AcMNPVP35抑制HaSNPV诱导的Tn-Hi5细胞凋亡

苜蓿银纹夜蛾核多角体病毒(Autographa californica multicapsid nuclear polyhedrosis virus,AcMNPV)能够抑制棉铃虫核多角体病毒(Helicoverpa armigera Nucleopoly hedrovirus,HaSNPV)诱导的Tn Hi5 细胞凋亡,并能辅助HaSNPV在Tn Hi5细胞中复制,产生具有感染能力的子代病毒。瞬时表达实验证明,在Tn Hi5细胞中,p35具有明显抑制凋亡的能力,但是不能辅助HaSNPV在Tn Hi5细胞中的复制;进一步构建超表达p35 的重组病毒:vHap35,发现vHap35能够抑制Tn Hi5细胞凋亡,但是不能产生具有感染力的病毒粒子。电镜观察发现感染重组病毒的部分细胞中存在单粒包埋的病毒粒子(ODV)。     

Functional analysis of the Autographa californica nucleopolyhedrovirus IAP1 and IAP2

The Autographa californica nucleopolyhedrovirus (AcMNPV) contains three apoptosis suppressor genes: p35, iap1 and iap2. AcMNPV P35 functions as a pancaspase inhibitor, but the function of IAP1 and IAP2 has not been entirely resolved. In this paper, we analyze the function of IAP1 and IAP2 in de-tail. AcMNPV with p35-deletion inhibited the apoptosis of BTI-Tn-5B1-4 (Tn-Hi5) cells induced by a Helicoverpa armigera single nucleocapsid NPV (HearNPV) infection and rescued the replication of HearNPV and BV production in these cells. Transient-expression experiments indicated that both IAP1 and IAP2 suppress apoptosis of Tn-Hi5 cells during HearNPV infection. Recombinant HearNPVs ex-pressing AcMNPV iap1, iap2 and p35, respectively, not only prevented apoptosis but also allowed HearNPV to replicate in Tn-Hi5 cells. However, the iap1, iap2 and p35 genes when expressed in HearNPV were unable to rescue BV production. These results indicate that both AcMNPV iap1 and iap2 function independently as apoptosis inhibitors of and are potential host range factors.     

Baculovirus-based genetic screen for antiapoptotic genes identifies a novel IAP

The prototype baculovirus, Autographa californica multiple nuclear polyhedrosis virus (AcMNPV) expresses p35, a potent anti cell-death gene that promotes the propagation of the virus by blocking host cell apoptosis. Infection of insect Sf-21 cells with AcMNPV lacking p35 induces apoptosis. We have used this pro-apoptotic property of the p35 null virus to screen for genes encoding inhibitors of apoptosis that rescue cells infected with the p35 defective virus. We report here the identification of Tn-IAP1, a novel member of the IAP family of cell death inhibitors. Tn-IAP1 blocks cell death induced by p35 null AcMNPV, actinomycin D, and Drosophila cell-death inducers HID and GRIM. Given the conserved nature of the cell death pathway, this genetic screen can be used for rapid identification of novel inhibitors of apoptosis from diverse sources.     

Role of early and late replication events in induction of apoptosis by baculoviruses.

Autographa californica nuclear polyhedrosis virus (AcMNPV) mutants that lack the apoptotic suppressor gene p35 cause apoptosis in Spodoptera frugiperda SF21 cells. To identify a viral signal(s) that induces programmed cell death, we first defined the timing of apoptotic events during infection. Activation of a P35-inhibitable caspase, intracellular fragmentation of host and AcMNPV DNA, and cell membrane blebbing coincided with the initiation of viral DNA synthesis between 9 and 12 h after infection and thus suggested that apoptotic signaling begins at or before this time. Virus entry was required since binding of budded virus to host cell receptors alone was insufficient to induce apoptosis. To therefore determine the contribution of early and late replication events to apoptotic signaling, we used the AcMNPV mutant ts8 with a temperature-sensitive lesion in the putative helicase gene p143. At the nonpermissive temperature at which viral DNA synthesis was conditionally blocked, ts8 caused extensive apoptosis of the SF21 cell line p3576D, which dominantly interferes with anti-apoptotic function of viral P35. Confirming that apoptosis can be induced in the absence of normal viral DNA synthesis, parental SF21 cells also underwent apoptosis when infected with a ts8 p35 deletion mutant at the nonpermissive temperature. However, maximum levels of ts8 p35 deletion mutant-induced apoptosis required a temperature-sensitive event(s) that included the initiation of viral DNA synthesis. Collectively, these data suggested that baculovirus-induced apoptosis can be triggered by distinct early (pre-DNA synthesis) and late replicative events, including viral DNA synthesis or late gene expression.     

