1Department of Cell Biology and Anatomy and 2Department of Ophthalmology and Neuroscience Center of Excellence, Louisiana State University, Medical Center, New Orleans, Louisiana 70112
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ABSTRACT |
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Lo, Fu-Sun and
R. Ranney Mize.
Retinal input induces three firing patterns in neurons of the
superficial superior colliculus of neonatal rats. By using an in vitro isolated brain stem preparation, we recorded extracellular responses to electrical stimulation of the optic tract (OT) from 71 neurons in the superficial superior colliculus (SC) of neonatal rats
(P1-13). At postnatal day 1 (P1), all tested neurons
(n = 10) already received excitatory input from the
retina. Sixty-nine (97%) superficial SC neurons of neonatal rats
showed three response patterns to OT stimulation, which depended on
stimulus intensity. A weak stimulus evoked only one spike that was
caused by activation of
non-N-methyl-D-aspartate (NMDA) glutamate
receptors. A moderate stimulus elicited a short train (<250 ms) of
spikes, which was induced by activation of both NMDA and non-NMDA
receptors. A strong stimulus gave rise to a long train (>300 ms) of
spikes, which was associated with additional activation of L-type
high-threshold calcium channels. The long train firing pattern could
also be induced either by temporal summation of retinal inputs or by
blocking -aminobutyric acid-A receptors. Because retinal ganglion
cells show synchronous bursting activity before eye opening at P14, the
retinotectal inputs appear to be sufficient to activate L-type calcium
channels in the absence of pattern vision. Therefore activation of
L-type calcium channels is likely to be an important source for calcium
influx into SC neurons in neonatal rats.
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INTRODUCTION |
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During development, the retinotectal pathway of
mammals undergoes a synaptic refinement to form the adult pattern of
precise retinotopic connections in the superficial layers of the
superior colliculus (SC). In the rat, axons of retinal ganglion cells
enter the contralateral SC at embryonic day 16 (E16) and enter the
ipsilateral SC at E17. The retinotectal synapses are first formed at
E17 (Bunt et al. 1983; Lund and Bunt
1976
). The crossed and uncrossed retinotectal projections
initially distribute across the whole area of the SC. Subsequently most
of the ipsilateral projections retract caused by binocular competition
(Serfaty and Linden 1994
) during the first 10 postnatal
days (P10) (Land and Lund 1979
). At prenatal ages, axons
of retinal ganglion cells typically form side branches and often
arborize in topographically inappropriate regions. During the
refinement process, side branches and arbors from topographically inappropriate positions retract, and those at topographically correct
positions increase. This remodeling of axon arbors leads to an
adult-like topographic ordering of axonal arborization by P11-12
(O'Leary 1986
; Simon and O'Leary
1992a
,b
; Simon et al. 1994
), although even in
the adult there are still some aberrant ganglion cells that project to
topographically inappropriate regions of the SC (Rahman and
Yamadori 1994
).
The mechanisms underlying the synaptic refinement in another
subcortical visual pathwaythat from the retina to the lateral geniculate nucleus
were studied intensively (Shatz 1994
,
1996
). Before eye opening, retinal ganglion cells have
spontaneous synchronous bursting activity (Galli and Maffei
1988
; Maffei and Galli-Resta 1990
;
Meister et al. 1991
; Wong et al. 1993
).
This presynaptic activity can be transmitted faithfully to the
postsynaptic lateral geniculate neurons (Mooney et al.
1996
). The remodeling of presynaptic projections depends on
this retinal activity because blocking presynaptic activity and
synaptic transmission by tetrodotoxin (TTX), a Na+ channel
blocker, prevents the formation of eye-specific layers and
ON/OFF sublamination in ferret lateral geniculate nucleus (LGN) (Cramer and Sur 1996
; Shatz and Stryker
1988
). In addition, blocking
N-methyl-D-aspartic acid (NMDA) receptors or
nitric oxide synthase (NOS) also disrupts the formation of
ON/OFF sublaminae (Cramer and Sur 1994
;
Hahm et al. 1991
). Similarly, in the retinotectal pathway, the synaptic refinement appears to be activity dependent. Blocking NMDA receptor or NOS activity in the postsynaptic neuron also
disrupts synaptic refinement in the SC (Mize et al.
