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3. Novel diagnostic DNA methylation episignatures expand and refine the epigenetic landscapes of Mendelian disorders.

Author

Levy, MA, McConkey, H, Kerkhof, J, Barat-Houari, M, Bargiacchi, S, Biamino, E, Bralo, MP, Cappuccio, G, Ciolfi, A, Clarke, A, DuPont, BR, Elting, MW, Faivre, L, Fee, T, Fletcher, RS, Cherik, F, Foroutan, A, Friez, MJ, Gervasini, C, Haghshenas, S, Hilton, BA, Jenkins, Z, Kaur, S, Lewis, S, Louie, RJ, Maitz, S, Milani, D, Morgan, AT, Oegema, R, Østergaard, E, Pallares, NR, Piccione, M, Pizzi, S, Plomp, AS, Poulton, C, Reilly, J, Relator, R, Rius, R, Robertson, S, Rooney, K, Rousseau, J, Santen, GWE, Santos-Simarro, F, Schijns, J, Squeo, GM, St John, M, Thauvin-Robinet, C, Traficante, G, van der Sluijs, PJ, Vergano, SA, Vos, N, Walden, KK, Azmanov, D, Balci, T, Banka, S, Gecz, J, Henneman, P, Lee, JA, Mannens, MMAM, Roscioli, T, Siu, V, Amor, DJ, Baynam, G, Bend, EG, Boycott, K, Brunetti-Pierri, N, Campeau, PM, Christodoulou, J, Dyment, D, Esber, N, Fahrner, JA, Fleming, MD, Genevieve, D, Kerrnohan, KD, McNeill, A, Menke, LA, Merla, G, Prontera, P, Rockman-Greenberg, C, Schwartz, C, Skinner, SA, Stevenson, RE, Vitobello, A, Tartaglia, M, Alders, M, Tedder, ML, Sadikovic, B, Levy, MA, McConkey, H, Kerkhof, J, Barat-Houari, M, Bargiacchi, S, Biamino, E, Bralo, MP, Cappuccio, G, Ciolfi, A, Clarke, A, DuPont, BR, Elting, MW, Faivre, L, Fee, T, Fletcher, RS, Cherik, F, Foroutan, A, Friez, MJ, Gervasini, C, Haghshenas, S, Hilton, BA, Jenkins, Z, Kaur, S, Lewis, S, Louie, RJ, Maitz, S, Milani, D, Morgan, AT, Oegema, R, Østergaard, E, Pallares, NR, Piccione, M, Pizzi, S, Plomp, AS, Poulton, C, Reilly, J, Relator, R, Rius, R, Robertson, S, Rooney, K, Rousseau, J, Santen, GWE, Santos-Simarro, F, Schijns, J, Squeo, GM, St John, M, Thauvin-Robinet, C, Traficante, G, van der Sluijs, PJ, Vergano, SA, Vos, N, Walden, KK, Azmanov, D, Balci, T, Banka, S, Gecz, J, Henneman, P, Lee, JA, Mannens, MMAM, Roscioli, T, Siu, V, Amor, DJ, Baynam, G, Bend, EG, Boycott, K, Brunetti-Pierri, N, Campeau, PM, Christodoulou, J, Dyment, D, Esber, N, Fahrner, JA, Fleming, MD, Genevieve, D, Kerrnohan, KD, McNeill, A, Menke, LA, Merla, G, Prontera, P, Rockman-Greenberg, C, Schwartz, C, Skinner, SA, Stevenson, RE, Vitobello, A, Tartaglia, M, Alders, M, Tedder, ML, and Sadikovic, B

Abstract

Overlapping clinical phenotypes and an expanding breadth and complexity of genomic associations are a growing challenge in the diagnosis and clinical management of Mendelian disorders. The functional consequences and clinical impacts of genomic variation may involve unique, disorder-specific, genomic DNA methylation episignatures. In this study, we describe 19 novel episignature disorders and compare the findings alongside 38 previously established episignatures for a total of 57 episignatures associated with 65 genetic syndromes. We demonstrate increasing resolution and specificity ranging from protein complex, gene, sub-gene, protein domain, and even single nucleotide-level Mendelian episignatures. We show the power of multiclass modeling to develop highly accurate and disease-specific diagnostic classifiers. This study significantly expands the number and spectrum of disorders with detectable DNA methylation episignatures, improves the clinical diagnostic capabilities through the resolution of unsolved cases and the reclassification of variants of unknown clinical significance, and provides further insight into the molecular etiology of Mendelian conditions.

Published
2022

4. Utility of whole-exome sequencing for those near the end of the diagnostic odyssey: time to address gaps in care

Author

Sawyer, S. L., Hartley, T., Dyment, D. A., Beaulieu, C. L., Schwartzentruber, J., Smith, A., Bedford, H. M., Bernard, G., Bernier, F. P., Brais, B., Bulman, D. E., Chardon, Warman J., Chitayat, D., Deladoëy, J., Fernandez, B. A., Frosk, P., Geraghty, M. T., Gerull, B., Gibson, W., Gow, R. M., Graham, G. E., Green, J. S., Heon, E., Horvath, G., Innes, A. M., Jabado, N., Kim, R. H., Koenekoop, R. K., Khan, A., Lehmann, O. J., Mendoza-Londono, R., Michaud, J. L., Nikkel, S. M., Penney, L. S., Polychronakos, C., Richer, J., Rouleau, G. A., Samuels, M. E., Siu, V. M., Suchowersky, O., Tarnopolsky, M. A., Yoon, G., Zahir, F. R., Majewski, J., and Boycott, K. M.

Published
2016
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11. Alternative genomic diagnoses for individuals with a clinical diagnosis of Dubowitz syndrome

Author

Dyment, D. A. (David A.), O'Donnell-Luria, A. (Anne), Agrawal, P. B. (Pankaj B.), Coban Akdemir, Z. (Zeynep), Aleck, K. A. (Kyrieckos A.), Antaki, D. (Danny), Al Sharhan, H. (Hind), Au, P. B. (Ping-Yee B.), Aydin, H. (Hatip), Beggs, A. H. (Alan H.), Bilguvar, K. (Kaya), Boerwinkle, E. (Eric), Brand, H. (Harrison), Brownstein, C. A. (Catherine A.), Buyske, S. (Steve), Chodirker, B. (Bernard), Choi, J. (Jungmin), Chudley, A. E. (Albert E.), Clericuzio, C. L. (Carol L.), Cox, G. F. (Gerald F.), Curry, C. (Cynthia), De Boer, E. (Elke), De Vries, B. B. (Bert B. A.), Dunn, K. (Kathryn), Dutmer, C. M. (Cullen M.), England, E. M. (Eleina M.), Fahrner, J. A. (Jill A.), Geckinli, B. B. (Bilgen B.), Genetti, C. A. (Casie A.), Gezdirici, A. (Alper), Gibson, W. T. (William T.), Gleeson, J. G. (Joseph G.), Greenberg, C. R. (Cheryl R.), Hall, A. (April), Hamosh, A. (Ada), Hartley, T. (Taila), Jhangiani, S. N. (Shalini N.), Karaca, E. (Ender), Kernohan, K. (Kristin), Lauzon, J. L. (Julie L.), Lewis, M. E. (M. E. Suzanne), Lowry, R. B. (R. Brian), López-Giráldez, F. (Francesc), Matise, T. C. (Tara C.), McEvoy-Venneri, J. (Jennifer), McInnes, B. (Brenda), Mhanni, A. (Aziz), Garcia Minaur, S. (Sixto), Moilanen, J. (Jukka), Nguyen, A. (An), Nowaczyk, M. J. (Malgorzata J. M.), Posey, J. E. (Jennifer E.), Õunap, K. (Katrin), Pehlivan, D. (Davut), Pajusalu, S. (Sander), Penney, L. S. (Lynette S.), Poterba, T. (Timothy), Prontera, P. (Paolo), Rodovalho Doriqui, M. J. (Maria Juliana), Sawyer, S. L. (Sarah L.), Sobreira, N. (Nara), Stanley, V. (Valentina), Torun, D. (Deniz), Wargowski, D. (David), Witmer, P. D. (P. Dane), Wong, I. (Isaac), Xing, J. (Jinchuan), Zaki, M. S. (Maha S.), Zhang, Y. (Yeting), C. C. (Care4Rare Consortium), C. F. (Centers For Mendelian Genomics), Boycott, K. M. (Kym M.), Bamshad, M. J. (Michael J.), Nickerson, D. A. (Deborah A.), Blue, E. E. (Elizabeth E.), and Innes, A. M. (A. Micheil)

Subjects
genetic heterogeneity, genome sequencing, Dubowitz syndrome, exome sequencing, microarray
Abstract

Dubowitz syndrome (DubS) is considered a recognizable syndrome characterized by a distinctive facial appearance and deficits in growth and development. There have been over 200 individuals reported with Dubowitz or a “Dubowitz-like” condition, although no single gene has been implicated as responsible for its cause. We have performed exome (ES) or genome sequencing (GS) for 31 individuals clinically diagnosed with DubS. After genome-wide sequencing, rare variant filtering and computational and Mendelian genomic analyses, a presumptive molecular diagnosis was made in 13/27 (48%) families. The molecular diagnoses included biallelic variants in SKIV2L, SLC35C1, BRCA1, NSUN2; de novo variants in ARID1B, ARID1A, CREBBP, POGZ, TAF1, HDAC8, and copy-number variation at1p36.11(ARID1A), 8q22.2(VPS13B), Xp22, and Xq13(HDAC8). Variants of unknown significance in known disease genes, and also in genes of uncertain significance, were observed in 7/27 (26%) additional families. Only one gene, HDAC8, could explain the phenotype in more than one family (N = 2). All but two of the genomic diagnoses were for genes discovered, or for conditions recognized, since the introduction of next-generation sequencing. Overall, the DubS-like clinical phenotype is associated with extensive locus heterogeneity and the molecular diagnoses made are for emerging clinical conditions sharing characteristic features that overlap the DubS phenotype.

Published
2021

13. Phenotype delineation of ZNF462 related syndrome

Author

Kruszka, P., Hu, T., Hong, S., Signer, R., Cogne, B., Isidor, B., Mazzola, S.E., Giltay, J.C., Gassen, K.L.I. van, England, E.M., Pais, L., Ockeloen, C.W., Sanchez-Lara, P.A., Kinning, E., Adams, D.J., Treat, K., Torres-Martinez, W., Bedeschi, M.F., Iascone, M., Blaney, S., Bell, O., Tan, T.Y., Delrue, M.A., Jurgens, J., Barry, B.J., Engle, E.C., Savage, S.K., Fleischer, N., Martinez-Agosto, J.A., Boycott, K., Zackai, E.H., Muenke, M., Kruszka, P., Hu, T., Hong, S., Signer, R., Cogne, B., Isidor, B., Mazzola, S.E., Giltay, J.C., Gassen, K.L.I. van, England, E.M., Pais, L., Ockeloen, C.W., Sanchez-Lara, P.A., Kinning, E., Adams, D.J., Treat, K., Torres-Martinez, W., Bedeschi, M.F., Iascone, M., Blaney, S., Bell, O., Tan, T.Y., Delrue, M.A., Jurgens, J., Barry, B.J., Engle, E.C., Savage, S.K., Fleischer, N., Martinez-Agosto, J.A., Boycott, K., Zackai, E.H., and Muenke, M.

