标题: High Yield of Cells Committed to the Photoreceptor Fate from Expanded Mouse Reti [打印本页] 作者: 江边孤钓 时间: 2009-3-5 00:02 标题: High Yield of Cells Committed to the Photoreceptor Fate from Expanded Mouse Reti
作者:Faten Merhi-Soussi, Brigitte Angnieux, Kriss Canola, Corinne Kostic, Meriem Tekaya, Dana Hornfeld, Yvan Arsenijevic作者单位:Unit of Gene Therapy and Stem Cell Biology, Jules Gonin Eye Hospital, Lausanne, Switzerland . w* K$ ]. [& u; B ) _6 p* ]/ z e+ |8 w3 E4 A+ [
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【摘要】 % I! O7 ^# V/ n: M- G6 N6 N: q7 O The purpose of the present work was to generate, from retinal stem cells (RSCs), a large number of cells committed toward the photoreceptor fate in order to provide an unlimited cell source for neurogenesis and transplantation studies. We expanded RSCs (at least 34 passages) sharing characteristics of radial glial cells and primed the cells in vitro with fibroblast growth factor (FGF)-2 for 5 days, after which cells were treated with the B27 supplement to induce cell differentiation and maturation. Upon differentiation, cells expressed cell type-specific markers corresponding to neurons and glia. We show by immunocytochemistry analysis that a subpopulation of differentiated cells was committed to the photoreceptor lineage given that these cells expressed the photoreceptor proteins recoverin, peripherin, and rhodopsin in a same ratio. Furthermore, cells infected during the differentiation procedure with a lentiviral vector expressing green fluorescent protein (GFP) under the control of either the rhodopsin promoter or the interphotoreceptor retinoid-binding protein (IRBP) promoter, expressed GFP. FGF-2 priming increased neuronal differentiation while decreasing glia generation. Reverse transcription-polymerase chain reaction analyses revealed that the differentiated cells expressed photoreceptor-specific genes such as Crx, rhodopsin, peripherin, IRBP, and phosphodiesterase-. Quantification of the differentiated cells showed a robust differentiation into the photoreceptor lineage: Approximately 25%¨C35% of the total cells harbored photoreceptor markers. The generation of a significant number of nondifferentiated RSCs as well as differentiated photoreceptors will enable researchers to determine via transplantation studies which cells are the most adequate to integrate a degenerating retina. ) _! d: O; Q3 o- D- a# h. c& G" U
【关键词】 Radial glia Neurogenesis Neuron differentiation Lentivirus Mller cells$ P# i+ e+ b% L% O$ ^
INTRODUCTION# F0 X# w0 h* @" R! p6 t
. j) b% ]" ?0 l! }: KRetinal degenerative diseases, including retinitis pigmentosa (RP) , affect a significant percentage of the world population. The general effect of these diseases is photoreceptor death and consequently the loss of visual function. At this point in time, no effective vision-restoring treatments are available for patients with RP and AMD. One of the treatment strategies proposed for retinal degeneration is to use retinal stem cells (RSCs) to replace the type of cells that were lost, in the present case the photoreceptors. 0 v+ K/ i3 N W8 J , C0 c2 l; C% o$ {9 G; jThe retina consists of one glia, the M¨¹ller cells, and six neuronal cell types that are generated from RSCs in a stereotyped order during development .0 r' d1 v6 V0 q" d
% q5 R/ U5 T8 wLineage-tracing studies of single retinal progenitor cells (RPCs) have shown that retinal cells arise from multipotent progenitors described a method for preparation and transplantation of RPCs (passage 2) which increases the percentage of cells showing features of photoreceptor differentiation after transplantation. However, the authors did not investigate whether the RPCs maintain the capacity to generate photoreceptors after several passages. In addition, no quantification of RPCs differentiated into retina-specific neurons expressing rhodopsin in vitro was reported.* [9 d% C0 }. q. T
