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Advances in Fmoc solid-phase peptide synthesisCryo-transmission electron microscopy structure of a gigadalton peptide fiber of de novo design.Structure and flexibility of nanoscale protein cages designed by symmetric self-assembly.Structural plasticity of 4- -helical bundles exemplified by the puzzle-like molecular assembly of the Rop proteinDe novo design of protein homo-oligomers with modular hydrogen-bond network-mediated specificityStatistical analysis of crystallization database links protein physico-chemical features with crystallization mechanismsPeptides as new smart bionanomaterials: molecular-recognition and self-assembly capabilities.Designing degradable hydrogels for orthogonal control of cell microenvironments.Molecular tools for the construction of peptide-based materials.Isocyanide-based multicomponent reactions towards cyclic constrained peptidomimetics.Design of nanostructures based on aromatic peptide amphiphiles.Controlling the Assembly of Coiled-Coil Peptide Nanotubes.Peptide self-assembly: thermodynamics and kinetics.Coiled-Coil Design: Updated and Upgraded.Calmodulin EF-hand peptides as Ca2+ -switchable recognition tags.PEP-SiteFinder: a tool for the blind identification of peptide binding sites on protein surfaces.Strong contributions from vertical triads to helix-partner preferences in parallel coiled coils.Antigen-loaded pH-sensitive hydrogel microparticles are taken up by dendritic cells with no requirement for targeting antibodies.The d'--d--d' vertical triad is less discriminating than the a'--a--a' vertical triad in the antiparallel coiled-coil dimer motif.High thermodynamic stability of parametrically designed helical bundles.Polyoxometalate clusters integrated into peptide chains and as inorganic amino acids: solution- and solid-phase approaches.Cooperative self-assembly of peptide gelators and proteins.Accelerating the design of biomimetic materials by integrating RNA-seq with proteomics and materials science.A transferable coarse-grained model for diphenylalanine: how to represent an environment driven conformational transition.Conformational Dynamics of Asparagine at Coiled-Coil Interfaces.Design Principles of Peptide Based Self-Assembled Nanomaterials.Evolution of mechanics in α-helical peptide conjugated linear- and star-block PEG.Folding Topology of a Short Coiled-Coil Peptide Structure Templated by an Oligonucleotide Triplex.Collagen mimetic peptide discs promote assembly of a broad range of natural protein fibers through hydrophobic interactions.A de novo self-assembling peptide hydrogel biosensor with covalently immobilised DNA-recognising motifs.In vitro and in vivo supramolecular modification of biomembranes using a lipidated coiled-coil motif.Kinetic studies on strand displacement in de novo designed parallel heterodimeric coiled coils.Tuning peptide self-assembly by an in-tether chiral center.Cell-adhesive hydrogels composed of peptide nanofibers responsive to biological ionsAlignment of nanostructured tripeptide gels by directional ultrasonicationTransient supramolecular reconfiguration of peptide nanostructures using ultrasoundDirected Self-Assembly of Trimeric DNA-Bindingchiral Miniprotein Helicates
P2860
Q26770921-C93147F7-B792-4424-B9B9-B3B81A19A54CQ27670986-50BFFC39-2AC3-4360-9C58-0F4788FCDE17Q27677724-A015F554-F566-4345-889B-8F8F8869FD14Q27684684-A15CEE0F-2964-4A1E-9955-1B3F9786A03FQ27704825-B13785DA-EB64-4206-949F-0F60EED85FA9Q28540267-B4B5E77C-C3ED-4AEA-80BB-0235545B5238Q34610897-8C393B4D-41F2-41D6-A8A0-75CC60F33B2BQ37146704-9183848A-A019-47EA-8136-9085E7D959EBQ38180601-3700BECB-B4F2-483A-8121-65D450B771E3Q38194138-C7B35ED9-072D-447F-B6F9-DCE3F957F5F5Q38246910-D96095AB-BED1-4ED4-8198-4C55B11175D8Q38280549-EB3C54A2-CB83-4A0D-8229-4D4156E18CE6Q38917334-7A2E00C1-8084-4C53-BB6A-6F9B8049D2CDQ39094574-4281B615-8E42-446D-94E7-4A33DC6A6791Q39460538-5E6E19E8-B27D-4F13-87F2-B527866B2380Q42122972-B7F5B1ED-F2E5-4F3F-B275-32710056077DQ42161092-B7ADF888-794B-4820-B40D-F1E9830C6713Q42503600-D4DB6BF4-D302-4448-9CA5-9A71656405FCQ42557303-AFDDFB29-980F-4AC7-8ECA-B5E163043EBFQ42594061-E725676E-C2AB-4891-8104-2B9BAD14EE20Q42648060-C2254AD9-1DBF-40F1-86FD-A5B30296BAF4Q42690861-0A119437-AA82-4A0F-8E16-6130CBDE9BB6Q42774104-DE2998C7-FA21-44E5-B318-E4BE72EBC9FBQ44016142-DE8C4632-FE51-4E43-A233-9AE16912A885Q47323375-D02F3C6C-3288-4A17-B685-F4D4ABF4B253Q47400913-2994CA48-E656-46C1-88A5-E69FAC26ED7DQ47647347-F1FC344A-9D83-4643-8B91-6F8AFD75094AQ48312336-A35A8106-B9FC-4130-BFBD-5906B7DEB4C5Q50907134-6C2EE9CC-F041-400D-9647-3AF6970CDA94Q51355927-AECA91BE-08DA-4685-BC1D-2290C6DBE415Q54626815-8D34CF92-67B9-4131-B575-2D52ABEE056DQ55028398-A3C0F9EF-C0B1-435C-B8EA-17A51838563BQ55041647-0401F2A1-3F1D-4EB5-8DB4-6AF91E929506Q57907470-EE42359F-1A86-40CA-AA31-7E444305A6A2Q58212616-1335B9A6-0E03-4F23-AFC3-5F98B07DC94CQ58212639-2D3F0F13-8B5B-4EDF-8AE9-49498E21EEFDQ58698083-D1597EF3-8E7B-4629-AAE1-975AB9C7622A
P2860
description
article científic
@ca
article scientifique
@fr
articolo scientifico
@it
artigo científico
@pt
bilimsel makale
@tr
scientific article published on 04 March 2011
@en
vedecký článok
@sk
vetenskaplig artikel
@sv
videnskabelig artikel
@da
vědecký článek
@cs
name
De novo designed peptides for biological applications.
@en
De novo designed peptides for biological applications.
@nl
type
label
De novo designed peptides for biological applications.
@en
De novo designed peptides for biological applications.
@nl
prefLabel
De novo designed peptides for biological applications.
@en
De novo designed peptides for biological applications.
@nl
P2860
P356
P1476
De novo designed peptides for biological applications
@en
P2093
Aimee L Boyle
Derek N Woolfson
P2860
P304
P356
10.1039/C0CS00152J
P577
2011-03-04T00:00:00Z