Emergence, origin, and function of neutrophil-dendritic cell hybrids in experimentally induced inflammatory lesions in mice.

Although unusual neutrophils expressing major histocompatibility complex class II (MHC II) and costimulatory molecules have been detected at inflammatory sites in mice and humans, their identity, origin, and function remain unclear. We have demonstrated that, when cultured with granulocyte macrophage-colony-stimulating factor, neutrophils can give rise to a unique hybrid population exhibiting dual phenotypic and functionality of neutrophils and dendritic cells (DCs). Here we report that hybrid cells expressing surface markers of neutrophils (Ly6G, L-selectin, CXC chemokines receptor 2, and 7/4) and DCs (CD11c, MHC II, CD80, and CD86) become detectable in the peritoneal cavity, skin, lung, and lymph nodes under inflammatory conditions. Importantly, 20% to 30% of the adoptively transferred neutrophils acquired CD11c and MHC II expression when recovered from inflammatory lesions, demonstrating neutrophil → hybrid conversion in living animals. Using Escherichia coli strains expressing green fluorescent protein and ovalbumin, we further show hybrids play dual protective roles by rapidly clearing bacteria and presenting bacterial antigens to CD4 T cells. These results indicate that some of the neutrophils recruited to inflammatory lesions can differentiate into neutrophil-DC hybrids, thus challenging the classic view of neutrophils as terminally differentiated leukocytes destined to die or to participate primarily in host innate immunity.

Production of bacterial blight resistant lines from somatic hybridization between Oryza sativa L. and Oryza meyeriana L.

Novel bacterial blight (BB) resistance gene(s) for rice was (were) introduced into a cultivated japonica rice variety Oryza sativa (cv. 8411), via somatic hybridization using the wild rice Oryza meyeriana as the donor of the resistance gene(s). Twenty-nine progenies of somatically hybridized plants were obtained. Seven somatically hybridized plants and their parents were used for AFLP (amplified fragment length polymorphism) analysis using 8 primer pairs. Results confirmed that these plants were somatic hybrids containing the characteristic bands of both parents. The morphology of the regenerated rice showed characters of both O. sativa and O. meyeriana. Two somatic hybrids showed highest BB resistance and the other 8 plants showed moderate resistance. The new germplasms with highest resistance have been used in the rice breeding program for the improvement of bacterial blight resistance.

Epstein-Barr virus lytic cycle spreads via cell fusion in a nasopharyngeal carcinoma hybrid cell line.

NPC-KT cl.S61, a subclone derived from an epithelial-nasopharyngeal carcinoma hybrid cell line NPC-KT, showed extensive Epstein-Barr virus (EBV) production and cell fusion when the EBV replicative cycle was induced by 5-iodo-2'-deoxyuridine. On the contrary, parental NPC-KT cells produced virus at a lower level and did not show cell fusion. Cell fusion in cl.S61 cells was blocked by 2-deoxyglucose and acyclovir, inhibitors of glycosylation and EBV DNA polymerase, respectively, with a concomitant decrease in the number of cells expressing EBV growth-associated antigens. However, the frequency of virus antigen expression in parental NPC-KT cells was not significantly affected by these drugs. This result suggests that efficient production of EBV from cl.S61 cells is due to the spreading of viral replicative cycle via cell fusion. It was also demonstrated by in situ autoradiography that cl.S61 cells producing virus fused to not only EBV receptor/CR2 positive Raji and BJAB cells, but also to receptor-negative Jurkat cells. The possible mechanism of EBV entry into cells devoid of virus receptor by cell fusion is discussed.

Susceptibility of human-mouse T cell hybrids to HIV-productive infection.

Interspecies human x mouse cell hybrids were used to investigate the genetic basis of human permissivity to HTLV-IIIB infection. T cell hybrids between the mouse BW 51.47 T lymphoma line and normal, PHA-IL-2 activated, human peripheral mononuclear cells (PBMCs) were generated. These hybrids preferentially segregated human chromosomes, as assessed by phenotype and karyotype analysis. Viral integration occurred only in those hybrids expressing CD4+ at the cell surface. However, infectious progeny production was demonstrated only in two of the three CD4+ hybrids tested. By segregation analysis, we could correlate the absence of human chromosomes 1, 3, and 9 with the lack of infectious viral progeny.

Increased replication of simian immunodeficiency virus in CEM x174 cells by morphine sulfate.

