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The Journal of Neuroscience, February 1, 1998, 18(3):965-974
Presynaptic Localization of Kv1.4-Containing A-Type Potassium
Channels Near Excitatory Synapses in the Hippocampus
Edward C.
Cooper1,
Antonia
Milroy2,
Yuh Nung
Jan3,
Lily Yeh
Jan3, and
Daniel H.
Lowenstein1, 2
Departments of 1 Neurology, 2 Anatomy, and
3 Physiology and Biochemistry and Howard Hughes Medical
Institute, University of California San Francisco, San Francisco,
California 94143
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ABSTRACT |
Mammalian Shaker voltage-gated potassium channels
that contain the Kv1.4 subunit exhibit rapid activation and prominent
inactivation processes, which enable these channels to integrate brief
(approximiately milliseconds) depolarizations over time intervals of up
to tens of seconds. In the hippocampus, Kv1.4 immunoreactivity is
detected at greatest density in two regions: (1) the middle molecular
layer (MML), where perforant path axons synapse with dentate granule cells, and (2) the stratum lucidum (SL) of CA3, where the mossy fibers
travel in tight fasciculi and form en passante synapses onto CA3
pyramidal cells. We have studied the localization of Kv1.4 within these
regions in detail. First, we compared the distribution of Kv1.4 and
synaptophysin (a synaptic vesicle protein primarily localized near
termini) under confocal immunofluorescence microscopy. In the MML,
Kv1.4 and synaptophysin immunofluorescence appeared to overlap. In the
SL, however, Kv1.4 and synaptophysin staining was detected in
nonoverlapping, irregular patches (~5-10 µm in diameter).
Ultrastructural studies of these two regions revealed that Kv1.4
immunoreactivity was absent from the surface membranes of cell bodies
and dendrites and occurred prominently on axons, including axonal
"necks" near termini. Small excitatory synaptic boutons also were
labeled in the MML; by contrast, the mossy fiber synaptic expansions in
the SL were not stained. These localizations may enable
Kv1.4-containing channels to regulate the process of neurotransmitter
release at these excitatory synapses.
Key words:
voltage-gated potassium channel; mossy fiber; presynaptic
facilitation; Shaker; hippocampus; granule cells
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INTRODUCTION |
Neuronal voltage-gated potassium
channels have been shown to contribute to postsynaptic potentials,
propagated action potentials, action potential firing patterns, and
neurotransmitter release (Rudy, 1988 ; Hille, 1992). Molecular studies
over the last decade have provided evidence that the wide diversity of
voltage-gated potassium channels in the mammalian brain results, in
part, from the expression of a large number of genes for channel
subunits (Chandy and Gutman, 1995; Jan and Jan, 1997). The contribution to brain function made by a particular channel type depends on its
pattern of expression within different brain regions and cell types
(Llinas, 1988). Furthermore, because neurons are highly polarized cells
consisting of many distinct subcellular compartments, the cellular
function of a channel is determined ultimately by its localization at
the ultrastructural level.
The hippocampus is suitable for studies aimed at clarifying how channel
localization may relate to cellular and network properties, because
plasticity at hippocampal synapses is believed to play an important
role in learning and memory, and because the basic network, cells, and
synapses of the rodent hippocampus have been characterized extensively
in previous studies (Brown and Zador, 1990; Amaral and Witter, 1995;
Nicoll and Malenka, 1995). Anatomic studies have revealed that Kv1.4, a
Shaker family potassium channel  subunit, is expressed in
a distinctive pattern in the hippocampal formation (Sheng et al., 1992,
1993; Rhodes et al., 1995; Veh et al., 1995). High levels of Kv1.4 mRNA
are expressed by glutamatergic neurons of the medial entorhinal cortex,
dentate granule cell layer, and hippocampal pyramidal cell layer (Sheng
et al., 1992). Staining with anti-Kv1.4 antibodies has revealed high
expression of the protein in the middle molecular layer of the dentate
gyrus and the stratum lucidum of CA3, with lower levels of
immunoreactivity associated with other areas of the neuropil and cell
somata. This pattern of RNA and protein localization suggested that
Kv1.4-containing channels in the hippocampus might be targeted
specifically to axons and synaptic termini of glutamatergic neurons
(Sheng et al., 1992, 1993).
