Cultivation and characterisation of avian lymphocytes with natural killer cell activity

Poultry coccidiosis: recent advancements in control measures and vaccine development

Coccidiosis is recognized as the major parasitic disease of poultry and is caused by the apicomplexan protozoan Eimeria. Coccidiosis seriously impairs the growth and feed utilization of infected animals resulting in loss of productivity. Conventional disease control strategies rely heavily on chemoprophylaxis and, to a certain extent, live vaccines. Combined, these factors inflict tremendous economic losses to the world poultry industry in excess of USD 3 billion annually. Increasing regulations and bans on the use of anticoccidial drugs coupled with the associated costs in developing new drugs and live vaccines increases the need for the development of novel approaches and alternative control strategies for coccidiosis. This paper aims to review the current progress in understanding the host immune response to Eimeria and discuss current and potential strategies being developed for coccidiosis control in poultry.

Avian NK activities, cells and receptors

Natural killer (NK) activity has been examined in birds for over 30 years, but evidence that avian NK activity plays crucial roles in disease is only suggestive. In chickens, NK activity is mediated by TCR0 cells in the intestinal epithelium, but elsewhere subsets of alphabeta and gammadelta T cells (NKT cells) may be more important. There are few lectin-like NK receptor genes, located in the genomic region syntenic with the natural killer complex (NKC) as well as the major histocompatibility complex (MHC). In contrast, a huge number of Ig-like receptor genes are located in a region syntenic with the leukocyte receptor complex (LRC).

The effects of triodothyronine and thymulin on avian NK cytolytic activity

The effects of triiodothyronine (T3), thymulin, and recombinant chicken interferon-y (ChIFN-gamma) on natural killer (NK) cell cytotoxicity was investigated using the euthyroid control K and the T3-deficient sex-linked dwarf (SLD) chicken strains. Factorial design experiments were used to investigate the effects of T3 treatments where animals of both strains received either 0 or 0.1 ppm T3 supplementation to the standard chick starter diet. The ChIFN-gamma treatments were administered in vitro by incubation with effector cells overnight prior to the addition of the RP9 lymphoblastoma target cell line. All cytotoxicity assays were run at 50:1 and 25:1 effector/target (E/T) ratios. Treatments were begun at hatching and continued through 7 weeks. NK cells for these assays were enriched by separation of splenocytes over ficoll. Splenocyte preparations from untreated K strain consistently had significantly higher NK-mediated cytolysis than did samples from the untreated SLD at both E/T ratios. T3 treatment alone had no effect on NK activity in cell preparations from the K strain but did significantly enhance that activity in the T3-deficient SLD whereas IFN treatment alone enhanced NK activity in both strains. The combined T3 and IFN treatments resulted in a greater enhancement of NK cytolytic activity in both strains than any separate treatment and resulted in an elimination of differences in NK cell responsiveness between the K and SLD strains. Similar results were obtained when NK cell cultures were incubated in vitro with thymulin prior to assessing cytotoxicity. In vitro thymulin treatments alone significantly enhanced cytolytic activity for NK cells for both K and SLD strains. The greatest effect of in vitro thymulin exposure was to increase the responsiveness to NK cells to ChIFN-gamma stimulation.

Production and characterization of monoclonal antibodies detecting chicken interleukin-2 and the development of an antigen capture enzyme-linked immunosorbent assay

