TY - JOUR
T1 - Human pontine glioma cells can induce murine tumors
AU - Caretti, Viola
AU - Sewing, A. Charlotte P.
AU - Lagerweij, Tonny
AU - Schellen, Pepijn
AU - Bugiani, Marianna
AU - Jansen, Marc H.A.
AU - van Vuurden, Dannis
AU - Navis, Anna C.
AU - Horsman, Ilona
AU - Vandertop, William P.
AU - Noske, David P.
AU - Wesseling, Pieter
AU - Kaspers, Gertjan J.L.
AU - Nazarian, Javad
AU - Vogel, Hannes
AU - Hulleman, Esther
AU - Monje, Michelle
AU - Wurdinger, Thomas
N1 - Funding Information:
Acknowledgments We would like to thank the patients and families who so generously donated tissue for this research. We sincerely thank the architect and artist Alessandra luoni for drawing Fig. 1a. We gracefully acknowledge Alyssa Noll (Departments of Neurology and Pediatrics) for support with animal experiments, and Patty lovelace (FACS Core) for her expertise with flow cytometry experiments; all from Stanford, USA. The flow cytometer used was purchased using an NIH S10 Shared Instrumentation grant (1S10rr02933801). We are thankful to Jacqueline Cloos (Department of Pediatric Oncology, VU University Medical Center, The Netherlands) and Dana Bangs (Cytogenetics laboratory, Stanford, USA) for their mastery in analyzing metaphase spreads. We are also thankful to Sridevi Yadavilli for processing postmortem specimens and assisting in murine injections, research Center for genetic Medicine, Children’s National Medical Center, Washington, USA. This work was supported by the Semmy Foundation, KiKa Children Cancer Free, Child Health research Institute, lucile Packard Foundation for Children’s Health, as well as the Stanford CTSA—award number Ul1 Tr000093—(V.C.), Stanford University School of Medicine Dean’s Fellowship (V.C.), National Institutes of Neurological Disease and Stroke (NINDS grant K08NS070926), Alex’s lemonade Stand Foundation, McK-enna Claire Foundation, The Cure Starts Now, lyla Nsouli Foundation, Connor Johnson Memorial Fund, Dylan Jewett Memorial Fund, Dylan Frick Memorial Fund, Abigail Jensen Memorial Fund, Zoey ganesh Memorial Fund, Wayland Villars Memorial Fund and Musella Foundation.
PY - 2014
Y1 - 2014
N2 - Diffuse intrinsic pontine glioma (DIPG), with a median survival of only 9 months, is the leading cause of pediatric brain cancer mortality. Dearth of tumor tissue for research has limited progress in this disease until recently. New experimental models for DIPG research are now emerging. To develop preclinical models of DIPG, two different methods were adopted: cells obtained at autopsy (1) were directly xenografted orthotopically into the pons of immunodeficient mice without an intervening cell culture step or (2) were first cultured in vitro and, upon successful expansion, injected in vivo. Both strategies resulted in pontine tumors histopathologically similar to the original human DIPG tumors. However, following the direct transplantation method all tumors proved to be composed of murine and not of human cells. This is in contrast to the indirect method that included initial in vitro culture and resulted in xenografts comprising human cells. Of note, direct injection of cells obtained postmortem from the pons and frontal lobe of human brains not affected by cancer did not give rise to neoplasms. The murine pontine tumors exhibited an immunophenotype similar to human DIPG, but were also positive for microglia/macrophage markers, such as CD45, CD68 and CD11b. Serial orthotopic injection of these murine cells results in lethal tumors in recipient mice. Direct injection of human DIPG cells in vivo can give rise to malignant murine tumors. This represents an important caveat for xenotransplantation models of DIPG. In contrast, an initial in vitro culture step can allow establishment of human orthotopic xenografts. The mechanism underlying this phenomenon observed with direct xenotransplantation remains an open question.
AB - Diffuse intrinsic pontine glioma (DIPG), with a median survival of only 9 months, is the leading cause of pediatric brain cancer mortality. Dearth of tumor tissue for research has limited progress in this disease until recently. New experimental models for DIPG research are now emerging. To develop preclinical models of DIPG, two different methods were adopted: cells obtained at autopsy (1) were directly xenografted orthotopically into the pons of immunodeficient mice without an intervening cell culture step or (2) were first cultured in vitro and, upon successful expansion, injected in vivo. Both strategies resulted in pontine tumors histopathologically similar to the original human DIPG tumors. However, following the direct transplantation method all tumors proved to be composed of murine and not of human cells. This is in contrast to the indirect method that included initial in vitro culture and resulted in xenografts comprising human cells. Of note, direct injection of cells obtained postmortem from the pons and frontal lobe of human brains not affected by cancer did not give rise to neoplasms. The murine pontine tumors exhibited an immunophenotype similar to human DIPG, but were also positive for microglia/macrophage markers, such as CD45, CD68 and CD11b. Serial orthotopic injection of these murine cells results in lethal tumors in recipient mice. Direct injection of human DIPG cells in vivo can give rise to malignant murine tumors. This represents an important caveat for xenotransplantation models of DIPG. In contrast, an initial in vitro culture step can allow establishment of human orthotopic xenografts. The mechanism underlying this phenomenon observed with direct xenotransplantation remains an open question.
KW - Neoplasms
KW - microglia
KW - Pontine Neoplasms
KW - Animal Disease Model
UR - http://www.scopus.com/inward/record.url?scp=84901624624&partnerID=8YFLogxK
U2 - 10.1007/s00401-014-1272-4
DO - 10.1007/s00401-014-1272-4
M3 - Article
SN - 0001-6322
VL - 127
SP - 897
EP - 909
JO - Acta Neuropathologica
JF - Acta Neuropathologica
IS - 6
ER -