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The Journal of Neuroscience, August 13, 2003, 23(19):7426-7437
 Previous Article | Next Article 
ATP Modulation of Excitatory Synapses onto Interneurons
Baljit S. Khakh,1
Daniel Gittermann,1
Debra A. Cockayne,2 and
Alison Jones1
1Medical Research Council Laboratory of Molecular
Biology, Cambridge CB2 2QH, United Kingdom, and 2Roche
Bioscience, Palo Alto, California 94304
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Abstract
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Inhibitory interneurons play important roles in neuronal circuits, but the
synaptic mechanisms that regulate excitatory input onto interneurons remain to
be fully understood. We show that ATP-gated presynaptic P2X2 channels
facilitate excitatory transmission onto stratum radiatum interneurons but not
onto CA1 pyramidal neurons. ATP released endogenously during carbachol-induced
oscillations facilitates excitatory synapses onto interneurons. Overall, these
data provide evidence for the molecular identity, synaptic function, and
interneuron synapse specificity of a presynaptic neurotransmitter-gated cation
channel. The findings highlight a novel form of presynaptic facilitation for
hippocampal interneurons and suggest a role for extracellular ATP in neuronal
networks.
Key words: ATP; P2X; synapse; interneuron; channel; oscillation
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Introduction
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Inhibitory interneurons form extensive GABAergic and electrical synapses
among themselves and GABAergic synapses onto pyramidal neurons
(McBain and Fisahn, 2001 ). By
virtue of their precise projection patterns, distinct interneurons set a time
window for when pyramidal neurons cannot spike
(McBain and Fisahn, 2001).
Interneurons shape the ability of the hippocampus to process information
because they modulate and contribute to neuronal network oscillations in
distinct frequency bands in the hippocampus both in vivo and in
vitro (Buzsaki, 2002).
Theta (4 -12 Hz) oscillations are absent during immobility, occur during
states of locomotor activity, and are present during rapid eye movement sleep,
whereas gamma ( 30-80 Hz) oscillations occur during states of arousal,
focused attention, and the dreaming phase of sleep and disappear during
slow-wave sleep and anesthesia (McBain and
Fisahn, 2001). A key task is to understand the processes that
regulate excitatory input onto interneurons because they play a key role in
determining oscillatory activity. In this report, we show that ATP facilitates
excitatory synapses onto interneurons during oscillations.
A role for ATP as a neurotransmitter was suggested 30 years ago
(Burnstock, 1972). There is
accumulating evidence that extracellular ATP is both a transmitter and a
modulator in the nervous system (Khakh,
2001; North,
2002). Cell surface ATP-gated P2X channels have marked
Ca2+ permeability and constitute a relatively new family
distinct from channels for the more often studied neurotransmitters ACh,
serotonin, glutamate, GABA, and glycine. Seven mammalian P2X subunits are
known (P2X1-P2X7), and at least 11 distinct channels can be assembled in
pair-wise comparisons (Torres et al.,
1999). Multiple P2X subunits reside in postsynaptic and
presynaptic membranes in the brain
(MacDermott et al., 1999;
Khakh, 2001), and the
possibility that ATP has a widespread role in brain synapses is enticing
because ATP is found in the cytosol of cells
(Hinkle and McCarty, 1978), is
released in an activity-dependent way
(Zimmermann, 1994), mediates
an excitatory synaptic current in some neurons
(North, 2002), and is degraded
in the extracellular space by specific enzymes
(Zimmermann and Braun, 1996).
P2X channels are widely expressed in the hippocampus
(Kidd et al., 1995;
Collo et al., 1996;
Kanjhan et al., 1999;
Rubio and Soto, 2001), but the
physiology of ATP signaling at interneuron synapses has remained
unexplored.
In this study, we sought to understand the physiological role of P2X
channels in hippocampal CA3 neurons. We found no evidence for functional P2X
responses in CA3 pyramidal neuron somata from freshly isolated mouse brain
slices. We found evidence for functional P2X channels in the axons of CA3
neurons branching to their postsynaptic targets and predominantly in nerve
terminals forming synapses onto interneurons. Pharmacological experiments
suggested a role for P2X2, and we verified this by studying P2X2 null mice.
P2X2 channel expression in nerve terminals was specific for interneuron
synapses. Finally, our data indicate that nerve terminal P2X channels at
interneuron synapses are activated by endogenous ATP released during theta
frequency network oscillations. Collectively, these data provide evidence for
a hitherto unappreciated synaptic mechanism at excitatory synapses onto
interneurons.
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Materials and Methods
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Physiology. Young (10- to 15-d-old) C57 mice were killed in accord
with home office and local procedures, and a model 1000 Plus Vibratome was
used to prepare 250- to 300-µm-thick coronal slices of hippocampus
(Frazier et al., 1998). During
incubation the slices were submerged at room temperature in artificial CSF
comprising (in mM): 124 NaCl, 3.3 KCl, 2.4 MgSO4,10
D-glucose, 2.5 CaCl2, 1.2 KH2PO4,
and 25.9 NaHCO3 saturated with 95% O2 and 5%
CO2 gas. All experiments were performed at room temperature while
the tissue was superfused with artificial CSF (aCSF) at a rate of 2 ml/min.
Whole-cell patch-clamp recording was accomplished by using glass pipettes
pulled using a Flaming-Brown electrode puller (Sutter Instruments, Novato,
CA). The resistance of the pipettes was 5 M when filled with a
potassium gluconate-based internal solution, which comprised (in
mM): 130 K gluconate (or KCl), 1 EGTA, 2 MgCl2, 0.5
CaCl2, and 10 HEPES, pH 7.25. Cells were visualized with infrared
optics [Luigs & Neumann or Olympus Optical (Tokyo, Japan); 900 nm
infrared-differential interference contrast (IR-DIC)] on an upright microscope
(Olympus BX50 or BX51). The ATP puff was imaged with 10 µM
adenosine 5' triphosphate, BODIPY FL
2'-(or-3')O-(N-(2-amino ethyl) urethane), trisodium salt
(BODIPY-ATP; Molecular Probes, Eugene, OR) as a tracer on a setup using a
monochromator, cooled Imago CCD camera, and Vision software (TiLL Photonics).
