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Previous Article | Next Article
Volume 17, Number 4, Issue of February 15, 1997 pp. 1425-1434
Copyright ©1997 Society for NeuroscienceThe Expression and Function of Notch Pathway Genes in the Developing Rat Eye
Zheng-Zheng Bao and Constance L. Cepko Harvard Medical School, Department of Genetics and Howard Hughes Medical Institute, Boston, Massachusetts 02115
ABSTRACT
The Notch gene plays a role in the development of disparate tissues in multiple organisms. Because the vertebrate eye is an excellent model system for both patterning and cell fate determination, two processes that can involve Notch, we examined the expression patterns of Notch 1 and Notch 2, and their ligands Delta and Jagged, in the developing rat eye. Notch 1 and Delta were found to be expressed in the neural retina during the period of cell fate determination and differentiation. Notch 2 was found to be expressed in the non-neuronal derivatives of the optic cup, including the pigment epithelium, optic stalk, and ciliary body. Jagged was expressed in distinct regions within the optic vesicle, ciliary body, and lens, with patterns that changed over time. The potential function of Notch 1 in cell-type specification and differentiation was examined by introducing a constitutively active form of Notch 1 in vivo using a replication-incompetent retrovirus. This form of Notch 1 was found to cause abnormal growth and interfere with the differentiation of multiple retinal cell types.
Key words: Notch 1; Notch 2; Delta; Jagged; eye development; neural retina; PE; ciliary body; expression pattern
INTRODUCTION
The vertebrate eye has been an excellent model system for both neurobiologists and developmental biologists. The areas that have received the most attention are the formation of the various components of the eye through inductive interactions and the determination and differentiation of retinal neurons. For example, the anterior neural plate has been found to be necessary for induction of the lens placode, whereas the optic vesicle and lens are thought to induce overlying surface ectoderm to form the cornea (Duke-Elder and Cook, 1963
; Graw, 1996
Vertebrate homologs of characterized Drosophila genes have proven to be a valuable starting point for studying complex developmental processes in vertebrates. The Notch gene is among the best-characterized genes in Drosophila (for review, see Artavanis-Tsakonas et al., 1995
The Notch gene encodes a large transmembrane receptor. The extracellular domain of Notch interacts with the ligands Delta and Serrate (Vässin et al., 1987
Vertebrate homologs of Notch, Delta, and Serrate have been identified in several species (Betterhausen et al., 1995
To begin to examine these issues in a vertebrate system, we set out to study the expression patterns of the genes in the Notch pathway, including Notch 1, Notch 2, Delta, and Jagged (the rat homolog of the Serrate gene) in the developing rat eye. We have further explored the function of Notch using a replication-incompetent retroviral vector to deliver a gain-of-function allele of Notch to the developing rat retina in vivo.
MATERIALS AND METHODS
In situ hybridization. The cDNA fragments corresponding to nucleotide sequence 6737-7279 of rat Notch 1 (GenBank number X57405[GenBank]) and 6887-7443 of rat Notch 2 (GenBank number M 93661) were obtained by RT-PCR and confirmed by sequencing. The cDNA fragments were cloned into pBluescript (Stratagene, La Jolla, CA) and served as templates for Notch 1 and Notch 2 probes. This region between the cdc10/ankyrin repeats and PEST was chosen because it is the least conserved region among the mammalian Notch genes. Between Notch 1 and Notch 2, there is only 34% similarity in this region. The template for the rat Delta 1 probe was similarly obtained by RT-PCR on the basis of the nucleotide sequence 320-820 of the mouse Delta 1 sequence (GenBank number X 80903). The probe for Jagged was full length and was kindly provided by G. Weinmaster (University of California Los Angeles School of Medicine, Department of Biological Chemistry) (Lindsell et al., 1995
Whole-mount and section in situ hybridization procedures were essentially as described in Riddle et al. (1993)
Production of retroviruses. A replication-incompetent pLIA viral vector, based on the pBABE vector [derived originally from Moloney Murine Leukemia Virus (MMLV) by Morgenstern, 1990 70°C before use. The titers for mNIC, mNEC, and control LIA viruses after concentration were 2 × 106, 1 × 107, and 2 × 107 CFU/ml, respectively.
