Protein folding remains a fundamental challenge in molecular biology, particularly in understanding how polypeptide chains transition from denatured states to their functional conformations. Here we analyze the folding mechanisms of the engineered metamorphic proteins B4 and Sb3, which share highly similar sequences but adopt distinct topologies. Kinetic analyses revealed that B4 follows a two-state folding mechanism, whereas Sb3 involves the formation of an intermediate species. We further explore the role of topology in folding commitment using the metamorphic mutant Sb4, which can populate both conformations. By analyzing folding and unfolding behaviors under varying experimental conditions, our findings suggest that topology dictates folding mechanisms at an early stage. These results demonstrate that folding landscapes are primarily shaped by final native structures rather than sequence composition.
Topological determinants in protein folding dynamics: a comparative analysis of metamorphic proteins / Toso, Julian; Pennacchietti, Valeria; Di Felice, Mariana; Ventura, Eduarda S.; Toto, Angelo; Gianni, Stefano. - In: BIOLOGY DIRECT. - ISSN 1745-6150. - 20:1(2025). [10.1186/s13062-025-00642-x]
Topological determinants in protein folding dynamics: a comparative analysis of metamorphic proteins
Toso, Julian;Pennacchietti, Valeria;Di Felice, Mariana;Toto, Angelo;Gianni, Stefano
2025
Abstract
Protein folding remains a fundamental challenge in molecular biology, particularly in understanding how polypeptide chains transition from denatured states to their functional conformations. Here we analyze the folding mechanisms of the engineered metamorphic proteins B4 and Sb3, which share highly similar sequences but adopt distinct topologies. Kinetic analyses revealed that B4 follows a two-state folding mechanism, whereas Sb3 involves the formation of an intermediate species. We further explore the role of topology in folding commitment using the metamorphic mutant Sb4, which can populate both conformations. By analyzing folding and unfolding behaviors under varying experimental conditions, our findings suggest that topology dictates folding mechanisms at an early stage. These results demonstrate that folding landscapes are primarily shaped by final native structures rather than sequence composition.| File | Dimensione | Formato | |
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