Cytoskeletal changes accompanying ACTH-induced steroidogenesis in cultured embryonic adrenal gland cells from the Pekin duck

Summary Cells derived from the adrenal glands of duck embryos immediately prior to hatching were grown in culture and used to study the morphological and cytoskeletal changes and steroidogenic responses induced by 1–24 ACTH. Changes in the cytoskeletal components were observed by rhodamine-phalloidin staining for actin and by staining the tubulin immunoreactive components with FITC. The cultures were comprised of a small population of chromaffin cells and a larger population of steroidogenic cells. The chromaffin cells were distinguished by their tyrosine hydroxylase immunoreactivity. The steroidogenic cells were characterized by the presence of sudanophilic lipid droplets, numerous mitochondria, abundant smooth endoplasmic reticulum, microtubules distributed as a fairly even network throughout the cytoplasm, and microfilaments that formed an extensive and elaborate system of stress fibers with many parallel arrays. The cells readily responded to stimulation with ACTH by releasing corticosterone, aldosterone and deoxycorticosterone. Stimulation with ACTH also induced changes in both the cell morphology and the cytoskeleton. Exposure of the cells to Krebs-Henseleit buffer containing 1–24 ACTH caused them to form numerous fine filopodia, to lose their stress fibers, and to form a thick ring of actin at the periphery of the cell. In addition, many cells became extremely arborized with many long branched dendritic processes. The morphological changes appeared to be related to a redistribution of the actin components, and may be explained only in part by the rounding up or retraction of the cytoplasm. The results strongly suggest an involvement of the actin components of the cytoskeleton in the steroidogenic response to corticotropic stimulation.     

Structural and functional characteristics of primary cell cultures derived from the adrenal gland tissue of neonatal mallard ducklings (Anas platyrhynchos)

Summary Primary cell cultures were prepared from the adrenal glands of one-day-old mallard ducklings (Anas platyrhynchos). The cells attached equally well to uncoated plastic and glass surfaces and on surfaces that had been coated with collagen. The phase of logarithmic growth occurred between the second and the fourth day, and the cells became confluent between the fifth and the sixth day. Staining with Sudan black B and toluidine blue and viewing fixed preparations by transmission electron microscopy indicated that the cultures consisted mostly of steroidogenic cells. A smaller population of chromaffin cells was also present. Scanning electron microscopy showed that most of the cells had long filopodia, and some cells had numerous surface blebs that were interpreted as exocytotic vesicles. When incubated in Krebs-Henseleit buffer containing 1–24 ACTH the cultured cells released three corticosteroids, namely, corticosterone, aldosterone and deoxycorticosterone. These responses occurred within 15 min of exposure to medium containing 1–24 ACTH and continued throughout a 60-min period of continuous stimulation. The minimally effective concentration of 1–24 ACTH was 0.078 ng per ml (0.0234 nM) and, as the concentration was increased up to 10 ng per ml (2.99 nM), the total output of each hormone during the 60-min incubation period increased significantly according to the following semi-logarithmic relationship: Y=a+b log X, where Y=the total output of hormone, X=the concentration of 1–24 ACTH in the medium, and a=the total output of hormone when the medium contained 1.0 ng of 1–24 ACTH per ml. The total outputs of each hormone in the presence of a maximally effective concentration of 1–24 ACTH, however, were low compared to the responses of similarly stimulated tissue slices taken from the neonatal duckling. It is concluded that most of the cells comprising the confluent cultures were derived from steroidogenic cells in the neonatal adrenal. These cells appeared to retain corticotropin receptors during the course of developing into confluent monolayers, but their diminished steroidogenic capacity to respond when stimulated maximally suggests that some generational changes may have occurred.This work was supported by grants to James Cronshaw and W.N. Holmes from the University of California Committee on Research and the National Science Foundation (DIR-8820923), Washington, DC, USA     

The structural organization and the steroidogenic responsiveness in vitro of adrenal gland tissue from the neonatal mallard duck (Anas platyrhynchos)

