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Published in final edited form as: Clin Immunol. 2019 Nov 23;210:108317. doi: 10.1016/j.clim.2019.108317

Occurrence of Major Anti-retinal Autoantibodies Associated with Paraneoplastic Autoimmune Retinopathy

Grazyna Adamus 1,*, Rachel Champaigne 1, Sufang Yang 1
PMCID: PMC6989367  NIHMSID: NIHMS1545913  PMID: 31770612

Abstract

Autoantibodies (AAbs) against retinal antigens can be found in patients with cancer and unexplained vision loss unrelated to the cancer metastasis. Cancer-associated retinopathy (CAR) is a rare paraneoplastic visual syndrome mediated by AAbs. Our goal was to determine whether CAR patients with different malignancies have a specific AAb or repertoire of AAbs that could serve as biomarkers for retinal disease. We found AAbs against 12 confirmed retinal antigens, with α-enolase being the most frequently recognized. The significant finding of the study was a high incidence of anti-aldolase AAbs in colon-CAR, anti-CAII in prostate-CAR, and anti-arrestin in skin melanoma patients thus these AAbs could serve as biomarkers in the context of clinical presentation and could support the diagnosis of CAR. However, a lack of AAb restriction to any one antigenic protein or to one retinal cellular location makes screening for a CAR biomarker challenging.

1. INRODUCTION

There are autoimmune conditions of the retina that occur almost exclusively as paraneoplastic manifestations of cancer. Paraneoplastic retinopathy is rare. It is characterized by unexplained loss of vision associated with retinal dysfunction/degeneration, distant malignancy, and the presence of serum anti-retinal autoantibodies (AAbs). The most common visual paraneoplastic disorders include cancer-associated retinopathy (CAR) and melanoma–associated retinopathy (MAR)[13]. CAR is defined as an autoantibody-driven remote effect of systemic cancer that is associated with retinal degeneration that is not caused by tumor metastasis. Although the role of autoimmunity in retinal degeneration has not been fully explained, experimental and clinical studies corroborate that anti-retinal AAbs in high titers can penetrate into the retina, affecting function of the target antigens and, in turn, leading to retinal dysfunction and degeneration [4]. In general, about 1% of patients with cancer are estimated to be affected by various paraneoplastic syndromes and fewer related to the eye [5].

In visual paraneoplastic disorders, AAb responses are believed to be part of the anti-tumor response, triggered by tumor antigens that are released during tumor growth (neoantigens) and processed by antigen-presenting cells [6]. The persistent presence of anti-retinal AAbs is the serological hallmark of CAR and represents one of its required classification criterion [7]. Detectable levels of anti-retinal AAbs are present for many years and vision problems may manifest before detecting malignancy thus serum AAbs would have a strong predictive value in CAR/MAR [810]. The occurrence of an autoimmune retinal disease, including CAR might not require a new autoimmunization, but rather is a loss of control in the existing autoimmunity [11]. In addition, AAbs also occur in the presence of malignancy without paraneoplastic manifestation [12, 13]. However, sera of individuals prior to vision loss are not available, thus we cannot establish the exact timeline between the AAb generation and clinical manifestation of visual problems. It precludes us from full understanding the mechanisms that regulate such a transition.

Usually, patients with autoimmune retinopathies have a small number of anti-retinal AAbs. We are interested in a discovery of AAb profiles that are associated with unexplained vision loss that could forecast CAR or malignancy with a high probability, and in providing an immunopathogenic understanding of syndrome [1417]. Unfortunately, CAR is rare, highly heterogeneous and complex, considering that patients differ not only in antibody profiles but also in their clinical presentation. Our approach to the analysis of AAbs in such patients was based on an unbiased western blotting methodology and immunostaining of retina with serum. This approach revealed 12 clinically relevant AAbs that were detected at high frequencies. We hypothesized that CAR patients with different malignancies have a specific AAb or specific repertoire of AAbs that could serve as biomarkers for different type of CAR. Here, we present results from retrospective study of the largest cohort of seropositive patients until today with unexplained vision loss in the presence of different malignancies.

