The study was conducted in compliance with the institutional review board of Kyoto Prefectural University of Medicine from which approval for the study was obtained (permission RBMR-C-864-6). The study adhered to the tenets of the Declaration of Helsinki. Aqueous humor samples from treatment naive patients with BRVO complicated by macular edema (n = 19) and age-matched controls (n = 18) were donated from the biobank of Kyoto Prefectural University Hospital, Kyoto, Japan, for proteomic analysis (Table 1). Informed consent to use samples from the biobank was obtained from all patients after explanation of the nature and possible consequences of the study. Statistical analysis by the Student's t-test was used to verify that there was no statistically significant difference in age between the BRVO group and the age-matched control group (Table 1). All patients in the BRVO group had BRVO complicated by macular edema and were treatment naive. Duration of macular edema less than 3 months was required. In the BRVO group, exclusion criteria were glaucoma including neovascular glaucoma, iris rubeosis, hyphema, retinal neovascularization, vitreous hemorrhage, previous retinal photocoagulation, and diabetes mellitus. Patients with BRVO who used any kind of eye drops 3 months prior to sample collection were also excluded. Control samples were from age-matched patients from whom aqueous humor samples were obtained prior to cataract surgery. Patients in the control group had no other disease than cataract. Best corrected visual acuity (BCVA) was measured as the logarithm of the minimum angle of resolution (logMAR). Swept Source OCT (DRI-OCT Triton; Topcon, Tokyo, Japan) was used for optical coherence tomography (OCT) examination. The severity of macular edema was measured as central retinal thickness (CRT) with the caliper tool of the Topcon OCT software. Fluorescein angiography was performed with confocal scanning laser ophthalmoscope (Heidelberg Retina Angiograph 2; Heidelberg Engineering, Heidelberg, Germany), and the area of retinal nonperfusion was measured in disc areas using the “draw lesion” tool in Heidelberg Retinal Angiography 2. 

For confirmation of key findings of the proteomic analysis, additional BRVO samples (n = 15) and control samples (n = 5) were acquired from the biobank for enzyme-linked immunosorbent assay (ELISA) (Table 2). Eight samples from the BRVO group were also used for proteomic analysis. BRVO samples and control samples were age-matched and selected according to the inclusion and exclusion criteria stated earlier. Statistical analysis by the Student's t-test was used to verify that there was no statistically significant difference in age between the BRVO group and the age-matched control group (Table 2). 

Samples were stored at −80°C until preparation was initiated. Protein concentrations were measured with an infrared spectrometer (Direct Detect, Darmstadt, Germany). Samples were prepared according to the S-Trap Micro spin column digestion protocol from ProtiFi (Huntington, NY, USA). The volume of each sample was measured, and an equal volume of 2 × SDS lysis buffer (10% SDS, 100 mM triethylammonium bicarbonate [TEAB], pH 7.55) was added. The samples were centrifuged at 13.000g for 8 minutes. Disulfide bonds were reduced by adding tris(2-carboxyethyl)phosphine hydrochloride (TCEP) to the protein solution in SDS to a final concentration of 10 mM, followed by heating for 10 minutes at 95°C. The protein solution was cooled to room temperature. Cysteines were alkylated by adding iodoacetamide to a final concentration of 40 mM. To the SDS lysate, 12% aqueous phosphoric acid at 1:10 was added to a final concentration of 1.2% phosphoric acid. S-Trap buffer (90% methanol, 100 mM TEAB) was added. The buffer mixture was transferred into a microcolumn followed by centrifugation at 4000g until the buffer had passed through the S-Trap column. S-Trap binding buffer was added, followed by centrifugation at 4000g. Washing with the S-Trap binding buffer was performed three times. The S-Trap microcolumn was moved to a new 1.7 mL sample tube for digestion. A total of 20 µL digestion buffer was added into the top of the microcolumn. The column was incubated overnight at 37°C. 

Peptides were eluted first with 40 µL of 50 mM TEAB and then with 0.2% formic acid. Elutions were centrifuged at 4000g. Hydrophobic peptides were recovered with an elution of 35 µL 50% acetonitrile containing 0.2% formic acid. Elutions were pooled. The peptide concentration was measured with a fluorescence-based technique with tryptophan used as a standard with an excitation at 295 nm and emission at 350 nm as previously described.¹⁹ Each sample was dried in a vacuum centrifuge and stored at −80°C. 

