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Circadian PER2 protein oscillations do not persist in cycloheximide-treated mouse embryonic fibroblasts in culture

Authors :
Hitoshi Okamura
Masao Doi
Motomi Tainaka
Iori Murai
Yuichi Inoue
Source :
Chronobiology international. 35(1)
Publication Year :
2017

Abstract

It is not known whether the endogenous mammalian core clock proteins sustain measurable oscillations in cells in culture where de novo translation is pharmacologically inhibited. We studied here the mammalian core clock protein PER2, which undergoes robust circadian oscillations in both abundance and phosphorylation. With a newly developed antibody that enables tracing the endogenous PER2 protein oscillations over circadian cycles with cultured mouse embryonic fibroblast cells, we provide evidence that PER2 does not persist noticeable circadian rhythms when translation is inhibited.

Subjects

Subjects :
0301 basic medicine
endocrine system
Physiology
CLOCK Proteins
Endogeny
Cycloheximide
03 medical and health sciences
chemistry.chemical_compound
Mice
Physiology (medical)
Circadian Clocks
Animals
Circadian rhythm
Cells, Cultured
Translation (biology)
Period Circadian Proteins
Fibroblasts
Embryonic stem cell
Cell biology
Circadian Rhythm
PER2
030104 developmental biology
chemistry
Phosphorylation
Suprachiasmatic Nucleus

Details

ISSN :
15256073
Volume :
35
Issue :
1
Database :
OpenAIRE
Journal :
Chronobiology international
Accession number :
edsair.doi.dedup.....a1e8646ce0bc0f1013e94da68180796e

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