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Item Aberrant Neural Activity in Cortico-Striatal-Limbic Circuitry Underlies Behavioral Deficits in a Mouse Model of Neurofibromatosis Type 1(2022-05) Drozd, Hayley Paulina; McKinzie, David L.; Clapp, D. Wade; Shekhar, Anantha; Lukkes, Jodi L.; Lapish, Christopher L.; Block, Michelle L.Nearly 18% of children are diagnosed with developmental disabilities. Autism spectrum disorders (ASDs) and attention deficit hyperactivity disorder (ADHD) are increasingly common developmental disabilities, but neither is well understood. ADHD and ASD are both prevalent in the genetic disorder Neurofibromatosis type 1 (NF1) which impairs the Ras-MAPK/ERK pathway through mutation of the neurofibromin gene (NF1+/−). More broadly, syndromic forms of developmental disorders are often caused by mutations of proteins in pathways interconnected with Ras including TSC1/2, FMR1, and SynGAP. Of NF1 patients, around 30-50% are diagnosed with ASDs and more than 60% with ADHD. These studies are the first to show that male mice haploinsufficient for the Nf1 gene (Nf1+/−) exhibit deficits in behavioral inhibition in multiple contexts, a key feature of ADHD. They exhibit hyperactivity and impulsivity in an open field, delay discounting task, and cliff avoidance reaction test, rescuable through treatment with the clinically effective ADHD drug, guanfacine (α2A adrenergic receptor agonist). Previous experiments in our lab identified social deficits including deficits in consolidation of social memory. Using optogenetics and awake behaving electrode recordings, we explored the role of the cortico-striatal-limbic circuitry in impulsivity and in social deficits in male Nf1+/− mice. Manipulation of the prefrontal cortex, nucleus accumbens, or basolateral amygdala through optogenetics rescued social deficits. These studies are the first to record brain activity in a preclinical model of NF1 during impulsive behavior, finding broad spectrum changes across slow, delta, theta, and gamma oscillatory frequencies and decreased synchrony of the prefrontal cortex and nucleus accumbens during a delay discounting task. Overall, Nf1+/− male mice with deletion of a single NF1 gene recapitulate cognitive phenotypes of NF1 patients and are a useful model system to identify alterations in neural circuitry associated with ASD and ADHD.Item Dissecting the Effects of Different Pain Modalities and Oxycodone on Prodynorphin Expressing Neurons in the Mouse Prelimbic Cortex(2022-11) Zhou, Shudi; Atwood, Brady K.; Sheets, Patrick L.; McKinzie, David L.; Truitt, William A.; Jin, XiaomingCurrently, changes to endogenous opioid circuits in various pain modalities, including surgical and neuropathic pain, remain unclear. Dynorphin, which is released by prodynorphin-expressing neurons (Pdyn+ neurons), is the endogenous opioid ligand to kappa opioid receptors (KOR). Moreover, a recent study has shown an increase in prodynorphin (Pdyn) mRNA expression in the prelimbic cortex (PL) in a mouse model of chronic pain. However, alterations in the activity of PL Pdyn-expressing neurons (PLPdyn+ neurons) in postoperative and chronic pain have never been explored. Firstly, I found that the population of PLPdyn+ neurons consists of both pyramidal and inhibitory subtypes. Secondly, I found that one day after surgical incision of the mouse hind paw, the excitability of pyramidal PLPdyn+ neurons was increased in both male and female mice, while the excitability of inhibitory PLPdyn+ neurons was unchanged. However, when postoperative pain behavior subsided, inhibitory PLPdyn+ neurons were hyperexcitable in male mice, while pyramidal PLPdyn+ neurons were hypoexcitable in female mice. Lastly, I dissected electrophysiological changes to PLPdyn+ neurons in the spared nerve injury (SNI) model of chronic neuropathic pain. At both early and late stages of SNI pain development, increased excitability of pyramidal PLPdyn+ neurons was detected in both male and female mice. However, in both male and female mice, the excitability of inhibitory PLPdyn+ neurons decreased 3 days after SNI but was conversely increased when measured 14 days after SNI. My findings suggest that different subtypes of PLPdyn+ neurons manifest distinct alterations in the development of different pain modalities in a sex-specific manner.Item Effects of Carbon Nanotubes in Barrier Epithelial Cells via Effects on Lipid Bilayers(Office of the Vice Chancellor for Research, 2013-04-05) Lewis, Shanta; Petrache, Horia