Puffs of ATP were applied under visual control using a Picospritzer II
(General Valve, Fairfield, NJ). In all cases, we puffed P2X agonists for 50,
500, and 5000 msec to each cell and then in some cases removed the puffer
pipette and repositioned another containing glutamate onto the same neuron and
confirmed that the cells were responsive to glutamate; all cells responded to
glutamate. Use of the adenosine receptor antagonist
cyclopentyl-1,3-dipropylxanthine (10 -100 µM) in the bathing
medium ruled out P1 receptor involvement. Inward currents were recorded at -60
mV using pCLAMP 8 software, an Axoclamp 1D amplifier, and Digidata 1322 (Axon
Instruments, Foster City, CA). Interneurons within the CA1 region are
extremely diverse (Freund and Buzsaki,
1996). In a specific set of experiments, we attempted to relate
firing patterns (regular, irregular, and clustered) to the presence of
P2X-mediated facilitation, because only 60% of interneurons responded to
ATP and adenosine 5'-O-(thiotriphosphate)(ATP S) with a
change in excitatory synaptic transmission. Because we found no correlation,
we suggest that the 60% of interneurons that receive ATP-modulated
synapses are from a cross section of neurons that populate the stratum
radiatum and cannot be classified into a distinct class based on firing
properties. This said, the majority of interneurons in the stratum radiatum
fired regularly (Freund and Buzsaki,
1996). Antidromic action currents and evoked EPSCs were evoked
with the aid of a Grass S48 stimulator. For the experiments on antidromic
action currents, the monopolar glass stimulating electrode was placed in the
Schaffer collaterals, and voltage-clamp recordings were made from CA3
pyramidal neurons with all synaptic transmission blocked
(Semyanov and Kullmann,
2001).
Cultured hippocampal neurons were prepared and infected as described
(Khakh et al., 2001). For
measurements of ATP release, we collected five 20 µl samples every 5 min
from the bathing medium (3 ml, see above for constituents, bubbled with 95%
O2 and 5% CO2) surrounding the brain slices in a
scintillation vial. KCl, TTX, or muscarine was directly added to the bathing
medium after two or three control samples were collected. The 20 µl samples
were assayed for their ability to promote ATP-dependent bioluminescence using
the firefly luciferase assay (Sigma, Poole, UK) according to the
manufacturer's instructions.
Field recordings were obtained under conditions nearly identical to those
used for the whole-cell recordings to make comparisons possible. The recording
electrode (filled with ACSF) was placed in the CA3 cell body area
approximately halfway into the slice. We performed these experiments with
submerged slices with the aid of a 10x objective and adjusted the bath
volume to ensure that the slices were submerged under a thin film of
extracellular buffer (<0.5 mm in depth), which flowed over the slices.
Extracellular oscillations were measured with an Axoclamp 2A amplifier and
pCLAMP8 software.
All chemicals used were from Tocris (Bristol, UK) or Sigma. In the text,
the names of the chemicals abbreviated are
pyridoxal-phosphate-6-azophenyl-2',4'-disulfonic acid (PPADS),
carbamylcholine chloride (CCh), 6-cyano-2,3-dihydroxy-7-nitroquinoxaline
(CNQX), neomycin (Neo), and L-(+)-2-amino-4-phosphonobutyric acid
(L-AP-4).
Molecular biology. The embryonic stem cell work and generation of
the P2X2 -/- mice were performed using
routine methods (Hogan et al.,
1994), and a preliminary report was published previously in
abstract form (Cockayne et al.,
2002). Briefly, exons 2-11 were deleted and replaced by a neomycin
resistance cassette by homologous recombination in 129Ola-derived E14-1
embryonic stem cells (see Fig.
6). The remaining exon 1 is insufficient to form a functional
protein (Khakh, 2001;
North, 2002). The targeted
clones were injected into C57BL/6 blastocysts; chimeras were established; and
germ line transmission of the targeted allele was established by mating
chimeras to C57BL/6 mice. All mice analyzed in this study have the genetic
background 129Ola x C57BL/6 (The Jackson Laboratory, Bar Harbor, ME) and
were derived from homozygous wild-type and P2X2
-/- breeders. There were no obvious
behavioral or developmental deficits with the P2X2
-/- homozygous mice. PCR screening of tail
genomic DNA was performed using Extaq (Panvera): the sense primer in exon 1
was 5'-GTG CAG CTG CTC ATT CTG CTT-3'; the exon 2 antisense primer
was 5'-CTG CAC GAT GAA GAC GTA CCT-3'; and the Neo antisense
primer was 5'-ACG AGT TCT TCT GAG GGG ATC GGC-3'. We isolated mRNA
from whole brain and testis with oligo-dT beads using the Quick Prep Micro
mRNA purification kit (Amersham Biosciences, Arlington Heights, IL). cDNA was
reverse-transcribed from mRNA using Moloney murine leukemia virus reverse
transcriptase and oligo-dT primers (Advantage reverse transcriptase for PCR
kit; Clontech, Palo Alto, CA), and PCR was performed using Taq
polymerase (TaqPCR core kit; Qiagen, Hilden, Germany). We used rat
 -actin primers as controls [reverse transcription (RT)-PCR amplimers;
Clontech] and the following primers for the P2X2 gene: sense, 5'-ACG TTC
ATG AAC AAA AAC AAG-3'; and antisense, 5'-TCA AAG TTG GGC CAA ACC
TTT GG-3'. These primers are in exon 11 and amplify 358 bp of sequence
corresponding to the P2X2 C-terminal domain.
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Figure 6. P2X2 channels are the targets for ATP at interneuron synapses. A,
Top left, Diagrammatic representation of the endogenous mouse P2X2 (mP2X2)
locus with 11 exons. Top right, Representation of the targeted locus with
exons 2-11 deleted and replaced with Neo. In both diagrams, the black bars
indicate the approximate positions of the primers used for PCR analysis of
tail genomic DNA, as shown in the gel to the left. Both the PCR and Southern
blot (results not shown) approaches show that the mP2X2 gene is disrupted with
Neo, but because we ran the PCR screen with all three primers, this approach
additionally shows that exons downstream of exon 1 are deleted because no
wild-type band was detected (left gel). Right gel, RT-PCR results from
P2X2+/+ and P2X2
-/- mice with mRNA harvested from brain and
testis. There was P2X2 mRNA in both brain and testis from
P2X2+/+ mice but not from
P2X2-/- mice. mRNA for -actin
(-act) was present in both genotypes and tissues. mw, Molecular weight
markers. B, C, Nissl staining in
P2X2+/+ (B) and
P2X2-/- mice (C). The representative
voltage waveforms show responses of interneurons to depolarizing and
hyperpolarizing current injections. D, EPSC frequency against time
for 11 interneurons recorded from a P2X2+/+
mouse; the inset indicates that 64% of neurons responded to P2X activation in
this mouse. E, mEPSC frequency against time for 13 interneurons
recorded from a P2X2-/- mouse; the inset
indicates that only 15% of neurons responded to P2X activation in this mouse.
F, Summary of recordings for all neurons that responded to
ATPS from seven P2X2-/- and seven
P2X2+/+ mice. G, In the
P2X2-/- mice, the proportion of neurons that
receive P2X-modulated synapses is significantly reduced (p <
0.05). H, I, Resting membrane potentials (H) and membrane
resistances (I) for P2X2-/- and
P2X2+/+ mice.