1998
; Simon et al. 1992
; Wu et al. 1994
,
1996
). Therefore the refinement requires an interaction between
presynaptic and postsynaptic activity. However, in vivo studies
(Itaya et al. 1995
; Molotchnikoff and Itaya
1993
) reported that retinotectal synaptic transmission in neonatal rats is not established until P10-12, when the refinement is
almost complete. This finding contradicts the notion that postsynaptic activity plays an important role in the refinement of the retinotectal connection.
We used a novel in vitro isolated brain stem preparation (Xia
and Lo 1996) to study retinotectal transmission in neonatal rats (P1-13). Both extracellular and whole cell recordings
(Mize et al. 1998
) demonstrate that all tested
superficial SC neurons respond to electrical stimulation of the optic
tract (OT) as early as P1. Throughout the period before eye opening
(P1-13), almost all neurons show three different response patterns
that are associated with activation of non-NMDA receptors, NMDA
receptors, and L-type calcium channels, respectively. Activation of
L-type calcium channels by retinal inputs is induced by either spatial
summation or temporal summation of retinal input and also by blocking
-aminobutyric acid-A (GABAA) receptors. We present our
extracellular recording results.
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METHODS |
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The method for producing the in vitro isolated brain stem
preparation was previously described (Xia and Lo 1996).
In brief, Sprague-Dawley rat pups ranging in age from P1 to P13 were
anesthetized with Fluothane (halothane) and killed by decapitation. The
brain was removed and immersed in an artificial cerebrospinal fluid (ACSF) bubbled with 95% O2-5% CO2 at room
temperature. The brain was cut along the midline and glued onto a
silver plate. By using a dissection microscope, the surface of the
thalamus and midbrain was exposed by gently removing the forebrain.
This "isolated brain stem" was then placed into a submerged-type
recording chamber perfused with ACSF of 33°C at a rate of 4-5
ml/min. Extracellular recordings were made with patch electrodes filled
with 1 M NaCl (2-4 M
). We collected action potentials from cell
bodies, all of which were located at a depth of <140 µm as
determined by measuring the depth of the electrode below the pial
surface. Action potentials recorded from axons, identified by their
characteristic monophasic response and slow decay, were discarded
(Ahlsen et al. 1982
). Because the SC is not laminated
until P30 (Warton and Jones 1985
), we named all recorded
neurons as superficial SC neurons because of the uncertainty of the
division into superficial gray and optic layers. A pair of stimulating
electrodes was put on the OT fibers at the level of the thalamus.
Single electrical pulses (0.1-0.3 ms, 20-1,000 µA) were delivered
through stimulating electrodes to evoke postsynaptic responses in the
superficial SC. Electrical signals were amplified with an Axoclamp 2B
amplifier and collected by an Instrutek VR10B interface unit and stored
on a Macintosh Power PC (9500/132) with the Pulses (HEKA) software
program.
The ACSF contained (in mM) 124 NaCl, 2.5 KCl, 1.25 NaH2PO4, 0.1 MgSO4, 26 NaHCO3, 10 glucose, and 2 CaCl2 (pH 7.4 after saturation by gases). We applied different antagonists such as D-2-amino-5-phosphonopentanoic acid (D-APV, 100 µM), 6,7-dinitroquinoxaline-2,3-dione (DNQX, 25 µM), and bicuculline (10 µM) to block NMDA, nonNMDA, and GABA receptors. We also applied nitrendipine (10-20 µM) to block L-type high-threshold calcium channels.
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RESULTS |
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All recorded superficial SC neurons (n = 71 including 10 at P1) from neonatal rats at P1-13 responded to electrical stimulation of the OT. Among them, 69 (97%) neurons showed 3 different firing patterns in response to stimulation at different intensities.
