Encapsulation and melanization responses of Armigeres subalbatus against inoculated Sephadex beads

Cellular dynamics of host - parasitoid interactions: Insights from the encapsulation process in a partially resistant host

Cotesia typhae is an eastern African endoparasitoid braconid wasp that targets the larval stage of the lepidopteran stem borer, Sesamia nonagrioides, a maize crop pest in Europe. The French host population is partially resistant to the Makindu strain of the wasp, allowing its development in only 40% of the cases. Resistant larvae can encapsulate the parasitoid and survive the infection. This interaction provides a very interesting frame for investigating the impact of parasitism on host cellular resistance. We characterized the parasitoid ovolarval development in a permissive host and studied the encapsulation process in a resistant host by dissection and histological sectioning compared to that of inert chromatography beads. We measured the total hemocyte count in parasitized and bead-injected larvae over time to monitor the magnitude of the immune reaction. Our results show that parasitism of resistant hosts delayed encapsulation but did not affect immune abilities towards inert beads. Moreover, while bead injection increased total hemocyte count, it remained constant in resistant and permissive larvae. We conclude that while Cotesia spp virulence factors are known to impair the host immune system, our results suggest that passive evasion could also occur.

Predation risk increases immune response in a larval dragonfly (Leucorrhinia intacta)

Predators often negatively affect prey performance through indirect, non-consumptive effects. We investigated the potential relationship between predator-induced stress and prey immune response. To test this, we administered a synthetic immune challenge into dragonfly larvae (Leucorrhinia intacta) and assessed a key immune response (level of encapsulation) in the presence and absence of a caged predator (Anax junius) at two temperatures (22 degrees C and 26 degrees C). We hypothesized that immune response would be lowered when predators were present due to lowered allocation of resources to immune function and leading to reduced encapsulation of the synthetic immune challenge. Contrary to our expectations, larvae exposed to caged predators had encapsulated monofilaments significantly more than larvae not exposed to caged predators. Levels of encapsulation did not differ across temperatures, nor interact with predator exposure. Our results suggest that the previously observed increase in mortality of L. intacta exposed to caged predators is not driven by immune suppression. In situations of increased predation risk, the exposure to predator cues may induce higher levels of melanin production, which could lead to physiological damage and high energetic costs. However, the costs and risks of increased allocations to immune responses and interactions with predation stress remain unknown.

Laminin and a Plasmodium ookinete surface protein inhibit melanotic encapsulation of Sephadex beads in the hemocoel of mosquitoes

In refractory mosquitoes, melanotic encapsulation of Plasmodium ookinetes and oocysts is a commonly observed immune response. However, in susceptible mosquitoes, Plasmodium oocysts develop extracellularly in the body cavity without being recognized by the immune system. Like Plasmodium gallinaceum oocysts, negatively charged carboxymethyl (CM)-Sephadex beads implanted in the hemocoel of Aedes aegypti female mosquitoes were not usually melanized, but were coated with mosquito-derived laminin. Conversely, electrically neutral G-Sephadex beads were routinely melanized. Since mosquito laminin coated both CM-Sephadex beads and P. gallinaceum oocysts, we hypothesized that laminin prevents melanization of both. To test this hypothesis, we coated cyanogen-bromide-activated G-Sephadex beads with laminin, recombinant P. gallinaceum ookinete surface protein (PgS28) or bovine serum albumin (BSA). Beads were implanted into the abdominal body cavity of female Aedes aegypti and retrieved 4 days later. Uncoated controls as well as BSA-coated G-Sephadex beads were melanized in a normal manner. However, melanization of beads coated with mouse laminin, Drosophila L2-secreted proteins or PgS28 was markedly reduced. Fluorescent antibody labeling showed that PgS28-coated beads had adsorbed mosquito laminin on their surface. Thus, mosquito laminin interacting with Plasmodium surface proteins probably masks oocysts from the mosquito's immune system, thereby facilitating their development in the body cavity.

Insect hemocytes and their role in immunity

The innate immune system of insects is divided into humoral and cellular defense responses. Humoral defenses include antimicrobial peptides, the cascades that regulate coagulation and melanization of hemolymph, and the production of reactive intermediates of oxygen and nitrogen. Cellular defenses refer to hemocyte-mediated responses like phagocytosis and encapsulation. In this review, we discuss the cellular immune responses of insects with emphasis on studies in Lepidoptera and Diptera. Insect hemocytes originate from mesodermally derived stem cells that differentiate into specific lineages identified by morphology, function, and molecular markers. In Lepidoptera, most cellular defense responses involve granular cells and plasmatocytes, whereas in Drosophila they involve primarily plasmatocytes and lamellocytes. Insect hemocytes recognize a variety of foreign targets as well as alterations to self. Both humoral and cell surface receptors are involved in these recognition events. Once a target is recognized as foreign, hemocyte-mediated defense responses are regulated by signaling factors and effector molecules that control cell adhesion and cytotoxicity. Several lines of evidence indicate that humoral and cellular defense responses are well-coordinated with one another. Cross-talk between the immune and nervous system may also play a role in regulating inflammation-like responses in insects during infection.

