Tyrosine 807 of the v-Fms oncogene product controls cell morphology and association with p120RasGAP.

Expression of the v-fms oncogene of feline sarcoma virus in fibroblasts causes surface exposure of an activated receptor tyrosine kinase, v-Fms, that is autophosphorylated at multiple sites within its cytoplasmic domain. Cellular proteins interacting with this part of v-Fms modulate the mitogenic activity and morphology of the cells. We show here that the tyrosine residue in position 807 (Y-807) of the v-Fms molecule constitutes a major autophosphorylation site. The replacement of this residue by phenylalanine (Y807F mutation) allowed us to functionally dissect v-Fms-specific mitogenic and morphogenic cascades. Cells expressing the mutant v-Fms molecule resembled wild-type (wt) v-Fms-transformed (wt-v-Fms) cells in terms of [3H]thymidine uptake rates and activation of the Ras/Raf-1 mitogenic cascade. Such cells showed, however, a flat morphology and contained intact actin cables and fibronectin network. Our studies indicate that the v-Fms molecule controls cell morphology by a cascade that involves a direct interaction with p120RasGAP and p190RhoGAP: (i) in contrast to wt v-Fms molecules, the Y807F v-Fms protein failed to associate with and phosphorylate p120RasGAP; (ii) tight complexes between p120RasGAP and p190RhoGAP as well as detectable RhoGAP activity were present exclusively in wt-v-Fms cells; and (iii) p190RhoGAP was dispersed throughout the cytoplasm of wt-v-Fms cells, whereas its distribution was restricted to perinuclear regions of cells expressing the mutant v-Fms gene.

Influence of tyrosine residues Y705 and Y807 on the transforming potency of the v-fms oncogene product of feline sarcoma virus.

Cell transformation is characterized by overt changes in growth control and cell morphology. To study the role of tyrosine residues Y705 and Y807 of v-Fms of the McDonough strain of feline sarcoma virus in cell transformation we replaced them individually with phenylalanine residues. Cells expressing the mutant genes showed mitogenic properties similar to wild-type v-Fms transformed cells. However, the morphology of cells expressing the Y807F mutant remained the same as nontransformed cells. Four phosphoproteins of 190, 120, 55 and 50 kDa were detected in cells expressing the wild-type but were absent in cells expressing the mutant Y807F-v-fms gene.

Conversion of human fibroblasts to tissue macrophages by the Snyder-Theilen feline sarcoma virus (ST:FeSV(FeLV)): productive infection by Leishmania major.

The decisive role of macrophages in T-cell differentiation is best exemplified by cutaneous leishmaniasis. During infection, Leishmania attach to macrophages, the only site of replication for the parasite. We have recently demonstrated the conversion of human fibroblasts to tissue macrophages (TM) by transduction with the Snyder-Theilen feline sarcoma virus (ST:FeSV-(FeLV)). Since Leishmania have tropism only for macrophages, we have used the parasite to ascertain the functional phenotype of the ST:FeSV-induced TM. Here, we have demonstrated the productive infection of the ST:FeSV-induced TM by L. major. These results point to the utility of ST:FeSV-induced TM in studies that concern the role of human macrophages in T-cell differentiation during the course of infection by Leishmania.

Characterization of the transforming domain of a feline sarcoma virus encoding a fgr-related tyrosine kinase.

We investigated the transforming domain of a recently isolated feline sarcoma virus (TP1-FeSV) which encodes a fgr-related tyrosine kinase expressed as a gag-fgr fusion protein. The gag portion was removed and replication-competent expression vectors (RCAS) with inserted v-fgr sequences were established. Chicken embryo fibroblasts (CEF) were transfected and monitored for replication, integration and transcription of the proviral constructs. We demonstrated that transfected cells display morphological changes and are able to form colonies in soft-agar. This suggests that the gag portion of the fusion protein from TP1-FeSV is not necessary for the transformation of fibroblasts.

Conversion of human fibroblasts to tissue macrophages by the Snyder-Theilen sarcoma virus (ST:FeSV): tumouricidal effects on K-562 and Daudi tumour cell lines in monolayers and in agar suspensions.

We have previously demonstrated the conversion of human fibroblasts (HF) to tissue macrophages by transduction with the Snyder-Theilen feline sarcoma virus (ST:FeSV) [1-3]. The ST:FeSV-induced TM have been characterized both phenotypically and functionally, including their tumouricidal potential against colon adenocarcinoma (LS 180) cells. The present results show that ST:FeSV-induced TM produced significant lysis of K-562 tumour cells, but essentially no lysis of the Daudi tumour cells. Lysis of K-562 tumour cells by the ST:FeSV-induced TM was considerably more effective in 1% than in 10% FCS. Addition of TNF-alpha caused only a slight increase in the extent of lysis of K-562 tumour cells by the ST:FeSV-induced TM. Coincubation of the ST:FeSV-induced TM with K-562 cells in agar medium resulted in the inhibition of tumour cell proliferation. The results indicate that ST:FeSV-induced TM are potent oncocytotoxic agents of K-562 tumour cells, but are considerably less effective against the Daudi tumour cells.

