- Email: [email protected]
Genetic variation analysis in a Chinese Maffucci syndrome patient
Accepted Manuscript Genetic variation analysis in a Chinese Maffucci syndrome patient Yang Xue, MD, Jinwen Ni, MS, Mi Zhou, MS, Weiqi Wang, MS, Yuan Liu, MD, Yaowu Yang, MD, Professor, Xiaohong Duan, PHD, Professor PII:
S1010-5182(15)00160-2
DOI:
10.1016/j.jcms.2015.05.017
Reference:
YJCMS 2069
To appear in:
Journal of Cranio-Maxillo-Facial Surgery
Received Date: 7 January 2015 Revised Date:
25 May 2015
Accepted Date: 26 May 2015
Please cite this article as: Xue Y, Ni J, Zhou M, Wang W, Liu Y, Yang Y, Duan X, Genetic variation analysis in a Chinese Maffucci syndrome patient, Journal of Cranio-Maxillofacial Surgery (2015), doi: 10.1016/j.jcms.2015.05.017. 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 Genetic variation analysis in a Chinese Maffucci syndrome patient Yang Xuea MD, Jinwen Nia MS, Mi Zhoua MS, Weiqi Wangb MS, Yuan Liuc MD, Yaowu Yangb,* MD, Xiaohong Duana,* PHD a: State Key Laboratory of Military Stomatology, Department of Oral Biology, Clinic
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of Oral Rare and Genetic Diseases, School of Stomatology, the Fourth Military Medical University, 145 West Changle Road, Xi’an 710032, P. R. China
b: State Key Laboratory of Military Stomatology, Department of Oral and
145 West Changle Road, Xi’an 710032, P. R. China
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Maxillofacial Surgery, School of Stomatology, the Fourth Military Medical University,
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c: State Key Laboratory of Military Stomatology, Department of Oral Histology and Pathology, School of Stomatology, the Fourth Military Medical University, 145 West Changle Road, Xi’an 710032, P. R. China *Corresponding authors:
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Xiaohong Duan, Ph.D, Professor
State Key Laboratory of Military Stomatology, Department of Oral Biology, Clinic of Oral Rare and Genetic Diseases, School of Stomatology, the Fourth Military Medical
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University, 145 West Changle Road, Xi’an 710032, P. R. China
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Tel: 86-29-84776169;Fax: 86-29-84776169;E-mail: [email protected] Yaowu Yang, MD, Professor State Key Laboratory of Military Stomatology, Department of Oral and Maxillofacial Surgery, School of Stomatology, the Fourth Military Medical University, 145 West Changle Road, Xi’an 710032, P. R. China Tel: 86-29-84772503;Fax: 86-29-84772503;E-mail: [email protected] Sources of grants: This work was supported in part by grants of the National Natural Science Foundation
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of China [81470728 (XD), 81271116 (XD), 81470757(YY)].
ACCEPTED MANUSCRIPT Abstract Objective: To report on the molecular genetic analysis of a Chinese patient with Maffucci syndrome. Methods: Using the genomic DNA extracted from the patient’s hemangioma sample,
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the coding exons and exon/intron splice junctions of the IDH1 and IDH2 genes were amplified by polymerase chain reaction (PCR) and then sequenced. Genomic DNA
was extracted from blood and a hemangioma sample from the patient, and also from
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her mother’s blood, for chromosome microarray analysis (CMA) by Affymetrix CytoScan HD array.
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Results: None of the known pathogenic mutations in the whole IDH1 or IDH2 genes was found in the patient’s hemangioma sample. CMA detected 40 tumor-specific copy number variations (CNVs), and one copy number neutral loss of heterozygosity (LOH) region. Among the 73 known genes included in the 40 CNV regions, only 2 genes,
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CHEK2 (604373) located in 22q12.1 and EP300 (602700) located in 22q13.2, were found to be related to tumorigenesis. We did not find any CNVs at the IDH1 and IDH2 loci.
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Conclusions: This is the first molecular genetic analysis report on a Chinese patient
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with Maffucci syndrome and our data enrich the understanding of the genetic background of Maffucci syndrome in different ethnic groups. The relationship between CHEK2, EP300 and Maffucci syndrome needs to be further explored. Keywords: copy number variation, IDH1, IDH2, Maffucci syndrome, microarray analysis
ACCEPTED MANUSCRIPT Introduction Maffucci syndrome is a rare, nonhereditary and congenital mesodermal dysplasia, characterized by a combination of multiple enchondromas and hemangiomas (Pansuriya et al., 2011a). It was first described in 1881 by Maffucci, and about 200
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cases have been described in the literature to date (Cai et al., 2013; Ono et al., 2012). There is neither sex preponderance nor a difference in incidence among races (Amary et al., 2011; Gao et al., 2013; Jermann et al., 2001).
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In recent years, the genetic background of Maffucci syndrome has drawn great
attention. It has been reported that somatic mosaic isocitrate dehydrogenase 1 (IDH1)
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and IDH2 mutations are associated with enchondromas and spindle cell hemangiomas in Maffucci syndrome (Amary et al., 2011; Amyere et al., 2014; Pansuriya et al., 2011b). Here, we report on a Chinese female patient affected by Maffucci syndrome, with no somatic mosaic IDH1 or IDH2 mutations found in a hemangioma sample. A
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high-resolution Affymetrix CytoScan HD Array was used to detect the possible related copy number variation (CNV) as well as copy number neutral loss of heterozygosity (LOH).
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Patient data
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Materials and methods
At first presentation, the patient was 18 years old; she weighed 40 kg and was 126
cm tall. Her left leg was 20 cm shorter than her right leg, while her left arm was 10 cm shorter than her right arm. She was born to non-consanguineous and healthy parents. Her mother had a history of two spontaneous abortions, and the patient was born at 28 weeks with no specified cause for the premature birth. She had a healthy younger brother. She complained of a progressive but painless mass in the submental area for more than 2 years. The patient’s leg lengths had been unequal since she was
ACCEPTED MANUSCRIPT one year old, and she had significantly enlarged limbs and joints and multiple purple lesions on her hands and feet since she was 3 years old (Fig.1). The symptoms gradually worsened with age. Her first menstrual period was at 18 years old; her periods were irregular with small amounts of bleeding.
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Radiographs showed multiple, irregularly shaped radiolucent areas with stippled calcification on bilateral pelvis and the left femur, humerus, ulna, radius, and index
finger (Fig.2 A–D). The long bones on the left side of her body (including the femur,
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tibia, fibula, humerus, ulna and radius) were significantly shorter than those on the right. Computed tomographic angiography (CTA) with three dimensional
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reconstruction displayed the worm-eaten appearance of bone destruction involving the sternum, occipital bone, bilateral pelvis, scapula, ribs, humerus, radius and thumb, and left femur and index finger (Fig.2 E–G). Both computed tomography (CT) and CTA showed an extensive soft tissue mass of about 6.4 × 4.5 × 7.0 cm in the submental
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area. Multiple punctate calcification in the mass and bone involvement of the chin could also be seen (Fig.2 F and H).
The subcutaneous lesions in her hands and feet were diagnosed as venous
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malformation by physical examination and Doppler ultrasonography. No obvious
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change was found in the comprehensive metabolic panel (including general tests, electrolytes, and assessment of renal and hepatic function). Pathological examination after surgical resection of part of the lesions showed that the lesions in the tongue and submental area were venous malformations (Fig.3 A); and a biopsy showed that the lesion in the left humerus was an enchondroma (Fig.3 B). On the basis of these findings – the development of multiple enchondromas in the extremities and the presence of subcutaneous vascular lesions – the diagnosis of Maffucci syndrome was established.
ACCEPTED MANUSCRIPT With written informed consent, the patient and her mother were included in this study. The study was authorized by the Ethics Committee, School of Stomatology, the Fourth Military Medical University, Xi’an, China. Genomic DNA preparation
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Blood and fresh hemangioma samples were obtained from the patient. Genomic DNA (gDNA) was extracted using QIAamp DNA blood and a tissue mini kit, respectively (Qiagen Inc., Chatsworth, CA, USA).
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IDH1 and IDH2 mutation analysis
Using the gDNA extracted from the patient’s hemangioma sample, the coding
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exons and exon/intron splice junctions of the IDH1 and IDH2 genes were amplified by polymerase chain reaction (PCR). Primers and PCR amplification conditions were previously described (Amary et al., 2011). PCR products were purified with DNA Fragment Quick Purification/Recover Kit (DingGuo, Beijing, China) and sequenced
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with an ABI 377 Sequencer (Perkin-Elmer Corp., Norwalk, Conneticut, USA). Sequence variants were identified using DNAStar, MegAlign 5.01 (Demonstration System DNASTAR, Inc., Madison, USA).
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Single-nucleotide polymorphism (SNP) array analysis
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Genomic DNA was extracted from the patient’s blood and hemangiomas for chromosome microarray analysis (CMA) by Affymetrix CytoScan HD array (Affymetrix, Inc., Santa Clara, CA, USA). Hybridizations were performed according to the manufacturer’s protocols. The data obtained were analyzed using the Chromosome Analysis Suite software package (Affymetrix, Inc., Santa Clara, CA, USA). Gene annotation and gene overlap were determined using the human genome build 19 (hg19). All the identified CNVs were compared with those reported in the Database of Genomic Variants (DGV, http://projects.tcag.ca/variation/).
