key: cord-0022378-7spyzgt3
authors: Zhu, Jun; Inomata, Takenori; Di Zazzo, Antonio; Kitazawa, Koji; Okumura, Yuichi; Coassin, Marco; Surico, Pier Luigi; Fujio, Kenta; Yanagawa, Ai; Miura, Maria; Akasaki, Yasutsugu; Fujimoto, Keiichi; Nagino, Ken; Midorikawa-Inomata, Akie; Hirosawa, Kunihiko; Kuwahara, Mizu; Huang, Tianxiang; Shokirova, Hurramhon; Eguchi, Atsuko; Murakami, Akira
title: Role of Immune Cell Diversity and Heterogeneity in Corneal Graft Survival: A Systematic Review and Meta-Analysis
date: 2021-10-12
journal: J Clin Med
DOI: 10.3390/jcm10204667
sha: bf45bf2f1a0ef427b3d8d3fdaa494e8e64e89db7
doc_id: 22378
cord_uid: 7spyzgt3

Corneal transplantation is one of the most successful forms of solid organ transplantation; however, immune rejection is still a major cause of corneal graft failure. Both innate and adaptive immunity play a significant role in allograft tolerance. Therefore, immune cells, cytokines, and signal-transduction pathways are critical therapeutic targets. In this analysis, we aimed to review the current literature on various immunotherapeutic approaches for corneal-allograft rejection using the PubMed, EMBASE, Web of Science, Cochrane, and China National Knowledge Infrastructure. Retrievable data for meta-analysis were screened and assessed. The review, which evaluated multiple immunotherapeutic approaches to prevent corneal allograft rejection, showed extensive involvement of innate and adaptive immunity components. Understanding the contribution of this immune diversity to the ocular surface is critical for ensuring corneal allograft survival.

Corneal transplantation has been proven to be the most effective therapy for corneal disorders such as opacity, keratoconus, corneal degeneration, scarring due to keratitis, trauma, and any physio-pathological changes on the ocular surface [1] [2] [3] . In addition to the appropriate examination of the characteristics of the donor and the tissue [4] , immune privilege plays an important role in the success of corneal transplantation procedures [5, 6] .

Corneal immune and angiogenic privilege [7] is crucial to the success of corneal transplantation and is mainly dependent on resident heterogeneous immune cells, including 2 of 20 dendritic cells (DCs), Langerhans cells (LCs), mast cells, macrophages, T lymphocytes, and regulatory T cells [8] [9] [10] [11] . Additionally, the systemic immune response in certain autoimmune diseases (such as Sjögren's syndrome, systemic lupus erythematosus, and rheumatoid arthritis) affects the homeostasis of the ocular surface immune microenvironment, leading to the loss of corneal avascularity [12, 13] . The underlying mechanism involves various components of the immune system [14] . Consequently, immunological approaches have been introduced to improve corneal graft survival. Conventional prophylaxis, including topical or systemic medications such as corticosteroids, cyclosporine A, and tacrolimus, has been proven to be successful [15] [16] [17] . Although immunosuppressive drugs show promising effectiveness, their side effects such as cataracts, susceptibility to infection, and glaucoma cannot be disregarded [18, 19] . Several studies have been conducted on immunotherapy for corneal transplantation focusing on immune checkpoint inhibitors, human leukocyte antigen (HLA)-matching strategy, and immunomodulatory cytokines [20] [21] [22] . These studies give extraordinary contributions to the management of corneal graft rejections.

In this review, various immunotherapies for corneal transplantation were assessed to explore the effects on different immune cell populations, relative cytokines, and signaling pathways involved in graft survival. The results from this study could represent a guide for further independent studies focusing on alternative immunotherapy strategies for corneal transplantation.

Electronic bibliographic databases including PubMed, EMBASE, Cochrane, Web of Science, and China National Knowledge Infrastructure were used to collect published research papers (from January 1988 to December 2020), by combining the genetic terms. The final formula was as follows: [(corneal transplant) OR (corneal transplantation) OR (corneal grafts) OR (keratoplasty) OR (corneal allografts) OR (corneal graft survival) OR (corneal allograft survival) OR (keratoplasty survival)] AND [(innate) OR (adaptive) OR (immune) OR (innate immune) OR (adaptive immune)]. The design of this study followed the guidelines of the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) protocols [23] . The published languages were limited to English, Chinese, and German. The search results were screened for suitable topics and full articles accessible for systematic review. Full-text articles containing integral data for meta-analysis were collected. The study inclusion and exclusion criteria are presented in Table 1 . Search results were compiled using EndNote X9.3.2 (Clarivate Analytics, Philadelphia, PA, USA). In keeping with the quality standards for reporting systematic reviews and meta-analyses of observational studies [24] , two independent researchers (J.Z. and T.I.) screened the retrieved articles. The same investigators independently assessed the full text of the records that were deemed eligible in consensus. Table 1 . Inclusion and exclusion criteria for meta-analysis.

Study objective: corneal survival or rejection data from murine allogeneic corneal transplantation experiment; various intervention factors were investigated Study design: experimental research using the murine (mice or rat) corneal allograft model, studied using the valid data of experimental and control groups Outcome: evaluation of allograft survival from innate and adaptive immunity perspective, case number, mean survival or rejection days with standard deviation, survival or rejection rate, and follow-up duration

Experimental methods and protocols, reviews, systematic reviews, and conference proceedings 

Two independent reviewers (J.Z. and T.I.) extracted data from each eligible study using a standardized data-extraction sheet and subsequently cross-checked the results. Disagreements between the reviewers regarding the extracted data were resolved through discussion with a third reviewer (Y.O.). The following data were extracted: author's first name, date of publication, details of intervention in the study and control groups, sample size, mean survival or rejection days and standard deviation (SD), follow-up period and main results, and survival or rejection ratio of the mouse or rat corneal allografts. The unit of analysis was corneal allograft.

