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Frank Szulzewsky

Assistant Professor of Neurosurgery and
Adjunct Assistant Professor of Oncological Sciences

Brain tumors; meningioma; YAP1; TAZ; NTRK; gene fusions; mouse modeling

Szulzewsky Photo

Molecular Biology Program

Education

Dipl-Ing Technische Universität Berlin

Ph.D. Freie Universität Berlin, Max Delbrück Center for Molecular Medicine

Links

Lab Page

PubMed Literature Search

Frank.Szulzewsky@hsc.utah.edu

Research

The research of our lab is focused on the functions of oncogenic drivers found in several types of both pediatric and adult brain tumors, including Glioma, Meningioma, and Supratentorial (ST) Ependymoma. Pediatric and adult tumors can differ dramatically in their genetic markup and their underlying mutations. While adult cancers frequently harbor a highly aberrant genome with gains and losses of entire chromosomal regions, the genomes of pediatric cancers are oftentimes relatively more stable and are enriched for more defined mutations, such as gene fusions. Pediatric cancers that harbor targetable gene fusions are ideal candidates for targeted therapies. However, even though clinical trials targeting gene fusions have achieved promising initial responses (such as Larotrectinib in NTRK fusion positive tumors), these effects are usually only partial, and the tumors ultimately recur due to the occurrence of resistance mutations. Our lab utilizes genetically-engineered mouse models in order to study how specific oncogenes (such as gene fusions) drive tumor development, how these tumors respond to targeted therapies in vivo, and what mechanisms of resistance lead to treatment failure and tumor recurrence in order to develop novel adjuvant therapies that can increase treatment success and survival.

YAP1 gene fusions

YAP1 gene fusions frequently occur in rare cancers (often pediatric cancers) or subtypes of more common cancers. Our work was able to show that these fusions are strong oncogenic drivers and can induce the formation of tumors that resemble the human disease when expressed in mice. Different YAP1 fusions all exert strong YAP activity that is resistant to negative inhibition by the Hippo signaling pathway (a tumor suppressive protein cascade that inhibits the activity of wild type YAP1), and thereby constitute activating YAP mutations (Szulzewsky et al, 2020, Genes & Development; Szulzewsky et al, 2022, Genes & Development). In a subsequent project, we could show that the TFE3 domains and activity significantly contributes to the oncogenic functions of YAP1::TFE3 (Cimino et al, 2025, Scientific Reports).

Selected publications:

https://pubmed.ncbi.nlm.nih.gov/40887511/

https://pubmed.ncbi.nlm.nih.gov/36732631/

https://pubmed.ncbi.nlm.nih.gov/38315854/

https://pubmed.ncbi.nlm.nih.gov/36008139/

https://pubmed.ncbi.nlm.nih.gov/32675324/

YAP/TAZ activity in meningioma

We are investigating the role of oncogenic YAP/TAZ activity in low-grade versus high-grade NF2 mutant meningiomas. Around half of all meningiomas harbor mutations that result in the functional loss of NF2/Merlin, resulting in the deregulation of oncogenic YAP signaling. While low-grade NF2 mutant meningiomas harbor few recurrent additional mutations, high-grade tumors exhibit a highly aberrant genome with multiple concurrent mutations, as well as gains and losses of chromosomal regions. We could recently show that high-grade NF2 mutant meningiomas actively down-regulate oncogenic YAP activity, in part by overexpressing the YAP1 antagonist VGLL4 (Parrish et al, 2024, Neuro-Oncology Advances). We are aiming to understand why aggressive meningiomas downregulate YAP1 activity and what implications this has for the treatment of these tumors.

Selected publications:

https://pubmed.ncbi.nlm.nih.gov/40249111/

https://pubmed.ncbi.nlm.nih.gov/39380691/

https://pubmed.ncbi.nlm.nih.gov/38788713/

NTRK & ALK gene fusions in pediatric glioma

Gene fusions involving receptor tyrosine kinase genes (such as NTRK and ALK) are enriched in pediatric and infantile cancers, including pediatric glioma. Similar to other gene fusion-driven tumors, these cancers harbor few additional mutations (at least in treatment naïve tumors) and are mainly driven by the oncogenic activity induced by the gene fusion. Clinical trials with targeted agents directed at these gene fusions (such as Larotrectinib and Entrectinib against NTRK fusions) show high initial overall response rates, but ultimately fail due to the occurrence of resistant tumor cells. Using the RCAS/tv-a system for somatic cell gene transfer, we have developed several NTRK and ALK gene fusion-driven glioma mouse models (Schmid et al, 2024, Cell Reports). Treatment with tyrosine kinase inhibitors induces a rapid regression of these tumors, however, similar to the human disease, therapy-resistant persister cells ultimately lead to tumor recurrence. Several factors may contribute to therapy resistance, such as low drug penetration into the brain, tumor-microenvironment interactions, and the presence of drug efflux transporters. We are currently using these models to study the biology of these tumors and their response to targeted therapy, in order to ultimately overcome treatment resistance.

