Earthworm leukocytes kill HeLa, HEp-2, PC-12 and PA317 cells in vitro

Earthworm coelomic fluid contains biologically active molecules and leukocytes that participate in phagocytosis, encapsulation. Presumably they synthesize and secrete several effector modulators of innate immune responses such as antibacterial molecules, cytotoxic proteins and cytokines. Several lytic molecules have been detected in coelomic fluid previously but it is not yet clear which are actually released from the coelomocytes. Our aim was to analyze the cytotoxic effects of coelomocytes on mammalian target cells and to provide evidence that the lytic factors originate from coelomocytes. Cell-free coelomic fluid, supernatants of short-term cultured coelomocytes, and lysates from coelomocytes--derived by mechanical and detergent extraction--were used in cytotoxicity assays performed on different mammalian standard tumor cell lines and mouse fibroblasts. We used native and denaturized (using proteinase K, and trypsin digestions, or heat-inactivation) coelomocyte lysates (CCL). The viability controls of targeted cells were made by measuring photometrically and analyzing by inverted microscopy. According to our results the coelomic fluid, the supernatant of cultured coelomocytes, and the CCL significantly decreased ratios of living cells compared to controls in a dose-dependent manner. Our experiments performed with CCLs suggest that coelomocytes are responsible for the productions of cytotoxic components presumably proteins.     

Earthworm leukocyte populations specifically harbor lysosomal enzymes that may respond to bacterial challenge

Earthworm leukocytes (coelomocytes) are responsible for innate cellular immune functions such as phagocytosis and encapsulation against parasites and pathogens. Microbial killing results from the combined action of the phagocytic process with humoral immune factors such as agglutinins (e.g., lectins), lysosomal enzymes (e.g., acid phosphatase, lysozyme), and various cytotoxic and antimicrobial molecules. There is also evidence of weak adaptive immune responses against foreign transplants. This study focused on aspects of the innate immune response. First, anti-human acid phosphatase (anti-AcP) polyclonal antibody characterized different acid hydrolase patterns in coelomocytes. Second, flow cytometry identified a strongly immunoreactive coelomocyte population. Third, ultrastructural and cytochemical analyses revealed acid phosphatase in discrete granules (lysosomes) of effector hyaline and granular coelomocytes but not in mature chloragocytes. Coelomocytes were exposed to bacteria to assess how phagocytosis influences: (a) the production of acid phosphatase using Western blot, and (b) release of acid phosphatase using ELISA from cell-free coelomic fluid. Fourth, after phagocytosis, acid phosphatase levels differed between controls and experimentals. Fifth, we found a 39-kDa molecule that reacted intensely with anti-AcP. Our results suggest that effector earthworm coelomocytes may not eliminate pathogens only by phagocytosis but also by extracellular lysis.E.L. Cooper has been supported by The Alexander von Humboldt Foundation, a GAAC grant from the Federal Republic of Germany and two grants from NATO, a Cooperative Research grant (971128) and an Advanced Research Workshop grant (976680)     

棘皮动物免疫学研究进展

棘皮动物属原始后口动物、无脊椎动物的最高等类群,它处于由无脊椎动物向脊椎动物开始分支进化的阶段．研究棘皮动物的免疫功能和作用机理,对从比较免疫学角度探讨动物免疫系统进化过程有承前启后的重要意义．因此,有必要对棘皮动物的免疫学研究进展作一个较全面的综述,并理清未来的研究热点和方向．棘皮动物与其他无脊椎动物一样具有先天性免疫系统,但未发现脊椎动物所具有的获得性免疫．其免疫应答是由参与免疫反应的效应细胞——体腔细胞和多种体液免疫因子共同介导的．比较免疫学分析表明,棘皮动物存在脊椎动物补体系统的替代途径和凝集素途径,但未发现经典途径和明确的终端途径．棘皮动物先天性免疫系统存在数量庞大的基因家族．今后应加强对未知免疫相关基因、蛋白质、信号传导途径及效应分子的研究,回答免疫系统的起源、功能和进化等问题．     

Recent advances in the innate immunity of invertebrate animals

Invertebrate animals, which lack adaptive immune systems, have developed other systems of biological host defense, so called innate immunity, that respond to common antigens on the cell surfaces of potential pathogens. During the past two decades, the molecular structures and functions of various defense components that participated in innate immune systems have been established in Arthropoda, such as, insects, the horseshoe crab, freshwater crayfish, and the protochordata ascidian. These defense molecules include phenoloxidases, clotting factors, complement factors, lectins, protease inhibitors, antimicrobial peptides, Toll receptors, and other humoral factors found mainly in hemolymph plasma and hemocytes. These components, which together compose the innate immune system, defend invertebrate from invading bacterial, fungal, and viral pathogens. This review describes the present status of our knowledge concerning such defensive molecules in invertebrates.     

