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We estimated the volume occupied by the ipsilateral retinal projections to the dLGN in 1-month-old animals. The volume of the ipsilateral projection was significantly enlarged in MAOA-KO mice, compared to wild-type mice (Fig. 2). This was not related to changes in the total volume of the dLGN that was not significantly different (p = 0.57) in the mutants (mean ± SEM = 0.100 ± 0.007 mm3; n = 3) compared with normal mice (mean ± SEM = 0.106 ± 0.007 mm3; n = 4), indicating that 5-HT has not significantly affected the size of the target structure. Thereby, the percentage of dLGN volume occupied by ipsilateral fibers is increased from 15% in normals to 23% in mutants.
The Journal of Neuroscience, August 15, 1999, 19(16):7007-7024
Excess of Serotonin (5-HT) Alters the Segregation of Ispilateral and Contralateral Retinal Projections in Monoamine Oxidase A Knock-Out Mice: Possible Role of 5-HT Uptake in Retinal Ganglion Cells During Development
A. L. Upton1, N. Salichon2, C. Lebrand1, A. Ravary1, R. Blakely3, I. Seif2, and P. Gaspar1 1 Institut National de la Santé et de la Recherche Médicale U106, Hôpital de la Salpêtrière, 75651 Paris cedex 13, France, 2 Unité Mixte de Recherche 146, Institut Curie, 91405 Orsay, France, and 3 Department of Pharmacology, Vanderbilt University, Nashville, Tennessee 37212
ABSTRACT
TOP
ABSTRACT
INTRODUCTION
Retinal ganglion cell (RGCs) project to the ipsilateral and contralateral sides of the brain in the dorsal lateral geniculate nucleus (dLGN) and the superior colliculus (SC). Projections from both eyes are initially intermingled until postnatal day 3 (P3) but segregate into eye-specific layers by P8. We report that this segregation does not occur in monoamine oxidase A knock-out mice (MAOA-KO) that have elevated brain levels of serotonin (5-HT) and noradrenaline. The abnormal development of retinal projections can be reversed by inhibiting 5-HT synthesis from P0 to P15. We found that in MAOA-KO mice, 5-HT accumulates in a subpopulation of RGCs and axons during embryonic and early postnatal development. The RGCs do not synthesize 5-HT but reuptake the amine from the extracellular space. In both MAOA-KO and normal mice, high-affinity uptake of 5-HT and serotonin transporter (SERT) immunoreactivity are observed in retinal axons from the optic cup to retinal terminal fields in the SC and dLGN. In the dLGN, transient SERT labeling corresponds predominantly to the ipsilateral retinal projection fields. We show that, in addition to SERT, developing RGCs also transiently express the vesicular monoamine transporter gene VMAT2: thus, retinal axons could store 5-HT in synaptic vesicles and possibly use it as a borrowed neurotransmitter. Finally we show that the 5-HT-1B receptor gene is expressed by RGCs throughout the retina from E15 until adult life. Activation of this receptor is known, from previous studies, to reduce retinotectal activity; thus 5-HT in excess could inhibit activity-dependent segregation mechanisms. A hypothesis is proposed whereby, during normal development, localized SERT expression could confer specific neurotransmission properties on a subset of RGCs and could be important in the fine-tuning of retinal projections.
Key words: retinal ganglion cell; axon pruning; development; dorsal lateral geniculate; superior colliculus; monoamine oxidase; serotonin transporter; vesicular monoamine transporter; 5-HT1B receptor
INTRODUCTION
In all mammals, there is a partial crossing of the retinal projections to the visual centers that contain a binocular representation of the visual field. The development of this projection involves a series of complex processes, whereby retinal axons must choose whether to cross the midline in the optic chiasm (Godement, 1994
) and select their appropriate position within central targets of the dorsal lateral geniculate nucleus (dLGN) and superior colliculus (SC) (Cheng et al., 1995
The dLGN of ferrets and cats has been a favored model to study the mechanisms involved in the segregation of the crossed/uncrossed retinal fibers (Shatz, 1990
Competition between axons from both eyes and spontaneous patterns of neural activity generated in the retina are thought to be essential in the emergence of the adult pattern. Removal of one eye results in an expansion of the projection from the remaining eye (Insausti et al., 1984
In the present study, we examined the pattern of RGC projections in a mouse knock-out for monoamine oxidase A (MAOA), an enzyme which degrades serotonin (5-HT) and noradrenaline (NA). MAOA knock-out mice (MAOA-KO) have increased levels of brain 5-HT and NA during the first 2 weeks after birth (Cases et al., 1995
MATERIALS AND METHODS
Animals. Two strains of normal mice and two strains of MAOA-KO mice were used. C3H/HeJ and C57BL/6J inbred mice as well as MAOA-KO mice having a C3H/HeJ or C57BL/6J background were produced at the Curie Institute (Orsay, France). Wild-type mice were also purchased from a commercial source (Iffa Credo, Reims, France). MAOA-KO mice with a C3H/HeJ background were serendipitously obtained during attempts to create a transgenic mouse line constitutively expressing interferon-
(Cases et al., 1995
Drug treatments. To reduce 5-HT levels in MAOA-KO mouse pups, daily injections of parachlorophenylalanine, an inhibitor of 5-HT synthesis, were administered subcutaneously (300 mg/kg) in the neck from P0 to P15.
