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The Journal of Neuroscience, August 1, 2002, 22(15):6724-6731
Partial Peripheral Nerve Injury Promotes a Selective Loss of
GABAergic Inhibition in the Superficial Dorsal Horn of the Spinal
Cord
Kimberly A.
Moore*,
Tatsuro
Kohno*,
Laurie A.
Karchewski,
Joachim
Scholz,
Hiroshi
Baba, and
Clifford J.
Woolf
Neural Plasticity Research Group, Department of Anesthesia and
Critical Care, Massachusetts General Hospital and Harvard Medical
School, Charlestown, Massachusetts 02129
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ABSTRACT |
To clarify whether inhibitory transmission in the superficial
dorsal horn of the spinal cord is reduced after peripheral nerve injury, we have studied synaptic transmission in lamina II neurons of
an isolated adult rat spinal cord slice preparation after complete sciatic nerve transection (SNT), chronic constriction injury (CCI), or
spared nerve injury (SNI). Fast excitatory transmission remains intact
after all three types of nerve injury. In contrast, primary afferent-evoked IPSCs are substantially reduced in incidence, magnitude, and duration after the two partial nerve injuries, CCI and
SNI, but not SNT. Pharmacologically isolated GABAA
receptor-mediated IPSCs are decreased in the two partial nerve injury
models compared with naive animals. An analysis of unitary IPSCs
suggests that presynaptic GABA release is reduced after CCI and SNI.
Partial nerve injury also decreases dorsal horn levels of the GABA
synthesizing enzyme glutamic acid decarboxylase (GAD) 65 kDa
ipsilateral to the injury and induces neuronal apoptosis,
detected by terminal deoxynucleotidyl transferase-mediated biotinylated
UTP nick end labeling staining in identified neurons. Both of these
mechanisms could reduce presynaptic GABA levels and promote a
functional loss of GABAergic transmission in the superficial dorsal horn.
Key words:
neuropathic pain; GAD; CCI; SNI; cell death; disinhibition
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INTRODUCTION |
By modulating both synaptic inflow
and dorsal horn neuronal excitability, presynaptic and postsynaptic
inhibition regulates the transfer of information from the periphery to
the CNS. Reduction or elimination of spinal cord inhibition could be
expected, therefore, to augment sensory and motor responses to certain
signals from the periphery and could play a role in generating
pathological excitability. One example of pathological excitation in
the somatosensory system is the spontaneous pain and tactile
hypersensitivity that can follow peripheral nerve injury. Multiple
mechanisms appear to be responsible for this injury-induced pain,
including ectopic activity in primary afferents, induction of central
sensitization in the dorsal horn in response to such inputs, and
sprouting of the central terminals of large myelinated primary
afferents (Devor and Seltzer, 1999 ; Woolf and Mannion, 1999). Another
mechanism that has been proposed to contribute to neuropathic pain is
peripheral nerve injury-induced loss of inhibition in the spinal cord
(Bennett et al., 1989; Dubner, 1991). Indirect evidence suggests that
peripheral nerve injury promotes a loss of inhibitory transmission in
the spinal cord (Moore et al., 2001). Dorsal root potentials and
primary afferent depolarization, indicators of presynaptic inhibition at the central terminals of low-threshold myelinated fibers, are diminished after complete sciatic nerve axotomy (Wall and Devor, 1981).
Similarly, large A-fiber-mediated inhibition of C-fiber-evoked responses in dorsal horn neurons is also diminished (Woolf and Wall,
1982). Furthermore, reduced levels of GABA (Castro-Lopes et al., 1993;
Ibuki et al., 1997; Eaton et al., 1998) and its receptors (Bhisitkul et
al., 1990; Castro-Lopes et al., 1995) have been reported after axotomy
and chronic constriction injury (CCI) of the sciatic nerve, as have
indications of degenerative changes in the superficial dorsal horn
(Sugimoto et al., 1990). What has not been established, however, is
whether there is any nerve injury-induced loss of inhibition in the
superficial dorsal horn, the site of termination of small caliber
primary afferents, and whether such a loss results from diminished
presynaptic or postsynaptic inhibition.
To investigate this, primary afferent-evoked EPSCs and IPSCs,
respectively, have been analyzed in lamina II neurons of an isolated
adult rat spinal cord preparation with an attached dorsal root. The
primary afferent-evoked currents in lamina II neurons were recorded in
slices from naive rats and after three types of peripheral nerve
injury, complete sciatic nerve transection (SNT), CCI (Bennett and Xie,
1988), and spared nerve injury (SNI) (Decosterd and Woolf, 2000).
