The AUTOTAC chemical biology platform for targeted protein degradation via the autophagy-lysosome system

Recent advances in degraders engaging lysosomal pathways and related nanomedicine

The advent of targeted protein degradation (TPD) strategies presents unparalleled opportunities for innovating and expediting the development of new drugs. As the most mature TPD technology to date, proteolysis targeting chimeras (PROTACs) reliant on the ubiquitin proteasome system (UPS) have successfully transitioned from the laboratory to phase III clinical trials after nearly two decades of development. In recent years, the gradually emerging degraders engaging lysosomal pathways have further broadened the range of degradation mechanisms and substantially increased the diversity of potential targets and indications, ushering in a new era for the TPD field. Despite their significant advantages, the limited permeability, adverse pharmacokinetic properties, and off-target side effects caused by non-specific distribution still pose significant challenges to the clinical translation of these degraders. Currently, researchers are exploring the use of nanotechnology to surmount these obstacles and have achieved notable progress. This paper systematically summarizes the fundamental design principles, research status, challenges and future prospects of degraders engaging lysosomal pathways, and highlights the efforts and latest advances in related nanomedicine to optimize these degraders. The aim of this review is to deepen our comprehension of this emerging field and offer guidance for future exploration, development, and further utilization of new TPD techniques.

Biochemical investigation of LC3/GABARAP-ligand interaction as an important quality measure for LC3/GABARAP-targeting small molecules: addendum to the guidelines (4th edition)

Targeted protein degradation (TPD) represents a new therapeutic modality that allows the targeting of proteins that are considered undruggable by conventional small molecules. While TPD approaches via the ubiquitin-proteasome system are well established and validated, additional degradation pathways still require rigorous characterization. Here, we focus on macroautophagy/autophagy tethering compounds, a class of small molecules, designed to recruit cargo to LC3/GABARAP proteins for subsequent autophagosome-dependent degradation. We provide guidance for the biophysical and structural characterization of small molecule modulators for studying LC3/GABARAP-ligand interactions. In addition, we discuss potential limitations of autophagy-based TPD systems and emphasize the need for rigorous quality control in the development of LC3/GABARAP-targeting small molecules.Abbreviations: DSF: differential scanning fluorimetry; FP: fluorescence polarization; FRET: Förster/fluorescence resonance energy transfer; HTRF: homogeneous time-resolved fluorescence; ITC: isothermal titration calorimetry; LIR: LC3-interacting region; MGs: molecular glues; NMR: nuclear magnetic resonance; PROTACs: PROteolysis-TArgeting Chimeras; SPR: surface plasmon resonance; TPD: targeted protein degradation; TR-FRET: time-resolved Förster/fluorescence resonance energy transfer; UPS: ubiquitin-proteasome system.

Promoting Secretion of Pathological Tau Species Using an Induced Proximity Platform That Engages the Autophagy Pathway

Intracellular accumulation of aberrantly phosphorylated aggregated tau protein can contribute to neuronal dysfunction associated with many neurodegenerative diseases. Thus, removing such tau species is an attractive therapeutic hypothesis for these diseases. Targeted protein degradation (TPD) strategies leveraging the autophagy-lysosome pathway (ALP) are promising approaches to decrease protein aggregates by designating them for degradation. Here, we developed a novel heterobifunctional molecule, MRL828, combining a tau pathology-binding ligand and modified guanine moiety based on the autophagy-targeting chimaera technology to selectively designate aggregated tau proteins for clearance via the ALP. Surprisingly, the MRL828-dependent decrease in intracellular tau aggregates was dependent on the autophagosome, but not the lysosome. MRL828 treatment led to autophagosome-dependent secretion of oligomeric and phosphorylated tau species, suggesting a reduction of intracellular tau aggregates via secretory autophagy rather than degradation via the ALP. This work highlights a novel mechanism of action (MOA) of an ALP-based heterobifunctional molecule and a potential new strategy for the cellular removal of proteins of interest.

Targeted degradation of extracellular proteins: state of the art and diversity of degrader designs

Selective elimination of proteins associated with the pathogenesis of diseases is an emerging therapeutic modality with distinct advantages over traditional inhibitor-based approaches. This strategy, called targeted protein degradation (TPD), is based on hijacking the cellular proteolytic machinery using chimeric degrader molecules that physically link the target protein of interest with the degradation effectors. The TPD era began with the development of PROteolysis TAtrgeting Chimeras (PROTACs) in 2001, with various methods and applications currently available. Classical PROTAC molecules are heterobifunctional chimeras linking target proteins with E3 ubiquitin ligases. This induced interaction leads to the ubiquitylation of the target protein, which is needed for its recognition and subsequent degradation by the cellular proteasomes. However, this technology is limited to intracellular proteins since the effectors involved (E3 ubiquitin ligases and proteasomes) are located in the cytosol. The related methods for selective destruction of proteins present in the extracellular space have only emerged recently and are collectively termed extracellular TPD (eTPD). The prototypic eTPD technology utilizes LYsosomal TArgeting Chimeras (LYTACs) that link extracellular target proteins (secreted or membrane-associated) to lysosome-targeting receptors (LTRs) on the cell surface. The resulting complex is then internalized by endocytosis and trafficked to lysosomes, where the target protein is degraded. The successful elimination of various extracellular proteins via LYTACs and related approaches has been reported, including several important targets in oncology that drive tumor growth and dissemination. This review summarizes current progress in the eTPD field and focuses primarily on the respective technological developments. It discusses the design principles and diversity of degrader molecules and the landscape of available targets and effectors that can be employed for eTPD. Finally, it emphasizes current open questions, challenges, and perspectives of this technological platform to promote the expansion of the eTPD toolkit and further development of its therapeutic applications.

Native mass spectrometry for proximity-inducing compounds: a new opportunity for studying chemical-induced protein modulation

INTRODUCTION

Proximity-inducing compounds promote protein-protein interactions by bringing proteins into close spatial alignment. Among them, targeted protein degradation (TPD) compounds are noteworthy for their potential to target previously 'undruggable' proteins. Native mass spectrometry (nMS), a technique that enables the detection of non-covalent interactions, is emerging as a key tool for studying compound-induced ternary complex formation.

AREAS COVERED

This review highlights the use of nMS in unraveling the mechanisms of proximity-inducing compounds, focusing on all available studies published since 2020, identified through a PubMed database search. The authors explore how nMS helps investigate the efficacy and mechanisms of proteolysis-targeting chimeras (PROTACs) and molecular glues by capturing the binary and ternary complexes formed by E3 ligases, protein of interest (POI), and these molecules.

EXPERT OPINION

nMS excels at analyzing intact protein complexes, providing real-time insights into interactions between E3 ligases, POIs, and proximity-inducing agents. This analysis helps understand the formation, stability, and dynamic nature of the complexes along with precise data on stoichiometry and binding affinities, which are crucial for selecting and refining effective degraders. The future of nMS in TPD research is promising, with potential applications in kinetic analysis, degrader screenings, and exploration of novel E3 ligases and target proteins.

