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The Journal of Neuroscience, July 1, 2002, 22(13):5492-5504
Morphological and Functional Abnormalities in the Inner Retina of
the rd/rd Mouse
Enrica
Strettoi1,
Vittorio
Porciatti1,
Benedetto
Falsini2,
Vincenzo
Pignatelli1, and
Chiara
Rossi1
1 Istituto di Neurofisiologia del Consiglio Nazionale
delle Ricerche, 56100 Pisa, Italy, 2 Bascom Palmer Eye
Institute, Miami, Florida 33101, and 3 Istituto di
Oftalmologia, Università Cattolica, 00168 Roma, Italy
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ABSTRACT |
We investigated the effects of photoreceptor degeneration on the
anatomy and physiology of inner retinal neurons in a mouse model of
retinitis pigmentosa, the retinal degeneration (rd) mutant mouse.
Although there is a general assumption that the inner retinal cells do
not suffer from photoreceptor death, we confirmed major changes both
accompanying and after this process. Changes include sprouting of
horizontal cells, lack of development of dendrites of rod bipolar
cells, and progressive atrophy of dendrites in cone bipolar
cells. Electrophysiological recordings demonstrate a selective
impairment of second-order neurons that is not predictable on the basis
of a pure photoreceptor dysfunction. Our data point out the necessity
to prove integrity of the inner retina before attempting restoring
visual function through photoreceptor intervention. This is even more
important when considering that although intervention can be performed
before the onset of any symptoms in animals carrying inherited
retinopathies, this is obviously not true for human subjects.
Key words:
bipolar cells; dendritic remodeling; sprouting; retinitis
pigmentosa; ERG; morphology
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INTRODUCTION |
Retinitis pigmentosa (RP) leads to
blindness in thousands of people worldwide every year. Few if any
treatments are available for this pathological condition. Among natural
mutants, the retinal degeneration (rd)/rd mouse displays a form of
hereditary retinal degeneration that is considered a model for human
RP. In this mouse, rods begin degenerating around postnatal day (P) 8, followed by cones, and by 4 weeks virtually no photoreceptors are left (Carter-Dawson et al., 1978 ; Jimenez et al., 1996). Farber and Lolley
(1974) and Lolley and Farber (1976) showed that degeneration is
preceded by retinal accumulation of cGMP and is correlated with
deficient activity of the rod photoreceptor cGMP-phosphodiesterase (Bowes et al., 1990). Much of the studies devoted to the rd/rd mouse
have focused on the genetics, biochemistry, and morphology of
degenerating photoreceptors, with minor attention to possible effects
on inner retinal cells. However, classic and recent literature proves
that inner retinal neurons react to photoreceptor degeneration: a study
on retinas of human RP donors (Santos et al., 1997) showed loss of
inner nuclear layer (INL) and ganglion cell layer cells. Decreases in
the number of ganglion cells (Stone et al., 1992), as well as
alterations of the remaining rods and cones (Li et al., 1995), have
been reported previously. In rat models of degeneration, histochemical
changes in the inner plexiform layer (IPL) have been described
(Eisenfeld et al., 1984; Lund et al., 1997), although inner
retinal signaling remains sensitive (Bush et al., 1995). In rd mice,
immunoreactivity for L7, a marker for on-bipolar cells, shows
progressive changes (Ogilvie et al., 1997): Müller glia cells
(Sheedlo et al., 1995; Chaitin et al., 1996) and rod bipolar cells
(Kwan et al., 1999) are altered, as well as GABA and GABA-receptor immunoreactivity in the INL (Yazulla et al., 1997). Studies on mice
with a different photoreceptor alteration ("retinal degeneration slow" or rds mice) have shown that at late stages of photoreceptor loss, the INL becomes thinner and irregular (Sanyal et al., 1980), whereas the morphology of surviving rods becomes altered (Jansen and
Sanyal, 1992). In certain forms of RP, there are morphological and
electrophysiological abnormalities in postreceptoral cells (Fariss et
al., 2000). Retinal electrophysiological studies of RP patients
(Cidecyian and Jacobson, 1993; Falsini et al., 1994) indicate
dysfunctions at or beyond the receptor synapse.
Recently it has been shown that mutated photoreceptors can be rescued
by various approaches, including somatic and vector-based gene therapy
(Bennett et al., 1996, 1998; Jomary et al., 1997; Ali et al.,
2000; Acland et al., 2001; Takahasi et al., 1999), administration of
survival factors (Frasson et al., 1999; Ogilvie et al., 2000), and
transplantation of intact retinal sheets (Gouras et al., 1994; Woch et
al., 2001). The increasing efficacy of these strategies demands an
assessment of the long-term preservation of the inner retinal structure
despite the loss of photoreceptors: partial rescue of photoreceptors
would be doomed to failure if inner retinal layers had been
irreversibly affected by even partial photoreceptor loss.
The central purpose of our study was to test the integrity of the inner
retina in the rd/rd mutant mouse. We used anatomical and
electrophysiological techniques to reveal modifications in the inner
retina after photoreceptor loss. We have shown previously that in the
rd/rd mutant, rod bipolar and horizontal cells undergo profound
morphological alterations (Strettoi and Pignatelli, 2000). Here, we
describe additional alterations in cone bipolar cells at later stages
of photoreceptor degeneration, as well as functional abnormalities that
are detectable very early in the animal's life. At least some types of
amacrine cells, on the contrary, appear normal. Overall, we provide a
systematic analysis of the rd/rd retina structure and function that
casts doubt on the long-held dogma according to which inner
retinal neurons are relatively insensitive to photoreceptor degeneration.
