Protection from infectious bursal disease virus (IBDV)-induced immunosuppression by immunization with a fowlpox recombinant containing IBDV-VP2

Immunosuppression resulting from infectious bursal disease virus (IBDV) infection has critical health and welfare implications for birds, yet it is incompletely understood and largely overlooked as a measure of vaccine efficacy. The ability of a fowlpoxvirus recombinant (fpIBD1) containing the VP2 protein of IBDV to protect against IBDV-induced immunosuppression was investigated by measuring the convalescent chicken's ability to mount antibody responses to IBDV infection, and to inactivated IBDV and salmonella vaccines. An immunoglobulin (Ig)M response, but no IgG response, occurred after IBDV infection. Uninfected chickens produced a sustained IgM response and some IgG response to inactivated IBDV vaccine, while in previously infected birds only a transient IgM response was detected. A moderate suppression of the response to a commercial salmonella vaccine was evident after IBDV infection, which was largely prevented by immunization with fpIBD1. These results indicate that measurement of immunosuppression could be a useful strategy for assessing the efficacy of vaccines to protect against the consequences of IBDV infection.

Early replication in pulmonary B cells after infection with Marek's disease herpesvirus by the respiratory route

Abstract Natural infection with Marek's disease virus occurs through the respiratory mucosa after chickens inhale dander shed from infected chickens. The early events in the lung following exposure to the feather and squamous epithelial cell debris containing the viral particles remain unclear. In order to elucidate the virological and immunological consequences of MDV infection for the respiratory tract, chickens were infected by intratracheal administration of infective dander. Differences between susceptible and resistant chickens were immediately apparent, with delayed viral replication and earlier onset of interferon (IFN)-gamma production in the latter. CD4(+) and CD8(+) T cells surrounded infected cells in the lung. Although viral replication was evident in macrophages, pulmonary B cells were the main target cell type in susceptible chickens following intratracheal infection with MDV. In accordance, depletion of B cells curtailed viremia and substantially affected pathogenesis in susceptible chickens. Together the data described here demonstrate the role of pulmonary B cells as the primary and predominant target cells and their importance for MDV pathogenesis.

In ovo DNA immunisation followed by a recombinant fowlpox boost is fully protective to challenge with virulent IBDV

The aim of this study was to investigate the potential use of DNA vaccination delivered in ovo for protecting against challenge with infectious bursal disease virus (IBDV). Using a plasmid expressing the beta-galactosidase gene, DNA was successfully delivered to the embryo after in ovo injection and localises to the proventriculus and thymus. The coding sequence for the immunogenic IBDV protein, VP2, was cloned into pCI-neo, creating pCI-Vp2. Complete protection against IBDV was obtained by priming in ovo with pCI-Vp2, followed by boosting with the fowlpox recombinant, fpIBD1, also expressing the VP2 gene. This complete protection was not evident with either of the experimental vaccines on their own. An antibody response was not detected after the prime-boost vaccination, even after chicks had been challenged with IBDV, implying that the DNA prime delivered in ovo stimulated a protective cellular immune response.

Enhanced immunopathology induced by very virulent infectious bursal disease virus

Immunohistochemical and flow cytometric analyses of the bursa, spleen and thymus following infection with the very virulent infectious bursal disease virus (vvIBDV) strain UK661 revealed discrete differences from classical virulent infectious bursal disease virus strains. Bu-1+, immunoglobulin (Ig)M+ and IgG+ cells were all depleted from the bursa, spleen and thymus, suggesting loss of both immature and mature B lymphocytes. Small numbers of Bu-1+ cells repopulated the bursa 14 days post-infection but few of these expressed IgM or IgG. A transient increase in macrophages at 3 to 5 days post-infection was followed by a later influx of CD4+ and CD8+ T cells into the bursa. Loss of cortical thymocytes during the acute phase of infection suggested disruption of the T-cell system. The results showed that vvIBDV strain UK661 caused earlier and more severe pathology than classical virulent strains of infectious bursal disease virus. The marked influx of T cells into the infected bursa indicates that cell-mediated immunity is likely to be important in the clearance of vvIBDV.

Marek's disease is a natural model for lymphomas overexpressing Hodgkin's disease antigen (CD30)

