Chemical mimicry of viral capsid self-assembly

Stable structures of icosahedral symmetry can serve numerous functional roles, including chemical microencapsulation and delivery of drugs and biomolecules, epitope presentation to allow for an efficient immunization process, synthesis of nanoparticles of uniform size, observation of encapsulated reactive intermediates, formation of structural elements for supramolecular constructs, and molecular computing. By examining physical models of spherical virus assembly we have arrived at a general synthetic strategy for producing chemical capsids at size scales between fullerenes and spherical viruses. Such capsids can be formed by self-assembly from a class of molecules developed from a symmetric pentagonal core. By designing chemical complementarity into the five interface edges of the molecule, we can produce self-assembling stable structures of icosahedral symmetry. We considered three different binding mechanisms: hydrogen bonding, metal binding, and formation of disulfide bonds. These structures can be designed to assemble and disassemble under controlled environmental conditions. We have conducted molecular dynamics simulation on a class of corannulene-based molecules to demonstrate the characteristics of self-assembly and to aid in the design of the molecular subunits. The edge complementarities can be of diverse structure, and they need not reflect the fivefold symmetry of the molecular core. Thus, self-assembling capsids formed from coded subunits can serve as addressable nanocontainers or custom-made structural elements.

[1]  J. F. Stoddart,et al.  Thermodynamic Synthesis of Rotaxanes by Imine Exchange , 1999 .

[2]  D. Rudkevich Nanoscale Molecular Containers , 2002 .

[3]  D. Filman,et al.  Three-dimensional structure of poliovirus at 2.9 A resolution. , 1985, Science.

[4]  J. Rebek,et al.  Stabilization of Labile Carbonyl Addition Intermediates by a Synthetic Receptor , 2007, Science.

[5]  K. Baldridge,et al.  Structure/energy correlation of bowl depth and inversion barrier in corannulene derivatives: combined experimental and quantum mechanical analysis. , 2001, Journal of the American Chemical Society.

[6]  F. Crick,et al.  Structure of Small Viruses , 1956, Nature.

[7]  J. F. Stoddart,et al.  Rotaxane formation under thermodynamic control , 1999 .

[8]  Gareth W. V. Cave,et al.  Supramolecular blueprint approach to metal-coordinated capsules , 2005, Proceedings of the National Academy of Sciences of the United States of America.

[9]  Müller,et al.  Archimedean Synthesis and Magic Numbers: "Sizing" Giant Molybdenum-Oxide-Based Molecular Spheres of the Keplerate Type. , 1999, Angewandte Chemie.

[10]  L. T. Scott,et al.  Fragments of fullerenes: Novel syntheses, structures and reactions , 1996 .

[11]  L. T. Scott,et al.  X-ray quality geometries of geodesic polyarenes from theoretical calculations: what levels of theory are reliable? , 2005, The Journal of organic chemistry.

[12]  D. Cram,et al.  The design of molecular hosts, guests, and their complexes , 1988, Science.

[13]  A. S. Reddy,et al.  Density functional theory study on the effect of substitution and ring annelation to the rim of corannulene. , 2004, The Journal of organic chemistry.

[14]  L. T. Scott,et al.  Gas-Phase Molecular Structure of Decachlorocorannulene, C20Cl10. An Electron-Diffraction Study Augmented by ab Initio, DFT, and Normal Coordinate Calculations , 2003 .

[15]  Stuart J Rowan,et al.  Dynamic covalent chemistry. , 2002, Angewandte Chemie.

[16]  Jeremy K. M. Sanders,et al.  Dynamic Combinatorial Libraries of Macrocyclic Disulfides in Water , 2000 .

[17]  Andrew J. P. White,et al.  Template‐Directed Synthesis of a [2]Rotaxane by the Clipping under Thermodynamic Control of a Crown Ether Like Macrocycle Around a Dialkylammonium Ion , 2001 .

[18]  J. Siegel,et al.  Anion mediated structural motifs in silver(I) complexes with corannulene. , 2005, Organic & biomolecular chemistry.

[19]  Toshio Shimizu,et al.  SYNTHESIS, STRUCTURE, AND RING CONVERSION OF 1,2-DITHIETE AND RELATED COMPOUNDS , 1998 .

[20]  I. Agranat,et al.  Inversion Barrier of Corannulene. A Benchmark for Bowl-to-Bowl Inversions in Fullerene Fragments. , 1999, The Journal of organic chemistry.

[21]  J. Siegel,et al.  Synthesis of Corannulene and Alkyl Derivatives of Corannulene , 1999 .

[22]  A. Sygula,et al.  ‘Buckybowls’—introducing curvature by solution phase synthesis , 2001 .

[23]  K. Baldridge,et al.  Synthesis and properties of sym-pentasubstituted derivatives of corannulene. , 2003, Organic letters.

[24]  R. Cacciapaglia,et al.  Metathesis reaction of formaldehyde acetals: an easy entry into the dynamic covalent chemistry of cyclophane formation. , 2005, Journal of the American Chemical Society.

[25]  J. Siegel,et al.  Aromatic molecular-bowl hydrocarbons: synthetic derivatives, their structures, and physical properties. , 2006, Chemical reviews.

[26]  M. Fujita,et al.  Metal-directed self-assembly of two- and three-dimensional synthetic receptors , 1998 .

[27]  S. Harrison,et al.  The familiar and the unexpected in structures of icosahedral viruses. , 2001, Current opinion in structural biology.

[28]  R. Lawton,et al.  Dibenzo[ghi,mno]fluoranthene , 1966 .

[29]  J. Atwood,et al.  Sulfonatocalixarenes: molecular capsule and 'Russian doll' arrays to structures mimicking viral geometry. , 2006, Chemical communications.

[30]  P. Stang,et al.  Self-assembly of discrete cyclic nanostructures mediated by transition metals. , 2000, Chemical reviews.

[31]  Charles J. Pedersen,et al.  The Discovery of Crown Ethers (Noble Lecture) , 1988 .

[32]  J. Rebek Simultaneous encapsulation: molecules held at close range. , 2005, Angewandte Chemie.

[33]  Martin Saunders,et al.  Incorporation of helium, neon, argon, krypton, and xenon into fullerenes using high pressure , 1994 .