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Atrophy of Müller Glia and Photoreceptor Cells in Chick Retina Misexpressing cNSCL2

From the Department of Ophthalmology, University of Alabama at Birmingham School of Medicine.

	Abstract

Top Abstract Introduction Methods Results Discussion References

 
PURPOSE. To investigate whether and how the basic helix-loop-helix (bHLH) gene cNSCL2 is involved in retinal development.

METHODS. cNSCL2, the chick homologue of human NSCL2, was isolated and sequenced. In situ hybridization was used to examine its spatial and temporal expression pattern in the retina. Replication-competent retrovirus RCAS was used to drive cNSCL2 misexpression in the developing chick retina, and the effect of the misexpression was analyzed.

RESULTS. Expression of cNSCL2 in the retina was restricted. Its mRNA was detected in amacrine and horizontal cells, but not in photoreceptor, bipolar, or ganglion cells. Retroviral-driven misexpression of cNSCL2 in the developing chick retina resulted in missing photoreceptor cells and gross deficits in the outer nuclear layer (ONL). These deficits were probably not because of decreased photoreceptor production, in that the ONL appeared normal in early developmental stages. TUNEL⁺ cells were detected in the ONL, indicating that photoreceptor cells underwent apoptosis in retinas misexpressing cNSCL2. Müller glial cells were far fewer in the experimental retina than in the control, indicating that cNSCL2 also caused Müller glia atrophy. The onset of Müller glia disappearance preceded that of photoreceptor degeneration.

CONCLUSIONS. Expression of cNSCL2 in the chick retina was restricted to amacrine and horizontal cells. Misexpression of cNSCL2 caused severe retinal degeneration, and photoreceptor cells and Müller glia were particularly affected.

	Introduction

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The vertebrate retina contains six major types of cells: photoreceptors, horizontal cells, bipolar cells, amacrine cells, ganglion cells, and Müller glia. These cells are stereotypically organized into three nuclear layers separated by two synaptic layers. During retinal neurogenesis, precursors of each cell type migrate to their prospective location and undergo a unique differentiation program, enabling them to assume a distinct morphology and to perform a discrete function. The molecular mechanism underlying retinal development is not fully understood.

The Drosophila proneural genes, achaete-scute complex and atonal, encode the basic helix-loop-helix (bHLH) family of transcription factors and play important roles in neurogenesis in the fly. In vertebrates, a number of homologues have been identified and shown to play important roles in nervous system development.¹ In the developing retina, mash-1/cash-1, ngn1, math-5/cath5, and math3/cath3 are expressed in progenitor cells.^{2 3 4 5 6 7 8 9} math3/cath3 is also expressed in bipolar cells.^{10 11} Various spatial patterns of neuroD expression have been reported.^{7 8 11 12 13 14 15} Significant progress has been made in understanding how these proneural genes function during retinal neurogenesis. Mice without mash-1 do not exhibit any obvious abnormalities in eye development during embryogenesis and at birth, the time when the mutant mice die,^{16 17} but explant cultures of mash-1^-/- retinas showed a delay in differentiation of rod photoreceptors, horizontal cells, and bipolar cells; a decrease in bipolar cell number, and an increase in glia.¹⁷ Retinal explant cultures were also used to examine retinal phenotype of neuroD null mutation, and it is reported that mouse neuroD plays multiple roles during retinal development.¹⁵ Studies from our laboratory indicated that chick neuroD is involved in specifying a photoreceptor cell fate.^{14 18 19} Misexpression of neuroD in the developing chick retina results in an overproduction of photoreceptor cells specifically, and ectopic neuroD expression in cultured RPE cells promotes de novo generation of photoreceptor cells selectively.^{14 18 19}

