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The Journal of Neuroscience, May 1, 1999, 19(9):3486-3494
Voltage-Activated Calcium Currents in Rat Retinal Ganglion Cells
In Situ: Changes during Prenatal and Postnatal
Development
Susanne
Schmid and
Elke
Guenther
Department of Pathophysiology of Vision and Neuro-Ophthalmology,
Division of Experimental Ophthalmology, University Eye Hospital,
Röntgenweg 11, 72076 Tübingen, Germany
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ABSTRACT |
Voltage-activated calcium currents
(ICa) are one way by which calcium
influx into neurons is mediated. To investigate changes in kinetic
properties of ICa during neuronal
development and to correlate possible kinetic changes with specific
differentiation processes, the ICa of
retinal ganglion cells (RGCs) was recorded with the perforated
patch-clamp technique in rat retinal slices and in whole mounts at
different prenatal and postnatal stages.
ICa density increased between embryonic day
(E) 20 and the adult stage, paralleled by a shift in activation of the
-conotoxin GVIA-sensitive ICa toward more
negative membrane potentials. Furthermore, developmental alterations
were observed in ICa inactivation rate during a 120 msec test pulse and in steady-state inactivation of
ICa. The most striking feature in
ICa kinetics was a transient slowing of
calcium current deactivation, which peaked at postnatal day (P)3-5 and
affected all ICa subtypes.
Although the shift in activation and the decreased inactivation rate of
ICa can be explained by differential
regulation of distinct calcium channel subtypes, it is more likely that
a more general alteration of the cells' functional state was the
underlying factor in alterations in steady-state inactivation and
current deactivation of ICa.
Alterations in the -conotoxin GVIA-sensitive and the toxin-resistant
currents temporarily coincide with dendritic differentiation, and it is
tempting to speculate about their role in network formation in the
inner retina. In contrast, alterations in steady-state inactivation and
current deactivation may be involved in the regulation of RGC survival,
because they occur during the period of programmed cell death in the
ganglion cell layer.
In conclusion, distinct time windows of alterations in calcium channel
properties were found, and this study has provided a basis for
performing functional assays to clarify in detail the developmental
process to which these alterations are related.
Key words:
retina; retinal ganglion cell; development; perforated
patch clamp; voltage-activated calcium channels; kinetic properties; rat
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INTRODUCTION |
Calcium ions have a key regulatory
function for many neuronal pathways of the CNS. Intracellular calcium
has been shown to play a crucial role in regulating proliferation, cell
migration, and neurite outgrowth (for review, see Doherty and Walsh,
1994
; Gu et al., 1994; Kocsis et al., 1994; Rakic and Komuro, 1994; Rakic et al., 1994; Takuwa et al., 1995), as well as in
processes of neuronal plasticity (Mattson and Barger, 1993) and natural cell death (for review, see Orrenius and Nicotera, 1994; Wolszon et
al., 1994).
Neurons possess complex systems for regulating intracellular calcium
levels, including voltage-activated calcium channels in the plasma
membrane. It has been shown that activation of intracellular processes
that affect distinct developmental events depends on the type of
channel through which calcium enters the cell (Collins et al., 1991;
Komuro and Rakic, 1992). Knowing which types of calcium channels are
expressed during the development of a distinct neuron and what their
functional characteristics are is therefore important for an
understanding of the role of calcium currents in differentiation
processes in neural tissues in vivo and the correlation
between functional development and neuroanatomical differentiation.
The mammalian retinal ganglion cell (RGC) provides a particularly
attractive model for such investigations, because the morphological development and connectivity of this cell type have been well described
(Potts et al., 1982; Bunt et al., 1983; Perry et al., 1983; O'Leary et
al., 1986). To date, not much is known about alterations in calcium
current expression and kinetics during the development and maturation
of RGCs. However, it seems appropriate to link alterations in calcium
channel properties with distinct events in RGC development, because,
for example, neurite outgrowth and RGC survival depend for a restricted
developmental period on neurotrophic factors (Castillo et al., 1994;
Cohen et al., 1994; Cui and Harvey, 1994; Meyer-Franke et al., 1995).
These factors have been shown in various tissues to act by the
modulation of kinetic properties of voltage-activated calcium channels
(Eschweiler and Bähr, 1993; Levine et al., 1995a; Tanaka and
Koike, 1995).
Most previous studies on voltage-activated calcium channels in RGCs
were performed mainly in cell cultures and restricted to only one
distinct developmental stage (Lipton and Tauck, 1987; Karschin and
Lipton, 1989; Ishida, 1991; Kaneda and Kaneko, 1991; Guenther et al.,
1994a; Liu and Lasater, 1994; Bindokas and Ishida, 1996). Rörig
and Grantyn (1994) were the first to describe voltage-activated current
expression in mouse RGCs in two different embryonic stages in retinal
whole mounts, and Rothe and Grantyn (1994) investigated changes in the
relative abundance of different types of calcium currents in mouse RGCs
during the first 3 weeks of in vitro development.