Although excitatory transmission remained intact in all three models,
GABAergic inhibition was markedly reduced in the two partial peripheral
nerve injury models, CCI and SNI.
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MATERIALS AND METHODS |
Peripheral nerve injury models. Adult male Sprague
Dawley rats were anesthetized with halothane (2.5%), and the left
sciatic nerve was exposed. For complete SNT, the sciatic nerve was
ligated and severed in the popliteal fossa. For CCI, four 4-0 chromic gut sutures spaced ~1 mm apart were tied loosely around the sciatic nerve proximal to the trifurcation (Bennett and Xie, 1988). For SNI,
the tibial and common peroneal nerves were tightly ligated with 5-0 silk and sectioned distal to the ligation (Decosterd and Woolf, 2000).
Rats were allowed to recover in their normal environment for ~2 weeks
after injury.
Spinal cord slice preparation and electrophysiological
recording. Under urethane anesthesia (1.5 gm/kg, i.p.), the lumbar spinal cord was removed from nerve-injured rats (2 weeks after injury)
or age-matched naive adults and placed in preoxygenated ice-cold
Krebs' solution (composition in mM: NaCl 117, KCl 3.6, CaCl2 2.5, MgCl2
1.2, NaH2PO4 1.2, NaHCO3 25, and glucose 11). The pia arachnoid
membrane as well as all ventral and dorsal roots, except the L4 dorsal
root ipsilateral to the injury, were removed before cutting a
650-µm-thick transverse slice with the L4 dorsal root (10-20 mm)
intact (Yoshimura and Nishi, 1993; Kohno et al., 1999). The slice was
placed on a nylon mesh in the recording chamber and perfused with
Krebs' solution for at least 30 min before recording.
For whole-cell recording, the resistance of patch pipettes was 5-10
M when filled with internal solution (composition in mM:
Cs2SO4 110, CaCl2 0.5, MgCl2 2, EGTA 5, HEPES 5, TEA 5, ATP-Mg salt 5). Electrodes were positioned in lamina
II, which is identifiable as a distinct translucent band across the
superficial dorsal horn under a dissecting microscope with transmitted
illumination. Placing the electrode in such a manner targets a
heterogeneous group of intrinsic stalk and islet neurons in inner and
outer lamina II (Baba et al., 1999). Graded intensity dorsal root
stimulation sufficient to recruit A , A , and C-fibers was applied
with a suction electrode linked to a constant current stimulator, and evoked EPSCs and IPSCs were recorded in lamina II neurons voltage clamped to  70 or 0 mV, respectively. EPSCs were classified as monosynaptic if response latency remained constant with high-frequency (20 Hz) stimulation. Synaptic currents were amplified using an Axopatch
200A (Axon Instruments). Signals were filtered at 2 kHz and digitized
at 5 kHz. Data were collected using pCLAMP (Axon Instruments) and
analyzed using pCLAMP and Mini-analysis software (Synaptosoft).
Western blots. The ipsilateral L4 dorsal horn from naive,
CCI, and SNI rats was homogenized in lysis buffer to yield a
concentration of 40 µg/µl. Proteins were separated on 4-15% SDS
gradient polyacrylamide gels and then transferred to nitrocellulose
membranes (Immobilon-P, Millipore). Membranes were incubated with mouse
anti-glutamic acid decarboxylase (GAD) 65 kDa (1:2000; Chemicon)
(Chang and Gottlieb, 1988) or rabbit anti-GAD67 (1:4000; Chemicon)
(Kaufman et al., 1991), followed by horseradish peroxidase
(HRP)-conjugated goat anti-mouse (1:15,000; Jackson Laboratories) or
donkey anti-rabbit (1:2000; Amersham). Proteins were detected with the
enhanced chemiluminescence system (NEN), and then membranes were
stripped and reprobed with rabbit anti-p42 MAP kinase (ERK42) as a
loading control. Molecular weight markers were used to confirm that the
size of GAD65, GAD67, and ERK42 bands were consistent with their
predicted sizes. Band intensity was measured densitometrically using
NIH Image, normalized to ERK42 levels, and expressed as a percentage of
naive. Because ERK42 expression is unaffected by partial peripheral
nerve injury (R. R. Ji and C. J. Woolf, personal communication),
it is a suitable loading control for comparing GAD expression in naive
and injured rats.
