Dissertations / Theses on the topic 'Whole Cell Voltage Clamp'

Pannexins are vertebrate proteins with limited sequence homology to the invertebrate gap junction proteins, the innexins. However, in contrast to innexins and the vertebrate connexins, pannexins do not form gap junction channels. Instead they appear to solely function as unpaired membrane channels allowing the flux of molecules, including ATP, across the plasma membrane. We provided additional evidence for their ATP release function by demonstrating that the connexin mimetic peptides, which were thought to inhibit ATP release through connexin channels, do not inhibit their host connexin channels but instead inhibit pannexin1 channels by a mechanism of steric block. Therefore, the inhibitory effects of mimetic peptides on ATP release may represent supporting evidence for a role of pannexin1 in ATP release. We also analyzed the pore structure of pannexin1 channels with the Substituted Cysteine Accessibility Method. The thiol reagents MBB and MTSET reacted with several positions in the external portion of the first transmembrane segment and the first extracellular loop. In addition, MTSET reactivity was found in the internal portion of TM3. These data suggest that portions of TM1, E1 and TM3 line the pore of pannexin1 channels. Thus, the pore structure of pannexin1 is similar to that of connexin channels.

Whole-cell patch clamp electrophysiology of neurons in vivo enables the recording of electrical events in cells with great precision, and supports a wide diversity of morphological and molecular analysis experiments important for the understanding of single-cell and network functions in the intact brain. However, high levels of skill are required in order to perform in vivo patching, and the process is time-consuming and painstaking. Robotic systems for in vivo patching would not only empower a great number of neuroscientists to perform such experiments, but would also open up fundamentally new kinds of experiment enabled by the resultant high throughput and scalability. We discovered that in vivo blind whole cell patch clamp electrophysiology could be implemented as a straightforward algorithm and developed an automated robotic system that was capable of performing this algorithm. We validated the performance of the robot in both the cortex and hippocampus of anesthetized mice. The robot achieves yields, cell recording qualities, and operational speeds that are comparable to, or exceed, those of experienced human investigators. Building upon this framework, we developed a multichannel version of “autopatcher” robot capable establishing whole cell patch clamp recordings from pairs and triplets of neurons in the cortex simultaneously. These algorithms can be generalized to control arbitrarily large number of electrodes and the high yield, throughput and automation of complex set of tasks results in a practical solution for conducting patch clamp recordings in potentially dozens of interconnected neurons in vivo.

1. The electrical characteristics of the cell body of an identified excitatory motoneurone (cell 3) from the cockroach (Periplaneta americana) have been studied under current- and voltage-clamp. 2. Under voltage-clamp depolarising command pulses evoked an outward current which increased with the magnitude of the command step up to approximately +100mV, a component of the current developed more slowly and took longer to reach a maximum. With increasing depolarisation the outward current response fell to a lower level before further increasing. This current response gave rise to a characteristic N-shape I-V relationship. The position of the negative conductance region depends on the time current measurements are taken after the onset of the command pulse. 3. Externally applied cadmium (1mM) or manganese ions (5mM) abolished the slowly developing current responsible for the hump in the I-V relationship. These results indicate that calcium ions are required for the activation of this component of the outward current. Verapamil (50?M) also reduced this current component and appeared to be non-specific in reducing another current component. Furthermore, verapamil caused inactivation of the remaining current which was more marked for long duration (500ms) command pulses. 4. Externally applied TEA+ (at concentrations greater than 25mM) blocked the calcium-dependent current and a calcium-independent component. Under current-clamp TEA+ (50mM) unmasked a broad action potential. 5. Externally applied aminopyridines did not enhance excitability under current-clamp. Under voltage-clamp aminopyridines had significant effect in shifting the voltage dependence of the hump in the I-V relationship toward more negative potentials. 6. When holding at -90mV and stepping to more positive potentials there was no indication of an early, fast, transient component similar to IA. If present at all, IA made only a minor contribution to the total outward currents. 7. A double command pulse regime was used to study tail currents whereby a standard pre-pulse (pulse (I)) was immediately followed by a test pulse (pulse (II)) to various command potentials. Tail current measurements were taken during pulse (II). The tail currents showed strong outward rectification and were severely reduced in saline containing cadmium ions (ImM). 8. The tail-current reversal potential was dependent on the pulse (I) magnitude and duration. Preliminary results indicated that increasing the pulse (I) magnitude caused a negative shift in reversal potential. Increasing the pulse (I) duration from 10ms to 50ms caused a positive shift in the reversal potential equivalent to a two-fold increase in extracellular cation concentration. 9. A five-fold increase (from 3.1 to 15mM) in external potassium ion concentration produced a small and variable shift in reversal potential, which did not conform to that predicted by the Nernst equation. A five-fold decrease (from 235 to 47mM) in external chloride ion concentration had little effect on the tail current reversal potential but did cause a slight reduction in the outward currents. Furthermore, the voltage dependency of the hump in the I-V relationship was shifted toward more negative potentials. 10. Action potentials induced by intracellular citrate injection were only slightly enhanced by a four-fold increase (from 9 to 36mM) in external calcium ion concentration. They were reversibly reduced to a graded spike in saline containing verapamil (10?M) and reversibly abolished by manganese ions (40mM), but were relatively unaffected by sodium-free saline. These observations suggest that calcium ions were the major ion carrying the inward current under these conditions. 11. Carbon dioxide-induced action potentials were reversibly reduced to a graded spike in sodium-free or manganese saline (40mM) whereas tetrodotoxin (50nM) irreversibly abolished action potentials for wash period up to 20mins. These observations suggest that both calcium and sodium ions were responsible for the inward current under these conditions. 12. The regenerative component of the axotomy-induced action- potentials was reversibly reduced in sodium-free saline and only partially reduced with some broadening in calcium-free or manganese saline (40mM). Either treatment alone was insufficient to completely abolish or reduce the action potential to a graded spike. A combination of Na-free saline with manganese ions (40mM) caused a more complete block by reducing the regenerative component to a graded spike. These results suggest that sodium ions, and to a lesser extent, calcium ions were responsible for the inward current under these conditions.

