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The Journal of Neuroscience, December 15, 2001, 21(24):9529-9540
M Channel KCNQ2 Subunits Are Localized to Key Sites for
Control of Neuronal Network Oscillations and Synchronization in Mouse
Brain
Edward C.
Cooper1, 2,
Emily
Harrington1,
Yuh Nung
Jan2, 3, 4, and
Lily Y.
Jan2, 3, 4
Departments of 1 Neurology, 2 Physiology,
and 3 Biochemistry and 4 Howard Hughes Medical
Institute, University of California, San Francisco, San Francisco,
California 94143-0725
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ABSTRACT |
Mutations in the potassium channel subunit KCNQ2 lead to benign
familial neonatal convulsions, a dominantly inherited form of
generalized epilepsy. In heterologous cells, KCNQ2 expression yields
voltage-gated potassium channels that activate slowly ( , ~0.1 sec)
at subthreshold membrane potentials. KCNQ2 associates with KCNQ3, a
homolog, to form heteromeric channels responsible for the M current
(IM) in superior cervical ganglion
(SCG) neurons. Muscarinic acetylcholine and peptidergic receptors
inhibit SCG IM, causing slow EPSPs
and enhancing excitability. Here, we use KCNQ2N antibodies, directed
against a conserved N-terminal portion of the KCNQ2 polypeptide, to
localize KCNQ2-containing channels throughout mouse brain. We show that
KCNQ2N immunoreactivity, although widespread, is particularly
concentrated at key sites for control of rhythmic neuronal activity and
synchronization. In the basal ganglia, we find KCNQ2N immunoreactivity
on somata of dopaminergic and parvalbumin (PV)-positive (presumed
GABAergic) cells of the substantia nigra, cholinergic large aspiny
neurons of the striatum, and GABAergic and cholinergic neurons of the globus pallidus. In the septum, GABAergic, purinergic, and cholinergic neurons that contribute to the septohippocampal and septohabenular pathways exhibit somatic KCNQ2 labeling. In the thalamus, GABAergic nucleus reticularis neurons that regulate thalamocortical oscillations show strong labeling. In the hippocampus, many PV-positive and additional PV-negative interneurons exhibit strong somatic staining, but labeling of pyramidal and dentate granule somata is weak. There is
strong neuropil staining in many regions. In some instances, notably
the hippocampal mossy fibers, evidence indicates this neuropil staining
is presynaptic.
Key words:
M current; acetylcholine; epilepsy; benign familial
neonatal convulsions; channelopathy; neuromodulation; voltage-gated
potassium channel
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INTRODUCTION |
Genetic studies have revealed a new
family of potassium channels called KCNQ channels that play key roles
in heart, brain, and other tissues. Mutations in KCNQ1 cause hereditary
long-QT syndrome, a cardiovascular disorder associated with syncope and sudden death (Wang et al., 1996 ). Although KCNQ1 has not been found in
brain, investigators subsequently identified four homologous neuronal
KCNQ genes (KCNQ2-5). KCNQ2 and KCNQ3 mutations cause benign familial
neonatal convulsions (BFNC), a dominantly inherited epileptic syndrome
characterized by seizures during infancy and in later life (Biervert et
al., 1998; Singh et al., 1998). KCNQ4 mutations result in a form of
dominantly inherited deafness (Kubisch et al., 1999). KCNQ5 is widely
expressed in brain, heart, and skeletal muscle (Schroeder et al.,
2000a).
Interactions between KCNQ subunits are important for channel properties
but are incompletely understood. KCNQ1 interacts with the small
accessory subunit KCNE1, forming heteromeric voltage-gated channels
that activate much more slowly than those consisting of KCNQ1 alone
(Sanguinetti et al., 1996). KCNQ1/KCNE1 heteromers underlie a cardiac
current, IKS, that helps
repolarize Ca2+ action potentials. In
contrast, association of KCNQ1 with another accessory protein, KCNE3,
results in "leak" channels that are open at all physiological
membrane potentials. Such channels are expressed in gastrointestinal
epithelia, where they help regulate secretion (Schroeder et al.,
2000b). KCNQ2 and KCNQ3 subunits associate in SCG neurons to underlie a
slow, voltage-gated potassium current,
IM (Brown and Adams, 1980; Wang et
al., 1998). BFNC may be attributable to impaired activity of central
KCNQ2/KCNQ3 heteromers, because disease mutations in either subunit
reduce current density (Schroeder et al., 1998), and the two subunits
can be reciprocally coimmunoprecipitated from human brain (Cooper et
al., 2000).
Although KCNQ2/KCNQ3 heteromers are likely expressed by both central
and sympathetic neurons, understanding of the subunit composition and
properties of neuronal KCNQ channels is limited. KCNQ2, KCNQ3, and
KCNQ5 mRNAs exhibit wide, mostly overlapping distribution, whereas
KCNQ4 mRNA and protein appear concentrated in the cochlea and a few
brainstem nuclei (Kharkovets et al., 2000). Unlike KCNQ2, KCNQ3 can
form functional heteromers with KCNQ4 or KCNQ5 in heterologous cells
(Kubisch et al., 1999; Schroeder et al., 2000a). It is not known
whether these combinations are found in vivo. Whether the
properties of neuronal KCNQ channels are modified by accessory subunits
is also unknown. Many alternatively spliced KCNQ2 mRNA isoforms have
been isolated from brain and sympathetic ganglia (Nakamura et al.,
1998). When expressed heterologously, the products of these mRNAs
differ in their ability to form functional channels alone, interactions
with KCNQ3, and kinetics (Pan et al., 2001; Smith et al., 2001).
The association of epilepsy with KCNQ2 mutations that cause only small
reductions in channel activity (Schroeder et al., 1998) prompted us to
attempt to identify the central neurons and circuits that appear so
exquisitely sensitive to KCNQ channel levels. We mapped KCNQ2
immunoreactivity in brain sections using an antibody directed against a
region of KCNQ2 conserved among known splice variants. We found that
KCNQ2 immunoreactivity, although widespread, is concentrated at
key locations for control of brain rhythmic activity and neuronal synchronization.
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MATERIALS AND METHODS |
Materials. Plasmids encoding human KCNQ2 and KCNQ3
were gifts from Drs. T. Jentsch and B. Schroeder (Zentrum fur
Moleculare Neurobiologie, Hamburg, Germany); rabbit anti-vesicular
acetylcholine transporter (VAchT) antibodies were a gift from Dr.
