Nicotine coregulates multiple pathways involved in protein modification/degradation in rat brain

Kane, Justin K.; Konu, Özlen; Jennie, Z.; Li, Ming D.

doi:10.1016/j.molbrainres.2004.09.010

Cited by 56 publications

(40 citation statements)

References 60 publications

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“…Dunckley and Lukas found that nicotine exposure alters the expression of contactin 1, UBE2C, UBE2S, and Perkin in SH-SY5Y cells Lukas 2003, 2006) with a heavy emphasis on the ubiquitin proteosomal degradation pathway. Kane et al (2004) also reported changes in the proteosomaldegradation pathway using microarray analysis of nicotinetreated rat brain, but the contributing receptor subtypes in this study are not clear.…”

Section: Discussionmentioning

confidence: 73%

Gene regulation of α4β2 nicotinic receptors: microarray analysis of nicotine‐induced receptor up‐regulation and anti‐inflammatory effects

Hosur¹,

Leppanen²,

Abutaha³

et al. 2009

Journal of Neurochemistry

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Abstractα4β2 Nicotinic acetylcholine receptors play an important role in the reward pathways for nicotine. We investigated whether receptor up‐regulation of α4β2 nicotinic acetylcholine receptors involves expression changes for non‐receptor genes. In a microarray analysis, 10 μM nicotine altered expression of 41 genes at 0.25, 1, 8 and 24 h in hα4β2 SH‐EP1 cells. The maximum number of gene changes occurred at 8 h, around the initial increase in 3[H]‐cytisine binding. Quantitative RT‐PCR corroborated gene induction of endoplasmic reticulum proteins CRELD2, PDIA6, and HERPUD1, and suppression of the pro‐inflammatory cytokines IL‐1β and IL‐6. Nicotine suppresses IL‐1β and IL‐6 expression at least in part by inhibiting NFκB activation. Antagonists dihydro‐β‐erythroidine and mecamylamine blocked these nicotine‐induced changes showing that receptor activation is required. Antagonists alone or in combination with nicotine suppressed CRELD2 message while increasing α4β2 binding. Additionally, small interfering RNA knockdown of CRELD2 increased basal α4β2 receptor expression, and antagonists decreased CRELD2 expression even in the absence of α4β2 receptors. These data suggest that endoplasmic reticulum proteins such as CRELD2 can regulate α4β2 expression, and may explain antagonist actions in nicotine‐induced receptor up‐regulation. Further, the unexpected finding that nicotine suppresses inflammatory cytokines suggests that nicotinic α4β2 receptor activation promotes anti‐inflammatory effects similar to α7 receptor activation.

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Section: Discussionmentioning

confidence: 73%

Gene regulation of α4β2 nicotinic receptors: microarray analysis of nicotine‐induced receptor up‐regulation and anti‐inflammatory effects

Hosur¹,

Leppanen²,

Abutaha³

et al. 2009

Journal of Neurochemistry

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“…In addition, altered protein kinetics has been proposed as one method of altering nicotinic receptor function as observed in recent nicotinic response work in cultured neurons (35). Evidence for a conserved role of mammalian cct8 in the nicotine response (36) includes strong expression in mouse neural tissue (37). In addition, rat cct8 mRNA is upregulated in the prefrontal cortex after exposure to nicotine (38).…”

Section: Discussionmentioning

confidence: 99%

Nicotine response genetics in the zebrafish

Petzold

Balciunas

Sivasubbu

et al. 2009

Proc. Natl. Acad. Sci. U.S.A.

