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The Journal of Neuroscience, February 1, 2001, 21(3):1067-1075
Heterogeneity in the Basic Membrane Properties of Postnatal
Gonadotropin-Releasing Hormone Neurons in the Mouse
Joan A.
Sim,
Michael J.
Skynner, and
Allan E.
Herbison
Laboratory of Neuroendocrinology, The Babraham Institute, Cambridge
CB2 4AT, United Kingdom
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ABSTRACT |
The electrophysiological characteristics of unmodified, postnatal
gonadotropin-releasing hormone (GnRH) neurons in the female mouse were
studied using whole-cell recordings and single-cell RT-PCR
methodology. The GnRH neurons of adult animals fired action potentials
and exhibited distinguishable voltage-current relationships in
response to hyperpolarizing and depolarizing current injections. On the
basis of their patterns of inward rectification, rebound depolarization, and ability to fire repetitively, GnRH neurons in
intact adult females were categorized into four cell types (type I,
48%; type II, 36%; type III, 11%; type IV, 5%). The GnRH neurons of juvenile animals (15-22 d) exhibited passive membrane properties similar to those of adult GnRH neurons, although
only type I (61%) and type II (7%) cells were encountered, in
addition to a group of "silent-type" GnRH neurons (32%) that were
unable to fire action potentials. A massive, action
potential-independent tonic GABA input, signaling through the
GABAA receptor, was present at all ages.
Afterdepolarization and afterhyperpolarization potentials (AHPs) were
observed after single action potentials in subpopulations of each GnRH
neuron type. Tetrodotoxin (TTX)-independent calcium spikes, as well as
AHPs, were encountered more frequently in juvenile GnRH neurons
compared with adults. These observations demonstrate the existence of
multiple layers of functional heterogeneity in the firing properties of
GnRH neurons. Together with pharmacological experiments, these findings
suggest that potassium and calcium channels are expressed in a
differential manner within the GnRH phenotype. This heterogeneity
occurs in a development-specific manner and may underlie the functional
maturation and diversity of this unique neuronal phenotype.
Key words:
calcium channels; GnRH; LHRH; GABAA; receptor; patch-clamp electrophysiology; potassium channels; puberty
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INTRODUCTION |
The gonadotropin-releasing
hormone (GnRH) neurons are thought to represent a functionally
discrete population of cells that control mammalian fertility by
regulating the secretion of gonadotropic hormones from the pituitary
gland. Despite their clear importance in the survival of mammalian
species, relatively little is known about their molecular properties
and even less information is available on their electrophysiological
characteristics. This has resulted principally from the scattered
distribution of the GnRH cell bodies within the basal forebrain, which
has made their investigation in situ extremely difficult.
Because these neurons secrete GnRH in a pulsatile manner (Levine et
al., 1991 ), important questions exist about the basic membrane
properties of these neurons, as well as the mechanisms of pulsatility
and synchronicity within the GnRH neuronal network as a whole. It also
remains unclear whether the GnRH population is indeed a functionally
homogenous population, as is assumed for other neuroendocrine phenotypes.
Recent studies using GnRH promoter transgenics to target the GnRH
phenotype in the mouse (Pape et al., 1999; Skynner et al., 1999a;
Spergel et al., 1999; Simonian et al., 2000; Suter et al., 2000) have
provided one avenue through which the molecular and electrical nature
of GnRH neurons can be addressed in their native environment. In the
course of our own studies on fluorescent GnRH neurons in transgenic
mice, we found that this phenotype could, in fact, be recognized on a
topographical and morphological basis in a relatively reliable manner.
Thus, by combining visual identification with post hoc
single-cell RT-PCR characterization, we were able to demonstrate that
approximately one-half of neurons selected on the basis of their
location and morphology contained GnRH transcripts and therefore were
GnRH neurons (Skynner et al., 1999b). Although somewhat more laborious,
this approach does have the great benefit of avoiding any potential
confounding effects of fluorescence and/or transgene expression in GnRH neurons.
In the present study, our goal was to provide a characterization of the
basic membrane properties of native, unmodified GnRH neurons in the
female mouse. The GnRH neurons transcend from what is believed to be a
relatively quiescent state to one of episodic cyclical activity at
puberty (Ojeda and Urbanski, 1994). Thus, we also compared the
electrophysiological characteristics of juvenile and adult GnRH neurons
to try and elucidate any fundamental electrophysiological differences
that might underlie their functional maturation. On the basis of the
responses of GnRH neurons to hyperpolarizing and depolarizing current
injection, we have found that this neuronal phenotype does not exhibit
a single electrophysiological profile but that, surprisingly, up to
four different types can be identified. Furthermore, we provide
evidence that the prevalence of the various cell types changes across
the time of puberty, as may the levels of functional calcium channels.
Such observations indicate that multiple levels of functional
heterogeneity exist in a development-dependent manner within the GnRH
phenotype of the mouse.