Abstract

Contains fulltext : 208539.pdf (publisher's version ) (Closed access), Zinc finger protein 462 (ZNF462) is a relatively newly discovered vertebrate specific protein with known critical roles in embryonic development in animal models. Two case reports and a case series study have described the phenotype of 10 individuals with ZNF462 loss of function variants. Herein, we present 14 new individuals with loss of function variants to the previous studies to delineate the syndrome of loss of function in ZNF462. Collectively, these 24 individuals present with recurring phenotypes that define a multiple congenital anomaly syndrome. Most have some form of developmental delay (79%) and a minority has autism spectrum disorder (33%). Characteristic facial features include ptosis (83%), down slanting palpebral fissures (58%), exaggerated Cupid's bow/wide philtrum (54%), and arched eyebrows (50%). Metopic ridging or craniosynostosis was found in a third of study participants and feeding problems in half. Other phenotype characteristics include dysgenesis of the corpus callosum in 25% of individuals, hypotonia in half, and structural heart defects in 21%. Using facial analysis technology, a computer algorithm applying deep learning was able to accurately differentiate individuals with ZNF462 loss of function variants from individuals with Noonan syndrome and healthy controls. In summary, we describe a multiple congenital anomaly syndrome associated with haploinsufficiency of ZNF462 that has distinct clinical characteristics and facial features.

Published
2019

14. Phenotype delineation of ZNF462 related syndrome

Author

Kruszka, P, Hu, T, Hong, S, Signer, R, Cogne, B, Isidor, B, Mazzola, SE, Giltay, JC, van Gassen, KLI, England, EM, Pais, L, Ockeloen, CW, Sanchez-Lara, PA, Kinning, E, Adams, DJ, Treat, K, Torres-Martinez, W, Bedeschi, MF, Iascone, M, Blaney, S, Bell, O, Tan, TY, Delrue, M-A, Jurgens, J, Barry, BJ, Engle, EC, Savage, SK, Fleischer, N, Martinez-Agosto, JA, Boycott, K, Zackai, EH, Muenke, M, Kruszka, P, Hu, T, Hong, S, Signer, R, Cogne, B, Isidor, B, Mazzola, SE, Giltay, JC, van Gassen, KLI, England, EM, Pais, L, Ockeloen, CW, Sanchez-Lara, PA, Kinning, E, Adams, DJ, Treat, K, Torres-Martinez, W, Bedeschi, MF, Iascone, M, Blaney, S, Bell, O, Tan, TY, Delrue, M-A, Jurgens, J, Barry, BJ, Engle, EC, Savage, SK, Fleischer, N, Martinez-Agosto, JA, Boycott, K, Zackai, EH, and Muenke, M

Abstract

Zinc finger protein 462 (ZNF462) is a relatively newly discovered vertebrate specific protein with known critical roles in embryonic development in animal models. Two case reports and a case series study have described the phenotype of 10 individuals with ZNF462 loss of function variants. Herein, we present 14 new individuals with loss of function variants to the previous studies to delineate the syndrome of loss of function in ZNF462. Collectively, these 24 individuals present with recurring phenotypes that define a multiple congenital anomaly syndrome. Most have some form of developmental delay (79%) and a minority has autism spectrum disorder (33%). Characteristic facial features include ptosis (83%), down slanting palpebral fissures (58%), exaggerated Cupid's bow/wide philtrum (54%), and arched eyebrows (50%). Metopic ridging or craniosynostosis was found in a third of study participants and feeding problems in half. Other phenotype characteristics include dysgenesis of the corpus callosum in 25% of individuals, hypotonia in half, and structural heart defects in 21%. Using facial analysis technology, a computer algorithm applying deep learning was able to accurately differentiate individuals with ZNF462 loss of function variants from individuals with Noonan syndrome and healthy controls. In summary, we describe a multiple congenital anomaly syndrome associated with haploinsufficiency of ZNF462 that has distinct clinical characteristics and facial features.

Published
2019

15. PDXK mutations cause polyneuropathy responsive to pyridoxal 5'-phosphate supplementation

Author

Chelban, V., Wilson, M. P., Warman Chardon, J., Vandrovcova, J., Zanetti, M. N., Zamba-Papanicolaou, E., Efthymiou, S., Pope, S., Conte, M. R., Abis, G., Liu, Y. -T., Tribollet, E., Haridy, N. A., Botia, J. A., Ryten, M., Nicolaou, P., Minaidou, A., Christodoulou, K., Kernohan, K. D., Eaton, A., Osmond, M., Ito, Y., Bourque, P., Jepson, J. E. C., Bello, O., Bremner, F., Cordivari, C., Reilly, M. M., Foiani, M., Heslegrave, A., Zetterberg, H., Heales, S. J. R., Wood, N. W., Rothman, J. E., Boycott, K. M., Mills, P. B., Clayton, P. T., Houlden, H., Kriouile, Y., Khorassani, M. E., Aguennouz, M., Groppa, S., Marinova Karashova, B., Van Maldergem, L., Nachbauer, W., Boesch, S., Arning, L., Timmann, D., Cormand, B., Perez-Duenas, B., Di Rosa, G., Goraya, J. S., Sultan, T., Mine, J., Avdjieva, D., Kathom, H., Tincheva, R., Banu, S., Pineda-Marfa, M., Veggiotti, P., Ferrari, M. D., van den Maagdenberg, A. M. J. M., Verrotti, A., Marseglia, G., Savasta, S., Garcia-Silva, M., Ruiz, A. M., Garavaglia, B., Borgione, E., Portaro, S., Sanchez, B. M., Boles, R., Papacostas, S., Vikelis, M., Giunti, P., Salpietro, V., Oconnor, E., Kullmann, D., Kaiyrzhanov, R., Sullivan, R., Khan, A. M., Yau, W. Y., Hostettler, I., Papanicolaou, E. Z., Dardiotis, E., Maqbool, S., Ibrahim, S., Kirmani, S., Rana, N. N., Atawneh, O., Lim, S. -Y., Shaikh, F., Koutsis, G., Breza, M., Mangano, S., Scuderi, C., Morello, G., Stojkovic, T., Torti, E., Zollo, M., Heimer, G., Dauvilliers, Y. A., Striano, P., Al-Khawaja, I., Al-Mutairi, F., Alkuraya, F. S., Sherifa, H., Rizig, M., Okubadejo, N. U., Ojo, O. O., Oshinaike, O. O., Wahab, K., Bello, A. H., Abubakar, S., Obiabo, Y., Nwazor, E., Ekenze, O., Williams, U., Iyagba, A., Taiwo, L., Komolafe, M., Oguntunde, O., Pchelina, S., Senkevich, K., Shashkin, C., Zharkynbekova, N., Koneyev, K., Manizha, G., Isrofilov, M., Guliyeva, U., Salayev, K., Khachatryan, S., Rossi, S., Silvestri, Gabriella, Bourinaris, T., Xiromerisiou, G., Fidani, L., Spanaki, C., Tucci, A., Silvestri G. (ORCID:0000-0002-1950-1468), Chelban, V., Wilson, M. P., Warman Chardon, J., Vandrovcova, J., Zanetti, M. N., Zamba-Papanicolaou, E., Efthymiou, S., Pope, S., Conte, M. R., Abis, G., Liu, Y. -T., Tribollet, E., Haridy, N. A., Botia, J. A., Ryten, M., Nicolaou, P., Minaidou, A., Christodoulou, K., Kernohan, K. D., Eaton, A., Osmond, M., Ito, Y., Bourque, P., Jepson, J. E. C., Bello, O., Bremner, F., Cordivari, C., Reilly, M. M., Foiani, M., Heslegrave, A., Zetterberg, H., Heales, S. J. R., Wood, N. W., Rothman, J. E., Boycott, K. M., Mills, P. B., Clayton, P. T., Houlden, H., Kriouile, Y., Khorassani, M. E., Aguennouz, M., Groppa, S., Marinova Karashova, B., Van Maldergem, L., Nachbauer, W., Boesch, S., Arning, L., Timmann, D., Cormand, B., Perez-Duenas, B., Di Rosa, G., Goraya, J. S., Sultan, T., Mine, J., Avdjieva, D., Kathom, H., Tincheva, R., Banu, S., Pineda-Marfa, M., Veggiotti, P., Ferrari, M. D., van den Maagdenberg, A. M. J. M., Verrotti, A., Marseglia, G., Savasta, S., Garcia-Silva, M., Ruiz, A. M., Garavaglia, B., Borgione, E., Portaro, S., Sanchez, B. M., Boles, R., Papacostas, S., Vikelis, M., Giunti, P., Salpietro, V., Oconnor, E., Kullmann, D., Kaiyrzhanov, R., Sullivan, R., Khan, A. M., Yau, W. Y., Hostettler, I., Papanicolaou, E. Z., Dardiotis, E., Maqbool, S., Ibrahim, S., Kirmani, S., Rana, N. N., Atawneh, O., Lim, S. -Y., Shaikh, F., Koutsis, G., Breza, M., Mangano, S., Scuderi, C., Morello, G., Stojkovic, T., Torti, E., Zollo, M., Heimer, G., Dauvilliers, Y. A., Striano, P., Al-Khawaja, I., Al-Mutairi, F., Alkuraya, F. S., Sherifa, H., Rizig, M., Okubadejo, N. U., Ojo, O. O., Oshinaike, O. O., Wahab, K., Bello, A. H., Abubakar, S., Obiabo, Y., Nwazor, E., Ekenze, O., Williams, U., Iyagba, A., Taiwo, L., Komolafe, M., Oguntunde, O., Pchelina, S., Senkevich, K., Shashkin, C., Zharkynbekova, N., Koneyev, K., Manizha, G., Isrofilov, M., Guliyeva, U., Salayev, K., Khachatryan, S., Rossi, S., Silvestri, Gabriella, Bourinaris, T., Xiromerisiou, G., Fidani, L., Spanaki, C., Tucci, A., and Silvestri G. (ORCID:0000-0002-1950-1468)

Abstract

Objective: To identify disease-causing variants in autosomal recessive axonal polyneuropathy with optic atrophy and provide targeted replacement therapy. Methods: We performed genome-wide sequencing, homozygosity mapping, and segregation analysis for novel disease-causing gene discovery. We used circular dichroism to show secondary structure changes and isothermal titration calorimetry to investigate the impact of variants on adenosine triphosphate (ATP) binding. Pathogenicity was further supported by enzymatic assays and mass spectroscopy on recombinant protein, patient-derived fibroblasts, plasma, and erythrocytes. Response to supplementation was measured with clinical validated rating scales, electrophysiology, and biochemical quantification. Results: We identified biallelic mutations in PDXK in 5 individuals from 2 unrelated families with primary axonal polyneuropathy and optic atrophy. The natural history of this disorder suggests that untreated, affected individuals become wheelchair-bound and blind. We identified conformational rearrangement in the mutant enzyme around the ATP-binding pocket. Low PDXK ATP binding resulted in decreased erythrocyte PDXK activity and low pyridoxal 5′-phosphate (PLP) concentrations. We rescued the clinical and biochemical profile with PLP supplementation in 1 family, improvement in power, pain, and fatigue contributing to patients regaining their ability to walk independently during the first year of PLP normalization. Interpretation: We show that mutations in PDXK cause autosomal recessive axonal peripheral polyneuropathy leading to disease via reduced PDXK enzymatic activity and low PLP. We show that the biochemical profile can be rescued with PLP supplementation associated with clinical improvement. As B6 is a cofactor in diverse essential biological pathways, our findings may have direct implications for neuropathies of unknown etiology characterized by reduced PLP levels. ANN NEUROL 2019;86:225–240.

