Ed Roos

Nonmetastatic tumor cells acquire metastatic properties following somatic hybridization with normal cells.

SummarySomatic cell hybridization between nonmetastatic tumor cells and normal cells of the lymphoreticular system results in hybrid cells manifesting metastatic properties of defined target organ specificity. Thus, fusion of the nonmetastatic BALB/c originated NSI plasmacytoma with C57BL B lymphocytes resulted in hybridomas, each of which were metastatic. Of 10 hybridomas, 7 generated metastases in the spleen and liver, whereas 3 generated liver metastases. The generation of liver metastases by hybridomas which homed to both spleen and liver, but not by those which homed to the liver only, was controlled by the spleen. The acquisition of metastatic properties via somatic cell fusion seems to represent a general principle, in which the normal partner determines the target organ specificity for the metastatic growth. Thus, fusion of SP2/O myeloma cells with syngeneic B lymphocytes also resulted in a hybrid cell metastasizing to the spleen and liver, yet a somatic hybrid between NSI and a macrophage or dendritic-like cell metastasized to the lung. Cell surface molecules encoded by the genome of the normal partner was demonstrated to control the target organ specificity: antibodies against MHC-encoded antigens of the normal B cell partner prevented the generation of metastases by hybridomas metastasizing to the spleen and liver, but not by those metastasizing to the liver only. This is in accordance with the function of MHC molecules on lymphocytes in controlling their homing to lymphoid organs. Hybridomas of T cell lymphomas also manifested metastatic properties. Analysis of the cell surface Thy-1 antigens of a hybridoma (DCH10), produced via somatic fusion between BW5145 lymphoma and a putative macrophage cell indicated that cells of liver metastases (DCH10-Li) generated by the hybrid cells might have undergone further somatic cell fusion in vivo with host (T?) cells. These cells have acquired new metastatic properties, generating metastases in spleen, liver and kidneys. In fact, even the inoculation of the parental BW lymphoma cells resulted in a case of liver metastasis (BW-Li). Such BW-Li cells, upon reinoculation, also generated metastases in the spleen, liver and kidneys. Analysis of the Thyl phenotype indicated that BW-Li cells may also have undergone somatic cell fusion in vivo with host (T?) cells, resulting in the acquisition of metastatic properties. The pattern of cell-cell interactions (adhesion, infiltration) with liver cell monolayers of BW-Li cells and of DCH10-Li (T-cell lymphomas) was identical, and differed from cells of liver metastases of the myeloma-B cell hybridomas which might be based on responses to liver growth signals. Accordingly, the morphology of liver metastases generated by the two categories of hybridomas was different. It appears therefore, that (a) the acquisition of metastatic properties following somatic cell fusion with normal lymphoreticular cells is of a general significance; (b) somatic cell fusion provides an experimental system for the analysis of molecular properties determining the acquisition of metastatic capability; and (c) it may also represent a mechanism for tumor progression in vivo.

Mammary-carcinoma cells in mouse liver: infiltration of liver tissue and interaction with Kupffer cells.

Interactions between TA3 mammary-carcinoma cells and liver cells were studied with the electron microscope in mouse livers that had been perfused with a defined medium containing the tumour cells. Infiltration of liver tissue by the TA3 cells proceeded in the following steps. First, numerous small protrusions were extended through endothelial cells and into hepatocytes. Next, some cells had larger processes deeply indenting hepatocytes. Finally a few tumour cells became located outside the blood vessels. Two variant cell lines, TA3/Ha and TA3/St, differing in cell coat and surface charge, did not differ in the extent of infiltration. TA3/Ha cells were often encircled by thin processes of liver macrophages (Kupffer cells). Encircled cells were initially intact, but later some of them degenerated. These observations suggest that TA3/Ha cells were phagocytized by the Kupffer cells. Encirclement appeared to be inhibited after only 30 min, when many cells were still partly surrounded. Encirclement of TA3/St was much less frequent. After injection of tumour cells intra-portally in vivo, similar results were obtained, which demonstrated the validity of the perfused liver model. TA3/Ha cells formed much fewer tumour nodules in the liver than TA3/St cells.