Eleven monoclonal antibodies (mAbs) which are specific for chicken interleukin-2 (chIL-2) were produced and characterized by enzyme-linked immunosorbent assay (ELISA), Western blotting and neutralizing assays. These mAbs were used to develop a mAb-based antigen capture ELISA specific for chicken IL-2 detection. Anti-IL-2 mAbs bound specifically to E. coli-derived rchIL-2 in ELISA and identified a 16kDa IL-2 polypeptide band in Western blot. Several mAbs were shown to neutralize the biological activities of both rchIL-2 and native chicken IL-2 as measured by concanavalin A (ConA)-induced lymphocyte proliferation assay, IL-2 bioassay, and natural killer cell assay. Among the neutralizing mAbs, the mAb chIL-2/11 was most potent in neutralizing IL-2 activity. To develop a sensitive ELISA for the detection of chicken IL-2, an antigen capture ELISA was developed using the mAb chIL-2/16 as the antigen capture antibody and rabbit anti-IL-2 peptide antibody as the detection antibody. Using the mAb-based antigen capture ELISA, significant correlation between the level of IL-2 detected in bioassays and in ELISA was observed. These results showed that the mAb-based antigen capture ELISA is less time-consuming and more reliable compared to a conventional IL-2 bioassay for chicken IL-2. These neutralizing mAbs will facilitate basic immunobiological studies of the role of IL-2 in normal and disease states in chickens.

Defence mechanisms against viral infection in poultry: a review

Defence against viral infections in poultry consists of innate and adaptive mechanisms. The innate defence is mainly formed by natural killer cells, granulocytes, and macrophages and their secreted products, such as nitric oxide and various cytokines. The innate defence is of crucial importance early in viral infections. Natural killer cell activity can be routinely determined in chickens of 4 weeks and older using the RP9 tumour cell line. In vitro assays to determine the phagocytosis and killing activity of granulocytes and macrophages towards bacteria have been developed for chickens, but they have not been used with respect to virally infected animals. Cytokines, such as interleukin (IL)-1, IL-6 and tumour necrosis factor (TNF)-alpha, are indicators of macrophage activity during viral infections, and assays to measure IL-1 and IL-6 have been applied to chicken-derived materials. The adaptive defence can be divided into humoral and cellular immunity and both take time to develop and thus are more important later on during viral infections. Various enzyme-linked immunosorbent assays (ELISAs) to measure humoral immunity specific for the viruses that most commonly infect poultry in the field are now commercially available. These ELISAs are based on a coating of a certain virus on the plate. After incubation with chicken sera, the bound virus-specific antibodies are recognized by conjugates specific for chicken IgM and IgG. Cytotoxic T lymphocyte activity can be measured using a recently developed in vitro assay based on reticuloendotheliosis virus-transformed target cells that are loaded with viral antigens, e.g. Newcastle disease virus. This assay is still in an experimental stage, but will offer great opportunities in the near future for research into the cellular defence mechanisms during viral infections.

Production and in vitro characterization of recombinant chicken interleukin-2

Mammalian interleukin-2 (IL-2) is a well-characterized cytokine that plays key roles in T cell differentiation and activation, B cell development, and natural killer (NK) cell stimulation. Chicken IL-2, which is the first nonmammalian IL-2 cloned, differs substantially from mammalian IL-2 molecules. We undertook to study the functions of chicken IL-2 by producing recombinant molecules in prokaryotic and eukaryotic expression systems, determining the in vitro properties of these molecules, and examining the kinetics of endogenous IL-2 production in vitro. Recombinant chicken IL-2 (rChIL-2) produced in prokaryotic and eukaryotic expression systems induced proliferation of chicken splenocytes in vitro, demonstrating that glycosylation is not required for this activity. Polyclonal antibodies generated against prokaryotically produced rChIL-2 inhibited proliferation of splenocytes induced by eukaryotically and prokaryotically produced rChIL-2, as well as endogenously produced cIL-2 obtained from ConA-stimulated splenocytes. Human IL-2 or IL-15-induced CTLL proliferation was not blocked by rChIL-2 or polyclonal anti-rChIL-2 antibodies, indicating that chicken IL-2 cannot act as an antagonist of the mammalian IL-2 response. Endogenous chicken IL-2 appears to occur in vitro as a monomer of about 14.2 kDa and is secreted within 4 h after ConA stimulation. The production of rChIL-2 provides us with a useful tool for studying avian immunology as well as a potential vaccine-enhancing agent.

