Ribosome-Templated Azide-Alkyne Cycloadditions: Synthesis of Potent Macrolide Antibiotics by In Situ Click Chemistry.

Over half of all antibiotics target the bacterial ribosome-nature's complex, 2.5 MDa nanomachine responsible for decoding mRNA and synthesizing proteins. Macrolide antibiotics, exemplified by erythromycin, bind the 50S subunit with nM affinity and inhibit protein synthesis by blocking the passage of nascent oligopeptides. Solithromycin (1), a third-generation semisynthetic macrolide discovered by combinatorial copper-catalyzed click chemistry, was synthesized in situ by incubating either E. coli 70S ribosomes or 50S subunits with macrolide-functionalized azide 2 and 3-ethynylaniline (3) precursors. The ribosome-templated in situ click method was expanded from a binary reaction (i.e., one azide and one alkyne) to a six-component reaction (i.e., azide 2 and five alkynes) and ultimately to a 16-component reaction (i.e., azide 2 and 15 alkynes). The extent of triazole formation correlated with ribosome affinity for the anti (1,4)-regioisomers as revealed by measured Kd values. Computational analysis using the site-identification by ligand competitive saturation (SILCS) approach indicated that the relative affinity of the ligands was associated with the alteration of macrolactone+desosamine-ribosome interactions caused by the different alkynes. Protein synthesis inhibition experiments confirmed the mechanism of action. Evaluation of the minimal inhibitory concentrations (MIC) quantified the potency of the in situ click products and demonstrated the efficacy of this method in the triaging and prioritization of potent antibiotics that target the bacterial ribosome. Cell viability assays in human fibroblasts confirmed 2 and four analogues with therapeutic indices for bactericidal activity over in vitro mammalian cytotoxicity as essentially identical to solithromycin (1).

Desmethyl macrolides: synthesis and evaluation of 4-desmethyl telithromycin.

Novel sources of antibiotics are needed to address the serious threat of bacterial resistance. Accordingly, we have launched a structure-based drug design program featuring a desmethylation strategy wherein methyl groups have been replaced with hydrogens. Herein we report the total synthesis, molecular modeling, and biological evaluation of 4-desmethyl telithromycin (6), a novel desmethyl analogue of the third-generation ketolide antibiotic telithromycin (2) and our final analogue in this series. While 4-desmethyl telithromycin (6) was found to be equipotent with telithromycin (2) against wild-type bacteria, it was 4-fold less potent against the A2058G mutant. These findings reveal that strategically replacing the C4-methyl group with hydrogen (i.e., desmethylation) did not address this mechanism of resistance. Throughout the desmethyl series, the sequential addition of methyls to the 14-membered macrolactone resulted in improved bioactivity. Molecular modeling methods indicate that changes in conformational flexibility dominate the increased biological activity; moreover, they reveal 6 adopts a different conformation once bound to the A2058G ribosome, thus impacting noncovalent interactions reflected in a lower MIC value. Finally, fluorescence polarization experiments of 6 with E. coli ribosomes confirmed 6 is indeed binding the ribosome.

Desmethyl Macrolides: Synthesis and Evaluation of 4,10-Didesmethyl Telithromycin.

Novel sources of antibiotics are required to keep pace with the inevitable onset of bacterial resistance. Continuing with our macrolide desmethylation strategy as a source of new antibiotics, we report the total synthesis, molecular modeling and biological evaluation of 4,10-didesmethyl telithromycin (4), a novel desmethyl analogue of the 3rd-generation drug telithromycin (2). Telithromycin is an FDA-approved ketolide antibiotic derived from erythromycin (1). We found 4,10-didesmethyl telithromycin (4) to be four times more active than previously prepared 4,8,10-tridesmethyl congener (3) in MIC assays. While less potent than telithromycin (2), the inclusion of the C-8 methyl group has improved biological activity suggesting it plays an important role in antibiotic function.

Desmethyl Macrolides: Synthesis and Evaluation of 4,8-Didesmethyl Telithromycin.

There is an urgent need for novel sources of antibiotics to address the incessant and inevitable onset of bacterial resistance. To this end, we have initiated a structure-based drug design program that features a desmethylation strategy (i.e., replacing methyl groups with hydrogens). Herein we report the total synthesis, molecular modeling and biological evaluation of 4,8-didesmethyl telithromycin (5), a novel desmethyl analogue of the third-generation ketolide antibiotic telithromycin (2), which is an FDA-approved semisynthetic derivative of erythromycin (1). We found 4,8-didesmethyl telithromycin (5) to be eight times more active than previously prepared 4,8,10-tridesmethyl congener (3) and two times more active than 4,10-didesmethyl regioisomer (4) in MIC assays. While less potent than telithromycin (2) and paralleling the observations made in the previous study of 4,10-didesmethyl analogue (4), the inclusion of a single methyl group improves biological activity thus supporting its role in antibiotic activity.

Total synthesis of (-)-4,8,10-tridesmethyl telithromycin.

Novel sources of antibiotics are required to address the serious problem of antibiotic resistance. Telithromycin (2) is a third-generation macrolide antibiotic prepared from erythromycin (1) and used clinically since 2004. Herein we report the details of our efforts that ultimately led to the total synthesis of (-)-4,8,10-tridesmethyl telithromycin (3) wherein methyl groups have been replaced with hydrogens. The synthesis of desmethyl macrolides has emerged as a novel strategy for preparing bioactive antibiotics.