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MATERIALS AND METHODS |
All experimental procedures were done in compliance with the
Association for Research in Vision and Ophthalmology Statement for the
Use of Animals in Ophthalmology and Vision Research and with the rules
for animal experimentation of the Italian Ministry of Health.
Animals
rd/rd mutant mice of the C3HPde strain and wild-type (wt) mice
of the C57BL/6J strain were used for the present study. Animals were
kept in an artificial 12 hr light/dark cycle, with the illumination level below 60 photopic lux.
Histology
Immunocytochemistry. Adult (1-3 months) mice were
anesthetized with an intraperitoneal injection of avertin (15 mg/kg)
and perfused transcardially with 4% paraformaldehyde (PAF) in 0.1 M phosphate buffer. Young animals (10-20 d) were
enucleated under anesthesia, and their eyes were immersion fixed in
PAF. For immunocytochemistry (ICCH) on sections, whole eyes were
sucrose infiltrated, frozen, and serially sectioned at 14 µm on a
cryostat. Sections from groups of three age-matched animals of the same
strain were mounted on the same slide to ensure minimal differences in
tissue handling and allow ready comparisons. ICCH was also performed on
retinal whole mounts after retinal isolation from the eyecup following fixation. ICCH protocols were described in Strettoi and Pignatelli (2000). Primary antibodies were as follows: mouse and rabbit
anti-protein kinase C  (PKC; Sigma); rabbit anti-L7 (from Dr. C. Cepko, Harvard Medical School, Boston, MA); rabbit anti-mGluR6
(from Dr. S. Nakanishi, Osaka University, Osaka, Japan); mouse
and rabbit anti-calbindin D-28k [Swant; Haverkamp and Wassle (2000)];
mouse and rabbit anti-caldendrin (from Dr. M. R. Kreutz, Leibniz
Institute for Neurobiology, Magdeburg, Germany); rabbit
anti-neurokinin 3 (NK3, Nova Biological); mouse anti-Go (Chemicon); mouse and rabbit
anti-neurofilament 200 kDa (clone N52; Sigma); mouse anti-glutamine
synthetase (Chemicon); rabbit anti-glial fibrillary acidic protein
(GFAP, Sigma); goat anti-choline acetyl transferase (ChAT; Chemicon);
rabbit anti-tyrosine hydroxylase (TH; Chemicon); and rabbit
anti-disabled 1 (from Dr. T. Curran, St. Jude Children's Research
Hospital, Memphis, TN). A synopsis of all the antibodies used is
shown in Table 1. Secondary antibodies
were anti-mouse-Oregon Green 488 and anti-rabbit-Alexa 568 (Molecular
Probes; used for single and double staining) or anti-rabbit and
anti-goat conjugated with Cy3 (Sigma; used for single staining).
Retinal preparations were examined with a Leica TCS-NT confocal
microscope equipped with a krypton-argon laser. To compare retinal cell
morphologies in wild-type and rd preparations, the following parameters
were matched: age; fixation and immunostaining protocols; retinal
eccentricity, measured as a distance from the optic nerve head;
magnification, pinhole size, gain and offset of the confocal
microscope; and thickness of extended-focus images obtained at the
confocal. Files were saved in TIFF format and exported on an image
analyzer (MCI4, Imaging) for morphometry. Three to four littermates for
each strain for each age (P10, P20, P30, P90) were used for ICCH on
vertical sections and reacted with the full panel of antibodies listed
above; whole-mount ICCH was performed on P10 and P20 retinas to reveal
calbindin D and neurofilaments (three retinas, for each age, for each
strain of mice). Eighteen retinas (9 wt and 9 rd) were used for
whole-mount ICCH for the following antibodies:
PKC/Go, TH, and ChAT. Counts of TH-positive cells
were performed on photographic montages of the whole extensions of four
retinas for each strain of mice at P90. Counts of ChAT-positive
amacrine cells were performed on three retinas for each strain of mice
at P90, following the methods described in Galli-Resta et al. (2000). A
total of 50 animals were used for ICCH. Quantitative analysis of
sprouts emerging from cell bodies and dendrites of horizontal cells at
P10 was performed as follows: sections from six retinas, three from rd and three from wild-type mice, aged P15, were reacted in parallel and
stained with calbindin D antibodies. Images of identical size from
three adjacent sections from each retina at similar eccentricities were
obtained at the confocal microscope and exported on the image analyzer.
Sprouts encountered within a linear extension of 2.5 mm were counted
systematically. Counts from rd and wt were compared.
