Ecdysone titers during the molt cycle of the crayfish Orconectes sanborni

Do arthropods feel anxious during molts?

The molting process of arthropods, chiefly controlled by ecdysteroids, is generally considered very stressful. Our previous investigations have shown that crayfish, after having experienced stressful situations, display anxiety-like behavior (ALB), characterized by aversion to light in a dark/light plus-maze (DLPM). In the present experiments, the spontaneous exploratory behavior of isolated crayfish was analyzed in a DLPM at different stages of their molt cycle. All tested animals displayed transitory aversion to light similar to ALB, before and, mostly, after molting, but not during inter-molt. Injection of ecdysteroids into inter-molt animals elicited ALB after a delay of 4 days, suggesting a long-term, possibly indirect, hormonal effect. Importantly, ecdysteroid-induced ALB was suppressed by the injection of an anxiolytic benzodiazepine. Thus, molts and their hormonal control impose internal stress on crayfish, leading to aversion behavior that has the main characteristics of anxiety. These observations are possibly generalizable to many other arthropods.

Impact of cadmium on the ecdysteroids production in Gammarus fossarum

Gammarus fossarum is an important test organism which is currently used as a bio-indicator as well as in ecotoxicological tests. Nevertheless, data on ecdysteroids in endocrine toxicity test are not yet available for these species, despite its crucial role in molting and reproduction. In the present paper, ecdysteroids concentrations were studied during the molt cycle (in females) and embryonic development in G. fossarum (Crustacea, Amphipoda) in order to propose an ecdysteroids toxicity test. Ecdysteroids levels in G. fossarum showed a single peak during premolt at stage Dl-D2. In embryos, ecdysteroids levels progressively increased over stages 3 and 4, with peak levels at stage 4. A Cadmium toxicity test was proposed to examine if the molting and embryogenesis disturbances previously observed after cadmium exposure (Geffard et al. 2010) could be attributed to changes in ecdysteroids titers. Exposure to the different cadmium concentrations (3; 9; 300; 900 µg/l) increased ecdysteroids secretion by Y-organs in vitro, but it had no significant effect on exposed embryos (in vivo). Based on previous findings, we are led to conclude that the molting impairments in cadmium-exposed females of G. fossarum is connected to the changes in ecdysteroids concentrations.

Molt-inhibiting hormone-mediated regulation of ecdysteroid synthesis in Y-organs of the crayfish (Procambarus clarkii): involvement of cyclic GMP and cyclic nucleotide phosphodiesterase

Crustacean molt-inhibiting hormone (MIH), a polypeptide secreted by the X-organ/sinus gland complex of the eyestalks, regulates molting by inhibiting the synthesis of ecdysteroids by Y-organs. Previous results indicate the biosynthetic activity of Y-organs is likely controlled not only by the level of hemolymphatic MIH, but also by the responsiveness of Y-organs to MIH. The present studies were conducted to (a) identify the second messenger that mediates MIH-induced suppression of ecdysteroidogenesis, and (b) assess the possible involvement of cyclic nucleotide phosphodiesterase (PDE) in determining the responsiveness of Y-organs to MIH. Adding 8-bromo cAMP or 8-bromo cGMP to incubation medium significantly suppressed ecdysteroid production by Y-organs of the crayfish (Procambarus clarkii). Incubating Y-organs with MIH produced a significant increase in glandular cGMP, but MIH had no effect on glandular cAMP. The composite data indicate that MIH-induced suppression of ecdysteroidogenesis in Y-organs of P. clarkii is mediated by cGMP. Subsequently, Y-organs from various stages of the molt cycle were incubated with MIH, 3-isobutyl-1-methylxanthine (IBMX, an inhibitor of PDE), or both. Y-Organs from middle and late premolt stages were poorly responsive to MIH alone. Including IBMX in the incubation medium enhanced the responsiveness of the Y-organs to MIH at these stages. Moreover, glandular PDE activity in the Y-organs at these stages was significantly higher than other stages. The combined results suggest that molt cycle-associated changes in PDE activity affect the ability of MIH to stimulate cGMP accumulation and suppress ecdysteroidogenesis in Y-organs of P. clarkii.