Published
2019

16. Future of Rare Diseases Research 2017–2027: An IRDiRC Perspective

Author

Austin, C., Cutillo, C., Lau, L., Jonker, A., Rath, A., Julkowska, D., Thomson, D., Terry, S., de Montleau, B., Ardigò, D., Hivert, V., Boycott, K., Baynam, Gareth, Kaufmann, P., Taruscio, D., Lochmüller, H., Suematsu, M., Incerti, C., Draghia-Akli, R., Norstedt, I., Wang, L., Dawkins, Hugh, Austin, C., Cutillo, C., Lau, L., Jonker, A., Rath, A., Julkowska, D., Thomson, D., Terry, S., de Montleau, B., Ardigò, D., Hivert, V., Boycott, K., Baynam, Gareth, Kaufmann, P., Taruscio, D., Lochmüller, H., Suematsu, M., Incerti, C., Draghia-Akli, R., Norstedt, I., Wang, L., and Dawkins, Hugh

Abstract

Due to the remarkable global surge in activity in rare diseases research over the last six years, including contributions by the International Rare Diseases Research Consortium (IRDiRC), the Consortium's 2020 goals have been largely achieved by 2017. Though these developments are gratifying, enormous challenges remain. With this paradox in mind, IRDiRC set new global rare disease goals for the coming decade with the ultimate aim of improved health for people living with rare diseases worldwide. This article is protected by copyright. All rights reserved.

Published
2018

17. The International Rare Diseases Research Consortium: Policies and Guidelines to maximize impact

Author

Lochmüller, H., TorrentFarnell, J., Le Cam, Y., Jonker, A., Lau, L., Baynam, G., Kaufmann, P., Dawkins, Hugh, Lasko, P., Austin, C., Boycott, K., Lochmüller, H., TorrentFarnell, J., Le Cam, Y., Jonker, A., Lau, L., Baynam, G., Kaufmann, P., Dawkins, Hugh, Lasko, P., Austin, C., and Boycott, K.

Abstract

© 2017 European Society of Human Genetics. The International Rare Diseases Research Consortium (IRDiRC) has agreed on IRDiRC Policies and Guidelines, following extensive deliberations and discussions in 2012 and 2013, as a first step towards improving coordination of research efforts worldwide. The 25 funding members and 3 patient umbrella organizations (as of early 2013) of IRDiRC, a consortium of research funders that focuses on improving diagnosis and therapy for rare disease patients, agreed in Dublin, Ireland in April 2013 on the Policies and Guidelines that emphasize collaboration in rare disease research, the involvement of patients and their representatives in all relevant aspects of research, as well as the sharing of data and resources. The Policies and Guidelines provide guidance on ontologies, diagnostics, biomarkers, patient registries, biobanks, natural history, therapeutics, models, publication, intellectual property, and communication. Most IRDiRC members - currently nearly 50 strong - have since incorporated its policies in their funding calls and some have chosen to exceed the requirements laid out, for instance in relation to data sharing. The IRDiRC Policies and Guidelines are the first, detailed agreement of major public and private funding organizations worldwide to govern rare disease research, and may serve as a template for other areas of international research collaboration. While it is too early to assess their full impact on research productivity and patient benefit, the IRDiRC Policies and Guidelines have already contributed significantly to improving transparency and collaboration in rare disease research.

Published
2017

18. International Cooperation to Enable the Diagnosis of All Rare Genetic Diseases

Author

Boycott, K., Rath, A., Chong, J., Hartley, T., Alkuraya, F., Baynam, Gareth, Brookes, A., Brudno, M., Carracedo, A., den Dunnen, J., Dyke, S., Estivill, X., Goldblatt, J., Gonthier, C., Groft, S., Gut, I., Hamosh, A., Hieter, P., Höhn, S., Hurles, M., Kaufmann, P., Knoppers, B., Krischer, J., Macek, M., Matthijs, G., Olry, A., Parker, S., Paschall, J., Philippakis, A., Rehm, H., Robinson, P., Sham, P., Stefanov, R., Taruscio, D., Unni, D., Vanstone, M., Zhang, F., Brunner, H., Bamshad, M., Lochmüller, H., Boycott, K., Rath, A., Chong, J., Hartley, T., Alkuraya, F., Baynam, Gareth, Brookes, A., Brudno, M., Carracedo, A., den Dunnen, J., Dyke, S., Estivill, X., Goldblatt, J., Gonthier, C., Groft, S., Gut, I., Hamosh, A., Hieter, P., Höhn, S., Hurles, M., Kaufmann, P., Knoppers, B., Krischer, J., Macek, M., Matthijs, G., Olry, A., Parker, S., Paschall, J., Philippakis, A., Rehm, H., Robinson, P., Sham, P., Stefanov, R., Taruscio, D., Unni, D., Vanstone, M., Zhang, F., Brunner, H., Bamshad, M., and Lochmüller, H.

Abstract

© 2017 The Author(s) Provision of a molecularly confirmed diagnosis in a timely manner for children and adults with rare genetic diseases shortens their “diagnostic odyssey,” improves disease management, and fosters genetic counseling with respect to recurrence risks while assuring reproductive choices. In a general clinical genetics setting, the current diagnostic rate is approximately 50%, but for those who do not receive a molecular diagnosis after the initial genetics evaluation, that rate is much lower. Diagnostic success for these more challenging affected individuals depends to a large extent on progress in the discovery of genes associated with, and mechanisms underlying, rare diseases. Thus, continued research is required for moving toward a more complete catalog of disease-related genes and variants. The International Rare Diseases Research Consortium (IRDiRC) was established in 2011 to bring together researchers and organizations invested in rare disease research to develop a means of achieving molecular diagnosis for all rare diseases. Here, we review the current and future bottlenecks to gene discovery and suggest strategies for enabling progress in this regard. Each successful discovery will define potential diagnostic, preventive, and therapeutic opportunities for the corresponding rare disease, enabling precision medicine for this patient population.

Published
2017

19. Improved diagnosis and care for rare diseases through implementation of precision public health framework

Author

Baynam, Gareth, Bowman, F., Lister, K., Walker, C., Pachter, N., Goldblatt, J., Boycott, K., Gahl, W., Kosaki, K., Adachi, T., Ishii, K., Mahede, T., McKenzie, Fiona, Townshend, S., Slee, J., Kiraly-Borri, C., Vasudevan, A., Hawkins, A., Broley, S., Schofield, L., Verhoef, H., Groza, T., Zankl, A., Robinson, P., Haendel, M., Brudno, M., Mattick, J., Dinger, M., Roscioli, T., Cowley, M., Olry, A., Hanauer, M., Alkuraya, F., Taruscio, D., Posada De La Paz, M., Lochmüller, H., Bushby, K., Thompson, R., Hedley, V., Lasko, P., Mina, K., Beilby, J., Tifft, C., Davis, M., Laing, N., Julkowska, D., Le Cam, Y., Terry, S., Kaufmann, P., Eerola, I., Norstedt, I., Rath, A., Suematsu, M., Groft, S., Austin, C., Draghia-Akli, R., Weeramanthri, Tarun, Molster, C., Dawkins, Hugh, Baynam, Gareth, Bowman, F., Lister, K., Walker, C., Pachter, N., Goldblatt, J., Boycott, K., Gahl, W., Kosaki, K., Adachi, T., Ishii, K., Mahede, T., McKenzie, Fiona, Townshend, S., Slee, J., Kiraly-Borri, C., Vasudevan, A., Hawkins, A., Broley, S., Schofield, L., Verhoef, H., Groza, T., Zankl, A., Robinson, P., Haendel, M., Brudno, M., Mattick, J., Dinger, M., Roscioli, T., Cowley, M., Olry, A., Hanauer, M., Alkuraya, F., Taruscio, D., Posada De La Paz, M., Lochmüller, H., Bushby, K., Thompson, R., Hedley, V., Lasko, P., Mina, K., Beilby, J., Tifft, C., Davis, M., Laing, N., Julkowska, D., Le Cam, Y., Terry, S., Kaufmann, P., Eerola, I., Norstedt, I., Rath, A., Suematsu, M., Groft, S., Austin, C., Draghia-Akli, R., Weeramanthri, Tarun, Molster, C., and Dawkins, Hugh

Abstract

© Springer International Publishing AG 2017. Public health relies on technologies to produce and analyse data, as well as effectively develop and implement policies and practices. An example is the public health practice of epidemiology, which relies on computational technology to monitor the health status of populations, identify disadvantaged or at risk population groups and thereby inform health policy and priority setting. Critical to achieving health improvements for the underserved population of people living with rare diseases is early diagnosis and best care. In the rare diseases field, the vast majority of diseases are caused by destructive but previously difficult to identify protein-coding gene mutations. The reduction in cost of genetic testing and advances in the clinical use of genome sequencing, data science and imaging are converging to provide more precise understandings of the ‘person-time-place’ triad. That is: who is affected (people); when the disease is occurring (time); and where the disease is occurring (place). Consequently we are witnessing a paradigm shift in public health policy and practice towards ‘precision public health’. Patient and stakeholder engagement has informed the need for a national public health policy framework for rare diseases. The engagement approach in different countries has produced highly comparable outcomes and objectives. Knowledge and experience sharing across the international rare diseases networks and partnerships has informed the development of the Western Australian Rare Diseases Strategic Framework 2015?2018 (RD Framework) and Australian government health briefings on the need for a National plan. The RD Framework is guiding the translation of genomic and other technologies into the Western Australian health system, leading to greater precision in diagnostic pathways and care, and is an example of how a precision public health framework can improve health outcomes for the rare diseases population. Five vign

Published
2017

20. Severe connective tissue laxity including aortic dilatation in Sotos syndrome.

Author

Hood R.L., Boycott K.M., Stark Z., Boycott K., Roberston S.P., MacKenzie A., Majewski J., Brudno M., Dyment D., Hunter M.F., Bulman D.E., Mcgillivray G., Hood R.L., Boycott K.M., Stark Z., Boycott K., Roberston S.P., MacKenzie A., Majewski J., Brudno M., Dyment D., Hunter M.F., Bulman D.E., and Mcgillivray G.

Published
2016

22. A ZPR1 mutation is associated with a novel syndrome of growth restriction, distinct craniofacial features, alopecia, and hypoplastic kidneys.

Author

Ito, Y. A., Smith, A. C., Kernohan, K. D., Pena, I. A., Ahmed, A., McDonell, L. M., Beaulieu, C., Bulman, D. E., Smidt, A., Sawyer, S. L., Care4Rare Canada Consortium, Dyment, D. A., Boycott, K. M., and Clericuzio, C. L.

Subjects
AUTOSOMAL recessive polycystic kidney, ZINC-finger proteins, BALDNESS, FIBROBLASTS, MISSENSE mutation
Abstract

A novel autosomal recessive disorder characterized by pre‐ and postnatal growth restriction with microcephaly, distinctive craniofacial features, congenital alopecia, hypoplastic kidneys with renal insufficiency, global developmental delay, severe congenital sensorineural hearing loss, early mortality, hydrocephalus, and genital hypoplasia was observed in 4 children from 3 families of New Mexican Hispanic heritage. Three of the children died before 3 years of age from uremia and/or sepsis. Exome sequencing of the surviving individual identified a homozygous c.587T>C (p.Ile196Thr) mutation in ZPR1 Zinc Finger (ZPR1) that segregated appropriately in her family. In a second family, the identical variant was shown to be heterozygous in the affected individual's parents and not homozygous in any of her unaffected siblings. ZPR1 is a ubiquitously expressed, highly conserved protein postulated to transmit proliferative signals from the cell membrane to the nucleus. Structural modeling reveals that p.Ile196Thr disrupts the hydrophobic core of ZPR1. Patient fibroblast cells showed no detectable levels of ZPR1 and the cells showed a defect in cell cycle progression where a significant number of cells remained arrested in the G1 phase. We provide genetic and molecular evidence that a homozygous missense mutation in ZPR1 is associated with a rare and recognizable multisystem syndrome. [ABSTRACT FROM AUTHOR]

Published
2018
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23. Translating the genomics revolution: the need for an international gene therapy consortium for monogenic diseases

Author

Tremblay, Jp, Xiao, X., Aartsma-Rus, A., Barbas, C., Blau, H.m., Bogdanove, A.j., Boycott, K., Braun, S., Breakefield, Xo, Bueren, J.a., Buschmann, M., Byrne, B.j., Calos, M., Cathomen, T., Chamberlain, J., Chuah, Marinee, Cornetta, K., Davies, K.e., Dickson, J.g., Duchateau, P., Flotte, T.r., Gaudet, D., Gersbach, C.a., Gilbert, R., Glorioso, J., Herzog, R., High, K.a., Huang, W., Joung, J.k., Liu, D., Löchmuller, H., Lustig, L., Martens, J., Massie, B., Mavilio, F., Mendell, J.r., Nathwani, A., Ponder, K., Porteus, M., Puymirat, J., Samulski, J., Takeda, S., Thrasher, A., VandenDriessche, Thierry, Wei, Y., Wilson, J., Wilton, S.d., Wolfe, J.h., Gao, G., Cell Biology and Histology, and Division of Gene Therapy & Regenerative Medicine

Subjects
genomics revolution, Gene Therapy, monogenic diseases, Consortium
Published
2013

25. A novel mutation in <italic>LAMC3</italic> associated with generalized polymicrogyria of the cortex and epilepsy.

Author

Zambonin, J. L., Dyment, D. A., Xi, Y., Lamont, R. E., Hartley, T., Miller, E., Kerr, M., Care4Rare Canada Consortium, Boycott, K. M., Parboosingh, J. S., and Venkateswaran, S.

