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The Journal of Neuroscience, July 1, 2002, 22(13):5259-5264
BRIEF COMMUNICATION
Retinogeniculate Axons Undergo Eye-Specific Segregation in the
Absence of Eye-Specific Layers
Gianna
Muir-Robinson1,
Bryan J.
Hwang2, and
Marla
B.
Feller1
1 Neurobiology Section, Biology Division, University of
California San Diego, La Jolla, California 92093, and
2 Howard Hughes Medical Institute-National
Institutes of Health Research Scholars Program, Bethesda, Maryland
20892
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ABSTRACT |
Spontaneous retinal activity mediated by cholinergic
transmission regulates the segregation of retinal ganglion cell axons in the lateral geniculate nucleus of the thalamus into
eye-specific layers. The details of how the layers form are unknown.
Mice lacking the  2 subunit of the neuronal nicotinic acetylcholine
receptor lack ACh-mediated waves and as a result, do not form
eye-specific layers at any stage of development. However, during the
second postnatal week, 2 / mice have glutamate-mediated waves.
Here we show that after the first postnatal week, even in the absence of layers, retinothalamic axons segregate into an unlayered, patchy distribution of eye-specific regions. These results indicate that spontaneous neural activity may independently regulate eye-specific segregation and the formation of layers at the developing
retinothalamic projection.
Key words:
retinogeniculate segregation; retinal waves; spontaneous
activity; visual-system development; eye-specific layers; nicotinic
receptor subunits
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INTRODUCTION |
The development of precise neural
circuitry involves activity-dependent refinement of an initially crude
set of connections. This process has been studied extensively in the
visual system of binocular animals, where retinal ganglion cell axons
from the two eyes organize into eye-specific layers in the lateral
geniculate nucleus (LGN). These layers are examples of macroscopic
structures reflecting bulk organization of thousands of axons on the
millimeter-length scale in ferrets and cats and the hundreds of
micron-length scale in mice. The proposed mechanisms underlying the
development and plasticity of these structures are based on
activity-dependent segregation of axons representing the two eyes, a
process that occurs on a much smaller length scale involving the
formation, elimination, and reorganization of individual synaptic
connections (Katz and Shatz, 1996 ; Cline, 1998; Yuste and Sur, 1999).
However, the mechanism by which these synaptic rearrangements can lead to formation of macroscopic structures has not been studied directly.
Retinal ganglion cell axons segregate from an initially intermingled
projection into distinct eye-specific layers in the LGN, a process that
is complete in mice by postnatal day 8 (P8) (Godement et al., 1984; So
et al., 1990; Upton et al., 1999; Pham et al., 2001). This segregation
is driven by spontaneous retinal activity (Penn et al., 1998), called
retinal waves (Meister et al., 1991; Wong et al., 1993), which is
mediated by cholinergic synaptic transmission in the first postnatal
week but by glutamatergic transmission in the second postnatal week
(Bansal et al., 2000; Wong et al., 2000; Zhou and Zhao, 2000;
Sernagor et al., 2001).
Transgenic mice lacking the 2 subunit of the neuronal nicotinic
acetylcholine receptor (nAChR) (Xu et al., 1999) lack ACh-mediated waves between P1 and P7 (Bansal et al., 2000). Consistent with the
requirements for retinal activity in driving the formation of
eye-specific layers, 2/ mice fail to form normal eye-specific layers (Hwang et al., 2000; Rossi et al., 2001). Based on the assumption that poor macroscopic patterning reflects a failure of an
activity-dependent segregation process, it has been argued that
retinogeniculate axons remain wholly unsegregated in 2/ mice
(Rossi et al., 2001).
Here we demonstrate that retinogeniculate axons can segregate
independently of the formation of eye-specific layers. Double-labeling of retinogeniculate terminals from both eyes reveals that although 2/ mice do not form eye-specific layers at any stage of
development, retinogeniculate projections still segregate into a patchy
distribution. These findings demonstrate that segregation of left eye
and right eye axons can be uncoupled from macroscopic patterning in the visual system.
