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Previous Article | Next Article
The Journal of Neuroscience, July 1, 2000, 20(13):4829-4843
Ionic Mechanisms Underlying Repetitive High-Frequency Burst Firing in Supragranular Cortical Neurons
Joshua C. Brumberg, Lionel G. Nowak, and David A. McCormick Section of Neurobiology, Yale University School of Medicine, New Haven, Connecticut 06510
ABSTRACT
TOP
ABSTRACT
INTRODUCTION
Neocortical neurons in awake, behaving animals can generate high-frequency (>300 Hz) bursts of action potentials, either in single bursts or in a repetitive manner. Intracellular recordings of layer II/III pyramidal neurons were obtained from adult ferret visual cortical slices maintained in vitro to investigate the ionic mechanisms by which a subgroup of these cells generates repetitive, high-frequency burst discharges, a pattern referred to as "chattering." The generation of each but the first action potential in a burst was dependent on the critical interplay between the afterhyperpolarizations (AHPs) and afterdepolarizations (ADPs) that followed each action potential. The spike-afterdepolarization and the generation of action potential bursts were dependent on Na+, but not Ca2+, currents. Neither blocking of the transmembrane flow of Ca2+ nor the intracellular chelation of free Ca2+ with BAPTA inhibited the generation of intrinsic bursts. In contrast, decreasing the extracellular Na+ concentration or pharmacologically blocking Na+ currents with tetrodotoxin, QX-314, or phenytoin inhibited bursting before inhibiting action potential generation. Additionally, a subset of layer II/III pyramidal neurons could be induced to switch from repetitive single spiking to a burst-firing mode by constant depolarizing current injection, by raising extracellular K+ concentrations, or by potentiation of the persistent Na+ current with the Na+ channel toxin ATX II. These results indicate that cortical neurons may dynamically regulate their pattern of action potential generation through control of Na+ and K+ currents. The generation of high-frequency burst discharges may strongly influence the response of postsynaptic neurons and the operation of local cortical networks.
Key words: bursting; Na+ currents; chattering cells; visual cortex; afterdepolarizations; afterhyperpolarizations
INTRODUCTION
Cortical neurons in vivo frequently generate repetitive or single bursts of action potentials (Baranyi et al., 1993
; Gray and McCormick, 1996
The mechanisms of intrinsic bursting have been investigated in several different cell types (Llinas, 1988
Importantly, the firing properties of some cortical neurons can convert from single spiking to burst generating after prolonged activation (Kang and Kayano, 1994
In the present paper, the ionic mechanisms underlying both chattering and induced chattering in cortical neurons were studied using the ferret in vitro slice preparation. Results indicate that chattering, as well as induced bursting, is dependent on a sodium current and is calcium independent.
MATERIALS AND METHODS
Preparation of slices and solutions. Slices were obtained from 1- to 9-month-old male or female ferrets (Marshall Farms). The ferrets were deeply anesthetized with sodium pentobarbital (30 mg/kg) and decapitated. The brain was removed quickly, and the hemispheres were separated with a midline incision. Coronal slices of visual cortex were cut using a DSK microslicer (model DTK-1000, Ted Pella, Inc.). To maintain tissue viability, a modification of the technique developed by Aghajanian and Rasmussen (1989)
Sharp microelectrodes were pulled from medium-walled glass (1BF100; WPI) on a Sutter Instruments P-80 micropipette puller and beveled on a Sutter Instruments beveler to a final resistance of 80-120 M
. Electrodes were filled with 2 M potassium acetate (KAc) and sometimes with 1.5-2% (w/v) biocytin for subsequent histological identification of recorded cells.
To investigate the intrinsic mechanisms of high-frequency burst discharge in cortical neurons, ionic substitutions and pharmacological manipulations were used. In experiments examining the role of calcium in burst generation, several strategies were used. First, calcium was replaced in the bathing solution by 2 mM MnCl2 (NaH2PO4 was also removed from the bathing solution to prevent precipitation). A second strategy was to backfill the tips of the intracellular microelectrodes with the calcium chelator BAPTA (Sigma, St. Louis, MO) in concentrations of either 50 or 100 mM. Finally, the antiepileptic ethosuximide, which may reduce t-type Ca2+ channels, was added to the bathing solution (5 or 10 mM; Sigma).