L'etude des cellules vestibulaires de type i et ii isolees a partir des canaux semi-circulaires de cobaye en configuration whole cell clamp nous a permis de mettre en evidence et de caracteriser d'une part sur les cellules de type ii, un courant potassique i#k, un courant potassique calcium dependant et des phenomenes de resonance membranaire. Sur les cellules de type i, nous avons caracterise un courant potassique active au repos (i#k#v#i), un courant entrant potassique s'activant lors d'hyperpolarisations membranaires (i#i#r) et un courant majoritairement potassique et faiblement calcique s'inversant entre 60 mv et 40 mv. D'autre part, les cellules de type i presentent des mouvements reversibles affectant leur apex. Ces mouvements ont pu etre induits lors de stimulations chimiques, mecaniques ou electriques. Ces differentes proprietes ioniques et mecaniques suggerent des modalites specifiques du traitement de l'information par ces deux types de cellules

Ion channels play a critical role in maintaining homeostasis by moving various ions in and out of cells. The Na+-K+-2Cl- or NKCC1 ion channel is involved in the regulation of Na+, K+, and Cl- across cell membranes, and plays a key role in many forms of cellular physiology. In the cochlea, NKCC1 is involved in endolymph production and maintenance of the endocochlear potential. Our hypothesis is that blocking NKCC1 channels should directly impact auditory sensitivity causing hearing loss. Our lab has also shown that the hormone aldosterone (ALD) can upregulate NKCC1 protein expression in vitro and in vivo. In the present investigation, we use electrophysiology and molecular biology techniques to study the biophysical mechanisms underlying the action of ALD in vitro on NKCC1 in the SH-SY5Y cell line. Our initial protein expression studies using RT-PCR found that proteins specific to NKCC1channels were present in SH-SY5Y neuronal cells. Whole cell currents measured using patch clamp methodology, were used to analyze the effects of various compounds on NKCC1 in the SH-SY5Y cell line. Control data were collected under perfusion of extracellular solution (ECS), then ECS containing 10µM bumetanide was applied, and, finally a washout condition completed the experiment. Similar experiments were conducted using ALD, and we observed an increase in K+ currents when bumetanide as well as when ALD was applied. This is the first report that indicates that ALD can directly regulate K+ channels in SH-SY5Y cells.

The aim of this thesis was to study the effects of extremely low frequency (ELF) electromagnetic magnetic fields on potassium currents in neural cell lines ( Neuroblastoma SK-N-BE ), using the whole-cell Patch Clamp technique. Such technique is a sophisticated tool capable to investigate the electrophysiological activity at a single cell, and even at single channel level. The total potassium ion currents through the cell membrane was measured while exposing the cells to a combination of static (DC) and alternate (AC) magnetic fields according to the prediction of the so-called ‘ Ion Resonance Hypothesis ’. For this purpose we have designed and fabricated a magnetic field exposure system reaching a good compromise between magnetic field homogeneity and accessibility to the biological sample under the microscope. The magnetic field exposure system consists of three large orthogonal pairs of square coils surrounding the patch clamp set up and connected to the signal generation unit, able to generate different combinations of static and/or alternate magnetic fields. Such system was characterized in term of field distribution and uniformity through computation and direct field measurements. No statistically significant changes in the potassium ion currents through cell membrane were reveled when the cells were exposed to AC/DC magnetic field combination according to the afore mentioned ‘Ion Resonance Hypothesis’.

