Malignant Rabbit Fibroma Virus Research Articles

Regulation of p53 Gene Expression by a Poxviral Transcription Factor

Identification of regulators of p53 expression is a crucial step in understanding the diverse functions of p53 and its role in cellular homeostasis and responsiveness to insult. Several viral proteins inactivate p53 as a modulator of cell cycle progression and apoptosis. Here, we report that a unique leporipoxviral transcription factor greatly increases levels of p53 mRNA. C7, an early transcription factor from malignant rabbit fibroma virus (MV), is an important determinant of MV virulence. Its effects on cellular gene expression were studied both during MV infection and in isolation, with C7 DNA cloned into a pKC4 expression plasmid. In both settings, C7 caused increased p53 mRNA levels. The increased p53 mRNA reflected new transcription. C7-induced increased transcription was selective: mRNAs for some cellular genes increased but those for many other genes (e.g., Bcl2) were unchanged. Immunoblot and immunohistochemical analysis of pKC7-transfected and MV-infected cells showed that increased transcription led to an increase in p53 protein. EMSA analysis suggested that C7 bound the human p53 promoter between −240 and −614 bp. These studies document the direct effects of a viral transcription factor on cellular gene expression, specifically that it upregulates p53 transcription.

Effect of virus infection on levels of transcripts for cellular genes

Malignant rabbit fibroma virus (MV) induces tumors composed of proliferating cells, principally fibroblasts, and vasculature. These tumors are associated with large amounts of collagen and other connective tissue proteins. We studied the effect of MV infection on levels of mRNA for αl chains of collagens type I, III and V in RK-13 fibroblasts and α2 chain of collagen type I. MV infection induces expression of specific collagen genes at particular time points after infection in vitro. Expression of these collagen genes is clearly different in MV-infected cells compared to uninfected cells. Transcript levels for a cellular transcription factor that regulates expression of αl chain type I collagen, cbf-a, were increased in MV-infected cells prior to the increase in type I collagen mRNA. The virus infection also specifically induced increased levels of mRNA for the cellular transcription factors c-fos and SP1. MV infection is therefore associated with increased levels of specific cellular mRNAs, and is correspondingly associated with increased mRNA for transcription factors that may regulate transcription of these genes. The ability of malignant fibroma virus to influence expression of cellular genes may be exerted through the cells' own transcription regulatory apparatus.

Transforming Growth Factor Alpha, Shope Fibroma Growth Factor, and Vaccinia Growth Factor Can Replace Myxoma Growth Factor in the Induction of Myxomatosis in Rabbits

The epidermal growth factor (EGF) homologues encoded by vaccinia virus, myxoma virus, and malignant rabbit fibroma virus have been shown to contribute to the pathogenicity of virus infection upon inoculation of susceptible hosts. However, since the primary structures of these growth factors and the disease profiles induced by different poxvirus genera vary substantially, the degree to which the various EGF homologues perform similar roles in viral pathogenesis remains unclear. In order to determine whether different EGF-like growth factors can perform qualitatively similar functions in the induction of myxomatosis in rabbits, we created recombinant myxoma virus variants in which the native growth factor, myxoma growth factor (MGF), was disrupted and replaced with either vaccinia virus growth factor, Shope fibroma growth factor, or rat transforming growth factor alpha. Unlike the control virus containing an inactivated MGF gene, which caused marked attenuation of the disease syndrome and substantially less proliferation of the epithelial cell layers in the conjunctiva and respiratory tract, the recombinant myxoma virus strains expressing heterologous growth factors produced infections which were both clinically and histopathologically indistinguishable from wild-type myxomatosis. We conclude that these poxviral and cellular EGF-like growth factors, which are diverse with respect to primary structure and origin, have similar biological functions in the context of myxoma virus pathogenesis and are mitogenic for the same target cells.

Sequence and analysis of the BamHI “D” fragment of Shope fibroma virus: comparison with similar regions of related poxviruses

Differences observed in the virulence of two related leporipoxviruses are closely tied to a particular region of their genomes. For the virulent poxvirus of this pair, malignant rabbit fibroma virus (MV), this region is the BamHI “C” fragment, which is 10.7 kb. For the avirulent poxvirus, Shope fibroma virus, SFV, this region is the corresponding BamHI “D” fragment, which is 13.1 kb. As part of our attempt to understand the virulence of these two viruses, we sequenced these two DNA fragments. The sequence for the BamHI “C” fragment of MV is reported elsewhere (Strayer et al., 1991). We report here the sequence for SFV's BamHI “D” fragment and resultant open reading frames, and compare both DNA and open reading frame structures to those of MV and other known poxviruses. The BamHI “D”fragment of SFV contains 12 open reading frames of 100 amino acids or more, arranged similarly to orf's in MV and vaccinia. Striking similarities between SFV and MV are seen in certain parts of this restriction fragment, including substantial stretches of DNA in which the two viruses are identical. Clear homologies exist between these leporipox virus genomes and those of other related poxviruses. To understand the pathogenesis of virus infection, one must appreciate the structure of those viral genes that play important roles in infection.

