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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
21

Domain Boundaries are Essential for the Solubility of Nucleotide Binding Domains of ABC Transporters

Ikeda, Lynn Kumiko 01 January 2011 (has links)
SUR2A is a member of the ABC transporter superfamily. SUR2A mediated regulation of KATP channels is essential as mutations in the nucleotide binding domains (NBDs) of SUR2A are associated with cardiovascular disorders. Studies of eukaryotic NBDs, such as SUR2A, are hindered by low solubility of the isolated domain. We hypothesized that the solubility of heterologously expressed SUR2A NBDs depends on the definition of the domain boundaries. Boundaries were initially predicted using a combination of a structure-based sequence alignment and homology modeling, and subsequently verified by testing the solubility of five SUR2A NBD1 constructs with different N- or C-terminal boundaries. The boundaries of SUR2A NBD1 essential for solubility were identified. CD and NMR data indicate that SUR2A NBD1 is folded. Our method may be applied as a general method for developing suitable constructs of other NBDs of ABC proteins such as SUR isoforms, SUR2B and SUR2C, and the vacuolar transporter, Ycf1p.
22

Biophysical Studies of the First Nucleotide Binding Domain of SUR2A

de Araujo, Elvin Dominic 23 August 2011 (has links)
ATP-sensitive potassium (KATP) channels have crucial roles in several biological processes. KATP channels possess four regulatory sulfonylurea receptors. The SUR proteins are members of the ubiquitous ATP-binding cassette (ABC) superfamily. However, unlike most ABC proteins, SURs do not transport substrates but function strictly as regulators of KATP channel activity. Currently, studies into the molecular basis by which various mutations in SUR2A cause disease are highly limited. This is primarily a consequence of poor solubility of isolated SUR2A NBDs, as is typical for many eukaryotic NBDs. By employing structure-based sequence alignments and biophysical studies, we determined domain boundaries for SUR2A NBD1 that enabled, for the first time, NMR studies of NBD1. Our biophysical studies demonstrate that the isolated SUR2A NBD1 is folded and exhibits differential dynamics upon ATP binding activity. Additional studies are now possible to examine the effects of disease-causing mutations on structure, dynamics, and interactions of NBD1.
23

Effects of activating KATP channel mutations on neuronal function

McTaggart, James Suntac January 2011 (has links)
No description available.
24

The Potential of Modulating Na+ K+ Atpase Pumps and Katp Channels in the Development of a New Therapy to Treat Hyperkalemic Periodic Paralysis

Ammar, Tarek January 2017 (has links)
Hyperkalemic periodic paralysis (HyperKPP) is characterized by myotonic discharges and weakness/paralysis. It is a channelopathy that is caused by mutation in the SCN4A gene that encodes for the skeletal muscle Na+ channel isoform (Nav1.4) α-subunit. Limb muscles are severely affected while breathing musculature is rarely affected even though diaphragm expresses the Nav1.4 channel. The objective of this study was to investigate the mechanism(s) that render the HyperKPP diaphragm asymptomatic in order to find a novel long lasting therapeutic approach, to treat HyperKPP symptoms. A HyperKPP mouse model carrying the M1592V mutation was used because it has a similar phenotype to that of patients carrying the same mutation. HyperKPP diaphragm, the limb muscles soleus and EDL all had a higher tetrodotoxin (TTX) sensitive Na+ influx than wild type (WT), but only the soleus and EDL had a depolarized resting potential, lower force and greater K+-induced force loss when compared to WT. The lack of a membrane depolarization in HyperKPP diaphragm was because of greater electrogenic contribution of the Na+ K+ ATPase pump compared to WT while such increase was not observed in EDL and soleus. HyperKPP diaphragm also had greater action potential amplitude than EDL and soleus possibly because of higher Na+ K+ ATPase pump maintaining a low [Na+]i. An inhibition of PKA, but not of PKC, increased the sensitivity of the HyperKPP diaphragm to the K+-induced force depression. So, HyperKPP soleus was exposed to forskolin to increase cAMP levels in order to activate PKA to document whether greater activity of PKA will alleviate HyperKPP symptoms. At 4.7 mM K+, forskolin increased force production, but worsened the decrease in force at 8 and 11 mM K+. Forskolin also did not improve membrane excitability. Pinacidil a KATP channel opener, improved force production at all [K+]e by causing a hyperpolarization of resting EM which then allowed for greater action potential amplitude and more excitable fibers. It is concluded that the development of a better therapeutic approach to treat HyperKPP can include a mechanism which activates Na+ K+ ATPase pumps and KATP channels.
25

