Self-assembling biological complexes such as viral capsids have been manipulated to function in innovative nanotechnology applications. The E2 component of pyruvate dehydrogenase from Bacillus stearothermophilus forms a dodecahedral complex and potentially provides another platform for these purposes. In this investigation, we show that this protein assembly exhibits unusual stability and can be modified to encapsulate model drug molecules. To distill the E2 protein down to its structural scaffold core, we synthesized a truncated gene optimized for expression in Escherichia coli. The correct assembly and dodecahedral structure of the resulting scaffold was confirmed with dynamic light scattering and transmission electron microscopy. Using circular dichroism and differential scanning calorimetry, we found the thermostability of the complex to be unusually high, with an onset temperature of unfolding at 81.1 +/- 0.9 degrees C and an apparent midpoint unfolding temperature of 91.4 +/- 1.4 degrees C. To evaluate the potential of this scaffold for encapsulation of guest molecules, we made variants at residues 381 and 239 which altered the physicochemical properties of the hollow internal cavity. These mutants, yielding 60 and 120 mutations within this cavity, assembled into the correct architecture and exhibited high thermostability that was comparable to the wild-type scaffold. To show the applicability of this scaffold, two different fluorescent dye molecules were covalently coupled to the cysteine mutant at site 381. We demonstrate that these mutations can introduce non-native functionality and enable molecular encapsulation within the cavity while still retaining the dodecahedral structure. The unusually robust nature of this scaffold and its amenability to internal changes reveal its potential for nanoscale applications.
Self-assembling protein cages provide a wide range of possible applications in nanotechnology. We report the first example of an engineered pH-dependent molecular switch in a virus-like particle. By genetically manipulating the subunit-subunit interface of the E2 subunit of pyruvate dehydrogenase, we introduce pH-responsive assembly into a scaffold that is natively stable at both pH 5.0 and 7.4. The redesigned protein module yields an intact, stable particle at pH 7.4 that dissociates at pH 5.0. This triggered behavior is especially relevant for applications in therapeutic delivery.
Self-assembling protein cage structures have many potential applications in nanotechnology, one of which is therapeutic delivery. For intracellular targeting, pH-controlled disassembly of virus-like particles and release of their molecular cargo is particularly strategic. We investigated the potential of using histidines for introducing pH-dependent disassembly in the E2 subunit of pyruvate dehydrogenase. Two subunit interfaces likely to disrupt stability, an intratrimer interface (the N-terminus) and an intertrimer interface (methionine-425), were redesigned. Our results show that changing the identity of the putative anchor site 425 to histidine does not decrease stability. In contrast, engineering non-native pH-dependent behavior and modulating the transition pH at which disassembly occurs can be accomplished by mutagenesis of the N-terminus and by ionic strength changes. The observed pH-triggered disassembly is due to electrostatic repulsions generated by histidine protonation. These results suggest that altering the degree of electrostatic repulsion at subunit interfaces could be a generally applicable strategy for designing pH-triggered assembly in protein macromolecular structures.
Biomaterials such as self-assembling biological complexes have demonstrated a variety of applications in materials science and nanotechnology. The functionality of protein-based materials, however, is often limited by the absence or locations of specific chemical conjugation sites. In this investigation, we developed a new strategy for loading organic molecules into the hollow cavity of a protein nanoparticle that relies only on non-covalent interactions, and we demonstrated its applicability in drug delivery. Based on a biomimetic model that incorporates multiple phenylalanines to create a generalized binding site, we retained and delivered the antitumor compound doxorubicin by redesigning a caged protein scaffold. Through an iterative combination of structural modeling and protein engineering, we obtained new variants of the E2 subunit of pyruvate dehydrogenase with varying levels of drug-carrying capabilities. We found that an increasing number of introduced phenylalanines within the scaffold cavity generally resulted in greater drug loading capacities. Drug loading levels could be achieved that were greater than conventional nanoparticle delivery systems. These protein nanoparticles containing doxorubicin were taken up by breast cancer cells and induced significant cell death. Our novel approach demonstrates a universal strategy to design de novo hydrophobic binding domains within protein-based scaffolds for molecular encapsulation and transport, and it broadens the ability to attach guest molecules to this class of materials.
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