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Previous Article | Next Article
The Journal of Neuroscience, November 15, 1999, 19(22):9900-9912
Altered Midline Axon Pathways and Ectopic Neurons in the Developing Hypothalamus of Netrin-1- and DCC-Deficient Mice
Michael S. Deiner and David W. Sretavan Departments of Ophthalmology and Physiology, Biomedical Sciences Program, Beckman Vision Center, University of California, San Francisco, San Francisco, California 94143-0730
ABSTRACT
TOP
ABSTRACT
INTRODUCTION
Optic nerve formation in mouse involves interactions between netrin-1 at the optic disk and the netrin-1 receptor DCC (deleted in colorectal cancer) expressed on retinal ganglion cell (RGC) axons. Deficiency in either protein causes RGC pathfinding defects at the disk leading to optic nerve hypoplasia (Deiner et al., 1997
). Here we show that further along the visual pathway, RGC axons in netrin-1- or DCC-deficient mice grow in unusually angular trajectories within the ventral hypothalamus. In heterozygous Seyneu mice that also have a small optic nerve, RGC axon trajectories appear normal, indicating that the altered RGC axon trajectories in netrin-1 and DCC mutants are not secondarily caused by optic nerve hypoplasia. Intrinsic hypothalamic patterning is also affected in netrin-1 and DCC mutants, including a severe reduction in the posterior axon projections of gonadotropin-releasing hormone neurons. In addition to axon pathway defects, antidiuretic hormone and oxytocin neurons are found ectopically in the ventromedial hypothalamus, apparently no longer confined to the supraoptic nucleus in mutants. In summary, netrin-1 and DCC, presumably via direct interactions, govern both axon pathway formation and neuronal position during hypothalamic development, and loss of netrin-1 or DCC function affects both visual and neuroendocrine systems. Netrin protein localization also indicates that unlike in more caudal CNS, guidance about the hypothalamic ventral midline does not require midline expression of netrin.
Key words: optic chiasm; netrin; DCC; hypothalamus; gonadotropin-releasing hormone; luteinizing hormone-releasing hormone; antidiuretic hormone; vasopressin; supraoptic nucleus; oxytocin; visual system; retinal ganglion cell; axon guidance; cell migration; diencephalon; CD44; organum vasculosum of the lamina terminalis
INTRODUCTION
Despite the importance of the hypothalamus in neuroendocrine and autonomic function, little is known of the developmental mechanisms that give rise to the complex patterns of neuronal connectivity in this anterior CNS region. Most neurons of the neuroendocrine hypothalamus are born starting at approximately embryonic day 10.5 (E10.5) and subsequently migrate away from the ventricular zone to form hypothalamic neuronal groups (nuclei) distinguished by expression of specific neuropeptides or hormone-releasing factors (Altman and Bayer, 1978a
Caudal to the hypothalamus, cell differentiation and axon guidance about the ventral midline of the developing hindbrain and spinal cord appear to be organized by activities derived from midline structures such as the notochord and floor plate (for review, see Dodd et al., 1998
Here we investigated whether netrin-1 or DCC are involved in mouse hypothalamic development. The results show netrin-1 and DCC are required for normal development of RGC axon trajectories during chiasm formation and for development of gonadotropin-releasing hormone (GnRH) axon pathways. Furthermore, in the absence of netrin-1 or DCC, antidiuretic hormone (ADH) and oxytocin neurons of the supraoptic nucleus (SON) appear to migrate abnormally into the chiasm region. Thus, specific features of neuronal connectivity about the ventral hypothalamic midline are governed by netrin-1 and DCC. However, unlike in spinal cord and hindbrain, netrin does not appear to be expressed at the ventral hypothalamic midline and therefore cannot be used by the CNS as a midline cue at this location. Hypothalamic developmental abnormalities can now be added to corpus callosum defects (Serafini et al., 1996
MATERIALS AND METHODS
Netrin-1-, DCC-, Pax6-, and GAP-43-deficient mice. Production, breeding, and genotyping of the four mutant mouse strains used have been described previously. Netrin-1-deficient mice were produced via targeted deletion of the netrin-1 gene resulting in a fusion transcript comprised of all of domain VI and the first epidermal growth factor-like repeat of domain V of netrin-1 fused to the transmembrane domain of CD4 and the cytoplasmic domain of
-geo (Skarnes et al., 1995
Orientation terminology. During mouse embryogenesis at ~E8, a 90° turn occurs along the dorsal-ventral axis to create the cephalic flexure such that rostral CNS anterior to the flexure comes to lie ventrally. Because the present study describes results after the formation of the flexure and around birth, we have adopted the orientation terminology used conventionally in both the vision and the neuroendocrine literature. Anterior therefore refers to the direction toward the nose, and dorsal is toward the top of the head.
