High-throughput docking for the identification of new influenza A virus polymerase inhibitors targeting the PA-PB1 protein-protein interaction

n/

Probing the Binding Site of Abl Tyrosine Kinase Using in Situ Click Chemistry

Modern combinatorial chemistry is used to discover compounds with desired function by an alternative strategy, in which the biological target is directly involved in the choice of ligands assembled from a pool of smaller fragments. Herein, we present the first experimental result where the use of in situ click chemistry has been successfully applied to probe the ligand-binding site of Abl and the ability of this enzyme to form its inhibitor. Docking studies show that Abl is able to allow the in situ click chemistry between specific azide and alkyne fragments by binding to Abl-active sites. This report allows medicinal chemists to use protein-directed in situ click chemistry for exploring the conformational space of a ligand-binding pocket and the ability of the protein to guide its inhibitor. This approach can be a novel, valuable tool to guide drug design synthesis in the field of tyrosine kinases

Insight into the Allosteric Inhibition of Abl Kinase

5Abl kinase inhibitors targeting the ATP binding pocket are currently used as a front-line therapy for the treatment of chronic myelogenous leukemia (CML), but their use has significant limitation because of the development of drug resistance (especially due to the T315I mutation). Two compounds (GNF-2 and BO1) have been found able to inhibit the Abl activity through a peculiar mechanism of action. Particularly, GNF-2 acts as allosteric inhibitor against Bcr-Abl wild type (wt), but it has no activity against the gatekeeper mutant T315I. Its activity against the last mutant reappears when used together with an ATP-competitive inhibitor such as Imatinib or Nilotinib. A crystal structure of GNF-2 bound to the Abl myristoyl pocket (MP) has been released. On the contrary, BO1 shows an ATP-competitive/mixed mechanism of action against the wt, while it acts as an allosteric inhibitor against T315I. In order to better understand the mechanism of Abl allosteric inhibition, MD simulations and MM/GBSA analysis were performed on Abl wt and T315I in complex with GNF-2 and BO1, and the results were compared to those found for the natural myristoyl ligand. Similarly to that observed for the myristoyl group, the binding of an allosteric inhibitor to the MP promotes the formation of a compact and inhibited conformation of the wt protein, characterized by the stabilization of the intramolecular interactions that occur between SH2-SH3 and kinase domains. Conversely, an overall higher flexibility was observed with the Abl T315I mutant, especially in the case of GNF-2. Our analysis highlighted differences in the dynamic behavior of GNF-2 and BO1 which could explain the different biological profiles of the two allosteric inhibitors against the T315I mutant.nonenoneFallacara, Anna Lucia; Tintori, Cristina; Radi, Marco; Schenone, Silvia; Botta, MaurizioFallacara, Anna Lucia; Tintori, Cristina; Radi, Marco; Schenone, Silvia; Botta, Maurizi

SMALL MOLECULES SOLVING BIG PROBLEMS: PRESENT AND FUTURE OF DRUG DISCOVERY

The Drug development process has undergone a great change over the years. The way, from haphazard discovery of new natural products with a potent biological activity to a rational design of small molecule effective against a selected target, has been long and sprinkled with difficulties. The oldest drug development models are widely perceived as opaque and inefficient, with the cost of research and development continuing to rise even if the production of new drugs remains constant. The present paper, will give an overview of the principles, approaches, processes, and status of drug discovery today with an eye towards the past and the future

Inhibitors of tau-phosphorylating kinases

The phosphorylation of tau protein is finely regulated by a balance between phosphorylation and dephosphorylation processes carried out by kinases and phosphatases. It has been suggested that the disruption of this equilibrium and consequent abnormal tau phosphorylation contribute to the aggregation of tau. The understanding of this important mechanism is of high interest because of the implication of tau aggregates in the development of Alzheimer’s disease (AD). In the last few years, among the possible strategies which could be used to reduce tau phosphorylation, the inhibition of certain tyrosine kinases has been suggested as a promising alternative to the common therapeutic approaches. In this chapter we will first give an overview of the tau protein kinases, their roles in cells, regulation and importance in AD. This will be followed by a more detailed description of the role of Fyn, a member of the Src family kinases, in the physiological development of CNS and the pathological progress of AD. How the inhibition of Fyn could be used as a new strategy in the fight against AD will be discussed

