A Time Course Analysis of the Electrophysiological Properties of Neurons Differentiated from Human Induced Pluripotent Stem Cells (iPSCs)

Many protocols have been designed to differentiate human embryonic stem cells (ESCs) and human induced pluripotent stem cells (iPSCs) into neurons. Despite the relevance of electrophysiological properties for proper neuronal function, little is known about the evolution over time of important neuronal electrophysiological parameters in iPSC-derived neurons. Yet, understanding the development of basic electrophysiological characteristics of iPSC-derived neurons is critical for evaluating their usefulness in basic and translational research. Therefore, we analyzed the basic electrophysiological parameters of forebrain neurons differentiated from human iPSCs, from day 31 to day 55 after the initiation of neuronal differentiation. We assayed the developmental progression of various properties, including resting membrane potential, action potential, sodium and potassium channel currents, somatic calcium transients and synaptic activity. During the maturation of iPSC-derived neurons, the resting membrane potential became more negative, the expression of voltage-gated sodium channels increased, the membrane became capable of generating action potentials following adequate depolarization and, at day 48–55, 50% of the cells were capable of firing action potentials in response to a prolonged depolarizing current step, of which 30% produced multiple action potentials. The percentage of cells exhibiting miniature excitatory post-synaptic currents increased over time with a significant increase in their frequency and amplitude. These changes were associated with an increase of Ca²⁺ transient frequency. Co-culturing iPSC-derived neurons with mouse glial cells enhanced the development of electrophysiological parameters as compared to pure iPSC-derived neuronal cultures. This study demonstrates the importance of properly evaluating the electrophysiological status of the newly generated neurons when using stem cell technology, as electrophysiological properties of iPSC-derived neurons mature over time.     

GABAA Receptors Modulate Early Spontaneous Excitatory Activity in Differentiating P19 Neurons

Abstract: P19 embryonic carcinoma (EC) stem cells are pluripotent and are efficiently induced to differentiate into neurons and glia with retinoic acid (RA) treatment. Within 5 days, a substantial number of differentiating P19 cells express gene products that are characteristic of a neuronal phenotype. P19 neurons were used as a model to explore the relationship between neuronal “differentiation” in vitro and the acquisition of γ-aminobutyric acid (GABA_A) receptors and functional GABA responses. Pulse-labeling experiments using bromodeoxyuridine indicated that all neurons had become postmitotic within 3–4 days after treatment with RA. This was confirmed by a reduction in the immunocytochemical detection of the undifferentiated stem cell antigen SSEA-1. Subsequently, a transient expression of nestin was observed during the first 5 days in vitro (DIV) after exposure to RA. By 5–10 DIV after RA, a significant number of neurons (～80–90%) expressed immunocytochemically detectable glutamate decarboxylase and GABA coincident with the acquisition of membrane binding sites for tetanus toxin. These phenotypic markers were maintained for >30 DIV after RA. Under current-clamp conditions, random, low-amplitude, spontaneous electrical activity appeared in neurons within the first few days after RA treatment and this was blocked by the specific GABA_A receptor antagonist bicuculline. Thereafter, the appearance and progressive increases in the frequency of spontaneous action potentials in P19 neurons were observed that were similarly attenuated by bicuculline. In neurons > 5 DIV after RA, exogenous application of GABA elicited similar action potentials. The onset of excitatory responses to GABA or muscimol in voltage-clamped neurons appeared immediately after the cessation of neuronal mitosis and before the previously reported acquisition of responses to glutamate. In fura-2 imaging studies, the exogenous application of GABA resulted in neuron-specific increases in intracellular Ca²⁺. Thus, P19 neurons provide an in vitro model for the study of the early acquisition and properties of electrical excitability to GABA and the expression of functional GABA_A receptors.     

