Methylcholanthrene: a possible pseudosubstrate for adrenocortical 17 alpha-hydroxylase and aryl hydrocarbon hydroxylase

Transplantation of primary bovine adrenocortical cells into scid mice

Bovine adrenocortical cells were transplanted into scid mice, using a small cylinder inserted beneath the kidney capsule. The tissue formed from primary bovine adrenocortical cells replaced the essential functions of the animals' own adrenal glands, which were removed during the cell transplantation procedure. Most adrenalectomized animals bearing transplanted cells survived indefinitely, whereas adrenalectomized control animals died following surgery. Formation of well-vascularized tissue at the site of transplantation was associated with stable levels of cortisol in the blood, replacing the mouse glucocorticoid (corticosterone). Ultrastructurally, the cultured cells before transplantation had characteristics of rapidly growing cells, but tissue formed in vivo showed features associated with active steroidogenesis. We investigated two potentially critical aspects of the procedure: the provision of support for angiogenesis in the transplant by the inclusion of FGF-secreting 3T3 cells with the adrenocortical cells; and the administration of synthetic steroids as a temporary replacement for steroids lost by adrenalectomy. We found that FGF was required for the rapid formation of well-vascularized tissue, whereas steroid administration avoided some early mortality but was not absolutely required. In contrast to transplants formed from clonal cells, which did not usually secrete aldosterone, transplants formed from primary bovine adrenocortical cells, even though derived from the zona fasciculata, secreted aldosterone as well as cortisol.

Suppression of the acquisition of conditioned avoidance behavior in the rat by 3-methylcholanthrene

Repeated treatment with 3-methylcholanthrene (MC; 25 mg/kg body weight, i.p., two times per week, 1 month) in both male and female Wistar rats resulted in decreased performance in two sessions of a two-way active avoidance procedure. In addition, young male rats that were injected repeatedly with MC prepubertally showed diminished acquisition in conditioned avoidance behavior during both sessions. It appears that MC can alter both avoidance acquisition and retention test performance in adult male and female rats, as well as in young males. This effect was not associated with alterations in sex hormone levels. The findings of this study suggest a significant influence of MC on specific mental functions.

Modification of reproductive function in the rat by 3-methylcholanthrene

Repeated exposure of adult female Wistar rats to 3-methylcholanthrene (MC) (25 mg kg(-1) b.w., i.p., 2xwk, 1 mo) was associated with a significant increase in estrus cycle length. In addition, an increased frequency of females with constant diestrus and abnormal cycles was observed. Young females which had been exposed to MC prepubertally or whose parents had been treated with MC before and during mating also demonstrated cycle prolongation and an increased incidence of constant diestrus and abnormal cycles. These changes in female reproductive function were not associated with measurable changes in plasma sex hormone levels. In contrast, MC exposure in adult males was associated with significant reductions in circulating plasma testosterone levels. The present data also suggest that the offspring of parents who had been exposed repeatedly to MC before and during mating are also affected. Although the central nervous system in offspring of MC-treated parents appeared to be intact, their oral body temperature was significantly lower.

Steroid and xenobiotic effects on the adrenal cortex: mediation by oxidative and other mechanisms

Because steroids reach high concentrations within the adrenal cortex, effects of the direct interaction of steroids and cytochrome P450 enzymes are possible and may involve oxidative damage. Steroid pseudosubstrate effects studied in cultured adrenocortical cells show that these effects are probably not mediated by steroid receptors. Release of oxidants during pseudosubstrate interaction with cytochrome P450s may be responsible for loss of enzymatic activity observed; enzyme activity can be protected by cytochrome P450 inhibitors, antioxidants, and lowered oxygen concentration. There may be pathological effects of pseudosubstrates in the adrenal cortex. Cytochrome P450/pseudosubstrate effects could be involved in the aging and death of adrenocortical cells in vivo, and necrosis of the adrenal cortex due to excessive ACTH stimulation or due to the action of adrenolytic chemicals could result from damage by oxygen radicals originating from cytochrome P450s. The possible mechanism of damage to the adrenal cortex by the xenobiotics dimethylbenzanthracene, TCDD, 3-methylcholanthrene, and o', p'-DDD are reviewed.