Virus-induced loss of class I MHC antigens from the surface of cells infected with myxoma virus and malignant rabbit fibroma virus.

Shope fibroma virus (SFV) is a leporipoxvirus that causes localized benign fibromas in immunocompetent adult rabbits that spontaneously regress due, in part, to a cell-mediated immune response. Myxoma virus (MYX) and malignant rabbit fibroma virus (MRV) are related leporipoxviruses that induce rapidly lethal generalized infections accompanied by tumors and immunosuppression. Because only these latter two viruses are known to compromise cell-mediated antiviral responses, cell surface levels of class I MHC molecules in SFV-, MRV-, and MYX-infected cells were investigated by fluorescent activated cell sorting analysis using a variety of different anti-HLA mAb. After infection with MYX or MRV there is a rapid decrease in the levels of detectable surface class I epitopes as detected by each antibody and by 24 h postinfection class I MHC Ag levels at the cell surface approach the level of background fluorescence observed with control antibodies. In contrast, only a moderate class I decrease is seen during infection with either SFV or vaccinia virus, an orthopoxvirus that is neither tumorigenic nor immunosuppressive. Surface class I marker loss induced by MYX and MRV is not simply due to nonspecific inhibition of total cellular protein synthesis by the viruses because class I levels decrease much further than the extent measured by estimating surface marker turnover in the presence of the protein synthesis inhibitor cycloheximide. Thus the loss of cellular surface class I molecules greatly exceeds the drop in level caused by complete blockage of host cell gene expression, and must involve removal or masking of preexisting class I epitopes from the cell surface by MRV/MYX. Cell surface levels of the transferrin receptor are unaffected by MYX and MRV infection, suggesting the observed class I decrease is not a nonspecific effect on total cell surface glycoproteins. Analysis of cells infected with MRV/MYX in the presence of cycloheximide or of cytosine arabinoside, an inhibitor of poxviral DNA replication, indicates that the class I marker loss is mediated in part by one or more viral late gene products. A probable explanation is that MRV/MYX late protein(s) interact with the class I MHC complex to either physically sequester these away from the cell surface and inhibit their recycling or else induce a conformational change that precludes recognition by all class I antibodies tested. In either event, we propose that such a major perturbation of the class I MHC complex would likely downregulate the class I-mediated presentation of viral Ag required to initiate cell-mediated immunity to these viruses.

Deletion of the growth factor gene related to EGF and TGF alpha reduces virulence of malignant rabbit fibroma virus.

The role of the epidermal growth factor homologue in malignant rabbit fibroma virus (MRV) pathogenicity was investigated by constructing a viral growth factor deletion mutant (MRV-GF-). Since MRV is a recombinant virus with a myxoma virus background but possesses some terminal sequences derived from Shope fibroma virus, the growth factor gene in MRV is in fact identical to Shope fibroma growth factor (SFGF). Although no significant differences were detected in the in vitro characteristics of MRV and MRV-GF-, a pronounced attenuation was observed after inoculation of the test rabbits with MRV-GF-. Animals infected with wild-type MRV uniformly developed a fatal syndrome involving disseminated tumors accompanied by purulent conjunctivitis and rhinitis. In contrast, although MRV-GF- recipients developed similar initial signs of the MRV disease syndrome, 75% of these animals completely recovered from the viral and secondary bacterial infections and became immune to subsequent MRV challenge. Tumors in MRV-GF- recipients displayed earlier and more prominent inflammatory reactions than their wild-type MRV counterparts and contained fewer proliferating cells. Squamous metaplasia and hyperplasia of target epithelia were less pronounced in MRV-GF- than in MRV infection. We conclude that SFGF is a major virulence factor in MRV infection and is responsible for at least some of the cellular proliferation observed at tumor sites. In addition, the diminished ability of MRV-GF- to cause hyperplasia in nasal and conjunctival epithelia may decrease the extent of gram negative bacterial overgrowth as compared to the parental virus and hence contribute to the dramatic reduction in the lethality of MRV-GF- infection.

