Ontogeny of neuroendocrine centers in the eyestalk of Homarus gammarus embryos: an anatomical and hormonal approach

Summary

The ontogeny of the eyestalk neuroendocrine centers of the European lobster, Homarus gammarus, throughout embryonic development has been studied using light and electron microscopy, and the localization of specific neuroendocrine substances has been identified by immunocytochemistry. The procephalic lobes, which are the prospective eyestalks, develop progressively during embryonic development. In the nauplius stage two neuron masses are well defined. The visual structure originates from one of them and the neuroendocrine structure from the other. The four definitive optic ganglia are present at the mid-metanauplius stage and retain their appearance and location in larvae and adults. The organ of Bellonci, an internal sensory structure, appears at the mid-metanauplius stage and is mainly characterized by onion bodies. The medulla terminalis X-organ complex, an important neuroendocrine system, is present and already functional at the beginning of the embryonic metanauplius stage. Two neurohormones have been visualized immunocytochemically: the crustacean hyperglycemic hormone (CHH) and the gonad inhibiting hormone (GIH). Both neuropeptides are localized in the perikarya of neuroendocrine cells of the X-organ as well as in their tracts joining the presumptive sinus gland. However, the sinus gland has only been observed in the early larval stages just after hatching.     

Endogenous rhythms of haemolymph flow and cardiac performance in the crab Cancer magister

Heart rate and arterial haemolymph flow rates were measured in freshly trapped Dungeness crabs, Cancer magister, using a pulsed-Doppler flowmeter. In the laboratory, freshly collected subtidal crabs exhibited endogenous rhythms in both cardiac function and haemolymph flow through one or more arterial systems, of both tidal and diurnal periodicity. The strongest tidal rhythms were recorded in the sternal and paired anterolateral arteries. These endogenous rhythms of selective tissue perfusion are related to an underlying locomotor activity, but may also be involved with hormonal transport or feeding. Changes in both heart rate and stroke volume were responsible for the increases in haemolymph flow rates. These rhythms were not entrained by aerial exposure, since confinement of arhythmic crabs in intertidal cages did not re-entrain an endogenous tidal rhythm. Endogenous locomotory rhythms are known to be controlled by neurohormones released in cycles from the sinus gland on the eyestalk. These hormones may also control the endogenous cardiovascular rhythms, since these were abolished after eyestalk ablation in freshly collected Cancer magister. These results suggest that hormones synthesized and released by the X-organ/sinus gland complex may, together with pericardial hormones, play a role in modulation of crustacean cardiovascular function.     

Molt-inhibiting hormone immunoreactive neurons in the eyestalk neuroendocrine system of the blue crab, Callinectes sapidus

The production of ecdysteroid molting hormones by crustacean Y-organs is negatively regulated by a neuropeptide, molt-inhibiting hormone. It is generally agreed that molt-inhibiting hormone is produced and released by the eyestalk neuroendocrine system. In the present study, immunocytochemical methods were used to detect molt-inhibiting hormone immunoreactive neurons in eyestalk ganglia of the blue crab, Callinectes sapidus. The primary antiserum used was generated against molt-inhibiting hormone of the green shore crab, Carcinus maenas. A preliminary Western blot analysis indicated the antiserum binds molt-inhibiting hormone of Callinectes sapidus. Using confocal and conventional immunofluorescence microscopy, molt-inhibiting hormone immunoreactivity was visualized in whole mounts and thin sections of Callinectes sapidus eyestalk ganglia. Immunoreactivity was detected in 15-25 neurosecretory cell bodies in the medulla terminalis X-organ, their associated axons and collateral branches, and their axon terminals in the neurohemal sinus gland. The cellular organization of molt-inhibiting hormone immunoreactive neurons in blue crabs is generally similar to that reported for other crab species. The combined results suggest the cellular structure of the molt-inhibiting hormone neuroendocrine system is highly conserved among brachyurans.     

