Donald S. Sakaguchi

Stem cells and retinal repair.

Retinal stem cells (RSCs) are multipotent central nervous system (CNS) precursors that give rise to the retina during the course of development. RSCs are present in the embryonic eyecup of all vertebrate species and remain active in lower vertebrates throughout life. Mammals, however, exhibit little RSC activity in adulthood and thus little capacity for retinal growth or regeneration. Because CNS precursors can now be isolated from immature and mature mammals and expanded ex vivo, it is possible to study these cells in culture as well as following transplantation to the diseased retina. Such experiments have revealed a wealth of unanticipated findings, both in terms of the instructive cues present in the mature mammalian retina as well as the ability of grafted CNS precursors to respond to them. This review examines current knowledge regarding RSCs, together with other CNS precursors, from the perspective of investigators who wish to isolate, propagate, genetically modify, and transplant these cells as a regenerative strategy with application to retinal disease.

Basic Fibroblast Growth Factor (FGF-2) Induced Transdifferentiation of Retinal Pigment Epithelium: Generation of Retinal Neurons and Glia

In the present study we report that basic fibroblast growth factor (bFGF, FGF‐2) promotes the transdifferentiation of Xenopus laevis larval retinal pigment epithelium (RPE) into neural retina. Using specific antibodies we have examined the cellular composition of the regenerated retinal tissue. Our results show that, in addition to retinal neurons and photoreceptors, glial cells were also regenerated from the transdifferentiated RPE. These results were specific to FGF‐2, since other factors that were tested, including acidic FGF (aFGF, FGF‐1), epidermal growth factor (EGF), laminin, ECL, and Matrigel, exhibited no activity in inducing retinal regeneration. These results are the first in amphibians demonstrating the functional role of FGF‐2 in inducing RPE transdifferentiation. Transplantation studies were carried out to investigate retinal regeneration from the RPE in an in vivo environment. Sheets of RPE implanted into the lens‐less eyes of larval hosts transformed into neurons and glial cells only when under the influence of host retinal factors. In contrast, no retinal transdifferentiation occurred if the RPE was implanted into the enucleated orbit. Taken together, these results show that the amphibian RPE is capable of transdifferentiation into neuronal and glial cell‐phenotypes and implicate FGF‐2 as an important factor in inducing retinal regeneration in vitro. Dev. Dyn. 209:387–398, 1997.

Transplantation of BDNF-Secreting Mesenchymal Stem Cells Provides Neuroprotection in Chronically Hypertensive Rat Eyes

PURPOSE To evaluate the ability of mesenchymal stem cells (MSCs) engineered to produce and secrete brain-derived neurotrophic factor (BDNF) to protect retinal function and structure after intravitreal transplantation in a rat model of chronic ocular hypertension (COH). METHODS COH was induced by laser cauterization of trabecular meshwork and episcleral veins in rat eyes. COH eyes received an intravitreal transplant of MSCs engineered to express BDNF and green fluorescent protein (BDNF-MSCs) or just GFP (GFP-MSCs). Computerized pupillometry and electroretinography (ERG) were performed to assess optic nerve and retinal function. Quantification of optic nerve damage was performed by counting retinal ganglion cells (RGCs) and evaluating optic nerve cross-sections. RESULTS After transplantation into COH eyes, BDNF-MSCs preserved significantly more retina and optic nerve function than GFP-MSC-treated eyes when pupil light reflex (PLR) and ERG function were evaluated. PLR analysis showed significantly better function (P = 0.03) in BDNF-MSC-treated eyes (operated/control ratio = 63.00% ± 11.39%) than GFP-MSC-treated eyes (operated/control ratio = 31.81% ± 9.63%) at 42 days after surgery. The BDNF-MSC-transplanted eyes also displayed a greater level of RGC preservation than eyes that received the GFP-MSCs only (RGC cell counts: BDNF-MSC-treated COH eyes, 112.2 ± 19.39 cells/section; GFP-MSC-treated COH eyes, 52.21 ± 11.54 cells/section; P = 0.01). CONCLUSIONS The authors have demonstrated that lentiviral-transduced BDNF-producing MSCs can survive in eyes with chronic hypertension and can provide retina and optic nerve functional and structural protection. Transplantation of BDNF-producing stem cells may be a viable treatment strategy for glaucoma.

