[The effect of hypoxia on cholinesterase activity in rat sensorimotor cortex].

This study reports the dynamics of changes in postnatal ontogenesis of the activity of soluble and membrane-bound forms of acetylcholinesterase (AChE) and butyrylcholinesterase (BChE) in sensorimotor cortex of rats as well as the pattern of their changes after prenatal hypoxia (E14, 7% O2, 3 h) or acute hypoxia in adult animals (4 months, 7% O2, 3 h). In normally developing rats the activity of the membrane-bound AChE form in the sensorimotor cortex gradually increased up to the end of the first month after birth and remained at this high level during all further postnatal ontogenesis, while the activity of the soluble form of AChE reached its maximum on the 10th day after birth and decreased significantly by the end of the first month. In animals exposed to prenatal hypoxia the activity both of the soluble and membrane bound forms of AChE during the first two weeks after birth was 20-25% lower, as compared to controls but increased by the end of the first month and even exceeded the control values remaining increased up to old age (1.5 years). The activity of both BChE forms in rat sensorimotor cortex at all stages of postnatal ontogenesis was significantly lower than of AChE, although the dynamics of their changes was similar to that of AChE. Prenatal hypoxia led to a decrease in the activity of the membrane-bound form of BChE, as compared to controls, practically at all developmental stages studied, but was higher at the end of the first month after birth. At the same time, the activity of the soluble form of BChE was decreased only on the 20th day of development, as compared to the control, but increased from the end of the first month of life onwards. Acute hypoxia in adult rats also led to a decrease in the activity of both forms of AChE and BChE in the sensorimotor cortex but the dynamics of these changes was different for each enzyme. Thus, insufficient oxygen supply to the nervous tissue at different stages of ontogenesis has a significant effect on the activity and ratio of various forms of cholinesterases exhibiting either growth factor or signaling properties. This may lead to changes in brain development and formation of behavioural reactions, including learning and memory, and also increase the risk of development of the sporadic form of Alzheimer's disease (AD)--one of the most common neurodegenerative diseases of advanced age. This study expands our knowledge of the properties of brain cholinesterases under normal and pathological conditions and may be useful for developing new approaches towards prevention and treatment of AD.

[Attenuation of inhibitory influence of hormones on adenylyl cyclase systems in the myocardium and brain of rats with obesity and type 2 diabetes mellitus and effect of intranasal insulin on it].

The functional state of the adenylyl cyclase signaling system (ACSS) and its regulation by hormones, the inhibitors of adenylyl cyclase (AC)--somatostatin (SST) in the brain and myocardium and 5-nonyloxytryptamine (5-NOT) in the brain of rats of different ages (5- and 7-month-old) with experimental obesity and a combination of obesity and type 2 diabetes mellitus (DM2), and the effect of long-term treatment of animals with intranasally administered insulin (II) on ACSS were studied. It was shown that the basal AC activity in rats with obesity and DM2 was increased in the myocardium, and to the lesser extent in the brain, the treatment with II reducing this parameter. The AC stimulating effects of forskolin are decreased in the myocardium, but not in the brain, of rats with obesity and DM2. The treatment with II restored the AC action of forskolin in the 7-month-old animals, but has little effect on it in the 5-month-old rats. In obesity the basal AC activity and its stimulation by forskolin varied insignificantly and weakly changed in treatment of animals with II. The AC inhibitory effects of SST and 5-NOT in the investigated pathology are essentially attenuated, the effect of SST to the greatest extent, which we believe to be associated with a reduction in the functional activity of Gi-proteins. The II treatment of animals with obesity and with a combination of obesity and DM2 restored completely or partially the AC inhibiting effects of hormones, to the greatest extent in the brain. Since impaired functioning of ACSS is one of the causes of the metabolic syndrome and DM2, their elimination by treatments with II can be an effective approach to treat these diseases and their CNS and cardiovascular system complications.

