Conditional activation of cAMP signal transduction by protein kinase C. The effect of phorbol esters on adenylyl cyclase in permeabilized and intact cells

"Soluble" adenylyl cyclase-generated cyclic adenosine monophosphate promotes fast migration in PC12 cells

In a model for neuronal movement, PC12 cells undergo fast migration in response to nerve growth factor (NGF) and phorbol ester (PMA). We previously showed that NGF increases intracellular cAMP via activation of soluble adenylyl cyclase (sAC). In this report, we demonstrate that sAC activation is an essential component of NGF- + PMA-induced fast migration in PC12 cells. Interestingly, PMA also raises intracellular cAMP but does so by stimulating transmembrane adenylyl cyclases (tmAC); however, this tmAC-generated cAMP does not contribute to fast migration. Therefore, cells must possess independent pools of cAMP capable of modulating distinct functions.

A dual role of protein kinase C in insulin signal transduction via adenylyl cyclase signaling system in muscle tissues of vertebrates and invertebrates

Further decoding of a novel adenylyl cyclase signaling mechanism (ACSM) of the action of insulin and related peptides detected earlier (Pertseva et al. Comp Biochem Physiol B Biochem Mol Biol 1995;112:689-95 and Pertseva et al. Biochem Pharmacol 1996;52:1867-74) was carried out with special attention given to the role of protein kinase C (PKC) in the ACSM. It was shown for the first time that transduction of the insulin signal via the ACSM followed by adenylyl cyclase (AC, EC 4.6.1.1) activation was blocked in the muscle tissues of rat and mollusc Anodonta cygnea in the presence of pertussis toxin, inducing the impairment of G(i)-protein function, wortmannin, an inhibitor of phosphatidylinositol 3-kinase (PI3-K), and calphostin C, a blocker of PKC. The cholera toxin treatment of muscle membranes led to an increase in basal AC activity and a decrease in enzyme insulin reactivity. Phorbol ester and diacylglycerol activation of PKC (acute treatment) induced the inhibition of the insulin AC activating effect. This negative influence was also observed in the case of the AC system activated by biogenic amines. It was first concluded that the ACSM of insulin action involves the following signaling chain: receptor tyrosine kinase => G(i) (betagamma) => PI3-K => PKCzeta (?) => G(s) => AC => adenosine 3',5'-cyclic monophosphate. It was also concluded that the PKC system has a dual role in the ACSM: (1) a regulatory role (PKC sensitive to phorbol esters) that is manifested as a negative feedback modulation of insulin signal transduction via the ACSM; (2) a transductory role, which consists in direct participation of atypical PKC (PKCzeta) in the process of insulin signal transduction via the ACSM.

Structural determinants for post-transcriptional stabilization of lactate dehydrogenase A mRNA by the protein kinase C signal pathway

Activation of protein kinase C (PKC) and protein kinase A (PKA) in rat C6 glioma cells increases the half-life of short-lived lactate dehydrogenase (LDH)-A mRNA about 5- and 8-fold, respectively. PKA and PKC act synergistically and prolong LDH-A mRNA half-life more than 21-fold. Similar effects were observed after transfection and transcription of a globin/lactate dehydrogenase minigene consisting of a beta-globin expression vector in which the 3'-untranslated region (UTR) of beta-globin had been replaced with the LDH-A 3'-UTR. Synergism was only obtained by transcription of minigenes containing the entire 3'-UTR and did not occur when truncated 3'-UTR fragments were analyzed. Additional mutational analyses showed that a 20-nucleotide region, named PKC-stabilizing region (PCSR), is responsible for mediating the stabilizing effect of PKC. Previous studies (Tian, D., Huang, D., Short, S., Short, M. L., and Jungmann, R. A. (1998) J. Biol. Chem. 273, 24861-24866) have demonstrated the existence of a cAMP-stabilizing region in LDH-A 3'-UTR. Sequence analysis of PCSR identified a 13-nucleotide AU-rich region that is common to both cAMP-stabilizing region and PCSR. These studies identify a specific PKC-responsive stabilizing element and indicate that interaction of PKA and PKC results in a potentiating effect on LDH-A mRNA stabilization.