Sequence and analysis of a portion of the genomes of shope fibroma virus and malignant rabbit fibroma virus that is important for viral replication in lymphocytes

The 10.7-kb BamHI “C” restriction fragment of malignant rabbit fibroma virus (MV) contains genes that are important for its immunosuppressive activity. When this fragment is transferred to a related avirulent leporipoxvirus, Shope fibroma virus (SFV), recombinant viruses show clinical features characteristic of MV: they replicate in lymphocytes and alter immune function in vitro, induce disseminated tumors in recipient rabbits, and are immunosuppressive in vivo. The 10.7-kb BamHI “C” restriction fragment of MV was sequenced in its entirety. Its DNA sequence and the 14 ORF's derived from analyzing this sequence are discussed. Analysis of known open reading frames to which the ORF's from MV's Bam “C” fragment show homology permits us to identify some MV ORF's showing high degrees of similarity to known and postulated proteins produced by vaccinia virus. Functions for some of these vaccinia proteins are known, while functions for others are hypothetical or unknown. Further analysis of genetic determinants of MV's virulence has indicated that two overlapping restriction subfragments of the BamHI “C” fragment can transfer MV's virulent behavior to SFV. The 0.7-kb region in which these two subfragments overlap includes the C-terminus of MV orf C-7 and the N terminus of MV orf C-8. These correspond to the C- and N-termini, respectively, of SFV orf's D-9 and D-10 and to vaccinia orf's D-6 (early transcription factor) and D-7 (subunit of RNA polymerase). We sequenced the region of SFV's BamHI “D” fragment in this area and illustrate here the comparative sequences of this portion of SFV's genome and orf's. On the basis of comparisons between MV, SFV, and vaccinia in this area we discuss the potential significance of these observations.

Myxoma virus expresses a secreted protein with homology to the tumor necrosis factor receptor gene family that contributes to viral virulence

Poxviruses are known to contain a large number of open reading frames, particularly near the termini of the viral genome, that are not required for growth in tissue culture. However, many of these these gene products are believed to play important roles in determining the virulence of the virus by modulating the host immune response to the infection. Recently it has been shown that Shope fibroma virus encodes, within the terminal inverted repeats, a protein (T2) related to the cellular tumor necrosis factor receptor (TNFR) and which specifically binds both TNFa and TNFβ We have sequenced the terminal regions of two other Leporipoxviruses (myxoma virus and malignant rabbit fibroma virus) that are extremely invasive and capable of inducing extensive immunosuppression in rabbits and demonstrate that they also encode a closely related T2 homolog with all the structural motifs predicted for a secreted TNF binding protein. To investigate the biological role of the T2 protein, we have inactivated the myxoma virus T2 gene within each copy of the viral TIR by the insertion of a dominant selectable marker ( Escherichia coli guanosine phosphoribosyltransferase) and selection of the recombinant virus in the presence of mycophenolic acid. The success of the inactivation of both copies of T2 was confirmed by the loss a broad protein band (52–56 kDa) of the predicted size for T2 from the profile of proteins secreted from mutant virus-infected BGMK cells at earlytimes after infection. Although the T2-minus recombinant myxoma virus grew normally in tissue culture, upon infection of susceptible rabbits the viral disease was observed to be significantly attenuated. The majority of infected rabbits were able to mount an effective immune response to the infection and completely recovered. These survivor rabbits became immune to subsequent challenge with wild type myxoma virus. We conclude that the T2 viral protein is an important secreted virulence factor and that it in all likelihood functions by compromising the antiviral effects of TNF. We propose the term “viroceptor” to describe viral-encoded homologs of cellular lymphokine receptors whose function is to intercept the activity of the cognate lymphokine in order to short circuit the host immune response to the viral infection.

Myxoma virus and malignant rabbit fibroma virus encode a serpin-like protein important for virus virulence

