Influence of hormone concentration and time factor on TSH-FSH imprinting and overlap in CHO cells

Exposure of Chinese hamster ovarian cell cultures (cell line CHO) to TSH of FSH gave rise to hormonal imprinting. In earlier studies re-exposure after 48 h displayed a considerable increase in hormone binding. In the present experiments similar increase was demonstrated with an interval of five days. After 14 days, the increment was of lesser degree or even a decrease was noted in hormone-binding capacity. Although the CHO line originates from the target cells of gonadotropin, long-term positive imprinting was greater for TSH than for FSH, imprinting for FSH being negative rather than positive. The experimental results suggest that even very low concentrations (10(-13) mol) of hormone induce imprinting after an exposure as short as 60 min.     

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.     

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.     

Effect of inhibitors and activators of tyrosine kinase on insulin imprinting in Tetrahymena.

Primary exposure of Tetrahymena cells to insulin gave rise to hormonal (insulin) imprinting in the offspring generations, as judged from the increase in binding upon reexposure to insulin. Vanadate mimicked the action of insulin, inasmuch as it also induced imprinting for insulin, whereas the other tyrosine kinase activator tested, namely H2O2, had no such effect. However, combined treatment with vanadate+H2O2 + insulin induced a more pronounced imprinting for insulin than either insulin or vanadate on their own. The tyrosine kinase inhibitor genistein, a plant flavonoid, did not change the value for insulin binding significantly relative to the control immediately after exposure, but increased it slightly in the offspring generations after 24 h at high dilution. Upon combination with insulin, 10(-4)M genistein inhibited imprinting by insulin. These experimental observations suggest that there may be a key role for tyrosine kinase activity in the mechanism (development) of imprinting.     

Studies into hormonal imprinting in a Tetrahymena thermophila mutant incapable of lysosomal enzyme secretion

Reexposure to insulin after primary interaction (hormonal imprinting) was followed by a binding increase in T. pyriformis and by a binding decrease in T. thermophila. The sec. mutant, MS-1 strain of T. thermophila, which is unable of lysosomal enzyme secretion, also showed a binding increase on a second exposure to insulin, from which it follows that alteration of the enzyme secretion, or other factors associated with mutation, accounted for reversion of the trend of imprinting. Thyrotropic hormone (TSH) also gave rise to a negative imprinting in T. thermophila, but did not alter the binding relations of the MS-1 mutant strain.     

Involvement of selection and amplification mechanisms in hormone receptor development in a unicellular model system

It was demonstrated earlier, that long lasting exposure of Tetrahymena to a hormone (histamine) resulted in an increased responsiveness to a later re-exposure. However, it was difficult to establish whether selection or amplification plays a role in receptor differentiation. As diiodotyrosine (T2) enhances the growth of Tetrahymena, in the present experiment the effect of T2-treatment on a long-term culture of Tetrahymena pyriformis was analysed by mathematical-statistical methods to differentiate the effects of selection and amplification mechanisms on hormone receptor development. Although continuous and periodic treatment with T2 enhanced cell division equally, the resulting populations differed in structure. On continuous treatment the population tended to become inhomogenous. The variance tended to increase for 9 days and decreased afterwards without, however, returning to the control level. On periodic treatment the variance was the same as in the control group, but the second and third exposure were significantly more effective than the first treatment, suggesting that the primary encounter with the hormone had given rise to lasting alterations (hormonal imprinting). It follows that continuous exposure involves a selection process which does not, however, account for a steady increase of the growth rate; for initial amplification, taking place also in this condition, and selection which takes effect later, compensate one another's effects. Regarding the unicellular experimental system as a phylo- and ontogenetic model, the conclusion lies close at hand that the selection and amplication mechanisms promote hormone receptor development by joint rather than alternate action.     

Thyroid hormonal activity of the flame retardants tetrabromobisphenol A and tetrachlorobisphenol A

The thyroid hormonal-disrupting activity of the flame retardants tetrabromobisphenol A (TBBPA) and tetrachlorobisphenol A (TCBPA) was examined and compared with that of bisphenol A, a typical estrogenic xenobiotic. TBBPA and TCBPA, halogenated derivatives of bisphenol A, markedly inhibited the binding of triiodothyronine (T(3); 1 x 10(-10) M) to thyroid hormone receptor in the concentration range of 1 x 10(-6) to 1 x 10(-4) M, but bisphenol A did not. The thyroid hormonal activity of TBBPA and TCBPA was also examined using rat pituitary cell line GH3 cells, which grow and release growth hormone (GH) depending on thyroid hormone. TBBPA and TCBPA enhanced the proliferation of GH3 cells and stimulated their production of GH in the concentration range of 1 x 10(-6) to 1 x 10(-4) M, while bisphenol A was inactive. TBBPA, TCBPA, and bisphenol A did not show antagonistic action, i.e., these compounds did not inhibit the hormonal activity of T(3) to induce growth and GH production of GH3 cells. TBBPA and TCBPA, as well as bisphenol A, enhanced the proliferation of MtT/E-2 cells, whose growth is estrogen-dependent. These results suggest that TBBPA and TCBPA act as thyroid hormone agonists, as well as estrogens.     

