Activation Of Second Messenger Systems Research Articles

Ischemia-induced changes in extracellular levels of striatal cyclic AMP: role of dopamine neurotransmission.

Dopamine has been demonstrated to be involved in the development of ischemic neuronal damage in the striatum. This detrimental effect of dopamine may involve activation of second messenger systems, such as the cyclic AMP (cAMP) cascade, which may enhance the susceptibility of striatal neurons to ischemia. In the present study, we have evaluated the relationship between ischemia-induced changes in cAMP and dopamine neurotransmission. Microdialysis probes were implanted in both striata, and a D1 antagonist (SCH-23390, 100 microM) was administered through one probe and modified Ringer's solution through the other. After a stabilization period, rats (n = 6) were subjected to 20 min of ischemia by two-vessel occlusion plus hypotension. Extracellular samples were collected from both striata, before, during, and after ischemia, and analyzed for cAMP by radioimmunoassay. Ischemia induced a significant increase in extracellular cAMP (means +/- SE, fmol/microliter; baseline: 4.35 +/- 1.1, ischemia: 12.2 +/- 1.98), which was also observed at 4 h of recirculation (mean level of 8.45 +/- 1.14). Treatment with the D1 antagonist significantly inhibited the rise in extracellular cAMP during ischemia and recirculation. These results indicate that an ischemia-induced surge in dopamine and activation of D1 receptors are involved in the generation of cAMP during ischemia and recirculation. Because activation of the adenylate cyclase cascade may modulate the effects of glutamate, generation of cAMP through this pathway may play a role in facilitating the injurious effects of dopamine during ischemia.

CAMP-induced desensitization of surface cAMP receptors in Dictyostelium: different second messengers mediate receptor phosphorylation, loss of ligand binding, degradation of receptor, and reduction of receptor mRNA levels.

Surface cAMP receptors on Dictyostelium cells are linked to several second messenger systems and mediate multiple physiological responses, including chemotaxis and differentiation. Activation of the receptor also triggers events which desensitize signal transduction. These events include the following: 1) loss of ligand binding without loss of receptor protein; 2) phosphorylation of the receptor protein, which may lead to impaired signal transduction; 3) redistribution and degradation of the receptor protein; and 4) decrease of cyclic AMP (cAMP) receptor mRNA levels. These mechanisms of desensitization were investigated with the use of mutant synag7, with no activation of adenylyl cyclase; fgdC, with no activation of phospholipase C; and fgdA, with defects in both pathways. cAMP-induced receptor phosphorylation and loss of ligand binding activity was normal in all mutants. In contrast, cAMP-induced degradation of the receptor was absent in all mutants. The cAMP-induced decrease of cAMP-receptor mRNA levels was normal in mutant synag7, but absent in mutant fgdC. Finally, the cAMP analogue (Rp)-cAMPS induced loss of ligand binding without inducing second messenger responses or phosphorylation, redistribution, and degradation of the receptor. We conclude that 1) loss of ligand binding can occur in the absence of receptor phosphorylation; 2) loss of ligand binding and receptor phosphorylation do not require the activation of second messenger systems; 3) cAMP-induced degradation of the receptor may require the phosphorylation of the receptor as well as the activation of at least the synag7 and fgdC gene products; and 4) cAMP-induced decrease of receptor mRNA levels requires the activation of the fgdC gene product and not the synag7 gene product. These results imply that desensitization is composed of multiple components that are regulated by different but partly overlapping sensory transduction pathways.

