Primary integumentary allograft reactivity in the American cockroach, Periplaneta americana

Dscam in arthropod immune priming: What is known and what remains unknown

A popular view in the current academic circle is that invertebrates have no adaptive immunity. However, the immune memory and specificity of invertebrates pose a serious challenge to this view and constitute immune priming based on innate immunity. The Down syndrome cell adhesion molecule (Dscam) gene of invertebrates, with approximately 10,000 alternatively spliced isoforms, has a unique characteristic: it specifically binds to different types of bacteria and promotes cell phagocytosis; owing to its antibody-like function, Dscam is a key candidate protein for immune priming. However, the high molecular diversity of Dscam and the gaps and inconsistencies in the existing research make the study of regulation of immune priming by Dscam challenging. In recent years, significant research has been conducted on the Dscam-regulated immune functions in insects and crustaceans, providing preliminary results for Dscam-regulated innate immunity and immune priming, but some important questions remain unresolved. In this review, we summarize the existing knowledge about Dscam-regulated immunity and discuss three yet unanswered questions, the study of which may improve the understanding of the role of Dscam-regulated immune priming in invertebrates.

Enhanced Immune Protection of Mud Crab Scylla paramamosain in Response to the Secondary Challenge by Vibrio parahaemolyticus

“Immune priming” plays a vital part in the immune system of invertebrates, protecting against recurrent infections by pathogens, and can provide some ideas for the prevention and treatment of invertebrate diseases. Many invertebrates have been demonstrated recently to have immune priming, but the relevant mechanisms are not known. Expression of immune system–related genes in the hemocytes and hepatopancreas of the mud crab (Scylla paramamosain) before and after repeated stimulation with Vibrio parahaemolyticus were analyzed by real-time fluorescence quantitative polymerase chain reaction. Some molecules that may participate in the immune priming of S. paramamosain were screened out, and their possible roles in immune priming were interpreted. Crabs injected first with heat-killed V. parahaemolyticus (HkVp group) or physiologic (0.9%) saline (PS group) were rechallenged at 168 h with live V. parahaemolyticus (HkVp+Vp group and PS+Vp group, respectively). The log-rank test shows a significant difference in survival rate between the HkVp+Vp group and the other groups after the ICH (p < 0.05). Expression of genes involved in the toll-like receptor (TLR) signaling pathway and some antimicrobial peptide genes were detected. By, respectively, comparing gene quantification at different time points in hemocytes and the hepatopancreas, the molecules that may play a part in the early stage of the immune priming of S. paramamosain in the hemocytes are found to be down syndrome cell adhesion molecule (Dscam), Hyastatin, Cactus, Arasin, antilipopolysaccharide factor 3 (ALF3), ALF4, ALF5, and ALF6 as well as later acting molecules, such as Crustin, Dorsal, Pelle, and myeloid differentiation factor 88 (MyD88). The molecules that functioned throughout the entire period are TLR and Spaetzle. In the hepatopancreas, the molecules that may play a part in the early stages of immune priming are Dscam, Hyastatin, Arasin, ALF6, Pelle, Spaetzle, Dorsal and, in the later stage, ALF4. The molecules that functioned throughout the entire period are TLR, Crustin, Cactus, MyD88, ALF3, and ALF5. In summary, the immune function of S. paramamosain is enhanced after it receives the same repetitive stimulation by V. parahaemolyticus, indicating immune priming in S. paramamosain. Our study enriches research on immune priming in invertebrates and lays the foundation for further studies revealing the molecular mechanism of immune priming in crabs.

Infections by Pasteuria do not protect its natural host Daphnia magna from subsequent infections

The existence of immunological memory in invertebrates remains a contentious topic. Exposure of Daphnia magna crustaceans to a noninfectious dose of the bacterium Pasteuria ramosa has been reported to reduce the chance of future infection upon exposure to higher doses. Using clonal hosts and parasites, we tested whether initial exposure of the host to the parasite (priming), followed by clearing of the parasite with antibiotic, protects the host from a second exposure (challenge). Our experiments included three treatments: priming and challenge with the same or with a different parasite clone, or no priming. Two independent experiments showed that both the likelihood of infection and the degree of parasite proliferation did not differ between treatments, supporting the conclusion that there is no immunological memory in this system. We discuss the possibility that previous discordant reports could result from immune or stress responses that did not fade following initial priming.

