9 research outputs found

    Behavioral Effects of Inhibition of Cyclic Nucleotide Phosphodiesterase 2 (PDE2) in Mice

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    Cyclic nucleotide phosphodiesterases (PDEs) are a super-family of enzymes that regulate intracellular levels of the second messengers, cyclic AMP and cyclic GMP. Multiple PDEs have been shown to play vital roles in the central nervous system, with involvement in mood, reward mechanisms, and learning and memory. PDE2 is of special interest due to its high level of expression in forebrain regions, which are specifically implicated in mood and memory processes. In the first set of experiments, the potential role of PDE2 in depression- and anxiety-like behaviors was investigated using the forced swim test, tail suspension test, elevated plus maze, hole-board and step-through passive avoidance tests, as well as the object recognition test (ORT). The PDE2-selective inhibitor, Bay 60-7550 (3 mg/kg) did not significantly alter any of the depression- or anxiety-like behaviors, but did significantly enhance memory in the ORT. In the next set of experiments, the ORT was used to investigate the effect of PDE2 inhibition on various stages of learning and memory. Bay 60-7550 was administered 30-120 min prior to training, 0, 1, or 3 hrs after training, or 30 min prior to recall testing. Next, inhibitors of the cAMP or cGMP signaling pathways were administered 30 min prior to the PDE2 inhibitors Bay 60-7550 or ND7001, to assess the role cyclic nucleotide signaling on PDE2 inhibitor-enhanced memory. Finally, changes in the phosphorylation of CREB at Ser-133 and VASP at Ser-239 were determined to confirm activation of cAMP and cGMP signaling by PDE2 inhibition at behaviorally relevant doses. Bay 60-7550 (3 mg/kg) significantly enhanced memory of mice in the ORT when given 30 min prior to training, immediately after training, or 30 min prior to recall. Inhibitors of the cGMP pathway blocked the memory-enhancing effects of both Bay 60-7550 (3 mg/kg) and ND7001 (3 mg/kg). Bay 60-7550 (3 mg/kg) significantly enhanced the phosphorylation of CREB and VASP, both targets of PKG. While PDE2 inhibition did not appear to play a major role in depression- and anxiety-like behaviors in these tests, future research will further elucidate the role of PDE2 in other mood-related behavior tests. Additionally, PDE2 does appear to play a major role in learning and memory, as seen in the ORT. Developing a greater understanding of the role of PDE-2 in these memory processes will allow for potential drug development for the intervention of a variety of human diseases related to cognitive decline and memory impairment, which plague millions of individuals each year

    The Contribution of the Descending Pain Modulatory Pathway in Opioid Tolerance

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    Opioids remain among the most effective pain-relieving therapeutics. However, their long-term use is limited due to the development of tolerance and potential for addiction. For many years, researchers have explored the underlying mechanisms that lead to this decreased effectiveness of opioids after repeated use, and numerous theories have been proposed to explain these changes. The most widely studied theories involve alterations in receptor trafficking and intracellular signaling. Other possible mechanisms include the recruitment of new structural neuronal and microglia networks. While many of these theories have been developed using molecular and cellular techniques, more recent behavioral data also supports these findings. In this review, we focus on the mechanisms that underlie tolerance within the descending pain modulatory pathway, including alterations in intracellular signaling, neural-glial interactions, and neurotransmission following opioid exposure. Developing a better understanding of the relationship between these various mechanisms, within different parts of this pathway, is vital for the identification of more efficacious, novel therapeutics to treat chronic pain

    The Contribution of the Descending Pain Modulatory Pathway in Opioid Tolerance

    Get PDF
    Opioids remain among the most effective pain-relieving therapeutics. However, their long-term use is limited due to the development of tolerance and potential for addiction. For many years, researchers have explored the underlying mechanisms that lead to this decreased effectiveness of opioids after repeated use, and numerous theories have been proposed to explain these changes. The most widely studied theories involve alterations in receptor trafficking and intracellular signaling. Other possible mechanisms include the recruitment of new structural neuronal and microglia networks. While many of these theories have been developed using molecular and cellular techniques, more recent behavioral data also supports these findings. In this review, we focus on the mechanisms that underlie tolerance within the descending pain modulatory pathway, including alterations in intracellular signaling, neural-glial interactions, and neurotransmission following opioid exposure. Developing a better understanding of the relationship between these various mechanisms, within different parts of this pathway, is vital for the identification of more efficacious, novel therapeutics to treat chronic pain

    Insights into the Neurobiology of Craving in Opioid Use Disorder.