Electron microscopy. Two additional mice (1 rd and 1 wt), 3 months old, were anesthetized and perfusion fixed for electron microscopy with a mixture of 2.5% glutaraldehyde and 2%
paraformaldehyde in buffer. After enucleations, retinas were isolated,
dissected into small blocks, postfixed with osmium tetroxide, bloc
stained with uranyl acetate, dehydrated in ethanol, and embedded in
Epon/Araldite. Ultrathin sections were obtained from central retinal
areas, collected on grids, and examined with a Jeol 1200EX II electron
microscope. Photographs were obtained of rod bipolar axonal endings in
sublamina 5 of the inner plexiform layer. Negatives were printed at a
final magnification of 25,000×. Rod bipolar axonal endings were
identified by their typical morphology, analyzed with respect to
synaptic contacts, and measured along their major axis. A total of 20 endings from wt and an equal number from rd retinas were examined.
Gene-gun labeling. Single-cell staining with DiI and DiO was
performed with a helium gene gun (Bio-Rad) according to the
protocol described in Gan et al. (2000). Briefly, the gene gun
was loaded with single DiI and DiO bullets and set up at a pressure of
60-80 psi. Retinas were dissected from quickly enucleated eyes of
three wt and three rd animals that were 3 months old. Retinas were kept in ice-cold, oxygenated saline solution for 5 min and then were placed
receptor-side up on Millipore filter paper, dried, and exposed to a
single shooting of dye. After successful stain, retinas were fixed for
30 min in 2% PAF, rinsed in buffer, and examined at the confocal
microscope. To expose inner retinal neurons from wt retinas before
shooting them with the gene gun, the outer layers were removed by
gentle stripping with Millipore filter paper that was placed on the
outer retinal surface. A total number of 9 rd and 3 wt axonal
arborizations of horizontal cells were examined.
Electrophysiology
Twenty-six rd/rd mice, ages 12-14 d to 3.5 months, and 24 wt
mice as controls in the same age range were tested. Additional recordings were performed on mice expressing the rd mutation on the C57
background, obtained by back-crossing for more than eight generations.
No differences were detected between these rd mutants and those from
the C3H strain.
Animals were dark adapted overnight and anesthetized under dim light;
their pupils were dilated with 1% atropine (Tubilux Pharmaceuticals).
ERGs were recorded by corneal Ag-AgCl rings inserted below the eyelids
in response to 50 µsec broad-band white flashes of varying intensity
delivered by a standard Ganzfeld stimulator (Lace Elettronica, Pisa,
Italy). Background light for light-adapted recordings was by the same
Ganzfeld system. The intensity of stimulation and background was
controlled with neutral density filters. Flash intensity varied between
0.2 and 20 photopic cd/m2 per second.
Background intensity was set at 12 cd/m2,
except for one experiment in which it was changed to between 12 and 600 cd/m2. At the position occupied by
the mouse eye during experiments, directional variations of light
intensity did not exceed ±15% of the average intensity.
Electrical signals were differentially amplified 5000-fold with a high
common mode rejection amplifier (Lace Elettronica), bandpass filtered
between 0.1 and 1000 Hz, and digitized on-line at 2 kHz with 12 bit
accuracy. Digital signals were signal averaged (up to 50 waveforms,
depending on the noise level) and stored on a PC disk. Partial blocks
(two to six packets) of the total average were also stored to verify
reproducibility of waveforms. The interval between repeat flashes was
set to allow complete recovery of the b-wave between flashes,
except for one series of experiments in which responses were collected
at different stimulus repetition rates (flicker) between 0.1 and 20 Hz.
Electroretinographic a- and b-waves were quantified in their
amplitude (baseline to negative a-wave peak, a-wave to positive b-wave
peak) and time-to-peak (from stimulus onset to negative a-wave or
positive b-wave peak). For b-wave analysis, oscillatory potentials
(Peachey et al., 1993; Lyubarsky et al., 1999) were removed by
digital filtering. The light-intensity dependence of the a- and b-wave
amplitudes, measured at fixed times after stimulus onset, was
determined (Robson and Frishman, 1995, 1996; Rohrer et al., 1999).
Normalized initial slopes (Rohrer et al., 1999) of both ERG components
were also estimated and plotted as a function of light intensity. The
initial slope was measured as the slope of the tangent that best fits
the initial decline (for the a-wave) or rise (for the b-wave) of the
normalized waveform. The results were averaged, and comparisons were
made among averaged values. Errors are presented as SDs. To determine
statistical significance, Student's two-tailed t test or
ANOVA was used; p < 0.05 was considered statistically significant.
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RESULTS |
Anatomy
We compared systematically rod and cone bipolar cells,
horizontal cells, Müller glial cells, and some types of amacrine
cells of rd and wt retinas from P10 to P90.
On P10, many rows of photoreceptors are still present in the rd retina,
although their death process is actively taking place. Synaptogenesis
is effective in both plexiform layers. Most of the cell types examined
at this age appear indistinguishable from their wt counterparts;
namely, the dendrites of rod bipolar cells are very similar in wt and
rd, on P10, and axonal arborizations of rod bipolar cells, in both
strains, appear to be constituted of large clusters of small
varicosities, extending into sublaminas 4 and 5 of the IPL. We have
shown previously (Strettoi and Pignatelli, 2000) that the metabotropic
glutamate receptor, mGluR6, normally placed at the dendritic tips of
rod bipolars and depolarizing cone bipolars (Vardi et al., 2000), has a
distribution typical of the immature cells: staining is present in cell
bodies, in dendrites, and occasionally in axons of bipolar cells.
Horizontal cell bodies and axonal complexes appear normal.
