Andrew F. Rowley

Prophenoloxidase Activation: Nonself Recognition and Cell Cooperation in Insect Immunity

The mechanism of nonself recognition by the immune system of insects is unknown. In this report the activation of the prophenoloxidase system in the wax moth Galleria mellonella by a microbial product is shown to enhance the recognition of nonself material. These results explain previous observations of the interaction of two different blood cell populations in the cellular defense reactions of insects.

Invertebrate Immune Systems–Specific, Quasi-Specific, or Nonspecific?

Until recently, it was widely accepted that invertebrates fail to show a high degree of specificity and memory in their immune strategies. Recent reports have challenged this view such that our understanding of the capabilities of the invertebrate immune systems needs to be reassessed. This account critically reviews the available evidence that suggests the existence of a high degree of memory and specificity in some invertebrates and seeks mechanistic explanations of such observations. It is postulated that elevated levels of phagocytosis may be a partial explanation for this phenomenon.

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

Abstract 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.

Prostaglandins in non-insectan invertebrates: recent insights and unsolved problems

SUMMARY Prostaglandins (PG) are oxygenated derivatives of C20 polyunsaturated fatty acids including arachidonic and eicosapentaenoic acids. In mammals, these compounds have been shown to play key roles in haemostasis, sleep-wake regulation, smooth muscle tone, and vaso-, temperature and immune regulation. In invertebrates, PGs have been reported to perform similar roles and are involved in the control of oogenesis and spermatogenesis, ion transport and defence. Although there is often a detailed understanding of the actions of these compounds in invertebrates such as insects, knowledge of their mechanism of biosynthesis is often lacking. This account provides a critical review of our current knowledge on the structure and modes of biosynthesis of PGs in invertebrates, with particular reference to aquatic invertebrates. It emphasises some of the most recent findings, which suggest that some PGs have been misidentified. Prostaglandins in invertebrates can be categorised into two main types; the classical forms, such as PGE2 and PGD2 that are found in mammals, and novel forms including clavulones, bromo- and iodo-vulones and various PGA2 and PGE2 esters. A significant number of reports of PG identification in invertebrates have relied upon methods such as enzyme immunoassay that do not have the necessary specificity to ensure the validity of the identification. For example, in the barnacle Balanus amphitrite, although there are PG-like compounds that bind to antibodies raised against PGE2, mass spectrometric analysis failed to confirm the presence of this and other classical PGs. Therefore, care should be taken in drawing conclusions about what PGs are formed in invertebrates without employing appropriate analytical methods. Finally, the recent publication of the Ciona genome should facilitate studies on the nature and mode of biosynthesis of PGs in this advanced deuterostomate invertebrate.

Eicosanoids and their role in immune modulation in fish—a brief overview

Abstract Eicosanoids have been demonstrated to play a central role in immune regulation in mammals brought about by their direct effects on cells such as macrophages and lymphocytes or by their indirect effects via cytokines. Studies have shown that fish mononuclear phagocytes, granulocytes and thrombocytes synthesize and release both cyclooxygenase- and lipoxygenase-derived products such as prostaglandin E2, leukotriene B4 and lipoxin A4. Whether lymphocytes have the ability to generate leukotrienes and lipoxins is still unclear but they do appear to have 12-lipoxygenase activity that leads to the generation of 12-hydroxy fatty acid derivatives. As in mammals, leukotriene and lipoxin biosynthesis requires the presence of a 5-lipoxygenase activating protein-like molecule that is sensitive to the action of the specific inhibitor, MK-886. The prostaglandin-generating ability of trout macrophages can be altered by incubation with lipopolysaccharide suggesting the possible presence of an inducible cyclooxygenase activity. Prostaglandins have been found to suppress the mitogen-induced proliferation of trout leucocytes and the generation of humoral antibody and plasma cells both in vivo and in vitro. The lipoxygenase products, leukotriene B4 and lipoxin A4 have more variable effects ranging from inhibition to stimulation depending on the assay system employed. Overall, there is clear evidence that eicosanoids play a role in immune regulation in fish in a similar way to that reported in mammals.

The granular cells of Galleria mellonella during clotting and phagocytic reactions in vitro.

Light and electron-microscopic observations of the blood-cells (hemocytes) of the wax-moth Galleria mellonella showed that hemolymph coagulation was initiated by the rapid release of material from the granular cells. During incubation for short terms in vitro these cells showed progressive degranulation as material derived from the granules was discharged into the hemolymph. Attempts to determine the nature of this material by staining with ruthenium red proved mainly unsuccessful. When challenged with bacteria in vitro the granular cells failed to phagocytose these particles and instead the bacteria became embedded in the granular material surrounding these cells. The mode of coagulation reported here is compared with previous reports of the role of invertebrate hemocytes in hemolymph clotting.

Activation of the prophenoloxidase cascade and initiation of nodule formation in locusts by bacterial lipopolysaccharides.