ACCEPTED MANUSCRIPT Results IDH1 and IDH2 mutation analysis Neither IDH1-R132C/IDH2-R172S nor other mutations in the whole of the IDH1 or IDH2 genes were found in the patient’s hemangioma sample.
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Results of CytoSan HD array
Both the analyzed tumor and the blood samples had chromosomal aberrations. A summary of the CNVs in different categories and detailed information are presented
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in Tables 1 and 2, respectively. We found 15 regions with copy number gain and 25 regions with copy number loss in the patient’s hemangioma tissue when compared
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with the patient’s or her mother’s blood samples. Distribution of the CNVs in chromosomes was shown in Fig 4. Chromosome 22 exhibited the most frequent losses (20%); and chromosome X represented 6.7% of all gains and 12% of all losses. Most of the identified regions were known to have common CNV in the Database of
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Genomic Variants. Seventy-three known genes were included in the 40 regions, while 25 were found to be related to human disease (Table 2). In particular, somatic mutations in CHEK2 (604373) located in 22q12.1 and EP300 (602700) located in
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22q13.2 may play an important role in osteosarcoma (259500) and colorectal cancer
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(114500). We did not see any CNVs at the IDH1 and IDH2 loci. A summary of the LOH in different categories is presented in Table 3. We also
found an LOH region (Xq22.3 104232592-107407242) positive in the patient’s tumor tissue but negative in the patient’s blood sample (Table 4). After analysis, we found that the patient’s tumor-specific copy number neutral LOH located in Xq22.3 was caused by maternal uniparental disomy (data was not shown). Two of the 22 known genes in this region are related to human disease. Discussion
ACCEPTED MANUSCRIPT The typical clinical presentation of Maffucci syndrome includes multiple enchondromas and vascular lesions, which are commonly associated with phleboliths (Biber et al., 2004; Cai et al., 2013). It can be diagnosed relatively easily solely on clinical grounds (Gao et al., 2013). The diagnosis of Maffucci syndrome was
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established for the present patient on the basis of her typical presentation and pathological examination.
In recent years, the genetic background of Maffucci syndrome has attracted much
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attention. Parathyroid hormone receptor type 1 (PTHR1) gene mutation was screened for in leukocyte and/or tumor DNA samples from 30 Maffucci syndrome patients, but
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none was detected (Couvineau et al., 2008; Pansuriya et al., 2011a; Rozeman et al., 2004). Other genes involved in the IHH–PTHLH (Indian hedgehog–parathyroid hormone-like hormone) pathway, including parathyroid hormone related protein (PTHrP); Indian hedgehog (IHH); and guanine nucleotide binding protein, alpha
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stimulating activity polypeptide 1 (GNAS1); were tested in one Maffucci syndrome patient, but no mutation was found (Couvineau et al., 2008). Recently, somatic mosaic mutations in the gene encoding IDH1 and IDH2 were found to be associated with
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enchondromas and spindle cell hemangiomas in Ollier disease and Maffucci
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syndrome (Amary et al., 2011; Amyere et al., 2014; Pansuriya et al., 2011b). According to these reports, 18 out of 24 tested patients (75.0%) carried IDH1 mutation rather than IDH2, and IDH1-R132C was the only hotspot mutation (Table 5). The mutation was absent in the DNA from patients' blood, muscle or saliva (Pansuriya et al., 2011b). With an analysis of the published data on the tested hemangioma DNA samples of Maffucci syndrome patients (Amary et al., 2011; Amyere et al., 2014; Pansuriya et al., 2011b), we found that 4 out of 7 female patients (57.1%) and 6 out of 7 male patients (85.7%) carried an IDH1-R132C mutation. In
ACCEPTED MANUSCRIPT total, 10 out of 14 patients (71.4%) carried it (Table 5). We analyzed all the coding exons and intron–exon junctions of the IDH1 and IDH2 genes in the hemangioma DNA sample from our patient; however, neither the hotspot mutation nor any other known pathogenic mutation could be detected. Further research is needed to
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determine whether or not the IDH1-R132C mutation in hemangiomas from Mafucci syndrome patients has male predominance, because the number of tested patients is still limited.
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Recently, CNV has been recognized as one of the most important genomic
alterations that plays a role in cancer pathogenesis (Iafrate et al., 2004). In addition,
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somatic CNVs can be used to identify regions of the genome that are involved in disease phenotypes (Chen et al., 2013; Jasmine et al., 2012; Sanjmyatav et al., 2011). Though genome-wide analysis of CNV and LOH using Affymetrix SNP 6.0 array on enchondromas and chondrosarcomas from four Maffucci syndrome patients was
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reported (Pansuriya et al., 2011a), the causative gene was not identified. Using the Affymetrix SNP 6.0 array, recent research which included nine frozen tumor samples from patients with Maffucci syndrome found that the most frequently encountered
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somatic alterations were localized in 2p22.3, 2q24.3 and 14q11.2 (Amyere et al.,
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2014). Here, we report the first genome-wide analysis using Affymetrix CytoScan HD Array on hemangioma and blood samples from a Chinese patient with Maffucci syndrome. The Affymetrix CytoScan HD Array (a CNV-targeted array) is based on the validated Genome-Wide Human SNP Array 6.0 and characterized by 2.6 million CNV markers including approximately 750,000 genotype-able SNP probes and 1,900,000 non-polymorphism probes, with the median inter-marker distance of 500–600 bases (Wang et al., 2014). In addition, this chip provides allelic imbalance information from SNPs. It has great power to detect known and novel chromosome
ACCEPTED MANUSCRIPT aberrations across the entire human genome and features unbiased whole-genome coverage, with the highest physical coverage of the genome (Chen et al., 2013; Veerappa et al., 2013). After scan and analysis, we found 40 specific CNVs and one copy number neutral
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LOH region located in the X chromosome from the patient’s tumor tissue; however,
most of the identified regions were known to have common CNVs in the Database of Genomic Variants. There was no overlap between our result and the regions reported
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by Pansuriya et al. (2011a). Compared with the results of Amyere et al.(2014), we
found one somatic alteration localized in chromosome 14 (14q13.1) near to 14q11.2;
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and three somatic alterations localized in chromosome 2 (2q21.2-21.3, 2p15, 2q33.2) however, far away from 2p22.3 and 2q24.3. Ninety-five known genes were included in the CNV and LOH regions. According to the information published by OMIM, neither genes related to IDH1/IDH2, nor genes associated with angiogenesis,
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chondroma formation, growth or sexual characteristics were found, except for CHEK2 (604373) and EP300 (602700) , which have been reported to play important roles in tumorigenesis.
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CHK2, a protein kinase that is activated in response to DNA damage, is involved
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in cell cycle arrest. In addition to the relationship between somatic mutation of CHEK2 and osteosarcoma (259500), large sample clinical trials have found germline and somatic CHEK2 mutations in both sporadic and familial prostate cancer, suggesting that CHEK2 mutations may contribute to the development of prostate cancer through the reduction of CHK2 activation in response to DNA damage and/or oncogenic stress (Dong et al., 2003; Wu et al., 2006). Furthermore, Schutte et al. (2003) and Meijers-Heijboer et al. (2003) found the 1100delC in CHEK2 makes an appreciable contribution to breast and colorectal cancer susceptibility. The EP300
ACCEPTED MANUSCRIPT gene encodes p300, a histone acetyltransferase that regulates transcription via chromatin remodeling and is important in the processes of cell proliferation and differentiation (Gayther et al., 2000). Gayther et al. found that the EP300 gene had mutated in epithelial cancers (colorectal cancer and breast cancer) as well as cancer
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cell lines (colorectal, breast, and pancreatic) and provided the first evidence that it behaved as a classic tumor suppressor gene. Thereafter, Pasqualucci et al. (2011)
found that some patients with diffuse large B-cell lymphoma and follicular lymphoma
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displayed genomic deletions and/or somatic mutations in the EP300 gene. Recently, Le Gallo et al. (2012) identified somatic mutation in the EP300 gene in 13 primary
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serous endometrial tumors and 40 additional serous tumors. However, further research is needed to determine whether or not these two genes play a role in the development of enchondromas and hemangiomas. Conclusion
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No genetic study of an Asian patient with Maffucci syndrome had previously been reported. Here, for the first time, we detected genetic variations in hemangioma tissue and blood from a Chinese patient with Maffucci syndrome. No known pathogenic
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mutation was found in the IDH1 or IDH2 genes in the hemangioma sample.
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Additionally, we found 40 tumor-specific CNVs and 1 LOH region using Affymetrix CytoScan HD array. CHEK2 and EP300 might be the causative genes, this needs further confirmation. Our data enriches the understanding of the genetic background of Maffucci syndrome in different ethnic groups.
