A MassQL-Integrated Molecular Networking Approach for the Discovery and Substructure Annotation of Bioactive Cyclic Peptides.

The marine sponge-derived fungus Stachylidium bicolor 293 K04 is a prolific producer of specialized metabolites, including certain cyclic tetrapeptides called endolides, which are characterized by the presence of the unusual amino acid N-methyl-3-(3-furyl)-alanine. This rare feature can be used as bait to detect new endolide-like analogs through customized fragment pattern searches of tandem mass spectrometry data using the Mass Spec Query Language (MassQL). Here, we integrate endolide-specific MassQL queries with molecular networking to obtain substructural information guiding the targeted isolation and structure elucidation of the new proline-containing endolides E (1) and F (2). We showed that endolide F (but not E) is a moderate antagonist of the arginine vasopressin V1A receptor, a member of the G protein-coupled receptor superfamily.

Total synthesis and mechanism of action of the antibiotic armeniaspirol A.

Emerging antimicrobial resistance urges the discovery of antibiotics with unexplored, resistance-breaking mechanisms. Armeniaspirols represent a novel class of antibiotics with a unique spiro[4.4]non-8-ene scaffold and potent activities against Gram-positive pathogens. We report a concise total synthesis of (±) armeniaspirol A in six steps with a yield of 20.3% that includes the formation of the spirocycle through a copper-catalyzed radical cross-coupling reaction. In mechanistic biological experiments, armeniaspirol A exerted potent membrane depolarization, accounting for the pH-dependent antibiotic activity. Armeniaspirol A also disrupted the membrane potential and decreased oxygen consumption in mitochondria. In planar lipid bilayers and in unilamellar vesicles, armeniaspirol A transported protons across membranes in a protein-independent manner, demonstrating that armeniaspirol A acted as a protonophore. We provide evidence that this mechanism might account for the antibiotic activity of multiple chloropyrrole-containing natural products isolated from various origins that share a 4-acylphenol moiety coupled to chloropyrrole as a joint pharmacophore. We additionally describe an efflux-mediated mechanism of resistance against armeniaspirols.

Pharmacological Activation of Non-canonical NF-κB Signaling Activates Latent HIV-1 Reservoirs In Vivo.

"Shock and kill" strategies focus on purging the latent HIV-1 reservoir by treating infected individuals with therapeutics that activate the latent virus and subsequently eliminating infected cells. We have previously reported that induction of non-canonical nuclear factor κB (NF-κB) signaling through a class of small-molecule antagonists known as Smac mimetics can reverse HIV-1 latency. Here, we describe the development of Ciapavir (SBI-0953294), a molecule specifically optimized for HIV-1 latency reversal that was found to be more efficacious as a latency-reversing agent than other Smac mimetics under clinical development for cancer. Critically, this molecule induced activation of HIV-1 reservoirs in vivo in a bone marrow, liver, thymus (BLT) humanized mouse model without mediating systemic T cell activation. This study provides proof of concept for the in vivo efficacy and safety of Ciapavir and indicates that Smac mimetics can constitute a critical component of a safe and efficacious treatment strategy to eliminate the latent HIV-1 reservoir.

Optimization of the metabolic stability of a fluorinated cannabinoid receptor subtype 2 (CB2) ligand designed for PET studies.

The central CB2 receptor represents a promising target for the treatment of neuroinflammatory diseases as CB2 activation mediates anti-inflammatory effects. Recently, the F-18 labeled PET radiotracer [18F]7a was reported, which shows high CB2 affinity and high selectivity over the CB1 subtype but low metabolic stability due to hydrolysis of the amide group. Based on these findings twelve bioisosteres of 7a were synthesized containing a non-hydrolysable functional group instead of the amide group. The secondary amine 23a (Ki = 7.9 nM) and the ketone 26a (Ki = 8.6 nM) displayed high CB2 affinity and CB2:CB1 selectivity in in vitro radioligand binding studies. Incubation of 7a, 23a and 26a with mouse liver microsomes and LC-quadrupole-MS analysis revealed a slightly higher metabolic stability of secondary amine 23a, but a remarkably higher stability of ketone 26a in comparison to amide 7a. Furthermore, a logD7.4 value of 5.56 ±â€¯0.08 was determined for ketone 26a by micro shake-flask method and LC-MS quantification.

Optimization of pharmacokinetic properties by modification of a carbazole-based cannabinoid receptor subtype 2 (CB2) ligand.

Recently, the development of the fluorinated PET tracer [18F]1a for imaging of CB2 receptors in the central nervous system was reported. [18F]1a showed high CB2 affinity and selectivity over the CB1 subtype, but rapid biotransformation in mice. In addition to the amide hydrolysis, oxidative N-dealkylation and carbazole oxidation were postulated as main metabolic pathways. Based on these results, novel carbazole derivatives with additional 6-substituents (23a, 24a), modified hydrogenation state (26a) and enlarged fluoroalkyl substituent (13a, 13b) were synthesized and pharmacologically evaluated. The key step in the synthesis of substituted carbazoles 23a, 24a and 26a was a Fischer indole synthesis. Nucleophilic substitution of tosylated lactate 5 by carbazole anion provided the fluoroisopropyl derivatives 13a and 13b. Partial hydrogenation of the aromatic carbazole system (26a) was not tolerated by the CB2 receptor. A methylsulfonyl moiety in 6-position (24a) led to considerably reduced CB2 affinity, whereas a 6-methoxy moiety (23a) was well tolerated. An additional methyl moiety in the fluoroethyl side chain of 1a resulted in fluoroisopropyl derivatives 13 with unchanged high CB2 affinity and CB2: CB1 selectivity. Compared with the fluoroethyl derivative 1a, the carbazole N-atom of the fluoroisopropyl derivative 13a (Ki(CB2) = 2.9 nM) is better shielded against the attack of CYP enzymes as formation of N-oxides was not observed and N-dealkylation took place to a less amount.

Bioisosteric replacement of central 1,2,4-oxadiazole ring of high affinity CB2 ligands by regioisomeric 1,3,4-oxadiazole ring.

It has been reported that bioisosteric replacement of an 1,2,4-oxadiazole ring by an 1,3,4-oxadiazole ring leads to higher polarity, reduced metabolic degradation by human liver microsomes and reduced interaction with hERG channels. In a seven to eight step synthesis 1,3,4-oxadiazles 9a-c were synthesized as bioisosteric analogs of high-affinity but rather lipophilic CB2 ligands 1a-c containing an 1,2,4-oxadiazole ring. The 1,3,4-oxadiazole derivatives 9a and 9b show 10- and 50-fold reduced CB2 affinity compared to the 1,2,4-oxadiazole derivatives 1a and 1b, respectively. However, the 1,3,4-oxadiazole 9a has high CB2 affinity (Ki = 25 nM) and high selectivity over the CB1 receptor.