Enucleation of mouse pups. Mouse pups were anesthetized on ice, and a small cut was made along the line of the future opening of the eyelid. The eyeball was removed from its socket, and the optic nerve was severed. Pups were killed a minimum of 2 d later to allow the severed axons time to degenerate.
Anterograde axonal tracing by intraocular horseradish peroxidase injections. Mice were anesthetized either with a solution of 4% chloral hydrate (0.1 ml/10 gm body weight) for adults, or with a combination of ether and hypothermia for P3 and P8 pups. A solution of 30% horseradish peroxidase (HRP) (type VI; Sigma, St. Louis, MO) in physiological saline solution was injected into the vitreous chamber of the left eye using a Hamilton syringe inserted just behind the corneoscleral margin of the eye. Four microliters was injected into the left eye of adults and 1-2 µl for pups. Animals were killed 24 hr later: they were anesthetized and perfused through the aorta with ~20 ml (5 ml for pups) of saline followed by 100-200 ml (50 ml for pups) of 1% paraformaldehyde and 1.25% glutaraldehyde in 0.12 M phosphate buffer, pH 7.4. The brain was then dissected out of the animal and left in 10% sucrose overnight. The following morning each brain was sectioned on a freezing microtome into 40 µm sections collected serially in ice-cold phosphate buffer and stored for 2-24 hr before rinsing the sections for 10 min in 0.12 M acetate buffer, pH 3.3, at 4°C. They were then reacted for HRP using tetramethylbenzidine (67 mg/l) as the chromogen. The reaction was started by the addition of 0.006% H2O2. A second addition of H2O2 was made after 20 min. Slices were rinsed in 0.12 M acetate buffer, pH 3.3, at 4°C to stop the reaction. The reaction product was stabilized by a 3 min immersion in methyl salicylate before dehydration and mounting.
Computer analysis of volume of ipsilateral retinal projections to the dLGN. The area covered by HRP-labeled fibers was measured in complete series of coronal sections from normal and MAOA-KO mice at P3, P8, and P30-P34. Images of serial sections, including the dLGN, were digitized and the area of the ipsilateral projection to the dLGN was measured using a specially devised package from Imstar (Paris, France). The limits of the ipsilateral projection were either traced with the mouse on the computer screen or by setting an optical density threshold, in order to include all HRP-labeled elements (in this case, artifactual labeling such as blood vessels or precipitate was removed with the mouse). This measure does not distinguish between terminal fibers and fibers of passage and does not include isolated dispersed fibers. The volume of the labeled region for each section was calculated by multiplying the measured surface area by the thickness of the section. The total volume was obtained by adding this value for all sections containing detectable ipsilateral projections (15-20).
In a smaller sample of cases, the size of the dLGN was estimated from the same serial sections. For this, we delimited the external contours of HRP labeling in the contralateral dLGN and measured the area included within these contours: this measure includes both the area of contralateral HRP labeling and any unlabeled territory in the center.
Statistical comparisons between groups were made using Student's unpaired t test
Uptake of tritiated 5-HT. C3H mouse pups were killed on postnatal days 6, 8, 10, and 30. Some mice were enucleated 3 d beforehand. The brain was removed, and coronal slabs (4- to 5-mm-thick) including the tectum were excised and kept in preoxygenated ice-cold Krebs'-Ringer's bicarbonate buffer supplemented with 0.4% glucose for cutting into 70-µm-thick slices using a vibratome. Slices were preincubated for 10 min at 37°C, in Krebs'-Ringer's bicarbonate buffer containing 0.2% ascorbic acid and 10
7 M pargyline (Sigma) to inhibit monoamine oxidase, maintained under an atmosphere of 92% O2 and 8% CO2. 5-HT uptake was initiated by the addition of 50 µl of 5-hydroxy(G-3H) tryptamine creatinine sulfate (3H5-HT; 10-20 Ci/mmol; Amersham, Arlington Heights, IL ) per 5 ml of buffer to give a final concentration of 7 × 10
Controls were performed by the addition of the specific 5-HT transporter blocker fluoxetine 10
Fixed slices were mounted on gelatin-coated slides, air-dried for 5 min at room temperature, and dehydrated with P2O5 overnight. Sections were cleared in xylene for 1 hr, emulsion-coated with NTB2 (Eastman Kodak, Rochester, NY), and exposed for 7-10 d before developing with D-19 (Eastman Kodak).
Immunocytochemistry of 5-HT and SERT. 5-HT distribution in mice was studied using a rat monoclonal anti-5-HTantibody (1:70) from SeraLab. The specificity of this antibody has previously been described (Cases et al., 1996
Mice were deeply anesthetized and perfused through the aorta with 0.1 M sodium PBS, 4% paraformaldehyde. Brains were post-fixed for 24 hr, cryoprotected in 30% sucrose for 48 hr, frozen, and serially cut in coronal sections, 40-µm-thick. Sections were rinsed in PBS+ (PBS with 0.2% gelatin and 0.25% Triton X-100) for at least 30 min, and incubated overnight at room temperature with the primary antibodies. After washing in PBS+, sections were incubated for 2 hr with biotinylated anti-rat IgG (1:200; Amersham) for 5-HT, or biotinylated anti-rabbit IgG (1:200; Sigma) for SERT, rinsed, and incubated for 1.5 hr with the streptavidin-biotin-peroxidase complex (1:400; Amersham). After washing in Tris buffer (0.05 M, pH 7.8), peroxidase was revealed in 0.02% 3,3'-diaminobenzidine tetrahydrochloride (DAB; Sigma), 0.003% H2O2, and 0.6% nickel ammonium sulfate. Sections were mounted on gelatin-coated slides, dehydrated, and covered in Eukitt.
