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The Journal of Neuroscience, October 15, 1998, 18(20):8111-8125
Functional and Molecular Differences between Voltage-Gated
K+ Channels of Fast-Spiking Interneurons and Pyramidal
Neurons of Rat Hippocampus
Marco
Martina1,
Jobst
H.
Schultz2,
Heimo
Ehmke2,
Hannah
Monyer3, and
Peter
Jonas1
1 Physiologisches Institut der Universität
Freiburg, D-79104 Freiburg, Germany, 2 Physiologisches
Institut der Universität Heidelberg, D-69120 Heidelberg, Germany,
and 3 Zentrum für Molekulare Biologie der
Universität Heidelberg, D-69120 Heidelberg, Germany
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ABSTRACT |
We have examined gating and pharmacological characteristics of
somatic K+ channels in fast-spiking interneurons and
regularly spiking principal neurons of hippocampal slices. In nucleated
patches isolated from basket cells of the dentate gyrus, a fast delayed
rectifier K+ current component that was highly
sensitive to tetraethylammonium (TEA) and 4-aminopyridine (4-AP)
(half-maximal inhibitory concentrations <0.1 mM)
predominated, contributing an average of 58% to the total K+ current in these cells. By contrast, in pyramidal
neurons of the CA1 region a rapidly inactivating A-type
K+ current component that was TEA-resistant
prevailed, contributing 61% to the total K+
current. Both types of neurons also showed small amounts of the K+ current component mainly found in the other type
of neuron and, in addition, a slow delayed rectifier
K+ current component with intermediate properties
(slow inactivation, intermediate sensitivity to TEA). Single-cell
RT-PCR analysis of mRNA revealed that Kv3 (Kv3.1, Kv3.2) subunit
transcripts were expressed in almost all (89%) of the interneurons but
only in 17% of the pyramidal neurons. In contrast, Kv4 (Kv4.2, Kv4.3) subunit mRNAs were present in 87% of pyramidal neurons but only in
55% of interneurons. Selective block of fast delayed rectifier K+ channels, presumably assembled from Kv3 subunits,
by 4-AP reduced substantially the action potential frequency in
interneurons. These results indicate that the differential expression
of Kv3 and Kv4 subunits shapes the action potential phenotypes of
principal neurons and interneurons in the cortex.
Key words:
interneurons; voltage-gated K+
channels; Kv1, Kv2, Kv3, Kv4 subunits; nucleated patch; single-cell
RT-PCR; hippocampal slices
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INTRODUCTION |
Cortical neurons differ in the
intrinsic pattern of action potentials they generate on sustained
current injection (for review, see Connors and Gutnick, 1990 ).
Glutamatergic principal neurons in the hippocampus are regularly
spiking or intrinsically bursting and show adaptation (Madison and
Nicoll, 1984), whereas several types of GABAergic interneurons are
fast-spiking and generate high-frequency trains of action potentials
(Han et al., 1993; Scharfman, 1995). The specific functional properties
of ion channels that confer the different action potential phenotypes
are not entirely understood. K+ channels of both
delayed rectifier-type and inactivating A-type were found in
fast-spiking interneurons in stratum oriens-alveus of the hippocampal
CA1 region (Zhang and McBain, 1995a,b); the main difference to the
K+ current in principal neurons (Numann et al.,
1987; Ficker and Heinemann, 1992; Storm, 1990) appeared to be the
faster activation time course of the delayed rectifier component.
Delayed rectifier K+ channels with rapid activation
and deactivation were also identified in interneurons of CA1 stratum
pyramidale. Low concentrations of 4-AP and TEA blocked the delayed
rectifier component in interneurons of stratum pyramidale (Du et al.,
1996) but not in those of stratum oriens-alveus (Zhang and McBain,
1995a). The functional impact of these pharmacologically distinct
K+ channels on the discharge patterns of various
interneurons remains to be addressed.
The K+ channel subunit expression profile of
fast-spiking interneurons is also unclear. Native voltage-gated
K+ channels are multimeric proteins assembled from
pore-forming  subunits and auxiliary  subunits. The subunits
of rat K+ channels are encoded by four main
subfamilies of genes (Kv1, Kv2, Kv3, and Kv4), which are homologous to
the Shaker, Shab, Shaw, and Shal genes in Drosophila
(Chandy, 1991). Previous studies showed that Kv3.1 subunits are
expressed preferentially in parvalbumin-positive interneurons in the
hippocampus (Weiser et al., 1995; Du et al., 1996), but several
observations raise doubts that Kv3.1 is the only determinant of the
fast-spiking phenotype. First, regularly spiking pyramidal neurons in
the hippocampus also express Kv3.1 mRNA (Weiser et al., 1994). Second,
somatostatin-positive interneurons in the stratum oriens-alveus do not
express Kv3.1 protein (Du et al., 1996). Third, in situ
hybridization and immunocytochemical analysis indicated that scattered
cells throughout the hippocampus, perhaps corresponding to specific
interneuron subtypes, were also positive for Kv3.2/3.3 (Weiser et al.,
1994), Kv2 (Maletic-Savatic et al., 1995), and Kv4 subunits (Tsaur et
al., 1997; Serôdio and Rudy, 1998). Finally, Kv3.1-deficient mice
do not develop spontaneous seizures, contrary to what is expected if
Kv3.1 were the key determinant of the fast-spiking phenotype (Ho et
al., 1997). Thus, a complete molecular characterization of the
K+ channel repertoire of defined interneuron
subtypes is required before final conclusions regarding the molecular
basis of their intrinsic discharge patterns can be reached.
To address this issue, we compared the functional and molecular
properties of K+ channels in a prototypic
fast-spiking GABAergic interneuron (the dentate gyrus basket cell, BC)
and a regularly spiking glutamatergic principal neuron (the CA1
pyramidal cell, PC). The results suggest that differential expression
of Kv3 and Kv4 subunit genes is a main factor shaping the intrinsic
discharge patterns of hippocampal neurons.
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MATERIALS AND METHODS |
Cell identification and recording of K+
currents from nucleated patches. Transverse hippocampal slices of
300 µm thickness were cut from the brains of 11- to 16-d-old Wistar
rats using a Vibratome (Dosaka, Kyoto, Japan). Animals were killed by
decapitation, in agreement with national and institutional guidelines.
Basket cells in the dentate gyrus and pyramidal neurons in the
hippocampal CA1 subfield were identified visually using infrared
differential interference contrast (IR-DIC) videomicroscopy. Basket
cells were identified on the basis of the following criteria: large
size and pyramidal or fusiform shape of the soma, location of the soma at the border between granule cell layer and hilus, and orientation of
the apical dendrite perpendicular to the granule cell layer. Putative
interneurons were only accepted when the action potential frequency on
sustained injection of depolarizing current (0.5 or 1 sec, 100-400 pA)
exceeded 60 Hz at ~22°C (Han et al., 1993). Patch pipettes were
pulled from borosilicate glass tubing (2.0 mm outer diameter, 0.5 mm
wall thickness) and heat-polished before use. The pipette resistance
ranged from 2 to 5 M , and the series resistance in the whole-cell
configuration was 4-14 M. Only neurons with initial resting
potentials negative to  55 mV were accepted. To isolate nucleated
patches, negative pressure (50-150 mbar) was applied, and the patch
pipette was withdrawn slowly; a small negative pressure (10-20 mbar)
was kept during recording. Nucleated patches had input resistances of
2-5 G; their shape was spherical, and the diameter was 8.6 ± 0.5 µm, independent of the cell type. Previous estimates indicate
that the nucleated patch membrane follows a command voltage step with a
time constant <50 µsec (Martina and Jonas, 1997).
All measurements were made from nucleated patches, except the
current-clamp recordings of action potential patterns that were obtained in the whole-cell configuration (see Figs.
1A,B,
9A,B). An Axopatch 200A amplifier
(Axon Instruments, Foster City, CA) that included a bridge-balance
circuit for series resistance compensation in current-clamp mode was
used for measurements. Signals were filtered at 5 or 10 kHz using the
4-pole low-pass Bessel filter, and capacitive transients were reduced
by the compensation circuit of the amplifier. A 1401plus interface
(Cambridge Electronic Design, Cambridge, England) connected to a
personal computer was used for stimulus generation and data
acquisition. The sampling frequency was 10 or 20 kHz.
Nucleated patches were held at 90 mV. Pulse sequences were generated
by homemade programs that also allowed us to apply previously recorded
waveforms as voltage-clamp commands. Leakage and capacitive currents
were subtracted on-line using a "P over 4" procedure (Martina and
Jonas, 1997). Current components sensitive to a blocker were determined
off-line by direct subtraction of raw traces. Na+
currents, when apparent, were blocked by adding 0.3 or 0.5 µM tetrodotoxin (TTX; Sigma, St. Louis, MO) to the
external solution. Traces shown in the figures represent single sweeps
or averages from up to 10 sweeps. Test pulses were applied every 4-5
sec, except when the recovery from inactivation was studied (see Fig. 6G,H; time interval between pulse sequences, 20 sec). Test pulses were continuously applied during and after wash-in of
TEA, 4-AP, or dendrotoxin (DTX), and final recordings were made
in steady-state conditions. The washout of the blockers was also
examined; the effects were almost completely (TEA, <1 mM
4-AP) or partially ( 1 mM 4-AP) reversible. No correction
for liquid junction potentials was made. The electrophysiological data
included in this study were obtained from 80 BC patches and 66 PC
patches. All recordings were made at room temperature (20-24°C).
Solutions and chemicals. Slices were superfused with
physiological extracellular solution containing (in mM):
125 NaCl, 25 NaHCO3, 2.5 KCl, 1.25 NaH2PO4, 2 CaCl2, 1 MgCl2, and 25 glucose, bubbled with 95%
O2 and 5% CO2. 4-AP (Sigma) and TEA (Merck,
Darmstadt, Germany) were applied to nucleated patches either via bath
superfusion or using a multi-barrelled application pipette.
-Dendrotoxin (Alomone, Jerusalem, Israel) was applied exclusively
with the application pipette. Application pipette barrels were
continuously perfused with a Na+-rich solution
containing (in mM): 135 NaCl, 5.4 KCl, 1.8 CaCl2, 1 MgCl2, and 5 HEPES,
pH-adjusted to 7.2 with NaOH; in the experiments with DTX, 0.1% bovine
serum albumin was added. Recording pipettes were filled with
K+-rich internal solution, containing (in
mM): 140 KCl, 10 EGTA, 2 MgCl2, 2 Na2ATP, 2 glutathione-SH, and 10 HEPES, pH-adjusted to 7.3 with KOH. In some experiments, glutathione-SH was omitted. All
chemicals were from Merck or Sigma, unless specified differently.
