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Tweaking the immune system as an adjuvant for the treatment of retinal degenerations

Tweaking the immune system as an adjuvant for the treatment of retinal degenerations

来源期刊: Annals of Eye Science | 2017年3月 第2卷 第3期 - 发布时间: 15 March 2017.阅读量:892
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关键词:
Immune modulation retina retinal degeneration photoreceptor transplantation retinal repair
Immune modulation retina retinal degeneration photoreceptor transplantation retinal repair
DOI:
10.21037/aes.2017.01.05

Abstract: Blinding diseases such as photoreceptor degenerations are debilitating conditions that severely impair daily lives of affected patients. This group of diseases are amenable to photoreceptor replacement therapies and recent transplantation studies provided proof-of-principle for functional recovery at the retinal and behavioral level, though the actual mechanism of repair still needs further investigations. The immune system responds in several ways upon photoreceptor engraftment, resulting in T-cell and macrophage infiltrations and, consequently, decrease in graft survival. Most studies on the role of the immune system suggest a detrimental effect in a therapeutic setting. Conversely, the opposite idea wherein the immune system can be activated towards a protective state was also explored in other experimental paradigms. Here, Neves and colleagues explored the potential of cross-species studies and, to a certain extent, the concept of a protective immune system in retinal degeneration and therapy. Mesencephalic astrocyte-derived neurotrophic factor (MANF) was identified in this study as a novel factor that, by modulating the immune system, can slow down photoreceptor degeneration and improve transplantation outcome.

Abstract: Blinding diseases such as photoreceptor degenerations are debilitating conditions that severely impair daily lives of affected patients. This group of diseases are amenable to photoreceptor replacement therapies and recent transplantation studies provided proof-of-principle for functional recovery at the retinal and behavioral level, though the actual mechanism of repair still needs further investigations. The immune system responds in several ways upon photoreceptor engraftment, resulting in T-cell and macrophage infiltrations and, consequently, decrease in graft survival. Most studies on the role of the immune system suggest a detrimental effect in a therapeutic setting. Conversely, the opposite idea wherein the immune system can be activated towards a protective state was also explored in other experimental paradigms. Here, Neves and colleagues explored the potential of cross-species studies and, to a certain extent, the concept of a protective immune system in retinal degeneration and therapy. Mesencephalic astrocyte-derived neurotrophic factor (MANF) was identified in this study as a novel factor that, by modulating the immune system, can slow down photoreceptor degeneration and improve transplantation outcome.

The mammalian retina has a very limited regenerative capacity (1) and degeneration of the main light-sensing cells—rod and cone photoreceptors—results in permanent damage and consequently vision loss as observed in diseases such as retinitis pigmentosa (2). Such debilitating condition brings a significant burden to society and economy, thus, it is important to develop strategies that allow the repair of the degenerated tissues. Gene therapy (3), retinal prosthesis (4) and cell replacement approaches (5) are promising strategies to treat blinding diseases and significant resources are being allocated to these fields. On the other hand, few studies explored the endogenous regenerative capacity of the mammalian retina (6).

Multiple studies showed a role of the immune system in promoting endogenous repair in other tissues and disease paradigms addressing the interaction between immune system and endogenous regenerative potential (7-10). Neves and colleagues adopted a novel approach to study the role of the immune system in the regenerative capacity of the mammalian retina. Two model organisms were used and their best features explored for the purpose of the study: drosophila and its power for genetic studies, and the mouse that closely mimics the degenerative phenotypes present in human diseases (11).

During retinal neurodegenerative processes such as retinitis pigmentosa or age-related macular degeneration, microglia is activated and a pro-inflammatory environment is created. Upon CNS and thus also retina injury microglia within the tissue can acquire a M1 or M2 state and, depending on such states, the affected tissue enters a degenerative process and consequently cell death or shows signs for the onset of a repair mechanisms. This M1/M2 dichotomy was initially addressed by Neves et al. using drosophila as a model organism. In drosophila, hemocytes (cells with macrophage-like activities) respond to tissue injury and coordinate a cellular response and the resolution of the inflammatory process. In their study retinal damage was caused by exposure to UV light that resulted in the degeneration of the drosophila’s photoreceptors. Upon damage, photoreceptors secret PDGF- and VEGF-related factor 1 (Pvf-1), which in turn activates hemocytes for tissue repair, by binding to the Pv receptor (PvR). RNA sequencing analysis on isolated hemocytes during UV-mediated photoreceptor damage, revealed a significant upregulation of several factors including mesencephalic astrocyte-derived neurotrophic factor (MANF), which was further investigated. In the absence of MANF, the UV treated drosophila eye showed a significant tissue loss which could be rescued by overexpressing MANF in hemocytes. Despite MANF’s neuroprotective role, its mechanism was further dissected by identifying its effect on the morphology and marker expression of hemocytes. Hemocytes treated with human recombinant MANF in culture or overexpressing MANF in vivo resulted in an increased proportion of lamellocytes and increased positivity of the drosophila homologue of the mammalian M2 marker arginase 1 (arg1). These changes in morphology could be correlated to the mammalian M1/M2 phenotype observed in macrophages and microglia. Besides histological evidence for the presence of a M2-like phenotype in hemocytes upon injury, future studies may be helpful to confirm the M2 phenotype in more detail. In that regard, a comparison at the transcriptional level between the M2-like phenotype and true M2 and M1-microglia would help to dissect downstream elements of MANF. The immune modulatory potential of MANF in retinal repair was then determined by manipulating the amount of secreted and membrane-bound MANF. To achieve this, Neves and colleagues overexpressed MANF in the absence of the drosophila KDEI receptor homolog which resulted in a decreased number of lamellocytes formed and arg1 expressed. Phenotypically, tissue loss was significantly higher in these conditions, showing that MANF expression is critical for tissue repair.

