Megan Goh scite author profile

An attractive approach to target intracellular macromolecular interfaces is to design small high affinity proteins. In this manuscript a stable, autonomous, human derived non-immunogenic, disulphide-free VH domain, has been engineered for intracellular expression studies. VH domains can be designed to possess a large dynamic repertoire of binders, as opposed to other scaffolds types that are highly rigid and possess fewer sites of random variation. Picomolar inhibitors were identified using phage display against the eIF4F complex, which is commonly hyper-activated in many cancers. These molecules were also shown to impair cellular proliferation and to reduce the expression of malignancy related proteins. Structural characterization elucidated that these VH domains bound eIF4E at the eIF4G interaction interface via a novel binding pose. Molecules able to mimic this pose and interfere with the eIF4F complex are potentially important for wide-ranging tumour therapy applications.

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Engineering an autonomous VH domain to modulate intracellular pathways and to interrogate the eIF4F complex

Frosi

Lin

Jiang

et al. 2022

Nat Commun

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An attractive approach to target intracellular macromolecular interfaces and to model putative drug interactions is to design small high-affinity proteins. Variable domains of the immunoglobulin heavy chain (VH domains) are ideal miniproteins, but their development has been restricted by poor intracellular stability and expression. Here we show that an autonomous and disufhide-free VH domain is suitable for intracellular studies and use it to construct a high-diversity phage display library. Using this library and affinity maturation techniques we identify VH domains with picomolar affinity against eIF4E, a protein commonly hyper-activated in cancer. We demonstrate that these molecules interact with eIF4E at the eIF4G binding site via a distinct structural pose. Intracellular overexpression of these miniproteins reduce cellular proliferation and expression of malignancy-related proteins in cancer cell lines. The linkage of high-diversity in vitro libraries with an intracellularly expressible miniprotein scaffold will facilitate the discovery of VH domains suitable for intracellular applications.

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Diethyl phthalate (DEP) perturbs nitrogen metabolism in Saccharomyces cerevisiae

Goh

Cui

Wong

et al. 2022

Sci Rep

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Phthalates are ubiquitously used as plasticizers in various consumer care products. Diethyl phthalate (DEP), one of the main phthalates, elicits developmental and reproductive toxicities but the underlying mechanisms are not fully understood. Chemogenomic profiling of DEP in S. cerevisiae revealed that two transcription factors Stp1 and Dal81 involved in the Ssy1-Ptr5-Ssy5 (SPS) amino acid-sensing pathway provide resistance to DEP. Growth inhibition of yeast cells by DEP was stronger in poor nitrogen medium in comparison to nitrogen-rich medium. Addition of amino acids to nitrogen-poor medium suppressed DEP toxicity. Catabolism of amino acids via the Ehrlich pathway is required for suppressing DEP toxicity. Targeted metabolite analyses showed that DEP treatment alters the amino acid profile of yeast cells. We propose that DEP inhibits the growth of yeast cells by affecting nitrogen metabolism and discuss the implications of our findings on DEP-mediated toxic effects in humans.

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Engineering Disulphide-Free Autonomous Antibody VH Domains to modulate intracellular pathways

Frosi

Jiang²,

Ramlan

et al. 2022

Preprint

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Megan Goh

Engineering Disulphide-Free Autonomous Antibody VH Domains to modulate intracellular pathways

Engineering an autonomous VH domain to modulate intracellular pathways and to interrogate the eIF4F complex

Diethyl phthalate (DEP) perturbs nitrogen metabolism in Saccharomyces cerevisiae

Engineering Disulphide-Free Autonomous Antibody VH Domains to modulate intracellular pathways

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