The metabolism of histone fractions. VI. Differences in the phosphorylation of histone fractions during the cell cycle

Phosphorylation of histone fractions in the presence and absence of DNA synthesis was measured using the new “isoleucine-limiting” method for synchronizing Chinese hamster cells in early G₁-phase. Using preparative electrophoresis, histone f1 phosphorylation was found to be dependent upon cell-cycle position, being absent in G₁-arrested and G₁-traversing cells and active in the S-phase. The absence of f1 phosphorylation in G₁-arrested cells, which are known to exhibit f1 turnover, indicates that f1 phosphorylation is not an obligatory part of the f1 turnover process. In contrast to histone f1, it was found that histone f2a2 phosphorylation is independent of cell-cycle position, occurring with equal magnitude in the G₁-traversing state when DNA synthesis is essentially absent and in the S-phase when DNA synthesis is active. When cells were arrested in the G₁-state by isoleucine deprivation, f2a2 phosphorylation continued to be active, occurring at 56% of the rate observed in the G₁-traversing state. These results indicate that phosphorylation of histone f2a2 is independent of f2a2 synthesis, independent of DNA synthesis, and independent of histone f1 phosphorylation. Because f2a2 is actively phosphorylated in G₁-arrested cells known to be active in the synthesis of various types of RNA (including messenger) as well as in G₁-traversing and S-phase cells, we feel that phosphorylation of histone f2a2 should continue to be considered in models concerning activation of DNA template activity.