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Targeted protein degradation offers an alternative modality to classical inhibition and holds the promise of addressing previously undruggable targets to provide novel therapeutic options for patients. Heterobifunctional molecules co-recruit a target protein and an E3 ligase, resulting in ubiquitylation and proteosome-dependent degradation of the target. In the clinic, the oral route of administration is the option of choice but has only been achieved so far by CRBN- recruiting bifunctional degrader molecules. We aimed to achieve orally bioavailable molecules that selectively degrade the BAF Chromatin Remodelling complex ATPase SMARCA2 over its closely related paralogue SMARCA4, to allow in vivo evaluation of the synthetic lethality concept of SMARCA2 dependency in SMARCA4-deficient cancers. Here we outline structure- and property-guided approaches that led to orally bioavailable VHL-recruiting degraders. Our tool compound, ACBI2, shows selective degradation of SMARCA2 over SMARCA4 in ex vivo human whole blood assays and in vivo efficacy in SMARCA4-deficient cancer models. This study demonstrates the feasibility for broadening the E3 ligase and physicochemical space that can be utilised for achieving oral efficacy with bifunctional molecules. Protein degraders are an emerging drug modality; however, their properties lie beyond typical drug-like space. Here the authors report optimisation via structure-based exit vector and linker design towards the VHL-recruiting PROTAC ACBI2, an orally bioavailable and selective degrader of SMARCA2.

Pharmacological probes are important tools for exploring disease biology and discovering new therapies. Often molecules of insufficient quality are used instead, leading to spurious and misleading results. The Boehringer Ingelheim open innovation portal opnMe.com addresses this deficiency by sharing extensively validated pharmacological probes with the scientific community.Pharmacological probes are important tools for exploring disease biology and discovering new therapies. Often molecules of insufficient quality are used instead, leading to spurious and misleading results. The Boehringer Ingelheim open innovation portal opnMe.com addresses this deficiency by sharing extensively validated pharmacological probes with the scientific community.

Antimicrobial resistance is a global health threat that requires the development of new treatment concepts. These should not only overcome existing resistance but be designed to slow down the emergence of new resistance mechanisms. Targeted protein degradation, whereby a drug redirects cellular proteolytic machinery towards degrading a specific target, is an emerging concept in drug discovery. We are extending this concept by developing proteolysis targeting chimeras active in bacteria (BacPROTACs) that bind to ClpC1, a component of the mycobacterial protein degradation machinery. The anti- Mycobacterium tuberculosis ( Mtb ) BacPROTACs are derived from cyclomarins which, when dimerized, generate compounds that recruit and degrade ClpC1. The resulting Homo-BacPROTACs reduce levels of endogenous ClpC1 in Mycobacterium smegmatis and display minimum inhibitory concentrations in the low micro- to nanomolar range in mycobacterial strains, including multiple drug-resistant Mtb isolates. The compounds also kill Mtb residing in macrophages. Thus, Homo-BacPROTACs that degrade ClpC1 represent a different strategy for targeting Mtb and overcoming drug resistance. Antimicrobial resistance is a global health threat and the development of alternative strategies to overcome it is of high interest. Here, the authors report proteolysis targeting chimeras active in bacteria (BacPROTACs) that bind to ClpC1, a component of the mycobacterial protein degradation machinery, and apply them for targeting a range of mycobacterial strains, including antibiotic-resistant ones.

Targeted protein degradation using proteolysis-targeting chimeras (PROTACs) offers a promising strategy to eliminate previously undruggable proteins. PROTACs are bifunctional molecules that link a target protein with an E3 ubiquitin ligase, enabling the formation of a ternary complex that promotes ubiquitination and subsequent proteasomal degradation. Although many ternary complex structures are available, understanding how structural features relate to PROTAC function remains challenging due to the dynamic nature of these complexes. Here we show that the interface between the target protein SMARCA2 and the E3 ligase VHL is conformationally flexible and stabilized by interactions involving disordered loops. Using molecular dynamics simulations and X-ray crystallography of SMARCA2–VHL complexes bound to five different PROTACs, we find that interfacial residues often adopt energetically suboptimal, or ‘frustrated,’ configurations. We further show that the degree of frustration correlates with experimentally measured cooperativity for a set of 11 PROTACs. These findings suggest that quantifying interface frustration provides a rational, structure-based approach to guiding PROTAC design. PROTACs induce degradation by bridging a target protein and E3 ubiquitin ligase. Here, authors show that protein interface frustration correlates with cooperativity, offering a structural metric to prioritize PROTAC candidates prior to synthesis.

