Early identification of retinal subtypes in the developing, pre-laminated chick retina using the transcription factors Prox1, Lim1, Ap2α, Pax6, Isl1, Isl2, Lim3 and Chx10

European Journal of Histochemistry

Volumn 50, Issue 2, 2006, Pages 147-154

  Edqvist, P H D ^a   Myers, S M ^a   Hallböök, Finn ^a  

^a UPPSALA UNIVERSITY   (Sweden)

Author keywords

Chicken; Migration; Neurogenesis; Retinogenesis

Indexed keywords

TRANSCRIPTION FACTOR; TRANSCRIPTION FACTOR AP2ALPHA; TRANSCRIPTION FACTOR CHX10; TRANSCRIPTION FACTOR ISL1; TRANSCRIPTION FACTOR ISL2; TRANSCRIPTION FACTOR LIM1; TRANSCRIPTION FACTOR LIM3; TRANSCRIPTION FACTOR PAX6; TRANSCRIPTION FACTOR PROX1; UNCLASSIFIED DRUG; ANTIBODY; AVIAN PROTEIN; CHX10 PROTEIN, GALLUS GALLUS; DROSOPHILA PROTEIN; EYE PROTEIN; HOMEODOMAIN PROTEIN; INSULIN GENE ENHANCER BINDING PROTEIN ISL 1; INSULIN GENE ENHANCER BINDING PROTEIN ISL-1; ISL 2 PROTEIN, VERTEBRATE; ISL-2 PROTEIN, VERTEBRATE; LHX1 PROTEIN, HUMAN; LIM3 PROTEIN, DROSOPHILA; NERVE PROTEIN; PAIRED BOX TRANSCRIPTION FACTOR; PROSPERO RELATED HOMEOBOX 1 PROTEIN; PROSPERO-RELATED HOMEOBOX 1 PROTEIN; REPRESSOR PROTEIN; TRANSCRIPTION FACTOR AP 2;

ANIMAL CELL; ANIMAL TISSUE; ANTIBODY LABELING; ARTICLE; CELL FATE; CELL TYPE; CHICK; CONTROLLED STUDY; EMBRYO; IMMUNOHISTOCHEMISTRY; NONHUMAN; PROTEIN EXPRESSION; RETINA CELL; RETINA DEVELOPMENT; ANIMAL; CHICK EMBRYO; CLASSIFICATION; CYTOLOGY; IMMUNOLOGY; METABOLISM; PRENATAL DEVELOPMENT; RETINA; TIME;

ANIMALS; ANTIBODIES; AVIAN PROTEINS; CHICK EMBRYO; DROSOPHILA PROTEINS; EYE PROTEINS; HOMEODOMAIN PROTEINS; IMMUNOHISTOCHEMISTRY; NERVE TISSUE PROTEINS; PAIRED BOX TRANSCRIPTION FACTORS; REPRESSOR PROTEINS; RETINA; TIME FACTORS; TRANSCRIPTION FACTOR AP-2; TRANSCRIPTION FACTORS;

EID: 34347374063     PISSN: 1121760X     EISSN: None     Source Type: Journal    
DOI: None     Document Type: Article

References (43)

