bProtein kinases represent central and multifunctional regulators of a balanced virus-host interaction. Cyclin-dependent protein kinase 7 (CDK7) plays crucial regulatory roles in cell cycle and transcription, both connected with the replication of many viruses. Previously, we developed a CDK7 inhibitor, LDC4297, that inhibits CDK7 in vitro in the nano-picomolar range. Novel data from a kinome-wide evaluation (>330 kinases profiled in vitro) demonstrate a kinase selectivity. Importantly, we provide first evidence for the antiviral potential of the CDK7 inhibitor LDC4297, i.e., in exerting a block of the replication of human cytomegalovirus (HCMV) in primary human fibroblasts at nanomolar concentrations (50% effective concentration, 24.5 ؎ 1.3 nM). As a unique feature compared to approved antiherpesviral drugs, inhibition occurred already at the immediate-early level of HCMV gene expression. The mode of antiviral action was considered multifaceted since CDK7-regulated cellular factors that are supportive of HCMV replication were substantially affected by the inhibitors. An effect of LDC4297 was identified in the interference with HCMV-driven inactivation of retinoblastoma protein (Rb), a regulatory step generally considered a hallmark of herpesviral replication. In line with this finding, a broad inhibitory activity of the drug could be demonstrated against a selection of human and animal herpesviruses and adenoviruses, whereas other viruses only showed intermediate drug sensitivity. Summarized, the CDK7 inhibitor LDC4297 is a promising candidate for further antiviral drug development, possibly offering new options for a comprehensive approach to antiviral therapy. C yclin-dependent kinases (CDKs) are characterized as regulators of two major transitions in the cell cycle, namely, the initiation of the DNA synthesis (S) phase and the entry into mitosis (M) phase. CDKs are generally coregulated in activity by their interaction with distinct types or a selection of cyclins. In addition to cell cycle control, CDK/cyclin complexes have also been identified as conserved components of the RNA polymerase II (RNAP II) transcriptional machinery (1). CDK7 is both a CDK-activating kinase (CAK), which phosphorylates CDKs within the activation segment (T-loop), and a component of the transcription factor TFIIH, which phosphorylates the C-terminal domain (CTD) of RNAP II (2-5). This central importance of CDK7 has long been asserted as an essential role in cellular metabolism and viability. Recently, a study by Ganuza et al. (6) demonstrated that depletion of CDK7 in vivo had no phenotypic consequences in adult tissues with low proliferative indexes and that CDK7 is mostly dispensable for transcriptional regulation. In contrast, CDK7 activity appears basically essential for cell cycle activation via phosphorylation of CDKs, primarily CDK1 and CDK2, and genetic inactivation of CDK7 leads to cell cycle arrest in tissues with elevated cellular turnover. Thus, CDK7-related defects may not be universally expressed, but can be restric...
In this study, we explored the application of a yeast three-hybrid (Y3H)-based compound/protein display system to scanning the proteome for targets of kinase inhibitors. Various known cyclin-dependent kinase (CDK) inhibitors, including purine and indenopyrazole analogs, were displayed in the form of methotrexate-based hybrid ligands and deployed in cDNA library or yeast cell array-based screening formats. For all inhibitors, known cell cycle CDKs as well as novel candidate CDK-like and/or CDK-unrelated kinase targets could be identified, many of which were independently confirmed using secondary enzyme assays and affinity chromatography. The Y3H system described here may prove generally useful in the discovery of candidate drug targets.
Analysis of agonist-driven phosphorylation of G protein-coupled receptors (GPCRs) can provide valuable insights into the receptor activation state and ligand pharmacology. However, to date, assessment of GPCR phosphorylation using high-throughput applications has been challenging. We have developed and validated a bead-based immunoassay for the quantitative assessment of agonist-induced GPCR phosphorylation that can be performed entirely in multiwell cell culture plates. The assay involves immunoprecipitation of affinity-tagged receptors using magnetic beads followed by protein detection using phosphorylation state-specific and phosphorylation state-independent anti-GPCR antibodies. As proof of concept, five prototypical GPCRs (MOP, C5a1, D1, SST2, CB2) were treated with different agonizts and antagonists, and concentration-response curves were generated. We then extended our approach to establish selective cellular GPCR kinase (GRK) inhibitor assays, which led to the rapid identification of a selective GRK5/6 inhibitor (LDC8988) and a highly potent pan-GRK inhibitor (LDC9728). In conclusion, this versatile GPCR phosphorylation assay can be used extensively for ligand profiling and inhibitor screening.
Oncogenic Ras proteins are implicated in the most common life‐threatening cancers. Despite intense research over the past two decades, the progress towards small‐molecule inhibitors has been limited. One reason for this failure is that Ras proteins interact with their effectors only via protein‐protein interactions, which are notoriously difficult to address with small organic molecules. Herein we describe an alternative strategy, which prevents farnesylation and subsequent membrane insertion, a prerequisite for the activation of Ras proteins. Our approach is based on sequence‐selective supramolecular receptors which bind to the C‐terminal farnesyl transferase recognition unit of Ras and Rheb proteins and covalently modify the essential cysteine in the so‐called CaaX‐box.
e14718 Background: The majority of EGFR mutant tumors can be effectively treated with targeted drugs. Lung adenocarcinoma patients with EGFR Ex20 insertion mutations, however, lack safe and potent treatment options. These genetic alterations share homology with HER2 Ex20 insertion mutations and perturb the ATP binding pocket in a way that limits accessibility through currently available tyrosine kinase inhibitors. Second-generation EGFR inhibitors are partially active in EGFR Ex20 mutant models but their potent activity against wild type (WT) EGFR and the resulting adverse effects largely prohibit the clinical use of these drugs. To address this medical need, we developed PRB001, a novel EGFR kinase inhibitor. Methods: We facilitated protein X-ray crystallography to guide the development of small molecule inhibitors with high potency against EGFR/HER2 Ex20 mutant kinases and low activity against WT EGFR. Iterative compound optimization involved biochemical profiling concerning inhibition and binding kinetics, cellular profiling as well as mouse pharmacokinetic and mouse efficacy studies. Results: PRB001 exhibits potent activity against EGFR/HER2 Ex20 insertion mutations, in genetically engineered Ba/F3 cell line models and patient derived cell lines. At the same time, PRB001 exhibits a 10-100 fold lower activity against WT EGFR in several cellular models. Our data indicate that PRB001 and its derivatives display a therapeutic window for an effective treatment of EGFR Ex20 mutant tumors with a limited toxicity profile. Mouse xenograft experiments support these results, showing that, in contrast to second-generation EGFR inhibitors, PRB001 does not inhibit WT EGFR and does not lead to loss of weight of treated animals at effective doses of 90 mg/kg daily. Conclusions: Our data support the notion that PRB001 effectively kills a wide range of EGFR Ex20 mutant cellular models and together with its safety profile builds a basis for the development of a mutant-selective and clinically effective tyrosine kinase inhibitor.
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