Role of lipocortin I in the glucocorticoid induction of the terminal differentiation of a human squamous carcinoma

The human squamous cell carcinoma SqCC/Y1 undergoes spontaneous terminal differentiation in the confluent state. The degree of maturation was markedly increased by glucocorticoids and by both human recombinant and placental lipocortin I. Western analyses demonstrated cellular secretion of lipocortin into the medium. Glucocorticoid-induced maturation was antagonized by a lipocortin I-specific monoclonal antibody, by phospholipase A2 (PLA2), and by arachidonic acid. Induction of the differentiation of SqCC/Y1 cells by lipocortin I was prevented by arachidonic acid. The PLA2 inhibitor, dibromoacetophenone, caused an increase in envelope-competent cells indicating that inhibition of PLA2 results in induction of differentiation. Epidermal growth factor prevented the induction of differentiation by both lipocortin I and by glucocorticoids. The nonsteroidal lipoxygenase/cyclo-oxygenase inhibitor, phenidone, also increased SqCC/Y1 differentiation, suggesting that leukotrienes, thromboxanes, and/or prostaglandins may be involved in lipocortin-mediated regulation of SqCC/Y1 maturation. The findings support a role for lipocortin I in mediating the effects of glucocorticoids on epidermal cell differentiation.     

Effect of dexamethasone on prostaglandin synthesis and on lipocortin status in human endothelial cells. Inhibition of prostaglandin I2 synthesis occurring without alteration of arachidonic acid liberation and of lipocortin synthesis

Glucocorticoids have been shown to decrease prostaglandin I2 synthesis in human endothelial cells, suggesting the possible involvement of lipocortin in the inhibition of arachidonic acid liberation achieved by phospholipase A2 (De Caterina, R., and Weksler, B. B. (1986) Thromb. Haemostasis 55, 369-374). To test this hypothesis, human endothelial cells labeled with [14C]arachidonic acid were stimulated with thrombin (2 units/ml, 10 min), resulting in the secretion of free arachidonic acid together with various 14C-labeled metabolites, mainly 6-keto-prostaglandin F1 alpha, the stable derivative of prostaglandin I2. Under conditions where prior incubation of cells with dexamethasone reduced by 51% 6-keto-prostaglandin F1 alpha production, phospholipid hydrolysis induced by thrombin remained unaffected. Using three rabbit polyclonal antibodies directed against endonexin I, lipocortin I, and lipocortin II, evidence was obtained for the presence in human endothelial cells of equivalent amounts of lipocortin I and an immunologically unrelated 33-kDa protein, together with lower quantities of 67-kDa calelectrin/calcimedin. These Ca2+- and phospholipid-binding proteins were selectively extracted with [ethylene-bis(oxyethylene-nitrilo)]tetraacetic acid (EGTA) from cell membranes precipitated in the presence of Ca2+, and they displayed an inhibitory activity against pig pancreas phospholipase A2. However, the amounts of the three proteins were not changed by cell treatment with 2.5 microM dexamethasone, as detected upon polyacrylamide gel electrophoresis by silver staining, immunoblotting, or autoradiography following [35S]methionine in vivo labeling. Since the antiphospholipase A2 activity of EGTA extracts was hardly modified, it was concluded that an increased synthesis of lipocortin cannot account for the inhibition of prostaglandin synthesis brought about by dexamethasone, suggesting other biological functions for these proteins.     