NSCL is a two-member subfamily of bHLH genes homologous to Drosophila proneural gene atonal. Mammalian NSCL1 and NSCL2 were originally cloned by low-stringency hybridization.^{20 21} Northern blot analysis and in situ hybridization revealed that expression of mammalian NSCL1 and NSCL2 is specific to neural tissues.^{20 21 22} DNA microarray analysis has identified NSCL2 as a target of p53.²³ Targeted deletion of NSCL2 has been reported to result in a disruption of the hypothalamic–pituitary axis and triggers adult-onset obesity in mice.²⁴ The expression and function of mammalian NSCL1 and NSCL2 in retinal development remain to be studied.

cNSCL1 is the chick homologue of mammalian NSCL1 and, similar to its mammalian counterpart, appears specific to neural tissues.²⁵ In the developing retina, cNSCL1 is expressed transiently in the developing ganglion cells and later in Müller glia.²⁶ Misexpression of cNSCL1 decreases cell proliferation activity in the retina and in the external granular layer of the developing cerebellum,^{25 26} suggesting that one function of cNSCL1 may be to prevent postmitotic cells from reentering the cell cycle.

To learn whether and how NSCL2 is involved in retinal development, we cloned its chick homologue, cNSCL2, examined its expression pattern in the retina, and studied the effect of its misexpression on retinal development. We found that cNSCL2 was expressed in amacrine and bipolar cells. Misexpression of cNSCL2 in the developing retina resulted in retinal degeneration with profound atrophy of photoreceptors and glia.

	Methods

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Cloning of cNSCL2
We probed an E8 brain cDNA library²⁷ with human NSCL1.^{20 21} Among the positive clones, two were highly homologous to the human NSCL2 sequence^{21 22} and were named cNSCL2 (GenBank accession number AF109012). (GenBank is provided in the public domain by the National Center for Biotechnology Information and is available at http://www.nlm.nih.gov/genbank/.) The same library was probed using cNSCL2. Among the 28 clones isolated, 18 contained the cNSCL2 sequence.

In Situ Hybridization
Digoxigenin-labeled antisense RNA probes were synthesized from template DNA that contained approximately 1 kb of the 3' untranslated sequence and 138 bases of the 3' coding sequence (corresponding to the C' terminal 46 amino acids). In situ hybridization was performed on retinal cryosections as previously described.²⁶

Generating RCAS-cNSCL2 Retrovirus
The coding sequence of cNSCL2, along with 27 bases of the 5' untranslated region and 860 bases of the 3' untranslated region, was digested out of a cDNA clone with SmaI and XhoI. The DNA fragment was inserted into shuttle vector ClaI2Nco. A ClaI cassette was then generated and placed into RCAS, a replication-competent retrovirus.²⁸ Transfection with the recombinant proviral DNA and production of viral stock were as described.¹⁴ The control virus expressing green fluorescent protein (GTP) was generated previously.¹⁴

Microinjection of RCAS-cNSCL2
Retrovirus RCAS-cNSCL2, or RCAS-GFP, was microinjected into the neural tube and the subretinal space at E2, stage 15 to 17, as previously described.¹⁴ Retinas were harvested at different developmental stages and analyzed histologically in combination with immunostaining and in situ hybridization.

Immunohistochemical Analyses
Standard procedures of immunocytochemistry were used. Anti-LIM (4F2, 1:50), anti-AP2 (3B5, 1:50), and anti-vimentin (H5, 1:1000; or AMF-17b, 1:500) were obtained from the Developmental Studies Hybridoma Bank (Iowa University, Iowa City). Polyclonal anti-AP2 antibody (1:500) was purchased from Santa Cruz Biotechnology (Santa Cruz). Monoclonal antibody against Brn3a (1:200) was purchased from Chemicon (Temecula, CA). Pulse-labeling chick embryos with bromodeoxyuridine (BrdU) and detection of BrdU incorporation were performed as previously described.²⁶

Detection of Apoptotic Cells
The presence of apoptotic cells in cryosections of the developing retina was examined by the TUNEL method using a cell death detection kit (In Situ Cell Death Detection; Roche Molecular Biochemicals, Indianapolis, IN) according to the manufacturer’s instructions.