Spontaneous calcium transients in the immature adult-born neurons of the olfactory bulb

Spontaneous neuronal activity and concomitant intracellular Ca²⁺ signaling are abundant during early perinatal development and are well known for their key role in neuronal proliferation, migration, differentiation and wiring. However, much less is known about the in vivo patterns of spontaneous Ca²⁺ signaling in immature adult-born cells. Here, by using two-photon Ca²⁺ imaging, we analyzed spontaneous in vivo Ca²⁺ signaling in adult-born juxtaglomerular cells of the mouse olfactory bulb over the time period of 5 weeks, from the day of their arrival in the glomerular layer till their stable integration into the preexisting neural network. We show that spontaneous Ca²⁺ transients are ubiquitously present in adult-born cells right after their arrival, require activation of voltage-gated Na⁺ channels and are little sensitive to isoflurane anesthesia. Interestingly, several parameters of this spontaneous activity, such as the area under the curve, the time spent in the active state as well as the fraction of continuously active cells show a bell-shaped dependence on cell’s age, all peaking in 3–4 weeks old cells. This data firmly document the in vivo presence of spontaneous Ca²⁺ signaling during the layer-specific maturation of adult-born neurons in the olfactory bulb and motivate further analyses of the functional role(s) of this activity.     

Astrocyte calcium microdomains are inhibited by Bafilomycin A1 and cannot be replicated by low-level Schaffer collateral stimulation in situ

Astrocyte Gq GPCR and IP₃ receptor-dependent Ca²⁺ elevations occur spontaneously in situ and in vivo. These events vary considerably in size, often remaining confined to small territories of astrocyte processes called “microdomains” and sometimes propagating over longer distances that can include the soma. It has remained unclear whether these events are driven by constitutive (basal) GPCR signaling activity, neuronal action potential-dependent or quantal vesicular release, or some combination of these mechanisms. Here, we applied manipulations to increase or inhibit neuronal vesicular neurotransmitter release together with low-level stimulation of Schaffer collaterals in acute mouse hippocampal slices in an effort to determine the mechanisms underlying spontaneous astrocyte Ca²⁺ events. We found no significant change in spontaneous microdomain astrocyte Ca²⁺ elevations when neuronal action potentials were significantly enhanced or blocked. The astrocyte Ca²⁺ activity was also not affected by inhibitors of group I mGluRs. However, blockade of miniature neurotransmitter release using Bafilomycin A1 significantly reduced the frequency of microdomain astrocyte Ca²⁺ elevations. We then tested whether astrocyte Ca²⁺ microdomains can be evoked by low intensity SC stimulation. Importantly, microdomains could not be reproduced even using single, low intensity pulses to the SCs at a minimum distance from the astrocyte. Evoked astrocyte Ca²⁺ responses most often included the cell soma, were reduced by group I mGluR antagonists, and were larger in size compared to spontaneous Ca²⁺ microdomains. Overall, our findings suggest that spontaneous microdomain astrocyte Ca²⁺ elevations are not driven by neuronal action potentials but require quantal release of neurotransmitter which cannot be replicated by stimulation of Schaffer collaterals.     

Early neural development in vertebrates is also a matter of calcium

The calcium (Ca²⁺) signaling pathways have crucial roles in development from fertilization through differentiation to organogenesis. In the nervous system, Ca²⁺ signals are important regulators for various neuronal functions, including formation and maturation of neuronal circuits and long-term memory. However, Ca²⁺ signals are mainly involved in the earliest steps of nervous system development including neural induction, differentiation of neural progenitors into neurons, and the neuro-glial switch. This review examines when and how Ca²⁺ signals are generated during each of these steps with examples taken from in vivo studies in vertebrate embryos and from in vitro assays using embryonic and neural stem cells. Also discussed is the highly specific nature of the Ca²⁺ signaling pathway and its interaction with the other signaling pathways involved in early neural development.     

Regulation of later neurogenic stages of adult‐derived neural stem/progenitor cells by L‐type Ca2+ channels

In the adult hippocampus, new neurons are continuously generated and incorporated into the local circuitry in a manner dependent on the network activity. Depolarization evoked by neurotransmitters has been assumed to activate L‐type Ca²⁺ channels (LTCC) which regulate the intracellular Ca²⁺‐dependent signaling cascades. The process of neurogenesis contains several stages such as proliferation, fate determination, selective death/survival and maturation. Here, we investigated which stage of neurogenesis is under the regulation of LTCC using a clonal line of neural stem/progenitor cells, PZ5, which was derived from adult rat hippocampus. Although undifferentiated PZ5 cells were type 1‐like cells expressing both nestin and glial fibrillary acidic protein, they generated neuronal, astrocytic and oligodendrocytic populations in differentiation medium containing retinoic acid. Proliferation of undifferentiated PZ5 cells was dependent on neither the LTCC antagonist, nimodipine (Nimo) nor the LTCC agonists, Bay K 8644 (BayK) or FPL 64176 (FPL), whereas the fraction of neuronal population that expressed both βIII‐tubulin and MAP2 was reduced by Nimo but increased by BayK or FPL. At an earlier period of differentiation (e.g. day 4), the fraction of PZ5 cells expressing HuC/D, pan‐neuronal marker, was not affected either by the LTCC activation or inhibition. At a later period of differentiation (e.g. day 9), the fraction of dying neurons was decreased by LTCC activation and increased by LTCC inhibition. It is suggested that the LTCC activation facilitates the survival and maturation of immature neurons, and that its inhibition facilitates the neuronal death.     

