Abstract
Antibody-based blocking of vascular endothelial growth factor (VEGF) reduces choroidal neovascularization (CNV) and retinal edema, rescuing vision in patients with neovascular age-related macular degeneration (nAMD). However, poor response and resistance to anti-VEGF treatment occurs. We report that targeting the Notch ligand Jagged1 by a monoclonal antibody reduces neovascular lesion size, number of activated phagocytes and inflammatory markers and vascular leakage in an experimental CNV mouse model. Additionally, we demonstrate that Jagged1 is expressed in mouse and human eyes, and that Jagged1 expression is independent of VEGF signaling in human endothelial cells. When anti-Jagged1 was combined with anti-VEGF in mice, the decrease in lesion size exceeded that of either antibody alone. The therapeutic effect was solely dependent on blocking, as engineering antibodies to abolish effector functions did not impair the therapeutic effect. Targeting of Jagged1 alone or in combination with anti-VEGF may thus be an attractive strategy to attenuate CNV-bearing diseases.
Similar content being viewed by others
Introduction
Age-related macular degeneration (AMD) is a leading cause of vision loss worldwide. There are two types of AMD; the “dry” and the “wet” forms. Wet, or neovascular AMD (nAMD), is usually preceded by dry AMD, and is characterized by choroidal neovascularization (CNV) breaching the choroid-retinal barrier. This causes leakage and hemorrhaging into the retina, leading to photoreceptor death. CNV is responsible for the majority of severe vision loss in AMD and may progress to legal blindness if left untreated1. 8.7% of the global population aged between 45-85 years have AMD to date, of which ~5% have the wet form2. While the underlying mechanisms of nAMD development are unclear, inflammation is a critical component, and CNV lesions are infiltrated by immune cells such as T cells and phagocytes3,4,5,6.
Treatment of nAMD with anti-vascular endothelial growth factor (VEGF) antibody-based therapeutics by intravitreal (IVT) injections reduces neovascularization, inflammation, edema, and bleeding7. However, some patients show no or only limited therapeutic effect to anti-VEGF treatment8,9. Also, the effect can decline with time, and continuous VEGF blockade may even be toxic to ocular cell types and detrimental to retinal tissue, as VEGF maintains homeostatic functions in ocular physiology10,11,12,13,14. As nAMD is a chronic disease requiring sometimes lifelong monitoring and treatment, this is a problematic aspect of anti-VEGF-based treatment. Thus, there is a need for alternative treatment options based on identification of new targets or the use of combinatorial treatment to enhance the efficacy of VEGF blockade8,15,16.
Vascular endothelial cells are central in angiogenesis and the initiation and amplification of inflammatory responses. Even though their role in recruiting leukocytes to inflammatory lesions is well characterized, control of their response to inflammatory mediators and angiogenic factors is incompletely understood17. Importantly, the Notch signaling pathway enables inflammation through interaction with the NF-κB pathway18, and results in production of pro-inflammatory cytokines, like tumor necrosis factor alpha (TNF-α), interleukin-1 beta (IL-1β) and Toll-like receptor agonists. As such, inhibition of Notch signaling ameliorates experimental arthritis, acute colitis, acute lung injury and graft-versus-host disease19. At the cellular level, Notch signaling affects the functions of both endothelial and immune cells and, can act pro- or anti-angiogenic in a context-dependent manner20,21,22. For example, Notch ligand Delta-like 4 (DLL4) inhibits tip cell formation during VEGF-induced sprouting angiogenesis and promotes endothelial cell quiescence23,24,25. Like DLL4, Jagged1 is a membrane-bound protein with epidermal growth factor (EGF)-like repeats26. However, Jagged1 acts as an unambiguous pro-angiogenic factor through its relation to DLL425,27, and as such stimulates angiogenesis during development25, wound-healing28 and tumor angiogenesis29. Thus, Notch ligands are promising therapeutic targets in several cancer types30.
Here, we report that a monoclonal antibody targeting Jagged1 reduces CNV development in an experimental mouse model by decreasing lesion size, the numbers and reactivity of associated mononuclear phagocytes and the levels of pro-inflammatory cytokines. Furthermore, we demonstrate that Jagged1 expression in human endothelial cells is independent of VEGF stimuli. When we simultaneously targeted Jagged1 and VEGF by monoclonal antibodies in the CNV mouse model, the effect surpassed that of sole targeting of either factor. At last, we show that the therapeutic effect of targeting Jagged1 is solely dependent on target blockade, as engineering for lack of antibody effector functions did not impair the effect. Hence, we reveal that Jagged1 is an attractive target in CNV pathogenesis, which can be targeted alone or in combination with anti-VEGF to attenuate CNV-bearing retinal disorders.
Results
Rationale for targeting Jagged1
We hypothesized that Jagged1 is a relevant target in nAMD. This was based on several lines of evidence. First, we identified Jagged1 in mouse eyes in a relevant disease setting. This was done by taking advantage of a mouse model of nAMD where CNV was induced by laser injury of C57BL/6 J mice (Fig. 1a). Jagged1 staining was clear in CNV lesions on RPE-choroid-sclera flat mounts from mice 10 days after laser treatment, where it co-localized with the endothelial cell marker intercellular adhesion molecule-2 (ICAM-2; Fig. 1b), neuron-glial antigen 2 (NG2) on pericytes (Fig. 1c)31 and ionized calcium-binding molecule-1 (IBA-1) on macrophages (Fig. 1d)15,31,32,33. All antibodies used for staining are listed in Supplementary table 1.
Second, to address the translatability of Jagged1 in an ocular setting, we showed by immunohistochemistry on postmortem human eyes with anatomical signs of dry AMD by means of subretinal drusen deposits and retinal pigment epithelium (RPE) changes, that Jagged1 is occasionally expressed by the inner endothelial cell layer of choroidal blood vessels. In addition, endothelial staining of Jagged1 was detected in vessels of different sizes in choroidal vascular layers, but also in the middle and outer layers of arteries (Fig. 1e). Similar immunoreactivity was observed in normal ocular tissue of human eyes (Fig. 1f).
Third, we assessed the relationship between Jagged1 expression and VEGF signaling by stimulating confluent, serum-starved human umbilical vein endothelial cells (HUVECs) with VEGF (Fig. 1g-j). While DLL4 is induced by VEGF as a negative feedback regulator in endothelial cells23,34, Jagged1 is rather upregulated by inflammatory cytokines21. Protein expression was addressed by Western blotting, which revealed that indeed, VEGF stimuli increased DLL4 expression (Fig. 1g-h). This response was VEGF-specific, evident by its absence in the presence of the VEGF-blocking monoclonal antibody bevacizumab (Fig. 1i, j). Notably, increasing concentrations of VEGF did not affect Jagged1 expression under any of the tested conditions (Fig. 1g-j). This was also the case when performing without serum-starvation (Supplementary Fig. 1), demonstrating that the findings were not affected by growth factors in the culturing medium. Thus, the data support that Jagged1 expression in endothelial cells is independent of VEGF signaling.
Taken together, this provided a rationale for therapeutic targeting of Jagged1 in the laser-induced CNV disease model.
Anti-JAG1 inhibits CNV formation and reduces vascular leakage
To study the effects of Jagged1 targeting in the laser-induced CNV mouse model, we used a phage-display selected mouse immunoglobulin G2a (mIgG2a) antibody (anti-JAG1.b7035, hereafter referred to as anti-JAG1). A monoclonal mIgG2a with irrelevant specificity was used as a control. 5 mg/kg of each of antibody was injected intraperitoneally (IP) after laser treatment at day 0 (D0) and day 5 (D5) (Fig. 2a). The central parameters to assess treatment efficacy in the CNV model are reduction in vascular leakage and lesion size. Vascular leakage was assessed by fundus fluorescein angiography (FFA), performed using a Micron IV imaging system at D5 and D10 (Fig. 2a). Treatment with anti-JAG1 significantly reduced the fluorescent area 10 days after laser injury, while the control antibody did not (Fig. 2b-f). As scar size may correlate with fluorescent area, this also indicated an effect of anti-JAG1 on lesion size.
Next, we sought to determine whether targeting Jagged1 can reduce CNV lesion size (Fig. 2g–k). Mice were euthanized at D10, and following enucleation and dissection, CNV area was measured by immunofluorescence staining for ICAM-2, which is the most effective means of identifying CNV in this model36. ICAM-2 was clearly detected in lesions (Fig. 2h–j). Anti-JAG1 suppressed laser injury-induced CNV, resulting in a ~40% reduction in CNV area compared to the antibody control (Fig. 2k). This phenotype was also seen using another anti-mouse Jagged1 monoclonal antibody from hamster (Fig. 2k; clone HMJ1-2937). As expected, repeating the experiment with an anti-mouse VEGF mIgG2a antibody (anti-VEGF B20-4.1.1, referred to as anti-VEGF hereafter) reduced CNV size by 80% (Fig. 2l). In conclusion, Jagged1 blockade actively reduced lesion size after laser-induced CNV formation.
Jagged1 blockade reduces production of inflammatory mediators
Jagged1 expressed by endothelial cells has been shown to be a potent pro-angiogenic regulator25. In the context of the laser-induced CNV model, inflammatory cells, and in particular mononuclear phagocytes, are known to be potent initiators of the angiogenic process partly through their capacity to release pro-angiogenic factors38,39,40. Therefore, we assessed how anti-JAG1 treatment affected the inflammatory profile following CNV induction.
Fluorescence microscopy analysis on RPE-choroid-sclera flat mounts was used to assess the number of IBA-1-positive mononuclear phagocytes within and around the CNV lesion (Fig. 3a). This revealed clear IBA-1 staining in lesions after treatment with control IgG (Fig. 3b). We addressed the phagocytic profile by counting the total number of IBA-1 positive cells in lesions, and by characterizing their activation status by classifying them as either ramified or ameboid. While resting mononuclear cells show a distinct ramified morphology (Fig. 3c), activated cells retract their protrusions and acquire an ameboid shape (Fig. 3d39). After Jagged1 blockade, IBA-1 staining was reduced (Fig. 3e), which was mirrored by a significant 60% reduction in total number of IBA-1 positive cells (Fig. 3f). Furthermore, Jagged1 blockade resulted in a 2.0-fold higher fraction of ramified cells (Fig. 3g), and a 3.9-fold lower fraction of ameboid cells (Fig. 3h). To address the objectivity of these findings, the total area of IBA-1 specific fluorescence in lesions was quantified in image J, which confirmed a significant reduction after Jagged1 blockade (Fig. 3i). Manual quantifications were confirmed by independent counting and characterization of IBA-1 positive cells by a second observer (Supplementary Fig. 2a–c).
