Physiological functions of hemocytes newly emerged from the cultured hematopoietic organs in the silkworm, Bombyx mori

Abstract  Cellular immunity is a very important part of insect innate immunity. It is not clear if hemocytes entering the hemolymph require a maturation process to become competent. The establishment of a tissue culture system for the insect hematopoietic organs would enable physiological function assays with hemocytes newly emerged from hematopoietic organs. To this end, we established a hematopoietic organ culture system for the purebred silkworm pnd pS and then studied the physiological functions of the newly emerged hemocytes. We found that Grace's medium supplemented with 10% heated silkworm larval plasma was better for culturing the hematopoietic organs of pnd pS . Newly emerged hemocytes phagocytosed propidium iodide-labeled bacteria and encapsulated the Iml-2 coated nickel beads as well as pupal tissue debris. This culture system is therefore capable of generating physiologically functional hemocytes. These hemocytes can be used to study the mechanisms of the hemocyte immune response among others.     

Hematopoietic organs of<Emphasis Type="Italic"> Manduca sexta</Emphasis> and hemocyte lineages

Cells of the moth immune system are derived from organs that loosely envelop the four wing imaginal discs. The immune response in these insects is believed to depend on the activities of two main classes of hemocytes: plasmatocytes and granular cells. The fates of cells that arise from these hematopoietic organs have been followed by immunolabeling with plasmatocyte-specific and granular-cell-specific antibodies. Cells within each hematopoietic organ differ in their coherence and in their expression of two plasmatocyte-specific surface proteins, integrin and neuroglian. Within an organ there is no overlap in the expression of these two surface proteins; neuroglian is found on the surfaces of the coherent cells while integrin is expressed on cells that are losing coherence, rounding up, and dispersing. A granular-cell-specific marker for the protein lacunin labels the basal lamina that delimits each organ but only a small number of granular cells that lie on or near the periphery of the hematopoietic organ. When organs are cultured in the absence of hemolymph, all cells derived from hematopoietic organs turn out to immunolabel with the plasmatocyte-specific antibody MS13. The circulating plasmatocytes derived from hematopoietic organs have higher ploidy levels than the granular cells and represent a separate lineage of hemocytes.Edited by P. Simpson     

Prophenoloxidase binds to the surface of hemocytes and is involved in hemocyte melanization in Manduca sexta

In insects, melanotic encapsulation is an important innate immune response against large pathogens or parasites, and phenoloxidase (PO) is a key enzyme in this process. Activation of prophenoloxidase (proPO) to PO is mediated by a serine proteinase cascade. PO has a tendency to adhere to foreign surfaces including hemocyte surfaces. In this study, we showed that in the naïve larvae of the tobacco hornworm Manduca sexta, hemolymph proPO bound to the surface of granulocytes and spherule cells but not to oenocytoids, and about 10% hemocytes had proPO on their surfaces. When larvae were injected with water (injury) or microsphere beads (immune-challenge), hemolymph proPO was activated, and the number of hemocytes with surface proPO/PO increased at 12 h post-injection, but dropped to the normal level at 24 h. Hemocyte surface proPO can be activated in vitro, leading to melanization of these hemocytes. The number of melanized hemocytes from the larvae injected with water or microsphere beads significantly increased. We also showed that neither hemocytes nor cell-free plasma alone triggered melanization of immulectin-2-coated agarose beads in vitro. However, agarose beads were effectively melanized by isolated hemocytes in the presence of cell-free plasma. Our results suggest that activation of hemocyte surface proPO may initiate melanization, leading to the systemic melanization of hemocyte capsules.     