Interestingly, the mammalian retina displays a similar response to light injury (transient damage when exposed to 1,000 lux of light for 1.5 hours in C57BL/6 mice) with an upregulation of VEGF and PDGF-family proteins followed by increased MANF mRNA levels in dendritic cells (CD11b+). Curiously, crosstalk between activated microglia and Müller glia cells occurred upon damage resulting in Müller glia cells positive for MANF. The interplay between these two cell types has not been explored and might lead to novel insights in late stages of retinal degeneration. In accordance to other retinal degenerations, microglia became activated and migrated to the outer nuclear layer where degenerating cells are located. Conservation among species of the response towards retinal injury was further validated by inhibiting both PDGF signaling pathways leading to an increased number of CD11b+ cells in the vitreous and photoreceptor cell death.

The use of C57BL/6J mice for the retinal damage paradigm allows the retina to recover to a certain extend as shown by Neves and colleagues by transiently increasing the number of CD11b+ cells in the retina. Moreover, MANF’s broad neuroprotective effect was further validated in three more severe models of retinal degeneration: severe light damage using BALB/cJ, the Crxtvrm65 and Pde6brd1 mice. In contrast to C57BL/6 mice, BLAB/cJ mice do not harbor a protective variant of the RPE65 gene which, in turn, makes an optimal model of induced retinal degeneration. A single vitreal injection of human recombinant MANF protein resulted in a significant reduction in the level of cell death in the three paradigms of retinal degeneration. The extent of this neuroprotective effect was confirmed by human fibroblasts constitutively expressing MANF-GFP fusion protein that were transplanted into the vitreous of Crxtvrm65 mice. Two weeks after transplantation, MANF’s neuroprotective effect was still observed in this degeneration model by a significantly higher number of remaining photoreceptor rows.

The neuroprotective effect of MANF was convincingly shown in photoreceptor degenerations in general, however it would be of interest to determine whether MANF effects can specifically target also cones as in cone dystrophies. Additionally, photoreceptors are not the only cells that degenerate in retinopathies. Retinal pigment epithelium cells are one of the cell types affected in multiple retinal degenerations, such as sub-types of Retinitis Pigmentosa (2) and age-related macular degeneration (12). Determining MANF effects in RPE degenerations as it is observed in Ccl2/Cx3Cr1-/- mice (13) would further support the authors hypothesis for a broad spectrum application of MANF as a neuroprotective agent. Complementary to the latter, it would be of great interest to determine whether this mechanism is conserved in human retinas of patients suffering from AMD where the immune system is unbalanced. Such questions may be addressed in future studies.

A closer look into the CD11b+ cells (dendritic cells) in the vitreous revealed a round morphology, which reflects an alternative activation and MANF’s immunomodulatory effect. Upon vitreal delivery of MANF, the recruited innate immune cells were composed of monocytes and monocyte-derived macrophages (~60% to 80% of recruited cells). Neutrophils positive for Ly6-G+ (Gr1high) accounted for 15% and both neutrophils and macrophages expressed MANF and arg1 suggesting an anti-inflammatory response by the immune system. Besides MANF’s paracrine effect, it can partially regulate macrophages in an autocrine manner reflecting its immunomodulatory effect. To validate the dependence of MANF effects on the immune system, light-induced photoreceptor degeneration mouse models with impaired immune system, i.e., lacking CD11b+ cells or the Cx3Cr1-/- mouse were used. The absence of Cx3Cr1 protein leads to retinal degeneration and increased pro-inflammatory activation of immune cells. If MANF would be the sole effector of this immunomodulatory effect, administration of MANF would result in decreased levels of cell death. Interestingly, the authors observed the opposite effect in both mouse models: cell death remained constant. The expression levels of MANF in the Cx3Cr1 knockout mouse remained constant, which might be due to the contribution of cell types other than macrophages for the protective effect of MANF depended immunomodulation. Deeper understanding of this complex mechanism would provide novel insight in how the immune system can be modulated to support regenerative responses that may allow broad application in several neurodegenerative diseases.