In situ hybridization. After cold anesthesia, whole heads of E13, E15, and E17 embryos and of P0, P1, and P4 pups were directly frozen by immersion samples in isopentane cooled to
40°C. P6, P7, P8, P9, P10, and P15 pups and adult mice were anesthetized with chloral hydrate anesthesia and decapitated. The retinas were dissected out and frozen as above, after inclusion in Tissue-tek. We obtained 15-µm-thick cryostat sections and processed for in situ hybridization.
To prepare the SERT cRNA probes, a cDNA fragment corresponding to nucleotides 1510-2009 of the transcript (Blakely et al., 1991
In situ hybridization with cRNA probes was performed on 15 µm sections through the retina and brain of whole heads flash frozen in liquid nitrogen. Tissue sections were post-fixed for 15 min in 4% paraformaldehyde, washed in 1 × PBS, acetylated, washed in 1× PBS, dehydrated, and air-dried. Sections were covered with hybridization buffer containing 5 × 104 cpm/µl of the 35S-SERT, 35S-5-HT1B, or 35S-VMAT2 probes (50 µl/slide), and incubated overnight in a humid chamber at 48°C. Washes were then performed as previously described by Lebrand et al. (1998a)
Autoradiographs were obtained by apposing the sections to Hyperfilm
Retrograde labeling of RGCs with fluorogold. To identify RGC bodies projecting either ipsilaterally or contralaterally, injections of fluorogold were made into the dLGN on one side of the brain on P1 and P30. The injections were aimed to be large enough to involve the optic tract. P1 pups were anesthetized on ice, a small incision was made in the scalp, and a Hamilton syringe was used to pierce the skull and inject 0.1 µl of 5% fluorogold in H2O. Pups were killed 3 d later and perfused with 4% paraformaldehyde. Then the entire head was post-fixed for 48 hr and transferred to sterile 10% sucrose solution overnight, before sectioning at 15 µm on a cryostat. Those brains in which it was established that the initial injection of fluorogold had been in the correct location were kept and alternate sections through the retina were used for in situ hybridization.
One-month-old mice were anesthetized with 4% chloral hydrate (10 ml/kg) and placed in a stereotaxic frame; 0.2 µl of 5% fluorogold was injected 2.5 mm posterior to the bregma, 2.2 mm lateral to the midline, and 2-3 mm deep to the surface. Animals were perfused 48 hr later. The eyes were removed, and the retina was dissected away from the pigmented epithelium before being flattened. The entire retina was then photographed at low magnification to measure the area of the ipsilateral crescent (the area containing a high density of ipsilaterally projecting RGCs), and the density of labeled RGCs was measured from three micrographs at a high magnification (500×). The number of RGCs in the ipsilateral crescent was calculated from these measurements. Labeled RGCs outside the crescent were counted individually using an ocular grid.
RESULTS
Altered retinofugal projections in adult MAOA-KO mice
Intraocular injections of HRP were used to label retinofugal axons and terminals, and the pattern of labeling was compared in complete series of coronal sections through the thalamus and SC of normal and MAOA-KO mice with a C3H/HeJ background. Results in normal C3H/HeJ mice were comparable to those previously reported from other strains (Lavail et al., 1978
Dorsal lateral geniculate nucleus
In adult C3H/HeJ mice, the projections from the two eyes appear to occupy separate territories in the dLGN. Crossed retinal fibers innervate a large part of the dLGN, but leave a "gap" in the dorsomedial area (Fig. 1B), whereas ipsilateral retinal terminals form a group of several clusters in this same dorsomedial area (Fig. 1A). The ipsilateral and contralateral projection fields seem to be complementary as in each of the 15-20 coronal sections (40-µm-thick) containing ipsilateral retinogeniculate projections, the size and position of the ipsilateral projection correspond to the size and position of the gap seen in the contralateral projection. Although some contralateral axons traverse the gap, these axons are on their way to the SC and do not have terminals in the dLGN (Bhide and Frost, 1991
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Figure 1. Intraocular injections of HRP in MAOA-KO mice reveal abnormal retinal projections to the dLGN. Sections in A and B are taken from the brain of a 1-month-old wild-type C3H/HeJ mouse and in C and D from a MAOA-KO mouse of the same age. A and C show the dLGN ipsilateral to the eye injected with HRP. B and D show the dLGN contralateral to the injected eye. A, B, In the wild-type adult, the ipsilateral projection forms dense patches close to the dorsomedial border of the dLGN (A). The contralateral projection fills most of the dLGN, but there is a clear gap that corresponds in size to the patch formed by the ipsilateral projection (B). C, D, In MAOA-KO mice, the ipsilateral projection to the thalamus covers a larger area than in wild-type mice (C); the contralateral projection occupies the entire dLGN and does not contain the characteristic gap (D). Scale bar, 128 µm.