Samples were resuspended in 0.1% formic acid and analyzed with LFQ nLC-MS/MS. Of each sample, 0.7 to 1.0 µg was analyzed in triplicates. Mass spectrometry was performed on an Orbitrap Fusion Tribrid mass spectrometer (Thermo Fisher Scientific Instruments, Waltham, MA, USA) coupled to a Dionex UltiMate 3000 RSLC nano system (Thermo Fisher Scientific Instruments, Waltham, MA, USA). The mass spectrometer was equipped with an EasySpray ion source (Thermo Fisher Scientific Instruments). Liquid chromatography and label-free quantification (LFQ) were performed as described in a recent article²⁰ with few modifications. The orbitrap scan range (m/z) was 375 to 1500. The elution gradient was 3h, established by mixing buffer A (99.9% water and 0.1% formic acid) and buffer B (99.9% acetonitrile and 1% formic acid). Using the MaxQuant software version 1.6.6.0 (Max Planck Institute of Biochemistry, Martinsried, Germany; https://maxquant.net/maxquant/) for LFQ analysis,²¹ raw data files were searched against the UniProt Homo sapiens database (www.uniprot.org) downloaded on August 10, 2019. Settings for the database search were published in a previous work.²⁰ Unfiltered results of the database search are available in Supplementary File S1. 

Mass spectrometry data were further processed with Perseus software version 1.6.2.3 (Max Planck Institute of Biochemistry, Martinsried, Germany; https://maxquant.net/perseus/) to remove poorly identified proteins as described in a previous article.²² LFQ values were log₂ transformed, and mean LFQ values were calculated. At least two unique peptides were required for successful protein identification. Proteins were required to be successfully identified and quantified in at least 50% of the samples in each group. The median technical coefficient of variation was calculated for each of the proteins in each sample. The mean value for the samples was 11.3% (range, 6.49%–16.1%). 

Statistical analysis was performed on proteins that were successfully identified and quantified in at least 50% of the samples in the BRVO group and 50% of the samples in the control group. No imputation of missing values was performed prior to statistical analysis. Statistical analysis by the Student's t-test was conducted in Perseus to compare BRVO with controls. Furthermore, a subgroup analysis was performed to compare BRVO with greater than 5 disc areas of retinal nonperfusion and BRVO with less than or equal to 5 disc areas of retinal nonperfusion. Correction for multiple hypothesis testing was performed using the permutation-based method²³ in Perseus with the number of randomizations set to 250 and an S₀ parameter of 0.1. The false discovery rate was set to 0.05. CRT values were log₁₀ transformed prior to calculation of correlations to make the CRT values normally distributed. Correlations were calculated in STATA 16.0 (StataCorp, College Station, TX, USA) using Pearson's correlation coefficient (r). Correlations were considered statistically significant if P <0.05. Two-way scatter plots with prediction from a linear regression were created with STATA 16.0. 

Bioinformatic analysis of statistically significantly changed proteins was performed with GeneCodis software^24–26 (https://genecodis.genyo.es/) as previously described.²⁷ Cluster analysis of statistically significantly regulated proteins was performed with STRING 11.0 (string-db.org).^28–30 If more than one protein was listed in the IDs, the first listed UniProt ID was used for STRING analysis. If an isoform was not recognized by STRING, the regular UniProt ID without isoform was used. Cluster analysis was performed with the Markov Cluster Algorithm set to 2. 

