Signal-induced activation of caspases, the critical protease effectors of apoptosis, requires proteolytic processing of their inactive proenzymes. Consequently, regulation of procaspase processing is critical to apoptotic execution. We report here that baculovirus pancaspase inhibitor P35 and inhibitor of apoptosis Op-IAP prevent caspase activation in vivo, but at different steps. By monitoring proteolytic processing of endogenous Sfcaspase-1, an insect group II effector caspase, we show that Op-IAP blocked the first activation cleavage at TETD2G between the large and small caspase subunits. In contrast, P35 failed to affect this cleavage, but functioned downstream to block maturation cleavages (DXXD2(G/A)) of the large subunit. Substitution of P35's reactive site residues with TETDG failed to increase its effectiveness for blocking TETD2G processing of proSf-caspase-1, despite wild-type function for suppressing apoptosis. These data are consistent with the involvement of a novel initiator caspase that is resistant to P35, but directly or indirectly inhibitable by Op-IAP. The conservation of TETD2G processing sites among insect effector caspases, including Drosophila drICE and DCP-1, suggests that in vivo activation of these group II caspases involves a P35-insensitive caspase and supports a model wherein apical and effector caspases function through a proteolytic cascade to execute apoptosis in insects.The caspases are critical protease mediators of apoptosis and thus represent important targets for anti-apoptotic intervention (reviewed in Refs. 1-4). These highly conserved, aspartate-specific proteases are expressed as single-chain zymogens, which upon apoptotic signaling are activated by proteolytic processing, either by autoactivation, transactivation, or cleavage by other caspases (reviewed in Refs. 5 and 6). Once activated, the caspases proteolytically cleave a multitude of cellular substrates, leading to apoptotic death. Thus, caspase activation is a key regulatory point in the commitment to apoptosis.The molecular mechanisms regulating caspase activation are largely unknown. In mammals, a proteolytic cascade is initiated by group III caspases with long N-terminal prodomains (reviewed in Refs. 2, 3, 6, and 7). Upon activation, initiator caspases proteolytically cleave group II effector caspases at aspartate-containing sites through a regulated sequence of reactions that separate the large and small subunit, and then detach the short prodomain (reviewed in Ref. 4). To date, it is unknown whether analogous cascades are conserved in other organisms, including insects. Nevertheless, diverse apoptotic inhibitors from mammals, insects, and their associated viral pathogens are providing important insight into the regulatory mechanisms of caspase activation (8 -14).The baculoviruses encode two mechanistically distinct apoptotic suppressors, inhibitor of apoptosis (IAP) 1 and P35. Both viral proteins prevent premature insect cell death and thereby promote virus multiplication (reviewed in Ref. 15). The baculovirus...
The gene encoding the 35-kDa protein (35K gene) located within the EcoRI-S genome fragment of Autographa californica nuclear polyhedrosis virus (AcMNPV) is transcribed early in infection. To examine its function(s) with respect to virus multiplication, we introduced specific mutations of this early gene into the AcMNPV genome. In Spodoptera frugiperda (SF21) culture, deletion of the 35K gene reduced yields of extracellular, budded virus from 200to 15,000-fold, depending on input multiplicity. Mutant replication was characterized by dramatically diminished levels of late and very late (occlusion-specific) virus gene expression and premature cell lysis. In contrast, 35K gene inactivation had no effect on virus growth in cultured Trichoplusia ni (TN368) cells. Insertion of the 35K gene and its promoter at an alternate site (polyhedrin locus) restored virus replication to wild-type levels in SF21 culture. Subsequent insertion of 4 bp after codon 81 generated a frameshift mutant that exhibited a virus phenotype indistinguishable from that of 35K deletion mutants and demonstrated that the 35K gene product (p35) was required for wild-type replication in SF21 cells. Mutagenesis also indicated that the C terminus of p35, including the last 12 residues, was required for function. In complementation assays, wild-type virus bearing a functional 35K gene allele stimulated all aspects of 35K null mutant replication and suppressed early cell lysis. These findings indicated that p35 is a trans-dominant factor that facilitates AcMNPV growth in a cell line-specific manner.
The baculovirus p35 gene product inhibits virally induced apoptosis, developmental cell death in Caenorhabditis elegans and Drosophila, and neuronal cell death in mammalian systems. Therefore, p35 likely inhibits a component of the death machinery that is both ubiquitous and highly conserved in evolution. We now show for the first time that p35 also inhibits Fas- and tumor necrosis factor (TNF)-induced apoptosis. Additionally, p35 blocks TNF- and Fas-induced proteolytic cleavage of the death substrate poly(ADP-ribose) polymerase from its native 116-kDa form to the characteristic 85-kDa form. This cleavage is thought to be catalyzed by an aspartate-specific protease of the interleukin 1 beta-converting enzyme family designated prICE (Lazebnik, Y. A., Kaufmann, S. H., Desnoyers, S., Poirier, G. G., and Earnshaw, W. C. (1994) Nature 371, 346-347). Our data suggest that p35 must directly or indirectly inhibit prICE. Given that p35 inhibits both TNF and Fas killing, along with previous reports of its ability to block developmental, viral, and x-irradiation-induced cell death, the present results indicate that TNF- and Fas-mediated apoptotic pathways must have components in common with these highly conserved death programs.