Next, we used a multiplex assay to assess the levels of pro-inflammatory cytokines and chemokines in the retina and choroid-sclera 4 days after laser treatment. Anti-JAG1 reduced retinal concentrations of the inflammatory chemokines CX3CL1 (fractalkine) and CXCL16 along with the pro-inflammatory cytokine TNF-α, indicating an anti-inflammatory effect of Jagged1 blockade (Fig. 3j–l). Concentrations of various pro-inflammatory cytokines and chemokines in the retina and choroid-sclera are shown in Supplementary Fig. 3.
To understand whether the reduction in CNV-associated mononuclear phagocytes was a direct anti-inflammatory effect or a consequence of reduced neovascularization, we tested anti-JAG1 in a non-angiogenic eye model of inflammation—the light-induced retinal degeneration model (LIRD; Fig. 4a)41. In this model, isolectin B4 was used as a phagocytic marker. This was deemed a feasible approach, as staining for isolectin B4 together with IBA-1 in both retinal and RPE-sclera flat mounts demonstrated intense colocalization in non-vessel structures (Supplementary Fig. 2d–f). Although isolectin B4 is largely employed to identify endothelial cells, it also detects activated microglia both in rodents and humans42. Because the isolectin B4 staining gave such a strong signal intensity and vessels could easily be discerned from other cells, we chose it for quantification of signal intensities in images taken at low (×10) magnification. There was a tendency towards more microglia in RPE-choroid-sclera complexes (Fig. 4b, d) and less in retinal flat mounts after anti-JAG1-treatment (Fig. 4e–g), but no significant difference between anti-JAG1-treated mice and control mice was observed (Fig. 4d, g).
A consequence of light-induced retinal damage is apoptosis and a decrease in the number of cells over the entire retina, in particular the outer nuclear layer (ONL)43. We therefore measured and compared ONL thickness, including the ONL/inner nuclear layer (INL) ratio to normalize ONL thickness given the variations that may occur due to obliquity in tissue sectioning, as well as TUNEL quantification. Briefly, this revealed similar results for control IgG-treated (Fig. 4h–j) and anti-JAG1-treated mice (Fig. 4k–m), with no significant differences (Fig. 4n–p).
To corroborate our findings, we also tested anti-JAG1 in the delayed-type hypersensitivity model for human allergic contact dermatitis (Supplementary Fig. 2g–k)44. This is a model for an acute inflammatory response in the ear skin, characterized by dermal edema and leukocyte infiltration. Anti-JAG1 inhibited ear swelling at 24 hours (Supplementary Fig. 2h, i), which could reflect an effect on vascular permeability, but we observed no significant difference in the number of IBA-1-positive cells between anti-JAG1-treated mice and control mice (Supplementary Fig. 2j, k). Together, these findings suggest that Jagged1 blockade neither protects against light-induced photoreceptor cellular apoptosis nor directly affects mononuclear phagocyte recruitment and/or activation.
Jagged1 expression in CNV lesions and retinal vascular morphology is not affected by Jagged1 blockade
Therapeutic targeting of the Notch signaling pathway may have toxic effects on target-expressing tissues45. While this effect is notably less prominent for ligand-specific Notch modulation than for receptor or pan-Notch blockade45,46, antibody-induced target degradation or toxicity to retinal tissues could be a hurdle for clinical implementation of Jagged1 blockade in nAMD. To address this, we visualized the amount of Jagged1 found in CNV lesions after antibody treatment (Fig. 5a). Briefly, we found that neither the control IgG (Fig. 5b), anti-JAG1 (Fig. 5c) nor anti-VEGF (Fig. 5d) affected the colocalization of the endothelial marker ICAM-2 and Jagged1. Quantification revealed no significant alterations of Jagged1 levels after antibody treatment relative to control IgG (Fig. 5e, f).
Next, we addressed the effects of Jagged1 blockade on retinal vascular morphology and endothelial cell proliferation (Supplementary Fig. 4). By staining retinal flat-mounts with isolectin B4 (Supplementary Fig. 4a–c) and analyzing the resulting images with AngioTool Software (Supplementary Fig. 4d–f), we found that neither Jagged1 nor VEGF blockade significantly altered retinal vascular morphology. Furthermore, neither of the antibody treatments impaired endothelial cell proliferation, as evident by crystal violet staining of HUVEC cultures in both the presence and absence of VEGF stimuli (Supplementary Fig. 4m, n). Interestingly, addressing cytotoxicity by means of measuring release of lactate dehydrogenase (LDH) in culture revealed that in the presence of VEGF, anti-VEGF but not anti-JAG1 increased cytotoxicity of HUVECs (Supplementary Fig. 4o).
Furthermore, as we previously found that not only ocular endothelial cells, but also pericytes express Jagged1, we investigated the effects of Jagged1 blockade on pericyte coverage of retinal vessels (Supplementary Fig. 5). We did this by visualizing the extent and vicinity of isolectin B4 (marking endothelial cells) and NG2 (marking pericytes) in retinal flat-mounts from mice treated with either control IgG (Supplementary Fig. 5a) or anti-JAG1 (Supplementary Fig. 5b). Quantification revealed that Jagged1 blockade did not significantly affect pericyte coverage (Supplementary Fig. 5c).
Taken together, these findings strongly suggest that the observed effects of Jagged1 blockade in the CNV model are due to target blockade, not degradation, and that blockade is not toxic to retinal vascular tissue.
Jagged1 blockade results in upregulation of DLL4 in endothelial cells in CNV lesions
The physiological effects of Jagged1 signaling are closely linked to the opposing Notch ligand DLL425, forming a ligand pair with pathological implications in retinal disorders such as diabetic retinopathy47.
As a general rule, DLL4/Notch signaling restricts sprouting angiogenesis and promote endothelial quiescence23,24,25.
To address whether the observed effects of Jagged1 blockade could be related to DLL4 signaling, we visualized DLL4 expression in CNV lesions following antibody treatment (Fig. 6a). By immunohistochemical staining for ICAM-2 and DLL4, we found that DLL4 localizes to endothelial cells in control mice (Fig. 6b). Jagged1 blockade resulted in a markedly higher signal for DLL4 (Fig. 6c). A similar increase was not seen after VEGF blockade (Fig. 6d). Quantification of DLL4 and ICAM-2 positive area revealed a 7-fold upregulation of DLL4 after Jagged1 blockade, relative to control IgG (Fig. 6e). Interestingly, this increase in DLL4 was specific to endothelial cells, as similar effects were not observed in areas without ICAM-2 expression (Fig. 6f). Instead, anti-JAG1 and, to a larger extent, anti-VEGF caused a tendency towards reduced DLL4 expression in non-endothelial cells.
To understand whether these effects could relate to the VEGF response that drives nAMD, we next addressed the effects of Jagged1- and DLL4 signaling on the VEGF response in endothelial cells. We did this by capturing Jagged1 and DLL4 in an oriented manner in a cell culture plate before culturing HUVECs in the presence or absence of VEGF, then analyzing the cellular expression of VEGFR2 by Western blot (Fig. 6g). This demonstrated that in the presence of VEGF, DLL4 signaling reduced VEGFR2 levels by ~70% (Fig. 6h).
VEGF is a potent driver of vascular permeability, and as such, DLL4-mediated desensitization to VEGF could reduce edema following Jagged1 blockade. Alternatively, Jagged1 blockade could alleviate vascular leakage by increasing the expression of cellular junction proteins, such as VE-cadherin and ZO-1. To address this, we visualized VE-cadherin (Supplementary Fig. 6) and ZO-1 (Supplementary Fig. 7) in CNV lesions following antibody treatment. In general, VE-Cadherin and ZO-1 immunoreactivity was faint or barely detectable in all CNV lesions. We observed no apparent difference in neither VE-Cadherin nor ZO-1 expression levels or distributions between control IgG-, anti-JAG1- or anti-VEGF-treated mice.
Taken together, these findings suggest that an upregulation of DLL4 in endothelial cells, and consequently a desensitization of endothelial tissue to VEGF, could be part of the mechanism by which Jagged1 blockade elicit its effects in CNV.
Dosing of anti-JAG1 for persistent circulatory antibody levels
In contrast to soluble VEGF, Jagged1 is membrane-bound and expressed in several tissues26. As such, it may act as an antigen-sink upon antibody injection, which would require tailoring of antibody dosing for long-term therapeutic effect48. To assess this, we measured the plasma half-life of anti-JAG1 and anti-VEGF through a dose titration range of 5.0 (HI), 0.5 (MID), and 0.05 (LO) mg/kg in laser-treated C57BL/6 J mice (Fig. 7a). A control group of untreated mice injected with the HI dosage was included. The results revealed that the plasma half-lives of anti-JAG1 and anti-VEGF were comparable, both in the presence and absence of induced CNV at 5.0 mg/kg (4.4 vs 5.1 days in non-CNV, respectively, 4.5 vs 4.9 days following laser treatment) (Fig. 7b, d). In contrast, at 0.5 mg/kg, the plasma half-life was estimated to be ~1.5-fold shorter for anti-JAG1 than anti-VEGF (Fig. 7b, d). Furthermore, anti-JAG1 was present at 1.7-1.9-fold higher amounts than anti-VEGF after 24 hours in the both the HI and MID groups, while in the LO groups we could only detect anti-VEGF at levels <5 nM (insufficient for half-life calculation) (Fig. 7c). Thus, a larger amount of anti-JAG1 was cleared from circulation following the initial distribution phase. Taken together, the data suggest that at lower dosages, anti-JAG1 has a higher clearance rate than anti-VEGF, in line with an antigen-sink effect, which can be overcome at higher dosages.
