Sage Journals: Discover world-class research

Abstract

Hormonal imprinting is provoked perinatally by the appropriate hormone on its receptor, causing a life-long adjustment of the connection between the two participants. Faulty imprinting is caused by the presence of molecules similar to the hormone in this critical period, which results in a persistent alteration of the receptor. In the present experiment the transgenerational imprinting effect of a steroid-like environmental pollutant, benzpyrene, on the receptor binding capacity of filial thymic dexamethasone and uterine estrogen receptors was studied. The receptor density (B_max) of the thymic glucocorticoid receptors of the males was reduced up to the third (F₂) generation. In females this reduction was observed only in the F₁ generation of treated animals. There was no change in receptor affinity (K_d). Uterine estrogen receptors were not subjected to transgenerational imprinting. The experiments demonstrate (1) the possibility of the transgenerational transmission of imprinting effect, (2) the differences of steroid receptors in different organs, and (3) the differences of male's and female's reactions from this aspect. The results call attention to the dangers of perinatal aromatic hydrocarbon exposition to the progeny generations.

Keywords

hormonal imprinting transgenerational effects aromatic hydrocarbon steroid receptors glucocorticoid receptors estrogen receptors

Get full access to this article

View all access options for this article.

References

Csaba G. Phylogeny and ontogeny of hormone receptors: the selection theory of receptor formation and hormonal imprinting . Biol Rev 1980; 55: 47-63 .

Csaba G. Receptor ontogeny and hormonal imprinting . Experientia 1986; 42: 750-759 .

Csaba G. Interactions between the genetic programme and environmental influences in the perinatal critical period . Zool Sci 1991; 8: 313-825 .

Csaba G. Phylogeny and ontogeny of chemical signaling: origin and development of hormone receptors . Internat Rev Cytol 1994; 155: 1-48 .

Csaba G , Nagy SU. Influence of the neonatal suppression of TSH production (neonatal hyperthyroidism) on response to TSH in adulthood . J Endocrin Invest 1985; 8: 557-559 .

Mirzahosseini S , Karabélyos Cs , Dobozy O , Csaba G. Changes in sexual behavior of adult male and female rats neonatally treated with vitamin D3 . Hum Exp Toxicol 1996; 15: 573-576 .

Gaál A , Csaba G. The effect of neonatal treatment with retinoids (vitamin A or retinoic acid) on the binding capacity of thymic glucocorticoid receptor and uterine estrogen receptor in adult rats . Endocrin Metab 1997; 4: 115-119 .

Tchetnitchin A , Tchernitchin N. Imprinting of paths of heterodifferentiation by prenatal or neonatal exposure to hormones, pharmaceuticals, pollutants and other agents and conditions . Med Sci Res 1992; 20: 391-397 .

Bern HA , Gorski RA , Kawashima S. Longterm effects of prenatal hormone administration . Science 1973; 181: 189-190 .

10.

Bern HA , Jones LA , Mori T , Young PN. Exposure of neonatal mice to steroids: longterm effects on the mammary gland and other reproductive structures . J Ster Biochem 1975; 6: 673-676 .

11.

Bern HA et al. Altered mammary responsiveness to estradiol and progesterone in mice exposed neonatally to diethylstilbestrol . Cancer Lett 1992; 63: 117-124 .

12.

Birnbaum LS. Developmental effects of dioxin . Environ Health Perspect 1995; 103(Suppl 7): 89-94 .

13.

Csaba G , Karabélyos Cs , Dalló J. Fetal and neonatal action of a polycyclic hydrocarbon (benzpyrene) or a synthetic steroid hormone (allylestrenol) as reflected by the sexual behaviour of adult rats . J Dev Physiol 1993; 15: 337-340 .

14.

Gibson DSC , Roberts FA , Ewans GP. Changes in the hormone dependency of epithelial cell proliferation in the genital tract of mice following neonatal oestrogen treatment . Eur J Cancer 1991; 27: 1295-1301 .

15.

Iguchi T. Cellular effects of early exposure to sex hormones and antihormones . Int Rev Cytol 1992; 139: 1-57 .

16.

Newbold R. Cellular and molecular effects of developmental exposure to diethylstilbestrol: implications for other environmental estrogens . Environ Health Perspect 1995; 103(Suppl 7): 83-87 .

