A straightforward and atom-economical method is described for the synthesis of 2,3-disubstituted indoles. Anilines and 1,2-diols are condensed under neat conditions with catalytic amounts of either [Cp*IrCl(2)](2)/MsOH or RuCl(3)·xH(2)O/phosphine (phosphine = PPh(3) or xantphos). The reaction does not require any stoichiometric additives and only produces water and dihydrogen as byproducts. Anilines containing methyl, methoxy, chloro and fluoro substituents can participate in the cyclocondensation. Meta-substituted anilines give good regioselectivity for 6-substituted indoles, while unsymmetrical diols afford excellent regioselectivity for the indole isomer with an aryl or large alkyl group in the 2-position. The mechanism for the cyclocondensation presumably involves initial formation of the α-hydroxyketone from the diol. The ketone subsequently reacts with aniline to generate the α-hydroxyimine which rearranges to the corresponding α-aminoketone. Acid- or metal-catalysed electrophilic ring-closure with the release of water then furnishes the indole product.
Stapled
peptides have great potential as modulators of protein–protein
interactions (PPIs). However, there is a vast landscape of chemical
features that can be varied for any given peptide, and identifying
a set of features that maximizes cellular uptake and subsequent target
engagement remains a key challenge. Herein, we present a systematic
analysis of staple functionality on the peptide bioactivity landscape
in cellular assays. Through application of a “toolbox”
of diversified dialkynyl linkers to the stapling of MDM2-binding peptides
via a double-click approach, we conducted a study of cellular uptake
and p53 activation as a function of the linker. Minor changes in the
linker motif and the specific pairing of linker with peptide sequence
can lead to substantial differences in bioactivity, a finding which
may have important design implications for peptide-based inhibitors
of other PPIs. Given the complexity of the structure–activity
relationships involved, the toolbox approach represents a generalizable
strategy for optimization when progressing from in vitro binding assays to cellular efficacy studies.
Photoaffinity labelling is a useful method for studying how proteins interact with ligands and biomolecules, and can help identify and characterise new targets for the development of new therapeutics. We present the design and synthesis of a novel multifunctional benzophenone linker that serves as both a photo‐crosslinking motif and a peptide stapling reagent. Using double‐click stapling, we attached the benzophenone to the peptide via the staple linker, rather than by modifying the peptide sequence with a photo‐crosslinking amino acid. When applied to a p53‐derived peptide, the resulting photoreactive stapled peptide was able to preferentially crosslink with MDM2 in the presence of competing protein. This multifunctional linker also features an extra alkyne handle for downstream applications such as pull‐down assays, and can be used to investigate the target selectivity of stapled peptides.
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We herein present broadly useful, readily available and nonintegral hydroxylamine linkers for the routine solid-phase synthesis of hydroxamic acids. The developed protocols enable the efficient synthesis and release of a wide range of hydroxamic acids from various resins, relying on high control and flexibility with respect to reagents and synthetic processes. A trityl-based hydroxylamine linker was used to synthesize a library of peptide hydroxamic acids. The inhibitory effects of the compounds were examined for seven HDAC enzyme subtypes using a chemiluminescence-based assay.
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