Mark W Youngblood1,2,3, Daniel Duran1,2,4, Julio D Montejo1,2,5, Chang Li1,2,6,7, Sacit Bulent Omay1,2, Koray Özduman8, Amar H Sheth1,2, Amy Y Zhao1,2, Evgeniya Tyrtova1,2, Danielle F Miyagishima1,2,3, Elena I Fomchenko1,2, Christopher S Hong1,2, Victoria E Clark9, Maximilien Riche10, Matthieu Peyre10, Julien Boetto10, Sadaf Sohrabi1,2, Sarah Koljaka1,2, Jacob F Baranoski11, James Knight3,12, Hongda Zhu13, M Necmettin Pamir8, Timuçin Avşar14, Türker Kilic15, Johannes Schramm16, Marco Timmer17, Roland Goldbrunner17, Ye Gong13, Yaşar Bayri18, Nduka Amankulor19, Ronald L Hamilton19, Kaya Bilguvar3,12, Irina Tikhonova12, Patrick R Tomak2, Anita Huttner1,20, Matthias Simon16,21, Boris Krischek17, Michel Kalamarides10, E Zeynep Erson-Omay1,2, Jennifer Moliterno1,2, Murat Günel1,2,3,12,22. 1. 1Yale Program in Brain Tumor Research. 2. 2Department of Neurosurgery. 3. 3Department of Genetics, and. 4. 4Department of Neurosurgery, University of Mississippi Medical Center, Jackson, Mississippi. 5. 5Section of Neurosurgery, Dartmouth-Hitchcock Medical Center, Lebanon, New Hampshire. 6. 6Department of Neurosurgery, Xiangya Hospital, Central South University, Changsha, China. 7. 7The Third Xiangya Hospital, Central South University, Changsha, China. 8. 8Department of Neurosurgery, Acibadem Mehmet Ali Aydınlar University, School of Medicine, Istanbul, Turkey. 9. 9Department of Neurosurgery, Massachusetts General Hospital, Boston, Massachusetts. 10. 10Department of Neurosurgery, Hôpital Universitaire Pitié-Salpêtrière, AP-HP & Sorbonne Université, Paris, France. 11. 11Department of Neurosurgery, Barrow Neurological Institute, St. Joseph's Hospital and Medical Center, Phoenix, Arizona. 12. 12Yale Center for Genome Analysis, Yale University West Campus, Orange, Connecticut. 13. 13Department of Neurosurgery, Huashan Hospital, Shanghai Medical College, Fudan University, Shanghai, China. 14. 14Department of Medical Biology, BAU Faculty of Medicine, Istanbul, Turkey. 15. 15Department of Neurosurgery, Bahcesehir University, School of Medicine, Istanbul, Turkey. 16. 16University of Bonn Medical School, Bonn, Germany. 17. 17Center for Neurosurgery, University Hospital of Cologne, Germany. 18. 18Department of Neurosurgery, Marmara University School of Medicine, Istanbul, Turkey. 19. 19Department of Neurosurgery, University of Pittsburgh Medical Center, Pittsburgh, Pennsylvania. 20. 20Department of Pathology, Yale School of Medicine, New Haven, Connecticut and. 21. 21Department of Neurosurgery, Bethel Clinic, Bielefeld, Germany. 22. 22Department of Neuroscience, Yale School of Medicine, New Haven, Connecticut.
Abstract
OBJECTIVE: Recent large-cohort sequencing studies have investigated the genomic landscape of meningiomas, identifying somatic coding alterations in NF2, SMARCB1, SMARCE1, TRAF7, KLF4, POLR2A, BAP1, and members of the PI3K and Hedgehog signaling pathways. Initial associations between clinical features and genomic subgroups have been described, including location, grade, and histology. However, further investigation using an expanded collection of samples is needed to confirm previous findings, as well as elucidate relationships not evident in smaller discovery cohorts. METHODS: Targeted sequencing of established meningioma driver genes was performed on a multiinstitution cohort of 3016 meningiomas for classification into mutually exclusive subgroups. Relevant clinical information was collected for all available cases and correlated with genomic subgroup. Nominal variables were analyzed using Fisher's exact tests, while ordinal and continuous variables were assessed using Kruskal-Wallis and 1-way ANOVA tests, respectively. Machine-learning approaches were used to predict genomic subgroup based on noninvasive clinical features. RESULTS: Genomic subgroups were strongly associated with tumor locations, including correlation of HH tumors with midline location, and non-NF2 tumors in anterior skull base regions. NF2 meningiomas were significantly enriched in male patients, while KLF4 and POLR2A mutations were associated with female sex. Among histologies, the results confirmed previously identified relationships, and observed enrichment of microcystic features among "mutation unknown" samples. Additionally, KLF4-mutant meningiomas were associated with larger peritumoral brain edema, while SMARCB1 cases exhibited elevated Ki-67 index. Machine-learning methods revealed that observable, noninvasive patient features were largely predictive of each tumor's underlying driver mutation. CONCLUSIONS: Using a rigorous and comprehensive approach, this study expands previously described correlations between genomic drivers and clinical features, enhancing our understanding of meningioma pathogenesis, and laying further groundwork for the use of targeted therapies. Importantly, the authors found that noninvasive patient variables exhibited a moderate predictive value of underlying genomic subgroup, which could improve with additional training data. With continued development, this framework may enable selection of appropriate precision medications without the need for invasive sampling procedures.