Antipeptide antibodies for detecting crab (Callinectes sapidus) molt-inhibiting hormone

In crustaceans, the synthesis of ecdysteroid molting hormones is regulated by molt-inhibiting hormone (MIH), a neuropeptide produced by an eyestalk neuroendocrine system, the X-organ/sinus gland complex. Using sequence analysis software, two regions of the blue crab (Callinectes sapidus) MIH peptide were selected for antibody production. Two 14-mer peptides were commercially synthesized and used to generate polyclonal antisera. Western blot analysis revealed that each antiserum bound to proteins of the predicted size in extracts of C. sapidus sinus glands, and lysates of insect cells containing recombinant MIH. Thin section immunocytochemistry using either antiserum showed specific immunoreactivity in X-organ neurosecretory cell bodies, their associated axons and collaterals, and their axon terminals in the sinus gland.     

Localization of crustacean hyperglycemic hormone (CHH) in the X-Organ sinus gland complex in the eyestalk of the crayfish,Astacus leptodactylus (Nordmann, 1842)

The eyestalk of Astacus leptodactylus is investigated immunocytochemically by light, fluorescence, and electron microscopy, using an antiserum raised against purified crustacean hyperglycemic hormone (CHH). CHH can be visualized in a group of neurosecretory perikarya on the medualla terminalis (medulla terminalis ganglionic X-organ: MTGX), in fibers forming part of the MTGX-sinus gland tractus, and in a considerable part of the axon terminals composing the sinus gland. Immunocytochemical combined with ultrastructural investigations led to the identification of the CHH-producing cells and the CHH-containing neurosecretory granule type.     

Distribution of serotonergic neurons in the eyestalk and brain of the crab,Cancer antennarius

1. Serotonin-containing neurons were localized immunocytochemically in crab cerebral ganglia and their extensions in the eyestalk.2. Approximately 155 serotonergic cells were found in identifiable regions of the brain, the largest number being localized in the anterior cell cluster (40 reactive cells) and the bilateral anterior olfactory cell clusters (40 cells each).3. Serotonin immunoreactive cells were found in all three ganglionic divisions of the eyestalk. The medulla terminalis contains up to 15 reactive cells, of which only one occurs in the X-organ (origin of neurosecretory axons in the sinus gland nerve). The m. terminalis also contains three identifiable cells in the mediolateral border adjacent to the sinus gland nerve, of which one is a giant (up to 100 μm diameter), designated MT-1. The axon of MT-1 branches profusely after entering the m. terminalis neuropil.4. No serotonin immunoreactivity was apparent within the sinus gland, the sinus gland nerve or the organ of Bellonci.5. These findings are discussed in relation to the known serotonergic control of peptide hormone secretion by the eyestalk X-organ-sinus gland complex.     

The distribution of APGWamide and RFamides in the central nervous system and ovary of the giant freshwater prawn, Macrobrachium rosenbergii

Immunohistochemistry was used to identify the distribution of both APGWamide-like and RFamide-like peptides in the central nervous system (CNS) and ovary of the mature female giant freshwater prawn, Macrobrachium rosenbergii. APGWamide-like immunoreactivity (ALP-ir) was found only within the sinus gland (SG) of the eyestalk, in small- and medium-sized neurons of cluster 4, as well as their varicosed axons. RFamide-like immunoreactivity (RF-ir) was detected in neurons of all neuronal clusters of the eyestalk and CNS, except clusters 1 and 5 of the eyestalk, and dorsal clusters of the subesophageal, thoracic, and abdominal ganglia. The RF-ir was also found in all neuropils of the CNS and SG, except the lamina ganglionaris. These immunohistochemical locations of the APGWamide-like and RF-like peptides in the eyestalk indicate that these neuropeptides could modulate the release of the neurohormones in the sinus gland. The presence of RFamide-like peptides in the thoracic and abdominal ganglia suggests that it may act as a neurotransmitter which controls muscular contractions. In the ovary, RF-ir was found predominantly in late previtellogenic and early vitellogenic oocytes, and to a lesser degree in late vitellogenic oocytes. These RFs may be involved with oocyte development, but may also act with other neurohormones and/or neurotransmitters within the oocyte in an autocrine or paracrine manner.     

