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Volume 16, Number 21,
Issue of November 1, 1996
pp. 6676-6686
Copyright ©1996 Society for Neuroscience
Axonal Action-Potential Initiation and Na+ Channel
Densities in the Soma and Axon Initial Segment of Subicular Pyramidal
Neurons
Costa M. Colbert and
Daniel Johnston
Division of Neuroscience, Baylor College of Medicine, Houston,
Texas 77030
 ABSTRACT
- INTRODUCTION
- MATERIALS AND METHODS
- RESULTS
- DISCUSSION
- FOOTNOTES
- REFERENCES
ABSTRACT 
A long-standing hypothesis is that action potentials initiate first
in the axon hillock/initial segment (AH-IS) region because of a
locally high density of Na+ channels. We tested this idea
in subicular pyramidal neurons by using patch-clamp recordings in
hippocampal slices. Simultaneous recordings from the soma and IS
confirmed that orthodromic action potentials initiated in the axon and
then invaded the soma. However, blocking Na+ channels in
the AH-IS with locally applied tetrodotoxin (TTX) did not raise the
somatic threshold membrane potential for orthodromic spikes. TTX
applied to the axon beyond the AH-IS (30-60 µm from the soma)
raised the apparent somatic threshold by ~8 mV. We estimated the
Na+ current density in the AH-IS and somatic membranes by
using cell-attached patch-clamp recordings and found similar magnitudes
(3-4 pA/µm2). Thus, the present results suggest that
orthodromic action potentials initiate in the axon beyond the AH-IS
and that the minimum threshold for spike initiation of the neuron is
not determined by a high density of Na+ channels in the
AH-IS region.
Key words:
action potential;
action-potential initiation;
Na+ channel;
patch-clamp recording;
hippocampus;
pyramidal
neuron;
single-channel recording;
dual-electrode recording
INTRODUCTION
An important aspect of neuronal integration is the
transformation of information in the form of membrane potential to
all-or-none action potentials for communicating with other cells and
for signaling within the dendritic tree of the neuron. Where this
conversion occurs in the neuron has important implications for the
function of a neuron (Levy et al., 1990 ; Jaslove, 1992; Softky and
Koch, 1993; Shadlen and Newsome, 1994). Classic work on the motoneuron
(Araki and Otani, 1955; Coombs et al., 1957; Fuortes et al., 1957)
suggested that action potentials initiate in the initial segment/axon
hillock region of the neuron, presumably because of a more negative
transmembrane potential threshold for action-potential initiation in
this region than in the soma. Although the site of initiation under all
conditions is not completely resolved in cells with active dendrites
(Adams, 1992; Johnston et al., 1996), much recent evidence from
pyramidal and other neurons supports the classical notion that action
potentials initiate first in the axon and then propagate into the soma
and dendrites (Turner et al., 1991; Jaffe et al., 1992; Stuart and
Sakmann, 1994; Häusser et al., 1995; Spruston et al., 1995).
Why would the action potential initiate first in the initial segment?
Dodge and Cooley (1973) suggested that a high local density of
Na+ channels would lower the threshold membrane potential,
speculating a density as high as in the nodes of Ranvier. Indeed,
electron microscopists had identified membrane similarities between the
initial segment and the nodes (Palay et al., 1968; Peters et al.,
1968). Later modeling studies provided theoretical justification for
such a high density, making strong predictions about the overall firing
threshold of the neuron and the ability to backpropagate an action
potential into the soma (Moore et al., 1983; Traub et al., 1994; Mainen
et al., 1995).
We wished to test the hypothesis that a high local density of
Na+ channels in the initial segment determines the minimum
threshold of the neuron for action-potential initiation. Using
video-enhanced differential interference (DIC) microscopy in brain
slices (Stuart et al., 1993), we identified somata and initial segments
of subicular pyramidal neurons. We recorded Na+ currents
from these structures by using cell-attached patch-clamp techniques
and, to our surprise, found no large regional difference in
Na+ channel density. Thus, we recorded simultaneously from
initial segments and somata, verifying that orthodromic action
potentials initiate in the axon. Finally, as a first step in
determining the mechanisms of axonal initiation, we explored the
relationship between local Na+ channel density and the
lowest threshold of the neuron for action-potential initiation. By
locally applying tetrodotoxin (TTX) to block Na+ channels,
we found that Na+ channels in the axon, but not in the
initial segment, determine the minimum threshold for action-potential
initiation. Thus, the results suggested that action potentials initiate
in the axon at some distance from the soma and that the local density
of Na+ channels in the axon hillock/initial segment, which
is not high, does not determine the lowest threshold of the neuron for
action-potential initiation.
MATERIALS AND METHODS
Preparation and solutions. The present study used 2- to 8-week-old Sprague Dawley rats of both sexes. Older
animals were anesthetized with a lethal dose of a combination of
ketamine, xylazine, and acepromazine. Once deeply anesthetized, they
were perfused through the heart with cold modified artificial
cerebrospinal fluid (ACSF) containing (in mM): 124 NaCl,
2.5 KCl, 1.2 NaH2PO4, 25 NaHCO3,
0.5 CaCl2, 7.0 MgCl2, and 20 dextrose and
bubbled with 95%O2/5%CO2. In some animals,
110 mM choline chloride was substituted for NaCl. This
procedure aided visualization during recording and decreased background
blood vessel staining in slices prepared for neuron reconstructions.
Young pups were decapitated consciously. After removal of the brain,
300- to 400-µm-thick slices were cut using a Vibratome (Lancer),
incubated submerged in a holding chamber for 30 min at 32°C, and
stored submerged at room temperature. Except where otherwise noted, all
recordings were made submerged at room temperature (~24°C in bath).
