Myeloproliferative sarcoma virus: its effects on erythropoiesis in adult DBA/2J mice

Adult susceptible mice (DBA/2J) infected with MPSV (myeloproliferative sarcoma virus), a defective RNA tumour virus, develop splenomegaly and progressive disruption of the haematologic system culminating in death. The present study was specifically directed toward determining the effects of the virus on erythroid differentiation. Early and late precursor cells (erythroid burst-forming units; BFU-E and colony-forming units; CFU-E, respectively) were evaluated by the ability of bone marrow and spleen cells to form colonies of fully differentiated erythroid cells in vitro. MPSV caused substantial modification of both the BFU-E and CFU-E populations in the bone marrow and spleen of infected animals. Changes were detected in the CFU-E population preceding any significant increase in spleen weight. In the bone marrow, the proportion of CFU-E cells increased almost twofold by days 5-10 after virus infection but decreased by day 15. In the spleen, CFU-E frequency rose 40-fold by days 10-15 and then declined steadily prior to death. At the peak of CFU-E expansion, a small proportion of the population appeared to be erythropoietin (Ep) independent, although there was no evidence of a complete switch to Ep-independence which occurs in Friend virus-induced erythroleukemia. Dose-response curves showed that none of these data could be explained in terms of a changing responsiveness to Ep. However, evidence is presented that indicates that BFU-E from MPSV-infected animals lose or have a reduced requirement for burst-promoting activity (BPA) relative to normal cells although their progeny still need Ep for terminal erythroid differentiation.     

The myeloproliferative sarcoma virus causes transformation or erythroid progenitor cells in vitro

The myeloproliferative sarcoma virus induces spleen focus formation in vivo and transforms fibroblasts in vitro. We showed in this study that in vitro infection of spleen or bone marrow cells from susceptible mice with the myeloproliferative sarcoma virus leads to the formation of erythroid bursts. Under optimal conditions erythroid bursts formed in the absence of added erythropoietin, but the addition of as little as 0.05 U of erythropoietin per ml to infected cultures resulted in a significant increase in numbers of erythroid bursts and the proportion of hemoglobinized cells. A comparison of the kinetics of burst formation and the size of the induced bursts with those induced with Friend virus suggested that either sarcoma virus such as the myeloproliferative sarcoma virus or the target cells for the two viruses were not the same. Density characterization and heat lability studies indicated that the increased erythroid proliferation in vitro was a virus-induced event, but the possibility that the induced erythroid burst formation is mediated via interaction with a nonerythroid target cell and subsequent release of a soluble factor cannot be ruled out.     

Friend virus utilizes the BMP4-dependent stress erythropoiesis pathway to induce erythroleukemia

More than 50 years of genetic analysis has identified a number of host genes that are required for the expansion of infected cells during the progression of Friend-virus-induced erythroleukemia. In this report, we show that Friend virus induces the bone morphogenetic protein 4 (BMP4)-dependent stress erythropoiesis pathway in the spleen, which rapidly amplifies target cells, propagating their infection and resulting in acute splenomegaly. This mechanism mimics the response to acute anemia, in which BMP4 expressed in the spleen drives the expansion of a specialized population of stress erythroid progenitors. Previously we demonstrated that these progenitors, termed stress BFU-E, are targets for Friend virus in the spleen (A. Subramanian, H. E. Teal, P. H. Correll, and R. F. Paulson, J. Virol. 79:14586-14594, 2005). Here, we extend those findings by showing that Friend virus infects two distinct populations of bone marrow cells. One population, when infected, differentiates into mature erythrocytes in an Epo-independent manner, while a second population migrates to the spleen after infection, where it induces BMP4 expression and acts as a reservoir of virus. The activation of the stress erythropoiesis pathway in the spleen by Friend virus results in the rapid expansion of stress BFU-E, providing abundant target cells for viral infection. These observations suggest a novel mechanism by which a virus induces a stress response pathway that amplifies target cells for the virus, leading to acute expansion of infected cells.     

