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First published online 3 August 2005
doi: 10.1242/dev.01960

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A bHLH transcriptional network regulating the specification of retinal ganglion cells

¹ University of Lausanne, Eye Hospital Jules Gonin and Institute for Research in Ophthalmology, 15 avenue de France, 1004 Lausanne, Switzerland
² University of Geneva, Sciences II, Biochemistry Department, 30 quai Ernest-Ansermet, 1211 Geneva, Switzerland
³ Polish Academy of Sciences, Medical Research Center, Department of Endocrinology, ul. Banacha 1a, 02-097 Warsaw, Poland
⁴ Medical Center of Postgraduate Education, Department of Clinical Biochemistry, Marymoncka 99, 01-813 Warsaw, Poland

View larger version (83K): [in a new window]   Fig. 1. Several bHLH factors pattern the early retinal neuroepithelium. (A) At stage 14, HES1 transcripts accumulate in discrete domains in the eyecup (ec) and neural tube (nt). There is no detectable accumulation of HES1 transcripts in the central region (red bracket) of the presumptive retina. (B,C) The first ATH5- and NGN2-expressing cells are detected in the central retina (nr) at stage 15. (D) At stage 16, ASH1 transcripts are not detected in retina. (E) At stage 17, a robust accumulation of HES1 transcripts is taking place throughout the peripheral retina (J). In the central retina, a few cells located on the vitreous side express HES1 at a high level (arrowheads in E,I). (F,K) Most cells in the central retina express ATH5 and those expressing ATH5 strongly are mostly located on the vitreous side. (H) At stage 18, the sparse cells expressing Neuro M are scattered across the central retina (arrowhead in M). There are no cells expressing ATH5 or Neuro M in the HES1 domain (F,H,L,N). (O) Quantification of in situ hybridization. Adjacent retinal sections were hybridized with the indicated bHLH riboprobes at stage 18. The ATH5, Neuro M and NGN2 domains coincide in the central retina and they abut on the peripheral HES1 domain. ASH1 is detected in an annular sector (G, brackets) at the interface between the HES1 and ATH5 domains. l, lens. Scale bar: 140 µm in A; 80 µm in B,C; 100 µm in D-H.

View larger version (97K): [in a new window]   Fig. 2. Growth of the retina is accompanied by changes in the patterning of progenitor cells. (A,B,E) Between stages 18 and 26, the ATH5 domain expands in register with the threefold increase in retina diameter. (C) HES1 transcripts are abundant at the periphery and sparse in the central region. Scattered cells expressing HES1 at a high level are detected in the central retina (arrowheads in L). The HES1 and ATH5 expression domains are complementary (B,C), but the anterior margin of the ATH5 domain overlaps the posterior HES1 region, where HES1 transcript levels are decreasing (brackets in H,I). ATH5 and NGN2 transcripts accumulate in the posterior retina (B,D). The NGN2 domain extends beyond that of ATH5 (brackets in J,K). At stage 26, ASH1- and ATH5-expressing cells are interspersed in the posterior retina. ASH1 extends beyond ATH5 (arrowheads in E,F). At stage 30, ATH5 transcripts are distributed throughout the whole retina (G), except at the ciliary margin (arrows). ATH5 transcripts are not evenly distributed across the retina. They are abundant on the ventricular side of the proliferative zone (pz) (inset in G). At stage 30, HES1 expression is downregulated both in the peripheral and in the central retina (M). Sections in L and M were counterstained with Toluidine Blue. Scale bar: 380 µm in A-G; 40 µm in L; 60 µm in M; 240 µm in H,I; 150 µm in J,K.