In vitro studies of hematopoiesis in the silkworm: cell proliferation in and hemocyte discharge from the hematopoietic organ

The lepidopteran hematopoietic process is poorly understood. We therefore examined the fundamental properties of hematopoiesis in the silkworm Bombyx mori using hematopoietic organ culture. In a medium containing larval plasma taken from the fourth day of the final larval stadium, over 50,000 hemocytes per hematopoietic organ were discharged within 48 h, with the number of cells comprising the hematopoietic organ simultaneously increasing from approximately 20,000 to 40,000. However, in the absence of plasma, cell numbers comprising the hematopoietic organ were unchanged and the number of discharged cells was much less. Hematopoietic organs cultured with plasma showed strong mitotic indices in a BrdU incorporation assay, but did not when cultured without plasma, indicating that plasma contains hematopoietic factor(s). The hematopoietic stimulation ability of larval plasma was observed from the last day of the penultimate larval stadium to the prepupal stage. The response of the hematopoietic organs to larval plasma was highest at the beginning of the final larval stadium and decreased with aging. Most cells discharged from the hematopoietic organ were plasmatocytes and prohemocytes, irrespective of location and developmental stage. Using this in vitro culture method, we tested the effects of 20-hydroxyecdysone (20E) and juvenile hormone-I (JH-I) on B. mori hematopoiesis. 20E showed a weak, but significant, hematopoietic activity, whereas JH-I did not, suggesting that a part of larval hematopoiesis is endocrinally regulated.     

Reciprocal transplantation of wing discs between a wing deficient mutant (fl) and wild type of the silkworm, Bombyx mori

The wingless mutant flügellos ( fl ) of the silkworm lacks all four wings. Although wing discs of the fl seem to develop normally until the fourth larval instar, wing morphogenesis stops after the fourth larval ecdysis, probably caused by aberrant expression of an unidentified factor, referred to as fl . To characterize factor fl , the wing discs dissected from the wild-type (WT) and fl larvae were transplanted into other larvae and developmental changes of the discs were examined. When the wing disc from a WT larva was transplanted into another WT larva and allowed to grow until emergence, a small wing appeared that was covered with scales. Thus, the transplanted wing discs can develop autonomously, form scales and evert from adult skin. The WT wing discs transplanted into the fl larvae also developed at a high rate. However, the fl wing discs transplanted into the WT larvae did not develop during the larval to pupal developmental stages. These data suggest that the fl gene product (factor fl) works in the wing disc cells during wing morphogenesis. Its function cannot be complemented by hemolymph in the WT larva. It is also implied that the level of humoral factors and hormones required for wing morphogenesis are normally maintained in the fl larva.     

Characterization of cell clusters in larval hemolymph of the cabbage armyworm Mamestra brassicae and their role in maintenance of hemocyte populations

Maintenance of hemocyte populations is critical for both development and immune responses. In insects, the maintenance of hemocyte populations is regulated by mitotic division of circulating hemocytes and by discharge from hematopoietic organs. We found cell clusters in the hemolymph of Mamestra brassicae larvae that are composed of small, spherical cells. Microscopic observations revealed that the cells in these clusters are similar to immature or precursor cells present in hematopoietic organs. The results of bromodeoxyuridine (BrdU) incorporation experiments demonstrate that these cells are mitotically active. Furthermore, these cells maintain their immature state and proliferate until late in the last larval instar. The results of in vitro experiments showed that most of the cells changed their morphology to one consistent with plasmatocytes or granulocytes, and that the change was promoted by addition of larval hemolymph to the culture medium, in particular when hemolymph was collected at a prepupal stage. Taken together, our results suggested that cells in clusters may be an additional source of hemocytes during larval development.     

Insulin signaling is involved in hematopoietic regulation in an insect hematopoietic organ

Only a few extracellular hematopoietic factors have been identified in insects. We previously developed an in vitro culture system for the larval hematopoietic organ (HPO) of the silkworm Bombyx mori, and found that cell proliferation is linked to hemocyte discharge from the HPO. In this study, we tested hematopoietic activity of bombyxin, a peptide in the insulin family. When silkworm HPO was cultured with synthetic bombyxin-II, the number of discharged hemocytes increased in a dose-dependent manner, indicating that bombyxin promoted cell proliferation in the HPO. However, a neutralization experiment using anti-bombyxin-II antibody revealed that bombyxin is not the primary effector in larval plasma. Similarly, bovine insulin showed hematopoietic activity. Addition of molting hormone, 20-hydroxyecdysone, circumstantially enhanced the hematopoietic activity of bombyxin and insulin. Bombyxin and insulin induced phosphorylation of different sets of proteins in the HPO, suggesting that their signaling pathways are different.     