Such use of MANF was further extended to a photoreceptor replacement approach. Following transplantation of Nrl-eGFP rods into wild-type mice, microglia positive for MANF localized to the site of integrated photoreceptors suggesting that they might play a role in the transplantation outcome. Indeed, supplementation of MANF to rod transplantation significantly improved the transplantation success, which was determined by the number of GFP+ photoreceptors within the host ONL and interpreted as increased numbers of structurally integrated donor photoreceptors. However, recently four studies unveiled that following photoreceptor transplantation donor cells mainly exchange cytoplasmic material with host photoreceptors while structural integration occurs to a minor extend (14-17). Thus, it is currently unknown whether the transplantation improvement promoted by MANF as observed by Neves and colleagues is caused by an increased donor cell integration or donor-host cytoplasmic exchange. Identifying the mechanism by which MANF supplementation promotes transplanted photoreceptors will be an important pre-requisite to further develop the use of MANF for cell-based therapeutic interventions in the retina.

Aside of which mechanism is enhanced by MANF supplementation—structural integration or cytoplasmic exchange—the authors took advantage of previous data on donor photoreceptor age and its relationship to the transplantation outcome. MacLaren et al. [2006] followed by Bartsch et al. [2008] showed that young post-mitotic photoreceptors between postnatal day (P) 4–7 allow improved transplantation success when compared to their young or older counterparts (18,19). Hence, Neves et al., assessed the effect of MANF immunomodulation on photoreceptor transplantation using older, i.e., mature, Nrl-eGFP photoreceptors (p21) and compared the transplantation outcome to the “standard” age of donor cells—this is P4–7. In fact, transplanted P21 rods showed improved transplantation outcomes when supplemented with MANF when compared to controls—P21 rods without MANF—but it still had not a similar outcome as transplanted P7 rods. However, faster functional recovery (assessed by electroretinogram) was observed when MANF was supplemented to transplanted P7 rods when compared to control conditions.

In conclusion, Neves and colleagues’ study identified a key molecule involved in the immune response to retinal repair—MANF—and dissected its immunomodulatory and neuroprotective effects in different retinal disease paradigms underlining the view of a protective role of the immune system in retinal regeneration.