Proliferation and Differentiation Processes in the Heart Muscle Elements in Different Phylogenetic Groups

This article reviews, discusses, and summarizes data about the generative behavior of muscle tissue cells, the mechanisms of its regulation, and the organization of the endocrine function of the heart in the main phylogenetic groups. With respect to the ratio of processes of proliferation and differentiation, cell organization, and growth mechanism, muscle tissues of propulsive organs can be divided into three types, each revealed in one of three main groups of animals, lophotrochozoans, ecdysozoans, and chordates. Ecdysterone is likely to play the key role in the regulation of proliferation and differentiation processes in the heart muscle of crustaceans, and, most probably, also of molluscs. In each of the three main phylogenetic groups the endocrine function of the heart consisting of secretion of natriuretic peptides has a peculiar organization. Vertebrate cardiomyocytes are known to combine contractile and endocrine differentiation. Such functional dualism is absent in heart muscle elements of Lophotrochozoa and Ecdysozoa; in the heart of lopfotrochozoans, secretion of natriuretic peptides is performed by endothelial cells and their derivatives. Homology of the heart muscle in the animal kingdom as well as possible mechanisms of genomic and epigenomic regulation of different types of cardiomyogenesis are discussed.

20-hydroxyecdysone causes increased aggressiveness in female American lobsters, Homarus americanus

Lobsters become transiently more aggressive before ecdysis. This aggressiveness accompanies an increase in hemolymph titers of 20-hydroxyecdysone (20-HE). Combats between intermolt female lobsters, injected with premolt levels of 20-HE, and larger, saline-injected opponents were videotaped. Aggressive, defensive, and avoidance behaviors were ranked according to aggressiveness in a Rank of Aggression hierarchy, which included opponent-directed and (nonopponent) redirected behaviors. Treated animals performed more and more highly aggressive behaviors than saline-injected controls. Opponents of treated animals performed fewer aggressive behaviors than saline-injected control opponents. Controls performed more defensive behaviors than treated animals, when redirected behaviors were considered. Differences in avoidance behaviors among the four types of combatants were not significant. The total aggressive content was the same in treated and control fights, but the interactions between combatants in the two fights were significantly different. Treated animals were equally as aggressive and defensive as their opponents; controls were relatively less aggressive and more defensive than their opponents. These results correlate with molt-cycle variations in behavior, 20-HE titers, and the effects of 20-HE and molt-differentiated hemolymph on the claw opener muscle. They suggest that 20-HE orchestrates intrinsic, cellular, and nuclear events that produce the molt-cycle transformations in agonistic behavior and aggressive state of lobsters.

Protein production and the molting cycle in the crayfish Astacus leptodactylus (Nordmann, 1842). II. Hemocyanin and protein synthesis in the midgut gland

The midgut gland from the crayfish Astacus leptodactylus synthesizes and secretes hemocyanin and proteins linearly for at least 24 hr in vitro. There are no sex-specific differences in the rate of protein and hemocyanin synthesis. During a standard incubation of 5 hr, up to 64% of the newly synthesized protein represents hemocyanin, which is also the predominant secretory protein. There are pronounced changes in the rate of hemocyanin synthesis during the molting cycle which coincide with corresponding changes in total protein synthesis. The titer of protein and hemocyanin synthesis during an intermolt phase exhibits a biphasic profile with the highest values in intermolt stage C4 and in premolt stage D1.