The role of Na+ currents in burst generation was investigated using similar strategies. First, NaCl was replaced in the bathing medium with 126 mM cholineCl (leaving 27.25 mM Na+). Second, Na+ channels were blocked intracellularly using the quaternary lidocaine derivative QX-314 (10 mM in microelectrode; RBI, Natick, MA). Third, the Na+ channel blocker tetrodotoxin (TTX, 1 µM; Sigma) was either bath-applied or applied using a puffer pipette (see below). Fourth, the Na+ channel antagonist phenytoin was added to the bathing medium (120 µM; Sigma). Finally, the sea anemone sulcata toxin, ATX II (50 µM in pipette mixed in slice solution without divalent cations) (Calbiochem, La Jolla, CA), was pressure-ejected using brief pulses of pressurized N2 (10-250 msec; 200-350 kPa) applied to the back end of a micropipette (1-4 µm tip diameter) positioned on the surface of the slice in close proximity to the recording microelectrode. Each pulse resulted in the ejection of ~1-20 pl of solution. ATX II acts specifically to impede sodium channel inactivation, trapping the Na+ channel in a persistently conducting state (Romey et al., 1976
Intracellular recordings in vivo. To compare the electrophysiological properties of chattering cells in vitro with those obtained in vivo, these properties were measured in a few cells obtained from the primary visual cortex of halothane/N2O-anesthetized cats during the performance of other studies (Gray and McCormick, 1996
Data collection and analysis. Our present in vitro recordings were confined to layer II/III of the visual cortex because previous in vivo studies have identified chattering cells as residing within these layers (Gray and McCormick, 1996
Once a stable intracellular recording had been obtained (resting Vm of
60 mV or more negative, overshooting action potentials, ability to generate repetitive spikes to a depolarizing current pulse), the cell was classified, according to its discharge pattern to an injected current pulse, as either intrinsically bursting (intraburst frequency <300 Hz), regular spiking, fast spiking, or chattering (repetitive generation of two or more spikes per burst with an intraburst frequency of >300 Hz) (McCormick et al., 1985
Histology. After a recording was complete, the slice was then fixed in 4% paraformaldehyde in 0.1 M phosphate buffer. Slices were subsequently placed in 20% sucrose in 0.1 M phosphate buffer, sectioned on a freezing stage sliding microtome at 60 µm thickness, and reacted using an ABC kit (Vector Laboratories, Burlingame, CA) (Horikawa and Armstrong, 1988
RESULTS
Although extracellular and intracellular recordings in vivo have previously described the presence and properties of a subgroup of neurons, called chattering cells, that generate high-frequency (>300 Hz) burst discharges composed of relatively short duration (<0.6 msec measured at half height) action potentials, these cells are not commonly found in slices of cerebral cortex maintained in vitro. One possible explanation of the low incidence of chattering cells in vitro is that the discharge mode of these cells depends critically on factors modified by the in vitro technique. Therefore, as a first step in the present study, we determined what conditions are required for the occurrence of chattering in vitro. For that purpose we performed a series of extracellular recording experiments (13 experiments, 315 single-unit recordings) while neurons were activated by local application by pressure ejection of the metabotropic glutamate receptor agonist ACPD (500 µM in the pipette). ACPD was used only for the experiments in which we assessed the frequency of chattering cells using extracellular recording techniques; ACPD was not used for any subsequent recording experiments.
Two differences between in vitro and in vivo studies were examined. The first was the age of the animal. Previous in vivo intracellular recordings of chattering cells were obtained from adult cats (Gray and McCormick, 1996
Figure 1A,a shows a typical in vitro extracellular recording performed in a slice isolated from an adult (>3 months) ferret and maintained in an ACSF containing 1.2 mM calcium. The application of ACPD induced firing in a previously silent cell. Closer examination of the response (A,b, expanded trace) reveals that the firing consisted of high-frequency bursts of two to three action potentials each. The graph in Figure 1A,c represents the instantaneous firing frequency for the same cell and for the same epoch. Two frequency bands can be seen. The first one, which remains constant at ~420 Hz, corresponds to the intraburst frequency; the second one, between 1 and 11 Hz, corresponds to the interburst frequency that increases and then slowly decreases in response to application of ACPD. Note that although the interburst frequency varies in the 10-fold range, the intraburst frequency remains constant, a feature typical of chattering cells.
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Figure 1. ACPD (500 µM in pipette) activates chattering cells in a previously quiescent slice (A,a). Expanding the extracellular recording (A,b) reveals high-frequency repetitive bursts. The interburst frequencies are the bottom data points in A,c, and the intraburst frequency of this is >300 Hz (A,c, top traces). The developmental progression of the incidence of chattering is displayed in C. The bars represent the percentage of bursting neurons observed in the different aged animals or in B how the incidence of chattering was affected by different concentrations of extracellular Ca2+. The numbers above the bars (B, C) represent the number of chattering cells responsive to ACPD and the total number of units recorded.
The incidence of high-frequency (>300 Hz) bursting neurons in the supragranular layers exposed to different calcium concentrations during the extracellular recording experiments performed in adult (>3 months) animals is summarized in Figure 1B. High-frequency repetitive bursting neurons, using extracellular recording techniques, were observed in only 5% of the cells with 2 mM extracellular calcium; the incidence increased to 39% when 1.2 mM extracellular calcium concentration was used. The effect of calcium on the incidence of high-frequency bursting neurons is highly significant (
2 test, p < 0.0001).
The age of the animal also had a profound effect on the probability of observing high-frequency bursting neurons. With 1.2 mM calcium concentration in the ACSF, no cell with burst frequency >300 Hz could be observed in ferrets between 1 and 2 months old (Fig. 1C). In ferrets between 2 and 3 months old, the incidence of high-frequency bursting neurons was only 5%, but it increased, as mentioned previously, to 39% for ferrets older than 3 months. The effect of age on the incidence of high-frequency bursting neurons is also highly significant (
High-frequency bursting neurons as described above may not be equated with chattering cells; instead, the high-frequency bursting observed could have been an effect of ACPD on neurons that otherwise would not have generated such bursts. Intracellular recordings in the absence of ACPD confirmed, however, that chattering cells were observed only in animals that were older than 3 months of age. Recordings from visual cortical slices obtained from ferrets that were between 2 and 3 months of age revealed regular spiking (n = 24), intrinsically bursting (n = 4), or fast spiking neurons (n = 1) but no chattering cells (1.2 mM Ca2+ used), whereas intracellular recordings from animals that were 4 months of age or older did confirm the presence of chattering cells (Fig. 2).
