The Golgi apparatus and adrenal function: the effects of monensin on adrenocorticotropic hormone-stimulated steroidogenesis

The effects of monensin on Golgi complex of adrenal cortex and steroidogenesis

The ultrastructural and biochemical changes produced by monensin on zona fasciculata cells of the rat adrenal cortex are described. In this study we used adrenal cells in culture, adrenal slices and the intact animal. Monensin (1 microM) was added to the culture medium containing the cells, and to the incubation medium containing the adrenal slices, and was injected intravenously to the intact animal (0.65 mg/kg body weight). The ultrastructural alterations were similar in the three experimental conditions, and consisted of Golgi complex disorganization with dilated cisternae or large smooth vesicles. Quantitative analysis showed a significant increase of the relative volume of the Golgi area. The biochemical study demonstrated a significant decrease of corticosterone concentrations in culture medium after monensin addition, and in adrenal glands from treated rats. These results showed that monensin alters the fine structure of adrenal cortex Golgi complex and inhibits corticosteroidogenesis, which supports the probable role of the Golgi complex in the regulation of steroidogenesis.

Diminished adrenal steroidogenic activity in aging rats: new evidence from adrenal cells cultured from young and aged normal and hypoxic animals

Adrenal cells from 2-6-month-old young rats (Y cells) and from 19-25-month-old aged male rats (O cells) were adapted to primary monolayer culture. The cultures of Y and O cells appeared to be primarily epithelial and rounded up in response to stimulation with adrenocorticotropic hormone (ACTH). The general morphology of O cells was comparable to that observed in Y cells except for the presence of lipofuscin-like granules, a cellular marker of aging, in O cells, but not in Y cells. ACTH-stimulated steroid production by O cells was 52% lower than that by Y cells. Exposure of intact young rats to hypoxia (0.5 atmosphere) for 21 days prior to sacrifice and culture resulted in a 122% increase of ACTH-stimulated adrenal steroidogenic activity in the cultured cells, but this effect was not observed in adrenal cells cultured from hypoxic aged rats. The results suggest that there is an age-related diminution in rat adrenal steroidogenic capacity in response to ACTH stimulation in culture derived from Y and O animals; hypoxic stress magnifies this difference.

Effects of prolactin on the morphology and function of rat Leydig cells: short-term versus long-term administration

The bolus administration of prolactin (PRL) to adult rats did not cause any apparent change in the basal and luteinizing hormone (LH)-stimulated blood levels of testosterone (as estimated by radioimmune assay). Prolonged PRL infusion did not affect either basal testosterone plasma concentration or the morphology of Leydig cells (as evaluated by electron microscopy and stereology). Conversely, prolonged PRL treatment notably increased the gonadotrophic effects of chronic LH administration; this mainly consisted of a rise in the blood concentration of testosterone and a conspicuous hypertrophy of Leydig cells. The LH-induced increase in the volume of Leydig cells was the result of an increase in the volumes of all the organelles involved in steroid synthesis (i.e., smooth endoplasmic reticulum, peroxisomes and mitochondria). However, the trophic effects of PRL infusion exclusively concerned smooth endoplasmic reticulum and peroxisomes. In the light of these findings, the hypothesis is advanced that the mechanism underlying the gonadotrophic action of PRL involves an enhancement of the endogenous cholesterol synthesis, which could provide an abundance of precursors for testosterone synthesis, the post-cholesterol steps of which, in turn, would be exclusively controlled by LH.

Further characterization of the inhibitory effect of monensin on adrenal steroidogenesis

We have previously reported that treatment of cultured mouse adrenal tumor cells with 0.6-1.2 microM monensin, a monovalent carboxylic ionophore, results in disruption of the organized structure of the Golgi complex. This is associated with an inhibition of adrenocorticotropic hormone (ACTH) or dibutyryl cAMP-stimulated steroidogenesis and impairment of mitochondrial cholesterol side-chain cleavage activity. The present report describes further investigations regarding possible mechanisms for the inhibition. Monensin inhibits both synthesis of fluorogenic steroids and incorporation of [14C]acetate into the end-product steroid 11 beta,20 alpha-dihydroxy-4-pregnen-3-one. Supplementation of monensin-treated cells with 25-hydroxycholesterol, a readily available substrate for steroidogenesis, does not reverse the inhibitory effect on the reaction. The incorporation of L-[35S]methionine into trichloroacetic acid precipitable proteins in the isolated mitochondria of monensin-treated cells is inhibited approximately by 40%, whereas the inhibitory effect on the proteins in the cell homogenate is marginal. These findings suggest that a deficiency of newly synthesized proteins in mitochondria, rather than the availability of the substrate cholesterol, may be the primary factor causing impairment of steroidogenesis.

