Involvement of cycloheximide-sensitive mediators in the steroidogenic action of adrenocorticotropin and angiotensin II

The involvement of short-lived proteins in the steroidogenic action of corticotropic peptides has been investigated in vitro by means of a perifusion technique using frog adrenal glands. Graded concentrations of cycloheximide (10(-7) M to 10(-5) M) led to a dose-related inhibition of corticosterone and aldosterone production. The perifusion model gives detailed information on the kinetics of the inhibitory effect of cycloheximide. This effect was rapidly observed (the lag period was about 15 min), maximum inhibition being obtained 25 min after the end of administration of the protein synthesis inhibitor. Whatever the concentration of cycloheximide, corticosteroid output returned to basal values 2 h after the onset of cycloheximide infusion. Stimulation of steroidogenesis by ACTH and angiotensin II was totally inhibited by cycloheximide (10(-6) M) indicating that the synthesis of a labile protein was required for the adrenal response to corticotropic peptides. In addition, the stimulatory effect of cAMP and PGE1, which are considered to be the second messengers of ACTH and angiotensin II in amphibian interrenal gland, was blocked by cycloheximide. Taken together, these data suggest that a labile protein is involved in an early step of corticosteroid biosynthesis in the frog.     

Mechanism of corticotropin action on adrenal protein synthesis. The effects of inhibitors of protein synthesis and calcium chelators

We have recently shown that beside a general stimulation of most adrenal proteins, corticotropin induces a marked increase in a specific adrenal cytosolic protein, protein E, in intact and hypophysectomized rats. To further clarify the mechanisms by which corticotropin exerts its trophic action we have investigated the effects of cycloheximide, calcium and calcium chelator administration on intact and hypophysectomized animals. These substances were injected in rats with or without corticotropin, and slices of adrenal glands from control and treated animals were removed 5 h later, incubated with [14C]- or [3H]-leucine for 2 h, and cytosolic proteins analyzed by polyacrylamide gel electrophoresis using a dual labelling technique. When high doses of cycloheximide (higher than 500 micrograms) were injected in rats, incorporation of labelled leucine in adrenal slices of control and corticotropin-treated animals was inhibited. With 500 micrograms cycloheximide per rat, incorporation of labelled leucine in adrenal slices of control animals was normal, but the corticotropin stimulation of both protein E and total protein synthesis was inhibited. Lower doses of cycloheximide (100 micrograms per rat) completely inhibited the stimulatory effect of corticotropin on total protein synthesis but did not affect protein E synthesis, while after 50 micrograms per rat both stimulatory effects were preserved. The two higher doses of cycloheximide (500 and 100 micrograms per rat) could not completely block the steroidogenic effect of the hormone. The effects of calcium and calcium chelators were studied in 1-day hypophysectomized rats. Calcium alone or injected simultaneously with corticotropin has no effect. Calcium chelators injected simultaneously with corticotropin partially inhibited the stimulatory effects of corticotropin on steroidogenesis but totally inhibited stimulation of total protein synthesis, while the stimulation of protein E persisted. Our results show that after corticotropin, stimulation of protein E synthesis correlates better with steroidogenesis than with total protein synthesis.     

