- Email: [email protected]
Clinical and genetic diversity of nemaline myopathy from a single neuromuscular center in Korea
Accepted Manuscript Clinical and genetic diversity of nemaline myopathy from a single neuromuscular center in Korea
Jong-Mok Lee, Jeong Geun Lim, Jin-Hong Shin, Young-Eun Park, Dae-Seong Kim PII: DOI: Reference:
S0022-510X(17)34385-X doi:10.1016/j.jns.2017.10.020 JNS 15615
To appear in:
Journal of the Neurological Sciences
Received date: Revised date: Accepted date:
5 July 2017 19 September 2017 9 October 2017
Please cite this article as: Jong-Mok Lee, Jeong Geun Lim, Jin-Hong Shin, Young-Eun Park, Dae-Seong Kim , Clinical and genetic diversity of nemaline myopathy from a single neuromuscular center in Korea. The address for the corresponding author was captured as affiliation for all authors. Please check if appropriate. Jns(2017), doi:10.1016/ j.jns.2017.10.020
This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.
ACCEPTED MANUSCRIPT
Manuscript title Clinical and genetic diversity of nemaline myopathy from a single neuromuscular center in Korea
T
Authors
SC RI P
Jong-Mok Leea, Jeong Geun Limb, Jin-Hong Shina, Young-Eun Parkc, Dae-Seong Kima,c*
a
NU
Affiliations
Department of Neurology, Research Institute for Convergence of Biomedical Science
MA
and Technology, Pusan National University Yangsan Hospital Department of Neurology, Keimyung University School of Medicine
c
Department of Neurology, Pusan National University School of Medicine
ED
b
CE
PT
Running title; Clinical and genetic diversity of nemaline myopathy
Corresponding author
AC
Dae-Seong Kim, MD, PhD Department of Neurology, Pusan National University Yangsan Hospital 20 Geumo-ro, Mulgeum-eup, Yangsan-si, Gyeongsangnam-do, 50612, Republic of Korea. Tel: +82-55-360-2450 Fax: +82-55-360-2521 E-mail: [email protected]
ACCEPTED MANUSCRIPT
Acknowledgements We deeply appreciate to Kirsi Kiiski, Vilma-Lotta Lehtokari and other staffs of the Folkhälsan Institute of Genetics and The Department of Medical and Clinical Genetics at University of Helsinki for their contribution of identifying copy number variations in
SC RI P
T
triplicate region of NEB using array CGH.
Funding
This research was supported by Basic Science Research Program through the National
MA
and Technology (2013R1A1A2005521)
NU
Research Foundation of Korea (NRF) funded by the Ministry of Education, Science,
Conflict of interest
AC
CE
PT
ED
The authors state that there is no conflict of interest.
ACCEPTED MANUSCRIPT
Abstract Nemaline myopathy (NM), the most common of the congenital myopathies, is caused by various genetic mutations. In this study, we attempted to identify the causative mutations of NM and to reveal any specific genotype–phenotype relationship in Korean
SC RI P
T
patients with this disease. We investigated the clinical features and genotypes in 15 pathologically diagnosed NM patients, using whole exome sequencing (WES) combined with targeted sequencing and array-based comparative genomic hybridization. This strategy revealed pathogenic causative mutations in seven patients (46.7%), among
NU
whom mutations in the nebulin gene (NEB) were the most frequent (5 patients, 33.3%). Copy number variation (CNV) abnormality in NEB was not observed in any of our
MA
patients. In those with NEB-associated NM, the clinical spectrum was highly variable regardless of the mutation type. However, the majority of patients showing anterior
ED
lower leg weakness were associated with mutations located between NEB exons 166
PT
and 177. We concluded that the combination of WES and targeted Sanger sequencing is an effective strategy for analyzing genotypes in patients with NM, and that CNV in
CE
NEB may not be a frequent cause of this disease among Koreans.
AC
Keywords; nemaline myopathy, NEB, whole exome sequencing, comparative genomic hybridization, copy number variation
ACCEPTED MANUSCRIPT
1. Introduction Nemaline myopathy (NM), the most common of the congenital myopathies, is pathologically characterized by the presence of nemaline rods in skeletal muscle fibers. The nemaline rods are accumulations of degraded Z-disc components as well as broken
SC RI P
T
thin filaments [1].
NM is a genetically heterogeneous disease that is caused by pathological variants in the genes encoding components of the thin filaments and associated proteins. The thin filament of skeletal muscle consists of nebulin (NEB), tropomyosin-β and -γ (TPM2 and
NU
TPM3), actin (ACTA1), and troponin T (TNNT1) [2-6]. The actin and tropomyosin proteins are double-helical structures encircling the nebulin protein, and are bound to
MA
the Z-disc at the C-terminal and to tropomodulin at the N-terminal. The troponin T adjacent to tropomyosin regulates contraction in accordance with calcium ions. The
ED
stabilization of nebulin and tropomodulin is controlled by a muscle-specific protein,
PT
Kelch-like family member 40 (KLHL40) (Fig. 1) [7]. The dysregulation of these genes breaks the thin filament components directly or indirectly [8].
CE
The clinical spectrum of NM is known to be diverse [9-11]. Generally, NM can be classified into six clinical forms on the basis of age of onset and severity of motor and
AC
respiratory involvement [12]. In the severe neonatal form of NM, patients typically present with severe muscular hypotonia and respiratory failure at birth. Dilated cardiomyopathy or multiple joint contractures can be complicated. Amish NM is a clinically distinct autosomal recessive disease with neonatal onset and early childhood lethality. It is associated with TNNT1 mutations and has been described only in a single Amish family [6] and a single Dutch case [13]. Patients with intermediate congenital NM fail to achieve motor developmental milestones, or they become wheelchair-
ACCEPTED MANUSCRIPT
dependent and/or develop respiratory failure by the age of 11 years, although they initially show anti-gravity movement or independent respiration at birth. In the typical congenital form of the disease, patients show spontaneous anti-gravity limb movement, and respiratory involvement is not obvious. Patients may show delayed gross motor
T
development with proximal limb and bulbar weakness, which is static or progresses
SC RI P
very slowly. However, most of the patients with typical congenital NM are able to lead independent lives [10]. Childhood-onset NM is frequently inherited as an autosomal dominant trait, and patients usually develop their first symptom in their late first or
NU
second decade. Although a minority of the patients may become wheelchair-bound at adult age, most of them can lead independent ambulation. In adult-onset NM, patients
MA
develop generalized muscle weakness between the ages of 20 and 50 years and most of them can lead independent lives. In childhood- and adult-onset NM, cardiac
ED
involvement or respiratory failure is rare [14, 15]. Although NM is associated with many genetic causes, the genotype–phenotype
PT
correlation is not so clear in many of the cases. Furthermore, the large size of the genes
CE
associated with NM makes the genetic diagnosis a challenging task. For example, NEB, which is being considered as the most common causative gene of NM, has an enormous
AC
size with more than 180 exons. In this regard, the recent introduction and development of next-generation sequencing technology could be useful for exploring the genetic etiologies of NM. This notion led us to investigate and identify NM-causative gene mutations in affected patients. First, we attempted to identify causative mutations in all NM-related genes, using currently available technologies; namely, targeted Sanger sequencing of small-sized NM-related genes, whole exome sequencing (WES), and array-based comparative
ACCEPTED MANUSCRIPT
genomic hybridization (array-CGH) for the analysis of copy number variation (CNV) of NEB. Second, once the genetic diagnosis was established, we attempted to reveal the specific relationship between genotypes and clinical phenotypes, such as clinical
AC
CE
PT
ED
MA
NU
SC RI P
T
features or muscle biopsy findings.
ACCEPTED MANUSCRIPT
2. Methods 2.1. Patients We retrospectively recruited 15 patients from 14 unrelated families, who were diagnosed with NM at the neuromuscular clinic of Pusan National University Hospital
SC RI P
T
and Pusan National University Yangsan Hospital since 1998. The diagnosis of NM in all patients was based on the presence of nemaline rods in their muscle biopsy. Clinical information was collected from the patient’s medical records; gender, presence of affected family members, age at onset, initial symptom, distribution of muscle weakness,
NU
respiratory muscle involvement, and associated dysmorphic features. Laboratory findings, including serum creatine kinase (CK) levels and electrocardiogram and
MA
electromyography readings, were also obtained and analyzed. Written informed consent was obtained from all the patients examined for genomic DNA sequencing, and this
ED
study was approved by the ethical review board of Pusan National University Yangsan
PT
Hospital (IRB No. 05-2014-063). 2.2. Pathological analysis
CE
Open muscle biopsy was performed under local or general anesthesia on the clinically affected limb muscles. The biopsied muscles were flash frozen and stored at –80 °C
AC
until used. The serial frozen sections were stained with the following histochemical stains; hematoxylin and eosin (H&E), modified Gomori trichrome, nicotinamide adenine dinucleotide tetrazolium reductase (NADH-TR), and adenosine triphosphatase, at varying pH values. Muscle specimens were also prepared for electron microscopy observation. In brief, the specimens were fixed with 2% glutaraldehyde in 0.1 M cacodylate buffer. After shaking with a mixture of 4% osmium tetroxide, 1.5% lanthanium nitrate, and 0.2 M s-collidine
ACCEPTED MANUSCRIPT
for 2–3 hours, the samples were embedded in epoxy resin. Semi-thin sections of 1-μm thickness were stained with toluidine blue, whereas ultrathin sections of 50-nm thickness were stained with uranyl acetate and lead citrate. 2.3. DNA analysis
T
Genomic DNA extracted from each patient’s blood or skeletal muscles was used. First,
SC RI P
all coding exons and exon-intron boundaries of ACTA1 and TPM3 were amplified by PCR and analyzed by Sanger sequencing [5]. If no pathogenic mutation was identified in these two genes, other causative genes of congenital myopathies, including NM-
NU
related genes (NEB, CFL2, TPM2, TNNT1, KBTBD13, KLHL40, KLHL41, LMOD3, MYO18B, and MYPN), were evaluated by WES [2, 3, 6, 7, 15-20]. Exome capture was
MA
performed using the Illumina TruSeq Exome Enrichment Guide. Sequence reads were mapped to the human reference genome assembly (GRch37/hg19) using Integrative
ED
Genomics Viewer (IGV; Broad Institute, Cambridge, MA, USA). Variants potentially affecting protein structure or function, including nonsynonymous variants, frameshifts,
PT
or variants affecting splicing, were investigated. The variants showed a depth of more
CE
than 30 and a minor allele frequency of less than 0.01. We evaluated the impact of mutations using the SIFT/PROVEAN and Polyphen2 prediction system in the case of
AC
point mutations. The splice sites were evaluated with Human Splicing Finder [21]. Sanger sequencing was performed to confirm the mutations found by WES. Because WES has clear limitations in reading the triplicate region of NEB, Sanger fill- in was performed for patients in whom a single heterozygous variant or no variant was identified. In addition, all patient samples were sent to the Folkhälsan Institute of Genetics at the University of Helsinki for CNV analysis by targeted array-CGH, as
ACCEPTED MANUSCRIPT
previously described [22]. Information of the primer sequences used is available upon
AC
CE
PT
ED
MA
NU
SC RI P
T
request.
ACCEPTED MANUSCRIPT
3. Results Overviews of the clinical features and genetic analysis of the 15 patients with NM are summarized in Table 1 and Figure 2, respectively. In terms of age of onset and clinical features, we could classify our patients into three
SC RI P
T
groups: (1) the intermediate congenital form, (2) the typical congenital form, and (3) mild childhood-onset NM. None of our patients were classified as severe neonatal type, Amish NM, or mild adult-onset NM. Two patients (patients 1 and 2), who developed their first symptom at birth, were classified as intermediate congenital NM. Both of
NU
them showed generalized muscular hypotonia, and they developed respiratory failure requiring mechanical ventilation during the neonatal period. One patient showed
MA
marked limb muscle weakness with an inability to move the limbs against gravity. Five patients (patients 3, 4, 5, 6, and 7) had the typical congenital form of NM. In this group,
ED
two patients manifested subclinical weakness of the respiratory musculature (patients 4
PT
and 7), and one (patient 6) showed predominant calf weakness. Eight patients (patients 8, 9, 10, 11, 12, 13, 14, and 15) were classified into benign childhood-onset NM. Motor
CE
developmental delay with gait disturbance was the most common clinical manifestation, and facial paresis was evident in one patient (patient 10). Pes cavus or equinovarus
AC
deformity was observed in seven patients (patients 8, 9, 10, 11, 12, 13, and 14). This group could be further subdivided into six patients with predominant distal leg weakness, and one patient with evenly distributed weakness (patient 9). In one patient (patient 11), clinical information regarding muscle weakness distribution was not available. Among the six patients with predominant distal leg weakness, four (patients 8, 10, 13, and 14) showed predominant peroneal muscle weakness with foot drop, whereas
ACCEPTED MANUSCRIPT
the peroneal and calf muscles were equally affected in the other two individuals (patients 12 and 15). Six patients, all of whom were classified as having mild childhood-onset NM (patients 8, 9, 10, 13, 14, and 15), underwent muscle CT or MRI. Five of them manifested distal leg
T
dominant muscle weakness, whereas the sixth patient (patient 9) showed mild
SC RI P
generalized muscle weakness that was not confined to a specific muscle group. In patients 13 and 14, muscle CT showed preferential involvement of the bilateral tibialis anterior muscle. Patient 15 revealed a high signal change in the tibialis anterior, soleus,
NU
and gastrocnemius muscles in T2-weighted images of muscle MRI (Fig. 3A). Although patient 8 presented with predominant bilateral foot drop, his muscle CT showed a
MA
predominant affection of the right gastrocnemius muscle (Fig. 3B). Slight involvement of the gastrocnemius muscle with sparing of the anterior compartments of the lower legs
ED
and thigh muscles was observed in patient 10 (Fig. 3C). Patient 9 showed a patch-like distribution of abnormal intensities in the muscle CT (Fig. 3D). Serum CK levels were
PT
generally normal, except for one patient with an ACTA1 mutation (patient 7) who
CE
showed a markedly elevated serum CK level (5,370 IU/L; normal 7–151 IU/L) and associated hypertrophic cardiomyopathy.