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Figure 2. Quantification of the volume of the ipsilateral projection to the dLGN in wild-type and MAOA-KO mice. To estimate the volume of the dLGN receiving projections from the ipsilateral eye, the area of the dLGN covered by HRP reaction product in each section after intraocular injection of HRP, was measured using an image analysis program. The volume occupied by the terminals from the injected eye was calculated by multiplying the area measured by the thickness of each section (40 µm) from serial coronal sections through the dLGN. Totals are shown in cubic millimeters for wild-type C3H/HeJ mice at P3 (n = 4; mean ± SEM = 0.0102 ± 0.0013), P8 (n = 3; mean ± SEM = 0.0085 ± 0.0018), and P30 (n = 7; mean ± SEM = 0.0151 ± 0.0007) (white bars); for MAOA-KO mice at P3 (n = 4; mean ± SEM = 0.0094 ± 0.0013), P8 (n = 4; mean ± SEM = 0.0192 ± 0.0024), and P30 (n = 4; mean ± SEM = 0.0235 ± 0.0009) (black bars); and for adult MAOA-KO mice treated with PCPA during the first 15 postnatal days (n = 2; mean ± SEM = 0.01527 ± 0.0008) (striped bar). Values for MAOA-KO mice that differ significantly from wild-type are indicated by an asterisk above the bar (p 0.01, using Student's unpaired t test). At P3, the ipsilateral projections of wild-type and MAOA-KO mice occupy the same volume of the dLGN, whereas at P8 and P30, the ipsilateral projection in MAOA-KO mice is significantly larger than in wild-type animals. The ipsilateral projections of MAOA-KO mice treated with PCPA occupy the same volume as those of wild-type mice. Error bars indicate the SEM for each value.
Superior colliculus
In normal adult mice, crossed retinal projections to the SC spread throughout the stratum griseum superficiale (SGS) and stratum opticum (SO), whereas the uncrossed projection is mainly concentrated in the SO with a few scattered fibers in the deeper SGS. The distribution of the ipsilateral retinal fibers varies markedly along the rostrocaudal extent of the SC: rostrally, it forms a dense mediolateral line that becomes patchy more caudally and finally concentrates in a medial patch in the caudal two-thirds of the SC (Fig. 3). In MAOA-KO mice, no qualitative differences could be seen in the contralateral projection (data not shown), whereas the ipsilateral projection differed considerably from normal: it was more diffuse within the SO and spread further into the lower SGS (Fig. 3). Caudally, it remained distributed across the entire mediolateral axis for ~200 µm more than in the wild-type before becoming confined to the medial area. No dense clusters of labeling typical of normal ipsilateral projections were present throughout the rostrocaudal extent of the SC (Fig. 3).
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Figure 3. Abnormal retinal projections to the superior colliculus in MAOA-KO mice. One-month-old C3H/HeJ and MAOA-KO mice received intraocular HRP injections and were sacrificed 24 hr later. Rostrocaudal series of one in four, 40 µm coronal sections through the SC are illustrated. In the SC of wild-type animals, the ipsilateral projection forms discernible patches in the stratum opticum (so) and lower stratum griseum superficiale (sgs), and tends to cluster in a medial patch caudally; only scattered axons are visible in the upper SGS. In the SC of MAOA-KO mice, the ipsilateral projection appears to be more diffuse: it does not form patches in the SO, and it has a wider extension dorsally in the SGS, and caudally where it continues to be distributed mediolaterally even at caudal SC levels. Scale bar, 418 µm.
Pretectal nuclei
In the pretectal nuclei, retinal terminals formed clusters on both the ipsilateral and contralateral side. This arrangement was observed in normal as well as in MAOA-KO, but no detailed investigation of these nuclei was carried out to determine whether the size of the retinal projections was modified.Genetic background
The inbred C3H/HeJ genetic background from which the MAOA-KO are derived carries the gene for retinal degeneration causing photoreceptors to start degenerating by P15 (Sidman and Green, 1965
Development of the retinal projections in MAOA-KO mice
To identify when the abnormalities observed in MAOA-KO mice arise, we examined retinal afferents at P3 and at P8: before and after segregation has occurred in normal mice (Godement et al., 1984
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Figure 4. Development of retinal projections to the dLGN in wild-type and MAOA-KO mice. Intraocular injections of HRP into wild-type C3H/HeJ (+/+) animals aged P3 (A, B) and P8 (E, F) and MAOA-KO animals aged P3 (C, D) and P8 (G, H). A, C, E, and G show the dLGN ipsilateral to the eye injected with HRP. B, D, F, and H show the dLGN contralateral to the eye injected with HRP. A, B, In wild-type mice at P3, retinal projections fill a large proportion of the ipsilateral dLGN (A) and the entire contralateral dLGN (B). C, D, Ipsilateral and contralateral retinal projections illustrated here in MAOA-KO mice at P3 are identical to those of wild-type mice. E, F, In wild-type mice at P8, ipsilateral projections are confined to the dorsomedial part of the dLGN (E), and the contralateral projection has withdrawn from this region (F): segregation of the two inputs appears complete in normal animals. G, H, In MAOA-KO mice at P8, fibers to the ipsilateral (G) and contralateral (H) thalamus still innervate overlapping territories: segregation has failed to occur. Scale bar, 110 µm.
