Your search keyword '"DiTroia SP"' showing total 6 results

1. Germline GATA1s-generating mutations predispose to leukemia with acquired trisomy 21 and Down syndrome-like phenotype.

Author

Hasle H, Kline RM, Kjeldsen E, Nik-Abdul-Rashid NF, Bhojwani D, Verboon JM, DiTroia SP, Chao KR, Raaschou-Jensen K, Palle J, Zwaan CM, Nyvold CG, Sankaran VG, and Cantor AB

Subjects

Child, Preschool, Germ-Line Mutation, Humans, Male, Mutation, Phenotype, Trisomy, Down Syndrome complications, Down Syndrome genetics, GATA1 Transcription Factor genetics, Leukemia, Megakaryoblastic, Acute complications, Leukemia, Megakaryoblastic, Acute genetics, Leukemia, Myeloid complications

Abstract

Individuals with Down syndrome are at increased risk of myeloid leukemia in early childhood, which is associated with acquisition of GATA1 mutations that generate a short GATA1 isoform called GATA1s. Germline GATA1s-generating mutations result in congenital anemia in males. We report on 2 unrelated families that harbor germline GATA1s-generating mutations in which several members developed acute megakaryoblastic leukemia in early childhood. All evaluable leukemias had acquired trisomy 21 or tetrasomy 21. The leukemia characteristics overlapped with those of myeloid leukemia associated with Down syndrome, including age of onset at younger than 4 years, unique immunophenotype, complex karyotype, gene expression patterns, and drug sensitivity. These findings demonstrate that the combination of trisomy 21 and GATA1s-generating mutations results in a unique myeloid leukemia independent of whether the GATA1 mutation or trisomy 21 is the primary or secondary event and suggest that there is a unique functional cooperation between GATA1s and trisomy 21 in leukemogenesis. The family histories also indicate that germline GATA1s-generating mutations should be included among those associated with familial predisposition for myelodysplastic syndrome and leukemia., (© 2022 by the American Society of Nephrology.)

Published

2022

2. Recessive variants in COL25A1 gene as novel cause of arthrogryposis multiplex congenita with ocular congenital cranial dysinnervation disorder.

Author

Natera-de Benito D, Jurgens JA, Yeung A, Zaharieva IT, Manzur A, DiTroia SP, Di Gioia SA, Pais L, Pini V, Barry BJ, Chan WM, Elder JE, Christodoulou J, Hay E, England EM, Munot P, Hunter DG, Feng L, Ledoux D, O'Donnell-Luria A, Phadke R, Engle EC, Sarkozy A, and Muntoni F

Subjects

Face, Humans, Muscle, Skeletal, Mutation, Phenotype, Arthrogryposis diagnosis, Arthrogryposis genetics

Abstract

A proper interaction between muscle-derived collagen XXV and its motor neuron-derived receptors protein tyrosine phosphatases σ and δ (PTP σ/δ) is indispensable for intramuscular motor innervation. Despite this, thus far, pathogenic recessive variants in the COL25A1 gene had only been detected in a few patients with isolated ocular congenital cranial dysinnervation disorders. Here we describe five patients from three unrelated families with recessive missense and splice site COL25A1 variants presenting with a recognizable phenotype characterized by arthrogryposis multiplex congenita with or without an ocular congenital cranial dysinnervation disorder phenotype. The clinical features of the older patients remained stable over time, without central nervous system involvement. This study extends the phenotypic and genotypic spectrum of COL25A1 related conditions, and further adds to our knowledge of the complex process of intramuscular motor innervation. Our observations indicate a role for collagen XXV in regulating the appropriate innervation not only of extraocular muscles, but also of bulbar, axial, and limb muscles in the human., (© 2022 Wiley Periodicals LLC.)

Published

2022

3. Familial thrombocytopenia due to a complex structural variant resulting in a WAC-ANKRD26 fusion transcript.

Author

Wahlster L, Verboon JM, Ludwig LS, Black SC, Luo W, Garg K, Voit RA, Collins RL, Garimella K, Costello M, Chao KR, Goodrich JK, DiTroia SP, O'Donnell-Luria A, Talkowski ME, Michelson AD, Cantor AB, and Sankaran VG

Subjects

Adolescent, Adult, Aged, Cell Line, Cell Line, Tumor, Child, Chromosome Breakage, Chromosome Disorders genetics, Exome genetics, Female, HEK293 Cells, HeLa Cells, Humans, Male, Middle Aged, Mutation genetics, Pedigree, Thrombocytopenia congenital, Adaptor Proteins, Signal Transducing genetics, Intercellular Signaling Peptides and Proteins genetics, Polymorphism, Single Nucleotide genetics, Thrombocytopenia genetics

Abstract

Advances in genome sequencing have resulted in the identification of the causes for numerous rare diseases. However, many cases remain unsolved with standard molecular analyses. We describe a family presenting with a phenotype resembling inherited thrombocytopenia 2 (THC2). THC2 is generally caused by single nucleotide variants that prevent silencing of ANKRD26 expression during hematopoietic differentiation. Short-read whole-exome and genome sequencing approaches were unable to identify a causal variant in this family. Using long-read whole-genome sequencing, a large complex structural variant involving a paired-duplication inversion was identified. Through functional studies, we show that this structural variant results in a pathogenic gain-of-function WAC-ANKRD26 fusion transcript. Our findings illustrate how complex structural variants that may be missed by conventional genome sequencing approaches can cause human disease., Competing Interests: Disclosures: The authors declare no competing interests exist., (© 2021 Wahlster et al.)