Robert Edwards (University of California, San Francisco, CA).
Donkey anti-rabbit HRP-conjugated antibodies (Amersham Pharmacia
Biotech, Arlington Heights, IL) were used for Western blots. Dr.
Christoph Turck (Howard Hughes Medical Institute, University of
California, San Francisco) synthesized the KCNQ2N peptide.
Generation of anti-KCNQ2N antibodies. A peptide sequence
derived from the N-terminal region of KCNQ2N (GEKKLKVGFVGLDPGAPDSTRDC) was selected after analysis using MacVector software indicated high
immunogenicity, and BLAST database searches showed that the sequence
was unique to KCNQ2 and conserved among all known KCNQ2 clones. The
peptide was conjugated to keyhole limpet hemocyanin via a cysteine
residue added at the C terminus of the peptide during synthesis. Two
rabbits were immunized, and sera were collected (Animal Pharm Services,
Healdsburg, CA). After screening experiments identified immunopositive
sera, anti-KCNQ2N antibodies were purified against the peptide
immunogen immobilized on 1 ml columns prepared using SulfoLink (Pierce,
Rockford, IL).
Cell culture. Human embryonic kidney (HEK) cells were
grown in DMEM/F-12 media supplemented with 10% fetal bovine serum,
penicillin, and streptomycin. Cells were transfected with KCNQ2 or
KCNQ3 cDNA, or both, in pcDNA3 expression vectors using FuGene 6 (Roche
Molecular Biochemicals, Indianapolis, IN).
Western blot. Mouse brains were homogenized in
0.32 M ice-cold sucrose supplemented with Complete protease
inhibitors (Roche Molecular Biochemicals). Crude membranes were
prepared by differential centrifugation, resuspended at a concentration
of 100 mg of wet tissue/ml in Tris-buffered saline (TBS; 50 mM Tris and 100 mM NaCl) with protease
inhibitors, and stored at  80°C until use. Solubilized proteins from
transfected cells were prepared by lysis for 30 min with ice-cold TBS
containing 1% Triton X-100 and protease inhibitors, followed by
centrifugation for 30 min at 20,000 × g. Supernatants
were snap frozen in liquid N2 and stored at
80°C until use. SDS-PAGE, electrotransfer, and Western blotting
were performed as described previously (Cooper et al., 2000). To
estimate the molecular weights of KCNQ2N-immunoreactive bands on
Western blots, lanes were scanned using densitometry software
(AlphaInnotech), and positions were compared with molecular weight
standards (Precision protein standards; Bio-Rad, Hercules, CA).
Immunohistochemistry. All procedures using animals were in
conformity with National Institutes of Health guidelines for the use of
laboratory animals and approved by the University of California, San
Francisco Committee on Animal Research. Ten adult male C57B6 mice were
deeply anesthetized with sodium pentobarbital and perfused via the
ascending aorta with 5 ml of PBS followed by 50 ml of cold 4%
paraformaldehyde and 0.1% glutaraldehyde in 0.1 M sodium phosphate buffer. Brains were removed, post-fixed overnight, and then
stored in PBS before sectioning. Floating sections were cut at 20-30
mm using a vibrating microtome (Leica, Nussloch, Germany).
Immunoperoxidase staining procedures were performed on sections
floating in TBS, with additions as noted. Sections were treated with
1% peroxide to eliminate endogenous peroxidase activity, permeabilized
using 0.4% Triton X-100, blocked using 5% normal goat serum, 0.1%
bovine serum albumin, and 0.2% Triton X-100, and then incubated with
affinity-purified anti-KCNQ2N antibodies (0.5 µg/ml) for 18-36 hr at
4°C. After washing (60 min, five changes), sections were incubated in
block solution with biotinylated goat anti-rabbit antibodies (1:200;
Vector Laboratories, Burlingame, CA) for 2 hr at room temperature.
After washing, sections were incubated with ABC solution (Elite kit;
Vector Laboratories) for 2 hr at room temperature. Sections were washed
in 0.2% Triton X-100 and TBS for 1 hr and then in 0.1 M
Tris. Development of the peroxidase reaction product was performed
using 0.5 mg/ml diaminobenzamine (Sigma, St. Louis, MO) and 0.005%
peroxide. Control experiments using sections processed with omission of
the primary antibody, replacement of affinity-purified anti-KCNQ2N
antibodies with preimmune sera (1:1000), or preincubating the
antibodies with 1 µg/ml synthetic peptide resulted in loss of
immunostaining. Reactions using rabbit anti-VAchT antiserum (1:1000;
Roghani et al., 1998) were performed as described above.
For immunofluorescence colocalization experiments, monoclonal
antibodies against parvalbumin (1:2000; Sigma) and choline
acetyltransferase (1:100; Chemicon, Temecula, CA) were used. Goat
anti-rabbit IgG Cy2 and Goat anti-mouse IgG Cy3 antibodies
(Jackson ImmunoResearch, West Grove, PA) were used at 1:500
dilutions. Control experiments showed lack of interaction between the
secondary antibodies, species specificity of secondary antibodies, and
absence of background staining by secondary antibodies.
Image acquisition and analysis. Light and epifluorescence
microscopy were performed using a Nikon (Melville, NY) E800 instrument equipped with a SPOT RT slider digital camera (Diagnostic Instruments). Confocal microscopy was performed using a Bio-Rad MRC 1024 confocal microscope. Figures were prepared using Photoshop (Adobe Systems, Mountain View, CA) and labeled using Adobe Illustrator software, using
the stereotactic mouse brain atlas of Franklin and Paxinos (1997) as a guide.
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RESULTS |
Characterization of KCNQ2N antibodies
We raised antibodies against a synthetic peptide corresponding to
amino acids 16-37 within the cytoplasmic N-terminal region of KCNQ2.
The chosen sequence is unique to KCNQ2, absolutely conserved in rat,
mouse, and human KCNQ2 clones, and is derived from the first exon of
the KCNQ2 gene, which is not known to be subject to alternative
splicing. We tested immune sera using HEK cells transiently transfected
with cDNA encoding an 844-amino acid isoform of human KCNQ2 (Biervert
et al., 1998) (Fig.
1A,B). Immune (but not
preimmune) sera recognized a single predominant band of appropriate size (~85 kDa) in KCNQ2 transfected cells but not in untransfected cells (data not shown) or KCNQ3-transfected cells (Fig.