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Figure 2. Response of a chattering cell to different amplitudes of current injection. Current pulses lasted 120 msec, and the amplitude of each pulse is to the left of each voltage trace (A). Increasing the amplitude of the injected current pulse increases the interburst frequency (B). C plots the interburst frequency (y-axis) as a function of the burst number (x-axis) for another neuron. The interburst frequency is lowest for the first interval and then shortens and reaches a plateau. This effect is independent of the intensity of the injected current (D). Plotted are the interburst frequencies (y-axis) of the first ( ), second (+), and third (
) interburst intervals as a function of the strength of the injected current pulse (x-axis). In every case the interburst interval is longest for the first interval, and there is no difference between the second and third intervals. Note the amplitude and time courses of the afterhyperpolarizations after a single burst (A, 0.2 nA) and after repetitive burst firing (A, 1.0 nA).
As a result, all subsequent experiments used visual cortical tissue obtained from ferrets that were at least 4 months old. In these conditions, and provided the ACSF contained only 1.2 mM calcium, chattering cells similar in all respects to those recorded in vivo (Fig. 3) could be recorded, although with intracellular recordings their incidence was lower than when using extracellular recording techniques (approximately only 4% of neurons recorded from intracellularly were classified as chattering cells). It is unclear why chattering cells were less frequently encountered using intracellular recording techniques. We did find it more difficult to obtain stable recordings from chattering cells than regular spiking pyramidal cells. Similarly, interneurons are also encountered at frequencies lower than predicted based on the known cytology. One possibility is that the chattering state of action potential generation can be disrupted by the small leak associated with sharp electrode recording.
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Figure 3. Properties of a chattering cell in the cat visual cortex in vivo. A, Intracellular injection of a depolarizing current pulse reveals repetitive burst firing at 71 Hz. B, Intracellular injection of a short depolarizing current pulse results in the activation of a single action potential that exhibits a prominent fast afterhyperpolarization and afterdepolarization. Short depolarizing current pulses did not activate bursts of spikes that outlasted the duration of the current pulse. C, Increasing the duration of the current pulse resulted in the generation of bursts of action potentials and eventually in the generation of repetitive burst firing.
The effects of calcium may be related to the fact that decreasing extracellular Ca2+ increases excitability in neuronal tissue (Frankenhaeuser and Hodgkin, 1957
Spiking characteristics of chattering cells
Chattering neurons in vitro (n = 67) were characterized by the generation of repetitive high-frequency bursts of action potentials in response to the intracellular injection of depolarizing current pulses (Fig. 2A). This pattern of repetitive burst generation is different from the behavior of the intrinsic burst-generating (IB) pyramidal cells that are most often recorded in layer V. In IB cells a burst of action potentials typically occurs only once at the beginning of the pulse response and is followed by repetitive single action potential discharge (McCormick et al., 1985
Another defining characteristic of chattering cells is their high intraburst frequency. At the population level, the mean intraburst frequency is 400 ± 57 Hz (n = 11, range 310-473 Hz). This is considerably higher than for IB neurons (166 ± 36 Hz, n = 6). Action potential width (measured at half height for the first action potential of the bursts) for chattering cells averages 0.40 ± 0.11 msec (n = 11, range 0.21-0.54). This is significantly less (t test, p = 0.03) than the width obtained for regular spiking cells recorded in the same conditions (0.53 ± 0.15 msec, n = 15, range 0.18-0.75), although the distribution of spike width for the two populations shows considerable overlap. The duration of action potentials in chattering cells was also significantly (p = 0.0015) less than spike width in IB neurons (0.61 ± 0.10 msec, n = 6, range 0.45-0.69 msec).
The action potential height for chattering cells (measured from spike threshold, for the first spike of the burst) averaged 74 ± 22 mV. This was not significantly different from action potential height for regular spiking (77 ± 6 mV; p = 0.6) or for IB neurons (82 ± 8 mV; p = 0.4). In chattering cells, the amplitude of the first action potential within the burst is the largest, with subsequent action potentials having only slightly smaller amplitudes, attributable most likely to Na+ channel inactivation. On average, the second action potential of the burst displayed a height 10% smaller than that of the first, owing to changes in both the maximal height of the action potential and a small increase in action potential threshold (Figs. 3A, 4A).
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Figure 4. Properties of chattering cells in ferret visual cortex in vitro. A, Response of a chattering cell to a 120 msec depolarizing current pulse (0.5 nA). The dotted line indicates the approximate threshold for action potential initiation for each action potential within the burst. Note that the threshold assumes progressively more depolarized levels, and the burst is terminated when the ADP no longer exceeds threshold. Decreasing the duration of the current pulse duration at threshold evokes either single spikes or subthreshold responses (B). Increasing the duration of the current pulse increases the number of action potentials in response, from one to three (C). Overlaying the three traces suggests that the additional action potentials result from the activation of additional spikes by the ADP. Action potentials have been clipped in the overlay. Membrane potential is
An important property of action potential generation in chattering neurons is that each action potential or burst of action potentials was followed by a fast afterdepolarization (ADP) (see below and Figs. 3, 4). A couple of cells showed features intermediate between bursting and chattering cells (see traces in Figs. 10C, 12A). Similarly to bursting neurons, these cells generate a burst of action potentials only at the beginning of the current pulse. However, these cells displayed spike width (<0.5 msec) and intraburst frequency (>300 Hz) similar to those of chattering cells (these cells have not been included for the comparative statistics given above). Another feature of these cells was the prominent ADP that followed single action potential firing. These cells typically could be induced to chatter with steady depolarization, as described in the second part of Results (see below).
