CK2 is a ubiquitous Ser/Thr protein kinase involved in the control of various signaling pathways and is known to be constitutively active. In the present study, we identified aryl 2-aminothiazoles as a novel class of CK2 inhibitors, which displayed a non-ATP-competitive mode of action and stabilized an inactive conformation of CK2 in solution. Enzyme kinetics studies, STD NMR, circular dichroism spectroscopy, and native mass spectrometry experiments demonstrated that the compounds bind in an allosteric pocket outside the ATP-binding site. Our data, combined with molecular docking studies, strongly suggested that this new binding site was located at the interface between the αC helix and the flexible glycine-rich loop. A first hit optimization led to compound 7, exhibiting an IC 50 of 3.4 μM against purified CK2α in combination with a favorable selectivity profile. Thus, we identified a novel class of CK2 inhibitors targeting an allosteric pocket, offering great potential for further optimization into anticancer drugs.
Fragment-based drug discovery is a strategy widely used both in academia and pharmaceutical companies, to generate smallmolecule protein inhibitors and drug candidates. Among the approaches reported in the literature (growing, linking and merging), the linking approach theoretically offers the opportunity to rapidly gain in binding energy. Nevertheless, this approach is poorly represented when considering the compounds currently in clinical trials. Here, we report an exhaustive view of the cases published so far in the literature, together with the methods used to identify the two initial fragments either simultaneously or successively. We review the different types of linkers published and discuss how these linkers are designed to obtain the lead compound. Mixing merging and linking methods,
For over half a century, the carbazole skeleton has been the key structural motif of many biologically active compounds including natural and synthetic products. Carbazoles have taken an important part in all the existing anti-cancer drugs because of their discovery from a large variety of organisms, including bacteria, fungi, plants, and animals. In this article, we specifically explored the literature from 2012 to 2018 on the anti-tumour activities reported to carbazole derivatives and we have critically collected the most significant data. The most described carbazole anti-tumour agents were classified according to their structure, starting from the tricyclic–carbazole motif to fused tetra-, penta-, hexa- and heptacyclic carbazoles. To date, three derivatives are available on the market and approved in cancer therapy.
A series of indeno[1,2-b]indole-9,10-dione derivatives were synthesized as human casein kinase II (CK2) inhibitors. The most potent inhibitors contained a N(5)-isopropyl substituent on the C-ring. The same series of compounds was found to also inhibit the breast cancer resistance protein ABCG2 but with totally different structure-activity relationships: a N(5)-phenethyl substituent was critical, and additional hydrophobic substituents at position 7 or 8 of the D-ring or a methoxy at phenethyl position ortho or meta also contributed to inhibition. The best ABCG2 inhibitors, such as 4c, 4h, 4i, 4j, and 4k, behaved as very weak inhibitors of CK2, whereas the most potent CK2 inhibitors, such as 4a, 4p, and 4e, displayed limited interaction with ABCG2. It was therefore possible to convert, through suitable substitutions of the indeno[1,2-b]indole-9,10-dione scaffold, potent CK2 inhibitors into selective ABCG2 inhibitors and vice versa. In addition, some of the best ABCG2 inhibitors, which displayed a very low cytotoxicity, thus giving a high therapeutic ratio, and appeared not to be transported, constitute promising candidates for further investigations.
a b s t r a c tHerein we describe the synthesis and properties of substituted phenylaminopyrrolo[1,2-a]quinoxalinecarboxylic acid derivatives as a novel class of potent inhibitors of the human protein kinase CK2. A set of 15 compounds was designed and synthesized using convenient and straightforward synthesis protocols. The compounds were tested for inhibition of human protein kinase CK2, which is a potential drug target for many diseases including inflammatory disorders and cancer. New inhibitors with IC 50 in the microand sub-micromolar range were identified. The most promising compound, the 4-[(3-chlorophenyl) amino]pyrrolo[1,2-a]quinoxaline-3-carboxylic acid 1c inhibited human CK2 with an IC 50 of 49 nM. Our findings indicate that pyrrolo[1,2-a]quinoxalines are a promising starting scaffold for further development and optimization of human protein kinase CK2 inhibitors.
Protein CK2 has gained much interest as an anti-cancer drug target in the last decade. We had previously described the identification of a new allosteric site on the catalytic α-subunit, along with first small molecule ligands based on the 4-(4-phenylthiazol-2-ylamino) benzoic acid scaffold. In the present work, structure optimizations guided by a binding model led to the identification of the lead compound 2-hydroxy-4-((4-(naphthalen-2-yl)thiazol-2yl)amino)benzoic acid (27), showing a submicromolar potency against purified CK2α (IC 50 = 0.6 µM). Furthermore, 27 induced apoptosis and cell death in 786-O renal cell carcinoma cells (EC 50 = 5 µM) and inhibited STAT3 activation even more potently than the ATPcompetitive drug candidate CX-4945 (EC 50 s: 1.6 µM vs. 5.3 µM). Notably, the potencies of our allosteric ligands to inhibit CK2 varied depending on the individual substrate. Altogether, the novel allosteric pocket was proved a druggable site, offering an excellent perspective to develop efficient and selective allosteric CK2 inhibitors. Recently, we identified 2-aminothiazole derivatives as novel allosteric inhibitors of CK2α; 20 exemplarily shown are compounds 1-4 (Figure 1). Using complementary methods, it was demonstrated that compound 3 binds in an allosteric pocket adjacent to the ATP binding site, between the glycine-rich loop and the αC-helix. A preliminary hit optimization led to compound 4, exhibiting an IC 50 of 3.4 µM. However, it had yet to be shown that the new CK2 modulator class can be developed further into more potent drugs, which is often a limitation with allosteric target sites that were not evolutionary designed for high-affinity interactions with small molecules. 21, 22 Therefore, we carried out a compound optimization guided by a binding model, as will be described below. The cellular effects of the allosteric CK2
CK2α and CK2α′
are the two isoforms of the catalytic
subunit of human protein kinase CK2, an important target for cancer
therapy. They have similar, albeit not identical functional and structural
properties, and were occasionally reported to be inhibited with distinct
efficacies by certain ATP-competitive ligands. Here, we present THN27,
an indeno[1,2-b]indole derivative, as a further inhibitor
with basal isoform selectivity. The selectivity disappears when measured
using CK2α/CK2α′ complexes with CK2β, the
regulatory CK2 subunit. Co-crystal structures of THN27 with CK2α
and CK2α′ reveal that subtle differences in the conformational
variability of the interdomain hinge region are correlated with the
observed effect. In the case of CK2α′, a crystallographically
problematic protein so far, this comparative structural analysis required
the development of an experimental strategy that finally enables atomic
resolution structure determinations with ab initio phasing of potentially
any ATP-competitive CK2 inhibitor and possibly many non-ATP-competitive
ligands as well bound to CK2α′.
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