Regulation of L-type calcium channels in pituitary GH(4)C(1) cells by depolarization.

The neurosecretory anterior pituitary GH(4)C(1) cells exhibit the high voltage-activated dihydropyridine-sensitive L-type and the low voltage-activated T-type calcium currents. The activity of L-type calcium channels is tightly coupled to secretion of prolactin and other hormones in these cells. Depolarization induced by elevated extracellular K(+) reduces the dihydropyridine (+)-[(3)H]PN200-110 binding site density and (45)Ca(2+) uptake in these cells (). This study presents a functional analysis by electrophysiological techniques of short term regulation of L-type Ca(2+) channels in GH(4)C(1) cells by membrane depolarization. Depolarization of GH(4)C(1) cells by 50 mm K(+) rapidly reduced the barium currents through L-type calcium channels by approximately 70% and shifted the voltage dependence of activation by 10 mV to more depolarized potentials. Down-regulation depended on the strength of the depolarizing stimuli and was reversible. The currents recovered to near control levels on repolarization. Down-regulation of the calcium channel currents was calcium-dependent but may not have been due to excessive accumulation of intracellular calcium. Membrane depolarization by voltage clamping and by veratridine also produced a down-regulation of calcium channel currents. The down-regulation of the currents had an autocrine component. This study reveals a calcium-dependent down-regulation of the L-type calcium channel currents by depolarization.     

Ca2+-conductances in cultured rat retinal pigment epithelial cells

Membrane conductances for Ca²⁺ in cultured rat pigment epithelial cells were studied in the whole-cell configuration of the patch-clamp technique using barium (10 mM) as a charge carrier. Two types of voltage-dependent and verapamiland diltiazem-sensitive Ba²⁺ currents were observed. First, a nearly sustained current was activated by depolarization to potentials more positive than — 30mV and blocked by nifedipine (1 μM). This current was observed in cells of primary cultures less than 13 days old. Second, a transient nifedipine (1 μM) insensitive current was activated by depolarization to potentials more positive than — 55mV in cultures which were more than 13 days old. This current was not carried by sodium and blocked by 1 μM tetrodotoxin (TTX). In summary, cultured rat retinal pigment epithelial cells in younger primary cultures express Ba²⁺ currents indicating the presence of L-type Ca²⁺ channels. In order primary cultures a low-voltage activated channel was observed with properties different from T-type calcium channels or TTX-sensitive calcium conducting sodium channels. © 1994 Wiley-Liss, Inc.     

Low voltage-activated calcium channels in vascular smooth muscle: T-type channels and AVP-stimulated calcium spiking

An important path of extracellular calcium influx in vascular smooth muscle (VSM) cells is through voltage-activated Ca2+ channels of the plasma membrane. Both high (HVA)- and low (LVA)-voltage-activated Ca2+ currents are present in VSM cells, yet little is known about the relevance of the LVA T-type channels. In this report, we provide molecular evidence for T-type Ca2+ channels in rat arterial VSM and characterize endogenous LVA Ca2+ currents in the aortic smooth muscle-derived cell line A7r5. AVP is a vasoconstrictor hormone that, at physiological concentrations, stimulates Ca2+ oscillations (spiking) in monolayer cultures of A7r5 cells. The present study investigated the role of T-type Ca2+ channels in this response with a combination of pharmacological and molecular approaches. We demonstrate that AVP-stimulated Ca2+ spiking can be abolished by mibefradil at low concentrations (<1 microM) that should not inhibit L-type currents. Infection of A7r5 cells with an adenovirus containing the Cav3.2 T-type channel resulted in robust LVA Ca2+ currents but did not alter the AVP-stimulated Ca2+ spiking response. Together these data suggest that T-type Ca2+ channels are necessary for the onset of AVP-stimulated calcium oscillations; however, LVA Ca2+ entry through these channels is not limiting for repetitive Ca2+ spiking observed in A7r5 cells.     

