Cellular immune response in Rhodnius prolixus: role of ecdysone in hemocyte phagocytosis

In this paper we investigate in vivo and in vitro effects of orally administered azadirachtin and ecdysone on the phagocytic responses of Rhodnius prolixus 5th-instar larval hemocytes to the yeast Saccharomyces cerevisiae. Groups of insects fed non-treated blood (control) and insects that received azadirachtin plus ecdysone in the blood meal were inoculated with yeast cells in the hemocele. The injected yeast cells disappeared rapidly from the hemolymph, being removed completely by 90min after inoculation. In the insects treated only with azadirachtin the clearance of free yeast circulating particles was significantly delayed compared to the two previously mentioned groups. It was demonstrated that the binding of yeast cells to hemocytes was reduced in the insects treated only with azadirachtin in comparison to both non-treated control and azadirachtin plus ecdysone-treated groups. Phagocytosis occurred when yeast cells were added to hemocyte monolayers prepared with hemolymph from blood fed insects, treated or not with azadirachtin plus ecdysone, so that yeast cells were rapidly bound to hemocytes and internalized in high numbers. By contrast, insects treated with azadirachtin exhibited a drastic reduction in the quantity of yeast cell-hemocyte binding and subsequent internalization. In all groups, the hemocytes attached to the glass slides were predominantly plasmatocytes. The magnitude and speed of the cellular response suggests that hemocyte phagocytosis is one of the main driving forces for the clearance of free circulating yeast cells from the hemolymph. We propose that ecdysone modulates phagocytosis in R. prolixus larvae, and that this effect is antagonized by azadirachtin.     

Production of reactive oxygen species by hemocytes from the cattle tick Boophilus microplus.

We have investigated the phagocytic activity and the production of reactive oxygen species (ROS) by hemocytes from the cattle tick Boophilus microplus. Two main types of hemocytes were detected in tick hemolymph: plasmatocytes and granulocytes. The plasmocytes were the most abundant cells, being responsible for the in vivo phagocytosis of yeast. ROS production was evaluated by luminol-amplified luminescence and phenol red oxidation. The luminescence increased when hemocytes were incubated with bacteria, zymosan, or phorbol 12-miristate 13-acetate (PMA). The luminescence was inhibited by superoxide dismutase and catalase, which are antioxidant enzymes that remove superoxide and hydrogen peroxide, respectively. The phenol red oxidation assay also showed an increase in the level of hydrogen peroxide produced by hemocytes stimulated with bacteria and PMA. Taken all together, our data indicate that tick hemocytes are able to produce ROS during the phagocytic process similarly to vertebrate phagocytes.     

Biomphalaria glabrata: influence of calcium, lectins, and plasma factors on in vitro phagocytic behavior of hemocytes of noninfected or Schistosoma mansoni-infected snails.

In vitro phagocytosis of erythrocytes by hemocytes of B. glabrata, intermediate host of S. mansoni, is strongly influenced by calcium, several lectins, and plasma factors. Our results indicate that two different mechanisms of non-self-recognition in B. glabrata may occur: (1) In the presence of calcium, phagocytosis occurs in noninfected and in infected snails without involvement of any other substances, and hemocytes of schistosome resistant as well as those of susceptible snails are able to recognize and phagocytose the target cells. (2) In the absence of calcium, phagocytosis occurs if bridging molecules (heterologous lectins in our assays) were present for which effector and target cells possess binding sites or if target cells were plasma coated prior to the assays. In suspensions in homologous plasma, hemocytes of both snail strains, infected or noninfected, subsequently showed phagocytic activities of about 70-80%. Preincubation of target cells in homologous plasma resulted in similar high phagocytic activities of hemocytes even in the absence of plasma during the standard assay. In these assays, a significantly higher proportion of hemocytes of resistant snails phagocytosed plasma-opsonized erythrocytes, whereas hemocytes of susceptible snails internalized less erythrocytes per cell and needed 60 min to phagocytose at percentages equivalent to that of resistant hemocytes within 10 min. Preincubation of erythrocytes in resistant plasma significantly increased the subsequent phagocytic activity of susceptible hemocytes, whereas preincubation of erythrocytes in susceptible plasma decreased the phagocytosis level of resistant hemocytes.     

