Plasmatocytes from the moth Pseudoplusia includens induce apoptosis of granular cells

The primary immune response toward internal parasites and other large foreign objects that enter the insect hemocoel is encapsulation. Prior studies indicated that granular cells and plasmatocytes are the two hemocyte types required for capsule formation by the moth Pseudoplusia includens (Lepidoptera: Noctuidae). Capsules formed by P. includens also have a defined architecture with primarily granular cells attaching directly to the target, multiple layers of plasmatocytes adhering to this inner layer of granular cells, and a monolayer of granular cells attaching to the capsule periphery. Dye-exclusion assays indicated that granular cells die shortly after attaching to the capsule periphery, leaving a basal lamina-like layer around the capsule. In examining the mechanisms underlying granular cell death, we found that culture medium preconditioned by plasmatocytes induced apoptosis of granular cells. Characteristics of plasmatocyte-induced apoptosis included condensation of chromatin, cell surface blebbing and fragmentation of nuclear DNA. Plasmatocyte-conditioned medium did not induce apoptosis of other hemocyte types, and medium conditioned by other hemocyte types did not induce apoptosis of granular cells. The adhesive state of granular cells and plasmatocytes also affected levels of apoptosis. Conditioned medium from spread plasmatocytes induced higher levels of granular cell apoptosis than medium conditioned by unspread plasmatocytes. Reciprocally, spread granular cells underwent significantly higher rates of apoptosis than unspread granular cells in medium conditioned by spread plasmatocytes. In situ analysis indicated that granular cells on the periphery of capsules also undergo apoptosis. Collectively, our results suggest that spread plasmatocytes release one or more factors that induce apoptosis of granular cells, and that this response is important in the final phases of capsule formation.

Isolation and identification of a plasmatocyte-spreading peptide from the hemolymph of the lepidopteran insect Pseudoplusia includens

Insect blood cells (hemocytes) play an essential role in defense against parasites and other pathogenic organisms that infect insects. A key class of hemocytes involved in insect cellular immunity is plasmatocytes. Here we describe the isolation and identification of a peptide from the moth Pseudoplusia includens that mediates the spreading of plasmatocytes to foreign surfaces. This peptide, designated plasmatocyte-spreading peptide (PSP1), contains 23 amino acid residues in the following sequence: H-ENFNGGCLAGYMRTADGRCKPTF-OH. In vitro assays using the synthetic peptide at concentrations >/=2 nM induced plasmatocytes from P. includens to spread on the surface of culture dishes. Injection of this peptide into P. includens larvae caused a transient depletion of plasmatocytes from circulation. Labeling studies indicated that this peptide induced 75% of plasmatocytes that were double-labeled by the monoclonal antibodies 49G3A3 and 43E9A8 to spread, whereas plasma induced significantly more plasmatocytes to spread. This suggests that only a certain subpopulation of plasmatocytes responds to the peptide and that other peptidyl factors mediate plasmatocyte adhesion responses.

Granular cells are required for encapsulation of foreign targets by insect haemocytes

Haemocytes play an essential role in defending invertebrates against pathogens and parasites that enter their haemocoel. A primary defense response is encapsulation; a process in which haemocytes attach to the foreign organism and kill it. Whether encapsulation requires cooperation between specific subpopulations of haemocytes is unknown. Using purified subpopulations of haemocytes and an in vitro encapsulation assay, we investigated the process of capsule formation in the insect Pseudoplusia includens. Immunocytochemical staining revealed that capsule formation involves a three step process. Encapsulation began when granular cells attached to the foreign target. This was followed by attachment of multiple layers of plasmatocytes. Termination of capsule formation occurred when a subpopulation of granular cells formed a monolayer around the periphery of the capsule. Neither granular cells nor plasmatocytes were capable of forming a capsule independently. However, plasmatocytes encapsulated targets if granular cells were present or if targets were preincubated in medium conditioned by granular cells. The effect of granular cell-conditioned medium could be blocked by the addition of the cell adhesion recognition sequence, RGDS, but not by RGES. These results demonstrate experimentally that granular cells are required for encapsulation of foreign targets by plasmatocytes in vitro, and that the role of granular cells in this process involves an RGD-dependent cell adhesion mechanism.

Microplitis demolitor polydnavirus induces apoptosis of a specific haemocyte morphotype in Pseudoplusia includens

Microplitis demolitor polydnavirus (MdPDV) is associated with Microplitis demolitor, a parasitic wasp that attacks the larval stage of the lepidopteran Pseudoplusia includens. Previously, we observed that MdPDV induced several alterations in the granular cells and plasmatocytes of P. includens, the primary haemocytes involved in regulating the cellular immune response toward M. demolitor and other parasites. In examining the mechanisms underlying immunosuppression of this host, we found that MdPDV induced apoptosis of granular cells. Granular cells underwent apoptosis both when virus was injected into the haemocoel of P. includens larvae and after infection with MdPDV in vitro. Characteristics of MdPDV-induced apoptosis included condensation of chromatin, cell surface blebbing and fragmentation of DNA into a 200 bp ladder. Although MdPDV induced changes in the ability of plasmatocytes to adhere to foreign surfaces, apoptosis of this morphotype was not observed. Examples from the literature suggest that some viruses promote their own survival by suppressing apoptosis of host cells. However, since polydnaviruses are likely to be transmitted vertically, we suggest that MdPDV promotes its own survival by inducing apoptosis of host immune cells which would otherwise kill the developing M. demolitor egg.