In a previous study, we investigated in situ alterations in
calcium current composition and the pharmacological properties of
different types of calcium currents during prenatal and postnatal development in rat RGCs (Schmid and Guenther, 1996).
The present study now describes for the first time developmental
alterations in the kinetic properties of calcium currents during the
whole period of RGC development in situ. It thus provides the basis for more sophisticated functional assays that will clarify the role of these alterations in developmental processes that are
temporarily interrelated, such as RGC death, dendritic differentiation, and synapse formation.
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MATERIALS AND METHODS |
Preparation of slices and whole mounts. Postnatal
retinal slices were obtained from pigmented rats (Brown Norway) between embryonic day (E) 15 and the adult stage [
postnatal day (P) 20].
After cervical dislocation and enucleation, the retinas were gently
removed from the eye cups and kept in extracellular solution (ec1) on
ice that was continuously bubbled with oxygen. For slice preparation,
retinas were embedded in agar (2% in ec1) held at 39°C and
immediately cooled on ice. A small agar block containing the retina was
trimmed and glued to the stage of a vibratome (TSE). The stage was
immersed in ice-cold ec1, and slices of 200 µm were cut transversely.
Before being used for recording, the slices were incubated in ec1 and
continuously bubbled with oxygen for at least 1 hr at room temperature.
For preparation of embryonic retinal whole mounts, staged pregnant rats
were anesthetized with ether and injected with an overdose of Nembutal.
Embryos were quickly removed from the uterus and transferred into
ice-cold ec1. After decapitation, the eyes were removed and reimmersed
in ice-cold ec1. The retinas were dissected free and incubated in
oxygenated ec1 at room temperature for at least 1 hr before recording.
Embryonic retinas were not sliced, because retinal diameter was only
1-2 mm. Slicing of postnatal retinas was necessary because the layer
of Müller glia endfeet and ganglion cell axons overlying the
ganglion cell somata was too thick and sticky to be perforated by the
patch-electrode in retinas from stages older than P6. To provide
comparable conditions, all postnatal retinas were sliced.
Electrophysiological recording procedure. For
electrophysiological recordings, slices or whole mounts were
transferred into a poly-L-lysine-coated recording chamber
on a microscope stage (Zeiss Axioskop) and fixed with a small grid made
of fine nylon strings tightened between a U-shaped platinum wire. The
recording chamber was superfused with 1.5-2 ml of oxygenated ec1 per minute.
Patch pipettes were pulled out of borosilicate capillaries (Biologica).
Pipette resistance was 3-6 M
after heat-polishing. Pipettes were
first front-filled for 10 sec with intracellular solution (ic) and
thereafter backfilled with the same solution plus nystatin.
After sealing, light suction was applied, and the light of the
microscope was switched off. Some minutes later, series resistance started to decrease. After reaching 15-25 M, series resistance was
usually stable and did not decrease further. Cell capacity and series
resistance were then compensated, and recordings were started.
Recordings were made with an Axopatch 200 A amplifier at a sampling
rate of 10 kHz using a low-pass Bessel filter of 2 kHz. Series
resistance compensation was usually 60-80%. The liquid junction
potential was ~3 mV, and data were not corrected for it. The adequacy
of space clamping was assessed by fitting a single exponent to the
capacity charging current. Cells showing inadequate clamping were not
included in the analysis. Cells were normally kept at a holding
potential of 
80 mV, and increasingly depolarized test potentials
between 70 and 20 mV (in 10 mV steps) were applied for 120 msec at 10 sec intervals.
Data were displayed and stored for subsequent off-line analysis on an
IBM PC. The commercial software program PCLAMP 6.0.2 was used for data
acquisition and analysis, and Sigma-Plot was used for curve fitting and plotting.
Identification of retinal ganglion cells. Cells were chosen
for recording according to their position in the ganglion cell layer
and their soma size (Guenther et al., 1994b). Only large diameter
ganglion cells were selected. Because 
- or type I RGCs have been
shown to have much larger cell somata than displaced amacrine cells and
other types of RGCs (Perry, 1979; Thanos and Mey, 1995), we assume that
we mainly recorded from this ganglion cell type. Other morphological
criteria were inapplicable, because dendritic arborization, on which
ganglion cell identification in adults is normally based, is immature
in embryonic and postnatal stages <P10. Retrograde labeling of RGCs by
injection of 2 µl of the fluorescent dye DiI (25 mg/500 µl DMF;
Molecular Probes, Eugene, OR) into the superior colliculus of neonatal
Brown Norway rats was occasionally performed and yielded a 100%
correspondence with the identification made by soma size. Moreover, all
cells that fulfilled the size criteria showed substantially higher
transient sodium inward currents than cells identified as displaced
amacrine cells (except E15 cells, which do not express
voltage-activated currents). This is a further indication that they
were indeed RGCs.
