Functional state of adenylate cyclase signaling system in testis and ovary of fasted rats

Sensitivity of the adenylate cyclase signaling system (ACSS) to polypeptide hormones and biogenic amines is studied in testis and ovary of rats after the 2- and 4-day fasting as compared with control animals. In tissues of the fasted rats there is shown a decrease in the basal activity of adenylate cyclase (AC) and of the basal level of the GTP binding of heterotrimeric G protein. An increase of duration of fasting from 2 to 4 days led to intensification of these changes. In the fasted rats, the stimulating effects of chorionic gonadotropin, PACAP-38. and isoproterenol on the AC activity realized via G protein of the stimulatory type are enhanced, whereas the inhibitory effects of somatostatin on the AC activity realized via G protein of the inhibitory type are reduced. In testis of the fasted rats the stimulating effect of serotonin acting on AC via both types of G proteins are increased, while the inhibitory effects of the hormone decrease. Thus, under conditions of fasting, in rat testis and ovary the ACSS sensitivity to regulatory effects of hormones is changing: its stimulatory effects are increased, while its inhibitory effects, on the contrary, are decreased. We suggest these changes is one of the key mechanisms of adaptation of organism to deficiency of nutritional resources to be aimed at intensifying the tissues catabolic processes, preferably, lypolysis.     

Functional state of adenylyl cyclase signaling system in reproductive tissues of rats with experimental type-1 diabetes

Type-1 diabetes mellitus (DM) leads to numerous disturbances in the male and female reproductive systems. As was shown previously, one of the main causes of the development of complications in DM is a change in the sensitivity of the adenylyl cyclase signaling system (ACSS) to hormones. The aim of this work consisted in detection of disturbances in the hormone-regulated ACSS in reproductive system of rats with experimental type-1 DM (EDM1) caused by administration of streptozotocin. It has been shown that, in the testes of male rats with 5-day-long EDM1 the stimulating effects of human chorionic gonadotropin (HCG) and PACAP-38 on adenylyl cyclase (AC) and the GTP binding of G proteins are decreased considerably. In the uteri of female rats with EDM1 the effects of relaxin, PACAP-38, and biogenic amines are markedly decreased, whereas in ovaries only the effects of HCG are decreased. In all studied tissues of rats with EDM1 the attenuation of somatostatin inhibitory effects was observed, while in the uterus the inhibitory effects of serotonin and adrenalin were also decreased. Thus, in the reproductive tissues of rats with EDM1, the hormone regulatory effects on ACSS are decreased, especially the effect of HCG and the hormones, AC-inhibitors. We believe that the sensitivity of ACSS to hormones in EDM1 underlies the development of pathological changes in the reproductive system of diabetic rats under the conditions of hyperglycemia and insulin deficiency characteristic of type-1 DM.     

A decrease in the sensitivity of adenylyl cyclase and heterotrimeric g proteins to chorionic gonadotrophin and peptide hormones action in the tissues of reproductive system of rats with experimental type 2 diabetes

Patients with different forms of the diabetes, particularly with insulin-independent type 2 diabetes, have a wide spectrum of the disturbances of the functions of reproductive system. It is suggested that the main reason of these disturbances is altered sensitivity of reproductive system tissues to the regulatory action of hormones. The aim of this study was the identification of the changes in functioning of adenylyl cyclase system (ACS) sensitive to human chorionic gonadotrophin (hCG) and the peptide hormones in the ovary, testes and uterus of rats with neonatal streptozotocin (STZ) diabetes that is similar to the type 2 diabetes in humans. The effects of hCG, PACAP-38 and relaxin, realizing their effects via stimulatory G proteins (G_s), and somatostatin, acting via the inhibitory G protein (G_i), on adenylyl cyclase (AC) activity and GTP binding to the G proteins were studied. In rats with STZ type 2 diabetes the regulatory effects of hCG and PACAP-38 decreased in the ovary and testes, while the effects of somatostatin decreased in all investigated tissues (especially in the uterus). This caused attenuation of the hormonal effects, stimulating (hCG and PACAP-38) or inhibiting (somatostatin) AC activity, and in the decrease of their stimulatory effect on the GTP binding. At the same time a significant decrease of ACS sensitivity to relaxin in the tissues of diabetic rats was not found. Data obtained suggest that one of the key reasons for impairments of reproductive functions in experimental type 2 diabetes is the decrease of ACS sensitivity to the hormones, hCG, PACAP-38 and somatostatin, which play an important role in the reproductive system functioning.     

