Harnessing PROTACs to combat H5N1 influenza: A new frontier in viral destruction.

H5N1, a highly pathogenic avian influenza virus, poses an ongoing and significant threat to global public health, primarily due to its potential to cause severe respiratory illness and high mortality rates in humans. Despite extensive efforts in vaccination and antiviral therapy, H5N1 continues to exhibit high mutation rates, resulting in recurrent outbreaks and the emergence of drug-resistant strains. Traditional antiviral therapies, such as neuraminidase inhibitors and M2 ion channel blockers, have demonstrated limited efficacy, necessitating the exploration of innovative therapeutic strategies. Proteolysis-targeting chimeras (PROTACs) emerge as a novel and promising approach, leveraging the ubiquitin-proteasome system to selectively degrade pathogenic proteins. Unlike conventional inhibitors that only block protein function, PROTACs eliminate the target protein, providing a sustained therapeutic effect and potentially reducing the development of resistance. This paper offers a comprehensive examination of the current landscape of H5N1 infections, detailing the pathogenesis and challenges associated with existing treatments. It further explores the mechanism of action, design, and therapeutic potential of PROTACs in inhibiting H5N1. By targeting essential viral proteins, such as hemagglutinin and the RNA-dependent RNA polymerase complex, PROTACs hold the potential to revolutionize the treatment of H5N1 infections, offering a new frontier in antiviral therapy.

FBXO38 is dispensable for PD-1 regulation.

SKP1-CUL1-F-box protein (SCF) ubiquitin ligases are versatile protein complexes that mediate the ubiquitination of protein substrates. The direct substrate recognition relies on a large family of F-box-domain-containing subunits. One of these substrate receptors is FBXO38, which is encoded by a gene found mutated in families with early-onset distal motor neuronopathy. SCFFBXO38 ubiquitin ligase controls the stability of ZXDB, a nuclear factor associated with the centromeric chromatin protein CENP-B. Loss of FBXO38 in mice results in growth retardation and defects in spermatogenesis characterized by deregulation of the Sertoli cell transcription program and compromised centromere integrity. Moreover, it was reported that SCFFBXO38 mediates the degradation of PD-1, a key immune-checkpoint inhibitor in T cells. Here, we have re-addressed the link between SCFFBXO38 and PD-1 proteolysis. Our data do not support the notion that SCFFBXO38 directly or indirectly controls the abundance and stability of PD-1 in T cells.

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.

Lactobacillus delbrueckii alleviates lipopolysaccharide-induced muscle inflammation and atrophy in weaned piglets associated with inhibition of endoplasmic reticulum stress and protein degradation.

Pro-inflammatory cytokines in muscle play a pivotal role in physiological responses and in the pathophysiology of inflammatory disease and muscle atrophy. Lactobacillus delbrueckii (LD), as a kind of probiotics, has inhibitory effects on pro-inflammatory cytokines associated with various inflammatory diseases. This study was conducted to explore the effect of dietary LD on the lipopolysaccharide (LPS)-induced muscle inflammation and atrophy in piglets and to elucidate the underlying mechanism. A total of 36 weaned piglets (Duroc × Landrace × Large Yorkshire) were allotted into three groups with six replicates (pens) of two piglets: (1) Nonchallenged control; (2) LPS-challenged (LPS); (3) 0.2% LD diet and LPS-challenged (LD+LPS). On d 29, the piglets were injected intraperitoneally with LPS or sterilized saline, respectively. All piglets were slaughtered at 4 h after LPS or saline injection, the blood and muscle samples were collected for further analysis. Our results showed that dietary supplementation of LD significantly attenuated LPS-induced production of pro-inflammatory cytokines IL-6 and TNF-α in both serum and muscle of the piglets. Concomitantly, pretreating the piglets with LD also clearly inhibited LPS-induced nuclear translocation of NF-κB p65 subunits in the muscle, which correlated with the anti-inflammatory effects of LD on the muscle of piglets. Meanwhile, LPS-induced muscle atrophy, indicated by a higher expression of muscle atrophy F-box, muscle RING finger protein (MuRF1), forkhead box O 1, and autophagy-related protein 5 (ATG5) at the transcriptional level, whereas pretreatment with LD led to inhibition of these upregulations, particularly genes for MuRF1 and ATG5. Moreover, LPS-induced mRNA expression of endoplasmic reticulum stress markers, such as eukaryotic translational initiation factor 2α (eIF-2α) was suppressed by pretreatment with LD, which was accompanied by a decrease in the protein expression levels of IRE1α and GRP78. Additionally, LD significantly prevented muscle cell apoptotic death induced by LPS. Taken together, our data indicate that the anti-inflammatory effect of LD supply on muscle atrophy of piglets could be likely regulated by inhibiting the secretion of pro-inflammatory cytokines through the inactivation of the ER stress/NF-κB singling pathway, along with the reduction in protein degradation.

