The influence of plasma lipoproteins on steroidogenesis of cultured ovine fetal and neonatal adrenal cells

The present study examined the effects of serum and lipoproteins on the function of cultured adrenal cells from 115-127-day-old ovine fetuses and from newborn lambs. On day 1 of culture, corticosteroid output was similar in medium containing 2% horse serum or in serum-free medium, both for fetal and neonatal cells. However, on day 5, cells cultured in the absence of serum produced smaller amounts of these steroids than cells maintained in medium containing serum; the difference was more marked under ACTH1-24 stimulation. Conversely, cAMP production was never lower in the absence than in the presence of serum. When stimulated by ACTH1-24 on day 2 of culture, fetal or neonatal adrenal cells incubated in the presence of a saturating concentration of ovine LDL produced more corticosteroids than cells incubated in serum-free medium; HDL also enhanced ACTH1-24-induced steroidogenesis, but to a lesser extent. VLDL was effective only with neonatal cells. In fetal and neonatal cells cultured for 6 days in ACTH-free medium, VLDL and LDL increased ACTH-induced steroidogenesis, but HDL did not. On the other hand, when cells were cultured in the presence of ACTH1-24, LDL and HDL were equipotent in supporting ACTH1-24-induced steroid output. Three major lipoprotein fractions were observed in serum of fetal and newborn lambs. The concentration of cholesterol was very low in the VLDL fraction of fetuses, but it was similar to that of newborns in LDL. Conversely, 4 times more cholesterol was present in HDL of newborns than in HDL of fetuses. These results suggest that: (i) after several days of cell culture, cholesterol availability is an important limiting factor for the steroidogenesis of cells maintained under serum-free conditions; (ii) both an "LDL pathway" and an "HDL pathway" are operating in adrenal cells from fetal as well as newborn sheep; (iii) LDL and HDL are important physiological sources of cholesterol to support steroidogenesis by fetal and neonatal adrenal cells.     

Factors involved in supporting the growth and steroidogenic functions of bovine adrenal cortical cells maintained on extracellular matrix and exposed to a serum-free medium

Bovine adrenal cortex cells maintained on extracellular matrix (ECM)-coated dishes will proliferate actively when serum is replaced by HDL (25 micrograms protein/ml), insulin (10 ng/ml), and FGF (100 ng/ml). The cells have an absolute requirement for HDL in order to survive and grow. The omission of insulin, FGF, or both results in a slower growth rate and lower final cell density of the cultures. A requirement for transferrin (1 microgram/ml) becomes apparent only when cells have been grown for at least four generations in the absence of serum. Early passage (P1-P3) bovine adrenal cortex cells cultured in serum-free medium responded to ACTH (10(-8)M) with increased 11-deoxycortisol production; this effect was not observed in later passage cells (P7-P15). The cells' ability to utilize LDL-derived cholesterol and to respond to db cAMP (1mM) by increased steroid release was preserved in cells cultured for over 60 generations in the serum-free medium. HDL, although also able to increase steroid production in early-passage cultures exposed to ACTH or to ACTH and dibutyryl cyclic AMP (db cAMP), was 10 fold less potent than LDL. It did not support steroidogenesis in cultures not exposed to these trophic agents. The life span of bovine adrenal cortex cells grown in the serum-free medium on fibronectin (FN)- versus ECM-coated dishes was compared. Cells seeded in serum-containing medium and grown in serum-free medium had a life span of 34 versus 60 generations when maintained on fibronectin- or ECM-coated dishes, respectively. Cells seeded in the complete absence of serum in the serum-free medium on ECM- or fibronectin-coated dishes could be passaged for 26 or 13 generations, respectively. While FGF was an absolute requirement for cells cultured on fibronectin-coated dishes, it was not required when cells were maintained on ECM. These observations demonstrate the influence of the ECM not only in promoting cell growth and differentiation but also on the life span of cultured cells.     

In vitro trophic effects of synthetic ACTH1-24

In vitro trophic effects of adrenocorticotrophin1-24 (ACTH1-24, Synacthen) on adrenal cells were studied, using an in vitro assay system of guinea-pig adrenal segments kept in organ culture. Two separate methods for detecting growth activity were used, namely the measurement of thymidine kinase and a nucleic acid cytophotometric method. Synthetic ACTH was able to induce growth in the adrenal explants at very low concentrations (10-25 fg ml-1). Biphasic dose-response curves were obtained, comparable to those described for other cytochemical bioassays. The principles of this assay system may allow the development of a new bioassay for the measurement of plasma concentrations of ACTH or antibodies mimicking the growth effect of this trophic hormone.     