The effect of long-term diabetes mellitus induced by treatment with streptozotocin in 6-week-old rats on functional activity of the adenylyl cyclase system

In type 1 diabetes mellitus (DM), changes occurring in the adenylyl cyclase signaling system (ACSS) are one of the key causes of complications of the disease. Since type 1 DM has been most often diagnosed in childhood and adolescence, the study of changes in ACSS in the early development of the disease is a genuine problem. For this, we developed a prolonged model of type 1 DM, which was induced by treatment of 6-week-old rats with moderate doses of streptozotocin (1.5M-DM), and studied the functional state of ACSS in the brain, myocardium, and testes of rats with this model of the disease 7 months after its start. The 1.5M-DM model was compared with the model that was induced by streptozotocin treatment of adult, 5-month-old animals (5M-DM). It was shown that, in 1.5M-DM, in the tissues of diabetic rats, the functional activity of ACSS sensitive to biogenic amines and polypeptide hormones was significantly changed. In rats with 1.5M-DM, the adenylate cyclase (AC) inhibitory effects of somatostatin (in all studied tissues), noradrenaline (in the myocardium and the brain), and agonists of type 1 serotonin receptor (in the brain) were weakened to the greatest degree. In the brain, the AC-stimulating effects of relaxin, isoproterenol, and agonists of G_s-protein-coupled serotonin receptors also decreased; in the myocardium, the corresponding effects of GppNHp, relaxin, and β-adrenergic agonists declined; and, in the testes, the AC effects of GppNHp and chorionic gonadotropin declined. When comparing the 1.5M-DM and 5M-DM models, the most pronounced differences between them were found in the effect of DM on hormonal regulation of ACSS in the brain, this being true both for AC-stimulating effects of dopamine and PACAP-38 and for AC-inhibiting effects of bromocriptine and somatostatin. These results indicate significant changes in hormonal regulation of the nervous, cardiovascular, and reproductive systems in rats with early induction of type 1 DM, in some cases more severe changes as compared with late model of 5M-DM. These changes may be the basis for development of diabetic cardiomyopathy, cognitive deficiency, and hypogonadotropic states, which are often detected in children and adolescents with type 1 DM.     

Reactivity of the adenylyl cyclase system in rat tissues to biogenic amines and peptide hormones under starvation condition

Under starvation condition, sensitivity of the adenylyl cyclase system to regulatory action of biogenic amines and peptide hormones in rat tissues are changed. In the myocardium and skeletal muscles, after 2 and 4 days of starvation, the regulatory effects of isoproterenol and relaxin acting via G,-proteins on the adenylyl cyclase activity and the G-protein GTP-binding are significantly increased compared with control. At the same time, regulatory effects ofsomatostatin which are realized via Gi-proteins, on adenylyl cyclase system in the myocardium are decreased. Under prolonged starvation consisting of two consecutive 4-days periods, the effects of hormones acting via Gs-proteins on the adenylyl cyclase activity in muscle tissues are decreased to control value levels. The effects of hormones acting via Gi-proteins are largely reduced. In the brain, intensification of adenylyl cyclase stimulating hormonal effects was late and only observed after a 4-day starvation. Unlike muscle tissues, the increase of adenylyl cyclase stimulating effects in the brain is preserved after two-period starvation. The weakening of adenylyl cyclase inhibiting hormonal signals both in the brain and muscles is observed after a 2-day starvation and then the weakening is intensified. Possible role of glucose level and basal adenylyl cyclase activity in determination of the sensitivity of the adenylyl cyclase system to hormones under study is discussed. It is suggested that one of the key causes of physiological changes in animal organism under starvation involves alteration of hormonal signalling systems sensitivity, in particular that of the adenylyl cyclase system, to hormone regulatory action.     

