Tyrosine kinase mediated phosphorylation of the hexamerin receptor in the rice moth Corcyra cephalonica by ecdysteroids

Hexamerins are multifunctional insect storage proteins utilized during metamorphosis of holometabolous insects. These proteins are stage specifically taken up by the fat body cells from the haemolymph due to receptor-mediated endocytosis. The hexamerin receptor and the concomitant hexamerin sequestration in the rice moth Corcyra cephalonica is controlled by the steroid hormone 20-hydroxy-ecdysone (20E). However, the mechanism of receptor activation for hexamerin uptake is not yet clear. We report here that 20E stimulates the phosphorylation of 120 kDa hexamerin binding protein which has been demonstrated to represent the receptor. Phosphorylation of the receptor is suggested to be essential for receptor activation and occurs prior to the hexamerin uptake. The 20E stimulated phosphorylation is mediated partly by a tyrosine kinase as phosphotyrosine antibodies cross-react with the receptor and its phosphorylation is blocked partly by genistein. Back phosphorylation study provides additional evidence for 20E regulation of hexamerin receptor phosphorylation in intact fat body. The receptor phosphorylation is developmentally regulated. This is the first report demonstrating that (i) the uptake of hexamerin is dependent on the phosphorylation of hexamerin receptor and (ii) the phosphorylation is catalyzed partly by a tyrosine kinase which is activated by 20E through a non-genomic action.     

Significance of the 19-kDa hemolymph protein HP19 for the development of the rice moth Corcyra cephalonica: morphological and biochemical effects caused by antibody application

The hemolymph protein HP19 of the rice moth, Corcyra cephalonica, mediates the 20-hydroxyecdysone (20E)-dependent acid phosphatase (ACP) activity at a nongenomic level. Affinity-purified polyclonal antibody against HP19 (alphaHP19-IgG) was used in the present study to understand the role of HP19 during the postembryonic development of Corcyra. In the in vitro studies, HP19 action was blocked either by immuno-precipitation using alphaHP19-IgG, prior to its addition to the fat body culture or by the addition of the antibody directly to the culture, along with 20E and hemolymph containing HP19. The alphaHP19-IgG blocked the HP19-mediated 20E-dependent ACP activation. In the in vivo studies, the alphaHP19-IgG was injected into the fully developed last (final/Vth) instar larvae of Corcyra, to complex the HP19 in vivo, in order to block the action of HP19. The injection of alphaHP19-IgG resulted in defective development of larvae, which grew either into non-viable larvae or larval-pupal/pupal-adult intermediates relative to the effect of pre-immune IgG injected controls. The present study shows that HP19 plays an important role in controlling the metamorphosis of Corcyra by regulating the 20E-dependent ACP activity. Coupled with the earlier findings, the ecdysteroid hormone regulates this action at a nongenomic level.     

Complete sequence,expression and evolution of two members of the hexamerin protein family during the larval development of the rice moth,Corcyra cephalonica

Three distinct types of storage hexamerins are expressed in the "last-instar" larvae of the rice moth, Corcyra cephalonica. A cDNA expression library was constructed from fat body-RNA and screened with a polyclonal antibody raised against purified hexamerin (SP2) of Corcyra cephalonica. Two slightly different "full-length" hexamerin cDNA clones (Hex2a and Hex2b) were isolated and sequenced. Both include open reading frames of 2109 bp which are translated into polypeptides of 703 amino acids with 92.5% identity. Signal peptides of 19 amino acids are present at the N-termini. The 684 amino acids native proteins have a high content of aryl groups (17.6%). According to both the criteria for amino acid composition and the phylogenetic analysis, Hex2a and Hex2b belong to the lepidopteran arylphorins. Northern blot studies revealed that the Hex2 genes are species- and tissue-specifically expressed in fat body cells of "last-instar" (= 5th) larvae.     

Juvenile hormone inhibits the synthesis of major larval haemolymph proteins in rice moth, Corcyra cephalonica

Larval haemolymph proteins (LHP), LHP49 and LHP46 are produced in the penultimate and last larval instars. Starvation during the early and mid stage of last instar development prevents the production of both LHPs. Decapitation in early and mid last instar stimulates LHP synthesis and their concentration in haemolymph increases, while ligation in last instar larvae blocks the production of LHPs. Application of exogenous JH lowers the synthesis of LHP49 and LHP46 in Corcyra. These observations suggests that LHP49 and LHP46 synthesis is activated during the periods when JH titres are either low or undetectable.     