Responses of insect cells to baculovirus infection: protein synthesis shutdown and apoptosis.

Protein synthesis is globally shut down at late times postinfection in the baculovirus Autographa californica M nuclear polyhedrosis virus (AcMNPV)-infected gypsy moth cell line Ld652Y. A single gene, hrf-1, from another baculovirus, Lymantria dispar M nucleopolyhedrovirus, is able to preclude protein synthesis shutdown and ensure production of AcMNPV progeny in Ld652Y cells (S. M. Thiem, X. Du, M. E. Quentin, and M. M. Berner, J. Virol. 70:2221-2229, 1996; X. Du and S. M. Thiem, Virology 227:420-430, 1997). AcMNPV contains a potent antiapoptotic gene, p35, and protein synthesis arrest was reported in apoptotic insect cells induced by infection with AcMNPV lacking p35. In exploring the function of host range factor 1 (HRF-1) and the possible connection between protein synthesis shutdown and apoptosis, a series of recombinant AcMNPVs with different complements of p35 and hrf-1 were employed in apoptosis and protein synthesis assays. We found that the apoptotic suppressor AcMNPV P35 was translated prior to protein synthesis shutdown and functioned to prevent apoptosis. HRF-1 prevented protein synthesis shutdown even when the cells were undergoing apoptosis, but HRF-1 could not functionally substitute for P35. The DNA synthesis inhibitor aphidicolin could block both apoptosis and protein synthesis shutdown in Ld652Y cells infected with p35 mutant AcMNPVs but not the protein synthesis shutdown in wild-type AcMNPV-infected Ld652Y cells. These data suggest that protein synthesis shutdown and apoptosis are separate responses of Ld652Y cells to AcMNPV infection and that P35 is involved in inducing a protein synthesis shutdown response in the absence of late viral gene expression in Ld652Y cells. A model was developed for these responses of Ld652Y cells to AcMNPV infection.     

Expression of the Autographa californica nuclear polyhedrosis virus apoptotic suppressor gene p35 in nonpermissive Spodoptera littoralis cells.

Apoptosis was postulated as the main barrier to replication of the Autographa californica nuclear polyhedrosis virus (AcMNPV) in a Spodoptera littoralis SL2 cell line (N. Chejanovsky and E. Gershburg, Virology 209:519-525, 1995). Thus, we hypothesized that the viral apoptotic suppressor gene p35 is either poorly expressed or nonfunctional in AcMNPV-infected SL2 cells. These questions were addressed by first determining the steady-state levels of the p35 product, P35, in AcMNPV-infected SL2 cells. Indeed, very low levels of P35 were found in infected SL2 cells in comparison with those in SF9 cells. Overexpression of p35, in transient-transfection and recombinant-virus infection experiments, inhibited actinomycin D- and AcMNPV-induced apoptosis, as determined by reduced cell blebbing and release of oligonucleosomes and increased cell viability of SL2. However, SL2 budded-virus (BV) titers of a recombinant AcMNPV which highly expressed p35 did not improve significantly. Also, injection of S. littoralis larvae with recombinant and wild-type AcMNPV BVs showed similar 50% lethal doses. These data suggest that apoptosis is not the only impediment to AcMNPV replication in these nonpermissive S. littoralis cells, and probably in S. littoralis larvae, so p35 may not be the only host range determinant in this system.     

