Role of de novo protein synthesis in target cells recognized by cytotoxic T lymphocytes specific for vesicular stomatitis virus.

The requirements for viral and host protein synthesis in the generation of target antigens for cytotoxic T lymphocytes (CTL) was evaluated by using vesicular stomatitis virus (VSV) inactivated by UV irradiation (UV-VSV). EL4 target cells incubated with UV-VSV were recognized and lysed by anti-VSV CTL, indicating that de novo synthesis of viral proteins was not required for the generation of antigens recognized by antiviral CTL. Anti-VSV CTL from H-2b mice primarily recognize determinants derived from the VSV N protein bound to the class I major histocompatibility complex (MHC) antigen H-2Kb. Comparison of a cloned CTL line representing this specificity and a heterogeneous population of anti-VSV CTL showed that determinants other than that recognized by the cloned CTL were generated more efficiently from UV-VSV. By using vaccinia virus recombinants that express deletion fragments of the N protein, it was shown that these additional determinants were probably derived from VSV proteins other than the N protein. The protein synthesis inhibitor emetine was used to determine whether newly synthesized host proteins were required for antigen generation. The addition of emetine to target cells prior to or at the time of the addition of UV-VSV inhibited lysis by anti-VSV CTL. This inhibition could be due to depletion of newly synthesized MHC molecules from intracellular membranes. This hypothesis was supported by using brefeldin A to delay membrane protein transport in target cells during the time of incubation with emetine and UV-VSV, which resulted in partial reversal of the effect of emetine. These results suggest that newly synthesized class I MHC molecules are required for the generation of antigens recognized by anti-VSV CTL.     

Specificity of in vitro cytotoxic T cell clones directed against vesicular stomatitis virus

Cytotoxic T lymphocytes (CTL) generated in mice against a particular serotype of vesicular stomatitis virus (VSV) were previously shown to cross-reactively lyse syngeneic target cells infected with serologically distinct types of VSV. To analyze the antigenic basis of this T cell cross-reactivity, we generated CTL against VSV-Indiana (VSV-Ind) and established them by limiting dilution as cloned in vitro cell lines. The cells continuously proliferate in medium containing concanavalin A-induced T cell growth factors. All of the cells are Thy-1.2+ and Lyt-2.2+. Lysis by these cells is H-2Dd-restricted, no natural killer cell activity is detectable, and all the clones cross-reactively lyse target cells infected with either VSV-Ind or VSV-New Jersey (VSV-NJ). In addition, no specific blocking of primary, secondary, or cloned anti-VSV CTL was achieved with the use of several monoclonal antibodies specific for the glycoprotein of VSV and capable of neutralizing either VSV-Ind or VSV-NJ. These results suggest that VSV serotype-specific neutralizing antibodies may recognize immunodominant determinants of VSV glycoprotein that are distinct from those recognized by the majority of VSV-specific CTL.     

Lysis of target cells infected with vesicular stomatitis virus (VSV) in the presence of tunicamycin by anti-VSV cytotoxic T lymphocytes

We have analyzed the requirement for the expression of the major surface glycoprotein (G protein) of vesicular stomatitis virus (VSV) on target cells for recognition and lysis by anti-VSV cytotoxic T lymphocytes (CTL). In addition, we have attempted to determine if the carbohydrate moieties on the G protein are required for recognition and lysis by anti-VSV CTL. When VSV (Orsay) is grown at 30 degrees C in the presence of tunicamycin (TM), glycosylation of G protein is inhibited; however, nonglycosylated G protein is found on the surface of the cell and active virus particles are produced. In contrast, VSV (Orsay) grown at 39 degrees C in the presence of TM produces low titers of virus and the presence of G protein on the surface of cells is not detectable. The susceptibility of these target cells to lysis by anti-VSV CTL was analyzed. The results suggest that expression of the G protein is required for target cell lysis by anti-VSV CTL. However, the presence of the carbohydrate moieties on the G protein are nt an absolute requirement for recognition by anti-VSV CTL. VSV-infected target cells incubated in the presence of TM were lysed by anti-VSV CTL up to 50 to 80% of the infected target cell control. This result suggests either that some clones of anti-VSV CTL recognize carbohydrate moieties or that carbohydrate moieties play some as yet undefined nonantigenic role in the recognition of the target antigen by the CTL receptor.     