Reprogramming of HUVECs into Induced Pluripotent Stem Cells (HiPSCs), Generation and Characterization of HiPSC-Derived Neurons and Astrocytes

Neurodegenerative diseases are characterized by chronic and progressive structural or functional loss of neurons. Limitations related to the animal models of these human diseases have impeded the development of effective drugs. This emphasizes the need to establish disease models using human-derived cells. The discovery of induced pluripotent stem cell (iPSC) technology has provided novel opportunities in disease modeling, drug development, screening, and the potential for “patient-matched” cellular therapies in neurodegenerative diseases. In this study, with the objective of establishing reliable tools to study neurodegenerative diseases, we reprogrammed human umbilical vein endothelial cells (HUVECs) into iPSCs (HiPSCs). Using a novel and direct approach, HiPSCs were differentiated into cells of central nervous system (CNS) lineage, including neuronal, astrocyte and glial cells, with high efficiency. HiPSCs expressed embryonic genes such as nanog, sox2 and Oct-3/4, and formed embryoid bodies that expressed markers of the 3 germ layers. Expression of endothelial-specific genes was not detected in HiPSCs at RNA or protein levels. HiPSC-derived neurons possess similar morphology but significantly longer neurites compared to primary human fetal neurons. These stem cell-derived neurons are susceptible to inflammatory cell-mediated neuronal injury. HiPSC-derived neurons express various amino acids that are important for normal function in the CNS. They have functional receptors for a variety of neurotransmitters such as glutamate and acetylcholine. HiPSC-derived astrocytes respond to ATP and acetylcholine by elevating cytosolic Ca²⁺ concentrations. In summary, this study presents a novel technique to generate differentiated and functional HiPSC-derived neurons and astrocytes. These cells are appropriate tools for studying the development of the nervous system, the pathophysiology of various neurodegenerative diseases and the development of potential drugs for their treatments.     

Cell adhesion and intracellular calcium signaling in neurons

Cell adhesion molecules (CAMs) play indispensable roles in the developing and mature brain by regulating neuronal migration and differentiation, neurite outgrowth, axonal fasciculation, synapse formation and synaptic plasticity. CAM-mediated changes in neuronal behavior depend on a number of intracellular signaling cascades including changes in various second messengers, among which CAM-dependent changes in intracellular Ca²⁺ levels play a prominent role. Ca²⁺ is an essential secondary intracellular signaling molecule that regulates fundamental cellular functions in various cell types, including neurons. We present a systematic review of the studies reporting changes in intracellular Ca²⁺ levels in response to activation of the immunoglobulin superfamily CAMs, cadherins and integrins in neurons. We also analyze current experimental evidence on the Ca²⁺ sources and channels involved in intracellular Ca²⁺ increases mediated by CAMs of these families, and systematically review the role of the voltage-dependent Ca²⁺ channels (VDCCs) in neurite outgrowth induced by activation of these CAMs. Molecular mechanisms linking CAMs to VDCCs and intracellular Ca²⁺ stores in neurons are discussed.     

Astrocytes regulate amino acid receptor current densities in embryonic rat hippocampal neurons