Structural and functional characteristics of the adenylyl cyclase signaling system regulated by biogenic amines and peptide hormones in the muscle of a worm Lumbricus terrestris

It has been shown for the first time that biogenic amines (catecholamines and tryptophane derivatives) stimulate dose-dependently activity of adenylyl cyclase (AC) and GTP-binding of G-proteins in muscle of the cutaneous-muscle bag of the earthworm Lumbricus terrestris. By efficiency of their stimulating action on the AC activity, biogenic amines can be arranged in the following sequence: octopamine > tyramine > tryptamine = serotonin > dopamine > isoproterenol = adrenalin. The sequence of efficiency of their action on GTP-binding is somewhat different: serotonin > tryptamine > octopamine > dopamine = tyramine > adrenaline > isoproterenol. Sensitivity of AC and G-proteins in the worm muscle to biogenic amines is similar with that in smooth muscle of the molluse Anodonta cygnea (invertebrates), but differs markedly by this parameter from the rat myocardium (vertebrates). It has also been revealed that AC in the worm muscle is regulated by peptide hormones relaxin and somatostatin whose action is comparable with that in the mollusk muscle, but much weaker that the action of these hormones on the rat myocardium AC activity. Use of C-terminal peptides of alpha-subunits of G-proteins of the stimulatory (385-394 Galpha(s)) and inhibitory (346-355 Galpha(i2)) types that disrupt selectively the hormonal signal transduction realized via G(s)- and G(i)-proteins, respectively, allowed establishing that the AC-stimulating effects of relaxin, octopamine, tyramine, and dopamine in the worm muscle are realized via the receptors coupled functionally with G(s)-protein; the AC-inhibiting effect of somatostatin is realized via the receptor coupled with G(i)-protein, whereas serotonin and tryptamine activate both types of G-proteins.     

A constraint on cAMP signaling

Studies in invertebrates and vertebrates have demonstrated a critical role for cAMP signaling and adenylyl cyclase (AC) activity in learning and memory. In this issue of Neuron, Pineda et al. show that in the hippocampus, reduction of AC activity via the inhibitory G protein G(i) is critical for memory formation, suggesting that a balance of inhibitory and stimulatory regulators of AC is required for optimal cAMP signaling.     

Regulation of adenylyl cyclase signaling system by insulin, biogenic amines and glucagon at their separate and combined action in muscle membranes of mollusc Anodonta cygnea

In the smooth muscles of mollusc Anodonta cygnea the regulatory action of hormones on adenylyl cyclase signaling system (ACSS) are realized through the receptors of serpentine type (biogenic amines, isoproterenol, glucagon) and receptor tyrosine kinase (insulin) type. Intracellular mechanisms of their interaction are interconnected. Application of hormones, their antagonists and pertussis toxin in combination with insulin and biogenic amines or glucagon on adenylyl cyclase (AC) activity allows revealing the possible sites of cross-linking in the mechanisms of their action. Combined influence of insulin and serotonin or glucagon leads to decreased stimulation of adenylyl cyclase (AC) by these hormones, whereas combined application of insulin and isoproterenol suppresses AC-stimulating effect of insulin, but AC-inhibiting effect of isoproterenol is maintained in the presence and absence of non-hydrolysable analog of GTP—guanylyl imido diphosphate (GIDP). The specific blockage of AC-stimulating effect of serotonin by cyproheptadine—antagonist of serotonin receptors, did not change AC stimulation by insulin. Beta-adrenoblockers (propranolol and alprenolol) prevent inhibition of AC activity by isoproterenol, but did not change AC stimulation by insulin. Pertussis toxin blocked AC-inhibiting effect of isoproterenol and weakened AC-stimulating action of insulin. Thus, in the muscles of Anodonta cygnea negative interaction between ACS have been revealed, which are realized under combined influence of insulin and serotonin or glucagon, most probably, at the level of receptor of serpentine type (serotonin, glucagon), whereas under action of insulin and isoproterenol at the level of G_i protein and AC interaction.     