Summary The adrenal steroidogenic tissue of the neonatal mallard duckling is differentiated into an outer subcapsular zone where the cells contain many large lipid droplets, and an inner zone in which the cells appear to contain less lipid. The cells in both zones contain numerous mitochondria and an abundance of smooth endoplasmic reticulum, and their interdigitating plasma membranes possess many filipodia, coated pits and desmosome-like junctions. Islands of chromaffin cells are distributed throughout the steroidogenic tissue. Two types of chromaffin cell are present, one with vesicles containing densely staining material and the other more lightly staining material. Non-myelinated preganglionic fibers synapse with the chromaffin cells and the axonal terminals contain two types of dense-cored vesicles as well as acetylcholine-containing vesicles. The basal rates of corticosterone (B) and aldosterone (Aldo) release from tissue superfused with buffer containing no secretogogue were low and almost equal (B: Aldo=1.25); the corresponding rate of deoxycorticosterone (DOC) release was less than one-fortieth of the rates of B and Aldo release. The addition of 1–24 ACTH to the medium caused the rate of release of each hormone to increase as a semi-logarithmic function of the concentration and the induced increase in B release was always significantly higher than that of Aldo (B: Aldo=4.8). The corticotropin-induced rates of B and Aldo, but not DOC, release reflected do novo hormone synthesis. Norepinephrine, epinephrine and dopamine each suppressed the basal rates of B and Aldo release, but had no effect when the medium contained 1–24 ACTH. Acetylcholine (ACh) similarly suppressed the basal rates of hormone release, and neither suppressed nor enhanced the responses to medium containing 1–24 ACTH. The suppressive effects of the catecholamines and ACh were not dose-related. [Asp¹, Val⁵] angiotensin II induced significant semi-logarithmic dose-dependent increases in Aldo synthesis but had no effect on the release of either B or DOC.This work was supported by grants to J. Cronshaw and W.N. Holmes from the University of California Committee on Research and the National Science Foundation (DIR-8820923), Washington, D.C., USA     

Functional differences between two structurally distinct types of steroidogenic cell in the avian adrenal gland

Summary There are two regions of steroidogenic cells in the duck adrenal gland. An outer, subcapsular zone (SCZ), consisting of cells with irregularly shaped nuclei, shows relatively little smooth endoplasmic reticulum and mitochondria with shelf-like cristae. This region surrounds the inner zone (IZ) of the gland which is comprised of smaller cells with rounded nuclei, a more abundant smooth endoplasmic reticulum and mitochondria with tubular cristae. When samples of tissue from these distinct regions of the gland are superfused in vitro with media containing concentrations of 1–24 ACTH ranging from 100 to 1000 ng per ml (0.034 to 0.34 M) the steroidogenic cells in both zones release corticosterone in a dose-dependent manner. The dose-responsiveness of both the SCZ and the IZ cells over this range is a complex quadratic function of the 1–24 ACTH concentration in the medium and the semilogarithmic linear portions of the dose-response curves are restricted to a narrow midrange of ACTH concentrations. Throughout the dose-response range, however, the steroidogenic cells of the IZ are more responsive to corticotropic stimulation than are the cells of the SCZ. The cells of the two zones are further distinguished by their responses to a challenge for a second time with medium containing 1–24 ACTH; the responses of the IZ cells to a second challenge were greater than those of the SCZ cells, and at a high concentration of ACTH the SCZ slices showed no significant second response.This work was supported by a grant from the National Science Foundation (PCM 79-15777) to James Cronshaw and W.N. Holmes     

The effects of colchicine,vinblastine and cytochalasins on the corticotropic responsiveness and ultrastructure of inner zone adrenocortical tissue in the Pekin duck

Tissues slices superfused with medium containing no ACTH released only traces of corticosterone. Addition of ACTH to the medium caused the rate of corticosterone release to increase to a maximum about 45 min after the addition of ACTH, after which time it either remained constant or started to wane slightly. The rate of release was affected by tissue thickness; the maximum rate of corticosterone release occurred when the tissue slices were 200 microns. Stimulated adrenocortical cells had large spherical nuclei, numerous mitochondria with tubular cristae, numerous lipid droplets, and a large amount of smooth endoplasmic reticulum. Many cells had an extensive network of microfilaments adjacent to the plasma membrane and some microtubules. Prolonged superfusion caused degenerative changes in some of the cells. Both cytochalasin B and cytochalasin D, dissolved in DMSO before addition to the superfusion medium, inhibited the corticotropic responsiveness in a dose-dependent manner. Control tissue samples superfused with medium containing DMSO, but no ACTH and no cytochalasin, released significantly more corticosterone than corresponding unstimulated samples. Few or no microfilaments were observed in adrenocortical cells after treatment with cytochalasin. Neither colchicine nor vinblastine had any discernible effect on the corticotropic responsiveness. After treatment with colchicine, adrenocortical cells had an ultrastructure characteristic of inner zone stimulated cells except that they were mainly devoid of microtubules.     