Glucocorticoid effect on arachidonic acid metabolism in vivo

Glucocorticoids have been shown in in vitro systems to inhibit the release of arachidonic acid metabolites, namely prostaglandins (PGs) and leukotrienes, apparently, via the induction of a phospholipase A2 inhibitory protein, called lipocortin. On the basis of these in vitro results, it has been suggested that inhibition of eicosanoid production is, at least partially, responsible for the well-known anti-inflammatory effect of glucocorticoids. There is, however, no firm evidence proving that glucocorticoids also inhibit prostaglandin or leukotriene synthesis in vivo. In a series of studies, we have investigated the effects of anti-inflammatory steroids on the production of six different cyclo-oxygenase products in vivo. Urinary prostaglandin (PG) E2(1), PGF2 alpha, thromboxane B2 (TxB2), 6-keto-PGF1 alpha, and the major urinary metabolites of the E and F PGs, PGE-M and PGF-M, respectively, were determined by radioimmunoassay and by GC-MS. Administration of pharmacological doses of dexamethasone to rabbits failed to inhibit urinary excretion rates of PGE2, TxB2, 6-keto-PGF1 alpha and that of PGE-M and PGF-M. In contrast, urinary PGF2 alpha was slightly reduced by dexamethasone. In further experiments the effect of dexamethasone was studied in humans. Urinary excretion rates of PGE2, PGE-M, PGF-M, 2,3-dinor TxB2 and 2,3-dinor 6-keto-PGF1 alpha were not suppressed by dexamethasone. Collagen-induced platelet TxB2 formation and platelet aggregation was also unaltered. To test one possible explanation for the apparent discrepancy between in vitro and in vivo effects of glucocorticoids on arachidonic acid metabolites we investigated the effects of dexamethasone in vivo on basal and on antidiuretic hormone-stimulated renal PG synthesis. Dexamethasone treatment failed to inhibit both basal and antidiuretic hormone-stimulated PGE2 and PGF2 alpha production. We conclude that glucocorticoids in vivo do not decrease the basal rate of total body, kidney and platelet prostanoid synthesis, and that dexamethasone does not inhibit renal PG production when it is elevated by antidiuretic hormone, a physiological stimulus. Thus, a differential effect of glucocorticoids on basal vs stimulated PG synthesis cannot account for the discrepancy between in vivo and in vitro effects.     

Regulation of prostaglandin formation by glucocorticoids and their second messenger, lipocortins

Glucocorticoids induce the synthesis of a family of phospholipase inhibitory proteins, lipocortins. This family of lipocortins includes inhibitory proteins on phospholipase A2, phospholipase C and phosphatidylinositol phospholipase C. Hence, glucocorticoids reduce the formation of prostaglandins and leukotrienes by inhibiting cellular phospholipases, enzymes that degrade membrane phospholipids to release arachidonic acid, a precursor. The induction by glucocorticoids requires 1 h for the synthesis of mRNA and 5 h for the synthesis of proteins in various tissues and cells. However, glucocorticoids often exert their suppressive effects before the induction of lipocortins. This is now attributed to the nonenzymic formation of the adducts between glucocorticoids and lipocortins. These adducts are easily inserted into the membranes and more resistant to digestion of proteases, thus being more biologically potent with respect to suppression of the release of arachidonic acid, a precursor of prostaglandins and leukotrienes.     

Lack of involvement of lipocortin 1 in dexamethasone suppression of IL-1 release

The annexin lipocortin 1 is reported to mediate some anti-inflammatory effects of glucocorticoids, but the mechanisms of this mediation are incompletely understood. The involvement of lipocortin 1 in glucocorticoid inhibition of monocyte interleukin 1beta (IL-1beta) release has been investigated. Treatment of peripheral blood monocytes with 2 mug/ml lipopolysaccharide potently increased IL-1beta release (p = 0.001) and dexamethasone (10(-7) M) significantly reduced both resting and stimulated IL-1beta release (p = 0.009). A neutralizing monoclonal antibody to lipocortin 1 (0.5-50.0 mug/ml) was unable to inhibit this effect and recombinant lipocortin 1 (2 x 10(-6) M) and 188aa lipocortin 1 fragment (10(-8)-10(-6) M) had no effect. It is concluded that lipocortin 1 is not involved in the inhibition of monocyte IL-1beta release by glucocorticoids.     

