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.     

Regulation of protein synthesis in Y-organs of the blue crab (Callinectes sapidus): involvement of cyclic AMP

Paired Y-organs secrete ecdysteroid hormones that control cycles of growth and molting in crustaceans. Y-Organs are regulated, at least in part, by molt-inhibiting hormone (MIH), a polypeptide produced and released by the X-organ/sinus gland complex of the eyestalks. In the present studies, crab (Callinectes sapidus) Y-organs were incubated in vitro in the presence of [(35)S]methionine, and cyclic nucleotide analogs or experimental agents that influence the cAMP signaling pathway. In 4-hr incubations, 8-Br-cAMP and db-cAMP (but not 8-Br-cGMP) suppressed incorporation of [(35)S]methionine into Y-organ proteins; the effect of 8-Br-cAMP was concentration-dependent. Autoradiograms of radiolabeled Y-organ proteins separated on SDS-PAGE gels indicated the effect of 8-Br-cAMP was general (as opposed to selective) suppression of protein synthesis. Addition of both forskolin (an adenylyl cyclase activator) and 3-isobutyl-1-methylxanthine (a phosphodiesterase inhibitor) likewise suppressed incorporation of [(35)S]methionine into Y-organ proteins. Cycloheximide (a protein synthesis inhibitor) suppressed incorporation of [(35)S]methionine into Y-organ proteins and secretion of ecdysteroids. The combined results suggest that cAMP is involved in regulation of protein synthesis in C. sapidus Y-organs. We are currently investigating the link of protein synthesis to ecdysteroid production, and the possibility of cross-talk between cAMP and other cellular signaling pathways in Y-organs.     

Changes in intracellular calcium concentration in crustacean (Callinectes sapidus) Y-organs: relation to the hemolymphatic ecdysteroid titer

Secretion of ecdysteroid molting hormones by crustacean Y-organs is negatively regulated (inhibited) by molt-inhibiting hormone (MIH), a neuropeptide produced by neurosecretory cells in eyestalk ganglia. The inhibitory effect of MIH is mediated by one or more cyclic nucleotide second messengers. In addition, available data indicate that ecdysteroidogenesis is positively regulated (stimulated) by intracellular calcium. However, despite the apparent critical role of calcium in regulating ecdysteroidogenesis, the level of Ca(2+) in Y-organs cells has not been previously determined. In studies reported here, eyestalks were ablated from blue crabs (Callinectes sapidus) to remove the endogenous source of MIH and activate Y-organs. At 0, 3, 6, and 9 days after eyestalk ablation (D0, D3, D6, and D9, respectively), the level of Ca(2+) in Y-organ cells was determined using a fluorescent calcium indicator (Fluo-4), and the hemolymphatic ecdysteroid titer was determined by radioimmunoassay. Calcium fluorescence in D6 Y-organs was 3.5-fold higher than that in D0 controls; calcium fluorescence in D9 Y-organs was 3.9-fold higher than in D0 controls (P<0.05). Measurement of fluorescence along a transect drawn through representative cells indicated that the calcium fluorescence was localized to cytoplasm and not to nuclei. Associated with the increase in intracellular Ca(2+) was a significant increase in the hemolymphatic ecdysteroid titer: The level of ecdysteroids in hemolymph rose from 5.5?ng/mL on D0 to 49.6?ng/mL on D6 and 87.2?ng/mL on D9 (P<0.05). The results are consistent with the hypothesis that ecdysteroidogenesis is stimulated by an increase in intracellular Ca(2+).     