Animal models are essential for elucidating the molecular mechanisms of carcinogenesis. Hodgkin's and many diverse non-Hodgkin's lymphomas overexpress the Hodgkin's disease antigen CD30 (CD30(hi)), a tumor necrosis factor receptor II family member. Here we show that chicken Marek's disease (MD) lymphoma cells are also CD30(hi) and are a unique natural model for CD30(hi) lymphoma. Chicken CD30 resembles an ancestral form, and we identify a previously undescribed potential cytoplasmic signaling domain conserved in chicken, human, and mouse CD30. Our phylogeneic analysis defines a relationship between the structures of human and mouse CD30 and confirms that mouse CD30 represents the ancestral mammalian gene structure. CD30 expression by MD virus (MDV)-transformed lymphocytes correlates with expression of the MDV Meq putative oncogene (a c-Jun homologue) in vivo. The chicken CD30 promoter has 15 predicted high-stringency Meq-binding transcription factor recognition motifs, and Meq enhances transcription from the CD30 promoter in vitro. Plasma proteomics identified a soluble form of CD30. CD30 overexpression is evolutionarily conserved and defines one class of neoplastic transformation events, regardless of etiology. We propose that CD30 is a component of a critical intracellular signaling pathway perturbed in neoplastic transformation. Specific anti-CD30 Igs occurred after infection of genetically MD-resistant chickens with oncogenic MDV, suggesting immunity to CD30 could play a role in MD lymphoma regression.

Study of host-pathogen interactions to identify sustainable vaccine strategies to Marek's disease

Marek's disease virus is a highly cell-associated, lymphotropic alpha-herpesvirus that causes paralysis and neoplastic disease in chickens. The disease has been contained by vaccination with attenuated viruses and provides the first evidence for a malignant cancer being controlled by an antiviral vaccine. Marek's disease pathogenesis is complex, involving cytolytic and latent infection of lymphoid cells and oncogenic transformation of CD4+ T cells in susceptible chickens. Innate and adaptive immune responses develop in response to infection, but infection of lymphocytes results in immunosuppressive effects. The remarkable ability of MDV to escape immune responses by interacting with, and down-regulating, some key aspects of the immune system will be discussed in the context of genetic resistance. Resistance conferred by vaccination and the implications of targeting replicative stages of the virus will also be examined.

The immunologists' debt to the chicken

The immune system of the chicken is an invaluable model for studying basic immunology and has made seminal contributions to fundamental immunological principles. Graft versus host responses and the key role of lymphocytes in adaptive immunity were first described in work with chicken embryos and chickens. 2. Most notably, the bursa of Fabricius provided the first substantive evidence that there are two major lineages of lymphocytes. Bursa-derived lymphocytes, or B cells, make antibodies while thymus-derived, or T cells, are involved in cell-mediated immune responses. 3. Gene conversion, the mechanism used by the chicken to produce its antibody repertoire, was first described in the chicken and requires the unique environment of the bursa. Subsequently it has been shown that some mammals also use gene conversion. 4. The chicken's Major Histocompatibility Complex (MHC), the first non-mammalian MHC to be sequenced, is minimal, compact and some 20-fold smaller than that of mammals. Uniquely, the chicken MHC is strongly associated with resistance to infectious diseases. 5. The first attenuated vaccine was developed by Louis Pasteur against a chicken pathogen, fowl cholera, and the first vaccine against a natural occurring cancer agent, Marek's disease virus, was developed for the chicken. 6. Vaccination of chick embryos on the 18th d of incubation, another breakthrough using chickens, provides protection early after hatching. In ovo vaccination now is widely practised by the poultry industry. 7. Evidence that widespread and intensive vaccination can lead to increased virulence with some pathogens, such as Marek's disease virus and infectious bursal disease virus, was first described with chicken populations. It warns of the need to develop mo resustainable vaccination strategies in future and provides useful lessons for other species, including in the human population. 8. Recombinant DNA technologies now provide the opportunity for the rational design of new vaccines. Such vaccines could contain the protective immunogenic elements from several pathogens and immunomodulatory molecules to direct and enhance immune responses so providing improved protection. The important thing will be to design vaccines that are sustainable and do not drive pathogens to ever-increasing virulence.

Resistance to Marek's disease herpesvirus-induced lymphoma is multiphasic and dependent on host genotype

Genotype-dependent differences in Marek's disease (MD) susceptibility were identified using 14-day-old line N and 6(1) (resistant) and 151 and 7(2) (susceptible) inbred chickens infected with HPRS-16 MD virus (MDV). All line 72 chickens developed progressive MD. Line 15I had fluctuating MD-specific clinical signs and individuals recovered. A novel histologic scoring system enabled indices to be calculated for lymphocyte infiltration into nonlymphoid organs. All genotypes had increased mean lesion scores (MLSs) and mean total lesion scores after MDV infection. These differed quantitatively and qualitatively between the genotypes. Lines 6(1) and 7(2) had a similar MLS distribution in the cytolytic phase, although scores were greater in line 7(2). At the time lymphomas were visible in line 7(2), histologic lesions in line 6(1) were regressing. AV37+ cells were present in similar numbers in all genotypes in the cytolytic phase, suggesting that neoplastically transformed cells were present in all genotypes regardless of MD susceptibility. After the cytolytic phase, AV37+ cell numbers increased in lines 7(2) and 15I but decreased in lines 6(1) and N. In the cytolytic and latent phases, in all genotypes, most infiltrating cells were CD4+. After this time, line 7(2) and 15I lesions increased in size and most cells were CD4+; line 6(1) and N lesions decreased in size and most cells were CD8+. In all genotypes, AV37 immunostaining was weak in lesions with many CD8+ cells, suggesting that AV37 antigen expression or AV37+ cells were controlled by CD8+ cells. The rank order, determined by clinical signs and pathology, for MD susceptibility (highest to lowest) was 7(2) > 15I > 6(1) > N.

