty species including terrestrial C 3 species, terrestrial C 4 species that operate a biochemical CCM, and cyanobacteria and green algae that operate different types of biophysical CCM. Distinctive profiles were found for species with different modes of photosynthesis, revealing that evolution of the various CCMs was accompanied by co-evolution of the CBC. Diversity was also found between species that share the same mode of photosynthesis, reflecting lineage-dependent diversity of the CBC. Connectivity analysis uncovers constraints due to pathway and thermodynamic topology, and reveals that cross-species diversity in the CBC is driven by changes in the balance between regulated enzymes and in the balance between the CBC and the light reactions or end-product synthesis. • Calvin-Benson cycle metabolites were profiled in 20 species. • Calvin-Benson cycle has co-evolved with CO 2 -concentrating mechanisms. • Substantial diversity between species with the same photosynthesis mode. [ABSTRACT FROM AUTHOR]

Published

2024

11. Modeling bacterial microcompartment architectures for enhanced cyanobacterial carbon fixation.

Author

Trettel, Daniel S., Pacheco, Sara L., Laskie, Asa K., and Gonzalez-Esquer, C. Raul

Subjects

CARBON fixation, CARBONIC anhydrase, EXPERIMENTAL literature, MOLECULAR dynamics, GREEN business, CYANOBACTERIAL toxins

Abstract

The carboxysome is a bacterial microcompartment (BMC) which plays a central role in the cyanobacterial CO2-concentrating mechanism. These proteinaceous structures consist of an outer protein shell that partitions Rubisco and carbonic anhydrase from the rest of the cytosol, thereby providing a favorable microenvironment that enhances carbon fixation. The modular nature of carboxysomal architectures makes them attractive for a variety of biotechnological applications such as carbon capture and utilization. In silico approaches, such as molecular dynamics (MD) simulations, can support future carboxysome redesign efforts by providing new spatio-temporal insights on their structure and function beyond in vivo experimental limitations. However, specific computational studies on carboxysomes are limited. Fortunately, all BMC (including the carboxysome) are highly structurally conserved which allows for practical inferences to be made between classes. Here, we review simulations on BMC architectures which shed light on (1) permeation events through the shell and (2) assembly pathways. These models predict the biophysical properties surrounding the central pore in BMC-H shell subunits, which in turn dictate the efficiency of substrate diffusion. Meanwhile, simulations on BMC assembly demonstrate that assembly pathway is largely dictated kinetically by cargo interactions while final morphology is dependent on shell factors. Overall, these findings are contextualized within the wider experimental BMC literature and framed within the opportunities for carboxysome redesign for biomanufacturing and enhanced carbon fixation. [ABSTRACT FROM AUTHOR]

Published

2024

12. Atypical Carboxysome Loci: JEEPs or Junk?

Author

2020, USF Genomics Class, 2021, USF Genomics Class, Sutter, Markus, Kerfeld, Cheryl A, and Scott, Kathleen M

Subjects

Microbiology, Biological Sciences, Genetics, Human Genome, Biotechnology, 1.1 Normal biological development and functioning, USF Genomics Class 2020, USF Genomics Class 2021, autotroph, carbon dioxide fixation, carbonic anhydrase, carboxysome, microcompartment, Environmental Science and Management, Soil Sciences, Medical microbiology

Abstract

Carboxysomes, responsible for a substantial fraction of CO2 fixation on Earth, are proteinaceous microcompartments found in many autotrophic members of domain Bacteria, primarily from the phyla Proteobacteria and Cyanobacteria. Carboxysomes facilitate CO2 fixation by the Calvin-Benson-Bassham (CBB) cycle, particularly under conditions where the CO2 concentration is variable or low, or O2 is abundant. These microcompartments are composed of an icosahedral shell containing the enzymes ribulose 1,5-carboxylase/oxygenase (RubisCO) and carbonic anhydrase. They function as part of a CO2 concentrating mechanism, in which cells accumulate HCO3 - in the cytoplasm via active transport, HCO3 - enters the carboxysomes through pores in the carboxysomal shell proteins, and carboxysomal carbonic anhydrase facilitates the conversion of HCO3 - to CO2, which RubisCO fixes. Two forms of carboxysomes have been described: α-carboxysomes and β-carboxysomes, which arose independently from ancestral microcompartments. The α-carboxysomes present in Proteobacteria and some Cyanobacteria have shells comprised of four types of proteins [CsoS1 hexamers, CsoS4 pentamers, CsoS2 assembly proteins, and α-carboxysomal carbonic anhydrase (CsoSCA)], and contain form IA RubisCO (CbbL and CbbS). In the majority of cases, these components are encoded in the genome near each other in a gene locus, and transcribed together as an operon. Interestingly, genome sequencing has revealed some α-carboxysome loci that are missing genes encoding one or more of these components. Some loci lack the genes encoding RubisCO, others lack a gene encoding carbonic anhydrase, some loci are missing shell protein genes, and in some organisms, genes homologous to those encoding the carboxysome-associated carbonic anhydrase are the only carboxysome-related genes present in the genome. Given that RubisCO, assembly factors, carbonic anhydrase, and shell proteins are all essential for carboxysome function, these absences are quite intriguing. In this review, we provide an overview of the most recent studies of the structural components of carboxysomes, describe the genomic context and taxonomic distribution of atypical carboxysome loci, and propose functions for these variants. We suggest that these atypical loci are JEEPs, which have modified functions based on the presence of Just Enough Essential Parts.

Published

2022

13. Corrigendum: Atypical carboxysome loci: JEEPs or junk?

Author

USF Genomics Class, Markus Sutter, Cheryl A. Kerfeld, and Kathleen M. Scott

Subjects

carboxysome, microcompartment, carbonic anhydrase, carbon dioxide fixation, autotroph, Microbiology, QR1-502

Published

2024

14. Modeling bacterial microcompartment architectures for enhanced cyanobacterial carbon fixation

Author

Daniel S. Trettel, Sara L. Pacheco, Asa K. Laskie, and C. Raul Gonzalez-Esquer

Subjects

carbon fixation, bacterial microcompartments, carboxysome, molecular dynamics, permeation, phase separation, Plant culture, SB1-1110

Abstract

The carboxysome is a bacterial microcompartment (BMC) which plays a central role in the cyanobacterial CO2-concentrating mechanism. These proteinaceous structures consist of an outer protein shell that partitions Rubisco and carbonic anhydrase from the rest of the cytosol, thereby providing a favorable microenvironment that enhances carbon fixation. The modular nature of carboxysomal architectures makes them attractive for a variety of biotechnological applications such as carbon capture and utilization. In silico approaches, such as molecular dynamics (MD) simulations, can support future carboxysome redesign efforts by providing new spatio-temporal insights on their structure and function beyond in vivo experimental limitations. However, specific computational studies on carboxysomes are limited. Fortunately, all BMC (including the carboxysome) are highly structurally conserved which allows for practical inferences to be made between classes. Here, we review simulations on BMC architectures which shed light on (1) permeation events through the shell and (2) assembly pathways. These models predict the biophysical properties surrounding the central pore in BMC-H shell subunits, which in turn dictate the efficiency of substrate diffusion. Meanwhile, simulations on BMC assembly demonstrate that assembly pathway is largely dictated kinetically by cargo interactions while final morphology is dependent on shell factors. Overall, these findings are contextualized within the wider experimental BMC literature and framed within the opportunities for carboxysome redesign for biomanufacturing and enhanced carbon fixation.

Published

2024

15. Novel protein CcmS is required for stabilization of the assembly of β‐carboxysome in Synechocystis sp. strain PCC 6803.