Trimeric G proteins in crustacean (Callinectes sapidus) Y-organs: occurrence and functional link to protein synthesis

Crustacean Y-organs produce ecdysteroid molting hormones. Regulation of ecdysteroidogenesis appears to be complex, involving regulatory ligands (including but not limited to molt-inhibiting hormone, an eyestalk neurohormone) and the capacity of the Y-organs to respond to those ligands. Available data indicate cell signaling pathways involving cAMP, cGMP, or both may be involved in regulation of Y-organ function. Trimeric G proteins link receptor occupancy to regulation of intracellular cAMP levels. In studies reported here, we have assessed the occurrence of G proteins in blue crab (Callinectes sapidus) Y-organs, and the link of G proteins to Y-organ function. Bacterial toxin-catalyzed ADP-ribosylation revealed a PTX-sensitive (alpha i-like) protein in Y-organ membranes, but failed to reveal a CTX-sensitive (alpha s-like) protein in Y-organ membranes. Western blotting with primary antibodies raised against conserved regions of mammalian G proteins detected an alpha i-immunoreactive protein (approximately 40 kDa) and two alpha s-immunoreactive proteins (approximately 50 and approximately 57 kDa) in Y-organ membrane preparations. Incubation of Y-organ membrane fractions with cholera toxin significantly suppressed incorporation of [35S]-methionine into TCA-precipitable Y-organ proteins, but had no detectable effect on ecdysteroidogenesis in short-term (6 h) incubations. The combined results indicate that C. sapidus Y-organs possess both Gi and Gs proteins, and that alpha s is functionally linked to regulation of glandular protein synthesis.     

Characterization of molt-inhibiting hormone (MIH) action on crustacean Y-organ segments and dispersed cells in culture and a bioassay for MIH activity

Ecdysteroid secretion in vitro by gland quarters and dispersed cells of ecdysial glands (Y-organs) of the crab, Cancer antennarius Stimpson, was characterized. Optimum culture conditions are reported for maximum, sustained (72 hr) secretion and maintenance of cell viability in activated Y-organs obtained from de-eyestalked donors. Addition in vitro of eyestalk ganglia extracts containing the putative molt-inhibiting hormone (MIH) inhibited ecdysteroid production dose-dependently in the range of 0.1-4.0 and 0.01-4.0 eyestalk equivalents of MIH for gland quarters and dispersed cells, respectively. Inhibition by MIH was reversible, tissue specific as to source of MIH activity, and did not affect cell viability relative to controls. The results of replicate incubations of gland quarters with MIH were analyzed with formal statistics of parallel-line assay. The inhibitory action on ecdysteroid secretion is shown to be reproducibly linear and parallel in the dosage range, 0.1-4.0 eyestalk equivalents, amenable to calculation of relative potency among successive extracts, and of sufficiently high precision to serve as an MIH bioassay. Also, the results of these studies support the hypothesis that control of Y-organs by the eyestalks is physiologically direct.     

Expression of a recombinant molt-inhibiting hormone of the kuruma prawn Penaeus japonicus in Escherichia coli.

The crustacean molt-inhibiting hormone (MIH) suppresses ecdysteroid synthesis by the Y-organ. The MIH of the kuruma prawn Penaeus japonicus has recently been isolated and its cDNA cloned. In this study, we expressed the MIH in Escherichia coli to obtain a large quantity of this hormone with biological activity. The MIH cDNA was processed and ligated into an expression plasmid. E. coli was transformed with this plasmid, and then the recombinant MIH (r-MIH) was expressed. The r-MIH was put through the refolding reaction and was purified by reverse-phase HPLC. N-terminal amino acid sequence and time-of-flight mass spectral analyses supported the idea that the r-MIH had the entire sequence. By in vitro bioassay using the Y-organ of the crayfish, the r-MIH was found to be comparable to natural MIH in inhibiting ecdysteroid synthesis.     

Characterization and sequence elucidation of a novel peptide with molt-inhibiting activity from the South African spiny lobster, Jasus lalandii

