Developmental regulation of the larval hemolymph protein genes in Galleria mellonella

Development of quantitative proteomics using iTRAQ based on the immunological response of Galleria mellonella larvae challenged with Fusarium oxysporum microconidia

Galleria mellonella has emerged as a potential invertebrate model for scrutinizing innate immunity. Larvae are easy to handle in host-pathogen assays. We undertook proteomics research in order to understand immune response in a heterologous host when challenged with microconidia of Fusarium oxysporum. The aim of this study was to investigate hemolymph proteins that were differentially expressed between control and immunized larvae sets, tested with F. oxysporum at two temperatures. The iTRAQ approach allowed us to observe the effects of immune challenges in a lucid and robust manner, identifying more than 50 proteins, 17 of them probably involved in the immune response. Changes in protein expression were statistically significant, especially when temperature was increased because this was notoriously affected by F. oxysporum 104 or 106 microconidia/mL. Some proteins were up-regulated upon immune fungal microconidia challenge when temperature changed from 25 to 37°C. After analysis of identified proteins by bioinformatics and meta-analysis, results revealed that they were involved in transport, immune response, storage, oxide-reduction and catabolism: 20 from G. mellonella, 20 from the Lepidoptera species and 19 spread across bacteria, protista, fungi and animal species. Among these, 13 proteins and 2 peptides were examined for their immune expression, and the hypothetical 3D structures of 2 well-known proteins, unannotated for G. mellonella, i.e., actin and CREBP, were resolved using peptides matched with Bombyx mori and Danaus plexippus, respectively. The main conclusion in this study was that iTRAQ tool constitutes a consistent method to detect proteins associated with the innate immune system of G. mellonella in response to infection caused by F. oxysporum. In addition, iTRAQ was a reliable quantitative proteomic approach to detect and quantify the expression levels of immune system proteins and peptides, in particular, it was found that 104 microconidia/mL at 37°C over expressed many more proteins than other treatments.

Expression and localization of storage protein 1 (SP1) in differentiated fat body tissues of red hairy caterpillar, Amsacta albistriga Walker

The accumulation and utilization of storage proteins are prominent events linked to the metamorphosis of holometabolous insects. The female-specific storage protein 1 (SP1) is the major storage protein found in the hemolymph and fat body of female larvae of the groundnut pest, Amsacta albistriga. Here we show SP1 expression and localization in differentiated fat body tissues using biochemical and immunohistochemistry scrutiny. Comparison of A. albistriga SP1 with that of other species with respect to amino acid composition and N-terminal sequences show that SP1 is a methonine-rich protein and its identity was confirmed by means of immunoblot analysis. Northern blot studies revealed that the SP1 gene demonstrates stage- and tissue-specific expression in the peripheral fat body cells during the mid-larval period of fifth instar of A. albistriga. During the larval pupal transformation, SP1 are sequestered mainly by the perivisceral fat body tissues, until they serve the purpose of supplying amino acids for the production of egg yolk proteins. Further, electron microscopic studies using immunogold tracer techniques confirmed the localization of crystalline SP1 reserves, stored in the perivisceral fat body tissues. Hence, the peripheral fat body is responsible for biosynthesis of storage proteins, whereas the perivisceral fat body is a specialized storage organ.

Hormonal regulation of the expression of two storage proteins in the larval fat body of the greater wax moth (Galleria mellonella)

During larval development of the greater wax moth, Galleria mellonella, genes of storage proteins LHP76 and LHP82 are tissue- and stage-specifically expressed. In this study, hormonal regulation of this expression has been investigated in vivo. Messenger RNAs of the juvenile hormone (JH-suppressible) Lhp82 gene are present only during the feeding period of the final larval instar, suggesting that a high level of JH during earlier stages prevents its expression and that a small rise in JH titer observed on day 8 of the final larval instar is responsible for the rapid shut-off of its transcription. Application of 1micro g of JH analog (fenoxycarb) specifically inhibits expression of Lhp82, whereas Lhp76 mRNAs remain at the same level. 20-hydroxyecdysone (20HE) does not exert any inhibitory effects on transcription of Lhp genes when injected in a dose of 0.5 or 1.5 micro g per individual, regardless of larval age. However, the same dose of 20HE significantly lowers the rate of LHPs synthesis within the fat body and completely blocks secretion of LHPs into the hemolymph. Therefore, we propose that 20HE inhibits the synthesis of storage proteins and their secretion without altering the level of mRNAs.

