Your search keyword '"Duenas-Roque MM"' showing total 7 results

1. Clinical genome sequencing in patients with suspected rare genetic disease in Peru.

Author

Bazalar-Montoya J, Cornejo-Olivas M, Duenas-Roque MM, Purizaca-Rosillo N, Rodriguez RS, Milla-Neyra K, De La Torre-Hernandez CA, Sarapura-Castro E, Galarreta Aima CI, Manassero-Morales G, Chávez-Pasco G, Celis-García L, La Serna-Infantes JE, Chekalin E, Thorpe E, and Taft RJ

Abstract

There is limited access to molecular genetic testing in most low- and middle-income countries. The iHope program provides clinical genome sequencing (cGS) to underserved individuals with signs or symptoms of rare genetic diseases and limited or no access to molecular genetic testing. Here we describe the performance and impact of cGS in 247 patients from three clinics in Peru. Although most patients had at least one genetic test prior to cGS (70.9%), the most frequent was karyotyping (53.4%). The diagnostic yield of cGS was 54.3%, with candidate variants reported in an additional 22.3% of patients. Clinical GS results impacted clinician diagnostic evaluation in 85.0% and genetic counseling in 72.1% of cases. Changes in management were reported in 71.3%, inclusive of referrals (64.7%), therapeutics (26.3%), laboratory or physiological testing (25.5%), imaging (19%), and palliative care (17.4%), suggesting that increased availability of genomic testing in Peru would enable improved patient management., (© 2024. The Author(s).)

Published

2024

2. The impact of clinical genome sequencing in a global population with suspected rare genetic disease.

Author

Thorpe E, Williams T, Shaw C, Chekalin E, Ortega J, Robinson K, Button J, Jones MC, Campo MD, Basel D, McCarrier J, Keppen LD, Royer E, Foster-Bonds R, Duenas-Roque MM, Urraca N, Bosfield K, Brown CW, Lydigsen H, Mroczkowski HJ, Ward J, Sirchia F, Giorgio E, Vaux K, Salguero HP, Lumaka A, Mubungu G, Makay P, Ngole M, Lukusa PT, Vanderver A, Muirhead K, Sherbini O, Lah MD, Anderson K, Bazalar-Montoya J, Rodriguez RS, Cornejo-Olivas M, Milla-Neyra K, Shinawi M, Magoulas P, Henry D, Gibson K, Wiafe S, Jayakar P, Salyakina D, Masser-Frye D, Serize A, Perez JE, Taylor A, Shenbagam S, Abou Tayoun A, Malhotra A, Bennett M, Rajan V, Avecilla J, Warren A, Arseneault M, Kalista T, Crawford A, Ajay SS, Perry DL, Belmont J, and Taft RJ

Subjects

Humans, Male, Female, Child, Child, Preschool, Adolescent, Adult, Infant, Genetic Diseases, Inborn genetics, Genetic Diseases, Inborn diagnosis, Rare Diseases genetics, Rare Diseases diagnosis, Genetic Testing methods, Whole Genome Sequencing

