Movement of proteins across the digestive system of the tobacco budworm, Heliothis virescens

Bovine serum albumin (BSA) and anti‐BSA polyclonal antibody were used as model polypeptides to examine the movement of foreign proteins across the insect digestive system and their accumulation in hemolymph of fourth stadium tobacco budworms, Heliothis virescens (Fabricius) (Lepidoptera: Noctuidae). Hydrateable meal pads were developed in these studies as a method for easily introducing compounds into the insect digestive system. When insects were allowed to feed continuously on hydrated meal pads containing 0.8 mg of anti‐BSA per gram diet, the level of antibody found in hemolymph was 2.4 ± 0.1 and 3.4 ± 0.1 µg ml^?1 (average  1 SEM) after 8 and 16 h, respectively, as determined by enzyme‐linked immunosorbant assay (ELISA). Continuous feeding on hydrated meal pads containing the same concentration of BSA produced hemolymph concentrations of 1.5 ± 0.1 and 1.6 ± 0.1 µg ml^?1 hemolymph at 8 and 16 h, respectively. Western blot analyses demonstrated that BSA and anti‐BSA both retained their primary and multimeric structure and that anti‐BSA maintained its antigenic activity in the meal pads and after movement from meal pads into the hemolymph. When 1 µg of anti‐BSA or BSA was injected into the hemocoel of fourth instars, the concentrations decreased with time and 120 min after injection were 20% and 0.6% of the original concentration, respectively. When added at the same concentration to plasma in vitro, the decrease was 81.5% and 57.5%, respectively, at 2 h. The accumulation of native anti‐BSA and BSA protein in insect hemolymph is the result of their rate of movement across the gut and their rate of turnover in hemolymph. Movement of anti‐BSA and BSA across the digestive system was also noted in Helicoverpa zea (Boddie) (Lepidoptera: Noctuidae), Acheta domesticus (L.) (Orthoptera: Gryllidae), and Gromphadorhina portentosa (Schaum) (Blattaria: Blattellidae). Anti‐BSA and BSA were not detected in the hemolymph of Manduca sexta (L.) (Lepidoptera: Sphingidae) after feeding.     

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 role of neuropeptides in caterpillar nutritional ecology

Plant diet strongly impacts the fitness of insect herbivores. Immediately, we think of plant defensive compounds that may act as feeding deterrents or toxins. We are, probably, less aware that plants also influence insect growth and fecundity through their nutritional quality. However, most herbivores respond to their environment and select the diet which optimizes their growth and development. This regulation of nutritional balance may occur on many levels: through selecting and ingesting appropriate plant tissue and nutrient digestion, absorption and utilization. Here, we review evidence of how nutritional requirements, particularly leaf protein to digestible carbohydrate ratios, affect caterpillar herbivores. We propose a model where midgut endocrine cells assess and integrate hemolymph nutritional status and gut content and release peptides which influence digestive processes. Understanding the effects of diet on the insect herbivore is essential for the rational design and implementation of sustainable pest management practices.     

Uptake,flow, and digestion of casein and green fluorescent protein in the digestive system of Lygus hesperus Knight

Selected compounds were used to study physiological processes associated with digestion in the western tarnished plant bug, Lygus hesperus Knight. Durations of passage and rates of absorption, digestion, and excretion were determined for a digestible protein (casein), a non-digestible protein (green fluorescent protein, GFP), and a non-digestible carbohydrate (dextran). Dextran was used as a control to monitor the non-absorptive flow rate of ingesta through the digestive system. Fluorescent tracking of FITC-conjugates of casein and dextran, as well as immunoblotting and immunofluorescent staining of casein and GFP, were used to monitor the degradation (in vitro) and ingestion, digestion, and distribution (in vivo) of the respective compounds. Under our experimental conditions, L. hesperus took discrete meals, feeding and excreting at 2-3 h intervals. Rate of food passage was variable. FITC-dextran was found in the fecal material of most insects by 6-8 h after treatment initiation; by 12 h, 95% of ingested FITC-dextran was recovered from all insects. FITC-casein was digested extensively in in vitro homogenates of gut, hemolymph, and salivary gland. In vivo, FITC-casein was ingested and partially absorbed as a holoprotein into the hemolymph. Ingested FITC-casein was partially degraded in the gut and hemolymph within 2 h of ingestion, and no holoprotein was found after 12 h. In contrast, there was no detectable degradation of GFP in hemolymph, gut, and salivary gland homogenates after 24 h of incubation. Ingested GFP was not degraded in gut or hemolymph up to 8 h after treatment initiation, but did transfer to the hemolymph as a holoprotein. Analysis of immunohistological images confirmed that GFP bound to gut epithelial cell brush-border membranes. However, the mechanism by which GFP and casein pass as holoproteins into the hemolymph remains unknown.     