The leporipoxviruses Shope fibroma virus (SFV), the myxoma virus (MYX), and the SFV/MYX recombinant malignant rabbit fibroma virus (MRV) are closely related yet induce profoundly different diseases in the European rabbit. SFV, which produces a benign tumor at the site of inoculation, is cleared by the immune system after approximately 2 weeks whereas MYX and MRV induce a rapidly lethal systemic infection characterized by generalized suppression of host immune functions. DNA sequencing studies reveal that MRV and MYX possess homologous gene members of the T6/T8/T9 family originally described in the terminal inverted repeat (TIR) of SFV. We also describe a gene present in both MYX and MRV genomes, but which has apparently evolved in the SFV genome into a fragmented pseudogene that appears to contribute to the aggressive nature of MYX and MRV infections. Translation of this open reading frame, designated MYXOMA SERPIN 1 (SERP1), reveals a protein sequence with highly significant homology to the super-family of serine protease inhibitors (serpins) which also includes a number of other poxviral proteins. In the MYX genome the SERP1 gene lies entirely within the TIR sequences and is thus present as two copies, while in the MRV genome SERP1 is present in the unique sequences adjacent to the TIR boundary and hence is a single copy. The amino acid homology between the putative active site of SERP1 and those of other serpins predicts that the target enzyme will be different from the known catalog of serine antiprotease substrates. Deletion of this gene from MRV significantly attenuates the disease spectrum induced by the normally lethal virus. Although the MRV-S1 deletion construct (MRV with SERP1 gene deleted) grows in all tissue culture cells tested in a fashion identical to the MRV parent, the majority of rabbits infected with MRV-S1 are able to mount an effective immune response and totally recover from the virus infection to become resistant to subsequent challenge by MRV or MYX.

Tumorigenic poxviruses: Fine analysis of the recombination junctions in malignant rabbit fibroma virus, a recombinant between shope fibroma virus and myxoma virus

Malignant rabbit fibroma virus (MRV) has been shown to be a lethal tumorigenic poxvirus of rabbits derived from a recombination event between Shope fibroma virus (SFV), which induces benign fibromas in rabbits, and myxoma virus, the agent of myxomatosis. We have cloned and sequenced all of the MRV recombination junctions, which are located near the left and right terminal inverted repeat (TIR) regions, and present a composite map of the MRV genome with respect to the relevant gene products. The two junctions closest to the MRV termini, at identical positions at the left and right ends, are at nucleotide 5272 and result in an in-frame fusion protein (ORF T-5) in which the N-terminal 232 aa are derived from an SFV sequence linked to a C-terminus derived from myxoma. At the left MRV TIR the recombination junction distal from the terminus maps to nucleotide 9946 but leaves the adjacent gene virtually unchanged from its SFV homolog. At the right terminus, the relevant junction sequences from MRV and myxoma could not be cloned in wild-type Escherichia coli but were maintained stably in a recA recBC sbcB host. The SFV/myxoma junction at this location maps 5′ to a growth factor gene (SFGF) which is related to those encoding epidermal growth factor and transforming growth factor-α. As a result, the myxoma growth factor gene has been deleted in MRV and replaced in toto by the SFV gene. The recombination junction upstream from the SFGF gene creates an in-frame fusion in ORF T11-R in which the N-terminal amino acids are derived from myxoma and the remainder from SFV. In summary, MRV has received the following ORFs from SFV: at the left terminus T5 (fusion), T6, T7, and T8; at the right terminus, T5 (fusion), T6, T7, T8, T9-R, SFGF, and T11-R (fusion).

Immunosuppression during viral oncogenesis. V. Resistance to virus-induced immunosuppressive factor.

Rabbits given malignant rabbit fibroma virus (MV) develop severe immunologic dysfunction during the course of infection. Splenic T lymphocytes from these rabbits elaborate a soluble non-specific immunosuppressive factor (virus-induced suppressor factor (VISF]. As malignant rabbit fibroma virus infection progresses, normal immunologic responsiveness returns. This recovery is multi-factorial and involves production by T lymphocytes of a soluble factor capable of antagonizing the activity of VISF. This soluble anti-suppressor factor (ASF) is not a generalized immunologic potentiator. Its sole apparent effect on immune function appears to be to antagonize the activity of VISF. The protective effects of ASF are evident only when suppressor factors and ASF are simultaneously present in culture. Pre-treatment of target cells with ASF-containing culture supernatants does not render them insensitive to the immunosuppressive effects of subsequent treatment with VISF. In addition, ASF appears to be directly responsible for antagonizing VISF activity. That is, ASF does not appear to initiate an anti-suppressive cascade by activating a population of cells that in turn generate secondary protective factors. ASF-producing cells do not bind Vicia villosa lectin, as do contra-suppressor cells described by others. In almost all of these features, the system we describe herein differs from systems in which other investigators have described factors that antagonize the effects of suppressor factors.

Immunosuppression during viral oncogenesis. IV. Generation of soluble virus-induced immunologic suppressor molecules.