In normal mice at P3, the contralateral projection to the thalamus is spread throughout the dLGN (Fig. 4B), and the ipsilateral projection, although much more sparse, covers a large part of the dorsomedial dLGN (Fig. 4A). In the SC, the ipsilateral projection spreads throughout much of the SO and SGS, occupying a much larger proportion of the SC than in the adult (data not shown). At this stage, the RGC projections in MAOA-KO are indistinguishable from those of normal mice in the dLGN (Fig. 4C,D) and the SC (data not shown). By P8, the adult pattern of ipsilaterally projecting and contralaterally projecting terminals becomes apparent in normal mice (Fig. 4E,F). However in MAOA-KO, the normal loss of terminals from selective regions has not occurred, and the fibers remain intermingled (Fig. 4G,H). Quantitative evaluations in the dLGN showed that the ipsilateral projection is not significantly different in size in normal and MAOA-KO mice at P3 (Fig. 2), whereas at P8 the volume of the ipsilateral projection is significantly larger in MAOA-KO (225% of controls) (Fig. 2). This increase thus appears to be more substantial than that measured at P30 (155% of controls), suggesting that between P8 and 1 month some axonal remodeling may occur in the MAOA-KO.
Thus the development of the RGC projection pattern appears to be normal until P3, suggesting that the alterations are not related to abnormalities in the decussation of RGCs in the optic chiasm or to an abnormal target selection but to reduced segregation of contralateral and ipsilateral fibers into eye-specific regions between P3 and P8.
Number and distribution of ipsilaterally projecting RGCs
To determine whether this failure to segregate is the result of a decrease in naturally occurring cell death or an increase in aberrantly projecting RGCs, injections of the fluorescent tracer fluorogold were made in the dLGN of 1-month-old mice. The distribution of retrogradely labeled neurons was examined on flattened preparations of the retina. In normal mice, in agreement with previous descriptions, contralaterally projecting RGCs were found across the entire retina, whereas ipsilaterally projecting RGCs were found almost exclusively within a ventrotemporal crescent occupying ~20% of the retinal surface (Dräger and Olsen, 1980
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Table 1. Distribution and number of ipsilaterally projecting RGCs in wild-type and MAOA-KO mice Role of excess serotonin in the developmental abnormalities
MAOA deficiency causes increases of both 5-HT and NA levels in the brain that are most marked during development (Cases et al., 1995
Serotonin immunolabeling in RGCs and in retinal projections
When we looked for 5-HT in the brains of MAOA-KO mice (from E13 to P30), we found that 5-HT immunoreactivity could be detected all along the optic pathway from the RGC layer to axon terminals in the dLGN and the SC, between E15 and P15 (see also Cases et al., 1998
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Figure 5. 5-HT immunolabeling in RGCs and their axons during development. 5-HT immunolabeling of the developing visual pathway is readily visible in MAOA-KO mice (A-F), and faint 5-HT immunoreactivity is also detectable in retinal-like fibers in wild-type C3H/HeJ mice (G-I). 5-HT immunolabeling (DAB-nickel staining) appears dark purple. Some sections were counterstained with methyl green (blue and green) to show the histological structures. A-C, In the retina, where the pigment epithelium appears black, 5-HT immunostaining is visible in the ganglion cell bodies in the peripheral ventral retina, shown here at E17 (A, B) and P3 (C). Stained axons can be followed at the surface of the retinal ganglion cell layer (B, C) and in the optic nerve (on) (A, B). D, E, As shown in an E17 embryo, intense 5-HT immunolabeling can be followed along the visual pathway: in the optic tract (ot), in the superficial fibers coursing above the dLGN (D) and in the SC (E). F, A similar pattern is visible in MAOA-KO mice postnatally, until P15, as illustrated here at P8. There is dense 5-HT immunostaining of the entire superficial layers of the SC that ends abruptly at the junction between the superior and inferior colliculi (IC), similarly to the retinal inputs. G-I, In wild-type mice, light 5-HT immunolabeling could occasionally be detected in the visual pathway. G, A dense patch of 5-HT labeling (arrow) is visible in the dLGN of a P6 mouse. The localization of this patch resembles the location of the ipsilateral retinal projection shown in Figure 4G. H, A higher magnification of the same section shows that this patch contains a dense cluster of weakly labeled fine fibers (arrow), contrasting with the well-delineated but sparsely distributed 5-HT-positive fibers, that correspond to fibers originating in the raphe. I, 5-HT-labeled axons tipped with growth cones can be seen advancing in the optic tract in an E17 mouse. Scale bar (in F): A, 750 µm; B, C, 190 µm; D, 300 µm; E, 260 µm; F, 380 µm; G, 600 µm; H, 55 µm; I, 25 µm.