Go (labeling depolarizing bipolar cells) (Vardi, 1998)
and caldendrin (revealing subtypes of cone bipolar cells) (Haverkamp and Wassle, 2000) display a normal distribution. Glutamine synthetase, a cell-specific enzyme of Müller cells, reveals the full profiles of Müller cells, whereas immunoreactivity for GFAP is absent from them.
On P15, a difference in the thickness of the photoreceptor layer is
evident between wt and rd retinas. Death of photoreceptors in the rd
has reduced the outer nuclear layer (ONL) to approximately six rows of
photoreceptor nuclei. Some modifications start to become evident among
second-order neurons. In particular, neurofilament and calbindin
immunocytochemistry reveal sprouting of processes from horizontal
cells, which are mostly originating from processes emerging from axonal
complexes (Fig. 1). Sprouts are
represented by long thin neurites directed toward the IPL. Quantitative
analysis of sections stained with calbindin D antibodies reveal that
sprouts in the rd retina are 10 times more numerous than in the retina of the wt, in which they are found occasionally (Fig.
2).
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Figure 1.
Early modifications in horizontal cells.
A, B, Vertical sections of P15 retinas,
wt and rd. Red labeling indicates calbindin.
Green labeling indicates neurofilament antibodies. A
rich complement of neurites emerges from the axonal complexes
of horizontal cells in the retina of the mutant mouse
(arrows in B) and ramifies in the inner
nuclear layer (inl). C (normal
retina) and D (rd retina) show whole-mount preparations
from animals at P19. Staining is the same as above. At this
developmental stage, it is already evident that the axonal
arborizations of horizontal cells, stained in green, are
hypertrophic in the rd and form a loose meshwork of processes in the
outer plexiform layer of the retina.
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Figure 2.
Horizontal cell sprouting at P15. Counts refer to
sprouts encountered within a linear extension of 120 µm. Data are
shown as averages with SEs. The high number of ectopic processes in the
mutant is evident as compared with the normal retina.
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Müller cells display signs of hyper-reactivity because they label
for GFAP. Upregulation of GFAP has been described previously in other
forms of retinal degeneration as a sign of glial reaction (Sheedlo et
al., 1995; de Raad et al., 1996; Wang et al., 2000; Zeng et al.,
2000).
At this age, other cell types (rod and cone bipolar
cells and dopaminergic, cholinergic, and AII amacrines, which represent the major output neurons of rod bipolar cells) appear normal.
P18-P20
Only scattered photoreceptor nuclei are left in the ONL of the rd
mouse retina. At this age, synaptogenesis is completed (Blanks et al.,
1974a,b; Horsburgh and Sefton, 1987). Major changes are evident
in the retina of the rd: dendrites of rod bipolar cells have
disappeared from the central retina, and in the periphery, their growth
has been arrested. As a consequence, mGluR6 has become spatially
disorganized. Immunoreactivity appears clustered in the OPL, whereas
persistent labeling of axons is mostly evident in the INL (data not
shown). Rod bipolar axonal endings are unchanged as compared
with P10 in the rd. In the wt, on the contrary, they have grown
noticeably to reach the adult size (Fig.
3). Horizontal cell bodies are still
normal, whereas axonal arborizations have undergone further
modifications. This is mostly visible in whole-mount retinal
preparations reacted with antibodies against neurofilaments (Fig. 1).
Although processes of axonal complexes form a regular spider web with
tight meshes in the wt, the same processes appear hypertrophic in the
rd, and at the same time they cover poorly the retinal surface as a
loose net. Finally, although the general morphology of Müller
cells is normal as revealed by glutamine synthetase ICCH, there
is still increased reactivity for GFAP. Go and
caldendrin are still very similar to normal.
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Figure 3.
Rod bipolar endings in the rd
(left) and wt (right) retinas, at various
developmental stages. PKC staining reveals an arrested development in
the morphology of axonal arborizations of rod bipolar cells. At P11,
endings are indistinguishable in the two strains. At P19, the growth
that has taken place in the wt is already evident compared with the
nonvaried size in the rd. In the adult animal, large varicose endings
in the wt are paralleled by atrophic varicosities in the rd
(arrows in C, G). Electron microscopy
(D, H) reveals that single axonal
endings are smaller in the rd and also carry synaptic ribbons
(rb) of anomalous round shape, recalling the morphology
found at immature synapses.
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P30
Almost no rod photoreceptors are left by this stage in the rd
retina (Jimenez et al., 1996; LaVail et al., 1997). Leftover dendrites
of rod bipolars, particularly from the peripheral retina, have
undergone progressive retraction. There is also a visible difference in
size between single axonal endings of rod bipolars in rd and wt. This
is confirmed by electron microscopy performed at later stages.
Individual rod bipolar endings, measured in sublamina 5 of the IPL, are
noticeably smaller in the rd as compared with the wt (2.2 vs
3.5 µm; n = 20; SE = 1 µm). In addition,
synaptic ribbons are smaller and ball shaped (Fig.
3D,H). These ultrastructural features are typical of immature bipolar endings. Overall, rod bipolars
in the rd retina appear frozen in a late developmental stage.