An updated patent review of BRD4 degraders.

INTRODUCTION: Bromodomain-containing protein 4 (BRD4), an important epigenetic reader, is closely associated with the pathogenesis and development of many diseases, including various cancers, inflammation, and infectious diseases. Targeting BRD4 inhibition or protein elimination with small molecules represents a promising therapeutic strategy, particularly for cancer therapy. AREAS COVERED: The recent advances of patented BRD4 degraders were summarized. The challenges, opportunities, and future directions for developing novel potent and selective BRD4 degraders are also discussed. The patents of BRD4 degraders were searched using the SciFinder and Cortellis Drug Discovery Intelligence database. EXPERT OPINION: BRD4 degraders exhibit superior efficacy and selectivity to BRD4 inhibitors, given their unique mechanism of protein degradation instead of protein inhibition. Excitingly, RNK05047 is now in phase I/II clinical trials, indicating that selective BRD4 protein degradation may offer a viable therapeutic strategy, particularly for cancer. Targeting BRD4 with small-molecule degraders provides a promising approach with the potential to overcome therapeutic resistance for treating various BRD4-associated diseases.

Patenting perspective of modulators of ClpP endopeptidase: 2019-present.

INTRODUCTION: ClpP is a highly conserved serine protease that plays a crucial role in maintaining protein homeostasis in both bacterial cells and human mitochondria. Several studies have demonstrated the potential of ClpP as a drug target, with ClpP modulators, including both inhibitors and activators, showing promise in treating a range of conditions such as drug-resistant bacteria, malignant cancers, and fatty liver disease. AREA COVERED: This review provides an overview of patents related to ClpP modulators filed over the last five years, detailing their claims and therapeutic applications. The sources of patent information included databases of the European Patent Office, the China Patent Office and the U.S.A. patent Office, while relevant research articles were accessed through PubMed. EXPERT OPINION: The number of patents concerning ClpP modulators is on the rise, reflecting advancements in related research. By summarizing and outlining relevant patents, we aim to stimulate further interest among researchers, ultimately leading to the development of effective drugs based on ClpP modulators. The broad spectrum of diseases associated with ClpP dysfunction underscores the potential for ClpP modulators to address a wide range of therapeutic needs.

Effect of brine concentration on the quality of salted large yellow croaker during processing and refrigeration.

This study aimed to evaluate the effect of brine concentrations (4%, 8%, 12%, 16%) on the quality of salted large yellow croakers. During the wet salting processing, increased salinity inhibited myogenic fibers swelling and extracellular space expansion, and resulted in lower water content and higher salt content of salted large yellow croaker products. During refrigeration of salted large yellow croakers at 4 °C for 24 days, SDS-PAGE patterns showed that high salinity slowed down the degradation of proteins, which was further confirmed by changes in free amino acids (FAAs) and biogenic amine contents. The increases in K value, total volatile basic nitrogen (TVB-N) content, total viable counts (TVC) and the deterioration in sensory were delayed by increasing salinity. Notably, high salinity enhanced malondialdehyde (MDA) accumulation. The results suggested that high salinity inhibited tissue structure destruction, microbial growth, protein degradation and freshness reduction, but accelerated lipid oxidation of salted large yellow croakers. Supplementary Information: The online version contains supplementary material available at 10.1007/s10068-024-01573-5.

