Your search keyword '"Fuke, Tomoko"' showing total 7 results

1. Role of Imprinting Disorders in Short Children Born SGA and Silver-Russell Syndrome Spectrum.

Author

Tomoko Fuke, Akie Nakamura, Takanobu Inoue, Sayaka Kawashima, Kaori Isono Hara, Keiko Matsubara, Shinichiro Sano, Kazuki Yamazawa, Maki Fukami, Tsutomu Ogata, Masayo Kagami, Fuke, Tomoko, Nakamura, Akie, Inoue, Takanobu, Kawashima, Sayaka, Hara, Kaori Isono, Matsubara, Keiko, Sano, Shinichiro, Yamazawa, Kazuki, and Fukami, Maki

Subjects

PITUITARY dwarfism, CHROMOSOME duplication, FETAL growth retardation, DNA copy number variations, PATIENT compliance, COMPARATIVE genomic hybridization, RESEARCH, SEQUENCE analysis, CRANIOFACIAL abnormalities, RESEARCH methodology, SILVER-Russell syndrome, CASE-control method, GENETIC disorders, MEDICAL cooperation, EVALUATION research, HUMAN growth hormone, MULTIPLE human abnormalities, COMPARATIVE studies, GENES, CYTOGENETICS, SMALL for gestational age, DWARFISM, PHENOTYPES, DISEASE complications

Abstract

Background: (Epi)genetic disorders associated with small-for-gestational-age with short stature (SGA-SS) include imprinting disorders (IDs). Silver-Russell syndrome (SRS) is a representative ID in SGA-SS and has heterogenous (epi)genetic causes.Subjects and Methods: To clarify the contribution of IDs to SGA-SS and the molecular and phenotypic spectrum of SRS, we recruited 269 patients with SGA-SS, consisting of 103 and 166 patients referred to us for genetic testing for SGA-SS and SRS, respectively. After excluding 20 patients with structural abnormalities detected by comparative genomic hybridization analysis using catalog array, 249 patients were classified into 3 subgroups based on the Netchine-Harbison clinical scoring system (NH-CSS), SRS diagnostic criteria. We screened various IDs by methylation analysis for differentially methylated regions (DMRs) related to known IDs. We also performed clinical analysis.Results: These 249 patients with SGA-SS were classified into the "SRS-compatible group" (n = 148), the "non-SRS with normocephaly or relative macrocephaly at birth group" (non-SRS group) (n = 94), or the "non-SRS with relative microcephaly at birth group" (non-SRS with microcephaly group) (n = 7). The 44.6% of patients in the "SRS-compatible group," 21.3% of patients in the "non-SRS group," and 14.3% in the "non-SRS with microcephaly group" had various IDs. Loss of methylation of the H19/IGF2:intergenic-DMR and uniparental disomy chromosome 7, being major genetic causes of SRS, was detected in 30.4% of patients in the "SRS-compatible group" and in 13.8% of patients in the "non-SRS group."Conclusion: We clarified the contribution of IDs as (epi)genetic causes of SGA-SS and the molecular and phenotypic spectrum of SRS. Various IDs constitute underlying factors for SGA-SS, including SRS. [ABSTRACT FROM AUTHOR]

Published

2021

2. Contribution of gene mutations to Silver-Russell syndrome phenotype: multigene sequencing analysis in 92 etiology-unknown patients.

Author

Inoue, Takanobu, Nakamura, Akie, Iwahashi-Odano, Megumi, Tanase-Nakao, Kanako, Matsubara, Keiko, Nishioka, Junko, Maruo, Yoshihiro, Hasegawa, Yukihiro, Suzumura, Hiroshi, Sato, Seiji, Kobayashi, Yoshiyuki, Murakami, Nobuyuki, Nakabayashi, Kazuhiko, Yamazawa, Kazuki, Fuke, Tomoko, Narumi, Satoshi, Oka, Akira, Ogata, Tsutomu, Fukami, Maki, and Kagami, Masayo

Subjects

GENETIC mutation, EXOMES, SEQUENCE analysis, NOONAN syndrome, SKELETAL dysplasia, GENETIC testing