ACCEPTED MANUSCRIPT Competing interests The authors declare that they have no competing interests. Authors' contributions XD critically revised the manuscript, contributed to the study design, analysis, and
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supervised the research. YY coordinated clinical diagnosis, collected phenotype
information and contributed to the study design. YX drafted and critically revised the manuscript, performed the statistical analyses and the interpretation of the data. MZ
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performed the blood collection and DNA extraction. JN performed IDH1 and IDH2 mutation analysis. WW coordinated clinical diagnosis and collected phenotype
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information. YL coordinated histologic investigation and the description. All authors read and approved the final manuscript. Acknowledgments
We are thankful for the agreement of the patient and her family members for
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joining in this research.
ACCEPTED MANUSCRIPT References Amary MF, Damato S, Halai D, Eskandarpour M, Berisha F, Bonar F, et al.: Ollier disease and Maffucci syndrome are caused by somatic mosaic mutations of
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IDH1 and IDH2. Nat Genet 43: 1262-1265, 2011 Amyere M, Dompmartin A, Wouters V, Enjolras O, Kaitila I, Docquier PL, et al.: Common somatic alterations identified in Maffucci syndrome by molecular
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karyotyping. Mol Syndromol 5: 259-267, 2014
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Biber C, Ergun P, Turay UY, Erdogan Y, Hizel SB: A case of Maffucci 's syndrome with pleural effusion: ten-year follow-up. Ann Acad Med Singapore 33: 347-350, 2004
Cai Y, Wang R, Chen XM, Zhao YF, Sun ZJ, Zhao JH.: Maffucci syndrome with the
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spindle cell hemangiomas in the mucosa of the lower lip: a rare case report and literature review. J Cutan Pathol 40: 661-666, 2013 Chen W, Yuan L, Cai Y, Chen X, Chi Y, Wei P, et al.: Identification of chromosomal
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copy number variations and novel candidate loci in hereditary nonpolyposis
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colorectal cancer with mismatch repair proficiency. Genomics 102: 27-34, 2013 Couvineau A, Wouters V, Bertrand G, Rouyer C, Gerard B, Boon LM, et al.: PTHR1 mutations associated with Ollier disease result in receptor loss of function. Hum
Mol Genet 17: 2766-2775, 2008
Dong X, Wang L, Taniguchi K, Wang X, Cunningham JM, McDonnell SK, et al.: Mutations in CHEK2 associated with prostate cancer risk. Am J Hum Genet 72: 270-280, 2003
ACCEPTED MANUSCRIPT Gao H, Wang B, Zhang X, Liu F, Lu Y: Maffucci syndrome with unilateral limb: a case report and review of the literature. Chin J Cancer Res 25: 254-258, 2013 Gayther SA, Batley SJ, Linger L, Bannister A, Thorpe K, Chin SF, et al.: Mutations
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truncating the EP300 acetylase in human cancers. Nat Genet 24: 300-303, 2000 Iafrate AJ, Feuk L, Rivera MN, Listewnik ML, Donahoe PK, Qi Y, et al.: Detection of large-scale variation in the human genome. Nat Genet 36: 949-951, 2004
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Jasmine F, Rahaman R, Dodsworth C, Roy S, Paul R, Raza M, et al.: A genome-wide
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study of cytogenetic changes in colorectal cancer using SNP microarrays: opportunities for future personalized treatment. PLoS One 7: e31968, 2012 Jermann M, Eid K, Pfammatter T, Stahel R: Maffucci's syndrome. Circulation 104: 1693, 2001
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Le Gallo M, O'Hara AJ, Rudd ML, Urick ME, Hansen NF, O'Neil NJ, et al.: Exome sequencing of serous endometrial tumors identifies recurrent somatic mutations in chromatin-remodeling and ubiquitin ligase complex genes. Nat Genet 44:
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1310-1315, 2012
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Meijers-Heijboer H, Wijnen J, Vasen H, Wasielewski M, Wagner A, Hollestelle A, et al.: The CHEK2 1100delC mutation identifies families with a hereditary breast
and colorectal cancer phenotype. Am J Hum Genet 72: 1308-1314, 2003
Ono S, Tanizaki H, Fujisawa A, Tanioka M, Miyachi Y: Maffucci syndrome complicated with meningioma and pituitary adenoma. Eur J Dermatol 22:130-131, 2012 Pansuriya TC, Oosting J, Verdegaal SH, Flanagan AM, Sciot R, Kindblom LG, et al.:
ACCEPTED MANUSCRIPT Maffucci syndrome: a genome-wide analysis using high resolution single nucleotide polymorphism and expression arrays on four cases. Genes Chromosomes Cancer 50: 673-679, 2011a
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Pansuriya TC, van Eijk R, d'Adamo P, van Ruler MA, Kuijjer ML, Oosting J, et al.: Somatic mosaic IDH1 and IDH2 mutations are associated with enchondroma and spindle cell hemangioma in Ollier disease and Maffucci syndrome. Nat Genet 43:
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1256-1261, 2011b
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Pasqualucci L, Dominguez-Sola D, Chiarenza A, Fabbri G, Grunn A, Trifonov V, et al.: Inactivating mutations of acetyltransferase genes in B-cell lymphoma. Nature 471: 189-195, 2011
Rozeman LB, Sangiorgi L, Briaire-de Bruijn IH, Mainil-Varlet P, Bertoni F,
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Cleton-Jansen AM, et al., Enchondromatosis (Ollier disease, Maffucci syndrome) is not caused by the PTHR1 mutation p.R150C. Hum Mutat 24: 466-473, 2004 Sanjmyatav J, Junker K, Matthes S, Muehr M, Sava D, Sternal M, et al.: Identification
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of genomic alterations associated with metastasis and cancer specific survival in
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clear cell renal cell carcinoma. J Urol 186: 2078-2083, 2011 Schutte M, Seal S, Barfoot R, Meijers-Heijboer H, Wasielewski M, Evans DG, et al.: Variants in CHEK2 other than 1100delC do not make a major contribution to breast cancer susceptibility. Am J Hum Genet 72: 1023-1028, 2003
Veerappa AM, Vishweswaraiah S, Lingaiah K, Murthy M, Manjegowda DS, Nayaka R, et al.: Unravelling the complexity of human olfactory receptor repertoire by copy number analysis across population using high resolution arrays. PLoS One
ACCEPTED MANUSCRIPT 8: e66843, 2013 Wang Y, Yu Y, Hu X, Li B, Qian J: 22q11.2 Microduplication in a patient with 19p13.12-13.13 deletion. Gene 537:164-168, 2014
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cancer. Hum Mutat 27: 742-747, 2006
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Wu X, Dong X, Liu W, Chen J: Characterization of CHEK2 mutations in prostate
ACCEPTED MANUSCRIPT Figure legends Fig. 1 Clinical features of the patient: The patient had obvious submandibular swelling on anterior and lateral views (A–C); small vascular malformations on her
multiple vascular malformations on her hands and feet (I–N).
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ears (D and E), buccal mucosa (F) and tongue (G); unequal leg lengths (H); and
Fig. 2 Radiological features of the patient: (A–D) X-ray examination showed
multiple, irregularly shaped radiolucent areas with stippled calcification on bilateral
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pelvis and the left femur, humerus, ulna, radius, and index finger. It also showed that the long bones on her left side (including the femur, tibia, fibula, humerus, ulna and
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radius) were significantly shorter than on the right side. (E–G) Computed tomographic angiography (CTA) with three dimensional reconstruction showing the worm-eaten appearance of bone destruction involving the sternum, occipital bone, bilateral pelvis, scapula, ribs, humerus, radius and thumb, and left femur and index
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finger. (F and H) Both computed tomography (CT) and CTA showed an extensive soft tissue mass of about 6.4 × 4.5 × 7.0 cm in the submental area. Multiple punctate calcification in the mass and chin bone involvement also could be seen.
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Fig. 3 Histologic examination of the tumors: (A) Histological pattern of the
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hemangioma showing broad, thin-walled blood vessels, lined by a single layer of flat endothelial cells and filled with blood, within the skin dermis. (B) The enchondromas consist of abundant hyaline cartilage matrix. The chondrocytes are situated within lacunar spaces, have uniform small round nuclei, and finely granular, often vacuolated, eosinophilic cytoplasm. Fig. 4 Distribution of the copy number variations (CNVs) in chromosomes
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Table 1 Distribution of copy number variations (CNVs) in different categories Category of CNVs
No. of CNVs (gain/loss) 50 (21/29)
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Total CNVs from the patient’s tumor and blood samples
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CNVs from the patient’s tumor sample CNVs from the patient’s blood sample The patient’s tumor-specific CNVsa
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The patient’s tumor-specific CNVs means tumor CNVs not found in the patient’s blood sample.
