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The Journal of Neuroscience, October 15, 2001, 21(20):8015-8025
Induction of Mossy Fiber CA3 Long-Term Potentiation Requires
Translocation of Synaptically Released Zn2+
Yang
Li1,
Christopher
J.
Hough2,
Christopher J.
Frederickson3, 4, and
John M.
Sarvey1
Departments of 1 Pharmacology and
2 Psychiatry, Uniformed Services University of the Health
Sciences, Bethesda, Maryland 20814, and 3 NeuroBioTex, Inc.
and 4 Departments of Biomedical Engineering and Anatomy and
Neuroscience, The University of Texas Medical Branch, Galveston, Texas
77550
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ABSTRACT |
The mammalian CNS contains an abundance of chelatable
Zn2+ sequestered in the vesicles of glutamatergic
terminals. These vesicles are particularly numerous in hippocampal
mossy fiber synapses of the hilar and CA3 regions. Our recent
observation of frequency-dependent Zn2+ release from
mossy fiber synaptic terminals and subsequent entry into postsynaptic
neurons has prompted us to investigate the role of synaptically
released Zn2+ in the induction of long-term
potentiation (LTP) in field CA3 of the hippocampus. The rapid removal
of synaptically released Zn2+ with the
membrane-impermeable Zn2+ chelator CaEDTA (10 mM) blocked induction of NMDA receptor-independent mossy
fiber LTP by high-frequency electrical stimulation (HFS) in rat
hippocampal slices. Mimicking Zn2+ release by bath
application of Zn2+ (50-100 µM)
without HFS induced a long-lasting potentiation of synaptic
transmission that lasted more than 3 hr. Moreover, our experiments
indicate the effects of Zn2+ were not attributable
to its interaction with extracellular membrane proteins but required
its entry into presynaptic or postsynaptic neurons. Co-released
glutamate is also essential for induction of LTP under physiological
conditions, in part because it allows Zn2+ entry
into postsynaptic neurons. These results indicate that synaptically
released Zn2+, acting as a second messenger, is
necessary for the induction of LTP at mossy fiber CA3 synapses of hippocampus.
Key words:
zinc; long-term potentiation; CA3; hippocampus; CaEDTA; mossy fiber; plasticity; Na-pyrithione; Newport Green; synaptic
transmission
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INTRODUCTION |
The mammalian CNS contains an
abundance of chelatable Zn2+ sequestered
in the vesicles of glutamatergic terminals. These vesicles are
particularly numerous in hippocampal mossy fiber synapses of the hilar
and CA3 regions (Haug, 1967 ; Perez-Clausell and Danscher, 1985;
Frederickson, 1989; Frederickson et al., 2000; Li et al., 2001). A
possible synaptic signaling role for Zn2+
is suggested by its interactions with excitatory and inhibitory amino
acid receptors such as NMDA, AMPA, and GABA receptors (Peters et al.,
1987; Westbrook and Mayer, 1987). Zn2+
accumulates in synaptic vesicles through a specific
Zn2+ transporter, termed Zn transporter 3 (Palmiter et al., 1996). Vesicular Zn2+
release can be elicited by electrical stimulation (Howell et al., 1984;
Li et al., 2001) or membrane depolarization (by elevating extracellular
K+ concentration; Assaf and Chung, 1984;
Aniksztejn et al., 1987; Li et al., 2001). Characterization of this
Zn2+ release has revealed that it is
released in the same manner as neurotransmitters: the release is
Ca2+-dependent and tetrodotoxin-sensitive
(Li et al., 2001). Recently, it has been shown that extracellular
Zn2+ enters neurons through glutamate
receptors and voltage-dependent Ca2+
channels (VDCCs; Weiss and Sensi, 2000). Despite a considerable amount
of evidence suggesting that Zn2+ acts in
concert with neurotransmitters in the CNS, a specific physiological
role for synaptically released Zn2+ has
yet to be identified.
In addition to having routes of entry into neurons that are activated
during nerve transmission, Zn2+ is known
to interact with the protein kinases and phosphatases of signal
transduction pathways that affect changes in gene expression (Brewer et
al., 1979; Hubbard et al., 1991; Weinberger and Rostas, 1991; Quest et
al., 1992; Maret et al., 1999; Park and Koh, 1999; Lengyel et al.,
2000). Our recent observation (Li et al., 2001) of frequency-dependent
Zn2+ release from mossy fiber synaptic
terminals and subsequent entry into postsynaptic neurons of the dentate
gyrus has suggested to us that Zn2+ might
play a role in the normal physiological function of these neurons.
Detectable Zn2+ release varied over a
range of frequencies (10-200 Hz), which included frequencies used to
induce long-term potentiation (LTP). We hypothesized that translocation
of Zn2+ across synapses might be an
important physiological signal mediating some aspects of synaptic
plasticity, such as LTP.
LTP is an important model for studying the cellular mechanisms of
neuronal plasticity, learning, and memory.
Zn2+-deficient rats and rhesus monkeys
experience a learning and working memory deficit (Golub et al., 1995).
Although the possibility that Zn2+
released from the mossy fiber bouton might be involved in hippocampal LTP has been proposed by Weiss et al (1989) more than a decade ago,
much is still unknown about the involvement of synaptically released
Zn2+ in synaptic plasticity. Recently, two
groups failed to alter the induction of mossy fiber LTP by removing
synaptically released Zn2+ with the
Zn2+ chelator CaEDTA (Lu et al., 2000;
Vogt et al., 2000). Using fluorescence imaging, we show here that
although a low concentration (1 mM) of CaEDTA was not
sufficient to prevent synaptically released Zn2+ from reaching postsynaptic neurons
after high-frequency stimulation (HFS), a higher concentration (10 mM) of Zn2+ chelator was. This
treatment blocked the induction of LTP. Moreover, perfusion of slices
with exogenous Zn2+ (50-100
µM) could also induce long-lasting potentiation of the EPSP in the absence of HFS. Finally, our experiments indicate that the
effects of Zn2+ were not attributable to
its interaction with extracellular membrane proteins but required its
entry into presynaptic or postsynaptic neurons.