Increase of host cell longevity by the expression of 30K protein originating from silkworm hemolymph in an insect cell–baculovirus system

A recombinant baculovirus was constructed by the homologous recombination between wild-type AcMNPV DNA and a baculovirus transfer vector containing a gene coding for the 30K protein originating from silkworm hemolymph. The 30K protein was successfully expressed in Sf9 cells infected with the recombinant baculovirus (AcMNPV/30K). To investigate the effect produced by the expression of the 30K protein, host cell viability after infection was compared with that of Sf9 cells infected with AcMNPV/β-gal. The viability of the cells infected with AcMNPV/β-gal began to decrease exponentially 3 days after infection, whereas that of the cells infected with AcMNPV/30K remained at a high level until 5 days after infection. This indicates that the 30K protein increases cell longevity after viral infection. This increased cell longevity is considered to be due to the inhibition of host cell apoptosis induced by a baculovirus, and the extent of apoptosis was measured by the flow cytometric method. The percentage of the sub-G1 fraction, which represents the extent of apoptosis, was decreased by the expression of the 30K protein. This indicates that the expression of the 30K protein in insect cells increases host cell longevity by inhibiting apoptosis.     

ORF390 of white spot syndrome virus genome is identified as a novel anti-apoptosis gene

Apoptosis serves as an important defense strategy employed by host cells against viral invasion. Many viruses contain the anti-apoptotic genes to block the defense-by-death response of host cells. In this study, we tried to identify the putative anti-apoptotic genes in white spot syndrome virus (WSSV) genome. We confirmed that actinomycin D could induce apoptosis of shrimp primary cells. However, the apoptosis triggered by actinomycin D was inhibited by WSSV infection. As mutants of Autographa californica nucleopolyhedrovirus (AcMNPV), AcMNPVDelta35k/pol+ lacks a functional P35 gene undergoing apoptosis and its infection could induce Sf9 cell apoptosis. To identify the putative apoptotic suppressor gene of WSSV, overlapping cosmid clones representing the entire WSSV genome were individually cotransfected along with genome DNA of AcMNPVDeltaP35k/pol+. Using this marker rescue assay, a WSSV DNA fragment that was able to rescue AcMNPVDeltaP35k/pol+ infection in Sf9 cells was isolated. By further sequence analysis and rescue assay, the ORF390 was identified as a novel anti-apoptotic gene. The ORF displays two putative caspase9 cleavage sites LLVETDGPS, VKLEHDGSK, and a caspase3 cleavage site EEDEVDGVP. The ORF was cloned into the pIE1 vector and then the recombinant vector was transfected into Sf9 cells. The Sf9 cells did not show obvious characteristics of apoptosis when infected with AcMNPVDeltaP35k/pol+. And the transient expression of ORF390 allowed AcMNPVDeltaP35k/pol+ replication in Sf9 cells and resulted in the formation of polyhedra successfully. The results indicate that function of ORF390 in WSSV is a kind of apoptotic suppressor like P35 in AcMNPV.     

The 35-kilodalton protein gene (p35) of Autographa californica nuclear polyhedrosis virus and the neomycin resistance gene provide dominant selection of recombinant baculoviruses.

Autographa californica nuclear polyhedrosis virus (AcMNPV) recombinants were constructed to test the effectiveness of the AcMNPV 35-kilodalton protein gene (35K gene) and the bacterial neomycin resistance gene (neo) as dominant selectable markers for baculoviruses. Insertion of the AcMNPV apoptosis suppressor gene (p35) into the genome of p35-deletion mutants inhibited premature host cell death and increased virus yields up to 1200-fold at low multiplicities in Spodoptera frugiperda (SF21) cell cultures. When placed under control of an early virus promoter, the bacterial neomycin resistance gene (neo) restored multiplication of AcMNPV in the same cells treated with concentrations of the antibiotic G418 that inhibited wild-type virus growth greater than 1000-fold. The selectivity of these dominant markers was compared by serial passage of recombinant virus mixtures. After four passages, the proportion of p35-containing virus increased as much as 2,000,000-fold relative to deletion mutants, whereas the proportion of neo-containing viruses increased 500-fold relative to wild-type virus under G418 selection. The strength and utility of p35 as a selectable marker was further demonstrated by the construction of AcMNPV expression vectors using polyhedrin-based transfer plasmids that contain p35. Recombinant viruses with foreign gene insertions at the polyhedrin locus accounted for 15 to 30% of the transfection progeny. The proportion of desired viruses was increased to greater than 90% by linearizing the parental virus DNA at the intended site of recombination prior to transfection. These results indicate that p35 and neo facilitate the selection of baculovirus recombinants and that p35, in particular, is an effective marker for the generation of AcMNPV expression vectors.     