Data analyses. Time constants (
) were determined by
fitting the single exponential function
An*exp[(t K)/n] + C to the data,
where A is the amplitude relative to offset evaluated at the
start of the fit region (n), C is the
steady-state asymptote, and (t K)
is the time [set to zero at the beginning (K) of the fit region]. Fitting procedures were performed with PCLAMP routines using the noniterative Chebyshev technique and minimizing the sum-of-squared errors.
Time to peak (tp) was determined by measuring the time from
the beginning of the depolarization until peak current was reached.
Grouping of postnatal developmental stages. Postnatal stages
were grouped as follows: a neonatal stage P1-2, when the number of
RGCs is still maximum; an early postnatal stage P3-5, when most of the
RGCs die by programmed cell death (Potts et al., 1982; Schmid and
Guenther, 1996); stage P6-9, when programmed cell death of RGCs is
greatly diminished, and the displaced amacrine cells have migrated to
the ganglion cell layer (Perry et al., 1983); and P10-12, when cell
death is completed, and the size and complexity of dendritic trees are
greatest before being extensively remodeled (O'Leary et al., 1986;
Yamasaki and Ramoa, 1993). Rats that had opened their eyes (P20-27)
were considered adult, because RGCs were now receiving functional
input. For still unknown reasons, no stable recording conditions could
be established between P13 and P19, and data from these stages were not
included in the present study. Because experimental conditions were
unchanged, we believe that this problem was not caused by the recording
procedure but rather by the cellular membrane during the period of
dendritic remodeling and eye opening around P16/17.
Solutions and drugs. Ec1 was used for preparation and
maintenance of slices and whole mounts. It consisted of (in
mM): NaCl 130, KCl 5, CaCl2 2, MgCl2 1, HEPES 10, and glucose 20, pH 7.4 adjusted with 1 M NaOH. For the isolation of calcium currents, ec1 was
replaced with ec2, containing (in mM): choline chloride 110, KCl 5, BaCl2 2, MgCl2 1, HEPES 10, TEA-Cl
20, 4-AP 0.1, and glucose 20, pH 7.4, adjusted with 1 M
CsOH. Both solutions were held at room temperature and continuously
bubbled with oxygen during the whole experiment. A short puff of
tetrodotoxin (5 µm; Sigma, St. Louis, MO) was additionally applied by
a superfusion pipette after solution exchange to accelerate sodium
channel blocking.
The pipette solution (ic) contained (in mM): Cs acetate 90, CsCl2 40, MgCl2 2, EGTA 10, and HEPES 10, pH
7.2, adjusted with 1 M CsOH. Nystatin stock solution (1 mg/10 µl DMSO) was added to the ic to an end concentration of 50 µM. The solution was sonicated for 15 min before being
used. When stored on ice and strictly protected from light, the
nystatin containing ic had to be renewed every 2-3 hr.
The separation of different calcium current types in rat RGCs was based
on pharmacological properties (Guenther et al., 1994a; Rothe and
Grantyn, 1994; Schmid and Guenther, 1996). Drugs were applied by the
six-barrel superfusion pipette in the following order: -conotoxin
GVIA (5 µM; Alomone Labs), which irreversibly block the
N-type calcium channel, then nitrendipine (50 µM; Bayer AG, Wuppertal, Germany) [or alternatively nifedipine (50 µM; Sigma) plus diltiazem (50 µM; Sigma),
which together had the same blocking efficiency as nitrendipine] to
block the remaining L-type calcium channel, and finally cadmium (1 mM; Sigma), as an unspecific calcium channel blocker to
block the remaining toxin-resistant current. Additionally,
-conotoxin MVIIC (2 µm; Sigma) and -agatoxin IVA (100 nM) were applied in some experiments after dihydropyridine (DHP) application to test the sensitivity of the toxin-resistant calcium current for these drugs. All drugs were diluted in oxygenated ec2.
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RESULTS |
Expression of voltage-activated calcium currents
As reported before (Schmid and Guenther, 1996), voltage-activated
calcium currents were expressed in RGCs from E17 on and were
exclusively of a low-voltage-activating (LVA) type at this developmental stage (Fig.
1A). The number of RGCs
expressing LVA currents decreased in subsequent stages, and no LVA
current was detected in adult RGCs. LVA currents were not analyzed
further in the present study. High-voltage-activating (HVA) calcium
currents were expressed from E20 on (Fig. 1A). The
peak amplitude and current density of total calcium currents increased
from 26 pA (±5, n = 6) and 16 pA/pF (±3,
n = 6) at E17 to 326 pA (±28, n = 50) and 115 pA/pF (±9, n = 50) in the adult stage,
respectively (Schmid and Guenther, 1996). The HVA current consisted of
three pharmacologically distinct types: a -conotoxin GVIA-sensitive
current, a DHP-sensitive current, and a toxin-resistant current type,
which could not be blocked with any specific calcium channel blocker
(Fig. 1B). The ratio of these current types did not
significantly change during development except for a small decrease in
-conotoxin GVIA-sensitive current between P11 and the adult stage;
this was significant with p < 0.01 (Kruskal-Wallis
test) (Fig. 1C).