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MATERIALS AND METHODS |
Hippocampal slice preparation. Experiments were
conducted according to the principles set forth in the Guide for
Care and Use of Laboratory Animals (Institute of Animal Resources,
National Research Council, National Institutes of Health publication
74-23). Male adult Sprague Dawley rats were anesthetized with ketamine hydrochloride and decapitated. The brain was quickly removed and immersed in ice-cold (1-4°C) artificial CSF (ACSF) with the
composition of (in mM): NaCl, 124; KCl, 1.75;
MgSO4, 1.3; CaCl2, 2.4;
KH2PO4, 1.25;
NaHCO3, 26; and dextrose, 10, continuously
bubbled with 95% O2 and 5%
CO2. Transverse hippocampal slices 400 µm in
thickness were prepared using a McIlwain tissue chopper (Brinkmann
Instruments, Westbury, NY) or Vibratome (Frederic Haer, Brunswick, ME).
Slices were incubated in a 95% O2-5%
CO2-saturated interface recording chamber for at
least 1 hr before recording at 32°C.
Electrical stimulation and recordings. The mossy fiberCA3
pyramidal neuron responses were induced by the stimulation of mossy fiber axons with a 100-µm-diameter monopolar Teflon-insulated stainless steel wire electrode, exposed only at the tip (Fig. 1A). Extracellular recordings were obtained using
glass micropipettes filled with 2 M NaCl, 2-6
M resistance. The recording electrodes were placed at least 500 µm
from the stimulating electrodes along the trajectory of the mossy fiber
pathway. The recording electrodes were lowered to a distance of 80-100
µm beneath the slice surface. Paired pulse facilitation of the EPSP
was conducted at 20 and 80 msec interpulse intervals. Slices were
accepted for further study when the mossy fiber pathway showed
facilitation at the 80 msec interval. Because of the complex
circuitry of area CA3, the metabotropic Glu receptor (mGluR) II agonist
2-(2,3-dicarboxy-cyclopropyl)glycine (DCG-IV) was used at the end of
the experiments to verify that the signal was generated by mossy
fiber inputs (Kamiya et al., 1996). D-APV (50 µM) was added in ACSF to prevent contamination with the NMDA receptor-dependent pathway converging on CA3 neurons. For
inducing mossy fiberCA3 LTP, test stimuli were delivered to mossy
fiber axons every 30 sec (0.03 Hz). The stimulus intensity was set to
produce ~30% of the maximum EPSP. HFS consisted of one train of 100 Hz lasting 2 sec at the intensity that induced the maximum EPSP. The
maximal negative initial slope of the mossy fiberCA3 EPSP was
calculated and normalized to 30 min baseline value (defined as
100%).
Zn2+ imaging. Methods for imaging
Zn2+ fluorescence have been published (Li
et al., 2001). For extracellular Zn2+
fluorescence imaging, hippocampal slices were preloaded with 20 µM Newport Green (Molecular Probes, Eugene, OR)
dipotassium salt at room temperature in the dark for at least 30 min.
For intracellular Zn2+ imaging, the slices
were preloaded with 50 µM diacetate ester of Newport
Green in 0.5% dimethylsulfoxide containing 0.1% pluronic acid for
1 hr and then washed with ACSF. The
Zn2+-selective fluorescent dye Newport
Green has a Kd of 1 µM for Zn2+.
Newport Green fluorescence was minimally affected by the presence of
Ca2+ and Mg2+
at physiological concentrations (Li et al., 2001).
Ca2+ or Mg2+
(up to 10 mM), in the absence of
Zn2+, had little effect on the dye
fluorescence emission. All experiments were performed at 32°C under
constant ACSF perfusion on the thermostatically heated stage of an
inverted microscope (Axiovert 140; Zeiss, Oberkochen, Germany) coupled
to a Delta Ram xenon light source (PTI, Manmouth Junction, NJ) and
monochromator set to 506 nM. Emitted light images at 533 nm or greater were acquired at rates of 2-30 Hz through a 10×
0.1 numerical aperture objective with an intensified CCD camera (PTI
IC-100) and digitized using ImageMaster software (PTI). Autofluorescence was below the detection limits of the camera, and
photobleaching was negligible under these conditions; neither was
subtracted from the data. Images in Figures 7 and 8 were captured by an
Orca digital camera (Hamamatsu, Hamamatsu City, Japan) using Open Lab
Software (Improvision). To induce the release of
Zn2+ from mossy fiber terminals, bipolar
electrodes 300-500 µm apart were used for electrical stimulation to
excite mossy fiber axons. Trains of orthodromic stimuli (100 Hz, 200 µsec pulses at 500 µA unless otherwise noted) of various
frequencies were delivered using an S44 stimulator and a PS1U6
photoelectric stimulus isolation unit (Grass Electronics, Quincy, MA).
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RESULTS |
Rapid chelation of synaptically released Zn2+
blocks induction of mossy fiber LTP
To determine whether Zn2+ is involved
in this specific form of synaptic plasticity, we examined the effects
of applying CaEDTA, a cell-impermeable extracellular
Zn2+ chelator
(Kd = 10 16.4 M) that does not appreciably
alter Ca2+ concentration (Fredens and
Danscher, 1973; Dawson et al., 1986; Bers et al., 1994). Stimulation of
the mossy fiber axons produced an extracellular field EPSP recorded in
the dendritic region (stratum lucidum) of pyramidal neurons in field
CA3 of hippocampal slices (Fig.
1A). In control slices,
brief HFS produced EPSP potentiation (mossy fiber LTP; Fig.