Vertebrate cytokines interleukin 12 and gamma interferon, but not interleukin 10, enhance phagocytosis in the annelid Eisenia hortensis

Phagocytosis assays employing class I [interleukin 12 (IL-12)], and class II [gamma interferon (gIFN) and IL-10] human recombinant cytokines were carried out to determine the biological effects of these molecules on innate immune responses in the earthworm Eisenia hortensis. Coelomocytes from E. hortensis were pre-incubated with the cytokines for 16-20 h in vitro followed by introduction of Escherichia coli expressing green fluorescent protein (E. coli/GFP). The pro-inflammatory cytokines IL-12 and gIFN stimulated statistically significant (p ? 0.05) enhanced phagocytosis of E. coli/GFP by hyaline amoebocytes as determined by flow cytometry; 10 out of 21 earthworms (48%) responded to IL-12, while eight out of 21 (38%) responded to gIFN. In contrast, the anti-inflammatory cytokine IL-10 neither stimulated nor inhibited phagocytosis in nine earthworms tested. These results demonstrate that vertebrate pro-inflammatory cytokines influence invertebrate cellular responses of immune cells causing enhanced phagocytic activity in earthworm coelomocytes.     

Molecular cloning,characterization and expression analysis of MHCI and chemokines CXCR3 and CXCR4 gene from freshwater carp,Catla catla

The immune system with large number of molecules protects the host against a plethora of continuously evolving microbes. Major histocompatibility complex (MHC) molecules serve as cardinal elements of the adaptive immune system responsible for the activation of the adaptive immunity in the host. The present study reports MHCI molecule in freshwater carp, Catla catla, and its differential expression in immunologically relevant tissues post‐infection with Gram‐negative and Gram‐positive bacteria. The MHCI sequence of C. catla had 502 bp nucleotides encoding putative 146 amino acids. The phylogenetic analysis exhibited its evolutionary conservation within the Cyprinidae family and formed a different clade with the higher vertebrates. Simultaneously, CXCR3 and CXCR4 chemokines were cloned and characterized for their expression in infected tissues. Analysis of immunologically relevant tissues of the infected fish exhibited an increase of MHCI gene expression and the down‐regulation of CXCR3 and CXCR4 chemokines, indicating a tricky interaction between the innate and adaptive immune system. It was found that intestine, skin and spleen played a crucial role in the contribution of the defense activity which instigated the self‐immunity. These immune activities can provide useful information to understand the interaction of self and non‐self‐ immune system in freshwater fish, Catla catla.     

Did the molecules of adaptive immunity evolve from the innate immune system?

The antigen receptors on cells of innate immune systems recognizebroadly expressed markers on non-host cells while the receptorson lymphocytes of the adaptive immune system display a higherlevel of specificity. Adaptive immunity, with its exquisitespecificity and immunological memory, has only been found inthe jawed vertebrates, which also display innate immunity. Jawlessfishes and invertebrates only have innate immunity. In the adaptiveimmune response, T and B-lymphocytes detect foreign agents orantigens using T cell receptors (TCR) or immunoglobulins (Ig),respectively. While Ig can bind free intact antigens, TCR onlybinds processed antigenic fragments that are presented on moleculesencoded in the major histocompatibility complex (MHC). MHC moleculesdisplay variation through allelic polymorphism. A diverse repertoireof Ig and TCR molecules is generated by gene rearrangement andjunctional diversity, processes carried out by the recombinaseactivating gene (RAG) products and terminal deoxynucleotidyltransferase (TdT). Thus, the molecules that define adaptiveimmunity are TCR, Ig, MHC molecules, RAG products and TdT. Nodirect predecessors of these molecules have been found in thejawless fishes or invertebrates. In contrast, the complementcascade can be activated by either adaptive or innate immunesystems and contains examples of molecules that gradually evolvedfrom non-immune functions to being part of the innate and thenadaptive immune system. In this paper we examine the moleculesof the adaptive immune system and speculate on the existenceof direct predecessors that were part of innate immunity.     