Author

Chen, Xin, Zheng, Fangfang, Wang, Peng, and Mi, Hualing

Subjects

*SYNECHOCYSTIS, *PROTEINS, *SYNECHOCOCCUS

Abstract

Summary: The carboxysome plays an essential role in the carbon concentration mechanism in cyanobacteria. Although significant progress has been made in the structural analysis of the carboxysome, little is still known about its biosynthesis.We identified slr1911, a gene encoding a protein of unknown function in cyanobacterium Synechocystis sp. Strain PCC 6803 (Syn6803), which we termed ccmS by screening a low CO2‐sensitive mutant. CcmS interacts with CcmK1 and CcmM. The former is a shell protein of the β‐carboxysome and the latter is a crucial component of the β‐carboxysome, which is responsible for aggregating RuBisCO and recruiting shell proteins.The deletion of ccmS lowers the accumulation and assembly of CcmK1, resulting in aberrant carboxysomes, suppressed photosynthetic capacities, and leads to a slow growth phenotype, especially under CO2‐limited conditions.These observations suggest that CcmS stabilizes the assembly of the β‐carboxysome shell and likely connects the carboxysome core with the shell. Our results provide a molecular view of the role played by CcmS in the formation of the β‐carboxysome and its function in Syn6803. [ABSTRACT FROM AUTHOR]

Published

2023

16. Towards engineering a hybrid carboxysome.

Author

Nguyen, Nghiem Dinh, Pulsford, Sacha B., Hee, Wei Yi, Rae, Benjamin D., Rourke, Loraine M., Price, G. Dean, and Long, Benedict M.

Abstract

Carboxysomes are bacterial microcompartments, whose structural features enable the encapsulated Rubisco holoenzyme to operate in a high-CO2 environment. Consequently, Rubiscos housed within these compartments possess higher catalytic turnover rates relative to their plant counterparts. This particular enzymatic property has made the carboxysome, along with associated transporters, an attractive prospect to incorporate into plant chloroplasts to increase future crop yields. To date, two carboxysome types have been characterized, the α-type that has fewer shell components and the β-type that houses a faster Rubisco. While research is underway to construct a native carboxysome in planta, work investigating the internal arrangement of carboxysomes has identified conserved Rubisco amino acid residues between the two carboxysome types which could be engineered to produce a new, hybrid carboxysome. In theory, this hybrid carboxysome would benefit from the simpler α-carboxysome shell architecture while simultaneously exploiting the higher Rubisco turnover rates in β-carboxysomes. Here, we demonstrate in an Escherichia coli expression system, that the Thermosynechococcus elongatus Form IB Rubisco can be imperfectly incorporated into simplified Cyanobium α-carboxysome-like structures. While encapsulation of non-native cargo can be achieved, T. elongatus Form IB Rubisco does not interact with the Cyanobium carbonic anhydrase, a core requirement for proper carboxysome functionality. Together, these results suggest a way forward to hybrid carboxysome formation. [ABSTRACT FROM AUTHOR]

Published

2023

17. Adapting from Low to High: An Update to CO 2 -Concentrating Mechanisms of Cyanobacteria and Microalgae.

Author

Kupriyanova, Elena V., Pronina, Natalia A., and Los, Dmitry A.

Subjects

CARBON dioxide, CYANOBACTERIA, SYNECHOCOCCUS, CHLAMYDOMONAS reinhardtii, CARBONIC anhydrase, TWENTIETH century, MICROALGAE

Abstract

The intracellular accumulation of inorganic carbon (Ci) by microalgae and cyanobacteria under ambient atmospheric CO2 levels was first documented in the 80s of the 20th Century. Hence, a third variety of the CO2-concentrating mechanism (CCM), acting in aquatic photoautotrophs with the C3 photosynthetic pathway, was revealed in addition to the then-known schemes of CCM, functioning in CAM and C4 higher plants. Despite the low affinity of ribulose-1,5-bisphosphate carboxylase/oxygenase (Rubisco) of microalgae and cyanobacteria for the CO2 substrate and low CO2/O2 specificity, CCM allows them to perform efficient CO2 fixation in the reductive pentose phosphate (RPP) cycle. CCM is based on the coordinated operation of strategically located carbonic anhydrases and CO2/HCO3− uptake systems. This cooperation enables the intracellular accumulation of HCO3−, which is then employed to generate a high concentration of CO2 molecules in the vicinity of Rubisco's active centers compensating up for the shortcomings of enzyme features. CCM functions as an add-on to the RPP cycle while also acting as an important regulatory link in the interaction of dark and light reactions of photosynthesis. This review summarizes recent advances in the study of CCM molecular and cellular organization in microalgae and cyanobacteria, as well as the fundamental principles of its functioning and regulation. [ABSTRACT FROM AUTHOR]

Published

2023

18. BMC Caller: a webtool to identify and analyze bacterial microcompartment types in sequence data

Author

Markus Sutter and Cheryl A. Kerfeld

Subjects

Bacterial microcompartment, Protein HMM profile, Protein sequence analysis, Metabolosome, Carboxysome, Biology (General), QH301-705.5

Abstract

Abstract Bacterial microcompartments (BMCs) are protein-based organelles found across the bacterial tree of life. They consist of a shell, made of proteins that oligomerize into hexagonally and pentagonally shaped building blocks, that surrounds enzymes constituting a segment of a metabolic pathway. The proteins of the shell are unique to BMCs. They also provide selective permeability; this selectivity is dictated by the requirements of their cargo enzymes. We have recently surveyed the wealth of different BMC types and their occurrence in all available genome sequence data by analyzing and categorizing their components found in chromosomal loci using HMM (Hidden Markov Model) protein profiles. To make this a “do-it yourself” analysis for the public we have devised a webserver, BMC Caller ( https://bmc-caller.prl.msu.edu ), that compares user input sequences to our HMM profiles, creates a BMC locus visualization, and defines the functional type of BMC, if known. Shell proteins in the input sequence data are also classified according to our function-agnostic naming system and there are links to similar proteins in our database as well as an external link to a structure prediction website to easily generate structural models of the shell proteins, which facilitates understanding permeability properties of the shell. Additionally, the BMC Caller website contains a wealth of information on previously analyzed BMC loci with links to detailed data for each BMC protein and phylogenetic information on the BMC shell proteins. Our tools greatly facilitate BMC type identification to provide the user information about the associated organism’s metabolism and enable discovery of new BMC types by providing a reference database of all currently known examples.

Published

2022

19. Extracellular CahB1 from Sodalinema gerasimenkoae IPPAS B-353 Acts as a Functional Carboxysomal β-Carbonic Anhydrase in Synechocystis sp. PCC6803.

Author

Minagawa, Jun and Dann, Marcel

Subjects

SYNECHOCYSTIS, CARBONIC anhydrase, BICARBONATE ions, CYANOBACTERIA, ENZYMES

Abstract

Cyanobacteria mostly rely on the active uptake of hydrated CO2 (i.e., bicarbonate ions) from the surrounding media to fuel their inorganic carbon assimilation. The dehydration of bicarbonate in close vicinity of RuBisCO is achieved through the activity of carboxysomal carbonic anhydrase (CA) enzymes. Simultaneously, many cyanobacterial genomes encode extracellular α- and β-class CAs (EcaA, EcaB) whose exact physiological role remains largely unknown. To date, the CahB1 enzyme of Sodalinema gerasimenkoae (formerly Microcoleus/Coleofasciculus chthonoplastes) remains the sole described active extracellular β-CA in cyanobacteria, but its molecular features strongly suggest it to be a carboxysomal rather than a secreted protein. Upon expression of CahB1 in Synechocystis sp. PCC6803, we found that its expression complemented the loss of endogenous CcaA. Moreover, CahB1 was found to localize to a carboxysome-harboring and CA-active cell fraction. Our data suggest that CahB1 retains all crucial properties of a cellular carboxysomal CA and that the secretion mechanism and/or the machinations of the Sodalinema gerasimenkoae carboxysome are different from those of Synechocystis. [ABSTRACT FROM AUTHOR]

Published

2023

20. The stickers and spacers of Rubiscondensation: assembling the centrepiece of biophysical CO2-concentrating mechanisms.

