Intramolecular Silanoxy-Michael Reactions with Pendant Nitroalkenes: Racemic and Enantioselective.

We present the first racemic and scalemic examples of di-tert-butyl silanoxy-Michael additions. Our operationally simple protocol is selective for nitro-olefins and simply involves stirring the substrate with an appropriate hydrogen-bond donor catalyst without any special precautions to exclude air or moisture. For each substrate examined, we have developed complementary protocols that optimize yield and enantioselectivity. Our reactions scale well, and the products are valuable intermediates for further transformations, including for the preparation of enantioenriched vicinal amino alcohols.

Sulfamate-Tethered Aza-Wacker Strategy for a Kasugamine Synthon.

We present our preparation of a kasugamine synthon, which proceeds in 14 steps from a literature epoxide. We expect that this kasugamine derivative can be used for the total syntheses of kasugamycin, minosaminomycin, and analogue antibiotics. A key step in the synthesis is our laboratory's sulfamate-tethered aza-Wacker cyclization.

Taming Tethered Nitreniums for Alkene Functionalization Reactions.

We present the first examples of amino-trifluoroacetoxylations of alkenes using N-alkoxy carbamate tethers. Hypervalent iodine oxidants mediate this transformation, providing a "green" alternative to existing intramolecular amino-hydroxylation protocols which use toxic metals such as osmium. In all cases examined, the reaction is regioselective and stereospecific, with the geometry of the starting alkene controlling the diastereomeric outcome. By analogy to prior art and from our own observations, we posit that a transient nitrenium species serves as a key intermediate.

The Development of a Sulfamate-Tethered Aza-Michael Cyclization Allows for the Preparation of (-)-Negamycin tert-Butyl Ester.

We present the first examples of intramolecular aza-Michael cyclizations of sulfamates and sulfamides onto pendant α,ß-unsaturated esters, thioesters, amides, and nitriles. Stirring the substrate with catalytic quantities of the appropriate base delivers the product in good yield and excellent diastereoselectivity. The reactions are operationally simple, can be performed open to air, and are tolerant of a variety of important functional groups. We highlight the utility of this technology by using it in the preparation of a (-)-negamycin derivative.

Fun With Unusual Functional Groups: Sulfamates, Phosphoramidates, and Di-tert-butyl Silanols.

Compared to ubiquitous functional groups such as alcohols, carboxylic acids, amines, and amides, which serve as central "actors" in most organic reactions, sulfamates, phosphoramidates, and di-tert-butyl silanols have historically been viewed as "extras". Largely considered functional group curiosities rather than launch-points of vital reactivity, the chemistry of these moieties is under-developed. Our research program has uncovered new facets of reactivity of each of these functional groups, and we are optimistic that the chemistry of these fascinating molecules can be developed into truly general transformations, useful for chemists across multiple disciplines. In the ensuing sections, I will describe our efforts to develop new reactions with these "unusual" functional groups, namely sulfamates, phosphoramidates, and di-tert-butyl silanols.

Oxidations of Alcohols, Aldehydes, and Diols Using NaBr and Selectfluor.

We present protocols for the oxidation of alcohols and aldehydes and for the oxidative cyclization of diols which use a combination of Selectfluor and NaBr. For most substrates, the optimal solvent system is a 1:1 mixture of CH3CN/H2O, but, in select cases, biphasic 1:1 mixtures of EtOAc/H2O or CH2Cl2/H2O are superior. This procedure is operationally simple, uses inexpensive and readily available reagents, and tolerates a variety of functional groups. Mechanistic studies suggest that the active oxidant is hypobromous acid, generated by the almost instantaneous oxidation of Br- by Selectfluor in an aqueous milieu.

Sulfamate-Tethered Aza-Wacker Cyclization Strategy for the Syntheses of 2-Amino-2-deoxyhexoses: Preparation of Orthogonally Protected d-Galactosamines.

We present a new strategy for the assembly of protected d-galactosamine synthons. Our route uses a sulfamate-tethered aza-Wacker cyclization as a key step and commences from d-erythrono-1,4-lactone. This stands in contrast to most literature syntheses of 2-amino-2-deoxyhexose derivatives, as these generally employ glycals or hexoses as starting materials. This strategy may serve as a template for the assembly of many other 2-amino-2-deoxyhexoses with protection patterns difficult to access by conventional methods.

Ring Opening of Aziridines by Pendant Sulfamates Allows for Regioselective and Stereospecific Preparation of Vicinal Diamines.

The ring opening of aziridines by pendant sulfamates is a viable strategy for the rapid preparation of vicinal diamines. Our reaction is compatible with both disubstituted cis- and trans-aziridines; unsubstituted, N-alkyl, and N-aryl sulfamates engage effectively. In all cases examined, the cyclization reaction is perfectly regioselective and stereospecific. Once activated, the product oxathiazinane heterocycles can be ring opened with a diverse range of nucleophiles.