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MATERIALS AND METHODS |
Visualization of retinogeniculate projections.
All surgeries on mouse pups were performed according to institutional
guidelines and approved protocols. Animals were anesthetized with 3.5%
isoflurane/2%O2. The eyelid was cut open to
expose the temporal portion of the eye, and 0.1-1 µl of 2% cholera
toxin in 0.2% DMSO conjugated to either fluorescein isothiocyanate
(FITC) or tetramethylrhodamine isothiocyanate (TRITC) (List
Biological, Campbell, CA) was injected into the retina with a
fine glass micropipette with a picospritzer (World Precision
Instruments, Sarasota, FL). Cholera toxin is transported throughout
retinal ganglion cells, clearly labeling axons and terminals. Mice were
analyzed after 24 hr (at P8, P14, and P28). Animals were heavily
anesthetized with an overdose of isoflurane. After fixation by cardiac
perfusion with 4% paraformaldehyde in PBS, brains were sectioned
coronally to 100 µm on a Vibratome.
Image analysis. Eight-bit tagged image file format
images were acquired for TRITC- and FITC-labeled sections of the LGN
with a CCD camera (Optronics, Goleta, CA) attached to a Zeiss
(Thornwood, NY) Axioscope 2 with a 10× objective (numerical
aperture, 0.45). The TRITC and FITC images were digitized
independently. Only the three sections that contained the largest
ipsilateral projection (corresponding the middle third of the LGN) were
analyzed. Background fluorescence was subtracted from sections using a
rolling ball filter (NIH Image) and the gray scale was renormalized so
that the range of gray-scale values was from 0 to 256. Two kinds of image analysis were then performed on these images. Because we found
that the FITC-labeled ipsilateral/TRITC-labeled contralateral projections had a consistently better signal-to-noise ratio, we conducted our comparisons on these projections. We found similar results when we used the TRITC-labeled ipsilateral/FITC-labeled contralateral projections.
First, to determine the parameters presented in Table
1 [i.e., the size of the dorsal LGN
(dLGN) and the spatial extent and location of the ipsilateral
projection], images were binarized (Metamorph software; Universal
Imaging, West Chester, PA) The boundaries of the LGN were defined as
the perimeter that excluded label in the extrageniculate optic tract
fibers, the ventral LGN, and the intrageniculate leaf. The thresholds
for both contralateral and ipsilateral axons were chosen at the
location of the gray-scale histogram of the images at which there was a
clear delineation between the remaining background and signal
fluorescence. In general, this corresponded to a threshold value of
30-50 on the range of 0-256. Statistical analyses of measurements
comparing wild-type and 2/ parameters at a given threshold were
performed using a Student's t test. In addition, we used
these binary images in P28 wild-type mice and 2/ mice to
determine the sizes of the patches of ipsilateral projections. These
"islands" were defined as the noncontiguous projections distinct
from the major contiguous projection in the dorsal portion of the LGN
that were >10 µm2. Projections that
were <10 µm2 could not be measured
reliably.
Second, the same background-subtracted and renormalized images were
analyzed for segregation of ipsilateral and contralateral axons using
Igor Software (WaveMetrics, Lake Oswego, OR). Only the regions around
the ipsilateral projection were analyzed. These methods are described
in Results. The image analysis was done blind to genotype of the mice.
The methods used for fluorescence imaging and electrophysiology have
been described previously (Bansal et al., 2000).
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RESULTS |
2/ mice fail to form eye-specific layers at any stage
of development
Mice lacking the 2 subunit of the neuronal nAChR (Xu et al.,
1999) lack ACh-mediated waves between P1 and P7 but have
glutamate-mediated waves from P8 to P13 (Bansal et al., 2000). We used
intraocular injections of two different fluorescently labeled
-cholera toxins to visualize axon terminal fields from both eyes
simultaneously in coronal sections of the LGN (Fig.
1). We compared retinogeniculate projections in wild-type and 2/ mice by characterizing the projections at P8, P14, and P28. In all wild-type cases, eye-specific regions were well defined and highly stereotyped, consistent with normal development of layers by P8. That is, contralateral axons occupied the majority of LGN territory but were strictly excluded from
the dorsomedial region where the ipsilateral cluster terminated (Fig.