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Analysis. Synaptic currents were analyzed using MiniAnalysis
program 5.3.5 (Synaptosoft) and Origin 5.1 (Origin Lab Corp.). In the analysis
of miniature EPSCs (mEPSCs) and spontaneous EPSCs (sEPSCs), we designated a
particular neuron as a responder or nonresponder post hoc, after
analyzing all events with MiniAnalysis. Thus, responders were deemed as such
if they showed a reversible increase in frequency of events concomitant with
the agonist application (from frequency vs time plots). The frequency of
events varied from cell to cell; in most cases responders were very clear, but
neurons showing less than a doubling of the frequency could have been
classified as nonresponders. Data in the text and graphs are shown as mean
± SEM from n determinations as indicated. All experiments
comparing P2X2+/+ and P2X2
-/- mice were performed blind. Fast Fourier
transforms were performed on 20 sec segments of data within Clampfit 8.0 (Axon
Instruments) or Origin, and the peak power as shown in the figures was
determined between 3 and 20 Hz. Paired pulse facilitation was calculated as
the ratio of the means of the second response to the mean of the first from 20
individual sweeps for each cell.
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Results
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We first present data to show that P2X channels are functionally absent
from CA3 somata but are functionally present in axons and nerve terminals
emanating from CA3 neurons and forming synapses onto interneurons. We next
provide insight as to how P2X channels facilitate transmitter release from
these nerve terminals and into the molecular composition of the channels.
Finally, we provide evidence for how nerve terminal P2X channels may be
activated during network activity.
Little evidence for P2X channels in intact CA3 neuron somata
Of the seven known P2X subunits, P2X2, P2X4, and P2X6 are found in
hippocampal CA3 neurons (Collo et al.,
1996; Kanjhan et al.,
1999; Rubio and Soto,
2001). We performed patch-clamp recordings from neurons in freshly
isolated hippocampal slices and rapidly puffed ATP to measure P2X responses in
CA3 neurons. Brief puffs of ATP (0.1-1 mM), and the more stable ATP
analog ATPS (100 µM) failed to evoke inward currents in
CA3 neuron somata (Fig. 1A,
i; Table 1),
whereas we could readily measure fast glutamate-evoked currents from these
cells. This was surprising because a recent study reported ATP-evoked currents
with rise times approaching 300 msec in five CA3 neurons
(Mori et al., 2001).
Methodological differences offer a straightforward explanation for the
discrepancies between our data from freshly isolated mouse slices and those
using immature rat organotypic slices maintained in culture for 2-4 weeks. In
accord, larger P2X responses have been noted in sensory neurons after
culturing compared with responses from freshly isolated ganglia
(North, 2002).
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Figure 1. Functional P2X channels are absent from CA3 somata but modulate excitatory
synaptic transmission onto interneurons. A, Simplified diagrammatic
representation of the hippocampus and the feedforward circuit formed between
CA3 (green) and CA1 (blue) pyramidal neurons and interneurons (red).
i-iv, The black traces are current waveforms (-60 mV) for ATP puffs
(IATP), and the color traces are for glutamate puffs
(Iglut) to CA3 pyramidal neurons (i), SR
interneurons (ii), CA1 pyramidal neurons (iii), and SO
interneurons (iv). IATP in stratum oriens
interneurons had slow rise times (100s of milliseconds), whereas the
Iglut was fast (rise time, <20 msec). B, Six
successive images of a brain slice excited with 488 nm light with the output
filtered for emission at 510 nm. The pseudocolor images show the recording
electrode (top left) and interneuron filled with Lucifer yellow and the puffer
pipette filled with the fluorescent ATP analog BODIPY-ATP (bottom left). ATP
was puffed in the third frame. The plume of ATP spreads only 160 µm
and is restricted to the stratum radiatum: the concentration of BODIPY-ATP
beyond 160 µm is negligible. The last three frames show that ATP is
efficiently washed away after the puff. The interval between frames was 5 sec,
and the bath flow (3 ml/min) was downward. The bottom current trace is the
holding current from the interneuron. There was an increase in the inward
EPSCs during the ATP puff. The current recording and the image frames are not
exactly time-matched but agree to within 5 sec, such that the six frames
correspond to the current recording trace lasting 110 sec, shown below.
Scale bar, 160 µm. C, Line profile of the plume of ATP shown in
B. The peak fluorescence change decayed within a distance of 160
µm. D, Bar graph summarizing initial experiments with ATP puffs to
interneurons. E, Top, Recording of an interneuron holding current
(-60mV) before and during ATPS application in the bath and then with
ATPS and CNQX present. The bottom plot shows the frequency of EPSCs
recorded from the same cell plotted versus time. Note that all EPSCs are
blocked when CNQX was applied.
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Table 1. Little evidence for somatic fast ionotropic responses mediated by P2X
channels in mouse hippocampal neurons
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ATP was also ineffective at evoking inward currents in other, but not all,
types of hippocampal neurons (Fig. 1A,
ii-iv; Table
1). In contrast, glutamate evoked responses in all hippocampal
neurons (Fig. 1A,
i-iv; Table
1). High concentrations of ATP (3 mM) evoked large
inward currents in interneurons (Table
1), but these are artifacts because the pH of 3 mM ATP
is 5.5, and adjusting the pH to 7.4 renders 3 mM ATP ineffective
(Table 1). In contrast to the
lack of somatic ATP-evoked currents in CA3 neurons, we could measure
ATP-evoked currents in stratum oriens interneurons
(Fig. 1A, iv;
Table 1) and brainstem
trigeminal mesencephalic nucleus V neurons
(Khakh et al., 1997) when ATP
was similarly applied (-54 ± 10 pA; n = 6), as well as rapidly
desensitizing ACh-evoked currents (-95 ± 9.6 pA; n = 6of9
neurons) in stratum radiatum (SR) interneurons
(Frazier et al., 1998). The
ATP-evoked currents in stratum oriens interneurons displayed 10 -90% rise
times of 508 ± 112 msec (n = 6), whereas glutamate-evoked
currents reached peak responses with rise times of <20 msec
(Table 1). We did not study the
ATP-evoked current in stratum oriens interneurons further in this study. These
data indicate that P2X channels are not expressed at functionally detectable
levels in CA3 neuron somata.
ATP acting on P2X channels increases sEPSC frequency onto
interneurons
The majority of CA1 stratum radiatum interneurons receive their predominant
glutamatergic input from CA3 neuron Schaffer collaterals
(Gulyas et al., 1999). This
population of interneurons likely innervates CA1 pyramidal neurons to regulate
dendritic Ca2+ entry, spiking, or both
(Miles et al., 1996;
Gulyas et al., 1999;
McBain and Fisahn, 2001). Thus
one possible explanation for the lack of functional somatic P2X channels is
that the channels may be located in axons and nerve terminals away from CA3
neuron somata. We recorded glutamatergic sEPSCs from interneurons loaded with
Lucifer yellow to optically mark their position
(Fig. 1B) and then
puffed ATP or ATPS nearby to see whether P2X channels are functional in
nerve terminals and axons of CA3 neurons forming synapses onto interneurons
(Fig. 1B,C).
