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The Journal of Neuroscience, January 1, 1999, 19(1):85-95
Opioid Receptor Subtype Expression Defines Morphologically
Distinct Classes of Hippocampal Interneurons
Kurt R.
Svoboda1,
Cathy
E.
Adams2, and
Carl R.
Lupica1, 3
Departments of 1 Pharmacology and
2 Psychiatry, and 3 Program in Neuroscience,
University of Colorado Health Sciences Center, Denver, Colorado 80262
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ABSTRACT |
The inhibition of hippocampal pyramidal cells occurs via inhibitory
interneurons making GABAergic synapses on distinct segments of the
postsynaptic membrane. In area CA1 of the hippocampus, the activation
of mu- and delta-opioid receptors inhibits these interneurons, thereby
increasing the excitability of the pyramidal cells. Through the use of
selective opioid agonists and biocytin-filled whole-cell electrodes,
interneurons possessing somata located within stratum oriens of
hippocampal slices were classified according to the location of their
primary axon termination and the expression of mu- or delta-opioid
receptors. Activation of these opioid receptor subtypes resulted in
outward currents in the majority of interneurons, which is consistent
with their inhibition. Post hoc morphological analysis
revealed that those interneurons heavily innervating the pyramidal cell
body layer were much more likely to express mu-opioid receptors,
whereas cells with axons ramifying in the pyramidal neuron dendritic
layers were more likely to express delta-opioid receptors, as defined
by the generation of outward currents. This morphological segregation
of interneuron projections suggests that mu receptor activation would
diminish GABA release onto pyramidal neuron somata, thereby increasing
their excitability and output. Conversely, inhibition of interneurons
via delta receptor activation would amplify afferent signaling to
pyramidal neuron dendrites by reducing GABAergic inhibition of these structures.
Key words:
delta receptor; electrophysiology; enkephalin; GABA; hippocampus; inhibition; morphology; mu receptor; nonselective cation
current; opioid receptor; oriens/alveus interneurons; potassium
current
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INTRODUCTION |
The interaction among principal
cells and GABAergic inhibitory interneurons is one means through which
computational processes occur in mammalian cortical areas. In the
hippocampus, the diverse group of cells classified as inhibitory
interneurons constitutes between 10 and 20% of the total neuronal
population. The heterogeneity within this group of neurons is
attributed to the differential expression of calcium-binding proteins,
peptide cotransmitters, and ion channels (Zhang and McBain, 1995 ;
Chikwendu and McBain, 1996; Maccaferri and McBain, 1996; Svoboda and
Lupica, 1998) (for review, see Freund and Buzsáki, 1996). In
addition, a high degree of anatomical variability exists in the extent
and location of the inhibitory axon termination on the principal
(pyramidal) neuron membrane. Thus, inhibitory cells providing
perisomatic inhibition form synapses on pyramidal neuron somata (basket
cells) and axon initial segments (axo-axonic cells), whereas others
display circumscribed innervation of pyramidal neuron dendrites (Buhl
et al., 1994a; Cobb et al., 1995, 1997; Miles et al., 1996). Because of
this axonal segregation, these classes of interneurons exert distinct functional effects on pyramidal neurons in the hippocampus. For example, perisomatic inhibition has been shown to globally limit pyramidal neuron excitability by blocking
Na+-dependent action potentials (Miles et al.,
1996). Also, somatic inhibition can remove the inactivation of
voltage-dependent inward currents, thus permitting the synchronization
of groups of pyramidal neurons and the generation of  oscillations
(Cobb et al., 1995; Whittington et al., 1995). In contrast, GABAergic
IPSPs impinging on pyramidal neuron dendrites can shunt EPSPs, diminish
dendritically generated Ca2+ action potentials
(Masukawa and Prince, 1984; Miles et al., 1996; Tsubokawa and Ross,
1996), and remove the inactivation of dendritic K+
conductances (Hoffman et al., 1997). These physiological data, together
with the differing anatomical profiles of the interneurons strongly
suggest that perisomatic and dendritic inhibition serve distinct
functional roles in the hippocampus.
In addition to the sources of heterogeneity described above, there is
good evidence that different groups of interneurons are selectively
innervated by distinct neurotransmitter-containing afferents (Freund
and Antal, 1988; Freund et al., 1990; Fuzesi et al., 1997).
