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First published online January 10, 2007
doi: 10.1242/10.1242/dev.02750

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Neurogenic role of Gcm transcription factors is conserved in chicken spinal cord

Laurent Soustelle^1,*, Françoise Trousse^2,*, Cécile Jacques¹, Julian Ceron^1,, Philippe Cochard², Cathy Soula² and Angela Giangrande^1,

¹ Institut de Génétique et de Biologie Moléculaire et Cellulaire, CNRS/INSERM/ULP, B.P.10142, 67404 Illkirch Cedex, C.U. de Strasbourg, France.
² Centre de Biologie du Développement, UMR5547 CNRS/UPS, Université Paul Sabatier, 118 Route de Narbonne, 31062 Toulouse Cedex, France.

Author for correspondence (e-mail: angela{at}titus.u-strasbg.fr)

Accepted 20 November 2006

	SUMMARY

TOP SUMMARY INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
Although glial cells missing (gcm) genes are known as glial determinants in the fly embryo, the role of vertebrate orthologs in the central nervous system is still under debate. Here we show for the first time that the chicken ortholog of fly gcm (herein referred to as c-Gcm1), is expressed in early neuronal lineages of the developing spinal cord and is required for neural progenitors to differentiate as neurons. Moreover, c-Gcm1 overexpression is sufficient to trigger cell cycle exit and neuronal differentiation in neural progenitors. Thus, c-Gcm1 expression constitutes a crucial step in the developmental cascade that prompts progenitors to generate neurons: c-Gcm1 acts downstream of proneural (neurogenin) and progenitor (Sox1-3) factors and upstream of NeuroM neuronal differentiation factor. Strikingly, this neurogenic role is not specific to the vertebrate gene, as fly gcm and gcm2 are also sufficient to induce the expression of neuronal markers. Interestingly, the neurogenic role is restricted to post-embryonic stages and we identify two novel brain neuronal lineages expressing and requiring gcm genes. Finally, we show that fly gcm and the chick and mouse orthologs induce expression of neural markers in HeLa cells. These data, which demonstrate a conserved neurogenic role for Gcm transcription factors, call for a re-evaluation of the mode of action of these genes during evolution.

Key words: Drosophila melanogaster, Chicken, glial cells missing, Neurogenesis

	INTRODUCTION

TOP SUMMARY INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
Glial cells missing transcription factors (Gcm and Gcm2) are considered as the glial determinants in the fly embryonic central nervous system (CNS) (for a review, see Van De Bor and Giangrande, 2002). Their absence leads to glia-to-neuron transformation, and ectopic expression of gcm or gcm2 leads to differentiation of supernumerary glia at the expense of neurons, indicating a role as a molecular switch between neuronal and glial fates (Alfonso and Jones, 2002; Hosoya et al., 1995; Jones et al., 1995; Kammerer and Giangrande, 2001; Vincent et al., 1996).

Although structurally conserved throughout evolution, the function of these two genes in vertebrate gliogenesis has remained elusive (Altshuller et al., 1996; Anson-Cartwright et al., 2000; Basyuk et al., 1999; Kanemura et al., 1999; Kim et al., 1998; Schreiber et al., 2000). Previous studies have shown that Gcm1- deficient mice die during embryogenesis owing to developmental defects of the placenta (Anson-Cartwright et al., 2000; Schreiber et al., 2000), whereas Gcm2-deficient mice are viable but lack a parathyroid gland (Gunther et al., 2000). No defects were found in the CNS; however, Gcm1-knockout mice die by E10, thereby preventing functional analyses in the nervous system. Moreover, RT-PCR experiments revealed the presence of Gcm1 transcripts in mouse brain, starting from E12 (Iwasaki et al., 2003).

We and others have recently shown that fly gcm genes are required in a specific neuronal population of the larval visual system (Chotard et al., 2005; Yoshida et al., 2005). During optic lobe development, neuroblasts produce lamina precursor cells (LPCs), which divide once to produce lamina neurons (Selleck and Steller, 1991). gcm and gcm2 are coexpressed in LPCs and, in their absence, lamina neurons are not produced, indicating that these two genes are required in neuronal precursors to induce neuronal fate (Chotard et al., 2005; Yoshida et al., 2005). This puzzling observation raises the possibility that vertebrate gcm genes might also be required for neuronal differentiation, and calls for the role of gcm genes in evolution to be re-evaluated.

We here show that the chicken ortholog of fly gcm (herein referred to as c-Gcm1), but not the chicken ortholog of fly gcm2 (herein referred to as c-Gcm2), is expressed in early neuronal lineages of the developing chick spinal cord. Moreover, full neuronal differentiation is prematurely induced upon c-Gcm1 overexpression and inhibited upon blocking its pathway, thus revealing a neurogenic, rather than a gliogenic, role. We show that c-Gcm1 is required for precursors to enter the post-mitotic state, acting downstream of the neurogenin and Sox1-3 genes and upstream of NeuroM. Thus, we demonstrate for the first time that a vertebrate gcm gene is expressed and required in the CNS. We also show that, in flies, the neurogenic role of the gcm genes extends to the newly identified interneurons of the central brain. Moreover, gcm or gcm2 overexpression can induce ectopic neuronal differentiation after embryonic development. Finally, we show that fly, chick and mouse gcm genes induce expression of neuronal and glial markers in transfected HeLa cells. Thus, gcm genes have a double potential that is conserved during evolution.