During the slicing procedure, the slices were maintained in the same
ACSF as used for the perfusion. The holding chamber solution contained
(in mM): 120 sucrose, 64 NaCl, 2.5 KCl, 1.2 NaH2PO4, 25 NaHCO3, 1.5 CaCl2, 3.5 MgCl2, and 20 dextrose and was
bubbled with 95%O2/5%CO2. The external
recording solution contained 124 NaCl, 2.5 KCl, 1.2 NaH2PO4, 25 NaHCO3, 2.0 CaCl2, 1.0 MgCl2, and 20 dextrose and was
bubbled with 95%O2/5%CO2. In
experiments where antidromic stimuli were delivered, kynurenic acid
(5-10 mM, Sigma, St. Louis, MO) was added to the external
solution to block synaptic activation evoked by the stimulus. The
internal pipette solution used for whole-cell recordings contained (in
mM): 120 K-gluconate, 20 KCl, 10 HEPES, 0.4 EGTA, 4.0 NaCl,
4.0 MgATP, 0.3 MgGTP, and 14 phosphocreatine adjusted to pH 7.25 with
KOH. The internal pipette solution for cell-attached patch recordings
contained (in mM): 120 NaCl, 30 tetraethylammonium
chloride, 10 HEPES, 2 CaCl2, 3 KCl, 1 MgCl2,
and 5 4-aminopyridine (4-AP) adjusted to pH 7.4 with NaOH.
CdCl2 (200 µM) was included in the solution
in approximately one-third of the pipettes.
Recording techniques. Recordings were made from somata and
initial segments of subicular pyramids just beyond the end of the
hippocampal CA1 cell layer in horizontal hippocampal slices. Neurons
were visualized using infrared differential interference contrast (DIC)
optics (Axioskop, Ziess, Oberkochen, Germany) according to standard
techniques (Stuart et al., 1993). Patch-clamp recordings in the
whole-cell mode were made using a microelectrode amplifier (Axoclamp
2A, Axon Instruments, Foster City, CA) using pipettes (3-5 M ) of
borosilicate glass (Drummond, Broomall, PA) coated with SYLGARD (Dow
Corning, Corning, NY) and pulled using a P-87 Flaming-Brown pipette
puller (Sutter Instruments, Novato, CA). Cell-attached patch recordings
were made using a patch-clamp amplifier with a capacitive headstage
(Axopatch 200A, Axon Instruments). The same pipette glass was used as
in the whole-cell recordings, but the pipettes had much smaller tips
(~0.5 µm, 8-10 M; see Fig. 1A). Whole-cell
recordings were low-pass-filtered at 3 kHz (6 dB/octave) and digitized
at 10 kHz except when the shape of the action potential was observed.
In these cases, a low-pass filter of 10 kHz and a sampling rate of 50 kHz was used. Cell-attached patch recordings were filtered at 2 kHz
(8-pole Bessel filter) and sampled at 10 kHz. Data were digitized at 16 bit resolution (ADC488/16, IOTech) and stored by computer for off-line
analysis (Next Computer). Antidromic action potentials were stimulated
by constant current pulses (Neurolog, Digitimer) through a monopolar
tungsten electrode (AM Systems) placed in the alveus.
Fig. 1.
Whole-cell patch and cell-attached patch
recordings from subicular pyramidal cells. A, Differential
interference contrast (DIC) image of soma and initial segment showing
the positions of the whole-cell somatic recording electrode
(upper right) and the cell-attached initial segment
recording electrode (lower right). B,
Morphological reconstruction of soma and basal portion of the cell
after biocytin filling and subsequent visualization. The identity of
the axon (black process) was verified by following its path
into the alveus. Cell 95066b.
[View Larger Version of this Image (44K GIF file)]
Identification of axons. Subicular pyramidal cells were
chosen over CA1 pyramids because the somata do not lie in a tight cell
layer. The tight packing of CA1 somata made visualization of the
relatively small axon initial segments (<2 µm in diameter)
difficult. Furthermore, many CA1 axons begin on basal dendrites rather
than on the soma. In DIC, the initial segment membrane appeared as an
extension of the somatic membrane and was the only basal structure
easily seen without cleaning. Basal dendrites were typically more
difficult to visualize until a pipette with positive backpressure was
lowered into the region of the initial segment, which had somewhat of a
cleaning action. In cells that we have found to be less healthy on the
basis of resting membrane potential and input resistance, basal
dendrites could not be distinguished clearly from the axon because of a
generalized increase in the contrast of the cell. We chose only
pyramidal cells that seemed to have only a single branch coming from
the soma approximately opposite and parallel to the apical dendrite. To
verify that our visual criteria could be used effectively to identify
axons, we filled the neurons with biocytin, using a second recording
pipette in whole-cell mode (Horikawa and Armstrong, 1988) after the
cell-attached path recordings were complete (n = 14). A
video image of the soma and initial segment was digitized and stored
for later comparison (see Fig. 1A). Slices were fixed
in 4% paraformaldehyde in phosphate buffer solution (0.1M,
pH 7.4), and the biocytin-filled neurons were visualized using
avidin-biotinylated horseradish peroxidase (Vectastain ABC kit, Vector
Labs, Burlingame, CA) complexed with 3,3 -diaminobenzidine
tetrahydrochloride (DAB kit, Vector Labs). All of the filled cells were
pyramidal in morphology, and axons were identified by following their
path to the alveus. Camera lucida drawings (see Fig.
1B) were made from video images taken at various
focal planes and rechecked in the microscope. Not all structures that
we assumed to be axons could be followed to the alveus but, instead,
came to an end at the surface of the slice. In such cases, there was
never another structure that reached the alveus. In all cells where the
axon could be positively identified, we had identified the axon
correctly. Thus, we are confident that the great majority of the patch
recordings was indeed made on initial segments.