Furthermore, different interneurons express distinct sets of
neurotransmitter receptors (McBain and Dingledine, 1993; McBain et al.,
1994; Bergles et al., 1996; McMahon and Kauer, 1997; Miller et al.,
1997; Morales and Bloom, 1997; Frazier et al., 1998; Svoboda and
Lupica, 1998), suggesting further segregation of function. Among the
receptors expressed on inhibitory interneurons in the CA1 region of the
hippocampus are µ- and  -opioid receptors (Mansour et al., 1995;
Commons and Milner, 1997). Physiological studies have shown that
activation of these receptors can lead to the inhibition of interneuron
activity (Madison and Nicoll, 1988; Wimpey and Chavkin, 1991; Svoboda
and Lupica, 1998), resulting in diminished GABA release and the
disinhibition of pyramidal neurons (Zieglgansberger et al., 1979; Lee
et al., 1980; Nicoll et al., 1980; Siggins and Zieglgansberger, 1981;
Cohen et al., 1992; Lupica et al., 1992; Lupica, 1995). It was also
demonstrated that µ-opioid receptor activation resulted in a more
profound increase in pyramidal neuron excitability, the generation of
epileptiform activity, and the disruption of oscillations when
compared with receptor activation (Wimpey et al., 1989; Lupica and
Dunwiddie, 1991; Lupica, 1995; Whittington et al., 1998). These data
suggested that µ- and -opioid receptors may be expressed on
different subsets of interneurons providing inputs to distinct regions
of the pyramidal neuron membrane. To test this hypothesis, we have
examined the morphological differences between interneurons expressing
either µ- or -opioid receptors in the CA1 region of the
hippocampus, using biocytin as a cellular marker. Opioid receptor
subtype expression was determined through the application of highly
selective µ- or -opioid receptor agonists and the measurement of
membrane currents in voltage-clamped neurons. We then attempted to
classify interneurons based on opioid receptor subtype expression, as
defined by the generation of these outward currents, and the axonal and dendritic profiles. We observed that interneurons innervating the
pyramidal neuron perisomatic region were more likely to express µ-,
rather than -opioid receptors. In contrast, interneurons projecting
to pyramidal neuron dendritic regions more frequently expressed ,
rather than µ-opioid receptors.
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MATERIALS AND METHODS |
Electrophysiology. Hippocampal slices were prepared
and maintained as previously described (Miller et al., 1997). Briefly, 14-30-d-old male Sprague Dawley rats (Sasco, Omaha, NE) were killed by
rapid decapitation. Their brains were removed and placed in ice-cold,
oxygenated artificial CSF (aCSF; see below). Brain slices containing the hippocampus were cut transverse to the anteroposterior axis at 300 µm nominal thickness using a vibrating tissue slicer (Technical Products International, St. Louis, MO). The slices were then
stored suspended on netting in a beaker containing aCSF, aerated
continuously with 95% O2 and 5% CO2 at
room temperature. Control aCSF consisted of (in mM): NaCl,
126; KCl, 3.0; MgCl2, 1.5; CaCl2,
2.4; NaH2PO4, 1.2; glucose, 11.0; and
NaHCO3, 26, and was saturated with 95%
O2 and 5% CO2. Interneurons were visualized in
stratum oriens of area CA1 using a fixed stage upright microscope equipped with differential interference contrast optics and infrared illumination, as previously described in detail (Dodt and
Zieglgansberger, 1990; Miller et al., 1997). Whole-cell recordings were
obtained at room temperature (20-23°C) using an Axopatch-200A
amplifier (Axon Instruments, Burlingame, CA), and electrodes pulled
from thick-walled borosilicate capillary tubing (inner diameter, 0.75 mm; outer diameter, 1.5 mm; Sutter Instrument Company, Novato, CA). The
electrodes had resistances of 4-7 M , when filled with (in
mM): K+-gluconate, 125.0; KCl, 10.0;
HEPES, 10.0; EGTA, 1.0; CaCl2, 0.1; Mg2+-ATP, 2.0; and Na+-GTP, 0.2 (adjusted to pH 7.2-7.4 with 1 M KOH, and brought to 270-280 mOsm with deionized water). All interneurons were
voltage-clamped at  66 mV, unless otherwise stated, after correcting
for a liquid junction potential. Series resistance was <15 M and
was monitored throughout the experiments using the capacitative
currents generated by small (5 to 10 mV; 250 msec) voltage steps.
Cells were rejected from analysis if the series resistance
changed by  10-15%. Voltage-clamp protocols were delivered using a
pulse generator (AMPI Master 8; Jerusalem, Israel), and signals were
acquired using a personal computer-based data acquisition system
(Strathclyde Electrophysiology Software; courtesy of John Dempster,
Strathclyde University, UK).
Drug application. The selective -opioid receptor agonist
DPDPE (D-Pen2,
Pen5-enkephalin) and the selective µ-opioid
receptor agonist DAMGO (Tyr-D-Ala2,N-CH3-Phe4,Gly-ol-enkephalin)
were obtained from the National Institute on Drug Abuse Drug Supply
System (Rockville, MD). Both drugs were made at 100 times their final
concentration in deionized, purified water and added to the aCSF
bathing the slice (flow rate, 2 ml/min) using calibrated syringe pumps
(Razel Scientific Instruments, Stamford, CT). Unless otherwise stated,
both the µ and the agonists were applied at a concentration of 1 µM. This concentration has been shown in previous studies
to provide maximal occupation of, and selectivity at, the respective
receptor subtype (Mosberg et al., 1983; Goldstein and Naidu, 1989;
Lupica, 1995).