Infection with simian immunodeficiency virus induces cytopathic effects on CEM x174 cells in vitro. Syncytium formation of SIV-infected CEM x174 cells was significantly enhanced in the presence of morphine sulfate, with a concomitant increase in the activity of cellular reverse transcriptase and in the expression of SIV p27 core antigen. Parallel establishment of the viability of the morphine-treated cells indicates that the short-acting opioid protects against cell lysis induced by SIV so that replication and production of SIV particles continued and exceeded those without morphine treatment. This delayed cell lysis induced by morphine as seen in vitro correlated with an in vivo observation that peripheral blood mononuclear cells isolated from morphine-treated rhesus macaques displayed a less degree of programmed cell death by apoptosis during early stages of SIVmac infection. These studies suggest that the modification of the biological properties of HIV-infected cells by morphine sulfate may be one of the mechanisms by which opioids exacerbate the progression of HIV in drug abusers.

The blocks to human immunodeficiency virus type 1 Tat and Rev functions in mouse cell lines are independent.

Rodent cells present two blocks precluding the expression of the human immunodeficiency virus type 1 (HIV-1) genome. First, the viral protein Tat is only poorly active in these cells. Second, when the HIV-1 provirus is integrated in the genome of mouse cells, it electively fails to express the viral structural proteins, indicating a block to Rev action. Both defects can be complemented by fusion of the infected mouse cells with uninfected human cells. Because the production of high levels of Rev is dependent on Tat-mediated transactivation and because both Tat and Rev bind the viral transcript, it has been hypothesized that the two blocks found in rodent cells might be linked. In the present work, we demonstrate that overexpression of Rev in mouse cell lines does not relieve their block in HIV-1 structural-gene expression. In addition, we show that this defect is also present in human-mouse cell hybrids which contain human chromosome 12 and support Tat function. On that basis, we conclude that the blocks to HIV-1 Tat and Rev action in mouse cell lines are independent and result from the absence of distinct cellular elements that are critical for HIV-1 gene expression.

Effects of gangliosides on the growth of herpes simplex virus type 1-infected cells derived from neurons and on viral replication.

Although it is well-known that herpes simplex virus can establish latent infections in neurons of sensory and sympathetic ganglia, little is known about the viral or cellular factors which regulate the latent state. Experiments were designed to elucidate the effects that can be produced by adding gangliosides, abundant components in neurons but not in most other cell types, to virus-infected cells from mouse trigeminal ganglia and from the neuroblastoma x glioma hybrid cell line NG108-15. The results obtained indicate that gangliosides, when used in combination with acyclovir, efficiently protect the infected cells from lysis in both cell systems, and that they can exert antiviral activity at least in part via suppressing protein kinase C activity.

[The reproductive characteristics of the tick-borne encephalitis virus in interspecific somatic hybrids]. / Osobennosti reproduktsii virusa kleshchevogo éntsefalita v mezhvidovykh somaticheskikh gibridakh.

The study dealt with features of tick-borne encephalitis virus reproduction in two series of interspecies somatic hybrids generated by fusion of transformed cells of Chinese hamster (Ag17) with human diploid fibroblasts (KM/3) and with pseudonormal cells of Indian deer (Muntiacus munjak) (KOM). The viral infection in hybrid Ag17 cells ran an acute course with cell damage, but in KM/3 and KOM cells virus multiplication was not accompanied by the development of cytopathic effect. Two other parameters of tick-borne encephalitis virus infection under study: the extent of infectious particles production and electroimmunochemical properties were found to be under control of genomes of different parental cells.

Characterization of multiple mRNA species of simian immunodeficiency virus from macaques in a CD4+ lymphoid cell line.

Cytoplasmic poly(A)+ RNA was isolated from CEMX721.174 cells 5 to 10 days after infection with molecularly cloned simian immunodeficiency virus SIVmac239. Expression of SIV RNA was analyzed by Northern (RNA) blot hybridization and by sequencing of cDNA clones. As expected, a splice donor site was demonstrated in the untranslated leader sequence outside the left long terminal repeat. The region between pol and env was found to contain at least two splice donor and six splice acceptor sites. Splice acceptor and donor sites in the intergenic region were suitably positioned for expression of vpx, vpr, tat, and rev. Splice acceptor sites at nucleotides 8802 and 8805 were demonstrated in singly and doubly spliced RNAs with the potential of expressing nef and the second exons of tat and rev. Our results demonstrate a complex pattern of alternative splicing of SIV mRNAs. The results are very similar to what has been observed in human immunodeficiency virus type 1-infected cells, suggesting that both human and simian immunodeficiency viruses are subject to multiple levels of regulation.

Human genes other than CD4 facilitate HIV-1 infection of murine cells.