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Recently, Wu et al. during cell differentiation of progeny derived from RSCs should induce photoreceptor appearance in vitro. The purpose of the study described herein was to generate a large number of photoreceptors with epigenetic factors. We show that after long-term expansion, RSCs (characterized as radial glial cells) maintain the capacity to generate a large percentage of retinal neurons (approximately 57%) including cells committed to the photoreceptor pathway (approximately 25%¨C35% of the total cell population). Moreover, analysis of the differentiated cells by multiple approaches and parameters confirmed the acquisition of the photoreceptor fate. In this study, the high yield of photoreceptors in a controlled time and environment represents a promising tool for studying neurogenesis and screen photoreceptor-protective drugs as well as for providing an unlimited cell source for transplantation studies in animal models of retinal degeneration.8 s# c+ ]( z& x+ l
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MATERIALS AND METHODS# q% ~, K6 t( m* [( i
$ R% V% D9 W* j) d* d9 ~Isolation and Expansion of RSCs / S+ |0 A* _/ D9 O6 x& l; K , D2 t( B @/ q8 B" sRSCs were isolated from the neural retina of PN1 DBA/2J mice as previously described . Once every 5¨C7 days, adherent expanded cells were passaged by dissociation into single cells with trypsin-EDTA (Sigma Fluka Chemie AG) and plated in a new 75-cm2 uncoated flask at a density of 2 x 106 cells per flask. Differentiation experiments were performed using cells expanded up to passage 20, from four independent isolations of RSCs.% m: N8 e9 l/ {2 e
& g B! l1 I5 c; A1 wPriming and Differentiation , o* g$ z% J; [8 n# u E& U' v + y G; P' U) ?5 ^) s: TFor priming, 8 x 104 to 1.2 x 105 cells per well (up to passage 32) were seeded in 24-well culture dishes on glass coverslips precoated with 0.015 mg/ml poly(L-ornithin) (Sigma Fluka Chemie AG) and 1.1 µg/cm2 laminin (Sigma Fluka Chemie AG) and cultured in the basic medium plus FGF-2 (20 ng/ml) and heparan sulfate (2 µg/ml) (Sigma Fluka Chemie AG) for 5 days. After 5 days of FGF-2 priming, cells were switched to basic medium plus B27 (1:50) (Invitrogen, Basel, Switzerland, http://www.invitrogen.com) alone during an additional 5 days to induce cell differentiation and maturation. Cells were split into three groups: one subjected to the FGF-2 priming step only, the second group subjected to the FGF-2 priming step followed by differentiation with B27, and for the third group, cells were plated in B27-supplemented medium for 5 days without FGF-2 priming. After incubation at 37¡ãC in 5% CO2, cells were either fixed to be processed for immunocytochemistry analysis or harvested for RNA isolation. 7 ^( q& O) n) _' g# F' h. u: g3 f- U2 R# s
Lentiviral Transduction of RSCs ) D; [" G# z: Z, S3 i2 k9 n9 J' B8 U+ F8 r/ Z6 x& v1 u* W
During the differentiation procedure, cells were infected with a replication-defective, self-inactivating lentiviral vector encoding the green fluorescent protein (GFP) reporter gene under the control of the rhodopsin promoter (LV-Rhop-GFP), which is specific for photoreceptors in vivo, as previously described , and the p24 antigen titer was determined by enzyme-linked immunosorbent assay. After FGF-2 priming, 30 ng of p24 LV-Rhop-GFP or LV-IRBPp-GFP was used to infect cells in the basic medium containing B27 and cells were incubated for 5 days at 37¡ãC, 5% CO2. The cells were then fixed to be processed for GFP immunocytochemistry analysis. 1 X- I$ ?& I6 S5 ^$ F9 B$ } O% D0 G9 X3 |- z
Immunocytochemistry # B% [7 ~, ^7 f I, M6 ` 5 M |4 j% O, C( jThe cells were fixed with 4% paraformaldehyde at room temperature for 20 minutes. After fixing, the cells were washed with phosphate-buffered saline (PBS) and incubated overnight or 48 hours (Ret-P1) with the primary antibody (Table 1) at 4¡ãC in PBS buffer containing 10% normal goat serum (Dako Denmark A/S, Glostrup, Denmark, http://www.dako.dk) and 0.3% Triton X-100 (Sigma Fluka Chemie AG). After rinsing, the cells were incubated with a Cy3- or fluorescein isothiocyanate (FITC)-conjugated goat anti-mouse or goat anti-rabbit secondary antibody (Jackson ImmunoResearch Laboratories, Inc., West Grove, PA, http://www.jacksonimmuno.com) for 1 hour at room temperature. All cells were counterstained by incubating with 4,6-diamidino-2-phenylindole (DAPI) (0.3 µM; Molecular Probes, Eugene, OR, http://probes.invitrogen.com) for 3 minutes at room temperature followed by washing steps. For syntaxin immunocytochemistry, a biotinylated secondary antibody followed by the diaminobenzidine (DAB) peroxidase substrate system (Vector Laboratories, Burlingame, CA, http://www.vectorlabs.com) were used. For bromodeoxyuridine (BrdU) immunocytochemistry, cells were exposed to 500 nM BrdU overnight (Sigma Fluka Chemie AG). Next day, the cells were fixed with 4% paraformaldehyde at room temperature for 20 minutes. Incorporation of BrdU was detected using a monoclonal anti-BrdU antibody (GE Healthcare, Little Chalfont, Buckinghamshire, U.K., http://www.amershambiosciences.com) according to manufacturer¡¯s instructions. 