The role of ubiquitination in health and disease.

Ubiquitination is an enzymatic process characterized by the covalent attachment of ubiquitin to target proteins, thereby modulating their degradation, transportation, and signal transduction. By precisely regulating protein quality and quantity, ubiquitination is essential for maintaining protein homeostasis, DNA repair, cell cycle regulation, and immune responses. Nevertheless, the diversity of ubiquitin enzymes and their extensive involvement in numerous biological processes contribute to the complexity and variety of diseases resulting from their dysregulation. The ubiquitination process relies on a sophisticated enzymatic system, ubiquitin domains, and ubiquitin receptors, which collectively impart versatility to the ubiquitination pathway. The widespread presence of ubiquitin highlights its potential to induce pathological conditions. Ubiquitinated proteins are predominantly degraded through the proteasomal system, which also plays a key role in regulating protein localization and transport, as well as involvement in inflammatory pathways. This review systematically delineates the roles of ubiquitination in maintaining protein homeostasis, DNA repair, genomic stability, cell cycle regulation, cellular proliferation, and immune and inflammatory responses. Furthermore, the mechanisms by which ubiquitination is implicated in various pathologies, alongside current modulators of ubiquitination are discussed. Enhancing our comprehension of ubiquitination aims to provide novel insights into diseases involving ubiquitination and to propose innovative therapeutic strategies for clinical conditions.

Efficient PROTAC-ing: combinational use of PROTACs with signaling pathway inhibitors.

Targeted protein degradation is an innovative therapeutic modality for the degradation of disease-causing proteins. In a recent report combining high-throughput screening of small-molecule compounds and biochemical analyses, Mori et al. identified certain inhibitors of cellular pathways, such as PARylation and proteostatic pathways, which enhance proteolysis-targeting chimera (PROTAC)-induced protein degradation.

Decreased SREBP2 of the striatal cell relates to disrupted protein degradation in Huntington's disease.

This study delineated the intricate relation between cholesterol metabolism, protein degradation mechanisms, and the pathogenesis of Huntington's disease (HD). Through investigations using both animal models and cellular systems, we have observed significant alterations in cholesterol levels, particularly in the striatum, which is the primary lesion site in HD. Our findings indicate the dysregulation of cholesterol metabolism-related factors, such as LDLR and SREBP2, in HD, which may contribute to disease progression. Additionally, we uncovered disruptions in protein degradation pathways, including decreased neddylated proteins and dysregulated autophagy, which further exacerbated HD pathology. Moreover, our study highlighted the potential therapeutic implications of targeting these pathways. By restoring cholesterol levels and modulating protein degradation mechanisms, particularly through interventions, such as MLN4924, we observed potential improvements in cellular function, as indicated by the increased BDNF levels. These insights underscore the importance of simultaneously addressing cholesterol metabolism and protein degradation to alleviate HD pathology. Collectively, this study provides a basic understanding of the interplay between the decrease of SREBP2 and the dysfunctional protein degradation system derived from disrupted cholesterol metabolism in HD and HD cells.

Chemically induced degradation of PRC2 complex by EZH2-Targeted PROTACs via a Ubiquitin-Proteasome pathway.

Enhancer of zeste homolog 2 (EZH2) is a histone methyltransferase that plays an important role in cancer cells biology. However, present EZH2 inhibitors in clinic have not achieved satisfactory efficacy. Herein, a number of EZH2-targeted PROTAC compounds were designed and synthesized by selecting different linkers, using Tazemetostat as the protein of interest (POI) portion of PROTAC molecules, hoping to improve the defects of existing EZH2 inhibitors effectively. Among all the target compounds, ZJ-20 showed the best performance with an IC50 value of 5.0 nM against MINO cells, good pharmacokinetics parameters and a limited acceptable oral bioavailability. Significantly, ZJ-20 could achieve degradation of the entire PRC2 complex by targeting EZH2, which can serve as a lead compound for further study.

Molecular glue triggers degradation of PHGDH by enhancing the interaction between DDB1 and PHGDH.