In chattering cells, increasing the intensity of the injected current pulse decreased the interburst interval and therefore increased the number of burst discharges (n = 23 of 23 chattering neurons tested). For the chattering cell shown in Figure 2A, the interburst frequency in response to a +0.4 nA, 120 msec pulse was 25 Hz and at +1.0 nA it was 50 Hz.
The burst frequency (for all bursts, averaged for each current intensity) as a function of current injected is illustrated for another cell in Figure 2B. For this cell the slope of the regression line is 54 Hz/nA. At the population level, the slope of the burst rate versus injected current was 58 ± 23 Hz/nA (range 30-116 Hz/nA, n = 11). According to the regression line obtained between current injected and burst frequency, the amount of current required to obtain a burst discharge at 40 Hz is 0.77 ± 0.19 nA (range 0.50-1.10 nA), which is well within the range of the net synaptic current that cortical cells receive during responses to visual stimuli (Ahmed et al., 1998
Typically, the number of action potentials in the first burst is greater than the number of spikes in the next bursts (Fig. 2A). In general, the number of action potentials within a burst remains constant with increasing intensities of current injections. However, the number of action potentials in the first burst increased with increasing intensity of depolarizing current injected (Fig. 2A).
Interburst frequency versus current injected was also quantified for the successive bursts of the discharge (Fig. 2C,D). This analysis revealed that chattering cells did not show obvious adaptation in their burst discharge (Fig. 2C). In fact, we found that chattering cells displayed the opposite of adaptation, with the interburst frequency for the second interburst interval often being shorter than for the first. As a consequence, the slope for the first interburst frequency versus current injected is less steep than for the second or third (Fig. 2D). This was true also at the population level, for which the first interburst frequency versus current slope (43 ± 22 Hz/nA) was less steep than the one for the second (62 ± 27 Hz/nA) and third (63.7 ± 24 Hz/nA) interburst interval. When expressed as a ratio, the slope for the first interburst interval represented 64.7% that of the second interburst interval. The difference was found to be statistically significant (paired t test, p = 0.001 for first vs the second interburst, p = 0.005 for first vs third interburst interval). One possible explanation for this behavior is the occurrence of a larger number of spikes during the first burst, compared with those that follow. This larger number could lead to a stronger activation of potassium currents that would slow down the burst firing rate (see Fig. 9).
Previous studies have demonstrated that spike frequency adaptation results from the activation of various K+ currents, particularly a slow Ca2+-activated K+ current that underlies the slow AHP (Storm, 1990
Another characteristic of chattering cells was their ability to discharge either a single action potential or bursts of action potentials depending on the duration of the intracellularly injected depolarizing current pulse, both in vivo (Fig. 3C) (n = 5) and in vitro (Fig. 4C) (n = 8). The initiation of the first action potential in these neurons appeared to arise from the passive charging of the membrane in response to the depolarizing current pulse (Figs. 3A,B, 4A,B). Shortening the current pulse to 1-2 msec resulted in the initiation of only single action potentials, and these spikes displayed a fast afterhyperpolarization (AHP) followed by a fast afterdepolarization (Fig. 3B,C, 4B,C). This afterdepolarization appears to be actively generated and superimposed on the fast AHP, because the depolarizing phase of the fast AHP is much quicker than expected given the membrane time constant of these cells.
Increasing the duration of the depolarizing current pulses resulted in the afterdepolarization becoming suprathreshold for the generation of additional action potentials, until a burst of three to six spikes occurred (Figs. 3C, 4A,C). Within a burst, each subsequent action potential was triggered at more depolarized levels (Fig. 4A, dashed line) until the burst was terminated by an ADP that did not exceed spike threshold. Further increases in the duration of the depolarizing current pulse did not further increase the number of action potentials, because the burst was terminated by an afterhyperpolarization. After this afterhyperpolarization, additional bursts could occur, given a depolarizing current pulse of sufficient duration (Figs. 3A, 4A). No return excitation or "reverberation" was observed in these cells after cessation of the depolarizing current pulse, indicating that the chattering state of action potential generation required maintained depolarization.
Morphology of chattering cells
All morphologically identified chattering cells (n = 5) were pyramidal neurons in layer II/III and exhibited spiny apical dendrites extending to layer I where a terminal tuft was formed, similar to chattering cells that were intracellularly labeled in vivo (Gray and McCormick 1996
The subthreshold I-V plot in chattering cells is relatively linear
Unlike burst-generating thalamic neurons, chattering cells show little if any inward rectification or depolarizing "sag" in response to the intracellular injection of hyperpolarizing current pulses (n = 7). A series of membrane potential traces obtained in response to depolarizing and hyperpolarizing current pulses is presented in Figure 5B. The I-V plot (Fig. 5C) indicates that the resistance measured at the beginning of the plateau of the voltage deflection is not significantly different from the one measured near the end of the current injection. These results suggest that chattering cells possess little, if any, of the time-dependent anomalous rectifier conductance known as IAR or Ih.