Cellular-mediated reactions to foreign organisms inoculated into the hemocoel of Anopheles albimanus (Diptera: Culicidae)

The immune response against different organisms and particles inoculated in the hemocoel of female Anopheles albimanus Wiedemann was investigated. Histological and ultrastructural observations indicated that melanization and hemocyte type participation varied according to the particles inoculated. The initial responses against heat-killed Microccocus lysodeikticus and Escherichia coli included hemocyte lysis and melanization whereas the response to heat-killed Saccharomyces cerevisiae was only cellular, and an initial melanization of Sephadex G-25 (neutral charged) beads was followed by the formation of cellular aggregates. After 24 h, hemocytes were involved in all terminal encapsulation events. Plasmodium vivax Grassi and Feletti formalin-fixed sporozoites induced a weak response. Cellular aggregates were observed 1 h postinoculation, but participating hemocytes could not be identified because of the extensive cellular damage and lysis. Sporozoites were also observed in the core of these aggregates, mixed with cell debris and free in the hemolymph. The effect on the inoculated particles was also different-S. cerevisiae was encapsulated only by hemocytes, whereas M. lysodeikticus was lysed and E. coli was phagocytosed by plasmatocytes. These results indicate that hemocytes are important components in the immune response in An. albimanus.

The role of surface characteristics in eliciting humoral encapsulation of foreign bodies in Plasmodium-refractory and -susceptible strains of Anopheles gambiae

A refractory strain of the mosquito, Anopheles gambiae, melanotically encapsulates and kills many species of malaria parasites, whereas susceptible strains allow the parasites to develop normally. To study the role of surface characteristics in eliciting this immune response, 27 types of chromatography beads that differed in matrix type, charge, functional group, and functional group density were assayed for degree of melanotic encapsulation in refractory and susceptible mosquitoes. Overall, two glucan-based matrices, Sephadex (dextran) and cellulose, stimulated the strongest responses, regardless of functional group. Substituting matrix hydroxyl groups with functional groups on Sephadex and cellulose beads decreased the level of encapsulation. These results demonstrate that glucans induce melanotic encapsulation in An. gambiae. Beads with agarose, polystyrene, and acrylic matrices, and most methacrylate-based beads elicited little or no melanization; however, epoxide-methacrylate beads were encapsulated, demonstrating that glucans are not essential for eliciting a response. Comparisons between the two strains demonstrated that refractory mosquitoes melanized many bead types to a greater degree than did susceptible mosquitoes. On this basis, we propose that an important difference between the two strains is that one of the enzymes involved in the melanization pathway functions at a higher level in the refractory strain. Finally, of all beads tested, only 85% substituted CM-Sephadex beads were virtually unmelanized in susceptible mosquitoes but highly melanized in the refractory strain; thus, a specific surface microenvironment is necessary to demonstrate this effect.

A factor preventing melanization of sephadex CM C-25 beads in Plasmodium-susceptible and refractory anopheles gambiae

One major quantitative trait locus controls melanization of both malaria ookinetes and Sephadex CM beads in a refractory strain of the mosquito, Anopheles gambiae. Hemolymph transferred from a nonmelanizing, Plasmodium-susceptible strain (4arr) to a melanizing, Plasmodium-refractory strain (L35) caused a reduction in the melanization of CM beads. In addition, when beads were first incubated in vivo in susceptible mosquitoes and then recovered, washed, and transferred to refractory mosquitoes, a strong reduction in melanization was observed. No changes in melanization were observed when beads or hemolymph were transferred in the opposite direction or within a strain. Incubation of beads in vitro in refractory or susceptible hemolymph resulted in a reduction of melanization when these beads were subsequently transferred to refractory mosquitoes. This reduction was significantly stronger when susceptible hemolymph was used as the incubating medium. Protection from melanization was observed after 3-, 6-, and 24-h incubations of beads in susceptible mosquitoes with longer incubations resulting in greater protection. Treatment of protected beads with 1 M NaOH resulted in the loss of the protection but treatment with 1% sodium dodecyl sulfate (SDS), 1% SDS/DTT/boiling, or 1 M NaOAc (pH 8.9) did not. These results show that a melanization-preventing factor covalently binds to the surface of CM beads in susceptible mosquitoes and can subsequently prevent melanization in refractory mosquitoes.

Immunity to eukaryotic parasites in vector insects

Mosquitoes and blackflies have been the focus of recent efforts to elucidate factors influencing the susceptibility of vector insects to metazoan and protozoan parasites of medical significance. Vector species exhibit variation in cellular and humoral immune responses, as highlighted by studies of melanotic encapsulation and components of the phenoloxidase system. Significant progress has been made in the development of genetic maps based upon molecular markers, leading to the genetic analysis of loci influencing susceptibility. The identification of specific inducible antibacterial peptides, and the cloning of genes encoding immune effector proteins as well as potential regulatory factors, open the path to fruitful studies of vector insect innate immunity and its relationship to insect-parasite interactions.

Response of Plasmodium refractory and susceptible strains of Anopheles gambiae to inoculated Sephadex beads

A refractory strain of the mosquito, Anopheles gambiae, melanotically encapsulates and destroys malaria parasites in the midgut. Normal development of parasites is observed in a closely related susceptible strain. To examine the basis for the difference in response, the two strains were compared for responses to inoculated Sephadex beads of varying charge. Negatively charged C-25 beads elicited a much stronger reaction in the refractory strain where 49% of the beads were strongly melanized by 24 h, compared with only 5% in the susceptible strain. Male mosquitoes of each strain responded similarly, with 100% of the beads strongly melanized by 24 h in the refractory strain compared with only 5% in the susceptible strain males. A time course revealed that the melanization in refractory but not susceptible mosquitoes increases substantially over time; 91% of C-25 beads were melanized in refractory females at 72 h compared with 9% in the susceptible sample. Neutral G-25 beads and positively charged A-25 beads were melanized in both strains, demonstrating that the capacity to melanize foreign particles is present in susceptible mosquitoes.