1, two left columns). In contrast, in 2/ mice,
eye-specific projection patterns were always poorly formed (Fig. 1,
two right columns). Contralateral axons were present
throughout the entire LGN and were not excluded from the region
normally occupied by ipsilateral axons. Ipsilateral projections were
more diffuse than normal and arranged in an irregular pattern
throughout the dorsomedial and dorsolateral LGN. Ipsilateral axons were
highly concentrated at the dorsal pole at all ages but extended into
ventromedial regions between P14 and P28 that were normally occupied
exclusively by contralateral axons. These data are summarized in Table
1. In addition, ipsilateral axons cluster into noncontiguous islands. The size of these islands was measured from fluorescence images of P28
2/ and wild-type mice. In P28 2/ mice, there were 164 ± 13 islands ranging in size from 10 to 500 µm2 with a median size of 25 ± 2 µm2 (n = 4). In
contrast, in P28 wild-type mice, there were 55 ± 5 islands
ranging in size from 10 to 300 µm2 with
a median size of 20 ± 2 µm2
(n = 4).
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Figure 1.
Retinogeniculate projections are not organized
into eye-specific layers in 2/ mice. A pseudocolor
representation of retinogeniculate projections in wild-type and
2/ mice is shown. Projections from the ipsilateral projecting
eye were labeled with FITC-conjugated choleratoxin
(green), whereas the projections from the
contralateral eye were labeled with a TRITC-conjugated construct
(red). White corresponds to pixels for
which there is overlap between ipsilateral and contralateral axons. At
all ages, wild-type mice (two left columns) show clear
segregation of ipsilateral and contralateral axons. 2/ mice
(two right columns) have a diffuse ipsilateral
projection and no clear hole in the contralateral projection,
indicating a lack of complete segregation. Boxed regions
are shown at higher magnification to emphasize complex segregation
patterns. Scale bar, 100 µm.
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Importantly, normal layers fail to emerge in P14 or P28 2/ mice
despite the presence of normal glutamate-mediated waves in these mice
from P8 to P14 and despite visual experience from P14 to P28 (Rossi et
al., 2001). 2+/ mice were indistinguishable from wild type both in
retinal wave properties (Bansal et al., 2000) and in retinogeniculate
patterning into eye-specific layers (n = 6; data not
shown). Comparison between 2/ and wild-type Nissl-stained and
4',6'-diamidino-2-phenylindole-labeled LGN sections showed no
qualitative difference in LGN cell density or size (data not shown).
These findings indicate that nAChR signaling either in the retina
(Feller et al., 1996; Penn et al., 1998) or in the LGN (Cimino et al.,
1995; Lena and Changeux, 1999) is required for segregation of
retinogeniculate axons into eye-specific layers (Rossi et al.,
2001).
Retinogeniculate axons from the two eyes segregate into an
unlayered pattern in 2/ mice
In previous experiments, layer formation was interpreted to
reflect the success or failure of eye-specific segregation. Thus, in
experiments in which pharmacological (Penn et al., 1998) and genetic
manipulations (Upton et al., 1999; Rossi et al., 2001) prevented the
formation of normal eye-specific layers, it was concluded that
retinogeniculate axons remain wholly unsegregated. By taking advantage
of our two-color method of labeling retinal projections from the two
eyes, we found, surprisingly, that despite the lack of eye-specific
layers in 2/ mice, there was development of a patchy
eye-specific segregation of ipsilateral and contralateral fluorescent
label. Terminals in 2/ mice were largely unsegregated at P8, but
axons from the two eyes became segregated by P14, despite the
persistence of the unlayered pattern. Between P14 and P28, segregation
increased and became comparable with that seen in wild-type animals
that had well defined eye-specific layers (Fig. 1, two right
columns). Based on these findings, we hypothesize that spontaneous
activity during the second postnatal week and sensory activity in the
third and fourth postnatal weeks may drive the segregation of right and
left eye axons but is not sufficient to induce the formation of
eye-specific layers.