Cancer stem cells (CSCs) play a pivotal role in tumor initiation, proliferation, metastasis, drug resistance, and recurrence. Consequently, targeting CSCs has emerged as a promising avenue for cancer therapy. Recently, 3-phosphoglycerate dehydrogenase (PHGDH) has been identified as being intricately associated with the regulation of numerous cancer stem cells. Yet, reports detailing the functional regulators of PHGDH that can mitigate the stemness across cancer types are limited. In this study, the novel "molecular glue" LXH-3-71 was identified, and it robustly induced degradation of PHGDH, thereby modulating the stemness of colorectal cancer cells (CRCs) both in vitro and in vivo. Remarkably, LXH-3-71 was observed to form a dynamic chimera, between PHGDH and the DDB1-CRL E3 ligase. These insights not only elucidate the anti-CSCs mechanism of the lead compound but also suggest that degradation of PHGDH may be a more viable therapeutic strategy than the development of PHGDH inhibitors. Additionally, compound LXH-3-71 was leveraged as a novel ligand for the DDB1-CRL E3 ligase, facilitating the development of new PROTAC molecules targeting EGFR and CDK4 degradation.

Investigating NanoLuc-EGFR engineered cell lines for real-time monitoring of EGFR protein dynamics in live cells.

Evaluating the steady-state protein level of the EGFR in live cells presents significant challenges compared to measuring its kinase activity. Traditional testing methods, such as immunoblotting, ELISA, and immunofluorescence assays, are generally restricted to fixed cells or cell lysates. Despite their utility, these methods are cumbersome and provide only intermittent snapshots of EGFR levels at specific time points. With emerging trends in drug development shifting toward engineering novel agents that promote protein degradation, rather than simply inhibiting kinase activity, a tool that enables real-time, quantitative detection of drug effects in live cells could catalyze advances in the field. Such an innovation would expedite the drug development process, enhancing the translation of research findings into effective, patient-centered therapies. The NanoLuc-EGFR cell line, created through CRISPR genome editing, allows for the continuous tracking and analysis of EGFR protein levels and their degradation within live cells. This approach provides quantitative monitoring of protein dynamics in real time, offering insights that go beyond absolute protein levels to include aspects such as protein stability and degradation rate. Using this cell line model, we observed that AT13387 and H84T BanLec induce EGFR degradation in A549-HiBiT cells, with the results confirmed by immunoblotting. In contrast, Erlotinib, Osimertinib, and Cetuximab inhibit EGFR phosphorylation without altering total EGFR levels, as validated by the HiBiT luciferase assay. The NanoLuc-EGFR cell line marks a significant advancement in understanding protein regulation and serves as an instrumental platform for investigating targeted therapies that modulate protein kinases, especially those that induce protein degradation.

High resolution analysis of proteolytic substrate processing.

Members of the widely conserved HtrA family of serine proteases are involved in multiple aspects of protein quality control. In this context, they have been shown to efficiently degrade misfolded proteins or protein fragments. However, recent reports suggest that folded proteins can also be native substrates. To gain a deeper understanding of how folded proteins are initially processed and subsequently degraded into short peptides by human HTRA1, we established an integrated and quantitative approach using time-resolved mass spectrometry, circular dichroism spectroscopy and bioinformatics. The resulting data provide high-resolution information on up to 178 individual proteolytic sites within folded ANXA1 (consisting of 346 amino acids), the relative frequency of cuts at each proteolytic site, the preferences of the protease for the amino acid sequence surrounding the scissile bond, as well as the degrees of sequential structural relaxation and unfolding of the substrate that occur during progressive degradation. Our workflow provides precise molecular insights into protease-substrate interactions, which could be readily adapted to address other post-translational modifications such as phosphorylation in dynamic protein complexes.

Safety and clinical activity of BMS-986365 (CC-94676), a dual androgen receptor ligand-directed degrader and antagonist, in heavily pretreated patients with metastatic castration-resistant prostate cancer.