Caspase inhibitor P35 and inhibitor of apoptosis Op-IAP block in vivo proteolytic activation of an effector caspase at different steps

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 Sf-caspase-1, an insect group II effector caspase, we show that Op-IAP blocked the first activation cleavage at TETD downward arrowG between the large and small caspase subunits. In contrast, P35 failed to affect this cleavage, but functioned downstream to block maturation cleavages (DXXD downward arrow(G/A)) of the large subunit. Substitution of P35's reactive site residues with TETDG failed to increase its effectiveness for blocking TETD downward arrowG processing of pro-Sf-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 TETD downward arrowG 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.     

Baculovirus caspase inhibitors P49 and P35 block virus-induced apoptosis downstream of effector caspase DrICE activation in Drosophila melanogaster cells

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.     

The viral nucleocapsid protein of transmissible gastroenteritis coronavirus (TGEV) is cleaved by caspase-6 and -7 during TGEV-induced apoptosis

The transmissible gastroenteritis coronavirus (TGEV), like many other viruses, exerts much of its cytopathic effect through the induction of apoptosis of its host cell. Apoptosis is coordinated by a family of cysteine proteases, called caspases, that are activated during apoptosis and participate in dismantling the cell by cleaving key structural and regulatory proteins. We have explored the caspase activation events that are initiated upon infection of the human rectal tumor cell line HRT18 with TGEV. We show that TGEV infection results in the activation of caspase-3, -6, -7, -8, and -9 and cleavage of the caspase substrates eIF4GI, gelsolin, and alpha-fodrin. Surprisingly, the TGEV nucleoprotein (N) underwent proteolysis in parallel with the activation of caspases within the host cell. Cleavage of the N protein was inhibited by cell-permeative caspase inhibitors, suggesting that this viral structural protein is a target for host cell caspases. We show that the TGEV nucleoprotein is a substrate for both caspase-6 and -7, and using site-directed mutagenesis, we have mapped the cleavage site to VVPD(359) downward arrow. These data demonstrate that viral proteins can be targeted for destruction by the host cell death machinery.     

Activation of caspases measured in situ by binding of fluorochrome-labeled inhibitors of caspases (FLICA): correlation with DNA fragmentation

Activation of caspases is the key event of apoptosis and new methods are needed to assay this event, particularly in situ, in individual cells. To measure in situ caspases activation in the present study we employed fam-VAD-fmk and fam-VEID-fmk, the fluorochrome (fam)-labeled inhibitors of caspases (FLICA), which through the fluoromethylketone (fmk) moiety bind to active center of the activated enzymes. The peptide moiety of these inhibitors defines their specificity; VAD is generic to most caspases and VEID is caspase-6 specific. The frequencies of cells showing caspases activation were compared with those showing DNA fragmentation (detected by the TUNEL assay) in the same cultures. Apoptosis of HL-60 cells was induced by DNA topoisomerase I inhibitor camptothecin (CPT) or tumor necrosis factor-alpha combined with cycloheximide (TNF-alpha + CHX). The cells that bound FLICA had morphological changes typical of apoptosis. The intensity of their fluorescence was measured by laser scanning cytometry. Maximal rate of activation of the caspases, measured by the increase in frequency of the cells that bound fam-VAD-fmk, occurred between 30 and 90 min after the administration of TNF-alpha + CHX and between 2 and 4 h after the administration of CPT. In the CPT-treated cultures about 30% fewer cells bound fam-VEID-fmk than fam-VAD-fmk which suggests that the activation of caspase-6 was delayed or was not induced in some cells. A strong overall correlation between the cytometric assays of the apoptotic index based on the detection of caspases activation by the FLICA and the TUNEL assay was observed. The data indicate that FLICA offers a rapid and convenient method of assessing caspase's activation in individual cells and can also be used to estimate the frequency of apoptosis.     

