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The Journal of Neuroscience, October 15, 2000, 20(20):7672-7681
Mice Lacking Specific Nicotinic Acetylcholine Receptor
Subunits Exhibit Dramatically Altered Spontaneous Activity Patterns and
Reveal a Limited Role for Retinal Waves in Forming ON and OFF Circuits
in the Inner Retina
Anu
Bansal1, 2,
Joshua
H.
Singer1,
Bryan J.
Hwang1, 2,
Wei
Xu3,
Art
Beaudet3, and
Marla B.
Feller1
1 Synapse Formation and Function Unit, National
Institute of Neurological Disorders and Stroke, National Institutes of
Health, and 2 Howard Hughes Medical Institute-National
Institutes of Health Research Scholars Program, Bethesda, Maryland
20892, and 3 Department of Molecular and Human Genetics,
Baylor College of Medicine, Houston, Texas 77030
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ABSTRACT |
Before phototransduction, spontaneous activity in the developing
mammalian retina is required for the appropriate patterning of
retinothalamic connections, and there is growing evidence that this
activity influences the development of circuits within the retina
itself. We demonstrate here that the neural substrate that generates
waves in the mouse retina develops through three distinct stages.
First, between embryonic day 16 and birth [postnatal day 0 (P0)], we
observed both large, propagating waves inhibited by nicotinic
acetylcholine receptor (nAChR) antagonists and small clusters of cells
displaying nonpropagating, correlated calcium increases that were
independent of nAChR activation. Second, between P0 and P11, we
observed only larger propagating waves that were abolished by toxins
specific to  3 and  2 subunit-containing nAChRs. Third, between P11
and P14 (eye opening) we observed propagating activity that was
abolished by ionotropic glutamate receptor antagonists. The time course
of this developmental shift was dramatically altered in retinas from
mice lacking the 2 nAChR subunit or the 2 and 4 subunits.
These retinas exhibited a novel circuit at P0, no spontaneous
correlated activity between P1 and P8, and the premature induction at
P8 of an ionotropic glutamate receptor-based circuit. Retinas from
postnatal mice lacking the 3 nAChR subunit exhibited spontaneous,
correlated activity patterns that were similar to those observed in
embryonic wild-type mice. In 3 / and 2/ mice, the
development and distribution of cholinergic neurons and processes and
the density of retinal ganglion cells (RGCs) and the gross segregation
of their dendrites into ON and OFF sublaminae were normal. However, the
refinement of individual RGC dendrites is delayed. These results
indicate that retinal waves mediated by nAChRs are involved in, but not
required for, the development of neural circuits that define the ON and
OFF sublamina of the inner plexiform layer.
Key words:
retinal waves; calcium imaging; visual system
development; cholinergic amacrine cells; nicotinic receptor subunits; spontaneous activity
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INTRODUCTION |
In many regions of the developing
nervous system, spontaneous calcium and electrical signals have been
observed even before neural circuits are fully formed or sensory
transduction is possible (Yuste, 1997 ). This activity may promote the
functional maturation of neural circuits. For example, in the
developing visual system, before eye opening, retinal ganglion cells
(RGCs) spontaneously fire periodic bursts of action potentials that
propagate across the ganglion cell layer (Wong, 1999). This highly
correlated, propagating retinal activity, termed "retinal waves,"
is mediated at least in part by synaptic transmission. Spontaneous
retinal activity has been implicated in directing the refinement of
connections between RGC axons and their thalamic targets in the lateral
geniculate nucleus (Penn et al., 1998; Shatz and Stryker, 1988;
Chapman, 2000) (but see Cook et al., 1999). Spontaneous retinal
activity has been implicated also in the establishment of orientation
selectivity in primary visual cortex (Chapman and Godecke, 2000),
although other cues may be involved in the establishment of ocular
dominance columns (Crowley and Katz, 1999).
Spontaneous neural activity may also influence the development of the
retina itself. Although a general blockade of action potentials with
intraocular injections of tetrodotoxin had little effect on the
dendritic structure of RGCs in both embryonic (Campbell et al., 1997)
and postnatal cat retina (Wong et al., 1991), manipulations of
neurotransmitter systems providing synaptic input to ganglion cells had
more profound effects on RGC anatomy and function. For example,
Sernagor and Grzywacz (1996) demonstrated that blockade of retinal wave
activity in turtle retina with intraocular injection of the general
nicotinic acetylcholine receptor (nAChR) antagonist D-tubocurarine prevented the dark-rearing-induced changes
in RGC receptive fields. RGC dendrites are therefore unable to respond to altered sensory experience in the absence of spontaneous correlated activity. In another example, Lau et al. (1992) demonstrated that blockade of NMDA receptors before eye opening increase the spine density of RGCs in hamster. In addition, Bodnarenko and Chalupa (1993)
and Bodnarenko et al. (1995) demonstrated that the segregation of RGC
dendrites into ON and OFF sublamina requires glutamatergic neurotransmission from bipolar cells.
The fact that both cholinergic and glutamatergic neurotransmission are
implicated in the activity-dependent development of the retina is of
significant interest, because retinal waves are modulated
differentially by these two neurotransmitter systems during postnatal
development (Catsicas et al., 1998; Wong et al., 1998, 2000; Wong,
1999; Sernagor et al., 2000; Zhou and Zhao, 2000). For example, during
the first 10 postnatal days (P0-P10) in ferret, both the generation
and propagation of retinal waves are blocked by neuronal nAChR
antagonists (Feller et al., 1996). In ferret retinas older than P15,
waves are insensitive to nAChR antagonists and are blocked instead by
ionotropic glutamate receptor antagonists (Wong et al., 2000). The
timing of this developmental switch to glutamatergic transmission is
correlated with the appearance of bipolar cell terminals in the inner
plexiform layer (IPL) (Miller et al., 1999). It has not been
demonstrated previously whether the transition from cholinergic to
glutamatergic waves required nAChR-mediated retinal activity.
Here we show that the circuitry that mediates retinal waves in the
neonatal mouse retina makes a similar transition from nAChR-mediated to
ionotropic glutamate receptor-mediated transmission during postnatal
development. As in the ferret retina (Penn et al., 1998), the
functional nAChR receptors mediating waves in mice contain 3 and
2 subunits. We make use of genetically altered mice lacking these
nAChR subunits (Xu et al., 1999a,b) to assay their contribution to
spontaneous activity in the developing retina. Mice lacking the 3
subunit showed retinal wave activity with altered spatiotemporal properties, whereas mice lacking the 2 subunit had no detectable wave activity during the first postnatal week. The absence of cholinergic-mediated waves in 2/ mice induces them to make a
precocious transition to ionotropic glutamate receptor-mediated waves.
We then examined the contribution of nAChR-mediated waves to the
maturation of anatomical circuits in the inner retina by comparing in
2/ and normal mice the distribution of cholinergic processes and
the stratification of RGC dendritic arbors.