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a
45 (18/27) 5 (3/2) 40 (15/25)
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Size Location
Start
CN
OMIM
a
End
Confidence
Genes
state
3540374
221.661 3Gainb
135130039
116.662 3Gain
10145295
10285183
139.888 3Gain
6q27
168207950
168353004
7q36.3
155439095
155568696
8p23.3
1797152
1885919
0.87145376
Cardiomyopathy, dilated, 1LL (615373) 605557 Left ventricular noncompaction 8 (615373)
ARHGEF16 MEGF6
604266
MIR551A
615148
MGAT5
601774
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135013377
4p16.1
0.8713892
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2q21.2-21.3c
3318713
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PRDM16
1p36.32
Phenotype (MIM number)
number
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(kbp)
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Table 2 Regions with the patient’s tumor-specific copy number variations (CNVs)
0.8776457
145.054 3Gain
0.87163925
C6ORF124
129.601 3Gain
0.8785316
RBM33
88.767 3Gain
0.87061596
ARHGEF10
608136
Slowed nerve conduction velocity (608236)
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8p11.22
39247097
39386952
139.855 3Gain
0.878297
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ADAM5P ADAM3A 49882699
50010018
127.319 3Gain
0.8694517
WDFY4
10q26.3
131362146
131465557
103.411 3Gain
0.8731973
MGMT
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10q11.22
KCNQ1
2641128
2696586
55.458 3Gain
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2425429
52685758
2510942
52837735
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12p13.33
85.513 3Gain
151.977 3Gain
156569 Atrial fibrillation, familial, 3 (607554) Jervell and Lange-Nielsen syndrome (220400) 607542 Long QT syndrome-1 (192500)
0.8749602
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11p15.5
613316
0.86910707
Short QT syndrome-2 (609621)
KCNQ1OT1
CACNA1C
604115
Beckwith–Wiedemann syndrome (130650)
Timothy syndrome (601005) 114205 Brugada syndrome 3 (611875)
0.86786515
KRT86
601928
Monilethrix (158000)
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KRT83
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KRT85
602765
KRT84
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KRT82
Xp22.13
2p15 c 2q33.2 c
112823735
110.9 3Gain
0.8745371
34954712
35140658
185.946 3Gain
0.8710344
17712240
17768581
61717371
61832387
204090886
204212172
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18q12.2
112712835
56.341 3Gain
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13q34
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KRT75
0.86663646
SOX1 CELF4
NHS
Monilethrix (158000) Ectodermal dysplasia 4, hair/nail type
602767
(602032)
602766 601078 Pseudofolliculitis barbae, susceptibility to 609025 (612318) 602148 612679 Nance–Horan syndrome (302350) 300457 Cataract 40, X-linked (302200)
115.016 1Lossd
0.85956013
XPO1
121.286 1Loss
0.8628381
CYP20A1
602559
ACCEPTED MANUSCRIPT
606442
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ABI2 DNAH12
3p14.3
57508034
57642045
134.011 1Loss
0.86074513
SC
PDE12
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ARF4
603340
601177
FAM116A
37230368
49552685
37414508
3436.616 1Loss
0.88519186
184.14 1Loss
7q22.3
77257686
104948315
77349918
105095529
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7q11.23
92.232 1Loss
147.214 1Loss
C5ORF42
614571
NUP155
606694
Joubert syndrome 17 (614615)
0.8529884
EP
5p13.2
46116069
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5p11- q11.1
WDR70 MLLT4
159559
PTPN12
600079
0.8564842 RSBN1L 0.85920143
SRPK2
602980
Colon cancer (114500)
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Hemolytic anemia due to glutathione 30593771
74.973 1Loss
0.86142105
48709714
48925789
216.075 1Loss
0.88030905
11p11.12
50434607
51377161
942.554 1Loss
0.868982
11p11.12- q11
51581310
55039996
3458.686 1Loss
0.8715354
12q11-12
37959560
38428116
468.556 1Loss
0.8734972
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7937572
112.579 1Loss
reductase deficiency
TRIM48
GDF3
Klippel–Feil syndrome 3 (613702) 606522
Microphthalmia with coloboma 6 (613703) Microphthalmia, isolated 7 (613704)
0.8595156
EP
7824993
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12p13.31
138300
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11p11.2
GSR
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30518798
SC
8p12
DPPA3
608408
CLEC4C
606677
NANOGNB
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WNK1 1019260
1073052
53.792 1Loss
0.8710307
SC
12p13.33
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Neuropathy, hereditary sensory and
RAD52
14q13.1e
34930992
35067437
136.445 1Loss
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C14OFR147
0.862398
EAPP
17q23.2
59933393
49265359
59998268
71.483 1Loss
0.85486627
EP
49193876
AC C
17q21.33
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SNX6
64.875 1Loss
0.8602244
SPAG9 NME1 NME2
605232
autonomic, type II (201300) Pseudohypoaldosteronism, type IIC (614492)
600392 613540 609486 606098 605430 156490
Neuroblastoma (256700)
156491
MBTD1
BRIP1
Fanconi anemia, complementation group J 605882 (609054)
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INTS2
41019892
41078204
58.312 1Loss
0.86675566
606078
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36867803
90.818 1Loss
MYH9
Macrothrombocytopenia and progressive sensorineural deafness (600208) May–Hegglin anomaly (155100) 160775
Fechtner syndrome (153640)
0.8657487 Deafness, autosomal dominant 17 (603622)
EP
36776985
AC C
22q12.3
Megakaryoblastic leukemia, acute
MCHR1
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22q13.2
611346
SC
MKL1
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Breast cancer, early onset (114480)
Sebastian syndrome (605249) Epstein syndrome (153650) TXN2
609063
ACCEPTED MANUSCRIPT
SNAP29 21197828
21254889
57.061 1Loss
0.86194324
SC
22q11.21
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Cerebral dysgenesis, neuropathy, ichthyosis,
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PI4KA
29252732
237.825 1Loss
(609528)
Breast and colorectal cancer, susceptibility to Prostate cancer, familial, susceptibility to (176807) 604373 Breast cancer, susceptibility to (114480) Osteosarcoma, somatic (259500)
0.8577769
EP
29014907
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22q12.1
and palmoplantar keratoderma syndrome
600286
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CHEK2f
604202
Li–Fraumeni syndrome (609265) XBP1
Major affective disorder-7, susceptibility to 194355 (612371)
HSCB
608142
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TTC28
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615098
CCDC117
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SC
EP300 f
XPNPEP3
22q13.2
41288061
41499651
211.59 1Loss
TE D 58428644
61923701
3495.057 1Loss
0.8884171
Xp22.33
1211761
1358900
AC C
EP
Xp11.1
0.8741655
Xq25
122899948
123020078
147.139 1Loss
120.13 1Loss
602700
Rubinstein–Taybi syndrome (613684) Nephronophthisis-like nephropathy 1 613553 (613159)
0.8607409
RBX1
0.8740075
MIR128-1 SCML1
CRLF2
XIAP
Colorectal cancer, somatic (114500)
603814 611774 300227
300357 Lymphoproliferative syndrome X-linked 2 300079 (300635)
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Confidence: An indicator of the likelihood that the segment represents a real change in that region of the genome and is a measure of how likely
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a
the data fits the assigned state for that marker; b3Gain means heterozygous duplication; cSomatic alterations localized in chromosome 2, however
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far away from 2p22.3 and 2q24.3, reported by Amyere et al., 2014; d1Loss means heterozygous loss; eSomatic alteration localized in
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chromosome 14 (14q13.1) nearby 14q11.2, reported by Amyere et al., 2014; fSomatic mutations in these genes may play a role in tumorigenesis.
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OMIM: Online Mendelian Inheritance in Man.
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No. of LOH
Total CNVs from the patient’s tumor and blood samples
11
LOH from the patient’s tumor sample
6
LOH from the patient’s blood sample
5
The patient’s tumor-specific LOHa
1
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The patient’s tumor-specific LOH means tumor LOH not found in the patient’s blood samples.