Morphology of hemocyte lysis and clotting in the ridgeback prawn,Sicyonia ingentis

Summary Coagulation of hemolymph in the shrimp Sicyonia ingentis was studied using light and electron microscopy. Differential counts of unclotted hemolymph show that 54% of the hemocytes are deposit cells characterized by a high nucleocytoplasmic ratio, a few granules, and cytoplasm filled with distinctive deposits. The remaining hemocytes have numerous large or small granules filling the cytoplasm. Examination of clotted hemolymph to which trypan blue had been added shows that deposit cells lyse, whereas the granulocytes exclude the dye, attach to slides, and extend filopodia. This suggests that deposit cells, not granulocytes, initiate coagulation. Ultrastructural changes in deposit cells were studied at specific times after mixing hemolymph and seawater. Deposit cells fixed immediately after removal from shrimp were shaped like elliptical discs and contained abundant, 50 nm diameter cytoplasmic deposits. After 30 s in seawater, deposit cells displayed several cytoplasmic blebs, and had aggregated the deposits. Cytolysis occurred by 45 s. Linear arrays of deposit appeared to extend through breaks in the plasma membrane, forming filamentous strands that hydrated to produce the clot. At 1 min after withdrawal, spheres of clotted hemolymph were seen, each surrounding a lysed deposit cell. Granulocytes remained relatively unchanged and trapped between adjacent expanding clots. Coagulation via hemocyte lysis is compared with other clotting mechanisms observed in various crustaceans and arthropods.     

The Involvement of Hemocyte Prophenoloxidase in the Shell-Hardening Process of the Blue Crab,Callinectes sapidus

Cuticular structures of arthropods undergo dramatic molt-related changes from being soft to becoming hard. The shell-hardening process of decapod crustaceans includes sclerotization and mineralization. Hemocyte PPO plays a central role in melanization and sclerotization particularly in wound healing in crustaceans. However, little is known about its role in the crustacean initial shell-hardening process. The earlier findings of the aggregation of heavily granulated hemocytes beneath the hypodermis during ecdysis imply that the hemocytes may be involved in the shell-hardening process. In order to determine if hemocytes and hemocyte PPO have a role in the shell-hardening of crustaceans, a knockdown study using specific CasPPO-hemo-dsRNA was carried out with juvenile blue crabs, Callinectes sapidus. Multiple injections of CasPPO-hemo-dsRNA reduce specifically the levels of CasPPO-hemo expression by 57% and PO activity by 54% in hemocyte lysate at the postmolt, while they have no effect on the total hemocyte numbers. Immunocytochemistry and flow cytometry analysis using a specific antiserum generated against CasPPO show granulocytes, semigranulocytes and hyaline cells as the cellular sources for PPO at the postmolt. Interestingly, the type of hemocytes, as the cellular sources of PPO, varies by molt stage. The granulocytes always contain PPO throughout the molt cycle. However, semigranulocytes and hyaline cells become CasPPO immune-positive only at early premolt and postmolt, indicating that PPO expression in these cells may be involved in the shell-hardening process of C. sapidus.     

Tissue distribution and purification of prophenoloxidase in larvae of Asian Corn Borer, Ostrinia furnacalis Guenee (Lepidoptera: Pyralidae)

Using ammonium sulphate precipitation, Blue-Sepharose CL-6B, Phenyl-Sepharose CL-4B, prophenoloxidase (PPO) was isolated and purified from hemolymph of Ostrinia furnacalis larvae. This zymogen was a heterodimer, and composed of two subunits with the relative molecular mass ranging from 66.2 kD to 97.4 kD determined by SDS-PAGE. Western blotting and indirect immunofluorescence test showed that PPO was present in integument, hemolymph plasma and cell membrane of granular hemocytes and oenocytoids of O. furnacalis larvae.     

