Your search keyword '"Elizabeth A. Varga"' showing total 13 results

1. Defining the transcriptome of PIK3CA-altered cells in a human capillary malformation using single cell long-read sequencing

Author

Michelle A. Wedemeyer, Tianli Ding, Elizabeth A. R. Garfinkle, Jesse J. Westfall, Jaye B. Navarro, Maria Elena Hernandez Gonzalez, Elizabeth A. Varga, Patricia Witman, Elaine R. Mardis, Catherine E. Cottrell, Anthony R. Miller, and Katherine E. Miller

Subjects

Medicine, Science

Abstract

Abstract PIK3CA-related overgrowth spectrum (PROS) disorders are caused by somatic mosaic variants that result in constitutive activation of the phosphatidylinositol-3-kinase/AKT/mTOR pathway. Promising responses to molecularly targeted therapy have been reported, although identification of an appropriate agent can be hampered by the mosaic nature and corresponding low variant allele frequency of the causal variant. Moreover, our understanding of the molecular consequences of these variants—for example how they affect gene expression profiles—remains limited. Here we describe in vitro expansion of a human capillary malformation followed by molecular characterization using exome sequencing, single cell gene expression, and targeted long-read single cell RNA-sequencing in a patient with clinical features consistent with Megalencephaly-Capillary Malformation Syndrome (MCAP, a PROS condition). These approaches identified a targetable PIK3CA variant with expression restricted to PAX3+ fibroblast and undifferentiated keratinocyte populations. This study highlights the innovative combination of next-generation single cell sequencing methods to better understand unique transcriptomic profiles and cell types associated with MCAP, revealing molecular intricacies of this genetic syndrome.

Published

2024

2. Molecular characterization of gliomas and glioneuronal tumors amid Noonan syndrome: cancer predisposition examined

Author

Margaret Shatara, Kathleen M. Schieffer, Marilena Melas, Elizabeth A. Varga, Diana Thomas, Brianna A. Bucknor, Heather M. Costello, Gregory Wheeler, Benjamin J. Kelly, Katherine E. Miller, Diana P. Rodriguez, Mariam T. Mathew, Kristy Lee, Erin Crotty, Sarah Leary, Vera A. Paulson, Bonnie Cole, Mohamed S. Abdelbaki, Jonathan L. Finlay, Margot A. Lazow, Ralph Salloum, Maryam Fouladi, Daniel R. Boué, Elaine R. Mardis, and Catherine E. Cottrell

Subjects

glioma, glioneuronal tumor, Noonan syndrome, cancer predisposition, PTPN11, germline, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

IntroductionIn the setting of pediatric and adolescent young adult cancer, increased access to genomic profiling has enhanced the detection of genetic variation associated with cancer predisposition, including germline syndromic conditions. Noonan syndrome (NS) is associated with the germline RAS pathway activating alterations and increased risk of cancer. Herein, we describe our comprehensive molecular profiling approach, the association of NS with glioma and glioneuronal tumors, and the clinical and histopathologic characteristics associated with the disease.MethodsWithin an institutional pediatric cancer cohort (n = 314), molecular profiling comprised of paired somatic disease–germline comparator exome analysis, RNA sequencing, and tumor classification by DNA methylation analysis was performed.ResultsThrough the implementation of paired analysis, this study identified 4 of 314 (1.3%) individuals who harbored a germline PTPN11 variant associated with NS, of which 3 individuals were diagnosed with a glioma or glioneuronal tumor. Furthermore, we extend this study through collaboration with a peer institution to identify two additional individuals with NS and a glioma or glioneuronal tumor. Notably, in three of five (60%) individuals, paired genomic profiling led to a previously unrecognized diagnosis of Noonan syndrome despite an average age of cancer diagnosis of 16.8 years. The study of the disease-involved tissue identified signaling pathway dysregulation through somatic alteration of genes involved in cellular proliferation, survival, and differentiation.DiscussionComparative pathologic findings are presented to enable an in-depth examination of disease characteristics. This comprehensive analysis highlights the association of gliomas and glioneuronal tumors with RASopathies and the potential therapeutic challenges and importantly demonstrates the utility of genomic profiling for the identification of germline cancer predisposition.