The presence of lipocortin in human embryonic skin fibroblasts and its regulation by anti-inflammatory steroids

Human embryonic skin fibroblasts in culture produce pro-inflammatory lipid mediators and all types of prostanoids. When these cells were treated with the anti-inflammatory steroid, dexamethasone, prostaglandin production was inhibited. This phenomenon required glucocorticoid receptor occupancy and mRNA and protein synthesis. The inhibitory effect was prevented by treating the cells with a monoclonal antibody, BF 26, raised against renocortin, a lipocortin-like protein formed in rat kidney medulla interstitial cells in culture. When the proteins present in the supernatants and the cell pellets derived from control and dexamethasone-treated cells were analyzed for their ability to inhibit phospholipase A2, four inhibitory peaks, at 45, 30, 15 kDa and one peak under 12 kDa, were found in the supernatants of control and dexamethasone-treated cells, whereas one single inhibitory peak at 15 kDa was found in the cell pellets. The antiphospholipase activity was much greater in dexamethasone-treated cells than in control cells. These results suggest that preformed lipocortin exists in human cells and that lipocortin is synthesized and released under glucocorticoid treatment.     

Inhibition by glucocorticoids of PGE2 and ACTH secretion induced by phorbol esters and EGF in rat pituitary cells

In rat pituitary cells in primary culture glucocorticoids specifically inhibit PGE2 and ACTH secretions induced by TPA, a potent phorbol ester derivative (triamcinolone acetonide greater than dexamethasone greater than cortisol greater than or equal to corticosterone). However, while PGE2 secretion can be inhibited up to 80%, ACTH secretion can only be inhibited up to 40%. Similar inhibitory effects are observed with mepacrine, an inhibitor of phospholipase A2 (PLA2). Glucocorticoids having also been described as PLA2-inhibitors, their inhibitory effect on TPA-induced secretions could thus be related to their anti-PLA2 activity. Their inhibitory effect on PLA2 has been attributed to their ability to induce the synthesis of lipocortin, the activity of which could be regulated by activation of kinase C or EGF-receptor kinase. Since in our model, EGF-induced PGE2 secretion is also inhibited by dexamethasone, these results suggest that a lipocortin-like protein could be present in pituitary cells and involved in the effect of TPA and EGF on PGE2, and, at least partly, on ACTH release.     

Hormonal effects of PGF2 alpha output by cultures of epithelial and stromal cells in human endometrium

Estradiol stimulation and progesterone inhibition of human uterine PGF2 alpha production were studied using in vitro preparations of endometrial tissue and cells. Measurement of PGF2 alpha levels in media from primary cultures of glandular epithelia and stoma revealed that basal outputs were similar in both cell types but could be increased by estradiol only in epithelial cells. Tamoxifen (Tam) and trans-4-hydroxy tamoxifen (OHTam) did not affect basal PGF2 alpha outputs by secretory endometrium in organ culture and by monolayer cultures of epithelial cells, but counteracted the stimulatory effects of estradiol in both systems. The almost pure antiestrogenic activity exhibited by OHTam was at least 10 times greater than that of Tam, suggesting that the estrogen-stimulated increases in uterine PGF2 alpha output are mediated by specific estrogen receptors. Fragments of endometrium also released lipocortin, a phospholipase A2-inhibiting protein believed to mediate inhibitory effects of glucocorticoids on prostaglandin production in several types of cells. Although dexamethasone increased lipocortin and decreased PGF2 alpha output in secretory endometria in vitro, progesterone inhibited both lipocortin and PGF2 alpha output. The mechanisms by which P inhibits PGF2 alpha production remain to be elucidated.     

Dexamethasone-induced reduction of phospholipase D activity in the rat. Possible role of lipocortin

Subcutaneous injection of dexamethasone resulted in a reduction of demonstrable phospholipase D activity of rat brain and liver microsomes. Partially purified rat lung lipocortin inhibited the activity of both microsomal and partially purified rat brain phospholipase D. These results show that phospholipase D activity is suppressed by dexamethasone and one of the possible mechanisms of inhibition may be a phospholipase inhibitory protein, lipocortin.     

cDNA-cloning, sequencing and expression in glucocorticoid-stimulated quiescent Swiss 3T3 fibroblasts of mouse lipocortin I

We isolated and sequenced mouse lipocortin I cDNA clones from a lambda gt10 cDNA library prepared from Swiss 3T3 mRNA. The homology with human lipocortin I at the amino acid level is 86%. When confluent layers of Swiss 3T3 cells were stimulated with 10% fetal calf serum, expression of lipocortin I was strongly stimulated. In parallel, DNA synthesis was induced with a peak at 24 hours after glucocorticoid treatment indicating induction of cell proliferation. In the absence of serum glucocorticoid treatment provoked neither induction of DNA synthesis nor expression of lipocortin I. We conclude that serum contains an unidentified factor, which acts synergistically with glucocorticoids on cell proliferation and lipocortin I expression.     