Aldosterone biosynthesis induced by ACTH and angiotensin II in newborn rat adrenocortical cells transfected by c-EJ-Ha-ras oncogene.

Adrenocortical cells were obtained by fractionated trypsination of newborn rat adrenal glands and transfected with a plasmid containing the EJ/T24-Ha-ras oncogene. Isolation of adhesive cells led to a proliferative cell line with an overexpression of 21 kDa ras protein. These cells incubated with corticosterone or deoxycorticosterone as the precursor produced a high level of 18-hydroxycorticosterone and aldosterone as identified by gas chromatography- mass spectrometry. ACTH and angiotensin II increased the basal production of aldosterone nineteen-fold and six-fold respectively. Under ACTH stimulation the ratio between aldosterone and 18-hydroxycorticosterone production was 1:3. The transformation of corticosterone under angiotensin II stimulation yielded up to 41% of 18-hydroxycorticosterone (4.7 micrograms/mg of cell protein per 24h) and 4.4% of aldosterone (0.5 microgram/mg of cell protein per 24h) in a low potassium concentration medium (6 mmol/l). To our knowledge this is the first report of continuous proliferative adrenocortical cells producing aldosterone.     

Melanotropins: aldosterone- and corticosterone-stimulating activity in isolated rat adrenal cells

Stimulation of corticosterone and aldosterone production in rat adrenal decapsular and capsular cells respectively by alpha- and beta-melanotropins (alpha- and beta-MSH) have been investigated. Although they are considerably less potent than corticotropin (ACTH), the dose-response curves are parallel to those for ACTH except in the case of aldosterone stimulation by beta-MSH where the dose-response curve is biphasic. The steroidogenic actions of ACTH, beta-MSH and alpha-MSH are antagonized by corticotropin-inhibiting peptide in both capsular and decapsular cells. A synthetic analog of beta-MSH ([Gly10]-betac1-MSH) inhibits both beta-MSH and ACTH in aldosterone output in capsular cells, but it does not inhibit their corticosteroidogenic actions in decapsular cells.     

Effects of ACTH-(11-24) on the corticosteroid production of isolated adrenocortical cells

The steroidogenic action of ACTH-(11-24) was studied on isolated zona glomerulosa and zona fasciculata cells dispersed by collagenase. ACTH-(11-24) stimulated the corticosterone production of zona fasciculata cells and the aldosterone production of zona glomerulosa cells; in addition, it potentiated the effects of ACTH-(1-39) on both cell systems. It is suggested that the ACTH molecule contains more active sites for steroidogenesis than usually acknowledged, as has been found for lipolysis and behavior.     

Secretion of aldosterone and corticosterone by the adrenals of Brattleboro rats in response to ACTH administration

The secretions of aldosterone and corticosterone in response to administration of 0,5 mUI of (1,24) ACTH (synacthène-Ciba) were measured in the adrenal venous blood of 15 Brattleboro female rats genetically lacking vasopressin and in 15 Long-Evans female rats, pretreated with dexamethasone. The secretions of aldosterone and corticosterone increased according to a similar profile in the two groups of animals: maximum values were 20-30 min. after ACTH injection; however the steroidogenic secretion of the adrenal cortex was always about 50% less in the Brattleboro female rats than in Long-Evans female rats. This result suggests mainly that vasopressin may be involved in the mechanisms which control the in vivo production of aldosterone by the adrenal glomerulosa cells.     