Abstract

Occipital cortical malformation is a rare neurodevelopmental disorder characterized by pachygyria and polymicrogyria of the occipital lobes as well as global developmental delays and seizures. This condition is due to biallelic, loss-of-function mutations in LAMC3 and has been reported in four unrelated families to date. We report an individual with global delays, seizures, and polymicrogyria that extends beyond the occipital lobes and includes the frontal, parietal, temporal, and occipital lobes. Next-generation sequencing identified a homozygous nonsense mutation in LAMC3: c.3190C>T (p.Gln1064*). This finding extends the cortical phenotype associated with LAMC3 mutations. [ABSTRACT FROM AUTHOR]

Published
2018
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26. Translating the genomics revolution: The need for an international gene therapy consortium for monogenic diseases

Author

Tremblay, J.P., Xiao, X., Aartsma-Rus, A., Barbas, C., Blau, H.M., Bogdanove, A.J., Boycott, K., Braun, S., Breakefield, X.O., Bueren, J.A., Buschmann, M., Byrne, B.J., Calos, M., Cathomen, T., Chamberlain, J., Chuah, M., Cornetta, K., Davies, K.E., Dickson, J.G., Duchateau, P., Flotte, T.R., Gaudet, D., Gersbach, C.A., Gilbert, R., Glorioso, J., Herzog, R.W., High, K.A., Huang, W., Huard, J., Joung, J.K., Liu, D., Lochmüller, H., Lustig, L., Martens, J., Massie, B., Mavilio, F., Mendell, J.R., Nathwani, A., Ponder, K., Porteus, M., Puymirat, J., Samulski, J., Takeda, S., Thrasher, A., VandenDriessche, T., Wei, Y., Wilson, J.M., Wilton, S.D., Wolfe, J.H., Gao, G., Tremblay, J.P., Xiao, X., Aartsma-Rus, A., Barbas, C., Blau, H.M., Bogdanove, A.J., Boycott, K., Braun, S., Breakefield, X.O., Bueren, J.A., Buschmann, M., Byrne, B.J., Calos, M., Cathomen, T., Chamberlain, J., Chuah, M., Cornetta, K., Davies, K.E., Dickson, J.G., Duchateau, P., Flotte, T.R., Gaudet, D., Gersbach, C.A., Gilbert, R., Glorioso, J., Herzog, R.W., High, K.A., Huang, W., Huard, J., Joung, J.K., Liu, D., Lochmüller, H., Lustig, L., Martens, J., Massie, B., Mavilio, F., Mendell, J.R., Nathwani, A., Ponder, K., Porteus, M., Puymirat, J., Samulski, J., Takeda, S., Thrasher, A., VandenDriessche, T., Wei, Y., Wilson, J.M., Wilton, S.D., Wolfe, J.H., and Gao, G.

Abstract

Letter to the Editor

Published
2013

28. UBQLN2 Mutations in ALS and ALS/Dementia: A Genetic, Functional and Histopathological Analysis (S05.006)

Author

Fecto, F., primary, Deng, H.-X., additional, Chen, W., additional, Hong, S.-T., additional, Boycott, K., additional, Gorrie, G., additional, Siddique, N., additional, Yang, Y., additional, Shi, Y., additional, Zhai, H., additional, Jiang, H., additional, Hirano, M., additional, Rampersaud, E., additional, Jansen, G., additional, Donkervoort, S., additional, Bigio, E., additional, Brooks, B., additional, Ajroud, K., additional, Sufit, R., additional, Haines, J., additional, Mugnaini, E., additional, Pericak-Vance, M., additional, and Siddique, T., additional

Published
2012
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33. Specific combination of compound heterozygous mutations in 17β-hydroxysteroid dehydrogenase type 4 (HSD17B4) defines a new subtype of D-bifunctional protein deficiency

Author

McMillan Hugh J, Worthylake Thea, Schwartzentruber Jeremy, Gottlieb Chloe C, Lawrence Sarah E, MacKenzie Alex, Beaulieu Chandree L, Mooyer Petra A W, Wanders Ronald J A, Majewski Jacek, Bulman Dennis E, Geraghty Michael T, Ferdinandusse Sacha, and Boycott Kym M

Subjects
Polyneuropathy, Sensorineural hearing loss, Retinitis pigmentosa, Peroxisomes, Cerebellar ataxia, HSD17B4, Medicine
Abstract

Abstract Background D-bifunctional protein (DBP) deficiency is typically apparent within the first month of life with most infants demonstrating hypotonia, psychomotor delay and seizures. Few children survive beyond two years of age. Among patients with prolonged survival all demonstrate severe gross motor delay, absent language development, and severe hearing and visual impairment. DBP contains three catalytically active domains; an N-terminal dehydrogenase, a central hydratase and a C-terminal sterol carrier protein-2-like domain. Three subtypes of the disease are identified based upon the domain affected; DBP type I results from a combined deficiency of dehydrogenase and hydratase activity; DBP type II from isolated hydratase deficiency and DBP type III from isolated dehydrogenase deficiency. Here we report two brothers (16½ and 14 years old) with DBP deficiency characterized by normal early childhood followed by sensorineural hearing loss, progressive cerebellar and sensory ataxia and subclinical retinitis pigmentosa. Methods and results Biochemical analysis revealed normal levels of plasma VLCFA, phytanic acid and pristanic acid, and normal bile acids in urine; based on these results no diagnosis was made. Exome analysis was performed using the Agilent SureSelect 50Mb All Exon Kit and the Illumina HiSeq 2000 next-generation-sequencing (NGS) platform. Compound heterozygous mutations were identified by exome sequencing and confirmed by Sanger sequencing within the dehydrogenase domain (c.101C>T; p.Ala34Val) and hydratase domain (c.1547T>C; p.Ile516Thr) of the 17β-hydroxysteroid dehydrogenase type 4 gene (HSD17B4). These mutations have been previously reported in patients with severe-forms of DBP deficiency, however each mutation was reported in combination with another mutation affecting the same domain. Subsequent studies in fibroblasts revealed normal VLCFA levels, normal C26:0 but reduced pristanic acid beta-oxidation activity. Both DBP hydratase and dehydrogenase activity were markedly decreased but detectable. Conclusions We propose that the DBP phenotype seen in this family represents a distinct and novel subtype of DBP deficiency, which we have termed type IV based on the presence of a missense mutation in each of the domains of DBP resulting in markedly reduced but detectable hydratase and dehydrogenase activity of DBP. Given that the biochemical testing in plasma was normal in these patients, this is likely an underdiagnosed form of DBP deficiency.

Published
2012
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34. Adult siblings with homozygous G6PC3 mutations expand our understanding of the severe congenital neutropenia type 4 (SCN4) phenotype

Author

Fernandez Bridget A, Green Jane S, Bursey Ford, Barrett Brendan, MacMillan Andrée, McColl Sarah, Fernandez Sara, Rahman Proton, Mahoney Krista, Pereira Sergio L, Scherer Stephen W, Boycott Kym M, and Woods Michael O

Subjects
Albinism, Exome sequencing, G6PC3 protein, Inflammatory bowel disease, Oculocutaneous albinism type 4 (OCA4), Neutropenia, Severe congenital neutropenia type 4 (SCN4), SLC45A2 protein, Internal medicine, RC31-1245, Genetics, QH426-470
Abstract

Abstract Background Severe congenital neutropenia type 4 (SCN4) is an autosomal recessive disorder caused by mutations in the third subunit of the enzyme glucose-6-phosphatase (G6PC3). Its core features are congenital neutropenia and a prominent venous skin pattern, and affected individuals have variable birth defects. Oculocutaneous albinism type 4 (OCA4) is caused by autosomal recessive mutations in SLC45A2. Methods We report a sister and brother from Newfoundland, Canada with complex phenotypes. The sister was previously reported by Cullinane et al., 2011. We performed homozygosity mapping, next generation sequencing and conventional Sanger sequencing to identify mutations that cause the phenotype in this family. We have also summarized clinical data from 49 previously reported SCN4 cases with overlapping phenotypes and interpret the medical histories of these siblings in the context of the literature. Results The siblings’ phenotype is due in part to a homozygous mutation in G6PC3, [c.829C > T, p.Gln277X]. Their ages are 38 and 37 years respectively and they are the oldest SCN4 patients published to date. Both presented with congenital neutropenia and later developed Crohn disease. We suggest that the latter is a previously unrecognized SCN4 manifestation and that not all affected individuals have an intellectual disability. The sister also has a homozygous mutation in SLC45A2, which explains her severe oculocutaneous hypopigmentation. Her brother carried one SLC45A2 mutation and was diagnosed with “partial OCA” in childhood. Conclusions This family highlights that apparently novel syndromes can in fact be caused by two known autosomal recessive disorders.

Published
2012
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35. Missense mutations in ITPR1 cause autosomal dominant congenital nonprogressive spinocerebellar ataxia

Author

Huang Lijia, Chardon Jodi, Carter Melissa T, Friend Kathie L, Dudding Tracy E, Schwartzentruber Jeremy, Zou Ruobing, Schofield Peter W, Douglas Stuart, Bulman Dennis E, and Boycott Kym M

Subjects
Congenital nonprogressive spinocerebellar ataxia, Spinocerebellar ataxia type 29, Cerebellar atrophy, ITPR1, Gene identification, Medicine
Abstract

Abstract Background Congenital nonprogressive spinocerebellar ataxia is characterized by early gross motor delay, hypotonia, gait ataxia, mild dysarthria and dysmetria. The clinical presentation remains fairly stable and may be associated with cerebellar atrophy. To date, only a few families with autosomal dominant congenital nonprogressive spinocerebellar ataxia have been reported. Linkage to 3pter was demonstrated in one large Australian family and this locus was designated spinocerebellar ataxia type 29. The objective of this study is to describe an unreported Canadian family with autosomal dominant congenital nonprogressive spinocerebellar ataxia and to identify the underlying genetic causes in this family and the original Australian family. Methods and Results Exome sequencing was performed for the Australian family, resulting in the identification of a heterozygous mutation in the ITPR1 gene. For the Canadian family, genotyping with microsatellite markers and Sanger sequencing of ITPR1 gene were performed; a heterozygous missense mutation in ITPR1 was identified. Conclusions ITPR1 encodes inositol 1,4,5-trisphosphate receptor, type 1, a ligand-gated ion channel that mediates calcium release from the endoplasmic reticulum. Deletions of ITPR1 are known to cause spinocerebellar ataxia type 15, a distinct and very slowly progressive form of cerebellar ataxia with onset in adulthood. Our study demonstrates for the first time that, in addition to spinocerebellar ataxia type 15, alteration of ITPR1 function can cause a distinct congenital nonprogressive ataxia; highlighting important clinical heterogeneity associated with the ITPR1 gene and a significant role of the ITPR1-related pathway in the development and maintenance of the normal functions of the cerebellum.