Humoral factors reduce gap junction sensitivity to cytoplasmic pH. I. Organ ablation studies

The sensitivity of gap junctions connecting crayfish lateral axons to uncoupling by axoplasmic acidification was studied after altering the hormonal balance of animals by 1) ablation of eyestalks or sinus glands or 2) inducing long-lasting defensive posturing behavior (stress). Internal pH (pHi) was measured with microelectrodes, and junctional resistance (Rj) was calculated from input and transfer resistances. In isolated nerve cords from intact animals, the maximal Rj (Rjmax) reached after acidification varied diurnally (Rjmax approximately 10 and 0.6 M omega at 0900 and 1800 h, respectively). Basal Rj (20-30 k omega) did not change during the 24-h period. Organ ablation (eyestalks or sinus glands) or stress rendered gap junctions less sensitive to uncoupling by low pHi within 1 h or 2 days; recovery toward control values had different time courses. The reduced pH sensitivity of crayfish junctions seen after eyestalk ablation is attributable to stress in its early phase (lasting 1-2 days) and to ablation of the endocrine organs in its late phase (2-7 days). No striking structural differences accompanied these changes, indicating that the altered properties are not due to major changes in gap junction expression.

Ecdysteroids in relation to the molt cycle of the American lobster, Homarus americanus. I. Hemolymph titers and metabolites

Hemolymph ecdysteroid (Ecd) titers were measured using radioimmunoassay (RIA) during the molt cycle of the American lobster, Homarus americanus. Individual animals showed small, transitory rises of Ecds which increased in magnitude with the onset of premolt and culminated in a large premolt peak at morphological stages D2(2)-D3(1). Male lobsters had significant postmolt peaks and late premolt titers that remained high until ecdysis. In females, postmolt peaks were absent and late premolt titers reached basal levels before ecdysis. At least seven different Ecd metabolites were identified by high-performance liquid chromatography-RIA analyses. High polarity products (HP) were the most abundant metabolites in virtually every molt stage. Titers of HP were significantly higher in males during late postmolt-early intermolt and in late premolt. Levels of 20-hydroxyecdysone (20E) were equivalent in both sexes and correlated with the morphological changes associated with premolt. Evidence was also obtained for the presence of ecdysone, ponasterone A, and other as yet unidentified metabolites. The pattern of Ecd metabolites in the hemolymph supports other data indicative of 20E as the major molting hormone. Metabolism of 20E is primarily toward more polar compounds, including conjugates.

20 (OH) ecdysone-induced transition from intermolt to premolt protein biosynthesis patterns in the hypodermis of the crayfish, Astacus leptodactylus, in vitro

20 (OH) Ecdysone-induced alteration of protein biosynthesis and secretion by the hypodermis of the crayfish Astacus leptodactylus was studied using isolated tissues in vitro. Characteristic quantitative and qualitative changes of late intermolt tissues are governed by the hormone in a dose- and time-dependent manner. The greatest response to the hormone was observed in tissues which were exposed for 48 hr to 10(-8) M 20 (OH) ecdysone, followed by 1 day of hormone withdrawal. The observed differences correspond to the reprogramming in protein biosynthesis after transition from intermolt to the premolt stage.

Ecdysteroid titers during the molt cycle of Orchestia cavimana (Crustacea, Amphipoda)

Ecdysteroids were analyzed during a molt cycle in adult males of the crustacean Orchestia cavimana; levels were determined in the hemolymph and in whole bodies, using radioimmunoassay. Results show a single and sharp peak at the end of D1 stage, reaching 810 pg eq/microliter in the hemolymph (a 230-fold increase compared to the middle of intermolt). From B stage to the beginning of D1, levels are very low but increase regularly and significantly. The amplitude and the temporal position of the peak are discussed in detail, in relation to the precision of the staging (17 different stages can be easily made in Orchestia) and to the cuticle cycle (the hormonal peak occurs ca. 10 hr before the beginning of cuticle synthesis at D2). Preliminary experiments, using monoclonal antibodies during the period of low ecdysteroid titers or high-performance liquid chromatography followed by polyclonal RIA during the peak period, suggest that the immunoreactive hormone in O. cavimana behaves like 20-hydroxyecdysone. However, other minor compounds have been detected (some unknown, others migrating like ecdysone and ponasterone A in HPLC).