Phytochemicals at the plant-insect interface

Opportunities for genetic engineering of natural products are increasing, while discovery and development of synthetic insecticides and developmental regulators are declining. However, discovery and potential applications of natural compounds are constrained by present ecological knowledge and theory. Biochemistry offers additional perspective to chemical interaction across the interface between plant and herbivore. Phytochemical effects on an insect herbivore may be determined by physical, chemical, and biotic characteristics of the microenvironment during phytochemical transfer between plant and insect. The midgut lumen is often overlooked as part of this microenvironment. It initially determines rates of metabolism and uptake of phytochemicals into hemolymph, and ultimately the quantity of a compound seen by affected tissues. Additive processes such as absorption, binding, and transport by proteins in hemolymph may ultimately prove more crucial to toxication than subtractive processes such as metabolism and excretion. Uptake and transport of coumarins in hemolymph are being studied in larvae of the citrus root weevil Diaprepes abbreviatus. Studies with synthetic 7-amino-3-phenyl coumarin (coumarin-10) have preceded studies with natural coumarins. The fluorescence properties of coumarin-10 have enabled determination of absorption and binding to hemolymph proteins.     

Fusion of a soybean cysteine protease inhibitor and a legume lectin enhances anti-insect activity synergistically

Abstract 1 The soybean cysteine protease inhibitor soyacystatin N (scN) and Griffonia simplicifolia lectin II (rGSII) have defense functions against the coleopteran cowpea bruchid beetle Callosobruchus maculatus. However, the ability of the insect to activate scN‐insensitive digestive proteases and the relatively low potency of rGSII have hindered their practical application in plant protection. 2 Recent research suggests that defense proteins may achieve increased toxicity and durability when used in combination. Based on the structures of several natural toxin molecules, we hypothesized that covalently linked scN and rGSII could exhibit greater anti‐insect efficacy than the mixture containing individual proteins. 3 To test this hypothesis, a recombinant scN‐rGSII fusion protein that retained both protease inhibitor and lectin functions was constructed. 4 When fed to cowpea bruchid, this new protein showed a synergistic delay in insect development, whereas a mixture of the separate proteins only showed an additive effect. 5 Our results suggest that tethering digestive protease inhibitors to gut epithelium‐interacting lectins could give plant protection superior to strategies based on single genes or mixtures of single gene products.     

Systematic investigation of the hemolymph proteome of Manduca sexta at the fifth instar larvae stage using one- and two-dimensional proteomics platforms

Manduca sexta is an excellent insect model for studying insect physiology, including hemolymph proteins. Larvae stages of this insect are highly damaging to tobacco leaves causing a drastic decrease in crop yield. Investigation on the larval biology should help in controlling its destructive potential, thus increasing crop yields. The hemolymph is the source of its immunity to disease and environmental factors, which invariably involves protein components. To better understand the physiology of M. sexta and the protein components expressed during its life cycle, two complementary proteomics approaches, one- and two-dimensional gel electrophoresis (1-DGE and 2-DGE) in conjunction with N-terminal amino acid sequencing and liquid chromatography-mass spectrometry, were employed to analyze the fifth instar larvae hemolymph proteins. These proteomics approaches together identified 123 proteins, which constituted a total of 58 nonredundant proteins and belonged to 10 functional categories. Defense (49%), transport and metabolism (15%), storage (9%), and metamorphosis (7%) categories were highly represented accounting for 80% of the identified proteins. Besides identification of previously reported proteins, 18 novel proteins were identified, which include the lipoprotein-releasing system transmembrane protein lolC, 50S ribosomal protein L24, inducible serine protease inhibitor 1, imaginal disk growth factor, protein disulfide-isomerase-like protein ERp57, etc. The 2-DGE data were integrated to develop a 2-D gel reference map. Data obtained from 1-DGE and 2-DGE analyses are accessible through the M. sexta proteomics portal ( http://foodfunc.agr.ibaraki.ac.jp/mansehemoprot.html). Together, this study provides evidence for the presence of a large number of functionally diverse protein families in the hemolymph of M. sexta. These proteins correlate well with the fifth instar stage, the transition from larvae to pupae.     