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Figure 1.
A, Calcium current
(ICa) traces from three different
developmental stages, elicited by depolarization from the holding
potential of 80 mV to different membrane potentials between 70 and
+20 mV for 120 mV. The ICa in RGCs of E17 is
exclusively of the LVA type and is completely inactivated within 120 msec. The first HVA currents are expressed at E20.
ICa is almost completely sustained in adult
RGCs. Calibration bars, 50 pA. B, Total
ICa of an adult RGC elicited by
depolarization from 80 to 10 mV for 120 msec. The application of
the specific N-type channel blocker -conotoxin GVIA and the L-type
channel blocker nifedipine (a dihydropyridine) plus diltiazem reduced
total ICa, whereas application of the
Q-type channel blocker -agatoxin IVA and -conotoxin MVIIC had no
further effect on ICa. The toxin-resistant
calcium current was blocked by the unspecific calcium channel blocker
cadmium. Calibration bar, 100 pA. C, Ratio of the
-conotoxin GVIA-sensitive, the dihydropyridine-sensitive, and the
toxin-resistant calcium current subtype at different developmental
stages. Values were determined by the percentage of peak calcium
current at 10 mV that could be blocked by either -conotoxin GVIA
or subsequent application of dihydropyridines or was toxin resistant.
Only the decrease of the -conotoxin GVIA-sensitive current at the
adult stage marked by an asterisk is significant
(Kruskal-Wallis test, p < 0.01). For
n see Table 1. The number of different animals always
exceeds n/2. Vertical bars indicate SE.
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Developmental changes in current-voltage relations
To elicit HVA calcium currents, RGCs were successively depolarized
for 120 msec to different membrane potentials between 70 and 20 mV in
steps of 10 mV, starting from a holding potential of 80 mV. Figure
2 shows the current-voltage relation
(I-V plot) of the calcium currents at different
developmental stages. Calcium currents were elicited at E20 by
depolarization positive to 50 mV, and the maximum calcium inward
current was reached in all embryonic RGCs at a membrane potential of 0 mV (Fig. 2, 
). Depolarization to more positive membrane potentials
resulted in a decrease of the calcium current amplitudes, and calcium
currents finally reversed around +40 mV.
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Figure 2.
Current-voltage relation (I-V
plot) of peak ICa from four different
stages. The amplitude of peak ICa increased,
and the voltage of maximum ICa shifted from
0 to 10 mV during development. The holding potential was always 80
mV, n = 13 at E20, n = 12 at
P3-P5, n = 10 at P10-P12, and
n = 28 at the adult stage. Vertical bars indicate
SE.
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In subsequent stages, an increasing number of RGCs had a maximum total
calcium current at membrane potentials of 10 mV, resulting in mean
I-V plots with a maximum between 0 and 10 mV (Fig. 2, 
and 
). Adult RGCs, however, all showed a maximum inward calcium current at a membrane potential of 10 mV (Fig. 2, 
).
The specific channel blocker -conotoxin GVIA and dihydropyridine
were applied to clarify which types of calcium currents are responsible
for the developmental shift in the current-voltage relation. This is
illustrated for an RGC at the stages P3-5 (Fig. 3A) and in the adult (Fig.
3B). In embryonic and early postnatal RGCs, application of
-conotoxin GVIA resulted in a shift of maximum calcium current from
the control value of 0 to 10 mV in all cells tested. In contrast, no
shift was observed after application of -conotoxin GVIA in adult
RGCs where the control value was already 10 mV (Fig. 3B).
Further application of dihydropyridines did not shift the
I-V relation of calcium currents in any developmental stage. Moreover, application of dihydropyridines before that of -conotoxin GVIA had no effect on the I-V relation at any
developmental stage (data not shown).
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Figure 3.
I-V plots of peak
ICa before and after subsequent application
of -conotoxin GVIA and dihydropyridines from an RGC of P3-P5
(A) and the adult stage
(B). Although the application of -conotoxin
GVIA shifted the maximum ICa from 0 to 10
mV in P3-P5, there was no shifting effect in adult RGCs or after the
application of dihydropyridines. Note the different scales of the
current amplitudes.
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To confirm our suggestion that the developmental shift in maximum
current-voltage is caused by a shift in the -conotoxin GVIA-sensitive calcium current subtype, the whole-cell calcium current
after the application of -conotoxin GVIA was subtracted from the
control calcium current for each RGC. The I-V relation of
the resulting -conotoxin GVIA-sensitive subtype always revealed a
maximum at +10 mV at prenatal and neonatal stages, whereas it was at
10 mV in adult RGCs (Fig.
4A). Tail current
analysis of the -conotoxin GVIA-sensitive currents are shown in
Figure 4B. The activation curves of whole-cell tail
currents were fitted with the Boltzmann equation and revealed a shift
in half activation of 12.5 mV from 7 mV at P3-5 to 19.5 in the
adult.