Abstract

There is mounting evidence of the value of clinical genome sequencing (cGS) in individuals with suspected rare genetic disease (RGD), but cGS performance and impact on clinical care in a diverse population drawn from both high-income countries (HICs) and low- and middle-income countries (LMICs) has not been investigated. The iHope program, a philanthropic cGS initiative, established a network of 24 clinical sites in eight countries through which it provided cGS to individuals with signs or symptoms of an RGD and constrained access to molecular testing. A total of 1,004 individuals (median age, 6.5 years; 53.5% male) with diverse ancestral backgrounds (51.8% non-majority European) were assessed from June 2016 to September 2021. The diagnostic yield of cGS was 41.4% (416/1,004), with individuals from LMIC sites 1.7 times more likely to receive a positive test result compared to HIC sites (LMIC 56.5% [195/345] vs. HIC 33.5% [221/659], OR 2.6, 95% CI 1.9-3.4, p < 0.0001). A change in diagnostic evaluation occurred in 76.9% (514/668) of individuals. Change of management, inclusive of specialty referrals, imaging and testing, therapeutic interventions, and palliative care, was reported in 41.4% (285/694) of individuals, which increased to 69.2% (480/694) when genetic counseling and avoidance of additional testing were also included. Individuals from LMIC sites were as likely as their HIC counterparts to experience a change in diagnostic evaluation (OR 6.1, 95% CI 1.1-∞, p = 0.05) and change of management (OR 0.9, 95% CI 0.5-1.3, p = 0.49). Increased access to genomic testing may support diagnostic equity and the reduction of global health care disparities., Competing Interests: Declaration of interests E.T., E.C., K.R., J. Button, A.M., M.B., J.A., A.W., M.A., T.K., A.C., S.S.A., D.L.P., and R.J.T. were employees of and stockholders in Illumina, Inc. at the time of this investigation. V.R. is a stockholder in Illumina, Inc. J.O. is a stockholder in Illumina, Inc. and employee of C2N Diagnostics. J. Belmont and T.W. are stockholders in Illumina, Inc. and were compensated as research advisors through Genetics & Genomics Services Inc. C.S. was compensated as a consultant through Genetics & Genomics Services Inc. for statistical analysis. K.M. is an employee of Ambry Genetics., (Copyright © 2024 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2024

3. Damaging variants in FOXI3 cause microtia and craniofacial microsomia.

Author

Quiat D, Timberlake AT, Curran JJ, Cunningham ML, McDonough B, Artunduaga MA, DePalma SR, Duenas-Roque MM, Gorham JM, Gustafson JA, Hamdan U, Hing AV, Hurtado-Villa P, Nicolau Y, Osorno G, Pachajoa H, Porras-Hurtado GL, Quintanilla-Dieck L, Serrano L, Tumblin M, Zarante I, Luquetti DV, Eavey RD, Heike CL, Seidman JG, and Seidman CE

Subjects

Humans, Ear abnormalities, Face, Goldenhar Syndrome genetics, Congenital Microtia genetics, Micrognathism

Abstract

Purpose: Craniofacial microsomia (CFM) represents a spectrum of craniofacial malformations, ranging from isolated microtia with or without aural atresia to underdevelopment of the mandible, maxilla, orbit, facial soft tissue, and/or facial nerve. The genetic causes of CFM remain largely unknown., Methods: We performed genome sequencing and linkage analysis in patients and families with microtia and CFM of unknown genetic etiology. The functional consequences of damaging missense variants were evaluated through expression of wild-type and mutant proteins in vitro., Results: We studied a 5-generation kindred with microtia, identifying a missense variant in FOXI3 (p.Arg236Trp) as the cause of disease (logarithm of the odds = 3.33). We subsequently identified 6 individuals from 3 additional kindreds with microtia-CFM spectrum phenotypes harboring damaging variants in FOXI3, a regulator of ectodermal and neural crest development. Missense variants in the nuclear localization sequence were identified in cases with isolated microtia with aural atresia and found to affect subcellular localization of FOXI3. Loss of function variants were found in patients with microtia and mandibular hypoplasia (CFM), suggesting dosage sensitivity of FOXI3., Conclusion: Damaging variants in FOXI3 are the second most frequent genetic cause of CFM, causing 1% of all cases, including 13% of familial cases in our cohort., Competing Interests: Conflict of Interest The authors declare no conflicts of interest., (Copyright © 2022 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2023

4. Haploinsufficiency of SF3B2 causes craniofacial microsomia.

Author

Timberlake AT, Griffin C, Heike CL, Hing AV, Cunningham ML, Chitayat D, Davis MR, Doust SJ, Drake AF, Duenas-Roque MM, Goldblatt J, Gustafson JA, Hurtado-Villa P, Johns A, Karp N, Laing NG, Magee L, Mullegama SV, Pachajoa H, Porras-Hurtado GL, Schnur RE, Slee J, Singer SL, Staffenberg DA, Timms AE, Wise CA, Zarante I, Saint-Jeannet JP, and Luquetti DV