Histology. Biocytin (0.25%; Sigma, St. Louis, MO) was added
to the internal solution in the recording pipette for post
hoc evaluation of neuronal morphology. At the end of the recording session, the pipette was slowly withdrawn, and the slice was
transferred to chilled (4°C) 4% paraformaldehyde in PBS solution.
Slices were stored in the chilled fixative for 3-7 d and were not
resectioned before biocytin development procedures (Ceranik et al.,
1997). After fixation, they were rinsed in PBS (3 × 5 min),
quenched (0.3% H2O2/PBS for 30 min), rinsed
again in PBS (3 × 5 min), and then exposed to avidin-biotin
horseradish peroxidase complex containing 0.3% Triton X-100 (ABC kit;
Vector Laboratories, Burlingame, CA) for 4 d. On the fourth day,
they were rinsed again in PBS and then incubated in 0.04%
diaminobenzidine (DAB) and 0.0025% H2O2 for
20-30 min. The DAB reaction was stopped by rinsing again in PBS. The
slices were then dehydrated in incrementing concentrations of ethanol
(70, 95, 100, and 100%). After dehydration, they were cleared
in Hemo-D (3 × 5 min) and then mounted on slides. Cells were
reconstructed using a 40× objective with the aid of a camera lucida
drawing tube attached to an Olympus microscope.
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RESULTS |
Morphology of stratum oriens interneurons
Whole-cell recordings were obtained from 94 interneurons with
somata located within stratum oriens. Complete axon fills were observed
in 75 interneurons that were used in the subsequent morphological and
physiological analyses. The photomicrographs in Figure
1 illustrate the four major classes of
interneuron that were encountered in this study. These cells were
classified based on the stratum (pyramidale, lacunosum-moleculare,
radiatum, or oriens) that was most heavily innervated by the primary
axon (Fig. 1). Twelve interneurons (16%) displayed axonal
arborizations restricted, primarily, to the pyramidal cell body layer
(stratum pyramidale), and were thus classified as perisomatic cells
(Fig. 1A). These cells typically possessed two to
eight large, apically oriented dendrites that projected through stratum
pyramidale and terminated in stratum radiatum and/or stratum
lacunosum-moleculare (Fig. 1A, see Fig. 3). In addition, these neurons usually possessed several basally oriented dendrites within stratum oriens, occasionally making contact with the
alveus. Cells displaying these morphological characteristics include
the basket and axo-axonic cells that have been described by others
(Buhl et al., 1994b, 1995; Miles et al., 1996; Cobb et al., 1997) (for
review, see Freund and Buzsáki, 1996).
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Figure 1.
Morphology of stratum oriens interneurons.
Photomicrographs of the four subtypes of biocytin-filled
stratum oriens interneurons analyzed in this study. A,
An interneuron with its axon almost exclusively innervating stratum
pyramidale, in which the CA1 pyramidal cell bodies are located.
B, An OLM or horizontal cell. Note the dense axon
termination in stratum-lacunosum moleculare and the horizontally
oriented dendrites in stratum oriens. These are the defining anatomical
characteristics of this cell type. C, An interneuron
with its primary axonal ramification in stratum radiatum.
D, An interneuron with its primary axonal projection
confined to stratum oriens. The arrowheads denote
stratum pyramidale in A, C, and
D. Scale bar, 100 µm. a, Alveus;
SO, stratum oriens; SP, stratum
pyramidale; SR, stratum radiatum;
SL-M, stratum lacunosum-moleculare.
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Seventeen neurons (23%) exhibited axons that arborized
extensively within stratum lacunosum-moleculare (Fig.
1B, see Figs. 4, 5). This region is known to contain
the apical dendrites of CA1 pyramidal neurons that receive excitatory
input from afferents arising in the entorhinal cortex and thalamus
(Gulyas et al., 1993a; Desmond et al., 1994; Sik et al., 1995; Yanovsky
et al., 1997). Typically, these neurons possessed a single axon that
crossed stratum pyramidale, although some neurons had minor axon
collaterals that terminated either in stratum radiatum and/or stratum
oriens (see Fig. 4B). The dendrites of these cells
were oriented parallel to stratum oriens and confined exclusively to
this layer. These morphological characteristics are similar to those
described for the stratum oriens, lacunosum-moleculare interneurons
known as OLM or horizontal cells that are known to form synapses on the distal apical dendrites of CA1 pyramidal neurons (Lacaille et al.,
1987; McBain et al., 1994; Sik et al., 1995; Ali and Thomson, 1998)
(for review, see Freund and Buzsáki, 1996). The remainder of the
interneurons demonstrated primary axonal projections to either stratum
radiatum (22 of 75, 29%; Fig. 1C) or stratum oriens (24 of
75, 32%; Fig. 1D). Because some of these cells
provided substantial innervation of more than a single hippocampal
layer, they resembled interneurons previously described as bistratified cells (see Figs. 6A, 7) (Buhl et al., 1994a; Ali et
al., 1998). The dendritic structure of these cells varied considerably.
