Thyrotropin-releasing hormone induces redistribution of protein kinase C in GH4C1 rat pituitary cells

Thyrotropin-releasing hormone (TRH) affects hormone secretion and synthesis in GH4C1 cells, a clonal strain of rat pituitary cells. Recent evidence suggests that the intracellular mediators, inositol 1,4,5-trisphosphate and 1,2-diacylglycerol, which are generated as a result of TRH-induced hydrolysis of the polyphosphatidylinositols, may be responsible for some of the physiological events regulated by TRH. Because diacylglycerol is an activator of protein kinase C, we have examined a role for this enzyme in TRH action. The subcellular distribution of protein kinase C in control and TRH-treated cells was determined by measuring both enzyme activity and 12,13-[3H]phorbol dibutyrate binding in the cytosol and by measuring enzyme activity in the particulate fraction. Acute exposure of GH4C1 cells to TRH resulted in a decrease of cytosolic protein kinase C, and an increase in the level of the enzyme associated with the particulate fraction. The redistribution of protein kinase C induced by TRH was dose- and time-dependent, with maximal effects occurring within the first minute of TRH treatment. Analogs of TRH which do not bind to the TRH receptor did not induce redistribution of protein kinase C, while the active analog, methyl-TRH, did promote redistribution. Treatment of GH4C1 cells with phorbol myristate acetate also resulted in a shift in protein kinase C distribution, although the response was slower than that produced by TRH. TRH-induced redistribution of protein kinase C implies translocation of the enzyme from a soluble to a membrane-associated form. Because protein kinase C requires a lipid environment for activity, association with the membrane fraction of the cell suggests activation of the enzyme; thus, protein kinase C may play a role in some of the actions of TRH on GH4C1 cells.     

Thyrotropin-releasing hormone and phorbol esters induce phosphatidylcholine synthesis in GH3 pituitary cells. Evidence for stimulation via protein kinase C

Phorbol esters have been shown to stimulate phosphatidylcholine synthesis via the CDP-choline pathway. The present study compares the effects of phorbol esters and thyrotropin-releasing hormone (TRH) on phosphatidylcholine metabolism in GH3 pituitary cells. In a previous study (Kolesnick, R.N., and Paley, A.E. (1987) J. Biol. Chem. 262, 9204-9210), the potent phorbol ester, 12-O-tetradecanoylphorbol 13-acetate (TPA) induced time- and concentration-dependent incorporation of 32Pi and [3H]choline into phosphatidylcholine in short-term labeling experiments. In this study, TPA is shown to activate choline-phosphate cytidylyltransferase (EC 2.7.7.15), the regulatory enzyme of the CDP-choline pathway, by stimulating redistribution of the inactive cytosolic form of the enzyme to the membrane. Redistribution was quantitative. TPA reduced cytosolic activity from 3.5 +/- 0.4 to 1.5 +/- 0.3 nmol . min-1 x 10(7) cells-1 and enhanced particulate activity from 2.5 +/- 0.4 to 4.9 +/- 0.6 nmol . min-1 x 10(7) cells-1. TRH also stimulated time- and concentration-dependent 32Pi and [3H]choline incorporation into phosphatidylcholine. An increase was detectable after 5 min; and after 30 min, the levels were 164 +/- 9 and 150 +/- 11% of control, respectively; EC50 congruent to 2 X 10(-10) M TRH. These events correlated directly with TRH-induced 32Pi incorporation into phosphatidylcholine. TRH also stimulated redistribution of cytidylyl-transferase specific activity. TRH reduced cytosolic activity 45% and enhanced particulate activity 51%. Neither TRH nor TPA stimulated phosphatidylcholine degradation. In cells down-modulated for protein kinase C (Ca2+/phospholipid-dependent protein kinase), the effects of TPA and TRH on 32Pi incorporation into phosphatidylcholine were abolished. However, TRH-induced incorporation into phosphatidylinositol still occurred. These studies provide evidence that hormones may regulate phosphatidylcholine metabolism via the protein kinase C pathway.     