Differentiation and Morphological Integration of Neural Progenitor Cells Transplanted into the Developing Mammalian Eye

Abstract: Transplantation of neural stem/progenitor cells has been proposed as a novel approach for the replacement and repair of damaged CNS tissues. We have evaluated the influence of the host cellular microenvironment upon the survival, differentiation, and integration of neural progenitor cells transplanted into the CNS. Using this approach, we have investigated the fate of neural progenitor cells in vivo following transplantation into the developing mammalian eye. Murine brain progenitor cells (mBPCs) isolated from neonatal mice expressing the green fluorescent protein (GFP) transgene were transplanted into the eyes of Brazilian opossums (Monodelphis domestica). Monodelphis pups are born in an extremely immature, fetal‐like state. The eyes of neonatal pups provide a fetal‐like environment in which to study cellular interactions between host tissues and transplanted neural progenitor cells. mBPCs were transplanted by intraocular injection in hosts ranging in age from 5 days postnatal to adult. The transplanted cells were easily identified because of their GFP fluorescence. Extensive survival, differentiation, and morphological integration of mBPCs within the host tissue was observed. We found that the younger retinas provided a more supportive environment for the morphological integration of the transplanted mBPCs. Cells with morphologies characteristic of specific retinal cell types were observed. Moreover, some transplanted mBPCs were labeled with antibodies characteristic of specific neural/retinal phenotypes. These results suggest that the host environment strongly influences progenitor cell differentiation and that transplantation of neural progenitor cells may be a useful approach aimed at treating degeneration and pathology of the CNS.

Transplantation of Neural Progenitor Cells into the Developing Retina of the Brazilian Opossum: An in vivo System for Studying Stem/Progenitor Cell Plasticity

In developing cell transplant strategies to repair the diseased or injured retina is essential to consider host-graft interactions and how they may influence the outcome of the transplants. In the present study we evaluated the influence of the host microenvironment upon neural progenitor cells (NPCs) transplanted into the developing and mature retina of the Brazilian opossum, Monodelphis domestica. Monodelphis pups are born in an extremely immature state and the neonatal pups provide a fetal-like environment in which to study the interactions between host tissues and transplanted NPCs. Three different populations of GFP-expressing NPCs were transplanted by intraocular injection in hosts ranging in age from 5 days postnatal to adult. Extensive survival, differentiation and morphological integration of NPCs were observed within the developing retina. These results suggest that the age of the host environment can strongly influence NPC differentiation and integration.

Astrocyte-derived interleukin-6 promotes specific neuronal differentiation of neural progenitor cells from adult hippocampus

The purpose of this study was to investigate the ability of astrocyte‐derived factors to influence neural progenitor cell differentiation. We previously demonstrated that rat adult hippocampal progenitor cells (AHPCs) immunoreactive for the neuronal marker class III β‐tubulin (TUJ1) were significantly increased in the presence of astrocyte‐derived soluble factors under noncontact coculture conditions. Using whole‐cell patch‐clamp analysis, we observed that the cocultured AHPCs displayed two prominent voltage‐gated conductances, tetraethyl ammonium (TEA)‐sensitive outward currents and fast transient inward currents. The outward and inward current densities of the cocultured AHPCs were approximately 2.5‐fold and 1.7‐fold greater, respectively, than those of cells cultured alone. These results suggest that astrocyte‐derived soluble factors induce neuronal commitment of AHPCs. To investigate further the activity of a candidate neurogenic factor on AHPC differentiation, we cultured AHPCs in the presence or absence of purified rat recombinant interleukin‐6 (IL‐6). We also confirmed that the astrocytes used in this study produced IL‐6 by ELISA and RT‐qPCR. When AHPCs were cultured with IL‐6 for 6–7 days, the TUJ1‐immunoreactive AHPCs and the average length of TUJ1‐immunoreactive neurites were significantly increased compared with the cells cultured without IL‐6. Moreover, IL‐6 increased the inward current density to an extent comparable to that of coculture with astrocytes, with no significant differences in theoutward current density, apparent resting potential, or cell capacitance. These results suggest that astrocyte‐derived IL‐6 may facilitate AHPC neuronal differentiation. Our findings have important implications for understanding injury‐induced neurogenesis and developing cell‐based therapeutic strategies using neural progenitors.

