A possible mechanism of the influence of neuromodulators and modifiable inhibition on long-term potentiation and long-term depression of excitatory inputs to main hippocampal neurons

A hypothetic mechanism explaining the influence of various neuromodulators and modifiable disynaptic inhibition on the long-term potentiation and depression (LTP and LTD) of excitatory inputs to granule and pyramidal hippocampal cells is proposed. According to this mechanism, facilitation of the LTD/LTP of excitatory inputs to an inhibitory interneuron caused by the action of a neuromodulator on a receptor bound with Gi/0/(Gs or Gq/11) protein can reduce/augment the GABA release, weaken/intensify the target cell inhibition, and promote the induction of the LTP/LTD of excitatory inputs to this cell. In the absence of the inhibition, the same neuromodulator would promote the LTD/LTP induction in the target cell by activating the same receptor types. The resulting effect of a neuromodulator on a target cell depends on the ratio between the "strengths" of its excitatory and inhibitory inputs, on the presence of receptors of the same or different types at the interneuron and the target cell, and on the neuromodulator concentration due to its different affinity for receptors, interaction with which provide its influence on postsynaptic processes in opposite directions. The consequences of suggested mechanism are in agreement with the known experimental data.     

A unified postsynaptic mechanism for the effect of various neuromodulators on modification of potentiated and depressed inputs to hippocampal cells (hypothesis)

The unitary postsynaptic mechanism underlying the influence of diverse neuromodulators on modification of excitatory and inhibitory inputs to granule, pyramidal and inhibitory hippocampal cells is suggested. According to this mechanism, the effect of dopamine, adenosine, acetylcholine, noradrenaline, serotonin, somatostatin, galanin, opioids, cannabinoids, neuropeptide Y on postsynaptic receptors, bound to Gi/0 proteins, should promote LTD of excitatory inputs and LTP of inhibitory inputs. The effect of dopamine, adenosine, acetylcholine, noradrenaline, serotonin, vasopressin, tachykinin, histamine on postsynaptic receptors, bound to Gs and Gq/11 proteins, should oppositively modulate the same inputs. Only synaptically activated excitatory and inhibitory inputs can by influenced by neuromodulators. The character of neuromodulatory influence on modification of hippocampal synaptic efficacy, implying from the suggested mechanism is in accordance with known experimental data.     

Mechanism of opioid and substance P-mediated modulation of cortical signal transduction through the striatum

A mechanism of opioid and substance P-mediated modulation of a cortical signal transduction through the striatum is suggested. According to this mechanism, an activation of postsynaptic receptors, bound to Gi/0 proteins, should increase the magnitude of NMDA-dependent (NMDA-independent) LTD (LTP) of excitatory inputs and LTP (LTD) of inhibitory inputs to all types of striatal cells. An activation of postsynaptic receptors, bound to Gs or Gq/11 proteins, should oppositely modulate LTD and LTD in the same inputs. It follows from the model that the negative feedback loops can held the activity of a striatal output cells at the stable level due to recurrent activation by endogenous opioids of delta receptors on striatopallidal cells, mu and kappa receptors on striatonigral cells of striosomes and matrix, respectively, and subsequent suppression of the efficacy of corticostriatal inputs. Cholinergic interneurons, affected by enkephalin and substance P, are also involved in these feedback loops. We hypothesized that an activation of mu and delta receptors and/or inactivation of kappa receptors on striatal spiny cells might alleviate parkinsonian symptoms and recover locomotor activity.     

Possible mechanism of cannabinoid-mediated modulation of signal transduction through the basal ganglia

A possible mechanism of cannabinoid-mediated akinesia is suggested. This effect is proposed to be the consequence of a decrease in LTD/LTP in cortical inputs to striatopallidal/striatonigral cells in the matrix due to CB1 receptor activation. In addition, cannabinoids can attenuate locomotor activity due to a reducing of glutamate/GABA release from axon terminals of subthalamic nucleus/striatonigral cells of matrix and subsequent decrease/increase in the activity of neurons of globus pallidus/substantia nigra pars reticulata. Cannabinoid-mediated rise of dopamine release might be a result of a decrease of dopamine neuron inhibition by striatonigral cells of striosomes. It follows from the suggested mechanism that an inactivation (activation) of CB1 receptors leading to rise (lowering) of the motor activity can be useful for treatment of Parkinson (Huntington) disease.     