A change of hormonal regulation of adenylyl cyclase in epididymal adipose tissue of rats with experimental models of diabetes mellitus

One of the key causes of diabetes mellitus (DM) and its complications are hormonal disturbances in functioning of hormonal signaling systems, including the adenylyl cyclase signaling system (ACSS). The goal of this work was to study the functional state and hormonal sensitivity of ACSS in the epididymal adipose tissue of male rats in the 7-month model of mild type 1 DM (DM1), in the 18-month neonatal model of type 2 DM (DM2), and in the taken for comparison model of the 30 day-longs acute DM1. It is shown for the first time that in adipocytes from the epididymal fat of rats with the studied DM models the basal AC activity and its stimulation by forskolin were decreased, which indicates a weakening of the catalytic functions of the enzyme adenylyl cyclase (AC). Stimulation of AC by guanine nucleotides in DM changed to the lesser extent, which argues in favor of preservation of functions of heterotrimeric Gs-proteins in the epididymal fat. In rats with DM1 the sensitivity of AC of adipocytes to agonists of β-adrenergic receptors (β-AR), activators of lipolysis, remained practically unchanged, while in animals with DM2 the AC stimulating effects of β-AR-agonists were reduced or completely blocked, like in the case of β₃-AR-agonists BRL-37344 and CL-316243. In adipocytes of rats with DM1 the AC inhibitory effect of N⁶-cyclopentyladenosine, agonist of type 1 adenosine receptors (Aden₁R), an inhibitor of lipolysis, was attenuated, whereas in DM2 this effect was completely preserved. Thus, in the epididymal adipose tissue of rats with DM1 the antilipolytic AC cascades including Aden₁R were decreased and the stimulation of AC by β-AR-agonists was preserved, whereas in rats with DM2 the β-AR-mediated AC cascades activating lipolysis were reduced, but Aden₁R-mediated AC cascades inhibiting lipolysis did not change. The changes of hormonal regulation of ACSS in adipocytes from the epididymal fat lead to disturbances of the metabolic status of animals with DM1 and DM2 and should be considered in the diagnostics and treatment of DM and its complications.     

Structural-functional characteristics of the adenylyl cyclase signaling system regulated by biogenic amines and peptide hormones in muscles of the earthworm Lumbricus terrestris

It has been shown for the first time that biogenic amines (catecholamines and tryptophane derivatives) stimulate dose-dependently activity of adenylyl cyclase (AC) and GTP-binding of G-proteins in muscle of the skin-muscle sac of the earthworm Lumbricus terrestris. By efficiency of their stimulating action on the AC activity, biogenic amines can be arranged in the following sequence: octopamine > tyramine > tryptamine ≈ serotonin > dopamine > isoproterenol ≈ adrenalin. The sequence of efficiency of their action on GTP-binding is somewhat different: serotonin > tryptamine > octopamine > dopamine ≈ tyramine > adrenaline > isoproterenol. Sensitivity of AC and G-proteins in the worm muscle to biogenic amines is similar with that in smooth muscle of the mollusc Anodonta cygnea (invertebrates), but differs markedly by this parameter from the rat myocardium (vertebrates). It has also been revealed that AC in the worm muscle is regulated by peptide hormones, relaxin and somatostatin, whose action is comparable with that in the mollusc muscle, but much weaker that the action of these hormones on the rat myocardium AC activity. Use of Cterminal peptides of α-subunits of G-proteins of the stimulatory (385–394 Gαs) and inhibitory (346–355 Gαi2) types that disrupt selectively the hormonal signal transduction realized via Gsand Giproteins, respectively, allowed establishing that the AC-stimulating effects of relaxin, octopamine, tyramine, and dopamine in the worm muscle are realized via the receptors coupled functionally with Gs-protein; the AC-inhibiting effect of somatostatin is realized via the receptor coupled with Gi-protein, whereas serotonin and tryptamine activate both types of G-proteins.     

