Original Article

Mutation Screening of Six Exons of ABCA4 in Iranian
Stargardt Disease Patients

Ensieh Darbari1, PhD; Hamid Ahmadieh2,3, MD; Narsis Daftarian2,3, MD; Mozhgan Rezaei Kanavi2,3, PhD;
Fatemeh Suri2, PhD; Hamideh Sabbaghi4,5, PhD; Elahe Elahi1*, PhD

1School of Biology, College of Science, University of Tehran, Tehran, Iran
2Opthalmic Research Center, Research Institute for Ophthalmology and Vision Science, Shahid University of Medical Sciences, Tehran, Iran

3Ocular Tissue Engineering Research Center, Research Institute for Ophthalmology and Vision Science, Shahid Beheshti University of Medical
Sciences, Tehran, Iran

4Ophthalmic Epidemiology Research Center, Research Institute for ophthalmology and Vision Science, Shahid Beheshti University of Medical
Sciences, Tehran, Iran

5Department of Optometry, School of Rehabilitation, Shahid Beheshti University of Medical Sciences, Tehran, Iran

ORCID:
Ensieh Darbari: https://orcid.org/0000-0003-1050-6999
Elahe Elahi: https://orcid.org/0000-0002-6897-2223

Abstract
Purpose: Stargardt disease type 1 (STGD1) is a recessively inherited retinal disorder that can
cause severe visual impairment. ABCA4 mutations are the usual cause of STGD1. ABCA4 codes
a transporter protein exclusively expressed in retinal photoreceptor cells. The gene contains
50 exons. Mutations are most frequent in exons 3, 6, 12, and 13, and exons 10 and 42 each
contain two common variations. We aimed to screen these exons for mutations in Iranian STGD1
patients.
Methods: Eighteen STGD1 patients were recruited for genetic analysis. Diagnosis by retina
specialists was based on standard criteria, including accumulation of lipofuscin. The six ABCA4
exons were PCR amplified and sequenced by the Sanger method.
Results: One or more ABCA4-mutated alleles were identified in 5 of the 18 patients (27.8%).
Five different mutations including two splice site (c.1356+1G>A and c.5836-2A>G) and
three missense mutations (p.Gly1961Glu, p.Gly1961Arg, and p.Gly550Arg) were found. The
p.Gly1961Glu mutation was the only mutation observed in two patients.
Conclusion: As ABCA4 mutations in exons 6, 12, 10, and 42 were identified in approximately
25% of the patients studied, these may be appropriate exons for screening projects. As in other
populations, STDG1 causative ABCA4 mutations are heterogeneous among Iranian patients,
and p.Gly1961Glu may be relatively frequent.

Keywords: ABCA4; Mutation Screening; Retinal Dystrophy; Stargardt Disease; STGD1

J Ophthalmic Vis Res 2022; 17 (1): 51–58

INTRODUCTION

Stargardt disease type 1 (STGD1: OMIM No.
248200) is a relatively common form of macular

Correspondence to:

Elahe Elahi, PhD. College of Science, University of
Tehran, Tehran, Iran.
Email: elaheelahi@ut.ac.ir, elahe.elahi@gmail.com
Received 19-11-2020; Accepted 21-05-2021

Access this article online

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DOI: 10.18502/jovr.v17i1.10170

dystrophy with a prevalence of 1 in 8000 to 1 in
10,000.[1, 2] It is a genetic disease with an autosomal
recessive pattern of inheritance. Stargardt disease
begins in childhood or young adulthood, and
causes progressive bilateral loss of central vision,

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How to cite this article: Darbari E, Ahmadieh H, Daftarian N, Kanavi MR, Suri
F, Sabbaghi H, Elahi E. Mutation Screening of Six Exons of ABCA4 in Iranian
Stargardt Disease Patients. J Ophthalmic Vis Res 2022;17:51–58.