	MATERIALS AND METHODS

TOP SUMMARY INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
Fly strains
The wild-type strain used was Sevelen. Flies were raised at 25°C, except for experiments with tub-gal80^ts lines. gcm-gal4 carries a gal4 P-element inserted into the gcm promoter. UAS-gcm^DN was used to block gcm-gcm2 function with UAS-gcm^N7-4DN as a control (Soustelle et al., 2004). UAS-ncGFP targets GFP to the nucleus and cytoplasm, whereas UAS-mCD8GFP targets GFP to the membrane. actin-gal4 was used for overexpression experiments with UAS-gcm (Bernardoni et al., 1998) or UAS-gcm2 (Kammerer and Giangrande, 2001).

In situ hybridization
The c-Gcm1 RNA probe was synthesized from chicken EST pgr1n.pk002.g21 (Chicken EST project, Delaware Biotechnology Institute, Newark, USA). NeuroM and Sox2 probes were generated from specific PCR fragments to avoid cross-reactivity with transgenes. The c-Gcm2 probe was synthesized from the partial cDNA template described by Okabe and Graham (Okabe and Graham, 2004). Chicken embryos were staged according to Hamburger and Hamilton (Hamburger and Hamilton, 1992). In situ hybridization was performed according to Braquart-Varnier (Braquart-Varnier et al., 2004). Sections were digitalized and analyzed using Zeiss software, and images were manipulated using Adobe Photoshop. In situ hybridizations were performed according to Kammerer and Giangrande (Kammerer and Giangrande, 2001), except that Drosophila brains were fixed overnight at 4°C in 4% paraformaldehyde. Double in situ hybridization was performed using probes labeled with either digoxigenin or fluorescein. Mouse anti-digoxigenin (1:100, Boehringer Mannheim) or rabbit anti-FITC (1:10,000, Molecular probes) and fluorescent secondary antibodies were used for immunolabeling.

Immunohistochemistry
The Drosophila CNS was immunolabeled as described previously (Ceron et al., 2001). Primary antibodies used were: mouse anti-Repo (1:100, DSHB), rat anti-Elav (1:200, supernatant from DSHB), rabbit anti-phospho-Histone H3 (1:500, Upstate Biotechnology), rabbit anti-GFP (1:500, Molecular probes), mouse anti-Acj6 (1:50, DSHB). Secondary antibodies conjugated with FITC, Cy3 or Cy5 (Jackson) were used at 1:500. DAPI was used at 100 ng/ml for nuclei counterstaining. Brains were mounted in Vectashield (Vector) mounting medium.

Chicken tissue vibratome sections fixed in 4% formaldehyde were processed using standard protocols. Primary antibodies used were: rabbit anti-Pax6 (1:150, Covance), mouse (1:2000) and rabbit (1:1000) anti-ßIII-tubulin (Covance), mouse anti-Mnr2 (1:4, DSHB), mouse anti-Pax7 (1:2, DSHB), mouse anti-Lim1/2 (1:2, DSHB), mouse anti-BrdU (1:2000, DSHB), mouse anti-HuC/D (1:500, Molecular Probes), rabbit anti-GFP (1:500, Torrey). Rabbit anti-Sox1 (1:800), anti-Sox2 (1:4000) and anti-Sox3 (1:500) were used, but as similar results were obtained from each only data relative to Sox3 are shown. Secondary antibodies used were: anti-mouse Ig Alexa-546, anti-rabbit Ig Alexa 647 (1:1000, Molecular Probes). Sections or brains were analyzed using confocal microscopes (Leica).

Ectopic expression experiments
actin-gal4, tub-gal80^ts, UAS-gcm or UAS-gcm2 LII larvae were incubated at 30°C and brains dissected at LIII. The c-Gcm1 coding region (Hashemolhosseini et al., 2004) was cloned into the pCIG vector. The c-Gcm1BD-ER vector was constructed by cloning a PCR-amplified fragment (equivalent to amino acids 1-193 of c-Gcm1) into the CMV-based vector pCS2, which contains the repressor domain (amino acids 1-298) of the D. melanogaster Engrailed protein (Smith and Jaynes, 1996). The coding region of Ngn2 was cloned into expression plasmid pAdRSV-Sp. In ovo chicken electroporation was performed as previously described (Danesin et al., 2006; Itasaki et al., 1999). Expression vectors (1 µl) were used at 2 µg/µl, except for the c-Gcm1BD-ER construct which was used at 3 µg/µl, and were coinjected with control vectors pEGFP-N1 (Clontech, 0.6 µg/µl) or pCIG to visualize the transfected area. Flat-mounted spinal cord explants were cultivated in an organotypic culture system as previously described (Agius et al., 2004). Embryos or spinal cord explants were fixed in 4% formaldehyde in PBS for 2 hours for immunohistochemistry, or overnight for in situ hybridization, and dehydrated in an ethanol series. Cell proliferation was evaluated by bromodeoxyuridine (BrdU, Roche) incorporation. BrdU (10 mM) was injected into the lumen of the chicken neural tube and embryos were harvested 1 hour later. BrdU immunolabeling was performed on sections treated with 2N HCl in 0.2% Triton X-100/PBS for 30 minutes, after blocking and before incubation with primary antibodies.

Cell quantification
Quantifications were performed by calculating the percentage of electroporated (GFP-positive) cells labeled with a particular marker, divided by the total number of GFP-positive cells. Counts were performed on at least ten sections from three embryos in each experiment. Data were obtained from at least three independent experiments, in each of which at least 150 cells were counted. Results are expressed as the mean percentage±s.e.m. of labeled electroporated cells. Significance was analyzed using the Student's t test and P values are indicated in the figure legends.