Unfortunately, no definitive measure of the extent of the initial
segment exists to date for subicular pyramidal neurons. Thus, we
attempted to determine the length of the unmyelinated initial segment
by a modification of the extracellular biocytin technique (King et al.,
1989) suggested to us by Tamas Freund (personal communication). By
processing the tissue without detergent or freezing, myelinated axons
show greatly decreased staining, because the reagents must cross the
multiple lipid bilayers. We made three injections of biocytin (4%, 1.5 µl at each location) in each subiculum of urethane-anesthetized rats
(200 gm; n = 2). Coordinates were (in mm) from lambda
[1.5 anterior-posterior (AP), 2.5 medial-lateral (ML),  2.5
dorsal-lateral (DV) and 1.0 AP, 4.5 ML, 3.5 DV] and from bregma
(3.5 AP, 1.0 ML, 3.0 DV). Bite bar was at 0 mm. After survival
times of 5 and 12 hr, the rats were deeply anesthetized and then
transcardially perfused with 0.9% saline, followed by 10% formalin
and 4% paraformaldehyde. Coronal sections, 50 or 100 µm thick, were
cut by a vibratome. Sections were processed alternately with and
without detergent. In the sections processed with detergent, many
stained fibers could be seen in the alveus and in the terminal zones of
the perforant path. Much less staining of the alveus was seen in the
sections processed without detergent. Using the same criteria for
choosing cells and initial segments as described above, we identified
initial segments and measured their lengths (19.9 ± 0.75 µm;
mean ± SEM, range 15-30 µm; n = 34). Beyond
this length, staining of the axon was either not visible or just
faintly visible as a hairline. Axons beyond the initial segment in
sections processed with detergent, on the other hand, were more darkly
stained and could often be followed to the alveus. Although this method
is not unequivocal because of limitations on identifying axons,
possible variations in thickness of the myelin, et cetera, the results
suggest that the axons of the subicular pyramidal neurons are
myelinated beyond an initial segment of ~20 µm. These results
seem consistent with the electron microscopic data of Farinas
and DeFelipe (1991) in cortical pyramidal neurons and with
the extent of axoaxonic contacts on the proximal axon of subicular
pyramids (Somogyi et al., 1982).
RESULTS
Estimates of sodium channel densities in initial segment
and soma
To test the hypothesis that the density of Na+
channels in the initial segment is greater than that in the soma, we
directly measured Na+ currents through the initial segment
and somatic membranes by using cell-attached patch-clamp techniques
(Stuart et al., 1993; Magee and Johnston, 1995b). Axon initial segments
were identified for recording based on morphology as visualized, using
DIC optics (Fig. 1A). Neurons were
subsequently filled with biocytin and reconstructed so that an
unequivocal identification of the axon could be made (Fig.
1B; see Materials and Methods). As a test that we
were indeed recording from the pyramidal cell axon and not some other
cell (e.g., glia), we ruptured the patch immediately after making the
seal in five consecutive cells. An action potential could always be
recorded. At the end of each patch recording, we attempted to break
into the cell to establish the resting potential and to verify that an
action potential could be evoked. In approximately one-fourth of the
patches we were unsuccessful in gaining access to the cell.
Na+ channel activity in cell-attached patches was
identified as fast inward current with voltage-dependent kinetics.
Depolarizing steps from a holding potential of 90 mV to a command
potential of approximately 10 mV yielded synchronous activation of
the Na+ channels in the patch (Fig.
2A). Smaller depolarizing steps
(approximately 30 to 40 mV) evoked less synchronous initial
activation. In some trials, currents from additional openings could be
seen throughout the duration of the 50 msec command potential (more
probable in the smaller depolarizations; Fig. 2A).
The amplitudes of these currents were equal to or were small multiples
of a unitary current amplitude (i.e., current through a single open
Na+ channel). Plotting the unitary current amplitude versus
command potential (n = 7; Fig. 2B)
yielded a slope conductance of 14.8 pS and an extrapolated
Na+ reversal potential of +58 mV. Mg2+ (1 mM; n = 5) or Cd2+ (0.2 mM; n = 5) had no apparent effect on
channel activity.
Fig. 2.
Cell-attached recordings from axon initial
segment. A, Na+ channel activity after
depolarizing steps from 90 to 10, 30, and 40 mV.
Traces are individual consecutive sweeps. Note single
channel openings throughout the steps to 40 mV. Cell c95064. B,
I-V plot of Na+ channel activity. Unitary current
amplitudes are plotted as a function of membrane potential. The linear
regression crosses the membrane potential axis at +58 mV and has a
slope of 14.8 pS. Error bars are SEM. C, Summary of peak
Na+ currents in cell-attached patches from initial segment
(n = 27) and soma (n = 20). Peak
current per area of patch (pA/µm2) is plotted as a
function of the distance of the patch from the soma. The points at zero
distance correspond to somatic patches. The linear regression line
through all points has a slope of 0.018 pA/µm2 per
micrometer from soma.
[View Larger Version of this Image (25K GIF file)]
Comparisons of Na+ current density between cell-attached
patches on the soma (n = 20) and patches on the initial
segment (3-30 µm from the soma; n = 27) were made
using similar pipettes. Peak current was the maximum amplitude seen in
30-50 depolarizing steps to approximately 10 mV (Fig.
2A), and was normalized for the area of the patch
estimated visually. The initial 10 somatic recordings were divided into
two groups based on site: either central somatic or axon hillock. Axon
hillock sites were defined as those within 3 µm from the site of
attachment of the axon. No significant difference in peak current was
seen between the central somatic (3.29 ± 0.45 pA/µm2; n = 5) and axon hillock sites
(3.08 ± 0.51 pA/µm2; n = 5). The
remaining somatic recordings were made from the central somatic region.
Although there was some variability between patches, the peak current
per area did not increase as a function of distance from the soma
(m = 0.09; r2 = 0.17;
Fig. 2C). For comparison of the somatic and initial segment
peak currents, the animals were divided into two groups based on age:
pups ~2 weeks and older rats from 4-8 weeks. In the younger age
group, the peak current density in the soma was 2.9 ± 0.36 pA/µm2 (mean ± SEM; n = 10), and in
the initial segment it was 2.87 ± 0.33 (n = 18).