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Figure 4.
A, The -conotoxin GVIA-sensitive
ICa during development. Mean
I-V plots of the -conotoxin GVIA-sensitive
ICa of RGCs at stages E20, P3-P5, and in
the adult (n = 5 for E20, n = 14 for P3-P5, and n = 18 for the adult). The
maximum of the -conotoxin GVIA-sensitive calcium current shifted
from +10 to 10 mV between E20 and the adult. Vertical bars indicate
SE. B, Tail current analysis of the -conotoxin
GVIA-sensitive ICa. The activation curves of
the tail currents at different test potentials were fitted by the
Boltzmann equation f(x) = a/(1 + exp((Va1/2 Vm)/k)). The
membrane potential of half activation Va1/2 shifted from 7 mV at
P3-P5 to 19.5 mV at the adult (n = 14 for P3-P5
and n = 18 for the adult). Vertical bars indicate
SD.
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Developmental alterations in activation kinetics of
calcium currents
The time constant of activation (ac) and
time-to-peak (tp) current values were determined (see
Materials and Methods) to analyze activation kinetics for the different
types of voltage-activated calcium currents. Both parameters were
strongly voltage dependent at all developmental stages and did not
significantly change during development at test potentials between 50
and 20 mV (Student's t test, p < 0.001).
Figure 5 shows the mean time constants of activation and time-to-peak values of 12 adult RGCs before and after
application of -conotoxin GVIA. Both parameters showed an increase
for total calcium current within a potential range between 20 and 0 mV (Fig. 5, ). This increase was caused by activation of the
-conotoxin GVIA-sensitive current because it was abolished by
blocking this calcium current subtype (Fig. 5, diamonds).
Thus the -conotoxin GVIA-sensitive current is a slowly activating
calcium current subtype compared with the other subtypes. This can be
seen in Figure 6, where typical examples
for the total calcium current and the different isolated calcium
current subtypes are shown for an adult RGC. Time constants of
activation, tp values, and inactivation rates are indicated.
The -conotoxin GVIA-sensitive current displayed markedly slower
kinetics than the two other calcium current subtypes in all RGCs
tested.
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Figure 5.
Voltage dependence of time-to-peak
(tp) and the time constant of activation
(ac). For determination of values see Material
and Methods. ac was determined by a single exponential
function because multiple exponential functions did not reveal better
fits. Values for mean tp (top) and ac
(bottom) of the total ICa
() in adult RGCs decrease at larger depolarization and show a
transient increase between membrane potentials of 20 and +10 mV. This
increase is eliminated by the application of -conotoxin GVIA
(diamonds), indicating that the -conotoxin
GVIA-sensitive current, which activates at membrane potentials positive
from 20 mV, is a slowly activating current subtype. Bars indicate SE.
n = 12, each stage. The inset in the
bottom graph illustrates the determination of ac of an
original whole-cell calcium current trace of an adult RGC at a membrane
potential of 10 mV. The fitting region is indicated by two
arrows.
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Figure 6.
Current traces of the different calcium current
subtypes at depolarizations to a membrane potential to 10 mV. Current
traces of an adult RGC before and after application of -conotoxin
GVIA and subsequent application of dihydropyridines were subtracted to
isolate the pharmacologically distinct calcium current subtypes (also
see Materials and Methods). Time-to-peak (tp), time
constant of activation (ac), and inactivation
rates are indicated. In this example, 20% of the DHP-sensitive calcium
current inactivated, whereas the -conotoxin GVIA-sensitive calcium
current did not inactivate at all. In some other RGCs, the
DHP-sensitive current did not inactivate or both current types partly
inactivated.
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Inactivation of calcium currents
Calcium current inactivation rates in the present study indicated
the percentage of maximum calcium currents that were inactivated at the
end of a 120 msec test pulse. We found a significant decrease in
calcium current inactivation rates during RGC development. The total
calcium current inactivation rate was always near 100% at E17, when
only transient LVA currents were expressed (Fig. 1A).
In subsequent stages, mean inactivation rates at a test potential of
10 mV decreased significantly from 43% (±21, n = 11) at E20/21 to 18% (±12, n = 28) in adult RGCs
(Student's t test, p < 0.001) (Table
1).
Pharmacological separation of different calcium current subtypes
revealed large variations in the inactivation rates of the same current
subtype in different RGCs of the same developmental stage, especially
for the -conotoxin GVIA-sensitive and the dihydropyridine-sensitive calcium current type. The mean inactivation rates of the total calcium
current and the three calcium current subtypes are shown in Table 1.
The lowest and highest inactivation rates are indicated in brackets.
Interestingly, there are RGCs in which either the -conotoxin
GVIA-sensitive or the DHP-sensitive current type was not inactivated at
all, in contrast to RGCs in which both current types were partly
inactivated. RGCs in which both current types showed no inactivation
were not found. The mean rate of inactivation of the -conotoxin
GVIA-sensitive or the DHP-sensitive calcium current subtypes showed no
relation to RGC age (Table 1).
