Abstract
Retinitis pigmentosa (RP) is a group of blinding disorders caused by diverse mutations, including in rhodopsin (RHO). Effective therapies have yet to be discovered. The I307N Rho mouse is a light-inducible model of autosomal dominant RP. Our purpose was to describe the glial response in this mouse model to educate future experimentation. I307N Rho mice were exposed to 20,000 lx of light for thirty minutes to induce retinal degeneration. Immunofluorescence staining of cross-sections and flat-mounts was performed to visualize the response of microglia and Müller glia. Histology was correlated with spectral-domain optical coherence tomography imaging (SD-OCT). Microglia dendrites extended between photoreceptors within two hours of induction, withdrew their dendrites between twelve hours and one day, appeared ameboid by three days, and assumed a ramified morphology by one month. Glial activation was more robust in the inferior retina and modulated across the boundary of light damage. SD-OCT hyper-reflectivity overlapped with activated microglia. Finally, microglia transiently adhered to the RPE before which RPE cells appeared dysmorphic. Our data demonstrate the spatial and temporal pattern of glial activation in the I307N Rho mouse, and correlate these patterns with SD-OCT images, assisting in interpretation of SD-OCT images in preclinical models and in human RP.
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Discover the latest articles, news and stories from top researchers in related subjects.Introduction
Retinitis pigmentosa (RP) is a group of monogenic blinding disorders characterized by a primary phase of rod photoreceptor apoptosis followed by cone photoreceptor death. The clinical effects of these mutations and the resulting pattern of photoreceptor loss are progressive, concentric loss of peripheral vision, and night vision, with complete blindness in advanced disease1. Mutations in rhodopsin (RHO) represent approximately twelve-percent of all RP cases and are usually inherited in an autosomal dominant pattern2. Over 200 mutations in RHO have been described to date3. RP remains uncurable and one barrier to the generation of therapeutic interventions is the paucity of animal models for preclinical efficacy studies since a variety of mechanisms lead to the diseased phenotype4,5.
The I307N Rho mouse model of light-induced adRP recapitulates some crucial aspects of patients with the B1 phenotype, including sectoral and variably penetrant retinal degeneration6,7,8,9. These characteristics lend to the use of the I307N Rho mouse in preclinical efficacy studies or mechanistic studies. Furthermore, the light-inducible and tunable nature of retinal degeneration in the I307N Rho mouse creates an opportunity for controlled experimentation when compared to other mouse models of RP that experience early retinal degeneration that may overlap with the final stages of retinal development in the postnatal period7,10.
The generation and characterization of the I307N Rho mouse model was conducted over a decade ago by Budzynski et al. and has gained popularity among research groups in recent years6,7,8,10,11. Gargini et al. were the first to report activation of microglia and Müller glia at an early time point following illumination of the I307N Rho mouse and suggested that morphologically distinct cells exist in the area of injury when compared to nearby, relatively unaffected retina. They proposed that the model could be an excellent resource for studying cone death, retinal inflammation, and inner retinal remodeling8,10. We recently characterized the time-course of light-induced retinal degeneration in this model with spectral-domain optical coherence tomography (SD-OCT). We demonstrated that a hyper-reflective signal and retinal swelling were evident in the acute period following light challenge, which was followed by near-complete loss of the outer nuclear layer (ONL) within a week. We argued that these SD-OCT findings could be utilized as endpoints to produce an optimized preclinical efficacy study7. Recently, Zhang et al. demonstrated that whole-body exercise in the I307N Rho mouse mitigated both retinal inflammation, characterized by reduced microglia adherence to the RPE, and visual decline11.
A large body of literature suggests that the balance of microglia and Müller glia activity and resultant inflammatory signaling during retinal degeneration helps determine the extent of photoreceptor death or survival12,13. Many unique therapeutic approaches that involve modulating the inflammatory response have been studied in the context of retinal degeneration in RP14,15,16. Despite clear evidence for microglial activation in the I307N Rho mice with the work of Gargini et al. and Zhang et al.8,11, the temporal and spatial pattern of activation of microglia and Müller glia in the I307N Rho mouse remains unexplored. Without understanding the natural history of glial activation in the I307N Rho mouse, our ability to utilize this model for mechanistic studies or preclinical testing of anti-inflammatory interventions remains suboptimal.
To address this gap in knowledge, we utilized histologic techniques to demonstrate that microglia undergo rapid migration into the outer retina, expansion in number after CD45-positive monocytic cell infiltration, and morphological activation to an ameboid phenotype within three days of light exposure, before returning to a ramified configuration after ONL clearance. Müller glia exhibited a dramatically increased expression of glial fibrillary-acidic protein (GFAP) during retinal degeneration. Because we employed a method of overhead illumination designed to recapitulate the sector RP observed in patients with class B1 mutations17, these glial responses were sectoral, as more profound reactivity occurred in the inferior, damaged retina when compared to the relatively preserved superior retina. Interestingly, the hyper-reflective signal on SD-OCT demarcated morphologically activated microglia from ramified microglia on a co-isolated retinal flat-mount. During this analysis, we were surprised to discover rapid shifts in total retinal thickness (TRT), as the retina thinned during the first two hours after exposure to light then swelled beginning at four hours. Finally, migration and adherence of microglia to the RPE was a relatively late and transient event that occurred approximately one to two weeks after light exposure. Together, these results should help future studies to designate optimal time points for analysis of retinal glial cells and correlating the glial response with SD-OCT findings in animal models of RP.
Results
Retinal glial cells respond to damage in a sectoral pattern within the first week after light damage
We previously showed that exposure of the awake I307N Rho mouse to overhead, bright white-light results in inferonasal retinal degeneration7. Our rationale for employing overhead lighting rather than diffuse lighting via mirrored cages, which has been used elsewhere6,8,10, was to recapitulate the sectoral retinal injury seen in class B1 RP patients9. Gargini et al. have demonstrated that microglia progressed to an ameboid phenotype by day two after light exposure and that their activation occurred with regional dependence8. We thus expanded their analysis to determine whether microglia and Müller glia would follow a sectoral pattern of activation at other time points. To this end, we prepared frozen paraformaldehyde (PFA)-fixed cross-sections of the retina from I307N Rho mice before and one day through one month after light exposure. These sections were prepared along the superior-inferior axis to capture areas in the inferior retina that likely received the brunt of light exposure. Sections were subsequently stained with an antibody against CD45 (Fig. 1a), a receptor protein tyrosine phosphatase expressed in all nucleated hematopoietic cells18, or against GFAP, an intermediate filament associated protein that is expressed with Müller cell reactivity and in astrocytes19 (Fig. 1b).
