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Hsp90 is a molecular chaperone that is often overexpressed across multiple cancer types and has a potential value as a prognostic marker as well as a therapeutic target. Given the high interest in Hsp90 therapies, positron emission tomography or PET imaging of Hsp90 can be a valuable tool for patient selection. The limitations of the previously developed Hsp90 tracers prompted us to evaluate the recently developed brain-permeable [ 11 C]HSP990 PET probe to advance the development of Hsp90-targeted therapeutics. Given the brain accumulation of [ 11 C]HSP990 probe, application for glioblastoma imaging of this tracer is of particular interest. In vitro [ 11 C]HSP990 binding was assessed in breast cancer and glioma cell lines including patient-derived cells using Hsp90 inhibitors and RNA interference knockdown of Hsp90 isoforms. Saturation binding studies were conducted on these cells and tumour tissue homogenates, and autoradiography was performed on tissue sections. Ex vivo biodistribution and in vivo dynamic µPET/CT studies were performed in healthy mice and tumour-bearing mice, including immunocompromised subcutaneous human U87 and MDA-MB-231models and immunocompetent intracranial murine NS/CT-2A models at baseline and following a pre-treatment with Hsp90 inhibitors. High Hsp90-specific tracer uptake was observed in breast cancer and glioma cells, with Hsp90β inhibition resulting in the most substantial reduction in uptake. In vivo uptake was high in U87 tumours but low in MDA-MB-231, presumably due to the differences in Hsp90 expression in tumour tissue versus cultured cells. Differences in maximum binding capacity or B max across cell and tissue types support this hypothesis, especially given that the affinity measured as dissociation constant K d remained similar across all tissue types. Despite high NS/CT-2A tumour uptake in vitro, no contrast between the healthy brain tissue and the NS/CT-2A glioma was observed in vivo due to the high uptake by the healthy brain. [ 11 C]HSP990 is a promising tracer for identifying Hsp90-overexpressing tumours and may hold potential for patient stratification, prognosis, and therapy monitoring of novel Hsp90 therapeutics. High healthy brain uptake of this tracer precluded the differentiation of the tumour in the intracranial NS/CT-2A tumour model, therefore [ 11 C]HSP990 might not be a suitable tracer for the glioblastoma imaging. Tracer with a longer half-life might be needed to compare the washout of the tracer from the brain and the tumour tissue over several hours to identify a suitable imaging window. The online version contains supplementary material available at 10.1186/s41181-025-00386-z.

Functional cellular heterogeneity in tumours often underlies incomplete response to therapy and relapse. Previously, we demonstrated that the growth of the paediatric brain malignancy, sonic hedgehog subgroup medulloblastoma, is rooted in a dysregulated developmental hierarchy, the apex of which is defined by characteristically quiescent SOX2 + stem-like cells. Integrating gene expression and chromatin accessibility patterns in distinct cellular compartments, we identify the transcription factor Olig2 as regulating the stem cell fate transition from quiescence to activation, driving the generation of downstream neoplastic progenitors. Inactivation of Olig2 blocks stem cell activation and tumour output. Targeting this rare OLIG2-driven proliferative programme with a small molecule inhibitor, CT-179, dramatically attenuates early tumour formation and tumour regrowth post-therapy, and significantly increases median survival in vivo. We demonstrate that targeting transition from quiescence to proliferation at the level of the tumorigenic cell could be a pivotal medulloblastoma treatment strategy. Subject terms: Cancer stem cells, Mechanisms of disease, Cancer therapy

Rabies is a zoonotic neurological infection caused by lyssavirus that continues to result in devastating loss of human life. Many aspects of rabies pathogenesis in human neurons are not well understood. Lack of appropriate ex-vivo models for studying rabies infection in human neurons has contributed to this knowledge gap. In this study, we utilize advances in stem cell technology to characterize rabies infection in human stem cell-derived neurons. We show key cellular features of rabies infection in our human neural cultures, including upregulation of inflammatory chemokines, lack of neuronal apoptosis, and axonal transmission of viruses in neuronal networks. In addition, we highlight specific differences in cellular pathogenesis between laboratory-adapted and field strain lyssavirus. This study therefore defines the first stem cell-derived ex-vivo model system to study rabies pathogenesis in human neurons. This new model system demonstrates the potential for enabling an increased understanding of molecular mechanisms in human rabies, which could lead to improved control methods.