Global ETD Search

1	Base moléculaire et rôle du courant potassique transitoire I(A) des interneurones de l'hippocampe chez le rongeur Bourdeau, Mathieu 05 1900 (has links) Les mécanismes cellulaires et moléculaires qui sous-tendent la mémoire et l’apprentissage chez les mammifères sont incomplètement compris. Le rythme thêta de l’hippocampe constitue l’état « en ligne » de cette structure qui est cruciale pour la mémoire déclarative. Dans la région CA1 de l’hippocampe, les interneurones inhibiteurs LM/RAD démontrent des oscillations de potentiel membranaire (OPM) intrinsèques qui pourraient se révéler importantes pour la génération du rythme thêta. Des travaux préliminaires ont suggéré que le courant K+ I(A) pourrait être impliqué dans la génération de ces oscillations. Néanmoins, peu de choses sont connues au sujet de l’identité des sous-unités protéiques principales et auxiliaires qui soutiennent le courant I(A) ainsi que l’ampleur de la contribution fonctionnelle de ce courant K+ dans les interneurones. Ainsi, cette thèse de doctorat démontre que le courant I(A) soutient la génération des OPM dans les interneurones LM/RAD et que des protéines Kv4.3 forment des canaux qui contribuent à ce courant. De plus, elle approfondit les connaissances sur les mécanismes qui régissent les interactions entre les sous-unités principales de canaux Kv4.3 et les protéines accessoires KChIP1. Finalement, elle révèle que la protéine KChIP1 module le courant I(A)-Kv4.3 natif et la fréquence de décharge des potentiels d’action dans les interneurones. Nos travaux contribuent à l’avancement des connaissances dans le domaine de la modulation de l’excitabilité des interneurones inhibiteurs de l’hippocampe et permettent ainsi de mieux saisir les mécanismes qui soutiennent la fonction de l’hippocampe et possiblement la mémoire chez les mammifères. / Cellular and molecular mechanisms underlying learning and memory in mammals are incompletely understood. The theta rhythm in the hippocampus constitutes the « on-line » state of this structure which is crucial for declarative memory. In the CA1 hippocampal area, LM/RAD inhibitory interneurons exhibit intrinsic membrane potential oscillations (MPOs) that could be important for the generation of theta rhythm. Preliminary work suggested that K+ current I(A) could be involved in the generation of these oscillations. Nevertheless, little is known about the identity of the principal and auxiliary protein subunits underlying I(A) current and the extent of the functional contribution of this K+ current in hippocampal interneurons. Thus, this Ph.D. thesis shows that I(A) current underlies MPO generation in LM/RAD interneurons and that Kv4.3 proteins form channels that contribute to this current. Also, it deepens the knowledge on the mechanism controlling the interactions between Kv4.3 channel-forming principal subunits and KChIP1 auxiliary proteins. Finally, it reveals that KChIP1 modulates native I(A)-Kv4.3 current and the action potential discharge frequency in interneurons. Our work takes part in advancing the knowledge on the field of modulation of excitability in hippocampal inhibitory interneurons and allows a better understanding of the mechanisms underlying the function of the hippocampus and possibly memory in mammals. hippocampe rythme thêta interneurones excitabilité oscillations de potentiel membranaire courant I(A) Kv4.3 KChIP1 hippocampus theta rhythm interneurons excitability membrane potential oscillations I(A) current
2	Molecular characterization of cholinergic vestibular and olivocochlear efferent neurons in the rodent brainstem. Leijon, Sara January 2010 (has links) <p>The neural code from the inner ear to the brain is dynamically controlled by central nervous efferent feedback to the audio-vestibular epithelium. Although such efference provides the basis for a cognitive control of our hearing and balance, we know surprisingly little about this feedback system. This project has investigated the applicability of a transgenic mouse model, expressing a fluorescent protein under the choline-acetyltransferase (ChAT) promoter, for targeting the cholinergic audio-vestibular efferent neurons in the brainstem. It was found that the mouse model is useful for targeting the vestibular efferents, which are fluorescent, but