Aldosterone regulation of T-type calcium channels

Voltage-operated calcium channels play a crucial role in signal transduction in many excitable and non-excitable cell types. While a rapid modulation of their activity by hormone-activated kinases and/or G proteins has been recognized for a long time, a sustained control of their expression level has been only recently demonstrated. In adrenal H295R cells, for example, aldosterone treatment selectively increased low threshold T-type calcium current density without affecting L-type currents. Antagonizing the mineralocorticoid receptor (MR) with spironolactone prevented aldosterone action on T-type currents. By RT-PCR, we detected in these cells the presence of two different isoforms of L-type channels, alpha(1)C and alpha(1)D, and one isoform of T channel, alpha(1)H. A second T channel isoform (alpha(1)G) was also observed under particular culture conditions. Quantification of the specific messenger RNA by real time RT-PCR allowed us to show a 40% increase of the alpha1H messenger levels upon aldosterone treatment (alpha(1)G was insensitive), a response that was also completely prevented by spironolactone. Because T-type, but not L-type channel activity is linked to steroidogenesis, this modulation represents a positive, intracrine feed back mechanism exerted by aldosterone on its own production.Aldosterone has been also implicated in the pathogenesis and progression of ventricular hypertrophy and heart failure independently of its action on arterial blood pressure. We have observed that, in rat neonatal cardiomyocytes, aldosterone increases (by two-fold) L-type calcium current amplitude in ventricular but not in atrial cells. No significant effect of aldosterone could be detected on T-type currents, that were much smaller than L-type currents in these cells. However, aldosterone exerted opposite effects on T channel isoform expression, increasing alpha(1)H and decreasing alpha(1)G. Although the functional role of T channels is still poorly defined in ventricular cardiomyocytes, an overexpression of alpha(1)H could be partially responsible for the arrhythmias linked to hyperaldosteronism.Finally, T channels also appear to be involved in the neuroendocrine differentiation of prostate epithelial cells, a poor prognosis in prostate cancer. We have shown that the only calcium channel expressed in the prostatic LNCaP cells is the alpha(1)H isoform and that induction of cell differentiation with cAMP leads to a concomitant increase in both T-type current and alpha(1)H mRNA. In spite of the presence of MR in these cells, aldosterone only modestly increased alpha(1)H mRNA levels. A functional role for these channels was suggested by the observation that low nickel concentrations prevent neuritic process outgrowth.In conclusion, it appears that T-type calcium channel expression vary in different patho-physiological conditions and that aldosterone, in several cell types, is able to modulate this expression.     

Block of T-type Ca channels in guinea pig atrial cells by antiarrhythmic agents and Ca channel antagonists

Myocardial cells have two types of Ca channels commonly called T-type and L-type. Whole cell Ca channel currents in guinea pig atrial myocytes can be separated and quantitated by analyzing channel closing kinetics after a brief depolarization (tail current analysis). L-type Ca channels deactivate rapidly when the membrane is repolarized and T-type Ca channels deactivate relatively slowly. Ca channel block by the therapeutically useful Ca channel antagonists is voltage dependent, so it is desirable to study block of both channel types over an extended voltage range. Tail current analysis allows this and was used to study block of both types of Ca channels under identical conditions. Amiodarone, bepridil, and cinnarizine block T-type Ca channels more potently than L-type Ca channels when binding equilibrates at normal diastolic potentials (approximately -90 mV). None of these drugs is a selective blocker of T-type Ca channels because block of L-type Ca channels is enhanced when cells are almost completely depolarized. Although weak block of T-type Ca channels by 1,4-dihydropyridines has usually been reported, we found that felodipine blocks these channels with high affinity. When most T-type Ca channels are inactivated, the apparent dissociation constant (KI) is 13 nM. Felodipine also blocks T-type Ca channels in GH3 cells (a cell line derived from rat anterior pituitary), but KI = 700 nM. Thus, T-type Ca channels in different cell types are pharmacologically distinct. Felodipine can block L-type Ca channels in atrial cells more potently than T-type Ca channels, but block of L-type Ca channels is potent only at depolarized potentials; block of both channel types is comparable at normal diastolic membrane potentials. Felodipine and the 1,4-dihydropyridines isradipine and (-)-202-791 are approximately equipotent at blocking T-type Ca channels, but differ substantially in potency for block of L-type Ca channels. Block of T-type Ca channels may account for some of the pharmacological effects of 1,4-dihydropyridines and for the antiarrhythmic activity of amiodarone and bepridil.     

Differential expression of voltage-gated calcium channels in identified visual cortical neurons.