HeLa cell transfection
HeLa cells were grown in DMEM supplemented with fetal bovine serum and antibiotics and transfected with Effecten Transfection Reagent (Qiagen). Each cDNA was cloned into the pCIG vector. After 48 hours, transfected cells were analyzed by immunolabeling, using rabbit anti-Tuj1 (1:1000, Covance), mouse anti-GFAP (1:100, ICN Biomedicals), fluorescent secondary antibodies (1:600) and DAPI as above. Preparations were mounted in Polymount medium (Polysciences) and analyzed by confocal microscopy. Labeled cells were counted from three independent transfection assays. Results are expressed as the mean of counted cells.

	RESULTS

TOP SUMMARY INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
c-Gcm1 is expressed in the developing chicken CNS
To investigate the role of vertebrate gcm genes during neural development, we determined the expression profile of the two chicken orthologs c-Gcm1 (Hashemolhosseini et al., 2004) and c-Gcm2 (Okabe and Graham, 2004). c-Gcm1 RNA was observed as early as the primitive streak stage, in the presumptive neural plate (Fig. 1A). c-Gcm1-positive cells were found in the ectoderm (Fig. 1A,A') and were included in the domain expressing Sox2 (Fig. 1B), a marker of early neural progenitors (Bylund et al., 2003; Graham et al., 2003; Uwanogho et al., 1995). At the onset of rostral neural tube folding, high levels of transcripts were detected at all rostrocaudal levels of the developing CNS along the entire dorsoventral axis (Fig. 1C,D), except for the dorsal-most region (Fig. 1E). At E2.5, when neuronal differentiation has started (McConnell and Sechrist, 1980; Sechrist and Bronner-Fraser, 1991), c-Gcm1 expression was seen to be markedly reinforced in cells located in the lateral wall of the forming mantle layer, which are likely to correspond to newly generated neurons (Fig. 1F). From E3, c-Gcm1 RNA was not detected in the ventricular zone nor in the forming mantle layer (Fig. 1G and data not shown), indicating that c-Gcm1 expression is extinguished in late neuronal progenitors, before the appearance of glial progenitors (Rowitch, 2004). By contrast, c-Gcm2 RNA was never detected in the developing spinal cord at any of the stages analyzed, from E1 to E8 (see Fig. S1 in the supplementary material). However, in E1.5 embryos, c-Gcm2 was expressed in a restricted rostrocaudal domain of the hindbrain (see Fig. S1B,B' in the supplementary material).

These results reveal for the first time the expression profile of gcm genes in the embryonic vertebrate CNS.

c-Gcm1 overexpression promotes neuronal differentiation
To directly assess the function of c-Gcm1, we in ovo electroporated a c-Gcm1-expressing vector at E1.5 and analyzed neural tubes using markers specific to progenitor or post-mitotic cells. Electroporation of the c-Gcm1 vector cell-autonomously suppresses the expression of Sox1-3, which code for HMG-box transcription factors specific to CNS proliferating progenitors (Fig. 2A,A',G) (Bylund et al., 2003; Graham et al., 2003; Uwanogho et al., 1995). Only 15% of c-Gcm1-overexpressing cells coexpressed Sox1-3, as compared with 51% when control vector was electroporated (Fig. 2G). The effects of c-Gcm1 overexpression on Sox1-3, which were observed as early as 6 hours after electroporation, suggest that they may be direct (Fig. 2A,A') and concomitant with upregulation of NeuroM (Fig. 2B,B'), a marker for early post-mitotic neurons (Roztocil et al., 1997).

View larger version (128K): [in this window] [in a new window]   Fig. 1. Expression of c-Gcm1 in developing chicken embryonic CNS. c-Gcm1 in situ hybridization on whole chick embryos (A-D) and on transverse sections of embryonic spinal cord (E-G). (A,B) Dorsal views showing that c-Gcm1 expressing cells (purple) are detected in the anterior neural plate at stage 4, in an area corresponding to the epiblast as shown on transverse section in A'. (B) Colabeling shows that c-Gcm1-expressing cells are included in the Sox2 expression domain (red). (C) During neurulation, c-Gcm1 is strongly expressed throughout neural tube and neural plate. (D,E) Starting from E1.5 (stage 11), c-Gcm1 is expressed in the neural tube (D), along the entire dorsoventral axis except in the dorsal-most region (E). (F) At E2.5 (stage 14), c-Gcm1 expression is downregulated in neural progenitors lining the lumen whereas it is maintained in cells located in the newly formed intermediate mantle layer. (G) At E8 (stage 34), c-Gcm1 RNA is no longer detected in the spinal cord. hn, Hensen's node; ps, primitive streak. Scale bars: 60 µm in E; 70 µm in F; 150 µm in G.

Vertebrate neurogenesis is driven by proneural bHLH transcription factors such as the neurogenins (Ngns), which direct cell cycle exit of neural progenitors by repressing the expression of Sox1-3, and which promote neuronal differentiation by inducing the expression of NeuroM and NeuroD (Bertrand et al., 2002). Interestingly, Ngn2 overexpression upregulated c-Gcm1 (Fig. 2D,D'), whereas the reverse was not true (Fig. 2C,C'), placing c-Gcm1 downstream of proneural and upstream of neuronal differentiation factors.