Regulation of fibroblast cyclooxygenase synthesis by interleukin-1

We have prepared polyclonal antiserum against sheep seminal vesicle prostaglandin H synthase (also termed cyclooxygenase) which cross-reacted with human cyclooxygenase, thereby enabling us to directly determine the synthetic rate of cyclooxygenase protein and its modulation by the monokine interleukin-1 (IL-1). Cultured human dermal fibroblast cells were labeled with [35S]methionine, and the membrane-bound cyclooxygenase was solubilized and immunoprecipitated 35S-labeled fibroblast cyclooxygenase migrated on sodium dodecyl sulfate-polyacrylamide gel electrophoresis with a molecular size of approximately 73,000 daltons, similar to that of native sheep cyclooxygenase and of cyclooxygenase covalently labeled by [3H]aspirin, i.e. [3H]acetylcyclooxygenase. Additional validation of the immunoprecipitated 35S-labeled cyclooxygenase band indicated that it was specifically displaced by unlabeled sheep cyclooxygenase. N-terminal amino acid radiosequence analysis of [3H]proline-labeled cyclooxygenase revealed [3H]proline residues in positions 3, 6, and 8, consistent with the previously reported N-terminal sequence of sheep cyclooxygenase. Endoglycosidase H treatment of 35S-labeled fibroblast cyclooxygenase caused a decline in apparent molecular size (due to removal of mannose residues) which was similar to that seen with the native sheep cyclooxygenase. [35S]Methionine pulse-chase experiments indicated a half-life of 1 h for fibroblast cyclooxygenase. The monokine interleukin-1 stimulated fibroblast cyclooxygenase synthesis in a time- and dose-dependent fashion; as little as 0.03 unit/ml of IL-1 produced significant stimulation of 35S-labeled cyclooxygenase synthesis. Maximum stimulation was 3-10-fold after preincubation of the cells with 0.3 unit/ml of IL-1 for 12-16 h. IL-1 treatment of cells yielded parallel dose-response curves for stimulation of prostaglandin E2 formation, increased cellular cyclooxygenase activity, and increased synthetic rate of newly formed cyclooxygenase, suggesting that the IL-1 effect is mediated mainly, if not solely, via induction of cyclooxygenase synthesis.     

Acute ACTH regulation of adrenal corticosteroid biosynthesis. Rapid accumulation of a phosphoprotein

Two-dimensional gel electrophoresis was used to monitor proteins synthesized in unstimulated control and in adrenocorticotropic hormone (ACTH)- or cAMP-stimulated rat adrenal cells. Four proteins, which have similar proteolytic peptide maps, have been identified. The two found primarily in unstimulated cells are referred to as pb and pa, where pb is the protein with more basic isoelectric point. Similarly, proteins ib and ia were detected only in stimulated cells. The synthesis of pb occurs only in unstimulated cells and that of ib only in stimulated cells. Protein ib accumulates with the same lag time, rate, and stimulant dose response as the increase in steroid hormone synthesis. Pulse-chase studies showed that protein ib is not produced from pb by a post-translational modification. Proteins pb and ib thus seem identical with proteins p and i previously identified in rat adrenal cortex and corpus luteum (Krueger, R.J., and Orme-Johnson, N. R. (1983) J. Biol. Chem. 258, 10159-10167, and Pon, L.A., and Orme-Johnson, N.R. (1986) J. Biol. Chem. 261, 6594-6599). The acidic forms, pa and ia, appear after a longer lag time and are produced at a slower rate than the basic forms. Pulse-chase studies showed that the disappearance of the basic form of each protein occurs concurrently with the appearance of the corresponding acidic form. Addition of [32P]orthophosphate to stimulated adrenal cells allowed direct demonstration that proteins ib and ia are phosphorylated. Moreover, alkaline phosphatase treatment of [35S]methionine-labeled, cAMP-stimulated adrenal cells caused a large decrease in the amounts of ib and ia and the appearance of proteins with the same two-dimensional electrophoretic mobilities as pb and pa. These observations suggest that protein ib may mediate stimulation of steroidogenesis, be produced by an ACTH- or cAMP-dependent, cotranslational phosphorylation of protein pb, and be lost by a cycloheximide-insensitive, post-translational conversion to ia.     

