Calcium Modulation of Acth and Cholera Toxin Stimulated Adrenal Steroid and Cyclic-AMP Biosynthesis

Voltage dependent calcium and potassium currents in Y-1 adrenocortical cells are unresponsive to ACTH

In this report we use both whole cell and perforated patch clamp recording techniques to characterize calcium and potassium channels in Y-1 adrenocortical cells in order to assess their responsiveness to ACTH. Both transient and long-lasting components of an inward calcium current were identified which were similar to T and L-type Ca2+ currents. With Ba2+ as the charge carrier, the transient current activated at voltages more hyperpolarized than -50 mV with V1/2 for activation at -78.1 mV, and for steady state inactivation at -52.3 mV. The L-type current activated at -20 mV, with a V1/2 for activation at -29.9 mV and steady state inactivation at -44.2 mV. Under perforated patch conditions the response was shifted to more depolarized voltages. Both currents were responsive to agents which usually affect T- or L-type Ca2+ currents. The transient current was completely blocked by 50 microM lanthanum or 200 microM nickel and partially blocked by 300 mM amiloride. Cadmium (100 microM) and nifedipine (300 nM) completely blocked the long-lasting current while omega-conotoxin GVIA (1992 nM) inhibited the current by only 20-25%. The agonist, Bay K 8644 was stimulatory at 50 nM. Both transient and sustained outward potassium currents similar to A-type and delayed rectifier currents, respectively, were present. The transient current demonstrated fast activation at voltages more positive than -10 mV, inactivation with continued depolarization and steady state inactivation at V1/2 = -50 mV. The sustained current activated rapidly and had minimal inactivation with continued depolarization. The transient current was blocked by 5 mM 4AP and the sustained by 25 mM TEA. While Y-1 cells contain both calcium and potassium currents similar to those found in other adrenocortical cells, none of the currents were affected by ACTH or AII, secretagogues which stimulate steroidogenesis. These data, combined with the inability of both Ca2+ and K+ channel blockers to alter ACTH-induced steroidogenesis as reported earlier, suggests that neither calcium nor potassium currents are responsive to ACTH in Y-1 cells.

Calcium-dependent protein kinase activity and protein phosphorylation in zones of the adrenal cortex

The guinea pig adrenal cortex is composed of two chromatically distinct concentric zones. The steroidogenic response to ACTH by the two zones is likewise distinct: ACTH stimulates cholesterol side-chain cleavage activity in the outermost zone, but fails to do so in the inner zone. This despite the fact that adenylate cyclase activation by ACTH and cAMP formation are similar for the two zones. To further examine this model, protein kinase activity and protein phosphorylation have been examined. It was found that the cAMP-dependent, Ca2+/phospholipid-dependent, and Ca2+/calmodulin-dependent protein kinase activities were significantly higher in the outer zone than in the inner zone by 70, 60 and 800%, respectively. Although the physiological meaning of a zonal difference in protein kinase activity is not as yet clear, the marked difference in Ca2+/calmodulin-dependent protein kinase activity between the inner and outer zones correlates well with the marked difference in steroidogenesis that exists between the two zones. Of the Ca2+/calmodulin-dependent protein kinases known to exist, there is preliminary evidence to suggest the presence of kinase III in the guinea pig adrenal cortex. Protein phosphorylation induced by the three kinase systems in the two adrenocortical zones revealed notable differences in phosphoprotein patterns. In addition, it was found that exogenous calmodulin was phosphorylated and that the kinase responsible for this was more active in the inner zone.

Calcium, a "third messenger" of cAMP-stimulated adrenal steroid secretion

This study examines the role of extracellular calcium and calcium mobilization from intracellular stores in mediating cAMP-stimulated steroid secretion by rat adrenal glomerulosa cells (GC) and fasciculata cells (FC). When GC were incubated acutely in a calcium-deficient buffer, cAMP failed to significantly increase aldosterone secretion above base line. Aldosterone secretion, however, rose from 17 +/- 2 to 32 +/- 4 ng/10(6) cells (P less than 0.01) as calcium in the medium was increased from 0 to 3.5 mM. In contrast, cAMP-stimulated corticosterone production by FC was not influenced by changes in the external calcium concentration. Lanthanum (10(-4) M), an inhibitor of calcium influx, reduced cAMP-stimulated aldosterone secretion from 69 +/- 10 to 42 +/- 5 ng/10(6) cells (P less than 0.01) but failed to alter cAMP-stimulated fasciculata steroidogenesis. Depletion of intracellular calcium stores, achieved by incubating with EGTA, markedly blunted cAMP-stimulated corticosterone secretion in GC from 666 +/- 126 to 32 +/- 6 ng/10(6) cells (P less than 0.01), and cAMP-stimulated corticosterone secretion in FC from 2,223 +/- 407 to 414 +/- 58 ng/10(6) cells (P less than 0.01). TMB-8, a putative inhibitor of intracellular calcium mobilization, markedly inhibited (P less than 0.01) cAMP-stimulated aldosterone secretion by GC from 469 +/- 31 to 48 +/- 8 ng/10(6) cells and corticosterone secretion by FC from 9,867 +/- 1,821 to 2,832 +/- 586 ng/10(6) cells. These observations suggest that cAMP activation of adrenal steroidogenesis requires the release of calcium from intracellular stores.(ABSTRACT TRUNCATED AT 250 WORDS)