Protection from IBDV-induced bursal damage by a recombinant fowlpox vaccine, fpIBD1, is dependent on the titre of challenge virus and chicken genotype

Expression of the VP2 capsid protein of infectious bursal disease virus (IBDV) in an vaccine strain of fowlpox has produced an experimental recombinant vaccine, fpIBD1. Successful vaccination with fpIBD1 was dependent on the titre of challenge virus for high titres of challenge virus were able to overcome protection induced by fpIBD1 whereas challenge with a low titre of virus did not. The genotype of chicken also has an important effect on the outcome of challenge possibly as a result of the major histocompatability complex and its ability to present VP2-derived peptides to the immune system. It was not possible to protect the inbred white leghorn chicken strain, line 15I, from IBDV-induced bursal damage by vaccination with fpIBD1 even at the lowest titre of challenge virus used. All other inbred white leghorn chickens examined (line 6(1), C. B4 and C.B12) and outbred Rhode Island Red chickens were protected by fpIBD1. Protection by the fpIBD1 vaccine is induced in the absence of detectable serum antibodies, suggesting the possibility of a significant role for cell-mediated immunity in protection from IBDV challenge.

A quantitative duplex PCR technique for measuring amounts of cell-associated Marek's disease virus: differences in two populations of lymphoma cells

A duplex polymerase chain reaction (PCR) was developed to measure Marek's disease virus (MDV) load in two subpopulations of Marek's disease (MD) lymphoma cells from chickens. PCR primers were designed using the sequence of the MDV-ICP4 gene and the chicken IFNgamma gene. Each set of primers was present in the same reaction tube so that the 327 bp ICP4 product and the 420 bp IFNgamma product were co-amplified. Two different fluorescent dyes were used to 5'-end label one PCR primer of each pair to distinguish the IFNgamma and ICP4 products by colour. The IFNgamma PCR product was used as an internal standard enabling comparisons of MDV-ICP4 products between different samples. Neither duplex PCR product was preferentially amplified and both reactions were in their exponential phases when stopped. The products could be distinguished by both size and colour. MD lymphoma cells were taken ex vivo and separated on the basis of expressing a novel host surface antigen recognised by the monoclonal antibody AV37. AV37 + lymphoma cells had greater MDV-loads than AV37 lymphoma cells. The principles used here should be applicable to any cell phenotype and/or cell-associated DNA virus.

Counting absolute numbers of specific leukocyte subpopulations in avian whole blood using a single-step flow cytometric technique: comparison of two inbred lines of chickens

A novel flow cytometric technique was developed to determine the absolute numbers of leukocytes of specific phenotypes in whole blood from two lines of inbred chickens (line 7(2) and line 6(1)). This single step method is rapid, accurate, repeatable, can be used in the presence of nucleated erythrocytes and addresses the problems encountered when electronically counting the numbers of leukocytes in specific subpopulations in the blood of non-mammalian species. It is superior to previous methods in that (1) peripheral blood leukocytes (PBL) do not need to be separated by density gradient centrifugation, (2) erythrocyte lysis is not necessary and (3) absolute numbers of specific phenotypes of cells are determined directly. A standard volume of diluted whole blood was added to a standard number of fluorescent beads before incubation with fluorescently-conjugated monoclonal antibodies recognising specific PBL surface antigens. Samples were analysed by flow cytometry and electronic gates were set to count a standard number of beads and the concomitant fluorescently-labelled cells. Absolute numbers of B, CD4+ and CD8+ PBL were determined. Since the bead fluorescence is constant, it was also possible to measure relative MHC class I expression using fluorescence intensity. In both lines of chickens absolute numbers of all of the phenotypes of PBL measured increased with age. Although line 7(2) chickens had greater numbers of B, CD4+, and CD8+ PBL than line 6(1) chickens, there was no significant difference in the CD4+:CD8+ PBL ratios, the T:B PBL ratios or relative MHC class I expression between the two lines. Relative MHC class I expression increased with age in both lines.