In contrast, the toxin-resistant current subtype was always at least
partly inactivated, and mean inactivation rates of this current type
continuously decreased from 90% (±12, n = 9)
in neonatal animals to 20% (±12, n = 23) in
adults (Fig. 7; Table 1). We thus think
that the toxin-resistant current is a likely candidatefor mediation of
the decreased inactivation rate of total calcium current during
development. The downregulation of the -conotoxin GVIA-sensitive
current, however, may contribute a certain amount to this effect.
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Figure 7.
Original recordings of the toxin-resistant calcium
current in a P2 and an adult RGC. During a depolarizing test pulse from
80 to 10 mV for 120 msec, the toxin-resistant calcium current
inactivated almost completely at P2 (81%), whereas only 29% of the
toxin-resistant calcium current was inactivated at the adult.
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Steady-state inactivation
The steady-state inactivation of calcium currents at different
developmental stages was investigated by depolarization to 10 mV for
120 msec from holding potentials between 100 and 10 mV, which were
applied for 1.2 sec. Figure 8 shows the
mean steady-state inactivation curves for the total calcium current at
three different stages and the original calcium current traces of an
embryonic (E20) and an adult RGC. The separation of different calcium
current subtypes with specific antagonists was not possible here
because recovery of calcium currents was incomplete after a
steady-state protocol. Steady-state inactivation curves were sigmoid in
embryonic stages but showed a linear slope for holding potentials
beyond 70 mV in postnatal RGCs (Fig. 8, left). This can be
explained by the fact that the transient component of the total calcium current, which was more prominent in prenatal and neonatal stages (Fig.
8, right; Table 1), was inactivated almost completely at holding potentials between 70 and 50 mV, whereas the sustained calcium current component was inactivated only gradually between 70
and 10 mV, linear to the membrane potential.
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Figure 8.
Steady-state inactivation of
ICa at different developmental stages. A
test pulse to 0 mV was applied from holding potentials varying from
100 to 10 mV. The peak current amplitudes of each cell were
standardized to the maximum calcium current. The I-V
plot shows the mean standardized current amplitude for E20
(n = 10), P3-P5 (n = 5), and
adult (n = 5) with SE (left). A
large fraction of total ICa in E20
inactivated between 70 and 50 mV, whereas in the other stages
steady-state inactivation was nearly linear to voltage. The original
current traces (right) show that the strong inactivation
between 70 and 50 mV at E20 was caused by the inactivation of the
transient current component. There are large capacitive currents at the
beginning and end of the test pulses because they could not be
compensated at this pulse protocol.
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Deactivation of calcium currents
To estimate deactivation kinetics of the total calcium currents,
the deactivation time constant (deac) was
determined by fitting a single exponential function to the calcium tail
current at the end of the test pulse (Fig.
9A). As shown in Figure
9B (squares), deac showed no
voltage dependence in adult RGCs. The values for deac
were ~0.4 msec at all membrane potentials tested, and there was only
a small variation between different RGCs (Fig. 9C,
squares). In contrast, values for deac were
markedly higher in prenatal and early postnatal stages, especially at
P3-5 (Fig. 9A,B). Figure 9C shows the original
values of deac for all RGCs investigated from stages
P3-5 () and the adult (
). In most RGCs of P3-5,
deac was increased, resulting in mean values of ~1.5 msec for membrane potentials positive to 0 mV, but single values ranged
from 0.2 to 3.3 msec.
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Figure 9.
Time constant of deactivation of
ICa at different developmental stages.
A, Original recordings of total calcium currents at
repolarization from 10 to 80 mV for a RGC from P3
(left) and adult (right). Single
exponential curves were fitted to determine the time constants of
deactivation deac (see Material and Methods).
B, Mean values for the time constant of deactivation
(deac) of ICa at
repolarization to 80 mV from different test potentials for all
developmental stages. The mean values of deac for
embryonic ICa and especially for
ICa from P3-5 RGCs, as well as the SE, are
markedly increased. C, Original values of
deac for ICa of adult RGCs
() are all ~0.4 msec, whereas values of deac
for P3-P5 RGCs () show large variations between 0.2 and 3.3 msec.
|
|
Application of -conotoxin GVIA and further application of
dihydropyridine had no significant influence on deac.