It has not been possible as yet to record intracellularly from these
small axons and termini, and, hence, their electrophysiologic properties remain relatively uncharacterized. In heterologous expression studies, Kv1.4 differs from other members of the
Shaker subfamily by virtue of its rapid N-type inactivation
(Stuhmer et al., 1989). Kv1.4 also has uniquely prominent
desensitization (or "C-type inactivation"), which develops rapidly,
requires tens of seconds to recover completely, and is sensitive to
extracellular potassium ion concentration (Ruppersberg et al., 1991;
Pardo et al., 1992; Baukrowitz and Yellen, 1995). It is therefore of
interest to determine whether Kv1.4 is expressed on axons, where it
could contribute to the encoding and shaping of propagated action
potentials, and whether Kv1.4 is expressed at or near synaptic termini,
where it could influence the amount of transmitter release by
integrating temporally dispersed incident spike activity over a
milliseconds-to-seconds time range. For these reasons, we used
immunohistochemistry, confocal microscopy, and immunoelectron
microscopy to examine the cellular and subcellular localization of
Kv1.4 in the hippocampus and dentate gyrus.
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MATERIALS AND METHODS |
Preparation of tissue. Twelve male Sprague Dawley
rats (225-275 gm) were used for these studies. Protocols for animal
care were approved by the Committee for Animal Research of the
University of California, San Francisco, and were in accord with United
States Department of Agriculture and National Institutes of Health
guidelines for humane treatment of animals. Rats were deeply
anesthetized with sodium pentobarbital (50 mg/kg) and perfused via the
ascending aorta with heparinized saline followed by fixative. Fixative
solutions generally consisted of 4% freshly prepared paraformaldehyde/
0.1% glutaraldehyde (PG) in phosphate buffer. Some animals used for electron microscopy were perfused with solutions of 4%
paraformaldehyde, 0.5% glutaraldehyde, and 0.2% picric acid (PGP).
After rapid dissection and post-fixation for 1-2 hr at 4°C, tissue
was sectioned by vibratome at 50 µm in PBS. Tissue was either stored
in PBS or processed immediately for immunocytochemistry.
Antibodies and controls. The rabbit anti-Kv1.4 antibody used
in this study has been characterized extensively (Sheng et al., 1992,
1993). The antibody is directed against a 21 amino acid synthetic
peptide corresponding to residues 13-33, near the cytoplasmic N
terminus of the protein. Antibodies were affinity-purified against the
immobilized immunogenic peptide as described (Sheng et al., 1992).
Western blots of rat brain membranes with the anti-Kv1.4 antibody
detected a single band of ~95 kDa that comigrated with the band
detected in blots of HEK-293 cells that had been transfected with Kv1.4
in mammalian expression vectors (data not shown). The pattern of
hippocampal immunostaining observed here, like the ability of the
antibody to recognize the Kv1.4 band on blots, was abolished by
preincubation of the antibody with the immunogenic peptide. The mouse
anti-synaptophysin antibody was obtained from Sigma (St. Louis,
MO).
Light and laser-scanning confocal microscopy.
Immunoreactions were conducted at room temperature with constant
rotary shaking. Sections were washed in 100 mM Tris, pH
7.4, followed by Tris containing 1% hydrogen peroxide for 30 min.
After washing in Tris, sections were blocked and permeabilized for 1 hr
in Tris-buffered saline (TBS) containing 0.1% Triton X-100, 3% normal
serum (goat or horse, depending on secondary antibodies), 0.1% bovine
serum albumin, and 0.02% sodium azide. Section were incubated with
primary antibodies (anti-Kv1.4 at 1:1000 dilution, anti-synaptophysin at 1:10,000) for 18-48 hr. After washing (six changes, 60 min total)
in TBS/0.1% Triton X-100, secondary antibodies (vector goat
anti-rabbit for Kv1.4 immunoperoxidase; Jackson goat anti-rabbit for
Kv1.4 immunofluorescence; Jackson donkey anti-mouse for synaptophysin immunofluorescence, all at 1:200) were added and incubated for 2 hr.
For immunoperoxidase staining, the manufacturer's instructions were
followed (ABC Elite; Vector, Burlingame, CA), and development was
performed with 0.01% hydrogen peroxide.
Sections were mounted onto slides and coverslipped using Permount
(Sigma) or, for immunofluorescence, ProLong (Molecular Probes, Eugene,
OR). Slides were examined using a Zeiss Axiophot photomicroscope or a
Bio-Rad (Hercules, CA) M-600 laser-scanning confocal microscope.
Immunoelectron microscopy. Vibratome sections were processed
as for light microscopy, except that Triton X-100 was omitted from all
solutions, and tissue was permeabilized by incubation in 50% ethanol
in TBS for 30 min before blocking. In some experiments, the
immunoperoxidase stain was developed in the presence of 0.02% NiCl.
