Influence of interference with the cyclic AMP-adenylcyclase-phosphodiesterase system on TSH-induced hormonal imprinting in the Tetrahymena

Primary interaction of TSH with the unicellular Tetrahymena accounted for an increase in TSH binding capacity on reexposure, i.e. for a regular hormonal imprinting. TSH in itself did not give rise to a faulty imprinting (for insulin). Combination of TSH with dibutyryl cAMP reduced the intensity of imprinting, whereas theophylline or lithium ions not only reduced the efficacy of normal imprinting, but also gave rise to faulty imprinting (for insulin instead of TSH).     

Experimental observations on the mechanism of hormonal imprinting: influence of actinomycin D, methylamine and colchicine on receptor memory in a unicellular model system

The first interaction between target cell and hormone gives rise to hormonal imprinting, which accounts for greater responsiveness of the cell at later interactions. The mechanism of hormonal imprinting is obscure; we based experimental approach to its closer study on combined treatment of Tetrahymena, as model cells, with diiodotyrosine (T2), which stimulates the division, and cell growth inhibitors, which interfere with different stages of cell reproduction, and methylamine, which inhibits cluster formation in the membrane. Of these, actinomycin D and methylamine inhibited the growth of the Tetrahymena, while colchicine did not, and all three suppressed the division stimulating action of T2, but could not prevent hormonal imprinting, as demonstrated on later re-exposure to T2 of cells preexposed and not preexposed to T2 in combination with the inhibitors. It appears that the underlying mechanism of hormonal imprinting is highly complex, and involves many subcellular mechanisms and structures, but suppression of, or gross interference with, one or another of these cannot delete, only quantitatively reduce, the consequence of the first interaction with the hormone, i.e. hormonal imprinting.     

Insulin pretreatment (imprinting) produces elevated capacity in the insulin binding of Tetrahymena. Different binding by the cilia of the body and oral field

Gold-labeled insulin is bound first of all to the cilia of the oral field of Tetrahymena. A primary treatment (hormonal imprinting) with insulin increases the binding capacity even after 24h and makes it more sensitive for appearance a week later, within a minute of giving insulin-gold. The food vacuoles contain insulin-gold in pretreated cells or without pretreatment as well, though in imprinted situations the label can be found in pinocytotic vesicles at the bases of cilia in the oral field. Altogether, a functional difference can be observed between the cilia of the oral and non-oral surfaces of Tetrahymena and hormonal imprinting has a specifying effect on the binding of labeled hormone.     

Chemical reception mechanisms at a low level of phylogeny. Influence of polypeptide hormones and non-hormone polypeptides on the growth of Tetrahymena

The polypeptide hormones insulin, glucagon, thyrotropin (TSH), pregnant mare serum gonadotropin (PMSG) and adrenocorticotropin (ACTH) stimulated the growth of the Tetrahymena, and the non-hormone polypeptides (bovine serum albumin (BSA), protamine) had a similar effect. Re-exposure after 24 h accounted for a greater growth stimulation than pre-exposure alone in cultures treated with TSH and PMSG, and re-exposure after 7 days had such effect in all polypeptide-treated cultures. It follows that the non-hormone polypeptides had a similar imprinting potential to the polypeptide hormone. The non-hormone polypeptides were also able to cross-imprint for one another, i.e. pre-exposure to one enhanced the binding capacity of the cells for the other on re-exposure, and vice versa. A single treatment with a polypeptide hormone or a non-hormone polypeptide did in itself stimulate the growth of the Tetrahymena for as long as 1 week.     

Immunocytochemical verification of the insulin receptor's specificity in the nuclear envelope of Tetrahymena. Comparison with receptors of the plasma membrane

The unicellular Tetrahymena possess hormone receptors in the nuclear envelope similarly to higher rank animals. These receptors bind insulin and their specificity is detectable by monoclonal antibodies developed to insulin. The hormonal (insulin) pretreatment (imprinting) of the cell did not alter the binding capacity of the nuclear membrane, demonstrated by antibody-technique. The specific binding characteristics of the plasma membrane was demonstrated and this was significantly increased following imprinting. In the nucleus of Tetrahymena presence of insulin was not detected by immunocytochemical method.     