In the older age group, the peak current density in the soma was
3.2 ± 0.47 pA/µm2 (n = 10) and in
the initial segment it was 4.0 ± 0.35 pA/µm2
(n = 9). To convert from peak current density to the
density of Na+ channels in the membrane, we assumed that
the peak current represents synchronous opening of all the
Na+ channels in the patch. Thus, the number of channels in
the patch was the peak current divided by the unitary current amplitude
(current through a single open Na+ channel). From the
I-V plot (Fig. 2B), the unitary current
amplitude was ~1 pA at 10 mV. Thus, assuming an opening probability
of one at 10 mV and an accurate estimate of the patch area, the
density of Na+ channels was three to four channels per
micrometer squared throughout the somatic and initial segment
membrane.
The results of these measurements did not support the hypothesis of a
very high density of Na+ channels in the initial
segment/axon hillock region. Thus, we tested a number of hypotheses
related to the site of action-potential initiation, the sequence of
Na+ channel activation as the action potential invades the
soma, and the relative thresholds for the initiation of action
potentials in the axon and soma.
Sequence of action-potential invasion of the soma
We determined the sequence of invasion of the action potential
into the initial segment and soma by recording simultaneously from
these structures (Fig. 1). Axon initial segments were identified as
above using DIC optics (Fig. 1A; see Materials and
Methods). Current-clamp recordings from the soma were made in the
whole-cell configuration (Fig. 3; Soma
Vm; n = 5). The temporal derivative of
the membrane potential (Fig. 3; Soma
dVm/dt) was calculated to increase the
resolution of individual components of the action potential (Coombs et
al., 1957). Recordings from the initial segment were made in
cell-attached mode in voltage clamp. The transmembrane potential was
held near 0 mV to inactivate Na+ channels in the
patch. Thus, the cell-attached electrode recorded capacitive
transients across the membrane (Fig. 3; IS patch), which
were proportional to the temporal derivative of the membrane potential
(Magee and Johnston, 1995a). A comparison of whole-cell and
cell-attached recordings from adjacent sites on the soma verified that
this technique worked as expected (data not shown).
Fig. 3.
Sequence of antidromic action-potential (AP)
invasion of initial segment (IS) and soma. Dual-recording
electrode positions are as in Figure 1. Waveforms are individual
sweeps. Antidromic (1st), Left column shows
response to a single antidromic AP. Antidromic (2nd), Right
column is the response to the second of a pair of antidromic
APs. Soma Vm, Membrane potential recorded
through the somatic whole-cell electrode. Soma
dVm/dt, Time derivative of the somatic
membrane potential. IS patch, Cell-attached patch recording
in the IS. The current recorded is primarily capacitive and, thus, is
proportional to the time derivative of the transmembrane potential of
the patch. IS patch (failures), Cell-attached recordings in
the IS, in which the second antidromic action potential failed to
invade the soma. P1 corresponds to the peak in the response
attributable to charging of the patch by channels in the IS.
P2 corresponds to the charging of the patch by somatic
Na+ channels, which does not occur when the second somatic
AP fails. See text for details. RMP, 63 mV. Cell c95066a.
[View Larger Version of this Image (24K GIF file)]
To test the hypothesis that orthodromic action potentials initiate
somewhere in the axon and then propagate back into the soma, we
compared the sequence of charging of the initial segment and soma in
response to antidromic and orthodromic stimulation. If orthodromic
action potentials are actually initiated in the axon, then the sequence
of charging should be the same for both antidromic and orthodromic
action potentials. Recording simultaneously in the initial segment (IS)
and soma, antidromic action potentials were evoked by single shocks in
the alveus (Fig. 3, left panel; IS patch ~10
µm from soma). The action potential recorded in the soma (Figure 3;
Soma Vm) had a rising phase with two distinct
components, corresponding to two peaks, P1 and P2, in the derivative
(Figure 3; Soma dVm/dt). P1 was
always small relative to P2 in the somatic recordings. The two peaks
also appeared in the recording from the initial segment (Fig. 3;
IS patch), but compared with the peaks in the somatic
waveform, P1 was much larger relative to P2. This difference in
relative magnitude of the peaks corresponds to a much greater initial
rate of rise of the initial segment membrane potential as compared with
the somatic membrane potential. The slower rate of charging of the soma
is consistent with its greater capacitance. These data suggest the
following interpretation for the sequence of invasion of an antidromic
action potential, which is essentially that of Coombs et al. (1957).
The initial peak (P1) represents the change in membrane
potential attributable to the action potential actively invading the
initial segment (i.e., activating Na+ channels in the
initial segment) and passively charging the soma. The second peak
(P2) represents activation of Na+ channels in
the soma and dendrites, which the initial segment follows
passively.
As a test of the hypothesis that the peaks represented charging
attributable to distinct events (i.e., activation of Na+
channels in the initial segment vs the soma), we dissociated the
appearance of the peaks. Two antidromic action potentials were evoked
at a latency during the relative refractory period of the soma that
produced some failures of the full somatic action potential (Fig. 3,
right panel; Soma Vm). When the soma
fired (in 2 of 4 pairs of stimuli), the action potential was delayed,
as were the P2 peaks (Fig. 3; IS patch). When failures
occurred, only a single peak was detected in the initial segment [Fig.
3; IS patch (failures)]. Throughout, the
P2 peaks in the initial segment correlated well in magnitude and
latency with the somatic P2 peaks. The P1 peak was independent of the
presence of a somatic action potential and did not vary in latency
(Fig. 3, right panel). Thus, the existence of two peaks in
the waveforms seems to result from distinct activation of channels in
the initial segment and soma.
With the sequence of invasion determined for the antidromic action
potential, we observed the sequence of invasion of orthodromic action
potentials in the same recording configuration (Fig.
4A). The orthodromic stimulus was a
current injection through the somatic electrode. The orthodromic action
potentials produced a similar pattern of peaks in the recordings from
the soma and initial segment, although the latency between the peaks
was reduced (Fig. 4B; Soma dVm/dt,
IS patch). The shorter latency would be expected because the
orthodromic stimulus partially charged the capacitance of the soma
before initiation of an action potential. Thus, when the action
potential backpropagated from the initial segment into the soma, the
current from the initial segment could activate somatic Na+
channels more rapidly. A similar argument could be made for the greater
latency of the peaks corresponding to the second action potential (Fig.
