The C-terminal calcium-sensitive disordered motifs regulate isoform-specific polymerization characteristics of calsequestrin.

Calsequestrin (CASQ) exists as two distinct isoforms CASQ1 and CASQ2 in all vertebrates. Although the isoforms exhibit unique functional characteristic, the structural basis for the same is yet to be fully defined. Interestingly, the C-terminal region of the two isoforms exhibit significant differences both in length and amino acid composition; forming Dn-motif and DEXn-motif in CASQ1 and CASQ2, respectively. Here, we investigated if the unique C-terminal motifs possess Ca(2+)-sensitivity and affect protein function. Sequence analysis shows that both the Dn- and DEXn-motifs are intrinsically disordered regions (IDRs) of the protein, a feature that is conserved from fish to man. Using purified synthetic peptides, we show that these motifs undergo distinctive Ca(2+)-mediated folding suggesting that these disordered motifs are Ca(2+)-sensitivity. We generated chimeric proteins by swapping the C-terminal portions between CASQ1 and CASQ2. Our studies show that the C-terminal portions do not play significant role in protein folding. An interesting finding of the current study is that the switching of the C-terminal portion completely reverses the polymerization kinetics. Collectively, these data suggest that these Ca(2+)-sensitivity IDRs located at the back-to-back dimer interface influence isoform-specific Ca(2+)-dependent polymerization properties of CASQ.

Synthesis and anti-HCV determinant motif identification in pyranone carboxamide scaffold.

Hepatitis C Virus exhibits high genetic diversity. The current treatment for genotype-1 with ∼80% sustained virologic responses is a combination of pegylated interferon, ribavirin and boceprevir/telaprevir/simeprevir which is associated with several side effects and need close monitoring. Therefore, novel therapies are invited for safer and more efficient treatment. This study was designed for synthesis of new α-pyranone carboxamide analogs for evaluation of anti-HCV activity to delineate structure-activity relationship (SAR) and to identify anti-HCV determinant motif on this new scaffold. Forty four new α-pyranone carboxamide analogs were synthesized. Six potential anti-HCV candidates 11a (EC50=0.35 µM), 11e (EC50=0.48 µM), 12f (EC50=0.47 µM), 12g (EC50=0.39 µM), 12h (EC50=0.20 µM) and 12j (EC50=0.25 µM) with lower cytotoxicity (CC50>20 µM) were discovered through cell based HCV replicon system. The activity profile of forty four new α-pyranone carboxamide analogs suggests the role of an aromatic motif in the B region to add a synergistic effect to NHOH motif at 4-position and revels an anti-HCV activity determinants motif under this scaffold. The biochemical assay against most promising HCV target protein 'NS3 protease and NS5B polymerase' showed no activity and open a scope to explore new mechanism inhibitor.

Structure based medicinal chemistry approach to develop 4-methyl-7-deazaadenine carbocyclic nucleosides as anti-HCV agent.

The structure-based approaches were implemented to design and rationally select the molecules for synthesis and anti-HCV activity evaluation. The systematic structure-activity relationships of previously discovered molecules (types I, II, III) were analyzed to design new molecules (type IV) by bioisosteric replacement of the amino group. The ligand conformation, binding mode studies and drug like properties were major determinant for selection of molecules for final synthesis. The replacement of amino group with methyl restored the interactions with RNA-template (Tem 799) through bifurcated weak H-bond (C-H...O). This is an interesting finding observed from molecular modeling studies. It was found that 6c-e has anti-HCV activity (EC(50) in 37-46 µM) while 6a, 6b and 6g were inactive. The compound 6f (EC(50) 28 µM) was the most active among the series however it also showed some cytotoxicity (CC(50) 52.8 µM). Except 6f, none of the compounds were found to be cytotoxic (CC(50)>100 µM). The present study discloses structure-based approach for novel anti-HCV lead discovery and opens a future scope of lead optimization.

Probing cationic selectivity of cardiac calsequestrin and its CPVT mutants.

CASQ (calsequestrin) is a Ca2+-buffering protein localized in the muscle SR (sarcoplasmic reticulum); however, it is unknown whether Ca2+ binding to CASQ2 is due to its location inside the SR rich in Ca2+ or due to its preference for Ca2+ over other ions. Therefore a major aim of the present study was to determine how CASQ2 selects Ca2+ over other metal ions by studying monomer folding and subsequent aggregation upon exposure to alkali (monovalent), alkaline earth (divalent) and transition (polyvalent) metals. We additionally investigated how CPVT (catecholaminergic polymorphic ventricular tachycardia) mutations affect CASQ2 structure and its molecular behaviour when exposed to different metal ions. Our results show that alkali and alkaline earth metals can initiate similar molecular compaction (folding), but only Ca2+ can promote CASQ2 to aggregate, suggesting that CASQ2 has a preferential binding to Ca2+ over all other metals. We additionally found that transition metals (having higher co-ordinated bonding ability than Ca2+) can also initiate folding and promote aggregation of CASQ2. These studies led us to suggest that folding and formation of higher-order structures depends on cationic properties such as co-ordinate bonding ability and ionic radius. Among the CPVT mutants studied, the L167H mutation disrupts the Ca2+-dependent folding and, when folding is achieved by Mn2+, L167H can undergo aggregation in a Ca2+-dependent manner. Interestingly, domain III mutants (D307H and P308L) lost their selectivity to Ca2+ and could be aggregated in the presence of Mg2+. In conclusion, these studies suggest that CPVT mutations modify CASQ2 behaviour, including folding, aggregation/polymerization and selectivity towards Ca2+.

