Injected in each animal). In addition, there were significant differences in the relative eyespot size across treatments for J. coenia but not for B. anynana. 5E1-injected J. coenia had significantly smaller Triptorelin site eyespots relative to controls for a given wing size (Fig. 5D ). The wing size data combined with the eyespot size data suggests that Hh signaling promotes wing growth in both butterfly species but promotes larger eyespots only in J. coenia. Hh signaling appears to mediate eyespot size in B. anynana only indirectly through its effects on general wing growth, but does not appear to be playing a direct role in eyespot development in this species.DiscussionWe performed functional experiments in butterflies using an antibody that was developed to target Sonic Hh and inhibit this signaling pathway in rats. We showed that this antibody could potentially target other Hh family members, namely Hh from flies and butterflies, because the homologous epitope sequences of all these proteins were quite conserved across species. By performing a Western blot we showed that the antibody targeted protein fragments of the expected size and number as known Hh fragments from D. melanogaster, as well as similar sized fragments from B. anynana butterflies. Finally, we showed that by injecting the antibody into butterfly larvae, the expression of a known target of Hh signaling in the D. melanogaster wing, en/inv [28], was affected in B anynana and J. coenia larval wings. These results collectively indicate that the 5E1 antibody, once injected into butterflies, is likely inhibiting the Hh signaling pathway. The Hh signaling pathway is involved in cell proliferation in many tissues [29?1], and the uncontrolled activation of the Hh signaling pathway has been linked to the growth of tumors in many forms of cancer (reviewed in [32,33]). The specific role of Hh signaling in wing growth was demonstrated in D. melanogaster. Mutants lacking hh function had severely reduced wings [25,34], and reduced en expression [28], whereas hh gain-of-function mutants had enlarged wings with duplicated posterior compartment vein structures [34?6]. The hh knock down experiments of Basler and Struhl [34] were performed in D. melanogaster during the first larval instar, which is the time interval when the anterior/ posterior wing compartments are being established. The comparatively less drastic reduction in wing size resulting from Hh sequestration in B. anynana is likely in part the consequence of manipulations late in development, during the fifth instar, after the anterior-posterior axis has already been established, but just as eyespots begin to differentiate. Changes in wing size resulting from Hh sequestration in B. anynana and J. coenia during the fifth (-)-Indolactam V site instar suggest that Hh signaling continues to play a role in wing growth even during later larval development. While Hh sequestration inhibited wing growth in both butterflies, eyespot trait size reductions independent of wing size were only seen in J. coenia. B. anynana butterflies displayed small wings with proportionately-sized eyespots, whereas J. coenia displayed small wings with disproportionately small eyespots. This indicates that Hh signaling directly affects eyespot development in J. coenia but not in B. anynana, and that Hh signaling promotes larger eyespots in J. coenia. The functional study done here, directly manipulating Hh availability in B. anynana and J. coenia butterflies, has illuminated some surprising di.Injected in each animal). In addition, there were significant differences in the relative eyespot size across treatments for J. coenia but not for B. anynana. 5E1-injected J. coenia had significantly smaller eyespots relative to controls for a given wing size (Fig. 5D ). The wing size data combined with the eyespot size data suggests that Hh signaling promotes wing growth in both butterfly species but promotes larger eyespots only in J. coenia. Hh signaling appears to mediate eyespot size in B. anynana only indirectly through its effects on general wing growth, but does not appear to be playing a direct role in eyespot development in this species.DiscussionWe performed functional experiments in butterflies using an antibody that was developed to target Sonic Hh and inhibit this signaling pathway in rats. We showed that this antibody could potentially target other Hh family members, namely Hh from flies and butterflies, because the homologous epitope sequences of all these proteins were quite conserved across species. By performing a Western blot we showed that the antibody targeted protein fragments of the expected size and number as known Hh fragments from D. melanogaster, as well as similar sized fragments from B. anynana butterflies. Finally, we showed that by injecting the antibody into butterfly larvae, the expression of a known target of Hh signaling in the D. melanogaster wing, en/inv [28], was affected in B anynana and J. coenia larval wings. These results collectively indicate that the 5E1 antibody, once injected into butterflies, is likely inhibiting the Hh signaling pathway. The Hh signaling pathway is involved in cell proliferation in many tissues [29?1], and the uncontrolled activation of the Hh signaling pathway has been linked to the growth of tumors in many forms of cancer (reviewed in [32,33]). The specific role of Hh signaling in wing growth was demonstrated in D. melanogaster. Mutants lacking hh function had severely reduced wings [25,34], and reduced en expression [28], whereas hh gain-of-function mutants had enlarged wings with duplicated posterior compartment vein structures [34?6]. The hh knock down experiments of Basler and Struhl [34] were performed in D. melanogaster during the first larval instar, which is the time interval when the anterior/ posterior wing compartments are being established. The comparatively less drastic reduction in wing size resulting from Hh sequestration in B. anynana is likely in part the consequence of manipulations late in development, during the fifth instar, after the anterior-posterior axis has already been established, but just as eyespots begin to differentiate. Changes in wing size resulting from Hh sequestration in B. anynana and J. coenia during the fifth instar suggest that Hh signaling continues to play a role in wing growth even during later larval development. While Hh sequestration inhibited wing growth in both butterflies, eyespot trait size reductions independent of wing size were only seen in J. coenia. B. anynana butterflies displayed small wings with proportionately-sized eyespots, whereas J. coenia displayed small wings with disproportionately small eyespots. This indicates that Hh signaling directly affects eyespot development in J. coenia but not in B. anynana, and that Hh signaling promotes larger eyespots in J. coenia. The functional study done here, directly manipulating Hh availability in B. anynana and J. coenia butterflies, has illuminated some surprising di.