To determine whether premature engagement of neural progenitors towards a neuronal fate results in a full neuronal phenotype, we analyzed the expression of the pan-neuronal markers class III ß-tubulin (Tuj1, Fig. 3A-F) and HuC/D (Fig. 3G-H'), as well as that of interneuron marker Lim1/2 (Fig. 3F,I-J'). Twenty-four hours after electroporation, 55% of c-Gcm1-overexpressing cells expressed ßIII-tubulin and 40% were Lim1/2-positive, whereas only 9% of cells electroporated with a control vector differentiated into neurons in the same time window (Fig. 3F). Overexpression of c-Gcm1 also triggered neuronal differentiation in the embryonic brain, as assessed by premature expression of ßIII-tubulin in the forebrain (Fig. 3D). Neuronal progenitors normally exit the ventricular zone when they leave the cell cycle and start expressing neuronal differentiation markers. This behavior was retained in neural cells electroporated with a control vector (Fig. 3A,A',G,G',I,I'), whereas c-Gcm1-induced neurons were also found in the ventricular zone (Fig. 3B,B',H,H',J,J') and no longer expressed Pax7 (Fig. 3E), a feature indicative of premature differentiation.

These data demonstrate that c-Gcm1 overexpression prompts neural progenitors to differentiate prematurely by downregulating neural progenitor genes and upregulating a repertoire of neuronal characteristics.

c-Gcm1 overexpression does not promote glial differentiation
We then asked whether c-Gcm1 has the ability to induce glial cells in the embryonic spinal cord. We used Glast and O4 to identify astrocyte and oligodendrocyte precursors, respectively. Both markers start to be expressed in precursor cells of the neuroepithelium from E5/E6, corresponding to initiation of gliogenesis in chicken (Agius et al., 2004; Soula et al., 2001).

First, c-Gcm1 was electroporated at E1.5 and glial marker expression was analyzed 1.5 to 4 days later. Irrespective of the stage of phenotypic analysis (E3 or E5.5), c-Gcm1 overexpression did not trigger premature and/or ectopic expression of glial markers (Fig. 4A,B and data not shown). Strikingly, O4-positive cells were not detected in the ventral domain of the neuroepithelium (Fig. 4B).

Second, we overexpressed c-Gcm1 at late stages in a gliogenic context. E4.5/E5 spinal cords were electroporated ex ovo, plated in an organotypic culture system and expression of glial markers assessed three days later on transverse sections of spinal cord explants (Danesin et al., 2006). As with early electroporation, late c-Gcm1 overexpression did not induce ectopic expression of glial markers (Fig. 4C-G), and a reduction of the O4-expressing domain was observed (Fig. 4E). Accordingly, we found that c-Gcm1-overexpressing cells invariably expressed Lim1/2 (Fig. 4H,I) and most had left the neuroepithelium, indicating that they had adopted a neuronal fate. Altogether, our data show that c-Gcm1 overexpression induces neurogenesis at both early and late stages of spinal cord development.

A repressive form of the c-Gcm1 DNA-binding domain prevents neuronal differentiation
To further investigate the function of c-Gcm1 during neurogenesis, we generated a construct containing the repressor domain (ER) of the D. melanogaster Engrailed protein fused to the DNA-binding domain of c-Gcm1 (c-Gcm1BD-ER). ER fusion constructs have been successfully used to produce dominant-negative mutations that reproduce loss-of-function phenotypes in vertebrates and in flies (Feig, 1999).

View larger version (109K): [in this window] [in a new window]   Fig. 2. Overexpression of c-Gcm1 leads to depletion of proliferative neural progenitors. (A-F,J-P) Transverse sections after electroporation with control or c-Gcm1 expression vectors at the level of the truncal neural tube of E1.5 chicken embryos. For all images, the electroporated side is on the left; electroporated cells were detected by GFP immunolabeling or by GFP fluorescence (green in both cases). (A-B') GFP immunolabeling (A,B) and in situ hybridization using Sox2 (A') and NeuroM (B') probes. Note the decrease in Sox2 (A') and the increase in NeuroM (B') expression 6 hours after c-Gcm1 overexpression. (C-D') Ngn2 expression domain is not modified upon c-Gcm1 overexpression (C,C'), whereas Ngn2 overexpression induces c-Gcm1 expression (D,D') 24 hours after electroporation. Note that signal development was stopped before detection of endogenous c-Gcm1 mRNA in D'. (E,F) BrdU (red) and GFP colabeling in embryos subjected to a 1 hour BrdU pulse performed 30 hours after electroporation of control (E) or c-Gcm1 (F) expression vectors. Many of the cells electroporated with the control expression vector are in a proliferative state (arrows in E), whereas overexpression of c-Gcm1 markedly reduces the number of transfected BrdU-positive cells (F). Pax6 (J-M) and Pax7 (N-P) immunolabeling performed 24 hours after electroporation of control (J,J',L,O) or c-Gcm1 (K,K',M,N,N',P) expression vectors. c-Gcm1 overexpression strongly reduces the number of Pax6 (K,K',M) and Pax7 (N,N',P) expressing progenitors in the intermediate and dorsal neural tube, respectively. High magnifications of neural tube sections show GFP (L,M,O,P) and Pax6 (red in L,M) or Pax7 (red in O,P) colabeling. Neural progenitors electroporated with control vector maintain the expression of Pax6 and Pax7 (arrows in L,O), whereas neural progenitors electroporated with c-Gcm1 do not (arrows in M,P). (G-I) Percentage of transfected cells expressing Sox3 (G), incorporating BrdU (H) or expressing Pax6 (I), after electroporation of control or c-Gcm1 expression vectors. Asterisks indicate significant differences (P<0.05 in G, P<0.0001 in H; P<0.01 in I). Scale bars: 40 µm in A-F,J-K',N-O; 10 µm in L,M,O,P.

