Your search keyword '"Adam Rosenbaum"' showing total 7 results

1. Low-grade glioma risk SNP rs11706832 is associated with type I interferon response pathway genes in cell lines

Author

Adam Rosenbaum, Anna M. Dahlin, Ulrika Andersson, Benny Björkblom, Wendy Yi-Ying Wu, Håkan Hedman, Carl Wibom, and Beatrice Melin

Subjects

Medicine, Science

Abstract

Abstract Genome-wide association studies (GWAS) have contributed to our understanding of glioma susceptibility. To date, 25 risk loci for development of any of the glioma subtypes are known. However, GWAS studies reveal little about the molecular processes that lead to increased risk, especially for non-coding single nucleotide polymorphisms (SNP). A particular SNP in intron 2 of LRIG1, rs11706832, has been shown to increase the susceptibility for IDH1 mutated low-grade gliomas (LGG). Leucine-rich repeats and immunoglobulin-like domains protein 1 (LRIG1) is important in cancer development as it negatively regulates the epidermal growth factor receptor (EGFR); however, the mechanism responsible for this particular risk SNP and its potential effect on LRIG1 are not known. Using CRISPR-CAS9, we edited rs11706832 in HEK293T cells. Four HEK293T clones with the risk allele were compared to four clones with the non-risk allele for LRIG1 and SLC25A26 gene expression using RT-qPCR, for global gene expression using RNA-seq, and for metabolites using gas chromatography-mass spectrometry (GC–MS). The experiment did not reveal any significant effect of the SNP on the expression levels or splicing patterns of LRIG1 or SLC25A26. The global gene expression analysis revealed that the risk allele C was associated with upregulation of several mitochondrial genes. Gene enrichment analysis of 74 differentially expressed genes in the genome revealed a significant enrichment of type I interferon response genes, where many genes were downregulated for the risk allele C. Gene expression data of IDH1 mutated LGGs from the cancer genome atlas (TCGA) revealed a similar under expression of type I interferon genes associated with the risk allele. This study found the expression levels and splicing patterns of LRIG1 and SLC25A26 were not affected by the SNP in HEK293T cells. However, the risk allele was associated with a downregulation of genes involved in the innate immune response both in the HEK293T cells and in the LGG data from TCGA.

Published

2023

2. Integration of whole genome sequencing into a healthcare setting: high diagnostic rates across multiple clinical entities in 3219 rare disease patients

Author

Henrik Stranneheim, Kristina Lagerstedt-Robinson, Måns Magnusson, Malin Kvarnung, Daniel Nilsson, Nicole Lesko, Martin Engvall, Britt-Marie Anderlid, Henrik Arnell, Carolina Backman Johansson, Michela Barbaro, Erik Björck, Helene Bruhn, Jesper Eisfeldt, Christoph Freyer, Giedre Grigelioniene, Peter Gustavsson, Anna Hammarsjö, Maritta Hellström-Pigg, Erik Iwarsson, Anders Jemt, Mikael Laaksonen, Sara Lind Enoksson, Helena Malmgren, Karin Naess, Magnus Nordenskjöld, Mikael Oscarson, Maria Pettersson, Chiara Rasi, Adam Rosenbaum, Ellika Sahlin, Eliane Sardh, Tommy Stödberg, Bianca Tesi, Emma Tham, Håkan Thonberg, Virpi Töhönen, Ulrika von Döbeln, Daphne Vassiliou, Sofie Vonlanthen, Ann-Charlotte Wikström, Josephine Wincent, Ola Winqvist, Anna Wredenberg, Sofia Ygberg, Rolf H. Zetterström, Per Marits, Maria Johansson Soller, Ann Nordgren, Valtteri Wirta, Anna Lindstrand, and Anna Wedell

Subjects

Whole genome sequencing, Monogenic disease, Single nucleotide variant, Clinical diagnostics, Medicine, Genetics, QH426-470