As reported in a previous paper (Strettoi and Pignatelli, 2000), there
is a decreased immunoreactivity (IR) for mGluR6, which is condensed in
irregular clusters in the OPL, most probably corresponding to dendrites
of depolarizing cone bipolars. There is persistent immunoreactivity in
axons of bipolar cells in the rd.
ICCH for Go labels both rod and depolarizing cone
bipolars (Vardi, 1998). Thus, double staining with this antibody and
PKC is necessary to distinguish between cellular types. In the wt, regularly spaced spherical formations appear in the OPL. They exhibit
Go-IR but lack PKC-IR (Fig.
4A,B),
and they correspond to apical dendrites of depolarizing cone bipolars,
entering the synaptic pedicles of cone photoreceptor to establish
contacts in the OPL. Cone bipolar staining reveals differences, because in the rd it appears less regularly organized in space, with clustered dendrites in the OPL. The fine geometry of apical dendrites has been
totally lost in the rd by P30 (Fig. 4C).
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Figure 4.
Dendritic changes in depolarizing cone
bipolars and rod bipolars, revealed by Go
(green) and PKC (red) antibodies.
In the retina of the wt (A), green
staining in the OPL has the form of dots,
corresponding to the apical dendrites of bipolar cells entering the
synaptic pedicles ofindividual cones (arrow). Dendrites form a
continuous layer. Dendrites of rod bipolars (RB),
labeled by both antibodies, appear orange-yellow
(B). In the rd (C), both
the green layer and the yellow dendrites
have disappeared from the outer plexiform layer
(opl). Animals are 3 months old.
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Horizontal cell bodies are still regularly arranged in space, but
axonal complexes are very poorly organized, with uneven, large holes
formed by their loose processes in the OPL. At the single-cell level,
as shown by gene-gun staining with carbocyanine dyes (Fig.
5), this corresponds both to hypertrophy
of individual, large-size processes and to complete loss of fine-size
dendrites, which are normally postsynaptic to rods.
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Figure 5.
Late-stage modifications of horizontal cell axonal
arbors. Shown are single axonal arborizations of adult rd
(left) and wt (right) retinas, stained by
gene-gun delivery of DiI. The enlargement of both the whole
arborization in the rd and the hypertrophy of single, large-size
processes are evident. Thin ramifications have been lost.
Arrows point to axons.
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Caldendrin immunostaining (Fig.
6A,B)
and NK3 labeling (Fig. 6C,D) also reveal a
progressive retraction of cone bipolar dendrites in the OPL, because
the normal thin layer, well evident in the retina of the wt, has been
drastically reduced in the retina of the rd. GFAP hyper-reactivity, on
the contrary, has been reduced in Müller cells.
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Figure 6.
Dendritic loss in selective cone bipolars types.
Caldendrin staining reveals a variety of both on and off cone bipolars,
the dendrites of which form a continuous, thin layer in the outer
plexiform layer (opl) of the wt
(A, arrows). In the adult rd
(B), at later stages of photoreceptor
degeneration, this layer has totally disappeared, whereas the intensity
of cell body staining has remained unchanged. A similar decrement of
dendritic arbors is revealed by NK3 staining, shown in C
for the retina of the wt and in D for that of the rd,
that labels one variety of cone bipolar cells, the axons of which
ramify in the outer portion of the IPL
(ipl).
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P90
At this late stage of photoreceptor degeneration, all of the
second-order neurons that we have examined show major alterations (Figs. 3, 4, 6). Rod bipolars have totally lost even the few dendrites that had developed successfully. Cone bipolars (belonging both to the "on" and to the "off" physiological varieties) also
lost their dendritic complements, as shown by caldendrin, NK3,
and Go immunostaining. Horizontal cells bodies, as well
as axonal arborizations, are hypertrophic, whereas thin processes,
emerging either from bodies or axonal endings, have been lost. We
have shown previously that by this stage there is a loss of both rod bipolars and horizontal cells from the central retina, both reaching 30% (Strettoi and Pignatelli, 2000).
At all the ages examined, we found no changes in the morphology and
organization of three of the best-characterized types of amacrine
cells: starburst cholinergic amacrines, dopaminergic amacrines, and AII
amacrines. Starburst amacrines are large-field cells that occur in two
mirror-symmetric populations, the cell bodies of which are located in
the inner nuclear layer and the ganglion cell layer, with dendrites
forming two bands in the outer and inner third of the IPL, respectively
(Famiglietti, 1983). Their number has been estimated for the retina of
various mammals, including the mouse (Jeon et al., 1998). Their general
morphology and pattern of stratification do not vary in the retina of
rd mice up to 3 months of age (data not shown). Their number also remains unchanged (16,174 ± 415 cells in the rd vs 16,869 ± 400 cells found in the wt).
Dopaminergic amacrines are interplexiform cells: they have wide
dendritic arbors that ramify extensively in the outermost lamina of the
IPL. From these dendrites, a plexus of radially oriented processes
originates and runs toward the outer retina, to end freely in the OPL.
Dopaminergic amacrine cells are present in the retina in very low
number; there are 450 cells in the retina of the mouse (Gustincich et
al., 1997). We found a comparable number in the retina of the rd (452 cells per retina; SE ± 30; four retinas sampled,). Their
morphology was also normal in the retinas of rd mutant mice (data not shown).