1B, second lane). Purification of
antibodies using the immobilized peptide antigen enhanced the specific
detection of the KCNQ2 polypeptide. Preincubation with the KCNQ2N
peptide completely and specifically abolished the ability of the
affinity-purified antibodies to detect the KCNQ2 band (Fig.
1B, third through fifth lanes).
Western blots of adult mouse brain membranes using the
affinity-purified KCNQ2N antibodies revealed two strong bands of ~85
and 90 kDa (Fig. 1C), possibly representing known 844- and
872-amino acid "long" forms of KCNQ2 (Biervert et al., 1998; Singh
et al., 1998). Lower molecular weight KCNQ2N-immunoreactive bands
between ~40 and ~75 kDa were sometimes detected weakly in Western
blots of brain homogenates (data not shown). These lower molecular
weight immunoreactive bands, which were completely eliminated when
antibodies were preadsorbed with the peptide immunogen, may represent
"short" isoforms of KCNQ2N produced by alternative splicing
(Nakamura et al., 1998; Pan et al., 2001; Smith et al., 2001). However,
they were never prominent, and we have not yet investigated them
systematically. The steady-state protein levels of short isoforms of
KCNQ2 in adult mouse brain thus appear low compared with those of long forms.
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Figure 1.
Characterization of anti-KCNQ2N antisera and
affinity-purified antibodies. A, Western blots using
preimmune and immune sera against KCNQ2 expressed in HEK cells.
Immunoreactivity against the expressed ~85 kDa KCNQ2 band is absent
in preimmune sera and increases progressively during the immunization.
B, Immune sera detects the HEK-expressed KCNQ2 protein
but not KCNQ3 (~90 kDa; data not shown). After affinity purification
(AP), an ~70 kDa band background band is eliminated,
and recognition of transfected KCNQ2 is abolished by the KCNQ2N peptide
but not by a peptide from the KCNQ3 N terminus. C,
KCNQ2N antibodies detect two bands of ~85 and ~90 kDa in mouse
brain membranes. D, Immunoperoxidase staining by KCNQ2N
antibodies is abolished by preincubation of the antibodies with the
immunogenic peptide. Scale bar, 1 mm.
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Immunoperoxidase staining of mouse brain tissue sections revealed
widespread somatic staining of neurons and more diffuse neuropil
staining (discussed below). Staining of neuronal profiles and neuropil
was completely abolished by preincubation of the antibodies with the
immunogenic peptide (Fig. 1D).
Distribution of KCNQ2N immunoreactivity in mouse brain
We found extensive KCNQ2N immunoreactivity throughout the mouse
brain (Fig. 2). The structures most
heavily labeled were neuronal somata in many regions. Neuropil was
strongly labeled in cortex, the cerebellar molecular layer, and many
subcortical structures. White matter tracts exhibited weak or absent
staining.
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Figure 2.
Distribution of KCNQ2N immunoreactivity in the
mouse brain. A, Regions shown are the piriform cortex
(Pir), caudoputamen (CPu), ventral
pallidum (VPal), island of Calleja major
(IcjM), and medial septum (MS) and
diagonal band of Broca (dbB). B, Section
through the globus pallidus (GP), reticular
(Rt), laterodorsal (LD), and
ventrolateral (VL) thalamus, hippocampal mossy fibers
(MF), and lateral hypothalamus
(LH). C, Heavy staining of the
mossy fibers and habenula (Hb); staining in the fimbria
(fi), ventroposterior thalamus
(VP), amygdala (Am), and lateral
hypothalamus (LH) is lighter or moderate.
D, Staining in the subiculum (Sb),
mammillary body (MB), zona incerta (Zi),
and anterior pretectal (APt), lateral geniculate
(LG), and rostral interstitial
(RI) nuclei. The amygdala and medial geniculate
(MG) regions show light staining. E, The
anteroventral cochlear nucleus (AVCo), sensory division
of the trigeminal nucleus (5s), superior olive
(SO), trapezoid body (tz), dorsal
tegmentum (Dtg), Purkinje cell layer
(PC), and inferior colliculus (IC) show
moderate to heavy cell body staining. White matter tracts, including
the middle cerebellar peduncle (mcp) and facial
(7n) and vestibulocochlear (8n) nerves
are unlabeled. F, The vestibular (Ve),
dorsal cochlear (DCo), and dentate, interposed, and
medial cerebellar (DCb, Icb,
MCb) nuclei all show heavy staining, but the facial
nucleus (7) is unstained. Numbers
below the panel letters indicate rostrocaudal positions
of the sections according to the atlas of Franklin and Paxinos (1997).
Scale bars, 1 mm.
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Olfactory bulb and associated structures
The olfactory bulb receives input from nasal primary olfactory
sensory neurons, processes this input, and relays it to the olfactory
cortex (Shepherd and Greer, 1990). The principal neurons, the mitral
cells, have their somata in the narrow mitral cell layer and long
apical dendrites ending in the glomerular layer, where they receive
synaptic inputs from the nasal sensory cells. Several types of local
interneurons in these and adjoining external plexiform and internal
plexiform layers regulate the responsiveness of mitral cells to their
excitatory inputs from the periphery (Shepherd and Greer, 1990).
Central modulatory inputs to the bulb include cholinergic and
monoaminergic fibers from the diagonal band of Broca, locus ceruleus,
and raphe nuclei and a diversity of neuropeptides. KCNQ2N
immunostaining in the main olfactory bulb was strongest in the mitral
cell and glomerular layers (Fig. 3A). Somata of the mitral and
periglomerular cells, as well as the periglomerular neuropil, were
intensively stained. Other layers were lightly stained, except for cell
bodies of a few scattered interneurons in the external plexiform layer.
The tightly packed somata of the olfactory piriform cortex exhibited
moderate staining intensity (Fig. 2A,B).
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Figure 3.
