Expanding the HDAC druggable landscape beyond enzymatic activity

Olivet, Julien; Choi, Soon Gang; Sierra, Salvador; O’Grady, Tina; Revenga, Mario de la Fuente; Laval, Florent; Botchkarev, Vladimir V.; Gorgulla, Christoph; Coote, Paul; Blavier, Jérémy; Geffken, Ezekiel A.; Lakhani, Jimit; Song, Kijun; Yeoh, Zoe C.; Hu, Bin; Varca, Anthony C.; Bruyr, Jonathan; Ibrahim, Samira; Jivanjee, Tasneem; Bromley, Joshua D.; Nyquist, Sarah K.; Richardson, Aaron; Yue, Hong; Wang, Yan; Calonghi, Natalia; Stefan, Alessandra; Spirohn, Kerstin; Vertommen, Didier; Baietti, Maria F.; Lemmens, Irma; Seo, Hyuk‐Soo; Dozmorov, Mikhail G.; Willems, Luc; Tavernier, Jan; Das, Kalyan; Leucci, Eleonora; Hochkoeppler, Alejandro; Sun, Zhenyu; Calderwood, Michael A.; Hao, Tong; Shalek, Alex K.; Hill, David E.; Boeszoermenyi, Andras; Arthanari, Haribabu; Buhrlage, Sara J.; Dhe‐Paganon, Sirano; González-Maeso, Javier; Dequiedt, Franck; Twizere, Jean‐Claude; Vidal, Marc

doi:10.1101/2022.12.07.519454

Cited by 1 publication

(1 citation statement)

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“…Yeast can be used as a host for the production of heterologous proteins [70,71], metabolic engineering [72,73], and the construction of synthetic gene networks [74][75][76]. In a more translatable research perspective, yeast can also be used for drug discovery by screening large libraries of compounds for their ability to affect yeast growth or other phenotypes [77,78], and it can be engineered to express human disease-related proteins, allowing for the screening of compounds for their ability to modulate the activity of these proteins [79]. Finally, in the field of biophysical interactions, yeast is frequently and efficiently used to study direct and binary protein-protein interactions as it represents the only experimental structure allowing one to screen and test these biophysical interactions in a robust, reproducible, and high-throughput manner.…”

Section: Yeast This Tiny But Mighty Organismmentioning

confidence: 99%

Homo cerevisiae—Leveraging Yeast for Investigating Protein–Protein Interactions and Their Role in Human Disease

Laval

Coppin

Twizere

et al. 2023

IJMS

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Understanding how genetic variation affects phenotypes represents a major challenge, particularly in the context of human disease. Although numerous disease-associated genes have been identified, the clinical significance of most human variants remains unknown. Despite unparalleled advances in genomics, functional assays often lack sufficient throughput, hindering efficient variant functionalization. There is a critical need for the development of more potent, high-throughput methods for characterizing human genetic variants. Here, we review how yeast helps tackle this challenge, both as a valuable model organism and as an experimental tool for investigating the molecular basis of phenotypic perturbation upon genetic variation. In systems biology, yeast has played a pivotal role as a highly scalable platform which has allowed us to gain extensive genetic and molecular knowledge, including the construction of comprehensive interactome maps at the proteome scale for various organisms. By leveraging interactome networks, one can view biology from a systems perspective, unravel the molecular mechanisms underlying genetic diseases, and identify therapeutic targets. The use of yeast to assess the molecular impacts of genetic variants, including those associated with viral interactions, cancer, and rare and complex diseases, has the potential to bridge the gap between genotype and phenotype, opening the door for precision medicine approaches and therapeutic development.

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