AC
Modified Gomori trichrome staining of the biopsied muscle tissues showed characteristic nemaline bodies in all patients, except for one individual who was classified with an intermediate congenital form associated with TPM3 mutation (patient 2). In this patient, all muscle fibers were extremely atrophic, and the nemaline body was not readily identifiable under the light microscope, but was evident under the electron microscope. The locations of nemaline bodies in the muscle fibers were variable, being either in the cytoplasm or the subsarcolemmal area, or both, and did not show any
ACCEPTED MANUSCRIPT
significant correlation with the clinical phenotype or genes affected (Fig. 4). In most of the patients, the nemaline bodies were present in type 1 fibers, except for patient 5, in whom nemaline bodies were exclusively observed in atrophic type 2 fibers. Interestingly, two patients also showed core lesions in the NADH-TR stain at the same
T
time (central cores in patient 10 and minicores in patient 15). The clinical, pathological,
SC RI P
and genetic features of both patients had been previously reported elsewhere, and both had predominant distal leg weakness and mutations in NEB [23]. Other frequently observed pathological abnormalities included increased fiber size variability (13/15),
NU
type 1 fiber predominance (12/15), endomysial fibrosis (8/15), type 1 fiber atrophy (2/15), and increased number of muscle fibers with internal nuclei (2/15). However,
MA
none of these findings showed clear correlation with the patient’s clinical phenotype or genotype. Under electron microscopy, all showed the presence of characteristic
ED
filamentous aggregations, which were caused from disruption of the Z-band (Fig. 5). Dominant pathogenic mutations affecting TPM3 (patient 2) and ACTA1 (patient 7) were
PT
identified by Sanger sequencing [24]. Subsequent investigation revealed 16 additional
CE
mutations affecting NEB in 12 patients (Figure 2); namely, four nonsense mutations, three missense mutations, six small del/ins, and three splice site mutations. Eight
AC
mutations were novel (i.e., not reported elsewhere; bolded in Table 1), and their effects, evaluated using the prediction system SIFT/PROVEAN, Polyphen2, or Human Splicing Finder, were all found to be deleterious. Two known mutations (Ser8228Ser and Arg7970Serfs*48) were shared by two patients, respectively [23, 25]. In all patients with NEB-associated NM, at least one nonsense or frameshift mutation was identified, except in one patient in whom only a single heterozygous deletion of a single amino acid was identified (patient 5).
ACCEPTED MANUSCRIPT
None of our patients with NM possessed abnormal CNV of the triplicate region of NEB. Finally, we were able to confirm a genetic diagnosis in seven of the 15 patients with NM. Of the other eight patients, only a single heterozygous mutation in NEB was identified in seven individuals, and no mutation was identified in any NM-related gene
AC
CE
PT
ED
MA
NU
SC RI P
T
in the eighth individual (patient 4).
ACCEPTED MANUSCRIPT
4. Discussion In this study, we aimed to identify genetic defects in 15 patients with pathologically confirmed NM using WES combined with targeted sequencing, and were able to identify causative mutations in seven patients. Among the genes investigated, NEB was
SC RI P
T
the most common causative gene of NM in our series. Two other pathogenic variants detected by targeted Sanger sequencing consisted of a mutation affecting TPM3 and ACTA1 individually. Although the exact proportion is uncertain, mutations in NEB have been attributed to 50% of NM cases [26]. Our study showed that autosomal recessive
NU
pathogenic variants in NEB accounted for 38% of our pool, which is compatible with previous reports and shows that NEB is also the major causative gene of NM in Korea
MA
[27, 28].
WES has already shown a strong impact on the investigation of pathogenic variants in
ED
congenital myopathy, which has many candidate genes [29]. In our study, we identified
PT
pathogenic compound heterozygous variants of NEB in two patients using WES only. Among 11 patients in whom WES had identified either a single heterozygous mutation
CE
only or no significant mutation, three patients were revealed by Sanger sequencing to have additional pathogenic heterozygous variants at repetitive regions of NEB, and the
AC
genetic diagnosis was confirmed. The reason why WES had shown a relatively low detection rate in NEB is most likely due to the short read length of this technique [25, 30]. Because NEB has a highly repetitive region between exons 82 and 105, it is most likely that mapping errors cannot be avoided using current WES technology with its limited read length. Given that we had seven patients harboring only a single causative heterozygous mutation in NEB and one genetically undiagnosed patient, it is strongly suggested that cryptic pathogenic variants or large deletions in the highly repetitive
ACCEPTED MANUSCRIPT
region of NEB may not be detectable using the current standard technology of WES or Sanger sequencing [22]. In this regard, a recently developed single- molecule, real-time, new-generation sequencing technology that offers longer read lengths may be useful for overcoming this problem [31].
T
Recently, abnormal CNV in the triplicate region of NEB was implicated as a frequent
SC RI P
cause of NM [32]. However, no CNV abnormality was identified in our patients. Although the number of samples studied was small, this finding suggesting that CNV abnormality is not a common cause of NEB-related NM among Koreans may reflect an
NU
ethnic difference in the genetic background of the disease [32].
The clinical spectrum of NM was wider than previously recognized [25, 33]. Patients
MA
with TPM3- or ACTA1-associated NM typically showed onset at birth or in infancy. In ACTA1-associated NM, intrafamilial phenotypic variability has also been reported [27].
ED
The results of our study are compatible with the previous study, because our patients with TPM3 (patient 2) or ACTA1 (patient 7) mutations presented their symptoms at
PT
birth or in infancy [34]. In patients with NEB-associated NM, the age of onset and
CE
clinical severity were highly variable. Whereas both patients with the intermediate congenital form showed profound limb weakness associated with respiratory or
AC
swallowing difficulties, those with mild childhood-onset NM manifested mild limb weakness and many of them were still ambulatory. One of the most remarkable findings in our series is that only two cases were associated with respiratory failure, which is much fewer than that seen in previous studies [33, 35]. This is most likely because we definitely had a smaller number of patients with severe phenotype than the other study series (none with severe neonatal form and only two with intermediate congenital form). Another point is that distal leg weakness was frequent in NEB-associated NM, occurring
ACCEPTED MANUSCRIPT
in one patient with typical congenital NM (patient 6) and in six with mild childhoodonset NM (patients 8, 10, 12, 13, 14, and 15). Among them, four developed predominant weakness in the ankle extensors (patients 8, 10, 13, and 14) and one manifested predominant ankle flexor weakness (patient 6). In the other two patients,
T
ankle extensors and flexors were equally affected (patients 12 and 15).
SC RI P
In the previous studies using muscle MRI, the rectus femoris, vastus intermedius, and tibialis anterior muscles had been considered as the most frequently affected leg muscles in patients with NEB-related NM, and it had been suggested that predominant
NU
gastrocnemius muscle involvement may exclude the diagnosis of NEB-related NM [36]. However, another study showed definite involvement of the hamstring muscles in
MA
addition to the rectus femoris muscle and pronounced involvement of the gastrocnemius muscle in a patient with NEB mutations [37]. In our study, patient 14 with mild
ED
childhood-onset NM and distal dominant phenotype exhibited similar findings. His muscle MRI showed a selective involvement of muscles of the posterior group at the
PT
thigh level. Moreover, among his lower leg muscles, the tibialis anterior, gastrocnemius
CE
medialis, and soleus muscles were selectively affected (Fig. 3A). Thus, our study clearly showed that affection of the gastrocnemius muscle is not unusual in patients
AC
with NEB-associated NM, which had been reported to be rare in the literature [38]. The correlation between muscle pathology and clinical features in NM is still controversial. In a previous study, it was suggested that the number of rods observed in muscle pathology and the residual amount of nebulin protein in western blot analysis are correlated with clinical severity [39]. Another study suggested that the features of sarcomeric disturbance in electron microscopy findings are also correlated with muscle weakness in NM [40]. However, another study using a large number of pathology
ACCEPTED MANUSCRIPT
specimens showed that the numbers and localization of nemaline rods correlated poorly with clinical severity in NM [41]. We were not able to identify any significant correlations between the numbers or localization of rods with the clinical findings, such as age of onset and clinical severity of muscle weakness. Given the relatively small
T
patient number in our study, further study using a larger sample size will be needed to
SC RI P
elucidate this issue.
In terms of the genotype–phenotype correlation with regard to reported mutations in NEB, the clinical severity of our cohort differed from that of reported cases. Although
NU
the splice site mutation c.24579G>A (p.Ser8228Ser) was identified in two patients with mild childhood-onset NM in our series, the same mutation has been reported in the
MA
typical congenital form of the disease [25]. A small deletion leading to frame shifting (c.23908_23911delAGAG [p.Arg7970Serfs*48]), identified in two of our patients with
ED
mild childhood-onset NM manifesting as predominant distal leg weakness (patients 13 and 14), was associated with typical congenital NM in a previous report [33]. The
PT
clinical phenotype of two nonsense mutations identified from patients with relatively
CE
severe phenotypes in our cohort (c.8425C>T [p.Arg2809X] and c.23245C>T [p.Arg7749X]) was not available in the previous reports [25, 42]. Only patient 9,
AC
harboring the c.1674+1G>T mutation, showed similar clinical presentation to that of a reported case of mild childhood-onset NM [25]. This discrepancy could be explained by the unshared second mutation, which may have a potential role in muscle function. In addition, we were not able to identify any clear relationship between the mutation type and the patient’s clinical phenotype. For example, patient 12, who had compound heterozygous nonsense and frameshift mutations, was classified as mild childhood-
ACCEPTED MANUSCRIPT
onset NM, whereas another patient with compound heterozygous nonsense and missense mutations (patient 1) presented with severe phenotype (Table 1). Interestingly, the proportion of patients with distal manifestations in our cohort (47%) was significantly larger than that from a previous study employing a larger number of
T
families (showing only 10 out of 159 families (6%)) [25, 43, 44]. Although this
SC RI P
discrepancy could be due to the bias from the small cohort size, the higher frequency of distal manifestation in our cohort seems to be meaningful. Moreover, the majority of patients showing anterior lower leg weakness in our cohort had mutations located
NU
between NEB exons 166 and 177. Donner et al. had reported that the alternatively spliced exons 166–177 express 20 different transcripts in adult human tibialis anterior
MA
muscle, where exons 167 and 175 expressed the majority of these transcripts, which strongly suggests that mutations at this location could lead to clinical involvement of
ED
the anterior compartment of the lower legs [30]. A recent research study has suggested that the severity of the clinical features is
PT
determined by the degree of alteration of the binding affinity among nebulin,
CE
tropomyosin, and actin by the location and type of mutations in NEB [45]. Further study is needed in order to clarify this issue.
AC
In summary, our study showed that NEB is the most common NM-causative gene in Korean patients with this disease. Although combined WES and Sanger sequencing is an effective strategy for the detection of pathogenic variants in NM, the highly repetitive region in NEB is the major obstacle to a definite genetic analysis. Furthermore, contrary to the study results in western countries, abnormal CNV in the triplicate region of NEB may not be a frequent cause of NM among Koreans. Further study is required in order to establish the relationship between the genotypes and clinical features of NM.
ACCEPTED MANUSCRIPT
References [1] A.S. McElhinny, S.T. Kazmierski, S. Labeit, C.C. Gregorio, Nebulin: the nebulous, multifunctional giant of striated muscle., Trends Cardiovasc Med 13(5) (2003) 195-201. [2] K. Pelin, P. Hilpela, K. Donner, C. Sewry, P.A. Akkari, S.D. Wilton, D.
SC RI P
T
Wattanasirichaigoon, M.L. Bang, T. Centner, F. Hanefeld, S. Odent, M. Fardeau, J.A. Urtizberea, F. Muntoni, V. Dubowitz, A.H. Beggs, N.G. Laing, S. Labeit, A. de la Chapelle, C. Wallgren-Pettersson, Mutations in the nebulin gene associated with autosomal recessive nemaline myopathy., Proc. Natl. Acad. Sci. U.S.A. 96(5) (1999)
NU
2305-2310.
[3] K. Donner, M. Ollikainen, M. Ridanpää, H.-J. Christen, H.H. Goebel, M. de Visser,
MA
K. Pelin, C. Wallgren-Pettersson, Mutations in the beta-tropomyosin (TPM2) gene--a rare cause of nemaline myopathy., Neuromuscul Disord 12(2) (2002) 151-158.
ED
[4] N.G. Laing, S.D. Wilton, P.A. Akkari, S. Dorosz, K. Boundy, C. Kneebone, P.
PT
Blumbergs, S. White, H. Watkins, D.R. Love, A mutation in the alpha tropomyosin gene TPM3 associated with autosomal dominant nemaline myopathy., Nat Genet 9(1)
CE
(1995) 75-79.
