Your search keyword '"Daniel C Koboldt"' showing total 6 results

1. Biallelic SEPSECS variants in two siblings with pontocerebellar hypoplasia type 2D underscore the relevance of splice-disrupting synonymous variants in disease

Author

Swetha Ramadesikan, Scott E Hickey, Emily De Los Reyes, Anup D Patel, Samuel J Franklin, Patrick Brennan, Erin Crist, Kristy Lee, Peter White, Kim L McBride, Daniel C Koboldt, and Richard K Wilson

Subjects

General Medicine

Abstract

Noncoding and synonymous coding variants that exert their effects via alternative splicing are increasingly recognized as an important category of disease-causing variants. In this report, we describe two siblings who presented with hypotonia, profound developmental delays, and seizures. Brain MRI in the proband at 5 years showed diffuse cerebral and cerebellar white matter volume loss. Both siblings later developed ventilator-dependent respiratory insufficiency, scoliosis and are currently nonverbal and non-ambulatory. Extensive molecular testing including oligo array and clinical exome sequencing was non-diagnostic. Research genome sequencing under an IRB-approved study protocol revealed that both affected children were compound-heterozygous for variants in the SEPSECS gene. One variant was an initiator codon change (c.1A>T) that disrupted protein translation, consistent with the observation that most disease-causing variants are loss-of-function changes. The other variant was a coding change (c.846G>A) that was predicted to be synonymous but had been demonstrated to disrupt mRNA splicing in a minigene assay. SEPSECS gene encodes O-phosphoseryl-tRNA(Sec) selenium transferase; an enzyme that participates in the biosynthesis and transport of selenoproteins in the body. Variations in SEPSECS cause autosomal recessive pontocerebellar hypoplasia type 2D (PCHT 2D; OMIM #613811), a neurodegenerative condition characterized by progressive cerebrocerebellar atrophy, microcephaly, and epileptic encephalopathy. The identification of biallelic pathogenic variants in this family- one of which was a synonymous change not identified by prior clinical testing- not only ended the diagnostic odyssey for this family, but also highlights the contribution of occult pathogenic variants that may not be recognized by standard genetic testing methodologies.

Published

2022

2. Inherited and de novo variants extend the etiology of TAOK1-associated neurodevelopmental disorder

Author

Jesse M Hunter, Lauren J Massingham, Kandamurugu Manickam, Dennis Bartholomew, Rachel K Williamson, Jennifer L Schwab, Mohammad Marhabaie, Amy Siemon, Emily de los Reyes, Shalini C Reshmi, Catherine E Cottrell, Richard K Wilson, and Daniel C Koboldt

Subjects

General Medicine

Abstract

Alterations in the TAOK1 gene have recently emerged as the cause of developmental delay with or without intellectual impairment or behavioral abnormalities (MIM #619575). The thirty-two cases currently described in the literature have predominantly de novo alterations in TAOK1 and a wide spectrum of neurodevelopmental abnormalities. Here, we report four patients with novel pathogenic TAOK1 variants identified by research genome sequencing, clinical exome sequencing, and international matchmaking. The overlapping clinical features of our patients are consistent with the emerging core phenotype of TAOK1-associated syndrome: facial dysmorphism, feeding difficulties, global developmental delay, joint laxity, and hypotonia. However, behavioral abnormalities and gastrointestinal issues are more common in our cohort than previously reported. Two patients have de novo TAOK1 variants (one missense, one splice site) consistent with most known alterations in this gene. However, we also report the first sibling pair who both inherited a TAOK1 frameshift variant from a mildly affected mother. Our findings suggest that incomplete penetrance and variable expressivity are relatively common in TAOK1-associated syndrome, which holds important implications for clinical genetic testing.

Published

2022

3. Maternal mosaicism for a missense variant in the SMS gene that causes Snyder–Robinson syndrome

Author

Peter White, Daniel C. Koboldt, Theresa Mihalic Mosher, Scott E. Hickey, Mohammad Marhabaie, Samuel J Franklin, Samantha Choi, Kathleen M. Schieffer, Olivia Grischow, David M Gordon, Katherine E. Miller, and Richard K. Wilson

Subjects

Proband, Sanger sequencing, Genetics, biology, General Medicine, medicine.disease_cause, Hypotonia, symbols.namesake, Spermine synthase, biology.protein, symbols, medicine, Missense mutation, medicine.symptom, Hyperinsulinemic hypoglycemia, Gene, Allele frequency

Abstract

There is increasing recognition for the contribution of genetic mosaicism to human disease, particularly as high-throughput sequencing has enabled detection of sequence variants at very low allele frequencies. Here, we describe an infant male who presented at 9 mo of age with hypotonia, dysmorphic features, congenital heart disease, hyperinsulinemic hypoglycemia, hypothyroidism, and bilateral sensorineural hearing loss. Whole-genome sequencing of the proband and the parents uncovered an apparent de novo mutation in the X-linked SMS gene. SMS encodes spermine synthase, which catalyzes the production of spermine from spermidine. Inactivation of the SMS gene disrupts the spermidine/spermine ratio, resulting in Snyder–Robinson syndrome. The variant in our patient is absent from the gnomAD and ExAC databases and causes a missense change (p.Arg130Cys) predicted to be damaging by most in silico tools. Although Sanger sequencing confirmed the de novo status in our proband, polymerase chain reaction (PCR) and deep targeted resequencing to ∼84,000×–175,000× depth revealed that the variant is present in blood from the unaffected mother at ∼3% variant allele frequency. Our findings thus provided a long-sought diagnosis for the family while highlighting the role of parental mosaicism in severe genetic disorders.