Published
2012
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36. A generalizable pre-clinical research approach for orphan disease therapy

Author

Beaulieu Chandree L, Samuels Mark E, Ekins Sean, McMaster Christopher R, Edwards Aled M, Krainer Adrian R, Hicks Geoffrey G, Frey Brendan J, Boycott Kym M, and MacKenzie Alex E

Subjects
Orphan disease therapy, Preclinical drug development, Generalizable screening methods, Translational toolbox, Medicine
Abstract

Abstract With the advent of next-generation DNA sequencing, the pace of inherited orphan disease gene identification has increased dramatically, a situation that will continue for at least the next several years. At present, the numbers of such identified disease genes significantly outstrips the number of laboratories available to investigate a given disorder, an asymmetry that will only increase over time. The hope for any genetic disorder is, where possible and in addition to accurate diagnostic test formulation, the development of therapeutic approaches. To this end, we propose here the development of a strategic toolbox and preclinical research pathway for inherited orphan disease. Taking much of what has been learned from rare genetic disease research over the past two decades, we propose generalizable methods utilizing transcriptomic, system-wide chemical biology datasets combined with chemical informatics and, where possible, repurposing of FDA approved drugs for pre-clinical orphan disease therapies. It is hoped that this approach may be of utility for the broader orphan disease research community and provide funding organizations and patient advocacy groups with suggestions for the optimal path forward. In addition to enabling academic pre-clinical research, strategies such as this may also aid in seeding startup companies, as well as further engaging the pharmaceutical industry in the treatment of rare genetic disease.

Published
2012
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37. Incomplete X-linked congenital stationary night blindness: Characterization of mutations in the CACNAIF gene and an assessment of clinical variability

Author

Boycott, K M, Pearcel, W G, and Bech-Hansen, N T

Abstract

X-linked congenital stationary night blindness (CSNB) is a clinically and genetically heterogeneous non-progressive retinal disorder characterized by impaired night vision, decreased visual acuity, myopia, nystagmus, and strabismus. Two loci for CSNB exist on the X chromosome. The locus for complete CSNB (nonrecordable scotopic b-wave and lack of rod dark adaptation) has been mapped to Xp11.4 (Boycott et al. AJHG 62:865-875, 1998), while the gene responsible for incomplete CSNB (subnormal scotopic b-wave and mildly elevated rod adaptation), CACNA1F, has been identified in Xp11.23 (Bech-Hansen et al. Nature Genet. 19:264-267). Our analysis of this retina-specific L-type calcium channel a1-subunit gene has identified a total of 17 different mutations (two-thirds of which are predicted to cause a loss-of-function) in 36 families with incomplete CSNB. One of these mutations, L1045insC, is seen in 15 families of Mennonite ancestry from Western Canada. Clinical variability was examined in 66 patients from these families in terms of night blindness, myopia, visual acuity, congenital nystagmus and strabismus. In 80% of the patients at least one of the main features of CSNB (night blindness, myopia, and nystagmus) was absent. The only clinical feature present in all 66 patients tested was impaired visual acutiy. Among these Patients who shared the common CACNA1F mutation, considerable variability in clinical expression is evident and suggests the presence of genetic modifiers.This research was supported in part by the RP Research Foundation (Canada), the Alberta Heritage Foundation for Medical Research and the Roy Allen Endowment.

Published
1999
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38. 289P Non-tandem duplications in DMD: impacts on genetic counseling and medical decision making.

Author

Gross, B., Higginbotham, E., Lau, L., Sung, W., Moran, O., Hasnain, A., Stavropoulos, D., Bergeron, M. Beaulieu, Boycott, K., McNiven, V., Liu, R., and Matesanz, S.

Subjects
*PRENATAL genetic testing, *FERTILIZATION in vitro, *GENETIC testing, *FLUORESCENCE in situ hybridization, *GENETIC counseling
Abstract

Increased access to and utilization of genetic testing for diagnostic and family planning purposes have led to more children or fetuses incidentally identified to be at risk for dystrophinopathy. We present 3 unrelated cases of a likely benign non-tandem in-frame duplication of exons 45-51 of the DMD gene, inserted into chromosome 17 at q21 (chr17:40,203,142‐40,204,487; GRCh38/UCSC hg38). In case 1, a mother undergoing in vitro fertilization is informed she is a carrier for dystrophinopathy and wishes to proceed with testing of male embryos. Subsequent familial testing to create probes through sequencing with a genome backbone revealed a non-tandem DMD duplication. Case 2 is a 1-day-old male infant with multiple congenital anomalies and Case 3 is a 3-year-old female with developmental delay; both underwent a chromosomal microarray with subsequent FISH analysis showing the same non-tandem DMD duplication. Genome sequencing identified the breakpoints and resolved the genomic structure. In both patients, the duplication was paternally inherited. The father of Case 2 is unaffected, and the father of Case 3 has developmental delay without muscle symptoms. These unrelated families with the same partial DMD duplication are not at risk for dystrophinopathy, as the males have an intact copy of DMD and lack of dystrophinopathy symptoms. Instead, they have an identical complex structural rearrangement, likely a benign variant. As DMD gene duplications occur in ∼10% of dystrophinopathy, this information is vital for future patients with the same exons 45-51 duplication. In the era of advancing dystrophinopathy treatments and increased prenatal genetic testing, accurate classification of in-frame DMD duplications is essential, especially when found in asymptomatic individuals. Without further analysis of such duplications, the significant financial burden of preimplantation genetic testing and potential misguidance in medical management and family planning decisions based on assumed dystrophinopathy risk may occur. [ABSTRACT FROM AUTHOR]

Published
2024
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39. Functional correlation of genome-wide DNA methylation profiles in genetic neurodevelopmental disorders

Author

Michael A. Levy, Raissa Relator, Haley McConkey, Erinija Pranckeviciene, Jennifer Kerkhof, Mouna Barat‐Houari, Sara Bargiacchi, Elisa Biamino, María Palomares Bralo, Gerarda Cappuccio, Andrea Ciolfi, Angus Clarke, Barbara R. DuPont, Mariet W. Elting, Laurence Faivre, Timothy Fee, Marco Ferilli, Robin S. Fletcher, Florian Cherick, Aidin Foroutan, Michael J. Friez, Cristina Gervasini, Sadegheh Haghshenas, Benjamin A. Hilton, Zandra Jenkins, Simranpreet Kaur, Suzanne Lewis, Raymond J. Louie, Silvia Maitz, Donatella Milani, Angela T. Morgan, Renske Oegema, Elsebet Østergaard, Nathalie R. Pallares, Maria Piccione, Astrid S. Plomp, Cathryn Poulton, Jack Reilly, Rocio Rius, Stephen Robertson, Kathleen Rooney, Justine Rousseau, Gijs W. E. Santen, Fernando Santos‐Simarro, Josephine Schijns, Gabriella M. Squeo, Miya St John, Christel Thauvin‐Robinet, Giovanna Traficante, Pleuntje J. van der Sluijs, Samantha A. Vergano, Niels Vos, Kellie K. Walden, Dimitar Azmanov, Tugce B. Balci, Siddharth Banka, Jozef Gecz, Peter Henneman, Jennifer A. Lee, Marcel M. A. M. Mannens, Tony Roscioli, Victoria Siu, David J. Amor, Gareth Baynam, Eric G. Bend, Kym Boycott, Nicola Brunetti‐Pierri, Philippe M. Campeau, Dominique Campion, John Christodoulou, David Dyment, Natacha Esber, Jill A. Fahrner, Mark D. Fleming, David Genevieve, Delphine Heron, Thomas Husson, Kristin D. Kernohan, Alisdair McNeill, Leonie A. Menke, Giuseppe Merla, Paolo Prontera, Cheryl Rockman‐Greenberg, Charles Schwartz, Steven A. Skinner, Roger E. Stevenson, Marie Vincent, Antonio Vitobello, Marco Tartaglia, Marielle Alders, Matthew L. Tedder, Bekim Sadikovic, Human genetics, Amsterdam Reproduction & Development (AR&D), Pediatrics, Levy M.A., Relator R., McConkey H., Pranckeviciene E., Kerkhof J., Barat-Houari M., Bargiacchi S., Biamino E., Palomares Bralo M., Cappuccio G., Ciolfi A., Clarke A., DuPont B.R., Elting M.W., Faivre L., Fee T., Ferilli M., Fletcher R.S., Cherick F., Foroutan A., Friez M.J., Gervasini C., Haghshenas S., Hilton B.A., Jenkins Z., Kaur S., Lewis S., Louie R.J., Maitz S., Milani D., Morgan A.T., Oegema R., Ostergaard E., Pallares N.R., Piccione M., Plomp A.S., Poulton C., Reilly J., Rius R., Robertson S., Rooney K., Rousseau J., Santen G.W.E., Santos-Simarro F., Schijns J., Squeo G.M., John M.S., Thauvin-Robinet C., Traficante G., van der Sluijs P.J., Vergano S.A., Vos N., Walden K.K., Azmanov D., Balci T.B., Banka S., Gecz J., Henneman P., Lee J.A., Mannens M.M.A.M., Roscioli T., Siu V., Amor D.J., Baynam G., Bend E.G., Boycott K., Brunetti-Pierri N., Campeau P.M., Campion D., Christodoulou J., Dyment D., Esber N., Fahrner J.A., Fleming M.D., Genevieve D., Heron D., Husson T., Kernohan K.D., McNeill A., Menke L.A., Merla G., Prontera P., Rockman-Greenberg C., Schwartz C., Skinner S.A., Stevenson R.E., Vincent M., Vitobello A., Tartaglia M., Alders M., Tedder M.L., Sadikovic B., Levy, Michael A, Relator, Raissa, Mcconkey, Haley, Pranckeviciene, Erinija, Kerkhof, Jennifer, Barat-Houari, Mouna, Bargiacchi, Sara, Biamino, Elisa, Bralo, María Palomare, Cappuccio, Gerarda, Ciolfi, Andrea, Clarke, Angu, Dupont, Barbara R, Elting, Mariet W, Faivre, Laurence, Fee, Timothy, Ferilli, Marco, Fletcher, Robin S, Cherick, Florian, Foroutan, Aidin, Friez, Michael J, Gervasini, Cristina, Haghshenas, Sadegheh, Hilton, Benjamin A, Jenkins, Zandra, Kaur, Simranpreet, Lewis, Suzanne, Louie, Raymond J, Maitz, Silvia, Milani, Donatella, Morgan, Angela T, Oegema, Renske, Østergaard, Elsebet, Pallares, Nathalie Ruiz, Piccione, Maria, Plomp, Astrid S, Poulton, Cathryn, Reilly, Jack, Rius, Rocio, Robertson, Stephen, Rooney, Kathleen, Rousseau, Justine, Santen, Gijs W E, Santos-Simarro, Fernando, Schijns, Josephine, Squeo, Gabriella Maria, John, Miya St, Thauvin-Robinet, Christel, Traficante, Giovanna, van der Sluijs, Pleuntje J, Vergano, Samantha A, Vos, Niel, Walden, Kellie K, Azmanov, Dimitar, Balci, Tugce B, Banka, Siddharth, Gecz, Jozef, Henneman, Peter, Lee, Jennifer A, Mannens, Marcel M A M, Roscioli, Tony, Siu, Victoria, Amor, David J, Baynam, Gareth, Bend, Eric G, Boycott, Kym, Brunetti-Pierri, Nicola, Campeau, Philippe M, Campion, Dominique, Christodoulou, John, Dyment, David, Esber, Natacha, Fahrner, Jill A, Fleming, Mark D, Genevieve, David, Heron, Delphine, Husson, Thoma, Kernohan, Kristin D, Mcneill, Alisdair, Menke, Leonie A, Merla, Giuseppe, Prontera, Paolo, Rockman-Greenberg, Cheryl, Schwartz, Charle, Skinner, Steven A, Stevenson, Roger E, Vincent, Marie, Vitobello, Antonio, Tartaglia, Marco, Alders, Marielle, Tedder, Matthew L, Sadikovic, Bekim, Human Genetics, General Paediatrics, Graduate School, AGEM - Amsterdam Gastroenterology Endocrinology Metabolism, ARD - Amsterdam Reproduction and Development, ANS - Cellular & Molecular Mechanisms, ANS - Complex Trait Genetics, and ACS - Pulmonary hypertension & thrombosis