Enzyme-Linked Immunosorbent Assay (ELISA) was performed to measure aqueous concentrations of fibronectin and VEGF in 15 BRVO samples and 5 controls (Table 2). ELISA was conducted with the ab219046 Human Fibronectin SimpleStep ELISA kit (Abcam, UK)^31,32 and the ab222510 Human VEGF SimpleStep ELISA Kit (Abcam, UK).³³ Samples for fibronectin quantification were diluted 1:250, and samples for VEGF quantification were diluted 1:2. Assay preparation was performed according to the manufacturer's instructions. A volume of 50 µL of standard or sample was added to the wells following addition of 50 µL antibody solution (1:10 capture antibody solution and 1:10 detector antibody in Antibody Diluent 4BR from the kit). The solutions were incubated for 1 hour at room temperature on a plate shaker set to 480 rpm. Each well was washed with 3 × 350 µL wash buffer (1:10 Wash Buffer PT 10X from ELISA kit, Abcam, UK, in deionized water). A volume of 100 µL of TMB Development Solution (Abcam, UK) was added to each well followed by incubation for 10 minutes in the dark on a plate shaker set to 480 rpm. A volume of 100 µL of Stop Solution (provided in kit) was added to each well and the plate was shaken on a plate shaker for 1 minute. The optical density was recorded at 450 nm. The Student's t-test and Pearson's correlation coefficient (r) were used for statistical analysis of the ELISA data. Differences and correlations were considered statistically significant if P <0.05. Two-way scatter plots based on ELISA data with prediction from a linear regression were created in STATA 16.0. 

A total of 1403 proteins were successfully identified in the combined set of aqueous samples (Supplementary File S2). A total of 242 aqueous humor proteins were successfully identified and quantified in at least 50% of the samples in each group (Supplementary File S3) and statistical analysis was performed on these proteins. 

After correction for multiple hypothesis testing, a total of 52 proteins were statistically significantly changed in content in BRVO compared with controls (Table 3, Fig. 1A). Among the 52 proteins that were changed in content, 26 proteins were increased in content following BRVO, whereas another 26 proteins were decreased in content in BRVO (Table 3). 

Proteins that were changed in expression level in BRVO compared with controls were involved in cell adhesion, blood coagulation, platelet activation, and platelet degranulation (Fig. 2). BRVO was also associated with response to lipopolysaccharide, chemotaxis, and acute-phase response (Fig. 2). Proteins with cell adhesion features included fibronectin, hyaluronan-binding protein 2 chain, testican-1, microfibrillar-associated protein 4, neural cell adhesion molecule 1, contactin-1, calsyntenin-1, galectin-3-binding protein, and reelin. Proteins involved in response to lipopolysaccharide included S100A7, S100A8, S100A9, lipopolysaccharide-binding protein (LBP), and monocyte differentiation antigen CD14 (CD14). Proteins with chemotactic features included complement C5, S100A8, S100A9, ectonucleotide pyrophosphatase, and heparin cofactor 2. LBP, fibronectin, prothrombin, and inter-alpha-trypsin inhibitor heavy chain H4 were identified as acute-phase response proteins. 

STRING cluster analysis revealed a major cluster of proteins consisting of fibronectin, fibrinogen chains, complement factors, and apolipoproteins (Fig. 3). Another cluster consisted of S100A7, S100A8, S100A9, CD14, LBP, and complement C1q subcomponent subunit B (Fig. 3). Furthermore, a cluster of reelin, neural cell adhesion molecule 1, and contactin-1 was identified. 

Eleven proteins were positively correlated to severity of macular edema, whereas two proteins were negatively correlated to severity of macular edema (Table 4, Figs. 4, 5). Proteins that were positively correlated to CRT included apolipoprotein C-III; complement C3; complement C5; complement factor H; fibrinogen chains α, β, and γ; fibronectin; heparin cofactor 2; as well as inter-alpha-trypsin inhibitor chain H1; and chain H4 (Table 4, Figs. 4, 5). Alpha-enolase and contactin-1 were negatively correlated to CRT (Table 4, Figs. 4K, 4L). 

Proteomic analysis revealed an increased level of fibronectin in BRVO compared with controls (fold change = 2.80, P = 0.0000011) (Table 3; Fig. 5A). ELISA confirmed that fibronectin was significantly elevated in BRVO (0.10 µg/mL) compared with control subjects (0.022 µg/mL) (P = 0.011) (Fig. 5B). Proteomic analysis identified a correlation between aqueous fibronectin and BCVA (r = 0.46; P = 0.049) (Fig. 5C) (Supplementary File S4). The correlation between fibronectin and BCVA was confirmed with ELISA (r = 0.56; P = 0.032) (Fig. 5D). Proteome analysis identified a statistically significant correlation between fibronectin and the severity of macular edema measured as CRT (r = 0.60; P = 0.0061) (Table 4; Fig. 5E). This correlation was confirmed with ELISA (r = 0.53; P = 0.042) (Fig. 5F). Aqueous fibronectin correlated with VEGF in the BRVO samples (r = 0.70; P = 0.0039) (Fig. 6) (Supplementary File S5). 