The human CD4 glycoprotein is a specific receptor for the HIV family of retroviruses. When expressed on human cell lines, this molecule binds virus through direct interactions with the gp 120 viral envelope glycoprotein thus allowing virus infection to occur. Subsequent to binding, conformational changes in the viral envelope glycoproteins are thought to facilitate virus entry into the target cell through direct fusion of the virus with the cell membrane. In contrast to the infection observed in human cell lines, infection of murine cell lines even in the presence of the CD4 receptor does not readily occur. We have examined this species tropism of HIV infection. We report that the inability to infect murine cells is not a function of the receptor for HIV or a suppressive function of the murine cellular background. Human CD4 expression, configuration and down-modulation on the murine background are similar if not identical to expression on the human cell background. Utilizing a panel of interspecific cell hybridomas, we have been able to bypass the barrier to infectivity of human CD4-positive murine cells. We demonstrate that there are at least two different restrictions to infectivity on the mouse background which can be complemented by the human genome. One restriction appears to be an extremely early postbinding function likely to be molecules necessary for viral entry into cells, the second restriction is necessary for high levels of virus production. Our mapping studies suggest that fewer than five human chromosomes are necessary for reconstituting infectivity in the murine background. These results have implications for models of HIV-induced pathogenesis and infectivity.

Fusion of Rous-sarcoma-virus-transformed rat cells to morphologically normal human or rat cells results in transcriptional suppression of the provirus that depends on its chromosomal integration site.

The fusion of a Rous sarcoma virus (RSV)-transformed rat fibroblast clone to at least 2 different human cell types reproducibly produces phenotypically normal hybrids. Analysis of such hybrids reveals that proviral silence is the result of transcriptional down-regulation, presumably by a trans-acting human molecule. Furthermore, this phenomenon seems to be strongly influenced by the proviral chromosomal integration site and its imposition may entail a mechanism that is required only transiently.

Propagation of hepatitis A virus in hybrid cell lines derived from marmoset liver and Vero cells.

To establish monkey liver cell lines with a high susceptibility to hepatitis A virus (HAV), marmoset (Saguinus labiatus) liver cells were fused with Vero cells deficient in hypoxanthine-guanine phosphoribosyltransferase and the resulting hybrid cells were selected in HAT medium. Of four hybrid cell lines obtained (S. 1a/Ve-1 to -4), three (S. 1a/Ve-1, -3 and -4) were equally susceptible to HAV infection. When inoculated with a virus isolated from marmoset liver tissue (10% liver tissue extract) or a faecal virus (10% stool extract) from a human hepatitis A patient, all susceptible cell lines showed a significant elevation of viral antigen activity as seen in radioimmunoassay and/or immunofluorescent antibody assays, at 4 to 6 weeks post-infection (p.i.) with the liver-derived inoculum and at 6 to 8 weeks p.i. with the stool-derived inoculum. In S. 1a/Ve-1 cells, a representative of the susceptible hybrid cell lines, full adaptation of HAV (liver tissue virus concentrate) to cell culture was attained after four serial passages. Thereafter, the virus grew to a plateau titre of 10(8.5) TCID50/ml at 7 days p.i. in a growth experiment. The infected cells showed no cytopathic effects but eventually a persistent infection was established when a saturated level of virus growth was reached.

Several rat cell lines share a common defect in their inability to internalize murine coronaviruses efficiently.

Infection of rat cells, Schwannoma RN2, hepatoma HTC or myoblast L6, with the murine coronavirus JHM strain results in a persistent infection characterized by the release of virus over an extended period of time with a limited cytopathology. Several stages of the viral replication cycle have been examined in these cells in comparison to those in mouse L2 cells, which are totally permissive to JHM infection. Although the rat cells bound as much virus as the mouse cells. Their ability to internalize it was 40-fold less efficient than the mouse cells. This lower internalization efficiency was not enhanced by pH shock of infected cells, but was by treatment with polyethylene glycol. In all cell types there appeared to be no major differences in the ability of the internalized virus to replicate the viral RNA as determined by slot-blot analysis with a radiolabelled viral cDNA. A similar genetic mechanism appears to be operative in the lines because somatic cell hybrids formed between these lines in various combinations were also deficient in the ability to internalize bound virus. Taken together these results imply that rat cell lines in general share a common deficiency in their inability to internalize murine coronaviruses efficiently. This low efficiency in viral internalization may explain in part the ability of these lines to sustain persistent infections.

Electrofusion of individual animal cells directly to intact corneal epithelial tissue.

An electromechanical process was developed to electrofuse human and nonhuman cultured cells directly to rabbit corneal epithelial tissue in vitro and in situ. This new process was utilized successfully to incorporate functional gonococcal membrane attachment receptors from human lymphoma cells into superficial rabbit corneal epithelium. Thus, cell-tissue electrofusion biotechnology may be employed to establish unique and novel animal models for investigating receptor-mediated processes in vivo.

Human T cell leukemia viruses use a receptor determined by human chromosome 17.