To quantify the development of segregation in 2/ mice, we have
computed the amount of colocalization of ipsilateral and contralateral
axons. This method is independent of the threshold delineating signal
from background for the contralateral projection. This is especially
important when examining the contralateral projection, because there
are a significant number of axons that traverse the binocular region of
the LGN, making the fluorescence level in the nonterminal-containing
regions significantly above background. Hence, changing the threshold
can significantly change the details of the projection patterns, such
as the extent of overlap of ipsilateral and contralateral projecting
axons in the binocular region of the LGN (Fig. 1).
Figure 2A contains
examples of scatter plots in which each point represents the
fluorescence intensity for each 1 µm2
pixel of the contralateral projection (Fig. 2A,
left column) versus the fluorescence intensity of the
ipsilateral projection in the same pixel (Fig. 2A,
middle column). If ipsilateral and contralateral axons are
well segregated, the individual points are inversely related (i.e.,
there is high contralateral intensity where there is low ipsilateral
intensity) (e.g., P8 wild type). In contrast, if there is a substantial
amount of overlap, the individual points have a positive correlation
(i.e., contralateral and ipsilateral intensities will be high or low
together) (e.g., P8 2/). From these examples, it is apparent
that eye-specific segregation is initially absent in 2/ mice
(P8) but emerges with subsequent development (P28).
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Figure 2.
Segregation of ipsilateral and contralateral
retinogeniculate projections. A, Fluorescence image of
an ipsilateral (left) and contralateral
(middle) projection in the same LGN section.
Right, Scatter plot of contralateral and ipsilateral
intensity for each pixel in images. Pixel resolution, 1 µm. Scale
bar, 50 µm. WT, Wild type. B,
Segregation plots compare the extent of segregation independent of
contralateral thresholds. Traces that have lower
segregation fractions represent retinogeniculate projections that are
less segregated than traces that have higher values.
Each trace is the average of four brains (3 sections per brain); error
bars represent SD. Identical results were obtained for the other side
of the brain [i.e., FITC labeling the contralateral projection and
TRITC labeling the ipsilateral projection]. C,
Comparison of the fraction of pixels representing segregated
ipsilateral fibers at a single contralateral threshold. This is the
threshold that was chosen to generate the pseudocolor images of Figure
1. At P8 and at P14, projections in 2/ mice are significantly
less segregated than those in wild-type mice (**p < 0.01). By P28, the amount of segregation in 2/ mice is
comparable with the amount seen in wild-type mice
(p > 0.05).
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A summary of the results for all P8, P14, and P28 wild-type and
2/ mice is shown in Figure 2B. These
"segregation plots" are generated by computing the fraction of
fluorescent pixels of the ipsilateral projection that contain
fluorescence signal less than a critical threshold in the corresponding
pixels of the contralateral projection. The curves correspond to the
value of this fraction as a function of all possible threshold values of the contralateral image. A contralateral threshold of 0 implies that
all pixels in the contralateral image are considered "signal;" hence all ipsilateral axons are colocalized with contralateral axons
and the resulting segregation fraction = 0. If the contralateral threshold is set at the maximum pixel value, no pixels in the contralateral image are signal; hence all ipsilateral axons are segregated and the resulting segregation fraction = 1. The extent of segregation in two different LGNs can be compared by directly comparing these fractions at each value of the contralateral threshold. For example, P8 wild-type mice have a lower segregation fraction than
P14 wild-type mice at all values of the contralateral threshold; therefore we conclude that there is less segregation at P8 than at P14.
Segregation values at a threshold of 50 are compared for demonstration
(Fig. 2C). This threshold was used to generate the pseudocolor images of Figure 1.
This segregation analysis reveals novel features of retinogeniculate
development in wild-type and 2/ mice. First, although previous
studies using monocular labeling techniques concluded that ipsilateral
and contralateral axons in wild-type animals are fully segregated by
P8, we found that they also segregate during the second postnatal week,
reaching the adult level of segregation by P14 (Fig.