Replicative senescence and differentiated gene expression in cultured adrenocortical cells

We have used a differentiated endocrine cell type, the adrenocortical cell, to investigate the interrelationship of senescence and differentiation, the effects of the environment on differentiated gene expression, and the interrelationship of differentiated gene expression and proliferation. In bovine adrenocortical cells, expression of some differentiated functions is maintained to very late points in the replicative life span, whereas expression of others is lost at various times prior to senescence. There is clonal variation in the rate and extent of loss of functions. For steroid 17 alpha-hydroxylase, in situ hybridization shows that the observed decline in induction of 17 alpha-hydroxylase mRNA during senescence results from a decline in the fraction of cells expression the gene. Descendants of expressing cells in the primary cell population randomly become nonexpressing. Among clones there is a correlation between the fraction of cells expressing the gene and remaining replicative potential, although several experiments show no direct mechanism linking replicative senescence and 17 alpha-hydroxylase expression. Transfection with SV40 early region genes also dissociates the decline in growth and the change in 17 alpha-hydroxylase expression. SV40 T antigen selectively affects growth; expression of 17 alpha-hydroxylase is stabilized either in the on state, when cells are transfected early in the culture life span, or in the off state, when senescent cells are transfected. Thus, although the switching off of 17 alpha-hydroxylase expression and the loss of replicative potential are independent events, the switching process requires DNA replication. Because the switch is irreversible, changes in replicative potential occurring after the switch-off event do not affect the state of expression of the switched-off gene. Changes in differentiated cell properties and changes in replicative potential may be two facets of a general phenomenon of stochastic changes in gene expression in normal cells during senescence.

Loss of expression of a differentiated function gene, steroid 17 alpha-hydroxylase, as adrenocortical cells senescence in culture

Senescence in cultured adrenocortical cells involves changes in expression of differentiated functions as well as changes in responses to mitogenic stimulation. Steroid 17 alpha-hydroxylase (steroid 17 alpha-monooxygenase, EC 1.14.99.9) is an adrenal-specific enzyme, the expression of which is dependent on the presence of stimulators of cyclic AMP production, such as cholera toxin. Dot-blot hybridization of RNA from bovine adrenocortical cells that had been incubated with cholera toxin showed a marked decline in 17 alpha-hydroxylase mRNA levels as a function of population doubling level, closely paralleling the decline in induction of 17 alpha-hydroxylase enzyme activity. The lower levels of 17 alpha-hydroxylase induction did not result from a requirement for a longer time period for induction or from a specific defect in response to cholera toxin and were not caused by a general failure of enzyme induction in response to cyclic AMP. The decreased growth rate in older cells results from a general decline in response to several growth factors. However, the decline in 17 alpha-hydroxylase induction did not result from a loss of response of the cells to mitogens, since quiescent cells at a low population doubling level showed stimulation of 17 alpha-hydroxylase mRNA by cholera toxin to levels similar to those in nonquiescent cultures and added mitogens either had no effect on 17 alpha-hydroxylase mRNA levels or decreased them. There was, however, a specific posttranscriptional effect of insulin on 17 alpha-hydroxylase. The loss of 17 alpha-hydroxylase induction is unlikely to result from overgrowth of a minority cell type lacking the ability to induce 17 alpha-hydroxylase, because adrenocortical cell clones that had high levels of 17 alpha-hydroxylase induction gave rise to cells with lower levels of induction on subcloning. Thus, loss of 17 alpha-hydroxylase activity in adrenocortical cellular senescence results from a primary failure of accumulation of 17 alpha-hydroxylase mRNA after incubation with the inducing agent.

Physiological and pathological effects of steroids on the function of the adrenal cortex

The adrenal cortex is the site of the synthesis of steroid hormones such as the glucocorticoid cortisol and the mineralocorticoid aldosterone. The pathway of biosynthesis of these steroids from cholesterol involves a sequence of transformations using cytochrome P-450 enzymes which varies within the adrenal cortex as a result of the differential localization of enzymes within the zones. The hypothesis presented here is that as a result of the arrangement of the vasculature in the adrenal gland, high concentrations of steroids may be expected to accumulate and may have autoregulating effects. These may include the following: (1) the normal morphological and functional zonation of the adrenal cortex may be regulated by gradients of steroids in the adrenal cortex; (2) destruction of cytochrome P-450 enzymes on interaction with certain steroids which act as pseudosubstrates may form part of the pathogenesis of some steroidogenic enzyme deficiencies. Under normal conditions, the individual cytochrome P-450s are not rate-limiting for steroidogenesis. Under some pathological conditions, individual cytochrome P-450 enzyme activities may become rate-limiting, with consequent overproduction of precursor steroids, leading to mineralocorticoid or androgen excess.