20-Hydroxyecdysone mediated activation of larval haemolymph protein uptake by fat body cells of Corcyra cephalonica (Insecta)

Evidence is presented here to show that 20-hydroxyecdysone is essential for the activation of the larval fat body for differential uptake of larval haemolymph proteins (LHPs). By using radiolabelled LHPs it is shown that the fat body cells of Corcyra cephalonica selectively incorporate LHPs during late-larval and prepupal development. Fluorographic analysis of the labelled fat body proteins from prepupal stage separated on sodium dodecyl-sulphate polyacrylamide gels suggests that the LHPs are sequestered without any degradation. Although, during the last larval instar the uptake of all the three LHPs (LHP 1, LHP 2 and LHP 3) by the fat body cells is very low, 20-hydroxyecdysone treatment of early, mid or late-last instars causes a significant increase in uptake of all the three LHPs. However, the response to hormone treatment was more pronounced in late-last instar when compared to early and mid-last instar.     

Insecticidal action of Annona coriacea lectin against the flour moth Anagasta kuehniella and the rice moth Corcyra cephalonica (Lepidoptera: Pyralidae)

Annona coriacea lectin (ACLEC) was tested for insecticidal activity against larvae of two pyralid moths, Anagasta kuehniella and Corcyra cephalonica. ACLEC produced approximately 50% mortality and mass loss in A. kuehniella larvae when incorporated into an artificial diet at levels of 1.5% and 1.0% (w/w), respectively. In contrast, the inclusion of up to 2% ACLEC in the diet did not significantly decrease the survival or weight of C. cephalonica larvae. The nutritional indices for A. kuehniella and C. cephalonica suggested that ACLEC had a multi-mechanistic mode of action and was an antifeedant for both insects. The toxicity in A. kuehniella apparently resulted from a change in the gut membrane environment and consequent disruption of digestive enzyme recycling mechanisms. Affinity chromatography showed that ACLEC bound to midgut proteins of A. kuehniella and C. cephalonica. However, the 14 kDa subunit of ACLEC was not digested by midgut proteases of A. kuehniella, but was degraded by the corresponding C. cephalonica proteases within a few hours. These findings suggest the possibility of using ACLEC to engineer crop plants.     

Impact of modified atmospheres on respiration of last instar larvae of the rice moth,Corcyra cephalonica (Lepidoptera: Pyralidae)

Abstract

Effect of modified atmospheres (MAs) containing CO₂ at 20, 40, 60 and 80% or containing N₂ at 97 and 98% on the mortality of Corcyra cephalonica Stainton (Lepidoptera: Pyralidae) sixth instar larvae was studied to determine the LT values at 30?°C. The respiration rates of untreated and treated larvae with 60% CO₂ and/or 98% N₂ at LT₅₀ were measured using Q-Box RP1LP low range respirometry package. Total protein and triglycerides of treated and untreated larvae were assayed. Complete larval mortality was recorded after 72 and 144?h of treatment with 60% CO₂ and 98% N₂, respectively. Calculated LT₅₀ values were 39.3 at 60% CO₂ and 87.5?h at 98% N₂ MAs. Respiration quotient (RQ) in the light of consumed O₂ and produced CO₂ of untreated larvae was 1.0 while it was 0.85 at 60% CO₂ and 0.72 at 98% N₂. Duration time necessary for produced CO₂ curve to reach the maximum point (2000?ppm) was significantly shorter at untreated larvae (27.64?min) in comparison with that recorded at CO₂ (35.48?min) which also significantly less than that obtained at N₂ (98.54?min). At all treatments, total protein was decreased while triglycerides were increased in comparison with control.     

Site of hemolymph lectin production and its activation in vitro by 20-hydroxyecdysone

To identify the tissues which produce hemolymph lectin in larvae of Bombyx mori, ovary, testis, fat body, and hemocytes from 5th-instar larvae were cultured in vitro and the culture medium was partially purified and assayed for hemagglutinating activity. Among the tissues tested, hemocytes appeared to be a major source of the hemolymph lectins. Ovary produced lectins to about one-tenth of the amount observed for the hemocytes, whereas testis and fat body were not productive. To study the hormonal control of hemolymph lectin production by hemocytes, hemocytes from 4th-instar larvae were cultured in vitro. Hemagglutinating activity in the hemolymph of 4th-instar larvae was immunostainable with the monoclonal antibody raised against 350,000 dalton lectin found in the 5th-instar hemolymph, but their molecular sizes were larger than the 5th-instar hemolymph lectins. When 20-hydroxyecdysone was added into the medium, production of the lectin by the hemocytes was remarkably enhanced, depending upon the hormone concentration.     