6 S: d3 O. s+ M) _3 e& M; g1 M! W / B/ H0 @: }% r- K2 T( r8 mTable 1. Primary antibodies used for immunocytochemistry l W- c V- A' [( V * [2 l# b- ~& L1 R& ]; L4 j4 Z0 fFor quantitative analyses of labeled RSCs primed and/or differentiated in vitro, six monolayer fields were randomly chosen for each sample for each experiment. As a control, all antibodies labeled their cell-specific antigens in cryosections of the adult mouse retina. Control retina labeling of the Rho1D4 and the Ret-P1 antibodies are presented in supplemental online Fig. 1S. : g- E) t2 r0 R% \+ f3 ]. s; \* J " q" K0 \+ F4 E8 p4 L& `, uMeasurement of Cell Viability$ N5 K0 }, m( E u; b# `& l- T( |
* j3 ~0 F% a- M: ZCell survival was assessed using the double-labeling fluorescence technique fluorescein diacetate (FDA)/propidium iodide (PI) from Sigma Fluka Chemie AG, as previously described . The cultures were immersed in an FDA-PI mix (FDA 15 µg/ml and PI 15 µg/ml) diluted in the Lock¡¯s solution for 5 minutes at 37¡ãC. They were then rinsed with the Lock¡¯s solution. After this procedure, viable cells emitted green fluorescence and nonviable cells emitted red fluorescence. The viability was determined as the percentage of viable cells from a total of 1,600 cells.* N% c& h: W$ A! A
% b" P: q" t, q7 I% |* a7 \" tReverse Transcription-Polymerase Chain Reaction7 z3 T. ^% N. b
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Total RNA was extracted from differentiated cells using the Trizol reagent according to the manufacturer¡¯s instructions (Invitrogen). RNA pellets were washed with cold 75% ethanol, dried, reconstituted with sterile water, and quantified by spectrometry. The presence of equivalent concentrations of intact RNA from all samples was confirmed by electrophoresis in denaturating ethidium bromide-stained agarose gels. Identical amounts of RNA (1 µg) were reverse-transcribed using AMV-RT (Promega, Madison, WI, http://www.promega.com), random primers, and RNAsin ribonuclease inhibitor from Promega and dNTPs (GE Healthcare) in a total volume of 30 µl. Template cDNAs (5 µl) were then amplified in a typical 50-µl polymerase chain reaction (PCR) containing 2 ng/µl of the respective primers, 200 µM dNTP, and 2.5 units of Taq DNA polymerase (Invitrogen). The magnesium chloride concentration was 1.75 mM. The absence of DNA contamination in RNA preparations was tested by including RNA samples that had not been reverse-transcribed. Amplifications were carried out under the following conditions: denaturation for 5 minutes at 94¡ãC, followed by 30 cycles of denaturation at 94¡ãC for 30 seconds, annealing for 60 seconds at 57¡ãC (for Crx, IRBP, peripherin, and rhodopsin) or 55¡ãC (for phosphodiesterase- ) or touch down 60¡ãC-50¡ãC (for Mash1), and extension at 72¡ãC for 60 seconds, with a final extension at 72¡ãC for 10 minutes. In the case of rhodopsin and PDE-, it was necessary to perform a second PCR of 30 cycles on 2 µl of cDNA from the first PCR of B27-differentiated cells or of adult retina (for rhodopsin) to reveal the amplified sequence. PCR products were visualized by ethidium bromide/1.5% agarose gels. Sequences of gene-specific primers used in the PCRs were as follows:8 b. P# }4 S% P8 |1 {6 A/ M
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Crx (636 bp), 5'-TTCAAGAATCGTAGGGC/5'-TGAAACTTCCAGGCACTCTG # _+ C. z0 z: |9 Z! A j$ t( e1 w 1 y5 Y" |. o j' z2 g9 V/ ~IRBP (576 bp), 5'-CCTGACAGTAAGTCTGCCTC/5'-GTCCCAGGGAGCATTTTCTG j* T; }& K7 j) @ A) k 5 j" E; d5 B: |, p# s& R( E& z) DMash1 (266 bp), 5'-TTGAACTCTATGGCGGGTTC/5'-GGTTGGCTGTCTGGTTTGTT2 {! D8 i+ e' M$ V2 L: @: h
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PDE- (717 bp), 5'-CTCCATGGGTCCTCCATC/5'-CTGGATGCAACAGGACTT 7 [" H: a Z# I' C# Y7 Q8 V5 b6 N5 Z
Peripherin (644 bp), 5'-CAGATACGGCGGCCTAGATT/5'CGTTGTTCCCACAGCACTTG 8 f" i) q4 E. ?0 V$ v# a . y0 f! L: O& ARhodopsin (490 bp), 5'-CTTTACCTAAGGGCCTCCAC/5'-GCAGCTTCTTGTGCTGTACG. All PCR products were sequenced.( A$ F) k e& \. t