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MATERIALS AND METHODS |
Preparation of brain slices incorporating GnRH
neurons. All female mice (CBA/CaxC57BL/6J) were bred and housed
(lights on at 7:00 A.M. and off at 7:00 P.M.) at The Babraham
Institute and treated in accordance with UK Home Office regulations
under project 80/1005. Vaginal smears were taken on a daily basis to
identify adult female mice at diestrous or estrous stages of the
ovarian cycle. Between 9:00 and 11:00 A.M., juvenile (postnatal day
15-22) and adult (day 50-70) female mice were anesthetized with
isoflurane-RM (Rhone Merieux, Harlow, UK) and decapitated, and their
brains were rapidly removed and placed in ice-cold bicarbonate-buffered artificial CSF (ACSF) of the following composition (in
mM): 118 NaCl, 3 KCl, 0.5 CaCl2, 6.0 MgCl2, 11 D-glucose, 10 HEPES, and 25 NaHCO3 (pH 7.4 when bubbled with 95%
O2 and 5% CO2). Brains were blocked and glued with cyanoacrylate to the chilled stage of an
Oxford Vibratome (General Scientific, Redhill, UK), and 150-µm-thick
coronal slices containing the medial septum through to the preoptic
area were prepared. The slices were then incubated at 30°C for 30 min
in oxygenated recording ACSF (rACSF) consisting of (in
mM): 118 NaCl, 3 KCl, 2.5 CaCl2, 1.2 MgCl2, 11 D-glucose, 10 HEPES, and 25 NaHCO3, pH 7.3, and thereafter kept at room
temperature (20-23°C) for at least 1 hr before recording.
Whole-cell recording of GnRH neurons. Slices were
transferred to the recording chamber, held submerged, and continuously
superfused with rACSF at a rate of 6 ml/min. The slices were viewed
with an upright Axioskop FS microscope (Carl Zeiss, Jena, Germany) with
a 40× immersion objective (Achroplan 0.75W, Ph2, Zeiss), giving a
total magnification of 640× and Normaski differential interference
contrast optics. To aid visualization of neurons, a CCD camera (Sony
Corporation, Tokyo, Japan) was mounted on the microscope and
connected to a monochrome monitor (Panasonic). All recordings were made
at room temperature (20-23°C). Patch pipettes were pulled from
thin-walled borosilicate glass capillary tubing (1.5 mm outer diameter,
Clark Electromedical, Reading, UK) on a Flaming/Brown puller (P-97;
Sutter Instruments Co., Novato, CA). Pipette tips were coated with
either Sylgard resin (Dow Corning 184) or a wax pen (Dako, Glostrup,
Denmark) and fire-polished to a final resistance of 6-12 M . The
pipette solution was passed through a disposable 0.22 µm filter
before use and contained (in mM): 140 KCl, 1 CaCl2, 1 MgCl2, 10 HEPES, 4 MgATP, 0.1 Na2GTP, 10 EGTA, with pH adjusted to
7.3 with KOH. The reference electrode was a glass bridge containing 4%
agar-saline, of which one end was placed in the recording chamber and
the other end in a 3 M KCl-containing side
chamber connected to ground, via an Ag/AgCl pellet.
Whole-cell recordings were performed as described previously (Hamill et
al., 1981) using an Axoclamp-2B amplifier (Axon Instruments, Foster
City, CA) operating in bridge mode. Bridge balance was checked
frequently because of changes in series resistance. Current and voltage
were simultaneously generated and sampled on-line using a Digidata 1200 (Axon Instruments) interface connected to an IBM PC/AT clone. Signals
were filtered (0.3-10 kHz, Bessel filter of Axoclamp-2B) before
digitizing at a rate of 5 kHz. Acquisition and subsequent analysis of
the acquired data were performed using the "pClamp6" suite of
software (Axon Instruments). In addition, current and voltage signals
were recorded simultaneously onto a chart recorder (Gould TA 240, Valley View, OH) and DAT recorder (DTR 1204, Biological Sciences,
Claix, France). Traces and voltage-current curves were plotted using
"Origin 5" computer software (MicroCal Software, Northampton, MA).
After recordings of up to 1 hr duration, the cytoplasmic contents of
the recorded neuron were harvested under visual control, and
single-cell RT-PCR was used to examine for the presence of GnRH
transcripts as reported previously (Skynner et al., 1999b). Five
juvenile GnRH neurons exhibiting a silent-type electrophysiological profile were also assessed for the presence of GFAP transcripts, again
exactly as detailed previously (Skynner et al., 1999b). As controls,
the contents of cells located outside the distribution of the GnRH
neurons were harvested and processed for GnRH RT-PCR, as were the
contents of electrodes placed in the slice but not used to harvest
cellular contents (mock harvests).