Cloning and expression of fat body hexamerin receptor and its identification in other hexamerin sequestering tissue of rice moth, Corcyra cephalonica

Selective receptor mediated uptake is a widely prevalent mechanism in insects by which important macromolecules are acquired. Among the various proteins sequestered by the insect fat body, the larval hexamerins form the major group. In the present work full length cDNA (2.6 kb) of hexamerin receptor with an ORF of 2.4 kb was cloned from the larval fat body of rice moth, Corcyra cephalonica. This was followed by the recombinant expression of truncated N-terminal sequence of putative hexamerin receptor and the confirmation of the expressed recombinant protein as the truncated hexamerin receptor by ligand blot analysis. Apart from this we also analyzed other hexamerin sequestering tissues like salivary gland, male accessory reproductive gland and ovary for the presence of hexamerin receptor. We found that the receptor in these tissues was similar in size and mode of activation to that of fat body hexamerin receptor, thus cementing the fact that identical hexamerin receptors are present in all the hexamerin sequestering tissues in the rice moth.     

Identification and activation of storage protein receptor of Sarcophaga peregrina fat body by 20-hydroxyecdysone

Previous work showed that 20-hydroxyecdysone activates the fat body of Sarcophaga peregrina larvae to incorporate storage protein selectively from the hemolymph. In this study, storage protein receptors of the fat body membrane which were induced on pupation or on treatment of larval fat body with 20-hydroxyecdysone in vitro were identified. The binding of storage protein to its receptor required divalent cations, especially Ca2+, and the binding was very sensitive to pH. The storage protein receptor was inactivated when the fat body membrane was treated with trypsin. The storage protein receptor is probably a protein and it may be synthesized de novo or a cryptic form may be converted to the active form when the concentration of 20-hydroxyecdysone in the hemolymph reaches a physiological level.     

Regulation of the cardiac ryanodine receptor by protein kinase-dependent phosphorylation.

The exogenous addition of the catalytic subunit of cAMP-dependent protein kinase (PKA), cGMP-dependent protein kinase (PKG), or calmodulin (CaM) induced rapid phosphorylation of the ryanodine receptor (Ca2+ release channel) in canine cardiac microsomes treated with 1 mM [gamma-32P]ATP. Added protein kinase C (PKC) also phosphorylated the cardiac ryanodine receptor but at a relatively slow rate. The observed level of PKA-, PKG-, or PKC-dependent phosphorylation of the ryanodine receptor was comparable to the maximum level of [3H]ryanodine binding in cardiac microsomes, whereas the level of CaM-dependent phosphorylation was about 4 times greater. Phosphorylation by PKA, PKG, and PKC increased [3H]ryanodine binding in cardiac microsomes by 22 +/- 5, 17 +/- 4, and 15 +/- 9% (average +/- SD, n = 4-5), respectively. In contrast, incubation of microsomes with 5 microM CaM alone and 5 microM CaM plus 1 mM ATP decreased [3H]ryanodine binding by 38 +/- 14 and 53 +/- 15% (average +/- SD, n = 6), respectively. Phosphopeptide mapping and phosphoamino acid analysis provided evidence suggesting that PKA, PKG, and PKC predominantly phosphorylate serine residue(s) in the same phosphopeptide (peptide 1), whereas the endogenous CaM-kinase phosphorylates serine residue(s) in a different phosphopeptide (peptide 4). Photoaffinity labeling of microsomes with photoreactive 125I-labeled CaM revealed that CaM bound to a high molecular weight protein, which was immunoprecipitated by a monoclonal antibody against the cardiac ryanodine receptor. These results suggest that protein kinase-dependent phosphorylation and CaM play important regulatory roles in the function of the cardiac sarcoplasmic reticulum Ca2+ release channel.     

Induction of selective phosphorylation of a fat body protein of Sarcophaga peregrina larvae by 20-hydroxyecdysone.

20-Hydroxyecdysone was shown to induce selective phosphorylation of a fat body protein of Sarcophaga peregrina larvae with a molecular mass of 30 kDa. This phosphorylation was not associated with synthesis of new protein. Fractionation of 32P-labelled fat body by differential centrifugation showed that this protein was mainly present in the membrane-rich fraction, although we could not specify the membrane. Thus, 20-hydroxyecdysone may modify the function of the fat body by inducing phosphorylation of a specific membrane protein.