Effect of inhibition of endocytosis, recycling and lysosomal activity on the insulin binding capacity and imprintability of Tetrahymena

Dinitrophenol (DNP), an inhibitor of endocytosis of hormone receptors, Tris, an inhibitor of recycling and chloroquine, an inhibitor of lysosomal degradation, all decreased the binding of insulin and inhibited the development of hormonal imprinting in Tetrahymena. The effects of DNP and Tris seemed to be similar even quantitatively. The effect of chloroquine proved to be somewhat different, it appeared later, was more pronounced after 24 hours and more marked when insulin was also administered. Combined administration of Tris + DNP inhibited the binding of insulin but this inhibition was the one which disappeared most completely after 24 hours and the one where the inhibition of imprinting was the most pronounced. Tris + chloroquine led to severe destruction of the cells. The conclusion has been drawn that the inhibition of membrane circulation inhibits not only the hormone binding but also the development of imprinting in Tetrahymena.     

Induction of hormone receptor formation in the unicellular tetrahymena

Studies based on treatment with antibodies to thyrotropic hormone, luteotropic hormone, growth hormone or adrenocorticotropic hormone have shown that although the unicellular Tetrahymena does not possesssui generis receptors to all polypeptide hormones, such binding structures may arise, or become established in the membrane of the unicellular Tetrahymena in the presence of exogenous hormone. The Tetrahymena subjected to hormonal imprinting still contained an increased amount of hormone after six generation changes, which suggested that either hormone production had been induced by treatment, or the internalized hormone had not been degraded intracellularly. Thus the role of hormonal imprinting in receptor formation has also been substantiated by the immunocytochemical approach used in the present study.     

Influence of hormone treatment applied or begun in different phases of the cell cycle on hormonal imprinting in Tetrahymena

Primary exposure to a hormone (hormonal imprinting) alters--in the case of the Tetrahymena increases--cellular response to re-exposure(s) to the same hormone. The intensity of hormonal imprinting depends on the phase of the cell cycle in which the primary exposure has taken place. The effect of imprinting was greater on the cells exposed to the hormone in phase G1 than on those exposed in phase S or G2. The response pattern of the progeny generations corresponded to that of the primarily exposed (imprinted) ancestor cell, irrespective of their own pre-exposure in phase G1, G2 or S of their cycle.     

Effect of insulin imprinting on the 3H-amino acid uptake of the Tetrahymena

Insulin imprinting given to the unicellular Tetrahymena considerably increases the uptake and intracellular storage of amino acids even many generations after the actual contact with the hormone. On the other hand, both the first and the second contacts with insulin increase the rate of the excretion of the stored amino acids. On the basis of the results obtained it seems to be possible that both protein synthesis and exocytosis of the Tetrahymena change as an effect of imprinting, either in general or specifically due to the formation of new hormone receptors.     

Taxon-dependence of receptor level cell-to-cell communication in Tetrahymena: possible explanation for the transmission of hormonal imprinting

Insulin treatment induced in Tetrahymena pyriformis a positive hormonal imprinting, and in Tetrahymena thermophila a negative imprinting, resulting in increased and decreased binding capacity, respectively, at re-exposure to the hormone. The imprinting, or the information associated with it, is transferred by the nutrient medium of the insulin-treated cells to those not treated. The issue of transfer depends on the nature of the receiver taxon, leading always to a positive imprinting in Tetrahymena pyriformis, and to a negative imprinting in Tetrahymena thermophila, regardless of the nature of the 'imprinted' transmitter taxon. The findings substantiate the transferability of hormonal imprinting by the nutrient medium at the unicellular level, the key role of the postreceptorial mechanism in determining the trend of imprinting and may explain the persistence of imprinting in the progeny generations.     

Insulin treatment (hormonal imprinting) increases the insulin production of the unicellular Tetrahymena long term. Is there a simultaneous formation of hormone receptor and hormone?

Insulin treatment of Tetrahymena pyriformis resulted in a long-lasting increase in the insulin content of the cells. After about 200 generations, insulin levels significantly higher than in the control were demonstrated by using a quantitative immunocytochemical method. Although the insulin content fluctuated from day to day, it was always higher in the insulin pre-treated (imprinted) cells than in the controls. The results emphasise the simultaneous stimulation of hormone and receptor formation by hormonal imprinting.     