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Figure 5. Chattering cells exhibit relatively linear membrane properties. A, The response of a supragranular chattering cell in response to a 300 msec 0.4 nA depolarizing current pulse. B, The same cell as in A in response to a family of hyperpolarizing and depolarizing current pulses. C, Plot of the membrane response at 45 and 135 msec (see B) after the onset of the current pulses versus the amount of current injected. There is no evidence for substantial time- or voltage-dependent rectification.
Burst generation does not depend on calcium entry
In many neuronal cell types, calcium plays an important role in shaping their discharge patterns. To investigate the role of calcium in burst generation in chattering cells, calcium was removed from the bathing solution and replaced with 2 mM Mn2+ (n = 4). In all four cases the neurons continued to discharge bursts of action potentials, even after ~1 hr in the low Ca2+-containing solution (Fig. 6A,B). Removing extracellular Ca2+ also did not affect the fast AHP after each action potential (Figs. 6B,D). Similarly, in extracellular recordings of single chattering neurons, reducing the bath concentration of Ca2+ to 0.5 mM and raising Mg2+ to 8-10 mM also did not inhibit repetitive burst firing in putative chattering cells that were activated by ACPD or the muscarinic agonist acetyl-
-methylcholine (n = 4; data not shown). However, decreasing extracellular calcium did affect the interburst interval, by lengthening it (Fig. 6, compare A and B). From this data it does not appear that calcium has an essential role in the generation of burst discharges, because they, as well as the fast afterdepolarization after single action potentials, are still generated after the block of transmembrane Ca2+ conductances (Fig. 6A,B).
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Figure 6. Transmembrane calcium entry is not essential to burst generation. Neither removal of Ca2+ from the bathing medium (compare A, B) nor chelation of intracellular Ca2+ by BAPTA (compare E, F) inhibited bursting. A and B represent a different cell than pictured in E and F. Note that the interburst interval is lengthened due to both manipulations. Recordings obtained from another neuron reveal that ADPs are present in nominal Ca2+ in the bathing medium (compare C, D). In C and D the action potentials have been clipped to highlight the presence of the ADPs.
To further examine the role of Ca2+ in burst generation, recordings were made with microelectrodes filled with the calcium chelator BAPTA (either 50 mM; n = 9; or 100 mM, n = 2) (Fig. 6D,E). In no instance (n = 11) did BAPTA prevent the generation of burst discharges and spike ADPs. Similar to the 0 mM Ca2+ condition, chelating intracellular calcium led to an increase in the duration on the interburst interval after BAPTA had diffused into the neuron but did not affect spike duration or the fast spike afterhyperpolarization in chattering cells. In contrast, intracellular recordings in regular spiking neurons with electrodes containing BAPTA (n = 9) revealed a decrease in spike frequency adaptation and a broadening of the action potentials, confirming that this Ca2+ chelating agent was diffusing into the neurons (data not shown) (Lancaster and Nicoll, 1987
In thalamocortical neurons, bursts of action potentials are generated by low-threshold Ca2+ spikes (Llinas, 1988
Burst generation is dependent on Na+ entry
To study the role of Na+ in burst generation, NaCl was replaced with equimolar cholineCl. As can be seen in Figure 7, chattering was inhibited in this neuron after 20 min of infusion of the cholineCl solution without abolishing action potential generation (Fig. 7, compare A and B) (n = 2). Additionally, decreasing extracellular Na+ decreased and eventually eliminated the ADP before action potential generation was inhibited (Fig. 7C). This result implicates a Na+ current in the generation of the single spike ADP.
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Figure 7. Decreasing the extracellular Na+ concentration inhibits chattering. A, In normal bathing solution, intracellular injection of a depolarizing pulse results in repetitive doublets of action potentials and spike afterdepolarizations. B, Twenty minutes after replacement of NaCl with CholineCl, the repetitive doublets and the initial burst of action potentials are suppressed. C, Overlay of the action potentials before and during wash in low Na+ reveals that the low Na+ solution suppressed the spike ADP.
To further study the role of Na+ in the generation of spike afterdepolarizations, neurons were recorded with electrodes backfilled with the intracellular Na+ channel blocker QX-314 (10 mM dissolved in 2 M KAc). The effective concentration of QX-314 was determined initially by varying its concentration within the electrode from 1 µM to 100 mM; 10 mM was picked because it inhibited action potential generation consistently after 12-15 min, and this effect occurred slowly enough that the action on the spike ADP could be observed in regular spiking pyramidal cells that had relatively thin spikes followed by an ADP. QX-314 was generally effective (n = 8 of 11) in reducing the amplitude of the ADP in these neurons before decreasing the number of action potentials evoked per 120 msec depolarizing pulse (+0.5 nA). The intracellular infusion of QX-314 into chattering cells (n = 2) blocked the generation of repetitive burst discharges before the complete inhibition of action potentials (Fig. 8A). Additionally, the slow depolarizing potential on which the action potentials are initiated was reduced in amplitude by QX-314.
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Figure 8. A persistent Na+ current underlies chattering. A, Intracellular injection of a depolarizing pulse immediately after obtaining this intracellular recording revealed this cell to be a chattering neuron. After 3 min of recording with an electrode filled with 10 mM QX-314 (dissolved in 2 M KAc), the repetitive burst firing stopped before action potential generation was inhibited. Puffer application of TTX (1 µM) inhibited bursting over time before blocking action potential initiation (B). Bath application of the anti-epileptic phenytoin (120 µM) also inhibited chattering (C) in another neuron (current pulse was +0.5 nA).