Published

2024

3. Discovery of clinically relevant fusions in pediatric cancer

Author

Stephanie LaHaye, James R. Fitch, Kyle J. Voytovich, Adam C. Herman, Benjamin J. Kelly, Grant E. Lammi, Jeremy A. Arbesfeld, Saranga Wijeratne, Samuel J. Franklin, Kathleen M. Schieffer, Natalie Bir, Sean D. McGrath, Anthony R. Miller, Amy Wetzel, Katherine E. Miller, Tracy A. Bedrosian, Kristen Leraas, Elizabeth A. Varga, Kristy Lee, Ajay Gupta, Bhuvana Setty, Daniel R. Boué, Jeffrey R. Leonard, Jonathan L. Finlay, Mohamed S. Abdelbaki, Diana S. Osorio, Selene C. Koo, Daniel C. Koboldt, Alex H. Wagner, Ann-Kathrin Eisfeld, Krzysztof Mrózek, Vincent Magrini, Catherine E. Cottrell, Elaine R. Mardis, Richard K. Wilson, and Peter White

Subjects

Transcriptomics, Genomics, Pediatric neoplasms, Gene fusions, Cancer, RNA-Seq, Biotechnology, TP248.13-248.65, Genetics, QH426-470

Abstract

Abstract Background Pediatric cancers typically have a distinct genomic landscape when compared to adult cancers and frequently carry somatic gene fusion events that alter gene expression and drive tumorigenesis. Sensitive and specific detection of gene fusions through the analysis of next-generation-based RNA sequencing (RNA-Seq) data is computationally challenging and may be confounded by low tumor cellularity or underlying genomic complexity. Furthermore, numerous computational tools are available to identify fusions from supporting RNA-Seq reads, yet each algorithm demonstrates unique variability in sensitivity and precision, and no clearly superior approach currently exists. To overcome these challenges, we have developed an ensemble fusion calling approach to increase the accuracy of identifying fusions. Results Our Ensemble Fusion (EnFusion) approach utilizes seven fusion calling algorithms: Arriba, CICERO, FusionMap, FusionCatcher, JAFFA, MapSplice, and STAR-Fusion, which are packaged as a fully automated pipeline using Docker and Amazon Web Services (AWS) serverless technology. This method uses paired end RNA-Seq sequence reads as input, and the output from each algorithm is examined to identify fusions detected by a consensus of at least three algorithms. These consensus fusion results are filtered by comparison to an internal database to remove likely artifactual fusions occurring at high frequencies in our internal cohort, while a “known fusion list” prevents failure to report known pathogenic events. We have employed the EnFusion pipeline on RNA-Seq data from 229 patients with pediatric cancer or blood disorders studied under an IRB-approved protocol. The samples consist of 138 central nervous system tumors, 73 solid tumors, and 18 hematologic malignancies or disorders. The combination of an ensemble fusion-calling pipeline and a knowledge-based filtering strategy identified 67 clinically relevant fusions among our cohort (diagnostic yield of 29.3%), including RBPMS-MET, BCAN-NTRK1, and TRIM22-BRAF fusions. Following clinical confirmation and reporting in the patient’s medical record, both known and novel fusions provided medically meaningful information. Conclusions The EnFusion pipeline offers a streamlined approach to discover fusions in cancer, at higher levels of sensitivity and accuracy than single algorithm methods. Furthermore, this method accurately identifies driver fusions in pediatric cancer, providing clinical impact by contributing evidence to diagnosis and, when appropriate, indicating targeted therapies.