Clearance of bacteria injected into the hemolymph of the ridgeback prawn,Sicyonia ingentis (Crustacea: Decapoda): Role of hematopoietic tissue

In an earlier investigation, radiolabelled bacteria injected into the hemolymph of the shrimp Sicyonia ingentis were cleared rapidly from circulation. Most of the bacteria were localized in the gills, followed by other organs including the heart, abdominal musculature, and hematopoietic nodules (HPN). We determined the organ-specific effectiveness of bacterial clearance and found the HPN to be the most effective on a per gram basis. Light and electron microscopy were used to determine the mechanism of clearance in the HPN. The HPN are readily permeable to individual bacteria, which then are recognized and phagocytosed exclusively by small granule hemocytes. Within the first hour, the bacteria are degraded, leaving only whorls of membrane in the phagocytic vacuoles. Subsequently, the hemocytes that ingested bacteria lyse, as has been observed in vitro. These observations support earlier suggestions that hemocytes in the HPN are functionally mature and held in reserve until they are released into circulation. © 1996 Wiley-Liss, Inc.     

Schistosoma mansoni modulation of phagocytosis in Biomphalaria glabrata

Both short-term (3 hr) exposure of Biomphalaria glabrata snails (M-line and 13-16-R1) to Schistosoma mansoni (PR1) miracidia and in vitro incubation of parasite sporocysts with host hemolymph components altered host phagocytic ability. Hemocytes obtained from susceptible (M-line) snails that had been exposed to parasite miracidia for 3 hr showed reduced levels of phagocytosis of yeast cells in vitro compared to hemocytes from unexposed individuals. Incubation of whole hemolymph with sporocysts in vitro also reduced yeast phagocytosis in this susceptible strain. In contrast, resistant (13-16-R1) hemocytes showed increased levels of yeast phagocytosis after in vitro incubation with the parasite, and the opsonic properties of 13-16-R1 plasma were greater after exposure of snails to miracidia. These strain-specific effects of S. mansoni on host hemocyte phagocytosis and plasma opsonization were seen only when both plasma and hemocytes were present at the time of exposure to the parasite.     

Changes of gill and hemocyte-related bio-indicators during long term maintenance of the vent mussel Bathymodiolus azoricus held in aquaria at atmospheric pressure

The deep-sea hydrothermal vent mussel Bathymodiolus azoricus has been the subject of several studies aimed at understanding the physiological adaptations that vent animals have developed in order to cope with the particular physical and chemical conditions of hydrothermal environments. In spite of reports describing successful procedures to maintain vent mussels under laboratory conditions at atmospheric pressure, few studies have described the mussel's physiological state after a long period in aquaria. In the present study, we investigate changes in mucocytes and hemocytes in B. azoricus over the course of several months after deep-sea retrieval. The visualization of granules of mucopolysaccharide or glycoprotein was made possible through their inherent auto-fluorescent property and the Alcian blue-Periodic Acid Schiff staining method. The density and distribution of droplets of mucus-like granules was observed at the ventral end of lamellae during acclimatization period. The mucus-like granules were greatly reduced after 3 months and nearly absent after 6 months of aquarium conditions. Additionally, we examined the depletion of endosymbiont bacteria from gill tissues, which typically occurs within a few weeks in sea water under laboratory conditions. The physiological state of B. azoricus after 6 months of acclimatization was also examined by means of phagocytosis assays using hemocytes. Hemocytes from mussels held in aquaria up to 6 months were still capable of phagocytosis but to a lesser extent when compared to the number of ingested yeast particles per phagocytic hemocytes from freshly collected vent mussels. We suggest that the changes in gill mucopolysaccharides and hemocyte glycoproteins, the endosymbiont abundance in gill tissues and phagocytosis are useful health criteria to assess long term maintenance of B. azoricus in aquaria. Furthermore, the laboratory set up to which vent mussels were acclimatized is an applicable system to study physiological reactions such as hemocyte immunocompetence even in the absence of the high hydrostatic pressure found at deep-sea vent sites.     

Opsonizing properties of an isolated hemolymph agglutinin and demonstration of lectin-like recognition molecules at the surface of hemocytes fromMytilus edulis