无脊椎动物先天免疫模式识别受体研究进展

免疫系统的基本功能是“自己”与“非己”识别.对入侵物的识别是免疫防御的起始,最终引发效应物反应系统,包括吞噬作用、包被作用、激活蛋白酶级联反应和黑化作用以及诱导抗菌肽的合成等,从而清除或消灭入侵物.研究证明,这种“非己”识别是因为存在某些特异性的、可溶的或与细胞膜结合的模式识别受体,可以识别或结合微生物表面保守的、而在宿主中又不存在的病原相关分子模式.模式识别受体通过对病原相关分子的识别启动先天免疫防御.近年来这方面的研究进展很快,已经在无脊椎动物中确定了多种模式识别受体,包括肽聚糖识别蛋白、含硫酯键蛋白、革兰氏阴性菌结合蛋白、清除受体、C型凝集素、硫依赖型凝集素、Toll样受体和血素等,并对其性质和功能进行了研究.     

Electron-microscopic observations of normal coelomocytes from the earthworm,Lumbricus terrestris

Summary Coelomocytes of the earthworm, Lumbricus terrestris, were studied by transmission electron microscopy. Four morphological cell types are distinguishable: lymphocytic coelomocytes, granulocytic coelomocytes, eleocytes (chloragogen cells), and inclusion-containing coelomocytes. Within these major categories, several distinct cell types differ and may represent developmental stages. The two types of lymphocytic coelomocytes are small with central nuclei and scanty cytoplasms. Two types of granulocytic coelomocytes differ greatly in shape and content; both have small dark-staining granules that resemble lysosomes. Electrocytes, derived from chloragogen tissue, contain a variety of granules, inclusions and vacuoles. Inclusion-containing coelomocytes appear as two types which may be immature and mature forms. Although these cells resemble those that have been referred to as erythroid cells in other invertebrates, the large inclusion bodies are apparently unrelated to hemoglobin; they can undergo morphologic transformation and be extruded by exocytosis. This information on lymphocytic, granulocytic and inclusion-containing coelomocytes is crucial to understanding more about cellular immunity in the earthworm.D.S.L. is supported by USPHS Training Grant AI-00453-05. E.A.S., D.H.M. and E.L.C. are supported by USPHS Grant HD-09333-03     

Allorecognition and chimerism in an invertebrate model organism

The presence of highly specific histocompatibility reactions in colonial marine invertebrates that lack adaptive immune systems (such as the sponges, cnidarians, bryozoans and ascidians) provides a unique opportunity to investigate the evolutionary roots of allorecognition and to explore whether homologous innate recognition systems exist in vertebrates. Conspecific interactions among adult animals in these groups are regulated by highly specific allorecognition systems that restrict somatic fusion to self or close kin. In Hydractinia (Cnidaria:Hydrozoa), fusion/rejection responses are controlled by two linked genetic loci. Alleles at each locus are co-dominantly inherited. Colonies fuse if they share at least one haplotype, reject if they share no haplotypes, and display transitory fusion if they share only one allele in a haplotype—a pattern that echoes natural killer cell responses in mice and humans. Allorecognition in Hydractinia and other marine invertebrates serves as a safeguard against stem cell or germline parasitism thus, limiting chimerism to closely related individuals. These animals fail to become tolerant even if exposed during early development to cells from a histoincompatible individual. Detailed analysis of the structure and function of molecules responsible for allorecognition in basal marine invertebrates could provide clues to the innate mechanisms by which higher animals respond to organ and cell allografts, including embryonic tissues.Key words: allorecognition, chimerism, invertebrate, innate immune system     

The enhanced immune protection of Zhikong scallop Chlamys farreri on the secondary encounter with Listonella anguillarum

It is well known that invertebrates are devoid of adaptive immune components and rely primarily on innate immunity to defend against pathogens, but recent studies have demonstrated the existence of enhanced secondary immune protection in some invertebrates. In the present study, the cumulative mortality of scallops received two successive Listonella anguillarum stimulations was recorded, and variations of immune parameters including phagocytosis (phagocytic rate and phagocytic index), phenoloxidase-like enzyme, acid phosphatase and superoxide dismutase activities were also examined. The scallops received a previous short-term L. anguillarum stimulation were protected against a long-term stimulation of L. anguillarum. Significantly higher level of phagocytic activities and acid phosphatase activity were observed in the scallops received twice stimulations compared with those only received the secondary stimulation. These results indicated that a short-term immersion with L. anguillarum modulated the scallops' immune system and endowed the scallops with enhanced resistance to the secondary bacterial stimulation; phagocytosis and acid phosphatase were suspected to be involved in the protection.     

