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A role for leptin and ghrelin in the augmentation of heroin seeking induced by chronic food restriction.

Author(s): D'Cunha TM, Chisholm A, Hryhorczuk C, Fulton S, Shalev U

RATIONAL: Caloric restriction increases the risk of relapse in abstinent drug users. Hormones involved in the regulation of energy balance and food intake, such as leptin and ghrelin, are implicated in drug-related behaviors. OBJECTIVES: We investigated the...

Article GUID: 31811350
Effects of contingent and noncontingent nicotine on lever pressing for liquids and consumption in water-deprived rats.

Author(s): Frenk H, Martin J, Vitouchanskaia C, Dar R, Shalev U

Eur J Pharmacol. 2017 Jan 05;794:224-233 Authors: Frenk H, Martin J, Vitouchanskaia C, Dar R, Shalev U

Article GUID: 27889434
A role for kappa-, but not mu-opioid, receptor activation in acute food deprivation-induced reinstatement of heroin seeking in rats.

Author(s): Sedki F, Eigenmann K, Gelinas J, Schouela N, Courchesne S, Shalev U

Addict Biol. 2015 May;20(3):423-32 Authors: Sedki F, Eigenmann K, Gelinas J, Schouela N, Courchesne S, Shalev U

Article GUID: 24725195
Food restriction-induced augmentation of heroin seeking in female rats: manipulations of ovarian hormones.

Author(s): Sedki F, Gardner Gregory J, Luminare A, D'Cunha TM, Shalev U

Psychopharmacology (Berl). 2015 Oct;232(20):3773-82 Authors: Sedki F, Gardner Gregory J, Luminare A, D'Cunha TM, Shalev U

Article GUID: 26246318
Augmentation of Heroin Seeking Following Chronic Food Restriction in the Rat: Differential Role for Dopamine Transmission in the Nucleus Accumbens Shell and Core.

Author(s): D'Cunha TM, Daoud E, Rizzo D, Bishop AB, Russo M, Mourra G, Hamel L, Sedki F, Shalev U

Neuropsychopharmacology. 2017 Apr;42(5):1136-1145 Authors: D'Cunha TM, Daoud E, Rizzo D, Bishop AB, Russo M, Mourra G, Hamel L, Sedki F, Shalev U

Article GUID: 27824052
Exploring the role of locomotor sensitization in the circadian food entrainment pathway.

Author(s): Opiol H, de Zavalia N, Delorme T, Solis P, Rutherford S, Shalev U, Amir S

PLoS One. 2017;12(3):e0174113 Authors: Opiol H, de Zavalia N, Delorme T, Solis P, Rutherford S, Shalev U, Amir S

Article GUID: 28301599
Effects of chronic prenatal MK-801 treatment on object recognition, cognitive flexibility, and drug-induced locomotor activity in juvenile and adult rat offspring.

Author(s): Gallant S, Welch L, Martone P, Shalev U

Behav Brain Res. 2017 06 15;328:62-69 Authors: Gallant S, Welch L, Martone P, Shalev U

Article GUID: 28390877
The role of the paraventricular nucleus of the thalamus in the augmentation of heroin seeking induced by chronic food restriction.

Author(s): Chisholm A, Iannuzzi J, Rizzo D, Gonzalez N, Fortin É, Bumbu A, Batallán Burrowes AA, Chapman CA, Shalev U

Addict Biol. 2019 Jan 09;: Authors: Chisholm A, Iannuzzi J, Rizzo D, Gonzalez N, Fortin É, Bumbu A, Batallán Burrowes AA, Chapman CA, Shalev U

Article GUID: 30623532
Title:Exploring the role of locomotor sensitization in the circadian food entrainment pathway.
Authors:Opiol Hde Zavalia NDelorme TSolis PRutherford SShalev UAmir S
Link:https://www.ncbi.nlm.nih.gov/pubmed/28301599?dopt=Abstract
Category:PLoS One
PMID:28301599
Dept Affiliation: PSYCHOLOGY
1 Center for Studies in Behavioral Neurobiology, Department of Psychology, Concordia University, Montreal, QC, Canada.

Description:

Exploring the role of locomotor sensitization in the circadian food entrainment pathway.

PLoS One. 2017;12(3):e0174113

Authors: Opiol H, de Zavalia N, Delorme T, Solis P, Rutherford S, Shalev U, Amir S

Abstract

Food entrainment is the internal mechanism whereby the phase and period of circadian clock genes comes under the control of daily scheduled food availability. Food entrainment allows the body to efficiently realign the internal timing of behavioral and physiological functions such that they anticipate food intake. Food entrainment can occur with or without caloric restriction, as seen with daily schedules of restricted feeding (RF) or restricted treat (RT) that restrict food or treat intake to a single feeding time. However, the extent of clock gene control is more pronounced with caloric restriction, highlighting the role of energy balance in regulating clock genes. Recent studies have implicated dopamine (DA) to be involved in food entrainment and caloric restriction is known to affect dopaminergic pathways to enhance locomotor activity. Since food entrainment results in the development of a distinct behavioral component, called food anticipatory activity (FAA), we examined the role of locomotor sensitization (LS) in food entrainment by 1) observing whether amphetamine (AMPH) sensitization results in enhanced locomotor output of FAA and 2) measuring LS of circadian and non-circadian feeding paradigms to an acute injection of AMPH (AMPH cross-sensitization). Unexpectedly, AMPH sensitization did not show enhancement of FAA. On the contrary, LS did develop with sufficient exposure to RF. LS was present after 2 weeks of RF, but not after 1, 3 or 7 days into RF. When food was returned and rats regain their original body weight at 10-15 days post-RF, LS remained present. LS did not develop to RT, nor to feedings of a non-circadian schedule, e.g. variable restricted feeding (VRF) or variable RT (VRT). Further, when RF was timed to the dark period, LS was observed only when tested at night; RF timed to the light period resulted in LS that was present during day and night. Taken together our results show that LS develops with food entrainment to RF, an effect that is dependent on the chronicity and circadian phase of RF but independent of body weight. Given that LS involves reorganization of DA-regulated motor circuitry, our work provides indirect support for the role of DA in the food entrainment pathway of RF. The findings also suggest differences in neuronal pathways involved in LS from AMPH sensitization and LS from RF.

PMID: 28301599 [PubMed - indexed for MEDLINE]