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

In smooth muscles of mollusc Anodonta cygnea, hormones produce regulatory effects on the adenylyl cyclase (AC) signaling system via receptors of the serpentine (biogenic amine, isoproterenol, glucagon) and of tyrosine kinase (insulin) types. Intracellular mechanisms of their action are interconnected. Use of hormones, their antagonists, and pertussis toxin at the combined action of insulin and biogenic amines or of glucagon on the AC activity allows revealing possible intersection points in mechanisms of their action. The combined effect of insulin and serotonin or of glucagon leads to a decrease of stimulation of AC by these hormones, whereas at action of insulin and isoproterenol the AC-stimulatory effect of insulin is blocked, while the AC-inhibitory effect of isoproterenol is preserved both in the presence and in the absence of the non-hydrolyzed GTP analog - guanylylimidodiphosphate (GppNHp). Specific blocking of the AC-stimulatory serotonin effect by cyproheptadine - an antagonist of serotonin receptors - did not affect stimulation of AC by insulin. Beta-adrenoblockers (propranolol and alprenolol) interfered with inhibition of the AC activity by isoproterenol, but did not change the AC stimulation by insulin. Pertussis toxin blocked the AC-inhibitory effect of isoproterenol and attenuated the AC-stimulatory effect of insulin. Thus, in muscles of the mollusc Anodonta cygnea there have been revealed negative interrelations between the AC system, which are realized at the combined effect of insulin and serotonin or of glucagon, probably at the level of receptor of the serpentine type (serotonin, glucagon), while at action of insulin and isoproterenol - at the level of interaction of G1 protein and AC.

[Study of hormone responsiveness of the adenylyl cyclase signaling system in erythrocyte membranes of patients with type 2 diabetes mellitus].

Peptides of the insulin superfamily (insulin, insulin-like growth factor, relaxin), epidermal.growth factor (ECF) and biogenic amines (isoproterenol, adrenalin, noradrenalin, serotonin) stimulate the adenylyl cyclase signaling system (ACSS). In erythrocyte membranes from a control group of patients, the hormone activating affect on ACSS was potentiated in the presence of guanylylimidinodiphosphate (CppNHp). In erythrocyte membranes from patients of various severity of type 2 diabetes mellitus (DM2, early, medium and severe), the basal activity of AC was higher than in the control group and its responsiveness to hormones was different. It was reduced in patients with early and severe forms of DM2 both in the presence and absence of CppNHp. In patients with the medium severity of the disease, the stimulating effect of biogenic amines was not changed but there was no potentiating effect of CppNHp. The insulin superfamily peptides and ECF stimulated AC in the erythrocyte membranes of patients with the medium severity of DM2 to the same extent as in the control while, at the early and severe stages of the disease, the AC sensitivity to these hormones was significantly reduced. These data suggest that DM2 results in disturbances of the hormone stimulating properties of ACSS by insulin superfamily peptides, ECF and biogenic amines. In erythrocyte membranes, DM2 disturbs ACSS functions at the level of the catalytic component and its responsiveness to hormone action at the level of interactions between CG, and AC.

[Changes in the activity of amyloid-degrading metallopeptidases leads to disruption of memory in rats].

In old male Wistar rats (older than 12 months), or adult males (3-4 months) subjected to prenatal hypoxia (7% 02, 3 h, E14), a disruption of short-term memory was observed. The prenatal hypoxia also led to a decrease in the brain cortex expression of metallopeptidases neprilysin (NEP) and endothelin-converting enzyme (ECE-1) which regulate some neuropeptides and are the main beta-amyloid-degrading enzymes. Moreover, a significant decrease (by 2.7 times) in NEP activity in the sensorimotor cortex of old and adult rats subjected to prenatal hypoxia (by 1.7 times) was observed. To confirm possible involvement of these enzymes in memory, the analysis of the effect of microinjections of phosphoramidon (an inhibitor of NEP and ECE-1), and thiorphan (an inhibitor of NEP) into the rat sensorimotor cortex was carried out. In a two-level radial maze test, a disruption of short-term memory was observed 60 and 120 min after i.c. injection ofphosphoramidon (5.9 microg/microl) and 30 and 60 min after i.c. injection of thiorphan (2.5 microg/microl). The involvement of NEP and ECE-1 in short-term memory suggests that a decrease in the level of expression and activity of metallopeptidases involved in metabolism of beta-amyloid peptide (Abeta) and other neuropeptides is one of the main factors in disruption of cognitive functions after prenatal hypoxia or in the process of ageing.