Conversion of human fibroblasts to tissue macrophages by the Snyder-Theilen feline sarcoma virus (ST:FeSV): tumoricidal potential in monolayers and in agar suspensions.

In earlier studies [1-3], we have demonstrated the conversion of human fibroblasts (HF) to tissue macrophages (TM) by the Snyder-Theilen feline sarcoma virus (ST:(FeSV)). The purpose of the present study is to determine the cytolytic potential of ST:FeSV(FeLV)-induced TM against tumorigenic target cells under defined conditions in vitro. The results show that ST:FeSV-induced TM, but not mock-infected HF, produced significant lysis of human colon adenocarcinoma cells (LS-180) after a 3-day preincubation period, followed by a 4-day coincubation period at an effector to target cell ratio of 5:1. The presence of IFN-gamma, or lipopolysaccharides (LPS), and especially of M-CSF, during the coincubation period generally yielded optimal lysis of the tumor cells. Addition of LS-180 specific antibody (NRCO-4) substantially increased the cytolytic potential of TM. Significantly, coincubation of TM with LS-180 tumor cells in an agar medium, where no direct contact between cells occurs, resulted in the inhibition of tumor cell proliferation. Addition of LPS has further accentuated this inhibition. The results indicate that ST:FeSV-induced macrophages are potent oncocytolytic agents of LS-180 tumor cells in the absence and in the presence of direct contact between effector and target cells.

Conversion of human fibroblasts to tissue macrophages by the Snyder-Theilen feline sarcoma virus (ST:FeSV) is associated with the de-novo expression of IL-1 alpha, IL-1 beta, IFN-alpha, TNF-alpha, GM-CSF, and CD4.

In an earlier study, we have demonstrated the conversion of human fibroblasts (HF) to tissue macrophages (TM) by the Snyder-Theilen feline sarcoma virus (ST:(FeSV)) [1]. The present study shows that conversion of cultured HF by the ST:FeSV to TM resulted in the de-novo expression of interleukin-1 alpha, IL-1 beta, interferon-alpha, tumor necrosis factor-alpha, granulocyte-macrophage colony stimulating factor, and CD4. The conversion of HF to TM was also associated with increased expression of non-specific esterases as well as increased amount of ingested lipid material by the TM. Clonotypic and organotypic analyses of cells infected with the ST:FeSV(FeLV) showed a similar degree of conversion to TM among eleven individual clones of skin fibroblasts, and among fibroblasts obtained from eight different organs. These findings bear on the origin (heterogeneity) of TM, the nature of TM-induced cytokines, and the potential role of ST:FeSV-recruited TM during immune reactions in vivo.

Histiocytic conversion of human adult skin fibroblasts by the Snyder-Theilen feline sarcoma virus.

Oncogenes are apparently involved in the transformation/neodifferentiation of human cells. We now report a novel example of transformation/neodifferentiation: the specific conversion of cultured human adult skin fibroblasts (HSF) to histiocytes (tissue macrophages (TM)) by the Snyder-Theilen feline sarcoma virus (ST: (FeSV)). The de novo conversion of cultured HSF was demonstrated in a large fraction of ST:FeSV (FeLV)-transformed foci in the presence of dexamethasone (DX). Identification of tissue macrophages in ST:FeSV(FeLV)-infected HSF cultures was established by light-and transmission electron microscopy, histochemistry, immunohistochemistry, adherence-reattachment, latex particle uptake, and secretion of bioactive interleukin-1. The ST:FeSV gene and glucocorticosteroids, or other naturally occurring hormones, may play a role in morphogenetic processes within cells from a variety of normal and diseased tissues in situ, including induction of non-bone marrow, mesenchyme-derived, tissue macrophages.

Safety of human blood products: inactivation of retroviruses by heat treatment at 60 degrees C.