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a
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Category of LOH
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Table 3 Distribution of copy number neutral loss of heterozygosity (LOH) in different categories
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Size Start
End
Confidence
Genes
(kbp)
number 300277
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IL1RAPL2 TEX13A
300312
NRK
300791 314200
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SERPINA7 MUM1L1
107407242
3174.65
1
CXORF57
EP
104232592
RNF128
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Xq22.3
300439
TBC1D8B RIPPLY1 CLDN2
Phenotype (MIM number)
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Location
OMIM
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Table 4 Regions with the patient’s tumor-specific copy number neutral loss of heterozygosity (LOH)
300575 300520
Thyroxine-binding globulin deficiency
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MORC4 RBM41
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CXORF41
SC
NUP62CL
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TSC22D3 MID2 TEX13B
Deafness X-linked 1 (304500) Arts syndrome (301835)
311850
Gout, PRPS-related (300661) Phosphoribosylpyrophosphate synthetase superactivity
EP
TE D
PRPS1
Charcot-Marie-Tooth disease, X-linked recessive, 5 (311070)
(300661) 300506 300204 300313
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ATG4A
300663 303631
AC C
EP
TE D
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COL4A6
300880
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PSMD10
300620
SC
VSIG1
Leiomyomatosis, diffuse, with Alport syndrome (308940)
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No. of patients tested
mutation positive
with hemangioma
(%)
sample
10
6 (60.0%)
Male
14
12 (85.7%)
Total
24
18 (75.0%)
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Female
IDH1-R132C
mutation positive
SC
IDH1-R132C
(%)
7
4 (57.1%)
7
6 (85.7)
14
10 (71.4%)
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No. of patients
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Table 5 The relationship between IDH1-R132C mutation state and gender of patients with Maffucci syndrome
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The information was summarized from the following literature: Amary et al., 2011; Amyere et al., 2014; Pansuriya et al., 2011b
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EP
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M AN U
SC
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EP
TE D
M AN U
SC
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ACCEPTED MANUSCRIPT
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EP
TE D
M AN U
SC
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EP
TE D
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SC
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S1010-5182(15)00160-2
DOI:
10.1016/j.jcms.2015.05.017
Reference:
YJCMS 2069
To appear in:
Journal of Cranio-Maxillo-Facial Surgery
Received Date: 7 January 2015 Revised Date:
25 May 2015
Accepted Date: 26 May 2015
Please cite this article as: Xue Y, Ni J, Zhou M, Wang W, Liu Y, Yang Y, Duan X, Genetic variation analysis in a Chinese Maffucci syndrome patient, Journal of Cranio-Maxillofacial Surgery (2015), doi: 10.1016/j.jcms.2015.05.017. 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 Genetic variation analysis in a Chinese Maffucci syndrome patient Yang Xuea MD, Jinwen Nia MS, Mi Zhoua MS, Weiqi Wangb MS, Yuan Liuc MD, Yaowu Yangb,* MD, Xiaohong Duana,* PHD a: State Key Laboratory of Military Stomatology, Department of Oral Biology, Clinic
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of Oral Rare and Genetic Diseases, School of Stomatology, the Fourth Military Medical University, 145 West Changle Road, Xi’an 710032, P. R. China
b: State Key Laboratory of Military Stomatology, Department of Oral and
145 West Changle Road, Xi’an 710032, P. R. China
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Maxillofacial Surgery, School of Stomatology, the Fourth Military Medical University,
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c: State Key Laboratory of Military Stomatology, Department of Oral Histology and Pathology, School of Stomatology, the Fourth Military Medical University, 145 West Changle Road, Xi’an 710032, P. R. China *Corresponding authors:
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Xiaohong Duan, Ph.D, Professor
State Key Laboratory of Military Stomatology, Department of Oral Biology, Clinic of Oral Rare and Genetic Diseases, School of Stomatology, the Fourth Military Medical
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University, 145 West Changle Road, Xi’an 710032, P. R. China
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Tel: 86-29-84776169;Fax: 86-29-84776169;E-mail: [email protected] Yaowu Yang, MD, Professor State Key Laboratory of Military Stomatology, Department of Oral and Maxillofacial Surgery, School of Stomatology, the Fourth Military Medical University, 145 West Changle Road, Xi’an 710032, P. R. China Tel: 86-29-84772503;Fax: 86-29-84772503;E-mail: [email protected] Sources of grants: This work was supported in part by grants of the National Natural Science Foundation
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of China [81470728 (XD), 81271116 (XD), 81470757(YY)].
ACCEPTED MANUSCRIPT Abstract Objective: To report on the molecular genetic analysis of a Chinese patient with Maffucci syndrome. Methods: Using the genomic DNA extracted from the patient’s hemangioma sample,
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the coding exons and exon/intron splice junctions of the IDH1 and IDH2 genes were amplified by polymerase chain reaction (PCR) and then sequenced. Genomic DNA
was extracted from blood and a hemangioma sample from the patient, and also from
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her mother’s blood, for chromosome microarray analysis (CMA) by Affymetrix CytoScan HD array.
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Results: None of the known pathogenic mutations in the whole IDH1 or IDH2 genes was found in the patient’s hemangioma sample. CMA detected 40 tumor-specific copy number variations (CNVs), and one copy number neutral loss of heterozygosity (LOH) region. Among the 73 known genes included in the 40 CNV regions, only 2 genes,
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CHEK2 (604373) located in 22q12.1 and EP300 (602700) located in 22q13.2, were found to be related to tumorigenesis. We did not find any CNVs at the IDH1 and IDH2 loci.
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Conclusions: This is the first molecular genetic analysis report on a Chinese patient
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with Maffucci syndrome and our data enrich the understanding of the genetic background of Maffucci syndrome in different ethnic groups. The relationship between CHEK2, EP300 and Maffucci syndrome needs to be further explored. Keywords: copy number variation, IDH1, IDH2, Maffucci syndrome, microarray analysis
ACCEPTED MANUSCRIPT Introduction Maffucci syndrome is a rare, nonhereditary and congenital mesodermal dysplasia, characterized by a combination of multiple enchondromas and hemangiomas (Pansuriya et al., 2011a). It was first described in 1881 by Maffucci, and about 200
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cases have been described in the literature to date (Cai et al., 2013; Ono et al., 2012). There is neither sex preponderance nor a difference in incidence among races (Amary et al., 2011; Gao et al., 2013; Jermann et al., 2001).
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In recent years, the genetic background of Maffucci syndrome has drawn great
attention. It has been reported that somatic mosaic isocitrate dehydrogenase 1 (IDH1)
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and IDH2 mutations are associated with enchondromas and spindle cell hemangiomas in Maffucci syndrome (Amary et al., 2011; Amyere et al., 2014; Pansuriya et al., 2011b). Here, we report on a Chinese female patient affected by Maffucci syndrome, with no somatic mosaic IDH1 or IDH2 mutations found in a hemangioma sample. A
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high-resolution Affymetrix CytoScan HD Array was used to detect the possible related copy number variation (CNV) as well as copy number neutral loss of heterozygosity (LOH).
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Patient data
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Materials and methods
At first presentation, the patient was 18 years old; she weighed 40 kg and was 126
cm tall. Her left leg was 20 cm shorter than her right leg, while her left arm was 10 cm shorter than her right arm. She was born to non-consanguineous and healthy parents. Her mother had a history of two spontaneous abortions, and the patient was born at 28 weeks with no specified cause for the premature birth. She had a healthy younger brother. She complained of a progressive but painless mass in the submental area for more than 2 years. The patient’s leg lengths had been unequal since she was
ACCEPTED MANUSCRIPT one year old, and she had significantly enlarged limbs and joints and multiple purple lesions on her hands and feet since she was 3 years old (Fig.1). The symptoms gradually worsened with age. Her first menstrual period was at 18 years old; her periods were irregular with small amounts of bleeding.
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Radiographs showed multiple, irregularly shaped radiolucent areas with stippled calcification on bilateral pelvis and the left femur, humerus, ulna, radius, and index
finger (Fig.2 A–D). The long bones on the left side of her body (including the femur,
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tibia, fibula, humerus, ulna and radius) were significantly shorter than those on the right. Computed tomographic angiography (CTA) with three dimensional
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reconstruction displayed the worm-eaten appearance of bone destruction involving the sternum, occipital bone, bilateral pelvis, scapula, ribs, humerus, radius and thumb, and left femur and index finger (Fig.2 E–G). Both computed tomography (CT) and CTA showed an extensive soft tissue mass of about 6.4 × 4.5 × 7.0 cm in the submental
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area. Multiple punctate calcification in the mass and bone involvement of the chin could also be seen (Fig.2 F and H).
The subcutaneous lesions in her hands and feet were diagnosed as venous
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malformation by physical examination and Doppler ultrasonography. No obvious
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change was found in the comprehensive metabolic panel (including general tests, electrolytes, and assessment of renal and hepatic function). Pathological examination after surgical resection of part of the lesions showed that the lesions in the tongue and submental area were venous malformations (Fig.3 A); and a biopsy showed that the lesion in the left humerus was an enchondroma (Fig.3 B). On the basis of these findings – the development of multiple enchondromas in the extremities and the presence of subcutaneous vascular lesions – the diagnosis of Maffucci syndrome was established.
ACCEPTED MANUSCRIPT With written informed consent, the patient and her mother were included in this study. The study was authorized by the Ethics Committee, School of Stomatology, the Fourth Military Medical University, Xi’an, China. Genomic DNA preparation
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Blood and fresh hemangioma samples were obtained from the patient. Genomic DNA (gDNA) was extracted using QIAamp DNA blood and a tissue mini kit, respectively (Qiagen Inc., Chatsworth, CA, USA).
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IDH1 and IDH2 mutation analysis
Using the gDNA extracted from the patient’s hemangioma sample, the coding
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exons and exon/intron splice junctions of the IDH1 and IDH2 genes were amplified by polymerase chain reaction (PCR). Primers and PCR amplification conditions were previously described (Amary et al., 2011). PCR products were purified with DNA Fragment Quick Purification/Recover Kit (DingGuo, Beijing, China) and sequenced
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with an ABI 377 Sequencer (Perkin-Elmer Corp., Norwalk, Conneticut, USA). Sequence variants were identified using DNAStar, MegAlign 5.01 (Demonstration System DNASTAR, Inc., Madison, USA).
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Single-nucleotide polymorphism (SNP) array analysis
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Genomic DNA was extracted from the patient’s blood and hemangiomas for chromosome microarray analysis (CMA) by Affymetrix CytoScan HD array (Affymetrix, Inc., Santa Clara, CA, USA). Hybridizations were performed according to the manufacturer’s protocols. The data obtained were analyzed using the Chromosome Analysis Suite software package (Affymetrix, Inc., Santa Clara, CA, USA). Gene annotation and gene overlap were determined using the human genome build 19 (hg19). All the identified CNVs were compared with those reported in the Database of Genomic Variants (DGV, http://projects.tcag.ca/variation/).