Immunoreacted sections were washed in phosphate buffer, osmicated (1%
osmium tetraoxide in 0.1 M phosphate buffer, pH 7.4, 1 hr),
stained with 1% aqueous uranyl acetate (1 hr), dehydrated through
ethanol and propylene oxide, and flat-embedded in Epon on plastic
slides under Aclar coverslips. Silver-gold (~80 nm) thin sections
were cut from selected regions of the dentate gyrus and hippocampus and
collected on Butvar-coated single-slot grids. Thin sections were
examined using a JEOL 100CX electron microscope without poststaining or
after staining with Reynolds lead and photographed at 5600-19,000×
magnification. Preliminary experiments compared the staining pattern
associated with PG and PGP fixatives and NiCl enhancement. PGP
perfusion resulted in improved preservation of tissue ultrastructural
features but reduced penetration of immunostaining reagents. NiCl
enhancement resulted in a peroxidase reaction product that was denser
and less diffuse under electron microscopy. Optimal staining and
structural preservation were obtained under the following conditions:
PGP perfusion, NiCl enhancement, and collection of thin sections near
the surface of embedded tissue blocks for examination under the
electron microscope.
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RESULTS |
Kv1.4 localization by light and confocal microscopy
Light microscopic examination of transverse rat brain sections
stained for Kv1.4 by immunoperoxidase methods revealed a distinctive pattern that appeared to respect well known layer boundaries within both the dentate gyrus and hippocampus proper (Fig.
1A,B).
Thus, in the dentate gyrus (Fig. 1C), intense staining was
present in the middle third of the molecular layer, where perforant
path input from the medial entorhinal cortex is received. Heavy
staining also was noted in the region of the polymorphic layer
immediately below the granule cell layer, where the granule cell axons
collect to form the mossy fiber tract and produce branches that
innervate hilar interneurons. Staining was lighter in the outer
molecular layer (where lateral entorhinal cortex input is received) and lighter still in the inner molecular layer and granule cell layer (where associational and commissural inputs onto granule cells are
received).
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Figure 1.
Kv1.4 is localized to the dentate gyrus middle
molecular layer and to stratum lucidum. A, View of the
dorsal hippocampus at low magnification after immunoperoxidase staining
for Kv1.4. Reaction product is highest in the middle molecular layer,
the polymorphic layer, and stratum lucidum. B, Drawing
indicating the major tissue layers, the principal excitatory neurons,
and their synapses. Pathways labeled are pp, the
perforant (entorhinal-hippocampal) path; mf, the mossy
fiber tract; com, the commissural path; and sc, the Schaffer collateral path. Layers of the dentate
gyrus are labeled ml, the molecular layer;
gcl, the granule cell layer; and pml, the
polymorphic, or hilar, layer. Layers of the hippocampus are labeled
so, stratum oriens; sp, stratum
pyramidale; sr, stratum radiatum; slm,
stratum lacunosum-moleculare; and sl (in CA3 only), stratum lucidum. C, View of a portion of dentate gyrus
at higher magnification. Layers are labeled as in B, but the molecular
layer is divided into inner, middle, and outer regions
(iml, mml, and oml). Kv1.4 staining is present in several
layers, and is highest in the mml and pml. Mml staining has a fine,
homogeneous appearance. D, View of a portion of CA3 at
higher magnification. Kv1.4 staining within sl has a patchy or punctate
appearance (arrows) different from that seen in the mml.
E, View of a portion of distal CA3 at higher
magnification. In this region, Kv1.4 immunoreactivity (arrow) exhibits a fibrillar appearance different from
that seen in D. Scale bars: A, 0.25 mm;
C, E, 30 µm; D, 50 µm.
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In the hippocampus, staining in stratum lucidum was intense and filled
most of the layer. Staining also was noted in some areas within stratum
pyramidale. This CA3 staining, however, was variable in appearance and
unlike the more homogeneous staining seen in the middle molecular
layer. In some areas, the immunoreactivity appeared in irregularly
shaped patches (2-10 µm) (Fig. 1D); in other
areas, the antibody appeared to stain fibers or fiber bundles (Fig.
1E). Staining was lighter in stratum oriens and
stratum radiatum of both CA3 and CA1.
The distribution of Kv1.4 immunoreactivity observed in the dentate and
CA3 regions by light microscopy led us to hypothesize that
Kv1.4-containing channels in these regions might be expressed primarily
by glutamatergic neurons and perhaps in axons and terminals. The
combination of fibrillar and punctate immunostaining seen with
anti-Kv1.4 sera in the stratum lucidum of CA3 is reminiscent of the
appearance of intracellularly filled mossy fibers (Claiborne et al.,
1986; Dailey et al., 1994), which form large (up to 10 µm in
diameter) mossy fiber presynaptic expansions in this layer. Similar
punctate staining also is seen in material immunostained for
synaptophysin, which is associated with synaptic vesicles that fill the
mossy fiber expansions (Grabs et al., 1994). To clarify whether the
stratum lucidum puncta seen in Kv1.4-stained material reflected
staining of presynaptic mossy fiber expansions, we performed confocal
microscopy on tissue sections double-labeled by reaction with a
monoclonal anti-synaptophysin antibody and rabbit anti-Kv1.4
antisera.
