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4. Transcriptional Activation, Deactivation and Rebound Patterns in Cortex, Hippocampus and Amygdala in Response to Ketamine Infusion in Rats

Author

Jenny J. Kim, Matthew R. Sapio, Fernando A. Vazquez, Dragan Maric, Amelia J. Loydpierson, Wenting Ma, Carlos A. Zarate, Michael J. Iadarola, and Andrew J. Mannes

Subjects
ketamine, transcriptomic (RNA-Seq), molecular pharmacology, RNA-Seq, anesthesia, systems pharmacology, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571
Abstract

Ketamine, an N-methyl-D-aspartate (NMDA)-receptor antagonist, is a recently revitalized treatment for pain and depression, yet its actions at the molecular level remain incompletely defined. In this molecular-pharmacological investigation in the rat, we used short- and longer-term infusions of high dose ketamine to stimulate neuronal transcription processes. We hypothesized that a progressively stronger modulation of neuronal gene networks would occur over time in cortical and limbic pathways. A continuous intravenous administration paradigm for ketamine was developed in rat consisting of short (1 h) and long duration (10 h, and 10 h + 24 h recovery) infusions of anesthetic concentrations to activate or inhibit gene transcription in a pharmacokinetically controlled fashion. Transcription was measured by RNA-Seq in three brain regions: frontal cortex, hippocampus, and amygdala. Cellular level gene localization was performed with multiplex fluorescent in situ hybridization. Induction of a shared transcriptional regulatory network occurred within 1 h in all three brain regions consisting of (a) genes involved in stimulus-transcription factor coupling that are induced during altered synaptic activity (immediate early genes, IEGs, such as c-Fos, 9–12 significant genes per brain region, p < 0.01 per gene) and (b) the Nrf2 oxidative stress-antioxidant response pathway downstream from glutamate signaling (Nuclear Factor Erythroid-Derived 2-Like 2) containing 12–25 increasing genes (p < 0.01) per brain region. By 10 h of infusion, the acute results were further reinforced and consisted of more and stronger gene alterations reflecting a sustained and accentuated ketamine modulation of regional excitation and plasticity. At the cellular level, in situ hybridization localized up-regulation of the plasticity-associated gene Bdnf, and the transcription factors Nr4a1 and Fos, in cortical layers III and V. After 24 h recovery, we observed overshoot of transcriptional processes rather than a smooth return to homeostasis suggesting an oscillation of plasticity occurs during the transition to a new phase of neuronal regulation. These data elucidate critical molecular regulatory actions during and downstream of ketamine administration that may contribute to the unique drug actions of this anesthetic agent. These molecular investigations point to pathways linked to therapeutically useful attributes of ketamine.

Published
2022
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6. Comparative Analysis of Dorsal Root, Nodose and Sympathetic Ganglia for the Development of New Analgesics

Author

Matthew R. Sapio, Fernando A. Vazquez, Amelia J. Loydpierson, Dragan Maric, Jenny J. Kim, Danielle M. LaPaglia, Henry L. Puhl, Van B. Lu, Stephen R. Ikeda, Andrew J. Mannes, and Michael J. Iadarola

Subjects
dorsal horn, intermediolateral cell column (IML), dorsal root ganglia, sympathetic ganglia, nodose ganglia, RNA-Seq, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571
Abstract

Interoceptive and exteroceptive signals, and the corresponding coordinated control of internal organs and sensory functions, including pain, are received and orchestrated by multiple neurons within the peripheral, central and autonomic nervous systems. A central aim of the present report is to obtain a molecularly informed basis for analgesic drug development aimed at peripheral rather than central targets. We compare three key peripheral ganglia: nodose, sympathetic (superior cervical), and dorsal root ganglia in the rat, and focus on their molecular composition using next-gen RNA-Seq, as well as their neuroanatomy using immunocytochemistry and in situ hybridization. We obtained quantitative and anatomical assessments of transmitters, receptors, enzymes and signaling pathways mediating ganglion-specific functions. Distinct ganglionic patterns of expression were observed spanning ion channels, neurotransmitters, neuropeptides, G-protein coupled receptors (GPCRs), transporters, and biosynthetic enzymes. The relationship between ganglionic transcript levels and the corresponding protein was examined using immunohistochemistry for select, highly expressed, ganglion-specific genes. Transcriptomic analyses of spinal dorsal horn and intermediolateral cell column (IML), which form the termination of primary afferent neurons and the origin of preganglionic innervation to the SCG, respectively, disclosed pre- and post-ganglionic molecular-level circuits. These multimodal investigations provide insight into autonomic regulation, nodose transcripts related to pain and satiety, and DRG-spinal cord and IML-SCG communication. Multiple neurobiological and pharmacological contexts can be addressed, such as discriminating drug targets and predicting potential side effects, in analgesic drug development efforts directed at the peripheral nervous system.

