Ken D. McCarthy

Astrocytic neurotransmitter receptors in situ and in vivo

In the brain, astrocytes are associated intimately with neurons and surround synapses. Due to their close proximity to synaptic clefts, astrocytes are in a prime location for receiving synaptic information from released neurotransmitters. Cultured astrocytes express a wide range of neurotransmitter receptors, but do astrocytes in vivo also express neurotransmitter receptors and, if so, are the receptors activated by synaptically released neurotransmitters? In recent years, considerable efforts has gone into addressing these issues. The experimental results of this effort have been compiled and are presented in this review. Although there are many different receptors which have not been identified on astrocytes in situ, it is clear that astrocytes in situ express a number of different receptors. There is evidence of glutamatergic, GABAergic, adrenergic, purinergic, serotonergic, muscarinic, and peptidergic receptors on protoplasmic, fibrous, or specialized (Bergmann glia, pituicytes, Müller glia) astrocytes in situ and in vivo. These receptors are functionally coupled to changes in membrane potential or to intracellular signaling pathways such as activation of phospholipase C or adenylate cyclase. The expression of neurotransmitter receptors by astrocytes in situ exhibits regional and intraregional heterogeneity and changes during development and in response to injury. There is also evidence that receptors on astrocytes in situ can be activated by neurotransmitter(s) released from synaptic terminals. Given the evidence of extra-synaptic signaling and the expression of neurotransmitter receptors by astrocytes in situ, direct communication between neurons and astrocytes via neurotransmitters could be a widespread form of communication in the brain which may affect many different aspects of brain function, such as glutamate uptake and the modulation of extracellular space.

What Is the Role of Astrocyte Calcium in Neurophysiology

Astrocytes comprise approximately half of the volume of the adult mammalian brain and are the primary neuronal structural and trophic supportive elements. Astrocytes are organized into distinct nonoverlapping domains and extend elaborate and dense fine processes that interact intimately with synapses and cerebrovasculature. The recognition in the mid 1990s that astrocytes undergo elevations in intracellular calcium concentration following activation of G protein-coupled receptors by synaptically released neurotransmitters demonstrated not only that astrocytes display a form of excitability but also that astrocytes may be active participants in brain information processing. The roles that astrocytic calcium elevations play in neurophysiology and especially in modulation of neuronal activity have been intensely researched in recent years. This review will summarize the current understanding of the function of astrocytic calcium signaling in neurophysiological processes and discuss areas where the role of astrocytes remains controversial and will therefore benefit from further study.

Control of gap-junctional communication in astrocytic networks

Astrocytes, which constitute the most abundant cell type in mammalian brain, are extensively coupled to one another through gap junctions composed mainly of connexin43. In regions exhibiting high levels of connexin43 expression, tens of astrocytes are labeled following single-cell intracellular injection. Importantly, both the expression and the permeability of gap junctions are tightly regulated. Such long- and short-term regulations indicate that astrocytic networks might be subject to remodeling and to some plasticity. Since evidence for neuro-glial interaction exists, the degree of coupling between astrocytes could participate to set the tone of neuronal activity and to determine the sphere of influenced neurons. Research in this area is still at its early stages and significant progress requires a transition from the understanding of basic properties to the study of function.

Conditional Knock-Out of Kir4.1 Leads to Glial Membrane Depolarization, Inhibition of Potassium and Glutamate Uptake, and Enhanced Short-Term Synaptic Potentiation

During neuronal activity, extracellular potassium concentration ([K+]out) becomes elevated and, if uncorrected, causes neuronal depolarization, hyperexcitability, and seizures. Clearance of K+ from the extracellular space, termed K+ spatial buffering, is considered to be an important function of astrocytes. Results from a number of studies suggest that maintenance of [K+]out by astrocytes is mediated by K+ uptake through the inward-rectifying Kir4.1 channels. To study the role of this channel in astrocyte physiology and neuronal excitability, we generated a conditional knock-out (cKO) of Kir4.1 directed to astrocytes via the human glial fibrillary acidic protein promoter gfa2. Kir4.1 cKO mice die prematurely and display severe ataxia and stress-induced seizures. Electrophysiological recordings revealed severe depolarization of both passive astrocytes and complex glia in Kir4.1 cKO hippocampal slices. Complex cell depolarization appears to be a direct consequence of Kir4.1 removal, whereas passive astrocyte depolarization seems to arise from an indirect developmental process. Furthermore, we observed a significant loss of complex glia, suggestive of a role for Kir4.1 in astrocyte development. Kir4.1 cKO passive astrocytes displayed a marked impairment of both K+ and glutamate uptake. Surprisingly, membrane and action potential properties of CA1 pyramidal neurons, as well as basal synaptic transmission in the CA1 stratum radiatum appeared unaffected, whereas spontaneous neuronal activity was reduced in the Kir4.1 cKO. However, high-frequency stimulation revealed greatly elevated posttetanic potentiation and short-term potentiation in Kir4.1 cKO hippocampus. Our findings implicate a role for glial Kir4.1 channel subunit in the modulation of synaptic strength.