Abstract

Abstract Background We report the findings from 4437 individuals (3219 patients and 1218 relatives) who have been analyzed by whole genome sequencing (WGS) at the Genomic Medicine Center Karolinska-Rare Diseases (GMCK-RD) since mid-2015. GMCK-RD represents a long-term collaborative initiative between Karolinska University Hospital and Science for Life Laboratory to establish advanced, genomics-based diagnostics in the Stockholm healthcare setting. Methods Our analysis covers detection and interpretation of SNVs, INDELs, uniparental disomy, CNVs, balanced structural variants, and short tandem repeat expansions. Visualization of results for clinical interpretation is carried out in Scout—a custom-developed decision support system. Results from both singleton (84%) and trio/family (16%) analyses are reported. Variant interpretation is done by 15 expert teams at the hospital involving staff from three clinics. For patients with complex phenotypes, data is shared between the teams. Results Overall, 40% of the patients received a molecular diagnosis ranging from 19 to 54% for specific disease groups. There was heterogeneity regarding causative genes (n = 754) with some of the most common ones being COL2A1 (n = 12; skeletal dysplasia), SCN1A (n = 8; epilepsy), and TNFRSF13B (n = 4; inborn errors of immunity). Some causative variants were recurrent, including previously known founder mutations, some novel mutations, and recurrent de novo mutations. Overall, GMCK-RD has resulted in a large number of patients receiving specific molecular diagnoses. Furthermore, negative cases have been included in research studies that have resulted in the discovery of 17 published, novel disease-causing genes. To facilitate the discovery of new disease genes, GMCK-RD has joined international data sharing initiatives, including ClinVar, UDNI, Beacon, and MatchMaker Exchange. Conclusions Clinical WGS at GMCK-RD has provided molecular diagnoses to over 1200 individuals with a broad range of rare diseases. Consolidation and spread of this clinical-academic partnership will enable large-scale national collaboration.

Published

2021

3. Loqusdb: added value of an observations database of local genomic variation

Author

Måns Magnusson, Jesper Eisfeldt, Daniel Nilsson, Adam Rosenbaum, Valtteri Wirta, Anna Lindstrand, Anna Wedell, and Henrik Stranneheim

Subjects

Genomics, Rare disease, Mendelian, Single nucleotide variant, Structural variant, Population frequency, Computer applications to medicine. Medical informatics, R858-859.7, Biology (General), QH301-705.5

Abstract

Abstract Background Exome and genome sequencing is becoming the method of choice for rare disease diagnostics. One of the key challenges remaining is distinguishing the disease causing variants from the benign background variation. After analysis and annotation of the sequencing data there are typically thousands of candidate variants requiring further investigation. One of the most effective and least biased ways to reduce this number is to assess the rarity of a variant in any population. Currently, there are a number of reliable sources of information for major population frequencies when considering single nucleotide variants (SNVs) and small insertion and deletions (INDELs), with gnomAD as the most prominent public resource available. However, local variation or frequencies in sub-populations may be underrepresented in these public resources. In contrast, for structural variation (SV), the background frequency in the general population is more or less unknown mostly due to challenges in calling SVs in a consistent way. Keeping track of local variation is one way to overcome these problems and significantly reduce the number of potential disease causing variants retained for manual inspection, both for SNVs and SVs. Results Here, we present loqusdb, a tool to solve the challenge of keeping track of any type of variant observations from genome sequencing data. Loqusdb was designed to handle a large flow of samples and unlike other solutions, samples can be added continuously to the database without rebuilding it, facilitating improvements and additions. We assessed the added value of a local observations database using 98 samples annotated with information from a background of 888 unrelated individuals. Conclusions We show both how powerful SV analysis can be when filtering for population frequencies and how the number of apparently rare SNVs/INDELs can be reduced by adding local population information even after annotating the data with other large frequency databases, such as gnomAD. In conclusion, we show that a local frequency database is an attractive, and a necessary addition to the publicly available databases that facilitate the analysis of exome and genome data in a clinical setting.

Published

2020

4. Multi-ancestry genome-wide association study of 4069 children with glioma identifies 9p21.3 risk locus

Author

Jon Foss-Skiftesvik, Shaobo Li, Adam Rosenbaum, Christian Munch Hagen, Ulrik Kristoffer Stoltze, Sally Ljungqvist, Ulf Hjalmars, Kjeld Schmiegelow, Libby Morimoto, Adam J de Smith, René Mathiasen, Catherine Metayer, David Hougaard, Beatrice Melin, Kyle M Walsh, Jonas Bybjerg-Grauholm, Anna M Dahlin, and Joseph L Wiemels

Subjects

Cancer Research, Oncology, Neurology (clinical)