Expression of lipocortins in human bronchial epithelial cells: effects of IL-1beta , TNF-alpha, LPS and dexamethasone

In this study, we investigated the expression of lipocortin I and II (annexin I and I in the human bronchial epithelium, both in vivo and in vitro. A clear expression of lipocortin I and II protein was found in the epithelium in sections of bronchial tissue. In cultured human bronchial epithelial cells we demonstrated the expression of lipocortin I and II mRNA and protein using Northern blotting, FACScan analysis and ELISA. No induction of lipocortin I or II mRNA or protein was observed after incubation with dexamethasone. Stimulation of bronchial epithelial cells with IL-1beta, TNF-alpha or LPS for 24 h did not affect the lipocortin I or II mRNA or protein expression, although PGE(2) and 6-keto-PGF(1alpha) production was significantly increased. This IL-1beta- and LPS-mediated increase in eicosanoids could be reduced by dexamethasone, but was not accompanied by an increase in lipocortin I or II expression. In human bronchial epithelial cells this particular glucocorticoid action is not mediated through lipocortin I or II induction.     

Cutting edge: dexamethasone negatively regulates Syk in mast cells by up-regulating SRC-like adaptor protein

We have identified Src-like adaptor protein (SLAP) as one of several dexamethasone-inducible inhibitory regulators in mast cells. SLAP is a known inhibitor of T cell signaling and interacts with the tyrosine kinase, Zap70. Exposure of RBL-2H3 mast cells to dexamethasone markedly increased expression of SLAP. Cells so exposed or made to overexpress SLAP exhibited reduced Ag-stimulated phosphorylation of Syk (a cognate of Zap70), linker for activation of T cells, phospholipase Cgamma, and ERK. Ca(2+) mobilization, Ca(2+)-dependent degranulation, and ERK-dependent release of arachidonic acid were suppressed as well. Small interfering RNA directed against SLAP blocked the induction of SLAP and reversed the inhibitory effects of dexamethasone on phosphorylation of Syk, linker for activation of T cells, and phospholipase Cgamma, but not downstream events, which are likely suppressed by up-regulation of downstream of tyrosine kinase-1 and MAPK phosphatase-1. The induction of these inhibitory regulators may contribute to the immunosuppressive activity of dexamethasone in mast cells.     

Inhibition by glucocorticoids of tumor necrosis factor-mediated cytotoxicity. Evidence against lipocortin involvement

The role of the phospholipase inhibitor proteins, lipocortin-I and -II, in tumor necrosis factor (TNF)-mediated cytotoxicity against L929 fibrosarcoma cells was investigated. We previously reported that TNF-mediated cytotoxicity was inhibited by dexamethasone (DEX), suggesting an involvement of lipocortins. Now we show that, despite inhibition by DEX of TNF-induced arachidonic acid release, DEX has no effect on the synthesis of these lipocortins. Moreover, TNF itself has no effect on the synthesis and phosphorylation of lipocortin-I and -II. Also there was no difference in expression levels of lipocortin-I and -II between TNF-sensitive and -resistant cells. These data strongly suggest that the protective effect of DEX and other glucocorticoids is not mediated by lipocortins.     

Glucocorticoid-induced insulin resistance in vitro: inhibition of insulin-stimulated methylaminoisobutyric acid uptake