Distribution of KCNQ2N
immunoreactivity in the olfactory bulb, ventral forebrain, and
hippocampus. A, In olfactory bulb, strong neuropil
staining is detected in the glomerular layer. Periglomerular cells in
the glomerular layer (Gl) and mitral cells
(Mit) exhibit strong somatic staining. Staining is
lighter in the external plexiform (ePl), internal
plexiform (iPl),and granule cell
(GC) layers. B, In the basal forebrain,
strong neuropil and somatic staining is apparent in the medial septum
(MS), diagonal band of Broca (dbB), ventral
pallidum (VPal), and island of Calleja major
(IcjM). The anterior commissure
(AC) and caudoputamen (CPu) are
indicated. C, In the hippocampal formation, neuropil
staining is intense along the mossy fiber pathway in the hilus
(h) of the dentate gyrus (DG) and
stratum lucidum (inset, sl) of
CA3. Moderate neuropil staining is present in the stratum oriens
(so), stratum radiatum (sr), and stratum
lacunosum-moleculare (sl) of the hippocampus and
the dentate molecular layer (m). In the stratum
pyramidale (sp) and stratum granulosum
(g), staining is light, except for a few cell
bodies (e.g., CA3 inset). Similar profiles are seen in
the stratum pyramidale of CA1 and in the dentate granule cell layer
(Fig. 4). Scale bars: A-C, 250 µm;
inset, 125 µm.
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Septum and diagonal band
Neurons in the medial septal nucleus (MS) and diagonal band of
Broca (dbB) exhibited intense somatic labeling (Figs.
2A,
3B, 4C,E).
This region contains GABAergic interneurons,
GABAergic projection neurons whose axons innervate the
hippocampal formation (see Discussion), as well as cholinergic neurons.
Double immunofluorescence staining with parvalbumin (PV) and KCNQ2N
indicated that all PV-positive profiles in the MS were also strongly
KCNQ2N-immunoreactive (Fig. 4C). Additional
PV-negative, KCNQ2N-positive cells were also noted. Staining with
choline acetyltransferase (ChAT) revealed that some of these
PV-negative, KCNQ2N immunoreactive somata were cholinergic neurons
(Fig. 4D); however, many of the large, multipolar
ChAT-positive neurons in the MS exhibited low or undetectable KCNQ2N
staining (data not shown). Thus, subpopulations of both cholinergic and GABAergic neurons of the MS and dbB were strongly
KCNQ2N-immunoreactive.
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Figure 4.
KCNQ2N immunolocalization in the
hippocampus and basal forebrain. A-C, E-G,
Immunofluorescence of sections double-labeled with KCNQ2N
(red) and PV (green).
A, In CA3, KCNQ2N intensely labels mossy fiber
(MF) bundles in the stratum lucidum
(sl) and, less strongly, neuropil of the stratum
radiatum (sr) and stratum oriens (so).
Interneurons in the stratum pyramidale (sp) and oriens
are double-labeled by PV and KCNQ2N (white arrows).
Additional interneurons in the stratum oriens and radiatum (e.g.,
red arrow) are KCNQ2N-positive but PV-negative.
B, In the dentate gyrus, KCNQ2N stains hilar mossy fiber
and PV-positive interneurons in the granule cell layer
(sg). The stratum lacunosum-moleculare
(slm), stratum moleculare (sm), and hilus
(hi) are indicated. C, Detail of
E. The medial septum contains numerous PV-positive
(white arrows) and PV-negative cells labeled with
KCNQ2N. D, Colabeling in the medial septum by ChAT
(green) and KCNQ2N (red); the
red arrow indicates a colabeled cell; the white
arrow indicates a KCNQ2N-immunoreactive, ChAT-nonreactive
profile. E, Low-power view of septal region (as in Fig.
3B). The anterior commissure (AC) lacks
KCNQ2N immunostaining, but the medial septum (MS),
island of Calleja major (IcjM), dbB, and ventral
pallidum (VPal) show strong somatic and neuropil
staining. Boxes indicate regions shown at higher
magnification in C, G, and
H. F, In CA1, PV-positive (white
arrows) and PV-negative (red arrows)
interneurons in the stratum oriens, pyramidale, and radiatum show
moderate labeling for KCNQ2N. G, H, PV and KCNQ2N double
staining of the ventral pallidum. In G, only PV staining
is shown; in H, KCNQ2N (red) and PV
(green) staining are superimposed. Red
arrows indicate position of two of the numerous PV-negative,
KCNQ2N-positive cell bodies; white arrows show colabeled
cells. Scale bars: E, 250 µm; F
(applies to A, B), C, D, G,
H, 50 µm.
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In the lateral septal nucleus, moderate neuropil staining was
detected, but neurons were unstained (Fig.
5A). The small, densely packed cells of the triangular septal nucleus, responsible for the
strong purinergic input to the habenular region (Sperlágh et al.,
1998), exhibited strong staining for KCNQ2N (Fig. 5A, inset).
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Figure 5.
KCNQ2N immunostaining of the triangular septal
nucleus (TS) and habenula. A, KCNQ2N
strongly stained somata of tightly packed granular neurons in the
triangular nucleus (inset shows higher magnification)
and lightly stained the neuropil in the lateral dorsal septal nucleus
(LSD). The fibers of the hippocampal commissure
(HC) are unstained. LV, Lateral ventricle;
Cg, cingulate gyms. B, Immunoperoxidase
staining of habenula, showing intensely reactive somata in the medial
(MH) and lateral (LH)
regions. C, Colabeling for KCNQ2N (red)
and ChAT (green) is exhibited by the cholinergic
neurons of the medial habenula but not the neurons of the lateral
habenula. The fasciculus retroflexus (FR) the projection
pathway of the medial habenula to the interpeduncular nucleus, is
strongly ChAT-immunoreactive. D, Colabeling with
KCNQ2 (red) and PV (green) showing
that cholinergic KCNQ2-positive medial habenula neurons are
PV-negative, as expected. PV staining of the lateral habenula neuropil
is intense, and some lateral habenula somata appear to contain both
KCNQ2N and PV immunoreactivity. Scale bars: A, 250 µm;
inset, B-D, 50 µm.
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Basal ganglia
The basal ganglia include nigrostriatal circuitry that is
important for motor control and mesolimbic and ventral pallidal components involved in emotion and reward (Wilson, 1990). Approximately 95% of rodent caudoputaminal neurons are GABAergic, PV-negative principal cells, the spiny neurons, which project to the globus pallidus and substantia nigra reticulata. The remaining 5% of caudoputaminal cells are interneurons and include cholinergic neurons
and PV- and calbindin-expressing subpopulations of GABAergic cells
(Wilson, 1990). Immunoperoxidase staining of the caudoputamen for
KCNQ2N revealed light to moderate neuropil staining and conspicuous somatodendritic labeling of a small number of neurons (Fig.
6A). Double staining with
KCNQ2N and PV revealed three populations of neurons: those labeled by
KCNQ2N alone, PV alone, and both markers (Fig.
