Composition and seasonal variation of volatile organic compounds in Santolina etrusca (Lacaita) Marchi & D'Amato found at Acquapendente (Viterbo, Central Italy).

The main component of the essential oil of Santolina etrusca is viridiflorol (23.98-42.23%). a compound not found in the essential oil of Santolina camaecyparissus. The main component found in this study is the same found in the essential oil obtained from plants collected in Tuscany and Umbria. However, there are important differences in the other components of the essential oil, where we found the presence of eucalyptol (2.98-9.73%) and germacrene D (2.39-19.59%). Finally, seasonal variation of the essential oil composition induces a reduction of sesquiterpenes amounts with the corresponding increase of the monoterpenes during spring and summer.

Design, synthesis, crystallographic studies, and preliminary biological appraisal of new substituted triazolo[4,3-b]pyridazin-8-amine derivatives as tankyrase inhibitors.

Searching for selective tankyrases (TNKSs) inhibitors, a new small series of 6,8-disubstituted triazolo[4,3-b]piridazines has been synthesized and characterized biologically. Structure-based optimization of the starting hit compound NNL (3) prompted us to the discovery of 4-(2-(6-methyl-[1,2,4]triazolo[4,3-b]pyridazin-8-ylamino)ethyl)phenol (12), a low nanomolar selective TNKSs inhibitor working as NAD isostere as ascertained by crystallographic analysis. Preliminary biological data candidate this new class of derivatives as a powerful pharmacological tools in the unraveling of TNKS implications in physiopathological conditions.

Quantum mechanics/molecular mechanics (QM/MM) modeling of the irreversible transamination of L-kynurenine to kynurenic acid: the round dance of kynurenine aminotransferase II.

Kynurenine aminotransferase (KAT) is a key enzyme of the kynurenine pathway along the route of tryptophan catabolism. It catalyzes the irreversible transamination reaction of L-kynurenine (L-Kyn) to kynurenic acid (KYNA), an important neuroactive metabolite that plays a role in protecting neurons from excitatory neurotransmission. Although four isoforms (KAT-I to -IV) of this enzyme have been hitherto identified, KAT-II is the enzymatic isoform that mainly accounts for the synthesis of cerebral KYNA. In this study, the transamination mechanism of L-Kyn catalyzed by KAT-II is theoretically determined by performing combined quantum mechanical and molecular mechanical (QM/MM) simulations. The results are instrumental to explore the catalytic properties of the enzyme and to provide theoretical details on the mechanism of the intramolecular condensation of the ketoacid intermediate, leading to the final product KYNA. Ultimately, they will also be of value in the future design of new KAT-II selective inhibitors.

On the way to selective PARP-2 inhibitors. Design, synthesis, and preliminary evaluation of a series of isoquinolinone derivatives.

PARP-1 and PARP-2 are members of the family of poly(ADP-ribose)polymerases, which are involved in the maintenance of genomic integrity under conditions of genotoxic stimuli. The different roles of the two isoforms under pathophysiological conditions have not yet been fully clarified, and this is partially due to the lack of selective inhibitors. We report herein the synthesis and preliminary pharmacological evaluation of a large series of isoquinolinone derivatives as PARP-1/PARP-2 inhibitors. Among them, we identified the 5-benzoyloxyisoquinolin-1(2 H)-one derivative as the most selective PARP-2 inhibitor reported so far, with a PARP-2/PARP-1 selectivity index greater than 60.

Molecular docking and spatial coarse graining simulations as tools to investigate substrate recognition, enhancer binding and conformational transitions in indoleamine-2,3-dioxygenase (IDO).