17.

Janz DM , Bellward GD. In ovo 2,3,7,8- tetrachlorodibenzo-p-dioxin exposure in three avian species 2. Effects on estrogen receptor and plasma sex steroid hormones during the perinatal period . Toxicol Appl Pharmacol 1996; 139: 292-300 .

18.

Miglaccio S , Newbold RR , McLachlan JA , Korach KS. Alterations in estrogen levels during development affects the skeleton: use of an animal model . Environ Health Perspect 1995; 103(Suppl 7): 95-97 .

19.

Csaba G , Inczefi-Gonda Á. Effect of benzo(a)pyrene treatment of neonatal and growing rats on steroid receptor binding capacity in adulthood . Gen Pharmacol 1984; 15: 557-558 .

20.

Csaba G , Inczefi-Gonda Á. Benzpyrene exposure at 15 days of prenatal life reduces the binding capacity of thymic glucocorticoid receptors in adulthood . Gen Pharmacol 1992; 23: 123-124 .

21.

Csaba G , Inczefi-Gonda Á , Szeberényi Sz. Lasting impact of a single benzpyrene treatment in perinatal and growing age on the thymic glucocorticoid receptors of rats . Gen Pharmacol 1991; 22: 811-815 .

22.

Csaba G , Inczefi-Gonda Á. Uterus estrogen receptors' binding capacity is reduced in rat if exposed by benzpyrene neonatally . J Developm Physiol 1993; 19: 217-219 .

23.

Csaba G , Mag O , Inczefi-Gonda Á , Szeberényi Sz. Persistent influence of neonatal 2,3,7,8-tetrachloro-dibenzo-p-dioxin (TCDD) treatment of glucocorticoid receptors and on the microsomal enzyme system . J Developm Physiol 1991; 15: 337-340 .

24.

Gray Nelson K et al. Exposure to diethylstilbestrol during a critical developmental period of the mouse reproductive tract leads to persistent induction of two estrogen-regulated genes . Cell Growth Diff 1994; 5: 595-606 .

25.

McPherson GA. Analysis of radioligand binding experiments and microcomputing systeme . TIPS 1983; 41: 369-370 .

26.

McPherson GA. Analysis of radioligand binding experiments: a collection of computer programs to the IBM PC . J Pharmacol Methods 1985; 14: 213-228 .

27.

Okey AB , Riddick DS , Harper PA. Molecular biology of the aromatic hydrocarbon (dioxin) receptor . TIPS 1994; 15: 226-232 .

28.

Birnbaum LS. The mechanism of dioxin toxicity: relationship to risk assasment . Environ Health Perspect 1994; 102(Suppl 9): 157-167 .

29.

Campbell JH , Perkins P. Transgenerational effects of drug and hormonal treatments in mammals: a review of observations and ideas . Progr Brain Res 1988; 73: 535-553 .

30.

Milner RGD , Sheffrin RA. Vertical transmission of diabetes in the rat . J Developm Physiol 1982; 4: 39-51 .

31.

Csaba G , Inczefi-Gonda Á , Dobozy O. Hereditary transmission to the F1 generation of hormonal imprinting (receptor memory) induced in rats by neonatal exposure to insulin . Acta Physiol Hung 1984; 63: 93-99 .

32.

Sonderegger T , O'Shea S , Zimmermann E. Progeny of male rats addicted neonatally to morphine . Proc West Pharm Soc 1979; 22: 137-139 .

33.

Fuji T. Inherited disorders in the regulation of serum calcium in rats raised from parathyreoidectomised mothers . Nature 1978; 273: 236-237 .

34.

Marselos M , Tomatis L. Diethylstilbestrol: II, pharmacology, toxicology and carcinogeneity in experimental animals . Eur J Cancer 1992; 29A: 149-155 .

35.

Csaba G , Karabélyos Cs. Transgenerational effect of a single neonatal benzpyrene treatment (imprinting) on the sexual behavior of adult female rats . Hum Exp Toxicol 1997; 16: 553-556 .

Transgenerational effect of a single neonatal benzpyrene treatment on the glucocorticoid receptor of the rat thymus

Abstract

Keywords

Get full access to this article

References