Ionomycin inhibits thyrotropin-releasing hormone-induced translocation of protein kinase C in GH4C1 pituitary cells

Thyrotropin-releasing hormone (TRH) induces rapid and transient conversion of protein kinase C (Ca2+/phospholipid-dependent enzyme) from a soluble to a particulate-bound form in GH4C1 rat pituitary cells. Ionomycin (200 nM), a calcium ionophore, had no effect by itself on the subcellular distribution of protein kinase C. However, pretreatment of the cells with 200 nM ionomycin inhibited by greater than 50% the ability of TRH to cause translocation of protein kinase C from the cytosol to the particulate cell fraction. Inhibition by ionomycin required that the cells be incubated with the ionophore for at least 10 s before TRH addition. Ionomycin pretreatment did not alter the kinetics of TRH-induced protein kinase C redistribution. Incubation of the cells with 43 mM potassium prior to TRH addition almost completely reversed the inhibition induced by ionomycin. We propose that the mechanism by which ionomycin attenuates TRH action on protein kinase C may involve the capacity of the ionophore to empty the intracellular calcium reservoir which normally releases calcium into the cytosol in response to TRH. Our result provides evidence that the rise in intracellular calcium, which accompanies diacylglycerol formation following TRH action on polyphosphatidylinositide hydrolysis, may be required to achieve maximal conversion of protein kinase C to its presumed active, membrane-bound form in these cells.     

Activation of alpha-protein kinase C leads to association with detergent-insoluble components of GH4C1 cells

TRH and phorbol dibutyrate (PDBu) stimulate PRL secretion and synthesis from GH4C1 rat pituitary cells through activation of protein kinase C (PKC). TRH responses are mediated by increases in cellular levels of two PKC activators, Ca2+ and diacylglycerol (DAG), whereas PDBu acts as a DAG analog. We conducted experiments to compare the effects of Ca2+ and PDBu/DAG on alpha-PKC redistribution and to determine to what components of the particulate fraction activated alpha-PKC associates. Subcellular fractionation experiments demonstrated that TRH and PDBu both caused chelator-stable association of alpha-PKC with the particulate fraction. In contrast, Ca2+-mediated association with the particulate fraction was not chelator stable. Immunocytofluorescence experiments also demonstrated that TRH, PDBu, and increased cytosolic Ca2+ (due to ionomycin or K+ depolarization) caused redistribution. The effect of TRH was rapid and transient, similar to TRH stimulation of phospholipase C. The translocated alpha-PKC in the particulate fraction from TRH- or PDBu-treated cultures was not solubilized with Triton X-100. In comparable studies using an immunofluorescence assay, alpha-PKC immunofluorescence remained in detergent-insoluble preparations from TRH- and PDBu-stimulated, but not resting cells. The association of activated alpha-PKC with chelator- and detergent-insoluble material suggested that activated alpha-PKC may be associated with membrane and cytoskeletal components.     

Thyrotropin releasing hormone

Summary Thyrotropin releasing hormone (TRH) acutely stimulates release of thyrotropin (TSH) and prolactin from anterior pituitary cells. A considerable number of studies have been performed with neoplastic and nonneoplastic pituitary cells in culture to elucidate the sequence of intracellular events involved in this action. Although cyclic AMP was suggested as an intracellular messenger, it has been demonstrated that TRH stimulation of hormone release can be dissociated from changes in cyclic AMP concentration, thereby supporting the contention that cyclic AMP is not a required mediator. In contrast, stimulation of hormone release by TRH requires Ca²⁺ and it seems likely that Ca²⁺ is the intracellular coupling factor between TRH stimulation and hormone secretion. TRH has been shown to stimulate ⁴⁵Ca²⁺ efflux from preloaded pituitary cells. Enhanced ⁴⁵Ca²⁺ efflux is thought to reflect an increase in the free intracellular Ca²⁺ concentration which leads to hormone release; however, the source of this Ca^2– is uncertain. Results are reviewed from a series of experiments in pituitary cells which attempt to determine the pool (or pools) of Ca²⁺ that is affected by TRH. These include the following: the effects of decreasing the extracellular Ca^2– concentration on hormone release stimulated by TRH; the effect of TRH on cellular Ca²⁺ as monitored by chlortetracycline; the effects of TRH on Ca²⁺ influx; the effects of the organic Ca²⁺ channel blocking agents, verapamil and methoxyverapamil, on TRH-stimulated hormone release; and the effects of TRH on plasma membrane potential difference and on Ca²⁺-dependent action potentials. Based on these data, separate hypotheses of the early events in TRH stimulation of hormone release in mammotropes and thyrotropes are proposed. In mammotropes, TRH is thought to stimulate prolactin release optimally by elevating the free intracellular Cat+ concentration by mobilizing cellular Ca^2– only. In contrast, in thyrotropes under normal physiological conditions, TRH is thought to stimulate TSH release by mobilizing Ca² from a cellular pool (or pools) and to augment this effect by also inducing influx of extracellular Ca²⁺ through voltage-dependent channels in the plasma membrane.     

