Brent L. Fogel scite author profile

Importance Clinical exome sequencing (CES) is rapidly becoming a common molecular diagnostic test for individuals with rare genetic disorders. Objective To report on initial clinical indications for CES referrals and molecular diagnostic rates for different indications and for different test types. Design, Setting, and Participants Clinical exome sequencing was performed on 814 consecutive patients with undiagnosed, suspected genetic conditions at the University of California, Los Angeles, Clinical Genomics Center between January 2012 and August 2014. Clinical exome sequencing was conducted as trio-CES (both parents and their affected child sequenced simultaneously) to effectively detect de novo and compound heterozygous variants or as proband-CES (only the affected individual sequenced) when parental samples were not available. Main outcomes and Measures Clinical indications for CES requests, molecular diagnostic rates of CES overall and for phenotypic subgroups, and differences in molecular diagnostic rates between trio-CES and proband-CES. Results Of the 814 cases, the overall molecular diagnosis rate was 26% (213 of 814; 95% CI, 23%-29%). The molecular diagnosis rate for trio-CES was 31% (127 of 410 cases; 95% CI, 27%-36%) and 22% (74 of 338 cases; 95% CI, 18%-27%) for proband-CES. In cases of developmental delay in children (<5 years, n = 138), the molecular diagnosis rate was 41% (45 of 109; 95% CI, 32%-51%) for trio-CES cases and 9% (2of 23, 95% CI, 1%-28%) for proband-CES cases. The significantly higher diagnostic yield (P value = .002; odds ratio, 7.4 [95% CI, 1.6-33.1]) of trio-CES was due to the identification of de novo and compound heterozygous variants. Conclusions and Relevance In this sample of patients with undiagnosed, suspected genetic conditions, trio-CES was associated with higher molecular diagnostic yield than proband-CES or traditional molecular diagnostic methods. Additional studies designed to validate these findings and to explore the effect of this approach on clinical and economic outcomes are warranted.

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Clinical features and molecular genetics of autosomal recessive cerebellar ataxias

Fogel¹,

Perlman²

2007

The Lancet Neurology

254

253

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Bioinformatics-Based Identification of Expanded Repeats: A Non-reference Intronic Pentamer Expansion in RFC1 Causes CANVAS

Rafehi

Szmulewicz

Bennett

et al. 2019

The American Journal of Human Genetics

200

233

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Genomic technologies such as next-generation sequencing (NGS) are revolutionizing molecular diagnostics and clinical medicine. However, these approaches have proven inefficient at identifying pathogenic repeat expansions. Here, we apply a collection of bioinformatics tools that can be utilized to identify either known or novel expanded repeat sequences in NGS data. We performed genetic studies of a cohort of 35 individuals from 22 families with a clinical diagnosis of cerebellar ataxia with neuropathy and bilateral vestibular areflexia syndrome (CANVAS). Analysis of whole-genome sequence (WGS) data with five independent algorithms identified a recessively inherited intronic repeat expansion [(AAGGG) exp ] in the gene encoding Replication Factor C1 (RFC1). This motif, not reported in the reference sequence, localized to an Alu element and replaced the reference (AAAAG) 11 short tandem repeat. Genetic analyses confirmed the pathogenic expansion in 18 of 22 CANVAS-affected families and identified a core ancestral haplotype, estimated to have arisen in Europe more than twenty-five thousand years ago. WGS of the four RFC1-negative CANVAS-affected families identified plausible variants in three, with genomic re-diagnosis of SCA3, spastic ataxia of the Charlevoix-Saguenay type, and SCA45. This study identified the genetic basis of CANVAS and demonstrated that these improved bioinformatics tools increase the diagnostic utility of WGS to determine the genetic basis of a heterogeneous group of clinically overlapping neurogenetic disorders.

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Exome Sequencing in the Clinical Diagnosis of Sporadic or Familial Cerebellar Ataxia

et al. 2014

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he diagnostic evaluation of a patient with chronic progressive cerebellar ataxia is clinically challenging. Cerebellar ataxia is associated with a heterogeneous array of neurologic conditions spanning common acquired etiologies to rare genetic disorders present only in single families. [1][2][3][4][5] Currently, more than 60 distinct neurogenetic conditions are known to cause primary cerebellar ataxia. In most cases, it is difficult to differentiate these disorders owing to phenotype variability within a disorder and overlap between disorders. [1][2][3][4][5] Further complicating matters, there are nearly 300 additional genetic conditions that can include cerebellar ataxia as a clinical finding. 6 Many patients present to clinicians with lateonset symptoms and no reported family history 7 and, in the absence of other identifying etiologies, the role of genetic disease in this population is not well understood. 1,3,5 The availability of next-generation clinical exome sequencing (CES) has made it possible to perform genomewide genetic evaluations for patients as part of a detailed clinical workup. 8,9 This is a potentially useful addition to the physician's armamentarium because, given the number of rare genes related to ataxia, overuse of low-yield single-gene and genetic panel testing represents a significant cost to patient health care. 7,10 The anticipated widespread benefits of CES have already prompted recommendations for its inclusion as part of routine clinical algorithms. 4,5,9,11,12 Although CES is much less expensive than sequentially examining mul-IMPORTANCE Cerebellar ataxias are a diverse collection of neurologic disorders with causes ranging from common acquired etiologies to rare genetic conditions. Numerous genetic disorders have been associated with chronic progressive ataxia and this consequently presents a diagnostic challenge for the clinician regarding how to approach and prioritize genetic testing in patients with such clinically heterogeneous phenotypes. Additionally, while the value of genetic testing in early-onset and/or familial cases seems clear, many patients with ataxia present sporadically with adult onset of symptoms and the contribution of genetic variation to the phenotype of these patients has not yet been established.OBJECTIVE To investigate the contribution of genetic disease in a population of patients with predominantly adult-and sporadic-onset cerebellar ataxia. DESIGN, SETTING, AND PARTICIPANTSWe examined a consecutive series of 76 patients presenting to a tertiary referral center for evaluation of chronic progressive cerebellar ataxia. MAIN OUTCOMES AND MEASURESNext-generation exome sequencing coupled with comprehensive bioinformatic analysis, phenotypic analysis, and clinical correlation. RESULTSWe identified clinically relevant genetic information in more than 60% of patients studied (n = 46), including diagnostic pathogenic gene variants in 21% (n = 16), a notable yield given the diverse genetics and clinical heterogeneity of the cerebellar ataxias. CONCLUSIONS AND RELE...

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Mutations in XPR1 cause primary familial brain calcification associated with altered phosphate export

et al. 2015

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Primary familial brain calcification (PFBC) is a neurological disease characterized by calcium phosphate deposits in the basal ganglia and other brain regions, thus far associated with SLC20A2, PDGFB, or PDGFRB mutations. We identified in multiple PFBC families mutations in XPR1, a gene encoding a retroviral receptor with phosphate export function. These mutations alter phosphate export, providing a direct evidence of an impact of XPR1 and phosphate homeostasis in PFBC.

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Brent L. Fogel

Clinical Exome Sequencing for Genetic Identification of Rare Mendelian Disorders

Clinical features and molecular genetics of autosomal recessive cerebellar ataxias

Bioinformatics-Based Identification of Expanded Repeats: A Non-reference Intronic Pentamer Expansion in RFC1 Causes CANVAS

Exome Sequencing in the Clinical Diagnosis of Sporadic or Familial Cerebellar Ataxia

Mutations in XPR1 cause primary familial brain calcification associated with altered phosphate export

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