2B, left). These results imply that during the first postnatal week, the gross organization of the ipsilateral projection (location along the dorsoventral axis, contiguity, and size)
are established and contralateral axons withdraw from the area occupied
by ipsilateral axons. During the second week, retinogeniculate
projections continue to segregate until there is virtually no
detectable overlap between ipsilateral and contralateral projections
(Fig. 2). Second, at P8, segregation of projections in 2/ mice
is significantly less refined than the segregation observed in
wild-type mice (Fig. 2C), indicating that in addition to
preventing gross patterning, the absence of waves in 2/ mice
prevented any eye-specific segregation. This observation suggests that
eye-specific segregation into unlayered patterns requires
nAChR-mediated waves. Third, although 2/ mice never form clear
eye-specific layers, ipsilateral and contralateral axons do segregate
(Fig. 2B, right), and this segregation
occurs between P8 and P28. Thus, by P28, the amount of segregation in 2/ mice is comparable with the amount seen in wild-type mice (Fig. 2C), although layers are absent. These results
indicate that when macroscopic organization of the projection is
disrupted as it is in 2/ mice, waves in the second postnatal
week are sufficient to drive eye-specific segregation but not
sufficient to induce eye-specific layer formation.
Glutamate-receptor-mediated waves in 2/ mice differ from
those in wild-type mice
One possible reason that waves in the second postnatal week do not
induce layer formation is that correlations in retinal ganglion cell
firing induced by these late waves are different from those of early
waves (<P7) and are not appropriate to drive macroscopic
rearrangements of axonal arbors. To address this question, we compared
the spatiotemporal properties of waves in the first and second
postnatal weeks in wild-type and 2/ mice.
Experiments were conducted on retinas isolated from newborn mice
(P0-P14) and incubated in the calcium indicator fura-2 AM. The spatial
distribution and time course of spontaneous changes in intracellular
calcium concentration in the ganglion cell layer were assessed with
real-time fluorescence imaging and represented by the fractional change
in fluorescence,  F/F (Fig.
3A). In normal mice, during
the first postnatal week, periodic changes in intracellular calcium
concentrations associated with membrane depolarizations are driven by
cholinergic synaptic inputs (Feller et al., 1996; Zhou, 1998). At P11,
retinal waves switch from an nAChR-based to a glutamate receptor-based
circuitry (Bansal et al., 2000; Wong et al., 2000; Zhou and Zhao,
2000). Compared with nAChR-mediated waves recorded in wild-type mice
during the first postnatal week, glutamate receptor-mediated waves
recorded in wild-type mice during the second postnatal week propagate
at approximately twice the velocity and depolarize individual ganglion
cells at approximately twice the frequency (Fig. 3B-D). The
waves recorded in 2/ mice during the second postnatal week are
very similar to the early waves of wild-type mice in terms of frequency
of calcium transients and velocity (Fig. 3B-D). The reason
for the immature wave dynamics in 2/ mice is unknown. However,
these data indicate that the inability of retinal waves to restore
eye-specific layers in the second postnatal week is not likely to be
attributable to differing global retinal-activity patterns.
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Figure 3.
Comparison of the spatiotemporal properties of
retinal waves in wild-type and 2/ mice A,
Fractional change in fura-2 AM fluorescence averaged over a 200 µm2 region of retinas from wild-type
(WT) mice (left traces) and
2/ mice (right traces) during the first
(top) and second (bottom) postnatal
weeks. Downward deflections indicate increases in intracellular calcium
induced by propagating retinal waves. B,
Traces from current-clamp recordings from presumptive
ganglion cells in P12 retinas from WT (left trace) and
2/ (right trace) mice. C, Summary
data comparing the interwave interval recorded with fluorescence
imaging (n = 11 control mice between P2 and P11,
n = 13 control mice between P12 and P14, and
n = 8 2/ mice between P9 and P13).
D, Summary data comparing the wavefront velocity
(n = 10 waves in 3 control mice and
n = 10 waves in 3 2/ mice).