Structure-activity relationships of monomeric and dimeric synthetic ACTH fragments in perifused frog adrenal slices

The effect of synthetic monomeric and dimeric ACTH fragments on spontaneous and ACTH(1-39)-evoked steroidogenesis in frog interrenal tissue was studied in vitro. Infusion of ACTH fragment 11-24 (10(-6) M) or its dimeric conjugates, attached either by their N-terminal, Glu(11-24)2, or their C-terminal amino acid, (11-24)2Lys, had no effect on the spontaneous release of corticosteroids. The monomer ACTH(11-24) and the dimer Glu(11-24)2 were also totally devoid of effect on the steroidogenic response to ACTH(1-39) (10(-9)M). In contrast, the (11-24)2Lys conjugate (10(-6)M) significantly decreased ACTH-induced stimulation of corticosterone and aldosterone (-63 and -62%, respectively). The dimeric conjugate of the fragment ACTH(7-24), linked through the C-terminal ends, (7-24)2Lys (10(-6)M), was also completely devoid of effect on basal steroidogenesis but caused a marked decrease of ACTH-evoked corticosterone and aldosterone release (-72 and -80%, respectively). Conversely, infusion of the dimer (1-24)2Lys gave rise to a dose-related stimulation of corticosterone and aldosterone release. The time-course of the steroidogenic response to the dimer was similar to that of ACTH(1-24). The 1-24 conjugate was 70 times less potent than the monomers ACTH(1-24) and ACTH(1-39). These results suggest that amphibian adrenocortical cells contain only one class of ACTH receptor which recognizes the 11-24 domain of ACTH with an affinity which depends on the presence of a strong potentiator segment, located at the N-terminus end of ACTH(1-39). Since the ACTH-dimers are thought to induce cross-linking of the receptors, our results suggest that aggregation of ACTH receptors causes a down-regulation of the receptors.     

The reversibility of the effects of ACTH and cytochalasin B on the ultrastructure and steroidogenic activity of adrenocortical tumor cells in vitro

We have demonstrated previously that the steroidogenic activity of ACTH on cultured adrenal tumor cells is associated with cell rounding and a rearrangement of microfilaments. Cytochalasin B (CB) also induces cell rounding, but changes the conformation of microfilaments and severely inhibits steroidogenesis. ACTH and CB may have different modes of action on the contractile machinery which are related to their opposing actions on steroidogenesis. To investigate this possibility further, we have examined the reversibility of the morphological and functional effects of these agents. Cultures were incubated for 1 hr, with and without ACTH (10 microU/ml of media), or with CB (50 micrograms/ml), or with both agents simultaneously. After a media wash, the cultures were incubated for 1 hr, with and without ACTH. The steroid production of the cells during pre- and post-washout incubations was determined, and some cultures were fixed for electron microscopy at the end of both incubation periods. The three- to ten-fold increases in steroidogenic activity of ACTH-stimulated cells declined during recovery incubations, but remained well above basal values. These cells nearly reflattened and began to regain stress fibers which had been 'pulled apart'. The 'washed out' ACTH-stimulated cells were often refractory to restimulation. Cells recovering from CB also reflattened. Masses of filamentous felt induced by the drug disappeared from the cytoplasm, lost microvilli reappeared and stress fibers reformed. The 20-50% inhibition of basal steroidogenesis by CB was completely reversed. When ex-CB-treated cells were incubated with ACTH, their morphology and steroid production were typical of acutely stimulated cells. The recovery behavior of cells incubated with ACTH and CB simultaneously reflected the observation that there were cell-specific responses to one agent or the other during initial incubations. The persistence of heightened steroidogenic activity following a washout of ACTH and the rapid reversal of the effects of CB strongly support the concept that regulated actomyosin interactions are an integral part of the steroidogenic process.     

Effects of prostaglandins on adrenal steroidogenesis in the rat

To elucidate the role of prostaglandins in adrenal steroidogenesis, we studied aldosterone and corticosterone responses to

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of prostaglandin E₂ (PGE₂), prostaglandin F_2α (PGF_2α), prostacyclin (PGI₂), and arachidonic acid (AA) in collagenase dispersed rat adrenal capsular and decapsular cells. Whereas adrenocorticotrophic hormone (ACTH) and angiotensin II (AII) stimulated aldosterone production in capsular cells and ACTH stimulated corticosterone production in decapsular cells in a dose dependent fashion, aldosterone and corticosterone production were not stimulated significantly by PGE₂, PGF_2α, PGI₂, and AA. Although preincubation of dispersed adrenal cells with indomethacin ( ) markedly inhibited PGE₂ synthesis, ACTH- and AII-stimulated aldosterone production and ACTH-stimulated corticosterone production were not attenuated despite prostaglandin blockade. These results indicate that prostaglandins are unlikely to play an important role in adrenal steroidogenesis.     