Immunocytochemical localization of trehalase inhibitor in some insect species

Antibody against cockroach trehalase inhibitor was prepared and tested against the plasma of adult locusts and larval silkworms to determine whether these species possess a similar protein. An immunopositive response was elicited in both species. Studies using immunogold labeling show that adult cockroaches have trehalase inhibitor protein in granules of plasmatocytes and in oenocytoid-like structures. Localization of the immunoreactive protein with trehalase inhibitor antibody in locust hemocytes indicated that the protein is also contained in the granules of plasmatocytes. However, in the hemolymph of silkworm larvae, the immunoreactive protein was found only in the spherules of spherulocytes. The results suggest that insect hemolymph commonly contains trehalase inhibitor both in plasma and in certain hemocytes.     

Isolation of cDNA clones coding for humoral lectin of silkworm, Bombyx mori, larvae.

In the hemolymph of the silkworm, Bombyx mori, lectin with hemagglutinating activity against sheep red blood cells increases at larval-larval ecdysis and at spinning stage (Suzuki and Natori, 1983) and is induced by infection with cytoplasmic polyhedrosis virus. A Bombyx lectin polypeptide with molecular weight approx 280K is responsible for hemagglutinating activity, since antiserum raised against this polypeptide inhibited hemagglutinating activity. The site of synthesis of Bombyx lectin was determined by primary tissue cultures of fat body and hemocytes. A hemagglutinating activity assay demonstrated that hemocyte is responsible for the release of hemagglutinin into the culture medium. Isolation of cDNA clones coding for Bombyx lectin was carried out on the cDNA library prepared in an expression vector lambda gt11 starting with poly(A)+ RNA from spinning larval hemocytes. As a result of immunoscreening, several positive clones were obtained, and the cDNA clones were characterized.     

Effects of silkworm paralytic peptide on in vitro hematopoiesis and plasmatocyte spreading

Bombyx mori paralytic peptide (BmPP), a multifunctional cytokine-like molecule, is expressed in the hematopoietic organ-wing imaginal disc complex, suggesting that BmPP is involved in both immune response and the hematopoietic process. We studied the effects of BmPP on plasmatocytes and hematopoietic organs of the silkworm. BmPP (1 microM) stimulated spreading of circulating plasmatocytes, but the percentage of spread plasmatocytes was only 20%. Over 10 nM of BmPP, however, elicited prominent spreading in 70% of young plasmatocytes discharged from cultured hematopoietic organs. Cells in hematopoietic organs that were enzymatically dispersed did not spread even after adding 100 nM of BmPP, indicating that plasmatocytes acquired BmPP-sensitivity immediately after discharge. When cultured in a medium containing larval plasma, hematopoietic organs grew markedly and discharged a large number of hemocytes, over 95% of which were morphologically plasmatocytes. The hemocyte discharge was blocked in the medium containing BmPP dose-dependently, although hematopoietic organ growth was not suppressed. These results suggest that BmPP plays important roles both in hematopoietic regulation and in the hemocyte immune reaction of the silkworm.     

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.     

Prophenoloxidase Activation Is Required for Survival to Microbial Infections in Drosophila

The melanization reaction is a major immune response in Arthropods and involves the rapid synthesis of melanin at the site of infection and injury. A key enzyme in the melanization process is phenoloxidase (PO), which catalyzes the oxidation of phenols to quinones, which subsequently polymerize into melanin. The Drosophila genome encodes three POs, which are primarily produced as zymogens or prophenoloxidases (PPO). Two of them, PPO1 and PPO2, are produced by crystal cells. Here we have generated flies carrying deletions in PPO1 and PPO2. By analyzing these mutations alone and in combination, we clarify the functions of both PPOs in humoral melanization. Our study shows that PPO1 and PPO2 are responsible for all the PO activity in the hemolymph. While PPO1 is involved in the rapid early delivery of PO activity, PPO2 is accumulated in the crystals of crystal cells and provides a storage form that can be deployed in a later phase. Our study also reveals an important role for PPO1 and PPO2 in the survival to infection with Gram-positive bacteria and fungi, underlining the importance of melanization in insect host defense.     

