Small‐Molecule PROTACS: New Approaches to Protein Degradation

The current inhibitor‐based approach to therapeutics has inherent limitations owing to its occupancy‐based model: 1) there is a need to maintain high systemic exposure to ensure sufficient in vivo inhibition, 2) high in vivo concentrations bring potential for off‐target side effects, and 3) there is a need to bind to an active site, thus limiting the drug target space. As an alternative, induced protein degradation lacks these limitations. Based on an event‐driven model, this approach offers a novel catalytic mechanism to irreversibly inhibit protein function by targeting protein destruction through recruitment to the cellular quality control machinery. Prior protein degrading strategies have lacked therapeutic potential. However, recent reports of small‐molecule‐based proteolysis‐targeting chimeras (PROTACs) have demonstrated that this technology can effectively decrease the cellular levels of several protein classes.     

Small‐Molecule Control of Intracellular Protein Levels through Modulation of the Ubiquitin Proteasome System

Traditionally, biological probes and drugs have targeted the activities of proteins (such as enzymes and receptors) that can be readily controlled by small molecules. The remaining majority of the proteome has been deemed “undruggable”. By using small‐molecule modulators of the ubiquitin proteasome, protein levels, rather than protein activity, can be targeted instead, thus increasing the number of druggable targets. Whereas targeting of the proteasome itself can lead to a global increase in protein levels, the targeting of other components of the UPS (e.g., the E3 ubiquitin ligases) can lead to an increase in protein levels in a more targeted fashion. Alternatively, multiple strategies for inducing protein degradation with small‐molecule probes are emerging. With the ability to induce and inhibit the degradation of targeted proteins, small‐molecule modulators of the UPS have the potential to significantly expand the druggable portion of the proteome beyond traditional targets, such as enzymes and receptors.     

Structure‐Based Design of a Macrocyclic PROTAC

Constraining a molecule in its bioactive conformation via macrocyclization represents an attractive strategy to rationally design functional chemical probes. While this approach has been applied to enzyme inhibitors or receptor antagonists, to date it remains unprecedented for bifunctional molecules that bring proteins together, such as PROTAC degraders. Herein, we report the design and synthesis of a macrocyclic PROTAC by adding a cyclizing linker to the BET degrader MZ1. A co‐crystal structure of macroPROTAC‐1 bound in a ternary complex with VHL and the second bromodomain of Brd4 validated the rational design. Biophysical studies revealed enhanced discrimination between the second and the first bromodomains of BET proteins. Despite a 12‐fold loss of binary binding affinity for Brd4, macroPROTAC‐1 exhibited cellular activity comparable to MZ1. Our findings support macrocyclization as an advantageous strategy to enhance PROTAC degradation potency and selectivity between homologous targets.     

Therapeutic Targeting of Oncogenic K‐Ras by a Covalent Catalytic Site Inhibitor

We report the synthesis of a GDP analogue, SML‐8‐73‐1, and a prodrug derivative, SML‐10‐70‐1, which are selective, direct‐acting covalent inhibitors of the K‐Ras G12C mutant relative to wild‐type Ras. Biochemical and biophysical measurements suggest that modification of K‐Ras with SML‐8‐73‐1 renders the protein in an inactive state. These first‐in‐class covalent K‐Ras inhibitors demonstrate that irreversible targeting of the K‐Ras guanine‐nucleotide binding site is potentially a viable therapeutic strategy for inhibition of Ras signaling.     

Proteasomal Degradation of Zn-Dependent Hdacs: The E3-Ligases Implicated and the Designed Protacs That Enable Degradation

Protein degradation by the Ubiquitin-Proteasome System is one of the main mechanisms of the regulation of cellular proteostasis, and the E3 ligases are the key effectors for the protein recognition and degradation. Many E3 ligases have key roles in cell cycle regulation, acting as checkpoints and checkpoint regulators. One of the many important proteins involved in the regulation of the cell cycle are the members of the Histone Deacetylase (HDAC) family. The importance of zinc dependent HDACs in the regulation of chromatin packing and, therefore, gene expression, has made them targets for the design and synthesis of HDAC inhibitors. However, achieving potency and selectivity has proven to be a challenge due to the homology between the zinc dependent HDACs. PROteolysis TArgeting Chimaera (PROTAC) design has been demonstrated to be a useful strategy to inhibit and selectively degrade protein targets. In this review, we attempt to summarize the E3 ligases that naturally ubiquitinate HDACs, analyze their structure, and list the known ligands that can bind to these E3 ligases and be used for PROTAC design, as well as the already described HDAC-targeted PROTACs.     