Determination of membrane properties. Input resistance and
membrane time constants of neurons were estimated from small (0.02-0.1 nA, 100 msec duration) hyperpolarizing steps from resting membrane potential. Passing brief (20-30 msec) duration current pulses through
the recording electrode generated single action potentials. Parameters
such as spike amplitude, spike threshold, spike overshoot, and duration
were measured and given as mean ± SEM. Spike duration was
measured as two-thirds of the amplitude from baseline to peak. Afterhyperpolarizing potentials were characterized as those found to
occur immediately after depolarization. Statistical analysis was
undertaken by ANOVA with post hoc two-tailed t tests.
All drugs and reagents were applied via the superfusing ACSF solution.
Solutions were switched manually by means of a six-way tap, ensuring
that the bath was completely exchanged with control solution between
drug application (~20 sec). Unless stated otherwise, all
reagents were purchased from BDH/Sigma (Poole, UK). The drugs used were 4-aminopyridine (4-AP; Sigma), barium chloride
(BaCl2; Sigma), bicuculline methobromide (Tocris,
Bristol, UK), cadmium chloride (CdCl2; Sigma),
tetraethylammonium chloride (TEA-Cl; Lancaster Synthesis), and
tetrodotoxin (Alexis Corporation, San Diego, CA).
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RESULTS |
Identification of GnRH neurons
Using thin slices of the forebrain, neurons of ~10 µm diameter
that exhibited a bipolar-type morphology with a vertical orientation were identified within the medial septum and rostral preoptic area
(Fig. 1A).
Post-recording characterization with single-cell RT-PCR (Fig.
1B) revealed the presence of GnRH amplicons in 82% (31/38) of morphologically identified neurons in juvenile animals compared with 63% (44/69) of similarly identified cells in the adult
mouse. The visualization of putative GnRH neurons was greatly facilitated by the lack of extensive fiber tracts in the brain of
juvenile mice. No GnRH transcripts were detected in the cell contents
of neurons harvested from outside the medial septum and rostral
preoptic area, or in "mock harvests." The 213 bp amplicon product
(Fig. 1B) resulting from RT-PCR has been shown
previously to represent authentic murine GnRH-I cDNA (Skynner et al.,
1999b). Although providing positive amplicons with hypothalamic cDNA, the GFAP primers failed to detect any GFAP transcripts in the five
silent-type GnRH neurons recorded in juvenile mice. In our hands, the
post-recording identification was found to be dependent on the length
of our recording; long (>75 min) recordings invariably resulted in no
transcripts being detected. We therefore established a recording window
of  1 hr to ensure the detection of GnRH transcripts in recorded GnRH
neurons.
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Figure 1.
A, High-power photomicrograph of a
patched bipolar-type neuron (asterisk) located in the
rostral preoptic area subsequently proven to express GnRH transcripts.
B, Gel showing the presence of 213 bp GnRH amplicons in
cells 1, 2, 4, and 5. DNA 1 kb ladder is to the
right.
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General membrane properties and spontaneous activities of
GnRH neurons
Using the whole-cell configuration, the resting and active
membrane properties of juvenile and adult GnRH neurons were examined in
bridge mode. Resting membrane potentials were determined immediately after the rupture of the cell membrane and juvenile GnRH neurons found
to have a mean resting potential of  65.4 ± 1.5 mV
(n = 31). Adult GnRH neurons displayed resting
membrane potentials of a comparable range, with a mean value of
69.2 ± 1.1 mV (n = 44) (Table
1). We also found that the input
resistance, membrane time constant, spike threshold, and action
potential characteristics of juvenile and adult GnRH neurons were not
significantly different (Table 1).
In total, 27 of the adult GnRH neurons were from diestrous mice, and 17 were from estrous animals. With the single exception of action
potential duration, which was significantly greater in diestrous mice
(p < 0.05), no differences were detected in the
intrinsic membrane properties of adult GnRH neurons at these stages of
the estrous cycle (Table 1).
Approximately 80% of adult (34/44; 77%) and 60% of juvenile (18/31;
58%) GnRH neurons were found to be spontaneously active under
symmetrical chloride ion recording conditions (Fig.
2), with firing rates ranging from 0.02 to 6.5 Hz (adult, 0.9 ± 0.4 Hz; juvenile, 0.4 ± 0.1 Hz).
The addition of TTX (0.5 µM) to the bathing medium
revealed that the great majority of this activity was action potential
independent and thus spontaneous in nature (Fig. 2). Further addition
of bicuculline (10 µM) almost completely abolished these
spontaneous events (Fig. 2) in both adult (n = 6) and
juvenile (n = 5) GnRH neurons. Indeed, bath application of bicuculline alone (without preapplication of TTX) was able to
abolish almost all spontaneous events (data not shown). The effects of
TTX and bicuculline were reversible on washout (Fig. 2), whereas
complete recovery from compounds was dependent on the period of their
exposure to the slices.
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Figure 2.
Spontaneous synaptic activity recorded in GnRH
neurons from a 55-d-old female mouse. Top trace shows a
continuous trace of an experiment in which TTX (0.5 µM)
and bicuculline (10 µM) were applied to a GnRH neuron at
its resting membrane potential of 70 mV. The bottom
traces are expanded 1 sec traces recorded in control
(a), the presence of TTX
(b), the presence of both bicuculline and TTX
(c), and after washout
(d).