© 2022 Darbari et al. THIS IS AN OPEN ACCESS ARTICLE DISTRIBUTED UNDER THE CREATIVE COMMONS ATTRIBUTION LICENSE | PUBLISHED BY KNOWLEDGE E 51

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ABCA4 Mutations in Stargardt Disease; Darbari et al

impairment of color vision, and degeneration
of retinal pigment epithelium (RPE) cells.[2, 3]
Accumulation of orange–yellow flecks in the
macula is often observed during ophthalmoscopic
examination. ATP-binding cassette sub-family A
member 4 (ABCA4, OMIM: 601691; also known as
ABCR) is the most important Stargardt disease-
causing gene.[4–10] This gene is positioned on
chromosome 1p21-p22, contains 50 exons,
and encodes a 2273 amino acid protein that
belongs to ABC transporter protein family. ABC
transporter proteins have four essential domains,
including two transmembrane domains (TMDs)
and two cytoplasmic nucleotide-binding domains
(NBDs). TMDs are responsible for translocation of
substrates, and NBDs bind to ATP and hydrolyze
ATP to ADP to produce energy for the translocation.
ABCA4 expression is specific to the retina and its
protein product is responsible for the transport of
vitamin A derivatives in the outer segment disc
membranes of photoreceptors.[11, 12] Mutations in
the gene result in accumulation of toxic bisretinoid
adducts in RPE cells, eventually leading to RPE cell
death and macular degeneration.[13]

In addition to STGD1, mutations in ABCA4 can
cause several other types of retinal degenerative
diseases.[14–16] This suggests a complex
genotype/phenotype relationship between
mutations in the gene and the consequent
phenotypes. Additionally, the number of sequence
variations and disease-associated variations in
ABCA4 is astounding. Variability in frequencies
of the variations in different populations is
also notable. The Human Genome Mutation
Database (HGMD, http://www.hgmd.cf.ac.uk)
reports 1467 mutations in the ABCA4 gene as
cause of various retinal degenerative diseases;
629 of the mutations are associated with STGD1.
The Genome Aggregation Database (gnomAD
v2.1.1; https://gnomad.broadinstitute.org) reports
3979 sequence variations for ABCA4, including
exonic, intronic, UTR, splicing, and INDEL
variations; the frequency of 3930 of these is <0.01.
The Iranome database (http://www.iranome.ir)
which comprises exome sequence data on 800
healthy Iranians reports 389 ABCA4 sequence
variations, and the frequency of 301 of these is
<0.01. Clearly, common sequence variations are
unlikely to contribute to disease status, but rare
variations may have deleterious effects.

Here, we report the results of mutation screening
of six exons of the ABCA4 gene in 18 unrelated

Iranian Stargardt disease patients. To the best of
our knowledge, mutation screening of this gene in
Iranians has not been previously reported. Among
the 50 exons of ABCA4, exons that were more
likely to contain mutations were screened. Based
on the HGMD database, more mutations have been
reported in exons 3, 6, 12, and 13 than in other
exons. These exons of ABCA4 have, respectively,
33, 33, 39, and 45 reported mutations. In addition
to these, exons 10 and 42 were also screened.
A common nucleotide sequence variation that
causes p.His432Arg is positioned in exon 10.
Although now considered a polymorphism, this
variation was earlier thought to contribute to
disease status. Exon 42 was screened because
the most frequent disease-associated variation in
various populations is positioned within this exon.
This variation causes p.Gly1961Glu.

METHODS

This research was performed in accordance with
the Declaration of Helsinki, with informed consent
of participants or responsible guardians, and with
the approval of the Ethics Board of the University
of Tehran. Eighteen unrelated Stargardt patients
were sequentially recruited from the Retina Clinic
of Labbafinejad Medical Center affiliated to Shahid
Beheshti University of Medical Sciences, Tehran,
Iran. Ophthalmic examinations included visual
acuity assessment, fundus photographs (color,
infrared, and autofluorescence) and fluorescein
angiography (FA) for accumulation of lipofuscin
in the retina, measurement of macular thickness
by optical coherence tomography (OCT), visual
field (VF) testing, and electroretinography (ERG).
A combination of clinical presentations and
progression, decreased visual acuity, fundus
photographs, FA, VF, OCT, and ERG results
were considered for the diagnosis of Stargardt
disease.[17]

For genetic analysis, genomic DNA was isolated
from the white blood cells of the peripheral
blood of the patients. Exons 3, 6, 10, 12, 13, 42,
and flanking intronic regions of ABCA4 were
amplified by the polymerase chain reaction (PCR).
Primer sequences are available upon request. The
amplified PCR products were sequenced using
the Sanger sequencing protocol. Sequences were
analyzed using the Sequencher Software (Gene
Codes Corporation, Ann Arbor, MI). Variations were
assessed by comparison with ABCA4 reference