3B; Soma dVm/dt, IS patch).
Presumably, because the second action potential initiated during the
relative refractory period after the first action potential, charging
of the soma was somewhat slower during the somatic invasion of the
second action potential, activation of somatic Na+ channels
was delayed, and, thus, the interval between the peaks was increased.
The data from these dual recordings suggested that the sequence of
charging of the initial segment and the soma is the same. Thus, under
the conditions of our preparation and with our using a current step
through the somatic electrode as the orthodromic stimulus, action
potentials initiated in the axon before the soma.
Fig. 4.
Sequence of orthodromic action-potential (AP)
invasion of initial segment (IS) and soma. Dual-recording
electrode positions are as in Figure 1. Waveforms are single sweeps.
A, Somatic membrane potential recorded through the
whole-cell electrode. Orthodromic action potentials were evoked by a 50 msec duration, 200 pA current injection through the recording
electrode. B, Ortho (1st), Left column corresponds to the
first action potential evoked by the orthodromic stimulus. Ortho
(2nd), Right column corresponds to the second action potential
initiated by the stimulus. Soma Vm, Membrane
potential recorded through the somatic whole-cell electrode. Soma
dVm/dt, Time derivative of the somatic
membrane potential. IS patch, Cell-attached patch recording
in the IS. The current recorded is primarily capacitive and, thus, is
proportional to the time derivative of the transmembrane potential of
the patch. P1 and P2 correspond to charging of
the patch by channels in the initial segment and soma, respectively, as
in Figure 3. Note that, although the peaks occur with shorter latency,
the sequence of invasion of orthodromic APs is the same as that for
antidromic APs. Cell c95066a.
[View Larger Version of this Image (15K GIF file)]
Alterations of action-potential initiation by local
TTX application
We used the following rationale to examine the relationship
between local Na+ channel density and the site of
initiation of action potentials. Although the threshold for
action-potential initiation depends on many factors, including local
morphology and the relative magnitude of inward and outward
voltage-gated conductances, decreasing functional Na+
channel density should raise threshold. If there is a region of the
cell with a particularly low threshold (for any reason, not just
because of high Na+ channel density), then decreasing the
inward Na+ current in this region should increase the local
threshold and, thus, the overall threshold of the cell. On the other
hand, decreasing the Na+ channel density in some other
region of the cell (i.e., one that does not have the lowest threshold),
will have less effect on the overall threshold of the cell, because the
site with the lowest threshold will still fire at its (lower)
threshold. Using this rationale, we blocked Na+ channels
locally in the axon, initial segment, soma, and dendrites to test if
one region had a particularly low threshold as implied by Coombs et al.
(1957). We also tested the hypothesis of Mainen et al. (1995) that
Na+ channels in the initial segment provide most of the
conductance underlying the somatic action potential.
The remainder of the experiments used a single somatic patch-clamp
electrode in whole-cell mode to record somatic action potentials.
Tetrodotoxin (TTX, 10 µM) was ejected from a small
patch pipette (tip, <1 µm in diameter) onto different parts of
the cell to block Na+ channels. The slice was positioned so
that the flow of the external medium was away from the soma toward the
alveus. In all cases the initial segment was identified, and the
ejection of TTX was confirmed visually. To assess the effect of TTX on
action-potential initiation, we sequentially stimulated the cell
orthodromically and then antidromically within a single sweep. A single
shock from a stimulating electrode in the alveus activated antidromic
action potentials. A depolarizing current step through the somatic
recording electrode evoked orthodromic action potentials. An interval
of 100 msec between stimuli within each sweep was sufficiently long
enough to prevent interaction of the stimuli but short enough to
maintain a relatively constant concentration of TTX during the pair of
stimuli. Altering the order of the stimuli or the durations of the
current injections (data not shown) did not yield results
different from those presented here.
Initially, the effect of TTX on the initial segment was tested by
locally applying TTX 10-15 µm from the soma in small volumes
(n = 8; Fig. 5A). During the
application of TTX, the orthodromic current step continued to fire full
action potentials of similar amplitude at similar latency and somatic
membrane potential. The antidromic action potential, however, failed as
it invaded the soma, leaving a partial action potential ~25 mV in
amplitude (Fig. 5B, arrow). This result might be explained
in two ways. First, there could be a similar threshold in the soma and
initial segment so that blocking the initial segment does not greatly
alter the threshold in the soma in response to depolarization. Second,
the orthodromic depolarization could summate with the (now reduced)
current from the backpropagating action potential sufficiently to
activate somatic Na+ channels and fire the cell. To
distinguish between these possibilities, we paired subthreshold
depolarization of the soma with an antidromic action potential (Fig.
5C; n = 4). Two antidromic stimuli were given at a
latency of 100 msec. The second stimulus in the sweep was paired with a
subthreshold depolarization of the soma. The unpaired antidromic action
potentials failed when TTX was applied to the initial segment (Fig.
5C, arrow), but the antidromic action potentials paired with
depolarization produced somatic action potentials that were
indistinguishable from the pre-TTX controls. Thus, action potentials
initiated in the axon in response to a somatic current injection could
indeed summate with somatic depolarization to fire a full somatic
action potential. To test this idea further, we repeated the paradigm
of Figure 5B with a larger volume of TTX ejected from the
pipette to decrease the amplitude of the spikes propagating from the
axon to the soma (n = 4). When the antidromic action
potential was made very small (10-15 mV; Fig. 5D, bold
trace), the orthodromic action potential also failed (Fig.
5D, arrow), consistent with the idea that orthodromic spikes
were initiated in the axon. As the cell began to recover from the TTX,
as indicated by the larger antidromic action-potential amplitude, a
full action potential followed the orthodromic stimulus (Fig. 5D,
thin trace).
Fig. 5.
Local application of TTX to the initial
segment (IS) impairs antidromic invasion of the soma without
significantly altering the threshold for orthodromic AP initiation.
A, A somatic whole-cell electrode recorded from an injected
current into the soma. A stimulating electrode in the alveus evoked
antidromic APs. TTX was applied to the IS (12 µm from the soma).
