Stress effect of different temperatures and air exposure during transport on physiological profiles in the American lobster Homarus americanus.

Homarus americanus is an important commercial species that can survive 2-3 days out of water if kept cool and humid. Once caught for commercial purpose and shipped around the world, a lobster is likely to be subjected to a number of stressors, including emersion and air exposure, hypoxia, temperature changes and handling. This study focused on the effect of transport stress and specifically at different animal body temperature (6 and 15 degrees C) and air exposure during commercial transport and recovery process in water. Animals were monitored, by hemolymph bleeding, at different times: 0 h (arrival time at plant) 3 h, 12 h, 24 h and 96 h after immersion in the stocking tank with a water temperature of 6.5+/-1.5 degrees C. We analysed the effects by testing some physiological variables of the hemolymph: glucose, cHH, lactate, total protein, cholesterol, triglycerides, chloride and calcium concentration, pH and density. All these variables appeared to be influenced negatively by high temperature both in average of alteration from the physiological value and in recovering time. Blood glucose, lactate, total protein, cholesterol were significantly higher in the group with high body temperature compared to those with low temperature until 96 h after immersion in the recovery tank.

The crustacean hyperglycemic hormone precursors a and b of the Norway lobster differ in the preprohormone but not in the mature peptide.

The neuro-endocrine X-organ sinus-gland complex of crustaceans produces and releases the neuropeptides of the crustacean hyperglycemic hormone (cHH)/molt-inhibiting hormone (MIH)/gonad-inhibiting hormone (GIH) family that regulate important physiological processes, such as growth, reproduction and molting. We cloned two full-length cDNAs encoding the preprocHH-A and preprocHH-B of the Norway lobster Nephrops norvegicus of 132 and 131 amino acid residues. The two cHHs differ in the preprohormone but not in the mature peptide sequence. The mature cHH was expressed in bacteria as GST fusion protein that, in bioassay, shows a hyperglycemic activity similar to that of native cHH present in an eyestalk extract.

Ultrastructure of the hemocytes of Cetonischema aeruginosa larvae (Coleoptera, Scarabaeidae): involvement of both granulocytes and oenocytoids in in vivo phagocytosis.

In the context of comparative studies on immunity defence mechanisms of adults and larvae of the coleopteran Cetonischema aeruginosa (Drury, 1770) the ultrastructure of the circulating hemocytes of the third instar larval stage has been investigated by means of light and transmission electron microscopy (TEM). Six types of hemocytes were found in the hemolymph of C. aeruginosa and they were identified as prohemocytes, granulocytes, plasmatocytes, coagulocytes, oenocytoids and spherule cells. In order to identify the "professional" phagocyte cell, phagocytosis assays were performed in vivo by injection of 0.9 microm carboxylate-modified polystyrene latex beads. It was demonstrated that the granulocytes and the oenocytoids of C. aeruginosa were the only hemocyte types involved in this cellular response.

Gonad-inhibiting hormone of the Norway lobster (Nephrops norvegicus): cDNA cloning, expression, recombinant protein production, and immunolocalization.

The gonad-inhibiting hormone (GIH) belongs to a neuropeptide family synthesized and released in a neurohemal complex of crustacean eyestalks. The GIH is involved in gonad maturation and plays a more complex role in the control of reproduction and molting. With a combination of reverse transcription-polymerase chain reaction (RT-PCR) and rapid amplification of cDNA ends approaches we determined the cDNA sequence of the Norway lobster Nephrops norvegicus prepro GIH. The open reading frame of 339 bp codes for a polypeptide of 112 amino acids showing 96% identity with the other known GIH of Homarus americanus. The precursor peptide consists of a putative signal peptide of 31 amino acids and a putative mature peptide region of 81. RT-PCR analysis shows that GIH mRNA is expressed mainly in eyestalks, both in female and male; the expression of GIH mRNA also in supraesophageal ganglia suggests the existence of additional GIH-producing neurons besides those of eyestalks. A specific polyclonal antibody was raised against a portion of the mature peptide region obtained through expression in Escherichia coli fused to glutathione-S-transferase. Immunocytochemical studies were carried out by using this antibody in N. norvegicus and in other crustaceans, Munida rugosa and Squilla mantis; these locate GIH in superficial axon terminals of the releasing organ, the sinus gland. The identification of a second GIH sequence in crustaceans allows to hypothesize the occurrence, within the neuropeptide family, of three subfamilies probably involved in different functions: crustacean hyperglycemic hormones, GIHs and molt-inhibiting hormones/mandibular organ-inhibiting hormones.