Subjects
DNA methylation, clinical diagnostics, Syndrome, DNA methylation, clinical diagnostics, episignatures, neurodevelopmental syndromes, neurodevelopmental syndromes, Epigenesis, Genetic, Neurodevelopmental Disorders, Genetics, Humans, CpG Islands, DNA, Intergenic, episignatures, Episignature, Genetics (clinical)
Abstract

An expanding range of genetic syndromes are characterized by genome-wide disruptions in DNA methylation profiles referred to as episignatures. Episignatures are distinct, highly sensitive and specific biomarkers that have recently been applied in clinical diagnosis of genetic syndromes. Episignatures are contained within the broader disorder-specific genome-wide DNA methylation changes which can share significant overlap amongst different conditions. In this study we performed functional genomic assessment and comparison of disorder-specific and overlapping genome-wide DNA methylation changes related to 65 genetic syndromes with previously described episignatures. We demonstrate evidence of disorder-specific and recurring genome-wide differentially methylated probes (DMPs) and regions (DMRs). The overall distribution of DMPs and DMRs across the majority of the neurodevelopmental genetic syndromes analyzed showed substantial enrichment in gene promoters and CpG islands, and under-representation of the more variable intergenic regions. Analysis showed significant enrichment of the DMPs and DMRs in gene pathways and processes related to neurodevelopment, including neurogenesis, synaptic signaling and synaptic transmission. This study expands beyond the diagnostic utility of DNA methylation episignatures by demonstrating correlation between the function of the mutated genes and the consequent genomic DNA methylation profiles as a key functional element in the molecular etiology of genetic neurodevelopmental disorders. This article is protected by copyright. All rights reserved.

Published
2022
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40. SPEN haploinsufficiency causes a neurodevelopmental disorder overlapping proximal 1p36 deletion syndrome with an episignature of X chromosomes in females

Author

Gilles Morin, Krista Bluske, Nathaniel H. Robin, Laurence Faivre, Manuela Priolo, Dihong Zhou, Evangeline Kurtz-Nelson, Tianyun Wang, Omar Sherbini, Daryl A. Scott, Karen Stals, Fabíola Paoli Monteiro, Kaifang Pang, Sara Cabet, Francesca Clementina Radio, Bruno Dallapiccola, Marjon van Slegtenhorst, Rachel K. Earl, Katheryn Grand, Maria Iascone, Alice S. Brooks, Angelo Selicorni, July K. Jean Cuevas, Paolo Gasparini, Maria Lisa Dentici, Marialetizia Motta, Britt-Marie Anderlid, Kristin Lindstrom, Berrin Monteleone, Andrea Ciolfi, Karin Weiss, Katharina Steindl, Kirsty McWalter, Rosalba Carrozzo, Ruben Boers, Helen Kingston, Kym M. Boycott, Bekim Sadikovic, Laura Schultz-Rogers, Evan E. Eichler, Laura A Cross, Alison M R Castle, Louisa Kalsner, Lucia Pedace, Marijke R. Wevers, John M. Graham, Jessica Sebastian, Antonio Vitobello, Gaetan Lesca, Alexander P.A. Stegmann, Suneeta Madan-Khetarpal, Tahsin Stefan Barakat, Abdallah F. Elias, Teresa Robert Finestra, Adeline Vanderver, Peter D. Turnpenny, Bregje W.M. van Bon, Aida Telegrafi, David J. Amor, Deepali N. Shinde, Pedro A. Sanchez-Lara, Lisenka E.L.M. Vissers, Adam Jackson, Rolph Pfundt, Alessandro Bruselles, Andres Hernandez-Garcia, Karin E. M. Diderich, Flavio Faletra, Dana H. Goodloe, Joanne Baez, Sarit Ravid, Romano Tenconi, Sarah L. Sawyer, Lynn Pais, Bronwyn Kerr, Joost Gribnau, Lauren Carter, Melissa T. Carter, Zhandong Liu, Jennifer L. Kemppainen, Jennifer MacKenzie, Jimmy Holder, Elke de Boer, Margaret Au, Taila Hartley, Carol J Saunders, Luciana Musante, Bert B.A. de Vries, Tania Vertemati Secches, Haley McConkey, Willow Sheehan, Francesca Pantaleoni, Caterina Zanus, Christophe Philippe, Chelsea Roadhouse, Stefania Lo Cicero, Sian Ellard, R. Tanner Hagelstrom, Megha Desai, Fernando Kok, Joset Pascal, Marco Tartaglia, Eric W. Klee, Eva Morava, Michael A. Levy, Peggy Kulch, Lyndon Gallacher, Erica L. Macke, Emilia Stellacci, Siddharth Banka, Kristin G. Monaghan, Anita Rauch, Meghan C. Towne, Kate Chandler, Clinical Genetics, Developmental Biology, Radio, F. C., Pang, K., Ciolfi, A., Levy, M. A., Hernandez-Garcia, A., Pedace, L., Pantaleoni, F., Liu, Z., de Boer, E., Jackson, A., Bruselles, A., Mcconkey, H., Stellacci, E., Lo Cicero, S., Motta, M., Carrozzo, R., Dentici, M. L., Mcwalter, K., Desai, M., Monaghan, K. G., Telegrafi, A., Philippe, C., Vitobello, A., Au, M., Grand, K., Sanchez-Lara, P. A., Baez, J., Lindstrom, K., Kulch, P., Sebastian, J., Madan-Khetarpal, S., Roadhouse, C., Mackenzie, J. J., Monteleone, B., Saunders, C. J., Jean Cuevas, J. K., Cross, L., Zhou, D., Hartley, T., Sawyer, S. L., Monteiro, F. P., Secches, T. V., Kok, F., Schultz-Rogers, L. E., Macke, E. L., Morava, E., Klee, E. W., Kemppainen, J., Iascone, M., Selicorni, A., Tenconi, R., Amor, D. J., Pais, L., Gallacher, L., Turnpenny, P. D., Stals, K., Ellard, S., Cabet, S., Lesca, G., Pascal, J., Steindl, K., Ravid, S., Weiss, K., Castle, A. M. R., Carter, M. T., Kalsner, L., de Vries, B. B. A., van Bon, B. W., Wevers, M. R., Pfundt, R., Stegmann, A. P. A., Kerr, B., Kingston, H. M., Chandler, K. E., Sheehan, W., Elias, A. F., Shinde, D. N., Towne, M. C., Robin, N. H., Goodloe, D., Vanderver, A., Sherbini, O., Bluske, K., Hagelstrom, R. T., Zanus, C., Faletra, F., Musante, L., Kurtz-Nelson, E. C., Earl, R. K., Anderlid, B. -M., Morin, G., van Slegtenhorst, M., Diderich, K. E. M., Brooks, A. S., Gribnau, J., Boers, R. G., Finestra, T. R., Carter, L. B., Rauch, A., Gasparini, P., Boycott, K. M., Barakat, T. S., Graham, J. M., Faivre, L., Banka, S., Wang, T., Eichler, E. E., Priolo, M., Dallapiccola, B., Vissers, L. E. L. M., Sadikovic, B., Scott, D. A., Holder, J. L., Tartaglia, M., MUMC+: DA KG Lab Centraal Lab (9), and RS: FHML non-thematic output

Subjects
0301 basic medicine, SHARP, Male, obesity, genotype-phenotype correlations, Autism Spectrum Disorder, PROTEIN, Chromosome Disorders, Haploinsufficiency, RNA-Binding Protein, PHENOTYPE CORRELATIONS, 1p36, distal 1p36 deletion syndrome, DNA methylome analysis, episignature, neurodevelopmental disorder, proximal 1p36 deletion syndrome, SPEN, X chromosome, Adolescent, Child, Child, Preschool, Chromosome Deletion, Chromosomes, Human, Pair 1, Chromosomes, Human, X, DNA Methylation, DNA-Binding Proteins, Epigenesis, Genetic, Female, Humans, Intellectual Disability, Neurodevelopmental Disorders, Phenotype, RNA-Binding Proteins, Young Adult, 0302 clinical medicine, Neurodevelopmental disorder, Neurodevelopmental Disorder, Intellectual disability, MOLECULAR CHARACTERIZATION, Genetics (clinical), Genetics, DNA methylome analysi, SPLIT-ENDS, Hypotonia, Autism spectrum disorder, MONOSOMY 1P36, Pair 1, medicine.symptom, Rare cancers Radboud Institute for Health Sciences [Radboudumc 9], Human, DNA-Binding Protein, Biology, genotype-phenotype correlation, Chromosomes, 03 medical and health sciences, Genetic, SDG 3 - Good Health and Well-being, Report, REVEALS, medicine, Epigenetics, Preschool, Neurodevelopmental disorders Donders Center for Medical Neuroscience [Radboudumc 7], 1p36 deletion syndrome, IDENTIFICATION, MUTATIONS, medicine.disease, GENE, 030104 developmental biology, Chromosome Disorder, 030217 neurology & neurosurgery, Epigenesis
Abstract

Contains fulltext : 231702.pdf (Publisher’s version ) (Closed access) Deletion 1p36 (del1p36) syndrome is the most common human disorder resulting from a terminal autosomal deletion. This condition is molecularly and clinically heterogeneous. Deletions involving two non-overlapping regions, known as the distal (telomeric) and proximal (centromeric) critical regions, are sufficient to cause the majority of the recurrent clinical features, although with different facial features and dysmorphisms. SPEN encodes a transcriptional repressor commonly deleted in proximal del1p36 syndrome and is located centromeric to the proximal 1p36 critical region. Here, we used clinical data from 34 individuals with truncating variants in SPEN to define a neurodevelopmental disorder presenting with features that overlap considerably with those of proximal del1p36 syndrome. The clinical profile of this disease includes developmental delay/intellectual disability, autism spectrum disorder, anxiety, aggressive behavior, attention deficit disorder, hypotonia, brain and spine anomalies, congenital heart defects, high/narrow palate, facial dysmorphisms, and obesity/increased BMI, especially in females. SPEN also emerges as a relevant gene for del1p36 syndrome by co-expression analyses. Finally, we show that haploinsufficiency of SPEN is associated with a distinctive DNA methylation episignature of the X chromosome in affected females, providing further evidence of a specific contribution of the protein to the epigenetic control of this chromosome, and a paradigm of an X chromosome-specific episignature that classifies syndromic traits. We conclude that SPEN is required for multiple developmental processes and SPEN haploinsufficiency is a major contributor to a disorder associated with deletions centromeric to the previously established 1p36 critical regions.