Immunological basis for compatibility in parasitoid-host relationships

The insect immune system serves as a key defense against attack by parasitoids. Incompatible hosts often eliminate parasitoids by encapsulation, a process in which hemocytes form a multilayered envelope around the invading organism. Capsule formation involves cooperation between one or more classes of hemocytes and is likely mediated by cytokines and adhesion molecules. Reciprocally, parasitoids have evolved a variety of strategies for overcoming host immune responses. Some parasitoids passively avoid elimination by developing in locations inaccessible to host hemocytes or by possessing surface features that fail to elicit an immune response. Other species actively disrupt the host immune system by injecting specific factors into the host at oviposition. In particular, polydnaviruses associated with several taxa of parasitoids disrupt capsule formation by killing hemocytes or altering their ability to adhere to foreign surfaces. These symbionts have likely played a critical role in evolution of host range and in defining parasitoid-host compatibility.

Separation and behavior in vitro of hemocytes from the moth, Pseudoplusia includens

Hemocytes collected from larvae of Pseudoplusia includens (Lepidoptera:Noctuidae) were separated by centrifugation on Percoll cushions. The procedure resulted in 95% purity of plasmatocytes and greater than 99% purity of granular and spherule cells. Medium supplemented with chicken serum enhanced cell viability and promoted spreading of plasmatocytes. Cell-free plasma and medium preconditioned by plasmatocytes or granular cells stabilized cells in vitro and also accelerated spreading of plasmatocytes relative to medium supplemented with chicken serum. Oenocytoids were the only morphotype that exhibited endogenous phenoloxidase activity, while granular cells and plasmatocytes were the only cells that endocytosed fluorescent beads in vitro. Granular cells and plasmatocytes ingested fluorescently labelled beads, both in mixed populations of hemocytes and after separation. Plasmatocytes were the only morphotype that encapsulated large foreign targets in vitro following separation. Separated granular cells attached and spread on the surface of foreign targets but never formed a multilayered capsule.

Purification and characterization of calmodulin (lysine 115) N-methyltransferase from Paramecium tetraurelia

Calmodulin (lysine 115) N-methyltransferase was purified from the cytosolic fraction of Paramecium tetraurelia by sequential dialysis, cellulose phosphate chromatography, Reactive Red 120 agarose chromatography, and calmodulin-Sepharose affinity chromatography. The enzyme was purified 6800-fold with a 15% yield. SDS-PAGE analysis of the purified enzyme invariably revealed a major protein of 37 kDa that was reproducibly obtained and minor proteins of 35 and 28 kDa that were sometimes obtained in variable yields. The enzyme formed a mixture of mono-, di-, and trimethyllysine residues at lysine 115 of calmodulin in vitro, had a Km for the methyl donor, S-adenosyl methionine (AdoMet), of about 1 microM and a pH optimum of about 7.5. The purified enzyme had an absolute requirement for the reductant DTT for activity, whereas the enzyme in crude fractions did not. The enzyme is a monomer with an estimated molecular mass of 33 kDa. Ca2+, Mg2+, Mn2+, and Ni2+ stimulated calmodulin N-methyltransferase activity but Zn2+ did not. Calmodulin N-methyltransferase was inhibited by its reaction product S-adenosyl homocysteine (SAH), but not by sinefungin and tubercidin. The calmodulin antagonists calmidazolium and mellitin were inhibitory but W7 was not. The enzyme was not stimulated by Triton X-100 nor by NaCl. Only calmodulins with an unmethylated lysine at residue 115, including cam2 calmodulin, were substrates. Histones and calcium-binding proteins from Paramecium other than calmodulin did not act as substrates for the purified calmodulin N-methyltransferase and no other substrates in the cytosolic fraction were observed.

High-resolution scanning electron microscopy of frozen-hydrated cells

Cryo-fixed yeast Paramecia and sea urchin embryos were investigated with an in-lens type field-emission SEM using a cold stage. The goal was to further develop and investigate the processing of frozen samples for the low-temperature scanning electron microscope (LTSEM). Uncoated frozen-hydrated samples were imaged with the low-voltage backscattered electron signal (BSE). Resolution and contrast were sufficient to visualize cross-fractured membranes, nuclear pores and small vesicles in the cytoplasm. It is assumed that the resolution of this approach is limited by the extraction depth of the BSE which depends upon the accelerating voltage of the primary beam (V0). In this study, the lowest possible V0 was 2.6 kV because below this value the sensitivity of the BSE detector is insufficient. It is concluded that the resolution of the uncoated specimen could be improved if equipment were available for high-resolution BSE imaging at 0.5-2 kV. Higher resolution was obtained with platinum cryo-coated samples, on which intramembranous particles were easily imaged. These images even show the ring-like appearance of the hexagonally arranged intramembranous particles known from high-resolution replica studies. On fully hydrated samples at high magnification, the observation time for a particular area is limited by mass loss caused by electron irradiation. Other potential sources of artefacts are the deposition of water vapour contamination and shrinkage caused by the sublimation of ice. Imaging of partially dehydrated (partially freeze-dried) samples, e.g. high-pressure frozen Paramecium and sea urchin embryos, will probably become the main application in cell biology. In spite of possible shrinkage problems, this approach has a number of advantages compared with any other electron microscopy preparation method: no chemical fixation is necessary, eliminating this source of artefacts; due to partial removal of the water additional structures in the cytoplasm can be investigated; and finally, the mass loss due to electron beam irradiation is greatly reduced compared to fully frozen-hydrated specimens.