2. METHODS

2.1. Study population

Human subjects research was approved by the by the OHSU Institutional Review Board. Our research adhered to the tenets of the Declaration of Helsinki. All patient samples were originally deposited to the Autoimmune Retinopathy Serum Research Repository OHSU under approval by the OHSU Institutional Review Board. Samples used in this study were de-identified, and stored at −80°C, and results cannot be linked to subjects. We reviewed serum samples tested for AAbs from 2014 to 2017 and selected those that met our criteria as follows: progressive nature of vision loss, visual field defects, abnormal rod and/or cone responses on the ERG, and a diagnosed cancer that often triggered the suspicion of CAR. We selected seropositive patients with cancer that included 271 females and 170 males, showing a slight female predominance (F/M ratio 1.6 to 1). The average age of a CAR patient was 66 ±13 years old. These patients had been diagnosed with 20 different kinds of cancers (CAR group). Patients with malignant melanoma were included in the “CAR group”. We present findings for 441 seropositive patients for AAbs against 12 retinal autoantigens. There were additional 54 seronegative patients with cancer that met the selection criteria. We do not know whether these patients developed AAbs in the later time (they were not re-tested). For comparison, we included 127 sera of healthy individuals that have been examined for anti-retinal AAbs.

Selection of Frequent Autoantibodies

Initially, patient’s sera were analyzed by western blotting using human retinal extract according to previously published methods [18]. A verification of specificity of anti-retinal antibodies required an additional immunoblotting with purified or recombinant proteins of the appropriate molecular mass and the use of specific antibodies against those proteins (positive controls). The antigen identity was confirmed by immunoreactivity with 12 retinal proteins that included recoverin and retinal arrestin, heat shock protein 27 (HSP27), Rab6A GTPase, carbonic anhydrase II (CAII), cellular-retinaldehyde binding protein (CRALB), α-tubulin, glyceraldehyde 3-phosphate dehydrogenase (GAPDH), aldolase C, α-enolase, pyruvate kinase M2 (PKM2) and P62 (HSP60) [19]. Details are presented in Table 1. Only patients whose sera were verified for antibody specificity have been the focus of this study.

Table 1:

List of control proteins and antibodies used in the study

Antigen Molecular Mass Protein Name Source Control Antibody Source
23-kDa Recombinant Recoverin Purified in the lab Rat MAb anti-recoverin Made in the lab
23-kDa Recombinant HSP27 R&D Mouse anti-human HSP27 Thermo Fisher Scientific
23-kDa Recombinant Rab6A NOVUS Rabbit anti-human Rab6A NOVUS
30-kDa Purified CAII Sigma Sheep anti-human CAII Invitrogen
34-kDa Recombinant CRALBP NOVUS Rabbit anti-human CRALBP Thermo Fisher
36-kDa Purified GADPH Sigma Rabbit anti-human GADPH Sigma
40-kDa Aldolase C MP Biomedical Rabbit anti-aldolase C Cell Signaling Technology
46-kDa Purified retinal α-Enolase Purified in the lab Rat MAb anti-α-enolase Made in the lab
48-kDa Purfied retinal Arrestin Purified in the lab Mouse MAb anti-arrestin Made in the lab
52-kDa Purified Tubulin-α Sigma Goat anti-human tubulin-α Santa Cruz
56-kDa Recombinant PKM2 NOVUS Rabbit anti-human PKM2 Invitrogen
62-kDa Recombinant HSP60 StressMarq Rabbit anti-human HSP60 Cell signaling Technology
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2.2. Immunohistochemistry (IHC)

Donor human retina was fixed 1 hr in 4% paraformaldehyde and then 30% sucrose overnight. Retinal tissue was frozen in OCT as previously described [9]. Twelve microns tissue cryosections were prepared and then incubated with human serum diluted 1:30 [18]. A reference human serum, containing anti-recoverin antibodies was used as a positive control. A negative control contained secondary antibodies only. Color reaction was developed using peroxidase substrate (Pierce) for 15 min and then the tissue was counterstained with methyl green.

2.3. Statistics

The patients’ data were sorted according to their AAb positivity, cancer presence, and clinical manifestation. The Fisher’s exact test was used to compare the prevalence of positive antibodies between cases and healthy controls. ANOVA tests were performed to find statistical significant differences between CAR and control samples. Statistical significance values are as follows: *p< 0.05, **p<0.01, ***p<0.001, and ****p<0.0001. The analysis was performed using the GraphPad Prism 5.0a software.