Perforin-Dependent Cell Death in Skin Allograft Rejection of the Terrestrial Slug Incilaria fruhstorferi

The rejection of allografts in mammals is mainly mediated by cytotoxic T-lymphocytes, whereas no comparable immunoreactive cells have been described in invertebrates. The present study was undertaken to determine whether similar cytotoxic effector cells are present when allograft rejection occurs in the terrestrial slug Incilaria fruhstorferi. A piece of dorsal skin from a donor animal was orthotopically transplanted to a recipient. Immunohistochemistry for perforin, detection of apoptosis by the TUNEL (TdT-mediated dUTP-biotin nick-end labeling) method, and electron microscopy were performed using both donor and recipient tissues. Cellular changes in the rejection process continued over for 40 days. Two functional types of "effector" cells were recognized at the rejection site, but they were observed to be macrophages possessing perforin granules and phagocytosing damaged cells of the allograft. Three days after transplantation, the perforin-positive cells were recognized only in the recipient tissue surrounding the allograft. Five days after transplantation, these cells started to appear in the graft, while they disappeared from the host tissue. However, TUNEL-positive cells were not observed throughout the graft-rejection process. Electron microscopic examination of the graft tissue revealed autophagic degeneration of epithelial cells, mucous cells, pigment cells, fibroblasts, and muscle cells. These observations suggest that the molluscan slug has the capability to recognize differences in cell-surface molecules between the allogeneic and recipient tissues, and that an allograft is chronically rejected due to a type of immunocyte that can induce perforin-dependent cell death.

Leech responses to tissue transplantation

The aim of the present work is to describe histologically, histochemically and immunocytochemically, the sequence of events that lead to first and second set rejection of allo- or xenograft in leeches. Graft responses of leeches are comparable and are described following specific steps: inflammatory phase, rejection phase and granulation tissue formation (including re-epithelialisation, angiogenesis and fibroplasia).The responses to first and second graft in first set graft rejection as well as to the first transplant in second set graft experiments are identical and in the time span of a week all grafts are destroyed and disappear. In the second set graft rejection experiments the responses against the second transplant are markedly accelerated. The second graft shows massive structural alterations and it is rapidly rejected, within 3-4 days.Our results permit to highlight that in leeches there is a specific responsiveness of immune system similar to those described in highly divergent phyla.

Comparison of several types of allografts in Biomphalaria glabrata (Mollusca: Pulmonata)

Interpretation of prior studies on molluscan allografts is complicated by the variety of experimental methods used and recurring reports of acute rejection of digestive gland implants. In this study, allografts of adult digestive gland, saccular kidney, mantle, albumin gland, brain, ovotestis, heart, or amoebocyte-producing organ (APO) were implanted into the hemocoel of Biomphalaria glabrata snails, and their histological condition at 60 days post implantation (DPI) was compared with that of preimplantation tissues. Also, digestive gland tissue, still surrounded by body wall, was implanted from immature donors and examined at 120 DPI. All 60-day allografts maintained some degree of normal cell and tissue structure, and most displayed additional evidence of viability, i.e., contraction (heart), hyperplasia (APO), gametogenesis (ovotestis), secretion (albumin gland, digestive gland, and kidney), shell deposition (mantle), or neuroma formation (brain). Recipient hemocytic reaction was minimal or absent, except that in three of six ovotestis implants and five of seven digestive gland implants, variable numbers of acini were undergoing phagocytosis by hemocytes or had been reduced to granulomas. Among seven implants examined at 120 DPI, digestive gland acini were found in five (with one instance of hemocytic encapsulation). Thus, in this study, acute rejection of allografts did not occur. Although the observed hemocytic reactions could be viewed as evidence of chronic graft rejection, the inconsistent and protracted nature of these responses suggests instead that they represent resorption of degenerating tissue damaged by nonimmunological effects, e.g., mechanical trauma, heterotopic location, or autolysis.