We describe herein functional attributes and generation of immunologic suppressor activity elaborated in response to oncogenic virus infection. Malignant rabbit fibroma virus-induced immunologic suppressor factor (VISF) is a T cell product produced in peak quantities by spleen cells taken from infected rabbits 7 days after infection in vivo. Its production does not appear to require macrophage participation. VISF is highly labile, 3.5 to 12 kDa, and capable of suppressing both B and T lymphocytic responses. Indomethacin and the cyclic nucleotides cAMP and cGMP inhibit its generation. VISF activity is neither antigen nor species specific. It suppresses murine and leporine immune responses to antigens unrelated to the inducing virus. Comparable suppressor activity may be induced by infecting an apparently non-functional rabbit T lymphoma line, RL-5, with malignant rabbit fibroma virus. VISF is principally a suppressor-inducer factor: in vitro, lymphocytes exposed to VISF do not show decreased immunologic responsiveness until 4 days of culture. VISF induces T suppressor cell activity when normal spleen cells are exposed briefly to VISF. Thus, immunosuppressive consequences of malignant fibroma virus infection are partially mediated by a small, non-specific T cell-derived suppressor lymphokine with unique functional characteristics. Non-specific immunologic dysfunction that often attends virus infections may reflect the activity of such factors in humans as well.

Tumorigenic poxviruses: Transcriptional mapping of the terminal inverted repeats of shope fibroma virus

A composite transcriptional map for the entire 12.4-kb terminal inverted repeat (TIR) region of the Shope fibroma virus (SFV) genome has been determined. Northern blotting and S1-nuclease mapping were used to determine the regions which are transcribed, their temporal relationships, as well as the transcriptional initiation sites. Sequences representing the entire TIR are transcribed into poly(A) + mRNA at both early and late times in the infection. Fifteen transcriptional initiation sites were mapped, 12 within the TIRs and 3 within the unique sequences close to the junction between the right TIR and the unique internal sequences. Ten of the 12 transcriptional initiation sites within the TIR and 2 of the 3 sites outside the right TIR correspond to the 5′-ends of the major open reading frames (ORFs) Ti to T9 plus the SFV growth factor gene. The 3 other initiation sites map within ORFs but near potential start codons for shorter polypeptides. All the expressed ORFs are tandemly arranged and transcribed toward the hairpin terminus. At early times during SFV infection of cultured rabbit cells, transcription of each ORF gives rise to a transcript of distinct size, while at late times termination of transcription is imprecise and substantial read-through into downstream sequences occurs. These results are discussed in light of recent observations on the related recombinant leporipoxvirus, malignant rabbit fibroma virus, which suggest that one or more gene products from this region of the SFV genome are implicated in viral tumorigenicity.

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.

Virus-lymphocyte interactions during the course of immunosuppressive virus infection.

Malignant rabbit fibroma virus (MV) is a lymphocytotropic leporipoxvirus which produces profound immunological dysfunction and lethal fibromyxosarcoma. We examined virus recovery from splenic lymphocytes as a function of time after inoculation in vivo, and correlated this with both immunological function and expression of virus-induced host suppressor activity. MV was most abundant in lymphocytes obtained 4 days following inoculation. At that time, immune function was relatively normal and host suppressor activity was not observed. By 7 days after infection, when active host immunosuppressor functions were observed, virus recovery was decreased. Eleven days post-inoculation host immune function began to recover despite increasing virus-induced tumours and developing opportunistic infection. Simultaneously, MV was no longer recoverable from spleen cells. Spleen cells from day 11 tumour-bearing rabbits did not support MV replication as efficiently as did normal or day 4 or 7 splenic lymphocytes, but they did not alter the ability of MV to grow in the latter cells. By fluorescence examination and cytofluorography, splenic lymphocytes bearing MV antigens were abundant 7 days after infection but disappeared by 11 days. This was temporally related to production of neutralizing antibody to MV, and development of virus-specific lymphocyte proliferative activity. The composition of splenic lymphocytes changed as well: the normal ratio of about 1:1 for B and T cells changed to 1:2 by day 7, and then inverted to almost 2:1 by day 11. Rabbits infected with MV thus appear to recover their immune function, concurrently eliminate virus-infected lymphocytes, and elaborate high titres of neutralizing serum antibodies despite progressive infections and tumour development.

Immunosuppression in viral oncogenesis. III. Effects of virus infection on interleukin 1 and interleukin 2 generation and responsiveness.

