Some factors involved in the dissolution of Autographa californica nuclear polyhedrosis virus polyhedra by digestive fluids of Trichoplusia ni larvae

Factors involved in the dissolution of polyhedra of Autographa californica nuclear polyhedrosis virus (AcNPV) by digestive fluid collected from fifth stage Trichoplusia ni larvae were studied in vitro. Observations were made at timed intervals using phase contrast microscopy and transmission electron microscopy. When digestive fluid was heated at 50°C proteases retained activity. Exposure of polyhedra to digestive fluid previously heated to 50°C resulted in polyhedral matrix dissolution and envelope disruption in a manner similar to that of unheated digestive fluid, only delayed slightly. After exposure of polyhedra for 3 min, only enveloped virons were observed. Heating the digestive fluid to 60° or higher inactivated the proteases and altered the effect on polyhedra. Dissolution of the occlusion body matrix occurred but the polyhedral envelope remained and only a few weakened areas were observed in its structure. Within the polyhedral envelope, enveloped virons were not observed, only nucleocapsids and capsids. Exposure of polyhedra to 0.1 m sodium carbonate buffer at pHs of 9.5 or higher had effects similar to those of the digestive fluid with heat (60°C)-inactivated proteases. The addition of trypsin and chymotrypsin to the 0.1 m sodium carbonate buffer had no effect, while the addition of a bacterial protease (Streptomyces griseus) at pHs of 9.5 or higher resulted in dissolution of the matrix and disruption of the polyhedral envelope like the digestive fluid. Material infectious to TN-368 cells was obtained by exposure of AcNPV to T. ni digestive fluid. Maximum infectivity resulted from a 5-min exposure to unheated digestive fluid, with a dramatic decrease in infectivity with longer exposure. Exposure to digestive fluid with heat (60°C)-inactivated proteases resulted in a slower release of infectious material from the occlusion body, with a steady increase in the level of infectivity throughout the 30-min digestion period.     

Effects of Substituting Granulin or a Granulin-Polyhedrin Chimera for Polyhedrin on Virion Occlusion and Polyhedral Morphology in Autographa californica Multinucleocapsid Nuclear Polyhedrosis Virus

Substitution of granulin from the Trichoplusia ni granulosis virus (TnGV) for polyhedrin of the Autographa californica multinucleocapsid nuclear polyhedrosis virus (AcMNPV) yielded a few very large (2 to 5 μm) cuboidal inclusions in the cytoplasm and nucleus of infected cells. These polyhedra lacked the beveled edges characteristic of wild-type AcMNPV polyhedra, contained fractures, and occluded few virions. Placing a nuclear localization signal (KRKK) in granulin directed more granulin to the nucleus and resulted in more structurally uniform cuboidal inclusions in which no virions were observed. A granulin-polyhedrin chimera produced tetrahedral occlusions with more virions than granulin inclusions but many fewer than wild-type polyhedra. Despite the unusual structure of the granulin and granulin-polyhedrin inclusions, they interacted with AcMNPV p10 fibrillar structures and electron-dense spacers that are precursors of the polyhedral calyx. The change in inclusion shape obtained with the granulin-polyhedrin chimera demonstrates that the primary amino acid sequence affects occlusion body shape, but the large cuboidal inclusions formed by granulin indicate that the amino acid sequence is not the only determinant. The failure of granulin or the granulin-polyhedrin chimera to properly occlude AcMNPV virions suggests that specific interactions occur between polyhedrin and other viral proteins which facilitate normal virion occlusion and occlusion body assembly and shape in baculoviruses.     

The effect of inoculum concentration on the development of the nuclear polyhedrosis virus of Autographa californica in TN-368 cells

A multiplicity of infection (m.o.i.) of 25 or 50 mean tissue culture-infective doses (TCID₅₀) of Autographa californica NPV per cell of a TN-368 cell line initially infected >90% of attached cells whereas an m.o.i. of 1 or 5 TCID₅₀/cell initially infected <50% of the cells. An immunoperoxidase technique first detected nucleocapsid antigens at 6–12 hr postinfection (PI) and polyhedral protein antigen 12–18 hr PI, which was followed 4–6 hr later by polyhedra formation. At a m.o.i. of 50, the extracellular virus titer (nonoccluded progeny virus) increased between 6 and 12 hr PI while at m.o.i. of 25, 5, and 1, the titer increased at 12–18 hr PI. Antisera to nucleocapsids and polyhedral protein were specific and also failed to react with viral envelope antigens.     

