MmpL3 is the flippase for mycolic acids in mycobacteria

The defining feature of the mycobacterial outer membrane (OM) is the presence of mycolic acids (MAs), which, in part, render the bilayer extremely hydrophobic and impermeable to external insults, including many antibiotics. Although the biosynthetic pathway of MAs is well studied, the mechanism(s) by which these lipids are transported across the cell envelope is(are) much less known. Mycobacterial membrane protein Large 3 (MmpL3), an essential inner membrane (IM) protein, is implicated in MA transport, but its exact function has not been elucidated. It is believed to be the cellular target of several antimycobacterial compounds; however, evidence for direct inhibition of MmpL3 activity is also lacking. Here, we establish that MmpL3 is the MA flippase at the IM of mycobacteria and is the molecular target of BM212, a 1,5-diarylpyrrole compound. We develop assays that selectively access mycolates on the surface of Mycobacterium smegmatis spheroplasts, allowing us to monitor flipping of MAs across the IM. Using these assays, we establish the mechanism of action of BM212 as a potent MmpL3 inhibitor, and use it as a molecular probe to demonstrate the requirement for functional MmpL3 in the transport of MAs across the IM. Finally,we showthat BM212 bindsMmpL3 directly and inhibits its activity. Our work provides fundamental insights into OM biogenesis and MA transport in mycobacteria. Furthermore, our assays serve as an important platform for accelerating the validation of small molecules that target MmpL3, and their development as future antituberculosis drugs

Antiviral Mechanisms of N-Phenyl Benzamides on Coxsackie Virus A9

Enteroviruses are one of the most abundant groups of viruses infecting humans, and yet there are no approved antivirals against them. To find effective antiviral compounds against enterovirus B group viruses, an in-house chemical library was screened. The most effective compounds against Coxsackieviruses B3 (CVB3) and A9 (CVA9) were CL212 and CL213, two N-phenyl benzamides. Both compounds were more effective against CVA9 and CL213 gave a better EC50 value of 1 µM with high a specificity index of 140. Both drugs were most effective when incubated directly with viruses suggesting that they mainly bound to the virions. A real-time uncoating assay showed that the compounds stabilized the virions and radioactive sucrose gradient as well as TEM confirmed that the viruses stayed intact. A docking assay, taking into account larger areas around the 2-and 3-fold axes of CVA9 and CVB3, suggested that the hydrophobic pocket gives the strongest binding to CVA9 but revealed another binding site around the 3-fold axis which could contribute to the binding of the compounds. Together, our data support a direct antiviral mechanism against the virus capsid and suggest that the compounds bind to the hydrophobic pocket and 3-fold axis area resulting in the stabilization of the virion

A Series of COX-2 Inhibitors Endowed with NO-Releasing Properties: Synthesis, Biological Evaluation, and Docking Analysis

Herein we report the synthesis, biological evaluation, and docking analysis of a class of cyclooxygenase-2 (COX-2) inhibitors with nitric oxide (NO)-releasing properties. In an earlier study, a number of selective COX-2 inhibitors/NO donors were developed by conjugating a diarylpyrrole scaffold endowed with selective COX-2 inhibitory properties with various nitrooxyalkyl side chains such as esters, -amino esters, amides, -amino amides, ethers, -amino ethers, inverse esters, and amides. These candidates were found to have high invitro potencies (COX-2 inhibition at 10m: 96%), great efficacy in determining NO-vasorelaxing responses, and good antinociceptive activity in an abdominal writhing test. Among the compounds synthesized in the present work, derivative 2b [2-(2-(1-(3-fluorophenyl)-2-methyl-5-(4-sulfamoylphenyl)-1H-pyrrol-3-yl)acetamido)ethyl nitrate] showed particularly outstanding activity, with efficacy similar to that of celecoxib even at very low concentrations

Synthesis, biological evaluation and docking analysis of a new series of methylsulfonyl and sulfamoyl acetamides and ethyl acetates as potent COX-2 inhibitors