Combined Jagged1 and VEGF targeting enhances therapeutic outcome
Based on the finding that VEGF signaling is independent of Jagged1 expression, we investigated whether simultaneous blockade could elicit additive effect in the CNV model. Due to the dramatic effect of 5 mg/kg anti-VEGF (Fig. 2l), we reduced the dosage to 0.5 mg/kg and gave it in combination with 5 mg/kg anti-JAG1 at both D0 and D5 (Fig. 8a). This was chosen as a feasible approach, as 0.5 mg/kg anti-VEGF yielded detectable levels in circulation up to 72 hours after injection (Fig. 7b). While treatment with only 0.5 mg/kg anti-VEGF or 5 mg/kg anti-JAG1 reduced CNV lesion size by ~53% and ~73%, respectively, combined treatment resulted in a ~86% decrease (Fig. 8b). This additive effect highlights Jagged1 as an attractive target for treatment of CNV.
The effect of Jagged1 targeting is not dependent on antibody effector functions
Upon binding to target cells, monoclonal IgG antibodies can engage effector molecules, such as Fcγ receptors (FcγRs) and C1q. This may lead to activation of immune cells via effector functions that results in signaling events, phagocytosis or induction of cytotoxicity. Such effects may contribute to the therapeutic effect or be detrimental to ocular tissue in neovascular diseases, as has been observed in case of anti-VEGF therapeutics in AMD models and clinical settings49,50,51. In this study, we used mIgG2a antibodies, which are very potent inducers of Fc-mediated effector functions52. As such, we sought to determine whether the therapeutic effect was dependent upon effector functions.
To address this, we produced Fc-engineered variants of anti-VEGF and anti-JAG1 where three amino acid substitutions (P329G, L234A, and L235A (PGLALA)) were introduced in the CH2 domain of the Fc. These substitutions are expected to abolish binding to C1q and all FcγRs53. Following production in adherent human embryonal kidney (HEK)293E cells, size-exclusion chromatography (SEC) and SDS-PAGE analyses gave rise to pure monomeric fractions that bound recombinant mouse Jagged1 and VEGF in ELISA in a manner comparable to their WT counterparts (Supplementary Fig. 8) As expected for mIgG2a, the WT antibodies bound strongly to the four mouse FcγRs as well as the neonatal Fc receptor (FcRn), a regulator of IgG transport and plasma half-life54,55 (Supplementary Fig. 9). In contrast, the PGLALA-engineered antibodies did not bind the mouse FcγRs, but equally well to mouse FcRn (Supplementary Fig. 9).
Finally, we compared the PGLALA-engineered variants of anti-JAG1 and anti-VEGF in vivo with the WTs by IP injection (5 mg/kg) at D0 and D5 after laser treatment in the CNV mouse model (Fig. 8a). The PGLALA-engineered variants yielded a non-significant reduction of CNV size compared to WT anti-JAG1, in contrast to the ~threefold reduction for the anti-VEGF antibody (Fig. 8c). Thus, the therapeutic effect of Jagged1 blockade did not require immune effector functions.
Discussion
It has been estimated that 5–15% of nAMD patients are non- or poor responders to current antibody-based anti-VEGF treatment and develop worsened visual acuity, or stationary or increased retinal edema despite monthly injections56,57. In addition, some patients develop treatment resistance over time8. While pathologically high levels of VEGF are a key factor, there are also other aspects of angiogenesis in CNV formation and exudation that drive the disease58. As such, other pro-angiogenic factors may be attractive targets in strategies to rescue loss of vision in patients that do not respond satisfactory to anti-VEGF. There are currently several strategies in the clinical pipeline aiming at providing new treatment options by combinatory targeting of angiogenic signaling59,60, and a bispecific IgG1 antibody harboring specificity for both VEGF and angiopoietin-2 (faricimab) was recently approved by the FDA to treat diabetic macular edema and AMD15,61,62. The rationale for targeting angiopoietin-2 is that its upregulation has been shown to destabilize endothelial cell layers, which leads to fluid leakage and makes the cells more responsive to VEGF63.
Here, we propose an alternative strategy to treat nAMD by specific blocking of the Notch ligand Jagged1 by a monoclonal antibody, either alone or in combination with anti-VEGF. We demonstrated the advantage of targeting Jagged1 by the use of an experimental laser-induced mouse CNV model, which upon anti-JAG1 treatment resulted in reduced inflammation, vascular growth, and CNV lesion size as well as immune cell recruitment and activation, which could relate to the activating role of Jagged1-Notch signaling on microglial phagocytosis64. Supported by in vitro cellular data, we also demonstrated that the anti-JAG1 effect was independent of VEGF. In addition, with no discernable effects in a non-angiogenic inflammatory model, and only modest reduction in cytokine and chemokine levels in the retina and the choroid-sclera, the underlying mechanisms of our findings are likely more related to inhibition of angiogenesis than inflammation We found that Jagged1 blockade did not alter Jagged1 expression, but led to upregulation of DLL4 in endothelial cells in CNV lesions. Because Jagged1 may act as a partial antagonist to DLL425, Jagged1 blockade can augment DLL4-Notch1 signaling, which in turn increases DLL4 expression65. Hence, we postulate that the therapeutic effect of Jagged1 blockade could be at least in part explained by DLL4-mediated desensitization to pathological angiogenic signaling. Such a mechanism is in line with our cellular data, showing that stimulation of endothelial cells with DLL4 and VEGF results in reduced VEGFR2 expression, and with other demonstrations of DLL4 regulating angiogenic sprouting and inhibiting VEGF-induced endothelial cell responses23,24. While targeting of Jagged1 reduced CNV formation in vivo, the therapeutic effect was further enhanced by simultaneous administration of the anti-VEGF antibody. As such, anti-JAG1 may be given as monotherapy or as combinatory therapy together with anti-VEGF.
To our knowledge, this is the so far only report on Jagged1 targeting by a monoclonal antibody in the experimental CNV model. As expected, the effect was dependent on dosage of the anti-JAG1 and anti-VEGF antibodies. When the two antibodies were given at a high dose (5 mg/kg) alone, the effect of anti-VEGF treatment on CNV formation was more pronounced than when only anti-JAG1 was given. However, when we combined a 10-fold lower dose of anti-VEGF with a high dose of anti-JAG1, the treatment ultimately resulted in CNV size to near normal. The data suggest that Jagged1 antagonism may be a strategy to treat nAMD patients with treatment resistance to anti-VEGF monotherapy. Potentially, it may also be a relevant therapeutic target for other ocular diseases driven by neovascularization, but this remains to be investigated.
In contrast to our data, Ahmad et al. reported that the severity of laser-induced CNV in rats could be reduced by a small peptide corresponding to a region within the DSL domain of Jagged166. This would indicate that Jagged1 signaling has the opposite effect than shown herein. However, since the effect of Jagged1 is to inhibit DLL4-Notch1 signaling through weakening the ability of DLL4 to activate Notch167, this peptide may function as an activator of Notch rather than the ligand Jagged1 in situ. This view is supported by findings that a recombinant Notch1-trap to block Jagged1 reduces vascular permeability47, and has anti-angiogenic effects on both retinal and tumor angiogenesis68. Alternative strategies to target Jagged1-related effects in CNV could be either pan-Notch inhibition or by DLL4-mimicking peptides. However, pan-Notch inhibition by for example gamma secretase inhibitors may intensify the angiogenic response to laser injury66,69, and while DLL4-mediated Notch activation may inhibit CNV, myeloid Notch activation may actually drive CNV70,71. Thus, we assume Jagged1 to be a less ambiguous target than DLL4 and specific blocking through antibodies to be a suitable approach compared to pan-Notch strategies.
Reduced vascular leakage is a perhaps particularly important aspect of Jagged1 antagonism, as chronic edema causes permanent damage to retinal photoreceptors. Others have found Jagged1 blockade to increase extravasation in animals with dermal wounds28, and it may increase vascular permeability in other inflammatory conditions like contact dermatitis. Our findings that antibody blockade of Jagged1 reduced ear-swelling in the contact hypersensitivity model, as well as reduced vascular leakage in CNV as evaluated by FA, indicates an anti-leakage effect of Jagged1 blockade. Recent reports that Notch1-signaling prevents leakage supports this72,73. While we did not find Jagged1 blockade to reinstate the cellular junction proteins ZO-1 or VE-cadherin in CNV, the anti-leakage effect could be related to DLL4-mediated non-canonical Notch signaling or a decrease in VEGFR2 levels72,73. Others have found signaling through VEGFR2 to facilitate edema in models of diabetic retinopathy, which may relate to Jagged1-mediated signaling47,74. Notably, anti-JAG1 reduced retinal concentrations of the pro-inflammatory cytokine TNF-α after CNV induction, indicating an anti-inflammatory effect of Jagged1 blockade. TNF-α increases during CNV75, promotes angiogenesis and vascular permeability, and is known as a potent inducer of endothelial Jagged1 expression through NF-κB25,76. Thus, some of the ability of anti-JAG1 to attenuate CNV might be related to interruption of a feed-forward interaction between TNF-α and Jagged1.
The mouse anti-JAG1 mIgG2a antibody used (anti-JAG1.b70) binds strongly to the mouse ligand with a KD of 6 nM35. It fully discriminates between Jagged1 and Jagged2 and inhibits signaling through NOTCH1, −2 and −3. Importantly, the phage-display selected antibody also binds human Jagged1, and 7.5-fold stronger than the mouse counterpart (KD of 0.79 nM). Structurally, a solved co-crystal structure of the Fab fragment of specifically anti-JAG1.b70 in complex with a recombinant soluble form of human Jagged1 has revealed that it binds in an area located between the EGF-1 and Delta-Serrate-Lag DSL domains of Jagged1 (PDB structure 5BO1).