In some cases, the dendrites were confined to stratum oriens, where they often coursed parallel to the alveus. However, cells were also
encountered that had dendritic arborizations within stratum radiatum
(Fig. 1C). The observation that many axon arborizations were
confined to a single stratum suggested that these cells selectively targeted particular areas of the pyramidal neuron membrane.
Stratum oriens interneurons: physiology and
opioid pharmacology
A previously noted characteristic of stratum oriens
interneurons was the presence of the hyperpolarization-activated inward current known as Ih (Bergles et al., 1996;
Maccaferri and McBain, 1996; Parra et al., 1998; Svoboda and Lupica,
1998). This current was present in >90% of the cells in the present
study (86 of 94 cells), and its voltage and time dependence were
similar to those previously reported (Fig.
2B,C). In a previous study, we
have shown that the outward currents produced by µ- or -opioid
receptor activation in stratum oriens interneurons were caused by the
inhibition of Ih and the simultaneous activation
of a K+ current (Svoboda and Lupica, 1998). Both of
these actions are consistent with the hyperpolarization and subsequent
inhibition of these interneurons. In the present study, we used bath
application of highly selective µ- or -opioid agonists (1 µM DAMGO or 1 µM DPDPE, respectively) to
determine whether these cells expressed either of these opioid receptor
subtypes. An example of an outward current produced by DPDPE in a
biocytin-filled interneuron is shown in Figure 2D.
This cell presumably did not express µ-opioid receptors because an
outward current was not produced by DAMGO (Fig. 2D).
Throughout this study outward currents of 3 pA were considered the
minimum for classification of interneurons as µ- or
-opioid-sensitive. This value was approximately threefold higher
than the baseline noise in our recording apparatus.
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Figure 2.
Physiological characteristics and opioid
sensitivity of a stratum oriens interneuron. A, A camera
lucida reconstruction of an interneuron demonstrating extensive axonal
ramification in stratum radiatum from which the data shown in panels
B-D were obtained. B,
Current records obtained during 2 sec hyperpolarizing voltage steps
from 56 to 136 mV. The large inward current relaxation near the end
of the voltage steps is caused by activation of
Ih. C, Current-voltage
(I-V) relationship demonstrating
the instantaneous ( ) and steady-state ( ) currents obtained at
step potentials between 136 and 56 mV. D, Time
course of opioid-induced outward currents. The horizontal
bars indicate the duration of opioid agonist bath application.
In this example, the -opioid agonist DPDPE (1 µM)
produced an outward current, whereas the µ-opioid agonist DAMGO had
no effect. This illustrates the selectivity of these agonists.
Gaps in the record denote time points of
I-V generation.
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The µ-opioid agonist DAMGO was applied to 44 stratum oriens
interneurons, and 25 (57%) responded with outward currents. The agonist DPDPE was applied to 53 cells, with 32 (60%) demonstrating outward currents. Only 9 of 35 (26%) interneurons displayed outward currents in response to random sequential administration of both agonists (Fig. 2D). The observation that only a small
percentage of cells responded to both agonists supports previous
studies demonstrating the selectivity of these peptide agonists for
their respective opioid receptor subtypes (Mosberg et al., 1983;
Goldstein and Naidu, 1989; Lupica, 1995). Mean outward currents
associated with µ- or -opioid receptor activation observed
in interneurons projecting to each of the four hippocampal strata are
shown in Table 1. These data indicate
that the opioid agonists were equally effective in generating outward
currents and that there was no difference in the magnitude of the
currents generated in cells projecting to different hippocampal strata.
The generation of outward currents by the opioid agonists in these
neurons is consistent with hyperpolarization of the neuronal membrane
and the inhibition of these cells.
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Table 1.
Magnitude of outward currents produced by µ- or
-opioid receptor activation in stratum oriens interneurons,
segregated according to the stratum in which the primary axon arborized
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Opioid receptor expression in interneurons innervating
stratum pyramidale
The µ agonist DAMGO was applied to 11 of 12 cells that
were classified as perisomatic based on the location of their primary axonal ramification within stratum pyramidale. Ten of these cells (91%) responded with robust outward currents (Fig.
3, Table
2), suggesting that the majority of these
neurons expressed µ-opioid receptors. Of the 25 interneurons
demonstrating outward currents with µ-opioid receptor activation, 10 (40%) were classified as providing perisomatic input to the pyramidal
cell body layer. The opioid agonist DPDPE was applied to 9 of the
12 perisomatic cells, and only two (22%) demonstrated outward currents
(Table 2). Furthermore, in contrast to those cells expressing µ receptors, only 2 of the 32 (6%) interneurons responding to the agonist sent axons to stratum pyramidale. Figure 3 illustrates two
perisomatic cells that responded to µ- and not -opioid receptor
activation. Statistical analysis revealed that the difference between
the effects of the µ and agonists on the cells projecting to
stratum pyramidale was significant ( 2 = 27.0;
p < 0.001). Two additional neurons in which axons
could not be recovered possessed somatic and dendritic morphologies very similar to the perisomatic cells shown in Figure 3. Outward currents were also generated by the µ, and not the , agonist in
each of these neurons, but they were not included in the analyzed data
set.
