Predation by Engytatus varians (Distant) (Hemiptera: Miridae) on Bactericera cockerelli (Sulcer) (Hemiptera: Triozidae) and two Spodoptera species

Predation by Engytatus varians (Distant) adults on different development stages of the prey species Bactericera cockerelli (Sulcer) (egg, second, and third nymphal instars), Spodoptera exigua (Hübner) and Spodoptera frugiperda (J. E. Smith) (egg, first, and second larval instars) was evaluated using tomato (Solanum lycopersicum L.) leaflets or plants. These insects are the primary pest of several agriculturally important crops. The influence of E. varians age on the predation capacity was also analysed. Engytatus varians females consumed significantly more B. cockerelli eggs and nymphs than males. Additionally, female predators consumed significantly more second than third instar prey at two predator ages, while males consumed significantly more the second instar than third instar prey at all predator ages. In most of the cases, females also consumed significantly more S. exigua and S. frugiperda eggs than males; however, in terms of larvae consumption, this difference was observed only in some predator ages. Females consumed more the first than second instar S. exigua than males, whereas this behaviour was only observed in males when the predators were 15 and 17 days old. No significant differences were observed in the consumption of first and second instar of S. frugiperda for both sexes of the predators. Predator age did not cause any systematic effects on the predation rates of any prey species. Based on these results, we confirmed that E. varians has potential as a biological control agent for B. cockerelli and also for the Spodoptera species bioassayed.

The Role of Fibrinolysis in the Pathogenesis of the Haemorrhagic Syndrome Produced by Virulent Isolates of African Swine Fever Virus

The activity of several proteins involved in fibrinolysis and the morphological changes in the blood vessel walls of pigs infected with highly virulent (Malawi’83) and moderately virulent (Dominican Republic ‘78-DR’78) ASF virus isolates were determined. Pigs infected with the Malawi’83 virus developed an increased fibrinolytic activity due to high plasma levels of tissue-plasminogen activator (t-PA) of 71.3 ± 22.8 IU/ml (mean ± SD), which correlated well with an increased activation of interstitial capillary endothelial cells and high levels of 1150 ± 73.6 nM of fibrin monomer in the circulation. Animals infected with DR’78 virus, in contrast, showed an inhibition of fibrinolysis in the late stages of disease with almost a 5-fold increase of plasminogen activator inhibitor (PAI) activity of 196.0 AU/ml. These results suggest that activation of the fibrinolytic system in pigs infected with the Malawi’83 virus is probably due to increased formation and deposition of fibrin in the circulation, contributing to an increased bleeding tendency and higher mortality. On the contrary, animals infected with DR’78 virus developed an inhibition of fibrinolysis and thus a reduction in bleeding.

Toxicity and sublethal effects of six insecticides to last instar larvae and adults of the biocontrol agents Chrysoperla carnea (Stephens) (Neuroptera: Chrysopidae) and Adalia bipunctata (L.) (Coleoptera: Coccinellidae)

To further develop Integrated Pest Management (IPM) strategies against crop pests, it is important to evaluate the effects of insecticides on biological control agents. Therefore, we tested the toxicity and sublethal effects (fecundity and fertility) of flonicamid, flubendiamide, metaflumizone, spirotetramat, sulfoxaflor and deltamethrin on the natural enemies Chrysoperla carnea and Adalia bipunctata. The side effects of the active ingredients of the insecticides were evaluated with residual contact tests for the larvae and adults of these predators in the laboratory. Flonicamid, flubendiamide, metaflumizone and spirotetramat were innocuous to last instar larvae and adults of C. carnea and A. bipunctata. Sulfoxaflor was slightly toxic to adults of C. carnea and was highly toxic to the L4 larvae of A. bipunctata. For A. bipunctata, sulfoxaflor and deltamethrin were the most damaging compounds with a cumulative larval mortality of 100%. Deltamethrin was also the most toxic compound to larvae and adults of C. carnea. In accordance with the results obtained, the compounds flonicamid, flubendiamide, metaflumizone and spirotetramat might be incorporated into IPM programs in combination with these natural enemies for the control of particular greenhouse pests. Nevertheless, the use of sulfoxaflor and deltamethrin in IPM strategies should be taken into consideration when releasing either of these biological control agents, due to the toxic behavior observed under laboratory conditions. The need for developing sustainable approaches to combine the use of these insecticides and natural enemies within an IPM framework is discussed.

The effect of Chrysoperla carnea (Neuroptera: Chrysopidae) and Adalia bipunctata (Coleoptera: Coccinellidae) on the spread of cucumber mosaic virus (CMV) by Aphis gossypii (Hemiptera: Aphididae)

The effects of two aphidophagous predators, the larvae of Chrysoperla carnea and adults of Adalia bipunctata, on the spread of cucumber mosaic virus (CMV) transmitted in a non-persistent manner by the cotton aphid Aphis gossypii were studied under semi-field conditions. Natural enemies and aphids were released inside insect-proof cages (1 m × 1 m × 1 m) with a central CMV-infected cucumber plant surrounded by 48 healthy cucumber seedlings, and the spatiotemporal dynamics of the virus and vector were evaluated in the short and long term (1 and 5 days) in the presence and absence of the natural enemy. The spatial analysis by distance indices methodology together with other indices measuring the dispersal around a single focus was used to assess the spatial pattern and the degree of association between the virus and its vector. Both natural enemies significantly reduced the number of aphids in the CMV-source plant after 5 days but not after 1 day. The CMV transmission rate was generally low, especially after 1 day, due to the limited movement of aphids from the central CMV-source plant, which increased slightly after 5 days. Infected plants were mainly located around the central virus-infected source plant, and the percentage of aphid occupation and CMV-infected plants did not differ significantly in absence and presence of natural enemies. The distribution patterns of A. gossypii and CMV were only coincident close to the central plant. The complexity of multitrophic interactions and the role of aphid predators in the spread of CMV are discussed.

Lethal and sublethal effects of methoxyfenozide on the development, survival and reproduction of the fall armyworm, Spodoptera frugiperda (J. E. Smith) (Lepidoptera: Noctuidae)

The lethal and sublethal effects of the ecdysone agonist methoxyfenozide on the fall armyworm, Spodoptera frugiperda (J. E. Smith), were investigated by feeding a methoxyfenozide-treated diet to fifth instars until pupation in doses corresponding to the LC10 and LC25 for the compound. Larval mortality reached 8% and 26% in the low and high concentration groups, respectively, on the seventh day of the experiment. A progressive larval mortality of 12% for the LC10 and 60% for the LC25 was observed before pupation. Treated larvae exhibited lower pupal weights, higher pupal mortality, presence of deformed pupae, and more deformed adults than untreated larvae. The incorporation of methoxyfenozide into the diet had a significant effect on the timing of larval development. The development period for males and females was about seven days longer than the controls for both concentrations tested. In contrast, the compound affected neither pupae nor adult longevity. Finally, S. frugiperda adults that resulted from fifth instars treated with methoxyfenozide were not affected in their mean cumulative number of eggs laid per female (fecundity), nor percentages of eggs hatched (fertility), or the sex ratio. Our results suggest that the combination of lethal and sublethal effects of methoxyfenozide may have important implications for the population dynamics of the fall armyworm.