Antibodies. Anti-DCC [rabbit polyclonal; 1:3000; gift of Dr. E. Fearon, University of Michigan Medical Center (Reale et al., 1996
Immunohistochemistry. E12-E18 embryos (plug day = E0) were harvested from anesthetized C57/bl6 timed pregnant mice (Sretavan et al., 1994
80°C until use. Postnatal day 0 (P0) animals were first perfusion fixed with 4% PFA, immersion fixed in 4% PFA 1-2 d, and infiltrated 1-5 d in 30% sucrose in PBS before embedding in OCT. For immunostaining using paraffin sections, heads were fixed using Carnoy's fixative (Bancroft and Stevens, 1982
Immunolabeling of DCC, CD44, ADH, GnRH, CRH, GH, ACTH, FSH, and LH was performed on cryostat or paraffin sections preblocked in heat-inactivated normal goat or donkey serum (HINGS or HINDS, respectively) for 20 min. Incubations with primary antibody were performed at room temperature (RT) for 1-2 hr followed by five washes in 0.1 M PBS (4 min/wash). Secondary antibody was applied for 1-2 hr at RT; the sections were then washed five times before coverslipping. All antibody incubations were performed in the presence of 0.1% Triton X-100 and either 1% HINDS or 1% HINGS for blocking. In some cases, a second 10% HINGS or 10% HINDS 20 min blocking step was performed before addition of the secondary antibody. Netrin immunolabeling in 5- to 10-µm-thick paraffin sections was performed as described previously (Deiner et al., 1997
DiI labeling and angle measurements of RGC axons. Anterograde labeling of axons in the optic nerves with DiI (D-282; Molecular Probes, Eugene, OR) was performed as described in Sretavan et al. (1994)
Digital imaging. DiI and Cy3 fluorescence was visualized using rhodamine fluorescence optics, and Cy2 was visualized using fluorescein optics. Images of the immunolabeling patterns in tissue sections and whole mounts were captured digitally using a Photometrics PXL2 cooled CCD camera or an Optronics color CCD camera and processed for presentation using Adobe Photoshop and/or Illustrator. For all wild-type and mutant image pairs, images were collected using the same camera exposure times and processed simultaneously in Adobe Photoshop, allowing comparison between images. For multiple serial section reconstructions, ADH neurons in every third 20 µm section were imaged digitally, and Adobe Illustrator was used to trace the position of labeled neurons. Tracings of serial sections were then assembled into one single image file.
GH and ACTH assays. P0 wild-type and mutant pups were decapitated, and 20-30 µl of blood was collected in the presence of 1 µl of anticoagulant. Older ages were not examined because mutants die soon after birth. Blood was immediately centrifuged for 5 min at 3000 × g; serum was collected, either diluted in water (ACTH assay) or undiluted (GH RIA), and snap frozen. ACTH levels were assayed at the University of California, San Francisco, Clinical Laboratories, Department of Laboratory Medicine using an antibody-based chemiluminescence assay system, the ACTH 100T kit from Nichols Institute Diagnostics (catalog #60-4175; San Juan Capistrano, CA). GH levels were measured by radioimmunoassay using 125I-labeled mouse growth hormone, antiserum to rat growth hormone, and a mouse growth hormone standard generously supplied by Dr. A. F. Parlow (Harbor-University of California, Los Angeles, Medical Center).