Nesse estudo investigamos os efeitos da hipóxia tecidual aguda (HA) sobre as propriedades eletrofisiológicas intrínsecas dos neurônios pré-simpáticos bulboespinhais da área rostro-ventrolateral do bulbo (RVLM) de ratos jovens adultos submetidos previamente à hipóxia crônica intermitente (HCI) e os seus respectivos controle. Para marcarmos os neurônios pré-simpáticos bulboespinhais da RVLM, ratos Wistar jovens (P19-P21) anestesiados com ketamina e xilazina, receberam microinjeções bilaterais de rodamina, um traçador fluorescente retrógrado, na coluna intermediolateral da medula espinhal (T3-T6) e 2 dias após a recuperação da cirurgia, os animais foram submetidos ao protocolo de HCI, enquanto que ratos controle foram mantidos em condições de normóxia, durante 10 dias. No décimo primeiro dia, os ratos foram novamente anestesiados para a remoção do cérebro e as fatias do tronco cerebral contendo neurônios pré-simpáticos com marcação positivas foram registrados. Utilizamos a técnica de whole cell patch-clamp para estudo das propriedades eletrofisiológicas desses neurônios. As propriedades eletrofisiológicas intrínsecas foram analisadas antes e após a HA, a qual foi produzida pela perfusão das fatias do tronco cerebral com uma solução hipóxica (95% N2 + 5% CO2) durante 2 minutos na presença de bloqueadores sinápticos excitatórios e inibitórios. Todos os neurônios pré-simpáticos apresentaram característica intrínseca de autodespolarização e a frequência de disparos basal de potenciais de ação (PAs) desses neurônios de ratos do grupo controle e HCI foram similares [Controle= 5,03 ± 0,4 Hz (n=39) vs HCI= 6,31 ± 0,7 Hz (n=31); p > 0,05]. No grupo controle, a HA não alterou a frequência média de disparos de PAs (BS = 5,03 ± 0,4 Hz vs HA = 5,24 ± 0,3 Hz (n=39); p > 0,05], porém revelou diferentes perfis de disparo de PAs após 2 min de exposição à HA: i) 11 neurônios com aumento na frequência de disparos (BS = 5,1 ± 0,7 Hz vs HA = 7 ± 0,7 Hz; p < 0,05]; ii) 21 neurônios sem alteração na frequência de disparos (BS = 4,8 ± 0,5 Hz vs HA = 5,36 ± 0,6 Hz; p > 0,05] e iii) 7 neurônios com diminuição na frequência de disparos (BS = 7,3 ± 1,1 Hz vs HA = 3,6 ± 0,7 Hz; p < 0,05). No grupo HCI, a HA produziu aumento na frequência média de disparos (BS= 6,31 ± 0,7 Hz vs HA= 7,25 ± 0,8 Hz; n=31 - p < 0,05) e na análise do perfil de disparo de PAs, a HA revelou 2 subpopulações: i) 9 neurônios com aumento na frequência de disparos (BS = 4,7 ± 0,8 Hz vs HA = 8,2 ± 1,4 Hz; p < 0,05) e ii) 22 neurônios sem alteração na frequência de disparos (BS = 7,0 ± 1,0 Hz vs HA = 6,8 ± 1,0 Hz; p > 0,05). Esse estudo nos permitiu revelar diferentes subpopulações de neurônios pré-simpáticos que responderam de forma distintas à HA. Os resultados também sugerem que a HCI teria um efeito pré- condicionante na excitabilidade intrínseca dos neurônios pré-simpáticos em resposta à HA
In this study we evaluated the effects of acute hypoxia (AH) on the intrinsic electrophysiological properties of presympathetic neurons from rostro ventrolateral medulla (RVLM) of juvenile rats exposed to chronic intermittent hypoxia (CIH) or normoxic condition (control group). To label the RVLM bulbospinal presympathetic neurons, young Wistar rats (P 19 - 21) anesthetized with ketamine and xylazine, received bilateral microinjections of a fluorescent retrograde tracer (rhodamine retrobeads) were performed into the intermediolateral column of spinal cord (T3-T6) and two days after recovery of the surgery, the animals were submitted to CIH or normoxic protocol, during 10 days. On the 11th day, under anesthesia, brainstem slices were obtained and only the labeled RVLM presympathetic neurons were recorded, using whole-cell patch-clamp approach to study the electrophysiological properties of these neurons. The intrinsic electrophysiological properties were analyzed before and after AH, which was produced by slice perfusion with hypoxic solution (95% N2 and 5% CO2) during 2 min in the presence of excitatory and inhibitory synaptic antagonists. All recorded RVLM presympathetic neurons presented intrinsic pacemaker activity and the baseline firing frequency of these neurons from control and CIH group were similar [Control= 5,03 ± 0,4 Hz (n=39) vs HCI= 6,31 ± 0,7 Hz (n=31); p > 0,05]. In the control group, AH do not change the firing rate (BS = 5,03 ± 0,4 Hz vs HA = 5,24 ± 0,3 Hz (n=39); p > 0,05), but revealed different pattern of firing frequency after 2 min of AH: i) 11 neurons increased the firing frequency (BS = 4,9 ± 0,9 Hz vs HA = 6,9 ± 1,0 Hz; p < 0,05) ; ii) 21 neurons do not change the firing frequency (BS = 4,8 ± 0,5 Hz vs HA = 5,36 ± 0,6 Hz; p > 0,05) and iii) 7 neurons decreased the firing frequency (BS = 7,3 ± 1,1 Hz vs HA = 3,6 ± 0,7 Hz; p < 0,05). In the CIH group, the AH increased the firing rate comparing with basal condition (SB= 6,31 ± 0,7 Hz vs AH= 7,25 ± 0,8 Hz; n=31 - p < 0,05) and analyzing the pattern of action potential, AH revealed 2 subpopulations in this group: i) 9 neurons increased the firing frequency (SB = 4,7 ± 0,8 Hz vs AH = 8,2 ± 1,4 Hz; p < 0,05) and ii) 22 neurons do not change the firing frequency (SB = 7,0 ± 1,0 Hz vs AH = 6,8 ± 1,0 Hz; p > 0,05).. The data shows that AH revealed different subpopulations of presympathetic neurons and suggest that CIH plays a preconditioning in the intrinsic excitability of presympathetic neurons in response to acute hypoxia