View larger version (75K): [in this window] [in a new window]   Fig. 3. Overexpression of c-Gcm1 promotes premature neuronal differentiation. Electroporation with control or c-Gcm1 expression vectors in truncal neural tube (A-B',E-J') or telencephalon (C,D) of E1.5 embryos. Immunolabeling with ßIII-tubulin (Tuj1 in A-E), HuC/D (G-H') and Lim1/2 (I-J') neuronal markers were performed 24 hours after electroporation. (A-H') Electroporation of control vector (green in A,C,G,I) does not modify the expression pattern of ßIII-tubulin (red in A,A',C) or HuC/D (red in G,G'), whereas c-Gcm1 overexpression (green in B,D,E,H,J) leads to ectopic differentiation of Tuj1-positive (red in B,B',D; blue in E, arrows) and HuC/D-positive (red in H,H') neurons in the neuroepithelium. Inserts in B and H are high magnifications of c-Gcm1-overexpressing cells that coexpress ßIII-tubulin and HuC/D, respectively. (E) ßIII-tubulin (blue) and Pax7 (red) coimmunolabeling shows that c-Gcm1-overexpressing cells coexpress ßIII-tubulin but not Pax7 (arrows). (I-J') Compared with control (I,I'), c-Gcm1 overexpression induces the generation of Lim1/2-positive neurons within the ventricular zone (J,J'). (F) Percentage of transfected cells expressing ßIII-tubulin (Tuj1) and Lim1/2 after electroporation of control or c-Gcm1 expression vectors. Differences between the percentage of c-Gcm1 transfected cells expressing neuronal markers versus controls are statistically significant (asterisks, P<0.001). Scale bars: 40µm in A-D,G-J'; 10µm in insert in B,H; 20µm in E.

View larger version (88K): [in this window] [in a new window]   Fig. 4. Overexpression of c-Gcm1 promotes neuronal but not glial differentiation in spinal cord. (A,B) E1.5 neural tube electroporated with control or c-Gcm1 expression vectors (green) and analysis of O4 expression (red) three days later (E5/E5.5). (A) Electroporation of control vector does not modify the pattern of O4 decorating oligodendrocyte progenitors in the ventral neuroepithelium and no ectopic expression of O4 is observed. (B) Note that the endogenous O4-positive domain is strongly reduced (arrow) and no ectopic expression of O4 is detected when the c-Gcm1-expressing vector is used. (C-I) Electroporation with control (F,H) or c-Gcm1 (D,E,G,I) expression vector was performed in E4.5/E5 embryonic spinal cord that was further dissected, opened dorsally and plated in culture with neuroepithelial precursors up, as depicted in C. Glial and neuronal differentiation was assessed three days later by immunolabeling using Glast (D, red), O4 (E,F,G, red) and Lim1/2 (H,I, red). (D,E) Transverse sections of open-book spinal cords showing that c-Gcm1 overexpression does not induce ectopic Glast-positive (D) or O4-positive (E) cells. Note in E that the O4-positive domain is strongly reduced in the ventral spinal cord. (F,G) High magnifications show that some cells electroporated with control vector have adopted an O4-positive fate (F, arrows), whereas no c-Gcm1-overexpressing cells adopt such a fate (G). (H,I) High magnifications of explants showing that most cells electroporated with control vector are located in the neuroepithelium, and only a few of them reach the mantle layer and express Lim1/2 (H). By contrast, most c-Gcm1-overexpressing cells have left the neuroepithelium and all of them express Lim1/2 (I). ne, neuroepithelium; ML, mantle layer; FP, floor plate. Scale bars: 120µm in A-E; 40µm in F-I.

View larger version (78K): [in this window] [in a new window]   Fig. 5. Repression of c-Gcm1 targets inhibits neuronal differentiation without affecting cell cycle exit. (A-O') Electroporation of E1.5 embryos with control (C,C',E,G,I-K,M,N) or c-Gcm1BD-ER (BD-ER; A-B',D,D',F,H-J,L-O') expression vectors. Immunolabeling and in situ hybridization on transverse sections were performed 24 hours after electroporation using anti-ßIII-tubulin (Tuj1 in A,A') or Lim1/2 (B,B',E,F) antibodies or NeuroM probe (C-D'). (A-B') Overexpression of c-Gcm1BD-ER inhibits the generation of terminally differentiated neurons. (E,F) High magnification of electroporated neural tube showing that cells overexpressing c-Gcm1BD-ER do not express Lim1/2, whereas a fraction of cells electroporated with a control vector express Lim1/2 (arrow in E) as they reach the mantle layer. (I,J) Percentage of transfected cells expressing Lim1/2 (I) or MNR2 (J) after electroporation of control or c-Gcm1BD-ER expression vectors; asterisks indicate significant difference (P<0.01). (G,H) BrdU (red) and GFP immunolabeling on transverse sections obtained from embryos subjected to a 1 hour BrdU pulse performed 24 hours after electroporation of control (G) or c-Gcm1BD-ER (H) expression vectors. Note the presence of double-labeled cells in both cases (arrows). (M,N) Percentage of transfected cells incorporating BrdU (M) or expressing Sox3 (N) after electroporation of control or c-Gcm1BD-ER expression vectors. Note that values are not significantly different. (K,L,O,O') Similar profile of Sox3 (red in K,L) and Pax7 (red in O,O') expression upon electroporation of control (K) or c-Gcm1BD-ER (L,O,O') expression vectors. Scale bars: 50 µm in A-D',O,O'; 20 µm in G,H; 60 µm in I,J; 40 µm in K,L.

