54 research outputs found
Assessment of Covalently Binding Warhead Compounds in the Validation of the Cytomegalovirus Nuclear Egress Complex as an Antiviral Target
Herpesviral nuclear egress is a regulated process of viral capsid nucleocytoplasmic release.
Due to the large capsid size, a regular transport via the nuclear pores is unfeasible, so that a multistageregulated export pathway through the nuclear lamina and both leaflets of the nuclear membrane has
evolved. This process involves regulatory proteins, which support the local distortion of the nuclear
envelope. For human cytomegalovirus (HCMV), the nuclear egress complex (NEC) is determined
by the pUL50–pUL53 core that initiates multicomponent assembly with NEC-associated proteins
and capsids. The transmembrane NEC protein pUL50 serves as a multi-interacting determinant that
recruits regulatory proteins by direct and indirect contacts. The nucleoplasmic core NEC component
pUL53 is strictly associated with pUL50 in a structurally defined hook-into-groove complex and is
considered as the potential capsid-binding factor. Recently, we validated the concept of blocking the
pUL50–pUL53 interaction by small molecules as well as cell-penetrating peptides or an overexpression
of hook-like constructs, which can lead to a pronounced degree of antiviral activity. In this study,
we extended this strategy by utilizing covalently binding warhead compounds, originally designed
as binders of distinct cysteine residues in target proteins, such as regulatory kinases. Here, we
addressed the possibility that warheads may likewise target viral NEC proteins, building on our
previous crystallization-based structural analyses that revealed distinct cysteine residues in positions
exposed from the hook-into-groove binding surface. To this end, the antiviral and NEC-binding
properties of a selection of 21 warhead compounds were investigated. The combined findings are
as follows: (i) warhead compounds exhibited a pronounced anti-HCMV potential in cell-culturebased infection models; (ii) computational analysis of NEC primary sequences and 3D structures
revealed cysteine residues exposed to the hook-into-groove interaction surface; (iii) several of the
active hit compounds exhibited NEC-blocking activity, as shown at the single-cell level by confocal
imaging; (iv) the clinically approved warhead drug ibrutinib exerted a strong inhibitory impact on
the pUL50–pUL53 core NEC interaction, as demonstrated by the NanoBiT assay system; and (v) the
generation of recombinant HCMV ∆UL50-ΣUL53, allowing the assessment of viral replication under
conditional expression of the viral core NEC proteins, was used for characterizing viral replication
and a mechanistic evaluation of ibrutinib antiviral efficacy. Combined, the results point to a ratelimiting importance of the HCMV core NEC for viral replication and to the option of exploiting this
determinant by the targeting of covalently NEC-binding warhead compounds
Profiling of ERBB receptors and downstream pathways reveals selectivity and hidden properties of ERBB4 antagonists
ERBB receptor tyrosine kinases are involved in development and diseases like cancer, cardiovascular, neu rodevelopmental, and mental disorders. Although existing drugs target ERBB receptors, the next gener ation of drugs requires enhanced selectivity and understanding of physiological pathway responses to improve efficiency and reduce side effects. To address this, we developed a multilevel barcoded reporter profiling assay, termed ‘ERBBprofiler’, in living cells to monitor the activity of all ERBB targets and key physiological pathways simultaneously. This assay helps differentiate on-target therapeutic effects from off-target and off-pathway side effects of ERBB antagonists. To challenge the assay, eight estab lished ERBB antagonists were profiled. Known effects were confirmed, and previously uncharacterized properties were discovered, such as pyrotinib’s preference for ERBB4 over EGFR. Additionally, two lead compounds selectively targeting ERBB4 were profiled, showing promise for clinical trials. Taken together, this multiparametric profiling approach can guide early-stage drug development and lead to improved future therapeutic interventions
A highly selective purine-based inhibitor of CSF1R potently inhibits osteoclast differentiation
The colony-stimulating factor 1 receptor (CSF1R) plays an important role in the regulation of many inflammatory