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Figure 3.
Interneurons innervating stratum pyramidale:
morphology and opioid pharmacology. A, Camera lucida
reconstruction of an interneuron with its axonal projection restricted
almost exclusively to stratum pyramidale (same cell as Fig.
1A). The apical dendrites of this cell
(darker structures) extend across stratum radiatum and
into stratum lacunosum-moleculare. The inset at the
right illustrates time course of the DAMGO-induced
outward current. This cell was presumed to express µ and not receptors because an outward current was only generated with DAMGO.
B, Another interneuron with similar morphology to that
shown in A. The inset at the
left shows the time course of the DAMGO-generated
outward current. The lateral extent of the axon in this cell was 1133 µm. Note that this neuron did not respond to the agonist
DPDPE.
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Opioid receptor expression in interneurons innervating stratum
lacunosum-moleculare
The µ-opioid agonist DAMGO was applied to seven cells that
displayed dense primary axonal projections to stratum
lacunosum-moleculare (i.e., OLM or horizontal cells). Three of these
neurons (43%) responded with outward currents, suggesting the
expression of µ-opioid receptors on these cells (Table 2). Overall,
only 3 of the 25 cells (12%) responding to DAMGO displayed these
morphological characteristics. The agonist DPDPE was applied to 15 cells demonstrating OLM cell morphology. Clear outward currents were
observed in 11 (73%) of these neurons. Figure
4 shows reconstructions of OLM cells that
were exposed to the µ and/or the agonist, illustrating outward
currents produced by DPDPE. Statistical analysis revealed that a
significantly greater proportion of these dendritically projecting OLM
cells were sensitive to the - versus the µ-opioid agonist
(2 = 4.5; p < 0.05).
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Figure 4.
Stratum oriens interneurons innervating stratum
lacunosum- moleculare (OLM or horizontal cells): morphology and opioid
pharmacology. A, Camera lucida reconstruction of an
interneuron with its axonal projection almost exclusively in stratum
lacunosum-moleculare. The dendrites of this cell course parallel with
the alveus border and are restricted to stratum oriens. The
inset below illustrates the effect of the -opioid
agonist DPDPE on holding current. In this example, DAMGO failed to
generate an outward current. B, Reconstruction of
another interneuron with its axon ramifying within stratum
lacunosum-moleculare. The inset below shows the time
course of the -opioid agonist-generated outward current.
fiss, Hippocampal fissure.
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Some of the of the OLM cells expressing -opioid receptors possessed
axons that exited the CA1 region, crossed the hippocampal fissure, and
entered the dentate gyrus (Figs. 4B,
5A). In addition, the axon of
the -sensitive cell shown in Figure 5A ramified
extensively in stratum lacunosum-moleculare of CA3. Because cells of
this type may inhibit both CA1 and CA3 pyramidal neurons, they have been labeled "back-projection cells" (Sik et al., 1995). It has been suggested that back-projection cells may differ from more typical
OLM cells by the conspicuous absence of Ih (Sik
et al., 1995), although extensive analysis has not been possible
because of their limited numbers. However, the neuron shown in Figure 5
displayed prominent inward rectification upon hyperpolarization of the
membrane that is indicative of Ih (Fig.
5B). Therefore, at least some presumed back projection
interneurons appear to express these ion channels.
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Figure 5.
A stratum oriens "backprojection" cell
innervating stratum lacunosum-moleculare of hippocampal subfields CA1
and CA3: morphology and physiology. A, A camera lucida
reconstruction of the interneuron. In general, the morphology of this
cell was similar to those shown in Figure 4. Note that the axon of this
cell also crossed the hippocampal fissure and ramified extensively
within stratum lacunosum moleculare of CA3. The inset at
the right illustrates time course of the DPDPE-induced
outward current. The µ-opioid agonist DAMGO had no effect.
B, Current and voltage records obtained in this same
cell. Note the prominent inward "sag" on the current responses at
the most hyperpolarized potentials that is indicative of
Ih. C, A photomicrograph of
the interneuron reconstructed in A. The
arrowhead indicates the location of stratum pyramidale,
and the arrow denotes the border between CA1 and CA3.
Scale bar, 100 µm. fiss, Hippocampal fissure.