Glutamate Excitotoxicity In Epilepsy And Ischemia

Soundarapandian, Mangala Meenakshi 01 January 2007 (has links)
'Excitotoxicity' represents the excitatory amino acid mediated degeneration of neurons. Glutamate is the major excitatory neurotransmitter in the brain. Glutamate excitotoxicity has been implicated in a number of neurodegenerative disorders like Stroke, Epilepsy, Alzheimer's disease and traumatic brain injury. This neurotoxicity is summed up by the 'glutamate hypothesis' which describes the cause of neuronal cell death as an excessive release of glutamate causing over excitation of the glutamate receptors and subsequent increase in influx of calcium leading to cell death. An effort to counteract this neurotoxicity has lead to the development of glutamate receptor antagonists that can effectively serve as neuroprotective agents. Nevertheless, the downside to these drugs has been the side effects observed in clinical trial patients due to their disruptive action on the physiological function of these receptors like learning and memory. This work was undertaken to identify targets that can effectively be used to treat excitotoxicity without affecting any normal physiological functions. In one approach, (chapter I) we have identified the KATP channels as an effective modulator of epileptogenesis. In another approach, (Chapter II) we show that targeting the AMPA receptor subunit GluR2 is a practical strategy for stroke therapy. KATP channels that are gated by intracellular ATP/ADP concentrations are a unique subtype of potassium channels and play an essential role in coupling intracellular metabolic events to electrical activity. Opening of KATP channels during energy deficits in the central nervous system (CNS) induces efflux of potassium ions and in turn hyperpolarizes neurons. Thus, activation of KATP channels is thought to be able to counteract excitatory insults and protect against neuronal death. Here, we show that, functional Kir6.1 channels are located at excitatory pre-synaptic terminals as a complex with type-1 Sulfonylurea receptors (SUR1) in the hippocampus. The mutant mice with deficiencies in expressing the Kir6.1 or the SUR1 gene are more vulnerable to generation of epileptic form of seizures, compared to wild-type controls. Whole-cell patch clamp recordings demonstrate that genetic deletion of the Kir6.1/SUR1 channels enhances glutamate release at CA3 synapses. Hence, expression of functional Kir6.1/SUR1 channels inhibits seizure responses and possibly acts via limiting excitatory glutamate release. In addition to epilepsy, ischemic stroke is a leading cause of death in developed countries. A critical feature of this disease is a highly selective pattern of neuronal loss; certain identifiable subsets of neurons, particularly CA1 pyramidal neurons in the hippocampus are severely damaged, whereas others remain intact. A key step in this selective neuronal injury is Ca2+/Zn2+ entry into vulnerable neurons through [alpha]-amino-3-hydroxy-5-methyl-4-isoxazole propionic acid (AMPA) receptor channels, a principle subtype of glutamate receptors. AMPA receptor channels are assembled from glutamate receptor (GluR) -1, -2, -3, and -4 subunits. Circumstance data have indicated that the GluR2 subunits dictate Ca2+/Zn2+ permeability of AMPA receptor channels and gate injurious Ca2+/Zn2+ signals in vulnerable neurons. Here we show that ischemic insults induce toxic Ca2+ entry through AMPA receptors into vulnerable neurons by modification of GluR2 RNA editing. Thus, targeting of GluR2 subunit can be considered as a promising target for stroke therapy.
26

Investigations into the roles of potassium channels in hair growth. Studies confirming the presence of several ATP-­sensitive potassium (K+ATP) channels in hair follicles and exploring their mechanism of action using molecular biological, cell culture, organ culture and proteomic approaches.

Zemaryalai, Khatera January 2010 (has links)
Hair disorders cause significant distress. The main, but limited, treatment for hair loss is minoxidil, an ATP-­sensitive potassium (KATP) channel opener whose mechanism of stimulation is unclear. The regulatory component of KATP channels has three forms: SUR1, SUR2A and SUR2B which all respond to different molecules. Minoxidil only opens SUR2B channels, though SUR1 and SUR2B are present in human hair follicles. To expand our understanding, the red deer hair follicle model was used initially. Deer follicles expressed the same KATP channel genes as human follicles when growing (anagen), but no channels were detected in resting follicles. This reinforces the importance of KATP channels in active hair growth and the usefulness of the deer model. To assess whether SUR1 KATP channels are actually involved in human hair growth, the effects of a selective SUR1 channel opener, NNC55-­9216, on scalp follicle growth in organ culture was examined. NNC55-­9216 stimulated anagen; its effect was augmented by minoxidil. This creates the potential for more effective pharmaceuticals to treat hair loss via SUR1 channels, either alone or in combination with minoxidil. The dermal papilla plays a crucial regulatory role in hair follicle activity determining the type of hair produced. Minoxidil had no effect on dermal papilla cell proliferation, but altered the profile of proteins produced when assessed by proteomics. Further research into the roles of KATP channels and greater understanding of the significance of these protein changes should enhance our knowledge of hair biology and help the development of new, improved therapies for hair pathologies.
27

