Molecular interaction of 2,4-diacetylphloroglucinol (DAPG) with human serum albumin (HSA): The spectroscopic, calorimetric and computational investigation.

Drug molecule interaction with human serum albumin (HSA) affects the distribution and elimination of the drug. The compound, 2,4-diacetylphloroglucinol (DAPG) has been known for its antimicrobial, antiviral, antihelminthic and anticancer properties. However, its interaction with HSA is not yet reported. In this study, the interaction between HSA and DAPG was investigated through steady-state fluorescence, time-resolved fluorescence (TRF), circular dichroism (CD), Fourier transform infrared (FT-IR) spectroscopy, isothermal titration calorimetry (ITC), molecular docking and molecular dynamics simulation (MDS). Fluorescence spectroscopy results showed the strong quenching of intrinsic fluorescence of HSA due to interaction with DAPG, through dynamic quenching mechanism. The compound bound to HSA with reversible and moderate affinity which explained its easy diffusion from circulatory system to target tissue. The thermodynamic parameters from fluorescence spectroscopic data clearly revealed the contribution of hydrophobic forces but, the role of hydrogen bonds was not negligible according to the ITC studies. The interaction was exothermic and spontaneous in nature. Binding with DAPG reduced the helical content of protein suggesting the unfolding of HSA. Site marker fluorescence experiments revealed the change in binding constant of DAPG in the presence of site I (warfarin) but not site II marker (ibuprofen) which confirmed that the DAPG bound to site I. ITC experiments also supported this as site I marker could not bind to HSA-DAPG complex while site II marker was accommodated in the complex. In silico studies further showed the lowest binding affinity and more stability of DAPG in site I than in site II. Thus the data presented in this study confirms the binding of DAPG to the site I of HSA which may help in further understanding of pharmacokinetic properties of DAPG.

One-Pot Synthesis of Densely Substituted Pyrazolo[3,4-b]-4,7-dihydropyridines.

We have achieved a facile synthesis of a combinatorial library of densely substituted pyrazolo[3,4-b]-4,7-dihydropyridines- the mimics of antigenital wart drug podophyllotoxin-from 5-aminopyrazoles and 4-(methylthio) 4H-chromenes. The C(4) pyrazolyl 4H-chromenes, which also possess structural features of podophyllotoxin, were isolable intermediates in the two-step, one-pot condensation. The condensation took place in a one-pot, multicomponent manner when 3-oxo-3-phenylpropanenitriles, hydrazine (precursors for 5-aminopyrazoles) and 4-(methylthio)-4H-chromenes were heated in refluxing ethanol. The condensation, however, stops at 4H-chromene stage when methyl hydrazine or phenylhydrazine were employed. Our findings offer an opportunity for synthesis of a combinatorial library of podophyllotoxin mimics, thus paving the way for discovery of lead candidates for cancer treatment.

Structural insights into tumor-specific chaperoning activity of gamma synuclein in protecting estrogen receptor alpha 36 and its role in tamoxifen resistance in breast cancer.

Gamma synuclein (γSyn), a tumor-specific molecular chaperone, protects Hsp90 client proteins like ERα36 and stimulates rapid membrane-initiated estrogen signalling in breast cancer cells. However, the structural perspectives of this tumor-specific chaperone function of γSyn remains unclear. Hence, in this present work, we studied the conformational dynamics of ERα36 in the absence and presence of Hsp90 and γSyn. Results indicate that in a chaperone-free state, ERα36 undergoes an inter-domain movement and exposes the hydrophobic patch of residues that are responsible for binding with ubiquitin. However, independent of Hsp90, γSyn, by establishing transient interactions, prevents interdomain movement, unveils the co-activator binding groove, masks the ubiquitin-binding residues and maintains 'open' pocket conformation of LBD. By doing so, γSyn effectively protects ERα36 from degradation and maintains its functional state like Hsp90 based chaperoning machinery but independent of ATP. Our studies also show that the γSyn protected conformation of ERα36 can effectively bind with both estradiol (E2) and 4-hydroxy tamoxifen (4-OHT). Although they exhibit unique binding modes, they maintained the functionally active conformation of ERα36. Interestingly, the molecular dynamics simulation studies showed that 4-OHT, like γSyn, prevented the interdomain movements, primes the co-activator binding groove of ERα36 for complexation with downstream signalling proteins and this mechanism explains its agonist activity and associated anti-estrogen resistance observed in the presence of ERα36. The observed differences in the chaperoning mechanism of γSyn sheds light on its selectivity over Hsp90 in cancer cells, for promoting rapid protection of crucial oncogenic proteins. Based on our findings, we speculate that the compounds, which can hamper association of γSyn with ERα36 and/or can arrest ERα36 in an ubiquitin binding state, would be promising alternatives for treating ERα36 expressed breast carcinomas.