Regulation of crab Y-organ steroidogenesis in vitro: evidence that ecdysteroid production increases through activation of cAMP-phosphodiesterase by calcium-calmodulin

In decapod crustaceans steroidogenic glands (Y-organs) produce the molting hormone, ecdysone. A putative neuropeptide, molt-inhibiting hormone (MIH), released from eyestalk neurosecretory cells, directly regulates Y-organs by suppressing steroidogenesis; the effect is mediated by an increase in cAMP. We explored calcium-cAMP interactions in the regulation of Y-organs in vitro of the crab, Cancer antennarius. Basal ecdysteroid production was enhanced by extracellular calcium (EC). MIH suppression did not require EC but its action was blocked by high EC. The inhibitors of Ca2+ flux, lanthanum and ruthenium red, mimicked and enhanced MIH action. Calcium ionophore A23187 raised basal steroidogenesis dose-dependently (10(-6) to 10(-4) M) and with time course (effect evident after 2 h) similar to that of suppression by MIH. Low EC enhanced the suppressive effects on steroidogenesis of forskolin and dibutyryl cyclic AMP ((Bu)2cAMP) but not of MIH, lysine vasopressin (LVP), or 3-isobutyl-1-methyl-xanthine (IBMX); basal Y-organ cAMP levels were elevated by low EC and reduced by A23187. A23187 reduced the steroidogenic-suppressive effects of MIH, LVP, forskolin and (Bu)2cAMP but not of IBMX; rises in cAMP induced by MIH, LVP, and forskolin but not by IBMX were blunted by A23187. These findings suggested a stimulatory action of calcium on phosphodiesterase (PDE). The calmodulin (CM) inhibitor trifluoperazine (TFP; 10(-5) to 10(-4) M) reduced basal and A23187-stimulated steroidogenesis, enhanced the inhibitory effects of MIH and (Bu)2cAMP on ecdysteroid production, enhanced the stimulatory effects of MIH and forskolin on cAMP, and blocked the inhibition of cAMP by A23187. Y-organ PDE activity was enhanced by increasing free Ca2+ (10(-7) to 10(-5) M) and inhibited by TFP (10(-5) to 10(-4) M). Adenylate cyclase activity of Y-organ cell particulate fraction was unaffected by Ca2+ or TFP. Calcium stimulates steroidogenesis, apparently by activating a calcium-CM-dependent cAMP-PDE: the action is counter to the cAMP-mediated MIH-inhibitory system. Ca2+ fluxes were measured with dispersed Y-organ cells, in the presence and absence of agents that alter cAMP levels. The ionophore A23187, but not MIH or forskolin, increased 45Ca2+ entry by 45% over untreated control cells. Efflux from 45Ca2+-preloaded cells was increased 30% by MIH and forskolin, but not A23187. These data, together with those further above, suggest that MIH suppresses steroidogenesis in part by fostering Ca2+ depletion, and that the effect is mediated by cAMP.

Effect of Y-organ removal on limb regeneration and molting in the terrestrial crab, Sesarma haematocheir

The effect of Y-organ removal on limb regeneration and molting was investigated in the crab, Sesarma haematocheir. Basal growth of regenerating limb bud was achieved independently of the Y-organs. However, bilateral removal of the Y-organ inhibited premolt growth and molting. It was also found that removal of the Y-organs from crabs at stage D2 inhibited further premolt growth of regenerating limb bud and molting. Ecdysterone injections in Y-organless crabs induced premolt growth of regenerating limb bud and gastrolith formation, but were insufficient to induce molting.