Identification and subcellular localization of molecular complexes of Gq/11α protein in HEK293 cells

Heterotrimeric G-proteins localized in the plasma membrane convey the signals from G-protein-coupled receptors (GPCRs) to different effectors. At least some types of G-protein α subunits have been shown to be partly released from plasma membranes and to move into the cytosol after receptor activation by the agonists. However, the mechanism underlying subcellular redistribution of trimeric G-proteins is not well understood and no definitive conclusions have been reached regarding the translocation of Gα subunits between membranes and cytosol. Here we used subcellular fractionation and clear-native polyacrylamide gel electrophoresis to identify molecular complexes of G(q/11)α protein and to determine their localization in isolated fractions and stability in na?ve and thyrotropin-releasing hormone (TRH)-treated HEK293 cells expressing high levels of TRH receptor and G(11)α protein. We identified two high-molecular-weight complexes of 300 and 140 kDa in size comprising the G(q/11) protein, which were found to be membrane-bound. Both of these complexes dissociated after prolonged treatment with TRH. Still other G(q/11)α protein complexes of lower molecular weight were determined in the cytosol. These 70 kDa protein complexes were barely detectable under control conditions but their levels markedly increased after prolonged (4-16 h) hormone treatment. These results support the notion that a portion of G(q/11)α can undergo translocation from the membrane fraction into soluble fraction after a long-term activation of TRH receptor. At the same time, these findings indicate that the redistribution of G(q/11)α is brought about by the dissociation of high-molecular-weight complexes and concomitant formation of low-molecular-weight complexes containing the G(q/11)α protein.     

Metabolism of thyrotropin releasing hormone in brain extracts. Isolation and characterization of an imidopeptidase for histidylprolineamide.

An extract of porcine brain acetone powder incubated with thyrotropin-releasing hormone (TRH; pGlu-His-ProNH2) produces acid TRH (pGlu-His-Pro), histidine, and prolineamide. Fractionation of the brain extract by DEAE-cellulose chromatography produces three protein fractions which metabolize TRH. The activity of these fractions was characterized using TRH with a 3H-label on the histidine or proline as well as [His-3H]His-ProNH2. Fraction I contains pyroglutamate aminopeptidase and Fraction II contains TRH deamidase. Fraction III was found to contain a previously unrecognized enzyme which cleaves His-ProNH2 to histidine and proline. The histidylprolineamide imidopeptidase has been characterized. A competition study using a variety of compounds containing histidine or proline suggests that the best substrates for the imidopeptidase contain a free alpha-amino group on histidine and a blocked carboxyl group on proline, as is found in His-ProNH2. A survey of a variety of polypeptide hormones indicates that many of them inhibit the imidopeptidase activity. A kinetic study of the inhibition of the enzyme by adrenocorticotropic hormone (1-24) shows that the inhibition by polypeptide hormones is noncompetitive. We hypothesize that pituitary hormones may stimulate the production of (cyclo)-His-Pro by inhibiting alternate routes of TRH metabolism.     

Regulation of protein kinase C after stimulation of alpha 1-adrenoceptors in rat hippocampus.