Structural perspective of ARHI mediated inhibition of STAT3 signaling: an insight into the inactive to active transition of ARHI and its interaction with STAT3 and importinß.

ARHI, a putative tumor suppressor protein with unique 32 amino acid extension in the N-terminal region, differs from oncogenes Ras and Rap, negatively regulates STAT3 signaling and inhibits the migration of ovarian cancer cells. ARHI associates directly with STAT3, also forms complex with importinß, and prevents formation of RanGTPase-importinß complex, which is essential for transporting STAT3 into the nucleus. Hence, the structural aspects pertaining to ARHI mediated inhibition of STAT3 translocation can provide hints on the regulation of STAT3 signaling mechanism. Accordingly, in the present study, the structure of ARHI was predicted and its transition from inactive to active state studied using MD simulations and free energy landscape analysis. The transition of ARHI is marked by the movement of switch I region towards γ-phosphate of GTP, in addition, the hydrophobic interaction between N-terminal helix and switch II region of ARHI accounts for its low intrinsic GTPase activity. Further, the protein-protein interaction studies reveal that the residues of N-terminal helix, effector domain, P-loop and G box motif of ARHI actively form polar and non-polar interaction with NTD of STAT3 and make them compact thereby rendering STAT3 inaccessible for Ran-importinß mediated translocation. On the other hand, ARHI competes with RanGTPase and interacts with importinß via basic-acidic patch interaction, which leads to inhibition of STAT3 translocation. The interacting residues involved for this structural mechanism would be instrumental in designing inhibitors for STAT3, which mimics ARHI thereby leading to the suppression of cancer cell growth.

Molecular dynamic simulations of the tubulin-human gamma synuclein complex: structural insight into the regulatory mechanism involved in inducing resistance against Taxol.

Members of the synuclein family (α, ß and γ synucleins) are intrinsically disordered in nature and play a crucial role in the progression of various neurodegenerative disorders and cancers. The association of γSyn with both BubR1 as well as microtubule subunits renders resistance against various anti-cancer drugs. However, the structural aspects underlying drug resistance have not been explored. In this study, the mechanism involved in the association between γSyn and microtubule subunits (αßTub) was investigated and the results reveal a strong interaction between γSyn and the tail regions of αßTub. Complexation of γSyn induces conformational rearrangements in the nucleotide binding loops (NBL), interdomain and tail regions of both α and ßTub. Moreover, in ßTub, the massive displacement observed in M and S loops significantly alters the binding site of microtubule targeting drugs like Taxol. The resulting weak association between Taxol and ßTub of the γSyn-αßTub complex was confirmed by molecular dynamic simulation studies. In addition, the effect of Taxol on NBL, M and S loops of αßTub, is reversed in the presence of γSyn. These results clearly indicate that the presence of γSyn annulled the allosteric regulation imposed by Taxol on the αßTub complex as well as preventing the binding of microtubule targeting drugs, which eventually leads to the development of resistance against these drugs in cancer cells.

Structural insights into interacting mechanism of ID1 protein with an antagonist ID1/3-PA7 and agonist ETS-1 in treatment of ovarian cancer: molecular docking and dynamics studies.

Among the many abnormally expressed proteins in ovarian cancer, the prominent cancer in women, ID1 (inhibitors of DNA binding protein 1) is a potential one among other several targets. Interaction of ID1 with ETS-1 (transcriptional activator of p16(INK4a)) suppresses the transcription of p16(INK4a) and causes abnormal cell proliferation. A peptide aptamer (ID1/3-PA7) has been designed to prevent this interaction and thereby leading to the transcription of p16(INK4a). However, the structural basis behind the molecular interaction of ID1 with ETS-1 (agonist) and ID1/3-PA7 (antagonist) is poorly understood. In order to understand this structural recognition and their interaction mechanism, in silico methods were used. From this interaction analysis, the residues of ETS-1 involved in interaction with the p16(INK4a) promoter were found to be targeted by ID1. Subsequently, ETS-1 binding residues of ID1 were found to be targeted by its aptamer- ID1/3-PA7. These results suggest that both ETS-1 and ID1/3-PA7 binds at the same region harbored by the residues-H97, D100, R103, D104, L107, A144, C145, D149, D150 and C154 of ID1. All these observations correlate with the experimental reports, suggesting that the identified residues might play a crucial role in promulgating the oncogenic effects of ID1. In silico alanine scanning mutagenesis also confirms the role of identified hot spot residues in p16(INK4a) regulation. Finally, the molecular dynamic simulation studies reveal the prolonged stability of the aforementioned interacting complexes. The obtained results throw light on the structure and residues of ID1 involved in transcriptional regulation of p16(INK4a).