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    Purpose of reviewOpioids remain the most potent form of pain relief currently available, yet have a high abuse liability. Here we discuss underlying neurobiological changes in Opioid Use Disorder (OUD) that likely contribute to drug craving, which in turn drives continued drug use and relapse.Recent findingsCraving has emerged as a strong indicator in drug-seeking and relapse. Studies have demonstrated a number of allostatic changes in circuitry that facilitate learning of drug-stimuli relationships, thereby augmenting cue-triggered drug use and relapse.SummaryThis review will focus on key neurobiological changes in underlying circuitry observed during the initial and continued exposure to opioids that result in an increase in neural-reactivity to drug-related intrinsic and extrinsic drug cues, and to enhanced learning of drug-context correlations. This sensitized learning state may be an indication of the underlying framework that drives craving and ultimately, motivates increased salience of drug cues and drives drug-seeking

    Kappa Opioid Signaling at the Crossroads of Chronic Pain and Opioid Addiction

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    Pain is complex and is a unique experience for individuals in that no two people will have exactly the same physiological and emotional response to the same noxious stimulus or injury. Pain is composed of two essential processes: a sensory component that allows for discrimination of the intensity and location of a painful stimulus and an emotional component that underlies the affective, motivational, unpleasant, and aversive response to a painful stimulus. Kappa opioid receptor (KOR) activation in the periphery and throughout the neuroaxis modulates both of these components of the pain experience. In this chapter we focus on recent findings that KORs contribute to the emotional, aversive nature of chronic pain, including how expression in the limbic circuitry contributes to anhedonic states and components of opioid misuse disorder. While the primary focus is on preclinical pain models, we also highlight clinical or human research where there is strong evidence for KOR involvement in negative affective states associated with chronic pain and opioid misuse

    Gene therapy for guanidinoacetate methyltransferase deficiency restores cerebral and myocardial creatine while resolving behavioral abnormalities

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    Creatine deficiency disorders are inborn errors of creatine metabolism, an energy homeostasis molecule. One of these, guanidinoacetate N-methyltransferase (GAMT) deficiency, has clinical characteristics that include features of autism, self-mutilation, intellectual disability, and seizures, with approximately 40% having a disorder of movement; failure to thrive can also be a component. Along with low creatine levels, guanidinoacetic acid (GAA) toxicity has been implicated in the pathophysiology of the disorder. Present-day therapy with oral creatine to control GAA lacks efficacy; seizures can persist. Dietary management and pharmacological ornithine treatment are challenging. Using an AAV-based gene therapy approach to express human codon-optimized GAMT in hepatocytes, in situ hybridization, and immunostaining, we demonstrated pan-hepatic GAMT expression. Serial collection of blood demonstrated a marked early and sustained reduction of GAA with normalization of plasma creatine; urinary GAA levels also markedly declined. The terminal time point demonstrated marked improvement in cerebral and myocardial creatine levels. In conjunction with the biochemical findings, treated mice gained weight to nearly match their wild-type littermates, while behavioral studies demonstrated resolution of abnormalities; PET-CT imaging demonstrated improvement in brain metabolism. In conclusion, a gene therapy approach can result in long-term normalization of GAA with increased creatine in guanidinoacetate N-methyltransferase deficiency and at the same time resolves the behavioral phenotype in a murine model of the disorder. These findings have important implications for the development of a new therapy for this abnormality of creatine metabolism
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