For example, deac was 0.386 msec (±0.024;
n = 9) for the control current, 0.325 msec (±0.053;
n = 9) after application of -conotoxin GVIA, and
0.319 msec (±0.024; n = 9) after additional
application of dihydropyridine in adult RGCs at a test potential of 10 mV (not significant, paired Student's t test). This was
also true for RGCs of P3-5. Thus the transient increase of
deac in prenatal and neonatal stages, especially in
P3-5, was caused not by the slow deactivation of only one calcium
channel subtype but by the slow deactivation of all three calcium
channel subtypes.
| |
DISCUSSION |
This study aimed at determining the time windows within which
distinct alterations in calcium channel properties take place that
might be relevant for processes of RGC differentiation and retinal
wiring. The data acquired by this study thus provide a detailed
description of the expression and kinetic properties of
voltage-activated calcium channels in rat retinal ganglion cells during
the whole period of development. On the basis of the results presented
here, it will now be possible to perform more sophisticated functional
analysis at distinct points of retinal development.
HVA calcium currents were expressed in RGCs from E21 on. Rörig
and Grantyn (1994) showed an onset of HVA current expression in mouse
RGCs from E18 on. This corresponds well with our data, because
gestation in mice is 2-3 d shorter than in rats. A role of N-type
calcium channels in migration processes as proposed by Komuro and Rakic
(1992) can therefore be excluded, because rat RGCs migrate into the
ganglion cell layer between E14 and E20 (Bunt et al., 1983).
Perforated patch recordings of RGCs from prenatal to postnatal stages
revealed several alterations in kinetic properties of whole-cell
calcium currents: (1) an increase in total calcium current density; (2)
a shift in the potential of peak -conotoxin GVIA-sensitive current
from +10 to 10 mV; (3) a decrease in the inactivation rate, probably
attributable to the decrease in the toxin-resistant current
inactivation rate; (4) a decreased steady-state inactivation for
holding potentials beyond 70 mV; and (5) a transient slowing of
deactivation kinetics of all calcium current types peaking at
P3-5.
Alterations in current densities
An increase in the density of HVA calcium currents between onset
of channel expression and adulthood has already been shown for many ion
channels in different neuronal cell types and may be a common feature
of ion channels during neuronal development. In contrast, the
expression of LVA calcium channels was downregulated during RGC
differentiation in rats. This has also been shown in sensory neurons
and motoneurons of the chick (Gottmann et al., 1988, 1991; McCobb et
al., 1989), in amphibian spinal neurons (Barish, 1986), in mammalian
hippocampal neurons (Yaari et al., 1987), and in rat dorsal root
ganglion cells (Lovinger and White, 1989). A specific role of LVA
currents in early neuronal development has therefore been proposed
(Bertolino and Llinàs, 1992; Spitzer, 1994) but cannot yet be
related to distinct processes.
Alterations in kinetic properties
Along with the increase in total calcium current amplitude we
found a shift in the current-voltage relation that was caused by a
shift in the I-V relation of the whole-cell -conotoxin
GVIA-sensitive current toward more negative potentials.
Such activation shifts have been shown for sodium currents (Park and
Ahmed, 1991; Skaliora et al., 1993; Schmid and Guenther, 1998) and
recently for calcium currents in acute isolated neocortex neurons of
the rat (Lorenzon and Foehring, 1995). Because the activation of all
calcium current types shifted in the latter study toward more negative
potentials, the authors could not exclude systematic errors
attributable to an increase in series resistance during development. In
the present study, however, only the -conotoxin GVIA-sensitive
current subtype showed a shift in I-V relation. Moreover,
systematic errors were not responsible for the developmental shift in
calcium current-voltage relation during RGC development, because
series resistances were controlled and showed no developmental alterations. The restriction of this effect to only one specific calcium current subtype indicates a differential regulation of this
current type during RGC development. This may be based on molecular
alterations in one subunit or/and alterations in the subunit
composition of the ion channel (see below).
A differential regulation of channel subunits may also have been
responsible for the reduction in the inactivation rate of the
toxin-resistant current between P10 and P12 and the adult. Interestingly, Rossi et al. (1994) reported kinetic changes of calcium
currents in rat cerebellar granule cells during postnatal development
and described a similar reduction in total calcium current inactivation
rates from 50% to 10-20%. Unfortunately, different calcium current
subtypes were not pharmacologically distinguished in that study. The
authors also described a developmental reduction of steady-state
inactivation at a membrane potential of approximately 50 mV because
of the reduction of the transient current component during development.
Steady-state inactivation curves of calcium currents in cerebellar
granule cells of P11 and P24 in that study showed a striking similarity
to the steady-state inactivation curves in RGCs in our study at stages
E20/21 and P3/5 or the adult (Fig. 7). These kinetic alterations may
therefore reflect a more general feature of maturing neurons.
Because both the activation shift of macroscopic current and the
decrease of inactivation rate of ICa be related
to specific calcium channel subtypes, it would be interesting to know
whether these alterations are determined by alterations in the
molecular organization of these channel subtypes. The single-cell
RT-PCR method provides a powerful tool for that kind of analysis
(Schmid et al., 1998).
