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Chemosuppression of Retinal Axon Growth by the Mouse Optic Chiasm

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Presentation on theme: "Chemosuppression of Retinal Axon Growth by the Mouse Optic Chiasm"— Presentation transcript:

1 Chemosuppression of Retinal Axon Growth by the Mouse Optic Chiasm
Li-Chong Wang, Rivka A Rachel, Riva C Marcus, Carol A Mason  Neuron  Volume 17, Issue 5, Pages (November 1996) DOI: /S (00)

2 Figure 1 The Optic Chiasm Suppresses Neurite Outgrowth from Retinal Explants but Not from Dorsal Spinal Cord E15 mouse retinal explants (top) were cultured for 48 hr alone (A and C) or at a distance from optic chiasm explants (bottom, Ch) (B and D) in a collagen gel matrix. Retinal explants from VT retina (source of uncrossed axons) grew better in collagen alone than explants from VN retina (source of crossed axons). In chiasm cocultures, both the lengths and numbers of neurites from VT and VN retina were decreased compared with growth in collagen alone. Commissural axons from dorsal spinal cord explants (DSC) were unaffected by chiasm explants (E and F). Scale bar represents 100 μm. Neuron  , DOI: ( /S (00) )

3 Figure 2 Retinal Neurite Growth Is Suppressed by Optic Chiasm but Not by Cortex or Cerebellum Explants The cartoon schematically represents the method used to quantitate retinal neurite outgrowth. An image analysis system was used to determine overall neurite outgrowth (both number and length) in a specified area (represented by the dashed rectangle). Overall neurite outgrowth is expressed as the number of pixels covered by retinal neurites in a given area minus the area covered by the retinal explant (for details, see Experimental Procedures). (A) Neurite outgrowth from the four retinal quadrants differs when cultured in collagen alone, with VT retina growing the best (open bars). Growth of retinal neurites from each quadrant is significantly reduced in retina/chiasm cocultures (asterisk, p < 0.05). (B) Neurite outgrowth of retinal explants cocultured with explants from cerebellum, cortex, or chiasm expressed as a percent of growth in collagen alone. The chiasm data is the same as in (A). Retinal neurite outgrowth was unaffected by cerebellar and cortical explants. In retina/chiasm cocultures, retinal neurite outgrowth was reduced equally (by about 40%) for all four retinal poles. Neuron  , DOI: ( /S (00) )

4 Figure 3 Retinal Neurite Growth Is Suppressed by Chiasmatic but Not by Diencephalic Tissue In cultures where explants of chiasm (Ch) and diencephalon (Dien) were placed to either side of a VT retinal explant (VT), retinal axon growth was specifically suppressed on the side nearest the chiasm. Scale bar represents 100 μm. Neuron  , DOI: ( /S (00) )

5 Figure 4 A Diffusible Factor Mediates the Growth-Suppressing Effect of the Chiasm on Retinal Neurite Growth Camera lucida drawings of retinal explants cultured alone in the presence of a membrane barrier (A and C) or with a chiasm explant positioned on the opposite side of the membrane (B and D). The membrane barrier, which physically separates retinal and chiasmatic neurites, is represented by double lines. Scale bar represents 100 μm. (E) Graph depicting neurite outgrowth by the different retinal poles when retinal explants were cultured in the presence of membrane alone, or in the presence of cerebellum or chiasm explants positioned on the opposite side of the membrane. Retinal neurite growth was inhibited by explants of chiasm but not by cerebellum, confirming both the specificity and the diffusible nature of the chiasmatic growth-suppressing factor. Asterisks indicate p < 0.05. Neuron  , DOI: ( /S (00) )

6 Figure 5 The Chiasm Does Not Reorient the Growth of Retinal Axons
Histograms depicting the turning angle (α) of individual neurites or neurite bundles from VT and VN retinal explants cultured alone (A and B), or with a chiasm explant positioned in front (C and D) or to the side (E and F) of the retinal explant. The y axis gives the total number of retinal neurite bundles counted in 10° intervals (for details, see Experimental Procedures). A schematic diagram of the experimental paradigm for each case is shown on the right side of the figure. The turning angles of neurites from retinal explants positioned either in front or to the side of chiasm explants were not significantly different than those of retinal explants grown in collagen alone (p > 0.05). Furthermore, the distribution of turning angles for VT (source of uncrossed axons) and VN (source of crossed axons) retina were similar. The smaller number of retinal neurite bundles in graphs of VN retina compared with VT retina reflects the differential growth of VT and VN retina in collagen alone (see Results). Neuron  , DOI: ( /S (00) )