Differential susceptibility to Marek's disease is associated with differences in number, but not phenotype or location, of pp38+ lymphocytes

Flow cytometric and immunocytochemical techniques were used to quantify, identify and locate Marek's disease herpesvirus (MDV)-infected lymphocytes in lymphoid organs of infected chickens, by expression of the virus antigen pp38. Two closely related lines of chicken, one susceptible to Marek's disease (line 7(2)) and another resistant (line 6(1)), were infected at 2 weeks of age and compared at 10 sampling times between 0 and 50 days post-infection. In both lines 6(1) and 7(2), pp38+ lymphocytes were detected at 4-6 days in the spleen, thymus and bursa. pp38+ cells could not be detected from day 8 onwards. In both lines, pp38+ lymphocytes were located in the peri-ellipsoidal area of the spleen, the medulla of the thymic lobes and the medulla of the bursal follicles. In both lines, pp38+ cells were predominantly B lymphocytes, but CD4+ and CD8+ TCR alphabeta+ T lymphocytes were also detected in the thymus and spleen. For each organ, the mean number of pp38+ lymphocytes was greater in line 7(2) than in line 6(1). pp38+ lymphocytes were not detected in the peripheral blood at any time. The data show that the differential susceptibility of lines 6(1) and 7(2) to the development of Marek's disease lymphoma is not attributable to differences in phenotype or location of pp38+ lymphocytes, or the time of expression of pp38. However, susceptibility is associated with greater numbers of pp38+ lymphocytes.

The effects of cyclosporin A and cyclophosphamide on the populations of B and T cells and virus in the Harderian gland of chickens vaccinated with the Hitchner B1 strain of Newcastle disease virus

The cellular response to conjunctival vaccination with the Hitchner B1 strain of Newcastle disease virus was studied in the Harderian gland (HG) by immunohistochemistry. Bu-1+ cells and all subpopulations of T cells, (CD3+, CD4+, CD8+, TCR gamma delta, TCR alpha beta 1, and TCR alpha beta 2) were in the interstitial tissue between the ducts and the acini. Plasma cells with cytoplasmic IgM were more dispersed than the other cells and outlined the acini. Bu-1+ cells and all subpopulations of T cells increased at least three-fold after vaccination when compared to uninfected birds on the basis of the average cell counts in sections taken at 3, 5, 7, 10, 14, and 20 days after vaccination. The most marked increase was in the CD8+ cells which increased six-fold. Virus replicated for 10 days in cyclophosphamide (Cy) treated birds and for 7 days in cyclosporin A (CsA) treated birds compared with 5 days in untreated birds. Cy treatment prevented an antibody response to NDV and reduced Bu-1+ and IgM cells in the HG by 20-fold. Cy treatment resulted in a doubling of the number of T cells in the HG but these T cells may have been transiently disabled because it also caused a poor response of the lymphocytes in whole blood to the T cell mitogen concanavalin A (ConA). CsA reduced the T cell numbers in the HG and whole-blood responses to ConA by about 4-fold but T cell numbers rebounded to normal resting values after vaccination with NDV. The clearance time was prolonged either by T cells being less numerous than normal after CsA or being disabled after Cy. T cells, but not B cells, may therefore be essential for virus clearance. CD8+ cells expanded more than CD4+ cells after the vaccination of untreated and CsA-treated birds indicating that CD8+ cells may be key players in vaccinal immunity to NDV.

Marek's disease virus EcoRI-Q gene (meq) and a small RNA antisense to ICP4 are abundantly expressed in CD4+ cells and cells carrying a novel lymphoid marker, AV37, in Marek's disease lymphomas

Mature lymphomas produced in Rhode Island Red (RIR) chickens infected with the RB1B strain of Marek's disease virus (MDV) were examined for the presence of viral DNA and RNA and expression of viral antigens. In situ hybridization showed that all tumours examined contained viral DNA in areas of lymphoid infiltration. In 3/5 tumours, there was a correlation between the number and distribution of cells expressing the Marek's disease EcoRI-Q gene (meq) and those that carried the lymphoid cell marker AV37. Expression of the MDV-specific phosphoprotein pp38 was infrequent in lymphomas but abundant in a splenic tumour which also expressed the viral glycoprotein gB. Northern blot analysis of lymphocyte fractions purified by immunoaffinity showed that CD4+ and AV37+ fractions from lymphomas expressed meq and the small RNA antisense to ICP4 (SAR). The results are consistent with the notion that transformed cells are CD4+ cells, carrying the AV37 marker and expressing meq and SAR.

Monoclonal and polyclonal antibodies to chicken immunoglobulin isotypes specifically detect turkey immunoglobulin isotypes

Turkey immunoglobulin (Ig) isotypes IgG and IgM were isolated from blood and IgA was isolated from bile. Isolation was accomplished by gel filtration of the ammonium sulphate cut on Sephacryl S-200. Using immunoelectrophoresis and indirect ELISA, the cross-reactivity between antibodies, of monoclonal and polyclonal origin, specific for the Ig isotypes of chicken, and the purified turkey Ig isotypes was evaluated. Commercially available polyclonal antibodies, anti-chicken/IgA (alpha-chain specific, affinity purified), anti-chicken/IgG (Fc-fragment specific) and anti-chicken/IgM (mu-chain specific) showed an interspecies cross-reactivity with the corresponding turkey Ig isotypes. The monoclonal antibody (MAb) AV-G3 specifically detected turkey IgG, whereas MAb M1 reacted exclusively with turkey IgM. This panel of anti-immunoglobulins represents a useful tool for examining the humoral immune responses of turkeys.

