Caspase-dependent N-terminal cleavage of influenza virus nucleocapsid protein in infected cells

The nucleocapsid protein (NP) (56 kDa) of human influenza A viruses is cleaved in infected cells into a 53-kDa form. Likewise, influenza B virus NP (64 kDa) is cleaved into a 55-kDa protein with a 62-kDa intermediate (O. P. Zhirnov and A. G. Bukrinskaya, Virology 109:174-179, 1981). We show now that an antibody specific for the N terminus of influenza A virus NP reacted with the uncleaved 56-kDa form but not with the truncated NP53 form, indicating the removal of a 3-kDa peptide from the N terminus. Amino acid sequencing revealed the cleavage sites ETD16*G for A/Aichi/68 NP and sites DID7*G and EAD61*V for B/Hong Kong/72 NP. With D at position -1, acidic amino acids at position -3, and aliphatic ones at positions -2 and +1, the NP cleavage sites show a recognition motif typical for caspases, key enzymes of apoptosis. These caspase cleavage sites demonstrated evolutionary stability and were retained in NPs of all human influenza A and B viruses. NP of avian influenza viruses, which is not cleaved in infected cells, contains G instead of D at position 16. Oligopeptide DEVD derivatives, specific caspase inhibitors, were shown to prevent the intracellular cleavage of NP. All three events, the NP cleavage, the increase of caspase activity, and the development of apoptosis, coincide in cells infected with human influenza A and B viruses. The data suggest that intracellular cleavage of NP is exerted by host caspases and is associated with the development of apoptosis at the late stages of infection.     

Cleavage between replicase proteins p28 and p65 of mouse hepatitis virus is not required for virus replication

The p28 and p65 proteins of mouse hepatitis virus (MHV) are the most amino-terminal protein domains of the replicase polyprotein. Cleavage between p28 and p65 has been shown to occur in vitro at cleavage site 1 (CS1), (247)Gly downward arrow Val(248), in the polyprotein. Although critical residues for CS1 cleavage have been mapped in vitro, the requirements for cleavage have not been studied in infected cells. To define the determinants of CS1 cleavage and the role of processing at this site during MHV replication, mutations and deletions were engineered in the replicase polyprotein at CS1. Mutations predicted to allow cleavage at CS1 yielded viable virus that grew to wild-type MHV titers and showed normal expression and processing of p28 and p65. Mutant viruses containing predicted noncleaving mutations or a CS1 deletion were also viable but demonstrated delayed growth kinetics, reduced peak titers, decreased RNA synthesis, and small plaques compared to wild-type controls. No p28 or p65 was detected in cells infected with predicted noncleaving CS1 mutants or the CS1 deletion mutant; however, a new protein of 93 kDa was detected. All introduced mutations and the deletion were retained during repeated virus passages in culture, and no phenotypic reversion was observed. The results of this study demonstrate that cleavage between p28 and p65 at CS1 is not required for MHV replication. However, proteolytic separation of p28 from p65 is necessary for optimal RNA synthesis and virus growth, suggesting important roles for these proteins in the formation or function of viral replication complexes.     

In transduced cells, the US3 protein kinase of herpes simplex virus 1 precludes activation and induction of apoptosis by transfected procaspase 3

The US3 protein kinase of herpes simplex virus 1 blocks apoptosis induced by replication-incompetent virus mutants, proapoptotic members of the Bcl-2 family of proteins, and by a variety of other agents that act at the premitochondrial level in the proapoptotic cascade. To define the role of US3 in blocking apoptosis at the postmitochondrial level, we investigated the US3 protein kinase in transduced cells that were either transfected with a plasmid encoding procaspase 3 or superinfected with a proapoptotic mutant virus lacking the gene encoding the infected cell protein no. 4. (i) We show that US3 blocks the proteolytic cleavage that generates active caspase 3 from the transfected zymogen procaspase 3, concomitant with inhibition of apoptosis. (ii) Studies based on detection of fluorescence emitted upon cleavage of a synthetic caspase 3 substrate showed that expression of the US3 kinase and appearance of the cleaved substrate were mutually exclusive. (iii) An affinity-purified glutathione S-transferase (GST)-US3 fusion protein, but not the inactive GST-US3(K220N) protein, phosphorylated procaspase 3 in vitro. The studies published earlier on the effect of US3 on the upstream regulatory proteins and current studies suggest that the US3 protein kinase may act on several proteins in the proapoptotic cascade to enable the virus to complete its replication.     