Analysis. Traces and data points were fitted using a
nonlinear least-squares algorithm. To obtain the activation curve,
values of chord conductance (G) were calculated from the respective
peak currents, assuming ohmic behavior and a reversal potential of 95
mV. This potential was close to the experimentally determined reversal
potentials of tail currents, which were 98.8 ± 2.0 mV in BC
patches (n = 6) and 96.4 ± 5.0 mV in PC patches
(n = 3). Activation and inactivation curves were fitted
with functions based on the Boltzmann equation f = 1/{1 + exp[±(V-V1/2)/k]}, where V is the membrane potential,
V1/2 is the potential at which the value of the
Boltzmann function is 0.5, and k is the slope factor. The
activation curves were fitted with a Boltzmann function raised to the
fourth power; the midpoint potentials given indicate the potential at
which the conductance reached the half-maximal value. Data are reported
as mean ± SEM; error bars in Figures also represent SEM and were
plotted only when they exceeded the respective symbol size. Statistical
significance was assessed using a two-sided t test for
paired or unpaired samples at the significance level (P) indicated.
Figures show data pooled from different patches. SEs of fitted
parameters were obtained by analyzing data of individual experiments
separately.
Single-cell RT-PCR. Methods for single-cell RT-PCR were
similar to those described previously (Monyer and Jonas, 1995). Patch pipettes used for RT-PCR experiments (0.8-3 M) were filled with autoclaved internal solution containing (in mM): 140 KCl, 5 EGTA, 3 MgCl2, and 5 HEPES, pH-adjusted to 7.3 with
KOH. The cytoplasm of a whole-cell recorded neuron, either including
(Kv2, Kv3, and Kv4) or excluding (Kv1) the nucleus, was harvested into
the patch pipette by applying negative pressure. The harvested material was then expelled under visual control into an autoclaved reaction tube
containing hexamer random primers, deoxyribonucleoside triphosphates, dithiothreitol, ribonuclease inhibitor, and Superscript reverse transcriptase II (Life Technologies, Gaithersburg, MD), and incubated at 37°C for 1 hr. Subsequently, two rounds of PCR amplification with
nested primer pairs were performed; the template for the second PCR was
1 µl of the first reaction. The concentration of primers was 60 µM.
The large sequence diversity of K+ channel subunits
at the nucleotide level required the use of multiple sets of specific
primers rather than a single set of degenerate primers. To exclude
unpredictable primer interactions, the material from each neuron was
amplified only with a single set of primers (requiring a large number
of cells to be analyzed, n = 100). Transcripts of the
Kv1 subfamily (Kv1.1 and Kv1.6, and Kv1.2 and Kv1.4, respectively), of
the Kv2 subfamily (Kv2.1 and Kv2.2), and Kv4 subfamily (Kv4.1, Kv4.2, and Kv4.3) were amplified with common primers in the same two-step PCR.
Control experiments showed that these primers amplified the respective
cDNAs in plasmid mixtures with the same efficacy. Transcripts of the
Kv3 subfamily (Kv3.1 and Kv3.2) were amplified with specific primers in
different PCRs because attempts to employ common primers failed,
resulting in unequal amplification of Kv3.1 and Kv3.2 in plasmid
mixtures.
Primers in the two rounds of amplification were nested and
intron-overspanning whenever possible. For all PCR reactions the cycle
conditions were: 94°C for 5 min, after a hot start, 35 step cycles
(94°C for 30 sec; 55°C for 30 sec; 72°C for 40 sec), and 72°C
for 10 min. Positive controls for primer efficiency were run using
plasmids. Controls for possible contamination artifacts were performed
for each PCR amplification. Additional controls to exclude unspecific
harvesting of surrounding tissue components were performed by advancing
pipettes into the slice and taking them out again without seal
formation and suction (Monyer and Jonas, 1995). Both types of controls
gave negative results throughout. Amplification of genomic Kv2, Kv3,
and Kv4 subunit DNA could be excluded by the intron-overspanning
location of the primers. For Kv1 subunits, additional controls in which
the RT was omitted were performed. Such controls were always negative
only when the nucleus was not harvested. Thus, for Kv1 RT-PCR the
nucleus was never aspirated, even if this resulted in a lower amount of
cytoplasm collected. To verify the specificity of the amplifications,
the PCR products were tested using Southern blotting with radiolabeled oligonucleotides. The molecular identity of randomly selected PCR
products was confirmed by sequencing.
Primer sequences and locations (referring to published sequences in the
GenBank of the National Center for Biotechnology Information, www2.ncbi.nlm.nih.gov) were as follows: Kv1.1 (accession number M26161)
and Kv1.6 (X17621): Upper primer, 5'-TGG TGA TCA ACA TCT C(CT)G GGC-3'
(position 150-170 and 558-578, respectively); upper nested primer,
5'-ATC CTT TAT TAC TAC CAG TCG G-3' (308-329, 716-737); lower primer,
5'-GTC TCC AGG CAA AAG ATG AC-3' (578-597, 995-1014). Kv1.2 (X16003)
and Kv1.4 (X16002): Upper primer, 5'-AGC TTT GAT GCC ATT TTG TA-3'
(812-831, 1176-1195); upper nested primer, 5'-ACA G(GA)T (GT)TG GCT
TCT CTT TGA ATA-3' (1003-1026, 1370-1393); lower primer, 5'-AGA GGA
TGA CCC C(AG)A TGA AGA G-3' (1565-1586, 1950-1971). Kv2.1 (X16476)
and Kv2.2 (M77482): Upper primer, 5'-CTG GGG CAT CGA TGA GAT CTA CC-3'
(372-394, 701-723); lower primer, 5'-GTC ATG GTG ATG GTA GCC CAC
CA-3' (1104-1126, 1443-1465); lower nested primer, 5'-CGA AAG ATC TGG
ACC ACG CG-3' (889-908, 1218-1237). Kv3.1 (X62840): Upper primer,
5'-CAA GAG ATT GGC GCT CAG TGA C-3' (742-763); lower primer, 5'-CCC
AG(AG) GCC AG(AG) AAG ATG AT(AC) AGC A-3' (1326-1350); lower nested
primer, 5'-AA(AG) TGG CG(GT) GT(ACG) AGC TTG AAG AT-3' (1247-1269).
Kv3.2 (M59211): Upper primer, 5'-TTG AGG ATG CTG CGG GGC TGG-3'
(611-631); lower primer, same as for Kv3.1 (1187-1211); lower nested
primer, same as for Kv3.1 (1108-1130). Kv4.1 (M64226), Kv4.2 (S64320), Kv4.3 (U75448): Upper primer, 5'-T(CT)A TCG A(TC)G TGG TGG CCA TC-3'
(797-816, 1342-1361, 802-821); upper nested primer, 5'-TAC AC(AC)
CT(CG) AAG AGC TGT GC-3' (943-962, 1494-1513, 954-973); lower
primer, 5'-TGG TAG AT(CG) C(GT)(GA) CT(AG) AAG TT-3' (1228-1247, 1773-1792, 1223-1242).
The sequences of the probes for the Southern blots were: Kv1.1, 5'-CTT
CAT CAA GGA AGA GGA GCG CCC CCT A-3' (439-466); Kv1.2, 5'-TGG TGG GGT
GAC CTT CCA CAC CTA TTC-3' (1153-1179); Kv1.4, 5'-CGC AGG TGG ACA CAG
CAG ATT ATT GAA T-3' (1526-1553); Kv1.6, 5'-TTG CCT GCC CGA AGG TGG
TGA GGA TGA G-3' (847-874); Kv2.1, 5'-CTC TGG CCG AAC TCG TCT AGG
CTC-3' (654-677); Kv2.2, 5'-GGT TGC CCA AAT TCA TCG TTT TCT-3'
(983-1006); Kv3.1, 5'-TGA GAA CGT TCG AAA TGG CAC AC-3' (958-980);
Kv3.2, 5'-CCA GTC ATC AAC GGC ACC AGC-3' (823-843); Kv4.1, 5'-CTT GCC
TGT GCC AGT CAT TGT A-3' (1203-1224); Kv4.2, 5'-GCT ACC CGT GCC TGT
GAT CGT G-3' (1748-1769); Kv4.3, 5'-TCT GCC AGT CCC CGT CAT AGT C-3'
(1208-1229).
The washing conditions were 0.5× SSC at 55°C, except for Kv1 probes
(0.2× SSC at 55°C) and Kv4.2 probes (0.1× SSC at 55°C).
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RESULTS |
Macroscopic K+ currents differ between
interneurons and principal neurons
BCs and PCs differ in the frequency of action potentials generated
by sustained current injection (Fig.
1A,B),
suggesting a possible difference in the functional properties of the
voltage-gated K+ channels expressed. We have
therefore studied the somatic K+ channels in these
two types of neurons using the nucleated patch configuration, which
allowed us to examine channel gating under almost ideal voltage-clamp
conditions. Representative recordings of K+ currents
activated by test pulses to potentials between 80 and 70 mV are shown
in Figure 1C,D.
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Figure 1.
Interneurons and pyramidal neurons differ in
action potential pattern and in activation and inactivation properties
of their voltage-gated K+ channels.
A, B, Action potentials evoked by a 1 sec
depolarizing current pulse in a BC (A) and a PC
(B). Current-clamp recording in the whole-cell
configuration. Membrane potential before the pulse was 70 mV. Current
during the pulse was 160 and 120 pA, and holding current was 40 and
30 pA, respectively. One hundred micromolar Cd2+
was used in the external solution in both cell types. C,
D, Traces of K+ currents evoked in a
nucleated patch isolated from a BC (C) and a PC
(D); holding potential was 90 mV, pulse
potential varied from 80 to 70 mV (10 mV increment).
E, Peak conductance-voltage relation in nucleated
patches isolated from BCs (open circles,
n = 25) and PCs (filled
circles, n = 20). The curves represent
Boltzmann functions raised to the fourth power fitted to the data
points. Midpoint potentials were 1.0 ± 1.2 mV in BC patches and
3.5 ± 1.5 mV in PC patches, and slope factors were 17.6 ± 0.7 mV and 24.0 ± 0.3 mV, respectively. F,
Histogram of the ratio of current amplitude at the end of a 100 msec
pulse to that of the peak current for 66 BC patches (open
bars) and 44 PC patches (filled bars).
For BC patches, the mean current ratio was 0.75 both in the presence
(n = 51) and in the absence of glutathione-SH
(n = 15). For PC patches, the mean current ratio
was 0.35 in the presence (n = 40) and 0.39 in the
absence of glutathione-SH (n = 4). Test pulse to 70 mV.
