Oleic amide derivatives as small molecule stimulators of the human proteasome's core particle.

A series of oleic acid amide derivatives were synthesized based on our previous and continuing endeavors towards stimulation of the 20S core particle of the proteasome (20S CP) with the goal of increasing the protein degradation rate via the ubiquitin-independent pathway. The designed compounds were tested in a variety of biochemical and cell-based assays to assess their ability to increase the rate of hydrolysis of the 20S CP, and compared to a known fatty acid amide stimulator of the 20S CP, AM-404. AM-404 was previously described to stimulate the activity of the 20S CP, however, it does negatively affect viability of cells after prolonged dosing. Here we report the development of several small molecules with a similar ability to enhance the activity of the 20S CP as AM-404. While one molecule (17) was just as potent as AM-404, it still caused significant unwanted cytotoxicity. Molecules such as these are compatible with biochemical assays and short-term cell-based proteasome activity assays, but their unwanted toxicity limits their use in prolonged cell assays or in vivo studies.

Synthesis and Application of a Clickable Epoxomicin-Based Probe for Proteasome Activity Analysis.

The proteasome is a multisubunit protein complex responsible for the degradation of proteins, making it essential in myriad cellular processes. Several reversible and irreversible peptide substrates inspired by known proteasome inhibitors have been developed to visualize it and monitor its activity; however, they have limited commercial availability or possess fluorophores that overlap with other known chemical probes, limiting their simultaneous use. The protocols presented here describe the synthesis of a clickable epoxomicin-based probe followed by the copper-catalyzed installment of an azide-containing fluorophore, and the application of the synthesized peptide in proteasome activity assays by SDS-PAGE and flow cytometry. © 2022 The Authors. Current Protocols published by Wiley Periodicals LLC. Basic Protocol 1: Solid-phase synthesis of clickable peptide fragment (2) Basic Protocol 2: In-solution coupling of epoxy-ketone moiety to fragment (2) Basic Protocol 3: Copper-catalyzed click reaction of (3) with fluorophore of choice Basic Protocol 4: Monitoring proteasome activity by SDS-PAGE in HEK-293T cells Alternate Protocol: Monitoring proteasome activity by flow cytometry in HEK-293T cells.

Solid-Phase Synthesis and Application of a Clickable Version of Epoxomicin for Proteasome Activity Analysis.

Degradation of proteins by the proteasome is an essential cellular process and one that many wish to study in a variety of disease types. There are commercially available probes that can monitor proteasome activity in cells, but they typically contain common fluorophores that limit their simultaneous use with other activity-based probes. In order to exchange the fluorophore or incorporate an enrichment tag, the proteasome probe likely has to be synthesized which can be cumbersome. Here, we describe a simple synthetic procedure that only requires one purification step to generate epoxomicin, a selective proteasome inhibitor, with a terminal alkyne. Through a copper-catalyzed cycloaddition, any moiety containing an azide can be incorporated into the probe. Many fluorophores are commercially available that contain an azide that can be "clicked", allowing this proteasome activity probe to be included into already established assays to monitor both proteasome activity and other cellular activities of interest.

Dual-purpose isocyanides produced by Aspergillus fumigatus contribute to cellular copper sufficiency and exhibit antimicrobial activity.

The maintenance of sufficient but nontoxic pools of metal micronutrients is accomplished through diverse homeostasis mechanisms in fungi. Siderophores play a well established role for iron homeostasis; however, no copper-binding analogs have been found in fungi. Here we demonstrate that, in Aspergillus fumigatus, xanthocillin and other isocyanides derived from the xan biosynthetic gene cluster (BGC) bind copper, impact cellular copper content, and have significant metal-dependent antimicrobial properties. xan BGC-derived isocyanides are secreted and bind copper as visualized by a chrome azurol S (CAS) assay, and inductively coupled plasma mass spectrometry analysis of A. fumigatus intracellular copper pools demonstrated a role for xan cluster metabolites in the accumulation of copper. A. fumigatus coculture with a variety of human pathogenic fungi and bacteria established copper-dependent antimicrobial properties of xan BGC metabolites, including inhibition of laccase activity. Remediation of xanthocillin-treated Pseudomonas aeruginosa growth by copper supported the copper-chelating properties of xan BGC isocyanide products. The existence of the xan BGC in several filamentous fungi suggests a heretofore unknown role of eukaryotic natural products in copper homeostasis and mediation of interactions with competing microbes.

Cytotoxic Oligomers and Fibrils Trapped in a Gel-like State of α-Synuclein Assemblies.

α-Synuclein (α-Syn) aggregation is associated with Parkinson's disease (PD) pathogenesis. In PD, the role of oligomers versus fibrils in neuronal cell death is debatable, but recent studies suggest oligomers are a proximate neurotoxin. Herein, we show that soluble α-Syn monomers undergo a transformation from a solution to a gel state on incubation at high concentration. Detailed characterization of the gel showed the coexistence of monomers, oligomers, and short fibrils. In vitro, the gel was highly cytotoxic to human neuroblastoma cells. The individual constituents of the gel are short-lived species but toxic to the cells. They comprise a structurally heterogeneous population of α-helical and ß-sheet-rich oligomers and short fibrils with the cross-ß motif. Given the recent evidence of the gel-like state of the protein associated with neurodegenerative diseases, the gel state of α-Syn in this study represents a mechanistic and structural model for the in vivo toxicity of α-Syn in PD.