Original Article

Adenosine Receptors Expression in Human Retina and
Choroid with Age-related Macular Degeneration

Collin P. Goebel1, MD; Yong-Seok Song1,2, MS; Ismail S. Zaitoun1,2, PhD; Shoujian Wang1, MD, PhD; Heather A.
D. Potter1, MD; Christine M. Sorenson1,2, PhD; Nader Sheibani1,2,3,4, PhD

1Department of Ophthalmology and Visual Sciences, University of Wisconsin School of Medicine and Public Health, Madison,
WI, USA

2McPherson Eye Research Institute, University of Wisconsin School of Medicine and Public Health, Madison, WI, USA
3Department of Cell and Regenerative Biology, University of Wisconsin School of Medicine and Public Health, Madison, WI, USA

4Department of Biomedical Engineering, University of Wisconsin, Madison, WI, USA

ORCID:
Nader Sheibani: https://orcid.org/0000-0003-2723-9217

Abstract
Purpose: Adenosine signaling modulates ocular inflammatory processes, and its
antagonism mitigates neovascularization in both newborns and preclinical models of ocular
neovascularization including age-related macular degeneration (AMD). The adenosine receptor
expression patterns have not been well characterized in the human retina and choroid.
Methods: Here we examined the expression of adenosine receptor subtypes within the retina
and choroid of human donor eyes with and without AMD. Antibodies specifically targeting
adenosine receptor subtypes A1, A2A, A2B, and A3 were used to assess their expression
patterns. Quantitative real-time PCR analysis was used to confirm gene expression of these
receptors within the normal human retina and choroid.
Results: We found that all four receptor subtypes were expressed in several layers of the retina,
and within the retinal pigment epithelium and choroid. The expression of A1 receptors was
more prominent in the inner and outer plexiform layers, where microglia normally reside, and
supported by RNA expression in the retina. A2A and A2B showed similar expression patterns with
prominent expression in the vasculature and retinal pigment epithelium. No dramatic differences
in expression of these receptors were observed in eyes from patients with dry or wet AMD
compared to control, with the exception A3 receptors. Eyes with dry AMD lost expression of
A3 in the photoreceptor outer segments compared with eyes from control or wet AMD.
Conclusion: The ocular presence of adenosine receptors is consistent with their proposed role in
modulation of inflammation in both the retina and choroid, and their potential targeting for AMD
treatment.

Keywords: Caffeine; Choroid; Inflammation; Neovascularization; Neurodegeneration; Retina

J Ophthalmic Vis Res 2023; 18 (1): 51–59

Correspondence to:

Nader Sheibani, PhD. Department of Ophthalmology
and Visual Sciences, University of Wisconsin School of
Medicine and Public Health, 1111 Highland Ave., 9453 WIMR,
Madison, WI 53705-2275, USA.
E-mail: nsheibanikar@wisc.edu
Received: 09-06-2022 Accepted: 08-09-2022

Access this article online

Website: https://knepublishing.com/index.php/JOVR

DOI: 10.18502/jovr.v18i1.12725

This is an open access article distributed under the Creative Commons
Attribution License, which permits unrestricted use, distribution, and
reproduction in any medium, provided the original work is properly cited.

How to cite this article: Goebel PG, Song Y-S, Zaitoun IS, Wang
S, Potter HAD, Sorenson CM, Sheibani N. Adenosine Receptors
Expression in Human Retina and Choroid with Age-related Macular
Degeneration. J Ophthalmic Vis Res 2023;18:51–59.