Hemocytes and hemocytopoiesis in Silkworms.

A brief review is presented of the current state of ultrastructure, cytochemistry, and physiology of the hemocytes and meso- and metathoracic peri-imaginal-wing organs in silkworms. According to the accepted morphological classification, five circulating types of hemocytes are recognized in Bombyx mori as well as in Antheraea pernyi. They are prophemocytes or stem cells, plasmatocytes or pre-differentiated cells and three specialized cells, granulocytes, spherule cells and oenocytoids. During post-embryonic development the last four types are the most common in the circulating hemolymph. Plasmatocytes are considered to be pluripotent cells from which granulocytes, spherule cells and oenocytoids are derived. Contrary to the situation in most insects the plasmatocytes are not phagocytic in Antheraea. The granulocytes are efficient phagocytes. Both plasmatocytes and granulocytes are involved in pinocytosis. Another possible function of the granulocytes is hemolymph coagulation. The function of the spherule cells which contain a paracrystalline material (muco- or glycoproteins) is by no means clear. The phenoloxidase activity found within the cytosol of oenocytoids appears effective against the natural monophenol and diphenol substrates. The involvement of oenocytoids in the complex metabolism of phenols and particularly in the production of plasma phenolases has been reported. The mitotic division of five circulating hemocyte types is well known and was long regarded as the only mechanism of postembryonic hemocyte production. We present for silkworms, experimental evidence of the hemocytopoietic function of the meso- and metathoracic organs surrounding the imaginal wing discs. Ablation experiments demonstrate that the mitotic activity of free hemocytes is unable to maintain the normal hemocytogram in the absence of the two paris of organs. These organs are typically divided into cell islets ensheathed by a connective tissue membrane. Two types of islets may be classified by the disposition of the cells : the compact islets or aggregations of stem cells and the reticulate islets which are mainly composed of hemocytes at different steps of differentiation. The relative number of prohemocytes in the total hemocyte population ranges from 84 to 97 p. cent in organs of Antheraea pernyi. This well-defined cell type appears to be the major hemocyte type in hemocytopoietic organs. In Antheraea, the mitotic index (the relative number of mitotic hemocytes in the total cell population) varies from 0.5 to about 3 p. cent. Finally, our data direct attention to cyclic functional changes such as mitotic divisions and hemocyte differentiation which run parallel to the molting cycle.     

A scaleless wings mutant associated with tracheal system developmental deficiency in wing discs in the silkworm, Bombyx mori

A mutant of Bombyx mori has wings with few scales and is named scaleless. We investigated the morphology of this mutant and found that it had many fewer wing scales than the corresponding wild type (WT) silkworm and that the remaining scales were smaller in shape with fewer furcations. Reciprocal transplantation of wing discs between scaleless and WT revealed that the WT wing disc could develop into a small wing with scales after transplantation into a scaleless larva; however, the scaleless wing disc developed into a small wing without scales in a WT larva. Upon dissection of WT and scaleless wing discs at different stages from the fifth instar larva to adulthood, no obvious differences were found before pupation. However, after pupation, tracheae produced from WT wing veins extended to the lacunae between the veins and formed a network on the second day after pupation, whereas this did not happen in scaleless. At the same time, no marked difference in adult body tracheal development was found between the mutant and wild type. Furthermore, if the surface of a wing disc was cut and its veins injured, the resulting wing also had fewer scales than the corresponding WT. Also, we found that higher partial pressure of O2 could rescue the loss of scales in scaleless. These data suggest that the factors affecting the growth of scales were not produced in the hemolymph, but in the wing disc itself. It is also implied that wing scale development is dependent on the correct organization of the tracheal system in the wing disc.     