Activation of mouse lymphocytes by vesicular stomatitis virus.

Vesicular stomatitis virus (VSV) is a mitogen for mouse spleen cells, and infectious virus is not required for mitogenesis. At concentrations between 10 and 100 microgram per culture, VSV stimulated DNA synthesis and blast transformation. Maximal activation by VSV occurred 48 h after culture initiation. Spleen cells depleted of T-lymphocytes by treatment with anti-Thy 1.2 and complement and those obtained from congenitally athymic BALB/c nu/nu mice were activated by VSV, suggesting that VSV is a B-cell mitogen. Activation of spleen cells was independent of the host in which the virus was grown, since VSV grown in BHK-21, HKCC, or MDBK cells was mitogenic. The mitogenesis was specific for VSV, since MDBK cell-grown WSN influenza virus was not a mitogen in this in vitro activation system, VSV-specific antibody prevented VSV mitogenesis, and VSV was mitogenic for spleen cells from C3H/HeJ mice which were resistant to mitogenesis by endotoxin.     

Target antigens for H-2-restricted vesicular stomatitis virus-specific cytotoxic T cells.

Cytotoxic thymus-derived lymphocytes from mice infected with vesicular stomatitis virus (VSV) are H-2 restricted and virus specific for the Indiana and New Jersey strains of VSV. VSV-Indiana-immune T cells can lyse target cells infected with the temperature sensitive (ts) mutant ts 045 about 30 times better when target cell infection occurs at the permissive rather than the non-permissive temperature. Since this mutant fails to express the glycoprotein at the cell surface when grown at the nonpermissive temperature, our results support the view that the viral glycoprotein is involved in defining the major target antigen for VSV-specific T cells. However, the tl 17 mutant that expresses a mutant glycoprotein at the cell surface was lysed, suggesting that the expressed mutated glycoprotein can cross-react with Indiana wild-type glycoprotein. Targets infected at the nonpermissive temperature with VSV ts G31 (mutant in the matrix protein) are still susceptible to T cell-mediated lysis but at a lower level of sensitivity. These results are compatible with the interpretation that for VSV-specific T cell lysis of infected target cells, the viral glycoprotein is a major target antigen and must be expressed, and that the matrix protein plays a lesser role, probably by indirectly influencing glycoprotein configuration at the cell surface.     

The induction of interferon by vesicular stomatitis virus in mouse L cells.

Although no detectable interferon was produced when L cells were infected with wild-type VSV (VSV-o), considerable amounts of interferon were produced when cells were infected with UV-irradiated VSV-o at a multiplicity equivalent to 10 PFU/cell. Treatment of VSV-o with UV-light resulted in the marked reduction of the RNA synthesizing capacity and cytotoxity of the virus, and the UV-irradiated virus had neither infectivity nor interfering activity against homologous viruses. The amount of interferon induced by UV-VSV-o was markedly influenced by multiplicity of infection and incubation temperature. Less-virulent temperature-sensitive mutants (VSV-mp and VSV-sp) derived from L cells persistently infected with VSV induced interferon in L cells without treatment of the viruses with UV-light, but these viruses could not induce interferon if the infected cells were incubated at nonpermissive temperature, or if cells were infected at multiplicities of more than 10 PFU/cell. On the other hand, it was shown that treatment of cells with cycloheximide (100 μg/ml) delayed the expression of cell damage caused by non-irradiated VSV-o and resulted in the production of interferon when cycloheximide was removed from the cultures. These results indicate that VSV has intrinsically interferon-inducing capacity in L cells and can induce interferon if the induction is carried out under such condition that cell damage caused by VSV are suppressed or delayed. Furthermore, the effect of pretreatment of cells by interferon and undiluted passage of VSV-o on interferon induction was discussed in relation to persistent infection.     