We have isolated a peptide from extracts of sinus glands from a South African spiny lobster species, Jasus lalandii, by high-performance liquid chromatography (HPLC) and identified it as a putative molt-inhibiting hormone (MIH) by (i) an in vitro assay with J. lalandii Y-organs to measure the inhibition of ecdysteroid synthesis and (ii) an immunoassay using antiserum raised against MIH of the edible crab. The MIH of J. lalandii has 74 amino acid residues, a molecular mass of 9006 Da, a free N-terminus and an amidated C-terminus. The full primary sequence has been obtained from sequencing various digest fragments (tryptic, endoproteinase Asp-N, cyanogen bromide) of the unreduced (native) peptide: RFTFDCPGMMGQRYLYEQVEQVCDDCYNLYREEKIAVNCRENCFLNSWFTVCLQATMREHETPRFDIWR SIILKA-NH(2). Structural comparisons with other peptides show that the J. lalandii MIH belongs to the peptide family which includes the crustacean hyperglycemic hormone, molt-inhibiting hormone and vitellogenesis-inhibiting hormone (cHH/MIH/VIH). This novel peptide has 36-43% sequence identity to putative MIHs from other decapod crustaceans and 32-34% identity to the two cHH peptides previously identified in this spiny lobster species. This is the first report of a peptide with MIH activity in the Palinuridae infraorder.     

Expression of a Recombinant Molt-Inhibiting Hormone of the Kuruma Prawn Penaeus japonicus in Escherichia coli

The crustacean molt-inhibiting hormone (MIH) suppresses ecdysteroid synthesis by the Y-organ. The MIH of the kuruma prawn Penaeus japonicus has recently been isolated and its cDNA cloned. In this study, we expressed the MIH in Escherichia coli to obtain a large quantity of this hormone with biological activity. The MIH cDNA was processed and ligated into an expression plasmid. E. coli was transformed with this plasmid, and then the recombinant MIH (r-MIH) was expressed. The r-MIH was put through the refolding reaction and was purified by reverse-phase HPLC. N-terminal amino acid sequence and time-of-flight mass spectral analyses supported the idea that the r-MIH had the entire sequence. By in vitro bioassay using the Y-organ of the crayfish, the r-MIH was found to be comparable to natural MIH in inhibiting ecdysteroid synthesis.     

Crustacean molt-inhibiting hormone: Structure,function, and cellular mode of action

In Crustacea, secretion of ecdysteroid molting hormones by Y-organs is regulated, at least in part, by molt-inhibiting hormone (MIH), a polypeptide neurohormone produced by neurosecretory cells of the eyestalks. This article reviews current knowledge of MIH, with particular emphasis on recent findings regarding the (a) structure of the MIH peptide and gene, (b) levels of MIH in eyestalks and hemolymph, (c) cellular mechanism of action of MIH, and (d) responsiveness of Y-organs to MIH. At least 26 MIH/MIH-like sequences have been directly determined by protein sequencing or deduced from cloned cDNA. Recent studies reveal the existence of multiple forms of MIH/MIH-like molecules among penaeids and raise the possibility that molecular polymorphism may exist more generally among MIH (type II) peptides. The hemolymphatic MIH titer has been determined for two species, a crayfish (Procambarus clarkii) and a crab (Carcinus maenas). The data are dissimilar and additional studies are needed. Composite data indicate cellular signaling pathways involving cGMP, cAMP, or both may play a role in MIH-induced suppression of ecdysteroidogenesis. Data from the two species studied in our laboratories (P. clarkii and Callinectes sapidus) strongly favor cGMP as the physiologically relevant second messenger. Ligand-binding studies show an MIH receptor exists in Y-organ plasma membranes, but the MIH receptor has not been isolated or fully characterized for any species. Such studies are critical to understanding the cellular mechanism by which MIH regulates ecdysteroidogenesis. Rates of ecdysteroid synthesis appear also to be influenced by stage-specific changes in the responsiveness of Y-organs to MIH. The changes in responsiveness result, at least in part, from changes in glandular phosphodiesterase (PDE) activity. The PDE isotype (PDE1) present in Y-organs of C. sapidus is calcium/calmodulin dependent. Thus, calcium may regulate ecdysteroidogenesis through activation of glandular PDE.     