Embryonic rat hippocampal neurons were cultured in a serum-free defined medium (MEM/N3) either directly on poly-D -lysine (PDL) or on a confluent monolayer of postnatal cortical astrocytes, C6 glioma cells, or Rat2 fibroblasts. Neurons on PDL were grown in MEM/N3 or in MEM/N3 conditioned for 24 h by astrocytes or C6 cells. Membrane capacitance (C_m) and γ-aminobutyric acid (GABA)-, glycine-, kainate-, and N-methyl-D -aspartate (NMDA)-induced currents were quantified using whole-cell patch-clamp recordings. C_m as well as the amplitude and the density of these currents in neurons cultured on astrocytes were significantly greater than those in neurons grown on PDL after 24 and 48 h. C6 cells mimicked astrocytes in promoting C_m and GABA-, glycine-, and NMDA-evoked, but not kainate-evoked, currents. C_m and currents in neurons grown on Rat2 cells were comparable to those in neurons on PDL. Astrocytes maintained in culture for 3 months were noticeably less effective than freshly prepared ones just grown to confluence. Suppression of spontaneous cytoplasmic Ca²⁺ (Ca_c²⁺) elevations in astrocytes by 1,2-bis(2-aminophenoxy) ehane-N, N, N, N-tetraacetic acid acetoxymethyl ester (BAPTA-AM) loaded intracellularly blocked the observed modulatory effects. Medium conditioned by either astrocytes or C6 cells mimicked the effects of direct coculture of neurons on these cells in promoting C_m and amino acid-evoked currents. Inclusion of antagonists at GABA and glutamate receptors in coculture experiments blocked the observed effects. Thus, diffusible substances synthesized and/or secreted by astrocytes in a Ca_c²⁺-dependent manner can regulate neuronal growth and aminoacid receptor function, and these effects may involve neuronal GABA and glutamate receptors. © 1997 John Wiley & Sons, Inc. J Neurobiol 33: 848–864, 1997     

Glutamate Mediated Astrocytic Filtering of Neuronal Activity

Neuron-astrocyte communication is an important regulatory mechanism in various brain functions but its complexity and role are yet to be fully understood. In particular, the temporal pattern of astrocyte response to neuronal firing has not been fully characterized. Here, we used neuron-astrocyte cultures on multi-electrode arrays coupled to Ca²⁺ imaging and explored the range of neuronal stimulation frequencies while keeping constant the amount of stimulation. Our results reveal that astrocytes specifically respond to the frequency of neuronal stimulation by intracellular Ca²⁺ transients, with a clear onset of astrocytic activation at neuron firing rates around 3-5 Hz. The cell-to-cell heterogeneity of the astrocyte Ca²⁺ response was however large and increasing with stimulation frequency. Astrocytic activation by neurons was abolished with antagonists of type I metabotropic glutamate receptor, validating the glutamate-dependence of this neuron-to-astrocyte pathway. Using a realistic biophysical model of glutamate-based intracellular calcium signaling in astrocytes, we suggest that the stepwise response is due to the supralinear dynamics of intracellular IP₃ and that the heterogeneity of the responses may be due to the heterogeneity of the astrocyte-to-astrocyte couplings via gap junction channels. Therefore our results present astrocyte intracellular Ca²⁺ activity as a nonlinear integrator of glutamate-dependent neuronal activity.     

Astrocytic Gap Junctional Communication Decreases Neuronal Vulnerability to Oxidative Stress-Induced Disruption of Ca2+ Homeostasis and Cell Death

Abstract: We investigated the effect of uncoupling astrocytic gap junctions on neuronal vulnerability to oxidative injury in embryonic rat hippocampal cell cultures. Mixed cultures (neurons growing on an astrocyte monolayer) treated with 18-α-glycyrrhetinic acid (GA), an uncoupler of gap junctions, showed markedly enhanced generation of intracellular peroxides (2,7-dichlorofluorescein fluorescence), impairment of mitochondrial function [(dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide reduction], and cell death (lactate dehydrogenase release) following exposure to oxidative insults (FeSO₄ and 4-hydroxynonenal). GA alone had little or no effect on basal levels of peroxides, mitochondrial function, or neuronal survival. Intercellular dye transfer analyses revealed extensive astrocyte-astrocyte coupling but no astrocyte-neuron or neuron-neuron coupling in the mixed cultures. Studies of pure astrocyte cultures and microscope analyses of neurons in mixed cultures showed that the increased oxidative stress and cell death in GA-treated cultures occurred only in neurons and not in astrocytes. Antioxidants (propyl gallate and glutathione) blocked the death of neurons exposed to FeSO₄/GA. Elevations of neuronal intracellular calcium levels ([Ca²⁺]_i) induced by FeSO₄ were enhanced in neurons in mixed cultures exposed to GA. Removal of extracellular Ca²⁺ and the L-type Ca²⁺ channel blocker nimodipine prevented impairment of mitochondrial function and cell death induced by FeSO₄ and GA, whereas glutamate receptor antagonists were ineffective. Finally, GA exacerbated kainate- and FeSO₄-induced injury to pyramidal neurons in organotypic hippocampal slice cultures. The data suggest that interastrocytic gap junctional communication decreases neuronal vulnerability to oxidative injury by a mechanism involving stabilization of cellular calcium homeostasis and dissipation of oxidative stress.     