Endogenous inhibitor of protein kinases (type II inhibitor, GABA-modulin) blocks the phosphorylation catalyzed by cAMP-dependent protein kinase (PKA) and protein kinase C (PKC) as a competitive inhibitor of substrate proteins when histone is used as a substrate. Moreover, type II inhibitor blocks the phosphorylation of endogenous membrane proteins by PKC. Stimulation of alpha 1-adrenoceptors induced rapid redistribution of PKC from cytosol to membrane fraction which lasted at least 3 h, accompanied by rapid and short-lasting translocation of type II inhibitor from membrane to cytosol fraction. The cytosol content of type II inhibitor reached maximal level 10 and 20 min and became normal again 40 min after i.p. administration of methoxamine. The above actions of methoxamine were completely blocked by pretreatment with prazosin. It seems that short-lasting redistribution of type II inhibitor from membrane to cytosol fraction allows the effective phosphorylation of membrane proteins by PKC after stimulation of alpha 1-adrenoceptors.     

Spatial-temporal patterning of metabotropic glutamate receptor-mediated inositol 1,4,5-triphosphate, calcium, and protein kinase C oscillations: protein kinase C-dependent receptor phosphorylation is not required.

The metabotropic glutamate receptors (mGluR), mGluR1a and mGluR5a, are G protein-coupled receptors that couple via G(q) to the hydrolysis of phosphoinositides, the release of Ca(2+) from intracellular stores, and the activation of protein kinase C (PKC). We show here that mGluR1/5 activation results in oscillatory G protein coupling to phospholipase C thereby stimulating oscillations in both inositol 1,4,5-triphosphate formation and intracellular Ca(2+) concentrations. The mGluR1/5-stimulated Ca(2+) oscillations are translated into the synchronized repetitive redistribution of PKCbetaII between the cytosol and plasma membrane. The frequency at which mGluR1a and mGluR5a subtypes stimulate inositol 1,4,5-triphosphate, Ca(2+), and PKCbetaII oscillations is regulated by the charge of a single amino acid residue localized within their G protein-coupling domains. However, oscillatory mGluR signaling does not involve the repetitive feedback phosphorylation and desensitization of mGluR activity, since mutation of the putative PKC consensus sites within the first and second intracellular loops as well as the carboxyl-terminal tail does not prevent mGluR1a-stimulated PKCbetaII oscillations. Furthermore, oscillations in Ca(2+) continued in the presence of PKC inhibitors, which blocked PKCbetaII redistribution from the plasma membrane back into the cytosol. We conclude that oscillatory mGluR signaling represents an intrinsic receptor/G protein coupling property that does not involve PKC feedback phosphorylation.     

Subsecond and second changes in inositol polyphosphates in GH4C1 cells induced by thyrotropin-releasing hormone.

It has been demonstrated previously that thyrotropin-releasing hormone (TRH) induces changes in inositol polyphosphates in the GH3 and GH4C1 strains of rat pituitary cells within 2.5-5.0 s. TRH also causes a rapid rise in cytosolic free calcium concentration ([Ca2+]i) in these cells which is due largely to redistribution of cellular calcium stores. Therefore, it has been concluded that TRH acts to release sequestered calcium in these cells via enhanced generation of inositol 1,4,5-trisphosphate [Ins(1,4,5)P3]. If this conclusion were correct, TRH-enhanced accumulation of Ins(1,4,5)P3 should occur at least as rapidly as the increase in [Ca2+]i. We have shown previously that the rise in [Ca2+]i induced by TRH occurs within about 400 ms; thus, it was important to investigate the subsecond time-course of changes in inositol phosphates caused by TRH. Using a rapid mixing device, we have measured changes in inositol polyphosphates on a subsecond time scale in GH4C1 cells prelabelled with myo-[2-3H]inositol. Although TRH did alter inositol polyphosphate metabolism within 500 ms, the changes observed did not reveal a statistically significant increase in Ins(1,4,5)P3 within time intervals of less than 1000 ms. Thus, we have been unable to demonstrate that a TRH-induced rise in Ins(1,4,5)P3 precedes or occurs concomitantly with the rise in [Ca2+]i in GH4C1 cells. Although these results do not disprove the current view that Ins(1,4,5)P3 mediates the action of TRH on intracellular calcium redistribution, we conclude that caution should be exercised in this, and possibly other cell systems, in accepting the dogma that all of the rapid, agonist-induced redistributions of intracellular calcium are mediated by Ins(1,4,5)P3.     