1B). The averaged normalized EPSP slope 30 min after
HFS was 193 ± 10% (mean ± SEM; n = 9) of
baseline, and the potentiation was stable for >3 hr (maximum recording
duration) after our standard recording procedure (Bramham and Sarvey,
1996). To chelate Zn2+ released by HFS and
to prevent it from reaching postsynaptic neurons, we perfused slices
with 10 mM CaEDTA for 10 min before and 10 min
after HFS. This treatment blocked induction of LTP (103 ± 4%,
mean ± SEM; n = 11; Fig. 1C). Although
there was an initial small post-tetanic potentiation immediately after
HFS, it decayed to baseline within 5-10 min. These results suggest that Zn2+ released during HFS plays an
essential role in the induction of mossy fiber LTP. To determine
whether chelation of Zn2+ could alter the
maintenance of LTP, CaEDTA was applied 10 min after HFS. Figure
1D shows that CaEDTA (10 mM)
had no effect on established LTP, suggesting that the removal of
Zn2+ after HFS did not influence the late,
or maintenance, phase of LTP.
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Figure 1.
Rapid chelation of extracellular
Zn2+ blocks induction of mossy fiber LTP.
A, Schematic of a hippocampal slice showing stimulating
and recording sites. The traces on the
right show the field EPSPs evoked by stimulation of
mossy fibers (mf) and the
commissural-associational pathway. The group II mGluR agonist DCG-IV
(5 µM) selectively blocked mossy fiber responses to
17.3 ± 2% (n = 6) of those before drug
application but had little effect on the responses (to 97.7 ± 1.9%; n = 6) evoked by stimulating the
commissural-associational fibers in the stratum radiatum (electrode not shown). B, Mossy
fiber LTP (193 ± 10%; n = 9) induced by HFS
after recording a 30 min baseline (see Materials and Methods).
C, HFS failed to induce mossy fiber LTP (103 ± 4%; n = 11) in the presence of 10 mM
CaEDTA (dashed line). D, Adding CaEDTA
(10 mM; dashed line) 10 min after induction
of LTP did not affect the late, or maintenance, phase of LTP (175 ± 8%; n = 3). Each point in
B-D represents the averaged and normalized EPSP initial
negative slope, and error bars indicate SEM. Arrows
indicate HFS (100 Hz, 2 sec). B-D, Insets, EPSP
recorded during baseline and at the end of the recording period after
HFS. Calibration: 1.0 mV, 5 msec.
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Kinetics of Zn2+ chelation by CaEDTA
To verify that Zn2+ released from
mossy fiber terminals by HFS was adequately chelated by 10 mM CaEDTA, we loaded slices with the selective
extracellular Zn2+ fluorescent indicator
Newport Green dipotassium salt (cell-impermeable; Molecular Probes) and
visualized Zn2+ release after stimulation
in the presence and absence of CaEDTA. In a previous study (Li et al.,
2001), we found that electrically stimulated
Zn2+ release was frequency-dependent and
could be detected with as little as 10 Hz stimulation at 500 µA. The
degree of Zn2+ release also increased with
increasing stimulus amplitudes ranging from 20 to -500 µA (100 Hz
over 5 sec). Ten millimolar CaEDTA chelated 85% of the synaptically
released Zn2+, as indicated by Newport
Green fluorescence (Fig.
2A). This result verifies that the effect of CaEDTA on LTP induction in mossy
fiberCA3 synapses was achieved by its selective chelation of the
synaptically released Zn2+ from mossy
fiber terminals. After bath perfusion of 10 mM
CaEDTA for 10 min, followed by washout of the CaEDTA, we
could still induce normal release of
Zn2+ in normal ACSF (data not
shown). On the other hand, a lower concentration of CaEDTA (1 mM) failed to reduce the extracellular
Zn2+ after HFS, as evidenced by its
inability to reduce Newport Green fluorescence (Fig.
2A). Therefore, induction of LTP was essentially unaffected in 1 mM CaEDTA (Fig.
2B).
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Figure 2.
Zn2+ release with electrical
stimulation and the effects of Zn2+ chelator.
A, Extracellular Zn2+ released from
terminals after electrical stimulation (stim.) was
measured as the peak emission intensity of extracellular Newport Green
fluorescence in the absence and presence of Zn2+
chelator (3 determinations; error bars indicate SE). The paired images
on top correspond with each condition of the bar
graph. They were acquired before (controls in the first
row) and after (second row) HFS (200 µsec, 0.5 mA pulses for 5 sec). In these false-color images, increasing intensity
of Zn2+ fluorescence is represented by the spectrum
ranging from blue (the lowest) to red
(the highest). Scale bar, 100 µm. A', The
hatched area represents the region where images were
acquired. H, Hilus. Values plotted are the mean ± SEM; n = 4; *p < 0.05. A", Plot of electrical stimulation (100 Hz for 5 sec)-evoked rapid release of Zn2+ from neuronal
terminals measured by changes in Newport Green fluo- rescence intensity (arbitrary units). The
arrow indicates the beginning of stimulation.
B, A low concentration of CaEDTA (1 mM;
dashed line) had little effect on mossy fiber LTP
(227 ± 11%; n = 4) evoked by HFS. Each
point is the averaged and normalized EPSP initial
negative slope, and error bars indicate SEM. Arrows
indicate the time giving HFS (100 Hz, 2 sec). Calibration: 1.0 mV, 5 msec.
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These results are consistent with our calculations of the kinetics of
Zn2+ chelation in ACSF containing CaEDTA.
Our calculations predict that, in 10 mM CaEDTA, 100 µM extracellular Zn2+ would
be reduced to 33 nM within 0.1 msec, whereas in 1 mM CaEDTA, this concentration of
Zn2+ would only be reduced to 15 µM in 0.1 msec (Fig. 3; and
Appendix). Thus, we suggest that 10 mM CaEDTA effectively
removes Zn2+ released from nerve terminals
by HFS before its physiological function can be performed (Basolo and
Pearson, 1967; Davis et al., 1999). This explains why 1 mM
CaEDTA failed to block induction of LTP in this study (Fig.
2B) and in previous studies (Lu et al., 2000; Vogt et
al., 2000).
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Figure 3.