Published
2020
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7. Transcriptional Activation, Deactivation and Rebound Patterns in Cortex, Hippocampus and Amygdala in Response to Ketamine Infusion in Rats.

Author

Kim, Jenny J., Sapio, Matthew R., Vazquez, Fernando A., Maric, Dragan, Loydpierson, Amelia J., Ma, Wenting, Zarate Jr., Carlos A., Iadarola, Michael J., and Mannes, Andrew J.

Subjects
GENETIC regulation, KETAMINE abuse, NUCLEAR factor E2 related factor, KETAMINE, FLUORESCENCE in situ hybridization, HIPPOCAMPUS (Brain), AMYGDALOID body
Abstract

Ketamine, an N -methyl-D-aspartate (NMDA)-receptor antagonist, is a recently revitalized treatment for pain and depression, yet its actions at the molecular level remain incompletely defined. In this molecular-pharmacological investigation in the rat, we used short- and longer-term infusions of high dose ketamine to stimulate neuronal transcription processes. We hypothesized that a progressively stronger modulation of neuronal gene networks would occur over time in cortical and limbic pathways. A continuous intravenous administration paradigm for ketamine was developed in rat consisting of short (1 h) and long duration (10 h, and 10 h + 24 h recovery) infusions of anesthetic concentrations to activate or inhibit gene transcription in a pharmacokinetically controlled fashion. Transcription was measured by RNA-Seq in three brain regions: frontal cortex, hippocampus, and amygdala. Cellular level gene localization was performed with multiplex fluorescent in situ hybridization. Induction of a shared transcriptional regulatory network occurred within 1 h in all three brain regions consisting of (a) genes involved in stimulus-transcription factor coupling that are induced during altered synaptic activity (immediate early genes, IEGs, such as c-Fos, 9–12 significant genes per brain region, p < 0.01 per gene) and (b) the Nrf2 oxidative stress-antioxidant response pathway downstream from glutamate signaling (Nuclear Factor Erythroid-Derived 2-Like 2) containing 12–25 increasing genes (p < 0.01) per brain region. By 10 h of infusion, the acute results were further reinforced and consisted of more and stronger gene alterations reflecting a sustained and accentuated ketamine modulation of regional excitation and plasticity. At the cellular level, in situ hybridization localized up-regulation of the plasticity-associated gene Bdnf, and the transcription factors Nr4a1 and Fos, in cortical layers III and V. After 24 h recovery, we observed overshoot of transcriptional processes rather than a smooth return to homeostasis suggesting an oscillation of plasticity occurs during the transition to a new phase of neuronal regulation. These data elucidate critical molecular regulatory actions during and downstream of ketamine administration that may contribute to the unique drug actions of this anesthetic agent. These molecular investigations point to pathways linked to therapeutically useful attributes of ketamine. [ABSTRACT FROM AUTHOR]

Published
2022
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8. (350) The Persistent Pain Transcriptome: Distinct Transcriptional Signatures of Post-Surgical and Inflammatory Models Define Convergent Pathways to the Transition to Hyperalgesia

Author

Andrew J. Mannes, Matthew R. Sapio, Jenny Kim, Amelia J. Loydpierson, and Michael J. Iadarola

Subjects
education.field_of_study, business.industry, Population, Dynorphin, Spinal cord, Transcriptome, Anesthesiology and Pain Medicine, medicine.anatomical_structure, Nociception, Neurology, Hyperalgesia, Medicine, Neurology (clinical), medicine.symptom, business, Opioid peptide, Receptor, education, Neuroscience
Abstract