Stages of Marek's disease virus latency defined by variable sensitivity to interferon modulation of viral antigen expression

Cytokines in conditioned medium can suppress expression of viral internal antigens (VIA) in lymphocytes latently infected with Marek's disease virus. In the present study, conditioned media produced by spleen cells stimulated with concanavalin A or by mixed-lymphocyte reaction had significantly greater (P < 0.05) VIA-suppressive activity with lymphocytes harvested from birds at 14 days post infection than with those collected at 7 days. This finding defines two stages during the latent period in which sensitivity of lymphocytes to cytokine modulation of viral expression differs. Suppression involved proteins representing immediate-early, early and late viral antigens. Physico-chemical characterization of the suppressive factor in conditioned medium was consistent with that expected of interferon. Indeed, natural interferon prepared from avian reovirus-exposed chicken embryo cells, and recombinant chicken interferon, both mimicked the activity of conditioned medium and were more suppressive with lymphocytes from the later stage of latency.

Natural killer (NK) cells in domestic animals: phenotype, target cell specificity and cytokine regulation

A comprehensive review of NK cells in animals of veterinary medical importance has not been previously published. However, these cells have a high level of immunological/medical relevance due to their role in tumour cell destruction and B-cell regulation, as well as their inhibitory activities against various parasites and bacteria. In the present review, NK cells from agriculturally important animals are characterized. Cell phenotype descriptions have shown that for each species, unique (i.e. non-cross-reactive with anti-human CD antibodies) and different monoclonals are required to identify NK cells. These cells lyse certain tumour and virus transformed target cells and, as might be expected from the diverse species compared in this review, analysis of the tissue distribution of NK cells gives highly varied results. NK cell morphology differs in these species from small agranular to large granular lymphocytes. The final area considered relates to studies on the effects of cytokines on NK function and to research identifying which cytokines (if any) are produced by NK cells during activation responses. The largest quantity of available data concerns functional and descriptive studies in these animals. However, it is appropriate to consider this research as a starting point on which to build comparative and molecular studies of the roles of NK cells in immunosurveillance and immunoregulation.

Characterization of stimulatory surface molecular expression on avian T cells

We have characterized a monoclonal antibody (AT389), produced by immunization of mice with 4-day-old avian Concanavalin A blasts, which recognizes a 38-40 kDa homodimer present on the surface of all chicken T cells. AT389 increased the spontaneous and IL-2-driven proliferation of 3-day-old T-cell blasts. This antibody, in synergy with IL-2, increased cellular proliferation and cell survival of T-cell blasts over time. Together, these data suggest that AT389 recognizes a surface protein on avian T cells which may be related to known stimulatory surface markers on mammalian T cells.

Marek's disease virus-transformed chicken T-cell lines respond to lymphokines

Current assays for chicken interleukin-2 (IL-2) utilize mitogen-activated lymphocytes. However, very high inter-assay variability and sporadic high background proliferation limit their usefulness. In view of the above, several Marek's disease virus (MDV)-transformed T-cell lines (which grow well in a serum-supplemented medium) were tested for a response to chicken IL-2 when grown in serum-free media. Five of six lines examined showed a dose-dependent proliferative response to chicken T-cell conditioned media. One line, MDCC-CU14, was chosen for further studies. In addition to the tumor cells' dose-dependent responses to semi-purified chicken IL-2, they expressed T-cell activation antigens on the cell surface. Furthermore, the level of surface expression was enhanced on cells provided IL-2. Co-incubation of the tumor cells with monoclonal antibody INN-CH-16 (specific for an antigen on the surface of activated T-cells) and IL-2 resulted in a modulation of lymphokine-induced proliferation. Together, these data suggest that signalling mechanisms in MDV T-cell tumors are intact and that these lines can be used as an assay for chicken T-cell lymphokines. Furthermore, they provide an interesting model for the study of avian and mammalian T-cell transformation. Implications for the study of Marek's disease are also discussed.