We report herein the synthesis, biological evaluation and docking analysis of a new series of methylsulfonyl, sulfamoyl acetamides and ethyl acetates that selectively inhibit cyclooxygenase-2 (COX-2) isoform. Among the newly synthesized compounds, some of them were endowed with a good activity against COX-2 and a good selectivity COX-2/COX-1 in vitro as well as a desirable analgesic activity in vivo, proving that replacement of the ester moiety with an amide group gave access to more stable derivatives, characterized by a good COX-inhibition

A Novel Antimycobacterial Compound Acts as an Intracellular Iron Chelator

Efficient iron acquisition is crucial for the pathogenesis of Mycobacterium tuberculosis. Mycobacterial iron uptake and metabolism are therefore attractive targets for antitubercular drug development. Resistance mutations against a novel pyrazolopyrimidinone compound (PZP) that is active against M. tuberculosis have been identified within the gene cluster encoding the ESX-3 type VII secretion system. ESX-3 is required for mycobacterial iron acquisition through the mycobactin siderophore pathway, which could indicate that PZP restricts mycobacterial growth by targeting ESX-3 and thus iron uptake. Surprisingly, we show that ESX-3 is not the cellular target of the compound. We demonstrate that PZP indeed targets iron metabolism; however, we found that instead of inhibiting uptake of iron, PZP acts as an iron chelator, and we present evidence that the compound restricts mycobacterial growth by chelating intrabacterial iron. Thus, we have unraveled the unexpected mechanism of a novel antimycobacterial compound

Overcoming drug resistance for tuberculosis,

Despite enormous progress, tuberculosis (TB) is still a major global health problem. Poor patients’ adherence to the current treatment leads to the emergence of multidrug resistant (MDR) and extensively drug resistant (XDR) strains. While increased numbers of MDR-TB cases can be ascribed to difficulties in treating TB–HIV coinfected patients, many studies demonstrated that the emergence of drug-resistant TB is clearly linked to misdiagnosis and mismanagement of drug-susceptible TB. Therefore, rapid detection and proper treatment are needed globally to both cure TB patients and prevent wide spreading of the disease. This paper provides a survey of the major strategies that have been explored for overcoming drug resistance in TB

COX inhibitors: a patent review (2011 - 2014)

The COX enzymes play a central role in the biosynthetic pathway of important biological mediators called prostanoids. Differences in regulation of gene expression, stability of transcripts and proteins determine the different biological functions of COX-1 and COX-2. While the COX-1 gene has been considered to be a ‘housekeeping’ gene expressed in many tissues and cells, COX-2 gene is upregulated during inflammation, hypoxia and in many cancers

MmpL3 inhibitors: diverse chemical scaffolds inhibit the same target

MmpL3 belongs to the Resistance, Nodulation and Division (RND) superfamily whose role in mycobacteria is the formation of the outer membrane. Indeed, it has been shown that MmpL3 is associated with the export of mycolic acids in the form of trehalose monomycolates (TMM) to the periplasmic space or the outer membrane. In the last few years several whole cell-based screenings of compound libraries brought by a number of diverse chemical scaffolds active against M. tuberculosis (Mtb) that surprisingly share MmpL3 as target. The diverse identified pharmacophores owe important differences among each other, in fact while some of them display inhibitory activity against pathogens that are devoid of mycolic acids and are active against non-replicating Mtb bacilli, some others specifically target mycobacteria and do not kill non-replicating bacilli. The scope of this review is to provide the recent advances in MmpL3 inhibitor discovery with a special focus on structure activity relationship (SAR) studies in order to provide information that could help in developing novel membrane-active anti- TB agents. Moreover, this review will provide the most recent insights into the modes of action of the MmpL3 inhibitors

Mycobacterial tryptophan biosynthesis: a promising target for tuberculosis drug development?

The biosynthetic pathways of amino acids are attractive targets for drug development against pathogens with an intracellular behavior like M. tuberculosis (Mtb). Indeed, while in the macrophages Mtb has restricted access to amino acids such as tryptophan (Trp). Auxotrophic Mtb strains, with mutations in the Trp biosynthetic pathway, showed reduced intracellular survival in cultured human and murine macrophages and failed to cause the disease in immunocompetent and immunocompromised mice. Herein we present recent efforts in the discovery of Trp biosynthesis inhibitors