On the mechanism of relaxin action: the involvement of adenylyl cyclase signalling system

The molecular mechanism of relaxin action was studied taking into account the evolutionary relationship of the peptides belonging to the insulin superfamily and using the authors' previous data on the involvement of the adenylyl cyclase (AC) signalling system in the action of insulin and related peptides. Human relaxin 2 (10(-12)-10(-8) M) has been shown to cause a dose-dependent activating effect on AC in the human myometrium (+370%), in rat skeletal muscles (+117%) and the smooth foot muscles of the bivalve mollusc Anodonta cygnea (+73%). In these tissues mammalian insulin and insulin-like growth factor-1 (IGF-1) also had the AC activating effect. The order of efficiency of the above peptides based upon their ability to induce the maximal AC activating effect was as follows: relaxin > IGF-1 > insulin (human myometrium); IGF-1 > relaxin > insulin (rat skeletal muscle); molluscan insulin-like peptide > IGF-I > insulin > relaxin (molluscan muscle). The relaxin AC activating effect was inhibited with a selective tyrosine kinase blocker tyrphostin 47 and potentiated with Gpp[NH]p providing evidence for the participation of the receptor-tyrosine kinase and G-protein of the stimulatory type (Gs) in the regulatory action of relaxin. The conclusion is that the signalling chain: receptor tyrosine kinase ==> Gs protein ==> AC is involved in the mechanism of relaxin action.     

The hormone-sensitive adenylyl cyclase system of the ciliate Dileptus anser

The hormone-sensitive adenylyl cyclase system (AC system) was found and characterized for unicellular eukaryotes--the ciliatae Dileptus anser. It has been first shown that hormones of higher eukaryotes--biogenic amines (adrenalin, isoproterenol and serotonin) and peptide glucagon--stimulate in dose-dependent manner the activity of adenylyl cyclase (AC) of D. anser. The enzymatic activity was stimulated also by guanine nucleotides--GTP and their non-hydrolysable analogue Gpp[NH]p. Stimulating effects of hormones and guanine nucleotides strongly depend on the level of AC basal activity, which is relatively easy to reach (1430 to 3900 pmol cAMP/min per 1 mg of protein). The sensitivity of D. anser AC system to hormones and guanine nucleotides shows the presence of receptor or receptor-related molecules, capable of interacting with the hormone and activating AC through heterotrimeric G-proteins, in ciliatae. On the base of obtained data, a conclusion is made about the similarity of the structural-functional organization of AC systems of D. anser and higher eukaryotes.     

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.     

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.     

<Emphasis Type="Italic">Burkholderia</Emphasis> Hep_Hag autotransporter (BuHA) proteins elicit a strong antibody response during experimental glanders but not human melioidosis

Background  

The bacterial biothreat agents Burkholderia mallei and Burkholderia pseudomallei are the cause of glanders and melioidosis, respectively. Genomic and epidemiological studies have shown that B. mallei is a recently emerged, host restricted clone of B. pseudomallei.     

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.     

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.