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The Journal of Neuroscience, January 1, 2000, 20(1):114-122
Electrophysiological Characterization of Voltage-Gated
K+ Currents in Cerebellar Basket and Purkinje Cells: Kv1
and Kv3 Channel Subfamilies Are Present in Basket Cell Nerve
Terminals
Andrew P.
Southan and
Brian
Robertson
Electrophysiology Group, Department of Biochemistry, Imperial
College of Science, Technology and Medicine, London SW7 2AY, United
Kingdom
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ABSTRACT |
To understand the processes underlying fast synaptic transmission
in the mammalian CNS, we must have detailed knowledge of the identity,
location, and physiology of the ion channels in the neuronal membrane.
From labeling studies we can get clues regarding the distribution of
ion channels, but electrophysiological methods are required to
determine the importance of each ion channel in CNS transmission.
Dendrotoxin-sensitive potassium channel subunits are highly
concentrated in cerebellar basket cell nerve terminals, and we have
previously shown that they are responsible for a significant fraction
of the voltage-gated potassium current in this region. Here, we further
investigate the characteristics and pharmacology of the
voltage-dependent potassium currents in these inhibitory nerve
terminals and compare these observations with those obtained from
somatic recordings in basket and Purkinje cell soma regions. We find
that  -DTX blocks basket cell nerve terminal currents and not somatic
currents, and the IC50 for -DTX in basket cell terminals
is 3.2 nM. There are at least two distinct types of potassium currents in the nerve terminal, a DTX-sensitive low-threshold component, and a second component that activates at much more positive
voltages. Pharmacological experiments also reveal that nerve terminal
potassium currents are also markedly reduced by 4-AP and TEA, with both
high-sensitivity (micromolar) and low-sensitivity (millimolar)
components present. We suggest that basket cell nerve terminals have
potassium channels from both the Kv1 and Kv3 subfamilies, whereas
somatic currents in basket cell and Purkinje cell bodies are more homogeneous.
Key words:
potassium channels; cerebellum; synapse; basket cell; electrophysiology; mouse
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INTRODUCTION |
A proper understanding of many CNS
diseases and disorders requires identification of the ion channels
underlying them and knowledge of their normal physiological roles.
Recently, considerable progress has been made in understanding certain
forms of epilepsy (Biervert et al., 1998 ; Schroeder et al., 1998; Smart
et al., 1998), and episodic ataxia (Browne et al., 1994), both of which may be caused by mutations in genes encoding voltage-gated K (Kv) channels. Kv channels are crucial in regulating neuronal activity. The
proteins that comprise these ion channels belong to an extensive and
diverse group that exhibits discrete and selective patterns of
distribution throughout the brain (e.g., Kv1 subfamily: McNamara et
al., 1993, 1996; Wang et al., 1993, 1994; Sheng et al., 1994; Rhodes et
al., 1995, 1996; Kv3 subfamily: Weiser et al., 1994; Kv4 subfamily:
Sheng et al., 1992). Some Kv channel subtypes are concentrated in
specific groups of neurons and are often found tightly clustered within
distinct neuronal compartments (Wang et al., 1994; Rhodes et al.,
1995). Knowledge of such precise targetting has important implications
for defining the roles individual K+
channels play in regulating neuronal function. Two members of the Kv1
subfamily of potassium channels, Kv1.1 and 1.2, are densely concentrated in the distinctive nerve terminal
(pinceau) region of cerebellar basket cells,
surrounding the axon initial segment of Purkinje neurons (McNamara et
al., 1993; Wang et al., 1993). Such a dense concentration would
indicate that these channel -subunits play a significant role in
determining membrane excitability in this nerve terminal and in
regulating synaptic transmission between basket cells and Purkinje
neurons. However, physiological identification of ion channels in CNS
nerve terminals is difficult, principally because of their small size,
and consequently little direct data are available. Recently we have
demonstrated that whole-cell patch-clamp recordings from mouse
cerebellar basket cell terminal processes are possible (Southan and
Robertson, 1998a), and we showed that -dendrotoxin (which blocks
certain Kv1 subunits) blocks a fraction of voltage-dependent
K+ current in this region. Thus far,
presynaptic potassium channels have only been examined using direct
patch-clamp recordings from the giant excitatory terminal, the Calyx of
Held (Forsythe, 1994); the present study represents the first detailed
biophysical and pharmacological characterization of Kv channels in an
inhibitory CNS nerve terminal. Direct study of inhibitory, indeed any,
CNS nerve terminals is important, because different synaptic terminals have enormously varying properties, dependent on a large number of
factors, including target cell, presynaptic anatomy, and precise distribution of their constituent ion channels and receptors (Poncer et
al., 1997; Reyes et al., 1998; Walmsley et al., 1998). Our data
indicate that in addition to a DTX-sensitive
K+ current, there exists an additional
component that has several similarities to cloned channels belonging to
the Kv3 subfamily. We also examine the properties of
K+ currents in basket and Purkinje cell
somata and contrast these with the basket terminal potassium currents.
