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The Journal of Neuroscience, May 15, 2001, 21(10):3429-3442
Pituitary Control of BK Potassium Channel Function and
Intrinsic Firing Properties of Adrenal Chromaffin Cells
Peter V.
Lovell and
David P.
McCobb
Department of Neurobiology and Behavior, Cornell University,
Ithaca, New York 14853
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ABSTRACT |
The discovery that the hypothalamic-pituitary-adrenocortical
(HPA) endocrine stress axis controls an alternative splicing decision
in chromaffin Slo-encoded BK (big potassium)
channels raised the possibility that activation of the HPA could serve as a mechanism to tune the intrinsic electrical properties of epinephrine-secreting adrenal chromaffin cells. To test this, we
compared BK functional properties and cell excitability in chromaffin
cells from normal and hypophysectomized (pituitary-ablated) rats.
Hypophysectomy was found to alter the voltage dependence and kinetics
of BK gating, making channels less accessible for activation from rest.
Perforated-patch recordings revealed changes in action potential
waveform and repetitive firing properties. The maximum number of spikes
that could be elicited with a 2 sec depolarizing current pulse was
reduced by ~50% by hypophysectomy. The results indicate that
pituitary hormones can adapt the mechanics of adrenal catecholamine
release by tailoring BK channel function.
Key words:
hypophysectomy; BK channels; chromaffin cells; action
potentials; adrenal medulla; catecholamines; stress
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INTRODUCTION |
Descending synaptic input to
adrenomedullary chromaffin cells triggers the rapid release of
adrenaline, or epinephrine, by eliciting
Na+ and Ca2+
channel-dependent action potentials. Thus the intrinsic excitable properties of chromaffin cells, by defining action potential responses, play perhaps as great a role in limiting or patterning epinephrine secretion as does the input. In chromaffin cells, a significant fraction of the outward current gated at physiological voltages is
carried by BK (big K+) voltage- and
Ca2+-activated potassium channels, leading
several investigators to argue that BK channels play a central role in
shaping intrinsic excitability, particularly with respect to repetitive
firing (Solaro et al., 1995 ; Lingle et al., 1996; Lovell et al., 2000).
Recent evidence that pituitary stress hormones influence alternative splicing of Slo gene-encoded BK channels has raised the
hypothesis that stress-related activation of the
hypothalamic-pituitary-adrenocortical (HPA) axis may dynamically
control the character of autonomic crisis responses by tuning
chromaffin cell excitability (Xie and McCobb, 1998). To explore this,
we have characterized changes in chromaffin cell function resulting
from the surgical elimination of the HPA hormone cascade by hypophysectomy.
Hypophysectomy eliminates the source of adrenocorticotropic hormone
(ACTH), thereby dramatically and irreversibly reducing serum
corticosterone levels to the margin of detectability by radioimmunoassay. One consequence is a precipitous decline in the
adrenal transcription of the enzyme
phenylethanolamine-N-methyltransferase (PNMT), which
catalyzes the conversion of norepinephrine to epinephrine (Stachowiak
et al., 1988; Viskupic et al., 1994). That this reflects a dynamic and
bidirectional influence of the HPA on epinephrine synthesis is
supported by behavioral experiments (Stachowiak et al., 1988; Wong et
al., 1992; Baruchin et al., 1993; Lemaire et al., 1993; Betito et al.,
1994; Viskupic et al., 1994; Wong et al., 1995). In parallel with the
drop in PNMT transcription, hypophysectomy also alters the relative
abundance of two splice variants of Slo (Xie and McCobb,
1998). Thus at one splice site in the large C-terminal domain, the
optional inclusion of the 174 bp stress axis-regulated exon (STREX) is
progressively reduced. Injection of exogenous ACTH after hypophysectomy
prevents this decline, thus implicating the stress-related,
corticotrope subfunction of the pituitary (Xie and McCobb, 1998).
Xenopus oocyte expression studies suggest important
functional consequences for the hormonal regulation of Slo
splicing. The presence of the optional STREX in a Slo
cRNA construct expressed in an oocyte results in a negative shift in
the voltage dependence of channel activation, when compared with the
otherwise identical ZERO construct (lacking STREX). At a given voltage
and calcium concentration, the rates of activation and deactivation are
increased and decreased by STREX, as if its presence stabilizes the
open state of the channel.
The prominence of BK current in chromaffin cells suggests that changes
in BK properties resulting from hypophysectomy are likely to alter
cellular excitability. The results described in this report are
consistent with the idea that pituitary function exerts a dynamic,
regulatory control over the excitable properties of adrenal chromaffin
cells by altering the gating of BK channels, with probable
ramifications for autonomic function and pathology.
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MATERIALS AND METHODS |
Chromaffin cell dissociation and culture. The
techniques used in the isolation and culturing of chromaffin cells
closely followed those described by Lovell et al. (2000).
Hypophysectomies (surgical ablation of the pituitary gland) were
performed 5-6 weeks postpartum by aspiration of the pituitary tissue
exposed by trephination at the occipitosphenoid suture, accessed via
the parapharyngeal approach. Hypophysectomy was confirmed before cell
dissociation by comparison of body weights with those of unoperated
animals of the same age and source (Charles River Laboratories,
Wilmington, MA). Hypophysectomized rats received a 5% sucrose
supplement. Adrenomedullary tissue from the glands of hypophysectomized
(hypox; n = 24) and unoperated (normal;
n = 21) Sprague Dawley rats was surgically isolated,
minced, washed repeatedly in sterile HBSS (Life Technologies,
Gaithersburg, MD), and incubated for 60 min with gentle agitation in a
collagenase B solution (Boehringer Mannheim, Indianapolis, IN; 1.5 mg/ml in HBSS), pH 7.0, at 37°C. Extracted tissue was then washed
repeatedly in a Ca2+- and
Mg2+-free HBSS (Life Technologies) and
incubated for 30 min at 37°C in a solution containing trypsin (Life
Technologies; 0.125% in Ca2+- and
Mg2+-free HBSS). Chromaffin cells were
freed from clumps by repeated trituration through fire-polished Pasteur
pipettes and suspended in a preincubated (37°C) sterile culture
medium (Life Technologies; RPMI 1640 with 10% horse serum, 5% fetal
calf serum, 2 U/ml penicillin-G, 2 µg/ml streptomycin sulfate, and
100 U/ml nystatin). Cells were aliquoted (100 µl) in the center of 15 mm glue rings in 35 mm sterile plastic dishes (Falcon 3001; Fisher
Scientific, Pittsburgh, PA) coated with collagen (Vitrogen, Collagen
Corporation, Carlsbad, CA; 0.6 mg/ml dilution in sterile
ddH2O) or poly-D-lysine
(Sigma, St. Louis, MO; 0.01% in ddH2O). Cell
cultures were maintained in a 5% CO2 atmosphere
at 37°C and used over a period of 1-4 d. Culture medium was changed
as needed.
Staining of tissue sections and isolated chromaffin cells.
Dissociated cells were washed several times in a PBS
containing bovine serum albumin (BSA; 0.1%; Life Technologies) and
fixed for 60 min in a paraformaldehyde solution (PFA; 4% in PBS).
Cells were washed a second time in PBS with BSA and permeabilized for 10 min in a Triton X-100 solution at room temperature (0.2% Triton X-100 in PBS; Fisher Scientific). Cells were then incubated overnight with primary antibodies directed against PNMT (Diasorin, Stillwater, MN) and tyrosine hydroxylase (TH; Sigma). The following day, cells were
washed several times with PBS and incubated for 1 hr with Texas Red and
fluorescein secondary antibodies (Vector Laboratories, Burlingame, CA).