Structural organization of Bacillus subtilis phage phi29. A model

Phage phi29 is a nonisometric virus producing several types of morphological variants in normal infections. The study of these variants by electron microscopy, and their comparison with those from T-even phages, suggest that the capsid of phage phi29 is a prolate icosahedron. Phage phi29 capsid consists of a major protein, p8, and an additional protein, p8.5, making up the fibers. We have determined the number of subunits of each structural protein per viral particle taking into account the phage molecular weight (between 28 and 29.6 x 10(6)), the molecular weight of each structural protein, and the mass percentage of each protein with respect to the total protein mass of the phage. These values, together with the results obtained from chemical crosslinking of the structural proteins on the phage, suggest that the capsid contains protein p8 dimers clustered in trimers.

Compatibility of endoparasitoid Hyposoter didymator (Hymenoptera: Ichneumonidae) protected stages with five selected insecticides

Hyposoter didymator (Thunberg) (Hymenoptera: Ichneumonidae) is a koinobiont endoparasitoid that emerges from the parasitization of economically important noctuid pests. H. didymator also is considered one of the most important native biocontrol agents of noctuids in Spain. Side effects of five insecticides with very different modes of action (fipronil, imidacloprid, natural pyrethrins + piperonyl butoxide, pymetrozine, and triflumuron) at the maximum field recommended rate in Spain were evaluated on H. didymator parasitizing Spodoptera littoralis (Boisduval) larvae and pupae of the endoparasitoid. Parasitized larvae were topically treated or ingested treated artificial diet. Parasitoid cocoons were topically treated. Host mortality when parasitized larvae were treated, as well as further development of the parasitoid surviving (e.g., percentage of cocoons spun, adult emergence, hosts attacked, and numbered progeny) were determined. Toxicity after treatment of parasitized larvae differed depending on the mode of exposure and insecticide. Fipronil was always highly toxic; imidacloprid killed all host insects by ingestion, but it was less toxic to both host and parasitoids, when administered topically; natural pyrethrins + piperonyl butoxide and triflumuron showed differing degrees of toxicity, and pymetrozine was harmless. Parasitoid cocoons provided effective protection against all the insecticides, except fipronil.

Influence of azadirachtin, a botanical insecticide, on Chrysoperla carnea (Stephens) reproduction: toxicity and ultrastructural approach

A commercial formulation of azadirachtin (Align) was tested on Chrysoperla carnea (Stephens) (Neuroptera: Chrysopidae) adults to determine its effects on reproduction. Three methods of exposure were carried out in the laboratory (residual, direct contact and ingestion) with concentrations close to the maximum field recommended concentration in Spain (48 mg AI/liter). Align proved to be harmless to newly emerged adults irrespective of the mode of exposure. Nevertheless, fecundity was reduced in a reversible way in females that have ingested azadiracthin after the onset of oviposition. Fertility was not different from that of controls in all treatments. Additional tests showed that males were not involved in the reduction of oviposition. Electron microscopy studies pointed out that Align interfered with vitellogenin synthesis and/or its uptake by developing oocytes; thus, growing follicles in treated females were significantly smaller that those of the controls. The role of azadirachtin as a compound that may influence several hormonal and protein titers involved in reproduction is also discussed.

Topical toxicity of two acetonic fractions of Trichilia havanensis Jacq. and four insecticides to larvae and adults of Chrysoperla carnea (Stephens) (Neuroptera: Chrysopidae)

The toxicity of botanical origin compounds such as two acetonic fractions of the seed kernels of the Meliacea Trichilia havanensis Jacq with insecticide properties (azadirone (F12) and the mixture F18 [1,7+3,7-di-O-acethylhavanensin (4:1)], three insecticides commercially available (imidacloprid, natural pyrethrins+PBO, triflumuron) and phloxine B, were tested in the laboratory. Topical bioassays using third instar and newly emerged adults of the lacewing Chrysoperla carnea (Stephens) at the maximum field recommended rate in Spain for commercials and at 1,000 ppm of active ingredient for T. havanensis acetone fractions and phloxine-B, were carried out. Imidacloprid and triflumuron were very toxic to third instar larvae inhibiting adult emergence, being the rest of insecticides harmless. Fecundity and fertility were not affected by the non-toxic compounds. Concerning adults, only imidacloprid and natural pyrethrins killed them significantly 24 hours after treatment. Phloxine B, triflumuron and T. havanensis fractions were harmless and did not cause any effect on fecundity and fertility with the exception of triflumuron, which reduced considerably the egg hatch. It can be concluded that T. havanensis acetonic fractions and phloxine B were non-toxic to larvae and adults of C. carnea when treated topically, whereas triflumuron, natural pyrethrins and imidacloprid affected one or more of the evaluated parameters under our conditions.

African swine fever virus structural protein pE120R is essential for virus transport from assembly sites to plasma membrane but not for infectivity

This report examines the role of African swine fever virus (ASFV) structural protein pE120R in virus replication. Immunoelectron microscopy revealed that protein pE120R localizes at the surface of the intracellular virions. Consistent with this, coimmunoprecipitation assays showed that protein pE120R binds to the major capsid protein p72. Moreover, it was found that, in cells infected with an ASFV recombinant that inducibly expresses protein p72, the incorporation of pE120R into the virus particle is dependent on p72 expression. Protein pE120R was also studied using an ASFV recombinant in which E120R gene expression is regulated by the Escherichia coli lac repressor-operator system. In the absence of inducer, pE120R expression was reduced about 100-fold compared to that obtained with the parental virus or the recombinant virus grown under permissive conditions. One-step virus growth curves showed that, under conditions that repress pE120R expression, the titer of intracellular progeny was similar to the total virus yield obtained under permissive conditions, whereas the extracellular virus yield was about 100-fold lower than in control infections. Immunofluorescence and electron microscopy demonstrated that, under restrictive conditions, intracellular mature virions are properly assembled but remain confined to the replication areas. Altogether, these results indicate that pE120R is necessary for virus dissemination but not for virus infectivity. The data also suggest that protein pE120R might be involved in the microtubule-mediated transport of ASFV particles from the viral factories to the plasma membrane.