Baicalein tethers CD274/PD-L1 for autophagic degradation to boost antitumor immunity

Immune checkpoint inhibitors, especially those targeting CD274/PD-L1yield powerful clinical therapeutic efficacy. Thoughmuch progress has been made in the development of antibody-basedCD274 drugs, chemical compounds applied for CD274degradation remain largely unavailable. Herein,baicalein, a monomer of traditional Chinese medicine, isscreened and validated to target CD274 and induces itsmacroautophagic/autophagic degradation. Moreover, we demonstrate thatCD274 directly interacts with MAP1LC3B (microtubule associatedprotein 1 light chain 3 beta). Intriguingly, baicalein potentiatesCD274-LC3 interaction to facilitate autophagic-lysosomal degradationof CD274. Importantly, targeted CD274. degradation via baicaleininhibits tumor development by boosting T-cell-mediated antitumorimmunity. Thus, we elucidate a critical role of autophagy-lysosomalpathway in mediating CD274 degradation, and conceptually demonstratethat the design of a molecular "glue" that tethers the CD274-LC3interaction is an appealing strategy to develop CD274 inhibitors incancer therapy.Abbreviations: ATTECs: autophagy-tethering compounds; AUTACs: AUtophagy-TArgeting Chimeras; AUTOTACs: AUTOphagy-TArgeting Chimeras; AMPK: adenosine 5'-monophosphate (AMP)-activated protein kinase; BiFC: bimolecular fluorescence complementation; BafA1: bafilomycin A1; CD274/PD-L1/B7-H1: CD274 molecule; CQ: chloroquine; CGAS: cyclic GMP-AMP synthase; DAPI: 4'6-diamino-2-phenylindole; FITC: fluorescein isothiocyanate isomer; GFP: green fluorescent protein; GZMB: granzyme B; IHC: immunohistochemistry; ICB: immune checkpoint blockade; KO: knockout; KD: equilibrium dissociation constant; LYTAC: LYsosome-TArgeting Chimera; LIR: LC3-interacting region; MAP1LC3/LC3: microtubule associated protein 1 light chain 3; MST: microscale thermophoresis; NFAT: nuclear factor of activated T cells; NFKB/NF-kB: nuclear factor kappa B; NSCLC: non-small-cell lung cancer; PDCD1: programmed cell death 1; PROTACs: PROteolysis TArgeting Chimeras; PRF1: perforin 1; PE: phosphatidylethanolamine; PHA: phytohemagglutinin; PMA: phorbol 12-myristate 13-acetate; STAT: signal transducer and activator of transcription; SPR: surface plasmon resonance; TILs: tumor-infiltrating lymphocyte; TME: tumor microenvironment.

Cytoplasmic Vacuolization: A Fascinating Morphological Alteration From Cellular Stress to Cell Death

Cytoplasmic vacuolization is a cellular morphological alteration characterized by the presence of substantial vacuole-like structures originating from various cellular organelles. This phenomenon is often observed in various anticancer treatments, including chemotherapeutic drugs, and photodynamic therapy (PDT), and is frequently linked with cell death. Nevertheless, the precise mechanisms underlying cytoplasmic vacuolization and ensuing cell death remain ambiguous. Cytoplasmic vacuolization associated cell death (CVACD) is a complex process characterized by cellular stress, encompassing ER stress, heightened membrane permeability, ion imbalance, and mitochondrial dysfunction. The MAPK signaling pathway is closely associated with the activation of CVACD. This review provides a thorough examination of contemporary studies on cytoplasmic vacuolization in mammalian cells, elucidating its etiology, origins, and molecular pathways. Additionally, it highlights the potential of CVACD as an innovative therapeutic strategy for cancer.

Targeted protein degradation for cancer therapy

Targeted protein degradation (TPD) aims at reprogramming the target specificity of the ubiquitin-proteasome system, the major cellular protein disposal machinery, to induce selective ubiquitination and degradation of therapeutically relevant proteins. Since its conception over 20 years ago, TPD has gained a lot of attention mainly due to improvements in the design of bifunctional proteolysis targeting chimeras (PROTACs) and understanding the mechanisms underlying molecular glue degraders. Today, PROTACs are on the verge of a first clinical approval and recent structural and mechanistic insights combined with technological leaps promise to unlock the rational design of protein degraders, following the lead of lenalidomide and related clinically approved analogues. At the same time, the TPD universe is expanding at a record speed with the discovery of novel modalities beyond molecular glue degraders and PROTACs. Here we review the recent progress in the field, focusing on newly discovered degrader modalities, the current state of clinical degrader candidates for cancer therapy and upcoming design approaches.

Deubiquitinase-Targeting Chimeras (DUBTACs) as a Potential Paradigm-Shifting Drug Discovery Approach

Developing proteolysis-targeting chimeras (PROTACs) is well recognized through target protein degradation (TPD) toward promising therapeutics. While a variety of diseases are driven by aberrant ubiquitination and degradation of critical proteins with protective functions, target protein stabilization (TPS) rather than TPD is emerging as a unique therapeutic modality. Deubiquitinase-targeting chimeras (DUBTACs), a class of heterobifunctional protein stabilizers consisting of deubiquitinase (DUB) and protein-of-interest (POI) targeting ligands conjugated with a linker, can rescue such proteins from aberrant elimination. DUBTACs stabilize the levels of POIs in a DUB-dependent manner, removing ubiquitin from polyubiquitylated and degraded proteins. DUBTACs can induce a new interaction between POI and DUB by forming a POI-DUBTAC-DUB ternary complex. Herein, therapeutic benefits of TPS approaches for human diseases are introduced, and recent advances in developing DUBTACs are summarized. Relevant challenges, opportunities, and future perspectives are also discussed.

Manipulation of targeted protein degradation in plant biology

Inducible protein degradation systems are an important but untapped resource for the study of protein function in plant cells. Unlike mutagenesis or transcriptional control, regulated degradation of proteins of interest allows the study of the biological mechanisms of highly dynamic cellular processes involving essential proteins. While systems for targeted protein degradation are available for research and therapeutics in animals, there are currently limited options in plant biology. Targeted protein degradation systems rely on target ubiquitination by E3 ubiquitin ligases. Systems that are available or being developed in plants can be distinguished primarily by the type of E3 ubiquitin ligase involved, including those that utilize Cullin-RING ligases, bacterial novel E3 ligases, and N-end rule pathway E3 ligases, or they can be controlled by proteolysis targeting chimeras. Target protein ubiquitination leads to degradation by the proteasome or targeting to the vacuole, with both pathways being ubiquitous and important for the endogenous control of protein abundance in plants. Targeted proteolysis approaches for plants will likely be an important tool for basic research and to yield novel traits for crop biotechnology.

Targeting neurodegenerative disease-associated protein aggregation with proximity-inducing modalities

Neurodegenerative diseases (NDDs) are characterized by progressive neuronal dysfunction and anatomical changes caused by neuron loss and gliosis, ultimately leading to severe declines in brain function. While these disorders arise from a variety of pathological mechanisms, a common molecular feature is the accumulation of misfolded proteins, which occurs both inside and outside neurons. For example, Alzheimer's disease (AD) is defined by extracellular β-amyloid plaques and intracellular tau neurofibrillary tangles. These pathological protein aggregates are often resistant to traditional small molecule drugs. Recent advances in proximity-inducing chimeras such as proteolysis-targeting chimeras (PROTACs), lysosome-targeting chimeras (LYTACs), autophagy-targeted chimeras (AUTOTACs), dephosphorylation-targeting chimeras (DEPTACs) and ribonuclease-targeting chimeras (RIBOTACs) offer promising strategies to eliminate pathological proteins or mRNAs through intracellular degradation pathways. These innovative approaches open avenues for developing new therapies for NDDs. In this review we summarize the regulatory mechanisms of protein aggregation, highlight the advancements in proximity-inducing modalities for NDDs, and discuss the current challenges and future directions in therapeutic development.