Interrelated modification of excitatory and inhibitory synaptic connections in the olivary-cerebellar neuronal network

The model of simultaneous interrelated modification in the efficacy of synaptic inputs to different neurons of the olivary-cerebellar network is developed. The model is based on the following features of the network: simultaneous activation of the input layer (granule) cells and the output layer (deep cerebellar nuclei) cells by mossy fibers; simultaneous activation of Purkinje cells and cerebellar cells of the input and output layers by climbing fibers and their collaterals; the existence of local feedback excitatory, inhibitory, and disinhibitory circuits. The rise (decrease) of posttetanic Ca2+ concentration in reference to the level produced by previous stimulation causes the decrease (increase) in cGMP-dependent protein kinase G activity, and increase (decrease) inprotein phosphatase 1 activity. Subsequent dephosphorylation (phosphorylation) of ionotropic receptors results in simultaneous LTD (LTP) of the excitatory input together with the LTP (LTD) of the inhibitory input to the same neuron. The character of interrelated modifications of synapses at different cerebellar levels strongly depends on the olivary cell activity. In the presence (absence) of the signal from the inferior olive LTD (LTP) of the output cerebellar signal can be induced.     

Mechanisms of modification of excitatory and inhibitory inputs in various neurons of olivary-cerebellar network

It is known from the experimental data that at different cerebellar neurons there are voltage-dependent Ca2+ channels, NMDA receptors, metabotropic glutamate and GABAB receptors. This receptor arrangement ensures that activation of excitatory and inhibitory input results in changes in activity of protein kinases and phosphatases and subsequent modification of synaptic efficacy. The mechanism of synaptic plasticity is advanced that in accordance with the known experimental data concerning the modification of excitatory and inhibitory inputs to Purkinje cells, granule cells, and deep cerebellar nuclei cells. The mechanism is based on a postulate that phosphorylation/dephosphorylation of AMPA (GABAA) receptors on cerebellar cells causes the LTP/LTD of excitatory (LTD/LTP of inhibitory) transmission. It is assumed that modification rules for Purkinje cells, granule cells, and deep cerebellar nuclei cells, wherein cGMP-dependent protein kinase G is involved in synaptic plasticity, are distinct from those of hippocampal/neocortical cells, wherein cAMP-dependent protein kinase A is involved in synaptic plasticity, since cGMP (cAMP) concentration decreases (increases) with Ca2+ rise.     

The cortico-basal ganglia-thalamocortical circuit with synaptic plasticity. I. Modification rules for excitatory and inhibitory synapses in the striatum

It is pointed out that Ca(2+)-dependent modification rules for NMDA-dependent (NMDA-independent) synaptic plasticity in the striatum are similar to those in the neocortex and hippocampus (cerebellum). A unitary postsynaptic mechanism of synaptic modification is proposed. It is based on the assumption that, in diverse central nervous system structures, long-term potentiation/depression (LTP/LTD) of excitatory transmission (depression/potentiation of inhibitory transmission, LTDi/LTPi) is the result of an increasing/decreasing the number of phosphorylated AMPA and NMDA (GABA(A)) receptors. According to the suggested mechanism, Ca(2+)/calmodulin-dependent protein kinase II and protein kinase C, whose activity is positively correlated with Ca(2+) enlargement, together with cAMP-dependent protein kinase A (cGMP-dependent protein kinase G, whose activity is negatively correlated with Ca(2+) rise) mainly phosphorylate ionotropic striatal receptors, if NMDA channels are opened (closed). Therefore, the positive/negative post-tetanic Ca(2+) shift in relation to a previous Ca(2+) rise must cause NMDA-dependent LTP+LTDi/LTD+LTPi or NMDA-independent LTD+LTPi/LTP+LTDi. Dopamine D(1)/D(2) or adenosine A(2A)/A(1) receptor activation must facilitate LTP+LTDi/LTD+LTPi due to an augmenting/lowering PKA activity. Activation of muscarinic M(1)/M(4) receptors must enhance LTP+LTDi/LTD+LTPi as a consequence of an increase/decrease in the activity of protein kinase C/A. The proposed mechanism is in agreement with known experimental data.     