Prophenoloxidase activation in the hemolymph of Sarcophaga bullata larvae

Phenoloxidase in the hemolymph of Sarcophaga bullata larvae is present as an inactive proenzyme form. Localization studies indicate that the majority of the prophenoloxidase is present in the plasma fraction whereas only a minor fraction (about 4%) is present in the cellular compartments (hemocytes). Inactive prophenoloxidase can be activated by zymosan, not by either endotoxin or laminarin. This activation process is inhibited by the serine protease inhibitors, benzamidine and p-nitrophenyl-p～-guanidobenzoate. Exogenously added proteases, such as chymotrypsin and subtilisin, also activated the prophenoloxidase in the whole hemolymph but failed to activate the partially purified proenzyme. However, an activating enzyme isolated from the larval cuticle, which exhibits trypsinlike specificity, activated the partially purified prophenoloxidase. Inhibition studies and activity measurements also revealed the presence of a similar activating enzyme in the hemolymph. Thus, the phenoloxidase system in Sarcophaga bullata larval hemolymph seems to be comprised of a cascade of reactions. An endogenous protease inhibitor isolated from the larvae inhibited chymotrypsin-mediated prophenoloxidase activation but failed to inhibit the cuticular activating enzyme-catalyzed activation. Based on these studies, the roles of prophenoloxidase, endogenous activating proteases, and protease inhibitor in insect immunity are discussed.     

Mechanism of reduction in the number of the circulating hemocytes in the Pseudaletia separata host parasitized by Cotesia kariyai

Larval endoparasitoids can avoid the immune response of the host by the function of polydnavirus (PDV) and venom. PDV infects hemocytes and affects the hemocyte function of the host. In this paper, we investigated how PDV and venom affect the hemocyte population of the host. Cotesia kariyai, the larval endoparasitoid, lowers the hemocyte population of the noctuid host larvae soon after parasitization. The reduction in the number of circulating hemocytes is caused by the breakdown of the circulating hemocytes and of the hematopoietic organ which generates the circulating hemocytes. The decrease in the number of hemocytes shortly after parasitization is a response to the venom. However, the decrease in hemocyte population on and after 6 h post-parasitization appears to be caused by the PDV. Apoptosis in circulating hemocytes was observed on and after 6 h post-injection of PDV plus venom. It was revealed through cytometry that mitosis of circulating hemocytes was halted within 24 h after the injection of PDV plus venom. Apoptosis in the hematopoietic organ was induced 12 h after the injection of PDV plus venom. Furthermore, the plasma from the hosts injected with PDV plus venom depressed the number of hemocytes released from the hemotopoiteic organs.     

Multicellular-vesicle-promoting polypeptide from Trichoplusia ni: Tissue distribution and N-terminal sequence

An N-terminal amino acid sequence of a 16.9 kDa hemolymph polypeptide, “Vesicle Promoting Factor” (VPF) from Trichoplusia ni, revealed a high sequence homology (70%) with Manduca sexta apolipophorin-III. A polyclonal antibody developed against VPF, however, was not immunoreactive with either purified M. sexta or T. ni apolipophorin-III. Immunoblots of tissue homogenates of T. ni indicated that VPF was present in imaginal wing discs, central nervous system (CNS), silk glands, midgut and hemocytes from fifth instar larvae, and also in the IAL-TND1 cell line which can grow as either fluid-filled multicellular vesicles or multicellular aggregates. VPF was also detected immunologically in the hemolymph of adults of T. ni, and in hemolymph of adults and larvae of Galleria mellonella and Heliothis virescens. Testes, midgut, hemocytes, and wing discs, but not Malpighian tubules, of T. ni released VPF into tissue culture medium during a 3 h incubation period. © 1995 Wiley-Liss, Inc.

1 This article is a US Government work and, as such, is in the public domain in the United States of America.