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Electrophysiological characteristics of adult GnRH neurons
The families of electrotonic potentials evoked in
individual adult GnRH neurons in response to short (20-30 msec
duration) and long (200 msec) duration intracellular current pulses
were found to be heterogeneous (Fig. 3).
The most striking difference was observed in response to 200 msec
hyperpolarizing current pulses where four main profiles (types I-IV)
were consistently observed (Fig. 3; Table
2). The most abundant GnRH neurons (type
I, 48%) exhibited a linear-type voltage relationship in response to
hyperpolarizing current pulses (Fig. 3A), whereas in type II
cells (36%) this linear relationship was not maintained with larger
hyperpolarization and resulted in "runaway" of the voltage
transient and the generation of negative-going spike (Fig.
3B). In the other two populations of adult GnRH neurons,
negative current pulses evoked inward rectifying conductances with
properties of either the anomolous rectifier (type III, 11%) (Fig.
3C) or IQ/H (type IV, 5%)
(Fig. 3D), with mixed permeability for sodium and potassium
rectification (Halliwell and Adams, 1982; Rudy, 1988; Pape, 1996).
Rebound depolarization was observed after the termination of the
hyperpolarizing steps in all cell types, except for type II (Fig.
3B), where it was never detected. The final distinguishing
feature of the four cell types was observed in their response to 200 msec depolarizing current pulses where trains of fast action
potentials, varying in their frequency of firing, were observed in cell
types I, II, and IV, whereas cell type III displayed an initial fast
action potential followed by trains of smaller and slower spikes (Fig. 3C).
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Figure 3.
Intrinsic membrane properties of four types
(I-IV) of GnRH neurons recorded in adult female mice.
A-D, Responses to 20 and 200 msec
depolarizing and hyperpolarizing current pulses. In all four cell
types, threshold stimulation elicited a single action potential, which
clearly shows depolarizing afterpotential (ADP) of various duration and
amplitude. In each cell type, 200 msec duration hyperpolarizing current
injection revealed the presence of inward rectifiers with distinct
kinetics. The four cell types are characterized on the basis of their
inward rectification as well as the absence of rebound depolarization
in type II cells and the inability to fire repetitively after
depolarization in type III cells. Resting membrane potentials are given
for each cell.
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Table 2.
Comparison of intrinsic properties of the different GnRH
neuronal cell types in juvenile and adult female mice
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The short duration stimulation evoked single action potentials that
displayed afterspike depolarizing potentials (ADPs) of varying
amplitude and duration as well as AHPs (Fig. 3). Delayed AHPs were not
observed in any GnRH neurons. Although AHPs became more noticeable when
cells were held at depolarized potentials of 55 mV (data not shown),
the presence of ADPs and AHPs were found only in subpopulations of all
four cell types at their resting membrane potential (Table 2). The
resting membrane potential, input resistance, membrane time constant,
and action potential threshold and characteristics were not different
among any of the cell types (Table 2). Of the 17 GnRH neurons recorded
from estrous mice, 65, 23, 12, and 0% were judged to be of types I, II, III, and IV, respectively, compared with the 37, 44, 11, and 8%
categorization of GnRH neurons from diestrous mice (n = 27).
Electrophysiological characteristics of juvenile female mice
Recordings from the 31 juvenile GnRH neurons revealed that the
majority (n = 19; 61%) exhibited firing properties
similar to those of type I GnRH neurons in adult animals with a
linear-type voltage response to hyperpolarizing current and rebound
depolarization combined with sustained trains of fast action potentials
to depolarizing current (Fig.
4A). A small population
of neurons (n = 2; 6%) displayed type II-like
characteristics (data not shown). In terms of their intrinsic membrane
properties, these juvenile GnRH neurons were not found to be different
from the equivalent adult GnRH cell types (Table 2). Surprisingly,
however, the rest of the juvenile GnRH neurons (n = 10;
32%) failed to fire action potentials, regardless of the amplitude of
depolarizing current pulses (up to 0.5 nA), and were thus termed silent
cells (Fig. 4B). These silent cell types displayed a
range of rectification in response to hyperpolarizing current pulses as
seen in types I-III (e.g., type II in Fig. 4B). Indeed, their intrinsic properties differed from firing cells only in
their mean input resistance, which was very much lower at 0.60 ± 0.4 G (p < 0.05) (Table 2). Current-voltage
relationship plots of these neurons revealed strong outward and inward
rectification (Fig. 4B).
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Figure 4.
Intrinsic membrane properties of GnRH neurons
recorded in juvenile female mice. A, Type I neuron in
which action potentials could be evoked with 20 and 200 msec
depolarizing and hyperpolarizing current pulses. Voltage-current
relationship plotted from the end of 200 msec duration pulses. Note the
presence of afterhyperpolarization with the 20 msec depolarizing pulse.