© 2023 Goebel et al. THIS IS AN OPEN ACCESS ARTICLE DISTRIBUTED UNDER THE CREATIVE COMMONS ATTRIBUTION LICENSE | PUBLISHED BY KNOWLEDGE E 51

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Adenosine Receptors in Donor Eyes with ARMD; Goebel et al

INTRODUCTION

Age-related macular degeneration (AMD) is an
inflammatory driven neurodegenerative disorder that
develops in the elderly due to a combination of
genetics, the environment, and other factors. It
contributes to substantial irreversible central vision
loss in the industrialized countries and was present
in an estimated 6.5% of all American adults over
the age of 40 as of 2011.[1] AMD is characterized
by the deposition of cellular debris, called drusen
between the retina and choroid, and divided into
the categories of wet and dry AMD.[2] In patients
with wet AMD, subretinal neovascularization occurs,
which may lead to edema and hemorrhage. In
contrast, dry AMD is characterized by drusen and
retinal degeneration without neovascularization or
hemorrhage. Currently, treatment for AMD, especially
dry AMD, is very limited. Antibodies against vascular
endothelial growth factor (VEGF) improve visual
outcomes in most patients with wet AMD.[3, 4] In
addition, antioxidant vitamins and minerals slow
down the progression of moderate or severe dry
AMD but fail to prevent the development of moderate
AMD from mild AMD.[5] Thus, these therapeutics are
best for preventing progression in patients who have
already developed moderate or severe disease and
are unable to halt or reverse the disease process.

To develop better therapeutic targets for patients
with AMD, a more complete understanding of its
pathophysiology is required. The dysfunction and
death of retinal pigment epithelial (RPE) cells and
degeneration of photoreceptors are observed in
AMD. However, the detailed cellular and molecular
mechanisms driving this degeneration needs
further investigation. Several hypotheses have
been proposed, including accumulation of toxins,
dysfunction of mitochondria, and damage from
reactive oxygen species in the RPE cells and
choroidal vasculature.[5–8] Recently, immune and
inflammatory regulatory pathways have been
proposed to be the central components in the
pathophysiology of AMD, and preclinical models
have demonstrated complement and IgG deposition
in the RPE and choroid of mice with AMD.[5, 8–10]

Recent investigations indicate the importance
of adenosine receptors in modulation of ocular
inflammatory processes. Adenosine elicits its
effects through its G-protein coupled receptors:
A1, A2A, A2B, and A3.[11] Adenosine receptor A1
activation inhibits calcium influx-induced release
of neurotransmitters in the central nervous
system (CNS) under hypoxic conditions, creating
a neuroprotective effect.[12] Adenosine receptor A3

engagement has both pro- and anti-inflammatory
properties throughout the body, including the lung,
cardiac, and gastrointestinal systems.[10] Blockade
of the adenosine A2A receptor in microglial cells
reduces inflammatory responses and photoreceptor
cell loss in cultured human cells. Furthermore,
adenosine receptors A2A and A2B expression are
upregulated by hypoxia-inducible factor during
hypoxic conditions and inflammation in the eye,[13, 14]
and their antagonism blocks ischemia-mediated
retinal neovascularization.[15] Thus, the process of
inflammation and angiogenesis in dry and wet AMD
could be linked with adenosine receptor signaling.
However, the function of these receptors in the
RPE and choroid, and their potential activity in
pathophysiology of AMD, needs further evaluation.

The importance of adenosine receptor signaling
pathways in ocular inflammatory and neovascular
diseases has been further supported by studies
of caffeine, an adenosine receptor antagonist, in
both preclinical models and humans.[16] Maugeri and
colleagues found evidence that caffeine decreases
the permeability of the RPE layer and thus may inhibit
the development of macular edema.[17] In addition,
caffeine administered to infants born prematurely
for apnea diminishes the severity of retinopathy of
prematurity.[18] We recently showed that caffeine is
efficacious in mitigating choroidal neovascularization
in a preclinical model of wet AMD.[19] However, the
identity of adenosine receptor(s) involved in these
activities remains unknown, and results have yet to be
verified in humans. Here we assessed the presence of
specific adenosine receptors in the retina and choroid
of human donor eye samples from control and
patients with wet and dry AMD. These studies, to the
best of our knowledge, are the first to demonstrate
the presence of specific adenosine receptors in the
human retina and choroid and examine whether their
expression pattern is altered under AMD conditions.

