Proteomics of larval hemolymph in Bombyx mori reveals various nutrient-storage and immunity-related proteins

The silkworm, Bombyx mori, is an important economic insect for its production of silk. The larvae of many lepidopteran insects are major agricultural pests and often silkworm is explored as a model organism for other lepidopteran pest species. The hemolymph of caterpillars contains a lot of nutrient and immune components. In this study, we applied liquid chromatography–tandem mass spectrometry to gain a better understanding of the larval hemolymph proteomics in B. mori. We identified 752 proteins in hemolymph collected from day-4 fourth instar and day-7 fifth instar. Nearly half the identified proteins (49 %) were predicted to function as binding proteins and 46 % were predicted to have catalytic activities. Apolipophorins, storage proteins, and 30K proteins constituted the most abundant groups of nutrient-storage proteins. Of them, 30K proteins showed large differences between fourth instar larvae and fifth instar larvae. Besides nutrient-storage proteins, protease inhibitors are also expressed very highly in hemolymph. The analysis also revealed lots of immunity-related proteins, including recognition, signaling, effectors and other proteins, comprising multiple immunity pathways in hemolymph. Our data provide an exhaustive research of nutrient-storage proteins and immunity-related proteins in larval hemolymph, and will pave the way for future physiological and pathological studies of caterpillars.     

Specific Binding of Silkworm Bombyx mori 30-kDa Lipoproteins to Carbohydrates Containing Glucose

Insect lectins are important as part of nonspecific self-defense, but their antifungal mechanisms remain to be elucidated. Fungi contain glucans on the cell surface and insect glucan-binding proteins are considered to be essential for antifungal mechanisms. We purified glucose-binding proteins from hemolymph of pupae of the silkworm Bombyx mori, and the amino acid sequence analysis showed that their two proteins are 30-kDa lipoproteins, major components of B. mori hemolymph. These lipoproteins specifically bound to glucose and glucans, suggesting that they are involved in insect self-defense systems.     

Insect antimicrobial peptides and their applications

Insects are one of the major sources of antimicrobial peptides/proteins (AMPs). Since observation of antimicrobial activity in the hemolymph of pupae from the giant silk moths Samia Cynthia and Hyalophora cecropia in 1974 and purification of first insect AMP (cecropin) from H. cecropia pupae in 1980, over 150 insect AMPs have been purified or identified. Most insect AMPs are small and cationic, and they show activities against bacteria and/or fungi, as well as some parasites and viruses. Insect AMPs can be classified into four families based on their structures or unique sequences: the α-helical peptides (cecropin and moricin), cysteine-rich peptides (insect defensin and drosomycin), proline-rich peptides (apidaecin, drosocin, and lebocin), and glycine-rich peptides/proteins (attacin and gloverin). Among insect AMPs, defensins, cecropins, proline-rich peptides, and attacins are common, while gloverins and moricins have been identified only in Lepidoptera. Most active AMPs are small peptides of 20–50 residues, which are generated from larger inactive precursor proteins or pro-proteins, but gloverins (~14 kDa) and attacins (~20 kDa) are large antimicrobial proteins. In this mini-review, we will discuss current knowledge and recent progress in several classes of insect AMPs, including insect defensins, cecropins, attacins, lebocins and other proline-rich peptides, gloverins, and moricins, with a focus on structural-functional relationships and their potential applications.     

Flies without Trehalose

Living organisms adapt to environmental changes through metabolic homeostasis. Sugars are used primarily for the metabolic production of ATP energy and carbon sources. Trehalose is a nonreducing disaccharide that is present in many organisms. In insects, the principal hemolymph sugar is trehalose instead of glucose. As in mammals, hemolymph sugar levels in Drosophila are regulated by the action of endocrine hormones. Therefore, the mobilization of trehalose to glucose is thought to be critical for metabolic homeostasis. However, the physiological role of trehalose as a hemolymph sugar during insect development remains largely unclear. Here, we demonstrate that mutants of the trehalose-synthesizing enzyme Tps1 failed to produce trehalose as expected but survived into the late pupal period and died before eclosion. Larvae without trehalose grew normally, with a slight reduction in body size, under normal food conditions. However, these larvae were extremely sensitive to starvation, possibly due to a local defect in the central nervous system. Furthermore, Tps1 mutant larvae failed to grow on a low-sugar diet and exhibited severe growth defects on a low-protein diet. These diet-dependent phenotypes of Tps1 mutants demonstrate the critical role of trehalose during development in Drosophila and reveal how animals adapt to changes in nutrient availability.     

