Identification and initial characterization of matrix metalloproteinases in the yellow fever mosquito, Aedes aegypti.

Aedes aegypti is a major vector for arboviruses such as dengue, chikungunya and Zika viruses. During acquisition of a viremic bloodmeal, an arbovirus infects mosquito midgut cells before disseminating to secondary tissues, including the salivary glands. Once virus is released into the salivary ducts it can be transmitted to another vertebrate host. The midgut is surrounded by a basal lamina (BL) in the extracellular matrix, consisting of a proteinaceous mesh composed of collagen IV and laminin. BL pore size exclusion limit prevents virions from passing through. Thus, the BL probably requires remodelling via enzymatic activity to enable efficient virus dissemination. Matrix metalloproteinases (MMPs) are extracellular endopeptidases that are involved in remodelling of the extracellular matrix. Here, we describe and characterize the nine Ae. aegypti encoded MMPs, AeMMPs 1-9, which share common features with other invertebrate and vertebrate MMPs. Expression profiling in Ae. aegypti revealed that Aemmp4 and Aemmp6 were upregulated during metamorphosis, whereas expression of Aemmp1 and Aemmp2 increased during bloodmeal digestion. Aemmp1 expression was also upregulated in the presence of a bloodmeal containing chikungunya virus. Using polyclonal antibodies, AeMMP1 and AeMMP2 were specifically detected in tissues associated with the mosquito midgut.

Functional and biochemical characterization of the baculovirus caspase inhibitor MaviP35.

Many viruses express proteins which prevent the host cell death that their infection would otherwise provoke. Some insect viruses suppress host apoptosis through the expression of caspase inhibitors belonging to the P35 superfamily. Although a number of P35 relatives have been identified, Autographa californica (Ac) P35 and Spodoptera littoralis (Spli) P49 have been the most extensively characterized. AcP35 was found to inhibit caspases via a suicide substrate mechanism: the caspase cleaves AcP35 within its 'reactive site loop' then becomes trapped, irreversibly bound to the cleaved inhibitor. The Maruca vitrata multiple nucleopolyhedrovirus encodes a P35 family member (MaviP35) that exhibits 81% identity to AcP35. We found that this relative shared with AcP35 the ability to inhibit mammalian and insect cell death. Caspase-mediated cleavage within the MaviP35 reactive site loop occurred at a sequence distinct from that in AcP35, and the inhibitory profiles of the two P35 relatives differed. MaviP35 potently inhibited human caspases 2 and 3, DCP-1, DRICE and CED-3 in vitro, but (in contrast to AcP35) only weakly suppressed the proteolytic activity of the initiator human caspases 8, 9 and 10. Although MaviP35 inhibited the AcP35-resistant caspase DRONC in yeast, and was sensitive to cleavage by DRONC in vitro, MaviP35 failed to inhibit the proteolytic activity of bacterially produced DRONC in vitro.

A lepidopteran orthologue of reaper reveals functional conservation and evolution of IAP antagonists.

Genetic studies in Drosophila melanogaster have revealed that inhibitor of apoptosis (IAP) proteins and IAP antagonists such as reaper play a pivotal role in controlling cell death in insects. Interestingly, although the sequences and structures of IAPs are highly conserved, the sequence of IAP antagonists diverged very rapidly during evolution, making their identification difficult. Using a customized bioinformatics approach, we identified an IAP antagonist, IAP-binding motif 1 (Ibm1), from the genome of the silkworm Bombyx mori. This is the first reaper/grim orthologue identified in a nondipteran insect. Previous analysis indicated that both Reaper and Grim induce cell death through their N-terminal IBM as well as the Grim_helix3 (GH3) domain. Functional studies indicated that Ibm1 binds to an IAP protein from B. mori, BmIAP1, and induces apoptosis in insect cells via the IAP-binding motif, a seven amino acid sequence that is highly conserved in all IAP antagonists. Interestingly, Ibm1 also contains a region that is a statistically significant match to the GH3 domain. Mutational analysis indicated that the GH3-like motif in Ibm1 has an important supportive role in IAP-antagonist function and can trigger cell death under certain conditions.

Lack of involvement of mitochondrial factors in caspase activation in a Drosophila cell-free system.