Functional significance of interrenal cell zonation in the adrenal gland of the duck (Anas platyrhynchos)

Slices of whole adrenal gland tissue, incubated in vitro in the presence of ACTH for 1 h and 2 h produced corticosterone and aldosterone in constant ratio (16:1). Tangential slices taken from the region immediately below the connective tissue capsule and slices taken from deeper regions of the gland consisted primarily of cells conforming to the distinct structural characteristics of the subcapsular zone (SCZ) and inner zone (IZ) tissues respectively. When samples were incubated in the presence of ACTH for 1 h and 2 h, the interrenal cells of the SCZ produced relatively more aldosterone than cells taken from the IZ of the gland. The corticosterone: aldosterone ratio for the IZ after 1 h (68:1) and after 2 h (102:1) were ten times greater than the ratios for the SCZ after 1 h (7:1) and after 2 h (10:1). The SCZ slices were not more than 60 cells thick and consisted of cells arranged in cords. These cells contained irregular nuclei, mitochondria with shelf-like cristae and a moderate abundance of smooth endoplasmic reticulum. In contrast, the production of large amounts of corticosterone by the cells of the IZ was associated with tissue containing more vascular space than the SCZ and the cells contained large round nuclei surrounded by an abundance of smooth endoplasmic reticulum and the mitochondria had tubular rather than shelf-like cristae.     

Ontogenic corticosteroidogenesis of the domestic fowl: response of isolated adrenocortical cells

Ontogenic adrenocortical function of the domestic was investigated using adrenocortical cells isolated from embryonic chicks (18, 19, 20, and 21 days old) and male and female posthatch birds (1 day, 1 week, and 3 weeks old). Production of the predominant corticosteroids secreted by the chicken adrenal gland, corticosterone, cortisol, and aldosterone, was measured by radioimmunoassay after 2-hr incubation of cells with or without steroidogenic agents. Approaching hatch, basal and maximal ACTH-(1-24) (ACTH)-induced corticosteroid production increased steadily and peaked around 1 day posthatch (5-18 times and 3-9 times, respectively, the production values at 18 days embryonic life). Thereafter, corticosteroid production values decreased steadily to 3 weeks posthatch. Corticosterone predominated over the ages studied: Maximal ACTH-induced corticosterone production averaged 52 and 115 times the production values of aldosterone and cortisol, respectively. In addition, maximal ACTH-induced aldosterone production was roughly 2.2 times greater than cortisol production over the ages studied except for a short-lived, disproportionately greater aldosterone production at 1 day posthatch. In addition to perihatch and age-related differences in cellular corticosteroid production, there were also differences in cellular sensitivity to steroidogenic agents as indicated by the differences in half-maximal steroidogenic concentration values (ED50 values) of the steroidogenic agents. Sensitivity to ACTH increased 2.7 times from Day 18 of embryonic life to 1 day posthatch and then decreased steadily to 3 weeks posthatch. In addition, sensitivity to 8-bromo-cAMP (8-Br-cAMP) increased abruptly at 1 day posthatch (nearly 3 times) but then remained constant thereafter. However, a consistent change in cellular sensitivity to 25-hydroxycholesterol was not observed until 3 weeks posthatch (an increase in sensitivity of 3 times that at Day 18 of embryonic life). These data of cellular sensitivity suggest that there were distinct development and maturational alterations in the cellular loci at which ACTH, 8-Br-cAMP, and 25-hydroxycholesterol acted. Thus, during the transition from embryonic to postembryonic life of the domestic fowl, there are alterations in adrenocortical cell steroidogenic capacity and in the function of some cellular loci comprising the corticosteroidogenic pathway.     