Sendai Virus Infection Induces Apoptosis through Activation of Caspase-8 (FLICE) and Caspase-3 (CPP32)

Sendai virus (SV) infection and replication lead to a strong cytopathic effect with subsequent death of host cells. We now show that SV infection triggers an apoptotic program in target cells. Incubation of infected cells with the peptide inhibitor z-VAD-fmk abrogated SV-induced apoptosis, indicating that proteases of the caspase family were involved. Moreover, proteolytic activation of two distinct caspases, CPP32/caspase-3 and, as shown for the first time in virus-infected cells, FLICE/caspase-8, could be detected. So far, activation of FLICE/caspase-8 has been described in apoptosis triggered by death receptors, including CD95 and tumor necrosis factor (TNF)-R1. In contrast, we could show that SV-induced apoptosis did not require TNF or CD95 ligand. We further found that apoptosis of infected cells did not influence the maturation and budding of SV progeny. In conclusion, SV-induced cell injury is mediated by CD95- and TNF-R1-independent activation of caspases, leading to the death of host cells without impairment of the viral life cycle.     

An apoptosis-inhibiting gene from a nuclear polyhedrosis virus encoding a polypeptide with Cys/His sequence motifs.

Two different baculovirus genes are known to be able to block apoptosis triggered upon infection of Spodoptera frugiperda cells with p35 mutants of the insect baculovirus Autographa californica nuclear polyhedrosis virus (AcMNPV):p35 (P35-encoding gene) of AcMNPV (R. J. Clem, M. Fechheimer, and L. K. Miller, Science 254:1388-1390, 1991) and iap (inhibitor of apoptosis gene) of Cydia pomonella granulosis virus (CpGV) (N. E. Crook, R. J. Clem, and L. K. Miller, J. Virol. 67:2168-2174, 1993). Using a genetic complementation assay to identify additional genes which inhibit apoptosis during infection with a p35 mutant, we have isolated a gene from Orgyia pseudotsugata NPV (OpMNPV) that was able to functionally substitute for AcMNPV p35. The nucleotide sequence of this gene, Op-iap, predicted a 30-kDa polypeptide product with approximately 58% amino acid sequence identity to the product of CpGV iap, Cp-IAP. Like Cp-IAP, the predicted product of Op-iap has a carboxy-terminal C3HC4 zinc finger-like motif. In addition, a pair of additional cysteine/histidine motifs were found in the N-terminal regions of both polypeptide sequences. Recombinant p35 mutant viruses carrying either Op-iap or Cp-iap appeared to have a normal phenotype in S. frugiperda cells. Thus, Cp-IAP and Op-IAP appear to be functionally analogous to P35 but are likely to block apoptosis by a different mechanism which may involve direct interaction with DNA.     

Caspase 3-dependent killing of host cells by the parasite Entamoeba histolytica

The parasite Entamoeba histolytica is named for its ability to lyse host tissues. To determine the factors responsible, we have initiated an examination of the contribution of parasite virulence factors and host caspases to cellular destruction by the parasite. Amoebic colitis in C3H/HeJ mice was associated with extensive host apoptosis at sites of E. histolytica invasion. In vitro studies of E. histolytica –Jurkat T-cell interactions demonstrated that apoptosis required contact via the amoebic Gal/GalNAc lectin, but was unaffected by 75% inhibition of the amoebic cysteine proteinases. Parasite-induced DNA fragmentation was unaffected in caspase 8-deficient Jurkat cells treated with the caspase 9 inhibitor Ac-LEHD-fmk. In contrast, caspase 3-like activity was observed within minutes of E. histolytica contact and the caspase 3 inhibitor Ac-DEVD-CHO blocked Jurkat T cell death, as measured by both DNA fragmentation and ⁵¹Cr release. These data demonstrate rapid parasite-induced activation of caspase 3-like caspases, independent of the upstream caspases 8 and 9, which is required for host cell death.     