52 JOURNAL OF OPHTHALMIC AND VISION RESEARCH Volume 17, Issue 1, January-March 2021

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http://www.iranome.ir


ABCA4 Mutations in Stargardt Disease; Darbari et al

Figure 1. Fundus photographs (color, infrared, and autofluorescence), fluorescein angiography (FA), visual field (VF), optical
coherence tomography (OCT), and electroretinography (ERG) findings in a representative patient (STG-5). (A–D) and (F–I) represent
color (A & F), infrared (B & G), autofluorescence (C & H), and fluorescein angiographic (D & I) fundus photographs of the patient’s
right and left eyes, respectively, and demonstrate the lipofuscin accumulation in the macula. VF defects are evident in the right
(E) and left eyes (J). Reduced central macular thicknesses were illustrated in the OCT images of the right (K) and left (L) eyes. Note
the abnormal photopic ERG graphs and values for both eyes in (M).

sequence available at NCBI (NC_000001.10,
NM_000350.3, NP_000341.2).

RESULTS

The average age of patients at the disease onset
was 17 years (range 6–41 years). Of the 18 included
patients, 11 (61%) were male. The average age at
the examination was 26 years (range 8–45 years).
All investigated patients demonstrated decreased
best-corrected visual acuity and evidence of
lipofuscin accumulation in the macula, decreased
central macular thickness, constricted visual fields,
and variable degrees of ERG abnormalities [Figure
1].

Of the 18 patients screened, three (STG-2,
STG-6, and STG-18) had two definitive disease-
causing mutated ABCA4 alleles [Table 1]. Of
these, two patients had homozygous mutations
(p.Gly1961Arg and p.Gly550Arg), consistent with
them having been born to consanguineous
parents. The third patient had compound

heterozygous mutations; one was the very
common p.Gly1961Glu-causing mutation in
exon 42 that was noted above, and the other
was a donor splice site mutation in intron
10 (c.1356+1G>A). Patient STG-1 harbored a
splice site mutation (c.5836-2A>G) in intron
41 and a variation in exon 6 that causes
p.Arg212His [Table 1]. The intronic mutation
is a known STGD1-causing mutation. As the
p.Arg212His-causing variation was observed in
the homozygous state, the allele with the c.5836-
2A>G intronic mutation must be in cis with a
c.635G>A variation that causes p.Arg212His.
Although the p.Arg212His-causing variation has
sometimes been considered a polymorphism
because of its relatively high allele frequency
(0.052720), it was reported to contribute to
STGD1 status in a Turkish patient.[4, 7, 18, 19] It
is possible that in an individual with a clearly
disease-causing mutation such as the splice
site mutation of patient STG-1, the presence of
p.Arg212His will result in disease presentation.

JOURNAL OF OPHTHALMIC AND VISION RESEARCH Volume 17, Issue 1, January-March 2021 53



ABCA4 Mutations in Stargardt Disease; Darbari et al

Figure 2. Sequence chromatograms of five mutations observed among the Stargardt disease-affected patients studied. (A)
c.5836-2A>G in patient STG-1; (B) c.5881G>A mutation in patient STG-2; (C) c.5882G>A mutation in patient STG-5 and STG-
6; (D) mutation c.1356+1G>A in patient STG-6; and (E) mutation c.1648G>A in patient STG-18.

Alternatively, the second mutated ABCA4 allele
in patient STG-1 may be positioned in one of
the many exons not screened in this study.
Patient STG-5 also harbored two variations in
ABCD4, a variation that causes p.Gly1961Glu
and the intronic variation c.1356+11T>G.
Although the intronic mutation is rare (0.0001),
bioinformatics tools including Human Splice
Finder (http://umd.be/Redirect.html) and NNsplice
(https://www.fruitfly.org/seq_tools/splice.html)
predict that it would not affect splicing. Therefore,
the second mutated ABCA4 allele in patient
STG-5 is likely positioned in one of the exons not
screened. The presence of a shared haplotype
between the two mutated alleles that cause
p.Gly1961Glu cannot be ascertained because of
phase issues in the two heterozygous carriers,
STG-5 and STG-6. Sequence chromatographs
of the reported STGD1-associated mutations are
shown in Figure 2.