Immunohistochemistry. After perfusion with Zamboni's
fixative (2% paraformaldehyde and 15% picric acid in 0.1 M phosphate buffer, pH 7.4), spinal cord samples
were collected from naive and nerve-injured rats. Samples were
postfixed for 2 hr, cryoprotected overnight (20% sucrose in PBS),
embedded in OCT compound, and frozen. Cryostat sections (20 µm) were
thaw mounted onto cold Superfrost microscope slides (Fisher). Sections
were incubated overnight at 4°C with mouse anti-GAD65 (1:1000),
rabbit anti-GAD67 (1:1000), or mouse anti-GABAA receptor
2/3 subunit [1:20; Boehringer Mannheim; this antibody should
detect most dorsal horn GABAA receptors (Alvarez et al.,
1996)], followed by secondary antibody, anti-rabbit FITC, or
anti-mouse FITC (1:200; Vector) for 1 hr at room temperature. Fluorescent images were captured using a SPOT camera (Diagnostic Instruments Inc.), and staining intensity was measured using IPLab Image Analysis software (Scanalytics Inc.). Data were normalized to naive.
Detection of apoptosis. Triple fluorescent staining using
terminal deoxynucleotidyl transferase-mediated biotinylated UTP nick
end labeling (TUNEL), bisbenzimide (Hoechst 33342), and neuronal nuclei
(NeuN) immunohistochemistry was performed as described (Lewis et
al., 1999) on 10 randomly selected 10 µm transverse sections of the
L4 segment of the dorsal horn from six animals 7 d after SNI.
Data analysis. Data are expressed as mean ± SEM.
Student's paired and unpaired t test and the z
test were used where appropriate. p < 0.05 was
considered significant.
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RESULTS |
Peripheral nerve injury (CCI, SNI, or SNT) does not reduce
primary afferent-evoked EPSCs in lamina II neurons
In the L4 segment of spinal cord slices from naive adult rats, all
lamina II neurons studied had either A- or C-fiber-evoked fast EPSCs
(n = 83). Such primary afferent-evoked excitatory
responses remained present in all neurons studied after partial (CCI,
n = 57; SNI, n = 46) or complete (SNT,
n = 34) sciatic nerve lesions (Fig.
1A). Although the
activation threshold for A-fiber responses was shifted after nerve
injury (naive = 32 ± 2 µA, n = 81;
SNT = 22 ± 2 µA, n = 32, p < 0.0001; CCI = 23 ± 2 µA, n = 54, p = 0.0003; SNI = 49 ± 4 µA,
n = 37, p < 0.0001), when A and
A fibers were fully activated (100 µA, 0.05 msec), EPSC amplitudes
were similar in all four populations (Table
1). Furthermore, the resting membrane
potential was not affected by any of the sciatic nerve injuries (Table
1).
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Figure 1.
Partial peripheral nerve injury (CCI or SNI)
reduces primary afferent-evoked IPSCs in lamina II neurons.
A, Representative neuron from a CCI animal with a
monosynaptic A-fiber-evoked EPSC but no evoked IPSC. After CCI or
SNI, excitatory transmission remains intact, but the proportion of
neurons with no evoked IPSC increases (Naive = 1/65; SNT = 3/32, p = 0.20;
CCI = 7/41, p = 0.006;
SNI = 9/32, p < 0.0001).
*p < 0.05 compared with naive. B,
Representative A-fiber-evoked IPSCs recorded in spinal cord slices from
naive, CCI, and SNI rats. Note the reduction in amplitude and duration
in CCI and SNI traces. C,
Amplitude distributions for IPSCs recorded from naive rats and rats
subjected to SNT, CCI, or SNI. In both partial nerve injury models,
IPSC amplitudes were significantly decreased compared with the naive.
Arrows indicate means. D, Frequency
distributions of IPSC decay time constants ( ) from naive and
nerve-injured rats, as well as pharmacologically isolated glycine
(insensitive to 5-10 µM bicuculline;
n = 18) and GABAA (bicuculline
sensitive; n = 16) IPSCs.
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Table 1.
