Exocytosis and uptake of bacteria by isolated haemocyte populations of two crustaceans: evidence for cellular co-operation in the defence reactions of arthropods

Summary The role of exocytosis in the cellular defence reactions of arthropods was investigated using in vitro cultures of isolated haemocytes (blood cells) from the freshwater crayfish Pacifastacus leniusculus, and the shore crab Carcinus maenas. In both species, activated lysates of those cell types that contain the prophenoloxidase activating system (granular cells of crab and crayfish and semigranular cells of crayfish) were found to induce degranulation (exocytosis) of semigranular and granular cells. A cell lysate, in which the prophenoloxidase system was kept inactive, did not have this effect. Limited degranulation of granular cells of crab was also induced by lipopolysaccharides as has earlier been shown for crayfish semigranular cells. The phagocytic capability of semigranular cells from crayfish was lost after exocytosis induced by the Ca²⁺ ionophore A23187, and under no conditions were the granular cells of crabs or crayfish seen to ingest bacteria in vitro. An opsonic function for the attaching proteins of a 1,3-glucan-activated haemocyte lysate was demonstrated using the phagocytic hyaline cells from crabs. Phenoloxidase appeared to lack opsonic properties.We suggest that, in crustaceans, opsonization takes place through hierarchically stimulated exocytotic release, and biochemical activation of the prophenoloxidase activating system: first from lipopolysaccharide-sensitive cells (semigranular cells of crayfish or granular cells of crabs) and then from granular cells, triggered by the initially released and activated prophenoloxidase system. Finally, sticky proteins of the activated prophenoloxidase system coat the invader, rendering it susceptible to the phagocytes (hyaline cells in both crab and crayfish and, to a lesser extent, semigranular cells of crayfish). These processes would, together, constitute a cellular communication pathway not previously demonstrated for invertebrates.Abbreviations DMSO dimethyl sulfoxide - L-DOPA L-dihydroxy-phenylalanine - GLS granular cell lysate supernatant - HLS haemocyte lysate supernatant - HyLS hyaline cell lysate supernatant - LPS lipopolysaccharide - proPO prophenoloxidase - SGLS semigranular cell lysate supernatant - SITS 4-acetamido-4-isothiocyanatostilbene-2,2-disulfonic acid disodium salt     

Exocytosis of the prophenoloxidase activating system from crayfish haemocytes

Summary Lipopolysaccharides (LPS) and the -1,3-glucan laminarin G, both of which specifically activate the prophenoloxidase (proPO) activating system of crayfish haemocyte lysate, were found to induce degranulation (exocytosis) and subsequent lysis in vitro of monolayers of semigranular haemocytes from the crayfish,Pacifastacus leniusculus, (Table 1, Fig. 1 b), whereas the granular cells were unaffected (Fig. 1 c).Exocytosis of isolated semigranular or granular cells in vitro could also be evoked by the Ca² ionophore A23187 (Table 2, Fig. 1 d). In this case, the whole proPO system was released from the cellular vesicles in its inactive form, since the secreted material contained protease and prophenoloxidase as inactive proenzymes, which could be activated if LPS or -1,3-glucans were added (Table 3). The anion channel blocker SITS, which inhibits exocytosis in several systems, prevented degranulation triggered by -1,3-glucan, LPS, or ionophore.It is concluded that, in arthropods, LPS serve as an indicator of Gram negative bacteria and -1,3-glucan as an indicator of fungi. These non-self molecules elicit both the exocytotic release of the proPO system from the semigranular cells and the subsequent biochemical activation of this system.Abbreviations CFS crayfish saline - DMSO dimethyl sulfoxide - LDH lactate dehydrogenase - LPS lipopolysaccharide - proPO prophenoloxidase - SITS 4-acetamido-4-isothiocyanato-stilbene-2,2-disulfonic acid, disodium salt     