Ring Opening of Aziridines by Pendant Silanols Allows for Stereospecific Preparations of 1'-Amino-tetrahydrofurans.

We have developed a highly stereospecific cyclization of aziridine silanols into 1'-amino-tetrahydrofurans. Our protocol of stirring a substrate with 10 mol % Sc (OTf)3 and 1 equivalent of NaHCO3 in CH2Cl2 is mild and compatible with a range of activating aziridine N-substituents (including tosylates, mesylates, and carbamates) and functional groups on the alkyl chains (including substituted aryl rings, alkyl bromides, and alkyl ethers). In all cases examined, trans di-substituted aziridine silanols give products with an erythro configuration; conversely, cis di-substituted aziridine silanols give products with a threo configuration. While literature syntheses of 1'-amino-tetrahydrofurans exist, only one example, contemporaneous with our work, uses a similar cyclization for their construction. Control experiments demonstrate that, for this transformation, the silanol is not particularly privileged, and a variety of protecting groups on the alcohol (including other silicon protecting groups, benzyl ethers, and MOM ethers) are compatible with product formation.

Ring-Opening Reactions of Phosphoramidate Heterocycles.

We present protocols for the conversion of phosphoramidate heterocycles into 1,3-chloroamines and 1,3-aminoalcohols. For the formation of chloroamines, our optimized protocol involves heating the phosphoramidate starting material with 4 equivalents of HCl in a dioxane/toluene solvent mixture. The substituents on the phosphoramidate starting material have a profound influence on product formation. Phosphoramidates with a variety of aza-heterocyclic substituents engage, but those containing a 5-chloro-8-quinolinol arm are most competent for 1,3-chloroamine formation. Furthermore, only the phosphoramidate cis diastereomers allow for 1,3-chloroamine formation. X-ray crystallography studies coupled with DFT analysis provide a basis for the stark difference in reactivity between the cis and trans diastereomers. Amino-alcohol products form by heating phosphoramidate heterocycles with aqueous HF in toluene. Here, there is no diastereomeric preference or a requirement for an aza-heterocyclic arm. Based on a substrate survey, both reactions tolerate a broad range of substitution patterns and functional groups. This work establishes that phosphoramidates are competent synthons for interesting amine products and further increases the prominence of tethered aza-Wacker technology.

Hydroxyselenylation and Tethered Silanoxyselenylation of Allylic Silanols.

We present protocols for the highly regioselective hydroxyselenylation and silanoxyselenylation of allylic silanols. N-(Phenylseleno)phthalimide acts as the selenylating agent for both transformations. Under basic conditions, hydroxyselenylation proceeds with >20:1 regioselectivity, and the products are valuable synthons for further transformations. We show that the silanol plays a critical role in maintaining the yield and regioselectivity of this reaction. Surprisingly, under acidic conditions, the hydroxyselenylation pathway is blocked, and products of a tethered silanoxyselenylation are exclusive.

Highly Stereospecific Cyclizations of Homoallylic Silanols.

We demonstrate that di-tert-butylsilanols are competent nucleophiles for the intramolecular interception of palladium π-allyl species. In these reactions, allyl ethyl carbonates are the best precursors for the formation of palladium π-allyl intermediates, and [(Cinnamyl)PdCl]2/BINAP is superior to other Pd salt/ligand framework combinations. Our optimized protocol is compatible with a variety of silanol substrates. Importantly, the cyclization is perfectly stereospecific, proceeding via an anti-syn mechanism, which stands in contrast to reported analogous reactions of alcohols and phenols, known to proceed via an anti-anti mechanism. The alkenes in the product dioxasilinanes serve as blank slates for further functionalization.

Progress towards the syntheses of Bactobolin A and C4-epi-Bactobolin A using a sulfamate-tethered aza-Wacker cyclization strategy.

We present a progress report towards Bactobolin A and C4-epi-Bactobolin A. Sulfamate-tethered aza-Wacker cyclization followed by a Tsuji-Wacker ketone synthesis furnishes a key tricyclic intermediate which we hypothesize can be elaborated into C4-epi-Bactobolin A. Epimerization of one of the stereocenters of this compound furnishes an intermediate which we hypothesize can be elaborated into Bactobolin A.

1,4-Benzoquinone antimicrobial agents against Staphylococcus aureus and Mycobacterium tuberculosis derived from scorpion venom.