Activation of the Jun N-terminal kinase pathway by friend spleen focus-forming virus and its role in the growth and survival of friend virus-induced erythroleukemia cells

Members of the mitogen-activated protein kinase (MAPK) family, including Jun amino-terminal kinase (JNK) and extracellular signal-related kinase (ERK), play an important role in the proliferation of erythroid cells in response to erythropoietin (Epo). Erythroid cells infected with the Friend spleen focus-forming virus (SFFV) proliferate in the absence of Epo and show constitutive activation of Epo signal transduction pathways. We previously demonstrated that the ERK pathway was constitutively activated in Friend SFFV-infected erythroid cells, and in this study JNK is also shown to be constitutively activated. Pharmacological inhibitors of both the ERK and JNK pathways stopped the proliferation of primary erythroleukemic cells from Friend SFFV-infected mice, with little induction of apoptosis, and furthermore blocked their ability to form Epo-independent colonies. However, only the JNK inhibitor blocked the proliferation of erythroleukemia cell lines derived from these mice. The JNK inhibitor caused significant apoptosis in these cell lines as well as an increase in the fraction of cells in G(2)/M and undergoing endoreduplication. In contrast, the growth of erythroleukemia cell lines derived from Friend murine leukemia virus (MuLV)-infected mice was inhibited by both the MEK and JNK inhibitors. JNK is important for AP1 activity, and we found that JNK inhibitor treatment reduced AP1 DNA-binding activity in primary erythroleukemic splenocytes from Friend SFFV-infected mice and in erythroleukemia cell lines from Friend MuLV-infected mice but did not alter AP1 DNA binding in erythroleukemia cell lines from Friend SFFV-infected mice. These data suggest that JNK plays an important role in cell proliferation and/or the survival of erythroleukemia cells.     

Autocrine differentiation-inhibiting factor (ADIF) from chicken erythroleukemia cells acts on human and mouse early BFU-E erythroid progenitors

tsAEV-LSCC HD3 chicken erythroid cells transformed by the avian erythroblastosis virus (AEV) secrete an autocrine differentiation-inhibiting factor, ADIF, which blocks differentiation without affecting proliferation of the chicken erythroid cells that synthesize and secrete it into the culture medium. The chicken erythroleukemia cell ADIF activity is not restricted to avians. It prevents dimethylsulfoxide (DMSO) from stimulating murine Friend erythroleukemia cells to synthesize hemoglobin. ADIF also blocks erythroid differentiation in normal human and murine bone marrow where it selectively targets the early BFU-E (burst-forming) erythroid precursor cells without affecting the more advanced CFU-E erythroid precursor cells or cells of the different granulocyte-macrophage lineage.     

Hemopoietic precursor cell defects in nonanemic but stem cell-deficient W44/W44 mice

Hematopoietic stem cell deficiencies cause a severe macrocytic anemia in W/Wv mice. W44/W44 mice, on the other hand, are not anemic, but, since they accept marrow implants without prior total body irradiation, they have inherited a stem cell lesion. In an attempt to identify the aberrant stem cell(s), we have determined the concentration in W44/W44 marrow of hematopoietic precursors known to be deficient in W/Wv marrow. The in vitro erythroid burst-forming units (BFU-E), the in vivo spleen colony-forming units (CFU-S), and the cells that repopulate the erythroid compartment of stem cell-deficient mice were examined. The progenitors of 7-day bursts are dramatically reduced in W/Wv marrow but are present in normal concentrations in W44/W44 marrow. W44/W44 marrow CFU-S, unlike W/Wv, generate visible spleen colonies 10 days after injection into lethally irradiated recipients. The colonies are, however, smaller and at least 2 times less numerous than those produced from equivalent numbers of +/+ marrow. An additional defect was the inability of W44/W44 stem cells to compete with genetically marked +/+ cells during erythroid repopulation. An estimate of the number of W44/W44 stem cells needed to compete with +/+ cells was provided by enriching W44/W44 progenitors fivefold. Twice as many enriched W44/W44 marrow cells as unfractionated +/+ cells were required to replace competitor cells. This suggests that there are up to 10 times fewer stem cells somewhere in the W44/W44 erythrogenerative pathway. The data support the conclusion that an erythroid progenitor less mature than the BFU-E is one of the cells most severely affected by expression of the mutant gene.     

Effects of murine erythroleukemia inducers on mouse erythroid colony formation in culture.

The effect of various agents which are known to increase the differentiation of Friend erythroleukemia cells was investigated in cultures of mouse bone marrow cells. N,N-dimethylacetamide (5 and 15 mM) and acetamide (60 mM) significantly increased the number of erythroid colonies observed. Tetramethylurea, dimethylformamide, pyridine N-oxide, and butyric acid were ineffective. Dimethylsulfoxide at a concentration of 1% significantly increased colony number in cultures of marrow cells obtained from male mice, but had no effect in cultures of female bone marrow cells.     