Structure of African swine fever virus late promoters: requirement of a TATA sequence at the initiation region

A number of mutations, including deletions, linker scan substitutions, and point mutations, were performed in the promoter of the late African swine fever virus (ASFV) gene coding for the capsid protein p72. The consequences of the mutations in terms of promoter activity were analyzed by luciferase assays using plasmids transfected into infected cells. The results showed that the promoter function is contained between nucleotides -36 and +5 relative to the transcription initiation site. Moreover, two major essential regions for promoter activity, centered at positions -13 and +3, were located along the 41-bp sequence, the latter mapping in the transcription start site. Sequence alignment with other ASFV late promoters showed homology in the region of transcriptional initiation, where the presence of the sequence TATA was observed in most of the promoters. Substitution of these four residues in three other late viral promoters strongly reduced their respective activities. These results show that cis-acting control elements of ASFV p72 gene transcription are restricted to a short sequence of about 40 bp and suggest that transcription of late genes is initiated around a TATA sequence that would function as an initiator element.

African swine fever virus EP153R open reading frame encodes a glycoprotein involved in the hemadsorption of infected cells

The open reading frame EP153R, located within the EcoRI E' fragment of the African swine fever (ASF) virus genome, is predicted to encode a membrane protein of 153 amino acids that presents significant homology to the N-terminal region of several CD44 molecules. EP153R contains multiple putative sites for N-glycosylation, phosphorylation, and myristoylation, a central transmembrane region, a C-type animal lectin-like domain, and a cell attachment sequence. Transcription of EP153R takes place at both early and late times during the virus infection. The disruption of the gene, achieved by insertion of the marker gene LacZ within EP153R, did not change either the in vitro virus growth rate or the virus-sensitive/resistant condition of up to 17 established cell lines, but abrogated the hemadsorption phenomenon induced in ASF virus-infected cells. As the sequence and expression of the ASF virus protein pEP402R, a CD2 homolog responsible for the adhesion of erythrocytes to susceptible cells, was unaffected in cultures infected with the EP153R deletion mutant, we conclude that the gene EP153R is needed to induce and/or maintain the interaction between the viral CD2 homolog and its corresponding cell receptor.

Characterization of the african swine fever virus protein p49: a new late structural polypeptide

The open reading frame B438L, located within the EcoRI B fragment of the African swine fever virus genome, is predicted to encode a protein of 438 amino acids with a molecular mass of 49.3 kDa. It presents a cell attachment RGD (Arg-Gly-Asp) motif but no other significant similarity to protein sequences in databases. Northern blot and primer extension analysis showed that B438L is transcribed only at late times during virus infection. The B438L gene product has been expressed in Escherichia coli, purified and used as an antigen for antibody production. The rabbit antiserum specific for pB438L recognized a protein of about 49 kDa in virus-infected cell extracts. This protein was synthesized late in infection by all the virus strains tested, was located in cytoplasmic virus factories and appeared as a structural component of purified virus particles.

African swine fever virus dUTPase is a highly specific enzyme required for efficient replication in swine macrophages

The African swine fever virus (ASFV) gene E165R, which is homologous to dUTPases, has been characterized. A multiple alignment of dUTPases showed the conservation in ASFV dUTPase of the motifs that define this protein family. A biochemical analysis of the purified recombinant enzyme showed that the virus dUTPase is a trimeric, highly specific enzyme that requires a divalent cation for activity. The enzyme is most probably complexed with Mg(2+), the preferred cation, and has an apparent K(m) for dUTP of 1 microM. Northern and Western blotting, as well as immunofluorescence analyses, indicated that the enzyme is expressed at early and late times of infection and is localized in the cytoplasm of the infected cells. On the other hand, an ASFV dUTPase-deletion mutant (vDeltaE165R) has been obtained. Growth kinetics showed that vDeltaE165R replicates as efficiently as parental virus in Vero cells but only to 10% or less of parental virus in swine macrophages. Our results suggest that the dUTPase activity is dispensable for virus replication in dividing cells but is required for productive infection in nondividing swine macrophages, the natural host cell for the virus. The viral dUTPase may play a role in lowering the dUTP concentration in natural infections to minimize misincorporation of deoxyuridine into the viral DNA and ensure the fidelity of genome replication.

Virus-specific cell receptors are necessary, but not sufficient, to confer cell susceptibility to African swine fever virus

The entry of African swine fever (ASF) virus into Vero cells and swine macrophages is mediated by saturable binding sites located in the plasma membrane, which have been related, as in other virus-cell systems, to the sensitivity of the cell to the virus. In order to define this correlation, we have analyzed up to 16 cell lines derived from different species for their sensitivity to virus infection, to determine the step in the virus infective cycle that was blocked in each resistant cell, the presence of saturable cell receptors and the percentage of bound and internalized virus in these cells. Specific ASF virus receptors were found in different quantities in many sensitive and resistant cell lines. The most restricted cells showed a reduced efficiency of virus binding and virus internalization, as well as a lower amount of cell receptors for the virus attachment protein p12. Other resistant cells were restricted only after early virus translation or virus DNA replication, proving that the presence of virus-specific receptors may be necessary, but not sufficient, to guarantee the cell permissiveness to the virus, and that the ASF virus infection can be arrested at different steps on the infective cycle.

The African swine fever virus prenyltransferase is an integral membrane trans-geranylgeranyl-diphosphate synthase

In a previous study, it was shown that the protein encoded by the gene B318L of African swine fever virus (ASFV) is a trans-prenyltransferase that catalyzes in vitro the condensation of farnesyl diphosphate and isopentenyl diphosphate to synthesize geranylgeranyl diphosphate and longer chain prenyl diphosphates (Alejo, A., Yáñez, R. J., Rodríguez, J. M., Viñuela, E., and Salas, M. L. (1997) J. Biol. Chem. 272, 9417-9423). To investigate the in vivo function of the viral enzyme, we have determined, in this work, its subcellular localization and activity in cell extracts. Two systems were used in these studies: cells infected with ASFV and cells infected with a recombinant pseudo-Sindbis virus carrying the complete B318L gene. In this latter system, the trans-prenyltransferase was found to colocalize with the endoplasmic reticulum marker protein-disulfide isomerase, whereas in cells infected with ASFV, the viral enzyme was present in cytoplasmic viral assembly sites, associated with precursor viral membranes derived from the endoplasmic reticulum. In addition, after subcellular fractionation, the viral enzyme partitioned into the membrane fraction. Extraction of membrane proteins with alkaline carbonate and Triton X-114 indicated that the ASFV enzyme behaved as an integral membrane protein. The membrane enzyme synthesized predominantly all-trans-geranylgeranyl diphosphate from farnesyl diphosphate and isopentenyl diphosphate. These results indicate that the viral B318L protein is a trans-geranylgeranyl-diphosphate synthase, being the only enzyme of this type that is known to have a membrane localization.

