We describe here the characterization of the so far identified human DNase I family DNases, DNase I, DNase X, DNase gamma, and DNAS1L2. The DNase I family genes are found to be expressed with different tissue specificities and suggested to play unique physiological roles. All the recombinant DNases are shown to be Ca(2+)/Mg(2+)-dependent endonucleases and catalyze DNA hydrolysis to produce 3'-OH/5'-P ends. High activities for DNase I, DNase X, and DNase gamma are observed under neutral conditions, whereas DNAS1L2 shows its maximum activity at acidic pH. These enzymes have also some other peculiarities: different sensitivities to G-actin, aurintricarboxylic acid, and metal ions are observed. Using a transient expression system in HeLa S3 cells, the possible involvement of the DNases in apoptosis was examined. The ectopic expression of each DNase has no toxic effect on the host cells; however, extensive DNA fragmentation is observed only in DNase gamma-transfected cells after the induction of apoptosis. Furthermore, DNase gamma is revealed to be located at the perinuclear region in living cells, and to translocate into the nucleus during apoptosis. Our results demonstrate that DNase I, DNase X, DNase gamma, and DNAS1L2 have similar but unique endonuclease activities, and that among DNase I family DNases, DNase gamma is capable of producing apoptotic DNA fragmentation in mammalian cells.
Analyses of cleavage ends of DNA fragments in apoptotic rat thymocytes induced by gamma-ray irradiation or by treatment with dexamethasone revealed that in both cases the fragments produced had 3'-hydroxyl (OH) and 5'-phosphoryl (P) ends of DNA chains. Rat thymocyte nuclei contained at least three endonuclease activities (deoxyribonucleases alpha, beta and gamma) that were able to cleave chromatin to mononucleosomal and oligonucleosomal fragments. The nuclei of apoptotic rat thymocytes induced by gamma-ray irradiation or dexamethasone retained considerable deoxyribonuclease gamma activity, but not alpha or beta deoxyribonuclease activity. During the induction of apoptosis, treatment with cycloheximide, which suppressed apoptosis, resulted in marked decreases of deoxyribonucleases alpha and beta activities. After release of cycloheximide inhibition, DNA fragmentation associated with apoptosis occurred in the cycloheximide-treated thymocyte nuclei, in which deoxyribonuclease gamma activity was only observed. The purified deoxyribonucleases alpha and beta were divalent cation-independent acidic endonucleases, which were separated on a CM5PW column by HPLC. The molecular masses of deoxyribonucleases alpha and beta were 28 kDa and 30 kDa, respectively, as determined by TSK G-2000SW gel-filtration HPLC, and both were 32 kDa in molecular mass as determined by SDS/PAGE. In contrast, deoxyribonuclease gamma, a neutral endonuclease, required both Ca2+ and Mg2+ for full activity and was inhibited by Zn2+. The molecular mass of deoxyribonuclease gamma was 31 kDa and 33 kDa when measured by gel filtration and SDS/PAGE, respectively. Under these optimal conditions, deoxyribonuclease gamma was shown to produce 3'-OH/5'-P ends of nucleosomal DNA fragments, while deoxyribonucleases alpha and beta both formed DNA fragments with 3'-P/5'-OH ends. The ends formed by cleavage with deoxyribonuclease gamma were the same as those produced in apoptotic rat thymocytes. On the basis of these results, it seems likely that deoxyribonuclease gamma is responsible for internucleosomal cleavage of chromatin during thymic apoptosis.
An endonuclease named DNase gamma has been purified from the nuclei of apoptotic rat thymocytes [Shiokawa, Ohyama, Yamada and Tanuma (1997) Biochem. J. 326, 675-681]. Here we report the molecular cloning of a cDNA encoding a 35 kDa precursor protein for rat DNase gamma. A 1.6 kb mRNA coding for the DNase gamma precursor is detected at high levels in spleen, lymph nodes, thymus and liver. By using reverse transcriptase-mediated PCR, expression of DNase gamma mRNA is observed in kidney and testis but not in brain or heart. Analysis of recombinant DNase gamma reveals that full-length DNase gamma, including the N-terminal precursor, is an inactive proenzyme. The mature form of recombinant DNase gamma, from which the N-terminal precursor has been removed, has the same properties as purified DNase gamma: requirement for divalent cations, dependence on pH, sensitivity to Zn2+, and cleavage of chromosome DNA to nucleosomal units. In HeLa S3 cells stably transfected with the DNase gamma cDNA, exogenously introduced DNase gamma is activated by apoptotic stimuli; enhancement of DNA fragmentation, chromatin condensation and nuclear collapse are observed. These findings provide evidence for the involvement of DNase gamma in DNA fragmentation and nuclear structural changes during apoptosis.
Nucleosomal DNA fragmentation is detected in myoblasts only when apoptosis is induced under differentiating conditions. However, the molecular mechanisms and the DNase responsible for the differentiation-dependent apoptotic DNA laddering are poorly understood. Here we show that a Ca 2؉ /Mg 2؉ -dependent endonuclease, DNase ␥, is induced in C2C12 myoblasts during myogenic differentiation and catalyzes apoptotic DNA fragmentation in differentiating myoblasts. A Ca 2؉ /Mg 2؉ -dependent, Zn 2؉ -sensitive endonuclease activity appears in C2C12 myoblasts during myogenic differentiation. The enzymatic properties of the inducible DNase were found to be quite similar to those of DNase I family of DNases. Reverse transcriptase-PCR analysis revealed that the induction of DNase ␥, a member of the DNase I family of DNases, is correlated with the appearance of inducible DNase activity. The induction of DNase ␥ occurs simultaneously with myogenin induction but precedes the up-regulation of p21. A high level of DNase ␥ expression was also detected in differentiated myotubes but not in skeletal muscle fibers in which DNase X is highly expressed. The role of DNase ␥ in myoblast apoptosis was evaluated in the following experiments. Proliferating myoblasts acquire DNA ladder producing ability by the ectopic expression of DNase ␥, but not DNase X, suggesting that the expression level of DNase ␥ is the determinant of the differentiation-dependent apoptotic DNA laddering observed in myoblasts. DNA fragmentation during differentiation-induced apoptosis is strongly suppressed by the antisensemediated down-regulation of DNase ␥. Importantly, the extent of DNA laddering is well correlated with the level of endogenous DNase ␥ activity. Our data demonstrate that DNase ␥ is the endonuclease responsible for DNA fragmentation in apoptosis associated with myogenic differentiation.
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