Your search keyword '"Koebbe, Laura L"' showing total 6 results

1. Expression quantitative trait loci influence DNA damage-induced apoptosis in cancer

Author

Bigge, Jessica, Koebbe, Laura L., Giel, Ann-Sophie, Bornholdt, Dorothea, Buerfent, Benedikt, Dasmeh, Pouria, Zink, Alexander M., Maj, Carlo, and Schumacher, Johannes

Published

2024

2. The genetic regulation of the gastric transcriptome is associated with metabolic and obesity-related traits and diseases.

Author

Koebbe, Laura L., Hess, Timo, Giel, Ann-Sophie, Bigge, Jessica, Gehlen, Jan, Schueller, Vitalia, Geppert, Michael, Dumoulin, Franz Ludwig, Heller, Joerg, Schepke, Michael, Plaßmann, Dominik, Vieth, Michael, Venerito, Marino, Schumacher, Johannes, and Maj, Carlo

Subjects

*GENETIC regulation, *GENE expression, *LOCUS (Genetics), *BODY composition, *TRANSCRIPTOMES, *PLANT protection

Abstract

Tissue-specific gene expression and gene regulation lead to a better understanding of tissue-specific physiology and pathophysiology. We analyzed the transcriptome and genetic regulatory profiles of two distinct gastric sites, corpus and antrum, to identify tissue-specific gene expression and its regulation. Gastric corpus and antrum mucosa biopsies were collected during routine gastroscopies from up to 431 healthy individuals. We obtained genotype and transcriptome data and performed transcriptome profiling and expression quantitative trait locus (eQTL) studies. We further used data from genome-wide association studies (GWAS) of various diseases and traits to partition their heritability and to perform transcriptome-wide association studies (TWAS). The transcriptome data from corpus and antral mucosa highlights the heterogeneity of gene expression in the stomach. We identified enriched pathways revealing distinct and common physiological processes in gastric corpus and antrum. Furthermore, we found an enrichment of the single nucleotide polymorphism (SNP)-based heritability of metabolic, obesity-related, and cardiovascular traits and diseases by considering corpus- and antrum-specifically expressed genes. Particularly, we could prioritize gastric-specific candidate genes for multiple metabolic traits, like NQO1 which is involved in glucose metabolism, MUC1 which contributes to purine and protein metabolism or RAB27B being a regulator of weight and body composition. Our findings show that gastric corpus and antrum vary in their transcriptome and genetic regulatory profiles indicating physiological differences which are mostly related to digestion and epithelial protection. Moreover, our findings demonstrate that the genetic regulation of the gastric transcriptome is linked to biological mechanisms associated with metabolic, obesity-related, and cardiovascular traits and diseases. [ABSTRACT FROM AUTHOR]

Published

2024

3. Elucidation of the genetic causes of bicuspid aortic valve disease

Author

Gehlen, Jan, Stundl, Anja, Debiec, Radoslaw, Fontana, Federica, Krane, Markus, Sharipova, Dinara, Nelson, Christopher P., Al-Kassou, Baravan, Giel, Ann Sophie, Sinning, Jan Malte, Bruenger, Christopher M. H., Zelck, Carolin F., Koebbe, Laura L., Braund, Peter S., Webb, Thomas R., Hetherington, Simon, Ensminger, Stephan, Fujita, Buntaro, Mohamed, Salah A., Shrestha, Malakh, Krueger, Heike, Siepe, Matthias, Kari, Fabian Alexander, Nordbeck, Peter, Buravezky, Larissa, Kelm, Malte, Veulemans, Verena, Adam, Matti, Baldus, Stephan, Laugwitz, Karl Ludwig, Haas, Yannick, Karck, Matthias, Mehlhorn, Uwe, Conzelmann, Lars Oliver, Breitenbach, Ingo, Lebherz, Corinna, Urbanski, Paul, Kim, Won Keun, Kandels, Joscha, Ellinghaus, David, Nowak-Goettl, Ulrike, Hoffmann, Per, Wirth, Felix, Doppler, Stefanie, Lahm, Harald, Dressen, Martina, von Scheidt, Moritz, Knoll, Katharina, Kessler, Thorsten, Hengstenberg, Christian, Schunkert, Heribert, Nickenig, Georg, Noethen, Markus M., Bolger, Aidan P., Abdelilah-Seyfried, Salim, Samani, Nilesh J., Erdmann, Jeanette, Trenkwalder, Teresa, Schumacher, Johannes, Gehlen, Jan, Stundl, Anja, Debiec, Radoslaw, Fontana, Federica, Krane, Markus, Sharipova, Dinara, Nelson, Christopher P., Al-Kassou, Baravan, Giel, Ann Sophie, Sinning, Jan Malte, Bruenger, Christopher M. H., Zelck, Carolin F., Koebbe, Laura L., Braund, Peter S., Webb, Thomas R., Hetherington, Simon, Ensminger, Stephan, Fujita, Buntaro, Mohamed, Salah A., Shrestha, Malakh, Krueger, Heike, Siepe, Matthias, Kari, Fabian Alexander, Nordbeck, Peter, Buravezky, Larissa, Kelm, Malte, Veulemans, Verena, Adam, Matti, Baldus, Stephan, Laugwitz, Karl Ludwig, Haas, Yannick, Karck, Matthias, Mehlhorn, Uwe, Conzelmann, Lars Oliver, Breitenbach, Ingo, Lebherz, Corinna, Urbanski, Paul, Kim, Won Keun, Kandels, Joscha, Ellinghaus, David, Nowak-Goettl, Ulrike, Hoffmann, Per, Wirth, Felix, Doppler, Stefanie, Lahm, Harald, Dressen, Martina, von Scheidt, Moritz, Knoll, Katharina, Kessler, Thorsten, Hengstenberg, Christian, Schunkert, Heribert, Nickenig, Georg, Noethen, Markus M., Bolger, Aidan P., Abdelilah-Seyfried, Salim, Samani, Nilesh J., Erdmann, Jeanette, Trenkwalder, Teresa, and Schumacher, Johannes

