The critical role of the variable domain in driving proteotoxicity and aggregation in full-length light chains.

Light chain (AL) amyloidosis is the most common systemic amyloid disease characterized by abnormal accumulation of amyloid fibrils derived from immunoglobulin light chains (LCs). Both full-length (FL) LCs and their isolated variable (VL) and constant (CL) domains contribute to amyloid deposits in multiple organs, with the VL domain predominantly forming the fibril core. However, the role and interplay of these domains in amyloid aggregation and toxicity are poorly understood.

The folding and misfolding of multidomain proteins.

Protein folding represents a vital process for any living organism. While significant insights have been gained from studying single-domain proteins, our current knowledge on the folding mechanisms of multidomain proteins remains relatively limited, primarily due to their inherent complexity. The principal aim of this review lies in summarizing the emerging view pertaining multi-domain folding, emphasizing their modular nature, which minimizes misfolding and facilitates evolutionary innovation.

Estimation of Ligand Binding Free Energy Using Multi-eGO.

The computational study of ligand binding to a target protein provides mechanistic insight into the molecular determinants of this process and can improve the success rate of drug design. All-atom molecular dynamics (MD) simulations can be used to evaluate the binding free energy, typically by thermodynamic integration, and to probe binding mechanisms, including the description of protein conformational dynamics. The advantages of MD come at a high computational cost, which limits its use.

A PDZ tandem repeat folds and unfolds via different pathways.

Protein folding and unfolding experiments are interpreted under the assumption of microscopic reversibility, that is, that at equilibrium one process is the reverse of the other. Single-domain proteins illustrate the validity of such an interpretation, although reversibility does not necessarily hold under the different conditions typically used for folding and unfolding experiments. In fact, more complex proteins, which often exhibit irreversible unfolding, are generally considered not amenable to folding kinetics studies.

Folding and Binding Kinetics of the Tandem of SH2 Domains from SHP2.

The SH2 domains of SHP2 play a crucial role in determining the function of the SHP2 protein. While the folding and binding properties of the isolated NSH2 and CSH2 domains have been extensively studied, there is limited information about the tandem SH2 domains. This study aims to elucidate the folding and binding kinetics of the NSH2-CSH2 tandem domains of SHP2 through rapid kinetic experiments, complementing existing data on the isolated domains.