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Item Cellular Mechanisms Mediating the Actions of Nerve Growth Factor in Sensory Neurons(2007-08-08T15:24:37Z) Park, Kellie Adrienne; Vasko, Michael R.Nerve growth factor (NGF) is a neurotrophin upregulated with injury and inflammation. Peripheral administration of NGF causes hyperalgesia and allodynia in animals. Blocking NGF signaling reverses these effects. At the cellular level, chronic exposure of sensory neurons to NGF enhances expression the neurotransmitter, calcitonin gene-related peptide (CGRP). Acute exposure to NGF increases capsaicin-evoked CGRP release from sensory neurons in culture. Thus, NGF increases peptide release from neurons by: (1) increasing expression of peptides, and/or (2) altering their sensitivity. The increase in peptide outflow by either mechanism could contribute to development of hyperalgesia and allodynia. The signaling cascades mediating the actions of NGF in sensory neurons are unclear. Therefore, experiments were designed to determine which pathways regulate changes in iCGRP content and evoked release from primary sensory neurons in culture. The Ras/MEK/ERK cascade was identified as a possible regulator of iCGRP expression in response to NGF. To test this pathway, it was manipulated in neurons by (1) expression of dominant negative or constitutively active isoforms of Ras, (2) farnesyltransferase inhibition, (3) manipulation of the RasGAP, synGAP, and (4) blocking MEK activity. When the pathway was blocked, the NGF-induced increase in iCGRP expression was attenuated. When the Ras pathway was activated, iCGRP expression increased. These data indicate that Ras, and downstream signaling kinases, MEK and ERK, regulate the NGF-induced increases in CGRP in sensory neurons. To determine which pathway(s) regulate the increase in capsaicin-evoked iCGRP release upon brief exposure to NGF, the Ras/MEK/ERK pathway was manipulated as described above, and pharmacological inhibitors of the PI3 kinase, PLC, and Src kinase pathways were used. There were no differences observed in NGF-sensitization when the Ras and PI3 kinase pathways were inhibited, suggesting these two pathways were not involved. However, when the Src kinase inhibitor PP2 was used, the NGF-induced increase in release was completely blocked. Furthermore, the PKC inhibitor, BIM, also inhibited the sensitization by NGF. This data indicate Src and PKC regulate of sensitivity of sensory neurons in response to brief exposure to NGF. Thus, there is differential regulation of iCGRP content and evoked release from sensory neurons in response to NGF.Item Mechanism for Initiation of Food Allergy: Dependence on skin barrier mutations and environmental allergen co-stimulation(Elsevier, 2018) Walker, Matthew; Green, Jeremy; Ferrie, Ryan; Queener, Ashley; Kaplan, Mark H.; Cook-Mills, Joan M.; Pediatrics, School of MedicineBackground Mechanisms for the development of food allergy in neonates are unknown but are clearly linked in patient populations to a genetic predisposition towards skin barrier defects. Whether skin barrier defects functionally contribute to development of food allergy is unknown. Objective The purpose of the study was to determine whether skin barrier mutations, that are primarily heterozygous in patient populations, contribute to the development of food allergy. Methods Mice heterozygous for the Flgft and Tmem79ma mutations were skin sensitized with environmental allergens and food allergens. After sensitization, mice received oral challenge with food allergen and then inflammation, inflammatory mediators, and anaphylaxis were measured. Results We define development of inflammation, inflammatory mediators, and food allergen-induced anaphylaxis in neonatal mice with skin barrier mutations following brief concurrent cutaneous exposure to food and environmental allergens. Moreover, neonates of allergic mothers have elevated responses to suboptimal sensitization with food allergens. Importantly, the responses to food allergens by these neonatal mice were dependent on genetic defects in skin barrier function and on exposure to environmental allergens. Blockade of ST2 during skin sensitization inhibited development of anaphylaxis, antigen-specific IgE and inflammatory mediators. The neonatal anaphylactic responses and antigen-specific IgE were also inhibited by oral pre-exposure to food allergen but, interestingly, this was blunted by concurrent pre-exposure of the skin to environmental allergen. Conclusion These studies uncover mechanisms for food allergy sensitization and anaphylaxis in neonatal mice that are consistent with features of human early life exposures and genetics in clinical food allergy and demonstrate that changes in barrier function drive development of anaphylaxis to food allergen.Item Mechanisms of the downregulation of prostaglandin E₂-activated protein kinase A after chronic exposure to nerve growth factor or prostaglandin E₂(2013-10-07) Malty, Ramy Refaat Habashy; Vasko, Michael R.; Brustovetsky, Nickolay; Cummins, Theodore R.; Hudmon, Andy; Nicol, Grant D.Chronic inflammatory disorders are characterized by an increase in excitability of small diameter sensory neurons located in dorsal root ganglia (DRGs). This sensitization of neurons is a mechanism for chronic inflammatory pain and available therapies have poor efficacy and severe adverse effects when used chronically. Prostaglandin E₂ (PGE₂) is an inflammatory mediator that plays an important role in sensitization by activating G-protein coupled receptors (GPCRs) known as E-series prostaglandin receptors (EPs) coupled to the protein kinase A (PKA) pathway. EPs are known to downregulate upon prolonged exposure to PGE₂ or in chronic inflammation, however, sensitization persists and the mechanism for this is unknown. I hypothesized that persistence of PGE₂-induced hypersensitivity is associated with a switch in signaling caused by prolonged exposure to PGE₂ or the neurotrophin nerve growth factor (NGF), also a crucial inflammatory mediator. DRG cultures grown in the presence or absence of either PGE₂ or NGF were used to study whether re-exposure to the eicosanoid is able to cause sensitization and activate PKA. When cultures were grown in the presence of NGF, PGE₂-induced sensitization was not attenuated by inhibitors of PKA. Activation of PKA by PGE₂ was similar in DRG cultures grown in the presence or absence of NGF when phosphatase inhibitors were added to the lysis and assay buffers, but significantly less in cultures grown in the presence of NGF when phosphatase inhibitors were not added. In DRG cultures exposed to PGE₂ for 12 hours-5 days, sensitization after re-exposure to PGE₂ is maintained and resistant to PKA inhibition. Prolonged exposure to the eicosanoid caused complete loss of PKA activation after PGE₂ re-exposure. This desensitization was homologous, time dependent, reversible, and insurmountable by a higher concentration of PGE₂. Desensitization was attenuated by reduction of expression of G-protein receptor kinase 2 and was not mediated by PKA or protein kinase C. The presented work provides evidence for persistence of sensitization by PGE₂ as well as switch from the signaling pathway mediating this sensitization after long-term exposure to NFG or PGE₂.Item Nerve growth factor/p75 neurotrophin receptor–mediated sensitization of rat sensory neurons depends on membrane cholesterol(Elsevier, 2013-09-17) Zhang, YH; Khanna, R; Nicol, Grant D.; Department of Pharmacology and Toxicology, IU School of MedicineNerve growth factor (NGF) is an important mediator in the initiation of the inflammatory response and NGF via activation of the p75 neurotrophin receptor (p75(NTR)) and downstream sphingomyelin signaling leads to significant enhancement of the excitability of small-diameter sensory neurons. Because of the interaction between sphingomyelin and cholesterol in creating membrane liquid-ordered domains known as membrane or lipid rafts, we examined whether neuronal NGF-induced sensitization via p75(NTR) was dependent on the integrity of membrane rafts. Here, we demonstrate that the capacity of NGF to enhance the excitability of sensory neurons may result from the interaction of p75(NTR) with its downstream signaling partner(s) in membrane rafts. Two agents known to disrupt membrane rafts, edelfosine and methyl-β-cyclodextrin (MβCD), block the increase in excitability produced by NGF. In contrast, treatment with MβCD containing saturated amounts of cholesterol does not alter the capacity of NGF to augment excitability. In addition, adding back MβCD with cholesterol restored the NGF-induced sensitization in previously cholesterol-depleted neurons, suggesting that cholesterol and the structural integrity of rafts are key to promoting NGF-mediated sensitization. Using established protocols to isolate detergent-resistant membranes, both p75(NTR) and the neuronal membrane raft marker, flotillin, localize to raft fractions. These results suggest that downstream signaling partners interacting with p75(NTR) in sensory neurons are associated with membrane raft signaling platforms.Item Peripheral Synthesis of an Atypical Protein Kinase C Mediates the Enhancement of Excitability and the Development of Mechanical Hyperalgesia Produced by Nerve Growth Factor(Elsevier, 2018-02) Kays, Joanne; Zhang, Yi Hong; Khorodova, Alla; Strichartz, Gary; Nicol, Grant D.; Pharmacology and Toxicology, School of MedicineNerve growth factor (NGF) plays a key role in the initiation as well as the prolonged heightened pain sensitivity of the inflammatory response. Previously, we showed that NGF rapidly augmented both the excitability of isolated rat sensory neurons and the mechanical sensitivity of the rat’s hind paw. The increase in excitability and sensitivity was blocked by the myristoylated pseudosubstrate inhibitor of atypical PKCs (mPSI), suggesting that an atypical PKC may play a key regulatory role in generating this heightened sensitivity. Our findings raised the question as to whether NGF directs changes in translational control, as suggested for long-lasting long-term potentiation (LTP), or whether NGF leads to the activation of an atypical PKC by other mechanisms. The current studies demonstrate that enhanced action potential (AP) firing produced by NGF was blocked by inhibitors of translation, but not transcription. In parallel, in vitro studies showed that NGF elevated the protein levels of PKMζ, which was also prevented by inhibitors of translation. Intraplantar injection of NGF in the rat hind paw produced a rapid and maintained increase in mechanical sensitivity whose onset was delayed by translation inhibitors. Established NGF-induced hypersensitivity could be transiently reversed by injection of rapamycin or mPSI. These results suggest that NGF produces a rapid increase in the synthesis of PKMζ protein in the paw that augments neuronal sensitivity and that the ongoing translational expression of PKMζ plays a critical role in generating as well as maintaining the heightened sensitivity produced by NGF.Item RET-DEPENDENT AND RET-INDEPENDENT