not the auditory efferents, which are not highlighted. This model enables, for the first time, physiological studies of the vestibular efferent neurons and their synaptic inputs. We next assessed the expression of the potassium channel family Kv4, known to generate transient potassium currents upon depolarization. Such potassium currents are found in auditory efferent neurons, but it is not known whether Kv4 subunits are expressed in these neurons. Moreover, it is not known if Kv4 is present and has a function in the vestibular efferent neurons. Double labelling with anti-ChAT and anti-Kv4.2 or Kv4.3 demonstrates that the Kv4.3 subunits are abundantly expressed in audio-vestibular efferents, thus indicating that this subunit is a large contributor to the excitability and firing properties of the auditory efferent neurons, and most probably also for the vestibular efferent neurons. In addition, we also unexpectedly found a strong expression of Kv4.3 in principal cells of the superior olive, the neurons which are important for sound localization.</p> Vestibular efferents olivocochlear efferents principal cells GFP ChAT superior olivary complex Kv4.3 transient outward current A-type current Molecular biology Molekylärbiologi Neurobiology Neurobiologi NATURAL SCIENCES NATURVETENSKAP Neuroscience Neurovetenskap
3	Base moléculaire et rôle du courant potassique transitoire I(A) des interneurones de l'hippocampe chez le rongeur Bourdeau, Mathieu 05 1900 (has links) Les mécanismes cellulaires et moléculaires qui sous-tendent la mémoire et l’apprentissage chez les mammifères sont incomplètement compris. Le rythme thêta de l’hippocampe constitue l’état « en ligne » de cette structure qui est cruciale pour la mémoire déclarative. Dans la région CA1 de l’hippocampe, les interneurones inhibiteurs LM/RAD démontrent des oscillations de potentiel membranaire (OPM) intrinsèques qui pourraient se révéler importantes pour la génération du rythme thêta. Des travaux préliminaires ont suggéré que le courant K+ I(A) pourrait être impliqué dans la génération de ces oscillations. Néanmoins, peu de choses sont connues au sujet de l’identité des sous-unités protéiques principales et auxiliaires qui soutiennent le courant I(A) ainsi que l’ampleur de la contribution fonctionnelle de ce courant K+ dans les interneurones. Ainsi, cette thèse de doctorat démontre que le courant I(A) soutient la génération des OPM dans les interneurones LM/RAD et que des protéines Kv4.3 forment des canaux qui contribuent à ce courant. De plus, elle approfondit les connaissances sur les mécanismes qui régissent les interactions entre les sous-unités principales de canaux Kv4.3 et les protéines accessoires KChIP1. Finalement, elle révèle que la protéine KChIP1 module le courant I(A)-Kv4.3 natif et la fréquence de décharge des potentiels d’action dans les interneurones. Nos travaux contribuent à l’avancement des connaissances dans le domaine de la modulation de l’excitabilité des interneurones inhibiteurs de l’hippocampe et permettent ainsi de mieux saisir les mécanismes qui soutiennent la fonction de l’hippocampe et possiblement la mémoire chez les mammifères. / Cellular and molecular mechanisms underlying learning and memory in mammals are incompletely understood. The theta rhythm in the hippocampus constitutes the « on-line » state of this structure which is crucial for declarative memory. In the CA1 hippocampal area, LM/RAD inhibitory interneurons exhibit intrinsic membrane potential oscillations (MPOs) that could be important for the generation of theta rhythm. Preliminary work suggested that K+ current I(A) could be involved in the generation of these oscillations. Nevertheless, little is known about the identity of the principal and auxiliary protein subunits underlying I(A) current and the extent of the functional contribution of this K+ current in hippocampal interneurons. Thus, this Ph.D. thesis shows that I(A) current underlies MPO generation in LM/RAD interneurons and that Kv4.3 proteins form channels that contribute to this current. Also, it deepens the knowledge on the mechanism controlling the interactions between Kv4.3 channel-forming principal subunits and KChIP1 auxiliary proteins. Finally, it reveals that KChIP1 modulates native I(A)-Kv4.3 current and the action potential discharge frequency in interneurons. Our work takes part in advancing the knowledge on the field of modulation of excitability in hippocampal inhibitory interneurons and allows a better understanding of the mechanisms underlying the function of the hippocampus and possibly memory in mammals. hippocampe rythme thêta interneurones excitabilité oscillations de potentiel membranaire courant I(A) Kv4.3 KChIP1 hippocampus theta rhythm interneurons excitability membrane potential oscillations I(A) current