Earthworm leukocytes react with different mammalian antigen-specific monoclonal antibodies

We identified conserved molecules (enzymes, peptides, cytokines) that might play a role in invertebrate innate immunity. We found these molecules by immunoserological and immunohistochemical methods in association with coelomocytes, leukocytes located in the coelomic cavity of the earthworm Eisenia foetida. We detected the enzyme Cu-Zn-superoxide-dismutase (SOD), cytokines (tumor necrosis factor-alpha, TNFalpha; transforming growth factor-alpha, TGFalpha; and alpha peptide hormone, thyreotrope stimulating hormone, TSH) in earthworm coelomocytes with monoclonal antibodies developed originally against human and/or mouse antigens. Three coelomocyte subpopulations were identified according to their form, size and granularity by microscopic and flow cytometric analysis. These cell populations showed different reactivity with antibodies against mammalian cell surface (CD) markers and different intracellular antigens. Two coelomocyte types showed cell surface positivity with anti-Thy-1 (CD90), CD24 and TNF-alpha antibodies. Strong cytoplasmic reaction was shown with anti-TNF-alpha and anti-SOD mAbs and a weaker but unambiguous reaction with thyroid stimulating hormone (TSH) in two cell populations. The third population was negative for all of the monoclonal antibodies. Our flow cytometric results were confirmed by confocal microscopy both on the cell surfaces and intracellularly.     

Allorecognition and chimerism in an invertebrate model organism

The presence of highly specific histocompatibility reactions in colonial marine invertebrates that lack adaptive immune systems (such as the sponges, cnidarians, bryozoans, and ascidians) provides a unique opportunity to investigate the evolutionary roots of allorecognition and to explore whether homologous innate recognition systems exist in vertebrates. Conspecific interactions among adult animals in these groups are regulated by highly specific allorecognition systems that restrict somatic fusion to self or close kin. In Hydractinia (Cnidaria:Hydrozoa), fusion/rejection responses are controlled by two linked genetic loci. Alleles at each locus are co-dominantly inherited. Colonies fuse if they share at least one haplotype, reject if they share no haplotypes, and display transitory fusion if they share only one allele in a haplotype – a pattern that echoes natural killer cell responses in mice and humans. Allorecognition in Hydractinia and other marine invertebrates serves as a safeguard against stem cell or germline parasitism thus, limiting chimerism to closely related individuals. These animals fail to become tolerant even if exposed during early development to cells from a histoincompatible individual. Detailed analysis of the structure and function of molecules responsible for allorecognition in basal marine invertebrates could provide clues to the innate mechanisms by which higher animals respond to organ and cell allografts, including embryonic tissues.     

Cytotoxicity and cytotoxic molecules in invertebrates

Although lacking the components that characterize the acquired immunity systems of vertebrates, invertebrates nevertheless possess effective general innate immune mechanisms which exhibit striking parallels with those of vertebrates. These innate immune systems include both cellular and humoral elements. Invertebrate phagocytes synthesize both oxygen-dependent and oxygen-independent molecules to combat infectious agents. Cytotoxic substances employed by invertebrates include reactive intermediates of oxygen and nitrogen, antimicrobial peptides, lectins, cytokine- and complement-like molecules, and quinoid intermediates of melanin. The signal transduction pathways that are involved in mediating the production of these substances appear to be very similar among animal species, suggesting a common ancestral origin for the innate immune systems.     

