New orally active dual enkephalinase inhibitors (DENKIs) for central and peripheral pain treatment.

Protecting enkephalins, endogenous opioid peptides released in response to nociceptive stimuli, is an innovative approach for acute and neuropathic pain alleviation. This is achieved by inhibition of their enzymatic degradation by two membrane-bound Zn-metallopeptidases, neprilysin (NEP, EC 3.4.24.11) and aminopeptidase N (APN, EC 3.4.11.2). Selective and efficient inhibitors of both enzymes, designated enkephalinases, have been designed that markedly increase extracellular concentrations and half-lives of enkephalins, inducing potent antinociceptive effects. Several chemical families of Dual ENKephalinase Inhibitors (DENKIs) have previously been developed but devoid of oral activity. We report here the design and synthesis of new pro-drugs, derived from co-drugs combining a NEP and an APN inhibitor through a disulfide bond with side chains improving oral bioavailability. Their pharmacological properties were assessed in various animal models of pain targeting central and/or peripheral opioid systems. Considering its efficacy in acute and neuropathic pain, one of these new DENKIs, 19-IIIa, was selected for clinical development.

Highly sensitive quenched fluorescent substrate of Legionella major secretory protein (msp) based on its structural analysis.

Legionella pneumophila has been shown to secrete a protease termed major secretory protein (Msp). This protease belongs to the M4 family of metalloproteases and shares 62.9% sequence similarity with pseudolysin (EC 3.4.24.26). With the aim of developing a specific enzymatic assay for the detection and quantification of Msp, the Fluofast substrate library was screened using both enzymes in parallel. Moreover, based on the crystal structure of pseudolysin, a model of the Msp structure was built. Screening of the peptide library identified a lead substrate specifically cleaved by Msp that was subsequently optimized by rational design. The proposed model for Msp is consistent with the enzymatic characteristics of the studied peptide substrates and provides new structural information useful for the characterization of the protease. This study leads to the identification of the first selective and high affinity substrate for Msp that is able to detect picomolar concentrations of the purified enzyme. The identified substrate could be useful for the development of a novel method for the rapid detection of Legionella.

Pluripotentialities of a quenched fluorescent peptide substrate library: enzymatic detection, characterization, and isoenzymes differentiation.

Protease inhibitors represent a major class of drugs, even though a large number of proteases remain unexplored. Consequently, a great interest lies in the identification of highly sensitive substrates useful for both the characterization and the validation of these enzyme targets and for the design of inhibitors as potential therapeutic agents through high-throughput screening (HTS). With this aim, a synthetic substrate library, in which the highly fluorescent (L)-pyrenylalanine residue (Pya) is efficiently quenched by its proximity with the p-nitro-(L)-phenylalanine (Nop) moiety, was designed. The cleavage between Pya and Nop leads to a highly fluorescent metabolite providing the required sensitivity. This library, characterized by a water-soluble primary sequence Ac-SGK-Pya-(X)(n)(-)Nop-GGK-NH(2), X being a mixture of 10 natural amino acids (A, I, L, K, F, W, E, Q, T, P) and n varying from 0 to 3, was validated using enzymes belonging to the four main types of hydrolases: serine-, metallo-, cystein-, and aspartyl-proteases. The selectivity of substrates belonging to this library was evidenced by characterizing specific substrates for the isoenzymes NEP-1 and NEP-2. This library easily synthesized is of great interest for the identification and development of selective and specific substrates for still uncharacterized endoproteases.