Alteration of intracellular traffic by monensin; mechanism, specificity and relationship to toxicity

Monensin, a monovalent ion-selective ionophore, facilitates the transmembrane exchange of principally sodium ions for protons. The outer surface of the ionophore-ion complex is composed largely of nonpolar hydrocarbon, which imparts a high solubility to the complexes in nonpolar solvents. In biological systems, these complexes are freely soluble in the lipid components of membranes and, presumably, diffuse or shuttle through the membranes from one aqueous membrane interface to the other. The net effect for monensin is a trans-membrane exchange of sodium ions for protons. However, the interaction of an ionophore with biological membranes, and its ionophoric expression, is highly dependent on the biochemical configuration of the membrane itself. One apparent consequence of this exchange is the neutralization of acidic intracellular compartments such as the trans Golgi apparatus cisternae and associated elements, lysosomes, and certain endosomes. This is accompanied by a disruption of trans Golgi apparatus cisternae and of lysosome and acidic endosome function. At the same time, Golgi apparatus cisternae appear to swell, presumably due to osmotic uptake of water resulting from the inward movement of ions. Monensin effects on Golgi apparatus are observed in cells from a wide range of plant and animal species. The action of monensin is most often exerted on the trans half of the stacked cisternae, often near the point of exit of secretory vesicles at the trans face of the stacked cisternae, or, especially at low monensin concentrations or short exposure times, near the middle of the stacked cisternae. The effects of monensin are quite rapid in both animal and plant cells; i.e., changes in Golgi apparatus may be observed after only 2-5 min of exposure. It is implicit in these observations that the uptake of osmotically active cations is accompanied by a concomitant efflux of H+ and that a net influx of protons would be required to sustain the ionic exchange long enough to account for the swelling of cisternae observed in electron micrographs. In the Golgi apparatus, late processing events such as terminal glycosylation and proteolytic cleavages are most susceptible to inhibition by monensin. Yet, many incompletely processed molecules may still be secreted via yet poorly understood mechanisms that appear to bypass the Golgi apparatus. In endocytosis, monensin does not prevent internalization. However, intracellular degradation of internalized ligands may be prevented.(ABSTRACT TRUNCATED AT 400 WORDS)

Effects of acute and chronic treatments with atrial natriuretic factor (ANF) on the Leydig cells of the rat testis

Acute ANF bolus administration (40 micrograms.kg-1) did not affect secretory activity and morphology of rat Leydig cells. Prolonged (7-day) ANF infusion (20 micrograms.kg-1.h-1), on the contrary, elevated both basal and hCG-stimulated testosterone blood concentration, and caused a notable hypertrophy of rat Leydig cells. Leydig-cell hypertrophy was due to increases in the volume of all the organelles involved in cholesterol and testosterone synthesis (i.e. mitochondria, smooth endoplasmic reticulum and peroxisomes). These findings suggest that ANF, when chronically administered, is able to stimulate the growth and steroidogenic capacity of rat Leydig cells.

Monensin influences basal and human growth hormone-releasing hormone 44-induced release of stored and new rat growth hormone and prolactin

When previous data suggested a growth hormone-releasing factor (GRF)-sensitive branch in intracellular hormone processing, the monensin-sensitive Golgi apparatus seemed a likely candidate. We examined monensin's effect on basal and GRF-stimulated release of newly synthesized and stored rat growth hormone (rGH) and rat prolactin (rPRL). 14C-Pre-labeled, perifused rat pituitary fragments were exposed to [3H]leucine in 0-10 microM monensin; a pulse of 3 nM GRF assessed subsequent secretory responsivity. Monensin dose-dependently reduced basal release of stored [14C]rGH and [14C]rPRL. GRF-stimulated release of stored [14C]hormone was doubled after 0.03 microM and 0.1 microM monensin; higher concentrations diminished stored hormone release. Low concentrations of monensin accelerated basal (0.03 microM and 0.1 microM) and GRF-stimulated (0.03 microM) [3H]rGH and [3H]rPRL release without altering recovery; higher monensin concentrations (greater than or equal to 1 microM) reduced basal, and abolished GRF-stimulated, new hormone release and reduced total [3H]rGH and [3H]rPRL recovery. These data are consistent with a GRF-sensitive and monensin-influenced branch in intracellular hormone processing that regulates the fraction of new hormone exiting the cell without prior immersion in storage compartments.

