6533b827fe1ef96bd128676b

RESEARCH PRODUCT

Chain Stiffness of Elastin-Like Polypeptides

Sabine FluegelManfred SchmidtKarl FischerJonathan R. McdanielAshutosh Chilkoti

subject

chemistry.chemical_classificationMolar massHydrodynamic radiusPolymers and PlasticsbiologyDispersityBioengineeringPeptideArticleElastinMolecular WeightBiomaterialsDynamic light scatteringChain (algebraic topology)chemistryPolymer chemistryHydrodynamicsMaterials ChemistryBiophysicsbiology.proteinElectrophoresis Polyacrylamide GelPeptidesElastinRepeat unit

description

The hydrodynamic radii of a series of genetically engineered monodisperse elastin like polypeptides (ELP) was determined by dynamic light scattering in aqueous solution as function of molar mass. Utilizing the known theoretical expression for the hydrodynamic radius of wormlike chains, the Kuhn statistical segment length was determined to be lk = 2.1 nm, assuming that the length of the peptide repeat unit was b = 0.365 nm, a value derived for a coiled conformation of ELP. The resulting chain stiffness is significantly larger than previously reported by force-distance curve analysis (lk < 0.4 nm). The possible occurrence of superstructures, such as hairpins or helices, would reduce the contour length of the ELP, further increasing lk. Accordingly, the value lk = 2.1 nm reported here represents a lower limit of the chain stiffness for ELP.

yearjournalcountryeditionlanguage
2010-10-20Biomacromolecules
https://doi.org/10.1021/bm100965y