Expression of enzymes of covalent protein modification during regulated and dysregulated proliferation of mammary epithelial cells: PKA, PKC and NMT

Three proteins are functionally interlinked in the targeting of protein phosphorylation catalyzed by the C-subunit of PKA: PKA itself, AKAPs and NMT. Furthermore, in a variety of biological contexts, mechanisms exist whereby PKA and PKC are able to modulate the activity of one another. We have investigated the expression and subcellular distribution of these proteins in two models of mammary cell proliferation and differentiation--the normal rat mammary gland during pregnancy and lactation and human breast tissue before and after malignant transformation. Modulation of PKA does not acutely affect activity or sub-cellular distribution of PKC in mammary acini, nor does modulation of PKC acutely affect PKA activity or subcellular distribution. Therefore, the co-ordinate expression of these two protein kinases in normal and cancerous mammary epithelial cells and the greater basal activation level of them both accompanying increased mitogenic activity, which we have reported, does not result from short-term cross-talk between them. Although basal and total levels of PKA diminish in rodent mammary epithelial cells during the transition from proliferative to secretory functional mode, the level of expression of AKAPs increases. The expression of two apparently mammary-specific and mostly membrane-associated AKAPs is tightly linked to the onset and maintenance of differentiated function in rat mammary tissue. Paradoxically, the probable analogues of these two AKAPs in human mammary tissue are hyperexpressed when normal epithelial cells transform to a cancer phenotype--conventionally regarded as a process involving a degree of dedifferentiation. Mammary AKAP hyperexpression in breast cancers is accompanied by increases in the levels of total and basal PKA. One mechanism whereby NMT is targeted to membranes, via interaction with ribosomal proteins, has recently been elucidated. Our data support the contention that the localization of NMT is an important variable in the regulation of cellular proliferation, but they do not characterize the mechanisms whereby the differential targeting of NMT is achieved. As yet we lack a full tool-kit with which to examine NMT either to draw firm conclusions regarding the identity of particular isoforms found in particular sub-cellular locations or to define the relationships between these different molecular variants. However, it is technically possible to transfect cells with inducible NMT expression constructs engineered in such a way that the recombinant, catalytically competent, NMT that they encode is targeted either to membranes or to cytosol: an exploration of the effects of such transfections on cellular proliferation would afford a critical test of the mechanistic involvement of NMT in the control of mitogenesis.

Glucocorticoids stimulate CREB binding to a cyclic-AMP response element in the rat serine dehydratase gene

Transcription of the rat serine dehydratase (SDH) gene, which is stimulated in hepatocytes by glucagon through the activity of the second messenger, cAMP, is augmented by pretreatment with glucocorticoids. A putative cAMP response element (CRE) located approximately 3.5 kbp upstream of the transcriptional start site was hypothesized to be responsible for this effect. Here we have demonstrated by DNaseI footprinting and site-directed mutagenesis that the phosphorylated cAMP response element binding protein (CREB) binds to a cAMP response element different from that described previously. While the amount of CREB in the extracts is unaltered by hormone treatment, more CREB is capable of binding the response element upon addition of dexamethasone (Dex). These studies suggest that synergistic induction of the SDH gene by cAMP and Dex is through a CRE and is due, in part, to regulation of CREB-DNA binding by treatment of the cells with glucocorticoids.

Opposing regulatory effects of protein kinase C on the cAMP cascade in human HL-60 promyelocytic leukemia cells

The functional role of protein kinase C in the cAMP signaling cascade was investigated in human promyelocytic leukemia (HL-60) cells. Protein kinase C activation after short exposure to 100 nM phorbol 12-myristate 13-acetate (PMA) increased the intracellular cAMP level up to 3- to 5-fold after 30 min. Such enhancement was almost completely blocked by the selective protein kinase C inhibitor bisindolylmaleimide (GF 109203X). In addition, PMA, but not 4-alpha-PMA, synergistically elevated cAMP levels when adenylyl cyclase was activated directly by forskolin or indirectly by G protein activation after cholera toxin treatment or guanosine 5'-O-(3-thiotriphosphate) (GTPgammaS) treatment in digitonin-permeabilized cells. The results indicate that protein kinase C directly increases adenylyl cyclase activity and synergistically enhances it, when it is simultaneously activated otherwise. On the other hand, a 10-min treatment with PMA cut the cAMP accumulation induced by histamine, prostaglandin E2, or isoproterenol by 50-70%. However, the binding affinity and total binding of [3H]histamine to membrane receptors was not effected by PMA, suggesting that the site of protein kinase C's action is not at the receptor level. Western blot analysis of protein kinase C isozymes revealed that PMA (100 nM) caused translocation of cytosolic protein kinase C such as alpha, beta and epsilon to the particulate/membrane fraction. Treatment with a lower concentration of PMA (10 nM) translocated the protein kinase C-epsilon within 2 min, while it had little effect on the translocation of protein kinase C-alpha and -beta up to 20 min. However, simultaneous treatment with 10 nM PMA plus histamine for 5 min significantly inhibited the histamine-mediated cAMP generation, indicating that the protein kinase C-epsilon could be involved in the inhibition of receptor-mediated cAMP generation. Taken together, we conclude that PMA, through the activation of protein kinase C, has two opposite effects on the cAMP signaling cascade in HL-60 cells: a direct activation of adenylyl cyclase and an inhibition of receptor-mediated signal transduction.