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The K+ currents in the two classes of cells differed
in the voltage dependence of activation. The normalized
K+ conductance-voltage relations, calculated from
the respective peak current amplitudes, showed indistinguishable
midpoint potentials (p > 0.5) but significantly
steeper voltage dependence in BC patches than in PC patches (slope
factors were k = 17.6 ± 0.7 mV and 24.0 ± 0.3 mV, respectively; p < 0.001; Fig.
1E). Accordingly, the threshold for
K+ channel activation was ~10 mV more positive in
BCs than in PCs (Fig. 1E).
K+ currents in the two classes of neurons also
differed markedly in the time course and the extent of inactivation.
K+ currents in BC patches showed only minimal
inactivation during 100 msec pulses, whereas K+
currents in PC patches decayed substantially (Fig.
1C,D). The ratio of the current at the end of a
100 msec pulse to 70 mV to that at the peak was on average 0.75 ± 0.02 for BCs (n = 66) and 0.35 ± 0.02 for PCs
(n = 44, p < 0.001; Fig.
1F), independent of whether or not glutathione-SH (2 mM) was present in the internal solution (Ruppersberg et
al., 1991).
In addition to these functional differences, the maximal value of the
somatic K+ conductance density differed between the
two classes of neurons. For a test pulse to 70 mV and a
K+ current reversal potential of 95 mV (see
Materials and Methods), the somatic K+ conductance
density was 175 pS µm 2 in BCs, significantly
larger than in PCs (95 pS µm2; p < 0.001; Table 1). These results
indicated that somatic macroscopic K+ currents in
the two types of neurons differed in several characteristics, such as
voltage dependence of activation, time course of inactivation, and
conductance density.
Dissection of three K+ current components by
external 4-AP and TEA
4-AP and TEA were shown previously to distinguish between
recombinant K+ channels assembled from subunits of
different Kv subfamilies (Baldwin et al., 1991; Pak et al., 1991;
Taglialatela et al., 1991; Rettig et al., 1992; Kirsch and Drewe,
1993). We, therefore, examined the effects of these blockers on the
K+ currents of the two cell types. Micromolar
concentrations of external 4-AP, which selectively inhibit recombinant
Kv3 channels (Kirsch and Drewe, 1993; Grissmer et al., 1994), reduced
markedly the K+ currents in BC patches (Fig.
2A) but had smaller
effects in PC patches (Fig. 2B). The concentration
dependence of the block by 4-AP is illustrated in Figure 2C.
In both types of neurons, the data points could not be adequately
fitted by a single Hill equation, independently of whether the Hill
coefficient was constrained to 1 or left as a free parameter. We
therefore fitted the data with the sum of two Hill equations,
constraining the Hill coefficients to 1 (Kirsch and Drewe, 1993). The
half-maximal inhibitory concentrations (IC50 values) of the
two components were comparable in the two types of neurons (52 µM and 4.3 mM vs 15 µM and 1.8 mM), but their relative contribution was reverse. The
high-affinity component predominated in BC patches, whereas the
low-affinity component prevailed in PC patches (the blocked fractions
were 69 and 20% vs 25 and 68%; Fig. 2C). These results
indicated that the macroscopic K+ current in both
cell types consisted of multiple components that differed in their 4-AP
sensitivity.
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Figure 2.
Effects of external 4-AP, TEA, and DTX on
K+ current components in interneurons and pyramidal
neurons. A, B, K+
currents evoked by test pulses to 70 mV (from a holding potential of
90 mV) in the absence and in the presence of 0.1 and 10 mM 4-AP in a BC patch (A) and a PC
patch (B). C, Inhibition of the
peak K+ current by 4-AP, plotted against 4-AP
concentration, for BC patches (open circles,
n = 6) and PC patches (filled
circles, n = 5). Data points were fitted
with the sum of two Hill equations. For BC patches, the
IC50 values were 52 µM and 4.3 mM, and the blocked fractions were 69 and 20%. For PC
patches, the IC50 values were 15 µM and 1.8 mM, and the blocked fractions were 25 and 68%,
respectively. D, E, K+
currents evoked by test pulses to 70 mV (from a holding potential of
90 mV) in the absence and in the presence of 1 or 10 mM
TEA in a BC patch (D) and a PC patch
(E). F, Inhibition of the peak
K+ current by TEA, plotted against TEA
concentration, for BC patches (open circles,
n = 8-22) and PC patches (filled
circles, n = 6-10). Data points were
fitted with the sum of two Hill equations. For BC patches, the
IC50 values were 70 µM and 1.3 mM, and the blocked fractions were 46 and 27%. For PC
patches, the IC50 values were 10 µM and 1.7 mM, and the blocked fractions were 6 and 25%,
respectively. The Hill coefficients were constrained to 1 in all
cases. G, H, DTX (200 nM) had
only minimal effects on the K+ current in BC patches
(G) and PC patches
(H).
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TEA blocks recombinant K+ channels with very
different affinities. Kv3 channels are highly sensitive to external TEA
(Rettig et al., 1992), whereas Kv2 channels show intermediate
sensitivity (Taglialatela et al., 1991), and Kv4 channels are
TEA-resistant (Pak et al., 1991). External TEA reduced markedly the
K+ currents in BC patches (Fig.
2D) but had much smaller effects in PC patches (Fig.
2E). The concentration dependence of the block by TEA
is depicted in Figure 2F. As with 4-AP, the sum of
two Hill equations was required to fit adequately the data points. The
IC50 values of the two components were 70 µM
and 1.3 mM for BC patches and 10 µM and 1.7 mM for PC patches. The blocked fractions were substantially
larger in BC patches than in PC patches (46 and 27% vs 6 and 25%;
Fig. 2F). As with 4-AP, these results suggested that
the K+ current in both cell types consisted of two
components with different TEA sensitivity, and a third, TEA-resistant
component (Fig. 2F).
We next examined possible additive effects of low concentrations of
4-AP and TEA. In the presence of 0.5 mM 4-AP, further addition of 1 mM TEA reduced the peak K+
current to 75 ± 2% in BC patches (n = 4) and
95 ± 6% in PC patches (n = 5). These effects
were significantly smaller than those of 1 mM TEA in
isolation (p < 0.01 for both cell types; Fig.
2F). Conversely, in the presence of 1 mM
TEA, further addition of 0.2 mM 4-AP had no significant
effect; the peak K+ current was reduced to only
91 ± 3% and 94 ± 3% of the value in the presence of 1 mM TEA alone, respectively (n = 3, p > 0.1 in both cell types). These results indicated
that the current that was highly sensitive to 4-AP was also highly
sensitive to TEA and vice versa.
DTX (200 nM), a selective blocker of recombinant
K+ channels assembled from Kv1.1, Kv1.2, and Kv1.6
subunits (Pongs, 1992), had only minimal effects on the
K+ currents in both types of neurons; the peak
current in the presence of DTX was 100.0 ± 2.0% of the control
value in BC patches (n = 6, p > 0.5)
and 95.0 ± 3.0% in PC patches (n = 4, p > 0.01; Fig.
2G,H).
Pharmacological dissection allowed us to separate the
K+ current components in the two types of neurons
and to investigate their gating properties in isolation. Subtraction of
currents evoked in the presence of low concentrations of either 4-AP
(Fig. 3A,B,
top traces) or TEA (Fig.
3A,B, bottom
traces) from those in the absence of blockers revealed a
first K+ current component that showed fast
activation and very little, if any, inactivation during 100 msec
pulses. The 20-80% rise time was 0.9 ± 0.1 msec in BC patches
(n = 9) and 1.5 ± 0.4 msec in PC patches
(n = 9) at 70 mV test pulse potential. In contrast, subtraction of currents in the presence of 20 mM TEA plus
0.5 mM 4-AP from those in the presence of 0.5 mM 4-AP alone (Fig. 3C,D,
top traces) or subtraction of the currents in
the presence of 20 mM TEA from those in the presence of 1 mM TEA (Fig. 3C,D, bottom traces) revealed a second component with slower
activation. The rise time was 6.3 ± 1.3 msec in BC patches
(n = 9) and 5.4 ± 0.9 msec in PC patches
(n = 9) at 70 mV. Finally, a third component that
persisted in the presence of 20 mM TEA showed rapid
activation and inactivation (Fig.
3E,F). The rise times were
0.9 ± 0.3 msec in BC patches and 1.0 ± 0.1 msec in PC
patches, and the inactivation time constants were 43.8 ± 4.4 msec
(n = 9) and 44.4 ± 4.5 msec (n = 11) at 70 mV test pulse potential, respectively.
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Figure 3.
Current subtraction analysis suggests the presence
of three kinetically distinct K+ current components.
A, B, Fast delayed rectifier
K+ current component,
Icontrol I0.5
mM 4-AP (top traces) or
Icontrol I1
mM TEA (bottom traces).
C, D, Slow delayed rectifier
K+ current component, I0.5
mM 4-AP I0.5 mM
4-AP + 20 mM TEA (top traces) or
I1 mM TEA I20 mM TEA (bottom
traces). E, F, A-type
K+ current component, I20
mM TEA. Traces in A,
C, and E were recorded from BC patches,
traces in B, D, and F from
PC patches. Currents were evoked by test pulses to 70 mV (from a
holding potential of 90 mV).
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These results indicated that the K+ currents in both
BCs and PCs were composed of three pharmacologically and kinetically
distinct components: a fast delayed rectifier component that was highly sensitive to both 4-AP and TEA, a slow delayed rectifier with intermediate TEA-sensitivity, and an inactivating (A-type)
K+ current component that was largely TEA-resistant.
The contribution of the three components to the total
K+ current, as assessed by subtraction analysis,
differed substantially in the two types of neurons (Table 1). In BC
patches, the relative contributions of the three components were
58 ± 6%, 26 ± 5%, and 17 ± 4%. In contrast, in PC
patches the contributions were 12 ± 4%, 27 ± 4%, and
61 ± 4% (Table 1).
Activation and inactivation of the three K+
current components
We next compared the voltage dependence of activation and
inactivation of the three pharmacologically dissected current
components in BC and PC patches. The fast delayed rectifier component
in BC patches showed an activation curve with a midpoint potential of
7.1 ± 0.9 mV and steep activation characteristics (slope factor k = 11.5 ± 0.8 mV; Fig.
4A,C;
Table 1). This component showed no inactivation during 100 msec pulses
and very little inactivation by 10 sec prepulses (Fig.