METHODS

Human Donor Eyes and Other Materials

Deidentified human ocular samples were from the
Lion Gift of Sight (St. Paul, MN). The eyes were
collected by written consent from donors or donors’
family for medical research as delineated by the
Declaration of Helsinki. We were provided with a
list of 28 potential donor samples with histological
evaluations, of which 13 were control eyes and 15
were eyes with AMD. Eyes from two donors with wet
AMD, two donors with dry AMD, and two donors
with no AMD were selected by the help of our

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Adenosine Receptors in Donor Eyes with ARMD; Goebel et al

ocular pathologist from the available samples.
Each experimental group contained samples
matched by age and gender, and all samples
included the macula. Presumptive diagnoses were
confirmed histologically. Anti-ADORA1 (55026-1-AP,
Proteintech, Rosemont, IL), anti-ADORA2A (PA1-042),
anti-ADORA2B (PA5-72850), and anti-ADORA3
(PA5-36350) were obtained from Thermo Fisher
Scientific (Carlsbad, CA). Anti-collagen IV antibody
was from Southern Biotech (1340-01; Birmingham,
AL). Cy5-labeled anti-goat (705-175-147) and Cy2-
labelled anti-rabbit (305-225-045) were obtained
from Jackson ImmunoResearch Laboratories (West
Grove, PA).

Antibody Staining and Microscopic Analysis
of Eye Sections

Four paraffin sections, taken from each donor eye,
were placed on glass slides. Sections were washed
with xylene four times for five min. This was followed
by two washes in 100% and 95% ethanol for 10
min, and the pure water for 5 min. Slides were
then heated in a citrate solution (H-3300, Vector
Laboratories, Burlingame, CA) for 11 min to retrieve
epitopes. For each set of samples, slides were then
stained overnight with 750 𝜇L ADORA1, ADORA2A,
ADORA2B, and ADORA3 primary antibodies, diluted
in blocking buffer (1:500; PBS with 1% bovine serum
albumin, 0.2% skim milk powder, and 0.3% Triton-
X100). Diluted Anti-collagen IV antibody (1:500) was
added to each sample to target vasculature in the
samples, and DAPI diluted 1:1000 was added to each
sample to visualize the cellular nuclei of the retina
and choroid. The slides were then rinsed with PBS
buffer three times for 5 min, and 750 𝜇L of appropriate
secondary antibodies (diluted 1:500 in PBS blocking
buffer) were added to each sample. Slides were
incubated at room temperature for 4 h allowing
the visualization of collagen in the vasculature and
adenosine receptor expression.

Following staining with primary and secondary
antibodies, the expression of the A1, 2A, 2B, and A3
receptors in donor eyes with wet AMD, dry AMD, or no
AMD were compared using fluorescence microscopy.
Light intensity and exposure time were standardized
for each group of slides under the microscope.
Photographs were taken of fluorescence emission
patterns for the adenosine receptor, collagen IV,
and DAPI located within the macula and underlying
choroid. The fluorescence intensity in each sample
was then compared to determine the predominant
location of each adenosine receptor in the retina and

choroid, as well as look for differences in adenosine
receptor expression between wet and dry AMD
compared to control.

RNA Isolation and Quantitative PCR (qPCR)
Analysis

The retina and RPE/choroid were dissected from
at least three non-diseased human eyes of similar
age (male and female) and cut into smaller pieces
in cold PBS. The tissue samples were snap frozen
in liquid nitrogen and stored at –80ºC for RNA
preparation. Tissue samples (50–100 mg) were
dissolved in 1 mL of Trizol reagent (Invitrogen, San
Diego, CA). Total RNA was extracted using RNeasy
mini kit as recommended (Qiagen, Valencia, CA).
Complementary DNA was prepared using 1 μg of
total RNA and the RNA to cDNA EcoDry Premix
(TaKaRa, Mountain View, CA) and diluted 1:10. qPCR
was conducted in triplicates using a Mastercycler
Realplex (Eppendorf, Enfield, CT) and TB-Green qPCR
Premix (TaKaRa). The cycles for amplification were
95ºC for 2 min; 40 cycles of amplification (95ºC for 15
s, 60ºC for 40 s); and dissociation curve step (95ºC
for 15 s, 60ºC for 15 s, 95ºC for 15 s). The relative
fluorescent units (RFUs) at a threshold fluorescence
value (Ct) were used for linear regression line and
assessment of nanograms of DNA. The target gene
expression levels were determined by comparing the
RFU at the Ct to the standard curve and normalized
by the housekeeping gene ribosomal protein L13α
(RPL13A). The primer sequences used in this study are
listed in Table 1. Each sample was run in triplicates.