Most models of induced hyperalgesia display stereotyped behavioral responses to modalities such as heat and low threshold mechanical stimuli. Despite this, the nociceptive apparatus and the subsequent subjective experiences that define hyperalgesia differ greatly, as do accompanying symptoms of the associated pain state. Based on several recent in-depth studies of the activation patterns of primary afferents, we predicted that divergent activation paradigms could trigger distinct plastic events at second-order neurons that converge to sensitize the spinal circuits to evoked stimuli. The spinal circuits engaged by inflammatory and post-surgical pain states can be elucidated based on multiplex labeling and time course evaluations of the transcriptional signatures using deep sequencing. These experiments revealed a population of neurons apparently undetected by single-cell and single-nucleus sequencing methods because of its sparse representation in the superficial laminae of the dorsal horn. Investigations into the character and connectivity of these second order spinal neurons revealed that they participate similarly in at least two models of hyperalgesia. These models are driven by different transcriptional machinery at the level of the dorsal spinal cord, and the most transcriptionally evident neurons express very high levels of both the opioid peptide dynorphin and receptors that may be involved in phenotypic switching during hyperalgesia. We identified multiple cell populations, representing opponent processes acting to promote and abrogate hyperalgesia. Surprisingly, both neural and glial substrates of plasticity were divergent between the models, but converged at the pathway level. Examples of convergent pathways included immune-like activation and upregulation of the dynorphin precursor gene, whereas the activation of neuronal genes was divergent. These investigations outline a multidisciplinary strategy for identification of targets for analgesia and hyperalgesia research, and identify a set of neuronal receptors for future analgesic target development.

Published
2019
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9. (342) Molecular Transcriptomic Effects of General Anesthesia on Gene Expression in Frontal Lobe, Hippocampus, and Amygdala after Administration of Ketamine and Isoflurane

Author

Amelia J. Loydpierson, Michael J. Iadarola, Andrew J. Mannes, Matthew R. Sapio, and Jenny Kim

Subjects
Modern medicine, business.industry, medicine.drug_class, Sedation, Hippocampus, Dissociative, Anesthesiology and Pain Medicine, Neurology, Frontal lobe, Isoflurane, Anesthesia, Anesthetic, medicine, Ketamine, Neurology (clinical), medicine.symptom, business, medicine.drug
Abstract

General anesthesia and monitored sedation are vital to nearly all procedural aspects of modern medicine. Inhaled agents such as halogenated gases have long been an integral aspect of anesthesia. In recent years, the noncompetitive NMDA antagonist and dissociative anesthetic ketamine has seen increasing utilization in general anesthesia, as well as in the treatment of chronic pain and depression. The use of ketamine for such chronic conditions has raised questions into its addictive potential, and its potential role in the treatment of existing addictions. New investigations using high density electrical recordings and other multidimensional techniques have led to a clearer understanding of how these agents work, and how they can be utilized to fill clinical needs. To further study their effects at the molecular level, we used deep RNA sequencing to examine the time course (1hr, 10hr, or 10hr + 24hr recovery) of gene changes induced in the frontal cortex, hippocampus, and amygdala during ketamine or isoflurane administration. When compared to isoflurane, the transcriptional signature of ketamine showed similarities and differences that suggested region-specific gene regulation patterns that highlight the molecular underpinnings of the broad clinical uses of ketamine. The evaluation of brain regions subserving the diverse functions of learning and memory, executive function, and emotional-affective dimensions yielded insight into the neural localization of anesthetic actions and potential vulnerabilities associated with general anesthesia. Our investigation demonstrates unique region-specific and time-dependent transcriptional signatures that bridge molecular and systems level findings to expand current understanding of the shifts in neuronal activity associated with general anesthetics and their downstream effects.

Published
2019
Full Text
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10. Comparative Analysis of Dorsal Root, Nodose and Sympathetic Ganglia for the Development of New Analgesics.

Author

Sapio, Matthew R., Vazquez, Fernando A., Loydpierson, Amelia J., Maric, Dragan, Kim, Jenny J., LaPaglia, Danielle M., Puhl, Henry L., Lu, Van B., Ikeda, Stephen R., Mannes, Andrew J., and Iadarola, Michael J.

Subjects
PERIPHERAL nervous system, AUTONOMIC nervous system, SPINAL nerve roots, GANGLIA, DORSAL root ganglia, G protein coupled receptors, NONOPIOID analgesics
Abstract

Interoceptive and exteroceptive signals, and the corresponding coordinated control of internal organs and sensory functions, including pain, are received and orchestrated by multiple neurons within the peripheral, central and autonomic nervous systems. A central aim of the present report is to obtain a molecularly informed basis for analgesic drug development aimed at peripheral rather than central targets. We compare three key peripheral ganglia: nodose, sympathetic (superior cervical), and dorsal root ganglia in the rat, and focus on their molecular composition using next-gen RNA-Seq, as well as their neuroanatomy using immunocytochemistry and in situ hybridization. We obtained quantitative and anatomical assessments of transmitters, receptors, enzymes and signaling pathways mediating ganglion-specific functions. Distinct ganglionic patterns of expression were observed spanning ion channels, neurotransmitters, neuropeptides, G-protein coupled receptors (GPCRs), transporters, and biosynthetic enzymes. The relationship between ganglionic transcript levels and the corresponding protein was examined using immunohistochemistry for select, highly expressed, ganglion-specific genes. Transcriptomic analyses of spinal dorsal horn and intermediolateral cell column (IML), which form the termination of primary afferent neurons and the origin of preganglionic innervation to the SCG, respectively, disclosed pre- and post-ganglionic molecular-level circuits. These multimodal investigations provide insight into autonomic regulation, nodose transcripts related to pain and satiety, and DRG-spinal cord and IML-SCG communication. Multiple neurobiological and pharmacological contexts can be addressed, such as discriminating drug targets and predicting potential side effects, in analgesic drug development efforts directed at the peripheral nervous system. [ABSTRACT FROM AUTHOR]

