A survey on the effect of steroid hormone on type C virus production from cultured murine cells.

Dexamethasone stimulates type C virus production induced by iododeoxyuridine (IdUrd) from several murine cell lines: uninfected BALB cells, virally transformed nonproducer K-BALB cells, mouse neuroblastoma N-4 cells, and rat tumor XC cells. Dexamethasone also stimulates virus production from BALB cells newly infected by some murine leukemia or leukemia sarcoma viruses, from a murine myelogenous leukemic cell line (M-1) producing type C virus, from K-BALB(l) cells (K-BALB producing cells previously induced by IdUrd), and from K-BALB cells rescued by Rauscher leukemia virus. However, this stimulatory effect is not universal, since we observed that dexamethasone did not stimulate virus production from BALB cells newly infected by B-tropic virus, from S2CL3 cells producing N-tropic virus (a clone of spontaneously transformed BALB cells), from virus producing normal rat kidney cells, and from a mouse adrenal gland tumor Y-1 cell line chronically producing type C virus. Some estrogenic hormones that do not have any stimulatory effect on virus production from BALB or K-BALB cells induced by IdUrd stimulate virus production from normal rat kidney cells induced by IdUrd. When there is no stimulation of virus production in a cell system by steroid hormones, very often there is some inhibitory activity. Furthermore, we observed that in JLSV10 cells chronically producing Rauscher leukemia virus and in K-BALB cells newly infected by Rauscher leukemia virus, virus production is enhanced by dexamethasone when the cells are still producing a low titer of virus but is not enhanced when the cells are producing a high titer of virus.     

Growth of murine sarcoma virus-transformed rat kidney cells in nude mice: absence of induction of host endogenous viruses.

Clonal isolates of the normal rat kidney cell line (NRK) transformed by a defective murine sarcoma virus (Kirsten strain) were injected into nude mice of BALB/c background to determine whether the growth of these cells as tumors was accompanied by the induction of host endogenous type C viruses. All the virus-transformed clones produced rapidly growing tumors in nude mice, but neither the induction of mouse endogenous viruses nor the rescue and spread of the transforming sarcoma virus were observed during the growth of tumors. The degree of expression of the tumor virus structural proteins in the transformed cells did not determine the cellular phenotype with regard to tumorigenicity in nude mice, nor did it modify the cellular growth properties in vitro. Consistent with earlier observations with simian virus 40-transformed mouse and rat cells, the ability of sarcoma virus-transformed NRK cells to initiate tumor growth in nude mice appeared to be correlated with anchorage-independent growth in vitro.     

Biologic properties of viable deletion mutants of simian virus 40 (SV40) rescued from the cells of an SV40-induced hamster lymphocytic leukemia

A lymphocytic leukemia induced by the oncogenic DNA simian virus 40 (SV40) in an inbred LSH/SsLak Syrian golden hamster was evoked to produce infectious SV40 by fusion of the leukemia cells with grivet monkey kidney (GMK) cells and by exposure of the leukemia cells to the chemical inducers mitomycin C and cycloheximide. Plaque-purified viable substrains of the rescued SV40 when studied by restriction endonuclease digestion of viral DNA were found to contain small deletions within the Hind III restriction fragment C. These deletions lay near the viral origin of DNA replication. Ten plaque-purified substrains of the rescued virus identified by immunofluorescence as being SV40 were found, when compared to the wild-type SV40, to replicate slowly and to form small plaques. Although these substrains transformed NIH/3T3 cells as efficiently as the wild-type SV40 in tissue culture, they were generally less oncogenic in vivo--7 of the 10 failed to induce tumors. The 3 oncogenic SV40-rescued substrains were not found to exhibit "lymphocytotropism," i.e., the capacity to infect and neoplastically transform preferentially hamster lymphocytes. Thus the hamster lymphocytic leukemia originally induced by the wild-type SV40 was most likely a chance-stochastic event rather than the result of tropism-determinism mediated by the virus, as is usually the case with leukemogenic RNA viruses.     

A discrepancy in XC and oncogenicity assays for murine leukemia virus in AKR mice.