Fig. 5. Viral constructs for expressing truncated forms of the Notch 1 gene. A, Full-length Notch 1 protein consists of extracellular EGF repeats, Lin/Notch repeats (LN), transmembrane domain (TM), cytoplasmic cdc10/ankyrin repeats, and a PEST sequence. Truncations of Notch, mNIC, and mNEC, with myc epitope tags, were inserted into the cloning site of pLIA. B, pLIA retroviral vector. On the basis of the MMLV backbone, pLIA has a cloning site for expressing exogenous genes under the transcriptional control of the LTR. It also contains an IRES sequence directing the translation of a marker gene, PLAP.
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Infection of retinae. In vivo infection of retinae was carried out by injection of virus into the eyes of postnatal day 0 (P0) rats (C/D, Charles River Laboratories, Wilmington, MA). The subretinal space between the PE and retina was targeted (Turner and Cepko, 1987
E18 rat retinal explants were infected in vitro by the following procedures. Retinae were dissected and placed on top of polycarbonate filters with 0.8-µm-diameter pore (Costar, Cambridge, MA). The filters were then floated in medium containing 45% DMEM, 45% F12 medium, and 10% fetal calf serum (FCS), in 12-well culture plates. Viral infection was carried out immediately by adding 1 µl of a viral stock with 8 µg/ml of polybrene in a drop of medium (~50 µl) covering the retina. The retinal explants were cultured at 37°C in a 5% CO2 humidified incubator and harvested 2 weeks later. For double staining, X-gal histochemistry for -galactosidase activity was carried out first. The tissues were washed extensively with PBS before the AP staining proceeded.
Immunohistochemical staining. Anti-myc tag antibody (9E10) was purchased from Santa Cruz Biotechnology (Santa Cruz, CA). NIH 3T3 cells infected with either mNIC or mNEC viruses were fixed with 4% paraformaldehyde at room temperature for 10 min. After they were blocked with 10% FCS in DME plus 0.2% Triton X-100 for 30 min, the cells were incubated with 0.5 µg/ml 9E10 antibody in 1% bovine serum albumin (BSA) in PBS for 1 hr at room temperature. Biotinylated anti-mouse secondary antibody (Vector Laboratories, Burlingame, CA) was used at 1:400 dilution in 1% BSA and 1% normal horse serum. It was followed by incubation with avidin and biotin-conjugated horseradish peroxidase complexes (Elite ABC kit, Vector Laboratories) for 20 min at room temperature. DAB substrate kit (Vector Laboratories) was used to visualize the staining.
RESULTS
Expression patterns of Notch 1, Notch 2, Delta, and Jagged define domains in the embryonic rat eye
To define the expression patterns of genes in the Notch pathway, in situ hybridization was carried out on intact embryos ("whole mounts") and sections of ocular structures. At rat E12.5, the lens placode has not yet invaginated to form the lens vesicle, and the PNR appears thicker than the PPE (Fig. 1A). Sections and whole mounts of E12.5 embryos were hybridized with antisense probes for Notch 1, Notch 2, Delta, and Jagged. At this stage, Delta RNA was not detectable in the optic vesicle, but was detectable at a high level in scattered cells in the ventricular zone (VZ) of the forebrain (Fig. 1B). In contrast, Jagged was found to be expressed at a high level in both the PNR and the lens placode. Jagged expression was limited to the dorsal half of these areas (Fig. 1C,D). Notch 1 expression was barely detectable in the optic vesicle at this stage, but was detectable at a high level in the forebrain VZ (data not shown). A low level of Notch 2 expression was seen in the PPE (data not shown).
