Ultrasmall Gold Nanoparticles as Clients of Biomolecular Condensates.

Liquid-liquid phase separation (LLPS) of biopolymers to form condensates is a widespread phenomenon in living cells. Agents that target or alter condensation can help uncover elusive physiological and pathological mechanisms. Owing to their unique material properties and modes of interaction with biomolecules, nanoparticles represent attractive condensate-targeting agents. Our work focused on elucidating the interaction between ultrasmall gold nanoparticles (usGNPs) and diverse types of condensates of tau, a representative phase-separating protein associated with neurodegenerative disorders. usGNPs attract considerable interest in the biomedical community due to unique features, including emergent optical properties and good cell penetration. We explored the interaction of usGNPs with reconstituted self-condensates of tau, two-component tau/polyanion and three-component tau/RNA/alpha-synuclein coacervates. The usGNPs were found to concentrate into condensed liquid droplets, consistent with the formation of dynamic client (nanoparticle) - scaffold (tau) interactions, and were observable thanks to their intrinsic luminescence. Furthermore, usGNPs were capable to promote LLPS of a protein domain which is unable to phase separate on its own. Our study demonstrates the ability of usGNPs to interact with and illuminate protein condensates. We anticipate that nanoparticles will have broad applicability as nanotracers to interrogate phase separation, and as nanoactuators controlling the formation and dissolution of condensates.

Biochemical and Bioinformatic Studies of Mutations of Residues at the Monomer-Monomer Interface of Human Ornithine Aminotransferase Leading to Gyrate Atrophy of Choroid and Retina.

Deficit of human ornithine aminotransferase (hOAT), a mitochondrial tetrameric pyridoxal-5'-phosphate (PLP) enzyme, leads to gyrate atrophy of the choroid and retina (GA). Although 70 pathogenic mutations have been identified, only few enzymatic phenotypes are known. Here, we report biochemical and bioinformatic analyses of the G51D, G121D, R154L, Y158S, T181M, and P199Q pathogenic variants involving residues located at the monomer-monomer interface. All mutations cause a shift toward a dimeric structure, and changes in tertiary structure, thermal stability, and PLP microenvironment. The impact on these features is less pronounced for the mutations of Gly51 and Gly121 mapping to the N-terminal segment of the enzyme than those of Arg154, Tyr158, Thr181, and Pro199 belonging to the large domain. These data, together with the predicted ΔΔG values of monomer-monomer binding for the variants, suggest that the proper monomer-monomer interactions seem to be correlated with the thermal stability, the PLP binding site and the tetrameric structure of hOAT. The different impact of these mutations on the catalytic activity was also reported and discussed on the basis of the computational information. Together, these results allow the identification of the molecular defects of these variants, thus extending the knowledge of enzymatic phenotypes of GA patients.

Site-directed double monoubiquitination of the repeat domain of the amyloid-forming protein tau impairs self-assembly and coacervation.

In Alzheimer's disease and related disorders called tauopathies, the microtubule-associated protein tau accumulates in the brain in the form of amyloid-like supramolecular filaments. As an intrinsically disordered protein, tau undergoes many post-translational modifications, including ubiquitination. Alterations to the levels of ubiquitination of tau have been observed at various stages of neurodegenerative conditions. We focus on proteoform-specific interrogations to obtain mechanistic insight into the effects of ubiquitination on disease-related conformational transitions of tau. Single and double ubiquitination of tau at residues Lys311 and Lys317 is strongly associated with pathological conditions. In this study, we leveraged disulfide-directed chemistry to install ubiquitin at one or both of those positions in the isolated microtubule-binding repeat domain of tau. We obtained homogeneously modified tau proteins and observed that they retained disordered character in solution. We found that ubiquitination in position 317 (with or without ubiquitination in position 311) impaired the formation of ordered fibrillar structures via oligomeric intermediates. Since the transition to fibrillar species may proceed via an alternative condensation pathway involving liquid droplet intermediates, we further tested the ability of the ubiquitinated proteoforms to phase separate. Single monoubiquitinated tau species were able to coacervate, however no liquid droplets were observed for the double ubiquitinated form. Taken together, the data indicate that double ubiquitination in the third repeat of tau disfavors the formation of amyloid aggregates by distinct mechanisms, suggesting that the presence of ubiquitinated residues 311 and 317 in insoluble tau may result from modifications in advanced stages of aggregation. These findings contribute to our understanding of the influence of site-specific ubiquitination on the pathological conformational transitions of a prototypical intrinsically disordered protein.