Abstract

Background Although recent sequencing studies have revealed that 10% of childhood gliomas are caused by rare germline mutations, the role of common variants is undetermined and no genome-wide significant risk loci for pediatric central nervous system tumors have been identified to date. Methods Meta-analysis of 3 population-based genome-wide association studies comprising 4069 children with glioma and 8778 controls of multiple genetic ancestries. Replication was performed in a separate case–control cohort. Quantitative trait loci analyses and a transcriptome-wide association study were conducted to assess possible links with brain tissue expression across 18 628 genes. Results Common variants in CDKN2B-AS1 at 9p21.3 were significantly associated with astrocytoma, the most common subtype of glioma in children (rs573687, P-value of 6.974e-10, OR 1.273, 95% CI 1.179–1.374). The association was driven by low-grade astrocytoma (P-value of 3.815e-9) and exhibited unidirectional effects across all 6 genetic ancestries. For glioma overall, the association approached genome-wide significance (rs3731239, P-value of 5.411e-8), while no significant association was observed for high-grade tumors. Predicted decreased brain tissue expression of CDKN2B was significantly associated with astrocytoma (P-value of 8.090e-8). Conclusions In this population-based genome-wide association study meta-analysis, we identify and replicate 9p21.3 (CDKN2B-AS1) as a risk locus for childhood astrocytoma, thereby establishing the first genome-wide significant evidence of common variant predisposition in pediatric neuro-oncology. We furthermore provide a functional basis for the association by showing a possible link to decreased brain tissue CDKN2B expression and substantiate that genetic susceptibility differs between low- and high-grade astrocytoma.

Published

2023

5. The Ghost Rules

Author

Adam Rosenbaum and Adam Rosenbaum

Subjects

Ghost stories, Novels, Ability--Fiction, Ghosts--Fiction, Brothers--Fiction, Friendship--Fiction

Abstract

Twelve-year-old Elwood McGee never asked to have “ghost-sight,” and it involves a lot more drool-dodging than he expected. Ghosts are the WORST—and they're all over the place in this sharp-witted middle grade debut novel.Did you know that ghosts love coffee? They're not trying to be scary. They're just deprived of an appropriate amount of caffeine! They also bump into things by accident, are occasionally nosy, and get a little nervous when they're seen by the living. Elwood McGee knows these ghost facts because he's one of those rare people with the gift of ghost-sight. And it turns out ghosts are everywhere! Especially in the small Tennessee town where Elwood and his family had to move following the death of his big brother Noah, which Elwood thinks was his fault. Once Elwood figures out he can see ghosts, he becomes single-mindedly determined to use his powers to see Noah and talk to him once last time. With the help of two girls who live on his street, Elwood embarks on a journey through the surprisingly funny world of ghosts and faces the realities of letting go. At once hilarious and heart wrenching, Adam Rosenbaum makes his middle grade debut with a supernaturalish novel about grief that's perfect for fans of Gordon Korman and Dan Gutman.A Junior Library Guild Gold Standard Selection

Published

2024

6. Integration of whole genome sequencing into a healthcare setting: high diagnostic rates across multiple clinical entities in 3219 rare disease patients

Author

Tommy Stödberg, Magnus Nordenskjöld, Emma Tham, Virpi Töhönen, Karin Naess, Bianca Tesi, Eliane Sardh, Erik Björck, Martin Engvall, Helena Malmgren, Josephine Wincent, Adam Rosenbaum, Peter Gustavsson, Sofie Vonlanthen, Anders Jemt, Måns Magnusson, Helene Bruhn, Anna Wredenberg, Mikael Oscarson, Sofia Ygberg, Kristina Lagerstedt-Robinson, Erik Iwarsson, Carolina Backman Johansson, Christoph Freyer, Michela Barbaro, Ellika Sahlin, Henrik Stranneheim, Anna Lindstrand, Anna Wedell, Ann Nordgren, Ulrika von Döbeln, Britt-Marie Anderlid, Mikael Laaksonen, Maria Pettersson, Henrik Arnell, Nicole Lesko, Rolf Zetterström, Chiara Rasi, Ann-Charlotte Wikström, Malin Kvarnung, Valtteri Wirta, Sara Lind Enoksson, Giedre Grigelioniene, Maria Johansson Soller, Anna Hammarsjö, Ola Winqvist, Daphne Vassiliou, Håkan Thonberg, Per Marits, Jesper Eisfeldt, Daniel Nilsson, and Maritta Hellström-Pigg

Subjects

medicine.medical_specialty, lcsh:QH426-470, DNA Copy Number Variations, Inheritance Patterns, lcsh:Medicine, Genomics, Disease, Cohort Studies, Genetic Heterogeneity, Rare Diseases, Internal medicine, Genetics, medicine, Humans, Medical diagnosis, Indel, Monogenic disease, Molecular Biology, Genetics (clinical), Whole genome sequencing, Sweden, Whole Genome Sequencing, business.industry, Information Dissemination, Research, lcsh:R, High-Throughput Nucleotide Sequencing, Uniparental Disomy, medicine.disease, Human genetics, Uniparental disomy, Single nucleotide variant, lcsh:Genetics, Clinical diagnostics, Mutation, Molecular Medicine, business, Delivery of Health Care, Rare disease, Microsatellite Repeats

