Histone H1 quantity determines the efficiency of chromatin condensation in both apoptotic and live cells.

Although chromatin condensation is a well-known hallmark of apoptosis, the generation mechanism has not been clarified. Histone H1, a positively-charged abundant nuclear protein, is located in the linker region of chromatin. There are several Histone H1 subtypes that are encoded by variant genes. Using serial histone H1-deletion mutant cells established from the chicken B-cell leukemia line DT40, we found that apoptotic chromatin condensation was decreased in relation to histone H1 protein level and that the chromatin in nuclei prepared from the live null mutant cells had a high accessibility of DNases and transposase. This indicated that linker histone H1 was the general chromatin condensation factor and that the loss of histone H1 generated open chromatin in both apoptotic and live cells.

Histone H1 quantity determines the efficiencies of apoptotic DNA fragmentation and chromatin condensation.

Oligonucleosomal DNA fragmentation and chromatin condensation are two hallmarks of apoptosis. However, their generation mechanisms are not entirely understood. Histone H1, a positively charged nuclear protein located in the linker region of chromatin, is involved in higher-order chromatin structures and tight chromatin packing. On the basis of the physical and biochemical characteristics of histone H1, we hypothesized that histone H1 plays a role in determining the efficiencies of apoptotic DNA fragmentation and chromatin condensation. Therefore, we examined histone H1 quantity in five human leukemia cell lines and compared the efficiencies. The cell lines were categorized into two groups according to their origins: (i) Ramos and Molt-4 cells of lymphoid origin and (ii) U937, ML-1, and HL60 cells of myeloid origin. Compared to the lymphoid-origin group, the myeloid-origin group had lower levels of histone H1 but more open chromatin. Furthermore, the myeloid-origin group showed marked DNA fragmentation but less chromatin condensation during apoptosis. These results suggested that histone H1 determined chromatin structure and that its quantity affected the efficiencies of DNA fragmentation and chromatin condensation in apoptosis.

DNase γ, DNase I and caspase-activated DNase cooperate to degrade dead cells.

Serum endonucleases are essential for degrading the chromatin released from dead cells and preventing autoimmune diseases such as systemic lupus erythematosus. Serum DNase I is known as the major endonuclease, but recently, another endonuclease, DNase γ/DNase I-like 3, gained attention. However, the precise role of each endonuclease, especially that of DNase γ, remains unclear. In this study, we distinguished the activities of DNase γ from those of DNase I in mouse serum and concluded that both cooperated in degrading DNA during necrosis: DNase γ functions as the primary chromatolytic activity, causing internucleosomal DNA fragmentation, and DNase I as the secondary one, causing random DNA digestion for its complete degradation. These results were confirmed by two in vivo experimental mouse models, in which necrosis was induced, acetaminophen-induced hepatic injury and streptozotocin-induced ß-cell necrosis models. We also determined that DNase γ functions as a backup endonuclease for caspase-activated DNase (CAD) in the secondary necrosis phase after γ-ray-induced apoptosis in vivo.