EPSC amplitudes and resting membrane potentials (RMP) in
lamina II neurons from naive and nerve-injured rats
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Partial peripheral nerve injury (CCI or SNI) reduces primary
afferent-evoked IPSCs in lamina II neurons
In contrast to excitatory transmission that remains intact after
nerve injury, the proportion of superficial dorsal horn neurons with
primary afferent-evoked IPSCs was significantly decreased by 17% after
CCI and by 28% after SNI (Fig. 1A). Moreover, the IPSCs remaining in CCI and SNI animals were significantly reduced in
both amplitude and duration (Fig. 1B-D,
Table 2). Complete sciatic nerve section
had no detectable effect on inhibitory synaptic transmission in lamina
II of the dorsal horn. The proportion of SNT neurons with IPSCs (Fig.
1A) did not differ from naive, nor did IPSC
amplitudes and kinetics (Fig. 1C,D, Table 2). In
the CCI group, those cells with no primary afferent-evoked IPSCs were further analyzed to determine whether they had spontaneous IPSCs (sIPSCs). In this subgroup of neurons, sIPSCs were present and of
normal amplitude, but their frequency was reduced 2.4 ± 0.4 Hz
(n = 5) compared with that found in neurons with evoked
IPSCs (4.7 ± 1.3 Hz; n = 5).
Selective loss of GABAA receptor-mediated IPSCs in CCI
and SNI models
Multiple inhibitory inputs converge on dorsal horn neurons, and
some inhibitory interneurons in lamina II coexpress GABA and glycine
(Todd and Sullivan, 1990). Therefore, coapplication of both bicuculline
(BCC) (5-10 µM; a GABAA receptor antagonist) and strychnine (0.5 µM; a glycine receptor antagonist)
was required to completely block primary afferent-evoked IPSCs in
lamina II neurons from naive rats (Fig.
2A). The kinetics of
the GABAA and glycine receptor-mediated IPSCs differed
considerably, however. Glycine IPSCs, isolated by BCC to block
GABAA receptors, were short lasting, peaking at 4.8 ± 0.6 msec (n = 9) and decaying with a time constant
() of 9.2 ± 0.8 msec (n = 18) (Fig.
1D). GABAA IPSCs, isolated by strychnine
to block glycine receptors, had a slower time to peak (6.9 ± 0.8 msec; n = 13) and decayed with a longer (30.8 ± 3.2 msec; n = 16) (Fig. 1D).
Although ~80% of IPSCs in naive slices had both GABAA-
and glycine-mediated components, the predominant influence was
GABAA receptor-mediated, as shown by both the kinetics
(Fig. 1D) and the high sensitivity of these composite
IPSCs to BCC (Fig. 2A). After partial, but not
complete, sciatic nerve injury, the IPSC kinetics shifted closer to
those resembling pure glycinergic currents (Fig. 1D), and the BCC-sensitive (GABAA) component was reduced
significantly (Fig. 2A,B).
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Figure 2.
Selective loss of GABAA IPSCs in CCI
and SNI models. A, In naive neurons, the
GABAA receptor antagonist bicuculline (5-10
µM) blocked a large fraction of the primary
afferent-evoked IPSC (n = 14). However, after CCI
(n = 13) or SNI (n = 7),
bicuculline had little effect. Coapplication of bicuculline and
strychnine (0.5 µM) reduced IPSCs to 4.3 ± 1.1 pA
(n = 19). B, The amplitude of the
GABAA component, but not the glycine component, of evoked
IPSCs was significantly reduced after CCI (p = 0.014) or SNI (p = 0.002), but not SNT
(p = 0.745). Numbers of
neurons are indicated in parentheses. p < 0.05 compared with naive.
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Reduced GABA release accounts for the loss of inhibition
To determine whether presynaptic or postsynaptic factors
are responsible for the attenuation of the GABAA
receptor-mediated inhibition in lamina II neurons, the
frequency and amplitude of sIPSCs and miniature IPSCs, respectively,
were investigated. The overall frequency of sIPSCs was not
significantly affected by CCI or SNI, but the frequency of the
strychnine-insensitive, GABAA receptor-mediated sIPSCs was
significantly reduced by both partial nerve injuries (Table
3), consistent with a presynaptic locus for the loss of inhibition. In contrast, the frequency of
BCC-insensitive, glycine receptor-mediated sIPSCs was unaffected by CCI
or SNI, as were the amplitude distributions of both GABAA
and glycine sIPSCs (Table 3). A reduction in GABAA
receptor-mediated sIPSC frequency, in the absence of an effect on sIPSC
amplitude, reflects either a loss of action potential-driven synaptic
currents or diminished activity-independent (miniature) synaptic
release. Analysis of miniature GABAA receptor-mediated
IPSCs revealed a decrease in frequency, but not amplitude, after CCI or
SNI (Fig. 3), consistent with diminished
presynaptic GABA release.