Abstract

Background We report the findings from 4437 individuals (3219 patients and 1218 relatives) who have been analyzed by whole genome sequencing (WGS) at the Genomic Medicine Center Karolinska-Rare Diseases (GMCK-RD) since mid-2015. GMCK-RD represents a long-term collaborative initiative between Karolinska University Hospital and Science for Life Laboratory to establish advanced, genomics-based diagnostics in the Stockholm healthcare setting. Methods Our analysis covers detection and interpretation of SNVs, INDELs, uniparental disomy, CNVs, balanced structural variants, and short tandem repeat expansions. Visualization of results for clinical interpretation is carried out in Scout—a custom-developed decision support system. Results from both singleton (84%) and trio/family (16%) analyses are reported. Variant interpretation is done by 15 expert teams at the hospital involving staff from three clinics. For patients with complex phenotypes, data is shared between the teams. Results Overall, 40% of the patients received a molecular diagnosis ranging from 19 to 54% for specific disease groups. There was heterogeneity regarding causative genes (n = 754) with some of the most common ones being COL2A1 (n = 12; skeletal dysplasia), SCN1A (n = 8; epilepsy), and TNFRSF13B (n = 4; inborn errors of immunity). Some causative variants were recurrent, including previously known founder mutations, some novel mutations, and recurrent de novo mutations. Overall, GMCK-RD has resulted in a large number of patients receiving specific molecular diagnoses. Furthermore, negative cases have been included in research studies that have resulted in the discovery of 17 published, novel disease-causing genes. To facilitate the discovery of new disease genes, GMCK-RD has joined international data sharing initiatives, including ClinVar, UDNI, Beacon, and MatchMaker Exchange. Conclusions Clinical WGS at GMCK-RD has provided molecular diagnoses to over 1200 individuals with a broad range of rare diseases. Consolidation and spread of this clinical-academic partnership will enable large-scale national collaboration.

Published

2021

7. Loqusdb: added value of an observations database of local genomic variation

Author

Jesper Eisfeldt, Anna Wedell, Henrik Stranneheim, Daniel Nilsson, Adam Rosenbaum, Måns Magnusson, Anna Lindstrand, and Valtteri Wirta

Subjects

medicine.medical_specialty, Computer science, Population, Population frequency, Genomics, Mendelian, lcsh:Computer applications to medicine. Medical informatics, computer.software_genre, Polymorphism, Single Nucleotide, Biochemistry, Genome, DNA sequencing, Structural variation, User-Computer Interface, 03 medical and health sciences, INDEL Mutation, Structural Biology, Intellectual Disability, Databases, Genetic, medicine, Humans, Nucleotide, Indel, education, lcsh:QH301-705.5, Molecular Biology, Exome, 030304 developmental biology, chemistry.chemical_classification, 0303 health sciences, education.field_of_study, Database, Applied Mathematics, 030305 genetics & heredity, Genetic Variation, Structural variant, Computer Science Applications, Single nucleotide variant, lcsh:Biology (General), chemistry, lcsh:R858-859.7, Medical genetics, DNA microarray, Rare disease, computer, Software

Abstract

Background Exome and genome sequencing is becoming the method of choice for rare disease diagnostics. One of the key challenges remaining is distinguishing the disease causing variants from the benign background variation. After analysis and annotation of the sequencing data there are typically thousands of candidate variants requiring further investigation. One of the most effective and least biased ways to reduce this number is to assess the rarity of a variant in any population. Currently, there are a number of reliable sources of information for major population frequencies when considering single nucleotide variants (SNVs) and small insertion and deletions (INDELs), with gnomAD as the most prominent public resource available. However, local variation or frequencies in sub-populations may be underrepresented in these public resources. In contrast, for structural variation (SV), the background frequency in the general population is more or less unknown mostly due to challenges in calling SVs in a consistent way. Keeping track of local variation is one way to overcome these problems and significantly reduce the number of potential disease causing variants retained for manual inspection, both for SNVs and SVs. Results Here, we present loqusdb, a tool to solve the challenge of keeping track of any type of variant observations from genome sequencing data. Loqusdb was designed to handle a large flow of samples and unlike other solutions, samples can be added continuously to the database without rebuilding it, facilitating improvements and additions. We assessed the added value of a local observations database using 98 samples annotated with information from a background of 888 unrelated individuals. Conclusions We show both how powerful SV analysis can be when filtering for population frequencies and how the number of apparently rare SNVs/INDELs can be reduced by adding local population information even after annotating the data with other large frequency databases, such as gnomAD. In conclusion, we show that a local frequency database is an attractive, and a necessary addition to the publicly available databases that facilitate the analysis of exome and genome data in a clinical setting.

Published

2020