Augmentation of natural cell-mediated cytotoxic activity by supernatant from in vitro mitogen-stimulated, in vivo hormone-treated lymphocytes in immature male (K strain) chickens

Newly hatched White Leghorn male chicks were used in this study. Triiodothyronine (T3; 0.1 or 1 ppm) and Thyrotropin Releasing Hormone (TRH; 1 or 5 ppm) were added to the feed for an 8-week period starting at hatch. A fifth group received the unsupplemented diet and served as controls. Peripheral blood lymphocytes from each treatment group were cultured in vitro with or without different mitogens (PHA, Con-A, or LPS), and the culture supernatants were tested for the presence of lymphokines (LK). The natural cell-mediated cytotoxicity (NCMC) assay was carried out with or without supernatant using the standard chromium (Cr51) release assay. Control untreated chicks were used as donors for effector cells and the P815 mouse mastocytoma was used as a target. Supernatant from in vivo 1 ppm T3- or 5 ppm TRH-treated lymphocytes significantly suppressed NCMC (or cells mediating NCMC, e.g., NK cells). However, supernatant from 1 ppm T3-treated, PHA-stimulated lymphocytes significantly enhanced NK cells cytotoxicity, while supernatant from 5 ppm TRH-treated lymphocytes with PHA stimulation tended to suppress cytotoxicity. These results provide evidence supporting a regulatory role of the hypothalamo-pituitary thyroid axis on lymphokine (LK) production. The results also suggest that these hormones act on different subpopulation of lymphocytes, and therefore, the mediators released by them.

Importance of cell-mediated immunity in Marek's disease and other viral tumor diseases

Cell-mediated immune (CMI) responses to viral tumor diseases are often used as examples of the importance of antiviral and antitumor immunity in chickens. Especially, reticuloendotheliosis virus (REV) and Marek's disease herpesvirus (MDV) are used as models to study the development of cytotoxic T-lymphocytes against viral and tumor antigens and activation of natural killer (NK) cells. Major histocompatibility complex Class I-restricted, antiviral cytotoxic T-lymphocytes expressing CD4-/CD8+ markers are induced after infection with REV. Thus far, this is the only example of Class I-restricted cytotoxic T-lymphocytes in chickens. Antiviral cytotoxic T-lymphocytes may be induced by infection with MDV or by vaccination, but conclusive evidence has not yet been provided. Antitumor responses have not been demonstrated against REV-induced tumors. Although Marek's disease is often used as an example for the importance of antitumor immunity, there is a lack of convincing data demonstrating antitumor immunity mediated by cytotoxic T-lymphocytes. Activation of NK cells by MDV infection or vaccination is probably an important part of CMI responses against Marek's disease viral antigens but not against tumor antigens.

Cytotoxic T lymphocytes in reticuloendotheliosis virus-infected chickens

Cytotoxic T lymphocytes were functionally demonstrated in spleen cells from chickens 7 days post inoculation with reticuloendotheliosis virus using a Cr-release assay. Major histocompatibility complex (MHC)-restricted cytotoxicity was demonstrated using effector and target cells from two different strains of chickens of known avian MHC haplotype. Anti-viral specificity was shown and in vivo generation of MHC-restricted cytotoxicity was evaluated. Cytotoxic T cells were distinguished from macrophages and natural killer cells. Their cytotoxicity was not antibody dependent. Higher levels of cytolysis were found with cytotoxic T cells from embryonally bursectomized vs. intact chickens over a large range of effector to target cell ratios. Using monoclonal antibodies, cytotoxic T cells were further defined as Ia+ T cells by immunofluorescence, antibody plus complement-mediated lysis of effector cells and blocking of cytolysis in the Cr-release assay.