These data give us an insight into the molecular identities of native
K+ currents in defined regions of an
important mammalian CNS circuit.
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MATERIALS AND METHODS |
Tissue preparation and recording methodology has been previously
described in detail (Southan and Robertson, 1998a,b).
Tissue preparation and solutions. Cerebellar slices
were prepared from 3- to 5-week-old TO strain male mice (Charles
River). After cervical dislocation and decapitation, the brain was
immediately dissected out into a chilled (~4°C) oxygenated
sucrose-based artificial CSF (ACSF) solution. Parasaggital
cerebellar slices (250-µm-thick) were then prepared in cold sucrose
ACSF solution (see below) using a Vibroslice (Campden Instruments,
Loughborough, UK). A submerged-type incubation chamber containing the
standard ACSF solution bubbled with 95% O2 and
5% CO2 housed the slices at room temperature
(20-23°C) until recordings commenced (20 min to 6 hr maximum after
slicing). The standard ACSF contained (in mM): NaCl 124, KCl 3, NaHCO3 26, NaH2PO4 2.5, MgSO4 2, CaCl2 2, and
D-glucose 10, and was maintained at pH 7.3-7.4 with 95%
O2 and 5%
CO2. The sucrose-based dissection/slicing solution was identical to this standard ACSF with the exception of
isosmotic substitution of sodium chloride with sucrose (74.5 gm/l).
Recording apparatus and techniques. For electrophysiological
recording, slices were placed in a glass-bottomed recording chamber (volume, ~1 ml) and continuously perfused with ACSF at 3-5 ml/min. Individual neurons and nerve terminals were visualized with
differential interference contrast (DIC) optics at 630× overall
magnification using an Axioskop FS microscope (Carl Zeiss, Oberkochen,
Germany). For somatic recordings, Purkinje cells were readily
identified by their large soma (~20 µm diameter) and distinctive
distribution in the cerebellar folia; basket cells were identified
according to their location in the lower third of the molecular layer
and by their characteristic size (soma diameter, ~10 µm). Basket
cell nerve terminals could be visualized as fine processes surrounding the Purkinje cell soma, descending to the axon initial segment region
(Ramón y Cajal, 1911; Palay and Chan-Palay, 1974). All basket
cell soma and nerve terminal recordings were unambiguously confirmed
using Lucifer yellow fluorescence microscopy after all electrophysiological measurements had been taken (Southan and Robertson, 1998a).
Recordings were made using patch-clamp techniques with electrodes of
resistance between 3 and 6 M for somatic recording and 10-15 M
for basket cell nerve terminal recording. All electrodes were
fabricated from filamented borosilicate glass (GC150-F10; Clark
Electromedical Instruments, Reading, UK) using a PP83 microelectrode puller (Narishige, Tokyo, Japan) and were filled with an
intracellular solution consisting of (in mM): KCl 140;
MgCl2 1; CaCl2 1; EGTA 10;
and HEPES 10, pH 7.3. For basket cell recordings, this intracellular solution was supplemented with 1-4 mg/ml Lucifer yellow (Lithium salt;
Sigma, Poole, UK) to confirm cell identity after recording.
Electrophysiological recordings were made using an EPC-9 amplifier
(Heka Electronik, Lambrecht, Germany), controlled by Pulse software
(version 8.05; Heka) running on a Macintosh computer (Power PC,
7500/100). Data were sampled between 4 and 24 kHz after being filtered
at one-third the appropriate sampling frequency. Mean series resistance
for basket somatic recording was 18 ± 1 M (n = 25), and 75-95% compensation was used. Terminal series resistance
(14-30 M) was monitored and compensated for (65-95%) throughout.
Where the series resistance of the cells was unstable, recordings were excluded from analysis. Except where indicated, currents were leak-subtracted on-line using a p/4 subtraction routine.
Data analysis was performed using Axograph (version 3.5; Axon
Instruments, Foster City, CA), Pulsefit (version 8.05; Heka), Igor
(version 2.04; Wavemetrics) and Kaleidagraph (version 3.04) software. Data are presented as mean value ± SEM, where
n = number of cells. Statistical significance was
determined using a Student's t or Wilcoxon signed rank test
(Statview II; Abacus Concepts, Calabasas, CA). Activation curves were
determined by fitting a Boltzmann expression to calculated conductance
(Gv) values. The equation used was: Gv = Gmax/{1 + exp [ (V V1/2)/k]}, where Gmax is the maximum conductance,
V the membrane voltage,
V1/2 the half activation voltage, and
k the slope factor.
Concentration response curves were constructed using the logistic
function: Response = maximum response/[1+
(IC50/concentration)], where data were poorly
fitted by this equation, a satisfactory fit was obtained from the sum
of two separate functions.
Drugs and peptidergic toxins. Toxin I and toxin K were
obtained by purification of Dendroaspis polylepis venom
using previously described methods (Robertson et al., 1996);
-DTX,  -DTX, charybdotoxin, apamin, agitoxin-2 (AgTX-2), and
margatoxin (MgTX) were obtained from Alomone Labs (Jerusalem, Israel).