Expression of the apoptosis suppressor gene p35, derived from the baculovirus Autographa californica nuclear polyhedrosis virus, markedly inhibited the cell death of stably transfected mammalian neural cells whether the cell death was induced by glucose withdrawal, calcium ionophore, or serum withdrawal. The p35 protein, which is required to block virus-induced apoptosis of cultured insect cells, is only the second gene product shown to block mammalian neural cell death, with Bcl-2 being the first. Because there is no apparent homology between p35 and Bcl-2, the existence of a cellular death program that may be modulated at multiple points is suggested. Furthermore, these findings demonstrate that the putative cellular death program is conserved across species and cell types.
Programmed cell death, or apoptosis, occurs throughout the course of normal development in most animals and can also be elicited by a number of stimuli such as growth factor deprivation and viral infection. Certain morphological and biochemical characteristics of programmed cell death are similar among different tissues and species. During development of the nematode Caenorhabditis elegans, a single genetic pathway promotes the death of selected cells in a lineally fixed pattern. This pathway appears to be conserved among animal species. The baculovirus p35‐encoding gene (p35) is an inhibitor of virus‐induced apoptosis in insect cells. Here we demonstrate that expression of p35 in C. elegans prevents death of cells normally programmed to die. This suppression of developmentally programmed cell death results in appearance of extra surviving cells. Expression of p35 can rescue the embryonic lethality of a mutation in ced‐9, an endogenous gene homologous to the mammalian apoptotic suppressor bcl‐2, whose absence leads to ectopic cell deaths. These results support the hypothesis that viral infection can activate the same cell death pathway as is used during normal development and suggest that baculovirus p35 may act downstream or independently of ced‐9 in this pathway.
Transcription of the gene encoding a 35,000-molecular-weight protein (35K protein) from the EcoRI-S region (86.8 to 87.8 map units) of Autographa california nuclear polyhedrosis virus (AcMNPV) occurs early in infection and declines later. The region promoting the gene for the 35K protein, extending from 426 base pairs (bp) upstream to 12 bp downstream from the RNA start site, was linked to the bacterial chloramphenicol acetyltransferase gene (CAT) for analysis. CAT expression was monitored in cells that were transfected with plasmids containing the promoter-CAT fusion as well as cells infected with recombinant viruses containing the chimeric gene inserted into the AcMNPV genome. Mapping of the 5' ends of CAT-specific RNAs indicated that transcription initiated from the proper sites in both assays; moreover, the promoter fragment retained its early activity, despite an alternate location in the viral genome. The 5' boundary of upstream regulatory sequences was determined by constructing deletions of the promoter fragment extending toward the early RNA start site (position +1). In transient assays, a gradual reduction in CAT expression occurred as sequences from positions -426 to -31 were removed. In contrast, promoter deletions from positions -426 to -155 in recombinant viruses exhibited no effect on CAT expression, whereas deletions to position -55 abolished early expression but had no effect on late expression. Late CAT expression was eliminated when deletions to position -4 removed part of the late RNA start site. DNA signals potentiating early transcription were therefore located upstream (between positions -155 and -55) from those involved in late transcription of the gene encoding the 35K protein. Potential consensus sequences for early and late regulatory elements were identified.
Baculoviruses induce widespread apoptosis in invertebrates. To better understand the pathways by which these DNA viruses trigger apoptosis, we have used a combination of RNA silencing and overexpression of viral and host apoptotic regulators to identify cell death components in the model system of Drosophila melanogaster. Here we report that the principal effector caspase DrICE is required for baculovirus-induced apoptosis of Drosophila DL-1 cells as demonstrated by RNA silencing. proDrICE was proteolytically cleaved and activated during infection. Activation was blocked by overexpression of the cellular inhibitor-of-apoptosis proteins DIAP1 and SfIAP but not by the baculovirus caspase inhibitor P49 or P35. Rather, the substrate inhibitors P49 and P35 prevented virus-induced apoptosis by arresting active DrICE through formation of stable inhibitory complexes. Consistent with a two-step activation mechanism, proDrICE was cleaved at the large/small subunit junction TETD 230 -G by a DIAP1-inhibitable, P49/P35-resistant protease and then at the prodomain junction DHTD 28 -A by a P49/P35-sensitive protease. Confirming that P49 targeted DrICE and not the initiator caspase DRONC, depletion of DrICE by RNA silencing suppressed virus-induced cleavage of P49. Collectively, our findings indicate that whereas DIAP1 functions upstream to block DrICE activation, P49 and P35 act downstream by inhibiting active DrICE. Given that P49 has the potential to inhibit both upstream initiator caspases and downstream effector caspases, we conclude that P49 is a broad-spectrum caspase inhibitor that likely provides a selective advantage to baculoviruses in different cellular backgrounds.
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