Chemotactic attraction of Crassostrea virginica hemolymph cells to Staphylococcus lactus.

The nuclear polyhedrosis virus (NPV) of Porthetria dispar was isolated and purified through a two-step zonal centrifugation procedure. The LD₅₀ of the purified NPV was determined by a dose-response assay. Quantitative analyses were made of whole polyhedra and of separated fractions of polyhedral protein, virus rods, and denatured material, i.e., the pellet obtained from low speed centrifugation of dissolved polyhedra, to determine the protein, DNA, and “RNA” (orcinol-positive material) present in this NPV. Approximately one-half the “RNA” was present in the denatured material. Trace elements were also determined, and four, Fe, Mg, Cu, and Zn, of the ten assayed were present in the polyhedral protein fraction, while only Mg and Zn were in the virus rod fraction.     

USE OF SERIAL SECTIONS TO DELINEATE THE STRUCTURE OF PORTHETRIA DISPAR VIRUS IN THE ELECTRON MICROSCOPE

Consecutive serial sections of polyhedra obtained from gipsy moth larvae infected with P. dispar virus revealed bundles of viral rods scattered and oriented at random within the polyhedral body. Each bundle was entirely surrounded by a dense, sharply defined membrane. The rods measured 18 to 22 mµ in diameter and averaged 280 mµ in length. No spherical viral particles were encountered. The effects of variable compression and periodic distortion of the sections on the appearance of the virus are discussed.     

Purification and properties of the Bombyx mori nuclear polyhedrosis virus liberated from polyhedra by dissolution with silkworm gut juice

Occluded virions of the Bombyx mori nuclear polyhedrosis virus were efficiently liberated from polyhedra by dissolution with the silkworm gut juice. The liberated virions were purified by sucrose density gradient centrifugation and the bands of enveloped virions were observed in the gradients. There was no functional difference between the gut juice-liberated and the carbonate-liberated virions. Disruption of enveloped virions by the gut juice was observed, but the formation of nucleocapsids from the degradation of the occluded virions was not detected. High yields of the enveloped virions from the polyhedra dissolved by the gut juice was obtained by separating the virions through sucrose density gradient centrifugation immediately after the dissolution of the polyhedra. Many factors, e.g., rearing seasons, silkworm strains, and rearing conditions, affect the polyhedra-dissolving property of the larval gut juice.     

Serological relationships among plusiinae baculoviruses

Antisera were produced against nucleocapsids, NP-40 detergent soluble proteins, or polyhedral protein of the multiply embedded nuclear polyhedrosis virus (MNPV) of Autographa californica, nucleocapsids of Trichoplusia ni singly embedded virus (SNPV), and polyhedral protein of Lymantria dispar MNPV. Antigens consisting of nucleocapsids, NP-40 soluble proteins, and polyhedral protein were prepared from A. californica MNPV, T. ni MNPV, L. dispar MNPV, Rachiplusia ou MNPV, T. ni SNPV, and Pseudoplusia includens SNPV. Radial immunodiffusion patterns formed with Plusiinae nucleocapsid antigens and antiserum to nucleocapsids of A. californica MNPV or T. ni SNPV revealed a distinction between multiply and singly embedded viruses. The same alignment of Plusiinae viruses was observed in reactions between A. californica NP-40 soluble protein antiserum and the NP-40 soluble protein fractions from the Plusiinae NPVs. There were no reactions between the Plusiinae SNPV nucleocapsid antigens and the A. californica MNPV nucleocapsid antiserum. However, there were faint precipitin bands between MNPV nucleocapsid antigens and T. ni SNPV nucleocapsid antiserum. Each of the polyhedral protein fractions from the Plusiinae formed a single precipitin band with the antiserum to polyhedral protein of either A. californica or L. dispar. The precipitin bands formed with the A. californica antiserum by polyhedral proteins of T. ni SNPV, P. includens SNPV, and R. ou MNPV were confluent, and shared partial identity with those formed by A. californica MNPV and T. ni MNPV. All precipitin bands formed by Plusiinae polyhedral proteins against antiserum to L. dispar polyhedral protein were confluent, and shared partial identity with that formed by L. dispar polyhedral protein.     

