Takeo Kubota scite author profile

The life-threatening Immunodeficiency, Centromeric Instability and Facial Anomalies (ICF) syndrome is a genetically heterogeneous autosomal recessive disorder. Twenty percent of patients cannot be explained by mutations in the known ICF genes DNA methyltransferase 3B or zinc-finger and BTB domain containing 24. Here we report mutations in the cell division cycle associated 7 and the helicase, lymphoid-specific genes in 10 unexplained ICF cases. Our data highlight the genetic heterogeneity of ICF syndrome; however, they provide evidence that all genes act in common or converging pathways leading to the ICF phenotype.

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A new assay for the analysis of X-chromosome inactivation based on methylation-specific PCR

Kubota¹,

et al. 1999

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The pattern of X-chromosome inactivation in females is currently evaluated by assays of differential methylation in the genes between the active and the inactive X chromosomes, with methylation-sensitive enzymes. We report a new assay in the human androgen receptor (HUMARA) locus involving a methylation-specific polymerase chain reaction (M-PCR) technique, independent of the use of restriction enzymes. The assay involves the chemical modification of DNA with sodium bisulfite and subsequent PCR. By using the assay with specific primers for the methylated allele, we obtained an X-inactivation pattern based on the ratio of the maternal inactive X to the paternal inactive X. These patterns were consistent with those obtained by conventional PCR assay at the same locus in 48 female cases. We also obtained another X-inactivation pattern based on the ratio of the maternal active X to the paternal active X by using specific primers for the unmethylated allele. The latter pattern was complementary to the former pattern, and a combination of these patterns produced a reliable X-inactivation pattern. The assay revealed that 12 (11%) of the 105 normal females had non-random inactivation patterns (>80:20 or <20:80). Four patients with an X; autosome translocation showed extremely non-random patterns, and these results were consistent with those obtained by previous molecular/cytogenetic studies. We conclude that M-PCR provides an accurate assay for X-inactivation and that it can be performed on various DNA samples unsuitable for restriction digestion.

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The spectrum of mutations in UBE3A causing Angelman syndrome

Fang

Lev-Lehman

Tsai³

et al. 1999

151

128

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Angelman syndrome (AS) is characterized by mental retardation, absence of speech, seizures and motor dysfunction. AS is caused by maternal deletions for chromosome 15q11-q13, paternal uniparental disomy (UPD), imprinting defects or loss-of-function mutations in the UBE3A locus which encodes E6-AP ubiquitin-protein ligase. The UBE3A gene is imprinted with paternal silencing in human brain and similar silencing of the Ube3a locus in Purkinje cells and hippocampal neurons in the mouse. We have sequenced the major coding exons for UBE3A in 56 index patients with a clinical diagnosis of AS and a normal DNA methylation pattern. The analysis identified disease-causing mutations in 17 of 56 patients (30%) including 13 truncating mutations, two missense mutations, one single amino acid deletion and one stop codon mutation predicting an elongated protein. Mutations were identified in six of eight families (75%) with more than one affected case, and in 11 of 47 isolated cases (23%); no mutation was found in one family with two siblings, one with a typical and one with an atypical phenotype. Mutations were de novo in nine of the 11 isolated cases. An amino acid polymorphism of threonine substituted for alanine at codon 178 was identified, and a 3 bp length polymorphism was found in the intron upstream of exon 8. In all informative cases, phenotypic expression was consistent with imprinting with a normal phenotype when a mutation was on the paternal chromosome and an AS phenotype when a mutation was on the maternal chromosome. Laboratory diagnosis and genetic counseling for AS are complex, and mutation analysis is valuable in clinically typical AS patients with a normal methylation analysis.

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Three novel DNMT3B mutations in Japanese patients with ICF syndrome

Shirohzu¹,

Kubota²,

Kumazawa³

et al. 2002

Am. J. Med. Genet.

110

102

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ICF syndrome is a rare autosomal recessive disorder characterized by immunodeficiency, centromeric instability, and facial anomalies. It is caused by mutations in a de novo DNA methyltransferase gene, DNMT3B. We here report the first three Japanese cases of ICF syndrome from two unrelated families. All patients had typical facial dysmorphism and immunoglobulin A (IgA) deficiency, but none of them had apparent mental retardation. Cytogenetic analysis of peripheral blood lymphocytes showed chromosomal abnormalities, including multiradial configurations and a stretching of the pericentromeric heterochromatin of chromosomes 1 and 16. Hypomethylation of classical satellite 2 DNA was also observed. Mutation analyses of DNMT3B revealed three novel mutations: patient 1 from the first family was a compound heterozygote for a nonsense mutation (Q42Term) and a missense mutation (R832Q); patients 2 and 3 from the second family were both homozygous for a missense mutation (S282P). The R832Q mutation occurred within the conserved methyltransferase domain, and thus may affect the enzyme activity directly. The S282P mutation, on the other hand, occurred close to the PWWP domain, which is presumably involved in protein-protein interaction. This is the first missense mutation mapped to the N-terminal half of the protein, suggesting that the region plays an important role in the regulation of the DNMT3B enzyme.

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Takeo Kubota

Methylation-specif ic PCR simplifies imprinting analysis

Mutations in CDCA7 and HELLS cause immunodeficiency–centromeric instability–facial anomalies syndrome

A new assay for the analysis of X-chromosome inactivation based on methylation-specific PCR

The spectrum of mutations in UBE3A causing Angelman syndrome

Three novel DNMT3B mutations in Japanese patients with ICF syndrome

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