Abstract

Aims The present study aims to characterize the genetic risk architecture of bicuspid aortic valve (BAV) disease, the most common congenital heart defect. Methods and results We carried out a genome-wide association study (GWAS) including 2236 BAV patients and 11 604 controls. This led to the identification of a new risk locus for BAV on chromosome 3q29. The single nucleotide polymorphism rs2550262 was genome-wide significant BAV associated (P = 3.49 x 10(-08)) and was replicated in an independent case-control sample. The risk locus encodes a deleterious missense variant in MUC4 (p.Ala4821Ser), a gene that is involved in epithelial-to-mesenchymal transformation. Mechanistical studies in zebrafish revealed that loss of Muc4 led to a delay in cardiac valvular development suggesting that loss of MUC4 may also play a role in aortic valve malformation. The GWAS also confirmed previously reported BAV risk loci at PALMD (P = 3.97 x 10(-16)), GATA4 (P = 1.61 x 10(-09)), and TEX41 (P = 7.68 x 10(-04)). In addition, the genetic BAV architecture was examined beyond the single-marker level revealing that a substantial fraction of BAV heritability is polygenic and similar to 20% of the observed heritability can be explained by our GWAS data. Furthermore, we used the largest human single-cell atlas for foetal gene expression and show that the transcriptome profile in endothelial cells is a major source contributing to BAV pathology. Conclusion Our study provides a deeper understanding of the genetic risk architecture of BAV formation on the single marker and polygenic level.

Published

2023

4. Elucidation of the genetic causes of bicuspid aortic valve disease

Author

Gehlen, Jan, primary, Stundl, Anja, additional, Debiec, Radoslaw, additional, Fontana, Federica, additional, Krane, Markus, additional, Sharipova, Dinara, additional, Nelson, Christopher P, additional, Al-Kassou, Baravan, additional, Giel, Ann Sophie, additional, Sinning, Jan Malte, additional, Bruenger, Christopher MH, additional, Zelck, Carolin F, additional, Koebbe, Laura L, additional, Braund, Peter S, additional, Webb, Thomas R, additional, Hetherington, Simon, additional, Ensminger, Stephan, additional, Fujita, Buntaro, additional, Mohamed, Salah A, additional, Shrestha, Malakh, additional, Krueger, Heike, additional, Siepe, Matthias, additional, Kari, Fabian Alexander, additional, Nordbeck, Peter, additional, Buravezky, Larissa, additional, Kelm, Malte, additional, Veulemans, Verena, additional, Adam, Matti, additional, Baldus, Stephan, additional, Laugwitz, Karl Ludwig, additional, Haas, Yannick, additional, Karck, Matthias, additional, Mehlhorn, Uwe, additional, Conzelmann, Lars Oliver, additional, Breitenbach, Ingo, additional, Lebherz, Corinna, additional, Urbanski, Paul, additional, Kim, Won Keun, additional, Kandels, Joscha, additional, Ellinghaus, David, additional, Nowak-Goettl, Ulrike, additional, Hoffmann, Per, additional, Wirth, Felix, additional, Doppler, Stefanie, additional, Lahm, Harald, additional, Dreßen, Martina, additional, von Scheidt, Moritz, additional, Knoll, Katharina, additional, Kessler, Thorsten, additional, Hengstenberg, Christian, additional, Schunkert, Heribert, additional, Nickenig, Georg, additional, Nöthen, Markus M, additional, Bolger, Aidan P, additional, Abdelilah-Seyfried, Salim, additional, Samani, Nilesh J, additional, Erdmann, Jeanette, additional, Trenkwalder, Teresa, additional, and Schumacher, Johannes, additional