Calculated kinetics of chelation of 100 µM Zn2+ in ACSF by 1 and 10 mM CaEDTA. The rate of chelation of 100 µM
Zn2+ by 1 and 10 mM CaEDTA was estimated
using published and estimated forward and reverse rate constants as
described in Appendix. Only the first 0.1 msec after the release of
Zn2+ is given. Equilibrium conditions are assumed
for 1 and 10 mM CaEDTA in ACSF in the absence of
Zn2+ at time 0. Note that, under these conditions,
equilibrium concentrations after introduction of 100 µM
Zn2+ are not achieved within this time frame.
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Removal of synaptically released Zn2+ does not
affect basal synaptic transmission
Disodium EDTA nominally saturated with equimolar
Ca2+ (CaEDTA) has been used to add the
chelator to physiological buffers such as ACSF without appreciably
reducing the concentration of extracellular Ca2+, which is essential for normal
synaptic transmission. To verify this, we measured the concentration of
free Ca2+ in ACSF using a
Ca2+ electrode. Addition of 1 mM CaEDTA did not alter the free
Ca2+. Addition of 10 mM CaEDTA
reduced the measured concentration of free
Ca2+ from 2.25 ± 0.02 mM
(mean ± SEM; n = 3) to 2.03 ± 0.03 mM (mean ± SEM;
n = 3; Fig.
4A). This was probably
attributable to incomplete saturation of the EDTA with
Ca2+ during its manufacture. When we added
an extra 0.22 mM CaCl2 to
ACSF containing 10 mM CaEDTA to compensate for
the Ca2+ deficit, the concentration of
free Ca2+ was 2.25 ± 0.01 mM (mean ± SEM; n = 3).
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Figure 4.
Exposure of slices to a high concentration of
CaEDTA does not alter normal basal synaptic responses at mossy
fiberCA3 synapses with low-frequency stimulation. A,
Free Ca2+ was measured in normal ACSF (left
bar) and in ACSF containing 10 mM CaEDTA
(middle bar). The right bar shows the
concentration of Ca2+ measured in ACSF containing 10 mM CaEDTA with an additional 0.22 mM
CaCl2 (2.4 mM CaCl2 in normal ACSF)
added to restore free Ca2+ to the level in normal
ACSF. B, Plot of the EPSP against time, with
bath-applied CaEDTA (10 mM) indicated by a dashed
line. Each point represents the averaged initial
slope of evoked EPSP (n = 6). The averaged values
were then normalized to the mean initial slope during 30 min baseline
recording (percent ± SEM). The traces on
top represent recording before (1)
and during (2) CaEDTA perfusion.
C, The paired pulse ratio is unaffected by the addition
of CaEDTA, as shown on the left. The bar
graph demonstrates the average paired pulse ratios from six
recordings in which two stimuli were given 40 msec apart in the
presence and absence of CaEDTA. Calibration in B, C: 0.5 mV, 5 msec.
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Ten millimolar CaEDTA had no effect on basal synaptic transmission
elicited by low-frequency stimulation, as measured by the initial slope
of the EPSP at mossy fiberCA3 synapses (Fig. 4B). The chelator at this concentration also had no effect on paired pulse
facilitation, a physiological property of presynaptic terminal function
at mossy fiberCA3 synapses (Fig. 4C). Our data
demonstrate that basal synaptic function is not altered in the presence
of 10 mM Zn2+
chelator. Thus, the data suggest that the effects of CaEDTA we observed
were attributable to changes in Zn2+ concentration.
Mimicking Zn2+ release by adding exogenous
Zn2+ induces a long-lasting potentiation of synaptic
transmission
In the experiments described above, 10 mM CaEDTA
apparently blocked the induction of LTP, because it chelated the
Zn2+ released during HFS. We then
hypothesized that the addition of exogenous
Zn2+ to extracellular bathing solution in
the absence of HFS would enhance the strength of synaptic transmission
and would induce a long-lasting potentiation of the EPSP in field CA3.
As shown in Figure 5A, the
EPSP was gradually potentiated to 195 ± 17% of baseline
(mean ± SEM; n = 8) during a 20 min exposure to
100 µM Zn2+ and
remained potentiated for >3 hr. Zn2+ does
not affect the afferent volley in our experimental conditions. Throughout this experiment, the only stimulation applied was
low-frequency test stimuli. These data strongly suggest that
Zn2+ is able to enhance synaptic strength
at mossy fiberCA3 synapses. Once long-lasting potentiation of the
EPSP was established, washing away the exogenous
Zn2+ with ACSF containing 10 mM CaEDTA (10 min) did not halt the potentiation (Fig. 5A). This result also indicates that the potentiating
effect of Zn2+ was not attributable to its
prolonged binding to plasma membrane components. Figure 5B
shows the frequency (given as a percentage) with which various
concentrations of Zn2+ induced
long-lasting potentiation. In these concentration-response studies, we
could reliably induce long-lasting potentiation of the EPSP in
concentrations of 50 µM (71%;
n = 7) and 100 µM (100%; n = 9) Zn2+. Estimates of
the concentration of Zn2+ released from
the mossy fibers during HFS have ranged from 10 to 100 µM (Vogt et al., 2000; Li et al., 2001);
Zn2+ concentration could reach as much as
300 µM under extreme conditions (Frederickson,
1989). In the presence of 300 µM
Zn2+, we observed long-lasting
potentiation of the EPSP in less than half the slices tested
(n = 7; Fig. 5B). This high failure rate might be caused by the neurotoxic effect of
Zn2+ at this high concentration
(Frederickson et al., 2000).
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Figure 5.
Exogenous Zn2+ induces
long-lasting potentiation of the EPSP. A, Plot of
exogenous Zn2+-induced long-lasting potentiation.
Zn2+ (100 µM) was applied for 20 min
(line) after recording a 30 min baseline. Application of
Zn2+ was followed by wash with 10 mM
CaEDTA. Inset, EPSP recorded before and after
exposure to Zn2+. Note that the afferent volley
(arrow) was not affected. B, Percentage
of LTP induced by different concentrations of exogenous
Zn2+. Calibration in A: 1.0 mV, 5 msec.
