Your search keyword '"Palus, Brooke"' showing total 10 results

1. Enteropathy-associated T cell lymphoma subtypes are characterized by loss of function of SETD2

Author

Moffitt, Andrea B, Ondrejka, Sarah L, McKinney, Matthew, Rempel, Rachel E, Goodlad, John R, Teh, Chun Huat, Leppa, Sirpa, Mannisto, Susanna, Kovanen, Panu E, Tse, Eric, Au-Yeung, Rex KH, Kwong, Yok-Lam, Srivastava, Gopesh, Iqbal, Javeed, Yu, Jiayu, Naresh, Kikkeri, Villa, Diego, Gascoyne, Randy D, Said, Jonathan, Czader, Magdalena B, Chadburn, Amy, Richards, Kristy L, Rajagopalan, Deepthi, Davis, Nicholas S, Smith, Eileen C, Palus, Brooke C, Tzeng, Tiffany J, Healy, Jane A, Lugar, Patricia L, Datta, Jyotishka, Love, Cassandra, Levy, Shawn, Dunson, David B, Zhuang, Yuan, Hsi, Eric D, and Dave, Sandeep S

Subjects

Genetics, Cancer, Hematology, Lymphoma, Rare Diseases, Clinical Research, Biotechnology, Digestive Diseases, 2.1 Biological and endogenous factors, Aetiology, Animals, DNA Copy Number Variations, Enteropathy-Associated T-Cell Lymphoma, Female, Gene Expression Profiling, Gene Silencing, Histone-Lysine N-Methyltransferase, Humans, Male, Mice, Knockout, Middle Aged, Mutation, Sequence Analysis, DNA, T-Lymphocytes, Medical and Health Sciences, Immunology

Abstract

Enteropathy-associated T cell lymphoma (EATL) is a lethal, and the most common, neoplastic complication of celiac disease. Here, we defined the genetic landscape of EATL through whole-exome sequencing of 69 EATL tumors. SETD2 was the most frequently silenced gene in EATL (32% of cases). The JAK-STAT pathway was the most frequently mutated pathway, with frequent mutations in STAT5B as well as JAK1, JAK3, STAT3, and SOCS1 We also identified mutations in KRAS, TP53, and TERT Type I EATL and type II EATL (monomorphic epitheliotropic intestinal T cell lymphoma) had highly overlapping genetic alterations indicating shared mechanisms underlying their pathogenesis. We modeled the effects of SETD2 loss in vivo by developing a T cell-specific knockout mouse. These mice manifested an expansion of γδ T cells, indicating novel roles for SETD2 in T cell development and lymphomagenesis. Our data render the most comprehensive genetic portrait yet of this uncommon but lethal disease and may inform future classification schemes.

Published

2017

2. The whole-genome landscape of Burkitt lymphoma subtypes

Author

Panea, Razvan I., Love, Cassandra L., Shingleton, Jennifer R., Reddy, Anupama, Bailey, Jeffrey A., Moormann, Ann M., Otieno, Juliana A., Ong'echa, John Michael, Oduor, Cliff I., Schroeder, Kristin M.S., Masalu, Nestory, Chao, Nelson J., Agajanian, Megan, Major, Michael B., Fedoriw, Yuri, Richards, Kristy L., Rymkiewicz, Grzegorz, Miles, Rodney R., Alobeid, Bachir, Bhagat, Govind, Flowers, Christopher R., Ondrejka, Sarah L., Hsi, Eric D., Choi, William W.L., Au-Yeung, Rex K.H., Hartmann, Wolfgang, Lenz, Georg, Meyerson, Howard, Lin, Yen-Yu, Zhuang, Yuan, Luftig, Micah A., Waldrop, Alexander, Dave, Tushar, Thakkar, Devang, Sahay, Harshit, Li, Guojie, Palus, Brooke C., Seshadri, Vidya, Kim, So Young, Gascoyne, Randy D., Levy, Shawn, Mukhopadyay, Minerva, Dunson, David B., and Dave, Sandeep S.