Studies of murine leukemia virus expression in AKR mice are presented. Material from in vivo and in vitro sources of normal tissues and lymphomas was assayed for in vitro infectivity, using the XC plaque assay, and for oncogenicity, by assessing lymphoma-accelerating capacity after inoculation into newborn animals. Normal tissues from healthy young AKR mice up to 7 months of age were found to have XC but not oncogenic activity. XC activity persisted, and weak oncogenic activity appeared in older mice. Cocultivation of normal young cells with NIH Swiss mouse embryo cells did not result in the appearance of oncogenic activity, although XC virus increased in titer. A cell-free filtrate of a virus-accelerated lymphoma was studied for host range. Virus as measured by polymerase and gs antigen was found to be propagated on NIH Swiss mouse embryo and wild mouse embryo cells, but not on human rhabdomyosarcoma, normal rat kidney, rabbit corneal, and BALB/c embryo cells. Virus as measured by the XC assay grew better on NIH Swiss mouse than on BALB/c embryo cells. Both of these cell lines propagated virus as measured by the oncogenicity assay. Supernatants from an in vitro cell line from a virus-accelerated lymphoma did not produce XC plaques but were oncogenic. Those from two cell lines of spontaneous lymphomas were negative with both assays. Cultivation of supernatants from these cultured lymphoma cells with NIH Swiss mouse embryo cells resulted in material which produced small plaques on the XC assay. These findings are interpreted as showing the presence of two viruses in AKR mice. One is XC positive and present throughout life. The other is oncogenic, appears later in life, and could be a separate virus or a variant of the first one.     

Temperature-dependent alterations in 2-deoxyglucose uptake in rat cells transformed by a cold-sensitive murine sarcoma virus mutant

Cells transformed by Moloney sarcoma virus (MSV) take up 2-deoxyglucose at a faster rate at 39° C than uninfected or Moloney leukemia virus (MoLV)—infected normal rat kidney (NRK) cells. In a sarcoma-virus-transformed cell line, NRK (MSV-lb), whose transformed phenotype is expressed at 39° C (permissive) but not at 33° C (non-permissive), the stimulation of 2-deoxyglucose uptake at 39° C is temperature dependent; the increase is observed when cells are grown at 39° C but not at 33 C. When these cells were shifted from the non-permissive to the permissive temperature, the uptake increased from a rate near that of uninfected cells to a rate half that of NRK cells infected with Moloney sarcoma-leukemia complex (MSV-MoLV). The reverse change occurred when the cells were shifted from the permissive to the non-permissive temperature. Thus in a sarcoma virus-infected rat cell line where the maintenance of the transformed state is dependent on a cold-sensitive viral function, the uptake of 2-deoxyglucose is reduced in the cold-sensitive cells and correlated with the expression of the transformed phenotype.     

Production of plasminogen activator by cells transformed by herpesviruses.

Plasminogen activator is produced by hamster cells transformed by human herpesviruses. These cell lines have previously been shown to be oncogenic when injected s.c. into newborn syngeneic hamsters. Lysis of fibrin overlays by these cell lines was plasminogen dependent. Normal hamster embryo fibroblasts and a hamster cell line transformed by PARA-7 (an adenovirus-SV 40 hybrid) failed to produced lysis. In separate experiments fibrin overlay of lytically infected secondary rabbit kidney cells did not show induction of this activity during the normal course of productive infection. The human cell line TE-85 clone F-5, a clonal cell line from a human osteogenic sarcoma, failed to produce plasminogen activator, but two separate clones of these cells that were morphologically transformed after exposure to UV-inactivated herpes simplex virus type 2 produced rapid lysis of the fibrin overlay. Clonal variation was observed in herpes simplex virus types 1 and 2-transformed hamster lines and is under investigation. It is suggested that plasminogen activator detection may serve as a convenient assay system for transformation of normal cells by herpesviruses.     

Sensitization of transformed rat cells to parvovirus MVMp is restricted to specific oncogenes