Two juvenile hormone suppressible storage proteins may play different roles in Hyphantria cunea Drury

We isolated and sequenced cDNA clones corresponding to two storage proteins (HcSP-1 and HcSP-2) from fall webworm, Hyphantria cunea. The cDNAs for HcSP-1 (2,337 bp) and HcSP-2 (2,572 bp) code for 753 and 747 residue proteins with predicted molecular masses of 88.3 and 88.5 kDa, respectively. The calculated isoelectric points are pI = 8.4 (HcSP-1) and 7.6 (HcSP-2). Multiple alignment analysis of the amino acid sequence revealed that HcSP-1 is most similar to SL-1 from S. litura (73.8% identity) and other methionine-rich hexamers, whereas HcSP-2 is most similar to the SL-2 alpha subunit from S. litura (74.8% identity) and other moderately methionine-rich hexamers. The two storage proteins from H. cunea shared only 38.4% identity with one another. According to both phylogenetic analyses and the criteria of amino acid composition, HcSP-1 belongs to the subfamily of Met-rich storage proteins (6% methionine, 10% aromatic amino acid), and HcSP-2 belongs to the subfamily of moderately methionine-rich storage proteins (3.2% methionine, 12.9% aromatic amino acid). Topical application of the JH analog, methoprene, after head ligation of larvae, suppressed transcription of the SP genes, indicating hormonal effects at the transcriptional level. The HcSP-1 transcript was detected by Northern blot analysis in Malpighian tubule, testis, and ovary, in addition to fat body where it was most abundant. The HcSP-2 transcript was detected only in fat body and Malpighian tubule. The accumulation of HcSP-1 in ovary and HcSP-2 in Malpighian tubule might be related to differential functions in both organs.

Local expression and distribution of a storage protein in the ovary of Hyphantria cunea

Storage protein-1 (HcSP-1) is a major storage protein found in the hemolymph and fat body of Hyphantria cunea. HcSP-1 has a high methionine (6.0%) and low aromatic amino acid content (8.5%) (Cheon et al., 1998). In this study, the accumulation and expression of HcSP-1 in ovary was investigated using biochemical and immunocytochemical methods. HcSP-1 was detected in the ovaries in 6-day-old pupae and accumulated toward the end of pupal life, when HcSP-1 transcripts were detectable by Northern blot analysis and RT-PCR. In situ hybridization showed that the HcSP-1 mRNA was located in the nurse cells and follicular epithelial cells, but not in the oocyte. Though most of the HcSP-1 that is incorporated in the yolk bodies of the oocyte is probably sequestered from the surrounding hemolymph, HcSP-1 is an important yolk protein contributing to early yolk body formation before the development of patency by the follicular epithelium.

Expression of larval hemolymph proteins (Lhp) genes and protein synthesis in the fat body of greater wax moth (Galleria mellonella) larvae during diapause

When one-day-old, last instar Galleria mellonella larvae are exposed to 18 degrees C they enter diapause and cease further development for several months. During diapause a group of proteins (72-84 kDa) synthesized in the fat body and secreted into the hemolymph is markedly elevated. Partial sequencing of the N-terminus of two proteins from this group confirmed their identity with larval hemolymph proteins (LHP) belonging to the family of hexameric storage proteins. The expression of two Lhp genes of known sequence (Lhp76 and Lhp82) were monitored in both diapausing and non-diapausing individuals. The expression of both genes and subsequent synthesis of the proteins (LHP76 and LHP82) is maintained until at least 90-100 days of diapause.

Differential gene expression in insects: transcriptional control

Studies on transcriptional control of gene expression play a pivotal role in many areas of biology. In non-Drosophilid insects, the cuticle, chorion, immune response, silk gland, storage proteins, and vitellogenin are foci for advances in basic research on promoter elements and transcription factors. Insects offer other advantages for gene regulation studies, including the availability of applied problems. In non-Drosophilid insects, the most serious problem for transcriptional control studies is the lack of homologous in vivo expression systems. Once this deficiency is addressed, the full impact of research on transcription control will be realized throughout the field of entomology.