Analysis was performed using OpenMetaAnalyst version 12.11.14 (available online: http://www.cebm.brown.edu/openmeta/, accessed on 6 October 2021) [25] . The study weight was calculated using the Mantel-Haenszel method. Statistical heterogeneity was assessed using Cochran's Q and I 2 tests. I 2 represents the percentage of total variation across trials, which accounts for heterogeneity. As there was no heterogeneity (I 2 < 50%) among the studies, a fixed-effects model was applied. When I 2 was < 50%, a random-effects analysis was performed.

The articles included in this systematic review were published between 1 January 1988, and 31 December 2020. In total, 1307 studies were selected according to the search strategy, 995 studies were excluded owing to irrelevant titles or topics, and 264 studies with human subjects or other animal models were excluded. Thirty articles were finally included in the meta-analysis ( Figure 1 ). Of these, 11 articles were from the United States [26] [27] [28] [29] [30] [31] [32] [33] [34] [35] [36] , 10 from China [37] [38] [39] [40] [41] [42] [43] [44] [45] [46] , seven from Germany [47] [48] [49] [50] [51] [52] [53] , and one each from France [54] and Portugal [55] . Altogether, 845 corneal allografts were identified in these studies (Table 2) . Twelve studies used a rat allograft model, whereas eighteen studies used a mouse allograft model. Fifteen studies reported the mean survival or rejection days, one study reported median survival days, all thirty studies reported the survival or rejection rate, and one study reported immunoreaction days. 

The 30 studies selected for meta-analysis covered mainstream research directions for immune therapy for corneal transplantation. The number of research papers in descending order were as follows: anti-VEGF therapy (6) > DCs and LCs (6: 3 for each) > IL-1RA (4), CLTA-4 Ig therapy (4) > anti-IL-17 antibody (2), IL-10 (2), anti-CD154 antibody (2), CCR7-CCL19 blockade (2) , and regulatory T cells (2) . Among these immunotherapies, immature dendritic cell intervention presented the longest mean difference in survival time by 14.61 days, and IL-17 had a protective role with a mean difference of 10.98 days. Regulatory T cells also demonstrated a strong promotion for graft privilege with a mean difference of 9.42 days.

The role of CD4 + and CD8 + T cells in alloantigen recognition is implied in the initiation of rejection [56, 57] . In this review, the respective contributions of these two cell subsets in murine corneal-allograft rejection were investigated. Six studies [58] [59] [60] [61] [62] [63] used anti-CD4 antibodies in murine corneal transplantation. While four studies showed that systemic or local administration of anti-CD4 antibodies could reduce the rejection rate, two of these studies [59, 61] reported that anti-CD8 antibody administration did not reduce the rejection rate of corneal allografts. Two other studies [64, 65] examined the role of CD8 + T cells in allograft rejection and found that CD8 + T cell-mediated rejection had a slow tempo and CD8 + T cells were not essential in promoting corneal-graft rejection. Together, these results showed that CD4 + T cells play a major role in allograft rejection.

DCs are potent antigen-presenting cells (APCs) with various subsets and different states. Immature DC attributes were evaluated in relation to corneal allograft tolerance in a total of 65 eyes across three studies [43] [44] [45] . Given immature DC intervention, the mean difference in survival time was significantly prolonged by 14.61 days (95% CI, 8.55 to 20.69; P < 0.001) (Figure 2A ). The role of LCs, a distinct population of DCs, in corneal-allograft rejection was also evaluated; three papers with 146 cases were reviewed [26] [27] [28] . Compared with the control grafts (treated with immature DCs), those with donor-derived LCs exhibited a significantly increased rejection rate (odds ratio (OR) = 4.94 (95% CI, 2.48 to 9.84)) ( Figure 2B ).

DCs are potent antigen-presenting cells (APCs) with various subsets and different states. Immature DC attributes were evaluated in relation to corneal allograft tolerance in a total of 65 eyes across three studies [43] [44] [45] . Given immature DC intervention, the mean difference in survival time was significantly prolonged by 14.61 days (95% CI, 8.55 to 20.69; P < 0.001) (Figure 2A ). The role of LCs, a distinct population of DCs, in cornealallograft rejection was also evaluated; three papers with 146 cases were reviewed [26] [27] [28] . Compared with the control grafts (treated with immature DCs), those with donor-derived LCs exhibited a significantly increased rejection rate (odds ratio (OR) = 4.94 (95% CI, 2.48 to 9.84)) ( Figure 2B ). 