4B,D). The 20-80% rise time was
strongly voltage-dependent, ranging from 16.8 msec at 10 mV to 0.9 msec at 70 mV (Fig. 4E). A striking kinetic property
was the very fast deactivation kinetics; the deactivation time constant
at 40 mV was on average 5.8 ± 0.4 msec (n = 8;
Fig. 4F). The corresponding K+
current component in PC patches was similar (Fig. 4); the only significant difference between the two cell types was the more negative
midpoint potential of the activation curve in PCs (Table 1).
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Figure 4.
Activation and inactivation of the fast delayed
rectifier K+ current component. A,
B, Traces of K+ current obtained by
subtraction (Icontrol I0.5 mM 4-AP) in BC patches. In
A, the test pulse potential was varied from 80 to 70 mV (10 mV increment), and the holding potential was 90 mV. In
B, the potential of the prepulse (10 sec) was varied
from 110 to 40 mV, and the test pulse potential was kept constant
at 20 mV. C, Activation curves for BC patches
(open circles, n = 14) and PC
patches (filled circles, n = 9). Data points were fitted with Boltzmann functions raised to the
fourth power. Pulse program as described in A.
D, Steady-state inactivation curves for BC patches
(open circles, n = 6) and PC patches
(filled circles, n = 5).
Pulse program as described in B. E,
20-80% rise time, plotted against test pulse voltage for BC patches
(open circles, n = 14) and PC
patches (filled circles, n = 9). Data in C-E were obtained by
subtraction of either Icontrol I0.5 mM 4-AP or
Icontrol I1
mM TEA. Because the two approaches gave similar
results, data were pooled. F, Deactivation time course
at 40 mV in a BC patch. Pulse program: holding potential 90 mV, 100 msec pulse to 20 mV, 100 msec pulse to 40 mV, and step back to 90
mV. Top traces were obtained in the absence and presence
of 0.5 mM 4-AP, bottom trace represents
subtracted current. Note the fast deactivation of the
4-AP-sensitive component (decay  4.9 msec for the trace shown). For
curve parameters, see Table 1.
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The slow delayed rectifier component in BC patches showed an activation
curve with more positive midpoint potential (3.3 ± 4.9 mV) and
less steep voltage dependence (slope factor, 17.3 ± 1.5 mV; Fig.
5A,C;
Table 1) than that of the fast delayed rectifier component. This
K+ current showed little inactivation during 100 msec test pulses but substantial inactivation by 10 sec prepulses (Fig.
5B,D). In agreement with the less
steep activation curve, the rise time was less voltage-dependent,
ranging from 14.3 msec at 10 mV to 6.4 msec at 70 mV (Fig.
5E). The deactivation kinetics were markedly slower than
those of the first component; the deactivation time constant at 40 mV
was on average 22.3 ± 2.0 msec (n = 6; Fig. 5F). The slow delayed rectifier K+
current component in PC patches was similar to that in BC patches in
some but not all functional properties. Significant differences between
the two classes of cells were found in the steepness of the activation
curves (Fig. 5C, Table 1) and in the rise times of the
current for potentials  20 mV (Fig. 5E; p < 0.01 at 10 mV).
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Figure 5.
Activation and inactivation of the slow delayed
rectifier K+ current component. A,
B, Traces of K+ current obtained by
subtraction in BC patches (I0.5 mM
4-AP I0.5 mM 4-AP + 20 mM TEA in A, I1
mM TEA I20 mM
TEA in B). C, Activation curves
for BC patches (open circles, n = 9)
and PC patches (filled circles,
n = 9). Data points were fitted with Boltzmann
functions raised to the fourth power. D, Steady-state
inactivation curves for BC patches (open circles,
n = 9) and PC patches (filled
circles, n = 10); 10 sec prepulses. Data
points were fitted with sum of a Boltzmann function and a constant.
E, 20-80% rise time, plotted against test pulse
voltage for BC patches (open circles,
n = 9) and PC patches (filled
circles, n = 9). F,
Deactivation time course at 40 mV in a BC patch. Top
traces represent I0.5 mM
4-AP, and I0.5 mM 4-AP + 20 mM TEA, bottom trace represents
subtracted current. Note the slow deactivation (decay 21.6 msec).
Pulse programs identical to those used for Figure 4. For curve
parameters, see Table 1.
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The A-type, TEA-insensitive, component in BC patches had an activation
curve with a midpoint potential of 6.2 ± 3.3 mV and a slope
factor of 23.0 ± 0.7 mV (Fig.
6A,C;
Table 1). The current component showed marked inactivation during 100 msec test pulses and complete inactivation by 10 sec prepulses. The
steady-state inactivation curve had a midpoint potential of 75.5 ± 2.5 mV and showed steep voltage dependence (slope factor, 8.5 ± 0.8 mV; Fig. 6B,D). Both the
rise time of the current and the time constant of inactivation onset
were fast and largely independent of voltage (Fig.
6E,F).
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Figure 6.
Activation and inactivation of the A-type
K+ current component. A,
B, Traces of K+ current in the
presence of 20 mM TEA in BC patches. C,
Activation curves for BC patches (open circles,
n = 9) and PC patches (filled
circles, n = 11). Data points were fitted
with Boltzmann functions raised to the fourth power. D,
Steady-state inactivation curves for BC patches (open
circles, n = 9) and PC patches
(filled circles, n = 17); 10 sec prepulses. Data points were fitted with Boltzmann functions.
E, 20-80% rise time, plotted against test pulse
voltage. F, Decay , plotted against test pulse
voltage, for BC patches (open circles,
n = 9) and PC patches (filled
circles, n = 11). The decay phase of the
current during a 100 msec pulse was fitted with the sum of a single
exponential function and a constant. G, Traces of
K+ currents in the presence of 20 mM
TEA. Pulse protocol: holding potential 90 mV, 150 msec pulse to 50 mV
(conditioning pulse), pulse of variable duration to 90 mV, 150 msec
pulse to 50 mV (test pulse), and step back to 90 mV. Top
traces from a BC patch, bottom traces from PC
patch. H, Time course of recovery from inactivation for
BC patches (open circles, n = 5) and
PC patches (filled circles, n = 6). The amplitude of the peak current evoked by the test pulse
divided by that evoked by the conditioning pulse was plotted against
the interpulse interval. Data points were fitted with the sum of two
exponentials. Pulse programs in A-F were
identical to those used for Figure 4. For curve parameters, see Table
1.
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The A-type K+ current component in PC patches was
indistinguishable from that in BC patches in all functional properties
examined, except in the kinetics of the recovery from inactivation. The inactivation recovery time course, investigated by a double-pulse protocol, was biexponential in both classes of cells. However, the slow
component predominated in BC patches, whereas the fast component
prevailed in PC patches. In contrast, the values of the time constants
were similar in the two classes of neurons (Fig.
6G,H; Table 1).
Single-cell RT-PCR analysis of K+ channel
subunit transcripts
A comparison of the functional properties of K+
channels in BC and PC patches with those of recombinant
K+ channels (Baldwin et al., 1991; Pak et al., 1991;
Taglialatela et al., 1991; Rettig et al., 1992; Grissmer et al., 1994)
may suggest that the fast delayed rectifier K+
current component that predominated in BCs was mediated by Kv3 subunits, whereas the inactivating component that predominated in PCs
was mediated by Kv4 subunits. According to the functional properties,
the slow delayed rectifier component could be attributable to Kv2
subunits, but the contribution of Kv1 subunits could not be excluded
entirely. We therefore analyzed the expression of Kv1, Kv2, Kv3, and
Kv4 subunit transcripts by single-cell RT-PCR. The cytoplasm of single
neurons was harvested into the recording pipette, and the harvested
material was used for reverse transcription and PCR with specific
nucleotide primers (Monyer and Jonas, 1995; see Materials and Methods).
The amplified cDNA products were visualized on ethidium bromide-stained
gels and probed with specific radiolabeled oligonucleotides (Fig.
7).
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Figure 7.
Differential expression of Kv1, Kv2, Kv3, and Kv4
subunit mRNAs in BCs and PCs. Top panels, ethidium
bromide-stained gels of the PCR products amplified with primers
specific for Kv1.2/Kv1.4 (A), Kv2.1/Kv2.2
(B), Kv3.2 (C), and
Kv4.1/Kv4.2/Kv4.3 transcripts (D). Bottom
panels, Differential hybridization of gels with selective
radiolabeled oligonucleotide probes specific for Kv1.2
(A), Kv2.2 (B), Kv3.2
(C), and Kv4.2 transcripts
(D). Left lanes, material from
five different BCs; right lanes, from five different
PCs. Molecular weight markers are shown in the lanes on the very left
and right, together with the corresponding number of base pairs.
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Single-cell RT-PCR analysis revealed that Kv1, Kv2, Kv3, and Kv4
subunits were expressed differentially in BCs and PCs (Figs. 7,
8). The Kv3.1 subunit mRNA was detected
in 89% of BCs (n = 9) but only in 17% of PCs examined
(n = 6). Similarly, 83% of BCs expressed Kv3.2 subunit
mRNA (n = 6), whereas only 17% of PCs were Kv3.2
mRNA-positive (n = 6). In contrast, the Kv4 subunit mRNA was the dominant Kv mRNA species in pyramidal neurons; it was
detected in 87% of PCs (n = 15) but also in 55% of
BCs analyzed (n = 11; Figs. 7, 8). The Kv2 subunit mRNA
was detected in 31% of BCs (n = 13) and in 67% of PCs
(n = 12), suggesting that subunits from this subfamily
were the major contributors to the slow delayed rectifier component in
both types of neurons. Kv1 subunit mRNA levels were low in both cell
types. With Kv1.1/Kv1.6 common primers, 33% of BCs (n = 6) and 20% of PCs (n = 5) were positive; with Kv1.2/Kv1.4 common primers, 0% of BCs (n = 5) and 33%
of PCs (n = 6) were positive.
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Figure 8.
Expression profile of Kv1, Kv2, Kv3, and Kv4
subunit mRNAs in BCs and PCs. A, Percentage of BCs
expressing a given K+ channel subunit transcript;
B, percentage of PCs expressing a given transcript. A
cell was considered to express a given subunit mRNA when the ethidium
bromide-stained gel showed a signal of the expected molecular weight,
and the Southern blot with the respective oligonucleotide probe gave a
positive result. A direct comparison of the values obtained for Kv1 to
those for Kv2, Kv3, and Kv4 may not be possible because the harvesting
procedure was different (see Materials and Methods).
