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The Journal of Neuroscience, December 1, 2002, 22(23):10346-10356

The Netrin 1 Receptors Unc5h3 and Dcc Are Necessary at Multiple Choice Points for the Guidance of Corticospinal Tract Axons

Jacqueline H. Finger¹, Rod T. Bronson^{1, 2}, Belinda Harris¹, Kenneth Johnson¹, Stefan A. Przyborski¹, and Susan L. Ackerman¹

¹ The Jackson Laboratory, Bar Harbor, Maine 04609, and ² Tufts University School of Veterinary Medicine, North Grafton, Massachusetts 01536

	ABSTRACT

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Migrating axons require the correct presentation of guidance molecules, often at multiple choice points, to find their target. Netrin 1, a bifunctional cue involved in both attracting and repelling axons, is involved in many cell migration and axon pathfinding processes in the CNS. The netrin 1 receptor DCC and its Caenorhabditis elegans homolog UNC-40 have been implicated in directing the guidance of axons toward netrin sources, whereas the C. elegans UNC-6 receptor, UNC-5 is necessary for migrations away from UNC-6. However, a role of vertebrate UNC-5 homologs in axonal migration has not been demonstrated. We demonstrate that the Unc5h3 gene product, shown previously to regulate cerebellar granule cell migrations, also controls the guidance of the corticospinal tract, the major tract responsible for coordination of limb movements. Furthermore, we show that corticospinal tract fibers respond differently to loss of UNC5H3. In addition, we observe corticospinal tract defects in mice homozygous for a spontaneous mutation that truncates the Dcc transcript. Postnatal day 0 netrin 1 mutant mice also demonstrate corticospinal tract abnormalities. Last, interactions between the Dcc and Unc5h3 mutations were observed in gene dosage experiments. This is the first evidence of an involvement in axon guidance for any member of the vertebrate unc-5 family and confirms that both the cellular and axonal guidance functions of C. elegans unc-5 have been conserved in vertebrates.

Key words: dorsal funiculus; mouse; spinal cord; pyramidal decussation; rcm; P3 domain

	INTRODUCTION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Development of the CNS depends on correct cellular migrations and axonal pathfinding to establish connectivity. Although axons navigate pathways that can be complex and cover large distances, their routes are simplified through intermediate targets, termed choice points (Stoeckli and Landmesser, 1998). As an axon encounters successive choice points during pathfinding, it responds to different sets of molecules. These guidance molecules provide attractive and repulsive signals to specific receptors present on the growth cone. For example, the Caenorhabditis elegans bifunctional cue UNC-6 guides axon migrations by attractive or repulsive mechanisms depending on the response of its receptor (Hedgecock et al., 1990; Wadsworth et al., 1996; Culotti and Merz, 1998). Cells and axons expressing the UNC-6 receptor UNC-5 are repelled by an UNC-6 gradient (Hedgecock et al., 1990; Leung-Hagesteijn et al., 1992; Wadsworth et al., 1996). In contrast, UNC-6 is predominantly attractive for cells and axons expressing the UNC-40 receptor (Hedgecock et al., 1990; Chan et al., 1996).

In vertebrates, similar mechanisms are involved in commissure formation. Spinal cord commissural axons expressing the vertebrate unc-40 homolog Dcc are attracted ventrally toward regions of netrin 1 (Ntn1) expression in the floor plate (Kennedy et al., 1994; Keino-Masu et al., 1996). On reaching the midline, additional cues are necessary for axons to cross the midline, such as axonin-1 (contactin 2) and NrCAM (Stoeckli and Landmesser, 1998). Another receptor molecule, Roundabout (Robo), is postulated to be required on the axons to prevent them from recrossing the midline, presumably by repulsion from Slit expressed at the midline (Li et al., 1999). Thus, the migration route of axons appears broken down into steps, each of which requires a particular set of molecules.

Here we show that in addition to its role in controlling the migrations of cerebellar neurons (Ackerman et al., 1997; Leonardo et al., 1997), Unc5h3 also plays a role in axonal guidance, a role not demonstrated previously for the vertebrate unc-5 genes in vivo. Our results indicate that Unc5h3 controls the pathfinding of corticospinal tract (CST) axons at two distinct points, the decussation and the final turn into the dorsal funiculus. Also, we describe CST defects in mice homozygous for a newly identified mutant allele of Dcc, Dcc^kanga, which, unlike the targeted mutant allele, survives to adulthood. Furthermore, we demonstrate that aberrant axonal projections in Unc5h3^rcm mutant mice are modulated by mutations in the Dcc gene. Last, we show that Ntn1 mutant mice have defects in the pyramidal decussation and dorsal funiculus, demonstrating a role for this guidance cue in the control of CST axons.

	MATERIALS AND METHODS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Mice. The Unc5h3^rcm (Unc5h3^{rcmTg(Ucp)1.23Kz}), Dcc^tm1Wbg, and Ntn1 (Ntn1^{Gt(pGT1.8TM)629Wcs}) mutations were maintained on C57BL/6J × SJL/J segregating, 129×1/SvJ, and C57BL/6J backgrounds, respectively (Serafini et al., 1996; Ackerman et al., 1997; Fazeli et al., 1997). Dcc^kanga mice arose in a C.AKR-Tgn^cog/+ research mouse colony at The Jackson Laboratory, and the Tgn^cog mutation has been segregated out of the line. Mutant mice were obtained from heterozygous crosses and were identified by either PCR or their abnormal gait; Ntn1/Ntn1 mice were identified by the absence of corpus callosum and anterior commissure in forebrain sections (Serafini et al., 1996).

Immunohistology. Adult mice were anesthetized with tribromoethanol and intracardially perfused with PBS followed by cold 4% paraformaldehyde (PFA) in PBS. After overnight incubation at 4°C, brains and spinal cords were dissected and rinsed in PBS. Brains and spinal cords of newborn mice were immersed in either 4% PFA (anti-DCC and anti-neurofilament) or Carnoy's fixative (60% methanol, 30% chloroform, and 10% acetic; anti-neurofilament only) for 24 hr. After processing in ethanol or sucrose, the tissue was embedded in either OCT (Tissue-Tek, Torrance, CA) at 20°C or paraffin and sectioned at 7-12 µm.