In addition to the predominant effect of T lymphocytes on allograft rejection, the involvement of macrophages in grafted corneas was reviewed. Six studies [66] [67] [68] [69] [70] [71] on the effects of macrophages on corneal-allograft survival were included; their results showed the increased number of macrophages and the production of Th1 cytokines, interferon-γ (IFN-γ), interleukin-2 (IL-2), IL-12, IL-1, tumor necrosis factor-alpha (TNF-α), C-C motif chemokine ligand 3 (CCL3), and inducible nitric oxide synthase (iNOS), which were observed in rejected grafts compared to controls. Macrophages play a role in the early phase of corneal-allograft rejection. Maruyama et al. [66] found that CD11b+ macrophages are critical for the development of inflammation-dependent lymphangiogenesis in the eye. Using macrophage depletion or CD11b-/-or F4/80-/-mouse models could lead to fewer lymphatic vessels and less lymphangiogenesis, providing immune privilege to the grafts. Yamada et al. [71] reported that enhanced graft acceptance might be attributed to the suppression of alloantigen-induced Th1 polarization through the induction of macrophages with reduced intracellular glutathione levels. Together, these results suggest that macrophages are non-negligible components in the immunopathogenesis of corneal graft rejection.

Although numerous immune cells and their cytokine production are involved in the corneal-allograft immune reaction, few studies have generated statistical data for metaanalysis under a unified standard assessment. The representative data analysis is as follows: four studies with a total of 98 cases were included in the assessment of the effect of IL-1 receptor antagonist (IL-1RA) on corneal allografts [37] [38] [39] 42] . The mean survival time was significantly prolonged in the IL-1RA intervention groups compared to the control group, with a mean difference of 3.65 days (95% CI, 2.30 to 5.01, P < 0.001) ( Figure 3A) . 

In addition to the classic T-cell receptor (TCR) and major histocompatibility complex (MHC) interactions that initiate T cell activation, we investigated the function of several representative costimulatory signaling pathways in corneal-allograft survival [40, [47] [48] [49] . For the B7-CTLA-4 interaction, we reviewed four studies including 109 cases [40, [47] [48] [49] . The mean survival time was significantly higher in the CLTA-4 Ig intervention groups than in the control group, with a mean difference of 4.08 days (95% CI, 3.33 to 4.82, P < 0.001) ( Figure 4A ).

For the CD40-CD154 pathway, we reviewed two studies including 116 cases [29, 30] . The survival rates were significantly higher in the anti-CD154 antibody intervention groups than in the control group (OR = 0.05; 95% CI, 0.03 to 0.10; P < 0.001) ( Figure 4B) .

For the C-C chemokine receptor type 7 (CCR7)-CC-chemokine ligand 19 (CCL19) pathway, we reviewed two studies including 58 cases [32, 53] . The survival rates were significantly higher when CCR7-CCL19 was blocked using CCL19 Ig or CCR7-/-mouse models than the survival rate in the control group (OR = 0.30; 95% CI, 0.10 to 0.88; P = 0.028) ( Figure 4C) . Two studies with a total of 40 cases were included in the assessment of the effect of IL-17 on corneal allografts [33, 34] . The mean rejection days were significantly reduced in the anti-IL-17 antibody intervention groups compared to the control group, with a mean difference of 10.98 days (95% CI, 6.01 to 15.94; P < 0.001) ( Figure 3B ). It is suggested that IL-17 may contribute to the immune privilege of corneal allografts.

Six studies with a total of 153 cases were included in the assessment of the effect of vascular endothelial growth factor (VEGF) on corneal allografts [31, 35, 36, 51, 52, 54] . Allograft survival rates were significantly higher in the anti-VEGF intervention groups compared to the control group, with an OR of 4.33 (95% CI, 2.16 to 8.71) ( Figure 3C) .

Two studies with a total of 28 cases were included in the assessment of the effect of IL-10 on corneal allografts [50, 55] . No significant difference was found in the intervention groups compared to the control group. The standardized mean difference was 1.23 days (95% CI, −6.20 to 3.73, P = 0.627) ( Figure 3D ).

In addition to the classic T-cell receptor (TCR) and major histocompatibility complex (MHC) interactions that initiate T cell activation, we investigated the function of several representative costimulatory signaling pathways in corneal-allograft survival [40, [47] [48] [49] . For the B7-CTLA-4 interaction, we reviewed four studies including 109 cases [40, [47] [48] [49] . The mean survival time was significantly higher in the CLTA-4 Ig intervention groups than in the control group, with a mean difference of 4.08 days (95% CI, 3.33 to 4.82, P < 0.001) ( Figure 4A ). 

Tregs are a subset of CD4 + T cells with highly expressed CD4 + CD25 + surface m [72] ; numerous studies have reported their immunosuppressive function in organ plantation. In this review, two papers including thirty-two cases were assessed [ The mean survival time was significantly prolonged in the Treg intervention group pared with that in the PBS control group, with a standard mean difference of 9.4 (95% CI, 4.14 to 14.70; P < 0.001) ( Figure 5 ). 

Immune privilege is critical to the survival of corneal transplants and include phangiogenic and hemangiogenic privilege, which prevents blood and lymphatic v For the CD40-CD154 pathway, we reviewed two studies including 116 cases [29, 30] . The survival rates were significantly higher in the anti-CD154 antibody intervention groups than in the control group (OR = 0.05; 95% CI, 0.03 to 0.10; P < 0.001) ( Figure 4B) .

For the C-C chemokine receptor type 7 (CCR7)-CC-chemokine ligand 19 (CCL19) pathway, we reviewed two studies including 58 cases [32, 53] . The survival rates were significantly higher when CCR7-CCL19 was blocked using CCL19 Ig or CCR7-/-mouse models than the survival rate in the control group (OR = 0.30; 95% CI, 0.10 to 0.88; P = 0.028) ( Figure 4C ).

