Your search keyword '"Brokamp E"' showing total 23 results

1. Next-Generation Phenotyping: Introducing PhecodeX for Enhanced Discovery Research in Medical Phenomics

Author

Shuey, MM, primary, Stead, WW, additional, Aka, I, additional, Barnado, AL, additional, Bastarache, JA, additional, Brokamp, E, additional, Campbell Joseph, MS, additional, Carroll, RJ, additional, Goldstein, JA, additional, Lewis, A, additional, Malow, BA, additional, Mosley, JD, additional, Osterman, T, additional, Padovani-Claudio, DA, additional, Ramirez, A, additional, Roden, DM, additional, Schuler, BA, additional, Siew, E, additional, Sucre, J, additional, Thomsen, I, additional, Tinker, RJ, additional, Van Driest, S, additional, Walsh, C, additional, Warner, JL, additional, Wells, QS, additional, Wheless, L, additional, and Bastarache, L, additional

Published

2023

2. Histone H3.3 beyond cancer: Germline mutations in Histone 3 Family 3A and 3B cause a previously unidentified neurodegenerative disorder in 46 patients

Author

Bryant, L. (Laura), Li, D. (Dong), Cox, S.G. (Samuel G.), Marchione, D. (Dylan), Joiner, E.F. (Evan F.), Wilson, K. (Khadija), Janssen, K. (Kevin), Lee, P. (Pearl), March, K. (Keith), Nair, D. (Divya), Sherr, E. (Elliott), Fregeau, B. (Brieana), Wierenga, K.J. (Klaas J.), Wadley, A. (Alexandrea), Mancini, G.M.S. (Grazia), Powell-Hamilton, N. (Nina), Kamp, J.J.P. (Jacques) van de, Grebe, T. (Theresa), Dean, J. (John), Ross, A.J. (Alison), Crawford, H.P. (Heather P.), Powis, Z. (Zoe), Cho, M.T. (Megan T.), Willing, M.C. (Marcia C.), Manwaring, L. (Linda), Schot, R. (Rachel), Nava, C. (Caroline), Afenjar, A. (Alexandra), Lessel, D. (Davor), Wagner, M. (Matias), Klopstock, T. (Thomas), Winkelmann, B., Catarino, C.B. (Claudia B.), Retterer, K. (Kyle), Schuette, J.L. (Jane L.), Innis, J.W. (Jeffrey), Pizzino, A. (Amy), Lüttgen, S. (Sabine), Denecke, J. (Jonas), Strom, T.M. (Tim), Monaghan, K.G. (Kristin G.), Yuan, Z.-F. (Zuo-Fei), Dubbs, H. (Holly), Bend, R. (Renee), Lee, J.A. (Jennifer A.), Lyons, M.J. (Michael J.), Hoefele, J. (Julia), Günthner, R. (Roman), Reutter, H. (Heiko), Keren, B. (Boris), Radtke, K. (Kelly), Sherbini, O. (Omar), Mrokse, C. (Cameron), Helbig, K.L. (Katherine L.), Odent, S. (Sylvie), Cogne, B. (Benjamin), Mercier, S. (Sandra), Bezieau, S. (Stephane), Besnard, T. (Thomas), Kury, S. (Sebastien), Redon, R. (Richard), Reinson, K. (Karit), Wojcik, M.H. (Monica H.), Õunap, K. (Katrin), Ilves, P. (Pilvi), Innes, A.M. (A Micheil), Kernohan, K.D. (Kristin), Costain, G. (Gregory), Meyn, M.S. (M Stephen), Chitayat, D. (David), Zackai, E. (Elaine), Lehman, A. (Anna), Kitson, H. (Hilary), Martin, M.G. (Martin G.), Martinez-Agosto, J.A. (Julian A.), Nelson, S.F. (Stan F.), Palmer, C.G.S. (Christina G S), Papp, J.C. (Jeanette C.), Parker, N.H. (Neil H.), Sinsheimer, J.S. (Janet S.), Vilain, E. (Eric), Wan, J. (Jijun), Yoon, A.J. (Amanda J.), Zheng, A. (Allison), Brimble, E. (Elise), Ferrero, G.B. (Giovanni Battista), Radio, F.C. (Francesca Clementina), Carli, D. (Diana), Barresi, S. (Sabina), Brusco, A. (Alfredo), Tartaglia, M. (Marco), Thomas, J.M. (Jennifer Muncy), Umana, L. (Luis), Weiss, M.M. (Marjan M.), Gotway, G. (Garrett), Stuurman, K.E. (Kyra), Thompson, M.L. (Michelle L.), McWalter, K. (Kirsty), Stumpel, C.T.R.M. (Constance T R M), Stevens, S.J.C. (Servi J C), Stegmann, A.P.A. (Alexander P A), Tveten, K. (Kristian), Vøllo, A. (Arve), Prescott, T. (Trine), Fagerberg, C. (Christina), Laulund, L.W. (Lone Walentin), Larsen, M.J. (Martin J.), Byler, M. (Melissa), Lebel, R.R. (Robert Roger), Hurst, A.C. (Anna C.), Dean, J. (Joy), Schrier Vergano, S.A. (Samantha A.), Norman, J. (Jennifer), Mercimek-Andrews, S. (Saadet), Neira, J. (Juanita), Van Allen, M.I. (Margot I.), Longo, N. (Nicola), Sellars, E. (Elizabeth), Louie, R.J. (Raymond J.), Cathey, S.S. (Sara S.), Brokamp, E. (Elly), Héron, D. (Delphine), Snyder, M. (Molly), Vanderver, A. (Adeline), Simon, C. (Celeste), de la Cruz, X. (Xavier), Padilla, N. (Natália), Crump, J.G. (J Gage), Chung, W. (Wendy), Garcia, B. (Benjamin), Hakonarson, H. (Hakon), Bhoj, E.J. (Elizabeth J.), Bryant, L. (Laura), Li, D. (Dong), Cox, S.G. (Samuel G.), Marchione, D. (Dylan), Joiner, E.F. (Evan F.), Wilson, K. (Khadija), Janssen, K. (Kevin), Lee, P. (Pearl), March, K. (Keith), Nair, D. (Divya), Sherr, E. (Elliott), Fregeau, B. (Brieana), Wierenga, K.J. (Klaas J.), Wadley, A. (Alexandrea), Mancini, G.M.S. (Grazia), Powell-Hamilton, N. (Nina), Kamp, J.J.P. (Jacques) van de, Grebe, T. (Theresa), Dean, J. (John), Ross, A.J. (Alison), Crawford, H.P. (Heather P.), Powis, Z. (Zoe), Cho, M.T. (Megan T.), Willing, M.C. (Marcia C.), Manwaring, L. (Linda), Schot, R. (Rachel), Nava, C. (Caroline), Afenjar, A. (Alexandra), Lessel, D. (Davor), Wagner, M. (Matias), Klopstock, T. (Thomas), Winkelmann, B., Catarino, C.B. (Claudia B.), Retterer, K. (Kyle), Schuette, J.L. (Jane L.), Innis, J.W. (Jeffrey), Pizzino, A. (Amy), Lüttgen, S. (Sabine), Denecke, J. (Jonas), Strom, T.M. (Tim), Monaghan, K.G. (Kristin G.), Yuan, Z.-F. (Zuo-Fei), Dubbs, H. (Holly), Bend, R. (Renee), Lee, J.A. (Jennifer A.), Lyons, M.J. (Michael J.), Hoefele, J. (Julia), Günthner, R. (Roman), Reutter, H. (Heiko), Keren, B. (Boris), Radtke, K. (Kelly), Sherbini, O. (Omar), Mrokse, C. (Cameron), Helbig, K.L. (Katherine L.), Odent, S. (Sylvie), Cogne, B. (Benjamin), Mercier, S. (Sandra), Bezieau, S. (Stephane), Besnard, T. (Thomas), Kury, S. (Sebastien), Redon, R. (Richard), Reinson, K. (Karit), Wojcik, M.H. (Monica H.), Õunap, K. (Katrin), Ilves, P. (Pilvi), Innes, A.M. (A Micheil), Kernohan, K.D. (Kristin), Costain, G. (Gregory), Meyn, M.S. (M Stephen), Chitayat, D. (David), Zackai, E. (Elaine), Lehman, A. (Anna), Kitson, H. (Hilary), Martin, M.G. (Martin G.), Martinez-Agosto, J.A. (Julian A.), Nelson, S.F. (Stan F.), Palmer, C.G.S. (Christina G S), Papp, J.C. (Jeanette C.), Parker, N.H. (Neil H.), Sinsheimer, J.S. (Janet S.), Vilain, E. (Eric), Wan, J. (Jijun), Yoon, A.J. (Amanda J.), Zheng, A. (Allison), Brimble, E. (Elise), Ferrero, G.B. (Giovanni Battista), Radio, F.C. (Francesca Clementina), Carli, D. (Diana), Barresi, S. (Sabina), Brusco, A. (Alfredo), Tartaglia, M. (Marco), Thomas, J.M. (Jennifer Muncy), Umana, L. (Luis), Weiss, M.M. (Marjan M.), Gotway, G. (Garrett), Stuurman, K.E. (Kyra), Thompson, M.L. (Michelle L.), McWalter, K. (Kirsty), Stumpel, C.T.R.M. (Constance T R M), Stevens, S.J.C. (Servi J C), Stegmann, A.P.A. (Alexander P A), Tveten, K. (Kristian), Vøllo, A. (Arve), Prescott, T. (Trine), Fagerberg, C. (Christina), Laulund, L.W. (Lone Walentin), Larsen, M.J. (Martin J.), Byler, M. (Melissa), Lebel, R.R. (Robert Roger), Hurst, A.C. (Anna C.), Dean, J. (Joy), Schrier Vergano, S.A. (Samantha A.), Norman, J. (Jennifer), Mercimek-Andrews, S. (Saadet), Neira, J. (Juanita), Van Allen, M.I. (Margot I.), Longo, N. (Nicola), Sellars, E. (Elizabeth), Louie, R.J. (Raymond J.), Cathey, S.S. (Sara S.), Brokamp, E. (Elly), Héron, D. (Delphine), Snyder, M. (Molly), Vanderver, A. (Adeline), Simon, C. (Celeste), de la Cruz, X. (Xavier), Padilla, N. (Natália), Crump, J.G. (J Gage), Chung, W. (Wendy), Garcia, B. (Benjamin), Hakonarson, H. (Hakon), and Bhoj, E.J. (Elizabeth J.)