甲壳动物高血糖激素家族生理功能研究进展

甲壳动物高血糖激素家族是甲壳动物特有的神经多肽激素家族,主要由眼柄的X-器窦腺复合体(XO-SG)合成与分泌,包括高血糖激素(CHH)、蜕皮抑制激素(MIH)、性腺抑制激素(GIH)和大颚器抑制激素(MOIH),协同调控着甲壳动物的生长、繁殖与蜕皮等生理生化过程.本文就目前CHH家族神经肽的功能研究,包括功能研究的方法、各个激素的功能以及分泌调控等研究进展作一综述.     

A comparative immunocytochemical investigation of the crustacean hyperglycemic hormone (CHH) in the eyestalks of some decapod crustacea

The eyestalk of the astacideans Orconects limosus, Nephrops norvegicus, and Homarus gammarus, and the palinuran Palinurus vulgaris, was examined with an antiserum raised against purified crustacean hyperglycemic hormone (CHH) of the astacidean species Astacus leptodactylus. A distinct immunopositive reaction occurs in a group of neurosecretory cells in the medulla terminalis ganglionic X-organ (MTGX), in the MTGX-sinus gland tractus, and in a considerable part of the sinus gland. The immunoreactive sites in the eyestalk of the investigated species correspond to the site of production, storage, and release of the CHH. Preliminary investigations with this antiserum also indicate that a positive immunoreaction can be obtained in the eyestalk of other decapod crustaceans, for example, of the brachyuran Macropipus puber and the caridean Palaemon serratus.     

Localization of crustacean hyperglycemic hormone (CHH) and gonad-inhibiting hormone (GIH) in the eyestalk ofHomarus gammarus larvae by immunocytochemistry and in situ hybridization

This study deals with the localization of crustacean hyperglycemic hormone (CHH) and gonad-inhibiting hormone (GIH) in the eyestalk of larvae and postlarvae ofHomarus gammarus, by immunocytochemistry and in situ hybridization. The CHH and GIH neuropeptides are located in the perikarya of neuroendocrine cells belonging to the X-organ of the medulla terminalis, in their tract joining the sinus gland, and in the neurohemal organ itself, at larval stages I, II and III and at the first postlarval stage (stage IV). In all the investigated stages, the mRNA encoding the aforementioned neuropeptides could only be detected in the perikarya of these neuroendocrine cells. In stage I, approximately 19 CHH-immunopositive and 20 GIH-immunopositive cells are present, both with a mean diameter of 7±1 μm. GIH cells are preferably localized at the periphery of the X-organ surrounding the CHH cells that are centrally situated. Colocalization of CHH and GIH immunoreactions can be observed in some cells. The cell system producing CHH and GIH in the larval and postlarval eyestalk is thus functional and is morphologically comparable to the corresponding neuroendocrine center in the adult lobster.     

Crustacean Hyperglycemic Neuropeptides

The neurosecretory structures in the crustacean eyestalk areconsidered to be the source of factors regulating a considerablevariety of physiological processes. Although many hormonal "factors"have been postulated, only a few have been characterized indetail. Two pigmentary effector regulating neuropeptides havebeen completely characterized. A third substance, the hyperglycemichormone, has been isolated and characterized in terms of aminoacid composition. It is larger than the pigmentary effectorhormones (mol wt 6,000–7,000) and it is the first of theheretofore described invertebrate neurohormones that containsdisulfide bridges. Unlike the pigmentary effector hormones,the hyperglycemic neuropeptide exhibits species or systematicgroup specificity, recognizable by differences in amino acidcompositions and also expressed by lack of interspecific (orintergroup) biological activity. An antiserum permitted thedevelopment of a radioimmunoassay and immunocytochemical demonstrationof the hormone producing perikarya in decapods and in an isopod.Large immunopositive perikarya form a distinct group in themedulla terminalis ganglionic X-organ. This group sends a conspicuoustract of axons to the neurohemal organ, the sinus gland, wherethe hormone is stored in large quantities. It is believed tobe necessary for the regulation of resting levels of blood sugarand for elevation of blood sugar in situations of physiologicalneed. In general, however, the physiological mode of actionof the hormone is largely unknown.     

