Functional activity of adenylyl and guanylyl cyclases in human spermatozoa with different motility

The most important functional characteristic of ejaculated spermatozoa is their ability to engage in directed sustained movement, which to a large extent determines their fertility. It is assumed that enzymes with cyclase activity—adenylyl cyclase (AC) and guanylyl cyclase (GC)—soluble and membrane-bound forms of which are found in human and mammalian sperm, play the key role in regulation of motility. However, the functional activity of the cyclases in ejaculated spermatozoa with different motilities and their contribution to the regulation of this process are virtually unexplored. The goal of this work was to determine the functional characteristics of AC and GC in ejaculates of human spermatozoa with different contents of motile forms and the study of regulation of these enzymes by hormones and nonhormonal agents. We found differences in the activity and regulatory properties of AC and GC in ejaculates differing in motile forms of spermatozoa. The basal AC activity and its sensitivity to bicarbonate anions and manganese cations, activators of cytosolic AC (cAC), were increased in ejaculates with a high proportion of motile spermatozoa. At the same time, the AC effects of forskolin, GppNHp, and adrenergic receptor agonists acting via membrane-bound AC (mAC) in this case were significantly reduced. Cytosolic GC in the ejaculates with a high proportion of motile spermatozoa was more sensitive to manganese cations, but the basal activity of GC was altered slightly. An increase in the content of motile spermatozoa in ejaculate led to a decrease in the sensitivity of CNP to receptor GC, while the sensitivity to ANP was maintained, which indicates a change in the pattern of enzyme regulation with natriuretic peptides in favor of ANP, an important regulator of sperm chemotaxis. Thus, we have concluded that the change in proportion of motile spermatozoa in ejaculate induces changes of functional activity and regulatory properties of soluble and membrane-bound forms of AC and GC, which can be used to control the motility, chemotaxis, acrosomal reaction, and other processes determining fertility of male germ cells.     

The effect of prolonged intranasal administration of serotonin on the activity of hypothalamic signaling systems in male rats with neonatal diabetes

The functioning of the serotonergic system of the brain is impaired in type II diabetes (T2D), and this leads to metabolic and hormonal dysfunction. The elevation of serotonin level in the CNS is one of the approaches for correcting of the serotonergic system of the brain. The aim of the present work was to investigate the effect of intranasal serotonin (InS) administration for 5 weeks at a daily dose of 20 μg on the metabolic parameters and functional activity of adenylate cyclase signaling system (ACSS) sensitive to peptide hormones and biogenic amines in the hypothalamus of male rats with neonatal T2D. Neonatal model of T2D was induced by injecting streptozotocin (70 mg/kg) into 5-day-old rat pups. Four-month-old animals with apparent T2D manifestations were divided into two groups: an untreated group (D0, n = 6) and a group that received InS treatment (DIS, n = 6). InS administration to diabetic rats restored ACSS regulation by the agonists of type 2 dopamine receptors (DA₂R) and type 4 melanocortin receptors (MC₄R) and enhanced the inhibitory effect of serotonin on adenylate cyclase activity. Elevated expression of genes encoding DA₂R, MC₄R, and serotonin receptor of the 1B subtype (5-HT_1BR) was among the main causes of this change. The relative activity of signaling cascades involving various types of serotonin (G_s-coupled 5-HT_4,6,7R/G_i-coupled 5-HT₁R), dopamine (DA₁R/ DA₂R), and melanocortin (MC₃R/MC₄R) receptors involved in ACSS regulation was also altered in the animals of the DIS group. InS administration restored hormonal regulation in the hypothalamus, improved glucose tolerance, and increased the sensitivity of tissues to insulin. The data obtained show that the elevation of serotonin level in the CNS is a promising approach for the recovery of hypothalamic signaling pathways in T2D and correction of the metabolic disturbances dependent on these pathways.     

The helices with heptad regularity in cytoplasmic domains of membrane-bound adenylyl cyclases and their possible role in interaction with other adenylyl cyclase signaling system components

The helices with heptad regularity in C1 and C2 cytoplasmic domains of membrane-bound adenylyl cyclases (AC) of mammals were identified. The most helices were localized in N-terminal and central regions of high conservative C1a and C2a subdomains of AC. The regions are responsible for regulation of enzyme functional activity. The amino acid regions, corresponding to these helices, were homologous to G-protein beta and gamma subunit regions, which participate in coupling with alpha subunits and in forming the heterotrimeric alpha beta gamma complex. The similarity was found both primary and secondary structure levels. On the basis of obtained data the next supposition was made. The regular helices of C1a and C2a subdomains of AC can interact with G protein alpha-helices the by coiled-coil mechanism and thus regulate the AC catalytic activity. Additionally, the regular helices were identified in variable C1b and C2b subdomains of several AC types (in particular, I and III types). Some of the helices are similar in the secondary structure level to amphipatic helices of bacterial AC, which participate in calmodulin binding, and can carry out also the calmodulin-binding function.     