Fig. 1. Expression of Delta and Jagged in the optic vesicle at E12.5. A, Diagram of the E12.5 optic vesicle. B, In situ hybridization of a section with the Delta probe. Delta was not detected in the optic vesicle region (marked by arrowheads). In contrast, Delta hybridization was observed in a subset of cells in the VZ of the forebrain (F). C, In situ hybridization with the Jagged probe. Jagged hybridization was observed in the dorsal region of both PNR and lens placode. It was also expressed in the VZ of the forebrain. D, Whole-mount in situ hybridization with the Jagged probe. Jagged hybridization was observed in the dorsal region of the retina (arrow) and lens placode (arrowhead). LP, Lens placode; PPE, presumptive pigment epithelium; PNR, presumptive neural retina.
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At E15.5, the lens vesicle and optic cup are completely formed due to the invagination of the lens placode and optic vesicle, respectively. The PE comprises a layer that is one cell thick surrounding the neural retina. Sections of the eye of an E15.5 embryo were hybridized with Notch 1, Notch 2, Delta, and Jagged probes. At this stage, Notch 1 and Delta were expressed in many cells in the neural retina (Fig. 2A,C). The positive cells, however, appeared to be excluded from the periphery of the retina, the area corresponding to the presumptive ciliary body and iris. Interestingly, Jagged expression was limited to the presumptive ciliary body region and was not seen in the neural retina or presumptive iris (Fig. 2D). Jagged was also expressed at higher levels on the ventral side of the ciliary body region (Fig. 2D, inset), in contrast to its dorsal-restricted expression pattern at E12.5. Notch 2 was absent from the neural retina but was expressed in the PE and optic stalk (Fig. 2B). Only Jagged was expressed in the lens, mostly in the equatorial region, and to a lesser extent in the anterior portion in the area of actively proliferating cells (Fig. 2D). At this stage, the posterior of the lens is filled by differentiating lens fiber cells. 
Fig. 2. Expression of Notch 1, Notch 2, Delta, and Jagged in the E15.5 eye cup. Coronal sections of an E15.5 rat eye (ventral side) are shown. A, Notch 1 expression was observed only in the neural retina. B, Notch 2 expression was observed in the PE and optic stalk. C, Delta expression was observed in neural retina, similar to that of Notch 1. D, Jagged hybridization signal was observed in the presumptive ciliary body and the equatorial region and anterior of the lens. In contrast to the earlier dorsal expression patterns, the expression of Jagged was largely symmetrical in the dorsal and ventral sides of the optic cup and lens (inset). NR, Neural retina; CB, ciliary body region; I, iris; L, lens; OS, optic stalk; PE, pigment epithelium.
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Notch pathway genes are expressed in areas of active neurogenesis and morphogenesis
Notch 1 expression correlates well with neurogenesis in the retina, which occurs from E14 to P10, with the peak around P0 (Alexiades and Cepko, 1996
Fig. 3. Expression of Notch 1, Notch 2, Delta, and Jagged in the postnatal eye. A, Diagram of the cellular composition of the P5 retina. At this age, three layers can be distinguished. The ganglion cell layer contains mostly differentiated ganglion cells; the inner plexiform layer consists of dendritic processes of the differentiated amacrine cells and ganglion cells; the VZ has both differentiated and undifferentiated cells at this stage. Differentiated cone photoreceptors and some rod photoreceptors are located within the top half of the VZ, whereas horizontal cells are within the center and bottom half of the VZ. B, Notch 1 in P5 retina; C, Notch 1 in adult retina; D, Delta in P5 retina; E, Notch 2 in P5 eye; F, Jagged in P5 eye. Note that both Notch 2 and Jagged are expressed in the ciliary body (arrows). A subset of cells in the INL and GCL also express Jagged (arrowheads). GCL, Ganglion cell layer; IPL, inner plexiform layer; VZ, ventricular layer: N, undifferentiated neuroblast; c, cone photoreceptor; h, horizontal cell; a, amacrine cell; g, ganglion cell; r, rod photoreceptor.