Tetraethylammonium (TEA), 4-aminopyridine (4-AP), and tetrodotoxin
(TTX) were obtained from Sigma. All drugs were bath-applied, and salts
were ANALAR or equivalent grade and obtained from BDH Chemicals
(Poole, UK) or Sigma.
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RESULTS |
We have recorded from three different membrane locations on two
different cell types in the mouse cerebellum, namely Purkinje cell
somata, and the somata and terminals of basket cells, which make
inhibitory synapses on axosomatic regions of Purkinje cells. To
facilitate direct comparisons between K+
currents, identical solutions and protocols were used throughout. In
all basket cell experiments, TTX was included at 1 µM. In
Purkinje cell-excised somatic patches, the voltage-gated
Na+ current was negligible (Fig.
1A).
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Figure 1.
Activation curves from data obtained from
soma and nerve terminal recording sites. Insets show
typical currents recorded from each region using +10 mV incrementing
steps to +50 mV from a holding potential of 90 mV. A,
Purkinje cell soma outside-out voltage-clamp experiments gave
activation data with threshold at approximately 50 mV. The Boltzmann
function shown superimposed on the data points gave
V1/2 and slope values quoted in
Results. B, Whole-cell voltage-clamp responses
from the basket cell soma region exhibited similar activation
characteristics to Purkinje cell soma responses. C, In
basket cell terminal recordings, conductance threshold was more
negative, approximately 70 mV, and was best fit with the sum of two
Boltzmann functions. Values given in Results.
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Potassium currents in Purkinje somata
Because the whole-cell potassium currents from Purkinje cell
somatic recordings are extremely large (peak amplitude often exceeding
15 nA during a step from 90 to +30 mV), we chose to study these
currents in outside-out patches, where more satisfactory voltage
control could be achieved. Patches were excised within 30 sec of
establishing the whole-cell configuration and held at a membrane
potential of 90 mV. Virtually all patches pulled off from Purkinje
cell somatic regions yielded significant outward currents, most of
which had peak amplitudes of >400 pA at +30 mV with patch electrodes
of 3-5 M resistance. Mean maximum conductance was 7.5 ± 0.7 nS (n = 6). Potassium conductance-voltage curves were
well-fitted with a single, first-order Boltzmann function, yielding a
mean V1/2 of 17.3 ± 0.7 mV
(n = 6) and slope factor (k) of 11.3 ± 0.6 mV (Fig. 1A; n = 6). Threshold
for current activation was approximately 50 mV. For the voltage step
from 90 to 40 mV, mean activation time constant measured by a
single exponential fit was 2.9 ± 0.3 msec (n = 6), decreasing exponentially with voltage to 0.2 ± 0.03 msec
(n = 6) for the step from 90 to +50 mV (Fig.
2A). Single
exponentials provided a good fit to the current activation phase (data
not shown). Only slight inactivation was seen during 15 msec steps (and
then only at more positive voltages); however, more marked current
decay was observed on longer (200 msec) voltage steps (Fig.
3C,E). Large and rapid tail
currents were consistently seen after repolarization to 90 mV.
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Figure 2.
Activation time constant data for Purkinje cell
soma and basket cell soma and nerve terminal recording sites.
A, Purkinje cell soma data. B, Basket
cell soma data. C, Basket cell terminal data.
D, Repetitive voltage steps to +20 mV from 90 mV evoke
total terminal Kv current, which is not potentiated by repetitive
pulsing. Note, current traces are not leak-subtracted and also show
action currents.
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Figure 3.
Concentration-response curves for the
potassium channel blockers TEA and 4-AP obtained using outside-out
patches pulled off from basket cell and Purkinje cell soma regions.
Closed circles show block of peak current, and
open circles show block of steady-state current
throughout. A, B, TEA reduced basket cell somatic
currents in a dose-dependent fashion; peak and steady-state
current exhibited similar sensitivity. C, D,
Purkinje cell soma currents were reduced by TEA at concentrations
>0.01 mM, again peak and steady-state values
were similar, and virtually all of the current was blocked by 10 mM TEA. E, F, 4-AP blocks Purkinje cell
somatic currents; peak and steady-state current show similar
sensitivity to this agent. IC50 values quoted in Results
were obtained from the fits illustrated here.
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Somatic and nerve terminal potassium currents in basket cells
Activation curves were constructed for basket cell somatic and
nerve terminal voltage-gated potassium currents using whole-cell voltage-clamp data. Currents were obtained from a holding potential of
90 mV, through a series of incrementing voltage steps (+10 mV) up to
+50 mV. Conductance was calculated from peak current data for each
voltage step and fitted with a Boltzmann equation (see Materials and Methods).
For whole-cell basket somatic currents, maximum conductance was
86.6 ± 17.3 nS (n = 9), and the mean activation
curve was fitted with a single Boltzmann function, with a
V1/2 = 18.4 ± 0.8 mV
(n = 9) and slope factor of 13.0 ± 0.7 mV (Fig.