Prolonged elevation of insulin content in the unicellular tetrahymena after insulin treatment: induction of insulin production or storage?

In the unicellular organism, Tetrahymena, the first encounter with an exogeneously given hormone results in hormonal imprinting. This causes an increase of the binding capacity of receptors and the production of the appropriate hormone in the progeny generations of the treated cell. In the present experiments the quantity (using radioimmunoassay) and localization (using confocal laser scanning microscopy) of the immunologically insulin‐like material (hereafter insulin) were studied for 10 days after 4 h or 24 h 10⁻⁶ m insulin treatment (hormonal imprinting). Forty‐eight hours after both insulin treatments a high quantity of insulin was present in the cells. This value was also significantly increased after 96 h. After 8 days the difference to the control was significant only in the 24 h treated group. Confocal microscopy (using antibody to pig insulin) localized insulin in the cell body. The oral field contained extremely high quantities of the endogeneous hormone. Insulin treatment (after 48 and 96 h) caused an elevation of insulin content in general, and specific accumulation in the posterior sections of the cell, around the nucleus and in the periphery were observed. Ten days after both treatments only the peripheral region of the cell body and the ciliary row contained more insulin than the control. This means that after insulin treatment the quantity of insulin increases for a lengthy time period which is followed by the expression of insulin in the peripheral region. Insulin contained by Tetrahymena 48 h after imprinting stimulated glucose uptake of rat diaphragm. Copyright © 1999 John Wiley & Sons, Ltd.     

Verification of epigenetic inheritance in a unicellular model system: multigenerational effects of hormonal imprinting

The unicellular Tetrahymena has receptors for hormones of higher vertebrates, produces these hormones, and their signal pathways are similar. The first encounter with a hormone in higher dose provokes the phenomenon of hormonal imprinting, by which the reaction of the cell is quantitatively modified. This modification is transmitted to the progeny generations. The duration of the single imprinter effect of two representative signal molecules, insulin and 5-HT (5-hydroxytryptamine), in two concentrations (10-6 and 10-15 M) were studied. The effects of imprinting were followed in 5 physiological indices: (i) insulin binding, (ii) 5-HT synthesis, (iii) swimming behaviour, (iv) cell growth and (v) chemotaxis in progeny generations 500 and 1000. The result of each index was different from the non-imprinted control functions, growth rate, swimming behaviour and chemotactic activity to insulin being enhanced, while others, e.g. synthesis and chemotactic responsiveness of 5-HT and the binding of insulin were reduced. This means that a function-specific heritable epigenetic change during imprinting occurs, and generally a single encounter with a femtomolar hormone concentration is enough for provoking durable and heritable imprinting in Tetrahymena. The experiments demonstrate the possibility of epigenetic effects at a unicellular level and call attention to the possibility that the character of unicellular organisms has changed through to the present day due to an enormous amount of non-physiological imprinter substances in their environment. The results - together with results obtained earlier in mammals - point to the validity of epigenetic imprinting effects throughout the animal world.     

Studies into secretions of Tetrahymena: enzymes secreted into inorganic medium.

The peptides secreted by Tetrahymena cells into inorganic medium were chromatographed. Six fractions showing a marked enzyme-like activity were examined for influence on certain physiological parameters of Tetrahymena. The enzymatically active fractions increased the phagocytic activity of Tetrahymena and decreased its binding capacity for lectins and hormone (insulin), but enhanced insulin imprinting at primary interaction. It remains to be clarified whether these effects were due to the enzymatic or other components of the fractions investigated, or to lack of the compensatory influence of the fractions not studied.     

Influence of deciliation and ciliary regeneration on hormonal imprinting in Tetrahymena. Observations on the 'localization' of imprinting

Imprinting induced in Tetrahymena with insulin is not abolished by deciliation. No imprinting occurred in deciliated cells exposed to insulin at 1 or 2 h of regeneration. However, imprinting did occur if Tetrahymena was exposed to insulin after 3 h of regeneration. It appears that while presence of cilia is a prerequisite of imprinting, the pertinent information is not, or not exclusively stored in the cilia.     