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Postnatal Notch 2 expression appeared to be stronger in the ciliary body region than in the PE, in contrast to the E15 expression pattern (Fig. 3E). Jagged expression was confined to the ciliary body (Fig. 3F). Extending from the periphery of the optic cup, the ciliary body undergoes extensive folding in the neonatal period. At P0 and P5, a subset of inner nuclear layer cells and ganglion layer cells also appeared to express Jagged (Fig. 3F).
The spatial and temporal expression patterns of Notch 1, Notch 2, Delta, and Jagged are summarized in Figure 4. They appear to define different domains in the developing eye. Notch 2 expression is only in the non-neuronal tissues, including the PE, optic stalk, and ciliary body, whereas Notch 1 is expressed only in the neural retina. The domain of Delta expression is largely overlapping with that of Notch 1. The spatial-temporal pattern of expression of Jagged is especially dynamic. Its expression is seen in the neural retina, ciliary body, and lens. In each case, it is expressed by a subset of cells in a particular region (e.g., dorsal retina and lens placode at E12.5). 
Fig. 4. Schematic summary of Notch 1, Notch 2, Delta, and Jagged expression patterns in the developing eye, at E12.5 (A, B), E15.5 (C, D), P0 (E, F). Notch 1 and Jagged patterns are shown in A, C, E; Notch 2 and Delta patterns are summarized in B, D, F.
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Persistent Notch activity interferes with retinal cell differentiation
The expression patterns of Notch 1 and Delta correlate well with specification and differentiation in the neural retina. To assess the role of Notch 1 in the developing retina, a replication-incompetent retrovirus was used to express portions of the Notch 1 gene. This approach allowed examination of the effects of these genes on small subsets of cells in an otherwise unperturbed retina. The retroviral vector, LIA, was engineered to express a cDNA from the LTR promoter, which also includes an IRES sequence directing the translation of the human PLAP gene (Fig. 5B). This enables detection of infected clones by histochemical staining for AP. mNIC encodes the cytoplasmic domain of mouse Notch 1 with a myc tag at the N terminus (Fig. 5A). mNEC encodes the extracellular and transmembrane domains of mouse Notch 1 with a myc tag attached at the C terminus (Fig. 5A). On the basis of the results obtained with similar truncations in Drosophila Notch (Rebay et al., 1993
To examine the expression of the Notch constructs, NIH 3T3 cells were infected by the viruses, and the expression of the truncated Notch genes was examined by immunohistochemical staining with an anti-myc antibody. The mNIC-infected clones demonstrated mostly nuclear staining, whereas mNEC-infected clones displayed staining on the plasma membrane (Fig. 6A,C). This is consistent with previous findings that truncated Notch, without the extracellular domain, is translocated to the nucleus, although full-length Notch is localized on the cell membrane (Fortini et al., 1993 
Fig. 6. Expression of the truncated Notch 1 gene in infected 3T3 cells, detected by immunohistochemical staining with an anti-myc antibody, 9E10. A, mNIC-infected 3T3 cells stained with the 9E10 monoclonal antibody (mAb). B, mNIC-infected 3T3 cells stained with X-Phos/NBT shows the expression of PLAP. C, mNEC-infected cells stained with the 9E10 mAb. Note that the Notch 1 intracellular domain was mostly translocated to nuclei, whereas the Notch 1 extracellular domain was localized to the cell membrane.
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Newborn (P0) rat retinae were infected in vivo by intraocular injection of virus (Turner and Cepko, 1987 
Fig. 7. Clonal morphology of LIA- and mNIC-infected clones. P0 retinae were infected in vivo by intraocular injection. Retinae were harvested 3 weeks later, stained with X-Phos/NBT, and then sectioned to reveal clonal morphology. A-C, Control LIA-infected clones. Four cell types were observed: rod photoreceptor, amacrine cell, bipolar cell, and Müller glia. D-F, mNIC-infected clones. Note the grossly abnormal morphology within clones infected with the virus expressing an activated form of Notch 1. OS, Outer segment layer; IS, inner segment layer; ONL, outer nuclear layer; OPL, outer plexiform layer; INL, inner nuclear layer; IPL, inner plexiform layer; GCL, ganglion cell layer; a, amacrine cell; r, rod photoreceptor; b, bipolar cell; m, Müller glia.