The rat cell line FR3T3 was transformed with the retroviral oncogenes v-myc or v-src, with the DNA tumor viruses SV40 or bovine papilloma virus strain 1 (BPV-1) or with the 69% transforming region of BPV-1. The transformants were compared with the uncloned parental line for their susceptibility to the lytic effect and to the replication of MVMp, an autonomous parvovirus. Expression of v-myc and v-src proteins and of SV40 large T antigen correlated with a greater cell susceptibility to MVMp-induced killing. Thus, the expression of both cytoplasmic and nuclear oncogene products may sensitize rat fibroblasts to MVMp. In contrast, cell lines transformed by BPV-1, including highly tumorigenic and tumor-derived clones, were on the average as resistant as the parental cell line to MVMp infection. A similar resistance to MVMp-induced killing was displayed by BPV-1-transformed NIH3T3 cells. However, supertransformation of one of the BPV-1-transformants by the human EJ-Harvey ras-1 oncogene, known to sensitize FR3T3 and NIH3T3 cells, correlated with an increase in susceptibility to MVMp. Therefore, the failure of BPV-1 transformation to sensitize murine cells to parvoviral attack may be ascribed to the tumor virus rather than to the cells undergoing transformation. Hence, cell sensitization to MVMp appears to be oncogene-specific and cannot be taken as an absolute correlative with neoplastic transformation.     

Decreased interferon sensitivity and production in cells transformed by sv40 and other oncogenic agents

From a pool of primary rat embryo fibroblast cells, three lines—two SV40-infected and one control—were serially propagated. Prior to unequivocal morphological evidence of transformation, increased sensitivity to vesicular stomatitis virus (VSV) was found in the two SV40-infected lines when compared to the control line. The increased VSV sensitivity of the transformed cells seems to be due to a diminished production of and sensitivity to interferon, and not to differences in adsorption. When a collection of diverse transformed cell lines were also compared with arbitrarily selected control cell populations, the majority of the transformed cells also exhibited enhanced VSV sensitivity. Lines transformed by methylcholanthrene also featured this property. The data suggest that diminished sensitivity to and production of interferon is an early consequence of infection by oncogenic viruses, and a property that persists in many lines of transformed cells.     

Viral oncogenesis and the immune system

Oncogenic transformation of normal cells and the establishment of transformed cells to form malignant tumors is a complex, multistep process influenced by viruses in multiple ways. The relationship between viruses and the immune system manifests itself, in part, through various roles of viruses in transformation of host cells, including cells of the immune system. A large number of viruses participate in oncogenic transformation of cells in many animal species. Candidates for oncogenic transformation in man are human T lymphotropic viruses I and II, certain human papillomavirus types, hepatitis B virus, and Epstein-Barr virus. Various mechanisms, which may overlap with one another, have been proposed to account for viral oncogenesis. These include introduction of a directly transforming viral gene, retroviral transduction of protooncogenes, mutagenesis, uncoupling of cellular protooncogene expression from normal regulatory controls, overexpression of normal cellular genes resulting from effects of viral cis- or trans-acting factors, and inactivation of tumor suppressor genes. A second critical area of interaction between viruses and the immune system is in the selection of transformed cells. When cell transformation is accompanied by expression of tumor antigens, the immune system may influence tumor cell establishment and selection of transformed cells for metastatic outgrowth. Finally, host well-being may be severely compromised when viruses infect cells of the immune system, leading to an inability to mount immunological responses specific for opportunistic microorganisms and for cells transformed by viruses or nonviral agents. Human immunodeficiency virus infection exemplifies this phenomenon, although other viruses also negatively affect the immune system. The role of normal immune responses in limiting tumor cell growth is evident from the increased incidence of malignancies in immunocompromised hosts.     

Microvascular endothelial cells increase proliferation and inhibit apoptosis of native human acute myelogenous leukemia blasts

Interactions between acute myelogenous leukemia (AML) blasts and neighbouring endothelial cells in the bone marrow seem important both for disease development and susceptibility to chemotherapy. We investigated the effects of soluble mediators released by microvascular endothelial cells on native human AML cells. AML cells derived from 33 patients were cocultured with microvascular endothelial cells, separated by a semipermeable membrane. We investigated the effect of coculture on AML cell proliferation, viability/apoptosis and cytokine release. Coculture increased AML cell proliferation, and this growth enhancement included the clonogenic leukemia cell subset. Increased release of several soluble mediators was also detected (interleukin 3, interleukin 6, granulocyte-macrophage and granulocyte colony-stimulating factors) in cocultures. Our cytokine neutralization experiments suggest that an intercellular crosstalk involving several soluble mediators contribute to the increased leukemia cell proliferation. The presence of endothelial cells had an additional antiapoptotic effect on the AML cells. The endothelial cells did not have any growth-enhancing effect on native human acute lymphoblastic leukemia cells. Our in vitro results suggest that the release of soluble mediators by microvascular endothelial cells supports leukemic hematopoiesis through paracrine mechanisms by direct enhancement of AML blast proliferation and by inhibition of leukemic cell apoptosis.     