	Results

Top Abstract Introduction Methods Results Discussion References

 
Sequence of cNSCL2
Library screening identified a bHLH gene encoding a protein of 137 amino acids. The bHLH domain of the isolated sequence was 100% identical with that of human NSCL2, and the overall sequence identity between them was 81% (Fig. 1) . We therefore referred to this gene as cNSCL2, the chick homologue of mammalian NSCL2. The bHLH domain of cNSCL2 is 95% identical with that of cNSCL1, with 61% overall sequence identity (Fig. 1) .

View larger version (26K): [in this window] [in a new window]   Figure 1. Alignment of the deduced amino acid sequence of cNSCL2 with that of human NSCL2 and NSCL1 and chick cNSCL1. Identical residues are indicated by dots. Gaps, represented by hyphens, were introduced to maximize homology. The bHLH region is marked.

View larger version (114K): [in this window] [in a new window]   Figure 2. Spatial-temporal pattern of cNSCL2 expression in the developing retina. (A–C) Cryosections of chick retinas at E4 (A), E7 (B), and E10 (C) hybridized with digoxigenin-labeled antisense RNA probes against cNSCL2. (D–F) Double labeling of E15 retina with anti-cNSCL2 RNA probes and anti-AP2 antibodies. (D) View of cNSCL2 mRNA-positive cells; (E) view of AP2+ cells with epifluorescence; (F) simultaneous view of both cNSCL2 mRNA+ cells and AP2+ cells demonstrates a colocalization of the two markers. Arrows: double-labeled, displaced amacrine cells (F). Magnification, (A–C) x50; (D–F) x100.

Photoreceptor Deficits in Retinas Misexpressing cNSCL2
To study the role of cNSCL2 in retinal development, its coding sequence was inserted into RCAS to achieve cNSCL2 misexpression in retinal cells under viral control. A retroviral suspension of RCAS-cNSCL2, or RCAS-GFP as a control, was microinjected into the subretinal space and the neural tube of chick embryos at E2. Because the retrovirus is replication competent, its administration into embryos at an early developmental stage resulted in widespread viral infection both within and outside the central nervous system.³⁰ Grossly, embryos infected with RCAS-cNSCL2 developed normally, and their eye sizes appeared indistinguishable from those of the control. This is in contrast to the misexpression of cNSCL1. RCAS-cNSCL1 embryos die midway through gestation and exhibit severe developmental abnormalities including small eyes, an enlarged and exposed tectum, and retarded limb.^{25 26 30}

Histologic analyses of RCAS-cNSCL2 retinas at E12 and beyond, however, revealed severe photoreceptor deficits and gross alterations of the structure of the outer nuclear layer (ONL). In normal chick retina, the ONL is a continuous structure consisting of both cones and rods, with the majority being cones that express visinin. In the experimental retina, however, the ONL became fragmented with photoreceptorless regions interrupting the normal-looking patches (Figs. 3A 3B) . Staining a partially infected retina with a specific antibody against viral protein p27 showed that the ONL was specifically abnormal in those regions where the retrovirus was present (Fig. 3C , dark boxes), whereas the ONL in the adjacent, uninfected regions appeared normal (Fig. 3C , light boxes). Thus, the photoreceptor paucity was directly related to cNSCL2 misexpression in the region.

View larger version (143K): [in this window] [in a new window]   Figure 3. Photoreceptor deficits in E12 retinas misexpressing cNSCL2. (A) Distribution of cone photoreceptor cells revealed with in situ hybridization using digoxigenin-labeled antisense RNA probes against visinin. Visinin+ cells were not continuous, but interrupted by photoreceptorless regions (arrows). No gross disruptions of the GCL and INL were apparent. White asterisk: RPE. (B, C) Immunostaining with a specific antibody against p27, a viral protein. Thorough infection resulted in interruption of the ONL (arrows in B), and partial infection produced a milder distortion of the ONL (C). Distortion of the ONL was apparent only in infected regions (dark boxes). In the adjacent, uninfected regions, the ONL appeared normal (light boxes). Magnifications, x50.

