Maintenance of caspase-3 proenzyme dormancy by an intrinsic "safety catch" regulatory tripeptide.

Caspase-3 is synthesized as a dormant proenzyme and is maintained in an inactive conformation by an Asp-Asp-Asp "safety-catch" regulatory tripeptide contained within a flexible loop near the large-subunit/small-subunit junction. Removal of this "safety catch" results in substantially enhanced autocatalytic maturation as well as increased vulnerability to proteolytic activation by upstream proteases in the apoptotic pathway such as caspase-9 and granzyme B. The safety catch functions through multiple ionic interactions that are disrupted by acidification, which occurs in the cytosol of cells during the early stages of apoptosis. We propose that the caspase-3 safety catch is a key regulatory checkpoint in the apoptotic cascade that regulates terminal events in the caspase cascade by modulating the triggering of caspase-3 activation.

Gamma-radiation-induced growth arrest and apoptosis in p53-null lymphoma cells is accompanied by modest transcriptional changes in many genes.

Damage to DNA produces cell cycle arrest, apoptosis, or both. The response in cells with p53 tumor suppressor function involves transcriptional changes, but whether that holds for cells lacking active p53, as in most tumors, is not known. Better characterization of the DNA damage response in tumors lacking p53 function is relevant to cytotoxic therapy. We have explored whether gamma-irradiated p53-null mouse T lymphoma cells undergo marked changes in transcription. Their arrest in G2/M prior to apoptosis required transcription. Transcripts whose abundance altered on irradiation were sought by subtractive hybridization, and 1010 candidate clones from two oppositely enriched cDNA populations were sequenced. Hybridization revealed small (<3-fold) increases or decreases in the transcripts of more than 15 genes, including some implicated in cell cycle control (e.g., BTG, Bap1) or apoptosis (e.g., STAT1, calpain), but no marked changes like those associated with other forms of T-cell death. Moreover, the expression of some critical apoptosis regulators, such as Bcl-2 family members, did not change. Hence, the G2/M arrest and apoptosis in the irradiated p53-null lymphoma appears to involve modest expression changes for many genes, but post-transcriptional alterations may be more critical.

Cell death attenuation by 'Usurpin', a mammalian DED-caspase homologue that precludes caspase-8 recruitment and activation by the CD-95 (Fas, APO-1) receptor complex.

Apoptotic cell suicide initiated by ligation of CD95 (Fas/APO-1) occurs through recruitment, oligomerization and autocatalytic activation of the cysteine protease, caspase-8 (MACH, FLICE, Mch5). An endogenous mammalian regulator of this process, named Usurpin, has been identified (aliases for Usurpin include CASH, Casper, CLARP, FLAME-1, FLIP, I-FLICE and MRIT). This protein is ubiquitously expressed and exists as at least three isoforms arising by alternative mRNA splicing. The Usurpin gene is comprised of 13 exons and is clustered within approximately 200 Kb with the caspase-8 and -10 genes on human chromosome 2q33-34. The Usurpin polypeptide has features in common with pro-caspase-8 and -10, including tandem 'death effector domains' on the N-terminus of a large subunit/small subunit caspase-like domain, but it lacks key residues that are necessary for caspase proteolytic activity, including the His and Cys which form the catalytic substrates diad, and residues that stabilize the P1 aspartic acid in substrates. Retro-mutation of these residues to functional caspase counterparts failed to restore proteolytic activity, indicating that other determinants also ensure the absence of catalytic potential. Usurpin heterodimerized with pro-caspase-8 in vitro and precluded pro-caspase-8 recruitment by the FADD/MORT1 adapter protein. Cell death induced by CD95 (Fas/APO-1) ligation was attenuated in cells transfected with Usurpin. In vivo, a Usurpin deficit was found in cardiac infarcts where TUNEL-positive myocytes and active caspase-3 expression were prominent following ischemia/reperfusion injury. In contrast, abundant Usurpin expression (and a caspase-3 deficit) occurred in surrounding unaffected cardiac tissue, suggesting reciprocal regulation of these pro- and anti-apoptotic molecules in vivo. Usurpin thus appears to be an endogenous modulator of apoptosis sensitivity in mammalian cells, including the susceptibility of cardiac myocytes to apoptotic death following ischemia/ reperfusion injury.

A combinatorial approach defines specificities of members of the caspase family and granzyme B. Functional relationships established for key mediators of apoptosis.

There is compelling evidence that members of the caspase (interleukin-1beta converting enzyme/CED-3) family of cysteine proteases and the cytotoxic lymphocyte-derived serine protease granzyme B play essential roles in mammalian apoptosis. Here we use a novel method employing a positional scanning substrate combinatorial library to rigorously define their individual specificities. The results divide these proteases into three distinct groups and suggest that several have redundant functions. The specificity of caspases 2, 3, and 7 and Caenorhabditis elegans CED-3 (DEXD) suggests that all of these enzymes function to incapacitate essential homeostatic pathways during the effector phase of apoptosis. In contrast, the optimal sequence for caspases 6, 8, and 9 and granzyme B ((I/L/V)EXD) resembles activation sites in effector caspase proenzymes, consistent with a role for these enzymes as upstream components in a proteolytic cascade that amplifies the death signal.

Inhibitor-induced changes in the intrinsic fluorescence of human cyclooxygenase-2.

The steady state tryptophan fluorescence of apo-human cyclooxygenase-2 (hCox-2) is quenched approximately 40%-50% by the slow binding inhibitors diclofenac, indomethacin, ketoprofen, NS-398, and DuP-697. The effects of these inhibitors on tryptophan fluorescence are both time and concentration dependent. Addition of each inhibitor results in a rapid fluorescence decrease, followed by a slower time dependent quenching. The slow, time dependent loss of fluorescence follows first-order kinetics, the rate constants for the process increasing with inhibitor concentration in a saturation-type manner. The rapid fluorescence loss also increases with increasing inhibitor concentration in the same manner. These results are consistent with the initial formation of a rapid equilibrium complex of enzyme and inhibitor (EI), followed by the slower formation of a tightly bound enzyme-inhibitor complex (EI*). The fluorescence of the EI complex is not significantly different from that of the EI* complex. The kinetic parameters of each inhibitor derived for this process (Ki and kon) are close to those obtained by determination of the rate constants for the onset of enzyme inhibition, thereby linking the fluorescence changes with inhibitor binding. The reversible inhibitors ibuprofen and docosahexaenoic acid do not quench the protein fluorescence but do decrease both the rate of the slow fluorescence loss and the magnitude of the initial rapid fluorescence decrease caused by the slow binding inhibitors, consistent with their competitive behavior. ASA-acetylated apo-hCox-2 shows the same fluorescence-quenching behavior in the presence of most of the above inhibitors. However, acetylation apparently blocks the binding of diclofenac, whereas the affinity of ibuprofen is increased. The effects of the collisional quenching agents iodide and acrylamide on both the native and inhibited enzyme are small (< 20% quenching at 0.3 M), showing that inhibitor binding does not result in an increased solvent accessibility of protein tryptophans. The cause of the inhibitor-induced quenching of the intrinsic apo-hCox-2 fluorescence is likely energy transfer to the bound inhibitor. Calculations based on the inhibitor-tryptophan distances in ovine Cox-1 indicate that the distances are within the required range for significant quenching to occur.