I.; Blazer-Yost, Bonnie L.; Witzmann, FrankCarbon nanotubes (CNTs) are one of many nanoparticles (NP) which are being developed as part of the burgeoning nanotechnology. The tubes have similar physical properties to known toxic materials, such as asbestos; yet there is a lack of evidence showing that they may be hazardous to humans, specifically to our barrier epithelial cells. We measured the effects of CNTs on human airway epithelial cells (Calu-3 cell line) using electrophysiology. This is a technique which measures transepithelial electrical resistance (TEER), a measure of monolayer integrity; and short circuit current (SCC) a measure of net ion transport across the cell. Exposed cells showed significant decreases in TEER when incubated for 48 hours with physiologically relevant concentrations of 4μg/cm2 - 0.4ng/cm2 of multi-wall (MW) and 4μg/cm2 - 0.04ng/cm2 single-wall (SW) CNT. TEER is a measure of barrier function which is important in cells that maintain separate compartments in the body. The impaired barrier function, despite sustained cell viability, led us to investigate the mechanism by which the CNT were interacting with the cell when applied topically. Model lipid membranes connected to an ion channel amplifier, Planar Bilayer Workstation (BLM), were used. Membranes were formed using the neutral diphytanoylphosphatidylcholine (DPhPC) and negatively charged diphytanoyl phosphatidylserine (DPhPS) lipids. CNTs caused random, transient currents ranging from 0pA to 6479pA to traverse the membrane. In the presence of Gramicidin A, an ion channel reporter protein, the tubes induced increased gramicidin channel formation in the membrane to saturation level and then membrane lysis. This CNT- lipid interaction indicated that short MWCNTs permits unregulated ion movement across the lipid membrane. Disruption in the selective permeability of the plasmalemma may impact the tissue’s barrier function.Item Effects of ondansetron on apamin-sensitive small conductance calcium-activated potassium currents in pacing-induced failing rabbit hearts(Elsevier, 2019) Yin, Dechun; Yang, Na; Tian, Zhipeng; Wu, Adonis Z.; Xu, Dongzhu; Chen, Mu; Kamp, Nicholas J.; Wang, Zhuo; Shen, Changyu; Chen, Zhenhui; Lin, Shien-Fong; Rubart-von der Lohe, Michael; Chen, Peng-Sheng; Everett, Thomas H., IV; Medicine, School of MedicineBackground Ondansetron, a widely prescribed antiemetic, has been implicated in drug-induced long QT syndrome. Recent patch clamp experiments have shown that ondansetron inhibits the apamin-sensitive small conductance calcium-activated potassium current (IKAS). Objective The purpose of this study was to determine whether ondansetron causes action potential duration (APD) prolongation by IKAS inhibition. Methods Optical mapping was performed in rabbit hearts with pacing-induced heart failure (HF) and in normal hearts before and after ondansetron (100 nM) infusion. APD at 80% repolarization (APD80) and arrhythmia inducibility were determined. Additional studies with ondansetron were performed in normal hearts perfused with hypokalemic Tyrode's (2.4 mM) solution before or after apamin administration. Results The corrected QT interval in HF was 326 ms (95% confidence interval [CI] 306–347 ms) at baseline and 364 ms (95% CI 351–378 ms) after ondansetron infusion (P < .001). Ondansetron significantly prolonged APD80 in the HF group and promoted early afterdepolarizations, steepened the APD restitution curve, and increased ventricular vulnerability. Ventricular fibrillation was not inducible in HF ventricles at baseline, but after ondansetron infusion, ventricular fibrillation was induced in 5 of the 7 ventricles (P = .021). In hypokalemia, apamin prolonged APD80 from 163 ms (95% CI 146–180 ms) to 180 ms (95% CI 156–204 ms) (P = .018). Subsequent administration of ondansetron failed to further prolong APD80 (180 ms [95% CI 156–204 ms] vs 179 ms [95% CI 165–194 ms]; P = .789). The results were similar when ondansetron was administered first, followed by apamin. Conclusion Ondansetron is a specific IKAS blocker at therapeutic concentrations. Ondansetron may prolong the QT interval in HF by inhibiting small conductance calcium-activated potassium channels, which increases the vulnerability to ventricular arrhythmias.Item Electrophysiological and Pharmacological Properties of the Neuronal Voltage-gated Sodium Channel Subtype Nav1.7(2007-12) Sheets, Patrick L.; Cummins, Theodore R.; Nicol, Grant D.; Oxford, Gerry S.; Vasko, Michael