[Structural and functional organization of the adenylyl cyclase signaling mechanism of insulin-like growth factor 1 revealed in the muscle tissue in vertabrates and invertebrates].

Based on the earlier discovered by the authors adenylyl cyclase signaling mechanisms (ACSM) of action of insulin and relaxin, the study was performed of the presence a similar action mechanism of another representative of the insulin superfamily--the insulin-like growth factor 1 (IGF-1) in the muscle tissues of vertebrates (rat) and invertebrates (mollusc). For the first time there was detected participation of ACSM in the IGF-1 action, including the six component signaling cascade: receptor tyrosine kinase --> G(i)-protein (betagamma-dimer) --> phosphatidylinositol-3-kinase (PI-3-K) --> protein kinase Czeta (PKCzeta) --> G(-)protein --> adenylyl cyclase. By this mechanism structural-functional organization at postreceptor stages, in coincides completely with the mechanism of insulin and relaxin, which we revealed in rat skeletal muscle. In smooth muscle of the mollusc Anodonta cygnea this ACSM of action of IGF-1 has only one difference--the protein kinase C included in this mechanism is represented not by PKCzeta isoform, but by another isoform close to PKCepsilon of the vertabrate brain. Earlier we revealed the same differences in muscle of this mollusc in the ACSM of action of insulin and relaxin.

[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.

Studies of the molecular mechanisms of action of relaxin on the adenylyl cyclase signaling system using synthetic peptides derived from the LGR7 relaxin receptor.

The peptide hormone relaxin produces dose-dependent stimulation of adenylyl cyclase activity in rat tissues (striatum, cardiac and skeletal muscle) and the muscle tissues of invertebrates, i.e., the bivalve mollusk Anodonta cygnea and the earthworm Lumbricus terrestris, adenylyl cyclase stimulation being more marked in the rat striatum and cardiac muscle. Our studies of the type of relaxin receptor involved in mediating these actions of relaxin involved the first synthesis of peptides 619-629, 619-629-Lys(Palm), and 615-629, which are derivatives of the primary structure of the C-terminal part of the third cytoplasmic loop of the type 1 relaxin receptor (LGR7). Peptides 619-629-Lys(Palm) and 615-629 showed competitive inhibition of adenylyl cyclase stimulation by relaxin in rat striatum and cardiac muscle but had no effect on the action of relaxin in rat skeletal muscle or invertebrate muscle, which is evidence for the tissue and species specificity of their actions. On the one hand, this indicates involvement of the LGR7 receptor in mediating the adenylyl cyclase-stimulating action of relaxin in rat striatum and cardiac muscle and, on the other, demonstrates the existence of other adenylyl cyclase signal mechanisms for the actions of relaxin in rat skeletal muscle and invertebrate muscle, not involving LGR7 receptors. The adenylyl cyclase-stimulating effect of relaxin in the striatum and cardiac muscles was found to be decreased in the presence of C-terminal peptide 385-394 of the alpha(s) subunit of the mammalian G protein and to be blocked by treatment of membranes with cholera toxin. These data provide evidence that in the striatum and cardiac muscle, relaxin stimulates adenylyl cyclase via the LGR7 receptor, this being functionally linked with G(s) protein. It is also demonstrated that linkage of relaxin-activated LGR7 receptor with the G(s) protein is mediated by interaction of the C-terminal half of the third cytoplasmic loop of the receptor with the C-terminal segment of the alpha(s) subunit of the G protein.

[The disturbance of the transduction of adenylyl cyclase inhibiting hormonal signal in myocardium and brain of rats with experimental type II diabetes].

