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. 2022 May 16;15:113. doi: 10.1186/s12920-022-01269-x

Identification of a novel CNV at the EYA4 gene in a Chinese family with autosomal dominant nonsyndromic hearing loss

Weixun Zhang 1,2,3,4,5,#, Jing Song 1,2,3,4,#, Busheng Tong 6, Mengye Ma 1,2,3,4, Luo Guo 1,2,3, Yasheng Yuan 1,2,3,4,5,7,, Juanmei Yang 1,2,3,4,7,
PMCID: PMC9109401  PMID: 35578334

Abstract

Background

Hereditary hearing loss is a heterogeneous class of disorders that exhibits various patterns of inheritance and involves many genes. Variants in the EYA4 gene in DFNA10 are known to lead to postlingual, progressive, autosomal dominant nonsyndromic hereditary hearing loss.

Patients and methods

We collected a four-generation Chinese family with autosomal-dominant nonsyndromic hearing loss (ADNSHL). We applied targeted next-generation sequencing (TNGS) in three patients of this pedigree and whole-genome sequencing (WGS) in the proband. The intrafamilial cosegregation of the variant and the deafness phenotype were confirmed by PCR, gap-PCR and Sanger sequencing.

Results

A novel CNV deletion at 6q23 in exons 8–11 of the EYA4 gene with a 10 bp insertion was identified by TNGS and WGS and segregated with the ADNSHL phenotypes.

Conclusions

Our results expanded the variant spectrum and genotype‒phenotype correlation of the EYA4 gene and autosomal dominant nonsyndromic hereditary hearing loss in Chinese Han individuals. WGS is an accurate and effective method for verifying the genomic features of CNVs.

Supplementary Information

The online version contains supplementary material available at 10.1186/s12920-022-01269-x.

Keywords: EYA4, DFNA10, Copy number variation (CNV), Deafness, Whole genome sequencing (WGS)

Introduction

Hearing loss is the most common sensory deficit in modern society and affects approximately 466 million people worldwide, 34 million of whom are children [1, 2]. Hereditary hearing loss patterns vary among autosomal dominant, autosomal recessive, X-linked, and mitochondrial patterns of inheritance. Unlike syndromic hearing losses, non-syndromic hearing loss are not associated with other clinical abnormalities [3]. In 75–80% of cases, NSHL is inherited autosomally recessively, while 20% are inherited autosomally dominantly. X-linked (2–5%) or mitochondrial patterns of inheritance (1%) are rare in NSHL [3, 4]. The main characteristics of autosomal dominant hearing loss are high genetic and clinical heterogeneity and a delayed onset (postlingual), which are easily overlooked during hearing screening of newborns. At present, 51 different genes and 67 different loci have been linked to autosomal-dominant NSHL [5].

The EYA4 gene, which is located on chromosome 6q22.3-q23.2, was first identified as a causal gene of DFNA10 in a large American family in 1996 [6]. The EYA4 gene encodes eye absent 4 protein and is considered necessary for the proper development of multiple human organs, including the eye, inner ear, and heart. The EYA4 protein comprises two functional domains that contain a 271-amino-acid highly conserved C-terminal EYA domain (eyaHR) and an N-terminal variable region with a proline-serine-threonine (PST)-rich transactivation domain (eyaVR) [7]. By mediating interactions with the sine oculis family of proteins (Six1–Six6), mammalian EYA proteins function as transcriptional coactivators [8].

Researchers from different countries have found novel variants of the EYA4 gene and deletions of the EYA4 allele in different families with hearing loss based on sequencing analysis [914]. Late-onset, progressive, sensorineural hearing loss and age of onset from 6 to 50 years are the common characteristics among the tested families. Mid-frequency hearing is affected first, and all frequencies gradually become affected with increasing age. The degree of hearing loss also ranges from mild to moderate or severe with spontaneous evolution [15].

In recent years, next-generation sequencing (NGS) technology, including both targeted and whole-genome sequencing (WGS), has been considered an efficient and swift method to detect potential variants [16, 17]. This method provides a guiding role in the diagnosis and treatment of hereditary hearing loss [18]. Copy number variations (CNVs) are genomic variants within species that reflect differences in copy numbers, including deletions, duplications, and amplifications of DNA sequences. By using cytogenomics techniques such as comparative genomic hybridization (CGH), SNP arrays, WES and WGS, many novel CNVs associated with NSHL phenotypes have been identified [1923]. With the development of diagnostic WGS, the accessibility, robustness and accuracy of CNVs throughout the genome have dramatically improved. Compared to genomic microarrays, the investigation of genomic features such as copy number, content and positional information has become more precise through the WGS method and algorithm [24, 25].