Observations that anti-VEGF antibody-based therapeutics, such as aflibercept and bevacizumab, in complex with VEGF may facilitate platelet aggregation and thrombocyte activation through FcγRIIa in both human and transgenic murine model systems, highlights the importance of considering Fc-mediated effector functions in an ocular setting50,51. As Jagged1 is membrane-bound, anti-JAG1 may cross-bind Jagged1 ligands and potentially initiate unwanted Fc-mediated side-effects by engaging of FcγR expressing immune cells. If the therapeutic outcome is solely dependent on blockade, and independent of effector functions, the constant Fc part can be engineered to be effector-negative. This will then reduce the risk of adverse events15. In our study, we addressed this by comparing the WT anti-JAG1 with an Fc-engineered version with three amino acid substitutions (PGLALA)53. Our results revealed that reduction of CNV size only requires blocking of Jagged1. As such, a humanized version could be made by combining anti-Jagged binding Fab with an effector function silenced Fc or an alternative scaffold. Notably, the PGLALA-substitutions do not affect the ability of the Fc to interact in a pH-dependent manner with FcRn, which regulates plasma half-life and transcellular transport54,55,77. Preventing the interaction with FcRn may however also be beneficial in a clinical setting to minimize systemic exposure following intravitreal injection15,78. Surprisingly, PGLALA anti-VEGF exhibited an increased therapeutic effect on lesion size compared to the WT antibody in our model. This suggests a possible effector-related impairment on anti-VEGF approaches, and is in line with PGLALA being present in the aforementioned faricimab.
Furthermore, our study centers on a mouse in vivo model where antibodies were administrated by IP injection. This is in contrast to a clinical setting where antibody-based therapeutics are given by intravitreal injections (IVTs), in which the aim is for the antibody design to retain high ocular concentrations while minimizing systemic exposure78,79,80. However, accurate interpretation and translation of pre-clinical studies must take into consideration how the therapeutics are administrated as well as cross-species differences that may affect the outcome52,81,82,83. One challenge is that IVTs in mice are notoriously difficult due to anatomical challenges. To translate our encouraging findings on Jagged1 targeting into clinical practice, the concept must be tested in established larger-animal models for laser-induced CNV and IVTs, preferably in non-human primates, which are extensively used for preclinical evaluation15,84,85,86,87.
Methods
Animals
Care, use, and treatment of experimental animals were in strict agreement with the ARVO Statement for the Use of Animals in Ophthalmic and Vision Research. Female C57BL/6 J mice (8–10 weeks old; Janvier Laboratory, Le Genest Saint Isle, France) were used in this study. Animal care and experiments were carried out in accordance with Norwegian and EU guidelines for care and use of laboratory animals, and were approved by the Norwegian Food Safety Authority (FOTS IDs 8620, 9129, 14191, and 28347). All animal studies were conducted at the Department of Comparative Medicine, Oslo University Hospital, Rikshospitalet. Female mice were used for all studies to avoid gender influence on outcome and variation of laser-induced CNV. Animal care and experiments were carried out in accordance with Norwegian and EU guidelines for care and use of laboratory animals, and were approved by the Norwegian Food Safety Authority (FOTS IDs 8620, 9129, 14191, and 28347). All animal studies were conducted at the Department of Comparative Medicine, Oslo University Hosptial, Rikshospitalet. Animals were kept in open cages (Eurostandard type III) that were changed every or every second week, depending of number of animals/cage, with a maximum of 8 adult animals per cage. All animals were provided with enrichment in the form of houses, tunnels, paper, and chewing sticks. The relative humidity in the housing environment was maintained at 55% ± 10%, with an air exchange rate in the housing rooms of 20/hour and a temperature of 21 ± 1 °C and a light cycle of 12 hours dark/12 hours light, with one hour gradually dusk and dawn from 7 am and 7 pm and complete darkness between 8 pm and 7 am. During the lit part of the light cycle, lighting strength was maintained at day standard (70–100 lux). Animals had free access to water (purified by reversed osmosis and ionic exchange) and food ad libitum. In all procedures, animals were anesthetized by IP injection of 100 mg/kg ketamine hydrochloride (Pfizer Animal Health, New York, NY) and 10 mg/kg xylazine (CP-Pharma, Burgdorf, Germany), and pupils were dilated with topical administration of tropicamide 5 mg/ml and phenylephrine hydrochloride 100 mg/ml (Bausch & Lomb UK Ltd., Kingston-upon-Thames, England).
Antibody treatment
The anti-JAG1.b7035, anti-VEGF B20.4.1.188, and the isotype control antibody (IgG, anti-Ragweed) were provided by Genentech. Anti-JAG1 (HMJ1-29, hamster IgG) mAb was provided by Professor Hideo Yagita, Juntendo University, Tokyo, Japan37. WT and PGLALA variants of anti-VEGF B20.4.1.1 and anti-JAG1.70 were produced in HEK293E cells as described below. All antibodies were diluted in sterile PBS and injected IP at a dose of 5 mg/kg body weight unless otherwise specified on the day of laser photocoagulation (day 0) and on day 5.
Recombinant proteins and staining reagents
All commercially acquired proteins, their usage, concentrations, and suppliers used are listed in Supplementary Table 1.
CNV Induction
Laser photocoagulation was performed using a 532-nm laser (Visulas 532 S; Carl Zeiss Meditec, Oberkochen, Germany). The pulses had a duration of 0,1 second, a power of 80 mW, and a spot size of 50 µm. Prior to laser pulse application, each eye was anesthetized with topical tetracain hydrochloride 10 mg/ml (Bausch & Lomb). Lubricating eye drops (Methocel 2%; Omnivision, Neuhausen, Switzerland) on a glass coverslip were applied to the cornea, and the retina was viewed through a slit lamp microscope. Each laser pulse (three or four per eye) was applied approximately two to three disc diameters from the optic disc. A vaporization bubble indicated disruption of Bruch’s membrane. After the application of laser burns, sterile eye drops (Viscotears; Laboratoires Thea, Clermont-Ferrand, France) was applied to both eyes. Mice were then placed on a pre-warmed plate at 35 °C until they awakened.
Antigen binding and Fc receptor ELISA
96-well ELISA plates were coated with 500 ng/mL of either recombinant, soluble murine Jagged1 (or murine VEGF diluted in PBS and added at a volume of 100 µL per well. Following ON incubation at 4 °C, plates were blocked by adding 250 µL of PBS supplemented with 4% skimmed milk (M) and incubating at RT with shaking for 2 hours. All plates were washed four times with PBS supplemented with 0.05% Tween20 (T). Antibodies were diluted in PBSTM and added to the plates in a titration series from 2000–15.63 ng/mL in a final volume of 100 µL. After 1.5 hours of incubation on a shaker at RT, the plates were washed as previously described.
To verify antigen binding and protein functionality of the murine antibodies, the plates were washed as previously described and 100 µL of anti-murine Fc from goat conjugated to alkaline phosphatase (ALP) diluted in PSTM added to all wells. After final incubation (1 h, RT on a shaker) and washing, the ELISA was developed by adding 100 µL of 10 µg/mL p-nitrophenyl-phosphate substrate (S0942, Sigma Aldrich) dissolved in diethanolamine solution. Absorbance at 405 nm was measured on a Sunrise spectrophotometer (Tecan).
To evaluate Fcγ and neonatal Fc receptor (FcγR and FcRn) binding to the relevant antibodies, ELISA plates were coated with either 500 ng/mL murine VEGF or an equimolar amount of soluble murine Jagged1 (1923 ng/mL). Antibodies were added to blocked ELISA plates in a titration series from 2000 to 0.92 ng/mL. Next, biotinylated murine-soluble versions of FcγR1-4 (CD64, CD32, CD16, and CD16-2, Sino Biologics) and FcRn (Immunitrack; Supplementary Table 1) were incubated with ALP-conjugated streptavidin in 20 µL PBSTM (pH 7.4 and 5.5 for FcγRs and FcRn, respectively) at RT for 20 minutes and added to the ELISA at final concentrations of 250 ng/mL FcRs and 3.36 µg/mL streptavidin-ALP. After 1 h shaking incubation at RT, Fc-FcR binding was visualized by adding ALP-substrate.
Half-life analysis
A titration series of anti-JAG1 and anti-VEGF (5.0, 0.5, and 0.05 mg/kg) was injected IP into 6 mice per dosage. Blood samples of 25 µL were drawn from the saphenous vein at 24, 48, 72, 120, 168, and 264 hours post injection through heparinized micro capillary pipettes. The samples were kept on ice and centrifuged at 17,000 × g at 4°C for 5 minutes to separate the serum from the plasma. The serum was harvested from the samples, diluted 1:10 in 50% glycerol/PBS and stored in 96-well plates at −20°C until analysis.
Analysis was carried out by antigen-binding ELISA. Serial dilutions of either anti-JAG1or anti-VEGF from 2000 to 0.98 ng/mL was added to each plate as a quantification standard. Serum samples were diluted 1:400–1:50 in 100 µL PBSTM and added to the blocked ELISA plates. Serum antibody levels were calculated by nonlinear regression and interpolating antibody levels against the standard in GraphPad prism (version 8.3.1, GraphPad Software LLC). Values were transformed to a logarithmic scale and calculated using a log(agonist) vs. response equation for variable slopes. Serum concentrations were calculated as a percentage relative to that found after the presumed end of the α-phase (= after 24 hours, set to 100%). β-phase half-life was calculated in Microsoft Excel version 16.16.19 (200210) using the equation t1/2 = log 0.5(log Ax/A0)*t, where Ax is the amount calculated at the given time (t) and A0 is the amount calculated after 24 hours. Compound elimination was visualized by a nonlinear fit of the percentage values to a semilogarithmic model in GraphPad prism.
Production of recombinant proteins
The cDNA sequences encoding the constant domains of WT mIgG2a isotypes and the variable heavy chains (HCs) of anti-JAG and anti-VEGF were synthesized and subcloned into pFuse vectors with zeocin resistance by GenScript Biotech Corporation. Matching murine kappa light chains (kLCs) were synthesized and subcloned into separate pFuse vectors. Effector-negative antibodies were generated by targeted mutagenesis of the constant domains to introduce PGLALA (P329G, L234A, and L235A)53.
