The importance of axial chirality in enantioselective synthesis has been widely recognized for decades. The practical access to certain structures such as biaryl amino phenols known as NOBINs in enantiopure form, however, still remains a challenge. In drug delivery, the incorporation of axially chiral molecules in systematic screening has also received a great deal of interest in recent years, which calls for innovation and practical synthesis of structurally different axially chiral entities. Herein we present an operationally simple catalytic
N
-alkylation of sulfonamides using commercially available chiral amine catalysts to deliver two important classes of axially chiral compounds: structurally diverse NOBIN analogs as well as axially chiral
N
-aryl sulfonamides in excellent enantiopurity. Structurally related chiral sulfonamide has shown great potential in drug molecules but enantioselective synthesis of them has never been accomplished before. The practical catalytic procedures of our methods also bode well for their wide application in enantioselective synthesis.
We report the atomic-resolution (1.3
Å) X-ray crystal structure
of an open conformation of the dapE-encoded N-succinyl-l,l-diaminopimelic acid desuccinylase
(DapE, EC 3.5.1.18) from Neisseria meningitidis.
This structure [Protein Data Bank (PDB) entry 5UEJ] contains two bound
sulfate ions in the active site that mimic the binding of the terminal
carboxylates of the N-succinyl-l,l-diaminopimelic acid (l,l-SDAP) substrate. We demonstrated
inhibition of DapE by sulfate (IC50 = 13.8 ± 2.8 mM).
Comparison with other DapE structures in the PDB demonstrates the
flexibility of the interdomain connections of this protein. This high-resolution
structure was then utilized as the starting point for targeted molecular
dynamics experiments revealing the conformational change from the
open form to the closed form that occurs when DapE binds l,l-SDAP and cleaves the amide bond. These simulations demonstrated
closure from the open to the closed conformation, the change in RMS
throughout the closure, and the independence in the movement of the
two DapE subunits. This conformational change occurred in two phases
with the catalytic domains moving toward the dimerization domains
first, followed by a rotation of catalytic domains relative to the
dimerization domains. Although there were no targeting forces, the
substrate moved closer to the active site and bound more tightly during
the closure event.
The TiIV‐mediated synthesis of spirocyclic NH‐azetidines from oxime ethers using either an alkyl Grignard reagent or terminal olefin ligand exchange coupling partner is described. Through a proposed Kulinkovich‐type mechanism, a titanacyclopropane intermediate forms and serves as a 1,2‐aliphatic dianion equivalent, inserting into the 1,2‐dielectrophilc oxime ether to ultimately give rise to the desired N‐heterocyclic four‐membered ring. This transformation proceeds in moderate yield to furnish previously unreported and structurally diverse NH‐azetidines in a single step.
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