Baculovirus inhibitor of apoptosis functions at or upstream of the apoptotic suppressor P35 to prevent programmed cell death.

Members of the inhibitor of apoptosis (iap) gene family prevent programmed cell death induced by multiple signals in diverse organisms, suggesting that they act at a conserved step in the apoptotic pathway. To investigate the molecular mechanism of iap function, we expressed epitope-tagged Op-iap, the prototype viral iap from Orgyia pseudotsugata nuclear polyhedrosis virus, by using novel baculovirus recombinants and stably transfected insect cell lines. Epitope-tagged Op-iap blocked both virus- and UV radiation-induced apoptosis. With or without apoptotic stimuli, Op-IAP protein (31 kDa) cofractionated with cellular membranes and the cytosol, suggesting a cytoplasmic site of action. To identify the step(s) at which Op-iap blocks apoptosis, we monitored the effect of Op-iap expression on in vivo activation of the insect CED-3/ICE death proteases (caspases). Op-iap prevented in vivo caspase-mediated cleavage of the baculovirus substrate inhibitor P35 and blocked caspase activity upon viral infection or UV irradiation. However, unlike the stoichiometric inhibitor P35, Op-IAP failed to affect activated caspase as determined by in vitro protease assays. These findings provide the first biochemical evidence that Op-iap blocks activation of the host caspase or inhibits its activity by a mechanism distinct from P35. Moreover, as suggested by the capacity of Op-iap to block apoptosis induced by diverse signals, including virus infection and UV radiation, iap functions at a central point at or upstream from steps involving the death proteases.     

Reprieval from execution: the molecular basis of caspase inhibition

The suppression of apoptosis is essential to the propagation of viruses, and to the control of development and homeostasis in insects and mammals. The central components of all apoptotic pathways are proteases of the caspase family. Therefore, it is not surprising that the processes of natural selection, as well as pharmaceutical chemists, have designed compounds that directly target caspase activity in attempts to regulate apoptosis. The mechanisms used by highly specialized naturally occurring caspase inhibitors (both host and viral) have remained obscure for some time. However, recently there has been significant progress in this field, particularly because of the structural elucidation of the complexes between caspases and an endogenous inhibitor (XIAP) and a viral inhibitor (p35). This article reviews the newly defined molecular basis for the regulation of the caspases by viral and endogenous inhibitors.     

Active depletion of host cell inhibitor-of-apoptosis proteins triggers apoptosis upon baculovirus DNA replication

Apoptosis is an important antivirus defense by virtue of its impact on virus multiplication and pathogenesis. To define molecular mechanisms by which viruses are detected and the apoptotic response is initiated, we examined the antiviral role of host inhibitor-of-apoptosis (IAP) proteins in insect cells. We report here that the principal IAPs, DIAP1 and SfIAP, of the model insects Drosophila melanogaster and Spodoptera frugiperda, respectively, are rapidly depleted and thereby inactivated upon infection with the apoptosis-inducing baculovirus Autographa californica multicapsid nucleopolyhedrovirus (AcMNPV). Virus-induced loss of these host IAPs triggered caspase activation and apoptotic death. Elevation of IAP levels by ectopic expression repressed caspase activation. Loss of host IAP in both species was triggered by AcMNPV DNA replication. By using selected inhibitors, we found that virus-induced IAP depletion was mediated in part by the proteasome but not by caspase cleavage. Consistent with this conclusion, mutagenic disruption of the SfIAP RING motif, which acts as an E3 ubiquitin ligase, stabilized SfIAP during infection. Importantly, SfIAP was also stabilized upon the removal of its 99-residue N-terminal leader, which serves as a critical determinant of IAP turnover. These data indicated that a host pathway initiated by virus DNA replication and acting through instability motifs embedded within IAP triggers IAP depletion and thereby causes apoptosis. Taken together, the results of our study suggest that host modulation of cellular IAP levels is a conserved mechanism by which insects mount an apoptotic antiviral response. Thus, host IAPs may function as critical sentinels of virus invasion in insects.