Corticotropin-induced changes in a soluble desmolase preparation

Following simple homogenization, substantial desmolase activity is recovered in rat adrenal 105 000 × g supernatant. The desmolase complex sediments at 3–4 S on sucrose gradients, is found in the clear cytosol, requires NADPH, is derived from mitochondria and is inhibited by aminoglutethimide and pregnenolone. The lipid fraction contains little or no desmolase activity but greatly enhances pregnenolone synthesis in soluble desmolase preparations, presumably by supplying free cholesterol substrate. Prior adrenocorticotropin (ACTH) administration enhances pregnenolone synthesis in the 105 000 × g supernatant, and cycloheximide, an inhibitor of adrenal protein synthesis, does not block this effect of ACTH (but rather potentiates it). The ACTH effect may be largely explained by an increase in free cholesterol, which enhances the activity of both the lipid fraction and clear cytosol, since: free cholesterol levels are increased by ACTH, particularly with cycloheximide pretreatment; type I and inverted type I difference spectrum changes, indicating greater cholesterol availability for binding to cytochrome P-450, are enhanced by ACTH with or without cycloheximide treatment; cholesterol-rich lipid fraction enhances such spectral changes and obliterates the differences in spectral and pregnenolone-synthesizing activities betwen control and ACTH-stimulated soluble desmolase preparations; and desmolase stimulatory properties of clear cytosol co-chromatographs with [¹⁴C]cholesterol. Since cycloheximide blocks ACTH-induced effects in intact mitochondria but not in the soluble desmolase preparation, it is postulated that the labile protein required during ACTH action functions to overcome a ?restraining influence’ which is present in intact mitochondria but not in the soluble desmolase system. The ‘restraining influence’ may be due to limited cholesterol-desmolase interaction.     

Effects of adrenocorticotropin and cycloheximide on adrenal diglyceride kinase

We studied the effects of adrenocorticotropin (ACTH) and cycloheximide on adrenal enzymes involved in phosphatidate synthesis. Treatment of rats in vivo with ACTH induced a rapid increase in phosphatide synthesis from diglyceride and ATP in adrenal homogenates, and cycloheximide treatment prevented this increase if given before ACTH and rapidly reversed the increase if given after ACTH. The stimulatory effect of ACTH appeared to be largely due to an increase in diglyceride substrate, as kinase activity was not altered. The inhibitory effect of cycloheximide, on the other hand, appeared to be due to a decrease in diglyceride kinase activity. Neither ACTH nor cycloheximide treatment had any effect on the activity of glycerol-3'-phosphate acyltransferase or phosphatidate phosphatase. Our findings suggest that (a) ACTH increases the flow of phospholipid (and their levels) throughout the entire circular pathway, i.e., phosphatidate leads to CDP-diacylglycerol leads to inositides leads to diglycerides leads to phosphatidate, and (b) a labile protein may serve to allow entry into a recycling of diglyceride in this pathway. In addition, since cycloheximide blocked carbachol-induced increases in pancreatic and salivary glandular phosphatidate synthesis resulting from phosphatidylinositol hydrolysis and consequent diglyceride generation, the putative labile protein may have widespread importance.     

Apparent increases in phospholipid degradation and turnover during combined treatment with protein synthesis inhibitors and adrenocorticotropin

Inhibitors of protein synthesis, cycloheximide and puromycin, blocked ACTH (adrenocorticotropin)-induced increases in phospholipid mass, including phosphatidylinositol, but paradoxically increase 32P-labelling (but not [3H]glycerol-labelling) therein. Cycloheximide also provoked an initial rapid decrease in 32P-prelabelled phospholipids, followed by an increase in [32P]Pi incorporation. These effects of cycloheximide and puromycin occurred in ACTH-treated (but not in control) cells. It appears that inhibition of protein synthesis during ACTH action provokes an increase in phospholipid degradation, followed by partial resynthesis of the phospholipid head groups.     

