Mariangela Agamennone

Biphenyl Sulfonylamino Methyl Bisphosphonic Acids as Inhibitors of Matrix Metalloproteinases and Bone Resorption

A number of matrix metalloproteinases (MMPs), proteins important in the balance of bone remodeling, play a critical role both in cancer metastasis and in bone matrix turnover associated with the presence of cancer cells in bone. Here, we report the synthesis and biological evaluation of a new class of MMP inhibitors characterized by a bisphosphonate function as the zinc binding group. Since the bisphosphonate group is also implicated in osteoclast inhibition and provides a preferential affinity to biological apatite, the new molecules can be regarded as bone‐seeking medicinal agents. Docking experiments were performed to clarify the mode of binding of bisphosphonate inhibitors in the active site of MMP‐2. The most promising of the studied bisphosphonates showed nanomolar inhibition against MMP‐2 and resulted in potent inhibition of osteoclastic bone resorption in vitro.

Synthesis, SAR, and Biological Evaluation of α-Sulfonylphosphonic Acids as Selective Matrix Metalloproteinase Inhibitors

Selective MMP inhibitors: Eleven α‐sulfonylphosphonates were synthesized and tested as MMP inhibitors. The IC50 values for most of them are in the nanomolar range against MMP‐2, ‐8, ‐13, and ‐14, with an interesting selectivity profile versus MMP‐9.

Bovine lactoferrin-derived peptides as novel broad-spectrum inhibitors of influenza virus.

Abstract Bovine lactoferrin (bLf) is a multifunctional glycoprotein that plays an important role in innate immunity against infections, including influenza. Here we have dissected bLf into its C- and N-lobes and show that inhibition of influenza virus hemagglutination and cell infection is entirely attributable to the C-lobe and that all major virus subtypes, including H1N1 and H3N2, are inhibited. By far-western blotting and sequencing studies, we demonstrate that bLf C-lobe strongly binds to the HA2 region of viral hemagglutinin, precisely the highly conserved region containing the fusion peptide. By molecular docking studies, three C-lobe fragments were identified which inhibited virus hemagglutination and infection at fentomolar concentration range. Besides contributing to explain the broad anti-influenza activity of bLf, our findings lay the foundations for exploiting bLf fragments as source of potential anti-influenza therapeutics.

Fragmenting the S100B-p53 interaction: combined virtual/biophysical screening approaches to identify ligands.

S100B contributes to cell proliferation by binding the C terminus of p53 and inhibiting its tumor suppressor function. The use of multiple computational approaches to screen fragment libraries targeting the human S100B–p53 interaction site is reported. This in silico screening led to the identification of 280 novel prospective ligands. NMR spectroscopic experiments revealed specific binding at the p53 interaction site for a set of these compounds and confirmed their potential for further rational optimization. The X‐ray crystal structure determined for one of the binders revealed key intermolecular interactions, thus paving the way for structure‐based ligand optimization.

Probing the S1′ Site for the Identification of Non‐Zinc‐Binding MMP‐2 Inhibitors

Matrix metalloproteinases (MMPs) are zinc‐dependent enzymes involved in several pathological states. Among them, MMP‐2 is a relevant therapeutic target because of its role in cancer development and progression. Many MMP inhibitors (MMPIs) have been discovered over the last 30 years, and the majority of them contain a functional group that binds the zinc ion (zinc‐binding group; ZBG). Unfortunately, no MMPIs have reached the market yet, owing to toxic effects due to unselective interactions of the ZBG. The new generation of MMPIs that do not bind the zinc ion could overcome problems of selectivity and toxicity, but have so far been developed only for MMP‐8, ‐12, and ‐13. In this work, a virtual screening protocol was established by combining ligand‐ and structure‐based methods to identify non‐zinc‐binding MMP‐2 inhibitors using a new‐generation MMP‐8 inhibitor as a probe to find unexplored interactions in the MMP‐2 S1′ site. The screening allowed the identification of micromolar MMP‐2 inhibitors that putatively avoid binding the zinc ion, as demonstrated by docking calculations. The LIA model, built to correlate predicted and experimental binding energies of the identified non‐zinc‐binding MMP‐2 hits, underpins the reliability of the predicted docking poses.