The cAMP-dependent protein kinase A and protein kinase C-beta pathways synergistically interact to activate HIV-1 transcription in latently infected cells of monocyte/macrophage lineage

The HIV-1 long terminal repeat (LTR) responds to a variety of cellular signal transduction pathways. We demonstrate that the cAMP-dependent protein kinase A (PKA) and protein kinase C (PKC) signaling pathways synergize to increase HIV-1 LTR-mediated transcription and viral replication in a latently infected promonocytic cell line (U1). The LTR-mediated synergy induced by cholera toxin (Ctx), a potent activator of the cAMP-dependent PKA pathway, and the PKC activator phorbol 12-myristate 13-acetate (PMA) was abrogated by a PKC-beta-specific inhibitor (LY333531). In contrast, the LTR-mediated synergy induced by Ctx and TNF alpha was not affected by LY333531. The synergy induced by Ctx and TNF alpha was also abrogated by mutation of the cAMP-responsive downstream sequence elements (DSE) in the 5' untranslated leader region, whereas the DSE mutations did not affect the synergy induced by Ctx and PMA. These distinctions indicate that Ctx cooperates differently with TNF alpha and PMA to activate the HIV-1 LTR. Ctx and PMA synergistically activated AP-1- and NF-kappa B-dependent transcription, even though no cooperative binding of AP-1 or NF-kappa B was observed in gel shift assays. An extensive mutational analysis of the HIV-1 LTR that included the NF-kappa B and AP-1 binding sites revealed no distinct cis-acting element or region within the HIV-1 LTR that was required for the transcriptional synergy. Ctx and PMA also synergistically interact to activate the HTLV-1 LTR. These results indicate that the transcriptional synergy elicited by Ctx and PMA targets multiple functional elements and promoters, requires a cooperative interaction between the PKA and PKC-beta pathways, and differs mechanistically from the transcriptional synergy induced by Ctx and TNF alpha.

PDGF-stimulated cyclic AMP formation in airway smooth muscle: assessment of the roles of MAP kinase, cytosolic phospholipase A2, and arachidonate metabolites

Platelet-derived growth factor (PDGF) stimulates cyclic AMP (cAMP) synthesis in cultured guinea-pig airway smooth muscle (ASM) cells. However, this stimulation is normally countered by the action of cAMP phosphodiesterases. Thus, cAMP synthesis was observed only in cells pre-treated with either 3-isobutyl-1-methylxanthine (IBMX) or with cholera toxin. cAMP synthesis was inhibited by pre-treating cells with well-defined inhibitors of arachidonate metabolite synthesis, such as AACOCF3 [a cytosolic phospholipase A2 (cPLA2) inhibitor] and indomethacin (a cyclooxygenase inhibitor). This suggests that arachidonate metabolites (e.g., prostaglandins) released in response to PDGF stimulate cAMP synthesis. The presence of functional prostaglandin (PG) receptors was confirmed by experiments that showed that exogenous PGE2 stimulated cAMP formation. cPLA2 is regulated by mitogen-activated protein kinase (MAPK) in a number of cell types. The presence of this pathway in ASM cells and its role in regulating arachidonate metabolism were supported by the finding that pre-treatment of cells with PD098059 (an inhibitor of mitogen-activated protein kinase kinase-1 activation) reduced PDGF-stimulated cAMP synthesis. The cAMP formed in response to the arachidonate metabolites subsequently reduced the PDGF-dependent activation of c-Raf, MAPK, and DNA synthesis, suggesting the presence of a negative feedback pathway.