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Southern blot analysis confirmed the identity of the PCR products and,
in addition, revealed that multiple mRNA members of a given Kv
subfamily were frequently coexpressed in a single cell. For the Kv4
subfamily, 18% of BCs expressed both Kv4.2 and Kv4.3 mRNA, 27% were
positive only for Kv4.2 mRNA, and 9% were positive only for Kv4.3
mRNA. In 46% of PCs both Kv4.2 and Kv4.3 mRNA were detected, and 40%
were positive only for Kv4.2 mRNA, whereas the exclusive expression of
Kv4.3 mRNA was never observed. None of the cells expressed Kv4.1
subunit mRNA. For the Kv2 subfamily, 15% of BCs expressed both Kv2.1
and Kv2.2 mRNA, whereas 8% were positive for either Kv2.1 or Kv2.2
mRNA, respectively. Similarly, in 50% of PCs both Kv2.1 and Kv2.2 mRNA
were detected, but only 8% were positive for either Kv2.1 or Kv2.2
mRNA. For the Kv1 family, 33% of BCs expressed Kv1.1 mRNA, whereas
Kv1.2, Kv1.4, and Kv1.6 mRNA were not detected. In PCs, 20% of cells
expressed Kv1.1 mRNA; 17% of cells coexpressed Kv1.2 and Kv1.4 mRNA,
whereas 17% were positive only for Kv1.2 mRNA. None of the cells
expressed Kv1.6 subunit mRNA. These results showed a differential
expression of K+ channel subunit mRNAs between
interneurons and pyramidal neurons and were consistent with the view
that the K+ channels in the two cell types were
mainly assembled from Kv2, Kv3, and Kv4 subunits. In addition, the
results indicate coexpression of mRNAs of multiple members of a
subfamily in a single neuron, suggesting the possibility of the
formation of heteromeric channels.
Selective activation of fast delayed rectifier
K+ channels during high-frequency action potential
trains
The present results showed that fast delayed rectifier
K+ channels, probably assembled from Kv3 subunits,
predominated in BCs. To examine directly the contribution of these
channels to the fast-spiking phenotype, we investigated the effects of
low concentrations of 4-AP on the action potential pattern of BCs (Fig.
9A,B).
Application of 4-AP at a concentration that blocked the fast delayed
rectifier K+ current component selectively (0.2 mM) converted the fast-spiking phenotype into a
substantially slower spiking mode (Fig. 9B;
n = 4), indicating a main contribution of Kv3 channels
in fast spiking.
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Figure 9.
Kv3-type channels are the main voltage-gated
K+ channels contributing to the fast repolarizations
and afterhyperpolarizations during action potential trains in BCs.
A, B, Train of action
potentials evoked in a BC (whole-cell, current-clamp recording) by a
current pulse (1 sec, 160 pA), in the absence (A)
and presence (B) of 0.2 mM 4-AP.
Membrane potential before the pulse was 70 mV (holding current, 40
pA). One hundred micromolar Cd2+ was used in the
external solution in both conditions. C,
K+ current in a BC patch during a high frequency
train. The experimentally recorded action potential pattern was applied
as voltage-clamp command (inset). The resulting current
is shown in the absence (top trace) and presence
(bottom trace) of 0.2 mM 4-AP, with 0.3 µM TTX added to the bath solution. Average of 10 individual sweeps, leak and capacitive currents were subtracted by a P
over 4 procedure. Holding potential, 70 mV. Different BCs in
A, B, and C.
D, Summary graph of deactivation and activation time
constants of the Kv3-like K+ current component in
BCs plotted against voltage. The voltage trajectories of BC action
potentials are shown on the right.
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To quantify the contribution of the three K+ current
components to repolarization and afterhyperpolarization during a
high-frequency spike train, action potential patterns were applied as
voltage-clamp commands to BC patches (Fig. 9C). The
transient outward currents activated by each spike were almost
completely blocked by 0.2 mM 4-AP (n = 3),
indicating that the fast delayed rectifier K+
channels were activated selectively. Fast activation at the action potential peak and fast deactivation at the resting potential appeared
to be the key properties that underlie the selective activation of
these channels during action potential trains (Fig. 9D). In
contrast, the contribution of the slow delayed rectifier K+ channels and the A-type K+
channels was minimal, presumably because their activation was too slow,
or because they were largely inactivated at the resting potential.
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DISCUSSION |
Using the nucleated patch configuration that allows us to
investigate somatic ion channels under almost ideal voltage-clamp conditions (Martina and Jonas, 1997), we have examined the kinetic properties of K+ channels of identified fast-spiking
interneurons and regularly spiking pyramidal neurons in brain slices
from 11- to 16-d-old rats. In both BCs and PCs two distinct delayed
rectifier K+ current components and an A-type
K+ current component were identified. Whereas the
functional characteristics of the three components were relatively
similar in the two types of neurons, the contribution to the
total current in nucleated patches differed substantially. The fast
delayed rectifier K+ current predominated in BC
patches, whereas the A-type component was mainly found in PC patches.
The slow delayed rectifier K+ current was present in
both types of neurons (Table 1).
Using single-cell RT-PCR, the most sensitive method for mRNA detection,
we have analyzed the expression of Kv subunit mRNAs in BCs and PCs.
Based on their functional properties, Kv2, Kv3, and Kv4 were the
primary candidate subunits from which the native somatic channels were
likely to be assembled. A contribution of members of the Kv1 subfamily
as homomers or in combination with subunits (Sewing et al., 1996)
was less likely because recombinant Kv1.1, Kv1.2, and Kv1.6 channels
are highly sensitive to DTX (Stühmer et al., 1989; Pongs, 1992),
and Kv1.4 channels show very slow recovery from inactivation
(Ruppersberg et al., 1990). The results of the RT-PCR analysis were
consistent with the view that the reciprocal expression of Kv3.1/Kv3.2
and Kv4.2/Kv4.3 subunits underlies the different relative contributions
of the fast delayed rectifier component and the A-type component in the
two types of neurons.
Comparison with recombinant K+ channels
In agreement with the results of the molecular analysis, the
native K+ current components showed several
functional similarities with recombinant K+ channels
assembled from Kv3, Kv2, and Kv4 subunits, respectively.
The fast delayed rectifier K+ current component
resembled recombinant Kv3.1 and Kv3.2 channels in most basic properties
(Rettig et al., 1992; Kirsch and Drewe, 1993; Grissmer et al., 1994). Like the native K+ current component, Kv3.1 and
Kv3.2 channels are highly sensitive to both external TEA
(IC50 0.1-0.2 mM) and 4-AP (0.08 mM), activate and deactivate rapidly (deactivation time
constant at 40 mV, ~3 msec), and show only minimal inactivation.
However, the midpoint potential of the activation curve of recombinant
Kv3 channels is more positive (6-19 mV), whereas the voltage
dependence is similar (6-10 mV voltage per e-fold change in
conductance) to that observed for the native channels.
The slow delayed rectifier K+ current component was
similar to recombinant Kv2 channels in some but not all functional
properties. Like the native K+ current component,
recombinant Kv2 channels show intermediate TEA-sensitivity (5.5 mM for recombinant Kv2 channels; Taglialatela et al., 1991)
and slow activation time course. Unlike the native K+ current, however, the midpoint potential of the
inactivation curve of Kv2 channels is more positive (midpoint potential
25 mV; Shi et al., 1994).
The native A-type K+ current component was very
similar to recombinant Kv4 channels. Kv4 channels are insensitive to
TEA (10 mM), are blocked only by high concentrations of
4-AP, and have a relatively flat activation curve (midpoint potential,
7 mV; slope factor, 20-22 mV; Baldwin et al., 1991; Pak et al.,
1991). The midpoint potential and steepness of the inactivation curve (69 and 4.7 mV; Pak et al., 1991) are also comparable to those of the
native A-type K+ current component. A contribution
of Kv1.4 to the A-type current in BC and PC patches appeared unlikely,
because the recovery of recombinant Kv1.4 channels from inactivation
extends over several seconds (Ruppersberg et al., 1990).
DTX, a selective blocker of Kv1.1, Kv1.2, and Kv1.6 channels
(Stühmer et al., 1989; Pongs, 1992), had only minimal effects on
the K+ current in both BC and PC patches, indicating
that Kv1.1, Kv1.2, and Kv1.6 channels were not present at the soma of
these neurons. Single-cell RT-PCR analysis revealed, however, that
Kv1.1 is expressed in subsets of both BCs and PCs and that Kv1.2 is
present in a subset of PCs. These results agree with previous in
situ hybridization studies (Kues and Wunder, 1992) and may confirm
the suggestion that Kv1 subunit proteins are specifically segregated to
axons and presynaptic structures (Jonas et al., 1989; Sheng et al., 1994).
Differential expression of K+ channel subunits
in BCs and PCs
Previous studies indicated that Kv3.1 subunits are expressed
preferentially in parvalbumin-positive, probably fast-spiking, interneurons in the hippocampus (Weiser et al., 1995; Du et al., 1996)
and in fast-spiking interneurons of the neocortex (Massengill et al.,
1997). Using single-cell RT-PCR analysis for several
K+ channel subunits, we extend these findings and
show that both Kv3.1 and Kv3.2 subunit mRNA were expressed in almost
all BCs, whereas they were detected only in a minor subset of PCs.
Conversely, Kv4.2 and Kv4.3 subunit mRNAs were expressed in the
majority of PCs, whereas the detection frequency in BCs was
substantially lower. This suggests that the expression of Kv3 and Kv4
subunit genes in the two types of neurons is regulated reciprocally.
Differential expression of Kv3 and Kv4 subunits appears to be part of a
complex genetic program that regulates the expression of voltage- and ligand-gated ion channel subunits in both types of neurons (Geiger et
al., 1995; Gan et al., 1996).
The present results indicate that the coexpression of multiple members
of the same K+ channel subfamily in a single cell is
a main principle of the molecular organization of native
K+ channel mosaics. Evidence for coexpression is
provided by the high percentage of interneurons positive for Kv3.1 and
Kv3.2 mRNA (>80%) in RT-PCR experiments with specific primers and by
the codetection of Kv2.1/Kv2.2, Kv4.2/Kv4.3, and Kv1.2/Kv1.4 subunit mRNA in experiments with common primers. This suggests that the macroscopic K+ current in BCs and PCs could be
mediated by heteromeric channels assembled independently from subunits
of the different subfamilies (Ruppersberg et al., 1990; Covarrubias et
al., 1991).
The coexpression of Kv3.1 and Kv3.2 subunits distinguishes dentate
gyrus basket cells from several other neuron types that express the two
subunits in an alternative manner (Weiser et al., 1994). Because the
gating properties of recombinant Kv3.1 and Kv3.2 channels are almost
indistinguishable, coexpression is unlikely to have direct impact on
K+ channel gating (Rettig et al., 1992). However,
coexpression possibly enables specific regulatory pathways, because
Kv3.2 (but not Kv3.1) subunits are inhibited by cAMP-dependent
phosphorylation (Moreno et al., 1995). In addition, coexpression of
Kv3.1 and Kv3.2 subunits provides a molecular backup system in
interneurons that could compensate genetic K+
channel defects. This may explain why Kv3.1-deficient mice unexpectedly do not show increased spontaneous seizure activity (Ho et al., 1997).