Abstract

Although somatic mutations in Histone 3.3 (H3.3) are well-studied drivers of oncogenesis, the role of germline mutations remains unreported. We analyze 46 patients bearing de novo germline mutations in histone 3 family 3A (H3F3A) or H3F3B with progressive neurologic dysfunction and congenital anomalies without malignancies. Molecular modeling of all 37 variants demonstrated clear disruptions in interactions with DNA, other histones, and histone chaperone proteins. Patient histone posttranslational modifications (PTMs) analysis revealed notably aberrant local PTM patterns distinct from the somatic lysine mutations that cause global PTM dysregulation. RNA sequencing on patient cells demonstrated up-regulated gene expression related to mitosis and cell division, and cellular assays confirmed an increased proliferative capacity. A zebrafish model showed craniofacial anomalies and a defect in Foxd3-derived glia. These data suggest that the mechanism of germline mutations are distinct from cancer-associated somatic histone mutations but may converge on control of cell proliferation.

Published

2020

3. Spectrum of neurodevelopmental disease associated with the GNAO1 guanosine triphosphate-binding region

Author

Kelly, M, Park, M, Mihalek, I, Rochtus, A, Gramm, M, Perez-Palma, E, Axeen, ET, Hung, CY, Olson, H, Swanson, L, Anselm, I, Briere, LC, High, FA, Sweetser, DA, Kayani, S, Snyder, M, Calvert, S, Scheffer, IE, Yang, E, Waugh, JL, Lal, D, Bodamer, O, Poduri, A, Adams, DR, Aday, A, Alejandro, ME, Allard, P, Ashley, EA, Azamian, MS, Bacino, CA, Baker, E, Balasubramanyam, A, Barseghyan, H, Batzli, GF, Beggs, AH, Behnam, B, Bellen, HJ, Bernstein, JA, Bican, A, Bick, DP, Birch, CL, Bonner, D, Boone, BE, Bostwick, BL, Brokamp, E, Brown, DM, Brush, M, Burke, EA, Burrage, LC, Butte, MJ, Chen, S, Clark, GD, Coakley, TR, Cogan, JD, Colley, HA, Cooper, CM, Cope, H, Craigen, WJ, D'Souza, P, Davids, M, Davidson, JM, Dayal, JG, Dell'Angelica, EC, Dhar, SU, Dipple, KM, Donnell-Fink, LA, Dorrani, N, Dorset, DC, Douine, ED, Draper, DD, Dries, AM, Eckstein, DJ, Emrick, LT, Eng, CM, Enns, G-GM, Eskin, A, Esteves, C, Estwick, T, Fairbrother, L, Fernandez, L, Ferreira, C, Fieg, EL, Fisher, PG, Fogel, BL, Friedman, ND, Gahl, WA, Glanton, E, Godfrey, RA, Goldman, AM, Goldstein, DB, Gould, SE, Gourdine, J-PF, Groden, CA, Gropman, AL, Haendel, M, Hamid, R, Hanchard, NA, High, F, Holm, IA, Horn, J, Howerton, EM, Huang, Y, Jamal, F, Jiang, Y-H, Johnston, JM, Jones, AL, Karaviti, L, Koeller, DM, Kohane, IS, Kohler, JN, Konick, S, Koziura, M, Krasnewich, DM, Krier, JB, Kyle, JE, Lalani, SR, Lau, CC, Lazar, J, LeBlanc, K, Lee, BH, Lee, H, Levy, SE, Lewis, RA, Lincoln, SA, Loo, SK, Loscalzo, J, Maas, RL, Macnamara, EF, MacRae, CA, Maduro, VV, Majch-erska, MM, Malicdan, MC, Mamounas, LA, Manolio, TA, Markello, TC, Marom, R, Martin, MG, Martinez-Agosto, JA, Mar-waha, S, May, T, McConkie-Rosell, A, McCormack, CE, McCray, AF, Merker, JD, Metz, TO, Might, M, Moretti, PM, Morimoto, M, Mulvihill, JJ, Murdock, DR, Murphy, JL, Muzny, DM, Nehrebecky, ME, Nelson, SF, Newberry, JS, Newman, JH, Nicholas, SK, Novacic, D, Orange, JS, Orengo, JP, Pallais, JC, Palmer, CGS, Papp, JC, Parker, NH, Pena, LDM, Phillips, JA, Posey, JE, Postlethwait, JH, Potocki, L, Pusey, BN, Reuter, CM, Rives, L, Robertson, AK, Rodan, LH, Rosenfeld, JA, Sampson, JB, Samson, SL, Schoch, K, Scott, DA, Shakachite, L, Sharma, P, Shashi, V, Signer, R, Silverman, EK, Sinsheimer, JS, Smith, KS, Spillmann, RC, Stoler, JM, Stong, N, Sullivan, JA, Tan, QK-G, Tifft, CJ, Toro, C, Tran, AA, Urv, TK, Vilain, E, Vogel, TP, Waggott, DM, Wahl, CE, Walker, M, Walley, NM, Walsh, CA, Wan, J, Wangler, MF, Ward, PA, Waters, KM, Webb-Robertson, B-JM, Westerfield, M, Wheeler, MT, Wise, AL, Wolfe, LA, Worthey, EA, Yamamoto, S, Yang, Y, Yoon, AJ, Yu, G, Zastrow, DB, Zhao, C, Zheng, A, Kelly, M, Park, M, Mihalek, I, Rochtus, A, Gramm, M, Perez-Palma, E, Axeen, ET, Hung, CY, Olson, H, Swanson, L, Anselm, I, Briere, LC, High, FA, Sweetser, DA, Kayani, S, Snyder, M, Calvert, S, Scheffer, IE, Yang, E, Waugh, JL, Lal, D, Bodamer, O, Poduri, A, Adams, DR, Aday, A, Alejandro, ME, Allard, P, Ashley, EA, Azamian, MS, Bacino, CA, Baker, E, Balasubramanyam, A, Barseghyan, H, Batzli, GF, Beggs, AH, Behnam, B, Bellen, HJ, Bernstein, JA, Bican, A, Bick, DP, Birch, CL, Bonner, D, Boone, BE, Bostwick, BL, Brokamp, E, Brown, DM, Brush, M, Burke, EA, Burrage, LC, Butte, MJ, Chen, S, Clark, GD, Coakley, TR, Cogan, JD, Colley, HA, Cooper, CM, Cope, H, Craigen, WJ, D'Souza, P, Davids, M, Davidson, JM, Dayal, JG, Dell'Angelica, EC, Dhar, SU, Dipple, KM, Donnell-Fink, LA, Dorrani, N, Dorset, DC, Douine, ED, Draper, DD, Dries, AM, Eckstein, DJ, Emrick, LT, Eng, CM, Enns, G-GM, Eskin, A, Esteves, C, Estwick, T, Fairbrother, L, Fernandez, L, Ferreira, C, Fieg, EL, Fisher, PG, Fogel, BL, Friedman, ND, Gahl, WA, Glanton, E, Godfrey, RA, Goldman, AM, Goldstein, DB, Gould, SE, Gourdine, J-PF, Groden, CA, Gropman, AL, Haendel, M, Hamid, R, Hanchard, NA, High, F, Holm, IA, Horn, J, Howerton, EM, Huang, Y, Jamal, F, Jiang, Y-H, Johnston, JM, Jones, AL, Karaviti, L, Koeller, DM, Kohane, IS, Kohler, JN, Konick, S, Koziura, M, Krasnewich, DM, Krier, JB, Kyle, JE, Lalani, SR, Lau, CC, Lazar, J, LeBlanc, K, Lee, BH, Lee, H, Levy, SE, Lewis, RA, Lincoln, SA, Loo, SK, Loscalzo, J, Maas, RL, Macnamara, EF, MacRae, CA, Maduro, VV, Majch-erska, MM, Malicdan, MC, Mamounas, LA, Manolio, TA, Markello, TC, Marom, R, Martin, MG, Martinez-Agosto, JA, Mar-waha, S, May, T, McConkie-Rosell, A, McCormack, CE, McCray, AF, Merker, JD, Metz, TO, Might, M, Moretti, PM, Morimoto, M, Mulvihill, JJ, Murdock, DR, Murphy, JL, Muzny, DM, Nehrebecky, ME, Nelson, SF, Newberry, JS, Newman, JH, Nicholas, SK, Novacic, D, Orange, JS, Orengo, JP, Pallais, JC, Palmer, CGS, Papp, JC, Parker, NH, Pena, LDM, Phillips, JA, Posey, JE, Postlethwait, JH, Potocki, L, Pusey, BN, Reuter, CM, Rives, L, Robertson, AK, Rodan, LH, Rosenfeld, JA, Sampson, JB, Samson, SL, Schoch, K, Scott, DA, Shakachite, L, Sharma, P, Shashi, V, Signer, R, Silverman, EK, Sinsheimer, JS, Smith, KS, Spillmann, RC, Stoler, JM, Stong, N, Sullivan, JA, Tan, QK-G, Tifft, CJ, Toro, C, Tran, AA, Urv, TK, Vilain, E, Vogel, TP, Waggott, DM, Wahl, CE, Walker, M, Walley, NM, Walsh, CA, Wan, J, Wangler, MF, Ward, PA, Waters, KM, Webb-Robertson, B-JM, Westerfield, M, Wheeler, MT, Wise, AL, Wolfe, LA, Worthey, EA, Yamamoto, S, Yang, Y, Yoon, AJ, Yu, G, Zastrow, DB, Zhao, C, and Zheng, A

Abstract

OBJECTIVE: To characterize the phenotypic spectrum associated with GNAO1 variants and establish genotype-protein structure-phenotype relationships. METHODS: We evaluated the phenotypes of 14 patients with GNAO1 variants, analyzed their variants for potential pathogenicity, and mapped them, along with those in the literature, on a three-dimensional structural protein model. RESULTS: The 14 patients in our cohort, including one sibling pair, had 13 distinct, heterozygous GNAO1 variants classified as pathogenic or likely pathogenic. We attributed the same variant in two siblings to parental mosaicism. Patients initially presented with seizures beginning in the first 3 months of life (8/14), developmental delay (4/14), hypotonia (1/14), or movement disorder (1/14). All patients had hypotonia and developmental delay ranging from mild to severe. Nine had epilepsy, and nine had movement disorders, including dystonia, ataxia, chorea, and dyskinesia. The 13 GNAO1 variants in our patients are predicted to result in amino acid substitutions or deletions in the GNAO1 guanosine triphosphate (GTP)-binding region, analogous to those in previous publications. Patients with variants affecting amino acids 207-221 had only movement disorder and hypotonia. Patients with variants affecting the C-terminal region had the mildest phenotypes. SIGNIFICANCE: GNAO1 encephalopathy most frequently presents with seizures beginning in the first 3 months of life. Concurrent movement disorders are also a prominent feature in the spectrum of GNAO1 encephalopathy. All variants affected the GTP-binding domain of GNAO1, highlighting the importance of this region for G-protein signaling and neurodevelopment.

Published

2019

4. Understanding Adult Participant and Parent Empowerment Prior to Evaluation in the Undiagnosed Diseases Network

Author

Palmer, CGS, McConkie-Rosell, A, Holm, IA, LeBlanc, K, Sinsheimer, JS, Briere, LC, Dorrani, N, Herzog, MR, Lincoln, S, Schoch, K, Spillmann, RC, Brokamp, E, and Network, UD

Subjects

Parents, Adult, Male, Decision Making, Clinical Sciences, Pilot Projects, Genetic Counseling, Clinical Research, Surveys and Questionnaires, Diagnosis, Humans, Patient Reported Outcome Measures, Adaptation, Child, Genetics & Heredity, Undiagnosed condition, Uncertainty, Reproducibility of Results, Infant, Disease Management, Undiagnosed Diseases Network, Support groups, Power, Psychological, Female, Empowerment, Undiagnosed disease

Abstract

The burden of living with an undiagnosed condition is high and includes physical and emotional suffering, frustrations, and uncertainty. For patients and families experiencing these stressors, higher levels of empowerment may be associated with better outcomes. Thus, it is important to understand the experiences of patients with undiagnosed conditions and their families affected by undiagnosed conditions in order to identify strategies for fostering empowerment. In this study, we used the Genetic Counseling Outcome Scale (GCOS-24) to assess levels of empowerment and support group participation in 35 adult participants and 67 parents of child participants in the Undiagnosed Diseases Network (UDN) prior to their UDN in-person evaluation. Our results revealed significantly lower empowerment scores on the GCOS-24 in adult participants compared to parents of child participants [t(100) = - 3.01, p = 0.003, average difference = - 11.12, 95% CI (- 3.78, - 18.46)] and no significant association between support group participation and empowerment scores. The majority of participants (84.3%, 86/102) are not currently participating in any support groups, and participation rates were not significantly different for adult participants and parents of child participants (11.4 vs. 19.7%, respectively, FE p = 0.40). Open-ended responses provided additional insight into support group participation, the challenges of living with undiagnosed conditions, and positive coping strategies. Future research will evaluate the extent to which empowerment scores change as participation in the UDN unfolds.