Author

Ang, Warren Shou Leong, How, Jian Ann, How, Jian Boon, and Mueller-Cajar, Oliver

Subjects

*PHASE separation, *BINDING sites, *SCAFFOLD proteins, *STICKERS, *PROKARYOTES, *OXYGENASES

Abstract

Aquatic autotrophs that fix carbon using ribulose 1,5-bisphosphate carboxylase/oxygenase (Rubisco) frequently expend metabolic energy to pump inorganic carbon towards the enzyme's active site. A central requirement of this strategy is the formation of highly concentrated Rubisco condensates (or Rubiscondensates) known as carboxysomes and pyrenoids, which have convergently evolved multiple times in prokaryotes and eukaryotes, respectively. Recent data indicate that these condensates form by the mechanism of liquid–liquid phase separation. This mechanism requires networks of weak multivalent interactions typically mediated by intrinsically disordered scaffold proteins. Here we comparatively review recent rapid developments that detail the determinants and precise interactions that underlie diverse Rubisco condensates. The burgeoning field of biomolecular condensates has few examples where liquid–liquid phase separation can be linked to clear phenotypic outcomes. When present, Rubisco condensates are essential for photosynthesis and growth, and they are thus emerging as powerful and tractable models to investigate the structure–function relationship of phase separation in biology. [ABSTRACT FROM AUTHOR]

Published

2023

21. Regulation of the high-specificity Rubisco genes by the third CbbR-type regulator in a hydrogen-oxidizing bacterium Hydrogenovibriomarinus.

Author

Toyoda, Koichi, Yoshizawa, Yoichi, Ishii, Masaharu, and Arai, Hiroyuki

Subjects

*REGULATOR genes, *CARBON dioxide, *GENES, *PROMOTERS (Genetics), *RECOMBINANT proteins

Abstract

The obligate chemolithoautotrophic bacterium, Hydrogenovibrio marinus MH-110, has three ribulose-1,5-bisphosphate carboxylase/oxygenase (Rubisco) isoenzymes, CbbM, CbbLS-1, and CbbLS-2, which differ in CO 2 /O 2 specificity factor values. Expressions of CbbM and CbbLS-1 are regulated differently by transcriptional regulators of the LysR family, CbbRm and CbbR1, respectively. CbbLS-2 has the highest specificity and is induced under low CO 2 conditions, but the regulator for the cbbL2S2 genes encoding CbbLS-2 remains unidentified. In this study, the cbbR2 gene encoding the third CbbR-type regulator was identified in the downstream region of the cbbL2S2 and carboxysome gene cluster via transposon mutagenesis. CO 2 depletion induced the cbbR2 gene. The cbbR2 knockout mutant could not grow under low CO 2 conditions and did not produce CbbLS-2. Recombinant CbbR2 protein was bound to the promoter region of the cbbL2S2 genes. These results indicate that CbbR2 is the specific regulator for CbbLS-2 expression. [ABSTRACT FROM AUTHOR]

Published

2022

22. Chromatic Acclimation in Cyanobacteria: Photomorphogenesis in Response to Light Quality

Author

Maurya, Pankaj K., Kumar, Vinod, Mondal, Soumila, Singh, Shailendra P., and Rastogi, Rajesh Prasad, editor

Published

2021

23. Rubisco packaging and stoichiometric composition of the native β-carboxysome in Synechococcus elongatus PCC7942.

Author

Sun Y, Sheng Y, Ni T, Ge X, Sarsby J, Brownridge PJ, Li K, Hardenbrook N, Dykes GF, Rockliffe N, Eyers CE, Zhang P, and Liu LN

Abstract

Carboxysomes are anabolic bacterial microcompartments that play an essential role in CO2 fixation in cyanobacteria. This self-assembling proteinaceous organelle uses a polyhedral shell constructed by hundreds of shell protein paralogs to encapsulate the key CO2-fixing enzymes Rubisco and carbonic anhydrase. Deciphering the precise arrangement and structural organization of Rubisco enzymes within carboxysomes is crucial for understanding carboxysome formation and overall functionality. Here, we employed cryo-electron tomography and subtomogram averaging to delineate the three-dimensional packaging of Rubiscos within β-carboxysomes in the freshwater cyanobacterium Synechococcus elongatus PCC7942 grown under low light. Our results revealed that Rubiscos are arranged in multiple concentric layers parallel to the shell within the β-carboxysome lumen. We also detected Rubisco binding with the scaffolding protein CcmM in β-carboxysomes, which is instrumental for Rubisco encapsulation and β-carboxysome assembly. Using Quantification conCATamer (QconCAT)-based quantitative mass spectrometry, we determined the absolute stoichiometric composition of the entire β-carboxysome. This study provides insights into the assembly principles and structural variation of β-carboxysomes, which will aid in the rational design and repurposing of carboxysome nanostructures for diverse bioengineering applications., (© The Author(s) 2024. Published by Oxford University Press on behalf of American Society of Plant Biologists.)

Published

2024

24. Engineering CO 2 -fixing modules in E. coli via efficient assembly of cyanobacterial Rubisco and carboxysomes.

Author

Sun Y, Chen T, Ge X, Ni T, Dykes GF, Zhang P, Huang F, and Liu LN

Abstract

Rubisco (ribulose 1,5-bisphosphate carboxylase/oxygenase) is the central enzyme for converting atmospheric CO 2 into organic molecules, playing a crucial role in the global carbon cycle. In cyanobacteria and some chemoautotrophs, Rubisco complexes, along with carbonic anhydrase, are enclosed within specific proteinaceous microcompartments, known as carboxysomes. The polyhedral carboxysome shell ensures a dense packaging of Rubisco and creates a high-CO 2 internal environment to facilitate the fixation of CO 2 . Rubisco and carboxysomes have been popular targets for bioengineering, with the intent of enhancing plant photosynthesis, crop yields, and biofuel production. However, efficient generation of Form 1B Rubisco and cyanobacterial β-carboxysomes in heterologous systems remains challenging. Here, we developed genetic systems to efficiently engineer functional cyanobacterial Form 1B Rubisco in E. coli, by incorporating Rubisco assembly factor Raf1 and modulating the RbcL/S stoichiometry. We further accomplished effective reconstitution of catalytically active β-carboxysomes in E. coli with cognate Form 1B Rubisco by fine-tuning the expression levels of individual β-carboxysome components. In addition, we investigated the encapsulation mechanism of Rubisco into carboxysomes via constructing hybrid carboxysomes; this was achieved by creating a chimeric encapsulation peptide incorporating SSLDs that permits the encapsulation of Form 1B Rubisco into α-carboxysome shells. Our study provides insights into the assembly mechanisms of plant-like Form 1B Rubisco and its encapsulation principles in both β-carboxysomes and hybrid carboxysomes, and highlights the inherent modularity of carboxysome structures. The findings lay the framework for rational design and repurposing of CO 2 -fixing modules in bioengineering applications, e.g. crop engineering, biocatalyst production, and molecule delivery., (Copyright © 2024. Published by Elsevier Inc.)

Published

2024

25. Molecular Design Principles of Bacterial Carbon Fixation: Investigations into Carboxysome Assembly and Permeability

Author

Turnsek, Julia Borden

Subjects

Biochemistry, Microbiology, Molecular biology, carbon fixation, carboxysome, microcompartment, phase separation