Caspase-3-mediated processing of poly(ADP-ribose) glycohydrolase during apoptosis

Poly(ADP-ribose) glycohydrolase (PARG) is responsible for the catabolism of poly(ADP-ribose) synthesized by poly(ADP-ribose) polymerase (PARP-1) and other PARP-1-like enzymes. In this work, we report that PARG is cleaved during etoposide-, staurosporine-, and Fas-induced apoptosis in human cells. This cleavage is concomitant with PARP-1 processing and generates two C-terminal fragments of 85 and 74 kDa. In vitro cleavage assays using apoptotic cell extracts showed that a protease of the caspase family is responsible for PARG processing. A complete inhibition of this cleavage was achieved at nanomolar concentrations of the caspase inhibitor acetyl-Asp-Glu-Val-Asp-aldehyde, suggesting the involvement of caspase-3-like proteases. Consistently, recombinant caspase-3 efficiently cleaved PARG in vitro, suggesting the involvement of this protease in PARG processing in vivo. Furthermore, caspase-3-deficient MCF-7 cells did not show any PARG cleavage in response to staurosporine treatment. The cleavage sites identified by site-directed mutagenesis are DEID(256) downward arrow V and the unconventional site MDVD(307) downward arrow N. Kinetic studies have shown similar maximal velocity (V(max)) and affinity (K(m)) for both full-length PARG and its apoptotic fragments, suggesting that caspase-3 may affect PARG function without altering its enzymatic activity. The early cleavage of both PARP-1 and PARG by caspases during apoptosis suggests an important function for poly(ADP-ribose) metabolism regulation during this cell death process.     

Cleavage and inactivation of antiapoptotic Akt/PKB by caspases during apoptosis

The oncogene Akt/PKB/RAC-PK is a serine/threonine kinase that mediates survival signals and has protective effects against apoptosis induced by a variety of stimuli. The kinase activity of Akt has been demonstrated to be critical in transmitting survival signals. We found that Akt protein was down-regulated during apoptosis. The down-regulation was blocked by a caspase inhibitor, indicating that Akt was cleaved by caspases during apoptosis. The Akt protein incubation with active caspases in vitro revealed that it was cleaved at three sites to produce 40- and 44-kDa fragments. The two cleavage sites were between the NH(2)-terminal pleckstrin homology domain (PH domain) and the kinase domain (TVAD(108 downward arrow)G and EEMD(119 downward arrow)F) and in the COOH-terminal regulatory domain (SETD(434 downward arrow)T). The loss of COOH-terminal domain of the Akt protein reduced its kinase activity and the overexpression of NH(2)-terminal and COOH-terminal-deleted Akt fragment increased the sensitivity to apoptosis-inducing stimuli. These results indicate that caspase-dependent cleavage of anti-apoptotic Akt turns off the survival signals, resulting in the acceleration of apoptotic cell death.     

Alphaviruses induce apoptosis in Bcl-2-overexpressing cells: evidence for a caspase-mediated, proteolytic inactivation of Bcl-2.