Phenylhydrazine stimulates lymphopoiesis and accelerates Abelson murine leukemia virus-induced pre-B cell lymphomas

Infection of bone marrow or fetal liver cells with Abelson murine leukemia virus (A-MuLV) results in the transformation of pre-B cells and the development of erythroid colonies, indicating that the abl oncogene can affect the growth characteristics of immature cells in both the B cell and erythroid lineages. By comparison, infection of mice with A-MuLV results primarily in the development of pre-B cell lymphomas. To determine whether A-MuLV could induce erythroid disease in vivo, NFS/N mice were pretreated with phenylhydrazine (PHZ) to stimulate erythropoiesis and increase the frequency of potential target cells for A-MuLV. No erythroleukemias developed in mice treated with PHZ. Instead, the latency for pre-B cell lymphomas was reduced by half. This acceleration of disease could be attributed to a marked increase in pre-B cells as targets for transformation by A-MuLV in the bone marrows but not the spleens of treated mice. Increases in the frequencies of T cells in bone marrow and spleen also followed treatment with PHZ. These results show that although PHZ-induced anemia stimulates the production of T and B cells as well as erythroid progenitors, PHZ-treated mice do not develop erythroleukemia or T cell lymphomas. It was also found that the genetically determined resistance of adult C57BL/6 mice to lymphoma induction by A-MuLV could not be overcome by pretreatment with PHZ even though the frequency of pre-B cells in bone marrow was greatly increased by this treatment.     

Lymphocyte Deficiencies Increase Susceptibility to Friend Virus-Induced Erythroleukemia in Fv-2 Genetically Resistant Mice

The study of genetic resistance to retroviral diseases provides insights into the mechanisms by which organisms overcome potentially lethal infections. Fv-2 resistance to Friend virus-induced erythroleukemia acts through nonimmunological mechanisms to prevent early virus spread, but it does not completely block infection. The current experiments were done to determine whether Fv-2 alone could provide resistance or whether immunological mechanisms were also required to bring infection under control. Fv-2-resistant mice that were CD4(+) T-cell deficient were able to restrict early virus replication and spread as well as normal Fv-2-resistant mice, but they could not maintain control and developed severe Friend virus-induced splenomegaly and erythroleukemia by 6 to 8 weeks postinfection. Mice deficient in CD8(+) T cells and, to a lesser extent, B cells were also susceptible to late Friend virus-induced disease. Thus, Fv-2 resistance does not independently prevent FV-induced erythroleukemia but works in concert with the immune system by limiting early infection long enough to allow virus-specific immunity time to develop and facilitate recovery.     

Preinfection treatment of resistant mice with CpG oligodeoxynucleotides renders them susceptible to friend retrovirus-induced leukemia

We recently reported that immunostimulatory oligodeoxynucleotides (CpG oligodeoxynucleotides [CpG-ODN]) were effective in postexposure treatment of retrovirus-induced disease (A. R. M. Olbrich et al., J. Virol. 76:11397-11404, 2002). We now show that the timing of treatment is a critical factor in treatment efficacy. In stark contrast to the success of postexposure treatments, we found that CpG treatment of susceptible mice prior to Friend retrovirus infection accelerated the development of virus-induced erythroleukemia. Furthermore, 70.8% of mice that were resistant to Friend virus-induced leukemia developed disease after inoculation of CpG-ODN before infection. The CpG pretreatment of these mice enhanced viral loads in their spleens and blood compared to controls that received ODN without CpG motifs. The main target cells of Friend virus, erythroid precursor cells and B cells, proliferated after CpG-ODN inoculation and provided an enlarged target cell population for viral infection. Our present findings together with our previous report demonstrate that CpG-ODN treatment of viral infections may be a double-edged sword that can result in an effective therapy but also in an acceleration of disease progression depending on the time point of treatment.     

Multistage Friend erythroleukemia: independent origin of tumor clones with normal or rearranged p53 cellular oncogenes.

The erythroleukemia induced by Friend virus complex in adult mice is a multistage malignancy characterized by the emergence, late in the disease, of tumorigenic cell clones. We have previously shown that a significant proportion of these clones have unique rearrangements in their cellular p53 oncogene. The clonal relationships among Friend tumor cells isolated in the late stages of Friend erythroleukemia were analyzed by examining the unique integration site of Friend murine leukemia virus and the unique rearrangement in their cellular p53 oncogene. The majority of clones isolated from individual mice infected with Friend virus were clonally related as judged by the site of Friend murine leukemia virus integration. However, Southern gel analysis of DNA from individual Friend cell clones indicated that all of the clones with a normal p53 gene from the same mice were clonally related, but were unrelated to the Friend cell lines with a rearranged p53 gene. These results suggest that Friend tumor cells with rearrangements in their p53 gene arise as the result of a unique transformation event, rather than by progression from already existing tumor cells with a normal p53 gene. They also suggest that such rearrangements in the p53 gene confer a strong selective advantage to these cells in vivo.     