In the present study, we present a four-generation Chinese pedigree with autosomal dominant nonsyndromic hearing loss. A novel CNV deletion at 6q23 was identified in the affected individuals by targeted next-generation sequencing (TNGS) and WGS, and this information sheds new light on the pathogenic mechanism of EYA4 variants.

Patients, materials and methods

Family and clinical evaluation.

A Chinese family (FY-140) classified as of Han origin presented with late-onset, progressive hearing loss. Approval for the study was obtained from the Ethics Committee of the Eye & ENT Hospital, Fudan University for Human Studies. Written informed consent was obtained from the participants or the parents of minors. The assessment of all the individuals was based on audiological methods, including pure-tone audiometry, acoustic impedance, auditory brainstem response (ABR), distortion product of otoacoustic emission (DPOAE) and otological examination. Clinical information, such as age of onset, degree of hearing loss, progression of hearing loss, noise exposure and history of using aminoglycosides, was collected from family members if available. Information on deceased family members was obtained from relatives. The proband (II-2) was subjected to a high-resolution CT scan of the temporal bone. All the individuals accepted electrocardiography for the reason that some references indicated that EYA4 gene variants may cause heart disease in patients.

Targeted genomic capturing and next-generation sequencing

Genomic DNA was isolated using the TIANamp Blood DNA Midi Kit (TIANGEN Biotech, Beijing China) and fragmented to 150 bp using an ultrasonoscope (Covaris S220, Massachusetts, USA). End repair, adenylation and adapter ligation were performed for library preparation using a standard library construction kit (MyGenostics Inc., Beijing, China). Targeted DNA fragments were captured by a sequence capture array (MyGenostics Inc., Beijing, China). High-throughput sequencing and processing and bioinformatic data analysis were performed using the DNBSEQ-T7 sequencing platform (MGI Tech Co, Shenzhen China). The raw sequence reads were filtered using the BWA MultiVision software package and then aligned to GRCh38/hg38 (University of California Santa Cruz version). SNPs and indels were identified using the GATK Indel Genotyper and ANNOVA software. A CNV analysis was performed using the log2 ratio of the read depth on each exon.

Whole-genome sequencing

The genomic DNA samples were fragmented by sonication to a size of 300–500 bp. Sequence analysis was performed using the TruSeq Nano DNAHT Sample Prep Kit (Illumina Inc., Massachusetts, USA) following the manufacturer’s instructions. The total effective data yield of the sample was approximately 430 million reads, and the data showed a coverage of > 99.62% at 20X. After the raw sequence reads were mapped to the human genome reference sequence (USSC) (GRCh38/hg38), SpeedSeq software was used. SNPs, indels, CNVs and SVs were captured using GATK HaplotypeCaller, ANNOVAR and SpeedSeq software.

PCR, gap-PCR and Sanger sequencing

PCR, gap-PCR and Sanger sequencing were performed to analyze the cosegregation of variants with NSHL in this family. All primers were designed with Primer3 software (Applied Biosystems). Gap-PCR was designed to detect certain CNVs of the EYA4 gene. The following seven PCR primers were used for analysis of the suspected variants: EYA4 gene (Forward1, 5′-ATGAAGCCAAACACATATATTTCAA-3′; Forward2, 5′-TAGTGGCTACAGCCCCAGATCA-3′; and Reverse, 5′-AAACATTTTGGATGACGTTCCAT-3′) and CDH23 gene (Forward1, 5′-CACCCAGGTGGTGATCCAAGT-3′; Reverse1, 5′-GGAGCAGGAGAGTAGCTCTGGTTG-3′; Forward2, 5′'-CAGTACCAGCTGCTGACAGTGC-3′; and Reverse2, AGCAGGGCATATGTGGGTCATCT-3′). The cycling program was as follows: 95 °C for 2 min; 11 cycles of 94 °C for 20 s, 64–0.5 °C per cycle for 40 s, and 72 °C for 1 min; 24 cycles of 94 °C for 20 s, 58 °C for 30 s, and 72 °C for 1 min; 72 °C for 2 min; and 4 °C for the rest of the time. The standard protocols for Sanger sequencing were performed using an ABI 3730XL Dx Genetic AnalyserAnalyzer (Applied Biosystems) and PolyPhred software to confirm the detected variants in patients (II-2, II-3, II-6 and III-1) and healthy family members (I-2, III-2, III-3, III-5, IV-1 and IV-2).