3. RESULTS

3.1. Prevalence of Autoantibodies

A broad spectrum of antibody reactivities was observed in the series of 441 patients with cancer and unexplained vision loss. In the search for a potential target for those AAbs, we identified 12 retinal autoantigens that represented photoreceptor-specific proteins, such as recoverin, retinal arrestin, CRALBP, and the small GTPase Rab6, 2 heat shock proteins HSP27 and P62 (HSP60), CAII, α-tubulin, and 4 glycolytic enzymatic proteins that were also found in the outer segments of photoreceptor cells: GAPDH, aldolase C, α-enolase, and PKM2 [20, 21]. The occurrence of CAR AAbs was compared to those revealed in the control group and the results showed that AAbs were more frequent in the CAR group (p=0.0025), including AAbs against ubiquitous antigens, such as aldolase, enolase, GADPH, and CAII. The prevalence of specific AAbs in both groups is presented in Table 2. Reactivities against recoverin, Rab6 and CRALBP proteins were not detected in healthy individuals. The positivity rate in CAR for a single AAbs was 37% and 25% patients had double positivity, 14% had triple AAbs, 6% 4 AAbs, and 1% had 5 AAbs. This suggests that an increased number of specific AAbs was more strongly associated with CAR. Moreover, few specific AAbs occurred in same patient that created antibody profiles related to the patient.

Table 2.

Frequency of anti-retinal autoantibodies against 12 autoantigens in normal individuals and patients with cancer and vision loss

Antigen Normal (N=127) CAR (N=441)
Aldolase 5% 16%
Arrestin 2% 14%
CAII 15% 28%
CRALBP 0 3%
Enolase 13% 43%
GAPDH 11% 17%
HSP27 1% 4%
p62 2% 15%
PKM2 4% 8%
Rab6 0 5%
Recoverin 0 3%
Tubulin 2% 5%
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3.2. Cellular Targets of Anti-retinal Autoantibodies

The immunostaining of human retina by different serum samples was dependent on the combination of specificity and location of target antigens in retina. Because most patients had more than 1 anti-retinal AAbs detected by western blotting it was not surprising serum AAbs shows diverse patterns of the retina immunostaining. Examples of such immunostaining are represented in Figure 1. AAbs that were against photoreceptor cell antigens immunostained outer segments (Fig. 1 CEJ), outer and inner segments (Fig 1 DIK), or the whole photoreceptor cells (Fig. 1 BK). AAbs against enolase usually stained the ganglion cell layer (Fig. 1 DFHIKL).

Figure 1.

Figure 1.

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Patterns of immunostaining of human retina cryosections with serum anti-retinal autoantibodies. Immunoperoxidase staining depended on antibody specificities and accessibility to the antigen in the tissue : (A) control staining, no serum, only secondary antibodies; (B) labeling of Ph layer; (C) labeling of OS in photoreceptor cells; (D) labeling of OS and IS in photoreceptor cells and GCL and NF; (E) labeling of OS and the junction between the IS and OS of rod and cone photoreceptors (F) labeling of OLM; (G) labeling of ONL and INL; (H) labeling of Ph cells, INL, IPL, GCL; (I) labeling of OS and IS and IPL and GCL; (J) labeling of OS of rods and cones, and outer limiting membrane; (K) Labeling of Ph cells, INL and GCL; and (L) labeling of IPL and GCL; Retinal layers are: OS, outer segments; IS, inner segments; Ph, photoreceptors; OLM, outer limiting membrane; ONL, outer nuclear layer; OPL, outer plexiform layer; INL, inner nuclear layer; IPL, inner plexiform layer; and GCL, ganglion cell layer; NF, nerve fiber layer. Arrows point at strongest immunostaining.

3.3. Correlation of Autoantibodies with Tumors in CAR

There were at least 20 different undelaying tumors reported in association of 12 specific AAbs with the most frequent being breast cancer (22%), malignant skin melanoma (19%), lung cancer (11%; SCCL, NSCCL, adenocarcinoma), and gynecologic cancers (8%; ovarian, endometrial, uterine, and cervical). Cancers like prostate, colon, thyroid cancers, and lymphomas occurred at lower incidence in association with ocular disturbances (Table 3). Figure 2 shows the occurrence of vision loss in the relation to cancer diagnosis. The majority of patients (85%) reported vision loss months to years after diagnosis of cancer and 15% developed vision problems around the time of cancer diagnosis (in particular, patients with lung cancers) or vision loss was preceding a discovery of their malignancies. The median time delay between finding cancer and ocular symptoms was ~3 years (ranged from 0 to 15 years).

