Isoliquiritigenin: a potential drug candidate for the management of erectile dysfunction.

OBJECTIVE: This study aimed to assess the erectogenic properties of isoliquiritigenin taking sildenafil (SDF) as the standard. METHODS: The binding affinity of isoliquiritigenin (ISL) with the erectile marker proteins (endothelial nitric oxide synthase [eNOS] and enzyme phosphodiesterase type 5 [PDE5]) was investigated using Autodock Vina, which was validated using molecular dynamics simulation. Furthermore, the effect of ISL on the eNOS and PDE5 messenger ribonucleic acid (mRNA) expression and the sexual behavior of mice was investigated, along with the assessment of the pharmacokinetics of ISL. KEY FINDINGS: The results revealed that the binding affinity of ISL-eNOS/PDE5 and SDF-eNOS/PDE5 was in the range of -7.5 to -8.6 kcal/mol. The ISL-eNOS/PDE5 complexes remained stable throughout the 100 ns simulation period. Root mean square deviation, Rg, SASA, hydrogen, and hydrophobic interactions were similar between ISL-eNOS/PDE5 and SDF-eNOS/PDE5. Analysis of mRNA expressions in paroxetine (PRX)-induced ED mice showed that the co-administration of PRX with ISL reduced PDE5 and increased eNOS mRNA expression, similar to the co-administered group (PRX+SDF). The sexual behavior study revealed that the results of PRX+ISL were better than those of the PRX+SDF group. Pharmacokinetic evaluation further demonstrated that ISL possesses drug-like properties. CONCLUSIONS: The results showed that ISL is equally potent as SDF in terms of binding affinity, specific pharmacological properties, and modulating sexual behavior.

RET Alterations Differentiate Molecular Profile of Medullary Thyroid Cancer.

PURPOSE: Medullary thyroid cancer (MTC) is a rare cancer originating from parafollicular C cells of the thyroid gland. Therapeutically relevant alterations in MTC are predominantly reported in RET oncogene, and lower-frequency alterations are reported in KRAS and BRAF. Nevertheless, there is an unmet need existing to analyze the MTC in the Indian cohort by using in-depth sequencing techniques that go beyond the identification of known therapeutic biomarkers. MATERIALS AND METHODS: Here, we characterize MTC using integrative whole-exome and whole-transcriptome sequencing of 32 MTC tissue samples. We performed clinically relevant variant analysis, molecular pathway analysis, tumor immune-microenvironment analysis, and structural characterization of RET novel mutation. RESULTS: Mutational landscape analysis shows expected RET mutations in 50% of the cases. Furthermore, we observed mutations in known cancer genes like KRAS, HRAS, SF3B1, and BRAF to be altered only in the RET-negative cohort. Pathway analysis showed differential enrichment of mutations in transcriptional deregulation genes in the RET-negative cohort. Furthermore, we observed novel RET kinase domain mutation Y900S showing affinity to RET inhibitors accessed via molecular docking and molecular dynamics simulation. CONCLUSION: Altogether, this study provides a detailed genomic characterization of patients with MTC of Indian origin, highlighting the possible utility of targeted therapies in this disease.

Computational investigation on the effect of Oleuropein aglycone on the α-synuclein aggregation.

Parkinson's disease (PD) is considered to be the second most common progressive neurodegenerative brain disorder after Alzheimer's disease, which is caused by misfolding and aggregation of Alpha-synuclein (α-synuclein). It is characterized by distinct aggregated fibrillary form of α-synuclein known as the Lewy bodies and Lewy neurites. The most promising approach to combat PD is to prevent the misfolding and subsequent aggregation of α-synuclein. Recently, Oleuropein aglycone (OleA) has been reported to stabilize the monomeric structure of α-synuclein, subsequently favoring the growth of nontoxic aggregates. Therefore, understanding the conformational dynamics of α-synuclein monomer in the presence of OleA is significant. Here, we have investigated the effect of OleA on the conformational dynamics and the aggregation propensity of α-synuclein using molecular dynamics simulation. From molecular dynamics trajectory analysis, we noticed that when OleA is bound to α-synuclein, the intramolecular distance between non-amyloid-ß component domain and C-terminal domain of α-synuclein was increased, whereas long-range hydrophobic interactions between the two region were reduced. Oleuropein aglycone was found to interact with the N-terminal domain of α-synuclein, making this region unavailable for interaction with membranes and lipids for the formation of cellular toxic aggregates. From the binding-free energy analysis, we found binding affinity between α-synuclein and OleA to be indeed high (ΔGbind = -12.56 kcal mol-1 from MM-PBSA and ΔGbind = -27.41 kcal mol-1from MM-GBSA). Our findings in this study thus substantiate the effect of OleA on the structure and stabilization of α-synuclein monomer that subsequently favors the growth of stable and nontoxic aggregates.Communicated by Ramaswamy H. Sarma.

Computational Study on the Role of γ-Synuclein in Inhibiting the α-Synuclein Aggregation.