Interacting Presynaptic k-Opioid and GABAA Receptors Modulate Dopamine Release from Rat Striatal Synaptosomes

Abstract— The presynaptic regulation of stimulated dopa-mine release from superfused rat striatal synaptosomes by opioids and γ-aminobutyric acid (GABA) was studied. It was found that in addition to dopamine D₂ autoreceptors, calcium-dependent K⁺-stimulated [³H]dopamine release was inhibited through activation of a homogeneous population of k -opioid receptors in view of the potent inhibitory effect of the k -selective agonist U69.593 (EC₅₀ 0.2 nM) and its antagonism by norbinaltorphimine. Neither μ-nor δ-selective receptor agonists affected release of [³H]-dopamine. In addition, GABA potently inhibited the evoked [³H]dopamine release (EC₅₀ 0.4 nM) through activation of GABA_A receptors in view of the GABA-mimicking effect of muscimol, the sensitivity of its inhibitory effect to picro-toxin and bicuculline, and the absence of an effect of the GABA_B receptor agonist baclofen. In the presence of a maximally effective concentration of GABA, U69,593 did not induce an additional release-inhibitory effect, indicating that these receptors and the presynaptic D₂ receptor are colocalized on the striatal dopaminergic nerve terminals. The excitatory amino acid agonists N-methyl-d -aspartate and kainate, as well as the cholinergic agonist carbachol, stimulated [³H]dopamine release, which was subject to k -opioid receptor-mediated inhibition. In conclusion, striatal dopamine release is under regulatory control of multiple excitatory and inhibitory neurotransmitter by activation of colocalized presynaptic receptors for excitatory amino acids, acetylcholine, dopamine, dynorphins, and GABA within the dopaminergic nerve terminals. Together, these receptors locally control ongoing dopamine neurotransmission.     

Modulatory effects of catecholamines on neurons of the rat visual cortex: single-cell iontophoretic studies

The catecholamines noradrenaline and dopamine have been proposed as neuromodulators of cortical neuron excitability, and such a regulation could be mediated by specific adrenergic and dopaminergic receptors. We characterized electrophysiologically some of the types of responses to the iontophoretic application of adrenergic and dopaminergic agonists and antagonists on single cells in the rat visual cortex (areas occipital 1 monocular or Oc1M and occipital 1 binocular or Oc1B). For the majority of spontaneously active and visual cortical cells, noradrenaline and dopamine decreased the firing frequency. In the case of visually driven (synaptically activated) neurons, background firing was the main component of the response to be inhibited by the administration of noradrenaline, clonidine, and oxymetazoline, leading to an enhancement of the signal-to-noise ratio. Since these effects could be reduced or blocked by a previous ejection of the specific alpha 2-antagonist idazoxan, the findings support a role for alpha 2-adrenergic receptors in the transmission of sensory inputs to the visual cortex. These effects were not found with the mixed alpha-adrenergic agonist phenylephrine nor with the beta-agonist isoproterenol. Finally, the use of the inhibitory amino acid GABA rules out a simple hyperpolarizing response as the mechanism underlying noradrenaline modulatory effects in the cerebral cortex.     