Cell staining was observed with a Nikon Eclipse E600-FN scope and
imaged using a Spot (Diagnostic Instruments) camera and Spot 2.2 software. For adrenal sections, PFA-perfused glands were embedded in
paraffin, sectioned, mounted, and stained with hematoxylin and eosin.
Electrophysiological methods. Macroscopic BK currents
(0.1-1 nA) were recorded from inside-out and outside-out patches using standard patch-clamp recording techniques as described by Hamill et al.
(1981) and Sakmann and Neher (1985). Patches were excised from cultured
chromaffin cells using standard borosilicate electrodes (World
Precision Instruments, Sarasota, FL; inside-outside diameter, 1.12-1.5 mm) pulled to resistances of 2-4 M and coated with
Sylgard 184 (Dow Corning, Midland, MI) to reduce electrode
capacitance. All patch experiments were performed at room temperature
(22.5°C) in symmetrical [K+] recording
solutions designed to eliminate the driving force on potassium and
permit any DC offset to be canceled at 0 mV. For inside-out patches,
high-resistance seals (2-4 G) were achieved with a gentle suction
and with patches pulled rapidly in
Ca2+-free saline. Currents were recorded
with a List EPC-7 patch-clamp amplifier (Heka Electronik, Lambrecht,
Germany), Bessel high-pass filtered at 10 kHz, digitally converted with
an ITC-16 analog-to-digital (Instrutech Corporation, Great Neck,
NY), and stored on a Macintosh Power personal computer 8100/80 using
the Pulse 8.02 software package (Heka, Lambrecht, Germany).
For whole-cell recording of calcium currents, standard patch-clamp
recording techniques were used. Chromaffin cells were typically held at
 70 mV, and the voltage dependence of calcium currents was measured by
a series of increasing voltage steps (I-V plots). The
effect of calcium channel rundown was minimized by using an intersweep
interval of at least 10 sec, and every effort was made to finish
experiments 10 min after achieving whole-cell access. To investigate
the effect of the action potential (AP) waveform on calcium influx, a
series of action potential waveform templates (APWs) was used. APWs
consisted of a set of two APs varying in amplitude, half-amplitude
duration, and afterhyperpolarization (AHP) magnitude (the third spikes
from normal and hypox spike trains) and a second set of spike trains
varying in spike number and frequency. The APW baselines were set to a
resting potential of 70 mV and delivered as standard voltage-clamp
pulses. Inverted, one-quarter-scale waveforms were also presented to
determine appropriate values for off-line leak subtraction. A measure
of the effect of APWs on calcium entry was determined by calculating
the proportion (nCS/hCS) of the integrated area under the normal
calcium spike (nCS) as a function of that measured for the hypox
calcium spike (hCS).
For perforated-patch recordings, high-resistance seals were achieved as
described above, and recordings were made in current-clamp mode when
the apparent input resistance had dropped to values between 50 and 150 M. Wherever necessary, a small holding current was used to maintain
the resting potentials between 65 and 75 mV. Previous studies
indicated that many cells recorded in whole-cell mode exhibited little
or no repetitive firing capabilities. Much greater repetitive firing
was observed in perforated-patch mode. The reduced firing may be caused
by the buffering of cytoplasmic [Ca2+] by EGTA internally
perfused through the recording electrode. To verify that the perforated
patch was not ruptured during recording, input resistance was monitored
during deliberate rupture at the end of the recording. For excitability
measurements, a series of 2 sec current pulses of increasing strength
was used to elicit repetitive firing. The magnitude of current and
serial increment of steps was adjusted by trial and error to fit the
varying input resistances of the cells. For pharmacology, cells were
exposed to bath-applied 1 mM tetraethylammonium (TEA) as
described below for voltage clamp.
Solutions. For all solutions, osmolarity was measured by dew
point osmometry and adjusted to within 3% of 300 Osm. For
consistency, all comparative characterizations of BK properties that
are described, except where indicated, used a single solution made up
once in large volume and stored in frozen aliquots. This solution,
which was used in both the electrode and bath, contained the following: 160 mM KCl, 10 mM HEPES, and no added
calcium. The pH was adjusted with KOH to 7.4. The free-calcium
concentration (~1 µM), estimated previously at ~6
µM (Lovell et al., 2000) using a
Ca2+ ion-selective electrode, was more
accurately determined using a Fura-6F (Molecular Probes, Eugene, OR)
ratiometric calcium indicator calibrated against a calcium buffer
series (kit 2; Molecular Probes) and measured with an SLM-Aminco
8000c spectrofluorimeter (Spectronic Unicam, Rochester, NY). In the
indicated experiments, an additional KMeSO3-based
saline was used that contained (in mM): 140 KMeSO3, 20 KOH, 10 HEPES, 5 HEDTA, and 1.865 Ca(MeSO3)2; pH was adjusted to 7.4 with 5% MeSO3 to make a solution
calculated to have a free-calcium concentration of 4 µM.
A zero-calcium solution was made by adding EGTA (1.9 mg/ml; Sigma) to
the KMeSO3-based saline. Bath-applied solutions
were delivered with a seven-barrel, gravity-fed perfusion system. All
other solutions, TEA+ (1 mM;
ICN Biomedicals, Aurora, OH) and charybdotoxin (CTX; 10 nM;
Alomone Labs, Jerusalem, Israel), were made in the stock 1 µM [Ca2+] recording
saline, and pH was adjusted to 7.4.
Whole-cell calcium currents were recorded in voltage clamp using a
bath-perfused CsCl-based rodent Ringer's solution containing the
following (in mM): 2 CaCl2, 10 HEPES,
and 150 TEAOH; pH was adjusted to 7.4 with HCl. For pharmacology, 100 µM cadmium and 1 µM tetrodotoxin were added
directly to the Ringer's solution, and pH was adjusted to 7.4. The
pipette solution contained the following (in mM): 140 CsCl,
5 MgCl2, and 10 EGTA (free acid); pH was adjusted
to 7.4 with CsOH. ATP (1 mM ATP-Mg) and GTP (0.1 mM GTP-Li) were added to the pipette saline to reduce
calcium channel rundown. Every effort was made to finish current
recordings within 10 min of achieving the whole-cell recording configuration.
For current-clamp recordings, the bath solution contained the following
(in mM): 145 NaCl, 5 KCl, 10 HEPES, 2 CaCl2, and 1 MgCl2; pH was
adjusted to 7.4 with 2 M NaOH. For pharmacology, TEA+ (1 mM) or CTX (10 nM) was added directly to the Ringer's solution, pH was
adjusted to 7.4, and the bath was perfused. The technique used to
obtain perforated patches closely followed procedures described by
Herrington et al. (1995). The tip of a patch electrode (2-4
M) was first filled with whole-cell saline containing (in mM): 140 KCl, 5 MgCl2, 10 EGTA, and
10 HEPES, pH 7.4. The electrode barrel was then backfilled with a
solution containing 20 µl of fresh stock Amphotericin B (6 mg/100
µl of DMSO; Life Technologies) and 40 µl of stock Pluronic acid
F-127 (2.5 mg/100 µl of DMSO; Molecular Probes) added to 1 ml of
whole-cell recording saline. To maintain perforating efficacy, fresh
aliquots were used for each hour of recording. Every effort was made to
achieve rapid seals with resistances of 1-2 G shortly after the
electrodes were filled.