Although mitochondrial proteins play well-defined roles in caspase activation in mammalian cells, the role of mitochondrial factors in caspase activation in Drosophila is unclear. Using cell-free extracts, we demonstrate that mitochondrial factors play no apparent role in Drosophila caspase activation. Cytosolic extract from apoptotic S2 cells, in which caspases were inhibited, induced caspase activation in cytosolic extract from normal S2 cells. Mitochondrial extract did not activate caspases, nor did it influence caspase activation by cytosolic extract. Silencing of Hid, Reaper, or Grim reduced caspase activation by apoptotic cell extract. Furthermore, a peptide representing the amino terminus of Hid was sufficient to activate caspases in cytosolic extract, and this activity was not enhanced by addition of mitochondria or mitochondrial lysate. The Hid peptide also induced apoptosis when introduced into S2 cells. These results suggest that caspase activation in Drosophila is regulated solely by cytoplasmic factors and does not involve any mitochondrial factors.

The role of apoptosis in defense against baculovirus infection in insects.

The baculoviruses make up a large, diverse family of DNA viruses that have evolved a number of fascinating mechanisms to manipulate their insect hosts. One of these is the ability to regulate apoptosis during infection by expressing proteins that can inhibit caspase activation and/or activity, including the caspase inhibitor P35 and its relatives, and the inhibitor of apoptosis (IAP) proteins. Experimental manipulations of the expression of these antiapoptotic genes, either by genetic deletions or by RNAi, have shed light on the effectiveness of apoptosis in combating baculovirus infection. The results of these experiments indicate that apoptosis can be an extremely powerful response to baculovirus infection, reducing viral replication, infectivity, and the ability of the virus to spread within the insect host even if a successful infection is established. Apoptosis is especially effective when it is combined with other innate antiviral defenses, which are largely unexplored in insects to date.

Deletions in the Ac-iap1 gene of the baculovirus AcMNPV occur spontaneously during serial passage and confer a cell line-specific replication advantage.

The PstI-I region of the Autographa californica multicapsid nucleopolyhedrovirus (AcMNPV) genome was previously shown to be a frequent target of spontaneous deletions during serial virus passage in TN-368 cells (Kumar and Miller, Virus Res. 7 (1987) 335). Analysis of two of these serial passage mutants showed that a portion of the Ac-iap1 gene was deleted. To directly test the effect of loss of Ac-iap1, three different deletions in Ac-iap1 were introduced into recombinant viruses and the ability of these viruses to replicate was examined in two cell lines, TN-368 and SF-21, as well as in two species of insect larvae, Trichoplusia ni and Spodoptera frugiperda. The mutant viruses were indistinguishable from wild type or control revertant virus in their ability to infect larvae of either species. Moreover, no effect was seen on the rate of replication or the overall amounts of budded or occluded virus produced in cultured cells. However, in co-infection experiments using TN-368 cells, it was consistently observed that mutants lacking a functional Ac-iap1 gene out-competed control viruses carrying Ac-iap1. Interestingly, this replication advantage was only evident in the TN-368 cell line, the cell line used for the original serial passage experiments, and not in SF-21 cells.

Baculoviruses and apoptosis: the good, the bad, and the ugly.

Since 1991, when a baculovirus was first shown to inhibit apoptosis of its host insect cells, considerable contributions to our knowledge of apoptosis have arisen from the study of these viruses and the anti-apoptotic genes they encode. Baculovirus anti-apoptotic genes include p35, which encodes the most broadly acting caspase inhibitor protein known, and iap (inhibitor of apoptosis) genes, which were the first members of an evolutionarily conserved gene family involved in regulation of apoptosis and cytokinesis in organisms ranging from yeast to humans. Baculoviruses also provide an ideal system to study the effects of an apoptotic response on viral pathogenesis in an animal host. In this review, I discuss a number of interesting recent developments in the areas of apoptotic regulation by baculoviruses and the effects of apoptosis on baculovirus replication and pathogenesis.

c-IAP1 is cleaved by caspases to produce a proapoptotic C-terminal fragment.