1B; n = 9).
In contrast, the conductance-voltage curve obtained from measurements
at the nerve terminal was poorly fitted by a single Boltzmann function,
and a better fit was obtained with the sum of two Boltzmann functions
(Fig. 1C). The first component, comprising some 38% of the
total curve, had a V1/2 = 52.8 ± 2.5 mV (n = 9), with k = 8.3 ± 2.1 mV (n = 9), whereas the second, more positively activating component (62% of the total K+
conductance) had a V1/2 = 6.5 ± 7.3 mV (n = 9), with k = 18.1 ± 2.4 mV (n = 9). Maximal conductance for the
whole-cell terminal K+ current was
11.5 ± 1.6 nS. Current threshold was approximately 50 mV for
the somatic current and approximately 70 mV for nerve terminal recordings.
For both somatic and terminal recordings, potassium current activation
kinetics were rapid, voltage-dependent, and well-fitted by a single
exponential function. For the step from 90 to 40 mV,
K+ current activation time constants were
2.6 ± 0.9 ms (n = 4), decreasing to 0.5 ± 0.1 msec (n = 4) at +50 mV in basket soma (Fig.
2B). For K+ current in
basket cell terminal regions, activation time constants were slightly
faster, being 1.8 ± 0.3 msec at 40 mV and 0.4 ± 0.02 msec
for the step from 90 to +50 mV (n = 4; Fig.
2C). In mammalian expression systems, Kv1.2 homomeric
currents display a remarkable "pulse-potentiation" when activated
by strong depolarizing voltage steps at frequencies >1 Hz (Grissmer et
al., 1994; P. McIntosh and B. Robertson, unpublished observations. This
also occurs in tandem-linked Kv1.1/1.2 channels). Because the basket terminal has a significant proportion of Kv1.2 channel subunits, we
were interested to find out whether a similar phenomenon occurred in
native membranes. Figure 2D shows that when subjected
to an identical voltage-stimulation protocol as Kv1.2 channels in cell lines (where an approximately five times enhancement of activation rate
was observed), no potentiation occurred; indeed current amplitudes declined slightly with increasing pulse numbers. Similar observations were made in four other nerve terminal recordings.
Basket cell and Purkinje cell somatic current pharmacology
Basket cells
We have previously shown that during 200 msec voltage
steps from 90 to +30 mV, the somatic potassium current recorded from basket cells is reduced by high concentrations (10-30 mM)
of TEA, yet is insensitive to a number of other potassium channel
blockers; namely 4-AP, -DTX, -DTX, Toxin I, Toxin K, apamin, and
CbTX (Southan and Robertson, 1998a; see also Table
1 for concentrations). Here, we extend
these observations examining margatoxin (MgTX) and agitoxin-2 (AgTX-2),
which are reported to be potent blockers of Kv1.1 and Kv1.2 potassium
channel subunits in oocytes (Garcia et al., 1994; Hopkins et al.,
1996). Additionally, Koch et al., (1997) have shown that considerable
MgTX binding is present in the cerebellum. However, at the high
concentrations tested here (10 nM), we observed no
significant effects of either of these toxins on basket cell somatic
potassium current (Table 1).
A full concentration-response relationship for TEA was obtained using
outside-out patches (n = 5) of somatic membrane
obtained from basket cells (Fig. 3A,B). Surprisingly, the
majority (~80%) of outside-out patches pulled off from basket cell
somata yielded no measurable voltage-activated potassium currents, this
was in spite of large currents (see above) being present in the
whole-cell configuration before the patch was excised. Patches were
always pulled off from within the central region of the basket soma. This may suggest that voltage-gated potassium channels in the somatic
region of these neurons are clustered in certain "hot" zones on the
membrane surface.
In the remaining 20% of excised patches that did exhibit appreciable
potassium current during voltage steps from 90 to +30 mV mean control
amplitude was 303 ± 177 pA (range, 83-1008 pA; n = 5). These currents were blocked by TEA, and the TEA
concentration-response curve was fitted with a
single component, yielding IC50 values of 99 µM for peak current and 206 µM for steady-state current (Fig.
3A,B; n = 5). Ninety percent of the total
somatic potassium current was blocked by 10 mM
TEA. At TEA concentrations >100 µM, the
remaining K+ current was essentially
noninactivating. Block by TEA was rapid in both onset and washout
(within 10 sec of solution change), and was fully reversible.
Purkinje cells
In these experiments, K+
current pharmacology was examined using outside-out patches excised
from central regions of the Purkinje cell soma, well away from the axon
hillock. Voltage-gated K+ current (200 msec voltage step from 90 to +30 mV) in these isolated membrane
patches had a mean amplitude of 668 ± 112 pA (range, 253-1400
pA; n = 12). Purkinje soma voltage-activated
K+ current was completely insensitive to
-DTX, Toxin I, Toxin K, and -DTX (all at 200 nM). Current was also resistant to block by
apamin, CbTX, MgTX, and AgTX-2 (Table 1). However, both TEA and 4-AP
were effective blockers of these somatic membrane
K+ currents. For TEA,
IC50 values were calculated as 131 µM for peak current, similar to the value of
173 µM (n = 6) obtained from
measurements of block of steady-state current (Fig. 3C,D). For the K+ channel blocker 4-AP,
IC50 values were 133 µM
for peak current and 271 µM for steady-state
current (n = 6; Fig. 3E,F; see also Table
1). Once again, block by these agents was rapid in onset and fully
reversible, and almost all K current could be blocked at high
concentrations of TEA and 4-AP.
