Fusicoccin A (FC) is a diterpene glycoside that stabilizes protein-protein interactions (PPIs) between 14-3-3 adapter proteins and their phosphoprotein interaction partners. Recently, FC has gained attention for its pro-apoptotic and neuroprotective properties in cell culture. Although the exact molecular mechanism(s) is (are) unresolved, 14-3-3 PPIs are central to this activity. With the goal of refining the pharmacology of this chemotype, we conducted a systematic analysis of the structural features that govern FC-induced stabilization of 14-3-3 PPIs utilizing a C-terminal phosphorylation recognition motif. This study confirmed that a C-terminal amino acid with a small alkyl group is required for the interaction of FC at canonical C-terminal 14-3-3 PPI interfaces. Using bioinformatics, this structural insight was leveraged to assemble a database of 119 candidate 14-3-3 PPIs that can serve as targets for FC. This group includes a subset of proteins with experimentally determined C-terminal phosphosites that have not been explored as potential targets of FC.
Ansa-bridged prodiginines are bioactive pigments produced by bacteria. Certain of these structures are reported to be antagonists of protein-protein interactions involved in apoptosis. We describe a new entry to alkaloids of this type, demonstrated with a concise asymmetric synthesis of (+)-roseophilin (3). Our route constructs the pyrrolophane motif via phosphoryl transfer-terminated macroaldolization and passes through a previously unexplored prototropic form of the natural product.
A method
to transform pyridazine N-oxides into 2-aminofurans
using a combination of UV light and transition metal catalysis has
been developed. These electron-rich species exhibit a surprising range
of useful reactivity, including the ability to participate in complexity
building cascade processes when reacted with dienophiles. This study
also establishes 2-aminofurans as valuable synthons that support modular
synthetic entry to the shared heterocyclic core of certain aspidosperma
and amaryllidaceae alkaloids.
A new family of air- and moisture-stable enantiopure C,N-palladacycles (PIN-acac complexes) were prepared in good overall yield in three steps from 2-iodo-1-naphthoic acid and enantiopure β-amino alcohols. Three of these PIN complexes were characterized by single-crystal X-ray analysis. As anticipated, the naphthalene and imidazoline rings of PIN-acac complexes 18a and 18b were canted significantly from planarity and projected the imidazoline substituents R1 and R2 on opposite faces of the palladium square plane. Fifteen PIN complexes were evaluated as catalysts for the rearrangement of prochiral (E)-allylic trichloroacetimidate 19 (eq 2) and the SN2′ allylic substitution of acetic acid with prochiral (Z)-allylic trichloroacetimidate 23. Although these complexes were kinetically poor catalysts for the Overman rearrangement, they were good catalysts for the allylic substitution reaction, providing branched allylic esters in high yield. However, enantioselectivities were low to moderate and significantly less than that realized with palladacyclic complexes of the COP family. Computational studies support an anti-acetoxypalladation/syn-deoxypalladation mechanism analogous to that observed with COP catalysts. The computational study further suggests that optimizing steric influence in the vicinity of the carbon ligand of a chiral C,N-palladacycle, rather than near the nitrogen heterocycle, is the direction to pursue in future development of improved enantioselective catalysts of this motif.
Methyl groups are ubiquitous in biologically active molecules. Thus, new tactics to introduce this alkyl fragment into polyfunctional structures are of significant interest. With this goal in mind, a direct method for the Markovnikov hydromethylation of alkenes is reported. This method exploits the degenerate metathesis reaction between the titanium methylidene unveiled from Cp2Ti(μ‐Cl)(μ‐CH2)AlMe2 (Tebbe's reagent) and unactivated alkenes. Protonolysis of the resulting titanacyclobutanes in situ effects hydromethylation in a chemo‐, regio‐, and site‐selective manner. The broad utility of this method is demonstrated across a series of mono‐ and di‐substituted alkenes containing pendant alcohols, ethers, amides, carbamates, and basic amines.
A photochemical method for the direct synthesis of 1H-pyrazoles from pyridazine N-oxides was developed. This chemistry features a regioselective approach to nonsymmetrically substituted pyridazine N-oxides. Herein, we highlight the first strategic use of photoinduced ring-opening reactions of 1,2-diazine N-oxides for the preparative synthesis of nitrogen heterocycles.
We describe a new synthesis of the 3-chloro-(4′-methoxy)-2,2′-pyrrolylfuran segment (3) of (+)− roseophilin. The route exploits a isoxazoylpyrrole intermediate, wherein the isoxazole ring serves as a β-diketone equivalent and a directing group for palladium catalyzed chlorination of the attached pyrrole. Subsequent reduction of the N–O bond and acid promoted cyclization afords roseophilin segment 3b in five steps and 19% overall yield. This strategy was extended to the synthesis of 3-chloro-(4′-alkoxy)-2,2′-pyrrolylfurans (16a–c) and 4-alkoxy-2,2′-bipyrroles (20a–c), which are building blocks to synthesize bioactive prodiginine natural products and their congeners.
Fusicoccin A (FC)
is a fungal phytotoxin that stabilizes protein–protein
interactions (PPIs) between 14-3-3 adapter proteins and their phosphoprotein
interaction partners. Recently, FC has emerged as an important chemical
probe of human 14-3-3 PPIs involved in cancer and neurobiology. These
previous studies have established the structural requirements for
FC-induced stabilization of 14-3-3·client phosphoprotein complexes;
however, the effect of 14-3-3 isoforms on FC activity remains underexplored.
This is a relevant question for the continued development of FC variants
because there are seven isoforms of 14-3-3 in humans. Despite their
sequence and structural similarities, a growing body of experimental
evidence supports both tissue-specific expression of 14-3-3 isoforms
and isoform-specific functions
in vivo
. Herein, we
interrogate the isoform-specificity profile of FC
in vitro
using recombinant 14-3-3 isoforms and a library of fluorescein-labeled
hexaphosphopeptides mimicking the C-terminal recognition domains of
client proteins that are characterized targets of FC
in vivo
. Our results reveal modest isoform preferences for individual client
phospholigands and demonstrate that FC differentially stabilizes PPIs
involving 14-3-3σ. Together, these data support the feasibility
of developing FC variants with enhanced isoform selectivity.
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