Subgroup analysis revealed that the aqueous fibronectin content was higher in BRVO with greater than 5 disc areas of retinal nonperfusion compared with BRVO with less than or equal to 5 disc areas of retinal nonperfusion (fold change = 2.88; P = 0.00013) (Fig. 1B, Table 5). A total of 31 proteins were significantly different in BRVO with greater than 5 disc areas of nonperfusion compared with BRVO with less than or equal to 5 disc areas of nonperfusion (Fig. 1B, Table 5). Patients with BRVO and greater than 5 disc areas of retinal nonperfusion had higher aqueous levels of fibrinogen chains, apolipoprotein C-III, and apolipoprotein A-IV, and lower aqueous levels of amyloid-like protein 2, contactin-1, reelin, and alpha-enolase (Table 5). 

The presented study aimed at identifying large-scale protein changes in aqueous humor from patients with BRVO giving insights into intraocular molecular changes of the condition. A multitude of proteins were regulated in BRVO compared with age-matched controls. Protein changes were generally more pronounced in BRVO with greater than 5 disc areas of retinal nonperfusion. Multiple proteins were correlated to severity of macular edema indicating a multifactorial nature of the condition. 

Fibronectin correlated with BCVA and severity of macular edema. Fibronectin is a 230 to 270 kDa glycoprotein that exists in a soluble form and an insoluble form.^34–36 The soluble form in the aqueous humor regulates thrombosis and accelerates wound healing.^35,36 At the wall of injured vessels the soluble form of fibronectin is rapidly deposited and promotes platelet aggregation when linked with fibrin.³⁷ Our data indicated that the increased level of fibronectin was associated with retinal ischemia as the content of fibronectin was higher in BRVO with greater than 5 disc areas of retinal nonperfusion. The correlation between fibronectin and BCVA may be explained by the fact that fibronectin was associated with severity of macular edema and retinal nonperfusion, which are complications that cause visual impairment in BRVO. A strong correlation between fibronectin and VEGF was observed in BRVO. The increased level of fibronectin in BRVO may reflect a stage of increased VEGF-driven vascular permeability with leakage of fibronectin. In summary, aqueous fibronectin may be an indicator of the severity of BRVO. 

The plasma proteins, such as fibrinogen chains, apolipoproteins, and complement factors, were upregulated in BRVO and correlated with severity of macular edema. The upregulation of the mentioned plasma proteins may represent an activation of the coagulation cascade, as well as a disruption of the blood-retinal barrier that results in leakage of plasma proteins.^11,17 Patients with BRVO and greater than 5 disc areas of retinal nonperfusion had higher levels of fibrinogen chains, apolipoproteins, and complement factors, which may be explained by increased vascular permeability due to ischemia.^9,10,38,39 BRVO was associated with regulation of proteins involved in “response to lipopolysaccharide,” including the proinflammatory proteins LBP, CD14, S100A7, S100A8, and S100A9 (Fig. 2). Lipopolysaccharide is the major component of the outer membrane of gram-negative bacteria. Recognition of lipopolysaccharide requires LBP, CD14, and Toll-like receptor 4 (TLR4) that have regulatory functions in the innate immune system.^40,41 LBP and CD14 may contribute to the inflammatory response in BRVO, but did not correlate with severity of macular edema and BCVA. 

S100A7, S100A8, and S100A9 belong to the S100 protein family of small calcium-binding proteins⁴² that contribute to lipopolysaccharide response in a TLR4 dependent manner.⁴² We have previously suggested that proteins of the S100 family are regulated in retinal vein occlusion²² and our study indicates that the turnover of S100 proteins is altered in BRVO. However, the S100 proteins did not correlate with CRT and BCVA, and our data does not provide an underlying explanation for the S100 regulation. 