120

127

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Tobacco use is predicted to result in over 1 billion deaths worldwide by the end of the 21 st century. How genetic variation contributes to the observed differential predisposition in the human population to drug dependence is unknown. The zebrafish (Danio rerio) is an emerging vertebrate model system for understanding the genetics of behavior. We developed a nicotine behavioral assay in zebrafish and applied it in a forward genetic screen using gene-breaking transposon mutagenesis. We used this method to molecularly characterize bdav/ cct8 and hbog/gabbr1.2 as mutations with altered nicotine response. Each have a single human ortholog, identifying two points for potential scientific, diagnostic, and drug development for nicotine biology and cessation therapeutics. We show this insertional method generates mutant alleles that are reversible through Cre-mediated recombination, representing a conditional mutation system for the zebrafish. The combination of this reporter-tagged insertional mutagen approach and zebrafish provides a powerful platform for a rich array of questions amenable to genetic-based scientific inquiry, including the basis of behavior, epigenetics, plasticity, stress, memory, and learning.behavior ͉ addiction

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“…Behavioral assays have been developed in a number of animal models to measure many of the known physiological manifestations associated with drug addiction, including locomotor sensitization (Benwell & Balfour, 1992;Kalivas & Stewart, 1991), conditioned place preference (CPP; Tzschentke, 1998), self-administration (Stairs, Neugebauer, & Bardo, 2010), and withdrawal (André, Gulick, Portugal, & Gould, 2008). Behavioral assays define changes induced by drug exposure and enable differential molecular analysis of the resulting transcriptional (i.e., gene expression) and epigenetic states (Kane, Konu, Ma, & Li, 2004;Kumar et al, 2005;Levine et al, 2005;Nestler, 2008;Renthal et al, 2007;Romieu et al, 2008;Shen et al, 2008). As the reinforcing properties of addictive drugs are highly conserved, behavioral assays have been adapted to zebrafish to study addiction to cocaine (Darland & Dowling, 2001), ethanol (Lockwood, Bjerke, Kobayashi, & Guo, 2004;Peng et al, 2009), amphetamines (Ninkovic & Bally-Cuif, 2006;Webb et al, 2009), and opiates (Bretaud et al, 2007;Lau, Bretaud, Huang, Lin, & Guo, 2006;Sanchez-Simon & Rodriguez, 2008).…”

Section: Drug Addiction and Dependencementioning

confidence: 99%

Zebrafish for the Study of the Biological Effects of Nicotine

Klee

Ebbert

Schneider

et al. 2011

Nicotine & Tobacco Research

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Introduction: Zebrafish are emerging as a powerful animal model for studying the molecular and physiological effects of nicotine exposure. The zebrafish have many advantageous physical characteristics, including small size, high fecundity rates, and externally developing transparent embryos. When combined with a battery of molecular-genetic tools and behavioral assays, these attributes enable studies to be conducted that are not practical using traditional animal models. Methods:We reviewed the literature on the application of the zebrafish model as a preclinical model to study the biological effects of nicotine exposure. Results:The identified studies used zebrafish to examine the effects of nicotine exposure on early development, addiction, anxiety, and learning. The methods used included green fluorescent protein-labeled proteins to track in vivo nicotine-altered neuron development, nicotine-conditioned place preference, and locomotive sensitization linked with high-throughput molecular and genetic screens and behavioral models of learning and stress response to nicotine. Data are presented on the complete homology of all known human neural nicotinic acetylcholine receptors in zebrafish and on the biological similarity of human and zebrafish dopaminergic signaling.Conclusions: Tobacco dependence remains a major health problem worldwide. Further understanding of the molecular effects of nicotine exposure and genetic contributions to dependence may lead to improvement in patient treatment strategies. While there are limitations to the use of zebrafish as a preclinical model, it should provide a valuable tool to complement existing model systems. The reviewed studies demonstrate the enormous opportunity zebrafish have to advance the science of nicotine and tobacco research.

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Nicotine coregulates multiple pathways involved in protein modification/degradation in rat brain

Cited by 56 publications

References 60 publications

Gene regulation of α4β2 nicotinic receptors: microarray analysis of nicotine‐induced receptor up‐regulation and anti‐inflammatory effects

Gene regulation of α4β2 nicotinic receptors: microarray analysis of nicotine‐induced receptor up‐regulation and anti‐inflammatory effects

Nicotine response genetics in the zebrafish

Zebrafish for the Study of the Biological Effects of Nicotine

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