Effect of intranasal insulin and serotonin on functional activity of the adenylyl cyclase system in myocardium, ovary, and uterus of rats with prolonged neonatal model of diabetes mellitus

The disturbances in hormonal signaling systems, adenylyl cyclase system (ACS) in particular, occur at the early stages of diabetes mellitus (DM) being one of the key causes of its complications. Since the correlation between the severity of DM and severity of disturbances in ACS is established, studying ACS activity can be used for monitoring DM and its complications and evaluating the effectiveness of their treatment. Recently, intranasal insulin (I-I) and the drugs increasing brain serotonin level, thus effectively restoring CNS functions, have begun to be used for the treatment of type 2 DM. However, the mechanisms of their action on peripheral tissues and organs at DM are not understood. The aim of this work was to study an influence of I-I and intranasal serotonin (I-S) on the functional activity of ACS in myocardium, ovary and uterus of rats with a neonatal model of type 2 DM. In the tissues of diabetic rats the changes in the regulation of adenylate cyclase (AC) by guanine nucleotides and hormones acting on enzyme in stimulatory and inhibitory manner were found, and these changes were characterized by receptor and tissue specificity. In diabetic rats I-I restored AC-stimulating effects of isoproterenol in the myocardium, that of guanine nucleotides and gonadotropin in the ovaries and relaxin in the uterus, as well as AC-inhibiting effects of somatostatin in all tissues and norepinephrine in the myocardium. Treatment with I-S led to a partial recovery of AC-inhibiting effect of norepinephrine in the diabetic myocardium, but did not affect the regulation of AC by other hormones. These data indicate that I-I normalizes the functional activity of ACS in the myocardium and in the tissues of reproductive system of female rats with neonatal DM, whereas the effect of I-S on ACS in the studied tissues is less pronounced. These results should be considered for the design and optimization of the strategy of I-I and I-S application for the treatment of DM and its complications.     

Disturbance of transduction of adenylyl cyclase-inhibiting hormonal signaling in the myocardium and brain of rats with experimental type 2 diabetes

Presently, our work, as well as that of other authors, has produced convincing evidence in favor of the idea that disturbances in hormonal signaling systems are one of the main causes of the development of pathological alterations and complications in diabetes. However, the molecular mechanisms underlying these disturbances remain practically unstudied, particularly in insulin-independent type 2 diabetes. Using a neonatal streptozotocin model of type 2 diabetes, whose duration was either 80 or 180 days, we studied changes in the functional activity of components of the hormone-regulated adenylyl cyclase (AC) signaling system in the myocardium and brain striatum of diabetic rats as compared with control animals. In diabetes, the G_i-realized process of transduction of the hormonal signal inhibiting AC activity has been shown to be markedly impaired. This is manifested as a decrease of the inhibitory effect of hormones on AC activity and an attenuation of their stimulation of the G-protein’s GTP-binding activity. In the case of noradrenaline (myocardium), the inhibitory pathway of the AC system regulation is completely suppressed, while the stimulatory pathway is preserved. An increase in the duration of diabetes development from 80 to 180 days leads to some decrease in the transduction of hormonal signals realized via G_i-proteins. The stimulatory effects of biogenic amines and relaxin on AC activity and GTP binding in the myocardium and brain of diabetic rats change relatively little, both in the 80-and in the 180-day diabetes. Thus, in the experimental type 2 diabetes, disturbances in G_i-protein coupled signal cascades are primarily observed, through which hormones realize their inhibition of AC activity.     