Protein-protein interactions and human cellular cofactors as new targets for HIV therapy

Two novel approaches for the development of new drugs against AIDS are summarized each leading to the achievement of important discoveries in anti-HIV therapy. Despite the success of HAART in reducing mortality, resistant strains continue to emerge in the clinic, underscoring the importance of developing next-generation drugs. Protein-protein interactions and human cellular cofactors represent the new targets of tomorrow in HIV research. The most relevant results obtained in the last few years by the two new strategies are described herein

Protein-protein interactions and human cellular cofactors as new targets for HIV therapy

Two novel approaches for the development of new drugs against AIDS are summarized each leading to the achievement of important discoveries in anti-HIV therapy. Despite the success of HAART in reducing mortality, resistant strains continue to emerge in the clinic, underscoring the importance of developing next-generation drugs. Protein protein interactions and human cellular cofactors represent the new targets of tomorrow in HIV research. The most relevant results obtained in the last few years by the two new strategies are described herein

Pyrrolo[2,3-d]pyrimidines as kinase inhibitors

The pyrrolo[2,3-d]pyrimidine nucleus is a deaza-isostere of adenine, the nitrogenous base of ATP, and is present in many ATP-competitive inhibitors of different kinases. In the last few years the number of articles and patents that have appeared involving this type of inhibitors has dramatically increased and some compounds have been approved for the treatment of inflammatory or myeloproliferative diseases. Other derivatives are currently being evaluated in clinical trials. This review deals with pyrrolo[2,3-d]pyrimidine derivatives active as kinase inhibitors that have been reported in the literature from 2011 to 2016, with a particular interest on the recently patented compounds. The molecules are classified depending on the inhibited kinase, focusing on their chemical structures

Pyrrolo[2,3-d]pyrimidines active as Btk inhibitors

Introduction: Btk is a tyrosine kinase dysregulated in several B-cell malignancies and autoimmune diseases, and this has given rise to a search for Btk inhibitors. Nevertheless, only one Btk inhibitor, ibrutinib, has been approved to date, although other compounds are currently being evaluated in clinical trials or in preclinal stages. Area covered: This review, after a brief introduction on Btk and its inhibitors already in clinical trials, focusses on pyrrolo[2,3-d]pyrimidine derivatives patented in the last five years as Btk inhibitors. Indeed, the pyrrolo[2,3-d]pyrimidine scaffold, being a deaza-isostere of adenine, the nitrogenous base of ATP, is an actively pursued target for Btk inhibitors. The patent literature since 2012 have been extensively investigated, pointing out the general features of the patented compounds and, when it is possible, their mechanism of action. Expert opinion: The recently patented pyrrolo[2,3-d]pyrimidines, acting as reversible or irreversible inhibitors, showed a very interesting in vitro activity. For this reason, the development of compounds endowed with this scaffold could afford a significant impact in the search for drug candidates for the treatment of immune diseases or B-cell malignancies

3-Arylidene-N-hydroxyoxindoles: A New Class of Compounds Endowed with Antitumor Activity

A series of compounds containing the N-hydroxyoxindole scaffold were synthesized and evaluated for antitumor activity. The compounds showed potent antiproliferative activity against the wild-type p53 IGROV-1 ovarian carcinoma cell line and considerably lower efficacy against the mutant IGROV-1/Pt1 subline that lacks p53 function. The differential response of ovarian carcinoma cells depending on p53 status was also reflected in the varied susceptibility to apoptosis of the treated cell lines. These results support a role for the p53 transcription factor as a determinant of cytotoxicity. The therapeutic potential of the most promising compound of the series was evaluated in the treatment of an IGROV-1 xenograft growing as ascitic tumor in mice. Using intraperitoneal administration, daily treatment with the compound for four weeks produced a significant delay in the onset of ascites