Inactivation of the cellular p53 gene is a common feature of Friend virus-induced erythroleukemia: relationship of inactivation to dominant transforming alleles.

The Friend erythroleukemia virus complex contains no cell-derived oncogene. Transformation by this virus may therefore involve mutations affecting cellular gene expression. We provide evidence that inactivating mutations of the cellular p53 gene are a common feature in Friend virus-induced malignancy, consistent with an antioncogene role for p53 in this disease. We have shown that frequent rearrangements of the p53 gene cause loss of expression or synthesis of truncated proteins, whereas overexpression of p53 protein is seen in other Friend cell lines. We now demonstrate that p53 expression in the latter cells is also abnormal, as a result of missense mutations in regions encoding highly conserved amino acids. Three of these aberrant alleles obtained from cells from different mice were cloned and found to function as dominant oncogenes in gene transfer assays, supporting the view that certain naturally occurring missense mutations in p53 confer a dominant negative phenotype on the encoded protein.     

Target cells for Friend virus-induced erythroid bursts in vitro

Erythropoietin (Epo) acts on mouse bone marrow cells in vitro in plasma clot or methyl cellulose culture systems to induce the formation of single erythroid colonies, or clusters of erythroid colonies termed bursts. Our laboratory has recently reported the observation that infection of mouse bone marrow cells in vitro with the polycythemia-inducing strain of Friend virus (FV) resulted in the formation of erythroid bursts after 5 days in plasma clot culture in the absence of added Epo. We have now used this system to characterize the target cells for this FV-induced erythroid transformation. The greatest number of FV bursts were observed when marrow cells were obtained from mice whose erythropoiesis had been stimulated by bleeding or phenylhydrazine treatment. Bleeding also resulted in an increase in the number of FV bursts following the infection of spleen cells in vitro. Hypertransfusion of mice, which results in decreased erythropoiesis, yielded a reduced number of FV bursts in vitro, as did prior treatment with actinomycin D. Cell separation studies using velocity sedimentation at unit gravity showed that the cells, which give rise to FV bursts, sedimented with a modal sedimentation velocity between 5.1–8.5 mm/hr. The Epo-dependent colony-forming unit erythroid (CFU-E), which gives rise to a single erythroid colony, also sediments with a modal velocity between 5.1–8.5 mm/hr, while the Epo-dependent day 8 burst-forming unit erythroid (day 8 BFU-E) sediments with a modal velocity between 3.0–6.0 mm/hr. A 20 min incubation of marrow cells with high specific activity ³H-thymidine, prior to virus infection, resulted in a 75–80% reduction in the number of FV bursts. Mixing cells from the upper portion of the gradient, which yielded no FV bursts, with cells from an area in which high numbers of FV bursts were observed did not result in the inhibition of burst formation. These experiments indicate that the primary target cells for FV bursts in vitro are most probably erythroid precursor cells that have matured beyond the day 8 BFU-E and are closely related to the CFU-E.     

Ex vivo and in vivo biological effects of a truncated form of the receptor tyrosine kinase stk when activated by interaction with the friend spleen focus-forming virus envelope glycoprotein or by point mutation

The erythroleukemia-inducing Friend spleen focus-forming virus (SFFV) encodes a unique envelope protein, gp55, which interacts with the erythropoietin (Epo) receptor complex, causing proliferation and differentiation of erythroid cells in the absence of Epo. Susceptibility to SFFV-induced erythroleukemia is conferred by the Fv-2 gene, which encodes a short form of the receptor tyrosine kinase Stk/Ron (sf-Stk) only in susceptible strains of mice. We recently demonstrated that sf-Stk becomes activated by forming a strong interaction with SFFV gp55. To examine the biological consequences of activated sf-Stk on erythroid cell growth, we prepared retroviral vectors which express sf-Stk, either in conjunction with gp55 or alone in a constitutively activated mutant form, and tested them for their ability to induce Epo-independent erythroid colonies ex vivo and disease in mice. Our data indicate that both gp55-activated sf-Stk and the constitutively activated mutant of sf-Stk induce erythroid cells from Fv-2-susceptible and Fv-2-resistant (sf-Stk null) mice to form Epo-independent colonies. Mutational analysis of sf-Stk indicated that a functional kinase domain and 8 of its 12 tyrosine residues are required for the induction of Epo-independent colonies. Further studies demonstrated that coexpression of SFFV gp55 with sf-Stk significantly extends the half-life of the kinase. When injected into Fv-2-resistant mice, neither the gp55-activated sf-Stk nor the constitutively activated mutant caused erythroleukemia. Surprisingly, both Fv-2-susceptible and -resistant mice injected with the gp55-sf-Stk vector developed clinical signs not previously associated with SFFV-induced disease. We conclude that sf-Stk, activated by either point mutation or interaction with SFFV gp55, is sufficient to induce Epo-independent erythroid colonies from both Fv-2-susceptible and -resistant mice but is unable to cause erythroleukemia in Fv-2-resistant mice.     

