Literature DB >> 20471351

Light-mediated TIM degradation within Drosophila pacemaker neurons (s-LNvs) is neither necessary nor sufficient for delay zone phase shifts.

Chih-Hang Anthony Tang1, Erica Hinteregger, Yuhua Shang, Michael Rosbash.   

Abstract

Circadian systems are entrained and phase shifted by light. In Drosophila, the model of light-mediated phase shifting begins with photon capture by CRYPTOCHROME (CRY) followed by rapid TIMELESS (TIM) degradation. In this study, we focused on phase delays and assayed TIM degradation within individual brain clock neurons in response to light pulses in the early night. Surprisingly, there was no detectable change in TIM staining intensity within the eight pacemaker s-LNvs. This indicates that TIM degradation within s-LNvs is not necessary for phase delays, and similar assays in other genotypes indicate that it is also not sufficient. In contrast, more dorsal circadian neurons appear light-sensitive in the early night. Because CRY is still necessary within the s-LNvs for phase shifting, the results challenge the canonical cell-autonomous molecular model and raise the question of how the pacemaker neuron transcription-translation clock is reset by light in the early night. Copyright 2010 Elsevier Inc. All rights reserved.

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Year:  2010        PMID: 20471351      PMCID: PMC3024912          DOI: 10.1016/j.neuron.2010.04.015

Source DB:  PubMed          Journal:  Neuron        ISSN: 0896-6273            Impact factor:   17.173


  45 in total

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Authors:  P Emery; R Stanewsky; C Helfrich-Förster; M Emery-Le; J C Hall; M Rosbash
Journal:  Neuron       Date:  2000-05       Impact factor: 17.173

2.  A pdf neuropeptide gene mutation and ablation of PDF neurons each cause severe abnormalities of behavioral circadian rhythms in Drosophila.

Authors:  S C Renn; J H Park; M Rosbash; J C Hall; P H Taghert
Journal:  Cell       Date:  1999-12-23       Impact factor: 41.582

3.  Defining the role of Drosophila lateral neurons in the control of circadian rhythms in motor activity and eclosion by targeted genetic ablation and PERIOD protein overexpression.

Authors:  E Blanchardon; B Grima; A Klarsfeld; E Chélot; P E Hardin; T Préat; F Rouyer
Journal:  Eur J Neurosci       Date:  2001-03       Impact factor: 3.386

4.  The circadian clock of fruit flies is blind after elimination of all known photoreceptors.

Authors:  C Helfrich-Förster; C Winter; A Hofbauer; J C Hall; R Stanewsky
Journal:  Neuron       Date:  2001-04       Impact factor: 17.173

5.  Photic signaling by cryptochrome in the Drosophila circadian system.

Authors:  F J Lin; W Song; E Meyer-Bernstein; N Naidoo; A Sehgal
Journal:  Mol Cell Biol       Date:  2001-11       Impact factor: 4.272

6.  Synergic entrainment of Drosophila's circadian clock by light and temperature.

Authors:  Taishi Yoshii; Stefano Vanin; Rodolfo Costa; Charlotte Helfrich-Förster
Journal:  J Biol Rhythms       Date:  2009-12       Impact factor: 3.182

7.  Roles of the two Drosophila CRYPTOCHROME structural domains in circadian photoreception.

Authors:  Ania Busza; Myai Emery-Le; Michael Rosbash; Patrick Emery
Journal:  Science       Date:  2004-06-04       Impact factor: 47.728

8.  Electrical silencing of Drosophila pacemaker neurons stops the free-running circadian clock.

Authors:  Michael N Nitabach; Justin Blau; Todd C Holmes
Journal:  Cell       Date:  2002-05-17       Impact factor: 41.582

9.  Cryptochrome, compound eyes, Hofbauer-Buchner eyelets, and ocelli play different roles in the entrainment and masking pathway of the locomotor activity rhythm in the fruit fly Drosophila melanogaster.

Authors:  Dirk Rieger; Ralf Stanewsky; Charlotte Helfrich-Förster
Journal:  J Biol Rhythms       Date:  2003-10       Impact factor: 3.182

10.  Drosophila free-running rhythms require intercellular communication.

Authors:  Ying Peng; Dan Stoleru; Joel D Levine; Jeffrey C Hall; Michael Rosbash
Journal:  PLoS Biol       Date:  2003-09-15       Impact factor: 8.029
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  31 in total

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2.  mir-276a strengthens Drosophila circadian rhythms by regulating timeless expression.

Authors:  Xiao Chen; Michael Rosbash
Journal:  Proc Natl Acad Sci U S A       Date:  2016-05-09       Impact factor: 11.205

Review 3.  Studying circadian rhythms in Drosophila melanogaster.

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Journal:  Methods       Date:  2014-01-09       Impact factor: 3.608

4.  Temporal calcium profiling of specific circadian neurons in freely moving flies.

Authors:  Fang Guo; Xiao Chen; Michael Rosbash
Journal:  Proc Natl Acad Sci U S A       Date:  2017-09-26       Impact factor: 11.205

Review 5.  Circadian Rhythms and Sleep in Drosophila melanogaster.

Authors:  Christine Dubowy; Amita Sehgal
Journal:  Genetics       Date:  2017-04       Impact factor: 4.562

Review 6.  Molecular genetic analysis of circadian timekeeping in Drosophila.

Authors:  Paul E Hardin
Journal:  Adv Genet       Date:  2011       Impact factor: 1.944

7.  GW182 controls Drosophila circadian behavior and PDF-receptor signaling.

Authors:  Yong Zhang; Patrick Emery
Journal:  Neuron       Date:  2013-04-10       Impact factor: 17.173

8.  Flavin reduction activates Drosophila cryptochrome.

Authors:  Anand T Vaidya; Deniz Top; Craig C Manahan; Joshua M Tokuda; Sheng Zhang; Lois Pollack; Michael W Young; Brian R Crane
Journal:  Proc Natl Acad Sci U S A       Date:  2013-12-02       Impact factor: 11.205

9.  Morning and evening oscillators cooperate to reset circadian behavior in response to light input.

Authors:  Pallavi Lamba; Diana Bilodeau-Wentworth; Patrick Emery; Yong Zhang
Journal:  Cell Rep       Date:  2014-04-17       Impact factor: 9.423

10.  Circadian rhythm of temperature preference and its neural control in Drosophila.

Authors:  Haruna Kaneko; Lauren M Head; Jinli Ling; Xin Tang; Yilin Liu; Paul E Hardin; Patrick Emery; Fumika N Hamada
Journal:  Curr Biol       Date:  2012-09-13       Impact factor: 10.834
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