B, Silent-type neuron in which no action potential could
be evoked with either 20 or 200 msec depolarizing and hyperpolarizing
current pulses. Voltage-current relationship plotted from the end of
200 msec pulse. The resting membrane potential was 67 mV in cell
A and 72 mV in cell B.
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Although the percentage of juvenile GnRH neurons (33%) that displayed
ADPs was similar to that of adults (36%), many more juvenile GnRH
neurons (38%) were found to exhibit AHPs (Fig. 4A) compared with adult GnRH cells (7%) (Table 2).
Effects of ion channel blockers on the excitability of
GnRH neurons
TTX
Adult GnRH neurons were found to fire
Na+-dependent action potentials,
because 0.5 µM TTX abolished evoked action
potentials in all cells tested (n = 40) (Fig.
5A). In response to
incremental increases in depolarizing current pulses in the presence of
TTX, a strong outward rectification was observed with the concomitant unmasking of a hyperpolarization "notch" at the beginning of the voltage trace (Fig. 5A). This likely represents the presence
of the A-type potassium conductance
(IA) (Rudy, 1988). The corresponding current-voltage relationship measured at the end of the 200 msec current pulses showed that TTX had no effect on conductances evoked in
the hyperpolarizing direction but had a marked rectification in the
depolarizing direction, as revealed by the flat region positive to 50
mV (Fig. 5A). The rebound depolarization spikes after large
hyperpolarizing current pulses were also abolished, or occasionally
attenuated, by TTX (Fig. 5A).
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Figure 5.
The effect of tetrodotoxin
(TTX) on cell type I in adult and juvenile GnRH
neurons. Families of voltage were evoked in adult GnRH
(Aa) and in juvenile GnRH neurons (Ba)
with 200 msec current pulses in control and in the presence of TTX. The
corresponding voltage-current relationship obtained from the adult
GnRH neuron (Ab) shows marked rectification with
depolarizing pulses. Note the presence of an "A" notch
(arrow) in the presence of TTX. Bb,
Expanded traces in response to 0.06 nA depolarizing current pulse,
showing that in the presence of TTX, calcium spikes are revealed. The
insets illustrate the differences in the shape and
duration of sodium (no TTX) and calcium (in TTX) spikes. The resting
membrane potential is 74 mV in cell A and 74 mV in
cell B.
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The application of TTX to juvenile GnRH neurons also abolished fast
action potentials and revealed the presence of a strong outward
rectification (Fig. 5B). Interestingly, this
hyperpolarization notch could often be seen in juvenile GnRH neurons
even without TTX (n = 15) (Fig. 5B). In many
juvenile GnRH neurons (47%), the application of TTX also revealed the
presence of repetitive Ca2+ spikes (Fig.
5Ba), which subsequently resulted in an increase in the
amplitude of the AHP conductance (Fig. 5Bb). Similar
TTX-independent spikes were only observed in 15% of adult GnRH neurons
(data not shown).
Tetraethylammonium
In several experiments, the effects of outward current blockers on
GnRH neurons were examined (Fig. 6). In
both juvenile (n = 2) and adult (n = 3)
GnRH neurons, 1 mM TEA was found to prolong the
duration of the action potential and decrease cell excitability (Fig.
6A). No effect of TEA was observed on the resting
membrane potential or on the amplitude of responses evoked with
negative current pulses. However, in two silent-type GnRH neurons, TEA depolarized the membrane potential by 2 mV and also increased the
amplitude of electrotonic potentials evoked with depolarizing current
pulses. However, TEA had no effect in the hyperpolarizing direction on
these cells (data not shown). Although TEA blocks a wide range of
potassium conductances, the delaying of the repolarization phase in
association with a decrease in cell excitability observed here would be
most compatible with the blocking of a delayed rectifier (IK) or large current (BK)
calcium-activated potassium channel (Rudy, 1988).
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Figure 6.
The effect of tetraethylammonium
(TEA) and 4-aminopyridine (4-AP) on the
spike discharge of adult GnRH neurons. A, Families of
voltage were evoked in cell type I, with 200 msec hyperpolarizing and
depolarizing current pulses in the presence and absence of 1 mM TEA. TEA decreased cell excitability in GnRH neurons,
and as shown by the inset, it produced this effect by
broadening the action potential. B, Responses to 200 msec depolarizing and hyperpolarizing current pulses in cell type IV in
the presence of 100 µM 4-AP. 4-AP produced an increase in
cell excitability by altering the repolarization phase of the action
potential as shown in the inset. The resting membrane
potential is 70 mV in cell A and 74 mV in cell
B.
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4-Aminopyridine
The application of 100 µM 4-AP was found to increase
adult GnRH neuron excitability (n = 2) (Fig.