View larger version (103K): [in a new window]   Fig. 3. Activity of the electroporated ATH5 promoter in stage 22-23 retina. (A) When controlled by the ubiquitous CMV promoter, GFP and lac reporters are both expressed in the electroporated peripheral retina. (B-F) The ATH5-promoter/lac and the CMV-promoter/GFP reporter plasmids were electroporated alone (B,C), in combination with a NGN2 expression vector (D,E) or in combination with NGN2 and HES1 expression vectors (F). (B) GFP-positive cells are distributed throughout the peripheral (p) and central (c) retina, whereas lac+ cells are confined to the central region (arrowhead). (C) lac+ cells (arrowheads) are sparse in the central retina. (D) Overexpression of NGN2 increases the proportion of lac+ cells in the central, but not in the peripheral retina (arrowhead in E). (F) No lac+ cells were detected when both NGN2 and HES1 were overexpressed in the central retina. Data presented in each panel are representative of at least five independent experiments. l, lens. Scale bar: 170 µm in A; 120 µm in B; 30 µm in C; 40 µm in D,F; 80 µm in E.

View larger version (42K): [in a new window]   Fig. 4. Transcriptional analysis of ATH5-expressing single cells. Stage 22-23 (E3.5) retinal cells were transfected with an ATH5-promoter/GFP-reporter plasmid either singly or in combination with a vector expressing NGN2. They were cultured for either 24 (E4.5) or 48 hours (E5.5). Stage 26 (E5) retinal cells were transfected with the ATH5-promoter/GFP-reporter plasmid and cultured for 24 hours (E6). Individual GFP-positive cells were collected and processed for single-cell RT-PCR using the primers listed in Table S1 (see supplementary material). (A) Representative transcriptional profiles obtained with a set of 39 cells from the five groups generated by the experiment, as identified by the colour code in B. RT-PCRs of total RNA isolated from E8 retina (NRE8) were used as positive controls for each set of primers. (C) Ratios of HES1-, Neuro M-, Delta 1- and ASH1-positive cells to the total number of cells tested for expression of these genes.

View larger version (34K): [in a new window]   Fig. 5. Co-expression of RGC-specific genes and bHLH transcription factors in newborn RGCs and RGC precursors. Cells were transfected with an ATH5-promoter/GFP-reporter plasmid at stage 26 (E5) and cultured for 24 hours. (A, right) Transcriptional profile of a newborn RGC. This neuron-like GFP-positive cell (left) expresses ATH5, Neuro M, ß3 and BRN3C, but not ASH1. (B) ATH5-expressing cells do not always co-express Neuro M, ß3 and BRN3C. (C) Colocalization of ß3 promoter activity and HES1 or Neuro M expression. Cells were transfected with a ß3-promoter/lacZ-reporter plasmid at stage 24. After 24 hours in culture, lacZ-expression was revealed and cells were processed for in situ hybridization with (a) HES1- or (b,c) Neuro M-specific riboprobes. Arrowhead in a indicates a double-labelled cell.

View larger version (37K): [in a new window]   Fig. 6. Regulation of the ATH5 promoter during retinogenesis. (A) Retinal cells isolated at stages 22 (E3) to 37 (E12) were transfected with an ATH5-promoter/CAT-reporter plasmid singly or in combinations with ATH5 and/or NGN2 expression vectors. Cells were assayed for CAT activity 24 hours after transfection. ATH5 transcription is passing through three phases in the course of retinogenesis. During the first phase (HH22-HH24), the promoter is weakly active and responds strongly to NGN2 overexpression, except in the presence of ATH5. During the second phase (HH25-HH30), upregulation of promoter activity coincides with a transient increase in ATH5 mRNA (curve). ATH5 and NGN2 both enhance promoter activity and ATH5 becomes dominant over NGN2. The third phase (HH34 and beyond) sees a decrease in ATH5 mRNA and is marked by the inability of either proneural protein to transactivate the promoter. (B) Retinal cells isolated at stages 22-23 and 29-30 were transfected with an ATH5-promoter/lacZ-reporter plasmid singly or in combinations with NGN2 or ATH5 expression vectors. lac+ cells were counted after 24 hours in culture. The number of lac+ cells obtained upon transfection with a control SV40-promoter/lacZ-reporter plasmid at each stage is set at 100 and cell numbers are given relative to this value. (C) Schematic representation of promoter activity as revealed by X-gal and CAT assays. Approximately 30% of cells express ATH5 at stages 22-23 and 29-30. The horizontal arrows indicate average promoter activity as measured by CAT assay, the open arrowhead marks the threshold for X-gal detection. At stage 22-23, promoter activity is low and only one in 30 ATH5-expressing cells is detected by X-gal. Overexpression of NGN2 increases promoter activity 10-fold but only six out of 30 ATH5-expressing cells are stained with X-gal. At stage 29-30, the whole population of ATH5-expressing cells is stained with X-GAL upon ATH5 overexpression. (D) At stage 22-23, most cells are weakly stained with X-GAL (arrowheads in a). Overexpression of NGN2 strongly enhances promoter activity (b) and the number of X-gal stained cells. At stage 29-30, cells display strong promoter activity (c) and overexpression of ATH5 enhances staining intensity (d).