Soluble precursor of membrane-associated protein kinase in uterine smooth muscle cells

Incubation of smooth muscle strips from rat uterus with isoproterenol resulted in redistribution of protein kinase activity between the cytosol and a 20,000 to 50,000g membrane fraction. Similarities in the elution properties of the cytosolic and membrane-associated forms of the enzyme on DEAE-cellulose ion exchange chromatography further suggested the two forms were the same. The nature of membrane binding of the soluble enzyme was investigated using smooth muscle microsomal and cytosol fractions. Membranes readily bound the soluble enzyme when the two subcellular compartments were reconstituted and incubated at 30 °C for 10 min. The extent of binding was proportional to the ratio of membranes to cytosol and was characterized by the inhibition of soluble enzyme activity toward exogenous substrates in a Triton X-100 reversible manner. In marked contrast to the binding of soluble protein kinase to heart particulate fractions, binding of the cytosol enzyme to smooth muscle cell membranes was unaffected by ionic strength or cAMP. The latter property indicated holoenzyme was bound in a manner similar to the free catalytic subunit of cAMP-dependent protein kinase and suggested the enzyme was bound by association between the membrane and the catalytic subunit. Binding of cytosol protein kinase to the membranes rendered the enzyme insensitive to trypsin digestion and the capacity of the smooth muscle cell membranes to bind the soluble enzyme exceeded that of other rat tissue fractions. Resistance to salt extraction and proteolysis, as well as its detergent dependence, suggested the soluble enzyme became an integral or intrinsic membrane protein following association with the membrane. The ability of membranes to incorporate [γ-³²P]ATP into phosphoprotein was lost on detergent extraction of protein kinase and restored in an apparently specific manner when extracted and washed membranes were reconstituted with soluble enzyme. The intrinsic nature of membrane protein kinase and the apparent specificity with which the soluble enzyme was hound by membranes further indicated that, in myometrium. hormone-induced translocation of protein kinase is an important mechanism by which enzyme activity is increased in the vicinity of its in situ substrates.     

Thyrotropin-releasing hormone activates KCa channels in gastric smooth muscle cells via intracellular Ca2+ release

Thyrotropin-releasing hormone (TRH) is released in high concentrations into gastric juice, but its direct effect on gastric smooth muscles has not been studied yet. We undertook studies on TRH effect on gastric smooth muscle using contraction and patch clamp methods. TRH was found to inhibit both acetylcholine- and BaCl2-induced contractions of gastric strips. TRH, applied to single cells, inhibited the voltage-dependent Ca2+ currents and activated the whole-cell K+ currents. The TRH-induced changes in K+ currents and membrane potential were effectively abolished by inhibitors of either intracellular Ca2+ release channels or phospholipase C. Neither activators, nor blockers of protein kinase C could affect the action of TRH on K+ currents. In conclusion, TRH activates K+ channels via inositol-1,4,5-trisphosphate-induced release of Ca2+ in the direction to the plasma membrane, which in turn leads to stimulation of the Ca2+-sensitive K+ conductance, membrane hyperpolarization and relaxation. The data imply that TRH may act physiologically as a local modulator of gastric smooth muscle tone.     

