Original Article

Variable Expressivity of Wolfram Syndrome in a Family
with Multiple Affected Subjects

Mehraban Mirrahimi1*, MS; Sare Safi2*, PhD; Maryam Mohammadzadeh3, MD; Azadeh Doozandeh3, MD
Fatemeh Suri3, PhD

1Ocular Tissue Engineering Research Center, Research Institute for Ophthalmology and Vision Science, Shahid Beheshti
University of Medical Sciences, Tehran, Iran

2Ophthalmic Epidemiology Research Center, Research Institute for Ophthalmology and Vision Science, Shahid Beheshti
University of Medical Sciences, Tehran, Iran

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

ORCID:
Fatemeh Suri: https://orcid.org/0000-0002-3170-2940

Sare Safi: https://orcid.org/0000-0002-5860-6908
Mehraban Mirrahimi: https://orcid.org/0000-0001-8220-7758
*First and second authors contributed equally to this work.

Abstract

Purpose: To study the genetic basis and clinical manifestations of Wolfram
syndrome in a multi-affected family.
Methods: Complete clinical examinations including urological, ophthalmic,
neurological, and endocrinologic assessment were performed for three affected
family members. Genomic DNA was extracted from peripheral blood leukocytes
with salting out method and all WFS1 exons and their flanking regions were
sequenced. Candidate variation was screened for segregation in the pedigree
by Sanger sequencing.
Results: A known pathogenic missense mutation in WFS1 gene (c.1885C>T
which leads to p.Arg629Trp in the encoded protein) was identified in all affected
individuals. Both clinical and genetic investigations confirmed Wolfram syndrome
diagnosis with variable phenotypic features.
Conclusion: Identical mutations in the Wolfram syndrome causative gene can
lead to variable manifestations of the syndrome even in the same family. Although
the medical findings and clinical examination are imperative for the diagnosis of
Wolfram syndrome, genetic testing is useful to confirm the diagnosis, especially
in cases with possible reduced penetrance of the characteristic signs.

Keywords: Variable Clinical Manifestations; WFS1 Gene; Wolfram Syndrome

J Ophthalmic Vis Res 2021; 16 (4): 602–610

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Variability of Wolfram Syndrome; Mirrahimi et al

INTRODUCTION

Wolfram syndrome (WFS) also called DIDMOAD
(diabetes insipidus, diabetes mellitus,
optic atrophy, deafness) is a progressive
neurodegenerative disease affecting multiorgan
systems.[1] Wolfram and Wagener first described
this entity in four siblings in 1938.[2] It’s a kind
of rare genetic disorder with a prevalence
of approximately 1 per 770,000 in the United
Kingdom and 1 per 100,000 in North America.[1]
WFS is inherited in an autosomal recessive
pattern; therefore, it should be more prevalent in
populations with high rates of consanguineous
marriages. However, only limited cases have been
reported from the Eastern Mediterranean countries
where this kind of marriage is more common.
There is no published data on the prevalence of
the disease in Iran.[3]

The WFS manifestations are variable. However,
juvenile-onset diabetes mellitus (DM) and optic
atrophy (OA) are two characteristic features
for clinical diagnosis of the syndrome that are
typically exhibited at the mean age of 6 and
11 years, respectively. Other common clinical
manifestations include diabetes insipidus (DI),
sensorineural deafness, urinary tract involvement,
and neuropsychiatric disorders.[1]

WFS (WFS1; OMIM 222300) is caused by a
deleterious mutation in the WFS1 gene (OMIM
606201) on chromosome 4p16, which encodes
Wolframin protein; a kind of endoplasmic reticulum
(ER) transmembrane glycoprotein highly expressed
in pancreatic, beta insulinoma, and brain cells. The
decline in Wolframin protein leads to the ER
stress and malfunctioning of the cells.[4] Not
only more than 400 distinct mutations of the WFS1

Correspondence to:

Fatemeh Suri, PhD. Ophthalmic Research Center,
Research Institute for Ophthalmology and Vision
Science, Shahid Beheshti University of Medical
Sciences, No. 23, Paidarfar St., Boostan 9 St., Pasdaran
Ave., Tehran 16666, Iran.
E-mail: fatemehsuri@gmail.com.
Received: 31-01-2021 Accepted: 25-04-2020

Access this article online

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

DOI: 10.18502/jovr.v16i4.9750

gene have been reported till now (http://www.
hgmd.cf.ac.uk/ac/gene.php?gene=WFS1), but the
less frequent phenotypic and genotypic variant of
WFS (WFS2; OMIM 604928) related to mutation
in CISD2 gene (OMIM 6011507) encoding CDGSH
iron sulfur domain 2 protein have also been
recognized.[5]

In this study, we analyzed the clinical
characteristics and genetic findings of a multi-
affected family with variable clinical manifestations
of the syndrome.