For immunofluorescence studies with mouse monoclonal anti-calcium/calmodulin (CaM) kinase II antibody (Oncogene Research Products, San Diego, CA), antigen retrieval was performed on paraffin sections by microwaving slides in 0.01 M sodium citrate, pH 6, for 8 min. After boiling, the slides were cooled to room temperature in this solution for 30 min, washed in PBS, and incubated in the anti-CaM kinase II antibody (1:100) overnight at 4°C before detection with Cy3-labeled goat anti-mouse secondary antibody (1:100; Chemicon, Temecula, CA). For studies with mouse monoclonal anti-DCC (Novocastra) and anti-neurofilament antibody 2H3 (Developmental Studies Hybridoma Bank, Iowa City, IA), antigen retrieval was performed as described above. Sections were washed in Tris-buffered saline and incubated in anti-DCC (1:30) or anti-neurofilament (1:50) overnight at 4°C before detection with biotin-labeled goat anti-mouse IgG₁ secondary antibody (1:500; Southern Biotechnology Associates, Inc., Birmingham, AL) and Alexa Fluor 488-labeled streptavidin (1:500; Molecular Probes, Eugene, OR). For studies with the mouse monoclonal anti-neurofilament antibody 2H3 only, paraffin sections were blocked in PBS, 0.3% Triton X-100, 3% nonfat dried milk, and 5% DMSO (PBS/T-MD) twice for 1 hr each. Primary antibody (1:50 in PBS/T-MD) was applied and incubated for 2 d at 4°C. After washes in PBS and 0.3% Triton X-100 (PBS/T) and PBS/T-MD, Cy3-conjugated goat anti-mouse secondary antibody (1:500 in PBS/T-MD) was applied and incubated overnight at 4°C. Slides were mounted using either Slow Fade Light Anti-Fade media (Molecular Probes) or Fluoromount G (Electron Microscopy Sciences, Ft. Washington, PA). All images were captured from a Leitz (Wetzlar, Germany) DMRXE microscope with the SPOT digital camera (Diagnostic Instruments, Sterling Heights, MI), an Olympus Optical (Tokyo, Japan) BX50 microscope with a Retiga 1300 camera (Optical Analysis Corp., Nashua, NH) or a Leitz TCSNT confocal microscope (Leica, Bannockburn, IL).

Biotin dextran amine tract tracing. All animal procedures were approved by the Animal Care and Use Committee at The Jackson Laboratory. Unc5h3^rcm/Unc5h3^rcm (n = 5) and Dcc^kanga/Dcc^kanga (n = 6) animals and their corresponding wild-type controls (n = 6), were anesthetized with tribromoethanol, and 3 holes were made in the skull over the right cerebral hemisphere ~1-2 mm apart, using a handheld microdrill with a 1 mm dental drill bit (Fine Science Tools, North Vancouver, British Columbia, Canada). One microliter of 15% biotin dextran amine (BDA; Molecular Probes) was injected at a depth of 1 mm using a 32 gauge needle attached to a 5 µl Hamilton (Reno, NV) syringe. After 7-10 d, the animals were anesthetized and intracardially perfused with 4% PFA in PBS. The dissected brains and spinal cords were fixed overnight, rinsed in PBS, and allowed to sink in 20% sucrose in PBS before embedding in OCT medium at -20°C for cryosectioning.

Serial sections (10 µm) were mounted on slides coated with poly-L-lysine (Sigma, St. Louis, MO). Sections were air-dried at room temperature for 1 hr, fixed in acetone for 10 min, and air-dried again for 15 min. Sections were washed in PBS/T and incubated in blocking solution (PBS/T and 2% BSA) for 30 min. Streptavidin-Cy3 (Jackson ImmunoResearch, West Grove, PA) was applied at a concentration of 0.5 µg/ml and incubated overnight at 4°C. To assess the injection quality, the forebrains of injected animals were cryosectioned (10 µm), and every third cryosection was stained with streptavidin-Cy3. Slides were mounted using Slow Fade Light Anti-Fade media, and images were captured as above.

In situ hybridization. Postnatal day 0 (P0) brains were fixed overnight at 4°C in 4% PFA in PBS. The paraffin-embedded tissues were sectioned and mounted on Plus slides (Fisher Scientific, Springfield, NJ). Prehybridization washes, hybridization, and posthybridization washes were performed as described previously using ³³P-labeled Unc5h3 and Ntn1 antisense and sense riboprobes (Przyborski et al., 1998). Sections were counterstained with hematoxylin.

Southern blot analysis and reverse transcription-PCR. Genomic DNA (15 µg) was digested by EcoRI and transferred to a nylon filter by standard methods (Osmonics Inc., Minnetonka, MN). Hybridization was performed at 65°C with a [³²P]dCTP-labeled probe corresponding to bp 3149-4266 of the Dcc coding region.

Total or poly(A⁺) RNA was isolated from adult brain (1 µg), and cDNA was prepared using random hexamers and Superscript reverse transcriptase (Invitrogen, Carlsbad, CA) according to the manufacturer's instructions. For PCR, 2 µl of the reverse transcription (RT) reaction was incubated with buffer, dNTPs, 400 nM primers, and ExTaq polymerase (TaKaRa, Tokyo, Japan) according to the manufacturer's directions. Exon structure was based on the human genomic sequence of Dcc (Cho et al., 1994; Cooper et al., 1995). Primer sequences were designed from the Dcc coding sequence (GenBank accession number NM_007831(Cooper et al., 1995): exon 26, 5'-GCCATCCCTGTACCAACACTAGAAAG-3' (bp 3748-3773); exon 27, 5'-CTGGCTGAGACAAAAGCGGT-3' (bp 4111-4092); exon 28, 5'-TGGCTGGATCCTCTGTGGGCT-3' (bp 4252-4232); and exon 29, 5'-TTAAAAGGCTGAGCCTGTGATGG-3' (bp 4344-4322). For genomic PCR, 100 ng of DNA was used in standard PCRs using a 400 nM concentration of each primer corresponding to the intron sequence on either side of exon 29: forward primer, 5'-AGCCTACCAAGACCTCATCCTGAC-3'; and reverse primer, 5'-GCAGTGACAAAGACCCAGAACTATG-3'.

	RESULTS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

The CST is absent from the dorsal funiculus of the spinal cord in Unc5h3^rcm/Unc5h3^rcm mice

The C. elegans UNC-5 and UNC-40 receptors mediate UNC-6-dependent migrations of both axons and cells during development of the nervous system (Hedgecock et al., 1990). Similarly, the vertebrate homologs of unc-6 and unc-40, Ntn1 and Dcc, are necessary for the migration of axons of several commissures and neurons of the pontine nuclei (Serafini et al., 1996; Fazeli et al., 1997). Although the unc-5 homolog Unc5h3 is necessary for proper granule cell migration during cerebellar formation (Ackerman et al., 1997; Przyborski et al., 1998), the role of the vertebrate UNC-5 homologs in the guidance of axons during CNS development has not been established. Thus, we examined several axon tracts known to be under netrin 1 and DCC guidance in Unc5h3^rcm/Unc5h3^rcm mice.

