Synthesis, in silico study (DFT, ADMET) and crystal structure of novel sulfamoyloxy-oxazolidinones: Interaction with SARS-CoV-2.

A new series of sulfamoyloxyoxazolidinone (SOO) derivatives have been synthesized and characterized by single-crystal X-ray diffraction, NMR, IR, MS and EA. Chemical reactivity and geometrical characteristics of the target compounds were investigated using DFT method. The possible binding mode between SOO and Main protease (Mpro) of SARS-CoV-2 and their reactivity were studied using molecular docking simulation. Single crystal X-ray diffraction showed that SOO crystallizes in a monoclinic system with P 2 1 space group. The binding energy of the SARS-CoV-2/Mpro-SOO complex and the calculated inhibition constant using docking simulation showed that the active SOO molecule has the ability to inhibit SARS-CoV2. We studied the prediction of absorption, distribution, properties of metabolism, excretion and toxicity (ADMET) of the synthesized molecules.

Behaviour of Tetrabenazine in Acid Medium: Reassessment and Impact on Formulation.

Thorough studies of previous analytical stress data of tetrabenazine, a dopamine depleting agent, showed a potential susceptibility to acidic conditions. Hence, the behavior of tetrabenazine acidic solutions was studied by LC-MS and NMR spectroscopy. Reverse-phase LC-MS analysis of tetrabenazine acidic aqueous solutions consistently showed a main lipophilic impurity in a proportion of 15 to 20%. NMR spectroscopy studies did not allow to completely ascertain its structure. However, we hypothesize an interconversion of trans-tetrabenazine with its unstable cis isomer via an open isoquinolinium intermediate. Evaluation of tetrabenazine integrity in orodispersible films was reassessed in light of these observations after formulation and during stability study. Even if interconversion of trans-tetrabenazine with its cis isomer was observed in orodispersible films containing tetrabenazine, this phenomenon seems not to have any consequences for the overall tetrabenazine bioavailability.

Discovery of holoenzyme-disrupting chemicals as substrate-selective CK2 inhibitors.

CK2 is a constitutively active protein kinase overexpressed in numerous malignancies. Interaction between CK2α and CK2ß subunits is essential for substrate selectivity. The CK2α/CK2ß interface has been previously targeted by peptides to achieve functional effects; however, no small molecules modulators were identified due to pocket flexibility and open shape. Here we generated numerous plausible conformations of the interface using the fumigation modeling protocol, and virtually screened a compound library to discover compound 1 that suppressed CK2α/CK2ß interaction in vitro and inhibited CK2 in a substrate-selective manner. Orthogonal SPR, crystallography, and NMR experiments demonstrated that 4 and 6, improved analogs of 1, bind to CK2α as predicted. Both inhibitors alter CK2 activity in cells through inhibition of CK2 holoenzyme formation. Treatment with 6 suppressed MDA-MB231 triple negative breast cancer cell growth and induced apoptosis. Altogether, our findings exemplify an innovative computational-experimental approach and identify novel non-peptidic inhibitors of CK2 subunit interface disclosing substrate-selective functional effects.

The combined use of analytical tools for exploring tetanus toxin and tetanus toxoid structures.

Aldehyde detoxification is a process used to convert toxin into toxoid for vaccine applications. In the case of tetanus toxin (TT), formaldehyde is used to obtain the tetanus toxoid (TTd), which is used either for the tetanus vaccine or as carrier protein in conjugate vaccines. Several studies have already been conducted to better understand the exact mechanism of this detoxification. Those studies led to the identification of a number of formaldehyde-induced modifications on lab scale TTd samples. To obtain greater insights of the changes induced by formaldehyde, we used three industrial TTd batches to identify repeatable modifications in the detoxification process. Our strategy was to combine seven analytical tools to map these changes. Mass spectrometry (MS), colorimetric test and amino acid analysis (AAA) were used to study modifications on amino acids. SDS-PAGE, asymmetric flow field flow fractionation (AF4), fluorescence spectroscopy and circular dichroism (CD) were used to study formaldehyde modifications on the whole protein structure. We identified 41 formaldehyde-induced modifications across the 1315 amino acid primary sequence of TT. Of these, five modifications on lysine residues were repeatable across TTd batches. Changes in protein conformation were also observed using SDS-PAGE, AF4 and CD techniques. Each analytical tool brought a piece of information regarding formaldehyde induced-modifications, and all together, these methods provided a comprehensive overview of the structural changes that occurred with detoxification. These results could be the first step leading to site-directed TT mutagenesis studies that may enable the production of a non-toxic equivalent protein without using formaldehyde.

Toward selective CK2alpha and CK2alpha' inhibitors: Development of a novel whole-cell kinase assay by Autodisplay of catalytic CK2alpha'.

Human protein kinase CK2 is an emerging target for the development of novel anti-cancer therapeutics. CK2 is a tetramer composed of two catalytically active α- and/or α'-subunits, bound to a dimer of the regulatory ß-subunit. Inhibitors targeting one of the two isoforms of the catalytically active CK2-subunit (α- and α') are important to study the distinct functions of these isoforms toward different CK2 associated pathologies. The present study for the first time describes the successful Autodisplay of the CK2α'-subunit, the paralogous isoform of CK2α. Expression on the cell surface of E. coli of CK2α' alone and in combination with the regulatory CK2ß-subunit was confirmed by outer membrane isolation and protease accessibility test. Kinase activity of surface displayed CK2 could be detected with a CE-based assay and was found to be 3.06×10(-6) µmol/min for CK2α' alone and 1.02×10(-5) µmol/min when expressed in combination with CK2ß. The comparison of the influence of NaCl on activity of the α'-subunit alone and in combination with the non-catalytically active ß-subunit indicated interaction of both subunits on the cell surface. TMCB (4,5,6,7-tetrabromo-2-(dimethylamino)-1H-benzo[d]imidazol-1-yl)acetic acid), a known CK2 inhibitor described with distinct Ki values of 83 nM and 21 nM for the two different catalytic CK2 subunits α and α' was used for testing. First, inhibition of TMCB toward the purified CK2 holoenzyme CK2α2ß2 was determined and resulted in a Ki value of 10.1 nM. Second, Ki values were determined with the surface displayed isoform CK2 holoenzymes and turned out to be of 31.1 nM for CK2α2ß2 and 19.6 nM for CK2α'2ß2. The inhibition data as obtained represented the distinct affinities of TMCB toward the two isoform holoenzymes. This indicated, that the surface display of CKα and CK2α', in the context of the corresponding holoenzymes, can be used to identify selective compounds. A set of twelve ATP competitive CK2 inhibitors with an indeno[1,2-b]indole scaffold was tested in order to demonstrate suitability for this application.

Synthesis, Biological Evaluation and Molecular Modeling of Substituted Indeno[1,2-b]indoles as Inhibitors of Human Protein Kinase CK2.

Due to their system of annulated 6-5-5-6-membered rings, indenoindoles have sparked great interest for the design of ATP-competitive inhibitors of human CK2. In the present study, we prepared twenty-one indeno[1,2-b]indole derivatives, all of which were tested in vitro on human CK2. The indenoindolones 5a and 5b inhibited human CK2 with an IC50 of 0.17 and 0.61 µM, respectively. The indeno[1,2-b]indoloquinone 7a also showed inhibitory activity on CK2 at a submicromolar range (IC50 = 0.43 µM). Additionally, a large number of indenoindole derivatives was evaluated for their cytotoxic activities against the cell lines 3T3, WI-38, HEK293T and MEF.