Using the whole-cell patch-clamp technique, Ca2+ channel currents were examined in three distinct types of neurons derived from rat primary visual cortex. Callosal-projecting and superior colliculus-projecting neurons were identified following in vivo retrograde labeling with fluorescent "beads." A subset of intrinsic GABAergic visual cortical neurons was identified with the monoclonal antibody VC1.1. Although high voltage-activated Ca2+ channel currents were measured in all three cell types, clear differences in the densities of these channels were observed. There were also marked variations in the relative amplitudes of the inactivating and noninactivating components of the high voltage-activated currents, suggesting that N- and L-type Ca2+ channels are differentially distributed. Although low voltage-activated or T-type currents were measured in subsets of both types of projection neurons, they were not observed in VC1.1-positive cells. These results provide a direct demonstration that voltage-gated Ca2+ channels are expressed in neurons of the mammalian visual cortex and reveal that the distribution and densities of different Ca2+ channel types in diverse classes of visual cortical neurons are distinct.     

T-type Ca2+ channels in vascular smooth muscle: multiple functions

Vascular smooth muscle is a major constituent of the blood vessel wall, and its many functions depend on type and location of the vessel, developmental or pathological state, and environmental and chemical factors. Vascular smooth muscle cells (VSMCs) use calcium as a signal molecule for multiple functions. An important component of calcium signaling pathways is the entry of extracellular calcium via voltage-gated Ca2+ channels, which in vascular smooth muscle cells (VSMCs) are of two main types, the high voltage-activated (HVA) L-type and low voltage-activated (LVA) T-type channels. Whereas L-type channels function primarily to regulate Ca2+ entry for contraction, it is generally accepted that T-type Ca2+ channels do not contribute significantly to arterial vasoconstriction, with the possible exception of the renal microcirculation. T-type Ca2+ channels are also present in some veins that display spontaneous contractile activity, where they likely generate pacemaker activity. T-type Ca2+ channel expression has also been associated with normal and pathological proliferation of VSMCs, often stimulated by external cues in response to insult or injury. Expression of T-type channels has been linked to the G1 and S phases of the cell cycle, a period important for the signaling of gene expression necessary for cell growth, progression of the cell cycle and ultimately cell division. To better understand T-type Ca2+ channel functions in VSM, it will be necessary to develop new approaches that are specifically targeted to this class of Ca2+ channels and its individual members.     

Angiotensin II-induced increase of T-type Ca2+ current and decrease of L-type Ca2+ current in heart cells

The effect of angiotensin II (Ang II) on the T- and L-type calcium currents (I(Ca)) in single ventricular heart cells of 18-week-old fetal human and 10-day-old chick embryos was studied using the whole-cell voltage clamp technique. Our results showed that in both, human and chick cardiomyocytes, Ang II (10(-7)M) increased the T-type calcium current and decreased the L-type I(Ca). The effect of Ang II on both types of currents was blocked by the AT1 peptidic antagonist, [Sar1, Ala8] Ang II (2 x 10(-7)M). Protein kinase C activator, phorbol 12,13-dibutyrate, mimicked the effect of Ang II on the T- and L-type calcium currents. These results demonstrate that in fetal human and chick embryo cardiomyocytes Ang II affects the T- and L-type Ca2+ currents differently, and this effect seems to be mediated by the PKC pathway.     

Angiotensin II type 1 receptor activation modulates L- and T-type calcium channel activity through distinct mechanisms in bovine adrenal glomerulosa cells

In adrenal zona glomerulosa cells, calcium entry is crucial for aldosterone production and secretion. This influx is stimulated by increases of extracellular potassium in the physiological range of concentrations and by angiotensin II (Ang II). The high threshold voltage-activated (L-type) calcium channels have been shown to be the major mediators for the rise in cytosolic free calcium concentration, [Ca2+]c, observed in response to a depolarisation by physiological potassium concentrations. Paradoxically, both T- and L-type calcium channels have been shown to be negatively modulated by Ang II after activation by a sustained depolarisation. While the modulation of T-type channels involves protein kinase C (PKC) activation, L-type channel inhibition requires a pertussis toxin-sensitive G protein. In order to investigate the possibility of additional modulatory mechanisms elicited by Ang II on L-type channels, we have studied the effect of PKC activation or tyrosine kinase inhibition. Neither genistein or MDHC, two strong inhibitors of tyrosine kinases, nor the phorbol ester PMA, a specific activator of PKC, affected the Ang II effect on the [Ca2+]c response and on the Ba2+ currents elicited by cell depolarisation with the patch-clamp method. We propose a model describing the mechanisms of the [Ca2+]c modulation by Ang II and potassium in bovine adrenal glomerulosa cells.     