Single spike pattern
As shown in the left column of Fig. 1, weak stimulation (1 pulse, 0.1-0.3 ms, <100 µA) only induced one spike from superficial SC neurons at P1-13 (Fig. 1, A-E). These results also show a tendency for shortened response latency during development. We defined the minimal intensity that constantly induced one spike as threshold (1T).
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Short train firing pattern
When the stimulus intensity increased to two to five times that of threshold, superficial SC neurons gave a short train of spikes (Fig. 1, A-E, middle traces). The train duration was always <250 ms. The amplitude of spikes either remained constant or decreased gradually. There was also a tendency of decreasing train duration during development, most likely caused by the increase of GABA-mediated inhibition during development. The responses shown in Fig. 1 are typical of those of the remaining population from which we recorded.
Long train firing pattern
Increasing stimulus intensity to 5-10 times that of threshold resulted in a long train of spikes in superficial SC neurons. The train duration of spikes ranged from 300 to 1,000 ms. In the same neuron, the long train duration increased with increasing stimulus intensity. This firing pattern was characterized by a specific change in spike amplitude (Fig. 1, A-E, right traces). The first spike was always at the maximal amplitude. Later spikes decreased gradually in amplitude and even vanished. After that, even later spikes increased gradually. The concave envelope of spikes produced by this event implied a large and long-lasting depolarization of the membrane, the likely cause being Na+ channels that were partially or completely inactivated. The long spike train could be induced not only by increasing stimulus intensity but also by other manipulations. As shown in Fig. 1F, a single electrical pulse at 1T intensity elicited just one spike (left trace). Three pulses of the same intensity at 20-50 Hz induced a long train of spikes (middle trace). This result indicates that the long train firing pattern can be produced either by spatial summation of retinal inputs from increasing stimulus intensity or by temporal summation of retinal inputs from repetitive stimuli. In addition, application of bicuculline, a GABAA receptor antagonist, usually transformed a single spike or short train firing pattern into a long train firing pattern (right trace). This effect was confirmed for seven tested neurons at P1-13. This indicates that GABAA receptor-mediated inhibition prevents the generation of the long train firing at low stimulus intensity.
Pharmacological analyses of the three firing patterns
The long train firing pattern transformed into a short train pattern at the same stimulus intensity after blocking L-type high-threshold calcium channels by application of nitrendipine, an L-type calcium blocker (Fig. 2, A vs. B and E vs. F). Because nitrendipine did not affect single spike or short train firing patterns induced by weak or moderate stimulation, the blockade of the long train pattern was unlikely to be caused by a decrease of presynaptic neurotransmitter release. Thus the long train firing pattern must be associated with activation of postsynaptic L-type calcium channels. Additional application of D-APV, an NMDA receptor antagonist, changed the short train pattern into a single spike pattern in response to strong stimulation (Fig. 2, B vs. C and F vs. G). The single spike was abolished by additional application of DNQX, a non-NMDA antagonist (Fig. 2, C vs. D and G vs. H). The results shown in Fig. 2 are virtually identical to those nitrendipine, APV, and DNQX results in eight other neurons from which we recorded. In summary, the first spike appears to be mediated by non-NMDA receptors, late spikes in the short train by NMDA receptors, and late spikes in the long train by L-type calcium channels.
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DISCUSSION |
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In adult rats, stimulation of the OT induces a single spike in
most SC neurons (Sefton 1969). However, in neonatal rats
(P1-13), stimulation of the OT may elicit three firing patterns,
depending on stimulus intensity. Among them, the L-type calcium
channel-mediated long train firing pattern is the most striking event.
It was not observed in adults. The following factors may account for
the difference between neonatal and adult rats. 1) In
neonatal rats, the aberrant retinotectal projections probably provide
more retinal inputs to single SC neurons than those in adult rats.
Namely, a SC neuron may receive inputs from topographically appropriate and inappropriate regions of both retinae. Strong stimulation of the OT
recruits more OT fibers, which converge onto the single SC neuron.
