Your search keyword '"Fisk, Katrina"' showing total 11 results

1. GABRA1-related disorders:from genetic to functional pathways

Author

Musto, Elisa, Liao, Vivian W Y, Johannesen, Katrine M, Fenger, Christina D, Lederer, Damien, Kothur, Kavitha, Fisk, Katrina, Bennetts, Bruce, Vrielynck, Pascal, Delaby, Delphine, Ceulemans, Berten, Weckhuysen, Sarah, Sparber, Peter, Bouman, Arjan, Ardern-Holmes, Simone, Troedson, Christopher, Battaglia, Domenica I, Goel, Himanshu, Feyma, Timothy, Bakhtiari, Somayeh, Tjoa, Linda, Boxill, Martin, Demina, Nina, Shchagina, Olga, Dadali, Elena, Kruer, Michael, Cantalupo, Gaetano, Contaldo, Ilaria, Polster, Tilman, Isidor, Bertrand, Bova, Stefania M, Fazeli, Walid, Wouters, Leen, Miranda, Maria J, Darra, Francesca, Pede, Elisa, Le Duc, Diana, Jamra, Rami Abou, Küry, Sébastien, Proietti, Jacopo, McSweeney, Niamh, Brokamp, Elly, Andrews, Peter Ian, Gouray Garcia, Marie, Chebib, Mary, Møller, Rikke S, Ahring, Philip K, Gardella, Elena, Musto, Elisa, Liao, Vivian W Y, Johannesen, Katrine M, Fenger, Christina D, Lederer, Damien, Kothur, Kavitha, Fisk, Katrina, Bennetts, Bruce, Vrielynck, Pascal, Delaby, Delphine, Ceulemans, Berten, Weckhuysen, Sarah, Sparber, Peter, Bouman, Arjan, Ardern-Holmes, Simone, Troedson, Christopher, Battaglia, Domenica I, Goel, Himanshu, Feyma, Timothy, Bakhtiari, Somayeh, Tjoa, Linda, Boxill, Martin, Demina, Nina, Shchagina, Olga, Dadali, Elena, Kruer, Michael, Cantalupo, Gaetano, Contaldo, Ilaria, Polster, Tilman, Isidor, Bertrand, Bova, Stefania M, Fazeli, Walid, Wouters, Leen, Miranda, Maria J, Darra, Francesca, Pede, Elisa, Le Duc, Diana, Jamra, Rami Abou, Küry, Sébastien, Proietti, Jacopo, McSweeney, Niamh, Brokamp, Elly, Andrews, Peter Ian, Gouray Garcia, Marie, Chebib, Mary, Møller, Rikke S, Ahring, Philip K, and Gardella, Elena

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 analyse the electro-clinical features and the functional effects of GABRA1-variants to establish genotype–phenotype correlations. Methods Genetic and electro-clinical data of 27 individuals (22 unrelated and 2 families) harbouring 20 different GABRA1 variants were collected and accompanied with 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 EEG posterior epileptiform discharges) was described for variants in the extra-cellular domain and the small transmembrane loops. These variants displayed loss-of-function (LoF) effects and the patients generally had a favourable 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 to delineate specific sub-phenotypes for LoF and GoF variants, though 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 patho-mechanism and precision medicine approach in, 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 analyse the electro-clinical features and the functional effects of GABRA1-variants to establish genotype-phenotype correlations.METHODS: Genetic and electro-clinical data of 27 individuals (22 unrelated and 2 families) harbouring 20 different GABRA1 variants were collected and accompanied with 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 EEG posterior epileptiform discharges) was described for variants in the extra-cellular domain and the small transmembrane loops. These variants displayed loss-of-function (LoF) effects and the patients generally had a favourable 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 to delineate specific sub-phenotypes for LoF and GoF variants, though 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 patho-mechanism and precision medicine approach in GABRA1-related di

Published

2024

2. Revealing hidden genetic diagnoses in the ocular anterior segment disorders

Author

Ma, Alan, Yousoof, Saira, Grigg, John R., Flaherty, Maree, Minoche, Andre E., Cowley, Mark J., Nash, Benjamin M., Ho, Gladys, Gayagay, Thet, Lai, Tiffany, Farnsworth, Elizabeth, Hackett, Emma L., Fisk, Katrina, Wong, Karen, Holman, Katherine J., Jenkins, Gemma, Cheng, Anson, Martin, Frank, Karaconji, Tanya, Elder, James E., Enriquez, Annabelle, Wilson, Meredith, Amor, David J., Stutterd, Chloe A., Kamien, Benjamin, Nelson, John, Dinger, Marcel E., Bennetts, Bruce, and Jamieson, Robyn V.