Replication of African swine fever virus DNA in infected cells

We have examined the ultrastructural localization of African swine fever virus DNA in thin-sections of infected cells by in situ hybridization and autoradiography. Virus-specific DNA sequences were found in the nucleus of infected Vero cells at early times in the synthesis of the viral DNA, forming dense foci localized in proximity to the nuclear membrane. At later times, the viral DNA was found exclusively in the cytoplasm. Electron microscopic autoradiography of African swine fever virus-infected macrophages showed that the nucleus is also a site of viral DNA replication at early times. These results provide further evidence of the existence of nuclear and cytoplasmic stages in the synthesis of African swine fever virus DNA. On the other hand, alkaline sucrose sedimentation analysis of the replicative intermediates synthesized in the nucleus and cytoplasm of infected macrophages showed that small DNA fragments ( approximately 6-12S) were synthesized in the nucleus at an early time, whereas at later times, larger fragments of approximately 37-49S were labeled in the cytoplasm. Pulse-chase experiments demonstrated that these fragments are precursors of the mature cross-linked viral DNA. The formation of dimeric concatemers, which are predominantly head-to-head linked, was observed by pulsed-field electrophoresis and restriction enzyme analysis at intermediate and late times in the replication of African swine fever virus DNA. Our findings suggest that the replication of African swine fever virus DNA proceeds by a de novo start mechanism with the synthesis of small DNA fragments, which are then converted into larger size molecules. Ligation or further elongation of these molecules would originate a two-unit concatemer with dimeric ends that could be resolved to generate the genomic DNA by site-specific nicking, rearrangement, and ligation as has been proposed in the de novo start model of Baroudy et al. (B. M. Baroudy, S. Venkatesam, and B. Moss, 1982, Cold Spring Harbor Symp. Quant. Biol. 47, 723-729) for the replication of vaccinia virus DNA.

African swine fever virus is enveloped by a two-membraned collapsed cisterna derived from the endoplasmic reticulum

During the cytoplasmic maturation of African swine fever virus (ASFV) within the viral factories, the DNA-containing core becomes wrapped by two shells, an inner lipid envelope and an outer icosahedral capsid. We have previously shown that the inner envelope is derived from precursor membrane-like structures on which the capsid layer is progressively assembled. In the present work, we analyzed the origin of these viral membranes and the mechanism of envelopment of ASFV. Electron microscopy studies on permeabilized infected cells revealed the presence of two tightly apposed membranes within the precursor membranous structures as well as polyhedral assembling particles. Both membranes could be detached after digestion of intracellular virions with proteinase K. Importantly, membrane loop structures were observed at the ends of open intermediates, which suggests that the inner envelope is derived from a membrane cisterna. Ultraestructural and immunocytochemical analyses showed a close association and even direct continuities between the endoplasmic reticulum (ER) and assembling virus particles at the bordering areas of the viral factories. Such interactions become evident with an ASFV recombinant that inducibly expresses the major capsid protein p72. In the absence of the inducer, viral morphogenesis was arrested at a stage at which partially and fully collapsed ER cisternae enwrapped the core material. Together, these results indicate that ASFV, like the poxviruses, becomes engulfed by a two-membraned collapsed cisterna derived from the ER.

Vaccinia virus-induced apoptosis in immature B lymphocytes: role of cellular Bcl-2

Apoptosis is a form of physiological cell death which can be initiated in response to various stimuli including virus infections. We show that vaccinia virus (VV) infection induces apoptosis in an immature B lymphocyte line, WEHI-231. In these cells, several VV-specific proteins were synthesized during the infection, but neither virus production nor viral DNA synthesis were detected. The intracellular levels of the proto-oncogene Bcl-2, which effectively protects cells from programmed cell death, were found to be down-regulated by the VV infection, suggesting that this down-regulation might be involved in the viral induction of apoptosis in WEHI-231 cells. Stable transfectants overexpressing human Bcl-2 were shown to be resistant to the apoptosis produced by the infection, a finding consistent with the proposed role for the down-regulation of endogenous Bcl-2 in VV-induced apoptotic death.

Migration of mitochondria to viral assembly sites in African swine fever virus-infected cells

An examination by electron microscopy of the viral assembly sites in Vero cells infected with African swine fever virus showed the presence of large clusters of mitochondria located in their proximity. These clusters surround viral factories that contain assembling particles but not factories where only precursor membranes are seen. Immunofluorescence microscopy revealed that these accumulations of mitochondria are originated by a massive migration of the organelle to the virus assembly sites. Virus infection also promoted the induction of the mitochondrial stress-responsive proteins p74 and cpn 60 together with a dramatic shift in the ultrastructural morphology of the mitochondria toward that characteristic of actively respiring organelles. The clustering of mitochondria around the viral factory was blocked in the presence of the microtubule-disassembling drug nocodazole, indicating that these filaments are implicated in the transport of the mitochondria to the virus assembly sites. The results presented are consistent with a role for the mitochondria in supplying the energy that the virus morphogenetic processes may require and make of the African swine fever virus-infected cell a paradigm to investigate the mechanisms involved in the sorting of mitochondria within the cell.

Inducible gene expression from African swine fever virus recombinants: analysis of the major capsid protein p72

A method to study the function of individual African swine fever virus (ASFV) gene products utilizing the Escherichia coli lac repressor-operator system has been developed. Recombinant viruses containing both the lacI gene encoding the lac repressor and a strong virus late promoter modified by the insertion of one or two copies of the lac operator sequence at various positions were constructed. The ability of each modified promoter to regulate expression of the firefly luciferase gene was assayed in the presence and in the absence of the inducer isopropyl beta-D-thiogalactoside (IPTG). Induction and repression of gene activity were dependent on the position(s) of the operator(s) with respect to the promoter and on the number of operators inserted. The ability of this system to regulate the expression of ASFV genes was analyzed by constructing a recombinant virus inducibly expressing the major capsid protein p72. Electron microscopy analysis revealed that under nonpermissive conditions, electron-dense membrane-like structures accumulated in the viral factories and capsid formation was inhibited. Induction of p72 expression allowed the progressive building of the capsid on these structures, leading to assembly of ASFV particles. The results of this report demonstrate that the transferred inducible expression system is a powerful tool for analyzing the function of ASFV genes.

Inhibition of nuclear factor kappaB activation by a virus-encoded IkappaB-like protein

Certain viruses have evolved mechanisms to counteract innate immunity, a host response in which nuclear factor kappaB (NF-kappaB) transcription factors play a central role. African swine fever virus encodes a protein of 28.2 kDa containing ankyrin repeats similar to those of cellular IkappaB proteins, which are inhibitors of NF-kappaB. Transfection of the African swine fever virus IkappaB gene inhibited tumor necrosis factor- or phorbol ester-induced activation of kappaB- but not AP-1-driven reporter genes. Moreover, African swine fever virus IkappaB co-immunoprecipitated with p65 NF-kappaB, and the purified recombinant protein prevented the binding of p65-p50 NF-kappaB proteins to their target sequences in the DNA. NF-kappaB activation induced by tumor necrosis factor, as detected by mobility shift assays or by transfection of kappaB-driven reporter genes, is impaired in African swine fever virus-infected cells. These results indicate that the African swine fever virus IkappaB gene homologue interferes with NF-kappaB activation, likely representing a new mechanism to evade the immune response during viral infection.

