Abstract
Neurons have recently emerged as essential cellular constituents of the tumour microenvironment, and their activity has been shown to increase the growth of a diverse number of solid tumours1. Although the role of neurons in tumour progression has previously been demonstrated2, the importance of neuronal activity to tumour initiation is less clear—particularly in the setting of cancer predisposition syndromes. Fifteen per cent of individuals with the neurofibromatosis 1 (NF1) cancer predisposition syndrome (in which tumours arise in close association with nerves) develop low-grade neoplasms of the optic pathway (known as optic pathway gliomas (OPGs)) during early childhood3,4, raising the possibility that postnatal light-induced activity of the optic nerve drives tumour initiation. Here we use an authenticated mouse model of OPG driven by mutations in the neurofibromatosis 1 tumour suppressor gene (Nf1)5 to demonstrate that stimulation of optic nerve activity increases optic glioma growth, and that decreasing visual experience via light deprivation prevents tumour formation and maintenance. We show that the initiation of Nf1-driven OPGs (Nf1-OPGs) depends on visual experience during a developmental period in which Nf1-mutant mice are susceptible to tumorigenesis. Germline Nf1 mutation in retinal neurons results in aberrantly increased shedding of neuroligin 3 (NLGN3) within the optic nerve in response to retinal neuronal activity. Moreover, genetic Nlgn3 loss or pharmacological inhibition of NLGN3 shedding blocks the formation and progression of Nf1-OPGs. Collectively, our studies establish an obligate role for neuronal activity in the development of some types of brain tumours, elucidate a therapeutic strategy to reduce OPG incidence or mitigate tumour progression, and underscore the role of Nf1mutation-mediated dysregulation of neuronal signalling pathways in mouse models of the NF1 cancer predisposition syndrome.
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Data availability statement
Original western blots are included in the Supplementary Information (supplementary Fig. 1). Human pilocytic astrocytoma RNA-seq data are deposited with the Gene Expression Omnibus under accession number GSE163071. The cell lines and other reagents described here are freely available and can be obtained by contacting the corresponding authors and with a standard materials transfer agreement. Any other relevant data are available from the corresponding authors upon reasonable request. Source data are provided with this paper.
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Acknowledgements
This work was supported by grants from the Department of Defense (W81XWH-15-1-0131 to M.M. and D.H.G., and W81XWH-19-1-0260 to Y.P.), National Institute of Neurological Disorders and Stroke (R01NS092597 to M.M. and R35NS07211 to D.H.G.), NIH Director’s Pioneer Award (DP1NS111132 to M.M.), National Cancer Institute (P50CA165962), National Eye Institute (P30EY026877 to J.L.G. and F32EY029137 to K.-C.C.), Brantley’s Project supported by Ian’s Friends Foundation (to Y.P. and M.M.), Gilbert Family Foundation (to D.H.G. and J.L.G.), Robert J. Kleberg, Jr. and Helen C. Kleberg Foundation (to M.M.), Cancer Research UK (to M.M.), Unravel Pediatric Cancer (to M.M.), McKenna Claire Foundation (to M.M.), Kyle O’Connell Foundation (to M.M.), Virginia and D. K. Ludwig Fund for Cancer Research (to M.M.), Waxman Family Research Fund (to M.M.), Stanford Maternal and Child Health Research Institute (to E.M.G.), Stanford Bio-X Institute (to J.D.H.), Will Irwin Research Fund (to M.M.), Research to Prevent Blindness, Inc. (to J.L.G.) and Alex’s Lemonade Stand Foundation (to Y.P.) The authors thank G. Grant and A. Bet for low-grade glioma samples from the Stanford Center for Childhood Brain Tumors Tissue Bank; C. Gardner from The St. Louis Children’s Hospital Pediatric Tumor Bank (supported by the St. Louis Children’s Hospital Foundation and Children’s Surgical Sciences Institute); and Stanford Animal Histology Services for optic nerve paraffin-block sectioning.
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M.M. and D.H.G. conceived the project. Y.P., J.D.H., T.B., N.F.S., X.G., B.Y., C.A., S.B.M., A.P., S.S., Y.M., K.C.-C., X.X., J.A.T., E.M.G., J.R.H. and J.J.L. conducted experiments. Y.P., M.M. and D.H.G. designed the experiments and wrote the manuscript. Y.P., J.D.H., N.F.S. and Y.M. performed data analyses. O.C. provided statistical expertise and RNA-seq analyses. K.C-C., X.X. and J.L.G. provided vision science expertise and performed PERGs. L.M.L. provided samples of human pilocytic astrocytoma. All authors contributed to manuscript editing. M.M. and D.H.G supervised all aspects of the work.