Regulation of ATP-dependent surfactant secretion and activation of second-messenger systems in alveolar type II cells

Several different classes of agonists are known to stimulate exocytosis in type II cells. These agonists cause increases in second messengers, such as adenosine 3',5'-cyclic monophosphate (cAMP) or cytosolic Ca2+, and/or stimulate protein kinase C. We studied generation of cAMP and phosphoinositide (PI) turnover in monolayer cultures of type II cells and measured [Ca2+]i in single cultured cells. ATP [10-4 M], which stimulates secretion of phosphatidylcholine (PC) and increases cellular cAMP, also stimulated PI turnover and increased [Ca2+]i. 12-O-tetradecanoylphorbol-13-acetate (TPA), which stimulates PC secretion and activates protein kinase C, did not increase [Ca2+]i. Pretreatment of type II cells with the calmodulin antagonist N-(6-aminohexyl)-5-chloro-1-naphthalenesulfonamide (W-7) inhibited the PC secretion induced by ATP and TPA and blocked the increase in PI turnover caused by ATP. ATP-dependent surfactant secretion and stimulation of PI turnover could also be inhibited by pretreatment of the cells with pertussis toxin. We used the fluorescent probe indo-1 to measure [Ca2+]i in single cultured type II cells. ATP produced rapid transient increases in [Ca2+]i, which could be prevented by pretreatment of the cells with either TPA or W-7. Our data suggest that pertussis toxin-sensitive G protein(s) are involved in ATP-dependent activation of PI turnover and in secretion of surfactant in type II cells. Activation of protein kinase C blocks the ATP-stimulated increase in [Ca2+]i. Finally, calmodulin may be involved in the regulation of ATP-dependent increase in [Ca2+]i, the activation of PI turnover, and the secretion of surfactant in type II cells. lung; exocytosis; cell calcium; G proteins; phosphoinositide turnover

Regulation of ATP-dependent surfactant secretion and activation of second-messenger systems in alveolar type II cells

Several different classes of agonists are known to stimulate exocytosis in type II cells. These agonists cause increases in second messengers, such as adenosine 3',5'-cyclic monophosphate (cAMP) or cytosolic Ca2+, and/or stimulate protein kinase C. We studied generation of cAMP and phosphoinositide (PI) turnover in monolayer cultures of type II cells and measured [Ca2+]i in single cultured cells. ATP [10(-4) M], which stimulates secretion of phosphatidylcholine (PC) and increases cellular cAMP, also stimulated PI turnover and increased [Ca2+]i. 12-O-tetradecanoylphorbol-13-acetate (TPA), which stimulates PC secretion and activates protein kinase C, did not increase [Ca2+]i. Pretreatment of type II cells with the calmodulin antagonist N-(6-aminohexyl)-5-chloro-1-naphthalenesulfonamide (W-7) inhibited the PC secretion induced by ATP and TPA and blocked the increase in PI turnover caused by ATP. ATP-dependent surfactant secretion and stimulation of PI turnover could also be inhibited by pretreatment of the cells with pertussis toxin. We used the fluorescent probe indo-1 to measure [Ca2+]i in single cultured type II cells. ATP produced rapid transient increases in [Ca2+]i, which could be prevented by pretreatment of the cells with either TPA or W-7. Our data suggest that pertussis toxin-sensitive G protein(s) are involved in ATP-dependent activation of PI turnover and in secretion of surfactant in type II cells. Activation of protein kinase C blocks the ATP-stimulated increase in [Ca2+]i. Finally, calmodulin may be involved in the regulation of ATP-dependent increase in [Ca2+]i, the activation of PI turnover, and the secretion of surfactant in type II cells.

Natural products as probes for new drug target identification

One traditional aspect of natural products in medical research has been their use in the identification and investigation of the physiological/pathological role of receptors and enzymes as possible targets for drug design programmes. Classical examples of this function of natural products in drug research can be seen in the investigation of the cholinergic system. For example, the importance of alkaloids such as nicotine, physostigmine and curare for research into the nicotinic receptor and muscarine, pilocarpine and the tropane alkaloids on the muscarinic receptor. On binding of a ligand to its cell surface membrane receptor and prior to a physiological/pharmacological response two mechanisms are currently known to be involved in membrane signal transductance. In the minority of cases signal transductance involves the direct opening of an ion channel, for example sodium ion influx, but in the majority of cases involves stimulation of a family of G-proteins and subsequent activation of second messenger systems. For example, the cyclic-AMP/adenylate cyclase system and the phosphoinositol cycle. In this communication, the part played currently by the tumour-promoting and pro-inflammatory phorbol esters from the plant family Euphorbiaceae in furthering our understanding of the role of a group of related kinases from one arm of the phosphoinositol cycle as a signal transduction pathway will be illustrated. The possibilities of using these new receptors as targets for future drug development will also be described.

