Antibody-enhanced phagocytosis of lamprey polymorphonuclear leucocytes against sheep erythrocytes

The immune system of jawless vertebrates: insights into the prototype of the adaptive immune system

Jawless vertebrates diverged from an ancestor of jawed vertebrates approximately 550 million years ago. They mount adaptive immune responses to repetitive antigenic challenges, despite lacking major histocompatibility complex molecules, immunoglobulins, T cell receptors, and recombination-activating genes. Instead of B cell and T cell receptors, agnathan lymphocytes express unique antigen receptors named variable lymphocyte receptors (VLRs), which generate diversity through a gene conversion-like mechanism. Although gnathostome antigen receptors and VLRs are structurally unrelated, jawed and jawless vertebrates share essential features of lymphocyte-based adaptive immunity, including the expression of a single type of receptor on each lymphocyte, clonal expansion of antigen-stimulated lymphocytes, and the dichotomy of cellular and humoral immunity, indicating that the backbone of the adaptive immune system was established in a common ancestor of all vertebrates. Furthermore, recent evidence indicates that, unlike previously thought, agnathans have a unique classical pathway of complement activation where VLRB molecules act as antibodies instead of immunoglobulins. It seems likely that the last common ancestor of all vertebrates had an adaptive immune system resembling that of jawless vertebrates, suggesting that, as opposed to jawed vertebrates, agnathans have retained the prototype of vertebrate adaptive immunity.

Evolution of innate and adaptive immune systems in jawless vertebrates

Because jawless vertebrates are the most primitive vertebrates, they have been studied to gain understanding of the evolutionary processes that gave rise to the innate and adaptive immune systems in vertebrates. Jawless vertebrates have developed lymphocyte-like cells that morphologically resemble the T and B cells of jawed vertebrates, but they express variable lymphocyte receptors (VLRs) instead of the T and B cell receptors that specifically recognize antigens in jawed vertebrates. These VLRs act as antigen receptors, diversity being generated in their antigen-binding sites by assembly of highly diverse leucine-rich repeat modules. Therefore, jawless vertebrates have developed adaptive immune systems based on the VLRs. Although pattern recognition receptors, including Toll-like receptors (TLRs) and Rig-like receptors (RLRs), and their adaptor genes are conserved in jawless vertebrates, some transcription factor and inflammatory cytokine genes in the TLR and RLR pathways are not present. However, like jawed vertebrates, the initiation of adaptive immune responses in jawless vertebrates appears to require prior activation of the innate immune system. These observations imply that the innate immune systems of jawless vertebrates have a unique molecular basis that is distinct from that of jawed vertebrates. Altogether, although the molecular details of the innate and adaptive immune systems differ between jawless and jawed vertebrates, jawless vertebrates have developed versions of these immune systems that are similar to those of jawed vertebrates.

The evolution of inflammatory mediators

Invertebrates do not display the level of sophistication in immune reactivity characteristic of mammals and other 'higher' vertebrates. Their great number and diversity of forms, however, reflect their evolutionary success and hence they must have effective mechanisms of defence to deal with parasites and pathogens and altered self tissues. Inflammation appears to be an important first line defence in all invertebrates and vertebrates. This brief review deals with the inflammatory responses of invertebrates and fish concentrating on the cell types involved and the mediators of inflammation, in particular, eicosanoids, cytokines and adhesion molecules.

Identification of squalamine in the plasma membrane of white blood cells in the sea lamprey, Petromyzon marinus

It is well established that innate mechanisms play an important role in the immunity of fish. Antimicrobial peptides have been isolated and characterized from several species of teleosts. Here, we report the isolation of an antimicrobial compound from the blood of bacterially challenged sea lamprey, Petromyzon marinus. An acetic acid extract from the blood cells of challenged fish was subjected to solid-phase extraction, cation-exchange chromatography, gel-filtration chromatography, and reverse-phase high-performance liquid chromatography, with the purified fractions assayed for antimicrobial activity. Surprisingly, antimicrobial activity in these fractions originated from squalamine, an aminosterol previously identified in the dogfish shark, Squalus acanthias. Further chromatographic and mass spectrometric analyses confirmed the identity of squalamine, an antimicrobial and antiangiogenic agent, in the active fraction from the sea lamprey blood cells. Immunocytochemical analysis localized squalamine to the plasma membrane of white blood cells. Therefore, we postulate that squalamine has an important role in the innate immunity that defends the lamprey against microbial invasion. The full biochemical and immunological roles of squalamine in the white blood cell membrane remain to be investigated.