Resulting constructs were used in transient co-transfection of HEK293E cells at a HC:LC ratio of 1:2 using Lipofectamine 2000 as per manufacturer’s instructions. Antibodies were collected as supernatant fractions every day for 10 days and further purified on an anti-murine kLC CaptureSelect affinity matrix (ThermoFisher, 09050907). Protein fractions were eluted by the use of 0.1 M glycine-HCl (pH 3.0) and neutralized by adding 1 M Tris-HCl (pH 8.0). Eluates were buffer exchanged into sterile-filtered PBS on 50 K spin columns (Merck Millipore, UFC905096) and monomeric fractions secured by size-exclusion chromatography (SEC) by the use of a Superdex200 10/300 column (GE Healthcare) coupled to an Äkta Avant 25 (GE Healthcare). Resulting histograms and a non-reducing SDS-PAGE run on a 12% Bis-Tris polyacrylamide gel (ThermoFisher, NW00125BOX) were used to evaluate protein size and purity. Proteins were stored in LoBind Eppendorf tubes (Eppendorf, Z666505) at −20 °C until the day of experiments.
Fundus fluorescein angiography (FFA)
FFA was performed with the retinal imaging microscope Micron IV (Phoenix Research Laboratories, Pleasanton, CA, USA). Laser treatment was performed as described above except the image-guided laser system (Meridian Merilas 532 green laser photocoagulator attached to the Micron IV) was used. Four laser burns were induced in each eye with a fixed spot size of 50 µm, duration of 70 ms, and power level of 270 mW. 10 days after laser photocoagulation, mice were anesthetized, pupils dilated, and IP injected with 10 mg/ml fluorescein sodium (Anatera; Alcon Laboratories, Fort Worth, TX, USA) at 100 µg/g body weight. The animals were positioned on the Micron IV stage and Hypromellose coupling fluid applied to the eye. The camera and eye position was adjusted ensuring correct alignment and focus on the optic nerve head plane using standard color fundus photography before adjusting to the appropriated filter set for fluorescein angiography. Images were captured using the Discover software (Phoenix Research Laboratories). Fluorescent fundus images were taken with the Micron IV light source at maximum intensity and without extra gain at 11, 13, and 15 minutes after fluorescein injection. The fluorescent area of CNV lesions was determined using open-source software, ImageJ (National Institutes of Health, Bethesda, MD, USA). Briefly, RGF Tiff files were imported into ImageJ and individual color channels were separated. Red and blue channels were removed and all area values were measured from the green channel. A green channel binary image was then generated using automated image thresholding (Otsu’s threshold clustering algorithm), CNVs were surrounded with the polygon selection tool and the fluorescent area for each CNV lesion was calculated.
Murine contact hypersensitivity model
DNFB-induced contact hypersensitivity is a delayed-type hypersensitivity model for human allergic contact dermatitis. Mice were sensitized to DNFB by painting the shaved abdomen with 25 μl of a 0.5% solution in acetone/olive oil (4:1), in addition to 5 μl to each paw, on day 0 and 1. Treatment with Anti-JAG1.b70 was compared with isotype control—both at 5 mg/kg—by IP injections 3 hours before induction of the elicitation phase. The elicitation phase was induced on day 5 by painting the right ear with 20 μl of 0.5% DNFB solution. The thickness of the ears was measured using a micrometer. Swelling was calculated by subtracting the baseline thickness from the thickness measured at various time points. Anesthesia was induced by isoflurane inhalation. No animals were excluded from the analysis. Ears were harvested, fixated in formalin, and embedded in paraffin sectioned longitudinally, for later immunohistochemical analysis.
Immunostainings and microscopy of retinal pigment epithelium (RPE)-choroid-sclera flat mounts
Mice were euthanatized 10 days after laser photocoagulation. Eyes were immediately enucleated and fixed with 4% paraformaldehyde (Sigma-Aldrich, St.Louis, MO, USA) in PBS for 1 hour at room temperature. After three washes with PBS, the anterior segment and retina were dissected out, four or five radial cuts in the remaining RPE-choroid-sclera were made, and incubated with a blocking buffer (PBS+ 0.5% Triton X-100 + 5% donkey serum) for 2 hours at 4 °C. After removal of the blocking buffer, the eye tissues were subsequently incubated with primary antibodies diluted in PBS with 1.25% BSA + 1% Triton X-100 overnight at 4 °C. After three washes with PBS, the tissues were incubated with fluorescently labeled secondary antibodies for 90 minutes at room temperature. Hoechst 33258 nuclear dye (0.5 µg/ml) was used as counterstain. The RPE-choroid-sclera complexes were then flat mounted with ProLong Diamond Antifade mountant (ThermoFisher) on a glass slide. Used antibodies are listed in Supplementary Table 1.
Fluorescence microscopy was performed with a Nikon Ellipse 80i (Nikon, Tokyo, Japan) with Nikon Plan Fluor oil objectives ×20/0.75 and ×40/1.30. Images were obtained using ZEN pro (Carl Zeiss Microscopy GmbH, Jena, Germany) image acquisition software. Single-channel images for each fluorochrome were captured at ×40 magnification. All digital images were taken under the same conditions. CNV areas (in µm2) were quantified by ICAM-2 immunostaining using ImageJ software. Briefly, CZI files were imported into ImageJ, and individual color channels separated. A binary image was then generated using automated image thresholding (Otsu’s threshold clustering algorithm), CNVs were surrounded with the polygon selection tool, and the ICAM-2-positive areas were calculated. To ensure reliable data analysis of the CNV lesions, exclusion criteria were applied as described previously89. Briefly, a lesion was excluded if (1) there was choroidal hemorrhage encroaching on the lesion; (2) the lesion was linear instead of circular; (3) the lesion had fused with another lesion; (4) the lesion had a size indicating it was an outlier lesion as defined below; or (5) the lesions was the only lesion in an eye. An outlier lesion was categorized as (1) “too big” (>10,000 µm2 in area and was more than five times larger than the next biggest lesion in the eye; (2) “too small” (<1/5 the area of the next smallest lesion in the eye; this criterion applied only if at least one lesion in the eye was more than 5000 µm2); or (3) “too different” (after all of the lesions in a specific treatment group were measured, the lesion’s area was fivefold greater than the mean for that group; this criterion applied only for lesions that were >5000 µm2.
Quantification of IBA-1-positive reactive mononuclear phagocytes in CNVs was performed as described previously39. Briefly, a 200 µm diameter circular selection around the laser spot was defined using ImageJ 1.53k and the number of round-shaped (ameboid) versus ramified mononuclear phagocytes counted. The built-in cell counter module and visual grid was applied in ImageJ to aid in counting, to mark and classify counted cells. Both the counting and morphology classifications were performed by two independent observers.
Confocal microscopy image processing
All images were taken under the same conditions on a Zeiss LSM 880 confocal microscope, with tile scan and ×60/1.40-NA oil immersion objective. CZI files were imported into FIJI software and individual color channel separated. A binary image was then generated using automatic image thresholding (Otsu’s threshold clustering algorithm).
Pericyte coverage of retinal vessels was calculated from four images per retina. All digital images were taken under the same conditions. Pericyte coverage was calculated as the ratio of area covered by NG2 positive cells and normalized to the area covered by Isolectin B4 positive endothelial cells. CZI files were imported into ImageJ and individual color channels separated. A binary image was then generated using automated image thresholding (Otsu’s threshold clustering algorithm).
Quantification of Fluorescence intensity
For fluorescence intensity quantification, the confocal images were opened using FIJI software. The images were stacked and sum slices were made in Fiji. After that, all channels were split, and threshold for each channel was calculated individually. The fluorescence intensity of target protein, such as DLL4 and Jagged1 were calculated in separate channels. Areas to calculate in each image were selected manually. The graphs show quantification of four replicates per group.
Light-induced retinal degeneration
The model of fundus camera-delivered light-induced retinal degeneration was described recently in detail41. In brief, mice were dark-adapted overnight, anesthetized, and pupils dilated as described above. Fluorescein was administered as a single IP injection of 100 µl 20 mg/ml fluorescein sodium (total dose of 2 mg fluorescein/mouse). Mice were then placed on the animal stage; the optic disc was centered in the field of view and the camera focused on the retina. 3 minutes after the fluorescein injection, light was applied to the right eye at an intensity of 54,000 lux for 4 minutes. Light intensity from the Micron IV fundus camera was measured using a light meter (Cat # S90199, Thermo Fisher Scientific). After repositioning, the left eye was illuminated for 4 minutes starting 10 minutes after the fluorescein injection. Immediately after illumination of the 2nd eye, mice were injected IP with either anti-JAG1.b70 or isotype control antibody and placed on a pre-warmed plate at 35 °C until they awakened. 7 days after illumination, mice were euthanatized, eyes immediately enucleated, and fixed with 4% paraformaldehyde in PBS for 1 hour at RT. Right eyes were processed for retinal and RPE-choroid-sclera flat mounts, while left eyes were paraffin-embedded, sectioned, and stained with TUNEL assay.
Terminal transferase dUTP nick end labeling (TUNEL)
Samples were fixed in 4% paraformaldehyde and embedded in paraffin, then sectioned accordingly. Rehydration and consequently permeabilization diluted Proteinase K 1/100 in dH2O was performed, followed by quenching or inactivation of endogenous peroxidases. After washing, the TUNEL assay was performed according to the manufacturer’s instructions (Abcam, USA; TUNEL Assay Kit-HRP-DAB (ab206386). The sections were then rinsed with PBS, counterstained with hematoxylin, and coverslipped before analysis by light microscopy. Stained slides were scanned by a Pannoramic MIDI II scanner (3DHISTECH, Hungary) at ×20 magnification and digitized with high resolution, at a pixel size of 0.243094 mm × 0.243094 mm.
