Latent Marek's disease virus can be activated from its chromosomally integrated state in herpesvirus-transformed lymphoma cells.

Marek's disease virus (MDV), a lymphotropic herpesvirus, induces T-cell lymphomas in chicken, its natural host. The lymphoma cells are latently infected with MDV but the viral contribution to the transformed phenotype is not understood. To investigate the virus-cell interaction, we focused on the status of MDV in the transformed cells. By the use of highly sensitive fluorescent in situ hybridization with metaphase chromosomes, we found (i) MDV DNA to be randomly integrated at multiple sites in the chromosomes of primary lymphoma cells from chicken tissues; (ii) extrachromosomal, circular MDV genomes were absent and linear virion DNA was usually not detectable in the latently infected lymphoma cells; (iii) the pattern of integration sites revealed the clonal origin of the tumour cells; which (iv) was retained in in vitro established cell lines derived from primary lymphomas; (v) activation of the lytic phase of MDV's life cycle occurred in vitro suggesting that MDV can escape from its integrated status by an unknown mechanism.     

Macrophage restriction of Marek's disease virus replication and lymphoma cell proliferation.

Macrophages are shown to restrict the replication of Marek's disease virus (MDV) and isotope uptake by spleen cells from chickens bearing Marek's disease (MD) tumors. The titer of virus from duck embryo fibroblasts (DEF) co-cultivation with MDV-spleen cells pretreated to deplete marcophages was 4- to 18-fold higher than with untreated cells. Treated MDV-spleen cells increased isotope uptake by 2-fold. These restrictive activities are attributable to macrophage regulation of cell proliferation.     

Demonstration of cells with Marek's disease tumor-associated surface antigen in chicks infected with herpesvirus of turkey, O1 strain.

The presence of Marek's disease tumor-associated surface antigen (MATSA) was demonstrated by the direct and indirect membrane immunofluorescent tests, in chicks inoculated 7-10 days earlier with herpesvirus of turkeys (HVT), O1 strain. In in vitro cultures of spleen lymphocytes and ovaries obtained from these chicks, MATSA-positive cells were also detected after 1-7 days cultivation. A possible mechanism of protection by HVT vaccine against Marek's disease is proposed.     

Cell-mediated cytotoxicity of lymphocytes from chickens inoculated with herpesvirus of turkey against a Marek's disease lymphoma cell line (MSB-1).

Using a new device which increases the sensitivity of detection of specific immune lysis of target cells by labeling them with [35S]-methionine, the in vitro cell-mediated cytotoxic response of spleen lymphocytes and peripheral blood lymphocytes from chickens vaccinated with herpesvirus of turkey (HVT), O1 strain, against MSB-1 line cells was clearly demonstrated. The cytotoxic activity was clearly inhibited by pretreatment of effector lymphocytes with anti-T lymphocyte serum and complement. The activity was greater using T cells purified from spleen lymphocytes and peripheral blood lymphocytes than with the unfractionated cells, indicating that T lymphocytes play the main role in effector activity. Using sera from HVG-vaccinated chickens, no significant cytotoxic effects were detected in the complement-dependent antibody cytotoxicity test against MSB-1 cells. These results suggest that cellular immunity against the surface antigen of Marek's disease (MD) lymphoma cells is mainly related to the preventive mechanism against MD incidence by HVT vaccination.     

Release of mitotic descendants by giant cells from irradiated Burkitt's lymphoma cell line.

Polyploid giant cells are produced as part of the response of p53 mutant Burkitt's lymphoma cell lines to high doses of irradiation. Polyploid giant cells arise by endo-reduplication in the first week after a single 10 Gray dose of irradiation. Within the giant cells a sub-nuclear structure is apparent and within this, sub-nuclear autonomy is evident, as displayed by independent nuclear structure and DNA replication in different parts of the nucleus. The majority of these cells soon die as apoptotic polykaryons. However, approximately 10-20% of giant cells remain viable into the second week after irradiation and begin vigorous extrusion of large degraded chromatin masses. During the second week, the giant cells begin to reconstruct their nuclei into polyploid 'bouquets', where chromosome double-loops are formed. Subsequently, the bouquets return to an interphase state and separate into several secondary nuclei. The individual sub-nuclei then resume DNA synthesis with mitotic divisions and sequester cytoplasmic territories around themselves, giving rise to the secondary cells, which continue mitotic propagation. This process of giant cell formation, reorganization and breakdown appears to provide an additional mechanism for repairing double-strand DNA breaks within tumour cells.     

Retroviral insertional activation of the c-myb proto-oncogene in a Marek's disease T-lymphoma cell line.

