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Polymers and Self Assembly: From Biology to Nanomaterials Poster Session II

33-POS

Board 33

Immobilization of RubisCO by Self-Assembled Nanotubes

Yuan Sun, Sriram Satagopan, F. Robert Tabita,

Jon Parquette

.

The Ohio State University, Columbus, USA.

Biology-inspired catalysts, such as ribulose-1,5-bisphosphate carboxylase-oxygenase

(RuBisCO), efficiently reduce CO

2

resulting in products that are subsequently metabolized to

energy-rich compounds like glucose by the sequential action of multiple enzymes. However, the

use of free or cell-based enzymes as biocatalysts for large-scale industrial processes pose

significant limitations due to their incompatibility with reaction conditions that often depart from

their physiological states. Although biological catalysts, such as RubisCO, are among the most

efficient and ubiquitous catalysts for CO

2

fixation, the use of free or cell-based enzymes as

biocatalysts for large-scale industrial processes pose significant drawbacks due to their

incompatibility with reaction conditions that often depart from their physiological states.

However, cells often compartmentalize various biological reactions to address challenges such as

the toxicity of accumulating intermediates, competing reaction pathways and slow turnover rates.

Objective

: In this work, we attempt to mimic biological compartmentalization, where structures

such as carboxysomes naturally encapsulate RubisCO and carbonic anhydrase and provide a

protected environment to maximize CO

2

assimilation.

Methods

: To initiate such studies, we

have attempted to encapsulate RubisCO within self-assembled nanotubes. Conditions were

established such that RubisCO was successfully sequestered into a variety of self-assembling

nanotubes.

Results

: The encapsulated protein was enzymatically active and was clearly

associated with the nanotubes and removed from solution based on a number of criteria.

Conclusion

: These nanostructures were also found to enhance the stability of RubisCO toward

proteases and other environmental factors. We expect this research will permit encapsulated

biocatalysts to be useful in scalable CO

2

conversions and other processes.