Trefoil factor-2, human spasmolytic polypeptide, promotes branching morphogenesis in MCF-7 cells.

Members of the trefoil factor (TFF) family are highly expressed in endodermal ulcerative wound healing and selectively in neoplastic proliferation of various glandular epithelia. There is some evidence that TFF1 and TFF3 affect cell motility, are indirectly involved in growth suppression, and are associated with mucin expression. TFF2 is co-expressed with TFF1 in gastric surface epithelial cells, but its potential role in vivo is unclear. We analyzed potential effects on cell proliferation and morphogenesis of TFF2 on a panel of epithelial and mesenchymal cell lines. TFF2 had no measurable effect on the proliferation of any of the cell lines tested. In type 1 collagen lattices, TFF2 at a low concentration (25-100 nM) induced the formation of highly complex branched structures in the breast carcinoma cell line MCF-7 over a period of 14 to 42 days. No significant effect was shown with other cell lines. This morphogenic effect was abolished by monoclonal antibodies specific for either TFF2 or TFF1. TFF2 did not affect cell motility in MCF-7 cells as measured by videomicroscopy, in contrast to previous studies using TFF1. TFF2-treated MCF-7 colonies showed a 30% reduction in the number of apoptotic bodies, corroborated by trypan blue exclusion and DNA fragmentation ELISA, indicating TFF2 promotes cell survival via inhibition of apoptosis and can act as a morphogen in the presence of TFF1. These properties may complement the actions of TFF1 as a motogen and may explain differential expression in endodermal wound healing.

p53 expression in cultured cells following radioisotope labelling.

p53 inhibits division following cellular damage. Cultured cells were found to express p53 protein following pulse labelling with radioisotopes, even at low doses normally used for growth and metabolic labelling studies. Some stem cells are exquisitely sensitive to radiation and thus p53 may have evolved as a major regulator of stem cell function. Therefore any genetic damage may be able to induce p53 expression, which in turn will affect the biochemical outcome of many experiments by both cell cycle arrest and other mechanisms. In some cases the use of radioisotopes may directly change the results of the experiment. This will require a careful re-evaluation of the current literature and experimental protocols utilising radioisotopes.

Colony-stimulating factors and interferon-gamma differentially affect cell surface molecules shared by monocytes and neutrophils.

Monocytes and neutrophils share a common progenitor and perform many similar functions, as reflected in the expression of several shared membrane molecules. We show here that such molecules can be independently regulated by the cytokines interferon-gamma (IFN-gamma) and the colony-stimulating factors (CSF) in the context of the cell type on which they are present. Thus, IFN-gamma causes neutrophils to express the high-affinity receptor for IgG, Fc gamma RI, which has been considered to be a monocyte-specific receptor. Although neutrophil Fc gamma RI never reaches the levels present on monocytes, it is induced more rapidly and by lower amounts of IFN-gamma than monocyte Fc gamma RI. Of the CSF, only macrophage (M) CSF has an effect which is to cause a decrease in expression of monocyte Fc gamma RI. Secondly, after culture monocytes express Fc gamma RIII which is constitutively expressed by neutrophils. Although neutrophil Fc gamma RIII can be readily modulated by IFN-gamma, granulocyte (G) CSF and granulocyte-macrophage (GM) CSF, these cytokines do not alter the low levels of monocyte Fc gamma RIII. Thirdly, expression of the gp55 protein recognized by CD14 monoclonal antibodies is decreased after exposure of monocytes to IFN-gamma. Neutrophils express low levels of CD14 and, in this case, IFN-gamma causes an increase in the CD14 antigen on these cells. Of all the molecules investigated, only HLA class II is confined to monocytes, with increases in expression induced by IFN-gamma but not by the CSF.

The Fc receptor, FcRI, and other activation molecules on human mononuclear phagocytes after treatment with interferon-gamma.

Human monocytes and the myeloid cell lines U937 and HL60 have been tested with monoclonal antibodies (MoAbs) reactive with 22 different cell surface molecules before and after treatment with interferon-gamma (IFN-gamma). An increase in the expression of the high affinity Fc receptor, FcRI, and the receptor for interleukin 2, IL-2R, were the most consistent alterations which were observed. In addition, expression of the gp55 molecule recognized by CD14 MoAbs was decreased on monocytes. Of the MHC Class II molecules, there was little expression by the myeloid cell lines and no enhancement after IFN-gamma treatment. In contrast monocytes expressed all three MHC Class II subloci with DR much greater than DQ and DP. However there was much variation in IFN-gamma-mediated increase in expression of the individual subregions. In monocytes, the alteration in expression of FcRI, IL-2R, gp55 and MHC Class II molecules took place in a co-ordinate fashion and reached a plateau only after 48 h. In U937 cells, activation proceeded more rapidly and was at maximum levels between 12-16 h. This increase in FcRI appears to be a hallmark of IFN-gamma activation for mononuclear phagocytes (Mph) as the other alterations are either not found on all types of Mph (gp55, MHC Class II) or are induced by other cytokines on Mph and on other cells (IL-2R, MHC Class II). Conversely, other cytokines do not induce FcRI on Mph. These results also suggest that the cell membrane phenotypic changes induced in Mph by IFN-gamma may not be extensive and that FcRI must play a specific role in the IFN-gamma-activated Mph.