[5] K.J. Nowak, D. Wattanasirichaigoon, H.H. Goebel, M. Wilce, K. Pelin, K. Donner,
AC
R.L. Jacob, C. Hübner, K. Oexle, J.R. Anderson, C.M. Verity, K.N. North, S.T. Iannaccone, C.R. Müller, P. Nurnberg, F. Muntoni, C. Sewry, I. Hughes, R. Sutphen, A.G. Lacson, K.J. Swoboda, J. Vigneron, C. Wallgren-Pettersson, A.H. Beggs, N.G. Laing, Mutations in the skeletal muscle alpha-actin gene in patients with actin myopathy and nemaline myopathy., Nat Genet 23(2) (1999) 208-212.
ACCEPTED MANUSCRIPT
[6] J.J. Johnston, R.I. Kelley, T.O. Crawford, D.H. Morton, R. Agarwala, T. Koch, A.A. Schäffer, C.A. Francomano, L.G. Biesecker, A novel nemaline myopathy in the Amish caused by a mutation in troponin T1., Am J Hum Genet 67(4) (2000) 814-821. [7] G. Ravenscroft, S. Miyatake, V.-L. Lehtokari, E.J. Todd, P. Vornanen, K.S. Yau,
T
Y.K. Hayashi, N. Miyake, Y. Tsurusaki, H. Doi, H. Saitsu, H. Osaka, S. Yamashita, T.
SC RI P
Ohya, Y. Sakamoto, E. Koshimizu, S. Imamura, M. Yamashita, K. Ogata, M. Shiina, R.J. Bryson-Richardson, R. Vaz, O. Ceyhan, C.A. Brownstein, L.C. Swanson, S. Monnot, N.B. Romero, H. Amthor, N. Kresoje, P. Sivadorai, C. Kiraly-Borri, G.
NU
Haliloglu, B. Talim, D. Orhan, G. Kale, A.K. Charles, V.A. Fabian, M.R. Davis, M. Lammens, C.A. Sewry, A. Manzur, F. Muntoni, N.F. Clarke, K.N. North, E. Bertini, Y.
MA
Nevo, E. Willichowski, I.E. Silberg, H. Topaloğlu, A.H. Beggs, R.J.N. Allcock, I. Nishino, C. Wallgren-Pettersson, N. Matsumoto, N.G. Laing, Mutations in KLHL40 are
ED
a frequent cause of severe autosomal-recessive nemaline myopathy., Am J Hum Genet 93(1) (2013) 6-18.
PT
[8] C.A.C. Ottenheijm, H. Granzier, New insights into the structural roles of nebulin in
CE
skeletal muscle., J Biomed Biotechnol 2010 (2010) 968139. [9] D. Sanoudou, A.H. Beggs, Clinical and genetic heterogeneity in nemaline myopathy
AC
– a disease of skeletal muscle thin filaments., Trends Mol Med 7(8) (2001) 362-368. [10] C. Wallgren-Pettersson, C.A. Sewry, K.J. Nowak, N.G. Laing, Nemaline myopathies., Semin Pediatr Neurol 18(4) (2011) 230-238. [11] L. Levesque, M.R. Del Bigio, S. Krawitz, A.A. Mhanni, A de novo dominant mutation in ACTA1 causing congenital nemaline myopathy associated with a milder phenotype: expanding the spectrum of dominant ACTA1 mutations., Neuromuscul Disord 23(3) (2013) 239-242.
ACCEPTED MANUSCRIPT
[12] C. Wallgren-Pettersson, A.H. Beggs, N.G. Laing, 51st ENMC International Workshop: Nemaline Myopathy. 13-15 June 1997, Naarden, The Netherlands., Neuromuscul. Disord., 1998, pp. 53-56. [13] W.L. van der Pol, J.F. Leijenaar, W.G.M. Spliet, S.W. Lavrijsen, N.J.G. Jansen,
T
K.P.J. Braun, M. Mulder, B. Timmers-Raaijmakers, K. Ratsma, D. Dooijes, M.M. van
SC RI P
Haelst, Nemaline myopathy caused byTNNT1 mutations in a Dutch pedigree., Mol Genet Genomic Med 2(2) (2014) 134-137.
[14] C. Lomen-Hoerth, M.L. Simmons, S.J. Dearmond, R.B. Layzer, Adult-onset
NU
nemaline myopathy: Another cause of dropped head., Muscle Nerve 22(8) (1999) 11461150.
MA
[15] M. Yuen, S.A. Sandaradura, J.J. Dowling, A.S. Kostyukova, N. Moroz, K.G. Quinlan, V.-L. Lehtokari, G. Ravenscroft, E.J. Todd, O. Ceyhan-Birsoy, D.S. Gokhin, J.
ED
Maluenda, M. Lek, F. Nolent, C.T. Pappas, S.M. Novak, A. D'Amico, E. Malfatti, B.P. Thomas, S.B. Gabriel, N. Gupta, M.J. Daly, B. Ilkovsk i, P.J. Houweling, A.E. Davidson,
PT
L.C. Swanson, C.A. Brownstein, V.A. Gupta, L. Medne, P. Shannon, N. Martin, D.P.
CE
Bick, A. Flisberg, E. Holmberg, P. Van den Bergh, P. Lapunzina, L.B. Waddell, D.D. Sloboda, E. Bertini, D. Chitayat, W.R. Telfer, A. Laquerrière, C.C. Gregorio, C.A.C.
AC
Ottenheijm, C.G. Bonnemann, K. Pelin, A.H. Beggs, Y.K. Hayashi, N.B. Romero, N.G. Laing, I. Nishino, C. Wallgren-Pettersson, J. Melki, V.M. Fowler, D.G. MacArthur, K.N. North, N.F. Clarke, Leiomodin-3 dysfunction results in thin filament disorganization and nemaline myopathy., J Clin Invest 124(11) (2014) 4693-4708. [16] C.W. Ockeloen, H.J. Gilhuis, R. Pfundt, E.J. Kamsteeg, P.B. Agrawal, A.H. Beggs, A. Dara Hama-Amin, A. Diekstra, N.V.A.M. Knoers, M. Lammens, N. van Alfen,
ACCEPTED MANUSCRIPT
Congenital myopathy caused by a novel missense mutation in the CFL2 gene., Neuromuscul Disord 22(7) (2012) 632-639. [17] N. Sambuughin, K.S. Yau, M. Olivé, R.M. Duff, M. Bayarsaikhan, S. Lu, L. Gonzalez-Mera, P. Sivadorai, K.J. Nowak, G. Ravenscroft, F.L. Mastaglia, K.N. North,
T
B. Ilkovski, H. Kremer, M. Lammens, B.G.M. van Engelen, V. Fabian, P. Lamont, M.R.
SC RI P
Davis, N.G. Laing, L.G. Goldfarb, Dominant mutations in KBTBD13, a member of the BTB/Kelch family, cause nemaline myopathy with cores., Am J Hum Genet 87(6) (2010) 842-847.
NU
[18] V.A. Gupta, G. Ravenscroft, R. Shaheen, E.J. Todd, L.C. Swanson, M. Shiina, K. Ogata, C. Hsu, N.F. Clarke, B.T. Darras, M.A. Farrar, A. Hashem, N.D. Manton, F.
MA
Muntoni, K.N. North, S.A. Sandaradura, I. Nishino, Y.K. Hayashi, C.A. Sewry, E.M. Thompson, K.S. Yau, C.A. Brownstein, T.W. Yu, R.J.N. Allcock, M.R. Davis, C.
ED
Wallgren-Pettersson, N. Matsumoto, F.S. Alkuraya, N.G. Laing, A.H. Beggs, Identification of KLHL41 Mutations Implicates BTB-Kelch-Mediated Ubiquitination as
PT
an Alternate Pathway to Myofibrillar Disruption in Nemaline Myopathy., Am J Hum
CE
Genet 93(6) (2013) 1108-1117.
[19] E. Malfatti, J. Böhm, E. Lacène, N. Romero, J. Laporte, A premature stop codon in
AC
MYO18B is associated with severe nemaline myopathy with cardiomyopathy, Neuromuscul Disord 25 S186. [20] S. Miyatake, S. Mitsuhashi, Y.K. Hayashi, E. Purevjav, A. Nishikawa, E. Koshimizu, M. Suzuki, K. Yatabe, Y. Tanaka, K. Ogata, S. Kuru, M. Shiina, Y. Tsurusaki, M. Nakashima, T. Mizuguchi, N. Miyake, H. Saitsu, K. Ogata, M. Kawai, J. Towbin, I. Nonaka, I. Nishino, N. Matsumoto, Biallelic Mutations in MYPN, Encoding
ACCEPTED MANUSCRIPT
Myopalladin, Are Associated with Childhood-Onset, Slowly Progressive Nemaline Myopathy., Am J Hum Genet 100(1) (2017) 169-178. [21] F.-O. Desmet, D. Hamroun, M. Lalande, G. Collod-Béroud, M. Claustres, C. Béroud, Human Splicing Finder: an online bioinformatics tool to predict splicing
T
signals., Nucleic Acids Res 37(9) (2009) e67.
SC RI P
[22] K. Kiiski, L. Laari, V.-L. Lehtokari, M. Lunkka-Hytönen, C. Angelini, R. Petty, P. Hackman, C. Wallgren-Pettersson, K. Pelin, Targeted array comparative genomic hybridization--a new diagnostic tool for the detection of large copy number variations in
NU
nemaline myopathy-causing genes., Neuromuscul Disord 23(1) (2013) 56-65. [23] Y.-E. Park, J.-H. Shin, B. Kang, C.-H. Lee, D.S. Kim, NEB-related core-rod
MA
myopathy with distinct clinical and pathological features., Muscle Nerve 53(3) (2016) 479-484.
ED
[24] S.Y. Kim, Y.-E. Park, H.-S. Kim, C.-H. Lee, D.H. Yang, D.S. Kim, Nemaline myopathy and non-fatal hypertrophic cardiomyopathy caused by a novel ACTA1
PT
E239K mutation., J. Neurol. Sci. 307(1-2) (2011) 171-173.
CE
[25] V.-L. Lehtokari, K. Kiiski, S.A. Sandaradura, J. Laporte, P. Repo, J.A. Frey, K. Donner, M. Marttila, C. Saunders, P.G. Barth, J.T. den Dunnen, A.H. Beggs, N.F.
AC
Clarke, K.N. North, N.G. Laing, N.B. Romero, T.L. Winder, K. Pelin, C. WallgrenPettersson, Mutation update: the spectra of nebulin variants and associated myopathies., Hum Mutat 35(12) (2014) 1418-1426. [26] N.B. Romero, S.A. Sandaradura, N.F. Clarke, Recent advances in nemaline myopathy., Curr Opin Neurol 26(5) (2013) 519-526.
ACCEPTED MANUSCRIPT
[27] M.C. Sharma, D. Jain, C. Sarkar, H.H. Goebel, Congenital myopathies – a comprehensive update of recent advancements., Acta Neurol Scand 119(5) (2009) 281292. [28] M.W. Lawlor, C.A. Ottenheijm, V.-L. Lehtokari, K. Cho, K. Pelin, C. Wallgren-
T
Pettersson, H. Granzier, A.H. Beggs, Novel mutations in NEB cause abnormal nebulin
SC RI P
expression and markedly impaired muscle force generation in severe nemaline myopathy., Skelet Muscle 1(1) (2011) 23.
[29] M. Scoto, T. Cullup, S. Cirak, S. Yau, A.Y. Manzur, L. Feng, T.S. Jacques, G.
NU
Anderson, S. Abbs, C. Sewry, H. Jungbluth, F. Muntoni, Nebulin (NEB) mutations in a childhood onset distal myopathy with rods and cores uncovered by next generation
MA
sequencing., Eur J Hum Genet 21(11) (2013) 1249-1252. [30] K. Donner, M. Sandbacka, V.-L. Lehtokari, C. Wallgren-Pettersson, K. Pelin,
ED
Complete genomic structure of the human nebulin gene and identification of alternatively spliced transcripts., Eur J Hum Genet 12(9) (2004) 744-751.
PT
[31] A. Rhoads, K.F. Au, PacBio Sequencing and Its Applications., Genomics
CE
Proteomics Bioinformatics 13(5) (2015) 278-289. [32] K. Kiiski, V.-L. Lehtokari, A. Löytynoja, L. Ahlstén, J. Laitila, C. Wallgren-
AC
Pettersson, K. Pelin, A recurrent copy number variation of the NEB triplicate region: only revealed by the targeted nemaline myopathy CGH array., Eur J Hum Genet 24(4) (2016) 574-580. [33] D. Piga, F. Magri, D. Ronchi, S. Corti, D. Cassandrini, E. Mercuri, G. Tasca, E. Bertini, F. Fattori, A. Toscano, S. Messina, I. Moroni, M. Mora, M. Moggio, I. Colombo, T. Giugliano, M. Pane, C. Fiorillo, A. D'Amico, C. Bruno, V. Nigro, N. Bresolin, G.P. Comi, New Mutations in NEB Gene Discovered by Targeted Next-
ACCEPTED MANUSCRIPT
Generation Sequencing in Nemaline Myopathy Italian Patients., J Mol Neurosci 59(3) (2016) 351-359. [34] B. Ilkovski, N. Mokbel, R.A. Lewis, K. Walker, K.J. Nowak, A. Domazetovska, N.G. Laing, V.M. Fowler, K.N. North, S.T. Cooper, Disease severity and thin filament
T
regulation in M9R TPM3 nemaline myopathy., J. Neuropathol. Exp. Neurol. 67(9)
SC RI P
(2008) 867-877.