At present, the data obtained by us and other authors give evidence that disturbances in hormonal signaling systems are the main causes of development of pathological changes and complications under the diabetes. However, the molecular mechanisms of these disturbances remain obscure, especially in the case of insulin-independent type II diabetes. Using neonatal streptozotocin model of 80- and 180-days type II diabetes the changes in functional activity of hormone-regulated adenylyl cyclase (AC) signaling systems components in the myocardium and the brain striatum of diabetic rats in comparison with the control animals were found. The transduction of AC inhibitory hormonal signal meditated through Gi proteins was shown to by disturbed under diabetes. This was manifested in both the decrease of hormone inhibitory effect on AC activity and weakening of hormone stimulation of G-protein GTP-binding activity. In the case of noradrenaline (myocardium) the inhibitory pathway of AC regulation by the hormone was vanished and the stimulation pathway, in contrary, was protected. Prolongation of diabetes from 80 up to 180 days led to some weakening of Gi-protein-mediated hormonal signal transduction. Stimulating effect of biogenic amines and relaxin on the AC activity and GTP-binding in the myocardium and brain of diabetic rats were weakly changed in the case of both 80- and 180-days diabetes. To sum up, the experimental type II diabetes caused disturbances mainly in Gi-coupled signaling cascades participating in hormone inhibition of AC activity.

[Regulatory calcium effect on adenylyl cyclase functional activity in the infusorian Dileptus anser].

Earlier we have shown that some non-hormonal activators of adenylyl cyclase (AC) and hormones of higher vertebrate animals are able to affect functional activity of the AC system in the infusorian Dileptus anser. In the present work, sensitivity of this infusorian AC to Ca2+ was studied and it was found that calcium cations at concentrations of 0.5-10 microM stimulated significantly the enzyme activity in D. anser partially purified membranes. An increase of Ca2+ concentrations to 100 microM and higher led to the complete block of their stimulatory effect. In the EDTA-treated membranes the enzyme activity was reduced markedly, but it was restored significantly by addition of Ca2+. Calmodulin antagonists--chlorpromazine, W-7, and W-5--caused a dose-dependent decrease of the enzyme activity stimulated by 5 microM Ca2+ with IC50 values of 35, 137, and 174 microM, respectively. The AC-stimulating effects of biogenic amines (serotonin and octopamine) were completely retained in the presence of 2.5 and 100 microM Ca2+, whereas effects of peptide hormones (relaxine and EGF) were hardly changed in the presence of 2.5 microM calcium ions, but were markedly inhibited by 100 microM Ca2+. In the EDTA-treated membranes, the AC effects of biogenic amines were reduced, while the effects of peptide hormones were not revealed. On addition of Ca2+, the AC effects of biogenic amines were completely restored, whereas the effects of peptide hormones were not detected or were restored to a non-significant degree. Calmodulin antagonists slightly affected the AC effects of peptide hormones at concentrations efficient in the case of vertebrate AC, but decreased them markedly at higher concentrations. The AC effects of biogenic amines were little sensitive even to high antagonist concentrations. The obtained data show that targets of action of peptide hormones in the infusorian D. anser cell culture are the AC forms whose activity does not D. depends on calcium cations and possibly is regulated by Ca2+/calmodulin, whereas targets of action of biogenic amines are calcium-independent enzyme forms.

[Streptozocin model of diabetes mellitus in the mollusc Anodonta cygnea: functional state of the adenylyl cyclase mechanisms of action of peptides of the insulin superfamily and their effect on carbohydrate metabolism enzymes].

In terms of development of evolutionary biomedicine using invertebrate animals as models for study of molecular grounds of various human diseases, for the first time the streptozocin (ST) model of insulin-dependent diabetes in the mollusc Anodonta cygnea has been developed. This model is based on the following authors' data: (1) redetection of insulin-related peptides (IRP) in mollusk tissues: (2) discovery of the adenylyl cyclase signal mechanism (ACSM) of action of insulin and other peptides of the insulin superfamily in tissues of mammals, human, and mollusc. A. cygnea; (3) concept of molecular defects in hormonal signal systems as causes of endocrine diseases. Studies on the ST model have revealed in mollusc smooth muscle on the background of hyperglycemia at the 2nd, 4th, and 8th day after the ST administration a decrease of the ACSM response to activating action of insulin, IGF-1, and relaxin. These functional disturbances were the most pronounced at the 2nd day of development and rather less marked at the 4th and 8th day. Analysis of data on effect of hormonal and non-hormonal (NaF, GIDP, and forskolin) ACSM activators has shown that the causes of impair of signal-transducing function of this mechanism are (1) a hyperglycemia-induced increase of the basal AC activity and as a consequence--a decrease of the enzyme catalytic potentials in response to hormone; (2) a decrease of functions of Gs-protein and of its coupling with AC. Besides, administration of ST produced in the mollusc muscles an attenuation of regulation by insulin of carbohydrate metabolism enzyme (glucose-6-phosphate dehydrogenase, glycogensynthase). The pattern of disturbances in the studied parameters in the mollusc is very similar to that revealed by the authors in rat and human muscle tissues in type 1 diabetes.