This diploma thesis deals with study of the rate-dependence of the magnitude of a current through the heart channel that conducts slowly activating component of delayed rectifier outward current (IKs). This property is very important for the IKs channel function. When other repolarizing currents are insufficient, but also when the heart rate accelerates, especially during elevated sympathetic tone, IKs provides so-called repolarization reserve, which prevents excessive lengthening of cardiac action potential repolarization. The IKs channel structure is encoded by the KCNQ1 (pore-forming -subunit) and KCNE1 (modulatory -subunit) genes. Mutations in these genes disrupt the physiological function of the IKs channel and cause inherited arrhythmogenic syndromes, especially long QT syndrome (LQTS). Such mutations include the c.926C>T (p.T309I) mutation in the KCNQ1 gene, which results in LQTS type 1 in heterozygous carriers. The theoretical part of the thesis provides basic information about the IKs channel and the patch clamp technique, this knowledge is necessary for the practical part. The experimental part is focused on cultivation of the CHO cell line and its transient transfection for subsequent electrophysiological measurements by whole-cell patch clamp technique to study the dependence of the IKs magnitude on stimulation frequency, both in the wild type channels (i.e. without mutation) and in those with cotransfected wild type and T309I subunits.

Neuronal nicotinic acetylcholine receptors (nAChRs) are expressed in both the periperhal and central nervous systems, and are involved in pre-, post-, and non-synaptic control of neuronal activation. In the brain, these receptors play an important role in a variety of physiological processes such as cognition, development, learning, and memory formation. Malfunction of these receptors have been implicated in neurodegenerative diseases like Alzheimer's disease (AD), schizophrenia, and Parkinson's disease. To date, 17 different nAChR subunits, including α2-α7 and β2-β4, have been cloned that can form homo- and/or hetero-pentameric ionotropic receptors. The unique combinations of subunit pentamers manifest in distinct functional receptors. Using single-cell real-time quantitative RT-PCR, we identified the individual expression rates and co-expression rates of the different nAChR subunits in rat CA1 hippocampal interneurons in efforts to characterize functional receptors involved in learning and memory. The two-way combination of subunits with highest expression in hippocampal interneurons was α3β2. Moreover, this combination was expressed in ratios near 1:3 or 3:1 α3 to β2 respectively. To investigate the functionality of α3β2 receptors in different stoichiometries, we injected human α3 and rat β2 subunit mRNA in 1:3, 1:1, and 3:1 ratios into Xenopus laevis oocytes for expression. Two-electrode voltage clamp was then performed with the application of different concentrations of ACh to produce full dose-response curves and channel kinetics data. Distinct α3β2 functional channels were identified from the different expression ratios based on significant differences in channel kinetics (i.e.- peak current rise times, peak current decay times, steady state current in forced desensitization) Dose-response curves produced no significant difference in EC50 values in the different expression groups. However, there was a trend to greater agonist sensitivity with increased α3 expression relative to β2. α3β2 receptors were further characterized through forced desensitization of the receptors and generation of IV plots. The findings from this study elucidate the neuronal nAChR subunit combinations that form functional channels in hippocampal interneurons.

A key function of the nervous system is to sample data from the external world, generate internal signals, and transform them into meaningful information that can be used to trigger behaviour. In order to gain insight into the underlying mechanism for signal transformation, the visual system has been extensively studied: partly owing to the stimulus being reliably presentable, and the anatomy being well described. The Drosophila visual system is one such system, with the added advantage of genetic tractability. In this thesis, I studied the filtering property of visual neurons at two levels, biophysical and circuit levels. The first study looks at signal transformation at the biophysical level, at the input of the visual system, in photoreceptors. Voltage-gated potassium channels counteract the depolarization caused by opening of light sensitive channels, and the heterogeneous properties of their kinetics can fine-tune the photoreceptor’s frequency response to fulfill the animal’s ecological requirements. Shaker (Kv1) and Shab (Kv2) have been identified as fast and slow inactivating components of the photoreceptor’s outward currents, however a current with intermediate kinetics (IKf) has not been molecularly identified, but had been postulated to be Shal (Kv4). I focused on characterizing this current using whole-cell patch clamp in wild type and mutants, and using antibodies for Shal. My results from whole-cell patch clamp indicated that IKf in adult R1-6 cells are not Shal, from their voltage dependence and insensitivity to a Kv4 blocker. This calls for alternative molecular basis for IKf, which is likely to be a slow inactivating component of Shaker, or a combination of its many splice variants. The second study looks at signal transformation at the circuit level, at the output end, in the third optic neuropil, lobula. Visual projection neurons project from the lobula to the central brain, and have been proposed to carry behaviourally relevant visual features to higher brain regions. It was recently shown that optogenetic activation of individual visual projection neuron types could induce distinct behaviours such as takeoff and backward walking, linking these visual neurons to specific behavioural programs downstream. Using in vivo two-photon calcium imaging, I recorded visually evoked calcium responses from three of these cell types. Cell types that showed induced takeoff and backward walking preferentially responded to dark looming stimuli or fragmented expanding local features, suggesting their role in behaviours triggered by object approach. To explore how this visual information is transformed in the downstream circuit, we identified several candidate neurons that receive input from this cell type by anatomical overlap, and then validated their connections using optogenetic activation and calcium imaging. One downstream cell-type that projects bilaterally had very similar response properties to its upstream partner, whereas another cell-type that projects ipsilaterally seemed to filter out some information from its upstream partner. This is one of the first studies that functionally characterizes lobula visual projection neurons and their downstream partners in Drosophila, and their response properties agree with the general idea that visual information becomes increasingly selective as it is sent to higher brain regions.