Abstract

All life on Earth relies on biological carbon fixation, the process by which organisms convert inorganic carbon, primarily in the form of carbon dioxide (CO2), into longer chain compounds to fuel cellular processes. To enhance the efficiency of CO2 fixation, certain types of bacteria, specifically cyanobacteria and some proteobacteria, evolved specialized proteinaceous microcompartments called carboxysomes. Carboxysomes encapsulate the enzymes carbonic anhydrase and Rubisco inside a polyhedral layer of shell proteins. This molecular architecture serves to concentrate CO2 around Rubisco, allowing it to operate at its maximum catalytic rate.Correct carboxysome assembly is essential to the survival of the organism in CO2 concentrations found in today’s atmosphere (~0.04%). In the ⍺-carboxysome lineage, the disordered scaffold protein CsoS2 links Rubisco and shell proteins, and is absolutely required for carboxysome formation and cell growth at ambient CO2 levels. This work examines how the sequence of CsoS2 scales from a disordered amino acid chain to directing the ordered self-assembly of thousands of proteins. It investigates how cells utilize specific chemistries, such as redox reactions, to assist in this assembly pathway. The result of this molecular design and coordinated construction is to build a carboxysome with a precise permeability, yet this permeability has never been measured. Results presented here address these fundamental questions.I interrogated highly conserved and repetitive residues in CsoS2 to determine their role in carboxysome assembly. Through in vivo mutagenesis and in vitro biochemical assays I discovered that the residues VTG and Y are necessary for carboxysome assembly, and bind weakly yet multivalently to shell proteins. Conserved cysteine doublets, which hinted at a role for redox in assembly, showed no effect when mutated in vivo, but displayed biochemical phenotypes in vitro. In a major step towards reconstituting carboxysomes in vitro, I demonstrated formation of carboxysome-like phase-separated condensates with Rubisco, CsoS2, and shell, thereby showing that key carboxysome proteins can self-associate in a cell-free environment.Once assembled correctly, the carboxysome establishes a permeability barrier and selectivity filter, allowing entry of essential metabolites such as ribulose bisphosphate and bicarbonate while restricting leakage of CO2. To measure carboxysome permeability, we developed two parallel methods, one based on a bulk plate assay and one on single-particle microscopy. Both methods utilized the redox sensitive reporter protein roGFP to simultaneously measure both the permeability of reducing agents and the internal carboxysome redox environment. Data from both approaches revealed that purified carboxysomes were permeable to the reducing agent TCEP, which reduced encapsulated roGFP over time.Carboxysomes are the bacterial domain’s solution to the problem of capturing dilute CO2 from air and water, concentrating it, and converting it into sugars. Carboxysome functionality depends on the robust self-assembly of thousands of proteins, establishment of a specific internal chemical environment, and control over metabolite permeability. Insights from this work augment our understanding of these processes, and will aid future efforts to engineer carboxysomes into alternative organisms or cell-free systems for enhanced biological carbon capture.

Published

2023

26. Self-Assembly, Organisation, Regulation, and Engineering of Carboxysomes: CO2-Fixing Prokaryotic Organelles

Author

Sun, Yaqi, Huang, Fang, Liu, Lu-Ning, and Wang, Qiang, editor

Published

2020

27. Advances in the bacterial organelles for CO2 fixation.

Author

Liu, Lu-Ning

Subjects

*SYNTHETIC biology, *ORGANELLES, *CARBON dioxide, *CARBONIC anhydrase, *ENGINEERING design, *PROTEIN engineering

Abstract

Carboxysomes are a family of bacterial microcompartments (BMCs), present in all cyanobacteria and some proteobacteria, which encapsulate the primary CO 2 -fixing enzyme, Rubisco, within a virus-like polyhedral protein shell. Carboxysomes provide significantly elevated levels of CO 2 around Rubisco to maximize carboxylation and reduce wasteful photorespiration, thus functioning as the central CO 2 -fixation organelles of bacterial CO 2 -concentration mechanisms. Their intriguing architectural features allow carboxysomes to make a vast contribution to carbon assimilation on a global scale. In this review, we discuss recent research progress that provides new insights into the mechanisms of how carboxysomes are assembled and functionally maintained in bacteria and recent advances in synthetic biology to repurpose the metabolic module in diverse applications. CO 2 -concentrating mechanisms (CCMs) provide a means for accumulating CO 2 around Rubisco to overcome the inherent limitations of Rubisco and enhance CO 2 fixation. Carboxysomes are proteinaceous organelles in cyanobacteria and some proteobacteria which serve as the central CO 2 -fixing factory of CCMs. Carboxysomes sequester the cellular Rubisco and carbonic anhydrase from the cytoplasm, using a selectively permeable shell that structurally resembles virus capsids. Great efforts have been made recently to advance our understanding of the molecular mechanisms underlying carboxysome structure, assembly, biogenesis, and physiology. Advances in fundamental knowledge about carboxysome assembly and function has stimulated rational design and engineering of the protein organelles for improving CO 2 fixation and new functions. [ABSTRACT FROM AUTHOR]

Published

2022

28. Atypical Carboxysome Loci: JEEPs or Junk?

Author

Sutter, Markus, Kerfeld, Cheryl A., and Scott, Kathleen M.

Subjects

LOCUS (Genetics), CARBONIC anhydrase, BIOLOGICAL transport, CARBON dioxide fixation, OPERONS, NUCLEOTIDE sequencing, OXYGENASES

Abstract

Carboxysomes, responsible for a substantial fraction of CO2 fixation on Earth, are proteinaceous microcompartments found in many autotrophic members of domain Bacteria , primarily from the phyla Proteobacteria and Cyanobacteria. Carboxysomes facilitate CO2 fixation by the Calvin-Benson-Bassham (CBB) cycle, particularly under conditions where the CO2 concentration is variable or low, or O2 is abundant. These microcompartments are composed of an icosahedral shell containing the enzymes ribulose 1,5-carboxylase/oxygenase (RubisCO) and carbonic anhydrase. They function as part of a CO2 concentrating mechanism, in which cells accumulate HCO3− in the cytoplasm via active transport, HCO3− enters the carboxysomes through pores in the carboxysomal shell proteins, and carboxysomal carbonic anhydrase facilitates the conversion of HCO3− to CO2, which RubisCO fixes. Two forms of carboxysomes have been described: α-carboxysomes and β-carboxysomes, which arose independently from ancestral microcompartments. The α-carboxysomes present in Proteobacteria and some Cyanobacteria have shells comprised of four types of proteins [CsoS1 hexamers, CsoS4 pentamers, CsoS2 assembly proteins, and α-carboxysomal carbonic anhydrase (CsoSCA)], and contain form IA RubisCO (CbbL and CbbS). In the majority of cases, these components are encoded in the genome near each other in a gene locus, and transcribed together as an operon. Interestingly, genome sequencing has revealed some α-carboxysome loci that are missing genes encoding one or more of these components. Some loci lack the genes encoding RubisCO, others lack a gene encoding carbonic anhydrase, some loci are missing shell protein genes, and in some organisms, genes homologous to those encoding the carboxysome-associated carbonic anhydrase are the only carboxysome-related genes present in the genome. Given that RubisCO, assembly factors, carbonic anhydrase, and shell proteins are all essential for carboxysome function, these absences are quite intriguing. In this review, we provide an overview of the most recent studies of the structural components of carboxysomes, describe the genomic context and taxonomic distribution of atypical carboxysome loci, and propose functions for these variants. We suggest that these atypical loci are JEEPs, which have modified functions based on the presence of Just Enough Essential Parts. [ABSTRACT FROM AUTHOR]

Published

2022

29. Atypical Carboxysome Loci: JEEPs or Junk?

Author

USF Genomics Class, Markus Sutter, Cheryl A. Kerfeld, and Kathleen M. Scott

Subjects

carboxysome, microcompartment, carbonic anhydrase, carbon dioxide fixation, autotroph, Microbiology, QR1-502

Abstract

Carboxysomes, responsible for a substantial fraction of CO2 fixation on Earth, are proteinaceous microcompartments found in many autotrophic members of domain Bacteria, primarily from the phyla Proteobacteria and Cyanobacteria. Carboxysomes facilitate CO2 fixation by the Calvin-Benson-Bassham (CBB) cycle, particularly under conditions where the CO2 concentration is variable or low, or O2 is abundant. These microcompartments are composed of an icosahedral shell containing the enzymes ribulose 1,5-carboxylase/oxygenase (RubisCO) and carbonic anhydrase. They function as part of a CO2 concentrating mechanism, in which cells accumulate HCO3− in the cytoplasm via active transport, HCO3− enters the carboxysomes through pores in the carboxysomal shell proteins, and carboxysomal carbonic anhydrase facilitates the conversion of HCO3− to CO2, which RubisCO fixes. Two forms of carboxysomes have been described: α-carboxysomes and β-carboxysomes, which arose independently from ancestral microcompartments. The α-carboxysomes present in Proteobacteria and some Cyanobacteria have shells comprised of four types of proteins [CsoS1 hexamers, CsoS4 pentamers, CsoS2 assembly proteins, and α-carboxysomal carbonic anhydrase (CsoSCA)], and contain form IA RubisCO (CbbL and CbbS). In the majority of cases, these components are encoded in the genome near each other in a gene locus, and transcribed together as an operon. Interestingly, genome sequencing has revealed some α-carboxysome loci that are missing genes encoding one or more of these components. Some loci lack the genes encoding RubisCO, others lack a gene encoding carbonic anhydrase, some loci are missing shell protein genes, and in some organisms, genes homologous to those encoding the carboxysome-associated carbonic anhydrase are the only carboxysome-related genes present in the genome. Given that RubisCO, assembly factors, carbonic anhydrase, and shell proteins are all essential for carboxysome function, these absences are quite intriguing. In this review, we provide an overview of the most recent studies of the structural components of carboxysomes, describe the genomic context and taxonomic distribution of atypical carboxysome loci, and propose functions for these variants. We suggest that these atypical loci are JEEPs, which have modified functions based on the presence of Just Enough Essential Parts.