Retention of CXCR4 in the endoplasmic reticulum blocks dissemination of a T cell hybridoma

The dissemination of T cell hybridomas to multiple nonhematopoietic tissues is blocked by pertussis toxin, suggesting the involvement of a chemokine. To study whether this chemokine is SDF-1, we employed a strategy proposed previously for gene therapy of AIDS, whereby the SDF-1 receptor CXCR4 (also a coreceptor for HIV) is retained in the endoplasmic reticulum (ER) and fails to reach the cell surface. We transfected SDF-1, carrying an ER retention sequence, into a T cell hybridoma. This altered chemokine is retained in the ER, where it binds CXCR4 and prevents the latter protein from reaching the surface. These cells failed to migrate toward SDF-1 or to invade fibroblast monolayers, although they could still migrate toward thymus and activation-regulated chemokine (TARC) and invade TARC-treated monolayers. Furthermore, the ability of the transfected cells to disseminate to multiple organs upon intravenous injection into mice was abolished. This dissemination reflects the in vivo migration patterns of activated and memory T cells into nonhematopoietic tissues, which is thus likely to depend on CXCR4. Attempts to block CXCR4 function as a therapy for AIDS may affect this migration with consequences for T cell function. Our results also suggest a decisive role for CXCR4 in the dissemination of hematopoietic malignancies expressing this receptor.

Effect of the chemokine receptor CXCR7 on proliferation of carcinoma cells in vitro and in vivo

The chemokine CXCL12/SDF-1 and its receptor CXCR4 have been implicated in invasion, survival and proliferation of carcinoma cells. Recently, CXCR7 was identified as a second receptor for CXCL12. We observed that CXCL12 promoted proliferation of CT26 colon and KEP1 mammary carcinoma cells, and this was blocked when CXCR7 was downregulated by ‘intrakines’ or RNAi, but not by CXCR4 inhibitors. The K1R mutant of CXCL12, which acts as a CXCR4 antagonist, also promoted proliferation through CXCR7 and is therefore a selective CXCR7 agonist. The effect of CXCR7 was not due to reduced apoptosis, and CXCR7 mediated chemotaxis of the carcinoma cells towards CXCL12. These results differ from those in a previous report on other carcinoma cells. We conclude that CXCL12 can be a potent growth factor for carcinoma cells by acting on CXCR7. Nevertheless, we observed no effect of complete and stable CXCR7 suppression on the growth of s.c. tumours or lung metastases of KEP1 and CT26 cells. A CXCR7 inhibitor has been reported to reduce growth of other tumours. Our results indicate that this inhibitor may not be applicable to therapy of all carcinomas.

Adhesion molecules in lymphoma metastasis

SummaryRecently, many surface proteins of lymphoid cells that mediate adhesion to other cells and extracellular matrix have been identified. Several of these cellular adhesion molecules (CAM) are also expressed by metastatic lymphoma cells and may mediate adhesion to tissue components during the metastatic process. Correlations observed between expression of certain CAM, like MEL-14 and CD44, and particular patterns of spread, support this notion, but conclusive evidence is scarce.We have used T-cell hybridomas to study the mechanisms of wide-spread lymphoid metastasis. The results obtained with this model are reviewed here. The advantages are that a large number of genetically similar cell lines can be generated, which can be grouped in large panels of highly invasive and non-invasive cells. Invasiveness of these cells in hepatocyte and fibroblast monolayers correlates with exprimental metastasis.Lymphoid CAM that are potentially involved in metastasis are reviewed. Several of these CAM are not, or not consistently, expressed by the invasive T-cell hybridomas, indicating that they are not indispensable. Notably, some of the CAM involved in the onset of an immune response or in migration into inflamed tissues, like ICAM-1 and VLA-4, and the ‘homing receptors’ MEL-14 and LPAM-1 do not seem to be involved. CAM that are consistently expressed by the T-cell hybrids include LFA-1, the beta-1 integrin subunit CD29, CD31 (PECAM-1) and CD44 (‘Hermes homing receptor’).We have generated considerable evidence that LFA-1 is required for efficient metastasis of T-cell hybrids, based on the behavior of LFA-1-deficient mutants and revertants. High levels of LFA-1 are required. The relevant counterstructure is probably ICAM-2 rather than ICAM-1. Preliminary results suggest that also a beta-1 integrin, possibly VLA-5, plays a role. Finally, we summarize evidence indicating that CD31 and CD44 are primary candidates for involvement in metastatic spread of T-cell hybridomas.