Examination of the corpus callosum and anterior and hippocampal commissures revealed no apparent defects in Unc5h3^rcm/Unc5h3^rcm brains (data not shown), nor were obvious defects in commissural axons observed in transverse sections of spinal cord in mutant mice. However, a dramatic reduction of the size of the dorsal funiculus was seen in Unc5h3^rcm mutant mice (Fig. 1A,B). The dorsal funiculus is composed of three axonal tracts: the ascending gracilis and cuneatus tracts, which enter the spinal cord from the hindlimbs and forelimbs, respectively, and the descending corticospinal tract, which resides in the ventral-most portion of the dorsal funiculus (Joosten, 1990; Stanfield, 1992). When compared with that of wild-type mice, the dorsal funiculus appeared shorter and thinner at the ventral aspect, suggesting CST defects in Unc5h3^rcm/Unc5h3^rcm mice.

View larger version (120K): [in this window] [in a new window]   Figure 1.   CST abnormalities in Unc5h3rcm/Unc5h3rcm mice. The dorsal funiculus (arrows) is shown in transverse sections of cervical spinal cord from wild-type (A, C) and Unc5h3rcm/Unc5h3rcm (B, D) mice stained with LFB and counterstained with cresyl violet (A, B) or antibody against CaM kinase II (C, D). The ipsilateral ventral pyramidal tract crosses the midline dorsally, forming the pyramidal decussation (E, wild type; F, Unc5h3rcm/Unc5h3rcm). Note the thinner decussation of pyramidal tract fibers (arrows) in Unc5h3rcm/Unc5h3rcm brain, and the CST is missing from the dorsal funiculus of the mutant spinal cord. Scale bars, 100 µm.

To more closely examine the CST in mutant animals, immunohistochemistry was performed using an antibody against CaM kinase II, which is expressed on the CST but not the ascending tracts, in the dorsal funiculus (Terashima et al., 1994). Compared with the wild type, there were almost no axons expressing CaM kinase II in the Unc5h3^rcm/Unc5h3^rcm dorsal funiculus, confirming the absence of the CST in these animals (Fig. 1C,D). This defect was also observed in two other mutant alleles of Unc5h3 (data not shown).

CST axons originate from layer V neurons in the cerebral cortex and pass through the internal capsule and over the pontine nuclei in the pons, becoming the distinct ventral ipsilateral bundles constituting the pyramidal tract in the hindbrain (Stanfield, 1992; Gianino et al., 1999). Just before the spinal cord, the ventral CST fibers cross dorsally over the midline, forming the pyramidal decussation, and enter the spinal cord, continuing down the cord as the ventral-most tract in the dorsal funiculus of the spinal cord. The pyramidal tract was examined in adult wild-type and Unc5h3^rcm/Unc5h3^rcm hindbrains stained with the myelin stain Luxol fast blue (LFB). No apparent differences between wild-type and mutant animals were observed in this tract as it passed through the hindbrain (data not shown). The pyramidal decussation, although thinner than that of the wild type, was also present in Unc5h3^rcm/Unc5h3^rcm mice (Fig. 1E,F), but the CST axons could not be traced further in LFB-stained sections. Therefore, the CST disruption in these mice appears to be, at least in part, below the level of the pyramidal decussation.

Unc5h3^rcm mutant CST axons follow two abnormal trajectories

To visualize the path of CST axons we performed anterograde labeling of Unc5h3^rcm/Unc5h3^rcm and wild-type control adult animals. BDA was injected unilaterally into the motor cortex, and 1 week after surgery, brains and spinal cords were dissected and serially sectioned. Examination of coronal sections from BDA-injected mutant and wild-type animals confirmed that the pyramidal tract traversed the hindbrain normally in mutant animals (Fig. 2A,B). However, just before the decussation in the ventral region of the hindbrain of Unc5h3^rcm mutant animals, the pyramidal tract broadened, spreading from medial to lateral (Fig. 2C,D). In wild-type controls, broadening of the pyramidal tract was not observed, and at the level of the pyramidal decussation, the labeled CST axons moved dorsally, crossing the midline (Fig. 2E). In contrast, at the decussation of Unc5h3^rcm mutant mice, two distinct bundles formed, with one bundle in its normal position close to the midline and another axon bundle located in a slightly lateral position (Fig. 2F).

View larger version (95K): [in this window] [in a new window]   Figure 2.   The migration of the CST through the Unc5h3rcm/Unc5h3rcm hindbrain. BDA injected into the motor cortex of wild-type (A, C, E) and Unc5h3rcm/Unc5h3rcm (B, D, F) animals was visualized with streptavidin-Cy3. The trajectories of the ipsilateral pyramidal tract (arrow) appear similar in both wild-type (A) and Unc5h3rcm/Unc5h3rcm (B) mice through the hindbrain before the pyramidal decussation. Just before the pyramidal decussation (C, D), the pyramidal tract broadens (arrows) in Unc5h3rcm/Unc5h3rcm mice, whereas the labeled fibers in the wild-type brain remain bundled (arrow). At the pyramidal decussation, the mutant tract splits (arrows) into medial and lateral fiber bundles (F). The relative level of sections is shown in the accompanying diagrams at the bottom. Scale bars, 100 µm.

Once achieving the dorsal contralateral gray matter, decussated fibers curved into the ventral-most portion of the dorsal funiculus of the wild-type spinal cord (Fig. 3A). Tracing of the more medial bundle of axons in the Unc5h3^rcm/Unc5h3^rcm hindbrain confirmed that, as seen in LFB-stained sections, pyramidal tract axons crossed to the contralateral side (data not shown). However, in contrast to the wild-type CST mice, only a few decussated Unc5h3^rcm/Unc5h3^rcm CST axons were funneled correctly into the contralateral dorsal funiculus, as evidenced by a small amount of staining in the ventral region of the dorsal funiculus of the cervical spinal cord (Fig. 3B). Therefore, most CST fibers that cross the midline in these mutant animals do not enter the dorsal funiculus.

View larger version (58K): [in this window] [in a new window]   Figure 3.   Aberrant CST axon migration in Unc5h3rcm/Unc5h3rcm spinal cord. BDA injected into the motor cortex of wild-type (A, C, E) and Unc5h3rcm/Unc5h3rcm (B, D, F) animals was visualized with streptavidin-Cy3. Labeled contralateral CST fibers (arrow) are present in the wild-type (A) dorsal funiculus (dotted line), whereas only a few labeled fibers are seen in the dorsal funiculus of Unc5h3rcm/Unc5h3rcm animals (B, arrow). In contrast to the wild-type spinal cord, many labeled axons are visible in the contralateral lateral funiculus (C, D, elongated dotted line, arrows) and the dorsal gray matter at the thoracic level of the spinal cord of Unc5h3rcm/Unc5h3rcm mice. The ipsilateral lateral funiculus of the wild-type cervical spinal cord (E) does not contain labeled CST fibers, whereas many labeled ipsilateral CST fibers move from the ventral pyramidal tract into the ipsilateral lateral funiculus of the Unc5h3rcm/Unc5h3rcm spinal cord (F, arrow). The relative level of sections is shown in the accompanying diagrams at the bottom. LF, Contralateral lateral funiculus. Scale bars, 100 µm.