Published

2020

3. Australia and New Zealand renal gene panel testing in routine clinical practice of 542 families

Author

Tanudisastro, Hope A., Holman, Katherine, Ho, Gladys, Farnsworth, Elizabeth, Fisk, Katrina, Gayagay, Thet, Hackett, Emma, Jenkins, Gemma, Krishnaraj, Rahul, Lai, Tiffany, Wong, Karen, Patel, Chirag, Mallawaarachchi, Amali, Mallett, Andrew J., Bennetts, Bruce, Alexander, Stephen I., and McCarthy, Hugh J.

Published

2021

4. GABRA1‐Related Disorders: From Genetic to Functional Pathways

Author

Musto, Elisa, primary, Liao, Vivian W. Y., additional, Johannesen, Katrine M., additional, Fenger, Christina D., additional, Lederer, Damien, additional, Kothur, Kavitha, additional, Fisk, Katrina, additional, Bennetts, Bruce, additional, Vrielynck, Pascal, additional, Delaby, Delphine, additional, Ceulemans, Berten, additional, Weckhuysen, Sarah, additional, Sparber, Peter, additional, Bouman, Arjan, additional, Ardern‐Holmes, Simone, additional, Troedson, Christopher, additional, Battaglia, Domenica I., additional, Goel, Himanshu, additional, Feyma, Timothy, additional, Bakhtiari, Somayeh, additional, Tjoa, Linda, additional, Boxill, Martin, additional, Demina, Nina, additional, Shchagina, Olga, additional, Dadali, Elena, additional, Kruer, Michael, additional, Cantalupo, Gaetano, additional, Contaldo, Ilaria, additional, Polster, Tilman, additional, Isidor, Bertrand, additional, Bova, Stefania M., additional, Fazeli, Walid, additional, Wouters, Leen, additional, Miranda, Maria J., additional, Darra, Francesca, additional, Pede, Elisa, additional, Le Duc, Diana, additional, Jamra, Rami Abou, additional, Küry, Sébastien, additional, Proietti, Jacopo, additional, McSweeney, Niamh, additional, Brokamp, Elly, additional, Andrews, Peter Ian, additional, Gouray Garcia, Marie, additional, Chebib, Mary, additional, Møller, Rikke S., additional, Ahring, Philip K., additional, and Gardella, Elena, additional

Published

2023

5. GABRA1‐Related Disorders: From Genetic to Functional Pathways.

Author

Musto, Elisa, Liao, Vivian W. Y., Johannesen, Katrine M., Fenger, Christina D., Lederer, Damien, Kothur, Kavitha, Fisk, Katrina, Bennetts, Bruce, Vrielynck, Pascal, Delaby, Delphine, Ceulemans, Berten, Weckhuysen, Sarah, Sparber, Peter, Bouman, Arjan, Ardern‐Holmes, Simone, Troedson, Christopher, Battaglia, Domenica I., Goel, Himanshu, Feyma, Timothy, and Bakhtiari, Somayeh

Subjects

EPILEPSY, GENETIC disorders, SEIZURES (Medicine), EPILEPTIFORM discharges, MILD cognitive impairment, GAIN-of-function mutations, TRANSMEMBRANE domains

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 2024;95:27–41 [ABSTRACT FROM AUTHOR]

Published

2024

6. Shariant platform: Enabling evidence sharing across Australian clinical genetic-testing laboratories to support variant interpretation