Statistical Analysis

Differences between the expression level of ADORA
in the retina and RPE/Choroid were evaluated using
t-tests and GraphPad Prism version 8 (GraphPad
Software, La Jolla, CA). P < 0.05 was considered
significant. Data are the mean ± standard deviation.

RESULTS

Adenosine Receptors Expression in Retina
and Choroid

Each eye section selected for fluorescent staining
was from a patient between the ages of 76 and 100
years old at the time of death. One male and one
female sample was chosen for each of the AMD and
control groups. Each sample was preserved within 28
h of the patient’s death. All samples demonstrated

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Adenosine Receptors in Donor Eyes with ARMD; Goebel et al

Figure 1. Expression of ADORA1 in retinal and choroidal cross sections. (A) ADORA1, (B) collagen IV, and (C) merged images and
DAPI staining of eye sections with no AMD (Control). (D) A higher magnification of C. (E) ADORA1, (F) collagen IV, and (G) merged
images and DAPI staining of eye sections with dry AMD. (H) A higher magnification of G. (I) ADORA1, (J) collagen IV, and (K)
merged images and DAPI staining of eye sections with wet AMD. (L) Higher magnification of K. Scale bar = 400 µm (A, B, C, E, F,
G, I, J, and K) and 200 µm (D, H, and L).
V, vitreous; C, choroid.

Figure 2. Expression of ADORA2A in retinal and choroidal cross sections. (A) ADORA2A, (B) collagen IV, (C) merged images and
DAPI staining of eye sections with no AMD (Control). (D) A higher magnification of C. (E) ADORA2A, (F) collagen IV, and (G) merged
images and DAPI staining of eye sections with dry AMD. (H) A higher magnification of G. (I) ADORA2A, (J) collagen IV, and (K)
merged images and DAPI staining of eye sections with wet AMD. (L) A higher magnification of K. Scale bar = 400 µm (A, B, C, E,
F, G, I, J, and K) and 200 µm (D, H, and L).
V, vitreous; C, choroid.

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Adenosine Receptors in Donor Eyes with ARMD; Goebel et al

Figure 3. Expression of ADORA2B in retinal and choroidal cross sections. (A) ADORA2B, (B) collagen IV, and (C) merged images
and DAPI staining of eye sections with no AMD (Control). (D) A higher magnification of C. (E) ADORA2B, (F) collagen IV, (G) merged
images and DAPI staining of eye sections with dry AMD. (H) A higher magnification of G. (I) ADORA2B, (J) collagen IV, and (K)
merged images and DAPI staining of eye sections with wet AMD. (L) A higher magnification of K. Scale bar = 400 µm (A, B, C, E,
F, G, I, J, and K) and 200 µm (D, H, and L).
V, vitreous; C, choroid.

Figure 4. Expression of ADORA3 in retinal and choroidal cross sections. (A) ADORA3, (B) collagen IV, and (C) merged images and
DAPI staining of eye sections with no AMD (Control). (D) Higher magnification of C. (E) ADORA3, (F) collagen IV, and (G) merged
images and DAPI staining of eye sections with dry AMD. (H) higher magnification of F. (I) ADORA3, (J) collagen IV, and (K) merged
images and DAPI staining of eye sections with wet AMD. (L) Higher magnification of K. Scale bar = 400 µm (A, B, C, E, F, G, I, J,
and K) and 200 µm (D, H, and L).
V, vitreous; C, choroid.