6B). This increase in excitability resulted from a
decrease in spike latency and was observed as an increase in the
frequency of spontaneous synaptic activities as well as evoked firing
rates (Fig. 6B). This effect would be compatible with
the blocking of an IA conductance
(Rudy, 1988). The addition of 4-AP (100 µM) to
two silent-type GnRH neurons was found to increase the amplitude of the
electrotonic potentials evoked with depolarizing current pulses.
Barium
In four adult GnRH neurons, Ba2+
applied at 100 µM was found to increase cell excitability
but either had no effect on membrane potential (n = 3)
or evoked a small 7 mV increase (n = 1). The block
produced by Ba2+ on the amplitude of
electrotonic potentials evoked with hyperpolarizing currents was
uniform but also observed in the depolarizing direction, blocking
outward rectifiers (data not shown). Of all the potassium channel
blockers examined, Ba2+ produced the most
dramatic effects on the silent-type GnRH neurons found in juvenile
animals; addition of BaCl2 (100 µM) produced membrane depolarization (ranging
from 21-44 mV; n = 3) concomitant with increases in
resistance in both depolarizing and hyperpolarizing directions (Fig.
7). The effects of
Ba2+ were readily reversed on washout
(Fig. 7).
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Figure 7.
The effect of barium on GnRH neurons. Responses to
200 msec depolarizing and hyperpolarizing current pulses evoked in a
silent-type juvenile GnRH neuron in control, on addition of 100 µM barium and after washout. The corresponding
voltage-current relationships at the beginning (30 msec,  ) and end
(190 msec,  ) are plotted, revealing the presence of rectification
with depolarizing and hyperpolarizing pulses. Note the blockade of both
inward and outward rectification in Ba2+, which was
readily reversible. Resting membrane potential was 65 mV but brought
to 70 mV with DC.
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Cesium
Addition of the potassium channel blocker CsCl at 100 µM had little to no effect on the
I-V relationship in type I neurons (n = 2; data not shown). However, cesium
(Cs+) produced a variable increase in the
amplitude of the electrotonic potentials evoked with hyperpolarizing
current pulses in types II, III, and IV GnRH neurons (n = 5) (Fig. 8). Indeed, it is well documented that the different inward rectifiers differ in their sensitivity to Cs+, and in the case of
type III GnRH neurons (Fig. 8A), where it had the
most pronounced effect, it was both voltage and concentration dependent. The effect produced at 100 µM
concentration was effective only on more negative jumps but became more
uniform at 300 µM concentration (Fig. 7).
Cs+ had little effect on the excitability
of GnRH neurons and was reversible on washout.
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Figure 8.
The effect of cesium on type III
(A) and type IV (B) GnRH
neurons. Families of voltage are evoked with 200 msec depolarizing and
hyperpolarizing current pulses in control and in the presence of 100 or
300 µM Cs+. Note the blockade of
anomolous rectification (A) and
IQ/H (B) by
Cs+, without any effect on cell excitability.
Voltage-current relationship plotted from the end of the 200 msec
pulse in control () and in the presence of cesium (). Resting
membrane potential was 72 mV in A and 75 mV in
B.
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DISCUSSION |
Most GnRH neurons in mammalian species exhibit a bipolar-type
morphology with a distinct vertical orientation (Silverman et al.,
1994). As before (Skynner et al., 1999b), we show that many of the
neurons displaying these characteristics contain GnRH transcripts and
therefore are GnRH neurons. The specificity of this procedure is
further indicated by the absence of GnRH amplicons in both mock
harvests and cells located outside the GnRH distribution. It is
important to recognize, however, that GnRH neurons which do not display
a clear bipolar morphology will not be sampled in our procedure. Thus,
although our results should be representative of the majority of GnRH
neurons, they may not necessarily reflect the entire population.
Notwithstanding these caveats, the present procedure has provided the
means for the first detailed electrophysiological analysis of native
mammalian GnRH neurons while avoiding any potential confounding effects
that may arise from the investigation of transgenically modified,
fluorescent GnRH neurons.
Heterogeneity within the adult GnRH neuronal population
Immunocytochemical and in situ hybridization studies
have reported heterogeneity in GnRH neuron morphology (Wray and
Hoffman, 1986) as well as their expression of specific receptors,
immediate early genes, and neuropeptides, including GnRH itself (Hiatt
et al., 1992; Merchenthaler et al., 1993; Porkka-Heiskanen et al., 1994; Wang et al., 1995; Gore et al., 1996; Simonian et al., 2000). We
now provide direct evidence for functional heterogeneity in the basic
membrane properties of these neurons. Most strikingly, the types III
and IV GnRH neurons were found to display strong inward rectification
to hyperpolarizing current pulses that were indicative of the presence
of IIR and
IQ/H, respectively. Experiments with
Cs+ provided further support for
IIR-type potassium channels in type III GnRH neurons, as well as their less prominent existence in types II
and IV cells. In contrast, type I GnRH neurons did not exhibit any
inward rectification. Further distinguishing characteristics of the
different cell types were the inability of type III GnRH neurons to
fire repetitively in response to a depolarizing current and the absence
of rebound depolarization in type II cells. This latter phenomenon
suggests the likelihood of lower levels of functional T-type
Ca2+ channels (Huguenard, 1996) in type II
GnRH neurons compared with the others.