Finally, AII amacrines represent the largest population of amacrine
cells in the mammalian retina. They can be labeled by means of disabled
3 antibodies (Rice and Curran, 2000). Because they receive a major
synaptic input from rod bipolar cells (Strettoi et al., 1992), we
expected to find some abnormalities in this type of amacrine as a
secondary effect of morphological variations of rod bipolar cells.
However, their general morphological features appeared well preserved
at all the ages tested (Fig. 7). We
cannot exclude the possibility, however, that changes in their number or dendritic organization occur later in time.
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Figure 7.
Vertical sections from wt
(A) and rd (B) retinas,
reacted with antibodies to the protein disabled 1. AII amacrine cells
are labeled. These are characteristic cells, which display
bi-stratified dendrites that span both the outer and inner halves of
the IPL (ipl). Their morphology is normal in the
rd.
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Electrophysiology
No electroretinographic responses at flash
intensities below cone threshold could be elicited at any age in the rd
mice. Therefore, an appropriate comparison between wt and rd mouse ERGs
was attainable only for cone-mediated responses. It has been shown
previously that for adult mice, cone-mediated ERGs can be isolated by
suppressing rod circulating current by means of a steady light-adapting
background (Peachey et al., 1993). It has also been demonstrated (Pugh
et al., 1998; Lyubarsky et al., 1999) that a background intensity producing 4000-6000 photoisomerizations per rod is capable of suppressing >90% of the rod circulating current. This background, however, could not have been bright enough to suppress the circulating current of immature mouse rods, the sensitivity of which is known to be
significantly lower than that attained in adult life (Fulton and
Rushton, 1978). In preliminary experiments, it was found that a
background of 12 photopic cd/m2 almost
completely eliminated rod-mediated a-waves in (P15) dark-adapted ERG
recordings, leaving a residual a-wave, the kinetic characteristics of
which could be ascribed to the suppression of cone circulating current
(Lyubarsky et al., 1999). Additional experiments showed that this
cone-mediated a-wave was similar in shape and amplitude to that
recorded in the dark-adapted state in both wt and rd mice at P15, 1 sec
after the delivery of a bright conditioning flash (producing 50,000 isomerizations per rod per second) [i.e., following a procedure
similar to that reported in Lyubarsky and Pugh (1996) and Pugh et al.
(1998)]. Therefore, it was assumed that under the present experimental
conditions, the steady background used to isolate cone ERGs did not
suppress, or only minimally suppressed, wt and rd cone responses.
Figure 8A shows
representative cone-mediated ERGs obtained from a wt and an rd mouse at
P15, the age at which most reliable responses were recorded from rd
mice. It can be seen that, compared with the wt responses, rd ERGs are
reduced in amplitude and show profound changes in their waveforms. More
specifically, the b-waves are markedly slowed in latency, time-to-peak,
and duration. As a consequence of the b-wave latency increase, the
time-to-peak of the a-wave is also substantially increased, compared
with the wt a-wave. In Figure 8B these differences
are quantified as means ± SE recorded from four wt and rd mice.
It can be seen that, at all intensities, cone-mediated a-wave
amplitudes are reduced, on average, by 50% compared with wt values.
Mean b-wave amplitudes of rd mice show increasing losses as flash
intensity increases. The greatest mean loss is observed at the maximum
intensity (10× decrease) and is by far greater than that observed for
the a-wave amplitude.
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Figure 8.
A, Cone-mediated ERGs recorded at
different stimulus intensities in a wt and an rd mouse at P14-15. Note
the sluggish rd b-wave response and its prolonged latency and duration
as compared with the control animal. B, Amplitudes and
times-to-peak of cone ERG a- and b-wave components plotted as a
function of stimulus intensity for the wt and rd mice.
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An attempt was also made to compare the changes in response kinetics
with light intensity of both cone-mediated a-waves and b-waves from rd
and wt mice at P15. The leading edge of cone a-wave is thought to
reflect mostly the suppression of cone circulating current (Hood and
Birch, 1995; Smith and Lamb, 1997), although a contribution of
off-bipolar cells cannot be excluded (Sieving et al., 1994; Bush and
Sieving, 1996), whereas the b-wave is shaped by the contribution of
both on- and off-bipolar cells (Sieving et al., 1994). Figure
9A shows a-wave response
families recorded at increasing intensities (0.2, 2, and 20 photopic
cd/m2 per second) from an rd and a wt
mouse. In Figure 9B, the normalized amplitudes, measured at
fixed times after stimulus onset, and the normalized initial slopes
(see Materials and Methods) of the a-waves shown in Figure
9A are compared for both animals. The rd mouse a-waves show
reduced sensitivity (i.e., the light intensity required to reach a
given normalized amplitude is 0.8 log units greater in the rd compared
with the wt animal) and a reduced normalized initial slope, compared
with the wt a-waves. The rd normalized initial slope appears to be more
reduced at higher compared with lower flash intensities. Changes in
both parameters indicated reduced sensitivity and altered kinetics of
the rd cone a-waves compared with wt controls.
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Figure 9.
A, A-wave response families
recorded at increasing intensities (0.2, 2, and 20 photopic
cd/m2 per second) from an rd and a wt mouse.