Basket cell terminal pharmacology
Recording membrane currents from basket cell terminal processes
presents considerable technical obstacles. Their small size (typically
 2 µm; Ramón y Cajal, 1911; Palay and Chan-Palay, 1974) means
visualization, accurate electrode positioning, and successful formation
of G seals is particularly challenging, even when using DIC optics
and high resistance (up to 15 M), small tip aperture patch
electrodes. Confirmation of the identity of the recording site is an
absolute requirement when recording from these fine basket cell
processes, requiring successful, unambiguous retrograde loading of
basket interneurons with an intracellular tracer such as Lucifer yellow
during electrophysiological recording. Although the success rate for
terminal recordings is extremely low compared to that achievable for
somatic recording, we have nevertheless been able to achieve a
sufficient number of whole-cell recordings where both high-quality
electrophysiological data and certain identification was obtained. We
have shown that 200 nM -DTX rapidly blocks a significant
fraction of basket cell terminal potassium current and dramatically
increases IPSC frequency and amplitude (Southan and Robertson 1998a,b).
Here, we present data for nerve terminal patch-clamp recordings through
an extensive range of concentrations of -DTX (0.1-500
nM; Fig.
4A,B). A single component logistic curve fit to these data would indicate that the
IC50 for -DTX block of voltage-gated
K+ currents in basket cell terminals is
3.2 nM (n = 6). Significantly, the -DTX-induced block of potassium current is maximal at 50 nM, with no further
K+ current reduction occurring with either
200 or 500 nM. The remaining DTX-insensitive
terminal current (40-70%; n = 7) was sometimes, although not always, slower to reach peak amplitude, and only very
slowly inactivating over the time course of the voltage pulse. Figure
4C shows how the terminal potassium steady-state
current-voltage relationship is modified after exposure to 200 nM -DTX (n = 3) with the
threshold of the remaining potassium current being some 20-30 mV more
positive than the threshold of the control current. Fitting Boltzmann
curves from these I-V data revealed again that control
K+ conductance required two components,
with V1/2 values of 42 mV
(k = 7 mV) and 2 mV (k = 16 mV)
respectively; these values are consistent with those described above
under control conditions (see above), whereas the "high-threshold"
potassium conductance in 200 nM -DTX was
well-fitted with a single Boltzmann curve, with a
V1/2 = +4.1 mV (k = 16.2 mV); n = 3 terminals.
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Figure 4.
-DTX blocks a proportion of nerve terminal
potassium current. A, Concentration-response data
showing reduction of nerve terminal potassium steady-state current by
-DTX. The IC50 is 3.2 nM. B,
Example basket cell terminal currents through a range of -DTX
concentrations. C, In the presence of a supramaximal
concentration of -DTX, the current-voltage curve is shifted to the
right, moving current threshold from approximately 60 to 40 mV for
this example (n = 3).
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Block of "whole terminal" voltage-activated
K+ current by external TEA was tested
through a range of concentrations between 0.01 and 30 mM
(n = 3-7 at each concentration). Block by TEA was also
rapid in onset (apparent within 10 sec of solution change), blocking up
to a mean of ~70% of the steady-state current at the highest
concentration examined. The data points were poorly fitted using a
single component logistic curve and are more satisfactorily fit using
the sum of two components, with corresponding
IC50 values for external TEA of 170 µM and 25 mM (Fig.
5A,B). The less TEA-sensitive component should be taken as an estimate, because values for inhibition with higher concentrations of TEA were difficult to obtain.
Interestingly, 4-AP, which had no effects on basket cell somatic
potassium current even at concentrations up to 5 mM (Southan and Robertson 1998a), reduced nerve
terminal current at concentrations of  10 µM.
At the limit of solubility in our ACSF (5 mM),
~60% of the steady-state current was blocked by 4-AP. Block of
terminal peak potassium current by 4-AP was not significantly different
from that of the steady-state data (200 msec steps). Figure 5,
C and D, shows block of nerve terminal potassium
current for a range of concentrations of 4-AP. Mean data points (Fig.
5C) were once again poorly fit by a single component curve
and were therefore fitted with the sum of two curves.
IC50 values obtained from this two component logistic fit are 8 µM and 7.8 mM (n = 2-5 terminals).
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Figure 5.
