Abstract
Kindler syndrome (KS; OMIM 173650) is a rare autosomal recessive skin disorder, which results in symptoms including blistering, epidermal atrophy, increased risk of cancer, and poor wound healing. The majority of mutations of the disease-determining gene (FERMT1 gene) are single nucleotide substitutions, including missense mutations, nonsense mutations, etc. Large deletion mutations are seldom reported. To determine the mutation in the FERMT1 gene associated with a 7-year-old Chinese patient who presented clinical manifestation of KS, we performed direct sequencing of all the exons of FERMT1 gene. For the exons 2–6 without amplicons, we analyzed the copy numbers using quantitative real-time polymerase chain reaction (qRT-PCR) with specific primers. The deletion breakpoints were sublocalized and the range of deletion was confirmed by PCR and direct sequencing. In this study, we identified a new 17-kb deletion mutation spanning the introns 1–6 of FERMT1 gene in a Chinese patient with severe KS phenotypes. Her parents were carriers of the same mutation. Our study reported a newly identified large deletion mutation of FERMT1 gene involved in KS, which further enriched the mutation spectrum of the FERMT1 gene.
中文概要
目 的
Kindler 综合征(Kindler syndrome, KS; OMIM 173650), 又称伴大疱的先天性皮肤异色症, 是一种罕见的常染色体隐性遗传性皮肤病, 其致病基因为编码Fermitin 家族同源物1 蛋白的FERMT1 基因。本研究旨在对一例临床诊断为KS的患儿及其父母进行FERMT1 基因突变分析
创新点
本研究中的KS 病例为FERMT1 基因新纯合缺失突变所致, 为目前证实缺失范围最大的病例。
方 法
经知情同意后, 采集一例患儿及父母外周血。首先利用Sanger 测序检测患儿FERMT1 基因所有外显子(外显子1∼15)及两侧内含子区域; 随后利用实时定量聚合酶链式反应(qRT-PCR)测定部分外显子(外显子1、2∼7、14 和15)的拷贝数, 最终通过PCR 和测序方法确定患儿FERMT1基因的断裂位点。
结 论
本研究报告了一例FERMT1 基因新大片段纯合缺失(17 252 bp 纯合缺失)所致的KS(图1∼3), 扩展了该基因突变数据库。同时, 本研究提示该疾病的基因诊断方法不应局限于常规DNA 外显子测序, 应综合多种方法进行突变分析, 以防止大片段缺失病例的漏检。
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1 Introduction
Kindler syndrome (KS; OMIM 173650) is a rare autosomal recessive skin disorder characterized by blistering, extensive epidermal atrophy, photosensitivity, increased risk of cancer, and poor wound healing. The mucosal involvement included early and severe periodontitis, and/or esophageal, gastrointestinal, and genital involvement (Jobard et al., 2003; Siegel et al., 2003; Has and Bruckner-Tuderman, 2006; Kern et al., 2007). It was first described by Theresa Kindler (1954) in a 14-year-old girl who had suffered from acral blistering since childhood and subsequently developed poikiloderma and photosensitivity.
The KS disease-determining gene, termed FERMT1 gene (OMIM 607900), was mapped to chromosome 20p12.3 (Jobard et al., 2003; Siegel et al., 2003). This gene contains 15 exons and spans 48.5 kb of genomic DNA. The coding sequences extend from exon 2 to exon 15. The encoded protein (kindling-1, 677 amino acid (aa), molecular weight of 77.3 kDa) is implicated in linking the actin cytoskeleton to the extracellular matrix (Jobard et al., 2003; Siegel et al., 2003). Lack of kindling-1 in keratinocytes would result in decreased cell adhesion, reduced proliferation, increased apoptosis, and loss of cell polarity (Herz et al., 2006).
In our present study, genetic analysis, including the direct sequencing of all exons and quantitative real-time polymerase chain reaction (qRT-PCR) were performed in order to identify a new, larger deletion mutation spanning about 17 kb from the intron 1 to intron 6 of FERMT1 gene in a Chinese KS family.
2 Materials and methods
2.1 Patient and DNA samples
Genomic DNA was extracted from the peripheral blood leukocytes of the patient and her parents, using the phenol-chloroform method. Informed consent was obtained from the patient’s parents. The project was approved by the Ethics Committee of the Capital Institute of Pediatrics (Beijing, China).
2.2 Molecular genetic analysis
2.2.1 DNA sequence analysis
For the patient with clinically confirmed KS, we screened all exons (exons 1–15) and flanking sequences of the FERMT1 gene using Sanger sequencing. The primers for the PCR and the annealing temperatures were as described by Siegel et al. (2003). The PCR products were purified and direct sequencing of fragments was carried out with an ABI 3730 automatic sequencer (Applied Biosystems, USA).
