Monitoring the Immunoproteasome in Live Cells Using an Activity-Based Peptide-Peptoid Hybrid Probe.

Activity-based probes have greatly improved our understanding of the intrinsic roles and expression levels of various proteins within cells. To be useful in live cells, probes must be cell permeable and provide a read-out that can be measured without disrupting the cells or the activity of the target. Unfortunately, probes for the various forms of the proteasome that can be utilized in intact cells are limited; commercially available probes are most effectively used with purified protein or cell lysate. The proteasome, both the 26S and various isoforms of the 20S CP, is an important target with reported roles in cancer, autoimmune disorders, and neurodegenerative diseases. Here, we present the development of a selective probe for the immunoproteasome, a specialized isoform of the 20S proteasome, that becomes expressed in cells that encounter an inflammatory signal. Using a one-bead, one-compound library of small peptides, we discovered a trimer sequence efficiently cleaved by the immunoproteasome with significant selectivity over the standard proteasome. Upon conjugating this sequence to rhodamine 110 and a peptoid, we generated a probe with a considerable improvement in sensitivity compared to that of current aminomethylcoumarin-based proteasome probes. Importantly, our probe was capable of labeling immunoproteasome-expressing cells while maintaining its selectivity over other cellular proteases in live cell cultures. We anticipate this probe to find wide utility for those that wish to study the immunoproteasome's activity in a variety of cell lines and to be used as a reporter to discover small molecules that can perturb the activity of this proteasome isoform.

ReSPONDINg TACtically, degrading strategically.

Targeted protein degradation has become a popular strategy to expand the druggable proteome, but therapeutic options for membrane proteins are limited. Sun et al. have now developed R-spondin chimeras (ROTACs) that effectively mediate lysosomal degradation of PD-L1, thus providing a modular platform that may be applicable to other membrane proteins.

Advancing targeted protein degrader discovery by measuring cereblon engagement in cells.

Measurement of target engagement in cells is critical to understand the molecular pharmacology of drugs and chemical probes. Many targeted protein degraders engage the E3 ligase CRL4CRBN and induce proximity with target neosubstrates resulting in their polyubiquitination and subsequent proteasomal degradation. Here we describe the development of a sensitive and robust cellular NanoBRET-based assay that measures occupancy of the CRBN ligand binding site. The assay is based on a bioluminescence resonance energy transfer (BRET) between NanoLuc luciferase tagged CRBN and a BODIPY-lenalidomide tracer which can be competed out by CRBN ligands, including PROTACs and molecular glues. The assay is compatible with a 384-well plate setup, does not require transfections and can be performed in a single day with only 3-4h of laboratory time. The protocols can be used to design other NanoLuc fusion engagement assays based on BODIPY tracers.

Structural rationalization of GSPT1 and IKZF1 degradation by thalidomide molecular glue derivatives.

Thalidomide and its derivatives are molecular glues that bind cereblon (CRBN), a component of an E3 ubiquitin ligase complex, and mediate protein interactions with neosubstrates resulting in their polyubiquitination and proteasomal degradation. The structural features of neosubstrate binding have been elucidated that highlight key interactions with a ß-hairpin degron containing a glycine, which is present in a wide-range of proteins, including zinc-finger transcription factors such as IKZF1, and the translation termination factor GSPT1. Here, we profile 14 closely-related thalidomide derivatives in CRBN occupancy, and IKZF1 and GSPT1 degradation cell-based assays, and use crystal structures, computational docking and molecular dynamics to delineate subtle structure-activity relationships. Our findings will enable the rational design of CRBN modulators in the future, and help avoid the degradation of GSPT1 which is broadly cytotoxic.

Development of a covalent cereblon-based PROTAC employing a fluorosulfate warhead.

Many cereblon (CRBN) ligands have been used to develop proteolysis targeting chimeras (PROTACs), but all are reversible binders of the E3 ubiquitin ligase. We recently described the use of sulfonyl exchange chemistry to design binders that covalently engage histidine 353 in CRBN for the first time. Here we show that covalent CRBN ligands can be used to develop efficient PROTAC degraders. We demonstrate that the fluorosulfate PROTAC FS-ARV-825 covalently labels CRBN in vitro, and in cells the BRD4 degrader is insensitive to wash-out and competition by potent reversible CRBN ligands, reflecting enhanced pharmacodynamics. We anticipate that covalent CRBN-based PROTACs will enhance degradation efficiencies, thus expanding the scope of addressable targets using the heterobifunctional degrader modality.

HiBiT-SpyTag: A Minimal Tag for Covalent Protein Capture and Degrader Development.