Summary Mytilus hemolymph was found to contain an agglutinin which could be inhibited by mucin. The agglutinin was isolated by affinity chromatography using neuraminidase-treated mucin/Sepharose.In vitro phagocytosis experiments revealed that only about 5% of washed hemocytes phagocytosed yeast cells suspended in a Tris-buffered NaCl-solution, whereas yeast suspended in hemolymph was normally ingested by more than 50% of the hemocytes. This relatively high phagocytic activity was shown to depend on the presence of two serum factors: When purified agglutinin was added to saline-suspended yeast, phagocytosis rates returned to normal, demonstrating opsonizing properties of the purified agglutinin. — On the other hand, addition of Ca⁺⁺-ions to saline caused an increase of the phagocytic activity of hemocytes. This was interpreted to indicate the activation of divalent cation-dependent recognition molecules at the hemocyte surface. The function of these postulated recognition factors was demonstrated by phagocytosis inhibition tests. Their location at the hemocyte membrane became evident by binding of specific antiagglutinin IgG purified by help of an agglutinin/Sepharose column from an antiserum raised againstMytilus serum proteins. Consequently, humoral as well as cell bound agglutinin molecules are involved in the attachment of yeast cells toMytilus hemocytes which subsequently internalize foreign cells.Abbreviations DAB dimethylamino benzaldehyde - PO peroxidase - IgG immunoglobulin G     

Phagocytosis and nodule formation by hemocytes of Manduca sexta larvae following injection of Pseudomonas aeruginosa

The time course of clearance of an injected dose of 10⁶ CFU ml^?1 hemolymph of Pseudomonas aeruginosa ATCC 9027 in larvae of the tobacco hornworm, Manduca sexta, has been examined in detail. The clearance process has been subdivided into three stages during which the rates of reduction in concentration of circulating viable bacteria were clearly different. Contributions of hemocyte reactions to bacterial clearance were examined during stages I and II. During stage I (0–2 hr postinoculation (PI), nodule formation produced a dramatic reduction in circulating bacteria by entrapping over 90% of the injected dose in the first 30 min. Phagocytosis of bacteria by circulating hemocytes and subsequent intracellular digestion contributed significantly to reductions in circulating bacteria during stage II (2–8 hr PI). Viable cells of the virulent P. aeruginosa P11-1 were trapped in nodules as efficiently as the less virulent 9027 during the first 30 min after injection into M. sexta. Bacteria of strain P11-1 were also phagocytosed by hemocytes during stage II, however, phagocytosed bacteria were observed less frequently in P11-1-treated insects and intracellular digestion of these bacteria was only rarely observed. The increased virulence of P11-1 in larvae of M. sexta may be due to less efficient phagocytosis by circulating hemocytes and to insensitivity of this strain to killing reactions in nodules and following phagocytosis.     

Immunophenotyping of Mya arenaria neoplastic hemocytes using propidium iodide and a specific monoclonal antibody by flow cytometry

Disseminated neoplasia (DN) is a disorder referred to as hemic neoplasia (HN) in the soft-shell clam Mya arenaria. Traditionally, diagnosis is performed by hematocytology or histology. The intensity of the disease is generally given as the percentage of transformed neoplastic cells out of total number of hemocytes. Flow cytometry techniques have found a field of application in diagnosis of HN with analysis of ploidy. Hemocytes of the soft-shell clams with HN display tetraploid DNA content, as shown by propidium iodide staining. This feature makes difficult HN diagnosis in the soft-shell clam, especially for early stages of the condition, since the percentage of normal circulating cells undergoing mitosis, which also are tetraploid, remains unknown in molluscs. Use of specific monoclonal antibodies in a flow cytometry assay was foreseen as a way to overcome the difficulty. The purpose of this study was to develop a double staining protocol using propidium iodide for hemocyte cycle analysis and the MAb 1E10 for staining of HN cells. Our results showed a correlation between tetraploid and MAb 1E10-stained hemocytes in a single clam with moderate HN. This protocol offers some potential for further investigation of this cell disorder. However, a validation step will be necessary to confirm our preliminary results.     

Lipopolysaccharide-binding protein of Bombyx mori participates in a hemocyte-mediated defense reaction against gram-negative bacteria

BmLBP is a lipopolysaccharide-binding protein in B. mori and participates in bacterial clearance in vivo. Here, we investigated the function of BmLBP more specifically. More than 90% of injected gram-negative rough strains to which BmLBP binds were removed from the plasma within 30 min post-injection, whereas it required 8h for the clearance of smooth strains to which BmLBP does not bind. Observation of the hemocoel after the injection of Escherichia coli rough strain showed that melanized nodules were formed at 30 min post-injection when the clearance of injected E. coli cells had occurred. Fluorescence microscope observation revealed that E. coli cells were actually trapped in the nodules formed in vivo. Furthermore, plasma pre-treated E. coli rough cells (BmLBP bound) added to hemocytes isolated in vitro caused vigorous hemocyte aggregations with the bacteria, while plasma pre-treated smooth cells did not. The formation of aggregates was inhibited by anti-BmLBP serum pre-treatment, suggesting that BmLBP causes the clearance of bacteria by promoting hemocyte nodule formation.     