Enhancement of Sf-9 cell growth and longevity through supplementation of culture medium with hemolymph

The benefits of insect cell culture medium supplementation with hemolymph of Lonomia obliqua were investigated. The addition of hemolymph to the medium induced high levels of cell growth, and the viability was maintained for longer periods. The maximum cell yield increased almost 3-fold after hemolymph supplementation. Cultures in their stationary phase were rescued through hemolymph supplementation, also reaching high cell concentrations. These actions were much dependent on the concentration of hemolymph; low hemolymph concentration had a positive effect in cell growth, whereas high hemolymph concentration showed a deleterious effect. Fractionation of hemolymph by gel filtration chromatography showed the presence of three factors with different activity in insect cell culture: an potential anti-apoptotic factor, a growth-promoting factor, and an enzyme that hydrolyzes sucrose. Addition of hemolymph to the medium induced high levels of glucose production. The sucrose to glucose conversion was also linearly dependent upon the hemolymph concentration. Therefore, we conclude that cell growth and longevity can be increased by supplementation of the culture medium with hemolymph.     

The synthesis of hemolymph proteins by the larval midgut of an insect Calpodes ethlius (Lepidoptera:Hesperiidae)

Ligated tubes of Calpodes ethlius (Lepidoptera:Hesperiidae) larval midgut with normal (i.e. apical secretions into the lumen and basal into the hemocel or medium) or inverted orientation (i.e. apical secretions into the hemocoel or medium and basal into the lumen) were incubated in artificial hemolymph in the presence of [³⁵S]methionine to investigate protein synthesis and vectorial secretion. The midgut synthesizes and secretes at least eight polypeptides basally and seven apically. The tissue also synthesizes many other polypeptides that are not released at either surface. Two dimensional analysis of proteins labeled in vitro and in vivo showed that (a) proteins synthesized in vitro are the same as those synthesized in vivo, (b) different proteins are secreted on apical and basal surfaces, (c) in vitro apical secretions are the same as in vivo luminal proteins, (d) at least two of the basal secretions can be demonstrated in the hemolymph labeled in vivo. Almost all basal secretions showed immunological similarity with hemolymph proteins as observed by immunoprecipitation and fluorography. Arylphorin is a main hemolymph protein synthesized by the midgut. Midgut arylphorin has been identified by its precipitation by antibodies to hemolymph arylphorin. We conclude that insect midgut has bi-directional secretion. Luminal proteins (presumably digestive enzymes and perhaps goblet cell luminal contents) are carried to the apical face. A different set of proteins are carried basally to the hemolymph.     

Juvenile hormone binding protein traffic — Interaction with ATP synthase and lipid transfer proteins

Juvenile hormone (JH) controls insect development, metamorphosis and reproduction. In insect hemolymph a significant proportion of JH is bound to juvenile hormone binding protein (JHBP), which serves as a carrier supplying the hormone to the target tissues. To shed some light on JHBP passage within insect tissues, the interaction of this carrier with other proteins from Galleria mellonella (Lepidoptera) was investigated. Our studies revealed the presence of JHBP within the tracheal epithelium and fat body cells in both the membrane and cytoplasmic sections. We found that the interaction between JHBP and membrane proteins occurs with saturation kinetics and is specific and reversible. ATP synthase was indicated as a JHBP membrane binding protein based upon SPR-BIA and MS analysis. It was found that in G. mellonella fat body, this enzyme is present in mitochondrial fraction, plasma membranes and cytosol as well. In the model system containing bovine F₁ ATP synthase and JHBP, the interaction between these two components occurs with K_d = 0.86 nM. In hemolymph we detected JHBP binding to apolipophorin, arylphorin and hexamerin. These results provide the first demonstration of the physical interaction of JHBP with membrane and hemolymph proteins which can be involved in JHBP molecule traffic.     