Stage-specific changes in calcium concentration in crustacean (Callinectes sapidus) Y-organs during a natural molting cycle, and their relation to the hemolymphatic ecdysteroid titer

Secretion of ecdysteroid molting hormones by crustacean Y-organs is suppressed by molt-inhibiting hormone (MIH). The suppressive effect of MIH on ecdysteroidogenesis is mediated by one or more cyclic nucleotide second messengers. In addition, existing data indicate that ecdysteroidogenesis is positively regulated (stimulated) by intracellular Ca(++). Despite the apparent critical role of calcium in regulating ecdysteroidogenesis, the level of Ca(++) in Y-organ cells has not been previously measured during a natural molting cycle for any crustacean species. In studies reported here, a fluorescent calcium indicator (Fluo-4) was used to measure Ca(++) levels in Y-organs during a molting cycle of the blue crab, Callinectes sapidus. Mean calcium fluorescence increased 5.8-fold between intermolt (C4) and stage D3 of premolt, and then dropped abruptly, reaching a level in postmolt (A) that was not significantly different from that in intermolt (P>0.05). The level of ecdysteroids in hemolymph of Y-organ donor crabs (measured by radioimmunoassay) showed an overall pattern similar to that observed for calcium fluorescence, rising from 2.9 ng/mL in intermolt to 357.1 ng/mL in D3 (P<0.05), and then dropping to 55.3 ng/mL in D4 (P<0.05). The combined results are consistent with the hypothesis that ecdysteroidogenesis is stimulated by an increase in intracellular Ca(++).     

Uptake of high-density lipoprotein by Y-organs of the crab,cancer antennarius. II. formal characterization of receptor-mediation with isolated membranes

Y-organs are the ecdysial glands of crustaceans, responsible for synthesis and secretion of ecdysteroid hormones. For this purpose, the glands acquire cholesterol as obligate precursor entirely from circulating high-density lipoprotein (HDL). A preceding study provided evidence for the mechanism of acquisition: Y-organs take up cholesterol bound to HDL by an energy-requiring process, receptor-mediated absorptive endocytosis. The present study characterized the receptors involved utilizing isolated Y-organ membranes. HDL binding was saturable and specific; a dissociation constant (K_d) of 1.08 × 10^?7 M and a binding maximum at equilibrium (B_max) of 70 μg HDL protein/mg membrane protein, were obtained. Binding was decreased by protease and was dependent upon calcium. Y-organs are regulated negatively by a peptide hormone from the eystalks, molt-inhibiting hormone (MIH). Y-organ membranes from de-eyestalked crabs (MIH absent) exhibited the same K_d value as membranes from intact crabs, but a B_max 17% higher. Thus, MIH activity apparently does not change the binding affinity of HDL, but decreases the number of binding sites. These results agree with our previous findings that MIH depresses ecdysteroid synthesis in part by inhibiting cholesterol uptake. Generally, Y-organ cells appear to contain receptors for HDL that are of high affinity and high binding capacity, similar to the characteristics reported for the binding of insect HDL (vitellogenin) to fat bodies and oocytes. © 1995 Wiley-Liss, Inc.     

High-level expression of biologically active human prolactin from recombinant baculovirus in insect cells

We examined the feasibility of high-level production of recombinant human prolactin, a multifunctional protein hormone, in insect cells using a baculovirus expression system. The human prolactin cDNA with and without the secretory signal sequence was cloned into pFastBac1 baculovirus vector under the control of polyhedrin promoter. Prolactin was produced upon infection of either Sf9 or High-Five cells with the recombinant baculovirus containing the human prolactin cDNA. The production of recombinant prolactin varied from 20 to 40 mg/L of monolayer culture, depending on the cell types. The prolactin polypeptide with its own secretory signal was secreted into the medium. N-terminal amino acid sequence analysis of the recombinant polypeptide purified from the culture medium indicated that the protein was processed similar to human pituitary prolactin. Carbohydrate analysis of the purified protein indicated that a fraction of the recombinant prolactin made in insect cells appeared to be glycosylated. Also, both secreted and nonsecreted forms of the recombinant prolactin in insect cells were biologically equivalent to the native human prolactin (pituitary derived) in the Nb2 lymphoma cell proliferation assay.     

