The steroidogenic acute regulatory protein (StAR) has recently been shown to be a factor necessary for cholesterol transport into adrenal and gonadal mitochondria, which is the regulated, rate-limiting step in steroidogenesis. We show here that StAR mRNA is highly expressed in normal adult adrenals (n = 9), adrenocortical adenomas (n = 16), adrenal hyperplasias (n = 6), adrenocortical carcinomas (n = 6) and adrenals adjacent to tumor tissues (n = 9). There was a good correlation between the expression of StAR and the cholesterol side-chain cleavage enzyme/20,22-desmolase (P450 scc) mRNAs both in normal (r = 0.93; P < 0.01) and in tumor (r = 0.97; P < 0.001) tissues. No StAR mRNA was detected in Northern blots of liver, kidney, breast, parathyroid or phaeochromocytoma RNAs. In cultured adrenocortical cells, adrenocorticortropin (ACTH), (Bu)2cAMP, and cholera toxin increased StAR and P450 scc mRNA accumulation 6- to 18-fold, dose- and time-dependently. StAR (and P450 scc) mRNA increased relatively slowly in response to ACTH treatment, with the maximal increment at 24 h, while the mRNA of the early response gene c-fos peaked within 2 h. The protein kinase inhibitor H-7 inhibited basal and ACTH-induced StAR mRNA expression. Our results show that StAR mRNA is expressed at high levels in normal human adrenals and adrenocortical neoplasms. It is up-regulated in parallel with P450 scc by ACTH in adult adrenocortical cells, which suggests that ACTH is at least one of the key regulators of adrenal StAR expression.
Adrenomedullin (ADM) is a polypeptide originally discovered in a human pheochromocytoma and is also present in normal adrenal medulla. It has been proposed that ADM could be involved in the regulation of adrenal steroidogenesis via paracrine mechanisms. Our aim was to find out if ADM gene is expressed in adrenocortical tumors and how ADM gene expression is regulated in adrenal cells. ADM mRNA was detectable by Northern blotting in most normal and hyperplastic adrenals, adenomas and carcinomas. The average concentration of ADM mRNA in the hormonally active adrenocortical adenomas was about 80% and 7% of that in normal adrenal glands and separated adrenal medulla respectively. In adrenocortical carcinomas, the ADM mRNA concentration was very variable, but on average it was about six times greater than that in normal adrenal glands. In pheochromocytomas, ADM mRNA expression was about ten times greater than that in normal adrenals and three times greater than in separated adrenal medulla. In primary cultures of normal adrenal cells, a protein kinase C inhibitor, staurosporine, reduced ADM mRNA accumulation in a dose- and time-dependent fashion (P < 0.01), whereas it simultaneously increased the expression of human cholesterol side-chain cleavage enzyme (P450 scc) gene (a key gene in steroidogenesis). In cultured Cushing's adenoma cells, adrenocorticotropin, dibutyryl cAMP ((Bu)2cAMP) and staurosporine inhibited the accumulation of ADM mRNA by 40, 50 and 70% respectively (P < 0.05), whereas the protein kinase C activator, 12-O-tetradecanoyl phorbol 13-acetate (TPA), increased it by 50% (P < 0.05). In primary cultures of pheochromocytoma cells, treatment with (Bu)2cAMP for 1 and 3 days increased ADM mRNA accumulation two- to threefold (P < 0.05). Our results show that ADM mRNA is present not only in adrenal medulla and pheochromocytomas, but also in adrenocortical neoplasms. Both protein kinase A- and C-dependent mechanisms regulate ADM mRNA expression in adrenocortical and pheochromocytoma cells supporting the suggested role for ADM as an autocrine or paracrine (or both) regulator of adrenal function.