Tregs are a subset of CD4 + T cells with highly expressed CD4 + CD25 + surface markers [72] ; numerous studies have reported their immunosuppressive function in organ transplantation. In this review, two papers including thirty-two cases were assessed [41, 46] . The mean survival time was significantly prolonged in the Treg intervention groups com-pared with that in the PBS control group, with a standard mean difference of 9.42 days (95% CI, 4.14 to 14.70; P < 0.001) ( Figure 5 ).

survival. (B) Anti-CD154 antibody increases the allograft survival rate. (C) CCR7-CCL19 blockade improves the allograft survival rate. CI, confidence intervals; EV, event; Trt, treatment; Ctrl, control.

Tregs are a subset of CD4 + T cells with highly expressed CD4 + CD25 + surface markers [72] ; numerous studies have reported their immunosuppressive function in organ transplantation. In this review, two papers including thirty-two cases were assessed [41, 46] . The mean survival time was significantly prolonged in the Treg intervention groups compared with that in the PBS control group, with a standard mean difference of 9.42 days (95% CI, 4.14 to 14.70; P < 0.001) ( Figure 5 ). 

Immune privilege is critical to the survival of corneal transplants and includes lymphangiogenic and hemangiogenic privilege, which prevents blood and lymphatic vessels from invading the cornea. This privilege maintains the transparency of corneal tissue, which provides visual functions. During the inflammation process, inflammatory cells and their products such as cytokines and growth factors could be delivered through the blood and lymphatic vessels, leading to the immune rejection. 

Immune privilege is critical to the survival of corneal transplants and includes lymphangiogenic and hemangiogenic privilege, which prevents blood and lymphatic vessels from invading the cornea. This privilege maintains the transparency of corneal tissue, which provides visual functions. During the inflammation process, inflammatory cells and their products such as cytokines and growth factors could be delivered through the blood and lymphatic vessels, leading to the immune rejection.

The process of corneal-allograft survival requires a delicate balance between immune and inflammatory reactions to provide the allografts with relative immune privilege.

T lymphocytes play a central role in the adaptive immune response and thus strongly impact the outcome of allografts [73] . The CD4 + and CD8 + T cell were designated for allorecognition in corneal transplantation [56] . CD4 + T cells have been shown to play a pivotal role in corneal-allograft rejection. In a clinical report, rapamycin, an inhibitor of a serine-threonine protein kinase, mammalian target of rapamycin complex-1, could inhibit effector T cell proliferation and activation; it was found to prevent 78% rejection in the first year during the management of high-risk transplant patients [18] .

As major components of the innate immune system, DCs, neutrophils, macrophages, and natural killer cells are essential for protecting against pathogens and repairing tissue damage [74] . DCs also play an important role in the innate detection of pathogens and activation of the adaptive immune system [75] . Immature DCs (with lower levels of HLA-DR, CD80, CD83, and CD86), including bone-marrow-derived immunosuppressive cells [76] , could induce T-cell tolerance, whereas mature DCs induce T-cell immunity [77] [78] [79] [80] [81] . Immature DCs were found to be associated with longer allograft survival compared with normal controls during the immune response process of corneal transplantation (Figure 2A ) [45] .

Another important type of APC, LCs are bone marrow-derived tissue-resident macrophages [82] . During immune and inflammatory reactions after corneal injury, LCs migrate into the central corneal epithelium along with neutrophils and monocytes [83, 84] and can induce cytotoxic T-cell responses towards donor MHC alloantigens in corneal grafts [85] .

Yamaguchi et al. [86] found a notable up-regulation of the complement activation pathway in corneal transplantation Füst et al. [87] reported that the complement system might be activated both through the classical and alternative pathways in the aqueous humor of the patients with Fuchs' dystrophy. In addition to this, certain scholars have found that the presence of an increased concentration of C1rs-C1inh complex in tear samples [88] , suggests the classical pathway of complement might be activated in the early postoperative period after penetrating keratoplasty. Previously, Zhang X et al. [89] reported that anti-CD45 antibody plus complement-mediated targeting of donor tissue is the most efficient way to deplete corneal passenger leukocytes. More recently, by applying eculizumab, a C5-blockade agent, Islam R et al. [90] introduced a potential therapy for inhibiting xenograft-induced innate inflammatory responses. Despite lacking relevant clinical studies, these data give us new ideas for high-risk corneal transplantation immunotherapeutic strategy.

CCR7 is mainly expressed in activated B and T lymphocytes and can stimulate DC maturation and T-cell homing [91] . The chemokine CCL19 is one of the ligands (the other is CCL21) for CCR7. CCR7 can induce the movement of antigen-specific effector and central memory T cells move to the lymph nodes, followed by CCR7-CCL19 interaction [92] . CCR7-deficient mice show severely delayed kinetics for the antibody response, lack of contact sensitivity, and delayed-type hypersensitivity reactions [93] . Figure 4C shows that blockade of the CCR7-CCL19 axis could prolong mouse corneal-allograft survival. Thus, this blockade could be a potential approach for the manipulation of DC maturation during corneal transplantation.