Antigen-receptor genes of the agnathan lamprey are assembled by a process involving copy choice

Jawless vertebrates have acquired immunity but do not have immunoglobulin-type antigen receptors. Variable lymphocyte receptors (VLRs) have been identified in lamprey that consist of multiple leucine-rich repeat (LRR) modules. An active VLR gene is generated by the assembly of a series of variable gene segments, including many that encode LRRs. Stepwise assembly of the gene segments seems to occur by replacement of the intervening DNA between the 5' and 3' constant-region genes. Here we report that lamprey (Lethenteron japonicum) assemble their VLR genes by a process involving 'copy choice'. Regions of short homology seemed to prime copying of donor LRR-encoding sequences into the recipient gene. Those LRR-encoding germline sequences were abundant and shared extensive sequence homologies. Such genomic organization permits initiation of copying anywhere in an LRR-encoding module for the generation of various hybrid LRRs. Thus, a vast repertoire of recombinant VLR genes could be generated not only by copying of various LRR segments in diverse combinations but also by the use of multiple sites in an LRR gene segment for priming.

Identification of two Ikaros-like transcription factors in lamprey

The jawless Agnatha (lampreys and hagfishes) represent the phylogenetically oldest order of vertebrates that are believed to lack the adaptive immune system of jawed vertebrates. In order to search for molecular markers specific for cellular components of the adaptive immune system in lampreys, we used the polymerase chain reaction (PCR) to identify genes for transcription factors of the Ikaros family in genomic DNA and cDNA libraries from two species of lampreys, Petromyzon marinus and Lampetra fluviatilis. The mammalian Ikaros-like family of transcription factors consists of five members, Ikaros, Helios, Aiolos, Eos and Pegasus, of which the first three appear to be essential for lymphocyte development. Two different Ikaros-like genes, named IKLF1 and IKLF2, were identified in lamprey. They both have the conserved exon-intron structure of seven exons and show alternative splicing like their counterparts in jawed vertebrates. The genes code for predicted proteins of 589 and 513 amino acid residues, respectively. The proteins contain six highly conserved zinc finger motifs that are 83-91% identical to the mammalian members of the Ikaros-like family. The remaining parts of the sequences are, however, mostly unalignable. Phylogenetic analysis based on the alignable segments of the sequences does not identify the orthologous gene in jawed vertebrates but rather shows equidistance of the lamprey Ikaros-like factors to each other and to Ikaros, Helios, Aiolos and Eos. Expression studies by reverse transcription (RT)-PCR and in situ hybridization (ISH), however, provide evidence for moderate expression in presumed lymphoid tissues like the gut epithelium and for high levels of expression in the gonads, especially in the ovary.

Thy-1 immunoreactivity in the larval sea lamprey (Petromyzon marinus L.), a vertebrate without a definitive thymus

Agnathans are the only vertebrates without a thymus, yet lampreys possess putative lymphocytes whose responses parallel those of T cells in gnathostomes. The phylogenetically conserved Thy-1 antigen is often associated with the thymus, thymocytes, and T cells. An immunohistochemical study, using commercial anti-rat brain Thy-1.1 antiserum and an immunoperoxidase procedure (peroxidase anti-peroxidase) was conducted to identify any Thy-1 antigenicity in various tissues of larval sea lampreys (Petromyzon marinus L.) lightly fixed in a chilled aldehyde-based solution. The primary focus of the experiment was to discover if Thy-1 immunoreactivity was associated with haemopoietic sites and (or) leukocytes. This technique permitted conventional histological sectioning, preserved tissue architecture, and retained Thy-1 antigenicity. In the haemopoietic typhlosole, the peripheral stroma and many lymphocyte-like cells stained intensely, as did similar cells in the opisthonephros, intestinal venous sinus, and liver. Immunoreactivity in the pharynx was evidenced only by weakly staining stroma in small labyrinthine subdermal foci dorsal and ventral to some external gill openings. It is proposed that if functions analogous to thymic activities exist in the larval lamprey, the typhlosole is the most likely site for their discovery.

Cytochemical characterization of leucocytes from the seawater teleost, gilthead seabream (Sparus aurata L.)