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MATERIALS AND METHODS |
Retinal preparation. All procedures were performed in
accordance with approved animal use protocols at National Institutes of
Health. Retinas were isolated from newborn mice (P0-P13) that had been
deeply anesthetized with halothane and then decapitated. They were
placed ganglion cell layer-up in a temperature-controlled chamber
(30°C; Warner Systems) mounted on the stage of an upright microscope
(Axioskop; Zeiss, Thornwood, NY) and perfused continuously with
artificial CSF (ACSF; in mM: 119 NaCl, 2.5 KCl, 1.3 MgCl2, 1.0 KH2PO4, 2.5 CaCl2, 26.2 NaHCO3, and 11 D-glucose) bubbled with 95%
O2 and 5% CO2.
Fluorescence imaging. Isolated retinas were incubated with
10 µM fura-2 AM (Molecular Probes, Eugene, OR) in ACSF
containing 1% DMSO and 0.02% pluronic acid for 2-6 hr in an
oxygenated chamber at 28°C. All experiments were conducted with 380 nm illumination under a 10× water immersion objective (Olympus
Optical, Tokyo, Japan). Images were acquired with a silicon-intensified
target camera (MIT 300; Dage, Michigan City, IN). An initial
background frame was acquired and was subtracted on a pixel-by-pixel
basis from all subsequent frames to create a difference image. The
difference image was averaged over four video frames, giving a time
resolution of 120 msec/frame. Images were processed by a digital video
processor (DVP-32; Instrutech, Port Washington, NY) and recorded onto
s-videotape (Panasonic). The average fluorescence intensity over a 200 µm2 area was monitored on each retina to
determine the frequency and peak amplitude of the fractional changes in
fluorescence,  F/F. Recorded waves were digitized and analyzed on an
Apple (Cupertino, CA) Macintosh computer using NIH Image software to
determine the area, frequency, and velocity.
Electrophysiology. Whole-cell voltage- or current-clamp
recordings were made using an Axopatch 200B amplifier and pClamp6 software (Axon Instruments, Foster City, CA). The amplitude of postsynaptic currents (PSCs) was taken as the maximum current recorded during a compound event. Vhold was 60
mV. The intracellular solution consisted of (in mM): 98.3 potassium gluconate, 1.7 KCl, 0.6 EGTA, 5 MgCl2,
2 Na2-ATP, 0.3 GTP, and 40 HEPES, pH 7.25, with
KOH. The calculated ECl was 60 mV.
Pharmacology. All pharmacological agents (RBI/Sigma, St.
Louis, MO) were dissolved in ACSF and bath-applied to retina.
Conotoxins were provided by M. McIntosh, University of Utah,
Salt Lake City, UT (Cartier et al., 1996; Luo et al., 1998). To
facilitate peptide penetration into retinal tissue, the retinas were
incubated in 2 mg/ml collagenase/dispase (Boehringer Mannheim,
Indianapolis, IN) for 10 min at 30°C. Although this treatment was
found to alter the spatiotemporal properties of waves in normal mice,
primarily by restricting the size of propagating waves
(n = 3), this treatment was necessary to allow
conotoxins to penetrate into the tissue (Fig. 1C). A similar
collagenase treatment was used to load retinas from animals older than
P5 with fura-2 AM (see Fig. 3C). All drug effects were
reported as mean ± SD. Significance was tested using a Student's
t test unless noted otherwise (Sigmastat).
Immunohistochemistry. Mice older than P2 were perfused with
a 4% solution of paraformaldehyde (Sigma) in 0.1 M
phosphate buffer for 10 min. For P2 preparations, eyes were
immersion-fixed in 4% paraformaldehyde in 0.1 M phosphate
buffer for 30 min. Eyecups were post-fixed for an additional 60 min.
Eyes were cryoprotected in 30% sucrose in Tris-buffered saline and
were cut into 14 µm transverse sections on a cryostat. Sections were
mounted and permeabilized in a solution containing (in %): 20 normal
donkey serum, 5 sucrose, 0.5 Triton X-100, and 0.001 sodium azide for 2 hr. Primary antibodies to choline acetyltransferase (anti-ChAT,
generated in goat; Chemicon, Temecula, CA) and the vesicular
acetylcholine transporter (anti-VAChT, generated in rabbit; a gift from
S. Landis, National Institutes of Health, Bethesda, MD) were
diluted into this solution at 1:100 and 1:1000, respectively. Sections
were incubated in primary antibodies at 4°C for 24 hr and
fluorescence-labeled secondary antibodies for 30 min (1:50
fluorescein-conjugated anti-goat and 1:150 rhodamine red-X-conjugated
anti-rabbit; Jackson ImmunoResearch, West Grove, PA). The following
controls were performed to ensure primary and secondary antibody
specificity: (1) incubation with no primary and then one or both
secondary antibodies yielded no specific staining; and (2) incubation
with one primary antibody and both secondary antibodies or both primary
antibodies and one secondary antibody resulted in staining that was
indistinguishable from incubation with a single primary and
animal-matched secondary antibody combination.
Ganglion cell morphology. RGCs were filled while recording
with pipettes containing 0.4-0.5% Lucifer yellow dissolved in
internal solution. Retinas were then fixed in 4% paraformaldehyde,
incubated in 10 µM 4,6-diamidino-2-phenylindole
(DAPI) in phosphate buffer solution to label cell nuclei,
mounted on slides, and viewed on either a deconvolution microscope
(Scanalytics Cellscan, Axiophot) or a confocal microscope (Zeiss 410).
RGCs were identified on the basis of dendritic morphology, soma
size, presence of a large Na+ current,
and, in some cases, presence of an axon. Dendritic stratifications were
measured from 3-D reconstructions (NIH Image and Metamorph Software;
Universal Imaging, West Chester, PA). The location and width (taken at
half-maximum) of these stratifications were normalized to the width of
the IPL, which was obtained by measuring the distance between
DAPI-labeled nuclei in the ganglion cell layer and inner nuclear layer.
Ganglion cell dendrites were also visualized after retrograde transport
of 1,1'-dioctadecyl-3,3,3',3'-tetramethyl indocarbocyanine percholate
(DiI) crystals applied to the optic nerves of animals that had been
perfusion- and post-fixed with 4% paraformaldehyde. Again, RGCs were
reconstructed using a confocal microscope, and dendritic
stratifications were counted from the 3-D reconstructions (NIH Image
and Metamorph Software; see Fig. 5A2). The density of RGCs
was measured by dividing the number of cell bodies contained in a
single z section of the ganglion cell layer by the total area of that section.
Genotyping. Genotyping of mice lacking the 3, 2, and
4 subunits was done by PCR with primer sequences as previously
described (Xu et al., 1999a,b). 3/ mice were generated in
litters containing 3/, 3+/, and 3+/+ offspring.