Differential effects of ACTH or 8-Br-cAMP on growth and replication in a functional adrenal tumor cell line

The effects of ACTH and 8-Br-cAMP on growth and replication of a functional mouse adrenal tumor cell line (Y-1) were investigated. ACTH and 8-Br-cAMP both inhibited DNA synthesis and replication when added to randomly growing cell cultures. ACTH addition and serum deprivation each arrested cells in G₁; an additional point of arrest in G₂ occurred with 8-Br-cAMP. Cells whose growth was arrested in G₁ by ACTH had a significantly larger volume and protein and RNA content compared to cells arrested in G₁ by serum deprivation. When ACTH or 8-Br-cAMP was added with serum to cells arrested by serum deprivation, the wave of DNA synthesis and cell division seen with serum was abolished. ACTH and 8-Br-cAMP had no effect on the serum-induced increases in protein and RNA content, rates of leucine incorporation into protein and uridine incorporation into RNA, and RNA polymerase I activity observed in cells during the pre-replicative period. Partial inhibition of the serum-induced increase in uridine transport occurred. ACTH and cAMP do not appear to inhibit replication by generalized negative pleiotypic effects but rather to inhibit the initiation of DNA synthesis more specifically. The ACTH-arrested Y-1 cell resembles an in vivo hypertrophied adrenal cortical cell.     

Sensitivity of the fetal rat pituitary-adrenal system to corticotropin-releasing factor in organ culture.

Six groups of adrenal glands from 17-day fetal rats were explanted to organ culture for 2 days. In one group, adrenal gland was cultured alone, and in the remaining five groups adrenal gland was cultured with pituitaries from fetuses ranging in age from 14 to 18 days. In each of the groups, half of the cultures had corticotropin-releasing factor (CRF) added to the medium. A histometric parameter utilized the size of adrenocortical cells as an indicator of sensitivity of the pituitary-adrenal system. When 17-day adrenal gland was cultured alone, addition of CRF did not cause any enlargement of cortical cells. When the adrenal gland was cultured with two 14-day pituitaries, cortical cells were enlarged. Addition of CRF to this culture induced no further change. With two 15-day pituitaries in the presence of CRF, cortical cells were slightly larger than those in the absence of CRF. With 16- to 18-day pituitaries, a marked hypertrophy of cortical cells was induced, and the addition of CRF caused further acceleration in their enlargement. These results suggest that, in organ culture, 14-day pituitary can release some adrenocorticotropic hormone (ACTH) with or without additional CRF. Older pituitaries (16- to 18-day) can apparently release an amount of ACTH in the presence of CRF that is greater than their own spontaneous ACTH secretion.     

Adrenocorticotropin-induced unresponsiveness in cultured adrenal tumor cells.

Our results demonstrate that adrenocorticotropin (ACTH)-induced refractoriness occurs in cultured adrenal tumor cells. Cells became 85% refractory to ACTH-induced cyclic AMP formation in 20 min and the effect persisted if the hormone remained in the incubation medium. Refractory cells gradually regained hormone-specific responsiveness within 24 h if cultures were incubated in fresh media containing serum. The observed effect is hormone specific since cyclic AMP could not induce unresponsiveness to ACTH. The addition of ACTH plus inhibitors of protein synthesis partially reversed hormone-specific refractoriness. However, preincubation with cycloheximide or diphtheria toxin led to superinduction of ACTH-induced cyclic AMP formation. These experiments suggest that unresponsiveness, following hormonal activation of adrenal cells, may be related to a decrease in hormone-specific binding sites or to synthesis of an adenylate cyclase inhibitor.     

Adrenocorticotropin-induced unresponsiveness in cultured adrenal tumor cells

Our results demonstrate that adrenocorticotropin (ACTH)-induced refractoriness occurs in cultured adrenal tumor cells. Cells became 85% refractory to ACTH-induced cyclic AMP formation in 20 min and the effect persisted if the hormone remained in the incubation medium. Refractory cells gradually regained hormone-specific responsiveness within 24 h if cultures were incubated in fresh media containing serum. The observed effect is hormone specific since cyclic AMP could not induce unresponsiveness to ACTH. The addition of ACTH plus inhibitors of protein synthesis partially reversed hormone-specific refractoriness. However, preincubation with cycloheximide or diphtheria toxin led to superinduction of ACTH-induced cyclic AMP formation. These experimens suggest that unresponsiveness, following hormonal activation of adrenal cells may be related to a decrease in hormone-specific binding sites or to synthesis of an adenylate cyclase inhibitor.     