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Figure 3.
GABA transmission is reduced by a presynaptic
mechanism after partial nerve injury. The frequency of miniature
GABAA IPSCs (recorded in the presence of 0.5 µM TTX and 0.5 µM strychnine) was
significantly decreased from 4.0 ± 0.3 Hz (n = 5) in naive slices to 2.2 ± 0.5 Hz (n = 8;
p = 0.024) in CCI slices and 2.0 ± 0.6 Hz
(n = 6; p = 0.020) in SNI
slices. The amplitude of miniature GABAA IPSCs was
unaffected by partial nerve injury (Naive = 11.7 ± 1.8 pA; CCI = 10.5 ± 0.6 pA;
SNI = 13.8 ± 2.3 pA). p < 0.05 compared with naive.
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Partial nerve injury reduces GAD65 levels
Western blot analysis of the two isoforms of the GABA synthesizing
enzyme, GAD65 and GAD67, revealed a small (20-40%), but significant,
decrease in GAD65 protein levels after both CCI and SNI. In contrast,
GAD67 was generally unaffected (Fig. 4).
Immunohistochemical analysis revealed that GAD65 was downregulated
throughout the ipsilateral dorsal horn (laminas I-IV) (Fig.
4B); however, no reduction was observed in the
contralateral dorsal horn (Fig. 4B), implying that
reduced GABA release may be a general feature in all laminas of the
dorsal horn ipsilateral, but not contralateral, to the lesion.
Furthermore, Western blotting demonstrates that GAD65 downregulation
was time dependent. In CCI rats, GAD65 levels drop within 6 d of
injury and slowly return to baseline within 4 weeks of the injury (Fig.
4A). In SNI rats, GAD65 also falls within 6 d of
injury, but in contrast to CCI rats, it remains depressed at 4 weeks
(Fig. 4A).
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Figure 4.
Partial nerve injury reduces GAD65 levels and
induces neuronal apoptosis. A, The 65 kDa, but not the
67 kDa, isoform of GAD was reduced in the lumbar (L4) dorsal
horn ipsilateral to CCI or SNI when measured by Western blotting. The
graph shows the time course of regulation. Data are
normalized to ERK42 and expressed as a percentage of naive.
*p < 0.05 compared with naive. B,
Immunohistochemical analysis revealed diminished GAD65 levels in the
ipsilateral dorsal horn (laminas I-IV) 2 weeks after CCI
(n = 46 sections from 4 rats; p < 0.0001) and SNI (n = 31 sections from 6 rats;
p < 0.0001). A small decrease in the levels of
GAD67 was detectable after CCI (n = 52 sections
from 4 rats; p = 0.002). Scale bar, 100 µm.
*p < 0.05 compared with naive. C,
TUNEL (green) and chromatin staining with
bisbenzimide (blue), combined with immunostaining for
the neuronal marker NeuN (red), revealed apoptotic cell
death in the superficial dorsal horn of spinal cord segment L4 1 week
after SNI. The top row shows a section through the
ipsilateral dorsal horn with TUNEL-positive cells in laminas I and II
(arrowheads). An example of neuronal apoptosis in lamina
II is given below. Arrows point to a TUNEL-positive
neuron with condensed chromatin structure, indicating nuclear
pyknosis.
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Neuronal death occurs in the dorsal horn after partial peripheral
nerve injury
A reduction in the releasable GABA pool, reflected by the
diminution of both miniature GABAA IPSC frequency (Fig. 3)
and evoked IPSC amplitude (Figs. 1, 2), might reflect decreased GABA
production within the axon terminals of GABAergic interneurons
attributable to GAD65 downregulation (Fig.
4A). Alternatively, or additionally, it could also
reflect selective degeneration of this population of inhibitory
interneurons resulting from excitotoxic cell death induced by excessive
nerve discharge at the time of the injury (Sugimoto et al., 1990).
