Interest in drugs that covalently modify their target is driven by the desire for enhanced efficacy that can result from the silencing of enzymatic activity until protein resynthesis can occur, along with the potential for increased selectivity by targeting uniquely positioned nucleophilic residues in the protein. However, covalent approaches carry additional risk for toxicities or hypersensitivity reactions that can result from covalent modification of unintended targets. Here we describe methods for measuring the reactivity of covalent reactive groups (CRGs) with a biologically relevant nucleophile, glutathione (GSH), along with kinetic data for a broad array of electrophiles. We also describe a computational method for predicting electrophilic reactivity, which taken together can be applied to the prospective design of thiol-reactive covalent inhibitors.
Proteolysis targeting chimeras (PROTACs) are heterobifunctional small molecules that simultaneously bind to a target protein and an E3 ligase, thereby leading to ubiquitination and subsequent degradation of the target. They present an exciting opportunity to modulate proteins in a manner independent of enzymatic or signaling activity. As such, they have recently emerged as an attractive mechanism to explore previously "undruggable" targets. Despite this interest, fundamental questions remain regarding the parameters most critical for achieving potency and selectivity. Here we employ a series of biochemical and cellular techniques to investigate requirements for efficient knockdown of Bruton's tyrosine kinase (BTK), a nonreceptor tyrosine kinase essential for B cell maturation. Members of an 11-compound PROTAC library were investigated for their ability to form binary and ternary complexes with BTK and cereblon (CRBN, an E3 ligase component). Results were extended to measure effects on BTK-CRBN cooperative interactions as well as in vitro and in vivo BTK degradation. Our data show that alleviation of steric clashes between BTK and CRBN by modulating PROTAC linker length within this chemical series allows potent BTK degradation in the absence of thermodynamic cooperativity.
A practical electrochemical
oxidation of unactivated C–H
bonds is presented. This reaction utilizes a simple redox mediator,
quinuclidine, with inexpensive carbon and nickel electrodes to selectively
functionalize “deep-seated” methylene and methine moieties.
The process exhibits a broad scope and good functional group compatibility.
The scalability, as illustrated by a 50 g scale oxidation of sclareolide,
bodes well for immediate and widespread adoption.
C–N
cross-coupling is one of the most valuable and widespread
transformations in organic synthesis. Largely dominated by Pd- and
Cu-based catalytic systems, it has proven to be a staple transformation
for those in both academia and industry. The current study presents
the development and mechanistic understanding of an electrochemically
driven, Ni-catalyzed method for achieving this reaction of high strategic
importance. Through a series of electrochemical, computational, kinetic,
and empirical experiments, the key mechanistic features of this reaction
have been unraveled, leading to a second generation set of conditions
that is applicable to a broad range of aryl halides and amine nucleophiles
including complex examples on oligopeptides, medicinally relevant
heterocycles, natural products, and sugars. Full disclosure of the
current limitations and procedures for both batch and flow scale-ups
(100 g) are also described.
Reductive electrosynthesis has faced long-standing challenges in applications to complex organic substrates at scale. Here, we show how decades of research in lithium-ion battery materials, electrolytes, and additives can serve as an inspiration for achieving practically scalable reductive electrosynthetic conditions for the Birch reduction. Specifically, we demonstrate that using a sacrificial anode material (magnesium or aluminum), combined with a cheap, nontoxic, and water-soluble proton source (dimethylurea), and an overcharge protectant inspired by battery technology [tris(pyrrolidino)phosphoramide] can allow for multigram-scale synthesis of pharmaceutically relevant building blocks. We show how these conditions have a very high level of functional-group tolerance relative to classical electrochemical and chemical dissolving-metal reductions. Finally, we demonstrate that the same electrochemical conditions can be applied to other dissolving metal–type reductive transformations, including McMurry couplings, reductive ketone deoxygenations, and epoxide openings.
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