Effects of several pro-opiomelanocortin derived peptides on steroidogenesis in ovine and bovine adrenal cells

The effects of several peptides derived from the amino-terminal end of proopiomelanocortin (N-POMC) alone or in combination with ACTH on ovine and bovine adrenal cell steroidogenesis have been studied. Neither porcine N-POMC1-61 amide, nor gamma 3-MSH, nor been studied. Neither porcine N-POMC1-61 amide, nor gamma 3-MSH, nor Lys-gamma 3-MSH alone had any steroidogenic effect while porcine N-POMC1-80 alone had a week but significant steroidogenic effect on isolated adrenal, the effect being more pronounced on cultural adrenal cells. The potentiation by N-POMC peptides of the steroidogenic action of ACTH was investigated using both freshly isolated and cultured adrenal cells. At 10(-8) M N-POMC1-61 amide, gamma 3-MSH and Lys-gamma 3-MSH did not modify the ACTH dose-response for steroids (gluco- and mineralocorticoids) and cAMP production. Likewise, the stimulatory effect of 10(-12) M ACTH was not modified by increasing concentrations (10(-11) to 10(-8) M) of N-POMC1-61 amide or gamma 3-MSH. On the other hand, an additive effect of 10(-8) M N-POMC1-80 on the steroidogenic action of low concentration of ACTH was observed. This again was more pronounced in cultured adrenal cells. The same effects were observed when increasing concentrations of this peptide (10(-9) and 10(-8) M) were added together with 10(-12) M ACTH. This result indicates that the potentiating effects of N-POMC derived peptides on the steroidogenic effect of ACTH which has been described on rat and human adrenal, is not a general phenomenon in mammals.     

In vitro studies of nuclear volume of rat adrenocortical cells: lace of ACTH effect

The effect of ACTH on nuclear volume of adrenocortical cells in the zona fasciculata of rat adrenal cortex was examined in vitro. Sections of adrenal gland were incubated for 60 or 90 min in Krebs-Ringer's solution with 1% glucose in the presence of ACTH, actinomycin D, cycloheximide and aminoglutethimide. ACTH, despite its clear effect in stimulating steroidogenesis, did not exert a direct effect on the nuclear volume of cells studied. This phenomenon is not dependent upon the stimulation of steroidogenesis, since aminoglutethimide does not influence the nuclear volume of adrenocortical cells studied; rather, ACTH in the presence of aminoglutethimide leads to a decrease in their volume. Actinomycin D does not influence nuclear volume while after incubation with cycloheximide nuclei were larger than the control. The presence of ACTH did not alter this effect. These results indicate no relationship between the degree of corticosterone output and nuclear volume in rat adrenocortical cells of the zona fasciculata in vitro.     

ACTH and growth hormone relationship in fetal rat adrenal steroidogenesis in vitro.

The effects of growth hormone and ACTH, alone or in combination, on fetal rat adrenal steroidogenesis in vitro were examined on the last day of intrauterine development. ACTH increased, while growth hormone did not affect fetal adrenal weight. ACTH increased fetal rat adrenal steroidogenesis, hydroxylation of 4-14C-progesterone to corticosterone, 18-hydroxy-11-deoxycorticosterone, 11-hydroxycorticosterone and aldosterone. Growth hormone alone had no effect on fetal adrenal steroidogenesis. ACTH and growth hormone administered together increased the conversion of progesterone to the above mentioned steroids to a greater extent than ACTH alone. The results indicate that growth hormone may participate in the fetal rat adrenal steroidogenesis potentiating the effects of fetal pituitary ACTH.     

The ultrastructure of functional mouse adrenal cortical tumor cells in vitro.

