Biomimetic synthesis of ordered silica structures mediated by block copolypeptides

In biological systems such as diatoms and sponges, the formation of solid silica structures with precisely controlled morphologies is directed by proteins and polysaccharides and occurs in water at neutral pH and ambient temperature. Laboratory methods, in contrast, have to rely on extreme pH conditions and/or surfactants to induce the condensation of silica precursors into specific morphologies or patterned structures. This contrast in processing conditions and the growing demand for benign synthesis methods that minimize adverse environmental effects have spurred much interest in biomimetic approaches in materials science. The recent demonstration that silicatein—a protein found in the silica spicules of the sponge Tethya aurantia—can hydrolyse and condense the precursor molecule tetraethoxysilane to form silica structures with controlled shapes at ambient conditions seems particularly promising in this context. Here we describe synthetic cysteine-lysine block copolypeptides that mimic the properties of silicatein: the copolypeptides self-assemble into structured aggregates that hydrolyse tetraethoxysilane while simultaneously directing the formation of ordered silica morphologies. We find that oxidation of the cysteine sulphydryl groups, which is known to affect the assembly of the block copolypeptide, allows us to produce different structures: hard silica spheres and well-defined columns of amorphous silica are produced using the fully reduced and the oxidized forms of the copolymer, respectively.

[1]  Buddy D. Ratner,et al.  Template-imprinted nanostructured surfaces for protein recognition , 1999, Nature.

[2]  Kui Yu,et al.  Ion-Induced Morphological Changes in “Crew-Cut” Aggregates of Amphiphilic Block Copolymers , 1996, Science.

[3]  M. Liff,et al.  NMR study of crosslinking by oxidation of four‐cysteine polypeptide models of the elastic network phase of wool fibre , 1998 .

[4]  D. Morse Silicon biotechnology: harnessing biological silica production to construct new materials , 1999 .

[5]  Mark E. Davis,et al.  Transesterification on “imprinted” silica , 1996 .

[6]  G. Stucky,et al.  Efficient Catalysis of Polysiloxane Synthesis by Silicatein α Requires Specific Hydroxy and Imidazole Functionalities. , 1999, Angewandte Chemie.

[7]  G. Stucky,et al.  Silicatein alpha: cathepsin L-like protein in sponge biosilica. , 1998, Proceedings of the National Academy of Sciences of the United States of America.

[8]  D. Zhao,et al.  Topological construction of mesoporous materials , 1998 .

[9]  D. Zhao,et al.  Evaluating Pore Sizes in Mesoporous Materials: A Simplified Standard Adsorption Method and a Simplified Broekhoff−de Boer Method , 1999 .

[10]  B. Heide,et al.  Enzyme-analog built polymers. 20. Molecular recognition through the exact placement of functional groups on rigid matrixes via a template approach , 1986 .

[11]  S. Mann Biomineralization and biomimetic materials chemistry , 1995 .

[12]  J. Strickland A practical hand-book of seawater analysis , 1972 .

[13]  G. Wulff,et al.  Molecular Imprinting in Cross-Linked Materials with the Aid of Molecular Templates - A Way towards Artificial Antibodies , 1995 .

[14]  Fredrickson,et al.  Triblock copolymer syntheses of mesoporous silica with periodic 50 to 300 angstrom pores , 1998, Science.

[15]  Q. Huo,et al.  Preparation of Hard Mesoporous Silica Spheres. , 1997 .

[16]  B. Volcani,et al.  Silicon and Siliceous Structures in Biological Systems , 1981, Springer New York.

[17]  J. S. Beck,et al.  Ordered mesoporous molecular sieves synthesized by a liquid-crystal template mechanism , 1992, Nature.

[18]  E. G. Vrieling,et al.  Diatom silicon biomineralization as an inspirational source of new approaches to silica production , 1999 .

[19]  Mark E. Davis,et al.  Rational Catalyst Design via Imprinted Nanostructured Materials , 1996 .

[20]  Klaus Mosbach,et al.  Drug assay using antibody mimics made by molecular imprinting , 1993, Nature.

[21]  A. Berger,et al.  Poly-L-cysteine , 1956 .

[22]  Q. Huo,et al.  Cooperative Formation of Inorganic-Organic Interfaces in the Synthesis of Silicate Mesostructures , 1993, Science.

[23]  B. D. Kay,et al.  Sol-gel transition in simple silicates II☆ , 1982 .

[24]  T. Deming,et al.  Facile synthesis of block copolypeptides of defined architecture , 1997, Nature.

[25]  G. Stucky,et al.  Silicatein α: Cathepsin L-like protein in sponge biosilica , 1998 .

[26]  J. Heilmann,et al.  Selective Catalysis on Silicon Dioxide with Substrate-Specific Cavities† , 1994 .

[27]  Mark E. Davis,et al.  Investigations into the Mechanisms of Molecular Recognition with Imprinted Polymers , 1999 .

[28]  G. Stucky,et al.  Silicatein filaments and subunits from a marine sponge direct the polymerization of silica and silicones in vitro. , 1999, Proceedings of the National Academy of Sciences of the United States of America.

[29]  H. Ogoshi,et al.  Silicic Acid Polymerization Catalyzed by Amines and Polyamines , 1998 .

[30]  Bruce Dunn,et al.  Probes of Pore Environment and Molecule-Matrix Interactions in Sol-Gel Materials , 1997 .

[31]  D. M. Nelson,et al.  A solvent extraction method for the colorimetric determination of nanomolar concentrations of silicic acid in seawater , 1986 .

[32]  G. Whitesides,et al.  Structure-Reactivity Relations for Thiol-Disulfide Interchange , 1987 .

[33]  G. Ozin,et al.  Lamellar aluminophosphates with surface patterns that mimic diatom and radiolarian microskeletons , 1995, Nature.

[34]  Jackie Y. Ying,et al.  SYNTHESIS AND APPLICATIONS OF SUPRAMOLECULAR-TEMPLATED MESOPOROUS MATERIALS , 1999 .

[35]  R. Rachel,et al.  Characterization of a 200-kDa diatom protein that is specifically associated with a silica-based substructure of the cell wall. , 1997, European journal of biochemistry.