Voltage-clamp analysis of BK properties. Analysis of current
and voltage data was performed off-line using custom-written software
for Igor Pro (Wavemetrics, Lake Oswego, OR). Single channel and
multichannel (5-30 channels) clamp data were averaged, linear leak was
subtracted, and various kinetic and steady-state parameters were
measured. The fraction of total current that was inactivated after a
350 msec (BKi/BKtotal) step
to +80 mV was determined by calculating the proportion of current
present at the end of a 350 msec step as a function of the estimated
peak current. Measurements of the time constant for current decay,
activation, and inactivation were estimated by fitting at least 70% of
the waveform with a Levenburg-Marquardt least-squares search algorithm
for single-exponential equations. The calcium dependence and voltage
dependence of both activation and inactivation were estimated by
measuring the peak conductance of traces activated at increasingly
positive test potentials. The voltage of half-activation
(V0.5), maximum conductance, and slope
conductance were calculated by fitting conductance versus voltage plots
(G-V) with a single Boltzmann equation of the
form:
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(1)
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where s is the slope in millivolts per
exponential-fold change in conductance and
V0.5 is the voltage of
half-activation. Properties of BK channel gating measured from hypox
and normal rats were compared using a Mann-Whitney test for mean
differences ( = 0.05).
Current-clamp analysis of excitability. For each trace in an
I-V series, several features of both the spike train and
individual action potential waveforms were measured. The maximum number
of spikes elicited by a 2 sec depolarizing pulse was characterized. For
each of the first three spikes in a trace, the peak-to-trough amplitude
(positive peak of the AP to minimum trough of the AHP), the
half-amplitude spike duration (time elapsed between the half-amplitude coordinates for the rising and falling phase of the AP), and the magnitude of the AHP (minimum voltage of the AHP minus the baseline voltage) were measured. Peak-to-trough voltage, half-amplitude duration, AHP voltage, and maximum spike number values were averaged and compared using a Student's t test for mean differences
( = 0.05).
Mathematical modeling of cellular excitability. All
simulations were performed using Nodus modeling software (De
Schutter, 1989) on a Power Macintosh 7100/80 computer. The model
consisted of a spherical cell (20 µm in diameter) with a passive
specific membrane resistance of 40 k/cm 1, specific capacitance of 1 µF/cm2, and cytoplasmic resistivity of
200 /cm1. Active membrane properties
included three voltage-gated ionic currents (equations in the Appendix)
simulated by standard Hodgkin and Huxley equations (Hodgkin and
Huxley, 1952). These included a fast-inactivating sodium conductance
[modeled after Hodgkin and Huxley (1952)], a standard leak current,
and one of two non-inactivating voltage-gated potassium channels. The
potassium conductances were calcium insensitive and identical in every
way except in their voltage dependence of half-activation
(V0.5 = 20 vs 40 mV). To evaluate
firing behavior during current injection, the following equation was
solved for membrane potential
(Vm):
|
(2)
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where Cm is total capacitance,
ER is the resting membrane potential,
gion is the conductance for any given
channel in the cell, t is time,
Eion is the equilibrium potential for
each ion, RL is the inverse of the
passive leak conductance, and Iinj is the magnitude of the current injection step. The first term in Equation 2 describes the passive leak current; the second term represents the
sum of the voltage-dependent ionic currents. The total somatic
resistance is given by:
|
(3)
|
where D = 10 µM. To
estimate the change in voltage as a function of time during current
injection, Equation 2 was integrated using the Fehlberg method
(Forsythe et al., 1977) with a fixed time step ( t = 0.05 msec) described by the equation:
|
(4)
|
where V0 is the initial
membrane voltage. In current-clamp simulation, spike trains were
elicited from the two model cells by 1 sec square-current injection
steps. Direct comparisons of cellular excitability were made by
enumerating the spikes elicited during the depolarizing pulse for each
of the cells at the same level of current injection. Voltage-clamp
analysis of the steady-state parameters of the potassium currents was
made using voltage-clamp protocols like those described above for BK channels.
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RESULTS |
Chromaffin cells from hypophysectomized rats
Chromaffin cells were isolated from rats between 2 and 6 months
after hypophysectomy and compared with cells isolated from unoperated
rats from the same cohort. Successfully hypophysectomized rats were
readily distinguished from unoperated rats and the very few rats that
were incompletely hypophysectomized by their small size (162 ± 23.8 vs 530 ± 248 gm) and finer, softer, and whiter fur. Paraffin
sections from normal and hypox adrenals stained with hematoxylin
and eosin illustrate differences in cortical and medullary tissues
(Fig. 1A,B).
Dissociated chromaffin cells from hypophysectomized rats are
essentially indistinguishable from those from unoperated rats when
viewed under a light microscope (Fig. 1C1,D1). Fluorescent
immunoreactivity using antibodies directed against the
catecholamine-synthetic enzyme TH also appeared very similar,
confirming their identification as chromaffin cells (Fig. 1C2,D2). Although some hypox cells were strongly positive
for PNMT, the intensity of staining for most cells was substantially lower than that for cells from normal animals (Fig. 1C3,D3).
This observation is consistent with what is known about glucocorticoid regulation of PNMT expression in chromaffin cells (Ross et al., 1990;
Betito et al., 1992; Evinger et al., 1992). The total yield of cells
was consistently lower from hypox animals, approximately commensurate
with, and presumed to result from, the cessation of somatic growth
accompanying the loss of growth hormone-producing pituitary cells.
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Figure 1.
Effects of hypophysectomy on rat adrenal glands.
A, B, Cross sections of normal (A)
and hypox (B) adrenals stained with hematoxylin
and eosin illustrate the anatomical differences. Note the smaller
overall size of the hypox gland and the convex surface and reduced
relative area of cortex, particularly the inner zona reticularis,
relative to medulla. C, D, Dissociated medullary cells
viewed under bright field (C1, D1) and
immunofluorescence after staining for the catecholamine-synthesizing
enzyme TH (C2, D2) appear essentially unaffected
by hypophysectomy. In contrast, hypox cells exhibited a reduced
immunoreactivity to the epinephrine-synthesizing enzyme PNMT
(C3, D3), with substantially fewer, although not a
complete loss of, strongly reactive cells. Scale bar: C1,
D1, 50 µm.
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Inside-out patches pulled from hypophysectomized rat chromaffin cells
were qualitatively similar to those from unoperated animals. BK
channels are characterized by their codependence on voltage and
cytoplasmic [Ca2+] as well as their
large single-channel conductance. Activation of currents elicited by a
step to +80 mV from negative holding potentials
(Vh = 100 mV) revealed channels with activation
and inactivation kinetics requiring significant membrane depolarization in constant 1 µM
[Ca2+]i. As
discussed below, both hypox and normal rat patches typically expressed
predominantly inactivating (BKi) current,
although sustained (BKs) and mixed
(BKi and BKs) currents were
found in a smaller number of patches. A series of traces (Fig.
2A, top four
traces) recorded from a small hypox patch exhibiting a mixed-BK
phenotype reveals at least three to four BKi
channels and at least one sustained or very slowly inactivating
BKs channel. In agreement with previous reports
for normal rat chromaffin cells (Solaro et al., 1995; Lovell et al.
2000), single-channel conductances for both channel types were
calculated to be ~270 pS (in symmetrical
K+). An ensemble average of 16 traces
(Fig. 2A, bottom trace) illustrates the
dependence of the channels on intracellular
[Ca2+]. The ~25 pA current present in
1 µM Ca2+ was
almost entirely absent in zero Ca2+
saline. As discussed below, few if any additional voltage-dependent channels were activated by this step in the absence of
Ca2+. The current was quickly restored
after return to normal saline (washout not shown).
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Figure 2.
Hypophysectomized rat chromaffin cells express
inactivating and non-inactivating large-conductance voltage- and
calcium-dependent K+ currents. BK channel activation
is tightly controlled by cytoplasmic [Ca2+].
A, Top four traces, Single traces
recorded from an inside-out patch show the rapid activation of
individual channels activated during consecutive steps to +80 mV in the
presence of 1 µM [Ca2+]i
(Vhold = 100 mV). At least four to five
large-conductance channels are visible above the baseline.