A possible mechanism of influence of modifiable striatal lateral inhibition on the conditioned selection of motor activity

A mechanism of the influence of dopamine-evoked modulation of lateral inhibition in the striatum on a conditioned selection of motor activity is proposed. According to suggested modulation rules for inhibitory transmission, action of dopamine on postsynaptic D1 (D2) receptors on striatonigral (striatopallidal) cells promotes long-term depression (potentiation) of inhibitory inputs simultaneously with potentiation (depression) of "strong" excitatory inputs that open NMDA channels on these neurons. If excitatory inputs are "weak" and NMDA channels are closed, modulation rules have opposite signs. Activation of presynaptic D2 (D1) receptors results in a decrease (increase) in GABA release from striatopallidal (striatonigral) axon terminals that innervate striatonigral (striatopallidal) cells. Thereof, dopamine-evoked modulation of lateral inhibition simultaneously strengthens both potentiation (depression) of excitatory inputs to "strongly" activated striatonigral (striatopallidal) neurons rising (reducing) their activity, and depression (potentiation) of excitatory inputs to "weakly" activated striatonigral (striatopallidal) neurons reducing (rising) their activity. Subsequent reorganization of neuronal activity in the cortico-basal-ganglia-thalamocortical loop promotes a conditioned selection of motor reaction because of the further increase (decrease) in activity of those motocortical neurons that "strongly" ("weakly") activated the striatum during dopamine release in response to conditioned stimulus.     

Calcineurin-mediated LTD of GABAergic inhibition underlies the increased excitability of CA1 neurons associated with LTP

Coincident pre- and postsynaptic activity generates long-term potentiation (LTP), a possible cellular model of learning and memory. LTP has two components: (1) an increase in the excitatory postsynaptic potential (EPSP), and (2) an increase in the ability of the EPSP to generate a spike (E-S coupling of LTP). We have used pharmacological and genetic approaches to address the molecular nature of E-S coupling in CA1 pyramidal neurons. Blockade of the Ca2+-sensitive phosphatase, calcineurin, prevents induction of E-S coupling without interfering with LTP of the EPSP. Calcineurin produces its effect on E-S coupling by inducing a long-lasting depression (LTD) of the GABA(A)-mediated inhibitory postsynaptic potentials (IPSPs). This LTD of the IPSP was prevented by blockade of NMDA receptors. Thus, the tetanus that elicits NMDA-dependent LTP mediates a coordinately regulated double function. It produces LTP of the EPSP and, concomitantly, LTD of the IPSP that leads to enhancement of E-S coupling.     

Striatal glutamate release evoked in vivo by NMDA is dependent upon ongoing neuronal activity in the substantia nigra, endogenous striatal substance P and dopamine

The aim of the present microdialysis study was to investigate whether the increase in striatal glutamate levels induced by intrastriatal perfusion with NMDA was dependent on the activation of extrastriatal loops and/or endogenous striatal substance P and dopamine. The NMDA-evoked striatal glutamate release was mediated by selective activation of the NMDA receptor-channel complex and action potential propagation, as it was prevented by local perfusion with dizocilpine and tetrodotoxin, respectively. Tetrodotoxin and bicuculline, perfused distally in the substantia nigra reticulata, prevented the NMDA-evoked striatal glutamate release, suggesting its dependence on ongoing neuronal activity and GABA(A) receptor activation, respectively, in the substantia nigra. The NMDA-evoked glutamate release was also dependent on striatal substance P and dopamine, as it was antagonized by intrastriatal perfusion with selective NK(1) (SR140333), D(1)-like (SCH23390) and D(2)-like (raclopride) receptor antagonists, as well as by striatal dopamine depletion. Furthermore, impairment of dopaminergic transmission unmasked a glutamatergic stimulation by submicromolar NMDA concentrations. We conclude that in vivo the NMDA-evoked striatal glutamate release is mediated by activation of striatofugal GABAergic neurons and requires activation of striatal NK(1) and dopamine receptors. Endogenous striatal dopamine inhibits or potentiates the NMDA action depending on the strength of the excitatory stimulus (i.e. the NMDA concentration).     