QX-314 modulates various channels in addition to Na+ channels, such as calcium and potassium currents (Connors and Prince, 1982
The role of sodium in the generation of chattering behavior was further examined using bath application of the anti-epileptic phenytoin (n = 3). Phenytoin decreases neuronal excitability by modulating Na+ currents, specifically by decreasing the persistent Na+ current (Chao and Alzheimer, 1995
The interburst interval is generated by an afterhyperpolarization
The cessation of action potential generation in a burst occurs when the spike fast afterdepolarization does not reach action potential threshold. After the generation of a burst of spikes there is an afterhyperpolarization that appears to be actively generated, because it hyperpolarizes the membrane potential below its resting level (Figs. 2A, 9A,C) and becomes increasingly larger with increasing numbers of action potentials (Figs. 7A, 9A). Block of action potential generation with QX-314 included in the recording microelectrode (10 mM) or bath application of tetrodotoxin (1 µM) revealed that AHP was also an active process at more depolarized membrane potentials (Fig. 9C) (n = 3). Although the ionic mechanisms of this afterhyperpolarization were not examined, it is most likely generated by a K+ current (Chen et al., 1996
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Figure 9. The interburst hyperpolarization is actively generated. A, Intracellular injection of a short depolarizing current pulse in a chattering cell generates either one or two action potentials with an increase in the duration of the pulse. Following the action potentials is a hyperpolarization that lasts for ~20-30 msec. B, Block of transmembrane Ca2+ currents with low Ca2+ and raised Mn2+ does not block the interburst AHP. C, Block of action potentials with tetrodotoxin reveals how the interburst AHP depends on the generation of a burst of action potentials.
Repolarizing phase of the chattering cell action potential
Examination of the derivative of the action potential waveforms revealed that the peak rate of repolarization of the chattering cell action potential (201.05 ± 19.19 V/sec, n = 11) is faster than that of regular spiking neurons (153.04 ± 23.82 V/sec, n = 15) but not significantly so (t test, p > 0.05). Computing the ratio of the peak rate of rise to the peak rate of fall for chattering cells (3.09 ± 0.04, n = 11) and regular spiking neurons (3.93 ± 0.02, n = 15) reveals a significant difference (t test, p < 0.03). The repolarizing phase of the chattering cell action potential was sensitive to bath application of TEA (1 mM, n = 2; 5 mM, n = 3) but was not sensitive to bath application of the A-type K+ channel antagonist 4-AP (5 mM, n = 3). Although preliminary, these results suggest that a fast non-A-type K+ current may mediate the repolarizing phase of the chattering cell action potential, as recently suggested for fast spiking interneurons (Erisir et al., 1999
Induction of rhythmic burst discharges
In 20 regular spiking neurons, the injection of a prolonged (300-1000 msec) depolarizing current pulse resulted in a train of single action potentials that exhibited relatively little spike frequency adaptation. In addition, in these cells, each action potential was followed by a fast AHP and a prominent ADP (Fig. 10D). Using several different manipulations, neurons with these spiking characteristics could be induced to discharge bursts of action potentials (Fig. 10). Four different protocols were used to switch a neuron from discharging trains of single action potentials to rhythmic bursts of action potentials (chattering): (1) intracellular injection of constant depolarizing current (~1.0 nA) for 15-60 sec; (2) intracellular injection of 30 +1.0-nA step pulses (500 msec duration); (3) raising of extracellular K+ from 2.5 to 5.0 mM; and (4) potentiation of the persistent Na+ current by the extracellular application of the sea anemone toxin ATX II.
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Figure 10. Induction of chattering in a regular spiking neuron. A-D, Same data presented in increasingly fine detail by expanding the time base. A, Induction protocol. The spike discharge pattern was examined by injecting a 500 msec duration depolarizing current pulse once every 2 sec before and after constant depolarization for 16 sec. B, C, The neuron responds to the depolarizing current pulses with a train of single action potentials (except for a doublet at the beginning of the pulse) before tonic current injection. After current injection, the neuron now responds to the current pulse with the generation of repetitive bursts. Action potentials and their derivative reveal the presence of fast spike afterhyperpolarizations and afterdepolarization.
Current injection induces rhythmic bursting
Intracellular injection of constant depolarizing current (approximately +1.0 nA) for 15-60 sec converted a subset of neurons from repetitive single action potential discharges to the generation of repetitive doublets or triplets (bursts) of action potentials (n = 10) (Figs. 10, 11). Three characteristics appeared to be important for a neuron to be able to be converted in this manner: a relatively short duration action potential (width at half height <0.7 msec), and the generation of a fast AHP and a fast ADP after each action potential (Figs. 10, 11). The generation of a prolonged (15-60 sec) period of action potentials through the injection of depolarizing current results in a broadening of the action potential by slowing the repolarizing phase (see below), allowing the spike ADP to become suprathreshold for the activation of an additional spike (Figs. 10, 11). After the induction procedure, the threshold for action potential initiation was at a more depolarized level for the first spike within the burst, and subsequent action potentials within the burst had thresholds at even more depolarized levels (paired t tests, p values < 0.05). Additionally, there was no observable change in Rin before versus after induction (paired t tests, p values > 0.05). In control experiments, neither regular spiking neurons with spike width at half amplitude >0.8 msec (n = 16) nor fast spiking presumed interneurons (n = 4) were convertible by constant depolarizing current injections.
