Phosphorylation of a Cleaved Tau Proteoform at a Single Residue Inhibits Binding to the E3 Ubiquitin Ligase, CHIP.

Microtubule-associated protein tau (MAPT/tau) accumulates in a family of neurodegenerative diseases, including Alzheimer's disease (AD). In disease, tau is aberrantly modified by post-translational modifications (PTMs), including hyper-phosphorylation. However, it is often unclear which of these PTMs contribute to tau's accumulation or what mechanisms might be involved. To explore these questions, we focused on a cleaved proteoform of tau (tauC3), which selectively accumulates in AD and was recently shown to be degraded by its direct binding to the E3 ubiquitin ligase, CHIP. Here, we find that phosphorylation of tauC3 at a single residue, pS416, is sufficient to block its interaction with CHIP. A co-crystal structure of CHIP bound to the C-terminus of tauC3 revealed the mechanism of this clash and allowed design of a mutation (CHIPD134A) that partially restores binding and turnover of pS416 tauC3. We find that pS416 is produced by the known AD-associated kinase, MARK2/Par-1b, providing a potential link to disease. In further support of this idea, an antibody against pS416 co-localizes with tauC3 in degenerative neurons within the hippocampus of AD patients. Together, these studies suggest a discrete molecular mechanism for how phosphorylation at a specific site contributes to accumulation of an important tau proteoform.

Inhibiting a dynamic viral protease by targeting a non-catalytic cysteine.

Viruses are responsible for some of the most deadly human diseases, yet available vaccines and antivirals address only a fraction of the potential viral human pathogens. Here, we provide a methodology for managing human herpesvirus (HHV) infection by covalently inactivating the HHV maturational protease via a conserved, non-catalytic cysteine (C161). Using human cytomegalovirus protease (HCMV Pr) as a model, we screened a library of disulfides to identify molecules that tether to C161 and inhibit proteolysis, then elaborated hits into irreversible HCMV Pr inhibitors that exhibit broad-spectrum inhibition of other HHV Pr homologs. We further developed an optimized tool compound targeted toward HCMV Pr and used an integrative structural biology and biochemical approach to demonstrate inhibitor stabilization of HCMV Pr homodimerization, exploiting a conformational equilibrium to block proteolysis. Irreversible HCMV Pr inhibition disrupts HCMV infectivity in cells, providing proof of principle for targeting proteolysis via a non-catalytic cysteine to manage viral infection.

Site-Selective Protein Immobilization on Polymeric Supports through N-Terminal Imidazolidinone Formation.

Protein immobilization techniques on polymeric supports have enabled many applications in biotechnology and materials science. Attaching the proteins with controlled orientations has inherent advantages, but approaches for doing this have been largely limited to cysteine or noncanonical amino acid targeting. Herein, we report a method to attach the N-terminal positions of native proteins to polymer resins site-specifically through the use of 2-pyridinecarboxyaldehyde (2PCA) derivatives. For high protein loadings and practical synthesis, we initiated this work by preparing highly reactive 2PCA derivatives using Pd-catalyzed cross-coupling amination. The resulting compounds were attached to amine-containing polyethylene glycol acrylamide resin (PEGA-NH2), which subsequently reacted with the N-termini of proteins to produce linkages that were stable over the long term but could be reversed through the addition of hydroxylamine. We envision that this site-selective, 2PCA-based protein immobilization can provide a simple and generalizable immobilization protocol.

Effects of Conformational Changes in Peptide-CRM197 Conjugate Vaccines.

Conjugate vaccines prepared with the cross-reactive material 197 (CRM197) carrier protein have been successful in the clinic and are of great interest in the field of immunotherapy. One route to preparing peptide-CRM197 conjugate vaccines involves an activation-conjugation strategy, effectively coupling lysine residues on the protein to cysteine thiolate groups on the peptide of interest using a heterobifunctional linker as an activation agent. This method has been found to result in two distinct populations of conjugates, believed to be the result of a conformational change of CRM197 during preparation. This report explores the factors that lead to this conformational change, pointing to a model in which the unintentional alkylation of histidine-21 by the activating agent promotes the "opening" of the monomeric protein. This exposes a new set of lysine residues that are modified by additional activation agents. Subsequent peptide ligation to these sites results in the two conformers. This is the first time that a specific chemical modification is demonstrated to induce a defined conformational change for this carrier protein. Importantly, alternative conditions and reagents have been found to minimize this effect, improving the conformational homogeneity of peptide-CRM197 conjugates.