Humanized neurofibroma model from induced pluripotent stem cells delineates tumor pathogenesis and developmental origins
Juan Mo, … , David H. Gutmann, Lu Q. Le
Juan Mo, … , David H. Gutmann, Lu Q. Le
Published October 27, 2020
Citation Information: J Clin Invest. 2021;131(1):e139807. https://doi.org/10.1172/JCI139807.
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Research Article Neuroscience Oncology

Humanized neurofibroma model from induced pluripotent stem cells delineates tumor pathogenesis and developmental origins

Abstract

Neurofibromatosis type 1 (NF1) is a common tumor predisposition syndrome caused by NF1 gene mutation, in which affected patients develop Schwann cell lineage peripheral nerve sheath tumors (neurofibromas). To investigate human neurofibroma pathogenesis, we differentiated a series of isogenic, patient-specific NF1-mutant human induced pluripotent stem cells (hiPSCs) into Schwannian lineage cells (SLCs). We found that, although WT and heterozygous NF1-mutant hiPSCs-SLCs did not form tumors following mouse sciatic nerve implantation, NF1-null SLCs formed bona fide neurofibromas with high levels of SOX10 expression. To confirm that SOX10+ SLCs contained the cells of origin for neurofibromas, both Nf1 alleles were inactivated in mouse Sox10+ cells, leading to classic nodular cutaneous and plexiform neurofibroma formation that completely recapitulated their human counterparts. Moreover, we discovered that NF1 loss impaired Schwann cell differentiation by inducing a persistent stem-like state to expand the pool of progenitors required to initiate tumor formation, indicating that, in addition to regulating MAPK-mediated cell growth, NF1 loss also altered Schwann cell differentiation to promote neurofibroma development. Taken together, we established a complementary humanized neurofibroma explant and, to our knowledge, first-in-kind genetically engineered nodular cutaneous neurofibroma mouse models that delineate neurofibroma pathogenesis amenable to future therapeutic target discovery and evaluation.

Authors

Juan Mo, Corina Anastasaki, Zhiguo Chen, Tracey Shipman, Jason Papke, Kevin Yin, David H. Gutmann, Lu Q. Le

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Figure 5

Differentiation into SCPs of hiPSCs with loss of NF1 and TP53.

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Differentiation into SCPs of hiPSCs with loss of NF1 and TP53. (A and B)...
(A and B) TP53 loss was genetically engineered using CRISPR/Cas9 in NF1–/– hiPSCs. Expression of neurofibromin, Cas9, and TP53 was measured by Western blotting. GAPDH was used as an internal loading control. (C) qPCR was performed to measure mRNA levels of TP53 and p21 in NF1–/– sgTP53 hiPSCs. (D) After editing and single-cell clone selection, NF1–/– sgTP53 hiPSCs retained their pluripotency, as verified by the expression of pluripotent markers (NANOG, SOX2, and Oct3/4). However, the SCP marker SOX10 was negative. Differentiation of NF1–/– sgTP53 hiPSCs into SCPs was confirmed by fluorescence staining using SCP markers (SOX10, AP2a, p75, GAP43, and nestin). Scale bar: 50 μm. (E) mRNA levels of the indicated SCP markers were measured. (F) Cell proliferation was compared between NF1–/– sgScr hiPSC-SCPs and NF1–/– sgTP53 hiPSC-SCPs using the CellTiter-Glo assay. Comparisons between groups were performed by 2-way ANOVA. Lum, luminescence. (G and H) mRNA levels of the indicated SCP markers (G) and stem cell markers (H) were compared between NF1–/– sgScr hiPSC-SCPs and NF1–/– sgTP53 hiPSC-SCPs.