A conserved spider silk domain acts as a molecular switch that controls fibre assembly

A huge variety of proteins are able to form fibrillar structures, especially at high protein concentrations. Hence, it is surprising that spider silk proteins can be stored in a soluble form at high concentrations and transformed into extremely stable fibres on demand. Silk proteins are reminiscent of amphiphilic block copolymers containing stretches of polyalanine and glycine-rich polar elements forming a repetitive core flanked by highly conserved non-repetitive amino-terminal and carboxy-terminal domains. The N-terminal domain comprises a secretion signal, but further functions remain unassigned. The C-terminal domain was implicated in the control of solubility and fibre formation initiated by changes in ionic composition and mechanical stimuli known to align the repetitive sequence elements and promote β-sheet formation. However, despite recent structural data, little is known about this remarkable behaviour in molecular detail. Here we present the solution structure of the C-terminal domain of a spider dragline silk protein and provide evidence that the structural state of this domain is essential for controlled switching between the storage and assembly forms of silk proteins. In addition, the C-terminal domain also has a role in the alignment of secondary structural features formed by the repetitive elements in the backbone of spider silk proteins, which is known to be important for the mechanical properties of the fibre.

[1]  W. Jahnke,et al.  Measurement of fast proton exchange rates in isotopically labeled compounds , 1993 .

[2]  J. Thornton,et al.  PROCHECK: a program to check the stereochemical quality of protein structures , 1993 .

[3]  A. Bacher,et al.  The solution structure of the N-terminal domain of riboflavin synthase. , 2001, Journal of molecular biology.

[4]  D. Cohn,et al.  An essential role for the C-terminal domain of a dragline spider silk protein in directing fiber formation. , 2006, Biomacromolecules.

[5]  M. Knight,et al.  Beta transition and stress-induced phase separation in the spinning of spider dragline silk. , 2000, International journal of biological macromolecules.

[6]  Fritz Vollrath,et al.  Liquid crystals and flow elongation in a spider's silk production line , 1999, Proceedings of the Royal Society of London. Series B: Biological Sciences.

[7]  A. Lupas Coiled coils: new structures and new functions. , 1996, Trends in biochemical sciences.

[8]  J. Hardy,et al.  Silk-inspired polymers and proteins. , 2009, Biochemical Society transactions.

[9]  C. Renner,et al.  The chain register in heterotrimeric collagen peptides affects triple helix stability and folding kinetics. , 2002, Journal of molecular biology.

[10]  George T Detitta,et al.  Thermofluor-based high-throughput stability optimization of proteins for structural studies. , 2006, Analytical biochemistry.

[11]  Fritz Vollrath,et al.  Changes in element composition along the spinning duct in a Nephila spider , 2001, Naturwissenschaften.

[12]  C. Dobson Protein folding and misfolding , 2003, Nature.

[13]  J. Gosline,et al.  The mechanical design of spider silks: from fibroin sequence to mechanical function. , 1999, The Journal of experimental biology.

[14]  R. Lewis,et al.  Analysis of the conserved N-terminal domains in major ampullate spider silk proteins. , 2005, Biomacromolecules.

[15]  F. Grosse,et al.  The conserved C-termini contribute to the properties of spider silk fibroins. , 2005, Biochemical and biophysical research communications.

[16]  Thomas Scheibel,et al.  Spider silk: from soluble protein to extraordinary fiber. , 2009, Angewandte Chemie.

[17]  Josef H. Exler,et al.  The amphiphilic properties of spider silks are important for spinning. , 2007, Angewandte Chemie.

[18]  N. Bulleid,et al.  The role of cysteine residues in the folding and association of the COOH-terminal propeptide of types I and III procollagen. , 1994, The Journal of biological chemistry.

[19]  A. Bax,et al.  Protein backbone angle restraints from searching a database for chemical shift and sequence homology , 1999, Journal of biomolecular NMR.

[20]  R. Timpl,et al.  The collagen superfamily. , 1995, International archives of allergy and immunology.

[21]  Ad Bax,et al.  Proton-proton correlation via carbon-carbon couplings: a three-dimensional NMR approach for the assignment of aliphatic resonances in proteins labeled with carbon-13 , 1990 .

[22]  David L. Kaplan,et al.  Mechanism of silk processing in insects and spiders , 2003, Nature.

[23]  P. Privalov Stability of proteins: small globular proteins. , 1979, Advances in protein chemistry.

[24]  T. Lefèvre,et al.  Conformational and orientational transformation of silk proteins in the major ampullate gland of Nephila clavipes spiders. , 2008, Biomacromolecules.

[25]  H. Kessler,et al.  An efficient strategy for assignment of cross-peaks in 3D heteronuclear NOESY experiments , 1999, Journal of biomolecular NMR.

[26]  Fritz Vollrath,et al.  Liquid crystalline spinning of spider silk , 2001, Nature.

[27]  Anna Rising,et al.  N-terminal nonrepetitive domain common to dragline, flagelliform, and cylindriform spider silk proteins. , 2006, Biomacromolecules.

[28]  Charles D Schwieters,et al.  The Xplor-NIH NMR molecular structure determination package. , 2003, Journal of magnetic resonance.

[29]  Christian Griesinger,et al.  Heteronuclear multidimensional NMR experiments for the structure determination of proteins in solution employing pulsed field gradients , 1999 .

[30]  Sanjay B. Hari,et al.  High-throughput thermal scanning: a general, rapid dye-binding thermal shift screen for protein engineering. , 2009, Journal of the American Chemical Society.

[31]  A. Bausch,et al.  Interfacial rheological properties of recombinant spider-silk proteins , 2009, Biointerphases.

[32]  S. Rammensee,et al.  Assembly mechanism of recombinant spider silk proteins , 2008, Proceedings of the National Academy of Sciences.

[33]  R. Rudolph,et al.  Primary structure elements of spider dragline silks and their contribution to protein solubility. , 2004, Biochemistry.

[34]  M Ikura,et al.  Improved three-dimensional1H−13C−1H correlation spectroscopy of a13C-labeled protein using constant-time evolution , 1991, Journal of biomolecular NMR.

[35]  Daiwen Yang,et al.  Solution structure of eggcase silk protein and its implications for silk fiber formation , 2009, Proceedings of the National Academy of Sciences.