6B-D). The somata of neurons
labeled by KCNQ2N but not PV appeared larger than those labeled by both
KCNQ2N and PV or by PV alone. Because the cholinergic interneurons of
the striatum are larger and less numerous than the GABAergic principal
cells and interneurons, we suspected that the KCNQ2N-only-labeled cells might include such neurons. Indeed, double immunofluorescence staining
for ChAT and KCNQ2N revealed that the larger, most strongly KCNQ2N-immunoreactive cells in the caudoputamen were cholinergic large
aspiny neurons with the typical dendritic morphology of these cells
(Fig. 6D).
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Figure 6.
KCNQ2N immunolocalization in the caudoputamen
(CPu). A, Immunoperoxidase stain showing
moderate neuropil staining and moderate to heavy staining of somata and
proximal dendrites in the CPu, but little staining in the corpus
callosum (CCal). B, C, Double immunolabeling
for PV (PARV, green) and KCNQ2N
(red) in the lateral caudoputamen. Many cells are
labeled strongly by PV and weakly by KCNQ2N (e.g., those indicated by
wide white arrows). A few, typically larger, cells are
labeled by KCNQ2N but not by PV (red arrows) or
PV but not KCNQ2N (thin white arrow). D,
Double immunolabeling for choline acetyltransferase (green)
and KCNQ2N (red) in the caudo putamen. Many cells exhibit
staining by both antibodies, but some are stained weakly for KCNQ2
only. Cell nuclei are counterstained with DAPI (blue). Scale
bars, 100 µm.
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Figure 7.
KCNQ2N immunolocalization in the globus pallidus
(GP) and nucleus reticularis thalami (Rt).
A, Immunoperoxidase stain using KCNQ2N antibodies shows
strong staining of neuronal profiles in the CPu, GP externa
and interna (Gpe, Gpi), and Rt, but not in
neighboring thalamic relay nuclei, ventroposterior lateral
(VPl) and ventroposterior medial (VPm), or the
internal capsule (IC). B, Double immunolabeling
of a similar section to A, using KCNQ2N and PV antibodies.
Double-labeled neurons (orange to yellow) are
numerous in the nRT and Gpe. In addition, a few neurons (red
arrows) in the IC show labeling for KCNQ2N but not PV.
C, Immunoperoxidase staining with VAchT antibodies reveals
the distribution of cholinergic neurons in and near the Gpe. VAchT
labels neuropil strongly in the CPu and moderately in the Gpe and Rt.
Intensely labeled neurons are preferentially located at periphery of
and ventral to the Gpe. D, Higher magnification view of Rt,
showing that all PV-labeled neurons are also KCNQ2N labeled.
E, Detail of D, showing punctate appearance of
KCNQ2N staining. F, Higher magnification view of region near
border of IC and ventral border of Gpe (location indicated by
box in C), after double immunolabeling with
KCNQ2N (red) and ChAT (green). Neuropil and
neurons of Gpe are labeled by KCNQ2N only, but a few neurons
(arrows) at border are stained by both antibodies.
G, Higher magnification views of Gpe double-labeled with PV
(green) and KCNQ2N (red). Most cells appear
yellow or orange because of colabeling with both
markers, but a few preferentially located near periphery of Gpe are
labeled by KCNQ2 only (arrows). Scale bars: A,
250 µm; B, C, 100 µm; D, 25 µm;
E, 10 µm; F, G, 50 µm.
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In the globus pallidus, the main target of output from the
caudoputamen, both neuropil and neuronal somata exhibited strong KCNQ2N
staining (Figs. 2B, 7).
The pallidum is reported to consist almost entirely of PV-positive
GABAergic neurons (Parent et al., 1996). Unexpectedly, double labeling
with PV revealed two populations of KCNQ2N-immunoreactive cells in the
globus pallidus: those that expressed both markers (which were far more
numerous) and those that expressed KCNQ2N but not PV (which were
preferentially located near the periphery of the globus pallidus) (Fig.
7B,G). In the rodent, cholinergic
neurons functionally similar to those of the more ventrally located
basal forebrain cholinergic nucleus are found within and at the borders
of the globus pallidus and within the internal capsule (Arvidsson et
al., 1997). We visualized these "ectopic" cholinergic neurons by
immunostaining using a rabbit antibody against VAchT (Fig.
7C). Double labeling with KCNQ2N and ChAT revealed,
as expected, that most of the KCNQ2N-labeled cells within the globus
pallidus were ChAT-negative. However, a few neurons, preferentially
located at the edge of the globus pallidus, were immunoreactive for
both KCNQ2N and ChAT (Fig. 7F).
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Figure 8.
Regions of high KCNQ2N immunoreactivity in
thalamus and brainstem. A, Ventral midbrain. Staining is
detected in the substantia nigra reticulata (SNr) and
red (Rd), interpeduncular (IP), and
oculomotor (3) nuclei. The medial lemniscus
(ml) and oculomotor nerve (3n) are
unstained. B, Heavy staining is shown in the zona
incerta and substantia nigra reticulata, but the cerebral
peduncles and medial longitudinal fasciculus
(Cped, MLF) are not stained.
C, The anteroventral cochlear nucleus (AVCo)
shows somatic staining, but the nearby cochlear nerve and spinal tract
of the trigeminal nucleus (8n, 5n) are
unstained. D, Substantia nigra compacta
(SNc), substantia nigra reticulata, and ventral
tegmental nuclei (VTA) showing somatic staining. Scale
bars: A, 500 µm; B-D, 250 µm.
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The ventral pallidum and islands of Calleja are important targets of
dopaminergic afferents from the ventral tegmental area and are
components of mesolimbic circuitry implicated for reward, addiction,
emotions, and thought disorders (Missale et al., 1998). These regions
exhibited strong neuropil and somatic staining for KCNQ2N (Figs.
3B, 4E,G,H). Double
labeling revealed that some of the KCNQ2N immunoreactive neurons in
these regions also expressed PV (Fig. 4G,H).
Amygdala
Very light neuropil staining was detected throughout the amygdala,
and somatic staining was not conspicuous in the region (Fig.
2C,D).