Discovery of 2,4-quinazolinedione derivatives as LC3B recruiters in the facilitation of protein complex degradations

Targeted protein degradation through autophagosome-tethering compounds (ATTECs) that bypasses the ubiquitination process has garnered increasing attention. LC3B, a key protein in autophagosome formation, recruits substrates into the autophagy-lysosome system for degradation. In this study, we systematically optimized 2,4-quinazolinedione derivatives as LC3B-recruiting fragments, utilizing the CDK9 indicator. By attaching the designed LC3B-recruiting fragment to CDK9 inhibitor SNS-032 through a linker, the resulting bifunctional ATTEC molecule simultaneously degraded CDK9 and its associated Cyclin T1. Two-dimensional NMR experiments confirmed the direct interaction between the novel LC3B-recruiting fragments and LC3B. Mechanistic studies elucidated that degradation occurred via an LC3B-dependent autophagy-lysosomal pathway. Additionally, the general applicability of leveraging LC3B-recruiting fragments linked to inhibitors for the targeted degradation of protein complexes was validated with PRC2 and CDK2/4/6 along with their respective Cyclins. This work provides a series of novel LC3B-recruiting fragments that enrich the ATTEC toolbox and can be applied to the degradation of diverse intracellular disease-causing proteins.

An updated review on the role of small molecules in mediating protein degradation

Targeted protein degradation (TPD) technologies, inspired by physiological processes, have recently provided new directions for drug development. Unlike conventional drug development focusing on targeting the active sites of disease-related proteins, TPD can utilize any nook or cranny of a protein to drive degradation through the cell's inherent destruction mechanism. It offers various advantages such as stronger pharmacological effects, an expanded range of drug targets, and higher selectivity. Based on the ubiquitin-proteasome system and the lysosomal degradation pathway, a variety of TPD strategies have been developed including PROTAC, PROTAB, and AUTOTAC. These TPD strategies have continuously enriched the toolbox for targeted protein degradation and expanded the scope of application, providing new ideas for biological research and drug discovery. This review attempts to introduce up-to-date research progress in the TPD strategies, focusing mainly on their design concepts, advantages, potential applications, and challenges, which may provide some inspiration for drug design, drug discovery, and clinical application for biologists and chemists.

Implications of frequent hitter E3 ligases in targeted protein degradation screens

Targeted protein degradation (TPD) offers a promising approach for chemical probe and drug discovery that uses small molecules or biologics to direct proteins to the cellular machinery for destruction. Among the >600 human E3 ligases, CRBN and VHL have served as workhorses for ubiquitin-proteasome system-dependent TPD. Identification of additional E3 ligases capable of supporting TPD would unlock the full potential of this mechanism for both research and pharmaceutical applications. This perspective discusses recent strategies to expand the scope of TPD and the surprising convergence of these diverse screening efforts on a handful of E3 ligases, specifically DCAF16, DCAF11 and FBXO22. We speculate that a combination of properties, including superficial ligandability, potential for promiscuous substrate interactions and high occupancy in Cullin-RING complexes, may position these E3 ligases as 'low-hanging fruit' in TPD screens. We also discuss complementary approaches that might further expand the E3 ligase landscape supporting TPD.

Targeted protein degradation with bifunctional molecules as a novel therapeutic modality for Alzheimer's disease & beyond

Alzheimer's disease (AD) is associated with memory and cognitive impairment caused by progressive degeneration of neurons. The events leading to neuronal death are associated with the accumulation of aggregating proteins in neurons and glia of the affected brain regions, in particular extracellular deposition of amyloid plaques and intracellular formation of tau neurofibrillary tangles. Moreover, the accumulation of pathological tau proteoforms in the brain concurring with disease progression is a key feature of multiple neurodegenerative diseases, called tauopathies, like frontotemporal dementia (FTD) where autosomal dominant mutations in the tau encoding MAPT gene provide clear evidence of a causal role for tau dysfunction. Observations from disease models, post-mortem histology, and clinical evidence have demonstrated that pathological tau undergoes abnormal post-translational modifications, misfolding, oligomerization, changes in solubility, mislocalization, and intercellular spreading. Despite extensive research, there are few disease-modifying or preventative therapeutics for AD and none for other tauopathies. Challenges faced in tauopathy drug development include an insufficient understanding of pathogenic mechanisms of tau proteoforms, limited specificity of agents tested, and inadequate levels of brain exposure, altogether underscoring the need for innovative therapeutic modalities. In recent years, the development of experimental therapeutic modalities, such as targeted protein degradation (TPD) strategies, has shown significant and promising potential to promote the degradation of disease-causing proteins, thereby reducing accumulation and aggregation. Here, we review all modalities of TPD that have been developed to target tau in the context of AD and FTD, as well as other approaches that with innovation could be adapted for tau-specific TPD.

Targeting Tau Protein with Proximity Inducing Modulators: A New Frontier to Combat Tauopathies

Dysregulation of correct protein tau homeostasis represents the seed for the development of several devastating central nervous system disorders, known as tauopathies, that affect millions of people worldwide. Despite massive public and private support to research funding, these diseases still represent unmet medical needs. In fact, the tau-targeting tools developed to date have failed to translate into the clinic. Recently, taking advantage of the modes that nature uses to mediate the flow of information in cells, researchers have developed a new class of molecules, called proximity-inducing modulators, which exploit spatial proximity to modulate protein function(s) and redirect cellular processes. In this perspective, after a brief discussion about tau protein and the classic tau-targeting approaches, we will discuss the different classes of proximity-inducing modulators developed so far and highlight the applications to modulate tau protein's function and tau-induced toxicity.

Multivalent RGD Peptide-Mediated Nanochimera for Lysosomal Degradation of PDL1 Protein

The development of immune checkpoint inhibitors, especially PDL1 antibodies, has revolutionized cancer therapy, but the posttherapy recycling of PDL1 proteins poses a significant challenge by inducing resistance and reducing treatment efficacy. To address this, we introduce an integrin-driven, lysosome-targeted nanochimera, composed of poly(glutamic acid), RGD peptides, and PDL1 antibodies, is designed to engage the target PDL1 protein, with the αvβ3 integrin binding to the multivalent RGD peptides to direct the complex through the endocytosomal pathway to the lysosome, ensuring PDL1 degradation and blocking its recycling. Our in vitro and in vivo experiments demonstrate that these nanochimeras potently activate T-cell antitumor immunity by downregulating PDL1 expression within tumor cells and tissues, significantly enhancing the efficacy of PDL1 antibodies. A key discovery of our study is the pivotal role of multivalent RGD peptides in facilitating target protein degradation, providing valuable insights for the development of more efficacious and sophisticated immunotherapies.