Bottom trace, An ensemble average of 16 such steps
reveals a mixture of both non-inactivating and slowly inactivating BK
current components. Replacement of the 1 µM
[Ca2+]i with zero-calcium saline
abolishes nearly all K+ current (washout not shown).
B, BK channel characterization was further assessed by
perfusion of pharmacological blockers onto channels in outside-out
patches. Ensemble-averaged currents were suppressed by 60 and 90%
after treatment with 1 mM TEA chloride (top)
or 10 nM CTX (bottom), respectively.
C, In an inside-out patch, ensemble-averaged
traces produced by repeated steps to +80 mV from a
series of increasingly positive conditioning potentials activated a
rapid and completely inactivating voltage-dependent potassium current
(conditioning voltages shown to the left of each
trace). D, Peak conductance measurements of the
currents in C were plotted as a function of the
conditioning potential and fit to Boltzmann equations to illustrate the
voltage dependence of BK channel activation ( ) and inactivation
( ).
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Both inactivating and non-inactivating BK currents in normal and hypox
cells exhibited BK-typical pharmacological block by relatively low
concentrations of TEA+ and CTX, as
illustrated in Figure 2B. Perfusion of
TEA+ (1 mM) onto
outside-out patches produced a reversible reduction by at least 50%,
and 10 nM CTX reduced the current by ~90%.
Currents other than BK in patches were small. Exposure of the same
inside-out patch to either potassium chloride- or potassium
methanesulfonate-based salines yielded virtually identical results,
suggesting that few if any chloride channels or chloride-sensitive
K+ channels are expressed in chromaffin
cells. We occasionally recorded a calcium-dependent leak current with
little single-channel noise and no voltage dependence, but this tended
to diminish within a few minutes and was eliminated by leak subtraction
protocols. There was no significant contribution to the current traces
by voltage-gated channels that were calcium independent in either normal or hypox cells. Occasionally a voltage- and calcium-independent current with single-channel conductance approaching that of BK channels
was recorded. The occurrence of such channels did not differ detectably
between normal and hypox cells, but patches in which these channels
interfered with measurement of the voltage-dependent component were
excluded from the data analysis.
Peak amplitudes measured from macroscopic-like ensemble traces were
used to determine the voltage dependence of activation and
inactivation. In Figure 2C, sample traces from a typical
patch expressing predominantly BKi current are
shown. Depending on the number of channels in the patch and the time
available before patch breakdown, 5-15 repeat traces were averaged for
conductance (G) values (Fig.
2D).
Hypophysectomy alters the voltage-dependent gating of chromaffin
BK currents
Comparisons of STREX and ZERO splice variants of Slo in
Xenopus oocyte expression studies demonstrated that the
inclusion of STREX shifts the voltage dependence of gating in the
negative direction, or enhances the apparent calcium sensitivity. The
observed reduction in STREX associated with hypophysectomy (Xie and
McCobb, 1998) would thus predict a positive shift in the voltage
dependence of activation of native BK channels with hypophysectomy. To
test this we stepped patches from normal and hypox chromaffin cells to
increasingly positive test potentials in 20 mV increments. Cells were
initially held at a holding potential of 140 mV, a value sufficiently
negative to deinactivate, and thus uncover, virtually all available
channels. The voltage dependence of half-activation (V0.5) was then determined by plotting
peak conductance values as a function of test potential and fitting the
points with a standard Boltzmann equation. On average, patches from
hypox cells required more positive test potentials for activation than
did patches from normal cells. Thus mean
V0.5 values (±SEM) for hypox patches
were 36 mV more positive than were those for normal patches (Fig.
3A) (39.9 ± 5.08 mV for
24 hypox patches compared with 3.3 ± 4.27 mV for 24 normal
patches; p < 0.0001). The steepness of the voltage
dependence was not significantly different between groups (31.3 ± 2.7 and 24.6 ± 6.5 mV/e-fold change in conductance for hypox and
normal patches, respectively). From the frequency distribution in
Figure 3B, it is evident that both populations exhibited a
broad range of V0.5 values. The wide
variability of voltage-dependent gating observed can be partially
explained by heterogeneous mixing of BK channel types. Thus in
individual cells, BK channels may be composed of varying proportions of
STREX and ZERO-like subunits (as well as  subunits) as determined by
a binomial expansion from the percentages of starting subunits. Lovell
et al. (2000) and Ding et al. (1998) have argued that a similar
model can accurately predict the broad range of BK channel inactivation
rates that has been observed in both the rat and bovine chromaffin cell
population (see description below).
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Figure 3.
Hypophysectomy alters the voltage-dependent gating
of BK channels. A, BK currents from hypox cells are
half-activated at significantly more positive voltages than are those
from normal rat. Normalized mean value G-V composite
curves were generated from a set of independently averaged maximum
conduction, slope, and half-activation values obtained from Boltzmann
equation fits of ensemble currents from 24 normal and hypox cells.
B, Despite the broad spectrum of patch variability in BK
voltage dependence across both cell populations, the majority of hypox
cells exhibited the right-shifted BK. Hypox rats (39.9 ± 5.08 mV;
mean ± SEM) were on average half-activated
(V0.5) at more positive potentials
(+36 mV) than were comparable unoperated normal rats (A;
3.3 ± 4.27 mV; p < 0.0001). C,
D, Average rates of BK deactivation were similarly affected.
Ensemble-averaged traces of BK tail currents
(C), activated by brief steps to +80 mV followed
by a step down to 80 mV (Vh = 100),
were normalized with respect to peak current and overlaid to illustrate
the comparatively slow and fast deactivation kinetics recorded from
typical normal (thick trace) and hypophysectomized rat
cells, respectively. Single-exponential equations (thin
lines) were fit to between 10 and 90% of the maximum
deactivating current during the step to 80 mV from +80 mV.
Deactivation kinetics was broadly distributed across a spectrum
of values in both populations (D). However, hypox
cells (n = 32; 3.9 ± 0.4 msec) on average
expressed currents that deactivated more quickly than did 55 normal rat
cells (4.7 ± 0.2 msec; p = 0.032).
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Previous studies showed that in conjunction with the shift in the
voltage of half-activation, inclusion of STREX in oocyte-expressed Slo transcripts increases and decreases the rates of
activation and deactivation gating, respectively (Saito et al., 1997;
Xie and McCobb, 1998). Our comparison of native BK gating kinetics in
normal and hypox chromaffin cell patches gives results consistent with
a decrease in the relative abundance of STREX splice variants associated with hypophysectomy. In Figure 3C, averaged
ensemble traces from hypox and normal rat inside-out patches were
overlaid to illustrate the typical effect of hypophysectomy on the
rates of channel activation and deactivation. Despite heterogeneity across both populations (Fig. 3D), hypophysectomy decreased
the average time constant for deactivation from 4.7 ± 0.2 msec
(mean ± SE) to 3.9 ± 0.4 msec (n = 55 normal and 32 hypox patches, respectively; p = 0.032). Time constants for activation averaged 2.0 ± 0.3 and 3.9 ± 0.5 msec for 55 normal and 32 hypox patches, respectively (p = 0.0005). The distributions of deactivation
values indicate a greater proportion of slowly deactivating patches in
normal cells (Fig. 3D). Apparent bimodalities in the
distributions of V0.5 values and
deactivation kinetics (Fig. 3B,D) raise the possibility that
hypophysectomy might functionally alter a subpopulation of cells.
However, sampling limitations and the difficult nature of these
measurements prevent a firm conclusion at this time. Taken together,
the results described above are consistent with the idea that a
decrease in the relative abundance of STREX-containing channel subunits
after surgical ablation of the pituitary alters the gating properties
of native BK channels.
