Structural proteins from whelk egg capsule with long range elasticity associated with a solid-state phase transition.

The robust, proteinaceous egg capsules of marine prosobranch gastropods (genus Busycotypus ) exhibit unique biomechanical properties such as high elastic strain recovery and elastic energy dissipation capability. Capsule material possesses long-range extensibility that is fully recoverable and is the result of a secondary structure phase transition from α-helical coiled-coil to extended β-sheet rather than of entropic (rubber) elasticity. We report here the characterization of the precursor proteins that make up this material. Three different proteins have been purified and analyzed, and complete protein sequences deduced from messenger ribonucleic acid (mRNA) transcripts. Circular dichroism (CD) and Fourier transform infrared (FTIR) spectroscopy indicate that the proteins are strongly α-helical in solution and primary sequence analysis suggests that these proteins have a propensity to form coiled-coils. This is in agreement with previous wide-angle X-ray scattering (WAXS) and solid-state Raman spectroscopic analysis of mature egg capsules.

[1]  Olga Kononova,et al.  Mechanical transition from α-helical coiled coils to β-sheets in fibrin(ogen). , 2012, Journal of the American Chemical Society.

[2]  Caroline Louis-Jeune,et al.  Prediction of protein secondary structure from circular dichroism using theoretically derived spectra , 2012, Proteins.

[3]  R. Shadwick,et al.  Relationship between body mass and biomechanical properties of limb tendons in adult mammals. , 1994, The American journal of physiology.

[4]  Himadri S. Gupta,et al.  Pseudoelastic behaviour of a natural material is achieved via reversible changes in protein backbone conformation , 2012, Journal of The Royal Society Interface.

[5]  Oliver D. Testa,et al.  CC+: a relational database of coiled-coil structures , 2008, Nucleic Acids Res..

[6]  Mark W. Denny,et al.  THE PHYSICAL PROPERTIES OF SPIDER'S SILK AND THEIR ROLE IN THE DESIGN OF ORB-WEBS , 1976 .

[7]  J. Hearle A critical review of the structural mechanics of wool and hair fibres. , 2000, International journal of biological macromolecules.

[8]  E. Fuchs,et al.  Elucidating the early stages of keratin filament assembly , 1990, The Journal of cell biology.

[9]  Christian Riekel,et al.  The mechanical properties of hydrated intermediate filaments: insights from hagfish slime threads. , 2003, Biophysical journal.

[10]  A. Lendlein,et al.  Shape-memory polymers. , 2002, Angewandte Chemie.

[11]  R. Pithawalla,et al.  Keratin-like components of gland thread cells modulate the properties of mucus from hagfish (Eptatretus stouti) , 1991, Cell and Tissue Research.

[12]  W. Lu,et al.  Nanomechanical Properties of Vimentin Intermediate Filament , 2012 .

[13]  T. Sutherland,et al.  Natural templates for coiled-coil biomaterials from praying mantis egg cases. , 2012, Biomacromolecules.

[14]  Sarah Rauscher,et al.  Structural disorder and protein elasticity. , 2012, Advances in experimental medicine and biology.

[15]  A. Geddes,et al.  Ultrastructure of the fibrous protein from the egg capsules of the whelk Buccinum undatum. , 1969, Journal of ultrastructure research.

[16]  T. Weis-Fogh Molecular interpretation of the elasticity of resilin, a rubber-like protein , 1961 .

[17]  E. Atkins,et al.  Molecular bending and networks in a basement membrane-like collagen: packing in dogfish egg capsule collagen. , 1993, International journal of biological macromolecules.

[18]  D. Moss Biomedical Applications of Synchrotron Infrared Microspectroscopy , 2010 .

[19]  Paul J. Flory,et al.  Theory of Elastic Mechanisms in Fibrous Proteins , 1956 .

[20]  M. Delorenzi,et al.  An HMM model for coiled-coil domains and a comparison with PSSM-based predictions , 2002, Bioinform..

[21]  R. Hodges,et al.  The two‐stranded α‐helical coiled‐coil is an ideal model for studying protein stability and subunit interactions , 1992, Biopolymers.

[22]  Andrei N. Lupas,et al.  The structure of α-helical coiled coils , 2005 .

[23]  A. Lupas,et al.  Predicting coiled coils from protein sequences , 1991, Science.

[24]  Ueli Aebi,et al.  Molecular mechanisms underlying the assembly of intermediate filaments. , 2004, Experimental cell research.

[25]  Gail J. Bartlett,et al.  New currency for old rope: from coiled-coil assemblies to α-helical barrels. , 2012, Current opinion in structural biology.

[26]  The occurrence of reducible compounds in an invertebrate structure protein ofBuccinum undatum (L.) , 1976, Experientia.

[27]  M. Buehler,et al.  Coiled-coil intermediate filament stutter instability and molecular unfolding , 2011, Computer methods in biomechanics and biomedical engineering.

[28]  T. M. Parker,et al.  Elastin: a representative ideal protein elastomer. , 2002, Philosophical transactions of the Royal Society of London. Series B, Biological sciences.

[29]  J. Gosline,et al.  Molecular design of the α–keratin composite: insights from a matrix–free model, hagfish slime threads , 2004, Proceedings of the Royal Society of London. Series B: Biological Sciences.