Functionally distinct K+ channels shape the
action potential patterns of central neurons
The present results indicate that the fast delayed rectifier
K+ channels, most likely assembled from Kv3.1 and
Kv3.2 subunits, are the main channels contributing to the
repolarization and afterhyperpolarization during action potential
trains in fast-spiking hippocampal interneurons (Fig. 9). High
voltage-activating Kv3 channels appear to be specialized to facilitate
fast spiking because they limit action potential duration without
affecting spike initiation (Kanemasa et al., 1995). The positive
threshold and the steep voltage dependence of activation allow Kv3
channels to activate very quickly in the overshooting phase of an
action potential. Once repolarization is completed, however, rapid
deactivation of Kv3 channels ensures that the next spike can be
generated with minimal delay.
The main function of A-type K+ channels, presumably
assembled from Kv4.2 and Kv4.3 subunits, appears to be facilitation of regular spiking with low frequency, contrary to that of Kv3 channels. Kv4 channels activate in the subthreshold voltage range and inactivate subsequently, thus delaying the initiation of action potentials (Hille,
1992; Song et al., 1998). The afterhyperpolarization after the spike
then promotes recovery of Kv4 channels from inactivation, resetting
them into the initial state. The location of the inactivation curve of
these channels, however, indicates that they are partially inactivated
at rest, particularly in interneurons that have more depolarized
resting potentials than principal neurons (Scharfman, 1995). Thus,
either hyperpolarization after activation of inhibitory synapses or
synaptic release of modulatory substances (e.g.,
Zn2+ ions) is required to increase the number of
available Kv4 channels (Talukder and Harrison, 1995).
In conclusion, the fast-spiking phenotype of basket cells in the
dentate gyrus appears to be shaped by three main determinants that act
in a synergistic manner: specific functional properties of interneuron
Na+ channels (steep steady-state inactivation curve
and fast recovery from inactivation; Martina and Jonas, 1997), high
level of expression of fast delayed rectifier K+
channels assembled from Kv3.1 and Kv3.2 subunits, and low level of
expression of A-type K+ channels assembled from
Kv4.2 and Kv4.3 subunits. Whether these results can be generalized to
interneurons in other neuronal circuitries remains to be addressed.
| |
FOOTNOTES |
Received April 24, 1998; revised July 23, 1998; accepted July 30, 1998.
Supported by German Israeli Foundation Grant I 0352-073.01/94 to P.J.
and Deutsche Forschungsgemeinschaft Grant Mo 432/3-1 to H.M. We thank
Drs. L. Y. Jan, D. McKinnon, O. Pongs, L. Salkoff, S. H. Snyder, and J. S. Trimmer for providing plasmids, Dr. D. J. Surmeier for sharing unpublished data, and Drs. J. Bischofberger and
J. R. P. Geiger for critically reading this manuscript.
M.M. and J.H.S. contributed equally to this work.
Correspondence should be addressed to Dr. Peter Jonas, Physiologisches
Institut, Universität Freiburg, Hermann-Herder-Strasse 7, D-79104
Freiburg, Germany.
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REFERENCES |
-
Baldwin TJ,
Tsaur M-L,
Lopez GA,
Jan YN,
Jan LY
(1991)
Characterization of a mammalian cDNA for an inactivating voltage-sensitive K+ channel.
Neuron
7:471-483[Web of Science][Medline].
-
Chandy KG
(1991)
Simplified gene nomenclature.
Nature
352:26[Medline].
-
Connors BW,
Gutnick MJ
(1990)
Intrinsic firing patterns of diverse neocortical neurons.
Trends Neurosci
13:99-104[Web of Science][Medline].
-
Covarrubias M,
Wei A,
Salkoff L
(1991)
Shaker, Shal, Shab, and Shaw express independent K+ current systems.
Neuron
7:763-773[Web of Science][Medline].
-
Du J,
Zhang L,
Weiser M,
Rudy B,
McBain CJ
(1996)
Developmental expression and functional characterization of the potassium-channel subunit Kv3.1b in parvalbumin-containing interneurons of the rat hippocampus.
J Neurosci
16:506-518[Abstract/Free Full Text].
-
Ficker E,
Heinemann U
(1992)
Slow and fast transient potassium currents in cultured rat hippocampal cells.
J Physiol (Lond)
445:431-455[Abstract/Free Full Text].
-
Gan L,
Perney TM,
Kaczmarek LK
(1996)
Cloning and characterization of the promoter for a potassium channel expressed in high frequency firing neurons.
J Biol Chem
271:5859-5865[Abstract/Free Full Text].
-
Geiger JRP,
Melcher T,
Koh D-S,
Sakmann B,
Seeburg PH,
Jonas P,
Monyer H
(1995)
Relative abundance of subunit mRNAs determines gating and Ca2+ permeability of AMPA receptors in principal neurons and interneurons in rat CNS.
Neuron
15:193-204[Web of Science][Medline].
-
Grissmer S,
Nguyen AN,
Aiyar J,
Hanson DC,
Mather RJ,
Gutman GA,
Karmilowicz MJ,
Auperin DD,
Chandy KG
(1994)
Pharmacological characterization of five cloned voltage-gated K+ channels, types Kv1.1, 1.2, 1.3, 1.5, and 3.1, stably expressed in mammalian cell lines.
Mol Pharmacol
45:1227-1234[Abstract].
-
Han Z-S,
Buhl EH,
Lörinczi Z,
Somogyi P
(1993)
A high degree of spatial selectivity in the axonal and dendritic domains of physiologically identified local-circuit neurons in the dentate gyrus of the rat hippocampus.
Eur J Neurosci
5:395-410[Web of Science][Medline].
-
Hille B
(1992)
In: Ionic channels of excitable membranes. Sunderland, MA: Sinauer.
-
Ho CS,
Grange RW,
Joho RH
(1997)
Pleiotropic effects of a disrupted K+ channel gene: reduced body weight, impaired motor skill and muscle contraction, but no seizures.
Proc Natl Acad Sci USA
94:1533-1538[Abstract/Free Full Text].
-
Jonas P,
Bräu ME,
Hermsteiner M,
Vogel W
(1989)
Single-channel recording in myelinated nerve fibers reveals one type of Na channel but different K channels.
Proc Natl Acad Sci USA
86:7238-7242[Abstract/Free Full Text].
-
Kanemasa T,
Gan L,
Perney TM,
Wang L-Y,
Kaczmarek LK
(1995)
Electrophysiological and pharmacological characterization of a mammalian Shaw channel expressed in NIH 3T3 fibroblasts.
J Neurophysiol
74:207-217[Abstract/Free Full Text].
-
Kirsch GE,
Drewe JA
(1993)
Gating-dependent mechanism of 4-aminopyridine block in two related potassium channels.
J Gen Physiol
102:797-816[Abstract/Free Full Text].
-
Kues WA,
Wunder F
(1992)
Heterogeneous expression patterns of mammalian potassium channel genes in developing and adult rat brain.
Eur J Neurosci
4:1296-1308[Web of Science][Medline].
-
Madison DV,
Nicoll RA
(1984)
Control of the repetitive discharge of rat CA1 pyramidal neurones in vitro.
J Physiol (Lond)
354:319-331[Abstract/Free Full Text].
-
Maletic-Savatic M,
Lenn NJ,
Trimmer JS
(1995)
Differential spatiotemporal expression of K+ channel polypeptides in rat hippocampal neurons developing in situ and in vitro.
J Neurosci
15:3840-3851[Abstract].
-
Martina M,
Jonas P
(1997)
Functional differences in Na+ channel gating between fast-spiking interneurones and principal neurones of rat hippocampus.
J Physiol (Lond)
505:593-603[Abstract/Free Full Text].
-
Massengill JL,
Smith MA,
Son DI,
O'Dowd DK
(1997)
Differential expression of K4-AP currents and Kv3.1 potassium channel transcripts in cortical neurons that develop distinct firing phenotypes.
J Neurosci
17:3136-3147[Abstract/Free Full Text].
-
Monyer H,
Jonas P
(1995)
Polymerase chain reaction analysis of ion channel expression in single neurons of brain slices.
In: Single-channel recording (Sakmann B,
Neher E,
eds), pp 357-373. New York: Plenum.
-
Moreno H,
Kentros C,
Bueno E,
Weiser M,
Hernandez A,
Vega-Saenz de Miera E,
Ponce A,
Thornhill W,
Rudy B
(1995)
Thalamocortical projections have a K+ channel that is phosphorylated and modulated by cAMP-dependent protein kinase.
J Neurosci
15:5486-5501[Abstract].
-
Numann RE,
Wadman WJ,
Wong RKS
(1987)
Outward currents of single hippocampal cells obtained from the adult guinea-pig.
J Physiol (Lond)
393:331-353[Abstract/Free Full Text].
-
Pak MD,
Baker K,
Covarrubias M,
Butler A,
Ratcliffe A,
Salkoff L
(1991)
MShal, a subfamily of A-type K+ channel cloned from mammalian brain.
Proc Natl Acad Sci USA
88:4386-4390[Abstract/Free Full Text].
-
Pongs O
(1992)
Molecular biology of voltage-dependent potassium channels.
Physiol Rev
72:S69-S88.
-
Rettig J,
Wunder F,
Stocker M,
Lichtinghagen R,
Mastiaux F,
Beckh S,
Kues W,
Pedarzani P,
Schröter KH,
Ruppersberg JP,
Veh R,
Pongs O
(1992)
Characterization of a Shaw-related potassium channel family in rat brain.
EMBO J
11:2473-2486[Web of Science][Medline].
-
Ruppersberg JP,
Schröter KH,
Sakmann B,
Stocker M,
Sewing S,
Pongs O
(1990)
Heteromultimeric channels formed by rat brain potassium-channel proteins.
Nature
345:535-537[Medline].
-
Ruppersberg JP,
Stocker M,
Pongs O,
Heinemann SH,
Frank R,
Koenen M
(1991)
Regulation of fast inactivation of cloned mammalian IK(A) channels by cysteine oxidation.
Nature
352:711-714[Medline].
-
Scharfman HE
(1995)
Electrophysiological diversity of pyramidal-shaped neurons at the granule cell layer/hilus border of the rat dentate gyrus recorded in vitro.
Hippocampus
5:287-305[Web of Science][Medline].
-
Serôdio P,
Rudy B
(1998)
Differential expression of Kv4 K+ channel subunits mediating subthreshold transient K+ (A-type) currents in rat brain.