BK inactivation is unaffected by hypophysectomy
The rate and extent of inactivation have been shown to vary
dramatically across chromaffin cell populations of rat and bovine, as
well as between the species (Solaro et al., 1995; Lingle et al., 1996;
Lovell et al., 2000). In oocytes coinjected with Slo cRNA,
at least two distinct but related accessory subunits can confer rapid
inactivation that is similar to that in native chromaffin cells
(Wallner et al., 1999; Xia et al., 1999, 2000; Uebele et al., 2000).
These and other related subunits that do not confer inactivation
can markedly shift the voltage dependence of activation gating as well,
although the latter effect varies between them. To address whether
inactivation properties are subject to regulation by pituitary
hormones, ensemble currents from numerous multichannel patches were
obtained. Inactivation properties were not appreciably different
between hypox and normal cells.
Patches from either normal or hypox rats were categorized as
BKi if at least 90% of the peak current in a
patch inactivated within 350 msec and BKs if at
least 90% of the current was sustained through 350 msec (see Materials
and Methods for details). Similar to what has been described previously
for normal rat cells (Neely and Lingle, 1992a,b; Solaro et al.,
1995; Lovell et al. 2000), the majority (67.1%) of hypox
patches were found to express the rapid and completely inactivating
variant of BK (Fig. 4A,
top left trace), whereas smaller proportions
exhibited the more slowly inactivating mixed current (24.4%;
n = 20; Fig. 4A, top
right, bottom left traces) or completely
non-inactivating BKs current (8.5%;
n = 7; Fig. 4A, bottom right
trace). The results are detailed in Table
1. No significant difference was found in
the fraction of current inactivated during a 350 msec voltage
step (BKi/BKtotal) in 1 µM Ca2+ measured
in 58 hypox (0.81 ± 0.04; mean ± SE) and 73 normal
(0.86 ± 0.03; p = 0.74) patches. Histograms
plotting the distribution of
BKi/BKtotal values for the
normal and hypox populations appear nearly indistinguishable (Fig.
4B). Time constants of inactivation measured in a
subset of 47 hypox and 67 normal cells, excluding those expressing
extremely slow or non-inactivating currents, measured 49.1 ± 3.0 msec as compared with 48.0 ± 2.2 msec (p = 0.81), respectively. These results suggest that the expression of subunits that confer inactivation is not under dynamic regulatory control by the pituitary.
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Figure 4.
BK current inactivation appears unaffected by
hypophysectomy. A, Ensemble-averaged currents activated
by steps to +80 mV in the presence of 4 or 1 µM
[Ca2+] illustrate the wide range of
channel inactivation kinetics found across the hypox cell population.
The measured rate constant of inactivation is shown at the top
right of each trace. B, Frequency
distributions showing the proportion of total current inactivated
during a 350 msec step
(BKi/BKtotal) suggest
that the hypox cells exhibit inactivation properties
(n = 82) that are very similar to those featured in
normal cells (n = 97).
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Table 1.
Breakdown of the numbers of inside-out patches expressing
only BKi, BKs, or both BKi and
BKs in chromaffin cells from normal and posthypophysectomy
adrenal glands
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The excitable properties of chromaffin cells are altered
by hypophysectomy
The BK functional heterogeneity that is apparent in rat and bovine
chromaffin cells has been postulated to underlie differences in their
firing properties, particularly with respect to rapid repetitive firing
(Solaro et al., 1995; Lingle et al., 1996; Xie and McCobb, 1998; Lovell
et al., 2000). Because an HPA-related change in chromaffin cell
excitability could have profound consequences on the neurosecretory
output of catecholamines, we have addressed whether hypophysectomy
measurably alters excitability per se by the use of perforated-patch
methods with current-clamp electronics. From both normal and hypox
cells, characteristically large action potentials, overshooting 0 mV
and with similar waveforms, could be elicited (Fig.
5A). Trains of action
potentials could be elicited by 2-sec-duration, suprathreshold current
injections. A broad range of spiking responses was evident across both
cell populations, ranging from cells responding with no more than a
single spike (Fig. 5A, top right trace) to those
responding with a varying number of spikes, peaking at up to 18, during
the 2 sec injection (Fig. 5A, bottom left trace).
Considerable variation in spike amplitude and duration was encountered,
as discussed below. Normal and hypox cells did not differ measurably
with respect to input resistance or mean initial resting potential.
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Figure 5.
Chromaffin cell repetitive firing properties are
altered by hypophysectomy. A, Series of spike trains
recorded from typical hypox and normal rat cells are plotted to
illustrate the broad range of spiking abilities across both cell
populations. In some cells the 2 sec depolarizing pulse was only
capable of maximally eliciting a single spike (A;
top right trace), whereas in others 18 or more could be
generated (A; bottom left trace).
B, On average, hypox cells were found to fire
significantly fewer spikes per 2 sec pulse (4.88 ± 0.46;
mean ± SEM; n = 48) than did comparable
normal cells (9.67 ± 0.69; n = 56;
p < 0.0001). The asterisk indicates
that mean values were significantly different according to a standard
Student's t test (*p < 0.05).
C, To characterize changes in the temporal dynamics of
repetitive firing, the precise timing of individual spikes from 48 hypox and normal cell traces that exhibited maximum firing were plotted
against time on a raster diagram. The hypox cell population fired fewer
total APs (227 vs 471 APs) than did normal cells. D,
Poststimulus time histograms from the cells in C,
normalized with respect to the total number of spikes, show that hypox
cells exhibit a more rapid time-dependent decay in firing frequency
than do normal cells.
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Chromaffin cells from hypox animals showed a markedly lower propensity
for repetitive firing. The number of spikes elicited by a progressive
series of long, current injection steps has been used as an indicator
of repetitive firing properties of chromaffin cells (Solaro et
al., 1995). Chromaffin action potentials can be carried by
Na+, Ca2+, or
both ionic currents. Progressive inactivation of
Na+ channels during a train of action
potentials typically produces a graded decrease in spike amplitude and
an increase in spike duration and Ca2+
dependence. Previous studies suggest that catecholamine exocytosis can
be triggered by the rapid rise in intracellular
[Ca2+] associated with the activation of
a variety of voltage-dependent Ca2+
channels (Artalejo et al., 1994; López et al., 1994). Therefore, we counted as a spike any quick, transient voltage inflection that
exceeded the baseline and was indicative of the regenerative activation
of Na+ or
Ca2+ channels. To minimize variation from
preexisting Na+ or
Ca2+ channel inactivation, the membrane
potential between steps was held between 70 and 75 mV, by manually
adjusting a small holding current, if needed. The beginning amplitude
and serial increment of the steps were adjusted by trial and error to
fit the input resistance of the cell, raising the "baseline"
voltage during the step at modest increments through the range over
which spikes could be elicited. Under these conditions, hypox cells
were consistently found to fire many fewer spikes than did normal
cells. On average, the maximum number of spikes that could be elicited
was 4.88 ± 0.46 (mean ± SEM; n = 48) for
hypox cells compared with 9.67 ± 0.69 for normal cells (Fig.
5B) (n = 56; p < 0.0001, Student's unpaired t test for mean differences). The raster
plots and frequency distributions in Figure 5, C and
D, illustrate the differences between treatment groups.
Differences in the peak frequency of action potential generation in the
earlier part of the steps and in the tendency to continue firing over
the step duration both contribute to the mean differences in spike
numbers (Fig. 5D).