Different effects of L-, N- and T-type calcium channel blockers on striatal dopamine release measured by microdialysis in freely moving rats.

Using a microdialysis method, we have investigated effects of the voltage-dependent calcium channel blockers, verapamil, nicardipine, omega-conotoxin and flunarizine on the dopamine release and metabolism in the striatum of freely moving rat. Perfusion of verapamil (1-300 microM) and nicardipine (1-100 microM), an L-type calcium channel blocker, into the striatum through the dialysis membrane showed a dose-dependent decrease of dopamine release in the dialysate and slight increase of 3,4-dihydroxyphenylacetic acid (DOPAC) and homovanillic acid (HVA) levels. Treatment of omega-conotoxin (0.1, 1 microM), an N-type channel blocker, decreased about 50% basal dopamine release and slightly decreased DOPAC and HVA levels. Treatment with flunarizine (10 microM), an T-type channel blocker, did not affect the dopamine release and metabolism. From these data, it appears that treatments of the L- and N-type voltage-dependent calcium channel blockers in rat striatum suppress basal dopamine release, but T-type blocker does not suppress it, suggesting that L-, N- and T-type calcium channels regulate in vivo dopamine release in a different mechanism.     

Adenosine inhibits calcium channel currents via A1 receptors on salamander retinal ganglion cells in a mini-slice preparation

The effects of adenosine on high-voltage-activated calcium channel currents in tiger salamander retinal ganglion cells were investigated in a mini-slice preparation. Adenosine produced a concentration-dependent decrease in the amplitude of calcium channel current with a maximum inhibition of 26%. The effects of adenosine on calcium channel current were both time- and voltage-dependent. In cells dialyzed with GTP-gamma-s, adenosine caused a sustained and irreversible inhibition of calcium channel current, suggesting involvement of a GTP-binding protein. The inhibitory effect of adenosine on calcium channel current was blocked by the A1 antagonist 8-cyclopentyltheophylline (DPCPX, 1-10 microm), but not by the A2 antagonist 3-7-dimethyl-1-propargylxanthine (DMPX, 10 microm), and was mimicked by the A1 agonist N6-cyclohexyladenosine (CHA, 1 microm) but not by the A2 agonist 5'-(N-cyclopropyl) carbox-amidoadenosine (CPCA, 1 microm). Adenosine's inhibition of calcium channel current was not affected by the L-type calcium channel blocker nifedipine (5 microm). However, adenosine's inhibition of calcium channel current was reduced to approximately 10% after application of omega-conotoxin GVIA (1 microm), suggesting that adenosine inhibits N-type calcium channels. These results show that adenosine acts on an A1 adenosine receptor subtype via a G protein-coupled pathway to inhibit the component of calcium channel current carried in N-type calcium channels.     

Modulation of T-type Ca2+ channels by corticotropin-releasing factor through protein kinase C pathway in MN9D dopaminergic cells

Corticotrophin-releasing factor (CRF) is the main regulator of the body's stress axis and its signal is translated through G-protein-coupled CRF receptors (CRF-R1, CRF-R2). Even though CRF receptors are present in the midbrain dopamine neurons, the cellular mechanism of CRF action is not clear yet. Since voltage-dependent Ca(2+) channels are highly expressed and important in dopamine neuronal functions, we tested the effect of CRF on voltage-dependent Ca(2+) channels in MN9D cells, a model of dopamine neurons. The application of CRF-related peptide, urocortin 1, reversibly inhibited T-type Ca(2+) currents, which was a major Ca(2+) channel in the cells. The effect of urocortin was abolished by specific CRF-R1 antagonist and was mimicked by protein kinase C (PKC) activator, phorbol 12-myristate 13-acetate. PKC inhibitors abolished the effect of urocortin. These results suggest that urocortin modulates T-type Ca(2+) channel by interacting with CRF-R1 via the activation of PKC signal pathway in MN9D cells.     