Immune response versus susceptibility to Marek's disease

It was hypothesized that the generation of activated T cells through an efficient and rapid immune response during the early pathogenesis of Marek's disease virus (MDV) infection provides a large pool of target cells for transformation. Therefore, the correlation between genetic susceptibility to Marek's disease (MD) and in vitro mitogenic responses of lymphocytes as a measure of cell-mediated immune competence and efficiency was tested. In one series of trials, spleen cells from strains of chickens with differing levels of susceptibility to MD tumors were stimulated with graded doses of Concanavalin A (Con A) or phytohemagglutin (PHA). In a second series of trials, peripheral blood lymphocytes from individual chickens within genetic strains were tested at the same time chickens were challenged with MDV to determine susceptibility. Responsiveness was determined using one-way mixed lymphocyte reaction (MLR) tests as well as mitogen stimulation. Data from the tests comparing chicken strains supported the hypothesis in some but not all cases. The S13 chickens, which are more susceptible than P2a chickens to MD, were significantly more responsive, and highly resistant N2a chickens were significantly less responsive to Con A. In contrast, five other resistant strains were either more responsive (UCD-058, OS13) or equally responsive (UCD-140, OS5, C) to Con A when compared with P2a chickens. The PHA responses were even less predictive of MD susceptibility. No general correlation was observed between responsiveness to either mitogen or MLR tests and subsequent tumor development in trials comparing individuals within strains.

Functional and biochemical characterizations of avian T lymphocyte antigens identified by monoclonal antibodies

Seven monoclonal antibodies (mAb) were used to characterize antigens present on chicken T lymphocytes and on natural killer cells by flow cytometry, radioimmunoprecipitation and by effects on cell-mediated cytotoxicity and mitogen-induced proliferation. mAb CTLA8 and 5 stained 73% of thymus, 44% of spleen and 51% of peripheral blood lymphocytes (PBL), respectively, and immunoprecipitated 65- and 45-kDa proteins from detergent extracts of 125I surface-labeled thymocytes. Pretreatment of splenic lymphocytes with mAb CTLA5 and 8 in the presence of rabbit complement (C) eliminated the concanavalin A (Con A)-induced T cell proliferative responses. mAb CTLA3, 4 and 9 stained 43% of thymus, 36% of spleen and 18% of PBL, and immunoprecipitated 33-35-kDa proteins. Pretreatment of spleen cells with mAb 4 or 9 plus C reduced, but did not eliminate, the Con A-induced proliferative response and significantly reduced both major histocompatibility complex (MHC)-restricted and non-MHC-restricted cellular cytotoxicity. mAb CTLA1 and 6 stained 58% of thymus, 13% of spleen and 19% of PBL. mAb CTLA1 and 6 immunoprecipitated a 65-kDa protein. mAb CTLA1 and 6 had no effect on the Con A-induced blastogenesis and CTLA6 caused no decrease in virus-specific cytotoxic T lymphocyte and natural killer activity. These results indicate that (a) mAb CTLA5 and 8 identify antigens on mature T lymphocytes that are similar in tissue distribution, molecular mass and function to the mammalian CD5 antigen; (b) mAb CTLA3, 4 and 9 detect the avian homologue of CD8 antigen; and (c) mAb CTLA1 and 6 identify the avian homologue of CD4 antigen.

Immune mechanisms in infections of poultry

Resistance to infectious agents may depend upon innate mechanisms or acquired immune responses. Inflammation, phagocytosis, cell-mediated immunity and antibodies are components of a complex reaction which result either in resistance or in susceptibility. Most infectious organisms stimulate immune responses within every compartment of the immune system. In rather few infections of poultry, it is possible to pinpoint a limited number of immune reactions that are primarily responsible for resistance. In some situations, autoimmunity may contribute to the pathology associated with infections.

Cultivation of avian rotaviruses in chicken lymphocytes and lymphoblastoid cell lines

Avian rotavirus isolates were used to infect normal chicken spleen cells, lymphoblastoid T cell lines transformed by Marek's disease virus, an avian leukosis virus-transformed B cell line, and a reticuloendotheliosis virus-transformed line, which is a pre-B, pre-T cell line. All five isolates tested were able to infect spleen cells and the three types of lymphoblastoid cell lines, suggesting that avian rotaviruses can infect both B and T cells. Splenic lymphocytes were considerably less susceptible to infection than chick kidney cells. Lymphoblastoid cell lines remained virus-positive during a 10-day culture period. Virus was neutralized by the addition of low dilutions of normal chicken serum and high dilutions of chicken anti-rotavirus serum.