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The mNIC-infected clones displayed grossly abnormal morphology and were much larger than the control LIA-infected clones (Fig. 7D-F). Although the control clones were usually contained within one 20 µm section, the majority of mNIC-infected clones spanned 5-10 sections. Extensive attempts to quantify the number of cells within the mNIC clones were unsuccessful. The formazan precipitate obscured the position of cell bodies, particularly because the processes were heavily labeled and wrapped around nearby cells. The formazan precipitate also absorbed fluorescence of dyes such as DAPI, making it difficult to count the number of nuclei within a clone. Nonetheless, when a series of sections were made through mNIC-infected clones, it was clear that there were more than two cells within a clone, making these clones larger than the control, LIA-infected clones.
Although clonal morphology varied among the mNIC clones, the most common morphology (35 of 45 clones) resembled a "Christmas tree" with a major "trunk" extending across the retina (Fig. 7D-F). Long, horizontal processes ("branches") were found in both the optic fiber layer and the inner plexiform layer. Shorter processes were seen in the outer plexiform layer. Some clones had a more severe phenotype in which the extensive formazan precipitates in the stained cells almost resembled a tumor. The laminated structure of the retina was disturbed around the clones and appeared thicker than in uninfected regions. A few clones (2 of 45 clones) had normal morphology. The effect of the mNEC virus was assayed similarly; however, the mNEC-infected clones appeared to be completely normal, with normal morphology, clonal composition, and size (data not shown).
To determine whether embryonic retinal cells responded similarly to the truncated forms of Notch, E18 retinae were used for infection. Because injection into the subretinal space is much more difficult in utero, E18 retinae were dissected, infected, and cultured as explants. Viruses were added to the explant on the first day of culture, and the infected retinae were harvested 2 weeks later. The growth and differentiation of retinal cells in explant cultures are similar to those in vivo (Sparrow et al., 1990 
Fig. 8. Morphology of mNIC- and mNEC-infected clones within retinal explants. E18 retinal explants were co-infected with BAG virus, encoding lacZ, and mNIC virus (A) or mNEC virus (B). The explants were harvested 2 weeks later and processed to visualize both BAG-infected clones (blue) and mNIC- or mNEC-infected clones (purple). Photographs were taken from the photoreceptor side of the retina. Note mNIC-infected clones were very large, with abnormal morphology, including extensive processes. In contrast, mNEC-infected clones appeared normal. The effect of the activated Notch appeared to be restricted to infected cells, because blue clones were normal even when located very close to mNIC-infected clones (arrows).
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DISCUSSION
In this study, we determined the expression patterns in the developing eye of several genes in the Notch pathway: Notch 1, Notch 2, Delta, and Jagged. We have also investigated the function of Notch 1 in vivo by using a replication-incompetent retrovirus to deliver a constitutively active allele of Notch 1. For genes such as Notch, which can have broad and complex effects, analysis of gene function within clones in an otherwise normal environment allows one to examine cell autonomous effects. With use of this retroviral strategy, it was found that activated Notch interferes with the normal differentiation of retinal cells, resulting in large aberrant clones with abnormal morphology.The expression patterns of Notch pathway genes suggest a role in the patterning of the eye
The expression patterns of Notch 2 and Jagged suggest a role in the patterning of ocular tissues. Notch 2 was expressed only in the non-neuronal derivatives of the optic cup, including the PE, optic stalk, and ciliary margin. The onset of Notch 2 expression in these domains was quite early. Therefore, Notch 2 will be useful as an early marker for these regions. Because very little is known about the mechanisms that define these nonretinal tissues as distinct from the contiguous retina, it will be of interest to investigate whether Notch 2 plays an active role in patterning this region of the optic cup.