B, Normalized amplitudes, measured at fixed times after
stimulus onset, and the normalized initial slopes (see Materials and
Methods) of the rd and control a-waves shown
A.
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|
In Figure 10A the
response families of cone-mediated b-waves recorded at increasing flash
intensities (0.2, 2, and 20 cd/m2 per
second) from one rd and one wt animal are shown. Normalized amplitudes
(measured at fixed times after stimulus onset) and initial slopes of
the same responses are compared for both animals in Figure
10B. The b-wave amplitude of the rd mouse is lower,
at the intermediate intensity, and slightly larger, at the lowest and
highest intensity, than that of wt mouse (Fig. 10B).
This behavior reflects mostly a significant departure from linearity
for the rd b-wave amplitude compared with wt amplitude that, in
agreement with other studies (Lyubarsky et al., 1999), is linear in the same intensity range. The lower slope at the two lowest intensities of
the rd, compared with the wt amplitude, may reflect a loss in light
sensitivity. The initial slope of normalized response reveals a change
in the b-wave kinetic for the rd mouse compared with the control. This
is mainly reflected by the slope difference at the highest
intensity.
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Figure 10.
A, Response families of
cone-mediated b-waves recorded at increasing flash intensities (0.2, 2, and 20 cd/m2 per second) from one rd and one wt
animal. B, Normalized amplitudes (measured at fixed
times after stimulus onset) and initial slopes of the same responses
shown in A.
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|
Flicker ERG responses obtained in the wt and rd mouse at different
temporal frequencies between 0.1 and 20 flashes per second are shown in
Figure 11A. Responses
of the rd animal are shown on a normalized scale to allow better
comparison of waveforms with those of the control. It is evident that
in the rd, unlike in the wt control, ERG responses are dominated by the
negative component, and by increasing the flash rate, the sluggish
positive response component became progressively more attenuated. This
confirms a general trend already observed for the single flash
responses, where the rd b-wave not only is attenuated but also
undergoes substantial waveform changes, being delayed and with longer
duration than that observed in the control (Fig.
11B). In addition, the flicker experiment provides
further evidence that the cone-mediated ERG abnormality in the rd mouse
involves more the b-wave than the a-wave component.
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[in a new window]
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Figure 11.
A, Cone-mediated flicker ERGs
obtained at different temporal frequencies for a wt and an rd mouse at
P15 and P14, respectively. Vertical calibration bar indicates 20 and 10 µV for the wt and rd mouse, respectively. Horizontal bar indicates 20 msec for both animals. B, Peak-to-peak b-wave amplitudes
and times-to-peak plotted as a function of temporal frequency for both
animals. C, Mean (±SD) amplitudes and times-to-peak of
the cone ERG b-wave recorded from wt and rd mice at different ages.
Adult values (P60) are also shown for comparison. n = 4-6 animals for each group and postnatal day. Note the rapid
increase in amplitude and shortening in time-to-peak in wt animals
between P14 and P18. By contrast, no changes can be observed in rd
b-waves during the same time window.
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|
Figure 11C shows the mean (±SD) amplitudes and
times-to-peak of the b-wave recorded at different postnatal
ages in rd and wt mice. In wt animals, there are progressive,
significant increases in amplitude
(F(4,18) = 21.64; p < 0.01) as well as a decline in time-to-peak
(F(4,18) = 19.8; p < 0.01). Values close to those observed in adult animals are observed at
P18. In rd mice, mean amplitudes and times-to-peak do not change
significantly with postnatal age, maintaining the values observed at
P14. Overall, these data indicate that cone-mediated b-waves of rd
mice, unlike those of wt, show no signs of maturation throughout the
second postnatal week. In rd mice, mean amplitudes and times-to-peak do
change significantly with postnatal age, maintaining the values observed at P14.
| |
DISCUSSION |
In this paper we provide conclusive evidence that inner retinal
neurons in a well established model of retinitis pigmentosa undergo a
series of impressive changes accompanying and following photoreceptor
loss. Changes fall into two groups: sprouting of processes in
horizontal cells and underdevelopment of dendrites in rod bipolar
cells, and later retraction of dendrites in cone bipolar cells. A
Müller glial reaction, in the form of GFAP transient hyperexpression, is also described. Thus, we describe early-onset alterations in the morphology of some rod-related neurons (rod bipolars, axonal arborizations of horizontal cells) and upregulation of
GFAP in Müller cells during the acute phase of rod photoreceptor death. Later, cone-connected neurons (cone bipolar cells, cell bodies
of horizontal cells) also undergo major modifications. It has to be
noted that changes in second-order neurons appear first in those cells
that establish connections with photoreceptors at the time of their
death (such as rod bipolars and axonal complexes of horizontal cells),
as though they were more vulnerable to photoreceptor degeneration at
the time of synaptogenesis. This is confirmed by the fact that AII
amacrine cells, which receive major synaptic input from rod bipolars
but establish connections in the IPL well before the onset of
photoreceptor degeneration, remain normal, like dopaminergic and
cholinergic amacrines.
The morphological changes recall closely the effects of trophic factor
deprivation in various neurons, in which one of the first consequences
of nurturing molecule removal is retraction of dendrites. The release
of diffusible molecules capable of affecting survival from normal
retinas has been proven recently (Mohand-Said et al., 1998). Most
probably, bipolar cells receive trophic information from photoreceptors
that guide and sustain the appropriate development of their dendritic
arbors. Without such trophic signals, dendrites first underdevelop and
then, inevitably, undergo atrophy.