Identification of chicken Bu-1 alloantigens using the monoclonal antibody AV20

The genetically polymorphic chicken antigen Bu-1 (chB6) has been identified by alloantisera raised against RPL line 6(3) (Bu-1a) and line 7(2) (Bu-1b) birds and subsequently by monoclonal antibodies (mAbs) which identify individual alloantigens. We have produced a monoclonal antibody, AV20, which recognises a monomorphic determinant on the antigen Bu-1. AV20 identifies a marker on both bursal and peripheral B cells. Staining characteristics on bursa, spleen, thymus and peripheral blood lymphocytes are similar to those of the allotypic antibodies which identify Bu-1a and Bu-1b. However, AV20 identified B cells in partially inbred birds as well as inbred lines including line 6(1) and line 7(2), indicating that it recognises a monomorphic determinant, AV20 immunoprecipitated an antigen with a Mwr of 150 kDa under non-reducing conditions and 70-75 kDa under reducing conditions indicating it is a homodimer. Serial immunoprecipitations or bursal-cell lysates from line 6(1) or line 7(2) confirmed that AV20 recognised the same antigen as mAbs against Bu-1a and Bu-1b in the respective lines.

Chicken B-cell marker chB6 (Bu-1) is a highly glycosylated protein of unique structure

The chB6 molecule is expressed on chicken B cells throughout most of their development, as well as on some non-lymphoid cells. It has long been used as an allotypic marker in important studies of B-cell development, though its function is unknown. We isolated a chB6 cDNA by expression cloning and sequenced two further alleles following polymerase chain reaction amplification. The results show that chB6 is a typical type I transmembrane protein, highly glycosylated in the extracellular region and carrying a large intracellular region. It has no recognizable similarity to known mammalian molecules and thus represents a unique B-cell marker. Its presence in chickens may be related to differences in the properties of B-cell development between chickens and mammalian species. The sequences of the different alleles of this gene revealed a higher level of polymorphism than expected. A restriction fragment length polymorphism linked to the CHB6 gene has been used to determine its location on the linkage map of the chicken genome, which will allow the definitive evaluation of reported associations with disease resistance.

Differences in distribution of lymphocyte antigens in chicken lines divergently selected for antibody responses to sheep red blood cells

The proportion of cells showing differentiation antigens specific for T cells, B cells and leukocytes was studied at various ages in peripheral blood, and at 14 weeks of age in the bursa of Fabricius, spleen and thymus of two lines of chicken that had been selected over 13 generations for either high (H) or low (L) antibody responses to sheep red blood cells (SRBC), and also in a randombred control (C) line. Flow cytometry showed no consistently significant differences between the three lines in numbers of circulating lymphocytes and other leukocytes after hatching. However, higher percentages of CD4+ cells and B cells were present in the spleen and thymus from the H line compared with the L line. However, the L line was characterized by a higher proportion of splenic CD8+ cells and spleen cells expressing gamma-delta T-cell receptors. Immunization with sheep red blood cells had no effect on the distribution of CD4+ or CD8+ cells in the various tissues at 2 and 7 days after immunization. These results suggest that previously reported differences in in vivo immune responses between these chicken lines may be related to the differences in resident T-lymphocyte subpopulations in the lymphoid tissues. The involvement of T-cell subsets and non-antigen-specific mechanisms in divergent selection on humoral immune responses in chickens is discussed.

Identification and analysis of the expression of CD8 alpha beta and CD8 alpha alpha isoforms in chickens reveals a major TCR-gamma delta CD8 alpha beta subset of intestinal intraepithelial lymphocytes

Expression screening has been used to clone cDNAs encoding the alpha- and beta-chains of chicken CD8. Amino acid sequence similarities with the mammalian sequences were about 30%. Many amino acid residues of structural or functional importance were more highly conserved, as were the overall structures of both chains. Like human CD8 alpha, the chicken alpha-chain lacked sites for N-linked glycosylation, but the beta-chain contained three such sites. In COS cells transfected with CD8 beta cDNA, surface expression of the beta-chain was dependent on co-transfection of the alpha-chain cDNA, indicating that, as in mammals, chicken CD8 can be expressed as a CD8 alpha alpha homodimer or as a CD8 alpha beta heterodimer. Immunofluorescence analysis with mAbs that were shown to identify the CD8 alpha- and CD8 beta-chains revealed that the vast majority of the CD8+ cells in the thymus, spleen, and blood of adult chickens express both CD8 alpha- and CD8 beta-chains. However, a relatively large proportion of the CD8+ TCR-gamma delta cells in the spleens of embryos and young chicks express only the alpha-chain of CD8. Among intestinal epithelial lymphocytes the major CD8+ T cell populations present in mice are conserved, but there is a population of TCR-gamma delta CD8 alpha beta cells that is not found in rodents. This observation is important in interpretation of experiments examining the pathways of development of intestinal intraepithelial lymphocytes in chickens.