Involvement of protein kinase C in the UTP-mediated potentiation of cyclic AMP accumulation in mouse J774 macrophages

1. We have investigated the effects of nucleotide analogues on cyclic AMP formation in mouse J774 macrophages and the mechanisms involved. 2. UTP, in the concentration range 0.1-100 microM, induced concentration-dependent potentiation of prostaglandin E1 (PGE1)-induced cyclic AMP formation, but had no effect on basal cyclic AMP formation. UDP showed an equal potency, while 2-methylthio ATP, alpha, beta-methylene ATP and beta,gamma-methylene ATP gave either a slight increase or had no effect at concentrations up to 100 microM. ATP, although 100 fold less effective than UTP, also caused cyclic AMP potentiation, but had no effect on agonist-stimulated or basal cyclic AMP levels. 3. The cyclic AMP potentiation effect of UTP correlated with increased [Ca2+]i and inositol phosphate (IP) formation over the same concentration range. 4. Ionomycin, which evokes an increase in [Ca2+]i without affecting IP formation, did not cause an increase in cyclic AMP content, indicating that UTP-induced cyclic AMP regulation is not due to activation of Ca(2+)-sensitive adenylyl cyclase isoforms. 5. Although reduced, UTP potentiation was seen in cells incubated in a Ca(2+)-free and/or BAPTA-containing medium. Under these conditions, the UTP-increased IP accumulation was similarly reduced. 6. Exposure of cells to phorbol 12-myristate 13-acetate (PMA) also increased PGE1 stimulation of cyclic AMP levels, and the UTP-induced potentiation of cyclic AMP formation was inhibited by either staurosporine or Ro 31-8220. Pretreatment of cells with PMA for 4-24 h resulted in marked attenuation of UTP-stimulated cyclic AMP potentiation. 7. Pretreatment with pertussis toxin (24 h, 100 ng ml-1) did not significantly affect UTP-induced cyclic AMP potentiation and IP formation, although it increased the cyclic AMP response to PGE1. 8. Analysis of J774 cells by Western blotting with antibodies specific for different protein kinase C (PKC) isoforms shows the presence of the beta I, beta II, delta, epsilon, eta, mu, lambda and zeta isoforms. Moreover, UTP significantly increased the level of PKC beta I, beta II, delta, epsilon, mu, lambda and zeta immunoreactivity in the membrane fraction and decreased the cytosolic reactivity of PKC beta II, delta, epsilon and zeta. 9. Immunoblot studies also indicate the presence of type II adenylyl cyclase. 10. These results indicate that PKC is required for the potentiation of adenylyl cyclase activity by macrophage pyrimidinoceptors, which exhibit a higher specificity for UTP and UDP than for ATP.

Modulation of cyclic AMP levels in a clonal neural cell line by inhibitors of tyrosine phosphorylation

The convergence of tyrosine kinase and cyclic AMP (cAMP) signal transduction pathways was investigated in the HT4.7 neural cell line with inhibitors of tyrosine kinases and tyrosine phosphatases. The protein tyrosine kinase inhibitor genistein inhibited isoproterenol-stimulated cAMP production by 40-60% in whole cells, with no effect on basal cAMP levels. In both whole cells and membranes, genistein also inhibited cAMP produced in response to direct stimulation of adenylyl cyclase with forskolin. However, in the absence of phosphodiesterase inhibitors, genistein presentation resulted in an increase in cAMP levels. Genistein inhibited phosphodiesterase activity by 80-85%, indicating that tyrosine phosphorylation stimulates both cAMP synthesis and degradation. The decrease in cAMP levels by genistein was not merely competitive inhibition of adenylyl cyclase with respect to ATP, since the Km of adenylyl cyclase for ATP remained essentially the same in either the presence or the absence of genistein. Another tyrosine kinase inhibitor, herbimycin A, which inhibits by a different mechanism than genistein, also decreased forskolin-stimulated cAMP in whole cells. As would be expected for the involvement of tyrosine phosphorylation in the control of cAMP production, inhibition of tyrosine phosphatases by vandate increased forskolin-stimulated cAMP production. These results suggest that cAMP production can be regulated by tyrosine phosphorylation, and the simultaneous activation of both cAMP synthesis and degradation may serve to alter the duration of cAMP elevation.