Marek's disease virus (MDV) is an avian herpesvirus that causes, in chickens, a lymphoproliferative disease characterized by malignant transformation of T lymphocytes. The rapid onset of polyclonal tumors indicates the existence of MDV-encoded oncogenic products. However, the molecular basis of MDV-induced lymphoproliferative disease and latency remains largely unclear. Several lines of evidence suggest that MDV and Rous-associated virus (RAV) might cooperate in the development of B-cell lymphomas induced by RAV. Our present results indicate for the first time that MDV and RAV might also act synergistically in the development of T-cell lymphomas. We report an example of an MDV-transformed T-lymphoblastoid cell line (T9) expressing high levels of a truncated C-MYB protein as a result of RAV integration within one c-myb allele. The chimeric RAV-c-myb mRNA species initiated in the 5' long terminal repeat of RAV are deprived of sequences corresponding to c-myb exons 1 to 3. The attenuation of MDV oncogenicity has been strongly related to structural changes in the MDV BamHI-D and BamHI-H DNA fragments. We have established that both DNA restriction fragments are rearranged in the T9 MDV-transformed cells. Our results suggest that retroviral insertional activation of the c-myb proto-oncogene is a critical factor involved in the maintenance of the transformed phenotype and the tumorigenic potential of this T-lymphoma cell line.     

Status of Marek's disease virus in established lymphoma cell lines: herpesvirus integration is common.

Six cell lines derived from Marek's disease lymphomas of chickens and turkeys were investigated for the status of Marek's disease virus (MDV) DNA. In the transformed T- and B-cell lines, viral DNA could be detected by conventional Southern blot hybridization, by Gardella gel electrophoresis, and by in situ hybridization of metaphase and interphase chromosomes. Integration of viral DNA into the host cell chromosome was observed in all cell lines. Two to 12 integration sites of viral DNA could be detected in metaphase chromosome spreads. The integration sites were characteristic for the individual cell lines and were preferentially located at the telomers of large- and mid-sized chromosomes or on minichromosomes. In four of six cell lines, a minor population of latently infected cells supported the lytic cycle of MDV, giving rise to linear virion DNAs. In one of these cell lines, a third species of MDV DNA could be detected with properties reminiscent of covalently closed circular DNA. The finding that MDV integrates regularly into the genomes of latently infected cells is crucial to understanding the molecular biology of herpesvirus-induced tumors in the natural host.     

Depression of in vitro responsiveness to phytohemagglutinin in spleen cells cultured from chickens with Marek's disease.

Cultures of dispersed spleen cells, prepared from MDV-infected chickens with MD visceral lymphomas, showed marked depression of responsiveness to the T cell mitogen PHA, as measured by 3H-Tdr incorporation in cells in vitro. When data are expressed quantitatively in terms of cpm/10(5) viable cells, the functional depletion of PHA-responsive cells appear to result from lower levels of 3H-Tdr incorporation in the PHA-stimulated spleen cultures from chickens with acute MD symptoms, as compared to similar cultures from uninfected isolator-reared control chickens. It is suggested that depression of PHA-induced blastogenesis is spleen cell cultures from chickens with acute MD reflects virus-related alterations in T lymphocytes.     

Propagation and infectivity titration of the Gifu-1 strain of chicken anemia agent in a cell line (MDCC-MSB1) derived from Marek's disease lymphoma

Chicken anemia agent (CAA) propagated in an established cell line derived from Marek's disease (MD) lymphoma (MDCC-MSB1). When passaged 19 times in MDCC-MSB1 cell cultures, it produced anemia of the same severity in chicks as it did before passage. Titration of the infectivity of CAA was performed successfully with subcultures of MDCC-MSB1 cell cultures which had been inoculated with serial tenfold dilutions of infected material. In it, no infected cultures could be subcultured. The propagation of CAA was also proved in the MD cell line, MDCC-JP2, and the avian lymphoid leukosis (LL) cell line, LSCC-1104B1, but not in the two MD cell lines, MDCC-RP1 and MDCC-BP1, or in the two LL cell lines, LSCC-1104X5 and LSCC-TLT. No CAA propagated in cell cultures prepared from skin and muscle, liver, or brain of chick embryos, or kidney, thymus, bursa of Fabricius, bone marrow, or white blood cells of chickens.     

Transplantable Marek's disease lymphomas. IV. Differences in lethality of lymphoma cell lines determined by route of inoculation

Mortality caused by inoculation of cells from four Marek's disease herpes virus-induced transplantable lymphomas was studied in two related inbred lines of chickens. While i.m. inoculation of 10(4) cells from each lymphoma generally caused death of all syngeneic recipients by 18 days post-inoculation, one of the lymphomas (UG2) was unique in that the same number of cells, when inoculated i.v., caused less than 20% mortality by that time. Lethality induced by cells from the other three lymphomas, when inoculated i.v., was as high or higher than when inoculated i.m. Mortality after intra-abdominal or s.c. inoculation of cells from all four lymphomas was similar to that after i.m. inoculations. Chickens inoculated with syngeneic UG2 cells by the i.v. route were significantly protected against a subsequent i.m. challenge with the same or other syngeneic lymphoma cells. However, UG2 lymphoma cells were highly lethal when inoculated i.v. into birds previously treated with the antimacrophage agent carageenan or immunosuppressed by neonatal treatment with cyclophosphamide. Thus, UG2 cells are distinctive in that, when inoculated i.v., they do not cause death of syngeneic hosts but instead induce resistance to a lethal challenge.