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Decoupling transcription factor expression and activity enables dimmer switch gene regulation

Chiara Ricci-Tam, Ishay Ben-Zion, Jue Wang, Julius Palme, Ang Li, Yonatan Savir, Michael Springer

2021Science58 citationsDOIOpen Access PDF

Abstract

Circuit design for control of metabolism A transcriptional control mechanism in yeast that allows cells to respond to changes in nutrient concentrations works very much like a household light-dimmer switch. That is, the system separately controls whether gene expression is “on” or “off” and the extent of gene expression. The galactose-responsive pathway is activated when yeast need to switch from metabolizing glucose to metabolizing galactose. Ricci-Tam et al. found that, rather than using two separate elements for the switch and dimmer controls, yeast use a single transcription factor, Gal4p, separately regulating its abundance (through transcriptional regulation) and its catalytic activity (through interaction with a protein-binding partner). Such regulation may be common and can allow responses to the environment on physiological and evolutionary time scales. Science , this issue p. 292

Topics & Concepts

DimmerDecoupling (probability)Transcription factorCell biologyGene expressionTranscription (linguistics)BiologyGeneGeneticsPhysicsEngineeringVoltagePhilosophyControl engineeringLinguisticsQuantum mechanicsCRISPR and Genetic EngineeringGenomics and Chromatin DynamicsRNA Research and Splicing
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