51 research outputs found

    Autistic disorder associated with a paternally derived unbalanced translocation leading to duplication of chromosome 15pter-q13.2: a case report

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    Autism spectrum disorders have been associated with maternally derived duplications that involve the imprinted region on the proximal long arm of chromosome 15. Here we describe a boy with a chromosome 15 duplication arising from a 3:1 segregation error of a paternally derived translocation between chromosome 15q13.2 and chromosome 9q34.12, which led to trisomy of chromosome 15pter-q13.2 and 9q34.12-qter. Using array comparative genome hybridization, we localized the breakpoints on both chromosomes and sequence homology suggests that the translocation arose from non-allelic homologous recombination involving the low copy repeats on chromosome 15. The child manifests many characteristics of the maternally-derived duplication chromosome 15 phenotype including developmental delays with cognitive impairment, autism, hypotonia and facial dysmorphisms with nominal overlap of the most general symptoms found in duplications of chromosome 9q34. This case suggests that biallelically expressed genes on proximal 15q contribute to the idic(15) autism phenotype

    Multiple forms of atypical rearrangements generating supernumerary derivative chromosome 15

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    <p>Abstract</p> <p>Background</p> <p>Maternally-derived duplications that include the imprinted region on the proximal long arm of chromosome 15 underlie a complex neurobehavioral disorder characterized by cognitive impairment, seizures and a substantial risk for autism spectrum disorders<abbrgrp><abbr bid="B1">1</abbr></abbrgrp>. The duplications most often take the form of a supernumerary pseudodicentric derivative chromosome 15 [der(15)] that has been called inverted duplication 15 or isodicentric 15 [idic(15)], although interstitial rearrangements also occur. Similar to the deletions found in most cases of Angelman and Prader Willi syndrome, the duplications appear to be mediated by unequal homologous recombination involving low copy repeats (LCR) that are found clustered in the region. Five recurrent breakpoints have been described in most cases of segmental aneuploidy of chromosome 15q11-q13 and previous studies have shown that most idic(15) chromosomes arise through BP3:BP3 or BP4:BP5 recombination events.</p> <p>Results</p> <p>Here we describe four duplication chromosomes that show evidence of atypical recombination events that involve regions outside the common breakpoints. Additionally, in one patient with a mosaic complex der(15), we examined homologous pairing of chromosome 15q11-q13 alleles by FISH in a region of frontal cortex, which identified mosaicism in this tissue and also demonstrated pairing of the signals from the der(15) and the normal homologues.</p> <p>Conclusion</p> <p>Involvement of atypical BP in the generation of idic(15) chromosomes can lead to considerable structural heterogeneity.</p

    Functional Analysis of MeCP2 Mutations Associated with Rett Syndrome Using Transient Expression Systems

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    レット症候群は生後半年から1歳半ころに発症する重度の精神発達遅滞を伴う疾患で女児の1万人から1万5千人に1人に発症する頻度の高い遺伝子疾患である。この疾患の原因遺伝子が最近MeCP2遺伝子であることが判明した。レット症候群の患者でみられる変異がMeCP2の本来の機能にどのような影響を及ぼすかを理解することは、レット症候群の病態を解明する上での手がかりになる。MeCP2は2つの機能ドメインを持ち、一つはメチル化CpGに結合するメチル化結合ドメイン(MBD)で、もう一つはヒストン脱アセチル化酵素をリクルートするSin3Aと結合する転写抑制ドメイン(TRD)である。報告されている変異の中でミスセンス変異の多くは、この二つのドメイン内でみられ、特にMBD内での変異の割合は多い。MBD内のミスセンス変異のMeCP2機能への影響を把握するため、培養細胞を用いた遺伝子導入発現系を開発して解析を行った

    Functional Characterisation of MeCP2 Mutatiions Found in Male Patients with X Linked Mental Retardation

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    MeCP2の遺伝子変異は、Rett症候群以外の疾患の患者でも見つかり、X染色体性の精神発達遅滞を伴う男性患者においても報告された。これらの患者ではMBD内の変異として137番目のGluからGlyと140番目AlaからValのアミノ酸変異が確認された。これらの変異に関して、開発した二つの機能解析系を用いて解析を行ったところ、140番目の変異では、メチル化DNAに対しての転写抑制活性は完全に維持されており、137番目の変異ではわずかに転写抑制活性の低下がみられる程度であった。また、マウス細胞のヘテロクロマチン親和性についても140番と137番目の変異は共に明らかな点状の像を示し、親和性は維持されていた。これらの遺伝性の精神発達遅滞を伴う男性患者でのMeCP2の変異は、その機能への影響がレット症候群の場合と比較して軽度であるため、Rett症候群とは異なる病態を呈する成因となっている可能性が示唆された

    Abnormal Intracellular Accumulation and Extracellular Aβ Deposition in Idiopathic and Dup15q11.2-q13 Autism Spectrum Disorders