View larger version (117K): [in this window] [in a new window]   Figure 4. Presence of bipolar cells in the photoreceptorless regions of the ONL in E12 retinas misexpressing cNSCL2. Bipolar cells were identified by in situ hybridization with an antisense RNA probe against chx10. (A) A control retina infected with RCAS-GFP. (B) A retina infected with RCAS-cNSCL2. Magnifications, x50.

View larger version (80K): [in this window] [in a new window]   Figure 5. Various types of nonphotoreceptor neurons in an E12 retina and BrdU+ cells in an E9 retina partially infected with RCAS-cNSCL2. (A) A single layer of horizontal cells (4F2+/LIM+, in red) both in infected (blue) and uninfected regions. (B) Amacrine cells, marked by AP2 immunoreactivity (red), in infected (blue) and uninfected regions. (C) Ganglion cells, identified with Brn3a expression (red or dark), in infected and uninfected regions. (D) BrdU+ cells (red) in infected and uninfected regions in an E9 retina. Magnifications, x50.

View larger version (56K): [in this window] [in a new window]   Figure 6. Photoreceptor degeneration in retinas misexpressing cNSCL2. (A) Anti-P27 immunohistochemistry of an E9 retina infected with RCAS-cNSCL2. The ONL appeared normal. (B, C) TUNEL+ cells in E11 retinas infected with RCAS-GFP (B) or RCAS-cNSCL2 (C). TUNEL+ cells were absent in the ONL of the control (B) but were present in experimental retina (C, arrows). (D) Quantification of TUNEL+ cells in the ONL of RCAS-cNSCL2, or RCAS-GFP, retinas at different developmental stages. Shown are means ± SD of TUNEL+ cells per view area under a x20 objective. Each data point represents three retinas with more than 20 view areas scored in each retina.

Glial Cell Atrophy in cNSCL2 Retinas
Müller cells are the major glial component of the retina and are the last group of cells born during retinal neurogenesis. In the chick retina, glial genesis takes place on E8 in the central retina. Müller cells extend across nearly the entire radial length of the retina. Their somas reside in the middle of the INL and their processes reach and form the external and inner limiting membranes. Developing Müller glia can be identified by the expression of vimentin,³⁵ cNSCL1,²⁶ and glutamine synthetase.³⁶ In retinas partially infected with RCAS-cNSCL2, cNSCL1 expression was detected in uninfected regions, but not in infected regions (Figs. 7A 7B) . Double labeling showed that vimentin⁺ cells were scarce in regions where no cNSCL1 expression was detected (Fig. 7B) . Reduction in vimentin⁺ cell number was apparent only in regions infected with RCAS-cNSCL2 (Fig. 7C) . Expression of glutamine synthetase was also specifically absent in regions infected with RCAS-cNSCL2 (data not shown).

View larger version (141K): [in this window] [in a new window]   Figure 7. Reduction of Müller glia cell number in retinas infected with RCAS-cNSCL2. (A) Double labeling with antisense RNA probes against cNSCL1 (purple) and anti-p27 antibody (red) in a partially infected E12 retina. In uninfected regions, cNSCL1 mRNA was present in Müller glia located in the middle of the INL. In the infected region, however, no cNSCL1+ cells were present. (B) Double labeling with antisense RNA probes against cNSCL1 (purple) and anti-vimentin antibody (red/brown) in a partially infected E12 retina. When cNSCL1+ cells were absent, the number of vimentin+ cells was conspicuously reduced (red box). (C) Double-labeling for vimentin (red/brown) and p27 (blue) in a partially infected E12 retina. Note that the number of vimentin+ cells was specifically decreased in regions infected with RACS-cNSCL2. (D) Double-labeling for vimentin (red/brown) and p27 (blue) in a thoroughly infected E12 retina, showing that by E12 vimentin+ cells was essentially gone, except in a few places (arrows). (E) Double-labeling for vimentin (red) and p27 (blue) of an E9 retina. At this early stage of development, vimentin+ cells were abundantly present in the peripheral retina (left). Note, however, that their number decreased toward the central retina (right), the development of which was more advanced than the peripheral retina. Magnifications, (A–C) x50; (D) x25; (E) x50.