Hippocampal formation
The hippocampal formation includes the dentate gyrus, hippocampus
(CA1, CA2, and CA3), and the subicular complex (Amaral and Witter,
1995). The dentate granule cells receive excitatory inputs on their
apical dendrites in the molecular layer; their axons, the mossy fibers,
project to form synapses on the apical dendrites of the CA3 pyramidal
cells. The CA3 pyramidal cells project in turn to CA1, where they
synapse with CA1 pyramidal cells. In addition to this so-called
trisynaptic circuit of glutamatergic principal cells, numerous
interneurons play critical roles regulating the excitability of the
principal cells and helping synchronize pyramidal cell output (Cobb et
al., 1995; Freund and Gulyás, 1997). Additional extrinsic
cholinergic, monoaminergic, and GABAergic inputs, as well as numerous
neuropeptides, modulate the activity of this circuitry (Amaral and
Witter, 1995). The most striking feature of the KCNQ2N immunoperoxidase
staining pattern in the hippocampal formation was the intense staining
of the mossy fiber pathway in the dentate hilus and the stratum lucidum
of CA3 (Figs. 3C, 4A). KCNQ2N also stained
the neuropil in the dentate molecular layer and stratum oriens,
radiatum, and lacunosum-moleculare (Fig. 3C). Scattered
throughout all layers in the dentate, hippocampus, and subiculum were
neuronal somata stained with moderate intensity (Fig. 3C,
inset). Aside from these occasional neuronal profiles, the
granule cell and pyramidal cell layers exhibited the lowest intensity
of KCNQ2N immunoreactivity in the region. PV marks an important
subpopulation of hippocampal interneurons, primarily located within and
near the principal cell layers, whose axons arborize widely within the
pyramidal layer to form axosomatic synapses with principal cells
(Freund and Gulyás, 1997). Double-label immunolabeling revealed
that nearly all the KCNQ2N-stained neuronal profiles in the dentate
granule cell layer (Fig. 4B) or pyramidal cell layers
of CA3 or CA1 (Fig. 4A,F) or the subiculum (data not shown) were PV-positive interneurons. In stratum oriens or radiatum, however, most of the scattered KCNQ2N-immunoreactive profiles were not
stained for PV.
Habenula and interpeduncular nucleus
As discussed above, purinergic neurons in the triangular septal
nucleus send a massive projection to innervate the medial habenular
neurons (Sperlágh et al., 1998), which, in turn, send a
cholinergic projection via the myelinated fibers of the fasciculus retroflexus to the interpeduncular nucleus.
The neurons of both the medial and lateral habenula exhibited intense
staining for KCNQ2N (Figs. 2B,C,
5B-D). The neurons of the medial habenula and its
output pathway, the fasciculus retroflexus, were strongly labeled by
ChAT but not by PV. KCNQ2N colabeled the cholinergic neurons in the
medial habenula but not the fibers of the fasciculus retroflexus (Fig.
6C). The KCNQ2N-labeled neurons of the lateral habenula were
unstained by both PV and ChAT but received intense innervation by
PV-stained fibers (Fig. 5D). The intermediate,
lateral, and rostral divisions of the interpeduncular nucleus, targets
of cholinergic innervation from the medial habenula via the
fasciculus retroflexus, exhibited strong staining of neuronal cell
bodies (Fig. 8A).
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Figure 9.
Distribution of KCNQ2N immunoreactivity in the
cerebellum. A, Immunoperoxidase stain showing strong
staining of Purkinje cell (pc) somata and
molecular level neuropil (m), with light staining
of the granule cell layer (gc) and absent
staining of deep cerebellar white matter (wm). Scattered
cells in the granule cell layer exhibit moderate somatic staining.
B, Higher-magnification view showing that immunopositive
granule cell layer neurons are stained on their somata and apical
dendrites. Staining of dendrites of Purkinje cells is not apparent.
C, Double immunofluorescence image (red,
KCNQ2N; green, PV), showing that both markers label
Purkinje cells, but KCNQ2N-positive granule cell layer neurons are
PV-negative, as expected for Golgi cells. Purkinje cell somata are
surrounded by PV-positive axons and termini derived from inhibitory
basket and stellate cells whose somata are located in the molecular
layer. Scale bars: A, 250 µm; B, 100 µm; C, 50 µm.
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Thalamus
Thalamic nuclei represent the final relay point for sensory
information of all modalities and also receive reciprocal excitatory inputs from the region of the cerebral cortex to which they project. The activity of thalamic relay neurons and the thalamocortical circuit
is strongly influenced by the GABAergic interneurons of the thalamic
reticular nucleus. The reticular nucleus is an important target of
ascending monoaminergic, cholinergic, and tachykinin inputs that
control transitions between sleep and wakefulness (McCormick and Bal,
1997). All of the neurons of the reticular thalamic nucleus were very
heavily labeled by KCNQ2N (Figs. 2B,C, 7A,B,D,E). As expected, PV also stained these same
neurons strongly. In higher-magnification images, KCNQ2N
immunoreactivity had a strong punctate component that appeared in part
to be intracellularly localized (Fig. 7E). Although
light neuropil staining was present throughout the remaining portions
of the thalamus, immunoreactivity of thalamic relay neurons was in
general very slight or not apparent. Exceptions to this were the
ventral zona incerta (Figs. 2D, 8B), the
dorsal division of the anterior pretectal nucleus (Fig.
2D), and the rostral interstitial nucleus (Fig.
2D) of the medial longitudinal fasciculus, where many
neuronal somata exhibited moderate to heavy KCNQ2N immunoreactivity.
Cerebral cortex
Neuropil staining for KCNQ2N was present throughout the cerebral
cortex, and many neurons exhibited moderate somatic staining (Fig. 2).
Examination of sections double-labeled with PV and KCNQ2N and
counterstained with 4',6-diamidino-2-phenylindole revealed that the
intensity of staining of cortical neurons by KCNQ2N was very
heterogeneous, ranging from inconspicuous to moderate or heavy (data
not shown). Highly KCNQ2N-immunoreactive cortical neuronal somata
included both PV-positive and -negative cells.
Hypothalamus
Neurons in the lateral hypothalamic nucleus were stained with
moderate intensity (Fig. 2C). In the mammillary body,
neurons and neuropil showed light to moderate staining (Fig.
2D). KCNQ2N staining was absent or light in median,
posterior, arcuate, dorsomedian, and ventromedian nuclei.
Midbrain
KCNQ2N immunoreactivity was strong in the neurons of the medial
accessory oculomotor nucleus and magnocellular red nucleus (Fig.
8A). Strong staining was also seen in the neurons of the substantia nigra reticulata and compacta and the ventral tegmental areas (Fig. 8B,D). A recent immunohistochemical study of
KCNQ4 showed strong labeling of the substantia nigra compacta and the ventral tegmental area (Kharkovets et al., 2000). This is intriguing, because KCNQ2 and KCNQ4 are unable to form heteromers when coexpressed in experimental cells (Kubisch et al., 1999), and suggests that two
distinct KCNQ channels may be expressed by the same neurons.