R.; Schild, John H.Voltage-gated sodium channels (VGSCs) are transmembrane proteins responsible for the initiation of action potentials in excitable tissues by selectively allowing Na+ to flow through the cell membrane. VGSC subtype Nav1.7 is highly expressed in nociceptive (pain-sensing) neurons. It has recently been shown that individuals lacking the Nav1.7 subtype do not experience pain but otherwise function normally. In addition, dysfunction of Nav1.7 caused by point mutations in the channel is involved in two inherited pain disorders, primary erythromelalgia (PE) and paroxysmal extreme pain disorder (PEPD). This indicates Nav1.7 is a very important component in nociception. The aims of this dissertation were to 1) investigate if the antipsychotic drug, trifluoperazine (TFP), could modulate Nav1.7 current; 2) examine changes in Nav1.7 properties produced by the PE mutation N395K including sensitivity to the local anesthetic (LA), lidocaine; and 3) determine how different inactivated conformations of Nav1.7 affect lidocaine inhibition on the channel using PEPD mutations (I1461T and T1464I) that alter transitions between the different inactivated configurations of Nav1.7. Standard whole-cell electrophysiology was used to determine electrophysiological and pharmacological changes in WT and mutant sodium currents. Results from this dissertation demonstrate 1) TFP inhibits Nav1.7 channels through the LA interaction site; 2) the N395K mutation alters electrophysiological properties of Nav1.7 and decreases channel sensitivity to the local anesthetic lidocaine; and 3) lidocaine stabilizes Nav1.7 in a configuration that decreases transition to the slow inactivated state of the channel. Overall, this dissertation answers important questions regarding the pharmacology of Nav1.7 and provides insight into the changes in Nav1.7 channel properties caused by point mutations that may contribute to abnormal pain sensations. The results of this dissertation on the function and pharmacology of the Nav1.7 channel are crucial to the understanding of pain pathophysiology and will provide insight for the advancement of pain management therapies.Item Epilepsy Mutations in Different Regions of the Nav1.2 Channel Cause Distinct Biophysical Effects(2020-06) Mason, Emily R.; Cummins, Theodore; Sullivan, William J., Jr.; Brustovetsky, Nickolay; Sheets, Patrick; Hashino, EriWhile most cases of epilepsy respond well to common antiepileptic drugs, many genetically-driven epilepsies are refractory to conventional antiepileptic drugs. Over 250 mutations in the Nav1.2 gene (SCN2A) have been implicated in otherwise idiopathic cases of epilepsy, many of which are refractory to traditional antiepileptic drugs. Few of these mutations have been studied in vitro to determine their biophysical effects on the channels, which could reveal why the effects of some are refractory to traditional antiepileptic drugs. The goal of this dissertation was to characterize multiple epilepsy mutations in the SCN2A gene, which I hypothesized would have distinct biophysical effects on the channel’s function. I used patch-clamp electrophysiology to determine the biophysical effects of three SCN2A epilepsy mutations (R1882Q, R853Q, and L835F). Wild-type (WT) or mutant human SCN2A cDNAs were expressed in human embryonic kidney (HEK) cells and subjected to a panel of electrophysiological assays. I predicted that the net effect of each of these mutations was enhancement of channel function; my results regarding the L835F and R1882Q mutations supported this hypothesis. Both mutations enhance persistent current, and R1882Q also impairs fast inactivation. However, examination of the same parameters for the R853Q mutation suggested a decrease of channel function. I hypothesized that the R853Q mutation creates a gating pore in the channel structure through which sodium leaks into the cell when the channel is in its resting conformation. This hypothesis was supported by electrophysiological data from Xenopus oocytes, which showed a significant voltage-dependent leak current at negative potentials when they expressed the R853Q mutant channels. This was absent in oocytes expressing WT channels. Overall, these results suggest that individual mutations in the SCN2A gene generate epilepsy via distinct biophysical effects that may require novel and/or tailored pharmacotherapies for effective management.Item Impact of Acute Ethanol Injections on Medial Prefrontal Cortex Neural Activity(2019-12) Morningstar, Mitchell