The cytochemical characterization of head-kidney and peripheral blood leucocytes of gilthead seabream (Sparus aurata L.) was studied by light and electron microscopy. Neutrophilic granulocytes show some cytoplasmic granules, which are positive for alkaline phosphatase and peroxidase but acid phosphatase negative. The scarce granules found in the cytoplasm of the circulating neutrophils and their cytochemical features seem to be indicative of an immature stage. Acidophils are also alkaline phosphatase and peroxidase positive at pH 11.0. They are strongly positive for acid phosphatase and acid phosphatase activity may thus be considered a cytochemical marker to characterize and differentiate neutrophilic from acidophilic granulocytes in this fish species. Three granule populations are characterized in the cytoplasm of the gilthead seabream acidophils: the first is positive only for peroxidase and the second contains a dense core with acid and alkaline phosphatase activities, surrounded by a thin peroxidase positive electron-dense halo. The third granule type contains an eccentric core, which is strongly positive for acid and alkaline phosphatase and peroxidase. As regards their cytochemical features, the first and second granule types seem to correspond respectively to the azurophilic and specific granules found in acidophils of mammals and could be involved in phagocytic processes, thus playing an important microbicidal role in this species. The monocytes, monocyte-macrophages and macrophages show different cytochemical features. The first have scarce acid phosphatase-positive lysosomes, while blood monocyte-macrophages and macrophages are positive for acid and alkaline phosphatases and for peroxidase; the monocyte-macrophages show scarce lysosomes.

Ultrastructural observations on peritoneal exudate cells from the striped bass

An ultrastructural study was conducted of the principal cells recovered from the peritoneal exudate of striped bass (Morone saxatilis) injected with killed Bacillus cereus. The most frequently observed cells were identified as macrophages, eosinophils, and neutrophils on the basis of comparing their structure with that reported for other fish species and higher vertebrates. All three of the types of cells were phagocytic; however, the numbers of bacteria engulfed were limited. Like other studies of this type in fish, the peritoneum of the striped bass proved to be a good source of cells for morphological investigations of phagocytosis.

The immune response in adult sea lamprey (Petromyzon marinus L.): the effect of temperature

Adult lamprey were shown to produce antigen-specific antibody in response to weekly injections of human O-type erythrocytes ('O'-RBC) at both 17 degrees C and 9 degrees C. At the higher temperature, high titre antisera were produced earlier and at a faster rate than in animals kept at 9 degrees C. Lamprey kept at 9 degrees C, after a long lag period, eventually produced titres comparable to those obtained at 17 degrees C. Lamprey immunized and maintained at 9 degrees C were capable of producing high titres of antibody in response to second injection of antigen after the primary response titre had declined.

A histological and electron-microscopic study of the cell types involved in rejection of skin allografts in ammocoetes

The rejection of skin allografts by the larval lamprey, Lampetra reissneri, was studied by light- and electron-microscopy, with particular attention to the cell types involved in the reaction. In all allografts, melanophores were destroyed within 20-60 days (the mean survival time, 36 +/- 12 days). Neither the epidermis nor the underlying collagenous lamella was invaded by host cells until the 60th day. A heavy infiltration of host leucocytes was observed in the allografts in melanophore and adipose layers and in the bundles of muscles. Throughout all stages from 10 to 60 days after the grafting, the cells of the polymorphonuclear leucocyte (PMN) series and eosinophilic granulocytes predominated, but macrophages were not observed at any stages examined. Plasma cells occurred occasionally at later stages (40-60 days) of allograft rejection, but lymphocytes were rarely found at any stages of graft rejection. These observations, combined with the recent finding of the antibody-enhanced phagocytic activity of granulocyte-series cells in the lamprey, indicate that PMNs, but not lymphocytes, function as the major effector cells in allograft rejection in this phylogenetically oldest class of contemporary vertebrates.

Electron microscopy of the leucocytes of the typhlosole in ammocoetes, with special attention to the antibody-producing cells

In an attempt to determine the role in the immune responses of the typhlosole, a hematopoietic tissue along the ventral wall of the larval lamprey Lampetra reissneri, scanning and transmission electron microscopic observations were made on ammocoetes hyperimmunized with sheep red blood cells. Besides including the cells of the erythrocyte series, this tissue also contained the following leucocytes forming an amorphous parenchyma: the cells of the granulocyte series, the most predominant cell type, possessing a markedly lobed nucleus and membrane-bounded granules of various sizes; the macrophages possessing primary and secondary lysosomes and long lamellipodia on the cell surface; the lymphocytes of a large nucleocytoplasmic ratio with a number of long, spiky microvilli, constituting a major type of rosette-forming (antigen-binding) cells; and the plasma cells possessing highly extended cisternae of rough endoplasmic reticula that are characteristic of the higher vertebrates. The immunoperoxidase technique, which employs rabbit antibodies against lamprey immunoglobulin, proved that these plasma cells do contain immunoglobulin. These results strongly indicate that the typhlosole of the larval lamprey, besides functioning as a hematopoietic tissue, is actively involved in the antibody responses. It is also stressed that the plasma cell occurs in the most primitive vertebrates as an immunologically competent cell.