Cholesterol accumulation in adrenocortical mitochondria after ACTH-stimulation

Rat adrenocortical cell suspensions (10(6) cells) were incubated with ACTH (40 nM) in 2 ml of Krebs-Ringer bicarbonate buffer for 90 min. About 42 nmol of corticosterone and 14 nmol of 18-hydroxydeoxycorticosterone were generated and released into the medium. Aminoglutethimide at 50 microM inhibited the steroidogenesis to 16%. Mitochondrial pellets were prepared from the cells incubated in the absence, or in the presence, of ACTH and aminoglutethimide, and cholesterol content was determined. The mitochondria of the cells incubated without the drugs contained 25.2 micrograms cholesterol/mg protein. Cholesterol content increased by 10% in the mitochondria of the ACTH-stimulated cells. The mitochondria of the cells incubated in the presence of both ACTH and aminoglutethimide contained 143% of cholesterol compared to those of the nontreated cells. When rats were subjected to ether stress after aminoglutethimide pretreatment, cholesterol content of the mitochondrial fraction increased to about 200% compared to that of the control rats. These results suggest that a cholesterol pool exists in the adrenocortical mitochondria and that the amount increases during the steroidogenic stimulation of the cells. The mitochondria were fixed with filipin-containing fixative and examined by freeze-fracture electron microscopy. Accumulations of filipin-cholesterol complexes were observed in the inner membrane of the mitochondria as protuberances or pits 25 nm in diameter.     

A comparative study on the steroidogenic response due to training and ACTH treatment in the adrenal cortex of the male rat

The aim of this study was to ascertain the effects of training and ACTH administration on the steroidogenic in vitro response in the adrenal cortex of the rat when the tissue was incubated with ACTH. ACTH in vivo treatment resulted in a highly significant increase in the steroidogenic response (P less than 0.001) whereas training as such caused only a slight but insignificant increase in the steroidogenic responsiveness (P greater than 0.05). Training furthermore strongly suppressed the ACTH in vivo induced response (P less than 0.001). ACTH as such revealed the smallest effect on adrenal mass but the biggest effect on the steroidogenic response. It would seem that long term exercise resulted in an overall increase in the mass and size of the adrenal glands by either increasing the size of existing cells or by increasing the number of cells or both. The latter exercise-induced proliferation of adrenal tissue may involve an adaptive mechanism whereby larger total quantities of adrenal tissue of lowered steroidogenic efficiencies (on a mass basis) are produced in order to meet the stress resulting from the training program.     

Adrenal adenylate cyclase and steroidogenic activities of 63 day old ovine fetuses: in vitro effects of ACTH1-24 and forskolin

This study examines the activity of the adenylate cyclase system and that of some enzymes of the steroidogenic pathway of adrenal cells from 62-63 day old ovine fetuses. Synthetic corticotropin (ACTH1-24), cholera toxin and forskolin stimulated both cAMP and corticoid productions by freshly isolated adrenal cells. The cAMP response to ACTH1-24 was lower than that to forskolin. However, forskolin-induced steroidogenesis was significantly lower than the ACTH1-24-induced steroid output. Freshly isolated cells metabolized quickly [14C]-labeled pregnenolone mainly through the 17-deoxy pathway. The amounts of cortisol and of corticosterone formed, in the presence of exogenous pregnenolone, were roughly 15-fold higher than under maximal stimulation by ACTH1-24. When the cells were cultured for 6 days in the absence or presence of ACTH1-24 (10(-8) M) or forskolin (10(-5) M), a small development of the cAMP response to these factors was observed in the course of the experiment. However, the mechanism of this development appeared different, according to the conditions of culture. The amounts of corticosterone secreted on day 6 by ACTH1-24- or forskolin-treated cells were 2- to 4-fold higher than on day 1, whereas cortisol outputs were much lower on day 6 than on day 1. The response to ACTH1-24 of cells maintained in ACTH-free media decreased dramatically during the culture in terms of both cortisol and of corticosterone. On day 6 of the experiment, the metabolism of [14C]pregnenolone was lower than on day 1 under all 3 conditions of culture. Only the 3 beta-hydroxysteroid dehydrogenase/isomerase activity could be maintained by continuous treatment with forskolin. However, both ACTH1-24 and forskolin enhanced the production of pregnenolone from an endogenous substrate. In conclusion, these results present evidence that: 1) the adenylate cyclase system is not a bottleneck in the steroidogenic response to ACTH1-24 of freshly isolated adrenal cells from 62-63 day old ovine fetuses; 2) the main rate-limiting step for steroidogenesis by these cells is the availability of pregnenolone; 3) neither ACTH1-24 nor forskolin is able to maintain the activity of most enzymes involved in the metabolization of pregnenolone by cultured cells while increasing pregnenolone availability; 4) some inhibiting factors are involved in the loss of adrenal cells responsiveness to ACTH between days 50 and 100 of gestation, and they probably act mainly on the adenylate cyclase system.     