The effects of crustacean cardioactive peptide on locust oviducts are calcium-dependent

The role of calcium as a second messenger in the crustacean cardioactive peptide (CCAP)-induced contractions of the locust oviducts was investigated. Incubation of the oviducts in a calcium-free saline containing, a preferential calcium cation chelator, or an extracellular calcium channel blocker, abolished CCAP-induced contractions, indicating that the effects of CCAP on the oviducts are calcium-dependent. In contrast, sodium free saline did not affect CCAP-induced contractions. Co-application of CCAP to the oviducts with preferential L-type voltage-dependent calcium channel blockers reduced CCAP-induced contractions by 32-54%. Two preferential T-type voltage-dependent calcium channel blockers both inhibited CCAP-induced oviduct contractions although affecting different components of the contractions. Amiloride decreased the tonic component of CCAP-induced contractions by 40-55% and flunarizine dihydrochloride decreased the frequency of CCAP-induced phasic contractions by as much as 65%, without affecting tonus. Flunarizine dihydrochloride did not alter the proctolin-induced contractions of the oviducts. Results suggest that the actions of CCAP are partially mediated by voltage-dependent calcium channels similar to vertebrate L-type and T-type channels. High-potassium saline does not abolish CCAP-induced contractions indicating the presence of receptor-operated calcium channels that mediate the actions of CCAP on the oviducts. The involvement of calcium from intracellular stores in CCAP-induced contractions of the oviducts is likely since, an intracellular calcium antagonist decreased CCAP-induced contractions by 30-35%.     

A role for voltage gated T-type calcium channels in mediating "capacitative" calcium entry?

Calcium entry through plasma membrane calcium channels is one of the most important cell signaling mechanism involved in such diverse functions as secretion, contraction and cell growth by regulating gene expression, proliferation and apoptosis. The identity of plasma membrane calcium channels, the main regulators of calcium entry, involved in cell proliferation has been thus extensively sought. Among these, a calcium entry pathway called capacitative calcium entry (CCE), activated by calcium store depletion, is particularly important in non-excitable cells. Though this capacitative calcium entry is generally supposed to occur through TRP channels there is some evidence that voltage-dependent T-type calcium channels may contribute to calcium entry after store depletion. Here we show that though mibefradil, a T-type calcium channel blocker, is able to reduce capacitative calcium entry induced by either thapsigargin or ATP, this was not mimicked by any other T-type calcium channel inhibitors even in cells overexpressing alpha(1H) T-type calcium channels, leading us to conclude that T-type calcium channels are not responsible for the capacitative calcium entry observed in different cancer cell lines. On the contrary, we show that the action of mibefradil on capacitative calcium entry is due to an action on store-operated calcium channels.     

Ionic currents in cardiac myocytes of squid, Alloteuthis subulata

This paper provides the first study of voltage-sensitive membrane currents present in heart myocytes from cephalopods. Whole cell patch clamp recordings have revealed six different ionic currents in myocytes freshly dissociated from squid cardiac tissues (branchial and systemic hearts). Three types of outward potassium currents were identified: first, a transient outward voltage-activated A-current (I_A), blocked by 4-aminopyridine, and inactivated by holding the cells at a potential of −40 mV; second, an outward, voltage-activated, delayed rectifier current with a sustained time course (I_K); and third, an outward, calcium-dependent, potassium current (I_K(Ca)) sensitive to Co²⁺ and apamin, and with the characteristic N-shaped current voltage relationship. Three inward voltage-activated currents were also identified. First, a rapidly activating and inactivating, sodium current (I_Na), blocked by tetrodotoxin, inactivated at holding potentials more positive than −40 mV, and abolished when external sodium was replaced by choline. Second, an L-type calcium current (I_Ca,L) with a sustained time course, suppressed by nifedipine or Co²⁺, and enhanced by substituting Ca²⁺ for Ba²⁺ in the external medium. The third inward current was also carried by calcium ions, but could be distinguished from the L-type current by differences in its voltage dependence. It also had a more transient time course, was activated at more negative potentials, and resembled the previously described low-voltage-activated, T-type calcium current. Accepted: 24 September 1999     

The effects of sodium removal on the two types of calcium currents in single frog atrial cells.

The effects of sodium removal on the two types of calcium currents were studied in enzymatically dispersed frog (Rana esculenta) atrial myocytes with the single pipette patch-clamp technique. Reduction of calcium currents was recorded when NaCl was replaced either by TEACl, LiCl, TrisCl, cholineCl or by mannitol. An involvement of the Na-Ca exchange mechanism could be ruled out since the decrease was also observed after replacing external Ca with Ba. The slight shift of the apparent reversal potential recorded in our study suggests that the inward flow of Na ions through calcium channels does not contribute significantly to the L-type calcium current. Once again, the slight negative shift of the steady-state inactivation curve of the L-type calcium current cannot explain this decrease while no shift was recorded for the T-type calcium current. Even if a TTX-resistant Na current was recorded from a few cells this current cannot explain the decrease of calcium currents which was always observed upon sodium removal. To date we have no explanation for this effect.     