Molecular Mechanisms Regulating Ontogeny of O2- and CO2-Chemosensitivity in Rat Adrenomedullary Chromaffin Cells: Role of Nicotinic ACh and Opioid Receptor Signalling

Salman, Shaima 18 September 2014 (has links)
<p>Catecholamine (CAT) secretion from adrenomedullary chromaffin cells (AMCs) is essential for survival of the fetus and for adaptation of the newborn to extrauterine life. CAT secretion protects the fetus from intrauterine hypoxia (low O<sub>2</sub>) and is required for maintaining cardiac conduction and preparing the lungs for air breathing. Asphyxial stressors (e.g. hypoxia, hypercapnia (high PCO<sub>2</sub>), and acidosis (low pH)) arising from labor contractions and postnatal apneas, are the main stimuli for the ‘non-neurogenic’ CAT release from perinatal AMCs. In the rat, the mechanisms of hypoxia chemosensitivity in AMCs involve inhibition of a variety of K<sup>+</sup> channels, leading to membrane depolarization, voltage-gated Ca<sup>2+</sup> entry, and CAT secretion. The magnitude of this depolarization is regulated by the simultaneous activation of ATP-sensitive K<sup>+</sup> (K<sub>ATP</sub>) channels, which tends to hyperpolarize the membrane potential during hypoxia. Interestingly, chemosensitivity of rat AMCs and CAT secretion in response to asphyxial stressors are markedly reduced postnatally following the development of functional innervation of these cells by the splanchnic nerve.</p> <p>The primary purpose of this thesis was to delineate molecular mechanisms involved in the suppression of hypoxia and hypercapnia chemosensitivity following splanchnic innervation in neonatal rat AMCs. Experiments were designed to test the general hypothesis that the ontogeny of O<sub>2</sub> and CO<sub>2</sub> sensitivity in AMCs is regulated by the activation of postsynaptic nicotinic ACh and opioid receptor signalling pathways following innervation. Previous studies in this laboratory showed that exposure of perinatal rat AMCs to nicotine <em>in utero </em>and <em>in vitro</em> resulted in the selective blunting of hypoxia (but <em>not</em> hypercapnia) chemosensitivity. The underlying mechanism was attributable to the increased membrane hyperpolarization caused by the functional upregulation of K<sub>ATP</sub> channels. In Chapter 2, I report the results of investigations of molecular mechanisms involved in the nicotine-induced upregulation of K<sub>ATP</sub> channels, using a rat fetal-derived, O<sub>2</sub>- and CO<sub>2</sub>-sensitive immortalized chromaffin cell line (MAH cells), as a model. Exposure of MAH cells to chronic nicotine (50 μM) for 7 days in culture caused an increase in the expression of the K<sub>ATP</sub> channel subunit, Kir6.2. This effect was blocked by α-bungarotoxin, a blocker of homomeric α7 nicotinic acetylcholine receptors (α7 nAChRs). The upregulation of Kir6.2 in MAH cells was also dependent on the transcription factor, hypoxia inducible factor (HIF)-2α. First, whereas the upregulation of Kir6.2 was present in wild type and scrambled control MAH cells, it was absent in HIF-2α-deficient (shHIF-2α) MAH cells. Second, chronic nicotine caused a progressive, time-dependent increase in HIF-2α accumulation that occurred in parallel with the increase in Kir6.2 expression. Third, chromatin immunoprecipitation (ChIP) assays revealed the binding of HIF-2α to a hypoxia response element (HRE) in the promoter region of the Kir6.2 gene. These data suggest that chronic nicotine causes the accumulation of HIF-2α which results in the transcriptional upregulation of the Kir6.2 gene. These observations were validated in an <em>in vivo</em> model where rat pups were exposed to nicotine <em>in utero</em>. Western blot analysis of adrenal gland tissues from nicotine-exposed (relative to saline-exposed) pups revealed a significant increase in Kir6.2 subunit expression and HIF-2α accumulation, and both were restricted to the medullary (but not cortical) tissue.</p> <p>Chapter 3 tested the hypothesis that postnatal innervation causes the suppression of O<sub>2</sub>- and CO<sub>2</sub>-chemosensitivity in neonatal AMCs via opioid receptor signalling. It was found that chronic μ- and δ-opioid agonists (2 μM) <em>in vitro </em>led to the suppression of both O<sub>2</sub>- and CO<sub>2</sub>-chemosensitivity; this was correlated with the upregulation of K<sub>ATP</sub> channel expression and the downregulation of carbonic anhydrase (CA) I and II respectively. The underlying molecular and signalling mechanisms were further investigated in Chapter 4. Using the MAH cell model, it was found that exposure to a combination of μ- and δ-opioid agonists for 7 days resulted in the naloxone-sensitive upregulation of Kir6.2 subunit and the downregulation of CAII. Similar to chronic nicotine exposure, the effects of chronic opioids on the upregulation of Kir6.2 and downregulation of CAII were HIF-2α-dependent. Western blot analysis revealed that HIF-2α accumulation in opioid-treated MAH cells occurred along a time-course that paralleled the upregulation of Kir6.2 subunit. ChIP assays demonstrated the binding of HIF-2α to the promoter region of the Kir6.2 subunit gene in opioid-treated MAH cells. Moreover, PKA activity (but not PKC or CaMK) was found to be required for the effects of opioids on Kir6.2 and CAII expression, but not HIF-2α accumulation. In complementary <em>in vivo</em> studies, adrenomedullary tissues from morphine-exposed rat pups showed an increased expression of both HIF-2α and Kir6.2, and decreased expression of CA1 and II protein. These findings have uncovered novel mechanisms by which postnatal innervation contributes to the ontogeny of O<sub>2</sub>- and CO<sub>2</sub>-chemosensitivity in rat adrenal chromaffin cells. They also suggest mechanisms by which exposure of the fetus to nicotine in cigarette smoke or opioids from drug abuse might contribute to abnormal arousal reflexes, and pathophysiological conditions such as Sudden Infant Death Syndrome (SIDS).<strong></strong></p> / Doctor of Philosophy (PhD)
28

