Scientific Reports (Apr 2021)

HyperBeta: characterizing the structural dynamics of proteins and self-assembling peptides

  • Marco S. Nobile,
  • Federico Fontana,
  • Luca Manzoni,
  • Paolo Cazzaniga,
  • Giancarlo Mauri,
  • Gloria A. A. Saracino,
  • Daniela Besozzi,
  • Fabrizio Gelain

DOI
https://doi.org/10.1038/s41598-021-87087-0
Journal volume & issue
Vol. 11, no. 1
pp. 1 – 10

Abstract

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Abstract Self-assembling processes are ubiquitous phenomena that drive the organization and the hierarchical formation of complex molecular systems. The investigation of assembling dynamics, emerging from the interactions among biomolecules like amino-acids and polypeptides, is fundamental to determine how a mixture of simple objects can yield a complex structure at the nano-scale level. In this paper we present HyperBeta, a novel open-source software that exploits an innovative algorithm based on hyper-graphs to efficiently identify and graphically represent the dynamics of $$\beta$$ β -sheets formation. Differently from the existing tools, HyperBeta directly manipulates data generated by means of coarse-grained molecular dynamics simulation tools (GROMACS), performed using the MARTINI force field. Coarse-grained molecular structures are visualized using HyperBeta ’s proprietary real-time high-quality 3D engine, which provides a plethora of analysis tools and statistical information, controlled by means of an intuitive event-based graphical user interface. The high-quality renderer relies on a variety of visual cues to improve the readability and interpretability of distance and depth relationships between peptides. We show that HyperBeta is able to track the $$\beta$$ β -sheets formation in coarse-grained molecular dynamics simulations, and provides a completely new and efficient mean for the investigation of the kinetics of these nano-structures. HyperBeta will therefore facilitate biotechnological and medical research where these structural elements play a crucial role, such as the development of novel high-performance biomaterials in tissue engineering, or a better comprehension of the molecular mechanisms at the basis of complex pathologies like Alzheimer’s disease.