Building an asymmetric brain: Development of the zebrafish epithalamus

Seminars in Cell and Developmental Biology

Volumn 20, Issue 4, 2009, Pages 491-497

  Snelson, Corey D ^a   Gamse, Joshua T ^a  

^a VANDERBILT UNIVERSITY   (United States)

Author keywords

Brain asymmetry; Epithalamus; Parapineal; Review; Zebrafish

Indexed keywords

BRAIN ASYMMETRY; BRAIN DEVELOPMENT; BRAIN FUNCTION; EPITHALAMUS; HABENULA; HEMISPHERIC DOMINANCE; INTERPEDUNCULAR NUCLEUS; NONHUMAN; PINEAL BODY; REVIEW; VERTEBRATE; ZEBRA FISH;

DANIO RERIO;

EID: 67549083190     PISSN: 10849521     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.semcdb.2008.11.008     Document Type: Review

References (64)

1. Hobert O., Johnston Jr. R.J., and Chang S. Left-right asymmetry in the nervous system: the Caenorhabditis elegans model. Nat Rev Neurosci 3 (2002) 629
2. Toga A.W., and Thompson P.M. Mapping brain asymmetry. Nat Rev Neurosci 4 (2003) 37
3. Cooke J. Developmental mechanism and evolutionary origin of vertebrate left/right asymmetries. Biol Rev Camb Philos Soc 79 (2004) 377
4. Sherman S.M., and Spear P.D. Organization of visual pathways in normal and visually deprived cats. Physiol Rev 62 (1982) 738
5. Cantalupo C., and Hopkins W.D. Asymmetric Broca's area in great apes. Nature 414 (2001) 505
6. Vallortigara G., Rogers L.J., and Bisazza A. Possible evolutionary origins of cognitive brain lateralization. Brain Res Brain Res Rev 30 (1999) 164
7. McManus C. Right hand, left hand. 1st ed. (2002), Weidenfeld and Nicolson, London
8. Geschwind N., and Levitsky W. Human brain: left-right asymmetries in temporal speech region. Science 161 (1968) 186
9. Eckert M.A., and Leonard C.M. Developmental disorders: dyslexia. In: Hugdahl K., and Davidson R.J. (Eds). The assymetrical brain (2004), The MIT Press, Cambridge 651-680
10. Habib M., and Robichon F. Structural correlates of brain asymmetry: studies in left-handed and dyslexic individuals. In: Hugdahl K., and Davidson R.J. (Eds). The assymetrical brain (2004), The MIT Press, Cambridge 681-716
11. Green M.F., Sergi M.J., and Kern R.S. The laterality of schizophrenia. In: Hugdahl K., and Davidson R.J. (Eds). The assymetrical brain (2004), The MIT Press, Cambridge 743-772
12. Lennox B.R., Park S.B., Jones P.B., and Morris P.G. Spatial and temporal mapping of neural activity associated with auditory hallucinations. Lancet 353 (1999) 644
13. Purves D., Augustine G.J., Fitzpatrick D., Katz L.C., LaMantia A.-S., McNamara J.O., and Williams S.M. Early brain development. In: Purves D., et al. (Ed). Neuroscience (2001), Sinauer Associates, Inc., Sunderland, MA
14. Concha M.L., and Wilson S.W. Asymmetry in the epithalamus of vertebrates. J Anat 199 (2001) 63
15. Driever W., Stemple D., Schier A., and Solnica-Krezel L. Zebrafish: genetic tools for studying vertebrate development. Trends Genet 10 (1994) 152
16. Snelson C.D., Burkart J.T., and Gamse J.T. Formation of the asymmetric pineal complex in zebrafish requires two independently acting transcription factors. Dev Dyn (2008)
17. Snelson C.D., Santhakumar K., Halpern M.E., and Gamse J.T. Tbx2b is required for the development of the parapineal organ. Development 135 (2008) 1693
18. Concha M.L., Burdine R.D., Russell C., Schier A.F., and Wilson S.W. A nodal signaling pathway regulates the laterality of neuroanatomical asymmetries in the zebrafish forebrain. Neuron 28 (2000) 399
19. Gamse J.T., Shen Y.C., Thisse C., Thisse B., Raymond P.A., Halpern M.E., et al. Otx5 regulates genes that show circadian expression in the zebrafish pineal complex. Nat Genet 30 (2002) 117
20. Yanez J., and Anadon R. Afferent and efferent connections of the habenula in the rainbow trout (Oncorhynchus mykiss): an indocarbocyanine dye (DiI) study. J Comp Neurol 372 (1996) 529