Although human c-IAP1 and c-IAP2 have been reported to possess antiapoptotic activity against a variety of stimuli in several mammalian cell types, we observed that full-length c-IAP1 and c-IAP2 failed to protect cells from apoptosis induced by Bax overexpression, tumor necrosis factor alpha treatment or Sindbis virus infection. However, deletion of the C-terminal RING domains of c-IAP1 and c-IAP2 restored antiapoptotic activity, indicating that this region negatively regulates the antiapoptotic function of the N-terminal BIR domain. This finding is consistent with the observation by others that the spacer region and RING domain of c-IAP1 functions as an E3 ligase, promoting autoubiquitination and degradation of c-IAP1. In addition, we found that c-IAP1 is cleaved during apoptosis to 52- and 35-kDa fragments. Both fragments contain the C-terminal end of c-IAP1 including the RING finger. In vitro cleavage of c-IAP1 with apoptotic cell extracts or with purified recombinant caspase-3 produced similar fragments. Furthermore, transfection of cells with the spacer-RING domain alone suppressed the antiapoptotic function of the N-terminal BIR domain of c-IAP1 and induced apoptosis. Optimal death-inducing activity of the spacer-RING required both the spacer region and the zinc-binding RING domain of c-IAP1 but did not require the caspase recruitment domain located within the spacer region. To the contrary, deletion of the caspase recruitment domain increased proapoptotic activity, apparently by stabilizing the C-terminal fragment.

Sindbis virus induces apoptosis through a caspase-dependent, CrmA-sensitive pathway.

Sindbis virus infection of cultured cells and of neurons in mouse brains leads to programmed cell death exhibiting the classical characteristics of apoptosis. Although the mechanism by which Sindbis virus activates the cell suicide program is not known, we demonstrate here that Sindbis virus activates caspases, a family of death-inducing proteases, resulting in cleavage of several cellular substrates. To study the role of caspases in virus-induced apoptosis, we determined the effects of specific caspase inhibitors on Sindbis virus-induced cell death. CrmA (a serpin from cowpox virus) and zVAD-FMK (N-benzyloxycarbonyl-Val-Ala-Asp-fluoromethyl ketone) inhibited Sindbis virus-induced cell death, suggesting that cellular caspases facilitate apoptosis induced by Sindbis virus. Furthermore, CrmA significantly increased the rate of survival of infected mice. These inhibitors appear to protect cells by inhibiting the cellular death pathway rather than impairing virus replication or by inhibiting the nsP2 and capsid viral proteases. The specificity of CrmA indicates that the Sindbis virus-induced death pathway is similar to that induced by Fas or tumor necrosis factor alpha rather than being like the death pathway induced by DNA damage. Taken together, these data suggest a central role for caspases in Sindbis virus-induced apoptosis.

Modulation of cell death by Bcl-XL through caspase interaction.

The caspases are cysteine proteases that have been implicated in the execution of programmed cell death in organisms ranging from nematodes to humans. Many members of the Bcl-2 family, including Bcl-XL, are potent inhibitors of programmed cell death and inhibit activation of caspases in cells. Here, we report a direct interaction between caspases and Bcl-XL. The loop domain of Bcl-XL is cleaved by caspases in vitro and in cells induced to undergo apoptotic death after Sindbis virus infection or interleukin 3 withdrawal. Mutation of the caspase cleavage site in Bcl-XL in conjunction with a mutation in the BH1 homology domain impairs the death-inhibitory activity of Bcl-XL, suggesting that interaction of Bcl-XL with caspases may be an important mechanism of inhibiting cell death. However, once Bcl-XL is cleaved, the C-terminal fragment of Bcl-XL potently induces apoptosis. Taken together, these findings indicate that the recognition/cleavage site of Bcl-XL may facilitate protection against cell death by acting at the level of caspase activation and that cleavage of Bcl-XL during the execution phase of cell death converts Bcl-XL from a protective to a lethal protein.

Herpesvirus saimiri encodes a functional homolog of the human bcl-2 oncogene.

Here we demonstrate that open reading frame 16 (ORF16) of the oncogenic herpesvirus saimiri protects cells from heterologous virus-induced apoptosis. The BH1 and BH2 homology domains are highly conserved in ORF16, and ORF16 heterodimerizes with Bcl-2 family members Bax and Bak. However, ORF16 lacks the core sequence of the conserved BH3 homology domain, suggesting that this region is not essential for anti-apoptotic activity. Conservation of a functional bcl-2 homolog among gammaherpesviruses suggests that inhibition of programmed cell death is important in the biology of these viruses.