D.; Lapish, Christopher; Goodlett, Charles; Linsenbardt, DavidThe medial prefrontal cortex (mPFC) is a cortical brain region involved in the evaluation and selection of motivationally relevant outcomes. mPFC-mediated cognitive functions are impaired following acute alcohol exposure. In rodent models, ethanol (EtOH) doses as low as 0.75 g/kg yield deficits in cognitive functions. These deficits following acute EtOH are thought to be mediated, at least in part, by decreases in mPFC firing rates. However, these data have been generated exclusively in anesthetized rodents. To eliminate the potentially confounding role of anesthesia on EtOH modulated mPFC activity, the present study investigated the effects of acute EtOH injections on mPFC neural activity in awake-behaving rodents. We utilized three groups: the first group received 2 saline injections during the recording. The second group received a saline injection followed 30 minutes later by a 1.0 g/kg EtOH injection. The last group received a saline injection followed 30 minutes later by a 2.0 g/kg EtOH injection. One week following the awake-behaving recording, an anesthetized recording was performed using one dose of saline followed 30 minutes later by one dose of 1.0 g/kg EtOH in order to replicate previous studies. Firing rates were normalized to a baseline period that occurred 5 minutes prior to each injection. A 5-minute time period 30 minutes following the injection was used to compare across groups. There were no significant differences across the awake-behaving saline-saline group, indicating no major effect on mPFC neural activity as a result of repeated injections. There was a significant main effect across treatment & behavioral groups in the saline-EtOH 1.0 g/kg group with reductions in the EtOH & Sleep condition. In the saline-EtOH 2.0 g/kg, mPFC neural activity was only reduced in lowered states of vigilance. This suggests that EtOH only causes gross changes on neural activity when the animal is not active and behaving. Ultimately this means that EtOH’s impact on decision making is not due to gross changes in mPFC neural activity and future work should investigate its mechanism.Item An investigation of the neural circuitry of cued alcohol behaviors in P and Wistar rats(2017-12) McCane, Aqilah Maryam; Lapish, Christopher; Czachowski, CristineAlcohol-paired cues invigorate alcohol-seeking and drinking behaviors in both rodents and individuals with alcohol use disorder (AUD). Additionally, genetic susceptibility plays a key role in alcohol addiction behaviors. Alcohol preferring (P) rats model both genetic vulnerability and symptoms of AUD. The basolateral amygdala (BLA), prefrontal cortex (PFC), hippocampus (HC) and nucleus accumbens (NA) are important brain regions involved in cued alcohol seeking. These regions are interconnected and their functional connections are hypothesized to be critical in the expression of motivated behaviors. Electrophysiological recordings in these four regions were collected in P rats engaged in a cued alcohol task. Data were filtered in the theta band (5-11 Hz) and segregated by behavioral epoch. The phase locking index γ was computed and used to measure strength of phase locking between signals from any two brain regions. The cross correlation between the amplitude of two signals was used to determine directionality. PFC-NA synchrony increased after stimuli presentation and remained elevated, relative to baseline synchrony. PFC-NA synchrony was also stronger for trials in which the animal made three or more lever presses (rewarded; R), compared to trials in which the animal responded fewer than three times (not-rewarded; NR). During lever pressing, PFC-BLA, NA-HC and PFC-HC synchrony was stronger after presentation of the DS+, in R compared to NR trials. NA-HC and PFC-BLA synchrony was stronger when responses were withheld in extinction, relative to conditioning. These data inform our knowledge of how corticolimbic connections are involved in cued ethanol seeking behaviors.Item Loss of inversin contributes to renal cystic disease through altered cellular processes and decreased sodium transport in renal epithelial cells(2017-05) Kulkarni, Nalini H.; Blazer-Yost, Bonnie L.Type II nephronophthisis (NPHP2) is an autosomal recessive renal cystic disorder characterized by mutations in the inversin gene. Humans and mice with mutations in inversin have enlarged cystic kidneys. Increased kidney size in NPHP2 may involve altered cell