Ecdysteroids in the shrimp Palaemon serratus: relations with molt cycle

Ecdysteroids were studied during the molt cycle of the shrimp Palaemon serratus using radioimmunoassay and HPLC. Continuous presence of ecdysteroids was observed in whole extracts, with two hormonal peaks: a minor peak during stage B and a major one during stage D2. The ecdysteroid titers were generally higher in females than in males. The ecdysteroid peak at stage B was more pronounced in the integument (cuticle and epidermis) than in other tissues and, at this time, 20-hydroxyecdysone was the predominant form. The observed 20-hydroxyecdysone peaks in stages B and D2 are correlatable to the previously reported rise in integumental carbonic anhydrase activity.

[Immunochemical study of the proteins of various tissues in Crustacea (Decapoda): nature, role, origin]

The main proteins of the haemolymph of Crustacea Decapoda have been identified and analysed: haemocyanin, plasma coagulogen, heteroagglutinins, vitellogenins, and molt-related proteins. All these complex components exhibit a high molecular weight and as oligomeric fractions are able to aggregate or dissociate in subunits according to the composition of medium and experimental procedures. Besides their important rôle in the defense mechanism, some proteins are involved in the edification of diverse tissues. They are detected within different compartments: soft integument, calcified carapace and hepatopancreas. They are either in transit or sequestered or synthetized within these tissues. In the crayfish Astacus leptodactylus, some components have been identified in different compartments: --in aqueous extracts from soft integument: the haemocyanin, coagulogen and both fraction F1 (lipoprotein with an approximate molecular weight of 45 kdal) and fraction F2 related to the molt. Both coagulogen and fraction F2 appear sometimes as melanized. These two latter fractions exhibit some glucose-mannose residues and they occur with a higher relative amount than in the blood. --in soluble extracts from calcified cuticle: among the numerous fractions showing a high molecular weight, the haemocyanin and coagulogen are detected. --in aqueous extracts from hepatopancreas: both haemocyanin and coagulogen appear with a little relative amount. Components termed as Fa and Fb are found with a high concentration. One minor fraction is also detected. --in aqueous extracts from eggs: the haemocyanin and fraction Fb are present. Other proteins showing only some antigenic identities with those of the haemolymph are also detected in all these tissues. The haemolymph proteins are not present within these compartments following a passive diffusion. Indeed, their relative amount varies according to the tissue investigated and is different from that found in the blood. Except the haemocyanin detected in all tissues with different aggregation states, the haemolymph proteins identified vary in the organs studied. A qualitative and quantitative selection occurs when the blood proteins enter the other compartments. Perhaps some other proteins are not detected following alterations underwent either in the epithelial barriers or during the tannage process or the chitino-proteic complex formation or due to experimental procedures. On the other hand, each tissue has its own proteins. The integument contains crustacyanins alpha, beta, gamma; the eggs are mainly constituted of lipovitellins and the hepatopancreas is rich in small molecular weight proteins and digestive enzymes.(ABSTRACT TRUNCATED AT 400 WORDS)

Uptake and retention of moulting hormones by the integument of crayfishes in vitro: I. Influence of temperature, hormone concentration and hormone structure

Uptake kinetics of [3H]ecdysone into crayfish hypodermis in vitro reveals three different components: a very rapid (within 1 min), highly temperature-dependent (Q10 = 3) and high uptake rate, a second much lower uptake which is only slightly temperature-dependent (Q10 = 1-1.3), and a plateau which is reached after about 20 min at 20 degrees C. Preincubation of tissue with unlabelled hormone reduces the initial uptake rate to a value characteristic for the second, less steep uptake phase. The activation energy for the initial uptake is 45 kJ/mole. At equilibrium the hormone is 4-fold enriched as compared to the medium, the delta G for this enrichment being 3 kJ/mole. The efflux is much lower than the influx and is linear. There is no linear relation between external hormone concentration and initial uptake rate. The initial uptake can be significantly reduced by an excess of diverse ecdysteroids with moulting hormone activity but not by hydrocortisone.