Intracellular Astrocyte Calcium Waves In Situ Increase the Frequency of Spontaneous AMPA Receptor Currents in CA1 Pyramidal Neurons

Spontaneous neurotransmitter release and activation of group I metabotropic glutamate receptors (mGluRs) each play a role in the plasticity of neuronal synapses. Astrocytes may contribute to short- and long-term synaptic changes by signaling to neurons via these processes. Spontaneous whole-cell AMPA receptor (AMPAR) currents were recorded in CA1 pyramidal cells in situ while evoking Ca2+ increases in the adjacent stratum radiatum astrocytes by uncaging IP3. Whole-cell patch clamp was used to deliver caged IP3 and the Ca2+ indicator dye Oregon green BAPTA-1 to astrocytes. Neurons were patch-clamped and filled with Alexa 568 hydrazide dye to visualize their morphological relationship to the astrocyte. On uncaging of IP3, astrocyte Ca2+ responses reliably propagated as a wave into the very fine distal processes, synchronizing Ca2+ activity within astrocyte microdomains. The intracellular astrocyte Ca2+ wave coincided with a significant increase in the frequency of AMPA spontaneous EPSCs, but with no change in their kinetics. AMPAR current amplitudes were increased as well, but not significantly (p = 0.06). The increased frequency of AMPAR currents was sensitive to the group I mGluR antagonists LY367385 and 2-methyl-6-(phenylethynyl)-pyridine, suggesting that (1) astrocytes released glutamate in response to IP3 uncaging, and (2) glutamate released by astrocytes activated group I mGluRs to facilitate the release of glutamate from excitatory neuronal presynaptic boutons. These results extend previous studies, which have shown astrocyte modulation of neuronal activity in vitro and suggest that astrocyte-to-neuron signaling in intact tissue may contribute to synaptic plasticity.

Selective Stimulation of Astrocyte Calcium In Situ Does Not Affect Neuronal Excitatory Synaptic Activity

Astrocytes are considered the third component of the synapse, responding to neurotransmitter release from synaptic terminals and releasing gliotransmitters--including glutamate--in a Ca(2+)-dependent manner to affect neuronal synaptic activity. Many studies reporting astrocyte-driven neuronal activity have evoked astrocyte Ca(2+) increases by application of endogenous ligands that directly activate neuronal receptors, making astrocyte contribution to neuronal effect(s) difficult to determine. We have made transgenic mice that express a Gq-coupled receptor only in astrocytes to evoke astrocyte Ca(2+) increases using an agonist that does not bind endogenous receptors in brain. By recording from CA1 pyramidal cells in acute hippocampal slices from these mice, we demonstrate that widespread Ca(2+) elevations in 80%-90% of stratum radiatum astrocytes do not increase neuronal Ca(2+), produce neuronal slow inward currents, or affect excitatory synaptic activity. Our findings call into question the developing consensus that Ca(2+)-dependent glutamate release by astrocytes directly affects neuronal synaptic activity in situ.

Loss of IP3 Receptor-Dependent Ca2+ Increases in Hippocampal Astrocytes Does Not Affect Baseline CA1 Pyramidal Neuron Synaptic Activity