Targeted Protein Degradation in Cancer Therapy via Hydrophobic Polymer-Tagged Nanoparticles

Targeted protein degradation (TPD) strategies offer a significant advantage over traditional small molecule inhibitors by selectively degrading disease-causing proteins. While small molecules can lead to recurrence and resistance due to compensatory pathway activation, TPD addresses this limitation by promoting protein degradation, thereby reducing the likelihood of recurrence and resistance over the long-term. Despite these benefits, bifunctional TPD molecules face challenges such as low solubility, poor bioavailability, and limited tumor specificity. In this study, we developed polymer-based nanoparticles that combine TPD strategies with nanotechnology through a hydrophobic tagging method. Hydrophobic polymer-tagged nanoparticles facilitate targeted protein degradation by incorporating hydrophobic polymers that mimic hydrophobic residues in misfolded proteins. This system combines degradation and delivery capabilities within a polymer-based platform, inducing protein degradation while improving solubility, stability, and tumor targeting. These nanoparticles consist of a block copolymer composed of an androgen receptor ligand (ARL)-conjugated hydrophobic polylactic acid (PLA) and a hydrophilic polyethylene glycol (PEG), connected by a GSH-cleavable disulfide bond. In aqueous solutions, this block copolymer (ARL-PLA-SS-PEG) forms micelles that degrade in reducible cellular environments. The micelles demonstrated significant in vitro degradation of the target androgen receptor (AR). Furthermore, they achieved substantial tumor accumulation and significantly inhibited tumor growth in a tumor-bearing mouse model. A mechanistic study revealed that the micelle-mediated TPD follows a dual pathway involving both proteasome and autophagosome. This approach has the potential to serve as a universal platform for protein degradation, eliminating the need to develop disease-specific TPD molecules.

Targeted Degradation Technology Based on the Autophagy-Lysosomal Pathway: A Promising Strategy for Treating Preeclampsia

In recent years, targeted protein degradation (TPD) strategies leveraging the autophagy-lysosomal pathway (ALP) have transcended the limitations of conventional drug molecules, emerging as a highly promising approach for selectively eliminating disease-related proteins via the cell's intrinsic degradation machinery. These TPD methods, such as autophagosome-tethering compounds (ATTEC), autophagy-targeting chimera (AUTAC), AUTOphagy-TArgeting chimera (AUTOTAC), and chaperone-mediated autophagy (CMA) targeting chimera, exhibit efficacy in degrading misfolded protein aggregates associated with neurodegenerative disorders. Moreover, the excessive accumulation of misfolded proteins or protein complexes in the placenta has been identified as a significant contributor to preeclampsia (PE). Given the lack of effective treatments for PE, the application of autophagy-mediated TPD technology presents a novel therapeutic avenue. This review draws parallels between misfolded protein aggregates in neurodegenerative diseases and placenta-derived PE, integrating a substantial number of full-text studies. By harnessing TPD technologies grounded in the ALP, these autophagic degraders offer a pioneering approach for targeted therapy in PE by dismantling potential targets. Presently, there is limited exploration of ALP technology for identifying target proteins in the placenta. Nonetheless, we have proposed several potential target proteins, laying the groundwork for future therapeutic endeavors.

Tau degradation in Alzheimer's disease: Mechanisms and therapeutic opportunities

In Alzheimer's disease (AD), tau undergoes abnormal post-translational modifications and aggregations. Impaired intracellular degradation pathways further exacerbate the accumulation of pathological tau. A new strategy - targeted protein degradation - recently emerged as a modality in drug discovery where bifunctional molecules bring the target protein close to the degradation machinery to promote clearance. Since 2016, this strategy has been applied to tau pathologies and attracted broad interest in academia and the pharmaceutical industry. However, a systematic review of recent studies on tau degradation mechanisms is lacking. Here we review tau degradation mechanisms (the ubiquitin-proteasome system and the autophagy-lysosome pathway), their dysfunction in AD, and tau-targeted degraders, such as proteolysis-targeting chimeras and autophagy-targeting chimeras. We emphasize the need for a continuous exploration of tau degradation mechanisms and provide a future perspective for developing tau-targeted degraders, encouraging researchers to work on new treatment options for AD patients. HIGHLIGHTS: Post-translational modifications, aggregation, and mutations affect tau degradation. A vicious circle exists between impaired degradation pathways and tau pathologies. Ubiquitin plays an important role in complex degradation pathways. Tau-targeted degraders provide promising strategies for novel AD treatment.

Next steps for targeted protein degradation

Targeted protein degradation (TPD) has greatly advanced as a therapeutic strategy in the past two decades, and we are on the cusp of rationally designed protein degraders reaching clinical approval. Offering pharmacological advantages relative to occupancy-driven protein inhibition, chemical methods for regulating biomolecular proximity have provided opportunities to tackle disease-related targets that were undruggable. Despite the pre-clinical success of designed degraders and existence of clinical therapies that serendipitously utilize TPD, expansion of the TPD toolbox is necessary to identify and characterize the next generation of molecular degraders. Here we highlight three areas for continued growth in the field that should be prioritized: expansion of TPD platform with greater spatiotemporal precision, increased throughput of degrader synthesis, and optimization of cooperativity in chemically induced protein complexes. The future is bright for TPD in medicine, and we expect that innovative approaches will increase therapeutic applications of proximity-induced pharmacology.

New strategies to enhance the efficiency and precision of drug discovery

Drug discovery plays a crucial role in medicinal chemistry, serving as the cornerstone for developing new treatments to address a wide range of diseases. This review emphasizes the significance of advanced strategies, such as Click Chemistry, Targeted Protein Degradation (TPD), DNA-Encoded Libraries (DELs), and Computer-Aided Drug Design (CADD), in boosting the drug discovery process. Click Chemistry streamlines the synthesis of diverse compound libraries, facilitating efficient hit discovery and lead optimization. TPD harnesses natural degradation pathways to target previously undruggable proteins, while DELs enable high-throughput screening of millions of compounds. CADD employs computational methods to refine candidate selection and reduce resource expenditure. To demonstrate the utility of these methodologies, we highlight exemplary small molecules discovered in the past decade, along with a summary of marketed drugs and investigational new drugs that exemplify their clinical impact. These examples illustrate how these techniques directly contribute to advancing medicinal chemistry from the bench to bedside. Looking ahead, Artificial Intelligence (AI) technologies and interdisciplinary collaboration are poised to address the growing complexity of drug discovery. By fostering a deeper understanding of these transformative strategies, this review aims to inspire innovative research directions and further advance the field of medicinal chemistry.

Artificial targeting of autophagy components to mitochondria reveals both conventional and unconventional mitophagy pathways