MECHANISMS OF GFL-INDUCED ENHANCEMENT IN THE CAPSAICIN STIMULATED-RELEASE OF iCGRP FROM SENSORY NEURONS(2010-02-02T22:18:31Z) Schmutzler, Brian S.; Hingtgen, Cynthia M., 1966-; Cummins, Theodore R.; Vasko, Michael R.; Broustovetski, Nikolai; Hudmon, AndyThe glial cell line-derived neurotrophic factor (GDNF) family ligands (GFLs) are peptides implicated in the inflammatory response. They are released in increased amounts during inflammation and induce thermal hyperalgesia. Whether these molecules directly affect the sensitivity of primary nociceptive sensory neurons is unknown. This information could provide a link between increased inflammation-induced release of GFLs and their ability to promote inflammatory hyperalgesia. These molecules bind to one of four GFRα receptor subtypes, and this GFL-GFRα complex often translocates to the receptor tyrosine kinase, Ret. The focus of this dissertation was to determine whether GFLs modulate the stimulated-release of calcitonin gene-related peptide (CGRP). Isolated sensory neurons and freshly dissociated spinal cord tissue were used to examine the enhancement in stimulated-release of CGRP, a measure of sensitization. Exposure of isolated sensory neurons to GDNF, neurturin, and artemin, enhanced the capsaicin stimulated-release of immunoreactive CGRP (iCGRP). Sensitization by GFLs occurred in freshly dissociated spinal cord tissue. Persephin, another member of the GFL family, did not enhance stimulated-release of iCGRP. These results demonstrate that specific GFLs are mediators of neuronal sensitivity. The intracellular signaling pathways responsible for this sensitization were also evaluated. Inhibition of the mitogen activated protein kinase (MAPK)/extracellular signal-related kinase 1/2 (Erk 1/2) pathway selectively abolished the enhancement of CGRP release by GDNF. NTN-induced sensitization was abolished by inhibition of the phosphatidylinositol-3-kinase (PI-3K) pathway. Reduction in Ret abolished the GDNF-induced sensitization, but did not fully inhibit NTN or ART-induced sensitization. Inhibition of other cell surface receptors (neural cell adhesion molecule (NCAM), and Integrin β-1) had distinct effects on the sensitization capability of each of the GFLs. Ret and NCAM inhibition in combination abolished ART-induced sensitization. It was necessary to inhibit Ret, NCAM, and Integrin β-1 to prevent the NTN-induced sensitization. These data demonstrate that the GFLs use distinct signaling mechanisms to induce the sensitization of nociceptive sensory neurons. The work presented in this thesis provides the first evidence for these novel and distinct Ret-independent pathways for GFL-induced actions and provides insight into the mechanism of sensory neuronal sensitization in general.Item Temporally distinct impairments in cognitive function following a sensitizing regimen of methamphetamine(2014-08-01) Janetsian, Sarine Sona; Lapish, Christopher; Neal-Beliveau, Bethany S.; Goodlett, Charles R.Methamphetamine (MA) is a widely abused psychostimulant that has been shown to evoke an array of neurobiological abnormalities and cognitive deficits in humans and in rodent models (Marshall & O'Dell, 2012). Alterations in cognitive function after repeated drug use may lead to impaired decision-making, a lack of behavioral control, and ultimately the inability to abstain from drug use. Human studies have shown that alterations in neurobiology resulting from prolonged MA use may lead to a number of cognitive deficits, including impairments in executive function, learning, memory, and impulsivity. These impairments, specifically those that engage the prefrontal cortex (PFC) or hippocampus (HC), may persist or recover based on the duration of abstinence. In rodents, repeated intermittent injections of MA yield protracted changes in neurobiology and behavior, which have been shown to effectively model a number of the biological and cognitive abnormalities observed in addiction. In order to assess the temporal evolution of impaired cognitive function throughout abstinence, sensitization was first induced in rats (7 x 5.0 mg/kg MA over 14 days). MA-treated rats initially exhibited a robust increase in locomotion that transitioned to stereotypy as the induction phase progressed. Then, the effects of MA sensitization on social interaction (SI), temporal order recognition (TOR) and novel object recognition (NOR) was assessed at one-day and 30-days post induction. No differences were observed in SI in either group or after a single injection of MA. However, an acute injection of 5.0 mg/kg of MA 30-minutes prior to testing dramatically reduced SI time. Impairments in TOR and NOR were observed in MA-treated rats after one day of abstinence, and impairments in TOR, but not NOR, were observed on day 30 of abstinence. No differences in TOR and NOR after a single injection of MA or saline were observed. These data establish that after 30 days of abstinence from a sensitizing regimen of MA, the ability to recall the temporal sequence that two stimuli were encountered was impaired and that was not attributable to impaired novelty detection. These data also suggest that at least some of the neurocognitive abnormalities caused by chronic MA administration may normalize after prolonged abstinence, since the ability to detect novelty recovered after 30 days of abstinence. These data provide compelling support that, since MA-sensitization caused temporal deficits in memory, PFC and HC function may be differentially impaired throughout the time course of abstinence.