Confocal images of the CA3 region stained for synaptophysin were
similar to those stained for Kv1.4 (Fig.
2A,B).
Both proteins appeared to be expressed at high levels within patches in
stratum lucidum and at lower levels within other strata. However,
double labeling revealed little overlap in the synaptophysin and
Kv1.4-immunoreactive patches in stratum lucidum (Fig. 2C).
Thus, it appeared that the Kv1.4-containing patches did not correspond
to mossy fiber expansions.
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Figure 2.
A-F, Localization
of Kv1.4 and synaptophysin by confocal microscopy. A,
Synaptophysin immunoreactivity in CA3. Immunofluorescence occurs at
high density in patches within sl. Expression is lower in sr and sp.
B, Kv1.4 immunoreactivity in CA3. Within sl, pattern appears similar to that observed for synaptophysin. C,
Superimposition of A and B. Kv1.4
and synaptophysin patches in sl are largely noncoinciding.
D, Synaptophysin expression in the dentate.
Immunoreactivity occurs in fine puncta throughout the molecular layer.
Signal intensity is oml > mml, iml > gcl. E,
Kv1.4 expression in the dentate. Signal intensity is mml > oml > iml > gcl. F, Superimposition of
D and E. Scale bar, 25 µm.
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In the dentate gyrus, confocal images of Kv1.4-stained tissue exhibited
a laminar pattern of expression similar to that seen in
immunoperoxidase-stained material, with highest expression within the
middle molecular layer (Fig. 2E). Synaptophysin
immunoreactivity was strong throughout the molecular layer but was most
abundant in the outer rather than in the middle third (Fig.
2D). In contrast to the large, isolated patches of
synaptophysin (Fig. 2A) and Kv1.4 (Fig.
2B) immunofluorescence seen in stratum lucidum,
staining in the dentate occurred in small, evenly distributed puncta.
This probably reflected the fact that perforant path axons pass through the molecular layer as individual axons or very small fasciculi and
form small (~1 µm) termini (Laasch and Cowan, 1966; Matthews et
al., 1976). Although in merged images from double-labeled confocal sections, the distribution of two markers appeared to overlap extensively (Fig. 2F), higher resolution imaging
would be required to determine whether this represented colocalization
within termini.
Immunoelectron microscopy
At the level of light microscopy, Kv1.4 distribution in the
molecular layer of the dentate gyrus appeared different from that in
stratum lucidum of CA3. In the middle molecular layer, Kv1.4 staining
was rather homogeneous over the entire region that contained terminals;
in stratum lucidum, it appeared fibrillar and patchy and seemed to
arise from structures distinct from nerve terminals. To characterize
the subcellular localization of the channel in these regions better, we
examined sections reacted with Kv1.4 antibodies using the electron
microscope.
Dentate gyrus
Thin sections of regions of the dentate gyrus cut from
immunoreacted material exhibited the well described ultrastructural features of the region (Laasch and Cowan, 1966; Matthews et al., 1976).
Within the middle molecular layer, the largest profiles within sections
were the lightly contrasted, microtubule-filled distal portions of
dendrites. Clustered in spaces between these dendrites were the smaller
profiles of spines, myelinated and unmyelinated axons, and presynaptic
boutons. Figure 3A provides an
orienting drawing indicating the region selected for analysis (compare
with Fig. 1). Figure 3B illustrates the typical spatial relationship between the granule cells, their dendrites, and perforant path derived afferents. Kv1.4 immunoreactivity appeared to be exclusively presynaptic, associated with axons and termini, but not
with dendrites or spines (Figs. 3, 4).
Within transversely sectioned axons, Kv1.4 staining sometimes filled
profiles homogeneously, but often was associated asymmetrically with a
portion of the cell membrane (Fig. 3C,D). Axons
sectioned lengthwise revealed a patchy, discontinuous distribution of
Kv1.4 immunoreactivity, which sometimes adjoined vesicle-filled axonal
dilations where en passante synapses were seen (Fig. 3D).
Patches of reaction product also were noted within small myelinated
fibers in the molecular and polymorphic layers (Fig.