[Comparative study of molecular mechanisms of natural and synthetic polycationic peptides action on the activity of the adenylyl cyclase signaling system].

The molecular mechanisms of action of natural and synthetic polycationic peptides, forming amphiphilic helices, on the heterotrimeric G-proteins and enzyme adenylyl cyclase (AC), components of hormone-sensitive AC system, were studied. It is shown that synthetic peptides C-epsilonAhx-WKK(C10)-KKK(C10)-KKKK(C10)-YKK(C10)-KK (peptide I) and (GRGDSGRKKRRQRRRPPQ)2-K-epsilonAhx-C(Acm)(peptide II) in dose-dependent manner stimulate the basal AC activity, inhibit forskolin-stimulated AC activity and decrease both stimulating and inhibiting AC effects of the hormones in the tissues (brain striatum, heart muscle) of rat and in smooth muscles of the mollusc Anodonta cygnea. AC effects of these peptides are decreased after membrane treatment by cholera and pertussis toxins and are inhibited in the presence of the peptides, corresponding to C-terminal regions 385-394 alphas- and 346-355 alphai2-subunits of G-proteins. These data give evidence that the peptides I and II act on the signaling pathways which are realized through Gs- and Gi-proteins. At the same time, natural polycationic peptide mastoparan acts on AC system through Gi-proteins and blocks hormonal signals mediated via Gi-proteins only. Consequently, the action of mastoparan on G-proteins is selective and differs from the action of the synthetic peptides. It is also shown that peptide II, with branched structure, directly interacts not only with G-proteins (less effective in comparison with peptide I with hydrophobic radicals and mastoparan), but also with enzyme AC, the catalytic component of AC system. On the basis of data obtained the following conclusions were made: 1) the formation of amphiphilic helices is not enough for selective activation of G-protein by polycationic peptides, and 2) the primary structure of the peptides, the distribution of positive charged amino acids and hydrophobic radicals in them are very important for selective interaction between polycationic peptides and G-proteins.

Role of prostaglandin E2 in regulation of low and high water osmotic permeability in frog urinary bladder.

The water osmotic permeability of frog urinary bladder was found to be increased from 0.08 +/- 0.01 to 1.28 +/- 0.20 microl/min cm2 when serosal bathing medium was changed 4 times for a fresh Ringer solution. High epithelium permeability is accompanied by an increased content of cyclic AMP in the bladder tissue (by 42%, P < 0.01), higher activity of both basal and forskolin-stimulated membrane adenylate cyclase (AC) (by 109% and 74%, respectively, P < 0.05) and by appearance of aggregates of intramembranous particles in the apical membrane. The water flow was inhibited by 10(-9)-10(-5) M prostaglandin E2 (PGE2); the inhibitory effect was eliminated in the presence of 10(-4) M N-ethylmaleimide. The increase of water permeability due to changes of the bathing medium was accompanied by a decrease of serosal PGE2 concentration from 14.8 +/- 1.0 in the 1st solution to 0.6 +/- 0.1 nM in the 5th. 10(-6) M PGE2 in vitro inhibited the activity of membrane AC from highly permeable bladders by 33.4% (P < 0.02). Pretreatment of the membranes with 10 microg/ml pertussis toxin (PT) completely reversed this effect (+149%, P < 0.01). A significant activation of AC was also observed under 10(-10) M PGE2 (by 196%). These data demonstrate that the water permeability could be markedly increased independently of ADH, suggesting that the trigger role in activation of water transport is played by a decreased level of PGE2 which could stimulate AC.