Characterization of an African swine fever virus 20-kDa DNA polymerase involved in DNA repair

African swine fever virus (ASFV) encodes a novel DNA polymerase, constituted of only 174 amino acids, belonging to the polymerase (pol) X family of DNA polymerases. Biochemical analyses of the purified enzyme indicate that ASFV pol X is a monomeric DNA-directed DNA polymerase, highly distributive, lacking a proofreading 3'-5'-exonuclease, and with a poor discrimination against dideoxynucleotides. A multiple alignment of family X DNA polymerases, together with the extrapolation to the crystal structure of mammalian DNA polymerase beta (pol beta), showed the conservation in ASFV pol X of the most critical residues involved in DNA binding, nucleotide binding, and catalysis of the polymerization reaction. Therefore, the 20-kDa ASFV pol X most likely represents the minimal functional version of an evolutionarily conserved pol beta-type DNA polymerase core, constituted by only the "palm" and "thumb" subdomains. It is worth noting that such an "unfingered" DNA polymerase is able to handle templated DNA polymerization with a considerable high fidelity at the base discrimination level. Base excision repair is considered to be a cellular defense mechanism repairing modified bases in DNA. Interestingly, the fact that ASFV pol X is able to conduct filling of a single nucleotide gap points to a putative role in base excision repair during the ASFV life cycle.

Proteolytic processing in African swine fever virus: evidence for a new structural polyprotein, pp62

We have identified an open reading frame (ORF), CP530R, within the EcoRI C' fragment of the African swine fever virus (ASFV) genome that encodes a polyprotein of 62 kDa (pp62). Antisera raised against different regions of ORF CP530R recognized a polypeptide of 62 kDa in ASFV-infected cells during the late phase of virus replication, after the onset of viral DNA synthesis. Pulse-chase experiments showed that polyprotein pp62 is posttranslationally processed to give rise to two proteins of 35 kDa (p35) and 15 kDa (p15). This proteolytic processing was found to take place at the consensus sequence Gly-Gly-X through an ordered cascade of proteolytic cleavages like that which also occurs with ASFV polyprotein pp220 (C. Simón-Mateo, G. Andrés, and E. Viñuela, EMBO J. 12:2977-2987, 1993). Immunofluorescence studies showed that polyprotein pp62 is localized in the viral factories. In addition, immunoprecipitation analysis of purified virus particles showed that mature products p35 and p15 are major structural proteins. According to these results, polyprotein processing represents an essential strategy for the maturation of ASFV structural proteins.

Virus-like particules in the poison glant of the parasitic wasp Opius concolor

Virus-like particles (VLP's) have been found in the poison glands of adult females of the parasitic wasp Opius concolor Szèpl. (Hymenoptera, Braconidae). These VLP's are found in the secretory cells either free in the cytoplasm or within cytoplasmic vesicles, sometimes associated to a secretory apparatus. Negative staining of these VLP's has revealed the occurrence of two different particles. The first type exhibits icosahedral symmetry (diameter around 70nm) and hollow surface spikes, this morphology being typical of the genus Cypovirus (Reoviridae). The other type is pleomorphic and presents an envelope with clubshaped projections (diameter ranging from 30 to 60nm), as classical textbook examples of Coronaviruses, but smaller. Function and full characterisation of these particles are not yet known.

African swine fever virus-specific cytotoxic T lymphocytes recognize the 32 kDa immediate early protein (vp32)

African swine fever (ASF) virus-specific cytotoxic T lymphocyte (CTL) activity has been studied in a model in which SLA inbred minipigs were experimentally infected with an attenuated isolate of the virus. The CTL assays were performed using alveolar macrophages as target cells. The specific lysis is mediated by purified CD8+ lymphocytes but not by CD4+ cells and can be blocked by incubation with anti-SLA class I monoclonal antibodies. The purified CD8+ population produced high levels of interferon-gamma after ASF virus stimulation. In an attempt to define the viral proteins recognized by CTL, target cells infected with a recombinant vaccinia virus (VV) expressing the ASF virus p32, an immediate early protein during ASF virus replication, were recognized and lysed by CTL. This assay may be useful for VV recombinant screening in order to identify other potential target ASF virus proteins.

Protein cell receptors mediate the saturable interaction of African swine fever virus attachment protein p12 with the surface of permissive cells

Previous studies have demonstrated that the entry of African swine fever virus (ASFV) into Vero cells and swine macrophages is mediated by saturable binding sites located on the plasma membrane. The ASFV protein p12 has been implicated in virus attachment to the host cell, but the cellular component responsible for the interaction with the virus is largely unknown. We have studied the binding of recombinant p12 and ASFV to different cell lines. Permissive cells were able to bind p12 in saturable and nonsaturable interactions, as reported for ASFV. Experiments of binding recombinant p12 have been used for the initial characterization of the specific receptors on Vero cells. The treatment of cell surfaces with different enzymes and lectins resulted in the inhibition of the p12 binding activity by several proteases, but not by glycosidases or lipase, suggesting that the receptor is composed of protein, with no carbohydrates or lipids involved in the virus attachment to the cellular membrane. The recovery of receptor activity after pronase treatment was completed in 6 h in culture medium containing tunicamycin, and could not be restored in the presence of cycloheximide, confirming that synthesis of new proteins, but not glycosylation, was required for the recovery of the receptor activity. These data support the idea that membrane protein(s) on the surface of permissive cells act as receptors for ASFV and that this specific interaction is, at least, one necessary step in a productive virus infection.

African swine fever virus trans-prenyltransferase

The present study describes the characterization of an African swine fever virus gene homologous to prenyltransferases. The gene, designated B318L, is located within the EcoRI B fragment in the central region of the virus genome, and encodes a polypeptide with a predicted molecular weight of 35,904. The protein is characterized by the presence of a putative hydrophobic transmembrane domain at the amino end. The gene is expressed at the late stage of virus infection, and transcription is initiated at positions -118, -119, -120, and -122 relative to the first nucleotide of the translation start codon. Protein B318L presents a colinear arrangement of the four highly conserved regions and the two aspartate-rich motifs characteristic of geranylgeranyl diphosphate synthases, farnesyl diphosphate synthases, and other prenyltransferases. Throughout these regions, the percentages of identity between protein B318L and various prenyltransferases range from 28.6 to 48.7%. The gene was cloned in vector pTrxFus without the amino-terminal hydrophobic region and expressed in Escherichia coli. The recombinant protein, purified essentially to homogeneity by affinity chromatography, catalyzes the sequential condensation of isopentenyl diphosphate with different allylic diphosphates, farnesyl diphosphate being the best allylic substrate of the reaction. All-trans-polyprenyl diphosphates containing 3-13 isoprene units are synthesized, which identifies the B318L protein as a trans-prenyltransferase.