Specific binding of silkworm Bombyx mori 30-kDa lipoproteins to carbohydrates containing glucose

Insect lectins are important as part of nonspecific self-defense, but their antifungal mechanisms remain to be elucidated. Fungi contain glucans on the cell surface and insect glucan-binding proteins are considered to be essential for antifungal mechanisms. We purified glucose-binding proteins from hemolymph of pupae of the silkworm Bombyx mori, and the amino acid sequence analysis showed that their two proteins are 30-kDa lipoproteins, major components of B. mori hemolymph. These lipoproteins specifically bound to glucose and glucans, suggesting that they are involved in insect self-defense systems.     

The synthesis of hemolymph proteins by the larval epidermis of an insect Calpodes ethlius (Lepidoptera: Hesperiidae)

Sheets of the dorsal abdominal integument from fifth instar larvae of Calpodes ethlius (Lepidoptera: Hesperiidae) were incubated in artificial hemolymph in the presence of [³⁵S]methionine to investigate protein synthesis and vectorial secretion. The epidermis synthesizes and secretes at least 13 polypeptides basally and 15 apically. Two dimensional analysis of proteins labeled in vitro and in vivo showed that (a) most of the polypeptides secreted on apical and basal surfaces are different, (b) in vitro apical secretions are the same as in vivo cuticular proteins, (c) at least four of the basal secretions can be demonstrated in hemolymph labeled in vivo.Antibodies made against whole hemolymph recognized five basally secreted polypeptides and one apically secreted polypeptide both on fluorograms of immunoprecipitates and immunoblots. Arylphorin is secreted from both surfaces. Arylphorin synthesized in vitro has been identified through its precipitation by antibodies to hemolymph arylphorin in epidermis, cuticle and medium. We conclude that insect epidermis has bi-directional secretion. Cuticular proteins are carried to the apical face. A different set of proteins are carried basally to the hemolymph.     

Hemostasis in larvae of Manduca sexta: formation of a fibrous coagulum by hemolymph proteins

Little is known of the participation of insect hemolymph proteins in wound healing and clot formation. We describe the assembly of purified hemolymph protein from the tobacco hornworm into an extended fibrous coagulum in the absence of hemocytes. This coagulum resembles the clot formed from bovine fibrinogen and thrombin. Structural components of the coagulum are present in hemolymph, however, spontaneous assembly occurs only in hemolymph collected through a wound. The fibrous coagulum assembles from purified structural protein(s) following addition of a non-protein factor from hemolymph, which is also present in Grace's insect cell culture medium.     

Transport of lipids in insects

Many insect species are almost completely dependent on lipids for their metabolic needs, although this is usually a function of developmental stage. The primary storage organ is the fat body, which can constitute 50% of the fresh weight of the insect and also acts as the major metabolic center (analogous to the vertebrate adipose tissue and liver). Bathing the fat body (and all other tissues and organs) is the hemolymph, the main functions of which are to transport nutrient substrates to utilization sites and to deliver metabolic wastes to the excretory system. Although neutral lipids are stored as triglycerides, in times of need they appear to be endergonically released into the hemolymph as diglycerides in the majority of insects thus far studied (particularly silkmoths and locusts). Indeed, diglycerides constitute the largest neutral lipid fraction in the hemolymph of silkmoths, locusts, cockroaches, bugs, etc. In the hemolymph the diglyceride is found as a constituent of specific lipoproteins, and one specific lipoprotein class (lipoprotein I; high density lipoprotein) appears to be necessary for the transport of diglyceride from the fat body cell into the hemolymph. This particular lipoprotein is also involved in the transport of cholesterol from the gut into the hemolymph. Thus, lipoprotein I appears to be the major neutral lipid and sterol transport agent in the insects studied and, in addition, plays a regulatory role in the release of both diglycerides and sterols. Hemolymph lipoprotein II (very high density lipoprotein) may be important in providing protein and lipid to the insect ovary during oogenesis. Ecdysone, the polyhydroxy steroidal insect molting hormone, is probably carried "free" in the hemolymph, although reports exist of specific hemolymph-binding proteins in some species. The other major insect growth hormone, juvenile hormone, is transported by hemolymph lipoproteins in silkmoths and locusts and by a lower molecular weight hemolymph protein in the tobacco hornworm.     