The expression of Jagged in the developing eye also suggests a role in patterning. Its expression was seen as early as E12.5 in the dorsal regions of the optic vesicle and lens placode. Patterning along the dorsal/ventral (DV) and anterior/posterior axes is evident within several laminae of the retina. Retinal ganglion projections to the tectum depend on the DV position of ganglion cells in the retina. Some Eph family receptor tyrosine kinases are expressed in a gradient in the retina along the DV axis (Cheng et al., 1995
In Drosophila, the role of the Notch pathway in tissue patterning and morphogenesis has been studied. It has been found that Notch, Delta, and Serrate are essential for wing margin formation and outgrowth (Couso et al., 1995 Expression of Notch 1 and Delta suggests a role in cell fate determination
The expression of Notch 1 and Delta in the developing eye appears to be within undifferentiated progenitor cells of the neural retina. This is consistent with their expression in the other regions of developing CNS (Coffman et al., 1990Notch activity and cell differentiation
Expression of an activated Notch 1 allele in retrovirally infected cells led to aberrant differentiation of retinal cell types in an otherwise normal environment. Analogously, Notch has been shown to be involved in the differentiation pathway of multiple cell types in Drosophila and Xenopus retina. Expression of activated Notch appears to block cell differentiation (Cagan and Ready, 1989
Among mNIC-infected clones, the most common "Christmas tree" morphology resembled aberrant Müller glial cells and/or undifferentiated neuroblast cells. Only Müller glia and undifferentiated neuroblasts have vertical processes extending across all retinal layers. Undifferentiated neuroblast cells do not have horizontal processes. The mNIC clones, however, had extensive horizontal processes. If these clones were indeed aberrant Müller glial cells, Notch may block neuronal differentiation but allow some aspects of glial differentiation to take place. Definitive identification of the mNIC-infected cells will require characterization by molecular markers. Unfortunately, we have been unable to detect the infected clones by indirect immunofluorescent staining, because of the low expression levels of the myc tag and AP in the infected clones. Thus, clones could only be located using the more sensitive AP histochemical staining, and the formazan precipitates that result obscure fluorescence and other detection methods that could be used to detect cell type-specific antigens within a clone. The low expression levels of the mNIC construct were unusual, because the control LIA and mNEC had much higher expression levels. One possible explanation is that a high level of Notch activity kills infected cells, and thus only those clones with low expression levels, e.g., attributable to a disadvantageous integration site, survive. In support of this idea is the finding that the titers of mNIC on NIH 3T3 cells or within the retina were 5- to 10-fold lower than the other two constructs used in this study and compared with other constructs that we have made.
Although the problem with detection has also prevented us from determining the number of cells per clone, it appears that the size of the mNIC clones was ~10 times larger than the control clones. Although the increased size may be attributable to the presence of very large cells, it seems that on sections of some mNIC clones there are more than the two cells that are observed in control, LIA-infected clones. It appears likely that the large clones are attributable to abnormal proliferation and abnormal morphology. Proliferation has been seen to result from other studies of truncated Notch. A truncated Notch 1 homolog in human (TAN-1) and in mouse (int-3) have been shown to cause distinct forms of T cell lymphoma and mammary tumors, respectively (Ellisen et al., 1991
FOOTNOTES
Received July 25, 1996; revised Dec. 5, 1996; accepted Dec. 13, 1996.
This work was supported by funding from the Howard Hughes Medical Institute and the National Institutes of Health (Grant EYO 9676 to C.L.C. and EY 06726-01 to Z.-Z.B.). We thank Dr. Jeffrey S. Nye for his generosity in providing the mNIC and mNEC constructs, and Dr. Gerry Weinmaster for her gift of the Jagged probe. We thank John Lin, Eric Morrow, Michael Belliveau, Xianjie Yang, Malcolm Logan, and Vern Twombly for discussion and helpful comments on this manuscript, and Liz Molinari and Shawn Fields-Berry for excellent technical assistance.
Correspondence should be addressed to Dr. Constance L. Cepko at Harvard Medical School, Department of Genetics and Howard Hughes Medical Institute, 200 Longwood Avenue, Boston, MA 02115.
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