Sulfur-containing molecules participate in many essential biological processes. Of utmost importance is the methylthioether moiety, present in the proteinogenic amino acid methionine and installed in tRNA by radical-S-adenosylmethionine methylthiotransferases. Although the thiol-ene reaction for carbon-sulfur bond formation has found widespread applications in materials or medicinal science, a biocompatible chemo- and regioselective hydrothiolation of unactivated alkenes and alkynes remains elusive. Here, we describe the design of a general chemoselective anti-Markovnikov hydroalkyl/aryl thiolation of alkenes and alkynes-also allowing the biologically important hydromethylthiolation-by triplet-triplet energy transfer activation of disulfides. This fast disulfide-ene reaction shows extraordinary functional group tolerance and biocompatibility. Transient absorption spectroscopy was used to study the sensitization process in detail. The hereby gained mechanistic insights were successfully employed for optimization of the catalytic system. This photosensitized transformation should stimulate bioimaging applications and carbon-sulfur bond-forming late-stage functionalization chemistry, especially in the context of metabolic labelling.
Herein, we report
the synthesis of protected 1,2-amino alcohols
starting from carbonyl compounds and α-silyl amines. The reaction
is enabled by a Cr/photoredox dual catalytic system that allows the in situ generation of α-amino carbanion equivalents
which act as nucleophiles. The unique nature of this reaction was
demonstrated through the aminoalkylation of ketones and an acyl silane,
classes of electrophiles that were previously unreactive toward addition
of alkyl-Cr reagents. Overall, this reaction broadens the scope of
Cr-mediated carbonyl alkylations and discloses an underexplored retrosynthetic
strategy for the synthesis of 1,2-amino alcohols.
Synthesis of bicyclic
scaffolds has attracted growing interest
because they are of high importance in modern pharmaceutical development.
Here we report a strategy to access polysubstituted 2-oxabicyclo[2.1.1]hexanes
in a single operation from readily accessible benzoylformate esters
and bicyclo[1.1.0]butanes via visible-light-induced triplet energy
transfer catalysis. The process is proposed to involve a formal [2π
+ 2σ] photocycloaddition/backbone C–H abstraction/aryl
group migration sequence. A diverse range of (hetero)aryl groups successfully
underwent migration to the backbone (C2) position to provide previously
inaccessible bicyclic molecules, and the ester group of the product
can serve as a handle for downstream manipulation, thus offering opportunities
to rapidly build up molecular complexity and access new sp3-rich chemical space.
A nickel-catalyzed conjunctive cross-coupling of simple alkenyl amides with aryl iodides and aryl boronic esters is reported. The reaction is enabled by an electron-deficient olefin (EDO) ligand, dimethyl fumarate, and delivers the desired 1,2-diarylated products with excellent regiocontrol. Under optimized conditions, a wide range of amides derived from 3-butenoic acid, 4-pentenoic acid, and allyl amine are compatible substrates. This methodology represents the first example of regiocontrolled 1,2-diarylation directed by a native amide functional group. Computational analysis sheds light on potential substrate binding mode and the role of EDO ligand in the reductive elimination step.
A nickel-catalyzed 1,2-diarylation
of alkenyl ketones with aryl
iodides and arylboronic esters is reported. Ketones with a variety
of substituents serve as effective directing groups, offering high
levels of regiocontrol. A representative product is diversified into
a wide range of useful products that are not readily accessible via
existing 1,2-diarylation reactions. Preliminary mechanistic studies
shed light on the binding mode of the substrate, and Hammett analysis
reveals the effect of electronic factors on initial rates.
The allylation of aldehydes is a fundamental transformation in synthetic organic chemistry. Among the multitude of available reagents, especially allylsilanes have been established as preferred allyl source. As initially reported by Hosomi & Sakurai, these non-toxic and highly stable reagents add to carbonyls via an open transition state upon Lewis acid activation. Herein, we report a general strategy to access a variety of valuable homoallylic alcohols in opposite chemo- and diastereoselectivity to the established Hosomi–Sakurai conditions by switching to photocatalytic activation in combination with a closed transition state (Chromium catalysis). Moreover, this dual catalytic approach displays a straightforward way to introduce excellent levels of enantioselectivity and its mild conditions allow for a broad substrate scope including chiral boron-substituted products as a highlight. To emphasize the synthetic utility, our method was applied as the key step in the synthesis of a bioactive compound and in the late-stage functionalization of steroid derivatives. Detailed mechanistic studies and DFT calculations hint towards an unprecedented photo-initiated chain being operative.
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