A comparative study of four cytochemical detection methods of concanavalin A binding sites on the cell membrane

Abstract Four different electron cytochemical methods to detect concanavalin A (ConA) binding sites on the plasma membrane of mouse fibroblasts were compared in this study. The ConA binding sites were made visible either by adding ConA, followed by horseradish peroxidase (HRP) or hemocyanin (HC), or by marking the sites with complexes of ConA with ferritin (Fer) or with micro-peroxidase (MP). HC and Fer are directly visible in the electron microscope; HRP and MP are detected by their electron-dense reaction product with diaminobenzidin and H 2 O 2 . Differences in sensitivity of the ConA binding sites for the different markers were found and resulted in a tentative interpretation of the labelling reactions. All experiments suggested that normal and transformed murine fibroblasts both have plasma membranes in which the binding sites can move equally well and can be induced to form clusters. These results are discussed in relation with the hypothesis that differences in clustering of ConA sites between normal and transformed cells are responsible for differences in the agglutinability by ConA of these cells.

Stromal Cell-Derived Factor-1-Induced LFA-1 Activation During In Vivo Migration of T Cell Hybridoma Cells Requires Gq/11, RhoA, and Myosin, as well as Gi and Cdc42

Dissemination of T cell hybridomas in mice, a model for in vivo migration of memory T cells and for T lymphoma metastasis, depends on the chemokine stromal cell-derived factor-1 (SDF-1) and the integrin LFA-1 and correlates well with invasion into fibroblast cultures. In addition to the known role of the pertussis toxin-sensitive heterotrimeric GTPase Gi, we show that also the pertussis toxin-insensitive GTPase Gq/11 is required for dissemination and invasion. Furthermore, we show that the small GTPases, Cdc42 and RhoA, are involved, and that invasion is blocked by inhibitors of actinomyosin contraction. Gq/11, RhoA, and contraction are specifically required for LFA-1 activation, since 1) they are essential for LFA-1-dependent migration toward low SDF-1 concentrations through ICAM-1-coated filters, but not for migration toward high SDF-1 levels, which is LFA-1 independent; 2) G protein (AlF4−)-induced adhesion to ICAM-1 requires RhoA and contraction; 3) constitutively active Gq induces aggregation, mediated by LFA-1. We previously reported that binding of this activated LFA-1 to ICAM-1 triggers a signal, transduced by the ζ-associated protein 70 tyrosine kinase, that activates additional LFA-1 molecules. This amplification of LFA-1 activation is essential for invasion. We show here that ζ-associated protein 70-induced LFA-1 activation requires neither Cdc42 and RhoA nor contraction and is thus quite different from that induced by SDF-1. We conclude that two modes of LFA-1 activation, with distinct underlying mechanisms, are required for the in vivo migration of T cell hybridomas.