[35] C. Wallgren-Pettersson, K. Pelin, K.J. Nowak, F. Muntoni, N.B. Romero, H.H. Goebel, K.N. North, A.H. Beggs, N.G. Laing, E.I.C.O.N. Myopathy, Genotype-
NU
phenotype correlations in nemaline myopathy caused by mutations in the genes for nebulin and skeletal muscle alpha-actin., Neuromuscul Disord 14(8-9) (2004) 461-470.
MA
[36] V. Straub, P.G. Carlier, E. Mercuri, TREAT-NMD workshop: pattern recognition in genetic muscle diseases using muscle MRI: 25-26 February 2011, Rome, Italy.,
ED
Neuromuscul Disord 22 Suppl 2 (2012) S42-53. [37] H. Jungbluth, C.A. Sewry, S. Counsell, J. Allsop, A. Chattopadhyay, E. Mercuri, K.
PT
North, N. Laing, G. Bydder, K. Pelin, C. Wallgren-Pettersson, F. Muntoni, Magnetic
CE
resonance imaging of muscle in nemaline myopathy., Neuromuscul Disord 14(12) (2004) 779-784.
AC
[38] M.M.R. Kathryn N North, Nemaline Myopathy. https://www.ncbi.nlm.nih.gov/books/NBK1288/, 2012 (accessed 11 June 2015). [39] E. Malfatti, V.-L. Lehtokari, J. Böhm, J.M. De Winter, U. Schäffer, B. Estournet, S. Quijano-Roy, S. Monges, F. Lubieniecki, R. Bellance, M.T. Viou, A. Madelaine, B. Wu, A.L. Taratuto, B. Eymard, K. Pelin, M. Fardeau, C.A.C. Ottenheijm, C. WallgrenPettersson, J. Laporte, N.B. Romero, Muscle histopathology in nebulin-related nemaline
ACCEPTED MANUSCRIPT
myopathy: ultrastrastructural findings correlated to disease severity and genotype., Acta Neuropathol Commun 2 (2014) 44. [40] M.M. Ryan, B. Ilkovski, C.D. Strickland, C. Schnell, D. Sanoudou, C. Midgett, R. Houston, D. Muirhead, X. Dennett, L.K. Shield, U. De Girolami, S.T. Iannaccone, N.G.
T
Laing, K.N. North, A.H. Beggs, Clinical course correlates poorly with muscle
SC RI P
pathology in nemaline myopathy., Neurology 60(4) (2003) 665-673.
[41] J.-M. Hong, S.-M. Kim, I.-N. Sunwoo, S.-H. Kim, T.-S. Kim, D.-S. Shim, Y.-C. Choi, Clinical heterogeneity in Korean patients with nemaline myopathy., Yonsei Med J
NU
51(2) (2010) 225-230.
[42] V.-L. Lehtokari, K. Pelin, M. Sandbacka, S. Ranta, K. Donner, F. Muntoni, C.
MA
Sewry, C. Angelini, K. Bushby, P. Van den Bergh, S. Iannaccone, N.G. Laing, C. Wallgren-Pettersson, Identification of 45 novel mutations in the nebulin gene associated
ED
with autosomal recessive nemaline myopathy., Hum. Mutat. 27(9) (2006) 946-956. [43] C. Wallgren-Pettersson, V.-L. Lehtokari, H. Kalimo, A. Paetau, E. Nuutinen, P.
PT
Hackman, C. Sewry, K. Pelin, B. Udd, Distal myopathy caused by homozygous
CE
missense mutations in the nebulin gene., Brain 130(6) (2007) 1465-1476. [44] V.-L. Lehtokari, K. Pelin, A. Herczegfalvi, V. Karcagi, J. Pouget, J. Franques, J.F.
AC
Pellissier, D. Figarella-Branger, M. von der Hagen, A. Huebner, B. Schoser, H. Lochmüller, C. Wallgren-Pettersson, Nemaline myopathy caused by mutations in the nebulin gene may present as a distal myopathy., Neuromuscul Disord 21(8) (2011) 556562. [45] M. Marttila, M. Hanif, E. Lemola, K.J. Nowak, J. Laitila, M. Grönholm, C. Wallgren-Pettersson, K. Pelin, Nebulin interactions with actin and tropomyosin are altered by disease-causing mutations., Skelet Muscle 4 (2014) 15.
ACCEPTED MANUSCRIPT
Figure 1. Schematic diagram depicting the structural organization of the protein players in nemaline myopathy. A, A-band; I, I-band; M, M-line; Z, Z-disc; KLHL, Kelch-like protein. Figure 2. Flow diagram of the sequence in genetic investigation.
T
Figure 3. Magnetic resonance imaging (A) and computed tomography (B, C, and D)
SC RI P
findings of distal legs. In patient 15, the bilateral tibialis anterior, gastrocnemius medialis, and left soleus muscles show high T2 signals (A, arrows). In computed tomography, low-density lesions are observed in the right soleus and gastrocnemius
NU
muscles in patient 8 (B, arrows), as well as in the bilateral gastrocnemius and soleus muscles in patient 10 (C, arrows). In patient 9, a patch-like distribution of abnormal
MA
intensities is evident (D). (E) Normal computed tomography of lower legs. Figure 4. Distribution of nemaline rods in muscle fiber observed under a light
ED
microscope. In patients 3 (A), 7 (B), 13 (C), and 14 (D), the nemaline rods are scattered across the muscle fiber. On the other hand, in patients 5 (E), 6 (F), 9(G), and 12 (H), the
PT
nemaline rods are located mainly at the subsarcolemmal areas. All slides were stained
CE
with modified Gomori trichrome stain. Bar: 50 µm (A–H). Figure 5. Electron microscopy findings of nemaline myopathies. In patient 8, electron-
AC
dense nemaline rods (arrow) are clearly observed along with the Z-line disruptions (arrowhead) (A). In patient 12, nemaline rods are accumulated mainly in the subsarcolemmal areas (B). In patient 2, numerous nemaline rods are scattered in atrophic muscle fibers, which were not clearly observed under the light microscope (C). In patient 7, only Z-line disruptions are observed. (D). Bars indicate 5 µm in (A) and (B), 2 µm in (C), and 1 µm in (D). All sections were stained with uranyl acetate and lead citrate.
MA
NU
SC RI P
T
ACCEPTED MANUSCRIPT
AC
CE
PT
ED
Fig. 1
MA
NU
SC RI P
T
ACCEPTED MANUSCRIPT
AC
CE
PT
ED
Fig. 2
AC
Fig. 3
CE
PT
ED
MA
NU
SC RI P
T
ACCEPTED MANUSCRIPT
SC RI P
T
ACCEPTED MANUSCRIPT
AC
CE
PT
ED
MA
NU
Fig. 4
NU
SC RI P
T
ACCEPTED MANUSCRIPT
AC
CE
PT
ED
MA
Fig. 5
ACCEPTED MANUSCRIPT
Table 1. Clinical and laboratory data of fifteen patients with nemaline myopathy Pat ient nu 1 2 3 4 5 6 7 8 9 10 11 12 mb er
Upp er extre mity , Prox imal Low er extre mity , Prox imal Ankl e, Dors iflex ion Ankl e, Plan tar flexi on Resp irato
Typi cal
Typ ical
Typ ical
Chi ldh ood ons et
Chil dhoo d onset
Childho od onset
Chil dho od onse t
3 Mo /F
1 Yr /F
5 Yr / M
3 Mo /F
6 Mo /M
6 Yr / F
20 Yr / M
16 Yr /M
15 Yr / M
9 Yr / M
9 Yr /F
At birth
At bir th
At birt h
At birt h
At birth
1 Yr
10 Mo
5 Yr
3 Yr
5 Yr
Poor sucki ng
Hy po to nia
Poo r suc kin g
Poo r suc kin g
Wea k cryin g
Mot or dev elo pm ent dela y
Mo tor dev elo pm ent del ay
Ac hill es ten don con trac ture
Slow runn er after 3 years old
None
M ot he r
No ne
No ne
None
N/ A
No ne
No ne
2
3+
5
N/ A
3
2
4
4
Chil dhoo d onset
14
15
Child hood onset
Child hood onset
Chi ldh ood ons et
T
Ty pic al
24 Yr /M
20 Yr /M
43 Yr / M
6 Yr
9 Yr
9 Yr
9Yr
10 Yr
Distal lower extremit y weaknes s
Toein gait
Dista l lowe r extre mity weak ness
Unsta ble gait and slow runner
Slow runner
Foo t dro p for 4 yea rs
Non e
N/A
N/A
None
Broth er
Broth er
Bro ther
NU
SC RI P
25 Yr / M
MA
ED
Fam ily histo ry Mus cle wea knes s
Typ ical
4
2
N/ A
4
4
N/A
5
4
4+
5
PT
Clini cal featu re at onse t
Int er me dia te
CE
Age / Gen der Sym pto m onse t age
Inter medi ate
AC
Sub grou p
13
N/ A
2
4
4
5
4
4
N/A
5
5
5
3
2
3+
4
N/ A
2
5
4+
1-2
4
2
N/A
4+
2
1
2
2
3+
4
N/ A
2
3
4+
5
4
4+
N/A
4+
5
4
2
Posit ive
M ec ha
Ne gati ve
Pne um oni
N/A
Neg ativ e
Ort hop nea
Ne gati ve
Nega tive
Negativ e
Neg ativ e
Nega tive
Negati ve
Negati ve
Neg ativ e
ACCEPTED MANUSCRIPT
ry invo lvem ent
a
at 15 Yr
15
25
7
119
N/ A
5,3 70
151
24
N/A
N SR
N/ A
N/ A
NSR
NS R
N/ A
N/ A
NSR
N/ A
N/A
My opa thic
N/A
scat tere d
AC TA 1
142
No rm al
N/ A
N/ A
N/A
N/ A
Elec trom yogr aphy
N/A
M yo pat hic
N/ A
My opa thic
Nor mal
My opa thic
My opa thic
Loca tion of rods in LM
scatt ered
No vis ibl e in L M
scat tere d
sub sar col em ma
subsa rcole mma
Sca tter ed, sub sarc ole mm a
Gen e
NEB
TP M 3
NE B
No ne
NEB
NE B
†‡
c.3 2T >A †
‡
ex16 1;c.2 3245 C>T *
AC
ex84/9 2/100; c.1269 8A>T† p.R28 09X p.L44 23W p.D42 33V
p. M1 1K
ED
PT
CE
ex61;c .8425 C>T* ex87/9 5/103; c.1326 8T>G
p.R7 749 X
ex29;c .2875_ 2877d elTG T*
p.C95 9del
ex13 9;c.2 0928 delG
c.71 5G> A†
*
p.L6 977 Nf s* 5
SC RI P
N/A
Pred icted cons eque nce
N/A
118
118
103
NSR
NS R
NSR
N/A
N/A
N/ A
Trivial TR
N/A
N/A
N/A
N/A
N/ A
N/A
N/A
Myo pathi c
Myop athic
Myop athic
My opa thic
scat tere d
Scatt ered, subs arcol emm a
Scattere d, subsarco lemma
N/A
subs arcol emm a
scatter ed
scatter ed
Sca tter ed
NE B
NEB
NEB
NEB
NEB
NEB
NEB
NE B
ex80 ;c.11 930 G> A *‡
ex82/ 90/98; c.124 78A> T†‡ int18; c.167 4+1G >T*
ex39;c.46 17_4629d elTTATA AAGCAG AT insAAA* ex175;c.2 4684G>A*
ex167;c .23908_ 23911d elAGA G*
ex167;c .23908_ 23911d elAGA G*
MA
Card iac ultra sono grap hy
Hy pert rop hic car dio my opa thy
Nucl eotid e chan ge
47
T
36
NU
Seru m CK, U/L (nor mal; 0145) Elec troca rdio grap hy
nic al ve nti lat io n
p.E2 39K
p.W 3977 X
p.I416 0F
p.H1539Q fs*12 p.S8228S
int14 4;c.2 1522 +3A> G*
ex82/ 90/98; c.1239 7delA ‡
ex88/ 96/10 4;c.13 389G >A ‡
p.M4 133X p.W4 463X
ex33 ;c.33 87de lC* ex17 5;c.2 4684 G>A *
p.R797 0Sfs*48
p.R797 0Sfs*48
p.Y1 130 Mfs *53 p.S8 228 S
Abbreviations; Intermediate, intermediate congenital form; Typical, typical congenital form; Childhood, mild nemaline myopathy with childhood onset; CK, creatine kinase; N/A, not applicable; LM, light microscope; Mo, months; NSR, normal sinus rhythm; TR, tricuspid valve regurgitation; Yr, years Novel mutations are bold. Variant was identified by whole exome sequencing* or Sanger sequencing†. T he exon 82-89, 90-97, and 98-105 are identical. Therefore, this variant may be in any of these locations‡ . NEB, NG_009382, NM_001271208; TPM3, NG_008621, NM_152263; ACTA1, NG_006672, NM_001100
ACCEPTED MANUSCRIPT
Frequency
Increased fiber size variation
13/15 (87%)
Type 1 fiber predominance
12/15 (80%)
Endomysial fibrosis
8/15 (53%)
Type 1 fiber atrophy
2/15 (13%)
Increased fibers with internal nuclei
2/15 (13%)
Core lesion
2/15 (13%)
AC
CE
PT
ED
MA
NU
SC RI P
Abnormal pathologic findings
T
Table 2. Summary of muscle pathology findings
ACCEPTED MANUSCRIPT
AC
CE
PT
ED
MA
NU
SC RI P
T
Highlights Whole exome sequencing is useful for genetic diagnosis of nemaline myopathy. NEB is the most common causative gene among Korean patients with nemaline myopathy. Distal leg weakness is frequent in NEB associated childhood onset nemaline myopathy.