Identification of new anti-Candida compounds by ligand-based pharmacophore virtual screening

Abstract Candida albicans represents the most prevalent microbial population in mucosal and systemic infections, usually confined to severely immunocompromised people. Considering the increase of resistant strains and the demand for new antifungal drugs endowed with innovative mechanism of action, we performed a ligand-based virtual screening in order to identify new anti-Candida compounds. Starting from a large library of natural/semisynthetic products and several published synthesized compounds, three coumarin derivatives were discovered in silico as new hit compounds and submitted to the in vitro assay in order to confirm their predicted biological activity.

Amino Acid Derivatives as New Zinc Binding Groups for the Design of Selective Matrix Metalloproteinase Inhibitors

A number of matrix metalloproteinases (MMPs) are important medicinal targets for conditions ranging from rheumatoid arthritis to cardiomyopathy, periodontal disease, liver cirrhosis, multiple sclerosis, and cancer invasion and metastasis, where they showed to have a dual role, inhibiting or promoting important processes involved in the pathology. MMPs contain a zinc (II) ion in the protein active site. Small-molecule inhibitors of these metalloproteins are designed to bind directly to the active site metal ions. In an effort to devise new approaches to selective inhibitors, in this paper, we describe the synthesis and preliminary biological evaluation of amino acid derivatives as new zinc binding groups (ZBGs). The incorporation of selected metal-binding functions in more complex biphenyl sulfonamide moieties allowed the identification of one compound able to interact selectively with different MMP enzymatic isoforms.

Fragment-Based Discovery of 5-Arylisatin-Based Inhibitors of Matrix Metalloproteinases 2 and 13

Matrix metalloproteinases (MMPs) are well‐established targets for several pathologies. In particular, MMP‐2 and MMP‐13 play a prominent role in cancer progression. In this study, a structure‐based screening campaign was applied to prioritize metalloproteinase‐oriented fragments. This computational model was applied to a representative fragment set from the publically available EDASA Scientific compound library. These fragments were prioritized, and the top‐ranking hits were tested in a biological assay to validate the model. Two scaffolds showed consistent activity in the assay, and the isatin‐based compounds were the most interesting. These latter fragments have significant potential as tools for the design and realization of novel MMP inhibitors. In addition to their micromolar activity, the chemical synthesis affords flexible and creative access to their analogues.

Phosphonate Emerging Zinc Binding Group in Matrix Metalloproteinase Inhibitors.

Matrix metalloproteinases (MMPs) are zinc-dependent endopeptidases, capable to degrade the extracellular matrix (ECM) in physiologic conditions. Because of their overexpression and pivotal role in many pathological events, they have been proposed as a therapeutic and prognostic target for a number of diseases. Selectivity among MMPs is essential for realizing the clinical potential of inhibitors. The design of MMP inhibitors (MMPIs) has largely focused on development of various compounds containing a zinc binding group (ZBG) in their structure, with hydroxamate being the most potent one. Due to the high degree of homology in the catalytic domain of all the MMPs, the specificity and selectivity of first generation hydroxamate MMPIs were minimal, with several off-target effects and binding to other metzincins. This review highlights the role of phosphonate as ZBG in the design and development of new MMPIs.

Catechol-based matrix metalloproteinase inhibitors with additional antioxidative activity

Abstract New catechol-containing chemical entities have been investigated as matrix metalloproteinase inhibitors as well as antioxidant molecules. The combination of the two properties could represent a useful feature due to the potential application in all the pathological processes characterized by increased proteolytic activity and radical oxygen species (ROS) production, such as inflammation and photoaging. A series of catechol-based molecules were synthesized and tested for both proteolytic and oxidative inhibitory activity, and the detailed binding mode was assessed by crystal structure determination of the complex between a catechol derivative and the matrix metalloproteinase-8. Surprisingly, X-ray structure reveals that the catechol oxygens do not coordinates the zinc atom.