Both T- and L-type Ca2+ channels can contribute to excitation-contraction coupling in cardiac Purkinje cells.

Although L-type Ca2+ channels have been shown to play a central role in cardiac excitation-contraction (E-C) coupling, little is known about the role of T-type Ca2+ channels in this process. We used the amphotericin B perforated patch method to study the possible role of T-type Ca2+ current in E-C coupling in isolated canine Purkinje myocytes where both Ca2+ currents are large. T-type Ca2+ current was separated from L-type Ca2+ current using protocols employing the different voltage dependencies of the channel types and their different sensitivities to pharmacological blockade. We showed that Ca2+ admitted through either T- or L-type Ca2+ channels is capable of initiating contraction and that the contractions depended on Ca2+-induced Ca2+ release from the sarcoplasmic reticulum (SR). The contractions, however, had different properties. Those initiated by Ca2+ entry through T-type Ca2+ channels had a longer delay to the onset of shortening, slower rates of shortening and relaxation, lower peak shortening, and longer time to peak shortening. These differences were present even when L-type Ca2+ current amplitude, or charge entry, was less than that of T-type Ca2+ current, suggesting that Ca2+ entry through the T-type Ca2+ channel is a less effective signal transduction mechanism to the SR than is Ca2+ entry through the L-type Ca2+ channel. We conclude that under our experimental conditions in cardiac Purkinje cells Ca2+ entry through the T-type Ca2+ channel can activate cell contraction. However, Ca2+ entry through the L-type Ca2+ channel is a more effective signal transduction mechanism. Our findings support the concept that different structural relationships exist between these channel types and the SR Ca2+ release mechanism.     

Modulation of Ca2+ channels by atrial natriuretic peptide in the bovine adrenal glomerulosa cell.

In the bovine adrenal glomerulosa cell, calcium influx through voltage-dependent calcium channels is critical to maintaining an aldosterone secretory response. In patch clamp, atrial natriuretic peptide (ANP) inhibits T-type calcium channel current yet stimulates L-type calcium channel current. In the present study the channel effects of ANP observed in the patch-clamp configuration were extended and related to populations of cells. We observed the following. (i) The effect of ANP on T-channel current resulted in the reduction in the open state probability. ANP decreased the mean open state duration from 14.2 to 1.8 ms/sweep. (ii) In the weakly depolarized cell stimulated by 8 mM K+, ANP reduced the level of aequorin luminescence (a measure of cytosolic calcium) and completely inhibited the stimulated rate of aldosterone secretion, returning it to prestimulation values. These effects are consistent with a decrease in net calcium channel influx and the reported inhibition of T-channel current. In contrast, the calcium channel blocker, nitrendipine, which at low dose selectively blocks L-type calcium channel flux, only slightly reduced luminescence, and partially inhibited the sustained secretory response. (iii) In the strongly depolarized cell, stimulated by 60 mM K+, ANP increased the level of aequorin luminescence consistent with an increase in net calcium channel influx and the reported stimulation of L-channel current. These results indicate that under physiological conditions the inhibition of T-type calcium channels may be involved in the inhibition of the aldosterone secretion induced by ANP.     

Role of Multiple Calcium and Calcium-Dependent Conductances in Regulation of Hippocampal Dentate Granule Cell Excitability

We have constructed a detailed model of a hippocampal dentate granule (DG) cell that includes nine different channel types. Channel densities and distributions were chosen to reproduce reported physiological responses observed in normal solution and when blockers were applied. The model was used to explore the contribution of each channel type to spiking behavior with particular emphasis on the mechanisms underlying postspike events. T-type calcium current in more distal dendrites contributed prominently to the appearance of the depolarizing after-potential, and its effect was controlled by activation of BK-type calcium-dependent potassium channels. Co-activation and interaction of N-, and/or L-type calcium and AHP currents present in somatic and proximal dendritic regions contributed to the adaptive properties of the model DG cell in response to long-lasting current injection. The model was used to predict changes in channel densities that could lead to epileptogenic burst discharges and to predict the effect of altered buffering capacity on firing behavior. We conclude that the clustered spatial distributions of calcium related channels, the presence of slow delayed rectifier potassium currents in dendrites, and calcium buffering properties, together, might explain the resistance of DG cells to the development of epileptogenic burst discharges.