The ability to rapidly and selectively modulate cellular protein levels using small molecules is essential for studying complex biological systems. Degradation tags, such as dTAG, allow for selective protein removal with a specific degrader molecule, but their utility is limited by the large tag size (>12 kDa) and the low efficiency of fusion product gene knock-in. Here, we describe the development of a short 24 amino acid peptide tag that enables cell-based quantification and covalent functionalization of proteins to which it is fused. The minimalistic peptide, termed HiBiT-SpyTag, incorporates the HiBiT peptide for protein level quantification and SpyTag, which forms a spontaneous isopeptide bond in the presence of the SpyCatcher protein. Transient expression of dTAG-SpyCatcher efficiently labels HiBiT-SpyTag-modified BRD4 or IRE1α in cells, and subsequent treatment with the dTAG13 degrader results in efficient protein removal without the need for full dTAG knock-in. We also demonstrate the utility of HiBiT-SpyTag for validating the degradation of the endoplasmic reticulum (ER) stress sensor IRE1α, which led to the development of the first PROTAC degrader of the protein. Our modular HiBiT-SpyTag system represents a valuable tool for the efficient development of degraders and for studying other proximity-induced pharmacology.

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.

Cereblon covalent modulation through structure-based design of histidine targeting chemical probes.

Electrophilic biocompatible warheads, particularly cysteine-reactive acrylamides, have enabled the development of covalent inhibitor drugs and chemical biology probes, but cysteine is rarely present in protein binding sites. Therefore, expansion of the list of targetable amino acid residues is required to augment the synthetic bology toolkit of site-selective protein modifications. This work describes the first rational targeting of a specific histidine residue in a protein binding site using sulfonyl exchange chemistry. Structure-based drug design was used to incorporate sulfonyl fluoride and triazole reactive groups into the isoindolinone thalidomide congener EM12 to yield potent covalent inhibitors of the cereblon E3 ubiquitin ligase complex through engagement of His353. Conversely, the fluorosulfate derivative EM12-FS labels His353, but degrades a novel neosubstrate, the protein N-terminal glutamine amidohydrolase NTAQ1, which is involved in the N-end rule pathway and DNA damage response. Targeted protein degradation using cereblon ligands has become an important new drug discovery modality and the chemical probes and covalent labeling strategy described here will broadly impact this exciting area of therapeutic research.

Identification of a covalent binder to the oncoprotein gankyrin using a NIR-Based OBOC screening method.

Despite huge advancements in the process of synthesizing small molecules as part of one-bead-one-compound (OBOC) libraries, progress lags in the ability to screen these libraries against proteins of interest. Recently, we developed a method to screen OBOC libraries in which a target protein is labeled with a near-infrared (NIR) range fluorophore. The labeled protein incubates with beads of a library in a 96-well plate, then the plate is imaged for fluorescence. Fluorescence intensities produced by the labeled protein binding the bead can be quantitated and provide a basis to rank hits. Here, we present an application of this technique by screening the oncoprotein gankyrin against a 343-member peptoid library. The library was composed of four positions occupied by one of seven amines. In the third position, an amine that facilitates covalent binding via a sulfonyl fluoride moiety was incorporated. After screening for gankyrin binders twice, ten structures showed overlap in the types of amines present at each position. These initial hits were validated with an in-gel fluorescence assay in which the labeled ligands covalently interacted with purified gankyrin. Excitingly, one peptoid was validated from this analysis. This hit was also shown to bind gankyrin in the presence of HEK 293T lysate. Results from this study demonstrate successful use of our screening method to quickly identify quality binders to a target protein of interest.

The Immunoproteasome: An Emerging Target in Cancer and Autoimmune and Neurological Disorders.

The immunoproteasome (iCP) is an isoform of the 20S proteasome that is expressed when cells are stressed or receive an inflammatory signal. The primary role of the iCP is to hydrolyze proteins into peptides that are compatible with being loaded into a MHC-I complex. When the activity of the iCP is dysregulated or highly expressed, it can lead to unwanted cell death. Some cancer types express the iCP rather than the standard proteasome, and selective inhibitors have been developed to exploit this difference. Here, we describe diseases known to be influenced by iCP activity and the current status for targeting the iCP to elicit a therapeutic response. We also describe a variety of chemical tools that have been developed to monitor the activity of the iCP in cells. Finally, we present the future outlook for targeting the iCP in a variety of disease types and with mechanisms besides inhibition.

Fluorescent Probes with Unnatural Amino Acids to Monitor Proteasome Activity in Real-Time.

The proteasome is an essential protein complex that, when dysregulated, can result in various diseases in eukaryotic cells. As such, understanding the enzymatic activity of the proteasome and what can alter it is crucial to elucidating its roles in these diseases. This can be done effectively by using activity-based fluorescent substrate probes, of which there are many commercially available that target the individual protease-like subunits in the 20S CP of the proteasome. Unfortunately, these probes have not displayed appropriate characteristics for their use in live cell-based assays. In the work presented here, we have developed a set of probes which have shown improved fluorescence properties and selectivity toward the proteasome compared to other cellular proteases. By including unnatural amino acids, we have found probes which can be utilized in various applications, including monitoring the effects of small molecule stimulators of the proteasome in live cells and comparing the relative proteasome activity across different cancer cell types. In future studies, we expect the fluorescent probes presented here will serve as tools to support the discovery and characterization of small molecule modulators of proteasome activity.