DISCUSSION

All diseases associated with ABCA4 are
progressive retinopathies accompanied by
degeneration of photoreceptor cells that
can lead to blindness. There is a significant
association between the severity of phenotype
and the nature of the ABCA4 mutations.
Stargardt disease is generally considered
to be less severe than cone-rod dystrophy
(CRD) or retinitis pigmentosa (RP).[20, 21]
Deletions, nonsense mutations, and INDELs are
usually associated with severe phenotypes.[5]
Missense mutations are more commonly
found in less severely affected patients. It is
interesting that the pathogenicity of some
missense mutations, such as p.His432Arg and
p.Arg212His discussed above, and even of
p.Gly1961Glu that is described below, remains
controversial.

54 JOURNAL OF OPHTHALMIC AND VISION RESEARCH Volume 17, Issue 1, January-March 2021

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ABCA4 Mutations in Stargardt Disease; Darbari et al

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JOURNAL OF OPHTHALMIC AND VISION RESEARCH Volume 17, Issue 1, January-March 2021 55



ABCA4 Mutations in Stargardt Disease; Darbari et al

One or more ABCA4-mutated alleles were
identified in 5 of the 18 Iranian STGD1 patients
(27.8%) in whom only six of the gene’s 50 exons
were screened. No variant nucleotide was found in
exons 3 and 13, and the single variation found by
screening exon 10 was in fact in intron 10. Without
considering p.Arg212His as a mutation that affects
disease status, five different mutations were
observed. Three of the mutations were missense
mutations. P.Gly1961Glu and p.Gly1961Arg affect
an amino acid that is localized in the second
NBD domain. Although p.Gly1961Glu has been
reported as one of the most frequent mutations
in Stargardt patients of various populations,
its pathogenicity has been questioned largely
because of the relatively high frequency of its
coding allele in some populations.[22] For example,
its frequencies in the Somalian, Ashkenazi, Qatar,
and Iranian populations are reported to be 0.10,[22]
0.024 (gnomAD), 0.023,[23] and 0.026 (Iranome),
respectively. The consensus appears to be that
p.Gly1961Glu is a moderate mutation.[5, 24] In the
homozygous state, it presents a mild form of
STGD1; in the compound heterozygous state with
a more deleterious mutation, it can contribute
to a severe form of Stargardt disease.[5] As in
other populations, p.Gly1961Glu may be relatively
common among Iranian STGD1 patients, as it was
observed in two patients of the relatively small
cohort studied here. P.Gly1961Arg is found less
frequently than p.Gly1961Glu in retinal dystrophy
patients. The frequency of the allele that causes
p.Gly1961Arg among Iranians is 0.0025, and the
frequency is <0.01 in most other populations as
well (Iranome, gnomeAD). P.Gly550Arg, that has
been reported as a Stargardt disease-causative
mutation, was the third missense mutation found
in the Iranian cohort.[25] P.Gly550 is localized in
the extracytosolic domain 1 (ECD1) of the protein
encoded by ABCA4.

The molecular consequences of two observed
splice site mutations were not critically
investigated. C.5836-2A> G that abolishes the
acceptor splice site in intron 41 was previously
reported in a CRD patient of a Chinese cohort.[6]
C.1356+1G>A is being reported for the first time
in a Stargardt disease-affected patient, although
c.1356+1G>T was previously reported in age-
related macular degeneration patients.[26] This
signifies potential variability of phenotypic features
associated with any ABCA4 mutation.

To the best of our knowledge, this is the first
report of the ABCA4 mutation screening of the
Iranian patients affected by Stargardt disease. Of
course, more patients need to be screened in
order to achieve a representative profile of ABCA4
mutation in this population. This knowledge will be
needed for various purposes, including possible
initiatives for gene therapy.

Acknowledgments

Some of patients in the current article are provided
by the disease registry, titled ”The Iranian National
Registry of Inherited Retinal Dystrophy (IRDReg®)”
and code number of IR.SBMU.ORC.REC.1396.15
from the ethic committee, that was supported
by the deputy of research and technology in
Shahid Beheshti University of medical sciences.
(http://dregistry.sbmu.ac.ir).

Financial Support and Sponsorship

Nil.

Conflicts of Interest

There are no conflicts of interest.

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