Published

2022

30. Permanent draft genome of Thiobacillus thioparus DSM 505T, an obligately chemolithoautotrophic member of the Betaproteobacteria

Author

Boden, Rich [Univ. of Plymouth (United Kingdom). School of Biological and Marine Sciences and Sustainable Earth Inst.] (ORCID:000000024496152X)

Published

2017

31. Permanent draft genome of Thiobacillus thioparus DSM 505T, an obligately chemolithoautotrophic member of the Betaproteobacteria.

Author

Hutt, Lee P, Huntemann, Marcel, Clum, Alicia, Pillay, Manoj, Palaniappan, Krishnaveni, Varghese, Neha, Mikhailova, Natalia, Stamatis, Dimitrios, Reddy, Tatiparthi, Daum, Chris, Shapiro, Nicole, Ivanova, Natalia, Kyrpides, Nikos, Woyke, Tanja, and Boden, Rich

Subjects

Betaproteobacteria, Carboxysome, Chemolithoautotroph, Denitrification, Sulfur oxidation, Thiobacillus thioparus, Genetics, Biochemistry and Cell Biology

Abstract

Thiobacillus thioparus DSM 505T is one of first two isolated strains of inorganic sulfur-oxidising Bacteria. The original strain of T. thioparus was lost almost 100 years ago and the working type strain is Culture CT (=DSM 505T = ATCC 8158T) isolated by Starkey in 1934 from agricultural soil at Rutgers University, New Jersey, USA. It is an obligate chemolithoautotroph that conserves energy from the oxidation of reduced inorganic sulfur compounds using the Kelly-Trudinger pathway and uses it to fix carbon dioxide It is not capable of heterotrophic or mixotrophic growth. The strain has a genome size of 3,201,518 bp. Here we report the genome sequence, annotation and characteristics. The genome contains 3,135 protein coding and 62 RNA coding genes. Genes encoding the transaldolase variant of the Calvin-Benson-Bassham cycle were also identified and an operon encoding carboxysomes, along with Smith's biosynthetic horseshoe in lieu of Krebs' cycle sensu stricto. Terminal oxidases were identified, viz. cytochrome c oxidase (cbb3, EC 1.9.3.1) and ubiquinol oxidase (bd, EC 1.10.3.10). There is a partial sox operon of the Kelly-Friedrich pathway of inorganic sulfur-oxidation that contains soxXYZAB genes but lacking soxCDEF, there is also a lack of the DUF302 gene previously noted in the sox operon of other members of the 'Proteobacteria' that can use trithionate as an energy source. In spite of apparently not growing anaerobically with denitrification, the nar, nir, nor and nos operons encoding enzymes of denitrification are found in the T. thioparus genome, in the same arrangements as in the true denitrifier T. denitrificans.

Published

2017

32. A PII-Like Protein Regulated by Bicarbonate: Structural and Biochemical Studies of the Carboxysome-Associated CPII Protein.

Author

Wheatley, Nicole, Eden, Kevin, Ngo, Joanna, Rosinski, Justin, Sawaya, Michael, Cascio, Duilio, Collazo, Michael, Hoveida, Hamidreza, Hubbell, Wayne, and Yeates, Todd

Subjects

allostery, bicarbonate, carbon concentrating mechanism, carboxysome, nitrogen regulatory PII proteins, Adenosine Diphosphate, Bacterial Proteins, Betaproteobacteria, Bicarbonates, Crystallography, X-Ray, Models, Molecular, Protein Binding, Protein Conformation

Abstract

Autotrophic bacteria rely on various mechanisms to increase intracellular concentrations of inorganic forms of carbon (i.e., bicarbonate and CO2) in order to improve the efficiency with which they can be converted to organic forms. Transmembrane bicarbonate transporters and carboxysomes play key roles in accumulating bicarbonate and CO2, but other regulatory elements of carbon concentration mechanisms in bacteria are less understood. In this study, after analyzing the genomic regions around α-type carboxysome operons, we characterize a protein that is conserved across these operons but has not been previously studied. On the basis of a series of apo- and ligand-bound crystal structures and supporting biochemical data, we show that this protein, which we refer to as the carboxysome-associated PII protein (CPII), represents a new and distinct subfamily within the broad superfamily of previously studied PII regulatory proteins, which are generally involved in regulating nitrogen metabolism in bacteria. CPII undergoes dramatic conformational changes in response to ADP binding, and the affinity for nucleotide binding is strongly enhanced by the presence of bicarbonate. CPII therefore appears to be a unique type of PII protein that senses bicarbonate availability, consistent with its apparent genomic association with the carboxysome and its constituents.

Published

2016

33. Theoretical Study of the Initial Stages of Self-Assembly of a Carboxysome’s Facet

Author

Fuentes-Cabrera, Miguel [Oak Ridge National Lab. (ORNL), Oak Ridge, TN (United States). Center for Nanophase Materials Science and Computer Science and Mathematics Division]

Published

2016

34. Decoding the Absolute Stoichiometric Composition and Structural Plasticity of α-Carboxysomes

Author

Yaqi Sun, Victoria M. Harman, James R. Johnson, Philip J. Brownridge, Taiyu Chen, Gregory F. Dykes, Yongjun Lin, Robert J. Beynon, and Lu-Ning Liu

Subjects

CO2-concentrating mechanisms, absolute quantification, bacterial microcompartment, carbon fixation, carboxysome, mass spectrometry, Microbiology, QR1-502

Abstract

ABSTRACT Carboxysomes are anabolic bacterial microcompartments that play an essential role in carbon fixation in cyanobacteria and some chemoautotrophs. This self-assembling organelle encapsulates the key CO2-fixing enzymes, Rubisco, and carbonic anhydrase using a polyhedral protein shell that is constructed by hundreds of shell protein paralogs. The α-carboxysome from the chemoautotroph Halothiobacillus neapolitanus serves as a model system in fundamental studies and synthetic engineering of carboxysomes. In this study, we adopted a QconCAT-based quantitative mass spectrometry approach to determine the stoichiometric composition of native α-carboxysomes from H. neapolitanus. We further performed an in-depth comparison of the protein stoichiometry of native α-carboxysomes and their recombinant counterparts heterologously generated in Escherichia coli to evaluate the structural variability and remodeling of α-carboxysomes. Our results provide insight into the molecular principles that mediate carboxysome assembly, which may aid in rational design and reprogramming of carboxysomes in new contexts for biotechnological applications. IMPORTANCE A wide range of bacteria use special protein-based organelles, termed bacterial microcompartments, to encase enzymes and reactions to increase the efficiency of biological processes. As a model bacterial microcompartment, the carboxysome contains a protein shell filled with the primary carbon fixation enzyme Rubisco. The self-assembling organelle is generated by hundreds of proteins and plays important roles in converting carbon dioxide to sugar, a process known as carbon fixation. In this study, we uncovered the exact stoichiometry of all building components and the structural plasticity of the functional α-carboxysome, using newly developed quantitative mass spectrometry together with biochemistry, electron microscopy, and enzymatic assay. The study advances our understanding of the architecture and modularity of natural carboxysomes. The knowledge learned from natural carboxysomes will suggest feasible ways to produce functional carboxysomes in other hosts, such as crop plants, with the overwhelming goal of boosting cell metabolism and crop yields.