Table 3:

Occurrence of cancers associated with vision loss and the presence of anti-retinal autoantibodies

Cancer (n=441) Total (N) %
Bladder 12 3%
Brain 7 2%
Breast 96 22%
Colon 21 5%
Esophagus 3 >1%
Gynecological (ovarian, endometrial, uterine, cervical) 32 7%
Leukemia 9 2%
Liver 8 2%
Lung (SCCL, NSCCL, adenocarcinoma) 47 11%
Lymphoma 17 4%
Melanoma 82 19%
Multiple myeloma 5 1%
Pancreas 7 2%
Pituitary 5 1%
Prostate 30 7%
Renal 4 1%
Sarcoma 3 >1%
Skin, not melanoma 14 3%
Testis 4 1%
Thyroid 16 4%
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Figure 2.

Figure 2.

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A diagram showing the latency between the occurrence of vision loss and cancer diagnosis illustrated for breast bladder, colon, gynecological cancers (GYN), melanoma, lung, prostate, and thyroid cancers. The median time delay between finding cancer and ocular symptoms was ~3 years (dotted line).

The frequency of specific AAbs differed in subgroups of cancer patients. The most frequent were anti-α-enolase AAbs (43%), followed by anti-CAII (28%), anti-GADPH (17%), anti-aldolase C (16%), anti-P62 (15%), anti-arrestin (14%), anti-PKM2 (8%), anti-tubulin-α (5%), anti-Rab6 (5%), anti-HSP27 (4%), anti-recoverin (3%), and anti-CRALBP (3%) AAbs. Some AAbs revealed strong association with particular cancers. As an example Figure 3 shows statistically relevant incidence of AAbs in breast, colon, prostate, lung cancers and melanoma. Anti-CAII AAbs were found more frequent in prostate-CAR (50%; p<0.0001), breast-CAR (32%; p=0.0003), and others, implying that AAbs against ubiquitous proteins cannot be ignored when evaluating results from the antibody screening. This includes AAbs against glycolytic enzymes (enolase, aldolase, GADPH, PKM2) that were significantly elevated in patients than those in healthy controls. A unique new finding was a high incidence of anti-aldolase C AAbs in 53% patients with colon cancer (p<0.0001), and anti-GAPDH AAbs in gynecological cancers (27%; p=0.0050) where in other cancers these AAbs were detected below 15% rate (Figure 2). Anti-PKM2 AAbs were present in 33% bladder-CAR, 19% breast-CAR, and 16% colon-CAR. Another remarkable finding was a detection of anti-arrestin AAbs in thyroid-CAR (33%), breast-CAR (23%), colon-CAR (21%), bladder-CAR (22%), and melanoma (15%, p=0.0023). Anti-Rab6 AAbs were associated with prostate-CAR and bladder-CAR at 11% frequencies. Anti-CRALBP AAbs were the most frequent in thyroid-CAR (20%). Anti-tubulin-α AAbs were strongly associated with patients with liver malignancy (60%). Anti-P62 AAbs were frequently detected in thyroid-CAR (19%) and gynecological-CAR (19%), and in 17% of lung-CAR patients (p=0.00176). Anti-recoverin AAbs were found at low frequencies and always with 3 or more of other anti-retinal AAbs. The odd ratio, sensitivity and specificity, a positive test result and a negative test result respectively, differed depending on AAbs and the overview is shown in Table 4. The results showed a very high sensitivity and moderate specificity for all autoantigens. For anti-recoverin, anti-CRAMBP, and anti-Rab6, the calculation is not included in the table because the small sample size and their absence in the control group, limited obtaining meaningful results.

Figure 3.

Figure 3.

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Prevalence of specific anti-retinal autoantibodies in normal subjects and patients with different cancers. Statistically significant increases of AAbs was determined for: (A) anti-recoverin AAbs in breast-CAR; B - anti-GADPH in breast-CAR; C – anti-aldolase AAbs in colon-CAR; D – anti-CAII AAbs in prostate-CAR; E – anti-arrestin AAbs in melanoma-CAR; and F – anti-P62 AAbs in lung-CAR. Open bars – negative, black bars – positive for antibodies

Table 4.