Effect of ACTH on cholesterol and steroid synthesis in adrenocortical tissues

Previous studies have established that under normal conditions, adrenal HMG-CoA reductase activity is higher in hamsters than in rats and humans. The hamster reductase activity follows a diurnal rhythm corresponding to that of plasma ACTH and glucocorticoids [Endocrinology 107 (1980) 215] but not to that of aldosterone. ACTH treatments to hamsters increased reductase activity after a latency of 60 min; this enhancement was prevented by cycloheximide [J. steroid Biochem. 24 (1986) 325]. Immunotitration and immunoblotting studies confirmed that ACTH caused an increase in reductase protein synthesis. In rats, long-term (1-9 days) and short-term (3 h) treatments with ACTH also induced increase in adrenal HMG-CoA reductase activity and reductase protein. In the presence of iodoacetamide and inhibitors of proteolytic enzyme, a main specific band of enzyme was evinced in the area of 102 +/- 6 kDaMr, by Western blotting, for both hamster homogenate and microsomal preparations (Endocrinology, 120 (1987]. Similarly Mr values were found with rat adrenal preparations. The concentration of mRNA, analyzed using the c-DNA pRed-10 coding for the Chinese hamster ovary reductase, was increased in adrenals of hamsters treated with ACTH. The reductase mRNA levels also fluctuated during the day in parallel with those of reductase activity and reductase protein. In conclusion, these results indicate that ACTH and other conditions inducing a change in hamster adrenal HMG-CoA reductase activity provoke parallel changes in reductase mRNA and reductase protein content. ACTH acts on the adrenal reductase of species synthesizing large as well as small quantities of cholesterol, thus indicating the general importance of this hormonal control.     

The role of protein kinases in ACTH-stimulated steroidogenesis.

The effect of highly purified bovine cytosolic adrenal cortical protein kinase isozyme II catalytic subunit (ATP: Protein Phosphotransferase EC 2.7.1.37) on the formation of pregnenolone from cholesterol in rat and bovine adrenal mitochondrial extracts has been investigated. No stimulation was observed although a low level incorporation of [³²P] from [³²P]-ATP into a component or components of the extract was detected. The mitochondrial extracts contained alkaline phosphatase activity that was inhibited by L-cysteine and dithiothreitol. It is concluded that the acute stimulation by ACTH of corticoid production in the rat adrenal does not involve protein kinase mediated phosphorylation of a component or components of the cholesterol sidechain cleavage mixed-function oxygenase system.     

Measurement of the dynamics of stimulation and inhibition of steroidogenesis in isolated rat adrenal cells by using column perfusion

Isolated adrenal cells were perfused in a small column by using Bio-Gel polyacrylamide beads as an inert supporting matrix, and the time-course of the response to various stimuli was observed by measuring fluorogenic 11-hydroxycorticosteroids in the effluent. A small but significant response was observed 1 min after stimulation with physiological concentrations of ACTH (adrenocorticotrophin), but the response did not start to build up rapidly for 3-4min and eventually reached a plateau after 9-10min. A similar pattern of events was observed for the decay of the steroid output on removal of ACTH. ACTH analogues, including one with a long duration of action in vivo, were found to produce responses with similar kinetics. However, cyclic AMP caused a more rapid increase in steroidogenesis and its effects were more short-lived after withdrawal. If, as present evidence suggests, cyclic AMP is produced rapidly after ACTH stimulation the delayed build-up of the steroidogenic response to ACTH would indicate that cyclic AMP may not be the intracellular mediator. When inhibitors were applied during ACTH stimulation, aminoglutethimide, which blocks mitochondrial conversion of cholesterol into pregnenolone (3beta-hydroxypregn-5-en-20-one), caused a rapid fall in steroid output (1 min), whereas cycloheximide took longer to achieve its full effect. Nevertheless, the response had fallen by 50% in 2 min, indicating a much shorter half-life than that previously reported for the labile protein implicated in steroidogenesis. In addition the rapid response to cyclic AMP makes it unlikely that steroid production is induced as a result of initiation of protein synthesis. This suggests that the labile protein plays an obligatory but permissive role in the development of the response. Column perfusion has proved to be a simple technique which can readily yield accurate data on responses of cells to stimulants and inhibitors.     

Deficiency of joining of Okazaki-type fragments in absence of cellular protein synthesis.