Malignant rabbit fibroma virus (MV) is an oncogenic immunosuppressive leporipoxvirus. We studied the effects of MV infection and MV-associated tumor-induced suppressor factor (TISF) on the production of and responsiveness to interleukins 1 and 2. Adherent cells from MV tumor-bearing rabbits elaborate adequate amounts of IL 1 in response to E. coli endotoxin. Neither live virus nor TISF alters the production or the responsiveness to IL 1. However, when we examined spleen cells from rabbits 7 days after MV inoculation, we noted that their ability to produce and respond to IL 2 is deficient. Despite their relatively poor capacity to produce IL 2, these spleen cells express receptor for IL 2 in normal amounts, as measured by the monoclonal antibody 7D4. TISF derived from T lymphocytes from MV tumor-bearing rabbits is by itself capable of inhibiting partially normal secretion of IL 2 and also the response of the cloned murine T cell line HT-2 to added IL 2. Full expression of the immunosuppressive capacity of spleen cells from MV tumor-bearing rabbits requires cell-cell contact, however, and cannot be replaced by either live virus or spleen cell supernatants. Such spleen cells inhibit normal mitogen responsiveness, a defect not remedied by adding exogenous IL 2. Immunologic dysfunction induced by MV infection is transient, and by 11 days after virus inoculation, actively mediated recovery from immunosuppression is observed. We found that spleen cells from rabbits studied 11 days postinoculation secreted IL 2 normally. Thus, immunologic dysfunction secondary to infection with malignant rabbit fibroma virus reflects deficiencies in both elaboration of and response to IL 2, and return of immune function later in the course of the infection is associated with return of the ability of lymphocytes to secrete IL 2.

Transcriptional mapping of early RNA from regions of the Shope fibroma and malignant rabbit fibroma virus genomes

Malignant rabbit fibroma virus (MV) is a recombinant poxvirus derived from Shope fibroma virus (SFV) and rabbit myxoma virus ( D. S. Strayer, E. Skaletsky, G. F. Cabirac, P. A. Sharp, L. B. Corbeil, S. Sell, and J. L. Leibowitz, 1983a, J. Immunol. 130, 399–404; W. Block, C. Upton, and G. McFadden, 1984, Virology 140, 113–124). We report here the transcriptional mapping of early RNAs transcribed from the SFV sequences within MV and from the corresponding regions in SFV. Hybridization analysis and S1 nuclease mapping of RNA using viral DNA probes were used to define 5′ and 3′ ends of the various transcripts. The RNAs described here are transcribed in one direction in a densely arranged head to tail fashion similar to that described for some vacinia virus early transcriptional units. At late times of infection the early SFV RNAs are not detected whereas the early MV RNAs are present in minor amounts. The early SFV and MV transcripts range in size from 3170 to 425 nucleotides (nt) long. All of the longer transcripts are produced as a result of read through transcription. Three MV transcripts contain fused SFV and rabbit myxoma virus sequences due to transcription through the recombination junction region in the MV genome. Two other MV transcripts are transcribed from a unique initiation site near another recombination junction region resulting in RNAs that are composed of SFV sequences having unique 5′ ends.

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.

Immunologic dysfunction during viral oncogenesis: II. Inhibition of cellular immunity to viral antigens by malignant rabbit fibroma virus

The ability of two related viruses—Shope fibroma virus (SFV) and malignant rabbit fibroma virus (MV)—to induce virus-specific immune responses in lymphocytes of recipient animals was studied. SFV produces a benign local tumor which regresses in 12–14 days. Using an assay for virus-induced lymphocyte blastogenesis lymphocytes reactive to SFV were detected, both in rabbits bearing SFV-induced tumors and in rabbits whose SFV-induced tumor had regressed. These virus-reactive cells were detected in peripheral blood and spleen, and in lymph nodes draining the primary tumor. In contrast, MV produces a disseminated tumor and eventual death. MV does not induce detectable blastogenic responses in lymphocyte populations. SFV and MV are antigenically cross reactive: rabbits immune to SFV do not develop MV-induced tumors, and antisera to each virus neutralize both equally. Lymphocytes from SFV-infected rabbits proliferate in vitro in response to MV that has been inactivated by ultraviolet light (uv/MV) but not to infectious MV. In contrast, lymphocytes from rabbits infected with MV do not respond to uv-inactivated MV or to SFV. Thus, infectious MV inhibits the development of normal blastogenic responses in vivo and prevents the expression of those responses in lymphocytes from MV-resistant, SFV-immune rabbits in vitro. The relevance of this impairment to the differences in the clinical courses of SFV- and MV-induced tumors is discussed.