Features of the action potential waveform also differed between
normal and hypox cells (Fig. 6). Among
normal and hypox cells capable of firing at least one spike, the action
potential peak-to-trough amplitude was slightly greater for normal than
for hypox cells (Fig. 6B) (p = 0.005, 0.078, and 0.010 for first, second, and third spikes,
respectively). Moreover, the AHP amplitude (the difference between the
baseline voltage and the voltage at the bottom of the trough) was
smaller for hypox than for normal cells (Fig. 6C), and
half-amplitude duration was greater for hypox than for normal cells
(Fig. 6D) (p = 0.06, 0.015, and 0.003 for first, second, and third spikes, respectively). The
divergence between normal and hypox AP waveforms continued to progress
beyond the first three spikes, as can be observed qualitatively in
Figure 5A.
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Figure 6.
Hypophysectomy decreases repetitive firing,
altering features of the action potential waveform. A,
The third APs from a normal and a hypox trace were
selected and overlaid to illustrate the effect of hypophysectomy on
spike waveform. From such traces, the peak-to-trough
amplitude (PTA), the magnitude of the AHP, and the half-amplitude spike
duration (HAD) were measured for a subset of cells capable of firing at
least a single spike. A more detailed description of the methods used
to quantify AP waveform features can be found in Materials and Methods.
B, Normal cells were found to have a greater PTA than do
hypox cells (p = 0.005, 0.078, and 0.010 for
the first, second, and third spikes, respectively). C,
Similarly, the absolute magnitude of the AHP was found to be
larger for normal than for hypox cells (p = 0.332, 0.014, and 0.003 for the first, second, and third spikes,
respectively). D, HADs for the first three action
potentials were greater for hypox than for normal cells
(p = 0.06, 0.015, and 0.003 for the first,
second, and third spikes, respectively). Asterisks
indicate that mean values were significantly different according to a
standard Student's t test (*p < 0.05). Ampl., Amplitude; Num.,
number.
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The observed differences in action potential waveform could be
primarily or fully attributed to the changes in BK functional properties described above. Although changes in
Na+ or Ca2+
current density that are associated with hypophysectomy, if they occur,
could contribute to waveform changes, reduced activation of BK channels
would be expected to both slow repolarization and diminish the AHP.
This would increase the number of channels entering an inactivated
state and reduce the number recovering from inactivation, thus
decreasing the number of Na+ channels
available to drive subsequent spikes. In turn, the shorter resulting
spikes would be less effective in activating BK channels, worsening the
progressive spike broadening and further diminishing the AHP.
Functional BK channels could thus be the critical factor in minimizing
the progressive accumulation of Na+ and
Ca2+ channels in an inactivated state. A
sharp decrease in BK channel expression with hypophysectomy might also
affect AP waveforms and repetitive firing, an argument that would be
functionally equivalent to a positive shift in the gating of individual
channels. However, this is difficult to measure in whole-cell mode,
independent of changes in calcium current, because of the complexity
introduced by the interaction between changes in the BK primary voltage
dependence and the secondary voltage dependence of the BK
channel, which derives both from the voltage-dependent gating
of calcium channels and the U-shaped calcium I-V curve.
The results presented here suggest that BK channels can drive rapid AP
repolarization and enhance the duration and amplitude of AHPs,
properties speculated to be important for facilitating repetitive
firing. Recent modeling studies of turtle cochlear hair cell electrical
tuning (Wu and Fettiplace, 1996) and rat hippocampal pyramidal cell
spike broadening (Shao et al., 1999) suggest that even subtle shifts in
the voltage dependence and/or kinetics of potassium channel gating will
significantly alter features of cellular excitability. To investigate
these issues we constructed a mathematical simulation of cellular
excitability using the computational modeling package Nodus (De
Schutter, 1989). Two non-inactivating voltage-dependent potassium
currents (IKv20 and
IKv40; numbers indicate
V0.5 values for the respective
currents) were independently paired with a classical Hodgkin and
Huxley-type fast-inactivating sodium current (Hodgkin and Huxley, 1952)
(Fig. 7A) and a leak current
in a model cell with dimensions and physical parameters similar to
those measured in rat chromaffin cells. A detailed description of the
modeling parameters can be found in Materials and Methods. In a
symmetrical potassium gradient, brief steps to positive potentials from
100 mV activate voltage-dependent currents (see Fig. 7A,
inset graphs). Conductance-voltage plots, constructed by
plotting the peak current as a function of the test potential,
illustrate the ~20 mV shift in the voltage dependence of
half-activation between IKv20 and
IKv40 (Fig. 7A). As
predicted by the shift in voltage dependence, the rates of
IKv20 channel activation and
deactivation were also faster and slower than were those of
IKv40, respectively. The effect of
this voltage shift on repetitive firing properties is illustrated in
Figure 7C. Over a broad range of 1 sec depolarizing current
pulses (0-2 nA), the IKv20 cell
responded with a greater range of sustained spiking (between 1 and 13 APs/sec) than did the IKv40 cell
(2-3 APs/sec; Fig. 7C). An overlay of the first APs from
the IKv20 and
IKv40 cells elicited by a brief 10 msec (2 nA) depolarizing step suggests that both an increased AHP
amplitude and fast AP repolarization, features promoted by the
left-shift in the voltage dependence of gating, play a role in
facilitating increased excitability (Fig. 7B). These
results argue that even in the simplest scenario (i.e., a cell that
contains only two distinct channel types), shifting the voltage
dependence of potassium channel gating in the negative direction can
greatly enhance repetitive firing ability. As such, the modeling
results support the idea that a shift in BK channel properties
resulting from hypophysectomy can at least in part explain the
increased firing ability observed in the normal rat cells.
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Figure 7.
A conductance-based model composed of a
voltage-gated sodium current, a leak current, and a potassium current
can exhibit dramatic differences in repetitive firing ability. A
detailed description of the model can be found in Materials and
Methods. A, A conductance-voltage plot
(G-V) shows the steady-state activation for the
two voltage-dependent potassium currents used in the model
(IKv20, IKv40; 20 and 40 represent measured V0.5 values for
each channel). The G-V plots were constructed by
plotting the peak values of currents (A, inset graphs)
activated in a symmetrical potassium gradient by a series of increasing
test potentials. B, An expanded view of the first APs
elicited from the IKv20 (thick
line) and IKv40 (thin
line) model cells by a short 2 nA current pulse is shown.
Shifting the voltage dependence of activation in the negative direction
effectively decreased the half-amplitude spike duration while
increasing the magnitude of the AHP. C, Over a broad
range of depolarized membrane potentials, the cell expressing the
IKv20 potassium current
(left) was better able to sustain repetitive firing than
was the cell expressing only the IKv40
channels (right). Current injection values are shown to
the left of each pair of plots.
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The idea that BK channels enhance repetitive firing ability in
chromaffin cells is further supported by pharmacological experiments. The contributions of BK channels to AP waveform and repetitive firing
were explored by applying 1 mM
TEA+ during current-clamp recording. This
concentration typically blocks BK current by >60% in outside-out
patches (see Fig. 2B). TEA+ reversibly reduced the repetitive
firing of all seven cells that otherwise fired a train of spikes in
response to current steps from an average of 10.9 ± 4.5 spikes/2
sec (mean ± SD) to 3.9 ± 2.2 spikes/2 sec
(p < 0.0001; Fig.
8A,B).
TEA+ application also increased the
average spike duration by at least twofold (22.0 ± 10.0 vs
8.3 ± 1.6 msec; TEA vs control), while significantly decreasing
the magnitude of the AHP for the first spike (0.4 ± 0.7 vs
7.5 ± 1.6 mV; p < 0.0001; Fig. 8C).
In agreement with previous studies using the BK channel blocker
charybdotoxin (Solaro et al., 1995), these experiments further support
the suggested role for BK channels in defining action potential
waveform and repetitive firing properties and strongly suggest that the
differences between normal and hypox chromaffin cell excitability are
likely to derive from the differences in the voltage-dependent gating of BK channels in these cells.