Involvement of the hyperglycemic neurohormone family in the control of reproduction in decapod crustaceans

Summary

In the last few years, (bio)chemical and molecular biological studies have shown that several members of the hyperglycemic hormone family are present in different molecular forms. In vivo and in vitro bioassays revealed that some of these isoforms also play a role in the control of reproduction in decapod crustaceans. This communication gives a review of the cytological aspects of the eyestalk X-organ sinus gland complex, responsible for the synthesis, storage and release of these neuropeptides, and the molecular and functional aspects of those members involved in the control of reproduction. Finally, the role of the hyperglycemic hormone family in the regulation of reproduction in the female lobster is described as an example of the (possible) interactions of the members of the hyperglycemic hormone family with other (neuro)endocrine factors in the reproductive process of crustaceans.     

Identification of a putative egg-laying hormone in neural and ovarian tissues of the black tiger shrimp, Penaeus monodon, using immunocytochemistry

The existence of an egg-laying hormone (ELH) was identified for the first time in the black tiger shrimp, Penaeus monodon, by means of immunoenzyme and immunofluorescence techniques. This was achieved using a polyclonal antibody produced against expressed recombinant ELH of the female Australian blacklip abalone, Haliotis rubra. The shrimp ELH reactive material was found to be localised within female neurosecretory tissues and the secretory tissue of the antennal gland, but was not identified in the X-organ sinus gland within the eyestalk. It was also present in the ovary, where the amount of ELH present was observed to be greatest in the period prior to spawning. These findings implied that the induction of P. monodon spawning might be involved with humoral regulation relating to ELH expression.     

锯缘青蟹窦腺显微和超微结构研究

借助光学和电子显微镜观察据缘青蟹（Ｓｃｙｌｌａ ｓｅｒｒａｔａ）窦腺的形态结构。窦腺位于眼柄视神经节内髓背侧近外髓处。窦腺呈羹状;腺体壁山神经分泌细胞的末梢和神经胶质细胞组成。神经末梢内充满了电子致密的神经分泌颗粒。根据颗粒的大小、形态及电子致密度等特征,可以区分出４种类型的神经末梢。一些末梢中的多形性颗粒可能是由Ⅱ型末梢中的颗粒转变而成的。一些现象表明,神经分泌物质可以通过胞吐作用或一种类似“顶浆分泌”的方式释放,从而说明神经激素的释放可能是多途径的．     

Identification and characterization of a hyperglycemic hormone from freshwater giant prawn, Macrobrachium rosenbergii

Crustacean hyperglycemic hormone (CHH), a physiologically important neurohormone stored in the sinus gland of eyestalks, primarily regulates carbohydrate metabolism and also plays significant roles in reproduction, molting and other physiological processes. In the freshwater giant prawn, Macrobrachium rosenbergii, an injection of X-organ sinus gland (XOSG) extract evoked a hyperglycemic response, peaked in 1 h. The hyperglycemic effect of the eyestalk extract was maximal at the dose of 0.5 eyestalk equivalent. CHH fractionated by RP-HPLC, in M. rosenbergii was identified by its hyperglycemic activity and partial amino acid sequence, and the molecular weight of 8534 was determined by matrix-assisted laser desorption ionization mass spectrometry--time of flight analysis (MALDI-TOF). The amino acid sequence of the first 25 residues of CHH showed 72% homology with the first 25 residues of CHH A and CHH B of the American lobster Homarus americanus.     