The fate of exotoxin of Bacillus thuringiensis in Galleria mellonella caterpillars

Three hours after parenteral administration of ³²P-labeled exotoxin of Bacillus thuringiensis to caterpillars of Galleria mellonella, 80% of the radioactivity was localized in the hemolymph in the form of the original exotoxin. The remaining radioactivity occurred in the organs of the caterpillar, especially in the spinning glands and the intestine. After peroral administration, the exotoxin does not pass the intestinal wall into the hemolymph to a measurable degree. In this case, the exotoxin is split in the intestinal wall and the products of ³²P reutilization have been found in the hemolymph. The mechanism of action of the exotoxin in the insect organism is discussed; presumably it depends on different ways of administration of the substance.     

Isolation of two Locust protein targets of a protein tyrosine phosphatase from Metarhizium anisopliae strain CQMa102

In entomopathogenic fungi, secretory protein phosphatases might function in the utilization of phosphoproteins from the environment. But if secreted into the host, secretory protein phosphatases might play a role in pathogenesis by dephosphorylation of host phosphoproteins. Our group purified a novel phosphatase from entomopathogenic fungi, Metarhizium anisopliae. The substrate specificity and inhibitor sensitivity indicate that the phosphatase is a protein tyrosine phosphatase (PTPase). In order to analyze the targets of the PTPase in Locusta migratoria hemolymph, two-dimensional electrophoresis and mass spectrometry were used. The results indicated that the PTPase could specifically dephosphorylate two phosphoproteins from L. migratoria hemolymph. One phosphoprotein was identified as trans-Golgi p230. Previous studies have shown that trans-Golgi p230 participates in vesicular transport of functional proteins from the distal Golgi compartment. trans-Golgi p230 can be inactivated by dephosphorylation, which implies that M. anisopliae could interfere with the correct transportation of functional proteins by secreting extracellular PTPase into the hemolymph. There are some secretion proteins, such as transferrin, have been thought to participate in the insect innate immune against microbial infection, therefor M. anisopliae could interfere with immune defenses of L. migratoria by secreting extracellular PTPase into the hemolymph.     

Protease and phospholipase inhibition protect Veneza zonata (Hemiptera Coreidae) against septicemia caused by parasite trypanosomatid 563DT

Veneza zonata (Hemiptera Coreidae) is an insect which causes losses in several crops, and it is also an important vector of lower trypanosomatids. V. zonata specimens were collected on rural properties in Londrina, state of Paraná, Southern Brazil. Inoculation of Leptomonas 563DT into V. zonata hemocoel caused insect death within approximately 24 h, with large bacterial proliferation into their hemocoels. Some bacteria which were found in the digestive tract of those insects, such as Escherichia coli, Providencia rettgeri, and Kluyveria ascorbata, were also found in their hemolymph, which suggests that trypanosomatid crossing into hemocoel caused mechanical lesions in the digestive tract that allowed intestinal bacteria to infect the hemolymph, thereby leading to lethal septicemia. In this study we analysed proteolytic activities from the 563DT Leptomonas strain, which is pathogenic for V. zonata, aiming at evaluating the potential use of this Leptomonas strain for the biocontrol of the insect. The proteolytic action was evaluated on cells and on culture supernatants of trypanosomatids. We also evaluated the gelatinolytic activities, the action over natural and synthetic substrates for aminopeptidases, and the action of protease inhibitors during all trypanosomatid growth stages. A significant reduction in the number of insect deaths was observed when Leptomonas 563DT were incubated with inhibitors of proteases and phospholipases before being inoculated into the insects, which suggests that those enzymes are involved in the pathogenic mechanism.     