Published

2019

3. Clinical testing panels for ALS : global distribution, consistency, and challenges

Author

Dilliott, Allison A., Al Nasser, Ahmad, Elnagheeb, Marwa, Fifita, Jennifer, Henden, Lyndal, Keseler, Ingrid M., Lenz, Steven, Marriott, Heather, Mccann, Emily, Mesaros, Maysen, Opie-Martin, Sarah, Owens, Emma, Palus, Brooke, Ross, Justyne, Wang, Zhanjun, White, Hannah, Al-Chalabi, Ammar, Andersen, Peter M., Benatar, Michael, Blair, Ian, Cooper-Knock, Johnathan, Harrington, Elizabeth A., Heckmann, Jeannine, Landers, John, Moreno, Cristiane, Nel, Melissa, Rampersaud, Evadnie, Roggenbuck, Jennifer, Rouleau, Guy, Traynor, Bryan, Van Blitterswijk, Marka, Van Rheenen, Wouter, Veldink, Jan, Weishaupt, Jochen, Drury, Luke, Harms, Matthew B., Farhan, Sali M. K., Dilliott, Allison A., Al Nasser, Ahmad, Elnagheeb, Marwa, Fifita, Jennifer, Henden, Lyndal, Keseler, Ingrid M., Lenz, Steven, Marriott, Heather, Mccann, Emily, Mesaros, Maysen, Opie-Martin, Sarah, Owens, Emma, Palus, Brooke, Ross, Justyne, Wang, Zhanjun, White, Hannah, Al-Chalabi, Ammar, Andersen, Peter M., Benatar, Michael, Blair, Ian, Cooper-Knock, Johnathan, Harrington, Elizabeth A., Heckmann, Jeannine, Landers, John, Moreno, Cristiane, Nel, Melissa, Rampersaud, Evadnie, Roggenbuck, Jennifer, Rouleau, Guy, Traynor, Bryan, Van Blitterswijk, Marka, Van Rheenen, Wouter, Veldink, Jan, Weishaupt, Jochen, Drury, Luke, Harms, Matthew B., and Farhan, Sali M. K.

Abstract

Objective: In 2021, the Clinical Genome Resource (ClinGen) amyotrophic lateral sclerosis (ALS) spectrum disorders Gene Curation Expert Panel (GCEP) was established to evaluate the strength of evidence for genes previously reported to be associated with ALS. Through this endeavor, we will provide standardized guidance to laboratories on which genes should be included in clinical genetic testing panels for ALS. In this manuscript, we aimed to assess the heterogeneity in the current global landscape of clinical genetic testing for ALS. Methods: We reviewed the National Institutes of Health (NIH) Genetic Testing Registry (GTR) and members of the ALS GCEP to source frequently used testing panels and compare the genes included on the tests. Results: 14 clinical panels specific to ALS from 14 laboratories covered 4 to 54 genes. All panels report on ANG, SOD1, TARDBP, and VAPB; 50% included or offered the option of including C9orf72 hexanucleotide repeat expansion (HRE) analysis. Of the 91 genes included in at least one of the panels, 40 (44.0%) were included on only a single panel. We could not find a direct link to ALS in the literature for 14 (15.4%) included genes. Conclusions: The variability across the surveyed clinical genetic panels is concerning due to the possibility of reduced diagnostic yields in clinical practice and risk of a missed diagnoses for patients. Our results highlight the necessity for consensus regarding the appropriateness of gene inclusions in clinical genetic ALS tests to improve its application for patients living with ALS and their families.

Published

2023

4. Clinical testing panels for ALS: global distribution, consistency, and challenges

Author

Dilliott, Allison A., primary, Al Nasser, Ahmad, additional, Elnageeb, Marwa, additional, Fifita, Jennifer, additional, Henden, Lyndal, additional, Keseler, Ingrid M., additional, Lenz, Steven, additional, Marriott, Heather, additional, McCann, Emily, additional, Mesaros, Maysen, additional, Opie-Martin, Sarah, additional, Owens, Emma, additional, Palus, Brooke, additional, Ross, Justyne, additional, Wang, Zhanjun, additional, White, Hannah, additional, Al-Chalabi, Ammar, additional, Andersen, Peter M., additional, Benatar, Michael, additional, Blair, Ian, additional, Cooper-Knock, Johnathan, additional, Drury, Luke, additional, Harrington, Elizabeth, additional, Heckmann, Jeannine, additional, Landers, John, additional, Moreno, Cristiane, additional, Nel, Melissa, additional, Rampersaud, Evadnie, additional, Roggenbuck, Jennifer, additional, Rouleau, Guy, additional, Traynor, Bryan, additional, van Blitterswijk, Marka, additional, van Rheenen, Wouter, additional, Veldink, Jan, additional, Weishaupt, Jochen, additional, Harms, Matthew B., additional, and Farhan, Sali M.K., additional

Published

2022

5. Examining O‐xylosyltransferase in Drosophila

Author

Palus, Brooke, primary and Selva, Erica, additional

Published

2015

6. Examining O‐xylosyltransferase shedding in Drosophila (539.1)

Author

Palus, Brooke, primary

Published

2014

7. Expert panel curation of 31 genes in relation to limb girdle muscular dystrophy.

Author

Mohan, Shruthi, McNulty, Shannon, Thaxton, Courtney, Elnagheeb, Marwa, Owens, Emma, Flowers, May, Nunnery, Teagan, Self, Autumn, Palus, Brooke, Gorokhova, Svetlana, Kennedy, April, Niu, Zhiyv, Johari, Mridul, Maiga, Alassane Baneye, Macalalad, Kelly, Clause, Amanda R., Beckmann, Jacques S., Bronicki, Lucas, Cooper, Sandra T., and Ganesh, Vijay S.