During secondary signal transduction, the engagement of T cells and APCs depends on the interaction of CD40, which is expressed by B cells and APCs, with the CD40 ligand (CD40L, also known as CD154), which is expressed by activated T cells [94] . CD40 is a 48 kDa transmembrane protein that is initially expressed on B cells, DCs, macrophages, and monocytes, as well as predominantly on corneal limbal epithelial cells [95, 96] . CD154 could be a transmembrane protein or in its soluble form [97] . The engagement of CD40 on the DC surface can promote cytokine production, costimulatory molecule expression, and antigen presentation [98] . However, the inhibition of CD40-CD154 could suppress the secondary signal, consequently reducing allograft rejection, which is consistent with the meta-analysis results in this study ( Figure 4B ).

Another well-known co-stimulatory molecule pathway is the interaction between the B7 (CD80/86) family and CTLA-4. CTLA-4 is a receptor expressed by both CD4+ and CD8+ T cells, which mediates the suppression of T-cell activation. CTLA-4 interacts with CD80 and CD86 on APCs with high affinity and competes with CD28; its interaction with CD80/86 could induce co-stimulation [99] . Experimental data from articles reviewed here showed that CTLA-4 blockade could improve allograft survival ( Figure 4A ). Therefore, CTLA-4 could be used in an immune regulatory mechanism to inhibit the ability of APCs to stimulate naïve T cells.

Recently, owing to its immunosuppressive and tolerogenic properties, programmed death ligand-1 (PD-L1) has drawn scientists' attention as a potential therapeutic target in corneal transplantation. Nosov et al. [100] reported that local PD-L1 gene transfer in cultured corneas prolonged corneal allograft survival and attenuated graft rejection. Hori et al. [8] suggested that PD-L1-induced apoptosis is a mechanism of immune privilege of corneal allografts. Shen et al. [101] emphasized the importance of peripheral tissue-derived PD-L1 in down-regulating local immune responses in allografts. PD-L1 is constitutively expressed on endothelial cells of the cornea, iris-ciliary body, and neural retinal [102] . Sugita et al. reported that human corneal endothelial cells expressing PD-L1 suppress PD-1 + T helper 1 cells via a contact-dependent mechanism [103] . Although there have been no clinical trials on the application of this immune checkpoint inhibitor for corneal transplantation, Dutra et al. [104] reported a successful corneal transplant in a patient treated with Nivolumab for metastatic non-small cell lung cancer and suggested that the treatment with anti-PD1 could not be regarded as an absolute contraindication to corneal transplantation.

IL-1 is an important pro-inflammatory cytokine involved in the initiation of both innate and adaptive immune responses [105] . It has two subtypes: IL-1α and IL-1β. The former mediates the early stages of tissue injury, whereas the latter is responsible for a later inflammatory response [106] . IL-1RA is a suppressor that inhibits IL-1-mediated lymphocyte proliferation. Recombinant IL-1RA specifically inhibits IL-1α and IL-1β activities, and its action has been verified in various inflammatory diseases [107] . In this review, recombinant IL-1RA was found to exhibit the same suppressive effect on allograft rejection ( Figure 3A ). In clinical research, human corneal limbal epithelial cells were cultured on the amniotic membrane stroma and the results showed that the expression of IL-1RA was upregulated [108] . This underlying mechanism offers new ideas for the clinical reduction of ocular surface inflammation after corneal transplantation. IL-17A is mainly produced by Th17 cells, which are a subset of the CD4+ T cell-derived population [109] . IL-17A is a pro-inflammatory cytokine implicated in the pathogenesis of inflammatory and autoimmune diseases [110] [111] [112] . Unlike other pro-inflammatory cytokines, such as IL-1, IFN-γ, and IL-6, IL-17A plays a protective role during acute corneal graft survival. In this review, a meta-analysis of two studies demonstrated that IL-17A depletion using an anti-IL-17A antibody could exacerbate corneal-allograft rejection ( Figure 3B ). However, Yin et al. [113] reported that prophylactic neutralization of IL-17 significantly increased corneal-allograft survival and reversed rejection in the late-term post-engraftment. Other than in the corneal allograft setting, Kwan T et al. [114] reported that IL-17 deficiency or neutralization was protective against graft rejection in a murine kidney allograft model. This suggests that IL-17 has spatiotemporal heterogeneity in corneal transplantation [33, 113, 115] .

Corneal neovascularization is mediated by VEGF [115, 116] ; VEGF-A combined with VEGF receptor 1 and VEGFR-2 can initiate neovascularization. Furthermore, VEGF plays an important pathogenic role in ocular surface disorders [116] [117] [118] . In corneal transplantation, neovascularization is the major cause of graft failure, especially in high-risk corneal grafts [73, [119] [120] [121] . Accordingly, a higher graft survival rate was observed on the use of anti-VEGF antibodies or soluble VEGFR molecules to block this pathway ( Figure 3C ). In clinical practice, anti-VEGF therapies appear to be the most promising approach for corneal neovascularization in grave condition such as high-risk corneal transplantation. Human studies demonstrated that subconjunctival injection of bevacizumab could reduce corneal neovascularization [122] [123] [124] .

Tregs are a subpopulation of a subset of thymus-derived CD4+ T cells that express high levels of IL-2Rα (CD25); they modulate the immune system, maintain a tolerance to self-antigens, and prevent autoimmune diseases [72] . In mice, Tregs express CD25 and the transcriptional regulator forkhead box P3 (FOXP3) [121] . Tregs have been observed to be effective in preventing autoimmune diseases and delaying graft rejection [119, 121, [125] [126] [127] [128] . Although their suppressive function has been reported in mouse models ( Figure 5 ), the expansion of the Treg population continues to be difficult.