Corrigendum: A Molecular CO2 Reduction Catalyst Based on Giant Polyoxometalate {Mo368}.

[This corrects the article DOI: 10.3389/fchem.2018.00514.].

A review on HCV inhibitors: Significance of non-structural polyproteins.

Hepatitis C virus (HCV) mortality and morbidity is a world health misery with an approximate 130-150 million chronically HCV tainted and suffering individuals and it initiate critical liver malfunction like cirrhosis, hepatocellular carcinoma or liver HCV cancer. HCV NS5B protein one of the best studied therapeutic target for the identification of new drug candidates to be added to the combination or multiple combination medication recently approved. During the past few years, NS5B has thus been an important object of attractive medicinal chemistry endeavors, which induced to the surfacing of betrothal preclinical drug molecules. In this scenario, the current review set limit to discuss research published on NS5B and few other therapeutic functional inhibitors concentrating on hit investigation, hit to lead optimization, ADME parameters evaluation, and the SAR data which was out for each compound type and similarity taken into consideration. The discussion outlined in this specific review will surly helpful and vital tool for those medicinal chemists investigators working with HCV research programs mainly pointing on NS5B and set broad spectrum identification of creative anti HCV compounds. This mini review also tells each and every individual compound ability related how much they are active against NS5B and few other targets.

A Molecular CO2 Reduction Catalyst Based on Giant Polyoxometalate {Mo368}.

Photocatalytic CO2 reduction in water is one of the most attractive research pursuits of our time. In this article we report a giant polyoxometalate {Mo368} based homogeneous catalytic system, which efficiently reduces CO2 to formic acid with a maximum turnover number (TON) of 27,666, turnover frequency (TOF) of 4,611 h-1 and external quantum efficiency of the reaction is 0.6%. The catalytic system oxidizes water and releases electrons, and these electrons are further utilized for the reduction of CO2 to formic acid. A maximum of 8.3 mmol of formic acid was observed with the loading of 0.3 µmol of the catalyst. Our catalyst material is also stable throughout the reaction. The starting materials for this experiment are CO2 and H2O and the end products are HCOOH and O2. The formic acid formed in this reaction is an important H2 gas carrier and thus significant in renewable energy research.

A conformational mimetic approach for the synthesis of carbocyclic nucleosides as anti-HCV leads.

Computer-aided approaches coupled with medicinal chemistry were used to explore novel carbocyclic nucleosides as potential anti-hepatitis C virus (HCV) agents. Conformational analyses were carried out on 6-amino-1H-pyrazolo[3,4-d]pyrimidine (6-APP)-based carbocyclic nucleoside analogues, which were considered as nucleoside mimetics to act as HCV RNA-dependent RNA polymerase (RdRp) inhibitors. Structural insight gained from the modeling studies revealed the molecular basis behind these nucleoside mimetics. The rationally chosen 6-APP analogues were prepared and evaluated for anti-HCV activity. RdRp SiteMap analysis revealed the presence of a hydrophobic cavity near C7 of the nucleosides; introduction of bulkier substituents at this position enhanced their activity. Herein we report the identification of an iodinated compound with an EC50 value of 6.6 µM as a preliminary anti-HCV lead.

Identification of calcium binding sites on calsequestrin 1 and their implications for polymerization.

Biophysical studies have shown that each molecule of calsequestrin 1 (CASQ1) can bind about 70-80 Ca(2+) ions. However, the nature of Ca(2+)-binding sites has not yet been fully characterized. In this study, we employed in silico approaches to identify the Ca(2+) binding sites and to understand the molecular basis of CASQ1-Ca(2+) recognition. We built the protein model by extracting the atomic coordinates for the back-to-back dimeric unit from the recently solved hexameric CASQ1 structure (PDB id: ) and adding the missing C-terminal residues (aa350-364). Using this model we performed extensive 30 ns molecular dynamics simulations over a wide range of Ca(2+) concentrations ([Ca(2+)]). Our results show that the Ca(2+)-binding sites on CASQ1 differ both in affinity and geometry. The high affinity Ca(2+)-binding sites share a similar geometry and interestingly, the majority of them were found to be induced by increased [Ca(2+)]. We also found that the system shows maximal Ca(2+)-binding to the CAS (consecutive aspartate stretch at the C-terminus) before the rest of the CASQ1 surface becomes saturated. Simulated data show that the CASQ1 back-to-back stacking is progressively stabilized by the emergence of an increasing number of hydrophobic interactions with increasing [Ca(2+)]. Further, this study shows that the CAS domain assumes a compact structure with an increase in Ca(2+) binding, which suggests that the CAS domain might function as a Ca(2+)-sensor that may be a novel structural motif to sense metal. We propose the term "Dn-motif" for the CAS domain.