Published
2021

41. Clinical application of fetal genome-wide sequencing during pregnancy: position statement of the Canadian College of Medical Geneticists.

Author

Lazier J, Hartley T, Brock JA, Caluseriu O, Chitayat D, Laberge AM, Langlois S, Lauzon J, Nelson TN, Parboosingh J, Stavropoulos DJ, Boycott K, and Armour CM

Subjects
Adult, Canada, Child, Female, Fetus, Humans, Pregnancy, Prenatal Care, Genetic Counseling, Prenatal Diagnosis methods
Abstract

Purpose and Scope: The aim of this position statement is to provide recommendations for Canadian healthcare professionals regarding the use of genome-wide sequencing (GWS) in the context of diagnostic testing of the fetus during pregnancy. This statement was developed to facilitate clinical translation of GWS as a prenatal diagnostic test and the development of best practices in Canada, but the applicability of this document is broader and aims to help professionals in other healthcare systems., Methods of Statement Development: A multidisciplinary group was assembled to review existing literature on fetal GWS for genetic diagnosis in the context of suspected monogenic diseases and to make recommendations relevant to the Canadian context. The statement was circulated for comments to the Canadian College of Medical Geneticists (CCMG) membership-at-large and, following incorporation of feedback, approved by the CCMG Board of Directors on 19 February 2021., Results and Conclusions: The use of prenatal GWS is indicated for the investigation of multiple fetal anomalies. Its use in the context of isolated fetal anomaly should be guided by available resources and current evidence, which is continually changing. During pregnancy, GWS should be ordered by, or in collaboration with, a medical geneticist. It should be used following detailed phenotyping to interrogate known disease genes, preferably using a trio approach, following detailed fetal phenotyping. Testing should be done with an overall aim to help in the management of the pregnancy, delivery and postnatal care. It should be guided by personal utility of the test for the pregnant person and clinical utility for pregnancy and birth management, as outlined herein. Genetic counselling is crucial in making the parental decision an informed decision. Chromosomal microarray analysis should be completed in parallel or prior to GWS and should be preceded by Quantitative Fluorescent PCR (QF-PCR) for detection of common aneuploidies. In normal circumstances, only pathogenic and likely pathogenic variants with a high likelihood of being associated with the identified fetal anomalies should be reported. Reporting of secondary findings, defined as purposeful analysis of variants in a set of medically actionable genes, should not, by default, be performed in the prenatal context. Laboratories should only report incidental findings that reveal risk of a significant Mendelian condition during infancy and childhood. Should a laboratory have a policy for reporting incidental findings in medically actionable adult-onset conditions, they should only be reported with explicit opt-in consent signed by the tested individuals. Genetic counselling is crucial in disclosing the test results and the implications the results may have for the fetus. It should be emphasised that negative results do not rule out a genetic diagnosis nor guarantee a good prognosis. Postnatal phenotyping and reanalysis of existing data should be considered. Families should be given the opportunity to participate in research studies as appropriate. These recommendations will be routinely re-evaluated as knowledge of the diagnostic and clinical utility of fetal GWS during pregnancy improves., Competing Interests: Competing interests: TN: spouse employed by Illumina., (© Author(s) (or their employer(s)) 2022. Re-use permitted under CC BY-NC. No commercial re-use. See rights and permissions. Published by BMJ.)

Published
2022
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42. Novel diagnostic DNA methylation episignatures expand and refine the epigenetic landscapes of Mendelian disorders.

Author

Levy MA, McConkey H, Kerkhof J, Barat-Houari M, Bargiacchi S, Biamino E, Bralo MP, Cappuccio G, Ciolfi A, Clarke A, DuPont BR, Elting MW, Faivre L, Fee T, Fletcher RS, Cherik F, Foroutan A, Friez MJ, Gervasini C, Haghshenas S, Hilton BA, Jenkins Z, Kaur S, Lewis S, Louie RJ, Maitz S, Milani D, Morgan AT, Oegema R, Østergaard E, Pallares NR, Piccione M, Pizzi S, Plomp AS, Poulton C, Reilly J, Relator R, Rius R, Robertson S, Rooney K, Rousseau J, Santen GWE, Santos-Simarro F, Schijns J, Squeo GM, St John M, Thauvin-Robinet C, Traficante G, van der Sluijs PJ, Vergano SA, Vos N, Walden KK, Azmanov D, Balci T, Banka S, Gecz J, Henneman P, Lee JA, Mannens MMAM, Roscioli T, Siu V, Amor DJ, Baynam G, Bend EG, Boycott K, Brunetti-Pierri N, Campeau PM, Christodoulou J, Dyment D, Esber N, Fahrner JA, Fleming MD, Genevieve D, Kerrnohan KD, McNeill A, Menke LA, Merla G, Prontera P, Rockman-Greenberg C, Schwartz C, Skinner SA, Stevenson RE, Vitobello A, Tartaglia M, Alders M, Tedder ML, and Sadikovic B

Abstract

Overlapping clinical phenotypes and an expanding breadth and complexity of genomic associations are a growing challenge in the diagnosis and clinical management of Mendelian disorders. The functional consequences and clinical impacts of genomic variation may involve unique, disorder-specific, genomic DNA methylation episignatures. In this study, we describe 19 novel episignature disorders and compare the findings alongside 38 previously established episignatures for a total of 57 episignatures associated with 65 genetic syndromes. We demonstrate increasing resolution and specificity ranging from protein complex, gene, sub-gene, protein domain, and even single nucleotide-level Mendelian episignatures. We show the power of multiclass modeling to develop highly accurate and disease-specific diagnostic classifiers. This study significantly expands the number and spectrum of disorders with detectable DNA methylation episignatures, improves the clinical diagnostic capabilities through the resolution of unsolved cases and the reclassification of variants of unknown clinical significance, and provides further insight into the molecular etiology of Mendelian conditions., Competing Interests: The authors declare no competing interests., (© 2021 The Author(s).)

Published
2021
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43. When to think outside the autozygome: Best practices for exome sequencing in "consanguineous" families.

Author

Eaton A, Hartley T, Kernohan K, Ito Y, Lamont R, Parboosingh J, Barrowman N, Innes AM, and Boycott K

Subjects
Canada epidemiology, Consanguinity, Female, Genetic Diseases, Inborn diagnosis, Genetic Diseases, Inborn genetics, Genetic Diseases, Inborn pathology, Genetics, Population trends, Homozygote, Humans, Male, Mutation genetics, Pedigree, Exome Sequencing, Exome genetics, Genetic Diseases, Inborn cerebrospinal fluid, Genetic Testing
Abstract

Exome sequencing (ES) is an effective diagnostic tool with a high yield in consanguineous families. However, how diagnostic yield and mode of inheritance relate to family structure has not been well delineated. We reviewed ES results from families enrolled in the Care4Rare Canada research consortium with various degrees of consanguinity. We contrasted the diagnostic yield in families with parents who are second cousins or closer ("close" consanguinity) vs those more distantly related or from isolated populations ("presumed" consanguinity). We further stratified by number of affected individuals (multiple affected ["multiplex"] vs single affected [simplex]). The overall yield in 116 families was 45.7% (n = 53) with no significant difference between subgroups. Homozygous variants accounted for 100% and 75% of diagnoses in close and presumed consanguineous multiplex families, respectively. In simplex presumed consanguineous families, a striking 46.2% of diagnoses were due to de novo variants, vs only 11.8% in simplex closely consanguineous families (88.2% homozygous). Our data underscores the high yield of ES in consanguineous families and highlights that while a singleton approach may frequently be reasonable and a responsible use of resources, trio sequencing should be strongly considered in simplex families in the absence of confirmed consanguinity given the proportion of de novo variants., (© 2020 John Wiley & Sons A/S. Published by John Wiley & Sons Ltd.)

Published
2020
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44. MSTO1 mutations cause mtDNA depletion, manifesting as muscular dystrophy with cerebellar involvement.

Author

Donkervoort S, Sabouny R, Yun P, Gauquelin L, Chao KR, Hu Y, Al Khatib I, Töpf A, Mohassel P, Cummings BB, Kaur R, Saade D, Moore SA, Waddell LB, Farrar MA, Goodrich JK, Uapinyoying P, Chan SHS, Javed A, Leach ME, Karachunski P, Dalton J, Medne L, Harper A, Thompson C, Thiffault I, Specht S, Lamont RE, Saunders C, Racher H, Bernier FP, Mowat D, Witting N, Vissing J, Hanson R, Coffman KA, Hainlen M, Parboosingh JS, Carnevale A, Yoon G, Schnur RE, Boycott KM, Mah JK, Straub V, Foley AR, Innes AM, Bönnemann CG, and Shutt TE

Subjects
Adolescent, Adult, Atrophy, Cells, Cultured, Cerebellar Diseases diagnostic imaging, Cerebellar Diseases pathology, Cerebellar Diseases physiopathology, Child, DNA Copy Number Variations, Female, Fibroblasts metabolism, Fibroblasts pathology, Humans, Male, Middle Aged, Mitochondrial Diseases diagnostic imaging, Mitochondrial Diseases pathology, Mitochondrial Diseases physiopathology, Muscles pathology, Muscular Dystrophies diagnostic imaging, Muscular Dystrophies pathology, Muscular Dystrophies physiopathology, Phenotype, Young Adult, Cell Cycle Proteins genetics, Cerebellar Diseases genetics, Cytoskeletal Proteins genetics, DNA, Mitochondrial, Mitochondrial Diseases genetics, Muscular Dystrophies genetics, Mutation
Abstract

MSTO1 encodes a cytosolic mitochondrial fusion protein, misato homolog 1 or MSTO1. While the full genotype-phenotype spectrum remains to be explored, pathogenic variants in MSTO1 have recently been reported in a small number of patients presenting with a phenotype of cerebellar ataxia, congenital muscle involvement with histologic findings ranging from myopathic to dystrophic and pigmentary retinopathy. The proposed underlying pathogenic mechanism of MSTO1-related disease is suggestive of impaired mitochondrial fusion secondary to a loss of function of MSTO1. Disorders of mitochondrial fusion and fission have been shown to also lead to mitochondrial DNA (mtDNA) depletion, linking them to the mtDNA depletion syndromes, a clinically and genetically diverse class of mitochondrial diseases characterized by a reduction of cellular mtDNA content. However, the consequences of pathogenic variants in MSTO1 on mtDNA maintenance remain poorly understood. We present extensive phenotypic and genetic data from 12 independent families, including 15 new patients harbouring a broad array of bi-allelic MSTO1 pathogenic variants, and we provide functional characterization from seven MSTO1-related disease patient fibroblasts. Bi-allelic loss-of-function variants in MSTO1 manifest clinically with a remarkably consistent phenotype of childhood-onset muscular dystrophy, corticospinal tract dysfunction and early-onset non-progressive cerebellar atrophy. MSTO1 protein was not detectable in the cultured fibroblasts of all seven patients evaluated, suggesting that pathogenic variants result in a loss of protein expression and/or affect protein stability. Consistent with impaired mitochondrial fusion, mitochondrial networks in fibroblasts were found to be fragmented. Furthermore, all fibroblasts were found to have depletion of mtDNA ranging from 30 to 70% along with alterations to mtDNA nucleoids. Our data corroborate the role of MSTO1 as a mitochondrial fusion protein and highlight a previously unrecognized link to mtDNA regulation. As impaired mitochondrial fusion is a recognized cause of mtDNA depletion syndromes, this novel link to mtDNA depletion in patient fibroblasts suggests that MSTO1-deficiency should also be considered a mtDNA depletion syndrome. Thus, we provide mechanistic insight into the disease pathogenesis associated with MSTO1 mutations and further define the clinical spectrum and the natural history of MSTO1-related disease.