ACCEPTED MANUSCRIPT Results IDH1 and IDH2 mutation analysis Neither IDH1-R132C/IDH2-R172S nor other mutations in the whole of the IDH1 or IDH2 genes were found in the patient’s hemangioma sample.
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Results of CytoSan HD array
Both the analyzed tumor and the blood samples had chromosomal aberrations. A summary of the CNVs in different categories and detailed information are presented
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in Tables 1 and 2, respectively. We found 15 regions with copy number gain and 25 regions with copy number loss in the patient’s hemangioma tissue when compared
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with the patient’s or her mother’s blood samples. Distribution of the CNVs in chromosomes was shown in Fig 4. Chromosome 22 exhibited the most frequent losses (20%); and chromosome X represented 6.7% of all gains and 12% of all losses. Most of the identified regions were known to have common CNV in the Database of
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Genomic Variants. Seventy-three known genes were included in the 40 regions, while 25 were found to be related to human disease (Table 2). In particular, somatic mutations in CHEK2 (604373) located in 22q12.1 and EP300 (602700) located in
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22q13.2 may play an important role in osteosarcoma (259500) and colorectal cancer
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(114500). We did not see any CNVs at the IDH1 and IDH2 loci. A summary of the LOH in different categories is presented in Table 3. We also
found an LOH region (Xq22.3 104232592-107407242) positive in the patient’s tumor tissue but negative in the patient’s blood sample (Table 4). After analysis, we found that the patient’s tumor-specific copy number neutral LOH located in Xq22.3 was caused by maternal uniparental disomy (data was not shown). Two of the 22 known genes in this region are related to human disease. Discussion
ACCEPTED MANUSCRIPT The typical clinical presentation of Maffucci syndrome includes multiple enchondromas and vascular lesions, which are commonly associated with phleboliths (Biber et al., 2004; Cai et al., 2013). It can be diagnosed relatively easily solely on clinical grounds (Gao et al., 2013). The diagnosis of Maffucci syndrome was
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established for the present patient on the basis of her typical presentation and pathological examination.
In recent years, the genetic background of Maffucci syndrome has attracted much
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attention. Parathyroid hormone receptor type 1 (PTHR1) gene mutation was screened for in leukocyte and/or tumor DNA samples from 30 Maffucci syndrome patients, but
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none was detected (Couvineau et al., 2008; Pansuriya et al., 2011a; Rozeman et al., 2004). Other genes involved in the IHH–PTHLH (Indian hedgehog–parathyroid hormone-like hormone) pathway, including parathyroid hormone related protein (PTHrP); Indian hedgehog (IHH); and guanine nucleotide binding protein, alpha
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stimulating activity polypeptide 1 (GNAS1); were tested in one Maffucci syndrome patient, but no mutation was found (Couvineau et al., 2008). Recently, somatic mosaic mutations in the gene encoding IDH1 and IDH2 were found to be associated with
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enchondromas and spindle cell hemangiomas in Ollier disease and Maffucci
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syndrome (Amary et al., 2011; Amyere et al., 2014; Pansuriya et al., 2011b). According to these reports, 18 out of 24 tested patients (75.0%) carried IDH1 mutation rather than IDH2, and IDH1-R132C was the only hotspot mutation (Table 5). The mutation was absent in the DNA from patients' blood, muscle or saliva (Pansuriya et al., 2011b). With an analysis of the published data on the tested hemangioma DNA samples of Maffucci syndrome patients (Amary et al., 2011; Amyere et al., 2014; Pansuriya et al., 2011b), we found that 4 out of 7 female patients (57.1%) and 6 out of 7 male patients (85.7%) carried an IDH1-R132C mutation. In
ACCEPTED MANUSCRIPT total, 10 out of 14 patients (71.4%) carried it (Table 5). We analyzed all the coding exons and intron–exon junctions of the IDH1 and IDH2 genes in the hemangioma DNA sample from our patient; however, neither the hotspot mutation nor any other known pathogenic mutation could be detected. Further research is needed to
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determine whether or not the IDH1-R132C mutation in hemangiomas from Mafucci syndrome patients has male predominance, because the number of tested patients is still limited.
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Recently, CNV has been recognized as one of the most important genomic
alterations that plays a role in cancer pathogenesis (Iafrate et al., 2004). In addition,
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somatic CNVs can be used to identify regions of the genome that are involved in disease phenotypes (Chen et al., 2013; Jasmine et al., 2012; Sanjmyatav et al., 2011). Though genome-wide analysis of CNV and LOH using Affymetrix SNP 6.0 array on enchondromas and chondrosarcomas from four Maffucci syndrome patients was
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reported (Pansuriya et al., 2011a), the causative gene was not identified. Using the Affymetrix SNP 6.0 array, recent research which included nine frozen tumor samples from patients with Maffucci syndrome found that the most frequently encountered
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somatic alterations were localized in 2p22.3, 2q24.3 and 14q11.2 (Amyere et al.,
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2014). Here, we report the first genome-wide analysis using Affymetrix CytoScan HD Array on hemangioma and blood samples from a Chinese patient with Maffucci syndrome. The Affymetrix CytoScan HD Array (a CNV-targeted array) is based on the validated Genome-Wide Human SNP Array 6.0 and characterized by 2.6 million CNV markers including approximately 750,000 genotype-able SNP probes and 1,900,000 non-polymorphism probes, with the median inter-marker distance of 500–600 bases (Wang et al., 2014). In addition, this chip provides allelic imbalance information from SNPs. It has great power to detect known and novel chromosome
ACCEPTED MANUSCRIPT aberrations across the entire human genome and features unbiased whole-genome coverage, with the highest physical coverage of the genome (Chen et al., 2013; Veerappa et al., 2013). After scan and analysis, we found 40 specific CNVs and one copy number neutral
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LOH region located in the X chromosome from the patient’s tumor tissue; however,
most of the identified regions were known to have common CNVs in the Database of Genomic Variants. There was no overlap between our result and the regions reported
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by Pansuriya et al. (2011a). Compared with the results of Amyere et al.(2014), we
found one somatic alteration localized in chromosome 14 (14q13.1) near to 14q11.2;
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and three somatic alterations localized in chromosome 2 (2q21.2-21.3, 2p15, 2q33.2) however, far away from 2p22.3 and 2q24.3. Ninety-five known genes were included in the CNV and LOH regions. According to the information published by OMIM, neither genes related to IDH1/IDH2, nor genes associated with angiogenesis,
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chondroma formation, growth or sexual characteristics were found, except for CHEK2 (604373) and EP300 (602700) , which have been reported to play important roles in tumorigenesis.
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CHK2, a protein kinase that is activated in response to DNA damage, is involved
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in cell cycle arrest. In addition to the relationship between somatic mutation of CHEK2 and osteosarcoma (259500), large sample clinical trials have found germline and somatic CHEK2 mutations in both sporadic and familial prostate cancer, suggesting that CHEK2 mutations may contribute to the development of prostate cancer through the reduction of CHK2 activation in response to DNA damage and/or oncogenic stress (Dong et al., 2003; Wu et al., 2006). Furthermore, Schutte et al. (2003) and Meijers-Heijboer et al. (2003) found the 1100delC in CHEK2 makes an appreciable contribution to breast and colorectal cancer susceptibility. The EP300
ACCEPTED MANUSCRIPT gene encodes p300, a histone acetyltransferase that regulates transcription via chromatin remodeling and is important in the processes of cell proliferation and differentiation (Gayther et al., 2000). Gayther et al. found that the EP300 gene had mutated in epithelial cancers (colorectal cancer and breast cancer) as well as cancer
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cell lines (colorectal, breast, and pancreatic) and provided the first evidence that it behaved as a classic tumor suppressor gene. Thereafter, Pasqualucci et al. (2011)
found that some patients with diffuse large B-cell lymphoma and follicular lymphoma
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displayed genomic deletions and/or somatic mutations in the EP300 gene. Recently, Le Gallo et al. (2012) identified somatic mutation in the EP300 gene in 13 primary
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serous endometrial tumors and 40 additional serous tumors. However, further research is needed to determine whether or not these two genes play a role in the development of enchondromas and hemangiomas. Conclusion
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No genetic study of an Asian patient with Maffucci syndrome had previously been reported. Here, for the first time, we detected genetic variations in hemangioma tissue and blood from a Chinese patient with Maffucci syndrome. No known pathogenic
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mutation was found in the IDH1 or IDH2 genes in the hemangioma sample.
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Additionally, we found 40 tumor-specific CNVs and 1 LOH region using Affymetrix CytoScan HD array. CHEK2 and EP300 might be the causative genes, this needs further confirmation. Our data enriches the understanding of the genetic background of Maffucci syndrome in different ethnic groups.