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Statistical Analysis , U+ p7 u4 |' i! N" s4 P& w: H+ i" P$ s8 F8 W. s, s: ^! y
Values are presented as means ¡À SEM of several (n) independent experiments from two to four different culture preparations of RSCs. Data for nestin and BrdU labelings (three groups each) were compared by analysis of variance/Scheffe test, and data for ß-tubulin-III and glial fibrillary acidic protein (GFAP) stainings (two groups each) were compared by student¡¯s t test. P values less than .05 were considered as statistically significant. " ]! V( A& Z; j4 J+ t& |2 V/ z. d7 h2 m2 W5 ?, U5 z" y7 Q0 ?
RESULTS1 W* p. a3 o. f
, X5 c. h' V9 `1 ?Progressive Decrease of RSC Number During a Two-Step Procedure & W" i" V) O4 S+ t& k - g4 O, J- t% n0 o, z' K9 r: A8 `We have previously isolated a homogeneous population of radial glial cells from PN1 mice retinas which proliferates on a long-term basis (34 passages) and contains cells behaving like RSCs . After FGF-2 priming, we treated cells with the B27 supplement alone for another 5 days to induce full cell differentiation and maturation. After 3 days, numerous cells died after the B27 stimulation, whereas the remaining cells underwent cell differentiation. The proportion of nestin-positive cells decreased by 46% upon the FGF-2 priming procedure (51% ¡À 5% nestin-positive, Fig. 1C; n = 5, p - y; X8 V) x) l: W7 S5 D
2 P3 |' P; ?; T" Y" j2 TFigure 1. Nestin expression and RSC proliferation during expansion, cell priming, and cell differentiation. (A): Immunocytochemistry for nestin on RSCs cultured in medium containing EGF and FGF-2. (B): Immunocytochemistry for BrdU after 5 days of FGF-2 priming. (C): Quantitative analysis of nestin-positive cells in EGF FGF-2 after 5 days of FGF-2 priming (FGF-2 DIV#5) and after 5 days of FGF-2 priming followed by 5 days of B27 differentiation (B27 DIV#10) (n = 5 for all conditions). (D): Quantitative analysis of BrdU-positive cells, BrdU incubated during 24 hours of the first day of FGF-2 priming (FGF-2 DIV#1), the last 24 hours of the 5 days of FGF-2 priming (FGF-2 DIV#5), and the last 24 hours of the 5 days of FGF-2 priming plus 5 days of B27 differentiation (B27 DIV#10) (n = 3 for all conditions). The number of cells expressing nestin or BrdU decreased significantly after 5 days of FGF-2 priming and 5 days of B27 differentiation. Results are presented as mean ¡À SEM. *p 9 m" ?3 S& W' L T& _- v" |' [# L4 V
RSCs Differentiate into Retinal Neurons and Glial Cells" g- g5 \7 {3 n" e
. T' | ` V. d" KTo further characterize the cells generated before and during this two-step procedure, we plated the expanded RSCs on poly(L-ornithin) and laminin-coated coverslips in the expansion medium and fixed them as soon as they adhered (after a few hours) in order to process the RSCs for immunocytochemistry. Our results showed that no markers of the differentiated state such as ß-tubulin-III, an early neuronal marker, or GFAP, a marker of glial cells, were observed before the FGF-2 priming (Table 2). We then characterized the cells after the priming procedure. After 5 days of FGF-2 priming, RSCs generated a large percentage of cells adopting the neuronal fate: 57.4% ¡À 6.9% of the cells expressed ß-tubulin-III (Table 2, n = 3). Note that the neuron-like cells expressing the ß-tubulin-III filament are very immature and that they present few or no neurites, suggesting that these cells are composed by neuroblasts and immature neurons (Fig. 2A, 2B). High cell density (8 x 104 to 1.2 x 105 cells/well) was necessary to obtain such a percentage of cells committed to the neuronal fate. After 5 days of FGF-2 stimulation, we observed only a low percentage of mature neurons with neuritis, as previously described . Furthermore, a subpopulation of the FGF-2-primed and B27-differentiated cells expressed syntaxin (Fig. 2G and Table 2, 22.5% ¡À 2.9%, n = 4, two RSC culture preparations, passage 3 and passage 14), a marker of amacrine cells. For syntaxin immunocytochemistry, we used a biotinylated secondary antibody followed by the DAB peroxidase substrate which, in this case, gives a better sensitivity than immunofluorescence.6 \9 s' H# p$ t$ d, Q1 k+ ~. Y
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Table 2. Quantitative evaluation of different cell markers 8 p- }/ u- z7 d3 d. q ~/ G2 D F5 G* v( ^