The pattern‐recognition molecule mindin binds integrin Mac‐1 to promote macrophage phagocytosis via Syk activation and NF‐κB p65 translocation

Mindin has a broad spectrum of roles in the innate immune system, including in macrophage migration, antigen phagocytosis and cytokine production. Mindin functions as a pattern‐recognition molecule for microbial pathogens. However, the underlying mechanisms of mindin‐mediated phagocytosis and its exact membrane receptors are not well established. Herein, we generated mindin‐deficient mice using the CRISPR‐Cas9 system and show that peritoneal macrophages from mindin‐deficient mice were severely defective in their ability to phagocytize E  coli. Phagocytosis was enhanced when E  coli or fluorescent particles were pre‐incubated with mindin, indicating that mindin binds directly to bacteria or non‐pathogen particles and promotes phagocytosis. We defined that ¹³¹I‐labelled mindin binds with integrin Mac‐1 (CD11b/CD18), the F‐spondin (FS)‐fragment of mindin binds with the α_M‐I domain of Mac‐1 and that mindin serves as a novel ligand of Mac‐1. Blockade of the α_M‐I domain of Mac‐1 using either a neutralizing antibody or si‐Mac‐1 efficiently blocked mindin‐induced phagocytosis. Furthermore, mindin activated the Syk and MAPK signalling pathways and promoted NF‐κB entry into the nucleus. Our data indicate that mindin binds with the integrin Mac‐1 to promote macrophage phagocytosis through Syk activation and NF‐κB p65 translocation, suggesting that the mindin/Mac‐1 axis plays a critical role during innate immune responses.     

Reconstructing immune phylogeny: new perspectives

Numerous studies of the mammalian immune system have begun to uncover profound interrelationships, as well as fundamental differences, between the adaptive and innate systems of immune recognition. Coincident with these investigations, the increasing experimental accessibility of non-mammalian jawed vertebrates, jawless vertebrates, protochordates and invertebrates has provided intriguing new information regarding the likely patterns of emergence of immune-related molecules during metazoan phylogeny, as well as the evolution of alternative mechanisms for receptor diversification. Such findings blur traditional distinctions between adaptive and innate immunity and emphasize that, throughout evolution, the immune system has used a remarkably extensive variety of solutions to meet fundamentally similar requirements for host protection.     

Earthworm coelomocytes in vitro

Summary Contamination and low viability of earthworm coelomocytes in tissue culture have delayed in vitro studies. Using penicillin, streptomycin, tetracycline and Amphotericin B,Lumbricus terrestis coelomocytes were maintained viable and uncontaminated for 10 days at 15°C in medium L-15 supplemented with 5 to 10% fetal bovine serum. The coelomocytes survived for at least 10 days with 85% viability as assessed by trypan blue exclusion assays and phagocytosis of heat-killed yeast. Studies on the thymidine uptake, however, were negative. With the involvement of coelomocytes in tissue graft rejection, in vitro techniques can now be applied to study their capacity in the immune response. Supported in part by USPHS Research Grant 1 RO 1 HD09333-01 to E. L. Cooper.     

Diverse lectin repertoires in tunicates mediate broad recognition and effector innate immune responses

It is widely recognized that humoral and phagocyte-associated lectins constitute critical components of innate immunity in vertebrates and invertebrates. Their functions include not only self/non-self recognition but also engaging associated effector mechanisms, such as complement-mediated opsonization and killing of potential pathogens. One of the unresolved questions concerns the diversity in recognition capacity of the lectin repertoire, particularly in those organisms lacking adaptive immunity. In this paper, we discuss evidence suggesting that lectin repertoire in invertebrates and protochordates is highly diversified, and includes most of the lectin classes described so far in vertebrate species, as well as associated effector pathways.     

The evolution of adaptive immune systems

A clonally diverse anticipatory repertoire in which each lymphocyte bears a unique antigen receptor is the central feature of the adaptive immune system that evolved in our vertebrate ancestors. The survival advantage gained through adding this type of adaptive immune system to a pre-existing innate immune system led to the evolution of alternative ways for lymphocytes to generate diverse antigen receptors for use in recognizing and repelling pathogen invaders. All jawed vertebrates assemble their antigen-receptor genes through recombinatorial rearrangement of different immunoglobulin or T cell receptor gene segments. The surviving jawless vertebrates, lampreys and hagfish, instead solved the receptor diversification problem by the recombinatorial assembly of leucine-rich-repeat genetic modules to encode variable lymphocyte receptors. The convergent evolution of these remarkably different adaptive immune systems involved innovative genetic modification of innate-immune-system components.