The role of the BRCA1-mediated DNA damage repair pathway in regulating human brain development remains unknown, although it has been studied in mouse development. We report evidence for breast cancer type 1 susceptibility protein (BRCA1) being a molecular correlate of proliferation in human neural progenitor cells and in medulloblastoma (MB), a malignant pediatric hindbrain cancer whose cells resemble undifferentiated neural stem cells. In a computational search for molecules potentially keeping Group 3 (G3) and Group 4 (G4) MB tumour cells in a state of stalled differentiation, BRCA1 emerged as a leading candidate gene. We surveyed four independent transcriptomic datasets collectively spanning 142 human developing brain samples, multiple brain regions, and over 1.7 million single cells, and found that BRCA1 transcription is consistently enriched in human neural stem and progenitor cells, relative to differentiating or mature neurons. Across the human lifespan, BRCA1 expression is enriched in the brain during early development, particularly the first trimester of gestation. By analyzing 714 tumours, the largest transcriptomic survey of MB tumours to date, we found that BRCA1 expression is increased in carriers of isochromosome 17q (i17q) aberrations and in G4 MB tumours. Increased BRCA1 expression is associated with worse prognosis in G3 and G4 MB. In the developing cerebellum as well as in the cancer context, BRCA1 expression is correlated with transcription of the cell cycle and DNA damage repair pathways. When considered with previous mouse studies, our work is consistent with a model in which BRCA1 promotes genome surveillance in neural progenitors during human brain development and in G3 and G4 MB tumour growth, thus supporting proliferation.