Sraboni Chaudhury scite author profile

This study provides a demonstration in the rat of a clear genetic difference in the propensity for addiction-related behaviors following prolonged cocaine self-administration. It relies on the use of selectively bred high-responder (bHR) and low-responder (bLR) rat lines that differ in several characteristics associated with "temperament," including novelty-induced locomotion and impulsivity. We show that bHR rats exhibit behaviors reminiscent of human addiction, including persistent cocaine-seeking and increased reinstatement of cocaine seeking. To uncover potential underlying mechanisms of this differential vulnerability, we focused on the core of the nucleus accumbens and examined expression and epigenetic regulation of two transcripts previously implicated in bHR/ bLR differences: fibroblast growth factor (FGF2) and the dopamine D2 receptor (D2). Relative to bHRs, bLRs had lower FGF2 mRNA levels and increased association of a repressive mark on histones (H3K9me3) at the FGF2 promoter. These differences were apparent under basal conditions and persisted even following prolonged cocaine self-administration. In contrast, bHRs had lower D2 mRNA under basal conditions, with greater association of H3K9me3 at the D2 promoter and these differences were no longer apparent following prolonged cocaine self-administration. Correlational analyses indicate that the association of H3K9me3 at D2 may be a critical substrate underlying the propensity to relapse. These findings suggest that low D2 mRNA levels in the nucleus accumbens core, likely mediated via epigenetic modifications, may render individuals more susceptible to cocaine addiction. In contrast, low FGF2 levels, which appear immutable even following prolonged cocaine exposure, may serve as a protective factor. addiction | dopamine | fibroblast growth factor | nucleus accumbens | reinstatement A pproximately 16% of adults in the United States report drug use within the past year (1). However, not everyone who experiments with drugs becomes an addict, as an estimated 8.5% of the population, or 25 million Americans, meet Diagnostic and Statistical Manual of Mental Disorders IV (2) criteria for substance abuse and dependence (1). Environmental and societal factors play a role in addiction liability (e.g., refs. 3-5), and there is ample evidence demonstrating a role for genetic factors (e.g., refs. 6-10). However, studying the interplay among these factors is difficult in human studies because of the inability to control for environmental factors and the challenge of parsing causes from consequences. Preclinical animal models are therefore essential for defining the complex interactions between genes and environment, and uncovering the neural mechanisms that might render an individual more susceptible to drug addiction. The first animal model characterizing individual differences in the propensity to take drugs of abuse was introduced over two decades ago by Piazza et al. (11), who showed that, like humans, only some rats readily self-administer such drugs. Furthermore...

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Activity-dependent synaptic plasticity modulates the critical phase of brain development

Chaudhury

Sharma

Kumar

et al. 2016

Brain and Development

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A-Kinase Anchoring Protein 150 Mediates Transient Receptor Potential Family V Type 1 Sensitivity to Phosphatidylinositol-4,5-Bisphosphate

Jeske¹,

Por²,

Belugin³

et al. 2011

Journal of Neuroscience

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A-kinase anchoring protein 150 (AKAP150) is a scaffolding protein that controls protein kinase A- and C-mediated phosphorylation of the transient receptor potential family V type 1 (TRPV1), dictating receptor response to nociceptive stimuli. The phospholipid phosphatidylinositol-4,5-bisphosphate (PIP2) anchors AKAP150 to the plasma membrane in naïve conditions, and also affects TRPV1 activity. In the present study, we sought to determine whether the effects of PIP2 on TRPV1 are mediated through AKAP150. In trigeminal neurons and CHO cells, the manipulation of cellular PIP2 led to significant changes in the association of AKAP150 and TRPV1. Following PIP2 degradation, increased TRPV1:AKAP150 co-immunoprecipitation was observed, resulting in increased receptor response to capsaicin treatment. Phospholipase C activation in neurons isolated from AKAP150−/− animals indicated that PIP2 -mediated inhibition of TRPV1 in the whole cell environment requires expression of the scaffolding protein. Furthermore, the addition of PIP2 to neurons isolated from AKAP150 wild-type mice reduced PKA-sensitization of TRPV1 compared to isolated neurons from AKAP150−/− mice. These findings suggest that PIP2 degradation increases AKAP150 association with TRPV1 in the whole cell environment, leading to sensitization of the receptor to nociceptive stimuli.