Synchronous retinal inputs produce spatial summation of excitatory
postsynaptic potentials (EPSPs) and depolarize the neuron, which then
reaches the threshold of L-type calcium channels (Mize et al.
1998
). 2) In neonatal rats, GABA receptor-mediated inhibition is weaker than that in adults. In the rat SC, GABAergic neurons and GABAA receptors are present before birth
(Warton et al. 1990
), which is consistent with our
results. That application of bicuculline transferred a single spike or
short train firing pattern into a long train firing pattern even at P1
confirms that GABAA receptor-mediated inhibition already
exists at P1. However, several lines of evidence indicate there is a
postnatal increase of GABA receptor-mediated inhibition
(Schliebs and Rothe 1988
; Schliebs et al.
1986
; Shi et al.1997
; Warton et al.
1990
). The weaker inhibition in neonatal rats makes temporal
summation of retinal inputs possible. Thus repetitive stimuli at 20-50
Hz may induce membrane depolarization large enough to activate L-type calcium channels. 3) In neonatal rats, the contribution of
NMDA receptors in retinotectal transmission is larger than that in adults (Hestrin 1992
; Shi et al. 1997
).
Our whole cell recordings show that strong stimulation of the OT
induces a depolarizing plateau potential mediated by L-type calcium
channels. This plateau potential is triggered by an NMDA
receptor-mediated EPSP (Mize et al. 1998
). Therefore a
prominent NMDA-mediated EPSP is a prerequisite of activation of L-type
calcium channels.
Although L-type calcium channels are activated by electrical
stimulation of the OT, activation of L-type channels is most likely an
endogenous event in superficial SC neurons of neonatal rats. Before eye
opening, retinal ganglion cells have spontaneous synchronous bursting
activity (Galli and Maffei 1988; Maffei and Galli-Resta 1990
; Meister et al. 1991
;
Wong et al. 1993
). The synchronization of retinal inputs
leads to spatial summation, and high-frequency bursting causes temporal
summation of retinal inputs on single SC neurons. Therefore spontaneous
retinal activity before eye opening appears likely to be sufficient to
activate L-type calcium channels of superficial SC neurons. Synaptic
plasticity requires an increase of intracellular Ca2+
concentration. Previously, studies emphasized that NMDA receptors are
the main source of calcium influx into postsynaptic neurons during
synaptic plasticity (Bear 1996
; Cramer and Sur
1996
; Simon et al. 1992
). Our results suggest
that activation of NMDA receptors not only causes calcium influx
through receptors per se but also secondarily activates L-type
high-threshold calcium channels because the long train of spikes is
also blocked by APV. This dual activation of NMDA receptors and L-type
calcium channels is likely to induce a much longer and larger calcium
influx into superficial SC neurons in neonatal rats.
It will be important in future studies to determine directly the extent
of the contributions of these two channels to calcium influx in both
developing and adult rats. It will also be useful to resolve the
discrepancy with previous studies that failed to activate tectal
neurons via retinal stimulation before P10. (Itaya et al.
1995; Molotchnikoff and Itaya 1993
). The
discrepancy is likely due to the in vitro versus in vivo preparations
used. In in vivo experiments, it is more difficult to maintain synaptic transmission due to anesthesia, hypothermia, anoxia, and other unfavorable conditions. A real advantage of our isolated brain stem
preparation is the ability to maintain an intact, functional retinotectal circuitry at very early postnatal ages.
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ACKNOWLEDGMENTS |
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We thank Drs. W. Guido for use of his electrophysiological facility and J. R. Cork for valuable help in this study.
This work was supported by National Institutes of Health Grants EY-02973 and NS-36000.
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FOOTNOTES |
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Address for reprint requests: F.-S. Lo, Dept. of Cell Biology and Anatomy, LSU Medical Center, 1901 Perdido St., New Orleans, LA 70112.
The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
Received 10 August 1998; accepted in final form 8 October 1998.
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REFERENCES |
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