growth, apoptosis, electrolyte transport and fluid accumulation in the cysts. To test this hypothesis, histology and transcriptome analysis were performed on one-day old wild-type and inv/inv mice to uncover molecular pathways altered in the mutant mice. Histology of inv/inv mice kidneys showed dilated cystic tubules compared to wild type. Pathway analysis of transcriptome data showed that inversin exerts its effects on kidneys, at least in part, through the transcriptional regulation of genes implicated in inflammation, immune response, cellular metabolism, cell cycle and ion transport. Genes involved in inflammation or immune response were upregulated whereas the genes involved in cell cycle progression and ion transport were downregulated. To validate the array findings from inv/inv mice kidneys, functional consequence of inversin loss on transepithelial ion transport was measured by electrophysiological techniques in shRNA mediated inversin-depleted renal cell type isolated from mouse cortical collecting duct (mCCD). Depletion of inversin decreased vasopressin-induced Na+ absorption, but did not alter Cl- secretion in mCCD cells. Addition of amiloride, a specific blocker of the epithelial sodium channel (ENaC), abolished basal ion transport in both inversin knockdown and control cells indicating ENaC involvement. Loss of inversin decreased Na+ absorption and this effect, in part, was mediated by transcriptional and post-translational regulation of ENaC mediators. To better understand inversin function in renal cells, transcriptome analysis was performed in control and inversin-depleted mCCD cells. Pathway analysis showed that inversin-depletion altered the genes represented in cell cycle, cellular assembly and organization, DNA replication, cell proliferation and ion transport in this isolated renal cell type. In concordance with the array data from inv/inv mice kidneys, a decrease in the expression of cell cycle, ion transport and apoptotic genes were observed accompanied by an upregulation of genes implicated in inflammatory or immune response indicating a direct effect of inversin on renal cells. Together, this study utilized a combination of transcriptome and functional analyses to unravel the role of inversin in renal cells. These data demonstrate that loss of inversin can cause a delay in cell cycle progression with a decrease in cell proliferation and apoptosis which in turn can perturb the development of the renal tubule. Also, a decrease in Na+ reabsorption together with differential regulation of other ion transporters can result in altered electrolyte transport contributing to cystogenesis, cyst growth, fluid accumulation and cyst expansion in NPHP2.Item Recording Intrinsic Nerve Activity at the Sinoatrial Node in Normal Dogs With High-Density Mapping(AHA, 2021-02) Yang, Yufan; Yuan, Yuan; Wong, Johnson; Fishbein, Michael C.; Chen, Peng-Sheng; Everett, Thomas H., IV; Medicine, School of MedicineBackground: It is known that autonomic nerve activity controls the sinus rate. However, the coupling between local nerve activity and electrical activation at the sinoatrial node (SAN) remains unclear. We hypothesized that we would be able to record nerve activity at the SAN to investigate if right stellate ganglion (RSG) activation can increase the local intrinsic nerve activity, accelerate sinus rate, and change the earliest activation sites. Methods: High-density mapping of the epicardial surface of the right atrium including the SAN was performed in 6 dogs during stimulation of the RSG and after RSG stellectomy. A radio transmitter was implanted into 3 additional dogs to record RSG and local nerve activity at the SAN. Results: Heart rate accelerated from 108±4 bpm at baseline to 125±7 bpm after RSG stimulation (P=0.001), and to 132±7 bpm after apamin injection (P<0.001). Both electrical RSG stimulation and apamin injection induced local nerve activity at the SAN with the average amplitudes of 3.60±0.72 and 3.86±0.56 μV, respectively. RSG stellectomy eliminated the local nerve activity and decreased the heart rate. In ambulatory dogs, local nerve activity at the SAN had a significantly higher average Pearson correlation to heart rate (0.72±0.02, P=0.001) than RSG nerve activity to HR (0.45±0.04, P=0.001). Conclusions: Local intrinsic nerve activity can be recorded at the SAN. Short bursts of these local nerve activities are present before each atrial activation during heart rate acceleration induced by stimulation of the RSG.