Generation of long-term human cytolytic cell lines with persistent natural killer activity

Human cell lines maintained by in vitro stimulation with the HLA-A, B-negative, DR-positive, Epstein Barr virus-transformed, lymphoblastoid cell line Daudi in the presence of conditioned medium demonstrated significant NK activity for over 6 wk in continuous culture. These cells lyse K562 and a broad panel of lymphoblastoid cell lines but do not lyse normal peripheral blood lymphocytes or pokeweed mitogen blasts. They possess the sheep red blood cell receptor but lack other T cell markers (Lyt-3+, OKT3-). Natural killer activity correlated with the presence of a Mac 1-positive subpopulation of cells present in these long-term lines.     

Strandedness of Pichinde virus RNA.

The Pichinde virus RNA did not possess the following characteristics of eucaryotic mRNA: polyadenylic acid sequence, capped methylated structure, and ability to direct protein synthesis in vitro. Polysomal RNA extracted from cells infected with Pichinde virus reannealed with 32P-labeled virus RNA, protecting about 60% of the latter against RNase degestion. The polyadenylic acid-containing polysomal RNA also reannealed to the 32P-labeled virus RNA to approximately the same extent. These indicate that the major part of the genomic RNA of Pichinde virus is negative stranded.     

In vivo selection of lymphocyte-tropic and macrophage-tropic variants of lymphocytic choriomeningitis virus during persistent infection.

This study demonstrates cell-specific selection of viral variants during persistent lymphocytic choriomeningitis virus infection in its natural host. We have analyzed viral isolates obtained from CD4+ T cells and macrophages of congenitally infected carrier mice and found that three types of variants are present in individual carrier mice: (i) macrophage-tropic, (ii) lymphotropic, and (iii) amphotropic. The majority of the isolates were amphotropic and exhibited enhanced growth in both lymphocytes and macrophages. However, some of the lymphocyte-derived isolates grew well in lymphocytes but poorly in macrophages, and a macrophage-derived isolate replicated well in macrophages but not in lymphocytes. In striking contrast, the original wild-type (wt) Armstrong strain of lymphocytic choriomeningitis virus that was used to initiate the chronic infection and from which the variants are derived grew poorly in both lymphocytes and macrophages. These three types of variants also differed from the parental virus in their ability to establish a chronic infection in immunocompetent hosts. Adult mice infected with the wt Armstrong strain cleared the infection within 2 weeks, whereas adult mice infected with the variants harbored virus for several months. These results suggest that the ability of the variants to persist in adult mice is due to enhanced replication in macrophages and/or lymphocytes. This conclusion is further strengthened by the finding that the variants and the parental wt virus grew equally well in mouse fibroblasts and that the observed growth differences were specific for cells of the immune system.     

Course and extent of variation of equine infectious anemia virus during parallel persistent infections.

Comparisons of peptide and oligonucleotide maps of glycoproteins and RNA from nine isolates of equine infectious anemia virus (EIAV) that were generated during parallel infections of two Shetland ponies revealed that each isolate was structurally unique. Each EIAV isolate contained a unique subset of variant peptides, oligonucleotides, or both, indicating that structural variation in EIAV is a random and noncumulative process and that a large spectrum of possible EIAV variants can be generated in infected animals.     

Rapid emergence of novel antigenic and genetic variants of equine infectious anemia virus during persistent infection.

Previous results from our laboratory have demonstrated that equine infectious anemia virus displays structural variations in its surface glycoproteins and RNA genome during passage and chronic infections in experimentally infected Shetland ponies (Montelaro et al., J. Biol. Chem. 259:10539-10544, 1984; Payne et al., J. Gen. Virol. 65:1395-1399, 1984). The present study was undertaken to obtain an antigenic and biochemical characterization of equine infectious anemia virus isolates recovered from an experimentally infected pony during sequential disease episodes, each separated by intervals of only 4 to 8 weeks. The virus isolates could be distinguished antigenically by neutralization assays with serum from the infected pony and by Western blot analysis with a monoclonal antibody against the major surface glycoprotein gp90, thus demonstrating that novel antigenic variants of equine infectious anemia virus predominate during each clinical episode. The respective virion glycoproteins displayed different electrophoretic mobilities on sodium dodecyl sulfate-polyacrylamide gels, indicating structural variation. Tryptic peptide and glycopeptide maps of the viral proteins of each virus isolate revealed biochemical alterations involving amino acid sequence and glycosylation patterns in the virion surface glycoproteins gp90 and gp45. In contrast, no structural variation was observed in the internal viral proteins pp15, p26, and p9 from any of the four virus isolates. Oligonucleotide mapping experiments revealed similar but unique RNase T1-resistant oligonucleotide fingerprints of the RNA genomes of each of the virus isolates. Localization of altered oligonucleotides for one virus isolate placed two of three unique oligonucleotides within the predicted env gene region of the genome, perhaps correlating with the structural variation observed in the envelope glycoproteins. Thus these results support the concept that equine infectious anemia virus is indeed capable of relatively rapid genomic variations during replication, some of which result in altered glycoprotein structures and antigenic variants which are responsible for the unique periodic disease nature observed in persistently infected animals. The findings of envelope specific differences in isolates of visna virus and of human T-cell lymphotropic virus III (acquired immune deficiency syndrome-related virus) suggest that this variation may be a common characteristic of the subfamily Lentivirinae.     

Role of virus variants and cells in maintenance of persistent infection by measles virus.