Subjects

Adolescent, Adult, Animals, Child, Exome genetics, Female, Genetic Association Studies, Goldenhar Syndrome pathology, Humans, Infant, Male, Mutation, Neural Crest growth & development, Neural Crest pathology, Pedigree, Spliceosomes genetics, Xenopus laevis, Goldenhar Syndrome genetics, Haploinsufficiency, RNA Splicing Factors genetics

Abstract

Craniofacial microsomia (CFM) is the second most common congenital facial anomaly, yet its genetic etiology remains unknown. We perform whole-exome or genome sequencing of 146 kindreds with sporadic (n = 138) or familial (n = 8) CFM, identifying a highly significant burden of loss of function variants in SF3B2 (P = 3.8 × 10 -10 ), a component of the U2 small nuclear ribonucleoprotein complex, in probands. We describe twenty individuals from seven kindreds harboring de novo or transmitted haploinsufficient variants in SF3B2. Probands display mandibular hypoplasia, microtia, facial and preauricular tags, epibulbar dermoids, lateral oral clefts in addition to skeletal and cardiac abnormalities. Targeted morpholino knockdown of SF3B2 in Xenopus results in disruption of cranial neural crest precursor formation and subsequent craniofacial cartilage defects, supporting a link between spliceosome mutations and impaired neural crest development in congenital craniofacial disease. The results establish haploinsufficient variants in SF3B2 as the most prevalent genetic cause of CFM, explaining ~3% of sporadic and ~25% of familial cases., (© 2021. The Author(s).)

Published

2021

5. New SHH and Known SIX3 Variants in a Series of Latin American Patients with Holoprosencephaly.

Author

de Castro VF, Mattos D, de Carvalho FM, Cavalcanti DP, Duenas-Roque MM, Llerena J Jr, Cosentino VR, Honjo RS, Leite JCL, Sanseverino MT, de Souza MPA, Bernardi P, Bolognese AM, Santana da Silva LC, Barbero P, Correia PS, Bueno LSM, Savastano CP, and Orioli IM

Abstract

Holoprosencephaly (HPE) is the failure of the embryonic forebrain to develop into 2 hemispheres promoting midline cerebral and facial defects. The wide phenotypic variability and causal heterogeneity make genetic counseling difficult. Heterozygous variants with incomplete penetrance and variable expressivity in the SHH , SIX3 , ZIC2 , and TGIF1 genes explain ∼25% of the known causes of nonchromosomal HPE. We studied these 4 genes and clinically described 27 Latin American families presenting with nonchromosomal HPE. Three new SHH variants and a third known SIX3 likely pathogenic variant found by Sanger sequencing explained 15% of our cases. Genotype-phenotype correlation in these 4 families and published families with identical or similar driver gene, mutated domain, conservation of residue in other species, and the type of variant explain the pathogenicity but not the phenotypic variability. Nine patients, including 2 with SHH pathogenic variants, presented benign variants of the SHH , SIX3 , ZIC2 , and TGIF1 genes with potential alteration of splicing, a causal proposition in need of further studies. Finding more families with the same SIX3 variant may allow further identification of genetic or environmental modifiers explaining its variable phenotypic expression., Competing Interests: The authors have no conflicts of interest to declare., (Copyright © 2021 by S. Karger AG, Basel.)

Published

2021

6. MYT1 role in the microtia-craniofacial microsomia spectrum.

Author

Luquetti DV, Heike CL, Zarante I, Timms AE, Gustafson J, Pachajoa H, Porras-Hurtado GL, Ayala-Ramirez P, Duenas-Roque MM, Jimenez N, Ibanez LM, and Hurtado-Villa P

Subjects

Child, Congenital Microtia pathology, Female, Goldenhar Syndrome pathology, Humans, Male, Mutation, Syndrome, Congenital Microtia genetics, DNA-Binding Proteins genetics, Goldenhar Syndrome genetics, Transcription Factors genetics