B, Traces are somatic whole-cell current-clamp records of
the response to orthodromic and antidromic APs. Pre, Six
consecutive baseline sweeps. TTX, Six consecutive sweeps
during TTX application. Note that the antidromic AP failed to invade
the soma (arrow), but the orthodromic AP initiated with
similar latency and membrane-potential threshold. Recover,
Five consecutive sweeps as the cell recovered. C, The full
somatic AP was not mediated by Na+ channels in the IS but
by somatic Na+ channels. Sweeps with and without TTX are
superimposed. In the presence of TTX, the antidromic AP failed to
invade the soma (arrow). Pairing subthreshold depolarization
with an antidromic AP allowed the soma to fire a full AP. Note that the
paired antidromic AP in TTX was indistinguishable from the control
condition. Thus, somatic channels were sufficient to produce a full AP.
RMP, 63 mV. D, In another cell, a greater ejection of TTX
decreased the amplitude of the antidromic AP to ~10 mV (bold
trace). The orthodromic stimulus evoked a similar small spike
(arrow) that was insufficient to fire the soma but had the
same latency and threshold as APs before the application of TTX. The
following sweep (thin trace) had a somewhat larger
antidromic AP (25 mV). This greater current from the IS, paired with
the depolarization of the soma by the orthodromic stimulus, resulted in
a full somatic AP. RMP, 65 mV. Cell c95082.
[View Larger Version of this Image (17K GIF file)]
Despite its profound effects on the ability of the action potential to
invade the soma, the application of TTX to the initial segment did not
greatly alter the latency or the somatic membrane potential at which
the action potentials appeared. Thus, according to the argument
outlined above, the initial segment was not the site of initiation of
action potentials. Furthermore, although Na+ channels in
the initial segment supplied current to charge the soma during the
somatic invasion of the action potential, somatic Na+
channels, once activated, were of sufficient density to produce a full
action potential in the soma. To refine this result further, we applied
TTX locally to the soma and to the proximal apical dendrite of the
pyramidal neurons (Fig. 6A;
n = 6).
Fig. 6.
Local application of TTX near the soma and apical
dendrite does not significantly alter the threshold for AP initiation.
A, Experimental configuration as in Figure 5, except that
the TTX pipette was placed at the initial segment (12 µm from the
soma), the soma, or the apical dendrite (12 µm from the soma). In
each of the lower panels, the bold trace
corresponds to the presence of TTX; the thin traces
correspond to the sweep just before the application of TTX.
B, Local application of TTX to the initial segment caused a
failure of the antidromic AP (open arrow), without altering
the threshold to orthodromic stimuli. C, Local application
of TTX to the soma caused a partial block of the somatic AP.
Inset shows same sweeps at faster sweep speed. D,
Local application of TTX to the apical dendrite had no effect on
antidromic or orthodromic AP invasion of the soma. RMP, 65 mV. Cell
c95094.
[View Larger Version of this Image (13K GIF file)]
Application of TTX regions near the soma resulted in distinct patterns
of invasion of the action potential in single cells (Fig. 6;
n = 5). TTX applied to the initial segment in small
volumes, as before, reduced the antidromic action potential without
altering the orthodromic action potential (Fig. 6B, bold
trace). TTX applied to the soma altered both the orthodromic
action potential and the antidromic action potential (Fig.
6C). At the peak of the effect of TTX application to the
soma, the orthodromic action potential initiated at a similar membrane
potential as in the control condition (filled arrow,
thin trace) but was delayed, broad, and reduced in amplitude (Fig.
6C and inset; filled arrow, bold traces). Because
larger ejection volumes of TTX were used at the soma, some TTX likely
diffused to the initial segment, which itself would explain the failure
of the antidromic action potential to invade the soma. The reduced
amplitude of the somatic action potential, however, was not explained
simply by decreased current from the initial segment: when TTX was
applied to the soma (Fig. 6C), the failed antidromic action
potential, which provided a measure of the current flow from the axon
into the soma, was actually slightly larger than when TTX was applied
to the initial segment (Fig. 6B). These results
support the notion that activation of somatic Na+ channels
is not only sufficient to produce a full action potential in the soma,
but necessary. Finally, applying TTX to the very proximal apical
dendrite had no effect (Fig. 6D), even when
relatively large ejection volumes were used, as compared with those
applied to the initial segment. Thus, there was no evidence for
dendritic involvement in the initiation of action potentials in
response to the orthodromic stimuli used (i.e., current injection at
the soma). TTX applied to regions of the cell near the soma had little
effect on the somatic membrane potential at which orthodromic action
potentials appeared at the soma. Thus, for the orthodromic stimuli
used, the site of initiation was not in the soma, initial segment, or
the proximal dendrite.
The results of the TTX applications taken together with the results of
the dual recordings, which showed that the action potential appeared in
the initial segment before the soma, point to an axonal site of
initiation. Thus, we applied TTX to various positions along the axon
between the soma of the pyramidal neuron and the alveus (Fig.
7A) while performing the same
orthodromic/antidromic stimulus paradigm already described (Fig.
7B). The effect of TTX applied to the axon varied as a
function of position. TTX applied to sites near the stimulating
electrode in the alveus completely blocked the antidromic action
potential (i.e., not even a partial action potential was observed) but
had no effect on the orthodromic spike (data not shown). This result
suggests that the antidromic action potential was blocked by raising
the threshold near the stimulating electrode distal to the site of
initiation for an orthodromic action potential. TTX applied at ~50
µm from the soma increased the latency and somatic membrane potential
at which action potentials appeared. In two of six cells orthodromic
initiation of action potentials in response to the current step was
prevented altogether (Fig. 7B,C). The effect was rapidly
reversible with action-potential initiation returning to baseline
within seconds (Fig. 7B, bottom panel). During this shift in
the apparent threshold at the soma, there was no readily observable
change in the antidromic action potential in four of six cells (Fig.