Characterization of the African swine fever virus structural protein p14.5: a DNA binding protein

The gene encoding the structural protein p14.5 of African swine fever virus (ASFV) has been mapped and sequenced. This gene, designated E120R, is located in the Sa/l H/EcoRl E restriction fragment of the ASFV genome and is predicted to encode a protein of 120 amino acids with a molecular weight of 13.4 kDa. Northern-blot analysis showed that E120R is transcribed at late times during the viral replication cycle. The E120R gene product has been expressed in Escherichia coli, purified, and used as an antigen for antibody production. The antiserum anti-pE120R recognized a protein in infected cell extracts with an apparent molecular mass of 14.5 kDa, named p14.5. This antiserum also detected protein p14.5 in purified virus particles. Protein p14.5 is synthesized late in infection and is located in viral factories. Immunoprecipitation analysis and binding-assay experiments have shown that protein p14.5 interacts with a protein that could correspond to the major structural protein p72. Purified protein p14.5 interacts with DNA in a sequence-independent manner. It binds to both single-stranded and double-stranded DNA. A possible role of protein p14.5 in the encapsidation of ASFV DNA is suggested.

Assembly of African swine fever virus: role of polyprotein pp220

Polyprotein processing is a common strategy of gene expression in many positive-strand RNA viruses and retroviruses but not in DNA viruses. African swine fever virus (ASFV) is an exception because it encodes a polyprotein, named pp220, to produce several major components of the virus particle, proteins p150, p37, p34, and p14. In this study, we analyzed the assembly pathway of ASFV and the contribution of the polyprotein products to the virus structure. Electron microscopic studies revealed that virions assemble from membranous structures present in the viral factories. Viral membranes became polyhedral immature virions after capsid formation on their convex surface. Beneath the lipid envelope, two distinct domains appeared to assemble consecutively: first a thick protein layer that we refer to as core shell and then an electron-dense nucleoid, which was identified as the DNA-containing domain. Immunofluorescence studies showed that polyprotein pp220 is localized in the viral factories. At the electron microscopic level, antibodies to pp220 labeled all identifiable forms of the virus from the precursor viral membranes onward, thus indicating an early role of the polyprotein pp220 in ASFV assembly. The subviral localization of the polyprotein products, examined on purified virions, was found to be the core shell. In addition, quantitative studies showed that the polyprotein products are present in equimolar amounts in the virus particle and account for about one-fourth of its total protein content. Taken together, these results suggest that polyprotein pp220 may function as an internal protein scaffold which would mediate the interaction between the nucleoid and the outer layers similarly to the matrix proteins of other viruses.

Inhibition of apoptosis by the African swine fever virus Bcl-2 homologue: role of the BH1 domain

The function of the African swine fever virus (ASFV) bcl-2 homologue, gene A179L, in the regulation of apoptosis was investigated using as a model system the human myeloid leukemia cell line K562 induced to die by apoptosis with inhibitors of macromolecular synthesis, a process that is prevented by overexpression of human bcl-2. It is shown that transfection of K562 cells with the ASFV A179L gene protects these cells from apoptotic cell death induced by a combination of cycloheximide and actinomycin D or by treatment with cytosine arabinoside. To test the functional role of the highly conserved BH1 domain present in the A179L protein, the Gly residue at position 85 was mutated to Ala, since it has been shown that substitution of the corresponding Gly in human Bcl-2 abrogates its death-repressor activity. It was found that the Gly-to-Ala mutation in the BH1 domain of the viral protein abolished its capacity to protect the K562 cells from apoptosis, indicating that this Gly is essential for A179L action. This finding stresses the functional similarity of the BH1 domains of the viral protein and cellular Bcl-2.

Intermediate class of mRNAs in African swine fever virus

A transcriptional analysis of the African swine fever virus (ASFV) I226R and I243L genes is presented. Steady-state kinetics and transfection experiments showed the existence of a new temporal class of ASFV mRNAs transcribed from these genes, with the characteristics of the poxvirus intermediate transcripts. Transcription of the I226R gene gave rise to intermediate and late mRNAs that started from different sites, while the I243L gene produced early, intermediate, and late mRNAs, also starting from different sites. The presence of intermediate genes suggests a cascade model for the regulation of ASFV gene expression.

The African swine fever virus IAP homolog is a late structural polypeptide

The analysis of the complete nucleotide sequence of the African swine fever virus genome has revealed the existence of a number of genes potentially capable of modifying the host's response to the virus infection. In this report, we describe the results of the characterization of the A224L gene that encodes a novel member of the family of apoptosis inhibitors known as IAP proteins. A224L is expressed during the late phase of the infectious cycle, and its polypeptide product is assembled into virus particles.

Vectors for the genetic manipulation of African swine fever virus

Plasmid vectors designed to facilitate the genetic manipulation of African swine fever virus (ASFV) are described. Our results demonstrate that the beta-glucuronidase enzyme (GUS) can be used to follow gene expression in ASFV-infected cells. Infectious plaques formed by ASFV expressing GUS are visually detectable, thus providing a simple and highly sensitive method for the selection of ASFV recombinants. These and previous results have allowed us to construct two chimeric gene cassettes that constitute the basic tools for the generation of vectors to carry out the deletion of multiple target sequences from the ASFV genome. These cassettes, formed by: (a) a virus promoter; (b) the coding sequence of a reporter gene, either Lac Z or gusA; and (c) a strong signal for the 3' end formation of ASFV mRNAs, can be easily isolated by endonuclease restriction from their corresponding plasmid vectors. A general insertion/coexpression plasmid vector, pEPV2, has also been constructed. pEPV2 facilitates the insertion of foreign genes, together with the Lac Z reporter, into the thymidine kinase locus of ASFV. The functionality of pEPV2 has been tested by generating a recombinant ASFV expressing the luciferase gene. The vectors presented in this report constitute the first reported set of tools for the genetic manipulation of ASFV.

Production and purification of recombinant African swine fever virus attachment protein p12

The conditions for cultivation of Spodoptera frugiperda (Sf9) insect cells for production of recombinant baculoviruses have been studied, to scale-up and improve the efficiency of the process for production of the African swine fever virus attachment protein p12 in the baculovirus expression system. It was shown that the total virus and recombinant protein production in insect cells infected with the Acp12 recombinant baculovirus were slightly dependent on cell density, but largely dependent on the serum concentration, in the case of suspended cells, but not in static monolayer cultures. The yield of recombinant protein p12 exceeded 50 mg per 1 of 2 x 10(9) cells, representing more than 10% of total cell proteins, a level > 20-fold higher than that observed with other eukaryotic expression systems. The presence of p12 in the cytoplasmic fraction of infected cells has allowed the purification of the protein by a simple two-step procedure of aqueous phase partition and octyl-glucoside solubilization. The recombinant protein p12 was able to inhibit, in a dose-dependent manner, the African swine fever virus production in swine macrophages infected with a number of different virus isolates, including attenuated, virulent, highly passaged on tissue culture, and non-haemadsorbing strains, indicating a fundamental role for p12 in the early interaction of the virus with the natural target cell receptors. However, pigs immunized with purified recombinant p12 did not develop protective immunity against African swine fever.

