Conformational modification of serpins transforms leukocyte elastase inhibitor into an endonuclease involved in apoptosis.

The best-characterized biochemical feature of apoptosis is degradation of genomic DNA into oligonucleosomes. The endonuclease responsible for DNA degradation in caspase-dependent apoptosis is caspase-activated DNase. In caspase-independent apoptosis, different endonucleases may be activated according to the cell line and the original insult. Among the known effectors of caspase-independent cell death, L-DNase II (LEI [leukocyte elastase inhibitor]-derived DNase II) has been previously characterized by our laboratory. We have thus shown that this endonuclease derives from the serpin superfamily member LEI by posttranslational modification (A. Torriglia, P. Perani, J. Y. Brossas, E. Chaudun, J. Treton, Y. Courtois, and M. F. Counis, Mol. Cell. Biol. 18:3612-3619, 1998). In this work, we assessed the molecular mechanism involved in the change in the enzymatic activity of this molecule from an antiprotease to an endonuclease. We report that the cleavage of LEI by elastase at its reactive center loop abolishes its antiprotease activity and leads to a conformational modification that exposes an endonuclease active site and a nuclear localization signal. This represents a novel molecular mechanism for a complete functional conversion induced by changing the conformation of a serpin. We also show that this molecular transformation affects cellular fate and that both endonuclease activity and nuclear translocation of L-DNase II are needed to induce cell death.

Acid DNases and their interest among apoptotic endonucleases.

Apoptosis is characterized by cell shrinkage, nuclear condensation and internucleosomal DNA cleavage. Besides the central role of caspases and other proteases, cell death triggers DNA degradation so that DNases have an active role in apoptotic cell death. The best-characterized apoptotic DNase is CAD, a neutral Mg-dependent endonuclease. Its activity is regulated by its inhibitor, ICAD, which is cleaved by caspases. Other neutral DNases have been shown to cleave nuclear DNA in apoptotic conditions: endonuclease G, GADD. In cells, the cytosolic pH is maintained to 7.2, mostly due to the activity of the Na(+)/H(+) exchanger. In many apoptotic conditions, a decrease of the intracellular pH has been shown. This decrease may activate different acid DNases, mostly when pH decreases below 6.5. Three acidic DNases II are so far known: DNase II alpha, DNase II beta and L-DNase II, a DNase II, derived from the serpin LEI (Leukocyte Elastase Inhibitor). Their activation during cell death is discussed in this review.

Effect of apoptogenic stimuli on colon carcinoma cell lines with a different c-myc expression level.

We have recently demonstrated that a high c-myc endogenous amplification level confers an apoptosis-prone phenotype to serum-deprived colon carcinoma SW613-S cells. The aim of this study was to gain new insights into the features of c-myc-dependent apoptosis, by extending our analysis to different apoptogenic stimuli. The study was carried out on clones, derived from the human colon carcinoma SW613-S cell line, which harbor different levels of endogenous c-myc amplification, and on isogenic cell lines with an enforced c-myc overexpression. Our results indicate that cells with endogenous or transfected exogenous c-myc overexpression (SW613-12A1 and -2G1mycP2Tu1 cell lines, respectively), activate the apoptotic machinery in response to the treatment with etoposide, doxorubicin and vitamin D3, which induce apoptosis through the death receptor Fas. The low levels of c-myc expression present in SW613-B3 and -B3mycC5, seem to be unable to activate Fas-mediated apoptosis, thus suggesting that only a high c-myc expression can bypass the lack of Fas receptor. Apoptosis induction mediated by DNA damage and long-term culture was independent of c-myc expression. A pathway of apoptosis characterized by the activation of the enzyme L-DNase II, was observed in both 12A1 and B3 cell lines.