Conversion of Bcl-2 to a Bax-like death effector by caspases.

Caspases are a family of cysteine proteases implicated in the biochemical and morphological changes that occur during apoptosis (programmed cell death). The loop domain of Bcl-2 is cleaved at Asp34 by caspase-3 (CPP32) in vitro, in cells overexpressing caspase-3, and after induction of apoptosis by Fas ligation and interleukin-3 withdrawal. The carboxyl-terminal Bcl-2 cleavage product triggered cell death and accelerated Sindbis virus-induced apoptosis, which was dependent on the BH3 homology and transmembrane domains of Bcl-2. Inhibitor studies indicated that cleavage of Bcl-2 may further activate downstream caspases and contribute to amplification of the caspase cascade. Cleavage-resistant mutants of Bcl-2 had increased protection from interleukin-3 withdrawal and Sindbis virus-induced apoptosis. Thus, cleavage of Bcl-2 by caspases may ensure the inevitability of cell death.

The iap genes: unique arbitrators of cell death.

The iap family of anti-apoptotic genes, originally discovered in viruses, has grown considerably in the past two years with the addition of a number of evolutionary conserved cellular homologues. Although the mechanism(s) by which these novel proteins block cell death is still unknown, intriguing clues to their function have been revealed by the discovery of interactions between some of the IAP homologues and cellular proteins involved in carrying out apoptotic signalling. Here, Rollie Clem and Colin Duckett discuss how the various IAP proteins may function in regulating apoptosis.

A conserved family of cellular genes related to the baculovirus iap gene and encoding apoptosis inhibitors.

The baculovirus inhibitor of apoptosis gene, iap, can impede cell death in insect cells. Here we show that iap can also prevent cell death in mammalian cells. The ability of iap to regulate programmed cell death in widely divergent species raised the possibility that cellular homologs of iap might exist. Consistent with this hypothesis, we have isolated Drosophila and human genes which encode IAP-like proteins (dILP and hILP). Like IAP, both dILP and hILP contain amino-terminal baculovirus IAP repeats (BIRs) and carboxy-terminal RING finger domains. Human ilp encodes a widely expressed cytoplasmic protein that can suppress apoptosis in transfected cells. An analysis of the expressed sequence tag database suggests that hilp is one of several human genes related to iap. Together these data suggest that iap and related cellular genes play an evolutionarily conserved role in the regulation of apoptosis.

Anti-apoptotic genes of baculoviruses.

Baculoviruses possess two different classes of genes with anti-apoptptic activity: p35 and iap. The p35 gene product (P35) is able to block apoptosis induced by a variety of stimuli in phylogenetically diverse organisms. P35 has recently been shown to be capable of inhibiting the ICE/ced-3 family of cysteine proteases, a family of enzymes which are implicated in cell death and which exhibit specificity for cleavage at aspartate residues. The products of the iap genes are a distinct class of proteins containing a carboxyl ring finger and tandem duplications of a unique motif known as the BIR motif. Homologues of the baculovirus iap genes have been identified in the human genome. Both classes of baculovirus anti-apoptotic genes will continue to be important tools in defining the pathways involved in apoptosis. Since our demonstration in 1991 that a baculovirus prevents host cells from undergoing apoptosis by expressing a gene known as p35(Clem et al., 1991), the study of baculovirus-induced apoptosis and the anti-apoptotic genes they possess has led to discoveries with far-reaching implications for viral pathogenesis, human disease, and the study of cell death. It is now known that a variety of eukaryotic viruses encode genes which allow them to control cellular apoptosis. Understanding the mechanism(s) by which these viral gene products act provides fundamental insights into the pathways regulating apoptosis. In this review, we discuss the inhibition of apoptosis by baculoviruses, concentrating mainly on the nature and mechanism of action of the two classes of baculovirus genes, p35 and iap, which are able to control apoptosis in a diversity ofeukaryotes.

Influence of infection route on the infectivity of baculovirus mutants lacking the apoptosis-inhibiting gene p35 and the adjacent gene p94.