Expression of a dominant-negative construct (gcm^DN) containing the Gcm DNA-binding domain and the repressor domain of Engrailed blocked both Gcm and Gcm2 activities, producing the same phenotypes as those observed in the double gcm-gcm2 deficiency (Chotard et al., 2005; Soustelle et al., 2004; Yoshida et al., 2005). By contrast, gcm^DN expression in neurons that do not express gcm-gcm2 did not induce any defect (Fig. 8C,D), further confirming that the gcm^DN construct acts by blocking the Gcm pathway rather than by non-specifically repressing gene expression.

This construct provided us with a unique opportunity to explore the role of gcm-gcm2 in cells that can be specifically visualized by the gcm-gal4 driver. As gcm-gal4;UAS-gcm^DN animals die as embryos, we crossed gcm-gal4;UAS-gcm^DN flies with tub-Gal80^ts transgenic flies, which ubiquitously express a temperature-sensitive Gal80 protein that represses Gal4 at 18°C (McGuire et al., 2003). gcm-gal4, tub-gal80^ts;UAS-gcm^DN animals are viable and fertile when grown at 18°C but do not hatch when grown at 30°C. Flies expressing gcm^DN (shift at early LII) showed the same visual system neuronal and glial loss (see Fig. S5 in the supplementary material) as observed in the gcm-gcm2 double deficiency (Chotard et al., 2005), providing a final validation of the approach. Importantly, these phenotypes were not observed in animals containing a gcm^N7-4DN transgene, which carries a point mutation abolishing DNA binding (Soustelle et al., 2004; Vincent et al., 1996). All cbc neurons were missing in gcm-gal4, tub-gal80^ts;UAS-gcm^DN, UAS-ncGFP animals (Fig. 8B), whereas they were still present in gcm-gal4, tub-gal80^ts;UAS-gcm^N7-4DN, UAS-ncGFP control animals (Fig. 8A). Interestingly, the cbc phenotype was observed when using one gcm^DN transgene, whereas defects in the visual system were only induced when using two transgenes, suggesting that different cells display distinct requirements for the Gcm pathway and further confirming the specificity of gcm^DN phenotypes.

View larger version (68K): [in this window] [in a new window]   Fig. 6. Context-dependent role of gcm during post-embryonic development. (A-C'') Elav (green) and Repo (red) coimmunolabeling on wing imaginal discs. Right panels (A'',B'',C'') show merge of Elav (A,B,C) and Repo (A',B',C') immunolabeling. gcm overexpression leads to neuronal and glial differentiation (compare B-C'' with A-A''). Note that some ectopic neurons and glial cells are closely associated but neuronal and glial markers never colocalize (see C''). (D-F'') Elav (green) and Acj6 (red) coimmunolabeling on wing imaginal discs. Right panels (D'',E'',F'') show merge of Elav (D,E,F) and Acj6 (D',E',F') immunolabeling. Note that some ectopic Elav-positive neurons coexpress Acj6 (white asterisks in F). C-C'' and F-F'' are magnifications of squares shown in B'' and E'', respectively. Scale bars: 50 µm in A-B'',D-E''; 200µm in C-C'',F-F''.

View larger version (97K): [in this window] [in a new window]   Fig. 7. gcm and gcm2 are expressed in central brain neuronal lineages. (A-A'') gcm (A) and gcm2 (A') double in situ hybridization on wild-type Drosophila LIII brain hemispheres. (A'') Merge of gcm (red) and gcm2 (green) labeling. gcm and gcm2 RNAs are coexpressed in lamina neuronal [lamina precursor cells (LPCs)] and glial [glial precursor cells (GPCs)] progenitors as well as in a central brain cluster (area encircled by dotted line in A-A''). (B-C') GFP immunolabeling on gcm-gal4,UAS-mCD8GFP (gcm>GFP) LIII (B) or whole-mount adult brains (C,C'). Note that the GFP expression profile mimics gcm expression pattern in larvae. Anterior (C) and posterior (C') views of the same adult brain are shown. Neuronal somata of dorsolateral (dcbcs) and medial (mcbcs) clusters are encircled by white (C) and yellow (C') dotted lines, respectively. (D-D''') GFP (green), phospho-Histone H3 (red) and DAPI (blue) colabeling at late LI gcm-gal4,UAS-ncGFP larva. (D''') Merge of D-D''; note that a single GFP-positive cell undergoes mitosis as shown by phospho-Histone H3 expression. Scale bars: 40 µm in A-A''; 40 µm in B; 50 µm in C-C'';400 µm in D-D''.

Fly, chick and mouse gcm genes induce the expression of neuronal and glial markers in HeLa cells
The finding that fly gcm genes induce different cell fates, whereas c-Gcm1 only induces neuronal differentiation, prompted us to determine the potential of fly and vertebrate gcm genes in a cellular context. We transfected HeLa cells, a human cell line of non-neural origin, with an expression vector carrying fly gcm or c-Gcm1. Because neurogenic potential had never been reported in mammals, we also performed the same type of experiments using a mouse Gcm1 expression vector.

