Browsing by Subject "ATP"
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Item Calcium Signaling Mechanisms Mediate Clock-Controlled ATP Gliotransmission among Immortalized Rat SCN2.2 Cell Cultures(2010-10-12) Burkeen, Jeffrey FranklinThe hypothalamus is an integral part of the brain's regulation of mammalian physiology and behavior. Among many functions, this regulatory center activates the sympathetic nervous system, maintains appropriate body temperature, controls food intake, and controls release of hormones from the pituitary gland. Deep within the hypothalamus lie a paired cluster of cells, the suprachiasmatic nuclei (SCN), which function as the chief circadian pacemaker. The goal of the present thesis research was to study rhythmically controlled ATP gliotransmission. I used an immortalized SCN2.2 hypothalamic cell line to determine the mechanism by which ATP signaling is regulated in this context. Additionally, this research aimed to elucidate if clock-controlled ATP gliotransmission is fundamentally distinct from stimulus-evoked calcium-dependent mechanisms that regulate intercellular ATP signaling among astrocytes. In this thesis, I show that there are multiple ATP signaling mechanisms present among SCN2.2 cells. cAMP-dependent signaling mediates clock-controlled ATP accumulation but not stimulus-evoked ATP signaling. In addition, pharmacological studies suggest that disparate purinergic receptor-mediated mechanisms are involved in the regulation of clock-controlled versus stimulus-evoked ATP signaling. Rhythmic accumulation of ATP in SCN2.2 cultures is modulated by calcium-dependent processes. Peaks in ATP accumulation coincide with elevated mitochondrial calcium levels, while troughs in ATP accumulation coincide with periods of high cytosolic calcium levels, suggesting a possible mechanistic link between circadian shifts in intracellular calcium handling and ATP handling in SCN2.2 cells. Clock-controlled ATP accumulation in SCN2.2 cells is not a by-product of rhythmic cell cycle or rhythmic cell death. Overall, my research suggests that the ATP accumulation rhythm in SCN2.2 cells is likely an output of the biological clock, mediated by astrocytic calcium signaling processes, and not an output of cell division or cell death. Estimation of ATP accumulation in SCN2.2 cultures at peak time points suggests that clock-controlled ATP release is critical to the function of astrocytes in the mammalian brain, perhaps in the regulation of brain metabolism, the regulation of sleep/wake physiology, or the integration of both.Item Melatonin modulates intercellular communication among immortalized rat suprachiasmatic nucleus cells(2009-05-15) Cox, Kimberly YvonneThe mammalian brain contains a regulatory center in the diencephalic region known as the hypothalamus that plays a critical role in physiological homeostasis, and contains a variety of centers for behavioral drives, such as hunger and thirst. Located deep within the hypothalamus is the suprachiasmatic nucleus (SCN), or the master biological clock, that organizes rhythmic physiology and behavior, such that critical events take place at the most appropriate time of the day or night and in the most appropriate temporal, phase relationships. Cell-to-cell communication is essential for conveying inputs to and outputs from the SCN. The goal of the present study was to use an immortalized neural cell line (SCN2.2), derived from the presumptive anlage of the rat suprachiasmatic nucleus, as an in vitro model system to study intercellular communication among SCN cells. I tested whether the pineal neurohormone melatonin could modulate cell-to-cell signaling, via both dye coupling (gap junctional communication) and calcium waves (ATP-dependent gliotransmission). I also tested whether extracellular ATP could influence the spread of calcium waves in SCN2.2 cells. Lastly, the ability of extracellular ATP to modulate SCN physiological responses to melatonin in SCN2.2 cells was examined. I show that melatonin at a physiological concentration (nM) reduced dye coupling (gap junctional communication) in SCN2.2 cells, as determined by a scrape loading procedure employing the fluorescent dye lucifer yellow. Melatonin caused a significant reduction in the spread of calcium waves in cycling SCN2.2 cultures as determined by ratiometric calcium imaging with Fura-2 AM, a calcium sensitive indicator dye. This reduction was greatest when an endogenous circadian rhythm in extracellular ATP accumulation, determined by luciferase assay, was at its trough or lowest extracellular concentration. In addition, melatonin and ATP interacted in the regulation of gliotransmission (calcium waves), and this interaction was also specific to particular phases of the endogenous SCN physiological rhythmicity. Thus, I have established that a complex interaction exists between established melatonin signaling pathways and this newly discovered ATP accumulation rhythm, with the mechanisms underlying this relationship linked to endogenous cycling of SCN cellular physiology.Item Regulation and Synchronization of the Master Circadian Clock by Purinergic Signaling from Suprachiasmatic Nucleus Astrocytes(2012-10-19) Womac, Alisa DianeMolecular, cellular, and physiological processes within an organism are set to occur at specific times throughout the day. The timing of these processes is under control of a biological clock. Nearly all organisms on Earth have biological clocks, ranging from unicellular bacteria and fungi to multicellular plants, insects, reptiles, fish, birds, and mammals. The biological clock is an endogenous time-keeping mechanism that generates the onset of many processes and coordinates the phases of processes over 24 hours. While the biological clock allows these organisms to maintain roughly 24-hour, or circadian, timing in daily processes, many organisms have the ability to set their clocks, or entrain them, to changes in light. In mammals, the suprachiasmatic nucleus (SCN) is the master biological clock that entrains daily physiological and behavioral rhythms to the appropriate times of day and night. The SCN is located in the hypothalamus and contains thousands of neurons and glia that function in coordinating system-level physiological rhythms that are entrained to environmental light cues. Many of these neurons and glia are individual circadian oscillators, and the cellular mechanisms that couple them into ensemble oscillations are emerging. Adenosine triphosphate (ATP) is a transmitter involved in local communication among astrocytes and between astrocytes and neurons. ATP released from astrocytes may play a role in SCN cellular communication and synchrony. Extracellular ATP accumulated rhythmically in the rat SCN in vivo, and ATP released from rat SCN astrocytes in vitro was rhythmic, with a periodicity near 24 hours. ATP released from mouse SCN astrocytes was circadian, and disruption of the molecular clock abolished rhythmic extracellular ATP accumulation. SCN astrocyte cultures with disrupted molecular clocks also had marked reductions in total ATP accumulation compared to SCN astrocyte cultures with functional biological clocks. Furthermore, ATP-induced calcium transients were rhythmic, and this rhythmic purinergic sensitivity was abolished in clock mutant astrocytes. Pharmacological blockade of purinergic signaling, with antagonists of both the P2X7 and P2Y1 receptors, led to a gradual reduction in the amplitude of coordinated ATP accumulation over three days. These purinergic receptor antagonists, as expected, led to a reduction in calcium responses of SCN astrocytes to ATP and led to a dampening of clock gene expression rhythms as determined by PER2::LUC bioluminescence reporting in SCN astrocytes. These data demonstrate that astrocytes of the mammalian SCN rhythmically release ATP and are rhythmically sensitive to ATP in a manner dependent on their intrinsic molecular clock. Ensemble rhythmicity of SCN astrocytes is, in turn, dependent on that rhythmic purinergic signaling via both P2X and P2Y classes of ATP receptors. These results are indicative of a functional role for ATP accumulation within the SCN, with astrocytes releasing ATP every 24 hours for continual signaling onto astrocytes and neurons to maintain daily coordinated synchrony of the clocks in these cells.