The total number of CD45-positive cells were counted in the major retinal lamina of either the inferior retina or the superior retina (Fig. 1c). Importantly, CD45 staining co-localized with the ionized calcium-binding adapter molecule 1, an accepted marker of microglia20 (see Supplementary Fig. 1a). We chose to utilize the CD45 marker since it yielded more consistent results. Microglia showed a sectoral pattern of activation, as two-way repeat-measures ANOVA demonstrated that retinal sector is a significant independent factor and the total number of microglia was significantly higher only in the inferior retina, but not superior retina, compared to baseline during post-hoc testing. Furthermore, there were dramatic shifts in microglia localization within the retina. With the majority of ONL already degenerated by day eight, the microglial response appeared to resolve towards the baseline distribution. Microglia did not migrate to the ONL or subretinal space (SRS) in wild-type littermates exposed to the same light damage protocol one day prior (see Supplementary Fig. 1b).
To quantify the differences in GFAP-positivity in the inferior versus superior retina, we measured the mean fluorescence intensity (MFI) of each image relative to baseline (Fig. 1d). The statistical peak of GFAP accumulation occurred in the inferior retina on days eight and fifteen after illumination. Furthermore, the independent variable of retinal sector showed significance in two-way repeat-measures ANOVA, again suggesting regional differences in glial activation. Wild-type animals exposed to the light damage protocol did not develop GFAP-positive Müller cell processes (see Supplementary Fig. 1b). These results indicate that retinal degeneration in the I307N Rho mice induced both sectoral and temporal activation of microglia and Müller glia.
Microglia undergo rapid and dramatic morphological changes and expand in number after monocyte infiltration
Next, we sought to improve our understanding of microglia in the acute phase after light challenge. I307N Rho mice were exposed to light and PFA-fixed retinal flat-mounts were prepared from early time points (e.g., within hours of the cessation of illumination) and up to one month thereafter. Flat-mounts were then stained with anti-CD45, anti-GFAP, anti-Iba1 and/or isolectin B4 (IB4) and CD45-positive cell counts were performed.
Microglia migrated from the inner retina (IPL and GCL), beginning as early as two hours after light exposure, followed by repopulation of the inner retina on day three (Fig. 2a,b). When microglia at the interface of the OPL and ONL were manually isolated for 3D-reconstructions, dendrites could be seen infiltrating the ONL as early as two hours and four hours (Fig. 2c); individual phagocytic events were also apparent at high magnification at these time points (see Supplementary Fig. 2a). Continued phagocytosis from twelve hours through one day (Fig. 2a, white arrows) coincided with retraction of microglia dendrites until a fulminant ameboid morphology was attained by day three, likely after profound phagocytosis (Fig. 2c). Indeed, at the day three time point, a large fraction of the nuclei appeared pyknotic (Supplementary Fig. 2a). As time extended from day eight through one month after light exposure, microglia returned to a ramified morphology (see Supplementary Fig. 2b). Again, retinal microglia in wild-type littermates that were exposed to the same light damage protocol did not show evidence of morphological change (see Supplementary Fig. 2c). Furthermore, prominent co-localization of Iba1 and CD45 signal was observed in samples belonging to I307N Rho mice, offering further evidence that the CD45 signal was derived from microglia or macrophage (see Supplementary Fig. 2d).
CD45-positive monocytic cells were visualized within the inner retina, particularly on day three (Fig. 2a, red arrows). Since monocyte-derived macrophage infiltrate the retina of other mouse models of retinal degeneration21,22,23,24, we counted CD45-positive monocytic cells (Fig. 3a). The highest mean infiltration of CD45-positive monocytic cells occurred on days one and three post-light exposure when compared to baseline, though the magnitude of infiltration was highly variable (Fig. 3b). Indeed, the extent of CD45-positive monocytic cell infiltration likely reflects the severity of retinal degeneration, which can range from mild to severe even with the same dose of light7. We also observed that the CD45-positive monocytic cells appeared to infiltrate via the optic nerve head (ONH) and major retinal veins and noted that those in the day three samples appeared to be more dispersed when compared to day one (Fig. 3a).
Microglia and Müller glia organize across the front of ONL hyper-reflectivity on SD-OCT
We previously reported that a hyper-reflective signal develops in the ONL of the I307N Rho mouse during retinal degeneration on day one7. Therefore, we sought to determine if the area within which the microglia manifest an activated morphology coincides with the area of hyper-reflectivity on SD-OCT at the four hour time point when we both expected a mature hyper-reflective signal and distinct microglia morphology. To this end, we utilized the retinal vasculature as a reference to produce an overlay of a CD45 and Isolectin-B4 (IB4) co-stained retinal flat-mount and its corresponding SD-OCT hyper-reflective signal (Fig. 4a). Strikingly, morphologically distinct populations of microglia were observed across the hyper-reflectivity front in the XY-dimension (Fig. 4b), which was also seen in the Z-dimension as the microglia within the focus of light injury projected into the photoreceptor layer, beyond the interface of the OPL and ONL (Fig. 4c). The co-existence of morphologically distinct populations of microglia across the boundary of degeneration was evident at every time point up to one month (see Supplementary Fig. 3). Furthermore, CD45 and GFAP signal co-modulated across the front of injury on day eight when we expected intense microglia and Müller activation, suggestive of a coordinated response (Fig. 4d).
Development of hyper-reflective SD-OCT signal, and transient retinal thinning, precedes the phase of profound microglial migration
The development of a hyper-reflective signal in SD-OCT scans is a common feature of models of light-induced retinal degeneration in the acute phase of injury26. Interestingly, we observed that the hyper-reflective signal was well-developed by two hours after illumination when only microglial dendrites, and not cell bodies, had permeated the ONL (Fig. 2c), suggesting that the hyper-reflectivity was not derived from microglia in the ONL by themselves. To better address the contribution of microglia, if any, to the hyper-reflective signal, we performed serial SD-OCT scans of I307N Rho mice early after light exposure (Fig. 5a).