Differential redistribution of protein kinase C in human aldosteronoma cells and adjacent adrenal cells stimulated with ACTH and angiotensin II

We have examined protein kinase C activity and hormone secretion in aldosteronoma cells derived from adrenocortical glomerulosa cells and in adjacent adrenal cells containing adrenocortical fasciculata-reticularis cells. When aldosteronoma cells were stimulated with ACTH or angiotensin II, protein kinase C activity gradually decreased in cytosol whereas it increased in membrane. Coincident with the changes of protein kinase C activity, there was enhancement of secretion of aldosterone. On the other hand, incubation of adjacent adrenal fasciculata-reticularis cells with ACTH induced cortisol secretion and an increase in cytosolic protein kinase C activity, accompanied by a decrease in the enzyme activity in membrane. Upon stimulation with angiotensin II, adjacent adrenal fasciculata-reticularis cells did not secrete cortisol and no significant changes of protein kinase C activities were observed in either cytosolic or membrane fractions. These results indicate that both ACTH and angiotensin II stimulate aldosterone secretion and cause translocation of protein kinase C from cytosol to membranes in aldosteronoma cells, whereas, in fasciculata-reticularis cells, only ACTH stimulates cortisol secretion and this is associated with translocation of protein kinase C in the opposite direction, viz., from membrane to cytosol.     

Distribution of active protein kinase C in smooth muscle.

To localize activated protein kinase C (PKC) in smooth muscle cells, an antibody directed to the catalytic site of the enzyme was used to assess PKC distribution by immunofluorescence techniques in gastric smooth muscle cells isolated from Bufo marinus. An antibody to vinculin was used to delineate the cell membrane. High-resolution three-dimensional images of immunofluorescence were obtained from a series of images collected through focus with a digital imaging microscope. Cells were untreated or treated with agents that increase PKC activity (10 microM carbachol for 1 min, 1 microM phorbol 12-myristate 13-acetate (PMA) for 10 min), or have no effect on PKC activity (1 micrometer 4-alpha phorbol, 12,13-didecanoate (4-alpha PMA)). In unstimulated cells, activated PKC and vinculin were located and organized at the cell surface. Cell cytosol labeling for activated PKC was sparse and diffuse and was absent for vinculin. After treatment with carbachol, which stimulates contraction and PKC activity, in addition to the membrane localization, the activated PKC exhibited a pronounced cytosolic fibrillar distribution and an increased total fluorescence intensity relative to vinculin. The distributions of activated PKC observed after PMA but not 4-alpha PMA were similar to those observed with carbachol. Our results indicate that in resting cells there is a pool of activated PKC near the cell membrane, and that after stimulation activated PKC is no longer membrane-confined, but is present throughout the cytosol. Active PKC appears to associate with contractile filaments, supporting a possible role in modulation of contraction.     

Thyrotropin releasing hormone action in pituitary cells. Protein kinase C-mediated effects on the epidermal growth factor receptor

Thyrotropin releasing hormone (TRH) causes phosphatidylinositol bisphosphate hydrolysis to form inositol trisphosphate and diacylglycerol. Since diacylglycerol activates protein kinase C (Ca2+/phospholipid-dependent enzyme), this enzyme may be involved in mediating the physiological response to TRH. Activation of protein kinase C leads to phosphorylation of receptors for epidermal growth factor (EGF) and decreased EGF affinity. The present study examined the effect of TRH on EGF binding to intact GH4C1 rat pituitary tumor cells to test whether TRH activates protein kinase C. Cells were incubated with TRH at 37 degrees C and specific 125I-EGF binding was then measured at 4 degrees C. 125I-EGF binding was decreased by a 10-min treatment with 0.1-100 nM TRH to 30-40% of control in a dose-dependent manner. 125I-EGF binding was not altered if cells were incubated at 4 degrees C, although TRH receptors were saturated or in a variant pituitary cell line without TRH receptors. TRH (10 min at 37 degrees C) decreased EGF receptor affinity but caused little change in receptor density, 125I-EGF internalization, or degradation. When cells were incubated continuously with TRH, there was a recovery of 125I-EGF binding after 24 h. Incubation with the protein kinase C activating phorbol ester TPA caused an immediate (less than 10 min) profound (greater than 85%) decrease in 125I-EGF binding followed by partial recovery at 24 h. Maximally effective doses of TRH and TPA decreased EGF receptor affinity with half-times of 3 min. EGF treatment (5 min) caused an increase in the tyrosine phosphate content of several proteins; prior incubation with TRH resulted in a small decline in the EGF response. GH4C1 cells were incubated with 500 nM TPA for 24 h in order to down-regulate protein kinase C. Protein kinase C depletion was confirmed by immunoblots and the effects of TRH and TPA on 125I-EGF binding were tested. TRH and TPA were both much less effective in cells pretreated with phorbol esters. TRH increased cytoplasmic pH measured with an intracellularly trapped pH sensitive dye after mild acidification with nigericin. This TRH response is presumed to be the result of protein kinase C-mediated activation of the amiloride-sensitive Na+/H+ exchanger and was blunted in protein kinase C-depleted cells. All of these results are consistent with the view that TRH acts rapidly in the intact cell to activate protein kinase C and that a consequence of this activation is EGF receptor phosphorylation and Na+/H+ exchanger activation.     