There are few clinical trials that use cell therapies or targeted antibodies for prolonging corneal graft survival, demonstrating a large gap between animal research and clinical practice. We collected and analyzed data from clinical reports on inflammatory cytokine levels after human corneal transplantation. Our results showed that TNF-α, IFN-γ, IL-1β, and IL-2 levels in the aqueous humor of keratoplasty rejection cases were much higher than those in cases where the grafts survived [129] [130] [131] [132] [133] (Figure 6 ).

These findings prove that above novel approaches and basic studies conducted in animal models provide promising future perspectives on the application of immunosuppression to improve the outcomes of corneal transplantations. For example, it has been reported that third-party allogeneic mesenchymal stromal cells could prevent rejection in a pre-sensitized high-risk model of corneal transplantation [134] . Moreover, our previous research has revealed the immunoregulatory effect of donor's bone-marrow-derived suppressor cells in a mouse model of high-risk corneal transplantation [76] . These cellular therapies may provide a potential method of dealing with neovascularization and graft rejection. A phase 1b clinical trial led by VISICORT (EudraCT ID is 2018-000890-60) is currently underway to test the safety and feasibility of healthy donor bone-marrow-derived mesenchymal stem cells as an immunotherapy for patients with a high risk of rejection of corneal transplants. Additionally, clinical studies have suggested that anti-VEGF drugs, including bevacizumab and aflibercept, could be a safe and efficient treatment alternative to improve the outcomes of corneal transplantation in patients. Previous reports have demonstrated that anti-VEGF therapy improved graft survival in patients who have undergone penetrating keratoplasty [135] [136] [137] . However, when considering the current immunotherapies for corneal transplantation, the diverse experimental methods in animal models and the lack of clinical trials contribute to the disconnection between basic research and clinical practice. Clinical trials using novel therapeutic strategies are required. the expansion of the Treg population continues to be difficult.

There are few clinical trials that use cell therapies or targeted antibodies for prolonging corneal graft survival, demonstrating a large gap between animal research and clinical practice. We collected and analyzed data from clinical reports on inflammatory cytokine levels after human corneal transplantation. Our results showed that TNF-α, IFN-γ, IL-1β, and IL-2 levels in the aqueous humor of keratoplasty rejection cases were much higher than those in cases where the grafts survived [129] [130] [131] [132] [133] (Figure 6 ). Finally, as in other tissues beyond the eye, the homeostatic equilibrium of the ocular surface is critically maintained by complex and heterogeneous parainflammatory mechanisms [138] [139] [140] . Cross-talk between APCs, T cells, and various other immune cells plays a central role in corneal graft tolerance (Figure 7) . Furthermore, graft retention or graft rejection is not always directly related to immune privilege. Conditions such as trauma, infection, and endothelial corneal dystrophy could be the direct cause of corneal graft failure, altering the parainflammatory homeostatic equilibrium.

This study had certain limitations. Firstly, owing to a lack of data from clinical studies, all selected studies were based on murine allogeneic transplantation models, not humans. Second, studies were selected from the same research groups or had similar publication dates because of the small number of included studies. Third, data availability bias may exist because only graft survival was selected as an outcome, and several studies were excluded because of insufficient survival data for analysis. In addition, these reviews were limited to the penetrating keratoplasty models; other surgeries like Descemet-stripping automated endothelial keratoplasty and Descemet-membrane endothelial keratoplasty were not included. The goal of this study was to summarize a wide range of immunotherapy for corneal transplantation; it was difficult to strictly control various biases. Thus, to address these limitations, further studies are required.

Finally, as in other tissues beyond the eye, the homeostatic equilibrium of the ocular surface is critically maintained by complex and heterogeneous parainflammatory mechanisms [138] [139] [140] . Cross-talk between APCs, T cells, and various other immune cells plays a central role in corneal graft tolerance (Figure 7) . Furthermore, graft retention or graft rejection is not always directly related to immune privilege. Conditions such as trauma, infection, and endothelial corneal dystrophy could be the direct cause of corneal graft failure, altering the parainflammatory homeostatic equilibrium. This study had certain limitations. Firstly, owing to a lack of data from clinical studies, all selected studies were based on murine allogeneic transplantation models, not humans. Second, studies were selected from the same research groups or had similar publication dates because of the small number of included studies. Third, data availability bias may exist because only graft survival was selected as an outcome, and several studies were excluded because of insufficient survival data for analysis. In addition, these reviews 

This review demonstrates that the heterogeneity and diversity of immune response in allograft rejection, which may unveil alternative critical and effective targets for improving corneal transplantation survival. 

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HLA-A,B and DR matching in corneal transplantation

Preferred reporting items for systematic review and meta-analysis protocols (PRISMA-P) 2015: Elaboration and explanation

Meta-analysis of observational studies in epidemiology: A proposal for reporting. Meta-analysis Of Observational Studies in Epidemiology (MOOSE) group

Clinical and Prodromal Ocular Symptoms in Coronavirus Disease: A Systematic Review and Meta-Analysis. Investig. Ophthalmol. Vis. Sci. 2020

The differential effects of donor versus host Langerhans cells in the rejection of MHC-matched corneal allografts

Characteristics of rejection of orthotopic corneal allografts in the rat

Depletion of donor-derived Langerhans cells promotes corneal allograft survival

Blockade of CD40-CD154 costimulatory pathway promotes survival of allogeneic corneal transplants