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FGF2 is a target and a trigger of epigenetic mechanisms associated with differences in emotionality: Partnership with H3K9me3

Chaudhury

Aurbach

Sharma

et al. 2014

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

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Posttranslational modifications of histone tails in chromatin template can result from environmental experiences such as stress and substance abuse. However, the role of epigenetic modifications as potential predisposing factors in affective behavior is less well established. To address this question, we used our selectively bred lines of high responder (bHR) and low responder (bLR) rats that show profound and stable differences in affective responses, with bLRs being prone to anxiety-and depression-like behavior and bHRs prone to addictive behavior. We first asked whether these phenotypes are associated with basal differences in epigenetic profiles. Our results reveal broad between-group differences in basal levels of trimethylated histone protein H3 at lysine 9 (H3K9me3) in hippocampus (HC), amygdala, and nucleus accumbens. Moreover, levels of association of H3K9me3 at Glucocorticoid Receptor (GR) and Fibroblast growth Factor 2 (FGF2) promoters differ reciprocally between bHRs and bLRs in these regions, consistent with these genes' opposing levels of expression and roles in modulating anxiety behavior. Importantly, this basal epigenetic pattern is modifiable by FGF2, a factor that modulates anxiety behavior. Thus, early-life FGF2, which decreases anxiety, altered the levels of H3K9me3 and its binding at FGF2 and GR promoters of bLRs rendering them more similar to bHRs. Conversely, knockdown of HC FGF2 altered both anxiety behavior and levels of H3K9me3 in bHRs, rendering them more bLR-like. These findings implicate FGF2 as a modifier of epigenetic mechanisms associated with emotional responsiveness, and point to H3K9me3 as a key player in the regulation of affective vulnerability.C hromatin remodeling is a mediator of lasting neural changes in response to experience, such as exposure to stress and drugs of abuse (1-7). Indeed, the interaction of certain modified histones with specific gene promoters has been shown to be an important mechanism of experience-dependent neuroplasticity (8-13). Although numerous studies have examined the impact of the environment on neural epigenetic profiles, relatively few studies have focused on preexisting differences in epigenetic profiles as potential predisposing factors in emotional reactivity. Such studies require the availability of an animal model where difference in "temperament" or propensity for specific affective responses can be reliably predicted and altered. Our laboratory has generated such an animal model that captures vulnerability for "internalizing disorders" vs. "externalizing disorders." Selectively bred high responder (bHR) rats exhibit greater responsiveness to novelty and to drug seeking behavior (externalizing behaviors), whereas selectively bred low responders (bLR) exhibit greater anxiety and depression-like responses (internalizing behaviors) (14, 15). These genetically bred phenotypes amplify behavioral traits observed in outbred animals (16)(17)(18)(19)(20).Several genes have been implicated in modifying these phenotypes, both in the bred and outbr...

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Expression of Synaptic Proteins in the Hippocampus and Spatial Learning in Chicks following Prenatal Auditory Stimulation

2010

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Prenatal auditory stimulation by species-specific sound influences the expression and levels of calcium-binding proteins in the chick hippocampus, which is important to learning and memory. Stimulation by sitar music additionally produces structural changes in the hippocampus. Synapse density, which influences the synaptic plasticity, is also increased following both types of sound stimulation. Here we report the expression of mRNA as well as levels of synaptic proteins (synaptophysin, synapsin I and PSD-95) in the hippocampus of developing chicks subjected to prenatal auditory stimulation. Further, to evaluate the behavioral outcome following acoustic stimulation, posthatch day 1 (PH1) chicks were analyzed by T-maze test for spatial learning. Fertilized zero day eggs were incubated under normal conditions and subjected to patterned sounds of species-specific or sitar music at 65 dB levels for 15 min/h over 24 h at a frequency range of 100–6,300 Hz for a period of 11 days from embryonic day (E) 10 until hatching. Following both types of prenatal acoustic stimulation, a significant increase in the levels of synaptophysin mRNA and protein was found from E12, whereas that of synapsin I and PSD-95 was observed from E16, suggesting early maturation of the excitatory synapse. A significant decrease in the time taken to reach the target over the 3 trials in both sound-stimulated groups indicates improved spatial learning. In the music-stimulated group, however, the time taken to reach the target was reduced from the very first trial, which may point to an involvement of other behavioral attributes in facilitating spatial navigation.

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