Results

Clinical evaluation

The pedigree of the family includes 15 members (eight men and seven women) over four generations (Fig. 1A). Five individuals were diagnosed with NSHL based on their medical history and audiological function examination results. The self-reported age of onset of hearing impairment ranged from 26 to 43 years. Assessments of the four affected living members showed mild to severe bilaterally symmetric NSHL across all frequencies, and the disease affected both sexes (Table 1). In addition to hearing loss, the patients had no other clinical symptoms or signs. No patients complained of vestibular symptoms. The temporal bone scans and cardiac examinations of the proband yielded normal results. The initial hearing loss showed an audiogram pattern called a “cookie bite”, which was usually mild and only affected mid-frequencies. Progressive hearing loss expanded to other frequencies at later stages (Fig. 1B). Other audiometric tests' results in affected individuals including ABR, DPOAE, acoustic impedance and otological examination were also consistent with the diagnosis of NSHL.

Fig. 1.

Fig. 1

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a Pedigree diagram of the four generations of FY-140 with ADNSHL. b Audiogram curves of the 4 affected members of FY140. Right ear tonal audiometric curves showing that the audiogram of III-1 exhibits a ‘cookie-bite’ pattern

Table 1.

Summary of the phenotypic information of the family members

Subjects Gender Age (years) Pure-tone average (dBHL) Audiogram shape Degree of hearing loss
At testing At onset Left Right
I-1 Male 76 82 90 Severe
I-2 Female 72 Normal Normal Normal hearing
II-1 Male 62 Normal Normal Normal hearing
II-2 Female 57 42 77 98 Flat Moderate–severe
II-3 Male 54 43 83 94 Flat Severe
II-4 Female 51 Normal Normal Normal hearing
II-5 Male 53 Normal Normal Normal hearing
II-6 Female 44 37 75 71.25 Flat–sloping Moderate–severe
III-1 Male 32 26 55 45 Cookie–bite Moderate
III-2 Male 30 Normal Normal Normal hearing
III-3 Male 27 Normal Normal Normal hearing
III-4 Female 26 Normal Normal Normal hearing
III-5 Female 26 Normal Normal Normal hearing
IV-1 Male 4 Normal Normal Normal hearing
IV-2 Female 2 Normal Normal Normal hearing
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Identification of novel CNV by TNGS

Patients II-2, III-1, and III-5 were subjected to targeted NGS of 147 deafness-related genes, and 8 SNPs and 1 CNV were detected. A novel CNV in exons 8–11 of the EYA4 gene and two previously identified variants (c.7630T > G, p. Leu2544Val and c.8257G > A p. Ala2753Thr) in the CDH23 gene were found in all three patients (Fig. 2A, B). The intrafamilial cosegregation of the variants and the hearing loss phenotype were confirmed by long-range PCR and Sanger sequencing in all family members.

Fig. 2.

Fig. 2

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Identification of a novel copy number variation in the EYA4 gene in a Chinese family. a Schematic diagram showing the position of the EYA4 gene deletion on chromosome 6. The red bar indicates the alignment position of the deletion. b Copy number of each exon calculated from the fluorescence peak ratios identified from the CNV analysis. c Scheme of the normal and inverted alleles. d Gap-PCR product of the distal breakpoint junction showing segregation with the phenotype in the family. e Sanger sequencing of the inverted allele by EYA4_Ex7_F and EYA4_In11_R covering the two breakpoints and a 10-bp insertion