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M.M. is an SAB member for Cygnal Therapeutics. M.M. is listed as an inventor on a patent (US10377818B2) coordinated through Stanford University related to targeting neuron–glioma interactions for therapy.
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Peer review information Nature thanks Botond Roska, Rosalind Segal and Frank Winkler for their contribution to the peer review of this work. Peer reviewer reports are available.
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Extended data figures and tables
Extended Data Fig. 1 Increased activity of the optic nerve drives growth of Nf1-OPG.
a, Representative fluorescence microscopy images reveal YFP expression within the optic nerve and retina freshly isolated from Thy1::ChR2-YFP, but not wild-type, mice. n = 3 mice from each group were examined with similar results. Scale bar, 30 μm. b, Immunohistochemistry using green fluorescent protein (GFP)- and yellow fluorescent protein (YFP)-specific antibodies reveals YFP expression (green) specifically in the retinal ganglion cells (BRN3A+) (red) of Thy1::ChR2-YFP, but not wild-type, mice. n = 3 mice from each group were examined with similar results. Scale bar, 15 μm. Arrow, cells shown in the inset. GCL, ganglion cell layer, IPL, inner plexiform layer, INL, inner nuclear layer, OPL, outer plexiform layer, ONL, outer nuclear layer. c, Representative Ki67 immunohistochemistry images (arrows indicate Ki67+ cells) and quantification of unstimulated (unstim) (n = 6) and stimulated (stim) (n = 6) Nf1OPG;Thy1::ChR2-YFP mice. Scale bar, 20 μm. Unpaired t-test with Welch’s correction. d, Plotting optic nerve volume against proliferation shows separation between unstimulated and stimulated groups. e, Immunofluorescence images of S100β (red), IBA1 (green) and DAPI (blue) reveal increased per cent of S100β+ (P = 0.005), but not IBA1+ (P = 0.6739), cells in the stimulated group (n = 6 mice), relative to the unstimulated group (n = 5 mice). Unpaired t-test with Welch’s correction. f, PERG performed on Nf1OPG mice raised in regular light cycles (12:12) (n = 6 eyes) or reared in dark (n = 6 eyes) from 6–12 weeks of age. Mann–Whitney test. g, Dark-rearing experimental paradigm. n = 5 (wild type 12:12), 7 (Nf1OPG 12:12), 6 (Nf1OPG dark 6–16 weeks old) and 12 (Nf1OPG dark 6–12 weeks old). Data are mean ± s.e.m. NS, not significant (P > 0.05). Each data point is one mouse in c–e. All tests were two-sided. Illustrations created with BioRender.com (f, g).
Extended Data Fig. 2 Retinal activity during a susceptible period is required for initiation of Nf1-OPG.
a, Representative Ki67 immunohistochemistry (arrows, Ki67+ cells), S100β immunofluorescence (green) and haematoxylin and eosin (H&E) (arrows indicate abnormal nuclei) images. Scale bar, 20 μm. b, Quantification of the per cent of S100β+ cells in Nf1OPG mice reared in regular light cycles (12:12) or dark-reared (24-h darkness) from 6 to 16 or 6 to 12 weeks of age. n = 4 (wild type 12:12), 5 (Nf1OPG 12:12), 5 (Nf1OPG dark 6–16 weeks old) and 5 (Nf1OPG dark 6–12 weeks old) mice. c, Representative immunohistochemistry images (white, BRN3A; blue, DAPI) in the ganglion cell layer, and quantification of per cent BRN3A+ cells in wild-type mice reared in regular light cycles (12:12, n = 5 mice), or dark (24-h darkness, n = 6 mice). P = 0.9307. Scale bar, 10 μm. d, Dark-rearing experimental paradigm with observation until 24 weeks after return to regular light cycles at 12 weeks. Half-yellow and half-grey lightbulbs and yellow bars indicate 12-h light/12-h dark cycles (12:12). Grey lightbulbs and black bars indicate dark-rearing periods (24-h darkness). Arrow, tumour initiation. e, Optic nerve volume (left) and proliferation (per cent Ki67+ cells) (right) of Nf1OPG mice reared in regular light cycles (12:12) or dark-reared (24-h darkness) from 6 to 12 weeks of age and observed until 24 weeks. n = 7 (wild type 12:12), 6 (Nf1OPG 12:12) and 6 (Nf1OPG dark 6–12 weeks old) mice. f, Plotting optic nerve volume against proliferation shows no OPG (tumour) in the dark-reared Nf1OPG mice. Tumour is gated against the maximum volumes and proliferation of 24-week-old wild-type mice. g, IBA1 (green) immunofluorescence images and quantification. Scale bars, 20 μm. n = 4 mice in each group. h, i, Quantification of CD8+ (n = 6 and 4 mice in 12:12 and dark groups, respectively) and PDGFRα+ cell density (n = 5 and 6 mice in 12:12 and dark groups, respectively). Data are mean ± s.e.m. Mann–Whitney test (c). Brown–Forsythe and Welch ANOVA tests with Dunnett’s T3 correction for multiple comparison (b, F = 11.18, P = 0.0071; e, volume, F = 11.19, P = 0.0011). Kruskal–Wallis test with Dunn’s correction for multiple comparisons (e, proliferation, P = 0.0008). Unpaired t-test with Welch’s correction (g–i). NS, not significant (P > 0.05). Each data point is one mouse in b, e–i. Each data point is one eye in c. All tests were two-sided. Illustrations created with BioRender.com (d).