Author

Tudini, Emma, primary, Andrews, James, additional, Lawrence, David M., additional, King-Smith, Sarah L., additional, Baker, Naomi, additional, Baxter, Leanne, additional, Beilby, John, additional, Bennetts, Bruce, additional, Beshay, Victoria, additional, Black, Michael, additional, Boughtwood, Tiffany F., additional, Brion, Kristian, additional, Cheong, Pak Leng, additional, Christie, Michael, additional, Christodoulou, John, additional, Chong, Belinda, additional, Cox, Kathy, additional, Davis, Mark R., additional, Dejong, Lucas, additional, Dinger, Marcel E., additional, Doig, Kenneth D., additional, Douglas, Evelyn, additional, Dubowsky, Andrew, additional, Ellul, Melissa, additional, Fellowes, Andrew, additional, Fisk, Katrina, additional, Fortuno, Cristina, additional, Friend, Kathryn, additional, Gallagher, Renee L., additional, Gao, Song, additional, Hackett, Emma, additional, Hadler, Johanna, additional, Hipwell, Michael, additional, Ho, Gladys, additional, Hollway, Georgina, additional, Hooper, Amanda J., additional, Kassahn, Karin S., additional, Krishnaraj, Rahul, additional, Lau, Chiyan, additional, Le, Huong, additional, San Leong, Huei, additional, Lundie, Ben, additional, Lunke, Sebastian, additional, Marty, Anthony, additional, McPhillips, Mary, additional, Nguyen, Lan T., additional, Nones, Katia, additional, Palmer, Kristen, additional, Pearson, John V., additional, Quinn, Michael C.J., additional, Rawlings, Lesley H., additional, Sadedin, Simon, additional, Sanchez, Louisa, additional, Schreiber, Andreas W., additional, Sigalas, Emanouil, additional, Simsek, Aygul, additional, Soubrier, Julien, additional, Stark, Zornitza, additional, Thompson, Bryony A., additional, U, James, additional, Vakulin, Cassandra G., additional, Wells, Amanda V., additional, Wise, Cheryl A., additional, Woods, Rick, additional, Ziolkowski, Andrew, additional, Brion, Marie-Jo, additional, Scott, Hamish S., additional, Thorne, Natalie P., additional, Spurdle, Amanda B., additional, Akesson, Lauren, additional, Allcock, Richard, additional, Ashton, Katie, additional, Bell, Damon A., additional, Brown, Anna, additional, Buckley, Michael, additional, Burnett, John R., additional, Burrows, Linda, additional, Byrne, Alicia, additional, Chan, Eva, additional, Cliffe, Corrina, additional, Clifton-Bligh, Roderick, additional, Dooley, Susan, additional, Fernandez, Miriam Fanjul, additional, Farnsworth, Elizabeth, additional, Ha, Thuong, additional, Henry, Denae, additional, Holds, Duncan, additional, Holman, Katherine, additional, Jackson, Matilda, additional, Kang, Sinlay, additional, Luxford, Catherine, additional, McManus, Sam, additional, Mehrtens, Rachael, additional, Meldrum, Cliff, additional, Mossman, David, additional, Pantaleo, Sarah-Jane, additional, Phelan, Dean, additional, Pontikinas, Electra, additional, Ravine, Anja, additional, Roscioli, Tony, additional, Scott, Rodney, additional, Simons, Keryn, additional, and Vanwageningen, Oliver, additional

Published

2022

7. A serendipitous journey to a promoter variant: The c.‐106C>A variant and its role in late‐onset ornithine transcarbamylase deficiency

Author

Hertzog, Ashley, primary, Selvanathan, Arthavan, additional, Halligan, Rebecca, additional, Fazio, Timothy, additional, de Jong, Gerard, additional, Bratkovic, Drago, additional, Bhattacharya, Kaustuv, additional, Tolun, Adviye Ayper, additional, Bennetts, Bruce, additional, and Fisk, Katrina, additional

Published

2022

8. Paternal retraction of a fragile X allele to normal size, showing normal function over two generations

Author

Bartlett, Essra, primary, Archibald, Alison D., additional, Francis, David, additional, Ling, Ling, additional, Thomas, Rob, additional, Chandler, Gabrielle, additional, Ward, Lisa, additional, O'Farrell, Gemma, additional, Pandelache, Alison, additional, Delatycki, Martin B., additional, Bennetts, Bruce H., additional, Ho, Gladys, additional, Fisk, Katrina, additional, Baker, Emma K., additional, Amor, David J., additional, and Godler, David E., additional

Published

2021

9. A serendipitous journey to a promoter variant: The c.‐106C>A variant and its role in late‐onset ornithine transcarbamylase deficiency.

Author

Hertzog, Ashley, Selvanathan, Arthavan, Halligan, Rebecca, Fazio, Timothy, de Jong, Gerard, Bratkovic, Drago, Bhattacharya, Kaustuv, Tolun, Adviye Ayper, Bennetts, Bruce, and Fisk, Katrina

Published

2022

10. Paternal retraction of a fragile X allele to normal size, showing normal function over two generations.

Author

Bartlett, Essra, Archibald, Alison D., Francis, David, Ling, Ling, Thomas, Rob, Chandler, Gabrielle, Ward, Lisa, O'Farrell, Gemma, Pandelache, Alison, Delatycki, Martin B., Bennetts, Bruce H., Ho, Gladys, Fisk, Katrina, Baker, Emma K., Amor, David J., and Godler, David E.