Published

2018

5. De novo variants in DENND5B cause a neurodevelopmental disorder.

Author

Scala M, Tomati V, Ferla M, Lena M, Cohen JS, Fatemi A, Brokamp E, Bican A, Phillips JA 3rd, Koziura ME, Nicouleau M, Rio M, Siquier K, Boddaert N, Musante I, Tamburro S, Baldassari S, Iacomino M, Scudieri P, Rosenfeld JA, Bellus G, Reed S, Al Saif H, Russo RS, Walsh MB, Cantagrel V, Crunk A, Gustincich S, Ruggiero SM, Fitzgerald MP, Helbig I, Striano P, Severino M, Salpietro V, Pedemonte N, and Zara F

Subjects

Humans, Brain metabolism, Guanine Nucleotide Exchange Factors genetics, Guanine Nucleotide Exchange Factors metabolism, Lipids, rab GTP-Binding Proteins metabolism, Neurodevelopmental Disorders genetics, Neurodevelopmental Disorders metabolism, Epilepsy genetics, Epilepsy metabolism, Intellectual Disability genetics, Intellectual Disability metabolism

Abstract

The Rab family of guanosine triphosphatases (GTPases) includes key regulators of intracellular transport and membrane trafficking targeting specific steps in exocytic, endocytic, and recycling pathways. DENND5B (Rab6-interacting Protein 1B-like protein, R6IP1B) is the longest isoform of DENND5, an evolutionarily conserved DENN domain-containing guanine nucleotide exchange factor (GEF) that is highly expressed in the brain. Through exome sequencing and international matchmaking platforms, we identified five de novo variants in DENND5B in a cohort of five unrelated individuals with neurodevelopmental phenotypes featuring cognitive impairment, dysmorphism, abnormal behavior, variable epilepsy, white matter abnormalities, and cortical gyration defects. We used biochemical assays and confocal microscopy to assess the impact of DENND5B variants on protein accumulation and distribution. Then, exploiting fluorescent lipid cargoes coupled to high-content imaging and analysis in living cells, we investigated whether DENND5B variants affected the dynamics of vesicle-mediated intracellular transport of specific cargoes. We further generated an in silico model to investigate the consequences of DENND5B variants on the DENND5B-RAB39A interaction. Biochemical analysis showed decreased protein levels of DENND5B mutants in various cell types. Functional investigation of DENND5B variants revealed defective intracellular vesicle trafficking, with significant impairment of lipid uptake and distribution. Although none of the variants affected the DENND5B-RAB39A interface, all were predicted to disrupt protein folding. Overall, our findings indicate that DENND5B variants perturb intracellular membrane trafficking pathways and cause a complex neurodevelopmental syndrome with variable epilepsy and white matter involvement., Competing Interests: Declaration of interests A.C. is an employee of GeneDx, LLC. The Department of Molecular and Human Genetics at Baylor College of Medicine receives revenue from clinical genetic testing completed at Baylor Genetics Laboratories., (Copyright © 2024 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2024

6. Next-generation phenotyping: introducing phecodeX for enhanced discovery research in medical phenomics.

Author

Shuey MM, Stead WW, Aka I, Barnado AL, Bastarache JA, Brokamp E, Campbell M, Carroll RJ, Goldstein JA, Lewis A, Malow BA, Mosley JD, Osterman T, Padovani-Claudio DA, Ramirez A, Roden DM, Schuler BA, Siew E, Sucre J, Thomsen I, Tinker RJ, Van Driest S, Walsh C, Warner JL, Wells QS, Wheless L, and Bastarache L

Subjects

Polymorphism, Single Nucleotide, Phenotype, Phenomics, Genome-Wide Association Study

Abstract

Motivation: Phecodes are widely used and easily adapted phenotypes based on International Classification of Diseases codes. The current version of phecodes (v1.2) was designed primarily to study common/complex diseases diagnosed in adults; however, there are numerous limitations in the codes and their structure., Results: Here, we present phecodeX, an expanded version of phecodes with a revised structure and 1,761 new codes. PhecodeX adds granularity to phenotypes in key disease domains that are under-represented in the current phecode structure-including infectious disease, pregnancy, congenital anomalies, and neonatology-and is a more robust representation of the medical phenome for global use in discovery research., Availability and Implementation: phecodeX is available at https://github.com/PheWAS/phecodeX., (© The Author(s) 2023. Published by Oxford University Press.)

Published

2023

7. Heterozygous rare variants in NR2F2 cause a recognizable multiple congenital anomaly syndrome with developmental delays.

Author

Ganapathi M, Matsuoka LS, March M, Li D, Brokamp E, Benito-Sanz S, White SM, Lachlan K, Ahimaz P, Sewda A, Bastarache L, Thomas-Wilson A, Stoler JM, Bramswig NC, Baptista J, Stals K, Demurger F, Cogne B, Isidor B, Bedeschi MF, Peron A, Amiel J, Zackai E, Schacht JP, Iglesias AD, Morton J, Schmetz A, Seidel V, Lucia S, Baskin SM, Thiffault I, Cogan JD, Gordon CT, Chung WK, Bowdin S, and Bhoj E

Subjects

Animals, Humans, COUP Transcription Factor II genetics, Muscle Hypotonia, Syndrome, Abnormalities, Multiple genetics, Abnormalities, Multiple diagnosis, Heart Defects, Congenital genetics, Hernias, Diaphragmatic, Congenital genetics, Intellectual Disability genetics

Abstract

Nuclear receptor subfamily 2 group F member 2 (NR2F2 or COUP-TF2) encodes a transcription factor which is expressed at high levels during mammalian development. Rare heterozygous Mendelian variants in NR2F2 were initially identified in individuals with congenital heart disease (CHD), then subsequently in cohorts of congenital diaphragmatic hernia (CDH) and 46,XX ovotesticular disorders/differences of sexual development (DSD); however, the phenotypic spectrum associated with pathogenic variants in NR2F2 remains poorly characterized. Currently, less than 40 individuals with heterozygous pathogenic variants in NR2F2 have been reported. Here, we review the clinical and molecular details of 17 previously unreported individuals with rare heterozygous NR2F2 variants, the majority of which were de novo. Clinical features were variable, including intrauterine growth restriction (IUGR), CHD, CDH, genital anomalies, DSD, developmental delays, hypotonia, feeding difficulties, failure to thrive, congenital and acquired microcephaly, dysmorphic facial features, renal failure, hearing loss, strabismus, asplenia, and vascular malformations, thus expanding the phenotypic spectrum associated with NR2F2 variants. The variants seen were predicted loss of function, including a nonsense variant inherited from a mildly affected mosaic mother, missense and a large deletion including the NR2F2 gene. Our study presents evidence for rare, heterozygous NR2F2 variants causing a highly variable syndrome of congenital anomalies, commonly associated with heart defects, developmental delays/intellectual disability, dysmorphic features, feeding difficulties, hypotonia, and genital anomalies. Based on the new and previous cases, we provide clinical recommendations for evaluating individuals diagnosed with an NR2F2-associated disorder., (© 2023. The Author(s), under exclusive licence to European Society of Human Genetics.)