Antigen processing and presentation of vesicular stomatitis virus glycoprotein

Antigen processing and presentation is the complex series of steps involving numerous compartments of cells derived from multiple lineages. This collective process is central to the initiation of specific cellular immune responses. Internalization of foreign proteins or infectious agents, degradation of proteins to peptides, and transfer to 1a heterodimers which are then translocated to the cell surface, comprise the pathway. This can be blocked by drugs which interfere with compartment acidification (ammonium chloride, methylamine, chloroquine), protein synthesis (emetine), vesicle trafficking (brefeldin A), and microtubule metabolism (taxol, colchicine, nocadazole).     

The soluble viral glycoprotein of vesicular stomatitis virus efficiently sensitizes target cells for lysis by CD4+ T lymphocytes

The soluble glycoprotein Gs of vesicular stomatitis virus (VSV), at approximately 10(4) molecules per cell, sensitized target cells for lysis by clones of CD4+ cytolytic T lymphocytes (CTL). In addition to lysis, the clones responded by proliferation and interleukin-2 release. Targets sensitized by Gs competed effectively with VSV-infected cells for recognition. Immune cytolysis by these CD4+ CTLs was restricted by class II major histocompatibility complex (MHC) antigens and was specific to VSV. The specific class II MHC antigen which was restricting for each clone remained the same whether the targets were sensitized by infection with VSV or by exogenously added soluble antigen. Sensitization by Gs appeared to require prior processing because the antigen-presenting cells that were fixed prior to exposure to Gs failed to be recognized by the CTL clones. The high efficiency of this uptake and processing was suggested by the inability of Gs at concentrations up to 10(7) per cell to block superinfection by VSV or to effect the RNA-synthetic machinery of uninfected cells. Also, Gs failed to hemolyze sheep erythrocytes when there was hemolysis by virions or an amino-terminal peptide of the VSV glycoprotein. Extrapolation of these results to viral diseases was possible because soluble viral glycoproteins were naturally synthesized during many viral infections and class II MHC antigens were inducible in cells of nonlymphoid origin. Therefore, CD4+ CTLs may be important participants in increasing virus-induced pathology, especially among adjacent uninfected cells.     

Trojan horse lymphocytes: a vesicular stomatitis virus-specific T-cell clone lyses target cells by carrying virus

We have isolated a vesicular stomatitis virus (VSV)-specific CD4+ CD8- murine T-cell clone. This clone proliferates only in response to VSV and lyses infected tumor cells bearing class II major histocompatibility antigens in short-term chromium release assays. In addition, the cell has VSV antigens on its surface and is capable of killing uninfected tumor cells without major histocompatibility antigen restriction in a 2-day assay. This latter cytolytic activity is eliminated by anti-VSV antibody, indicating that its lytic activity is provided by the virus. [35S]methionine labeling and immunoprecipitation experiments demonstrated that viral protein translation is initiated after incubation of the clone with a tumor target cell, defining this as the mechanism of its cytolytic activity.     

Efficient induction of peptide-specific cytotoxic T lymphocytes by LPS-activated spleen cells

Lipopolysaccharides of gram-negative bacteria are potent activators of B cells, dendritic cells and monocytes/macrophages. We have investigated the use of LPS-activated spleen cells as antigen-presenting cells to induce CD8+ cytotoxic T lymphocytes in vivo that are reactive to MHC class I binding peptides. Compared with resting spleen cells, CTL induction was more efficient and less variable for different peptides with LPS-activated spleen cells. Cytotoxic responses were specific for the immunized peptides and contained high affinity CD8+ T cells. The removal of dendritic cells and monocytes/macrophages by Sephadex G10 column did not show profound effects on CTL induction, indicating that B-cell blasts were largely responsible. This easily accessible method should facilitate the screening of MHC class I binding peptides to determine whether or not the host's T-cell repertoire contains reactive T cells.     

N protein is the predominant antigen recognized by vesicular stomatitis virus-specific cytotoxic T cells.