The Chemokine Receptor CXCR6 and Its Ligand CXCL16 Are Expressed in Carcinomas and Inhibit Proliferation

The chemokine receptor CXCR6 and its ligand CXCL16 are involved in inflammation. Thus far, they were known to be expressed mainly by T cells and macrophages, respectively. However, we detected both in all of 170 human primary mammary carcinomas and at similar levels in all 8 human mammary carcinoma cell lines tested by microarray analysis. Expression was confirmed by reverse transcription-PCR and for the cell lines also by fluorescence-activated cell sorting analysis. CXCR6 and CXCL16 were also detected in several mouse and human mammary, colon, and pancreatic carcinoma cell lines. CXCL16 is a transmembrane protein from which the soluble chemokine can be cleaved off. The transmembrane form is present on the surface of the carcinoma cells. Surprisingly, suppression of either CXCR6 or CXCL16 led to greatly enhanced proliferation in vitro as well as in vivo, indicating that their interaction inhibits proliferation. This notion was verified using inhibitory antibodies and by introduction of CXCL16 into a rare CXCL16-negative cell line. The effect was mediated by the G protein-coupled receptor CXCR6 because it was blocked by the G(i) protein inhibitor pertussis toxin. In contrast, the soluble CXCL16 chemokine enhanced proliferation, and this was also mediated by CXCR6 but not via G(i) protein. It is remarkable that both CXCR6 and CXCL16 are expressed by all mammary carcinomas because cells that lose either acquire a growth advantage and should be selected during tumor progression. This suggests an unknown important role in tumor formation. Proteases, possibly macrophage derived, might convert inhibitory transmembrane CXCL16 into the stimulatory chemokine.

Membrane-associated cytoskeleton and coated vesicles in cultured hepatocytes visualized by dry-cleaving.

Abstract Dry-cleaving is introduced as a new technique for visualization of the cytoplasmic side of adherent membrane in cultured cells. Basically, cells are fixed and critical point-dried in situ and subsequently broken by means of adhesive tape. The plane of cleavage is dependent on the fixation scheme applied. The method has been used for the study of substrate-adherent membranes in primary cultured hepatocytes, in combination with a variety of scanning- and transmission electron microscopic (SEM and TEM) techniques. It is shown that a two-dimensional filamentous web is apposed to the entire hepatocytic plasma membrane. Particular patterns within the web can be recognized, among which a ‘spider-web’ pattern appears to be associated with the early stage of coated vesicle development. During successive stages of coated vesicle formation the coat appears to be connected to filaments, directly in its mid-stage and by means of radial spokes in its final stage. The significance of the spider-web pattern with respect to the endocytotic process and the interrelationship of coated vesicles and filamentous structures are discussed.

Cytoplasmic domain mutants of beta1 integrin, expressed in beta 1-knockout lymphoma cells, have distinct effects on adhesion, invasion and metastasis.

Structural requirements for β1 integrin cytoplasmic domain functions in adhesion, migration and signaling have been studied mainly for fibroblasts in vitro. The relevance for β1-dependent in vivo migration of lymphoid cells has not been assessed. To study this, we transfected β1 mutants into β1-deficient double knockout (DKO) ESb lymphoma cells, and tested the capacity of the cells to metastasize to liver and spleen. This was compared to α4β1-dependent invasion into cell monolayers in vitro and Mn2+-induced adhesion to fibronectin. Deletion of the five C-terminal residues or mutation of both threonines T788 and T789 to alanines blocked invasion and metastasis and greatly reduced adhesion, in line with known in vitro effects. However, mutations of the NPXY motif tyrosines had unexpected consequences. A Y783F mutation had no effect at all, but a Y783,795F double mutation strongly reduced Mn2+-induced adhesion, whereas it had limited effects on invasion and metastasis. Furthermore, cells expressing a β1β2 chimeric subunit, which contains phenylalanines in the NPXY/F motifs, adhered poorly but invasion and metastasis was fully restored to the same levels as for cells expressing wild-type β1. We conclude that part of the functions of the β1 cytoplasmic domain that are required for adhesion are not essential for β1-dependent invasion and metastasis.