Published

2023

8. GABRA1-Related Disorders: From Genetic to Functional Pathways.

Author

Musto E, Liao VWY, Johannesen KM, Fenger CD, Lederer D, Kothur K, Fisk K, Bennetts B, Vrielynck P, Delaby D, Ceulemans B, Weckhuysen S, Sparber P, Bouman A, Ardern-Holmes S, Troedson C, Battaglia DI, Goel H, Feyma T, Bakhtiari S, Tjoa L, Boxill M, Demina N, Shchagina O, Dadali E, Kruer M, Cantalupo G, Contaldo I, Polster T, Isidor B, Bova SM, Fazeli W, Wouters L, Miranda MJ, Darra F, Pede E, Le Duc D, Jamra RA, Küry S, Proietti J, McSweeney N, Brokamp E, Andrews PI, Gouray Garcia M, Chebib M, Møller RS, Ahring PK, and Gardella E

Abstract

Objective: Variants in GABRA1 have been associated with a broad epilepsy spectrum, ranging from genetic generalized epilepsies to developmental and epileptic encephalopathies. However, our understanding of what determines the phenotype severity and best treatment options remains inadequate. We therefore aimed to analyze the electroclinical features and the functional effects of GABRA1 variants to establish genotype-phenotype correlations., Methods: Genetic and electroclinical data of 27 individuals (22 unrelated and 2 families) harboring 20 different GABRA1 variants were collected and accompanied by functional analysis of 19 variants., Results: Individuals in this cohort could be assigned into different clinical subgroups based on the functional effect of their variant and its structural position within the GABRA1 subunit. A homogenous phenotype with mild cognitive impairment and infantile onset epilepsy (focal seizures, fever sensitivity, and electroencephalographic posterior epileptiform discharges) was described for variants in the extracellular domain and the small transmembrane loops. These variants displayed loss-of-function (LoF) effects, and the patients generally had a favorable outcome. A more severe phenotype was associated with variants in the pore-forming transmembrane helices. These variants displayed either gain-of-function (GoF) or LoF effects. GoF variants were associated with severe early onset neurodevelopmental disorders, including early infantile developmental and epileptic encephalopathy., Interpretation: Our data expand the genetic and phenotypic spectrum of GABRA1 epilepsies and permit delineation of specific subphenotypes for LoF and GoF variants, through the heterogeneity of phenotypes and variants. Generally, variants in the transmembrane helices cause more severe phenotypes, in particular GoF variants. These findings establish the basis for a better understanding of the pathomechanism and a precision medicine approach in GABRA1-related disorders. Further studies in larger populations are needed to provide a conclusive genotype-phenotype correlation. ANN NEUROL 2023., (© 2023 American Neurological Association.)

Published

2023

9. Practical considerations for reinterpretation of individual genetic variants.

Author

Appelbaum PS, Berger SM, Brokamp E, Brown HS, Burke W, Clayton EW, Evans BJ, Hamid R, Marchant GE, Martin DM, O'Connor BC, Pagán JA, Parens E, Roberts JL, Rowe J, Schneider J, Siegel K, Veenstra DL, and Chung WK

Subjects

Humans, Genetic Testing, Genetic Predisposition to Disease

Abstract

Competing Interests: Conflict of Interest W.K.C. is on the Regeneron Genetics Center Scientific Advisory Board and is a member of the Board of Directors of Prime Medicine. All other authors declare no conflicts of interest.

Published

2023

10. Challenges of variant reinterpretation: Opinions of stakeholders and need for guidelines.

Author

Berger SM, Appelbaum PS, Siegel K, Wynn J, Saami AM, Brokamp E, O'Connor BC, Hamid R, Martin DM, and Chung WK

Subjects

Focus Groups, Humans, Laboratories, Surveys and Questionnaires, Counselors, Genetic Testing

Abstract

Purpose: The knowledge used to classify genetic variants is continually evolving, and the classification can change on the basis of newly available data. Although up-to-date variant classification is essential for clinical management, reproductive planning, and identifying at-risk family members, there is no consistent practice across laboratories or clinicians on how or under what circumstances to perform variant reinterpretation., Methods: We conducted exploratory focus groups (N = 142) and surveys (N = 1753) with stakeholders involved in the process of variant reinterpretation (laboratory directors, clinical geneticists, genetic counselors, nongenetic providers, and patients/parents) to assess opinions on key issues, including initiation of reinterpretation, variants to report, termination of the responsibility to reinterpret, and concerns about consent, cost, and liability., Results: Stakeholders widely agreed that there should be no fixed termination point to the responsibility to reinterpret a previously reported genetic variant. There were significant concerns about liability and lack of agreement about many logistical aspects of variant reinterpretation., Conclusion: Our findings suggest a need to (1) develop consensus and (2) create transparency and awareness about the roles and responsibilities of parties involved in variant reinterpretation. These data provide a foundation for developing guidelines on variant reinterpretation that can aid in the development of a low-cost, scalable, and accessible approach., Competing Interests: Conflict of Interest W.K.C. is on the Regeneron Genetics Center Scientific Advisory Board and the Board of Directors of Prime Medicine. The other authors declare no conflicts of interest., (Copyright © 2022 American College of Medical Genetics and Genomics. Published by Elsevier Inc. All rights reserved.)

Published

2022

11. Correction to: An autosomal dominant neurological disorder caused by de novo variants in FAR1 resulting in uncontrolled synthesis of ether lipids.

Author

Ferdinandusse S, McWalter K, Te Brinke H, IJlst L, Mooijer PM, Ruiter JPN, van Lint AEM, Pras-Raves M, Wever E, Millan F, Guillen Sacoto MJ, Begtrup A, Tarnopolsky M, Brady L, Ladda RL, Sell SL, Nowak CB, Douglas J, Tian C, Ulm E, Perlman S, Drack AV, Chong K, Martin N, Brault J, Brokamp E, Toro C, Gahl WA, Macnamara EF, Wolfe L, Waisfisz Q, Zwijnenburg PJG, Ziegler A, Barth M, Smith R, Ellingwood S, Gaebler-Spira D, Bakhtiari S, Kruer MC, van Kampen AHC, Wanders RJA, Waterham HR, Cassiman D, and Vaz FM

Published

2021

12. One is the loneliest number: genotypic matchmaking using the electronic health record.

Author

Brokamp E, Koziura ME, Phillips JA 3rd, Tang LA, Cogan JD, Rives LC, Robertson AK, Duncan L, Bican A, Peterson JF, Newman JH, Hamid R, and Bastarache L

Subjects

Genotype, Humans, Electronic Health Records

Published

2021

13. A description of novel variants and review of phenotypic spectrum in UBA5 -related early epileptic encephalopathy.

Author

Briere LC, Walker MA, High FA, Cooper C, Rogers CA, Callahan CJ, Ishimura R, Ichimura Y, Caruso PA, Sharma N, Brokamp E, Koziura ME, Mohammad SS, Dale RC, Riley LG, Phillips JA, Komatsu M, and Sweetser DA

Subjects

Adolescent, Brain diagnostic imaging, Brain physiology, Child, Cohort Studies, Epilepsy genetics, Female, Genetic Association Studies, HEK293 Cells, Humans, Male, Muscle Hypotonia, Mutation, Missense, Proteins genetics, Proteins metabolism, Spasms, Infantile diagnostic imaging, Spasms, Infantile pathology, Young Adult, Phenotype, Spasms, Infantile genetics, Spasms, Infantile metabolism, Ubiquitin-Activating Enzymes genetics, Ubiquitin-Activating Enzymes metabolism

Abstract

Early infantile epileptic encephalopathy-44 (EIEE44, MIM: 617132) is a previously described condition resulting from biallelic variants in UBA5 , a gene involved in a ubiquitin-like post-translational modification system called UFMylation. Here we report five children from four families with biallelic pathogenic variants in UBA5 All five children presented with global developmental delay, epilepsy, axial hypotonia, appendicular hypertonia, and a movement disorder, including dystonia in four. Affected individuals in all four families have compound heterozygous pathogenic variants in UBA5 All have the recurrent mild c.1111G > A (p.Ala371Thr) variant in trans with a second UBA5 variant. One patient has the previously described c.562C > T (p. Arg188*) variant, two other unrelated patients have a novel missense variant, c.907T > C (p.Cys303Arg), and the two siblings have a novel missense variant, c.761T > C (p.Leu254Pro). Functional analyses demonstrate that both the p.Cys303Arg variant and the p.Leu254Pro variants result in a significant decrease in protein function. We also review the phenotypes and genotypes of all 15 previously reported families with biallelic UBA5 variants, of which two families have presented with distinct phenotypes, and we describe evidence for some limited genotype-phenotype correlation. The overlap of motor and developmental phenotypes noted in our cohort and literature review adds to the increasing understanding of genetic syndromes with movement disorders-epilepsy., (© 2021 Briere et al.; Published by Cold Spring Harbor Laboratory Press.)