Published

2022

35. Uncovering the roles of the scaffolding protein CsoS2 in mediating the assembly and shape of the α-carboxysome shell.

Author

Li T, Chen T, Chang P, Ge X, Chriscoli V, Dykes GF, Wang Q, and Liu L-N

Subjects

Bacterial Proteins metabolism, Bacterial Proteins genetics, Bacterial Proteins chemistry, Carbonic Anhydrases metabolism, Carbonic Anhydrases genetics, Carbonic Anhydrases chemistry, Halothiobacillus chemistry, Halothiobacillus cytology, Halothiobacillus genetics, Halothiobacillus metabolism, Organelles metabolism, Ribulose-Bisphosphate Carboxylase metabolism, Ribulose-Bisphosphate Carboxylase chemistry, Ribulose-Bisphosphate Carboxylase genetics

Abstract

Carboxysomes are proteinaceous organelles featuring icosahedral protein shells that enclose the carbon-fixing enzymes, ribulose-1,5-bisphosphate carboxylase oxygenase (Rubisco), along with carbonic anhydrase. The intrinsically disordered scaffolding protein CsoS2 plays a vital role in the construction of α-carboxysomes through bridging the shell and cargo enzymes. The N-terminal domain of CsoS2 binds Rubisco and facilitates Rubisco packaging within the α-carboxysome, whereas the C-terminal domain of CsoS2 (CsoS2-C) anchors to the shell and promotes shell assembly. However, the role of the middle region of CsoS2 (CsoS2-M) has remained elusive. Here, we conducted in-depth examinations on the function of CsoS2-M in the assembly of the α-carboxysome shell by generating a series of recombinant shell variants in the absence of cargos. Our results reveal that CsoS2-M assists CsoS2-C in the assembly of the α-carboxysome shell and plays an important role in shaping the α-carboxysome shell through enhancing the association of shell proteins on both the facet-facet interfaces and flat shell facets. Moreover, CsoS2-M is responsible for recruiting the C-terminal truncated isoform of CsoS2, CsoS2A, into α-carboxysomes, which is crucial for Rubisco encapsulation and packaging. This study not only deepens our knowledge of how the carboxysome shell is constructed and regulated but also lays the groundwork for engineering and repurposing carboxysome-based nanostructures for diverse biotechnological purposes., Importance: Carboxysomes are a paradigm of organelle-like structures in cyanobacteria and many proteobacteria. These nanoscale compartments enclose Rubisco and carbonic anhydrase within an icosahedral virus-like shell to improve CO 2 fixation, playing a vital role in the global carbon cycle. Understanding how the carboxysomes are formed is not only important for basic research studies but also holds promise for repurposing carboxysomes in bioengineering applications. In this study, we focuses on a specific scaffolding protein called CsoS2, which is involved in facilitating the assembly of α-type carboxysomes. By deciphering the functions of different parts of CsoS2, especially its middle region, we provide new insights into how CsoS2 drives the stepwise assembly of the carboxysome at the molecular level. This knowledge will guide the rational design and reprogramming of carboxysome nanostructures for many biotechnological applications., Competing Interests: The authors declare no conflict of interest.

Published

2024

36. Rubisco packaging and stoichiometric composition of a native β-carboxysome.

Author

Sun Y, Sheng Y, Ni T, Ge X, Sarsby J, Brownridge PJ, Li K, Hardenbrook N, Dykes GF, Rockliffe N, Eyers CE, Zhang P, and Liu LN

Abstract

Carboxysomes are anabolic bacterial microcompartments that play an essential role in carbon fixation in cyanobacteria. This self-assembling proteinaceous organelle encapsulates the key CO 2 -fixing enzymes, Rubisco and carbonic anhydrase, using a polyhedral shell constructed by hundreds of shell protein paralogs. Deciphering the precise arrangement and structural organization of Rubisco enzymes within carboxysomes is crucial for understanding the formation process and overall functionality of carboxysomes. Here, we employed cryo-electron tomography and subtomogram averaging to delineate the three-dimensional packaging of Rubiscos within β-carboxysomes in the freshwater cyanobacterium Synechococcus elongatus PCC7942 that were grown under low light. Our results revealed that Rubiscos are arranged in multiple concentric layers parallel to the shell within the β-carboxysome lumen. We also identified the binding of Rubisco with the scaffolding protein CcmM in β-carboxysomes, which is instrumental for Rubisco encapsulation and β-carboxysome assembly. Using QconCAT-based quantitative mass spectrometry, we further determined the absolute stoichiometric composition of the entire β-carboxysome. This study and recent findings on the β-carboxysome structure provide insights into the assembly principles and structural variation of β-carboxysomes, which will aid in the rational design and repurposing of carboxysome nanostructures for diverse bioengineering applications., Competing Interests: Competing Interests The authors declare no conflict of interest.

Published

2024

37. Conserved and repetitive motifs in an intrinsically disordered protein drive ⍺-carboxysome assembly.

Author

Turnšek JB, Oltrogge LM, and Savage DF

Subjects

Carbonic Anhydrases metabolism, Carbonic Anhydrases chemistry, Carbonic Anhydrases genetics, Carbon Dioxide metabolism, Carbon Dioxide chemistry, Amino Acid Motifs, Carbon Cycle, Organelles metabolism, Intrinsically Disordered Proteins metabolism, Intrinsically Disordered Proteins chemistry, Intrinsically Disordered Proteins genetics, Ribulose-Bisphosphate Carboxylase metabolism, Ribulose-Bisphosphate Carboxylase chemistry, Ribulose-Bisphosphate Carboxylase genetics, Bacterial Proteins metabolism, Bacterial Proteins chemistry, Bacterial Proteins genetics

Abstract

All cyanobacteria and some chemoautotrophic bacteria fix CO 2 into sugars using specialized proteinaceous compartments called carboxysomes. Carboxysomes enclose the enzymes Rubisco and carbonic anhydrase inside a layer of shell proteins to increase the CO 2 concentration for efficient carbon fixation by Rubisco. In the ⍺-carboxysome lineage, a disordered and highly repetitive protein named CsoS2 is essential for carboxysome formation and function. Without it, the bacteria require high CO 2 to grow. How does a protein predicted to be lacking structure serve as the architectural scaffold for such a vital cellular compartment? In this study, we identify key residues present in the repeats of CsoS2, VTG and Y, which are necessary for building functional ⍺-carboxysomes in vivo. These highly conserved and repetitive residues contribute to the multivalent binding interaction and phase separation behavior between CsoS2 and shell proteins. We also demonstrate 3-component reconstitution of CsoS2, Rubisco, and shell proteins into spherical condensates and show the utility of reconstitution as a biochemical tool to study carboxysome biogenesis. The precise self-assembly of thousands of proteins is crucial for carboxysome formation, and understanding this process could enable their use in alternative biological hosts or industrial processes as effective tools to fix carbon., Competing Interests: Conflict of interest D. F. S. is a co-founder and scientific advisory board member of Scribe Therapeutics. All other authors declare that thye have no conflicts of interests with the contents of this article., (Copyright © 2024 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2024

38. Corrigendum: Atypical carboxysome loci: JEEPs or junk?

Subjects

SPAM email, CARBON dioxide fixation

Abstract

This document is a corrigendum for an article titled "Atypical carboxysome loci: JEEPs or junk?" published in Frontiers in Microbiology. The corrigendum addresses an error in the acknowledgments section of the original article, where the names of the students who contributed to the manuscript were incorrectly listed. The corrected names of the students are provided in the corrigendum. The authors apologize for the error and state that it does not affect the scientific conclusions of the article. [Extracted from the article]

Published

2024

39. Selective molecular transport through the protein shell of a bacterial microcompartment organelle

Author

Bobik, Thomas [Iowa State Univ., Ames, IA (United States). Roy J. Carver Dept. of Biochemistry, Biophysics, and Molecular Biology]