Concomitant with the ATP puff, we recorded a 740% (n = 5)
increase in spontaneous EPSC frequency from interneurons
(Fig. 1D). A puff of
aCSF produced no detectable changes in the sEPSC frequency (n = 5),
and the ATP responses were blocked 80% (n = 5;
Fig. 1D) by the slowly
dissociating ATP receptor antagonist PPADS (30 µM; recovery to
50% of initial with a 30 min wash; n = 4), which blocks
homomeric P2X2 but not P2X4 or P2X6 channels
(North, 2002). We did not use
the P2 receptor antagonist suramin because it blocks glutamate-gated ion
channel responses (Khakh and Henderson,
1998), whereas PPADS does not (see below). The facilitating
responses were constant for agonist applications every 2-3 min, desensitized
slowly (mean  , 1.8 min), and were not mimicked by
 ,-methylene-ATP (North,
2002). ATPS (100 µM) was as effective as ATP
(1 mM; see below and Fig.
4B). We subsequently used ATPS because this P2X
agonist is more stable than ATP (Khakh et
al., 1997). Of the subunits present
(Collo et al., 1996;
Kanjhan et al., 1999;
Rubio and Soto, 2001), the
data provide strong evidence for P2X2 subunit-containing channels
(North, 2002) close to nerve
terminals emanating from CA3 neurons. Later we present direct evidence for
this.
Facilitation by P2X channels is specific to synapses onto
interneurons
Interneurons and pyramidal neurons were identified on the basis of
anatomical location, neuron shape, presence or lack of a thick apical
dendrite, firing patterns, and decay time of sEPSCs
(Fig. 2A,B).
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Figure 2. Interneuron-specific modulation by P2X channels. A, IR-DIC image
of a stratum radiatum interneuron with a patch electrode approaching from the
left; note the absence of thick dendrites. The right trace is a representative
voltage waveform in response to a 200 pA depolarizing current injection. The
upward deflections are action potentials, the frequencies of which are
maintained throughout the step. The bottom plot shows the distribution of
sEPSC decay times recorded from 13 interneurons, and the inset shows an
average of 20 sESPCs from one interneuron. B, IR-DIC image of a CA1
pyramidal neuron with a patch electrode positioned on the soma; note the thick
dendrites. The right trace is a representative voltage waveform in response to
a 20 pA depolarizing current injection. The upward deflections are action
potentials, the frequency of which decreases dramatically during the step. The
bottom plot shows the distribution of sEPSC decay times recorded from a CA1
pyramidal neuron, and the inset shows an average of 20 sESPCs from one
pyramidal neuron. We could readily discern interneurons from CA1 pyramidal
neurons using infrared (775-900 nm) differential interference contrast optics
on the basis of anatomical location, neuron shape, presence or lack of a thick
apical dendrite, firing patterns, and decay time of sEPSCs. Pyramidal neurons
accommodate on depolarizing current injection, whereas interneurons do not,
and sEPSCs onto interneurons decay approximately twice as fast as those onto
pyramidal neurons (3.4 ± 0.2 msec, 2369 events; n = 13; vs 7.0
± 0.4 msec, 342 events; n = 6), possibly reflecting
neuron-specific expression of distinct glutamate-gated channels
(McBain and Fisahn, 2001).
C, Interneuron data: sEPSC frequency over time before and during
ATPS application (n = 9). D, CA1 pyramidal neuron
data: sEPSC frequency over time before and during ATPS application
(data shown for n = 4 of 17 neurons; the remaining 13 neurons did not
respond; see Results). E, F, Time-resolved plots of mEPSC frequency
for interneurons (E; n = 10) and CA1 pyramidal neurons
(F; n = 16) before and during ATPS application.
ATPS was applied in the bath.
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We recorded from interneurons and pyramidal neurons, both targets of CA3
axons in the CA1 area (Freund and Buzsaki,
1996), to see whether P2X-mediated modulation was equivalent with
bath applications of agonists. For the vast majority of CA1 pyramidal neurons,
we detected no effect of ATPS on sEPSC frequency and amplitude (13 of
17 neurons); however, in 4 of 17 CA1 neurons, there was an increase in the
frequency of sEPSCs by 2160% from 0.2 ± 0.08 Hz and an increase in the
amplitude of sEPSCs by 34.1 ± 13.7% from -10.3 ± 2.8 pA
(Fig. 2D). We did not
study these neurons any further in this study because it is unclear whether
sEPSCs are quantal in nature or result from increased axonal excitability. We
next measured action potential-independent quantal mEPSCs
(MacDermott et al., 1999) in
the presence of TTX. In all cases (16 of 16), for CA1 pyramidal neurons we
observed no increases in mEPSC frequency or amplitude. Thus the frequency of
mEPSCs was 0.4 ± 0.2 Hz in control and 0.8 ± 0.6 Hz in the
presence of ATPS (n = 16; p > 0.05). In contrast,
during recordings from interneurons, sEPSC (n = 9) and mEPSC
(n = 10) frequency increased dramatically
(Fig. 2C,E). The
effect of ATPS on EPSCs was not affected by blocking GABAA
and GABAB receptors with bicucculline (100 µM) and
3-[[3,4-dichlorophenyl)methyl]amino]propyl] diethoxymethyl)phosphinic acid
(CGP52432) (5 µM). Similar to data with ATPS alone (see
below), the sESPC frequency increase was 1051 ± 250% from 1.0 ±
0.3 Hz when ATPS was applied in slices pretreated with bicucculline and
CGP52432 (n = 10). These data suggest that P2X channel expression in
nerve terminals does not occur in synapses onto pyramidal neurons, that the
coupling between P2X activation and release is weak, or that presynaptic P2X
channel expression is so low that it is functionally undetectable at these
synapses. In contrast, activation of P2X channels in excitatory nerve
terminals onto interneurons increases neurotransmitter release.
Concomitant increases in sEPSC frequency and decreases in evoked EPSC
amplitude
We next performed a specific set of experiments to compare the effect of
P2X channel activation on sEPSCs and evoked EPSCs recorded simultaneously from
interneurons. The majority of neurons (9 of 12;
Fig. 3C,D) showed a
robust and reversible increase in sEPSC frequency to 1000% of control
from 0.4 ± 0.1 to 3.4 ± 0.5 Hz in ATPS, returning to 0.31
± 0.09 Hz on wash-out (3 of 12, no response), with no significant
increase in sEPSC amplitude from -13.5 ± 1.2 pA in control to -13.7
± 0.7 pA (p > 0.05) in ATPS. The time course of the
increase in sEPSCs was matched by a concomitant decrease in the amplitude of
evoked glutamatergic EPSCs by 41.4 ± 4.7% (p < 0.05) from
-91.6 ± 8.6 pA. To ensure that we were indeed recording from
interneurons that receive input from the Schaffer collaterals, we washed out
the ATPS and tested the effect of the group III mGluR agonist L-AP-4,
which is expressed abundantly on Schaffer collateral nerve terminals onto
interneurons (Shigemoto et al.,
1996; Scanziani et al.,
1998) (Fig. 3). In
all 12 neurons, L-AP-4 decreased the sESPC frequency to 46.8 ± 6.7%
(p < 0.05) of control (0.8 ± 0.2 Hz), with a concomitant
decrease in the amplitude of evoked EPSCs by 32.3 ± 7.7% (p
< 0.05) from -94.8 ± 12.2 pA. In accord with previous findings, the
L-AP-4 effect on evoked EPSCs and sEPSCs was partially reversible to 86.6
± 7.3 and 71.3 ± 8.7% of control values, respectively
(Scanziani et al., 1998).