Many decussated labeled axons were observed in the dorsal gray matter adjacent to the dorsal funiculus and just into the white matter of the contralateral lateral funiculus of Unc5h3^rcm/Unc5h3^rcm cervical and thoracic spinal cord, whereas only a few labeled fibers were seen in the lateral white matter of cervical and thoracic spinal cord sections of wild-type controls (Fig. 3C,D). These axons in wild-type mice likely comprise a minor proportion of CST fibers (<5%) that normally split from the main bundle after decussating and instead of entering the dorsal funiculus enter the gray matter of upper cervical spinal cord sections directly (Gianino et al., 1999). However, it is not clear whether this normal pathway of a small percentage of fibers is acting as a permissive default substrate for the aberrant Unc5h3^rcm mutant fibers.

As mentioned above, in Unc5h3^rcm/Unc5h3^rcm mice, a significant proportion of labeled CST axons split from the pyramidal tract just before decussating. These fibers continued to follow an ipsilateral trajectory into the cervical spinal cord, whereas in wild-type mice, this split in the pyramidal tract was not seen, and all of the visible fibers crossed the midline (Fig. 3E,F). Although the mutant fibers remained ipsilateral, they did not stay ventral but eventually entered the lateral funiculus of the spinal cord, which was not observed in the ipsilateral lateral white matter in wild-type animals (Fig. 3E,F). These Unc5h3^rcm/Unc5h3^rcm ipsilateral CST axon fibers were positioned in the outermost region of the lateral funiculus of the spinal cord, away from the spinal gray matter.

To determine whether Unc5h3 is expressed in cortical neurons that generate CST axons, in situ hybridization was performed on the presumptive motor cortex at embryonic day 17.5 (E17.5) and P0 (a time when leading axons have entered the cervical spinal cord). Unc5h3 mRNA was widely expressed in the wild-type cortex, with highest levels in the cortical plate. Low levels of expression were also noted in other regions of the cortex, including layer V, that were not seen in the sense control (Fig. 4A-C; data not shown).

View larger version (90K): [in this window] [in a new window]   Figure 4.   Unc5h3 and DCC expression at P0. In situ hybridization was performed with Unc5h3-specific antisense and sense probes on sagittal sections of P0 wild-type forebrain (A-C). At P0, the neurons of the cortical plate and presumptive layers V and VI express the Unc5h3 transcript (B). A corresponding bright-field photograph of the sections is shown in A, and the Unc5h3-specific sense control showing no signal is shown in C. Immunofluorescence with monoclonal anti-DCC antibody and secondary and tertiary antibody control (without primary antibody) on sagittal sections of P0 wild-type forebrain (D, E) shows that DCC is expressed throughout the cortex (CO). DCC immunofluorescence on sagittal sections of P0 wild-type hindbrain (F, H, overlay) revealed very few DCC-positive fibers. The presumptive CST axons (arrow) were detected by immunofluorescence with antibody to the 160 kDa neurofilament on neighboring sections (G, H, overlay). CC, Corpus callosum; CO, cortex; CP, cortical plate; IZ, intermediate zone; PN, pontine nuclei; V, layer V; VI, layer VI. Scale bars, 100 µm.

Expression of another netrin 1 receptor, DCC, was also detected throughout the wild-type E17.5 and P0 cortex by immunofluorescence (Fig. 4D,E; data not shown). However, we were not able to detect DCC-positive CST fibers as they passed through the hindbrain of E17.5 or P0 animals (Fig. 4F-H; data not shown).

Dcc^kanga: a spontaneous mutant allele of Dcc

Because of the perinatal lethality of the recessive Dcc-targeted mutant allele, it has not been possible to study the role of Dcc in structures that develop postnatally (Fazeli et al., 1997). However, this difficulty has been circumvented by our identification of a spontaneous recessive mutation of Dcc that survives into adulthood.

Adult mice homozygous for a spontaneous mutation that results in the mild to severe inability to maintain an upright position were identified in a production colony. These mice often move their hind legs in a concerted manner, resulting in a somewhat hopping gait; thus this mutation was named kanga. Analysis of brains of these mice demonstrated that both the corpus callosum and the anterior commissure were missing (Fig. 5A,B). In addition, the pontine nuclei were absent from the hindbrain (data not shown).

View larger version (111K): [in this window] [in a new window]   Figure 5.   kanga, a spontaneous mutant allele of Dcc. Luxol fast blue- and cresyl violet-stained frontal sections through the forebrain of wild-type (A), Dcckanga/Dcckanga (B), and Dcctm1Wbg/Dcckanga (C) mice are shown. Note the absence of the corpus callosum (CC) and hippocampal commissures (HC) in the Dcckanga/Dcckanga and Dcctm1Wbg/Dcckanga forebrains. D, Southern blot of EcoRI-digested genomic DNA from wild-type, Dcckanga/+, and Dcckanga/Dcckanga mice probed with cDNA corresponding to a portion of the Dcc coding region (bp 3149-4266). Note the 5.0 and 6.7 kb RFLPs between wild-type and Dcckanga heterozygotes or homozygotes. E, RT-PCR of Dcc transcripts in Dcckanga mutants. Dcc cDNA between exon 26 through the last exon of coding region (exon 29) does not amplify from Dcckanga/Dcckanga (Ex 26-29). However, primers corresponding to exons 26 and 27 or exons 26 and 28 (Ex 26-27, Ex 26-28, respectively) do amplify products from mutant cDNA. F, PCR analysis of exon 29 using primers from the surrounding introns (410 bp) demonstrates that exon 29 is deleted in Dcckanga/Dcckanga genomic DNA. An unrelated fragment from chromosome 3 (320 bp) was amplified as an internal control for the PCR. Scale bar, 100 µm.