A Kinetic Model of Dopamine- and Calcium-Dependent Striatal Synaptic Plasticity

Corticostriatal synapse plasticity of medium spiny neurons is regulated by glutamate input from the cortex and dopamine input from the substantia nigra. While cortical stimulation alone results in long-term depression (LTD), the combination with dopamine switches LTD to long-term potentiation (LTP), which is known as dopamine-dependent plasticity. LTP is also induced by cortical stimulation in magnesium-free solution, which leads to massive calcium influx through NMDA-type receptors and is regarded as calcium-dependent plasticity. Signaling cascades in the corticostriatal spines are currently under investigation. However, because of the existence of multiple excitatory and inhibitory pathways with loops, the mechanisms regulating the two types of plasticity remain poorly understood. A signaling pathway model of spines that express D1-type dopamine receptors was constructed to analyze the dynamic mechanisms of dopamine- and calcium-dependent plasticity. The model incorporated all major signaling molecules, including dopamine- and cyclic AMP-regulated phosphoprotein with a molecular weight of 32 kDa (DARPP32), as well as AMPA receptor trafficking in the post-synaptic membrane. Simulations with dopamine and calcium inputs reproduced dopamine- and calcium-dependent plasticity. Further in silico experiments revealed that the positive feedback loop consisted of protein kinase A (PKA), protein phosphatase 2A (PP2A), and the phosphorylation site at threonine 75 of DARPP-32 (Thr75) served as the major switch for inducing LTD and LTP. Calcium input modulated this loop through the PP2B (phosphatase 2B)-CK1 (casein kinase 1)-Cdk5 (cyclin-dependent kinase 5)-Thr75 pathway and PP2A, whereas calcium and dopamine input activated the loop via PKA activation by cyclic AMP (cAMP). The positive feedback loop displayed robust bi-stable responses following changes in the reaction parameters. Increased basal dopamine levels disrupted this dopamine-dependent plasticity. The present model elucidated the mechanisms involved in bidirectional regulation of corticostriatal synapses and will allow for further exploration into causes and therapies for dysfunctions such as drug addiction.     

The Cdk5 inhibitor Roscovitine increases LTP induction in corticostriatal synapses

In corticostriatal synapses, LTD (long-term depression) and LTP (long-term potentiation) are modulated by the activation of DA (dopamine) receptors, with LTD being the most common type of long-term plasticity induced using the standard stimulation protocols. In particular, activation of the D1 signaling pathway increases cAMP/PKA (protein kinase A) phosphorylation activity and promotes an increase in the amplitude of glutamatergic corticostriatal synapses. However, if the Cdk5 (cyclin-dependent kinase 5) phosphorylates the DARPP-32 (dopamine and cAMP-regulated phosphoprotein of 32 kDa) at Thr⁷⁵, DARPP-32 becomes a strong inhibitor of PKA activity. Roscovitine is a potent Cdk5 inhibitor; it has been previously shown that acute application of Roscovitine increases striatal transmission via Cdk5/DARPP-32. Since DARPP-32 controls long-term plasticity in the striatum, we wondered whether switching off CdK5 activity with Roscovitine contributes to the induction of LTP in corticostriatal synapses. For this purpose, excitatory population spikes and whole cell EPSC (excitatory postsynaptic currents) were recorded in striatal slices from C57/BL6 mice. Experiments were carried out in the presence of Roscovitine (20 μM) in the recording bath. Roscovitine increased the amplitude of excitatory population spikes and the percentage of population spikes that exhibited LTP after HFS (high-frequency stimulation; 100Hz). Results obtained showed that the mechanisms responsible for LTP induction after Cdk5 inhibition involved the PKA pathway, DA and NMDA (N-methyl-D-aspartate) receptor activation, L-type calcium channels activation and the presynaptic modulation of neurotransmitter release.     