Strikingly, the three gcm genes induced the expression of ßIII-tubulin in almost half of the transfected HeLa cells, indicating that all three genes share neurogenic potential (data not shown). Because previous studies in mouse fibroblasts showed that mouse Gcm1 induces expression of an astrocytic marker (Iwasaki et al., 2003), we also assayed the gliogenic role of the three gcm genes in a similar transfection assay and indeed observed GFAP expression in almost two-thirds of the transfected HeLa cells (data not shown). We then asked whether gcm genes induce the expression of neuronal and glial markers in the same cells, and indeed found colabeling upon transfection of fly, chicken and mouse gcm/Gcm1 genes (Fig. 9A-D'''). Interestingly, upon quantification of labeling, we found that most cells expressed both GFAP and ßIII-tubulin (60% to 80%, depending on the species), the remainder expressing either marker (Fig. 9E). Thus, expression in a naive context reveals the double neurogenic and gliogenic potentials of gcm genes throughout evolution. These findings allow us to reconcile the apparent discrepancy between the gliogenic potential previously described for fly (Hosoya et al., 1995; Jones et al., 1995; Vincent et al., 1996) and mouse (Iwasaki et al., 2003) genes and their neurogenic potential in fly and chicken (Chotard et al., 2005; Yoshida et al., 2005) (see also present study). Interestingly, transfection of gcm genes does not induce expression of the O4 antigen, which is specific to oligodendrocyte precursors (data not shown), indicating that the observed increase in GFAP and ßIII-tubulin labeling is not due to a general, non-specific enhancement of gene expression. Altogether, in vitro and in vivo data support the hypothesis that the Gcm class of transcription factors plays versatile roles in the fly and vertebrate CNS.

View larger version (71K): [in this window] [in a new window]   Fig. 8. Neuronal differentiation requires Gcm activity in central brain. GFP immunolabeling in (A) control (gcm-gal4,tub-gal80ts;UAS-ncGFP;UAS-gcmN7-4DN) and (B) gcm-gcm2 loss-of-function (LOF) (gcm-gal4,tub-gal80ts;UAS-ncGFP;UAS-gcmDN) LIII CNS. Note that dcbcs and mcbcs (encircled by white and yellow dotted lines, respectively) are missing in gcm-gcm2 LOF but not in control animals as marked by the white and yellow asterisks in B. In these conditions of a single dose of the UAS-gcmDN transgene, lamina development (neurons and glia) is less affected than with two doses of UAS-gcmDN transgene (see Fig. S5 in the supplementary material). Arrows in A,B indicate processes of glia at the interhemispheric junction. (C,D) Development of central brain atonal-positive lineage is not affected by the gcmDN construct. GFP immunolabeling in control (atonal-gal4,UAS-mCD8GFP in C) and gcm-gcm2 LOF (atonal-gal4,UAS-mCD8GFP,UAS-gcmDN in D) LIII CNS shown in dorsal view. In control (C) as well as in gcm-gcm2 LOF (D) animals, atonal lineage includes two clusters of 20-30 neurons that are connected by a commissure crossing the midline (dashed line) and which extend a bundle of ipsilateral axons (arrows) into the optic lobes. Thus, gcmDN expression does not affect the development of atonal-positive neurons. Scale bars: 100 µm in A,B; 180 µm in C,D.

View larger version (66K): [in this window] [in a new window]   Fig. 9. Fly, chick and mouse gcm genes induce expression of neuronal and glial markers in HeLa cells. GFAP (A,B,C,D), GFP (A',B',C',D'), Tuj1 (A'',B'',C'',D'') and DAPI (A''',B''',C''',D''') colabeling and merges (A'''',B'''',C'''',D'''') of HeLa cells transfected with expression vectors carrying c-Gcm1 (A-A''''), gcm (d-gcm1 in B-B''''), mouse Gcm1 (m-gcm1 in C-C'''') or vector as control (D-D''''). Scale bar: 20 µm. (E) Percentage of transfected cells expressing neuronal/glial markers. n indicates the number of GFP-positive cells counted. Note that all gcm1 genes induce the expression of GFAP and Tuj1 markers and that these two markers colocalize in most transfected cells.

	DISCUSSION

TOP SUMMARY INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Data concerning the neurogenic role of fly gcm genes and expression of c-Gcm1 at the onset of neurogenesis formed the basis for a functional analysis in the chicken spinal cord. We here show that c-Gcm1 overexpression leads to the downregulation of genes specifically expressed in proliferative neural progenitors of the ventricular zone and concomitantly induces the full neuronal differentiation program. Conversely, blocking the c-Gcm1 pathway does not modify the proliferation rate and expression of progenitor genes, but prevents neuronal differentiation gene expression. c-Gcm1 acts as a neuronal differentiation gene, downstream of proneural genes and upstream of NeuroM. Neuronal differentiation relies on the repression of the Sox genes, which has been proposed to be mediated by neurogenin (Bertrand et al., 2002; Bylund et al., 2003; Graham et al., 2003; Uwanogho et al., 1995). Blocking Sox gene expression, however, leads cells to acquire an early post-mitotic phenotype, but does not allow these cells to fully differentiate into neurons (Bylund et al., 2003), indicating that late events require other Ngn-dependent pathways. c-Gcm1 is likely to constitute a relay of the neurogenin pathway that is indispensable to trigger complete neuronal differentiation.