Unexpectedly, we observed that the retinal thickness decreased in the inferonasal retina soon after the cessation of light exposure. We thus measured the total retinal thickness (TRT) in the superotemporal and inferonasal retina where mild to no degeneration and maximal degeneration were expected, respectively. A significant reduction in TRT of the inferonasal retina was detected from thirty minutes to two hours after illumination. In support of our previous work7, TRT then increased from four hours to one day after light challenge before decreasing up to day eight (Fig. 5b). We measured ONL hyper-reflectivity in parallel with ImageJ (https://imagej.nih.gov/ij/) for each SD-OCT scan. We found that reflectivity appears as early as fifteen minutes after light exposure but achieves a statistically significant value only at forty-five minutes post illumination before continuing to increase up to day one (Fig. 5c). Of note, we previously demonstrated that the day one time point achieved the maximal hyper-reflective signal during a three day time course7. The magnitude of changes to TRT (both shrinking and swelling) was qualitatively proportional to the development of hyper-reflective signal (see Supplementary Fig. 4a). Importantly, wild-type littermates subjected to the same protocol did not exhibit significant changes in TRT or hyper-reflectivity (see Supplementary Fig. 4b). Taken together, the radical shifts in TRT may be the main contributor to producing the hyper-reflective signal rather than the infiltration of microglia of the ONL.
Microglia migrate and transiently adhere to the RPE after light exposure
We previously showed that the RPE in the I307N Rho mouse remains morphologically and functionally intact fifteen days after light challenge despite rapid and robust degeneration of the ONL7. In their study, Zhang et al. employed microglia adherence to the RPE as an endpoint for microglial activation11. In addition, subretinal microglia may protect the RPE during light-induced retinal degeneration27. Given these observations, we sought to determine if microglial migration to the RPE is an early event and if microglia establish permanent residence at the RPE after light exposure.
We thus exposed I307N Rho mice to light and extracted their eyes on day three and up to one month after that for preparation of IF-staining of RPE flat-mounts with anti-CD45, anti-Iba1, or anti-zonula occludins-1 (ZO1), a junctional protein expressed at the periphery of RPE cells28 (Fig. 6). The day one time point was excluded since significant amounts of degenerated retina co-segregated with RPE during dissection. We observed that microglia established transient and late residence on the RPE, particularly on day eight (Fig. 6a–e). Microglial adherence to RPE also occurred in a sectoral pattern with an inferonasal bias (Fig. 6f). The co-localization of CD45 and Iba1 signal on RPE flat-mounts again demonstrated that these cells were likely microglia or macrophage (see Supplementary Fig. 5a). The RPE appeared grossly dysmorphic on day three after light exposure with both enlarged, irregular cells and small cells. Interestingly, dysmorphia existed predominantly along the edge of light damage (see Supplementary Fig. 5b–d). By day eight and afterward, the RPE resumed a more normal cobblestone appearance with isolated areas of irregular cells. These observations suggested that RPE partially recover histologically after an initial insult.
Discussion
Our goal in utilizing the I307N Rho mouse has been to recapitulate the B1 phenotype of human adRP, which is characterized by the coexistence of areas of intense retinal degeneration with areas of healthy retina. Since many humans with the B1 phenotype experience more severe disease in the inferior and nasal retina, it has been proposed that asymmetric illumination from above (e.g. sunlight, room lighting) yields this sectoral pattern9,17. We previously demonstrated that exposure of the I307N Rho mouse to a bright overhead light induces retinal swelling, outer retina hyper-reflectivity, and eventual retinal thinning in SD-OCT scans with an inferonasal bias7. Our analysis here suggests that the inferonasal patterning is preserved at the histological level as a more profound increase in microglia and Müller glia reactivity occurred in the inferior retina. Moreover, the inferonasal hyper-reflectivity coincided with the region of the retina that contained morphologically active microglia. Our time course analysis further demonstrated the major events and timing involved in the response of microglia after light treatment, which can be correlated with the phases of retinal shrinkage, retinal swelling, and ONL loss on SD-OCT (Fig. 7).
Other research groups have induced the I307N Rho mouse with short durations of relatively low intensity, but diffuse, lighting in mirrored cages6,8,10. In our previous study, we found that longer durations and higher intensities were required to produce retinal degeneration when using overhead light7. The light damage protocol employed in the present study (30’ of 20,000 lx of light) was selected because it generated severe ONL loss, similar to that observed in the studies performed by Budzynski et al. and Gargini et al.6, 8. Given this, we expect that the results presented here regarding glial behavior in the I307N Rho mouse, specifically within the focus of light-induced retinal generation, are generalizable to other light damage protocols that are titrated to severe ONL loss. Indeed, microglia also achieved a fulminant ameboid morphology in the study by Gargini et al.8 However, since the position of the light source likely affects the area of the retina receiving illumination, differences in the spatial distribution of glial activation should be expected. To this point, Zhang et al. reported more TUNEL-positive photoreceptor nuclei in the superior retina after exposure of I307N Rho mice to light while in a white opaque polypropylene cage11.
The rate of retinal degeneration in humans and animal models of RP depends, in part, on the inciting gene defect9,29 and likely correlates with the magnitude of microglial morphological activation. Light-inducible models with swift retinal degeneration, including the I307N Rho and arrestin−/− mice26, exhibit activated microglia with a qualitatively large size and a frank ameboid morphology, apparent on day three in our study. The rd1 and rd10 mouse models exhibit slower, but still rapid retinal degeneration that occurs in the weeks after eye opening and their microglia display smaller round bodies with few dendrites30,31. In the more slowly progressive P23H RHO rat and P23H Rho mouse, microglia retract their dendrites yet maintain an intermediate ramified phenotype27,32,33. Thus morphological activation of microglia towards a large, ameboid phenotype likely occurs in proportion to the size of the phagocytic bolus introduced by retinal degeneration, and may have important implications for cell signaling, such as the production of IL-1β34.