Discrepancy in hormone binding and information transfer between sister cells of Tetrahymena clones

Tetrahymena cells treated with insulin in mass cultures were separated to single-cell clones or one of the "sister-cells" of dividing Tetrahymena (in single-cell culture) was treated with insulin. In both cases the FITC-insulin binding of sister-cells were compared. The insulin imprinting significantly increased the insulin binding of cells. There was also a significant difference between the imprinted and not imprinted sisters as well as between the not imprinted sisters. This demonstrates the existence of a difference (in hormone binding) between sister-cells and justifies that the information of the first hormone treatment (imprinting) is not equally divided between the sister-cells.     

Cell-mediated transmission of hormonal imprinting to virgin mammalian cells in culture and failure of transmission with the nutrient medium

Chinese hamster ovary (CHO) cells and Chang liver cells which had already interacted with a hormone (gonadotropin, TSH, insulin) in culture, transmitted hormonal imprinting to virgin cells not previously involved in the interaction. The information associated with imprinting was not mediated by the nutrient medium, because the nutrient medium of the hormone-treated cells did not induce imprinting in virgin cells and even reduced rather than enhanced the hormone binding capacity thereof. Thus the transmission of information is in all probability associated with a direct cell-cell contact.     

Specificity of the cell-to-cell transmission of hormonal imprinting in cell cultures

Chang liver cells and Chinese hamster ovary (CHO) cells were imprinted either with insulin or with thyrotropin (TSH). Chang liver cells responded to insulin but not to TSH. As an effect of imprinting evoked by insulin administration the binding of insulin administered for the second time was enhanced. In the mixed culture of imprinted and intact cells the extent of the binding was similar to that seen in the cultures of the cells having received imprintatory treatment alone. CHO cells also responded to TSH, imprinting developed and was transmitted to the cells which were not in interaction with the hormone (intact cells). In CHO cells also insulin gave rise to imprinting for insulin, whereas TSH gave rise to moderate binding imprinting for insulin. On the other hand, insulin imprinting did not enhance the binding of TSH. The obtained results indicate that both the imprinting itself and the specificity of the transmission of imprinting depend on the characteristics of the cell-type in question. The extent of the transmission, however, is always proportional to the extent of imprinting.     

Effect of stress and stress hormones on the hormone (insulin) binding of Tetrahymena

The unicellular Tetrahymena pyriformis GL produce, store and secrete vertebrate‐like hormones. In earlier experiments the effect of different stressors on the hormone levels of Tetrahymena was studied and an elevation of these was found. In the present experiments the hormone binding was investigated, using flow cytometric method. FITC‐insulin binding was elevated after concentrated (5, 10, or 20 mg ml^?1) NaCl or 0.01%, 0.1%, or 0.05% formaldehyde treatment, or after thermal stress (37°C). Serotonin given together with NaCl increased and together with formaldehyde decreased the binding. Histamine always decreased the binding and insulin was indifferent. Four hours after osmotic stress, hormone binding significantly decreased and this was not influenced by hormones. However, 4 h after formaldehyde stress the binding elevated and this was further increased by repeated hormone treatments. The results show that the stress in Tetrahymena provokes an activation of its hormonal system (hormone production and binding), which is differently influenced by exogeneously given hormones. Copyright © 2009 John Wiley & Sons, Ltd.     

Cytochemical investigation into the Ca-dependence of positive and negative hormonal imprinting in Tetrahymena

Insulin gives rise to positive imprinting in Tetrahymena pyriformis, but to negative imprinting in T. thermophila, as revealed by the respective increases and decreases in the insulin-binding capacity of these organisms observed during later interactions with this hormone. We found that changes in insulin-binding capacity exhibited parallelism with fluctuations of the levels of free, intracellular Ca2+ detectable by Quin-2 labeling. An exception was the second interaction of T. thermophila with insulin, which although showing a positive trend, produced a relatively small increase in the level of intracellular Ca2+. These observations suggest an interrelationship between hormone-binding capacity and the fluctuation of intracellular Ca2+ levels. Either hormone binding depends on the availability of Ca2+, or, alternatively, the latter depends on the binding capacity. Further studies are required to elucidate the true nature of this interdependence.