Development of induced glioblastoma by implantation of a human xenograft in Yucatan minipig as a large animal model.

BACKGROUND: Glioblastoma is the most common and deadliest primary brain tumor for humans. Despite many efforts toward the improvement of therapeutic methods, prognosis is poor and the disease remains incurable with a median survival of 12-14.5 months after an optimal treatment. To develop novel treatment modalities for this fatal disease, new devices must be tested on an ideal animal model before performing clinical trials in humans. NEW METHOD: A new model of induced glioblastoma in Yucatan minipigs was developed. Nine immunosuppressed minipigs were implanted with the U87 human glioblastoma cell line in both the left and right hemispheres. Computed tomography (CT) acquisitions were performed once a week to monitor tumor growth. RESULTS: Among the 9 implanted animals, 8 minipigs showed significant macroscopic tumors on CT acquisitions. Histological examination of the brain after euthanasia confirmed the CT imaging findings with the presence of an undifferentiated glioma. COMPARISON WITH EXISTING METHOD: Yucatan minipig, given its brain size and anatomy (gyrencephalic structure) which are comparable to humans, provides a reliable brain tumor model for preclinical studies of different therapeutic METHODS: in realistic conditions. Moreover, the short development time, the lower cyclosporine and caring cost and the compatibility with the size of commercialized stereotactic frames make it an affordable and practical animal model, especially in comparison with large breed pigs. CONCLUSION: This reproducible glioma model could simulate human anatomical conditions in preclinical studies and facilitate the improvement of novel therapeutic devices, designed at the human scale from the outset.

Expression of CYP2R1 and VDR in human brain pericytes: the neurovascular vitamin D autocrine/paracrine model.

1,25 Dihydroxyvitamin D3 (1,25D) is a hormone produced from vitamin D through two hydroxylating steps catalyzed successively in the liver by the vitamin D 25-hydroxylase Cyp2R1 and in the kidney by the 25-hydroxyvitamin D3 1α-hydroxylase Cyp27B1. 1,25D behaves like a steroid hormone. It regulates gene transcription by interacting with a nuclear receptor named vitamin D receptor (VDR) for the vitamin D receptor. Although the role of vitamin D is historically related to rickets, its physiological function largely encompasses bone tissues. Accumulating evidence has indicated that 1,25D can also be considered a neurosteroid. For example, both VDR and CYP27B1 are expressed in brain cells. Similarly, the neuroprotective and anti-inflammatory potential of 1,25D in nervous tissue has been shown experimentally. The regulation of Cyp27B1, which catalyzes the last step of 1,25D synthesis, by the inflammatory cytokines tumor necrosis factor-α and interferon-γ has been reported recently. However, the fate of Cyp2R1 that catalyzes the first enzymatic reaction of the vitamin D metabolism has not received attention. Using human brain pericytes, we studied the expression of CYP2R1 and VDR genes when these cells were challenged to an inflammatory stimulus. We found a significant upregulation of these two genes in human brain pericytes challenged with tumor necrosis factor-α and interferon-γ. These results suggest the existence of an autocrine/paracrine vitamin D system in the neurovascular unit. The function of this novel signaling system might be critical in the control of neuroinflammation and in brain pathologies.

Brain mesenchymal stem cells: The other stem cells of the brain?

Multipotent mesenchymal stromal cells (MSC), have the potential to differentiate into cells of the mesenchymal lineage and have non-progenitor functions including immunomodulation. The demonstration that MSCs are perivascular cells found in almost all adult tissues raises fascinating perspectives on their role in tissue maintenance and repair. However, some controversies about the physiological role of the perivascular MSCs residing outside the bone marrow and on their therapeutic potential in regenerative medicine exist. In brain, perivascular MSCs like pericytes and adventitial cells, could constitute another stem cell population distinct to the neural stem cell pool. The demonstration of the neuronal potential of MSCs requires stringent criteria including morphological changes, the demonstration of neural biomarkers expression, electrophysiological recordings, and the absence of cell fusion. The recent finding that brain cancer stem cells can transdifferentiate into pericytes is another facet of the plasticity of these cells. It suggests that the perversion of the stem cell potential of pericytes might play an even unsuspected role in cancer formation and tumor progression.