Cells derived from a transplantable mouse adrenal cortical tumor maintain their differentiated function in vitro and secrete steroids in response to ACTH and other stimulatory agents. The cell line has been widely employed for various biochemical investigations but there have been few attempts to correlate this work with morphologic data. This communication describes the electron microscopic appearance of the tumor transplant in vivo and primary cultures derived from it at various intervals after the cells are placed in culture. Tumor cells in vivo bear considerable resemblance to normal adult mouse adrenal cortical cells. Organelles generally considered to be directly involved in steroid biosynthesis (mitochondria, smooth endoplasmic reticulum and lipid droplets) are not drastically altered. Certain modifications of the vasculature and cell membrane, seemingly related to steroidogenesis, are present in both the tumor and normal adrenal cortex. Within 2 days after the tumor cells are introduced to culture, their cytoplasm assumes a more simplified appearance. Smooth endoplasmic reticulum is less conspicuous and free ribosomes and polysomes are very abundant. Mitchondrial inner membranes are reorganized from a saccular arrangement in the cells in vivo into distinct lamellar cristae. The tumor cells now resemble undifferentiated embryonic adrenal cells, or cultured adrenal cells from various mammalian sources which have dedifferentiated in the absence of ACTH. In their morphologically unspecialized state, the normal cells are incapable of functional responses to ACTH. In contrast, the cultured, dedifferentiated tumor cells respond within minutes to this hormone and can demonstrate 5-20 fold increases in their basal steroid output. These data suggest that substantial steroidogenic activity can occur although the characteristic appearance of adrenal mitochondria is absent.     

The Ultrastructure of Functional Mouse Adrenal Cortical Tumor Cells in vitro

Cells derived from a transplantable mouse adrenal cortical tumor maintain their differentiated function in vitro and secrete steroids in response to ACTH and other stimulatory agents. The cell line has been widely employed for various biochemical investigations but there have been few attempts to correlate this work with morphologic data. This communication describes the electron microscopic appearance of the tumor transplant in vivo and primary cultures derived from it at various intervals after the cells are placed in culture. Tumor cells in vivo bear considerable resemblance to normal adult mouse adrenal cortical cells. Organelles generally considered to be directly involved in steroid biosynthesis (mitochondria, smooth endoplasmic reticulum and lipid droplets) are not drastically altered. Certain modifications of the vasculature and cell membrane, seemingly related to steroidogenesis, are present in both the tumor and normal adrenal cortex. Within 2 days after the tumor cells are introduced to culture, their cytoplasm assumes a more simplified appearance. Smooth endoplasmic reticulum is less conspicuous and free ribosomes and polysomes are very abundant. Mitochondrial inner membranes are reorganized from a saccular arrangement in the cells in vivo into distinct lamellar cristae. The tumor cells now resemble undifferentiated embryonic adrenal cells, or cultured adrenal cells from various mammalian sources which have dedifferentiated in the absence of ACTH. In their morphologically unspecialized state, the normal cells are incapable of functional responses to ACTH. In contrast, the cultured, dedifferentiated tumor cells respond within minutes to this hormone and can demonstrate 5–20 fold increases in their basal steroid output. These data suggest that substantial steroidogenic activity can occur although the characteristic appearance of adrenal mitochondria is absent.     

Infusion of ACTH stimulates expression of adrenal ACTH receptor and steroidogenic acute regulatory protein mRNA in fetal sheep

The late-gestation plasma cortisol surge in the sheep fetus is critical for stimulating organ development and parturition. Increased adrenal responsiveness is one of the key reasons for the surge; however, the underlying mechanisms are not fully understood. Our recent studies suggest that ACTH-mediated increased expression of ACTH receptor (ACTH-R) and steroid acute regulatory protein (StAR) may play a role in enhancing responsiveness. Hence, we examined effects of ACTH infusion in fetal sheep on mRNA expression of these two mediators of adrenal responsiveness and assessed the functional consequences of this treatment in vitro. Fetuses of approximately 118 and 138 days of gestational age (dGA) were infused with ACTH-(1-24) for 24 h. Controls received saline infusion. Arterial blood was sampled throughout the infusion. Adrenals were isolated and analyzed for ACTH-R and StAR mRNA, or cells were cultured for 48 h. Cells were stimulated with ACTH, and medium was collected for cortisol measurement. Fetal plasma ACTH and cortisol concentrations increased over the infusion period in both groups. ACTH-R mRNA levels were significantly higher in ACTH-infused fetuses in both the 118 and 138 dGA groups. StAR mRNA increased significantly in both the 118 and 138 dGA groups. Adrenal cells from ACTH-infused fetuses were significantly more responsive to ACTH stimulation in terms of cortisol secretion than those from saline-infused controls. These findings demonstrate that increases in circulating ACTH levels promote increased expression of ACTH-R and StAR mRNA and are coupled to heightened adrenal responsiveness.     

