Engineering the kinetic stability of a β-trefoil protein by tuning its topological complexity.

Kinetic stability, defined as the rate of protein unfolding, is central to determining the functional lifetime of proteins, both in nature and in wide-ranging medical and biotechnological applications. Further, high kinetic stability is generally correlated with high resistance against chemical and thermal denaturation, as well as proteolytic degradation. Despite its significance, specific mechanisms governing kinetic stability remain largely unknown, and few studies address the rational design of kinetic stability.

Immature ALS-associated mutant superoxide dismutases form variable aggregate structures through distinct oligomerization processes.

Protein misfolding and aggregation are hallmarks of many diseases, including amyotrophic lateral sclerosis (ALS). In familial ALS, aberrant self-association of mutant Cu,Zn-superoxide dismutase (SOD1) is implicated as a key contributor to disease. Mutations have the largest impacts on the stability of the most immature form of SOD1, the unmetallated, disulfide-reduced monomer (apoSH SOD1).

Methodological advances and strategies for high resolution structure determination of cellular protein aggregates.

Aggregation of proteins is at the nexus of molecular processes crucial to aging, disease, and employing proteins for biotechnology and medical applications. There has been much recent progress in determining the structural features of protein aggregates that form in cells; yet, owing to prevalent heterogeneity in aggregation, many aspects remain obscure and often experimentally intractable to define. Here, we review recent results of structural studies for cell-derived aggregates of normally globular proteins, with a focus on high-resolution methods for their analysis and prediction.

A fine balance of hydrophobic-electrostatic communication pathways in a pH-switching protein.

Allostery is the phenomenon of coupling between distal binding sites in a protein. Such coupling is at the crux of protein function and regulation in a myriad of scenarios, yet determining the molecular mechanisms of coupling networks in proteins remains a major challenge. Here, we report mechanisms governing pH-dependent myristoyl switching in monomeric hisactophilin, whereby the myristoyl moves between a sequestered state, i.

Quenched hydrogen-deuterium amide exchange optimization for high-resolution structural analysis of cellular protein aggregates.

Inclusion bodies (IBs) are large, insoluble aggregates that often form during the overexpression of proteins in bacteria. These aggregates are of broad fundamental and practical significance, for recombinant protein preparation and due to their relevance to aggregation-related medical conditions and their recent emergence as promising functional nanomaterials. Despite their significance, high resolution knowledge of IB structure remains very limited.