Regulatory properties of adenylyl and guanylyl cyclase in human spermatozoa

Completion of maturation of spermatozoa (capacitation) occurs in the female genital tract. As a result, spermatozoa acquire the high motility and the capability for acrosomal reaction, which determines their fertility. There are evidences that adenylyl cyclase and guanylyl cyclase signaling systems detected in human and mammalian spermatozoa are involved in these processes. The goal of the present study was characterization of these systems in human ejaculate spermatozoa (ES) and in human fertile spermatozoa (FS) isolated by a density gradient centrifugation. In FS homogenate the basal activity of the adenylyl cyclase (AC) was significantly higher as compared with ES (47 ± 5 vs. 28 ± 3 pmol cAMP/min per mg of protein). At the same time, the AC stimulatory effects of non-hormonal activators of soluble and membrane-bound forms of AC (NaHCO₃, Mn²⁺, forskolin, and non-hydrolyzable GTP analogue—GppNHp) in FS were lower as compared with ES. Isoproterenol, serotonin, PACAP-38, and, to the lesser extent, noradrenalin and adenosine stimulated the AC activity in ES. Among hormones inhibiting AC, only adenosine decreased the enzyme activity. At the same time, in FS the inhibitory AC effects of adenosine, noradrenalin, and serotonin were markedly expressed, and the stimulatory effects of these hormones were decreased or absent. The basal activity of guanylyl cyclase (GC) in ES and FS homogenates was 27 ± 3 and 21 ± 2 pmol cGMP for 1 min per 1 mg protein, respectively, and was significantly increased in the presence of 10 mM Mn²⁺. The stimulatory GC effects of natriuretic peptides—ANP and CNP, activators of receptor forms of GC, was significantly higher in ES than in FS, and the effect of ANP was more pronounced as compared with CNP. The data indicate the multiplicity of cAMP- and cGMP-dependent signaling cascades regulating fertility of human spermatozoa. We found that the sensitivity of AC and GC to hormones in the common pool of ES and in the fraction of highly motile FS isolated by centrifugation was essentially different, which is to be considered when using FS for accessory reproductive technology.     

Increased sensitivity of fat cell adenylate cyclase to stimulatory agonists during fasting is not related to impaired inhibitory coupling system

In rat adipocytes, inhibition of the forskolin-stimulated cyclic AMP response by nicotinic acid and N6-phenylisopropyladenosine was unaltered by a 72 h fasting. Under assay conditions favouring inhibition, basal and forskolin-stimulated adenylate cyclase responses to inhibition by GTP and nicotinic acid were also unimpaired by fasting. Under the same conditions, however, low GTP concentrations elicited a clear activatory effect in membranes from fasted but not from fed rats. Fasting failed to alter the incorporation of [32P]ADP ribose into the alpha i-subunit of Ni and the attenuation of nicotinic acid inhibitory action that are both induced by pertussis toxin. These results, demonstrating unimpaired inhibitory control of adenylate cyclase in starved rat adipocytes, suggest that the permissive effect of fasting on the action of stimulatory receptor agonists in fat cells reflects a specific increase in the activity of the adenylate cyclase stimulatory coupling system.     

The Peptides Mimicking the Third Intracellular Loop of 5-Hydroxytryptamine Receptors of the Types 1B and 6 Selectively Activate G Proteins and Receptor-Specifically Inhibit Serotonin Signaling via the Adenylyl Cyclase System

The third intracellular loop (ICL3) of G protein-coupled receptors has, as a rule, a key role in their interaction with heterotrimeric G proteins. We synthesized peptides corresponding to the C-terminal region of the ICL3 (C-ICL3) of 5-hydroxytryptamine receptors of the type 1B (5-HT_1BR) and 6 (5-HT₆R) and studied their influence on the functional activity of adenylyl cyclase signaling system (ACSS) in synaptosomal membranes isolated from the rat brain. The 5-HT_1BR-peptide ARERKATKTL^307–316K-amide mimicking agonist-activated 5-HT_1BR reduced forskolin-stimulated adenylyl cyclase (AC) activity and activated pertussis toxin-sensitive G proteins. It lowered inhibitory effects of serotonin and 5-HT_1BR-agonists on forskolin-stimulated AC activity and their stimulating effects on GTP binding. This was not the case in the presence of 5-HT_1BR-antagonists. The 5-HT₆R-peptides mimicking 5-HT₆R activated both the basal AC activity and GTP binding of cholera toxin-sensitive G proteins. They lowered the stimulating effect of serotonin and 5-HT₆R-agonists on AC and G_s proteins, but in the presence of 5-HT₆R-antagonists their action was blocked. Of all the 5-HT₆R-peptides with linear and dimeric structure we studied the palmitoylated peptide KHSRKALKASL^258–268K(Pal)A-amide had a most pronounced effect both on the basal and 5-HT₆R-agonist-stimulated ACSS. The data was obtained indicating that the peptides corresponding to C-ICL3 of 5-HT_1BR and 5-HT₆R selectively activate G_i and G_s proteins, respectively, and in a receptor-specific manner reduce signal transduction via serotonin-sensitive ACSS in the rat brain. The results of the study give strong evidence in favor of active participation of C-ICL3 of these 5-HTRs in their coupling with the G proteins.     