Quantification of cytokines and chemokines by Luminex technology
Total proteins from retinas (n = 6/group) or choroid-scleras (n = 12/group) were isolated using the cell lysis kit (171-304011, Bio-Rad Laboratories, Hercules, CA, USA) and lysis beads (Lysing Matrix D, 6913-100, MP Biomedicals) following the respective instructions. Protein extracts were quantified using the BCA method (Pierce BCA assay kit, 23225, Thermo-Scientific) and stored at −20 °C for maximum 1 week. All samples were normalized to the selected concentration of 1.3 mg/ml and assayed for cytokines. The cytokine/chemokine concentrations were determined using the Mouse Chemokine 31-plex Mouse (12009159, Bio-Rad Laboratories) according to the manufacturer’s instructions. Samples in duplicates were analyzed, using Bio-Plex MAGPIX Multiplex Reader and Bio-Plex Manager 6.1 software (Bio-Rad Laboratories).
Cell culture
Umbilical cords were obtained from the Department of Gynecology and Obstetrics at the Oslo University Hospital, following the informed consent of donors, and according to a protocol approved by the Regional Committee for Research Ethics (S-05152). Human umbilical vein endothelial cells (HUVECs) were isolated as previously described90 and cultured in MCBD131 medium containing 7.5% FBS, 10 ng/mL EGF, 1 ng/mL bFGF, 1 µg/mL hydrocortisone, 50 µg/mL gentamicin, 250 ng/mL fungizone and 1% L-glutamine. Cells were maintained at 37 °C in 95% humidity/5% CO2 atmosphere, split 1:3, and used between passages 2 and 5. rhVEGF165 (Bio-Techne, Abingdon, UK) was added to confluent HUVEC cultures grown in 12-well plates at final concentrations of 0, 10, or 100 ng/ml, respectively, and cultured for another 24 hours. For serum starvation experiments, HUVECs were seeded in plates as previously specified, in serum-containing culturing medium. After 4 hours, cell attachment to the substrate was verified by visual inspection, before replacing the medium with serum-free medium (i.e., culturing medium with all supplements, except 7.5% FBS). Then, cells were incubated for 24 hours before starting experiments. Adherent HEK293E cells used for recombinant protein production were incubated at 37 °C and 5% CO2/95% air and cultured in GlutaMAX-containing RPMI medium (Life Technologies) supplemented with 10% fetal calf serum (FCS) and 25 U/mL penicillin (BioWhittaker). HEK293E cell cultures were split 1:5 between passages and grown to confluency prior to transfection.
Notch stimulation with immobilized ligands
Plates were coated with recombinant human Jagged1 or DLL4 as previously described91. Briefly, for Jagged1, plates were coated with rabbit anti-His-tag in PBS for 1 hour at 37 °C, then blocked in complete medium for 1 hour at 37 °C before coating with recombinant human Jagged1 His-tag in PBS for 2 hours at 37 °C. For DLL4, plates were coated with anti-human IgG Fcγ in PBS for 1 hour at 37 °C, followed by blocking as previously described and coating with recombinant DLL4 Fc-tag for 2 hours. Cells were then seeded at a density of 2.5 × 104/cm2 and incubated at 37oC overnight before stimulation with 10 ng/mL VEGF165 for 24 hours.
Protein extraction and Western blot
Cells were washed with cold PBS and lysed in 10 mM Tris buffer (pH 6.8) containing 5 mM EDTA, 6 mM NaF, 5 mM tetrasodium pyrophosphate (Na4P2O7), 2% SDS, as well as inhibitors of proteases (Sigma P5726, 1:100) and phosphatases (Sigma P8340, 1:100). Sample buffer (72% glycerol, 28% β-mercaptoethanol, 0.33 mg/ml bromophenol blue) was added at a 1:7 ratio (v/v), and samples heated to 65 °C for 10 minutes. Protein concentrations were determined by the RC DC Protein Assay from Bio-Rad and 10 µg protein loaded in each well in a 15-well 10% or 4–20% polyacrylamide Bio-Rad mini-PROTEAN®TGX™ precast tris-glycine gel. 5 µl BLUltra Prestained Protein Ladder (6,5 to 270 kDa) (Bio-Helix) was used to estimate molecular weight of protein of interest. Separated proteins were transferred to a nitrocellulose membrane using the Trans-blot® Turbo™ transfer system using the program ‘mixed MW’. Following transfer, membranes were blocked with 5% no-fat milk (M) (Bio-Rad) or 5% BSA in TBST (Tris-buffered saline with 0.01% Tween 20, pH 7.4) for 30 minutes. Next, membranes were incubated with primary antibodies overnight (4 °C), followed by washing with TBST, and finally incubated with HRP-conjugated secondary antibodies for 2 hours. Substrate (SuperSignal™ West Dura Extended Duration Substrate, 32106 or 34076, Thermo Fisher Scientific) was added to the membrane, and product formation detected using ChemiDoc XRS+ system and Image Lab 4.1. When necessary, membranes were stripped using Restore PLUS western blot stripping buffer (Thermo Fisher Scientific) according to manufacturer’s instructions, then blocked again and stained with new antibodies. Anti-DLL4 was diluted in 5% BSA-TBST, anti-Jag1in 1% TBSTM, anti-β-tubulin in 1% TBSTM, and HRP-conjugated anti-rabbit IgG in 1% M as specified in Supplementary table 1. Bands were quantified using volume tools in Image Lab 4.1 and normalized to β-tubulin by using the following formula: (volume intensity protein of interest)/(volume intensity β-tubulin).
Crystal violet proliferation assay
Relative cell density was determined as previously described by crystal violet staining92. Briefly, cells were seeded in 96-well plates at a density of 6 × 103 cells per well in the presence of control IgG, bevacizumab, or anti-JAG1 antibodies at 25 µg/ml, and either with or without 10 ng/mL VEGF. Following cultivation for the number of days specified in results, cells were fixed using 4% paraformaldehyde for 10 minutes, then dried for 20 minutes then stored at 4 °C until the end of the experiment. Fixed cells were stained with 70 µl 0.1% crystal violet (Apotekforeningen, Oslo) in PBS for 4 minutes then thoroughly washed in cold tap water. Nuclear dye was then resuspended in 33% acetic acid (Sigma-Aldrich) on a shaking incubator at RT for 5 minutes before absorbance was measured at 550 nm in an Epoch (BioTek) plate reader with Gen5 software (BioTek).
LDH assay
Cytotoxicity was measured by leakage of LDH using the Cytotoxicity Detection KitPLUS (LDH) (Sigma 4744926001) according to the manufacturer’s instructions. Briefly, cells were cultured for 3 days in medium supplemented with 10 ng/ml VEGF in the presence of 25 µg/ml control IgG, anti-JAG1, or bevacizumab. 100 µl of the detection reagent was then added to each well and incubated in the dark for 25 minutes before the stop reagent was added. OD was then measured at 492 nm with an Epoch (BioTek) plate reader with Gen5 software (BioTek).
Immunohistochemistry of normal human eyes
Formalin-fixed, paraffin-embedded human eyes that either showed signs of dry AMD such as drusen formation and RPE alterations, or with no pathological traits, were obtained from the diagnostic biobank at the Division of Pathology, Oslo University Hospital, and used in accordance with a protocol approved by the Regional Committee for Research Ethics, Health Region South, Norway (approval 2013/803) following informed consent of all donors. JAG1 was detected by manual staining: tissue sections (4 µm thick, formalin-fixed, paraffin-embedded) were deparaffinized, boiled for 20 minutes in Dako Target Retrieval Solution pH 6, incubated with Dako Peroxidase Blocking Reagent for 5 minutes followed by incubation with rabbit monoclonal anti-JAG1 diluted in PBS with 1.25% BSA overnight at 4 °C, then incubated with Rabbit-on-Rodent HRP-Polymer (Biocare Medical, Pacheco, CA, USA) for 30 minutes followed by incubation with Discovery Purple chromogen for 30 minutes (Roche Tissue Diagnostics—Ventana Medical Systems, Tucson, AZ, USA). Hematoxylin was used as counterstain. Unless otherwise indicated, all incubations were performed at room temperature.
Statistics
Data are presented as mean ± SEM unless otherwise specified. Unpaired students’ t test was used to compare experimental parameters to the relevant controls. T tests were performed using Prism 8 (GraphPad, San Diego, CA). Two-tailed p values ≤ 0.05 were considered statistically significant. For comparing multiple variables, one-way ANOVA with subsequent Bonferroni’s multiple comparison test was used.
Reporting summary
Further information on research design is available in the Nature Portfolio Reporting Summary linked to this article.
Data availability
All data supporting the findings described are available in this paper and in the Supplementary Information. The Source Data and Supplementary Information are provided in this article. All performed statistical analyses are described in the Source Data. In certain cases, representative microscopy images are shown for simplicity. Where specified, these and related images have been used for quantification purposes and statistical analysis. In these cases, related numerical data from both representative images and all related, not shown images are included in the Source Data provided with this article. Related, underlying raw image files are stored locally at the research institutions and may be obtained from the corresponding authors J.T.A. and E.S. following requests sent to email addresses provided with this paper (j.t.andersen@medisin.uio.no and eiriksundlisater@gmail.com) who will strive to handle requests within 60 working days. Source data are provided with this paper.
References
Ambati, J. & Fowler, B. J. Mechanisms of age-related macular degeneration. Neuron 75, 26–39 (2012).
Wong, W. L. et al. Global prevalence of age-related macular degeneration and disease burden projection for 2020 and 2040: a systematic review and meta-analysis. Lancet Glob. Health 2, e106–e116 (2014).
Chen, M. & Xu, H. Parainflammation, chronic inflammation, and age-related macular degeneration. J. Leukoc. Biol. 98, 713–725 (2015).
Ambati, J., Atkinson, J. P. & Gelfand, B. D. Immunology of age-related macular degeneration. Nat. Rev. Immunol. 13, 438–451 (2013).
Lopez, P. F. et al. Pathologic features of surgically excised subretinal neovascular membranes in age-related macular degeneration. Am. J. Ophthalmol. 112, 647–656 (1991).
