A Computational Framework for Interacting with Physical Molecular Models of the Polypeptide Chain

Chakraborty, Promita

08 May 2014

Although nonflexible, scaled molecular models like Pauling-Corey's and its descendants have made significant contributions in structural biology research and pedagogy, recent technical advances in 3D printing and electronics make it possible to go one step further in designing physical models of biomacromolecules: to make them conformationally dynamic. We report the design, construction, and validation of a flexible, scaled, physical model of the polypeptide chain, which accurately reproduces the bond rotational degrees-of-freedom in the peptide backbone. The coarse-grained backbone model consists of repeating amide and alpha-carbon units, connected by mechanical bonds (corresponding to phi and psi angles) that include realistic barriers to rotation that closely approximate those found at the molecular scale. Longer-range hydrogen-bonding interactions are also incorporated, allowing the chain to easily fold into stable secondary structures. This physical model can serve as the basis for linking tangible bio-macromolecular models directly to the vast array of existing computational tools to provide an enhanced and interactive human-computer interface. We have explored the boundaries of this direction at the interface of computational tools and physical models of biological macromolecules at the nano-scale. Using a CAD-biocomputational framework, we have provided a methodology to design and build physical protein models focusing on shape and dynamics. We have also developed a workflow and an interface implemented for such bio-modeling tools. This physical-digital interface paradigm, at the intersection of native state proteins (P), computational models (C) and physical models (P), provides new opportunities for building an interactive computational modeling tool for protein folding and drug design. Furthermore, this model is easily constructed with readily obtainable parts and promises to be a tremendous educational aid to the intuitive understanding of chain folding as the basis for macromolecular structure. / Ph. D.

Physical models

polypeptides

Ramachandran plot

3D-printing

molecular model

protein folding

structural biology

biochemistry education

physical-digital interface

macromolecule

Peppytide

Studium konformačního chování krátkých peptidových fragmentů metodami kvantové chemie / Conformational Behaviour of Small Peptide Fragments Studied by the Quantum Chemical Methods

Kalvoda, Tadeáš

January 2020

To what extent conformational preference of short peptide sequences within proteins determine their three-dimensional structure? Large-scale quantum chemical calculations coupled with modern solvation methods represent unique set of tools to elucidate key determinants of the biomolecular structure ab initio. Full conformational sampling was performed on model systems representing short peptide fragments. The computed data reveal some of the underlying physico-chemical principles determining the spatial structure of proteins, and provide very important data for finding and tuning the optimal algorithm that may provide a full coverage of (ideally all) low-energy conformers. Keywords: Conformational space, peptide fragments, protein structure, solvation methods, Ramachandran plot, DFT-D3 methods