Figure 2. RSCs possess the potential to differentiate along neural and glial cell lineages after FGF-2 and B27 stimulations. (A): Numerous FGF-2-primed cells started to express the early neuronal marker ß-tubulin-III. Note that the cells expressing the ß-tubulin-III filament are very immature and that they present few or no neuritis. (B): Enlargement of ß-tubulin-III-stained cells marked by a white square in (A). A ß-tubulin-III-positive cell is indicated with an arrow and a ß-tubulin-III-negative cell with an arrowhead. (C¨CG): After FGF-2 priming and differentiation with B27, cells differentiated along neural and glial lineages. (C): Exposure to B27 for 5 days sustained neuronal maturation, as revealed by the appearance of long neurites. (D): An illustration of ß-tubulin-III (arrows), Cy3 red signal, and GFAP (a marker of glial cells) (arrowhead), FITC green signal, double-labeled cells. (E): Phase-contrast image of (D) in which cells adopt a variety of neuronal (arrows) as well as glial (arrowhead) cell morphologies. (F): GS (M¨¹ller cells), Cy3 red signal; the nuclei of all cells are stained with DAPI (blue signal) in (A¨CD, F). (G): Syntaxin-positive cells (arrows) (marker of amacrine cells) and -negative cells (arrowhead). Magnifications: x200 (A, D, E), x400 (C, F, G). Abbreviations: DAPI, 4,6-diamidino-2-phenylindole; FGF, fibroblast growth factor; FITC, fluorescein isothiocyanate; GFAP, glial fibrillary acidic protein; GS, glutamine synthetase; RSC, retinal stem cell.0 D$ l) l; N- h/ {6 ]. |
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A direct incubation of the expanded RSCs in a medium containing the B27 supplement, without FGF-2 priming, had a significantly weaker effect on neuronal differentiation (6.1% ¡À 0.7% ß-tubulin-III-positive cells) and increased glia generation (69.9% ¡À 2.8% GFAP-positive cells) as compared with our standard two-step procedure (ß-tubulin-III-positive: 21.3% ¡À 4.4% and glial cells: 34% ¡À 2.5%, respectively) (Table 2). These results show that priming is necessary to obtain a large number of neurons and that B27 treatment induces retinal cell differentiation along the neural and glial lineages. In parallel experiments, we studied the potential contribution of laminin and heparan sulfate to the priming effect, independent of FGF-2. Laminin alone (in the absence of FGF-2 and heparan sulfate) had no effect: All the cells died within 48 to 72 hours (n = 3). Furthermore, cells plated on laminin in the medium plus heparan sulfate, in the absence of FGF-2, also died within 48 to 72 hours (n = 3). In the presence of FGF-2, 93.7% ¡À 1.54% (n = 3) of the cells were viable after 5 days of culture. Addition of the heparan sulfate proteoglycan could prevent FGF-2 degradation but had no priming effect independent of FGF-2, in our conditions. These results demonstrate that, in our culture conditions, FGF-2 is the factor necessary to prime RSCs into a neuronal fate, prior to the B27 switch.+ [# C) ? l; b1 Z# C* M
* b) j7 d$ m f- `. ]* |0 U6 vExpression of Photoreceptor Markers by the Primed and Differentiated Cells * e& H |3 p& H" a( w" V % a0 o t" j' }/ LWe investigated the potential of the FGF-2-primed and B27-differentiated RSCs to express photoreceptor markers. After 5 days of FGF-2 priming followed by 5 days of B27 treatment, we observed numerous bright cells with a neuronal morphology (Fig. 3A). Immunocytochemistry revealed that these bright cells expressed recoverin (Fig. 3B), a soluble calcium-binding protein, usually located in photoreceptors and in few bipolar cells (supplemental online Fig. 2S). Double-immunolabeling against recoverin and rhodopsin (Ret-P1 antibody) revealed that 99% of the rhodopsin-expressing cells were also positive for recoverin and that 100% of the recoverin-positive cells expressed rhodopsin (318 cells analyzed at passage five and 32; supplemental online Fig. 2S). 2 C& V0 X W: [3 w4 v+ Y6 R7 B$ ~+ [; G% X2 k; e* B+ n