Acquired immune deficiency syndrome (AIDS) can be transferred to patients by blood transfusions or human blood preparations, such as cryoprecipitates or factor VIII concentrates. Retroviruses have been discussed as infectious AIDS agents and more recently human T-lymphotropic retroviruses designated as HTLV type III and LAV (lymphadenopathy-associated virus) have been isolated from AIDS patients. Whether heat treatment at 60 degrees C (pasteurization) of liquid human plasma protein preparations inactivates retroviruses was therefore investigated. Pasteurization had already been included in the routine manufacturing process of human plasma protein preparations in order to guarantee safety with regard to hepatitis B. Since high titer preparations of human retroviruses were not available, heat inactivation was studied using Rous sarcoma virus added to the various plasma protein preparations tested. This retrovirus which was obtained in preparations of 6.0 log10 FFU/ml was shown to be at least as heat stable as two mammalian retroviruses studied, i.e., feline and simian sarcoma virus. In all of eight different plasma protein preparations tested, Rous sarcoma virus was completely inactivated after a heat treatment lasting no longer than 4 hr. It is thus concluded that pasteurization of liquid plasma protein preparations at 60 degrees C over a period of 10 hr must confer safety to these products with respect to AIDS, provided that the AIDS agents are retroviruses of comparable heat stability as Rous sarcoma virus and the mammalian retroviruses tested.

In vitro transformation of murine pre-B lymphoid cells by Snyder-Theilen feline sarcoma virus.

Snyder-Theilen feline sarcoma virus (ST-FeSV) codes for a protein kinase with specificity for tyrosine residues (Barbacid et al., Proc. Natl. Acad. Sci. U.S.A. 77:5158-5163, 1980), properties analogous to those of the transforming gene product of Abelson murine leukemia virus (Witte et al., Nature (London) 283:826-831, 1980). In the present report, ST-FeSV was demonstrated to transform murine hematopoietic cells under in vitro assay conditions which detect lymphoid cell transformation by Abelson murine leukemia virus. Bone marrow colony formation was shown to require ST-FeSV, follow single-hit kinetics, and require the presence of mercaptoethanol in the agar medium. ST-FeSV-induced colonies could be established in culture as continuous cell lines that demonstrated unrestricted self-renewal capacity and leukemogenicity in vivo. The hematopoietic blast cells transformed by ST-FeSV in culture appeared to be at an early stage of B cell differentiation. They possessed Lyb 2 surface antigens, were dependent on mercaptoethanol for growth, and contained only low levels of terminal deoxynucleotidyl transferase. Moreover, a large fraction of the lines synthesized immunoglobulin mu chain in the absence of light chains. Thus, the phenotype of ST-FeSV hematopoietic transformants was indistinguishable from that of the pre-B lymphoblast transformants induced by Abelson murine leukemia virus. These findings indicate that the in vitro functional similarities in the onc gene products of ST-FeSV and Abelson murine leukemia virus may reflect a common pathway by which they exert their oncogenic potential.

Regulation of viral and cellular oncogene expression by cytosine methylation.

Mink cells morphologically transformed by either Snyder-Theilen feline sarcoma virus (ST-FeSV) or Abelson murine leukemia virus (Abelson-MuLV) exhibit relatively high rates of reversion to the nontransformed phenotype. The proviral DNAs are conserved within the revertant lines and have not undergone changes in integration sites due to translocations or other genomic rearrangements. In contrast, expression of well-defined viral-encoded transforming proteins is blocked and elevated levels of phosphotyrosine characteristic of the parental transformed cells are reduced to control levels. Loss of the transformed phenotype is associated with increased cytosine methylation of proviral DNA sequences while levels of methylation resume control levels upon spontaneous retransformation of revertant clones. Following molecular cloning, and transfection to Rat-2 cells, ST-FeSV proviral DNAs from revertant and transformed cells induced similar numbers of transformed foci. Cytosine methylation sites involved in regulation of expression of the major ST-FeSV encoded transforming protein have been localized within the proviral DNA itself rather than in adjacent cellular flanking sequences. In contrast to the v-fes proviral DNA, c-fes, the cellular homolog of the ST-FeSV acquired transforming sequences, is highly methylated in cytosine residues in both transformed and revertant clones. These findings demonstrate regulation of viral oncogene-mediated transformation by cytosine methylation and suggest that expression of cellular homologs of viral oncogenes, such as c-fes, are also subject to regulation at this level.

Association of the transforming proteins of the ST and GA strains of feline sarcoma virus and their in vitro associated protein kinase activities with cellular membranes.

The translation products of the Snyder-Theilen (ST) and Gardner-Arnstein (GA) strains of feline sarcoma virus (FeSV), termed gag-fes proteins, are high molecular weight polyproteins containing different amounts of the amino terminus of the feline leukemia virus (FeLV) gag gene-coded precursor protein linked to a similar sarcoma virus-specific polypeptide. Both polyproteins are phosphoproteins with indistinguishable in vitro associated tyrosine-specific protein kinase activities. The polyproteins are extremely hydrophobic proteins which are intimately associated with the plasma membrane fraction of transformed cells. Approximately 10% of the proteins are modified by glycosylation and expressed on the cell surface where they are accessible to lactoperoxidase-mediated radio-iodination and trypsinization. Cell surface localization of the polyproteins does not appear to be necessary for transformation. However, preliminary evidence suggests that the amount of FeLV p30 sequences at the amino end of the proteins may have some effect on the intracellular distribution of the gag-fes polyproteins and on the phenotype of the transformed cell.