Accumulating evidence indicates that microparticles (MPs) are important mediators of the interaction between cancer and the hemostatic system. We conducted a large prospective cohort study to determine whether the number of circulating procoagulant MPs is elevated in cancer patients and whether the elevated MP levels are predictive of occurrence of venous thrombembolism (VTE). We analyzed plasma samples of 728 cancer patients from the ongoing prospective observational Vienna Cancer and Thrombosis Study. Study endpoint was the occurrence of symptomatic VTE. Sixty-five age- and sex-matched healthy controls were recruited for defining the cut-off point for elevated MPs (4.62 nanomolar phosphatidylserine [nM PS]), which was set at the 95th percentile of MP levels in healthy controls. The measurement of MPs was performed after capture onto immobilized annexin V, and determination of their procoagulant activity was quantified with a prothrombinase assay. During a median observation period of 710 days, 53 patients developed VTE. MP levels (nM PS) were significantly higher in cancer patients than in healthy controls (median [25th-75th percentile], 3.95 [1.74-7.96] vs. 1.19 [0.81-1.67], p < 0.001). Multivariate analysis including age, sex, surgery, chemo- and radiotherapy showed no statistically significant association of the hazard ratio of elevated MPs with VTE (0.95 [95% CI, 0.55-1.64], p = 0.856). In conclusion, MP levels were elevated in cancer patients compared to healthy individuals in this study. However, elevated MP levels were not predictive of VTE.

Targeting subunits of BAF/PBAF chromatin remodeling complexes has been proposed as an approach to exploit cancer vulnerabilities. Here, we develop proteolysis targeting chimera (PROTAC) degraders of the BAF ATPase subunits SMARCA2 and SMARCA4 using a bromodomain ligand and recruitment of the E3 ubiquitin ligase VHL. High-resolution ternary complex crystal structures and biophysical investigation guided rational and efficient optimization toward ACBI1, a potent and cooperative degrader of SMARCA2, SMARCA4 and PBRM1. ACBI1 induced anti-proliferative effects and cell death caused by SMARCA2 depletion in SMARCA4 mutant cancer cells, and in acute myeloid leukemia cells dependent on SMARCA4 ATPase activity. These findings exemplify a successful biophysics- and structure-based PROTAC design approach to degrade high profile drug targets, and pave the way toward new therapeutics for the treatment of tumors sensitive to the loss of BAF complex ATPases. A structure-based design allows the development of a potent PROTAC to degrade BAF ATPase subunits SMARCA2 and SMARCA4 via recruitment of E3 ubiquitin ligase VHL and induce cancer cell death.

In this study, we present the synthesis and incorporation of a metabolic isoleucine precursor compound for selective methylene labeling. The utility of this novel α-ketoacid isotopologue is shown by incorporation into the protein Brd4-BD1, which regulates gene expression by binding to acetylated histones. High quality single quantum 13C−1 H-HSQC were obtained, as well as triple quantum HTQC spectra, which are superior in terms of significantly increased 13C-T2 times. Additionally, large chemical shift perturbations upon ligand binding were observed. Our study thus proves the great sensitivity of this precursor as a reporter for side-chain dynamic studies and for investigations of CH-π interactions in protein-ligand complexes.