Jong-Mok Lee, Jeong Geun Lim, Jin-Hong Shin, Young-Eun Park, Dae-Seong Kim PII: DOI: Reference:
S0022-510X(17)34385-X doi:10.1016/j.jns.2017.10.020 JNS 15615
To appear in:
Journal of the Neurological Sciences
Received date: Revised date: Accepted date:
5 July 2017 19 September 2017 9 October 2017
Please cite this article as: Jong-Mok Lee, Jeong Geun Lim, Jin-Hong Shin, Young-Eun Park, Dae-Seong Kim , Clinical and genetic diversity of nemaline myopathy from a single neuromuscular center in Korea. The address for the corresponding author was captured as affiliation for all authors. Please check if appropriate. Jns(2017), doi:10.1016/ j.jns.2017.10.020
This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.
ACCEPTED MANUSCRIPT
Manuscript title Clinical and genetic diversity of nemaline myopathy from a single neuromuscular center in Korea
T
Authors
SC RI P
Jong-Mok Leea, Jeong Geun Limb, Jin-Hong Shina, Young-Eun Parkc, Dae-Seong Kima,c*
a
NU
Affiliations
Department of Neurology, Research Institute for Convergence of Biomedical Science
MA
and Technology, Pusan National University Yangsan Hospital Department of Neurology, Keimyung University School of Medicine
c
Department of Neurology, Pusan National University School of Medicine
ED
b
CE
PT
Running title; Clinical and genetic diversity of nemaline myopathy
Corresponding author
AC
Dae-Seong Kim, MD, PhD Department of Neurology, Pusan National University Yangsan Hospital 20 Geumo-ro, Mulgeum-eup, Yangsan-si, Gyeongsangnam-do, 50612, Republic of Korea. Tel: +82-55-360-2450 Fax: +82-55-360-2521 E-mail: [email protected]
ACCEPTED MANUSCRIPT
Acknowledgements We deeply appreciate to Kirsi Kiiski, Vilma-Lotta Lehtokari and other staffs of the Folkhälsan Institute of Genetics and The Department of Medical and Clinical Genetics at University of Helsinki for their contribution of identifying copy number variations in
SC RI P
T
triplicate region of NEB using array CGH.
Funding
This research was supported by Basic Science Research Program through the National
MA
and Technology (2013R1A1A2005521)
NU
Research Foundation of Korea (NRF) funded by the Ministry of Education, Science,
Conflict of interest
AC
CE
PT
ED
The authors state that there is no conflict of interest.
ACCEPTED MANUSCRIPT
Abstract Nemaline myopathy (NM), the most common of the congenital myopathies, is caused by various genetic mutations. In this study, we attempted to identify the causative mutations of NM and to reveal any specific genotype–phenotype relationship in Korean
SC RI P
T
patients with this disease. We investigated the clinical features and genotypes in 15 pathologically diagnosed NM patients, using whole exome sequencing (WES) combined with targeted sequencing and array-based comparative genomic hybridization. This strategy revealed pathogenic causative mutations in seven patients (46.7%), among
NU
whom mutations in the nebulin gene (NEB) were the most frequent (5 patients, 33.3%). Copy number variation (CNV) abnormality in NEB was not observed in any of our
MA
patients. In those with NEB-associated NM, the clinical spectrum was highly variable regardless of the mutation type. However, the majority of patients showing anterior
ED
lower leg weakness were associated with mutations located between NEB exons 166
PT
and 177. We concluded that the combination of WES and targeted Sanger sequencing is an effective strategy for analyzing genotypes in patients with NM, and that CNV in
CE
NEB may not be a frequent cause of this disease among Koreans.
AC
Keywords; nemaline myopathy, NEB, whole exome sequencing, comparative genomic hybridization, copy number variation
ACCEPTED MANUSCRIPT
1. Introduction Nemaline myopathy (NM), the most common of the congenital myopathies, is pathologically characterized by the presence of nemaline rods in skeletal muscle fibers. The nemaline rods are accumulations of degraded Z-disc components as well as broken
SC RI P
T
thin filaments [1].
NM is a genetically heterogeneous disease that is caused by pathological variants in the genes encoding components of the thin filaments and associated proteins. The thin filament of skeletal muscle consists of nebulin (NEB), tropomyosin-β and -γ (TPM2 and
NU
TPM3), actin (ACTA1), and troponin T (TNNT1) [2-6]. The actin and tropomyosin proteins are double-helical structures encircling the nebulin protein, and are bound to
MA
the Z-disc at the C-terminal and to tropomodulin at the N-terminal. The troponin T adjacent to tropomyosin regulates contraction in accordance with calcium ions. The
ED
stabilization of nebulin and tropomodulin is controlled by a muscle-specific protein,
PT
Kelch-like family member 40 (KLHL40) (Fig. 1) [7]. The dysregulation of these genes breaks the thin filament components directly or indirectly [8].
CE
The clinical spectrum of NM is known to be diverse [9-11]. Generally, NM can be classified into six clinical forms on the basis of age of onset and severity of motor and
AC
respiratory involvement [12]. In the severe neonatal form of NM, patients typically present with severe muscular hypotonia and respiratory failure at birth. Dilated cardiomyopathy or multiple joint contractures can be complicated. Amish NM is a clinically distinct autosomal recessive disease with neonatal onset and early childhood lethality. It is associated with TNNT1 mutations and has been described only in a single Amish family [6] and a single Dutch case [13]. Patients with intermediate congenital NM fail to achieve motor developmental milestones, or they become wheelchair-
ACCEPTED MANUSCRIPT
dependent and/or develop respiratory failure by the age of 11 years, although they initially show anti-gravity movement or independent respiration at birth. In the typical congenital form of the disease, patients show spontaneous anti-gravity limb movement, and respiratory involvement is not obvious. Patients may show delayed gross motor
T
development with proximal limb and bulbar weakness, which is static or progresses
SC RI P
very slowly. However, most of the patients with typical congenital NM are able to lead independent lives [10]. Childhood-onset NM is frequently inherited as an autosomal dominant trait, and patients usually develop their first symptom in their late first or
NU
second decade. Although a minority of the patients may become wheelchair-bound at adult age, most of them can lead independent ambulation. In adult-onset NM, patients
MA
develop generalized muscle weakness between the ages of 20 and 50 years and most of them can lead independent lives. In childhood- and adult-onset NM, cardiac
ED
involvement or respiratory failure is rare [14, 15]. Although NM is associated with many genetic causes, the genotype–phenotype
PT
correlation is not so clear in many of the cases. Furthermore, the large size of the genes
CE
associated with NM makes the genetic diagnosis a challenging task. For example, NEB, which is being considered as the most common causative gene of NM, has an enormous
AC
size with more than 180 exons. In this regard, the recent introduction and development of next-generation sequencing technology could be useful for exploring the genetic etiologies of NM. This notion led us to investigate and identify NM-causative gene mutations in affected patients. First, we attempted to identify causative mutations in all NM-related genes, using currently available technologies; namely, targeted Sanger sequencing of small-sized NM-related genes, whole exome sequencing (WES), and array-based comparative
ACCEPTED MANUSCRIPT
genomic hybridization (array-CGH) for the analysis of copy number variation (CNV) of NEB. Second, once the genetic diagnosis was established, we attempted to reveal the specific relationship between genotypes and clinical phenotypes, such as clinical
AC
CE
PT
ED
MA
NU
SC RI P
T
features or muscle biopsy findings.
ACCEPTED MANUSCRIPT
2. Methods 2.1. Patients We retrospectively recruited 15 patients from 14 unrelated families, who were diagnosed with NM at the neuromuscular clinic of Pusan National University Hospital
SC RI P
T
and Pusan National University Yangsan Hospital since 1998. The diagnosis of NM in all patients was based on the presence of nemaline rods in their muscle biopsy. Clinical information was collected from the patient’s medical records; gender, presence of affected family members, age at onset, initial symptom, distribution of muscle weakness,
NU
respiratory muscle involvement, and associated dysmorphic features. Laboratory findings, including serum creatine kinase (CK) levels and electrocardiogram and
MA
electromyography readings, were also obtained and analyzed. Written informed consent was obtained from all the patients examined for genomic DNA sequencing, and this
ED
study was approved by the ethical review board of Pusan National University Yangsan
PT
Hospital (IRB No. 05-2014-063). 2.2. Pathological analysis
CE
Open muscle biopsy was performed under local or general anesthesia on the clinically affected limb muscles. The biopsied muscles were flash frozen and stored at –80 °C
AC
until used. The serial frozen sections were stained with the following histochemical stains; hematoxylin and eosin (H&E), modified Gomori trichrome, nicotinamide adenine dinucleotide tetrazolium reductase (NADH-TR), and adenosine triphosphatase, at varying pH values. Muscle specimens were also prepared for electron microscopy observation. In brief, the specimens were fixed with 2% glutaraldehyde in 0.1 M cacodylate buffer. After shaking with a mixture of 4% osmium tetroxide, 1.5% lanthanium nitrate, and 0.2 M s-collidine
ACCEPTED MANUSCRIPT
for 2–3 hours, the samples were embedded in epoxy resin. Semi-thin sections of 1-μm thickness were stained with toluidine blue, whereas ultrathin sections of 50-nm thickness were stained with uranyl acetate and lead citrate. 2.3. DNA analysis
T
Genomic DNA extracted from each patient’s blood or skeletal muscles was used. First,
SC RI P
all coding exons and exon-intron boundaries of ACTA1 and TPM3 were amplified by PCR and analyzed by Sanger sequencing [5]. If no pathogenic mutation was identified in these two genes, other causative genes of congenital myopathies, including NM-
NU
related genes (NEB, CFL2, TPM2, TNNT1, KBTBD13, KLHL40, KLHL41, LMOD3, MYO18B, and MYPN), were evaluated by WES [2, 3, 6, 7, 15-20]. Exome capture was
MA
performed using the Illumina TruSeq Exome Enrichment Guide. Sequence reads were mapped to the human reference genome assembly (GRch37/hg19) using Integrative
ED
Genomics Viewer (IGV; Broad Institute, Cambridge, MA, USA). Variants potentially affecting protein structure or function, including nonsynonymous variants, frameshifts,
PT
or variants affecting splicing, were investigated. The variants showed a depth of more
CE
than 30 and a minor allele frequency of less than 0.01. We evaluated the impact of mutations using the SIFT/PROVEAN and Polyphen2 prediction system in the case of
AC
point mutations. The splice sites were evaluated with Human Splicing Finder [21]. Sanger sequencing was performed to confirm the mutations found by WES. Because WES has clear limitations in reading the triplicate region of NEB, Sanger fill- in was performed for patients in whom a single heterozygous variant or no variant was identified. In addition, all patient samples were sent to the Folkhälsan Institute of Genetics at the University of Helsinki for CNV analysis by targeted array-CGH, as
ACCEPTED MANUSCRIPT
previously described [22]. Information of the primer sequences used is available upon
AC
CE
PT
ED
MA
NU
SC RI P
T
request.
ACCEPTED MANUSCRIPT
3. Results Overviews of the clinical features and genetic analysis of the 15 patients with NM are summarized in Table 1 and Figure 2, respectively. In terms of age of onset and clinical features, we could classify our patients into three
SC RI P
T
groups: (1) the intermediate congenital form, (2) the typical congenital form, and (3) mild childhood-onset NM. None of our patients were classified as severe neonatal type, Amish NM, or mild adult-onset NM. Two patients (patients 1 and 2), who developed their first symptom at birth, were classified as intermediate congenital NM. Both of
NU
them showed generalized muscular hypotonia, and they developed respiratory failure requiring mechanical ventilation during the neonatal period. One patient showed
MA
marked limb muscle weakness with an inability to move the limbs against gravity. Five patients (patients 3, 4, 5, 6, and 7) had the typical congenital form of NM. In this group,
ED
two patients manifested subclinical weakness of the respiratory musculature (patients 4
PT
and 7), and one (patient 6) showed predominant calf weakness. Eight patients (patients 8, 9, 10, 11, 12, 13, 14, and 15) were classified into benign childhood-onset NM. Motor
CE
developmental delay with gait disturbance was the most common clinical manifestation, and facial paresis was evident in one patient (patient 10). Pes cavus or equinovarus
AC
deformity was observed in seven patients (patients 8, 9, 10, 11, 12, 13, and 14). This group could be further subdivided into six patients with predominant distal leg weakness, and one patient with evenly distributed weakness (patient 9). In one patient (patient 11), clinical information regarding muscle weakness distribution was not available. Among the six patients with predominant distal leg weakness, four (patients 8, 10, 13, and 14) showed predominant peroneal muscle weakness with foot drop, whereas
ACCEPTED MANUSCRIPT
the peroneal and calf muscles were equally affected in the other two individuals (patients 12 and 15). Six patients, all of whom were classified as having mild childhood-onset NM (patients 8, 9, 10, 13, 14, and 15), underwent muscle CT or MRI. Five of them manifested distal leg
T
dominant muscle weakness, whereas the sixth patient (patient 9) showed mild
SC RI P
generalized muscle weakness that was not confined to a specific muscle group. In patients 13 and 14, muscle CT showed preferential involvement of the bilateral tibialis anterior muscle. Patient 15 revealed a high signal change in the tibialis anterior, soleus,
NU
and gastrocnemius muscles in T2-weighted images of muscle MRI (Fig. 3A). Although patient 8 presented with predominant bilateral foot drop, his muscle CT showed a
MA
predominant affection of the right gastrocnemius muscle (Fig. 3B). Slight involvement of the gastrocnemius muscle with sparing of the anterior compartments of the lower legs
ED
and thigh muscles was observed in patient 10 (Fig. 3C). Patient 9 showed a patch-like distribution of abnormal intensities in the muscle CT (Fig. 3D). Serum CK levels were
PT
generally normal, except for one patient with an ACTA1 mutation (patient 7) who
CE
showed a markedly elevated serum CK level (5,370 IU/L; normal 7–151 IU/L) and associated hypertrophic cardiomyopathy.