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Figure 11. Overlay of action potentials before, during, and recovery from induced repetitive bursting. A, Overlay of the four traces in Figure 10D before and during induction reveals the action potentials to become broader in duration and a marked decrease in the fast spike afterhyperpolarization. Subsequently, the fast afterdepolarization is able to generate additional action potentials. B, During recovery from chattering induction, the action potential returns to its original duration and the fast afterhyperpolarization returns.
Step pulses similar to those used by Kang and Kayano (1994)
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Figure 12. Raising extracellular K+ induces bursting. Raising extracellular K+ from 2.5 mM (a) to 5.0 mM (b) induced bursting to the same depolarizing current pulse (bottom trace, +0.5 nA). Inset shows that in 5.0 mM K+, the ADP reaches threshold for the generation of a second action potential. C, Magnification of the initial responses for 2.5 mM K+ (a) and 5.0 mM K+ (b) highlighting the transition from single spiking to bursting.
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Figure 13. Potentiation of the persistent Na+ current induces bursting. Local application of ATX II (50 µM in pipette) evoked bursting in response to a 120 msec +0.5 nA current pulse (B). A represents the response before ATX II application.
Closer examination of the action potentials and the first derivative of their voltage revealed that induction of repetitive bursting was associated with a striking loss of the fast afterhyperpolarization, which allowed the afterdepolarization after each action potential to initiate additional spikes (Figs. 10D, 11A). In addition, induction of repetitive bursting was associated with a broadening of the action potential and a decrease in the maximal rate of fall of each spike. Quantitative analysis revealed that the spike widths of the action potentials after induction (0.64 ± 0.14 msec) of rhythmic bursting were significantly broader than the preinduction action potential (0.5 ± 0.12 msec, paired t tests, n = 8, p values <.05). Recovery from induction was associated with a reversal of these effects (Figs. 10D, 11B). Thus it appears that induction of repetitive burst firing results from a loss of the fast afterhyperpolarization, which broadens the action potential and allows the unmasking or further expression of a slow inward current underlying the ADP. The result of these two phenomena is that when the membrane repolarizes it reaches a more depolarized level that is still above threshold, and thus an additional action potential is generated and bursting is induced.
Interestingly, during the induction procedure, the derivative of the action potential revealed two distinct phases of rapid upswing during the rising phase of the action potential (Fig. 11A). Closer examination of the action potentials revealed that the transition between these two phases appeared as a "hump" on the rising phase of the action potential (data not shown). Indeed, we often noted with intracellular recordings that when chattering cells deteriorate, their action potentials fractionate into two active components, with the small component being generated first (data not shown). These results suggest that the action potentials in chattering cells are generated in at least two compartments, presumably being initiated in the initial segment of the axon, followed by propagation and generation of the action potentials in soma and/or dendrites (Stuart and Sakmann, 1994
Raising extracellular K+ induces bursting
The generation of bursts of action potentials appears to rely on the interplay of the fast AHP and ADP after action potential generation. To test this hypothesis, we increased [K+]o to determine whether this may induce the generation of repetitive burst discharges (Fig. 12). Indeed, increasing [K+]o from 2.5 to 5.0 mM changed the response of a subset of cortical neurons from the generation of a train of single action potentials to the generation of repetitive doublets of action potentials (Fig. 12). Comparison of the action potentials in the normal and high K+ conditions revealed that spikes were broadened, the amplitude of the fast AHP was decreased, and the spike ADP became suprathreshold for the initiation of an additional action potential (Fig. 12, inset).
The raising of extracellular K+ was effective in inducing repetitive doublet firing in five of six neurons tested, all of which had prominent ADPs. For three of these five neurons, current injections were also used to induce repetitive doublet firing. The pattern of action potential generation after current-induced alterations and those induced by raising [K+]o were similar (data not shown).
Potentiation of the persistent Na+ current induces bursting
To examine whether modifications of the inactivation of Na+ currents could induce chattering, we applied the sea anemone toxin ATX II. This toxin reduces Na+ channel inactivation but does not affect activation (Romey et al., 1976
DISCUSSION
Extracellular recordings in awake, behaving animals reveal that bursts of action potentials at rates of >300 Hz are relatively common (Bair et al., 1994
Ionic mechanisms of intrinsic burst generation in cortical neurons
Previous studies of the ionic mechanisms of burst generation in cortical neurons have focused largely on low-frequency (<300 Hz) burst firing in large layer V neocortical pyramidal cells or in hippocampal pyramidal neurons. These bursts appear as an all-or-none discharge of two to five action potentials with each successive spike decreasing in amplitude and broadening in duration and may be generated by either the activation of a slow Ca2+ current in the dendrites (Helmchen et al., 1999
Our present results strongly support the role of Na+, but not Ca2+, currents in the initiation of a spike afterdepolarization that is critical for the generation of high-frequency burst discharges in chattering neurons. Two important factors in the generation of high-frequency burst discharges were short duration action potentials, which allow the occurrence of high-frequency (>300 Hz) burst discharges, and the activation of a fast spike afterdepolarization that was large enough to reach spike threshold for the initiation of an additional action potential (Fig. 4). The intracellular injection of short-duration depolarizing current pulses did not generate burst discharges in these cells in an all-or-none fashion. The generation of a high-frequency burst required both the maintained depolarization of the cell with the intracellular current injection as well as the occurrence of an afterdepolarization. This result suggests that these cells may generate action potentials either singly, in response to a short-duration depolarizing postsynaptic potential, or in bursts, with varying numbers of action potentials, depending on the duration of the underlying synaptic depolarization. The number of spikes is limited, however, to typically four or five, owing to the activation of ionic currents that repolarize the membrane (Fig. 9).