Receptor 'memory' in Tetrahymena: does it satisfy the general criteria of memory? An experimental study on induction and extinction by retroactive interference in a unicellular organism

Diiodotyrosine induced receptor 'memory' at a concentration as low as 10(-18) M. Repeated exposure enhanced cellular responsiveness. Treatment with diiodotyrosine for 1 h, 4 times, induced receptor 'memory' more efficiently than a single uninterrupted treatment for 4 h. Immediately after induction, the receptor 'memory' is subject to retroactive interference by foreign hormonal stimuli, and can be extinguished completely by combined hormone treatment. Thus, the phenomenon of retroactive interference also takes effect at the unicellular level. The experimental observations indicate that receptor 'memory', induced in Tetrahymena by hormonal imprinting, has certain common features with the neuronal memory of higher organisms.     

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.     

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.     

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.     

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).     

The role of Ca2+ in hormonal imprinting of the Tetrahymena

It is known from model experiments on Tetrahymena that primary exposure to a hormone induces receptor formation or amplification, in other words a hormonal imprinting. Substances acting on the intracellular Ca2+ level of the Tetrahymena, such as TMB-8, EDTA, EGTA, NiCl2 and La(NO3)3, interfered with hormonal imprinting of the unicellular to different degrees, and some of them influenced hormone (insulin, TSH) binding also independently of imprinting. Interference with the intracellular Ca-metabolism generally influenced imprinting by insulin and TSH, which were mediated by different mechanisms, to dissimilar degrees, or in opposite directions. On combined application of the agents acting on Ca-metabolism, their effects were additive. It appears that intact Ca-mediation is an essential prerequisite for normal hormonal imprinting.     

Influence of low and high temperature on diiodotyrosine imprinting in Tetrahymena

Hormonal imprinting takes place at the primary interaction between target cell and hormone, and alters cellular response to the hormone for lifetime (at the unicellular level in many subsequent generations). Imprinting induced in Tetrahymena cells by diiodotyrosine at the optimum temperature of 25 degrees C took effect on re-exposure to the hormone at 25 degrees C and 15 degrees C, but failed to take effect if the cells were first exposed to the hormone at 15 degrees C or 32 degrees C.     

Prolonged impact of pubertal serotonin treatment (hormonal imprinting) on the later serotonin content of white blood cells

The first encounter between the developing receptor and its target hormone establishes the hormonal imprinting which is needed for the normal function of the cell. In the presence of foreign-however able to bind-molecules, faulty imprinting develops with lifelong consequences. Hormonal imprinting influences not only the receptors, but also the later hormone production of cells. The critical time of hormonal imprinting is the perinatal period, however it can be executed sometimes (in continuously differentiating cells) also at puberty. As in earlier experiments single neonatal serotonin treatment caused a life-long alteration of white blood serotonin content in female rats, the early (10-19 day) and late (8 weeks) effect of single pubertal serotonin treatment was studied presently, by using flow cytometry. In contrast to the earlier (neonatal) results, pubertal treatment caused a radical reduction of serotonin content in male's lymphocytes, monocytes, granulocytes and mast cells, independent on the time of study. The effect in females was rather increasing, however uncertain. The experiments call attention to the possible different effects of neonatal and pubertal hormonal imprinting and to the imprintability of blood cells in adolescence.     

Thymic epithelium in vitro. IV. Regulation of growth and mediator production by epidermal growth factor

The regulation of thymic epithelial cell function has been examined using pure cultures of morphologically distinct thymic epithelial cells and the ubiquitous hormone epidermal growth factor (EGF). Small thymic epithelial cells, TECS, had receptors for EGF with high affinity, Kd = 1.2 X 10(-9) M, and exhibited increased DNA synthesis and increased RNA synthesis upon stimulation with EGF. In addition, incubation of TECS monolayers with EGF resulted in enhanced production of prostaglandin E2. In contrast, large thymic epithelial cells, TECL, did not express receptors for EGF and demonstrated no biological response to the hormone. These results suggest the possibility that intrathymic regulation of lymphoid cells may occur via the action of "nonimmunologic" mediators on thymic epithelial cells. They further suggest the more general possibility that immunologic and nonimmunologic hormonal systems may be linked via intersecting cellular pathways.     

Studies into hormonal imprinting in intact and transformed 3T3 fibroblast cell lines

The cells of the NIH 3T3 fibroblast line responded to primary interaction with insulin by a positive imprinting, i.e. by an increased binding capacity for the hormone on re-exposure. Positive imprinting, although to a lesser degree, was also induced by thyrotropin. However, oncogenic transformation by polyoma virus oncogens resulted in decreased imprinting in both the middle-T-antigen (MT3) and small-T-antigen-expressing (N4) 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.     

The biological basis and clinical significance of hormonal imprinting, an epigenetic process

The biological phenomenon, hormonal imprinting, was named and defined by us (Biol Rev, 1980, 55, 47-63) 30?years ago, after many experimental works and observations. Later, similar phenomena were also named to epigenetic imprinting or metabolic imprinting. In the case of hormonal imprinting, the first encounter between a hormone and its developing target cell receptor-usually at the perinatal period-determines the normal receptor-hormone connection for life. However, in this period, molecules similar to the target hormone (members of the same hormone family, synthetic drugs, environmental pollutants, etc), which are also able to bind to the receptor, provoke faulty imprinting also with lifelong-receptorial, behavioral, etc.,-consequences. Faulty hormonal imprinting could also be provoked later in life in continuously dividing cells and in the brain. Faulty hormonal imprinting is a disturbance of gene methylation pattern, which is epigenenetically inherited to the further generations (transgenerational imprinting). The absence of the normal or the presence of false hormonal imprinting predispose to or manifested in different diseases (e.g., malignant tumors, metabolic syndrome) long after the time of imprinting or in the progenies.     

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.