Kinnunen, K., Petrovski, G., Moe, M. C., Berta, A. & Kaarniranta, K. Molecular mechanisms of retinal pigment epithelium damage and development of age‐related macular degeneration. Acta Ophthalmol. 90, 299–309 (2012).
Villegas, V. M., Aranguren, L. A., Kovach, J. L., Schwartz, S. G. & Flynn, H. W. Jr. Current advances in the treatment of neovascular age-related macular degeneration. Expert Opin. Drug Deliv. 14, 1–10 (2016).
Yang, S., Zhao, J. & Sun, X. Resistance to anti-VEGF therapy in neovascular age-related macular degeneration: a comprehensive review. Drug Des. Dev. Ther. 10, 1857–1867 (2016).
Amoaku, W. M. et al. Defining response to anti-VEGF therapies in neovascular AMD. Eye 29, 721–731 (2015).
Forooghian, F., Cukras, C., Meyerle, C. B., Chew, E. Y. & Wong, W. T. Tachyphylaxis after intravitreal bevacizumab for exudative age-related macular degeneration. Retin 29, 723–731 (2009).
Group, C. of A. M. D. T. T. (CATT) R. et al. Five-year outcomes with anti–vascular endothelial growth factor treatment of neovascular age-related macular degeneration the comparison of age-related macular degeneration treatments trials. Ophthalmology 123, 1751–1761 (2016).
Kurihara, T., Westenskow, P. D., Bravo, S., Aguilar, E. & Friedlander, M. Targeted deletion of Vegfa in adult mice induces vision loss. J. Clin. Investig. 122, 4213–4217 (2012).
Nishijima, K. et al. Vascular endothelial growth factor-A is a survival factor for retinal neurons and a critical neuroprotectant during the adaptive response to ischemic injury. Am. J. Pathol. 171, 53–67 (2007).
Lytvynchuk, L., Sergienko, A., Lavrenchuk, G. & Petrovski, G. Antiproliferative, apoptotic, and autophagic activity of ranibizumab, bevacizumab, pegaptanib, and aflibercept on fibroblasts: implication for choroidal neovascularization. J. Ophthalmol. 2015, 1–10 (2015).
Regula, J. T. et al. Targeting key angiogenic pathways with a bispecific Cross MA b optimized for neovascular eye diseases. EMBO Mol. Med. 8, 1265–1288 (2016).
Volz, C. & Pauly, D. Antibody therapies and their challenges in the treatment of age-related macular degeneration. Eur. J. Pharm. Biopharm. 95, 158–172 (2015).
Cook‐Mills, J. M. & Deem, T. L. Active participation of endothelial cells in inflammation. J. Leukoc. Biol. 77, 487–495 (2005).
Osipo, C., Golde, T. E., Osborne, B. A. & Miele, L. A. Off the beaten pathway: the complex cross talk between Notch and NF-κB. Lab Invest 88, 11–17 (2008).
Tran, I. T. et al. Blockade of individual Notch ligands and receptors controls graft-versus-host disease. J. Clin. Invest. 123, 1590–1604 (2013).
Radtke, F., Fasnacht, N. & MacDonald, H. R. Notch signaling in the immune system. Immunity 32, 14–27 (2010).
Poulsen, L. et al. Inhibition of endothelial NOTCH1 signaling attenuates inflammation by reducing cytokine-mediated histone acetylation at inflammatory enhancers. Arterioscler. Thromb. Vasc. Biol. 38, 854–869 (2018).
Phng, L.-K. & Gerhardt, H. Angiogenesis: a team effort coordinated by notch. Dev. Cell 16, 196–208 (2009).
Lobov, I. B. et al. Delta-like ligand 4 (Dll4) is induced by VEGF as a negative regulator of angiogenic sprouting. Proc. Natl Acad. Sci. 104, 3219–3224 (2007).
Williams, C. K., Li, J.-L., Murga, M., Harris, A. L. & Tosato, G. Up-regulation of the Notch ligand Delta-like 4 inhibits VEGF-induced endothelial cell function. Blood 107, 931–939 (2006).
Benedito, R. et al. The notch ligands Dll4 and Jagged1 have opposing effects on angiogenesis. Cell 137, 1124–1135 (2009).
Grochowski, C. M., Loomes, K. M. & Spinner, N. B. Jagged1 (JAG1): structure, expression, and disease associations. Gene 576, 381–384 (2016).
Suchting, S. & Eichmann, A. Jagged gives endothelial tip cells an edge. Cell 137, 988–990 (2009).
Pedrosa, A.-R. et al. Endothelial Jagged1 antagonizes Dll4 regulation of endothelial branching and promotes vascular maturation downstream of Dll4/Notch1. Arterioscler. Thromb. Vasc. Biol. 35, 1134–1146 (2018).
Pedrosa, A.-R. et al. Endothelial Jagged1 promotes solid tumor growth through both pro-angiogenic and angiocrine functions. Oncotarget 6, 24404–24423 (2015).
Briot, A. & Iruela-Arispe, M. L. Blockade of specific NOTCH ligands: a new promising approach in cancer therapy. Cancer Discov. 5, 112–114 (2015).
Stallcup, W. B. Pericyte biology - novel concepts. Adv. Exp. Med. Biol. 1109, 5–19 (2018).
Ohsawa, K., Imai, Y., Sasaki, Y. & Kohsaka, S. Microglia/macrophage‐specific protein Iba1 binds to fimbrin and enhances its actin‐bundling activity. J. Neurochem. 88, 844–856 (2004).
Huang, M.-T. et al. Endothelial intercellular adhesion molecule (ICAM)–2 regulates angiogenesis. Blood 106, 1636–1643 (2005).
Hellström, M. et al. Dll4 signalling through Notch1 regulates formation of tip cells during angiogenesis. Nature 445, 776–780 (2007).
Lafkas, D. et al. Therapeutic antibodies reveal Notch control of transdifferentiation in the adult lung. Nature 528, 127 (2015).
Campa, C. et al. Effects of an Anti–VEGF-A monoclonal antibody on laser-induced choroidal neovascularization in mice: optimizing methods to quantify vascular changes. Invest. Ophthalmol. Vis. Sci. 49, 1178–1183 (2008).
Moriyama, Y. et al. Delta-like 1 is essential for the maintenance of marginal zone B cells in normal mice but not in autoimmune mice. Int. Immunol. 20, 763–773 (2008).
He, L. & Marneros, A. G. Macrophages are essential for the early wound healing response and the formation of a fibrovascular scar. Am. J. Pathol. 182, 2407–2417 (2013).
Lückoff, A., Scholz, R., Sennlaub, F., Xu, H. & Langmann, T. Comprehensive analysis of mouse retinal mononuclear phagocytes. Nat. Protoc. 12, 1136–1150 (2017).
Lückoff, A. et al. Interferon‐beta signaling in retinal mononuclear phagocytes attenuates pathological neovascularization. Embo Mol. Med. 8, 670–678 (2016).
Zhong, X. et al. Fundus camera-delivered light-induced retinal degeneration in mice with the RPE65 Leu450Met variant is associated with oxidative stress and apoptosiscamera-delivered light-induced retinal degeneration. Invest. Ophthalmol. Vis. Sci. 57, 5558–5567 (2016).
Tisi, A., Parete, G., Flati, V. & Maccarone, R. Up-regulation of pro-angiogenic pathways and induction of neovascularization by an acute retinal light damage. Sci. Rep. UK 10, 6376 (2020).
Chistyakov, D. V. et al. Mechanisms and treatment of light-induced retinal degeneration-associated inflammation: insights from biochemical profiling of the aqueous humor. Int J. Mol. Sci. 21, 704 (2020).
Gaspari, A. A. & Katz, S. I. Contact hypersensitivity. Curr. Protoc. Immunol. 8, 4.2.1–4.2.5 (1993).
Andersson, E. R. & Lendahl, U. Therapeutic modulation of Notch signalling — are we there yet? Nat. Rev. Drug Discov. 13, nrd4252 (2014).
Christopoulos, P. F. et al. Targeting the notch signaling pathway in chronic inflammatory diseases. Front. Immunol. 12, 668207 (2021).
Miloudi, K. et al. NOTCH1 signaling induces pathological vascular permeability in diabetic retinopathy. Proc. Natl. Acad. Sci. 116, 201814711 (2019).
Keizer, R. J., Huitema, A. D. R., Schellens, J. H. M. & Beijnen, J. H. Clinical pharmacokinetics of therapeutic monoclonal antibodies. Clin. Pharmacokinet. 49, 493–507 (2010).
Murinello, S., Mullins, R. F., Lotery, A. J., Perry, V. H. & Teeling, J. L. Fcγ receptor upregulation is associated with immune complex inflammation in the mouse retina and early age-related macular degeneration. Invest. Ophthalmol. Vis. Sci. 55, 247–258 (2014).
Nomura, Y., Kaneko, M., Miyata, K., Yatomi, Y. & Yanagi, Y. Bevacizumab and aflibercept activate platelets via FcγRIIa activation of platelets via FcγRIIa. Invest. Ophthalmol. Vis. Sci. 56, 8075–8082 (2015).
MEYER, T. et al. Bevacizumab immune complexes activate platelets and induce thrombosis in FCGR2A transgenic mice. J. Thromb. Haemost. 7, 171–181 (2009).
Bruhns, P. Properties of mouse and human IgG receptors and their contribution to disease models. Blood 119, 5640–5649 (2012).
Schlothauer, T. et al. Novel human IgG1 and IgG4 Fc-engineered antibodies with completely abolished immune effector functions. Protein Eng. Des. Sel. 29, 457–466 (2016).
Junghans, R. P. & Anderson, C. L. The protection receptor for IgG catabolism is the beta2-microglobulin-containing neonatal intestinal transport receptor. Proc. Natl Acad. Sci. 93, 5512–5516 (1996).
Roopenian, D. C. et al. The MHC class I-like IgG receptor controls perinatal IgG transport, IgG homeostasis, and fate of IgG-Fc-coupled drugs. J. Immunol. 170, 3528–3533 (2003).
Suzuki, M. et al. Predictive factors for non-response to intravitreal ranibizumab treatment in age-related macular degeneration. Br. J. Ophthalmol. 98, 1186–1191 (2014).