Basket cell nerve terminal currents are blocked by
both TEA and 4-AP. A, Data from terminals exposed to a
range of concentrations of TEA are here fit with the sum of two
logistic curves. B, Example Kv currents from one
terminal exposed to increasing TEA concentrations. C, In
contrast to the 4-AP insensitivity of the somatic region, basket cell
terminal currents exhibit dose-dependent reduction in the presence of
4-AP. Graph shows block of steady-state current data fitted with the
sum of two logistic curves. D, Example currents from a
single nerve terminal experiment through a range of 4-AP concentrations
(*denotes n = 2 terminals).
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Figure 6 shows the results of experiments
showing that low (1 mM) concentrations of TEA could further
block terminal K+ current already
maximally blocked by DTX. In three cells, 200 nM -DTX
was applied to achieve maximal block of the low-threshold Kv
current (Fig. 4B). Adding 1 mM
TEA under such conditions blocked the high-threshold current by ~80%
at +50 mV, with no further change in threshold.
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Figure 6.
Basket cell terminal current in the presence of
-DTX and after addition of 1 mM TEA. Normalized
current-voltage relationship for three cells in a maximal-blocking
concentration of -DTX (200 nM). Note more positive
voltage threshold. The remaining DTX-insensitive, high-threshold Kv
current is further reduced by 1 mM TEA (see also example
traces in inset).
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To summarize, our pharmacological experiments strongly suggest the
presence of two distinct types of voltage-gated
K+ channels in basket cell terminals.
These two currents, the DTX-sensitive low-threshold current and the
DTX-insensitive, strongly TEA-sensitive high-threshold current, have
almost identical V1/2 values to those obtained from the activation curve of terminal
K+ conductance (which had two separable
components). Additionally, the overall proportions of the currents are
in the same range as those obtained from Boltzmann fits. These results
give us further confidence that the two components in the Boltzmann fit
to terminal K+ conductance were not an
artifact attributable to series resistance problems, or poor space
clamp caused by the complicated geometry of the terminals. In the very
worst case, uncompensated series resistance would lead to an error of
several millivolts with large terminal K+
currents (~1 nA at very depolarized voltages), which may pull the
Boltzmann curve down at positive voltages. However, our results for
V1/2 values were remarkably consistent
both between different cells and also where series resistance and
voltage-gated currents were large or small. Furthermore, if our Kv
channels were electrotonically dispersed with poor voltage control (as
a result of complex terminal morphology), we would not only expect
slowing of current activation, but also slowing of current return at
the end of the voltage step. This is not seen in our records. Poor
space clamp would also lead to greater spread in our values for
V1/2. Drawing the threads of these
different results together leads us to propose that basket cell
terminals have at least two separate voltage-gated
K+ channels, in contrast to the somatic
regions of basket cells and Purkinje cells, which appear more homogeneous.
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DISCUSSION |
Here we examine certain properties of Kv currents in three regions
of an important cerebellar circuit; Purkinje cell bodies and basket
cell bodies and terminals. Our aim is to relate the properties of
native Kv currents to channel-mapping studies in the cerebellum and
experiments on cloned Kv channels in expression systems, to determine
the role of specific potassium channels in cerebellar neuronal
integration. It is hoped that such studies will eventually help in
understanding how mutations in single Kv genes lead to complex CNS
disorders (Cooper and Jan, 1999).
Potassium currents in Purkinje cell bodies
Patch-clamp recordings from these cells revealed a partially
inactivating voltage-gated K+ current that
activated with a V1/2 = 17 mV, which
is similar to results found previously in organotypic slices and cell
culture (Gahwiler and Llano, 1989; Hirano and Hagiwara, 1989; Wang et al., 1991; Raman and Bean, 1999). Some of these studies showed a
rapidly inactivating Kv current (Gahwiler and Llano 1989; Hirano and
Hagiwara, 1989; Wang et al., 1991). Here, inactivation was only
significant over longer steps. Our physiological data are similar to
those obtained by Raman and Bean (1999), who used whole-cell clamp of
dissociated Purkinje cells from slightly younger mice and identified
both calcium-dependent and calcium-independent K+ currents, activating from thresholds of
50 and 40 mV, respectively.
In our pharmacological experiments on Purkinje cell somatic
K+ current, we saw no sensitivity to a
variety of DTX homologs, MgTX, AgTX-2, apamin, and CbTX. Only the broad
spectrum K+ channel blockers 4-AP and TEA
were effective. There are two likely targets for TEA in Purkinje
somatic patches, calcium-activated K+
current or voltage-gated K+ current. Under
our recording conditions, there is likely to be little or no
contribution from calcium-activated currents. Furthermore, the
current was unaffected by either 1 µM apamin or 100 nM charybdotoxin. Our results, showing micromolar
sensitivities for TEA and 4-AP, DTX insensitivity, and a fairly
positive V1/2 value, are consistent with the properties of potassium channels belonging to the Kv3 subfamily. Labeling studies (Goldman-Wohl et al., 1994; Weiser et al., 1994) also indicate that Kv3.3 subunits are present in Purkinje cells.