View larger version (38K): [in a new window]   Fig. 7. HES1 exerts a dominant-negative effect upon the ATH5 promoter. (A) Retinal cells at stages 22-23 or 29-30 were transfected with an ATH5-promoter/CAT-reporter plasmid alone or with different combinations of the ATH5, NGN2 and HES1 expression vectors. NGN2 and HES1 expression vectors were co-transfected in different ratios, as indicated. (B) Peripheral and central regions of retina were dissected at stage 22-23. They were electroporated with NGN2 and control expression vectors and cultured as explants for 24 hours. The presence of ATH5 mRNA was detected by northern blot hybridisation. Overexpression of NGN2 upregulated ATH5 expression in the central but not in the peripheral retina. (C) Retinal cells at stages 24 or 29-30 were transfected with an ATH5-promoter/lacZ-reporter plasmid singly or in combinations with ATH5 or NGN2 expression vectors. lac+ cells were revealed and processed for in situ hybridization with a HES1-specific riboprobe. Overexpression of NGN2 increased the relative number of double-labelled cells, indicating that the NGN2 protein can activate the ATH5 promoter in cells that express HES1 (a), unlike the ATH5 protein (b).

View larger version (85K): [in a new window]   Fig. 8. ATH5 expression is upregulated during the last S phase. (A) Retinal cells isolated at stages 22-23 and 28-29 were transfected with an ATH5-promoter/lacZ-reporter plasmid singly or in combinations with NGN2 or ATH5 expression vectors and pulse-labelled with [3H]-thymidine at the end of a 24-hour culture period. (Left) The number of lac+ cells counted when the reporter plasmid was transfected alone is set at 1. (Right) At stage 22-23, overexpression of NGN2 enhances promoter activity in proliferating cells (a) and increases the pool of nonradioactive cells whose ATH5 promoter is upregulated (b). At stage 28-29, lac+ cells whose promoter is strongly upregulated are unlabelled (d). The detection of double-labelled cells (c) and their increased number upon ATH5 overexpression indicate that ATH5 promoter activity is upregulated during the S phase. (B, left) A retina at stage 29-30 was pulse-labelled for 45 minutes with BrdU and chased for 15 minutes. Transverse sections were hybridized with an ATH5-specific riboprobe. Most BrdU-positive cells are in S phase and their nuclei are located on the vitreous side (vi) of the pz. ATH5 transcripts accumulate on the ventricular side (ve) of the pz in the region where cells are in the G1 and G2 phases of the cell cycle. A few BrdU-positive nuclei are located in this region (arrowheads). (Right) Schematic of mitosis in the pz. Scale bar: 40 µm.

View larger version (27K): [in a new window]   Fig. 9. Interacting transcriptional patterns as retinal cells go through three consecutive phases during the conversion of progenitors into newborn RGCs.