PUBLICATION

High-Throughput Chemical Screen Identifies a Novel Potent Modulator of Cellular Circadian Rhythms and Reveals CKIα as a Clock Regulatory Kinase

Authors

Hirota, T., Lee, J.W., Lewis, W.G., Zhang, E.E., Breton, G., Liu, X., Garcia, M., Peters, E.C., Etchegaray, J.P., Traver, D., Schultz, P.G., and Kay, S.A.

ID

ZDB-PUB-110103-9

Date

2010

Source

PLoS Biology 8(12): e1000559 (Journal)

Registered Authors

Traver, David

Keywords

Luminescence, Circadian rhythms, Small interfering RNAs, Phosphorylation, Chronobiology, Circadian oscillators, Zebrafish, Kinase inhibitors

MeSH Terms

Adenine/analogs & derivatives*
Adenine/metabolism
Animals
Biological Clocks/drug effects*
Biological Clocks/genetics
CLOCK Proteins/genetics*
CLOCK Proteins/metabolism*
Casein Kinase I/metabolism
Cell Line, Tumor
Circadian Rhythm/drug effects*
Circadian Rhythm/genetics
Circadian Rhythm/physiology*
Cyclin-Dependent Kinases/metabolism
Gene Expression Regulation/drug effects
Gene Expression Regulation/genetics
Gene Knockdown Techniques
Genome-Wide Association Study
Histones/metabolism
Humans
Mice
Mice, Inbred Strains
Mitogen-Activated Protein Kinase 1/metabolism
Period Circadian Proteins/metabolism
Protein Kinase Inhibitors/pharmacology
Protein Serine-Threonine Kinases/antagonists & inhibitors
Protein Serine-Threonine Kinases/metabolism
RNA Interference
Transcription Factors/genetics
Transcription Factors/physiology
Zebrafish/genetics
Zebrafish/physiology

PubMed

21179498 Full text @ PLoS Biol.

Abstract

The circadian clock underlies daily rhythms of diverse physiological processes, and alterations in clock function have been linked to numerous pathologies. To apply chemical biology methods to modulate and dissect the clock mechanism with new chemical probes, we performed a circadian screen of <120,000 uncharacterized compounds on human cells containing a circadian reporter. The analysis identified a small molecule that potently lengthens the circadian period in a dose-dependent manner. Subsequent analysis showed that the compound also lengthened the period in a variety of cells from different tissues including the mouse suprachiasmatic nucleus, the central clock controlling behavioral rhythms. Based on the prominent period lengthening effect, we named the compound longdaysin. Longdaysin was amenable for chemical modification to perform affinity chromatography coupled with mass spectrometry analysis to identify target proteins. Combined with siRNA-mediated gene knockdown, we identified the protein kinases CKIδ, CKIα, and ERK2 as targets of longdaysin responsible for the observed effect on circadian period. Although individual knockdown of CKIδ, CKIα, and ERK2 had small period effects, their combinatorial knockdown dramatically lengthened the period similar to longdaysin treatment. We characterized the role of CKIα in the clock mechanism and found that CKIα-mediated phosphorylation stimulated degradation of a clock protein PER1, similar to the function of CKIδ. Longdaysin treatment inhibited PER1 degradation, providing insight into the mechanism of longdaysin-dependent period lengthening. Using larval zebrafish, we further demonstrated that longdaysin drastically lengthened circadian period in vivo. Taken together, the chemical biology approach not only revealed CKIα as a clock regulatory kinase but also identified a multiple kinase network conferring robustness to the clock. Longdaysin provides novel possibilities in manipulating clock function due to its ability to simultaneously inhibit several key components of this conserved network across species.

Genes / Markers

Figures

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Expression

Phenotype

Mutations / Transgenics

Human Disease / Model

Sequence Targeting Reagents

Fish

Antibodies

Orthology

Engineered Foreign Genes

Mapping

Hirota et al., 2010 ZDB-PUB-110103-9 PMID:21179498

High-Throughput Chemical Screen Identifies a Novel Potent Modulator of Cellular Circadian Rhythms and Reveals CKIα as a Clock Regulatory Kinase

Hirota et al., 2010

ZDB-PUB-110103-9
PMID:21179498