An antibody to recombinant crustacean hyperglycaemic hormone of Nephrops norvegicus cross-reacts with neuroendocrine organs of several taxa of malacostracan Crustacea.

The crustacean hyperglycaemic hormones (cHHs) are multifunctional neuropeptides that play a central role in the physiology of crustaceans. A partial cDNA coding for cHH of the Norway lobster, Nephrops norvegicus, was cloned; this cDNA was fused to glutathione- S-transferase (GST) to obtain a recombinant fusion protein that was used to raise a rabbit antiserum and to perform a biological assay. The specificity of the purified antibody was demonstrated by means of Western blotting. To validate the specificity of the purified antibody to the cHH of N. norvegicus and its cross-reactivity with other species, we performed standard immunocytochemistry of the eyestalk on: (1) paraffin sections of the decapod species N. norvegicus, Munida rugosa and Astacus leptodactylus and of the stomatopod Squilla mantis; (2) semithin resin sections of N. norvegicus and Palaemon elegans; (3) ultrathin sections of N. norvegicus sinus gland (transmission electron microscopy studies). The pattern of immunoreactivity shown by N. norvegicus eyestalk sections conforms to distribution, relative amount and ultrastructural features of cHH-containing neurons and nerve endings as reported in the previous literature. In all the crustacean species examined, the antibody marks precisely the X organ-sinus gland complex and unspecific staining is completely lacking. In addition, its specific cross-reaction by immunoprecipitation depletes shrimp eyestalk extract of hyperglycaemic activity in an in vivo bioassay. The results obtained show a cHH-specific molecular recognition despite the fact that the species tested belong to systematic groups increasingly remote in the phylogenetic tree. The antibody could be used for advancing our knowledge on cHH activity in a variety of crustacean species, e.g. for monitoring reproductive and stress conditions.

Lipopolysaccharide-induced hyperglycemia is mediated by CHH release in crustaceans.

Septicemia in crustaceans may occur occasionally due to Gram-negative opportunistic bacteria, especially under conditions of intensive aquaculture. The lipopolysaccharide (LPS) endotoxin induces in mammals septic shock and the activation by LPS of hormone release through the hypothalamo-pituitary axis is well known. In crustaceans an increase in circulating Crustacean hyperglycemic hormone and hyperglycemia are reported to result from exposure to several environmental stressors but the metabolic and hormonal effects of LPS in vivo are undescribed. A sublethal dose of LPS (Sigma, Escherichia coli 0111:B4) was injected into at least five individuals of species representative of crustacean taxa and life habits: Squilla mantis (Stomatopoda); the Decapoda Crangon crangon and Palaemon elegans (Caridea), Nephrops norvegicus (Astacidea), Munida rugosa and Paguristes oculatus (Anomura), Pilumnus hirtellus, Macropipus vernalis, Parthenope massena, and Ilia nucleus (Brachyura). Within 3 hr an increase in blood sugar developed ranging from 26.00 +/- 8.37 sd mg/dl in M. rugosa to 201.50 +/- 95. 91 sd mg/dl in P. oculatus and a significant increase of 79% in M. rugosa up to 1300% in P. hirtellus over control levels was observed. The involvement of eyestalk hormones in this generalized response was tested on S. mantis, M. vernalis, and P. elegans; LPS injected into eyestalkless animals did not elicit a significant hyperglycemic response compared with saline-injected controls. Eyestalkless animals injected with one eyestalk equivalent homogenate in saline from untreated animals did show a change in color from red to normal likely due to red pigment concentrating hormone and a hyperglycemic response within 2 hr. Eyestalkless animals injected with homogenate from LPS-treated shrimps showed the change in color but not the hyperglycemic response. It is concluded that LPS directly, or cytokines circulated upon challenge by the endotoxin, may act on the medulla terminalis X-organ-sinus gland complex and release CHH selectively eliciting an hyperglycemic stress response, after which CHH stores become relatively depleted.