BACKGROUND: Metastatic castration-resistant prostate cancer (mCRPC) that progresses on androgen receptor pathway inhibitors (ARPIs) may continue to be driven by AR signaling. BMS-986365 is an orally administered ligand-directed degrader targeting the AR via a first-in-class dual mechanism of AR degradation and antagonism. CC-94676-PCA-001 (NCT04428788) is a phase 1 multicenter study of BMS-986365 in patients with progressive mCRPC. PATIENTS AND METHODS: Patients who progressed on androgen deprivation therapy, ≥ 1 ARPI, and taxane chemotherapy (unless declined/ineligible) were enrolled. The study included dose escalation (Part A) and expansion (Part B) of BMS-986365 up to 900 mg twice daily (BID). Primary objectives were safety, tolerability, and to define maximum tolerated dose (MTD) and/or recommended phase 2 dose (RP2D). Key secondary endpoints included decline in prostate-specific antigen ≥50% (PSA50) and radiographic progression-free survival (rPFS). RESULTS: Parts A and B enrolled 27 and 68 patients, respectively. In Part B, the median number of prior therapies was 4 (range 2-11). The most common treatment-related adverse events (TRAEs) were asymptomatic prolonged corrected QT interval (47%) and bradycardia (34%). Part A MTD was not reached and RP2D selection is ongoing. Across Part B three highest doses (400-900 mg BID, n = 60), PSA50 was 32% (n = 19), including 50% (n = 10/20) at 900 mg; median rPFS (95% CI) was 6.3 months (5.3-12.6), including 8.3 months (3.8-16.6) at 900 mg; and rPFS was longer in patients without versus with prior chemotherapy: 16.5 months (5.5-not evaluable) versus 5.5 months (2.7-8.3), respectively. Efficacy was observed in patients with AR ligand binding domain (LBD) WT or with AR LBD mutations. CONCLUSIONS: BMS-986365 was well tolerated, with a manageable safety profile, and demonstrated activity in heavily pretreated patients with potentially higher benefit in chemotherapy-naïve patients. These data show BMS-986365's potential to overcome resistance to current ARPIs, regardless of AR LBD mutation status.

Quantitative mapping of proteasome interactomes and substrates using ProteasomeID.

Proteasomes are essential molecular machines responsible for the degradation of proteins in eukaryotic cells. Altered proteasome activity has been linked to neurodegeneration, auto-immune disorders and cancer. Despite the relevance for human disease and drug development, no method currently exists to monitor proteasome composition and interactions in vivo in animal models. To fill this gap, we developed a strategy based on tagging of proteasomes with promiscuous biotin ligases and generated a new mouse model enabling the quantification of proteasome interactions by mass spectrometry. We show that biotin ligases can be incorporated in fully assembled proteasomes without negative impact on their activity. We demonstrate the utility of our method by identifying novel proteasome-interacting proteins, charting interactomes across mouse organs, and showing that proximity-labeling enables the identification of both endogenous and small-molecule-induced proteasome substrates.

Selective Protein Degradation through Tetrazine Ligation of Genetically Incorporated Unnatural Amino Acids.

Small molecule-responsive tags for targeted protein degradation are valuable tools for fundamental research and drug target validation. Here, we show that genetically incorporated unnatural amino acids bearing a strained alkene or alkyne functionality can act as a minimalist tag for targeted protein degradation. Specifically, we observed the degradation of strained alkene- or alkyne-containing kinases and E2 ubiquitin-conjugating enzymes upon treatment with hydrophobic tetrazine conjugates. The extent of the induced protein degradation depends on the identity of the target protein, unnatural amino acid, and tetrazine conjugate, as well as the site of the unnatural amino acid in the target protein. Mechanistic studies revealed proteins undergo proteasomal degradation after tetrazine tethering, and the identity of tetrazine conjugates influences the dependence of ubiquitination on protein degradation. This work provides an alternative approach for targeted protein degradation and mechanistic insight, facilitating the future development of more effective targeted protein degradation strategies.

Targeted degradation of METTL3 against acute myeloid leukemia and gastric cancer.