We found that both variants of the CDH23 gene (NM_022124), c.7630T > G (p. Leu2544Val) in exon 52 and c.8257G > A (p. Ala2753Thr) in exon 54, were been carried by four patients (II-2, II-3, II-6 and III-1) and five healthy family members (I-2, III-2, III-3, III-5, IV-1 and IV-2) by Sanger sequencing. These four patients and five healthy family members are all heterozygous for both variants of the CDH23 gene. According to the pedigree diagram, the inheritance pattern of the hearing loss in this family was dominant. Both variants of the CDH23 gene did not co-segregate with the phenotype (BS4-ACMG).The genotype for each variant in the pedigree and the Sanger sequencing results of these family members are described in the supplemental material (Additional file 1: Fig. S1, Additional file 2: Fig. S2, Additional file 3: Fig. S3). We believe they are in cis-mutation and not in compound heterozygosity in each subject. Although they have been reported in a previous paper that detected both variants in a deafness patient from China, these variants did not appear in the general populations databases [26]. The minor allele frequency (MAF) of p. Leu2544Val variant is 0.000051 (East Asian) in GnomAD, while the p. Ala2753Thr variant is novel (PM2-ACMG). These variants were predicted as benign by silico pathogenicity prediction tools REVEL, MutationTaster, SIFT and Polyphen 2 (BP4-ACMG). According to ACMG standards and guidelines, both variants in the CDH23 gene are classified as PM2, BP4 and BS4, and the criteria for both alleles will be of uncertain significance (Table 2). In general, CDH23 gene mutations cause autosomal recessive non-syndromic hearing loss [4, 27]. Based on the ACMG classification and intrafamilial cosegregation analysis of these variants, we inferred that the c.7630T > G and c.8257G > A variants in the CDH23 gene may not be the cause of the disease in this family. In contrast, a CNV in the EYA4 gene was found only in the patients, and none of the healthy family members were carriers of this deletion (Fig. 2C). Therefore, this variant in the EYA4 gene could be considered the cause of the disease. Because patient I-1 died, we were unable to collect a sample of his DNA. We inferred that patients II-2, II-3 and II-6 inherited the heterozygotic variant from their father and that patient III-1 inherited the variant from patient II-2.

Table 2.

Identified CDH23 variant and in silico molecular genetic analysis

Gene name Transcript accession number cDNA change Protein change Position (GRCh38/hg18) REVEL MutationTaster SIFT Polyphen 2 ACMG Classification
CDH23 NM_0221 24;exon52 c.7630T > G p.Leu2544Val chr10:71803045 Benign (0.025) Disease causing (0.999999989) Benign (0.393) Benign (0.002) Uncertain Significance (PM2 + BP4 + BS4)
CDH23 NM_0221 24;exon56 c.8257G > A p.Ala2753Thr chr10:71807355 Benign (0.363) Disease causing (0.999999778) Benign (0.01) Benign (0.032) Uncertain Significance (PM2 + BP4 + BS4)
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Verification of CNV by WGS

We performed WGS using genomic DNA from patient III-1 to further identify potential variants. We identified on average 3,585,580 SNPs and 732,397 indels in coding regions or introns. Then, Single-nucleotide variants (SNVs) and InDel from WGS data were filtered as follows: (1) variants with MAF below 0.01 in 1000Genomes, ExAC03 Asian population and gnomAD Asian population (2) coding/splicing variants (3) variants that are predicted to be likely pathogenic/pathogenic by any of the following software such as SIFT, POLYPhen V2, MutationTaster, Cadd, Dann, and dbscSNV, were considered as likely causal variants. CNV analysis was performed using the log2-ratio of read depth on each exon. Priority was given to variants found in deafness genes (annotated as deafness genes in one or more of the following databases: OMIM, HPO, HGMD, InterVar, HPO, MGI, ClinVar, ISCA and MalaCards). There were 64 variants predicted as candidates, including 47 SNVs, 3 indels, and 2 CNVs. With WGS, TNGS, Sanger sequencing, and cosegregation analysis, we identified a novel CNV that might cause disease.

The complex genomic rearrangement in the dataset encompassed a 17.4-kb deletion spanning exons 8 to 11 and a 10-base insertion (chr6: 133461414 insTTTGAATTTT). As shown in Fig. 2, the distal breakpoint mapped to chr6: 133461414 (GRCh38/hg38), and the proximal breakpoint mapped to chr6: 133478832 (GRCh38/hg38) (Fig. 2C). To validate the identified CNV, gap-PCR of the region spanning the breakpoint was performed. The primers Forward1 and Reverse amplify a gap-PCR product specific for the variant allele, whereas the primers Forward2 and Reverse amplify a product from the normal EYA4 gene. The 500-bp PCR product was obtained from all 4 affected individuals (II-2, II-3, II-6 and III-1) in the family but not from the unaffected family members (I-2, III-2, III-3, III-5, IV-1 and IV-2). The normal EYA4 gene product was found in all family members (Fig. 2D). The generated PCR products were subjected to Sanger sequencing, and a sequence analysis of the resultant amplicons confirmed the junction of the two breakpoints through the 10-bp insertion identified by WGS (Fig. 2E). This deletion has been submitted to LOVD under accession ID 00361730.