The role of parvalbumin-containing interneurons in the regulation of spontaneous synchronous activity of brain neurons in culture

Subtypes of inhibitory GABAergic neurons containing Ca²⁺-binding proteins play a pivotal role in the regulation of spontaneous synchronous [Ca²⁺]_i transients in a neuronal network. In this study it is shown that: (1) the interneurons that containing Ca²⁺-binding proteins at buffer concentration can be identified by the shape of Ca²⁺-signa1 in response to depolarization or activation of ionotropic glutamate receptors; (2) Ca²⁺-binding proteins are involved in desynchronization of spontaneous Ca²⁺ transients. At low frequencies of spontaneous synchronous [Ca²⁺]_i transients (less than 0.2 Hz) neurons show quasi-synchronous pulsations. At higher frequencies, synchronization of spontaneous synchronous [Ca²⁺]_i transients occurs in all neurons; (3) it is established that several synchronous oscillations with different frequencies coexist in the network and the amplitude of their depolarizing pulse also varies. This phenomenon is apparently the mechanism that selectively directs information in separate neurons using the same network; and (4) in one population of interneurons at high frequencies of spontaneous synchronous [Ca²⁺]_i transients the inversion of Cl^– concentration gradient is observed. In this case, the inhibition of GABA(A) receptors suppresses the activity of neurons in this population and excites other neurons in the network. Thus, the GABAergic neurons that contain Ca-binding proteins show different mechanisms to regulate the synchronous neuronal activities in cultured rat hippocampal cells.     

Inhibition of spontaneous synchronous activity of hippocampal neurons by excitation of GABAergic neurons

The molecular mechanisms of the neuronal spontaneous synchronous activity (SSA) regulation by population of GABAergic neurons have been investigated in rat hippocampal culture. The neurons from this population contain Ca²⁺-permeable KA receptors on the presynaptic membrane. Using image analysis, confocal microscopy and immunocytochemistry, we identified by the shape of Ca²⁺ signal the population of GABAergic neurons with unique charachteristics allowing these neurons to control SSA. The SSA in a neuronal network was suppressed by the KA-receptor mediated [Ca²⁺]i increase in neurons of this population. Agonists of GluR5/GluK1-containing KA receptors (domoic acid (DA), SYM2081, and ATPA) evoked a fast high-amplitude Ca²⁺ signal without desensitization only in this population of neurons. This fact points to Ca²⁺ permeability of KA receptors in these neurons. The GABA(A) receptor antagonist bicuculline increased the activity of AMPA but not KA receptors of these neurons, indicating presynaptical localization of KA receptors. Depolarization of cells induced by KCl (unlike bicuculline-induced depolarization) increased the activity of AMPA and KA receptors twofold, which points to the dependence of the activity on depolarization. A tenfold increase of the SSA frequency in neurons of this population caused an increase in the basal [Ca²⁺]i level, which was accompanied by inhibition of SSA in another numerous population of neurons, suggesting that an increased GABAergic inhibition takes place. Prolonged high-frequency oscillations causes a global [Ca²⁺]i increase in the neurons of this population and their subsequent death. Thus, KA receptors in the population of fast GABAergic neurons may implement a negative feedback under hyperexcitation by glutamate enhancing GABA release due to the fast and prolonged [Ca²⁺]i increase. It has been shown that this mechanism can be used to suppress hyperactivation of a certain population of neurons under high-frequency SSA and ischemia. It is obvious that selective death of inhibitory neurons from this population may lead to hyperexcitability of certain brain regions.     