RESULTS
Netrin-1 and DCC expression in the developing hypothalamus
Immunostaining using a polyclonal pan-netrin antibody [from T. E. Kennedy; see Deiner et al. (1997)
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Figure 1. DCC and netrin expression in the E12 mouse hypothalamus. The schematic diagrams on the left show the eyes, optic nerves, and ventral hypothalamus. The red rectangle indicates the anterior-posterior hypothalamic level at which tissue sections were obtained for netrin (middle) and DCC (right) immunostaining. Tissue sections separated by 20-30 µm were used for netrin and DCC immunostaining at each level. In all panels, dorsal is at the top. a-f, Netrin (arrowheads) was found in bilateral patches at different sites along the anterior-posterior length of the hypothalamus. a, Netrin expression at the ventral medial septal and diagonal band region is shown. The area of the dotted rectangle is shown at higher magnification in the inset at the top right. Staining in blood cells and vessels is nonspecific. b, Note the absence of netrin at the ventral midline region. c, d, Netrin is expressed at the ventral-lateral hypothalamic regions corresponding approximately to where axons of chiasm neurons (see Fig. 2) grow dorsally to join the TPOC and where the initial portions of the optic tract will later develop. There is no apparent ventral midline netrin expression. e, Netrin expression in the ventricular zone is shown. The area of the dotted rectangle is shown at higher magnification in the inset at the top right. Such bilateral patches of netrin were found in the ventricular zone region scattered throughout the anterior-posterior length of the hypothalamus. f, Netrin expression in the presumptive lateral posterior ME region is shown. g-l, DCC expression at different levels along the anterior-posterior length of the hypothalamus is shown. DCC was found in specific domains distributed throughout the hypothalamus but was absent from the ventricular zones. D, Dorsal; DB, diagonal band; ME, median eminence; MS, medial septum; OC, future chiasm region; OT, future region of the optic tract; POA, preoptic area. Scale bar, 200 µm.
Relationship to RGC axons and chiasm neurons
At E12.5, the first RGC axons have arrived at the ventral hypothalamus and have begun to form the chiasm. As the RGC axons enter the midline region, they encounter optic chiasm neurons that are found along the posterior boundary of the future chiasm and are organized into an inverted V-shaped array (for review, see Mason and Sretavan, 1997
Starting from E12 onward, netrin was expressed bilaterally along the optic nerves (see Fig. 2a) and just posterior to the attachment point of the optic nerves to the brain, lateral to the midline (see Fig. 1c). The location of this lateral zone of netrin protein expression approximately correlated with the location of the chiasm neuron axons and the future position of the initial portions of the optic tracts. By E14-E16, although similar in overall pattern, the levels of netrin expression were greatly reduced. During RGC axon ingrowth and chiasm formation, netrin was not detected at the ventral midline in the hypothalamus (Fig. 1a-f). The early pattern of hypothalamic netrin protein expression reported here is similar to that of netrin mRNA (T. Serafini, personal communication), suggesting that the immunostaining pattern accurately reflects netrin protein distribution.
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Figure 2. Relationship of netrin and DCC expression to RGC axons, chiasm neurons, and GnRH and ADH neurons. a, Netrin expression in the optic nerve at E14 (the retina is toward the top). b, Immunostaining of an adjacent optic nerve section with anti-netrin antibody omitted. Note nonspecific staining of blood cells. c, DCC expression on RGC axons within the E14 optic nerve. d, Immunostaining of an adjacent optic nerve section with anti-DCC antibody omitted. e, E12.5 horizontal section dorsal to where the optic nerves attach to the hypothalamus showing netrin (dark blue) bilaterally in the approximate future region of the optic tract (see also Fig. 1c,d). f, E12.5 coronal section through the region of CD44-immunopositive chiasm neurons (red). g, The same section as in f showing that DCC (green) is expressed by many neurons in this area. h, Overlay of images in f and g showing colocalization of CD44 and DCC on neurons in this area. Most CD44-positive cells express DCC. i, CD44 expression (red) on a dorsolaterally projecting axon of a chiasm neuron. j, The same section as in i showing expression of DCC (green) in the same region. k, Overlay of images in i and j showing DCC expression on CD44-positive axons. l, Summary diagram of netrin expression (red) with respect to the developing RGC axon and chiasm neuron pathway. DCC expression on RGC axons and chiasm neurons and axons is depicted in green. m, E18 Sprague Dawley rat coronal sections through the POA showing DCC-immunopositive neurons and axons. Inset, The approximate region (boxed area) shown in m-o. Similar results were seen in E16 mouse POA (data not shown). n, The same section as in m showing GnRH expression (red) in a neuron cell body (*) and axon (arrowheads). o, Overlay showing cellular colocalization of DCC and GnRH. p, Summary diagram showing netrin expression (red) in the position where many GnRH neuron cell bodies reside (the preoptic area) and along the pathway taken by many GnRH axons as they grow toward the ME (dorsal regions adjacent to the third ventricle). DCC expression on GnRH neurons and their axons is depicted in green. q, E14 coronal section at the level of the SON showing DCC expression (green) in the tissue surrounding but not within the SON. Inset, The approximate region (boxed area) shown in higher magnification in q-s. r, A section adjacent to q showing netrin expression (red) within and just outside of the SON. s, Superimposition of q and s. t, E16 coronal section showing DCC expression in tissue surrounding the SON (arrow), including the region of the optic tract (asterisk). u, Adjacent section showing ADH-immunopositive neurons (red) within the SON. v, Superimposition of t and u. A, Anterior. Scale bars: a-d, 25 µm; e, 200 µm; f-h, 10 µm; i-k, 1 µm; m-o, 10 µm; q-s, 100 µm; t, u, 100 µm; v, 100 µm. OT, Future region of the optic tract; POA, preoptic area; SON, supraoptic nucleus.