Alpha-enolase and contactin-1 were negatively correlated to CRT. BRVO patients with greater than 5 disc diameters of retinal nonperfusion had lower levels of both proteins, indicating that their regulation is related to retinal ischemia. Alpha-enolase is a glycolytic enzyme known to be expressed in the cytoplasm and on cell membranes of retinal ganglion cells, Müller cells, cones, and rods.⁴³ Changes in retinal alpha-enolase have been observed following experimental retinal detachment,⁴⁴ suggesting that the protein is sensitive to retinal stress. Contactin-1 is a cell adhesion protein involved in axonal organization in early central nervous system development.⁴⁵ Retinal contactin-1 has been found to be downregulated following hyperglycemia,⁴⁶ indicating that contactin-1 is downregulated in retinal stress. 

Arterial hypertension is a well-documented risk factor in BRVO.⁴⁷ It is a limitation of this study that data on arterial hypertension were not available for patients who donated aqueous samples to the biobank. Although our study achieved good coverage of the aqueous proteome, detection of low abundance proteins remains a challenge in discovery-type proteomics.^11,17 For example, low-abundant proteins, such as VEGF, interleukin-6, and interleukin-8, were not identified in our proteome analysis and VEGF quantification with ELISA was necessary. Detection of low abundance proteins with discovery-type proteomics is limited by a number of factors including sample complexity, technical variation, and fragmentation efficiency. Sample complexity with high dynamic ranges of protein abundances makes detection of low-abundant proteins difficult as protein abundances may stretch over 13 orders of magnitude depending on the material under study.⁴⁸ Low abundance proteins tend to yield larger spectral count variation resulting in underestimation of differences in expression level.⁴⁹ Fragmentation efficiency of tryptic peptides remains a limiting factor in identification of lowly abundant proteins.⁴⁸ Furthermore, low-abundant proteins with low molecular weight, for example interleukin-8, yield very few tryptic peptides, which makes them complicated to identify with mass spectrometry.⁵⁰ 

The sample material is another limitation of our study. Key proteins identified with proteomic techniques may correlate with growth factors and cytokines known to be associated with macular edema in BRVO. For example, the samples could also have been screened for inflammatory proteins, such as interleukin-6 and interleukin-8. Owing to the low volume and the low protein concentration of the aqueous samples, we only had sufficient sample material to verify the correlation between fibronectin and VEGF. 

BRVO was associated with multiple aqueous protein changes. Proteome changes were more pronounced in BRVO with greater than 5 disc areas of retinal nonperfusion. Fibronectin was increased in BRVO and higher in BRVO with greater than 5 disc areas of retinal nonperfusion. Fibronectin correlated with BCVA, severity of macular edema and VEGF. Our findings suggest that aqueous fibronectin may reflect severity and vascular permeability in BRVO. Multiple proteins were correlated to the size of macular edema indicating that macular edema is a multifactorial complication. The plasma proteins apolipoprotein C-III, complement C3, complement C5, complement factor H, and fibrinogen chains were increased in BRVO and correlated with severity of macular edema. Alpha-enolase and contactin-1 were negatively correlated with severity of macular edema. Our study indicated that the expression of alpha-enolase and contactin-1 is related to retinal nonperfusion. The proinflammatory proteins LBP, CD14, S100A7, S100A8, and S100A9 were regulated in BRVO and may contribute to an inflammatory response in BRVO. 

The authors thank Mona Britt Hansen, Aarhus University, Aarhus, Denmark, for her expert technical assistance; and Orthoptist Roy Ewan, Department of Ophthalmology, Odense University Hospital, Odense, Denmark, for assisting the authors with English editing of the manuscript. The authors thank Fight for Sight Denmark, Helene og Viggo Bruuns Fond, the Svend Andersen Foundation, Synoptik-Fonden, the Herta Christensen Foundation, the North Denmark Region (2013-0076797), Speciallæge Heinrich Kopps Legat, and the Danish Ophthalmological Society for their generous support. The mass spectrometers used for the study were funded by A.P. Møller og Hustru Chastine Mc-Kinney Møllers Fond til almene Formaal. 

Disclosure: L.J. Cehofski, None; K. Kojima, None; N. Terao, None; K. Kitazawa, None; S. Thineshkumar, None; J. Grauslund, None; H. Vorum, None; B. Honoré, None