3F). Kv1.4 immunoperoxidase staining was observed
within synaptic boutons (Fig. 4). The dense stain was associated
asymmetrically with a portion of the cell membrane. In many cases, the
Kv1.4-immunopositive boutons appeared clearly as asymmetric, Gray's
type 1 (excitatory) synapses onto spines (Fig.
4B-E). Immunopositive synapses exhibited
the simple (Fig. 4C-E) or complex (Fig.
4B) morphologies described previously for the
perforant path-derived synapses of this region (Laasch and Cowan, 1966;
Matthews et al., 1976). The immunoperoxidase stain occasionally
appeared to arise near the presynaptic active zone (Fig.
4D). More typically, it arose from the axonal neck or
a portion of the nerve terminal membrane within the synaptic bouton
distant from the active zone (Figs. 3D,
4B,C, E).
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Figure 3.
Immunoelectron microscopic localization of
Kv1.4 on axons within the dentate gyrus. A,
B, Schematic drawings indicating the area depicted in
electron micrographs in C-E and Figure
4. Box within A contains a portion of the
dentate molecular and granule cell layers and is expanded as
B; box within B encloses
the middle molecular layer alone and includes representations of the
main features contained within the accompanying electron micrographs: dendrites of granule cells that flank smaller profiles of perforant path-derived axons, their termini, and spines. C, Axon
sectioned longitudinally exhibits membrane-associated puncta of
immunoreaction product at three locations (arrowheads).
Also notable within the stained axon are microtubules and a dense core
granule (arrow). D, An axon (course
indicated by white arrowheads) in longitudinal section
synapses with an unlabeled spine. Label (dark arrowhead) is present in an axon near the synapse. Two small profiles in cross
section are also labeled (dark arrowheads).
E, Small labeled and unlabeled profiles in cross section
crowded between two longitudinally sectioned dendrites. Labeled
profiles (1-4) are of variable size, contain
synaptic vesicles, and may represent portions of axons at various
distances from termini. F, A small myelinated axon sectioned obliquely contains dense reaction product associated with the
cell membrane (polymorphic layer). Den, Dendrite;
mit, mitochondrion; s, spine;
sv, synaptic vesicles. Scale bars, 0.5 µm.
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Figure 4.
Kv1.4 localization within presynaptic termini in
the middle molecular layer. A, Drawing based on the
micrograph shown in B. B, Single, complex
terminal forming three synapses with two spines. Immunoreaction product
(arrowhead) appears to arise from portion of terminal
membrane opposite from synaptic active zones. C,
Membrane-associated stain is detected within two presynaptic termini.
Within one (T1), reaction product is near, but
apparently not within an active zone. The second labeled terminal (T2)
synapses with two spines. Reaction product (arrowheads)
also is noted within an axon (ax) seen in longitudinal
section and associated with the membrane of another profile that
contains clear synaptic vesicles and dense core granules.
D, Cluster of three synapses. In one terminal
(T1), reaction product appears to arise from the
membrane at the active zone. E, Stain in a small profile
of a presynaptic terminal. Scale bars, 0.2 µm. Abbreviations are as
in Figure 3.
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CA3
Within stratum pyramidale of CA3, Kv1.4 immunoreactivity was
associated with the cytoplasmic aspects of the endoplasmic reticulum of
pyramidal cells but not the cell membrane. Stratum lucidum contained
three principal structures: pyramidal cell dendrites, tightly packed
fasciculi of mossy fiber axons, and synaptic complexes (Fig.
5B). The mossy fiber-CA3
synaptic structures, as described previously (Blackstad and Kjaerheim,
1961; Laasch and Cowan, 1966; Claiborne et al., 1986; Chicurel and
Harris, 1992), consisted of unusual presynaptic expansions complex,
multilobulated profiles, filled with synaptic vesicles, in association
with the so-called "thorny excrescences"the complex spines
and spine branches of the CA3 pyramidal cells. Tightly fasciculated
groupings of mossy fiber axons frequently were located near these
synapses. Although the individual axons were small (diameters of
0.2-0.5 µm), fasciculi typically contained ~100-200 axons, giving
an overall size similar to that of an individual presynaptic
expansion.
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Figure 5.