The specificity of anti-vesicular stomatitis virus (VSV)-specific cytotoxic T cells was explored with cell lines expressing VSV genes introduced by electroporation. Low levels of nucleocapsid (N) protein were detected on the surface of VSV-infected cells, but N protein could not be detected on the plasma membrane of transfected EL4 cells. Intracellular N protein was detectable by enzyme-linked immunosorbent assay or immunoprecipitation in some of the transfected cell lines but not in others, unless the transfected genes were induced by sodium butyrate. However, all of the stably transfected EL4 cell lines expressing the VSV-Indiana N protein were efficiently lysed by serotype-specific and cross-reactive anti-VSV cytotoxic T cells (CTLs). Primary cross-reactive anti-VSV CTLs appeared to be specific solely for N protein, based on cold-target competition assays using infected and transfected target cells. Cell lines expressing 100- to 1,000-fold less N protein than did VSV-infected cells were efficiently lysed by both primary and secondary anti-VSV CTLs. Cell lines expressing 100-fold less G protein than did VSV-infected cells were not lysed by either population of effectors. Significantly, cold-target competition studies with secondary CTLs demonstrated that N protein-expressing cell lines were more efficient competitors than were VSV-infected cells even though the latter expressed 100- to 1,000-fold more N protein. This was not an artifact of viral infection since infection of the transfected cell lines did not affect their ability to compete. The possibility that cell lines constitutively expressing internal virus proteins present antigen more effectively than infected cells do is discussed.     

Inability of mice to generate cytotoxic T lymphocytes to vesicular stomatitis virus restricted to H-2Kk or H-2Dk

H-2k mice are unable to generate cytotoxic T lymphocytes (CTL) to vesicular stomatitis virus (VSV). This apparent unresponsiveness is found for both major serotypes of VSV, VSV-Indiana and VSV-New Jersey. CTL unresponsiveness occurs despite the ability of H-2k mice to generate a humoral immune response against VSV that is comparable to that found in responder (H-2b and H-2a) strains. All H-2k mice regardless of background genes, including various Ig allotypes, were found to be nonresponders. H-2k-linked unresponsiveness mapped to both H-2Kk and H-2Dk and occurred despite the presence of responder alleles in (responder x nonresponder)F1 mice. The unresponsiveness cannot be attributed to an inability of VSV-infected H-2k target cells to express viral surface antigens of H-2 molecules. Further, unresponsiveness cannot be overcome by using secondary stimulation in vivo or in vitro. H-2k-linked unresponsiveness does not appear to be due to suppression, and no complementation has been found in various (nonresponder x nonresponder)F1 mice. Thus unresponsiveness to VSV in association with H-2Kk or H-2Dk appears to represent an extensive defect of immune responsiveness that probably occurs because VSV is not a natural mouse pathogen.     

Effects of chloroquine and cytochalasin B on the infection of cells by Sindbis virus and vesicular stomatitis virus

The effects of cytochalasin B and chloroquine on the process of endocytosis of Sindbis virus particles and polystyrene spheres were determined by electron microscopy. The effects of these agents on the process of infection (attachment, penetration, and uncoating) of BHK-21 cells by Sindbis virus and vesicular stomatitis virus were also determined. Cytochalasin B completely blocked ingestion of Sindbis virus particles or latex spheres by BHK cells but had no effect on the ability of Sindbis virus or vesicular stomatitis virus to infect or replicate in BHK cells. Chloroquine did not inhibit the ingestion of either latex spheres or virus particles but greatly reduced the yields of virus produced. These data suggest that endocytosis is not essential for the infection of cultured cells by Sindbis virus or vesicular stomatitis virus.     

Uridine labeling of human lymphocytes: Differential uptake by T and B cells

Human peripheral blood lymphocytes were labeled with [³H]uridine and separated into immunoglobulin (Ig)-positive-enriched and Ig-negative populations by rosetting and Ficoll sedimentation. The Ig-negative (T cell-rich) fraction was found to be more heavily labeled than the B cell-enriched population, in agreement with previous results in rats. Combined autoradiography and rosetting confirmed the differential uridine labeling of T and B cells. Incorporation of cytidine and adenosine by T and B cell-enriched populations showed similar but less dramatic differential labeling.     