processes, and overexpression of the kinase is implicated in several disease states. Identifying selective, smallmolecule inhibitors of CSF1R may be a crucial step toward treating these disorders. Through modelling, synthesis, and a systematic structure-activity relationship study, we have identified a number of potent and highly
selective purine-based inhibitors of CSF1R. The optimized 6,8-disubstituted antagonist, compound 9, has
enzymatic IC50 of 0.2 nM, and displays a strong affinity toward the autoinhibited form of CSF1R, contrasting that
of other previously reported inhibitors. As a result of its binding mode, the inhibitor shows excellent selectivity
(Selectivity score: 0.06), evidenced by profiling towards a panel of 468 kinases. In cell-based assays, this inhibitor
shows dose-dependent blockade of CSF1-mediated downstream signalling in murine bone marrow-derived
macrophages (IC50 = 106 nM) as well as disruption of osteoclast differentiation at nanomolar levels. In vivo
experiments, however, indicate that improve metabolic stability is needed in order to further progress this
compound class
Fragment-Based Interrogation of the 14–3–3/TAZ Protein–Protein Interaction
The identification of chemical starting points for the development of molecular glues is challenging. Here, we employed fragment screening and identified an allosteric stabilizer of the complex between 14-3-3 and a TAZ-derived peptide. The fragment binds preferentially to the 14-3-3/TAZ peptide complex and shows moderate stabilization in differential scanning fluorimetry and microscale thermophoresis. The binding site of the fragment was predicted by molecular dynamics calculations to be distant from the 14-3-3/TAZ peptide interface, located between helices 8 and 9 of the 14-3-3 protein. This site was confirmed by nuclear magnetic resonance and X-ray protein crystallography, revealing the first example of an allosteric stabilizer for 14-3-3 protein-protein interactions
An Antiherpesviral Host-Directed Strategy Based on CDK7 Covalently Binding Drugs: Target-Selective, Picomolar-Dose, Cross-Virus Reactivity
The repertoire of currently available antiviral drugs spans therapeutic applications against a number of important human pathogens distributed worldwide. These include cases of the pandemic severe acute respiratory coronavirus type 2 (SARS-CoV-2 or COVID-19), human immunodeficiency virus type 1 (HIV-1 or AIDS), and the pregnancy- and posttransplant-relevant human cytomegalovirus (HCMV). In almost all cases, approved therapies are based on direct-acting antivirals (DAAs), but their benefit, particularly in long-term applications, is often limited by the induction of viral drug resistance or side effects. These issues might be addressed by the additional use of host-directed antivirals (HDAs). As a strong input from long-term experiences with cancer therapies, host protein kinases may serve as HDA targets of mechanistically new antiviral drugs. The study demonstrates such a novel antiviral strategy by targeting the major virus-supportive host kinase CDK7. Importantly, this strategy focuses on highly selective, 3D structure-derived CDK7 inhibitors carrying a warhead moiety that mediates covalent target binding. In summary, the main experimental findings of this study are as follows: (1) the in vitro verification of CDK7 inhibition and selectivity that confirms the warhead covalent-binding principle (by CDK-specific kinase assays), (2) the highly pronounced antiviral efficacies of the hit compounds (in cultured cell-based infection models) with half-maximal effective concentrations that reach down to picomolar levels, (3) a particularly strong potency of compounds against strains and reporter-expressing recombinants of HCMV (using infection assays in primary human fibroblasts), (4) additional activity against further herpesviruses such as animal CMVs and VZV, (5) unique mechanistic properties that include an immediate block of HCMV replication directed early (determined by Western blot detection of viral marker proteins), (6) a substantial drug synergism in combination with MBV (measured by a Loewe additivity fixed-dose assay), and (7) a strong sensitivity of clinically relevant HCMV mutants carrying MBV or ganciclovir resistance markers. Combined, the data highlight the huge developmental potential of this host-directed antiviral targeting concept utilizing covalently binding CDK7 inhibitors
White Paper: Mimetics of Class 2 Tumor Suppressor Proteins as Novel Drug Candidates for Personalized Cancer Therapy