Kv1.4 localization in the stratum lucidum of
CA3. A, B, Schematic drawings indicating
the area depicted in electron micrographs. Box within
A encloses a portion of stratum pyramidale and stratum lucidum and is expanded as B; box within
B encloses representations of main features of the
accompanying electron micrographs: large proximal dendrites of
pyramidal cells are flanked either by fasciculi of mossy fiber axons or
by synaptic structures formed by mossy fiber expansions and complex
pyramidal cell spines. C, Labeled axons within a mossy
fiber fasciculus (MF fasc) pass between a CA3 pyramidal
cell soma (soma) and the proximal dendrite
(den) of another pyramidal cell. D, Lower
magnification view of stratum lucidum containing a mossy fiber
fasciculus with transverse and obliquely sectioned mossy fibers, a
pyramidal cell dendritic branch (den), and a "synaptic
complex" consisting of multiple spine branches (s) derived from a pyramidal cell "thorny
excrescence" and synaptic vesicle-filled, multilobulated mossy fiber
expansions (MFE). Numerous stained axons in cross
section are noted (solid arrowheads). Another axon,
sectioned lengthwise, is stained heavily near its transition into a
mossy fiber expansion (open arrowheads).
E, A longitudinally sectioned axon within a mossy fiber
fasciculus contains immunoreaction product near the site of origin of
a presynaptic expansion. F, Stained small axon
sectioned longitudinally. MT, Microtubule. Scale bars:
C, D, 0.5 µm; (0.25 µm in
D, inset); E, 0.2 µm;
F, 0.2 µm.
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Kv1.4 immunoreactivity was observed most frequently within the
fasciculated mossy fiber axons (Fig. 5C,D). Axons
sectioned transversely sometimes appeared to be filled homogeneously
with immunoperoxidase stain, but in many cases, dense stain appeared to
be associated asymmetrically with the cytoplasmic side of a portion of
the axonal membrane (Fig. 5D, inset). Axonal
profiles captured in a more lengthwise orientation sometimes appeared
to be filled for >1 µm with reaction product, but more often there were smaller patches (<1 µm) of staining that either filled the axon
(Fig. 5F) or were associated asymmetrically with the
membrane on one side. Prominent Kv1.4 immunoreactivity also was noted
at portions of axons immediately adjacent to expansions (Fig.
5D,E; see Discussion).
Kv1.4 immunoreactivity was rarely observed associated with the
membranes of the mossy fiber expansions. When such staining was noted,
it appeared to be present at a narrow point within the expansion lying
between two or more larger, vesicle-filled areas. However, Kv1.4
immunoreactivity was not observed at or immediately adjacent to
presynaptic release sites and was absent from dendritic branches and
spines of the CA3 pyramidal cells.
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DISCUSSION |
The neuronal cell membrane may be viewed as consisting of several
distinct functional domains. The contribution made by an ion channel
protein to the cell depends both on the intrinsic properties of the
channel and on the particular subcellular location where it is inserted
into the cell membrane (Llinas, 1988). A growing body of evidence
suggests that the electrical properties of each neuronal type are
regulated through precise control of the membrane localization of
channels and receptors at specific sites within subcellular domains
(Baude et al., 1993; Wang et al., 1993; Laube et al., 1996; McNamara et
al., 1996; Alonso et al., 1997). We have found that Kv1.4 is expressed
within the hippocampal formation on axons and within or near the
presynaptic termini of two types of excitatory neurons. Within the
dentate gyrus molecular layer, Kv1.4 immunoreactivity is detected
within both the preterminal, unmyelinated portions of the perforant
pathway axons and their presynaptic boutons. In CA3, Kv1.4
immunoreactivity is prominent in the densely packed fasciculi of the
mossy fiber axons and can be observed adjacent to the mossy fiber
terminal expansions. However, we did not detect Kv1.4 staining
associated with the membranes of the large expansions where transmitter
release sites are found.
Kv1.4 is localized in the hippocampus on unmyelinated axons of
glutamatergic neurons
We found evidence for Kv1.4 expression by glutamatergic neurons
forming axodendritic synapses in the hippocampus but not for expression
by inhibitory neurons forming axosomatic synapses. Although staining
was seen associated with myelinated fibers (e.g., Fig.
3F), the most abundant staining was associated with
unmyelinated fibers. Previous studies using degeneration methods
suggest that at least 70% of the excitatory synapses found within the
outer two-thirds of the dentate molecular layer represent perforant path input onto granule cell dendrites (Matthews et al., 1976). Furthermore, these synapses exhibit characteristic morphology that is
identified readily in thin sections (Laasch and Cowan, 1966). For these
reasons, it is highly likely that the stained profiles we observed in
the molecular layer represent, at least in large part, perforant
path-derived axons and termini. The identification of the stained axons
seen in CA3 as mossy fibers is unambiguous because of the
characteristic appearance of the mossy fiber fasciculi and synaptic
expansions.