We studied the expression of inhibin alpha-subunit in normal and hyperplastic adrenal glands, as well as in various adrenocortical tumors. The protein expression of inhibin alpha was performed by immunohistochemistry. Virilizing adenomas showed strong immunoreactivity against monoclonal inhibin alpha-subunit antibody, whereas other adenomas were only weakly positive or completely negative. In the adrenal cortex no inhibin alpha immunoreactivity was detected in the zona glomerulosa. Zona fasciculata showed weak staining for inhibin alpha, however, strong immunostaining was detected in zona reticularis both in normal and hyperplastic adrenal glands. Adrenal medulla was negative for inhibin alpha. In conclusion, we show high expression of inhibin alpha subunit in zona reticularis of normal and hyperplastic adrenal glands as well as strong expression in virilizing adenomas.
We have analyzed the expression of the c-myc proto-oncogene in human adrenal glands in vivo and in primary cell cultures by Northern blot analysis. c-myc mRNA was consistently expressed in all human adrenals studied. Expression in adult adrenals was found to be approximately 50% of that in fetal adrenals, but much higher than that in adult liver and kidney. Adrenocorticotropin (ACTH) treatment increased c-myc mRNA accumulation dose- and time-dependently up to more than 5-fold (on average), with the maximal effect at 2 h. (Bu)2cAMP and 12-O-tetradecanoyl phorbol 13-acetate (TPA) also induced c-myc gene expression. There was no synergistic effect between the ACTH, (Bu)2cAMP and TPA treatments. The basal level of c-myc expression was reduced by the protein kinase inhibitors H-7 (1-(5-isoquinolinesulfonyl)-2-methyl-piperazine dihydrochloride), staurosporine and HA1004 (N-(2-guanidinoethyl)-5-isoquinolinesulfonamide hydrochloride). H-7 totally abolished ACTH-, TPA- and (Bu)2cAMP-induced c-myc expression, while staurosporine inhibited the stimulatory effects of ACTH and TPA, and HA1004 weakly inhibited the effects of ACTH and (Bu)2cAMP. Incubation with cycloheximide or 10% fetal calf serum increased c-myc mRNA levels 3- and 4-fold respectively. Our data show that the c-myc gene is expressed abundantly in normal human adrenals, and that this expression can be regulated by multiple factors in the primary cultures.
Abundant c-myc gene expression in neoplasms has been often linked to poor prognosis. As c-myc mRNA is expressed and hormonally regulated in human adrenals, we examined the c-myc gene expression in adrenal tumors by RNA analysis and immunohistochemistry to find out the possible role of c-myc in adrenal neoplasms. The abundant expression of the c-myc gene in normal adrenals was localized to the zona fasciculata and zona reticularis, with much lower expression in the zona glomerulosa and adrenal medulla. In hormonally active adrenocortical carcinomas (n = 6) and in virilizing adenomas (n = 4), c-myc mRNA levels were approximately 10% of those in normal adrenals (n = 11). In contrast, adrenal adenomas from patients with Cushing's (n = 4) and Conn's (n = 9) syndrome, non-functional adenomas (n = 2), adrenocortical hyperplasias (bilateral, n = 5; nodular, n = 4), and non-functional adrenocortical carcinomas (n = 3) expressed c-myc mRNA to the same extent as normal adrenals. The c-myc mRNA abundance in benign adrenal pheochromocytomas (n = 19) was similar to that in normal adrenal medulla. However, in malignant adrenal pheochromocytomas (n = 6), the average c-myc mRNA levels were approximately threefold that in benign adrenal pheochromocytomas. There was a good correlation between c-myc mRNA expression and immunohistochemical reactivity in both normal and pathological adrenal tissues. Southern blot analysis revealed no amplification or rearrangement of the c-myc gene in any of the adrenal tumors. In conclusion, c-myc expression localized to zona fasciculata and reticularis in normal adrenals. Virilizing adenomas and hormonally active adrenocortical carcinomas expressed c-myc mRNA clearly less than the other adrenal neoplasms and normal adrenal tissue. On the other hand, malignant pheochromocytomas contained more c-myc mRNA than benign ones. Further studies are required to clarify the mechanisms and significance for the distinct expression pattern of the c-myc gene in different adrenal neoplasms.
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