Two 1,4-benzoquinone derivatives, found in the venom of the scorpion Diplocentrus melici following exposure to air, have been isolated, characterized, synthesized, and assessed for antimicrobial activities. Initially a white, viscous liquid, the extracted venom colors within minutes under ambient conditions. From this colored mixture, two compounds, one red, the other blue, were isolated and purified using chromatography. After a variety of NMR and mass spectrometry experiments, the red compound was determined to be 3,5- dimethoxy-2-(methylthio)cyclohexa-2,5-diene-1,4-dione, and the blue compound was determined to be 5-methoxy-2,3- bis(methylthio)cyclohexa-2,5-diene-1,4-dione. Because extremely small amounts of these compounds were isolated from the scorpion venom, we developed laboratory syntheses from commercially available precursors, allowing us to produce sufficient quantities for crystallization and biological assays. The red benzoquinone is effective against Staphylococcus aureus [minimum inhibitory concentration (MIC) = 4 µg/mL], while the blue benzoquinone is active against Mycobacterium tuberculosis (MIC = 4 µg/mL) and even against a multidrug-resistant (MDR) strain with nearly equal effectiveness. The bactericidal effects of both benzoquinones show comparable activity to commercially available antibiotics used against these pathogens and were cytotoxic to neoplastic cell lines, suggesting their potential as lead compounds for the development of novel antimicrobial and anticancer drugs. Importantly, the blue benzoquinone was also effective in vivo with mouse models of MDR tuberculosis infection. After treatment for 2 mo, four mice with late-stage active MDR tuberculosis had a significant decrease in pulmonary bacillary loads and tissue damage. Healthy mice served as negative controls and tolerated treatment well, without adverse side effects.

Highly Regio- and Diastereoselective Tethered Aza-Wacker Cyclizations of Alkenyl Phosphoramidates.

We present highly diastereoselective tethered aza-Wacker cyclization reactions of alkenyl phosphoramidates. "Arming" the phosphoramidate tether with 5-chloro-8-quinolinol was essential to achieving >20:1 diastereoselectivity in these reactions. The substrate scope with respect to alkenyl alcohols and phosphoramidate tether was extensively explored. The scalability of the oxidative cyclization was demonstrated, and the product cyclophosphoramidates were shown to be valuable synthons, including for tether removal. With chiral alkenyl precursors, enantiopure cyclic phosphoramidates were formed.

Tethered Silanoxyiodination of Alkenes.

We present the first examples of tethered silanoxyiodination reactions of allylic alcohols. The products are useful silanediol organoiodide synthons and are formed with high regioselectivity and diastereocontrol. The reaction is scalable greater than 10-fold without loss of yield or selectivity. Furthermore, the products are starting materials for further transformations, including deiodination, C-N bond installation, epoxide synthesis, and desilylation. DFT calculations provide a basis for understanding the exquisite 6-endo selectivity of this silanoxyiodination reaction and show that the observed products are both kinetically and thermodynamically preferred.

A Formal Rearrangement of Allylic Silanols.

We show that 1M aqueous HCl/THF or NaBH4/DMF allows for demercurative ring-opening of cyclic organomercurial synthons into secondary silanol products bearing terminal alkenes. We had previously demonstrated that primary allylic silanols are readily transformed into cyclic organomercurials using Hg(OTf)2/NaHCO3 in THF. Overall, this amounts to a facile two-step protocol for the rearrangement of primary allylic silanol substrates. Computational investigations suggest that this rearrangement is under thermodynamic control and that the di-tert-butylsilanol protecting group is essential for product selectivity.

Sulfamate-tethered aza-Wacker approach towards analogs of Bactobolin A.

Here, we describe an approach towards analogs of the potent antibiotic Bactobolin A. Sulfamate-tethered aza-Wacker cyclization reactions furnish key synthons, which we envision can be elaborated into analogs of Bactobolin A. Docking studies show that the C4 epimer of Bactobolin A and the C4/C6 diastereomer interact with different residues of the 23S rRNA (bacterial ribosome 50S subunit) than the natural product, suggesting that these molecules could be valuable tool compounds for fundamental studies of the bacterial translational machinery.

N-arylated oxathiazinane heterocycles are convenient synthons for 1,3-amino ethers and 1,3-amino thioethers.

This communication describes a variety of nucleophilic ring openings of N-arylated oxathiazinane heterocycles. We find that this reaction is compatible with phenoxides, naphthoxides, and thiolates and allows for the rapid assembly of N-aryl-amino ethers and N-aryl-amino thioethers. Fourteen examples are shown and a mechanistic pathway is hypothesized.

Mechanistic Analysis of the C-H Amination Reaction of Menthol by CuBr2 and Selectfluor.

The mechanism of the Ritter-type C-H amination reaction of menthol with acetonitrile using CuBr2, Selectfluor, and Zn(OTf)2, first disclosed by Baran and coworkers in 2012, was studied using a combination of online electrospray ionization mass spectrometry, continuous UV/vis spectrometric monitoring, and density functional theory calculations. In addition to corroborating Baran's original mechanistic proposal, these studies uncovered a second pathway to product formation, which likely only occurs in microdroplets. DFT calculations show that neither pathway has a barrier that is greater than 6.8 kcal/mol, suggesting that both mechanisms are potentially operative under ambient conditions.