1、MacLaren RE, Pearson RA, MacNeil A, et al. Retinal repair by transplantation of photoreceptor precursors. Nature 2006;444:203-7. MacLaren RE, Pearson RA, MacNeil A, et al. Retinal repair by transplantation of photoreceptor precursors. Nature 2006;444:203-7.
2、Bartsch U, Oriyakhel W, Kenna PF, et al. Retinal cells integrate into the outer nuclear layer and differentiate into mature photoreceptors after subretinal transplantation into adult mice. Exp Eye Res 2008;86:691-700. Bartsch U, Oriyakhel W, Kenna PF, et al. Retinal cells integrate into the outer nuclear layer and differentiate into mature photoreceptors after subretinal transplantation into adult mice. Exp Eye Res 2008;86:691-700.
3、Singh MS, Balmer J, Barnard AR, et al. Transplanted photoreceptor precursors transfer proteins to host photoreceptors by a mechanism of cytoplasmic fusion. Nat Commun 2016;7:13537. Singh MS, Balmer J, Barnard AR, et al. Transplanted photoreceptor precursors transfer proteins to host photoreceptors by a mechanism of cytoplasmic fusion. Nat Commun 2016;7:13537.
4、Santos-Ferreira T, Llonch S, Borsch O, et al. Retinal transplantation of photoreceptors results in donor-host cytoplasmic exchange. Nat Commun 2016;7:13028. Santos-Ferreira T, Llonch S, Borsch O, et al. Retinal transplantation of photoreceptors results in donor-host cytoplasmic exchange. Nat Commun 2016;7:13028.
5、Pearson RA, Gonzalez-Cordero A, West EL, et al. Donor and host photoreceptors engage in material transfer following transplantation of post-mitotic photoreceptor precursors. Nat Commun 2016;7:13029. Pearson RA, Gonzalez-Cordero A, West EL, et al. Donor and host photoreceptors engage in material transfer following transplantation of post-mitotic photoreceptor precursors. Nat Commun 2016;7:13029.
6、Ortin-Martinez A, Tsai EL, Nickerson PE, et al. A Re-interpretation of Cell Transplantation: GFP Transfer from Donor to Host Photoreceptors. Stem Cells 2016. [Epub ahead of print].Ortin-Martinez A, Tsai EL, Nickerson PE, et al. A Re-interpretation of Cell Transplantation: GFP Transfer from Donor to Host Photoreceptors. Stem Cells 2016. [Epub ahead of print].
7、Tuo J, Bojanowski CM, Zhou M, et al. Murine ccl2/cx3cr1 deficiency results in retinal lesions mimicking human age-related macular degeneration. Invest Ophthalmol Vis Sci 2007;48:3827-36. Tuo J, Bojanowski CM, Zhou M, et al. Murine ccl2/cx3cr1 deficiency results in retinal lesions mimicking human age-related macular degeneration. Invest Ophthalmol Vis Sci 2007;48:3827-36.
8、Ambati J, Fowler BJ. Mechanisms of age-related macular degeneration. Neuron 2012;75:26-39. Ambati J, Fowler BJ. Mechanisms of age-related macular degeneration. Neuron 2012;75:26-39.
9、Neves J, Zhu J, Sousa-Victor P, et al. Immune modulation by MANF promotes tissue repair and regenerative success in the retina. Science 2016;353:aaf3646 Neves J, Zhu J, Sousa-Victor P, et al. Immune modulation by MANF promotes tissue repair and regenerative success in the retina. Science 2016;353:aaf3646
10、Shechter R, Miller O, Yovel G, et al. Recruitment of beneficial M2 macrophages to injured spinal cord is orchestrated by remote brain choroid plexus. Immunity 2013;38:555-69. Shechter R, Miller O, Yovel G, et al. Recruitment of beneficial M2 macrophages to injured spinal cord is orchestrated by remote brain choroid plexus. Immunity 2013;38:555-69.
11、Miron VE, Boyd A, Zhao JW, et al. M2 microglia and macrophages drive oligodendrocyte differentiation during CNS remyelination. Nat Neurosci 2013;16:1211-8. Miron VE, Boyd A, Zhao JW, et al. M2 microglia and macrophages drive oligodendrocyte differentiation during CNS remyelination. Nat Neurosci 2013;16:1211-8.
12、Kyritsis N, Kizil C, Zocher S, et al. Acute inflammation initiates the regenerative response in the adult zebrafish brain. Science 2012;338:1353-6. Kyritsis N, Kizil C, Zocher S, et al. Acute inflammation initiates the regenerative response in the adult zebrafish brain. Science 2012;338:1353-6.
13、Burzyn D, Kuswanto W, Kolodin D, et al. A special population of regulatory T cells potentiates muscle repair. Cell 2013;155:1282-95. Burzyn D, Kuswanto W, Kolodin D, et al. A special population of regulatory T cells potentiates muscle repair. Cell 2013;155:1282-95.
14、Karl MO, Reh TA. Regenerative medicine for retinal diseases: activating endogenous repair mechanisms. Trends Mol Med 2010;16:193-202. Karl MO, Reh TA. Regenerative medicine for retinal diseases: activating endogenous repair mechanisms. Trends Mol Med 2010;16:193-202.
15、Pearson RA, Hippert C, Graca AB, et al. Photoreceptor replacement therapy: challenges presented by the diseased recipient retinal environment. Vis Neurosci 2014;31:333-44. Pearson RA, Hippert C, Graca AB, et al. Photoreceptor replacement therapy: challenges presented by the diseased recipient retinal environment. Vis Neurosci 2014;31:333-44.
16、Luo YH, da Cruz L. The Argus(?) II Retinal Prosthesis System. Prog Retin Eye Res 2016;50:89-107. Luo YH, da Cruz L. The Argus(?) II Retinal Prosthesis System. Prog Retin Eye Res 2016;50:89-107.
17、Dalkara D, Goureau O, Marazova K, et al. Let There Be Light: Gene and Cell Therapy for Blindness. Hum Gene Ther 2016;27:134-47. Dalkara D, Goureau O, Marazova K, et al. Let There Be Light: Gene and Cell Therapy for Blindness. Hum Gene Ther 2016;27:134-47.
18、Hartong DT, Berson EL, Dryja TP. Retinitis pigmentosa. Lancet 2006;368:1795-809. Hartong DT, Berson EL, Dryja TP. Retinitis pigmentosa. Lancet 2006;368:1795-809.
19、Karl MO, Hayes S, Nelson BR, et al. Stimulation of neural regeneration in the mouse retina. Proc Natl Acad Sci U S A 2008;105:19508-13. Karl MO, Hayes S, Nelson BR, et al. Stimulation of neural regeneration in the mouse retina. Proc Natl Acad Sci U S A 2008;105:19508-13.
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