4	Protein-Ligand Interactions and Allosteric Regulation of Activity in DREAM Protein Gonzalez, Walter G 23 March 2016 (has links) Downstream regulatory antagonist modulator (DREAM) is a calcium sensing protein that co-assembles with KV4 potassium channels to regulate ion currents as well as with DNA in the nucleus, where it regulates gene expression. The interaction of DREAM with A-type KV4 channels and DNA has been shown to regulate neuronal signaling, pain sensing, and memory retention. The role of DREAM in modulation of pain, onset of Alzheimer’s disease, and cardiac pacemaking has set this protein as a novel therapeutic target. Moreover, previous results have shown a Ca2+ dependent interaction between DREAM and KV4/DNA involving surface contacts at the N-terminus of DREAM. However, the mechanisms by which Ca2+ binding at the C-terminus of DREAM induces structural changes at the C- and N-terminus remain unknown. Here, we present the use of biophysics and biochemistry techniques in order to map the interactions of DREAM and numerous small synthetic ligands as well as KV channels. We further demonstrate that a highly conserved network of aromatic residues spanning the C- and N-terminus domains control protein dynamics and the pathways of signal transduction on DREAM. Using molecular dynamics simulations, site directed mutagenesis, and fluorescence spectroscopy we provide strong evidence in support of a highly dynamic mechanism of signal transduction and regulation. A set of aromatic amino acids including Trp169, Phe171, Tyr174, Phe218, Phe235, Phe219, and Phe252 are identified to form a dynamic network involved in propagation of Ca2+ induced structural changes. These amino acids form a hydrophobic network connecting the N- and C-terminus domains of DREAM and are well conserved in other neuronal calcium sensors. In addition, we show evidence in support of a mechanism in which Ca2+ signals are propagated towards the N-terminus and ultimately lead to the rearrangement of the inactive EF-hand 1. The observed structural motions provide a novel mechanism involved in control of the calcium dependent KV4 and DNA binding. Altogether, we provide the first mechanism of intramolecular and intermolecular signal transduction in a Ca2+ binding protein of the neuronal calcium sensor family. DREAM KChIP EF-hand CaBP NS5806 Molecular Dynamics Kv4.3 Calcium binding proteins CaBP Calcium ITC Fluorescence Spectroscopy PBD Photothermal beam Deflection Biochemistry Biophysics Molecular Biology Structural Biology
5	The impact of the β-subunit DPP10 on cardiac action potential and native voltage-gated K+ and Na+ currents Metzner, Katharina 16 March 2020 (has links) Cardiac accessory β-subunits are part of macromolecular ion channel complexes. They can modulate electrophysiological properties of resulting ion currents and action potentials and are supposed to contribute to cardiac disease e.g. arrhythmias or Brugada syndrome. In my thesis, we characterized the functions of dipeptidyl peptidase-like protein 10 (DPP10), a transmembrane β-subunit of cardiac Na+ and K+ channels. Previous studies revealed that DPP10 is expressed in human heart and acts as regulator of Kv channel kinetics. In electrophysiological experiments, we found that DPP10 modulates Ito through Kv4.3 channel complexes by accelerating current densities and the time course of activation, inactivation and recovery from inactivation. Interestingly, co-expression of DPP10 with Kv4.3 and KChIP2 in CHO cells induced a slowly inactivating fraction of Ito, providing evidence for a contribution of Ito on the sustained outward K+ current in cardiomyoctes. Until then, the sustained fraction of K+ currents was thought to be due to IKur. We further studied the contribution of Kv4-mediated Ito to total K+ currents in human atrial