1. Adler R. A model of retinal cell differentiation in the chick embryo. Prog Retin Eye Res 2000; 19:529-57.
2. Adler R, Belecky-Adams T, editors. 1999. Cell fate determination in the chick embryo retina. San Diego: Academic Press. 463-74 pp.
3. Akagi T, Inoue T, Miyoshi G, Bessho Y, Takahashi M, Lee JE, et al. Requirement of multiple basic helix-loop-helix genes for retinal neuronal subtype specification. J Biol Chem 2004; 279:28492-8.
4. Alexiades MR, Cepko CL. Subsets of retinal progenitors display temporally regulated and distinct biases in the fates of their progeny. Development 1997; 124:1119-31.
5. Altshuler DM, Turner DL, Cepko CL. Specification of cell type in the vertebrate retina. In: Lam DMK, Shatz CJ, eds. Development of the visual system. Cambridge: MIT Press, 1991, pp 37-58.
6. Belecky-Adams T, Cook B, Adler R. Correlations between terminal mitosis and differentiated fate of retinal precursor cells in vivo and in vitro: analysis with the window-labeling technique. Dev Biol 1996; 178:304-15.
7. Belecky-Adams T, Tomarev S, Li HS, Ploder L, McInnes RR, Sundin O, et al. Pax-6, Prox 1, and Chx10 homeobox gene expression correlates with phenotypic fate of retinal precursor cells. Invest Ophthalmol Vis Sci 1997; 38:1293-303.
8. Bisgrove DA, Godbout R. Differential expression of AP-2alpha and AP-2beta in the developing chick retina: repression of R-FABP promoter activity by AP-2. Dev Dyn 1999; 214:195-206.
9. Callaerts P, Halder G, Gehring WJ. PAX-6 in development and evolution. Annu Rev Neurosci 1997; 20:483-532.
10. Cepko CL. The roles of intrinsic and extrinsic cues and bHLH genes in the determination of retinal cell fates. Curr Opin Neurobiol 1999; 9:37-46.
11. Chen CM, Cepko CL. Expression of Chx10 and Chx10-1 in the developing chicken retina. Mech Dev 2000; 90:293-7.
12. Dyer MA. Regulation of proliferation, cell fate specification and differentiation by the homeodomain proteins prox1, six3, and chx10 in the developing retina. Cell Cycle 2003a; 2:350-7.
13. Dyer MA, Cepko CL. p27Kip1 and p57Kip2 regulate proliferation in distinct retinal progenitor cell populations. J Neurosci 2001; 21:4259-71.
14. Dyer MA, Livesey FJ, Cepko CL, Oliver G. Prox1 function controls progenitor cell proliferation and horizontal cell genesis in the mammalian retina. Nat Genet 2003b; 34:53-8.
15. Edqvist PH, Hallböök F. Newborn horizontal cells migrate bi-directionally across the neuroepithelium during retinal development. Development 2004; 131:1343-51.
16. Fuhrmann S, Chow L, Reh TA. Molecular control of cell diversification in the vertebrate retina. Results Probl Cell Differ 2000; 31:69-91.
17. Galli-Resta L, Resta G, Tan SS, Reese BE. Mosaics of islet-1-expressing amacrine cells assembled by short-range cellular interactions. J Neurosci 1997; 17:7831-8.
18. Galvez JM, Puelles L, Prada C. Inverted (displaced) retinal amacrine cells and their embryonic development in the chick. Exp Neurol 1977; 56:151-7.
19. Green ES, Stubbs JL, Levine EM. Genetic rescue of cell number in a mouse model of microphthalmia: interactions between Chx10 and G1-phase cell cycle regulators. Development 2003; 130:539-52.
20. Hamburger V, Hamilton HL. A series of normal stages in the development of the chick embryo. J. Morphol. 1951; 88:49-92.
21. Hatakeyama J, Tomita K, Inoue T, Kageyama R. Roles of homeobox and bHLH genes in specification of a retinal cell type. Development 2001; 128:1313-22.
22. Hobert O, Westphal H. Functions of LIM-homeobox genes. Trends Genet 2000; 16:75-83.
23. Inoue T, Hojo M, Bessho Y, Tano Y, Lee JE, Kageyama R. Math3 and NeuroD regulate amacrine cell fate specification in the retina. Development 2002; 129:831-42.
24. Kahn AJ. An autoradiographic analysis of the time of appearance of neurons in the developing chick neural retina. Dev Biol 1974; 38:30-40.
25. Kolb H, Nelson R, Ahnelt P, Cuenca N. Cellular organization of the vertebrate retina. In: Kolb H, Ripps H, Wu S, eds. Concepts and challenges in retinal biology: a tribute to John E. Dowling (Progress in Brain Research 131). Amsterdam: Elsevier, 2001, pp 3-26.
26. La Vail MM, Rapaport DH, Rakic P. Cytogenesis in the monkey retina. J Comp Neurol 1991; 309:86-114.
27. Livesey FJ, Cepko CL. Vertebrate neural cell-fate determination: lessons from the retina. Nat Rev Neurosci 2001; 2:109-18.
28. Marquardt T. Transcriptional control of neuronal diversification in the retina. Prog Retin Eye Res 2003; 22:567-77.
29. Marquardt T, Ashery-Padan R, Andrejewski N, Scardigli R, Guillemot F, Gruss P. Pax6 is required for the multipotent state of retinal progenitor cells. Cell 2001; 105:43-55.
30. Masland RH. The fundamental plan of the retina. Nat Neurosci 2001; 4:877-86.
31. Mo Z, Li S, Yang X, Xiang M. Role of the Barhl2 homeobox gene in the specification of glycinergic amacrine cells. Development 2004; 131:1607-18.
32. Ohkawara T, Shintani T, Saegusa C, Yuasa-Kawada J, Takahashi M, Noda M. A novel basic helix-loop-helix (bHLH) transcriptional repressor, NeuroAB, expressed in bipolar and amacrine cells in the chick retina. Brain Res Mol Brain Res 2004; 128:58-74.
33. Rapaport DH, Wong LL, Wood ED, Yasumura D, LaVail MM. Timing and topography of cell genesis in the rat retina. J Comp Neurol 2004; 474:304-24.
34. Rowan S, Cepko CL. Genetic analysis of the homeodomain transcription factor Chx10 in the retina using a novel multifunctional BAC transgenic mouse reporter. Dev Biol 2004; 271:388-402.
35. Rutherford AD, Dhomen N, Smith HK, Sowden JC. Delayed expression of the Crx gene and photoreceptor development in the Chx10-deficient retina. Invest Ophthalmol Vis Sci 2004; 45:375-84.
36. Shirasaki R, Pfaff SL. Transcriptional codes and the control of neuronal identity. Annu Rev Neurosci 2002; 25:251-81.
37. Shkumatava A, Fischer S, Muller F, Strahle U, Neumann CJ. Sonic hedgehog, secreted by amacrine cells, acts as a short-range signal to direct differentiation and lamination in the zebrafish retina. Development 2004; 131:3849-58.
38. Sugihara Y. Displaced amacrine cells in the chick retina: developmental and experimental observations. Okajimas Folia Anat Jpn 1983; 59:363-85.
39. Tsuchida T, Ensini M, Morton SB, Baldassare M, Edlund T, Jessell TM, et al. Topographic organization of embryonic motor neurons defined by expression of LIM homeobox genes. Cell 1994; 79:957-70.
40. Turner DL, Snyder EY, Cepko CL. Lineage-independent determination of cell type in the embryonic mouse retina. Neuron 1990; 4:833-45.
41. Vetter ML, Brown NL. The role of basic helix-loop-helix genes in vertebrate retinogenesis. Semin Cell Dev Biol 2001; 12:491-8.
42. Vogel-Hopker A, Momose T, Rohrer H, Yasuda K, Ishihara L, Rapaport DH. Multiple functions of fibroblast growth factor-8 (FGF-8) in chick eye development. Mechanisms of Development 2000; 94:25-36.
43. Wetts R, Fraser SE. Multipotent precursors can give rise to all major cell types of the frog retina. Science 1988; 239:1142-5.