2005
DOI: 10.1152/ajpregu.00647.2004
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Adenosine and ATP-sensitive potassium channels modulate dopamine release in the anoxic turtle (Trachemys scripta) striatum

Abstract: Excessive dopamine (DA) is known to cause hypoxic/ischemic damage to mammalian brain. The freshwater turtle Trachemys scripta, however, maintains basal striatal DA levels in anoxia. We investigated DA balance during early anoxia when energy status in the turtle brain is compromised. The roles of ATP-sensitive potassium (K(ATP)) channels and adenosine (AD) receptors were investigated as these factors affect DA balance in mammalian neurons. Striatal extracellular DA was determined by microdialysis with HPLC in t… Show more

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Cited by 21 publications
(22 citation statements)
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“…Facultative anaerobes are evolutionarily adapted to withstand long periods without oxygen; anoxia survival tolerance of at least several hours has been established in the fruit fly D. melanogaster (Wingrove and O'Farrell, 1999;Haddad, 2006) while some turtles can withstand anoxia for days to months (Ultsch, 2006). These anoxia-tolerant organisms, in contrast to mammalian systems, enter a state of deep reversible hypometabolism, thereby losing neural function but maintaining a balance between energy requirements and supply by suppressing energy-demanding functions, including the release of excitatory neurotransmitters (Milton et al, 2002;Milton and Lutz, 2005) and ion flux (Sick et al, 1982;Perez-Pinzon et al, 1992;Bickler et al, 2000), which together suppress electrical activity (Fernandes et al, 1997;Gu and Haddad, 1999). Anoxia tolerance then permits survival of extended anoxia without neuronal deficit (Haddad, 2006;Kesaraju et al, 2009).…”
Section: Discussionmentioning
confidence: 99%
“…Facultative anaerobes are evolutionarily adapted to withstand long periods without oxygen; anoxia survival tolerance of at least several hours has been established in the fruit fly D. melanogaster (Wingrove and O'Farrell, 1999;Haddad, 2006) while some turtles can withstand anoxia for days to months (Ultsch, 2006). These anoxia-tolerant organisms, in contrast to mammalian systems, enter a state of deep reversible hypometabolism, thereby losing neural function but maintaining a balance between energy requirements and supply by suppressing energy-demanding functions, including the release of excitatory neurotransmitters (Milton et al, 2002;Milton and Lutz, 2005) and ion flux (Sick et al, 1982;Perez-Pinzon et al, 1992;Bickler et al, 2000), which together suppress electrical activity (Fernandes et al, 1997;Gu and Haddad, 1999). Anoxia tolerance then permits survival of extended anoxia without neuronal deficit (Haddad, 2006;Kesaraju et al, 2009).…”
Section: Discussionmentioning
confidence: 99%
“…However, NMDA-receptor (NMDAR)-dependent excitotoxicity is also suppressed by δ-opioid receptors (Pamenter and Buck, 2008) which exist at surprisingly high density in the turtle brain (Xia and Haddad, 2001), and aid resistance to glutamate and hypoxic stress in mammals (Zhang et al, 2000). AMPA receptor currents, meanwhile, are also reduced by activation of mitochondrial ATP-dependent K + channels (Zivkovic and Buck, 2010), which in turn also reduce glutamate and dopamine release in early anoxia (Milton and Lutz, 2005;Milton et al, 2002). In longer anoxic exposures, glutamate release is suppressed by adenosine and GABA (Thompson et al, 2007).…”
Section: Ion Channels and Neurotransmittersmentioning
confidence: 99%
“…In longer anoxic exposures, glutamate release is suppressed by adenosine and GABA (Thompson et al, 2007). Adenosine in turn affects channel arrest (Pék and Lutz, 1997;Pérez-Pinzón et al, 1993), dopamine release (Milton and Lutz, 2005;Milton et al, 2002), NMDAR currents (Buck and Bickler, 1998) and cerebral blood flow (Hylland et al, 1994). …”
Section: Ion Channels and Neurotransmittersmentioning
confidence: 99%
“…The 52% decrease in anoxic AMPA receptor currents, for example, is abolished by mitochondial K ATP (mK ATP ) antagonists [31], as is the 50% decrease in anoxic NMDAR currents [32]. The reduced efflux of K + in early anoxia is also mediated in part by the opening of K ATP channels [33], and blocking K ATP together with adenosine receptor blockade increases both Glu and DA release in the early anoxic turtle brain [26,27]. As ATP demand is suppressed to meet reduced energy delivery, however, ATP levels return to basal, K ATP channels close and other mechanisms function to maintain reduced brain function, including the aforementioned GABA increases [34] and an upregulation of protective pathways.…”
Section: Adaptations For Anoxic Survival In the Brain Of The Turtle Tmentioning
confidence: 99%