Published

2022

5. Elucidation of the genetic causes of bicuspid aortic valve disease

Author

Gehlen, Jan, Stundl, Anja, Debiec, Radoslaw, Fontana, Federica, Krane, Markus, Sharipova, Dinara, Nelson, Christopher P., Al-Kassou, Baravan, Giel, Ann Sophie, Sinning, Jan Malte, Bruenger, Christopher M. H., Zelck, Carolin F., Koebbe, Laura L., Braund, Peter S., Webb, Thomas R., Hetherington, Simon, Ensminger, Stephan, Fujita, Buntaro, Mohamed, Salah A., Shrestha, Malakh, Krueger, Heike, Siepe, Matthias, Kari, Fabian Alexander, Nordbeck, Peter, Buravezky, Larissa, Kelm, Malte, Veulemans, Verena, Adam, Matti, Baldus, Stephan, Laugwitz, Karl Ludwig, Haas, Yannick, Karck, Matthias, Mehlhorn, Uwe, Conzelmann, Lars Oliver, Breitenbach, Ingo, Lebherz, Corinna, Urbanski, Paul, Kim, Won Keun, Kandels, Joscha, Ellinghaus, David, Nowak-Goettl, Ulrike, Hoffmann, Per, Wirth, Felix, Doppler, Stefanie, Lahm, Harald, Dressen, Martina, von Scheidt, Moritz, Knoll, Katharina, Kessler, Thorsten, Hengstenberg, Christian, Schunkert, Heribert, Nickenig, Georg, Noethen, Markus M., Bolger, Aidan P., Abdelilah-Seyfried, Salim, Samani, Nilesh J., Erdmann, Jeanette, Trenkwalder, Teresa, Schumacher, Johannes, Gehlen, Jan, Stundl, Anja, Debiec, Radoslaw, Fontana, Federica, Krane, Markus, Sharipova, Dinara, Nelson, Christopher P., Al-Kassou, Baravan, Giel, Ann Sophie, Sinning, Jan Malte, Bruenger, Christopher M. H., Zelck, Carolin F., Koebbe, Laura L., Braund, Peter S., Webb, Thomas R., Hetherington, Simon, Ensminger, Stephan, Fujita, Buntaro, Mohamed, Salah A., Shrestha, Malakh, Krueger, Heike, Siepe, Matthias, Kari, Fabian Alexander, Nordbeck, Peter, Buravezky, Larissa, Kelm, Malte, Veulemans, Verena, Adam, Matti, Baldus, Stephan, Laugwitz, Karl Ludwig, Haas, Yannick, Karck, Matthias, Mehlhorn, Uwe, Conzelmann, Lars Oliver, Breitenbach, Ingo, Lebherz, Corinna, Urbanski, Paul, Kim, Won Keun, Kandels, Joscha, Ellinghaus, David, Nowak-Goettl, Ulrike, Hoffmann, Per, Wirth, Felix, Doppler, Stefanie, Lahm, Harald, Dressen, Martina, von Scheidt, Moritz, Knoll, Katharina, Kessler, Thorsten, Hengstenberg, Christian, Schunkert, Heribert, Nickenig, Georg, Noethen, Markus M., Bolger, Aidan P., Abdelilah-Seyfried, Salim, Samani, Nilesh J., Erdmann, Jeanette, Trenkwalder, Teresa, and Schumacher, Johannes

Abstract

Aims The present study aims to characterize the genetic risk architecture of bicuspid aortic valve (BAV) disease, the most common congenital heart defect. Methods and results We carried out a genome-wide association study (GWAS) including 2236 BAV patients and 11 604 controls. This led to the identification of a new risk locus for BAV on chromosome 3q29. The single nucleotide polymorphism rs2550262 was genome-wide significant BAV associated (P = 3.49 x 10(-08)) and was replicated in an independent case-control sample. The risk locus encodes a deleterious missense variant in MUC4 (p.Ala4821Ser), a gene that is involved in epithelial-to-mesenchymal transformation. Mechanistical studies in zebrafish revealed that loss of Muc4 led to a delay in cardiac valvular development suggesting that loss of MUC4 may also play a role in aortic valve malformation. The GWAS also confirmed previously reported BAV risk loci at PALMD (P = 3.97 x 10(-16)), GATA4 (P = 1.61 x 10(-09)), and TEX41 (P = 7.68 x 10(-04)). In addition, the genetic BAV architecture was examined beyond the single-marker level revealing that a substantial fraction of BAV heritability is polygenic and similar to 20% of the observed heritability can be explained by our GWAS data. Furthermore, we used the largest human single-cell atlas for foetal gene expression and show that the transcriptome profile in endothelial cells is a major source contributing to BAV pathology. Conclusion Our study provides a deeper understanding of the genetic risk architecture of BAV formation on the single marker and polygenic level.