Effects of chronic noise or daily water restriction on the pituitary-adrenal axis in male rats

Pituitary-adrenal function was studied in male rats chronically stressed with noise as well as under water restriction regimen. Chronic noise did not modify either in vivo or in vitro corticoadrenal function. Daily water restriction decreased body weight and increased relative adrenal weight as well as the serum levels of ACTH and corticosterone. In vitro corticoadrenal responsiveness to ACTH was similar in control and water restricted rats. Thus, no evidence for increased adrenal sensitivity to ACTH in the pre-watering period was found in water restricted rats.     

Maintenance of cell proliferation and steroidogenesis in cultured human fetal adrenal cells chronically exposed to adrenocorticotropic hormone: rationalization of in vitro and in vivo findings

Previous studies indicated that acute exposure of adrenal cells to adrenocorticotropic hormone (ACTH) markedly stimulates steroidogenic capacity in vitro but also inhibits cell proliferation. However, in vivo, ACTH is known to stimulate adrenal cell growth. To address this discrepancy, we determined the effect of long-term (9-11 days) continuous or intermittent exposure to ACTH on human fetal adrenal cell proliferation and steroidogenesis. Adrenal glands from fetuses 18-22 wk gestation were studied. Fetal zone cells were plated either on plastic or on an extracellular matrix (ECM) in the presence and absence of basic fibroblast growth factor (bFGF) (0.5 ng/ml) and 1 or 10 nM ACTH. As determined by cell counting, bFGF stimulated cell proliferation during 9 days in culture. In the presence of bFGF, the average doubling time decreased from 44 to 30 h on plastic and from 37 to 26 h on ECM. Under these conditions, ACTH did not inhibit cell proliferation. Proliferation of fetal adrenal corticosteroid-producing cells in the ACTH-treated cultures also was assessed by histochemical staining for 3 beta-hydroxysteroid dehydrogenase (3 beta HSD). The number of positive cells increased more than 4-fold between Days 5 and 9 in culture. Continuous treatment with 1 nM ACTH increased dehydroepiandrosterone sulfate (DHAS) production 5- to 10-fold during the first 5 days in culture. Thereafter, the stimulated hormone production decreased over time, although there was still a difference of almost 100-fold between the control and ACTH-treated cultures at the end of 9 days.(ABSTRACT TRUNCATED AT 250 WORDS)     

18-Ethynyl-deoxycorticosterone inhibition of steroid production is different in freshly isolated compared to cultured calf zona glomerulosa cells

The inhibiting effects of 18-ethynyl-deoxycorticosterone (18-E-DOC) as a mechanism-based inhibitor on the late-steps of the aldosterone biosynthetic pathway were examined in calf adrenal zona glomerulosa cells in primary culture and in freshly isolated calf zona glomerulosa cells. 18-E-DOC inhibited the stimulated secretion of aldosterone and 18-hydroxycorticosterone in a similar dose-response and time fashion. No significant differences were found between the inhibition in cultured and freshly isolated cells (K_i of 0.25 vs 0.26 μM) Corticosterone secretion stimulated by ACTH or angiotensin II was also cultured in freshly isolated zona glomerulosa and fasciculata cells, but was not inhibited in cultured calf adrenal cells. Cortisol secretion stimulated by ACTH was not inhibited by 18-E-DOC in cultured zona fasciculata adrenal cells, but was inhibited in freshly isolated zona fasciculata cells with a K_i of 48 μM. The secretion of 18-hydroxyDOC or 19-hydroxyDOC stimulated by ACTH was not inhibited by 18-E-DOC. The bovine adrenal has been reported to have cytochrome P-450 11β-hydroxylases that can perform the various hydroxylations required for the synthesis of cortisol and aldosterone in the different areas of the adrenal. In other species a distinct 11β-hydroxylase which participates in the biosynthesis of aldosterone and is located in the zona glomerulosa has been described. These studies with the mechanism-based inhibitor, 18-E-DOC, suggest that the bovine adrenal functions in a manner very similar to that of other species and raises the possibility that a distinct 11β-hydroxylase with aldosterone synthase activity might be present, but has not been cloned as yet.     

Effect of temperature during preparation of rat adrenal quarters and isolated cell suspension of their ACTH responsiveness.