Co-Occlusion and Persistence of a Baculovirus Mutant Lacking the Polyhedrin Gene

A co-occlusion process was evaluated as a commercially and ecologically acceptable strategy for the development of genetically improved baculovirus insecticides. Coinfection of Spodoptera frugiperda (IPLB-SF-21) tissue culture cells with Autographa californica nuclear polyhedrosis virus (AcMNPV) and an AcMNPV mutant (Ac-E10) lacking the polyhedrin gene resulted in occlusion of both virus types within polyhedra. The amount of occluded Ac-E10 virions in progeny polyhedra populations during serial passage in Trichoplusia ni larvae was evaluated. Maintenance of the mutant in progeny polyhedra required polyhedra inocula containing equal numbers of the two virus types at a high dose. A significant reduction in occluded mutant nucleocapsids occurs with inoculum levels below a 100% lethal dose. At inoculum levels below a 30% lethal dose, the majority of fourth-instar larvae were infected with only one type of virus. The commercial application and ecological advantages of the co-occlusion process are discussed.     

Infectivity of nuclear polyhedrosis virus extracted with digestive juices

Autographa californica NPV, which had been obtained by dissolving polyhedra in the digestive juice of Estigmene acrea larvae, was infectious to a Trichoplusia ni cell line (TN-368). Virions thus botained were infective, and as few as 0.0025–0.005 polyhedral equivalents could infect newly transferred tissue culture cells. Activity decreased after 8 min of digestion.     

The Baculovirus Core Gene ac83 Is Required for Nucleocapsid Assembly and Per Os Infectivity of Autographa californica Nucleopolyhedrovirus

Autographa californica multiple nucleopolyhedrovirus (AcMNPV) ac83 is a baculovirus core gene whose function in the AcMNPV life cycle is unknown. In the present study, an ac83-knockout AcMNPV (vAc83KO) was constructed to investigate the function of ac83 through homologous recombination in Escherichia coli. No budded virions were produced in vAc83KO-transfected Sf9 cells, although viral DNA replication was unaffected. Electron microscopy revealed that nucleocapsid assembly was aborted due to the ac83 deletion. Domain-mapping studies revealed that the expression of Ac83 amino acid residues 451 to 600 partially rescued the ability of AcMNPV to produce infectious budded virions. Bioassays indicated that deletion of the chitin-binding domain of Ac83 resulted in the failure of oral infection of Trichoplusia ni larvae by AcMNPV, but AcMNPV remained infectious following intrahemocoelic injection, suggesting that the domain is involved in the binding of occlusion-derived virions to the peritrophic membrane and/or to other chitin-containing insect tissues. It has been demonstrated that Ac83 is the only component with a chitin-binding domain in the per os infectivity factor complex on the occlusion-derived virion envelope. Interestingly, a functional inner nuclear membrane sorting motif, which may facilitate the localization of Ac83 to the envelopes of occlusion-derived virions, was identified by immunofluorescence analysis. Taken together, these results demonstrate that Ac83 plays an important role in nucleocapsid assembly and the establishment of oral infection.     

Morphology of the Nucleoprotein Component of Rabies Virus

The intracytoplasmic ground substance, or matrix, associated with the development of rabies virus and the nucleocapsid of the virus were investigated. The filaments of the matrix were identified as virus-specific by means of ferritin-labeled antibodies. In thin sections, the diameter was 15 nm and the strands seemed to be incorporated into virions during morphogenesis of the virus. The nucleocapsid was isolated from purified virus preparations and was studied in negative contrast. The rabies nucleocapsid appeared as a single-stranded helix with a diameter of 16 nm and a periodicity of 7.5 nm; its length was in excess of 1 mum.     