Parasitism by Cotesia plutellae alters the hemocyte population and immunological function of the diamondback moth, Plutella xylostella

Cotesia plutellae, a solitary endoparasitoid wasp, parasitizes the diamondback moth, Plutella xylostella, and induces host immunosuppression and lethality in the late larval stage. This study focused on changes of cellular immunity in the parasitized P. xylostella in terms of hemocyte composition and cellular functions. In third and fourth instar larvae of nonparasitized P. xylostella, granular cells represented the main hemocyte type (60-70%) and plasmatocytes were also present at around 15% among the total hemocytes. Following parasitization by C. plutellae, the relative proportions of these two major hemocytes changed very little, but the total hemocyte counts exhibited a significant reduction. Functionally, the granular cells played a significant role in phagocytosis based on a fluorescence assay using fluorecein isothiocyanate-labeled bacteria. The phagocytic activity of the granular cells occurred as early as 5 min after incubation with the bacteria, and increased during the first 40 min of incubation. The parasitism by C. plutellae significantly inhibited phagocytosis of the granular cells. Plasmatocytes also exhibited minor phagocytic activity. Moreover, plasmatocyte phagocytosis was not inhibited by parasitism. On the other hand, hemocyte-spreading behavior in response to pathogen infection was significant only for plasmatocytes, which exhibited a characteristic spindle shape upon infection. A significant spreading of the plasmatocytes was found as early as 5 min after pathogen incubation and their ratio increased during the first 40 min.An insect cytokine, plasmatocyte-spreading peptide 1 (PSP1) from Pseudoplusia includens, was highly active in inducing plasmatocyte-spreading behavior of P. xylostella in a dose-dependent manner. P. xylostella parasitized by C. plutella was significantly inhibited in plasmatocyte-spreading in response to an active dose of PSP1. An in vivo encapsulation assay showed that the parasitized P. xylostella could not effectively form the hemocyte capsules around injected agarose beads. This research demonstrates that the parasitism of C. plutellae adversely affects the total hemocyte populations in number and function, which would contribute to host immunosuppression.     

An entomopathogenic bacterium, Xenorhabdus nematophila, inhibits hemocyte phagocytosis of Spodoptera exigua by inhibiting phospholipase A(2)

Phagocytosis is a hemocytic behavior against bacterial infection. An entomopathogenic bacterium, Xenorhabdus nematophila, inhibits immune responses of target insects and causes hemolymph septicemia. This study analyzed how X. nematophila could inhibit phagocytosis to increase its pathogenicity. Granular cells and plasmatocytes were the main phagocytic hemocytes of Spodoptera exigua determined by observing fluorescence-labeled bacteria in the cytosol. X. nematophila significantly inhibited phagocytosis of both hemocytes, while heat-killed X. nematophila lost its inhibitory potency. However, co-injection of X. nematophila with arachidonic acid did not show any significant inhibition of hemocyte phagocytosis. In fact, hemocytes of S. exigua infected with X. nematophila showed significant reduction in phospholipase A(2) (PLA(2)) activity. Dexamethasone, a specific PLA(2) inhibitor, significantly inhibited phagocytosis of both cell types. However, the inhibitory effect of dexamethasone was recovered by addition of arachidonic acid. Incubation of hemocytes with benzylideneacetone, a metabolite of X. nematophila, inhibited phagocytosis in a dose-dependent manner. These results suggest that X. nematophila produces and secretes PLA(2) inhibitor(s), which in turn inhibit the phagocytic response of hemocytes.     

Phagocytic activity of hemocytes of M-line Biomphalaria glabrata snails: effect of exposure to the trematode Echinostoma paraensei

The phagocytic activity of hemocytes from 6-8-mm M-line Biomphalaria glabrata snails was studied in an in vitro assay using glutaraldehyde-fixed sheep erythrocytes (SRBC) as target cells. For individual snails, the percentage of hemocytes ingesting SRBC during a 1-hr interval, termed the phagocytic activity index (PAI), was determined. Hemocytes from snails infected for 1 day with Echinostoma paraensei had a slightly elevated PAI, but at both 8 and 30 days postexposure (DPE), hemocytes from infected snails had a significantly lower PAI than controls. Hemocytes taken from snails at 8 DPE also had a low PAI using rabbit erythrocytes and yeast as target cells. The low PAI at 8 DPE is attributed to the presence of large numbers of poorly spreading hemocytes with low phagocytic activity. Hemocytes from snails with 30-day infections were well spread but nonetheless had a low PAI. The presence of plasma from 8-day infected snails did not alter the PAI of hemocytes from control snails, nor was the PAI of hemocytes from infected snails changed by plasma from control snails. SRBC preincubated for 60 min in plasma from various groups of M-line snails did not elicit an increase in PAI when presented to hemocytes from control snails; in some cases, as with plasma from 6-8-mm control snails, such preincubation significantly reduced the PAI below levels obtained using SRBC preincubated in culture medium. As compared to hemocytes from snails with normally developing, 8-day-old intraventricular sporocysts (IS), hemocytes from snails exposed to infection but subsequently lacking IS had a significantly higher PAI.(ABSTRACT TRUNCATED AT 250 WORDS)     