The effect of temperature during preparation of rat adrenal quarters or isolated adrenal cell suspension on their response to ACTH was examined through a comparison of amounts of corticosterone produced after their incubation. The response to ACTH added in vitro was considerably higher when adrenal quarters and isolated adrenal cell suspension were prepared at room temperature (25 degree C) than when prepared at ice-cold. Endogenous steroidogenesis was not affected by the temperature. It seemed unlikely that this higher response to ACTH of adrenal quarters or isolated adrenal cell suspension prepared at room temperature was due to an activation of the cells. A possibility was discussed that cooling adrenal quarters or isolated adrenal cell suspension during the preparation may create an unphysiological state in some place to related the cell membrane.     

Hormonal regulation of insulin-like growth factor I secretion by bovine adrenal cells

The role of insulin-like growth factor I (IGF-I) on the specific function of several steroidogenic cells has been recently reported. Since IGF-I is produced by several tissues, we have investigated whether bovine adrenal cells secrete this peptide. Purification of conditioned medium from adrenal cells incubated with [35S]methionine through affinity chromatography (monoclonal anti-IGF-I antibody), high pressure liquid chromatography, and polyacrylamide gel electrophoresis revealed a single band of similar Mr as pure recombinant IGF-I. Moreover, the purified adrenal-secreted IGF-I displaced bound 125I-IGF-I to its adrenal receptors, and pretreatment of adrenal cells with the purified peptide enhanced the acute corticotropin (ACTH)-induced cAMP production as recombinant IGF-I. The basal secretion of IGF-I (6 +/- 1 ng/48 h/10(6) cells) was stimulated 3-, 4.5-, and 9.5-fold by fibroblast growth factor, angiotensin II (A-II), and ACTH, respectively, but not by growth hormone. The stimulatory effects of A-II and ACTH were dose-dependent (ED50 congruent to 2.5 x 10(-8) and 1.5 x 10(-10) M, respectively), and the effects of both hormones were additive. Glucocorticoids were not the mediators of the effect of the two hormones on IGF-I secretion, since inhibition of their steroidogenic action by aminoglutethimide did not significantly modify IGF-I secretion. An immunoreactive IGF-I material was also secreted by mouse adrenal tumor cell line Y-1, but the stimulatory effect of ACTH was only 2-fold, and there was no effect of A-II. Since bovine adrenal cells contain specific IGF-I receptors and this peptide is required for the maintenance of some adrenal cell-specific function, the present data suggest that IGF-I may act in an autocrine fashion to stimulate adrenal cell differentiation stimulated by ACTH and A-II.     

Vasopressin: a potent growth factor in adrenal glomerulosa cells in culture

Previous studies have shown that vasopressin stimulates the mitotic activity in adrenal zona glomerulosa cells in intact as well as in hypophysectomized rats. (Payet and Isler, Cell and Tissue Res. 172, 1976; Payet and Lehoux, J. steroid Biochem. 12, 1980). We now report that this effect is direct and specific, since vasopressin stimulates the mitotic activity of rat adrenal zona glomerulosa cells in primary cultures. These cells were prepared by dissociation with collagenase in the culture medium MEM-d-Valine. Isolated cells were placed in 3.5 diameter petri dishes in MEM-d-valine medium containing 15% fetal calf serum and antibiotics for two days and 5% fetal calf serum for subsequent cultures. The medium was changed at 24 hr intervals. The hormones were added 3 days after the culture was started. The mitogenic effect of vasopressin was found to be dependent both on time and hormone concentrations. Vasopressin (10(-11) M) stimulated thymidine incorporation 4.8 +/- 0.6-fold after 2 days of treatment and 5.3 +/- 1.6-fold after 8 days. When ACTH (10(-11) M) was added together with vasopressin (10(-11) M) the mitogenic effect was enhanced at 6.5 +/- 1.9-fold after 2 days and 12.9 +/- 6.9-fold after 8 days of treatment. The aldosterone and corticosterone outputs were also stimulated by the combined presence of vasopressin and ACTH in the incubation medium; a maximal effect was observed between 6 and 8 days of treatment. Vasopressin (10(-11) M) + ACTH (10(-11) M) stimulated the aldosterone output 7-fold and that of corticosterone by 18-fold. When added alone, vasopressin, as well as ACTH alone had only a small effect on the aldosterone output. However, ACTH alone stimulated the corticosterone output 10-fold. In conclusion, vasopressin is an important and specific growth factor of the adrenal zona glomerulosa cells. In addition, together with ACTH vasopressin stimulates the aldosterone and corticosterone output both in vivo and in vitro in primary cell cultures.