METHODS

The research was approved by the Ethics
Committee of the Ophthalmic Research Center at
Shahid Beheshti University of Medical Sciences,
Tehran, Iran. All study procedures were explained
to the subjects and were performed in accordance
with the Declaration of Helsinki. The signed
consent form was also obtained.

Subjects and Clinical Examination

Three affected siblings of Persian ethnicity from
four offspring of a consanguineous marriage
diagnosed with WFS referred to Torfeh Medical
Center due to visual impairment were studied.
Diagnosis criteria for the WFS were DM and OA
unexplained by any other causes. The clinical
evaluations including urological, ophthalmic,
neurological, and endocrinological examinations
were performed for all affected individuals.
The pedigree data was gathered [Figure 1] and
auditory evaluation was accomplished by pure
tone audiometry, speech discrimination score,
audiometric thresholds, and tympanometry.
Ophthalmic evaluations including slit lamp
examination, tonometry, gonioscopy, indirect
ophthalmoscopy, and fundus photography were
also performed. In addition, the color vision and
visual field were assessed but the results were
unreliable due to patients’ severe visual loss.
Blood samples were taken from all participants

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How to cite this article: Mirrahimi M, Safi S, Mohammadzadeh M,
Doozandeh A, Suri F. Variable Expressivity of Wolfram Syndrome in a Family
with Multiple Affected Subjects. J Ophthalmic Vis Res 2021;16:602–610.

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https://knepublishing.com/index.php/JOVR
http://www.hgmd.cf.ac.uk/ac/gene.php?gene=WFS1
http://www.hgmd.cf.ac.uk/ac/gene.php?gene=WFS1


Variability of Wolfram Syndrome; Mirrahimi et al

for genetic and biochemical evaluation. Brain and
spinal magnetic resonance imaging (MRI) and total
abdominopelvic sonography were conducted.

Genetic and Molecular Analysis

Genomic DNA was extracted from peripheral blood
leukocytes using the standard salting out protocol.
Primers were designed to amplify all exons and
their flanking regions of the WFS1 gene using
GeneRunner version 3.05 software. To validate
further, we checked them for the specificity
to the target template with NCBI Primer-Blast
(http://www.ncbi.nlm.nih.gov/tools/primer-blast/).
Polymerase chain reactions (PCR) were done
and subsequently sequenced with the Sanger
protocol. All PCR products were sequenced
using ABI Big Dye terminator chemistry with an
ABI 3730XL genetic analyzer instrument (Applied
Biosystems, Foster city, CA, USA). Sequences were
analyzed using Sequencher 5.0 software (Gene
Codes Corporation, Ann Arbor, MI, USA). The
sequencing data was assembled to their reference
sequence of WFS1 (NG_011700.1, NM_006005.3,
and NP_005996.2) to find the disease causative
mutation. Subsequently, the candidate causing
variation was screened for segregation in all family
members by Sanger sequencing.

RESULTS

Genetic Results

A homozygous missense mutation (c.1885C>T) on
exon 8 of WFS1 gene that causes p.Arg629Trp
in the encoded protein was detected in all three
affected members of the family. The parents
were heterozygous for the causative variant and
the healthy sister was homozygous for the wild-
type allele. Figure 2 shows DNA sequence
chromatograms of c.1885 position in WFS1 in three
different genotypic features in the members of this
family. Mutation c.1885C>T has been reported to
be pathogenic in patients with WFS.

Clinical Findings

The clinical features of all participants have been
represented in Table 1. The parents are second
cousins once removed, having four offspring; three
of them manifesting signs and symptoms of WFS
[Figure 1].

Case V.2

A 31-year-old male patient was referred to the
ophthalmology clinic due to visual impairment. He
was diagnosed with DM at the age of four and has
been on insulin therapy since then. He has been
suffering from visual impairment from the age of 6.
He subsequently developed DI and hearing loss
at the age of 21. At the time of study, his serum
HbA1C level was 7.7%. The ophthalmic evaluation
showed the best-corrected visual acuity of light
perception bilaterally with no nystagmus. Cataract
was observed in both eyes and the intraocular
pressure was 18 mmHg bilaterally. Funduscopy
revealed proliferative diabetic retinopathy (PDR)
in the right eye and moderate nonproliferative
diabetic retinopathy (NPDR) in the left eye with
no evidence of macular edema. OA with severe
optic nerve head pallor was obvious in both eyes
[Figure 3a]. The history and ocular examinations
approved the progressive OA in the context of
WFS. Abdominopelvic sonography revealed mild
hydronephrosis in the right kidney with normal
kidney size, normal parenchymal thickness, and
echo pattern. Also, mild bladder wall thickness with
trabeculation was detected. These are consistent
with neurogenic bladder. Auditory tests with pure
tone audiometry showed sensorineural hearing
loss. Brain and lumbar spine MRIs were normal.