Virus-lymphocyte interactions: inductive signals necessary to render B lymphocytes susceptible to vesicular stomatitis virus infection.

We examined the inductive signals necessary to render B lymphocytes capable of supporting a productive vesicular stomatitis virus infection. Small murine splenic B cells in the G0 phase of the cell cycle were cultured with stimulators which allow progression through various stages in the activation and/or differentiation pathway leading to antibody secretion. We found that vesicular stomatitis virus expression is dependent on the state of B-cell activation and that three distinct phases can be defined. A nonsupportive state, which is defined by the failure to produce infection centers, viral proteins, or PFUs, is characteristic of freshly isolated small B cells, B cells cultured 48 h without further stimulation, or B cells in the G1 phase of the cell cycle induced by culture with T-cell-derived lymphokines. This refractory state was not due to a failure of virus uptake. Activation of G0 B cells with anti-immunoglobulin at doses which allow entry into the S phase rendered them capable of synthesizing viral proteins and increased the number of B cells producing infection centers, without enhancing PFU production on a per cell basis. In contrast, B cells stimulated with multiple inductive signals provided by anti-immunoglobulin and lymphokines showed increased infectious particle production (7 PFU per infection center). Lipopolysaccharide stimulation, acting through another induction pathway, caused the maximum increase in the number of infected B cells and production of infectious particles (25 PFU per infection center).     

In vitro induction of HLA-restricted cytotoxic T lymphocytes against autologous Epstein-Barr Virus transformed B lymphoblastoid cell line

Cytotoxic T lymphocytes (CTL) against autologous EBV-transformed B lymphoblastoid cell line (LCL) were induced in vitro by culturing peripheral blood lymphocytes (PBL) of healthy donors together with mitomycin C-treated autologous LCL for 6 days. The cytotoxic cells developed only from the E-rosette-positive fraction but not from the negative fraction of PBL. These CTL killed autologous LCL but not PWM-stimulated autologous PBL. In addition, the CTL killed allogeneic LCL when at least 1 of the HLA-A antigens was identical with that of the LCL of CTL donor. However, identity of HLA-B and HLA-C antigens was not enough for a significant killing of allogeneic LCL. The specificity of the CTL was also confirmed by a cold target inhibition test. These results indicated that the CTL induced specifically recognized EBV-transformed cells with HLA restriction.     

The matrix protein of vesicular stomatitis virus binds dynamin for efficient viral assembly

Matrix proteins (M) direct the process of assembly and budding of viruses belonging to the Mononegavirales order. Using the two-hybrid system, the amino-terminal part of vesicular stomatitis virus (VSV) M was shown to interact with dynamin pleckstrin homology domain. This interaction was confirmed by coimmunoprecipitation of both proteins in cells transfected by a plasmid encoding a c-myc-tagged dynamin and infected by VSV. A role for dynamin in the viral cycle (in addition to its role in virion endocytosis) was suggested by the fact that a late stage of the viral cycle was sensitive to dynasore. By alanine scanning, we identified a single mutation of M protein that abolished this interaction and reduced virus yield. The adaptation of mutant virus (M.L4A) occurred rapidly, allowing the isolation of revertants, among which the M protein, despite having an amino acid sequence distinct from that of the wild type, recovered a significant level of interaction with dynamin. This proved that the mutant phenotype was due to the loss of interaction between M and dynamin. The infectious cycle of the mutant virus M.L4A was blocked at a late stage, resulting in a quasi-absence of bullet-shaped viruses in the process of budding at the cell membrane. This was associated with an accumulation of nucleocapsids at the periphery of the cell and a different pattern of VSV glycoprotein localization. Finally, we showed that M-dynamin interaction affects clathrin-dependent endocytosis. Our study suggests that hijacking the endocytic pathway might be an important feature for enveloped virus assembly and budding at the plasma membrane.