There was no significant effect of L-AP-4 on sEPSC amplitude (5.7 ±
5.0% change from -12.3 ± 0.8 pA; p > 0.05). The finding
that ATPS facilitates sEPSC frequency and depresses evoked EPSC
amplitude in the same interneurons in which L-AP-4 depresses synaptic
transmission strongly suggests that ATPS acts on Schaffer collateral
nerve terminals onto interneurons
(Scanziani et al., 1998).
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Figure 3. ATPS modulation of evoked and spontaneous EPSCs at interneuron
synapses. A-D, Data for ATPS application during recordings
from interneurons. A, Evoked EPSCs; B, sEPSC amplitude;
C, sEPSC frequency recorded simultaneously before, during, and after
ATPS application for one representative neuron. D,
Representative sEPSCs. A, Inset, Representative evoked EPSCs. In each
case, the bar graphs to the right show average data from all experiments of
this type. In all these cases, after washing out ATPS(10-20 min),
we applied L-AP-4, and the effect of this agonist is illustrated in
E-H. E, Evoked EPSCs; F, sEPSC amplitude;
G, sEPSC frequency before, during, and after L-AP-4
application for one representative neuron. H, Representative sEPSCs.
E, Inset, Representative evoked EPSCs. In each case, the bar graphs
to the right show average data from all experiments of this type. a, i, b,
i, c, iii, Before, during, and after agonist application,
respectively.
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ATP activates Ca2+-permeable channels to
increase release probability at interneuron synapses
The predominant effect of P2X channel activation at interneurons was a
decrease in evoked EPSCs and an increase in the frequency of sEPSCs (see
above), which may reflect a combination of effects on nerve terminals, axons,
or both. We next measured action potential-independent quantal mEPSCs
(MacDermott et al., 1999) in
the presence of TTX to see whether we could detect P2X channel-mediated
presynaptic responses. At interneuron synapses, in the presence of TTX (0.5
µM; n = 14) to block action potentials or in the
presence of TTX and Cd2+ (100 µM;
n = 13) to block action potentials and Ca2+
channels, ATP and ATPS still evoked robust increases in the frequency
of mEPSCs, reflected as shifts in the interevent distribution to shorter times
with no change in the amplitude distributions
(MacDermott et al., 1999)
(Fig. 4A). However,
the effect was abolished when extracellular Ca2+ was
removed (n = 5; Fig.
4B), arguing against a contribution of metabotropic ATP
receptors and instead suggesting that ATP likely gates
Ca2+-permeable P2X channels in nerve terminals to
increase the probability of vesicle fusion
(MacDermott et al., 1999).
Antidromic action currents onto CA3 neurons fail when P2X channels
open
One possible explanation for why evoked EPSCs decrease in amplitude at the
same time as sEPSCs increase in frequency is that open axonal P2X channels may
depress action potential initiation, conduction in axons, or both, whereas the
concomitant opening of presynaptic channels increases quantal release.
Analysis of mEPSCs strongly suggests that quantal release is increased
(Fig. 4). In the case of axonal
channels, one expects open channels to increase membrane conductance and shunt
action potentials both anterogradely toward the synapse and also retrogradely
to the soma from which the axon originates or to depolarize axons such that
sodium channels are inactivated. We performed experiments to test for this
directly using an approach similar to that used recently by Semyanov and
Kullmann (2001). We completely
blocked synaptic transmission onto CA3 neurons using a mixture of blockers
(CNQX, bicucculline, and D-2-amino-5-phosphonovaleric acid, all at 100
µM) and recorded from voltage-clamped CA3 neurons. Antidromic
action currents were evoked with a monopolar glass-stimulating electrode
placed in the Schaffer collaterals
(Semyanov and Kullmann, 2001),
and recorded in CA3 neuron somata at stimulus strengths resulting in 60%
success rates. On application of ATPS, we observed a significant
decrease in the action current success rate for all neurons tested in this way
from a mean success rate of 65.3 ± 8.7 to 2.5 ± 2.9%
(Fig. 5A-C; n
= 9; p < 0.05). In accord with the reversible suppression of
evoked EPSCs (Fig.
3A), the effect of ATPS on action current success
rate was also reversible to a rate of 57.1 ± 7.1% (p > 0.05
compared with control). Representative traces and data from the whole sample
are presented in Figure
4A-C. Seemingly, the predominant effect of P2X channel
activation in axons is to depress antidromic action currents, and this
supports our hypothesis that P2X channels are expressed in the axons emanating
from CA3 pyramidal neurons.
The P2X2 subunit is required for ATP-evoked interneuron synapse
facilitation
P2X2 channels were the most likely molecular targets for ATP, but we sought
definitive proof by using P2X2 deletion mice in which the last 10 of the 11
P2X2 exons have been replaced with a neomycin resistance cassette
(Fig. 6A; see
Materials and Methods). RT-PCR confirmed the absence of P2X2 mRNA from whole
brain and testis from P2X2-/- mice, whereas
the expected band was obtained from P2X2+/+
mice (Fig. 6A) and for
-actin in both genotypes (Fig.
6A). The overall anatomy of the hippocampus and spiking
properties of interneurons were normal in
P2X2-/- mice (n = 47 and 49 neurons
from seven mice of each genotype; Fig.
6B,C), and there were no differences in either resting
membrane potential (-58.9 ± 0.8 and -59.6 ± 0.9 mV; p
> 0.05) or membrane resistance (657 ± 70 and 512 ± 45
M; p > 0.05) for P2X2+/+
and P2X2-/- mice (n = 47 and 49;
Fig. 6G,H). However,
there was a stark difference between P2X2-/-
and P2X2+/+ mice with respect to ATPS
modulation of glutamatergic synaptic transmission onto interneurons
(Fig. 6D,E,G). We
recorded ATPS modulation in 47% of neurons from
P2X2+/+ mice (42 of 90), but in
P2X2-/- mice, this was significantly reduced
to 16% (13 of 80, seven mice for each genotype;
Fig. 6, D,E, results
from individual mice, G-I, results from all mice). Thus, the
predominant target in neurons that responded to ATPS with an increase
in the frequency of mEPSCs is either a homomeric or heteromeric assembly
comprising P2X2 subunits. We next compared the absolute changes in EPSC
frequency for neurons that responded to ATPS between
P2X2-/- and
P2X2+/+ mice because if P2X2 and putative
P2X4/P2X6 channels are expressed in the same nerve terminals, then one may
expect the response magnitude to be reduced in
P2X2-/- mice. The absolute magnitude of the
frequency change was the same (Fig.
