Vassilis J. Marmaras

Regulators and signalling in insect haemocyte immunity.

The innate immune system of insects relies on both humoral and cellular immune responses that are mediated via activation of several signalling pathways. Haemocytes are the primary mediators of cell-mediated immunity in insects, including phagocytosis, nodulation, encapsulation and melanization. The last years, research has focused on the mechanisms of microbial recognition and activation of haemocyte intracellular signalling molecules in response to invaders. The powerful tool, RNA interference gene silencing, helped several regulators involved in immune responses, to be identified. In this review, we summarize recent advances in understanding the role(s) of receptors and intracellular signalling molecules involved in immune responses.

Immune response in insects: The role of phenoloxidase in defense reactions in relation to melanization and sclerotization

It is well known that activated prophenoloxidase (proPO) plays an important role in cuticular melanization and sclerotization. In addition, studies dealing with immune response of insects suggest that phenoloxidase (PO) is also critical in the defense reactions of insects against invaders. proPO is activated by elicitors derived from microbial cell wall components such as peptidoglycan, beta-1,3-glucan, and lipopolysaccharide (LPS). According to our recent studies we proposed a model clarifying the role of PO in both cellular and humoral immune responses. LPS triggers Ceratitis capitata hemocytes via induced protein tyrosine phosphorylation to release biologically active molecules, including p47 and proPO-activators. Furthermore, hemocytes in response to LPS facilitate clearance of LPS from the hemocoel of medfly. The effector molecules involved in the LPS clearance are hemocyte surface-associated p47 (mp47), soluble p47 (sp47), activated proPO, and tyrosine. A similar LPS clearance system in the integument of medfly in vitro was also demonstrated. According to our data, the proposed mechanism for LPS clearance from hemocoel and from integument is the crosslinking of LPS to p47 or certain integumental proteins via the intermediacy of reactive tyrosine derivatives generated by PO activity, as is the case for cuticular protein-chitin crosslinks during sclerotization. We also demonstrated that metabolites of the eumelanin biosynthesis and not melanin itself or N-acetyldopamine (NADA), the key precursor of sclerotizing agent, were necessary for the immune responses by hemocytes and integument.

Phagocytosis of Escherichia coli by insect hemocytes requires both activation of the Ras/mitogen-activated protein kinase signal transduction pathway for attachment and beta3 integrin for internalization.

Insect hemocytes in response to lipopolysaccharide (LPS) of Gram-negative bacteria facilitate binding and internalization of either cell-associated or cell-free LPS (Charalambidis, N. D., Foukas L. C., and Marmaras V. J. (1996) Eur. J. Biochem. 236, 200–206). An early event in LPS signaling in hemocytes involves protein tyrosine phosphorylation (Charalambidis N. D., Zervas C. G., Lambropoulou M., Katsoris P. G., and Marmaras V. J.(1995) Eur. J. Cell Biol. 67, 32–41). Here we report further data of LPS-mediated signal transduction responsible for Escherichia coliphagocytosis. We demonstrate that both adhesion of hemocytes to substrata and LPS stimulation can cause activation of p44MAPK in Ceratitis capitata hemocytes but with distinct kinetics indicating different functions. In addition, we showed that Drk, a homolog protein to the mammalian GRB2, is implicated in the transmission of LPS signaling, indicating that the Ras/mitogen-activated protein kinase pathway is involved. Either the cell-free or the cell-associated LPS appears to attach to the hemocyte surface by the same mechanism that is based on the cross-linking of LPS to membrane-associated p47 via the intermediacy of tyrosine derivatives generated by the action of phenol oxidase. By contrast, the cell-free LPS internalization into the hemocytes differs from the cell-associated LPS internalization. For E. coli internalization integrin receptors as well as cytoskeletal rearrangements are required, as judged by inhibition of E. coli internalization in the presence of the RGD peptide, β3-integrin antibodies, and cytochalasin D.

Innate immunity in insects: surface-associated dopa decarboxylase-dependent pathways regulate phagocytosis, nodulation and melanization in medfly haemocytes

