Binding properties of different categories of IDO1 inhibitors: a microscale thermophoresis study.

AIM: Inhibition of IDO1 is a strategy pursued in the immune-oncology pipeline for the development of novel anticancer therapies. At odds with an ever-increasing number of inhibitors being disclosed in the literature and patent applications, only very few compounds have hitherto advanced in clinical settings. MATERIALS & METHODS: We have used MicroScale Thermophoresis analysis and docking calculations to assess on a quantitative basis the binding properties of distinct categories of inhibitors to IDO1. RESULTS: Results shed further light on hidden molecular aspects governing the recognition by the enzyme of compounds with different mechanism of inhibition. CONCLUSION: Results pinpoint specific binding features of distinct inhibitors to IDO1 that offer clues for the design of next-generation inhibitors of the enzyme.

Aptamer Binding Studies Using MicroScale Thermophoresis.

The characterization and development of highly specific aptamers requires the analysis of the interaction strength between aptamer and target. MicroScale Thermophoresis (MST) is a rapid and precise method to quantify biomolecular interactions in solution at microliter scale. The basis of this technology is a physical effect referred to as thermophoresis, which describes the directed movement of molecules through temperature gradients. The thermophoretic properties of a molecule depend on its size, charge, and hydration shell. Since at least one of these parameters is altered upon binding of a ligand, this method can be used to analyze virtually any biomolecular interaction in any buffer or complex bioliquid. This section provides a detailed protocol describing how MST is used to obtain quantitative binding parameters for aptamer-target interactions. The two DNA-aptamers HD1 and HD22, which are targeted against human thrombin, are used as model systems to demonstrate a rapid and straightforward screening approach to determine optimal buffer conditions.

One Question, Multiple Answers: Biochemical and Biophysical Screening Methods Retrieve Deviating Fragment Hit Lists.

Fragment-based lead discovery is gaining momentum in drug development. Typically, a hierarchical cascade of several screening techniques is consulted to identify fragment hits which are then analyzed by crystallography. Because crystal structures with bound fragments are essential for the subsequent hit-to-lead-to-drug optimization, the screening process should distinguish reliably between binders and non-binders. We therefore investigated whether different screening methods would reveal similar collections of putative binders. First we used a biochemical assay to identify fragments that bind to endothiapepsin, a surrogate for disease-relevant aspartic proteases. In a comprehensive screening approach, we then evaluated our 361-entry library by using a reporter-displacement assay, saturation-transfer difference NMR, native mass spectrometry, thermophoresis, and a thermal shift assay. While the combined results of these screening methods retrieve 10 of the 11 crystal structures originally predicted by the biochemical assay, the mutual overlap of individual hit lists is surprisingly low, highlighting that each technique operates on different biophysical principles and conditions.

Itraconazole inhibits enterovirus replication by targeting the oxysterol-binding protein.

Itraconazole (ITZ) is a well-known antifungal agent that also has anticancer activity. In this study, we identify ITZ as a broad-spectrum inhibitor of enteroviruses (e.g., poliovirus, coxsackievirus, enterovirus-71, rhinovirus). We demonstrate that ITZ inhibits viral RNA replication by targeting oxysterol-binding protein (OSBP) and OSBP-related protein 4 (ORP4). Consistently, OSW-1, a specific OSBP/ORP4 antagonist, also inhibits enterovirus replication. Knockdown of OSBP inhibits virus replication, whereas overexpression of OSBP or ORP4 counteracts the antiviral effects of ITZ and OSW-1. ITZ binds OSBP and inhibits its function, i.e., shuttling of cholesterol and phosphatidylinositol-4-phosphate between membranes, thereby likely perturbing the virus-induced membrane alterations essential for viral replication organelle formation. ITZ also inhibits hepatitis C virus replication, which also relies on OSBP. Together, these data implicate OSBP/ORP4 as molecular targets of ITZ and point to an essential role of OSBP/ORP4-mediated lipid exchange in virus replication that can be targeted by antiviral drugs.

The role of the Tra1p transcription factor of Magnaporthe oryzae in spore adhesion and pathogenic development.

Transcription factors play a critical regulatory role in development by binding DNA and initiating alterations in gene transcription. The transcript of the putative Magnaporthe oryzae transcription factor-encoding gene TRA1 accumulates during germination and this accumulation was previously found to depend on the transcription factor Con7p. In the current work tra1⁻ mutants were generated and these strains were found to exhibit a reduced attachment, germination, appressorium formation and virulence. Adhesion to artificial and plant surfaces was affected, and FITC-labelled concanavalin A, a lectin which inhibits attachment of Magnaporthe spores, showed a reduced affinity for mutant spore tip where it normally preferentially binds. We used microarray analysis to identify Tra1p-dependent genes from two different sources: aerial structures and conidia. Mutation of 11 Tra1p-dependent genes showed that the predicted transcription factor encoding gene TDG2 is required for normal adhesion and virulence, that the genes TDG7 and TDG4 are required for normal sporulation and that TDG6 is required for wild-type levels of spore adhesion.