In the caudal midbrain, neurons of the central and external nucleus of
the inferior colliculus were moderately stained, as were neurons of the
dorsal tegmental nucleus (Fig. 2E).
Pons and cerebellum
Neurons of the supratrigeminal nucleus and sensory division of the
trigeminal nucleus exhibited moderate KCNQ2N immunoreactivity, but the
magnocellular (motor) division of the trigeminal nucleus showed no
somatic staining (Fig. 2E). In the nucleus of the
trapezoid body and the superior olive, relay points of the central
auditory pathway, somatic staining was strong. Somatic staining was
particularly strong in the anteroventral and dorsal divisions of the
cochlear nucleus and was moderate in the subnuclei of the vestibular
nucleus. Of note, KCNQ4 immunoreactivity is also found in the
anteroventral (but not dorsal) cochlear nucleus, superior olive, and
inferior colliculus (Kharkovets et al., 2000).
In the cerebellar cortex, the neuropil was moderately stained in
the molecular layer and lightly stained in the granule cell layer (Fig.
2E,F). Examination of the cerebellar sections
at higher magnification revealed that Purkinje cell somata exhibited
strong KCNQ2N immunoreactivity, but, regardless of the orientation of the tissue section, the large proximal dendrites of these cells were
not visualized (Fig. 9). This suggested
that the neuropil staining in the molecular layer was predominantly
attributable to channels located on small distal dendrites or,
alternatively, was located on presynaptic fibers or termini (e.g.,
climbing and parallel fibers). Notable in the granule cell layer was
the absence of immunoreactivity associated with the granule cells
themselves. However, scattered throughout the thickness of the granular
layer were a population of large neurons, stained with moderate
intensity on their somata with KCNQ2N. Many of these cells exhibited
staining on a single large process oriented toward the Purkinje cell
layer (Fig. 9B). These neurons are likely Golgi
cells, on the basis of their morphology and absence of PV
immunoreactivity (Fig. 9C; Watanabe et al., 1998). The Golgi
and Purkinje neurons both have extensive dendritic arborizations in the
cerebellar molecular layer. Trafficking of KCNQ2-containing channels to
distal parts of these dendrites could contribute to the strong
molecular layer neuropil staining for KCNQ2N. Neurons of the deep
cerebellar nuclei also exhibited strong KCNQ2N immunoreactivity (Fig.
2F).
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Figure 10.
Distribution of KCNQ2N immunoreactivity in
septohippocampal and thalamocortical neuronal networks.
A, In the medial septum, KCNQ2N-immunoreactive
(Q2+) GABAergic projection neurons receive excitatory
inputs from nearby Q2+ cholinergic neurons. Both sets of septal neurons
project to the hippocampus. Septal cholinergic fibers innervate all
cell types in the hippocampus, but septal GABAergic fibers selectively
innervate hippocampal interneurons (some Q2+) that arborize broadly to
control activity and synchronization of hippocampal principal cells.
B, In the thalamocortical network, glutamatergic
thalamic relay neurons receive excitatory sensory inputs, and project
to pyramidal cells (PC) in the sensory cortex, with collateral output
to the Q2+ GABAergic reticular thalamic neurons.
Thalamic reticular neurons project back to the relay nuclei, thereby
helping synchronize prominent rhythmic firing associated with
drowsiness and sleep. Ach, Acetylcholine.
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DISCUSSION |
KCNQ2N immunoreactivity is widely distributed in the mouse brain
but is concentrated in particular subsets of neurons in brain circuits.
KCNQ2 is highly expressed in cholinergic and dopaminergic neurons that
exert wide-ranging modulatory influences, as well as GABAergic
interneurons within several brain regions. Moreover, KCNQ2 appears to
be strategically localized in several circuits that control oscillatory
neuronal activities. This study provides a road map for additional
studies of central KCNQ channels. It highlights the possibility that
central KCNQ2-containing channels may be important effectors for
diverse neurotransmitters (including but not limited to acetylcholine)
that modulate the activity of neurons and circuits in which these
subunits are expressed.
M current in native neurons
IM is one of several currents in
rodent superior sympathetic ganglion neurons that are active at rest or
are activated between resting and threshold membrane potentials to
control excitability and spike frequency (Brown and Adams, 1980; Adams
et al., 1986; Jones, 1989). When IM is
inhibited by one of several metabotropic receptors, including M1
muscarinic receptors, B2 bradykinin receptors, substance P, and
luteinizing hormone-releasing hormone receptors, depolarization
is favored, and spike frequency adaptation is reduced. Because
peptidergic neurotransmitters in the ganglion have long durations of
action and diffuse to cells at a distance from their release sites (Jan
and Jan, 1982), IM also serves as a
mechanism of sustained, heterosynaptic modulation (Adams and Brown,
1982).
The generalized epileptic phenotype resulting from partial
loss-of-function mutations in KCNQ2 or KCNQ3 (Schroeder et al., 1998)
is consistent with the hypothesis that these channels function similarly to control excitability in the brain and suggests an additional role in regulation of neuronal synchronization. Thus far,
studies of central IM have focused
primarily on intrinsic properties of hippocampal CA1 pyramidal cells
(Halliwell and Adams, 1982; Malenka et al., 1986; Storm, 1989; Charpak
et al., 1990; Charpak and Gähwiler, 1991; Schweitzer et al.,
1993; Aiken et al., 1995; Lampe et al., 1997; Madamba et al., 1999;
Schweitzer, 2000), and investigations of
IM in only a few other central
neuronal types have been reported (McCormick and Prince, 1986;
Constanti and Sim, 1987). Isolation of
IM requires an unusual voltage
protocol and until recently has been hampered by lack of
pharmacological tools. Thus, although many of the neurons that exhibit
strong KCNQ2N immunolabeling in our study have received scrutiny by
electrophysiologists, it may remain an open question whether
IM is a prominent somatic current in
these cells. This issue may be addressed by targeted electrophysiological studies of KCNQ2N-immunoreactive neurons, aided by
newly developed, selective KCNQ channel blockers and openers (Wang et
al., 1998; Rundfeldt, 2000). In some neurons, somatically localized
KCNQ2 may be primarily associated with intracellular membranes. These
intracellular channels might be destined for trafficking to axonal,
dendritic, or perisynaptic sites, or their surface deployment near the
soma could be regulated by activity or other factors. Finally, the
observation that KCNQ1 forms leak channels when associated with KCNE3
(Schroeder et al., 2000b), highlights the possibility that central
channels containing KCNQ2 may exhibit properties different from those
of IM.
