Investigations of receptor-mediated phagocytosis by hormone-induced (imprinted) Tetrahymena pyriformis

Hormonal imprinting in the unicellular Tetrahymena: the proto-model of epigenetics

The unicellular ciliate, Tetrahymena has a complete hormonal system. It has receptors for receiving hormones, produces, stores and secretes hormones, similar to mammalian ones and has signal transduction pathways, for transmitting the information given by the hormones. The first encounter with a hormone provokes the hormonal imprinting under the effect of which the further encounters with the same hormone induces altered (usually enhanced) reaction (hormone binding, hormone synthesis, chemoattraction, movement, growth etc.). The effect of imprinting is durable, it can be observed also after 1000 generations, or after one year in non-dividing cells. Receptors of the nuclear envelope also can be imprinted. The plasma membrane receptors provoked by imprinting are similar to the receptors of mammals. Although steroid hormones are not present in Tetrahymena, the production of them and their receptors can be induced by imprinting. The hormonal imprinting is an epigenetic process and inhibition of DNA-methylation alters the imprinting. Hormonal imprinting in Tetrahymena was likely the first epigenetic phenomenon which was justified at cellular level. It is very useful for the unicells, as it helps to avoid dangerous molecules more easily or to find useful ones and by this contributes to the permanence of the population's life.

Effect of concanavalin A (Con-A) on the hormone production of the unicellular Tetrahymena and the immune cells of the rat. A comparative study

Tetrahymena populations were treated with 10(-15) g ml(-1) or 10(-6) g ml(-1) concanavalin-A (Con-A) in tryptone-yeast medium for 1 h. Rat peritoneal immune cells (mast cells, lymphocytes, monocyte-granulocyte group) were also treated with 10(-6) g ml(-1) Con-A, for 1 h. The cells' hormone (ACTH, histamine, serotonin, endorphin, triiodothyronine (T(3))) content was measured by using immunocytochemistry and flow cytometry. The extremely low dose of Con-A universally and significantly elevated the hormone contents, while the result of higher dose was uncertain. In the immune cells, Con-A significantly decreased the ACTH level in each cell type and histamine level in mast cells. The results demonstrate the very high sensitivity of Tetrahymena receptors for a non-hormone (lectin) molecule, which can bind to the insulin receptors and mimics the effect of insulin. The results also show that Tetrahymena receptors are more sensitive to lower concentrations of molecules than to higher ones. The universal hormone-production stimulating effect of Con-A-which is observed in Tetrahymena-is specified in rat.

Cell surface lectin-binding glycoconjugates on marine planktonic protists

Carbohydrate-protein interactions appear to play an important role in the phagocytosis of microbial prey by free-living protozoa. The present study utilizes FITC-labelled plant lectins to investigate the presence and localization of cell surface glycoconjugates on live and fixed planktonic protists (Dunaliella primolecta, Oxyrrhis marina, Goniomonas amphinema, Paraphysomonas vestita and Euplotes vannus). With live flagellate preparations, lectins primarily bound to external cell surfaces, with minimal internal staining observed. In contrast, cell fixation permeabilized cell membranes, allowing lectins to bind to internal structures, such as nuclear membranes and food vacuoles, interfering with the characterization of cell surface glycoconjugates. The method developed to label cell surface sugar moieties of live planktonic protists successfully overcomes the problems associated with fixation, and thus provides a useful protocol for future studies on protistan cell surface carbohydrate characterization.

Chemotactic selection with insulin, di-iodotyrosine and histamine alters the phagocytotic responsiveness of Tetrahymena

Chemotactic selection is a method by which populations of cells exposed to ligands can be isolated and subsequently cultivated. We used Tetrahymena pyriformis GL cultures selected by chemotactic selection to insulin (10 nM), histamine (0.1 nM) and di-iodotyrosine (T2, 10 nM) to study the phagocytotic capacity under the induction of selector hormones. Our results show a long-lasting link between chemotactically selected cultures and phagocytotic activity. Cells selected to histamine produced the highest phagocytotic activity upon a second exposure to the selector hormone. T2 selection was also strongly effective, however, the phagocytosis stimulation was not specific to the hormone given later. Insulin selected sub-populations had different phagocytotic responses to the control substance itself, whereas histamine selected sub-populations seem to be heterogeneous in the phagocytotic response to histamine. For insulin, the increased endocytotic or metabolic activity was demonstrated by the lack of non-phagocytotic cells. These experiments call attention to the evolutionary role of selection in the later developing receptor-hormone relationship.

Chemotactic selection of Tetrahymena pyriformis GL induced with histamine, di-iodotyrosine or insulin

It has been hypothesized that in phylogeny the encounter between potential signalling molecules and the continously changing cell membrane could result in the formation of a ligand specific receptor. This chemical (hormonal) imprinting is then transmitted to the progeny generations. It is, however, very difficult to know whether the selection of cells with receptor-like patterns or amplification of complete receptor-like patterns led to the formation of the receptor-hormone complex. The new technique of 'chemotactic selection provides a physiological response-guided selection of cells. It also enables the testing of subpopulations with the characteristic selector ligand. We show here that of three chemotactic ligands (histamine, di-iodotyrosine (T2) and human insulin), insulin and T2 selected subpopulations express a significantly high chemotactic response. Since the control medium has a selector capacity itself, we introduced a chemotactic selection coefficient (Chsel) which facilitates the comparison of all groups. Using this factor we found that insulin (Chsel = 1.57), functions as a strong selector and T2 (Chsel = 0.98), was a weak selector. Morphometric evaluation of the cells showed a good correlation between chemotactic responsiveness and morphometric characteristics of subpopulations selected with insulin and histamine. T2 data suggest that the long lasting responsiveness is not general, but might be subpopulation specific.