2/4/ mice were raised on a 2/ homozygote
background and generated litters containing 4/, 4+/, and
4+/+ offspring. These mice were back-crossed at least six
generations into the C57black6 strain; C57black6 mice were used for
comparison in all experiments. DiI labeling was also conducted in
2/4+/+ and 2+/+4+/+ littermate pairs.
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RESULTS |
Waves in P0-P7 mice are mediated by nAChRs containing 3 and
2 subunits
Experiments were conducted on retinas isolated acutely from
newborn mice (P0-P13) and incubated in the calcium indicator fura-2 AM. The spatial distribution and time course of spontaneous changes in
intracellular calcium concentration
([Ca2+]i) in the
ganglion cell layer were assessed by real-time fluorescence imaging and
represented by the fractional change in fluorescence F/F. Periodic
changes in [Ca2+]i
are associated with membrane depolarizations driven by barrages of
synaptic inputs (Feller et al., 1996) and therefore can be interpreted
as a measure of cell electrical activity.
Retinal waves recorded in mice have spatiotemporal properties similar
to those previously characterized in ferret (Feller et al., 1996, 1997)
and chick (Wong et al., 1998; Sernagor et al., 2000). Waves initiate in
random locations and propagate across the retina, stopping at
well-defined boundaries (Fig.
1A). These boundaries
are determined in part by a "refractory period" that we define as
the period after a wave has passed through a region of the retina
during which another wave cannot propagate through that same region.
Using a previously described method (Feller et al., 1996), we
calculated the wave refractory period in mice to be 25-35 sec (data
not shown; n = 170 wave pairs, four retinas), shorter
than the 40-50 sec refractory period in ferrets (Feller et al.,
1996).
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Figure 1.
Retinal waves in normal mice are mediated by
nAChRs containing 3 and 2 subunits. A, Time
evolution of a single retinal wave visualized with fluorescence
imaging. Decreases in fura-2 fluorescence associated with the increased
calcium evoked by waves are shown at successive 0.5 sec intervals. The
last frame represents the "domain" of the wave,
defined as the total area of tissue covered by a single wave.
B, Spontaneous activity is blocked by toxins specific to
nAChRs containing the 3 subunit. Left, Effects of
50-100 µM curare (CUR), 2 µM dihydrobetaerthroidine (DBE), and 200 nM -bungarotoxin (BTX) on the
fractional change in fluorescence, F/F, averaged over 100 µm2 regions of P0-P6 retinas.
Right, Effects of -conotoxin-AU1B
(AU1B) and -conotoxin MII (MII)
on the number of waves per minute per square millimeter. The
collagenase treatment necessary for peptide penetration restricted wave
propagation (see Materials and Methods) and made F/F measurements in
a small region a poor reflection of the overall activity level.
Therefore, the conotoxin effects on wave activity were measured by
counting the number of waves observed in the total imaged area in a 10 min period. Scale bar, 100 µm.
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Bath application of nAChR antagonists D-tubocurarine
chloride (curare, 50-100 µM; n = 11 retinas) and dihydro--erythroidine (1 µM;
n = 7 retinas) blocked all spontaneous increases in
[Ca2+]i associated
with retinal waves (Fig. 1B). This indicates that retinal waves require nAChR-mediated synaptic transmission, a result
that has been observed in rabbit (Masland, 1977; Zhou, 1998), turtle
(Sernagor and Grzywacz, 1999), and ferret (Feller et al., 1996) but not
chick (Catsicas et al., 1998; Wong et al., 1998; Sernagor et al.,
2000).
Nicotinic AChRs found in the CNS are either homomultimers consisting
entirely of 7 subunits or heteromultimers containing a combination
of and subunits (Sargent, 1993; McGehee and Role, 1995; Role
and Berg, 1996). In heterologous expression systems, 3 subunits form
functional nAChRs only in the presence of either the 2 or 4
subunit (Sargent, 1993; Role and Berg, 1996). In situ
hybridization (Zoli et al., 1995) and antibody labeling have localized
these subunits to the retina (Aizenman et al., 1990; Hamassaki-Britto
et al., 1994). We used high-affinity antagonists selective for nAChRs
containing particular subunits or subunit combinations to identify the
functional receptors mediating waves. Bath application of
-bungarotoxin (200 nM), a toxin with a high affinity for nAChRs containing the 7 subunit, only weakly attenuated periodic [Ca2+]i
increases (F/F = 90 ± 2% of control; n = 3, three mice; Fig. 1B). Thus, nAChRs containing the
7 subunit do not appear to be required for wave generation. On the
other hand, -conotoxin-MII (1 µM) and
-conotoxin-AU1B (1-10 µM), toxins that
preferentially block 32 and 34 nAChRs, respectively
(Cartier et al., 1996; Luo et al., 1998), dramatically reduced wave
frequency (-conotoxin-MII, 5 ± 3% of control;
n = 3, three mice; -conotoxin-AU1B, 45 ± 10% of control; n = 5, two mice; p < 0.001; Fig. 1B). Although the specificity of these
toxins may be compromised at the high concentrations used here (Cartier
et al., 1996), and their specificity has not been determined for mouse
nAChRs, the maximal inhibition by -conotoxin-MII indicates that in
mice, as in ferrets (Penn et al., 1998), an 3- and 2-containing
nAChR is the most critical to retinal waves.
The potential lack of specificity of conotoxins as well as the growing
evidence that nAChRs in vivo may contain more than one
subunit from each of the and families indicate that our pharmacological studies do not precisely define the role that 3 and
2 subunits play in retinal wave generation. Hence, we studied the
spontaneous retinal activity in transgenic mice lacking either the 3
or 2 nAChR subunit or both the 2 and 4 subunits. The gross
phenotypes of the 3/ (Xu et al., 1999a), 2/, and 2/4 / (Xu et al., 1999b) mice have been described
previously. Generally, 3/ and 2/4/ mice have
similar phenotypes, exhibiting a loss of function of the autonomic
nervous system, delayed eye opening, and high mortality after the first
postnatal week (Xu et al., 1999a,b). The 2/ mice, however,
although exhibiting a normal phenotype, show abnormal passive avoidance
behavior (Picciotto et al., 1995), increased neurodegeneration with
aging (Zoli et al., 1999), and a reduced anti-nociceptive response to
nicotine (Marubio et al., 1999).
Correlated activity in the 3/ retina has altered
spatiotemporal properties mediated by the extension of an embryonic
wave-generating mechanism
Retinas from mice lacking the 3 subunit exhibited spontaneous
correlated activity different from that of wild-type retinas. We have
classified the spontaneous activity in 3/ mice into two
categories: large propagating waves (each wave covering >0.075 mm2) and small (<0.075
mm2), co-active domains (Fig.
2A,B). Note that this
distinction of size is not absolute: all events <0.025
mm2 (represented by the 1st bin in
the summary histograms of Fig. 2B) correspond to a
simultaneous increase in
[Ca2+]i; all
events >0.075 mm2 (4th-40th bins of Fig.