Our senses are constantly bombarded with information. How does the brain integrate such a variety of inputs to generate appropriate behaviours? Innate defensive behaviours are a good model to address this question. They are essential for animal survival and the brain circuits that control them are highly conserved across species. Moreover, the sensory inputs and behavioural outputs can be well defined and reliably reproduced in the lab. This allows us to study function of the individual components of the circuit controlling these behaviours. Ventromedial hypothalamus (VMH) is a key brain region for controlling responses to predators; it has been shown that inactivating the VMH can reduce defensive behaviours. Interestingly, activating the VMH output neurons (SF1+ cells) can produce a variety of different behaviours, from immobility to escape, depending on the intensity of activation. During my PhD I used a variety of approaches to address the question of the function of the VMH in control of defensive behaviours. At first I hypothesised that the VMH might act as a centre responsible for choosing an appropriate behavioural response according to the stimulus. I set to investigate how different activation levels of SF1+ neurons can produce such different behavioural outputs, and how this activity is modulated in vivo in response to predator stimuli. I began the project by quantifying mouse defensive behaviours in response to olfactory and auditory predator cues, as well as to the optogenetic activation of SF1+ neurons. I then questioned whether there was heterogeneity within the population of SF1+ neurons, which could explain their ability to trigger different behaviours. I performed patch clamp recordings from acute brain slices and conducted a study of the electrophysiological properties of SF1+ neurons. I next investigated how SF1+ neurons integrate excitatory inputs from the medial amygdala, a region which receives olfactory inputs from the accessory olfactory bulb. By combining optogenetics with slice electrophysiology and behavioural assessment, I described the physiology and relevance of this connection. Finally, I investigated in vivo activity in the VMH in response to predator cues by performing calcium imaging of the VMH neurons in freely moving mice. By presenting different sensory stimuli, I addressed the question of heterogeneity of the input pattern to the VMH neurons and the relationship between the VMH activity and the behavioural output. Taken all together, the results of this project have led to a hypothesis whereby the function of the VMH is to facilitate rather than directly control the choice of an appropriate behavioural response.

Increases in basolateral amygdala (BLA) activity drive avoidance-seeking behavior that may be associated with stress induced drug seeking. Activity of BLA pyramidal neurons is regulated by local and paracapsular gamma aminobutyric acid (GABA) interneurons. The lateral paracapsular interneurons (LPCs) border the external capsule, receive dense cortical/thalamic input and provide feed-forward inhibition onto BLA principle neurons. The GABAergic LPCs also express high concentrations of g-protein coupled µ-opioid receptors (MORs). Therefore, the effects of opiates on LPC activity and local GABA release were examined. Fluorescently double labeled LPCs were observed in glutamate decarboxylase (GAD) 65-mcherry/GAD67-green fluorescent protein (GFP) transgenic mice. Whole-cell electrophysiology experiments demonstrated that acute exposure to [D-Ala2, N-Me-Phe4, Gly5-ol]-enkephalin (DAMGO; a synthetic selective MOR agonist), reduced LPC firing and spontaneous inhibitory postsynaptic current (sIPSC) frequency in LPCs, with no apparent effect on spontaneous excitatory currents (sEPSCs). Current injection induced firing in LPC neurons, but less effectively than in saline controls. Morphine-exposed mice (10mg/kg/day, across 5 days, 1-2 days off) had increased sIPSCs compared to saline-injected controls, as well as enhanced adenylyl cyclase (AC) activity. Together these data show that LPC neurons are a highly sensitive targets for opiate-induced inhibition, and that long-term opiate exposure results in impaired LPC excitability, possibly contributing to anxiety observed during opiate withdrawal.