7 Figure 6 A Diffusible Chiasmatic Factor(s) Affects the Growth Rate but Not the Initiation of Retinal Neurites Retinal neurites were cocultured with chiasm or cerebellum explants at a distance of approximately 1000 μm and maintained for 3–5 days in culture. A filter (F) was placed close to the chiasm or cerebellum to preclude contact with retinal neurites. (A and B) Schematic diagram of neurite outgrowth. (A) At 17 hr in vitro (i.v.), neurites extended the same relative distance (230 μm) in all three groups. (B) Retinal axons reached the filter by 3 days in vitro (d.i.v.) when grown alone or with cerebellar explants. In chiasm cocultures, retinal axons did not reach the filter until 5 days in vitro. Box 1 represents the area used to determine initial neurite outgrowth (based on the average length of neurites after 17 hr in culture). Box 2 represents the final area covered by retinal neurites after reaching the filter. Both measurements were taken from cultures following fixation after 3–5 days in vitro. (C and D) Histograms depicting initial (C) and final (D) amounts of neurite growth. Neurite growth in the initial phase and at the time the filter was reached was similar in all three groups. Even though retinal axons cultured with the chiasm took longer to reach the filter, the amount of growth was ultimately similar (ANOVA, p > 0.05). Neuron  , DOI: ( /S (00) )

8 Figure 7 Retinal Neurite Outgrowth Is Suppressed by the Floor Plate
Camera lucida drawings of retinal explants grown for 24 hr alone (A and B), or with explants from cortex (Ctx; C and D), chiasm (Ch; E and F), or floor plate (FP; G and H). The explants of cortex, chiasm, and floor plate were positioned either in front (C, E, and G) or to one side (D, F, and H) of the retinal explant. (I) Graph depicting retinal neurite outgrowth from VT or VN retina in the combinations shown in (A)–(H). Both chiasm and floor plate, but not cortex, significantly suppressed retinal neurite outgrowth. Retinal neurite outgrowth was suppressed further by the floor plate than by chiasm explants. Single asterisk, p < 0.05; double asterisks, p < Scale bar represents 100 μm. Neuron  , DOI: ( /S (00) )

9 Figure 8 Netrin-1-Secreting COS Cells Promote, Not Suppress, Retinal Neurite Growth Retinal explants cultured for 24 hr with COS cells transfected with vector alone (−) (A and C) or with netrin-1 (+) (B and D). Scale bar represents 100 μm. (E) Graph depicting retinal neurite outgrowth of VT and VN retina cultured with vector alone, COS(−), or with netrin-1, COS(+), transfected COS cells. Neurite outgrowth was significantly increased by netrin-1-transfected COS cells compared with COS cells transfected with vector alone. (F) Retinal explants were divided in half, and the amount of retinal neurite outgrowth in the halves nearest to and farthest from the netrin-1 or vector alone transfected COS cells graphed. The growth of neurites extending only from the half-retinas nearest to the netrin-1-transfected COS cells was significantly increased. Netrin-1-transfected COS cells did not obviously reorient growth of retinal neurites, suggesting that netrin-1 has a trophic but not tropic effect on retinal neurite outgrowth. Double asterisks indicate p < 0.01. Neuron  , DOI: ( /S (00) )

10 Figure 8 Netrin-1-Secreting COS Cells Promote, Not Suppress, Retinal Neurite Growth Retinal explants cultured for 24 hr with COS cells transfected with vector alone (−) (A and C) or with netrin-1 (+) (B and D). Scale bar represents 100 μm. (E) Graph depicting retinal neurite outgrowth of VT and VN retina cultured with vector alone, COS(−), or with netrin-1, COS(+), transfected COS cells. Neurite outgrowth was significantly increased by netrin-1-transfected COS cells compared with COS cells transfected with vector alone. (F) Retinal explants were divided in half, and the amount of retinal neurite outgrowth in the halves nearest to and farthest from the netrin-1 or vector alone transfected COS cells graphed. The growth of neurites extending only from the half-retinas nearest to the netrin-1-transfected COS cells was significantly increased. Netrin-1-transfected COS cells did not obviously reorient growth of retinal neurites, suggesting that netrin-1 has a trophic but not tropic effect on retinal neurite outgrowth. Double asterisks indicate p < 0.01. Neuron  , DOI: ( /S (00) )

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