7B). In two cells, however, there was an increase in the
latency of the antidromic action potential (Fig. 7D). This
result can be explained by the TTX application reducing the safety
factor in the axon some distance from the soma. As the antidromic
action potential propagated through the affected region, it slowed or
even began to fall. Once beyond this region, however, the action
potential regained its normal shape and invaded the soma, as in the
control condition. Thus, all that was observed at the soma was a change
in latency. No differences in these results were found between adult or
pup slices or between room temperature and 31-32°C
(n = 3).
Fig. 7.
Local application of TTX to the axon alters the
threshold for orthodromic AP initiation. A, Experimental
configuration as in Figure 5, except that the TTX pipette was placed
near the axon 50 µm from the soma. In each sweep a 500 pA current
step through the recording electrode was followed by an antidromic
stimulus in the alveus. B, Pre, Five consecutive sweeps
before the application of TTX. TTX, Five consecutive sweeps
after TTX was applied to the axon. Recover, Six consecutive
sweeps during the recovery from the TTX application. Note that the
antidromic AP was not altered by the TTX application. C,
Single sweeps from B for comparison at increased gain.
Application of TTX on the axon increased the apparent threshold for
orthodromic AP initiation by at least 10 mV (bold trace).
RMP, 61. Cell c95090. D, In another cell, application of
TTX to the axon (60 µm from soma) increased the latency of the
antidromic action potential. Threshold for the orthodromic AP increased
by >10 mV (data not shown). RMP, 63 mV. Cell c95082.
[View Larger Version of this Image (14K GIF file)]
Although the extent of the spread of TTX could not be monitored
directly, which ultimately limited the resolution of this technique,
the physiological effects of TTX application at the soma and at the
initial segment (~10 µm from the soma) provided useful controls for
the effects of TTX application to the axon (~50 µm from the axon).
First, as shown above, TTX applied to the initial segment blocked
somatic invasion of antidromic action potentials without significantly
changing the orthodromic threshold. Thus, the increased orthodromic
threshold observed when TTX was applied to the axon could not be
explained simply by diffusion of TTX to the soma or to the initial
segment. Second, TTX applied to the axon, sufficient to raise the
orthodromic threshold nearly 10 mV, did not block the somatic invasion
of antidromic action potentials (compare Fig. 7C,D). Using
these physiological checks on the spread of TTX, we observed the effect
of TTX application on orthodromic action-potential threshold as a
function of distance from the soma. To ensure adequate delivery of TTX
at positions 10 and 20 µm from the soma, we required a failure of
somatic invasion of the antidromic action potential (compare Fig.
5B). To control for the spread of TTX to the initial segment
from more distal positions (>20 µm from the soma), we required that
the TTX application not cause any failure or decrease in the
amplitude or latency of the somatic invasion of the antidromic
action potential. If these conditions were not met, we waited for
recovery and repeated the application of TTX. The effect of
TTX on the apparent somatic threshold was greatest (~8 mV) when TTX
was applied at distances 30-60 µm from the soma (Fig.
8; n = 8 cells), suggesting that the
initiation of orthodromic action potentials depended critically on the
excitability of this region of the axon.
Fig. 8.
Shift in threshold for orthodromic
action-potential (AP) initiation as a function of the location of TTX
application. Experimental configuration is the same as in Figure 7. To
control for the spread of TTX and to ensure adequate delivery, TTX
ejections at locations 10 and 20 µm from the soma were required to be
sufficient to block somatic invasion of the antidromic AP, as in Figure
5. TTX ejections beyond 20 µm were required not to block somatic
invasion of the antidromic AP. The most effective locations of TTX
application seem to be in the axon beyond the initial segment. Error
bars are SEM. Numbers under each point are the
number of neurons tested with TTX at that distance from the soma.
[View Larger Version of this Image (13K GIF file)]
DISCUSSION
The present data support a picture of action-potential initiation
similar to the classical scheme derived from the work of Eccles and
colleagues in the motoneuron (Coombs et al., 1957) yet quite different
in some important details. Consistent with the motoneuron findings,
action potentials initiate in the axon at a lower membrane potential
than in the soma. However, in contrast to the conclusions of Eccles and
colleagues, the present data suggest that the site of initiation is in
the axon beyond the end of the initial segment and that the thresholds
in the axon hillock and in the initial segment (for at least most of
its length) are similar to that of the somatic membrane. Moreover, the
present findings are inconsistent with the classic hypothesis of a very
high local density of Na+ channels in the axon hillock and
initial segment (Dodge and Cooley, 1973).
Estimates of Na+ channel density
Estimates of Na+ channel density from cell-attached
patch recordings from somata agree well with other recent studies
estimating channel density with similar techniques (Stuart and Sakmann,
1994; Magee and Johnston, 1995), and slightly lower than estimates
derived from dissociated somata (Sah et al., 1988; Cummins et al.,
1994). Assumptions in estimating the actual density of channels from
current density measurements include the area of the patch, the
probability of opening, the number of activatable channels, and
uniformity of density in the membrane (i.e., no clustering). The
greatest potential sources of error in these measurements at present
seem to be the estimate of the area of the patch attributable to
stretching of the membrane. Such errors might confound the results if
they are of different magnitudes in somatic and initial segment
patches, because our conclusions are based on a relative measure of the
densities. As an absolute measure of the density of channels, it would
not be surprising if we underestimated the density by two- to
threefold.
Estimates using other techniques have found evidence for a greater
density of Na+ channels in the initial segment than in the
soma, although quantitative measures by each of these techniques is
difficult. A study using fluophore-labeled Na+ channel
toxins and confocal microscopy (with resolution ~1 µm), estimated a
fourfold, but sometimes up to a 30-fold, greater labeling of the
initial segment of cultured spinal cord neurons (Angelides et al.,
1988). Cortical neurons in the same study showed a less obvious
increase. A study of retinal ganglion cells (requiring permeabilization
of the cells for visualization) estimated a sevenfold increase in
density in the initial segment (Wollner and Catterall, 1986). Finally,
a freeze fracture study in frog dorsal root ganglion cells found
particle counts (not necessarily Na+ channels) to be
threefold higher in the initial segment than in the soma (Matsumoto and
Rosenbluth, 1985). These results suggest that the density of
Na+ channels may be higher in the initial segment in some
cell types. None of these results, however, supports the conjecture
that the density of Na+ channels may approach that in a
node of Ranvier (Dodge and Cooley, 1973; Mainen et al., 1995). Recent
estimates of nodal densities are on the order of 1000-2000
channels/µm2 (Black et al., 1990), as compared with 3-4
channels/µm2 estimated in initial segments in the present
study.