Abstract

The FMR1 premutation (PM:55‐199 CGG) is associated with fragile X‐associated tremor/ataxia syndrome (FXTAS) and when maternally transmitted is at risk of expansion to a hypermethylated full mutation (FM: ≥ 200 CGG) that causes fragile X syndrome (FXS). We describe a maternally transmitted PM (77 CGG) that was passed to a son (103 CGG), and to a daughter (220–1822 CGG), who were affected with FXTAS and FXS, respectively. The male with the PM showed low‐level mosaicism for normal size of 30 and 37 CGG. This male had two offspring: one female mosaic for PM and FM (56, 157, >200 CGG) and another with only a 37 CGG allele detected in multiple tissues, neither with a clinical phenotype. The female with the 37 CGG allele showed normal levels of FMR1 methylation and mRNA and passed this 37 CGG allele to one of her daughters, who was also unaffected. These findings show that post‐zygotic paternal retraction can lead to low‐level mosaicism for normal size alleles, with these normal alleles being functional when passed over two generations. [ABSTRACT FROM AUTHOR]

Published

2022

11. Nationwide, Couple-Based Genetic Carrier Screening.

Author

Kirk EP, Delatycki MB, Archibald AD, Tutty E, Caruana J, Halliday JL, Lewis S, McClaren BJ, Newson AJ, Dive L, Best S, Long JC, Braithwaite J, Downes MJ, Scuffham PA, Massie J, Barlow-Stewart K, Kulkarni A, Ruscigno A, Kanga-Parabia A, Rodrigues B, Bennetts BH, Ebzery C, Hunt C, Cliffe CC, Lee C, Azmanov D, King EA, Madelli EO, Zhang F, Ho G, Danos I, Liebelt J, Fletcher J, Kennedy J, Beilby J, Emery JD, McGaughran J, Marum JE, Scarff K, Fisk K, Harrison K, Boggs K, Giameos L, Fitzgerald L, Thomas L, Burnett L, Freeman L, Harris M, Berbic M, Davis MR, Cifuentes Ochoa M, Wallis M, Wall M, Chow MTM, Ferrie MM, Pachter N, Quayum N, Lang N, Kasi Pandy P, Casella R, Allcock RJN, Ong R, Edwards S, Sundercombe S, Jelenich S, Righetti S, Lunke S, Kaur S, Stock-Myer S, Eggers S, Walker SP, Theodorou T, Catchpool T, Clinch T, Roscioli T, Hardy T, Zhu Y, Fehlberg Z, Boughtwood TF, and Laing NG

Subjects

Adult, Female, Humans, Male, Pregnancy, Australia, Feasibility Studies, Patient Acceptance of Health Care statistics & numerical data, Decision Making, Heterozygote, Family Characteristics, Reproductive Behavior, Genetic Carrier Screening methods, Genetic Carrier Screening statistics & numerical data, Genetic Diseases, Inborn genetics, Genetic Diseases, Inborn prevention & control, Genetic Diseases, Inborn psychology

Abstract

Background: Genomic sequencing technology allows for identification of reproductive couples with an increased chance, as compared with that in the general population, of having a child with an autosomal recessive or X-linked genetic condition., Methods: We investigated the feasibility, acceptability, and outcomes of a nationwide, couple-based genetic carrier screening program in Australia as part of the Mackenzie's Mission project. Health care providers offered screening to persons before pregnancy or early in pregnancy. The results obtained from testing at least 1281 genes were provided to the reproductive couples. We aimed to ascertain the psychosocial effects on participants, the acceptability of screening to all participants, and the reproductive choices of persons identified as having an increased chance of having a child with a condition for which we screened., Results: Among 10,038 reproductive couples enrolled in the study, 9107 (90.7%) completed screening, and 175 (1.9%) were newly identified as having an increased chance of having a child with a genetic condition for which we screened. These conditions involved pathogenic variants in 90 different genes; 74.3% of the conditions were autosomal recessive. Three months after receiving the results, 76.6% of the couples with a newly identified increased chance had used or planned to use reproductive interventions to avoid having an affected child. Those newly identified as having an increased chance had greater anxiety than those with a low chance. The median level of decisional regret was low in all result groups, and 98.9% of participants perceived screening to be acceptable., Conclusions: Couple-based reproductive genetic carrier screening was largely acceptable to participants and was used to inform reproductive decision making. The delivery of screening to a diverse and geographically dispersed population was feasible. (Funded by the Medical Research Future Fund of the Australian government; ClinicalTrials.gov number, NCT04157595.)., (Copyright © 2024 Massachusetts Medical Society.)

Published

2024