The boundary between damaged and preserved retina is a unique feature in the induced I307N Rho mouse and showed a steep gradient in microglia morphology, GFAP-expression by Müller glia, and partially reversible RPE injury. This organization points to potential, unique interactions among these cell types in close space35 that may not occur in models of global retinal degeneration that exhibit a more uniform distribution of microglia, like the P23H RHO rat36. Though we established correlation between Müller glia and microglia, we did not investigate the mechanisms of interaction between these cell types. However, crosstalk between Müller glia and microglia has been reported to help determine photoreceptor survival in other models16,37,38,39. Müller glia are capable of providing crucial neuroprotective support to photoreceptors, for example, by secreting LIF40, but can also contribute to the inflammatory response via secretion of cytokines41,42. Microglia similarly have shown evidence for neuroprotective and neurotoxic effects on photoreceptor survival13,43. Even more, subretinal microglia may protect the RPE during rapid light-induced retinal degeneration27. The seemingly opposing capabilities of microglia and Müller glia may appear incongruous during pan-retinal degeneration, but may be reconciled in the context of the lesion boundary in the I307N Rho mouse where pro-survival pathways and clearance of unsalvageable retina must co-exist in close but distinct spaces. Interestingly, Stefanov et al. noted that horizontal cell remodeling is most severe at the boundary of retinal degeneration in the I307N Rho mouse, which is suggestive of unique signaling events10.
Our data indicate that the number of microglia and/or macrophage increases after the infiltration of CD45-positive monocytic cells via the inner retinal veins and ONH. Our analysis, however, did not differentiate between endogenous microglia, infiltrating macrophage, and monocyte-derived macrophage22,23,24,44,45,46. Genetic techniques to differentiate microglia or monocyte-derived macrophage based on endogenous fluorescence have been employed by others21,22. These methodologies alongside single-cell RNA-seq have demonstrated that microglia and monocyte-derived macrophage may behave differently during retinal degeneration, both in terms of tropism within the retina, as endogenous microglia have displayed a bias towards populating the SRS in the P23H Rho knock-in mouse, and gene expression profiles22,23,27. Future studies with the I307N Rho mouse ought to examine the relative abundance of endogenous microglia versus monocyte-derived macrophage across the boundary of light-damage and assay for differences in phenotype31.
We found that microglia in the I307N Rho mouse reduce in number, move towards homeostatic positioning among the retinal layers, and exhibit a more ramified phenotype in the weeks following light exposure. Interestingly, microglia are capable of defaulting to the baseline, homeostatic transcriptome weeks after acute inflammation in endotoxin uveitis47. On the other hand, microglia in slowly progressive forms of RP may remain pro-inflammatory even after significant photoreceptor loss, which has been demonstrated in the P23H RHO rat48. Data from our present and past work with the I307N Rho model demonstrate that the ONL within the focus of light-induced retina can stably persist when mild retinal degeneration occurs7. Given this finding, determining whether microglia in the I307N Rho mouse can re-establish a homeostatic transcriptome after light exposure and what signals are required for such a transition in phenotype may be of value in illuminating novel therapeutic targets that could be exploited for the treatment of slowly progressive forms of RP.
As we suggested in our previous work, the origin of the outer retina hyper-reflectivity may illuminate potential therapeutic targets7. Though it is well-documented that retinal swelling occurs during light-induced retinal degeneration26,49,50, we found that TRT decreased when hyper-reflectivity initiated in the first hour after cessation of light exposure. Light adaptation in mice induces changes in retinal structures that are apparent via SD-OCT, including expansion of the SRS and photoreceptor outer segments, in part due to changes in osmotic forces and water movement during phototransduction51,52,53,54. Since overactivation of phototransduction may underlie retinal degeneration in the I307N Rho mouse6, the massive reduction in retinal thickness and hyper-reflectivity that occurs very early after light exposure could involve dysregulated water movement after a period of increased respiratory demand54 or G-protein-induced swelling of outer segments53. Fluid balance and retinal reflectivity may also be altered by Müller glia activity via modulation in the expression of aquaporin-4, the Kir4.1 potassium channel, or transient receptor potential isoform 4 (TRPV4) as well as changes to the integrity of the blood-retinal-barrier changes49,55,56. To this end, the I307N Rho mouse may help provide a link between novel pathological findings on SD-OCT, including the origin of retinal hyper-reflectivity, shrinking, and swelling, and associated mechanisms during retinal degeneration.
Our study presents an in-depth time course of the glial response during light-induced degeneration in the I307N Rho mouse and correlates these findings with SD-OCT imaging. Continued characterization of the I307N Rho mouse may uncover new insights regarding the B1 phenotype of adRP associated with mutations in RHO in human. Furthermore, comparison of the glial response after light-induction in the I307N Rho mouse and during retinal degeneration in animal models of slowly progressive and/or global RP could provide new perspectives for evaluating glial biology.
Methods
Animal models
All work abided by the Association for Research in Vision and Ophthalmology (ARVO) Statement for the Use of Animals in Ophthalmic and Vision Research and received prior approval from the Institutional Animal Care and Use Committee (IACUC) at the University of Florida. Animal breeding and genotyping was executed, as described in Massengill et al.7. Briefly, mice were reared in a 12:12-h dim-red light:dark lighting cycle with a maximum light intensity of 200 lx in the Animal Care Facility at the University of Florida. Genotyping via PCR was performed with forward and reverse primers with sequences of GGTCATCTTCTTCCTGATCTGCTGGC and TGCCAGCAGTCTGAGTGCAATG (IDT Technologies, Coralville, IA, USA), respectively, at a Tm of 61 ºC. The wild-type and I307N Rho PCR products (both ~ 260 bp products) were differentiated by restriction digestion with AflIII (New England Biosciences, Ipswich, MA, USA), where only the I307N Rho PCR product was cut and liberated two pieces of DNA with lengths of approximately 150 and 110 base-pairs, followed by agarose gel electrophoresis.