Although no significant loss of neurons is observed in lamina II after
a complete sciatic nerve section (Coggeshall et al., 2001),
TUNEL-positive profiles indicative of apoptosis peak within 1 week
after CCI (Whiteside and Munglani, 2001). The extent to which these
profiles represent neurons or glia is unclear. We have now found
TUNEL-positive profiles with pyknotic nuclei, detected by chromatin
staining, in the L4 segment of the dorsal horn 7 d after an SNI
lesion (1.48 ± 0.08 profiles per 10 µm section). Many of the
TUNEL-positive profiles were located in the superficial dorsal horn and
were not stained by NeuN, a specific neuronal marker. Nevertheless,
apoptotic neuronal (TUNEL-positive/NeuN-positive) profiles were found
in laminas I and II after SNI (0.16 ± 0.03 profiles per 10 µm
section) (Fig. 4C). The non-NeuN-stained population may
represent dying non-neuronal cells or neurons that have lost NeuN immunoreactivity.
GABAA receptors remain intact after CCI and SNI
In addition to changes in GABA release, dynamic regulation of
GABAA receptor density might contribute to spinal
disinhibition. The analysis of miniature GABAA IPSCs
showing a reduction in frequency, but not amplitude (Fig. 3), suggests
that synaptic GABAA receptors remain present and functional
after both partial nerve injuries. Immunohistochemistry confirmed that
GABAA receptor expression was not decreased after either
partial nerve injury (Fig. 5).
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Figure 5.
GABAA receptors remain after partial
nerve injury. Immunohistochemical analysis for GABAA
receptor in the lumbar dorsal horn revealed a small upregulation after
CCI (n = 27 sections from 3 rats;
p = 0.031) but not SNI (n = 55 sections from 6 rats). Scale bar, 100 µm. Data are expressed as a
percentage of naive. p < 0.05 compared with
naive.
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DISCUSSION |
We have found a loss of postsynaptic GABAA
receptor-mediated inhibition in the superficial dorsal horn in two
different partial peripheral nerve injury models. Because similar
changes did not occur after a complete section of the sciatic nerve, it
appears that some intact input is required for the loss of inhibition to occur. After either CCI or SNI nerve lesion, GABAergic inhibitory transmission in lamina II neurons was diminished, whereas glycinergic transmission remained mostly intact. Most IPSCs observed in slices from
naive rats had both GABAA- and glycine receptor-mediated components. However, the duration of the GABAA IPSCs was up
to three times longer than that of the glycine IPSCs, suggesting that
the GABAA component may normally play a more critical role in limiting neuronal firing frequency and controlling long latency or
polysynaptic inputs to the dorsal horn. Therefore, a loss of GABAergic
postsynaptic inhibition might be expected to amplify excitatory
responses of lamina II neurons to afferent inputs. The overall
functional significance for sensory processing in the spinal cord will
depend on whether similar changes also occur in other dorsal horn
laminas, as well as the connectivity and transmitter content of the
affected lamina II neurons, a heterogeneous population that may include
excitatory and inhibitory interneurons.
After either CCI or SNI, GABAA receptors remained present,
but unitary GABA release was significantly decreased, suggesting that
presynaptic, rather than postsynaptic, changes account for the loss of
GABAergic inhibition in lamina II. GABA synthesis relies on two GAD
isoforms, GAD65 and GAD67, each of which is encoded by a distinct,
differentially regulated gene. GAD isoforms are commonly coexpressed in
GABAergic interneurons; however, GAD67 is primarily cytosolic,
localized to neuronal cell bodies and dendrites, whereas GAD65 is
preferentially targeted to membranes and nerve endings where it may
preferentially synthesize GABA for vesicular release (Soghomonian and
Martin, 1998). Our immunohistochemical analysis illustrates a
differential distribution pattern for the two isoforms. Further studies
will be required to determine whether these isoforms are coexpressed in
the same neurons in the dorsal horn.