Isolation and purification of a cell adhesion factor from crayfish blood cells

Isolated granular haemocytes (blood cells) from the crayfish Pacifastacus leniusculus attached and spread in vitro on coverslips coated with a lysate of crayfish haemocytes. No cell adhesion activity was detected in crayfish plasma. The cell adhesion activity was only present in haemocyte lysates in which the prophenoloxidase (proPO) activating system (Soderhall and Smith, 1986a, b) had been activated; either by lipopolysaccharide (LPS), the beta-1,3-glucan laminarin, or by preparing the lysate in 5 mM Ca2+. Both lysates of granular or of semigranular haemocytes could mediate adhesion. After A23187-induced exocytosis of the granular cells, cell adhesion activity could be generated in the secreted material if it was incubated with laminarin. The factor responsible for cell adhesion was isolated from an active haemocyte lysate and purified by ammonium sulfate precipitation, cation exchange chromatography and Con A-Sepharose; it had a molecular mass of approximately 76 kD on an SDS-polyacrylamide gel. An antibody to this 76-kD band inhibited cell adhesion. Ca2+ was necessary in the medium for the cells to adhere to the adhesion factor. With cyanide or azide, the cells attached but failed to spread. It is suggested that in vivo the cell adhesion factor is stored in the secretory granules of the semigranular and the granular cells in a putative inactive pro-form, which can be released during exocytosis and, in the presence of beta- 1,3-glucans or LPS, be activated outside the cells to mediate cell attachment and spreading, processes of essential importance in arthropod host defense.     

A cell adhesion factor from crayfish haemocytes has degranulating activity towards crayfish granular cells

A factor able to mediate cell adhesion of semigranular and granular haemocytes of the crayfish Pacifastacus leniusculus was recently purified from crayfish haemocyte lysate (Johansson and Söderhäll, J. Cell Biol.106, 1795–1803, 1988). It is a protein with a mass of 76 kDa, and its activity seems to be generated concomitantly with the activation of the prophenoloxidase (proPO) activating system. In this paper, we present evidence that this same protein is also responsible for the previously reported degranulating activity of a crayfish haemocyte lysate, in which the proPO system has been activated. First, the 76 kDa band in SDS-polyacrylamide electrophoresis seems to be a single protein, since in isoelectric focusing the purified cell adhesion factor fraction migrated as one band with an isoelectric point of 7.2. Second, this fraction was also able to degranulate crayfish granular cells in vitro, and third, antibodies to this 76 kDa protein, which are known to block cell adhesion, could also inhibit degranulation in vitro.     

Flow cytometric analysis of crayfish haemocytes activated by lipopolysaccharides

Lipopolysaccharides (LPS) from Gram-negative bacteria are strong stimulators of white river crayfish, Procambarus zonangulus, haemocytes in vitro. Following haemocyte treatment with LPS and with LPS from rough mutant R5 (LPS Rc) from Salmonella minnesota, flow cytometric analysis revealed a conspicuous and reproducible decrease in cell size as compared to control haemocytes. These LPS molecules also caused a reduction in haemocyte viability as assessed by flow cytometry with the fluorescent dyes calcein-AM and ethidium homodimer. The onset of cell size reduction was gradual and occurred prior to cell death. Haemocytes treated with LPS from S. minnesota without the Lipid A moiety (detoxified LPS) decreased in size without a reduction of viability. The action of LPS on crayfish haemocytes appeared to be related to the activation of the prophenoloxidase system because phenoloxidase (PO)-specific activity in the supernatants from control and detoxified LPS-treated cells was significantly lower than that from LPS and LPS-Rc treated cells (P相似文献   

The role of prophenoloxidase activation in non-self recognition and phagocytosis by insect blood cells

Experiments indicate that the prophenoloxidase activating system, which is responsible for melanin production, is also involved in immunorecognition in insects. Using haemocyte monolayer preparations of Blaberus craniifer, Galleria mellonella and Leucophae maderae, it was shown that laminarin, a β 1,3-glucan extracted from fungal cell walls and an activator of the prophenoloxidase system, enhanced the phagocytosis of test bacteria.Scanning electron microscopy of haemocyte monolayers showed that incubation of test bacteria with laminarin significantly increased the number of microorganisms attached to both the plasmatocytes and the granular cells. Furthermore with the granular cells, these bacteria became entrapped in an amorphous matrix. This material probably consists of the “sticky” proteins previously reported to be produced by crustacean haemocytes following prophenoloxidase activation. Pretreatment of haemocytes with laminarin abolished the stimulatory effect on ingestion, indicating that these “sticky” proteins are opsonic, since they would have been discharged from the haemocytes onto the glass monolayer leaving few molecules available for subsequent coating of the test particles.Preliminary biochemical studies on the G. mellonella prophenoloxidase system demonstrated that it was activated by trypsin, laminarin and laminarin G, a highly purified β 1,3-glucan, but not by dextran. Serine protease activities were also enhanced by adding laminarin to a haemocyte lysate supernatant, suggesting that the stimulatory mechanism may involve the proteolytic activity of such enzymes.     