We were also able to demonstrate the presence of the
IA potassium conductance in GnRH
neurons, although no particular relationship with the different cell
types was found. In a similar manner, the ADP and AHP conductances were
also found to exist in all four of the GnRH cell types but,
interestingly, only in subpopulations of each. Calcium entry through
N-type Ca2+ channels has been proposed to
underlie the AHP, whereas entry through P/Q- and T-type
Ca2+ channels is thought to be responsible
for generation of ADP (Kobayashi et al., 1993; Sim and Allen,
1998). Together, these observations in native GnRH neurons
indicate the existence of multiple layers of functional heterogeneity
within the GnRH phenotype. At one level, there appears to be diversity
in the levels of expression of different
Ca2+ channels, although at another, this
involves differential expression of channels underlying the
IIR and
IQ/H conductances.
Previous electrophysiological studies have demonstrated the presence of
IK,
IA, and
IIR, as well as low- and
high-threshold-activated calcium conductances, in immortalized GT1
cells (Bosma, 1993; Hales et al., 1994; Van Goor et al., 1999a,b) and
cultured embryonic GnRH neurons of the mouse (Kusano et al., 1995).
Although detailed information on the basic membrane properties of green
fluorescent protein (GFP)-expressing GnRH neurons is not yet available,
it is interesting to note that outward potassium currents indicative of
IA and
IK conductances were reported by
Spergel and colleagues (1999). However, our observation of fast AHPs in
only a minority of GnRH neurons is at odds with its presence in all
GFP-GnRH cells (Spergel et al., 1999). The reasons underlying this
difference are not clear, but it is worth noting that the GFP-GnRH
neurons had much lower resting membrane potentials (55 ± 4 mV),
and this would likely enable greater calcium entry on depolarization
and facilitate the AHP conductance. Also, the GFP-GnRH neurons analyzed were obtained from a range of 1- to 24-week-old male and female mice.
It is important to note, however, that GnRH neurons in the ovariectomized guinea pig (Lagrange et al., 1995) also express IA- and
IIR-type potassium currents and,
interestingly, appear similar to the GnRH type IV neuron reported here.
The functional significance of different levels of multiple potassium
and calcium ion channels in native GnRH neurons is not yet clear.
However, the IA,
IK, and AHP conductances have all been
shown to play important roles in determining the repetitive firing
patterns of neurons and are selectively modulated by neurotransmitter input (Rudy, 1988; Schwindt et al., 1988; Storm, 1990; Schoppa and
Westbrook, 1999). The expression of these channels may well be critical
in determining the specific patterned activities that control
neurosecretory output from GnRH neurons. It is also of interest to note
that a pacemaker role has been attributed to IH (Kelly and Ronnekleiv, 1994; Pape,
1996), and its presence in a small population of GnRH neurons may be
significant in the generation of synchronized release of GnRH.
Furthermore, the presence of rebound depolarization in cell types I,
II, and IV would result in any coordinated inhibitory input generating
synchronized firing (Huguenard, 1996; Bean and McDonough, 1998) in the
GnRH neurons of this type.
Postnatal changes in GnRH neurons across puberty
Because the profile of GnRH secretion is believed to change
substantially after puberty (Ojeda and Urbanski, 1994), it was surprising to find relatively little difference between the basic membrane properties of juvenile and adult female GnRH neurons. Neurons
recorded from both age groups were spontaneously active and this was
shown to result almost exclusively from a substantial GABAergic barrage
signaling through the GABAA receptor. This
receptor has also been identified in mouse GFP-GnRH and guinea pig GnRH neurons (Lagrange et al., 1995; Spergel et al., 1999). Much of this
GABA release is action potential independent and likely represents the
tonic activation of extrasynaptic  5 x 2-type
GABAA receptors on GnRH neurons (Brickley et al.,
1996; Sim et al., 2000).
One striking difference, however, was the presence of silent-type GnRH
neurons in only the juvenile mice. Experiments revealed the presence of
both inward and outward rectifiers in these cells but a complete
inability to fire action potentials. Although glial cells express a
range of potassium channels (Bordey and Sontheimer, 2000), we believe
that these recordings are not from glial cells because they did not
contain GFAP transcripts and, further, were encountered only in
juvenile mice. Intriguingly, preliminary work indicates that the
Gn11-immortalized GnRH neurons, obtained from the nasal placode, are
similarly unable to fire action potentials (Maggi et al., 2000).
However, the precise nature of these interesting GnRH-expressing cells
remains unknown. One intriguing speculation, however, is that they may
represent the forebears of the adult type III and type IV GnRH neurons,
which could be of particular importance to synchronized GnRH activity.