Published

2021

14. An autosomal dominant neurological disorder caused by de novo variants in FAR1 resulting in uncontrolled synthesis of ether lipids.

Author

Ferdinandusse S, McWalter K, Te Brinke H, IJlst L, Mooijer PM, Ruiter JPN, van Lint AEM, Pras-Raves M, Wever E, Millan F, Guillen Sacoto MJ, Begtrup A, Tarnopolsky M, Brady L, Ladda RL, Sell SL, Nowak CB, Douglas J, Tian C, Ulm E, Perlman S, Drack AV, Chong K, Martin N, Brault J, Brokamp E, Toro C, Gahl WA, Macnamara EF, Wolfe L, Waisfisz Q, Zwijnenburg PJG, Ziegler A, Barth M, Smith R, Ellingwood S, Gaebler-Spira D, Bakhtiari S, Kruer MC, van Kampen AHC, Wanders RJA, Waterham HR, Cassiman D, and Vaz FM

Subjects

Humans, Phenotype, Aldehyde Oxidoreductases genetics, Ethers, Lipids, Spastic Paraplegia, Hereditary genetics

Abstract

Purpose: In this study we investigate the disease etiology in 12 patients with de novo variants in FAR1 all resulting in an amino acid change at position 480 (p.Arg480Cys/His/Leu)., Methods: Following next-generation sequencing and clinical phenotyping, functional characterization was performed in patients' fibroblasts using FAR1 enzyme analysis, FAR1 immunoblotting/immunofluorescence, and lipidomics., Results: All patients had spastic paraparesis and bilateral congenital/juvenile cataracts, in most combined with speech and gross motor developmental delay and truncal hypotonia. FAR1 deficiency caused by biallelic variants results in defective ether lipid synthesis and plasmalogen deficiency. In contrast, patients' fibroblasts with the de novo FAR1 variants showed elevated plasmalogen levels. Further functional studies in fibroblasts showed that these variants cause a disruption of the plasmalogen-dependent feedback regulation of FAR1 protein levels leading to uncontrolled ether lipid production., Conclusion: Heterozygous de novo variants affecting the Arg480 residue of FAR1 lead to an autosomal dominant disorder with a different disease mechanism than that of recessive FAR1 deficiency and a diametrically opposed biochemical phenotype. Our findings show that for patients with spastic paraparesis and bilateral cataracts, FAR1 should be considered as a candidate gene and added to gene panels for hereditary spastic paraplegia, cerebral palsy, and juvenile cataracts.

Published

2021

15. Histone H3.3 beyond cancer: Germline mutations in Histone 3 Family 3A and 3B cause a previously unidentified neurodegenerative disorder in 46 patients.

Author

Bryant L, Li D, Cox SG, Marchione D, Joiner EF, Wilson K, Janssen K, Lee P, March ME, Nair D, Sherr E, Fregeau B, Wierenga KJ, Wadley A, Mancini GMS, Powell-Hamilton N, van de Kamp J, Grebe T, Dean J, Ross A, Crawford HP, Powis Z, Cho MT, Willing MC, Manwaring L, Schot R, Nava C, Afenjar A, Lessel D, Wagner M, Klopstock T, Winkelmann J, Catarino CB, Retterer K, Schuette JL, Innis JW, Pizzino A, Lüttgen S, Denecke J, Strom TM, Monaghan KG, Yuan ZF, Dubbs H, Bend R, Lee JA, Lyons MJ, Hoefele J, Günthner R, Reutter H, Keren B, Radtke K, Sherbini O, Mrokse C, Helbig KL, Odent S, Cogne B, Mercier S, Bezieau S, Besnard T, Kury S, Redon R, Reinson K, Wojcik MH, Õunap K, Ilves P, Innes AM, Kernohan KD, Costain G, Meyn MS, Chitayat D, Zackai E, Lehman A, Kitson H, Martin MG, Martinez-Agosto JA, Nelson SF, Palmer CGS, Papp JC, Parker NH, Sinsheimer JS, Vilain E, Wan J, Yoon AJ, Zheng A, Brimble E, Ferrero GB, Radio FC, Carli D, Barresi S, Brusco A, Tartaglia M, Thomas JM, Umana L, Weiss MM, Gotway G, Stuurman KE, Thompson ML, McWalter K, Stumpel CTRM, Stevens SJC, Stegmann APA, Tveten K, Vøllo A, Prescott T, Fagerberg C, Laulund LW, Larsen MJ, Byler M, Lebel RR, Hurst AC, Dean J, Schrier Vergano SA, Norman J, Mercimek-Andrews S, Neira J, Van Allen MI, Longo N, Sellars E, Louie RJ, Cathey SS, Brokamp E, Heron D, Snyder M, Vanderver A, Simon C, de la Cruz X, Padilla N, Crump JG, Chung W, Garcia B, Hakonarson HH, and Bhoj EJ

Subjects

Animals, Forkhead Transcription Factors genetics, Germ-Line Mutation, Humans, Zebrafish genetics, Zebrafish metabolism, Zebrafish Proteins metabolism, Histones genetics, Histones metabolism, Neurodegenerative Diseases genetics

Abstract

Although somatic mutations in Histone 3.3 (H3.3) are well-studied drivers of oncogenesis, the role of germline mutations remains unreported. We analyze 46 patients bearing de novo germline mutations in histone 3 family 3A ( H3F3A ) or H3F3B with progressive neurologic dysfunction and congenital anomalies without malignancies. Molecular modeling of all 37 variants demonstrated clear disruptions in interactions with DNA, other histones, and histone chaperone proteins. Patient histone posttranslational modifications (PTMs) analysis revealed notably aberrant local PTM patterns distinct from the somatic lysine mutations that cause global PTM dysregulation. RNA sequencing on patient cells demonstrated up-regulated gene expression related to mitosis and cell division, and cellular assays confirmed an increased proliferative capacity. A zebrafish model showed craniofacial anomalies and a defect in Foxd3-derived glia. These data suggest that the mechanism of germline mutations are distinct from cancer-associated somatic histone mutations but may converge on control of cell proliferation., (Copyright © 2020 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works. Distributed under a Creative Commons Attribution NonCommercial License 4.0 (CC BY-NC).)

Published

2020

16. Missed diagnoses: Clinically relevant lessons learned through medical mysteries solved by the Undiagnosed Diseases Network.