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Coordenação de Aperfeiçoamento de Pessoal de Nível Superior - CAPES
It was been demonstrated that curine and reticuline, induced a vasodilator effect in the rat small mesenteric arteries through inhibition of voltage-gated Ca2+ channels (VGCC). These compounds, curine and reticuline were isolated from the root barks of Chondrondendron platyphyllum and Ocotea duckei Vattimo, respectively, therefore the aim of this work was to evaluate the vasodilator mechanism of curine and reticuline, bisbenzylisoquinoline alkaloids (BBA), isolated from the root barks of Chondrondendron platyphyllum and Ocotea duckei Vattimo, respectively, using functional and molecular approaches. Tension measurements in aorta rings, whole-cell patch-clamp and confocal techniques were employed to study the action of these alkaloids. The A7r5 smooth muscle derived cell line was used for Ca2+ currents measuring and the intracellular calcium concentration ([Ca2+]i) were evaluated using confocal microscopy. The main results are as follows: in aortic rings, curine (3 - 300 μM) antagonized KCl (60 mM) and Bay K8644 (3 x 10-7 M) induced contractions. In whole-cell configuration, curine reduced the voltage-activated peak amplitude of ICa,L in a concentration-dependent manner. However, the Ca+2 current density versus voltage relationship and maximal activation voltage of ICa,L were not changed. Moreover curine did not also affect the steady-state activation of ICa,L, but shifted the steady-state inactivation curve of ICa,L for more negative potentials, however this effect was not changed in the presence of IBMX, dbcAMP and 8-brcGMP, suggesting that cyclic mononucleotides, such as cAMP and cGMP, are not involved in curine effect. In confocal experiments, curine inhibited the rise on the [Ca2+]i induced by KCl (60 mM) in dispersed vascular smooth muscle cells. In reference to reticuline (3 300 μM) was verified that alkaloid agonized CaCl2 and KCl-induced contractions and elicited vasorelaxation in aortic rings. In whole-cell configuration, reticuline reduced the voltage-activated peak amplitude of ICa,L in a concentration-dependent manner, but did not change the characteristics of current density versus. voltage relationship. Reticuline shifted leftwards the steady-state inactivation curve of ICa,L, however this effect was not changed after application of dibutyryl cyclic adenosine monophosphate to the cell. In cells pretreated with forskolin, an adenylate cyclase activator, the addition of reticuline caused further inhibition of the Ca2+ currents suggesting an additive effect, indicating that cyclic mononucleotides were not involved. Taken together the results have shown that curine and reticuline elicits vasorelaxation due to the blockade of the L-type voltage-dependent Ca2+ current in rat aorta smooth muscle cells. The reported effect may contribute to the potential cardioprotective efficacy of curine and reticuline.
Curina e reticulina são alcalóides isolados das cascas do caule e raízes de Chondrondendron platyphyllum e de Ocotea duckei Vattimo, respectivamente. Estudos anteriores demonstraram que esses alcalóides são capazes de induzir efeito vasodilatador em artéria mesentérica e aorta de rato, respectivamente, devido possível inibição dos canais para Ca2+ dependentes de voltagem (VGCC). O objetivo deste trabalho foi investigar o mecanismo vasodilatador de curina e reticulina realizando experimentações funcionais e moleculares. Foram utilizadas medidas de tensão em anéis de aorta de rato, e empregadas técnicas de patch-clamp e de microscopia confocal para estudos da ação desses alcalóides. Também foram utilizadas células A7r5, uma linhagem de células musculares lisas embrionária derivada de aorta torácica de rato, que foram usadas para medir as correntes de Ca2+ macroscópicas e a concentração de cálcio intracelular ([Ca2+]i), que foram avaliadas usando a técnicas de patch-clamp e microscopia confocal, respectivamente. Os principais resultados são: em anéis de aorta, curina (3 - 300 μM) antagonizou as contrações induzidas por KCl (60 mM) e Bay K8644 (3 x 10-7 M). Na configuração whole-cell patch clamp , curina reduziu a amplitude da corrente de cálcio do tipo L (ICa,L) de maneira dependente de concentração. Porém, curina não alterou as características das correntes na relação corrente-voltagem. A voltagem de ativação máxima para ICa,L não foi diferente em relação ao controle. Além disso, curina também não afetou a ativação no estado estacionário das ICa,L, mas deslocou a curva da inativação estacionária para potenciais mais negativos. No entanto, esse efeito promovido por curina não foi alterado na presença de IBMX, dbcAMP e 8- brcGMP, sugerindo que os mononucleotídeos cíclicos, como APMc e GMPc, não estão envolvidos no efeito da curina. Em experimentos com microscopia confocal curina inibiu os transientes de cálcio intracelulares, e reduziu o aumento de [Ca2+]i induzidos por KCl (60 mM) em células de músculo liso vascular. Em relação à reticulina (3 300 μM), foi verificado que esse alcalóide antagonizou as contrações induzidas por CaCl2 e KCl, provocando vasorelaxamento em anéis de aorta. Na configuração whole-cell patch clamp , reticulina também reduziu a amplitude das ICa,L de maneira dependente de concentração, mas não mudou as características da corrente na relação corrente-voltagem. A reticulina deslocou para potenciais mais negativos a curva de inativação estacionária para as ICa,L. Porém, esse efeito não foi alterado após a aplicação de dbcAMP e 8-brcGMP. Em células pré-tradadas com forskolina, um ativador da adenilil ciclase, a adição da reticulina causou uma inibição adicional das correntes de Ca2+ que sugere um efeito aditivo da reticulina, indicando que os mononucleotídeos cíclicos não estão envolvidos. Dessa forma, curina e reticulina provocaram vasorelaxamento, devido ao bloqueio das correntes de Ca2+ dependentes de voltagem do tipo-L em células de músculo liso, em cultura e recémdispersas, de aorta de rato, revelando que esses alcalóides têm um importante potencial como modelo químico para a concepção e posterior desenvolvimento de novos fármacos com propriedade protetora cardiovascular.