The dependence of integration of newly formed DNA chain ( less than 10 S) into larger DNA on concomitant protein synthesis was studied in a special cellular system. Exponentially growing Ehrlich ascites tumor cells in vivo show decreasing rated and finally complete cessation of protein and DNA synthesis upon transfer into an isotonic but non-nutritive environment (Hanks' balanced salt solution). Both protein and DNA synthesis is stimulated in these cells for a period of 30 min when they are placed into fresh Hanks' balanced salt solution; however, stimulation of protein synthesis is completely prevented in Hanks' balanced salt solution containing cycloheximide. This system allowed us to investigate the formation and fate of newly formed DNA chains ( less than 10 S) in dependence of protein synthesis. Analysis of DNA produced in [3H]thymidine pulses showed that DNA chains smaller than 18 S were still formed during the phase of totally delayed protein synthesis and in the presence of cycloheximide, but they were not converted into DNA molecules sedimenting faster than 18 S under these conditions. Stimulation of protein synthesis for a period of 30 min allowed the short DNA pieces to be chased into larger DNA 30 min post stimulation of protein synthesis. The results clearly indicate that DNA chain growth, by sealing of DNA chains smaller than 18 S, is strongly dependent of concomitant protein synthesis. Direct chain elongation by addition of new deoxyribonucleotides is less dependent on concomitant cellular protein synthesis.     

Low density lipoprotein receptor degradation is influenced by a mediator protein(s) with a rapid turnover rate, but is unaffected by receptor up- or down-regulation

Treatment of cultured human skin fibroblasts with cycloheximide retarded the down-regulation of low density lipoprotein (LDL) receptor activity caused by 25-hydroxycholesterol. The rate of LDL receptor degradation, measured directly by means of [35S]methionine pulse-chase experiments, was also markedly inhibited by cycloheximide (or puromycin), suggesting that continuous synthesis of a short-lived mediator protein(s) was necessary for normal LDL receptor turnover. In the absence of cycloheximide, both the up- and down-regulation of LDL receptor activity took place with a half-time of approximately 12 hr. Pulse-chase measurements with [35S]methionine yielded a receptor half-life (t1/2) of 11.7 +/- 2.2 hr (n = 10) in up-regulated cells; the t1/2 in the partially down-regulated state was similar. The presence of LDL or 25-hydroxycholesterol did not alter this degradation rate. Regulation of LDL receptor activity under these various culture conditions therefore probably occurred solely as a result of changes in the rate of receptor synthesis. The cycloheximide-sensitive factor(s) that influences receptor turnover apparently did not play a regulatory role in the up- or down-regulation of the LDL receptor.     

A mechanism for the in vitro stimulation of adrenal cortisol biosynthesis by epidermal growth factor

EGF stimulates adrenal steroidogenesis in ewes and in ovine adrenal slices. In vitro, The stimulation is blocked by the cholesterol synthesis inhibitors compactin and AY 9944. EGF stimulates the incorporation of [14C]acetate into cholesterol. EGF increases the activity of the rate limiting enzyme in cholesterol biosynthesis, HMG CoA reductase. EGF has no effect on the levels of any intermediates involved in the conversion of pregnenolone to cortisol, although ACTH produced changes consistent with 17 alpha-hydroxylase activation. We propose that EGF increases adrenal cortisol synthesis in vitro by a stimulation of cholesterol precursor biosynthesis mediated through activation of HMG CoA reductase.     

Factors affecting the adrenocorticotropic hormone stimulation of rabbit adrenal 17α-hydroxylase activity