Organ interactions in the regulation of hematopoiesis: in vitro interactions of bone, thymus, and spleen with bone marrow stem cells in normal, Sl/Sld and W/Wv mice.

Hematopoietic cell differentiation is influenced by organ-dependent microenvironmental factors as well as humoral regulators. A technique is described for examining certain aspects of the hemopoietic inductive microenvironment in vitro. Suspension and agar cultures of mouse bone marrow were used to study the effects of organ stromal factors on cellular proliferation and differentiation. Bone, spleen, and thymus fragments from irradiated mice were placed in direct contact with or separated by a Nuclepore membrane from syngeneic marrow cells growing in suspension cultures. Normal adult mouse bone and spleen influenced granulocytic differentiation as well as cell proliferation. In this system, bone marrow and organ fragments from W/Wv and SlSld mice behaved like those of their non-anemic littermates. The most prominent difference between W/Wv and Sl/Sla mice and their normal counterparts was observed in the inductionof CFU-C from splenic precursors un-er the influence of CSA. In both types of anemic mice, in vitro generation of CFU-C from spleen was abnormal in young animals but was corrected by four months of age.     

A constitutively activated erythropoietin receptor stimulates proliferation and contributes to transformation of multipotent, committed nonerythroid and erythroid progenitor cells.

If the env gene of spleen focus-forming virus (SFFV) is replaced by a cDNA encoding a constitutively active form of the erythropoietin receptor, EPO-R(R129C), the resultant recombinant virus, SFFVcEPO-R, induces transient thrombocytosis and erythrocytosis in infected mice. Clonogenic progenitor cell assays of cells from the bone marrow and spleens of these infected mice suggest that EPO-R(R129C) can stimulate proliferation of committed megakaryocytic and erythroid progenitors as well as nonerythroid multipotent progenitors. From the spleens of SFFVcEPO-R-infected mice, eight multiphenotypic immortal cell lines were isolated and characterized. These included primitive erythroid, lymphoid, and monocytic cells. Some expressed proteins characteristic of more than one lineage. All cell lines resulting from SFFVcEPO-R infection contained a mutant form of the p53 gene. However, in contrast to infection by SFFV, activation of PU.1 gene expression, by retroviral integration, was not observed. One cell line had integrated a provirus upstream of the fli-1 gene, in a location typically seen in erythroleukemic cells generated by Friend murine leukemia virus infection. This event led to increased expression of fli-1 in this cell line. Thus, infection by SFFVcEPO-R can induce proliferation and lead to transformation of nonerythroid as well as very immature erythroid progenitor cells. The sites of proviral integration in clonal cell lines are distinct from those in SFFV-derived lines.     

Sl/Sld mice have an increased number of gap junctions in their bone marrow stromal cells

To study the defect of the hematopoietic inductive microenvironment (HIM) in Sl/Sld mice, femoral bone marrow tissue of 10 of each mutant, (Sl/Sld and W/Wv) their normal littermates (Sl+/Sl+ and W+/W+), and 20 normal C57BL mice were examined by electron microscopy using morphometric and statistical methods. Gap junctions were observed in all strains of mice, in the following stromal cell types: 1) reticular cells, 2) between reticular cells and periarterial adventitial cells, and 3) between periarterial adventitial cells. The frequency of gap junctions in bone marrow stromal cells of Sl/Sld mice (mean = 2.2/9.4 X 10(-3) mm2) was significantly higher than in control mice. It is suggested that there is a relationship between the increased numbers of gap junctions in bone marrow stromal cells of Sl/Sld mice and the defect in HIM function in these genetically anemic animals.