[1] Chow D, Nunalee M L, Lim D W, et al. Peptide-Based biopolymers in biomedicine and biotechnology[J]. Materials Science & Engineering R-Reports, 2008, 62: 125-155
[2] Langer R, Tirrell D A. Designing materials for biology and medicine[J]. Nature, 2004, 428: 487-492
[3] DiMarco R L, Heilshorn S C. Multifunctional materials through modular protein engineering[J]. Advanced Materials,2012, 24: 3 923-3 940
[4] Lutolf M P, Hubbell J A. Synthetic biomaterials as instructive extracellular microenvironments for morphogenesis in tissue engineering[J]. Nature Biotechnology, 2005, 23: 47-55
[5] Wong J Y, Weng Z P, Moll S, et al. Identification and validation of a novel cell-recognition site (KNEED) on the 8th type III domain of fibronectin[J]. Biomaterials, 2002, 23: 3 865-3 870
[6] Biondi M, Ungaro F, Quaglia F, et al. Controlled drug delivery in tissue engineering[J]. Advanced Drug Delivery Reviews, 2008, 60: 229-242
[7] Hennink W E, van Nostrum C F. Novel crosslinking methods to design hydrogels[J]. Advanced Drug Delivery Reviews, 2002, 54:13-36
[8] Petka W A, Harden J L, McGrath K P, et al. Reversible hydrogels from self-assembling artificial proteins[J]. Science,1998, 281:389-392
[9] Shen W. Structure, dynamics, and properties of artificial protein hydrogels assembled through coiled-coil domains[D]. California Institute of Technology, 2005
[10] Shen W, Lammertink R G H, Sakata J K, et al. Assembly of an artificial protein hydrogel through leucine zipper aggregation and disulfide bond formation[J]. Macromolecules, 2005, 38: 3 909-3 916
[11] Shen W, Zhang K C, Kornfield J A, et al. Tuning the erosion rate of artificial protein hydrogels through control of network topology[J]. Nature Materials,2006, 5: 153-158
[12] Cao Y, Li H B. Engineering tandem modular protein based reversible hydrogels[J]. Chemical Communications, 2008, 36: 4 144-4 146
[13] Cao Y, Li H B. Polyprotein of GB1 is an ideal artificial elastomeric protein[J]. Nature Materials, 2007, 6: 109-114
[14] Lv S, Cao Y, Li H B. Tandem modular protein-based hydrogels constructed using a novel two-component approach[J]. Langmuir, 2012, 28:2 269-2 274
[15] Yang J Y, Xu C Y, Wang C, et al. Refolding hydrogels self-assembled from N-(2-hydroxypropyl)-methacrylamide graft copolymers by antiparallel coiled-coil formation[J]. Biomacromolecules, 2006, 7: 1 187-1 195
[16] Stevens M M, Allen S, Davies M C, et al. Molecular level investigations of the inter-and intramolecular interactions of pH-responsive artificial triblock proteins[J]. Biomacromolecules, 2005, 6: 1 266-1 271
[17] Wright E R, Conticello V P. Self-Assembly of block copolymers derived from elastin-mimetic polypeptide sequences[J]. Advanced Drug Delivery Reviews, 2002, 54: 1 057-1 073
[18] Banta S, Wheeldon I R, Blenner M. Protein engineering in the development of functional hydrogels[M]. In Annual Review of Biomedical Engineering, Vol 12, Yarmush M L, Duncan J S, Gray M L, Eds. Annual Reviews: Palo Alto, 2010
[19] Foo C, Lee J S, Mulyasasmita W, et al. Two-Component protein-engineered physical hydrogels for cell encapsulation[J]. Proceedings of the National Academy of Sciences of the United States of America, 2009, 106: 22 067-22 072
[20] Macias M J, Gervais V, Civera C, et al. Structural analysis of WW domains and design of a WW prototype[J]. Nature Structural Biology, 2000, 7: 375-379
[21] Grove T Z, Osuji C O, Forster J D, et al. Stimuli-Responsive smart gels realized via modular protein design[J]. Journal of the American Chemical Society, 2010, 132:14 024-14 026
[22] Topp S, Prasad V, Cianci G C, et al. A genetic toolbox for creating reversible Ca2+-sensitive materials[J]. Journal of the American Chemical Society, 2006, 128: 13 994-13 995
[23] Ito F, Usui K, Kawahara D, et al. Reversible hydrogel formation driven by protein-peptide-specific interaction and chondrocyte entrapment[J]. Biomaterials, 2010, 31:58-66