A genome scan using polymorphic microsatellite markers was performed on affected F2 animals obtained by intercrossing the F1 progeny from a mapping cross (BALB/cBy.Akr affected × C57BL/6J). Analysis of these results demonstrated linkage of the kanga gene with markers D18Mit9 and D18Mit123 on chromosome 18 near the previously reported position of the Dcc gene (Justice et al., 1992; Stassen et al., 1996). The similarity of brain defects in kanga mutant animals to those reported for the targeted allele of Dcc (Fazeli et al., 1997), combined with the map position of kanga, suggested that kanga was a mutant allele of Dcc. Complementation tests were performed by crossing mice heterozygous for the targeted Dcc allele (Dcc^tm1Wbg) and kanga heterozygotes. Offspring were scored for ataxia at weaning. Ataxic animals were obtained at a frequency of 12% (9 of 75), and kanga was renamed Dcc^kanga. Histological analysis of affected animals from the complementation test confirmed that like Dcc^tm1Wbg mutant mice, the corpus callosum and hippocampal commissure were missing in the forebrain (Fig. 5C).

Southern blot analysis of wild-type and Dcc^kanga/Dcc^kanga genomic DNA revealed restriction fragment length polymorphisms (RFLPs) within the Dcc gene, suggesting a rearrangement in the Dcc^kanga genome (Fig. 5D). To further analyze the mutation in the Dcc^kanga allele, RT-PCR was performed using Dcc coding region-specific primers. No abnormalities in the length or sequence of amplified fragments through exon 26 of the Dcc coding sequence were observed in RT-PCR products from Dcc^kanga/Dcc^kanga cDNA (data not shown). However, when reactions were performed using primers corresponding to exons 26 and 29 (the last coding exon), products were not obtained from mutant cDNA (Fig. 5E). In reactions using the exon 26 primer with primers corresponding to exon 27 or 28, amplified products were obtained from mutant cDNA. Combined, these results suggest that Dcc transcripts in these mutants do not contain exon 29 (Fig. 5E). In agreement, PCRs using primers corresponding to intron sequence surrounding exon 29 failed to amplify from mutant DNA, demonstrating that this exon is deleted in Dcc^kanga/Dcc^kanga genomic DNA (Fig. 5F).

The CST of Dcc^kanga/Dcc^kanga mice is abnormal at the pyramidal decussation

A hopping gait has been reported previously in mice with CST defects (Dottori et al., 1998). Furthermore, DCC is expressed on the CST axons during extension of this tract (Shu et al., 2000). This prompted us to examine the CST of Dcc^tm1Wbg/Dcc^kanga mice from the complementation test and Dcc^kanga/Dcc^kanga mice. Anti-CaM kinase II immunohistochemical staining of transverse sections of spinal cord from adult Dcc^tm1Wbg/Dcc^kanga and Dcc^kanga/Dcc^kanga mice demonstrated that like Unc5h3^rcm/Unc5h3^rcm mice, the CST is absent from the dorsal funiculus of the spinal cord (Fig. 6). However, in contrast to Unc5h3^rcm/Unc5h3^rcm mice, in which a large number of CST axons crossed the midline, LFB staining did not detect decussating CST fibers in the hindbrains of these mutant mice (data not shown).

View larger version (61K): [in this window] [in a new window]   Figure 6.   The CST is absent from the dorsal funiculus of the spinal cord in Dcckanga/ Dcckanga mice. The dorsal funiculus is shown in transverse sections of cervical spinal cord from wild-type (A), Dcctm1Wbg/Dcckanga (B), and Dcckanga/Dcckanga (C) mice stained with antibody against CaM kinase II. CaM kinase II-positive fibers are present in the wild-type CST (arrows) but absent from the dorsal funiculus of mutant mice. Scale bar, 100 µm.

Anterograde tracing of the CST was performed by unilateral injection of BDA, as described above. In the pyramidal tract, Dcc^kanga/Dcc^kanga-labeled CST axons resembled the BDA-injected wild-type control mice (Fig. 7A,B). However, similar to Unc5h3^rcm mutants, the labeled fiber bundle spread medially to laterally just before the level expected of the decussation (Fig. 7C,D), and this broadened tract split into medial and lateral fiber bundles (Fig. 7E,F). However unlike Unc5h3^rcm/Unc5h3^rcm mice, neither axon bundle was observed to decussate in the Dcc^kanga mutant brain (Fig. 8A,B), confirming our LFB staining results. Furthermore, the medial pyramidal tract fiber bundle extended ipsilaterally in the ventral funiculus until at least the upper thoracic spinal cord, and the more lateral fiber bundle moved into the ventral regions of the ipsilateral lateral funiculus in the spinal cord (Fig. 8C,D). These lateral labeled fibers were slightly more ventral in the lateral funiculus relative to the nondecussating Unc5h3^rcm mutant fibers. However, in both Unc5h3^rcm/Unc5h3^rcm and Dcc^kanga/Dcc^kanga mice, CST axons separated from the main CST fiber bundle to project ipsilaterally and laterally into the spinal cord. As expected from our CaM kinase II immunofluorescence results, labeled fibers were not observed in the dorsal funiculus of Dcc^kanga mutant mice (Fig. 8E,F). Thus, mutation of the Dcc gene disrupts the decussation of all CST axons, whereas Unc5h3 mutations only affect the midline crossing of some CST axons.

View larger version (68K): [in this window] [in a new window]   Figure 7.   The CST broadens and splits in the hindbrain of Dcckanga/Dcckanga mice. BDA injected into the motor cortex of wild-type (A, C, E) and Dcckanga/Dcckanga (B, D, F) animals was visualized with streptavidin-Cy3. No differences in the placement of pyramidal tract fibers (arrow) in the hindbrain before the pyramidal decussation were noted between wild-type and mutant mice (A, B). Just before the expected level of the pyramidal decussation in Dcckanga/Dcckanga mice, labeled fibers broaden (arrows), whereas the labeled fibers (arrow) in the wild-type hindbrain remain bundled (C, D). At the pyramidal decussation, the Dcckanga/Dcckanga tract splits (arrows) into medial and lateral fiber bundles (F). The relative level of sections is shown in the diagrams at the bottom. Scale bars, 100 µm.

View larger version (46K): [in this window] [in a new window]   Figure 8.   The CST migrates incorrectly in the spinal cord of Dcckanga/Dcckanga mice. BDA injected into the motor cortex of wild-type (A, C, E) and Dcckanga/Dcckanga (B, D, F) animals was visualized with streptavidin-Cy3. Labeled fibers cross the midline (ML) dorsally in the wild-type pyramidal decussation (A) but do not decussate in Dcckanga/Dcckanga mice (B, arrow). Two bundles of ipsilateral fibers were observed in the Dcckanga/Dcckanga ventral cervical spinal cord (arrows) but not the wild-type spinal cord (C, D). The dorsal funiculus (dotted lines) in the wild type (arrow) but not mutant spinal cord contains labeled contralateral CST axons (E, F). The relative level of sections is shown in the diagrams at the bottom. Scale bars, 100 µm.