Subjects

*MUSCULAR dystrophy, *CREATINE kinase, *PHENOTYPES, *LEGAL evidence, *AGE of onset, *NEMALINE myopathy

Abstract

Objective Methods Results Interpretation Limb girdle muscular dystrophies (LGMDs) are a group of genetically heterogeneous autosomal conditions with some degree of phenotypic homogeneity. LGMD is defined as having onset >2 years of age with progressive proximal weakness, elevated serum creatine kinase levels and dystrophic features on muscle biopsy. Advances in massively parallel sequencing have led to a surge in genes linked to LGMD.The ClinGen Muscular Dystrophies and Myopathies gene curation expert panel (MDM GCEP, formerly Limb Girdle Muscular Dystrophy GCEP) convened to evaluate the strength of evidence supporting gene–disease relationships (GDR) using the ClinGen gene–disease clinical validity framework to evaluate 31 genes implicated in LGMD.The GDR was exclusively LGMD for 17 genes, whereas an additional 14 genes were related to a broader phenotype encompassing congenital weakness. Four genes (CAPN3, COL6A1, COL6A2, and COL6A3) were split into two separate disease entities, based on each displaying both dominant and recessive inheritance patterns, resulting in curation of 35 GDRs. Of these, 30 (86%) were classified as definitive, 4 (11%) as moderate, and 1 (3%) as limited. Two genes, POMGNT1 and DAG1, though definitively related to myopathy, currently have insufficient evidence to support a relationship specifically with LGMD.The expert‐reviewed assertions on the clinical validity of genes implicated in LGMDs form an invaluable resource for clinicians and molecular geneticists. We encourage the global neuromuscular community to publish case‐level data that help clarify disputed or novel LGMD associations. [ABSTRACT FROM AUTHOR]

Published

2024

8. Enteropathy-associated T cell lymphoma subtypes are characterized by loss of function of SETD2

Author

Zhuang, Yuan, Gascoyne, Randy D., Palus, Brooke C., Dave, Sandeep S., Tzeng, Tiffany J., Yu, Jiayu, Datta, Jyotishka, McKinney, Matthew, Rajagopalan, Deepthi, Smith, Eileen C., Tse, Eric, Iqbal, Javeed, Naresh, Kikkeri, Davis, Nicholas S., Ondrejka, Sarah L., Goodlad, John R., Mannisto, Susanna, Rempel, Rachel E., Kovanen, Panu E., Said, Jonathan, Richards, Kristy L., Chadburn, Amy, Leppa, Sirpa, Srivastava, Gopesh, Villa, Diego, Hsi, Eric D., Teh, Chun Huat, Love, Cassandra, Au-Yeung, Rex K.H., Kwong, Yok-Lam, Moffitt, Andrea B., Healy, Jane A., Levy, Shawn, Dunson, David B., Lugar, Patricia L., and Czader, Magdalena B.

Subjects

3. Good health

Abstract

Enteropathy-associated T cell lymphoma (EATL) is a lethal, and the most common, neoplastic complication of celiac disease. Here, we defined the genetic landscape of EATL through whole-exome sequencing of 69 EATL tumors. SETD2 was the most frequently silenced gene in EATL (32% of cases). The JAK-STAT pathway was the most frequently mutated pathway, with frequent mutations in STAT5B as well as JAK1 , JAK3 , STAT3 , and SOCS1 . We also identified mutations in KRAS , TP53 , and TERT . Type I EATL and type II EATL (monomorphic epitheliotropic intestinal T cell lymphoma) had highly overlapping genetic alterations indicating shared mechanisms underlying their pathogenesis. We modeled the effects of SETD2 loss in vivo by developing a T cell–specific knockout mouse. These mice manifested an expansion of γδ T cells, indicating novel roles for SETD2 in T cell development and lymphomagenesis. Our data render the most comprehensive genetic portrait yet of this uncommon but lethal disease and may inform future classification schemes.