Calcium plays a minor role in burst generation
The block of transmembrane Ca2+ currents with low Ca2+ and added Mn2+ did not block high-frequency burst firing in our experiments, indicating a nonessential role for transmembrane Ca2+ entry in the generation of these events. Similarly, the intracellular chelation of Ca2+ with BAPTA also did not block the generation of high-frequency burst discharges. However, this evidence is less strong because the chelation of intracellular Ca2+ may enhance burst firing in some cortical neurons, presumably through the removal of Ca2+-dependent inactivation of Ca2+ currents (Friedman and Gutnick, 1989
This is not to say that Ca2+ plays no role in the generation of chattering. In fact when chattering cells were recorded in bathing solution without Ca2+ or with electrodes filled with BAPTA, there was an increase in the intraburst frequency and a decrease in the interburst frequency. Thus it appears that Ca2+ can modulate the interburst frequency of chattering cells (Fig. 14B).
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Figure 14. Summary of the proposed mechanisms for chattering. Repetitive high-frequency bursting in response to a depolarizing current pulse is typical of chattering cells in vitro (A). Magnification of the bursts highlights the presence of fast AHPs after each action potential. Each burst is terminated by a Na+-dependent ADP that does not reach spike threshold (B) and is followed by the interburst AHP. The high-frequency bursts that typify chattering cells result as an interaction between fast Na+ spikes and a fast ADP; the interburst interval is governed by the rate at which the membrane repolarizes (C, interburst AHP) and the amplitude of any extrinsic depolarizing influences.
The activation of a Na+ current underlies bursting in chattering cells
The activation of a Na+ current plays an important role in burst generation in chattering cells, because replacement of NaCl with cholineCl, the extracellular application of tetrodotoxin or phenytoin, and the intracellular infusion of QX-314 all inhibited the fast spike afterdepolarization and bursting before inhibiting action potential generation (Franceschetti et al., 1995
One possibility is that chattering and the spike afterdepolarization are generated by the activation of a persistent Na+ current in the soma and/or dendrites. The persistent Na+ current is activated rapidly (French et al., 1990
Factors influencing chattering in vitro
The generation of rhythmic high-frequency burst discharges is not generally observed with the in vitro slice technique. Several possible variables may contribute to this, including the age and species of the animals used, the temperature and composition of the ionic medium, and the style of recording chamber (e.g., interface or submerged). We have not observed chattering cells in vitro in tissue from ferrets that are less than ~4 months of age. In rats, the action potential, the persistent Na+ current, and the ability to generate bursts are not mature until ~1 month postnatally (McCormick and Prince, 1987
An additional important factor is likely to be the composition of the ionic medium. We observed a significantly higher number of chattering cells in medium containing 1.2 mM Ca2+, and recently we have also observed that lowering Mg2+ from 2.0 mM to a more physiological level of 1.0 mM and raising K+ from 2.5 mM to a more physiological value of 3.5 mM also significantly enhances the incidence of chattering in vitro (our unpublished observations). Another important variable is likely the species of animal used, because chattering cells have not yet been observed in rodent cortex.
Is chattering a cell type or a discharge mode?
Our present results, and those of Kang and Kayano (1994)
The critical factor in this transformation appears to be the reduction in the fast afterhyperpolarization, which then allows the ADP to reach spike threshold (Fig. 4). The reduction of the fast AHP could be caused by a decrease in the driving force of K+, perhaps from accumulation of K+ in the pericellular space (Frankenhaeuser and Hodgkin, 1956
Does mode switching occur naturally? It is not yet known whether neurons in vivo switch between regular spiking and rhythmic bursting, although a significant incidence of burst firing occurs in awake behaving animals (Otto et al., 1991
Are chattering cells actually regular spiking cells in the "chattering mode"? We have not observed chattering neurons, with either extracellular or intracellular recordings, to change to the regular spiking mode in the absence of stimulation or after hyperpolarization. This suggests that a subset of cortical neurons are persistent chatterers and therefore identified as chattering cells (Gray and McCormick, 1996
Functional consequences of burst discharges
Many cortical synapses appear to have high failure rates (Allen and Stevens, 1994
In vivo it has been demonstrated that bursts convey more information than single spikes (Cattaneo et al., 1981
FOOTNOTES Received Jan. 21, 2000; revised April 13, 2000; accepted April 14, 2000.
This work was supported by National Institute of Mental Health National Research Service Award F32MH12358-01 (J.C.B.) and National Eye Institute Grant 1-R01-EY12388 (D.A.M.). Additional information may be obtained at www.mccormicklab.org. Thanks to Hal Blumenfeld, Anita Luthi, and James Monckton for critical discussions and reviewing this manuscript.
Correspondence should be addressed to Dr. Joshua C. Brumberg, Section of Neurobiology, Yale University School of Medicine, 333 Cedar Street, New Haven, CT 06510. E-mail: brumberg{at}biomed.med.yale.edu.
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