RGC axons expressed DCC during their course within the optic nerve (Fig. 2c), the chiasm, and the optic tract (Fig. 2q,t). Chiasm neurons and their axons also expressed DCC (Fig. 2f-k) and therefore, like RGC axons, may also be capable of responding to netrin. The expression data (summarized in Fig. 2l) indicate that RGC axons do not grow toward the midline and form the chiasm in response to netrin secreted from the hypothalamic midline. However, the bilateral patches of netrin expression in the optic nerve and the vicinity of the initial optic tract region suggest that netrin and DCC interactions could mediate some aspects of RGC or chiasm neuron axon pathway development in the ventral hypothalamus.
GnRH neurons and axon pathways
GnRH neurons originate in the olfactory placode and then migrate along olfactory axons to the mediobasal olfactory bulb where they enter the brain and take up final residence in several hypothalamic regions including the medial septum, diagonal band, and preoptic areas (Schwanzel-Fukuda and Pfaff, 1989
Netrin, DCC, and SON development
ADH and oxytocin neurons destined to form the SON are thought to arise in the ventral diencephalon ventricular zone and migrate laterally to form a well-defined nucleus that is bounded along its ventromedial border by the optic tract (Karim and Sloper, 1980
Abnormal RGC axon trajectories in netrin-1 and DCC mutants
We investigated and compared hypothalamic development between netrin-1- and DCC-deficient mice to identify developmental events dependent on netrin-1 and DCC interactions. On the basis of the pattern of netrin-1 and DCC expression and because RGC axons respond to netrin-1 in vitro (Wang et al., 1996
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Figure 3. Altered RGC axon trajectories at the ventral hypothalamus of DCC- or netrin-1-deficient mouse embryos. a, b, Each panel shows images of DiI-labeled RGC axons at the ventral hypothalamic region in wild-type (top, green), heterozygous (middle, green), and mutant (bottom, red) littermate E14 embryos. The retina of origin is toward the top left, and the optic tract is toward the bottom right. The arrow indicates the orientation (anterior is at the top), and the white dot indicates the midline. c, The schematic diagram shows the location of the angles 1 and 2 measured in RGC axon projections, for example, shown here for the projections of wild-type (top) and mutant (bottom) embryos of a. d, The graph shows angles 1 and 2 in heterozygous (Het; columns 1 and 2) or mutant (Mut; columns 3 and 4) embryos compared with wild-type (WT) embryos at E14-E15. Data from netrin and DCC embryos have been pooled. The amount in degrees by which angles 1 and 2 in heterozygotes or in mutants exceed angles 1 and 2 in wild-type embryos is plotted on the y-axis. Asterisks indicate a significant difference was found in mutants (but not heterozygotes) compared with wild type (Student's t test; p < 0.002 for mutants; p > 0.2 for heterozygotes; n = 5 wild type, 9 heterozygous, and 10 mutants). Black bars, angle 1; gray bars, angle 2. e, In the chiasm of wild-type embryos, a subset of RGC axons (asterisk; shown as a negative image to highlight axons) crosses the midline posterior to the main RGC axon bundle. The inset shows the outline of the main bundle in the chiasm (dark gray), and the red box indicates the approximate region from which the image in e was taken. In many cases of netrin-1 or DCC mutant embryos, RGC axons crossed the midline at a point that correlates with this posterior region. f, DiI-labeled RGC axons at the ventral hypothalamus of E14 wild-type (green) and Pax6 Seyneu/+ heterozygous (red) littermate embryos are shown. Although optic nerve size in Seyneu/+ heterozygous embryos is reduced, abnormally angular RGC axon trajectories such as those seen in netrin-1 or DCC mutants were not observed. g, The graph shows that angles 1 and 2 in Seyneu/+ heterozygous animals were not significantly different from those present in wild-type littermates (y-axis same as in d). Scale bars: a, b, f, 250 µm; e, 100 µm.