6F), and this suggests that specificity may exist within
members of the P2X family with respect to expression in nerve terminals or
that ATP-gated channels are upregulated in the
P2X2-/- mouse line. The clearest finding from
these experiments is that the majority of excitatory nerve terminals that
express functional P2X channels do so via a complex containing P2X2
subunits.
P2X2 subunits are also sufficient for ATP-evoked synaptic
facilitation
Because P2X2 subunit-containing channels are the predominant targets for
ATP in synapses onto SR interneurons, the next set of experiments tested for
the ability to measure ATPS-mediated increases in mEPSCs from pyramidal
cells by adding extra P2X2 channels. Recent work with GABA transporter type
1-green fluorescent protein (GFP)-labeled interneurons shows that the majority
(80 -90%) of hippocampal neurons in culture are pyramidal
(Chiu et al., 2002). In accord
with our previous work (Khakh et al.,
2001), we found no evidence for modulation of mEPSC frequency
(n = 4; Fig.
7B) in wild-type hippocampal neurons in culture, from 0.2
± 0.1 in control to 0.1 ± 0.1 Hz during ATPS. We next
expressed P2X2-GFP fusion proteins in hippocampal neurons with
Sindbis viruses (Fig.
7A), which results in approximately threefold to sixfold
channel overexpression (Khakh et al.,
2001). One day after infection, we recorded from nonfluorescing
neurons and puffed ATPS onto the surrounding fluorescent neurites
(Fig. 7A). In all such
cases, ATPS puffs reliably increased the frequency but not the
amplitude of mEPSCs from 0.6 ± 0.3 to 12.2 ± 2.6 Hz (n
= 5; Fig. 7C,D).
Whereas the P2X2 null mice tell us that P2X2 channels are required at SR
interneuron synapses, the present experiments provide complimentary support
that overexpressed P2X2 channels are also sufficient to endow synapses onto
CA1 neurons with nerve terminal P2X-mediated modulation.
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Figure 7. P2X2 channel overexpression endows cultured hippocampal neurons with
ATP-mediated facilitation of mEPSCs. A, Top, Sindbis virus construct
used to express P2X2-GFP under the control of a subgenomic promoter. Bottom,
Photomicrograph showing a field of view of cultured hippocampal neurons, with
the fluorescent GFP-expressing neurons shown in white. Note the mosaic
infection produced by Sindbis results in some uninfected neurons surrounded by
brightly fluorescing P2X2-GFP-expressing neurites. B, Current trace
from wild-type (wt) uninfected neuron in the presence of TTX; note that
ATPS causes no change in the frequency or amplitude of mEPSCs.
C, Current trace from a noninfected neuron surrounded by the neurites
of P2X2-GFP expressing neurons in the presence of TTX. D, shows
Average graph from six neurons from experiments like those illustrated in
C and four neurons from experiments like those shown in
B.
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ATPS does not trigger network activity
Cholinergic (CCh) induction of theta and gamma oscillations in the
hippocampus is a useful in vitro model for network activity in
vivo that may arise from medial septum cholinergic input
(Fisahn et al., 1998;
Fellous and Sejnowski, 2000;
Fisahn et al., 2002). We used
CCh (50 -100 µM) and also muscarine (10 µM) to
induce oscillations, but in keeping with previous nomenclature, we refer to
this as CCh-evoked activity. Under recording conditions similar to ours, CCh
evokes hippocampal theta oscillations with occasional ripples of gamma
(Fellous and Sejnowski, 2000;
Tiesinga et al., 2001).
Computational and experimental studies of CCh induced theta and gamma suggest
that excitatory transmission onto interneurons is important
(Fisahn et al., 1998;
Fellous and Sejnowski, 2000;
Traub et al., 2000;
Tiesinga et al., 2001). Does
P2X channel activation evoke network activity within the CA3 region of the
hippocampus? We found no evidence to indicate that ATPS (100
µM) evokes any change in the extracellular field potential
(n = 6). However, in the same slices, CCh evoked a robust increase in
extracellularly recorded field activity, which was completely blocked by TTX
(n = 6). Figure
8B shows power spectra for the representative traces in
Figure 8A, and
Figure 8C summarizes
findings for the whole data set. In agreement with the work of Fellous and
Sejnowski (2000), we recorded a
CCh-evoked oscillation with a fundamental frequency (Ff) of 12.4 ± 0.4
Hz (n = 6) (Tiesinga et al.,
2001). These experiments suggest that increasing the frequency of
sEPSCs by 700% in 60% of stratum radiatum interneurons (Figs.
1,
2,
3) is insufficient to trigger a
detectable network activity as measured in CA3.
P2X channels enhance interneuron synaptic transmission during network
activity
How are presynaptic P2X channels onto interneuron synapses activated
physiologically? ATP released during spiking
(Wieraszko et al., 1989;
Mori et al., 2001;
Pankratov et al., 2002) may
activate presynaptic P2X channels at interneuron synapses. To test for this,
we induced neuronal firing at physiological frequencies by inducing
oscillations with CCh (Fig. 8).
sEPSCs onto interneurons increased in frequency during oscillations by
1500% (Fig.
9A-C), and, reminiscent of the ability of TTX to block
oscillations (Fig.
8C), the increase in sEPSC frequency measured from
interneurons was only 225 ± 55% (n = 8) of control in the
presence of TTX. The major component of the increase in sEPSCs is likely
because of CCh-evoked oscillations. We asked whether endogenous ATP release
contributed to this enhanced synaptic transmission by activating presynaptic
facilitatory P2X channels that are functional at these synapses
(Fig. 4). Because PPADS has a
slow on rate (10 min), the simplest way to test for this was to compare
the effect of CCh on sEPSCs from control slices and those pretreated with 30
µM PPADS to block P2X channels. In control slices, application
of CCh resulted in an 1820 ± 480% (n = 23) increase in sEPSC
frequency onto interneurons (Fig.
9A,C), but in PPADS-treated slices, this was
significantly reduced to 422 ± 73%
(Fig. 9B,C; n
= 21; p < 0.05 compared with control slices), implying that the
PPADS-sensitive P2X component constitutes 77% of the total response.
There were no significant differences in the amplitude of CCh-evoked sEPSCs
when comparing across the whole data set for control slices and those
pretreated with PPADS (139 ± 12%; n = 23; 129 ± 8% of
control; n = 21; Fig.
9C). In a specific set of experiments, we also examined
the effect of blocking P2X channels in real time on CCh-evoked sEPSC
facilitation in interneurons in which this was constant for a baseline period
of at least 5-10 min (5 of 19 neurons). Representative traces are shown in
Figure 9D, and the
effect of PPADS is manifest as a decrease in the area of sEPSCs during CCh.
