Vailable on the putative role of cHH as a modulator of aggression. To fill this gap in knowledge, here we investigate the possible influence that cHH exerts on the agonistic behaviour of the red swamp crayfish, Procambarus clarkii. Specifically, we hypothesized that cHH, similarly to serotonin, could affect crayfish behaviour to the extent of reversing the hierarchical rank in combating pairs. To test this hypothesis, we manipulated the agonistic level of males in size-matched pairs through the injection of a dose of native cHH or phosphate saline solution (PBS) into the crayfish circulation. Our aims were to (1) describe the possible effect of cHH on the agonistic behaviour of crayfish and its duration, (2) assess the increased glycaemic level due to cHH injections, and (3) test whether possible changes in aggression associated with cHH injections are sufficient to reverse an established TA-02 site dominance hierarchy. Our general purpose is to quantify the possible effects of cHH on crayfish agonistic behaviour and to discuss the relative importance of other intrinsic/extrinsic factors in maintaining dominance hierarchies.Extraction of Native cHHTwenty animals were anesthetized for 5 min on ice before eyestalk ablation. From 40 eyestalks the crude extract of dissected sinus glands was collected by adding 200 mL of extraction solution (90 MetOH, 9 acetic acid, 1 H2O). After sonication, the sample was centrifuged at 12 0006 g for 10 min at 4uC and the supernatant was collected. The pellet was suspended in 200 mL of the extraction solution, sonicated and centrifuged again, and the two supernatants were mixed together. 1480666 The extract was purified on an RP-HPLC system (purchase 1454585-06-8 Gilson) equipped with a Zorbax SB-C18 4.66150 mm column from Agilent Technologies Inc. (DE, USA) thermostated at 25uC. Mobile phase A was 0.1 TFA in water, mobile phase B was 0.1 TFA in acetonitrile. The separation was done using a gradient of 0?00 B in 60 min at 1 mL/min. The resulting chromatogram is shown in Figure 1. The collected fractions were analyzed on an API150EX single quadrupole mass spectrometer (ABSciex), and those fractions containing the expected molecular mass of 8386 Da [37] were pooled and lyophilized. Peptide concentration was determined by UV absorbance at 280 nm using calculated e values of 9315 M21 cm21 for the peptide oxidized form. The extinction coefficient was computed using the ProtParam programme on the ExPASy server [38].Experimental Design (Fig. 2)Behavioural experiments were conducted in the laboratory 24786787 from 0800 to 1400 h during August 2011 to reduce possible interference due to circadian changes in blood glucose level [39]. During observations, we recorded the effects through time of the injected native cHH extract on crayfish behaviour and examined whether such extract might induce a change in the hierarchy. The experiment was planned in five phases in sequence, as described below.Phase 1: Hemolymph sampling and determination of initial glycemia. The animals were blotted dry and hemolymph (about 50 ml) was drawn from the pericardial sinus intoMaterials and Methods Collection and Holding ConditionsAbout 200 male crayfish were collected using baited traps from Lake Trasimeno (Umbria, central Italy) in July 2011 by professional fishermen. Once in the laboratory, each crayfish was individually marked onto its carapace with a waterproof paint and its cephalothorax length (from the tip of the rostrum to the posterior edge of the carapace) was measured usi.Vailable on the putative role of cHH as a modulator of aggression. To fill this gap in knowledge, here we investigate the possible influence that cHH exerts on the agonistic behaviour of the red swamp crayfish, Procambarus clarkii. Specifically, we hypothesized that cHH, similarly to serotonin, could affect crayfish behaviour to the extent of reversing the hierarchical rank in combating pairs. To test this hypothesis, we manipulated the agonistic level of males in size-matched pairs through the injection of a dose of native cHH or phosphate saline solution (PBS) into the crayfish circulation. Our aims were to (1) describe the possible effect of cHH on the agonistic behaviour of crayfish and its duration, (2) assess the increased glycaemic level due to cHH injections, and (3) test whether possible changes in aggression associated with cHH injections are sufficient to reverse an established dominance hierarchy. Our general purpose is to quantify the possible effects of cHH on crayfish agonistic behaviour and to discuss the relative importance of other intrinsic/extrinsic factors in maintaining dominance hierarchies.Extraction of Native cHHTwenty animals were anesthetized for 5 min on ice before eyestalk ablation. From 40 eyestalks the crude extract of dissected sinus glands was collected by adding 200 mL of extraction solution (90 MetOH, 9 acetic acid, 1 H2O). After sonication, the sample was centrifuged at 12 0006 g for 10 min at 4uC and the supernatant was collected. The pellet was suspended in 200 mL of the extraction solution, sonicated and centrifuged again, and the two supernatants were mixed together. 1480666 The extract was purified on an RP-HPLC system (Gilson) equipped with a Zorbax SB-C18 4.66150 mm column from Agilent Technologies Inc. (DE, USA) thermostated at 25uC. Mobile phase A was 0.1 TFA in water, mobile phase B was 0.1 TFA in acetonitrile. The separation was done using a gradient of 0?00 B in 60 min at 1 mL/min. The resulting chromatogram is shown in Figure 1. The collected fractions were analyzed on an API150EX single quadrupole mass spectrometer (ABSciex), and those fractions containing the expected molecular mass of 8386 Da [37] were pooled and lyophilized. Peptide concentration was determined by UV absorbance at 280 nm using calculated e values of 9315 M21 cm21 for the peptide oxidized form. The extinction coefficient was computed using the ProtParam programme on the ExPASy server [38].Experimental Design (Fig. 2)Behavioural experiments were conducted in the laboratory 24786787 from 0800 to 1400 h during August 2011 to reduce possible interference due to circadian changes in blood glucose level [39]. During observations, we recorded the effects through time of the injected native cHH extract on crayfish behaviour and examined whether such extract might induce a change in the hierarchy. The experiment was planned in five phases in sequence, as described below.Phase 1: Hemolymph sampling and determination of initial glycemia. The animals were blotted dry and hemolymph (about 50 ml) was drawn from the pericardial sinus intoMaterials and Methods Collection and Holding ConditionsAbout 200 male crayfish were collected using baited traps from Lake Trasimeno (Umbria, central Italy) in July 2011 by professional fishermen. Once in the laboratory, each crayfish was individually marked onto its carapace with a waterproof paint and its cephalothorax length (from the tip of the rostrum to the posterior edge of the carapace) was measured usi.
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