Extended Data Fig. 3 The intrinsic circadian clock associated with constant darkness does not contribute to Nf1-OPG initiation.
a, Entrained dark-rearing paradigm. Half-yellow and half-grey lightbulbs and yellow bars indicate 12-h light/12-h dark cycles (12:12). Grey lightbulbs and dashed black bars indicate entrained dark-rearing periods (24-h darkness with 15 min of light at 07.00 and 19.00). Arrow, tumour initiation. b, Optic nerve volume (left) and proliferation (per cent Ki67+ cells) (right) of Nf1+/− mice (no tumour control, n = 3) and Nf1OPG mice reared in regular light cycles (12:12, n = 5), or dark-reared (entrained) from 6 to 16 weeks of age (n = 7). Kruskal–Wallis test (volume, P = 0.0014; proliferation, P = 0.0005). c, Plotting optic nerve volume against proliferation shows few OPGs (tumours) in entrained dark-reared Nf1OPG mice. Tumour is gated against volume and proliferation of 16-week-old wild-type mice (22 mice raised in regular light cycles; grey regions mark the range of values). d, Representative Ki67 immunohistochemistry images of Nf1+/− mice (no tumour control, n = 3) and Nf1OPG mice reared in regular light cycles (12:12, n = 5), or dark-reared (entrained) from 6 to 16 weeks of age (n = 7). Arrows, Ki67+ cells. Scale bar, 20 μm. NS, not significant (P > 0.05). Each data point is one mouse in b, c. All tests were two-sided. Illustrations created with BioRender.com (a).
Extended Data Fig. 4 Targeting BDNF or TrkB signalling does not prevent formation of Nf1-OPGs.
a, Left, generation of retina + optic nerve explants for collecting secreted proteins in the conditioned medium. Right, retina + optic nerve explant preparations from Nf1+/−;Thy1::ChR2-YFP mice were stimulated by blue light (stim) or unstimulated (unstim) (complete darkness + 1 nM TTX), followed by conditioned medium collection and mass spectrometry measurement of BDNF and NLGN3. Fold changes of BDNF and NLGN3 in the conditioned medium between stimulated and unstimulated conditions are indicated. b, Representative EdU immunofluorescence images of Fig. 2a, showing increased Nf1 optic glioma cell proliferation (EdU incorporation) to increasing concentrations of NLGN3. Scale bar, 25 μm. n = 4 (vehicle (veh)), 3 (10 nM), 3 (30 nM) and 3 (70 nM) wells. c, Increased Nf1 optic glioma cell proliferation (EdU incorporation) to 70 nM NLGN1 (n = 3 wells), NLGN2 (n = 4 wells), NLGN3 (n = 7 wells) and BDNF (n = 3 wells), relative to vehicle (n = 8 wells for NLGN1, NLGN2 and NLGN3 and 3 wells for BDNF). d, Entrectinib (ent) treatment paradigm. Blue bar, time intervals when entrectinib was administered. Arrow, tumour initiation. e, Optic nerve volume (left) (P = 0.8690) and proliferation (per cent Ki67+ cells) (right) (P = 0.4536) of Nf1OPG + vehicle (n = 3), and Nf1OPG + entrectinib (n = 6) groups. f, Plotting optic nerve volume against proliferation shows OPG (tumour) in all Nf1OPG + entrectinib mice. Tumour is gated against volume and proliferation of 16-week-old wild-type mice (22 mice raised in regular light cycles; grey regions mark the range of values). Unpaired t-test with Welch’s correction (c, BDNF; e, proliferation). Brown-Forsythe and Welch ANOVA tests with Dunnett’s T3 correction for multiple comparison (c, NLGN1, NLGN2 and NLGN3, F = 44.85, P < 0.0001). Mann–Whitney test (e, volume). Data are mean ± s.e.m. NS, not significant (P > 0.05). Each data point is one well in c. Each data point is one mouse in e, f. All tests were two-sided. Illustrations created with BioRender.com (a).