Colony stimulating factor-1 induced growth stimulation of v-fms transformed fibroblasts

The v-fms oncogene, which is capable of transforming fibroblasts, was derived by recombination of a feline leukemia virus with a cellular gene (c-fms) that encodes the receptor for colony stimulating factor 1 (CSF-1). We examined the capacity of recombinant human CSF-1 (produced in a yeast expression system) to stimulate the growth of v-fms transformed rat fibroblasts. Recombinant human CSF-1 bound to v-fms transformed fibroblasts with high affinity (apparent Kd = 6.0 x 10(-10) M); only non-specific binding was observed on control cells. The number of colonies formed in soft agar by v-fms transformed cells was increased by CSF-1 treatment in a dose-dependent manner; a nine fold increase in the number of colonies was seen in the presence of 10(-8) M CSF-1. CSF-1 did not stimulate the growth of either non-transformed cell lines, a non-transformed cell line that expresses a mutated v-fms protein on the cell surface, or cells transformed by the v-fgr oncogene. The growth stimulating effect of CSF-1 on v-fms transformed cells was also seen in monolayer culture. The v-fms transformed cells treated with CSF-1 had a more refractile, rounded morphology than non-treated cells; no morphology change was observed in CSF-1 treated control cells. CSF-1 treatment also increased both the number and size of foci that arose from fibroblasts following transfection with the v-fms oncogene. These data show that the altered CSF-1 receptor encoded by the v-fms oncogene retains a capacity to bind, and be stimulated by, human CSF-1.     

The phenotypic plasticity of myeloma plasma cells as expressed by dedifferentiation into an immature, resilient, and apoptosis-resistant phenotype.

PURPOSE: We previously showed the ability of osteoclasts to support myeloma plasma cell survival and proliferation in vivo and ex vivo. The aim of the current study was to investigate osteoclast-induced phenotypic changes associated with long-term survival of myeloma cells in coculture. EXPERIMENTAL DESIGN: CD138-selected myeloma plasma cells from 16 patients were cocultured with human osteoclasts for up to 20 weeks. RESULTS: Precultured cells were typically CD45(low/intermediate) CD38(high) CD138(high), CD19(-)CD34(-). After >6 weeks, the phenotype of cocultured myeloma cells consistently shifted to cells expressing CD45(intermediate/high) CD19(low) CD34(low). Expression of CD38 and CD138 were reduced to subpopulations with CD38(intermediate) and CD138(low) levels. Morphologically, cocultured plasma cells became plasmablastic. Blocking interleukin-6 activity did not affect the immature phenotype of myeloma cells. The effect of dexamethasone on myeloma cells cultured alone or in cocultures at baseline and after 6 weeks of coculture was determined. When baseline myeloma cells were cultured alone, dexamethasone significantly increased the percentage of apoptotic cells over the spontaneous rate. Conversely, myeloma cells recovered from cocultures had high survival rates and were resistant to dexamethasone-induced apoptosis. Long-term coculture of normal CD34-expressing hematopoietic stem cells (HSC) resulted in loss of CD34 expression, suggesting a common mechanism for osteoclast-induced myeloma and HSC plasticity. CONCLUSIONS: This study indicates that myeloma cells have plasticity expressed by their ability to reprogram, dedifferentiate, and acquire autonomous survival properties.     

Oral squamous cell carcinoma cells induce osteoclast differentiation by suppression of osteoprotegerin expression in osteoblasts