Developmental changes of storage proteins and biliverdin-binding proteins in the haemolymph and fat body of the common cutworm, Spodoptera litura

The concentrations of three storage proteins (SL-1,SL-2 and SL-3, hexamers of 70-80kDa subunits) and two biliverdin-binding proteins (BP-A and BP-B, dimers of 165kDa) in the haemolymph and fat body during larval and pupal development of Spodoptera litura were determined by immunodiffusion tests using polyclonal antisera. SL-1 and SL-2 (methionine-rich) first appeared in the haemolymph of one-day-old sixth (final) instar larvae, prominently increased in the haemolymph during the later feeding period and were almost totally sequestered by the fat body after gut purge. SL-3 (arylphorin) was first detected in the haemolymph during the molting period to the final larval ecdysis, increased in concentration throughout the entire feeding period of the final larval instar and was partly sequestered by the fat body several hours later than the other storage proteins. BP-A showed nearly the same pattern in the haemolymph as SL-3: BP-B increased during feeding period and decreased during molting period and attained a maximum level during the penultimate larval instar, however its concentration decreased considerably and remained low in the final larval instar. BP-A was partly and BP-B was almost totally sequestered by the fat body 8 h after sequestration of SL-1 and SL-2, rendering the fat body blue in colour. These facts suggest an additional function of biliverdin-binding proteins as amino acid storage proteins and the results show a differential uptake mechanism for these proteins by the fat body.

Insect storage proteins: gene families and receptors

The accumulation and utilization of storage proteins are prominent events linked to the metamorphosis of holometabolous insects. Storage proteins are synthesized in fat body, secreted into the larval hemolymph and taken up by fat body shortly before pupation. Within the pupal fat body, these proteins are initially stored in protein granules, and later proteolytically broken down to supply amino acid resources necessary for the completion of adult development. Most, but not all storage proteins belong to a superfamily of hexameric larval serum proteins that are evolutionarily related to hemocyanin. This article reviews the classification of these proteins, based on their amino acid sequences, and the current knowledge of the receptors that mediate their selective uptake into pupal fat body.

Nucleotide sequence, structure and developmental regulation of LHP82, a juvenile hormone-suppressible hexamerin gene from the waxmoth, Galleria mellonella

We cloned and sequenced a composite cDNA corresponding to the 2.6 kb last instar-specific, juvenile hormone-suppressible Lhp82 mRNA from Galleria mellonella. The identity of the cDNA was confirmed by N-terminal amino acid sequencing of the purified Lhp82 subunit. In addition, we sequenced all coding regions and most of the intronic DNA as well as 1300 nucleotides of 5' flanking DNA from the Lhp82 gene. The eight exons of the Lhp82 gene specify a pre-protein of 706 residues, including the signal peptide of 18 amino acids. The deduced amino acid sequence of Lhp82 contains four potential N-glycosylation sites, and the calculated isoelectric point and molecular weight of secreted Lhp82 are pI = 6.43 and 79.9 kDa, respectively. Inspection of the 5' flanking and intronic regions of Lhp82 DNA revealed a 301 nucleotide cassette in intron 6 that appears to be a recently inserted repetitive element. We also performed Northern blot and nuclear run-off transcription experiments in order to determine the basis for Lhp82 gene inactivity after day 2 of the pupal stage. The results of these studies indicate that Lhp82 transcription is permanently shut off by the ecdysteroid pulse which occurs in the absence of juvenile hormone beginning 24 h post-pupation.

Purification and characterization of a flavin-binding storage protein from the hemolymph of Galleria mellonella

The 85K storage protein that accumulates in the hemolymph of Galleria mellonella during the final larval instar was isolated and purified from newly molted pupae. The separation of fresh hemolymph proteins from larvae or pupae by different chromatographic and electrophoretic procedures indicated the native protein had a M(r) of 170,000 and consisted of two identical 85K subunits. Crosslinking experiments using fresh hemolymph followed by Western blotting also indicated a dimeric structure for the native protein. Analyses of the dimer purified from pupal hemolymph indicated that 85K was a glycoprotein, containing approximately 6.5% neutral sugar and about 1.9% amino sugar. Like other insect flavin-binding proteins, 85K has a relatively high histidine content but an uncharacteristically high arginine content. The purified 85K dimer did not bind riboflavin, suggesting that the integrity of the molecule had been altered during purification. However, 85K purified in low yield by Affi-Gel Blue chromatography, did bind riboflavin, indicating that under certain, undefined conditions the functional integrity of the protein could be retained during purification.