Extended Data Fig. 5 NLGN3 expression analyses in human pilocytic astrocytomas.
a, qRT–PCR using Washington University School of Medicine (WUSM) samples reveals increased NLGN3 levels in NF1-associated pilocytic astrocytoma (NF1-PA) (n = 9); NLGN3 levels were not significantly increased in sporadic pilocytic astrocytoma (S-PA) in this dataset (n = 14), relative to non-neoplastic brain controls (NB) (n = 9); the same non-neoplastic brain cases are shown in each comparison). These results should be considered in the context of the larger dataset presented in b and the cases presented in Fig. 2e. b, NLGN3 expression of a previously published microarray dataset (GSE44971)21 reveals increased NLGN3 levels in pilocytic astrocytoma (n = 49), relative to non-neoplastic brain controls (n = 9). Red dots, NF1-associated pilocytic astrocytomas. c, No association between NLGN3 expression and sex, location or age was observed in the pilocytic astrocytoma RNA-seq dataset. From left to right, n = 6, 3, 6, 4, 4, 5, 6, 4, 4, 5, 6 and 4 samples. d, NLGN3 expression of the previously published microarray dataset21 reveals increased NLGN3 levels in all methylation groups, pilocytic astrocytomas located in cerebellum and diencephalon, relative to non-neoplastic brains. From left to right, n = 9, 12, 28, 9, 9, 35, 5, 6 and 3 samples. e, GO terms and differentially expressed genes in NLGN3-high and NLGN3-low groups from the pilocytic astrocytoma RNA-seq database. f, Gene set enrichment analysis reveals neuronal and immune signatures in NLGN3-high and NLGN3-low pilocytic astrocytomas, respectively. Mann–Whitney test (a, NB versus NF1-PA). Unpaired t-test with Welch’s correction (a, NB versus S-PA; b). Brown–Forsythe and Welch ANOVA tests with Dunnett’s T3 correction for multiple comparison (c, all comparisons are not statistically significant; d, methylation, F = 11.71, P = 0.0001; d, location, F = 23.48, P < 0.0001). Data are mean ± s.e.m. Each data point is one human sample in a–d. All tests were two-sided.
Extended Data Fig. 6 Optogenetic stimulation of retina + optic nerve explants.
a, Immunoblotting of retina + optic nerve tissues reveals no change in cleaved caspase-3 (CC3) levels (normalized to the amount of total caspase-3 (Cas-3)) between the unstimulated (unstim) and stimulated (stim) groups. n = 3 mice. P = 0.8938. b, Immunoblotting reveals the same levels of shed NLGN3 (s-NLGN3) in the conditioned medium of unstimulated Nf1+/+;Thy1::ChR2 (n = 6 mice) and Nf1+/−;Thy1::ChR2 (n = 6 mice) retina + optic nerve explants. c, Immunoblotting of optic nerve lysate reveals same levels of shed NLGN3 in dark-reared wild-type (n = 3) and Nf1+/− (n = 5) mice. d, ADAM10-mediated NLGN3 shedding. e, Immunoblotting reveals reduced shed NLGN3 levels in optic nerves of Nf1+/− mice after treatment with the ADAM10 inhibitor (ADAM10i) (GI254023X) (n = 4 mice), relative to vehicle (n = 3 mice) treatment. f, Immunoblotting of conditioned medium reveals increased ADAM10 in light-stimulated Nf1+/−;Thy1::ChR2 (left) (n = 7 mice), but not Nf1+/+;Thy1::ChR2 (right) (n = 3 mice), retina + optic nerve explants relative to their unstimulated (dark + TTX) counterparts. ns, not significant. Data are mean ± s.e.m. Wilcoxon test (a, f). Unpaired t-test with Welch’s correction (b, c, e). Each data point is one mouse in a–c, e, f. All tests were two-sided. Illustrations created with BioRender.com (d).
Extended Data Fig. 7 Targeting NLGN3 shedding prevents Nf1-OPG proliferation.
a, Representative Ki67 immunohistochemistry images of wild-type + vehicle (n = 3), Nf1OPG + vehicle 6–16 weeks old (n = 7) and Nf1OPG + ADAM10i 6–16 weeks old (n = 9) groups. b, Representative Ki67 immunohistochemistry images of Nf1OPG + vehicle (n = 9) and Nf1OPG + ADAM10i 12–16 weeks old (n = 8) groups. Arrows, Ki67+ cells. Scale bar, 20 μm.
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Pan, Y., Hysinger, J.D., Barron, T. et al. NF1 mutation drives neuronal activity-dependent initiation of optic glioma. Nature 594, 277–282 (2021). https://doi.org/10.1038/s41586-021-03580-6
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DOI: https://doi.org/10.1038/s41586-021-03580-6
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