Adrenocorticotropic hormone (ACTH)-stimulated 17α-hydroxylase activity of rabbit adrenal tissue has been shown to be associated with the subcellular fractions sedimented from 0.25 M sucrose at 33 000 × g for 60 min and at 105 000 × g for 60 min. The fraction sedimenting at 9000 × g for 20 min (mitochondria) contained the majority of the 11β-hydroxylase activity but also had a significant amount of 17α-hydroxylase activity. All subcellular 17α-hydroxylase activity showed an apparent preference for pregnenolone over progesterone. A 1 : 1 mixture of wholehomogenates of adrenal tissue from control and ACTH-stimulated rabbits incubated with[4-¹⁴C]pregnenolone synthesized as much 17α-hydroxylated corticosteroids as homogenate from the ACTH-stimulated tissue alone. However, the mixed homogenate synthesized only 1/4th–1/5th as much 17-deoxycorticosteroids as control, non-stimulated tissue, suggesting that the control tissue contained no inhibitor of 17α-hydroxylation, whereas ACTH-stimulated tissue may contain an inhibitor of 17-deoxycorticoid formation. 24-h dialysis of whole homogenates and subcellular fractions of adrenal tissue from control and ACTH-stimulated animals showed that 17α-hydroxylation was not activated in control tissue and somewhat inactivated in ACTH-stimulated tissue by this treatment. On the other hand, dialysis activated 17-deoxycorticoid formation by whole homogenates, but not in subcellular fractions, of both ACTH-stimulated and control adrenal tissue. Injection of 5 mg/kg cycloheximide prior to the first of 2 daily ACTH injections caused an average of 270 g body weight loss while not affecting the increase in adrenal weight effected by the ACTH. Adrenal tissue homogenates from cycloheximide injected animals produced only 50% as much 17α-hydroxycorticosteroids as homogenates of tissue from animals injected with ACTH alone and produced an amount of17-deoxycorticoids intermediate between homogenates of control and ACTH-stimulated tissue, suggesting the requirement of protein synthesis for 17α-hydroxylation stimulating activity of ACTH.     

The role of protein kinase activation in the control of steroidogenesis by adrenocorticotrophic hormone in the adrenal cortex

A method has been developed for investigation of the effect of adrenocorticotrophic hormone (ACTH) on the state of activation of a cyclic AMP-dependent protein kinase within cells of the adrenal cortex. Enzyme activity was measured in terms of the quantity of (32)P transferred from [gamma-(32)P]ATP to histone under conditions in which bound cyclic AMP did not dissociate from the regulatory subunit of the protein kinase ACTH (1x10(-2)i.u./ml) caused a rapid and complete activation of the cyclic AMP-dependent protein kinase activity within 2min of hormone addition to the isolated cells. In response to a range of ACTH concentrations a sigmoid log dose-response curve for protein kinase activation was obtained, with half-maximal stimulation attained at about 1x10(-3)i.u./ml. However, some low doses of ACTH that elicited a marked (but submaximal) steroidogenic response failed to cause a clear stimulation of protein kinase activity in isolated adrenal cells. Theophylline (2mm) potentiated the effect of ACTH on protein kinase activity. The results implicate an important role for protein kinase in ACTH action on the adrenocortical cell.     

Systematic shut-off of the hormone receptors in intraspecific adrenal x Leydig cell hybrids

The mouse Y1 adrenal cell line was fused with mouse Leydig cells in primary culture. The selected hybrids were examined for their response to gonadotropin (hCG) and ACTH. None of them bound specifically [125I]hCG, nor did they augment their cAMP production in response to gonadotropin or ACTH stimulation, whereas their adenylate cyclase remained responsive to forskolin and cholera toxin, thus indicating a repression of hCG receptor synthesis and probably a loss of ACTH receptors, rather than a lesion of the coupling between the hormone receptor complex and the adenylate cyclase. Basal pregnenolone production in 17 hybrids was close to that of Leydig and Y1 cells and was enhanced after 8-bromo adenosine 3',5'-monophosphate (8-Br-cAMP) stimulation in 11 of them. Therefore, the negative control leading to the extinction of both parental functions acts preferentially at the first step of steroidogenesis, i.e., the gene(s) coding for the hormone receptors.     