Metabolic regulation by α 1- and α 2-adrenoceptors

The role of α-adrenoceptors in the mediation of autonomic function, particularly in the control of the cardiovascular system, is widely known. However, α-adrenoceptors are also important in the regulation of a variety of metabolic processes that occur in the body either through direct action or by stimulation of the release of other mediators that control metabolic function. Thus, α 2-adrenoceptor activation by circulating or neuronally released catecholamines inhibits the release of insulin from pancreatic islet β-cells and, by inhibiting this response, α 2-adrenoceptor antagonists have been shown to have an antihyperglycemic effect. The α-adrenoceptor-mediated regulation of the release of pituitary hormones is indirect, with α-adrenoceptors being located on peptidergic neurons in the hypothalamus that secrete releasing hormones into the hypophysial portal system to regulate the secretion of hormones from the anterior pituitary gland. Thus, the increase in cortisol secretion from the adrenal glands following a meal is produced, at least in part, by an α 1-adrenoceptor-mediated increase in vasopressin and CRF-41 secretion from neurons on the hypothalamus that stimulate the release of adrenocorticotrophic hormone secretion from the pituitary gland, which subsequently stimulates the synthesis and release of cortisol from the adrenal medulla. In addition to metabolic regulation by α 1-and α 2-adrenoceptors within the endocrine system, α-adrenoceptors are also a component of the system that regulates certain aspects of metabolism within autonomic effector cells, such as the control of smooth muscle cell division and growth during periods of continued α-adrenoceptor activation as a result of activation of second messenger systems.

Gonadotrophin-releasing hormone: Physiological significance and relevance to cancer

Gonadotrophin releasing hormone (GnRH) is a decapeptide released by the hypothalamus. The binding of the peptide to pituitary receptors leads to the activation of second messenger systems. The physiological outcome of the exposure of pituitary cells to GnRH is the release of luteinising hormone (LH) and follicle-stimulating hormone (FSH). Continued exposure of these receptors to high concentrations of the peptide desensitises the receptor, thus inhibiting the release of gonadotrophins. This paradoxical effect has proved to be beneficial in the clinic where long-acting and enzyme-resistant analogues are used to inhibit the pituitary-gonadal axis, for example in the treatment of advanced prostatic cancer. In addition GnRH-analogues may affect tumour cells directly as observed in vitro. These direct effects have been described as inhibitory but recent data suggests that low concentrations of GnRH-analogues may stimulate short term growth of prostatic cancer cells in vitro. GnRH shares many other common characteristics with peptide growth factors, including common second messenger systems and receptor desensitisation on prolonged exposure to the ligand. It is possible that the direct inhibitory effects of GnRH-analogues are mediated through the desensitisation of tumour GnRH receptors, as suggested by recent observations. The nature and mechanism of the direct anti-tumour effect is important to understand and to promote the therapeutic efficacy of GnRH-analogues in the clinic.

Inhibitors of membrane transmethylation reactions prevent the lymphocyte chemokinetic response

The methylation of membrane phospholipids has been shown to occur following receptor-mediated activation of leukocytes. The present studies show that the human lymphocyte response to two positive chemokinetic signals (bradykinin and lymphocyte chemoattractant factor) can be interrupted by inhibitors of S- adenosyl- l- methionine-mediated transmethylation reactions. The chemokinetic response to the nonphysiologic stimulant colchicine is not affected. We speculate that phospholipid methylation accompanies receptor-mediated lymphocyte migration, and may facilitate activation of second messenger systems.