The function and distribution of voltage-gated ion channels along
vertebrate axonal membranes have been studied most extensively in the
case of peripheral myelinated axons (Hille, 1992; Ritchie, 1995). On
these axons, the nodes of Ranvier possess sodium channels at high
density but few voltage-gated potassium channels. The rapid
repolarization of the action potential appears to result from a high
resting conductance. Voltage-gated potassium channels are present at
greatest density at and near paranodal regions (Chiu and Schwartz,
1987; Wang et al., 1993; Mi et al., 1995), where they may provide a
more specialized function facilitating the propagation of the action
potential from node to node. Much less has been learned about the
function and distribution of voltage-gated channels on central
unmyelinated axons (Waxman, 1995). Freeze-fracture images of these
axons exhibit at far lower density the intramembranous particles
thought to represent channels and other membrane proteins (Black et
al., 1981). We have found patches of Kv1.4 immunoreactivity along the
unmyelinated axons in both perforant path and mossy fiber tracts,
suggesting that rapidly inactivating voltage-gated potassium channels
(A-type) are present on these unmyelinated axons of central
neurons.
A-type channels expressed on the somatodendritic portions of
neuronal membranes play key roles in the process that transforms graded
excitatory and inhibitory influences into a coded pattern of action
potential firing (Connor and Stevens, 1971; Neher, 1971; Hoffman et
al., 1997). Most axonal preparations used in physiologic studies lack
A-type channels; these axons propagate action potentials presented to
them, but are unable to respond in graded fashion to stimuli of
different intensities (Guttmann and Barnhill, 1970; Hille, 1992). By
contrast, the lightly myelinated axons of crustacean motor neurons
possess A-currents that underlie their ability to fire at different
frequencies in response to stimuli of different intensities (Hodgkin,
1948; Connor, 1975). Recent experiments using hippocampal slices
indicate that axonal A-type channels may regulate the efficiency with
which somatically recorded action potentials reach distal axonal
branches and evoke neurotransmitter release (Debanne et al., 1997). Our
anatomical studies provide additional evidence that, for some mammalian
central neurons, axonal functions may not be limited to faithful action
potential propagation. Axons may contribute dynamically, along with
somatodendritic domains, to the determination of firing frequency.
Kv1.4 is localized at nerve termini in the dentate
molecular layer and near mossy fiber termini within CA3
Within the outer two-thirds of the dentate molecular layer,
perforant path axons form small (~1 µm) termini that synapse on small spines derived from the distal dendrites of the granule cells.
The small size of these Kv1.4-immunopositive termini make direct study
of their electrophysiologic properties difficult. Studies using
unusually large termini in invertebrates and vertebrates have shown
that calcium entry and, therefore, the amount of neurotransmitter release are sensitive functions of action potential duration. Presynaptic voltage-gated potassium channels in these preparations play
key roles in the determination of action potential duration (Augustine,
1990; Jackson, 1991; Byrne and Kandel, 1996). The presence of Kv1.4
immunoreactivity within termini in the middle molecular layer suggests
that Kv1.4 may contribute to the electrical properties of these termini
and, therefore, the process of neurotransmitter release.
The mossy fiber-CA3 pyramidal cell synapses exhibit very different
morphology from those found in the middle molecular layer. Although
each mossy fiber axon traverses the entire length of CA3, it forms
synaptic contacts with only a small number of CA3 pyramidal cells.
These synapses are clustered at large, multilobulated expansions that
occur at regularly spaced intervals (~100 µm) along the length of
each mossy fiber axon. We found Kv1.4 immunoreactivity associated with
mossy fiber axons, including "neck" portions of axons adjacent to
synapse-bearing expansions. The mossy fiber expansions themselves,
however, did not exhibit Kv1.4 immunoreactivity. Thus, Kv1.4 may help
shape the propagated mossy fiber action potential and may regulate the
efficiency with which the action potential may invade particular
presynaptic expansions. Recent experiments involving the metabotropic
glutamate receptor mGluR2, which also appears to be targeted to the
axonal necks near mossy fiber termini, suggest that this localization
is sufficiently close to release sites to strongly influence
neurotransmission (Yokoi, 1996).