Published

2021

4. Direct‐to‐consumer genetic testing for factor V Leiden and prothrombin 20210G>A: the consumer experience

Author

Sarah L. Elson, Nicholas A. Furlotte, Bethann S. Hromatka, Catherine H. Wilson, Joanna L. Mountain, Helen M. Rowbotham, Elizabeth A. Varga, and Uta Francke

Subjects

Genetics, QH426-470

Abstract

Abstract Background Clinical genetic testing for inherited predisposition to venous thromboembolism (VTE) is common among patients and their families. However, there is incomplete consensus about which individuals should receive testing, and the relative risks and benefits. Methods We assessed outcomes of receiving direct‐to‐consumer (DTC) results for the two most common genetic risk factors for VTE, factor V Leiden in the F5 gene (FVL) and prothrombin 20210G>A in the F2 gene (PT). Two thousand three hundred fifty‐four customers (1244 variant‐positive and 1110 variant‐negative individuals) of the personal genetics company 23andMe, Inc., who had received results online for F5 and F2 variants, participated in an online survey‐based study. Participants responded to questions about perception of VTE risk, discussion of results with healthcare providers (HCPs) and recommendations received, actions taken to control risk, emotional responses to receiving risk results, and perceived value of the information. Results Most participants (90% of variant‐positive individuals, 99% of variant‐negative individuals) had not previously been tested for F5 and/or F2 variants. The majority of variant‐positive individuals correctly perceived that they were at higher than average risk for developing VTE. These individuals reported moderate rates of discussing results with HCPs (41%); receiving prevention advice from HCPs (31%), and making behavioral changes to control risk (e.g., exercising more, 30%). A minority (36%) of variant‐positive individuals worried more after receiving VTE results. Nevertheless, most participants reported that knowing their risk had been an advantage (78% variant‐positive and 58% variant‐negative) and were satisfied knowing their genetic probability for VTE (81% variant‐positive and 67% variant‐negative). Conclusion Consumers reported moderate rates of behavioral change and perceived personal benefit from receiving DTC genetic results for VTE risk.

Published

2020

5. Germline Variant Interpretation in Children with Severe Sepsis

Author

Benjamin T. Prince, Elizabeth A. Varga, and Kim L. McBride

Subjects

Immunology, Immunology and Allergy

Published

2022

6. 26. Co-occurrence of rosette-forming glioneuronal tumors with Noonan Syndrome

Author

Marilena Melas, Margaret Shatara, Kathleen M. Schieffer, Kristy Lee, Elizabeth A. Varga, Kristen M. Leraas, Diana P. Rodriguez, Mohamed S. Abdelbaki, Diana S. Osorio, Jonathan L. Finlay, Daniel R. Boué, Peter White, Vincent Magrini, Richard K. Wilson, Elaine R. Mardis, and Catherine E. Cottrell

Subjects

Cancer Research, Genetics, Molecular Biology

Published

2022

7. Homocysteine and MTHFR Mutations

Author

Elizabeth A. Varga and Stephan Moll

Subjects

Hyperhomocysteinemia, medicine.medical_specialty, Homocysteine, Homocystinuria, chemistry.chemical_compound, Physiology (medical), Internal medicine, medicine, Animals, Humans, Methylenetetrahydrofolate Reductase (NADPH2), Methionine, biology, business.industry, medicine.disease, Surgery, Venous thrombosis, B vitamins, Endocrinology, chemistry, Methylenetetrahydrofolate reductase, Mutation, biology.protein, Cardiology and Cardiovascular Medicine, business, Biomarkers, Kidney disease

Abstract

Homocysteine is a chemical in the blood that is produced when an amino acid (a building block of protein) called methionine is broken down in the body. We all have some homocysteine in our blood. Elevated homocysteine levels (also called hyperhomocysteinemia) may cause irritation of the blood vessels. Elevated levels of homocysteine show an increased risk for (1) hardening of the arteries (atherosclerosis), which could eventually result in a heart attack and/or stroke, and (2) blood clots in the veins, referred to as venous thrombosis. The purpose of this Cardiology Patient Page is to explain the relation between elevated homocysteine levels and blood clots in the arteries and veins; to discuss the causes of elevated homocysteine levels, including common genetic variants in the MTHFR gene (see the “What Do I Need to Know About a Hereditary Predisposition?” section); and to describe ways to monitor and lower homocysteine levels to possibly improve health. In 1962, it was reported that people with a rare genetic condition called homocystinuria were prone to develop severe cardiovascular disease in their teens and 20s. In this condition, a defective enzyme causes an accumulation of homocysteine in the blood, resulting in very high levels. Studies of children with homocystinuria led to the discovery that elevated homocysteine levels are a risk factor for developing atherosclerosis and blood clots in the arteries and veins. Although homocystinuria is a rare disease (affecting about 1 in 200 000 people), many more people have mildly or moderately elevated homocysteine levels. Some people have elevated homocysteine levels (Table 1) caused by a deficiency of B vitamins and folate in their diets. High homocysteine levels are also seen in people with kidney disease, low levels of thyroid hormones, psoriasis, and with certain medications (such as antiepileptic drugs and methotrexate).1 It has been recognized …