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Opioid receptor expression in interneurons innervating
stratum radiatum
The µ agonist DAMGO was applied to 12 interneurons that
possessed axons that arborized, primarily in stratum radiatum. Six (50%) of these neurons responded with outward currents (Table 2). When
the data were analyzed with regard to the total number of cells
expressing µ-opioid receptors projecting to all CA1 layers, it was
found that 24% (6 of 25) of these neurons projected to stratum
radiatum. Similar to µ receptor expression, DPDPE generated outward
currents in 6 of 11 (55%) interneurons that displayed primary axon
arborizations in stratum radiatum (Table 2). Overall, 6 of 32 (19%) of
the total DPDPE-sensitive cells exhibited primary axon innervation of
stratum radiatum. Two reconstructed interneurons within this class are
shown in Figure 6. Each of these neurons generated outward currents in response to DPDPE application, whereas only the interneuron shown in Figure 6A responded to
DAMGO. In addition, the cell shown in Figure 6A
displayed a robust secondary projection within stratum oriens.
Statistical analysis revealed no significant difference in µ- or
-opioid receptor expression in these interneurons with primary axon
projections in stratum radiatum (2 = 0.08;
p > 0.05).
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Figure 6.
Interneurons innervating stratum radiatum:
morphology and opioid pharmacology. A, Camera lucida
reconstruction of an interneuron with its axon projection in strata
radiatum and oriens. After further analysis (counting of axonal branch
points), it was determined that this cell more heavily innervated
stratum radiatum. The inset at the left
illustrates that both -opioid (DPDPE) and µ-opioid (DAMGO)
agonists generated robust outward currents in this cell.
B, Camera lucida reconstruction of an interneuron that
exhibited an axonal projection predominantly confined to stratum
radiatum. The inset at the right illustrates the time
course of the agonist-induced outward current. This cell did not
respond to the µ agonist DAMGO.
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Opioid receptor expression in interneurons innervating
stratum oriens
Many of the neurons demonstrating heavy axonal arborization in
stratum oriens also displayed significant innervation of stratum radiatum (Fig. 7). However, these cells
were classified according to the location of the densest axon
projection. The µ agonist DAMGO was applied to 16 interneurons in
which the primary axon projection was confined to stratum oriens. Only
6 (38%) of these interneurons displayed outward currents meeting the
minimum criterion (Table 1). Overall, 6 of 25 (24%) of all
DAMGO-sensitive cells demonstrated primary axonal arborization within
this cell layer. The agonist DPDPE was applied to 17 interneurons
with primary axon projections within stratum oriens. In contrast to the
µ-sensitive cells, the majority of these neurons (13 of 17, 76%)
demonstrated robust outward currents (Table 2). Of all of the classes
of interneurons expressing -opioid receptors, 13 of 32 (41%)
exhibited this morphology. Statistical analysis revealed a significant
difference in these stratum oriens-projecting interneurons with regard
to µ- or -opioid receptor expression (2 = 7.5;
p < 0.01). These data suggest that interneurons with
somata and primary axonal projections confined to stratum oriens were more likely to express - rather than µ-opioid receptors.
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Figure 7.
Interneurons primarily innervating stratum oriens:
morphology and opioid pharmacology. A, A camera lucida
reconstruction of a stratum oriens interneuron with its primary axonal
projection confined to this layer (same cell as shown in Fig.
1D). Note that the axon does not heavily
innervate stratum pyramidale, yet ramifies in both stratum radiatum and
oriens. This morphological profile is similar to that described for
"bistratified" neurons (Buhl et al., 1994a). The
inset at the right illustrates the time
course of the DAMGO- and DPDPE-induced holding current changes.
Although this interneuron was sensitive to both opioid agonists, only 6 of 16 interneurons responded to the µ agonist, whereas 13 of 17 responded to the -opioid receptor agonist. B,
Reconstruction of a stratum oriens interneuron that demonstrated an
extensive primary axonal projection within stratum oriens. The
inset at the right shows the time course
of the DPDPE-induced outward current in this same cell.
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Taken together, the above results supported the hypothesis that
GABAergic interneurons providing inhibitory input to different areas of
the pyramidal neuron membrane differentially express µ- or -opioid
receptors, as defined by the generation of outward currents. This
suggests that activation of these receptor subtypes can selectively
modulate inhibition impinging on these distinct membrane domains.
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DISCUSSION |
It has become increasingly clear that the location of synaptic
input to different regions of the neuronal membrane can strongly affect
the integrative functions of postsynaptic cells in the CNS (Calloway et
al., 1995; Cobb et al., 1995; Gulyas et al., 1993a; Miles et al., 1996;
Tsubokawa and Ross, 1996). The differential modulation of the activity
of inhibitory neurons providing input to these discrete membrane areas
probably occurs via innervation by select transmitter-containing
afferents and the expression of distinct sets of neurotransmitter
receptors (Freund and Buzsáki, 1996). Consistent with this idea,
the present study provides data to suggest that opioid receptor subtype
expression can distinguish subpopulations of hippocampal interneurons
based on the locations and patterns of their axonal arborizations in
relation to the pyramidal cell membrane. This implies that µ- or
-opioid receptors can reduce the inhibitory input to distinct
regions of the pyramidal neuron, thereby altering the integrative
behavior of these postsynaptic cells.