Macroautophagy/autophagy enables lysosomal degradation of a diverse array of intracellular material. This process is essential for normal cellular function and its dysregulation is implicated in many diseases. Given this, there is much interest in understanding autophagic mechanisms of action in order to determine how it can be best targeted therapeutically. In mitophagy, the selective degradation of mitochondria via autophagy, mitochondria first need to be primed with signals that allow the recruitment of the core autophagy machinery to drive the local formation of an autophagosome around the target mitochondrion. To determine how the recruitment of different core autophagy components can drive mitophagy, we took advantage of the mito-QC mitophagy assay (an outer mitochondrial membrane-localized tandem mCherry-GFP tag). By tagging autophagy proteins with an anti-mCherry (or anti-GFP) nanobody, we could recruit them to mitochondria and simultaneously monitor levels of mitophagy. We found that targeting ULK1, ATG16L1 and the different Atg8-family proteins was sufficient to induce mitophagy. Mitochondrial recruitment of ULK1 and the Atg8-family proteins induced a conventional mitophagy pathway, requiring RB1CC1/FIP200, PIK3C3/VPS34 activity and ATG5. Surprisingly, the mitophagy pathway upon recruitment of ATG16L1 proceeded independently of ATG5, although it still required RB1CC1 and PIK3C3/VPS34 activity. In this latter pathway, mitochondria were alternatively delivered to lysosomes via uptake into early endosomes.Abbreviation: aGFP: anti-GFP nanobody; amCh: anti-mCherry nanobody; ATG: autophagy related; ATG16L1: autophagy related 16 like 1; AUTAC/AUTOTAC: autophagy-targeting chimera; BafA1: bafilomycin A1; CALCOCO2/NDP52: calcium binding and coiled-coil domain 2; CCCP: carbonyl cyanide m-chlorophenylhydrazone; COX4/COX IV: cytochrome c oxidase subunit 4; DFP: deferiprone; DMSO: dimethyl sulfoxide; GABARAP: GABA type A receptor-associated protein; GABARAPL1: GABA type A receptor associated protein like 1; HSPD1/HSP60: heat shock protein family D (Hsp60) member 1; HRP: horseradish peroxidase; HTRA2/OMI: HtrA serine peptidase 2; IB: immunoblotting; IF: immunofluorescence; KO: knockout; LAMP1: lysosomal associated membrane protein 1; LIR: LC3-interacting region; MAP1LC3/LC3: microtubule associated protein 1 light chain 3; MEF: mouse embryonic fibroblast; NBR1: NBR1 autophagy cargo receptor; OMM: outer mitochondrial membrane; OPA1: OPA1 mitochondrial dynamin like GTPase; OPTN: optineurin; (D)PBS: (Dulbecco's) phosphate-buffered saline; PD: Parkinson disease; PFA: paraformaldehyde; POI: protein of interest; PtdIns3K: class III phosphatidylinositol 3-kinase; PtdIns3P: phosphatidylinositol-3-phosphate; RAB: RAB, member RAS oncogene family; RB1CC1/FIP200: RB1 inducible coiled-coil 1; SQSTM1: sequestosome 1; TAX1BP1: Tax1 binding protein 1; ULK: unc-51 like autophagy activating kinase 1; VPS: vacuolar protein sorting; WIPI: WD repeat domain, phosphoinositide interacting.

Targeted protein degradation via cellular trafficking of nanoparticles

Strategies that selectively bind proteins of interest and target them to the intracellular protein recycling machinery for targeted protein degradation have recently emerged as powerful tools for undruggable targets in biomedical research and the pharmaceutical industry. However, targeting any new protein of interest with current degradation tools requires a laborious case-by-case design for different diseases and cell types, especially for extracellular targets. Here we observe that nanoparticles can mediate specific receptor-independent internalization of a bound protein and further develop a general strategy for degradation of extracellular proteins of interest by making full use of clinically approved components. This extremely flexible strategy aids in targeted protein degradation tool development and provides knowledge for targeted drug therapies and nanomedicine design.

Targeted Covalent Modification Strategies for Drugging the Undruggable Targets

The term "undruggable" refers to proteins or other biological targets that have been historically challenging to target with conventional drugs or therapeutic strategies because of their structural, functional, or dynamic properties. Drugging such undruggable targets is essential to develop new therapies for diseases where current treatment options are limited or nonexistent. Thus, investigating methods to achieve such drugging is an important challenge in medicinal chemistry. Among the numerous methodologies for drug discovery, covalent modification of therapeutic targets has emerged as a transformative strategy. The covalent attachment of diverse functional molecules to targets provides a powerful platform for creating highly potent drugs and chemical tools as well the ability to provide valuable information on the structures and dynamics of undruggable targets. In this review, we summarize recent examples of chemical methods for the covalent modification of proteins and other biomolecules for the development of new therapeutics and to overcome drug discovery challenges and highlight how such methods contribute toward the drugging of undruggable targets. In particular, we focus on the use of covalent chemistry methods for the development of covalent drugs, target identification, drug screening, artificial modulation of post-translational modifications, cancer specific chemotherapies, and nucleic acid-based therapeutics.

An Autophagy-Targeting Chimera Induces Degradation of Androgen Receptor Mutants and AR-v7 in Castration-Resistant Prostate Cancer

Genetic alterations play a pivotal role in various human diseases, particularly cancer. The androgen receptor (AR) is a crucial transcription factor driving prostate cancer progression across all stages. Current AR-targeting therapies utilize competitive AR antagonists or pathway suppressors. However, therapy resistance often emerges due to AR mutations and AR splice variants, such as AR-v7. To overcome this, we developed ATC-324, an AR degrader using the innovative protein degradation technology platform AUTOphagy-TArgeting Chimera (AUTOTAC). ATC-324 was designed to comprise enzalutamide, an AR inhibitor, as a target-binding ligand and YT 6-2, a ligand of the autophagy receptor p62/SQSTM1, as an autophagy-targeting ligand. ATC-324 induces the formation of the AR/p62 complex, leading to autophagy-lysosomal degradation of AR. Importantly, ATC-324 effectively degrades AR mutants frequently detected in prostate cancer and codegrades AR-v7 as a heterodimer with full-length AR. ATC-324 reduces nuclear AR levels and downregulates the target gene expression of AR and AR-v7, leading to cytotoxicity in AR-positive prostate cancer cells. We also provide evidence of the therapeutic potential of ATC-324 in vivo as well as ex vivo bone organ culture. Moreover, ATC-324 remains potent in enzalutamide-resistant prostate cancer cells. These results demonstrate the potential of the AUTOTAC platform to target previously considered undruggable proteins and overcome certain drug resistance mechanisms. Significance: The characterization of an AUTOTAC-based degrader capable of inducing autophagic degradation of wild-type and mutated androgen receptors demonstrates the potential of this approach for targeting castration-resistant prostate cancer and overcoming drug resistance.

Chemically engineered antibodies for autophagy-based receptor degradation

Cell surface receptor-targeted protein degraders hold promise for drug discovery. However, their application is restricted because of the complexity of creating bifunctional degraders and the reliance on specific lysosome-shuttling receptors or E3 ubiquitin ligases. To address these limitations, we developed an autophagy-based plasma membrane protein degradation platform, which we term AUTABs (autophagy-inducing antibodies). Through covalent conjugation with polyethylenimine (PEI), the engineered antibodies acquire the capacity to degrade target receptors through autophagy. The degradation activities of AUTABs are self-sufficient, without necessitating the participation of lysosome-shuttling receptors or E3 ubiquitin ligases. The broad applicability of this platform was then illustrated by targeting various clinically important receptors. Notably, combining specific primary antibodies with a PEI-tagged secondary nanobody also demonstrated effective degradation of target receptors. Thus, our study outlines a strategy for directing plasma membrane proteins for autophagic degradation, which possesses desirable attributes such as ease of generation, independence from cell type and broad applicability.

Exploration of degrons and their ability to mediate targeted protein degradation

Degrons are short amino acid sequences that can facilitate the degradation of protein substrates. They can be classified as either ubiquitin-dependent or -independent based on their interactions with the ubiquitin proteasome system (UPS). These amino acid sequences are often found in exposed regions of proteins serving as either a tethering point for an interaction with an E3 ligase or initiating signaling for the direct degradation of the protein. Recent advancements in the protein degradation field have shown the therapeutic potential of both classes of degrons through leveraging their degradative effects to engage specific protein targets. This review explores what targeted protein degradation applications degrons can be used in and how they have inspired new degrader technology to target a wide variety of protein substrates.