A possible mechanism of dopamine-induced synergistic disinhibition of thalamic cells via "direct" and "indirect" pathways in basal ganglia

On the basis of the mechanism of synaptic plasticity that we have earlier suggested for striatal spiny neurons and with regard to the known data about the predominance of dopamine-sensitive D1/D2 receptors on the striatonigral/striatopallidal cells it is hypothesized that the induction of the long-term potentiation/depression of the efficacy of excitatory cortical inputs to these cells can underlie the excitatory/inhibitory effect of dopamine on the activity of neurons that originate the "direct"/"indirect" pathways through the basal ganglia. Both these effects will lead to an enhancement of the activity of thalamic cells and activity of the efferent neocortical neurons excited by thalamic cells. The long-term potentiation of corticostriatal inputs to striosomal neurons, where, predominantly, D1 receptors are located, can also be induced by dopamine. This effect can be responsible of a rise of inhibition of dopaminergic cells and decrease in dopamine release by these cells. Such an event sequence can provide a stable dopamine concentration in the loop neocortex-basal ganglia-thalamus-neocortex.     

Effect of Dopaminergic D1 Receptors on Plasticity Is Dependent of Serotoninergic 5-HT1A Receptors in L5-Pyramidal Neurons of the Prefrontal Cortex

Major depression and schizophrenia are associated with dysfunctions of serotoninergic and dopaminergic systems mainly in the prefrontal cortex (PFC). Both serotonin and dopamine are known to modulate synaptic plasticity. 5-HT_1A receptors (5-HT_1ARs) and dopaminergic type D1 receptors are highly represented on dendritic spines of layer 5 pyramidal neurons (L5PyNs) in PFC. How these receptors interact to tune plasticity is poorly understood. Here we show that D1-like receptors (D1Rs) activation requires functional 5HT_1ARs to facilitate LTP induction at the expense of LTD. Using 129/Sv and 5-HT_1AR-KO mice, we recorded post-synaptic currents evoked by electrical stimulation in layer 2/3 after activation or inhibition of D1Rs. High frequency stimulation resulted in the induction of LTP, LTD or no plasticity. The D1 agonist markedly enhanced the NMDA current in 129/Sv mice and the percentage of L5PyNs displaying LTP was enhanced whereas LTD was reduced. In 5-HT_1AR-KO mice, the D1 agonist failed to increase the NMDA current and orientated the plasticity towards L5PyNs displaying LTD, thus revealing a prominent role of 5-HT_1ARs in dopamine-induced modulation of plasticity. Our data suggest that in pathological situation where 5-HT_1ARs expression varies, dopaminergic treatment used for its ability to increase LTP could turn to be less and less effective.     

What mechanisms underlie involvement of different NMDA receptor subunits in the induction of hippocampal long-term potentiation and long-term depression?

There is a point of view that N-methyl-D-aspartate (NMDA) receptor subunit-specific signaling outcomes determine the direction of modifications of efficacy of synaptic transmission. Activation of NMDA receptors that contain the 2A subunit promotes LTP, while LTD requires activation of NMDA receptors containing 2B subunit. However, this hypothesis is inconsistent with some experimental data. For explanation of these data, we put forward an alternative hypothesis. According to this hypothesis, the activation of diverse subtypes of NMDA receptors can lead to ether LTP or LTD depending on the relation between posttetanic Ca2+ rise and increase in postsynaptic Ca2+ concentration produced by previous stimulation. Activation of NMDA receptors with 2B subunit can promote LTD of excitatory input to the pyramidal cell due to presence of these receptors on inhibitory interneurons, induction of the LTP in interneuron, and potentiation of inhibitory transmission between the interneuron and the target pyramidal cell.     

The cortico-basal ganglia-thalamocortical circuit with synaptic plasticity. II. Mechanism of synergistic modulation of thalamic activity via the direct and indirect pathways through the basal ganglia