2.2.2 Copy number analysis of FERMT1 gene
For the exons without amplification products by Sanger sequencing, we performed qRT-PCR in order to detect their copy numbers on an ABI Prism™ 7500 Sequence Detection System (Applied Biosystems, USA) using SYBR Green Master Mix (Applied Biosystems, Foster, USA). All data analysis was performed using the 2−ΔΔC T method in Microsoft Excel Version 2007. Primers were designed using the Primer Express 3.0 software (Applied Biosystems, USA) for the 9 exons of the FERMT1 gene and were evaluated using the National Center for Biotechnology Information’s BLAST program. Glyceraldehyde-3-phosphate dehydrogenase (GAPDH) was selected as endogenous control. All samples were run in triplicate. We used the ΔΔC T method to analyze the copy numbers and compare them with those of 20 healthy samples. Experiments were replicated at least twice if a deletion/duplication was suspected to have occurred.
2.2.3 Breakpoint analysis of FERMT1 gene
In order to sublocalize the deletion breakpoints, we designed 9 pairs of primers to amplify the non-overlapping fragments in introns 1 and 6. Subsequently, the junction fragment was amplified with the template DNA of the patient using a pair of primers, P10F in intron 1 (forward primer: 5′-AGGCAA GCAGTTAGGCCTAAT-3′) and P10R in intron 6 (reverse primer: 5′-ATGACAGAGCCCATTTCCTG-3′) to confirm the 5′ and 3′ breakpoints of the FERMT1 gene in the patient.
3 Results
3.1 Clinical features of the patient with Kindler syndrome
The patient, a 7-year-old female born to consanguineous parents, presented with recurrent blistering over the hands and feet (Fig. 1a). Her parents stated that blister generation might be associated with local friction. When given topical mupirocin ointment the sites of lesions were consequently healed without scarring, and it has been so since the early neonatal period. When she was eight months old, her teeth came through but dental caries were also observed. Subsequently, constipation, including dry stool and defecation difficulties, began at about the age of one. When exposed to sunlight she was found to be prone to photosensitivity. When she was seven years old, she was admitted to our department of dermatology. Upon physical examination, poikiloderma was noted on her face, neck, and upper chest, and erythematous lesions and skin atrophy were observed on the trunk and four extremities (Figs. 1b and 1c). In addition, pseudoainhum was obviously apparent. Examination of the oral cavity showed poor preservation of teeth and severe periodontitis, with easy bleeding (Figs. 1d–1f). She also stated that slight dysphagia existed. Electron microscopy showed a fracture of the lamina densa (Fig. 1g). Histopathological examinations of the skin biopsy with the abdominal involved area showed hyperkeratosis, atrophy of the epidermis, fracturing of the basal layer, and melanophages in the papillary dermis. A biopsy of the skin lesion showed the features of poikiloderma (Fig. 1h). The results of routine blood examinations, cranial computed tomography, and electroencephalogram were all normal.
3.2 Molecular genetic analysis
3.2.1 DNA sequence analysis
After the Sanger sequencing of the FERMT1 gene, no mutation was identified within 10 exons, including exons 1 and 7–15 in the patient. However, DNA sample from the patient failed to yield PCR amplification products for exon 2 to exon 6 (5 exons), whilst they could be amplified in the normal controls and her parents, which revealed that the amplification condition was optimal.
3.2.2 Gene copy number changes and breakpoint confirmation
Since no amplification products for exon 2 to exon 6 were observed with the patient, we were able to precisely identify the copy numbers of this gene (exons 1, 2–7, 14, and 15) using qRT-PCR on genomic DNA. This result further showed that, for exons 2–6, both of the patient’s parents carried one copy and the patient had no copy. However, for exons 1, 7, 14, and 15, the patient and her parents carried two copies (Fig. 2).
The results of DNA sequencing and copy numbers analysis revealed that the 5′ and 3′ breakpoints may be closed to exons 1 and 6, respectively. Several amplification results from intron 1 and intron 6 confirmed that 5′ and 3′ breakpoints were located in introns 1 and 6, respectively. With primers P10F and P10R, the truncated PCR product (763 bp) was obtained from the patient, which revealed that a homozygous large deletion mutation of 17 252 kb was observed in the patient. Meanwhile, her parents both carried the same heterozygous deletion mutation. However, no truncated fragments were observed within the normal controls (Fig. 3).
4 Discussion
In this paper, we have reported a Chinese patient with KS, who had been molecularly confirmed to carry a large homozygous deletion of the FERMT1 gene. To date, over 70 FERMT1 gene mutations have been reported (Lai-Cheong et al., 2007; Mansur et al., 2007; Has et al., 2008; Zhou et al., 2009; Mas-Vidal et al., 2010; Kartal et al., 2015; Youssefian et al., 2015). Many mutations are single nucleotide substitutions, including missense mutations, nonsense mutations, etc.