ACCEPTED MANUSCRIPT Competing interests The authors declare that they have no competing interests. Authors' contributions XD critically revised the manuscript, contributed to the study design, analysis, and
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supervised the research. YY coordinated clinical diagnosis, collected phenotype
information and contributed to the study design. YX drafted and critically revised the manuscript, performed the statistical analyses and the interpretation of the data. MZ
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performed the blood collection and DNA extraction. JN performed IDH1 and IDH2 mutation analysis. WW coordinated clinical diagnosis and collected phenotype
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information. YL coordinated histologic investigation and the description. All authors read and approved the final manuscript. Acknowledgments
We are thankful for the agreement of the patient and her family members for
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joining in this research.
ACCEPTED MANUSCRIPT References Amary MF, Damato S, Halai D, Eskandarpour M, Berisha F, Bonar F, et al.: Ollier disease and Maffucci syndrome are caused by somatic mosaic mutations of
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IDH1 and IDH2. Nat Genet 43: 1262-1265, 2011 Amyere M, Dompmartin A, Wouters V, Enjolras O, Kaitila I, Docquier PL, et al.: Common somatic alterations identified in Maffucci syndrome by molecular
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karyotyping. Mol Syndromol 5: 259-267, 2014
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Biber C, Ergun P, Turay UY, Erdogan Y, Hizel SB: A case of Maffucci 's syndrome with pleural effusion: ten-year follow-up. Ann Acad Med Singapore 33: 347-350, 2004
Cai Y, Wang R, Chen XM, Zhao YF, Sun ZJ, Zhao JH.: Maffucci syndrome with the
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spindle cell hemangiomas in the mucosa of the lower lip: a rare case report and literature review. J Cutan Pathol 40: 661-666, 2013 Chen W, Yuan L, Cai Y, Chen X, Chi Y, Wei P, et al.: Identification of chromosomal
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copy number variations and novel candidate loci in hereditary nonpolyposis
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colorectal cancer with mismatch repair proficiency. Genomics 102: 27-34, 2013 Couvineau A, Wouters V, Bertrand G, Rouyer C, Gerard B, Boon LM, et al.: PTHR1 mutations associated with Ollier disease result in receptor loss of function. Hum
Mol Genet 17: 2766-2775, 2008
Dong X, Wang L, Taniguchi K, Wang X, Cunningham JM, McDonnell SK, et al.: Mutations in CHEK2 associated with prostate cancer risk. Am J Hum Genet 72: 270-280, 2003
ACCEPTED MANUSCRIPT Gao H, Wang B, Zhang X, Liu F, Lu Y: Maffucci syndrome with unilateral limb: a case report and review of the literature. Chin J Cancer Res 25: 254-258, 2013 Gayther SA, Batley SJ, Linger L, Bannister A, Thorpe K, Chin SF, et al.: Mutations
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truncating the EP300 acetylase in human cancers. Nat Genet 24: 300-303, 2000 Iafrate AJ, Feuk L, Rivera MN, Listewnik ML, Donahoe PK, Qi Y, et al.: Detection of large-scale variation in the human genome. Nat Genet 36: 949-951, 2004
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Jasmine F, Rahaman R, Dodsworth C, Roy S, Paul R, Raza M, et al.: A genome-wide
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study of cytogenetic changes in colorectal cancer using SNP microarrays: opportunities for future personalized treatment. PLoS One 7: e31968, 2012 Jermann M, Eid K, Pfammatter T, Stahel R: Maffucci's syndrome. Circulation 104: 1693, 2001
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Le Gallo M, O'Hara AJ, Rudd ML, Urick ME, Hansen NF, O'Neil NJ, et al.: Exome sequencing of serous endometrial tumors identifies recurrent somatic mutations in chromatin-remodeling and ubiquitin ligase complex genes. Nat Genet 44:
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1310-1315, 2012
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Meijers-Heijboer H, Wijnen J, Vasen H, Wasielewski M, Wagner A, Hollestelle A, et al.: The CHEK2 1100delC mutation identifies families with a hereditary breast
and colorectal cancer phenotype. Am J Hum Genet 72: 1308-1314, 2003
Ono S, Tanizaki H, Fujisawa A, Tanioka M, Miyachi Y: Maffucci syndrome complicated with meningioma and pituitary adenoma. Eur J Dermatol 22:130-131, 2012 Pansuriya TC, Oosting J, Verdegaal SH, Flanagan AM, Sciot R, Kindblom LG, et al.:
ACCEPTED MANUSCRIPT Maffucci syndrome: a genome-wide analysis using high resolution single nucleotide polymorphism and expression arrays on four cases. Genes Chromosomes Cancer 50: 673-679, 2011a
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Pansuriya TC, van Eijk R, d'Adamo P, van Ruler MA, Kuijjer ML, Oosting J, et al.: Somatic mosaic IDH1 and IDH2 mutations are associated with enchondroma and spindle cell hemangioma in Ollier disease and Maffucci syndrome. Nat Genet 43:
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1256-1261, 2011b
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Pasqualucci L, Dominguez-Sola D, Chiarenza A, Fabbri G, Grunn A, Trifonov V, et al.: Inactivating mutations of acetyltransferase genes in B-cell lymphoma. Nature 471: 189-195, 2011
Rozeman LB, Sangiorgi L, Briaire-de Bruijn IH, Mainil-Varlet P, Bertoni F,
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Cleton-Jansen AM, et al., Enchondromatosis (Ollier disease, Maffucci syndrome) is not caused by the PTHR1 mutation p.R150C. Hum Mutat 24: 466-473, 2004 Sanjmyatav J, Junker K, Matthes S, Muehr M, Sava D, Sternal M, et al.: Identification
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of genomic alterations associated with metastasis and cancer specific survival in
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clear cell renal cell carcinoma. J Urol 186: 2078-2083, 2011 Schutte M, Seal S, Barfoot R, Meijers-Heijboer H, Wasielewski M, Evans DG, et al.: Variants in CHEK2 other than 1100delC do not make a major contribution to breast cancer susceptibility. Am J Hum Genet 72: 1023-1028, 2003
Veerappa AM, Vishweswaraiah S, Lingaiah K, Murthy M, Manjegowda DS, Nayaka R, et al.: Unravelling the complexity of human olfactory receptor repertoire by copy number analysis across population using high resolution arrays. PLoS One
ACCEPTED MANUSCRIPT 8: e66843, 2013 Wang Y, Yu Y, Hu X, Li B, Qian J: 22q11.2 Microduplication in a patient with 19p13.12-13.13 deletion. Gene 537:164-168, 2014
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cancer. Hum Mutat 27: 742-747, 2006
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Wu X, Dong X, Liu W, Chen J: Characterization of CHEK2 mutations in prostate
ACCEPTED MANUSCRIPT Figure legends Fig. 1 Clinical features of the patient: The patient had obvious submandibular swelling on anterior and lateral views (A–C); small vascular malformations on her
multiple vascular malformations on her hands and feet (I–N).
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ears (D and E), buccal mucosa (F) and tongue (G); unequal leg lengths (H); and
Fig. 2 Radiological features of the patient: (A–D) X-ray examination showed
multiple, irregularly shaped radiolucent areas with stippled calcification on bilateral
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pelvis and the left femur, humerus, ulna, radius, and index finger. It also showed that the long bones on her left side (including the femur, tibia, fibula, humerus, ulna and
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radius) were significantly shorter than on the right side. (E–G) Computed tomographic angiography (CTA) with three dimensional reconstruction showing the worm-eaten appearance of bone destruction involving the sternum, occipital bone, bilateral pelvis, scapula, ribs, humerus, radius and thumb, and left femur and index
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finger. (F and H) Both computed tomography (CT) and CTA showed an extensive soft tissue mass of about 6.4 × 4.5 × 7.0 cm in the submental area. Multiple punctate calcification in the mass and chin bone involvement also could be seen.
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Fig. 3 Histologic examination of the tumors: (A) Histological pattern of the
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hemangioma showing broad, thin-walled blood vessels, lined by a single layer of flat endothelial cells and filled with blood, within the skin dermis. (B) The enchondromas consist of abundant hyaline cartilage matrix. The chondrocytes are situated within lacunar spaces, have uniform small round nuclei, and finely granular, often vacuolated, eosinophilic cytoplasm. Fig. 4 Distribution of the copy number variations (CNVs) in chromosomes
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Table 1 Distribution of copy number variations (CNVs) in different categories Category of CNVs
No. of CNVs (gain/loss) 50 (21/29)
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Total CNVs from the patient’s tumor and blood samples
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CNVs from the patient’s tumor sample CNVs from the patient’s blood sample The patient’s tumor-specific CNVsa
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The patient’s tumor-specific CNVs means tumor CNVs not found in the patient’s blood sample.
