Computational design of a protein crystal

Lanci, Christopher J.; MacDermaid, Christopher M.; Kang, Seung-gu; Acharya, Rudresh; North, Benjamin; Yang, Xi; Qiu, Xiayang; DeGrado, William F.; Saven, Jeffery G.

doi:10.1073/pnas.1112595109

Cited by 157 publications

(169 citation statements)

References 61 publications

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“…Although effective methodologies have been developed for facilitating protein crystallization, 7,8 successes in obtaining 3D protein crystals by design have been rare. [9][10][11] In contrast, the ability to rationally engineer crystalline materials from small organic and inorganic building blocks, though still challenging, is considerably more advanced. 1,[12][13][14] A prominent class of these crystalline materials is metal-organic frameworks (MOFs), which have attracted much attention due their applications in separation, storage, and catalysis, etc.…”

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confidence: 96%

A Metal Organic Framework with Spherical Protein Nodes: Rational Chemical Design of 3D Protein Crystals

et al. 2015

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We describe here the construction of a three-dimensional, porous, crystalline framework formed by spherical protein nodes that assemble into a prescribed lattice arrangement through metal-organic linker-directed interactions. The octahedral iron storage enzyme, ferritin, was engineered in its C3 symmetric pores with tripodal Zn coordination sites. Dynamic light scattering and crystallographic studies established that this Zn-ferritin construct could robustly self-assemble into the desired bcc-type crystals upon coordination of a ditopic linker bearing hydroxamic acid functional groups. This system represents the first example of a ternary protein-metal-organic crystalline framework whose formation is fully dependent on each of its three components.

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confidence: 96%

A Metal Organic Framework with Spherical Protein Nodes: Rational Chemical Design of 3D Protein Crystals

et al. 2015

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“…Studying the structure of transient complexes in solution [149] may not only help identify potential crystal contacts, but also competing interactions that can hinder crystal assembly. The design of proteins that easily crystallize could also be used to validate and further enrich the microscopic insights obtained from the direct studies of protein-protein interactions [150].…”

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confidence: 99%

Soft matter perspective on protein crystal assembly

Fusco

Charbonneau

2016

Colloids and Surfaces B: Biointerfaces

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“…An important realization was that a large number of complex symmetries could be generated from only two distinct symmetry elements (for a protein, these must be rotational symmetries specified by its quaternary structure), provided the orientation of the symmetry axes with respect to each other could be carefully controlled. These principles have now been quite widely applied to design both protein cages and protein networks (16)(17)(18)(19)(20)(21)(22). The principal challenge to researchers has been to design new interactions between the protein subunits that promote assembly in the desired geometry, and, in particular, to align the angle between symmetry axes correctly.…”

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Flexible, symmetry-directed approach to assembling protein cages

Sciore

Koldewey

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

135

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The assembly of individual protein subunits into large-scale symmetrical structures is widespread in nature and confers new biological properties. Engineered protein assemblies have potential applications in nanotechnology and medicine; however, a major challenge in engineering assemblies de novo has been to design interactions between the protein subunits so that they specifically assemble into the desired structure. Here we demonstrate a simple, generalizable approach to assemble proteins into cage-like structures that uses short de novo designed coiled-coil domains to mediate assembly. We assembled eight copies of a C 3 -symmetric trimeric esterase into a well-defined octahedral protein cage by appending a C 4 -symmetric coiled-coil domain to the protein through a short, flexible linker sequence, with the approximate length of the linker sequence determined by computational modeling. The structure of the cage was verified using a combination of analytical ultracentrifugation, native electrospray mass spectrometry, and negative stain and cryoelectron microscopy. For the protein cage to assemble correctly, it was necessary to optimize the length of the linker sequence. This observation suggests that flexibility between the two protein domains is important to allow the protein subunits sufficient freedom to assemble into the geometry specified by the combination of C 4 and C 3 symmetry elements. Because this approach is inherently modular and places minimal requirements on the structural features of the protein building blocks, it could be extended to assemble a wide variety of proteins into structures with different symmetries.coiled coils | protein design | native mass spectrometry | analytical ultracentrifugation | cryoelectron microscopy

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Computational design of a protein crystal

Cited by 157 publications

References 61 publications

A Metal Organic Framework with Spherical Protein Nodes: Rational Chemical Design of 3D Protein Crystals

A Metal Organic Framework with Spherical Protein Nodes: Rational Chemical Design of 3D Protein Crystals

Soft matter perspective on protein crystal assembly

Flexible, symmetry-directed approach to assembling protein cages

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