Local thresholds and site of initiation of action potentials
Despite the conclusion carried forth that the axon hillock/initial
segment was the site of action-potential initiation, Coombs et al.
(1957) noted the possibility that action potentials might instead
initiate in the axon, perhaps at the first node of Ranvier. Their
experiments could not distinguish between these sites because of the
very short latencies involved. The site of initiation in the stretch
receptor was found, using different approaches, to be in the axon
beyond the initial segment (Edwards and Ottoson, 1958). Gogan et al.
(1983) have argued that the electrotonic length of the initial segment
of the motoneuron is relatively short. Thus, the first node of Ranvier
should be depolarized essentially to the same degree as the soma. If
the threshold of the initial segment, say attributable to equivalent
Na+ channel density, were similar to that of the soma, the
first node would likely be the site of initiation in the motoneuron.
The present experiment, that TTX applied to the axon raises the
apparent threshold in the soma, seems consistent with initiation of
orthodromic action potentials at the first node. However, similar
results might also be expected without invoking the presence of a node
if the axon had a lower threshold, in general, than the remainder of
the neuron. A lower threshold could be attributable to uniformly higher
density of Na+ channels or to small diameter. Whether the
Na+ channel density in the axon beyond the initial segment
is higher than that in the soma remains to be determined. With the
present technique, such measurements will be limited to larger cells.
The small diameter (<0.75 µm) of the axon beyond the initial segment
of the subicular pyramids precludes more distal measurements.
The present experiments leave open the possibility that
action-potential initiation occurs at a heminode at the very end of the
initial segment. Although we observed no great differences in current
in 27 patches throughout the extent of the initial segment, if a small
region at the end of the initial segment had a high density of
Na+ channels, then it is possible that we missed this high
density because of sampling error. Nonetheless, we found no evidence
for the hypothesis that the axon hillock/initial segment is a region of
uniformly high density that determines action-potential initiation.
Likewise, although the most effective location of TTX application seems
to be well beyond the end of the initial segment, we cannot completely
exclude the possibility that the shift in threshold is attributable to
an effect of TTX at the most distal region of the initial segment. If
spread of TTX to the distal initial segment explained the shift in
threshold, then the idea that initiation occurs in the initial segment
would, in some sense, be salvaged. This would be a somewhat semantic
argument, however, because the axon hillock and most of the initial
segment would still not provide the classically hypothesized function
of action potential initiation but rather, as we advocate here,
electrical isolation of the initiation zone from the soma modulated by
axoaxonic synapses (see below).
Function of the initial segment
The focus on the initial segment as the site of action-potential
initiation has overshadowed other potential functions of this region.
First, one well known feature of the initial segment is the presence of
axoaxonic GABA-mediated synapses, which have been hypothesized to alter
the initiation of action potentials (Palay et al., 1968; Peters et al.,
1968; Fariñas and DeFelipe, 1991; Cobb et al., 1995). Such
synapses would likely be particularly effective in inhibiting
action-potential initiation if the site of initiation were beyond the
initial segment. In such a configuration, the initial segment would
provide some electrical isolation between the soma-dendrites and the
usual site of initiation. Thus, the soma would not need to be
discharged fully by the inhibitory synapses to hyperpolarize the site
of initiation away from threshold. Second, a less well known feature of
the initial segment is a cisternal organelle, similar in morphology to
a spine apparatus, which is thought to be involved in the sequestration
of Ca2+ and to be coupled to the GABAergic synapses
(Benedeczky et al., 1994). Although no function for this cistern has
been demonstrated, the initial segment may be involved in the
regulation of Ca2+-dependent processes, particularly
related to repetitive firing (Lüscher et al., 1996). Third, when
action potentials initiate in the axon, they propagate back into the
soma. For such backpropagation to succeed, the initial segment must
provide enough current to charge the capacitance of the soma
sufficiently to activate somatic Na+ channels. Thus,
depending on the morphology of the cell, particularly the relative
diameters of the initial segment and the soma, an increased density of
Na+ channels may be needed to provide this current, without
necessarily being related to producing a low threshold for
action-potential initiation.
The present study only considered current injection into the soma as
the orthodromic stimulus. This does not preclude initiation of action
potentials in the dendrites under certain patterns of synaptic input.
The present result that the threshold in the soma and earlier results
(Stuart and Sakmann, 1994) that the threshold in the dendrites is at
least 10 mV higher than the axonal threshold suggest that the neuron is
biased toward initiation of action potentials in the axon. However,
axoaxonic synapses and other specializations of the initial segment may
alter the relative depolarization between the axon and the
soma-dendrites, thus removing this bias and allowing the dendrites to
initiate action potentials. Further work will be necessary to determine
how synaptic input to the initial segment modifies thresholds and
possibly the location of action-potential initiation.
FOOTNOTES
Received June 19, 1996; revised Aug. 5, 1996; accepted Aug. 12, 1996.
This work was supported by National Institute of Mental Health Grants
MH10896 to C.M.C. and NS11535, MH44754, and MH48432 to D.J.
We thank Jeffrey Magee for helpful discussions throughout this study,
Janet Stringer for comments on an earlier version of this manuscript
and for help performing the biocytin experiments, and Tamas Freund for
suggesting the anatomical method for estimating the length of the
initial segment.
Correspondence should be addressed to Costa M. Colbert, Division of
Neuroscience, Baylor College of Medicine, One Baylor Plaza, Houston, TX
77030.
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Compound via MeSH