Published

2015

8. Deep Vein Thrombosis (DVT) and Pulmonary Embolism (PE): Awareness and Prophylaxis Practices Reported by Patients with Cancer

Author

Anita Aggarwal, Lisa Fullam, Alan P. Brownstein, Gregory A. Maynard, Jack Ansell, Elizabeth A. Varga, Richard. J. Friedman, Frederick. R. Rickles, Anita Aggarwal, Lisa Fullam, Alan P. Brownstein, Gregory A. Maynard, Jack Ansell, Elizabeth A. Varga, Richard. J. Friedman, and Frederick. R. Rickles

Published

2015

9. Cardiology patient pages. Homocysteine and MTHFR mutations: relation to thrombosis and coronary artery disease

Author

Elizabeth A, Varga, Amy C, Sturm, Caron P, Misita, and Stephan, Moll

Subjects

Male, Pregnancy, Mutation, Pregnancy Complications, Hematologic, Humans, Female, Homocystinuria, Thrombosis, Coronary Artery Disease, Genetic Testing, Homocysteine, Methylenetetrahydrofolate Reductase (NADPH2), Diet Therapy

Published

2005

10. Homocysteine and MTHFR Mutations

Author

Elizabeth A. Varga, Amy C. Sturm, Stephan Moll, and Caron P. Misita

Subjects

medicine.medical_specialty, Hyperhomocysteinemia, Homocysteine, biology, business.industry, Diet therapy, Homocystinuria, medicine.disease, Thrombosis, Surgery, chemistry.chemical_compound, Venous thrombosis, B vitamins, Endocrinology, chemistry, Physiology (medical), Internal medicine, Methylenetetrahydrofolate reductase, biology.protein, Medicine, Cardiology and Cardiovascular Medicine, business

Abstract

Homocysteine is a chemical in the blood that is produced when an amino acid (a building block of protein) called methionine is broken down in the body. We all have some homocysteine in our blood. Elevated homocysteine levels (also called hyperhomocysteinemia) may cause irritation of the blood vessels. Elevated levels of homocysteine show an increased risk for (1) hardening of the arteries (atherosclerosis), which could eventually result in a heart attack and/or stroke, and (2) blood clots in the veins, referred to as venous thrombosis. The purpose of this Cardiology Patient Page is to explain the relation between elevated homocysteine levels and blood clots in the arteries and veins; to discuss the causes of elevated homocysteine levels, including common genetic variants in the MTHFR gene (see the “What Do I Need to Know About a Hereditary Predisposition?” section); and to describe ways to monitor and lower homocysteine levels to possibly improve health. In 1962, it was reported that people with a rare genetic condition called homocystinuria were prone to develop severe cardiovascular disease in their teens and 20s. In this condition, a defective enzyme causes an accumulation of homocysteine in the blood, resulting in very high levels. Studies of children with homocystinuria led to the discovery that elevated homocysteine levels are a risk factor for developing atherosclerosis and blood clots in the arteries and veins. Although homocystinuria is a rare disease (affecting about 1 in 200 000 people), many more people have mildly or moderately elevated homocysteine levels. Some people have elevated homocysteine levels (Table 1) caused by a deficiency of B vitamins and folate in their diets. High homocysteine levels are also seen in people with kidney disease, low levels of thyroid hormones, psoriasis, and with certain medications (such as antiepileptic drugs and methotrexate).1 It has been recognized …