[30]  Douglas S Fudge,et al.  Hagfish slime threads as a biomimetic model for high performance protein fibres , 2010, Bioinspiration & biomimetics.

[31]  J. Gosline,et al.  Elastic proteins: biological roles and mechanical properties. , 2002, Philosophical transactions of the Royal Society of London. Series B, Biological sciences.

[32]  Noah Linden,et al.  A de novo peptide hexamer with a mutable channel , 2011, Nature chemical biology.

[33]  Thomas L. Vincent,et al.  SCORER 2.0: an algorithm for distinguishing parallel dimeric and trimeric coiled-coil sequences , 2011, Bioinform..

[34]  Matthias Rief,et al.  The myosin coiled-coil is a truly elastic protein structure , 2002, Nature materials.

[35]  P. Shewry,et al.  Comparative structures and properties of elastic proteins. , 2002, Philosophical transactions of the Royal Society of London. Series B, Biological sciences.

[36]  H. Zahn,et al.  The Stress/Strain Curve of α-Keratin Fibers and the Structure of the Intermediate Filament , 1994 .

[37]  A. Miserez,et al.  Phase transition-induced elasticity of α-helical bioelastomeric fibres and networks. , 2013, Chemical Society reviews.

[38]  N. Greenfield Using circular dichroism spectra to estimate protein secondary structure , 2007, Nature Protocols.

[39]  George D Rose,et al.  Folding and binding: lingering questions, emerging answers. , 2012, Current opinion in structural biology.

[40]  E. Bendit The α–β Transformation in Keratin , 1957, Nature.

[41]  B. Berger,et al.  MultiCoil: A program for predicting two‐and three‐stranded coiled coils , 1997, Protein science : a publication of the Protein Society.

[42]  K. M. Rudall CHAPTER 9 – Silk and Other Cocoon Proteins , 1962 .

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

[44]  Robert E Shadwick,et al.  Mechanical characterization of an unusual elastic biomaterial from the egg capsules of marine snails (Busycon spp.). , 2002, Biomacromolecules.

[45]  A. Falick,et al.  Egg Case Protein-1 , 2005, Journal of Biological Chemistry.

[46]  G. Rogers Biology of the wool follicle: an excursion into a unique tissue interaction system waiting to be re‐discovered , 2006, Experimental dermatology.

[47]  E. Baer,et al.  Deformation in tendon collagen. , 1980, Symposia of the Society for Experimental Biology.

[48]  H. Magalhaes An Ecological Study of Snails of the Genus Busycon at Beaufort, North Carolina , 1948 .

[49]  Mark W. Denny,et al.  Nearshore Biomechanics. (Book Reviews: Biology and the Mechanics of the Wave-Swept Environment) , 1988 .

[50]  The α-β Transformation in Keratin , 1958, Nature.

[51]  J. Waite,et al.  Coating proteins: structure and cross-linking in fp-1 from the green shell mussel Perna canaliculus. , 2005, Biochemistry.

[52]  T. A. Rawlings Adaptations to Physical Stresses in the Intertidal Zone: The Egg Capsules of Neogastropod Molluscs , 1999 .

[53]  Ali Miserez,et al.  Non-entropic and reversible long-range deformation of an encapsulating bioelastomer. , 2009, Nature materials.

[54]  M. Buehler,et al.  Molecular dynamics simulation of the α-helix to β-sheet transition in coiled protein filaments: evidence for a critical filament length scale. , 2010, Physical review letters.

[55]  D. Woolfson The design of coiled-coil structures and assemblies. , 2005, Advances in protein chemistry.

[56]  Chunfu Xu,et al.  Rational design of helical nanotubes from self-assembly of coiled-coil lock washers. , 2013, Journal of the American Chemical Society.

[57]  Shawn Hoon,et al.  Accelerating the design of biomimetic materials by integrating RNA-seq with proteomics and materials science , 2013, Nature Biotechnology.

[58]  N. Price,et al.  An unusual type of secretory cell in the ventral pedal gland of the gastropod mollusc Buccinum undatum L. , 1976, Tissue & cell.

[59]  P. Bullough,et al.  High-resolution spot-scan electron microscopy of microcrystals of an alpha-helical coiled-coil protein. , 1990, Journal of molecular biology.

[60]  Zhiping Xu,et al.  Nanoconfinement Controls Stiffness, Strength and Mechanical Toughness of Β-sheet Crystals in Silk , 2010 .

[61]  D. Parry,et al.  An unusual intermediate filament subunit from the cytoskeletal biopolymer released extracellularly into seawater by the primitive hagfish (Eptatretus stouti). , 1994, Journal of cell science.

[62]  R. Shadwick,et al.  Reversibly labile, sclerotization-induced elastic properties in a keratin analog from marine snails: whelk egg capsule biopolymer (WECB) , 2007, Journal of Experimental Biology.

[63]  John M. Gosline,et al.  Elastin as a random‐network elastomer: A mechanical and optical analysis of single elastin fibers , 1981 .

[64]  M. Feughelman,et al.  Mechanical properties and structure of alpha-keratin fibres : wool, human hair, and related fibres , 1997 .