myocytes using 4-Aminopyridine to block IKur in combination with Heteropoda toxin 2 to block Kv4 channels. Using this approach, it was possible to separate an Ito fraction of about 19% contributing to the late current component. These data suggest that the generation of a sustained current component of Ito induced by DPP10 may affect the late repolarization phase of an atrial action potential. To further explore the functions of DPP10, we investigated a potential interaction with Nav channels in cardiomyocytes. It was possible to detect DPP10 in human ventricles, with higher expression levels in patients with heart failure. We demonstrated that DPP10 affects cellular action potentials in isolated rat cardiomyocytes after adenoviral gene transfer indicating a reduction in Na+ current density. Voltage-dependent Na+ channel activation and inactivation curve was shifted to more positive potentials with overexpression of DPP10, resulting in enhanced availability of Na+ channels for activation, along with increasing window Na+ current. Thus, we assumed a role of DPP10 on promotion of arrhythmias via interaction with Nav1.5. The results of this study can help to understand the complex interaction pattern between Nav and Kv channels and the role of their β-subunits, especially DPP10. In conclusion, DPP10 was identified as a new modulator of Kv and Nav currents in the human heart, suggesting that this β-subunit may contributes to cardiac arrhythmias and might be a new therapeutic target.:1 Introduction 1.1 The cardiac action potential 1.2 Cardiac potassium channels 1.2.1 The Kv4.3 channel complex 1.2.2 Accessory β subunits of K+ channel 1.2.3 The Kv1.5 channel 1.2.4 Separation of Ito and IKur in native cardiomyocytes 1.3 Cardiac sodium channels 1.3.1 Molecular construction of Nav1.5 channel 1.3.2 Accessory β subunits of Na+ channel 1.3.3 The role of Nav1.5 in cardiac electrical disorders 1.4 Aim of the thesis and systematic approach 2 The research articles 3 Summary 4 Zusammenfassung 6 References 7 Appendices 7.1 Abbreviations info:eu-repo/classification/ddc/610 ddc:610
6	Molecular characterization of cholinergic vestibular and olivocochlear efferent neurons in the rodent brainstem. Leijon, Sara January 2010 (has links) The neural code from the inner ear to the brain is dynamically controlled by central nervous efferent feedback to the audio-vestibular epithelium. Although such efference provides the basis for a cognitive control of our hearing and balance, we know surprisingly little about this feedback system. This project has investigated the applicability of a transgenic mouse model, expressing a fluorescent protein under the choline-acetyltransferase (ChAT) promoter, for targeting the cholinergic audio-vestibular efferent neurons in the brainstem. It was found that the mouse model is useful for targeting the vestibular efferents, which are fluorescent, but not the auditory efferents, which are not highlighted. This model enables, for the first time, physiological studies of the vestibular efferent neurons and their synaptic inputs. We next assessed the expression of the potassium channel family Kv4, known to generate transient potassium currents upon depolarization. Such potassium currents are found in auditory efferent neurons, but it is not known whether Kv4 subunits are expressed in these neurons. Moreover, it is not known if Kv4 is present and has a function in the vestibular efferent neurons. Double labelling with anti-ChAT and anti-Kv4.2 or Kv4.3 demonstrates that the Kv4.3 subunits are abundantly expressed in audio-vestibular efferents, thus indicating that this subunit is a large contributor to the excitability and firing properties of the auditory efferent neurons, and most probably also for the vestibular efferent neurons. In addition, we also unexpectedly found a strong expression of Kv4.3 in principal cells of the superior olive, the neurons which are important for sound localization. Vestibular efferents olivocochlear efferents principal cells GFP ChAT superior olivary complex Kv4.3 transient outward current A-type current Biochemistry and Molecular Biology Biokemi och molekylärbiologi Neurosciences Neurovetenskaper Natural Sciences Naturvetenskap Neurosciences Neurovetenskaper

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