[24] Micklitsch C M, Knerr P J, Branco M C,et al. Zinc-Triggered hydrogelation of a self-assembling beta-hairpin peptide[J]. Angewandte Chemie-International Edition, 2011, 50:1 577-1 579
[25] Zhang X, Chu X, Wang L, et al. Rational design of a tetrameric protein to enhance interactions between self-assembled fibers gives molecular hydrogels[J]. Angewandte Chemie-International Edition, 2012, 51: 4 388-4 392
[26] Wang H, Shi Y, Wang L, et al. Recombinant proteins as cross-linkers for hydrogelations[J]. Chemical Society Reviews, 2013, 42: 891-901
[27] Indik Z, Yeh H, Ornsteingoldstein N, et al. Alternative splicing of human elastin messenger-RNA indicated by sequence-analysis of cloned genomic and complementary-DNA[J]. Proceedings of the National Academy of Sciences of the United States of America, 1987, 84: 5 680-5 684
[28] Urry D W. Entropic elastic processes in protein mechanisms.2. Simple (passive) and coupled (active) development of elastic forces[J]. Journal of Protein Chemistry, 1988, 7: 81-114
[29] Vrhovski B, Weiss A S. Biochemistry of tropoelastin[J]. European Journal of Biochemistry, 1998, 258: 1-18
[30] Urry D W, Seitz M, Gaub H E, et al. Elastin: A representative ideal protein elastomer[J]. Philosophical Transactions of the Royal Society of London Series B-Biological Sciences, 2002, 357:169-184
[31] McPherson D T, Morrow C, Minehan D S, et al. Production and purification of a recombinant elastomeric polypeptide, g-(vpgvg)19-vpgv, from escherichia-coli[J]. Biotechnology Progress, 1992, 8: 347-352
[32] Urry D W. Physical chemistry of biological free energy transduction as demonstrated by elastic protein-based polymers[J]. Journal of Physical Chemistry B, 1997, 101: 11 007-11 028
[33] Urry D W. Free-Energy transduction in polypeptides and proteins based on inverse temperature transitions[J]. Progress in Biophysics & Molecular Biology, 1992, 57: 23-57
[34] Urry D W, Gowda D C, Parker T M, et al. Hydrophobicity scale for proteins based on inverse temperature transitions[J]. Biopolymers, 1992, 32: 1 243-1 250
[35] Lee J, Macosko C W, Urry D W. Mechanical properties of cross-linked synthetic elastomeric polypentapeptides[J]. Macromolecules, 2001, 34: 5 968-5 974
[36] Trabbic-Carlson K, Setton L A, Chilkoti A. Swelling and mechanical behaviors of chemically cross-linked hydrogels of elastin-like polypeptides[J]. Biomacromolecules, 2003, 4: 572-580
[37] Lee T A T, Cooper A, Apkarian R P, et al. Thermo-Reversible self-assembly of nanoparticles derived from elastin-mimetic polypeptides[J]. Advanced Materials, 2000, 12(15):1 105-1 110
[38] Dinerman A A, Cappello J, Ghandehari H, et al. Solute diffusion in genetically engineered silk-elastinlike protein polymer hydrogels[J]. Journal of Controlled Release, 2002, 82: 277-287
[39] Dinerman A A, Cappello J, Ghandehari H, et al. Swelling behavior of a genetically engineered silk-elastinlike protein polymer hydrogel[J]. Biomaterials, 2002, 23: 4 203-4 210
[40] Nagarsekar A, Crissman J, Crissman M, et al. Genetic synthesis and characterization of pH-and temperature-sensitive silk-elastinlike protein block copolymers[J]. Journal of Biomedical Materials Research, 2002, 62:195-203
[41] Nagarsekar A, Crissman J, Crissman M, et al. Genetic engineering of stimuli-sensitive silkelastin-like protein block copolymers[J]. Biomacromolecules, 2003, 4: 602-607
[42] Fancy D A, Kodadek T. Chemistry for the analysis of protein-protein interactions: Rapid and efficient cross-linking triggered by long wavelength light[J]. Proceedings of the National Academy of Sciences of the United States of America, 1999, 96: 6 020-6 024
[43] Elvin C M, Carr A G, Huson M G,et al. Synthesis and properties of crosslinked recombinant pro-resilin[J]. Nature, 2005, 437: 999-1 002
[44] Balu R, Whittaker J, Dutta N K, et al. Multi-Responsive biomaterials and nanobioconjugates from resilin-like protein polymers[J]. Journal of Materials Chemistry B, 2014, 2: 5 936-5 947
