Carboxysome encapsulation of the CO2-fixing enzyme Rubisco in tobacco chloroplasts

Long, Benedict M.; Hee, Wei Yih; Sharwood, Robert E.; Rae, Benjamin D.; Kaines, Sarah; Lim, Yi-Leen; Nguyen, Nghiem D.; Massey, Baxter; Bala, Soumi; Caemmerer, Susanne von; Badger, Murray R.; Price, G. Dean

doi:10.1038/s41467-018-06044-0

Cited by 206 publications

(187 citation statements)

References 72 publications

(128 reference statements)

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“…Given the self-assembly of BMC structures, there is a significant interest in engineering BMCs and design of new BMC-based nanobioreactors, molecular scaffolds, and biomaterials in biotechnology applications, for example, enhancing cell metabolism, enzyme encapsulation, molecular delivery, and therapy. Advanced knowledge about the structural resilience and variability of BMCs in response to environmental changes will not only inform strategies for producing robust BMC-based nanostructures in heterologous hosts, i.e., E. coli or plants [31,53,54], but also pave the way for modulating the formation of 2D nanomaterials as well as the opening and closure of BMC shell-based protein cages, thereby facilitating the functional regulation and targeted molecular delivery. Previously, we have demonstrated the feasibility of using genetic modification approach to manipulate the specific contacts at the interfaces of shell proteins and their self-assembly behaviors [12].…”

Section: Discussionmentioning

confidence: 99%

Self-Assembly Stability and Variability of Bacterial Microcompartment Shell Proteins in Response to the Environmental Change

et al. 2019

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Bacterial microcompartments (BMCs) are proteinaceous self-assembling organelles that are widespread among the prokaryotic kingdom. By segmenting key metabolic enzymes and pathways using a polyhedral shell, BMCs play essential roles in carbon assimilation, pathogenesis, and microbial ecology. The BMC shell is composed of multiple protein homologs that self-assemble to form the defined architecture. There is tremendous interest in engineering BMCs to develop new nanobioreactors and molecular scaffolds. Here, we report the quantitative characterization of the formation and self-assembly dynamics of BMC shell proteins under varying pH and salt conditions using high-speed atomic force microscopy (HS-AFM). We show that 400-mM salt concentration is prone to result in larger single-layered shell patches formed by shell hexamers, and a higher dynamic rate of hexamer self-assembly was observed at neutral pH. We also visualize the variability of shell proteins from hexameric assemblies to fiber-like arrays. This study advances our knowledge about the stability and variability of BMC protein self-assemblies in response to microenvironmental changes, which will inform rational design and construction of synthetic BMC structures with the capacity of remodeling their self-assembly and structural robustness. It also offers a powerful toolbox for quantitatively assessing the self-assembly and formation of BMC-based nanostructures in biotechnology applications. Electronic supplementary material The online version of this article (10.1186/s11671-019-2884-3) contains supplementary material, which is available to authorized users.

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Section: Discussionmentioning

confidence: 99%

Self-Assembly Stability and Variability of Bacterial Microcompartment Shell Proteins in Response to the Environmental Change

et al. 2019

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“…Given these limitations, other carbon fixation cycles found in nature could be attractive ( Table 3). It is conceivable, given recent advances in compartmentalization in synthetic biology [115,116] that highly efficient pathways like the Wood-Ljungdahl pathway that require high CO2 concentrations could be implemented under atmospheric CO2 concentrations in rewired carbon fixation organisms using synthetic carbon concentrating compartments or heterologously expressed carboxysomes [117].…”

Section: In the Cell Carbon Fixationmentioning

confidence: 99%

Electrical Energy Storage with Engineered Biological Systems

Salimijazi

Parra²,

Barstow

2019

Preprint

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The availability of renewable energy technologies is increasing dramatically across the globe thanks to their growing maturity. However, large scale electrical energy storage and retrieval will almost certainly be a required in order to raise the penetration of renewable sources into the grid. No present energy storage technology has the perfect combination of high power and energy density, low financial and environmental cost, lack of site restrictions, long cycle and calendar lifespan, easy materials availability, and fast response time. Engineered electroactive microbes could address many of the limitations of current energy storage technologies by enabling rewired carbon fixation, a process that spatially separates reactions that are normally carried out together in a photosynthetic cell and replaces the least efficient with non-biological equivalents. If successful, this could allow storage of renewable electricity through electrochemical or enzymatic fixation of carbon dioxide and subsequent storage as carbon-based energy storage molecules including hydrocarbon and non-volatile polymers at high efficiency. In this article we compile performance data on biological and non-biological component choices for rewired carbon fixation systems and identify pressing research and engineering challenges.

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“…YFP, tagged with a small targeting peptide from the carboxysome-organizing protein, CcmN, was incorporated into the shells. In a recent breakthrough, a minimal functional carboxysome was expressed in tobacco chloroplasts (Long et al, 2018). This result was achieved by introducing two a-carboxysome coat proteins and the large and small subunits from the cyanobacterium Cyanobium.…”

Section: Nanoreactorsmentioning

confidence: 99%

Engineering of Metabolic Pathways Using Synthetic Enzyme Complexes

Smirnoff

2018

Plant Physiol.

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Carboxysome encapsulation of the CO2-fixing enzyme Rubisco in tobacco chloroplasts

Cited by 206 publications

References 72 publications

Self-Assembly Stability and Variability of Bacterial Microcompartment Shell Proteins in Response to the Environmental Change

Self-Assembly Stability and Variability of Bacterial Microcompartment Shell Proteins in Response to the Environmental Change

Electrical Energy Storage with Engineered Biological Systems

Engineering of Metabolic Pathways Using Synthetic Enzyme Complexes

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