Effects of the C-terminal peptide of the alphaS subunit of the G protein on the regulation of adenylyl cyclase and protein kinase A activities by biogenic amines and glucagon in mollusk and rat muscles.

The C-terminal parts of the a subunits of heteromeric G proteins play an important role in the functional linkage of G proteins with receptors of the serpentine type. The present report describes studies of the effects of the C-terminal octapeptide 387-394 of the alphaS subunit of the mammalian G protein on the transmission of the hormonal signal via the hormone-sensitive adenylyl cyclase signal system, whose major components are receptors of the serpentine type, G proteins, and the enzymes adenylyl cyclase and protein kinase A. The peptide synthesized here, 387-394 amide (10(-7) - 10(-4) M), dose-dependently decreased adenylyl cyclase and protein kinase A activities stimulated by serotonin and glucagon in smooth muscle from the freshwater bivalve mollusk Anodonta cygnea and by the beta agonist isoproterenol in rat skeletal muscle. At a concentration as low as 10(-7) M, the peptide released potentiation of the stimulatory effects of hormones on adenylyl cyclase activity due to the non-hydrolyzable guanine nucleotide analog Gpp[NH]p. At the same time, it had almost no effect on the stimulation of adenylyl cyclase activity by non-hormonal agents (NaF, Gpp[NH]p, and forskolin). The inhibitory effects of hormones on adenylyl cyclase and protein kinase A activities persisted in the presence of the peptide. Our data demonstrate the importance of the C-terminal part of the alphaS subunit of the stimulatory G protein for its functional linkage with receptors of the serpentine type and throw light on the molecular mechanisms of the interactions between G proteins and receptors.

[Molecular causes of changes in sensitivity of adenylyl cyclase signaling system to biogenic amines in the heart muscle during experimental streptozotocin diabetes].

Changes in hormonal sensitivity of the adenylyl cyclase signaling system (ACS) and their possible molecular causes in the heart muscle of rats with experimental streptozotocin diabetes (type I diabetes) are investigated. An increase in stimulating effects of noradrenaline and isoproterenol on adenylyl cyclase (AC) activity have been shown. In the case of noradrenaline, this increase is due to suppression of Gi-protein function and Gi-coupled inhibitory AC signaling pathway. Meanwhile, in diabetic rats the influence of C-terminal peptide 346-355 of alphai2-subunit on hormonal activation of AC and GTP-binding is diminished. In the case of isoproterenol, along with its stimulating effect, at micromolar concentrations this hormone exerts inhibitory action, realized, presu- mably, through beta3-adrenergic receptors. Effect of isoproterenol on AC and GTP-binding in the heart of diabetic animals is modified by peptide 385-394 alphas, blocking Gs-coupled signaling pathways, and by peptide 346-355 alphai2, blocking transduction of inhibitory signals. In addition, a decrease in serotonin stimulating effect on components of ACS in diabetic animals was shown. The data obtained provide evidence for changes in ACS function in diabetes, which can be detected mainly at the G-protein level. The proposed peptide strategy is a new and perspective approach for studying molecular causes of functional violations in hormonal signaling systems arising at endocrine pathology.

[Inhibitory action of polycationic peptides on hormonal regulation of adenylyl cyclase of the ciliate Dileptus anser].