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Glutamate facilitates the potentiating effect
of Zn2+
Because glutamate is also released from mossy fiber terminals
during electrical stimulation, it is reasonable to expect that, under
physiological conditions, both glutamate and
Zn2+ are required for LTP induction in
these terminals. In our next set of experiments, we sought to verify
that simultaneous application of exogenous glutamate and
Zn2+ together is sufficient to induce
long-lasting potentiation. In these experiments, co-perfusion of
glutamate and Zn2+, to imitate the
co-release of both from synaptic terminals, induced long-lasting
potentiation (Fig. 6A)
similar to that induced by Zn2+ alone
(Fig. 5A). The mean potentiated EPSP slope was 241 ± 11% (mean ± SEM; n = 6) of baseline, and the
potentiation was stable for >3 hr. Glutamate alone, however, in the
presence of 10 mM CaEDTA induced only a transient
EPSP potentiation, followed by an immediate return to baseline after
glutamate washout (Fig. 6A). This result implies
that glutamate itself could not induce a persistent EPSP
potentiation. As summarized in Figure 6B, the effect
of Zn2+ on induction of long-lasting
potentiation was modulated by the level of glutamate in the bath. With
the standard low-frequency (0.03 Hz) test stimulation, adding
both glutamate and Zn2+ caused a more
rapid EPSP potentiation than did Zn2+
alone. These results indicate that glutamate enables the potentiating effect of Zn2+.
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Figure 6.
Glutamate facilitates the potentiating effect of
Zn2+. A, Co-application of glutamate
(100 µM) and Zn2+ (100 µM) expeditiously potentiated EPSPs; potentiation lasted
several hours (filled diamonds). Glutamate alone
(open squares; in the presence of CaEDTA) failed to
induce long-lasting potentiation of the EPSP. Exogenous glutamate and
Zn2+ were applied for 20 min (line)
after recording a 30 min baseline. Application of glutamate or
Zn2+ with glutamate was followed by wash with 10 mM CaEDTA. B, Comparison of the rate of
onset of long-lasting potentiation induced by Zn2+
alone and Zn2+ plus glutamate. Each
point represents the averaged, normalized EPSP initial
slope ± SEM from data in Figure 5A and
A, respectively.
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Potentiation of the EPSP requires the entry of
Zn2+ into neurons
One plausible explanation for this interaction is that glutamate
is required to permit Zn2+ entry into
pyramidal neurons. Glutamate allows Zn2+
to enter both directly through
Ca2+-permeable AMPA/kainate and NMDA
receptors and indirectly, via its depolarizing effects, through VDCC
(Choi and Koh, 1998; Weiss and Sensi, 2000). We directly tested whether
glutamate mediates Zn2+ translocation
across the postsynaptic membrane by the following experiments. Cells in
the slice were loaded with Newport Green diacetate (the cell-permeable
dye that, once inside the cell, is hydrolyzed by cytoplasmic esterases
to become membrane-impermeable) and then thoroughly washed to eliminate
unincorporated dye. Mossy fiber axons were then stimulated with HFS,
and the entry of Zn2+ into cells in the
CA3 pyramidal layer was imaged. In agreement with our previous
findings, HFS caused an immediate influx of Zn2+ into cells (Fig.
7A). The increase of
intracellular Zn2+ fluorescence elicited
by HFS was depressed by addition of either CaEDTA (10 mM) or CNQX (10 µM), an
antagonist of AMPA/kainate receptors (Fig. 7B). The
remaining fluorescence in the presence of 10 mM
CaEDTA was likely caused by rapid entry of a small fraction of released
Zn2+ into postsynaptic neurons or into
presynaptic terminals. CNQX can block entry of
Zn2+ not only through AMPA/kainate
receptors but also through VDCC and NMDA receptors by preventing
membrane depolarization by AMPA/kainate receptor channels. These
results agree with our finding that CaEDTA blocks HFS-induced LTP by
blocking Zn2+ entry into postsynaptic
neurons.
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Figure 7.
Increase of intracellular Zn2+
after HFS. A, Paired images of the pyramidal layer of
CA3 taken with a 63× water immersion objective lens. Electrical
stimulation increased intracellular Zn2+ in the CA3
region of hippocampal slices loaded with Newport Green diacetate
(cell-permeable). Before stimulation (1), no cell
bodies were labeled; they became visible (2)
after stimulation (100 Hz, 500 µA for 10 sec). Scale bar, 50 µm;
arrowheads indicate pyramidal cell bodies.
B, Intracellular Zn2+ was detected
with the fluorescence indicator Newport Green diacetate in normal ACSF
and ACSF containing CaEDTA (10 mM) or CNQX (10 µM). The results are plotted on the left.
the arrow indicates the beginning of stimulation. The
bar graph on the right summarizes the
effects of CaEDTA (n = 5) and CNQX
(n = 3) on the increase in intracellular
Zn2+ after electrical stimulation, expressed as
percentage of control. Error bars indicate SEM.
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Because CNQX blocked both Zn2+
translocation and LTP induction, we tested whether the introduction of
Zn2+ into neurons by a different route
could restore LTP. In several experiments,
Zn2+ entry via ionotropic glutamate
receptors and VDCC was blocked by 10 µM CNQX and 50 µM AP-5 (the NMDA receptor antagonist AP-5 was present in
the perfusate throughout these experiments) but allowed to enter via
sodium pyrithione, a selective Zn2+
ionophore (Zalewski et al., 1993), which directly increases
intracellular Zn2+ (Fig.
8A). After washout of
CNQX, Zn2+, and Na-pyrithione, a
long-lasting potentiation developed in the absence of HFS (158 ± 12%, mean ± SEM; n = 3). In contrast, without
Na-pyrithione, addition of Zn2+ alone in
the presence of CNQX failed to induce long-lasting potentiation of the
EPSP (93 ± 9%, mean ± SEM; n = 4; Fig.
8B). Likewise, pyrithione (50 µM) alone, in the absence of
Zn2+, had no long-lasting effect on the
EPSP (104 ± 5%, mean ± SEM; n = 5; data
not shown). In slices loaded with intracellular Newport Green, which
could also function as a selective intracellular Zn2+ chelator, the induction of LTP by HFS
was blocked (110 ± 4.5%, mean ± SEM; Fig.