Dcc modulates the position of nondecussating CST fibers in the Unc5h3^rcm/Unc5h3^rcm spinal cord

The presence of nondecussating CST fibers in both Unc5h3^rcm and Dcc^kanga mutant mice suggested that these genes might cooperate in guidance of CST fibers. Gene dosage experiments were performed to further investigate this possibility. Mice with a combination of Unc5h3^rcm and Dcc^tm1Wbg mutations were generated, and the position of CST fibers was determined by immunofluorescence analysis with antibodies to CaM kinase II.

In mice homozygous for the Unc5h3^rcm mutation but wild type at the Dcc locus, CST fibers that crossed the midline were found in the contralateral lateral funiculus, whereas those that failed to cross were found in the ipsilateral lateral funiculus but not the ventral funiculus (Figs. 3D,F, 9A). In contrast, only nondecussating fibers were observed in Dcc^kanga/Dcc^kanga mice in the ventral and the lateral funiculus as two separate bundles (Figs. 8D, 9B). Mice homozygous for the Unc5h3^rcm mutation and heterozygous for the Dcc^tm1Wbg mutation had CaM kinase II-positive fibers in both the lateral and ventral funiculus (Fig. 9C; data not shown). A few CaM kinase II-positive axons were also visible in the ventral funiculus of the cervical spinal cord of Unc5h3^rcm/+;Dcc^tm1Wbg/+ mice (Fig. 9D); however, labeled fibers were not seen in mice heterozygous for the Dcc^tm1Wbg mutation (Fig. 9E). Although aberrant CST fibers were found in the ventral funiculus of the cervical spinal cord, they did not continue into the thoracic spinal cord (data not shown). Also, as demonstrated by LFB staining, some CST fibers still crossed the midline at the pyramidal decussation in Unc5h3^rcm/Unc5h3^rcm;Dcc^tm1Wbg/+ mice (Fig. 9F). These results demonstrate that UNC5H3 and DCC act synergistically in the guidance of a portion of CST axons.

View larger version (107K): [in this window] [in a new window]   Figure 9.   CST fibers are present in the ventral funiculus of Unc5h3rcm/Unc5h3rcm;Dcctm1Wbg/+ adult mice. Transverse sections of adult cervical spinal cord from Unc5h3rcm/Unc5h3rcm (A), Dcckanga/Dcckanga (B), Unc5h3rcm/Unc5h3rcm;Dcctm1Wbg/+ (C), Unc5h3rcm/+;Dcctm1Wbg/+ (D), and Dcctm1Wbg/+ (E) mice were stained with anti-CaM kinase II antibody. Note that immunopositive fibers are present in the ventral funiculus (VF; arrow) of Dcckanga/Dcckanga, Unc5h3rcm/Unc5h3rcm;Dcctm1Wbg/+, and Unc5h3rcm/+;Dcctm1Wbg/+ but not Unc5h3rcm/Unc5h3rcm and Dcctm1Wbg/+ mice. Decussating CST fibers (arrows) are still present in Unc5h3rcm/Unc5h3rcm;Dcctm1Wbg/+ mice (F). Scale bars, 100 µm.

Dorsal funiculus defects in Ntn1/Ntn1 mice

Ligand-binding and other assays suggest that both DCC and UNC5H3 are receptors for the guidance molecule netrin 1 (Keino-Masu et al., 1996; Serafini et al., 1996; Leonardo et al., 1997; Przyborski et al., 1998; Stein et al., 2001). Furthermore, Dcc and Ntn1 homozygous mutant mice have similar commissural defects (Serafini et al., 1996; Fazeli et al., 1997). Thus, we investigated whether netrin 1 also mediates CST axon guidance.

In situ hybridization using an Ntn1-specific probe was performed on sections at the level of the pyramidal decussation, which was visualized on an adjacent section with antibody to neurofilament (Fig. 10A). Ntn1 was highly expressed at the midline just ventral to the central canal and adjacent to the point at which the decussating CST axons crossed the midline (Fig. 10B).

View larger version (153K): [in this window] [in a new window]   Figure 10.   Ntn1 is expressed adjacent to the midline crossover point of CST fibers at the pyramidal decussation in P0 mice. The pyramidal decussation of wild-type mice at P0 was visualized by anti-2H3 (160 kDa neurofilament isoform) antibody (A, arrows). In situ hybridization with an Ntn1-specific probe is shown on an adjacent section (B). At P0, Ntn1 expression is observed at the midline immediately below the central canal extending ventrally (arrow) toward the pyramidal decussation. Scale bar, 100 µm.

In addition, we examined the CST of Ntn1/Ntn1 mice. Because these mice die soon after birth (Serafini et al., 1996), it was not possible to trace the CST using BDA. Furthermore, CaM kinase II was not expressed in the dorsal funiculus at P0, making immunohistochemistry with this antibody uninformative. Thus, to visualize the pyramidal decussation and the dorsal funiculus of the cervical spinal cord, we performed immunofluorescence staining with a monoclonal antibody to the 160 kDa isoform of neurofilament. This neurofilament isoform is expressed on descending CST fibers, which at birth have reached the midcervical level of the spinal cord (Stanfield, 1992; Gianino et al., 1999), as well as the two ascending tracts of the dorsal funiculus (Fig. 11A).

View larger version (116K): [in this window] [in a new window]   Figure 11.   The dorsal funiculus is abnormal in Unc5h3rcm/Unc5h3rcm, Dcctm1Wbg/Dcctm1Wbg, and Ntn1/Ntn1 newborn mice. Transverse sections of P0 upper cervical spinal cord from wild type (A), Unc5h3rcm/Unc5h3rcm (B), Dcctm1Wbg/Dcctm1Wbg (C), and Ntn1/Ntn1 (D) mice were immunostained with anti-2H3 antibody. Note the abnormal shape of the ventral portion of the dorsal funiculus (df; A, arrows) is accompanied by many neurofilament-positive misplaced axons throughout the dorsal funicular region of the mutant spinal cords. The pyramidal decussation (arrows) was visualized with anti-2H3 antibody in wild-type mice (E) but was much reduced in Ntn1/Ntn1 newborn mice (F). Scale bars, 100 µm.

Analysis of hindbrain and spinal cord sections of P0 Unc5h3^rcm/Unc5h3^rcm mice confirmed that pyramidal tract axons decussated, but the dorsal funiculus in the cervical spinal cord appeared abnormal even in P0 animals (Fig. 11B). P0 Dcc^tm1Wbg/Dcc^tm1Wbg animals also exhibited abnormalities in the dorsal funiculus, with the expected absence of the pyramidal decussation (Fig. 11C; data not shown).