A possible mechanism underlying the modulatory role of dopamine, adenosine and acetylcholine in the modification of corticostriatal synapses, subsequent changes in signal transduction through the "direct" and "indirect" pathways in the basal ganglia and variations in thalamic and neocortical cell activity is proposed. According to this mechanism, simultaneous activation of dopamine D1/D2 receptors as well as inactivation of adenosine A1/A(2A) receptors or muscarinic M4/M1 receptors on striatonigral/striatopallidal inhibitory cells can promote the induction of long-term potentiation/depression in the efficacy of excitatory cortical inputs to these cells. Subsequently augmented inhibition of the activity of inhibitory neurons of the output nuclei of the basal ganglia through the "direct" pathway together with reduced disinhibition of these nuclei through the "indirect" pathway synergistically increase thalamic and neocortical cell firing. The proposed mechanism can underlie such well known effects as "excitatory" and "inhibitory" influence of dopamine on striatonigral and striatopallidal cells, respectively; the opposite action of dopamine and adenosine on these cells; antiparkinsonic effects of dopamine receptor agonists and adenosine or acetylcholine muscarinic receptor antagonists.     

Potential mechanisms of effects of endogenous neuromodulators on the interdependent activity of neurons in various nuclei of the basal ganglia

A possible mechanism of influence of neuromodulators on interdependent activity of neurons in the diverse basal ganglia nuclei is suggested. According to modulation rules, an activation of postsynaptic Gs- or Gq/11-(Gi/0-) protein coupled receptors promotes induction of long-term potentiation (depression) of excitatory inputs to different neurons and augmentation (lowering) of their activity; an activation of presynaptic Gs- or Gq/11-(Gi/0-) protein coupled receptors promotes a rise (decrease) of release of GABA and co-peptides from striatal terminals and glutamate release from subthalamic terminals in the globus pallidus and output nuclei. It follows from the modulation rules that, since identical receptors are present on striatal neuron and their axon terminals, effects of neuromodulator action in diverse basal ganglia nuclei can be summarized. Neuromodulators released from striato-nigral and striato-pallidal fibers could promote interdependent activity of neurons in "direct" and "indirect" pathways through the basal ganglia due to convergence of these fibers on cholinergic interneurons and pallido-striatal cells.     

Dopamine induces release of calcium from internal stores in layer II lateral entorhinal cortex fan cells.

The entorhinal cortex plays an important role in temporal lobe processes including learning and memory, object recognition, and contextual information processing. The alteration of the strength of synaptic inputs to the lateral entorhinal cortex may therefore contribute substantially to sensory and mnemonic functions. The neuromodulatory transmitter dopamine exerts powerful effects on excitatory glutamatergic synaptic transmission in the entorhinal cortex. Interestingly, inputs from midbrain dopamine neurons appear to specifically target clusters of excitatory cells located in the superficial layers of the entorhinal cortex. We have previously demonstrated that dopamine facilitates synaptic transmission through the activation of D₁-like receptors. This facilitation of synaptic transmission is dependent on both activation of classical D₁-like-receptors, and upon activation of dopamine receptors linked to increases in phospholipase C, inositol triphosphate (IP₃), and intracellular calcium. In the present study we combined electrophysiological recordings of evoked excitatory postsynaptic currents with imaging of intracellular calcium using the fluorescent indicator fluo-4 to monitor calcium transients evoked by dopamine in electrophysiologically identified putative fan and pyramidal cells of the lateral entorhinal cortex. Bath application of dopamine (1 μM), or the phosphatidylinositol (PI)-linked D₁-like-receptor agonist SKF83959 (5 μM), induced reliable and reversible increases in fluo-4 fluorescence and excitatory postsynaptic currents in fan cells, but not in pyramidal cells. In contrast, application of the classical D₁-like-receptor agonist SKF38393 (10 μM) did not result in significant increases in fluorescence. Blocking release of calcium from internal stores by loading cells with the IP₃ receptor blocker heparin (1 mM) or the ryanodine receptor blocker dantrolene (20 μM) abolished both the calcium transients and the facilitation of evoked synaptic currents induced by dopamine. Dopamine also induced calcium transients in fan cells when calcium was excluded from the extracellular medium, further indicating that the calcium transients are linked to release from internal stores. These results indicate that following D₁-like-receptor binding, dopamine selectively induces transient elevations in intracellular calcium via activation of IP₃ and ryanodine receptors, and that these elevations are linked to the facilitation of synaptic responses in putative layer II entorhinal cortex fan cells.