To analyze the altered RGC axon trajectories, we measured two RGC axon-turning angles in wild-type, heterozygous, and mutant littermates (see Fig. 3c). Because this phenotype appeared quite similar in both the netrin-1 and DCC mutants (compare Fig. 3a with b), we pooled the results from both sets of mutants. At E14-E15, both turning angles were significantly greater in netrin-1 and DCC mutants compared with wild-type littermates [p < 0.002 using Student's t test; n = 5 wild type and 10 pooled netrin-1 and DCC mutants; similar results found at E12-E13 (data not shown)]. For example, at E14-E15, compared with those in wild type, the turning angles in mutants were on average 23° greater at angle 1 (Fig. 3d, black bars) and 15° greater at angle 2 (Fig. 3d, gray bars). In E14-E15 heterozygotes, both turning angles were not significantly different compared with those in wild-type littermates (p > 0.2 using Student's t test; n = 5 wild type and 9 heterozygotes).
During normal development, early arriving RGC axons run in close apposition to chiasm neurons. As many more RGC axons continue to enter the hypothalamus to form the chiasm, RGC axons appear to be added anteriorly such that the main bundle of RGC axons is increasingly separated from the chiasm neurons (Sretavan et al., 1994
Angular RGC axon trajectories are independent of a small optic nerve
Because a smaller number of RGC axons exit the eye in netrin-1 or DCC mutants, we examined whether abnormal RGC axon chiasm trajectories could simply be a consequence of optic nerve hypoplasia. To investigate, we studied chiasm development in Seyneu mice that have a mutated Pax6 gene (Hill et al., 1991
Development of chiasm neurons
One local neuronal population that can influence RGC axon trajectories is chiasm neurons. Because chiasm neurons express DCC, and netrin was expressed in the region traversed by their axons, it was possible that defects in chiasm neuron development in DCC or netrin-1 mutants may have secondarily caused the abnormal RGC axon trajectories. Analysis of chiasm neuron development after CD44 immunostaining and DiI labeling in E12 littermates showed, however, that these neurons were arrayed normally in an inverted V-shape (compare Fig. 4a with b) and sent axons dorsally in mutants, similar to the pattern seen in wild-type embryos [compare Fig. 4c with d; DiI data not shown; also see Sretavan et al. (1994)
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Figure 4. Chiasm neuron development in DCC- or netrin-1-deficient mouse embryos. a, b, E12 hypothalamic whole-mount preparations showing CD44 immunostaining of the inverted V-shaped array of chiasm neurons (arrowheads) in heterozygous (HET; a) and netrin-1 mutant (MUT; b) littermates. These inverted V-shaped patterns are similar to that present in wild-type embryos (Sretavan et al., 1994
Reduced GnRH axon projections
At the ventral hypothalamus, in addition to angular RGC axon trajectories, the GnRH axon pathway was also severely affected in netrin-1 and DCC mutants. This was in agreement with a potential role for a direct involvement of netrin-1 and DCC interactions in the formation of the GnRH axon pathway because, as shown above, netrin was expressed along the route taken by developing GnRH axons. In wild-type animals, most anteriorly located GnRH neurons send axons posteriorly through the region of the organum vasculosum of the lamina terminalis (OVLT) just anterior to the chiasm and then along both ventral and dorsal routes adjacent to the third ventricle to reach the ME (Hoffman and Gibbs, 1982
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Figure 5. The axon pathways of GnRH neurons in wild-type and DCC- or netrin-1-deficient P0 littermates (coronal sections). a-h, Wild-type newborn animals (a-d) and their mutant littermates (e-h) are shown. a, b, Examples of GnRH axons in the OVLT of wild-type littermates from a DCC (a) and netrin-1 (b) litter are shown. c, d, Examples of GnRH axons in the ME regions of the same wild-type animals shown in a and b, respectively, are presented. e, f, Examples of GnRH axons in the OVLT of DCC (e)- and netrin-1 (f)-deficient animals are shown. The number of OVLT GnRH axons in DCC-deficient animals appears quite similar to that in wild type (compare with a, b). The number of OVLT GnRH axons in netrin-1-deficient animals appears reduced compared with that in wild type (compare with a, b). g, h, Examples of GnRH axon projections in the ME regions of DCC (g)- and netrin-1 (h)-deficient animals (same animals