Many cells in the inferior colliculus (IC) are excited by contralateral and inhibited by ipsilateral stimulation and are thought to be important for sound localization. These excitatory-inhibitory (EI) cells comprise a diverse group, even though they exhibit a common binaural response property. Previous extracellular studies proposed specific excitatory and/or inhibitory events that should be evoked by each ear and thereby generate each of the EI discharge properties. The proposals were inferences based on the well established response features of neurons in lower nuclei, the projections of those nuclei, their excitatory or inhibitory neurochemistry, and the changes in response features that occurred when inhibition was blocked. Here we recorded the inputs, the postsynaptic potentials, discharges evoked by monaural and binaural signals in EI cells with in vivo whole cell recordings from the inferior colliculus (IC) of awake bats. We also computed the excitatory and inhibitory synaptic conductances from the recorded sound evoked responses. First, we showed that a minority of EI cells either inherited their binaural property from a lower binaural nucleus or the EI property was created in the IC via inhibitory projections from the ipsilateral ear, features consistent with those observed in extracellular studies. Second, we showed that in a majority of EI cells ipsilateral signals evoked subthreshold EPSPs that behaved paradoxically in that EPSP amplitudes increased with intensity, even though binaural signals with the same ipsilateral intensities generated progressively greater spike suppressions. These ipsilateral EPSPs were unexpected since they could not have been detected with extracellular recordings. These additional responses suggested that the circuitry underlying EI cells was more complex than previously suggested. We also proposed the functional significance of ipsilaterally evoked EPSPs in responding to moving sound sources or multiple sounds. Third, by computing synaptic conductances, we showed the circuitry of the EI cells was even more complicated than those suggested by PSPs, and we also evaluated how the binaural property was produced by the contralateral and ipsilateral synaptic events.
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Background potassium currents play an important role in the regulation of the resting membrane potential and excitability of mammalian neurons. Recently cloned two- pore domain potassium channels (K2p) are believed to underlie these currents. The roles of K2P channels in general anesthesia and neuroprotection have been proposed recently. In view of this, we investigated the ability of trichloroethanol (an active metabolite of the non-volatile general anesthetic cldoral hydrate, widely used as a pediatric sedative) to modulate the activity of human TREK-1 and TRAAK channels. We found that trichloroethanol potently activates both hTREK-1 and hTRAAK channels at pharmacologically relevant concentrations. The parent compound chloral hydrate was also found to augtnent the activity of both the channels reversibly. Studies with carboxy- terminal deletion mutants (hTREK-1A89, hTREK-1 A100 and hTREK-1 A1 19), suggested that C-terminal tail is not essential for the activation of TREK-1 by trichloroethanol. Our findings identify TREK-1 and TRCL4K channels as molecular targets for trichloroethanol and we propose that activation of both these channels might contribute to the CNS depressant effects of chloral hydrate. Another channel TASK-2, which is essentially absent in the human brain was also found to be potently activated by both trichloroethanol and chloral hydrate. In another series of experiments, we studied the effects of methyl xanthines caffeine and theophylline on hTREK-1 channels. Caffeine and theophylline are used for therapeutic purposes and frequently cause life-threatening convulsive seizures due to systemic toxicity. The mechanisms for the epileptogenicity of caffeine and theophylline are not clear. Recent experiments using knockout mice provided direct evidence for a role for TREK-1 in the control of epileptogenesis. We hypothesized that the epileptogenicity of caffeine and theophylline may be related to the inhibition of TREK-1 channels. We investigated this possibility and observed massive inhibition of TREK-1 channels at toxicologically relevant concentrations. Experiments with the mutant TREK-1 channel (S348A mutant) suggested the involvement of cANP/PKA pathway in the inhibition of TREK-1 channels by caffeine and theophylline. We suggest that inhibition of TREK-1 channels may contribute to the convulsive seizures induced by toxic levels of caffeine and theophylline. Local anesthetics exhibit their clinical effects not only by binding to voltage-gated sodium channels, but also by interacting with other ion channels such as potassium channels. Because of the physiological significance of TREK-1 channels and their abundant expression in peripheral sensory neurons, we investigated the effects of lidocaine to see whether its interaction with 'REK-1 channels contribute to the conduction blockade. Lidocaine caused dose-dependent inhibition of TREK-1channels and the inhibition was voltage-independent. Cytoplasmic C-terminal tail is critically required for lidocaine action. Inhibition of TREK-1 channels is achieved at concentrations for iiz vivo action and this effect may have implications for the clinically observed drug action of lidocaine.

碩士
臺灣大學
動物學研究所
98
A growing number of reports have demonstrated that GABA acting on extrasynaptic GABAA receptors (GABAARs) exerts strong tonic inhibition in the target neurons, thereby controls the neuronal excitability. The cardiac vagal neurons (CVNs) in nucleus ambiguus (NA) is the principal motor neurons that control hart rate, and the noradrenergic (NAergic) A7 neurons are involved in modulating nociception by releasing noradrenaline in the dorsal spinal cord. It is proposed that GABA plays an important role in control excitability of CVNs (from NTS) and A7 neurons (from local GABAergic interneurons), these neurons receive very strong GABAergic inputs. In addition to phasic inhibitions mediated by GABAA and glycine receptors, evidences for existence of extrasynaptic GABAAR-mediated tonic inhibition in CVNs and A7 neurons have been provided. In this study, I wish to further characterize and compare what subunits of GABAARs are responsible to tonic GABAARs mediated current in these two nucleus. CVNs were retrograde-labeled by fluorescent tracer applied to pericardiac cavity in rats (P7-10 days). After surgery, the animals were allowed to survive for 48 hours and the transverse brainstem slices were cut. The fluorescent labeled CVNs were searched under fluorescent microscope and picked up by a grass pipette after electrophysiological experiments. They were lysed and the mRNA was extracted using Nanoprep Kit. Standard RT-PCR procedures were employed for analysis of expression profile of GABAAR subunits in CVNs. The procedure of A7 neurons were same as CVNs. They had a large somata diameter (~20 μm) located ~200 μm rostral to the trigeminal motor nucleus (the presumed A7 area) in sagittal brainstem slices in rats (P7-10 days). Since it has been reported that functional extrasynaptic GABAARs may consist of α1, α5, δ, γ1, γ2, and ε subunit, expression of these subunits was examined in both neurons. A total number of 77 fluorescent labeled CVNs and 33 A7 neurons were collected and subjected to GABAARs analysis. Only 35 of CVNs and 27 of A7 neurons expressed cholineacetyltransferase (ChAT) and dopamine beta-hydroxylase (DBH). In all of the CVNs, α1 subunits were detected mostly, α5, γ1, γ2, ε but less the δ subunits were also detected. The results of A7 neurons were similar as CVNs but the expression of γ2 subunits were also abundant. These results are consistent with our previously electrophysiological results, in which picrotoxin sensitive tonic GABAAR current was enhanced by zolpidem, an α1 and γ subunit agonist, and not by drug acting at α5 or δ subunits. Taken together, the present results suggest a role for α1 subunit in mediating tonic GABAAR-mediated inhibition in CVNs and A7 neurons.