Identification and analysis of the expression of CD8 alpha beta and CD8 alpha alpha isoforms in chickens reveals a major TCR-gamma delta CD8 alpha beta subset of intestinal intraepithelial lymphocytes

Expression screening has been used to clone cDNAs encoding the alpha- and beta-chains of chicken CD8. Amino acid sequence similarities with the mammalian sequences were about 30%. Many amino acid residues of structural or functional importance were more highly conserved, as were the overall structures of both chains. Like human CD8 alpha, the chicken alpha-chain lacked sites for N-linked glycosylation, but the beta-chain contained three such sites. In COS cells transfected with CD8 beta cDNA, surface expression of the beta-chain was dependent on co-transfection of the alpha-chain cDNA, indicating that, as in mammals, chicken CD8 can be expressed as a CD8 alpha alpha homodimer or as a CD8 alpha beta heterodimer. Immunofluorescence analysis with mAbs that were shown to identify the CD8 alpha- and CD8 beta-chains revealed that the vast majority of the CD8+ cells in the thymus, spleen, and blood of adult chickens express both CD8 alpha- and CD8 beta-chains. However, a relatively large proportion of the CD8+ TCR-gamma delta cells in the spleens of embryos and young chicks express only the alpha-chain of CD8. Among intestinal epithelial lymphocytes the major CD8+ T cell populations present in mice are conserved, but there is a population of TCR-gamma delta CD8 alpha beta cells that is not found in rodents. This observation is important in interpretation of experiments examining the pathways of development of intestinal intraepithelial lymphocytes in chickens.

Monomeric homologue of mammalian CD28 is expressed on chicken T cells

A mAb recognizing a 40- to 44-kDa monomeric molecule on the surface of chicken T cells was used to screen a cDNA expression library made from Con A-stimulated chicken spleen cells. The sequence of the cDNA obtained encoded a molecule having 50% amino acid sequence identity with mammalian CD28, but the cysteine residue involved in the inter-chain bridge of the mammalian CD28 homodimer was not conserved in the chicken sequence. The molecule produced in transfected COS-7 cells was also recognized by another mAb that had previously been thought to recognize an avian homologue of CD2. The sequence data establish that this molecule is a homologue of mammalian CD28 in the strict evolutionary sense.

Monomeric homologue of mammalian CD28 is expressed on chicken T cells

A mAb recognizing a 40- to 44-kDa monomeric molecule on the surface of chicken T cells was used to screen a cDNA expression library made from Con A-stimulated chicken spleen cells. The sequence of the cDNA obtained encoded a molecule having 50% amino acid sequence identity with mammalian CD28, but the cysteine residue involved in the inter-chain bridge of the mammalian CD28 homodimer was not conserved in the chicken sequence. The molecule produced in transfected COS-7 cells was also recognized by another mAb that had previously been thought to recognize an avian homologue of CD2. The sequence data establish that this molecule is a homologue of mammalian CD28 in the strict evolutionary sense.

Effect of in ovo bursectomy on the course of an infectious bronchitis virus infection in line C White Leghorn chickens

White Leghorn line C chicks were surgically bursectomised (Bx) in ovo to eliminate antibody production. After inoculation with infectious bronchitis virus (IBV) at 14 days after hatching, Bx chicks experienced a more severe and longer lasting infection than intact chicks. The severity and duration of clinical infection in the Bx chicks resembled that previously observed in the highly susceptible line 15I chicks, however no increase in mortality was observed, in contrast to the high levels of mortality recorded in IBV-inoculated line 15I chicks. After secondary challenge the degree of damage to the ciliated epithelium of the trachea was greater in the Bx chicks than in the intact chicks. The results indicate that, although antibodies play an important role in recovery from IBV infection, other immunological factor(s) may also be involved.

Use of cyproterone acetate to lower circulating corticosterone and its effects on lymphocytes in domestic fowl

Chickens were given daily injections of cyproterone acetate (CA) and the effects on plasma corticosterone, bodyweight, weights of the adrenals and lymphoid organs, numbers of circulating peripheral blood lymphocytes and their proliferation in the presence of lectins, concanavalin A (Con A) and phytohaemagglutinin (PHA), were investigated. Five daily doses of 10 or 30 mg CA kg-1 bodyweight each week over a three-week period caused a decrease in weight gain and a reduction in the relative weights of the bursa and thymus but not the spleen. There was a small decrease in the adrenals after treatment with 10 mg CA kg-1. When daily injections of CA were given over a seven-day period doses of 6 and 10 mg CA kg-1 bodyweight caused a significant (P less than 0.05) decrease in plasma corticosterone concentration after four days. However, after eight daily injections of CA a single injection of corticotrophin (10 iu ACTH kg-1) increased circulating corticosterone indicating CA had not completely blocked adrenal synthesis. CA had no effect on numbers of circulating peripheral blood lymphocytes or their ability to proliferate in the presence of Con A or PHA. The results indicate that CA is effective in lowering circulating corticosterone in the fowl but this did not affect the numbers or responsiveness of peripheral blood lymphocytes.