Brain-derived neurotrophic factor released from engineered mesenchymal stem cells attenuates glutamate- and hydrogen peroxide-mediated death of staurosporine differentiated RGC-5 cells

The purpose of this study was to determine the viability of cell-based delivery of brain-derived neurotrophic factor (BDNF) from genetically modified mesenchymal stem cells (MSCs) for neuroprotection of RGC-5 cells. RGC-5 cells were differentiated with the protein kinase inhibitor staurosporine (SS) and exposed to the cellular stressors glutamate or H2O2. As a neuroprotective strategy, these cells were then co-cultured across a membrane insert with mesenchymal stem cells (MSCs) engineered with a lentiviral vector for production of BDNF (BDNF-MSCs). As a positive control, recombinant human BDNF (rhBDNF) was added to stressed RGC-5 cells. After SS-differentiation RGC-5s developed neuronal-like morphologies, and a significant increase in the proportion of RGC-5s immunoreactive for TuJ-1 and Brn3a was observed. Differentiated RGC-5s also had prominent TrkB staining, demonstrating expression of the high-affinity BDNF receptor. Treatment of SS-differentiated RGC-5s with glutamate or H2O2, produced significant cell death (56.0 +/- 7.02 and 48.90 +/- 4.58% of control cells, respectively) compared to carrier-solution treated cells. BDNF-delivery from MSCs preserved more RGC-5 cells after treatment with glutamate (80.0 +/- 5.40% cells remaining) than control GFP expressing MSCs (GFP-MSCs, 57.29 +/- 1.89%, p < 0.01). BDNF-MSCs also protected more RGC-5s after treatment with H2O2 (65.6 +/- 3.47%) than GFP-MSCs (46.0 +/- 4.20%, p < 0.01). We have shown survival of differentiated RGC-5s is reduced by the cellular stressors glutamate and H2O2. Additionally, our results demonstrate that genetically modified BDNF-producing MSCs can enhance survival of stressed RGC-5 cells and therefore, may be effective vehicles to deliver BDNF to retinal ganglion cells affected by disease.

Temporary elevation of the intraocular pressure by cauterization of vortex and episcleral veins in rats causes functional deficits in the retina and optic nerve

PURPOSE To evaluate visual function in rats with chronic elevation of intraocular pressure (IOP). METHODS Chronic ocular hypertension was induced in the left eye of 14 adult Brown Norway rats by cauterizing 3 vortex veins and 2 major episcleral veins; the right eye served as a non-operated control. A control group (n=5) was sham operated on the left eye. Prior to surgery, the IOP was measured with a Tonopen, the pupil light reflex (PLR) evaluated with a custom-made computerized pupillometer and electroretinograms (ERGs) were recorded simultaneously from both eyes post surgically: IOP was measured on weeks 1, 3, 5 and 8 post-operatively, pupil light reflexes on weeks 1, 4 and 8 post-operatively, and ERGs on weeks 4 and 8 post-operatively. Sixty five days postoperatively, rats were euthanized and optic nerves and eye globes were prepared for histological analysis. RESULTS Seven days after surgery 5/14 rats developed significant elevation of the IOP in operated eyes (control eyes: 25.1+/-0.5mmHg; operated eyes: 34.1+/-0.6mmHg; mean+/-SEM; p=0.0004; Paired t-test). Elevation of the IOP was sustained at 3 (p=0.002) and 5 (p=0.007) weeks postoperatively. However, IOP values did not significantly differ between control and operated eyes 8 weeks postoperatively (p=0.192, Paired t-test). Sham operated animals showed no elevation of the IOP 7 days postoperatively. When the ratio between consensual and direct PLR (PLR(ratio)=consensual/direct PLR; pupil of unoperated eye recorded) was examined in rats which developed elevation of the IOP, preoperative values were 92.2+/-4% (mean+/-SEM), 1 week postoperatively 65+/-4% (significantly different from preoperative values, p<0.05 Repeated Measures ANOVA with Dunnetts Multiple Comparison test, n=5), 4 weeks postoperatively 60.6+/-3.2% (p<0.01, n=5). By 8 weeks postoperatively, pupil responses had essentially recovered 75.4+/-6.9% (p>0.05, n=5). Rats whose IOP values did not rise after surgery and sham operated rats did not develop pupil deficits 4 weeks postoperatively. Rats with elevated IOP displayed a significant decrease in ERG amplitudes in operated eyes at 4 weeks (a-wave(operated)/a-wave(control) (a-wave ratio)=42+/-14% (mean+/-SEM); b-wave(operated)/b-wave(control) (b-wave ratio)=43+/-16%) but not at 8 weeks postoperatively (a-wave ratio=88+/-8.4%; b-wave ratio=82.9+/-9%). Sham operated and rats whose IOP values remained non-elevated after surgery did not develop ERG deficits 4 weeks after surgery. Histological analysis did not reveal any damage in the eyes of animals with elevated intraocular ocular pressure with the exception of one rat, which still had ERG and pupil deficits at the end of experiment. CONCLUSIONS Development of ERG and PLR deficits are proportional to the elevation of the IOP in the rat model of chronic ocular hypertension. Functional monitoring of the ERG and PLR are useful objective techniques for the detection of retina and optic nerve deficits.