21. Aizawa H., Bianco I.H., Hamaoka T., Miyashita T., Uemura O., Concha M.L., et al. Laterotopic representation of left-right information onto the dorso-ventral axis of a zebrafish midbrain target nucleus. Curr Biol 15 (2005) 238
22. Gamse J.T., Kuan Y.S., Macurak M., Brosamle C., Thisse B., Thisse C., et al. Directional asymmetry of the zebrafish epithalamus guides dorsoventral innervation of the midbrain target. Development 132 (2005) 4869
23. Liang J.O., Etheridge A., Hantsoo L., Rubinstein A.L., Nowak S.J., Izpisua Belmonte J.C., et al. Asymmetric nodal signaling in the zebrafish diencephalon positions the pineal organ. Development 127 (2000) 5101
24. Gamse J.T., Thisse C., Thisse B., and Halpern M.E. The parapineal mediates left-right asymmetry in the zebrafish diencephalon. Development 130 (2003) 1059
25. Liu Y., and Halloran M.C. Central and peripheral axon branches from one neuron are guided differentially by Semaphorin3D and transient axonal glycoprotein-1. J Neurosci 25 (2005) 10556
26. Carl M., Bianco I.H., Bajoghli B., Aghaallaei N., Czerny T., and Wilson S.W. Wnt/Axin1/beta-catenin signaling regulates asymmetric nodal activation, elaboration, and concordance of CNS asymmetries. Neuron 55 (2007) 393
27. Kuan Y.S., Yu H.H., Moens C.B., and Halpern M.E. Neuropilin asymmetry mediates a left-right difference in habenular connectivity. Development 134 (2007) 857
28. Yanez J., Pombal M.A., and Anadon R. Afferent and efferent connections of the parapineal organ in lampreys: a tract tracing and immunocytochemical study. J Comp Neurol 403 (1999) 171
29. Meiniel A., and Collin J.P. The pineal complex of the ammocoete (Lampetra planeri). Connections of the pineal and parapineal organs with the epithalamic roof. Z Zellforsch Mikrosk Anat 117 (1971) 354
30. Hafeez M.A., and Merhige M.E. Light and electron microscopic study on the pineal complex of the coelacanth, Latimeria chalumnae Smith. Cell Tissue Res 178 (1977) 249
31. Solessio E., and Engbretson G.A. Antagonistic chromatic mechanisms in photoreceptors of the parietal eye of lizards. Nature 364 (1993) 442
32. Solessio E., and Engbretson G.A. Electroretinogram of the parietal eye of lizards: photoreceptor, glial, and lens cell contributions. Vis Neurosci 16 (1999) 895
33. Kemali M., Guglielmotti V., and Fiorino L. The asymmetry of the habenular nuclei of female and male frogs in spring and in winter. Brain Res 517 (1990) 251
34. Gurusinghe C.J., and Ehrlich D. Sex-dependent structural asymmetry of the medial habenular nucleus of the chicken brain. Cell Tissue Res 240 (1985) 149
35. Zilles K., Schleicher A., and Wingert F. Quantitative growth analysis of limbic nuclei areas fresh volume in diencephalon and mesencephalon of an albino mouse ontogenic series. III. Nucleus interpe-uncularis. J Hirnforsch 17 (1976) 21
36. Wree A., Zilles K., and Schleicher A. Growth of fresh volumes and spontaneous cell death in the nuclei habenulae of albino rats during ontogenesis. Anat Embryol (Berl) 161 (1981) 419
37. Christoph G.R., Leonzio R.J., and Wilcox K.S. Stimulation of the lateral habenula inhibits dopamine-containing neurons in the substantia nigra and ventral tegmental area of the rat. J Neurosci 6 (1986) 613
38. Park M.R. Monosynaptic inhibitory postsynaptic potentials from lateral habenula recorded in dorsal raphe neurons. Brain Res Bull 19 (1987) 581
39. Herkenham M., and Nauta W.J. Afferent connections of the habenular nuclei in the rat. A horseradish peroxidase study, with a note on the fiber-of-passage problem. J Comp Neurol 173 (1977) 123
40. Kimmel C.B., Warga R.M., and Schilling T.F. Origin and organization of the zebrafish fate map. Development 108 (1990) 581
41. Woo K., Shih J., and Fraser S.E. Fate maps of the zebrafish embryo. Curr Opin Genet Dev 5 (1995) 439
42. Woo K., and Fraser S.E. Order and coherence in the fate map of the zebrafish nervous system. Development 121 (1995) 2595