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Adenosine Receptors in Donor Eyes with ARMD; Goebel et al

Figure 5. Quantitative PCR results demonstrating relative mRNA expression of adenosine receptor subtypes in a human eye
sample without AMD. Blue bars display mRNA expression for each receptor in the retina, and orange bars display mRNA
expression for each receptor in the choroid. ADORA1 and ADORA2B showed significantly higher levels in the retina, while
ADORA2A and ADORA3 showed significantly higher levels in the choroid. *P < 0.05, n = 3.

Table 1. List of primers.

Gene Forward (5’ to 3’) Reverse (5’ to 3’)

ADORA1 gtccggtcctcatcctcac ccaccatcttgtaccggaga

ADORA2A cacaccactctccctagactctc ttcctcacacttacatttttcctg

ADORA2B cactgcttataatgctggtgatcta gggtggtcctcgagtggt

ADORA3 cccaattatatctcccccact aagtcaggcctccaaaacact

RPL13A aagcggatgaacaccaacc tgtggggcagcatacctc

successful staining with each of the adenosine
receptor antibodies. Furthermore, vascular staining
with collagen IV antibody and nuclear staining with
DAPI were performed for each of the samples.

Adenosine receptor A1 demonstrated expression
throughout the retina. A1 expression was particularly
prominent in the outer plexiform layer (OPL), inner
photoreceptor layer, and inner plexiform layer (IPL)
of the retina. Retinal pigment epithelium (RPE) was
also positive. No noticeable differences in choroidal
vascular or retinal expression of the A1 were
appreciated between patients with AMD compared
to control patients regardless of sex. Representative
images of A1 receptor staining in the retina and
choroid are shown in Figure 1.

Receptor A2A primarily demonstrated expression
within the retinal and choroidal vasculature, with a
modest expression within the outer (ONL) and inner
nuclear layers (INLs). The expression of the A2A was
also detected in the RPE and was similar in patients
with AMD compared to control eyes. However, there
did appear to be a modest decrease in A2A receptor
expression in retinal and choroidal vasculature in
samples from patients with wet and dry AMD. There
did not appear to be a dramatic difference in receptor

A2A expression between patients with wet AMD
compared with dry AMD [Figure 2].

Receptor A2B demonstrated expression
throughout the retina in all samples, particularly
the ganglion cell layer, ONL, and INL, and RPE.
Receptor A2B was also strongly expressed in the
retinal and choroidal vasculature in all samples.
However, there was no dramatic difference in A2B
receptor staining in the retina, retinal vasculature, or
choroidal vasculature of patients with AMD compared
with control eyes. Representative images of retinal
and choroidal staining with antibodies to the A2B
receptor are shown in Figure 3.

Receptor A3 was expressed primarily within the
ganglion cell layer, INL, and ONL of the retina, and
RPE. There was also some A3 receptor expression in
the retinal and choroidal vasculature of each sample.
A dramatic differences in A3 staining was observed
in dry AMD samples compared with control and
wet AMD samples. The dry AMD samples lost the
expression of A3 receptor in the photoreceptor outer
segments, which was prominently present in control
and wet AMD samples. However, no additional
differences in the intensity of staining were observed
in retina or choroid in patients with AMD compared

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Adenosine Receptors in Donor Eyes with ARMD; Goebel et al

to those with no AMD. Representative images of A3
receptor staining are shown in Figure 4.

Adenosine Receptors mRNA Expression in
Retina and RPE/Choroid Tissues

Quantitative PCR of cDNA prepared from the
retinal and choroidal/RPE tissues from normal
human eyes demonstrated notable expression of
adenosine receptors within both the retina and
choroid. Adenosine receptor A1 displayed gene
expression primarily within the retina, with little to
no choroidal expression. This was consistent with
predominant immunostaining of A1 receptor in IPL
and OPL, where microglia are normally residing.
We previously showed predominant expression
of A1 receptor in mouse microglia and retinal
vascular cells.[19] Receptors A2A, A2B, and A3
displayed gene expression within both the retina
and choroid. Although A1 receptor expression was
significantly lower, the expression of A2A and
A3 were significantly higher in the choroid/RPE
compared with the retina, as we previously reported
in human and mouse tissue samples.[19] The average
relative expression of each adenosine receptor in
both the retina and choroid/RPE is shown in Figure 5.