Transcytosis of Junonia coenia densovirus VP4 across the gut epithelium of Spodoptera frugiperda(Lepidoptera:Noctuidae)

The Junonia coenia densovirus rapidly traverses the gut epithelium of the host lepidopteran without replicating in the gut cells.The ability of this virus to transcytose across the gut epithelium is of interest for the potential use of virus structural proteins as delivery vehicles for insecticidal peptides that act within the insect hemocoel,rather than in the gut.In this study,we used fall armyworm,Spodoptera frugiperda to examine the binding of the virus to brush border membrane vesicle proteins by two-dimensional ligand blot analysis.We also assessed the rate of flux of the primary viral structural protein,VP4 fused to eGFP with a proline-rich linker(VP4-P-eGFP)through the gut epithelium ex vivo in an Ussing chamber.The mechanisms involved with transcytosis of VP4-P-eGFP were assessed by use of inhibitors.Bovine serum albumin(BSA)and eGFP were used as positive and negative control proteins,respectively.In contrast to BSA,which binds to multiple proteins on the brush border membrane,VP4-P-eGFP binding was specific to a protein of high molecular mass.Protein flux was significantly higher for VP4-P-eGFP after 2 h than for albumin or eGFP,with rapid transcytosis of VP4-P-eGFP within the first 30 min.In contrast to BSA which transcytosed following clathrin-mediated endocytosis,the movement of VP4-P-eGFP was vesicle-mediated but clathrin-independent.The specificity of binding combined with the efficiency of transport across the gut epithelium suggest that VP4 will provide a useful carrier for insecticidal peptides active within the hemocoel of key lepidopteran pests including S.frugiperda.     

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.     

The multi-tasking gut epithelium of insects

The insect gut epithelium plays a vital role in multiple processes, including nutrition, immunity and osmoregulation. Recent research is revealing the molecular and biochemical basis of these functions. For example, the pattern of nutrient acquisition by the gut epithelium is integrated into the overall regulation of nutrient allocation, as illustrated by evidence for systemic controls over expression of key genes coding digestive enzymes and transporters in carbohydrate acquisition; and the abundance and diversity of microorganisms in the gut lumen is regulated by multiple molecular properties of the gut epithelial cells, including the synthesis of enzymes that produce reactive oxygen species and anti-microbial peptides. These traits are underpinned by the function of the gut epithelium as a selective barrier which mediates the controlled movement of water, ions, metabolites and macromolecules between the gut lumen and insect tissues. Breakdown of the gut epithelial barrier has been implicated in muscle paralysis of insects at low temperatures (chill coma) and in aging. The key challenge for future research is to understand how the multiple functions of the insect gut epithelium are integrated by signaling interactions among epithelial cells, the gut microbiota and other insect organs.     

The distribution of a kinin-like peptide and its co-localization with a CRF-like peptide in the blood-feeding bug, Rhodnius prolixus

Rhodnius prolixus, a blood-feeding hemipteran insect, ingests large meals which are followed by rapid diuresis to eliminate excess water and salt. In Rhodnius, serotonin and an unidentified peptide(s) [33,34] have been shown to act as neurohormonal diuretic factors. In other insects, two families of diuretic peptides, the corticotropin releasing factor (CRF)-like, and kinin peptides [9], have been identified and sequenced. Recently, we demonstrated the presence of a CRF-like diuretic peptide in the CNS and digestive system of Rhodnius [47] using immunohistochemistry and bioassay.In this study, combining immunohistochemistry and radioimmunoassay (RIA) techniques, we show the presence of leucokinin-like peptide(s) in the CNS and digestive system of Rhodnius 5th instar. Additionally, double-label immunohistochemistry demonstrates that the leucokinin-like and CRF-like peptides are co-localized in the posterior lateral neurosecretory cells of the mesothoracic ganglionic mass (MTGM) and in neurohaemal areas on abdominal nerves one and two, suggesting the possibility of co-release of the peptides into the hemolymph.Partially purified extracts of the CNS and neurohaemal tissue were tested in vitro on Malpighian tubule secretion and cAMP assays. The factors eluting with increasing acetonitrile percentages from Sep-Pak cartridges were assayed in the presence or absence of ketanserin, a serotonin antagonist which blocks the effects of serotonin on Malpighian tubules. The results indicate activity of serotonin and a CRF-like diuretic peptide on Rhodnius Malpighian tubules, but fail to demonstrate activity of the leucokinin-like peptide(s).The rapid diuresis following feeding is a highly coordinated event, requiring the movement of water and salt across the epithelial cells of the crop into the hemolymph, and from the hemolymph across the cells of the Malpighian tubules. The urine then travels along the Malpighian tubules into the hindgut in order to be expelled. The presence of a leucokinin-like peptide(s) in the CNS and digestive system, which co-localizes with a CRF-like peptide(s), suggests that kinins may play a role in the rapid diuresis, although possibly not directly on the Malpighian tubules.     