Bcl-2 oncogene expression plays a role in the establishment of persistent viral infection by blocking virus-induced apoptosis. This might be achieved by preventing virus-induced activation of caspase-3, an IL-1beta-converting enzyme (ICE)-like cysteine protease that has been implicated in the death effector phase of apoptosis. Contrary to this model, we show that three cell types highly overexpressing functional Bcl-2 displayed caspase-3 activation and underwent apoptosis in response to infection with alphaviruses Semliki Forest and Sindbis as efficiently as vector control counterparts. In all three cell types, overexpressed 26 kDa Bcl-2 was cleaved into a 23 kDa protein. Antibody epitope mapping revealed that cleavage occurred at one or two target sites for caspases within the amino acid region YEWD31 (downward arrow) AGD34 (downward arrow) A, removing the N-terminal BH4 region known to be essential for the death-protective activity of Bcl-2. Preincubation of cells with the caspase inhibitor Z-VAD prevented Bcl-2 cleavage and partially restored the protective activity of Bcl-2 against virus-induced apoptosis. Moreover, a murine Bcl-2 mutant having Asp31, Asp34 and Asp36 substituted by Glu was resistant to proteolytic cleavage and abrogated apoptosis following virus infection. These findings indicate that alphaviruses can trigger a caspase-mediated inactivation of Bcl-2 in order to evade the death protection imposed by this survival factor.     

Apoptotic response of chicken embryonic fibroblast cells to infectious bursal disease virus infections reflects viral pathogenicity

Infectious bursal disease virus (IBDV) induces immunodeficiency in young chickens and apoptosis in chicken embryos. To understand the relation between the viral pathogenesis and the induction of cell death, chicken embryonic fibroblast (CEF) cells were infected with IBDV intermediate (im) and very virulent (vv) strains at different MOIs. The cell viability and DNA fragmentation were evaluated in infected cells. The cellular apoptotic pathway involve was investigated by determining the activities of caspase cascade. The imIBDV strain was replicated well in CEF cells and shown higher viral titers than vvIBDV. Apoptosis changes were observed only in vvIBDV-infected CEF cells at higher MOI 48 h post infection. Efflux of cytochrome c suggests that the intrinsic pathway of the apoptotic process induced by vvIBDV infection independently of virus replication. Prediction of caspase substrates cleavage sites revealed that different IBDV strains have conserved cleavage motif pattern for VP2 and VP5 viral proteins. These findings suggest the pathogenicity of IBDV strains might be involved in the induction of apoptosis in host cells.     

Mutagenesis of the yellow fever virus NS2B protein: effects on proteolytic processing, NS2B-NS3 complex formation, and viral replication.

To study the role of specific regions of the yellow fever virus NS2B protein in proteolytic processing and association with the NS3 proteinase domain, a series of mutations were created in the hydrophobic regions and in a central conserved hydrophilic region proposed as a domain important for NS2B function. The effects of these mutations on cis cleavage at the 2B/3 cleavage site and on processing at other consensus cleavage sites for the NS3 proteinase in the nonstructural region were then characterized by cell-free translation and transient expression in BHK cells. Association between NS2B and the NS3 proteinase domain and the effects of mutations on complex formation were investigated by nondenaturing immunoprecipitation of these proteins expressed in infected cells, by cell-free translation, or by recombinant vaccinia viruses. Mutations within the hydrophobic regions had subtle effects on proteolytic processing, whereas mutations within the conserved domain dramatically reduced cleavage efficiency or abolished all cleavages. The conserved domain of NS2B is also implicated in formation of an NS2B-NS3 complex on the basis of the ability of mutations in this region to eliminate both association of these two proteins and trans-cleavage activity. In addition, mutations which either eliminated proteolytic processing or had no apparent effect on processing were found to abolish recovery of infectious virus following RNA transfection. These results suggest that the conserved region of NS2B is a domain essential for the function of the NS3 proteinase. Hydrophobic regions of NS2B whose structural integrity may not be essential for proteolytic processing may have additional functions during viral replication.     

Differential requirements of NS4A for internal NS3 cleavage and polyprotein processing of hepatitis C virus