Ethanol differentially affects metabolic and mitotic processes in chick embryonic cells

Our laboratory has been investigating the mechanisms by which ethanol-induced growth inhibition occurs in a developing embryo, and our studies have focused on disruption of cellular signaling pathways. Previous work on ethanol-induced changes in signaling systems that regulate ornithine decarboxylase activity indicated that the pathways containing protein kinase A, protein kinase C (PKC), and insulin-dependent tyrosine kinase were important for the control of ornithine decarboxylase in chick embryonic cells. Herein, we report ethanol's effect on the regulation of glucose uptake and thymidine uptake by these same kinase pathways. A pronounced increase in glucose uptake was associated with PKC downregulation in both vehicle- and ethanol-exposed cells, with the larger increase occurring in ethanol-exposed cells. An increase in thymidine uptake was associated with an activation of all three kinases, as well as with downregulation of PKC. Because previous work on signaling pathways has looked for changes in the insulin signaling pathway, the work herein focuses on the signaling pathways involving protein kinase A and PKC. cAMP levels were increased by ethanol treatment, but the increase was relatively small. Analysis of changes in PKC activity induced by ethanol exposure showed a significant suppression of PKC activity in the ethanol-treated cells and suggested that, overall, ethanol treatment affects the regulation of glucose uptake in embryonic cells predominantly by PKC downregulation.

G protein beta gamma subunits

Guanine nucleotide binding (G) proteins relay extracellular signals encoded in light, small molecules, peptides, and proteins to activate or inhibit intracellular enzymes and ion channels. The larger G proteins, made up of G alpha beta gamma heterotrimers, dissociate into G alpha and G beta gamma subunits that separately activate intracellular effector molecules. Only recently has the G beta gamma subunit been recognized as a signal transduction molecule in its own right; G beta gamma is now known to directly regulate as many different protein targets as the G alpha subunit. Recent X-ray crystallography of G alpha, G beta gamma, and G alpha beta gamma subunits will guide the investigation of structure-function relationships.

Protein kinase Cs and tyrosine kinases in permissive action of prostacyclin on cerebrovascular regulation in newborn pigs

The involvement of protein kinase C (PKC) and protein tyrosine kinase (PTK) in hypercapnia-induced cerebral vasodilation in newborn pigs was investigated with closed cranial windows using the PKC stimulator phorbol 12-myristate 13-acetate (PMA), and the PTK inhibitors, genistein and herbimycin A. The influence of prostaglandin I2 was eliminated using the prostaglandin cyclooxygenase inhibitor, indomethacin. Changes in pial arteriolar diameters in response to hypercapnia [partial pressure of arterial CO2 approximately 9.3 kPa (70 torr)] were analyzed. Genistein (40 micrograms/mL), herbimycin A (10 microM), or PMA (1 microM) did not affect cerebral vasodilation to hypercapnia when applied topically. Indomethacin (5 mg/kg i.v.) treatment blocked the dilation to hypercapnia and attenuated hypercapnia-induced increase in cortical cAMP. Genistein and herbimycin A restored the response to hypercapnia to indomethacin-treated piglets. PMA also restored the pial arteriolar dilation and the cAMP response to hypercapnia to indomethacin-treated piglets. One-hour exposure to 10 microM PMA, to down-regulate PKC, blocked vasodilation to hypercapnia but did not inhibit vasodilation to sodium nitroprusside. After prolonged (2 h) topical exposure of indomethacin-treated piglets to 10 microM PMA, neither genistein nor iloprost could restore dilation to hypercapnia. These results indicate that PKC stimulation and/or PTK inhibition may permit hypercapnia-induced vasodilation. These data further suggest that PKC is downstream from PTK in the regulatory pathway. Because previous data showed prostaglandin I2 at subdilator concentrations can also return dilation to hypercapnia to piglets treated with indomethacin, prostaglandin I2 could provide its permissive input by activating PKC and/or inhibiting PTK.