2B) correspond to propagating events; and events
between the size of 0.025 and 0.075 mm2
(2nd and 3rd bins of Fig. 2B) represent a mixture of
nonpropagating and propagating events.
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Figure 2.
Waves in 3/ mice have altered
spatiotemporal properties. A, Retinal waves of postnatal
wild-type (P2 3+/+), 3/
(P2), and embryonic (E17 normal)
retinas. Each frame summarizes 90 sec of activity in
control ACSF (top row) and in 100 µM
D-tubocurarine (bottom row). Gray
background represents the total retinal surface labeled with
fura-2 AM. Each color corresponds to individual domains
with a color-coded time bar below each frame to indicate
the time of occurrence of each wave. Scale bar, 100 µm.
B, Normalized distribution of domain sizes for the three
classes of retinas pictured in A in control ACSF
(open bars) and in D-tubocurarine
(red lines). Bin size is 0.025 mm2.
3+/+ mice, n = 114 waves in control solutions,
four retinas, three mice; 3/ mice, n = 139 waves in control solutions; n = 93 in
D-tubocurarine, three retinas, three mice; embryonic normal
mice, n = 161 waves in control solutions;
n = 30 in D-tubocurarine, three
retinas, two mice. C, Retinal ganglion cells from
3/ mice have periodic compound PSCs comparable with those of
3+/+ mice. Left, PSC recorded by whole-cell voltage
clamp of RGCs in 3/ and 3+/+ mice. Right, PSC
peak amplitudes and inter-event intervals for 3+/+ (9 cells, 4 mice)
and 3/ (9 cells, 3 mice) mice.
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Consistent with the idea that propagating waves are mediated by
synaptic transmission, whole-cell recordings from RGCs in 3/
mice reveal periodic PSCs comparable in size and frequency with those
of littermate controls (Fig. 2C). Also, as in wild-type control retinas, the large propagating waves (>0.075
mm2) in 3/ retinas were blocked by
the general nAChR antagonist curare (100 µM;
n = 3; Fig. 2A), suggesting that
other nAChR subunits compensate for the missing 3 subunit; we
considered first the 7 subunit-containing nAChRs.
Although the 7 subunit is expressed in the retina (Hamassaki-Britto
et al., 1994), it is not thought to be functional on adult RGCs
(Aizenman et al., 1990; Baldridge, 1996). In agreement with these
observations, bath application of -bungarotoxin did not decrease
significantly the magnitude of F/F (data not shown, 66.7 ± 9.6% of control in 3/ mice; n = 3; 79.1 ± 5.3% in 3+/+ mice; n = 4; p = 0.281) indicating that waves in 3/ mice are not mediated
by increased numbers of 7 subunit-containing nAChRs. Other
candidates for compensatory receptor subunits are the 5 and 6
subunits. They are expressed in the retina (Zoli et al., 1995; Vailati
et al., 1999) and have been shown to form functional nAChRs with 2,
3, and 4 subunits (Ramirez-Latorre et al., 1996). Note that these
other subunits may form functional nAChRs in combination with 3 and
2 subunits in normal mice, in which case the compensation may
involve upregulation of subunits that are normally expressed.
In addition to propagating waves, 3/ mice supported a pattern of
activity previously unobserved in the developing, postnatal retina.
This activity was characterized by spontaneous increases in
[Ca2+]i correlated
across small regions containing only 10-20 cells (~0.025-0.075
mm2). None of the events observed in
wild-type mice is limited to such a small region of the retina (Fig.
2B, red arrow). These simultaneous
[Ca2+]i increases
did not propagate away from initiation sites, and their appearance was
not sensitive to bath application of curare (0 of 29 waves in curare
were large compared with 52 of 157 events in control; n = 3 retinas, Fig. 2A,B, second column, bottom). We
considered the possibility that these events are mediated by the
activation of GABAA receptors, a situation that
would be similar to the compensation seen in developing spinal cord
(Chub and O'Donovan, 1998; Milner and Landmesser, 1999). However,
these small events were not sensitive to 100 µM
picrotoxin, a GABAA receptor antagonist (85 ± 5% of control F/F in 3/ mice; n = 2;
87.5 ± 3.5% in 3+/+ mice; n = 2; includes
small and large events), raising the possibility that these correlated
increases in
[Ca2+]i are
nonsynaptic in origin.
The changes in the spatiotemporal properties of all spontaneous
activity in 3/ mice are summarized in Table
1. In comparison with littermate
controls, the interval between waves and the interval between
initiations were approximately halved in 3/ mice. However, although the interval between events decreased, the speed of wavefront propagation was comparable, indicating that the intercellular coupling
responsible for the propagation of the activity is not likely to have
changed. Interestingly, neither propagating waves nor the smaller
regions of simultaneous
[Ca2+]i increases
in 3/ mice consistently respected refractory boundaries defined
by previous waves as observed in wild-type mice.
The above results imply that in 3/ mice there are two distinct
mechanisms that underlie spontaneous generation of correlated activity
in the retina. The mechanism underlying the generation of larger waves
requires nAChR-mediated synaptic transmission not involving either 3
or 7 subunit-containing nAChRs. In contrast, the mechanism
responsible for the smaller regions of simultaneous [Ca2+]i increases
is neither nAChR nor GABAA receptor-mediated.
To determine whether these compensatory mechanisms are novel or are the
extension of a prenatal phenotype, we studied the properties of waves
in normal embryonic mice. The earliest age at which we could record
reliably spontaneous increases in
[Ca2+]i using
fluorescence imaging of fura-2 was embryonic day 16 (E16) or E17.
Similar to the postnatal 3/ retinas, embryonic retinas exhibited
two kinds of spontaneous correlated activity: larger propagating waves
that were more sensitive to curare (events covering >0.075
mm2) and small regions (covering <0.075
mm2) that underwent correlated increases
in [Ca2+]i and
were insensitive to nAChR antagonists (Fig. 2A, third
column). There was a lower percentage of larger waves in the E17
compared with 3/ retina (14 vs 33% E17 normal vs P0-P5
3/ mice; Fig. 2B), and these larger waves were
more sensitive to curare than the small waves (4 of 93 events in curare
covered an area >0.075 mm2 vs 19 of 139 events in control). Waves seen in E17 retinas were similar to those of
3/ retinas in that they did not always respect the refractory
boundaries defined by previous waves. At E17, however, a given local
retinal area participated in more spontaneous events than were observed
in postnatal 3/ retinas. This increase is attributable in part
to a reduction in the wave initiation interval (Table 1). These results
suggest that retinal waves seen in 3/ mice may be mediated, at
least in part, by an extension of the embryonic activity-generating
mechanism. These experiments do not address whether the presence of the
3 subunit in normal mice acts to suppress the initiation of these
small, nonpropagating events or whether the 3 subunit mediates all
propagating events.
