Age of diabetes onset in the mutant proinsulin syndrome correlates with mutational impairment of protein foldability and stability

Diverse heterozygous mutations in the human insulin gene cause a monogenic diabetes mellitus (DM) syndrome due to toxic misfolding of the variant proinsulin. Whereas mutations that add or remove cysteines (thereby leading to an odd number of thiol groups) generally lead to neonatal-onset DM, non-Cys-related mutations can be associated with a broad range of ages of onset. Here, we compare two mutations at a conserved position in the central B-chain α-helix: one neonatal in DM onset (ValB18→Gly) and the other with onset delayed until adolescence (AlaB18). The substitutions were introduced within a 49-residue single-chain insulin precursor optimized for folding efficiency (Zaykov, A., et al. ACS Chem. Biol. 9, 683-91 (2014)). Although mutations are each unfavorable, GlyB18 (a) more markedly perturbs DesDi folding efficiency in vitro than does AlaB18 and (b) more severely induces endoplasmic reticulum (ER) stress in cell-based studies of the respective proinsulin variants. In corresponding two-chain hormone analogs, GlyB18 more markedly perturbs structure, function and thermodynamic stability than does AlaB18. Indeed, the GlyB18-insulin analog forms a molten globule with attenuated α-helix content whereas the AlaA18 analog retains a nativelike cooperative structure with reduced free energy of unfolding (ΔΔGu 1.2(±0.2) kcal/mole relative to ValB18 parent). We propose that mutations at B18 variably impede nascent pairing of CysB19 and CysA20 to an extent correlated with perturbed core packing once native disulfide pairing is achieved. Differences in age of disease onset (neonatal or adolescent) reflect relative biophysical perturbations (severe or mild) of an obligatory on-pathway protein folding intermediate.

Socket2: A Program for Locating, Visualising, and Analysing Coiled-coil Interfaces in Protein Structures

Motivation Protein-protein interactions are central to all biological processes. One frequently observed mode of such interactions is the α-helical coiled coil (CC). Thus, an ability to extract, visualise, and analyse CC interfaces quickly and without expert guidance would facilitate a wide range of biological research. In 2001, we reported Socket, which locates and characterises CCs in protein structures based on the knobs-into-holes (KIH) packing between helices in CCs. Since then, studies of natural and de novo designed CCs have boomed, and the number of CCs in the RCSB PDB has increased rapidly. Therefore, we have updated Socket and made it accessible to expert and non-expert users alike. Results The original Socket only classified CCs with up to 6 helices. Here, we report Socket2, which rectifies this oversight to identify CCs with any number of helices, and KIH interfaces with any of the 20 proteinogenic residues or incorporating non-natural amino acids. In addition, we have developed a new and easy-to-use web server with additional features. These include the use of NGL Viewer for instantly visualising CCs, and tabs for viewing the sequence repeats, helix-packing angles, and core-packing geometries of CCs identified and calculated by Socket2. Availability and implementation Socket2 has been tested on all modern browsers. It can be accessed freely at http://coiledcoils.chm.bris.ac.uk/socket2/home.html. The source code is distributed using an MIT license and available to download under the Downloads tab of the Socket2 home page.

Molecular dynamics simulations suggest stabilizing mutations in a de novo designed α/β protein

Designing functional proteins that can withstand extreme heat is beneficial for industrial and protein therapeutic applications. Thus, elucidating the atomic-level determinants of thermostability is a major interest for rational protein design. To that end, we compared the structure and dynamics of a set of previously designed, thermostable proteins based on the activation domain of human procarboxypeptidase A2 (AYEwt). The mutations in these designed proteins were intended to increase hydrophobic core packing and inter-secondary-structure interactions. To evaluate whether these design strategies were successfully deployed, we performed all-atom, explicit-solvent molecular dynamics (MD) simulations of AYEwt and three designed variants at both 25 and 100°C. Our MD simulations agreed with the relative experimental stabilities of the designs based on their secondary structure content, Cα root-mean-square deviation/fluctuation, and buried-residue solvent accessible surface area. Using a contact analysis, we found that the designs stabilize inter-secondary structure interactions and buried hydrophobic surface area, as intended. Based on our analysis, we designed three additional variants to test the role of helix stabilization, core packing, and a Phe → Met mutation on thermostability. We performed the additional MD simulations and analysis on these variants, and these data supported our predictions.

Structural Determinants of Coiled Coil Mechanics

The natural abundance of coiled coil (CC) motifs in the cytoskeleton and the extracellular matrix suggests that CCs play a crucial role in the bidirectional mechanobiochemical signaling between cells and the matrix. Their functional importance and structural simplicity has allowed the development of numerous applications, such as protein-origami structures, drug delivery systems and biomaterials. With the goal of establishing CCs as nanomechanical building blocks, we investigated the importance of helix propensity and hydrophobic core packing on the mechanical stability of 4-heptad CC heterodimers. Using single-molecule force spectroscopy, we show that both parameters determine the force-induced dissociation in shear loading geometry; however, with different effects on the energy landscape. Decreasing the helix propensity lowers the transition barrier height, leading to a concomitant decrease in the distance to the transition state. In contrast, a less tightly packed hydrophobic core increases the distance to the transition state. We propose that this sequence-structure-mechanics relationship is evolutionarily optimized in natural CCs and can be used for tuning their mechanical properties in applications.

Structure of phosphorylated UBL domain and insights into PINK1-orchestrated parkin activation

Mutations in PARK2 and PARK6 genes are responsible for the majority of hereditary Parkinson’s disease cases. These genes encode the E3 ubiquitin ligase parkin and the protein kinase PTEN-induced kinase 1 (PINK1), respectively. Together, parkin and PINK1 regulate the mitophagy pathway, which recycles damaged mitochondria following oxidative stress. Native parkin is inactive and exists in an autoinhibited state mediated by its ubiquitin-like (UBL) domain. PINK1 phosphorylation of serine 65 in parkin’s UBL and serine 65 of ubiquitin fully activate ubiquitin ligase activity; however, a structural rationale for these observations is not clear. Here, we report the structure of the phosphorylated UBL domain from parkin. We find that destabilization of the UBL results from rearrangements to hydrophobic core packing that modify its structure. Altered surface electrostatics from the phosphoserine group disrupt its intramolecular association, resulting in poorer autoinhibition in phosphorylated parkin. Further, we show that phosphorylation of both the UBL domain and ubiquitin are required to activate parkin by releasing the UBL domain, forming an extended structure needed to facilitate E2–ubiquitin binding. Together, the results underscore the importance of parkin activation by the PINK1 phosphorylation signal and provide a structural picture of the unraveling of parkin’s ubiquitin ligase potential.