AC
Modified Gomori trichrome staining of the biopsied muscle tissues showed characteristic nemaline bodies in all patients, except for one individual who was classified with an intermediate congenital form associated with TPM3 mutation (patient 2). In this patient, all muscle fibers were extremely atrophic, and the nemaline body was not readily identifiable under the light microscope, but was evident under the electron microscope. The locations of nemaline bodies in the muscle fibers were variable, being either in the cytoplasm or the subsarcolemmal area, or both, and did not show any
ACCEPTED MANUSCRIPT
significant correlation with the clinical phenotype or genes affected (Fig. 4). In most of the patients, the nemaline bodies were present in type 1 fibers, except for patient 5, in whom nemaline bodies were exclusively observed in atrophic type 2 fibers. Interestingly, two patients also showed core lesions in the NADH-TR stain at the same
T
time (central cores in patient 10 and minicores in patient 15). The clinical, pathological,
SC RI P
and genetic features of both patients had been previously reported elsewhere, and both had predominant distal leg weakness and mutations in NEB [23]. Other frequently observed pathological abnormalities included increased fiber size variability (13/15),
NU
type 1 fiber predominance (12/15), endomysial fibrosis (8/15), type 1 fiber atrophy (2/15), and increased number of muscle fibers with internal nuclei (2/15). However,
MA
none of these findings showed clear correlation with the patient’s clinical phenotype or genotype. Under electron microscopy, all showed the presence of characteristic
ED
filamentous aggregations, which were caused from disruption of the Z-band (Fig. 5). Dominant pathogenic mutations affecting TPM3 (patient 2) and ACTA1 (patient 7) were
PT
identified by Sanger sequencing [24]. Subsequent investigation revealed 16 additional
CE
mutations affecting NEB in 12 patients (Figure 2); namely, four nonsense mutations, three missense mutations, six small del/ins, and three splice site mutations. Eight
AC
mutations were novel (i.e., not reported elsewhere; bolded in Table 1), and their effects, evaluated using the prediction system SIFT/PROVEAN, Polyphen2, or Human Splicing Finder, were all found to be deleterious. Two known mutations (Ser8228Ser and Arg7970Serfs*48) were shared by two patients, respectively [23, 25]. In all patients with NEB-associated NM, at least one nonsense or frameshift mutation was identified, except in one patient in whom only a single heterozygous deletion of a single amino acid was identified (patient 5).
ACCEPTED MANUSCRIPT
None of our patients with NM possessed abnormal CNV of the triplicate region of NEB. Finally, we were able to confirm a genetic diagnosis in seven of the 15 patients with NM. Of the other eight patients, only a single heterozygous mutation in NEB was identified in seven individuals, and no mutation was identified in any NM-related gene
AC
CE
PT
ED
MA
NU
SC RI P
T
in the eighth individual (patient 4).
ACCEPTED MANUSCRIPT
4. Discussion In this study, we aimed to identify genetic defects in 15 patients with pathologically confirmed NM using WES combined with targeted sequencing, and were able to identify causative mutations in seven patients. Among the genes investigated, NEB was
SC RI P
T
the most common causative gene of NM in our series. Two other pathogenic variants detected by targeted Sanger sequencing consisted of a mutation affecting TPM3 and ACTA1 individually. Although the exact proportion is uncertain, mutations in NEB have been attributed to 50% of NM cases [26]. Our study showed that autosomal recessive
NU
pathogenic variants in NEB accounted for 38% of our pool, which is compatible with previous reports and shows that NEB is also the major causative gene of NM in Korea
MA
[27, 28].
WES has already shown a strong impact on the investigation of pathogenic variants in
ED
congenital myopathy, which has many candidate genes [29]. In our study, we identified
PT
pathogenic compound heterozygous variants of NEB in two patients using WES only. Among 11 patients in whom WES had identified either a single heterozygous mutation
CE
only or no significant mutation, three patients were revealed by Sanger sequencing to have additional pathogenic heterozygous variants at repetitive regions of NEB, and the
AC
genetic diagnosis was confirmed. The reason why WES had shown a relatively low detection rate in NEB is most likely due to the short read length of this technique [25, 30]. Because NEB has a highly repetitive region between exons 82 and 105, it is most likely that mapping errors cannot be avoided using current WES technology with its limited read length. Given that we had seven patients harboring only a single causative heterozygous mutation in NEB and one genetically undiagnosed patient, it is strongly suggested that cryptic pathogenic variants or large deletions in the highly repetitive
ACCEPTED MANUSCRIPT
region of NEB may not be detectable using the current standard technology of WES or Sanger sequencing [22]. In this regard, a recently developed single- molecule, real-time, new-generation sequencing technology that offers longer read lengths may be useful for overcoming this problem [31].
T
Recently, abnormal CNV in the triplicate region of NEB was implicated as a frequent
SC RI P
cause of NM [32]. However, no CNV abnormality was identified in our patients. Although the number of samples studied was small, this finding suggesting that CNV abnormality is not a common cause of NEB-related NM among Koreans may reflect an
NU
ethnic difference in the genetic background of the disease [32].
The clinical spectrum of NM was wider than previously recognized [25, 33]. Patients
MA
with TPM3- or ACTA1-associated NM typically showed onset at birth or in infancy. In ACTA1-associated NM, intrafamilial phenotypic variability has also been reported [27].
ED
The results of our study are compatible with the previous study, because our patients with TPM3 (patient 2) or ACTA1 (patient 7) mutations presented their symptoms at
PT
birth or in infancy [34]. In patients with NEB-associated NM, the age of onset and
CE
clinical severity were highly variable. Whereas both patients with the intermediate congenital form showed profound limb weakness associated with respiratory or
AC
swallowing difficulties, those with mild childhood-onset NM manifested mild limb weakness and many of them were still ambulatory. One of the most remarkable findings in our series is that only two cases were associated with respiratory failure, which is much fewer than that seen in previous studies [33, 35]. This is most likely because we definitely had a smaller number of patients with severe phenotype than the other study series (none with severe neonatal form and only two with intermediate congenital form). Another point is that distal leg weakness was frequent in NEB-associated NM, occurring
ACCEPTED MANUSCRIPT
in one patient with typical congenital NM (patient 6) and in six with mild childhoodonset NM (patients 8, 10, 12, 13, 14, and 15). Among them, four developed predominant weakness in the ankle extensors (patients 8, 10, 13, and 14) and one manifested predominant ankle flexor weakness (patient 6). In the other two patients,
T
ankle extensors and flexors were equally affected (patients 12 and 15).
SC RI P
In the previous studies using muscle MRI, the rectus femoris, vastus intermedius, and tibialis anterior muscles had been considered as the most frequently affected leg muscles in patients with NEB-related NM, and it had been suggested that predominant
NU
gastrocnemius muscle involvement may exclude the diagnosis of NEB-related NM [36]. However, another study showed definite involvement of the hamstring muscles in
MA
addition to the rectus femoris muscle and pronounced involvement of the gastrocnemius muscle in a patient with NEB mutations [37]. In our study, patient 14 with mild
ED
childhood-onset NM and distal dominant phenotype exhibited similar findings. His muscle MRI showed a selective involvement of muscles of the posterior group at the
PT
thigh level. Moreover, among his lower leg muscles, the tibialis anterior, gastrocnemius
CE
medialis, and soleus muscles were selectively affected (Fig. 3A). Thus, our study clearly showed that affection of the gastrocnemius muscle is not unusual in patients
AC
with NEB-associated NM, which had been reported to be rare in the literature [38]. The correlation between muscle pathology and clinical features in NM is still controversial. In a previous study, it was suggested that the number of rods observed in muscle pathology and the residual amount of nebulin protein in western blot analysis are correlated with clinical severity [39]. Another study suggested that the features of sarcomeric disturbance in electron microscopy findings are also correlated with muscle weakness in NM [40]. However, another study using a large number of pathology
ACCEPTED MANUSCRIPT
specimens showed that the numbers and localization of nemaline rods correlated poorly with clinical severity in NM [41]. We were not able to identify any significant correlations between the numbers or localization of rods with the clinical findings, such as age of onset and clinical severity of muscle weakness. Given the relatively small
T
patient number in our study, further study using a larger sample size will be needed to
SC RI P
elucidate this issue.
In terms of the genotype–phenotype correlation with regard to reported mutations in NEB, the clinical severity of our cohort differed from that of reported cases. Although
NU
the splice site mutation c.24579G>A (p.Ser8228Ser) was identified in two patients with mild childhood-onset NM in our series, the same mutation has been reported in the
MA
typical congenital form of the disease [25]. A small deletion leading to frame shifting (c.23908_23911delAGAG [p.Arg7970Serfs*48]), identified in two of our patients with
ED
mild childhood-onset NM manifesting as predominant distal leg weakness (patients 13 and 14), was associated with typical congenital NM in a previous report [33]. The
PT
clinical phenotype of two nonsense mutations identified from patients with relatively
CE
severe phenotypes in our cohort (c.8425C>T [p.Arg2809X] and c.23245C>T [p.Arg7749X]) was not available in the previous reports [25, 42]. Only patient 9,
AC
harboring the c.1674+1G>T mutation, showed similar clinical presentation to that of a reported case of mild childhood-onset NM [25]. This discrepancy could be explained by the unshared second mutation, which may have a potential role in muscle function. In addition, we were not able to identify any clear relationship between the mutation type and the patient’s clinical phenotype. For example, patient 12, who had compound heterozygous nonsense and frameshift mutations, was classified as mild childhood-
ACCEPTED MANUSCRIPT
onset NM, whereas another patient with compound heterozygous nonsense and missense mutations (patient 1) presented with severe phenotype (Table 1). Interestingly, the proportion of patients with distal manifestations in our cohort (47%) was significantly larger than that from a previous study employing a larger number of
T
families (showing only 10 out of 159 families (6%)) [25, 43, 44]. Although this
SC RI P
discrepancy could be due to the bias from the small cohort size, the higher frequency of distal manifestation in our cohort seems to be meaningful. Moreover, the majority of patients showing anterior lower leg weakness in our cohort had mutations located
NU
between NEB exons 166 and 177. Donner et al. had reported that the alternatively spliced exons 166–177 express 20 different transcripts in adult human tibialis anterior
MA
muscle, where exons 167 and 175 expressed the majority of these transcripts, which strongly suggests that mutations at this location could lead to clinical involvement of
ED
the anterior compartment of the lower legs [30]. A recent research study has suggested that the severity of the clinical features is
PT
determined by the degree of alteration of the binding affinity among nebulin,
CE
tropomyosin, and actin by the location and type of mutations in NEB [45]. Further study is needed in order to clarify this issue.
AC
In summary, our study showed that NEB is the most common NM-causative gene in Korean patients with this disease. Although combined WES and Sanger sequencing is an effective strategy for the detection of pathogenic variants in NM, the highly repetitive region in NEB is the major obstacle to a definite genetic analysis. Furthermore, contrary to the study results in western countries, abnormal CNV in the triplicate region of NEB may not be a frequent cause of NM among Koreans. Further study is required in order to establish the relationship between the genotypes and clinical features of NM.
ACCEPTED MANUSCRIPT
References [1] A.S. McElhinny, S.T. Kazmierski, S. Labeit, C.C. Gregorio, Nebulin: the nebulous, multifunctional giant of striated muscle., Trends Cardiovasc Med 13(5) (2003) 195-201. [2] K. Pelin, P. Hilpela, K. Donner, C. Sewry, P.A. Akkari, S.D. Wilton, D.
SC RI P
T
Wattanasirichaigoon, M.L. Bang, T. Centner, F. Hanefeld, S. Odent, M. Fardeau, J.A. Urtizberea, F. Muntoni, V. Dubowitz, A.H. Beggs, N.G. Laing, S. Labeit, A. de la Chapelle, C. Wallgren-Pettersson, Mutations in the nebulin gene associated with autosomal recessive nemaline myopathy., Proc. Natl. Acad. Sci. U.S.A. 96(5) (1999)
NU
2305-2310.
[3] K. Donner, M. Ollikainen, M. Ridanpää, H.-J. Christen, H.H. Goebel, M. de Visser,
MA
K. Pelin, C. Wallgren-Pettersson, Mutations in the beta-tropomyosin (TPM2) gene--a rare cause of nemaline myopathy., Neuromuscul Disord 12(2) (2002) 151-158.
ED
[4] N.G. Laing, S.D. Wilton, P.A. Akkari, S. Dorosz, K. Boundy, C. Kneebone, P.
PT
Blumbergs, S. White, H. Watkins, D.R. Love, A mutation in the alpha tropomyosin gene TPM3 associated with autosomal dominant nemaline myopathy., Nat Genet 9(1)
CE
(1995) 75-79.