2/ mice do not have nAChR-mediated retinal waves
Unlike the 3/ mice, mice lacking the 2 subunit or 2
and 4 subunits of nAChRs exhibited no correlated spontaneous
activity between P1 and P8, as assessed by fluorescence imaging. We
found this to be the case for 2/4+/+ (n = 8),
2/4+/ (n = 12), and 2/4/ mice
(n = 7), indicating that the 2, not the 4 subunit, is critical in establishing this phenotype.
We found that lack of nAChR-mediated waves between P1 and P8
significantly altered the development of the circuits that mediate waves at other ages. We compared the properties of waves in P0 and
P8-P12 2/ mice with those measured in control retinas as described above. Waves recorded in P0 2/ mice are significantly different from those in normal postnatal mice (Fig.
3A; n = 7 mice; compared with Fig. 2A, first column). First, P0
2/ retinas exhibited both small regions with simultaneous
increases in
[Ca2+]i and
propagating waves that traversed larger regions of the retina. Second,
a large percentage of waves propagated across the entire imaged area
(>1 mm2; n = 3 2/4/ mice; n = 2 2/4+/ mice;
n = 3 2/4+/+ mice; Fig. 3B), which
is rarely seen in control animals (Fig. 2B).
Third, neither the coactive regions nor the propagating waves were inhibited by curare (100 µM;
n = 7 experiments, six mice; Fig. 3A).
Fourth, waves recorded in P0 2/ mice did not respect refractory
boundaries (Fig. 3A). Other spatiotemporal properties of
these waves are listed in Table 1.
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Figure 3.
2/ mice have altered retinal waves.
A, Retinal waves of P0 2/ mice. Same
configuration as Figure 2A. B,
Normalized distribution of domain sizes for P0 2/ mice in
control ACSF (open bars) and in
D-tubocurarine (red lines). Bin size is
0.025 mm2. n = 115 waves in
control solutions; n = 153 in
D-tubocurarine, three retinas, three mice.
C, Effects of nAChR antagonists [2 µM
dihydrobetaerthroidine (DBE) or 100 µM
D-tubocurarine (CUR)] and non-NMDA
ionotropic glutamate receptor antagonists [25 µM
6,7-dinitroquinoxaline-2,3-dione (DNQX) or 50 µM 6-cyano-7-nitroquinoxaline-2,3-dione
(CNQX)] on F/F averaged over 200 µm2 regions of retinas from P5-P14 normal and
P8-P11 2/ mice.
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Mouse retinas, like ferret (Wong, 1999) and rabbit (Zhou and Zhao,
2000) retinas, make a developmentally regulated switch from a
nAChR-mediated wave-generating circuit to one mediated by ionotropic
glutamate receptors (Fig. 3C). In normal animals, between P5
and P11, waves are blocked by nAChR antagonists (2 µM dihydrobetaerthroidine or 100 µM curare; n = 28 in 11 mice). During this period, the amplitudes of the F/Fs associated with waves
are attenuated but not blocked by non-NMDA glutamate receptor antagonists (25 µM DNQX or 50 µM CNQX; F/F = 50.4 ± 17.0% of control; n = 26 in 13 mice). Between P12 and P14,
however, we observed that waves are completely blocked by the non-NMDA
receptor antagonists (n = 5 in 4 mice). Waves at these
older ages are weakly modulated by nAChR antagonists (F/F = 64.8 ± 12.6% of control; n = 2 in two mice).
These results indicate that the developmental switch in wave-generating
circuitry occurs at approximately P11 in normal animals.
In 2/ mice, waves are absent between P1 and P8. When they emerge
at P8, waves are mediated by an ionotropic glutamate receptor-based circuit (Fig. 3C). These waves are always blocked by
non-NMDA receptor antagonists (n = 8, three 2/
mice) but not by nAChR antagonists (F/F = 90.6 ± 13.5%
of control; n = 8, three 2/ mice). In accordance
with these imaging results, whole-cell current-clamp recordings in 14 of 14 RGCs from normal mice (n = 5 mice, P7-P13) and
in 28 of 31 RGCs from 2/ mice (n = 10 mice,
P7-P13) showed rhythmic spontaneous depolarizations (data not shown).
The periodicity of these depolarizations was not significantly
different (intervals of 74.08 ± 10.90 sec for normal and
70.98 ± 7.08 sec for 2/ mice; p = 0.81),
and the depolarizations were blocked by bath application of 25 µM DNQX (n = 8 cells in 5 mice
for normal mice; n = 13 cells in seven 2/ mice).
These observations on the pharmacological profile of waves in 2/
mice suggest that the absence of an nAChR-based circuit allows for the
precocious appearance of glutamate receptor-mediated waves. We did not
study this transition in 3/ mice, because most of these mice die
by P8 (Xu et al., 1999a).
Altered retinal waves do not alter the stratification of
cholinergic amacrine cells
Because 2/ mice lacked retinal waves and 3/ mice had
altered retinal waves during the first postnatal week of development, we studied them to determine whether nAChR-mediated activity influences the anatomical features of the inner retina. We first examined the
distribution of retinal cholinergic neurons, a subpopulation of
amacrine cells called starburst amacrine cells (Vaney, 1984; Masland
and Tauchi, 1986). The highly stereotyped distribution of these cells
is well characterized in a number of mammalian species (Voigt, 1986;
Vardi et al., 1989; Famiglietti, 1991). Their processes stratify very
early in development into either a single OFF or ON sublamina (Feller
et al., 1996; West Greenlee et al., 1998). To determine whether
activation of nAChRs containing 3, 2, or 4 subunits was
required for the distribution and stratification of starburst amacrine
cells, we used two antibodies directed against markers of cholinergic
neurons, anti-ChAT and anti-VAChT.
At all ages examined, ChAT was localized to a subset of amacrine cell
somas located both in the inner nuclear layer (INL) and displaced into
the ganglion cell layer (GCL), and it was colocalized with VAChT in the
amacrine cell processes in the ON and OFF sublaminae (Fig.
4). Except at the earliest ages examined,
VAChT was not found in amacrine cell somas. Both ChAT and VAChT
expression were evident at P2, although ChAT expression was often quite
low (data not shown). At all developmental ages, there was no
difference in the distribution and stratification of ChAT- or
VAChT-immunopositive cells among normal, 2/, and 3/
retinas (n = 3 retinas for each phenotype and age).
Similar results were found for P2 and P8 2/4/ retinas
(n = 3 mice each age; data not shown). These findings
suggest that neither the subunit composition of retinal nAChRs nor the
existence of nAChR-mediated retinal waves influences the development or
distribution of cholinergic processes.
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Figure 4.
Stratification of cholinergic neurons from P2 to
P14 is normal in 2/ and 3/ mice. Transverse sections of
mouse retinas immunostained for ChAT and VAChT are shown. P2 retinas
are only stained for VAChT. Bottom right panel,
DAPI-labeled neuronal somas in the INL (top) and GCL
(bottom). Scale bar, 10 µm.
