Botulinum neurotoxin A (BoNT/A) belongs to the most dangerous class of bioweapons. Despite this, BoNT/A is used to treat a wide range of common medical conditions such as migraines and a variety of ocular motility and movement disorders. BoNT/A is probably best known for its use as an antiwrinkle agent in cosmetic applications (including Botox and Dysport). BoNT/A application causes long-lasting flaccid paralysis of muscles through inhibiting the release of the neurotransmitter acetylcholine by cleaving synaptosomal-associated protein 25 (SNAP-25) within presynaptic nerve terminals. Two types of BoNT/A receptor have been identified, both of which are required for BoNT/A toxicity and are therefore likely to cooperate with each other: gangliosides and members of the synaptic vesicle glycoprotein 2 (SV2) family, which are putative transporter proteins that are predicted to have 12 transmembrane domains, associate with the receptor-binding domain of the toxin. Recently, fibroblast growth factor receptor 3 (FGFR3) has also been reported to be a potential BoNT/A receptor. In SV2 proteins, the BoNT/A-binding site has been mapped to the luminal domain, but the molecular details of the interaction between BoNT/A and SV2 are unknown. Here we determined the high-resolution crystal structure of the BoNT/A receptor-binding domain (BoNT/A-RBD) in complex with the SV2C luminal domain (SV2C-LD). SV2C-LD consists of a right-handed, quadrilateral β-helix that associates with BoNT/A-RBD mainly through backbone-to-backbone interactions at open β-strand edges, in a manner that resembles the inter-strand interactions in amyloid structures. Competition experiments identified a peptide that inhibits the formation of the complex. Our findings provide a strong platform for the development of novel antitoxin agents and for the rational design of BoNT/A variants with improved therapeutic properties.
The adenosine A 2A receptor (A 2A R) has long been implicated in cardiovascular disorders. As more selective A 2A R ligands are being identified, its roles in other disorders, such as Parkinson's disease, are starting to emerge, and A 2A R antagonists are important drug candidates for nondopaminergic anti-Parkinson treatment. Here we report the crystal structure of A 2A receptor bound to compound 1 (Cmpd-1), a novel A 2A R/N-methyl D-aspartate receptor subtype 2B (NR2B) dual antagonist and potential anti-Parkinson candidate compound, at 3.5 Å resolution. The A 2A receptor with a cytochrome b562-RIL (BRIL) fusion (A 2A R-BRIL) in the intracellular loop 3 (ICL3) was crystallized in detergent micelles using vapor-phase diffusion. Whereas A 2A R-BRIL bound to the antagonist ZM241385 has previously been crystallized in lipidic cubic phase (LCP), structural differences in the Cmpd-1-bound A 2A R-BRIL prevented formation of the lattice observed with the ZM241385-bound receptor. The crystals grew with a type II crystal lattice in contrast to the typical type I packing seen from membrane protein structures crystallized in LCP. Cmpd-1 binds in a position that overlaps with the native ligand adenosine, but its methoxyphenyl group extends to an exosite not previously observed in other A 2A R structures. Structural analysis revealed that Cmpd-1 binding results in the unique conformations of two tyrosine residues, Tyr9 1.35 and Tyr271 7.36 , which are critical for the formation of the exosite. The structure reveals insights into antagonist binding that are not observed in other A 2A R structures, highlighting flexibility in the binding pocket that may facilitate the development of A 2A R-selective compounds for the treatment of Parkinson's disease.T he adenosine A 2A receptor (A 2A R) is one of the four subtypes of adenosine receptors (A 1 R, A 2A R, A 2B R, A 3 R). As a member of the G protein-coupled receptor (GPCR) family, the A 2A receptor couples to stimulatory G protein G s and elevates intracellular cAMP upon activation by endogenous adenosine. The A 2A R has been an attractive drug target due to its role in cardiovascular and immune system function, as well as in the central nervous system as a potential therapeutic target for Parkinson's disease (PD) (1-4). PD is a neurodegenerative disease that affects more than 1% of the population over 65 years old. Currently, major treatments target the restoration of dopamine signaling, which is impaired in PD patients, by dopamine-replacing agents. Although these treatments effectively address PD-related motor disturbances, the long-term use of dopamine-replacing agents is associated with the development of motor complications; therefore, there is a need for nondopaminergic drugs (2). It is known that A 2A R signaling regulates dopaminergic neurotransmission, and A 2A R antagonists have been shown to enhance D2 dopamine receptor signaling, which has been found to improve PD symptoms in animal models and patients, without the side effects common to dopaminereplacing agents, such...
Development of Dimethyl Sulfoxide Solubility Models Using 163 000 Molecules: Using a Domain Applicability Metric to Select More Reliable Predictions
The dimethyl sulfoxide (DMSO) solubility data from Enamine and two UCB pharma compound collections were analyzed using 8 different machine learning methods and 12 descriptor sets. The analyzed data sets were highly imbalanced with 1.7–5.8% nonsoluble compounds. The libraries’ enrichment by soluble molecules from the set of 10% of the most reliable predictions was used to compare prediction performances of the methods. The highest accuracies were calculated using a C4.5 decision classification tree, random forest, and associative neural networks. The performances of the methods developed were estimated on individual data sets and their combinations. The developed models provided on average a 2-fold decrease of the number of nonsoluble compounds amid all compounds predicted as soluble in DMSO. However, a 4–9-fold enrichment was observed if only 10% of the most reliable predictions were considered. The structural features influencing compounds to be soluble or nonsoluble in DMSO were also determined. The best models developed with the publicly available Enamine data set are freely available online at .
Recently, western countries have recorded a decrease in the death rate imputed to AIDS. This success has been largely attributed to the presence on the market of chemotherapies that inhibit the infectivity of the predominant causative agent, the HIV-1 virus, by targeting essential viral enzymes. One of these is the protease (HIV-1 PR) whose activity is a prerequisite for viral replication. Two main sites have been identified as potential targets for the inhibition of HIV-1 PR, the active site and the interface, the latter being largely responsible for the stabilization of the enzyme dimeric structure. The compounds that have reached clinical application so far target the active site of HIV-1 PR. These molecules act as transition state analogues and result from modifications of the peptidic scaffold into peptidomimetics. In order to improve their bioavailability, systematic biological screening and de novo design have been used to suggest new non-peptide inhibitors combining both antiviral potency and favorable pharmacokinetic properties. In parallel, compounds targeting other potential sites of inhibition have been tested. Peptides and peptidomimetics based on the terminal sequence of the enzyme, a site which is proposed to be less susceptible to mutations, have been shown to lead to HIV-1 PR inactivation. Cupric ion was described to bind a sequence on the protease surface, which includes cysteine and histidine residues, leading to the inhibition of the enzyme. In the future, these non-active site inhibitors could provide an alternative in anti-HIV drug combination strategies.
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