Comparative proteomics analysis of silkworm hemolymph during the stages of metamorphosis via liquid chromatography and mass spectrometry

The silkworm is a lepidopteran insect that has an open circulatory system with hemolymph consisting of blood and lymph fluid. Hemolymph is not only considered as a depository of nutrients and energy, but it also plays a key role in substance transportation, immunity response, and proteolysis. In this study, we used LC‐MS/MS to analyze the hemolymph proteins of four developmental stages during metamorphosis. A total of 728 proteins were identified from the hemolymph of the second day of wandering stage, first day of pupation, ninth day of pupation, and first day as an adult moth. GO annotations and categories showed that silkworm hemolymph proteins were enriched in carbohydrate metabolism, proteolysis, protein binding, and antibacterial humoral response. The levels of nutrient, immunity‐related, and structural proteins changed significantly during development and metamorphosis. Some, such as cuticle, odorant‐binding, and chemosensory proteins, showed stage‐specific expression in the hemolymph. In addition, the expression of several antimicrobial peptides exhibited their highest level of abundance in the hemolymph of the early pupal stage. These findings provide a comprehensive proteomic insight of the silkworm hemolymph and suggest additional molecular targets for studying insect metamorphosis.     

Clathrin‐dependent endocytosis predominantly mediates protein absorption by fat body from the hemolymph in Bombyx mori

During insect larval–pupal metamorphosis, proteins in the hemolymph are absorbed by the fat body for the maintenance of intracellular homeostasis; however, the type of proteins and how these proteins are internalized into the fat body are unclear. In Bombyx mori, the developmental profiles of total proteins in the hemolymph and fat body showed that hemolymph‐decreased protein bands (55–100 kDa) were in accordance with those protein bands that increased in the fat body. Inhibition of clathrin‐dependent endocytosis predominantly blocked the transportation of 55–100 kDa proteins from the hemolymph into the fat body, which was further verified by RNA interference treatment of Bmclathrin. Six hexamerins were shown to comprise ～90% of the total identified proteins in both the hemolymph and fat body by mass spectrum (MS) analysis. In addition, hemolymph‐specific proteins were mainly involved in material transportation, while fat body‐specific proteins particularly participated in metabolism. In this paper, four hexamerins were found for the first time, and potential proteins absorbed by the fat body from the hemolymph through clathrin‐dependent endocytosis were identified. This study sheds light on the protein absorption mechanism during insect metamorphosis.     

Changes observed in hemolymph proteins of the lawn armyworm,Spodoptera mauritia acronyctoides,during growth,development, and exposures to a nuclear polyhedrosis virus

Vertical electrophoresis with acrylamide gel was used to study the effects of a nuclear polyhedrosis virus (NPV) on the hemolymph proteins of Spodoptera mauritia acronyctoides. An electrophoretic pattern consisting of 20 basic bands of proteins was separated in hemolymph of normal larvae which were older than 17 days. These hemolymph proteins increased quantitatively during growth. All 20 proteins could not be detected in hemolymph of younger larvae by the techniques utilized. Additional proteins were separated with metamorphosis. Lethal doses of NPV resulted in a general reduction of hemolymph proteins (hypoproteinemia) in infected larvae. Sublethal doses of NPV elicited an increase in certain hemolymph proteins. Similar increases in proteins were also observed in larvae surviving ostensibly lethal levels of NPV, in larvae subjected to physical stress, and in larvae reared axenically without formaldehyde in their diets. These same proteins, however, were present in approximately the same quantities in mature larvae. Physiopathology of NPV in S. mauritia appears to involve stress factors, host reactions, and the host endocrine system.