Effect of adenosine on short-term synaptic plasticity in mouse piriform cortex in vitro: adenosine acts as a high-pass filter

Perrier, Simon P.; Gleizes, Marie Pierre; Fonta, Caroline; Nowak, Lionel G.

doi:10.14814/phy2.13992

Cited by 10 publications

(18 citation statements)

References 126 publications

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“…Exogenous adenosine can also be used to increase the adenosine concentration, Yuan et al found that the effect of preconditioning with adenosine on brain ischemic tolerance in rats. Perrier et al think that the main effects of adenosine were to decrease neurotransmitter release probability and to attenuate short‐term depression mechanisms. But this use is relatively rare, and it needs to be further examined.…”

Section: Discussionmentioning

confidence: 99%

Research progress on adenosine in central nervous system diseases

et al. 2019

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As an endogenous neuroprotectant agent, adenosine is extensively distributed and is particularly abundant in the central nervous system (CNS). Under physiological conditions, the concentration of adenosine is low intra‐ and extracellularly, but increases significantly in response to stress. The majority of adenosine functions are receptor‐mediated, and primarily include the A1, A2A, A2B, and A3 receptors (A1R, A2AR, A2BR, and A3R). Adenosine is currently widely used in the treatment of diseases of the CNS and the cardiovascular systems, and the mechanisms are related to the disease types, disease locations, and the adenosine receptors distribution in the CNS. For example, the main infarction sites of cerebral ischemia are cortex and striatum, which have high levels of A1 and A2A receptors. Cerebral ischemia is manifested with A1R decrease and A2AR increase, as well as reduction in the A1R‐mediated inhibitory processes and enhancement of the A2AR‐mediated excitatory process. Adenosine receptor dysfunction is also involved in the pathology of Alzheimer's disease (AD), depression, and epilepsy. Thus, the adenosine receptor balance theory is important for brain disease treatment. The concentration of adenosine can be increased by endogenous or exogenous pathways due to its short half‐life and high inactivation properties. Therefore, we will discuss the function of adenosine and its receptors, adenosine formation, and metabolism, and its role for the treatment of CNS diseases (such as cerebral ischemia, AD, depression, Parkinson's disease, epilepsy, and sleep disorders). This article will provide a scientific basis for the development of novel adenosine derivatives through adenosine structure modification, which will lead to experimental applications.

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Section: Discussionmentioning

confidence: 99%

Research progress on adenosine in central nervous system diseases

et al. 2019

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“…Expression of A 1 receptors and ecto 5′-nucleotidases has been found in the piriform cortex, pointing to a role of adenosine in neuromodulation (Goodman and Synder, 1982; Trieu et al, 2015). The main targets of adenosinergic modulation in the piriform cortex are excitatory synaptic inputs in pyramidal cell dendrites (Rezvani et al, 2007; Yang et al, 2007; Trieu et al, 2015; Perrier et al, 2019). The somata of pyramidal cells reside in layer II/III of the piriform cortex, while their apical dendritic arbors extend into the superficial layer I (Figure 5B).…”

Section: Purinergic Signaling In the Olfactory Cortexmentioning

confidence: 99%

“…The low ambient adenosine concentration at layer Ib synapses results from slow ATP-to-adenosine conversion due to low abundance of ecto 5′-nucleotidase and lack of synaptic ensheathment by glial cell processes, which provide one major source of ATP in the cortex (Haberly and Behan, 1983; Nevill and Haberly, 2004; Pankratov and Lalo, 2015; Trieu et al, 2015; Yi et al, 2017). Synapses between lateral olfactory tract fibers and pyramidal cell dendrites in layer Ia are not only depressed by adenosine, but can also be facilitated dependent on the frequency of synaptic activation (Perrier et al, 2019). While adenosine has no effect on the amplitude of fEPSP evoked by a train of stimuli at frequencies between 3 and 25 Hz, it strongly facilitates fEPSP at frequencies between 50 and 100 Hz (Perrier et al, 2019).…”

Section: Purinergic Signaling In the Olfactory Cortexmentioning

confidence: 99%

“…Synapses between lateral olfactory tract fibers and pyramidal cell dendrites in layer Ia are not only depressed by adenosine, but can also be facilitated dependent on the frequency of synaptic activation (Perrier et al, 2019). While adenosine has no effect on the amplitude of fEPSP evoked by a train of stimuli at frequencies between 3 and 25 Hz, it strongly facilitates fEPSP at frequencies between 50 and 100 Hz (Perrier et al, 2019). Since the entire range of stimulation frequencies used in that study reflects frequencies naturally occurring during odor perception depending on, e.g., odor concentrations, adenosine might fine-tune odor perception in an intensity-dependent manner.…”

Section: Purinergic Signaling In the Olfactory Cortexmentioning

confidence: 99%

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Purinergic Signaling in the Vertebrate Olfactory System

Rotermund

Schulz

Hirnet

et al. 2019

Front. Cell. Neurosci.

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Adenosine 5′-triphosphate (ATP) is an ubiquitous co-transmitter in the vertebrate brain. ATP itself, as well as its breakdown products ADP and adenosine are involved in synaptic transmission and plasticity, neuron-glia communication and neural development. Although purinoceptors have been demonstrated in the vertebrate olfactory system by means of histological techniques for many years, detailed insights into physiological properties and functional significance of purinergic signaling in olfaction have been published only recently. We review the current literature on purinergic neuromodulation, neuron-glia interactions and neurogenesis in the vertebrate olfactory system.

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“…Under normal circumstances, extracellular adenosine, a byproduct of neuronal ATP-driven vesicle release, establishes an inhibitory tone on synaptic terminals expressing the A1 adenosine receptor and provides negative feedback to active synapses. 10 Interestingly, when the authors delivered an adenosine receptor antagonist to sprouted mossy fiber slices from the brains of epileptic mice, they saw no effect on the evoked postsynaptic current. Thus, they concluded that the sprouted mossy fiber synapse lacks the normal inhibitory tone mediated by adenosine, thereby enabling a higher release probability.…”

Section: Commentarymentioning

confidence: 99%