Figure 3. RSC-derived cells expressed photoreceptor markers after FGF-2 priming and B27-stimulation. After a first step of FGF-2 priming of 5 days, cells were incubated with the B27 supplement for another 5 days. (A): Phase-contrast after FGF-2 and B27 stimulations. Note the numerous bright cells with a neuronal morphology (arrows). (B): Numerous bright cells of (A) are positive for recoverin (red labeling), a marker for photoreceptors and rare bipolar cells. (C): DAPI staining of nuclei of (B) showing that recoverin-expressing cells have a more condensed chromatin (arrows) in comparison with the other cells (arrowhead). (D): The chromatin of the photoreceptors located in the ONL is more dense in comparison with all the other cells of the retina (PN12). This difference also remains during adulthood. (E): Peripherin staining (green labeling) and (F) DAPI staining of the cells in (E). Magnifications: x400 (A¨CC, E, F), x200 (D). Abbreviations: DAPI, 4,6-diamidino-2-phenylindole; FGF, fibroblast growth factor; GCL, ganglion cell layer; INL, inner nuclear layer; ONL, outer nuclear layer (photoreceptor layers); PN, postnatal day.1 ~& B- N1 r! F0 R8 x/ p1 g
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Figure 4. RSCs possess the potential to differentiate along the photoreceptor lineage. (A): After FGF-2 priming and B27 stimulation, the differentiated cells expressed rhodopsin (arrows), an essential protein for phototransduction in photoreceptors. Some apoptotic cells (arrowhead) showed non-specific staining. These cells were not taken into account for the cell count. (B): DAPI staining of the nuclei of (A) showing that rhodopsin-expressing cells have a more condensed chromatin (arrows) in comparison with the other cells. Apoptotic cells (arrowhead) were not taken into account for the total cell count. (C, D): Primary cultures of PN1 retinal cells in FGF-2 and B27 showed that photoreceptors also have long neurites in these conditions, as revealed by rhodopsin labeling (C) and phase-contrast (D). (E, F): Cells were infected with a lentivirus expressing GFP under the control of the rhodopsin promoter (-GFP) (E) or under the control of the IRBP promoter (IRBP-GFP) (F) during the procedure of differentiation with the B27 supplement. GFP-positive cells are green. (G): Phase-contrast of (E). (H): Phase-contrast of (F). Magnification: x400. For quantification, see Table 2. Abbreviations: DAPI, 4,6-diamidino-2-phenylindole; FGF, fibroblast growth factor; GFP, green fluorescent protein; IRBP, interphotoreceptor retinoid-binding protein; PN, postnatal day; Rho, rhodopsin.) r3 C2 \7 [9 e( K1 ~( x% o
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These results demonstrate that the two-step procedure, FGF-2 priming and B27 treatment, is necessary for obtaining a large number of cells committed to the photoreceptor fate.: a: j6 z% w8 [+ J) n5 C: T
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In addition, we analyzed the expression of rhodopsin (using the Rho1D4 antibody) on primary cultures of photoreceptors and the morphology of these cells following the two-step procedure. PN1 primary retinal cells harbored a neuronal morphology in culture (Fig. 4D), and numerous cells were positive for the Rho1D4 antibody against rhodopsin (Fig. 4C). In our culture conditions, these photoreceptors also present neurites rather than being round as previously reported in studies using other media.$ T3 ]/ z1 [4 D8 ]1 F( {
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To analyze the activation of the rhodopsin promoter in the differentiated cells derived from the expanded RSCs, we plated 8 x 105 cells onto poly(L-ornithin) and laminin and primed these cells with FGF-2 during 5 days. Then, the cells were infected with a lentivirus expressing GFP under the control of the rhodopsin promoter (LV-Rhop-GFP) and exposed to B27 for five additional days. Immunocytochemistry using an antibody against GFP showed that 25.5% ¡À 4.3% (Table 2, n = 3) of the total cells were GFP-positive (Fig. 4E), showing an activation of the rhodopsin promoter by these cells. The GFP-positive cells harbored a neuronal morphology (Fig. 4G). Similarly, 29.95% ¡À 3.34% (Table 2; Fig. 4F, 4H) of the differentiated cells infected with a lentiviral vector expressing GFP under the control of the IRBP promoter (LV-IRBPp-GFP) expressed GFP. IRBP is a gene encoding for a protein expressed early during rodent retinal development .' Z* Y' b% p9 c e4 `, }4 b& i# g