Another important finding of the present study was the transient
slowing of calcium current deactivation in the embryonic and neonatal
stages. To exclude systematic errors, other parameters such as series
resistance, I-V relation of voltage-gated currents, amplitudes, and the adequacy of space clamp were checked for all cells
and showed no significant deviations from mean values. To our
knowledge, this is the first time that transient alterations in kinetic
properties of ion channels during neuronal differentiation have been
described in situ. Most previous studies compared only two
clearly distinct developmental stages, and transient kinetic alterations were thus probably not detected previously (Park and Ahmed,
1991; Skaliora et al., 1993); however, they cannot be excluded for
other developing neurons.
Because all subtypes of voltage-activated calcium currents showed this
transient slowing of deactivation, a general mechanism that originates
somewhere in the cell metabolism may cause this alteration rather than
a differential regulation of ion channel subunits. Interestingly, the
slowing of calcium current deactivation coincides with the slowing of
voltage-activated sodium current kinetics (Schmid and Guenther, 1998),
a process that results in broader action potentials and a larger sodium
ion influx. Because sodium currents have been shown to play a crucial
role in the formation and refinement of retinotectal projections
(O'Leary et al., 1986; Wong et al., 1993; Olson and Meyer, 1994), it
is an attractive idea that differential tuning of sodium current activity determines the wiring of retinotectal projections.
The interpretation of the slowing of calcium current deactivation
during the same period of development is much more difficult. Slow
current deactivation as well as the described shift of the -conotoxin GVIA-sensitive current, the reduction in steady-state inactivation, and the inactivation rate lead to an increase in calcium
ion influx. It remains to be determined by calcium imaging experiments
whether these kinetic alterations all lead to a rise of intracellular
free calcium, which in turn could trigger various differentiation
processes, such as calcium release from intracellular calcium stores or
gene transcription by calcium-regulated transcription factors (for
review, see Gallin and Greenberg, 1995).
Time windows of calcium current alterations
The shift of the -conotoxin GVIA-sensitive current and the
reduction of the inactivation rate of the toxin-resistant current occur
at the second postnatal week, which is a period of extensive dendritic
differentiation and remodeling. Because an increase in intracellular
calcium after voltage-dependent calcium channel activation has been
shown to be crucial for neurite outgrowth in amphibian spinal cord
neurons and rat dorsal root ganglion cells (Holliday and Spitzer, 1993;
Kocsis et al., 1994), the dendritic differentiation in RGCs
might also be regulated by the activation of specific voltage-gated
calcium channels. Immunocytochemical examination of the subcellular
distribution of the -conotoxin GVIA-sensitive and the
toxin-resistant calcium channel during this specific time period could
give further insights into their possible role in dendritic
differentiation processes.
In contrast, the alterations of steady-state inactivation and
deactivation time constants of ICa cannot be
related to a specific calcium channel subtype and occur mainly in the
first postnatal week, the period of maximum programmed cell death
(Potts et al., 1982). Nearly 50% of RGCs die within the first 2 weeks
of postnatal development because of apoptotic processes that have been
shown to be triggered by elevated intracellular calcium levels [Wyllie (1980); for review, see Orrenius and Nicotera (1994)]. This again points to the importance of calcium imaging experiments during this
critical period of RGC development to analyze the relation between
kinetic alterations described here and changes in intracellular calcium concentration.
There is evidence that those RGCs that did not make proper connections
within their target tissue predominantly died because of a lack of
neurotrophins (O'Leary et al., 1986; Cui and Harvey, 1995; Ma et al.,
1998). Interestingly, Levine et al. (1995b) described an increase of
HVA calcium currents by neurotrophins, and Franklin et al. (1995) found
that activation of voltage-activated calcium channels can substitute
for trophic factors in promoting cell survival of neurons that would
otherwise undergo programmed cell death. Thus there is evidence that
voltage-activated calcium currents are involved in mediating naturally
occurring apoptotic cell death, and the modulation of their kinetic
properties by neurotrophic factors is one way in which this could
occur. Because the slowing of deactivation and the reduction of
steady-state inactivation coincidences with the period of natural cell
death, it will also be necessary to investigate the effect of different
neurotrophins on these kinetic properties of voltage-activated calcium currents.
In summary, the present study provided insight into the regulation of
voltage-activated calcium channels during RGC differentiation and gives
some ideas about their possible role in developmental processes within
the retina. Because alterations of calcium channel properties occur
almost exclusively within the first or second postnatal week, we
conjecture that they are mainly related to either cell death or
dendritic differentiation processes. When RGCs receive the first visual
input at ages around P16-18, the properties of calcium currents are
already the same as in adult RGCs, indicating that the visual input
does not provide any trigger for further developmental changes.
| |
FOOTNOTES |
Received Sept. 23, 1998; revised Feb. 1, 1999; accepted Feb. 9, 1999.
This work was funded by the "Graduiertenkolleg Neurobiologie"
Tuebingen (German Research Council).
Correspondence should be addressed to Dr. Elke Guenther, Experimental
Ophthalmology, University Eye Hospital, Roentgenweg 11, D-72076
Tuebingen, Germany.
| |
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TOP
ABSTRACT
INTRODUCTION