OBJECTIVE: Recent large-cohort sequencing studies have investigated the genomic landscape of meningiomas, identifying somatic coding alterations in NF2, SMARCB1, SMARCE1, TRAF7, KLF4, POLR2A, BAP1, and members of the PI3K and Hedgehog signaling pathways. Initial associations between clinical features and genomic subgroups have been described, including location, grade, and histology. However, further investigation using an expanded collection of samples is needed to confirm previous findings, as well as elucidate relationships not evident in smaller discovery cohorts. METHODS: Targeted sequencing of established meningioma driver genes was performed on a multiinstitution cohort of 3016 meningiomas for classification into mutually exclusive subgroups. Relevant clinical information was collected for all available cases and correlated with genomic subgroup. Nominal variables were analyzed using Fisher's exact tests, while ordinal and continuous variables were assessed using Kruskal-Wallis and 1-way ANOVA tests, respectively. Machine-learning approaches were used to predict genomic subgroup based on noninvasive clinical features. RESULTS: Genomic subgroups were strongly associated with tumor locations, including correlation of HH tumors with midline location, and non-NF2tumors in anterior skull base regions. NF2meningiomas were significantly enriched in male patients, while KLF4 and POLR2A mutations were associated with female sex. Among histologies, the results confirmed previously identified relationships, and observed enrichment of microcystic features among "mutation unknown" samples. Additionally, KLF4-mutant meningiomas were associated with larger peritumoral brain edema, while SMARCB1 cases exhibited elevated Ki-67 index. Machine-learning methods revealed that observable, noninvasive patient features were largely predictive of each tumor's underlying driver mutation. CONCLUSIONS: Using a rigorous and comprehensive approach, this study expands previously described correlations between genomic drivers and clinical features, enhancing our understanding of meningioma pathogenesis, and laying further groundwork for the use of targeted therapies. Importantly, the authors found that noninvasive patient variables exhibited a moderate predictive value of underlying genomic subgroup, which could improve with additional training data. With continued development, this framework may enable selection of appropriate precision medications without the need for invasive sampling procedures.
Authors: Mark W Youngblood; Danielle F Miyagishima; Lan Jin; Trisha Gupte; Chang Li; Daniel Duran; Julio D Montejo; Amy Zhao; Amar Sheth; Evgeniya Tyrtova; Koray Özduman; Francesco Iacoangeli; Matthieu Peyre; Julien Boetto; Matthew Pease; Timuçin Avşar; Anita Huttner; Kaya Bilguvar; Türker Kilic; M Necmettin Pamir; Nduka Amankulor; Michel Kalamarides; E Zeynep Erson-Omay; Murat Günel; Jennifer Moliterno Journal: Neuro Oncol Date: 2021-05-05 Impact factor: 12.300
Authors: Corey M Gill; Joshua Loewenstern; John W Rutland; Hanane Arib; Margaret Pain; Melissa Umphlett; Yayoi Kinoshita; Russell B McBride; Joshua Bederson; Michael Donovan; Robert Sebra; Mary Fowkes; Raj K Shrivastava Journal: J Cancer Res Clin Oncol Date: 2021-03-14 Impact factor: 4.553
Authors: Colin J Przybylowski; Benjamin K Hendricks; Charuta G Furey; Joseph D DiDomenico; Randall W Porter; Nader Sanai; Kaith K Almefty; Andrew S Little Journal: J Neurol Surg B Skull Base Date: 2021-09-09
Authors: Claire L Adams; Emanuela Ercolano; Sara Ferluga; Agbolahan Sofela; Foram Dave; Caterina Negroni; Kathreena M Kurian; David A Hilton; C Oliver Hanemann Journal: Int J Mol Sci Date: 2020-02-13 Impact factor: 5.923
Authors: Niklas von Spreckelsen; Natalie Waldt; Rebecca Poetschke; Christoph Kesseler; Hildegard Dohmen; Hui-Ke Jiao; Attila Nemeth; Stefan Schob; Cordula Scherlach; Ibrahim Erol Sandalcioglu; Martina Deckert; Frank Angenstein; Boris Krischek; Pantelis Stavrinou; Marco Timmer; Marc Remke; Elmar Kirches; Roland Goldbrunner; E Antonio Chiocca; Stefan Huettelmaier; Till Acker; Christian Mawrin Journal: Acta Neuropathol Commun Date: 2020-04-03 Impact factor: 7.801
Authors: Alexander F Haddad; Jacob S Young; Ishan Kanungo; Sweta Sudhir; Jia-Shu Chen; David R Raleigh; Stephen T Magill; Michael W McDermott; Manish K Aghi Journal: Front Oncol Date: 2020-08-28 Impact factor: 6.244