Occasionally, in wild-type C3H mice, faint 5-HT immunoreactivity could be found in axonal terminal arbors that resemble those of RGCs. During embryonic life, 5-HT immunolabeling could be detected in growth cones and at the distal ends of axons in the optic tract (Fig. 5I). During postnatal life (from P0 to P9), 5-HT immunolabeling was visible in a few cases in terminal-like fibers forming a centromedial patch in the dLGN (Fig. 5G,H) and in the SO. On the other hand, no 5-HT-labeling was detectable in the retinas or the optic nerves of wild-type mice (during both embryonic and postnatal life) unless mice had been treated with the MAOA inhibitor clorgyline (20 mg/kg per 12 hr) for 2 d beforehand (Vitalis et al., 1998
High-affinity serotonin uptake and SERT immunolocalization in retinal projections
To determine the pharmacological characteristics of the 5-HT uptake that was detected in the developing RGC, we examined uptake of tritiated 5-HT in fresh brain slices of the SC in normal mice, at P5, P8, and P10. This technique detects only high-affinity 5-HT uptake sites (using 7 × 10
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Figure 6. 5-HT* uptake in retinal fibers innervating the superior colliculus of wild-type mice. A-E, High-affinity uptake of tritiated 5-HT in 70-µm-thick vibratome slices of C3H/HeJ mice aged P10. Labeling was revealed by autoradiography after emulsion coating. A'-C', HRP labeling after injection into the left eye in a C3H/HeJ mouse aged P8. A-C illustrate three coronal sections from rostral (A) to caudal (C) through the superior colliculus. Only one colliculus is shown, and the midline is to the right. High-affinity 5-HT uptake is seen in two different locations: (1) in varicose fibers, distributed all over the brainstem, that correspond to fibers from the raphe; and (2) as dense accumulation of terminals in the superficial SGS in which they form a continuous band, and in the SO and lower SGS in which they form discrete patches caudally (B, C) and a continuous line rostrally (A). A'-C', The distribution of retinal projections, labeled by intraocular injection of HRP, at three equivalent coronal levels to those in A-C is shown: ipsilateral projections can be observed in the left SC, and contralateral projections in the right SC. D, In a P10 mouse binocularly enucleated on P8, the areas of dense 5-HT uptake have completely disappeared in the SO and SGS of the SC (only one side is illustrated, the level corresponds approximately to that shown in B). E, In a P10 mouse in which the left eye was removed on P8, the area of dense 5-HT uptake is reduced contralaterally to the lesion in the SGS and ipsilaterally to the enucleation in the SO. Scale bar, 340 µm.
To confirm and extend these observations, the localization of the SERT was analyzed using immunocytochemistry in normal and MAOA-KO mice from E13 to P30. The protein appeared to be present exclusively on retinal axons, and no immunoreactivity was detected in cell bodies (not illustrated). In the retina, SERT-immunoreactive fibers were first detected at E15 running along the ventral surface of the retina (illustrated at E17 in Fig. 7A). In the optic nerve, they were mostly located ventrally (Fig. 7A) and laterally with a smaller medial contingent (Fig. 7B). In the optic chiasm, some SERT-labeled fibers could be seen to cross the midline (Fig. 7C). In the optic tract (Fig. 7D,K) and the central visual targets (Fig. 7L), SERT-positive fibers that appear to be RGC axons are intermingled with SERT-positive fibers that originate from the raphe. However, raphe fibers can be distinguished because they are characteristically very heavily stained with thick varicosities and tend to meander individually, whereas putative SERT-positive RGC axons are more lightly stained and tend to form bundles of smooth fibers (Fig. 7K) or clusters of very thin varicose fibers. Just postnatally, diffuse SERT labeling was observed in the dLGN, and fiber bundles were visible in the pretectum and the SC (Fig. 7L). Between P7 and P14, a dense patch of SERT labeling was noted in the dorsomedial dLGN in an area that corresponds to the ipsilateral projection field (Fig. 7E). This was confirmed by comparing consecutive sections from the same brain treated to reveal either HRP-labeled retinal afferents or SERT immunoreactivity (Fig. 7F,G). In the pretectal nuclei (data not shown) and in the SC, SERT-immunoreactive clusters were also visible from P7 to P14 (Fig. 7J, P9). Within the SC however, patches were not visible in all cases, possibly because of a technical limitation in detecting a lower density of immunoreactivity in this area. SERT labeling in the SC never produced the clear pattern observed after labeled 5-HT uptake of a band in the superficial SGS and distinct patches in the SO.