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Waves mediated by ACh have a limited role in the stratification of
RGC dendrites
The adult IPL is organized into five distinct strata where
different cell types, defined by a combination of immunohistochemical markers and physiological response properties, make their synaptic connections in spatially segregated bands (Wassle and Boycott, 1991;
Kolb, 1997). The five strata are grouped into two sublaminae: the two
strata closest to the INL constitute the OFF sublamina and contain
processes of cells responding to decreases in illumination; the three
strata closest to the RGC layer constitute the ON sublamina and contain
the processes of cells responding to increases in illumination (Kolb,
1997). Previous work indicates that RGC dendritic stratification
depends on glutamate-mediated afferent activity from bipolar cells
(Bodnarenko and Chalupa, 1993; Chapman et al., 1996). However, as seen
in Figure 4, during the developmental period (P0-P8) when retinal
waves are mediated normally by activation of nAChRs, cholinergic
neurons in 2/ and 3/ retinas were already stratified in
distinct layers within the ON and OFF sublaminae of the IPL. Because
distinct classes of RGCs co-stratify with cholinergic neurons (Vardi et
al., 1989; Famiglietti, 1992), we asked whether RGC dendritic
stratification was altered by the absence of normal nAChR-mediated
retinal activity. We therefore compared the developmental time course
of RGC dendritic stratification in wild-type and 2/ mice.
To assay stratification, we applied crystals of the lipophilic
fluorescent tracer molecule DiI to the optic nerve stump of paraformaldehyde-fixed eyes from both normal and transgenic animals (Fig. 5A1). This technique
permits bulk loading by passive diffusion of most or all of the RGCs in
the retina (Bodnarenko et al., 1995). RGC dendritic processes were then
reconstructed from fluorescence images of whole-mount retinas taken on
a confocal microscope and later analyzed in cross section to determine
the number of dendritic strata and the thickness of the IPL (Fig.
5A2). In each retina, confocal scans were conducted at four
to eight locations across the mid- to mid-peripheral retina.
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Figure 5.
RGCs from 2/ mice show slowed segregation
into the adult strata pattern. A1, Confocal sections of
DiI-labeled RGCs at different focal depths (GCL, IPL, and INL). Scale
bar, 10 µm. A2, Cross-sectional projection of DiI
reconstructions averaged over 250 µm of retina. Arrows
show individual layers. Scale bar, 15 µm. At P8, examples of retinas
that contained a single stratum are also shown. A3,
Distribution of the number of strata in retinas from P8 normal and
2/ mice. B1, Left, XY projection of
3-D-reconstructed, Lucifer yellow-filled RGCs from P8 normal and
2/ mice. Scale bar, 10 µm. Middle,
x-z projection of same cells. Right,
Pixel intensity profiles of x-z projection averaged
over the y-axis, normalized to maximum pixel intensity.
The region containing the cell body has been excluded.
B2, Lucifer yellow-filled RGCs in P2, P7-P8, and P14
retinas from normal and 2/ mice. Cells are arranged by relative
location in IPL, and error bars indicate the width of dendritic
stratification (see location and width arrows in
B1). B3, Widths of dendritic
stratification for P2, P7-P8, and P14 normal and 2/ mice.
Stratification widths are normalized to the total width of the IPL.
Error bars indicate SD.
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At P2, the inner retina in both normal and 2/ mice was quite
immature, with a thick GCL (two or three cell bodies thick), a thin
IPL, and no apparent dendritic stratifications (Fig. 5A2, top). By P8, at the end of the period with no wave activity in 2/ retinas, nearly all regions studied in both normal and
2/ mice had segregated into at least two distinct bands, the
presumptive ON and OFF sublaminae (Fig. 5A2, middle). Thus
the lack of nAChR activation did not prevent this first stage of gross
segregation. There was a small but insignificant difference, however,
in the extent of dendritic stratification between normal and
transgenic mice. The number of distinct layers observed in the IPL
ranged from one to four strata in both normal and 2/ retinas
(Fig. 5A3). These variations in the number of strata did not
correlate with different locations in the retina. In P8 wild-type mice
the median number of strata observed was three (n = 19 measurements from three normal mice; Fig. 5A3). In P8
2/ retinas, the median number of strata was two
(n = 17 from four 2/ mice), but this difference
was not statistically significant (Mann-Whitney test, p = 0.21). The retinas of P8 2/4/ and
3/ mice had significantly narrower IPLs, perhaps because of the
reduced overall size of the eye (Xu et al., 1999a,b), and RGC dendrites
were not stratified or were only weakly stratified into two distinct
sublaminae (data not shown, 8 measurements, two 2/4/
mice; 20 measurements, four 3/ mice). These were not included in
the population analysis. Dendritic stratification of 2/ 4+/
mice was not measured.
Between P8 and eye opening (P14), when retinal waves are mediated by
ionotropic glutamate receptor-mediated transmission, the IPL in both
normal and 2/ mice approximately doubled in size, and RGC
dendrites segregated into four or five distinguishable strata (Fig.
5A2, bottom). These findings are consistent with previous observations that this refinement is mediated by glutamatergic neurotransmission (Bodnarenko and Chalupa, 1993), because this transmission persists in 2/ mice between P8 and P14.
DiI labeling of RGCs also allowed us to ensure that there was no change
in the density of RGCs between normal and 2/ retinas. RGCs
undergo a tremendous amount of apoptotic cell death during the first
few postnatal days in mice; approximately half of all RGCs die
during this period (Young, 1984). Recent experiments indicate that RGC
survival may require spontaneous retinal activity (Shen et al., 1999).
By counting the DiI-labeled RGCs in the confocal section containing the
ganglion cell layer (Fig. 5A1, left frame), we
determined that at P8, after the period of cell death, there was no
significant difference in the density of cells between normal and
2/ mice (1266 ± 433 cells/mm2; n = 23, four
normal mice; 1300 ± 310 cells/mm2;
n = 14, five 2/ mice; p = 0.79). We conclude that the absence of waves from P1 to P7 did not
alter the overall amount of cell death. However, the spontaneous
correlated [Ca2+]i
increases mediated by some compensatory mechanism seen in P0 2/
mice (Fig. 3A) may be sufficient to initiate an
activity-dependent survival process (Shen et al., 1999).
Although application of DiI to the optic nerve allowed us to visualize
the dendritic stratification of RGCs averaged over the entire
population of RGC types, this technique might have overshadowed the
effects of wave-induced activity on individual cell types. It is
possible that nAChR transmission mediates the stratification of only a
subset of RGCs, because only a subset of RGCs is known to colocalize
with the ChAT-positive bands shown in Figure 4A
(Vardi et al., 1989; Famiglietti, 1992). Therefore, we quantified the
stratification of individual RGCs in both wild-type and 2/ mice.