GABA and GAD expression in the X-organ sinus gland system of the <Emphasis Type="Italic">Procambarus clarkii</Emphasis> crayfish: inhibition mediated by GABA between X-organ neurons

In crustaceans, the X-organ-sinus gland (XO-SG) neurosecretory system is formed of distinct populations of neurons that produce two families of neuropeptides: crustacean hyperglycemic hormone and adipokinetic hormone/red pigment-concentrating hormone. On the basis of electrophysiological evidence, it has been proposed that γ-aminobutyric acid (GABA) regulates both electrical and secretory activity of the XO-SG system. In this work we observed that depolarizing current pulses to neurons located in the external rim of the X-organ induced repetitive firing that suppressed the spontaneous firing of previously active X-organ neurons. Picrotoxin reversibly blocked this inhibitory effect suggesting that the GABA released from the stimulated neuron inhibited neighboring cells. Immunoperoxidase in X-organ serial sections showed co-localization of GABA and glutamic acid decarboxylase (GAD) including the aforementioned neurons. Immunofluorescence in whole mount preparations showed that two subpopulations of crustacean hyperglycemic hormone-containing neurons colocalized with GABA. The expression of GAD mRNA was determined in crayfish tissue and X-organ single cells by RT-PCR. Bioinformatics analysis shows, within the amplified region, 90.4% consensus and 41.9% identity at the amino acid level compared with Drosophila melanogaster and Caenorhabditis elegans. We suggest that crustacean hyperglycemic hormone-GABA-containing neurons can regulate the excitability of other X-organ neurons that produce different neurohormones.     

Molecular mechanisms regulating molting in a crustacean

Crustacean growth and development is characterized by periodic shedding (ecdysis) and replacement of the rigid exoskeleton. Secretions of the X-organ sinus gland complex control the cellular events that lead to growth and molting. Western blot and ELISA results showed a progressive increase in growth arrest-specific protein (Gas7) from early postmolt stage to a maximum at late postmolt stage. Phosphorylation of ERK2, a downstream signaling protein, was also identified in the subsequent stages. ERK2 phosphorylation resulted in the expression of molt-inhibiting hormone (MIH). Specific ERK inhibitors (PD98059 and UO126) exhibited the ability to reduce the molting duration of Fenneropenaeus indicus from 12-14 days to 7-8 days, suggesting that the ERK1/2 signaling pathway is responsible for the expression of MIH, which controls the molt cycle. We have identified the stage-specific expression of Gas7 (approximately 48 kDa) in the X-organ sinus gland complex of eyestalk which is involved in the downstream signaling of the ERK1/2 pathway regulating the expression of MIH during the molt cycle of the white shrimp, F. indicus. These are the first data showing an association between the Gas7 signal-transduction process and regulation of the molt cycle and provides an alternative molecular intervention mechanism to the traditional eyestalk ablation in crustaceans.     

Proteomics and signal transduction in the crustacean molting gland

Regulation of the molting cycle in decapod crustaceans involves2 endocrine organs: the X-organ/sinus gland (XO/SG) complexlocated in the eyestalk ganglia and the Y-organ (YO) locatedin the cephalothorax. Two neuropeptides [molt-inhibiting hormone(MIH) and crustacean hyperglycemic hormone (CHH)] are producedin the XO/SG complex and inhibit ecdysteroidogenesis in theYO. Thus, YO activation is induced by eyestalk ablation (ESA),which removes the primary source of MIH and CHH. Cyclic nucleotides(cAMP and cGMP) and nitric oxide (NO) appear to mediate neuropeptidesuppression of the YO. Proteomics was used to identify potentialcomponents of signal transduction pathways ("targeted" or cell-mapproteomics) as well as assess the magnitude of protein changesin response to activation ("global" or expression proteomics)in the tropical land crab, Gecarcinus lateralis. Total proteinsin YOs from intact and ES-ablated animals were separated bytwo-dimensional gel electrophoresis and expression profileswere assessed by image analysis and gene clustering software.ESA caused a >3-fold increase in the levels of 170 proteinsand >3-fold decrease in the levels of 89 proteins; a totalof 543 proteins were quantified in total YO extracts. ESA inducedsignificant changes in the levels of 3 groups of proteins elutingfrom a phosphoprotein column and detected with phosphoproteinstaining of two-dimensional gels;