Light damage protocol
A detailed protocol for light damage can be found in Massengill et al.7. Male and female mice were used for experimentation. Briefly, eight- to twelve-week old mice were dark adapted overnight in preparation for light damage. The following day, phenylephrine (Paragon BioTeck Inc., Portland, OR, USA) and atropine (Akorn, Lake Forest, IL, USA) were applied to the eye followed by a fifteen minute incubation, phenylephrine was then applied a second time followed by a second fifteen minute incubation, and phenylephrine was applied a third time immediately prior to challenging the mice with light. Ambulatory mice with maximally dilated eyes were placed into a cage with LED-lights fastened to its roof and the light was modulated to an intensity of 20,000 lx. Mice were exposed to the light for a thirty minute period and were utilized immediately for an experiment or returned to the 12:12-h dim-red light: dark lighting cycle. Light damage occurred between 4:00 PM and 12:00 AM.
Spectral-domain optical coherence tomography (SD-OCT)
Eyes were dilated with phenylephrine (Paragon BioTeck Inc., Portland, OR, USA) approximately fifteen minutes prior to SD-OCT scanning. If a single scan was to be performed, mice were anesthetized with intraperitoneal injection of a cocktail containing 1 mg/mL of xylazine (Vedco, Saint Joseph, MO, USA) and 2.5 mg/mL of ketamine (Vedco, Saint Joseph, MO, USA) diluted in sterile saline (Vedco, Saint Joseph, MO, USA) at a dosage of 0.5 μL per gram of body mass. For time course experiments when more than one scan needed to be performed in a single day, mice were anesthetized with inhaled 2% isoflurane (Patterson Veterinary, Greeley, CO, USA) via a nose cone utilizing a SurgiVet Isotec vaporizer (Smiths Medical, Minneapolis, MN, USA).
Two SD-OCT scanning protocols were employed with the Envisu SD-OCT ophthalmic imaging system (Leica Microsystems, Durham, NC, USA). The first protocol was used for measurement of total retinal thickness (TRT) and reflectivity as well as production of figures with the retina in a cross-sectional view. Here, 25 B-scans representing the average of 10 individual frames were captured across a 1.4 mm × 1.4 mm window of the retina. The averaging ensured high image resolution in cross-section, but sacrificed resolution of the en face fundus view. The second protocol was used for generating figures with the retina in an en face fundus view and for determining the area encompassed by the front of hyper-reflectivity. Here, 200 B-scans were captured across a 1.4 mm × 1.4 mm window of the retina. This protocol allowed for high resolution of the en face fundus view at the expense of low resolution in cross-section. In both protocols, scans were done with the ONH at the center of the image. A discussion regarding the measurement of the TRT and reflectivity as well as image processing can be found in the Supplementary Information.
Immunohistochemistry (IHC) of PFA-fixed frozen sections
Mice were euthanized by CO2 inhalation and cervical dislocation. Animal tattoo ink (Ketchum Mfg. Co., Lake Luzerne, NY, USA) was applied to the nasal portion of the cornea to maintain orientation. Eyes were enucleated, fixed with 4%-paraformaldehyde (PFA; Electron Microscopy Sciences, Hatfield, PA, USA) in PBS, dissected, cryo-protected in 30% sucrose, and frozen in Optimal Cutting Temperature Compound (Sakura, Torrance, CA, USA) as described in Massengill et al.7. Frozen OCT blocks were sectioned with a thickness of 16 μm along the superior to inferior axis at the level of the ONH with a Leica CM3050 S cryostat (Leica, Wetzlar, DEU) at − 20 °C. The Shandon Sequenza slide rack (Fisher Scientific, Hampton, NH, USA) was used for staining. Sections were hydrated with 500 μL PBS for ten minutes, permeabilized with PBS containing 0.5% Triton X-100 (PBS-T; Fisher Scientific, Hampton, NH, USA) with three 150 μL wash steps for five minutes each, incubated with 500 μL 0.5% NaBH4 (Sigma-Aldrich, St. Louis, MO, USA) in PBS three times for ten minutes each, washed with 500 μL PBS to remove the NaBH4, and incubated in 150 μL blocking buffer (10% normal horse serum in PBS-T; Vector Laboratories, Burlingame, CA, USA) for one hour at room-temperature. Primary antibody or antibodies were diluted in 150 μL of blocking buffer and incubated on the tissue at 4 °C overnight: rabbit anti-Iba1 1:500 (Wako, Osaka, JPN), goat anti-CD45 1:500 (R&D Systems, Minneapolis, MN, USA), and goat anti-GFAP 1:1000 (Abcam, Cambridge, UK). No primary antibody controls were incubated in blocking buffer only. Three 150 μL washes with PBS-T for five minutes each removed the primary antibody before application of 150 μL of secondary antibody or antibodies diluted to 1:2000 in blocking buffer: donkey anti-Goat IgG (H + L) Cross-Adsorbed Secondary Antibody Alexa Fluor 488 and donkey anti-Rabbit IgG (H + L) Secondary Antibody Alexa Fluor 594 (Thermo Fisher, Waltham, MA, USA). After a one hour incubation at room-temperature, secondary antibody solution was removed by washing three times with 150 μL of PBS-T for five minutes each as well as a single wash step with 500 μL of PBS. 500 μL of DAPI (Thermo Fisher, Waltham, MA, USA) diluted to 1:7000 in PBS was introduced to the slides for ten minutes followed by a final wash step with 500 μL of PBS. When staining for microglia (Iba1 or CD45), 150 μL of TrueBlack lipofuscin autofluorescence quencher (Biotum, Fremont, CA, USA) in 70% ethanol was applied to the slides for five minutes to minimize auto-fluorescence caused by oxidized lipid in highly phagocytic microglia. Two washes with 500 μL PBS removed the TrueBlack solution. Slides were cover-slipped with Fluoromount-G (Thermo Fisher, Waltham, MA, USA). A discussion regarding the measurement of the Müller glial and microglial response can be found in the Supplementary Information.