CCh increased sEPSC frequency by 1461 ± 174%, but in the same neurons
in the presence of PPADS, this was reduced to 310 ± 137% of control
(Fig. 9D, bar graphs;
n = 4). From these experiments, we suggest that the predominant
effect of PPADS is to reduce the CCh oscillation-evoked increase in sEPSC
frequency onto interneurons. We interpret this to indicate that CCh
oscillations release ATP, which acts presynaptically to facilitate transmitter
release. Consistent with this, we measured increases in ATP-dependent
bioluminescence from the firefly luciferase reaction in response to CCh
application to brain slices, demonstrating that ATP is released into the
extracellular space during neuronal oscillations at approximate theta
frequencies (Table 2).
CCh-evoked ATP release was significantly reduced when action potentials were
blocked by TTX (Table 2).
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Figure 9. ATP contributes to the facilitation of interneuron synapses that occurs
during oscillations. A, Top plot, Representative current trace from
an interneuron before and during the induction of CCh oscillations. Bottom
plot, EPSC area (10 sec bins) over time for this neuron. B, Top plot,
Representative current trace from an interneuron before and during the
induction of CCh oscillations in the continued presence of PPADS (30
µM). Bottom plot, EPSC area (10 sec bins) over time for this
neuron. C, Summary bar graphs for experiments like those illustrated
in A and B. D, Top plot, Current trace from an
interneuron before and during the induction of oscillations by CCh. Middle
plot, Effect of PPADS by plotting the EPSC area (10 sec bins) over time. The
bottom graphs summarize the findings from all such interneurons. E,
Top plot, Current trace from a CA1 pyramidal before and during the induction
of oscillations by CCh. As illustrated in the middle plot, there was little
change in EPSC areas during application of PPADS. The effect of CCh was less
pronounced in pyramidal neurons as compared to interneurons. The bottom graphs
summarize findings from all such experiments. In A, B, D, and
E, we plotted area versus time because during CCh applications, we
recorded increases in sEPSC frequency and a greater number of larger-amplitude
sEPSCs (see original traces in A, B, C, E). The large-amplitude
sEPSCs in the presence of CCh probably arise because CA3 neurons fire action
potentials during oscillations and cause release of transmitter synchronously
from multiple release sites onto interneurons. PPADS clearly reduced the
frequency of CCh-evoked sEPSCs (D, left graph), but although there
was a trend for the sEPSCs to decrease in amplitude in the presence of PPADS,
this did not reach significance (D, right graph).
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Consistent with the lack of presynaptic P2X channels at pyramidal neuron
synapses (Fig. 2), PPADS had no
effect on the sEPSC frequency onto CA1 pyramidal neurons during CCh
applications to evoke oscillations (Fig.
9E). Thus, CCh enhanced the sEPSC frequency onto
pyramidal neurons to 1053 ± 328% of control, and this did not change
with PPADS (1153 ± 332%; four of four neurons;
Fig. 9E). We also
performed several control experiments to strengthen our findings with PPADS as
an antagonist. PPADS was specific in that it did not block somatic glutamate
responses (n = 4), glutamatergic evoked EPSCs (n = 5), or
mEPSCs (n = 5); they were -293 ± 93, -142 ± 36, and
-15.8 ± 1.8 pA in control and -326 ± 103, -155 ± 45, and
-16.0 ± 1.8 pA in the presence of 30 µM PPADS,
respectively (p > 0.05 for each comparison).
A role for ATP in oscillations
Because facilitatory presynaptic P2X channels are found at interneuron
synapses and are likely activated during CCh-evoked oscillations, we sought to
determine whether endogenous ATP contributes to either the frequency or power
of CCh-induced oscillatory activity. First we ensured that PPADS did not block
either muscarinic receptors or the excitability of CA3 neurons. In agreement
with published work (Fisahn et al.,
2002), CCh depolarized CA3 pyramidal neurons by +8.9 ± 1.7
mV and increased spike frequency from 0.1 ± 0.1 to 5.8 ± 1.2 Hz
(n = 3). In the presence of PPADS, this was not markedly altered: the
CCh-evoked depolarization was +7.2 ± 1.5 mV, and action potential
firing increased from 0.1 ± 0.1 to 7.4 ± 2.0 Hz (n =
7). Moreover, the input-output curves for CA3 pyramidal neurons in the absence
and presence of PPADS were superimposable (n = 5).
We next tested the effect of blocking P2X channels with PPADS on CCh
oscillations. We determined the increase in power at the Ff (relative to the
basal situation before CCh) and compared it with the power at the Ff
attributable to CCh in slices pretreated with PPADS (30 µM for
at least 20 min). Thus, in control slices (no PPADS), CCh evoked oscillations
with an Ff of 13.8 ± 0.7 Hz (n = 10). In slices treated with
PPADS, CCh induced oscillations with an identical Ff at 13.4 ± 0.7 Hz
(n = 16), but the power was reduced significantly by 80% at the
Ff (p < 0.05; Fig.
10) in comparison with slices with no PPADS. These data suggest
that ATP released during oscillations contributes to the overall power of
cortical oscillations. A component of this may be ATP acting on P2X channels
in nerve terminals or axons, as we have shown for exogenous and endogenous ATP
at interneuron synapses.
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Figure 10. PPADS reduces the power of CCh oscillations. A, Representative
field potential traces and power spectra for CCh oscillations in a slice
pretreated with PPADS. Inset, Autocorrelograms (with positive lags shown).
B, Summary of experiments such as those illustrated in A
comparing the CCh-induced oscillation frequency and power for control slices
and those treated with PPADS. The recording electrode was positioned in CA3.
C, Summary of all experiments like those illustrated in A
and B.
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Discussion
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ATP-gated cationic P2X channels are numerous and widely expressed in the
brain; therefore, it is important to understand their physiological and
synaptic functions. Our data extend recent studies indicating that P2X
channels are found presynaptically
(MacDermott et al., 1999) by
additionally making five further advances. First, we provide evidence for the
presence and function of a molecularly defined P2X channel in a brain synapse.
Second, we demonstrate that P2X2 subunit-containing channels are functional
close to nerve terminals and in axons but surprisingly not in somata of CA3
neurons. Third, we provide evidence to suggest that the identity of the
postsynaptic target determines modulation by presynaptic P2X2-containing
channels within the CA1 region of the hippocampus. Fourth, we show that
endogenous ATP activates presynaptic P2X channels during network activity.
Fifth, we provide evidence in favor of a novel form of ATP-dependent
presynaptic facilitation for interneurons during oscillations.
