DNA ligase gene disruptions can depress viral growth and replication in poxvirus-infected cells.

Poxvirus-encoded DNA ligases are assumed to play a role in viral DNA replication; however mutational inactivation of vaccinia ligase has not been reported to affect viral growth rates in culture. This communication re-examines this surprising aspect of poxviral biology using both Shope fibroma virus (SFV) and vaccinia virus. SFV and vaccinia ligase deficiencies create essentially identical phenotypes. In particular, ligase-deficient SFV strains are mildly UV sensitive and etoposide resistant, phenotypes previously shown to characterize ligase-deficient vaccinia strains. Moreover, we find that ligase mutations can inhibit the growth of both SFV and vaccinia virus in vitro. The poor growth observed in the absence of a viral ligase is correlated with a two- to tenfold reduction in viral and extragenomic DNA synthesis. This phenotype is host dependent. No differences in viral growth or DNA yield were seen when vaccinia strains were cultured on rabbit (SIRC) cells, but ligase deficiencies reduced growth and DNA yields when vaccinia was plated on BSC-40 cells or SFV on SIRC cells. Despite these replicative defects, mutational inactivation of SFV ligase produced no detectable increase in the number of viral DNA breaks and had no effect on virus-catalyzed extragenomic DNA recombination or UV repair. We conclude that poxviral ligases do play a role in viral DNA replication, but the replicative defect is obscured in some cell lines.

Growth of malignant rabbit fibroma virus in lymphoid cells.

To understand better the immunosuppressive capacity of malignant rabbit fibroma virus (MV), we characterized MV growth in lymphoid cells. Replication of MV occurs in unstimulated normal spleen cells in vitro and is enhanced by adding T- or B-lymphocyte mitogens. In splenic T-lymphocyte preparations, comparable results are found: virus growth in the absence of mitogen, augmented by adding Con A. Unlike mature T cells, thymic lymphocytes support MV replication only when mitogen is added. When spleen cells from rabbits infected with MV in vivo are removed and cultured without mitogen, MV growth is again observed, with virus titer increasing about 10-fold per day of culture. In spleen cell populations from MV tumor-bearing rabbits, MV grows best in T lymphocytes, moderately in B lymphocytes, and least efficiently in adherent cells. When spleen cells are examined immediately following sacrifice, MV antigens are expressed solely on T lymphocytes from rabbits infected in vivo with MV 7 days previously. However, following overnight incubation in vitro a population of non-T lymphocytes displays cell membrane virus antigens. MV adapts itself somewhat to growth in lymphocytes, showing significantly greater growth in lymphocytes following passage in lymphocytes than is observed for non-lymphocyte-propagated virus. MV-infected lymphocytes also elaborate a factor that enhances MV growth in lymphocytes. Thus, MV replicates preferentially in mature T lymphocytes but will grow well in B cells as well. In vivo infection produces relatively small amounts of recoverable virus. However, when these lymphocytes are cultured in vitro virus replicates very well without added mitogens. These growth patterns may help to understand MV-induced immunologic dysfunction.

Reversal of virus-induced immune suppression.

We studied the immunosuppressive capacity of splenic lymphocytes from rabbits at different stages of progressive myxosarcoma induced by malignant rabbit fibroma virus (MV). Spleen cells taken from rabbits 7 days after virus inoculation proliferate poorly in response to Con A, and suppress normal responses to the mitogen. Those from animals 11 days after virus injection have recovered partially from MV-induced suppression. Further, their Con A responses are no longer suppressed by day 7 spleen cells. Supernatants from cultures of spleen cells from rabbits given MV 7 days previously suppress both antibody-producing and proliferative responses to unrelated antigens. Comparable supernatants from rabbits receiving MV 11 days before sacrifice neither suppress nor augment such responses. Mixing cells from 7 or 11 day MV rabbits with normal spleen cells gives similar results. When supernatants from spleen cell of rabbits with tumors induced 7 and 11 days previously are mixed, the supernatants from rabbits with 11-day-old tumors inhibit the suppressive capacity of those from animals with 7-day-old tumors. Similarly, mixing spleen cells from rabbits given MV 7 and 11 days previously results in culture supernatants that do not suppress normal antibody and proliferative responses. The ability of cells from rabbits given MV 11 days before to inhibit the effects of cells from rabbits given MV 7 days previously does not involve the production of interferon. Thus, despite progressive tumor burden, immunologic recovery is observed in rabbits 11 days after tumor virus inoculation. One factor in this recovery may be the generation of active inhibitors of virus-induced immunosuppression. Similar mechanisms may apply to recovery of immunologic function in other virus infections as well.

In vitro growth of two related leporipoxviruses in lymphoid cells.

We examined the in vitro growth patterns of two leporipoxviruses, malignant rabbit fibroma virus (MV) and Shope fibroma virus (SFV), in lymphoid cells. MV replicates well in normal spleen cells in vitro. At low m.o.i. (0.001), dramatic virus growth occurs in unstimulated cell cultures. This growth is enhanced by addition of the T lymphocyte mitogen, concanavilin A, or the B lymphocyte mitogen, Escherichia coli lipopolysaccharide. Shope fibroma virus does not grow in lymphocytes in culture, with or without mitogen stimulation. MV itself profoundly inhibits lymphocyte mitogenesis, while SFV does not. MV and SFV added to normal lymphocytes do not appear to alter their viability in culture. Thus, MV appears to be novel in its ability to replicate to high titer in resting lymphocytes. This growth pattern may be useful in understanding MV-induced immunologic dysfunction.

Electron microscopic immunoperoxidase studies on the accumulation of virus antigen in cells infected with Shope fibroma virus.

The indirect immunoperoxidase technique was used to investigate the development of the virus-specific intracellular and cell membrane antigens in cells infected with the Shope fibroma virus. Starting with 6 h p.i., virus antigen formed distinct inclusions within the cytoplasm frequently enclosed by endoplasmic reticulum. The endoplasmic reticulum disappeared almost completely 10 to 12 h p.i., coincidentally with the beginning of virus formation. The virus antigen was distributed throughout the cytoplasm. At the same time virus-induced antigen began to appear at the cell membrane and subsequently increased. No cytochemical staining could be observed on the endoplasmic reticulum, within the nucleus and within immature and mature virus particles. The correlation between antigen synthesis and changes in cell ultrastructure is discussed.

Rescue of vesicular stomatitis virus from homologous and heterologous interferon-induced resistance in human cell cultures by poxviruses.

In human cell cultures the ability of poxviruses to rescue vesicular stomatitis virus from human interferon-induced resistance was significantly more efficient than the ability to rescue it from simian interferon-induced resistance. The sensitivity of the poxvirus to interferon was not related to its ability to rescue vesicular stomatitis virus.