Implications des canaux K+ sur la régulation génique du canal ENaC, et impact de l'hyperglycémie sur le transport ionique et la réparation de l'épithélium respiratoire

Bardou, Olivier 04 1900 (has links)
Dans mon projet de doctorat, j’ai étudié des fonctions primordiales de l’épithélium respiratoire telles que la régulation du transport ionique, la clairance liquidienne et la réparation épithéliale. J’ai particulièrement mis l’emphase sur le rôle des canaux potassiques qui interviennent dans ces trois fonctions de l’épithélium respiratoire. J’ai tout d’abord prouvé que la modulation des canaux potassiques régulait l’activité du promoteur de αENaC, en partie via la voie de signalisation ERK1/2, dans des cellules alvéolaires. Cette régulation entraîne une variation de l’expression génique et protéique du canal ENaC. Physiologiquement, il en résulte une augmentation du phénomène de clairance liquidienne suite à l’activation des canaux K+, tandis que l’inhibition de ces canaux la diminue sévèrement. J’ai aussi pu démontrer que l’absence de canal KvLQT1 entraînait une diminution du courant (ENaC) sensible à l’amiloride, dans les cellules de trachée en culture primaire, isolées de souris KO pour kcnq1. Dans la seconde partie de mon étude, j’ai évalué l’impact de l’hyperglycémie sur la capacité de transport ionique et de réparation de cellules épithéliales bronchiques saines ou Fibrose Kystique. Mes résultats montrent que l’hyperglycémie diminue le transport transépithélial de chlore et le transport basolatéral de potassium. Des études préalables du laboratoire ayant montré que les canaux K+ et Cl- contrôlent les processus de réparation, j’ai donc évalué si ceux-ci étaient modifiés par l’hyperglycémie. Et en effet, l’hyperglycémie ralentit la vitesse de réparation des cellules issues des voies aériennes (CFBE-wt et CFBE-ΔF508). J’ai donc démontré que le transport de potassium intervenait dans des fonctions clés de l’épithélium respiratoire, comme dans la régulation génique de canaux ioniques, le contrôle de la clairance liquidienne alvéolaire, et que l’hyperglycémie diminuait le transport ionique (K+ et Cl-) et la réparation épithéliale. / During my Ph.D. training, I studied 3 important functions of respiratory epithelium : regulation of ion transport, liquid clearance and epithelial repair. I focused on potassium channels, because they control these three respiratory epithelial functions. First, I proved that αENaC promoter activity was regulated following K+ channel modulation, in alveolar cells. This regulation of αENaC promoter which might be through a modification of ERK1/2 phosphorylation, was followed by ENaC mRNA and protein expression regulation. I then showed that activation of KvLQT1 and KATP channels increased alveolar liquid clearance, whereas inhibition of these K+ channels decreased the alveolar clearance. I showed that the absence of KvLQT1 channel inhibited the amiloride-sensitive current (ENaC), in tracheal epithelial cells isolated from KvLQT1-KO mice. In the second part of my Ph.D. project, I studied the impact of hyperglycemia on Cystic Fibrosis (CF) and non-CF epithelial cells. I first observed that K+ and Cl- currents were reduced by hyperglycemia. Because we have previously shown that wound-healing process was dependant on K+ and Cl- channels, I then evaluated the impact of hyperglycemia on wound-healing. As expected, hyperglycemia slowed the repair rate of non-CF (CFBE-wt) and CF (CFBE-ΔF508) cell monolayers.
29