The widespread expression of c-Gcm1 and its overexpression phenotype strongly argue in favor of a general neurogenic role. Indeed, altering the c-Gcm1 protein does not modify expression of ventral, intermediate or dorsal markers (Fig. 5 and data not shown), although further experiments are required to definitively exclude a role for c-Gcm1 in specifying neuronal subpopulations. Absence of c-Gcm2 expression in the spinal cord excludes the possibility that the two c-Gcm genes play a redundant role in this tissue, although we cannot exclude a c-Gcm2 neurogenic/gliogenic role in other regions/stages.

Our study provides the first evidence for c-Gcm1 playing an essential role in the neurogenic process and points to an unexpected conservation of gcm gene function in neuronal differentiation in chicken and Drosophila. The question now is whether gcm neurogenic expression and function are also conserved in mammals. Our HeLa cell transfection data showing that neuronal characteristics are induced by fly gcm, c-Gcm1 and mouse Gcm1 support the hypothesis of conservation. These results may explain the stimulation of secondary neurulation observed in transgenic mice overexpressing mouse Gcm1 in the developing tail bud (Nait-Oumesmar et al., 2002). In the light of present data, and based on the fact that the expression of mouse and human orthologs is detected by RT-PCR in developing brains (Altshuller et al., 1996; Iwasaki et al., 2003; Kim et al., 1998), it will be crucial to determine the expression profile of mammalian gcm genes within the CNS and score for neuronal defects in Gcm-knockout mice.

Fly gcm genes are expressed and required in the neurons of the central brain. Owing to the fact that the only available tool to identify and target cbcs is the gcm-gal4 line, it is not possible to assess the specific roles of gcm and gcm2. Their similar levels of expression, however, suggest that both genes are required, as demonstrated in the visual system (Chotard et al., 2005). gcm genes are necessary for neuron generation rather than maintenance, in line with the early expression of gcm-gcm2 and with the lack of any phenotype in experiments removing gcm-gcm2 function in post-mitotic neurons (data not shown). Generating independent markers for the two cbcs will be crucial for characterizing the gcm pathway and the role of these neurons, which integrate information from different centers of the fly brain (see Fig. S3 in the supplementary material).

Our data show that fly Gcm/Gcm2 transcription factors induce glia or neuron differentiation depending on the cellular context. First, Gcm or Gcm2-induced neuron to glia transformation is more effective in the embryonic than in the larval CNS (data not shown). Second, Gcm or Gcm2 overexpression induces both Repo and Elav expression outside the CNS, but only Repo expression within the CNS. This implies that most neural cells express factors that do not allow Gcm to induce a neuronal pathway, or contain a positive factor that induces Gcm to trigger the glial pathway.

Although fly gcm genes are also necessary and sufficient for glial differentiation, c-Gcm1 overexpression does not induce gliogenesis in vivo and indeed c-Gcm1 activity inversely correlates with the production of glia in the spinal cord. Similarly, no glial defect has been reported for the Gcm1 and Gcm2 knockout mice (Anson-Cartwright et al., 2000; Gunther et al., 2000; Kim et al., 1998; Schreiber et al., 2000) and the only reported in situ expression (mouse Gcm1) concerns cells that do not correspond to known glial lineages (Iwasaki et al., 2003). On the other hand, the gliogenic potential is conserved in vitro because gcm genes induce glial markers in HeLa cells. We therefore speculate that gcm genes play a gliogenic role in discrete cell populations, in line with mouse Gcm1 overexpression inducing the expression of glial markers in brain cultures (Iwasaki et al., 2003), but not in retina (Hojo et al., 2000). The observation that most cells coexpress neuronal and glial markers in vitro, a situation that is not observed in vivo, strongly suggests that HeLa cells provide a naive context in which both potentials of gcm genes are revealed.

Altogether, the present data merit revisiting the role and potential of the classically defined fly glial master genes. We also identify a conserved neurogenic potential in this class of transcription factors and define a novel step in the pathways leading to neuronal differentiation. Finally, based on in vivo and in vitro data, we propose that fly as well as vertebrate gcm genes induce neurons and/or glial cells depending on the cellular context. The reiterated use of Gcm developmental pathways within and outside the CNS further emphasizes the need for cell-specific factors. In the future, one of the most challenging issues will be to perform screens to identify cues that are necessary for the neuronal program and to determine common versus specific features of the different Gcm pathways. This will enable us to understand how spatio-temporal patterning regulates and integrates these pathways to control cell specificity.

Supplementary material
Supplementary material for this article is available at http://dev.biologists.org/cgi/content/full/134/3/625/DC1

	ACKNOWLEDGMENTS

 
We thank the Bloomington Center and U. Tepass and C. Desplan for flies; M. Boeglin, D. Hentsch and J. L. Vonesch for assistance with imaging; J. Colonques and F. Tejedor for sharing unpublished data; all group members for advice and C. Diebold for technical assistance and N. Arbogast for keeping stocks; colleagues at CBD for advice, especially S. Bel-Vialar and F. Pituello, and N. Escalas for technical assistance. We thank P. Charnay for Ngn2 vector; T. Edlund for Sox1-3 antibodies; A. Graham for c-gcm2 cDNA; and D. Henrique for Sox2 probe. The confocal microscopy facility was financed by MESR (95.V.0015). This work was supported by INSERM, CNRS, Hôpital Universitaire de Strasbourg, ARC (A.G.), LIGUE (A.G.) and EEC (A.G.). L.S. was supported by ARC, AFM; F.T. by ARSEP and ARC; C.J. by MRT; J.C. by EMBO (short-term fellowship).

	Footnotes

 
^* These authors contributed equally to this work

Present address: Massachusetts General Hospital Cancer Center, Harvard Medical School, Charlestown, MA 02129, USA

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