Similar analysis of the upper cervical spinal cord of P0 Ntn1/Ntn1 mice demonstrated that the dorsal funiculus of these animals was clearly abnormal when compared with the wild-type controls (Fig. 11D). Furthermore, the examination of serial sections of the hindbrain demonstrated that the pyramidal decussation was much reduced in these mice (Fig. 11E,F). Because neurofilament is widely expressed in the hindbrain and spinal cord white matter, it is not clear whether these mice have the aberrant ipsilateral fibers seen in the tracing studies of Unc5h3^rcm/Unc5h3^rcm and Dcc^kanga/Dcc^kanga adult mice. However, these results demonstrate that netrin 1 also regulates CST development and may act, at least in part, via the UNC5H3 and DCC receptors.

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

As axons move through complicated migration pathways, they arrive at intermediate targets that act as choice points to guide their path. Our results demonstrate that netrin 1 and two of its receptors, UNC5H3 and DCC, are necessary at multiple points along the migration of the longest mammalian axonal tract, the corticospinal tract (Fig. 12). In addition to demonstrating that these molecules are necessary for CST axon guidance, our results reveal the existence of at least two groups of CST axons under different genetic regulation at the pyramidal decussation.

View larger version (41K): [in this window] [in a new window]   Figure 12.   CST pathways in Unc5h3rcm/Unc5h3rcm and Dcckanga/Dcckanga mice. A, Normal path of the CST through the brain. Axons from layer V neurons (V) in the cerebral cortex migrate through the internal capsule to the ventral aspect of the brain, where they proceed as parallel ipsilateral fiber bundles on either side of midline. In the hindbrain, these fibers form the pyramidal tract (PT), which crosses midline at the junction of the hindbrain and spinal cord (PD) before entering the dorsal spinal cord. B, CST abnormalities in Unc5h3rcm/Unc5h3rcm and Dcckanga/Dcckanga mice. Normally, the pyramidal tract decussates at the hindbrain-spinal cord junction and continues down the spinal cord in the ventral-most portion of the contralateral dorsal funiculus (dotted line). In Unc5h3rcm/Unc5h3rcm mice, some CST axons in the ipsilateral pyramidal tract separate from the main fiber bundle (solid lines). Although the more medial fiber bundle decussates, it does not move into the dorsal funiculus but instead enters and continues in the contralateral lateral funiculus and dorsal gray matter of the spinal cord. The lateral fiber bundle moves further laterally into the ipsilateral lateral funiculus of the spinal cord. Many CST axons in the ipsilateral pyramidal tract of Dcckanga/Dcckanga mice also separate with neither fiber bundle decussating (elongated dotted lines). The medial fiber bundle continues in the ipsilateral ventral funiculus of the spinal cord. As seen in Unc5h3rcm/Unc5h3rcm mice, the lateral fiber bundle moves further laterally into the ipsilateral lateral funiculus of the spinal cord. Ntn1 expression is present dorsal to the crossover point of the pyramidal decussation.

We describe a new mutant allele of the Dcc gene, Dcc^kanga, which we hypothesize is a hypomorphic allele. In contrast to the perinatal death of mice homozygous for the null Dcc^tm1Wbg-targeted allele (Fazeli et al., 1997), Dcc^kanga homozygotes survive into adulthood. We have demonstrated that the last coding exon of DCC is deleted in the Dcc^kanga mutant genome. Interestingly, this exon encodes a region known as the P3 domain that has been shown by in vitro axon turning assays to be required for both homodimerization of DCC and netrin 1-dependent attraction of axons (Kolodziej et al., 1996; Stein et al., 2001). In addition, results from similar assays demonstrate that the DCC P3 domain is also the target region for binding of the Slit receptor, Robo, which silences the netrin 1 response of DCC-expressing neurons (Stein and Tessier-Lavigne, 2001). After crossing the midline, it is hypothesized that axons upregulate Robo, which in turn binds to the P3 domain of DCC. This binding prevents homodimerization of DCC, thus converting the netrin 1-attractive response of these neurons to one of repulsion from the Slit ligand. CST axons do not cross the midline in Dcc^kanga mutant mice, providing in vivo confirmation of the requirement of the P3 DCC domain in netrin 1-mediated attraction to the midline. However, the absence of decussating CST axons in Dcc^kanga mutant mice precludes the analysis of Robo-DCC interactions in CST development.

The viability of the Dcc^kanga mutant mice allows analysis of the role of Dcc in CST development, which our results show separates into two bundles just before the pyramidal decussation in these mice (Fig. 12). Although both of these bundles move ipsilaterally into the spinal cord, the more medially located bundle approaches but does not cross the midline, whereas the lateral bundle maintains its lateral position. This failure of midline crossing is seen in other commissural axons under netrin 1 regulation in the developing brain (Serafini et al., 1996; Fazeli et al., 1997). In agreement, the CST pyramidal decussation is much reduced in Ntn1/Ntn1 animals. Combined, these data suggest that Dcc controls CST formation, in part via the attraction of DCC-expressing axons toward netrin 1 expressed at the midline in the developing brain and spinal cord (Keino-Masu et al., 1996).

We show that DCC is expressed throughout the cortex, and Unc5h3 is expressed in many layers of the cortex at a time when CST axons are extending. These results are consistent with the cell-autonomous phenotypes seen in mutants of the C. elegans homologs unc-5 and unc-40, suggesting that the effect of mutation of Unc5h3 or Dcc on the CST is a primary defect of the axon pathfinding of CST axons. However, we were unable to detect DCC on neurofilament-positive axons likely to be the CST over the pontine nucleus in the hindbrain. This is consistent with published results showing low levels of DCC expression on CST axons in the forebrain region but not in caudal regions of the brain (Shu et al., 2000). This may indicate that the DCC on these axons is below the levels of detection, as seen previously for EphA4 (Dottori et al., 1998; Leighton et al., 2001). Alternatively, DCC may be expressed only on pioneering axons, which represent only a small minority of the axons in the CST once later-arriving axons have fasciculated. Last, it is possible that this tract, unlike others affected by mutation of Dcc, uses DCC in a non-cell-autonomous manner.

Our results further indicate that netrin 1 is a possible ligand for these receptors by its expression pattern adjacent to the pyramidal decussation and by its abnormal phenotype at the decussation and the dorsal funiculus. The extensive disruption of the dorsal funiculus in all of the mutants examined at P0 suggests that the gracilis and cuneatus tracts, in addition to the CST, may also be abnormal, a possibility requiring further study.