[45] Vashi A V, Werkmeister J A, Vuocolo T,et al. Stabilization of collagen tissues by photocrosslinking[J]. Journal of Biomedical Materials Research Part A, 2012, 100A: 2 239-2 243
[46] Elvin C M, Brownlee A G, Huson M G, et al. The development of photochemically crosslinked native fibrinogen as a rapidly formed and mechanically strong surgical tissue sealant[J]. Biomaterials, 2009, 30: 2 059-2 065
[47] Elvin C M, Danon S J, Brownlee A G, et al. Evaluation of photo-crosslinked fibrinogen as a rapid and strong tissue adhesive[J]. Journal of Biomedical Materials Research Part A, 2010, 93A: 687-695
[48] Elvin C M, Vuocolo T, Brownlee A G, et al. A highly elastic tissue sealant based on photopolymerised gelatin[J]. Biomaterials, 2010, 31: 8 323-8 331
[49] Lv S, Dudek D M, Cao Y, et al. Designed biomaterials to mimic the mechanical properties of muscles[J]. Nature, 2010, 465: 69-73
[50] Lv S S, Bu T J, Kayser J, et al. Towards constructing extracellular matrix-mimetic hydrogels: An elastic hydrogel constructed from tandem modular proteins containing tenascin FnIII domains[J]. Acta Biomaterialia, 2013, 9: 6 481-6 491
[51] Fang J, Mehlich A, Koga N, et al. Forced protein unfolding leads to highly elastic and tough protein hydrogels[J]. Nature Communications, 2013, 4:2 974-2 983
[52] Bailey A J. The chemistry of natural enzyme-induced cross-links of proteins[J]. Amino Acids (Vienna), 1991, 1: 293-306
[53] Teixeira L S M, Feijen J, van Blitterswijk C A, et al. Enzyme-Catalyzed crosslinkable hydrogels: Emerging strategies for tissue engineering[J]. Biomaterials, 2012, 33:1 281-1 290
[54] Qin G, Rivkin A, Lapidot S, et al. Recombinant exon-encoded resilins for elastomeric biomaterials[J]. Biomaterials, 2011, 32: 9 231-9 243
[55] Lim D W, Nettles D L, Setton L A, et al. In situ cross-linkinig of elastin-like polypeptide block copolymers for tissue repair[J]. Biomacromolecules, 2008, 9: 222-230
[56] Nettles D L, Haider M A, Chilkoti A, et al. Neural network analysis identifies scaffold properties necessary for in vitro chondrogenesis in elastin-like polypeptide biopolymer scaffolds[J]. Tissue Engineering Part A, 2010, 16: 11-20
[57] Chung C, Anderson E, Pera R R, et al. Hydrogel crosslinking density regulates temporal contractility of human embryonic stem cell-derived cardiomyocytes in 3D cultures[J]. Soft Matter, 2012, 8:10 141-10 148
[58] Li L Q, Teller S, Clifton R J,et al. Tunable mechanical stability and deformation response of a resilin-based elastomer[J]. Biomacromolecules, 2011, 12: 2 302-2 310
[59] Chung C, Lampe K J, Heilshorn S C. Tetrakis(hydroxymethyl) phosphonium chloride as a covalent cross-linking agent for cell encapsulation within protein-based hydrogels[J]. Biomacromolecules, 2012, 13: 3 912-3 916
[60] Asai D, Xu D, Liu W, et al. Protein polymer hydrogels by in situ, rapid and reversible self-gelation[J]. Biomaterials, 2012, 33: 5 451-5 458
[61] Jo Y S, Gantz J, Hubbell J A, et al. Tailoring hydrogel degradation and drug release via neighboring amino acid controlled ester hydrolysis[J]. Soft Matter, 2009, 5: 440-446
[62] Miller J S, Shen C J, Legant W R, et al. Bioactive hydrogels made from step-growth derived PEG-peptide macromers[J]. Biomaterials, 2010, 31: 3 736-3 743
[63] Xu K D, Fu Y, Chung W J,et al. Thiol-ENE-Based biological/synthetic hybrid biomatrix for 3-D living cell culture[J]. Acta Biomaterialia, 2012, 8: 2 504-2 516
[64] Rizzi S C, Hubbell J A. Recombinant protein-co-PEG networks as cell-adhesive and proteolytically degradable hydrogel matrixes. Part 1: Development and physicochernical characteristics[J]. Biomacromolecules, 2005, 6: 1 226-1 238
[65] Halstenberg S, Panitch A, Rizzi S, et al. Biologically engineered protein-graft-poly(ethylene glycol) hydrogels: A cell adhesive and plasm in-degradable biosynthetic material for tissue repair[J]. Biomacromolecules, 2002, 3:710-723