6. Distinct Genetic Risk Profile in Aortic Stenosis Compared With Coronary Artery Disease.

Author

Trenkwalder T, Maj C, Al-Kassou B, Debiec R, Doppler SA, Musameh MD, Nelson CP, Dasmeh P, Grover S, Knoll K, Naamanka J, Mordi IR, Braund PS, Dreßen M, Lahm H, Wirth F, Baldus S, Kelm M, von Scheidt M, Krefting J, Ellinghaus D, Small AM, Peloso GM, Natarajan P, Thanassoulis G, Engert JC, Dufresne L, Franke A, Görg S, Laudes M, Nowak-Göttl U, Vaht M, Metspalu A, Stoll M, Berger K, Pellegrini C, Kastrati A, Hengstenberg C, Lang CC, Kessler T, Hovatta I, Nickenig G, Nöthen MM, Krane M, Schunkert H, Samani NJ, Schumacher J, Kals M, Reigo A, Teder-Laving M, Gehlen J, Webb TR, Giel AS, Koebbe LL, Feirer N, Billmann M, Srinivasan S, Zimmer S, Palmer CNA, Li L, Yang C, Borisov O, Adam M, Veulemans V, Joner M, and Xhepa E

Subjects

Humans, Female, Male, Middle Aged, Aged, Genetic Predisposition to Disease, ADAMTS7 Protein genetics, Risk Factors, Europe epidemiology, Coronary Artery Disease genetics, Coronary Artery Disease epidemiology, Genome-Wide Association Study, Aortic Valve Stenosis genetics, Aortic Valve Stenosis epidemiology

Abstract

Importance: Aortic stenosis (AS) and coronary artery disease (CAD) frequently coexist. However, it is unknown which genetic and cardiovascular risk factors might be AS-specific and which could be shared between AS and CAD., Objective: To identify genetic risk loci and cardiovascular risk factors with AS-specific associations., Design, Setting, and Participants: This was a genomewide association study (GWAS) of AS adjusted for CAD with participants from the European Consortium for the Genetics of Aortic Stenosis (EGAS) (recruited 2000-2020), UK Biobank (recruited 2006-2010), Estonian Biobank (recruited 1997-2019), and FinnGen (recruited 1964-2019). EGAS participants were collected from 7 sites across Europe. All participants were of European ancestry, and information on comorbid CAD was available for all participants. Follow-up analyses with GWAS data on cardiovascular traits and tissue transcriptome data were also performed. Data were analyzed from October 2022 to July 2023., Exposures: Genetic variants., Main Outcomes and Measures: Cardiovascular traits associated with AS adjusted for CAD. Replication was performed in 2 independent AS GWAS cohorts., Results: A total of 18 792 participants with AS and 434 249 control participants were included in this GWAS adjusted for CAD. The analysis found 17 AS risk loci, including 5 loci with novel and independently replicated associations (RNF114A, AFAP1, PDGFRA, ADAMTS7, HAO1). Of all 17 associated loci, 11 were associated with risk specifically for AS and were not associated with CAD (ALPL, PALMD, PRRX1, RNF144A, MECOM, AFAP1, PDGFRA, IL6, TPCN2, NLRP6, HAO1). Concordantly, this study revealed only a moderate genetic correlation of 0.15 (SE, 0.05) between AS and CAD (P = 1.60 × 10-3). Mendelian randomization revealed that serum phosphate was an AS-specific risk factor that was absent in CAD (AS: odds ratio [OR], 1.20; 95% CI, 1.11-1.31; P = 1.27 × 10-5; CAD: OR, 0.97; 95% CI 0.94-1.00; P = .04). Mendelian randomization also found that blood pressure, body mass index, and cholesterol metabolism had substantially lesser associations with AS compared with CAD. Pathway and transcriptome enrichment analyses revealed biological processes and tissues relevant for AS development., Conclusions and Relevance: This GWAS adjusted for CAD found a distinct genetic risk profile for AS at the single-marker and polygenic level. These findings provide new targets for future AS research.

Published

2025