We have previously developed an in vitro model for the induction of insulin resistance by glucocorticoids using 3T3-L1 fat cells (Grunfeld, Baird, Van Obberghen and Kahn 1981). In this model, glucocorticoid treatment was shown to decrease insulin binding and inhibit the acute stimulation of deoxyglucose uptake by insulin. We now extend the findings in this model to examine insulin stimulated methylaminoisobutyric acid (MAIB) uptake, an event whose expression requires m-RNA and protein synthesis and takes many hours. As previously seen with insulin stimulation of deoxyglucose uptake, one day of exposure to dexamethasone had little effect on insulin stimulation of MAIB uptake. Significant inhibition of insulin-stimulated MAIB uptake was seen after 2 days of exposure, and 3 days were required for the maximum effect of the glucocorticoid. The half-maximal concentration of dexamethasone required for inhibition was 1.6 nM. Exposure to dexamethasone produced a 57% decrease in the maximal response to insulin and a small but consistant shift in the sensitivity to insulin. As seen with the acute effects of insulin, the major locus of glucocorticoid action in inhibiting insulin stimulated MAIB uptake is also after the binding of insulin to its receptor. These data indicate that the inhibitory effects of glucocorticoids on insulin action in fat cells extend to those effects of insulin which require gene expression and are not merely limited to short-term metabolic actions of insulin.     

Inhibitory effect of aspirin on cholera toxin-induced phospholipase and cyclo-oxygenase activity

Cholera toxin (CT) stimulated phospholipase activity and caused [3H]arachidonic acid (3H-AA) release in a murine macrophage/monocyte cell line. Pretreatment of cells with dexamethasone, a phospholipase A2 (PLA2) inhibitor, did not affect CT-induced 3H-AA release. In contrast, aspirin, which is an inhibitor of phospholipase C (PLC), blocked CT-induced 3H-AA release and subsequent prostaglandin (PC) synthesis. The inhibitory effect of aspirin was dose dependent, with 4 mM reducing the CT response by approximately 50%. Similarly, inhibition was time dependent, occurring when the drug was added to the culture medium as late as 30 min after CT. Brief exposure (30 min) of the cells to aspirin did not alter their subsequent response to CT, but 3H-AA release from cells exposed to aspirin for 2.5 h was irreversibly inhibited. The data suggested that CT stimulation of AA metabolism may involve increased PLC activity.     

Calcium-independent phospholipases from guinea pig digestive tract as probes to study the mechanism of lipocortin

Two calcium-independent phospholipases isolated from guinea pig pancreas (lipase Ia, 37 kDa) and from guinea pig intestine (phospholipase B, 97 kDa) have been used to probe the mechanism of phospholipase inhibition by lipocortin. In the presence of calcium, both enzymes were inhibited by lipocortin I in a manner very similar to the inhibition of pig pancreas phospholipase A2. By using phospholipases that lack a requirement for calcium, we have for the first time been able to dissociate enzymatic activity from the role of calcium in the inhibitory process. It was found that lipocortin was without effect against phospholipase A1 and phospholipase B in the absence of calcium, under which conditions the inhibitory protein is unable to interact with anionic phospholipid surfaces. The same behavior toward phospholipase A1 was observed with two other related proteins, endonexin II or lipocortin V, and p68/67-kDa calelectrin or lipocortin VI. Together with the observation that lipocortins are active only in the presence of limited amounts of substrate, these data give further support to the "surface depletion model" of lipocortin inhibition, rather than to a mechanism involving a direct interaction between enzyme and inhibitor.     

Dexamethasone inhibits receptor-activated phosphoinositide breakdown in rat basophilic leukemia (RBL-2H3) cells

The activation of rat basophilic leukemia cells for histamine release is accompanied by Ca2+ influx and arachidonic acid release. IgE receptor but not A23187 ionophore stimulation of these cells also resulted in phosphoinositide breakdown. In these experiments, the culture of these cells with dexamethasone inhibited IgE- and ionophore-mediated histamine release. The concentration for 50% of maximal inhibition was 12 nM, and prolonged exposure to the drug was required, with maximal effect observed in 8 to 15 hr. The inhibitory effect of dexamethasone was reversible (t1/2 for recovery was 16 hr). Dexamethasone blocked the IgE-mediated 45Ca2+ influx and the release of [14C]-arachidonic acid (IC50 of 1 nM and 10 nM respectively). Dexamethasone inhibited the IgE receptor-mediated phosphoinositide breakdown (IC50 of 5 nM). It also decreased arachidonic acid release after A23187 stimulation demonstrating an effect on phospholipase A2. Therefore, exposure of the cells to dexamethasone results in the inhibition of both phospholipase A2 and phospholipase C pathways of arachidonic acid generation.