Table Info

Table 3.

Mechanisms of purinergic signaling in neuron-astrocyte-microglia interactions

Mechanism	Cell types involved	Key receptors	Function/Role	References
Purinergic signaling in brain homeostasis	Astrocytes, microglia, neurons	P2 receptors (P2Y1, P2Y12), A1Rs, A2ARs	Purinergic signaling regulates synaptic pruning, neuroprotection, maintaining brain development, and homeostasis	[75, 138, 139]
Neuron-astrocyte communication for homeostasis	Neurons and astrocytes	P2X, P2Y, A1Rs, A2ARs	Bidirectional communication: neurons release neurotransmitters causing Ca²⁺ changes in astrocytes, which release ATP to modulate synaptic activity and maintain brain homeostasis	[44, 140, 141]
ATP in synaptic transmission	Neurons and astrocytes	P2XRs, NMDA receptors, A1Rs, A2ARs	ATP mediates excitatory neurotransmission; P2XRs regulate synaptic plasticity, with roles in both LTP and synaptic depression	[44, 142, 143]
Astrocytic ATP release and synaptic regulation	Astrocytes and neurons	P2X, P2Y, A1Rs, A2ARs	Astrocytes release ATP, influencing synaptic excitability, ion balance, and synaptic plasticity through interaction with adenosine receptors (A1Rs, A2ARs)	[44, 144, 145]
Adenosine receptor interactions	Astrocytes and neurons	A1Rs, A2ARs	A2ARs enhance NMDA receptor activity and glutamate release, while A1Rs inhibit synaptic transmission, offering neuroprotective effects	[42, 146, 147]
ATP and calcium (Ca²⁺)-mediated communication	Astrocytes	P2Y, P2X	ATP activates purinergic receptors (P2X, P2Y) to induce Ca²⁺ increases in astrocytes, propagating Ca²⁺ waves that influence synaptic modulation	[148–150]
Neurovascular coupling and redox homeostasis	Astrocytes and blood vessels	A1Rs, A2ARs	Astrocytes regulate blood flow and redox balance in response to neuronal activity, utilizing ATP and adenosine signaling	[151, 152]
Reactive astrocytes in injury	Astrocytes	A1Rs, A2ARs	During injury, ATP and adenosine modulate astrocytic responses: A1Rs suppress excessive excitation; A2ARs promote synaptic facilitation and inflammation	[153, 154]
Microglial activation and neuroinflammatory responses	Microglia	P2X4, P2Y12, A2AR	ATP activates microglia through P2X and P2Y receptors, initiating immune responses; P2X4Rs mediate pro-inflammatory responses, while P2Y12Rs guide microglial migration	[155–157]
Adenosine modulation of microglial inflammation	Microglia	A2AR	Adenosine via A2ARs counterbalances ATP-induced activation of microglia, reducing inflammation and promoting neuroprotection	[157–160]
Astrocyte-microglia crosstalk during injury	Astrocytes and microglia	P2Y1, P2Y12	ATP release from damaged cells activates purinergic receptors on both astrocytes and microglia, amplifying the inflammatory response and modulating synaptic activity	[37, 75, 80]

LTP: long-term potentiation

Declarations

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