The aim of our proposed concept is to find new target structures for combating cancers with unmet medical needs. This, unfortunately, still applies to the majority of the clinically most relevant tumor entities such as, for example, liver cancer, pancreatic cancer, and many others. Current target structures almost all belong to the class of oncogenic proteins caused by tumor-specific genetic alterations, such as activating mutations, gene fusions, or gene amplifications, often referred to as cancer “driver alterations” or just “drivers.” However, restoring the lost function of tumor suppressor genes (TSGs) could also be a valid approach to treating cancer. TSG-derived proteins are usually considered as control systems of cells against oncogenic properties; thus, they represent the brakes in the “car-of-life.” Restoring these tumor-defective brakes by gene therapy has not been successful so far, with a few exceptions. It can be assumed that most TSGs are not being inactivated by genetic alteration (class 1 TSGs) but rather by epigenetic silencing (class 2 TSGs or short “C2TSGs”). Reactivation of C2TSGs in cancer therapy is being addressed by the use of DNA demethylating agents and histone deacetylase inhibitors which act on the whole cancer cell genome. These epigenetic therapies have neither been particularly successful, probably because they are “shotgun” approaches that, although acting on C2TSGs, may also reactivate epigenetically silenced oncogenic sequences in the genome. Thus, new strategies are needed to exploit the therapeutic potential of C2TSGs, which have also been named DNA methylation cancer driver genes or “DNAme drivers” recently. Here we present a concept for a new translational and therapeutic approach that focuses on the phenotypic imitation (“mimesis”) of proteins encoded by highly disease-relevant C2TSGs/DNAme drivers. Molecular knowledge on C2TSGs is used in two complementary approaches having the translational concept of defining mimetic drugs in common: First, a concept is presented how truncated and/or genetically engineered C2TSG proteins, consisting solely of domains with defined tumor suppressive function can be developed as biologicals. Second, a method is described for identifying small molecules that can mimic the effect of the C2TSG protein lost in the cancer cell. Both approaches should open up a new, previously untapped discovery space for anticancer drugs
A Flexible Multiwell Format for Immunofluorescence Screening Microscopy of Small-Molecule Inhibitors.
Large-scale screens in mammalian cells demand for flexible high-throughput screening platforms that allow to analyze cellular traits on a genome-wide level or to identify small-molecule inhibitors (SMIs) from complex compound libraries. In this study we developed and tested high-density cell arrays made out of polydimethylsiloxane (PDMS) that support cell growth directly on standard glass microscope objective slides. We analyzed the effect of 3 reference inhibitors (MLN-8054, VX-680, and flavopiridol) and 4 exploratory, cell permeable small-molecule kinase inhibitors (two benzothiophene-based and two 4-amino-6-arylpyrimidine-based compounds) on different cell lines, using prototype 5 × 5 and 9 × 9 array carpets. We found that high-density PDMS cell arrays support growth of a broad range of cell types, are well suited for compound screens, and are compatible with high-content screening platforms. This novel array format is of particular advantage for compound screening to identify SMIs, when a combination of flexibility with respect to culture volume, well density, and high-resolution imaging is required. In addition, we demonstrated the suitability of this format for reverse transfection and siRNA experiments
Role of Protein Kinase G in Growth and Glutamine Metabolism of Mycobacterium bovis BCG
The survival of pathogenic mycobacteria in macrophages requires the eukaryotic enzyme-like serine/threonine protein kinase G. This kinase with unknown specificity is secreted into the cytosol of infected macrophages and inhibits phagosome-lysosome fusion. The pknG gene is the terminal gene in a putative operon containing glnH, encoding a protein potentially involved in glutamine uptake. Here, we report that the deletion of pknG did not affect either glutamine uptake or intracellular glutamine concentrations. In vitro growth of Mycobacterium bovis BCG lacking pknG was identical to that of the wild type. We conclude that in M. bovis BCG, glutamine metabolism is not regulated by protein kinase G
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