DISCUSSION

The role of adenosine receptors in inflammatory
pathways, as well as prior clinical and preclinical
studies of their antagonism with caffeine suggest
that these receptors may play important roles in
the development of neurodegenerative diseases
such as AMD. However, previous literature has
not sufficiently examined the distribution of the
adenosine receptor subtypes in the human retina and
choroid. Furthermore, this is the first study to compare
the expression patterns of adenosine receptors in the
eyes of patients with and without AMD.

Collectively, our qPCR and antibody staining
experiments demonstrated that adenosine receptors
are widely expressed throughout the human eye and
are present within both the human retina and choroid.
Antibody staining suggested that receptors A1, A2A,
A2B, and A3 are widely expressed in multiple layers
of the human retina, providing further support for the
importance of these receptors in the human ocular
homeostasis and pathophysiology of AMD. A recent
study involving zebrafish studied the expression of
all four adenosine receptor subtypes, reporting A2A
and A2B receptors in both the inner and outer
plexiform and nuclear layers, and the ganglion cell

layer.[20] Our results demonstrated similar distribution
of the A2B receptors throughout the retina, but
we primarily observed the A2A receptors expressed
within the vasculature. Much like our results, A3
receptors were primarily in the inner and ONLs and
A1 receptors were primarily in the inner and OPLs.[20]
Therefore, our results indicate some overlap with
the preclinical models mapping the expression of
adenosine receptors in the retina, but we did find
differences in human retinal expression compared to
animal models.

Prior human studies have examined the location
of adenosine A1 receptors in the retina of humans
and other mammals. Like our results, these studies
demonstrated A1 expression in both the inner and
outer retina, with expression in the inner plexiform,
ganglion cell, inner nuclear, and photoreceptor
layers.[21, 22] A separate study demonstrated the
presence of A2 receptors within the human RPE but
did not attempt to map the A2 receptors throughout
the retina.[23]

In addition to the human neuroretina, receptors
A2A, A2B, and A3 were strongly expressed within
the retinal and choroidal vasculature. Studies have
suggested that the loss of the inner choroidal
vascular layer is associated with the development
of AMD and likely to occur due to inflammation
within the choroid.[24] Our observation of adenosine
receptors within the choroidal vasculature and their
involvement in inflammation suggests they may also
have a role in hallmark AMD changes within the
choroid.

We hypothesized that altered A2A expression in
patients with wet and dry AMD could contribute
to pathophysiology of AMD. Prior studies have
suggested that A2A receptor stimulation is pro-
inflammatory, and antagonism of the A2A receptor
can prevent neovascularization in the retina.[13–15]
Interestingly, our results suggest there may be a
modest decrease in the expression of the A2A
receptor in patients with AMD disease process,
which requires further verification in future studies.
Therefore, a change in the A2A receptor levels in
the human retina and choroid may disrupt normal
signaling in the eye potentially contributing to
pathogenesis of AMD.

A previous study in our lab examined the effect
of caffeine, an adenosine receptors antagonist, and
istradefylline, a specific A2A receptor antagonist, on
choroidal neovascularization after laser-induced
rupture of Bruch’s membrane. These studies
demonstrated that antagonism of adenosine
receptors, particularly A2A, was successful in

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Adenosine Receptors in Donor Eyes with ARMD; Goebel et al

inhibiting choroidal neovascularization. We also
demonstrated that caffeine inhibits the migration
of retinal and choroidal endothelial cells.[19] Thus,
the results of the current study suggesting that
the A2A receptor may have altered expression in
human eyes with AMD fits well with prior findings.
Together these results suggest a potential role
for adenosine receptor antagonism in preventing
changes associated with AMD.