Senescent cells emerge with aging and injury. The contribution of senescent cells to DNA methylation age (DNAmAGE) in vivo is uncertain. Furthermore, stem cell therapy can mediate “rejuvenation”, but how tissue regeneration controlled by resident stem cells affects whole tissue DNAmAGE is unclear. We assessed DNAmAGE with or without senolytics (BI01) in aged male mice (24–25 months) 35 days following muscle healing (BaCl2‐induced regeneration versus non‐injured). Young injured mice (5–6 months) without senolytics were comparators. DNAmAGE was decelerated by up to 68% after injury in aged muscle. DNAmAGE was modestly but further significantly decelerated by injury recovery with senolytics. ~1/4 of measured CpGs were altered by injury then recovery regardless of senolytics in aged muscle. Specific methylation changes caused by senolytics included differential regulation of Col, Hdac, Hox, and Wnt genes, which likely contributed to improved regeneration. Altered extracellular matrix remodeling using histological analysis aligned with the methylomic findings with senolytics. Without senolytics, regeneration had a contrasting effect in young mice and tended not to influence or modestly accelerate DNAmAGE. Comparing young to old injury recovery without senolytics using methylome‐transcriptome integration, we found a more coordinated molecular profile in young and differential regulation of genes implicated in muscle stem cell performance: Axin2, Egr1, Fzd4, Meg3, and Spry1. Muscle injury and senescent cells affect DNAmAGE and aging influences the transcriptomic‐methylomic landscape after resident stem cell‐driven tissue reformation. Our data have implications for understanding muscle plasticity with aging and developing therapies aimed at collagen remodeling and senescence. Injury then recovery markedly rewires the DNA methylome in aged skeletal muscle.The addition of senolytics during muscle regeneration decelerates DNAmAGE more than regeneration alone as well as targets collagen remodeling and stem cell function‐related genes. Regeneration in young adult mice has a less pronounced effect on the methylome‐transcriptome landscape than in aged skeletal muscle, but still elicits a distinct molecular profile versus aged skeletal muscle after injury.

A method for the preparation of ligand-covered superparamagnetic iron oxide nanoparticles via exchange reactions is described. 1,2-diol-ligands are used to provide a stable binding of the terminally modified organic ligands onto the surface of γ-Fe2O3-nanoparticles (r∼4 nm). The 1,2-diol-ligands are equipped with variable terminal functional groups (i.e., hydrogen bonding moieties, azido- bromo-, fluorescent moieties) and can be easily prepared via osmium tetroxide-catalyzed 1,2-dihydroxylation reactions of the corresponding terminal alkenes. Starting from octylamine-covered γ-Fe2O3-nanoparticles, ligand exchange was effected at 50∘C over 24–48 hours, whereupon complete ligand exchange is taking place as proven by thermogravimetric (TGA)- and IR-spectroscopic measurements. A detailed kinetic analysis of the ligand exchange reaction was performed via TGA analysis, demonstrating a complete ligand exchange after 24 hours. The method offers a simple approach for the generation of various γ-Fe2O3-nanoparticles with functional organic shells in a one-step procedure.

Skeletal muscle adaptation to external stimuli, such as regeneration following injury and hypertrophy in response to resistance exercise, are blunted with advanced age. The accumulation of senescent cells, along with defects in myogenic progenitor cell (MPC) proliferation, have been strongly linked as contributing factors to age-associated impairment in muscle adaptation. p53 plays an integral role in all these processes, as upregulation of p53 causes apoptosis in senescent cells and prevents mitotic catastrophe in MPCs from old mice. The goal of this study was to determine if a novel pharmaceutical agent (BI01), which functions by upregulating p53 through inhibition of binding to MDM2, the primary p53 regulatory protein, improves muscle regeneration and hypertrophy in old mice. BI01 effectively reduced the number of senescent cells in vitro but had no effect on MPC survival or proliferation at a comparable dose. Following repeated oral gavage with 2 mg/kg of BI01 (OS) or vehicle (OV), old mice (24 months) underwent unilateral BaCl 2 injury in the tibialis anterior (TA) muscle, with PBS injections serving as controls. After 7 days, satellite cell number was higher in the TA of OS compared to OV mice, as was the expression of genes involved in ATP production. By 35 days, old mice treated with BI01 displayed reduced senescent cell burden, enhanced regeneration (higher muscle mass and fiber cross-sectional area) and restoration of muscle function relative to OV mice. To examine the impact of 2 mg/kg BI01 on muscle hypertrophy, the plantaris muscle was subjected to 28 days of mechanical overload (MOV) in OS and OV mice. In response to MOV, OS mice had larger plantaris muscles and muscle fibers than OV mice, particularly type 2b + x fibers, associated with reduced senescent cells. Together our data show that BI01 is an effective senolytic agent that may also augment muscle metabolism to enhance muscle regeneration and hypertrophy in old mice.