Is all cyclo(His-Pro) derived from thyrotropin-releasing hormone?

Cyclo(His-Pro), or histidyl-proline diketopiperazine, is an endogenous cyclic dipeptide that is ubiquitously distributed in tissues and body fluids of both man and animals. This cyclic dipeptide is not only structurally related to thyrotropin-releasing hormone (TRH, pGlu-His-ProNH₂), but it can also arise from TRH by the action of the enzyme pyroglutamate amino-peptidase (pGlu-peptidase). The data on the distribution of TRH, cyclo(His-Pro), and pGlu-peptidase under normal and abnormal conditions are summarized and potential relationships analyzed. We conclude that all of the cyclo(His-Pro) cannot be derived from TRH. Two additional sources of cyclo(His-Pro) are suggested. It is proposed that 29,247 molecular weight TRH prohormone, prepro TRH, which contains 5 copies of TRH sequence, can be processed to yield cyclo(His-Pro). Thus, both TRH and cyclo(His-Pro) share a common precursor, prepro[TRH/Cyclo(His-Pro)].     

Gonadotropin release and redistribution of calcium-activated, phospholipid-dependent protein kinase in phorbol-stimulated rat pituitary cells

The effect of phorbol esters on calcium-activated, phospholipid-dependent kinase (protein kinase C) and luteinizing hormone (LH) secretion was examined in cultured rat anterior pituitary cells. The potent tumor promoter 12-O-tetra-decanoylphorbol-13-acetate (TPA) stimulated LH secretion and activated pituitary protein kinase C in the presence of calcium and phosphatidylserine. The enzyme activity present in cytosol and particulate fractions was eluted at about 0.05 M NaCl during DE52-cellulose chromatography. Preincubation of pituitary cells with TPA markedly decreased cytosolic protein kinase C activity and increased enzyme activity in the particulate fraction. The maximal TPA-induced change in enzyme activity, with a 76% decrease in cytosol and a 4.3-fold increase in the particulate fraction, occurred within 10 min. The dose-dependent changes in protein kinase C redistribution in TPA-treated cells were correlated with the stimulation of LH release by the phorbol ester. These results suggest that activation of protein kinase C by TPA is associated with intracellular redistribution of the enzyme and is related to the process of secretory granule release from gonadotrophs.     

Spatial and temporal regulation of protein kinase D (PKD)

Protein kinase D (PKD; also known as PKCmicro) is a serine/threonine kinase activated by diacylglycerol signalling pathways in a variety of cells. PKD has been described previously as Golgi-localized, but herein we show that it is present within the cytosol of quiescent B cells and mast cells and moves rapidly to the plasma membrane after antigen receptor triggering. The membrane redistribution of PKD requires the diacylglycerol-binding domain of the enzyme, but is independent of its catalytic activity and does not require the integrity of the pleckstrin homology domain. Antigen receptor signalling initiates in glycosphingolipid-enriched microdomains, but membrane-associated PKD does not co-localize with these specialized structures. Membrane targeting of PKD is transient, the enzyme returns to the cytosol within 10 min of antigen receptor engagement. Strikingly, the membrane-recycled PKD remains active in the cytosol for several hours. The present work thus characterizes a sustained antigen receptor-induced signal transduction pathway and establishes PKD as a serine kinase that temporally and spatially disseminates antigen receptor signals away from the plasma membrane into the cytosol.