Phagocytosis, melanization and nodulation in insects depend on phenoloxidase (PO) activity. In this report, we demonstrated that these three processes appear to be also dependent on dopa decarboxylase (Ddc) activity. Using flow cytometry, RNA interference, immunoprecipitation and immunofluorescence, we demonstrated the constitutive expression of Ddc and its strong association with the haemocyte surface, in the medfly Ceratitis capitata. In addition, we showed that Escherichia coli phagocytosis is markedly blocked by small interfering RNA (siRNA) for Ddc, antibodies against Ddc, as well as by inhibitors of Ddc activity, namely carbidopa and benzerazide, convincingly revealing the involvement of Ddc activity in phagocytosis. By contrast, latex beads and lipopolysaccharide (LPS) did not require Ddc activity for their uptake. It was also shown that nodulation and melanization processes depend on Ddc activation, because antibodies against Ddc and inhibitors of Ddc activity prevent haemocyte aggregation and melanization in the presence of excess E. coli. Therefore, phagocytosis, melanization and nodulation depend on haemocyte‐surface‐associated PO and Ddc. These three unrelated mechanisms are based on tyrosine metabolism and share a number of substrates and enzymes; however, they appear to be distinct. Phagocytosis and nodulation depend on dopamine‐derived metabolite(s), not including the eumelanin pathway, whereas melanization depends exclusively on the eumelanin pathway. It must also be underlined that melanization is not a prerequisite for phagocytosis or nodulation. To our knowledge, the involvement of Ddc, as well as dopa and its metabolites, are novel aspects in the phagocytosis of medfly haemocytes.

Translation of the mRNAs coding for the major hemolymph proteins of Ceratitis capitata in cell-free system: Comparison of the translatable mRNA levels to the respective biosynthetic levels of the proteins in the fat body during development

Four major hemolymph polypeptides (ceratitins) with molecular weights between 8.1 X 10(4) and 8.7 X 10(4) daltons have been identified in the fat body of late Ceratitis capitata larvae. Total fat body RNA from late larvae was translated in reticulocyte lysate, and the predominant in vitro translation products were shown to be the ceratitin precursors. The biosynthesis of these proteins during postembryonic development was studied in both tissue culture and cell-free system. Comparison of the biosynthetic patterns obtained in the two systems suggests a linear relationship between messenger concentration and protein synthesis. Three of these polypeptides show a coordinate pattern of synthesis and are immunologically related. After pupation, all four ceratitins are reabsorbed by the fat body where they accumulate.

Distinct signalling pathways promote phagocytosis of bacteria, latex beads and lipopolysaccharide in medfly haemocytes

In insects, phagocytosis is an important innate immune response against pathogens and parasites, and several signal transduction pathways regulate this process. The focal adhesion kinase (FAK)/Src and mitogen activated protein kinase (MAPK) pathways are of central importance because their activation upon pathogen challenge regulates phagocytosis via haemocyte secretion and activation of the prophenoloxidase (proPO) cascade. The goal of this study was to explore further the mechanisms underlying the process of phagocytosis. In particular, in this report, we used flow cytometry, RNA interference, enzyme‐linked immunosorbent assay, Western blot and immunoprecipitation analysis to demonstrate that (1) phagocytosis of bacteria (both Gram‐negative and Gram‐positive) is dependent on RGD‐binding receptors, FAK/Src and MAPKs, (2) latex bead phagocytosis is RGD‐binding‐receptor‐independent and dependent on FAK/Src and MAPKs, (3) lipopolysaccharide internalization is RGD‐binding‐receptor‐independent and FAK/Src‐independent but MAPK‐dependent and (4) in unchallenged haemocytes in suspension, FAK, Src and extracellular signal‐regulated kinase (ERK) signalling molecules participating in phagocytosis show both a functional and a physical association. Overall, this study has furthered knowledge of FAK/Src and MAPK signalling pathways in insect haemocyte immunity and has demonstrated that distinct signalling pathways regulate the phagocytic activity of biotic and abiotic components in insect haemocytes. Evidently, the basic phagocytic signalling pathways among insects and mammals appear to have remained unchanged during evolution.

Involvement of FAK/Src complex in the processes of Escherichia coli phagocytosis by insect hemocytes

Recently we demonstrated that lipopolysaccharide promotes activation of the Ras/mitogen‐activated protein cascade in hemocytes and that phagocytosis of Escherichia coli by insect hemocytes is mediated by an integrin‐dependent process [Foukas et al. (1998) J. Biol. Chem. 273, 14813–14818]. Here we report data concerning the focal adhesion kinase (FAK) tyrosine phosphorylation status in hemocytes in response to E. coli. We demonstrate that E. coli‐triggering stimulates a significant increase in tyrosine phosphorylation of FAK in hemocytes. Furthermore, immunoblotting analysis using anti‐Y397 demonstrated intense FAK activity at the Y397/SH2‐binding site in hemocytes treated with E. coli. In addition, antibody‐mediated inhibition of FAK and Src‐kinase has been shown to abolish FAK phosphorylation and E. coli phagocytosis, indicating a specific role for the FAK/Src complex in the processes of promoting cell phagocytosis. These findings expand the known signaling functions of FAK and provide insight into signal transduction events associated with hemocyte phagocytosis in response to E. coli.