Relationships Among Virus Spread, Cytopathogenicity, and Virulence as Revealed by the Noncytopathic Mutants of Newcastle Disease Virus

We have studied protein synthesis in cultured cells infected with the six noncytopathic (nc) mutants of the Australia-Victoria strain (AV-WT) of Newcastle disease virus and their plaque-forming revertants. Virus-specific polypeptides accumulated at 30 to 63% of wild-type levels in nc mutant-infected cells and between 66 and 175% of wild-type levels in revertant-infected cells. An exception was the L polypeptide, which accumulated in nc mutant-infected cells at only 5 to 20% of the levels found in wild-type infection. The reduced accumulation of the L polypeptide did not appear to be due to increased degradation of that polypeptide. A new polypeptide (X) accumulated instead of polypeptide P in cells infected with mutants nc4 or nc16 and in virions released from them. Peptide mapping identified X as an altered form of P. A revertant of mutant nc4 (nc4S1), which forms larger hemadsorbing spots, but still does not form plaques, accumulated P instead of the X polypeptide. Thus, a lesion in P can affect virus spread without affecting cytopathogenicity. Virions of mutant nc7 and two naturally occurring avirulent strains of Newcastle disease virus (NJ LaSota and B1-Hitchner) contained polypeptides (F₇ and F_A, respectively) related to, but migrating more rapidly than, F₀ in sodium dodecyl sulfate-polyacrylamide gels. As previously reported for avirulent strains, a brief treatment of nc7 virions with trypsin converted F₇ to F and increased infectivity. Similarly, culturing nc7-infected cells in the presence of trypsin facilitated fusion from within and viral spread from cell to cell. A plaque-forming revertant of nc7 still accumulated F₇ in virions, indicating that the lesions responsible for the F₇ and noncytopathic phenotypes are genetically separable. The virulent parental strain, AV-WT, exhibited a mean embryo death time of 42 h. Both the larger-spot-forming revertant of nc4 (nc4S1) and the small-plaque-forming revertant of nc7 exhibited a decrease in mean embryo death time (increase in virulence) from 74 to 63 h. A second-step, plaque-forming revertant derived from nc4S1 (nc4S1R1) exhibited a further decrease in mean embryo death time from 63 to 44 h. The results suggest that the F_A-F₇ and X lesions affect the ability of virus to spread from cell to cell. In addition, these lesions appear to be genetically separable from those responsible for the noncytopathic phenotype. However, both types of lesions cause an extension of mean embryo death time and, thus, may be relevant to virulence in vivo.     

Structural studies on the polyhedral inclusion bodies, virions, and DNA of the nuclear polyhedrosis virus of the cotton bollworm Heliothis zea.

The polyhedral inclusion body of the cotton bollworm nuclear polyhedrosis virus contains virions occluded in an orthogonal crystalline matrix. The virions appear as rods or, more frequently, as oval structures that form upon bending of the nucleocapsid within the viral membrane. The nucleocapsid consists at least of DNA surrounded by a capsid composed of subunits, possibly helically arranged. The viral DNA is circular and supercoiled. It is heterogenous in size with contour lengths ranging from 15 to 45 mum.     

Dissolution of Autographa californica nuclear polyhedrosis virus polyhedra by the digestive fluid of Trichoplusia ni (Lepidoptera:Noctuidae) larvae

The dissolution of polyhedra of Autographa californica nuclear polyhedrosis virus by digestive fluid collected from 5th stage Trichoplusia ni larvae was studied in vitro. Observations were made at timed intervals using phase contrast microscopy, and scanning and transmission electron microscopy. Dissolution occurred rapidly and in a detectable sequence. Under phase contrast, most polyhedra lost their refringence by 0.5 min. The polyhedra became rounded in appearance with small protuberances on the surface and Brownian movement was observed within. After 1 min, the envelope of most polyhedra had ruptured, releasing the enclosed virions. The protuberances were also observed under the scanning electron microscope after digestion for 0.5 min. Many shell fragments devoid of internal contents were seen after more lengthy digestion. Internal structural changes were revealed by electron microscopy. After 1 min of exposure, polyhedra were observed in all stages of dissolution. By 3 min, only virions, scattered about in heterogeneous material, could be distinguished.     

THE STRUCTURE OF INSECT VIRUS PARTICLES

Thin sections have been cut of the virus particles from four types of insect virus diseases: cytoplasmic polyhedroses of lepidopterous larvae, a nuclear polyhedrosis of Tipula paludosa (Diptera), a granulosis from Melanchra persicariae (Lepidoptera), and a new virus disease without polyhedra from T. paludosa. The cytoplasmic polyhedral viruses are thought to have composite particles in some cases. The shape and enveloping membranes of the different virus particles are compared. In the new virus disease of T. paludosa some of the virus particles appear to be empty; inclusion bodies surrounded by complicated membranes are also demonstrated.     