Published

2021

4. Early-onset Wilson disease caused by ATP7B exon skipping associated with intronic variant

Author

Scott E. Hickey, Tracy A. Bedrosian, Bimal Chaudhari, Erin Crist, Kim L. McBride, Peter White, Theresa Mihalic Mosher, Daniel C. Koboldt, Stephen G. Kaler, and Richard K. Wilson

Subjects

Genetics, Proband, Exon, medicine.diagnostic_test, Gene duplication, medicine, Missense mutation, splice, General Medicine, Biology, Exon skipping, Frameshift mutation, Genetic testing

Abstract

Wilson disease is a medically actionable rare autosomal recessive disorder of defective copper excretion caused by mutations in ATP7B, one of two highly evolutionarily conserved copper-transporting ATPases. Hundreds of disease-causing variants in ATP7B have been reported to public databases; more than half of these are missense changes, and a significant proportion are presumed unequivocal loss-of-function variants (nonsense, frameshift, and canonical splice site). Current molecular genetic testing includes sequencing all coding exons (±10 bp) as well as deletion/duplication testing, with reported sensitivity of >98%. We report a proband from a consanguineous family with a biochemical phenotype consistent with early-onset Wilson disease who tested negative on conventional molecular genetic testing. Using a combination of whole-genome sequencing and transcriptome sequencing, we found that the proband's disease is due to skipping of exons 6–7 of the ATP7B gene associated with a novel intronic variant (NM_000053.4:c.1947-19T > A) that alters a putative splicing enhancer element. This variant was also homozygous in the proband's younger sister, whose subsequent clinical evaluations revealed biochemical evidence of Wilson disease. Our work adds to emerging evidence that ATP7B exon skipping from deep intronic variants outside typical splice junctions is an important mechanism of Wilson disease; the variants responsible may elude standard genetic testing.

Published

2020

5. Novel in-frame FLNB deletion causes Larsen syndrome in a three-generation pedigree

Author

Brent Adler, Peter White, Theresa Mihalic Mosher, Kim L. McBride, Patrick J. Brennan, Richard K. Wilson, Scott E. Hickey, Beth A. Schmalz, Erin Crist, and Daniel C. Koboldt

Subjects

musculoskeletal diseases, Adult, Male, Proband, Heterozygote, Knee Dislocation, Filamins, Population, Disease, Biology, Osteochondrodysplasias, Filamin, Congenital Abnormalities, congenital knee dislocation, medicine, Humans, aplasia/hypoplasia of the patella, Abnormalities, Multiple, Family, FLNB, Larsen syndrome, Family history, education, Sequence Deletion, Genetics, Arthrogryposis, education.field_of_study, Base Sequence, bilateral talipes equinovarus, General Medicine, Middle Aged, medicine.disease, Pedigree, joint laxity, Child, Preschool, Mutation, Female, medicine.symptom, Rapid Communication

Abstract

A 4-yr-old female with congenital knee dislocations and joint laxity was noted to have a strong maternal family history comprising multiple individuals with knee problems and clubfeet. As the knee issues were the predominant clinical features, clinical testing included sequencing of LMX1B, TBX2, and TBX4, which identified no significant variants. Research genome sequencing was performed in the proband, parents, and maternal grandfather. A heterozygous in-frame deletion in FLNB c. 5468_5470delAGG, which predicts p.(Glu1823del), segregated with the disease. The variant is rare in the gnomAD database, removes a residue that is evolutionarily conserved, and is predicted to alter protein length. Larsen syndrome may present with pathology that primarily involves one joint and thus may be difficult to differentiate clinically from other skeletal dysplasias or arthrogryposis syndromes. The p.(Glu1823del) variant maps to a filamin repeat domain where other disease-causing variants are clustered, consistent with a probable gain-of-function mechanism. It has reportedly been observed in two individuals in the gnomAD database, suggesting that mild presentations of Larsen syndrome, like the individual reported here, may be underdiagnosed in the general population.

Published

2019

6. A de novo nonsense mutation in ASXL3 shared by siblings with Bainbridge–Ropers syndrome

Author

Theresa Mihalic Mosher, Scott E. Hickey, Kim L. McBride, Benjamin J. Kelly, Richard K. Wilson, Emily Sites, Dennis Bartholomew, Peter White, and Daniel C. Koboldt

Subjects

0301 basic medicine, Genetics, medicine.medical_specialty, business.industry, Nonsense mutation, Germline mosaicism, General Medicine, 030105 genetics & heredity, medicine.disease, Hypotonia, 03 medical and health sciences, 030104 developmental biology, Intellectual disability, medicine, Medical genetics, medicine.symptom, Hypertelorism, business, Exome, Exome sequencing

Abstract

Two sisters (ages 16 yr and 15 yr) have been followed by our clinical genetics team for several years. Both girls have severe intellectual disability, hypotonia, seizures, and distinctive craniofacial features. The parents are healthy and have no other children. Oligo array, fragile X testing, and numerous single-gene tests were negative. All four family members underwent research exome sequencing, which revealed a heterozygous nonsense mutation in ASXL3 (p.R1036X) that segregated with disease. Exome data and independent Sanger sequencing confirmed that the variant is de novo, suggesting possible germline mosaicism in one parent. The p.R1036X variant has never been observed in healthy human populations and has been previously reported as a pathogenic mutation. Truncating de novo mutations in ASXL3 cause Bainbridge–Ropers syndrome (BRPS), a developmental disorder with similarities to Bohring–Opitz syndrome. Fewer than 30 BRPS patients have been described in the literature; to our knowledge, this is the first report of the disorder in two related individuals. Our findings lend further support to intellectual disability, absent speech, autistic traits, hypotonia, and distinctive facial appearance as common emerging features of Bainbridge–Ropers syndrome.

Published

2018