Abstract

Background: Silver-Russell syndrome (SRS) is characterized by growth failure and dysmorphic features. Major (epi)genetic causes of SRS are loss of methylation on chromosome 11p15 (11p15 LOM) and maternal uniparental disomy of chromosome 7 (upd(7)mat). However, IGF2, CDKN1C, HMGA2, and PLAG1 mutations infrequently cause SRS. In addition, other imprinting disturbances, pathogenic copy number variations (PCNVs), and monogenic disorders sometimes lead to SRS phenotype. This study aimed to clarify the frequency and clinical features of the patients with gene mutations among etiology-unknown patients with SRS phenotype. Results: Multigene sequencing was performed in 92 out of 336 patients referred to us for genetic testing for SRS. The clinical features of the patients were evaluated based on the Netchine-Harbison clinical scoring system. None of the patients showed 11p15 LOM, upd(7)mat, abnormal methylation levels for six differentially methylated regions (DMRs), namely, PLAGL1:alt-TSS-DMR on chromosome 6, KCNQ1OT1:TSS-DMR on chromosome 11, MEG3/DLK1:IG-DMR on chromosome 14, MEG3:TSS-DMR on chromosome 14, SNURF:TSS-DMR on chromosome 15, and GNAS A/B:TSS-DMR on chromosome 20, PCNVs, or maternal uniparental disomy of chromosome 16. Using next-generation sequencing and Sanger sequencing, we screened four SRS-causative genes and 406 genes related to growth failure and/or skeletal dysplasia. We identified four pathogenic or likely pathogenic variants in responsible genes for SRS (4.3%: IGF2 in two patients, CDKN1C, and PLAG1), and five pathogenic variants in causative genes for known genetic syndromes presenting with growth failure (5.4%: IGF1R abnormality (IGF1R), SHORT syndrome (PIK3R1), Floating-Harbor syndrome (SRCAP), Pitt-Hopkins syndrome (TCF4), and Noonan syndrome (PTPN11)). Functional analysis indicated the pathogenicity of the CDKN1C variant. The variants we detected in CDKN1C and PLAG1 were the second and third variants leading to SRS, respectively. Our patients with CDKN1C and PLAG1 variants showed similar phenotypes to previously reported patients. Furthermore, our data confirmed IGF1R abnormality, SHORT syndrome, and Floating-Harbor syndrome are differential diagnoses of SRS because of the shared phenotypes among these syndromes and SRS. On the other hand, the patients with pathogenic variants in causative genes for Pitt-Hopkins syndrome and Noonan syndrome were atypical of these syndromes and showed partial clinical features of SRS. Conclusions: We identified nine patients (9.8%) with pathogenic or likely pathogenic variants out of 92 etiology-unknown patients with SRS phenotype. This study expands the molecular spectrum of SRS phenotype. [ABSTRACT FROM AUTHOR]

Published

2020

3. Epimutations of the IG-DMR and the MEG3-DMR at the 14q32.2 imprinted region in two patients with Silver-Russell Syndrome-compatible phenotype.

Author

Kagami, Masayo, Mizuno, Seiji, Matsubara, Keiko, Nakabayashi, Kazuhiko, Sano, Shinichiro, Fuke, Tomoko, Fukami, Maki, and Ogata, Tsutomu

Subjects

METHYLATION, MOSAICISM, HUMAN chromosome abnormalities, MICROGNATHIA, LEUKOCYTE count

Abstract

Maternal uniparental disomy 14 (UPD(14)mat) and related (epi)genetic aberrations affecting the 14q32.2 imprinted region result in a clinically recognizable condition which is recently referred to as Temple Syndrome (TS). Phenotypic features in TS include pre- and post-natal growth failure, prominent forehead, and feeding difficulties that are also found in Silver-Russell Syndrome (SRS). Thus, we examined the relevance of UPD(14)mat and related (epi)genetic aberrations to the development of SRS in 85 Japanese patients who satisfied the SRS diagnostic criteria proposed by Netchine et al and had neither epimutation of the H19-DMR nor maternal uniparental disomy 7. Pyrosequencing identified hypomethylation of the DLK1-MEG3 intergenic differentially methylated region (IG-DMR) and the MEG3-DMR in two cases. In both cases, microsatellite analysis showed biparental transmission of the homologs of chromosome 14, with no evidence for somatic mosaicism with full or segmental maternal isodisomy involving the imprinted region. FISH and array comparative genomic hybridization revealed neither deletion of the two DMRs nor discernible copy number alteration in the 14q32.2 imprinted region. Methylation patterns were apparently normal in other six disease-associated DMRs. In addition, a thorough literature review revealed a considerable degree of phenotypic overlap between SRS and TS, although body asymmetry was apparently characteristic of SRS. The results indicate the occurrence of epimutation affecting the IG-DMR and the MEG3-DMR in the two cases, and imply that UPD(14)mat and related (epi)genetic aberrations constitute a rare but important underlying factor for SRS. [ABSTRACT FROM AUTHOR]