KCNQ2 is highly expressed in modulatory cholinergic and
dopaminergic neurons
Somatic labeling for KCNQ2N was detected in several cell types
within the basal ganglia, including PV-colabeled neurons in the
striatum, globus pallidus, and substantia nigra reticulata, dopaminergic neurons of the substantia nigra compacta and ventral tegmental area, and cholinergic neurons in the striatum and near the
globus pallidus (Figs. 6-8). The KCNQ2N-immunoreactive cholinergic neurons of the neostriatum, so-called large aspiny neurons, represent only 1-2% of the striatal neurons but possess dense cholinergic axonal projections throughout the striatum and nucleus accumbens. These
projections represent the main cholinergic synapses in the striatum and
are thought important in movement disorders and psychiatric disturbances (Wilson, 1990). The dopaminergic neurons of the substantia nigra compacta and ventral tegmental area (Fig. 8D) provide
essential modulatory inputs to their striatal and limbic targets (Haber and Fudge, 1997).
KCNQ2 is strategically localized to septal and hippocampal neurons
that regulate hippocampal excitability and synchronization
We found strong KCNQ2N immunoreactivity on cholinergic and
GABAergic neurons in the medial septal region, and on PV-positive and
negative interneurons throughout the hippocampal formation (Figs.
3C, 4). These septal and hippocampal neurons are components of a neuronal network regulating the excitability and synchronization of hippocampal pyramidal cells (Cobb et al., 1995; Freund and Gulyás, 1997) (Fig. 10A). Septal cholinergic neurons
innervate both cholinergic and GABAergic neurons in the septum and both pyramidal cells and GABAergic interneurons in the hippocampus. Septal
GABAergic neurons projecting to the hippocampus selectively innervate
hippocampal interneurons (Freund and Antal, 1988). Recent evidence
suggests that acetylcholine exerts its most important influence on
hippocampal pyramidal neurons via an indirect pathway, by exciting
septal GABAergic projection neurons that inhibit hippocampal interneurons (Tóth et al., 1997; Wu et al., 2000). Because single hippocampal interneurons exert control over many pyramidal cells (Cobb
et al., 1995), this network represents a highly amplified mechanism for
cholinergic regulation of hippocampal excitability and synchronization
(Freund and Gulyás, 1997).
In vivo studies have demonstrated the importance of this
septohippocampal network for cognitive function during learning and memory tasks and for hypersynchronization associated with the generation of epileptic seizures. Lesions of the fimbria-fornix, which
conveys the axons of the cholinergic and parvalbumin-expressing GABAergic projection neurons from the medial septum to the hippocampus, interfere with learning and memory tasks and with the generation of the
theta rhythm in rats. These deficits can be partially reversed by the
grafting of cholinergic cells in the hippocampus (Dunnett et al., 1982;
Dickinson-Anson et al., 1998). Pharmacological studies argue that the
septohippocampal network is a critical site for the effects of
muscarinic drugs on learning and memory. Administration of the
muscarinic receptor antagonists scopolamine and atropine produces an
amnestic syndrome in rodents, primates, and humans (Deutsch and
Rocklin, 1967; Rusted, 1988; Rusted and Warburton, 1988; Rupniak et
al., 1989). In contrast, muscarinic agonists infused into the medial
septum elicit continuous hippocampal theta and facilitate learning and
memory in both young and aged rats (Givens and Olton, 1990; Monmaur and
Breton, 1991; Lawson and Bland, 1993; Markowska et al., 1995). In
rodents, localized septal infusion of the muscarinic agonist carbachol
has been shown to reverse the amnesia produced by systemic
administration of scopolamine (Givens and Olton, 1995). In contrast,
administration of high doses of pilocarpine, another muscarinic
agonist, produces status epilepticus in rodents and a chronic,
epileptic phenotype that serves as a leading experimental model of
human temporal lobe epilepsy (Cavalheiro et al., 1996).
KCNQ2 expression in reticular neurons that regulate
thalamocortical oscillations
Distinct patterns of rhythmic activity in thalamocortical circuits
are correlated with levels of sleep and arousal (Steriade and
Llinás, 1988). Abnormal rhythmic activity in this circuit is
likely important in many forms of generalized epilepsy (McCormick and
Contreras, 2001). GABAergic neurons in the thalamic reticular nucleus
regulate thalamocortical oscillations and help synchronize the firing
of thalamic relay neurons (McCormick and Bal, 1997) (Fig.
10B). Reticular neurons exhibited strong KCNQ2N
immunoreactivity (Fig. 7). Activation of serotonergic, adrenergic,
metabotropic glutamate, or tachykinin receptors on reticular nucleus
neurons causes slow membrane depolarization as the result of inhibition of a linear leak-type potassium current (McCormick and Wang, 1991; Cox
et al., 1995), bringing about a transition from bursting to relay-type
firing patterns (McCormick and Bal, 1997). Although purely speculative,
it would be interesting to test whether this potassium current arises
from KCNQ2 and auxiliary subunits in a manner analogous to the
interactions of KCNQ1 and KCNE3.
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FOOTNOTES |
Received July 30, 2001; revised Sept. 21, 2001; accepted Sept. 24, 2001.
This work was supported by an individual investigator grant from the
University of California, San Francisco Academic Senate (E.C.C.), by
National Institute of Neurological Disorders and Stroke Grant NS42100
(E.C.C.), and by a National Institute of Mental Health grant to the
Silvio Conte Center for Neuroscience at University of California, San
Francisco. L.Y.J. and Y.N.J. are investigators of the Howard Hughes
Medical Institute. We thank T. Jentsch for human KCNQ2 and KCNQ3 cDNA
clones, R. Edwards for anti-VAchT antibodies, S. Pleasure for use of
the Leica microtome, and T. Surti for help with ChAT immunostaining.
Correspondence should be addressed to Dr. Edward C. Cooper, Departments
of Neurology and Physiology, University of California, San Francisco,
Room U232, 533 Parnassus Avenue, Box 0725, San Francisco, CA
94143-0725. E-mail: ecooper{at}itsa.ucsf.edu.
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ABSTRACT
INTRODUCTION
Substance via MeSH