Alternate pathogenesis of systemic neoplasia in the bivalve mollusc Mytilus.

The proliferative disease systemic neoplasia, also termed hemic neoplasia or disseminated sarcoma, was studied in four Puget Sound, Washington populations of the bay mussel (Mytilus sp.). Using flow cytometric measurement of DAPI-stained cells withdrawn from the hemolymph, DNA content frequency histograms were generated for 73 individuals affected by the disease. The cells manifesting systemic neoplasia were found to exist as either of two separate types, characterized by G0G1 phase nuclear DNA contents of either approximately 4.9 x haploid (pentaploid form) or approximately 3.8 x haploid (tetraploid form). The two disease forms were found to coexist in all four mussel populations sampled, with overall relative prevalences of 66% pentaploid form, 29% tetraploid form, and 5% exhibiting both disease forms simultaneously. These findings represent the first unequivocal demonstration of multiple cell types in a bivalve neoplasia. The two forms appear to represent separate pathogenetic processes rather than sequential stages of a single pathogenesis. Two cell cycling parameters associated with proliferative activity were employed to compare the alternate forms: (i) the percentage of cells assigned to the DNA Synthesis (S) phase of the neoplastic cell cycle, and (ii) the proportion of neoplastic cell mitotic figures in hemocytological preparations. Mean values for both parameters were significantly higher for mussels with the tetraploid form of the disease, suggesting a higher rate of proliferation relative to the pentaploid form. Qualitatively, cells of the tetraploid form contained slightly lower nuclear and cytoplasmic volumes compared to those of the pentaploid form. An observed wide variation in neoplastic cell nuclear size within either disease form may reflect the distribution of cells in the G0G1, S, and G2M phases of the cell cycle. Potential etiologic relationships between the two forms are discussed.     

Opsonic involvement in phagocytosis by mollusk hemocytes.

Macrophages from the gastrophod mollusk Otala lactea are capable of in vitro recognition and phagocytosis of foreign particles such as yeast, mammalian erythrocytes, and bacteria. The degree of intensity of the phagocytic response, in certain instances, is governed by the surface characteristics of the particle in question as well as by the presence of opsonic factors.Hemagglutinins have been implicated as opsonins in certain invertebrates, including mollusks. Otala lacks serum lectins; however, its hemolymph stimulates phagocytosis of formalized yeast but not erythrocytes and bacteria. Hemagglutinin-containing extracts of Otala albumin gland were shown to opsonize formalized red cells. The rate of ingestion of the bacteria used in this study by Otala hemocytes was variable and was not influenced by the presence of hemolymph in the medium.     

Rapid phagocytosis and melanization of bacteria and Plasmodium sporozoites by hemocytes of the mosquito Aedes aegypti

Mosquitoes are vectors of many deadly and debilitating pathogens. In the current study, we used light and electron microscopies to study the immune response of Aedes aegypti hemocytes to bacterial inoculations, Plasmodium gallinaceum natural infections, and latex bead injections. After challenge, mosquitoes mounted strong phagocytic and melanization responses. Granulocytes phagocytosed bacteria singly or pooled them inside large membrane-delimited vesicles. Phagocytosis of bacteria, Plasmodium sporozoites, and latex beads was extensive; we estimated that individual granulocytes have the capacity to phagocytose hundreds of bacteria and thousands of latex particles. Oenocytoids were also seen to internalize bacteria and latex particles, although infrequently and with low capacity. Besides phagocytosis, mosquitoes cleared bacteria and sporozoites by melanization. Interestingly, the immune response toward 2 species of bacteria was different; most Escherichia coli were phagocytosed, but most Micrococcus luteus were melanized. Similar to E. coli, most Plasmodium sporozoites were phagocytosed. The immune response was rapid; phagocytosis and melanization of bacteria began as early as 5 min after inoculation. The magnitude and speed of the cellular response suggest that hemocytes, acting in concert with the humoral immune response, are the main force driving the battle against foreign invaders.     