5 G8 n5 k! _+ X0 m% VDetection of Transcripts Specific for Photoreceptors in Primed and Differentiated Cells ' N; X2 f6 h- K5 u" \9 |# { & C4 K7 { R% N% P# r1 yWe analyzed the ability of the differentiated RSCs to express regulatory genes that have been shown to be expressed in photoreceptors. As expected, we observed by reverse transcription-PCR (Fig. 5) that FGF-2 priming and B27 differentiation of RSCs resulted in the expression of peripherin-2, rhodopsin, and IRBP, as shown above by immunocytochemistry or lentiviral vector reporter activity. In the case of rhodopsin, it was necessary to perform a second PCR on cDNA of B27-differentiated cells to reveal the amplified product. A second PCR was also necessary to detect the amplified product for the positive control which represents the RNA extracted from adult retina, suggesting that we lack optimal conditions to amplify rhodopsin, which explains the discrepancy in immunocytochemistry results that show 34.8% ¡À 2.8% of differentiated rhodopsin-positive cells. In addition, we detected the expression of PDE-, a gene encoding for components of the phototransduction pathway . All these results corroborate the immunocytochemical observations that the FGF-2-primed and B27-differentiated RSCs acquire a photoreceptor phenotype.+ Z/ ^2 Z1 g& ^1 p9 k2 f
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Figure 5. RT-PCR of FGF-2-primed and B27-differentiated RSCs revealed genes expressed in photoreceptors. Cells differentiated in the B27 supplement after an FGF-2 priming step were harvested to undergo RT-PCR analysis. This figure is representative of three independent experiments showing the same results. After RT, the cDNA of the differentiated cells (RT ), the original RNA extract (negative control RT¨C), and the cDNA of adult retina as a positive control (C ) were amplified with specific primers. Differentiated cells expressed specific photoreceptor genes such as Crx, Mash1, rhodopsin, peripherin, IRBP, and PDE-. In the case of rhodopsin and PDE-, it was necessary to perform a second PCR on cDNA of B27-differentiated cells and cDNA of adult retina (for rhodopsin) to reveal the amplified sequence. Abbreviations: C , positive control; FGF, fibroblast growth factor; IRBP, interphotoreceptor retinoid-binding protein; PDE, phosphodiesterase; RSC, retinal stem cell; RT, reverse transcription; RT-PCR, reverse transcription-polymerase chain reaction.% `! |$ y6 B* S; g9 A' m4 s
2 m" w* P1 w/ d& gDISCUSSION ( d& m: u9 P' x+ T: M2 f$ t. g' _ ] U$ G
Herein, we describe specific conditions for the differentiation of expanded RSCs that produce a large number of cells committed to the photoreceptor fate as attested by the numerous photoreceptor markers expressed during the course of neuronal differentiation. This protocol offers an easy way to study photoreceptor neurogenesis and to provide a large source of retinal cells for transplantation studies. , E; g6 ]: H7 N' S7 [; q' K- b& N' [; L+ |% K; s, I" `# V& |; A( ]+ Q2 G
We have previously shown that the culture of radial glial cells derived from newborn mice contains a significant number of adherent RSCs able to expand up to 34 passages (1046 cells generated from one eye) without changing their proliferation rate and potential showed that long-term expanded neural stem cells, derived from the radial glia and also stimulated by FGF-2 and EGF, remain able to differentiate efficiently into neurons and astrocytes in vitro and upon transplantation into the adult brain.6 [6 X+ A7 o+ Z; ]: l% E/ G8 P" Z
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The induction of the cell fate of RSCs is controlled by not only intrinsic but also extrinsic signals arising from the microenvironment , however, in an earlier developmental stage, reported that in explants of E16 rat retina, exogenous FGF-2 did not have an effect on rhodopsin expression. In our study, we also did not observe expression of photoreceptor markers such as recoverin and rhodopsin after 5 days of FGF-2 stimulation of expanded RSCs, suggesting that our culture conditions maintain a large number of cells in a primitive stage. Our results show that FGF-2 priming induces neuronal commitment and that the B27 supplement directs subpopulations of these neurons toward a photoreceptor and an amacrine cell fate. All these results suggest that FGF-2 has a different action depending on the cell identity. $ y. u. @% j$ s/ K8 O9 N1 R+ z/ E( p$ w