Astrocytes in the hippocampus release calcium (Ca2+) from intracellular stores intrinsically and in response to activation of Gq-linked G-protein-coupled receptors (GPCRs) through the binding of inositol 1,4,5-trisphosphate (IP3) to its receptor (IP3R). Astrocyte Ca2+ has been deemed necessary and sufficient to trigger the release of gliotransmitters, such as ATP and glutamate, from astrocytes to modulate neuronal activity. Several lines of evidence suggest that IP3R type 2 (IP3R2) is the primary IP3R expressed by astrocytes. To determine whether IP3R2 is the primary functional IP3R responsible for astrocytic Ca2+ increases, we conducted experiments using an IP3R2 knock-out mouse model (IP3R2 KO). We show, for the first time, that lack of IP3R2 blocks both spontaneous and Gq-linked GPCR-mediated increases in astrocyte Ca2+. Furthermore, neuronal Gq-linked GPCR Ca2+ increases remain intact, suggesting that IP3R2 does not play a major functional role in neuronal calcium store release or may not be expressed in neurons. Additionally, we show that lack of IP3R2 in the hippocampus does not affect baseline excitatory neuronal synaptic activity as measured by spontaneous EPSC recordings from CA1 pyramidal neurons. Whole-cell recordings of the tonic NMDA receptor-mediated current indicates that ambient glutamate levels are also unaffected in the IP3R2 KO. These data show that IP3R2 is the key functional IP3R driving Gq-linked GPCR-mediated Ca2+ increases in hippocampal astrocytes and that removal of astrocyte Ca2+ increases does not significantly affect excitatory neuronal synaptic activity or ambient glutamate levels.

Astroglial Gap Junction Communication Is Increased by Treatment with Either Glutamate or High K+ Concentration

Abstract: Astroglia are extensively coupled by gap junctions and form a functional syncytium. Astroglial gap junctions are thought to be involved in the spatial buffering of K+ in vivo and in the Ca2+ waves seen on glutamate receptor activation. The conductivity of gap junctions is regulated by several second messengers, with up‐regulation by cyclic AMP and down‐regulation through activation of protein kinase C, decreases in intracellular pH, or increases in the free cytosolic Ca2+ concentration. The results presented here indicate that dye coupling of astroglia is significantly up‐regulated by membrane depolarization, both by increases in the extracellular K+ concentration and directly by ionophores. Furthermore, glutamate, kainate, and quisqualate, which depolarize astroglial cells through activation of ionotropic receptors, also increase dye coupling in astroglia. The effect of kainate and quisqualate was reversed by 6‐cyano‐7‐nitroquinoxaline‐2,3‐dione, an inhibitor of the ionotropic glutamate receptor. A dose‐dependent decrease in dye coupling was seen when the cells were injected with increasing concentrations of Ca2+. However, if the cells were simultaneously depolarized, the inhibitory effect of Ca2+ on gap junctional conductance was reversed. Significant increases over basal coupling was attained when the cells were injected with Ca2+ if they were treated with kainate or K+. These data suggest that ligands that depolarize astroglia enhance gap junction communication between astroglia and that this enhancement may be important in maintaining communication between astroglia in the face of elevated Ca2+ levels.

Activation of Protein Kinase C Blocks Astroglial Gap Junction Communication and Inhibits the Spread of Calcium Waves

Abstract: The following two processes related to astrocytes are thought to depend on intercellular coupling through gap junctions: the spatial buffering of K+o and the spread of calcium waves in the astrocytic syncytium. We have used the following two independent methods to measure the open state of gap junctions: injection of lucifer yellow, and optical calcium imaging of calcium waves in response to probing the cells with a micropipette. The spread of lucifer yellow and calcium waves was inhibited if the cells were treated with either phorbol 12‐myristate 13‐acetate (PMA) or a synthetic diacylglycerol that activates protein kinase C. Down‐regulation of protein kinase C by a 24‐h treatment with PMA inhibited the uncoupling effect of PMA, supporting a direct involvement of protein kinase C in the regulation of astroglial gap junctions. Purinergic P2Y receptors, which are coupled to the inositol phospholipid pathway, are expressed by most astroglia in culture. Activation of the P2Y purinergic receptor with the selective agonist 2‐methylthio‐ATP uncoupled astroglia in a manner similar to the effect of treatment with PMA. Modulation of gap junctional conductance could isolate specific pathways within the astrocytic syncytium to form an extraneuronal information transfer network in brain.

Engineering GPCR signaling pathways with RASSLs

We are creating families of designer G protein–coupled receptors (GPCRs) to allow for precise spatiotemporal control of GPCR signaling in vivo. These engineered GPCRs, called receptors activated solely by synthetic ligands (RASSLs), are unresponsive to endogenous ligands but can be activated by nanomolar concentrations of pharmacologically inert, drug-like small molecules. Currently, RASSLs exist for the three major GPCR signaling pathways (Gs, Gi and Gq). We review these advances here to facilitate the use of these powerful and diverse tools.