Author

Cope H, Spillmann R, Rosenfeld JA, Brokamp E, Signer R, Schoch K, Glanton E, Sullivan JA, Macnamara E, Lincoln S, Golden-Grant K, Orengo JP, Clark G, Burrage LC, Posey JE, Punetha J, Robertson A, Cogan J, Phillips JA 3rd, Martinez-Agosto J, and Shashi V

Subjects

Adolescent, Child, Child, Preschool, Female, Genetic Diseases, Inborn genetics, Genetic Testing standards, Humans, Information Dissemination, Male, Middle Aged, National Institutes of Health (U.S.), Phenotype, Precision Medicine methods, Undiagnosed Diseases genetics, United States, Young Adult, Databases, Factual, Diagnosis, Computer-Assisted methods, Genetic Diseases, Inborn diagnosis, Genetic Testing methods, Missed Diagnosis, Undiagnosed Diseases diagnosis

Abstract

Background: Resources within the Undiagnosed Diseases Network (UDN), such as genome sequencing (GS) and model organisms aid in diagnosis and identification of new disease genes, but are currently difficult to access by clinical providers. While these resources do contribute to diagnoses in many cases, they are not always necessary to reach diagnostic resolution. The UDN experience has been that participants can also receive diagnoses through the thoughtful and customized application of approaches and resources that are readily available in clinical settings., Methods: The UDN Genetic Counseling and Testing Working Group collected case vignettes that illustrated how clinically available methods resulted in diagnoses. The case vignettes were classified into three themes; phenotypic considerations, selection of genetic testing, and evaluating exome/GS variants and data., Results: We present 12 participants that illustrate how clinical practices such as phenotype-driven genomic investigations, consideration of variable expressivity, selecting the relevant tissue of interest for testing, utilizing updated testing platforms, and recognition of alternate transcript nomenclature resulted in diagnoses., Conclusion: These examples demonstrate that when a diagnosis is elusive, an iterative patient-specific approach utilizing assessment options available to clinical providers may solve a portion of cases. However, this does require increased provider time commitment, a particular challenge in the current practice of genomics., (© 2020 The Authors. Molecular Genetics & Genomic Medicine published by Wiley Periodicals LLC.)

Published

2020

17. Limitations of exome sequencing in detecting rare and undiagnosed diseases.

Author

Burdick KJ, Cogan JD, Rives LC, Robertson AK, Koziura ME, Brokamp E, Duncan L, Hannig V, Pfotenhauer J, Vanzo R, Paul MS, Bican A, Morgan T, Duis J, Newman JH, Hamid R, and Phillips JA 3rd

Subjects

Exome genetics, Genetic Testing, Humans, Rare Diseases genetics, Rare Diseases pathology, Undiagnosed Diseases diagnosis, Undiagnosed Diseases epidemiology, Whole Genome Sequencing, Genetic Predisposition to Disease, Rare Diseases diagnosis, Undiagnosed Diseases genetics, Exome Sequencing standards

Abstract

While exome sequencing (ES) is commonly the final diagnostic step in clinical genetics, it may miss diagnoses. To clarify the limitations of ES, we investigated the diagnostic yield of genetic tests beyond ES in our Undiagnosed Diseases Network (UDN) participants. We reviewed the yield of additional genetic testing including genome sequencing (GS), copy number variant (CNV), noncoding variant (NCV), repeat expansion (RE), or methylation testing in UDN cases with nondiagnostic ES results. Overall, 36/54 (67%) of total diagnoses were based on clinical findings and coding variants found by ES and 3/54 (6%) were based on clinical findings only. The remaining 15/54 (28%) required testing beyond ES. Of these, 7/15 (47%) had NCV, 6/15 (40%) CNV, and 2/15 (13%) had a RE or a DNA methylation disorder. Thus 18/54 (33%) of diagnoses were not solved exclusively by ES. Several methods were needed to detect and/or confirm the functional effects of the variants missed by ES, and in some cases by GS. These results indicate that tests to detect elusive variants should be considered after nondiagnostic preliminary steps. Further studies are needed to determine the cost-effectiveness of tests beyond ES that provide diagnoses and insights to possible treatment., (© 2020 Wiley Periodicals, Inc.)

Published

2020

18. Yield of whole exome sequencing in undiagnosed patients facing insurance coverage barriers to genetic testing.

Author

Reuter CM, Kohler JN, Bonner D, Zastrow D, Fernandez L, Dries A, Marwaha S, Davidson J, Brokamp E, Herzog M, Hong J, Macnamara E, Rosenfeld JA, Schoch K, Spillmann R, Loscalzo J, Krier J, Stoler J, Sweetser D, Palmer CGS, Phillips JA, Shashi V, Adams DA, Yang Y, Ashley EA, Fisher PG, Mulvihill JJ, Bernstein JA, and Wheeler MT

Subjects

Child, Child, Preschool, Female, Genetic Testing methods, Humans, Male, Retrospective Studies, United States, Insurance Coverage, Undiagnosed Diseases genetics, Exome Sequencing

Abstract

Background: Despite growing evidence of diagnostic yield and clinical utility of whole exome sequencing (WES) in patients with undiagnosed diseases, there remain significant cost and reimbursement barriers limiting access to such testing. The diagnostic yield and resulting clinical actions of WES for patients who previously faced insurance coverage barriers have not yet been explored., Methods: We performed a retrospective descriptive analysis of clinical WES outcomes for patients facing insurance coverage barriers prior to clinical WES and who subsequently enrolled in the Undiagnosed Diseases Network (UDN). Clinical WES was completed as a result of participation in the UDN. Payer type, molecular diagnostic yield, and resulting clinical actions were evaluated., Results: Sixty-six patients in the UDN faced insurance coverage barriers to WES at the time of enrollment (67% public payer, 26% private payer). Forty-two of 66 (64%) received insurance denial for clinician-ordered WES, 19/66 (29%) had health insurance through a payer known not to cover WES, and 5/66 (8%) had previous payer denial of other genetic tests. Clinical WES results yielded a molecular diagnosis in 23 of 66 patients (35% [78% pediatric, 65% neurologic indication]). Molecular diagnosis resulted in clinical actions in 14 of 23 patients (61%)., Conclusions: These data demonstrate that a substantial proportion of patients who encountered insurance coverage barriers to WES had a clinically actionable molecular diagnosis, supporting the notion that WES has value as a covered benefit for patients who remain undiagnosed despite objective clinical findings., (© 2019 National Society of Genetic Counselors.)

Published

2019

19. Magnetic Resonance Imaging characteristics in case of TOR1AIP1 muscular dystrophy.

Author

Bhatia A, Mobley BC, Cogan J, Koziura ME, Brokamp E, Phillips J, Newman J, Moore SA, and Hamid R

Subjects

Adolescent, Female, Humans, Lower Extremity pathology, Magnetic Resonance Imaging methods, Molecular Chaperones genetics, Muscle Weakness pathology, Muscle, Skeletal pathology, Muscular Atrophy pathology, Muscular Dystrophies, Limb-Girdle genetics, Muscular Dystrophies, Limb-Girdle pathology

Abstract

Mutations in the torsinA-interacting protein 1 (TOR1AIP1) gene result in a severe muscular dystrophy with minimal literature in the pediatric population. We review a case of TOR1AIP1 gene mutation in a 16-year-old Caucasian female with a long history of muscle weakness. Extensive clinical workup was performed and MRI at time of initial presentation demonstrated no significant muscular atrophy with heterogenous STIR hyperintensity of the lower extremity muscles. MRI findings seven years later included extensive atrophy of the lower extremities, with severe progression, including the gluteal muscles, iliopsoas, rectus femoris, and obturator internus. There was also significant atrophy of the rectus abdominis and internal and external oblique muscles, and iliacus muscles. The MRI findings showed more proximal involvement of lower extremities and no atrophy of the tibialis anterior, making TOR1AIP1 the more likely genetic cause. Muscle biopsy findings supported TOR1AIP1 limb-girdle muscular dystrophy. Though rare, TOR1AIP1 gene mutation occurs in pediatric patients and MRI can aid in diagnosis and help differentiate from other types of muscular dystrophy. Genetic and pathology workup is also crucial to accurate diagnosis and possible treatment of these patients., (Copyright © 2019 Elsevier Inc. All rights reserved.)

