K.R. Simonetta scite author profile

Summary Clamp loaders load sliding clamps onto primer-template DNA. The structure of the E. coli clamp loader bound to DNA reveals the formation of an ATP-dependent spiral of ATPase domains that tracks only the template strand, allowing recognition of both RNA and DNA primers. Unlike hexameric helicases, in which DNA translocation requires distinct conformations of the ATPase domains, the clamp loader spiral is symmetric and is set up to trigger release upon DNA recognition. Specificity for primed DNA arises from blockage of the end of the primer and accommodation of the emerging template along a surface groove. A related structure reveals how the ψ protein, essential for coupling the clamp loader to single-stranded DNA binding protein (SSB), binds to the clamp loader. By stabilizing a conformation of the clamp loader that is consistent with the ATPase spiral observed upon DNA binding, ψ binding promotes the clamp loading activity of the complex.

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Prospective discovery of small molecule enhancers of an E3 ligase-substrate interaction

Simonetta

et al. 2019

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Protein–protein interactions (PPIs) governing the recognition of substrates by E3 ubiquitin ligases are critical to cellular function. There is significant therapeutic potential in the development of small molecules that modulate these interactions; however, rational design of small molecule enhancers of PPIs remains elusive. Herein, we report the prospective identification and rational design of potent small molecules that enhance the interaction between an oncogenic transcription factor, β-Catenin, and its cognate E3 ligase, SCF β-TrCP . These enhancers potentiate the ubiquitylation of mutant β-Catenin by β-TrCP in vitro and induce the degradation of an engineered mutant β-Catenin in a cellular system. Distinct from PROTACs, these drug-like small molecules insert into a naturally occurring PPI interface, with contacts optimized for both the substrate and ligase within the same small molecule entity. The prospective discovery of ‘molecular glue’ presented here provides a paradigm for the development of small molecule degraders targeting hard-to-drug proteins.

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Recombinant Globular Tail Fragment of Myosin-V Blocks Vesicle Transport in Squid Nerve Cell Extracts

Brown

Simonetta

Sandberg

et al. 2001

The Biological Bulletin

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Molecular Mechanisms of DNA Polymerase Clamp Loaders

Kelch

Makino

Simonetta

et al. 2011

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K.R. Simonetta

The Mechanism of ATP-Dependent Primer-Template Recognition by a Clamp Loader Complex

Prospective discovery of small molecule enhancers of an E3 ligase-substrate interaction

Recombinant Globular Tail Fragment of Myosin-V Blocks Vesicle Transport in Squid Nerve Cell Extracts

Molecular Mechanisms of DNA Polymerase Clamp Loaders

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