The NS3 protein of hepatitis C virus (HCV) possesses protease activity responsible for the proteolytic cleavage of the viral polyprotein at the junctions of nonstructural proteins downstream of NS3. The NS3 protein was also found to be internally cleaved. In this study, we demonstrated that internal cleavages occurred on the NS3 protein of genotype 1b in the presence of NS4A, both in culture cells and with a mouse model system. No internal cleavage products were detected with the NS3 and NS4A proteins of genotype 2a. Three potential cleavage sites were detected in the NS3 protein (genotype 1b), with IPT(402)|S being the major one. The internal cleavage requires the polyprotein processing activity of NS3 protease, but when supplemented in trans, the internal cleavage efficiency is reduced. In addition, several mutations in NS4A disrupted the internal cleavage of NS3 but did not affect polyprotein processing, indicating that NS4A contributes differently to these two proteolytic activities. Furthermore, Ile-25, Val-26, and Ile-29 of the NS4A protein, important for the NS4A-dependent internal cleavages, were also shown to be critical for the transforming activity of NS3, but mutations at these critical residues resulted only in a slight increase of HCV replicating efficiency. The internal cleavage-associated enhancement of the transforming activity of NS3 was reduced when a T402A substitution at the major internal cleavage site was introduced. The multiple roles of NS4A in viral multiplication and pathogenesis make NS4A an ideal molecular target for HCV therapy.     

Caspase-3 mediated cleavage of HsRad51 at an unconventional site.

The human recombinase HsRad51 is cleaved during apoptosis. We have earlier observed cleavage of the 41-kDa full-length protein into a 33-kDa product in apoptotic Jurkat cells and in in vitro translated HsRad51 after treatment with activated S-100 extract. In this study, site-directed mutagenesis was used for mapping of the cleavage site to AQVD274 downward arrow G, which does not correspond to a conventional caspase cleavage site. The absence of HsRad51 cleavage in staurosporine-treated apoptotic MCF-7 cells, which lack caspase-3, indicates that caspase-3 is essential for HsRad51 cleavage in vivo. Cleavage into the 33-kDa fragment was generated by recombinant caspase-3 and -7 in in vitro translated wild type HsRad51, but not in the HsRad51 AQVE274 downward arrow G mutant. Similarly, HsRad51 of Jurkat cell extracts was cleaved into the 33-kDa product by recombinant caspase-3, whereas caspase-7 failed to cleave endogenous HsRad51. The cleavage of in vitro translated wild type and AQVE274 downward arrow G mutant HsRad51 as well as of endogenous HsRad51 also gave rise to a smaller fragment, which corresponds in size to a recently reported DVLD187 downward arrow N HsRad51 cleavage product. In Jurkat cell extracts, the AQVD274 downward arrow G and DVLD187 downward arrow N cleavage products of HsRad51 appeared at equal concentrations of caspase-3. Moreover both fragments were generated by induction of apoptosis in MDA-MB 157 cells with staurosporine and in Jurkat cells with camptothecin. Thus, two sites in the HsRad51 sequence are targets for caspase cleavage both in vitro and in vivo.     

Caspase proteolysis of desmin produces a dominant-negative inhibitor of intermediate filaments and promotes apoptosis

Caspase cleavage of key cytoskeletal proteins, including several intermediate filament proteins, triggers the dramatic disassembly of the cytoskeleton that characterizes apoptosis. Here we describe the muscle-specific intermediate filament protein desmin as a novel caspase substrate. Desmin is cleaved selectively at a conserved Asp residue in its L1-L2 linker domain (VEMD downward arrow M(264)) by caspase-6 in vitro and in myogenic cells undergoing apoptosis. We demonstrate that caspase cleavage of desmin at Asp(263) has important functional consequences, including the production of an amino-terminal cleavage product, N-desmin, which is unable to assemble into intermediate filaments, instead forming large intracellular aggregates. Moreover, N-desmin functions as a dominant-negative inhibitor of filament assembly, both for desmin and the structurally related intermediate filament protein vimentin. We also show that stable expression of a caspase cleavage-resistant desmin D263E mutant partially protects cells from tumor necrosis factor-alpha-induced apoptosis. Taken together, these results indicate that caspase proteolysis of desmin at Asp(263) produces a dominant-negative inhibitor of intermediate filaments and actively participates in the execution of apoptosis. In addition, these findings provide further evidence that the intermediate filament cytoskeleton has been targeted systematically for degradation during apoptosis.     