Cresolase, catecholase and laccase activities in haemocytes of the red swamp crayfish

Phenoloxidase activity in crayfish haemocyte lysates and extracts of haemocyte membranes were studied using native PAGE and SDS-PAGE gels and staining for cresolase, catecholase and laccase activities. The activation of the proenzyme, prophenoloxidase to phenoloxidase, in native PAGE was demonstrated following exposure to SDS. By staining samples separated in SDS-PAGE followed by renaturation, a high molecular mass phenoloxidase activity was identified in both the soluble and membrane fractions of haemocyte preparations. The membrane-associated activity appeared at only relatively high molecular mass (> 300 kDa), and could easily be eluted from membranes using detergents or NaCl. Further, this membrane-associated activity has a catecholase activity but not the cresolase activity seen in the soluble preparations. In addition, several other phenoloxidase enzymes were identified with different relative mobilities (250, 80, 72 and 10 kDa). Crayfish haemocytes also contained laccase activity, thought to be restricted to cuticle sclerotisation in the integument. Laccase activity in haemocytes might aid in the formation of capsule used to contain pathogens.     

The cytotoxic reaction of hemocytes from the freshwater crayfish, Astacus astacus

Crayfish hemocytes displayed cytotoxic capacity towards all tested mammalian tumor and nontumor cell lines. The ratio required for the cytotoxic action of effector cells to target cells was at least 1:1. The lysis of the target cells required a minimum of 1 hr to become detected. After separation and isolation of the hemocyte populations of crayfish, the semigranular and granular cells retained their cytotoxic capacity. These cells contain the prophenoloxidase activating (proPO) system, a complement-like pathway, which in an activated form lyses semigranular cells in vitro, but failed to kill the tested target cells.     

White spot syndrome virus (WSSV) interaction with crayfish haemocytes

WSSV particles were detected in separated granular cells (GCs) and semigranular cells (SGCs) by in situ hybridisation from WSSV-infected crayfish and the prevalence of WSSV-infected GCs was 5%, whereas it was 22% in SGCs. This indicates that SGCs are more susceptible to WSSV and that this virus replicated more rapidly in SGCs than in GCs and as a result the number of SGCs gradually decreased from the blood circulation. The effect of haemocyte lysate supernatant (HLS), containing the degranulation factor (peroxinectin), phorbol 12-myristate 13-acetate (PMA), the Ca(2+) ionophore A23187 on GCs from WSSV-infected and sham-injected crayfish was studied. The results showed that the percentage of degranulated GCs of WSSV-infected crayfish treated with HLS or PMA was significantly lower than that in the control, whereas no significant difference was observed when treated with the Ca(2+) ionophore. It was previously shown that peroxinectin and PMA have a degranulation effect via intracellular signalling involving protein kinase C (PKC), whereas the Ca(2+) ionophore uses an alternative pathway. HLS treatment of GCs and SGCs from WSSV-infected crayfish results in three different morphological types: non-spread, spread and degranulated cells. The non-spread cell group from both GCs and SGCs after treatment with HLS had more WSSV positive cells than degranulated cells, when detected by in situ hybridisation. Taken together, it is reasonable to speculate that the PKC pathway might be affected during WSSV infection. Another interesting phenomenon was that GCs from non-infected crayfish exhibited melanisation, when incubated in L-15 medium, while no melanisation was found in GCs of WSSV-infected crayfish. However, the phenoloxidase activities of both sham- and WSSV-injected crayfish in HLS were the same as well as proPO expression as detected by RT-PCR. This suggests that the WSSV inhibits the proPO system upstream of phenoloxidase or simply consumes the native substrate for the enzyme so that no activity is shown. The percentage of apoptotic haemocytes in WSSV-infected crayfish was very low, but it was significantly higher than that in the sham-injected crayfish on day 3 or 5 post-infection. The TEM observation in haematopoietic cells (hpt cells) suggests that WSSV infect specific cell types in haematopoietic tissue and non-granular hpt cells seem more favourable to WSSV infection.     

The effect of endogeneous proteinase inhibitors on the prophenoloxidase activating enzyme,a serine proteinase from crayfish haemocytes

Three proteinase inhibitors have so far been isolated and purified from crayfish haemolymph. One of these, isolated from crayfish plasma, namely a trypsin inhibitor with a molecular mass of 155 kDa was found to inhibit a serine proteinase, ppA, which is involved in the activation of prophenoloxidase, and is localized in the haemocytes. Another high molecular mass proteinase inhibitor, an α₂-macroglobulin from crayfish plasma, which is a dimer of 190 kDa-subunits, was only inhibitory towards ppA to a lesser extent. A 23 kDa subtilisin inhibitor, purified from haemocytes, did not have any effect on the serine proteinase.We suggest that mainly the trypsin inhibitor, but to some extent also the α₂-macroglobulin, are important in the regulation of the prophenoloxidase activating cascade, as they both inhibit ppA, which in its active form has been shown to mediate prophenoloxidase activation.     