Regulation of Myoplasmic Ca2+ During Fatigue in KATP Channel Deficient FDB Muscle Fibres

Selvin, David 23 September 2013 (has links)
It is known that muscles that lack KATP channel activity generate much greater unstimulated [Ca2+]i and force than normal muscles during fatigue. The increase in unstimulated force in KATP channel deficient muscles is abolished by a partial inhibition of L-type Ca2+ channels, suggesting that it is due to a Ca2+ influx through L-type Ca2+ channels and a subsequent increased myoplasmic Ca2+. However, there is also evidence that the increase in resting force is abolished by NAC, a ROS scavenger. The objective of this study was to reconcile these observations by studying the hypothesis that “the increase in resting [Ca2+]i during fatigue in KATP channel deficient muscles starts with an excess Ca2+ influx through L-type Ca2+ channels, followed by an excess ROS production that causes a further increase in resting [Ca2+]i”. To test the hypothesis, single FDB fibres were fatigued with one tetanic contraction/sec for 180 sec. KATP channel deficient fibres were obtained i) by exposing wild type muscle fibers to glibenclamide, a KATP channel blocker and ii) by using fibres from Kir6.2-/- mice, which are null mice for the Kir6.2 gene that encodes for the protein forming the channel pore. Verapamil, a L-type Ca2+ channel blocker, applied at 1 μM, significantly reduced resting [Ca2+]i during fatigue in glibenclamide-exposed wild type fibres. NAC (1 mM) also reduced resting [Ca2+]i in glibenclamide-exposed muscles. The results suggest that the increase in resting [Ca2+]i during fatigue in KATP channel deficient FDB fibres is due to an influx through L-type Ca2+ channels, and an excess ROS production.
30

Regulation of Myoplasmic Ca2+ During Fatigue in KATP Channel Deficient FDB Muscle Fibres

Selvin, David January 2013 (has links)
It is known that muscles that lack KATP channel activity generate much greater unstimulated [Ca2+]i and force than normal muscles during fatigue. The increase in unstimulated force in KATP channel deficient muscles is abolished by a partial inhibition of L-type Ca2+ channels, suggesting that it is due to a Ca2+ influx through L-type Ca2+ channels and a subsequent increased myoplasmic Ca2+. However, there is also evidence that the increase in resting force is abolished by NAC, a ROS scavenger. The objective of this study was to reconcile these observations by studying the hypothesis that “the increase in resting [Ca2+]i during fatigue in KATP channel deficient muscles starts with an excess Ca2+ influx through L-type Ca2+ channels, followed by an excess ROS production that causes a further increase in resting [Ca2+]i”. To test the hypothesis, single FDB fibres were fatigued with one tetanic contraction/sec for 180 sec. KATP channel deficient fibres were obtained i) by exposing wild type muscle fibers to glibenclamide, a KATP channel blocker and ii) by using fibres from Kir6.2-/- mice, which are null mice for the Kir6.2 gene that encodes for the protein forming the channel pore. Verapamil, a L-type Ca2+ channel blocker, applied at 1 μM, significantly reduced resting [Ca2+]i during fatigue in glibenclamide-exposed wild type fibres. NAC (1 mM) also reduced resting [Ca2+]i in glibenclamide-exposed muscles. The results suggest that the increase in resting [Ca2+]i during fatigue in KATP channel deficient FDB fibres is due to an influx through L-type Ca2+ channels, and an excess ROS production.

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