The segregation of inhibitory neurons based on the location of their
primary axon arbor revealed that those neurons providing perisomatic
input to pyramidal neurons (basket and axo-axonic cells) more
frequently expressed µ-opioid receptors. This was based on the
observation that 91% of those neurons innervating stratum pyramidale
and exposed to the µ agonist DAMGO responded with outward currents.
Conversely, these cells did not appear to abundantly express -opioid
receptors because outward currents were generated in only 22% of the
neurons in response to agonist application. The difference in the
expression of these receptors is even more striking when one considers
that 40% of all of the µ-opioid-sensitive interneurons encountered
in this study demonstrated primary axon arborizations in stratum
pyramidale, whereas only 6% of the -opioid-sensitive cells
innervated this layer. These results suggest that pyramidal neuron
output may be increased by the µ-opioid receptor-mediated decrease in
perisomatic GABAergic inhibition.
The functional significance of the differential targeting of the
postsynaptic membrane by µ- and -opioid receptor-expressing cells
is made clear by studies examining the roles these distinct forms of
inhibition play in modulating the activity of pyramidal neurons. It is
known that inhibitory cells synapsing on the perisomatic region of the
pyramidal neuron can inhibit the generation of
Na+-dependent action potentials (Miles et al., 1996)
and remove the inactivation of inward cation currents, thus permitting
the synchronous rebound firing of pyramidal neurons (Cobb et al.,
1995). Furthermore, since, in the rodent hippocampus, perisomatic cells
synapse on between 1000 and 2500 pyramidal cells, separated by as much
as 1 mm (Li et al., 1992; Buhl et al., 1994a; Sik et al., 1995; Freund and Buzsáki, 1996; Miles et al., 1996; Fig. 3B this
study), synchronization of activity among those pyramidal neurons
likely occurs over this relatively large distance (Cobb et al., 1995;
Whittington et al., 1998). Because µ-opioid receptors appear to be
preferentially expressed on perisomatic interneurons, it is likely that
activation of these receptors will diminish the negative modulation of
Na+ action potentials and reduce the
synchronous activity entrained by these cells. Recent data
demonstrating that µ-, but not -opioid, receptor activation can
disrupt synchronous long-range oscillations in the CA1 area of
hippocampal slices support this assertion (Whittington et al.,
1998).
Another result that might be expected from the reduction of perisomatic
GABAergic input to pyramidal neurons and the desynchronization of their
firing rates is the appearance of epileptiform activity. In experiments
measuring pyramidal neuron excitability using population spikes, the
activation of µ-opioid receptors consistently produced epileptiform
afterdischarges, whereas -opioid receptor activation resulted in
more limited increases in excitability (Wimpey et al., 1989; Lupica and
Dunwiddie, 1991). Furthermore, selective µ-opioid receptor agonists
are known to reduce electrically evoked IPSPs recorded in CA1 pyramidal
neurons, whereas -opioid agonists have no effect on these responses
(Lupica et al., 1992; Watson and Lanthorn, 1993; Lupica, 1995). This
suggests that IPSPs generated by electrical stimulation may be derived
from interneurons providing perisomatic input expressing µ-, and not
-opioid receptors. We hypothesize that the epileptiform activity
observed in pyramidal neurons after µ-opioid receptor activation
reflects the inhibition of interneurons providing global GABAergic
innervation of the somatic pyramidal cell membrane, whereas more
limited increases in excitability generated by receptor activation
are likely caused by a reduction in the dendritic inhibition of
excitatory inputs.
In contrast to the selective innervation of the perisomatic pyramidal
membrane by interneurons expressing µ-opioid receptors, those
inhibitory cells providing input to the dendritic region of the
pyramidal cell were more likely to express -opioid receptors, as
defined by the generation of outward currents by DPDPE. This was true
of the cells innervating the proximal basal dendritic region of stratum
oriens where 76% of the neurons exposed to the agonist
demonstrated outward currents and only 38% were sensitive to
µ-opioid receptor activation. Similarly, those inhibitory cells with
axons targeting the distal apical dendrites of the CA1 pyramidal neurons in stratum lacunosum-moleculare (OLM or horizontal cells) were
also significantly more likely to express , rather than µ-opioid
receptors (73 vs 43%, respectively). This suggests that -opioid
receptors, rather than modulating pyramidal neuron output by regulating
somatic inhibition, may more selectively modulate the excitatory inputs
to these cells by reducing dendritic inhibition.
Interneurons possessing axons targeting the proximal basal and proximal
apical pyramidal neuron dendrites in strata oriens and radiatum have
been referred to as "bistratified cells" (Buhl et al., 1994a, Figs.