The equilibrium detecting system of the cricket: Physiology and morphology of an identified interneuron

Summary1.The clavate receptor-to-interneuron system of the cricket,Acheta domesticus, was investigated physiologically and morphologically.2.Intracellular recordings made during controlled displacements of the crickets cerci allowed the identification of a pair of position sensitive interneurons (PSIs). Changes in the position of the cerci resulted in modulation of the membrane potential and altered the action potential frequency recorded from the PSIs (Fig. 2).3.Subsequent dye injection demonstrated that the PSIs were a bilaterally symmetric pair of interneurons that received their primary afferent input from club-shaped receptors, called clavate hairs (Fig. 1). The somata of the PSIs are located at the anterior edge of the terminal abdominal ganglion (Fig. 1 C), and the axons are located dorsolaterally in the connectives (Fig. 1 E).4.Receptive fields for the interneurons were determined by recording the extracellular neural activity from the ventral nerve cord while simultaneously displacing the animal in various orientations. The PSI receptive fields were essentially mirror images, each predominantly occupying one quadrant when plotted in polar coordinates. The receptive fields for the left and right PSIs occupy the left posterior and right posterior quadrants respectively (Fig. 5).5.Selective deletion of clavate hairs revealed that receptors located in the proximal, medial region of the clavate array provided the strongest input to the ipsilateral interneuron (Fig. 6).6.Clavate sensory neuron terminal arborizations were stained in order to examine their relationship with the dendrites of the PSIs (Fig. 7).

Growth cone interactions with a glial cell line from embryonic Xenopus retina

We have isolated a nonneuronal cell line from Xenopus retinal neuroepithelium (XR1 cell line). On the basis of immunocytochemical characterization using monoclonal antibodies generated in our laboratory as well as several other glial-specific antibodies, we have established that the XR1 cells are derived from embryonic astroglia. A monolayer of XR1 cells serves as an excellent substrate upon which embryonic retinal explants attach and elaborate neurites. This neurite outgrowth promoting activity appears not to be secreted into the medium, as medium conditioned by XR1 cells is ineffective in promoting outgrowth. Cell-free substrates were prepared to examine whether outgrowth promoting activity is also associated with the XR1 extracellular matrix (ECM). Substrates derived from XR1 cells grown on collagen are still capable of promoting outgrowth following osmotic shock and chemical extraction. This activity does not appear to be associated with laminin or fibronectin. Scanning electron microscopy was used to examine growth cones of retinal axons on XR1 cells and other substrates that supported neurite outgrowth. Growth cones and neurites growing on a monolayer of XR1 cells, or on collagen conditioned by XR1 cells, closely resemble the growth cones of retinal ganglion cells in vivo. A polyclonal antiserum (NOB1) generated against XR1 cells effectively and specifically inhibits neurite outgrowth on XR1-conditioned collagen. We therefore propose that neurite outgrowth promoting factors produced by these cells are associated with the extracellular matrix and may be glial specific.