Published

2005

11. Cardiology patient pages. Prothrombin 20210 mutation (factor II mutation)

Author

Elizabeth A, Varga and Stephan, Moll

Subjects

Venous Thrombosis, Mutation, Humans, Thrombophilia, Female, Prothrombin, Pulmonary Embolism, Blood Coagulation

Published

2004

12. Prothrombin 20210 Mutation (Factor II Mutation)

Author

Stephan Moll and Elizabeth A. Varga

Subjects

medicine.medical_specialty, Pregnancy, business.industry, Deep vein, Thrombophilia, medicine.disease, Thrombosis, Pulmonary embolism, medicine.anatomical_structure, Physiology (medical), Internal medicine, Hormone replacement therapy (male-to-female), medicine, Cardiology, Cardiology and Cardiovascular Medicine, Vein, business, Stroke

Abstract

Testing for the prothrombin 20210 mutation, also called factor II mutation, may have been offered by your doctor because you or someone in your family, has had (1) a blood clot in one of the deep veins of the body (also called deep vein thrombosis or DVT); (2) a blood clot that has traveled to the lung (called a pulmonary embolism or PE); (3) a blood clot in an unusual site (such as the mesenteric or cerebral sinus vein); (4) a heart attack or stroke at a young age; or (5) a history of recurrent pregnancy loss or stillbirth. A history like this in yourself or a family member may be indicative of an underlying thrombophilia. Thrombophilia is a term that describes a state in which the blood has an increased tendency to clot. People can have this increased tendency because they (1) have one or more inherited (genetic) risk factors, (2) have developed a chronic condition that puts them at increased risk, such as obesity, cancer, inflammatory bowel disease, or the persistence of certain antibodies (antiphospholipid antibodies), or (3) have a temporary condition that leads to an increased clotting tendency, such as recent surgery, trauma, a cast, prolonged immobility, pregnancy, or the use of oral contraceptives or hormone replacement therapy. The purpose of this Cardiology Patient Page is to provide more information about the prothrombin mutation, which is the second most common cause of hereditary thrombophilia. Normally, there is a fine balance in the body which ensures that there is not too much bleeding or blood clotting. If this balance is disrupted, a blood clot may occur. Throughout the course of a normal day, the blood vessels sustain many minor injuries of which you are not aware. In response, the body naturally triggers the “clotting cascade”—a sequence of events …

Published

2004

13. Genetic Evaluation and Counseling of Couples with Recurrent Miscarriage: Recommendations of the National Society of Genetic Counselors.

Author

Mercy Y. Laurino, Robin L. Bennett, Devki S. Saraiya, Lisa Baumeister, Debra Lochner Doyle, Kathleen Leppig, Barbara Pettersen, Robert Resta, Larry Shields, Stefanie Uhrich, Elizabeth A. Varga, and Wendy H. Raskind

Abstract

Abstract The objective of this document is to provide recommendations for genetic evaluation and counseling of couples with recurrent miscarriage (RM). The recommendations are the opinions of the multidisciplinary Inherited Pregnancy Loss Working Group (IPLWG), with expertise in genetic counseling, medical genetics, maternal fetal medicine, internal medicine, infectious disease, cytogenetics, and coagulation disorders. The IPLWG defines RM as three or more clinically recognized consecutive or non-consecutive pregnancy losses occurring prior to fetal viability (<24 weeks gestation). These recommendations are provided to assist genetic counselors and other health care providers in clinical decision-making, as well as to promote consistency of patient care, guide the allocation of medical resources, and increase awareness of the psychosocial and cultural issues experienced by couples with RM. The IPLWG was convened with support from the March of Dimes Western Washington State Chapter and the University of Washington Division of Medical Genetics. The recommendations are U.S. Preventive Task Force Class III, and are based on clinical experiences, review of pertinent English-language published articles, and reports of expert committees. This document reviews the suspected causes of RM, provides indications for genetic evaluation and testing, addresses psychosocial and cultural considerations, and provides professional and patient resources. These recommendations should not be construed as dictating an exclusive course of medical management, nor does the use of such recommendations guarantee a particular outcome. The professional judgment of a health care provider, familiar with the circumstances of a specific case, should always supersede these recommendations. [ABSTRACT FROM AUTHOR]

Published

2005