Published
2020
Full Text
View/download PDF

11. (350) The Persistent Pain Transcriptome: Distinct Transcriptional Signatures of Post-Surgical and Inflammatory Models Define Convergent Pathways to the Transition to Hyperalgesia.

Author

Sapio, M., Iadarola, M., Loydpierson, A., Kim, J., and Mannes, A.

Abstract

Most models of induced hyperalgesia display stereotyped behavioral responses to modalities such as heat and low threshold mechanical stimuli. Despite this, the nociceptive apparatus and the subsequent subjective experiences that define hyperalgesia differ greatly, as do accompanying symptoms of the associated pain state. Based on several recent in-depth studies of the activation patterns of primary afferents, we predicted that divergent activation paradigms could trigger distinct plastic events at second-order neurons that converge to sensitize the spinal circuits to evoked stimuli. The spinal circuits engaged by inflammatory and post-surgical pain states can be elucidated based on multiplex labeling and time course evaluations of the transcriptional signatures using deep sequencing. These experiments revealed a population of neurons apparently undetected by single-cell and single-nucleus sequencing methods because of its sparse representation in the superficial laminae of the dorsal horn. Investigations into the character and connectivity of these second order spinal neurons revealed that they participate similarly in at least two models of hyperalgesia. These models are driven by different transcriptional machinery at the level of the dorsal spinal cord, and the most transcriptionally evident neurons express very high levels of both the opioid peptide dynorphin and receptors that may be involved in phenotypic switching during hyperalgesia. We identified multiple cell populations, representing opponent processes acting to promote and abrogate hyperalgesia. Surprisingly, both neural and glial substrates of plasticity were divergent between the models, but converged at the pathway level. Examples of convergent pathways included immune-like activation and upregulation of the dynorphin precursor gene, whereas the activation of neuronal genes was divergent. These investigations outline a multidisciplinary strategy for identification of targets for analgesia and hyperalgesia research, and identify a set of neuronal receptors for future analgesic target development. [ABSTRACT FROM AUTHOR]

Published
2019
Full Text
View/download PDF

12. (342) Molecular Transcriptomic Effects of General Anesthesia on Gene Expression in Frontal Lobe, Hippocampus, and Amygdala after Administration of Ketamine and Isoflurane.

Author

Kim, J., Sapio, M., Loydpierson, A., Mannes, A., and Iadarola, M.

Abstract

General anesthesia and monitored sedation are vital to nearly all procedural aspects of modern medicine. Inhaled agents such as halogenated gases have long been an integral aspect of anesthesia. In recent years, the noncompetitive NMDA antagonist and dissociative anesthetic ketamine has seen increasing utilization in general anesthesia, as well as in the treatment of chronic pain and depression. The use of ketamine for such chronic conditions has raised questions into its addictive potential, and its potential role in the treatment of existing addictions. New investigations using high density electrical recordings and other multidimensional techniques have led to a clearer understanding of how these agents work, and how they can be utilized to fill clinical needs. To further study their effects at the molecular level, we used deep RNA sequencing to examine the time course (1hr, 10hr, or 10hr + 24hr recovery) of gene changes induced in the frontal cortex, hippocampus, and amygdala during ketamine or isoflurane administration. When compared to isoflurane, the transcriptional signature of ketamine showed similarities and differences that suggested region-specific gene regulation patterns that highlight the molecular underpinnings of the broad clinical uses of ketamine. The evaluation of brain regions subserving the diverse functions of learning and memory, executive function, and emotional-affective dimensions yielded insight into the neural localization of anesthetic actions and potential vulnerabilities associated with general anesthesia. Our investigation demonstrates unique region-specific and time-dependent transcriptional signatures that bridge molecular and systems level findings to expand current understanding of the shifts in neuronal activity associated with general anesthetics and their downstream effects. [ABSTRACT FROM AUTHOR]

Published
2019
Full Text
View/download PDF

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