Hamster embryo fibroblasts persistently infected with a derivative of the Schwarz vaccine strain of measles virus spontaneously released virus particles with an average buoyant density considerably lower than that of the parental virus. The released virus contained all of the measles virus structural proteins and interfered with replication of standard virus. All of the virus structural proteins were associated with a membrane-free cytoplasmic extract from the persistently infected cells. Membrane-free cytoplasmic extracts prepared from Vero cells lytically infected with Schwarz strain measles contained little or no virus envelope structural protein. Maintenance of persistent infection may involve both the presence of virus variants and a defect in the ability of the infected cell to replicate the virus efficiently.     

Alternative mechanisms of natural killer cell activation during herpes simplex virus infection

Although NK cells can kill both malignant cells and virus-infected cells without prior sensitization, it has remained unclear whether the mechanism by which an NK cell is activated in the presence of a tumor cell is similar to that induced by the presence of a virus-infected cell. In our experimental system using homogeneous populations of cloned human CD16+ NK cells, we found that HSV-infected target cells do not induce in the NK cells the same pharmacologically-active second messengers elicited by NK-sensitive tumor cells. Although phosphoinositide turnover and calcium signaling were generated in NK cells exposed to NK-sensitive tumor cells, the recognition of HSV-infected cells by NK cells did not result in similar transmembrane signaling. Furthermore, depending on the cell type infected by HSV, alternative mechanisms of cytotoxicity were employed. HSV-infected foreskin fibroblasts were rapidly and selectively killed by cloned NK cells without a requirement for IFN or accessory cells. In contrast to this direct cytotoxicity against HSV-infected foreskin fibroblasts, NK cell-mediated cytotoxicity against an HSV-infected fibrosarcoma cell line (1591) was dependent on IFN-alpha production by accessory cells. Importantly, in both systems of cytotoxicity, IFN-alpha activation of NK cells resulted in augmented killing against both infected and uninfected targets. These results suggest that NK cell activation induced during antiviral immunity is distinct from activation elicited during an antitumor response. These differences include the utilization of alternative forms of signal transduction and alternative mechanisms of cytotoxicity.     

Influenza virus-induced encephalopathy in mice: interferon production and natural killer cell activity during acute infection.

Mice injected intracerebrally with infectious influenza virus (60 hemagglutinin units) developed lethargy, seizures, comas, and died 2 to 5 days postinfection. As early as 6 h after infection, the cerebrospinal fluid (CSF) in these animals was infiltrated with polymorphonuclear cells, mononuclear leukocytes, and large granular lymphocytes. Potent natural killer (NK) cell activity was observed for both CSF and spleen cell populations over the same period. This NK cell activity correlated with interferon (IFN) levels in the CSF and serum. Treatment of lethally infected mice with either anti-IFN alpha-IFN beta or anti-ganglio-n-tetraoglyceramide antiserum ameliorated the disease, reduced mortality, and effected changes in the relative proportions of inflammatory cell populations infiltrating the CSF. The possible significance of IFN and NK cell activity in the development of this influenza virus-induced encephalopathy is discussed.     

Synthesis of virus-specific polypeptides and genomic RNA during the replicative cycle of Pichinde virus

A stock of plaque-purified Pichinde virus, prepared under conditions designed to limit the amounts of defective interfering virus, was used to infect BHK cells. At daily intervals after infection, cells were examined for infectious and radiolabeled virus particle production and for the synthesis of virus-specific polypeptides. Quantitative comparisons were also made of the concentrations of genomic Pichinde virus L and S RNAs in the cytoplasm of infected cells on different days after infection. Our results showed that virus particle production, rates of protein synthesis, and the intracellular levels of viral genomic RNAs all increased and decreased with similar kinetics, and that this regulation was independent of the cell growth cycle. We were unable to relate these changes in viral macromolecule and virus production to the appearance of readily identifiable defective interfering particles. Our findings suggest that regulation of virus replication early during the replicative cycle of Pichinde virus may not be dependent upon the generation of defective interfering virus.     

In vivo assessment of natural killer cell responses during chronic feline immunodeficiency virus infection

Accumulating evidence suggests that natural killer (NK) cells may have an important role in HIV-1 disease pathogenesis; however, in vivo studies are lacking. Feline immunodeficiency virus (FIV) infection of cats provides a valuable model to study NK cell function in vivo. The immune response against Listeria monocytogenes (Lm) is well characterized, allowing its use as an innate immune probe. We have previously shown that locally delivered IL-15 can improve Lm clearance in FIV-infected animals, and this correlated with an increase in NK cell number. In the present study, chronically FIV-infected and SPF-control cats were challenged with Lm by unilateral subcutaneous injection next to the footpad and then treated with 5-bromo-2'-deoxyuridine (BrdU). The Lm draining and contralateral control lymph nodes were evaluated for NK, NKT, CD4+ and CD8+ T cell number, proliferation, apoptosis, and NK cell function. Listeria monocytogenes burden was also assessed in both control and Lm draining lymph nodes. NK, NKT, CD4+ T and CD8+ T cells in the Lm-challenged lymph node of FIV-infected cats did not increase in number. In addition, after Lm challenge, NK cells from FIV-infected cats did not increase their proliferation rate, apoptosis was elevated, and perforin expression was not upregulated when compared to SPF-control cats. The failure of the NK cell response against Lm challenge in the draining lymph node of FIV-infected cats correlates with the delayed control and clearance of this opportunistic bacterial pathogen.