Drosophila seminal fluid proteins enter the circulatory system of the mated female fly by crossing the posterior vaginal wall

Seminal fluid proteins from males of many insect species affect the behavior and physiology of their mates. In some cases, these effects result from entry of the proteins into the female's circulatory system. In the fruit fly Drosophila melanogaster, some seminal fluid proteins enter the female's circulatory system after transfer from the male while others remain confined within the reproductive tract. To address where and how seminal fluid proteins enter the hemolymph of the mated female, we compared the kinetics of transfer and localization in mated females of two seminal fluid proteins that enter the hemolymph (Acp26Aa and Acp62F) and one that does not (Acp36DE). We also generated transgenic flies that produce Acp26Aa tagged with Aequorea victoria green fluorescent protein (GFP) to monitor its transfer in vivo. We report that Acps enter the female circulatory system from the posterior vagina immediately after insemination. The ability of Acps to enter the female hemolymph correlates with their ability to cross the intima that lines the posterior vagina. The ventral posterior vagina is structurally unlike other parts of the female reproductive tract in that it lacks muscles. We hypothesize that it has higher permeability thus affording access to the female's circulatory system.     

Identification and characterization of a novel cell-penetrating peptide of 30Kc19 protein derived from Bombyx mori

Cell-penetrating peptides (CPPs) or protein transduction domains (PTDs) have attracted increasing attention due to their high potential to deliver various, otherwise impermeable, bioactive agents, such as drugs and proteins across cell membranes. A number of CPPs have been discovered since then. Recently, 30Kc19 protein has attracted attention because it was the first cell-penetrating protein that has been found in insect hemolymph. Here, we report a cell-penetrating peptide derived from 30Kc19 protein, VVNKLIRNNKMNC, which efficiently penetrates cells when supplemented to medium for mammalian cell culture. Moreover, like other CPPs, this “Pep-c19” also efficiently delivered cell-impermeable cargo proteins, such as green fluorescent protein (GFP) into cells. In addition to the in vitro system, Pep-c19 exhibited the cell-penetrating property in vivo. When Pep-c19 was intraperitoneally injected into mice, Pep-c19 successfully delivered cargo proteins into various organ tissues with higher efficiency than the 30Kc19 protein itself, and without toxicity. Our data demonstrates that Pep-c19 has a great potential as a cell-penetrating peptide that can be used as a therapeutic tool to efficiently deliver different cell-impermeable cargo molecules into the tissues of various organs.     

Absorption of albumin by the midgut of a lepidopteran larva

In the last decade, the study of peptide and protein absorption by the insect gut has received increasing attention because of the considerable impact this information may have on the development of new delivery strategies for insecticide macromolecules targeting haemocoelic receptors. Available experimental evidence in vivo suggests that, in insects, peptides and proteins can cross the intestinal barrier reaching the haemocoel, but the functional bases of this absorption pathway have not yet been thoroughly investigated. The current knowledge of the mechanisms involved in protein and polypeptide absorption in animals derives from the extensive studies performed in mammalian polarised epithelial cells, where the transcellular transport of proteins by transcytosis has been demonstrated. In this process, proteins are internalised at one pole of the cell and transported by cytoplasmic vesicular traffic to the opposite plasma membrane domain, where they are released with unchanged biological activity. Here we report data on albumin translocation across the isolated midgut of Bombyx mori caterpillars perfused in vitro. The functional properties of the transepithelial transport of this protein are described and, since absorption prevails over secretion, its lumen-to-haemolymph flux is characterised. Low-temperature incubations nearly abolish the transepithelial transport, while the peculiar physiological features of the larval midgut, i.e. the high lumen positive transepithelial voltage and the luminal alkaline pH, do not affect the flux. The obtained results indicate that albumin crosses B. mori larval midgut by transcytosis.     