Discussion

CNVs are a common cause of hereditary hearing loss and are thought to play a role in nearly 20% of non-syndromic HL diagnoses [19]. In this study, we performed a comprehensive genetic analysis that included TNGS, WGS, gap-PCR and Sanger sequencing in a four-generation Chinese Han family with autosomal dominant NSHL. All the affected individuals in the family exhibited sensorineural deafness, which primarily affected low and mid-frequencies and had onset ages in the range of 26 to 43 years.

We identified a novel CNV deletion in exons 8–11 of the EYA4 gene with a 10 bp insertion. First, this variant cosegregated with NSHL symptoms in patients and was not detected in normal family members. Then, this CNV is predicted to affect the eyaHR domain. By interacting with members of the SIX and DACH protein families in a conserved network, the highly conserved C-terminal region of EYA4 (eyaHR) regulates embryonic development and follow-up functions after development of the mature organ of Corti. It regulates Na+/K+-ATPases and the development of mechanosensory cells of the inner ear [12]. Finally, we attempted to construct a three-dimensional structure of the CNV using the SWISS-MODEL software but failed because the structure was severely affected. These findings may also suggest that this novel CNV deletion is pathogenic in auditory function.

The hearing loss phenotype in the present family is similar to that reported for patients carrying EYA4 variants, i.e., late-onset, postlingual, progressive, and bilateral HL. In previous reports, flat-type hearing loss was observed in patients with truncating EYA4 variants. At onset, hearing impairment was usually mild and detected at mid-frequencies, resulting in an audiometric profile commonly referred to as a “cookie-bite” pattern. During its progression, hearing loss began to involve other frequencies. The progression rate of hearing loss caused by EYA4 was approximately 5.75 dB/year (95% CI 4.50–7.00 dB/year), which is relatively severe compared to POU4F3 and MYO6 gene mutation in ADNSHL patients [28, 29].

To date, variants in the EYA4 gene have been associated with HL in more than 50 ethnic groups worldwide. It was believed that EYA4 variants led to syndromic and non-syndromic NSHL, but EYA4 is not a frequently mutated gene in ADNSHL compared with other reported genes. The characteristics of all known EYA4 variants are summarized in Table 3. According to these variants, the severity of hearing loss was not significantly related to the types or locations of variants.

Table 3.

Summary of all known EYA4 variants and their hearing loss phenotypes

Variant type Nucleotide Change Exon/Intron Amino Acid Change Origin Age at HL on set HL degree Audiogram profile References
Splicing c.84-2A > G Intron 3

Chinese

Indian

 N/A N/A N/A

Chen et al. 2016 [36]

Panigrahi et al. [37]
Missense c.152C > T Exon 4 p.Ser51Phe America N/A N/A N/A Sloan-Heggen et al. [38]
Nonsense c.160G > T Exon 4 p.Glu54* Spanish 42 years Mild MF/flat Morín et al. [13]
Frameshift c.222_223del Exon 5 p.Val75Phefs*32 Japanese 61 years Mild to moderate HF/LF Shinagawa et al. [9]
Frameshift c.464delC Exon 8 p.Pro155Glnfs*43 Swedish Dutch N.A Childhood

N.A

Moderate

N.A

MF/HF

Neveling et al. [39]

