In a landmark study published in Nature Neuroscience, researchers have uncovered a striking division of labor within the brain’s endocannabinoid system, revealing that two prominent endogenous cannabinoids distinctly signal to different cell types in the adult mouse hippocampus—neurons and astrocytes. This discovery not only challenges the conventional understanding of how the endocannabinoid system modulates synaptic transmission and plasticity but also opens new avenues for exploring cell-specific pathways in neural regulation.
The endocannabinoid system, a major neuromodulatory network in the brain, has long been recognized for its role in regulating a broad spectrum of physiological processes including appetite, pain sensation, mood, and memory. At the heart of this system lie two principal endogenous ligands: 2-arachidonoylglycerol (2-AG) and anandamide (AEA). Both interact with the cannabinoid receptor type 1 (CB1R), but until now, the functional significance of having two native ligands operating through a single receptor remained enigmatic.
Diving deep into the hippocampus—a key brain region responsible for learning and memory—the new research elucidates how 2-AG and AEA distinctly influence synaptic circuits. Specifically, 2-AG robustly depresses synaptic transmission directly by activating CB1 receptors located on presynaptic neurons. This signaling cascade leads to a reduction in neurotransmitter release, serving as a classical inhibitory feedback mechanism to fine-tune neuronal communication.
Conversely, AEA leverages a more nuanced pathway, preferentially engaging CB1 receptors situated on astrocytes, the star-shaped glial cells traditionally considered supportive elements in the brain. Activation of astrocytic CB1Rs by AEA instigates a unique form of lateral synaptic potentiation, effectively enhancing synaptic strength in neighboring neuronal pathways. Such a mechanism introduces an indirect, spatially expansive form of synaptic modulation that complements the direct neuronal inhibition executed by 2-AG.
The dual signaling pathways mediated by these cannabinoids represent more than just parallel modes of communication—they embody a sophisticated system where one endogenous ligand tailors synaptic activity through neuronal inhibition, and the other fosters synaptic plasticity via astrocytic modulation. This bipartite signaling yields a delicate balance between synaptic depression and potentiation, vital for maintaining neural circuit stability and adaptability.
One of the most compelling insights from the study is the discovery that AEA-mediated activation of astrocytes is essential for spike-timing-dependent long-term potentiation (tLTP) in the hippocampus, a fundamental process underpinning learning and memory formation. Unlike 2-AG, which primarily contributes to synaptic suppression, AEA’s signaling to astrocytes facilitates the strengthening of synaptic connections when neural firing patterns align in a temporally precise manner—a hallmark of plasticity and cognitive flexibility.
The findings also challenge the traditional neuron-centric view of cannabinoid signaling, spotlighting the crucial role astrocytes play as active participants in synaptic modulation rather than passive bystanders. This paradigm shift acknowledges astrocytes as key cellular actors equipped with their own CB1 receptors responding selectively to anandamide, thereby reshaping the landscape of endocannabinoid neuroscience.
From a molecular standpoint, the receptor-specific and cell-type-specific signaling mechanisms suggest that 2-AG and AEA trigger distinct intracellular pathways upon binding CB1Rs, influenced by the cellular milieu of neurons versus astrocytes. Such divergence could explain the differing outcomes on synaptic transmission observed in the study and invites further research into the downstream signaling cascades tailored by each ligand-receptor interaction.
Moreover, the work highlights the spatial organization of endocannabinoid signaling within the synaptic microenvironment. The selective targeting of neuronal CB1Rs by 2-AG aligns with its role as a retrograde messenger that directly modulates presynaptic neurotransmitter release. In contrast, AEA’s astrocytic signaling pathway expands the reach of endocannabinoid modulation, affecting multiple neighboring synapses and potentially coordinating network-level plasticity.
This research carries profound implications not only for basic neuroscience but also for clinical domains. Understanding how distinct endocannabinoids selectively influence neuron-astrocyte interactions could offer novel therapeutic targets for neurological disorders characterized by synaptic dysfunction, including epilepsy, neurodegenerative diseases, and mood disorders.
The delineation of separate signaling roles for 2-AG and AEA also encourages a reevaluation of cannabinoid-based pharmacotherapies. The design of selective modulators that target either neuronal or astrocytic CB1 receptors could yield drugs with improved efficacy and fewer side effects, tailored to either inhibit or enhance specific synaptic functions.
In conclusion, the study by Noriega-Prieto and colleagues redefines the complexity of the brain’s endocannabinoid system by demonstrating how two endogenous ligands act in a highly selective, cell-type-dependent manner to orchestrate opposing yet complementary synaptic processes. This refined understanding sets the stage for future investigations into the intricate cellular dialogues that underpin brain function and offers fertile ground for translational research aimed at harnessing endocannabinoid pathways for therapeutic benefit.
As neuroscience continues to unravel the countless layers of brain communication, the discovery that 2-AG and anandamide distinctly signal to neurons and astrocytes respectively reasserts the multifaceted nature of plasticity and synaptic control. It underscores the sophistication of neuronal networks where different cell types and molecular signals coalesce to maintain cognitive processes essential to life.
This breakthrough invites a new appreciation of the brain’s glial components and the versatility of endocannabinoid signaling, providing fresh perspectives on how neural circuits are dynamically regulated in the adult hippocampus and potentially across other brain regions where CB1 receptors are expressed.
The discovery that AEA and 2-AG are not simply redundant ligands but instead engage unique cellular targets to produce functionally divergent outcomes challenges long-standing dogma. It compels the research community to reconsider cannabinoid signaling as a multifactorial system with tailored paths rather than a uniform mode of neurotransmission.
Building on these insights, future research is poised to explore how alterations in 2-AG and AEA signaling contribute to pathophysiological conditions, including the potential for astrocyte-specific endocannabinoid pathways as novel therapeutic entries in brain diseases where synaptic plasticity is disrupted.
Ultimately, the study heralds a new era in endocannabinoid science, where the fine-tuned dialogue between neurons and astrocytes is acknowledged as a cornerstone of synaptic health and cognitive function, promising exciting developments in brain research and medicine.
Subject of Research: The distinct signaling roles of endogenous cannabinoids 2-AG and anandamide on neurons and astrocytes in the adult mouse hippocampus.
Article Title: Distinct endocannabinoids specifically signal to astrocytes or neurons in the adult mouse hippocampus
Article References:
Noriega-Prieto, J.A., Falcón-Moya, R., Noeker, J.A. et al. Distinct endocannabinoids specifically signal to astrocytes or neurons in the adult mouse hippocampus. Nat Neurosci (2025). https://doi.org/10.1038/s41593-025-02148-1
Image Credits: AI Generated
DOI: https://doi.org/10.1038/s41593-025-02148-1
Tags: 2-arachidonoylglycerol role in synaptic transmissionanandamide effects on neuronal activityastrocytes and neurons communicationcannabinoid receptor type 1 signalingcell-specific pathways in brain regulationdistinct signaling mechanisms in brain cellsendocannabinoid system in brain functionendogenous cannabinoids and neurological researchhippocampus neural pathwaysneuromodulation in learning and memoryneurotransmitter release and inhibitionsynaptic plasticity and endocannabinoids