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Figure 8.
Blockade of channel function significantly reduces
repetitive firing. A1, Typical normal chromaffin cells
can be stimulated to fire >15 spikes during a 2 sec depolarizing
current pulse. A2, Subsequent bath application of 1 mM TEA+, a potent blocker of BK channel
activation, reversibly reduces the maximum rate of firing by >70%.
A3, Replacement of the bath saline with the standard
recording solution quickly restores normal firing ability.
B, Treatment with TEA+ significantly
reduced the average rate of firing from 10.9 ± 4.5 spikes/2 sec
(mean ± SD) to 3.9 ± 2.2 spikes/2 sec
(n = 7; p < 0.0001).
C, Specifically, TEA+-mediated BK
blockade (second spike in A1-A3
expanded) results in reproducible spike broadening and a reduction in
the magnitude of the AHP.
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Sustained chromaffin cell repetitive firing (or high-frequency patterns
of stimulation) has been shown to favor increased catecholamine release
via a primarily calcium-dependent mechanism (Zhou and Misler, 1995;
Elhamdani et al., 1998). Thus in normal rat cells, repetitive spiking,
characterized by long trains of relatively large-amplitude,
short-duration APs, would be expected to facilitate calcium entry and
epinephrine release by repeated activation of voltage-dependent calcium
currents. By driving rapid AP repolarization and increasing spike AHP
duration, BK channels would be predicted to facilitate calcium influx
through open channels when the driving force is maximal. Alternatively,
hypox rat APs, characteristically smaller and of longer duration, might
provide for an elongated calcium-entry window, thus facilitating
release. We therefore directly measured the effect of the AP waveform
on the dynamics of calcium entry.
In whole-cell recording mode, a series of positively increasing voltage
steps (Vh = 70 mV) activate large inward
voltage-dependent calcium currents (Fig.
9A) in normal and hypox rat
cell populations (n = 5). No significant differences
between the mean voltage of peak current activation or the kinetics of
calcium channel activation were observed (Fig. 9B). To
assess the importance of the action potential waveform in driving the
influx of calcium, a set of APWs broadly representing the spectrum of
APs recorded from normal and hypox cells was presented to either normal
or hypox cells using the whole-cell patch-clamp recording configuration
and solutions designed to isolate calcium currents. A short-HAD,
large-PTA normal rat third AP (nAPW) and a long-HAD, short-PTA hypox
third spike (hAPW) were presented to normal and hypox rat cells. Both
cell types (n = 5) responded to the presentation of
APWs with characteristic calcium spikes (Fig. 9C) that could
be reversibly blocked by the addition of 100 µM
cadmium (Cd2+) to the bath saline (result
not shown). A measure of the ability of each APW to trigger calcium
entry was established for the normal and hypox rat cells by dividing
the integrated area under the hypox APW-triggered calcium spike (hCS)
into that of the normal spike (nCS). The magnitude of the
calcium currents elicited by presentation of the same APW to hypox and
normal rat cells did not differ appreciably. On average, the ratio of
calcium spike areas (nCS/hCS) was nearly identical for the normal and
hypox cells (0.98 ± 0.06 vs 0.91 ± 0.16; mean ± SEM;
Fig. 9D), suggesting that despite dramatic differences in
the shapes of the APWs accumulated calcium entry would be similar.
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Figure 9.
The calcium entry during sustained repetitive
firing is likely to be more affected by spike frequency than by
features of the action potential waveform. A, In hypox
and normal rat chromaffin cells, calcium currents can be activated by
repeated steps to increasingly positive voltages from 80 mV.
B, Normalized I-V plots constructed by
measuring peak inward currents activated during a series of positive
voltage steps (like those in A) reveal only a minor
difference in the average voltage of peak current activation for the
normal and hypox rat cell populations (n = 5).
C, APWs (voltage trace) recorded
previously from typical normal and hypox spike trains were presented to
chromaffin cells in whole-cell voltage-clamp recording mode. Calcium
currents were elicited by waveform clamp in both hypox and normal cells
(n = 5). Total calcium influx was estimated by
integrating the area between the baseline and the current
trace. Calcium entry was quite similar in the two waveforms,
with greater duration barely compensating for the stronger
depolarization in the normal waveform. D, For
normal and hypox cells, average calcium accumulations during the normal
waveform, expressed as a fraction of that during the hypox waveform,
were 0.98 ± 0.06 and 0.91 ± 0.16, respectively.
E, Calcium entry elicited by presentation of normal
(right) or hypox (left) AP spike trains
in waveform clamp is shown. Calcium influx closely followed spike train
frequency, suggesting that calcium influx is more likely influenced by
repetitive firing than by features of the AP waveform.
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As described, sustained spiking in chromaffin cells favors
catecholamine exocytosis via a primarily calcium-dependent mechanism. To examine the effect of repetitive firing on calcium entry we presented both normal and hypox cells with spike train waveforms recorded previously from normal and hypox rat cells. Calcium spikes elicited by trains of APWs closely followed the rate of spike presentation, although apparent calcium channel inactivation appears to
result in reduced calcium spike amplitude during successive APWs.
Plateau depolarization, a feature of some cells that fail to fire
repetitively (see Fig. 5A), elicited only minor influxes of
calcium that are unlikely to contribute significantly to transmitter release (Fig. 9E). Together, these experiments suggest that
catecholamine release is likely to be increased more effectively by
increasing repetitive firing properties than by broadening the APW.
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DISCUSSION |
The primary finding of this paper is that surgical ablation of the
pituitary changes the properties of adrenal chromaffin BK channels as
characterized in excised patches and also changes features of cellular
excitability measured with the perforated-patch technique. More
specifically, BK currents in patches from hypox chromaffin cells
typically reach half-maximal activation at more positive voltages,
activate more slowly, and deactivate more rapidly than do channels in
patches from normal animals. Features of cellular excitability that
were found to differ in perforated-patch recordings included changes in
action potential waveform and the maximum numbers of spikes that could
be elicited during prolonged depolarizing current injection. Enhanced
repetitive firing greatly increases cytosolic calcium with important
functional consequences for controlling the magnitude of epinephrine secretion.
The finding that whole-cell excitability and BK functional properties
change in parallel supports the hypothesis that BK channels are a major
determinant in shaping intrinsic excitability. Solaro et al. (1995)
have suggested, on the basis of the heterogeneity in chromaffin cells,
that differences in BK channel deactivation might be responsible for
driving repetitive firing. Thus cells exhibiting slow BK deactivation
tended to exhibit BK inactivation (i.e., were BKi
cells), and BKi cells tended to have better
repetitive firing during prolonged depolarization than did
BKs cells. That BK channels can have a positive
rather than a negative relationship to repetitive firing is further
supported by evidence that BK channel blockade by
TEA+ or CTX can reduce or even eliminate
recurrent firing (Fig. 8A) (see also Solaro et al.,
1995). The results presented here suggest that several features of BK
gating contribute to the improved repetitive firing observed in normal
chromaffin cells. First, BK channels that open earlier (at more
negative voltages) and more quickly will drive more rapid
repolarization, thus minimizing entry of
Na+ and Ca2+
channels into an inactivated state. Second, slower deactivation will
increase both the duration and magnitude of the spike AHP, facilitating
deinactivation of inactivated Na+ and
Ca2+ channels. In this scenario, the
tendency of Na+ and
Ca2+ channels to accumulate in an
inactivated state comprises the primary limiting factor with respect to
sustained firing, and BK currents represent perhaps the most important
force counteracting this limitation. Modeling studies investigating the
role of potassium channels as enhancers of repetitive firings argue
that even an approximately 20 mV shift in half-activation can
substantially improve sustained firing by driving spike repolarization
and increasing AHP magnitude. In agreement with this view, the majority
of normal cells, as compared with hypox cells studied in parallel,
characteristically fired a greater number of spikes, the spikes
exhibited a shorter half-amplitude duration, and the AHP was more
pronounced. Moreover, the progressive decline in AP amplitude and
increase in half-amplitude width associated with the accumulative loss
of Na+ and
Ca2+ channels during sustained firing were
more severe in hypox cells than in normal cells. Thus normal cells were
better able to sustain spike amplitude and duration characteristics
over an action potential train.