The autophagy-lysosome pathway: a potential target in the chemical and gene therapeutic strategies for Parkinson's disease

Parkinson's disease is a common neurodegenerative disease with movement disorders associated with the intracytoplasmic deposition of aggregate proteins such as α-synuclein in neurons. As one of the major intracellular degradation pathways, the autophagy-lysosome pathway plays an important role in eliminating these proteins. Accumulating evidence has shown that upregulation of the autophagy-lysosome pathway may contribute to the clearance of α-synuclein aggregates and protect against degeneration of dopaminergic neurons in Parkinson's disease. Moreover, multiple genes associated with the pathogenesis of Parkinson's disease are intimately linked to alterations in the autophagy-lysosome pathway. Thus, this pathway appears to be a promising therapeutic target for treatment of Parkinson's disease. In this review, we briefly introduce the machinery of autophagy. Then, we provide a description of the effects of Parkinson's disease-related genes on the autophagy-lysosome pathway. Finally, we highlight the potential chemical and genetic therapeutic strategies targeting the autophagy-lysosome pathway and their applications in Parkinson's disease.

γ-Secretase Cleaves Bifunctional Fatty Acid-Conjugated Small Molecules with Amide Bonds in Mammalian Cells

Connecting two small molecules, such as ligands, fluorophores, or lipids, together via a linker with amide bonds is a widely used strategy to generate synthetic bifunctional molecules for various biological and biomedical applications. Such bifunctional molecules have been used in live-cell experiments under the assumption that they should be stable in cells. However, we recently found that a membrane-targeting bifunctional molecule, composed of a lipopeptide and the small-molecule ligand trimethoprim, referred to as mgcTMP, underwent amide-bond cleavage in mammalian cells. In this work, we first identified γ-secretase as the major protease degrading mgcTMP in cells. We next investigated the intracellular degradation of several different types of amide-linked bifunctional compounds and found that N-terminally fatty acid-conjugated small molecules are susceptible to γ-secretase-mediated amide-bond cleavage. In contrast, amide-linked bifunctional molecules composed of two small molecules, such as ligands and hydrophobic groups, which lack lipid modification, did not undergo intracellular degradation. These findings highlight a previously overlooked consideration for the development and application of lipid-based bifunctional molecules in chemical biology research.

Aptamer and N-Degron Ensemble (AptaGron) as a Target Protein Degradation Strategy

Target protein degradation (TPD) is a promising strategy for catalytic downregulation of target proteins through various cellular proteolytic pathways. Despite numerous reports on novel TPD mechanisms, the discovery of target-specific ligands remains a major challenge. Unlike small-molecule ligands, aptamers offer significant advantages, owing to their SELEX-based systematic screening method. To fully utilize aptamers for TPD, we designed an aptamer and N-degron ensemble system (AptaGron) that circumvents the need for synthetic conjugations between aptamers and proteolysis-recruiting units. In our AptaGron system, a peptide nucleic acid containing an N-degron peptide and a sequence complementary to the aptamer was designed. Using this system, we successfully degraded three target proteins, tau, nucleolin, and eukaryotic initiation factor 4E (eIF4E), which lack specific small-molecule ligands. Our results highlight the potential of the AptaGron approach as a robust platform for targeted protein degradation.

CDK9 recruits HUWE1 to degrade RARα and offers therapeutic opportunities for cutaneous T-cell lymphoma

Cutaneous T-cell lymphoma (CTCL) is a heterogeneous non-Hodgkin lymphoma originating in the skin and invading the systemic hematopoietic system. Current treatments, including chemotherapy and monoclonal antibodies yielded limited responses with high incidence of side effects, highlighting the need for targeted therapy. Screening with small inhibitors library, herein we identify cyclin dependent kinase 9 (CDK9) as a driver of CTCL growth. Single-cell RNA-seq analysis reveals a CDK9high malignant T cell cluster with a unique actively proliferating feature. Inhibition, depletion or proteolysis targeting chimera (PROTAC)-mediated degradation of CDK9 significantly reduces CTCL cell growth in vitro and in murine models. CDK9 also promotes degradation of retinoic acid receptor α (RARα) via recruiting the E3 ligase HUWE1. Co-administration of CDK9-PROTAC (GT-02897) with all-trans retinoic acid (ATRA) leads to synergistic attenuation of tumor growth in vitro and in xenograft models, providing a potential translational treatment for complete eradication of CTCL.

Targeting the SMURF2-HIF1α axis: a new frontier in cancer therapy

The SMAD-specific E3 ubiquitin protein ligase 2 (SMURF2) has emerged as a critical regulator in cancer biology, modulating the stability of Hypoxia-Inducible Factor 1-alpha (HIF1α) and influencing a network of hypoxia-driven pathways within the tumor microenvironment (TME). SMURF2 targets HIF1α for ubiquitination and subsequent proteasomal degradation, disrupting hypoxic responses that promote cancer cell survival, metabolic reprogramming, angiogenesis, and resistance to therapy. Beyond its role in HIF1α regulation, SMURF2 exerts extensive control over cellular processes central to tumor progression, including chromatin remodeling, DNA damage repair, ferroptosis, and cellular stress responses. Notably, SMURF2's ability to promote ferroptotic cell death through GSTP1 degradation offers an alternative pathway to overcome apoptosis resistance, expanding therapeutic options for refractory cancers. This review delves into the multifaceted interactions between SMURF2 and HIF1α, emphasizing how their interplay impacts metabolic adaptations like the Warburg effect, immune evasion, and therapeutic resistance. We discuss SMURF2's dual functionality as both a tumor suppressor and, in certain contexts, an oncogenic factor, underscoring its potential as a highly versatile therapeutic target. Furthermore, modulating the SMURF2-HIF1α axis presents an innovative approach to destabilize hypoxia-dependent pathways, sensitizing tumors to chemotherapy, radiotherapy, and immune-based treatments. However, the complexity of SMURF2's interactions necessitate a thorough assessment of potential off-target effects and challenges in specificity, which must be addressed to optimize its clinical application. This review concludes by proposing future directions for research into the SMURF2-HIF1α pathway, aiming to refine targeted strategies that exploit this axis and address the adaptive mechanisms of aggressive tumors, ultimately advancing the landscape of precision oncology.

Accurate de novo design of high-affinity protein binding macrocycles using deep learning

The development of macrocyclic binders to therapeutic proteins typically relies on large-scale screening methods that are resource-intensive and provide little control over binding mode. Despite considerable progress in physics-based methods for peptide design and deep-learning methods for protein design, there are currently no robust approaches for de novo design of protein-binding macrocycles. Here, we introduce RFpeptides, a denoising diffusion-based pipeline for designing macrocyclic peptide binders against protein targets of interest. We test 20 or fewer designed macrocycles against each of four diverse proteins and obtain medium to high-affinity binders against all selected targets. Designs against MCL1 and MDM2 demonstrate KD between 1-10 μM, and the best anti-GABARAP macrocycle binds with a KD of 6 nM and a sub-nanomolar IC50 in vitro. For one of the targets, RbtA, we obtain a high-affinity binder with KD < 10 nM despite starting from the target sequence alone due to the lack of an experimentally determined target structure. X-ray structures determined for macrocycle-bound MCL1, GABARAP, and RbtA complexes match very closely with the computational design models, with three out of the four structures demonstrating Ca RMSD of less than 1.5 Å to the design models. In contrast to library screening approaches for which determining binding mode can be a major bottleneck, the binding modes of RFpeptides-generated macrocycles are known by design, which should greatly facilitate downstream optimization. RFpeptides thus provides a powerful framework for rapid and custom design of macrocyclic peptides for diagnostic and therapeutic applications.

