Two cases of mosaic RhD blood-group phenotypes and paternal isodisomy for chromosome 1

Miyoshi, Osamu; Yabe, Ryuichi; Wakui, Keiko; Fukushima, Yoshimitsu; Koizumi, Shigeki; Uchikawa, Makoto; Kajii, Tadashi; Numakura, Chikahiko; Takahashi, Shunji; Hayasaka, Kiyoshi; Niikawa, Norio

doi:10.1002/ajmg.10000

Cited by 13 publications

(6 citation statements)

References 21 publications

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“…All of them were identified through the detection of homozygosity for an autosomal recessive disorder in discordance with the segregation analysis. Other two cases were incidentally identified during genome‐wide linkage analysis (Field, Tobias, Robinson, Paisey, & Bain, ; Miyoshi et al, ) and further two cases have been described with a phenotype that could not be attributed to a known recessive condition (Chen et al, ; Röthlisberger et al, ). Particularly, the karyotype of a female with paternal UPD1 (Chen et al, ) presenting with myopathy, infertility and short stature, showed the presence of two isochromosomes 1, which likely have arisen from an abnormal division following chromosome 1 monosomy.…”

Section: Discussionmentioning

confidence: 99%

Uniparental isodisomy of chromosome 1 results in glycogen storage disease type III with profound growth retardation

Ponzi

Alesi

Lepri

et al. 2019

Molec Gen & Gen Med

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Background Glycogen storage disease type III (GSDIII) is caused by mutations of AGL gene with debranching enzyme deficiency. Patients with GSDIII manifest fasting hypoglycemia, hepatomegaly, hepatopathy, myopathy, and cardiomyopathy. We report on an 18‐year‐old boy with a profound growth retardation (<3 SD ) besides typical clinical features of GSDIII, whereby endocrinological studies were negative. Methods and Results Molecular analysis of AGL gene revealed the homozygous reported variant c.3903_3904insA. Since discordant results from segregation studies showed the carrier status in one parent only, SNP array and short tandem repeats analyses were performed, revealing a paternal disomy of chromosome 1 (UPD1). Conclusion This study describes the first case of GSDIII resulting from UPD1. UPD can play an important role even in case of imprinted genes. DIRAS3 is a maternally imprinted tumor suppressor gene, located on chromosome 1p31, and implicated in growth and oncogenesis. It can be speculated that DIRAS3 overexpression might have a role in the severe short stature of our patient. The study emphasizes the importance of parental segregation analysis especially in patients with recessive conditions to look for specific genetic causes of disease and to estimate properly the risk of family recurrence.

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Section: Discussionmentioning

confidence: 99%

Uniparental isodisomy of chromosome 1 results in glycogen storage disease type III with profound growth retardation

Ponzi

Alesi

Lepri

et al. 2019

Molec Gen & Gen Med

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“…Recently a number of mosaic genome‐wide pUPDs were described with BWS‐like phenotypes (Morales et al, 2009; Yamazawa et al, 2011; Romanelli et al, 2011b). This is remarkable, since non‐mosaic genome‐wide pUPD is incompatible with fetal development and results in a hydatidiform mole (Devriendt 2005).…”

Section: Genome‐wide Upd Mosaics Associated With Imprinting Phenotypesmentioning

confidence: 99%

“…This is remarkable, since non‐mosaic genome‐wide pUPD is incompatible with fetal development and results in a hydatidiform mole (Devriendt 2005). Two of these rare BWS‐like cases were also reported to have developed multiple tumours (Morales et al, 2009; Romanelli et al, 2011b). The most likely mechanism of mosaic genome‐wide UPD is normal fertilization, followed by a failure of replication and condensation of the maternal pronuclei, followed by paternal genome endoreduplication, resulting in androgenetic/biparental mosaicism, with over‐representation of genome‐wide pUPD cell lines (Figure 2F).…”

Section: Genome‐wide Upd Mosaics Associated With Imprinting Phenotypesmentioning

confidence: 99%

The consequences of uniparental disomy and copy number neutral loss-of-heterozygosity during human development and cancer