Relationship between endogenous cyclic AMP production and steroid hormone secretion in chick adrenal cells

Dispersed chick adrenal cells were incubated with either ACTH, cholera toxin or forskolin. All three agents stimulated cyclic AMP accumulation and secretion of corticosterone and aldosterone by the dispersed cells. The dose-response to ACTH was similar for cyclic AMP and corticosterone but aldosterone secretion appeared to be more sensitive to ACTH stimulation. Concentrations higher than 10(-8) M of ACTH caused suppression of corticosterone output but not of cyclic AMP accumulation or aldosterone secretion. A significant cyclic AMP accumulation occurred within 30 min of exposure to ACTH whereas significant increases in steroid secretion were observed only after 30 min. An early increase (within 30 min) in cyclic AMP accumulation with both cholera toxin and forskolin was not accompanied by any significant stimulation of steroid secretion, which occurred only after 120 min. The results with the avian adrenal cells are consistent with the thesis that steroid production in the adrenocortical cells is stimulated by cyclic AMP-dependent pathways, whereas steroid release may be modulated by others.     

Actin filament organization regulates the induction of lens cell differentiation and survival

The actin cytoskeleton has the unique capability of integrating signaling and structural elements to regulate cell function. We have examined the ability of actin stress fiber disassembly to induce lens cell differentiation and the role of actin filaments in promoting lens cell survival. Three-dimensional mapping of basal actin filaments in the intact lens revealed that stress fibers were disassembled just as lens epithelial cells initiated their differentiation in vivo. Experimental disassembly of actin stress fibers in cultured lens epithelial cells with either the ROCK inhibitor Y-27632, which destabilizes stress fibers, or the actin depolymerizing drug cytochalasin D induced expression of lens cell differentiation markers. Significantly, short-term disassembly of actin stress fibers in lens epithelial cells by cytochalasin D was sufficient to signal lens cell differentiation. As differentiation proceeds, lens fiber cells assemble actin into cortical filaments. Both the actin stress fibers in lens epithelial cells and the cortical actin filaments in lens fiber cells were found to be necessary for cell survival. Sustained cytochalasin D treatment of undifferentiated lens epithelial cells suppressed Bcl-2 expression and the cells ultimately succumbed to apoptotic cell death. Inhibition of Rac-dependent cortical actin organization induced apoptosis of differentiating lens fiber cells. Our results demonstrate that disassembly of actin stress fibers induced lens cell differentiation, and that actin filaments provide an essential survival signal to both lens epithelial cells and differentiating lens fiber cells.     

QTL mapping for traits associated with stress neuroendocrine reactivity in rats

In the present study we searched for quantitative trait loci (QTLs) that affect neuroendocrine stress responses in a 20-min restraint stress paradigm using Brown–Norway (BN) and Wistar–Kyoto–Hyperactive (WKHA) rats. These strains differed in their hypothalamic–pituitary–adrenal axis (plasma ACTH and corticosterone levels, thymus, and adrenal weights) and in their renin–angiotensin–aldosterone system reactivity (plasma renin activity, aldosterone concentration). We performed a whole-genome scan on a F₂ progeny derived from a WKHA × BN intercross, which led to the identification of several QTLs linked to plasma renin activity (Sr6, Sr8, Sr11, and Sr12 on chromosomes RNO2, 3, 19, and 8, respectively), plasma aldosterone concentration (Sr7 and Sr9 on RNO2 and 5, respectively), and thymus weight (Sr10, Sr13, and Srl4 on RNO5, 10, and 16, respectively). The type 1b angiotensin II receptor gene (Agtrlb) maps within the confidence intervals of QTLs on RNO2 linked to plasma renin activity (Sr6, highly significant; LOD = 5.0) and to plasma aldosterone level (Sr7, suggestive; LOD = 2.0). In vitro studies of angiotensin II–induced release of aldosterone by adrenal glomerulosa cells revealed a lower receptor potency (log EC₅₀ = −8.16 ± 0.11 M) and efficiency (E_max = 453.3 ± 25.9 pg/3 × 10⁴ cells/24 h) in BN than in WKHA (log EC₅₀ = −10.66 ± 0.18 M; E_max = 573.1 ± 15.3 pg/3 × 10⁴ cells/24 h). Moreover, differences in Agtr1b mRNA abundance and sequence reinforce the putative role of the Agtr1b gene in the differential plasma renin stress reactivity between the two rat strains.