Increasing rate of cleavage at boundary between non-structural proteins 4B and 5A inhibits replication of hepatitis C virus

In hepatitis C virus, non-structural proteins are cleaved from the viral polyprotein by viral encoded proteases. Although proteolytic processing goes to completion, the rate of cleavage differs between different boundaries, primarily due to the sequence at these positions. However, it is not known whether slow cleavage is important for viral replication or a consequence of restrictions on sequences that can be tolerated at the cleaved ends of non-structural proteins. To address this question, mutations were introduced into the NS4B side of the NS4B5A boundary, and their effect on replication and polyprotein processing was examined in the context of a subgenomic replicon. Single mutations that modestly increased the rate of boundary processing were phenotypically silent, but a double mutation, which further increased the rate of boundary cleavage, was lethal. Rescue experiments relying on viral RNA polymerase-induced error failed to identify second site compensatory mutations. Use of a replicon library with codon degeneracy did allow identification of second site compensatory mutations, some of which fell exclusively within the NS5A side of the boundary. These mutations slowed boundary cleavage and only enhanced replication in the context of the original lethal NS4B double mutation. Overall, the data indicate that slow cleavage of the NS4B5A boundary is important and identify a previously unrecognized role for NS4B5A-containing precursors requiring them to exist for a minimum finite period of time.     

Subcellular localization of Aleutian mink disease parvovirus proteins and DNA during permissive infection of Crandell feline kidney cells.

Confocal microscopy allowed us to localize viral nonstructural (NS) and capsid (VP) proteins and DNA simultaneously in cells permissively infected with Aleutian mink disease parvovirus (ADV). Early after infection, NS proteins colocalized with viral DNA to form intranuclear inclusions, whereas VP proteins formed hollow intranuclear shells around the inclusions. Later, nuclei had irregular outlines and were virtually free of ADV products. In these cells, inclusions of viral DNA with or without associated NS protein were embedded in cytoplasmic VP protein. These findings implied that ADV replication within an infected cell is regulated spatially as well as temporally.     

S-phase-dependent cell cycle disturbances caused by Aleutian mink disease parvovirus.

We examined replication of the autonomous parvovirus Aleutian mink disease parvovirus (ADV) in relation to cell cycle progression of permissive Crandell feline kidney (CRFK) cells. Flow cytometric analysis showed that ADV caused a composite, binary pattern of cell cycle arrest. ADV-induced cell cycle arrest occurred exclusively in cells containing de novo-synthesized viral nonstructural (NS) proteins. Production of ADV NS proteins, indicative of ADV replication, was triggered during S-phase traverse. The NS+ cells that were generated during later parts of S phase did not undergo cytokinesis and formed a distinct population, termed population A. Formation of population A was not prevented by VM-26, indicating that these cells were arrested in late S or G2 phase. Cells in population A continued to support high-level ADV DNA replication and production of infectious virus after the normal S phase had ceased. A second, postmitotic, NS+ population (termed population B) arose in G0/G1, downstream of population A. Population B cells were unable to traverse S phase but did exhibit low-level DNA synthesis. Since the nature of this DNA synthesis was not examined, we cannot at present differentiate between G1 and early S arrest in population B. Cells that became NS+ during S phase entered population A, whereas population B cells apparently remained NS- during S phase and expressed high NS levels postmitosis in G0/G1. This suggested that population B resulted from leakage of cells with subthreshold levels of ADV products through the late S/G2 block and, consequently, that the binary pattern of ADV-induced cell cycle arrest may be governed merely by viral replication levels within a single S phase. Flow cytometric analysis of propidium iodide fluorescence and bromodeoxyuridine uptake showed that population A cells sustained significantly higher levels of DNA replication than population B cells during the ADV-induced cell cycle arrest. Therefore, the type of ADV-induced cell cycle arrest was not trivial and could have implications for subsequent viral replication in the target cell.     