43. Kozlowski D.J., Murakami T., Ho R.K., and Weinberg E.S. Regional cell movement and tissue patterning in the zebrafish embryo revealed by fate mapping with caged fluorescein. Biochem Cell Biol 75 (1997) 551
44. Staudt N., and Houart C. The prethalamus is established during gastrulation and influences diencephalic regionalization. PLoS Biol 5 (2007) e69
45. Masai I., Heisenberg C.P., Barth K.A., Macdonald R., Adamek S., and Wilson S.W. floating head and masterblind regulate neuronal patterning in the roof of the forebrain. Neuron 18 (1997) 43
46. Heisenberg C.P., Houart C., Take-Uchi M., Rauch G.J., Young N., Coutinho P., et al. A mutation in the Gsk3-binding domain of zebrafish Masterblind/Axin1 leads to a fate transformation of telencephalon and eyes to diencephalon. Genes Dev 15 (2001) 1427
47. Barth K.A., Miklosi A., Watkins J., Bianco I.H., Wilson S.W., and Andrew R.J. fsi zebrafish show concordant reversal of laterality of viscera, neuroanatomy, and a subset of behavioral responses. Curr Biol 15 (2005) 844
48. The emergence of the ectoderm: central nervous system and epidermis. In: Gilbert S.F. (Ed). Developmental Biology. 8th ed. (2006), Sinauer Associates Inc., Sunderland, MA 373-406
49. Hill C. Development of the epiphysis in Coregonus albus. J Morphol 5 (1891) 503
50. Concha M.L., Russell C., Regan J.C., Tawk M., Sidi S., Gilmour D.T., et al. Local tissue interactions across the dorsal midline of the forebrain establish CNS laterality. Neuron 39 (2003) 423
51. Gothilf Y., Coon S.L., Toyama R., Chitnis A., Namboodiri M.A., and Klein D.C. Zebrafish serotonin N-acetyltransferase-2: marker for development of pineal photoreceptors and circadian clock function. Endocrinology 140 (1999) 4895
52. Cooper M.S., and D'Amico L.A. A cluster of noninvoluting endocytic cells at the margin of the zebrafish blastoderm marks the site of embryonic shield formation. Dev Biol 180 (1996) 184
53. Raya A., and Belmonte J.C. Left-right asymmetry in the vertebrate embryo: from early information to higher-level integration. Nat Rev Genet 7 (2006) 283
54. Wright C.V., and Halpern M.E. Specification of left-right asymmetry. Results Probl Cell Differ 40 (2002) 96
55. Hamada H., Meno C., Watanabe D., and Saijoh Y. Establishment of vertebrate left-right asymmetry. Nat Rev Genet 3 (2002) 103
56. Long S., Ahmad N., and Rebagliati M. The zebrafish nodal-related gene southpaw is required for visceral and diencephalic left-right asymmetry. Development 130 (2003) 2303
57. Inbal A., Kim S.H., Shin J., and Solnica-Krezel L. Six3 represses nodal activity to establish early brain asymmetry in zebrafish. Neuron 55 (2007) 407
58. Zhang J., Talbot W.S., and Schier A.F. Positional cloning identifies zebrafish one-eyed pinhead as a permissive EGF-related ligand required during gastrulation. Cell 92 (1998) 241
59. Halpern M.E., Liang J.O., and Gamse J.T. Leaning to the left: laterality in the zebrafish forebrain. Trends Neurosci 26 (2003) 308
60. Bisgrove B.W., Essner J.J., and Yost H.J. Multiple pathways in the midline regulate concordant brain, heart and gut left-right asymmetry. Development 127 (2000) 3567
61. Gilmour D.T., Maischein H.M., and Nusslein-Volhard C. Migration and function of a glial subtype in the vertebrate peripheral nervous system. Neuron 34 (2002) 577
62. Aizawa H., Goto M., Sato T., and Okamoto H. Temporally regulated asymmetric neurogenesis causes left-right difference in the zebrafish habenular structures. Dev Cell 12 (2007) 87
63. Hamada H., Meno C., Saijoh Y., Adachi H., Yashiro K., Sakuma R., et al. Role of asymmetric signals in left-right patterning in the mouse. Am J Med Genet 101 (2001) 324
64. Zhu L., Marvin M.J., Gardiner A., Lassar A.B., Mercola M., Stern C.D., et al. Cerberus regulates left-right asymmetry of the embryonic head and heart. Curr Biol 9 (1999) 931