FGF-2 priming and B27 differentiation also generated a moderate percentage of glial cells (39%) and a high percentage of retinal neurons (57%, including cells committed to the photoreceptor and amacrine cell phenotypes) in comparison with other methods generally used to induce cell differentiation. We showed that direct plating of mitogen-expanded RSCs onto laminin-coated coverslips and incubation with B27, without FGF-2 priming, generated a large number of glial cells (69%) and few neurons (6%), showing that the FGF-2 priming procedure is necessary to generate numerous neurons (57%). Our results correlate with those of Wu et al. . These data and our present results suggest that FGF-2 had stimulated neuroblast and bipotent precursor proliferation, thus enhancing the yield of neurons.$ k2 R( h! g3 j B
4 c% V* j- g: ROur results showed that even after extensive amplification, B27-differentiated RSCs primed with FGF-2 expressed photoreceptor regulatory genes such as the homeobox gene Crx and the bHLH gene Mash1. Crx and Mash1 have been described as being important for photoreceptor development ; the presence of the two latter were also confirmed at the protein level. In addition, differentiated cells expressed the recoverin protein controlling Ca2 trafficking. These observations show that the differentiated cells initiate and undergo a robust program of photoreceptor differentiation at multiple gene levels. However, we did not detect any expression of the phototransduction gene PDE-ß, and the level of expression of PDE- was weak; we performed two PCRs reaching a total of 60 cycles of amplification to detect this product, indicating that our differentiation conditions can be improved in order to obtain fully differentiated photoreceptors. Moreover, further experiments are necessary to determine whether the photoreceptor cells derived from RSCs can become functional.: W4 R) T: p j5 t1 q
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As mentioned above, the B27-differentiated cells also expressed rhodopsin, a phototransduction gene. Several studies have indicated that Crx is responsible for controlling the expression of photoreceptor genes, including rhodopsin and Crx itself reported that in vitro human RSCs produce photoreceptors with only a round morphology, whereas after transplantation, RSCs generate cells with photoreceptor morphology and markers.) f* ~; [5 R7 [* E2 ?/ B
1 }0 V8 s9 z- |- zCONCLUSION 2 l* _6 y9 ?! u " U3 D. i% Z1 J# t' Q* e+ B: PPrevious studies of transplantation of progenitor cells into animal models of retinal degeneration have shown photoreceptor differentiation of grafted cells but limited levels of graft-host integration observed that a high number of grafted rat E17 RPCs differentiated into photoreceptors in vivo. However, these cells underwent only two passages before transplantation and the authors did not investigate whether such results could be obtained after several passages. Here, we generate a large number of expanded RSCs and differentiated cells committed to the photoreceptor phenotype in a repetitive and reliable manner. In the future, these cells will enable us to answer the question of whether the cells most adequate to integrate a degenerating retina are RSCs or cells already differentiated into photoreceptors. The availability of such cells can serve for understanding mechanisms that regulate the specification of retinal neurons and also provide an unlimited cell source for studying cell replacement for degenerative diseases of the retina.; C t- s2 x% ?8 p. G9 F
3 }- L! B$ }- N4 ]% f0 z( KDISCLOSURES& w. g5 c7 q& t9 P+ a
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The authors indicate no potential conflicts of interest. . b/ Y3 }3 {5 l$ z7 O, j ) q5 E4 ^. K; A4 u j7 P0 R) Y, BACKNOWLEDGMENTS! w7 T* {! \0 J
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We thank R.D.G. McKay for the generous gift of the anti-nestin antibody, Gabriel H. Travis and Walid N. Moghrabi for the anti-peripherin antibody, Jean Bennett for the rhodopsin promoter, Donald Zack and Q.L. Wang for the IRBP promoter, D. Hornfeld for editing help, and A. Bemelmans for scientific discussions. This work was supported by the Swiss National Science Foundation, the ProVisu Foundation, the Velux Foundation, and the French Association Against Myopathies.; P% P c, r% P+ k. r }4 A
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