Effect of increased circulating corticosterone on serum and thyroidal concentrations of iodothyronines and the responses to thyrotrophin in the immature fowl (Gallus domesticus)

Four-week-old fowl were given subcutaneous implants containing a mixture of corticosterone: cholesterol (1:4, w/w) to raise serum corticosterone concentration. The effects on circulating thyroxine (T4), triiodothyronine (T3), and reverse T3 (rT3), thyroidal T3 and T4 and responses to thyrotrophin (TSH) were examined. Increased circulating corticosterone caused an increase in the plasma concentration of T4 and a decrease in T3 and rT3 indicating reduced extrathyroidal 5 and 5' monodeiodination of T4. After single injections of 0.1 IU TSH/kg body weight were given 3 and 13 days after corticosterone implants there was an increase in the T3 response and a delay and reduction in the T4 response. This may have been due to a corticosterone-induced increase in the synthesis of T3 relative to that of T4. Although the relative increase in thyroidal T3 concentration was greater 3 days after corticosterone implants were given, no significant shift in the T4:T3 ratio in the thyroid glands was observed.

The effect of exposure to 40 degrees on the heat production and the serum concentrations of triiodothyronine, thyroxine, and corticosterone in immature domestic fowl

Four-week-old fowl were exposed to 40 degrees for 35 days and the effects on the serum concentrations of triiodothyronine (T3), thyroxine (T4), and corticosterone were investigated. Changes in resting heat production, food intake, body temperature, body weight gain, and growth (both in terms of skeletal growth and weight of selected organs) were also measured. Body temperature was increased at 40 degrees, and body weight gain and skeletal growth were both reduced. The serum concentrations of T3 and T4 were reduced at 40 degrees. The decrease in serum T3 was more strongly correlated with the reduction in food intake than was the reduction in T4. Resting heat production was decreased by exposure to 40 degrees; the reduction in heat production was correlated with serum T3 and serum T4 concentrations. Exposure to 40 degrees had no effect on adrenal weight or on serum corticosterone concentration but weights of the bursa, spleen, and thymus glands were decreased. These results suggest that (a) T3 is the principle metabolically active thyroid hormone in the chicken and that the reduction in heat production at 40 degrees is related to the decline in T3; (b) the reduction in T3 is a consequence of the reduction in food intake; and (c) the response to a stressor need not involve increased adrenocortical activity.

Effects of continuous treatment with synthetic ACTH1-24 or corticosterone on immature Gallus domesticus

Immature chickens were implanted with osmotic pumps filled with ACTH1-24 or pellets consisting of mixtures of cholesterol with corticosterone (0, 10, 20 or 40% by weight). Continuous infusion of ACTH1-24 (2.2 micrograms/hr:120 micrograms/kg body wt/day) caused increases in plasma concentrations of corticosterone, glucose, cholesterol, triglyceride, and uric acid during the first week, and a reduction in weight gain, an increase in the relative weights of the adrenals and liver, and a decrease in the weights of the bursa and spleen. Treatment with pellets containing corticosterone caused dose-related increases in the plasma concentrations of corticosterone, glucose, triglyceride, and cholesterol, an increase in liver size, and a decrease in the size of the bursa and spleen. Thus the effects of ACTH1-24 are probably almost entirely mediated by corticosterone. During the second week of treatment with ACTH or corticosterone the plasma corticosterone concentration was lower than during the first week. Replacing corticosterone implants at Day 7 did not cause plasma corticosterone concentration to return to that observed in the first week suggesting increased removal of the hormone from the circulation. This response resembles the stress-induced change in circulating corticosterone and may be part of the process of adaptation.

Endocrine changes in the fowl during infection with Eimeria maxima

Plasma concentrations of thyroxine (T4), triiodothyronine (T3), prolactin, growth hormone and corticosterone were measured in immature domestic fowl which were infected with Eimeria maxima, uninfected but given the same amount of food as those infected (pair-fed) or fed ad libitum. Infection with E maxima caused a decrease in plasma T4 concentration whereas pair feeding caused an increase when food intake was minimal. Plasma T3 concentrations were decreased similarly in both infected and pair-fed birds. Infection caused an increase in plasma prolactin concentration, whereas pair-feeding did not. The plasma concentration of growth hormone was not affected by any of the treatments. Plasma corticosterone concentration was markedly increased on days 5 and 6 in pair-fed birds but was not affected by infection with E maxima.