In our previous study we noted variable and
limited expression of A3 receptor in retina and
choroid/RPE tissues from mouse eyes.[19] However,
here we noted significant expression of A3 receptor
in human eye sections with predominant expression
in the choroid/RPE. The immune staining of the eye
sections from dry AMD patients lacked A3 staining
in the photoreceptor outer segments, which was
predominantly present in eye sections from control
and wet AMD patients. Thus, downregulation of A3
receptor expression may specifically contribute to
loss of photoreceptor cells in dry AMD and awaits
future studies of its significance in pathophysiology
of dry AMD.

Overall, this study suggests that adenosine
receptors are present throughout the retina and
choroidal vasculature and supports the potential
role of adenosine as a key signaling molecule and
inflammatory mediator in pathophysiology of AMD.
Furthermore, there may be changes in the levels
of adenosine receptor A2A and A3 expression in
patients who have AMD. However, the number of
samples evaluated here were limited and awaits
further confirmation of these results using additional
samples in future studies as more suitable samples
become available. We propose it is possible that the
adenosine receptors contribute to the development
of both wet and dry AMD and are suitable candidates
to be targeted in the ongoing search for AMD
therapeutics in future studies.

Ethical Considerations

The human eyes were obtained from Lions Gift of
Sight (formerly known as Minnesota Lions Eye Bank,
Saint Paul, MN) with the written consent of the donor
or the donor’s family for use in medical research in
accordance with the Declaration of Helsinki. Lions
Gift of Sight is licensed by the Eye Bank Association
of America (accreditation #0015204) and accredited
by the FDA (FDA Established Identifier 3000718528).
Donor tissue is considered pathological specimens
and is therefore exempt from the process of
Institutional Review Board approval.

Acknowledgements

The authors would like to thank the Lion Gift of Sight
(St. Paul, MN) personnel for obtaining the eyes and
preparing the tissues for immunostaining. They are
also thankful to the donors and their families for their
valuable contributions to the research.

Financial Support and Sponsorship

This work and/or the investigator(s) were supported
by an unrestricted award from Research to Prevent
Blindness to the Department of Ophthalmology
and Visual Sciences, Retina Research Foundation,
RRF/Daniel M. Albert chair, and by National Institutes
of Health grants P30 EY016665, R01 EY026078,
EY030076, EY032543, and HL158073. CPG was
recipient of a VitreoRetinal Surgery Foundation
research award, Edina, MN.

Conflicts of Interest

The authors declare no conflict of interest.

REFERENCES

1. Klein R, Chou CF, Klein BE, Zhang X, Meuer SM, Saaddine
JB. Prevalence of age-related macular degeneration in the
US population. Arch Ophthalmol 2011;129:75–80.

2. Bhutto I, Lutty G. Understanding age-related macular
degeneration (AMD): Relationships between the
photoreceptor/retinal pigment epithelium/Bruch’s
membrane/choriocapillaris complex. Mol Aspects Med
2012;33:295–317.

3. Hernandez-Zimbron LF, Zamora-Alvarado R, Ochoa-De la
Paz L, Velez-Montoya R, Zenteno E, Gulias-Canizo R, et
al. Age-related macular degeneration: New paradigms
for treatment and management of AMD. Oxid Med Cell
Longev 2018;2018:8374647.

4. Martin DF, Maguire MG, Ying GS, Grunwald JE, Fine SL,
Jaffe GJ. Ranibizumab and bevacizumab for neovascular
age-related macular degeneration. N Engl J Med
2011;364:1897–1908.

5. Handa JT, Bowes Rickman C, Dick AD, Gorin MB, Miller
JW, Toth CA, et al. A systems biology approach towards
understanding and treating non-neovascular age-related
macular degeneration. Nat Commun 2019;10:3347.

6. Jabbehdari S, Handa JT. Oxidative stress as a therapeutic
target for the prevention and treatment of early age-
related macular degeneration. Surv Ophthalmol 2020.