The main protein of the aggregation factor responsible for species-specific cell adhesion in the marine sponge Microciona prolifera is highly polymorphic

Species-specific cell recognition in sponges, the oldest living metazoans, is based on a proteoglycan-like aggregation factor. We have screened individual sponge cDNA libraries, identifying multiple related forms for the aggregation factor core protein (MAFp3). Northern blots show the presence in several human tissues of transcripts strongly binding a MAFp3-specific probe. The open reading frame for MAFp3 is not interrupted in the 5' direction, revealing variable protein sequences that contain numerous introns equally spaced. We have studied tissue histocompatibility within a sponge population, finding 100% correlation between rejection behavior and the individual-specific restriction fragment length polymorphism pattern using aggregation factor-related probes. PCR amplifications with specific primers showed that at least some of the MAFp3 forms are allelic and distribute in the population used. A pronounced polymorphism is also observed when analyzing purified aggregation factor in polyacrylamide gels. Protease digestion of the polymorphic glycosaminoglycan-containing bands indicates that glycans are also responsible for the variability. The data presented reveal a high polymorphism of aggregation factor components, which matches the elevated sponge alloincompatibility, suggesting an involvement of the cell adhesion system in sponge allogeneic reactions.

Transplantation immunity in the American cockroach, Periplaneta americana: the rejection of integumentary grafts from Blatta orientalis

The results from several previous studies have indicated that the American cockroach is able to respond to integumentary xenografts, but doubt remained as to whether cockroaches could effectively discriminate between self and allogeneic differences. This was emphasized by the fact that while one study reported that Periplaneta americana responded to grafts donated by the closely related genus Blatta orientalis, the data reported elsewhere, using a different assay system, found no such reactivity. Since we have subsequently reported, using a direct histological assay, that Periplaneta can in fact recognize and destroy integumentary allografts, we initiated a study to hopefully sort out the enigma presented by previous data using Blatta as a transplant donor. Integument from Blatta orientalis was transplanted orthotopically onto Periplaneta americana, and at various time points post-transplant, scored histologically for the survival of the subcuticular epidermal layer. The results clearly demonstrated that Periplaneta reacted to the Blatta tissue, because approximately 82% of the grafts had the epidermal layer destroyed by day 7 posttransplant. The kinetics of the response to Blatta was more in line with our allograft data, which would be in agreement with other work indicating that the closer the donor and recipient are on the phylogenetic tree, the less intense the reactivity to the foreign transplant.

In vitro allogeneic cytotoxicity in the solitary urochordate Styela clava

Hemocytes from the solitary urochordate Styela clava can effect allogeneic cytotoxicity in vitro. Spectrophotometric and microscopic quantification of eosin-y dye exclusion revealed significantly greater frequencies of cell death in allogeneic hemocyte cultures when compared to autogeneic controls. This cytotoxic response was characterized by 1) transient activity such that specific cytotoxicity could be detected for only 4 hours of culture though continued specific killing may have been obscured by spontaneous cell death; 2) a necessity for cellular interaction demonstrated by the elimination of allogeneic cytotoxicity in the absence of cell contact; 3) killing of multiple targets by effector cells due to high levels of response at low allogeneic ratios; 4) insensitivity to altered temperature; 5) increased cytotoxicity in the absence of autologous plasma; 6) an absence of xenogeneic reactivity; 7) the presence of three hierarchical levels (low, intermediate, and high) of response. These data reflect events involved in the recognition of allogeneic cellular determinants resulting in specific cytotoxicity effected by immunocompetent cells. Such in vitro recognition and cytotoxic recognition and cytotoxic reactivity may be responsible for adaptive reactions caused by histoincompatibility in solitary tunicates.