Published

2015

4. IMAGe syndrome: clinical and genetic implications based on investigations in three Japanese patients.

Author

Kato, Fumiko, Hamajima, Takashi, Hasegawa, Tomonobu, Amano, Naoko, Horikawa, Reiko, Nishimura, Gen, Nakashima, Shinichi, Fuke, Tomoko, Sano, Shinichirou, Fukami, Maki, and Ogata, Tsutomu

Subjects

FETAL growth retardation, GENETIC mutation, GLUCOCORTICOIDS, PHENOTYPES, HUMAN chromosomes, PLACENTA abnormalities

Abstract

Objective Arboleda et al. have recently shown that IMAGe (intra-uterine growth restriction, metaphyseal dysplasia, adrenal hypoplasia congenita and genital abnormalities) syndrome is caused by gain-of-function mutations of maternally expressed gene CDKN1C on chromosome 11p15.5. However, there is no other report describing clinical findings in patients with molecularly studied IMAGe syndrome. Here, we report clinical and molecular findings in Japanese patients. Patients We studied a 46, XX patient aged 8·5 years (case 1) and two 46, XY patients aged 16·5 and 15·0 years (cases 2 and 3). Results Clinical studies revealed not only IMAGe syndrome-compatible phenotypes in cases 1-3, but also hitherto undescribed findings including relative macrocephaly and apparently normal pituitary-gonadal endocrine function in cases 1-3, familial glucocorticoid deficiency ( FGD)-like adrenal phenotype and the history of oligohydramnios in case 2, and arachnodactyly in case 3. Sequence analysis of CDKN1C, pyrosequencing-based methylation analysis of Kv DMR1 and high-density oligonucleotide array comparative genome hybridization analysis for chromosome 11p15.5 were performed, showing an identical de novo and maternally inherited CDKN1C gain-of-function mutation (p.Asp274Asn) in cases 1 and 2, respectively, and no demonstrable abnormality in case 3. Conclusions The results of cases 1 and 2 with CDKN1C mutation would argue the following: [1] relative macrocephaly is consistent with maternal expression of CDKN1C in most tissues and biparental expression of CDKN1C in the foetal brain; [2] FGD-like phenotype can result from CDKN1C mutation; and [3] genital abnormalities may primarily be ascribed to placental dysfunction. Furthermore, lack of CDKN1C mutation in case 3 implies genetic heterogeneity in IMAGe syndrome. [ABSTRACT FROM AUTHOR]

Published

2014

5. Molecular and Clinical Studies in 138 Japanese Patients with Silver-Russell Syndrome.

Author

Fuke, Tomoko, Mizuno, Seiji, Nagai, Toshiro, Hasegawa, Tomonobu, Horikawa, Reiko, Miyoshi, Yoko, Muroya, Koji, Kondoh, Tatsuro, Numakura, Chikahiko, Sato, Seiji, Nakabayashi, Kazuhiko, Tayama, Chiharu, Hata, Kenichiro, Sano, Shinichiro, Matsubara, Keiko, Kagami, Masayo, Yamazawa, Kazuki, and Ogata, Tsutomu

Subjects

SILVER-Russell syndrome, CLINICAL medicine, JAPANESE people, MOLECULAR genetics, METHYLATION, PHENOTYPES, DEVELOPMENTAL biology, CLINICAL pathology, BRACHYDACTYLY, DISEASES