Accumulating evidence reveals the oncogenic role of methyltransferase-like 3 (METTL3) in a variety of cancers, either dependent or independent of its m6A methyl transferase activity. We have explored PROTACs targeting METTL3 and identified KH12 as a potent METTL3 degrader. Treatment of KH12 on MOLM-13 cells causes degradation of METTL3 with a DC50 value of 220 nM in a dose-, time- and ubiquitin-dependent fashion. In addition, KH12 is capable of reversing differentiation and possesses anti-proliferative effects surpassing the small molecule inhibitors on MOLM-13 cells. Notably, we first present that METTL3 degrader significantly suppresses the growth of various gastric cancer (GC) cells, where the m6A-independent activity of METTL3 plays a crucial role in tumorigenesis. The anti-GC effects of KH12 were further confirmed in patient-derived organoids (PDOs). This study offers therapeutic potentials of targeted degradation of METTL3 against GC implicated with non-catalytic function of METTL3 as well as against AML.

Differential regulation of physicochemical properties and myofibrillar protein degradation of yak meat by interactions between reactive oxygen species and reactive nitrogen species during postmortem aging.

BACKGROUND: This study aimed to explore how interactions between reactive oxygen species (ROS) and reactive nitrogen species (RNS) affect oxidative properties, nitrosative properties, and myofibrillar protein degradation during postmortem aging of yak meat. RESULTS: Yak longissimus dorsi was incubated with saline, ROS activator (H2O2)/inhibitor N-Acetyl-L-cysteine (NAC) and RNS activator S-Nitrosoglutathione (GSNO)/inhibitor L-NAME hydrochloride (L-NAME) combined treatments at 4 °C for 12, 24, 72, 120, and 168 h. The results indicated that regardless of whether RNS was activated or inhibited, activated ROS played a dominant role in myofibrillar protein degradation by oxidative modification to increase carbonyl content, disulfide bonds, surface hydrophobicity, and dimerized tyrosine while decreasing sulfhydryl content, thereby degrading nebulin, titin, troponin-t and desmin. Notably, the Warner-Bratzler shear force (WBSF) of the H2O2 + L-NAME group was the smallest, whereas that of the NAC + GSNO group was smaller than that of the NAC + L-NAME group. CONCLUSION: These findings provide new insights into meat tenderization patterns through the interaction between ROS and RNS. © 2024 Society of Chemical Industry.

Cellular stress increases DRIP production and MHC Class I antigen presentation.

Background: Defective ribosomal products (DRiPs) are non-functional proteins rapidly degraded during or after translation being an essential source for MHC class I ligands. DRiPs are characterized to derive from a substantial subset of nascent gene products that degrade more rapidly than their corresponding native retiree pool. So far, mass spectrometry analysis revealed that a large number of HLA class I peptides derive from DRiPs. However, a specific viral DRiP on protein level was not described. In this study, we aimed to characterize and identify DRiPs derived from a viral protein. Methods: Using the nucleoprotein (NP) of the lymphocytic choriomeningitis virus (LCMV) which is conjugated N-terminally to ubiquitin, or the ubiquitin-like modifiers FAT10 or ISG15 the occurrence of DRiPs was studied. The formation and degradation of DRiPs was monitored by western blot with the help of a FLAG tag. Flow cytometry and cytotoxic T cells were used to study antigen presentation. Results: We identified several short lived DRiPs derived from LCMV-NP. Of note, these DRiPs could only be observed when the LCMV-NP was modified with ubiquitin or ubiquitin-like modifiers, but not in the wild type form. Using proteasome inhibitors, we could show that degradation of LCMV-NP derived DRiPs were proteasome dependent. Interestingly, the synthesis of DRiPs could be enhanced when cells were stressed with the help of FCS starvation. An enhanced NP118-126 presentation was observed when the LCMV-NP was modified with ubiquitin or ubiquitin-like modifiers, or under FCS starvation. Conclusion: Taken together, we visualize for the first time DRiPs derived from a viral protein. Furthermore, DRiPs formation, and therefore MHC-I presentation, is enhanced under cellular stress conditions. Our investigations on DRiPs in MHC class I antigen presentation open up new approaches for the development of vaccination strategies.