shown in e, f, respectively) are presented. The GnRH axon projections are severely reduced compared with that in wild type but terminate in the appropriate lateral ME contact zone regions (see c, d). j, k, Unlike GnRH axons, axons of CRH-positive neurons in wild type (j) and mutant (k) appear to grow equally well into the medial ME contact zone (k is same animal shown in g). l, m, Axons of ADH-positive neurons, which also grow through the ME internal zone to the infundibulum, appeared similar in wild-type (l) compared with DCC mutant (m) infundibulum. n, o, In comparison with wild type (n), GnRH-positive axon projections were not reduced in an E18 GAP-43-deficient littermate (o). RGC axon growth in the chiasm is severely disrupted in GAP-43-deficient embryos. In all panels, dorsal is at the top. G43, GAP-43; Inf, infundibulum. Scale bars: a, b, e, f, 50 µm; c, d, g, h, 200 µm; j, k, 200 µm; l, m, 200 µm; n, o, 200 µm.
Because RGC axons forming the chiasm are positioned close to the path of GnRH axons, altered RGC axon trajectories in the ventral hypothalamus may have led to the reduced posterior GnRH axon projection. This possibility was examined in GAP-43-deficient mice in which RGC axon growth at the chiasm is disrupted to a greater extent than in netrin-1- or DCC-deficient embryos (Strittmatter et al., 1995
Ectopic ADH and oxytocin neurons
In addition to axon pathway defects, ectopic neurons were found in the ventral hypothalamus of both netrin-1- and DCC-deficient mice. In wild-type animals at P0, ADH- and oxytocin-immunopositive neurons are found within the SON (arrows in Fig. 6a; oxytocin data not shown) that is bounded ventromedially by the optic tract. In both netrin-1- and DCC-deficient animals, we observed trails of ADH neurons just beneath the ventrolateral hypothalamus pial surface extending from the SON to the ventral midline (Fig. 6b, arrowheads). These ectopic ADH neurons had leading and trailing processes (Fig. 6c) and resembled migrating neurons (for example, see Edmondson and Hatten, 1987
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Figure 6. Ectopic ADH and oxytocin neurons in DCC- or netrin-1-deficient P0 littermates (coronal sections). a, In a typical P0 wild-type animal, ADH-positive cells are confined laterally in the SON (arrows). b, In a DCC mutant littermate, ADH-positive neurons are found within the SON region (arrows) and ectopically in a trail (arrowheads) extending from the SON to the ventral midline. c, Under higher magnification, ectopic ADH neurons (arrowheads) have leading and trailing processes reminiscent of migrating neurons. d, Ectopic ADH neurons are found as bilateral cell clusters centered about the midline (arrow) in the region anterior to the chiasm. e, f, The positions of ADH-positive neurons (red) in individual coronal sections from wild-type (e) and DCC mutant (f) littermates were traced, and tracings from serial sections were stacked. The stacked tracings were then oriented to show the pattern of ADH expression at the ventral surface of the brain. The pituitary is at the bottom of each of these images (posterior), and the chiasm is at the top (anterior). The asterisk marks the location of ectopic neurons with migrating profiles (shown in c). The arrow points to the area containing ADH neuronal clusters at the midline (shown in d). g, Ectopic ADH neuron clusters are also found at the midline (arrow) in the region anterior to the chiasm in netrin-1 mutants. h, i, In contrast to a wild-type littermate (h), ectopic oxytocin neurons in the mutant (i) are found in the region anterior to the chiasm and form bilateral clusters at the midline (arrow). The arrowhead points to the optic nerve, just entering the brain. j, Higher magnification view of ectopic oxytocin neuron clusters in the region anterior to the chiasm in a DCC mutant (arrow indicates midline) is shown. k, m, The approximate number and distribution of ADH neurons in the PVN appeared similar in wild-type (k) and mutant (m) littermates. l, n, The approximate number and distribution of oxytocin neurons in the PVN appeared similar in wild-type (l) and mutant (n) littermates. o, p, ADH-positive neurons are normally restricted to the SON in E18 wild-type (o) or GAP-43-deficient (p) embryos even though RGC axon growth into the optic tracts in these mutant embryos is severely reduced. In all panels (except e, f) dorsal is at the top. Ant., Anterior; Post., posterior. Scale bars: a, b, 500 µm; c, 50 µm; d, g, j, 25 µm; h, i, 250 µm; k-n, 250 µm; o, p, 250 µm.