Case V.3

A 24-year-old female patient was diagnosed with
DM at the age of three who has been treated
with insulin NPH and regular. The presence of
OA in both eyes was diagnosed at the age of
12. She developed urinary tract disorders and
bladder dysfunction at the age of 12 for which
she took nitrofurantoin twice daily for prophylaxis.
The diagnosis of DI was confirmed with clinical
signs and symptoms, laboratory tests and water
deprivation test abdominopelvic sonography
revealed severe hydroureteronephrosis with
cortical loss in both kidneys in addition to
irregularity and increment in bladder wall thickness
that is consistent with neurogenic bladder [Figure
4]. Her visual acuity was finger counting at 1–2
m. Intraocular pressure was 19 mmHg in both
eyes. Fundus examination revealed bilateral
severe OA and nerve fiber loss [Figure 3b]. The
audiometry showed sensorineural hearing loss
in both ears which were moderate at 3000 Hz

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Variability of Wolfram Syndrome; Mirrahimi et al

Figure 1. Pedigree information of the Wolfram syndrome family. Black filled shapes represent affected patients. Open shapes
represent unaffected members.

Table 1. Clinical features of patients with wolfram syndrome

Patient ID Current age (years) Gender (M/F) Clinical findings

Case V.2 31 M DM, DI, OA, sensorineural hearing loss, neurogenic
bladder, mild hydronephrosis

Case V.3 24 F DM, DI, OA, sensorineural hearing loss, neurogenic
bladder, severe hydroureteronephrosis

Case V.4 23 M DM, DI, OA

DM, diabetes mellitus; DI, diabetes insipidus; OA, optic atrophy

and severe at 6000 Hz test tone [Figure 5a].
Tympanometry presented type A𝑛 in right and
type A𝑠 in left ear which suggested the reduced
tympanic membrane mobility in the left ear [Figure
5b]. Brain and lumbar spine MRI revealed normal
findings.

Case V.4

A 23-year-old man was diagnosed with insulin-
dependent DM at the age of four which has been
treated with insulin NPH and regular since the
diagnosis and subsequently was diagnosed with

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Figure 2. DNA sequence chromatograms of the identified WFS1 variation in three different genotypic features in the family.

Figure 3. Severe nerve fiber layer loss in cases V.2 and V.3.

DI. He subsequently developed visual impairment
and OA at the age of 11. His serum HbA1c level was
9.4% which represented uncontrolled DM. His best-
corrected visual acuity was finger counting at 20
cm in the right eye and hand motion in the left eye.
He underwent phacoemulsification and intraocular

lens implantation in both eyes. Intraocular
pressure was 18 mmHg bilaterally. On funduscopic
examination, there was severe OA [Figure 6].
His abdominopelvic sonography reported normal
kidney sizes with normal parenchymal thickness
and echo patterns. Neither hydronephrosis

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Figure 4. Abdominopelvic sonography in case V.3 showing severe hydronephrosis in both kidneys.

Figure 5. (a) Tympanogram of both ears in case V.3. (b) Audiograms of case V.3 showing sensorineural hearing loss in both ears.

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Figure 6. Severe optic atrophy with disc paleness in both eyes of case V.4.

nor stone or occupying lesion was detected.
Additionally, bladder wall thickness and shape
was normal without any evidence of trabeculation
or neurogenic bladder. He occasionally reported
urological symptoms which was proved by the
normal results of his abdominopelvic sonography.
He had no complaint of auditory loss and his
auditory tests were normal.