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Figure 7. SERT immunolabeling on RGC axons during development in wild-type mice. SERT immunolabeling is visible on RGC axons but not cell bodies in the developing visual pathway. A-D, Coronal cryostat sections (20 µm) from an E17 normal mouse. A, SERT-positive fibers are seen leaving the retina in the ventral part of the optic nerve. B-D, SERT immunolabeling can be followed in the optic nerve (on) (B), the chiasm (C), and the optic tract (ot) (D). Note that labeling is restricted to peripheral parts of the optic nerve. E-J, Free-floating sections from mice aged P8-P10. E, SERT immunolabeling is detected in a limited region of the dLGN (indicated by an arrow) as well as in thalamic axons in the reticularis (rt). F, G, After injections of HRP into one eye at P8, alternate brain sections were treated either to reveal the HRP (G) or immunolabeled for SERT (F). Exact superposition of adjacent sections was not possible because the two procedures resulted in different degrees of shrinkage of the tissue. However, alignment of consecutive sections indicated that the region of SERT immunolabeling in the dLGN corresponds to the area of the gap in contralateral projections (G) that receives projections from the ipsilateral eye. H, I, After monocular enucleation at P8, SERT-labeled fibers at P10 have totally disappeared from the dLGN ipsilateral to the eye that has been removed (I) but are still present ipsilateral to the remaining eye (i.e., contralateral to the enucleation) (H). J, In the SC at P9, SERT expression is concentrated in the SO in patches reminiscent of the ipsilateral retinal innervation and is not detectable in more superficial SGS. K, L, In higher magnification micrographs of SERT labeling at P0 in the optic tract (K) and at the pretectal-SC junction (L) raphe fibers appear densely immunoreactive and varicose, whereas the presumptive SERT-positive optic fibers are more linear, more lightly labeled, and are grouped in bundles. Scale bar: A, 331 µm; B-D, 230 µm; E, J, 400 µm; F, G, 150 µm; H, I, 300 µm; K, L, 35 µm.
To confirm that the SERT-labeled fiber terminals seen in the dLGN and pretectal nuclei come from the retina and to establish whether they originate in the ipsilateral or contralateral retina, normal pups were unilaterally enucleated on P7 or P8 (when the segregation of ipsilateral and contralateral projections is almost complete), and sacrificed 2 d later. After enucleation, the dense patches of SERT labeling in the dLGN and in the pretectal nuclei disappeared ipsilaterally to the enucleation (Fig. 7H,I), confirming their retinal origin, and suggesting that they arise essentially from the ipsilateral eye. Because of the variability of SERT labeling in the SC at these ages, we were not able to draw conclusions about the effects of monocular enucleation in the SC.
In MAOA-KO mice, the distribution of SERT immunoreactivity was identical to that in normal mice in the retina, optic nerve, and optic tract. But in MAOA-KO mice, SERT labeling of retinal fibers was more diffuse in the dLGN at P8 and was almost impossible to detect at any age in the SC (data not shown).
Expression of 5-HT1B receptors, SERT, and VMAT2 in the retina during development
To further demonstrate that SERT is expressed in RGCs of thedeveloping retina, we performed in situ hybridization (ISH) using a probe for SERT. In parallel, we investigated the localization of the 5-HT1B receptor (5-HT1B), and the VMAT2 genes, because we had previously found that they frequently coexist with transient SERT expression (Lebrand et al., 1998a
The first ganglion cells are born at E11, close to the optic nerve head, and their generation roughly follows a central to peripheral gradient (Dräger, 1985
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Figure 8. In situ hybridization of SERT, 5-HT1B receptor, and VMAT2. Antisense cRNA 35S-labeled probes to SERT (B, F, J), the 5-HT1B receptor (C, G, K) and VMAT2 (D, H, L) were hybridized to 15-µm-thick coronal sections through the retina at E15 (A-D), P1 (E-H), and P6 (I-L). The retinal pigmented epithelium (pe) was nonspecifically labeled by sense and antisense probes. A, E, and I are bright-field photomicrographs of Nissl-stained sections. A, At E15, two layers can be distinguished in the retina: the undifferentiated neuroepithelial cells and the postmitotic retinal ganglion cell layer (gc). The latter, outlined by a dashed line, first appears close to the optic nerve head (O) and subsequently at the periphery. E, At P1, the ganglion cell layer is clearly separated from the others by the inner plexiform layer. I, By P6, differentiation of the different retinal cell types is complete, and all layers of the retina are distinguishable. B-D, At E15, a small area at the periphery of the retinal ganglion cell (RGC) layer is positive for SERT (B), and a hybridization signal is observed in the entire RGC layer with probes for 5-HT1B (C) and VMAT2 (D). F-H, At P1, a restricted territory at the periphery of the RGC layer expresses SERT (F), whereas the entire RGC layer is still labeled with 5-HT1B (G) and VMAT2 (H). J-L, At P6, SERT mRNA labeling has become confined to small patches in the ventral part of the peripheral retina (J). 5-HT1B expression still extends throughout the RGC layer (K), whereasVMAT2 labeling (L) starts to decrease compared with younger ages. Scale bar: A-D, I-L, 150 µm; E-H, 300 µm.