When Kinases Meet PROTACs

Small molecule drugs targeting kinases have revolutionized treatment options for millions of patients worldwide, especially in oncology. These targeted treatments have less side effects because they inhibit a specific dysfunctional kinase usually with relatively narrow selectivity. However, kinase inhibitors do have well‐established liabilities, most prominently the emergence of drug resistance. Moreover, the majority of kinases are multidomain and multifunctional proteins that in addition to their enzymatic activity have scaffolding and other roles, and inhibitors seldom address these alternative functions. Recently, small molecule mediated targeted protein degradation emerged as a new pharmacological strategy. The majority of small molecule degraders are bispecific molecules called proteolysis targeting chimeras (PROTACs), and their mechanism of action is based on simultaneous recruitment of the target of interest and an E3 ligase, resulting in target polyubiquitination and eventual destruction by the proteasome. Over the last couple of years, PROTAC strategy has been developed and validated for a range of targets, including kinases. Here, we introduce the targeted protein degradation strategy, provide an overview of representative kinase PROTACs, and describe design rationales, efficacy and specificity. We also discuss their potential advantages, as well as comment on some of the limitations of this emerging pharmacological modality.     

Design of the First‐in‐Class,Highly Potent Irreversible Inhibitor Targeting the Menin‐MLL Protein–Protein Interaction

The structure‐based design of M‐525 as the first‐in‐class, highly potent, irreversible small‐molecule inhibitor of the menin‐MLL interaction is presented. M‐525 targets cellular menin protein at sub‐nanomolar concentrations and achieves low nanomolar potencies in cell growth inhibition and in the suppression of MLL‐regulated gene expression in MLL leukemia cells. M‐525 demonstrates high cellular specificity over non‐MLL leukemia cells and is more than 30 times more potent than its corresponding reversible inhibitors. Mass spectrometric analysis and co‐crystal structure of M‐525 in complex with menin firmly establish its mode of action. A single administration of M‐525 effectively suppresses MLL‐regulated gene expression in tumor tissue. An efficient procedure was developed to synthesize M‐525. This study demonstrates that irreversible inhibition of menin may be a promising therapeutic strategy for MLL leukemia.     

Boron‐Based Drug Design

The use of the element boron, which is not generally observed in a living body, possesses a high potential for the discovery of new biological activity in pharmaceutical drug design. In this account, we describe our recent developments in boron‐based drug design, including boronic acid containing protein tyrosine kinase inhibitors, proteasome inhibitors, and tubulin polymerization inhibitors, and ortho‐carborane‐containing proteasome activators, hypoxia‐inducible factor 1 inhibitors, and topoisomerase inhibitors. Furthermore, we applied a closo‐dodecaborate as a water‐soluble moiety as well as a boron‐10 source for the design of boron carriers in boron neutron capture therapy, such as boronated porphyrins and boron lipids for a liposomal boron delivery system.     

Multivalent Inhibitors for Carbohydrate‐Processing Enzymes: Beyond the “Lock‐and‐Key” Concept

During the last decades, tremendous chemical efforts have been dedicated to design monovalent inhibitors of carbohydrate‐processing enzymes, with comparatively few rewards in terms of marketed drugs. Recently, an alternative to the traditional “lock and key” approach has emerged. Multivalency, a widely used strategy for lectin inhibition, has been successfully applied to specific glycosidases and glycosyltransferases.     

Arylfluorosulfate‐Based Electrophiles for Covalent Protein Labeling: A New Addition to the Arsenal

Selective covalent modification of a targeted protein is a powerful tool in chemical biology and drug discovery, with applications ranging from identification and characterization of proteins and their functions to the development of targeted covalent inhibitors. Most covalent ligands contain an affinity motif and an electrophilic warhead that reacts with a nucleophilic residue of the targeted protein. Because the electrophilic warhead is prone to react and modify off‐target nucleophiles, its reactivity should be balanced carefully to maximize target selectivity. Arylfluorosulfates have recently emerged as latent electrophiles for selective labeling of context‐specific tyrosine and lysine residues in protein pockets. Here, we review the recent but intense introduction of arylfluorosulfates into the arsenal of available warheads for selective covalent modification of proteins. We highlight the untapped potential of this functional group for use in chemical biology and drug discovery.     

Light‐Controlled Histone Deacetylase (HDAC) Inhibitors: Towards Photopharmacological Chemotherapy

Cancer treatment suffers from limitations that have a major impact on the patient’s quality of life and survival. In the case of chemotherapy, the systemic distribution of cytotoxic drugs reduces their efficacy and causes severe side effects due to nonselective toxicity. Photopharmacology allows a novel approach to address these problems because it employs external, local activation of chemotherapeutic agents by using light. The development of photoswitchable histone deacetylase (HDAC) inhibitors as potential antitumor agents is reported herein. Analogues of the clinically used chemotherapeutic agents vorinostat, panobinostat, and belinostat were designed with a photoswitchable azobenzene moiety incorporated into their structure. The most promising compound exhibits high inhibitory potency in the thermodynamically less stable cis form and a significantly lower activity for the trans form, both in terms of HDAC activity and proliferation of HeLa cells. This approach offers a clear prospect towards local photoactivation of HDAC inhibition to avoid severe side effects in chemotherapy.