Similar transforming growth factors (TGFs) produced by cells transformed by different isolates of feline sarcoma virus.

Fisher rat embryo cells transformed by each of three independent isolates of feline sarcoma virus (FeSV) are shown to release transforming growth factors (TGFs) into cell culture medium. These acid- and heat-stable peptides compete for binding to, and stimulate phosphorylation of, EGF membrane receptors and promote anchorage-independent cell growth. Cells transformed by the Gardner and Synder-Theilen strains of FeSV produce high titers of TGF (60-200 ng eq EGF/liter) while cells transformed by McDonough FeSV produce TGF at only low levels (less than 10 ng eq EGF/liter). Growth factors produced by cells transformed by each of the three FeSV isolates functionally and biochemically resemble each other, mouse sarcoma growth factor (SGF), and TGFs produced by human tumor cells.

Gene products of McDonough feline sarcoma virus have an in vitro-associated protein kinase that phosphorylates tyrosine residues: lack of detection of this enzymatic activity in vivo.

The primary translational product of the McDonough (SM) strain of feline sarcoma virus (FeSV) is a 180,000-dalton molecule, SM P180, that contains the p15-p12-p30 region of the FeLV gag gene-coded precursor protein and a sarcoma virus-specific polypeptide. In addition, cells transformed by SM-FeSV express a 120,000-dalton molecule, SM P120, that is highly related to the non-helper virus domain of SM P180. Both SM-FeSV gene products were found to be intimately associated with the membrane fraction of SM-FeSV-transformed cells. Immunoprecipitates containing SM P180 and SM P120 exhibited a protein kinase activity capable of phosphorylating tyrosine residues of both viral gene products but not immune immunoglobulin G molecules. By independently immunoprecipitating each of the two SM-FeSV proteins we found that most of the tyrosine-specific phosphorylating activity was associated with the SM P120 molecule. In vivo analysis of 32P-labeled SM P180 and SM P120 revealed their phosphoprotein nature; however, both molecules exhibited low levels of phosphorylation and did not contain phosphotyrosine residues. Finally, we did not detect any significant elevation in the levels of phosphotyrosine in the protein fraction of SM-FeSV transformants. Thus, if SM-FeSV were to induce malignant transformation by a mechanism involving phosphorylation of tyrosine residues, the viral gene products must interact with a small subset of cellular proteins that do not represent a significant fraction of the total cellular protein content.

Differences in mechanisms of transformation by independent feline sarcoma virus isolates.

The Gardner and Snyder-Theilen isolates of feline sarcoma virus (FeSV) have previously been shown to encode high-molecular-weight polyproteins with a transforming function and an associated tyrosine-specific protein kinase activity. Cells transformed by these viruses exhibited morphological alterations, elevated levels of phosphotyrosine, and a reduced capacity for binding epidermal growth factor. In addition, polyproteins encoded by both of these FeSV isolates bound to, and phosphorylated tyrosine acceptor sites within, a 150,000-molecular-weight cellular substrate (P150). McDonough FeSV-transformed cells resembled Gardner and Snyder-Theilen FeSV transformants with respect to morphological changes and a reduced capacity for epidermal growth factor binding. in contrast to the other two FeSV isolates, however, McDonough FeSV encoded as its major translational product a high-molecular-weight polyprotein with probable transforming function but without protein kinase activity detectable under similar assay conditions. Moreover, total cellular levels of phosphotyrosine remained unaltered in McDonough FeSV-transformed cells, and the major McDonough FeSV polyprotein translational product lacked binding affinity for P150. These findings argue for differences in the mechanisms of transformation by these independently derived FeSV isolates.

Snyder-Theilen feline sarcoma virus P85 contains a single phosphotyrosine acceptor site recognized by its associated protein kinase.

Cells nonproductively transformed by a variant of the Snyder-Theilen strain of feline sarcoma virus (FeSV) expressed an 85,000-dalton polyprotein (P85) with associated tyrosine-specific protein kinase activity. We identified within this polyprotein a single tyrosine acceptor site for its enzyme activity. This acceptor site, as well as two serine phosphorylation sites localized with the p12 structural component of Snyder-Theilen FeSv P85, was phosphorylated in cells nonproductively transformed by Snyder-Theilen FeSv. In contrast, infection by Snyder-Theilen FeSV transformation-defective mutants resulted in phosphorylation only of the two serine acceptor sites, indicating phosphorylation of the tyrosine acceptor site to be transformation specific. In addition, we describe in vitro labeling conditions, using unfractionated cell extracts, which resulted in preferential phosphorylation of the single Snyder-Theilen FeSV tyrosine-specific acceptor site.