Analysis of Contingency Table: Overview

Table Analyzed P value Odds ratio 95% CI Sensitivity 95% CI Sperifidty 95% CI PPV 95% CI NPV 95%
Aldolase 0.0009 3.741 1.584 to 8.833 92% 0.8340 to 0.9701 25% 0.2081 to 0.2859 16% 0.1238 to 0.1938 95% 0.9000 to 0.9825
Arrestin <.0001 6.509 2.005 to 21.13 95% 0.8671 to 0.9901 25% 0.2086 to 0.2855 14% 0.1055 to 0.1716 98% 0.9325 to 0.9951
CAII 0.0025 2.223 1.309 to 3.778 87% 0.8003 to 0.9181 25% 0.2134 to 0.2983 28% 0.2397 to 0.3256 85% 0.7763 to 0.9075
Enolase <0.0001 5.203 2.981 to 9.083 92% 0.8763 to 0.9547 31% 0.2588 to 0.3560 43% 0.3819 to 0.4762 87% 0.8035 to 0.9262
GADPH 0.0009 3.741 1.584 to 8.833 92% 0.8340 to 0.9701 25% 0.2081 to 0.2859 16% 0.1238 to 0.1938 95% 0.9000 to 0.9825
HSP27 0.0906 5.362 0.7084 to 40.58 95% 0.7397 to 0.9987 23% 0.1950 to 0.2670 4% 0.02437 to 0.06374 99% 0.9569 to 0.9998
p62 <0.0001 10.37 2.503 to 42.93 97% 0.8992 to 0.9965 24% 0.2007 to 0.2749 14% 0.1120 to 0.1771 98% 0.9443 to 0.9981
PKM2 0.122 2.235 0.8592 to 5.812 88% 0.7437 to 0.9602 23% 0.1965 to 0.2704 8% 0.05976 to 0.1138 96% 0.9105 to 0.9871
Tubulin 0.2306 2.274 0.6714 to 7.704 88% 0.6985 to 0.9755 23% 0.1941 to 0.2665 5% 0.03334 to 0.07723 98% 0.9325 to 0.9951
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3.4. Association of Autoantibodies with Symptoms

The next question was whether specific anti-retinal AAbs are associated with retinal disease symptoms. Our analysis of clinical data showed that not every patient displayed all symptoms typical of CAR, likely because their disease was at different stage when sera were collected and tested for AAbs. Figure 4 comprises the patients’ symptoms and findings with the most frequently occurring specific AAbs. Vision loss was painless and bilateral, and was sudden (7%) or subacute (10%). Sudden onset of vision loss was more often related to anti-recoverin, anti-P62, and anti-arrestin AAbs. Some patients complained of night vision problems (nyctalopia, 15%), and light sensitivity (14%). Visual testing revealed the loss of visual acuity (42%), color vision loss (15%), and visual field testing showed peripheral and ring scotomas (32%). The ERG was abnormal, presenting defects in rod and cone functions (29%). Mild intraocular inflammation (iritis, vitritis) was occasionally present (9%) in association with anti-arrestin and anti-CAII AAbs. In Table 5 summarizes the major findings related to anti-retinal AAbs and 9 most common cancers in CAR. Overall, these results suggest that an increased prevalence of at least some AAbs in the context of ocular presentation may help with diagnosis of CAR.

Figure 4.

Figure 4.

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A diagram demonstrating the correlation between ocular symptoms and findings and the most frequent anti-retinal autoantibodies in patients; VF, visual field

Table 5:

Association of anti-retinal autoantibodies with 9 most common cancers in cancer-associated retinopathy (CAR)