Synthesis and Application of an Activity-Based Peptide-Peptoid Hybrid Probe for the Immunoproteasome.

The immunoproteasome (iCP), a specific isoform of the proteasome's catalytic particle, is becoming an important protein complex of interest in various diseases. However, there is still much left to be learned about its activity in cells and how this can be altered by various endogenous conditions or with treatment with small molecules. Current strategies to investigate the iCP lack in their ability to be used in live, intact cells, limiting them to use in endpoint experiments. The iCP-selective probe presented here has been shown to be compatible with various live-cell assays, including monitoring iCP activity kinetically in a plate reader-based assay and observing single cells with confocal microscopy. A well-studied iCP-selective inhibitor, ONX-0914, has also been demonstrated to decrease the fluorescence signal of the iCP probe in both of these assays, showing its potential function in investigating small-molecule modulators of the iCP. © 2019 by John Wiley & Sons, Inc. Basic Protocol 1: Synthesis of an immunoproteasome-selective peptide-peptoid hybrid probe Basic Protocol 2: Expression of the immunoproteasome in A549 cells Basic Protocol 3: Using the immunoproteasome probe to monitor activity in live cells with a fluorescence plate reader Basic Protocol 4: Using the immunoproteasome probe to monitor activity in live cells with confocal microscopy.

Rubiscolins are naturally occurring G protein-biased delta opioid receptor peptides.

The impact that ß-arrestin proteins have on G protein-coupled receptor trafficking, signaling and physiological behavior has gained much appreciation over the past decade. A number of studies have attributed the side effects associated with the use of naturally occurring and synthetic opioids, such as respiratory depression and constipation, to excessive recruitment of ß-arrestin. These findings have led to the development of biased opioid small molecule agonists that do not recruit ß-arrestin, activating only the canonical G protein pathway. Similar G protein-biased small molecule opioids have been found to occur in nature, particularly within kratom, and opioids within salvia have served as a template for the synthesis of other G protein-biased opioids. Here, we present the first report of naturally occurring peptides that selectively activate G protein signaling pathways at δ opioid receptors, but with minimal ß-arrestin recruitment. Specifically, we find that rubiscolin peptides, which are produced as cleavage products of the plant protein rubisco, bind to and activate G protein signaling at δ opioid receptors. However, unlike the naturally occurring δ opioid peptides leu-enkephalin and deltorphin II, the rubiscolin peptides only very weakly recruit ß-arrestin 2 and have undetectable recruitment of ß-arrestin 1 at the δ opioid receptor.

Gramicidin A Mutants with Antibiotic Activity against Both Gram-Positive and Gram-Negative Bacteria.

Antimicrobial peptides (AMPs) have shown potential as alternatives to traditional antibiotics for fighting infections caused by antibiotic-resistant bacteria. One promising example of this is gramicidin A (gA). In its wild-type sequence, gA is active by permeating the plasma membrane of Gram-positive bacteria. However, gA is toxic to human red blood cells at similar concentrations to those required for it to exert its antimicrobial effects. Installing cationic side chains into gA has been shown to lower its hemolytic activity while maintaining the antimicrobial potency. In this study, we present the synthesis and the antibiotic activity of a new series of gA mutants that display cationic side chains. Specifically, by synthesizing alkylated lysine derivatives through reductive amination, we were able to create a broad selection of structures with varied activities towards Staphylococcus aureus and methicillin-resistant S. aureus (MRSA). Importantly, some of the new mutants were observed to have an unprecedented activity towards important Gram-negative pathogens, including Escherichia coli, Klebsiella pneumoniae and Psuedomonas aeruginosa.

Recent Advances in Peptide Immunomodulators.

With the continued rise in antibiotic-resistant bacteria, there is an immense need for the development of new therapeutic agents. Host-defense peptides (HDPs) offer a unique alternative to many of the current approved antibiotics. By targeting the host rather than the pathogen, HDPs offer several benefits over traditional small molecule drug treatments, such as a slower propensity towards resistance, broad-spectrum activity and lower risk of patients developing sepsis. However, natural peptide structures have many disadvantages as well, including susceptibility to proteolytic degradation, significant costs of synthesis and host toxicity. For this reason, much work has been done to examine peptidomimetic structures, in the hopes of finding a structure with all of the desired qualities of an antibiotic drug. Recently, this research has included synthetic constructs that mimic the behavior of HDPs but have no structural similarity to peptides. This review article focuses on the progression of this field of research, beginning with an analysis of a few prominent examples of natural HDPs and moving on to describe how the information learned by studying them have led to the current design platforms.