IHC of retinal and RPE flat-mounts
Mice were euthanized by CO2 inhalation and cervical dislocation. Eyes were enucleated, fixed with 1%-PFA (Electron Microscopy Sciences, Hatfield, PA, USA) in PBS, dissected, and further fixed with 4%-PFA as described in Massengill et al.7. Tissues were incubated in 500 μL of PBS-T for thirty minutes at room-temperature for permeabilization. 500 μL of 0.5% Sodium Borohydride (Sigma-Aldrich, St. Louis, MO, USA) in PBS was applied to only the retina for thirty minutes at room-temperature then washed in PBS to reduce background staining. Retinal and RPE tissues were next incubated in 100 μL of blocking buffer (10% horse-serum in PBS-T; Vector Laboratories, Burlingame, CA, USA) overnight at 4 °C. Blocking buffer was removed and primary antibody or antibodies in 100 μL of blocking buffer were then applied to the tissues and incubated for one or three days for the RPE or retina, respectively: rabbit anti-Iba1 1:500 (Wako, Osaka, JPN), goat anti-CD45 1:500 (R&D Systems, Minneapolis, MN, USA), biotinylated GSL-IB4 from Griffonia simplicifolia 1:500 (Vector Laboratories, Burlingame, CA, USA), rabbit anti-GFAP 1:500 (Agilent Dako, Santa Clara, CA, USA), and rabbit anti-ZO1 1:200 (Invitrogen, Carlsbad, CA, USA). No primary antibody controls were incubated in blocking buffer only. Tissues were washed with 100 μL of PBS-T three times for five minutes each. Secondary antibody or antibodies diluted in 150 μL of blocking buffer were added to the tissue and incubated for one or two hours for RPE or retina, respectively: donkey anti-Goat IgG (H + L) Cross-Adsorbed Secondary Antibody Alexa Fluor 488 1:1000, donkey anti-Rabbit IgG (H + L) Secondary Antibody Alexa Fluor 594 1:000 (Thermo Fisher, Waltham, MA, USA), and Streptavidin Alexa Fluor 594 conjugate 1:500 (Invitrogen, Carlsbad, CA, USA). Tissues were washed with 100 μL of PBS-T three times for five minutes each, dissected into a clover configuration with four leaflets, flattened on a slide, and cover-slipped with Fluoromount-G (Thermo Fisher, Waltham, MA, USA). A discussion regarding image processing, cell counting, and the measurement of monocytic cell infiltration can be found in the Supplementary Information.
Statistical analysis
Graphs were generated and statistical analyses were performed using GraphPad Prism Software, Version 8 (GraphPad Software Inc., San Diego, CA, USA). Normality of raw populations and residuals was assessed with the Shapiro–Wilk test. Two-way repeated measures ANOVA with matching for one factor (mixed-model ANOVA) followed by Sidak’s multiple comparisons test was employed to compare differences in retinal sector within the same animals, but differences across time between separate animals (Fig. 1c,d). Two-way repeated measures ANOVA with matching for both factors (retinal sector & time) followed by Tukey’s multiple comparisons test was used to compare differences in retinal sector across time within the same animal (Fig. 5b,c). Parametric one-way ANOVA with Dunnett’s multiple comparisons test (Fig. 2b) and non-parametric one-way ANOVA (Kruskal–Wallis test) with Dunn’s multiple comparisons test (Fig. 3b) was employed to compare differences in independent samples across time when normality was or was not met, respectively. An alpha level of 0.05 was employed.
Data availability
The data produced in preparation of this manuscript are available at https://dataverse.harvard.edu/dataverse/Lewinlab.
References
Hamel, C. P. Gene discovery and prevalence in inherited retinal dystrophies. C. R. Biol. 337, 160–166. https://doi.org/10.1016/j.crvi.2013.12.001 (2014).
Dias, M. F. et al. Molecular genetics and emerging therapies for retinitis pigmentosa: basic research and clinical perspectives. Prog. Retin. Eye Res. 63, 107–131. https://doi.org/10.1016/j.preteyeres.2017.10.004 (2018).
Daiger, S. P., Bowne, J. & Sullivan, L. S. RetNet: Summaries of Genes and Loci Causing Retinal Diseases, https://www.sph.uth.tmc.edu/RetNet/ (2018).
Athanasiou, D. et al. The molecular and cellular basis of rhodopsin retinitis pigmentosa reveals potential strategies for therapy. Prog. Retin. Eye Res. 62, 1–23. https://doi.org/10.1016/j.preteyeres.2017.10.002 (2018).
Ferrari, S. et al. Retinitis pigmentosa: genes and disease mechanisms. Curr. Genom. 12, 238–249. https://doi.org/10.2174/138920211795860107 (2011).
Budzynski, E. et al. Mutations of the opsin gene (Y102H and I307N) lead to light-induced degeneration of photoreceptors and constitutive activation of phototransduction in mice. J. Biol. Chem. 285, 14521–14533. https://doi.org/10.1074/jbc.M110.112409 (2010).
Massengill, M. T. et al. Clinically relevant outcome measures for the I307N rhodopsin mouse: a model of inducible autosomal dominant retinitis pigmentosa. Invest. Ophthalmol Vis. Sci. 59, 5417–5430. https://doi.org/10.1167/iovs.18-25345 (2018).
Gargini, C., Novelli, E., Piano, I., Biagioni, M. & Strettoi, E. Pattern of retinal morphological and functional decay in a light-inducible, rhodopsin mutant mouse. Sci. Rep. 7, 5730. https://doi.org/10.1038/s41598-017-06045-x (2017).
Cideciyan, A. V. et al. Disease sequence from mutant rhodopsin allele to rod and cone photoreceptor degeneration in man. Proc. Natl. Acad. Sci. USA 95, 7103–7108 (1998).
Stefanov, A., Novelli, E. & Strettoi, E. Inner retinal preservation in the photoinducible I307N rhodopsin mutant mouse, a model of autosomal dominant retinitis pigmentosa. J. Comp. Neurol. 528, 1502–1522. https://doi.org/10.1002/cne.24838 (2020).
Zhang, X. et al. Wheel running exercise protects against retinal degeneration in the I307N rhodopsin mouse model of inducible autosomal dominant retinitis pigmentosa. Mol. Vis. 25, 462–476 (2019).
Subirada, P. V. et al. A journey into the retina: Müller glia commanding survival and death. Eur. J. Neurosci. 47, 1429–1443. https://doi.org/10.1111/ejn.13965 (2018).
Silverman, S. M. & Wong, W. T. Microglia in the retina: roles in development, maturity, and disease. Annu. Rev. Vis. Sci. 4, 45–77. https://doi.org/10.1146/annurev-vision-091517-034425 (2018).