Abstract

Background: Craniofacial microsomia (CFM), also known as the oculo-auriculo-vertebral spectrum, comprises a variable phenotype with the most common features including microtia and mandibular hypoplasia on one or both sides, in addition to lateral oral clefts, epibulbar dermoids, cardiac, vertebral, and renal abnormalities. The etiology of CFM is largely unknown. The MYT1 gene has been reported as a candidate based in mutations found in three unrelated individuals. Additional patients with mutations in this gene are required to establish its causality. We present two individuals with CFM that have rare variants in MYT1 contributing to better understand the genotype and phenotype associated with mutations in this gene., Methods/results: We conducted genetic analysis using whole-exome and -genome sequencing in 128 trios with CFM. Two novel MYT1 mutations were identified in two participants. Sanger sequencing was used to confirm these mutations., Conclusion: We identified two additional individuals with CFM who carry rare variants in MYT1, further supporting the presumptive role of this gene in the CFM spectrum., (© 2020 The Authors. Molecular Genetics & Genomic Medicine published by Wiley Periodicals LLC.)

Published

2020

7. Turner syndrome in diverse populations.

Author

Kruszka P, Addissie YA, Tekendo-Ngongang C, Jones KL, Savage SK, Gupta N, Sirisena ND, Dissanayake VHW, Paththinige CS, Aravena T, Nampoothiri S, Yesodharan D, Girisha KM, Patil SJ, Jamuar SS, Goh JC, Utari A, Sihombing N, Mishra R, Chitrakar NS, Iriele BC, Lulseged E, Megarbane A, Uwineza A, Oyenusi EE, Olopade OB, Fasanmade OA, Duenas-Roque MM, Thong MK, Tung JYL, Mok GTK, Fleischer N, Rwegerera GM, de Herreros MB, Watts J, Fieggen K, Huckstadt V, Moresco A, Obregon MG, Hussen DF, Ashaat NA, Ashaat EA, Chung BHY, Badoe E, Faradz SMH, El Ruby MO, Shotelersuk V, Wonkam A, Ekure EN, Phadke SR, Richieri-Costa A, and Muenke M

Subjects

Abnormalities, Multiple diagnosis, Abnormalities, Multiple genetics, Abnormalities, Multiple physiopathology, Adolescent, Adult, Asian People genetics, Child, Child, Preschool, Chromosomes, Human, X genetics, Face pathology, Facial Recognition, Female, Hispanic or Latino genetics, Humans, Infant, Infant, Newborn, Male, Middle Aged, Noonan Syndrome diagnosis, Noonan Syndrome genetics, Noonan Syndrome physiopathology, Phenotype, Population Surveillance, Turner Syndrome diagnosis, Turner Syndrome genetics, Turner Syndrome physiopathology, White People genetics, Young Adult, Abnormalities, Multiple epidemiology, Face abnormalities, Noonan Syndrome epidemiology, Turner Syndrome epidemiology

Abstract

Turner syndrome (TS) is a common multiple congenital anomaly syndrome resulting from complete or partial absence of the second X chromosome. In this study, we explore the phenotype of TS in diverse populations using clinical examination and facial analysis technology. Clinical data from 78 individuals and images from 108 individuals with TS from 19 different countries were analyzed. Individuals were grouped into categories of African descent (African), Asian, Latin American, Caucasian (European descent), and Middle Eastern. The most common phenotype features across all population groups were short stature (86%), cubitus valgus (76%), and low posterior hairline 70%. Two facial analysis technology experiments were conducted: TS versus general population and TS versus Noonan syndrome. Across all ethnicities, facial analysis was accurate in diagnosing TS from frontal facial images as measured by the area under the curve (AUC). An AUC of 0.903 (p < .001) was found for TS versus general population controls and 0.925 (p < .001) for TS versus individuals with Noonan syndrome. In summary, we present consistent clinical findings from global populations with TS and additionally demonstrate that facial analysis technology can accurately distinguish TS from the general population and Noonan syndrome., (Published 2019. This article is a U.S. Government work and is in the public domain in the USA.)

Published

2020