6 and 7, this study). The somata of these cells give rise to axons
terminating in parallel with excitatory Schaffer collateral/commissural
afferents on the CA1 pyramidal neuron dendrites. Therefore,
bistratified cells are believed to selectively modulate these
excitatory inputs. This suggests that inhibition of bistratified neuron
activity by -, and to a lesser degree µ-opioid, receptor
activation, would facilitate these excitatory inputs impinging on the
pyramidal neuron proximal dendrites. Furthermore, because the pyramidal
neuron IPSPs elicited by bistratified cell activation are significantly
slower to rise and decay, when compared with perisomatic cells (Buhl et
al., 1994a), these neurons may selectively modulate the slower
excitatory currents derived from NMDA receptor activation. In this way
the opioid-mediated inhibition of bistratified cell activity may
facilitate this excitatory input and the synaptic plasticity associated
with NMDA receptor activation, as demonstrated in lateral perforant
path long-term potentiation (Xie and Lewis, 1991).
In contrast to the relative paucity of knowledge of bistratified cell
function, the role that the OLM interneurons play in modulating
pyramidal neuron excitability is becoming increasingly clear. OLM cells
are activated via excitatory inputs from pyramidal neuron recurrent
collateral axons (Lacaille et al., 1987; Blasco-Ibanez and Freund,
1995; Maccaferri and McBain, 1995; Ali and Thomson, 1998), and they
selectively innervate the distal apical dendrites of the pyramidal
cells. Here the inhibitory OLM terminals overlap with excitatory
terminals originating from cells in the entorhinal cortex and the
thalamus (Gulyas et al., 1993b; Desmond et al., 1994; Sik et al., 1995;
Yanovsky et al., 1997). These neurons are considered "feedback" or
recurrent inhibitory cells because they are only activated after CA1
pyramidal neuron discharge. The activation of OLM neurons via
antidromic stimulation of pyramidal neurons axons can inhibit the EPSPs
recorded extracellularly in stratum lacunosum-moleculare after the
stimulation of the entorhinal cortex pathway (Maccaferri and McBain,
1995). This inhibition of entorhinal input to CA1 was also found to be
selective, because EPSPs generated by stimulation of stratum radiatum
were not affected by OLM neuron activation. These data suggest that,
when activated, the OLM cells may selectively reduce the excitatory
drive from entorhinal cortex to CA1, thus facilitating the flow of
information through the classic trisynaptic hippocampal circuit
(Macafferri and McBain, 1995; Ali and Thomson, 1998). Conversely, the
inhibition of OLM neurons by -opioid receptor activation, or
long-term synaptic depression (LTD, Macafferri and McBain, 1995), would
likely result in enhanced entorhinal EPSPs in the pyramidal neurons and
the diversion of information flow through the direct entorhinal
circuit. In this way, -opioid receptor activation may provide a
means through which CA1 pyramidal neurons can receive either
entorhinal- or CA3-derived synaptic information.
Together our data suggest that the differential expression of opioid
receptor subtypes on interneurons that provide segregated inhibitory
inputs to the pyramidal cell membrane may constitute a means to permit
the independent regulation of these projections. Thus, interneurons
that were inhibited by µ-opioid receptor activation innervated
stratum pyramidale more frequently than -opioid-sensitive cells, and
therefore, would be more likely to facilitate pyramidal neuron output.
In contrast, interneurons inhibited by -opioid receptor activation
were more likely to innervate the basal and apical dendritic pyramidal
neuron membrane, suggesting a role for these receptors in the
regulation of afferent signaling. However, a complete understanding of
the significance of these findings awaits identification of the
conditions through which opioid peptides are released and processed
into subtype selective agonists. Our data also more generally imply
that hippocampal interneurons can be segregated not only according to
morphological and neurochemical criteria, but also according to the
expression of subtypes of neurotransmitter receptors. Because the
hippocampal interneurons can influence the properties of large
populations of principal cells, the differential activation of opioid
receptor subtypes may provide a substrate on which the integrative
properties of these cells can be changed to accommodate specific
computational processes within this brain region.
| |
FOOTNOTES |
Received Aug. 9, 1998; revised Oct. 15, 1998; accepted Oct. 20, 1998.
This work was supported by National Institutes of Health Grants DA
07725 and MH 44212, United States Public Health Service.
Correspondence should be addressed to Dr. Carl R. Lupica, National
Institute on Drug Abuse, Intramural Research Program, 5500 Nathan Shock
Drive, Baltimore, MD 21224.
| |
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J. T. Williams, M. J. Christie, and O. Manzoni
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M. Alkondon, E. F. R. Pereira, H. M. Eisenberg, and E. X. Albuquerque
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K. D. Dougherty and T. A. Milner
Cholinergic Septal Afferent Terminals Preferentially Contact Neuropeptide Y-Containing Interneurons Compared to Parvalbumin-Containing Interneurons in the Rat Dentate Gyrus
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Top
Abstract
Introduction