HCV结构蛋白在昆虫细胞中的表达及病毒样颗粒的组装

本文利用Bac-to-Bac杆状病毒表达系统构建了含有丙型肝炎病毒(Hepatitis C Virus,HCV)结构蛋白编码基因的重组杆状病毒vAcHCVspl,并获得了HCV结构蛋白在昆虫细胞Sf21中的表达。HCV mRNA转录和蛋白质表达时相分析表明,感染后16h HCV结构蛋白编码基因开始转录,72h达最高峰;蛋白质表达则是在感染后48h开始,72h达到高峰。电镜观察表明vAcHCVspl感染的Sf21细胞96h时在细胞质中可见很多空泡,空泡中可见50nm的球形颗粒,为HCV结构蛋白组装的病毒样颗粒。     

中华绒螯蟹蜕皮抑制激素基因全长cDNA克隆和重组表达

根据实验室分离自中华绒螯蟹(Eriocheir sinensis)的一种蜕皮抑制激素(Molting-inhibiting hormone,MIH)N端氨基酸测序结果设计简并引物,采用RACE方法,首次从中华绒螯蟹眼柄中克隆到蜕皮抑制激素基因全长cDNA(Es-MIH,GenBank登录号:DQ341280),该基因全长为1457 bp,开放阅读框为330 bp,编码110个氨基酸(含有35个氨基酸的信号肽);其成熟肽包含C7-C44、C24-C40和C27-C53三个二硫键,有典型的CHH家族结构域。该cDNA编码的氨基酸序列与地蟹(Gecarcinus lateralis)MIH同源性最高,达到了85%。Northern杂交和半定量RT-PCR显示蜕皮间期成体蟹仅在眼柄中有MIH基因表达,提示该基因的表达具有一定组织特异性。利用pCR T7/NT TOPO TA系统重组表达MIH成熟肽,纯化的重组蛋白得率为0.3 g/L,纯化产物经质谱鉴定为中华绒螯蟹MIH。研究解决了CHH家族神经肽在机体中的表达量少,直接纯化较难的问题,为深入研究MIH的作用机制和在生产上控制中华绒螯蟹蜕皮和生长奠定了基础。     

Bacterial expression of the shrimp molt-inhibiting hormone (MIH): antibody production, immunocytochemical study and biological assay

Molting in shrimp is controlled by the molt-inhibiting hormone (MIH) and ecdysone. MIH inhibits the synthesis of ecdysone in the Y-organ, resulting in molt suppression; it is a neuropeptide member belonging to the eyestalk CHH/MIH/GIH family. The cloning of MIH (formerly MIH-like) of the shrimp Metapenaeus ensis has been reported in a previous study. To obtain a large quantity of fusion protein for antibody production and biological assay, the cDNA encoding the shrimp MIH was inserted into the pRSET bacterial expression vector. His-tagged fusion protein was produced and purified by an Ni2+-charged affinity column. Polyclonal antibody to rMIH was subsequently obtained by immunizing rabbits with purified recombinant proteins. Results from Western blot analysis indicated that the antibody was specific. Furthermore, results from immunocytochemical analysis showed that specific cells in three different clusters of the X-organ, the sinus gland and the axonal tract of the eyestalk contain MIH. To test for the molt-inhibiting activity of rMIH, shrimp at intermolt stage were injected with rMIH and the molt cycle duration of the injected shrimp was monitored. A significant increase in molt cycle duration was recorded for the shrimp injected with the recombinant protein.     

Native and recombinant proguanylin feature identical biophysical properties and are monomeric in solution

Guanylin, an intestinal peptide hormone and endogenous ligand of guanylyl cyclase C, is produced as the corresponding prohormone proguanylin. The mature hormone consists of 15 amino acid residues, representing the COOH-terminal part of the prohormone comprised of 94 amino acid residues. Here we report the recombinant expression and purification of proguanylin with its native disulfide connectivity, as well as the biophysical characterization of the recombinant and native protein. The comparison of recombinant and native proguanylin revealed identical biophysical and structural properties, as deduced from CZE, HPLC, and mass spectrometry, as well as NMR spectroscopy and CD spectroscopy at various temperatures and pH values. Exhaustive analytical ultracentrifugation studies were employed for protein concentrations up to the millimolar range to determine the association state of recombinant as well as native proguanylin, revealing both proteins to be monomeric at the applied solution conditions. As a result, a former identified close proximity between the termini of proguanylin is due to intramolecular interactions.     