Campello, L. et al. New Nrf2-inducer compound ITH12674 slows the progression of retinitis pigmentosa in the mouse model rd10. Cell Physiol. Biochem. 54, 142–159. https://doi.org/10.33594/000000210 (2020).
Cammalleri, M. et al. The urokinase-type plasminogen activator system as drug target in retinitis pigmentosa: new pre-clinical evidence in the rd10 mouse model. J. Cell Mol. Med. 23, 5176–5192. https://doi.org/10.1111/jcmm.14391 (2019).
Roche, S. L., Ruiz-Lopez, A. M., Moloney, J. N., Byrne, A. M. & Cotter, T. G. Microglial-induced Müller cell gliosis is attenuated by progesterone in a mouse model of retinitis pigmentosa. Glia 66, 295–310. https://doi.org/10.1002/glia.23243 (2018).
Sumaroka, A. et al. Autosomal dominant retinitis pigmentosa due to class B Rhodopsin mutations: an objective outcome for future treatment trials. Int. J. Mol. Sci. 20, 5344. https://doi.org/10.3390/ijms20215344 (2019).
Tonks, N. K., Charbonneau, H., Diltz, C. D., Fischer, E. H. & Walsh, K. A. Demonstration that the leukocyte common antigen CD45 is a protein tyrosine phosphatase. Biochemistry 27, 8695–8701 (1988).
Ekström, P., Sanyal, S., Narfström, K., Chader, G. J. & van Veen, T. Accumulation of glial fibrillary acidic protein in Müller radial glia during retinal degeneration. Invest. Ophthalmol. Vis. Sci. 29, 1363–1371 (1988).
Ito, D. et al. Microglia-specific localisation of a novel calcium binding protein, Iba1. Brain Res. Mol. Brain Res. 57, 1–9. https://doi.org/10.1016/s0169-328x(98)00040-0 (1998).
O’Koren, E. G., Mathew, R. & Saban, D. R. Fate mapping reveals that microglia and recruited monocyte-derived macrophages are definitively distinguishable by phenotype in the retina. Sci. Rep. 6, 20636. https://doi.org/10.1038/srep20636 (2016).
Ma, W. et al. Monocyte infiltration and proliferation reestablish myeloid cell homeostasis in the mouse retina following retinal pigment epithelial cell injury. Sci. Rep. 7, 8433. https://doi.org/10.1038/s41598-017-08702-7 (2017).
Ronning, K. E., Karlen, S. J., Miller, E. B. & Burns, M. E. Molecular profiling of resident and infiltrating mononuclear phagocytes during rapid adult retinal degeneration using single-cell RNA sequencing. Sci. Rep. 9, 4858. https://doi.org/10.1038/s41598-019-41141-0 (2019).
Karlen, S. J. et al. Monocyte infiltration rather than microglia proliferation dominates the early immune response to rapid photoreceptor degeneration. J. Neuroinflamm. 15, 344. https://doi.org/10.1186/s12974-018-1365-4 (2018).
Bolte, S. & Cordelières, F. P. A guided tour into subcellular colocalization analysis in light microscopy. J. Microsc. 224, 213–232. https://doi.org/10.1111/j.1365-2818.2006.01706.x (2006).
Levine, E. S. et al. Rapid light-induced activation of retinal microglia in mice lacking Arrestin-1. Vis. Res. 102, 71–79. https://doi.org/10.1016/j.visres.2014.07.011 (2014).
O’Koren, E. G. et al. Microglial function is distinct in different anatomical locations during retinal homeostasis and degeneration. Immunity 50, 723-737.e727. https://doi.org/10.1016/j.immuni.2019.02.007 (2019).
Naylor, A., Hopkins, A., Hudson, N. & Campbell, M. Tight junctions of the outer blood retina barrier. Int. J. Mol. Sci. 21, 211. https://doi.org/10.3390/ijms21010211 (2019).
Collin, G. B. et al. Mouse models of inherited retinal degeneration with photoreceptor cell loss. Cells 9, 931. https://doi.org/10.3390/cells9040931 (2020).
Zhao, L. et al. Microglial phagocytosis of living photoreceptors contributes to inherited retinal degeneration. EMBO Mol. Med. 7, 1179–1197. https://doi.org/10.15252/emmm.201505298 (2015).
Zhou, T. et al. Microglia polarization with M1/M2 phenotype changes in rd1 mouse model of retinal degeneration. Front. Neuroanat. 11, 77. https://doi.org/10.3389/fnana.2017.00077 (2017).
Noailles, A., Maneu, V., Campello, L., Lax, P. & Cuenca, N. Systemic inflammation induced by lipopolysaccharide aggravates inherited retinal dystrophy. Cell Death Dis. 9, 350. https://doi.org/10.1038/s41419-018-0355-x (2018).
Viringipurampeer, I. A. et al. NLRP3 inflammasome activation drives bystander cone photoreceptor cell death in a P23H rhodopsin model of retinal degeneration. Hum. Mol. Genet. 25, 1501–1516. https://doi.org/10.1093/hmg/ddw029 (2016).
Fernández-Arjona, M. D. M., Grondona, J. M., Fernández-Llebrez, P. & López-Ávalos, M. D. Microglial morphometric parameters correlate with the expression level of IL-1β, and allow identifying different activated morphotypes. Front. Cell Neurosci. 13, 472. https://doi.org/10.3389/fncel.2019.00472 (2019).
Natoli, R. et al. Microglia-derived IL-1β promotes chemokine expression by Müller cells and RPE in focal retinal degeneration. Mol. Neurodegener. 12, 31. https://doi.org/10.1186/s13024-017-0175-y (2017).
Noailles, A., Fernández-Sánchez, L., Lax, P. & Cuenca, N. Microglia activation in a model of retinal degeneration and TUDCA neuroprotective effects. J. Neuroinflamm. 11, 186. https://doi.org/10.1186/s12974-014-0186-3 (2014).
Hooper, M. J. & Ash, J. D. Müller cell biological processes associated with leukemia inhibitory factor expression. Adv. Exp. Med. Biol. 1074, 479–484. https://doi.org/10.1007/978-3-319-75402-4_59 (2018).