棉铃虫血淋巴酚氧化酶活性的微量测定

昆虫血淋巴黑化的形成由激活酚氧化酶原的级联系统所引发 ,酚氧化酶在昆虫体液免疫中起着重要作用。用抗凝剂从棉铃虫血淋巴中分离获得了血浆及完整的血细胞 ,以L DOPA为底物 ,牛胰蛋白酶为激活剂 ,测定了血浆及血细胞裂解液中酚氧化酶及酚氧化酶原的活性。结果表明 ,血浆及血细胞中两者都有一定量的分布。这一昆虫血淋巴酚氧化酶的微量测定方法 ,所需样品量少 ,耗时短 ,简便易行。     

Experimental infection of white spot syndrome virus in freshwater crayfish Pacifastacus leniusculus.

The signal freshwater crayfish Pacifastacus leniusculus was found to be susceptible to infection with white spot syndrome virus (WSSV). Histopathological observations of various tissues of virus-injected crayfish showed similar symptoms to those from WSSV-infected penaeid shrimp, but no appearance of white spots on the cuticle or reddish body colour were observed, although these are the prominent gross signs of white spot disease in shrimp. A gene probe for detecting WSSV was developed in order to detect the virus in affected cells and tissues using in situ hybridisation. Strong signals were observed in cells of virus-injected crayfish, but not in control-injected crayfish. The number of granular haemocytes in virus-injected crayfish was significantly higher than in sham-injected and non-injected crayfish from Days 5 to 8 (p < or = 0.05) and Days 3 to 8 (p < 0.01) post-injection, respectively. The proportion of granular haemocytes in virus-injected crayfish was also significantly higher than in sham-injected controls from Days 3 to 8 (p < 0.01). These results indicate that WSSV has a significant effect on the proportion of different haemocyte types in the freshwater crayfish.     

Effect of water temperature on the immune response and infectivity pattern of white spot syndrome virus (WSSV) in freshwater crayfish

The susceptibility of two species of freshwater crayfish, Pacifastacus leniusculus and Astacus astacus, to white spot syndrome virus (WSSV) by intramuscular injection was compared and the results show that both species are susceptible to WSSV. The effect of water temperature on the development of white spot disease in crayfish was also studied. Crayfish were exposed to different temperatures after WSSV injection or oral exposure and the mortalities were recorded over a period of 45 days. No mortality was observed when crayfish were held at 4+/-2 degrees C or 12+/-2 degrees C and reached 100% when these crayfish transferred to 22+/-2 degrees C. The mortalities of nearly moribund crayfish at 22+/-2 degrees C with WSSV could be delayed after transfer to temperature below 16 degrees C. These results clearly show that low temperature affects the WSSV pathogenicity in crayfish. Moreover, haemocyte counts, phenoloxidase activity, mRNA levels of prophenoloxidase (proPO) and the lipopolysaccharide and beta-1,3-glucan binding protein (LGBP) in crayfish exposed to various water temperatures were studied. Total haemocyte and granular cell counts of crayfish held at different temperatures were not significantly (P>0.05) different, except for the total haemocyte number at 18 degrees C was significantly (P<0.05) higher than in crayfish at 4 degrees C. The percentage of granular cells in crayfish held at 4 degrees C was the highest compared to crayfish maintained at other temperatures. The phenoloxidase activities in haemocyte lysate supernatant (HLS) of crayfish at all temperature groups remained similar. The amount of proPO-mRNAs in haemocytes was much higher than the amount of LGBP-m RNAs in all the experimental groups. However, there was no change in the level of pro PO-mRNA at the tested temperatures. Interestingly, the level of LGBP-mRNA of crayfish kept at 22 degrees C was much lower than in those held at lower temperatures. Proliferation of the haematopoietic tissues was higher at high temperatures which may support replication of WSSV, and explain the high mortality of crayfish with WSSV infection at high temperature. Based on these studies it is concluded that crayfish might act as a carrier of WSSV at low water temperature and could develop white spot disease if the water temperature is increased.     