Possibly as a consequence of uncompleted development of the outer part
of the cells, rod bipolar axonal endings also stop their growth, to
retain immature morphology. Single varicosities in the inner plexiform
layer never reach the adult size, whereas their synapses display
underdeveloped ultrastructural features. Thus, synaptogenesis is
altered not only in the OPL of the rd retina, as described in classic
studies (Blanks et al., 1974a,b), but also in the IPL. This
suggests a correlation between proper development of axonal
arborization and normal growth of dendritic arborization. Horizontal
cells, instead, change from an actively searching, sprouting status to
secondary hypertrophy and loss of thin processes. Their changes appear
different in cell bodies (connected to cones) as compared with axonal
arborizations (postsynaptic to rods). They first start to sprout and
later disorganize spatially before the cell bodies and their dendrites.
This suggests that (1) events detected in horizontal cells are related
to signals transmitted through the synaptic connections with
photoreceptors, and (2) separate districts of the same cell (cell body
vs axonal complex) receive different messages and react with different
cytoskeletal responses in time. Cone bipolar cells, as compared with
rod bipolars, succeed in reaching a mature morphology. This is
reasonable, because cone photoreceptors develop normally in the rd and
die only later as compared with rods (LaVail et al., 1997); however,
cone bipolar cells also eventually lose their normal complement of
dendrites in the OPL.
On the contrary, amacrine cells, which develop synaptic connections
before bipolar and horizontal cells, do not appear to react to
photoreceptor degeneration. It can be concluded that both short-term,
synaptogenesis-related changes and, later, modifications of
second-order neurons are quite dramatic in the rd mutation. This has to
be taken into account when devising strategies to cure RP, because they
probably have to be designed very early to prevent the secondary
effects on inner retinal cells.
Physiological modifications related to changes in the inner retina of
the rd mutant mouse are also quite striking. If a decrease in the
amplitude of cone-generated a-waves of the ERG is quite predictable on
the basis of a diminished cone response, a much larger decrease of the
b-wave can only be explained on the basis of a selective deficit of
second-order neurons. Alternatively, alterations in the efficacy of the
synaptic transmission between photoreceptors and cone bipolar cells
could be responsible. In particular, because the positive b-wave is
thought to reflect mostly the activity of depolarizing cone bipolar
cells, a decreased sensitivity (or a lower concentration) of
metabotropic glutamate receptors on the dendrites of such bipolar cells
could explain a delay and a change of shape in the response of
depolarizing neurons. Because we have observed decreased
immunoreactivity and displacement of mGluR6 in the OPL of developing rd
retinas (Strettoi and Pignatelli, 2000), this could explain the changes
demonstrated by means of ERG recordings.
Quantitative analysis of the dark-adapted a- and b-waves of the
heterozygous rd mouse was performed in the past by Low (1987). It was
found that at low stimulus intensities, a-waves were slower compared
with those of control animals, and a- and b-wave sensitivities were
increased compared with controls. The results were interpreted in terms
of reduced rates of cGMP metabolism. In Low's study, however, no
quantitative analysis of the ERG of the homozygous rd/rd mouse was
reported, and isolated cone-mediated responses were not evaluated.
Other studies (Frasson et al., 1999) evaluated the dark-adapted a- and
b-waves of the rd/rd mouse; however, no quantitative analysis of
sensitivity and kinetics of these components in the dark- or
light-adapted state were attempted.
All together, we demonstrate clearly that there are profound, early
detectable physiological and morphological changes in the inner retina
of the rd mutant mouse. These changes take place both during postnatal
development (so that they appear time related to synaptic events in the
retina) and later in life, suggesting that in different forms of
retinitis pigmentosa, usually appearing when synaptogenesis is well
completed, atrophy and apoptosis of second-order neurons have to be
expected. Thus, even in the fortunate outcome of gene therapy or
successful rescue of photoreceptors in retinal degeneration, attention
has to be paid to prevent or circumvent secondary effects on key
neurons of the inner retina. It is possible that the presence of
transplanted cells is capable, by itself, of partially reversing some
of the modifications described in second-order neurons, as shown by
some authors (Kwan et al., 1999).
| |
FOOTNOTES |
Received Dec. 27, 2001; revised March 22, 2002; accepted April 9, 2002.
This work was supported by National Institutes of Health Grant R01
EY12654 and TeleThon Project E833 to E.S. We thank Dr. S. Nakanishi for
the mGluR6 antibody, Dr. M. R. Kreutz for the caldendrin antibody,
and Dr. T. Curran for the disabled 1 antibody. We are grateful to Dr.
Rachel Wong for her contribution in applying the technique of gene-gun
staining of cells and for the gift of dye-bullets.
Correspondence should be addressed to Enrica Strettoi, Istituto di
Neurofisiologia del Consiglio Nazionale delle Ricerche, Area della
Ricerca, Via G. Moruzzi 1, 56100 Ghezzano, 56100 Pisa, Italy. E-mail:
strettoi{at}in.pi.cnr.it.
| |
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TOP
ABSTRACT
INTRODUCTION