Targeted protein degradation: current molecular targets, localization, and strategies

Targeted protein degradation (TPD) has revolutionized drug discovery by selectively eliminating specific proteins within and outside the cellular context. Over the past two decades, TPD has expanded its focus beyond well-established targets, exploring diverse proteins beyond cancer-related ones. This evolution extends the potential of TPD to various diseases. Notably, TPD can target proteins at demanding locations, such as the extracellular matrix (ECM) and cellular membranes, presenting both opportunities and challenges for future research. In this review, we comprehensively examine the exciting opportunities in the burgeoning field of TPD, highlighting different targets, their cellular environment, and innovative strategies for modern drug discovery.

Toward effective Atg8-based ATTECs: Approaches and perspectives

Induction of Atg8-family protein (LC3/GABARAP proteins in human) interactions with target proteins of interest by proximity-inducing small molecules offers the possibility for novel targeted protein degradation approaches. However, despite intensive screening campaigns during the last 5 years, no potent ligands for LC3/GABARAPs have been developed, rendering this approach largely unexplored and unsuitable for therapeutic exploitation. In this Viewpoint, we analyze the reported attempts identifying LC3/GABARAP inhibitors and provide our own point of view why no potent inhibitors have been found. Additionally, we designate reasonable directions for the identification of potent and probably selective LC3/GABARAP inhibitors for alternative therapeutic applications.

Targeting selective autophagy in CNS disorders by small-molecule compounds

Autophagy functions as the primary cellular mechanism for clearing unwanted intracellular contents. Emerging evidence suggests that the selective elimination of intracellular organelles through autophagy, compared to the increased bulk autophagic flux, is crucial for the pathological progression of central nervous system (CNS) disorders. Notably, autophagic removal of mitochondria, known as mitophagy, is well-understood in an unhealthy brain. Accumulated data indicate that selective autophagy of other substrates, including protein aggregates, liposomes, and endoplasmic reticulum, plays distinctive roles in various pathological stages. Despite variations in substrates, the molecular mechanisms governing selective autophagy can be broadly categorized into two types: ubiquitin-dependent and -independent pathways, both of which can be subjected to regulation by small-molecule compounds. Notably, natural products provide the remarkable possibility for future structural optimization to regulate the highly selective autophagic clearance of diverse substrates. In this context, we emphasize the selectivity of autophagy in regulating CNS disorders and provide an overview of chemical compounds capable of modulating selective autophagy in these disorders, along with the underlying mechanisms. Further exploration of the functions of these compounds will in turn advance our understanding of autophagic contributions to brain disorders and illuminate precise therapeutic strategies for these diseases.

Recent breakthroughs in innovative elements, multidimensional enhancements, derived technologies, and novel applications of PROTACs

Proteolysis Targeting Chimera (PROTAC) is an emerging and evolving technology based on targeted protein degradation (TPD). Small molecule PROTACs have shown great efficacy in degrading disease-specific proteins in preclinical and clinical studies, but also showed various limitations. In recent years, new technologies and advances in TPD have provided additional optimized strategies based on conventional PROTACs that can overcome the shortcomings of conventional PROTACs in terms of undruggable targets, bioavailability, tissue-specificity, spatiotemporal control, and degradation scope. In addition, some designs of special targeting chimeras and applications based on multidisciplinary science have shed light on novel therapeutic modalities and drug design. However, each improvement has its own advantages, disadvantages and application conditions. In this review, we summarize the exploration of PROTAC elements, depict a landscape of improvements and derived concepts of PROTACs, and expect to provide perspectives for technological innovations, combinations and applications in future targeting chimera design.

How to target membrane proteins for degradation: Bringing GPCRs into the TPD fold

We are now in the middle of a so-called "fourth wave" of drug innovation: multispecific medicines aimed at diseases and targets previously thought to be "undruggable"; by inducing proximity between two or more proteins, for example, a target and an effector that do not naturally interact, such modalities have potential far beyond the scope of conventional drugs. In particular, targeted protein degradation (TPD) strategies to destroy disease-associated proteins have emerged as an exciting pipeline in drug discovery. Most efforts are focused on intracellular proteins, whereas membrane proteins have been less thoroughly explored despite the fact that they comprise roughly a quarter of the human proteome with G-protein coupled receptors (GPCRs) notably dysregulated in many diseases. Here, we discuss the opportunities and challenges of developing degraders for membrane proteins with a focus on GPCRs. We provide an overview of different TPD platforms in the context of membrane-tethered targets, and we present recent degradation technologies highlighting their potential application to GPCRs.

Methylarginine targeting chimeras for lysosomal degradation of intracellular proteins

A paradigm shift in drug development is the discovery of small molecules that harness the ubiquitin-proteasomal pathway to eliminate pathogenic proteins. Here we provide a modality for targeted protein degradation in lysosomes. We exploit an endogenous lysosomal pathway whereby protein arginine methyltransferases (PRMTs) initiate substrate degradation via arginine methylation. We developed a heterobifunctional small molecule, methylarginine targeting chimera (MrTAC), that recruits PRMT1 to a target protein for induced degradation in lysosomes. MrTAC compounds degraded substrates across cell lines, timescales and doses. MrTAC degradation required target protein methylation for subsequent lysosomal delivery via microautophagy. A library of MrTAC molecules exemplified the generality of MrTAC to degrade known targets and neo-substrates-glycogen synthase kinase 3β, MYC, bromodomain-containing protein 4 and histone deacetylase 6. MrTAC selectively degraded target proteins and drove biological loss-of-function phenotypes in survival, transcription and proliferation. Collectively, MrTAC demonstrates the utility of endogenous lysosomal proteolysis in the generation of a new class of small molecule degraders.

Pooled endogenous protein tagging and recruitment for systematic profiling of protein function

The emerging field of induced proximity therapeutics, which involves designing molecules to bring together an effector and target protein-typically to induce target degradation-is rapidly advancing. However, its progress is constrained by the lack of scalable and unbiased tools to explore effector-target protein interactions. We combine pooled endogenous gene tagging using a ligand-binding domain with generic small-molecule-based recruitment to screen for induction of protein proximity. We apply this methodology to identify effectors for degradation in two orthogonal screens: using fluorescence to monitor target levels and a cellular growth that depends on the degradation of an essential protein. Our screens revealed new effector proteins for degradation, including previously established examples, and converged on members of the C-terminal-to-LisH (CTLH) complex. We introduce a platform for pooled induction of endogenous protein-protein interactions to expand our toolset of effector proteins for protein degradation and other forms of induced proximity.

Autophagy modulation in cancer therapy: Challenges coexist with opportunities

Autophagy, a crucial intracellular degradation process facilitated by lysosomes, plays a pivotal role in maintaining cellular homeostasis. The elucidation of autophagy key genes and signaling pathways has significantly advanced our understanding of this process and has led to the exploration of autophagy as a promising therapeutic approach. This review comprehensively assesses the latest developments in small molecule modulators targeting autophagy. Moreover, the review delves into the most recent strategies for drug discovery, specifically focusing on selective agents that exploit autophagosomes and lysosomes for targeted protein degradation. Additionally, this article highlights the prevailing challenges and outlines potential future advancements in the field. By amalgamating the cutting-edge knowledge in the field, we aim to offer valuable insights and references for the anti-cancer drug development of autophagy-targeted therapies, thus contributing to the advancement of novel therapeutic interventions.

