Insulin-Like Peptides of the Cerebropleural Ganglion of the Mollusc Anodonta cygnea: Isolation, Purification, and Radioligand Analysis

Cerebropleural ganglia from 4000 individuals of the mollusc Anodonta cygnea were submitted to procedures developed for isolation of vertebrate pancreatic insulins: homogenization and extraction, stage-like isoelectrical sedimentation, and ion-exchange chromatography. As a result of purification of the obtained preparation, using high-effective liquid chromatography, there were identified 7 protein peaks differing by time of retention on the reverse-phase sorbent in acetonitryl gradient and designated as insulin-related peptides (IRP), IRP1-IRP7. The material was characterized by the peptide ability to inhibit specific binding of ¹²⁵I-insulin and of insulin-related factor-1 (¹²⁵I-IGF-1) by plasma membranes of the rat liver and brain. The IC₅₀ value of peptide concentration (nM) able to replace 50% of the labeled hormone bound with the receptor amounted in the insulin radioreceptor system for IRP1 to 330, for IRP3 to 130, for IRP4 to 17, for IRP5 to130, for IRP6 to 420 nM. Peptide IRP7 at a maximal concentration (10⁴ ng/ml) replaced less than 50% of labeled hormone, whereas in IRP2 no inhibitory ability was detected under these experimental conditions. The IC₅₀ value in the case of ¹²⁵I-IGF-1 amounted for IRP1, IRP4, and IRP5 to17, for IRP2 to 50, for IRP3 to 83, for IRP6 to 133 nM. IRP7 at a concentration of 10⁴ ng/ml replaced less than 50% of labeled hormone. The same high relative affinity of the peptide IRP4 (12% of activity of standard insulin and IGF-1) to both receptor types is revealed. The results of analysis in two types of hormonal test systems indicate the ability of the insulin-related peptides of the anodonta cerebropleural ganglion to interact with the vertebrate receptor of insulin and IGF-1. This gives grounds to suggest the presence of the metabolic and growth-stimulating properties in these peptides. For the first time, the IGF-1 activity is revealed in insulin-like molecules in invertebrates. Taking into account the chromatographically revealed differences of physicochemical characteristics of individual IRP as well as predominance of their IGF-1-binding properties, there is suggested another organization of the IRP receptor-binding domains in IPR of this mollusc species, as compared with mammalian insulins.     

The FTO A/T Polymorphism and Elite Athletic Performance: A Study Involving Three Groups of European Athletes

Objective

The FTO A/T polymorphism (rs9939609) is a strong candidate to influence obesity-related traits. Elite athletes from many different sporting disciplines are characterized by low body fat. Therefore, the aim of this study was to assess whether athletic status is associated with the FTO A/T polymorphism.

Subjects and Methods

A large cohort of European Caucasians from Poland, Russia and Spain were tested to examine the association between FTO A/T polymorphism (rs9939609) and athletic status. A total of 551 athletes were divided by type of sport (endurance athletes, n = 266 vs. sprint/power athletes, n = 285) as well as by level of competition (elite-level vs. national-level). The control group consisted of 1,416 ethnically-matched, non-athletic participants, all Europeans. Multinomial logistic regression analyses were conducted to assess the association between FTO A/T genotypes and athletic status/competition level.

Results

There were no significantly greater/lesser odds of harbouring any type of genotype when comparing across athletic status (endurance athletes, sprint/power athletes or control participants). These effects were observed after controlling for sex and nationality. Furthermore, no significantly greater/lesser odds ratios were observed for any of the genotypes in respect to the level of competition (elite-level vs. national-level).

Conclusion

The FTO A/T polymorphism is not associated with elite athletic status in the largest group of elite athletes studied to date. Large collaborations and data sharing between researchers, as presented here, are strongly recommended to enhance the research in the field of exercise genomics.     

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.     

Purification and ligand-receptor analysis of insulin-related peptides from pedal ganglion of the mollusc Anodonta cygnea

Six insulin-related peptides (IRPs) from pedal ganglions of the molluscs Anodonta cygnea have been isolated and purified by reverse-phase chromatography. Each peptide (designated as IRP8-IRP13) showed its own retention time on the HPLC column. The testing of IRPs in radioreceptor systems specific for insulin and insulin growth factor-I (IGF-I) showed their ability to bind to both types of receptors. The concentration of IRPs, producing a 50% inhibition of porcine 125I-insulin binding with rat liver plasma membrane receptors (IC50) for IRP 10, was 1167 nM, IRP11--833 nM, IRP13--1333 nm. IRP8, IRP9, IRP12 in the maximum concentration of 10(4) ng/ml displaced less than 50% of labeled hormone. All of the six peptides were capable of competing with human 125I-IGF-I for binding to receptors of a fraction of rat brain membranes. IRP8, IRP9 and IRP12 had close means equal to 1167 nM, 1500 nM, 1167 nM, respectively. Another group including IRP10, IRP11 and IRP13 showed a much higher activity (833, 83 and 500 nM, respectively). The results obtained from radioligand analysis revealed the predominance of IGF-I binding properties in all peptides of pedal ganglions. At the same time, apparent proximity of IRP's physico-chemical characteristics to porcine insulin, and also the revealed dose-dependent binding to both insulin and IGF-I receptors suggest a bifunctionality of mollusc peptides. The expression level of this bifunctionality may be associated with the molecular structure pecularities of individual isoforms.     

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.     

Activity of receptor guanylyl cyclases in rats with neonatal streptozotocin diabetes and effect of intranasal administration of insulin and serotonin

In diabetes mellitus (DM) and its complications the functional activity of hormonal signaling systems and their sensitivity to the regulatory action of hormones are changed. We studied the activity of receptor forms of guanylyl cyclase (rGC) sensitive to natriuretic peptides ANP and CNP in the tissues of female rats with 240 day neonatal streptozotocin DM and the effects of intranasal administration of insulin and serotonin (6 weeks, daily dose for rat is 0.48 IU insulin or 20 μg serotonin). In diabetic rats, the increase of the basal rGC activity in the myocardium and its decrease in the uterus and ovaries were found, while in the brain, there were no differences from the control. The treatment of diabetic rats with insulin led to a decrease of the basal rGC activity in the myocardium and its restoration to a normal level in the ovaries. The administration of serotonin produced a less pronounced decrease in the basal enzyme activity in the myocardium compared to insulin and an insignificant increase in the brain. In the myocardium of diabetic rats, the guanylyl cyclase (GC)-stimulating effect of ANP was attenuated, whereas the CNP effect was enhanced; in the ovaries, the GC-stimulating effect of CNP and, to a lesser degree, the effect of ANP were decreased. In the uterus and brain of a diabetic rats, the rGC sensitivity to hormones was practically did not change. The administration of insulin to diabetic rats induces an increase of GC effect of ANP in the myocardium to its values in control and a decrease of CNP effect, as well as partially restored GC effect of CNP in the ovaries under the influence of CNP. The administration of serotonin somewhat enhanced effect of natriuretic peptides in the brain of both control and diabetic animals. Thus, in the neonatal model of type-2 DM in the myocardium and the tissues of the reproductive systems of rats, the functioning of natriuretic peptide-sensitive rGC is changed. The treatment of animals by insulin substantially restores rGC activity, while the intranasal serotonin administration has a little effect.