	Discussion

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Two members of the cNSCL subfamily of bHLH genes are expressed in the chick retina but have very different expression profiles. cNSCL1 is expressed first transiently in young ganglion cells and then persistently in glial cells.²⁶ However, cNSCL2 mRNA was detected in amacrine and horizontal cells in both developing and adult retina. The distinct expression patterns of the two related genes imply that they play different roles in retinal development, and illustrate that our antisense RNA probes were specific to each gene.

Retroviral-driven misexpression of cNSCL1 is lethal to the embryo and causes gross developmental abnormalities. In contrast, misexpression of cNSCL2 in chick embryos was tolerated, and the gross appearance of experimental embryos was indistinguishable from the control. Misexpression of cNSCL1 in the developing retina results in small eye, whereas reduction of eye size was not observed with cNSCL2 misexpression. At the microscopic level, cNSCL1 misexpression results in INL disorganization,²⁶ but cNSCL2 misexpression caused ONL disintegration. Apparently, cNSCL1 and cNSCL2 have dissimilar functions in retinal development, even though they belong to the same subfamily and their bHLH domains are 95% identical.

Some proneural genes are involved in neural cell fate specification, but cNSCL2 is unlikely to play a key role in the specification of amacrine and horizontal cell fates. At least it is not sufficient to instruct a progenitor cell to adopt such cell fates. Misexpression of cNSCL2 in the developing chick retina did not increase the number of AP2⁺ cells (amacrine cells) or horizontal cells (AP2⁺ or LIM⁺). The persistent expression of cNSCL2 in adult retina suggests that it may regulate the expression of genes that are involved in the maintenance or function of horizontal and amacrine cells.

The distortion of the ONL in retinas misexpressing cNSCL2 was marked by the absence of photoreceptor cells. The TUNEL assay revealed that young photoreceptor cells underwent apoptosis. Before E10, the number of TUNEL⁺ cells remained low, and the ONL appeared normal. Thus, misexpression of cNSCL2 in the developing retina interfered with the survival of photoreceptor cells and caused them to degenerate but had no effect on photoreceptor genesis.

Analyses with markers that identify different types of retinal neurons showed that there were no apparent deficits in the numbers of horizontal, bipolar, amacrine, and ganglion cells in retinas misexpressing cNSCL2. However, the three Müller glial markers, vimentin, cNSCL1, and glutamine synthetase, were either absent or were present in an extremely small number of cells. Vimentin⁺ cells were present in abundance at early developmental stages, but their number decreased as development proceeded, indicating that glial cells were produced under cNSCL2 misexpression. Examining cell proliferation with BrdU incorporation showed no difference in the number of BrdU⁺ cells between the experimental retina and the control. Taken together, these observations suggest that cNSCL2 misexpression causes young glial cells to disappear or to degenerate. However, it was difficult to pinpoint whether glial cells underwent apoptosis. Müller glia account for only 1 of the 14 tiers of the INL cells in the chick retina, and some INL cells undergo programmed cell death during normal development.

A decrease in glial cell number was observed before the reduction in photoreceptor cell number was noticeable. This raises the question of whether photoreceptor degeneration was secondary to glial degeneration. The idea that glia provides nourishment to photoreceptor cells has been in the literature for a long time, but solid data supporting the notion are scarce. Recent studies show that glial cells may mediate bFGF’s effect on promoting photoreceptor cell survival.³⁷ However, it is also possible that degeneration of photoreceptor cells and glial cells are independent events from cNSCL2 misexpression. Although proneural bHLH genes are known to block gliogenesis, the dramatic reduction in glial cell number in E12 retinas was unlikely due to cNSCL2 blocking gliogenesis, because a large number of glial cells were detected at earlier stages.