Regulation of expression of arylphorin and female-specific protein mRNAs in the tobacco hornworm, Manduca sexta

Two non-cross-hybridizing cDNA clones were isolated from a lambda gt11 cDNA library prepared from Day 2 fifth instar female fat body of Manduca sexta and shown by hybrid selection to code respectively for the two storage proteins arylphorin and female-specific protein (FSP). Analysis of the developmental expression of arylphorin showed its presence during the feeding phases of the penultimate (fourth) and final (fifth) larval instars and its absence during the molt. Abdominal ligation of larvae followed by infusion of Grace's medium showed that this amino acid-rich medium was able to maintain arylphorin expression in fourth instar larvae, but not continued high expression in fifth instar larvae. This nutrient medium however was sufficient to allow initiation of expression in newly ecdysed fifth larval abdomens. Infusion of 5 micrograms 20-hydroxyecdysone (20HE) caused a significant reduction of arylphorin RNA in ligated fourth larval abdomens, whereas 50 micrograms was required in Day 2 fifth larval abdomens to suppress this RNA. Thus, both the lack of incoming nutrients and the rising titer of ecdysteroid contribute to the loss of arylphorin mRNA at the molts and at wandering. By contrast, FSP mRNA was first detected in females on Day 2 of the fifth instar, but not in males until wandering, and then was present throughout the prepupal period. In females allatectomy caused the precocious appearance of FSP mRNA which was prevented by application of 10 micrograms methoprene, a juvenile hormone analog. Expression of FSP mRNA in males however appeared to be independent of hormonal milieu.

Synthesis of two storage proteins during larval development of the tobacco hornworm, Manduca sexta

Studies of synthesis and accumulation of the two storage proteins arylphorin and female-specific protein (FSP) during the final two larval instars of the tobacco hornworm showed both stage and temporal specificity. Arylphorin was present in both stages, but its synthesis ceased during the molt, during starvation, and at the wandering stage, and then resumed about 24 hr after the onset of feeding. During the larval molt about 25% of injected iodinated arylphorin was incorporated into the newly forming fifth instar cuticle. The cessation of arylphorin synthesis was mimicked by exposure of the fat body to 1 microgram/ml 20-hydroxyecdysone (20HE) in complete Grace's medium or to dilutions of Grace's medium greater than 50%. Lower concentrations of 20HE were ineffective, indicating that the cessation of synthesis in vivo was likely due to a combination of lack of excess nutrients and the hormonal milieu. The female-specific protein was not synthesized until the final larval instar, appearing first in females on Day 2 and later in males at the time of wandering, with synthesis continuing throughout the prepupal period. In vitro studies showed that this protein was synthesized as a 620-kDa protein, and then during secretion a 730-kDa immunoreactive form also appeared. Synthesis of FSP was inhibited by exposure of Day 2 fat body to 1 microgram/ml 20HE for 24 hr. Ligation followed by 20HE infusion showed that the disappearance of FSP from the hemolymph during the prepupal period was controlled by the rising ecdysteroid titer.

Role of hormones in starvation-induced delay in larval hemolymph protein gene expression in Galleria mellonella

Developmental Northern analysis of larval hemolymph protein gene transcripts in Galleria mellonella showed that Lhp76 is expressed all through the larval life, while Lhp82 is expressed only during the last larval stadium. Neither transcript was detectable in pharate adults and adult moths. In addition, these transcripts were not detectable during the first 48 h of the last larval stadium. Experimental analyses of the effects of the nutritional state and the hormonal levels of the last instar larvae on LHP gene expression suggests that the nutritional state of the larva has no direct effect, but nutrition acts through its effect on the hormone titers. Larvae starved after the first 24 h of the stadium and those fed on a non-protein diet produced both the transcripts on schedule on day 3. However, starvation during the first 24 or 48 h or feeding them on agar caused a marked delay in activation of Lhp82. These starved larvae pupated 4 to 12 days later than controls. Furthermore, JH titers in the starved larvae remain high even 5 days after ecdysis into the last instar. Prothorax-ligation of the starved and the starved-refed larvae accelerated production of the transcripts, thereby suggesting that the nutritional state does not directly affect LHP gene expression. Application of JH 1 to the ligated preparations resulted in selective blocking of Lhp82, while 20-OH ecdysone affected both the genes, thereby supporting the view that the insect hormones play an important role in stage-specific expression of LHP genes.