9). These data indicate that the
translocation of extracellular Zn2+ into
postsynaptic neurons is critical for the induction of LTP in mossy
fiberCA3 synapses and suggest an intracellular site of action for
Zn2+.
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|
Figure 8.
Potentiation of the EPSP requires entry of
Zn2+ into cells. A, Paired images of
the pyramidal layer of CA3 (taken with a 63× objective lens) loaded
with Newport Green diacetate before (1) and after
(2) exposure to Zn2+ (100 µM), Na-pyrithione (50 µM), and CNQX (10 µM). Scale bar, 50 µm; arrowheads
indicate pyramidal cell bodies. B, Plot of the EPSP
slope from a representative experiment to show that selectively
increasing intracellular Zn2+ potentiates the EPSP
(158 ± 12%; n = 4; filled
diamonds). Zn2+ (100 µM) and
Na-pyrithione (50 µM) were applied after the EPSP was
blocked by CNQX (10 µM). In a similar experiment without
Na-pyrithione, no EPSP potentiation was observed (93 ± 9%;
n = 4; open squares).
Lines indicate the duration of drug application.
Inset, Summary of four experiments in which slices were
treated with Na-pyrithione and Zn2+. Values of the
EPSP amplitude were taken from baseline (1), in
the presence of CNQX (2), and during EPSP
potentiation (3). Numbers
correspond to those in B. *Significant difference
(p < 0.05) between 1 and
3.
|
|
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Figure 9.
Intracellular Zn2+ chelator
blocks the induction of LTP. HFS failed to induce mossy fiber LTP
(110 ± 4.5%; n = 4) in slices loaded with
intracellular Newport Green, which was used here as a selective
intracellular Zn2+ chelator (dashed
line). Each point represents the averaged and
normalized EPSP initial negative slope, and error bars indicate SEM.
Inset, EPSP recorded during baseline and at the end of
recording after HFS. The arrow indicates HFS (100 Hz, 2 sec). Calibration: 1.0 mV, 5 msec.
|
|
| |
DISCUSSION |
Our results establish that synaptically released
Zn2+ plays an essential role in the
induction of LTP in mossy fiberCA3 synapses. Effective
Zn2+ chelation blocked the induction of
LTP by HFS. Bath application of exogenous
Zn2+ induced a long-lasting potentiation
of the EPSP, apparently by acting at an intracellular site rather than
at an extracellular site. Co-released glutamate is also essential for
induction of LTP under physiological conditions, in part because it
allows Zn2+ entry into postsynaptic neurons.
The mossy fiberCA3 synapse contains high concentrations of
Zn2+ in large synaptic boutons (Haug,
1967; Perez-Clausell and Danscher, 1985; Frederickson, 1989). This
Zn2+ is released in the same manner as a
neurotransmitter and is thought to be co-released with glutamate on
stimulation of presynaptic terminals. We found that
Zn2+ release is dependent on stimulation
frequency (Li et al., 2001). Each mossy fiber bouton terminates on the
proximal portion of apical CA3 dendrites with up to 35 release sites
(Chicurel and Harris, 1992). Mossy fiber synapses show tremendous
frequency facilitation that leads to plateau depolarizations during
long stimulus trains (Vogt et al., 2000). Although we do not know the exact relationship between the prominent presence of
Zn2+ and these unusual features, it
indicates that these synapses are capable of rapidly releasing large
amounts of Zn2+ during HFS. Therefore, it
is not surprising that a high concentration of
Zn2+ chelator was needed to buffer
effectively the Zn2+ released during the HFS.
In this investigation of the possible role of
Zn2+ in mossy fiberCA3 synaptic
plasticity, the removal of synaptically released Zn2+ with 10 mM CaEDTA blocked
the induction of LTP. Direct fluorescence imaging showed that 10 mM CaEDTA chelated 85% of the synaptically released
Zn2+. This result verifies that the effect
of CaEDTA on LTP induction in mossy fiberCA3 synapses was achieved
by its selective chelation of the synaptically released
Zn2+ from mossy fiber terminals. On the
other hand, a lower concentration of CaEDTA (1 mM) failed
to reduce the extracellular Zn2+ after
HFS, as evidenced by its inability to reduce Newport Green fluorescence. We have calculated that, under equilibrium conditions, 1 and 10 mM CaEDTA should indeed reduce 10-100
µM Zn2+ to 0.04-4
nM. The presence of 2.4 mM
Ca2+ and 1.3 mM
Mg2+ in the medium and the slow
dissociation rate of CaEDTA, however, limit the rate at which
Zn2+ is chelated (see Materials and
Methods and Appendix). Kinetic calculations indicate that
Zn2+ is chelated in a biphasic manner. The
initial rate of chelation, limited by the initial concentration of free
EDTA and rapidly dissociating MgEDTA, reaches completion in <0.1 msec.
The slower phase, limited by the dissociation of CaEDTA, requires many
seconds to reach completion at the equilibrium concentrations. Thus 1 mM CaEDTA was unable to prevent the micromolar
accumulations of Zn2+ induced by HFS from
mossy fiber terminals and entry into CA3 dendrites that we have
observed to take place within milliseconds, because it provided a lower
concentration of free EDTA and MgEDTA relative to the concentration of
released Zn2+. Ten millimolar CaEDTA, on
the other hand, provided enough free EDTA and MgEDTA to reduce the
10-100 µM Zn2+ released by
the mossy fiber terminals to concentrations below the level readily
detected by Newport Green fluorescence as well as those required for LTP.