J Neurophysiol
79:1081-1091[Abstract/Free Full Text].
-
Sewing S,
Roeper J,
Pongs O
(1996)
Kv1 subunit binding specific for Shaker-related potassium channel subunits.
Neuron
16:455-463[Web of Science][Medline].
-
Sheng M,
Tsaur M-L,
Jan YN,
Jan LY
(1994)
Contrasting subcellular localization of the Kv1.2 K+ channel subunit in different neurons of rat brain.
J Neurosci
14:2408-2417[Abstract].
-
Shi G,
Kleinklaus AK,
Marrion NV,
Trimmer JS
(1994)
Properties of Kv2.1 K+ channels expressed in transfected mammalian cells.
J Biol Chem
269:23204-23211[Abstract/Free Full Text].
-
Song W-J,
Tkatch T,
Baranauskas G,
Ichinohe N,
Kitai ST,
Surmeier DJ
(1998)
Somatodendritic depolarization-activated potassium currents in rat neostriatal cholinergic interneurons are predominantly of the A type and attributable to coexpression of Kv4.2 and Kv4.1 subunits.
J Neurosci
18:3124-3137[Abstract/Free Full Text].
-
Storm JF
(1990)
Potassium currents in hippocampal pyramidal cells.
Prog Brain Res
83:161-187[Web of Science][Medline].
-
Stühmer W,
Ruppersberg JP,
Schröter KH,
Sakmann B,
Stocker M,
Giese KP,
Perschke A,
Baumann A,
Pongs O
(1989)
Molecular basis of functional diversity of voltage-gated potassium channels in mammalian brain.
EMBO J
8:3235-3244[Web of Science][Medline].
-
Taglialatela M,
Vandongen AMJ,
Drewe JA,
Joho RH,
Brown AM,
Kirsch GE
(1991)
Patterns of internal and external tetraethylammonium block in four homologous K+ channels.
Mol Pharmacol
40:299-307[Abstract].
-
Talukder G,
Harrison NL
(1995)
On the mechanism of modulation of transient outward current in cultured rat hippocampal neurons by di- and trivalent cations.
J Neurophysiol
73:73-79[Abstract/Free Full Text].
-
Tsaur M-L,
Chou C-C,
Shih Y-H,
Wang H-L
(1997)
Cloning, expression and CNS distribution of Kv4.3, an A-type K+ channel subunit.
FEBS Lett
400:215-230[Web of Science][Medline].
-
Weiser M,
Vega-Saenz de Miera E,
Kentros C,
Moreno H,
Franzen L,
Hillman D,
Baker H,
Rudy B
(1994)
Differential expression of Shaw-related K+ channels in the rat central nervous system.
J Neurosci
14:949-972[Abstract].
-
Weiser M,
Bueno E,
Sekirnjak C,
Martone ME,
Baker H,
Hillman D,
Chen S,
Thornhill W,
Ellisman M,
Rudy B
(1995)
The potassium channel subunit KV3.1b is localized to somatic and axonal membranes of specific populations of CNS neurons.
J Neurosci
15:4298-4314[Abstract].
-
Zhang L,
McBain CJ
(1995a)
Voltage-gated potassium currents in stratum oriens-alveus inhibitory neurones of the rat CA1 hippocampus.
J Physiol (Lond)
488:647-660[Abstract/Free Full Text].
-
Zhang L,
McBain CJ
(1995b)
Potassium conductances underlying repolarization and afterhyperpolarization in rat CA1 hippocampal interneurones.
J Physiol (Lond)
488:661-672[Abstract/Free Full Text].
Copyright © 1998 Society for Neuroscience 0270-6474/98/18208111-15$05.00/0
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[PDF]
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[Full Text]
[PDF]
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[Full Text]
[PDF]
|
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[Abstract]
[Full Text]
[PDF]
|
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|
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[Full Text]
[PDF]
|
|
|
|
|
|
|
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[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
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67(5):
1513 - 1521.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
R. D. Traub, D. Contreras, M. O. Cunningham, H. Murray, F. E. N. LeBeau, A. Roopun, A. Bibbig, W. B. Wilent, M. J. Higley, and M. A. Whittington
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J Neurophysiol,
April 1, 2005;
93(4):
2194 - 2232.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
W. B. Wilent and D. Contreras
Stimulus-Dependent Changes in Spike Threshold Enhance Feature Selectivity in Rat Barrel Cortex Neurons
J. Neurosci.,
March 16, 2005;
25(11):
2983 - 2991.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
F. R. Fernandez, W. H. Mehaffey, M. L. Molineux, and R. W. Turner
High-Threshold K+ Current Increases Gain by Offsetting a Frequency-Dependent Increase in Low-Threshold K+ Current
J. Neurosci.,
January 12, 2005;
25(2):
363 - 371.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
J.-F. Leger, E. A. Stern, A. Aertsen, and D. Heck
Synaptic Integration in Rat Frontal Cortex Shaped by Network Activity
J Neurophysiol,
January 1, 2005;
93(1):
281 - 293.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. Toledo-Rodriguez, B. Blumenfeld, C. Wu, J. Luo, B. Attali, P. Goodman, and H. Markram
Correlation Maps Allow Neuronal Electrical Properties to be Predicted from Single-cell Gene Expression Profiles in Rat Neocortex
Cereb Cortex,
December 1, 2004;
14(12):
1310 - 1327.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
T. Shevchenko, R. Teruyama, and W. E. Armstrong
High-Threshold, Kv3-Like Potassium Currents in Magnocellular Neurosecretory Neurons and Their Role in Spike Repolarization
J Neurophysiol,
November 1, 2004;
92(5):
3043 - 3055.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
Z. Borhegyi, V. Varga, N. Szilagyi, D. Fabo, and T. F. Freund
Phase Segregation of Medial Septal GABAergic Neurons during Hippocampal Theta Activity
J. Neurosci.,
September 29, 2004;
24(39):
8470 - 8479.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
S. G. Birnbaum, A. W. Varga, L.-L. Yuan, A. E. Anderson, J. D. Sweatt, and L. A. Schrader
Structure and Function of Kv4-Family Transient Potassium Channels
Physiol Rev,
July 1, 2004;
84(3):
803 - 833.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. T. Perez-Garcia, O. Colinas, E. Miguel-Velado, A. Moreno-Dominguez, and J. R. Lopez-Lopez
Characterization of the Kv channels of mouse carotid body chemoreceptor cells and their role in oxygen sensing
J. Physiol.,
June 1, 2004;
557(2):
457 - 471.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
N. Axmacher and R. Miles
Intrinsic cellular currents and the temporal precision of EPSP-action potential coupling in CA1 pyramidal cells
J. Physiol.,
March 15, 2004;
555(3):
713 - 725.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
W. Shen, S. Hernandez-Lopez, T. Tkatch, J. E. Held, and D. J. Surmeier
Kv1.2-Containing K+ Channels Regulate Subthreshold Excitability of Striatal Medium Spiny Neurons
J Neurophysiol,
March 1, 2004;
91(3):
1337 - 1349.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
A. Lewis, Z. A. McCrossan, and G. W. Abbott
MinK, MiRP1, and MiRP2 Diversify Kv3.1 and Kv3.2 Potassium Channel Gating
J. Biol. Chem.,
February 27, 2004;
279(9):
7884 - 7892.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
N. Hatano, S. Ohya, K. Muraki, R. B. Clark, W. R. Giles, and Y. Imaizumi
Two Arginines in the Cytoplasmic C-terminal Domain Are Essential for Voltage-dependent Regulation of A-type K+ Current in the Kv4 Channel Subfamily
J. Biol. Chem.,
February 13, 2004;
279(7):
5450 - 5459.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
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J. H Goldberg, G. Tamas, and R. Yuste
Ca2+ imaging of mouse neocortical interneurone dendrites: Ia-type K+ channels control action potential backpropagation
J. Physiol.,
August 15, 2003;
551(1):
49 - 65.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
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
J. Neurosci.,
July 2, 2003;
23(13):
5698 - 5707.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
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S. Hattori, F. Murakami, and W.-J. Song
Quantitative Relationship Between Kv4.2 mRNA and A-Type K+ Current in Rat Striatal Cholinergic Interneurons During Development
J Neurophysiol,
July 1, 2003;
90(1):
175 - 183.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
E. Bracci, D. Centonze, G. Bernardi, and P. Calabresi
Voltage-dependent membrane potential oscillations of rat striatal fast-spiking interneurons
J. Physiol.,
May 15, 2003;
549(1):
121 - 130.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
J. C. Brumberg, F. Hamzei-Sichani, and R. Yuste
Morphological and Physiological Characterization of Layer VI Corticofugal Neurons of Mouse Primary Visual Cortex
J Neurophysiol,
May 1, 2003;
89(5):
2854 - 2867.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
Y. Dong and F. J. White
Dopamine D1-Class Receptors Selectively Modulate a Slowly Inactivating Potassium Current in Rat Medial Prefrontal Cortex Pyramidal Neurons
J. Neurosci.,
April 1, 2003;
23(7):
2686 - 2695.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
I. Fukui and H. Ohmori
Developmental changes in membrane excitability and morphology of neurons in the nucleus angularis of the chicken
J. Physiol.,
April 1, 2003;
548(1):
219 - 232.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
T. Volk, A. P. Schwoerer, S. Thiessen, J.-H. Schultz, and H. Ehmke
A polycystin-2-like large conductance cation channel in rat left ventricular myocytes
Cardiovasc Res,
April 1, 2003;
58(1):
76 - 88.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
C.-C. Lien and P. Jonas
Kv3 Potassium Conductance is Necessary and Kinetically Optimized for High-Frequency Action Potential Generation in Hippocampal Interneurons
J. Neurosci.,
March 15, 2003;
23(6):
2058 - 2068.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
D. V Vasilyev and M. E Barish
Regulation of an inactivating potassium current (IA) by the extracellular matrix protein vitronectin in embryonic mouse hippocampal neurones
J. Physiol.,
March 15, 2003;
547(3):
859 - 871.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
R. D. Traub, E. H. Buhl, T. Gloveli, and M. A. Whittington
Fast Rhythmic Bursting Can Be Induced in Layer 2/3 Cortical Neurons by Enhancing Persistent Na+ Conductance or by Blocking BK Channels
J Neurophysiol,
February 1, 2003;
89(2):
909 - 921.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
C.-Y. Chen, A. C. Bonham, C. G. Plopper, and J. P. Joad
Plasticity in Respiratory Motor Control: Selected Contribution: Neuroplasticity in nucleus tractus solitarius neurons after episodic ozone exposure in infant primates
J Appl Physiol,
February 1, 2003;
94(2):