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    <div><h3>Background</h3><p>It has been shown that amyloid ß (Aβ), a product of proteolytic cleavage of the amyloid β precursor protein (APP), accumulates in neuronal cytoplasm in non-affected individuals in a cell type–specific amount.</p> <h3>Methodology/Principal Findings</h3><p>In the present study, we found that the percentage of amyloid-positive neurons increases in subjects diagnosed with idiopathic autism and subjects diagnosed with duplication 15q11.2-q13 (dup15) and autism spectrum disorder (ASD). In spite of interindividual differences within each examined group, levels of intraneuronal Aβ load were significantly greater in the dup(15) autism group than in either the control or the idiopathic autism group in 11 of 12 examined regions (p<0.0001 for all comparisons; Kruskall-Wallis test). In eight regions, intraneuronal Aβ load differed significantly between idiopathic autism and control groups (p<0.0001). The intraneuronal Aβ was mainly N-terminally truncated. Increased intraneuronal accumulation of Aβ<sub>17–40/42</sub> in children and adults suggests a life-long enhancement of APP processing with α-secretase in autistic subjects. Aβ accumulation in neuronal endosomes, autophagic vacuoles, Lamp1-positive lysosomes and lipofuscin, as revealed by confocal microscopy, indicates that products of enhanced α-secretase processing accumulate in organelles involved in proteolysis and storage of metabolic remnants. Diffuse plaques containing Aβ<sub>1–40/42</sub> detected in three subjects with ASD, 39 to 52 years of age, suggest that there is an age-associated risk of alterations of APP processing with an intraneuronal accumulation of a short form of Aβ and an extracellular deposition of full-length Aβ in nonfibrillar plaques.</p> <h3>Conclusions/Significance</h3><p>The higher prevalence of excessive Aβ accumulation in neurons in individuals with early onset of intractable seizures, and with a high risk of sudden unexpected death in epilepsy in autistic subjects with dup(15) compared to subjects with idiopathic ASD, supports the concept of mechanistic and functional links between autism, epilepsy and alterations of APP processing leading to neuronal and astrocytic Aβ accumulation and diffuse plaque formation.</p> </div

    Epigenetics of autism spectrum disorders

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    The autism spectrum disorders (ASD) comprise a complex group of behaviorally related disorders that are primarily genetic in origin. Involvement of epigenetic regulatory mechanisms in the pathogenesis of ASD has been suggested by the occurrence of ASD in patients with disorders arising from epigenetic mutations (fragile X syndrome) or that involve key epigenetic regulatory factors (Rett syndrome). Moreover, the most common recurrent cytogenetic abnormalities in ASD involve maternally derived duplications of the imprinted domain on chromosome 15q11–13. Thus, parent of origin effects on sharing and linkage to imprinted regions on chromosomes 15q and 7q suggest that these regions warrant specific examination from an epigenetic perspective, particularly because epigenetic modifications do not change the primary genomic sequence, allowing risk epialleles to evade detection using standard screening strategies. This review examines the potential role of epigenetic factors in the etiology of ASD

    High-Resolution Molecular Characterization of 15q11-q13 Rearrangements by Array Comparative Genomic Hybridization (Array CGH) with Detection of Gene Dosage

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    Maternally derived duplication of the imprinted region of chromosome 15q11-q14 leads to a complex neurobehavioral phenotype that often includes autism, cognitive deficits, and seizures. Multiple repeat elements within the region mediate a variety of rearrangements, including interstitial duplications, interstitial triplications, and supernumerary isodicentric marker chromosomes, as well as the deletions that cause Prader-Willi and Angelman syndromes. To elucidate the molecular structure of these duplication chromosomes, we designed a high-resolution array comparative genomic hybridization (array CGH) platform. The array contains 79 clones that form a gapped contig across the critical region on chromosome 15q11-q14 and 21 control clones from other autosomes and the sex chromosomes. We used this array to examine a set of 48 samples from patients with segmental aneuploidy of chromosome 15q. Using the array, we were able to determine accurately the dosage, which ranged from 1 to 6 copies, and also to detect atypical and asymmetric rearrangements. In addition, the increased resolution of the array allowed us to position two previously reported breakpoints within the contig. These results indicate that array CGH is a powerful technique to study rearrangements of proximal chromosome 15q

    A Single-Tube Quantitative High-Resolution Melting Curve Method for Parent-of-Origin Determination of 15q Duplications

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    The most common chromosomal abnormalities associated with autism are 15q11–q13 duplications. Maternally derived or inherited duplications of 15q pose a substantial risk for an autism phenotype, while paternally derived duplications may be incompletely penetrant or result in other neurodevelopmental problems. Therefore, the determination of maternal versus paternal origin of this duplication is important for early intervention therapies and for appropriate genetic counseling to the families. We adapted a previous single-reaction tube assay (high-resolution melting curve analysis) to determine the parent of origin of 15q duplications in 28 interstitial duplication 15q samples, one family and two isodicentric subjects. Our method distinguished parent origin in 92% of the independent samples as well as in the familial inherited duplication and in the two isodicentric samples. This method accurately determines parental origin of the duplicated segment and measures the dosage of these alleles in the sample. In addition, it can be performed on samples where parental DNA is not available for microsatellite analysis. The development of this single-tube assay will make it easier for genetic testing laboratories to provide parent-of-origin information and will provide important information to clinical geneticists about autism risk in these individuals
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