Published

2015

40. Extracellular CahB1 from Sodalinema gerasimenkoae IPPAS B-353 Acts as a Functional Carboxysomal β-Carbonic Anhydrase in Synechocystis sp. PCC6803

Author

Jun Minagawa and Marcel Dann

Subjects

cyanobacteria, carbonic anhydrase, carboxysome, Synechocystis, Microcoleus chthonoplastes, Coleofasciculus chthonoplastes, Botany, QK1-989

Abstract

Cyanobacteria mostly rely on the active uptake of hydrated CO2 (i.e., bicarbonate ions) from the surrounding media to fuel their inorganic carbon assimilation. The dehydration of bicarbonate in close vicinity of RuBisCO is achieved through the activity of carboxysomal carbonic anhydrase (CA) enzymes. Simultaneously, many cyanobacterial genomes encode extracellular α- and β-class CAs (EcaA, EcaB) whose exact physiological role remains largely unknown. To date, the CahB1 enzyme of Sodalinema gerasimenkoae (formerly Microcoleus/Coleofasciculus chthonoplastes) remains the sole described active extracellular β-CA in cyanobacteria, but its molecular features strongly suggest it to be a carboxysomal rather than a secreted protein. Upon expression of CahB1 in Synechocystis sp. PCC6803, we found that its expression complemented the loss of endogenous CcaA. Moreover, CahB1 was found to localize to a carboxysome-harboring and CA-active cell fraction. Our data suggest that CahB1 retains all crucial properties of a cellular carboxysomal CA and that the secretion mechanism and/or the machinations of the Sodalinema gerasimenkoae carboxysome are different from those of Synechocystis.

Published

2023

41. Carboxysome Mispositioning Alters Growth, Morphology, and Rubisco Level of the Cyanobacterium Synechococcus elongatus PCC 7942

Author

Rees Rillema, Y Hoang, Joshua S. MacCready, and Anthony G. Vecchiarelli

Subjects

Rubisco, carbon dioxide assimilation, carbon dioxide concentration mechanism, carbon dioxide fixation, carboxysome, cell division, Microbiology, QR1-502

Abstract

ABSTRACT Cyanobacteria are the prokaryotic group of phytoplankton responsible for a significant fraction of global CO2 fixation. Like plants, cyanobacteria use the enzyme ribulose 1,5-bisphosphate carboxylase/oxidase (Rubisco) to fix CO2 into organic carbon molecules via the Calvin-Benson-Bassham cycle. Unlike plants, cyanobacteria evolved a carbon-concentrating organelle called the carboxysome—a proteinaceous compartment that encapsulates and concentrates Rubisco along with its CO2 substrate. In the rod-shaped cyanobacterium Synechococcus elongatus PCC 7942, we recently identified the McdAB system responsible for uniformly distributing carboxysomes along the cell length. It remains unknown what role carboxysome positioning plays with respect to cellular physiology. Here, we show that a failure to distribute carboxysomes leads to slower cell growth, cell elongation, asymmetric cell division, and elevated levels of cellular Rubisco. Unexpectedly, we also report that even wild-type S. elongatus undergoes cell elongation and asymmetric cell division when grown at the cool, but environmentally relevant, growth temperature of 20°C or when switched from a high- to ambient-CO2 environment. The findings suggest that carboxysome positioning by the McdAB system functions to maintain the carbon fixation efficiency of Rubisco by preventing carboxysome aggregation, which is particularly important under growth conditions where rod-shaped cyanobacteria adopt a filamentous morphology. IMPORTANCE Photosynthetic cyanobacteria are responsible for almost half of global CO2 fixation. Due to eutrophication, rising temperatures, and increasing atmospheric CO2 concentrations, cyanobacteria have gained notoriety for their ability to form massive blooms in both freshwater and marine ecosystems across the globe. Like plants, cyanobacteria use the most abundant enzyme on Earth, Rubisco, to provide the sole source of organic carbon required for its photosynthetic growth. Unlike plants, cyanobacteria have evolved a carbon-concentrating organelle called the carboxysome that encapsulates and concentrates Rubisco with its CO2 substrate to significantly increase carbon fixation efficiency and cell growth. We recently identified the positioning system that distributes carboxysomes in cyanobacteria. However, the physiological consequence of carboxysome mispositioning in the absence of this distribution system remains unknown. Here, we find that carboxysome mispositioning triggers changes in cell growth and morphology as well as elevated levels of cellular Rubisco.

Published

2021

42. Advances in the World of Bacterial Microcompartments.

Author

Stewart, Andrew M., Stewart, Katie L., Yeates, Todd O., and Bobik, Thomas A.

Subjects

*RECOMBINANT proteins, *CELL compartmentation, *BIOLOGICAL systems, *POTENTIAL functions, *BIOENGINEERING, *METABOLITES

Abstract

Bacterial microcompartments (MCPs) are extremely large (100–400 nm) and diverse proteinaceous organelles that compartmentalize multistep metabolic pathways, increasing their efficiency and sequestering toxic and/or volatile intermediates. This review highlights recent studies that have expanded our understanding of the diversity, structure, function, and potential biotechnological uses of MCPs. Several new types of MCPs have been identified and characterized revealing new functions and potential new associations with human disease. Recent structural studies of MCP proteins and recombinant MCP shells have provided new insights into MCP assembly and mechanisms and raised new questions about MCP structure. We also discuss recent work on biotechnology applications that use MCP principles to develop nanobioreactors, nanocontainers, and molecular scaffolds. Toxic and volatile metabolites present a problem to biological systems, which some bacteria overcome by producing bacterial microcompartments (MCPs) to sequester these molecules. Originally thought to be broadly categorized by two types, carbon-fixing or B 12 -dependent, recent studies have uncovered many new classes of MCPs, a number of which are associated with human disease. Recent structural studies of MCP proteins and higher order complexes have revealed many of the principles that underlie MCP assembly. As the structural and biochemical knowledge of MCPs has grown, MCP principles have driven new bioengineering applications. [ABSTRACT FROM AUTHOR]

Published

2021

43. Two new high-resolution crystal structures of carboxysome pentamer proteins reveal high structural conservation of CcmL orthologs among distantly related cyanobacterial species

Author

Sutter, Markus, Wilson, Steven C, Deutsch, Samuel, and Kerfeld, Cheryl A

Subjects

Biochemistry and Cell Biology, Ecology, Biological Sciences, Amino Acid Sequence, Bacterial Proteins, Conserved Sequence, Cyanobacteria, Molecular Conformation, Molecular Sequence Data, Static Electricity, Microcompartment, Carboxysome, CcmL, Genetics, Plant Biology, Plant Biology & Botany, Biochemistry and cell biology, Plant biology

Abstract

Cyanobacteria have evolved a unique carbon fixation organelle known as the carboxysome that compartmentalizes the enzymes RuBisCO and carbonic anhydrase. This effectively increases the local CO2 concentration at the active site of RuBisCO and decreases its relatively unproductive side reaction with oxygen. Carboxysomes consist of a protein shell composed of hexameric and pentameric proteins arranged in icosahedral symmetry. Facets composed of hexameric proteins are connected at the vertices by pentameric proteins. Structurally homologous pentamers and hexamers are also found in heterotrophic bacteria where they form architecturally related microcompartments such as the Eut and Pdu organelles for the metabolism of ethanolamine and propanediol, respectively. Here we describe two new high-resolution structures of the pentameric shell protein CcmL from the cyanobacteria Thermosynechococcus elongatus and Gloeobacter violaceus and provide detailed analysis of their characteristics and comparison with related shell proteins.