Published
2019
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45. Phenotype delineation of ZNF462 related syndrome.

Author

Kruszka P, Hu T, Hong S, Signer R, Cogné B, Isidor B, Mazzola SE, Giltay JC, van Gassen KLI, England EM, Pais L, Ockeloen CW, Sanchez-Lara PA, Kinning E, Adams DJ, Treat K, Torres-Martinez W, Bedeschi MF, Iascone M, Blaney S, Bell O, Tan TY, Delrue MA, Jurgens J, Barry BJ, Engle EC, Savage SK, Fleischer N, Martinez-Agosto JA, Boycott K, Zackai EH, and Muenke M

Subjects
Adolescent, Adult, Child, Child, Preschool, Facies, Female, Humans, Infant, Male, Phenotype, Syndrome, DNA-Binding Proteins genetics, Nerve Tissue Proteins genetics, Transcription Factors genetics
Abstract

Zinc finger protein 462 (ZNF462) is a relatively newly discovered vertebrate specific protein with known critical roles in embryonic development in animal models. Two case reports and a case series study have described the phenotype of 10 individuals with ZNF462 loss of function variants. Herein, we present 14 new individuals with loss of function variants to the previous studies to delineate the syndrome of loss of function in ZNF462. Collectively, these 24 individuals present with recurring phenotypes that define a multiple congenital anomaly syndrome. Most have some form of developmental delay (79%) and a minority has autism spectrum disorder (33%). Characteristic facial features include ptosis (83%), down slanting palpebral fissures (58%), exaggerated Cupid's bow/wide philtrum (54%), and arched eyebrows (50%). Metopic ridging or craniosynostosis was found in a third of study participants and feeding problems in half. Other phenotype characteristics include dysgenesis of the corpus callosum in 25% of individuals, hypotonia in half, and structural heart defects in 21%. Using facial analysis technology, a computer algorithm applying deep learning was able to accurately differentiate individuals with ZNF462 loss of function variants from individuals with Noonan syndrome and healthy controls. In summary, we describe a multiple congenital anomaly syndrome associated with haploinsufficiency of ZNF462 that has distinct clinical characteristics and facial features., (© 2019 Wiley Periodicals, Inc.)

Published
2019
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46. The Future of Asthma Care: Personalized Asthma Treatment.

Author

Holgate ST, Walker S, West B, and Boycott K

Subjects
Humans, Asthma, Precision Medicine methods
Abstract

Although once considered a single disease entity, asthma is now known to be a complex inflammatory disease engaging a range of causal pathways. The most frequent forms of asthma are identified by sputum/blood eosinophilia and activation of type 2 inflammatory pathways involving interleukins-3, -4, -5, and granulocyte-macrophage colony-stimulating factor. The use of diagnostics that identify T2 engagement linked to the selective use of highly targeted biologics has opened up a new way of managing severe disease. Novel technologies, such as wearables and intelligent inhalers, enable real-time remote monitoring of asthma, creating a unique opportunity for personalized health care., (Copyright © 2018 Elsevier Inc. All rights reserved.)

Published
2019
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47. Targeted exome analysis identifies the genetic basis of disease in over 50% of patients with a wide range of ataxia-related phenotypes.

Author

Sun M, Johnson AK, Nelakuditi V, Guidugli L, Fischer D, Arndt K, Ma L, Sandford E, Shakkottai V, Boycott K, Warman-Chardon J, Li Z, Del Gaudio D, Burmeister M, Gomez CM, Waggoner DJ, and Das S

Subjects
Adolescent, Adult, Aged, Aged, 80 and over, Ataxia classification, Ataxia diagnosis, Ataxia pathology, Canada, Child, Child, Preschool, Female, Humans, Male, Middle Aged, Mutation genetics, Phenotype, Sequence Analysis, DNA, Young Adult, Ataxia genetics, Exome genetics, Genetic Predisposition to Disease, Exome Sequencing
Abstract

Purpose: To examine the impact of a targeted exome approach for the molecular diagnosis of patients nationwide with a wide range of ataxia-related phenotypes., Methods: One hundred and seventy patients with ataxia of unknown etiology referred from clinics throughout the United States and Canada were studied using a targeted exome approach. Patients ranged in age from 2 to 88 years. Analysis was focused on 441 curated genes associated with ataxia and ataxia-like conditions., Results: Pathogenic and suspected diagnostic variants were identified in 88 of the 170 patients, providing a positive molecular diagnostic rate of 52%. Forty-six different genes were implicated, with the six most commonly mutated genes being SPG7, SYNE1, ADCK3, CACNA1A, ATP1A3, and SPTBN2, which accounted for >40% of the positive cases. In many cases a diagnosis was provided for conditions that were not suspected and resulted in the broadening of the clinical spectrum of several conditions., Conclusion: Exome sequencing with targeted analysis provides a high-yield approach for the genetic diagnosis of ataxia-related conditions. This is the largest targeted exome study performed to date in patients with ataxia and ataxia-like conditions and represents patients with a wide range of ataxia phenotypes typically encountered in neurology and genetics clinics.

Published
2019
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48. Development of Criteria for Epilepsy Genetic Testing in Ontario, Canada.

Author

Jain P, Andrade D, Donner E, Dyment D, Prasad AN, Goobie S, Boycott K, Lines M, and Snead OC

Subjects
Epilepsy epidemiology, Guidelines as Topic standards, Humans, Ontario epidemiology, Epilepsy diagnosis, Epilepsy genetics, Genetic Predisposition to Disease, Genetic Testing methods, Genetic Testing standards
Abstract

Multiple genes/variants have been implicated in various epileptic conditions. However, there is little general guidance available on the circumstances in which genetic testing is indicated and test selection in order to guide optimal test appropriateness and benefit. This is an account of the development of guidelines for genetic testing in epilepsy, which have been developed in Ontario, Canada. The Genetic Testing Advisory Committee was established in Ontario to review the clinical utility and validity of genetic tests and the provision of genetic testing in Ontario. As part of their mandate, the committee also developed recommendations and guidelines for genetic testing in epilepsy. The recommendations include mandatory prerequisites for an epileptology/geneticist/clinical biochemical geneticist consultation, prerequisite diagnostic procedures, circumstances in which genetic testing is indicated and not indicated and guidance for selection of genetic tests, including their general limitations and considerations. These guidelines represent a step toward the development of evidence-based gene panels for epilepsy in Ontario, the repatriation of genetic testing for epilepsy into Ontario molecular genetic laboratories and public funding of genetic tests for epilepsy in Ontario.

Published
2019
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49. Whole-exome sequencing is a valuable diagnostic tool for inherited peripheral neuropathies: Outcomes from a cohort of 50 families.

Author

Hartley T, Wagner JD, Warman-Chardon J, Tétreault M, Brady L, Baker S, Tarnopolsky M, Bourque PR, Parboosingh JS, Smith C, McInnes B, Innes AM, Bernier F, Curry CJ, Yoon G, Horvath GA, Bareke E, Gillespie M, Majewski J, Bulman DE, Dyment DA, and Boycott KM

Subjects
Acetyltransferases genetics, Charcot-Marie-Tooth Disease diagnosis, Charcot-Marie-Tooth Disease pathology, Exome genetics, Female, Humans, Intracellular Signaling Peptides and Proteins genetics, Kinesins genetics, Male, Mutation, Peripheral Nervous System Diseases diagnosis, Peripheral Nervous System Diseases pathology, Protein Serine-Threonine Kinases genetics, Charcot-Marie-Tooth Disease genetics, High-Throughput Nucleotide Sequencing, Peripheral Nervous System Diseases genetics, Exome Sequencing
Abstract

The inherited peripheral neuropathies (IPNs) are characterized by marked clinical and genetic heterogeneity and include relatively frequent presentations such as Charcot-Marie-Tooth disease and hereditary motor neuropathy, as well as more rare conditions where peripheral neuropathy is associated with additional features. There are over 250 genes known to cause IPN-related disorders but it is estimated that in approximately 50% of affected individuals a molecular diagnosis is not achieved. In this study, we examine the diagnostic utility of whole-exome sequencing (WES) in a cohort of 50 families with 1 or more affected individuals with a molecularly undiagnosed IPN with or without additional features. Pathogenic or likely pathogenic variants in genes known to cause IPN were identified in 24% (12/50) of the families. A further 22% (11/50) of families carried sequence variants in IPN genes in which the significance remains unclear. An additional 12% (6/50) of families had variants in novel IPN candidate genes, 3 of which have been published thus far as novel discoveries (KIF1A, TBCK, and MCM3AP). This study highlights the use of WES in the molecular diagnostic approach of highly heterogeneous disorders, such as IPNs, places it in context of other published neuropathy cohorts, while further highlighting associated benefits for discovery., (© 2017 John Wiley & Sons A/S. Published by John Wiley & Sons Ltd.)

Published
2018
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50. SHORT syndrome due to a novel de novo mutation in PRKCE (Protein Kinase Cɛ) impairing TORC2-dependent AKT activation.

Author

Alcantara D, Elmslie F, Tetreault M, Bareke E, Hartley T, Majewski J, Boycott K, Innes AM, Dyment DA, and O'Driscoll M

Subjects
Adaptor Proteins, Signal Transducing genetics, Adolescent, Dwarfism genetics, Female, Growth Disorders metabolism, HEK293 Cells, Humans, Hypercalcemia metabolism, Metabolic Diseases metabolism, Mutation, Nephrocalcinosis metabolism, Phosphatidylinositol 3-Kinases genetics, Phosphorylation, Protein Kinase C-epsilon metabolism, Proto-Oncogene Proteins c-akt genetics, Signal Transduction, Sirolimus pharmacology, TOR Serine-Threonine Kinases genetics, TOR Serine-Threonine Kinases metabolism, Growth Disorders genetics, Hypercalcemia genetics, Mechanistic Target of Rapamycin Complex 2 metabolism, Metabolic Diseases genetics, Nephrocalcinosis genetics, Protein Kinase C-epsilon genetics, Proto-Oncogene Proteins c-akt metabolism
Abstract

SHORT syndrome is a rare, recognizable syndrome resulting from heterozygous mutations in PIK3R1 encoding a regulatory subunit of phosphoinositide-3-kinase (PI3K). The condition is characterized by short stature, intrauterine growth restriction, lipoatrophy and a facial gestalt involving a triangular face, deep set eyes, low hanging columella and small chin. PIK3R1 mutations in SHORT syndrome result in reduced signaling through the PI3K-AKT-mTOR pathway. We performed whole exome sequencing for an individual with clinical features of SHORT syndrome but negative for PIK3R1 mutation and her parents. A rare de novo variant in PRKCE was identified. The gene encodes PKCε and, as such, the AKT-mTOR pathway function was assessed using phospho-specific antibodies with patient lymphoblasts and following ectopic expression of the mutant in HEK293 cells. Kinase analysis showed that the variant resulted in a partial loss-of-function. Whilst interaction with PDK1 and the mTORC2 complex component SIN1 was preserved in the mutant PKCε, it bound to SIN1 with a higher affinity than wild-type PKCε and the dynamics of mTORC2-dependent priming of mutant PKCε was altered. Further, mutant PKCε caused impaired mTORC2-dependent pAKT-S473 following rapamycin treatment. Reduced pFOXO1-S256 and pS6-S240/244 levels were also observed in the patient LCLs. To date, mutations in PIK3R1 causing impaired PI3K-dependent AKT activation are the only known cause of SHORT syndrome. We identify a SHORT syndrome child with a novel partial loss-of-function defect in PKCε. This variant causes impaired AKT activation via compromised mTORC2 complex function., (© The Author 2017. Published by Oxford University Press. All rights reserved. For Permissions, please email: journals.permissions@oup.com.)

Published
2017
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