[66] Sui Z, King W J, Murphy W L. Dynamic materials based on a protein conformational change[J]. Advanced Materials, 2007, 19(20): 3 377-3 380
[67] Cook W J, Walter L J, Walter M R. Drug-Binding by calmodulin-crystal-structure of a calmodulin trifluoperazine complex[J]. Biochemistry, 1994, 33: 15 259-15 265
[68] McGann C L, Levenson E A, Kiick K L. Resilin-Based hybrid hydrogels for cardiovascular tissue engineering[J]. Macromolecular Chemistry and Physics, 2013, 214: 203-213
[69] Stanfield R L, Wilson I A. Protein-Peptide interactions[J]. Current Opinion in Structural Biology, 1995, 5: 103-113
[70] Zakeri B, Fierer J O, Celik E, et al. Peptide tag forming a rapid covalent bond to a protein, through engineering a bacterial adhesin[J]. Proceedings of the National Academy of Sciences of the United States of America, 2012, 109: E690-E697
[71] Zakeri B, Howarth M. Spontaneous intermolecular amide bond formation between side chains for irreversible peptide targeting[J]. Journal of the American Chemical Society, 2010, 132(13): 4 526-4 527
[72] Sun F, Zhang W B, Mahdavi A, et al. Synthesis of bioactive protein hydrogels by genetically encoded SpyTag-SpyCatcher chemistry[J]. Proceedings of the National Academy of Sciences of the United States of America, 2014, 111: 11 269-11 274
[73] Martin L, Javier-Arias F, Alonso M, et al. Rapid micropatterning by temperature-triggered reversible gelation of a recombinant smart elastin-like tetrablock-copolymer[J]. Soft Matter, 2010, 6: 1 121-1 124
[74] Sui Z J, King W J, Murphy W L. Protein-Based hydrogels with tunable dynamic responses[J]. Advanced Functional Materials, 2008, 18: 1 824-1 831
[75] Yuan W, Yang J, Kopeckova P, et al. Smart hydrogels containing adenylate kinase: Translating substrate recognition into macroscopic motion[J]. Journal of the American Chemical Society, 2008, 130, 15 760-15 761
[76] Peng Q, Li H. Direct observation of tug-of-war during the folding of a mutually exclusive protein[J]. Journal of the American Chemical Society, 2009, 131: 13 347-13 354
[77] Peng Q, Kong N, Wang H C E,et al. Designing redox potential-controlled protein switches based on mutually exclusive proteins[J]. Protein Science, 2012, 21: 1 222-1 230
[78] Kong N, Peng Q, Li H. Rationally designed dynamic protein hydrogels with reversibly tunable mechanical properties[J]. Advanced Functional Materials, 2014, 24: 7 310-7 317
[79] Pradhan S, Farach-Carson M C. Mining the extracellular matrix for tissue engineering applications[J]. Regenerative Medicine, 2010, 5: 961-970
[80] Altunbas A, Pochan D J. Peptide-Based and polypeptide-based hydrogels for drug delivery and tissue engineering[M]. In Peptide-Based Materials, Deming T, Ed. Springer-Verlag Berlin: Berlin, 2012
[81] Ruoslahti E, Pierschbacher M D. New perspectives in cell-adhesion-RGD and integrins[J]. Science, 1987, 238: 491-497
[82] Mitra A, Mulholland J, Nan A, et al. Targeting tumor angiogenic vasculature using polymer-RGD conjugates[J]. Journal of Controlled Release, 2005, 102: 191-201
[83] Liu J C, Tirrell D A. Cell response to RGD density in cross-linked artificial extracellular matrix protein films[J]. Biomacromolecules, 2008, 9: 2 984-2 988
[84] Lutolf M P, Gilbert P M, Blau H M. Designing materials to direct stem-cell fate[J]. Nature, 2009, 462: 433-441
[85] Griffith L G, Swartz M A. Capturing complex 3D tissue physiology in vitro[J]. Nature Reviews Molecular Cell Biology, 2006, 7: 211-224
[86] Parisi-Amon A, Mulyasasmita W, Chung C, et al. Protein-Engineered injectable hydrogel to improve retention of transplanted adipose-derived stem cells[J]. Advanced Healthcare Materials, 2013, 2: 428-432
[87] Fong J H, Keating A E, Singh M. Predicting specificity in bZIP coiled-coil protein interactions[J]. Genome Biology, 2004, 5(2): R11. doi: 10.1186/gb-2004-5-2-r11
[88] Kim M, Tang S, Olsen B D. Physics of engineered protein hydrogels[J]. Journal of Polymer Science Part B-Polymer Physics, 2013, 51: 587-601
|