Microtubules, organelle transport, and steroidogenesis in cultured adrenocortical tumor cells. 1. An ultrastructural analysis of cells in which basal and ACTH-induced steroidogenesis was inhibited by taxol

In adrenocortical cells, the first step in the enzymatic processing of cholesterol to steroid end products occurs in the mitochondria. ACTH increases mitochondrial cholesterol and steroidogenesis. In cultured mouse adrenocortical tumor cells, microtubule-based organelle motility may increase the proximity of mitochondria to the SER, lipid droplets and endoscome-derived lysosomes, thereby facilitating the transfer of cholesterol from these organelles to the mitochondrial outer membrane. ACTH may increase opportunities for the transfer by promoting organelle motility and by increasing the number of lysosomes. Taxol, a microtubule polymerizer, inhibits basal and ACTH-induced steroidogenesis in these cells, presumably at the step where mitochondria obtain cholesterol. We examined the ultrastructure of taxol-treated, unstimulated and ACTH-stimulated cells, seeking alterations which conceivably could interefer with the proposed organelle transport and encounters, and thus correlate with taxol's inhibition of steroidogenesis. Primary cultured cells were incubated in serum-containing medium for 4 hr with and without ACTH (10 mU/ml), with 10 micrograms/ml and 50 micrograms/ml of taxol, and with ACTH and taxol 10 or taxol 50 simultaneously. Culture media were analyzed for the presence of secreted steroids at the end of 1, 2, and 4 hr of incubation. At the end of the fourth hour, unstimulated cells and cells treated with ACTH, taxol 50, and both agents simultaneously, were fixed and processed for EM. Taxol inhibited basal and ACTH-induced steroidogenesis in a dose-dependent fashion. In both unstimulated and ACTH-stimulated cells, taxol 50 formed numerous microtubule bundles, but did not markedly change the distribution of mitochondria and lipid droplets. SER tubules, and clusters of Golgi fragments, endosomes, and lysosomes appeared to be translocated towards the cell periphery along some of the microtubules. Taxol permitted an ACTH-induced cell rounding and microfilament rearrangement considered to facilitate organelle motility. Our data indicate that taxol disrupts the formation of lysosomes by these adrenal cells, but it seemed unlikely that taxol's ultrastructural effects could prevent organelle transport proposed to cause meetings between mitochondria and the SER or lipid droplets, or prevent ACTH-caused increases in these encounters. Taxol may instead prevent the transfer of lipid droplet or SER-contained cholesterol to adjacent mitochondria, by a means not detectable in our electron micrographs.

The effects of monensin on inhibition of steroidogenesis and disruption of the Golgi complex in adrenal cells are both reversible!

Following 15-30 min exposure to monensin, adrenocorticotropic hormone (ACTH)-stimulated steroidogenesis in cultured adrenal cells is inhibited by 37-48%. Electron microscopic studies reveal that, in monensin-treated cells, the Golgi complexes are disrupted into large vacuolar structures with loss of its organized structure indicating that the action of monensin on the organelles is comparably rapid. The inhibition is fully reversed after removal of the monensin-containing medium and exposure to fresh growth medium for a subsequent 4-24 h prior to stimulation. Concomitant with the restoration of full steroidogenic activity, the disrupted organelles are extensively reorganized in the cells after exposure to fresh growth medium for 4-24 h. These findings, which demonstrate, for the first time, a correlation between the morphology of the Golgi complex and steroidogenic activity, strengthen the possibility that the organelle may be involved in the regulation of steroidogenesis.

Effect of monensin and nocodazole on the intestinal lipid esterification in mouse jejunal organ culture

The ability of mouse jejunal explants to esterify a lipid emulsion containing oleic acid, palmitic acid and monopalmitin has been studied in different in vitro experimental conditions. The incubating lipid solution must have a minimum volume for obtaining optimal triglyceride esterification by the cultured intestinal mucosa. In our incubating conditions the exchange of oleic for palmitic acid does not significantly modify the amount of lipids esterified by the explants in 15 min. Monensin or nocodazole, added to the culture medium of intestinal explants for 3 hr, significantly change the amount of lipids esterified and secreted. The inhibition observed after nocodazole treatment disappears, however, when the explants are rinsed and the culture is allowed to continue for an additional 3 hr in a drug-free medium. These results suggest that the regulation of lipid metabolism can be studied in organ culture.