The predicted protein structure of kindlin-1 encoded by FERMT1 gene reveals several domains of interest, in particular the FERM domain which is interrupted by a pleckstrin homology (PH) domain (Jobard et al., 2003; Yates et al., 2012). The protein is expressed at high levels in epithelia, in particular in the epidermis and the gastro-intestinal tract (Sadler et al., 2006). Loss of kindlin-1 would interrupt the organization and anchorage of the actin cytoskeleton to integrin-associated platforms. To our knowledge, our patient carried the largest genomic deletion of the FERMT1 gene, spanning 17 kb from intron 1 to intron 6. We suspected that it was possible that this deletion might lead to a complete loss of exon 1 to exon 7 (1–319 aa). Moreover, it is noteworthy that the deletion range contained the translation initiation site (TIS) ATG located in exon 2. We used ORF (open reading frame) Finder (http://www.ncbi.nlm.nih.gov/gorf/orfig.cgi) to predict the complementary DNA (cDNA) sequences lacking in the original TIS for potential protein encoding segments. The predicted TIS might be the new start codon, which was 690 bp in length and encoded a 230-aa protein. The predicted protein starting at ATG in exon 7 was 447 aa shorter than normal kindlin-1. It is therefore presumed that the truncated kindlin-1 fragment might lead to elimination of the entire N-terminal FERM domain and most of the PH domain of kindlin-1. It is also possible that no kindlin-1 is expressed at all. It is a pity that we cannot perform a mutant protein expression analysis since no further samples of the patient’s skin were available.
During the repair of double strand breaks (DSBs) in DNA, several different mechanisms are involved, including non-homologous end-joining (NHEJ), microhomology-mediated replication-dependent recombination (MMRDR), and homologous recombination (HR) (including non-allelic homologous recombination (NAHR) and single strand annealing (SSA)) (Chen et al., 2010; Schipler and Iliakis, 2013). Large genomic deletions of the FERMT1 gene can often occur through erroneous recombination of non-allelic homologous repetitive elements, such as Alu sequences (Has et al., 2006). By blasting these with the wide sequences, we found that the 5′ and 3′ breakpoints had 14 bp identical sequences. Meanwhile, analysis of the intron sequence repeat elements by the RepeatMasker program revealed that the 5′ and 3′ breakpoints were located in the AluSg and AluSp elements, respectively. Thus, we suspected that the deletion breakpoints embedded in Alu repeats might be mediated by Alu-mediated HR. Zhou et al. (2009) assumed that 3017-bp deletion in the FERMT1 gene may be caused by matrix attachment regions (MARs) (the short homologous sequence GA and the sequence TTTAAA), rather than by the Alu/Alu HR.
To date, the genomic Sanger sequencing has been the main detection method to screen the FERMT1 mutation for KS patients, since the majority of FERMT1 mutations are single nucleotide substitutions, including missense mutations, nonsense mutations, etc. However, in some cases, FERMT1 mutations could not be disclosed using the methods outlined above. In view of the presence of many repeat sequences in introns of the FERMT1 gene, we suspected that a certain proportion of cases might be due to large scale deletion of this gene. As more KS patients were confirmed with large deletion of the FERMT1 gene (Has et al., 2008; Zhou et al., 2009), many researches revealed that a rational mutation detection strategy of FERMT1 mutations would be necessary for the genetic diagnosis of KS patients (Takeichi et al., 2015). Thus, we proposed that a copy number analysis of FERMT1 gene might be an optimal procedure for the patients not fully confirmed by genomic Sanger sequencing. This could help us to preliminarily determine the deletion range. Subsequently, the 5′ and 3′ breakpoints would be sublocalized by PCR and direct sequencing. Primers designed near the two breakpoints would help us to confirm the deleted sequences.
Our study identified a new large deletion mutation of FERMT1 gene, which might expand the mutation database. Moreover, based on the experience of detecting the mutation, we would emphasize that a rational diagnostic procedure of FERMT1 gene mutations screening would be advisable.
Compliance with ethics guidelines
Ying GAO, Jin-li BAI, Xiao-yan LIU, Yu-jin QU, Yan-yan CAO, Jian-cai WANG, Yu-wei JIN, Hong WANG, and Fang SONG declare that they have no conflict of interest.
All procedures followed were in accordance with the ethical standards of the responsible committee on human experimentation (institutional and national) and with the Helsinki Declaration of 1975, as revised in 2008 (5). Informed consent was obtained from the patient for being included in the study. Additional informed consent was obtained from the patient for whom identifying information is included in this article.
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Acknowledgements
We are grateful to the patient and her family for their participation in this study.
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ORCID: Jin-li BAI, http://orcid.org/0000-0002-7601-9213; Fang SONG, http://orcid.org/0000-0002-8844-1331
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Gao, Y., Bai, Jl., Liu, Xy. et al. A novel large deletion mutation of FERMT1 gene in a Chinese patient with Kindler syndrome. J. Zhejiang Univ. Sci. B 16, 957–962 (2015). https://doi.org/10.1631/jzus.B1500080
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DOI: https://doi.org/10.1631/jzus.B1500080