The adenylyl cyclase family

Hormone-sensitive adenylyl cyclase is a model system for the study of receptor-mediated signal transduction. It is comprised of three types of components: 1) receptors for hormones that regulate cyclic AMP (cAMP) synthesis, 2) regulatory GTP binding proteins (G proteins), and 3) the family of enzymes, the adenylyl cyclases. Concentrations of cAMP are altered by at least 35 different stimulatory or inhibitory hormones and neurotransmitters. Other signalling pathways may also influence cAMP production through regulation of particular adenylyl cyclase subtypes. The second messenger, cAMP propagates the hormone signal through the effects of cAMP-dependent protein kinase.While structural information on the adenylyl cyclases is limited, a cDNA clone for a calmodulin-sensitive form of bovine brain adenylyl cyclase has been isolated. The amino acid sequence encoded by the Type I cDNA is approximately 40% identical to those specified by three other adenylyl cyclase cDNAs that have been cloned subsequently. This degree of structural variation implies that there must be functional differences between the adenylyl cyclases.     

Alterations of Tubulin Function Caused by Chronic Antidepressant Treatment in Rat Brain

1. Antidepressants have been used clinically for many years; however, the neurochemical mechanism for their therapeutic effect has not been clarified yet. Recent reports indicate that chronic antidepressant treatment directly affects the postsynaptic membrane to increase the coupling between the stimulatory GTP-binding (G) protein, G_s, and adenylyl cyclase. Tubulin, a cytoskeletal element, is involved in the stimulatory and inhibitory regulation of adenylyl cyclase in rat cerebral cortex via direct transfer of GTP to G proteins. In this study, we investigated whether the functional change of the adenylyl cyclase system caused by chronic antidepressant treatment involves an alteration of tubulin function in the regulation of adenylyl cyclase activity.2. Male Sprague–Dawley rats were treated once daily with amitriptyline or saline by intraperitoneal injection (10 mg/kg) for 21 days, and their cerebral cortex membranes and GppNHp-liganded tubulin (tubulin-GppNHp) were prepared for what.3. GppNHp-stimulated adenylyl cyclase activity in cortex membranes from amitriptyline-treated rats was significantly higher than that in control membranes. Furthermore, tubulin–GppNHp prepared from amitriptyline-treated rats was more potent than that from control rats in the stimulation of adenylyl cyclase activity in the cortex membranes of the controls. However, there was no significant difference in manganese-stimulated adenylyl cyclase activity between control and amitriptyline-treated rats.4. The present results suggest that chronic antidepressant treatment enhances not only the coupling between G_s and the catalytic subunit of adenylyl cyclase but also tubulin interaction with G_s in the cerebral cortex of the rat.     