To analyse molecular mechanisms of regulatory action of different hormones on the activity of the adenylyl cyclase signaling system (ACS) of the ciliate Dileptus anser, we studied the influence on this process of six synthetic polycationic peptides and peptides, corresponding to C-terminal regions of mammalian G-protein 385-394 alphas- and 346-355 alphai2-subunits. As we reported earlier, these peptides block hormonal signal transduction in tissues of the higher eukaryotes. Now it has been found that both polycationic peptides, containing hydrophobic C to-radicals, and branched peptides decrease regulatory effects of peptide hormones (insulin, relaxin) and biogenic amines (serotonin, adrenaline) on adenylyl cyclase (AC) activity and GTP-binding. In regard to the following peptides Cys-epsilonAhx-Trp-Lys-Lys(C10)-Lys2-Lys(C10)-Lys3-Lys(C10)-Tyr-Lys-Lys(C10)-Lys-Lys-amide and [(Gly-Arg-Gly-Asp-Ser-Gly-Arg-Lys-Lys-Arg-Arg-Gln-Arg-Arg-Arg-Pro- Pro-Gly)2-Lys-EAhx-Cys]2 (epsilonAhx - E-aminocaproyl, C10 - caprinoyl group) their dose-dependent inhibitory action is shown. In cell culture of D. anser with a lower basal AC activity, both hydrophobic and branched peptides stimulated AC and GTP-binding without hormones. The data give evidence that these peptides can activate ACS of ciliates in a receptor-independent manner. No influence of peptides 385-394 alphas and 346-355 alphai2 on hormonal signal transduction in D. anser was observed, due, presumably, to some structural differences of G-proteins of the lower and higher eukaryotes. A conclusion was made about an important role of polycationic regions for functional coupling of hormone-activated receptor and G-proteins in the ciliate D. anser.

On the tyrosine kinase mechanism of the novel effect of insulin and insulinlike growth factor I. Stimulation of the adenylyl cyclase system in muscle tissues.

For the first time, insulinlike growth factor I (IGF-I), like insulin (Pertseva et al., Comp Biochem Physiol 112: 689-695, 1995), was shown to exercise a GTP-dependent stimulating action on adenylyl cyclase (AC; EC 4.6.1.1.) activity in the muscle tissues (membrane fraction) of mammal (rat) and mollusc (Anodonta cygnea). By studying the mechanism of the effect of peptides with selective inhibitors of tyrosine kinase activity, tyrphostin 47 (RG50864, 3,4-dihydroxy-alpha-cyanothiocinnamamide) and genistein (4,5,7-trihydroxyisoflavone), it was found that receptor tyrosine kinase is involved in this action. The data obtained suggest that the stimulating effect of insulin and IGF-1 is produced via the following signalling system: receptor tyrosine kinase --> stimulatory G-protein --> AC. Thus, the existence of a novel signalling pathway of transduction of signals generated by insulin and related peptides was hypothesised.

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.

A novel view on the mechanisms of action of insulin and other insulin superfamily peptides: involvement of adenylyl cyclase signaling system.

A new signaling mechanism common to mammalian insulin, insulin-like growth factor I, relaxin and mollusc insulin-like peptide, and involving receptor-tyrosine kinase==>G(i) protein (betagamma)==>phosphatidylinositol-3-kinase==>protein kinase Czeta==>adenylyl cyclase==>protein kinase A was discovered in the muscles and some other tissues of vertebrates and invertebrates. The authors' data were used to reconsider the problem of participation of the adenylyl cyclase-cAMP system in the regulatory effects of insulin superfamily peptides. A hypothesis has been put forward according to which the adenylyl cyclase signaling mechanism producing cAMP has a triple co-ordinating role in the regulatory action of insulin superfamily peptides on the main cell processes, inducing the mitogenic and antiapoptotic effects and inhibitory influence on some metabolic effects of the peptides. It is suggested that cAMP is a key regulator responsible for choosing the transduction pathway by concerted launching of one (proliferative) program and switching off (suppression) of two others, which lead to cell death and to the predomination of anabolic processes in a cell. The original data obtained give grounds to conclude that the adenylyl cyclase signaling system is a mechanism of signal transduction not only of hormones with serpentine receptors, but also of those with receptors of the tyrosine kinase type (insulin superfamily peptides and some growth factors).

Involvement of the adenylyl cyclase signaling system in the action of insulin and mollusk insulin-like peptide.

Involvement of the adenylyl cyclase signaling system in the mechanism of action of the mammalian insulin and epidermal growth factor as well as of insulin-like peptide isolated from the bivalve mollusk Anodonta cygnea has been studied. It was shown for the first time that insulin and insulin-like peptide exert in vitro the GTP-dependent stimulating action on the adenylyl cyclase activity. Epidermal growth factor has an analogous effect. Effectiveness of the peptides decreased in the order insulin-like peptide > epidermal growth factor > insulin in the foot smooth muscles of A. cygnea and insulin > epidermal growth factor > insulin-like peptide in the skeletal muscles of rat.