Analysis of the complete nucleotide sequence of African swine fever virus

We present an analysis of the complete genome of African swine fever virus (ASFV) strain BA71V, including 80 kbp of novel sequence and 90 kbp previously reported by several authors. The viral DNA is 170,101 nucleotides long and contains 151 open reading frames. Structural and/or functional information is available on 113 viral proteins. ASFV encodes five multigene families, putative membrane and secreted proteins, and enzymes involved in nucleotide and nucleic acid metabolism (including DNA repair) and protein modification. Database comparisons have provided clues about genes that may modulate the virus-host interaction, thus, possibly controlling ASFV virulence and persistence. The virus possesses genes similar to CD2, IkappaB, C-type lectins, MyD116/gadd34/gamma, 34.5, bcl-2/bax, iap, NifS, and ERV1, which may allow a viral regulation of cell adhesion, apoptosis, and redox metabolism, as well as of the host immune response against ASFV infection. The proteins encoded by different ASFV isolates are highly similar, the most variable ones being those belonging to multigene families, some membrane proteins, and those containing tandem repeats. DNA sequence data confirm the intermediate characteristics of ASFV between poxviruses and iridoviruses, supporting the notion that ASFV belongs to an independent virus family.

A set of African swine fever virus tandem repeats shares similarities with SAR-like sequences

A group of cross-hybridizing DNA segments contained within the EcoRI restriction fragments U', X and J of a Vero cell-adapted strain (BA71V) of African swine fever virus (ASFV) were mapped and sequenced. Analysis of the nucleotide sequence revealed the presence of a set of long internal repeated sequences composed of five types of tandemly repeat units of about 200 bp. These tandem repeats contain a G-rich core of 10-14 nucleotides surrounded by regions with a high A + T content distributed in oligo(dA).oligo(dT) tracts. Next to the repeated sequences we detected two related open reading frames that are members of a new multigene family (multigene family 300). Comparison of DNA sequences from several virus isolates indicated that this region undergoes frequent rearrangements leading to either duplications or deletions of the repeat units. These ASFV repeated sequences share similarities with chromosomal alpha satellite DNA, the scaffold-associated region and satellite III of Drosophila. Similar tandemly repeated sequences have not been described in other viruses.

Mapping and sequence of the gene encoding protein p17, a major African swine fever virus structural protein

The gene encoding protein p17, a major structural protein of African swine fever virus, has been mapped and sequenced. Protein p17 was purified from dissociated virus by reverse-phase HPLC and the amino acid sequence of a peptide obtained after digestion of protein p17 with cyanogen bromide was determined by automated Edman degradation. To map the gene encoding protein p17, a mixture of 17-mer oligonucleotides based upon a part of the amino acid sequence was hybridized to cloned African swine fever virus DNA restriction fragments. This allowed the location of the gene in the fragment EcoRI D of the viral genome. The nucleotide sequence of a Sa/l/KpnI fragment revealed an open reading frame designated D117R encoding a protein of 117 amino acids with a deduced molecular mass of about 13,000 Da. A transcriptional analysis revealed that the p17 gene is expressed late in the viral infection cycle.

The role of fibrinolysis in the pathogenesis of the haemorrhagic syndrome produced by virulent isolates of African swine fever virus

The activity of several proteins involved in fibrinolysis and the morphological changes in the blood vessel walls of pigs infected with highly virulent (Malawi'83) and moderately virulent (Dominican Republic '78-DR'78) ASF virus isolates were determined. Pigs infected with the Malawi'83 virus developed an increased fibrinolytic activity due to high plasma levels of tissue-plasminogen activator (t-PA) of 71.3 +/- 22.8 IU/ml (mean +/- SD), which correlated well with an increased activation of interstitial capillary endothelial cells and high levels of 1150 +/- 73.6 nM of fibrin monomer in the circulation. Animals infected with DR'78 virus, in contrast, showed an inhibition of fibrinolysis in the late stages of disease with almost a 5-fold increase of plasminogen activator inhibitor (PAI) activity of 196.0 AU/ml. These results suggest that activation of the fibrinolytic system in pigs infected with the Malawi'83 virus is probably due to increased formation and deposition of fibrin in the circulation, contributing to an increased bleeding tendency and higher mortality. On the contrary, animals infected with DR'78 virus developed an inhibition of fibrinolysis and thus a reduction in bleeding.

Swine-reconstituted SCID mice as a model for African swine fever virus infection

Injection of swine peripheral blood mononuclear cells into mice with severe combined immunodeficiency (SCID), resulted in the stable long-term establishment of a functional swine immune system (SCID-sw). Swine immunoglobulins were present in the serum of SCID-sw mice and swine cells were detected in the blood as well as in lymph nodes and spleen using monoclonal antibodies raised against cell subpopulations. Swine lymphocytes from reconstituted SCID mice responded in vitro to specific antigens or mitogens. When SCID-sw mice were challenged with African swine fever (ASF) virus, ASF virus-infected cells were detected in blood and spleen, and antiviral antibodies and virus-specific T cells were generated.

Nucleotide sequence and variability of the inverted terminal repetitions of African swine fever virus DNA

African Swine fever virus (ASFV) genome is a large (170-190 kb) double-stranded DNA molecule with structural features similar to those of Poxviruses. Prominent among those features are the presence of a hairpin loop structure at the end of the DNA molecule and terminal-inverted repeats (TIR). The TIRs have been previously demonstrated by electron microscopy and cross-hybridization of terminal restriction fragments. We have determined the sequence of both left and right DNA ends from the BA71V virus strain. The TIR is composed of 2134 bp and was identical at both genome ends. As much as 82% of the TIR sequence is made up of short (27-35 bp) sequences repeated within the TIR, in five different sets of repeats. The central portion of the TIR is occupied by a 34-bp sequence which is repeated in tandem 33 times. Length differences were found within TIRs of virus clones isolated from a single infected animal. The ASFV TIR resembles in structure the TIR of the related Poxviruses.

Multigene families in African swine fever virus: family 505

Sequencing of restriction fragment EcoRI A-SalI C of African swine fever virus has revealed the existence of a multigene family, designated family 505 because of the average number of amino acids in the proteins, composed of seven homologous and tandemly arranged genes. All the genes of family 505 are expressed during infection. Primer extension analysis showed that transcription is initiated a short distance (3 to 62 nucleotides) from the start codon of the corresponding open reading frame. The proteins of family 505 showed similarity to those of family 360 from African swine fever virus. In particular, a striking conservation of three regions at the amino terminus of the polypeptides was observed.