Receptor and tissue specificity of the effects of peptides corresponding to intracellular regions of the serpentine type receptors

Proximal regions of the third intracellular loop (ICL-3) are responsible for the interaction with heterotrimeric G proteins in most of the serpentine type receptors. The peptides corresponding to these regions are able to activate G proteins in the absence of hormone and to alter the transduction of hormonal signal via the respective homologous receptor. However, the molecular mechanisms of action of the peptides, their specificity to receptors and target tissues are currently not well understood. The goal of this work was to study the receptor and tissue specificity of peptides-derivatives of C-terminal regions of the ICL-3 of luteinizing hormone receptor (LHR), type 1 relaxin receptor (RXFP1), somatostatin receptors of types 1 and 2 (Som₁R and Som₂R), and 5-hydroxytryptamine receptors of subtype 1B and type 6 (5-HT_1BR and 5-HT₆R) on the functional activity of adenylyl cyclase (AC) and GppNHp-binding of G proteins in the brain, myocardium, and testis of rats. It was shown that the influence of peptides on AC and G proteins is well detected in tissues enriched in homologous receptors. The effects stimulating AC and GppNHp-binding were most pronounced in the testes for LHR peptide, in the brain for peptide 5-HT₆R, and in all of the tested tissues (but mainly in the myocardium) for the RXFP1 peptide. The AC-inhibiting effects of peptides Som₁R, Som₂R and 5-HT_1BR, as well as the stimulation of GppNHp binding induced by these peptides, were most pronounced in the brain. In the presence of the peptides, the AC effects of hormones acting via homologous receptors were significantly attenuated, while the AC effects of other hormones changed insignificantly. The findings suggest that biological activity of the peptides depends on their interaction with complementary regions of homologous receptors, which should be taken into account when developing highly selective regulators of hormonal signaling systems on the basis of these peptides.     

Inhibition of functional activity of the adenylyl cyclase signaling system of the ciliate Dileptus anser by colchicine and vinblastine

Cytoskeleton plays a key role in the functioning of hormonal signaling systems in vertebrate animals. However, data on the effect of cytoskeletal components, in particular microtubules, on the functional activity of chemosignaling systems of unicellular organisms are currently lacking. The goal of this work consisted of studying the effects of microtubule-disrupting agents, colchicine and vinblastine, on the adenylyl cyclase system of free living infusoria Dileptus anser. The incubation of D. anser with colchicine and vinblastine (10^?5–10^?6 M) weakly affected the basal activity of adenylyl cyclase (AC), but led to a significant decrease in or complete block of AC stimulation with nonhormonal (GppNHp, sodium fluoride) and hormonal agents (adrenaline, serotonin, glucagon). The basal level of GTP binding in heterotrimeric G proteins decreased and there was observed inhibition of stimulation of G proteins by hormones. Colchicine and vinblastine have been shown to interrupt adrenalin-produced AC stimulation achieved through G_s-protein, but weakly affect its inhibiting AC effect caused by the G_i-protein. Thus, it has been established for the first time that, in unicellular organisms, i.e., infusoria D. anser, microtubules are involved in the regulation of the functional activity of the AC system and their action is realized at the level of G proteins, which is similar to Gs-proteins in vertebrate animals.     

Fasting increases fat cell adenylate cyclase sensitivity to stimulatory agonists through enhanced ability of the stimulatory regulatory component Ns to dissociate

In rat fat cell membranes, a 72-hour fasting fails to alter the adenylate cyclase stimulatory responses to Mn2+, forskolin and cholera toxin and the cholera toxin catalyzed [alpha-32P] ADP ribose incorporation into the Mr = 42,000 and 46,000/48,000 alpha s peptides of Ns. In contrast, dose-response curves for GTP-stimulation of basal and isoproterenol-stimulated adenylate cyclase display higher maximal responses in fasted rats under conditions restraining (2 mM Mg2+) but not promoting (10 mM Mg2+) the dissociation of Ns. Moreover, at 10 mM Mg2+, the sensitivity of isoproterenol-stimulated adenylate cyclase to GTP is clearly increased in fasted rats. Finally, fasting reduces by 40% the lag-phase of adenylate cyclase activation by Gpp(NH)p. Taken together, these results are consistent with the hypothesis that the permissive effect of fasting on the fat cell adenylate cyclase response to stimulatory agonists is related to increased ability of Ns and the ternary H.R.Ns. complex to dissociate which is likely due to enhanced Ns affinity for guanine nucleotides.