In both partial nerve injury models, GAD65 protein levels declined
significantly in all laminas of the ipsilateral dorsal horn [see also
Eaton et al. (1998)]. This decrease may reflect reduced
transcription/translation of GAD65 and a loss of GABAergic interneurons
caused by cell death. Relative to GAD65, GAD67 is generally maintained
after partial peripheral nerve injury, although some loss may occur
after CCI. Several possible explanations could account for the
selective diminution of GAD65. GABAergic interneurons may undergo
apoptosis, leading to loss of both GAD65 and GAD67 followed by
compensatory upregulation of GAD67, but not GAD65, in those
interneurons that survive (Dumoulin et al., 1996). Alternatively, if
the two isozymes are not expressed in the same neurons, death of those
interneurons that express GAD65 with survival of those that express
GAD67 could account for the selective attenuation of GAD65. Finally,
GAD65 may be downregulated in response to partial peripheral nerve
injury independent of cell death. Reduction of GAD65 may be one of
several transient mechanisms that contribute to the early/intermediate
phases of hyperalgesia that follow nerve injury. Early changes in the
dorsal horn (e.g., reduced inhibition caused by reduced GABA synthesis)
and in primary afferent physiology (e.g., ectopic discharge in injured
and neighboring noninjured sensory fibers) might help to set the stage
for mechanisms that underlie the persistent phases of nerve
injury-induced pain hypersensitivity, such as death of inhibitory interneurons.
After SNT, where we failed to detect a loss of inhibition, there is
also an absence of neuronal loss in lamina II, as demonstrated recently
by unbiased stereological counts in electron microscopic sections
(Coggeshall et al., 2001). In contrast, after CCI, TUNEL-positive cells
indicating apoptosis have been identified in the ipsilateral dorsal
horn, although the cell type (i.e., whether they represent neurons or
not) was not specified (Whiteside and Munglani, 2001). We have now
found that apoptosis also occurs in the superficial dorsal horn after
SNI, and although most of the profiles do not express the neuronal
marker NeuN, positively identified apoptotic neurons were observed. It
is uncertain, however, whether this includes GABAergic interneurons,
because immunoreactivity may be lost as cells die. The number and
nature of neurons that are lost after partial nerve injury require
further investigation.
Diminished GABA release will reduce both presynaptic (influencing
synaptic inflow) and postsynaptic (modulating dorsal horn neuron
excitability) GABAA receptor-mediated inhibition, as well as GABAB receptor-mediated inhibition. Here, we
have demonstrated a decrease in GABAA receptor-mediated
postsynaptic inhibition. Earlier studies have reported that primary
afferent depolarization and dorsal root potentials, indirect indicators
of presynaptic inhibition, are reduced in large A-fibers after complete
sciatic nerve axotomy (Wall and Devor, 1981). It is highly probable
from our findings that GABA-mediated presynaptic inhibition of A- and C-fiber nociceptors that terminate in the superficial dorsal horn
will also be reduced after partial peripheral nerve injury as a result
of the reduction in the releasable GABA pool.
GABAergic transmission to lamina II neurons was reduced after two
distinct partial peripheral nerve lesions, CCI and SNI, both of which
generate marked pain hypersensitivity. Pharmacological antagonism of
GABAergic and glycinergic inhibitory transmission in the spinal cord in
normal animals also generates a neuropathic pain-like tactile
hypersensitivity (Yaksh, 1989; Sivilotti and Woolf, 1994;
Khandwala et al., 1997). These two observations raise the key question:
does diminished inhibitory transmission in the dorsal horn contribute
to heightened pain sensitivity after partial nerve injury? Although it
is not yet possible to answer this definitively, therapeutic
implications for patients could be substantial. To increase efficacy,
neuropathic pain management may need to include treatment directed at
preventing a loss of endogenous inhibitory control systems or
augmenting those that remain.
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FOOTNOTES |
Received Feb. 13, 2002; revised April 29, 2002; accepted May 1, 2002.
*
K.A.M. and T.K. contributed equally to this work.
This work was supported by National Institutes of Health (NIH) Grant
R01, National Institute of Neurological Disorders and Stroke Grant
NS38253-01 (C.J.W.), NIH National Research Service Award NS11076-01
(K.A.M.), and Alexander von Humboldt Foundation Grant V-3FLF-DEU/106
9701 (J.S.). We thank Drs. Katia Befort and Keiko Mizuno for
technical advice.
Correspondence should be addressed to Dr. Tatsuro Kohno, Neural
Plasticity Research Group, Department of Anesthesia and Critical Care,
Massachusetts General Hospital and Harvard Medical School, 149 13th
Street, Charlestown, MA 02129. E-mail:
Kohno{at}helix.mgh.harvard.edu.
K. A. Moore's present address: Department of Cellular and
Molecular Pharmacology, University of California San Francisco, San
Francisco, CA 94143-0450.
H. Baba's present address: Department of Anesthesiology, Niigata
University School of Medicine, Niigata, 951-8510, Japan.
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TOP
ABSTRACT
INTRODUCTION
Compound via MeSH
