Hydrophobic Hydration of a Single Polymer

• Main Author: Li, Isaac Tian Shi
• Other Authors: Walker, Gilbert C.
• Language: en_ca
• Published: 2012
• Subjects: single molecule force spectroscopy; atomic force microscopy; hydrophobicity; hydrophobic hydration; hydrophobic collapse; protein folding; polymer model; 0494; 0495
• Online Access: http://hdl.handle.net/1807/34783

Hydrophobic interactions guide important molecular self-assembly processes such as protein folding. On the macroscale, hydrophobic interactions consist of the aggregation of "oil-like" objects in water by minimizing the interfacial energy. However, the hydration mechanism of small hydrophobic molecules on the nanoscale (~1 nm) differs fundamentally from its macroscopic counterpart. Theoretical studies over the last two decades have pointed to an intricate dependence of molecular hydration mechanisms on the length scale. The microscopic-to-macroscopic cross-over length scale is critically important to hydrophobic interactions in polymers, proteins and other macromolecules. Accurate experimental determination of hydration mechanisms and their interaction strengths are needed to understand protein folding. This thesis reports the development of experimental and analytical techniques that allow for direct measurements of hydrophobic interactions in a single molecule. Using single molecule force spectroscopy, the mechanical unfolding of a single hydrophobic homopolymer was identified and modeled. Two experiments examined how hydrophobicity at the molecular scale differ from the macroscopic scale. The first experiment identifies macroscopic interfacial tension as a critical parameter governing the molecular hydrophobic hydration strength. This experiment shows that the solvent conditions affect the microscopic and macroscopic hydrophobic strengths in similar ways, consistent with theoretical predictions. The second experiment probes the hydrophobic size effect by studying how the size of a non-polar side-chain affects the thermal signatures of hydration. Our experimental results reveal a cross-over length scale of approximately 1 nm that bridges the transition from entropically driven microscopic hydration mechanism to enthalpically driven macroscopic hydration mechanism. These results indicate that hydrophobic interactions at the molecular scale differ from macroscopic scale, pointing to potential ways to improve our understanding and predictions of molecular interactions. The system established in this thesis forms the foundation for further investigation of polymer hydrophobicity.