Cancer Incidence of cancer Most frequent AAbs against retinal markers Time from AAbs detection to cancer diagnosis Major symptoms and findings
Breast 22% (96/441) Enolase, GAPDH, CAII, recoverin Mostly after or at the time of diagnosis Photopsia/photophobia, VA loss, ffERG dysfunction, pigmentary changes
Gynecological (ovarian, endometrial, uterine, cervical) 7% (33/441) GAPDH, aldolase, enolase Can precede, mostly after Progressive course, blurry vision, photopsia, VA loss, VF defect, retinal thinning
Lung (SCCL, NSCCL, adenocarcinoma) 11% (47/441) Enolase, p62, CAII Can precede Sudden onset, color vision loss, retinal thinning, vascular abnormalities
Colon 5% (21/441) Aldolase, CAII, enolase, (arrestin, recoverin) Can precede Sudden onset, progressive course, blurry vision, central vision loss, color vision loss, cone-ffERG dysfunction, retinal thinning
Prostate 8% (35/441) CAII, recoverin Can precede Progressive course, nyctalopia, VF defects, ERG dysfunction, attenuated vessels
Thyroid 4% (16/441) Enolase, arrestin At the time diagnosis or after Photopsia/photophobia, peripheral vision loss, VA loss, rod-ffERG dysfunction, retinal thinning
Melanoma 18% (78/441) Enolase, CAII, arrestin After Gradual loss, nyctalopia, VA loss, rod-ERG dysfunction
Lymphomas 4% (17/441) Arrestin, Enolase, p62 After VA loss, VF loss
Bladder 3% (12/441) CAII, Enolase, GADPH At the time diagnosis or after Progressive course, VA loss, ERG dysfunction; color vison loss
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VA = visual acuity, ERG = electroretinogram; VF = visual field

DISCUSSION

In recent years, several anti-retinal AAbs have been found in association with CAR [22, 23]. Our immunological studies identified 12 targets for AAbs that were frequently detected in the largest group of patients with unexplained vision loss and cancer so far. This study has demonstrated a striking lack of restriction of AAbs to any one antigenic protein or one retinal cellular location, thus screening for an antibody CAR marker is challenging. The complexity of cancer, degeneration of retina, and the immune response differed vastly between people and cancer type.

In the past, it has been speculated that anti-recoverin AAbs are the sole biomarker of CAR and other associated AAbs may be indirectly or synergistically involved. However, previous and current studies confirmed that anti-recoverin AAbs are rare [21]. Consequently, an absence of AAbs against recoverin does not exclude the diagnosis of paraneoplastic retinopathy in patients with the appropriate clinical profile of this disease. There are other specific AAbs present in patents at much higher frequencies in association with unexplained vision loss.

Anti-α-enolase AAbs were the most frequently found in patients with different tumors and had the highest incident in breast cancer, followed by prostate and thyroid carcinomas, and malignant melanoma. These antibodies are less predictive of associated neoplasm than are anti-recoverin AAbs [14]. The occurrence of anti-glycolytic enzymes antibodies (enolase, aldolase C, and GAPDH) was 2–3 times more frequent in CAR with gynecological cancers than normal women [17]. Glycolytic enzymes are highly expressed in the outer segment of photoreceptor cells as well as in other retinal cells, also in the majority of cancers related to paraneoplastic retinopathy [24, 25]. It is reasonable to assume that the overexpressed glycolytic antigens may elicit a humoral immunity, and in effect, attack the tumor and the retina [26]. Therefore, the generation of anti-enolase AAbs is a likely consequence of the uptake of enolase by antigen-presenting cells at the tumor site and subsequent B cell activation [26]. Healthy individuals also have some serum AAbs against retinal antigens, which makes a difficult interpretation of clinical significance of such findings. However, we have showed in the past that normal individuals had anti-enolase AAbs that bound to different epitopes [27] and were at lower incidence as compare to that of control AAbs of the same specificity. In general, the reason for the presence and abundance of AAbs in human sera, especially in younger and healthy individuals, is unknown. Some AAbs may be remnants of past immunological activities in infectious disease, but may also be present as a result of ongoing current disease [6]. Another potential source of those antigenic components is cancer (neoantigens), undergoing cell death due to anti-tumor response and necrosis, and the generation of AAbs as a direct consequence of the autoimmune process [6].

This study shows that at least some AAbs have a biomarker potential that includes the high frequency of anti-aldolase AAbs with colon-CAR. Finding anti-aldolase AAb responses in association with colon cancer may not be surprising because the aldolase protein is overexpressed in colorectal cancers and therefore, such an increased presence of this antigen could predispose the immune system to elicit anti-aldolase humoral response [28]. It is also important to mention that photoreceptor specific antigenic proteins (arrestin, recoverin, and rhodopsin) were also found to be expressed in different tumors (i.e. renal cell carcinoma, thyroid cancer, melanoma) and are considered to be a new class of cancer antigens (i.e. cancer-retina antigens) [29, 30]. The presence of anti-retinal AAbs in a patient with a history of cancer could be indicative of cancer recurrence, which is of primary concern, even in a patient who does not have typical paraneoplastic anti-retinal AAbs.