Individual RGCs were filled using a whole-cell recording pipette
containing internal solution and the fluorescent dye Lucifer yellow
(0.5%). Fluorescence images of filled RGCs acquired with either a
deconvolution microscope or a confocal microscope enabled us to measure
the width of dendritic stratification and its location within the IPL
(Fig. 5B1). To measure the IPL width, all somas were stained
by bath application of DAPI; the width of the IPL was taken as the
distance between DAPI-labeled cell nuclei in the GCL and INL. Figure
5B2 contains the measurements of individual RGC
stratification widths organized by location within the IPL.
At P2, consistent with the DiI measurements, we found that dendrites of
individual RGCs from wild-type (n = 11 cells, two mice)
or 2/ mice (n = 13 cells, two mice) ramified
throughout the IPL (Fig. 5B3). By P7-P8, RGC dendrites in
control retinas were more narrowly stratified than those in 2/
retinas (47 ± 20% of IPL; n = 28 cells, five
normal mice; compared with 70 ± 21% of IPL; n = 34 cells, six 2/ mice; p < 0.001; Fig.
5B2,B3). In addition, RGC dendrites in control retinas
showed some restriction to the ON or OFF sublaminae, whereas those in
2/ retinas did not (Fig. 5B2). By P14, in both
wild-type (n = 13 cells, two mice) and 2/
(n = 10 cells, three mice) mice, nearly all the RGCs were narrowly stratified (Fig. 5B3). Thus, the observation
that the strata in 2/ retinas are delayed in formation compared with normal mice at P7-P8 (Fig. 5A) could be attributable
to the delayed segregation of a subset of RGCs into the appropriate strata.
| |
DISCUSSION |
Altered activity patterns can change the development of functional
circuits that mediate retinal waves
In mouse retina, the synaptic circuitry responsible for the
spontaneous generation of correlated
[Ca2+]i increases
in the GCL evolves through three stages: E16-P0, P0-P11, and P11-P14
(Fig. 6). Normal embryonic retinas
support spontaneous activity that comprises simultaneous increases of [Ca2+]i in small
clusters of cells mediated by a non-nAChR circuit and activity that
propagates over substantially larger regions mediated by the activation
of nAChRs. During the first postnatal week, the normal retinal
circuitry matures so that there are no longer small coactive domains
but only propagating activity that is dependent on cholinergic
transmission mediated by 3 and 2 subunit-containing nAChRs. We
have demonstrated that mice lacking the 3 subunit continue to
support nAChR-mediated propagating retinal activity for at least 5 postnatal days. In contrast, 2/ retinas cannot support activity
during the first postnatal week, indicating that the 2 and not the
3 subunit is required to form postsynaptic nAChRs that mediate
waves.
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Figure 6.
Summary of development of the synaptic circuitry
that mediates waves in normal, 2/, and 3/ retinas. Each
color corresponds to a different wave-generating
circuit: yellow corresponds to non-nAChR circuitry that
mediates the nonpropagating events in embryonic normal and postnatal
3/ mice and the propagating event in P0 2/ mice;
red corresponds to circuits that require
activation of nAChRs; and blue corresponds to circuits
that require activation of ionotropic glutamate receptors. The
wave-generating circuitry in 3/ retinas was not studied in the
second postnatal week because of the premature death of the transgenic
mice.
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During the second postnatal week, propagating activity is mediated, at
least in part, by ionotropic glutamate receptors. Is cholinergic
activity required for the normal development of the glutamatergic
wave-generating circuit? We observed that 2/ mice do make the
switch to ionotropic glutamate receptor-mediated waves; however, they
make this transition 3-4 d earlier than normal mice (Fig.
3C). Note that although ionotropic glutamate receptor antagonists do not block fluorescence changes of the overall cell population in control P8-P11 retinas, they do block the rhythmic depolarizations recorded by whole-cell current clamp in individual RGCs. This apparent discrepancy might be attributable to the fact that
recordings are from primarily -type RGCs, and this particular subtype of RGC may be more sensitive to glutamatic modulation a few
days earlier than the network as a whole.
It is important to emphasize that even before the transition to
ionotropic, glutamate receptor-mediated waves occurs in normal mice,
the amplitude of fluorescence changes associated with retinal waves is
reduced in the presence of ionotropic glutamate receptor antagonists
(Fig. 3C). Glutamate secreted from migrating neurons or from
transient photoreceptor synapses in the IPL may modulate spontaneous
firing before bipolar cell synapses form (see Wong et al., 2000,
Discussion). Thus, upregulation of this source of glutamate or possibly
a premature establishment of bipolar cell synapses in the IPL may lead
to the precocious onset of the glutamatergic circuit induced by the
lack of nAChR-mediated waves.
Our studies reveal a novel non-nAChR-based mechanism for wave
generation. The small, coactive regions seen in embryonic normal and
postnatal 3/mice (Fig. 2A), as well as the
propagating activity observed in P0 2/ mice (Fig.
3A), persist in the presence of general nAChR antagonists.
This activity may be mediated by a combination of gap junctions and
chemical synaptic transmission, in some cases involving metabotropic
receptor-mediated signaling (Catsicas et al., 1998; Wong et al., 1998;
Sernagor and Grzywacz, 1999; Zhou and Zhao, 2000). Similar mechanisms
have been proposed to account for spontaneous activity in a variety of
circuits throughout the developing CNS (Yuste, 1997), including the
hippocampus (Leinekugel et al., 1997; Garaschuk et al., 1998) and
neocortex (Yuste et al., 1992; Owens and Kriegstein, 1998; Schwartz et
al., 1998; Peinado, 2000). It is unlikely that activity would be
propagated via diffusion of extracellular excitatory substances, such
as potassium (Burgi and Grzywacz, 1994; Sernagor and Grzywacz, 1999), because the regions of activation are quite limited (Copenhagen, 1996).
The observation that different circuits can generate rhythmic
depolarizations and propagating activity patterns in the same neural
circuit at different stages of development is not unique to the retina.