Van Beelen et al. [40]
Frameshift c.498del Exon 8 p.Thr167Leufs*31 Japanese 13 years Mild LF Shinagawa et al. [9]
Missense c.511G > C Exon 8 p.Gly171Arg Chinese 6–50 years Mild to severe HF/flat Liu [15]
Nonsense c.517C > T Exon 8 p.Gln173* Japanese 48 years Moderate Flat Shinagawa et al. [9]
Missense c.543C > G Exon 8 p.Tyr181Ter Chinese Second to the fourth decade Severe to profound Flat Mi et al. [32]
Frameshift c.579_580insTACC Exon 8 p.Asp194Tyrfs*52 Swedish 4–40 years Mild to profound N/A Frykholm et al. [41]
c.580 + 1G > A Intron 8 Japanese 45 years Moderate Flat Shinagawa et al. [9]
Frameshift c.614dupA Exon 9 p.Glu205Argfs*40 Chinese 20–40 years Moderate to profound HF/flat Huang et al. [42]
Frameshift c.781del Exon 10 p.Thr261Argfs*34 Spanish 26–44 years Mild to moderate Gently downsloping Morín et al. [13]
Missense c.804G > C Exon 10 p.Gln268His Slovak 10–40 years Moderate Gently downsloping Varga et al. [43]
Nonsense c.863C > A Exon 11 p.Ser288* Korean Korean

N.A

N.A

Moderate

Moderate to severe

Reverse U-shaped

Flat

Baek et al. [44]

Kim et al. [10]
Missense c.866C > T Exon 11 p.Thr289Met American N.A N.A N.A Miszalski-Jamka et al. [45]
Frameshift c.910del Exon 11 p.Ser305Leufs*15 Japanese 30 years Severe Flat Shinagawa et al. [9]
Missense c. 978C > G Exon 12 p.Phe326Leu Korean N.A Moderate Down sloping Choi et al. [46]
Nonsense c.988C > T Exon 12 p.Gln330* Japanese 16 years Moderate Flat Shinagawa et al. [9]
Frameshift c.1026_1027dupAA Exon 12 p.Thr343Lysfs*62 American N.A Moderate to profound Flat/Gently sloping Wayne et al. [12]
Frameshift c.1048_1049dupAA Exon 12 p.Arg352Profs*53 American N.A Moderate to severe MF/HF Makishima et al. [47]
Missense c.1078C > A Exon 12 p.Pro360Thr Spanish 44 years Mild to moderate Gently downsloping Morín et al. [13]
Missense c.1107G > T Exon 12 p.Glu369Asp Spanish 10–11 years Moderate to severe Gently downsloping Morín et al. [13]
Missense c.1109G > A Exon 13 p.Arg370His Philippines N.A N.A N.A Truong et al. 2019 [48]
Missense c.1109G > C Exon 13 p.Arg370Pro Japanese 30 years Mild to moderate MF Shinagawa et al. [9]
Missense c.1109G > C Exon 13 p.Val371Met Belgium N.A N.A N.A Sommen et al. [49]
Frameshift c.1115_1118dup TTGT Exon 13 p.Trp374Cysfs*6 Hungarian N.A N.A N.A Pfister et al. [50]
Missense c.1122G > T Exon 13 p.Trp374Cys Australian 10–25 years Mild to severe Gently downsloping Morín et al. [13]
Missense c.1154C > T Exon 13 p.Ser385Leu Italian N.A Mild to profound MF Cesca et al. [51]
Nonsense c.1177C > T Exon 13 p.Gln393*

Korean

Japanese

N.A

26 years

 moderate

HF

Flat

Kim [10]

Shinagawa et al. [9]
Frameshift c.1194del Exon 14 p.Met401Trpfs*3 Korean N.A Moderate Down sloping Choi et al. [46]
Missense c.1216G > C Exon 14 p.Gly406Arg Japanese 5 years Moderate Flat Shinagawa et al. [9]
Missense c.1223G > A Exon 14 p.Arg408His America N.A N.A N.A Miszalski-Jamka et al. [45]
Missense c.1281G > A Exon 14 p.Glu427Glu Spanish 26 years Moderate to profound Flat Morín et al. [13]
Splicing c.1282-12T > A Intron 14 Australian N.A Mild to profound Flat Hildebrand et al. [52]
Splicing c.1282-1G > A Intron 14 Spanish 12 years Mild to moderate MF/Flat Morín et al. [13]
Missense c.1301T > A Exon 15 p.Ile434Lys Chinese 8–38 years Mild to severe MF/flat Tan et al. [53]
Splicing c.1341-19T > A Intron 15 Germany N.A N.A N.A Vona et al. [54]
Nonsense c.1601C > G Exon 17 p.Ser534* Spanish 3–16 years Moderate to severe MF/Flat Morín et al. [13]
Missense c.1643C > G Exon 18 p.Thr548Arg Chinese 17–40 years Mild to profound N.A Sun et al. [11]
Missense c.1663G > C Exon 18 p.Ala555Pro Japanese 25 years Moderate N.A Shinagawa et al. [9]
Splicing c.1739-1G > A Intron 18 America 50 years N.A N.A Cirino et al. [55]
Nonsense c.1759C > T Exon 19 p.Arg587* Belgian 6–40 years Mild to moderate N.A Wayne et al. [12]
Frameshift c.1790del Exon 19 p.Val597Glyfs*4 Japanese 35 years Moderate Flat Iwasa et al. [56]
Missense c.1810G > T Exon 19 p.Gly604Cys Swedish Dutch N.A N.A N.A