Indoleamine 2,3-dioxygenase (IDO) is an heme-containing enzyme involved in the regulation of important immunological responses and neurological processes. The enzyme catalyzes the oxidative cleavage of the pyrrole ring of the indole nucleus of tryptophan (Trp) to yield N-formylkynurenine, that is the initial and rate limiting step of the kynurenine pathway. Some indole derivatives have been reported to act as effectors of the enzyme by enhancing its catalytic activity. On the basis of the recent availability of the crystal structure of IDO, in this work we investigate substrate recognition and enhancer binding to IDO using molecular docking experiments. In addition, conformational transitions of IDO in response to substrate and enhancer binding are studied using coarse graining simulations with the program FIRST. The results enable us to identify (i) the binding site of enhancer modulators; (ii) the motion of an electrostatic gate that regulates the access of the substrate to the catalytic site of the enzyme; (iii) the movement of the anchoring region of a hairpin loop that may assist the shuttle of substrates/products to/from the catalytic site of IDO. These data, combined with available site-directed mutagenesis experiments, reveal that conformational transitions of IDO in response to substrate and enhancer binding are controlled by distinct combination of two conformational states (open and close) of the above structural motifs. On this basis, a molecular mechanism regarding substrate recognition and activity enhancement by indole derivatives is proposed.

Poly(ADP-ribose)-polymerase-catalyzed hydrolysis of NAD+: QM/MM simulation of the enzyme reaction.

Poly(ADP-ribose) polymerase (PARP) is a nuclear enzyme which uses NAD+ as substrate and catalyzes the transfer of multiple units of ADP-ribose to target proteins. PARP is an attractive target for the discovery of novel therapeutic agents and PARP inhibitors are currently evaluated for the treatment of a variety of pathological conditions such as brain ischemia, inflammation, and cancer. Herein, we use the PARP-catalyzed reaction of NAD+ hydrolysis as a model for gaining insight into the molecular details of the catalytic mechanism of PARP. The reaction has been studied in both the gas-phase and in the enzyme environment through a QM/MM approach. Our results indicate that the cleavage reaction of the nicotinamide-ribosyl bond proceeds through an SN2 dissociative mechanism via an oxacarbenium transition structure. These results confirm the importance of the structural water molecule in the active site and may constitute the basis for the design of transition-state-based PARP inhibitors.

Docking studies on PARP-1 inhibitors: insights into the role of a binding pocket water molecule.

The binding mode of a series of competitive PARP-1 inhibitors was investigated employing a molecular docking approach by using Autodock 3.0. A particular attention was given to the role played by a water molecule present in some but not all the so far available crystal structures of the catalytic domain of PARP-1. Good correlation between calculated binding energies and experimental inhibitory activities was obtained either by including (r2=0.87) or not (r2=0.84) the structural water molecule. Closer inspection of our results suggested that this water molecule should be considered part of the hydration shell of polar inhibitors and not as a structural water.

Insights into phenylalanine derivatives recognition of VLA-4 integrin: from a pharmacophoric study to 3D-QSAR and molecular docking analyses.

The very late antigen-4 (VLA-4), also known as integrin alpha4beta1, is expressed on monocytes, T- and B-lympohocytes, basophils, and eosinophils and is involved in the massive recruitment of granulocytes in different pathological conditions such as multiple sclerosis and asthma. VLA-4 interacts with its endogenous ligand VCAM-1 during chronic inflammation, and blockade of VLA-4 /VCAM-1 interaction is a potential target for immunosuppression. Two classes of VLA-4 antagonists have so far been reported: beta-amino acid derivatives containing a diaryl urea moiety (BIO-1211) and phenylalanine derivatives (TR-14035). With the aim of clarifying the structural basis responsible for VLA-4 recognition by phenylalanine derivatives, we developed a combined computational study on a set of 128 antagonists available through the literature. Our computational approach is composed of three parts. (i) A VCAM-1 based pharmacophore was constructed with a restricted number of phenylalanine derivatives to identify the region of the protein that resembles synthetic antagonists. The pharmacophore was instrumental in constructing an alignment of a set of 128 compounds. This alignment was exploited to build a pseudoreceptor model with the RECEPTOR program. (ii) 3D-QSAR analysis was carried out on the computed electrostatic and steric interaction energies with the pseudoreceptor surface. The 3D-QSAR analysis yielded a predictive model able to explain much of the variance of the 128 antagonists. (iii) A homology modeling study of the headpiece of VLA-4 based on the crystal structure of alphavbeta3 was performed. Docking experiments of TR-14035 into the binding site of VLA-4 aided the interpretation of the 3D-QSAR model. The obtained results will be fruitful for the design of new potent and selective antagonists of VLA-4.