[5] K.J. Nowak, D. Wattanasirichaigoon, H.H. Goebel, M. Wilce, K. Pelin, K. Donner,
AC
R.L. Jacob, C. Hübner, K. Oexle, J.R. Anderson, C.M. Verity, K.N. North, S.T. Iannaccone, C.R. Müller, P. Nurnberg, F. Muntoni, C. Sewry, I. Hughes, R. Sutphen, A.G. Lacson, K.J. Swoboda, J. Vigneron, C. Wallgren-Pettersson, A.H. Beggs, N.G. Laing, Mutations in the skeletal muscle alpha-actin gene in patients with actin myopathy and nemaline myopathy., Nat Genet 23(2) (1999) 208-212.
ACCEPTED MANUSCRIPT
[6] J.J. Johnston, R.I. Kelley, T.O. Crawford, D.H. Morton, R. Agarwala, T. Koch, A.A. Schäffer, C.A. Francomano, L.G. Biesecker, A novel nemaline myopathy in the Amish caused by a mutation in troponin T1., Am J Hum Genet 67(4) (2000) 814-821. [7] G. Ravenscroft, S. Miyatake, V.-L. Lehtokari, E.J. Todd, P. Vornanen, K.S. Yau,
T
Y.K. Hayashi, N. Miyake, Y. Tsurusaki, H. Doi, H. Saitsu, H. Osaka, S. Yamashita, T.
SC RI P
Ohya, Y. Sakamoto, E. Koshimizu, S. Imamura, M. Yamashita, K. Ogata, M. Shiina, R.J. Bryson-Richardson, R. Vaz, O. Ceyhan, C.A. Brownstein, L.C. Swanson, S. Monnot, N.B. Romero, H. Amthor, N. Kresoje, P. Sivadorai, C. Kiraly-Borri, G.
NU
Haliloglu, B. Talim, D. Orhan, G. Kale, A.K. Charles, V.A. Fabian, M.R. Davis, M. Lammens, C.A. Sewry, A. Manzur, F. Muntoni, N.F. Clarke, K.N. North, E. Bertini, Y.
MA
Nevo, E. Willichowski, I.E. Silberg, H. Topaloğlu, A.H. Beggs, R.J.N. Allcock, I. Nishino, C. Wallgren-Pettersson, N. Matsumoto, N.G. Laing, Mutations in KLHL40 are
ED
a frequent cause of severe autosomal-recessive nemaline myopathy., Am J Hum Genet 93(1) (2013) 6-18.
PT
[8] C.A.C. Ottenheijm, H. Granzier, New insights into the structural roles of nebulin in
CE
skeletal muscle., J Biomed Biotechnol 2010 (2010) 968139. [9] D. Sanoudou, A.H. Beggs, Clinical and genetic heterogeneity in nemaline myopathy
AC
– a disease of skeletal muscle thin filaments., Trends Mol Med 7(8) (2001) 362-368. [10] C. Wallgren-Pettersson, C.A. Sewry, K.J. Nowak, N.G. Laing, Nemaline myopathies., Semin Pediatr Neurol 18(4) (2011) 230-238. [11] L. Levesque, M.R. Del Bigio, S. Krawitz, A.A. Mhanni, A de novo dominant mutation in ACTA1 causing congenital nemaline myopathy associated with a milder phenotype: expanding the spectrum of dominant ACTA1 mutations., Neuromuscul Disord 23(3) (2013) 239-242.
ACCEPTED MANUSCRIPT
[12] C. Wallgren-Pettersson, A.H. Beggs, N.G. Laing, 51st ENMC International Workshop: Nemaline Myopathy. 13-15 June 1997, Naarden, The Netherlands., Neuromuscul. Disord., 1998, pp. 53-56. [13] W.L. van der Pol, J.F. Leijenaar, W.G.M. Spliet, S.W. Lavrijsen, N.J.G. Jansen,
T
K.P.J. Braun, M. Mulder, B. Timmers-Raaijmakers, K. Ratsma, D. Dooijes, M.M. van
SC RI P
Haelst, Nemaline myopathy caused byTNNT1 mutations in a Dutch pedigree., Mol Genet Genomic Med 2(2) (2014) 134-137.
[14] C. Lomen-Hoerth, M.L. Simmons, S.J. Dearmond, R.B. Layzer, Adult-onset
NU
nemaline myopathy: Another cause of dropped head., Muscle Nerve 22(8) (1999) 11461150.
MA
[15] M. Yuen, S.A. Sandaradura, J.J. Dowling, A.S. Kostyukova, N. Moroz, K.G. Quinlan, V.-L. Lehtokari, G. Ravenscroft, E.J. Todd, O. Ceyhan-Birsoy, D.S. Gokhin, J.
ED
Maluenda, M. Lek, F. Nolent, C.T. Pappas, S.M. Novak, A. D'Amico, E. Malfatti, B.P. Thomas, S.B. Gabriel, N. Gupta, M.J. Daly, B. Ilkovsk i, P.J. Houweling, A.E. Davidson,
PT
L.C. Swanson, C.A. Brownstein, V.A. Gupta, L. Medne, P. Shannon, N. Martin, D.P.
CE
Bick, A. Flisberg, E. Holmberg, P. Van den Bergh, P. Lapunzina, L.B. Waddell, D.D. Sloboda, E. Bertini, D. Chitayat, W.R. Telfer, A. Laquerrière, C.C. Gregorio, C.A.C.
AC
Ottenheijm, C.G. Bonnemann, K. Pelin, A.H. Beggs, Y.K. Hayashi, N.B. Romero, N.G. Laing, I. Nishino, C. Wallgren-Pettersson, J. Melki, V.M. Fowler, D.G. MacArthur, K.N. North, N.F. Clarke, Leiomodin-3 dysfunction results in thin filament disorganization and nemaline myopathy., J Clin Invest 124(11) (2014) 4693-4708. [16] C.W. Ockeloen, H.J. Gilhuis, R. Pfundt, E.J. Kamsteeg, P.B. Agrawal, A.H. Beggs, A. Dara Hama-Amin, A. Diekstra, N.V.A.M. Knoers, M. Lammens, N. van Alfen,
ACCEPTED MANUSCRIPT
Congenital myopathy caused by a novel missense mutation in the CFL2 gene., Neuromuscul Disord 22(7) (2012) 632-639. [17] N. Sambuughin, K.S. Yau, M. Olivé, R.M. Duff, M. Bayarsaikhan, S. Lu, L. Gonzalez-Mera, P. Sivadorai, K.J. Nowak, G. Ravenscroft, F.L. Mastaglia, K.N. North,
T
B. Ilkovski, H. Kremer, M. Lammens, B.G.M. van Engelen, V. Fabian, P. Lamont, M.R.
SC RI P
Davis, N.G. Laing, L.G. Goldfarb, Dominant mutations in KBTBD13, a member of the BTB/Kelch family, cause nemaline myopathy with cores., Am J Hum Genet 87(6) (2010) 842-847.
NU
[18] V.A. Gupta, G. Ravenscroft, R. Shaheen, E.J. Todd, L.C. Swanson, M. Shiina, K. Ogata, C. Hsu, N.F. Clarke, B.T. Darras, M.A. Farrar, A. Hashem, N.D. Manton, F.
MA
Muntoni, K.N. North, S.A. Sandaradura, I. Nishino, Y.K. Hayashi, C.A. Sewry, E.M. Thompson, K.S. Yau, C.A. Brownstein, T.W. Yu, R.J.N. Allcock, M.R. Davis, C.
ED
Wallgren-Pettersson, N. Matsumoto, F.S. Alkuraya, N.G. Laing, A.H. Beggs, Identification of KLHL41 Mutations Implicates BTB-Kelch-Mediated Ubiquitination as
PT
an Alternate Pathway to Myofibrillar Disruption in Nemaline Myopathy., Am J Hum
CE
Genet 93(6) (2013) 1108-1117.
[19] E. Malfatti, J. Böhm, E. Lacène, N. Romero, J. Laporte, A premature stop codon in
AC
MYO18B is associated with severe nemaline myopathy with cardiomyopathy, Neuromuscul Disord 25 S186. [20] S. Miyatake, S. Mitsuhashi, Y.K. Hayashi, E. Purevjav, A. Nishikawa, E. Koshimizu, M. Suzuki, K. Yatabe, Y. Tanaka, K. Ogata, S. Kuru, M. Shiina, Y. Tsurusaki, M. Nakashima, T. Mizuguchi, N. Miyake, H. Saitsu, K. Ogata, M. Kawai, J. Towbin, I. Nonaka, I. Nishino, N. Matsumoto, Biallelic Mutations in MYPN, Encoding
ACCEPTED MANUSCRIPT
Myopalladin, Are Associated with Childhood-Onset, Slowly Progressive Nemaline Myopathy., Am J Hum Genet 100(1) (2017) 169-178. [21] F.-O. Desmet, D. Hamroun, M. Lalande, G. Collod-Béroud, M. Claustres, C. Béroud, Human Splicing Finder: an online bioinformatics tool to predict splicing
T
signals., Nucleic Acids Res 37(9) (2009) e67.
SC RI P
[22] K. Kiiski, L. Laari, V.-L. Lehtokari, M. Lunkka-Hytönen, C. Angelini, R. Petty, P. Hackman, C. Wallgren-Pettersson, K. Pelin, Targeted array comparative genomic hybridization--a new diagnostic tool for the detection of large copy number variations in
NU
nemaline myopathy-causing genes., Neuromuscul Disord 23(1) (2013) 56-65. [23] Y.-E. Park, J.-H. Shin, B. Kang, C.-H. Lee, D.S. Kim, NEB-related core-rod
MA
myopathy with distinct clinical and pathological features., Muscle Nerve 53(3) (2016) 479-484.
ED
[24] S.Y. Kim, Y.-E. Park, H.-S. Kim, C.-H. Lee, D.H. Yang, D.S. Kim, Nemaline myopathy and non-fatal hypertrophic cardiomyopathy caused by a novel ACTA1
PT
E239K mutation., J. Neurol. Sci. 307(1-2) (2011) 171-173.
CE
[25] V.-L. Lehtokari, K. Kiiski, S.A. Sandaradura, J. Laporte, P. Repo, J.A. Frey, K. Donner, M. Marttila, C. Saunders, P.G. Barth, J.T. den Dunnen, A.H. Beggs, N.F.
AC
Clarke, K.N. North, N.G. Laing, N.B. Romero, T.L. Winder, K. Pelin, C. WallgrenPettersson, Mutation update: the spectra of nebulin variants and associated myopathies., Hum Mutat 35(12) (2014) 1418-1426. [26] N.B. Romero, S.A. Sandaradura, N.F. Clarke, Recent advances in nemaline myopathy., Curr Opin Neurol 26(5) (2013) 519-526.
ACCEPTED MANUSCRIPT
[27] M.C. Sharma, D. Jain, C. Sarkar, H.H. Goebel, Congenital myopathies – a comprehensive update of recent advancements., Acta Neurol Scand 119(5) (2009) 281292. [28] M.W. Lawlor, C.A. Ottenheijm, V.-L. Lehtokari, K. Cho, K. Pelin, C. Wallgren-
T
Pettersson, H. Granzier, A.H. Beggs, Novel mutations in NEB cause abnormal nebulin
SC RI P
expression and markedly impaired muscle force generation in severe nemaline myopathy., Skelet Muscle 1(1) (2011) 23.
[29] M. Scoto, T. Cullup, S. Cirak, S. Yau, A.Y. Manzur, L. Feng, T.S. Jacques, G.
NU
Anderson, S. Abbs, C. Sewry, H. Jungbluth, F. Muntoni, Nebulin (NEB) mutations in a childhood onset distal myopathy with rods and cores uncovered by next generation
MA
sequencing., Eur J Hum Genet 21(11) (2013) 1249-1252. [30] K. Donner, M. Sandbacka, V.-L. Lehtokari, C. Wallgren-Pettersson, K. Pelin,
ED
Complete genomic structure of the human nebulin gene and identification of alternatively spliced transcripts., Eur J Hum Genet 12(9) (2004) 744-751.
PT
[31] A. Rhoads, K.F. Au, PacBio Sequencing and Its Applications., Genomics
CE
Proteomics Bioinformatics 13(5) (2015) 278-289. [32] K. Kiiski, V.-L. Lehtokari, A. Löytynoja, L. Ahlstén, J. Laitila, C. Wallgren-
AC
Pettersson, K. Pelin, A recurrent copy number variation of the NEB triplicate region: only revealed by the targeted nemaline myopathy CGH array., Eur J Hum Genet 24(4) (2016) 574-580. [33] D. Piga, F. Magri, D. Ronchi, S. Corti, D. Cassandrini, E. Mercuri, G. Tasca, E. Bertini, F. Fattori, A. Toscano, S. Messina, I. Moroni, M. Mora, M. Moggio, I. Colombo, T. Giugliano, M. Pane, C. Fiorillo, A. D'Amico, C. Bruno, V. Nigro, N. Bresolin, G.P. Comi, New Mutations in NEB Gene Discovered by Targeted Next-
ACCEPTED MANUSCRIPT
Generation Sequencing in Nemaline Myopathy Italian Patients., J Mol Neurosci 59(3) (2016) 351-359. [34] B. Ilkovski, N. Mokbel, R.A. Lewis, K. Walker, K.J. Nowak, A. Domazetovska, N.G. Laing, V.M. Fowler, K.N. North, S.T. Cooper, Disease severity and thin filament
T
regulation in M9R TPM3 nemaline myopathy., J. Neuropathol. Exp. Neurol. 67(9)
SC RI P
(2008) 867-877.
[35] C. Wallgren-Pettersson, K. Pelin, K.J. Nowak, F. Muntoni, N.B. Romero, H.H. Goebel, K.N. North, A.H. Beggs, N.G. Laing, E.I.C.O.N. Myopathy, Genotype-
NU
phenotype correlations in nemaline myopathy caused by mutations in the genes for nebulin and skeletal muscle alpha-actin., Neuromuscul Disord 14(8-9) (2004) 461-470.