Assessment of substrate specificity of hepatitis G virus NS3 protease by a genetic method

The RNA genome of hepatitis G virus (HGV) encodes a large polyprotein that is processed to mature proteins by viral-encoded proteases. The HGV NS3 protease is responsible for the cleavage of the HGV polyprotein at four different locations. No conserved sequence motif has been identified for the cleavage sites of the NS3 protease. To determine the substrate specificity of the NS3 protease, amino acid sequences cleaved by the NS3 protease were obtained from randomized sequence libraries by using a screening method referred to as GASP (Genetic Assay for Site-specific Proteolysis). Based on statistical analyses of the obtained cleavable sequences, a consensus substrate sequence was deduced: Gln-Glu-Thr-Leu-Val downward arrow Ser, with the scissile bond located between Val and Ser. The relevance of this peptide as a cleavable substrate was further supported by molecular modeling of the NS3 protease. Our result would provide an insight on the molecular activity of the NS3 protease and may be useful for the design of substrate-based inhibitors.     

Proper processing of dengue virus nonstructural glycoprotein NS1 requires the N-terminal hydrophobic signal sequence and the downstream nonstructural protein NS2a.

Expression of dengue virus gene products involves specific proteolytic cleavages of a precursor polyprotein. To study the flanking sequences required for expression of the dengue virus nonstructural glycoprotein NS1, we constructed a series of recombinant vaccinia viruses that contain the coding sequence for NS1 in combination with various lengths of upstream and downstream sequences. The NS1 products expressed by these viruses in infected CV-1 cells were immune precipitated and analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The data show that the 24-residue hydrophobic sequence preceding NS1 was necessary and sufficient for the production of glycosylated NS1 and that this sequence was cleaved from NS1 in the absence of most dengue virus proteins. This finding is consistent with previous proposals that this hydrophobic sequence serves as an N-terminal signal sequence that is cleaved by signal peptidase. The cleavage between the C terminus of NS1 and the downstream protein NS2a occurred when the complete NS2a was present. Recombinant viruses containing NS1 plus 15 or 49% of NS2a produced proteins larger than authentic NS1, indicating that the cleavage between NS1 and NS2a had not occurred. Failure of cleavage was not corrected by coinfection with a recombinant virus capable of cleavage. These results suggest that NS2a may be a cis-acting protease that cleaves itself from NS1, or NS2a may provide sequences for recognition by a specific cellular protease that cleaves at the NS1-NS2a junction.     

Notch1 antiapoptotic activity is abrogated by caspase cleavage in dying T lymphocytes

Excessive signaling via the Notch1 receptor inhibits apoptosis in T lymphocytes. Since several antiapoptotic proteins are cleaved by caspases during cell death, we investigated whether Notch1 was a caspase substrate. Results demonstrate that the intracellular domain of Notch1 (NICD) is cleaved into six fragments during apoptosis in Jurkat cells or peripheral T lymphocytes. Notch1 cleavage is prevented by the caspase inhibitors DEVD-fmk and VEID-fmk or by Bcl-2 expression. Caspase-3 and caspase-6 cleave the NICD into six fragments using sites located within the NF-kappaB binding domain, the ankyrin repeats and the transactivation domain. Notch1 cleavage correlates with the loss of HES-1 expression in apoptotic T cells. Notch1 fragments cannot inhibit activation-induced cell death in a T-cell hybridoma, confirming the abrogation of Notch1 antiapoptotic activity by caspases. The ability of the NICD but not the fragments to antagonize Nur77 activity supports a role for this factor in Notch1 antiapoptotic function.     

Limited caspase cleavage of human BAP31

Human BAP31 was cleaved at both of its two identical caspase cleavage sites in two previously reported models of apoptosis. We show here that only the most carboxy-terminal site is cleaved during apoptosis induced in HeLa cells by tunicamycin, tumor necrosis factor and cycloheximide, or staurosporine. Similar results were obtained in HL-60 cells using Fas/APO-1 antibodies, or cycloheximide. This limited cleavage, which is inhibited by several caspase inhibitors, removes eight amino acids from human BAP31 including the KKXX coat protein I binding motif. Ectopic expression of the resulting cleavage product induces redistribution of mannosidase II from the Golgi and prevents endoplasmic reticulum to Golgi transport of virus glycoproteins.