Nagai, N. et al. Non-responsiveness to intravitreal aflibercept treatment in neovascular age-related macular degeneration: implications of serous pigment epithelial detachment. Sci. Rep. UK 6, 29619 (2016).
Kwak, N., Okamoto, N., Wood, J. M. & Campochiaro, P. A. VEGF is major stimulator in model of choroidal neovascularization. Invest. Ophthalmol. Vis. Sci. 41, 3158–3164 (2000).
Cabral, T. et al. Retinal and choroidal angiogenesis: a review of new targets. Int. J. Retin. Vitreous 3, 31 (2017).
Sarkar, A., Sodha, S. J., Junnuthula, V., Kolimi, P. & Dyawanapelly, S. Novel and investigational therapies for wet and dry age-related macular degeneration. Drug Discov. Today 27, 2322–2332 (2022).
Wykoff, C. C. et al. Efficacy, durability, and safety of intravitreal faricimab with extended dosing up to every 16 weeks in patients with diabetic macular oedema (YOSEMITE and RHINE): two randomised, double-masked, phase 3 trials. Lancet 399, 741–755 (2022).
Heier, J. S. et al. Efficacy, durability, and safety of intravitreal faricimab up to every 16 weeks for neovascular age-related macular degeneration (TENAYA and LUCERNE): two randomised, double-masked, phase 3, non-inferiority trials. Lancet 399, 729–740 (2022).
Benest, A. V. et al. Angiopoietin-2 is critical for cytokine-induced vascular leakage. Plos One 8, e70459 (2013).
Grandbarbe, L. et al. Notch signaling modulates the activation of microglial cells. Glia 55, 1519–1530 (2007).
Caolo, V. et al. Feed-forward signaling by membrane-bound ligand receptor circuit THE CASE OF NOTCH DELTA-LIKE 4 LIGAND IN ENDOTHELIAL CELLS*. J. Biol. Chem. 285, 40681–40689 (2010).
Ahmad, I. et al. Regulation of ocular angiogenesis by notch signaling: implications in neovascular age-related macular degeneration. Invest. Ophthalmol. Vis. Sci. 52, 2868–2878 (2011).
Benedito, R. & Hellström, M. Notch as a hub for signaling in angiogenesis. Exp. Cell Res. 319, 1281–1288 (2013).
Kangsamaksin, T. et al. NOTCH decoys that selectively block DLL/NOTCH or JAG/NOTCH disrupt angiogenesis by unique mechanisms to inhibit tumor growth. Cancer Discov. 5, 182–197 (2015).
Dou, G. et al. RBP‐J, the transcription factor downstream of Notch receptors, is essential for the maintenance of vascular homeostasis in adult mice. FASEB J. 22, 1606–1617 (2008).
Camelo, S. et al. Delta-like 4 inhibits choroidal neovascularization despite opposing effects on vascular endothelium and macrophages. Angiogenesis 15, 609–622 (2012).
Dou, G.-R. et al. Myeloid-specific blockade of notch signaling attenuates choroidal neovascularization through compromised macrophage infiltration and polarization in mice. Sci. Rep. UK 6, 28617 (2016).
Polacheck, W. J. et al. A non-canonical Notch complex regulates adherens junctions and vascular barrier function. Nature 552, 258–262 (2017).
Boardman, R. et al. Activation of Notch signaling by soluble Dll4 decreases vascular permeability via a cAMP/PKA-dependent pathway. Am. J. Physiol. Heart C. 316, H1065–H1075 (2019).
Smith, R. O. et al. Vascular permeability in retinopathy is regulated by VEGFR2 Y949 signaling to VE-cadherin. Elife 9, e54056 (2020).
Shi, X. et al. Inhibition of TNF-α reduces laser-induced choroidal neovascularization. Exp. Eye Res. 83, 1325–1334 (2006).
Sainson, R. C. A. et al. TNF primes endothelial cells for angiogenic sprouting by inducing a tip cell phenotype. Blood 111, 4997–5007 (2008).
Roopenian, D. C. & Akilesh, S. FcRn: the neonatal Fc receptor comes of age. Nat. Rev. Immunol. 7, 715–725 (2007).
Gadkar, K. et al. Design and pharmacokinetic characterization of novel antibody formats for ocular therapeutics novel antibody formats for ocular therapeutics. Invest. Ophthalmol. Vis. Sci. 56, 5390–5400 (2015).
Ghosh, J. G. et al. Long-acting protein drugs for the treatment of ocular diseases. Nat. Commun. 8, 14837 (2017).
Mandal, A. et al. Ocular delivery of proteins and peptides: challenges and novel formulation approaches. Adv. Drug Deliv. Rev. 126, 67–95 (2018).
Grevys, A. et al. A human endothelial cell-based recycling assay for screening of FcRn targeted molecules. Nat. Commun. 9, 621 (2018).
Yu, L. et al. Interaction between bevacizumab and murine VEGF-A: a reassessment. Invest. Ophthalmol. Vis. Sci. 49, 522–527 (2008).
Bournazos, S., Wang, T. T., Dahan, R., Maamary, J. & Ravetch, J. V. Signaling by antibodies: recent progress. Annu Rev. Immunol. 35, 285–311 (2017).
Lukason, M. et al. Inhibition of choroidal neovascularization in a nonhuman primate model by intravitreal administration of an AAV2 vector expressing a novel anti-VEGF molecule. Mol. Ther. 19, 260–265 (2011).
Yu, Y., Lin, X., Wang, Q., He, M. & Chau, Y. Long‐term therapeutic effect in nonhuman primate eye from a single injection of anti‐VEGF controlled release hydrogel. Bioeng. Transl. Med. 4, e10128 (2019).
Nork, T. M. et al. Prevention of experimental choroidal neovascularization and resolution of active lesions by VEGF trap in nonhuman primates. Arch. Ophthalmol. 129, 1042–1052 (2011).
Picaud, S. et al. The primate model for understanding and restoring vision. Proc. Natl. Acad. Sci. 116, 26280–26287 (2019).
Fuh, G. et al. Structure-function studies of two synthetic anti-vascular endothelial growth factor fabs and comparison with the AvastinTM Fab. J. Biol. Chem. 281, 6625–6631 (2006).
Poor, S. H. et al. Reliability of the mouse model of choroidal neovascularization induced by laser photocoagulation recommendations for the mouse laser-induced CNV model. Invest. Ophthalmol. Vis. Sci. 55, 6525–6534 (2014).
Jaffe, E. A., Nachman, R. L., Becker, C. G. & Minick, C. R. Culture of human endothelial cells derived from umbilical veins. identification by morphologic and immunologic criteria. J. Clin. Invest. 52, 2745–2756 (1973).
Sundlisæter, E. et al. The alarmin IL-33 is a notch target in quiescent endothelial cells. Am. J. Pathol. 181, 1099–1111 (2012).
Fjær, R. et al. A novel somatic mutation in GNB2 provides new insights to the pathogenesis of Sturge–weber syndrome. Hum. Mol. Genet. 30, ddab144 (2021).
Acknowledgements
We thank Christian Siebel, Principal Scientist in the Discovery Oncology department at Genentech Inc., for providing anti-JAG1 (anti-JAG1.b70, mIgG2a), Genentech, Inc. for donation of anti-VEGF antibody B20-4.1.1., professor Hideo Yagita, Juntendo University, Tokyo, Japan, for providing anti-JAG1 (HMJ1-29, hamster IgG) mAb, and principal engineer Giang Nguyen for staining paraffin sections from adult human cadaver eyes. J.T.A. was supported by the Research Council of Norway (Grant no. 314909; 287927) and South-Eastern Norway Regional Health Authority (Grant no. 2018052; 2019084; 2021069), and in part by Dr. Jon S Larsens Foundation (T.T.G., M.C.M. and J.T.A.). T.T.G. was supported by internal funding from Division of Head, Neck, and Reconstructive Surgery, Oslo University Hospital. J.A.W. was supported by South-Eastern Norway Regional Health Authorities (Grant no. 2017013). E.S. was supported by the Research Council of Norway (Grant no. 240814) and The Norwegian Association of the Blind and Partially Sighted. E.S., G.P., and M.C.M. were supported by funding from the Medical Faculty, University of Oslo (2017/7294) for the small animal retinal imaging platform. Illustrations in Figs. 1a, 2a, g, 3a, 4a, 5a, 6a, 7a, 8a and Supplementary Fig. 2g were created with BioRender.com.
Author information
Authors and Affiliations
Contributions
T.T.G., J.T.A., and E.S. designed research, T.T.G., J.A.W., H.J., S.K., N.B., P.F.C., M.B., S.F., G.P., and E.S. performed research, M.C.M., G.H., J.H.F., B.S.S., J.T.A., and E.S. provided resources, T.T.G., J.A.W., S.K., J.T.A., and E.S. wrote the paper. All authors revised and approved the final version of the manuscript.
Corresponding authors
Ethics declarations
Competing interests
E.S. has received lecture fees from Allergan and consultancy fees from Sanofy Genzyme. M.C.M. has been a member of advisory boards at Bayer, Novartis, Roche and Allergan and has received lecture fees from Bayer and Roche. T.T.G. and J.T.A. have ownership interests in Authera AS. The remaining authors declare no competing interests.
Peer review
Peer review information
Nature Communications thanks Thomas Langmann, Scott Byrne, and the other, anonymous, reviewer(s) for their contribution to the peer review of this work.
Additional information
Publisher’s note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Supplementary information
Source data
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. The images or other third party material in this article are included in the article’s Creative Commons license, unless indicated otherwise in a credit line to the material. If material is not included in the article’s Creative Commons license and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Gjølberg, T.T., Wik, J.A., Johannessen, H. et al. Antibody blockade of Jagged1 attenuates choroidal neovascularization. Nat Commun 14, 3109 (2023). https://doi.org/10.1038/s41467-023-38563-w
Received:
Accepted:
Published:
DOI: https://doi.org/10.1038/s41467-023-38563-w
- Springer Nature Limited