Lapunzina

Monk

2011

Biology of the Cell

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UPD (uniparental disomy) describes the inheritance of a pair of chromosomes from only one parent. Mechanisms that lead to UPD include trisomy rescue, gamete complementation, monosomy rescue and somatic recombination. Most of these mechanisms can involve aberrant chromosomes, particularly isochromosomes and Robertsonian translocations. In the last decade, the number of UPD cases reported in the literature has increased exponentially. This is partly due to the advances in genomic technologies that have allowed for high-resolution SNP (single nucleotide polymorphism) studies, which have complemented traditional methods relying on polymorphic microsatellite markers. In this review, we discuss aberrant cellular mechanisms leading to UPD and their impact on gene expression. Special emphasis is placed on the unmasking of mutant recessive alleles and the disruption of imprinted gene dosage, which give rise to specific and recurrent imprinting phenotypes. Finally, we discuss how copy number maps determined from SNP array datasets have helped identify not only deletions and duplications but also recurrent copy number neutral regions of loss-of-heterozygosity, which have been reported in many cancer types and that may constitute an important driving force in cancer. These tiny regions of UPD also alter imprinted gene dosage, which may have cumulative tumourgenic effects in addition to that of unmasking homozygous cancer-associated mutations.

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“…Since the first case by Pulkkinen et al 1997, at least 19 cases of uniparental hetero‐ or isodisomy of chromosome 1 have been reported resulting in various autosomal recessive conditions with a typical phenotype, suggesting the lack of imprinted genes affecting growth and development on either the paternal or maternal alleles on that chromosome [Pulkkinen et al, 1997; Field et al, 1998; Gelb et al, 1998; Dufourcq‐Lagelouse et al, 1999; Takizawa et al, 2000; Miyoshi et al, 2001; Thompson et al, 2002; Fassihi et al, 2005; Zeng et al, 2006; Riveiro‐Alvarez et al, 2007; Benko et al, 2008] reviewed in a recent report [Turner et al, 2007].…”

Section: Discussionmentioning

confidence: 99%

“…Maternal isodisomy of chromosome 1 resulting in a homozygous nonsense mutation (c.2620delT, p.Phe874fsX898) in the LYST/CHS1 gene has been previously described in a 6‐year‐old male with classic CHS and normal physical and neurocognitive development [Dufourcq‐Lagelouse et al, 1999]. Additionally, chromosome 1 maternal or paternal iso‐ or heterodisomy has been reported in association with various isolated recessive disorders without other symptoms, such as growth or cognitive delays, suggesting a lack of imprinted genes on chromosome 1 [Pulkkinen et al, 1997; Field et al, 1998; Gelb et al, 1998; Takizawa et al, 2000; Miyoshi et al, 2001; Thompson et al, 2002; Fassihi et al, 2005; Zeng et al, 2006; Riveiro‐Alvarez et al, 2007; Turner et al, 2007; Benko et al, 2008].…”

Section: Introductionmentioning

confidence: 99%

Chediak–Higashi syndrome with early developmental delay resulting from paternal heterodisomy of chromosome 1

Manoli

Golas

Westbroek

et al. 2010

American J of Med Genetics Pt A

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Chediak-Higashi syndrome (CHS) is a rare autosomal recessive disease characterized by variable oculocutaneous albinism, immunodeficiency, mild bleeding diathesis and an accelerated lymphoproliferative state. Abnormal lysosome-related organelle membrane function leads to the accumulation of large intracellular vesicles in several cell types, including granulocytes, melanocytes, and platelets. This report describes a severe case of CHS resulting from paternal heterodisomy of chromosome 1, causing homozygosity for the most distal nonsense mutation (p.E3668X, exon 50) reported to date in the LYST/CHS1 gene. The mutation is located in the WD40 region of the CHS1 protein. The patient's fibroblasts expressed no detectable CHS1. Besides manifesting the classical CHS findings, the patient exhibited hypotonia and global developmental delays, raising concerns about other effects of heterodisomy. An interstitial 747kb duplication on 6q14.2 to 6q14.3 was identified in the propositus and paternal samples by comparative genomic hybridization. SNP genotyping revealed no additional whole chromosome or segmental isodisomic regions or other dosage variations near the crossover breakpoints on chromosome 1. Unmasking of a separate autosomal recessive cause of developmental delay, or an additive effect of the paternal heterodisomy, could underlie the severity of the phenotype in this patient.

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Two cases of mosaic RhD blood-group phenotypes and paternal isodisomy for chromosome 1

Cited by 13 publications

References 21 publications

Uniparental isodisomy of chromosome 1 results in glycogen storage disease type III with profound growth retardation

Uniparental isodisomy of chromosome 1 results in glycogen storage disease type III with profound growth retardation

The consequences of uniparental disomy and copy number neutral loss-of-heterozygosity during human development and cancer

Chediak–Higashi syndrome with early developmental delay resulting from paternal heterodisomy of chromosome 1

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