P2 purinergic receptor agonists enhance cAMP production in Madin-Darby canine kidney epithelial cells via an autocrine/paracrine mechanism

Mechanisms of cross-talk between different classes of signaling molecules are inadequately understood. We have used clonal Madin-Darby canine kidney (MDCK-D1) epithelial cells as a model system to investigate the effects of extracellular nucleotides (e.g. ATP, UTP), which promote increase in activity of several phospholipases, on cAMP production. In contrast to observations in some other cell systems, ATP and UTP, acting via P2 purinergic receptors, stimulated cAMP production in MDCK-D1 cells. At maximally effective concentrations, ATP and UTP were not additive with the beta-adrenergic receptor agonist isoproterenol, but were synergistic with forskolin in increasing cAMP production, indicating that G alpha s is activated by these nucleotides. Additionally, we found that (a) nucleotide-induced increases in cAMP were blocked by indomethacin, a cyclooxygenase inhibitor, (b) arachidonic acid increased cellular cAMP levels in an indomethacin-sensitive fashion, and (c) PGE2, the major metabolite of arachidonic acid, stimulated cAMP formation. Overall, our results suggest a mechanism by which extracellular nucleotides stimulate release of arachidonic acid which is metabolized to PGE2 which, in turn, acts in an autocrine/paracrine fashion via prostaglandin receptors to activate G alpha s and increase cAMP. Based on the ability of extracellular nucleotides to stimulate the formation and release of prostaglandins in MDCK-D1 epithelial and other cells, we hypothesize that receptor-mediated prostaglandin release may be a general mechanism that regulates cAMP formation in many types of cells.

Expression of type V adenylyl cyclase is required for epidermal growth factor-mediated stimulation of cAMP accumulation

Previously, this laboratory has demonstrated that epidermal growth factor (EGF) increases adenylyl cyclase activity in cardiac membranes and elevates cAMP accumulation in hearts and cardiac myocytes. Since EGF does not increase cAMP accumulation in all tissues, we investigated the possibility that the expression of a specific isoform of adenylyl cyclase (AC) was necessary to observe EGF-elicited stimulation of cAMP accumulation. HEK 293 cells were transfected with different isoforms of AC, and the ability of EGF to increase AC activity as well as elevate cAMP accumulation was determined. In cells transfected with AC I, II, V, and VI cDNAs, neither the expression nor the amount of the two isoforms of Gs alpha (45 and 52 kDa) were altered. Similarly, EGF-elicited phosphorylation of cellular proteins on tyrosine residues in various transfectants was unaltered. However, EGF increased AC activity and elevated cAMP accumulation only in cells expressing the rat and canine ACV. EGF did not alter either AC activity or cAMP accumulation in cells overexpressing types I, II, and VI isozymes. As assessed by the ability of an anti-Gs alpha antibody to obliterate the effect, stimulation of AC activity in AC V transfectants involved the participation of Gs alpha, a finding consistent with previous data concerning EGF effects on cardiac AC (Nair, B. G., Parikh, B., Milligan, G., and Patel, T. B. (1990) J. Biol. Chem. 265, 21317-21322). Thus we conclude that the expression of AC V isoform confers specificity to the ability of EGF to stimulate AC activity.

Characteristics of the alpha 2/beta 2-adrenergic receptor-coupled adenylyl cyclase system in rat myometrium during pregnancy

alpha 2A- and alpha 2B-adrenoreceptors (AR), identified by Northern blotting in rat myometrium, showed a differential expression during the course of pregnancy. Indeed, the alpha 2A-AR transcript was present at mid-pregnancy, whereas high levels of alpha 2B-AR mRNA could be detected at term. The role of these subtypes in modulating beta 2-AR-stimulated adenylyl cyclase activity was investigated on myometrial membranes from mid-pregnancy and term. At nanomolar concentrations of clonidine (full alpha 2-AR agonist) or oxymetazoline (partial alpha 2A-AR agonist), adenylyl cyclase activity was inhibited by up to 50 +/- 7% at mid-pregnancy or 75 +/- 7% at term, whereas at micromolar concentrations, alpha 2-AR agonists potentiate adenylyl cyclase activity by 140-170% at mid-pregnancy. Both inhibitory and stimulatory components of this biphasic response were blocked by yohimbine, a selective alpha 2-AR antagonist. Preincubation of myometrial membranes with Gi2 and/or Gi3 antisera eliminated alpha 2-AR mediated attenuation or potentiation of isoproterenol-stimulated adenylyl cyclase, thus indicating that both the inhibitory and stimulatory components are mediated via Gi2 and Gi3. In addition, type II and IV adenylyl cyclases were identified by Northern blotting in the pregnant rat myometrium. Altogether these data strongly suggest that the alpha 2A-AR at mid-pregnancy potentiates adenylyl cyclase types II and IV through beta gamma released from Gi2 and Gi3 proteins, whereas the alpha 2B-AR expression at term may be related to persistent inhibition.