The activation of the prophenoloxidase (proPO) system of the locusts, Schistocerca gregaria and Locusta migratoria, by several bacterial lipopolysaccharides (LPS) is described. Activation of proPO by LPS occurred only in the presence of whole blood homogenates and not with hemocyte lysate preparations alone. Levels of phenoloxidase generated by the different LPSs in vitro were also correlated with numbers of nodules formed in vivo by injection of these LPSs. This further strengthens the evidence for the involvement of proPO activation in the insect cellular defenses. Finally, the wisdom in using anticoagulants in order to stabilize fragile hemocytes in studies on the proPO system is discussed.

Enhanced Cellular Immunity in Shrimp ( Litopenaeus vannamei ) after ‘Vaccination’

It has long been viewed that invertebrates rely exclusively upon a wide variety of innate mechanisms for protection from disease and parasite invasion and lack any specific acquired immune mechanisms comparable to those of vertebrates. Recent findings, however, suggest certain invertebrates may be able to mount some form of specific immunity, termed ‘specific immune priming’, although the mechanism of this is not fully understood (see Textbox S1). In our initial experiments, either formalin-inactivated Vibrio harveyi or sterile saline were injected into the main body cavity (haemocoel) of juvenile shrimp (Litopenaeus vannamei). Haemocytes (blood cells) from V. harveyi-injected shrimp were collected 7 days later and incubated with a 1∶1 mix of V. harveyi and an unrelated Gram positive bacterium, Bacillus subtilis. Haemocytes from ‘vaccinated’ shrimp showed elevated levels of phagocytosis of V. harveyi, but not B. subtilis, compared with those from saline-injected (non-immunised) animals. The increased phagocytic activity was characterised by a significant increase in the percentage of phagocytic cells. When shrimp were injected with B. subtilis rather than vibrio, there was no significant increase in the phagocytic activity of haemocytes from these animals in comparison to the non-immunised (saline injected) controls. Whole haemolymph (blood) from either ‘immunised’ or non-immunised’ shrimp was shown to display innate humoral antibacterial activity against V. harveyi that was absent against B. subtilis. However, there was no difference in the potency of antibacterial activity between V. harveyi-injected shrimp and control (saline injected) animals showing that ‘vaccination’ has no effect on this component of the shrimps immune system. These results imply that the cellular immune system of shrimp, particularly phagocytosis, is capable of a degree of specificity and shows the phenomenon of ‘immune priming’ reported by other workers. However, in agreement with other studies, this phenomenon is not universal to all potential pathogens.

Synthesis of leukotriene B and other conjugated triene lipoxygenase products by blood cells of the rainbow trout, Salmo gairdneri

Stimulation of whole blood from rainbow trout with the calcium ionophore, A23187 (20 microM), produced leukotrienes B4 and B5 at concentrations in the range 22-30 ng.ml-1 and 8-24 ng.ml-1, respectively. Their identification and quantification was achieved using reverse-phase high-performance liquid chromatography, combined capillary column gas chromatography-electron capture chemical ionization mass spectrometry and ultraviolet spectroscopy. A number of other lipoxygenase products were also detected, but only partially analysed. The fatty acid composition of the leucocytes, which are presumed to be the site of leukotriene synthesis, was determined by thin-layer and gas-liquid chromatography to enable a comparison of the relative levels of the polyunsaturated fatty acids, which act as substrates for the synthesis of these lipoxygenase products. Arachidonic (20:4(n - 6)), eicosapentaenoic (20:5(n - 3)) and docosahexaenoic (22:6(n - 3)) acids represented approx. 6, 5 and 40%, respectively, of the total fatty acid content.

Studies on the activation of the prophenoloxidase system of insects by bacterial cell wall components

Abstract The ability of bacterial cell walls to activate the prophenoloxidase cascade was tested using Blaberus craniifer, Clitumnus extradentatus, Locusta migratoria and Schistocerca gregaria . Effects of modifying components of the cell wall on the activation of prophenoloxidase in a haemocyte lysate supernatant preparation were examined. Peptidoglycan was found to be an important factor for the activating ability of Gram-positive bacteria. Lysozyme treatment of Micrococcus luteus cell wall showed that the soluble peptidoglycan was the active component. Teichoic acid isolated from Staphylococcus aureus did not activate the prophenoloxidase cascade. However, removal of teichoic acid from the cell wall enhanced activation, probably by exposure of peptidoglycan. Several Escherichia coli K-12 strains, with differing lipopolysaccharide compositions, were also tested for activation of prophenoloxidase. Differences in the ability of the various strains to activate the prophenoloxidase cascade were apparent although no clear conclusions could be made. The role of capsular polysaccharides was investigated too, using two Klebsiella pneumoniae strains, a noncapsulate mutant and its capsulate parent strain. The capsular polysaccharide conferred an increased activating potential. This difference in activation was lost by removal of the capsule from the parent strain. These results are interpreted in terms of the nonself recognition process in insect haemolymph.