Effect of locally administered anti-CD154 (CD40 ligand) monoclonal antibody on survival of allogeneic corneal transplants

Inhibition of hemangiogenesis and lymphangiogenesis after normal-risk corneal transplantation by neutralizing VEGF promotes graft survival

Role of CCR7 in facilitating direct allosensitization and regulatory T-cell function in high-risk corneal transplantation

IL-17 promotes immune privilege of corneal allografts

IL-17A-dependent CD4+CD25+ regulatory T cells promote immune privilege of corneal allografts

Vascular Endothelial Growth Factor Receptor 1 morpholino increases graft survival in a murine penetrating keratoplasty model

Soluble vascular endothelial growth factor receptor-3 suppresses allosensitization and promotes corneal allograft survival

Subconjunctival interleukin-1 receptor antagonist inhibits graft rejection following high-risk penetrating keratoplasty in rats

Interleukin-1 receptor antagonist eye drops promoting high-risk corneal allografts survival in rats

SEB combined with IL-1ra could prolong the survival of the rat allografts in high-risk corneal transplantation

CTLA4-FasL protein for the prevention of immune rejection in mouse corneal transplantation

Adoptive transfer of donor corneal antigen-specific regulatory T cells can prolong mice corneal grafts survival

The experimental treatment of corneal graft rejection with the interleukin-1 receptor antagonist (IL-1ra) gene

Mechanism of immune tolerance induced by donor derived immature dendritic cells in rat high-risk corneal transplantation

Tolerogenic dendritic cells suppress murine corneal allograft rejection by modulating CD28/CTLA-4 expression on regulatory T cells

Exogenous IL-10 induces corneal transplantation immune tolerance by a mechanism associated with the altered Th1/Th2 cytokine ratio and the increased expression of TGF-beta

Subconjunctival injection of in vitro transforming growth factor-beta-induced regulatory T cells prolongs allogeneic corneal graft survival in mice

Bulfone-Paus, S. Inhibition of corneal allograft reaction by CTLA4-Ig

Immunomodulation after keratoplasty by CTL4-Ig and anti-CD154 antibodies

Influence of local and systemic CTLA4Ig gene transfer on corneal allograft survival

Effects of local and systemic viral interleukin-10 gene transfer on corneal allograft survival

Inflammatory corneal (lymph)angiogenesis is blocked by VEGFR-tyrosine kinase inhibitor ZK 261991, resulting in improved graft survival after corneal transplantation

Transient postoperative vascular endothelial growth factor (VEGF)-neutralisation improves graft survival in corneas with partly regressed inflammatory neovascularisation

Blockade of CCR7 leads to decreased dendritic cell migration to draining lymph nodes and promotes graft survival in low-risk corneal transplantation

Effects of rat anti-VEGF antibody in a rat model of corneal graft rejection by topical and subconjunctival routes

Interleukin 10 treatment does not prolong experimental corneal allograft survival

The use of CD4 and CD8 knockout mice to study the role of T-cell subsets in allotransplant rejection

CD4+ T cells are critical for corneal, but not skin, allograft rejection

Expression of an anti-CD4 single-chain antibody fragment from the donor cornea can prolong corneal allograft survival in inbred rats

Prolongation of rat corneal graft survival by treatment with anti-CD4 monoclonal antibody

Delay in corneal allograft rejection due to anti-CD4 antibody given alone and in combination with cyclosporin A and leflunomide

Promotion of murine orthotopic corneal allograft survival by systemic administration of anti-CD4 monoclonal antibody

The Effects of Anti-LAP Monoclonal Antibody Down-regulation of CD4+LAP+ T Cells on Allogeneic Corneal Transplantation in Mice

Effect of topically applied anti-CD4 monoclonal antibodies on orthotopic corneal allografts in a rat model

The role of cytotoxic T lymphocytes in corneal allograft rejection

Differential roles of CD8+ and CD8-T lymphocytes in corneal allograft rejection in 'high-risk' hosts

The maintenance of lymphatic vessels in the cornea is dependent on the presence of macrophages

Analysis of macrophage phenotype in rejected corneal allografts

Macrophages play a role in the early phase of corneal allograft rejection in rats

Effect of macrophage depletion on immune effector mechanisms during corneal allograft rejection in rats

Effect of local macrophage depletion on cellular immunity and tolerance evoked by corneal allografts

Promotion of corneal allograft survival by the induction of oxidative macrophages

Regulatory T cell modulation of cytokine and cellular networks in corneal graft rejection

Proangiogenic Function of T Cells in Corneal Transplantation

The biology of innate lymphoid cells

Dendritic cells and other innate determinants of T helper cell polarisation

Ex Vivo-Induced Bone Marrow-Derived Myeloid Suppressor Cells Prevent Corneal Allograft Rejection in Mice

Dendritic cells: Specialized and regulated antigen processing machines

Corneal Tissue From Dry Eye Donors Leads to Enhanced Graft Rejection

Novel immunotherapeutic effects of topically administered ripasudil (K-115) on corneal allograft survival

The resolvin D1 analogue controls maturation of dendritic cells and suppresses alloimmunity in corneal transplantation

Generation of Immature, Mature and Tolerogenic Dendritic Cells with Differing Metabolic Phenotypes

Langerhans cell origin and regulation

Fate of orthotopic corneal allografts in eyes that cannot support anterior chamber-associated immune deviation induction

Immunobiology of Langerhans cells on the ocular surface. I. Langerhans cells within the central cornea interfere with induction of anterior chamber associated immune deviation

Corneal allografts induce cytotoxic T cell but not delayed hypersensitivity responses in mice

Pathological processes in aqueous humor due to iris atrophy predispose to early corneal graft failure in humans and mice

The role of complement activation in the pathogenesis of Fuchs' dystrophy

C1r-C1s-C1inhibitor (C1rs-C1inh) complex measurements in tears of patients before and after penetrating keratoplasty

Depletion of passenger leukocytes from corneal grafts: An effective means of promoting transplant survival?