7. Jager RD, Mieler WF, Miller JW. Age-related macular
degeneration. N Engl J Med 2008;358:2606–2617.

8. Hollyfield JG, Bonilha VL, Rayborn ME, Yang X, Shadrach
KG, Lu L, et al. Oxidative damage-induced inflammation
initiates age-related macular degeneration. Nat Med
2008;14:194–198.

58 JOURNAL OF OPHTHALMIC AND VISION RESEARCH Volume 18, Issue 1, January-March 2023



Adenosine Receptors in Donor Eyes with ARMD; Goebel et al

9. Sakurai E, Anand A, Ambati BK, van Rooijen N,
Ambati J. Macrophage depletion inhibits experimental
choroidal neovascularization. Invest Ophthalmol Vis Sci
2003;44:3578–3585.

10. Nozaki M, Raisler BJ, Sakurai E, Sarma JV, Barnum SR,
Lambris JD, et al. Drusen complement components C3a
and C5a promote choroidal neovascularization. Proc Natl
Acad Sci U S A. 2006;103:2328–2333.

11. Auchampach JA. Adenosine receptors and angiogenesis.
Circ Res 2007;101:1075–1077.

12. Effendi WI, Nagano T, Kobayashi K, Nishimura Y. Focusing
on adenosine receptors as a potential targeted therapy in
human diseases. Cells 2020;9:785.

13. Madeira MH, Rashid K, Ambrosio AF, Santiago AR,
Langmann T. Blockade of microglial adenosine A2A
receptor impacts inflammatory mechanisms, reduces
ARPE-19 cell dysfunction and prevents photoreceptor loss
in vitro. Scientific Reports 2018;8:2272.

14. Aherne CM, Kewley EM, Eltzschig HK. The resurgence of
A2B adenosine receptor signaling. Biochim Biophys Acta
2011;1808:1329–1339.

15. Merighi S, Borea PA, Stefanelli A, Bencivenni S, Castillo CA,
Varani K, et al. A2a and a2b adenosine receptors affect
HIF-1alpha signaling in activated primary microglial cells.
Glia 2015;63:1933–1952.

16. Daly JW, Shi D, Nikodijevic O, Jacobson KA. The role
of adenosine receptors in the central action of caffeine.
Pharmacopsychoecologia 1994;7:201–213.

17. Maugeri G, D’Amico AG, Rasà DM, La Cognata V, Saccone
S, Federico C, et al. Caffeine prevents blood retinal barrier
damage in a model, in vitro, of diabetic macular edema. J
Cell Biochem 2017;118:2371–2379.

18. Chen JF, Zhang S, Zhou R, Lin Z, Cai X, Lin J, et
al. Adenosine receptors and caffeine in retinopathy of
prematurity. Mol Aspects Med 2017;55:118–125.

19. Sorenson CM, Song Y-S, Zaitoun IS, Wang S, Hanna
BA, Darjatmoko SR, et al. Caffeine inhibits choroidal
neovascularization through mitigation of inflammatory and
angiogenesis activities. Front Cell Dev Biol 2021;9:737426.

20. Grillo SL, McDevitt DS, Voas MG, Khan AS, Grillo MA,
Stella SL, Jr. Adenosine receptor expression in the adult
zebrafish retina. Purinergic Signal 2019;15:327–342.

21. Blazynski C, Perez MT. Adenosine in vertebrate retina:
Localization, receptor characterization, and function. Cell
Mol Neurobiol 1991;11:463–484.

22. Braas KM, Zarbin MA, Snyder SH. Endogenous adenosine
and adenosine receptors localized to ganglion cells of the
retina. Proc Natl Acad Sci U S A 1987;84:3906–3910.

23. Friedman Z, Hackett SF, Linden J, Campochiaro PA.
Human retinal pigment epithelial cells in culture possess
A2-adenosine receptors. Brain Res 1989;492:29–35.

24. Farazdaghi MK, Ebrahimi KB. Role of the choroid in
age-related macular degeneration: A current review. J
Ophthalmic Vis Res 2019;14:78–87.

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