UNC5H3 is necessary for correct guidance of CST axons at two choice points: the pyramidal decussation and the turn into the dorsal funiculus (Fig. 12). Like CST axons in the Dcc^kanga mutant mice, the CST in Unc5h3^rcm/Unc5h3^rcm mice splits into two fiber bundles at the pyramidal decussation. The lateral bundle continues ipsilaterally into the spinal cord. In contrast, the medial bundle decussates, possibly because of netrin 1-mediated attraction of DCC-expressing axons to the midline, but fails to turn into the dorsal funiculus, suggesting that DCC is not sufficient for the dorsal choice point. The final turn of CST axons into the dorsal funiculus takes place from a position lateral and slightly ventral with respect to the dorsal funiculus, suggesting that a repulsive guidance cue for turning axons would be expressed lateral to turning axons. The expression of Ntn1 transcripts at the ventral midline of the P0 pyramidal decussation makes it likely that UNC5H3-expressing axons would not be repulsed from netrin 1 to turn into the dorsal funiculus and instead use another, as yet unknown, repulsive ligand, which is expressed in the region lateral to migrating axons.

The existence of axons that are independently controlled at two separate choice points, the pyramidal decussation and the turn into the dorsal funiculus, may be indicative of two distinct sets of pioneering axons, perhaps arising from particular regions of the cortex. In agreement, mutations in the C. elegans unc-40 and unc-5 genes disrupt the navigation of pioneering axons (Hedgecock et al., 1990; Leung-Hagesteijn et al., 1992). Alternatively, the broadening and eventual bifurcation of the CST in Dcc^kanga and Unc5h3^rcm mutant mice at the expected level of the decussation suggests a role for DCC and UNC5H3 in fasciculation. This possibility is supported by work in C. elegans, which demonstrated that UNC-6 acts as a short-range cue for fasciculating PVP axons (Wadsworth et al., 1996; Culotti and Merz, 1998). Netrin 1 has also been implicated in short-range axonal guidance, directing DCC-expressing retinal ganglion cell axons as they exit the optic disk into the optic nerve (Deiner et al., 1997; de la Torre et al., 1997; Kennedy, 2000). In Drosophila, UNC5 can also demonstrate a short-range function by preventing axons from crossing the midline when expressed ectopically (Keleman and Dickson, 2001). Furthermore, UNC5H3 and DCC have immunoglobulin-like domains in the extracellular regions, and DCC also has extracellular fibronectin type III repeats, domains commonly found in cell adhesion molecules such as L1 and neural cell adhesion molecule (Van Vactor, 1998). Thus, in Unc5h3^rcm mutant and Dcc^kanga mutant mice, it may be that later-arriving axons are selectively defasciculating and making pathfinding errors at the choice point of the pyramidal decussation. In addition, Unc5h3^rcm mutant axons that do cross the midline may defasciculate from pioneering axons at the turn into the dorsal funiculus. Consistent with a role of Unc5h3 in fasciculation, a few labeled axons that may represent pioneering axons were found in the contralateral dorsal funiculus in Unc5h3^rcm/Unc5h3^rcm mice.

Nonallelic noncomplementation was observed between the Unc5h3^rcm and Dcc^tm1Wbg mutations. Although it is not clear whether the fibers in the ventral funiculus of Unc5h3^rcm/Unc5h3^rcm;Dcc^tm1Wbg/+ mice are altered from a normally attractive or repulsive response, a repulsion mechanism is supported by a previous study (Hong et al., 1999). Because both mutations are null alleles, this phenotype is likely attributable to the simultaneous reduction of UNC5H3 and DCC protein levels, not the presence of an altered protein product that binds to and impedes the function of another (Regan and Fuller, 1988; Regan and Fuller, 1990). Although physical interactions of UNC5H3 and DCC have been shown to mediate repulsion when ectopically expressed in Xenopus embryos (Hong et al., 1999), and additional results in C. elegans and Drosophila also suggest interactions (Hamelin et al., 1993; Chan et al., 1996; Colavita and Culotti, 1998; Keleman and Dickson, 2001), the fact that CST axons are not observed in the ventral funiculus of the Unc5h3^rcm mutant mouse makes it unlikely that Dcc^tm1Wbg modulation of the Unc5h3^rcm mutant phenotype is attributable to direct interactions of these protein products. Rather, this result suggests that these molecules may have partially redundant roles in mediating CST guidance at the midline. This suggestion is further strengthened by recent C. elegans studies demonstrating that unc-40 functions in both unc-5-independent and -dependent UNC-6-repulsed distal tip cell migrations (Merz et al., 2001).

The CST has a complicated migration path, likely controlled by many genes in addition to those genes in the netrin 1 signaling pathway, some of which have been identified (Cohen et al., 1998; Dottori et al., 1998; Kullander et al., 2001). Our results indicate that, even within the CST, some axons are apparently under the control of separate guidance mechanisms. Netrin 1, which is expressed in the internal capsule, has been shown to stimulate axonal outgrowth from cultured rat cortical explants (Richards et al., 1997). Interestingly, our analysis of Unc5h3^rcm mutant and Dcc^kanga mutant mice did not reveal defects in the CST as it traversed the hindbrain until just before the decussation. These results suggest that these two gene products are involved only in guidance of CST fibers into the spinal cord, or that absence of these genes is functionally compensated by other family members during the initial outgrowth stages of the CST.

	FOOTNOTES

Received Feb. 6, 2002; revised Sept. 12, 2002; accepted Sept. 16, 2002.

This work was supported by National Institutes of Health (NIH) Grant NS35900 (S.L.A.), NIH Postdoctoral Fellowship NS10757 (J.H.F.), NIH Resource Grant RR01183, and institutional National Cancer Institute core Grant CA34196 (The Jackson Laboratory). We thank Greg Martin and Jennifer Smith for assistance with images, Dr. Terrie Cunliffe-Beamer for surgical training, Chantal Longo-Guess for technical assistance, the Histology Department of The Jackson Laboratory for expertise and training, and Dr. Tom Gridley and Dr. Robert Burgess for critical reading of this manuscript. Dr. Robert Weinberg, Dr. Amin Fazeli, and Dr. Marc Tessier-Lavigne kindly provided Dcc^tm1Wbg and Ntn1 mice and the Ntn1 in situ probe. The 2H3 monoclonal antibody, developed by Drs. T. M. Jessell and J. Dodd, was obtained from the Developmental Studies Hybridoma Bank developed under the auspices of the National Institute of Child Health and Human Development and maintained by the University of Iowa, Department of Biological Sciences (Iowa City, IA).

Correspondence should be addressed to Susan L. Ackerman, The Jackson Laboratory, 600 Main Street, Bar Harbor, ME 04609. E-mail: sla{at}jax.org.

Dr. Przyborski's present address: School of Biological and Biomedical Sciences, University of Durham, South Road, Durham DH1 3LE, UK.

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