We detected anti-arrestin AAbs in thyroid-CAR, colon-CAR, bladder-CAR, and MAR, which coincides with the expression of arrestins in those tumors. Retinal arrestin (also called S-antigen) has been found to be a major pathogenic antigen in autoimmune uveitis [31]. Arrestins were initially discovered in the visual phototransduction system and include four mammalian members, two visual arrestin-1 in rod cells, arrestin-4 in cone cells, and two non-visual β-arrestin1 and β-arrestin 2 (also called arrestin-2 and arrestin-3) respectively [32]. β-Arrestins are overexpressed in late-stage cancers, such as human glioblastomas, breast cancer, and melanoma and act on the tumor cell proliferation, apoptosis, migration, and invasion [29, 33]. The expression of arrestins in different tumors is a potential source of the anti-arrestin autoimmune response. Altogether, these findings suggest that the occurrence of specific AAbs may correspond to differences in cellular location of antigens, availability of the antigen, duration of antibody exposure to its antigen, and immunopathological mechanisms CAR. It remains to be determined whether the autoantibody represents secondary autoimmunity (progression of retinal damage) or is a product of disease heterogeneity.

Due to AAbs presence in the general population as well as in multiple autoimmune diseases, showing the presence of AAbs alone does not make a diagnosis. Such results have to be interpreted in the context of clinical findings. Similarly, the absence of autoantibody does not exclude a disease. The initial AAb test result may be negative for retinal antigens but then AAbs develop over time, especially, if retinal disease progresses. Autoantibodies might not be directly responsible for the manifestation of the diseases; they could still be highly sensitive and specific marker to detect disease. Moreover, many different cell types have the same common proteins and only a very small subset of protein targets and their corresponding AAbs would be expected to be truly cell-type/disease-specific, and thus useful for disease detection and diagnosis. This process may depend on the protein accessibility in the cell and protective mechanism in the cell against adverse reaction [34, 35].

We recognize that this study has some limitations. CAR is rare and the ambiguity of its clinical picture on presentation, and limited access to clinical data in some cases makes the study difficult. To predict the development of CAR based on the AAbs presence alone or vision loss alone is problematic therefore test results must be interpreted in the context of clinical presentation. Also, our ethnic population consists of mainly of Caucasian individuals therefore the results are largely relevant for this group of patients. And finally, we limited our study to 12 autoantigens that were identified and verified but there might be others, awaiting a future discovery. Identification and verification of a discrete antigen in association with specific symptoms is very costly and therefore most antigenic proteins are known by their molecular mass. Thus, our investigation should be considered as a work-in-progress with the potential for future development of a bigger library of verified CAR autoantigens to help the medical community with better diagnosis and management strategies for their patients.

Highlights.

  • There is an association between the presence of anti-retinal autoantibodies, ocular symptoms and tumors in cancer-associated retinopathy (CAR)

  • Multiple autoantibody are detected in association with different kinds of cancer creating antibody signatures specific to patients

  • Some AAbs have a biomarker potential that includes the high frequency of anti-aldolase AAbs with colon-CAR

  • Anti-carbonic anhydrase II autoantibodies are frequently present in prostate-CAR

ACKNOWLEDGEMENT

Funding/Support: This work was supported by grant P30 EY010572 from the National Institutes of Health (Bethesda, MD) and by unrestricted departmental funding from Research to Prevent Blindness (New York, NY)

Abbreviations used in the paper

AAbs

autoantibodies

AR

autoimmune retinopathy

CAR

cancer-associated retinopathy

MAR

melanoma-associated retinopathy

REC

recoverin

ARR

retinal arrestin

HSP27

heat shock protein 27

CAII

carbonic anhydrase II

TUB

tubulin

GAPDH

glyceraldehyde 3-phosphate dehydrogenase

ALDO

aldolase

ENOL

enolase

GYN

gynecological cancers

ERG

electroretinogram

Footnotes

Financial Disclosures: The authors have nothing to disclose.

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