ATP signaling
The finding that P2X channels are not functionally expressed in CA3 neuron
somata was a surprise because P2X2, P2X4, and P2X6 immunostaining is present
in these neurons (Kanjhan et al.,
1999; Rubio and Soto,
2001). Recent studies show ATP-evoked currents in these neurons
(Mori et al., 2001). The
clearest difference between these studies and ours is that we used freshly
isolated mouse slices, whereas the ATP-evoked somatic currents are from rat
cultured slices (Mori et al.,
2001). It seems feasible that once isolated, neurons may either
retract their processes and therefore display aberrant somatic ATP-evoked
currents or otherwise upregulate somatic P2X expression, as has been suggested
for sensory neurons (North,
2002). We interpret our findings to indicate that P2X channels are
not functionally expressed in intact CA3 neuron somata but are predominantly
functional in the axons, and a specific set of nerve terminals, that emanate
from these neurons.
Decisive evidence for the role of distinct P2X channels in brain synapses
has been lacking because the discriminating differences between P2X channels
are fewer than the possible number of P2X channel assemblages
(North, 2002). We have
circumvented these limitations to some extent by using electrophysiology and
P2X2 subunit null mice. Our data show that >80% of the ATP-evoked
presynaptic response was blocked by PPADS (30 µM), which blocks
P2X2 but not P2X4 channels (North,
2002). In comparison, there is a residual response in P2X2 null
mice that amounts to 40% of the total population that respond to
ATPS in wild-type mice. The absolute magnitude of the response in these
40% of cells is similar to the component mediated by the total receptor
population in the wild-type mice, suggesting that the 40% residual component
may represent upregulation of an unknown P2X channel, or that expression of
P2X2 and the unknown channel type does not overlap in nerve terminals.
Overall, these findings imply that a presently unidentified channel, resistant
to PPADS, mediates at most 20% of the response. This component may be
upregulated in 40% of the neurons that have near normal peak responses in
the P2X2-/- mice and could conceivably
represent another P2X channel, including P2X7
(Deuchars et al., 2001;
Sperlagh et al., 2002).
Nonetheless, the predominant target for ATP at excitatory synapses onto
interneurons is a homomeric or heteromeric channel comprising P2X2. Moreover,
the facilitatory effect of ATPS on interneuron EPSCs was completely
blocked by removal of extracellular Ca2+ but persisted
in the presence of TTX and Cd2+, indicating that
ATPS likely gates a Ca2+-permeable ion channel in
nerve terminals (MacDermott et al.,
1999). P2X2 channels are known to have significant
Ca2+permeability on the basis of reversal potentials
(North, 2002).
The evidence that P2X channels are functional in Schaffer collateral axons
(Kanjhan et al., 1999) as well
as in nerve terminals is fourfold. First, we measured increases in action
potential-dependent sEPSC frequency while recording from the postsynaptic
targets of CA3 axons. Second, we measured increases in mEPSC frequency with
ATPS application. Third, we placed a stimulating electrode in the
Schaffer collaterals and measured evoked ESPCs from interneurons. During
ATPS application, evoked EPSCs decreased in peak amplitude, with a time
course matching the increase in frequency of sEPSCs recorded simultaneously
(Fig. 3). Fourth, we measured a
manifest increase in the failure of antidromic action currents recorded from
CA3 pyramidal neurons and evoked by stimulation in the Schaffer collaterals
during ATPS applications. Certain aspects of our findings are
reminiscent of the neuromuscular junction, nucleus tractus solitarius, and
dorsal horn (Fu and Poo, 1991;
Kato and Shigetomi, 2001;
Nakatsuka and Gu, 2001) but
constitute the first such findings for ATP effects on interneuron synaptic
transmission.
Facilitation by ATP during network activity
Within the CA1 region, stratum radiatum interneurons receive their
predominant excitatory input from Schaffer collaterals. By virtue of their
precise projection patterns, interneurons set a time window for when output
CA1 neurons cannot spike and additionally regulate dendritic
Ca2+ entry (McBain
and Fisahn, 2001). The present data indicate that exogenous
ATPS cannot trigger network oscillations, but that endogenous ATP is a
presynaptic modulator of neurotransmission at stratum radiatum interneuron
synapses during firing at approximately theta frequencies. The high
specificity of luciferase for ATP provides evidence for ATP release from brain
slices during CCh applications. Previous studies have demonstrated ATP release
into the extracellular buffer as a result of Schaffer collateral stimulation
(Wieraszko et al., 1989).
Thus, the most obvious sources of ATP are the CA3 neuron terminals themselves,
but alternative sources such as astrocytes
(Newman, 2001) cannot be
dismissed at present. Our experiments show that the facilitation of excitatory
synaptic transmission onto interneurons that occurs during oscillations is
partly mediated by endogenously released ATP activating P2X channels. Our
analysis of CCh-evoked oscillations in hippocampal slices favors the idea that
endogenous ATP may contribute to overall oscillation power, but further work
is needed before a complete understanding can emerge, for instance, to
understand the role of ATP at GABAergic synapses and at gap junctions
(McBain and Fisahn, 2001).
An unexpected finding from our work is that presynaptic P2X2-mediated
modulation appears specific for interneurons and is undetectable at synapses
onto CA1 pyramidal neurons. Elegant studies have described target synapse
specificity with respect to synaptic parameters such as short-term depression,
potentiation, and plasticity (for review, see
Toth and McBain, 2000;
Atwood and Karunanithi, 2002),
but with the exception of the metabotropic glutamate receptors
(Shigemoto et al., 1996), the
presynaptic proteins responsible have not been identified. Interestingly,
previous immunogold studies failed to find P2X2 channels in nerve terminals on
CA1 pyramidal neurons (Rubio and Soto,
2001), whereas there was expression in the Schaffer collateral
bundle at the light microscope level
(Kanjhan et al., 1999;
Rubio and Soto, 2001). Our
data offer a new interpretation of these apparently conflicting studies and
sharpen our view of P2X2-mediated signaling in the hippocampus: P2X2 channels
are in Schaffer collaterals, but expression in nerve terminals may be
determined by the identity of the postsynaptic target. Functional exclusion of
P2X2 channels from nerve terminals onto pyramidal neurons may be a saturable
process because approximately threefold to sixfold P2X2 channel overexpression
overcomes it. A restrictive barrier, perhaps associated with the cytoskeleton,
regulates movement of membrane proteins into hippocampal neuron axons
(Winckler et al., 1999). A
similar or more selective barrier at axonal branches, or at individual nerve
terminals, would be a simple way to ensure target synapse specificity of P2X2
channels, and some P2X channels may indeed interact with the cytoskeleton
(Parker, 1998;
Kim et al., 2001). As far as
we know, the present study, demonstrating preferential expression of
functional P2X channels not in CA3 pyramidal neuron somata but in their axons
and a specific set of nerve terminals that emanate from these, is the first
such example for a brain neuron. A recent study on AMPA channels in sensory
neurons (Lee et al., 2002) and
the present study prepare us for the possibility that preferential expression
near nerve terminals may be a physiologically important attribute of
neurotransmitter-gated ion channels.
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Top
Abstract
Introduction