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DISCUSSION |
We found that in mice lacking the 2 subunit of the nAChR,
retinogeniculate axons segregate in the absence of eye-specific layers.
In contrast to a contiguous layer in wild-type mice, ipsilateral projecting axons in 2/ mice are arranged as a series of small noncontiguous islands. Many previous studies of retinogeniculate development used the existence of eye-specific layers as the sole index
of retinogeniculate segregation. These findings demonstrate that
eye-specific segregation can be dissociated from layer formation. This
dissociation has important implications for models of how neural
activity may influence retinogeniculate development.
We found that although 2/ mice lack wave activity only during
the first postnatal week, they do not form eye-specific layers at any
point during development. This suggests that the first postnatal week
may constitute a critical period for eye-specific layer formation. This
finding confirms previous pharmacological (Penn et al., 1998) and
genetic (Rossi et al., 2001) studies that indicate that cholinergic
signaling and competition between the two eyes is necessary for of
eye-specific layer formation. We found that although 2/ mice
have glutamate receptor-mediated waves after P8, this activity is not
sufficient to drive layer formation. This inability of endogenous
activity to drive layer formation is not likely attributable to
differences in the spatiotemporal pattern, because glutamate
receptor-mediated waves during the second postnatal week in 2/
mice are similar to nAChR-mediated waves during the first postnatal
week in wild-type mice (Fig. 3). A critical period is likely determined
by a functional asymmetry between ipsilateral and contralateral
projections (Crair et al., 1998), perhaps because of the timing
difference between the ingrowth of ipsilateral and contralateral
projections (Godement et al., 1984) or the transient expression and/or
recognition of requisite molecules (Corriveau et al., 1998; Feldheim et
al., 1998; Upton et al., 1999; Land and Shamalla-Hannah, 2001; Pham et
al., 2001). Although the exact mechanism remains to be determined, it
is clear that both competition between the two eyes and the level of
endogenous retinal activity are critical in establishing eye-specific
layers (Stellwagen and Shatz, 2002).
Second, we found that in the second through fourth postnatal weeks,
projections from the two eyes become segregated within the unlayered
pattern. Despite the absence of eye-specific layers in 2/ mice,
we found that beginning in the second postnatal week, retinal inputs
from the two eyes segregate. This suggests that activity patterns
distinct from nAChR-mediated retinal waves, such as those mediated by
glutamate and visual experience, can drive eye-specific segregation,
perhaps through a Hebbian process (Katz and Shatz, 1996; Cline, 1998;
Zhang and Poo, 2001). We observe segregation on a similar length scale
in wild-type mice between the ages of P8 and P14, indicating that
patchy segregation is not a compensatory artifact of the transgenic
animals. Moreover, similar patchy retinogeniculate segregation patterns
have been described in animals that have normal spontaneous retinal
activity but do not form eye-specific layers. For example, patchy,
unlayered distributions of retinogeniculate inputs form in animals that have altered numbers of retinal axons crossing at the chiasm (Guillery, 1969) and in "rewired" ferrets in which retinal input is rerouted to auditory thalamus (Angelucci et al., 1997).
Thus, the retinogeniculate projection provides a robust system in which
the mechanisms of activity-dependent segregation can be studied.
Experiments that manipulate endogenous activity patterns at different
developmental stages in both normal and 2/ mice will allow us to
determine the cellular basis of the processes that drive eye-specific
segregation and layer formation.
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FOOTNOTES |
Received Feb. 26, 2002; revised April 10, 2002; accepted April 19, 2002.
This work was supported by Klingenstein Foundation and Whitehall
Foundation grants (G.M.-R., M.B.F.) and by the Howard Hughes Medical
Institute-National Institutes of Health Research Scholars Program
(B.J.H.). We thank J. El-Maasri for technical support.
Correspondence should be addressed to Marla B. Feller, Neurobiology
Section 0357, University of California San Diego, 9500 Gilman Drive, La
Jolla, CA 92093-0357. E-mail: mfeller{at}ucsd.edu.
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ABSTRACT
INTRODUCTION