Published

2019

20. Juvenile idiopathic arthritis associated with a mutation in GATA3.

Author

Patrick AE, Wang W, Brokamp E, Graham TB, Aune TM, and Duis JB

Subjects

Arthritis, Juvenile immunology, Arthritis, Juvenile metabolism, Autoimmune Diseases immunology, Autoimmune Diseases metabolism, Child, Preschool, Cytokines metabolism, DNA Mutational Analysis, GATA3 Transcription Factor metabolism, Humans, Male, Arthritis, Juvenile genetics, Autoimmune Diseases genetics, Autoimmunity, DNA genetics, GATA3 Transcription Factor genetics, Mutation

Abstract

Background: GATA3 is a transcription factor that is important during development and plays a role in differentiation and activity of immune cells, particularly T cells. Abnormal T cell function is found in autoimmune arthritis. We present the first known case of autoimmune arthritis associated with a novel GATA3 mutation., Methods: Whole exome sequencing of the proband was performed on a clinical basis. Peripheral blood mononuclear cells (PBMCs) were collected from the proband, healthy sibling, and parent. cDNA prepared from RNA was analyzed with polymerase chain reaction and Sanger sequencing. Intracellular proteins were assessed by immunoblot of PBMC homogenates. GATA3 in vitro activity was measured in HeLa cell cultures expressing a mammalian expression vector containing GATA3 or mutants generated by site-directed mutagenesis. GATA3 transcriptional activity was examined using a luciferase reporter assay system. T helper cell ex vivo function was evaluated by stimulating PBMCs to differentiate into effector T cells along Th0, Th1, Th2, and Th17 lineages, and re-stimulating effector cells to secrete cytokines. Cytokine production was measured by enzyme-linked immunosorbent assay., Results: The proband is the first known case of autoimmune arthritis associated with a mutation in GATA3. The proband M401VfsX106 protein is expressed and has a dominant negative function on GATA3 transcriptional activity. The proband PBMCs have markedly increased differentiation along the Th1 and Th17 pathways, with decreased differentiation along the Th2 pathway. Unexpectedly, Th0 cells from the proband express high levels of IFNγ., Conclusions: Our research presents the first known case of autoimmune arthritis associated with a mutation in GATA3. This work expands the phenotypic spectrum of GATA3 mutations. It reveals the novel insight that decreased and altered GATA3 activity coincides with autoimmune arthritis. This work suggests that modulation of GATA3 may be a therapeutic approach for patients with autoimmune arthritis.

Published

2019

21. Cases from the Undiagnosed Diseases Network: The continued value of counseling skills in a new genomic era.

Author

Macnamara EF, Schoch K, Glanton E, Fieg E, Brokamp E, Signer R, LeBlanc K, McConkie-Rosell A, and Palmer CGS

Subjects

Adolescent, Adult, Child, Child, Preschool, Genomics, Humans, Male, Young Adult, Diagnosis, Genetic Counseling psychology, Genetic Predisposition to Disease psychology, Genetic Testing, Social Networking, Undiagnosed Diseases psychology

Abstract

The "diagnostic odyssey" is well known and described in genetic counseling literature. Studies addressing the psychological, emotional, and financial costs of not having a diagnosis have shown how it permeates the lives of patients and families. The Undiagnosed Diseases Network aims to end this odyssey by providing diagnoses to individuals with undiagnosed conditions through multidisciplinary evaluations, whole exome and genome sequencing, and basic science research. It also provides an opportunity to learn from patients and families and to better understand their journeys and the impact of receiving a diagnosis. Seven cases are presented that outline challenges that come from working with chronically undiagnosed and newly diagnosed patients in a time when sequencing for clinical diagnosis is rapidly increasing. They illuminate the emotional journey of patients and families searching for a diagnosis and the mental health problems, financial distress, and chaos that can accompany not having answers. They also illustrate the surprising reactions patients and families can have to receiving a diagnosis, including anger, grief, and disappointment. While the lessons learned from these families are not novel, new strategies are presented for handling these challenges in undiagnosed and ultra-rare populations, groups that will increase with the rise of clinical sequencing., (© 2019 National Society of Genetic Counselors.)

Published

2019

22. A multidisciplinary approach to the clinical management of Prader-Willi syndrome.

Author

Duis J, van Wattum PJ, Scheimann A, Salehi P, Brokamp E, Fairbrother L, Childers A, Shelton AR, Bingham NC, Shoemaker AH, and Miller JL

Subjects

Health Knowledge, Attitudes, Practice, Health Personnel psychology, Humans, Prader-Willi Syndrome diagnosis, Surveys and Questionnaires, Disease Management, Interdisciplinary Communication, Prader-Willi Syndrome therapy

Abstract

Background: Prader-Willi syndrome (PWS) is a complex neuroendocrine disorder affecting approximately 1/15,000-1/30,000 people. Unmet medical needs of individuals with PWS make it a rare disease that models the importance of multidisciplinary approaches to care with collaboration between academic centers, medical homes, industry, and parent organizations. Multidisciplinary clinics support comprehensive, patient-centered care for individuals with complex genetic disorders and their families. Value comes from improved communication and focuses on quality family-centered care., Methods: Interviews with medical professionals, scientists, managed care experts, parents, and individuals with PWS were conducted from July 1 to December 1, 2016. Review of the literature was used to provide support., Results: Data are presented based on consensus from these interviews by specialty focusing on unique aspects of care, research, and management. We have also defined the Center of Excellence beyond the multidisciplinary clinic., Conclusion: Establishment of clinics motivates collaboration to provide evidence-based new standards of care, increases the knowledge base including through randomized controlled trials, and offers an additional resource for the community. They have a role in global telemedicine, including to rural areas with few resources, and create opportunities for clinical work to inform basic and translational research. As a care team, we are currently charged with understanding the molecular basis of PWS beyond the known genetic cause; developing appropriate clinical outcome measures and biomarkers; bringing new therapies to change the natural history of disease; improving daily patient struggles, access to care, and caregiver burden; and decreasing healthcare load. Based on experience to date with a PWS multidisciplinary clinic, we propose a design for this approach and emphasize the development of "Centers of Excellence." We highlight the dearth of evidence for management approaches creating huge gaps in care practices as a means to illustrate the importance of the collaborative environment and translational approaches., (© 2019 The Authors. Molecular Genetics & Genomic Medicine published by Wiley Periodicals, Inc.)

Published

2019

23. Understanding Adult Participant and Parent Empowerment Prior to Evaluation in the Undiagnosed Diseases Network.

Author

Palmer CGS, McConkie-Rosell A, Holm IA, LeBlanc K, Sinsheimer JS, Briere LC, Dorrani N, Herzog MR, Lincoln S, Schoch K, Spillmann RC, and Brokamp E

Subjects

Adaptation, Psychological, Adult, Child, Decision Making, Disease Management, Female, Genetic Counseling, Humans, Infant, Male, Patient Reported Outcome Measures, Pilot Projects, Reproducibility of Results, Surveys and Questionnaires, Uncertainty, Diagnosis, Parents psychology, Power, Psychological

Abstract

The burden of living with an undiagnosed condition is high and includes physical and emotional suffering, frustrations, and uncertainty. For patients and families experiencing these stressors, higher levels of empowerment may be associated with better outcomes. Thus, it is important to understand the experiences of patients with undiagnosed conditions and their families affected by undiagnosed conditions in order to identify strategies for fostering empowerment. In this study, we used the Genetic Counseling Outcome Scale (GCOS-24) to assess levels of empowerment and support group participation in 35 adult participants and 67 parents of child participants in the Undiagnosed Diseases Network (UDN) prior to their UDN in-person evaluation. Our results revealed significantly lower empowerment scores on the GCOS-24 in adult participants compared to parents of child participants [t(100) = - 3.01, p = 0.003, average difference = - 11.12, 95% CI (- 3.78, - 18.46)] and no significant association between support group participation and empowerment scores. The majority of participants (84.3%, 86/102) are not currently participating in any support groups, and participation rates were not significantly different for adult participants and parents of child participants (11.4 vs. 19.7%, respectively, FE p = 0.40). Open-ended responses provided additional insight into support group participation, the challenges of living with undiagnosed conditions, and positive coping strategies. Future research will evaluate the extent to which empowerment scores change as participation in the UDN unfolds.

Published

2018