Molecular Dynamics Simulations Use Atomistic Force Field to Capture RNA Folding with High Accuracy

Molecular dynamics simulations use atomistic force field to capture RNA folding with high accuracy

Ribonucleic acid (RNA) is one of life's most versatile molecules, with roles going far beyond being a messenger of genetic code, as it is fundamentally involved in gene regulation, processing, and maintenance across all living systems. This versatility is deeply tied to RNA's ability to adopt complex three-dimensional shapes, known as secondary and tertiary structures.

Cutting-Edge Molecular Dynamics Simulations Achieve Remarkable Precision in

Ribonucleic acid, more commonly known as RNA, has emerged as a molecular superstar in the world of biology, far surpassing its traditional role as a mere courier of genetic instructions. Its ability to fold into intricate three-dimensional forms underpins a diverse array of biological functions, from gene regulation to maintaining cellular homeostasis. This structural versatility has propelled RNA to the forefront of biotechnology and therapeuti…