Investigations of phagocytosis concerning the immunological defence mechanism of Mytilus edulis using a sublethal luminescent bacterial assay (Photobacterium phosphoreum).

1. A simple method for the determination of phagocytosis activity using mussel hemocytes by measuring the bioluminescence is presented. 2. The immunological defence activity based on phagocytosis is measured and quantified by a luminescent bacterial assay with Photobacterium phosphoreum. 3. The measuring system allows us to establish the stress of the immunological defence mechanism of organisms exposed to chemicals and polluted rivers or sewage. Results with reference substances and the phagocytosis indices of exposed mussels from Norwegian aquaculture plants compared to those of mussels from the German Wadden Sea are given as examples.     

Quantitative assessment of phagocytic activity of hemocytes in the prawn, Penaeus merguiensis, by flow cytometric analysis

BACKGROUND: The blood cells of crustaceans are involved in phagocytosis of invading microorganisms, contributing to their defense mechanisms. In this study, phagocytic activity of hemocytes of the prawn, Penaeus merguiensis, was quantitated by means of flow cytometric analysis. METHOD: This study was done in vitro. Hemolymph, which was extracted from prawns, was mixed with an equal volume of anticoagulant. Heat-killed Escherichia coli prestained with propidium iodide (PI) was then added. Hemocytes were fixed at various time intervals for flow cytometric analysis. This study was supplemented with electron micrographs using transmission electron microscopy (TEM), which showed three populations of hemocytes. RESULTS: It was observed that those hemocytes that were more active engulfed and digested bacteria readily, thus having higher red fluorescence intensity. The phagocytic activity was expressed as fluorescence unit or engulfed E. coli number per hemocyte. CONCLUSIONS: With this approach, the phagocytic and cellular activity of individual hemocyte populations could be studied quantitatively.     

Opsonin-independent and -dependent Phagocytosis in the Ascidian Halocynthia roretzi: Galactose-specific Lectin and Complement C3 Function as Target-dependent Opsonins

To clarify the molecular mechanisms of phagocytosis, we have been preparing monoclonal antibodies that inhibit phagocytosis by the hemocytes of the ascidian Halocynthia roretzi. A monoclonal antibody, RA5, inhibited the phagocytosis of non-treated sheep red blood cells (SRBCs) and yeast cells. It was demonstrated that the phagocytosis by the hemocytes was enhanced by pretreatment of target cells, SRBCs or yeast cells, with H. roretzi plasma. However, the RA5 antibody was unable to inhibit the phagocytosis of plasma-treated target cells. These results strongly suggest that the molecule recognized with the RA5 antibody is involved in the opsonin-independent phagocytosis. Western blot analysis showed that this antibody recognized a 200 kDa protein in H. roretzi hemocytes. On the other hand, flow cytometry analyses showed that a galactose-specific lectin (Gal-lectin) and complement C3 (AsC3), present in H. roretzi plasma, can bind to SRBCs and yeast cells, respectively, to enhance the phagocytosis of the respective target cells. Thus, H. roretzi hemocytes undergo opsonin-independent and -dependent phagocytosis, and Gal-lectin and AsC3 both function in the opsonin-dependent phagocytosis.     

Phagocytosis of the protozoan parasite, Marteilia sydneyi, by Sydney rock oyster (Saccostrea glomerata) hemocytes

QX disease is a fatal disease in Sydney rock oysters caused by the protozoan parasite Marteilia sydneyi. The current study investigates the phagocytosis of M. sydneyi by Sydney rock oyster hemocytes. It also compares the in vitro phagocytic activities of hemocytes from oysters bred for QX disease resistance (QXR) with those of wild-type oysters. After ingestion of M. sydneyi, hemocyte granules fused with phagosome membranes and the pH of phagosomes decreased. Significantly (p = <0.05) more phagosomes in QXR hemocytes showed obvious changes in pH within 40 min of phagocytosis, when compared with wild-type hemocytes. Phenoloxidase deposition was also evident in phagosomes after in vitro phagocytosis. Most importantly, ingested and melanised M. sydneyi were detected in vivo among hemocytes from infected oysters. Overall, the data suggest that Sydney rock oyster hemocytes can recognise and phagocytose M. sydneyi, and that resistance against QX disease may be associated with enhanced phagolysosomal activity in QXR oysters.