Differentiation of Trichoplusia ni MEV and Autographa californica MEV by macrophage migration inhibition tests

The macrophage migration inhibition test (MMI), an in vitro correlate of delayed hypersensitivity, was found to be an effective means of differentiating Trichoplusia ni and Autographa californica multiple embedded nuclear polyhedrosis viruses (NPV). Peritoneal exudate cells from guinea pigs sensitized to virions of T. ni NPV demonstrated significantly different MMI when challenged with T. ni vs A. californica virions. Similarly, when virions of A. californica NPV were employed as the sensitizing antigen, different percentages of MMI were observed in the homologuus versus heterologous challenges.The susceptibility of the fall armyworm, Spodoptera frugiperda, to these two pathogens was very similar as revealed by a comparison of LD₅₀'s, slopes, and fiducial limits of dose-mortality regression lines. In contrast, the cabbage looper, T. ni, was much more susceptible to A. californica NPV.The polyhedral sizes, shapes, and virion occlusion patterns of the two species of NPV were virtually indistinguishable.     

Fine Structure of Bacillus subtilis : I. Fixation

The fine structure of Bacillus subtilis has been studied by observing sections fixed in KMnO₄, OsO₄, or a combination of both. The majority of examinations were made in samples fixed in 2.0 per cent KMnO₄ in tap water. Samples were embedded in butyl methacrylate for sectioning. In general, KMnO₄ fixation appeared to provide much better definition of the boundaries of various structures than did OsO₄. With either type of fixation, however, the surface structure of the cell appeared to consist of two components: cell wall and cytoplasmic membrane. Each of these, in turn, was observed to have a double aspect. The cell wall appeared to be composed of an outer part, broad and light, and an inner part, thin and dense. The cytoplasmic membrane appeared (at times, under KMnO₄ fixation) as two thin lines. In cells fixed first with OsO₄ solution, and then refixed with a mixture of KMnO₄ and OsO₄ solutions, the features revealed were more or less a mixture of those revealed by each fixation alone. A homogeneous, smooth structure, lacking a vacuole-like space, was identified as the nuclear structure in a form relatively free of artifacts. Two unidentified structures were observed in the cytoplasm when B. subtilis was fixed with KMnO₄. One a tortuous, fine filamentous element associated with a narrow light space, was often found near the ends of cells, or attached to one end of the pre-spore. The other showed a special inner structure somewhat similar to cristae mitochondriales.     

The infectivity of a nuclear polyhedrosis virus of the velvetbean caterpillar for eight noctuid hosts

Eight species of noctuid larvae were tested for susceptibility to a nuclear polyhedrosis virus of the velvetbean caterpillar, Anticarsia gemmatalis. Velvetbean caterpillar larvae were highly susceptible to crude preparations of polyhedral inclusion bodies (PIBs; LD₅₀ = 4.7 PIBs/larva), but preparations of purified polyhedra were much less effective against these larvae (LD₅₀ = 319.7 PIBs/larva). Of seven other noctuid species tested, only Heliothis virescens was as susceptible to the virus as A. gemmatalis. High dosages were required to kill Heliothis zea, Trichoplusia ni, Pseudoplusia includens, and Spodoptera ornithogalli. Plathypena scabra and Spodoptera frugiperda were not susceptible.     

Ultrastructure and location of cytoplasmic fibrils inSpiroplasma floricola OBMG

The ultrastructure ofSpiroplasma floricola OBMG was investigated to identify subcellular structures that might be involved in motility and helicity. Optimal preservation for thin sectioning was achieved with either glutaraldehyde or a mixture of glutaraldehyde plus paraformaldehyde followed by OsO₄ and uranyl acetate. In thin sections, a 94-nm-wide band consisting of 4-nm-diameter fibrils was observed apposed to the cytoplasmic side of the plasma membrane. The band of fibrils extended axially the entire length of the cell. The addition of rethenium red to fixative solutions resulted in condensation of the fibrils. Freeze-substitution increased the apparent thickness of membranes but did not improve preservation of the fibrils. Freeze-fracturing revealed a 99-nm-wide zone containing few particles in fractured membrane surfaces. Treatment with deoxycholate or Triton X-100 to dissolve membranes yielded bands of fibrils comparable to those seen in thin sections. Based on these findings, a model indicating the intracellular location of the fibrils is proposed.