In the present study, the addition of 50-100 µM
exogenous Zn2+ to the solution bathing the
slice was required to induce a reliable, long-lasting potentiation of
the EPSP. These data suggest that Zn2+ is
able to enhance synaptic strength at mossy fiberCA3 synapses. Ten
micromolar Zn2+ did not appreciably alter
synaptic transmission. Hence, it can be assumed that under stimulation
conditions necessary to induce LTP, concentrations of >10
µM Zn2+ are released in the
synapse. In addition, this may explain why the removal of
Zn2+ released into the synaptic cleft
during basal conditions or low-frequency stimulation failed to alter
synaptic transmission. However, Zn2+ is
able to inhibit the NMDA receptor at concentrations as low as 50 nM (Chen et al., 1997) and may play an important role in shaping the NMDA receptor response at this synapse under normal physiological conditions. Our results confirm the previous observation that, although a deficiency of bouton Zn2+
in rats resulted in the impairment of mossy fiber LTP, it does not
appear to affect normal synaptic transmission (Lu et al., 2000). Thus,
synaptically released Zn2+ appears to have
little effect on basal synaptic function other than in modulating NMDA
responses (Peters et al., 1987; Westbrook and Mayer, 1987; Chen et al.,
1997) but is required for LTP induction by HFS in mossy fiberCA3
synapses, which does not require NMDA receptor activation (Harris and
Cotman, 1986). It is possible that Zn2+
may act on GABAergic interneurons resulting in an indirect effect on
the pyramidal cell. Zn2+ inhibits
hippocampal postsynaptic GABA current with a
Kd of 11 µM
(Mayer and Vyklicky, 1989). In our study, however, the removal of
released Zn2+ or the addition of 10 µM exogenous Zn2+
did not alter synaptic transmission in mossy fiberCA3 synapses. Furthermore, Zn2+ did not affect the
afferent volley in our experimental conditions. We have therefore
concluded that the indirect effects of
Zn2+ acting on interneurons did not
inhibit LTP at this synapse.
Because glutamate is also released from mossy fiber terminals during
electrical stimulation, it is reasonable to expect that, under
physiological conditions, both glutamate and
Zn2+ are required for LTP induction in
these terminals. The results from the present study indicate that
glutamate promotes Zn2+ entry into the
neuron by opening Zn2+-permeable channels.
It is known that glutamate allows Zn2+ to
enter cultured neurons directly through
Ca2+-permeable AMPA/kainate and NMDA
receptors and indirectly, via its depolarizing effects, through VDCC
(Choi and Koh, 1998; Weiss and Sensi, 2000). In the present study, the
increase of intracellular Zn2+ elicited by
HFS was depressed by addition of CNQX, which can block entry of
Zn2+ not only through AMPA/kainate
receptors but also through VDCC and NMDA receptors by preventing
membrane depolarization through the activation of AMPA/kainate
receptors. We can rule NMDA receptors out, because we included APV in
the ACSF. Toth et al. (2000) have reported that
Ca2+-permeable AMPA receptors are not
expressed in CA3 principal neurons, raising doubt that these channels
contribute significantly to Zn2+ entry in
this region. Kainate receptors or VDCC remain as primary candidates.
The possibility that these are the routes of
Zn2+ entry in the proximal dendrites of
CA3 pyramidal neurons in our experiments is also supported by the
presence of a high density of VDCCs and putative
Ca2+-permeable kainate receptors in mossy
fiberCA3 synapses (Westenbroek et al., 1990; Bortolotto et al.,
1999; Sui and Ruan, 2000). Ca2+ can enter
the CA3 pyramidal neurons through these same channels. An increase in
intracellular Ca2+ in postsynaptic neurons
during LTP induction has been established for all hippocampal synapses
except the mossy fiberCA3 synapse (Zalutsky and Nicoll, 1990).
Whether Ca2+ is required in the induction
of mossy fiber LTP is the subject of many debates. Other groups have
provided evidence that there is an initial rise in postsynaptic
intracellular Ca2+ during LTP induction at
the mossy fiber synapse (Yeckel et al., 1999). In these reports, LTP
was prevented by chelation of postsynaptic intracellular
Ca2+. Interpretation of these results,
however, is complicated by the fact that both the
Ca2+ indicator and chelator used in those
studies have higher affinities for Zn2+
than for Ca2+. It is impossible to exclude
in these studies the role of Zn2+ in LTP
induction. A delineation of the separate roles of
Zn2+ and Ca2+
in LTP induction and the possible interactions between these two ions
will require further investigation.
One of the hallmarks of the mossy fiber synapse is its apparent lack of
NMDA receptor-dependent synaptic plasticity. Some reports have
indicated that LTP at mossy fiberCA3 synapses may be of presynaptic
origin (Harris and Cotman, 1986; Nicoll and Malenka, 1999). However, in
other studies, mossy fiber LTP has required both presynaptic and
postsynaptic activation (Jaffe and Johnston, 1990). Many of these data
could be explained by such factors as the type of LTP-inducing stimulus
applied and the recording conditions, but the reasons for the
conflicting results are still unclear. Although examining the
presynaptic versus postsynaptic origin of LTP was not the goal of the
present study, our results would support either a presynaptic or a
postsynaptic origin of LTP. On release,
Zn2+ could be taken up by selective
high-affinity Zn2+ transporters in the
mossy fiber terminals or could enter the postsynaptic neuron through
glutamate and VDCC for induction of mossy fiber LTP. Our results cannot
eliminate either mechanism for several reasons: First, CaEDTA prevented
Zn2+ from entering both presynaptic
terminals and postsynaptic neurons. Second, bath-applied
Zn2+ could enter both mossy fiber
terminals and CA3 neurons. Third, although CNQX blocked postsynaptic
entry of Zn2+, there may still be a
substantial amount of Zn2+ taken up by
presynaptic terminals, as indicated by the difference in the
intracellular Newport Green fluorescence obtained in the presence of
CaEDTA compared with that obtained with CNQX blockade after HFS. These
arguments do not negate our observation, however, that
Zn2+ must enter cells to perform its role
in LTP induction through interactions with kinases, phosphatases, and
other intracellular signaling pathways.