Hemocyte surface phenoloxidase (PO) and immune response to Lipopolysaccharide (LPS) in Ceratitis capitata

Bacterial lipopolysaccharide (LPS) attachment at the hemocyte surface is based on the crosslinking of surface associated p47 to LPS, via the intermediacy of tyrosine derivatives generated by the action of phenoloxidase (PO). This attachment is an initial step for LPS internalization from hemocytes (Charalambidis et al., 1996). The results presented clearly show the critical role of hemocyte associated PO activity in the above processes. Biochemical and immunofluorescent analysis demonstrated unambiguously the presence of prophenoloxidase (proPO) on the hemocyte surface. The cell-surface expression of proPO appeared to be LPS-independent, whereas its activation was LPS-dependent. The activation of cell surface proPO involves a limited proteolysis, since upon activation with chymotrypsin proPO is converted to a set of smaller molecular weight proteins with PO activity. The activation appears to be due to enzyme activators, serine proteases, released upon LPS-stimulation. This hypothesis was supported from the activation of membrane proPO by the culture medium of hemocytes which have been triggered with LPS. In addition, proPO, activation was abolished by inhibitors of secretion and PMSF. The release of proPO activators upon LPS-stimulation is mediated via protein tyrosine phosphorylation, as genistein inhibited proPO activation, a situation similar to that reported by us for the release of the effector protein p47 (Charalambidis et al., 1995). The LPS-stimulated activation of cell-surface proPO is a prerequisite for LPS (either cell associated or cell free) internalization, as judged by the resistance of LPS binding to dissociation by proteinase K.

A β integrin subunit regulates bacterial phagocytosis in medfly haemocytes.

We have recently reported that the activation of focal adhesion kinase (FAK) and its downstream targets upon pathogen challenge regulate phagocytosis in medfly haemocytes. The goal of this study was to further explore the signalling pathway underlying the process of phagocytosis. In particular, in this report, we used flow cytometry, RNA interference, enzyme-linked immunosorbent assay, Western blot and immunoprecipitation analysis to demonstrate the haemocyte surface receptor, through which the extracellular signals in response to bacteria are transmitted intracellularly. The presented data demonstrate the expression of a beta integrin subunit in the surface of medfly haemocytes that transmits signals upon pathogen triggering to FAK and its downstream targets, Src, MAP kinases and Elk-1-like protein, for the engulfment of pathogen. Interestingly LPS is not internalized through integrins.

Distinct LPS-induced signals regulate LPS uptake and morphological changes in medfly hemocytes.

Recently we demonstrated that lipopolysaccharide (LPS) promotes activation of the Ras/ERK cascade in medfly hemocytes and that phagocytosis of Escherichia coli by insect hemocytes is mediated by an integrin-dependent process via the activation of FAK/Src complex (J Biol Chem 273 (1998) 14813; FEBS Letters 496 (2001) 55). In the current study we wanted to further elucidate the effects of LPS on medfly hemocytes, in order to better understand the regulation of the evolutionary conserved signaling mechanisms between insects and mammals. We initially observed that different stimuli, including LPS, E. coli, RGD, fibronectin and heat shock activate hemocyte ERK. The response of hemocytes to these stimuli denoted that hemocyte ERK is evidently stimulated by at least an LPS receptor and via an integrin-mediated process. The medfly hemocytes respond to LPS by changing their morphology, inducing the activation of several signaling pathways, including Ras/MEK/ERK, PI-3K/ERK and Rho pathways and contributing to LPS uptake. Experiments based on inhibitors of specific signaling pathways, such as manumycin A, toxin A, U0126, PD98059 and wortmannin revealed that Ras, MEK and PI-3K are involved in the activation of ERK. Whether PI-3K is an intermediate of Ras/MEK/ERK pathway or activates ERK via other signaling pathway it remains to be elucidated. ERK is not activated via Rho pathway, denoting that Rho may not be an upstream effector molecule of ERK pathway. Regarding the role(s) that these kinases play in hemocytes, it can be suggested that PI-3K and Rho GTPases can modulate hemocyte shape changes, whereas ERK, Ras and MEK cannot. In addition, PI-3K as well as Ras and MEK through ERK activation participate in LPS endocytosis. Therefore, PI-3K shares a dual role; it is involved both in cell shape changes and in LPS endocytosis. Since ERK activation appears to be independent of the integrity of actin filaments, as cytochalasin D and latrunculin A did not block ERK activation, it can be concluded that LPS endocytosis is independent of actin cytoskeleton remodeling as is the case in mammalian systems.