Molecular mechanisms of action of dendrons, containing 48-60 sequence of HIV-1 TAT-protein, on the functional activity of the adenylyl cyclase signaling systems

For the aims of studying molecular mechanisms of functioning of adenylyl cyclase signaling systems (ACS), we investigated the influence of synthetic polycationic peptides of the star-like structure (dendrons), containing 48-60 sequence of HIV-1 TAT-protein, on the functional activity of ACS components in smooth muscles of the mollusc Anodonta cygnea and in rat skeletal muscles. It has been shown that the following peptides (Gly-Arg-Lys-Lys-Arg-Arg-Gln-Arg-Arg-Arg-Pro-Pro-Gln)2-Lys-epsilonAhx(= epsilon-aminohexanoic acid)-Cys(Acm), referred to as peptide I, (Gly-Arg-Gly-Asp-Ser-Gly-Arg-Lys-Lys-Arg-Arg-Gln-Arg-Arg-Arg-Pro-Pro-Gln)2-Lys-epsilonAhx-Cys(Acm) (peptide II), [(Gly-Arg-Lys-Lys-Arg-Arg-Gln-Arg-Arg-Arg-Pro-Pro-Gln)2-Lys-epsilonAhx-Cys]2 (peptide III), and [(Gly-Arg-Gly-Asp-Ser-Gly-Arg-Lys-Lys-Arg-Arg-Gln-Arg-Arg-Arg-Pro-Pro-Gln)2-Lys-epsilonAhx-Cys]2 (peptide IV) inhibit in a dose-dependent manner the adenylyl cyclase (AC) activity stimulated by both nonhormanal agents (GppNHp and forskolin) and hormones, such as serotonin (mollusc) and isoproterenol (rat). Peptides III and IV (tetrameric dendrons) were most effective in comparison with peptides I and II (dimeric dendrons). The AC activity stimulated by hormones and forskolin was most sensitive to the action of dendrons. All dendrons stimulated GTP-binding activity of G-proteins: dimeric dendrons were most effective at 10(-5) M concentration, whereas tetrameric dendrons at 10(-6) M. In the presence of dendrons, the affinity of beta-antagonist [3H]-dihydroalprenolol to P-adrenergic receptor in rat muscle mem- branes was unchanged. At the same time, the affinity of beta-agonist isoproterenol to the receptor decreased, and no shift to the right was observed on the curve of isoproterenol-induced [3H]-dihydroalprenolol displacement in the presence of GTP. The obtained data show the disturbance of the coupling between the receptor and G-protein, which is the main reason of dendron inhibitory action on AC stimulation by hormones. Besides, these data demonstrated that hormones could disturb the functional activity of AC, i.e. a catalytic component of ACS.     

Effect of synthetic cationic peptides on activation of the adenylyl cyclase signaling system by biogenic amines in muscle tissue of molluscs and rats

The hormone-sensitive adenylyl cyclase signaling system (ACS), made of serpentine receptor, heterotrimeric G-protein and enzyme adenylyl cyclase (AC), regulates a wide spectrum of growth and metabolic processes in the cell. Molecular mechanisms of functional coupling of ACS components still remain obscure. We examined the influence of synthetic cationic peptides Ac-Ala-His(Ala)2-His-Ala-NH2 (I), Ac-Ala-His-(Ala)3-His-(Ala)2-His-Ala-NH2 (II), and Ac-(Pro)2-His-(Ala)2-His-(Ala)3-His-(Ala)2-His-Ala-NH2 (III) on the basal AC activity and that stimulated by nonhormonal (NaF) and hormonal reagents (serotonin--molluscs, beta-isoproterenol--rats) in smooth muscles of the freshwater bivalve molluscs Anodonta cygnea and in skeletal muscles of rats. Peptides II and III (the latter more effective) were shown to decrease hormone-stimulated AC activity in both tissues, in a dose-dependent manner. Peptide III strongly reduced NaF stimulating effect to AC, which suggests the involvement of this peptide in the functional coupling of both receptors with G-proteins, and of G-proteins with AC. A correlation was found between the efficacy of peptide action on the functional activity of ACS components and peptide length. As shown by IR-spectroscopy, in water all peptides can form helical structures. However, alpha-helicity of peptides I and II was higher than that of peptide III, which does not conform to a power series in efficacy of these peptides. Thus, it is the length of cationic peptides that plays a key role in hormonal regulation of the functional activity of ACS, especially on the step of receptor-G-protein coupling.     

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.