Our results introduce the idea that Zn2+
released from mossy fiber synapses acts as a presynaptically released
second messenger or trans-synaptic factor. A presynaptically released
factor that enhances synaptic strength could improve specificity and
efficacy of synaptic transmission. In addition to its crucial role for gene expression and transcription, Zn2+
has been shown to activate a number of protein kinases such as protein
kinase C (Hubbard et al., 1991; Quest et al., 1992), Ca/calmodulin kinase II (Brewer et al., 1979; Weinberger and Rostas, 1991; Lengyel et
al., 2000), and mitogen-activated protein kinase (Park and Koh, 1999),
which are associated with establishing LTP (Feng, 1995; Soderling and
Derkach, 2000; Sweatt, 2001). Mossy fiber boutons terminate on
the proximal portion of apical dendrites of CA3 pyramidal neurons. This
unusual structure may give Zn2+ direct
access to modulate gene transcription. Additionally, nanomolar Zn2+ signals modulate protein-tyrosine
phosphatases and, thus, the phosphorylation of myriad postsynaptic
proteins (Maret et al., 1999). Therefore, the present study raises the
intriguing possibility that entry of synaptically released
Zn2+ modulates intracellular signaling
pathways and gene transcription.
| |
FOOTNOTES |
Received May 7, 2001; revised July 20, 2001; accepted July 23, 2001.
This research was supported by grants from the Brain Injury Association
and National Institutes of Health Grant NS23865 to J.M.S., generous
support from Theodore and Vada Stanley to C.J.H., and in part by
National Institutes of Health Grants NS40215 and NS38585 to C.J.F. We
thank Richard Thompson for helpful discussions and Ajay Verma for
assistance with measurement of free Ca2+.
The opinions and assertions contained herein are the private opinions
of the authors and are not to be construed as official or reflecting
the views of the Uniformed Services University of the Health Sciences
or the United States Department of Defense.
Correspondence should be addressed to John Sarvey, Department of
Pharmacology, Uniformed Services University of the Health Sciences,
4301 Jones Bridge Road, Bethesda, MD 20814. E-mail: jsarvey{at}usuhs.mil.
| |
APPENDIX |
Calculations of Zn2+ chelation by CaEDTA in the
presence of the ions in ACSF.
Our modeling of Zn2+ chelation by
CaEDTA in the presence of the Ca2+ and
Mg2+ in ACSF included both equilibrium and
kinetics calculations. Although 1 mM CaEDTA may be adequate
to remove released free Zn2+ by
thermodynamic arguments, the kinetics of chelation may be too slow to
achieve adequate removal within the time frame of a synaptic event.
Equilibrium constants were obtained from Martell and Smith (1974) and
Bers et al. (1994). Kinetic constants were obtained from Davis et al.
(1999) and Hering and Morel (1988) (Table
1). In the absence of an experimentally
derived on-rate for Zn2+ complexing with
EDTA, we used the rate of diffusion (108
M/sec) as the rate that limits
Zn2+-EDTA complex formation. The off-rate
constant was then calculated from the
Kd. The equations used for the
equilibrium case are as follows:
Let C, M, Z, and E
represent the concentrations of the free ions of calcium, magnesium,
zinc, and EDTA, respectively. CE, ME, and
ZE represent the concentrations of the EDTA complexes of
Ca2+, Mg2+,
and Zn2+, respectively.
CT,
MT,
ZT, and
ET represent the total concentrations of Ca2+,
Mg2+, Zn2+,
and EDTA, respectively. KC,
KM, and
KZ represent the equilibrium dissociation constants for Ca2+,
Mg2+, and
Zn2+, respectively. Total concentration of
any one metal ion is the sum of chelated and free ions. Thus:
|
(1)
|
Total EDTA in solution is given by:
|
(2)
|
Substituting the chelated forms for the expressions containing
total concentrations in Equation 1 and rearranging, the total concentrations on the left:
|
(3)
|
|
(4)
|
Rearranging the definition of the dissociation constants and
substituting Equation 1 for the chelated forms:
|
(5)
|
we can derive three equations by substituting Equation 5 in
Equation 4:
|
(6)
|
|
(7)
|
|
(8)
|
Equations 6-8 are quadratic equations, each with three unknowns.
They could be solved simultaneously, but we used an iterative calculation method using Microsoft Excel. Estimates were made of each
ion concentration initially in the absence of
Zn2+ and then including
Zn2+, and a calculated value was
determined using Equations 6-8, in order of increasing affinity for
EDTA. With each calculation, the calculated value was substituted for
the estimate made for that ion. A macro was created to do this
iteratively until the difference between the calculated and estimated
values for Mg2+ concentration was less
than an arbitrary critical value (1 × 109). The results for
Zn2+ concentration are shown in Table
2. The equilibrium values for Ca2+, Mg2+,
and Zn2+ agreed with those calculated by
WEBMAXC version 2.10 (www.stanford.edu/~cpatton/webmaxc2.htm) using
the same equilibrium constants (Table 2). Our estimates of equilibrium
concentrations assumed a temperature of 32°C, pH 7.40, and an ionic
strength of 0.159 for ACSF.
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|
Table 2.
Equilibrium constants and Zn2+ concentration in
ACSF at two different concentrations of total Zn2+ and
CaEDTA
|
|
The kinetics of Zn2+ chelation were
calculated as follows: Let koff and
kon be the dissociation and
association rate constants. Then:
|
(9)
|
Substituting Equation 4 for E in Equation 9, the rate
of zinc chelation can be calculated from the concentrations of the three metal ions and other constants:
|
(10)
|
This equation is also quadratic. The equations for the other ions
were derived in the same way and have the same form. Again, we used an
Excel spreadsheet to calculate an approximation of the concentrations
of each of the three metal ions over time from initial conditions using
an appropriately small interval (1 × 107 sec). The initial conditions chosen
were consistent with our experimental conditions. These take the
concentrations of Ca2+ and
Mg2+ in ACSF to be those at equilibrium
with the given concentration of CaEDTA in the absence of
Zn2+. The given concentration of
Zn2+ was assumed to be released
instantaneously into the medium at time 0. Figure 3 shows the time
course of Zn2+ concentration change over
the course of 0.1 msec, a time frame considered typical for
neurotransmitter release.
| |
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ABSTRACT
INTRODUCTION