Proteolysis-targeting drug delivery system (ProDDS): integrating targeted protein degradation concepts into formulation design

Targeted protein degradation (TPD) has emerged as a revolutionary paradigm in drug discovery and development, offering a promising avenue to tackle challenging therapeutic targets. Unlike traditional drug discovery approaches that focus on inhibiting protein function, TPD aims to eliminate proteins of interest (POIs) using modular chimeric structures. This is achieved through the utilization of proteolysis-targeting chimeras (PROTACs), which redirect POIs to E3 ubiquitin ligases, rendering them for degradation by the cellular ubiquitin-proteasome system (UPS). Additionally, other TPD technologies such as lysosome-targeting chimeras (LYTACs) and autophagy-based protein degraders facilitate the transportation of proteins to  endo-lysosomal or autophagy-lysosomal pathways for degradation, respectively. Despite significant growth in preclinical TPD research, many chimeras fail to progress beyond this stage in the drug development. Various factors contribute to the limited success of TPD agents, including a significant hurdle of inadequate delivery to the target site. Integrating TPD into delivery platforms could surmount the challenges of in vivo applications of TPD strategies by reshaping their pharmacokinetics and pharmacodynamic profiles. These proteolysis-targeting drug delivery systems (ProDDSs) exhibit superior delivery performance, enhanced targetability, and reduced off-tissue side effects. In this review, we will survey the latest progress in TPD-inspired drug delivery systems, highlight the importance of introducing delivery ideas or technologies to the development of protein degraders, outline design principles of protein degrader-inspired delivery systems, discuss the current challenges, and provide an outlook on future opportunities in this field.

Autophagy receptor-inspired chimeras: a novel approach to facilitate the removal of protein aggregates and organelle by autophagy degradation

Neurodegenerative diseases (NDDs), mainly including Huntington's disease (HD), amyotrophic lateral sclerosis (ALS), and Alzheimer's disease (AD), are sporadic and rare genetic disorders of the central nervous system. A key feature of these conditions is the slow accumulation of misfolded protein deposits in brain neurons, the excessive aggregation of which leads to neurotoxicity and further disorders of the nervous system.

Molecular glue-mediated targeted protein degradation: A novel strategy in small-molecule drug development

Small-molecule drugs are effective and thus most widely used. However, their applications are limited by their reliance on active high-affinity binding sites, restricting their target options. A breakthrough approach involves molecular glues, a novel class of small-molecule compounds capable of inducing protein-protein interactions (PPIs). This opens avenues to target conventionally undruggable proteins, overcoming limitations seen in conventional small-molecule drugs. Molecular glues play a key role in targeted protein degradation (TPD) techniques, including ubiquitin-proteasome system-based approaches such as proteolysis targeting chimeras (PROTACs) and molecular glue degraders and recently emergent lysosome system-based techniques like molecular degraders of extracellular proteins through the asialoglycoprotein receptors (MoDE-As) and macroautophagy degradation targeting chimeras (MADTACs). These techniques enable an innovative targeted degradation strategy for prolonged inhibition of pathology-associated proteins. This review provides an overview of them, emphasizing the clinical potential of molecular glues and guiding the development of molecular-glue-mediated TPD techniques.

To homeostasis and beyond! Recent advances in the medicinal chemistry of heterobifunctional derivatives

The field of induced proximity therapeutics has expanded dramatically over the past 3 years, and heterobifunctional derivatives continue to form a significant component of the activities in this field. Here, we review recent advances in the field from the perspective of the medicinal chemist, with a particular focus upon informative case studies, alongside a review of emerging topics such as Direct-To-Biology (D2B) methodology and utilities for heterobifunctional compounds beyond E3 ligase mediated degradation. We also include a critical evaluation of the latest thinking around the optimisation of physicochemical and pharmacokinetic attributes of these beyond Role of Five molecules, to deliver appropriate therapeutic exposure in vivo.

Targeting the STAT3 pathway with STAT3 degraders

Signal transducer and activator of transcription 3 (STAT3) has been widely considered as a therapeutic target for various diseases, especially tumors. Thus far, several STAT3 inhibitors have been advanced to clinical trials; however, the development of STAT3 inhibitors is hindered by numerous dilemmas. Fortunately, STAT3 degraders represent an alternative and promising strategy to block STAT3, attracting extensive research interest. Here, we analyze the recent advancements of STAT3 degraders, including proteolysis targeting chimeras (PROTACs) and small-molecule natural products, focusing on their structures, mechanisms, and biological activities. We discuss the potential opportunities and challenges for developing STAT3 degraders. It is hoped that this Review will provide insights into the discovery of potent STAT3-targeting drugs.

Lysosomal dysfunction-derived autophagy impairment of gingival epithelial cells in diabetes-associated periodontitis with altered protein acetylation

Diabetes-associated periodontitis (DP) presents severe inflammation and resistance to periodontal conventional treatment, presenting a significant challenge in clinical management. In this study, we investigated the underlying mechanism driving the hyperinflammatory response in gingival epithelial cells (GECs) of DP patients. Our findings indicate that lysosomal dysfunction under high glucose conditions leads to the blockage of autophagy flux, exacerbating inflammatory response in GECs. Single-cell RNA sequencing and immunohistochemistry analyses of clinical gingival epithelia revealed dysregulation in the lysosome pathway characterized by reduced levels of lysosome-associated membrane glycoprotein 2 (LAMP2) and V-type proton ATPase 16 kDa proteolipid subunit c (ATP6V0C) in subjects with DP. In vitro stimulation of human gingival epithelial cells (HGECs) with a hyperglycemic microenvironment showed elevated release of proinflammatory cytokines, compromised lysosomal acidity and blocked autophagy. Moreover, HGECs with deficiency in ATP6V0C demonstrated impaired autophagy and heightened inflammatory response, mirroring the effects of high glucose stimulation. Proteomic analysis of acetylation modifications identified altered acetylation levels in 28 autophagy-lysosome pathway-related proteins and 37 sites in HGECs subjected to high glucose stimulation or siATP6V0C. Overall, our finding highlights the pivotal role of lysosome impairment in autophagy obstruction in DP and suggests a potential impact of altered acetylation of relevant proteins on the interplay between lysosome dysfunction and autophagy blockage. These insights may pave the way for the development of effective therapeutic strategies against DP.

Targeting EGFR with molecular degraders as a promising strategy to overcome resistance to EGFR inhibitors

Abnormal activation of EGFR is often associated with various malignant tumors, making it an important target for antitumor therapy. However, traditional targeted inhibitors have several limitations, such as drug resistance and side effects. Many studies have focused on the development of EGFR degraders to overcome this resistance and enhance the therapeutic effect on tumors. Proteolysis targeting chimeras (PROTAC) and Lysosome-based degradation techniques have made significant progress in degrading EGFR. This review provides a summary of the structural and function of EGFR, the resistance, particularly the research progress and activity of EGFR degraders via the proteasome and lysosome. Furthermore, this review aims to provide insights for the development of the novel EGFR degraders.