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Figure 9. SERT expression in relationship to ipsilateral retinal projections. A, B, Coronal sections taken through the retina of a P4 mouse pup injected in the ipsilateral thalamus on P1 with fluorogold. A, ISH using a probe for SERT mRNA. An arrow indicates the furthest extent of the ISH signal in the RGC layer. B, Same section photographed under UV fluorescence to reveal fluorogold retrogradely transported to the retina (magnification, 44×). The arrow indicates the edge of the ipsilaterally projecting region. Note that SERT hybridization signal in the ventral retina falls within the region containing ipsilaterally projecting cells. C, A reconstruction of the retina was made from a series of 15 µm horizontal sections, 60 µm apart, taken through one E17 C3H/HeJ retina and processed for ISH. The circumference of each retinal section is represented as a straight gray line with the region of SERT expression in RGCs represented by a thicker green bar. In sections through the lens, the end of the ganglion cell layer was taken as the end of the line. However, the most dorsal and the three most ventral sections that contained a continuous ganglion cell layer were divided at the point closest to the surface of the skin for the purpose of this reconstruction. The position of the optic nerve is indicated by a filled circle. The labeled territory forms a peripheral crescent that only excludes the dorsal peripheral retina. D, Summary of the anatomical organization of the crossed and uncrossed retinal pathways in rodents as previously described in the literature (Dräger and Olson, 1980
The territory of SERT expression includes part of the domain of ipsilaterally projecting RGCs in the ventrotemporal crescent of the retina (Dräger and Olsen, 1980
5-HT1B transcripts were found in the ganglion cell layer of the retina from E15 until adult life [illustrated at E15 (Fig. 8C), P1 (Fig. 8G), and P6 (Fig. 8K)]. In contrast with SERT expression, 5-HT1B transcripts are distributed across the entire retina, and this expression continues in the adult (despite the degeneration of the photoreceptor cells of the retina which is characteristic of the C3H/HeJ mice).
VMAT2 mRNA is detectable in the ganglion cell layer throughout the retina at the earliest embryonic age examined (E13) but its expression is transient: the hybridization signal becomes weaker after birth and ends between P8 and P10 [illustrated at E15 (Fig. 8D), P1 (Fig. 8H), and P6 (Fig. 8L)].
Thus, each of these three genes, SERT, VMAT2, and 5-HT1B has a different spatial and temporal pattern of expression in the retina but they are all expressed by RGCs during a postnatal developmental period, which is critical for the segregation of retinal afferents, and during which 5-HT can affect the final projection pattern.
DISCUSSION
In this paper we show that in MAOA-KO mice, elevated levels of brain 5-HT during the first 2 weeks of postnatal development prevent the ipsilateral and contralateral retinal projections from segregating into eye-specific areas in their target structures. Furthermore, we show that in normal and MAOA-KO mice SERT, VMAT2, and 5-HT1B are jointly expressed by a subpopulation of developing RGCs during the period of axonal remodeling. We propose that 5-HT could, via these molecules, influence retinofugal pathways and thereby help in sculpting their adult pattern of connections.
Elevated serotonin levels prevent segregation of RGC projections
In rodents, retinofugal axons invade their central primary targets, the dLGN and SC, during the second half of gestation. The majority of retinal fibers cross in the optic chiasm to reach contralateral targets, whereas a much smaller number of fibers remain uncrossed both in adults (Dräger and Olsen, 1980
The effect we see of MAOA inactivation resembles that found by Land and Rose (1985)
Possible targets of excess 5-HT in the primary visual pathways
The effects of 5-HT could be achieved by modifying the levels of neural activity in the developing retinofugal axons. Many lines of evidence suggest that segregation of inputs from both eyes is an activity-dependent process (for review, see Shatz, 1990
5-HT could also affect postsynaptic target cells. Several 5-HT receptors are present in the SC (5-HT2A, 5-HT7) and dLGN (5-HT2C, 5-HT7) during development or in the adult (Pazos et al., 1985
Another possible site of action of 5-HT is a direct trophic effect of 5-HT on RGCs. 5-HT has been reported to promote or inhibit axonal growth and increase cell survival in vitro (Goldberg et al., 1991
SERT in a subpopulation of RGCs
Our observations clearly demonstrate that SERT is transiently expressed by RGCs during a limited period of development even though developing RGCs do not have the capacity to synthesize 5-HT, because all 5-HT immunolabeling disappears in retinal axons after fluoxetine treatment (Cases et al., 1998
Of particular interest is the restricted extent of SERT expression during this period in a small, but well-defined region of the retina. This could confer unique neurotransmission properties on a group of RGCs, that combined with positional identity cues provided by other genes (Cheng et al., 1995
The peripheral region of the retina in which we found SERT expression corresponds to the RGCs with the latest birth dates (Dräger, 1985
A general role for 5-HT in the establishment of topographic projections in the brain
The influence of 5-HT on thalamic projections to the primary somatosensory (S1) cortex of rodents has been well documented. The cells of the ventrobasal nucleus of the thalamus that projects to the S1 cortex show a similar time course of expression of both SERT and VMAT2 to that observed in RGCs (Lebrand et al., 1996
There are several striking similarities between sensory thalamic neurons and peripheral RGCs: (1) both cell types are believed to be glutamatergic (Castel et al., 1993
FOOTNOTES Received Dec. 16, 1998; revised April 27, 1999; accepted June 4, 1999.
This work was supported by the Institut National de la Santé et de la Recherche Médicale, the Centre National de la Recherche Scientifique, the Curie Institute, and by the European Commission (BMH4 CT97-2412). We thank Edward De Maeyer and Constantino Sotelo for their support and advice, Denis Lecren for photographic assistance, Chantal Alvarez for technical help, and Diana Haranger for animal care. We are very grateful to Claudine Botteri, Pierre Godement and Christine Métin for critical reading of this manuscript and useful discussions.
Correspondence should be addressed to Dr. P. Gaspar at the above address.
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