Potassium current in basket cell somata
Cerebellar basket cells exhibit marked compartmentalization in
their voltage-gated K+ channels. The
somatic current is resistant to 4-AP, several dendrotoxin homologs
(which are selective for certain Kv1 channels), and certain other
peptidergic toxins. Of a wide array of blockers, TEA
(IC50, ~200 µM) was the only
agent able to inhibit Kv current here. Unfortunately, TEA is not a
wholly selective tool, but this high sensitivity invites us to
speculate which Kv -subunits are involved in somatic K+ current. Some Kv1 channels (Kv1.3, 1.6)
generally have sensitivities to TEA in the several millimolar range;
only Kv1.1 subunits have submillimolar sensitivity (Chandy and Gutman,
1995; Coetzee et al., 1999), but the absence of DTX sensitivity would
exclude Kv1.1 subunits. Kv2 channels require a several millimolar
concentration to block, and Kv4 channels also have very little
sensitivity to TEA (Coetzee et al., 1999). Perhaps the best candidates
come from the Kv3 subfamily, where TEA sensitivities range from 0.1 to
1 mM (Chandy and Gutman 1995; Coetzee et al., 1999). There
is little definitive literature with Kv3 antibody labeling in basket
cell bodies [although there is some possible somatic labeling with Kv3.2 (Weiser et al., 1994), but none with Kv3.4 (Laube et al., 1996)], but our present electrophysiological evidence showing the
midrange V1/2 value for somatic
current, and especially the absence of 4-AP sensitivity would strongly
argue against any known Kv3 -subunit being involved. This leaves two
possibilities, one, that Kv3 channels present in basket cell somata
have their properties changed dramatically through coassociation with
accessory ( -type) or -subunits (Robertson, 1997; Coetzee et al.,
1999), or, that another channel subfamily, such as KCNQ2, is present
here. KCNQ2 channels are related to the KvLQT family, and in
heteromultimers make the "M-current"' (H.-S. Wang et al.,
1998). KCNQ2 protein is found in the cerebellum
(Biervert et al., 1998; Schroeder et al., 1998; H.-S. Wang et
al., 1998), and homomultimers in oocytes have a
V1/2 of 37 mV (Biervert et al.,
1998), with an IC50 for TEA of 160 µM (H.-S. Wang et al., 1998), and are
insensitive to 2 mM 4-AP (Yang et al., 1998).
However, the kinetics of the basket cell somatic Kv current are fast,
and KCNQ2 channels in expression systems gate slowly.
Potassium current in terminals
We present here four independent lines of evidence supporting the
existence of at least two distinct Kv channel subfamilies present in
basket nerve terminals. The activation curve has two components,
low-threshold (V1/2, approximately
50 mV) and high-threshold (V1/2, approximately
4 mV), with the latter being ~60% of the total Kv conductance.
Only ~40% of the total outward current could be blocked by -DTX,
with an IC50 of 3.2 nM. The
-DTX-insensitive current also activated at more positive voltages
(V1/2 of 4 mV), and was
substantially blocked (~80%) by 1 mM TEA.
Concentration-response curves in TEA revealed two components; a
high-sensitivity component of ~170 µM and
another component in the high millimolar range. The experiments with
4-AP also revealed high- and low-sensitivity components. The simplest
explanation for these physiological and pharmacological data is that
Kv1 and Kv3 potassium channels constitute most (~85%) of the
voltage-gated K+ current in basket cell
terminals. The DTX sensitivity and its IC50 value
clearly implicates Kv1.1 and 1.2 channel subunits. A heteromultimer
containing equal amounts of Kv1.1 and 1.2 -subunits has TEA
sensitivity in the millimolar range and would be less TEA-sensitive
with greater numbers of 1.2 subunits in the tetramer (Christie et al.,
1990). Such channels would also have 4-AP sensitivity in the millimolar
range (Coetzee et al., 1999). There is also overwhelming anatomical
evidence for basket cell nerve terminals having substantial amounts of
Kv1.2/1.1 protein, often concentrated in "hot spots" (see above).
Although our data reveal high levels of certain Kv1 subtypes in basket
terminal processes, we are still in the dark as to why these channels
are frequently found clustered near specialized junctions (Wang et al.,
1994).
There are some unresolved issues however. Kv1.2 channels, expressed in
mammalian cell lines, display a remarkable potentiation of current
activation rate with voltage pulses delivered at frequencies faster
than 1 Hz (Grissmer et al., 1994; McIntosh and Robertson, unpublished
observations). No such potentiation of native Kv current was seen in
basket cell terminals. Additionally, the DTX-sensitive current has a
half activation voltage closer to values for Kv1.1/1.2 channels
expressed in Xenopus oocytes than the same channels
expressed in mammalian cells.
Antibody labeling reveals that Kv3 channel subunits are present in
basket cell terminals (Kv3.4: Laube et al., 1996; R. Fyffe, personal
communication; Kv3.2b: B. Rudy, personal communication). Kv3.1
and 3.2 proteins are frequently found expressed in axonal/terminal regions in CNS neurons, often GABAergic, that fire at high frequencies (Rudy et al., 1999). Our present data also suggest that Kv3 channels are present, making up ~50% of the total Kv current. The positive V1/2 and high TEA and 4-AP sensitivity
are all hallmarks of Kv3-type channels (Rudy et al., 1999).