Human T cell leukemia viruses (HTLV-I and HTLV-II) can infect many cell types in vitro. HTLV-I and HTLV-II use the same cell surface receptor, as shown by interference with syncytium formation and with infection by vesicular stomatitis virus (VSV) pseudotypes bearing the HTLV envelope glycoproteins. Human-mouse somatic cell hybrids were used to determine which human chromosome was required to confer susceptibility to VSV(HTLV) infection. The only human chromosome common to all susceptible cell hybrids was chromosome 17, and the receptor gene was localized to 17cen-qter. Antibodies to surface antigens known to be determined by genes on 17q did not block the HTLV receptor.

Extinction of JC virus tumor-antigen expression in glial cell--fibroblast hybrids.

JC virus (JCV) is a ubiquitous human papovavirus that shares sequence and structural homology with simian virus 40 (SV40). In contrast to SV40, expression of JCV is restricted to a small number of cell types, including human fetal glial cells, uroepithelial cells, amnion cells, and some endothelial cells. To study the control of JCV early region expression, we made heterokaryons and stable hybrids between JCV-transformed hamster glial cells and mouse fibroblasts. Binucleate heterokaryons exhibited extinction of large tumor antigen expression in the hamster nuclei as assayed by indirect immunofluorescence. This extinction was both time and dose dependent: extinction reached maximal levels at 24-36 hr after fusion and was dependent on the ratio of glial cell to fibroblast nuclei in multinucleated heterokaryons. Extinction also was observed in stable hybrids between the glial cells and mouse Ltk- cells. Southern blot analysis showed that the extinguished hybrids contained viral sequences. Reexpression of large tumor antigen was observed in several subclones, suggesting that extinction was correlated with the loss of murine fibroblast chromosomes from these hybrids. The cis-acting region that mediates extinction resides within the viral regulatory region, which contains two 98-base-pair repeats that have enhancer activity. These data demonstrate that cellular factors that negatively regulate viral gene expression contribute to the restricted cell-type specificity of this virus.

[Cytomorphologic study of a line of hybrid somatic cells persistently infected with the scrapie agent]. / Tsitomorfologicheskoe issledovanie linii gibridnykh somaticheskikh kletok, persistentno infitsirovannykh agentom skrepi.

Virological, cytological and electron microscopic methods were used to study the peculiarities of the scrapie agent persistence in the tissue culture of the mouse and human hybrid cells. A long-term persistence of the scrapie agents in the cells (658 days) has been obtained. The fact of persistence is confirmed by the results of biotest and electron microscopic studies of the mouse CNS. The agent persistence promotes a decrease in the mitotic activity of the infected cells and development of the ultramicroscopic changes in cells similar to the picture of the specific changes in the CNS of mice inoculated by scrapie agent.

Mechanism of interaction between endogenous ecotropic murine leukemia viruses in (BALB/c X C57BL/6) hybrid cells.

The germline ecotropic murine leukemia (MuLV) proviruses of BALB/c and C57BL/6 (B6) mice were analyzed to determine the molecular basis of low virus expression in these mouse strains and to determine the mechanism of interaction of these two proviruses. Previous work had demonstrated that the BALB/c endogenous ecotropic provirus was infectious but unable to induce XC cell syncytia formation, and that induced (BALB/c X B6) hybrid cells expressed 10- to 50-fold more XC syncytia than induced parental cells. Two independently isolated DNA clones of the B6 endogenous ecotropic provirus were noninfectious following transfection into cells, and cell lines that expressed this viral genome produced noninfectious MuLV. Nucleotide sequencing of the mutant region of the B6 provirus indicated that the defective nature of this provirus resulted from an amino acid substitution of proline for alanine in the central portion of reverse transcriptase. From the analysis of the virus produced by induced hybrid cells, and the patterns of steady-state viral RNA in induced cells, we propose that the enhanced XC cell syncytia formation observed in hybrid cells is due to trans-complementation of viral proteins and not viral recombination or trans-activation of viral genome expression.

Restriction of human adenovirus replication in Chinese hamster cell lines and their hybrids with human cells.

We have found that the replication of human adenovirus (Ad2) is restricted in multiple Chinese hamster cell lines including CHO and V79. The major site of restriction involves differential accumulation of late viral proteins as demonstrated by immunofluorescence assay and polyacrylamide gel electrophoresis with and without prior immunoprecipitation. Synthesis of fiber and penton base are markedly reduced, whereas others, such as the 100K polypeptide, are synthesized efficiently. This pattern of restriction is similar to that previously reported for Ad2 infection of several monkey cell lines; however, the restriction is more marked in the Chinese hamster cell lines. The restriction is most likely due to a deficient cellular function since stable cell hybrids between V79 or CHO and human cells are permissive for virus replication. By analysis of a series of hybrids with reduced numbers of human chromosomes, fiber synthesis was correlated with the presence of the short arm of human chromosome 3. More hybrids showed restoration of fiber synthesis than production of progeny virus, suggesting that more than one unlinked function is required for the latter.