The invasion of oral squamous cell carcinoma (SCC) cells into the mandibular bone is a common clinical problem. It has been reported that BHY cells, a human oral SCC cell line, are capable of invading mandibular bone of nude mice. These results led us to examine possible mechanisms of osteoclastogenesis induced by BHY cells using in vitro culture systems. When BHY cells were cocultured with mouse bone marrow cells (BMCs), only few osteoclasts were formed, even though BHY cells express the receptor activator of NF-kappaB ligand (RANKL). However, adding BHY cells to a coculture of mouse primary osteoblasts (POBs) and BMCs markedly induced osteoclastogenesis in the absence of osteotropic factors. Furthermore, another oral SCC cell line, HSC-2, which does not express RANKL, also induced osteoclastogenesis in our cocultures. These effects were significantly, but not completely, inhibited by adding osteoprotegerin (OPG). In addition, we also found that TNFalpha released from these cells partially contributes to osteoclastogenesis via a RANKL-independent mechanism. Adding BHY or HSC-2 cells suppressed mouse OPG mRNA expression and protein production by POBs in cocultures of POBs and human oral SCC cells. This finding is consistent with the result that BHY cells and HSC-2 cells did not enhance osteoclastogenesis in cocultures of BMCs and POBs from OPG-deficient mice. Immunohistochemical analysis showed a reduction of OPG expression in osteolytic lesions as compared to normal lesions from oral SCC patients. Therefore, oral SCC-induced suppression of OPG expression in POBs appears critical for osteoclastogenesis, rather than expression of RANKL in SCC cells.     

Oncogenic activation of murine mos protein kinase by DNA rearrangement of its N-terminal coding region.

An activated c-mos oncogene was detected by DNA transfection assay of hamster SHOK cells with DNAs from X-ray-induced mouse osteosarcoma. It was molecularly cloned by the cosmid rescue method and found to form transformed foci of SHOK cells. Genomic DNA sequencing revealed that in this oncogene the N-terminal coding region of the mouse proto-mos gene was deleted and replaced by a hamster-derived sequence in the primary transformant, suggesting that activation was due to the rearrangement during transfection. The gene product was about 37 kDa and was immunoprecipitated with anti-mos antibody from a lysate of a SHOK cell transfectant. This truncated mos (t-mos) gene transformed SHOK cells more effectively than v-mos. A chimeric gene construct of this hamster-derived upstream sequence and normal mouse c-mos also transformed SHOK cells at a lower level, whereas neither t-mos nor the chimeric c-mos gene transformed NIH3T3 cells appreciably. The high transforming efficiency of t-mos in SHOK cells was due not only to truncation of the coding region but also to its integration under a putative promoter sequence derived from the hamster genome. This is the first report of detection of an activated c-mos gene by DNA transfection assay.     

Changes in leucine aminotransferase isozymes by viral transformation and its correlation with the isozyme changes occurring during differentiation.

The isozyme pattern of leucine aminotransferase (EC 2.6.1.6) in various cell lines and their viral-transformed derivatives were examined. The Wistar 3C rat liver cell line was found to contain only isozyme I, while its simian virus 40-transformed counterpart had isozyme III in addition to isozyme I. A spontaneously transformed late passage clone of these liver cells was also found to have acquired isozyme III. Polyoma virus-transformed baby hamster kidney cells were also found to contain a greater predominance of isozyme III than their normal untransformed counterpart. Examination of the isozymes in a cloned normal rat kidney cell line transformed by a mutant of Rous sarcoma virus which is temeprature-sensitive for transformation indicated that, in fact, such an isozyme change does correlate with transformation. When grown at 36 degrees these cells contained predominantly isozyme III; however, upon reacquiring normal morphology and lowered glucose transport activity when grown at 40 degrees, their isozyme pattern was now found to be changed and consisted predominantly of isozyme I, as is found in normal adult rat kidney tissue. Isozyme III was found to be present in neonatal kidney tissue of the rat and hamster, and its predominance in the virus-transformed normal rat and baby hamster kidney cells was interpreted as indicative of the dedifferentiation of these cells upon viral transformation. A similar change of the isozyme pattern of leucine aminotransferase in chicken embryos during their development was observed, such that in 5-day-old embryos Form III was predominant, while in the more mature differentiated chicken embryo of Day 17, Form I was predominant.     

Transformation of horse skin cells by type-C sarcoma viruses.

A horse skin cell line (E. Derm, NBL-6, CCL-57) was susceptible to focus formation by the Kirsten mouse sarcoma virus, feline sarcoma virus (ST stain) and the MSV pseudotypes with woolly monkey, gibbon monkey, RD-114, AT-124, baboon placenta and murine xenotropic (BALB/c 3T3 and C57L/JD) type-C viruses. Foci were detected within 5 days after infection and the transformed cells continued to produce infectious virus and group-specific antigen of their respective type-C leukemia viruses. The transformation efficiency of various type-C sarcoma viruses in horse cells was also very high.