The infectivity of Autographa californica nuclear polyhedrosis virus mutants lacking the apoptosis-inhibiting gene p35 is decreased 1,000-fold or more in larvae of the insect Spodoptera frugiperda if the budded form of the virus is administered by hemocoelic injection; this decrease is correlated with the antiviral effects of apoptosis (R. J. Clem and L. K. Miller, J. Virol. 67:3730-3738, 1993). We have extended this correlation by showing that the infectivity of p35 mutant budded virus is restored to wild-type levels by expression of an unrelated baculovirus apoptosis-inhibiting gene, Cp-iap. We have also examined the oral infectivity of the occluded form of mutants lacking p35, the neighboring p94 gene, or both genes by feeding insects occluded virus. The oral infectivity of the p35 mutant was significantly reduced in S. frugiperda larvae, but this reduction (25-fold) was less than that observed for the hemocoelic route of infection (1,000-fold). The disruption of p94 alone had no apparent effect on infectivity by either route. Unexpectedly, however, the disruption of both p35 and p94 restored oral infectivity to nearly wild-type levels but did not exert this compensatory effect on infectivity by hemocoelic injection. Thus, the infectivity of the double p35/p94 mutant is affected in a route-specific manner in S. frugiperda larvae, suggesting a tissue-specific response to p35 and/or p94. Infectivity in a different host, Trichoplusia ni, was unaffected by all the mutants tested, consistent with previous studies indicating a lack of sensitivity to apoptosis in this species. However, T. ni and S. frugiperda larvae infected with p35 mutants failed to exhibit the symptom of morphological disintegration ("melting") typical of a wild-type infection, suggesting that p35 is required for the infection of some tissues in both species.

Control of programmed cell death by the baculovirus genes p35 and iap.

The SF-21 insect cell line undergoes rapid and widespread apoptosis when treated with actinomycin D or when infected with a mutant of the baculovirus Autographa californica nuclear polyhedrosis virus lacking a p35 gene or a functionally active iap (inhibitor of apoptosis) gene. Here we provide evidence that the basis for the induction of apoptosis by these two different stimuli is the cessation of RNA synthesis. We also show that expression of either p35 or two different functional iap homologs blocks apoptosis independently of other viral genes, indicating that these gene products act directly on the cellular apoptotic pathway. The iap genes encode a C3HC4 (or RING) finger motif found in a number of transcriptional regulatory proteins, as well as two additional Cys/His motifs (baculovirus iap repeats). We show that specific amino acids within both the C3HC4 finger and the N-terminal baculovirus iap repeat are critical for anti-apoptosis function. Overexpression of either mammalian bcl-2 or adenovirus E1B-19K, genes which block apoptosis when overexpressed in a number of mammalian cells, does not block actinomycin D-induced apoptosis in SF-21 cells.

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.

Apoptosis reduces both the in vitro replication and the in vivo infectivity of a baculovirus.

Apoptotic programmed cell death occurs when the insect cell line SF-21, derived from Spodoptera frugiperda, is infected with mutants of the baculovirus Autographa californica nuclear polyhedrosis virus (AcMNPV) which lack a functional p35 gene. However, infection of the Trichoplusia ni TN-368 cell line with p35 mutants does not result in apoptosis (R. Clem, M. Fechheimer, and L. Miller, Science 254:1388-1390, 1991). We have examined the effect of apoptosis on AcMNPV infections in cell lines and larvae of these two insect species. Production of viral progeny was significantly lower in SF-21 cells infected with p35 mutants than in cells infected with wild-type (wt) or revertant viruses. Viral gene expression was abnormal in SF-21 cells infected with p35 mutants; there was a delay in the transcription and translation of early and late viral genes, a lack of expression of very late genes, and a total cessation of protein synthesis late in the apoptotic process. In vivo analysis revealed that the dose of budded virus required for 50% lethality in S. frugiperda larvae was approximately 1,000-fold higher for p35 mutants than for wt or revertant viruses. In contrast, the replication and infectivity of p35 mutant viruses was equivalent to that of wt AcMNPV during infection of both TN-368 cells and T. ni larvae. Thus, the data indicate that a host apoptotic response provides protection against viral infection at the organismal level and that the p35 gene constitutes a host range determinant for AcMNPV infection.