Transition metal catalysis plays a central role in contemporary organic synthesis. Considering the tremendously broad array of transition-metal-catalyzed transformations, it is remarkable that the underlying elementary reaction steps are relatively few in number. Here we describe an alternative to the organometallic transmetallation step that is common in many metal-catalyzed reactions such as Suzuki-Miyaura coupling. Specifically, we demonstrate that vinyl boronic ester ate complexes, prepared by combining organoboronates and organolithium reagents, engage in Pd-induced metallate rearrangement wherein 1,2-migration of an alkyl or aryl group from boron to the vinyl α-carbon occurs concomitantly with C-Pd σ-bond formation. This elementary reaction enables a powerful cross-coupling reaction in which a chiral palladium catalyst merges three simple starting materials – an organolithium, an organoboronic ester, and an organotriflate – into chiral organoboronic esters with high enantioselectivity.
Under the influence
of a chiral palladium catalyst, 1,1-bis(pinacolboronate)
esters undergo asymmetric cross-coupling with bromoalkenes to generate
nonracemic allyl boronates with high levels of enantioselectivity.
The so-formed allyl boronates may be oxidized with hydrogen peroxide
to provide secondary allylic alcohols or with nitrosobenzene to furnish
nonracemic tertiary allylic alcohols. Mechanistic experiments suggest
the operation of a pathway involving outer-sphere stereoinvertive
transmetalation.
Despite continued research efforts, the threat of drug resistance from a variety of bacteria continues to plague clinical communities. Discovery and validation of novel biochemical targets will facilitate development of new drugs to combat these organisms. The methylerythritol phosphate (MEP) pathway to make isoprene units is a biosynthetic pathway essential to many bacteria. We and others have explored inhibitors of the MEP pathway as novel antibacterial agents. Mycobacterium tuberculosis, the causative agent of tuberculosis, and Yersinia pestis, resulting in the plague or “black death,” both rely on the MEP pathway for isoprene production. 1-Deoxy-D-xylulose 5-phosphate reductoisomerase (Dxr) catalyzes the first committed step in the MEP pathway. We examined two series of Dxr inhibitors based on the parent structure of the retrohydroxamate natural product FR900098. The compounds contain either an extended N-acyl or O-linked alkyl/aryl group, and are designed to act as bisubstrate inhibitors of the enzyme. While nearly all of the compounds inhibited both Mtb and Yp Dxr to some extent, compounds generally displayed more potent inhibition against the Yp homolog, with the best analogs displaying nM IC50 values. In bacterial growth inhibition assays, the phosphonic acids generally resulted in poor antibacterial activity, likely a reflection of inadequate permeability. Accordingly, diethyl and diPOM prodrug esters of these compounds were made. While the added lipophilicity did not enhance Yersinia activity, the compounds showed significantly improved antitubercular activities. The most potent compounds have Mtb MIC values of 3–12 µg/mL. Taken together, we have uncovered two series of analogs that potently inhibit Dxr homologs from Mtb and Yp. These inhibitors of the MEP pathway, termed MEPicides, serve as leads for future analog development.
Inhibition of the nonmevalonate pathway (NMP) of isoprene biosynthesis has been examined as a source of new antibiotics with novel mechanisms of action. Dxr is the best studied of the NMP enzymes and several reports have described potent Dxr inhibitors. Many of these compounds are structurally related to natural products fosmidomycin and FR900098, each bearing retrohydroxamate and phosphonate groups. We synthesized a series of compounds with two to five methylene units separating these groups to examine what linker length was optimal and tested for inhibition against Mtb Dxr. We synthesized ethyl and pivaloyl esters of these compounds to increase lipophilicity and improve inhibition of Mtb growth. Our results show that propyl or propenyl linker chains are optimal. Propenyl analog 22 has an IC50 of 1.07 μM against Mtb Dxr. The pivaloyl ester of 22, compound 26, has an MIC of 9.4 μg/mL, representing a significant improvement in antitubercular potency in this class of compounds.
The catalytic Suzuki-Miyaura cross-coupling with chiral γ,γ-disubstituted allylboronates in the presence of RuPhos ligand occurs with high regioselectivity and enantiospecificity, furnishing nonracemic compounds with quaternary centers. Mechanistic experiments suggest that the reaction occurs by transmetallation with allyl migration, followed by rapid reductive elimination.
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