It is unclear by what mechanisms cNSCL2 causes glial and photoreceptor cells to degenerate. Photoreceptor and glial cells normally do not express cNSCL2. One scenario is that ectopic cNSCL2 expression in these cells interferes with or upsets their normal differentiation programs and thus causes cell death. If this incompatibility exists, then it becomes plausible that cNSCL2 plays a role in safeguarding the development of amacrine and horizontal cells against inappropriate gene expression programs, such as those associated with glial or photoreceptor differentiation. It is possible that the development of a structure as complex as the retina may involve a selective mechanism by which cells that mistakenly express genes of another cell type would be eliminated. Another scenario is that the photoreceptor and glial atrophies were caused by microenvironment changes, such as the presence of high levels of metabolites toxic to these cells. Microenvironment changes could be caused by enhanced expression of cNSCL2 in horizontal cells and amacrine cells or misexpression of cNSCL2 in bipolar or ganglion cells. In preliminary experiments, E8 retinal cells were dissociated and cultured at low density for 3 to 4 days for scoring the number of photoreceptor cells, or more than 14 days for examining glial cell growth. Under these conditions, the number of visinin⁺ cells and the number of glial cells showed no differences between the experimental retina and the control retina. These would argue that the microenvironment played a role in causing the retinal degeneration in the experimental retinas. Keep in mind, however, that cellular properties may change under in vitro conditions. Müller glia are particularly known to change their morphologic and biochemical properties in vitro. Under our culture conditions, they readily re-entered the cell cycle. Therefore, the absence of glial and photoreceptor cell death in vitro does not necessarily show that their atrophiy in the retina is caused by the abnormal microenvironment in retinas misexpressing cNSCL2. Further studies using specific promoters to drive cNSCL2 misexpression in a cell type–specific manner may shed light on whether the loss of photoreceptors and glia is due to cNSCL2 misexpression in these cells or in other cells.

It is always of concern whether phenotypes observed in gain-of-function studies result from the presence of the exogenous protein itself or an alteration in the level of an endogenous protein. Because bHLH protein can form homo- or heterodimers, an exogenous bHLH protein could cause an imbalance of the endogenous bHLH proteins. Such an imbalance may produce nonspecific phenotypes. We have used RCAS to misexpress a number of bHLH genes including neuroD,¹⁴ cNSCL1,^{25 26} and neurogenin2 (Yan and Wang, unpublished results, 2000), in addition to cNSCL2. All these genes are homologous to the Drosophila proneural genes. Each gene misexpression manifests distinct phenotypes, not only at the gross level, but also at the microscopic level. Therefore, it is most likely that the phenotypes described in this report were specific to cNSCL2.

Our studies showed that cNSCL2 was cell type–specific in the retina and its misexpression caused severe photoreceptor degeneration and Müller glia atrophy. Thus, expression of cNSCL2 must be tightly regulated in the retina. If misexpression of a retinal gene causes retinal degeneration, it becomes important to regulate tightly and precisely the expression of genes that are artificially delivered into a tissue through, for example, gene therapies.

	Footnotes

 
Supported by National Eye Institute Grant EY11640; unrestricted grants to the Department of Ophthalmology, University of Alabama at Birmingham from Research to Prevent Blindness and the Alabama Eye Institute.

Submitted for publication March 27, 2001; revised July 12, 2001; accepted August 16, 2001.

Commercial relationships policy: N.

The publication costs of this article were defrayed in part by page charge payment. This article must therefore be marked "advertisement" in accordance with 18 U.S.C. 1734 solely to indicate this fact.

Corresponding author: Shu-Zhen Wang, 700 South 18th Street, Birmingham, AL 35294-0009. szwang{at}vision.vsrc.uab.edu

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