Insecticidal activity of a basement membrane-degrading protease against Heliothis virescens (Fabricius) and Acyrthosiphon pisum (Harris)

ScathL is a cathepsin L-like cysteine protease derived from the flesh fly Sarcophaga peregrina that functions in basement membrane (BM) remodeling during insect development. A recombinant baculovirus expressing ScathL (AcMLF9.ScathL) kills larvae of the tobacco budworm, Heliothis virescens, significantly faster than the wild-type virus. Here, we show that the occurrence of larval melanization prior to death was closely associated with the onset of high cysteine protease activity of ScathL in the hemolymph of fifth instars infected with AcMLF9.ScathL, but not with AcMLF9.ScathL.C146A, a recombinant baculovirus expressing a catalytic site mutant of ScathL. Fragmented fat body, ruptured gut and malpighian tubules, and melanized tracheae were observed in AcMLF9.ScathL-infected larvae. Phenoloxidase activity in hemolymph was unchanged, but the pool of prophenoloxidase was significantly reduced in virus-infected larvae and further reduced in AcMLF9.ScathL-infected larvae. The median lethal dose (LD(50)) for purified ScathL injected into fifth-instar H. virescens was 11.0 microg/larva. ScathL was also lethal to adult pea aphids, Acyrthosiphon pisum with a similar loss of integrity of the gut and fat body. Injection with purified ScathL.C146A or bovine trypsin at 20 microg/larva did not produce any effect in either insect. These results illustrate the potent insecticidal effects of ScathL cysteine protease activity and the potential for use of ScathL in development of insect resistant transgenic plants when combined with an appropriate delivery system.     

Functional mechanics of the plant defensive Griffonia simplicifolia lectin II: resistance to proteolysis is independent of glycoconjugate binding in the insect gut.

Griffonia simplicifolia lectin II (GSII) is a plant defensive protein that significantly delays development of the cowpea bruchid Callosobruchus maculatus (F.). Previous structure/function analysis by site-directed mutagenesis indicated that carbohydrate binding and resistance to insect gut proteolysis are required for the anti-insect activity of this lectin. However, whether there is a causal link between carbohydrate binding and resistance to insect metabolism remains unknown. Two proteases principally responsible for digestive proteolysis in third and fourth instar larvae of C. maculatus were purified by activated thiol sepharose chromatography and resolved as cathepsin L-like proteases, based on N-terminal amino acid sequence analysis. Digestion of bacterially expressed recombinant GSII (rGSII) and its mutant protein variants with the purified gut proteases indicates that carbohydrate binding, presumably to a target ligand in insect gut, and proteolytic resistance are independent properties of rGSII, and that both facilitate its efficacy as a plant defensive molecule.     

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.     

Trypanosoma rangeli interactions within the vector Rhodnius prolixus: a mini review

This article is an integrative mini review of the research on the interactions between Trypanosoma rangeli and the insect vector, Rhodnius prolixus. Special attention is given to the interactions of these parasites with the gut environment, gut walls, with hemolymph invasion, hemocytes, hemocyte microaggregations, prophenoloxidase-activating system, superoxide, and nitric acid generation and eicosanoid pathways. We described factors affecting vectorial capacity and suggested that T. rangeli may modulate the hemocoelic invasion and the survival of the parasites by overcoming the cellular and humoral defense reactions of the insect vector at different physiological events. The mechanisms of these interactions and their significance for parasite transmission are discussed.     

Secretory delivery of recombinant proteins in attenuated Salmonella strains: potential and limitations of Type I protein transporters

Live attenuated Salmonella strains have been extensively explored as oral delivery systems for recombinant vaccine antigens and effector proteins with immunoadjuvant and immunomodulatory potential. The feasibility of this approach was demonstrated in human vaccination trials for various antigens. However, immunization efficiencies with live vaccines are generally significantly lower compared to those monitored in parenteral immunizations with the same vaccine antigen. This is, at least partly, due to the lack of secretory expression systems, enabling large-scale extracellular delivery of vaccine and effector proteins by these strains. Because of their low complexity and the terminal location of the secretion signal in the secreted protein, Type I (ATP-binding cassette) secretion systems appear to be particularly suited for development of such recombinant extracellular expression systems. So far, the Escherichia coli hemolysin system is the only Type I secretion system, which has been adapted to recombinant protein secretion in Salmonella. However, this system has a number of disadvantages, including low secretion capacity, complex genetic regulation, and structural restriction to the secreted protein, which eventually hinder high-level in vivo delivery of recombinant vaccines and effector proteins. Thus, the development of more efficient recombinant protein secretion systems, based on Type I exporters can help to improve efficacies of live recombinant Salmonella vaccines. Type I secretion systems, mediating secretion of bacterial surface layer proteins, such as RsaA in Caulobacter crescentus, are discussed as promising candidates for improved secretory delivery systems.     

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.