Together with the previous studies of Xie and McCobb (1998), the
results suggest a molecular mechanism for pituitary control of
chromaffin cell excitability. Xie and McCobb (1998) reported that
hypophysectomy reduces the proportion of Slo transcripts including STREX, an effect prevented by injections of the pituitary hormone ACTH. Patches pulled from oocytes expressing homotetramers of
STREX or ZERO revealed that the former were half-activated at more
negative voltages and exhibited faster and slower activation and
deactivation kinetics, respectively. The straightforward hypothesis was
that hypox BK channels should appear more like oocyte-expressed Slo transcripts lacking STREX. This hypothesis is confirmed
here. Interestingly, the 36 mV positive shift in the voltage of
half-activation was greater than the difference between STREX and ZERO
forms expressed separately (as homomultimers). One explanation for this
observation is that native and oocyte environments somehow
differentially accentuate the difference deriving from STREX inclusion.
For example, in pituitary cells, a phosphorylation that impacts on the
Slo voltage-dependent gating appears to depend on the
presence of STREX (Shipston et al., 1999). At least five potential
sites on STREX meet the consensus criteria for cGMP-dependent protein
kinase and PKC-mediated phosphorylation, two of which also satisfy the criteria for PKA phosphorylation (Saito et al., 1997). Perhaps unavailable in oocytes, such a secondary factor might, but need not
necessarily, be subject to dynamic HPA regulation in native cells.
Factors unrelated to STREX splicing that are subject to HPA control
could also contribute to the differences we report here. As discussed
further below, accessory subunits, particularly those in the family
(McCobb et al., 1995; McManus et al., 1995; Dworetzky et al.,
1996; Meera et al., 1996; Oberst et al., 1997; Saito et al., 1997;
Jones et al., 1999a,b; Ramanathan et al., 1999; Wallner et al., 1999;
Xia et al., 1999, 2000; Uebele et al., 2000), can have effects on
activation and deactivation gating as well as on inactivation gating.
Other candidate mechanisms include post-translational modulation.
Despite possible contributions from unknown mechanism(s), hormonally
driven changes in STREX splicing can account for a large part of the
differences attributed to hypophysectomy.
With respect to activation and deactivation gating, BK currents in
bovine chromaffin cells more closely resemble those of hypox rats than
those of normal rats. Thus bovine currents are slower activating and
faster deactivating and activate at more positive voltages than do
normal rat BK currents. Importantly, the abundance of STREX relative to
ZERO forms of Slo mRNA is much less in bovine than in normal
rat adrenal medulla and more comparable with that in the hypox rat
(Chatterjee et al., 1999) (our unpublished observations). This
correlation supports the idea that differences at the STREX splice site
account for functional differences in channel properties.
Hormones mediating pituitary control of chromaffin excitability are
still under investigation. ACTH injection can prevent the decline in
STREX that would otherwise result from pituitary ablation (Xie and
McCobb, 1998). The precipitous drop in corticosterone that results from
the loss of ACTH with hypophysectomy could act directly on STREX
splicing. Although the impact on excitability is unknown,
corticosteroids have been reported to increase Kv1.5 K+ channel transcription selectively in
rat pituitary cells, ventricular myocytes, and skeletal muscle cells
(Levitan and Takimoto, 1998). Plasma ACTH levels in rats have been
measured at levels between 5 and 10 times those of bovine, and
corticosterone levels in rats are nearly 10-fold greater than levels of
the predominant analog cortisol in cows (el-Nouty et al., 1978;
Koehl et al., 1999; Manzanares et al., 1999; Veissier et al.,
1999; Viau et al., 1999). Although circumstantial, these arguments
raise the possibility that the HPA plays a role in both
species-specific and dynamic regulation of chromaffin BK gating
properties and excitability.
Interestingly, bovine currents also differ from those of normal rats in
having inactivation that is much slower or incomplete. In this respect,
currents in hypox rat cells do not resemble those in bovine.
Inactivation is undoubtedly conferred by one or more members of the subunit gene family, although which are involved has not been
established in chromaffin cells. Some but not all family members
also may shift the voltage dependence of BK gating in artificial
expression systems. The lack of change associated with hypophysectomy
that we see in inactivation would suggest that major changes in subunit composition may not occur. The data suggest that regulation of
inactivation is at least partially independent of the regulation of
activation and deactivation gating.
Accompanying the drop in STREX abundance and BK functional changes
resulting from hypophysectomy is a precipitous decline in the levels of
the epinephrine-synthesizing enzyme PNMT in chromaffin cells (Xie and
McCobb, 1998; see also Stachowiak et al., 1988; Viskupic et al., 1994).
Bidirectional changes in PNMT mRNA and PNMT enzymatic activity can be
driven by more subtle perturbations of glucocorticoid levels and by
behavioral stress paradigms (Wong et al., 1992; Baruchin et al., 1993;
Lemaire et al., 1993; Betito et al., 1994; Wong et al., 1995). Even
brief exposure to intense stress and repeated exposure to milder stress
can produce lasting changes (Lemaire et al., 1993; Betito et al.,
1994). The link between stress and PNMT is further supported by the
elucidation of glucocorticoid response element (GRE)-mediated
regulation of PNMT transcription. The present studies suggest that
changes in the epinephrine synthetic capacity of secreting cells may be
accompanied by improved repetitive firing that functionally increases
intracellular [Ca2+] and enhances
epinephrine secretion. It has long been recognized that the dynamics of
the adrenal epinephrine response profoundly affects cardiovascular and
respiratory function not only in crisis response situations but daily.
Epinephrine responses thus contribute to complex positive and negative
feedback regulation of brain, immune, metabolic, reproductive, and
other functions. The present findings motivate further exploration of
the possibility that chronic overactivation of the HPA produces a
functional hypertrophy of chromaffin excitability that is potentially
detrimental, perhaps elevating the risk of heart attack or stroke
provoked by acute autonomic activation.
| |
FOOTNOTES |
Received Dec. 22, 2000; revised Feb. 28, 2001; accepted March 2, 2001.
This work was supported by a grant from the American Heart Association
and National Institutes of Health to D.P.M. P.V.L. was supported
by National Institute of Mental Health Training Grant MH15793. We thank
Drs. Ron Harris-Warrick, Jason MacLean, and Bruce Johnson for many
helpful discussions and critical reading of this manuscript; D. G. James, A. Thabet, J. O'Brien, A. Gersten, and the Cornell Veterinary
Diagnostic Laboratories for technical assistance; and P. Zeller and S. Mahmoud for assistance with the computer simulations.
Correspondence should be addressed to Dr. David P. McCobb, Department
of Neurobiology and Behavior, W153 Mudd Hall, Cornell University,
Ithaca, NY 14853. E-mail: dpm9{at}cornell.edu.
| |
APPENDIX |
The ionic currents described by Equation 2 can be written as:
where gion is the maximum
conductance for each ionic current, and m, h, and
n are time- and voltage-dependent rate constants (written as
 in the following equations) for the activation and inactivation
rate constants. The time and voltage dependence of the rate constants
is given by:
where:
The magnitude and time course of the activation and inactivation
parameters used to describe the currents in Equation 2 are given below.
INa:
IKv20:
IKv40:
| |
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