Progress towards water-soluble triazole-based selective MMP-2 inhibitors.

Water solubility is a key aspect that needs to be addressed to obtain drug-like compounds. In an effort to improve the water solubility of our recently reported nanomolar matrix metalloproteinase type 2 (MMP-2) inhibitors based on triazole-substituted hydroxamates, we synthesized a new series of α-sulfone, α-tetrahydropyran and α-piperidine, α-sulfone clicked hydroxamates and determined their inhibitory activities against both MMP-2 and MMP-9. The best results were found for 13e, a water-soluble compound that displays a low nanomolar activity against MMP-2 and is 26-fold less active against MMP-9. This finding allowed us to pursue in vitro permeability through the Caco-2 monolayer and opened the possibility of carrying out further preclinical investigations. Docking and MD simulations have been performed in order to rationalize the biological results. The inhibitory activity of this compound against a panel of ten MMPs was determined showing an interesting MMP-2/MMP-1, -8, and -14 selectivity profile. The cytotoxicity and anti-invasive activity of the compounds on highly metastatic human fibrosarcoma tumor cells (HT1080) were determined, showing, at 10 µM concentration, a decrease in cell invasiveness up to 80%.

Potent "clicked" MMP2 inhibitors: synthesis, molecular modeling and biological exploration.

A new series of MMP2 inhibitors is described, following a fragment-based drug design approach. One fragment containing an azide group and a well known hydroxamate Zinc Binding Group in a α-sulfone, α-tetrahydropyrane scaffold, has been synthesized. Water-LOGSY, STD and competition-STD experiments indicate that this fragment binds to the active site of the enzyme. A click chemistry reaction was used to connect the azide to lipophilic alkynes selected to interact selectively with the S1' subunit of MMP2, as shown by docking and molecular dynamic experiments of the designed compounds. The most potent compounds 18 and 19 displayed an IC(50) of 1.4 and 0.3 nM against MMP2 respectively, and showed negligible activity towards MMP1 and MMP7, two metalloproteinases which have a shallow S1' subsite. Compound 18 also showed a promising selectivity profile against some antitarget metalloproteinases, such as MMP8, and considerably less activity against MMP14 (IC(50) = 65 nM), and MMP9 (IC(50) = 98 nM), other MMPs characterized by having a deep S1' pocket and, therefore, more similar to MMP2.

Permanent up-regulation of regulatory T-lymphocytes in patients with head and neck cancer.

Various immune functions of different types of immune cells are strongly impaired in patients with head and neck squamous cell carcinoma (HNSCC). Regulatory T-lymphocyte cells (Tregs) have been suggested to be involved in the immunomodulation of immune responses and contribute to HNSCC progression and immune escape. 'Naturally' occurring CD4+ CD25+ Tregs represent a small fraction within the different subsets of regulatory T cells, which are known to inhibit numerous immune functions of different types of immune cells. In this study, the cellular ratio of CD4+ CD25(high) Tregs to the entire population of CD4+ T-lymphocytes was analyzed with respect to different stages of tumor progression and disease. Our data indicate a significantly high increased abundance of CD4+ CD25(high) CD127(low) Tregs in the peripheral blood of patients with HNSCC, which in addition show modulated expression levels of various functional proteins. Surprisingly, increased Treg levels were found even in patients with no active disease several years after tumor resection, with no significant correlation to the individual tumor stage. Additionally, increased levels of chemokine CCL22, which mediates migration of Tregs to the tumor, and upregulation of the corresponding receptor protein CCR4 were observed in HNSCC. Our data strongly suggest that HNSCC leads to a permanent shift of Treg levels with hardly recognizable recovery rates.