Mimicking Molecular Chaperones to Regulate Protein Folding.

Folding and unfolding are essential ways for a protein to regulate its biological activity. The misfolding of proteins usually reduces or completely compromises their biological functions, which eventually causes a wide range of diseases including neurodegeneration diseases, type II diabetes, and cancers. Therefore, materials that can regulate protein folding and maintain proteostasis are of significant biological and medical importance. In living organisms, molecular chaperones are a family of proteins that maintain proteostasis by interacting with, stabilizing, and repairing various non-native proteins. In the past few decades, efforts have been made to create artificial systems to mimic the structure and biological functions of nature chaperonins. Herein, recent progress in the design and construction of materials that mimic different kinds of natural molecular chaperones is summarized. The fabrication methods, construction rules, and working mechanisms of these artificial chaperone systems are described. The application of these materials in enhancing the thermal stability of proteins, assisting de novo folding of proteins, and preventing formation of toxic protein aggregates is also highlighted and explored. Finally, the challenges and potential in the field of chaperone-mimetic materials are discussed.

Synthetic Nanochaperones Facilitate Refolding of Denatured Proteins.

The folding process of a protein is inherently error-prone, owing to the large number of possible conformations that a protein chain can adopt. Partially folded or misfolded proteins typically expose hydrophobic surfaces and tend to form dysfunctional protein aggregates. Therefore, materials that can stabilize unfolded proteins and then efficiently assist them refolding to its bioactive form are of significant interest. Inspired by natural chaperonins, we have synthesized a series of polymeric nanochaperones that can facilitate the refolding of denatured proteins with a high recovery efficiency (up to 97%). Such nanochaperones possess phase-separated structure with hydrophobic microdomains on the surface. This structure allows nanochaperones to stabilize denatured proteins by binding them to the hydrophobic microdomains. We have also investigated the mechanism by which nanochaperones assist the protein refolding and established the design principles of nanochaperones in order to achieve effective recovery of a certain protein from their denatured forms. With a carefully designed composition of the microdomains according to the surface properties of the client proteins, the binding affinity between the hydrophobic microdomain and the denatured protein molecules can be tuned precisely, which enables the self-sorting of the polypeptides and the refolding of the proteins into their bioactive states. This work provides a feasible and effective strategy to recover inclusion bodies to their bioactive forms, which has potential to reduce the cost of the manufacture of recombinant proteins significantly.

Deciphering the Multisite Interactions of a Protein and Its Ligand at Atomic Resolution by Using Sensitive Paramagnetic Effects.

Quantitative analysis of multisite interactions between a protein and its binding partner at atomic resolution is complicated because locating the binding sites is difficult and differentiating the flexibility of each binding site is even more elusive. Introduction of a paramagnetic metal center close to the binding pocket greatly attenuates the signals in the NMR spectrum upon binding. Herein, the multisite binding of hen egg white lysozyme (HEWL) with lanthanide complexes [Ln(DPA)3 ]3- (DPA=dipicolinic acid) was analyzed with sensitive paramagnetic NMR spectroscopy. Paramagnetic relaxation enhancement (PRE) revealed that HEWL interacts with [Ln(DPA)3 ]3- at four major binding sites in aqueous solution, which is in contrast to a previous X-ray structural analysis. The varied binding affinities for the ligands and different flexibilities at each binding site were in good agreement with atomistic molecular dynamics (MD) simulations. The present work demonstrates that a combination of paramagnetic NMR spectroscopy and MD simulations is a powerful tool to delineate the multisite interactions of a protein with its binding partner at atomic resolution, in terms of both affinity and flexibility.

Kinetic assay of the Michael addition-like thiol-ene reaction and insight into protein bioconjugation.

The chemical modification of proteins is a valuable technique in understanding the functions, interactions, and dynamics of proteins. Reactivity and selectivity are key issues in current chemical modification of proteins. The Michael addition-like thiol-ene reaction is a useful tool that can be used to tag proteins with high selectivity for the solvent-exposed thiol groups of proteins. To obtain insight into the bioconjugation of proteins with this method, a kinetic analysis was performed. New vinyl-substituted pyridine derivatives were designed and synthesized. The reactivity of these vinyl tags with L-cysteine was evaluated by UV absorption and high-resolution NMR spectroscopy. The results show that protonation of pyridine plays a key role in the overall reaction rates. The kinetic parameters were assessed in protein modification. The different reactivities of these vinyl tags with solvent-exposed cysteine is valuable information in the selective labeling of proteins with multiple functional groups.