The DNA polymerase-encoding gene of African swine fever virus: sequence and transcriptional analysis

The putative DNA polymerase-encoding gene of African swine fever virus has been sequenced. The gene, designated G1207R, is located in the central region of the viral genome, and encodes a protein of 1207 amino acids (aa) with a predicted M(r) of 139,835. The gene is transcribed at both early and late stages of infection into a 4.1-kb RNA. Transcription is initiated at tsp, 8 nucleotides (nt) upstream from the start codon. Open reading frame (ORF) G1207R contains four direct repeats in tandem close to the 3'-end. Each repeat consists of 12 nt, coding for the reiterated sequence, K/NPAG. The deduced aa sequence of G1207R shows significant similarity with DNA polymerases from cellular and viral origin, belonging to the alpha-like family of DNA polymerases. In particular, the G1207R protein presents a colinear arrangement of all the 3'-->5' exonuclease and polymerization highly conserved aa regions characteristic of this group of DNA-dependent DNA polymerases.

Two putative African swine fever virus helicases similar to yeast 'DEAH' pre-mRNA processing proteins and vaccinia virus ATPases D11L and D6R

Two open reading frames (ORFs) of African swine fever virus (ASFV) encoding putative helicases have been sequenced. The two genes, termed D1133L and B962L, are located in the central region of the viral genome, but are separated by about 40 kb of DNA. Both genes are expressed late during ASFV infection of Vero cells, after replication of viral DNA has begun. Contiguous to D1133L, three other ORFs (D129L, D79L and D339L), encoding putative proteins of unknown function, have been sequenced. Proteins D1133L and B962L contain the amino acid motifs that characterize helicases of superfamily II. D1133L is most similar to a group of putative helicases which includes two proteins of vaccinia virus (D11L and D6R) involved in transcription of the viral genome, their homologues in other poxviruses, the protein encoded by ORF 4 of the yeast plasmids, pGKL2 and pSKL, and the previously identified ASFV protein, Q706L. B962L resembles a group of RNA-helicase-like proteins which includes three proteins of Saccharomyces cerevisiae involved in pre-mRNA splicing (PRP2, PRP16 and PRP22), Drosophila melanogaster KURZ and MLE, and vaccinia virus 18R.

Mapping and sequence of the gene encoding the African swine fever virion protein of M(r) 11500

The gene encoding the African swine fever virus protein of M(r) 11,500, present in the virus particle, has been mapped and sequenced in the genome of the Vero cell-adapted virus strain BA71V. A serum raised against virion proteins of M(r) 12,000 to 13,000 isolated from polyacrylamide gels was used to screen a plasmid expression library, containing viral DNA random fragments, that expresses viral polypeptides fused to beta-galactosidase. Using this method, we have identified and sequenced the open reading frame (ORF) A137R, which initiates at the right end of the EcoRI A restriction fragment and extends into the EcoRI F fragment. Expression of the protein in Escherichia coli has confirmed that ORF A137R encodes a protein with an M(r) of about 12,000. A specific serum was raised against the E. coli-expressed protein, and has been used to identify the protein encoded by the ORF, which is translated at late times of infection and incorporated into the virus particle. Immunofluorescence experiments have shown that the protein localizes in virus factories.

Nucleotide sequence of a nucleoside triphosphate phosphohydrolase gene from African swine fever virus

A putative nucleoside triphosphate phosphohydrolase (NTPase) gene of African swine fever virus was identified by using a degenerate oligonucleotide probe derived from the nucleoside triphosphate binding motif, which is highly conserved among viral and cellular NTPases. The probe hybridized with fragments SalI E and EcoRI Q, which is entirely contained in the former one. Sequencing of this region revealed an open reading frame, designated Q706L, coding for a protein of 706 amino acids, with a calculated molecular weight of 80,283. The deduced amino acid sequence of this open reading frame has significant similarity with the putative helicase encoded by the killer plasmid pGKL2 of Kluyveromyces lactis as well as with the NTPase I of vaccinia virus and entomopoxvirus and a subunit of the early transcription factor of vaccinia and fowlpox virus. The protein encoded by this open reading frame contains the sequence features characteristic of helicases of the superfamily II. According to this, we propose the inclusion of the product of this ASF virus gene in this superfamily.

Consumption coagulopathy associated with shock in acute African swine fever

We studied the evolution of shock using a comprehensive array of haematological tests in pigs infected with the highly virulent strain Malawi '83 (Lilongwe 20/1). A sudden onset of illness was observed between day 5 and 7 after inoculation with development of flush, episodes of epistaxis and melaena. Prior to these clinical signs, initiation of a consumption coagulopathy was demonstrated with loss of antithrombin III and plasminogen activity. Our findings indicate that during infection with this highly virulent strain the development of a consumption coagulopathy precedes and possibly contributes to shock, which results in haemorrhage and death.

African swine fever virus encodes a CD2 homolog responsible for the adhesion of erythrocytes to infected cells

We have identified an open reading frame, EP402R, within the EcoRI E' fragment of the African swine fever virus genome that encodes a polypeptide of 402 amino acid residues homologous to the adhesion receptor of T cells, CD2. Transcription of EP402R takes place during the late phase of virus replication. The disruption of EP402R, achieved through the replacement of a 354-bp-long fragment from within EP402R by the marker gene lacZ, does not affect the virus growth rate in vitro but abrogates the ability of the virus to induce the adsorption of pig erythrocytes to the surface of infected cells. This result demonstrates that the protein encoded by EP402R is directly involved in the hemadsorption phenomenon induced by the infection of susceptible cells with African swine fever virus.

Inhibition of African swine fever virus binding and infectivity by purified recombinant virus attachment protein p12

The African swine fever virus protein p12, involved in virus attachment to the host cell, has an apparent molecular mass of 17 kDa in sodium dodecyl sulfate-polyacrylamide gel electrophoresis under nonreducing conditions. We have also identified 12- and 10-kDa forms of the p12 protein in infected Vero cells and found that the mature 17-kDa protein is the only form present in virus particles. The p12 protein has been produced in large amounts in Spodoptera frugiperda insect cells infected with a recombinant baculovirus. A 17-kDa protein that possessed the biological properties of the viral protein was produced, since it bound to susceptible Vero cells and not to receptor-negative L cells, which do not support virus replication. The binding of the baculovirus-expressed protein p12 to Vero cells was specifically blocked by virus particles. In addition, the recombinant protein purified by immunoaffinity chromatography blocked the specific binding of virus particles to susceptible cells and prevented infection, demonstrating that the p12 protein mediates the attachment of virions to specific receptors and indicating that blocking the p12-mediated interaction between African swine fever virus and receptors in Vero cells can inhibit infection. However, although antibodies specific for protein p12 are induced in natural infections and in animals inoculated with inactivated virus or recombinant protein p12, these antisera did not inhibit virus binding to the host cell or neutralize virus infectivity.