819 - 827.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
H Pawelzik, D I Hughes, and A M Thomson
Modulation of inhibitory autapses and synapses on rat CA1 interneurones by GABAa receptor ligands
J. Physiol.,
February 1, 2003;
546(3):
701 - 716.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
J. Mitterdorfer and B. P. Bean
Potassium Currents during the Action Potential of Hippocampal CA3 Neurons
J. Neurosci.,
December 1, 2002;
22(23):
10106 - 10115.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. Bartos, I. Vida, M. Frotscher, A. Meyer, H. Monyer, J. R. P. Geiger, and P. Jonas
Fast synaptic inhibition promotes synchronized gamma oscillations in hippocampal interneuron networks
PNAS,
October 1, 2002;
99(20):
13222 - 13227.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
G. M. J. Ramakers and J. F. Storm
A postsynaptic transient K+ current modulated by arachidonic acid regulates synaptic integration and threshold for LTP induction in hippocampal pyramidal cells
PNAS,
July 23, 2002;
99(15):
10144 - 10149.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
D. M. Porcello, C. S. Ho, R. H. Joho, and J. R. Huguenard
Resilient RTN Fast Spiking in Kv3.1 Null Mice Suggests Redundancy in the Action Potential Repolarization Mechanism
J Neurophysiol,
March 1, 2002;
87(3):
1303 - 1310.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
C.-C. Lien, M. Martina, J. H Schultz, H. Ehmke, and P. Jonas
Gating, modulation and subunit composition of voltage-gated K+ channels in dendritic inhibitory interneurones of rat hippocampus
J. Physiol.,
January 15, 2002;
538(2):
405 - 419.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
P. Mann-Metzer and Y. Yarom
Jittery Trains Induced by Synaptic-Like Currents in Cerebellar Inhibitory Interneurons
J Neurophysiol,
January 1, 2002;
87(1):
149 - 156.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
V. Riazanski, A. Becker, J. Chen, D. Sochivko, A. Lie, O. D Wiestler, C. E Elger, and H. Beck
Functional and molecular analysis of transient voltage-dependent K+ currents in rat hippocampal granule cells
J. Physiol.,
December 1, 2001;
537(2):
391 - 406.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
J. M. Bekkers and A. J. Delaney
Modulation of Excitability by {alpha}-Dendrotoxin-Sensitive Potassium Channels in Neocortical Pyramidal Neurons
J. Neurosci.,
September 1, 2001;
21(17):
6553 - 6560.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
P. A. Castro, E. C. Cooper, D. H. Lowenstein, and S. C. Baraban
Hippocampal Heterotopia Lack Functional Kv4.2 Potassium Channels in the Methylazoxymethanol Model of Cortical Malformations and Epilepsy
J. Neurosci.,
September 1, 2001;
21(17):
6626 - 6634.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
F. Espinosa, A. McMahon, E. Chan, S. Wang, C. S. Ho, N. Heintz, and R. H. Joho
Alcohol Hypersensitivity, Increased Locomotion, and Spontaneous Myoclonus in Mice Lacking the Potassium Channels Kv3.1 and Kv3.3
J. Neurosci.,
September 1, 2001;
21(17):
6657 - 6665.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. Galarreta and S. Hestrin
Spike Transmission and Synchrony Detection in Networks of GABAergic Interneurons
Science,
June 22, 2001;
292(5525):
2295 - 2299.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. Bartos, I. Vida, M. Frotscher, J. R. P. Geiger, and P. Jonas
Rapid Signaling at Inhibitory Synapses in a Dentate Gyrus Interneuron Network
J. Neurosci.,
April 15, 2001;
21(8):
2687 - 2698.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
R. K Ellerkmann, V. Riazanski, C. E Elger, B. W Urban, and H. Beck
Slow recovery from inactivation regulates the availability of voltage-dependent Na+ channels in hippocampal granule cells, hilar neurons and basket cells
J. Physiol.,
April 15, 2001;
532(2):
385 - 397.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
D. Hess and A. El Manira
Characterization of a high-voltage-activated IA current with a role in spike timing and locomotor pattern generation
PNAS,
April 12, 2001;
(2001)
91096198.
[Abstract]
[Full Text]
|
|
|
|
|
|
|
J.-H. Schultz, T. Volk, and H. Ehmke
Heterogeneity of Kv2.1 mRNA Expression and Delayed Rectifier Current in Single Isolated Myocytes From Rat Left Ventricle
Circ. Res.,
March 16, 2001;
88(5):
483 - 490.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
C. Chabbert, J. M. Chambard, A. Sans, and G. Desmadryl
Three Types of Depolarization-Activated Potassium Currents in Acutely Isolated Mouse Vestibular Neurons
J Neurophysiol,
March 1, 2001;
85(3):
1017 - 1026.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
J. T. Blaine and A. B. Ribera
Kv2 Channels Form Delayed-Rectifier Potassium Channels In Situ
J. Neurosci.,
March 1, 2001;
21(5):
1473 - 1480.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
S. Parameshwaran, C. E. Carr, and T. M. Perney
Expression of the Kv3.1 Potassium Channel in the Avian Auditory Brainstem
J. Neurosci.,
January 15, 2001;
21(2):
485 - 494.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. A Wigmore and M. G Lacey
A Kv3-like persistent, outwardly rectifying, Cs+-permeable, K+ current in rat subthalamic nucleus neurones
J. Physiol.,
September 15, 2000;
527(3):
493 - 506.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
U. Kraushaar and P. Jonas
Efficacy and Stability of Quantal GABA Release at a Hippocampal Interneuron-Principal Neuron Synapse
J. Neurosci.,
August 1, 2000;
20(15):
5594 - 5607.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
S. A. Malin and J. M. Nerbonne
Elimination of the Fast Transient in Superior Cervical Ganglion Neurons with Expression of KV4.2W362F: Molecular Dissection of IA
J. Neurosci.,
July 15, 2000;
20(14):
5191 - 5199.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
J. M Bekkers
Properties of voltage-gated potassium currents in nucleated patches from large layer 5 cortical pyramidal neurons of the rat
J. Physiol.,
June 15, 2000;
525(3):
593 - 609.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
T. Aoki and S. C. Baraban
Properties of a Calcium-Activated K+ Current on Interneurons in the Developing Rat Hippocampus
J Neurophysiol,
June 1, 2000;
83(6):
3453 - 3461.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
R. Shibata, K. Nakahira, K. Shibasaki, Y. Wakazono, K. Imoto, and K. Ikenaka
A-Type K+ Current Mediated by the Kv4 Channel Regulates the Generation of Action Potential in Developing Cerebellar Granule Cells
J. Neurosci.,
June 1, 2000;
20(11):
4145 - 4155.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. L. McAnelly and H. H. Zakon
Coregulation of Voltage-Dependent Kinetics of Na+ and K+ Currents in Electric Organ
J. Neurosci.,
May 1, 2000;
20(9):
3408 - 3414.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
O. N. Osipenko, R. J. Tate, and A. M. Gurney
Potential Role for Kv3.1b Channels as Oxygen Sensors
Circ. Res.,
March 17, 2000;
86(5):
534 - 540.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
G. Grosse, A. Draguhn, L. Hohne, R. Tapp, R. W. Veh, and G. Ahnert-Hilger
Expression of Kv1 Potassium Channels in Mouse Hippocampal Primary Cultures: Development and Activity-Dependent Regulation
J. Neurosci.,
March 1, 2000;
20(5):
1869 - 1882.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
A. E. Anderson, J. P. Adams, Y. Qian, R. G. Cook, P. J. Pfaffinger, and J. D. Sweatt
Kv4.2 Phosphorylation by Cyclic AMP-dependent Protein Kinase
J. Biol. Chem.,
February 25, 2000;
275(8):
5337 - 5346.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
I. Vida and M. Frotscher
A hippocampal interneuron associated with the mossy fiber system
PNAS,
February 1, 2000;
97(3):
1275 - 1280.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
T. Tkatch, G. Baranauskas, and D. J. Surmeier
Kv4.2 mRNA Abundance and A-Type K+ Current Amplitude Are Linearly Related in Basal Ganglia and Basal Forebrain Neurons
J. Neurosci.,
January 15, 2000;
20(2):
579 - 588.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
J. Kang, J. R. Huguenard, and D. A. Prince
Voltage-Gated Potassium Channels Activated During Action Potentials in Layer V Neocortical Pyramidal Neurons
J Neurophysiol,
January 1, 2000;
83(1):
70 - 80.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
J. Du, L. L Haak, E. Phillips-Tansey, J. T Russell, and C. J McBain
Frequency-dependent regulation of rat hippocampal somato-dendritic excitability by the K+ channel subunit Kv2.1
J. Physiol.,
January 1, 2000;
522(1):
19 - 31.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
S. Nedergaard
Regulation of Action Potential Size and Excitability in Substantia Nigra Compacta Neurons: Sensitivity to 4-Aminopyridine
J Neurophysiol,
December 1, 1999;
82(6):
2903 - 2913.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
R. Hernandez-Pineda, A. Chow, Y. Amarillo, H. Moreno, M. Saganich, E. V.-S. de Miera, A. Hernandez-Cruz, and B. Rudy
Kv3.1-Kv3.2 Channels Underlie a High-Voltage-Activating Component of the Delayed Rectifier K+ Current in Projecting Neurons From the Globus Pallidus
J Neurophysiol,
September 1, 1999;
82(3):
1512 - 1528.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
S. Vassanelli and P. Fromherz
Transistor Probes Local Potassium Conductances in the Adhesion Region of Cultured Rat Hippocampal Neurons
J. Neurosci.,
August 15, 1999;
19(16):
6767 - 6773.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
G. Baranauskas, T. Tkatch, and D. J. Surmeier
Delayed Rectifier Currents in Rat Globus Pallidus Neurons Are Attributable to Kv2.1 and Kv3.1/3.2 K+ Channels
J. Neurosci.,
August 1, 1999;
19(15):
6394 - 6404.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. Song, G. Helguera, M. Eghbali, N. Zhu, M. M. Zarei, R. Olcese, L. Toro, and E. Stefani
Remodeling of Kv4.3 Potassium Channel Gene Expression under the Control of Sex Hormones
J. Biol. Chem.,
August 17, 2001;
276(34):
31883 - 31890.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
D. Hess and A. El Manira
Characterization of a high-voltage-activated IA current with a role in spike timing and locomotor pattern generation
PNAS,
April 24, 2001;
98(9):
5276 - 5281.
[Abstract]
[Full Text]
[PDF]
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Top
Abstract
Introduction
Compound via MeSH