DISCUSSION

WFS is a rare progressive neurodegenerative
disorder characterized by OA and DM at childhood
which is inherited in an autosomal recessive
pattern.[6] Patients affected by this syndrome can
manifest different signs and symptoms of the
disease, for example, DI, sensorineural hearing
loss, and neurological signs such as ataxia,
and neurogenic bladder in combination with
DM or OA.[6] According to clinical history and
physical examination, the differential diagnosis
could include other causes of progressive
neurodegeneration like mitochondrial disorders,
mutant WFS1 gene-induced deafness, autosomal
dominant OA, Friedreich ataxia, Bardet–Biedl
syndrome, and Alström syndrome.[7] Among
this wide spectrum of clinical manifestations,
juvenile-onset DM and OA are both initial and
fundamental features of WFS.[8] In this study, we
reported the clinical and genetic characteristics of
three patients with WFS from a consanguineous
marriage. So far, a wide range of WFS1 gene
variants has been recognized as cause of the
disease.[4] Most of these mutations result in loss of
function protein expression which is responsible
for Wolframin protein inactivation and consequent
disease manifestations; however, the exact

genotype–phenotype correlation in WFS-affected
patients is not well understood.[9, 10] In this study,
we detected a known homozygous pathogenic
mutation (c.1885C>T) in exon 8 of WFS1 gene in all
the three affected patients that has been reported
in other studies as cause of the disease.[11–13]
Furthermore, we discovered that both parents
were heterozygous for the causative variant who
were healthy and the youngest sister of the
family was homozygous for the wild-type allele.
Therefore, not only the clinical diagnostic criteria
but also the genetic analysis in all three cases was
consistent with WFS. DM usually occurs during the
first decade of patients’ lives.[11] In our study, all of
our cases suffered from juvenile-onset DM with
the average age at onset of 3.8 years (ranging
from 3.5 to 4 years). While diabetes ketoacidosis
(DKA) may occur as the presenting features of the
syndrome,[14] none of our cases have experienced
any episodes of DKA or severe hypoglycemia yet.
As previously mentioned, Wolframin protein is
found in the ER of Langerhans β-cells and loss of
function mutations of the WFS1 gene can lead to
Wolframin protein dysfunction which consequently
leads to ER stress.[15] This phenomenon can lead
to non-autoimmune-mediated/induced destruction
of β-cells and subsequently, DM occurs. This
pathophysiology is consistent with the early onset
DM in WFS-affected patients in comparison with
autoimmune-mediated destruction of β-cells in
type 1 DM which is triggered later during life.[16]
Patients with WFS will progressively develop
ophthalmic complications in consequence of DM,
that is, diabetic retinopathy and cataract.[8] We
discovered diabetic retinopathy and cataract in
both eyes in one of the cases (Case V.2) which is
justified by longer duration of disease (27 years)

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in comparison with other participants. In addition
to DM, OA is another characteristic feature of
the syndrome which usually develops after DM
at the mean age of 11 years.[1, 11] According to OA
pathogenesis, WFS1 gene mutation reduces the
retinal ganglion cells survival which leads to retinal
axon layer atrophy and optic nerve shrinkage. The
latter will also result in progressive OA.[8] All of our
cases had symptoms and signs of OA after the
diagnosis of DM. The mean age at the onset of OA
in our cases was 9.6 years.

Other studies have reported hearing impairment
in 60% of WFS cases at the mean age of
16 years.[17] Auditory features of this hearing
impairment were compatible with sensorineural
hearing loss in mid to high frequencies. The
pathophysiology of this kind of hearing loss could
be the result of dysfunction in cochlear neurons,
vestibular nerve fibers of cranial nerve VIII, and
the central nervous system (including brain stem
and inferior colliculus).[18] In our study, we detected
a sensorineural hearing loss in high frequencies
confirmed by an audiometry in two of our cases
(Cases V.2 and V.3).

Urinary tract involvement is one of the signs of
the WFS. This manifestation mainly has a primary
feature rather than being secondary to DM, DI, or
WFS-induced myelopathy and could be present
independent of other features.[19] In our study, we
have found evidence of neurogenic bladder, that
is, hydronephrosis and bladder wall trabeculation
in two cases (Cases V.2 and V.3) which was mild in
the former and severe in the latter. These findings
could be a result of diabetic-induced peripheral
neuropathy,[20] however, since neither of our cases
presented any signs and symptoms of autonomic
or peripheral neuropathy, this finding will not be
probable. In our study, we found no signs and
symptoms of neurological complications neither in
physical examination nor in MRI images of the brain
and spine.

In conclusion, our study showed that an identical
mutation in WFS1 gene can represent variable
severity of clinical features of the disease even in
the same family. More studies on age- and sex-
matched cases may shed light on reasons behind
this variable clinical presentation and the role of
genetic background and environmental factors.
Additionally, further studies exploring different
WFS1 mutations will improve our knowledge
about genotype–phenotype correlations of this
syndrome.

Acknowledgement

The authors would like to thank Dr. Mahboobeh
Karimi and Dr. Alireza Abrishami for their valuable
contribution to this study.

Financial Support and Sponsorship

None.

Conflicts of Interest

There are no conflicts of interest.

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