Selected publications:

https://pubmed.ncbi.nlm.nih.gov/39365700/

https://pubmed.ncbi.nlm.nih.gov/39072755/

References

Selected publications

  1. Cimino PJ, Keiser DJ, Parrish AG, Holland EC, Szulzewsky F. C-terminal fusion partner activity contributes to the oncogenic functions of YAP1::TFE3. Sci Rep. 2025 Aug 31;15(1):32013. doi: 10.1038/s41598-025-17409-z. PMID: 40887511; PMCID: PMC12399754.
  2. Sievers P, Arora S, Hielscher T, Savran D, Schrimpf D, Banan R, Vonhören D, Pusch S, Sill M, Appay R, Wirsching HG, Hortobagyi T, Dohmen H, Acker T, Kohlhof-Meinecke P, Schweizer L, Wefers AK, Harter PN, Hartmann C, Beschorner R, Schittenhelm J, Behling F, Tabatabai G, Mawrin C, Snuderl M, Maas SLN, Wesseling P, Brandner S, Korshunov A, Ratliff M, Krieg SM, Wick W, Jones DTW, Pfister SM, Holland EC, von Deimling A, Szulzewsky F, Sahm F. Molecular signatures define BAP1-altered meningioma as a distinct CNS tumor with deregulation of Polycomb repressive complex target genes. Neuro Oncol. 2025 Apr 18:noaf105. doi: 10.1093/neuonc/noaf105. Epub ahead of print. PMID: 40249111.
  3. Parrish AG, Szulzewsky F. TRKing down drug resistance in NTRK fusion-positive cancers<sup>†</sup>. J Pathol. 2024 Oct;264(2):129-131. doi: 10.1002/path.6341. Epub 2024 Jul 29. PMID: 39072755.
  4. Schmid S, Russell ZR, Yamashita AS, West ME, Parrish AG, Walker J, Rudoy D, Yan JZ, Quist DC, Gessesse BN, Alvinez N, Hill KD, Anderson LW, Cimino PJ, Kumasaka DK, Parchment RE, Holland EC, Szulzewsky F. ERK signaling promotes resistance to TRK kinase inhibition in NTRK fusion-driven glioma mouse models. Cell Rep. 2024 Oct 22;43(10):114829. doi: 10.1016/j.celrep.2024.114829. Epub 2024 Oct 3. PMID: 39365700; PMCID: PMC11572037.
  5. Parrish AG, Arora S, Thirimanne HN, Rudoy D, Schmid S, Sievers P, Sahm F, Holland EC, Szulzewsky F. Aggressive high-grade NF2 mutant meningiomas downregulate oncogenic YAP signaling via the upregulation of VGLL4 and FAT3/4. Neurooncol Adv. 2024 Aug 24;6(1):vdae148. doi: 10.1093/noajnl/vdae148. PMID: 39380691; PMCID: PMC11459063.
  6. Chung CI, Yang J, Yang X, Liu H, Ma Z, Szulzewsky F, Holland EC, Shen Y, Shu X. Phase separation of YAP-MAML2 differentially regulates the transcriptome. Proc Natl Acad Sci U S A. 2024 Feb 13;121(7):e2310430121. doi: 10.1073/pnas.2310430121. Epub 2024 Feb 5. PMID: 38315854; PMCID: PMC10873646.
  7. Thirimanne HN, Almiron-Bonnin D, Nuechterlein N, Arora S, Jensen M, Parada CA, Qiu C, Szulzewsky F, English CW, Chen WC, Sievers P, Nassiri F, Wang JZ, Klisch TJ, Aldape KD, Patel AJ, Cimino PJ, Zadeh G, Sahm F, Raleigh DR, Shendure J, Ferreira M, Holland EC. Meningioma transcriptomic landscape demonstrates novel subtypes with regional associated biology and patient outcome. Cell Genom. 2024 Jun 12;4(6):100566. doi: 10.1016/j.xgen.2024.100566. Epub 2024 May 23. PMID: 38788713; PMCID: PMC11228955.
  8. Hu X, Wu X, Berry K, Zhao C, Xin D, Ogurek S, Liu X, Zhang L, Luo Z, Sakabe M, Trubicka J, Łastowska M, Szulzewsky F, Holland EC, Lee L, Hu M, Xin M, Lu QR. Nuclear condensates of YAP fusion proteins alter transcription to drive ependymoma tumourigenesis. Nat Cell Biol. 2023 Feb;25(2):323-336. doi: 10.1038/s41556-022-01069-6. Epub 2023 Feb 2. PMID: 36732631.
  9. Szulzewsky F, Arora S, Arakaki AKS, Sievers P, Almiron Bonnin DA, Paddison PJ, Sahm F, Cimino PJ, Gujral TS, Holland EC. Both YAP1-MAML2 and constitutively active YAP1 drive the formation of tumors that resemble NF2 mutant meningiomas in mice. Genes Dev. 2022 Aug 25;36(13-14):857–70. doi: 10.1101/gad.349876.122. Epub ahead of print. PMID: 36008139; PMCID: PMC9480855.
  10. Szulzewsky F, Arora S, Hoellerbauer P, King C, Nathan E, Chan M, Cimino PJ, Ozawa T, Kawauchi D, Pajtler KW, Gilbertson RJ, Paddison PJ, Vasioukhin V, Gujral TS, Holland EC. Comparison of tumor-associated YAP1 fusions identifies a recurrent set of functions critical for oncogenesis. Genes Dev. 2020 Aug 1;34(15-16):1051-1064. doi: 10.1101/gad.338681.120. Epub 2020 Jul 16. PMID: 32675324; PMCID: PMC7397849.
Last Updated: 9/5/25