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a
45 (18/27) 5 (3/2) 40 (15/25)
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Size Location
Start
CN
OMIM
a
End
Confidence
Genes
state
3540374
221.661 3Gainb
135130039
116.662 3Gain
10145295
10285183
139.888 3Gain
6q27
168207950
168353004
7q36.3
155439095
155568696
8p23.3
1797152
1885919
0.87145376
Cardiomyopathy, dilated, 1LL (615373) 605557 Left ventricular noncompaction 8 (615373)
ARHGEF16 MEGF6
604266
MIR551A
615148
MGAT5
601774
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135013377
4p16.1
0.8713892
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2q21.2-21.3c
3318713
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PRDM16
1p36.32
Phenotype (MIM number)
number
SC
(kbp)
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Table 2 Regions with the patient’s tumor-specific copy number variations (CNVs)
0.8776457
145.054 3Gain
0.87163925
C6ORF124
129.601 3Gain
0.8785316
RBM33
88.767 3Gain
0.87061596
ARHGEF10
608136
Slowed nerve conduction velocity (608236)
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8p11.22
39247097
39386952
139.855 3Gain
0.878297
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ADAM5P ADAM3A 49882699
50010018
127.319 3Gain
0.8694517
WDFY4
10q26.3
131362146
131465557
103.411 3Gain
0.8731973
MGMT
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10q11.22
KCNQ1
2641128
2696586
55.458 3Gain
EP 12q13.13
2425429
52685758
2510942
52837735
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12p13.33
85.513 3Gain
151.977 3Gain
156569 Atrial fibrillation, familial, 3 (607554) Jervell and Lange-Nielsen syndrome (220400) 607542 Long QT syndrome-1 (192500)
0.8749602
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11p15.5
613316
0.86910707
Short QT syndrome-2 (609621)
KCNQ1OT1
CACNA1C
604115
Beckwith–Wiedemann syndrome (130650)
Timothy syndrome (601005) 114205 Brugada syndrome 3 (611875)
0.86786515
KRT86
601928
Monilethrix (158000)
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KRT83
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KRT85
602765
KRT84
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KRT82
Xp22.13
2p15 c 2q33.2 c
112823735
110.9 3Gain
0.8745371
34954712
35140658
185.946 3Gain
0.8710344
17712240
17768581
61717371
61832387
204090886
204212172
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18q12.2
112712835
56.341 3Gain
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13q34
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KRT75
0.86663646
SOX1 CELF4
NHS
Monilethrix (158000) Ectodermal dysplasia 4, hair/nail type
602767
(602032)
602766 601078 Pseudofolliculitis barbae, susceptibility to 609025 (612318) 602148 612679 Nance–Horan syndrome (302350) 300457 Cataract 40, X-linked (302200)
115.016 1Lossd
0.85956013
XPO1
121.286 1Loss
0.8628381
CYP20A1
602559
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606442
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ABI2 DNAH12
3p14.3
57508034
57642045
134.011 1Loss
0.86074513
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PDE12
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ARF4
603340
601177
FAM116A
37230368
49552685
37414508
3436.616 1Loss
0.88519186
184.14 1Loss
7q22.3
77257686
104948315
77349918
105095529
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7q11.23
92.232 1Loss
147.214 1Loss
C5ORF42
614571
NUP155
606694
Joubert syndrome 17 (614615)
0.8529884
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5p13.2
46116069
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5p11- q11.1
WDR70 MLLT4
159559
PTPN12
600079
0.8564842 RSBN1L 0.85920143
SRPK2
602980
Colon cancer (114500)
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Hemolytic anemia due to glutathione 30593771
74.973 1Loss
0.86142105
48709714
48925789
216.075 1Loss
0.88030905
11p11.12
50434607
51377161
942.554 1Loss
0.868982
11p11.12- q11
51581310
55039996
3458.686 1Loss
0.8715354
12q11-12
37959560
38428116
468.556 1Loss
0.8734972
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7937572
112.579 1Loss
reductase deficiency
TRIM48
GDF3
Klippel–Feil syndrome 3 (613702) 606522
Microphthalmia with coloboma 6 (613703) Microphthalmia, isolated 7 (613704)
0.8595156
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7824993
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12p13.31
138300
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11p11.2
GSR
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30518798
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8p12
DPPA3
608408
CLEC4C
606677
NANOGNB
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WNK1 1019260
1073052
53.792 1Loss
0.8710307
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12p13.33
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Neuropathy, hereditary sensory and
RAD52
14q13.1e
34930992
35067437
136.445 1Loss
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C14OFR147
0.862398
EAPP
17q23.2
59933393
49265359
59998268
71.483 1Loss
0.85486627
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49193876
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17q21.33
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SNX6
64.875 1Loss
0.8602244
SPAG9 NME1 NME2
605232
autonomic, type II (201300) Pseudohypoaldosteronism, type IIC (614492)
600392 613540 609486 606098 605430 156490
Neuroblastoma (256700)
156491
MBTD1
BRIP1
Fanconi anemia, complementation group J 605882 (609054)
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INTS2
41019892
41078204
58.312 1Loss
0.86675566
606078
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36867803
90.818 1Loss
MYH9
Macrothrombocytopenia and progressive sensorineural deafness (600208) May–Hegglin anomaly (155100) 160775
Fechtner syndrome (153640)
0.8657487 Deafness, autosomal dominant 17 (603622)
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36776985
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22q12.3
Megakaryoblastic leukemia, acute
MCHR1
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22q13.2
611346
SC
MKL1
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Breast cancer, early onset (114480)
Sebastian syndrome (605249) Epstein syndrome (153650) TXN2
609063
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SNAP29 21197828
21254889
57.061 1Loss
0.86194324
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22q11.21
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Cerebral dysgenesis, neuropathy, ichthyosis,
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PI4KA
29252732
237.825 1Loss
(609528)
Breast and colorectal cancer, susceptibility to Prostate cancer, familial, susceptibility to (176807) 604373 Breast cancer, susceptibility to (114480) Osteosarcoma, somatic (259500)
0.8577769
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29014907
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22q12.1
and palmoplantar keratoderma syndrome
600286
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CHEK2f
604202
Li–Fraumeni syndrome (609265) XBP1
Major affective disorder-7, susceptibility to 194355 (612371)
HSCB
608142
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TTC28
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615098
CCDC117
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EP300 f
XPNPEP3
22q13.2
41288061
41499651
211.59 1Loss
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61923701
3495.057 1Loss
0.8884171
Xp22.33
1211761
1358900
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Xp11.1
0.8741655
Xq25
122899948
123020078
147.139 1Loss
120.13 1Loss
602700
Rubinstein–Taybi syndrome (613684) Nephronophthisis-like nephropathy 1 613553 (613159)
0.8607409
RBX1
0.8740075
MIR128-1 SCML1
CRLF2
XIAP
Colorectal cancer, somatic (114500)
603814 611774 300227
300357 Lymphoproliferative syndrome X-linked 2 300079 (300635)
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Confidence: An indicator of the likelihood that the segment represents a real change in that region of the genome and is a measure of how likely
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a
the data fits the assigned state for that marker; b3Gain means heterozygous duplication; cSomatic alterations localized in chromosome 2, however
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far away from 2p22.3 and 2q24.3, reported by Amyere et al., 2014; d1Loss means heterozygous loss; eSomatic alteration localized in
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chromosome 14 (14q13.1) nearby 14q11.2, reported by Amyere et al., 2014; fSomatic mutations in these genes may play a role in tumorigenesis.
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OMIM: Online Mendelian Inheritance in Man.
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No. of LOH
Total CNVs from the patient’s tumor and blood samples
11
LOH from the patient’s tumor sample
6
LOH from the patient’s blood sample
5
The patient’s tumor-specific LOHa
1
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The patient’s tumor-specific LOH means tumor LOH not found in the patient’s blood samples.
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a
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Category of LOH
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Table 3 Distribution of copy number neutral loss of heterozygosity (LOH) in different categories
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Size Start
End
Confidence
Genes
(kbp)
number 300277
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IL1RAPL2 TEX13A
300312
NRK
300791 314200
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SERPINA7 MUM1L1
107407242
3174.65
1
CXORF57
EP
104232592
RNF128
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Xq22.3
300439
TBC1D8B RIPPLY1 CLDN2
Phenotype (MIM number)
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Location
OMIM
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Table 4 Regions with the patient’s tumor-specific copy number neutral loss of heterozygosity (LOH)
300575 300520
Thyroxine-binding globulin deficiency
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MORC4 RBM41
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CXORF41
SC
NUP62CL
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TSC22D3 MID2 TEX13B
Deafness X-linked 1 (304500) Arts syndrome (301835)
311850
Gout, PRPS-related (300661) Phosphoribosylpyrophosphate synthetase superactivity
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PRPS1
Charcot-Marie-Tooth disease, X-linked recessive, 5 (311070)
(300661) 300506 300204 300313
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ATG4A
300663 303631
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COL4A6
300880
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PSMD10
300620
SC
VSIG1
Leiomyomatosis, diffuse, with Alport syndrome (308940)
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No. of patients tested
mutation positive
with hemangioma
(%)
sample
10
6 (60.0%)
Male
14
12 (85.7%)
Total
24
18 (75.0%)
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Female
IDH1-R132C
mutation positive
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IDH1-R132C
(%)
7
4 (57.1%)
7
6 (85.7)
14
10 (71.4%)
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No. of patients
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Table 5 The relationship between IDH1-R132C mutation state and gender of patients with Maffucci syndrome
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The information was summarized from the following literature: Amary et al., 2011; Amyere et al., 2014; Pansuriya et al., 2011b
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