Structural and functional implications
Our ability to draw conclusions regarding the functional role
played by the Kv1.4-containing channels localized by our studies is
limited by the present uncertainty regarding the complete subunit composition of the channels. Channels formed by coexpression of Kv1.4
with other Shaker family subunits exhibit voltage-dependent and kinetic properties that are qualitatively similar to, although quantitatively different from, those formed by Kv1.4 subunits alone (Po
et al., 1993; Rettig et al., 1994; Heinemann et al., 1996). In rat
brain, it has been shown that some Kv1.4 subunits form heteromeric
channels with Kv1.2 (Sheng et al., 1993) and Kv 1/2 (Rhodes et al.,
1995). Within the dentate gyrus, Kv1.2 immunoreactivity has been
observed within the middle molecular layer by light microscopy and
within axons and excitatory presynaptic termini by electron microscopy
(Sheng et al., 1994; Wang et al., 1994). Kv1.1, Kv1.2, Kv1.3, Kv1.6,
and Kv1/2 immunoreactivity have been detected within stratum lucidum
by light microscopy (Sheng et al., 1993; Rhodes et al., 1995; Veh et
al., 1995). Double-immunolabeling studies using electron microscopy may
clarify whether the Kv1 family channels expressed on the
entorhinal-hippocampal axons and termini and mossy fiber axons are
likely to include heteromers of these subunits. Interestingly, SAP-97,
a member of the family of membrane-associated guanylate kinase scaffold
proteins, has been shown by immunoelectron microscopy to be expressed
in dentate molecular layer excitatory termini and mossy fiber axons;
staining of mossy fiber expansions was not reported (Muller et al.,
1995). It would be of interest to determine whether Kv1.4 and SAP-97 are associated in these locations and, if so, what other, if any, proteins are held near Kv1.4 via interaction with SAP-97s SH3, PDZ, and
GK domains.
When expressed in heterologous systems, Kv1.4 is inhibited by phorbol
esters and by transmitter receptors linked to activation of protein
kinase C (Okada et al., 1992; Murray et al., 1994). Metabotropic
neurotransmitter receptors linked to protein kinase C are richly
expressed in the hippocampal formation (Amaral and Witter, 1995), but
their cell type and subcellular localizations are only beginning to be
described in detail (Baude et al., 1993; Shigemoto et al., 1993; Levey
et al., 1995). Whether this form of regulation of Kv1.4 activity occurs
in the hippocampus may be clarified by additional studies.
A second noteworthy feature of heterologously expressed Kv1.4 is its
fast inactivation and long-lasting desensitization. The kinetics and
molecular mechanisms underlying these features have been studied in
detail (Ruppersberg et al., 1991; Baukrowitz and Yellen, 1995; Liu et
al., 1996; Roeper et al., 1997). These properties make Kv1.4 an
obligate integrator of brief depolarizations, such as those associated
with propagated action potentials, over periods as long as tens of
seconds. It would be predicted that the action potentials propagated
along axons bearing Kv1.4 channels would broaden when firing
frequencies increased sufficiently to induce Kv1.4 inactivation and/or
desensitization.
The rapid onset and delayed recovery of Kv1.4 inactivation is of
particular interest in view of the prominent frequency-dependent plasticity of the mossy fiber synapses and the proposed contribution of
these synapses to hippocampal network function. Mossy fiber synapses
studied in slice preparations exhibit robust enhancement of synaptic
transmission during repetitive stimulation, called frequency
facilitation (Regehr et al., 1994; Salin et al., 1996). Like the
inactivation of Kv1.4, mossy fiber frequency facilitation occurs at low
stimulus frequencies between 0.025 and 0.33 Hz.
In models of hippocampal function, mossy fiber input plays a key role,
introducing fragments of sensory experience into the autoassociative
CA3-CA1 network, where they are processed into stable, multimodal
memories (Rolls, 1990). It will be interesting to determine in future
experiments whether Kv1.4 is involved in mossy fiber short-term
frequency-dependent plasticity and thereby, perhaps, contributes to the
discrimination between those stimuli associated with experience of
sufficient importance for storage in memory and those that are not.
| |
FOOTNOTES |
Received Sept. 29, 1997; revised Nov. 19, 1997; accepted Nov. 19, 1997.
This research was supported by National Institute of Neurological
Diseases and Stroke (NINDS) Grant NS01755, a Pfizer Postdoctoral Fellowship in Neuroscience, and an American Academy of
Neurology/Parke-Davis Young Investigator Award to E.C.C. A.M. was
supported by NINDS Grant NS23347 to H.J. Ralston. Y.N.J. and L.Y.J.
were supported by National Institute of Mental Health Grant MH48200 to
the Silvio Conte Neuroscience Center at the University of California
San Francisco. Y.N.J. and L.Y.J. are Howard Hughes Medical Institute Investigators. D.H.L. was supported by NINDS Grants NS32062 and NS35628
and a Klingenstein Fellowship in the Neurosciences. We thank Drs.
X. W. Meng, S. M. Hersch, H. J. Ralston III, P. T. Ohara, and R. A. Nicoll for helpful discussions.
Correspondence should be addressed to Dr. Daniel H. Lowenstein,
Department of Neurology, Box 0435, University of California San
Francisco, San Francisco, CA 94143.
| |
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A. M. Tiffany, L. N. Manganas, E. Kim, Y.-P. Hsueh, M. Sheng, and J. S. Trimmer
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Top
Abstract
Introduction