MA
[36] V. Straub, P.G. Carlier, E. Mercuri, TREAT-NMD workshop: pattern recognition in genetic muscle diseases using muscle MRI: 25-26 February 2011, Rome, Italy.,
ED
Neuromuscul Disord 22 Suppl 2 (2012) S42-53. [37] H. Jungbluth, C.A. Sewry, S. Counsell, J. Allsop, A. Chattopadhyay, E. Mercuri, K.
PT
North, N. Laing, G. Bydder, K. Pelin, C. Wallgren-Pettersson, F. Muntoni, Magnetic
CE
resonance imaging of muscle in nemaline myopathy., Neuromuscul Disord 14(12) (2004) 779-784.
AC
[38] M.M.R. Kathryn N North, Nemaline Myopathy. https://www.ncbi.nlm.nih.gov/books/NBK1288/, 2012 (accessed 11 June 2015). [39] E. Malfatti, V.-L. Lehtokari, J. Böhm, J.M. De Winter, U. Schäffer, B. Estournet, S. Quijano-Roy, S. Monges, F. Lubieniecki, R. Bellance, M.T. Viou, A. Madelaine, B. Wu, A.L. Taratuto, B. Eymard, K. Pelin, M. Fardeau, C.A.C. Ottenheijm, C. WallgrenPettersson, J. Laporte, N.B. Romero, Muscle histopathology in nebulin-related nemaline
ACCEPTED MANUSCRIPT
myopathy: ultrastrastructural findings correlated to disease severity and genotype., Acta Neuropathol Commun 2 (2014) 44. [40] M.M. Ryan, B. Ilkovski, C.D. Strickland, C. Schnell, D. Sanoudou, C. Midgett, R. Houston, D. Muirhead, X. Dennett, L.K. Shield, U. De Girolami, S.T. Iannaccone, N.G.
T
Laing, K.N. North, A.H. Beggs, Clinical course correlates poorly with muscle
SC RI P
pathology in nemaline myopathy., Neurology 60(4) (2003) 665-673.
[41] J.-M. Hong, S.-M. Kim, I.-N. Sunwoo, S.-H. Kim, T.-S. Kim, D.-S. Shim, Y.-C. Choi, Clinical heterogeneity in Korean patients with nemaline myopathy., Yonsei Med J
NU
51(2) (2010) 225-230.
[42] V.-L. Lehtokari, K. Pelin, M. Sandbacka, S. Ranta, K. Donner, F. Muntoni, C.
MA
Sewry, C. Angelini, K. Bushby, P. Van den Bergh, S. Iannaccone, N.G. Laing, C. Wallgren-Pettersson, Identification of 45 novel mutations in the nebulin gene associated
ED
with autosomal recessive nemaline myopathy., Hum. Mutat. 27(9) (2006) 946-956. [43] C. Wallgren-Pettersson, V.-L. Lehtokari, H. Kalimo, A. Paetau, E. Nuutinen, P.
PT
Hackman, C. Sewry, K. Pelin, B. Udd, Distal myopathy caused by homozygous
CE
missense mutations in the nebulin gene., Brain 130(6) (2007) 1465-1476. [44] V.-L. Lehtokari, K. Pelin, A. Herczegfalvi, V. Karcagi, J. Pouget, J. Franques, J.F.
AC
Pellissier, D. Figarella-Branger, M. von der Hagen, A. Huebner, B. Schoser, H. Lochmüller, C. Wallgren-Pettersson, Nemaline myopathy caused by mutations in the nebulin gene may present as a distal myopathy., Neuromuscul Disord 21(8) (2011) 556562. [45] M. Marttila, M. Hanif, E. Lemola, K.J. Nowak, J. Laitila, M. Grönholm, C. Wallgren-Pettersson, K. Pelin, Nebulin interactions with actin and tropomyosin are altered by disease-causing mutations., Skelet Muscle 4 (2014) 15.
ACCEPTED MANUSCRIPT
Figure 1. Schematic diagram depicting the structural organization of the protein players in nemaline myopathy. A, A-band; I, I-band; M, M-line; Z, Z-disc; KLHL, Kelch-like protein. Figure 2. Flow diagram of the sequence in genetic investigation.
T
Figure 3. Magnetic resonance imaging (A) and computed tomography (B, C, and D)
SC RI P
findings of distal legs. In patient 15, the bilateral tibialis anterior, gastrocnemius medialis, and left soleus muscles show high T2 signals (A, arrows). In computed tomography, low-density lesions are observed in the right soleus and gastrocnemius
NU
muscles in patient 8 (B, arrows), as well as in the bilateral gastrocnemius and soleus muscles in patient 10 (C, arrows). In patient 9, a patch-like distribution of abnormal
MA
intensities is evident (D). (E) Normal computed tomography of lower legs. Figure 4. Distribution of nemaline rods in muscle fiber observed under a light
ED
microscope. In patients 3 (A), 7 (B), 13 (C), and 14 (D), the nemaline rods are scattered across the muscle fiber. On the other hand, in patients 5 (E), 6 (F), 9(G), and 12 (H), the
PT
nemaline rods are located mainly at the subsarcolemmal areas. All slides were stained
CE
with modified Gomori trichrome stain. Bar: 50 µm (A–H). Figure 5. Electron microscopy findings of nemaline myopathies. In patient 8, electron-
AC
dense nemaline rods (arrow) are clearly observed along with the Z-line disruptions (arrowhead) (A). In patient 12, nemaline rods are accumulated mainly in the subsarcolemmal areas (B). In patient 2, numerous nemaline rods are scattered in atrophic muscle fibers, which were not clearly observed under the light microscope (C). In patient 7, only Z-line disruptions are observed. (D). Bars indicate 5 µm in (A) and (B), 2 µm in (C), and 1 µm in (D). All sections were stained with uranyl acetate and lead citrate.
MA
NU
SC RI P
T
ACCEPTED MANUSCRIPT
AC
CE
PT
ED
Fig. 1
MA
NU
SC RI P
T
ACCEPTED MANUSCRIPT
AC
CE
PT
ED
Fig. 2
AC
Fig. 3
CE
PT
ED
MA
NU
SC RI P
T
ACCEPTED MANUSCRIPT
SC RI P
T
ACCEPTED MANUSCRIPT
AC
CE
PT
ED
MA
NU
Fig. 4
NU
SC RI P
T
ACCEPTED MANUSCRIPT
AC
CE
PT
ED
MA
Fig. 5
ACCEPTED MANUSCRIPT
Table 1. Clinical and laboratory data of fifteen patients with nemaline myopathy Pat ient nu 1 2 3 4 5 6 7 8 9 10 11 12 mb er
Upp er extre mity , Prox imal Low er extre mity , Prox imal Ankl e, Dors iflex ion Ankl e, Plan tar flexi on Resp irato
Typi cal
Typ ical
Typ ical
Chi ldh ood ons et
Chil dhoo d onset
Childho od onset
Chil dho od onse t
3 Mo /F
1 Yr /F
5 Yr / M
3 Mo /F
6 Mo /M
6 Yr / F
20 Yr / M
16 Yr /M
15 Yr / M
9 Yr / M
9 Yr /F
At birth
At bir th
At birt h
At birt h
At birth
1 Yr
10 Mo
5 Yr
3 Yr
5 Yr
Poor sucki ng
Hy po to nia
Poo r suc kin g
Poo r suc kin g
Wea k cryin g
Mot or dev elo pm ent dela y
Mo tor dev elo pm ent del ay
Ac hill es ten don con trac ture
Slow runn er after 3 years old
None
M ot he r
No ne
No ne
None
N/ A
No ne
No ne
2
3+
5
N/ A
3
2
4
4
Chil dhoo d onset
14
15
Child hood onset
Child hood onset
Chi ldh ood ons et
T
Ty pic al
24 Yr /M
20 Yr /M
43 Yr / M
6 Yr
9 Yr
9 Yr
9Yr
10 Yr
Distal lower extremit y weaknes s
Toein gait
Dista l lowe r extre mity weak ness
Unsta ble gait and slow runner
Slow runner
Foo t dro p for 4 yea rs
Non e
N/A
N/A
None
Broth er
Broth er
Bro ther
NU
SC RI P
25 Yr / M
MA
ED
Fam ily histo ry Mus cle wea knes s
Typ ical
4
2
N/ A
4
4
N/A
5
4
4+
5
PT
Clini cal featu re at onse t
Int er me dia te
CE
Age / Gen der Sym pto m onse t age
Inter medi ate
AC
Sub grou p
13
N/ A
2
4
4
5
4
4
N/A
5
5
5
3
2
3+
4
N/ A
2
5
4+
1-2
4
2
N/A
4+
2
1
2
2
3+
4
N/ A
2
3
4+
5
4
4+
N/A
4+
5
4
2
Posit ive
M ec ha
Ne gati ve
Pne um oni
N/A
Neg ativ e
Ort hop nea
Ne gati ve
Nega tive
Negativ e
Neg ativ e
Nega tive
Negati ve
Negati ve
Neg ativ e
ACCEPTED MANUSCRIPT
ry invo lvem ent
a
at 15 Yr
15
25
7
119
N/ A
5,3 70
151
24
N/A
N SR
N/ A
N/ A
NSR
NS R
N/ A
N/ A
NSR
N/ A
N/A
My opa thic
N/A
scat tere d
AC TA 1
142
No rm al
N/ A
N/ A
N/A
N/ A
Elec trom yogr aphy
N/A
M yo pat hic
N/ A
My opa thic
Nor mal
My opa thic
My opa thic
Loca tion of rods in LM
scatt ered
No vis ibl e in L M
scat tere d
sub sar col em ma
subsa rcole mma
Sca tter ed, sub sarc ole mm a
Gen e
NEB
TP M 3
NE B
No ne
NEB
NE B
†‡
c.3 2T >A †
‡
ex16 1;c.2 3245 C>T *
AC
ex84/9 2/100; c.1269 8A>T† p.R28 09X p.L44 23W p.D42 33V
p. M1 1K
ED
PT
CE
ex61;c .8425 C>T* ex87/9 5/103; c.1326 8T>G
p.R7 749 X
ex29;c .2875_ 2877d elTG T*
p.C95 9del
ex13 9;c.2 0928 delG
c.71 5G> A†
*
p.L6 977 Nf s* 5
SC RI P
N/A
Pred icted cons eque nce
N/A
118
118
103
NSR
NS R
NSR
N/A
N/A
N/ A
Trivial TR
N/A
N/A
N/A
N/A
N/ A
N/A
N/A
Myo pathi c
Myop athic
Myop athic
My opa thic
scat tere d
Scatt ered, subs arcol emm a
Scattere d, subsarco lemma
N/A
subs arcol emm a
scatter ed
scatter ed
Sca tter ed
NE B
NEB
NEB
NEB
NEB
NEB
NEB
NE B
ex80 ;c.11 930 G> A *‡
ex82/ 90/98; c.124 78A> T†‡ int18; c.167 4+1G >T*
ex39;c.46 17_4629d elTTATA AAGCAG AT insAAA* ex175;c.2 4684G>A*
ex167;c .23908_ 23911d elAGA G*
ex167;c .23908_ 23911d elAGA G*
MA
Card iac ultra sono grap hy
Hy pert rop hic car dio my opa thy
Nucl eotid e chan ge
47
T
36
NU
Seru m CK, U/L (nor mal; 0145) Elec troca rdio grap hy
nic al ve nti lat io n
p.E2 39K
p.W 3977 X
p.I416 0F
p.H1539Q fs*12 p.S8228S
int14 4;c.2 1522 +3A> G*
ex82/ 90/98; c.1239 7delA ‡
ex88/ 96/10 4;c.13 389G >A ‡
p.M4 133X p.W4 463X
ex33 ;c.33 87de lC* ex17 5;c.2 4684 G>A *
p.R797 0Sfs*48
p.R797 0Sfs*48
p.Y1 130 Mfs *53 p.S8 228 S
Abbreviations; Intermediate, intermediate congenital form; Typical, typical congenital form; Childhood, mild nemaline myopathy with childhood onset; CK, creatine kinase; N/A, not applicable; LM, light microscope; Mo, months; NSR, normal sinus rhythm; TR, tricuspid valve regurgitation; Yr, years Novel mutations are bold. Variant was identified by whole exome sequencing* or Sanger sequencing†. T he exon 82-89, 90-97, and 98-105 are identical. Therefore, this variant may be in any of these locations‡ . NEB, NG_009382, NM_001271208; TPM3, NG_008621, NM_152263; ACTA1, NG_006672, NM_001100
ACCEPTED MANUSCRIPT
Frequency
Increased fiber size variation
13/15 (87%)
Type 1 fiber predominance
12/15 (80%)
Endomysial fibrosis
8/15 (53%)
Type 1 fiber atrophy
2/15 (13%)
Increased fibers with internal nuclei
2/15 (13%)
Core lesion
2/15 (13%)
AC
CE
PT
ED
MA
NU
SC RI P
Abnormal pathologic findings
T
Table 2. Summary of muscle pathology findings
ACCEPTED MANUSCRIPT
AC
CE
PT
ED
MA
NU
SC RI P
T
Highlights Whole exome sequencing is useful for genetic diagnosis of nemaline myopathy. NEB is the most common causative gene among Korean patients with nemaline myopathy. Distal leg weakness is frequent in NEB associated childhood onset nemaline myopathy.