Nevertheless, there are some subtle differences between the properties
of our terminal current and those results obtained in model systems.
Brew and Forsythe (1995) have identified Kv1 and Kv3 subfamily-like
currents in the somata of MNTB neurons in the auditory brainstem, which are important in maintaining fidelity of
high-frequency auditory information. It is more difficult to speculate
on the possible roles of Kv1 and Kv3 subfamily channels in basket cell terminals. Block of the Kv1 channels with DTX homologs leads to dramatic increases in spontaneous IPSCs in Purkinje cells (Southan and
Robertson 1998a,b; Tan and Llano 1999), suggesting a key role for these
channels in terminal excitability. Recent two-photon imaging of action
potential-evoked calcium rises in basket terminals reveals that DTX did
not increase Cai; only 4-AP produced dramatic increases in both Cai and spontaneous IPSCs (Tan
and Llano, 1999). Perhaps then, block of Kv1 subfamily channels alone
does not increase calcium entry during action potentials, and possibly
these channels are involved in setting resting excitability in
terminals and influencing the numbers of "failures" of transmission
(Southan and Robertson 1998b; Tan and Llano 1999). Recent work with a
Kv1.1-deficient transgenic mouse supports such a model (Zhang et al.,
1999).
The role of Kv3 channels in the terminals still eludes us. Although low
concentrations of 4-AP increase IPSCs and Cai
levels (Tan and Llano, 1999), low concentrations of TEA have only
modest effects on spontaneous IPSCs (Southan and Robertson, 1998b; Tan and Llano, 1999). It is possible that Kv3 channel block may only have
effects on high-frequency trains in basket cells (L.-Y. Wang et al.,
1998). Direct studies with paired recordings and ideally selective
blockers of Kv3 channels, will be required to fully address this. Our
present data, being the first electrophysiological and pharmacological
characterization of Kv currents in inhibitory nerve terminals, will
hopefully increase our understanding of the roles played by such
currents in fast synaptic transmission at CNS synapses.
| |
FOOTNOTES |
Received July 30, 1999; revised Oct. 15, 1999; accepted Oct. 18, 1999.
We thank the Wellcome Trust for supporting this project (045812) and
Bruce Walmsley and Robert Fyffe for helpful discussions.
Correspondence should be addressed to Dr. Brian Robertson,
Biochemistry, Imperial College of Science, Technology and Medicine, London SW7 2AY, UK. Email: brian.robertson{at}ic.ac.uk
Dr. Southan's present address: Channelwork Group, CeNeS Limited,
Compass House, Vision Park, Chivers Way, Histon, Cambridge CB4 9ZR, UK.
| |
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[Abstract]
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W. Shen, S. Hernandez-Lopez, T. Tkatch, J. E. Held, and D. J. Surmeier
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T. Ishikawa, Y. Nakamura, N. Saitoh, W.-B. Li, S. Iwasaki, and T. Takahashi
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A. M. Swensen and B. P. Bean
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M. Martina, G. L. Yao, and B. P. Bean
Properties and Functional Role of Voltage-Dependent Potassium Channels in Dendrites of Rat Cerebellar Purkinje Neurons
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P. D Dodson, B. Billups, Z. Rusznak, G. Szucs, M. C Barker, and I. D Forsythe
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Z. M. Khaliq, N. W. Gouwens, and I. M. Raman
The Contribution of Resurgent Sodium Current to High-Frequency Firing in Purkinje Neurons: An Experimental and Modeling Study
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H. M Brew, J. L Hallows, and B. L Tempel
Hyperexcitability and reduced low threshold potassium currents in auditory neurons of mice lacking the channel subunit Kv1.1
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T. J. Ebner and G. Chen
Spreading Acidification and Depression in the Cerebellar Cortex
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[Abstract]
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T. Sacco and F. Tempia
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P. D. Dodson, M. C. Barker, and I. D. Forsythe
Two Heteromeric Kv1 Potassium Channels Differentially Regulate Action Potential Firing
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Z.-L. Mo, C. L Adamson, and R. L Davis
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B. Maylie, E. Bissonnette, M. Virk, J. P. Adelman, and J. G. Maylie
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L. A. Cingolani, M. Gymnopoulos, A. Boccaccio, M. Stocker, and P. Pedarzani
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P. Mann-Metzer and Y. Yarom
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E. K. Lambe and G. K. Aghajanian
The Role of Kv1.2-Containing Potassium Channels in Serotonin-Induced Glutamate Release from Thalamocortical Terminals in Rat Frontal Cortex
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T. Ishikawa and T. Takahashi
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A. P Southan, N. P Morris, G. J Stephens, and B. Robertson
Hyperpolarization-activated currents in presynaptic terminals of mouse cerebellar basket cells
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TOP
ABSTRACT
INTRODUCTION