BACKGROUND: α-Synuclein (αS) is the precursor protein present in Lewy Bodies that helps in the formation of highly ordered amyloid fibrils that is associated with the occurrence of Parkinson's disease, a neuro-degenerative disorder. Many reports have now been focused on finding the probable targets to weaken this debilitating disease. Recently γ-synuclein (γS), a presynaptic protein, was highlighted to inhibit the aggregation propensity of αS both in vivo and in vitro. However the nature, location and specificity of molecular interactions existing between the αS and γS is not known in spite of the potential importance of γS as an inhibitor of αS. OBJECTIVE: To understand the inhibition of αS aggregation by γS at the molecular level. METHODS: Umbrella sampling method was used along with molecular dynamics simulation to investigate the conformational dynamics, degree of association and molecular interaction between the monomeric units in the αS/γS hetero-dimer. RESULTS AND DISCUSSION: The dissociation energy barrier for αS/γS hetero-dimer was found to be higher than αS/αS homo-dimer. αS can therefore readily form a hetero-dimer by combining with γS than forming a homo-dimer. We also observed strong transient interactions involving hydrogen bonds, salt-bridges and non-bonded contacts between the monomeric units in αS/γS hetero-dimer. CONCLUSION: Our findings suggest that γS may inhibit the aggregation propensity of αS.

Computational investigation on the effects of H50Q and G51D mutations on the α-Synuclein aggregation propensity.

The aggregation of α-synuclein is linked directly to the histopathology of Parkinson's disease (PD). However, several missense mutations present in the α-synuclein gene (SNCA) have been known to be associated with PD. Several studies have highlighted the effect of SNCA mutations on the α-synuclein aggregation, but their pathological roles are not completely established. In this study, we have focused on the effects of the recently discovered α-synuclein missense mutants (H50Q and G51D) on the aggregation using computational approaches. We performed all atom molecular dynamics (MD) simulation on these mutants and compared their conformational dynamics with Wild-Type (WT) α-synuclein. We noticed the solvent accessible surface area (SASA), radius of gyration, atomic fluctuations, and beta strand content to be higher in H50Q than G51D and WT. Using PDBSum online server; we analyzed the inter-molecular interactions that drive the association of monomeric units of H50Q, WT, and G51D in forming the respective homo-dimer. We noticed the interface area, number of interacting residues and binding free energy to be higher for H50Q homo-dimer than the WT and G51D homo-dimers. Our findings in this study suggest that in comparison to WT and G51D, H50Q mutation to have a positive effect on increasing the α-synuclein aggregation propensity. Hence, we see that H50Q and G51D mutation show conflicting effect on the aggregation propensity of α-synuclein.

Investigation on the Molecular Interactions Stabilizing the Structure of α-synuclein Fibril: An In silico Study.

BACKGROUND: Amyloid fibrils represent stable form of many misfolded proteins associated with numerous diseases like Parkinson's Disease (PD), Type II diabetes and Alzheimer's disease (AD). α-synuclein protein is the principal constituent of Lewy bodies that are considered to be pathological hallmark of PD. Recently, a high resolution structure of α-synuclein protein that stacks together forming fibrils in brains of PD patients were identified. What structural features drive pathology of PD can now be possibly answered from the fibril structure of protein. OBJECTIVES: To understand the molecular interactions those are responsible for the stability of the α- synuclein fibril structure. METHODS: To study the molecular interactions stabilizing the α-synuclein fibril, we have used a high resolution amyloid fibril structure (PDB ID 2N0A). The molecular interactions in fibril structure were studied using PDBSum server. We then looked into the destabilization of α-synuclein fibril by disrupting the salt-bridge holding the strands and probable methods to decompose fibril into structurally distinct units using Top-domain web-server. The effect of salt-bridges on the stability of the fibril structure was studied by mutating one of the residues involved in the formation of salt-bridge using molecular dynamics simulation. RESULTS: Our results indicate a finite salt-bridge (E46-K80) is crucial for stability of protofibril. Besides, we observed hydrogen bonds and non-bonded contacts involved in fibril stabilization. We noticed α-synuclein dimer predominantly exists in conformations distinct from fibril. CONCLUSION: We characterized the salient molecular interactions in α-synuclein fibril and these findings may be useful to design potential inhibitors for the treatment of PD.

Potential of mean force and molecular dynamics study on the transient interactions between α and ß synuclein that drive inhibition of α-synuclein aggregation.

Self-association of α-synuclein (αS) into pathogenic oligomeric species and subsequent formation of highly ordered amyloid fibrils is linked to the Parkinson's disease. So most of the recent studies are now focused on the development of potential therapeutic strategies against this debilitating disease. ß-synuclein (ßS), a presynaptic protein that co-localizes with αS has been recently reported to act as an inhibitor of αS self-assembly. But the specificity of molecular interaction, nature and location between αS/ßS is not known despite the potential importance of ßS as an inhibitor of αS. We used molecular dynamics and potential of mean force (PMF) to study association of αS/ßS and αS/αS. The calculated PMF indicates that contact wells are significantly deeper and presence of a minimum at αS/ßS separation of 13.5 Å with a free energy barrier of 40 kcal/mol. We observed the dissociation energy barrier to be two times higher for the hetero-dimer (αS/ßS) than the homo-dimer (αS/αS). We also carried out umbrella samplings involving two degrees of freedom (one being the distance between the monomeric units and the other angle between the long axes of the two monomeric chains) and observed similar PMF profile. We noticed relatively stronger range of transient interactions between the monomeric units in hetero-dimer (αS/ßS) than homo-dimer (αS/αS). So our findings suggest that αS readily combines with ßS to form hetero-dimer than combining with itself in forming homo-dimer. Hence we see predominant transient interactions between αS and ßS can be used to drive inhibition of αS aggregation.