Other than the presence of ectopic ADH and oxytocin neurons, hypothalamic neuronal migration and the positions of other hypothalamic nuclei did not appear to be generally disrupted in netrin-1- or DCC-deficient embryos. For example, as shown above, CD44 neurons were found in their appropriate location (see Fig. 4). Furthermore the paraventricular nucleus (PVN), which also normally contains ADH and oxytocin neurons (for review, see Swanson and Sawchenko, 1983
The optic tract and ectopic ADH neurons
The apposition of the SON and optic tract RGC axons (see Fig. 2q-v) suggests that RGC axons might normally serve as a barrier against abnormal neuron migration out of the SON. Fewer optic tract RGC axons in netrin-1 or DCC mutants (because of optic nerve hypoplasia) might then allow ectopic migration ventromedially out of this nucleus. To investigate, we examined the distribution of ADH neurons in E18 GAP-43-deficient embryos that have only very few RGC axons in the optic tracts (Sretavan and Kruger, 1998
Pituitary development in netrin-1 and DCC mutants
Because normal pituitary development and function depend on proper innervation from specific hypothalamic neurons (for example, see Schonemann et al., 1995
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Figure 7. Pituitary development in DCC- or netrin-1-deficient mice. a-d, Coronal sections of the pituitary gland at P0 are shown. The overall size and shape of the pituitary is not different between wild-type (a, c) and mutant (b, d) animals. Mutants have normal organization of the posterior pituitary, intermediate lobe, pituitary cleft, and anterior pituitary. a, ACTH-positive neurons in the intermediate lobe of a wild-type animal are shown. b, ACTH neurons are found in a similar pattern in a netrin-1-deficient littermate. c, GH-positive neurons are located in the anterior pituitary in wild-type animals. d, GH-positive neurons are found in a similar pattern in a netrin-1-deficient littermate. e, Plasma ACTH levels in P0 animals are shown. Values (in ng/l) were obtained for animals from three different DCC litters, and the values obtained for animals of each genotype were pooled. The numbers in parentheses indicate the number of animals of each genotype. Older ages were not examined because mutants die postnatally. Error bars indicate SEM. f, Plasma GH levels in P0 DCC litters are shown. Values (expressed as cpm) were obtained for animals from three different DCC litters, and the values for animals of each genotype were pooled. AP, Anterior pituitary; IL, intermediate lobe; PC, pituitary cleft; PP, posterior pituitary. Scale bar: a-d, 200 µm.
DISCUSSION
Results from this study demonstrate that specific aspects of mouse hypothalamus development require the guidance molecule netrin-1 and the netrin receptor DCC (see summary in Fig. 8). The similarities in phenotype in both netrin-1 and DCC mutants suggest that this is via direct netrin-1 and DCC interactions. In the absence of netrin-1 and DCC, RGC axons are affected together with GnRH axons as well as ADH and oxytocin neurons. Although previous studies have identified important regulatory genes involved in hypothalamic cell fate specification (Schonemann et al., 1995
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Figure 8. Summary of defects in RGC axon trajectories and in development of GnRH, ADH, and oxytocin (OXY) neurons in DCC- or netrin-1-deficient animals.