Published

2021

4. Expanding the phenotypic spectrum in RDH12-associated retinal disease.

Author

Scott HA, Place EM, Ferenchak K, Zampaglione E, Wagner NE, Chao KR, DiTroia SP, Navarro-Gomez D, Mukai S, Huckfeldt RM, Pierce EA, and Bujakowska KM

Subjects

Adolescent, Adult, Alleles, Amino Acid Substitution, Child, Child, Preschool, Female, Genetic Loci, Humans, Male, Optical Imaging, Pedigree, Tomography, Optical Coherence, Exome Sequencing, Young Adult, Alcohol Oxidoreductases genetics, Genetic Association Studies methods, Genetic Predisposition to Disease, Mutation, Phenotype, Retinal Diseases diagnosis, Retinal Diseases genetics

Abstract

Retinol dehydrogenase 12, RDH12, plays a pivotal role in the visual cycle to ensure the maintenance of normal vision. Alterations in activity of this protein result in photoreceptor death and decreased vision beginning at an early age and progressing to substantial vision loss later in life. Here we describe 11 patients with retinal degeneration that underwent next-generation sequencing (NGS) with a targeted panel of all currently known inherited retinal degeneration (IRD) genes and whole-exome sequencing to identify the genetic causality of their retinal disease. These patients display a range of phenotypic severity prompting clinical diagnoses of macular dystrophy, cone-rod dystrophy, retinitis pigmentosa, and early-onset severe retinal dystrophy all attributed to biallelic recessive mutations in RDH12 We report 15 causal alleles and expand the repertoire of known RDH12 mutations with four novel variants: c.215A > G (p.Asp72Gly); c.362T > C (p.Ile121Thr); c.440A > C (p.Asn147Thr); and c.697G > A (p.Val233Ille). The broad phenotypic spectrum observed with biallelic RDH12 mutations has been observed in other genetic forms of IRDs, but the diversity is particularly notable here given the prior association of RDH12 primarily with severe early-onset disease. This breadth emphasizes the importance of broad genetic testing for inherited retinal disorders and extends the pool of individuals who may benefit from imminent gene-targeted therapies., (© 2020 Scott et al.; Published by Cold Spring Harbor Laboratory Press.)

Published

2020

5. Author Correction: Maternal vitamin C regulates reprogramming of DNA methylation and germline development.

Author

DiTroia SP, Percharde M, Guerquin MJ, Wall E, Collignon E, Ebata KT, Mesh K, Mahesula S, Agathocleous M, Laird DJ, Livera G, and Ramalho-Santos M

Abstract

An Amendment to this paper has been published and can be accessed via a link at the top of the paper.

Published

2019

6. Maternal vitamin C regulates reprogramming of DNA methylation and germline development.

Author

DiTroia SP, Percharde M, Guerquin MJ, Wall E, Collignon E, Ebata KT, Mesh K, Mahesula S, Agathocleous M, Laird DJ, Livera G, and Ramalho-Santos M

Subjects

Animals, Ascorbic Acid Deficiency physiopathology, Cell Count, DNA-Binding Proteins genetics, Epigenomics, Female, Loss of Function Mutation, Meiosis physiology, Mice, Models, Animal, Pregnancy, Proto-Oncogene Proteins genetics, Ascorbic Acid metabolism, DNA Methylation physiology, Germ Cells physiology, Transcriptome physiology

Abstract

Development is often assumed to be hardwired in the genome, but several lines of evidence indicate that it is susceptible to environmental modulation with potential long-term consequences, including in mammals 1,2 . The embryonic germline is of particular interest because of the potential for intergenerational epigenetic effects. The mammalian germline undergoes extensive DNA demethylation 3-7 that occurs in large part by passive dilution of methylation over successive cell divisions, accompanied by active DNA demethylation by TET enzymes 3,8-10 . TET activity has been shown to be modulated by nutrients and metabolites, such as vitamin C 11-15 . Here we show that maternal vitamin C is required for proper DNA demethylation and the development of female fetal germ cells in a mouse model. Maternal vitamin C deficiency does not affect overall embryonic development but leads to reduced numbers of germ cells, delayed meiosis and reduced fecundity in adult offspring. The transcriptome of germ cells from vitamin-C-deficient embryos is remarkably similar to that of embryos carrying a null mutation in Tet1. Vitamin C deficiency leads to an aberrant DNA methylation profile that includes incomplete demethylation of key regulators of meiosis and transposable elements. These findings reveal that deficiency in vitamin C during gestation partially recapitulates loss of TET1, and provide a potential intergenerational mechanism for adjusting fecundity to environmental conditions.

Published

2019