HGG-31. HISTONE H3.3 G34R/V MUTATIONS STIMULATE PEDIATRIC HIGH-GRADE GLIOMA FORMATION THROUGH THE INDUCTION OF CHROMOSOMAL INSTABILITY

The histone H3.3 G34R/V mutations are known drivers of high-grade pediatric glioma (pHGG). However, the mechanism(s) for H3.3 G34R/V induced tumor formation are unclear. Chk1 phosphorylates H3.3 S31 at the pericentromere during early mitosis, suggesting a novel mitotic function. We observed that H3.3 G34 mutant pHGG cells have reduced mitotic H3.3 S31 phosphorylation compare to WT H3.3 cell lines. The H3.3 G34R mutation reduced Chk1 phosphorylation at S31 by >90% in an in vitro kinase assay. Overexpression of either H3.3 G34R or non-phosphorylatable S31A in H3.3 WT, diploid cells led to a significant increase in chromosome mis-segregations. Likewise, H3.3 G34 mutant pHGG cells have significantly elevated rates of mis-segregation as compare to H3.3 WT pHGG cells. During normal cell division, phospho-S31 is lost in late anaphase. However, when chromosome missegregation occurs, phospho-S31 spreads and stimulates p53 accumulation in G1 – thus suppressing aneuploid cell proliferation. Here we show that cells expressing mutant G34 fail to arrest following mis-segregation, despite having WT p53. These studies demonstrate that the H3.3 G34R/V mutations are sufficient to transform normal, diploid cells into proliferative, chromosomally instable cells. To determine if this process contributes to tumorigenesis, we used the RCAS/TVA mouse model to overexpress H3.3 WT, G34R, or S31A in the glial precursor cells of mice pups. Over 100 days, S31A and G34R mice had drastically reduced survival (averaging 77, 81, and 100 days for S31A, G34R, and WT mice). Furthermore, most G34R and S31A mice developed HGG, while H3.3 WT mice remained tumor-free and did not develop high-grade tumors. Our work strongly indicates that a major factor in H3.3 G34R pHGG formation is the induction of chromosomal instability – which occurs directly through the suppression of H3.3 S31 phosphorylation.