Neveling et al. [39]

Van Beelen et al. [40]
Nonsense c.1834A > T Exon 19 p.Lys612* Chinese 27 years Moderate Gently downsloping Hu et al. [16]
Missense c.1855T > G Exon 20 p.Trp619Gly Chinese N.A N.A N.A Xiao et al. [57]
CNV

Deletion 7689 bp

(Ex7 to Ex11)

 Japanese 25 years Moderate to severe LF/HF Shinagawa et al. [9]
CNV

Deletion 9.5 Mb

(Ex4 to Ex 20)

 Japanese 13 years Severe LF/HF Shinagawa et al. [9]
CNV

Deletion 2747 bp

(Ex15 to Ex17)

 Spanish 8 years Moderate Flat Morín et al. [13]
CNV

Deletion 9 Mb at 6q23.1–24.1

(Ex4–20)

 p.Asp194Glyfs*30 Polish N.A N.A N.A Dutrannoy et al. [30]
CNV

Deletion 4846 pb incl. intron 9, exon 10 and partial intron 10 c.581_804del

(In9, Ex10, part of In10)

 N.A N.A N.A Schönberger et al. [34]
CNV Deletion 10.4 Mb promoter and exon 1,2 (Ex1–2) Japanese 20-month-old Moderate to severe MF/flat Abe et al. [31]
CNV

Deletion 3.7 MB in 6q23.1q23.2

(Ex1–20)

 Italian 12 years N.A N.A Gana et al. [58]
CNV Deletion 12,835 bp (Ex6–10) Japanese 23 years Mild to sereve LF/HF/Flat Ishino et al. [14]
CNV Deletion 17.4 kb and 10 bp insertion (Ex8–11) Chinese 26–42 years Moderate–severe Flat This work
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Several CNVs in EYA4 have been linked to deafness (Fig. 3). One CNV disrupts the EYA4 gene and spares only exons 1–3 from the deletion [30]. The deleted sequence of the promoter and the first two exons was previously identified in a Japanese boy [31]. A deletion of four exons and a deletion spanning exons 4–20 have been reported to cause severe ADNSHL in Japanese individuals [9]. In addition, the EYA4 variant reportedly causes dilated cardiomyopathy accompanying NSHL in a single large family. In this family, a 4846-bp genomic deletion that resulted in loss of the EYA domain (eyaHR) and part of the variable region (eyaVR) was detected [32]. A heterozygous deletion of 2747 bp represented a copy variant loss encompassing exon 15 to exon 17 [13]. Additionally, in Japan, a novel hemizygous indel in the EYA4 gene was predicted to be p. (Val124_Pro323del) [14]. We now add a genomic rearrangement consisting of a deletion and a 10-bp insertion to this list (Fig. 3, Table 3).

Fig. 3.

Fig. 3

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Overview of the CNVs identified in this study and those previously identified in EYA4

The EYA4 gene is widely distributed in the inner ear, which includes otic vesicles, the Reissner membrane and the sensory epithelia of the vestibular system and Corti [12, 33]. Although the pathogenic mechanism of ADNSHL associated with EYA4 variants remains to be further investigated, haploinsufficiency is generally thought of as the major mechanism. Many reports indicate that EYA4 participates in important pathways in cardiac tissue. The physiological level of Eya4 phosphatase activity is thought to participate in normal cardiac gene regulation. Instead of most DCM genes that encode structural proteins, EYA4 is a transcriptional coactivator. Large deletions comprising the variable domain are most likely to affect cardiac functions. A patient carrying a de novo 9 MB interstitial deletion that disrupts the gene EYA4 presented a patent ductus arteriosus and aortic insufficiency. A family with a 4846-bp deletion was associated with DCM as well as NSHL. In the other 2 unrelated families, polymorphic loci on chromosome 6q23 to 24 were associated with DCM and NSHL. [30, 34]. For that reason, we performed electrocardiograms for all family members. None of the members exhibited a cardiac phenotype, and electrocardiograms showed no abnormalities. Including our work, many studies indicated that the genotype–phenotype correlation of large deletions in EYA4 and dilated cardiomyopathy was not very obvious [14]. One reason may be that previously reported cardiopathy was caused by other variants in the large deleted regions. Another reason is that the defect in a contiguous gene could account for the cardiac defects [34]. More experiments, including detecting EYA4 levels in nuclear and cytoplasmic components, may provide evidence for this theory. Increasing the yield of genetic testing among patients with both NSHL and DCM may allow for better detection of the EYA4 gene and cardiac pathology [35].