Abstract

Background: Recent studies have revealed relative frequency and characteristic phenotype of two major causative factors for Silver-Russell syndrome (SRS), i.e. epimutation of the H19-differentially methylated region (DMR) and uniparental maternal disomy 7 (upd(7)mat), as well as multilocus methylation abnormalities and positive correlation between methylation index and body and placental sizes in H19-DMR epimutation. Furthermore, rare genomic alterations have been found in a few of patients with idiopathic SRS. Here, we performed molecular and clinical findings in 138 Japanese SRS patients, and examined these matters. Methodology/Principal Findings: We identified H19-DMR epimutation in cases 1–43 (group 1), upd(7)mat in cases 44–52 (group 2), and neither H19-DMR epimutation nor upd(7)mat in cases 53–138 (group 3). Multilocus analysis revealed hyper- or hypomethylated DMRs in 2.4% of examined DMRs in group 1; in particular, an extremely hypomethylated ARHI-DMR was identified in case 13. Oligonucleotide array comparative genomic hybridization identified a ∼3.86 Mb deletion at chromosome 17q24 in case 73. Epigenotype-phenotype analysis revealed that group 1 had more reduced birth length and weight, more preserved birth occipitofrontal circumference (OFC), more frequent body asymmetry and brachydactyly, and less frequent speech delay than group 2. The degree of placental hypoplasia was similar between the two groups. In group 1, the methylation index for the H19-DMR was positively correlated with birth length and weight, present height and weight, and placental weight, but with neither birth nor present OFC. Conclusions/Significance: The results are grossly consistent with the previously reported data, although the frequency of epimutations is lower in the Japanese SRS patients than in the Western European SRS patients. Furthermore, the results provide useful information regarding placental hypoplasia in SRS, clinical phenotypes of the hypomethylated ARHI-DMR, and underlying causative factors for idiopathic SRS. [ABSTRACT FROM AUTHOR]

Published

2013

6. Paternal uniparental disomy 14 and related disorders.

Author

Kagami, Masayo, Matsuoka, Kentaro, Nagai, Toshiro, Yamanaka, Michiko, Kurosawa, Kenji, Suzumori, Nobuhiro, Sekita, Yoichi, Miyado, Mami, Matsubara, Keiko, Fuke, Tomoko, Kato, Fumiko, Fukami, Maki, and Ogata, Tsutomu

Published

2012

7. Genome-wide methylation analysis in Silver–Russell syndrome, Temple syndrome, and Prader–Willi syndrome.

Author

Hara-Isono, Kaori, Matsubara, Keiko, Fuke, Tomoko, Yamazawa, Kazuki, Satou, Kazuhito, Murakami, Nobuyuki, Saitoh, Shinji, Nakabayashi, Kazuhiko, Hata, Kenichiro, Ogata, Tsutomu, Fukami, Maki, and Kagami, Masayo

Subjects

PRADER-Willi syndrome, METHYLATION, CLUSTER analysis (Statistics), TEMPLES, HUMAN genome

Abstract

Background: Imprinting disorders (IDs) show overlapping phenotypes, particularly in Silver–Russell syndrome (SRS), Temple syndrome (TS14), and Prader–Willi syndrome (PWS). These three IDs include fetal and postnatal growth failure, feeding difficulty, and muscular hypotonia as major clinical features. However, the mechanism that causes overlapping phenotypes has not been clarified. To investigate the presence or absence of methylation signatures associated with overlapping phenotypes, we performed genome-wide methylation analysis (GWMA). Results: GWMA was carried out on 36 patients with three IDs (SRS [n = 16], TS14 [n = 7], PWS [n = 13]) and 11 child controls using HumanMethylation450 BeadChip including 475,000 CpG sites across the human genome. To reveal an aberrantly methylated region shared by SRS, TS14, and PWS groups, we compared genome-wide methylation data of the three groups with those of control subjects. All the identified regions were known as SRS-, TS14-, and PWS-related imprinting-associated differentially methylated regions (iDMRs), and there was no hypermethylated or hypomethylated region shared by different ID groups. To examine the methylation pattern shared by SRS, TS14, and PWS groups, we performed clustering analysis based on GWMA data. The result focusing on 620 probes at the 62 known iDMRs (except for SRS-, TS14-, and PWS-related iDMRs) classified patients into two categories: (1) category A, grossly normal methylation patterns mainly consisting of SRS group patients; and (2) category B, broad and mild hypermethylation patterns mainly consisting of TS14 and PWS group patients. However, we found no obvious relationship between these methylation patterns and phenotypes of patients. Conclusions: GWMA in three IDs found no methylation signatures shared by SRS, TS14, and PWS groups. Although clustering analysis showed similar mild hypermethylation patterns in TS14 and PWS groups, further study is needed to clarify the effect of methylation patterns on the overlapping phenotypes. [ABSTRACT FROM AUTHOR]

Published

2020