Our data also suggest the possibility that
Ca2+ conductances may play a more
prominent role in the cellular excitability of GnRH neurons in
juveniles compared with adults. The TTX-independent Ca2+ spikes (43%) and AHP conductances
(38%) were observed more frequently in juvenile GnRH neurons compared
with adult GnRH cells (11 and 7%, respectively). These slow spikes
arise from the activation of T-type Ca2+
channels (Bean and McDonough, 1998) and have also been identified in
the embryonically immortalized GT1 cells (Van Goor et al., 1999b).
Intriguingly, embryonic GnRH neurons also exhibit clear periodic
oscillations in their intracellular calcium concentrations (Terasawa et
al., 1999). Together, our present data suggest that either the
expression of T- and N-type Ca2+ channels
becomes progressively lower with postnatal development or other
alterations in GnRH neurons make their functional presence less obvious.
Conclusions
We provide here the first detailed account of the basic membrane
properties of postnatal GnRH neurons in the mouse and show that, like
other neurons, they express various conductances that underlie membrane
excitability. Unexpectedly, however, we have observed a marked degree
of heterogeneity in the expression of functional potassium and calcium
channels that play a role in determining the firing characteristics of
GnRH neurons. Developmentally, the major differences between juvenile
and adult GnRH neurons were those of reduced GnRH cell type
heterogeneity and a more apparent role for specific calcium channels in
juvenile GnRH neurons. Other neuroendocrine phenotypes such as the
oxytocin and vasopressin neurons do not exhibit substantial
heterogeneity in their membrane properties (Stern and Armstrong, 1995),
whereas the tuberoinfundibular dopaminergic neurons exhibit only small
degrees of variability (Loose et al., 1990). The apparent heterogeneity
in levels of channel expression within the GnRH neuronal populations
may well result from their scattered distribution and likely individual microenvironments. Precisely what impact this heterogeneity has on
function is not yet clear, but the present results provide critical
direct evidence for the hypothesis that the GnRH neurons develop into a
functionally heterogeneous population likely involved in multiple
neuronal networks.
| |
FOOTNOTES |
Received Sept. 11, 2000; revised Nov. 7, 2000; accepted Nov. 21, 2000.
This work was supported by the UK Biotechnology and Biological Sciences
Research Council. We thank Sandra Dye for assistance with the mice.
Correspondence should be addressed to Allan E. Herbison, Laboratory of
Neuroendocrinology, The Babraham Institute, Cambridge CB2 4AT, UK.
E-mail: allan.herbison{at}bbsrc.ac.uk.
| |
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S. M. Leupen, S. A. Tobet, W. F. Crowley Jr., and K. Kaila
Heterogeneous Expression of the Potassium-Chloride Cotransporter KCC2 in Gonadotropin-Releasing Hormone Neurons of the Adult Mouse
Endocrinology,
July 1, 2003;
144(7):
3031 - 3036.
[Abstract]
[Full Text]
[PDF]
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R. A. DeFazio, S. Heger, S. R. Ojeda, and S. M. Moenter
Activation of A-Type {gamma}-Aminobutyric Acid Receptors Excites Gonadotropin-Releasing Hormone Neurons
Mol. Endocrinol.,
December 1, 2002;
16(12):
2872 - 2891.
[Abstract]
[Full Text]
[PDF]
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R. A. DeFazio and S. M. Moenter
Estradiol Feedback Alters Potassium Currents and Firing Properties of Gonadotropin-Releasing Hormone Neurons
Mol. Endocrinol.,
October 1, 2002;
16(10):
2255 - 2265.
[Abstract]
[Full Text]
[PDF]
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C. S. Nunemaker, R. A. DeFazio, and S. M. Moenter
Estradiol-Sensitive Afferents Modulate Long-Term Episodic Firing Patterns of GnRH Neurons
Endocrinology,
June 1, 2002;
143(6):
2284 - 2292.
[Abstract]
[Full Text]
[PDF]
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S.-K. Han, I. M. Abraham, and A. E. Herbison
Effect of GABA on GnRH Neurons Switches from Depolarization to Hyperpolarization at Puberty in the Female Mouse
Endocrinology,
April 1, 2002;
143(4):
1459 - 1466.
[Abstract]
[Full Text]
[PDF]
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M. C. Kuehl-Kovarik, W. A. Pouliot, G. L. Halterman, R. J. Handa, F. E. Dudek, and K. M. Partin
Episodic Bursting Activity and Response to Excitatory Amino Acids in Acutely Dissociated Gonadotropin-Releasing Hormone Neurons Genetically Targeted with Green Fluorescent Protein
J. Neurosci.,
March 15, 2002;
22(6):
2313 - 2322.
[Abstract]
[Full Text]
[PDF]
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J. A. Sim, M. J. Skynner, and A. E. Herbison
Direct Regulation of Postnatal GnRH Neurons by the Progesterone Derivative Allopregnanolone in the Mouse
Endocrinology,
October 1, 2001;
142(10):
4448 - 4453.
[Abstract]
[Full Text]
[PDF]
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TOP
ABSTRACT
INTRODUCTION