Published

2013

44. A carboxysome-based CO 2 concentrating mechanism for C 3 crop chloroplasts: advances and the road ahead.

Author

Nguyen ND, Pulsford SB, Förster B, Rottet S, Rourke L, Long BM, and Price GD

Subjects

Photosynthesis physiology, Cyanobacteria metabolism, Cyanobacteria physiology, Cyanobacteria genetics, Plants, Genetically Modified, Carbon Dioxide metabolism, Chloroplasts metabolism, Crops, Agricultural genetics, Crops, Agricultural metabolism, Ribulose-Bisphosphate Carboxylase metabolism, Ribulose-Bisphosphate Carboxylase genetics

Abstract

The introduction of the carboxysome-based CO 2 concentrating mechanism (CCM) into crop plants has been modelled to significantly increase crop yields. This projection serves as motivation for pursuing this strategy to contribute to global food security. The successful implementation of this engineering challenge is reliant upon the transfer of a microcompartment that encapsulates cyanobacterial Rubisco, known as the carboxysome, alongside active bicarbonate transporters. To date, significant progress has been achieved with respect to understanding various aspects of the cyanobacterial CCM, and more recently, different components of the carboxysome have been successfully introduced into plant chloroplasts. In this Perspective piece, we summarise recent findings and offer new research avenues that will accelerate research in this field to ultimately and successfully introduce the carboxysome into crop plants for increased crop yields., (© 2024 The Authors. The Plant Journal published by Society for Experimental Biology and John Wiley & Sons Ltd.)

Published

2024

45. Increasing the uptake of carbon dioxide

Author

Eric Franklin and Martin Jonikas

Subjects

carbon fixation, carbon-concentrating mechanism, photosynthesis, carboxysome, synthetic biology, genetic engineering, Medicine, Science, Biology (General), QH301-705.5

Abstract

A mechanism for concentrating carbon dioxide has for the first time been successfully transferred into a species that lacks such a process.

Published

2020

46. Functional reconstitution of a bacterial CO2 concentrating mechanism in Escherichia coli

Author

Avi I Flamholz, Eli Dugan, Cecilia Blikstad, Shmuel Gleizer, Roee Ben-Nissan, Shira Amram, Niv Antonovsky, Sumedha Ravishankar, Elad Noor, Arren Bar-Even, Ron Milo, and David F Savage

Subjects

co2 fixation, co2 concentrating mechanism, photosynthesis, carboxysome, synthetic biology, Medicine, Science, Biology (General), QH301-705.5

Abstract

Many photosynthetic organisms employ a CO2 concentrating mechanism (CCM) to increase the rate of CO2 fixation via the Calvin cycle. CCMs catalyze ≈50% of global photosynthesis, yet it remains unclear which genes and proteins are required to produce this complex adaptation. We describe the construction of a functional CCM in a non-native host, achieved by expressing genes from an autotrophic bacterium in an Escherichia coli strain engineered to depend on rubisco carboxylation for growth. Expression of 20 CCM genes enabled E. coli to grow by fixing CO2 from ambient air into biomass, with growth in ambient air depending on the components of the CCM. Bacterial CCMs are therefore genetically compact and readily transplanted, rationalizing their presence in diverse bacteria. Reconstitution enabled genetic experiments refining our understanding of the CCM, thereby laying the groundwork for deeper study and engineering of the cell biology supporting CO2 assimilation in diverse organisms.

Published

2020

47. Linking the Dynamic Response of the Carbon Dioxide-Concentrating Mechanism to Carbon Assimilation Behavior in Fremyella diplosiphon

Author

Brandon A. Rohnke, Kiara J. Rodríguez Pérez, and Beronda L. Montgomery

Subjects

carbon dioxide assimilation, carbon dioxide concentration mechanism, carbon dioxide fixation, carboxysome, cyanobacteria, gas exchange, Microbiology, QR1-502

Abstract

ABSTRACT Cyanobacteria use a carbon dioxide (CO2)-concentrating mechanism (CCM) that enhances their carbon fixation efficiency and is regulated by many environmental factors that impact photosynthesis, including carbon availability, light levels, and nutrient access. Efforts to connect the regulation of the CCM by these factors to functional effects on carbon assimilation rates have been complicated by the aqueous nature of cyanobacteria. Here, we describe the use of cyanobacteria in a semiwet state on glass fiber filtration discs—cyanobacterial discs—to establish dynamic carbon assimilation behavior using gas exchange analysis. In combination with quantitative PCR (qPCR) and transmission electron microscopy (TEM) analyses, we linked the regulation of CCM components to corresponding carbon assimilation behavior in the freshwater, filamentous cyanobacterium Fremyella diplosiphon. Inorganic carbon (Ci) levels, light quantity, and light quality have all been shown to influence carbon assimilation behavior in F. diplosiphon. Our results suggest a biphasic model of cyanobacterial carbon fixation. While behavior at low levels of CO2 is driven mainly by the Ci uptake ability of the cyanobacterium, at higher CO2 levels, carbon assimilation behavior is multifaceted and depends on Ci availability, carboxysome morphology, linear electron flow, and cell shape. Carbon response curves (CRCs) generated via gas exchange analysis enable rapid examination of CO2 assimilation behavior in cyanobacteria and can be used for cells grown under distinct conditions to provide insight into how CO2 assimilation correlates with the regulation of critical cellular functions, such as the environmental control of the CCM and downstream photosynthetic capacity. IMPORTANCE Environmental regulation of photosynthesis in cyanobacteria enhances organismal fitness, light capture, and associated carbon fixation under dynamic conditions. Concentration of carbon dioxide (CO2) near the carbon-fixing enzyme RubisCO occurs via the CO2-concentrating mechanism (CCM). The CCM is also tuned in response to carbon availability, light quality or levels, or nutrient access—cues that also impact photosynthesis. We adapted dynamic gas exchange methods generally used with plants to investigate environmental regulation of the CCM and carbon fixation capacity using glass fiber-filtered cells of the cyanobacterium Fremyella diplosiphon. We describe a breakthrough in measuring real-time carbon uptake and associated assimilation capacity for cells grown in distinct conditions (i.e., light quality, light quantity, or carbon status). These measurements demonstrate that the CCM modulates carbon uptake and assimilation under low-Ci conditions and that light-dependent regulation of pigmentation, cell shape, and downstream stages of carbon fixation are critical for tuning carbon uptake and assimilation.

Published

2020

48. Bacterial Microcompartments

Author

Kerfeld, Cheryl A.

Subjects

General and Miscellaneous, carboxysome, horizontal gene transfer, bacterial organelle, polyhedral bacterial inclusions

Abstract

Bacterialmicrocompartments (BMCs) are organelles composed entirely of protein. They promote specific metabolic processes by encapsulating and colocalizing enzymes with their substrates and cofactors, by protecting vulnerable enzymes in a defined microenvironment, and by sequestering toxic or volatile intermediates. Prototypes of the BMCsare the carboxysomes of autotrophic bacteria. However, structures of similar polyhedral shape are being discovered in an ever-increasing number of heterotrophic bacteria, where they participate in the utilization of specialty carbon and energy sources.Comparative genomics reveals that the potential for this type of compartmentalization is widespread across bacterial phyla and suggests that genetic modules encoding BMCs are frequently laterally transferred among bacteria. The diverse functions of these BMCs suggest that they contribute to metabolic innovation in bacteria in a broad range of environments.

Published

2010

49. The Carboxysome and Other Bacterial Microcompartments

Author

Kerfeld, Cheryl A.

Subjects

General and Miscellaneous, metabolic modules, microbiology, carboxysome, bacterial microcompartments

Abstract

- Carboxysomes are part of the carbon concentrating mechanism in cyanobacteria and chemoautotrophs. - Carboxysomes are a subclass of bacterial microcompartments (BMCs); BMCs can encapsulate a range of metabolic processes. - Like some viral particles, the carboxysome can be modeled as an icosahedron-in its case, having 4,000-5,000 hexameric shell subunits and 12 surface pentamers to generate curvature. - The threefold axis of symmetry of the CsoS1D protein in carboxysomes forms a pore that can open and close, allowing for selective diffusion. - Genetic modules encoding BMC shell proteins and the enzymes that they encapsulate are horizontally transferable, suggesting they enable bacteria to adapt to diverse environments.

Published

2010

50. Photosynthetic Carbon Metabolism and CO2-Concentrating Mechanism of Cyanobacteria

Author

Pronina, Natalia A., Kupriyanova, Elena V., Igamberdiev, Abir U., and Hallenbeck, Patrick C., editor

Published

2017