Responses of Y1 adrenocortical tumor cells to o-nitrophenyl sulfenyl ACTH

NPS(o-nitrophenyl sulfenyl)-ACTH stimulated steroidogenesis in Y1 cells to the same maximum level as did ACTH, but with a 60-fold lower potency than the native hormone. NPS-ACTH also stimulated the extracellular accumulation of cAMP in Y1 cells with lower potency than the unmodified hormone. The amount of cAMP accumulated in the presence of NPS-ACTH approached 75% of the maximum with ACTH. In Y1 plasma membranes, NPS-ACTH was a partial agonist of adenylate cyclase activity, witn an efficacy dependent upon the type of guanyl nucleotide present. The steroidogenic responses of two Y1(Kin) mutants and two Y1(Cyc) mutants to NPS-ACTH paralleled their responses to ACTH and reflected closely their defects in cAMP-dependent protein kinase and ACTH-sensitive adenylate cyclase activity. These data imply an obligatory role for adenylate cyclase and cAMP-dependent protein kinase activities in stimulation of steroidogenesis in Y1 cells by NPA-ACTH.

Acute steroidogenic stimulation of cultured adrenocortical tumor cells: an electron microscopic analysis

The addition of ACTH to primary cultures of functional mouse adrenocortical tumor cells results in a marked increase in the production and release of steroids by these cells. The steroidogenic response to ACTH is detectable within minutes and is associated with a 'rounding-up' of the cells. The effects of ACTH were analyzed by scanning, conventional transmission and stereoscopic high voltage electron microscopy. Cell morphology was studied in unstimulated cells, in cells stimulated for 10-15 min in which only partial rounding had occurred, and after 2 hr of continuous stimulation when most of the cells had fully rounded. In unstimulated cultures, bundles of microfilaments (stress fibers) were prominent in cell extensions, subjacent to coated regions of the plasma membrane and frequently in proximity to microtubules and clusters of lysosome-like organelles. As the rounding process commenced, stress fibers disappeared from the cell edges. In 2 hr stimulated cells, Golgi complexes were hypertrophied. There were more microprojections from the plasma membrane than in control cells, as well as evidence of increased pinocytotic activity. There was an apparent polymerization of microtubules in elongated processes extending outward from the bases of the rounded cells and a concentration of lysosome-like organelles in these formations. The possible significance of these changes with respect to the differentiated function of adrenal cells is under continuing investigation in our laboratory.

Improved basal medium for Y-1 mouse adrenal cortex tumor cells in culture. I. Dependence of growth and steroid response on calcium ion concentration

An improved basal medium is presented that required only minimal supplementation with dialyzed fetal bovine serum or bovine serum albumin and fetuin to be comparable to Ham's F-10, which requires 15% horse serum (HS) and 2.5% fetal bovine serum (FBS) for the growth and function of Y-1, mouse adrenal cortex tumor, cells. Cell monolayers maintained for up to 2 weeks without any protein supplementation have retained their steroid response to ACTH. The medium differs from Ham's F-10 in its buffer composition and higher calcium-ion concentration. This medium should be a useful adjunct to studies pertaining to steroid and lipid intermediary metabolism, the retention of a specialized physiological function in a chemically defined medium, and the mechanism of hormonal response.

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.

Steroidogenesis and extracellular cAMP accumulation in adrenal tumor cell cultures

ACTH stimulated steroidogenesis and cAMP (adenosine 3',5'-monophosphate) accumulation in an adrenocortical mouse tumor cell line (clone Y1) with Kd values which differed by more than one order of magnitude (5.2 X 10(-11) M and 7 X 10(-10) M, respectively). All of the cAMP formed in response to added ACTH appeared extracellularly in 5- or 30-min incubations. ACTH, at 5 and 10 muU/ml, stimulated steroidogenesis to 25% and 40% of maximum activity; and increased the extracellular accumulation of cAMP 1.4-fold and 2.3-fold, respectively. The effects of ACTH appeared to be via an action on intracellular ATP, specific for cAMP and dependent on an ACTH-sensitive adenylate cyclase system. These observations indicate that ACTH increases cAMP accumulation in Y1 cells at virtually all steroidogenic concentrations and suggest that cAMP is an essential component of ACTH-stimulated steroidogenesis.

Effects of starvation and Ca++ on glucose-induced accumulation of cyclic 3',5'-AMP in pancreatic islets

Exposure to glucose in the presence of 3-isobutyl-1-methylxanthine leads to accumulation of cAMP in islets microdissected from ob/ob mice. This process is dependent on extracellular Ca++ but differs markedly from the glucose action on insulin release in the same in vitro system in disappearing after 18 h of starvation.