Brugia pahangi: inhibition of protein synthesis

The effects of inhibitors of protein synthesis and electron transport on the incorporation of [14C]leucine and [35S]methionine into protein by the filarial worm Brugia pahangi have been investigated. Cycloheximide inhibits the accumulation of both [14C]leucine and [35S]methionine by the worms and their incorporation into protein. In addition, inhibitors of electron transport and some anti-parasitic compounds also significantly inhibit filarial protein synthesis. Antimycin A and cyanide inhibit [14C]leucine incorporation into protein 63 and 72%, respectively, without affecting either motility or lactate production. Interestingly, the anti-malarial compounds chloroquine and quinacrine also significantly inhibit both accumulation and incorporation of [14C]leucine by B. pahangi. In addition, fluorographs of sodium dodecyl sulfate-polyacrylamide gels of homogenates from filariids incubated in [35S]methionine and cycloheximide with and without chloramphenicol indicate that there is a discrete population of proteins, possibly mitochondrial in origin, that are synthesized in the presence of cycloheximide and are not inhibited by chloramphenicol.     

Effect of endothelial-cell-conditioned medium on proteoglycan synthesis in cultured smooth muscle cells from pig aorta

The effect of porcine endothelial-cell-conditioned medium on proteoglycan synthesis by pig aorta smooth muscle cells was studied under serum-free conditions. Maximal stimulation of [35S]-sulfate incorporation (50%) into medium-secreted and cell layer proteoglycans was observed after 20 min and 4 h incubation, respectively. This stimulation can be explained neither by increased secretion nor by oversulfation of medium-secreted [35S]-labeled proteoglycans. Those [35S]-proteoglycans secreted (for 24 h) in the presence of endothelial cell-conditioned medium were characterized by a higher hydrodynamic size than those secreted in the presence of control medium, without modification of glycosaminoglycan chain length. Agreement between the stimulation of incorporation of [35S]-sulfate into glycanic chains (50.1%) and [14C]-serine residues associated with glycosaminoglycans (49.9%) involved an increase in the number of glycanic chains linked to protein cores. The lesser stimulation of [14C]-serine incorporation into secreted proteins (18%) suggested that stimulation of glycosaminoglycan synthesis was not the direct consequence of enhanced protein synthesis. Proteoglycan synthesis was studied in the presence of para-nitrophenyl-beta-D-xyloside. Fractionation of medium-secreted [35S]-proteoglycans and xyloside-initiated glycosaminoglycans revealed that stimulation of [35S]-glycosaminoglycan protein core acceptor for glycanic chain initiation. Our results suggest that the factor(s) secreted by endothelial cells are able to modify smooth muscle cell proteoglycan synthesis by stimulating the first step of protein core glycosylation. This stimulation was accompanied by an increase in proteoglycan hydrodynamic size.     

Interrenal activity in the female lizard Lacerta vivipara J.: in vitro response to ACTH 1-39 and to [Sar1, Val5] angiotensin II (ANG II)

A perifusion system technique was developed in order to determine in vitro the respective roles of ACTH and ANG II in the regulation of adrenal steroidogenesis in the lizard Lacerta vivipara. Synthetic human ACTH 1-39, administered as 20-min pulses, stimulated corticosterone (B) and aldosterone (A) release in a dose-dependent manner. The increase in corticosterone output was higher than that in aldosterone output, leading to an enhancement of the B/A ratio. Iterative stimulations with 1 nM ACTH (20-min pulses every 120 min) led to reproducible increases in corticosterone and aldosterone release. Prolonged stimulation with 1 nM ACTH (up to 240 min) caused a sustained increase in corticosteroid release, suggesting that, in the lizard, ACTH does not induce any desensitization phenomenon. The angiotensin II analogue [Sar1, Val5] ANG II also stimulated corticosterone and aldosterone release in a dose-dependent manner; the stimulatory effects of ANG II on both steroids were very similar. These results indicate that, in lizards, ACTH plays a major role in the regulation of adrenal steroidogenesis. Since ANG II stimulates the production of gluco- and mineralocorticoids, our data raise the question of the existence of two cell types synthesizing corticosterone and aldosterone, respectively, in reptiles.