The developing chick spinal cord supports spontaneous correlated
activity among synaptically connected interneurons and motoneurons that
also undergoes a developmental change in circuitry. The primary
neurotransmitter that drives activity switches from acetylcholine at E5
(Milner and Landmesser, 1999) to glutamate at E10 (O'Donovan and Chub,
1997). Remarkably, even at a single developmental stage, spinal cord
circuits can produce appropriate rhythmic activity via more than one
mechanism. Activity suppressed by nicotinic (at E5) or ionotropic
glutamatergic (at E10) receptor blockade is restored after some delay,
now mediated by GABAergic and glycinergic transmission (Chub and
O'Donovan, 1998; Milner and Landmesser, 1999). Thus both the retina
and spinal cord can alter their normal developmental program to
compensate for the lack of activity, perhaps through a homeostatic
regulation of the firing properties of the network (O'Donovan and
Chub, 1997; Feller, 1999).
nAChR-mediated waves play a limited role in the segregation of RGC
dendrites into the adult pattern of strata
Cholinergic neurons are present in the mouse retina, and the
patterning of their projections defines the ON and OFF sublaminae very
early in retinal development (Fig. 4). This agrees with studies in
other species: cat (Dann, 1989; Mitrofanis et al., 1989), chicken (Spira et al., 1987; Layer et al., 1997), marsupials (West Greenlee et
al., 1998), rabbit (Wong and Collin, 1989), and ferret (Feller et al.,
1996). In mouse, we found that RGC dendrites are localized to the ON
and OFF sublaminae by P8 and further segregate into the five strata
that characterize the adult retina by P14 (Fig. 5). Again, this finding
is consistent with the early stratification of RGC dendrites seen in
ferret (Bodnarenko et al., 1999) and cat (Bodnarenko et al., 1995).
Although the maintenance of RGC dendritic segregation into ON and OFF
sublaminae is known to be activity-dependent (Bodnarenko and Chalupa,
1993; Wingate and Thompson, 1994; Bodnarenko et al., 1995), the absence
of spontaneous, correlated activity in the 2/ retinas did not
prevent initial segregation of RGC dendrites into the ON and OFF
sublaminae. It did delay, however, their further refinement into the
adult pattern of strata.
The ON-OFF segregation of ganglion cell dendrites is thought to be
directed by the activity of glutamatergic bipolar cells whose axon
terminals are restricted to either the ON or OFF sublaminae of the IPL
(Bodnarenko and Chalupa, 1993). In the developing cat retina,
inhibition of glutamatergic synaptic transmission from ON cone bipolar
and rod bipolar cells with intraocular injections of the metabotropic
glutamate receptor agonist 2-amino-4-phosphonobutyrate prevents the
initially diffuse population of RGC dendrites from segregating into ON
and OFF sublaminae (Bodnarenko and Chalupa, 1993; Chapman, 2000). This
failure to segregate is permanent, and functional studies of the mature
visual system reveal many RGCs exhibiting both ON and OFF responses to
light (Bisti et al., 1998).
Our findings indicate, however, that the initial segregation into ON
and OFF sublaminae may occur before bipolar cells have made functional
synapses in the IPL. In the rat retina, bipolar cell terminals,
identified by recoverin immunolabeling, segregated into the ON and OFF
sublaminae of the IPL by P8 (Gunhan-Agar et al., 2000); in the ferret
retina, this process begins at P10 and is complete by P15 (Miller et
al., 1999). In ferret, the appearance of bipolar cell axon terminals in
the IPL coincides with the transition of spontaneous, correlated
activity from an nAChR- to a glutamate receptor-mediated process (Wong
et al., 2000). Assuming that in mouse retina the developmental switch
from nAChR-mediated to ionotropic glutamate receptor-mediated activity
coincides with the maturation of glutamatergic bipolar cell processes,
these processes should appear at approximately P11. Because the initial
segregation into ON and OFF sublaminae in normal and 2/ mice
occurs by P8, it must occur independently of both nAChR-mediated and
bipolar cell-mediated activity. This is consistent with the recent
finding that mice deficient in the predominant bipolar cell
metabotropic glutamate receptor mGluR6 have normal segregation of RGC
dendrites (Tagawa et al., 1999).
What then drives the initial RGC dendritic segregation? One possibility
is that activation of ionotropic glutamate receptors during the first
postnatal week (Fig. 3C) is necessary for RGC dendrites to
migrate into the appropriate sublaminae (Wong and Wong, 2000). However,
because the cholinergic circuitry is organized so early in development,
it seems likely that it plays some role in organizing synaptic
connections in the inner retina. The earliest markers of ON and OFF
sublaminae found in the chick IPL are the cholinergic
synapse-associated enzymes butrylcholinesterase and acetylcholinesterase. These molecules appear very early in embryonic development when the IPL first forms (Layer et al., 1997) and may serve
as signals for the initial RGC dendritic stratification. In turtle
retina, choline acetyltransferase also precedes the formation of
synapses (Nguyen et al., 2000). The idea that molecules can define
sublaminae in the IPL could also explain bipolar cell stratification in
the absence of postsynaptic targets (Gunhan-Agar et al., 2000). If
cholinergic synapses are the scaffolding around which the ON and OFF
sublaminae are built, the finding that ON-OFF segregation occurs in
mice lacking either 3 or 2 nAChR subunits suggests that
lamination is guided either by cholinergic transmission mediated by
muscarinic AChRs (Zhou and Zhao, 2000) by non-3, -2, or -4
nAChRs or by an activity-independent mechanism.
We found that cholinergic transmission did play a role in the
refinement of RGC dendritic arbors into the five distinct strata that
define the adult IPL. The delay of this refinement in P8 2/
retinas may result directly from a lack of cholinergic inputs onto RGC
dendrites or indirectly from a reduced cholinergic drive onto
glutamatergic bipolar cells (Hamassaki-Britto et al., 1994). The delay
we observed in the stratification of RGCs in P8 2/ mice was
eliminated by P14, indicating that spontaneous activity mediated by
ionotropic glutamate receptors is sufficient to drive the
stratification of RGC dendrites into their adult pattern.
In summary, we have characterized the changes in the spontaneous
activity and anatomy of retinas from mice lacking 3, 2, or 2
and 4 subunits of the nAChR. Together, our findings indicate that
nAChR-mediated spontaneous activity plays a distinct role in the normal
developmental progression of functional circuits that mediate waves and
a more limited role in the formation of the ON-OFF anatomical circuits
in the inner retina.
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FOOTNOTES |
Received April 14, 2000; revised June 27, 2000; accepted July 26, 2000.
This work was supported by National Institutes of Health Intramural
Research Program and National Institutes of Health Grant DA-12661 (W.X. and A.B.). A.B. and B.J.H. were supported by the Howard
Hughes Medical Institute-National Institutes of Health Research
Scholars Program. J.H.S. was supported by a National Institute of
General Medical Sciences pharmacology research associate training
fellowship. We thank the National Institute of Neurological Disorders
and Stroke Light Imaging Facility for use of a confocal microscope,
Rukmini Mirotznik for assistance with anatomical analysis, R. Mirotznik, Ralph Nelson, and Jeff Diamond for critical reading of this
manuscript, Margaret Coulombe for assistance with genotyping, Michael
McIntosh for kindly donating the conotoxins, and Avi orr-Urtreger for
providing access to the 4/ mouse.
Correspondence should be addressed to Marla B. Feller, Synapse
Formation and Function Unit, National Institute of Neurological Disorders and Stroke, National Institutes of Health, 36 Convent Drive,
36/5B16, Bethesda, MD 20892-4126. E-mail: marla{at}codon.nih.gov.
| |
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TOP
ABSTRACT
INTRODUCTION