Combined blockade of complement C5 and TLR co-receptor CD14 synergistically inhibits pig-to-human corneal xenograft induced innate inflammatory responses

Graft Site Microenvironment Determines Dendritic Cell Trafficking Through the CCR7-CCL19/21 Axis

Migratory responses of murine hepatic myeloid, lymphoid-related, and plasmacytoid dendritic cells to CC chemokines

CCR7 coordinates the primary immune response by establishing functional microenvironments in secondary lymphoid organs

A two-step, two-signal model for the primary activation of precursor helper T cells

CD40 expression in normal human cornea and regulation of CD40 in cultured human corneal epithelial and stromal cells

Functions of CD40 on B cells, dendritic cells and other cells

A soluble form of TRAP (CD40 ligand) is rapidly released after T cell activation

CD40/CD154 interactions at the interface of tolerance and immunity

The emerging role of CTLA4 as a cell-extrinsic regulator of T cell responses

Role of lentivirus-mediated overexpression of programmed death-ligand 1 on corneal allograft survival

The function of donor versus recipient programmed death-ligand 1 in corneal allograft survival

B7-H1-induced apoptosis as a mechanism of immune privilege of corneal allografts

Human corneal endothelial cells expressing programmed death-ligand 1 (PD-L1) suppress PD-1+ T helper 1 cells by a contact-dependent mechanism

04-32 Successful Corneal Transplantation in a Patient Treated with Nivolumab for Metastatic Non-Small Cell Lung Cancer

Interleukin-1 in the pathogenesis and treatment of inflammatory diseases

IL-1alpha and IL-1beta recruit different myeloid cells and promote different stages of sterile inflammation

Treating inflammation by blocking interleukin-1 in humans

Suppression of interleukin 1alpha and interleukin 1beta in human limbal epithelial cells cultured on the amniotic membrane stromal matrix

Functional specialization of interleukin-17 family members

IL-17 Augments B Cell Activation in Ocular Surface Autoimmunity

Characterization of IL-17AA and IL-17FF in rheumatoid arthritis and multiple sclerosis

Ablation of IL-17A abrogates progression of spontaneous intestinal tumorigenesis

Anti-IL-17 therapy restricts and reverses late-term corneal allorejection

IL-17 deficiency attenuates allograft injury and prolongs survival in a murine model of fully MHC-mismatched renal allograft transplantation

Kinetics of Angiogenic Responses in Corneal Transplantation

Topical administration of the kappa opioid receptor agonist nalfurafine suppresses corneal neovascularization and inflammation

Corneal lymphangiogenesis facilitates ocular surface inflammation and cell trafficking in dry eye disease

Vascular Endothelial Growth Factor (VEGF) Serological and Lacrimal Signaling in Patients Affected by Vernal Keratoconjunctivitis (VKC)

Management of high-risk corneal transplantation

Angiogenesis and lymphangiogenesis in corneal transplantation-A review

Impaired Function of Peripherally Induced Regulatory T Cells in Hosts at High Risk of Graft Rejection

Therapeutic effect of subconjunctival injection of bevacizumab in the treatment of corneal neovascularization

Subconjunctival bevacizumab for corneal neovascularization

Collagen-based scaffolds with infused anti-VEGF release system as potential cornea substitute for high-risk keratoplasty: A preliminary in vitro evaluation

Harnessing Advances in T Regulatory Cell Biology for Cellular Therapy in Transplantation

Haematopoietic stem cell transplantation for autoimmune diseases

In Vivo Expansion of Regulatory T Cells by Low-Dose Interleukin-2 Treatment Increases Allograft Survival in Corneal Transplantation

A New Immunotherapy Using Regulatory T-Cells for High-Risk Corneal Transplantation

Predicting the risk for corneal graft rejection by aqueous humor analysis

Aqueous humour cytokine profiles after Descemet's membrane endothelial keratoplasty

Soluble CD163 and interleukin-6 are increased in aqueous humour from patients with endothelial rejection of corneal grafts

Simultaneous quantification of 17 immune mediators in aqueous humour from patients with corneal rejection

Distinct cytokine pattern in aqueous humor during immune reactions following penetrating keratoplasty

Third-Party Allogeneic Mesenchymal Stromal Cells Prevent Rejection in a Pre-sensitized High-Risk Model of

Three-year corneal graft survival rate in high-risk cases treated with subconjunctival and topical bevacizumab

Avastin use in high risk corneal transplantation

Antiangiogenic therapy in high-risk keratoplasty

InflammAging at Ocular Surface: Clinical and Biomolecular Analyses in Healthy Volunteers

Pathological conversion of regulatory T cells is associated with loss of allotolerance

Variable Responses to Corneal Grafts: Insights from Immunology and Systems Biology

The authors thank all members of the Department of Ophthalmology, Juntendo University Graduate School of Medicine, for providing critical comments on this manuscript.

The authors declare no conflict of interest.