Studies on prophenoloxidase and protease activity of Blaberus craniifer haemocytes

Using a citrate-EDTA buffer as an anticoagulant it was possible to isolate intact haemocytes from the insect, Blaberus craniifer, without causing extensive degranulation and subsequent clotting. A haemocyte lysate from this insect contained prophenoloxidase (proPO), which could be activated by β 1,3-glucans. The activation process was dependent upon Ca²⁺ ions and seemed to occur by a limited proteolysis, since several serine protease inhibitors such as soybean trypsin inhibitor, benzamidine and $\text{p-}\text{nitrophenyl}\text{-p′-}\text{guanidobenzoate}$ blocked convertion of proPO to the active enzyme. Treatment of proPO with urea or heat also caused proPO activation but probably without the intervention of serine proteases, since the protease inhibitors used failed to block the activation. Within the haemocyte lysate, several endopeptidases were present, which were enhanced in activity by prior treatment with β 1,3-glucans. These endopeptidases were inhibited in activity when the haemocyte lysate was incubated with benzamidine prior to the addition of β 1,3-glucan. This provides further indications that the activation of proPO involves a limited proteolytic attack. The active phenoloxidase enzyme became strongly bound to foreign surfaces and this phenomenon may assist in providing opsonic properties for the proPO cascade.     

The 76 kD cell-adhesion factor from crayfish haemocytes promotes encapsulation in vitro

Summary Semigranular cells from the crayfish, Pacifastacus leniusculus, were separated by Percoll gradient centrifugation and were used to study the encapsulation of foreign particles. The semigranular cells were found strongly to encapsulate glass beads coated with haemocyte lysate in which the prophenoloxidase-activating system had been activated with laminarin or with a low concentration of calcium ions. The granular cells only weakly encapsulated these particles. The encapsulationpromoting factor was purified from haemocyte lysates and found to be a 76 kD protein which was recognized by an antiserum to the previously described 76 kD cell-adhesion factor. After the last step in purification (Con A-Sepharose chromatography), the flowthrough consisted of several proteins, which had some, but less, encapsulation-promoting activity and contained a 30 kD band that was also recognized by the antiserum to the 76 kD cell-adhesion factor. If the haemocyte lysate prepared in low [Ca²⁺] was incubated with a -1,3-glucan prior to purification, no 76 kD protein could be isolated but only a 30 kD protein. The 30 kD protein thus seems to be a degradation product of the 76 kD cell-adhesion factor. We conclude that the 76 kD protein which is released from degranulating haemocytes, and to a lesser extent its 30 kD fragment, can promote encapsulation. Phenoloxidase did not have any encapsulation-promoting activity.     

The role of the haematopoietic tissue in haemocyte production and maturation in the black tiger shrimp (Penaeus monodon)

The haematopoietic tissue (HPT) of the black tiger shrimp (Penaeus monodon) is located in different areas in the cephalothorax, mainly at the dorsal side of the stomach and in the onset of the maxillipeds and, to a lesser extent, towards the antennal gland. In young and in experimentally stimulated animals, the HPT is expanded in relatively larger and more numerous lobules throughout the cephalothorax. Four cell types could be identified in the HPT by electron microscopy. The type 1 cells are the presumed precursor cells that give rise to a large- and a small-granular young haemocyte, denominated as the type 2 and type 3 cells, respectively. A gradient of maturation from the type 1 towards the type 2 or 3 cells could frequently be observed. The presumed precursor cells are located towards the exterior of the lobules and maturing young haemocytes towards the inner part, where they can be released into the haemal lacunae. The type 4 cells show typical features of interstitial cells. Different stimulation experiments were carried out and various techniques were used to study the HPT in relation to the (circulating) haemocytes. The majority of the cells in the HPT are able to proliferate and proliferation can be increased significantly after the injection of saline and, to a much higher extent, after LPS injection. The circulating haemocytes of crustaceans are generally divided into hyaline (H), semigranular (SG) or granular (G) cells, of which large- and small-granular variants of each of these were suggested in the present study. Even after stimulation in this study, the circulating haemocytes scarcely divide. The high variations that were found in the total haemocyte count in the stimulation experiments were not accompanied by significant differences in differential haemocyte count and, therefore, appeared to be a less useful indicator of stress or health in P. monodon. Light and electron microscopical observations support the regulation of the populations of the different haemocyte types in the circulation by (stored) haemocytes from the connective tissue. In conclusion, according to morphological and immuno-chemical criteria, it is proposed in the present study to divide the haemocytes into a large-and a small-granular developmental series. After extensive morphological observations, it is suggested that the hyaline cells are the young and immature haemocytes of both the large- and small-granular cell line that are produced in the HPT, and can be released into the haemolymph. Indications were found that the granular cells, of at least the large-granular cell line, mature and accumulate in the connective tissue and are easily released into the haemolymph. Combining the results of the present study with literature, this proposed model for haemocyte proliferation, maturation and reaction will be discussed.