Prostaglandin E2 stimulates glutamate receptor‐dependent astrocyte neuromodulation in cultured hippocampal cells

Recent Ca²⁺ imaging studies in cell culture and in situ have shown that Ca²⁺ elevations in astrocytes stimulate glutamate release and increase neuronal Ca²⁺ levels, and that this astrocyte‐neuron signaling can be stimulated by prostaglandin E₂ (PGE₂). We investigated the electrophysiological consequences of the PGE₂‐mediated astrocyte‐neuron signaling using whole‐cell recordings on cultured rat hippocampal cells. Focal application of PGE₂ to astrocytes evoked a Ca²⁺ elevation in the stimulated cell by mobilizing internal Ca²⁺ stores, which further propagated as a Ca²⁺ wave to neighboring astrocytes. Whole‐cell recordings from neurons revealed that PGE₂ evoked a slow inward current in neurons adjacent to astrocytes. This neuronal response required the presence of an astrocyte Ca²⁺ wave and was mediated through both N‐methyl‐D ‐aspartate (NMDA) and non‐NMDA glutamate receptors. Taken together with previous studies, these data demonstrate that PGE₂‐evoked Ca²⁺ elevations in astrocyte cause the release of glutamate which activates neuronal ionotropic receptors. © 1999 John Wiley & Sons, Inc. J Neurobiol 41: 221–229, 1999     

Investigation of the effects of GABA receptor agonists in the differentiation of human induced pluripotent stem cells into dopaminergic neurons

The influence of GABA receptor agonists on the terminal differentiation in vitro of dopaminergic (DA) neurons derived from IPS cells was investigated. GABA-A agonist muscimol induced transient elevation of intracellular Ca²⁺ level ([Ca²⁺]_i) in the investigated cells at days 5 to 21 of differentiation. Differentiation of cells in the presence of muscimol reduced tyrosine hydroxylase expression. Thus, the presence of active GABA-A receptors, associated with phenotype determination via Ca²⁺-signalling was demonstrated in differentiating human DA neurons.     

The extracellular matrix and synapses

Extracellular matrix (ECM) molecules, derived from both neurons and glial cells, are secreted and accumulate in the extracellular space to regulate various aspects of pre- and postsynaptic differentiation, the maturation of synapses, and their plasticity. The emerging mechanisms comprise interactions of agrin, integrin ligands, and reelin, with their cognate cell-surface receptors being coupled to tyrosine kinase activities. These may induce the clustering of postsynaptic receptors and changes in their composition and function. Furthermore, direct interactions of laminins, neuronal pentraxins, and tenascin-R with voltage-gated Ca²⁺ channels, α-amino-3-hydroxy-5-methylisoxazole-4-proprionic acid (AMPA), and γ-aminobutyric acid_B (GABA_B) receptors, respectively, shape the organization and function of different subsets of synapses. Some of these mechanisms significantly contribute to the induction of long-term potentiation in excitatory synapses, either by the regulation of Ca²⁺ entry via N-methyl-D-aspartate receptors or L-type Ca²⁺ channels, or by the control of GABAergic inhibition.A.D. was supported by DFG grants Di 702/4-1,-2 and -3.     

Alternative splice isoforms of small conductance calcium-activated SK2 channels differ in molecular interactions and surface levels

Small conductance Ca²⁺-sensitive potassium (SK2) channels are voltage-independent, Ca²⁺-activated ion channels that conduct potassium cations and thereby modulate the intrinsic excitability and synaptic transmission of neurons and sensory hair cells. In the cochlea, SK2 channels are functionally coupled to the highly Ca²⁺ permeant α9/10-nicotinic acetylcholine receptors (nAChRs) at olivocochlear postsynaptic sites. SK2 activation leads to outer hair cell hyperpolarization and frequency-selective suppression of afferent sound transmission. These inhibitory responses are essential for normal regulation of sound sensitivity, frequency selectivity, and suppression of background noise. However, little is known about the molecular interactions of these key functional channels. Here we show that SK2 channels co-precipitate with α9/10-nAChRs and with the actin-binding protein α-actinin-1. SK2 alternative splicing, resulting in a 3 amino acid insertion in the intracellular 3′ terminus, modulates these interactions. Further, relative abundance of the SK2 splice variants changes during developmental stages of synapse maturation in both the avian cochlea and the mammalian forebrain. Using heterologous cell expression to separately study the 2 distinct isoforms, we show that the variants differ in protein interactions and surface expression levels, and that Ca²⁺ and Ca²⁺-bound calmodulin differentially regulate their protein interactions. Our findings suggest that the SK2 isoforms may be distinctly modulated by activity-induced Ca²⁺ influx. Alternative splicing of SK2 may serve as a novel mechanism to differentially regulate the maturation and function of olivocochlear and neuronal synapses.