Netrin-1 and DCC interactions and RGC growth in the developing hypothalamus
The mechanism by which the lack of netrin-1 and DCC interactions leads to the abnormally angular RGC axon trajectories remains unknown. Seyneu/+ heterozygous mice that have a small optic nerve do not exhibit abnormal RGC axon trajectories within the hypothalamus, indicating that optic nerve hypoplasia alone does not cause this phenotype. Previous studies show that chiasm neurons are involved in chiasm formation (for review, see Mason and Sretavan, 1997
Disrupted GnRH neuron axon projections
The results indicate that GnRH neuron migration and/or axon pathfinding require netrin-1 and DCC interactions. In DCC mutants, GnRH innervation of the OVLT appeared relatively unaffected, suggesting that a substantial number of GnRH neurons migrated appropriately into the hypothalamus and that GnRH axon pathfinding was not generally disrupted. Because individual GnRH axons reportedly form en passant synapses in the OVLT and then project into the ME (Hoffman and Gibbs, 1982
On the basis of the reduced GnRH axon projection, one might predict that netrin-1 or DCC deficiency would disrupt the regulation of gonadotropin release, leading to hypogonadism. If true, this would indicate that altered GnRH neuron development can lead to hypogonadism both via the failure of proper GnRH neuron migration into the CNS as in Kallman's syndrome (Schwanzel-Fukuda et al., 1989
Ectopic ADH and oxytocin neurons
During normal development, ADH and oxytocin neurons are thought to originate in the region of the ventral diencephalic sulcus and then to migrate laterally to the PVN and SON (Altman and Bayer, 1978a
One model of ADH and oxytocin neuron migration is that netrin-1 in the SON attracts migrating ADH and oxytocin neurons, and in mutants some neurons cannot therefore find their way to the SON and migrate to ectopic positions instead. However, on the basis of the trail of ectopic neurons leading back to the SON, we believe it is more likely that netrin-1 and DCC interactions are required to confine ADH and oxytocin neurons to the SON, and the absence of these interactions in mutants leads to inappropriate migration of neurons out of the SON. However, a consideration is that DCC was not expressed by neurons in the SON. It is possible that DCC was expressed by the SON neurons and was downregulated early on or that an unconventional netrin-1 and DCC interaction occurs in which DCC in the surrounding tissue serves as a "barrier" guidance cue signaling via netrin-1 to prevent neuronal migration out of the SON. An alternative that cannot be eliminated is that an unknown cell type normally prevents migration out of the SON and that its development is somehow affected in netrin-1- and DCC-deficient mutants.
A shared feature of all developmental defects
Although netrin and DCC expression patterns fit with a simple model in which netrin guides GnRH axons posteriorly, expression patterns do not suggest simple models to explain the altered RGC axon projections and the ectopic ADH neurons in mutants. However, although the three phenotypes identified in mutants involve neurons originating from separate regions of the CNS, we note that they all exhibit developmental defects around the ventral hypothalamus/chiasm midline region. This includes the presence of ectopic ADH and oxytocin neuron clusters, angular RGC axon trajectories, and severely reduced GnRH axon projections. The fact that all these developmental defects overlap anatomically at the ventral hypothalamic midline chiasm region allows for the possibility that one particular developmental defect in this region may have secondarily caused one or more of the other defects. For example, the presence of ectopic ADH neurons at the hypothalamic midline might alter RGC axon trajectories at the chiasm or even the ability of GnRH neurons to send axons posteriorly through this region.
Relationship to septo-optic dysplasia
In the adult, acquired disorders affecting the hypothalamus often involve the visual system because of the location of the chiasm on the ventral hypothalamic surface (for review, see Siatkowski and Glaser, 1995
FOOTNOTES Received May 27, 1999; revised Aug. 26, 1999; accepted Sept. 1, 1999.
This research was supported by National Institutes of Health (NIH) Grant EY 10688 and a grant from the That Man May See Foundation (D.S.), NIH Grant EY 02162 (Department of Ophthalmology), and NIH Grant EY 07120 (University of California, San Francisco). We thank Wylie Vale, Albert Parlow, Lawrence Frohman, Eric Fearon, Tim Kennedy, Mark Fishman, Tito Serafini, Amin Fazeli, and Marc Tessier-Lavigne for reagents and mice. Thanks to Selna Kaplan, Lita Ramos, Eric Birgbauer, Chris Severin, Judy Mak, and Amanda Kahn for technical assistance and contributions. The ACTH, LH, and FSH antibodies were a generous gift of the National Hormone and Pituitary Program, the National Institute of Diabetes and Digestive Kidney Research, the National Institute of Child Health and Human Development, and the United States Department of Agriculture. We also thank Michelle Bland, John Rubenstein, and Richard Weiner for their insightful comments.
Correspondence should be addressed to Dr. David Sretavan, Beckman Vision Center, Departments of Ophthalmology and Physiology, 10 Kirkham Street, Room K107, University of California, San Francisco, San Francisco, CA 94143-0730. E-mail: dws{at}itsa.ucsf.edu.
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