Conclusions

A novel CNV deletion at 6q23 in exons 8–11 of EYA4 in a Chinese ADNSHL family was identified by WGS and Sanger sequencing. The phenotype of the family differed from that of previously reported pedigrees with CNV deletion of EYA4 variants. The phenotypes also differed between individuals with the same variant in the same family. Our results highlight the complexity of the EYA4 genotype and phenotype.

Supplementary Information

12920_2022_1269_MOESM1_ESM.docx (163.9KB, docx)

Additional file 1: Pedigree diagram of the four generations of FY-140 with variants in CDH23.

12920_2022_1269_MOESM2_ESM.docx (322.9KB, docx)

Additional file 2: Sanger sequencing of c.7630T>G, p. Leu2544Val in Family FY-140.

12920_2022_1269_MOESM3_ESM.docx (334.1KB, docx)

Additional file 3: Figure S3. Sanger sequencing of c.8257G>A p. Ala2753Thr in Family FY-140.

Acknowledgements

We thank the patients and their family members for their cooperation in this study.

Author contributions

WZ, JS: original draft preparation, conducting experiments. JY and YY reviewed the manuscript. LG, MM, BT: conceptualization, supervision, methodology, reviewing and editing manuscript. All authors read and approved the final manuscript.

Funding

This project has received funding from the Natural Science Foundation of Shanghai (No 19ZR1408700), the Shanghai 2020 Science and Technology Innovation Action Plan One Belt One Road International Cooperation Project (20410740600) and the Clinical Research Plan of SHDC (SHDC2020CR1049B).

Availability of data and materials

The authors are not able to share the clinical data due to full anonymisation of the data is very difficult. The CNV in our study was called based on the human assembly GRCh38 (https://hgdownload.soe.ucsc.edu/downloads.html#human). This CNV has been submitted to LOVD under accession ID 00361730. All sequencing data used to support the findings of this study are available from the corresponding author upon request.

Declarations

Ethics approval and consent to participate

The study was conducted in accordance with the principles of the Declaration of Helsinki. Approval for the study was obtained from the Ethics Committee of the Eye & ENT Hospital, Fudan University for Human Studies. Written informed consent was obtained from the participants or the parents of minors.

Consent for publication

Not applicable.

Competing interests

None declared.

Footnotes

Publisher's Note

Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Weixun Zhang and Jing Song contributed equally to this work.

Contributor Information

Yasheng Yuan, Email: yuanyasheng@163.com.

Juanmei Yang, Email: yangjuanmei1982@126.com.

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Associated Data

This section collects any data citations, data availability statements, or supplementary materials included in this article.

Supplementary Materials

12920_2022_1269_MOESM1_ESM.docx (163.9KB, docx)

Additional file 1: Pedigree diagram of the four generations of FY-140 with variants in CDH23.

12920_2022_1269_MOESM2_ESM.docx (322.9KB, docx)

Additional file 2: Sanger sequencing of c.7630T>G, p. Leu2544Val in Family FY-140.

12920_2022_1269_MOESM3_ESM.docx (334.1KB, docx)

Additional file 3: Figure S3. Sanger sequencing of c.8257G>A p. Ala2753Thr in Family FY-140.

Data Availability Statement

The authors are not able to share the clinical data due to full anonymisation of the data is very difficult. The CNV in our study was called based on the human assembly GRCh38 (https://hgdownload.soe.ucsc.edu/downloads.html#human). This CNV has been submitted to LOVD under accession ID 00361730. All sequencing data used to support the findings of this study are available from the corresponding author upon request.

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