Di Pierdomenico, J. et al. Coordinated intervention of microglial and müller cells in light-induced retinal degeneration. Invest. Ophthalmol. Vis. Sci. 61, 47. https://doi.org/10.1167/iovs.61.3.47 (2020).
Arroba, A. I., Alvarez-Lindo, N., van Rooijen, N. & de la Rosa, E. J. Microglia-Müller glia crosstalk in the rd10 mouse model of retinitis pigmentosa. Adv. Exp. Med. Biol. 801, 373–379. https://doi.org/10.1007/978-1-4614-3209-8_47 (2014).
Ueki, Y., Wang, J., Chollangi, S. & Ash, J. D. STAT3 activation in photoreceptors by leukemia inhibitory factor is associated with protection from light damage. J. Neurochem. 105, 784–796. https://doi.org/10.1111/j.1471-4159.2007.05180.x (2008).
Rutar, M., Natoli, R., Valter, K. & Provis, J. M. Early focal expression of the chemokine Ccl2 by Müller cells during exposure to damage-inducing bright continuous light. Invest. Ophthalmol. Vis. Sci. 52, 2379–2388. https://doi.org/10.1167/iovs.10-6010 (2011).
Feng, C. et al. Expression of CCL2 and its receptor in activation and migration of microglia and monocytes induced by photoreceptor apoptosis. Mol. Vis. 23, 765–777 (2017).
Rashid, K., Akhtar-Schaefer, I. & Langmann, T. Microglia in retinal degeneration. Front. Immunol. 10, 1975. https://doi.org/10.3389/fimmu.2019.01975 (2019).
Zhang, M., Xu, G., Liu, W., Ni, Y. & Zhou, W. Role of fractalkine/CX3CR1 interaction in light-induced photoreceptor degeneration through regulating retinal microglial activation and migration. PLoS ONE 7, e35446. https://doi.org/10.1371/journal.pone.0035446 (2012).
Zhang, Y. et al. Repopulating retinal microglia restore endogenous organization and function under CX3CL1-CX3CR1 regulation. Sci. Adv. 4, eaap8492. https://doi.org/10.1126/sciadv.aap8492 (2018).
Huang, Y. et al. Dual extra-retinal origins of microglia in the model of retinal microglia repopulation. Cell Discov. 4, 9. https://doi.org/10.1038/s41421-018-0011-8 (2018).
Bell, O. H. et al. Single eye mRNA-Seq reveals normalisation of the retinal microglial transcriptome following acute inflammation. Front. Immunol. 10, 3033. https://doi.org/10.3389/fimmu.2019.03033 (2019).
Noailles, A. et al. Persistent inflammatory state after photoreceptor loss in an animal model of retinal degeneration. Sci. Rep. 6, 33356. https://doi.org/10.1038/srep33356 (2016).
Geiger, P., Barben, M., Grimm, C. & Samardzija, M. Blue light-induced retinal lesions, intraretinal vascular leakage and edema formation in the all-cone mouse retina. Cell Death Dis. 6, e1985. https://doi.org/10.1038/cddis.2015.333 (2015).
Aziz, M. K., Ni, A., Esserman, D. A. & Chavala, S. H. Evidence of early ultrastructural photoreceptor abnormalities in light-induced retinal degeneration using spectral domain optical coherence tomography. Br. J. Ophthalmol. 98, 984–989. https://doi.org/10.1136/bjophthalmol-2013-304515 (2014).
Li, Y. et al. Light-dependent OCT structure changes in photoreceptor degenerative rd 10 mouse retina. Invest. Ophthalmol. Vis. Sci. 59, 1084–1094. https://doi.org/10.1167/iovs.17-23011 (2018).
Lu, C. D. et al. Photoreceptor layer thickness changes during dark adaptation observed with ultrahigh-resolution optical coherence tomography. Invest. Ophthalmol. Vis. Sci. 58, 4632–4643. https://doi.org/10.1167/iovs.17-22171 (2017).
Zhang, P. et al. In vivo optophysiology reveals that G-protein activation triggers osmotic swelling and increased light scattering of rod photoreceptors. Proc. Natl. Acad. Sci. USA 114, E2937–E2946. https://doi.org/10.1073/pnas.1620572114 (2017).
Berkowitz, B. A. et al. Mitochondrial respiration in outer retina contributes to light-evoked increase in hydration in vivo. Invest. Ophthalmol. Vis. Sci. 59, 5957–5964. https://doi.org/10.1167/iovs.18-25682 (2018).
Iandiev, I. et al. Localization of glial aquaporin-4 and Kir41 in the light-injured murine retina. Neurosci. Lett. 434, 317–321. https://doi.org/10.1016/j.neulet.2008.02.026 (2008).
Jo, A. O. et al. TRPV4 and AQP4 channels synergistically regulate cell volume and calcium homeostasis in retinal Müller glia. J. Neurosci. 35, 13525–13537. https://doi.org/10.1523/JNEUROSCI.1987-15.2015 (2015).
Acknowledgements
We would like to thank our funding sources: the NIH who supported this work through the F30EY027163 Training Grant awarded to MTM, the Shaler Richardson Professorship Endowment awarded to ASL, and an unrestricted grant from the Research to Prevent Blindness. We also thank the Animal Care Facility staff at the University of Florida for providing excellent care to the experimental animals as well as the Ocular Gene Therapy Core in the Department of Ophthalmology at the University of Florida for providing access microscopy equipment. Finally, we would like to show our gratitude to Dr. John Ash at the University of Florida for providing the lighted cages, histological protocols, as well as access to equipment in his laboratory.
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M.T.M. designed, executed, processed, and analyzed the histological experiments and wrote the manuscript. N.F.A. processed and analyzed histological data and edited the manuscript. B.M.Y. processed histological specimens, performed preliminary experiments, and edited the manuscript. C.J.I. edited the manuscript and was consulted for experimental design and analysis. A.S.L. designed and analyzed experiments and edited the manuscript.
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Massengill, M.T., Ash, N.F., Young, B.M. et al. Sectoral activation of glia in an inducible mouse model of autosomal dominant retinitis pigmentosa. Sci Rep 10, 16967 (2020). https://doi.org/10.1038/s41598-020-73749-y
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DOI: https://doi.org/10.1038/s41598-020-73749-y
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