Adrenergic Receptors

During the past 15 years there has been a striking increase in the understanding of the molecular basis of cellular response to catecholamines. In addition to the two principal subtypes of beta-adrenergic receptors (beta 1 and beta 2), there are at least two (alpha 1, alpha 2) and very likely additional subtypes of alpha-adrenergic receptors. The discovery of guanine nucleotide binding (G) proteins as transducers of receptor occupancy to activation of second messenger systems provides a common theme in cellular regulation by catecholamines. Application of techniques such as radioligand binding and photoaffinity labeling have facilitated the direct identification, quantitation, and ultimately purification of alpha 1, alpha 2, beta 1, and beta 2 receptors. Each is a plasma membrane glycoprotein with a subunit molecular weight (without the carbohydrate portion of the glycoprotein) of 40,000 to 55,000 kDa. The recent cloning and sequencing of cDNAs for alpha 2-, beta 1-, and beta 2-adrenergic receptors has revealed that although each has a unique molecular structure, they appear to share several common features, including extracellular amino terminus, seven plasma membrane spanning domains, and intracellular carboxy terminus. The application of molecular biological techniques together with antireceptor antibodies, which will allow studies of adrenergic receptors independent of binding or functional properties, should help in answering the many unresolved questions related to activation and regulation of adrenergic receptors. Foremost among these is whether diseases such as hypertension are characterized by alterations in one or more adrenergic receptor subtypes.

Can Learning and Memory Be Understood?

Progress in unraveling the mysteries of the mind has been slow, but recent work indicates that a complete mechanistic understanding of at least simple forms of learning will soon be in hand. For example, it is becoming evident that associative learning is due to changes in existing neural circuits and that the acquisition of a learned behavior is due to the activation of second messenger systems in nerve cells.

Chapter 7 The role of protein kinases in the control of prolonged changes in neuronal excitability

This chapter discusses the properties of the bag cell neurons of Aplysia , with a major focus on the modulation of potassium and calcium currents by different second messenger systems linked to the activation of protein kinases. It provides a brief account of the evidence that the peptide synthesis may be modulated in these neurons and that their excitability can be modulated by the cell's own released peptides. The chapter also gives a description of the way in which a change in the nature of the response to a second messenger system is associated with a prolonged modification of excitability. The bag cell neurons have proved to be a model system for the investigation of mechanisms regulating changes in neuronal excitability that result in alterations in an animal behavior. The phosphorylation of proteins, coordinated through the activation of second messenger systems, results in the alterations of the properties of ionic currents, which regulate the excitability of these neurons, and in changes in the synthesis of peptides to be released during neuronal activity.

32] Detection and measurement of secretion from individual neuroendocrine cells using a reverse hemolytic plaque assay

Recent advances in technology have dramatically increased the resolution with which we may examine many features of biological systems. Intracellular recording and tracer injection techniques allow one to study the function of individual neurons and later characterize the same cells morphologically. In situ hybridization techniques can give us information about messenger RNA levels in single cells. More established techniques such as immunocytochemistry and electron microscopy also provide information at the cellular and even subcellular level. With each of these technological advances we have learned more about the mechanisms underlying cell function. We are also beginning to appreciate the role of heterogeneity among cells in relation to the function of the whole organism. Application of the reverse hemolytic plaque assay to the study of hormone or neurotransmitter secretion should help clarify this role. This technique permits accurate quantitation of hormone secreted from a large number of cells. Thus while cells can be studied individually they can also be categorized into functional subpopulations. As discussed in this chapter, many other techniques may be applied on cells which have already been functionally defined with the plaque assay. This should result in a clearer understanding of the roles of secretagogue binding and internalization, activation of second messenger systems, protein synthesis, and the cytoskeleton in hormone secretion. In the plaque assays described in this chapter individual pituitary cells are isolated in culture free from possible interactive effects coming from other cells. While these interactions are no doubt critical to the understanding of the function of the organism as a whole they can result in totally uninterpretable results. In fact, when we have gained some understanding into the functioning of individual cells it should be possible using the plaque assay to study the interactions among cells in a controlled fashion.