This series of experiments investigated dystrophin localization in the normal cerebellum and examined Purkinje neuron function in normal and dystrophin-deficient mice to better understand the physiological basis for cognitive deficits associated with Duchenne muscular dystrophy (DMD), a common genetic disorder among children. Cognitive impairments are consistently reported in DMD, yet precise mechanisms for their occurrence are unknown. Dystrophin protein, which is absent in DMD, is normally localized to muscles and specific neurons in the brain. Purkinje neurons are rich in dystrophin, specifically in somatic and dendritic membranes. Studies demonstrate perturbed cerebellar function in the absence of dystrophin, suggesting that DMD should be regarded as a cerebellar disorder in addition to being considered a neuromuscular disorder. However, theory and evidence are not generated from overlapping information: research investigating cerebellar involvement in DMD has focused on the vermal region, associated with motor function. The lateral region, implicated in cognition, has not been explicitly examined in DMD. The first experiment revisited the issue of dystrophin distribution in the mouse cerebellum using immunohistochemistry to investigate qualitative and quantitative differences between cerebellar regions. Both regions showed dystrophin localized to Purkinje neuron somatic and dendritic membranes, but dystrophin density was 30% greater in the lateral than the vermal region. The second experiment examined intrinsic electrophysiological properties of vermal and lateral Purkinje neurons from wild-type (WT) mice and from the mdx mouse model of DMD which lack dystrophin. Significant differences in action potential firing frequency, regularity, and shape were found between cerebellar regions. Purkinje neurons from mdx mouse cerebellum exhibited membrane hyperpolarization and irregular action potential firing, regardless of region. Spontaneous action potential firing frequency was reduced in Purkinje neurons from lateral cerebellum in mdx mice relative to controls, demonstrating that a loss of dystrophin causes a potent dysregulation of Purkinje neuron function in the region associated with cognition. This research extends our understanding of cerebellar pathology in DMD and its potential relevance to cognitive deficits in the disorder. Moreover, this research further supports the role of the cerebellum as a structure important for cognition and contributes to our understanding of dystrophin’s role in the brain.

Clinical studies reported side effects of muscular spasms and muscle stiffness following the administration of clofibrate, a drug once used to treat hyperlipidaemia in patients. Experiments with clofibrate and its analogues in animal models showed it produced these myotonic symptoms in muscle by reducing the chloride conductance of the muscle membrane. The effects of 2-(4-chlorophenoxy)propionic acid, an analogue of clofibric acid, was assessed on the rat ClC-1 channel (rClC-1). Racemic 2-(4-chlorophenoxy)propionic acid shifted the voltage dependence of rClC-1 activation to more depolarising potentials, a mechanism accounting for myotonic symptoms previously reported. Experiments with resolved enantiomers revealed that the effects recorded were due exclusively to S-(–) 2-(4- chlorophenoxy)propionic acid. The R-(+) enantiomer was ineffective at the concentrations tested. Further experiments with the compound at differing Cl- concentrations in the extracellular solution suggested that S-(–) 2-(4-chlorophenoxy)propionic acid altered the gating of ClC-1 by decreasing the affinity of the binding site where Cl- normally acts to ‘gate’ the channel. Similarities in the effects reported for most dominant mutations in the CLCN1 gene that lead to myotonia congenita and 2-(4-chlorophenoxy)propionic acid prompted experiments that introduced these point mutations in the human ClC-1 (hClC-1) gene to compare their mode of action to that of the drug. These mutations, F307S and A313T, predominantly altered the slow, or common, gate of the channel. Conversely, the effect of 2-(4-chlorophenoxy)propionic acid was predominantly on the fast gating process of hClC-1. A macroscopically similar effect therefore, can be produced by two different modes of action. Results suggested that both drug and mutations exert their action by affecting the transition of the channel from its closed to open state subsequent to Cl- binding. Investigation of the interaction between rClC-1 gating and a further 25 compounds structurally related to clofibric acid identified a number of compounds effective at shifting the open probability of fast gating to depolarising potentials. Fewer were identified that influence slow gating. Some compounds affected both gating processes, however, none were identified which influenced slow gating alone. Ability to displace the voltage dependent activation of the fast gate appeared to depend largely on the lipophilicity of the molecules tested, indicating the importance of hydrophobic interactions between drug and channel protein.
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Thesis (Ph.D.) -- University of Adelaide, School of Molecular and Biomedical Science, 2009