Neurohormonal control of ecdysone production: Comparison of insects and crustaceans

Summary

Ecdysteroid synthesis is regulated in insects by prothoracicotropic hormone (PTTH) and in crustaceans by molt-inhibiting hormone (MIH). These neurohormones exert opposite effects on their respective target tissues, PTTH stimulating the prothoracic glands and MIH inhibiting the Y-organs. The present work reviews recent progress in the neurohormonal regulation of prothoracic gland and Y-organ function. The steroid products of these glands are briefly discussed, as is current information on the structures of PTTH and MIH. Focus is placed on the mechanism of action of these hormones at the cellular level, as well as developmental changes in cellular sensitivity to PTTH. Though exerting different effects on ecdysteroid secretion, both PTTH and MIH increase cyclic nucleotide second messengers, are influenced by alterations in cellular calcium, and are likely to activate protein kinases. The contrasting steroidogenic effects of PTTH and MIH probably arise from differences in the cellular kinase substrates. In insects, such substrates enhance ecdysteroid secretion, possibly by increasing the translation of glandular proteins. In crustaceans, MIH-stimulated changes lead to the inhibition of both protein synthesis and steroidogenesis.     

Further Studies on Signaling Pathways for Ecdysteroidogenesis in Crustacean Y-Organs

The Y-organs of crustaceans secrete ecdysteroids (molting hormones)and are regulated (negatively) by a neurosecretory peptide,molt-inhibiting hormone (MIH). Signaling path(s) in Y-organswere explored that connect MIH receptors ultimately with suppressionof receptor number for the uptake of cholesterol (ecdysteroidprecursor) and of gene expression of steroidogenic enzymes.Experiments were conducted in vitro with Y-organs of crabs (Cancerantennarius, Menippe mercenaria) and crayfishes (Orconectessp.). It was confirmed in all species that steroidogenesis occursin the absence of external calcium (Ca⁺⁺), but increases toa maximum as Ca⁺⁺ is increased to 1 to 10 mM and is substantiallyinhibited at higher Ca⁺⁺ concentrations. MIH does not requireexternal Ca⁺⁺ for inhibitory action, but inhibition is eliminatedby high Ca⁺⁺concentrations. Several experimental approachesfailed to find evidence of phospholipase C activation, turnoverof inositol triphosphate or diacylglycerol generation connectedwith steroidogenesis. Unbinding or chelation of intracellularCa⁺⁺ with thapsigargin or TMB-8, respectively both caused dose-dependentinhibition of ecdysteroid output. Blockade of Ca⁺⁺ channelswith verapamil, nifedipine or nicardipine also inhibited steroidogenesis;highest doses inhibited profoundly to below Ca⁺⁺-free basallevels. Inhibition also was obtained with all doses of the Ca⁺⁺channel agonist/antagonist (–) BAY K 8644 in crabs, butin crayfishes lower doses were stimulatory. However, if thecrayfish cells were depolarized, allowing greater Ca⁺⁺ influx,the previously stimulatory doses of BAY K 8644 became inhibitory.Y-organ protein kinase C (PKC) is Ca⁺⁺-sensitive. Activationof PKC was uniformly stimulatory in crabs, but inhibitory incrayfishes. Cytochalasin D, which disrupts the actin cytoskeleton,and which causes moderate Ca⁺⁺ influx, stimulated hormone formation.These results are interpreted to indicate a regulatory rolefor Ca⁺⁺ in ecdysteroidogenesis, involving a local, submembranecirculation of Ca⁺⁺ through ion channels and Ca⁺⁺ pumps andinteraction with PKC in phosphorylating key proteins. An optimallocal Ca⁺⁺ environment fostering hormone synthesis is evidentsince too little or too much Ca⁺⁺ is inhibitory. Methyl farnesoate (MF) had no effect on ecdysone productionin crab or crayfish Y-organs in 24-hr incubations with MF at100 pM to 10 µM.