9. Expert Panel Curation of 31 Genes in Relation to Limb Girdle Muscular Dystrophy.

Author

Mohan S, McNulty S, Thaxton C, Elnagheeb M, Owens E, Flowers M, Nunnery T, Self A, Palus B, Gorokhova S, Kennedy A, Niu Z, Johari M, Maiga AB, Macalalad K, Clause AR, Beckmann JS, Bronicki L, Cooper ST, Ganesh VS, Kang PB, Kesari A, Lek M, Levy J, Rufibach L, Savarese M, Spencer MJ, Straub V, Tasca G, and Weihl CC

Abstract

Introduction: Limb girdle muscular dystrophies (LGMDs) are a group of genetically heterogeneous autosomal conditions with some degree of phenotypic homogeneity. LGMD is defined as having onset >2 years of age with progressive proximal weakness, elevated serum creatine kinase levels and dystrophic features on muscle biopsy. Advances in massively parallel sequencing have led to a surge in genes linked to LGMD., Methods: The ClinGen Muscular Dystrophies and Myopathies gene curation expert panel (MDM GCEP, formerly Limb Girdle Muscular Dystrophy GCEP) convened to evaluate the strength of evidence supporting gene-disease relationships (GDR) using the ClinGen gene-disease clinical validity framework to evaluate 31 genes implicated in LGMD., Results: The GDR was exclusively LGMD for 17 genes, whereas an additional 14 genes were related to a broader phenotype encompassing congenital weakness. Four genes ( CAPN3, COL6A1, COL6A2, COL6A3 ) were split into two separate disease entities, based on each displaying both dominant and recessive inheritance patterns, resulting in curation of 35 GDRs. Of these, 30 (86%) were classified as Definitive, 4 (11%) as Moderate and 1 (3%) as Limited. Two genes, POMGNT1 and DAG1 , though definitively related to myopathy, currently have insufficient evidence to support a relationship specifically with LGMD., Conclusions: The expert-reviewed assertions on the clinical validity of genes implicated in LGMDs form an invaluable resource for clinicians and molecular geneticists. We encourage the global neuromuscular community to publish case-level data that help clarify disputed or novel LGMD associations.

Published

2024

10. Clinical testing panels for ALS: global distribution, consistency, and challenges.

Author

Dilliott AA, Al Nasser A, Elnagheeb M, Fifita J, Henden L, Keseler IM, Lenz S, Marriott H, Mccann E, Mesaros M, Opie-Martin S, Owens E, Palus B, Ross J, Wang Z, White H, Al-Chalabi A, Andersen PM, Benatar M, Blair I, Cooper-Knock J, Harrington EA, Heckmann J, Landers J, Moreno C, Nel M, Rampersaud E, Roggenbuck J, Rouleau G, Traynor B, Van Blitterswijk M, Van Rheenen W, Veldink J, Weishaupt J, Drury L, Harms MB, and Farhan SMK

Subjects

Humans, Mutation, Genetic Testing methods, C9orf72 Protein genetics, Amyotrophic Lateral Sclerosis diagnosis, Amyotrophic Lateral Sclerosis genetics

Abstract

Objective : In 2021, the Clinical Genome Resource (ClinGen) amyotrophic lateral sclerosis (ALS) spectrum disorders Gene Curation Expert Panel (GCEP) was established to evaluate the strength of evidence for genes previously reported to be associated with ALS. Through this endeavor, we will provide standardized guidance to laboratories on which genes should be included in clinical genetic testing panels for ALS. In this manuscript, we aimed to assess the heterogeneity in the current global landscape of clinical genetic testing for ALS. Methods : We reviewed the National Institutes of Health (NIH) Genetic Testing Registry (GTR) and members of the ALS GCEP to source frequently used testing panels and compare the genes included on the tests. Results : 14 clinical panels specific to ALS from 14 laboratories covered 4 to 54 genes. All panels report on ANG , SOD1 , TARDBP , and VAPB ; 50% included or offered the option of including C9orf72 hexanucleotide repeat expansion (HRE) analysis. Of the 91 genes included in at least one of the panels, 40 (44.0%) were included on only a single panel. We could not find a direct link to ALS in the literature for 14 (15.4%) included genes. Conclusions : The variability across the surveyed clinical genetic panels is concerning due to the possibility of reduced diagnostic yields in clinical practice and risk of a missed diagnoses for patients. Our results highlight the necessity for consensus regarding the appropriateness of gene inclusions in clinical genetic ALS tests to improve its application for patients living with ALS and their families.

Published

2023