The effect of a single injection of thyrotrophin on serum concentrations of thyroxine, triiodothyronine, and reverse triiodothyronine in the immature chicken (Gallus domesticus)

Immature domestic fowl were given a single injection of 0.1 or 0.25 IU bovine thyrotrophin (TSH)/kg body wt by the intramuscular route and serum concentrations of thyroxine (T4), 3,5,3'-triiodothyronine (T3), and 3,3',5'-reverse T3 (rT3) were measured during the following 24 hr. The increase in T4 was markedly greater than that of T3. Serum rT3 concentration increased after an injection of 0.25 IU TSH/kg but the maximal concentration (75 pg/ml) was very low.

Effect of Iodide, methimazole, and thyroxine on thyroidal accumulation of radioiodide in immature domestic fowl

Accumulation of radioiodide by the thyroids of individual domestic fowl was measured with the technique described by T. F. Davison, J. G. Rowell, and J. Rea, [1981) J. Endocrinol. 89, 371-378). Radioiodide uptake was markedly decreased in birds given an excess of iodide in the drinking water (60 mg KI/liter) or injections of thyroxine (T4: 5 X 50 micrograms T4/kg body wt), in agreement with published findings. Treatment with a goitrogen (250 mg methimazole/liter drinking water) decreased 125I uptake for at least 8 days but thereafter uptake increased and this was accompanied by gross thyroidal enlargement. The results indicate that the thyroid partly compensates for goitrogenic inhibition.

Effects of dietary corticosterone on the growth and metabolism of immature Gallus domesticus

Four-week-old chicks were fed on diets containing corticosterone (0, 5, 10, 20, and 40 mg/kg) for 9 days. Food intake, weight gain, plasma concentrations of corticosterone and other constituents, some organ weights, and adrenal cholesterol concentration were measured. Plasma corticosterone concentration was increased (P less than 0.05) by dietary corticosterone, particularly at the two highest rates of inclusion. The concentrations of glucose, cholesterol, triglyceride, protein, and uric acid in the plasma increased (P less than 0.05) with increasing concentrations of dietary corticosterone. Growth rate and relative weight of the cloacal bursa declined (P less than 0.05), while the relative weight of the liver increased (P less than 0.01), with increasing dietary corticosterone; relative weights of the spleen and adrenals were not significantly affected, nor was the adrenal concentration of cholesterol. Abdominal fat was increased sixfold by the two highest corticosterone concentrations.

Effects of dietary corticosterone on peripheral blood lymphocyte and granulocyte populations in immature domestic fowl

Four-week-old chickens were fed on diets containing 0, 5, 10, 20 and 40 mg corticosterone per kg for eight days. Packed cell volume (PCV), the numbers of granulocytes (G) and lymphocytes (L), the G:L ratio and plasma corticosterone concentration were measured. Plasma corticosterone concentration was increased by dietary corticosterone from day 2 onwards. The number of lymphocytes was increased by serial bleeding but dietary corticosterone depressed the response and caused a dose-related lymphocytopenia from day 1. There was a dose related increase in granulocytes from day 4 and a dose-related increase in G:L ratio from day 1. A dose-related increase in PCV was evident only on days 2 and 4. Correlation coefficients showed little evidence of relationships between plasma corticosterone concentrations and the recorded blood variables.

Changes in plasma iodohormone concentrations during the day before hatching in Gallus domesticus

Plasma concentrations of thyroxine (T4) and triiodothyronine (T3) were measured at the onset of breathing, clicking and hatching in unstimulated chick embryos. There was a progressive increase in plasma T3 concentration from the onset of breathing (482 hr of incubation) to hatching (496 hr). Plasma T4 concentration did not change significantly between the start of breathing and clicking (494 hr) but decreased between the onset of clicking and hatching. Embryos stimulated with artificial clicks hatched 19 hr before their unstimulated counterparts but their plasma concentrations of T3 and T4 did not differ at hatching from those of unstimulated embryos; however, the plasma T3 concentration, but not T4, at hatching was higher than in unstimulated embryos incubated for a similar length of time, i.e. to the onset of breathing.

A comparison of the effects of infection with Eimeria maxima and dietary restriction on weight gain, plasma metabolites and liver glycogen in the immature fowl, Gallus domesticus

The effects of Eimeria maxima or restricted pair-feeding on weight gain, plasma concentrations of protein, glucose, free fatty acids (FFA) and uric acid and liver glycogen were compared in immature fowl. Food intake/kg body weight and weight gain decreased during the acute phase of infection (days 5-7) while weight loss was prolonged for an extra day compared with pair-fed birds. During recovery, food intake/kg body weight of infected birds was greater than that of non-infected controls but there was no evidence for an increase in growth rate compared with controls when body weight was considered. Growth rate of pair-fed birds was greater than that of infected birds during recovery, indicating their better use of ingested food. Liver glycogen and plasma protein concentration were decreased during the acute phase of infection but the concentrations of plasma glucose, free fatty acid (FFA) and uric acid were not affected. In pair-fed birds liver glycogen was depleted, concentrations of plasma glucose and uric acid decreased and FFA increased, and these changes persisted for the remainder of the experiment. The findings are similar to those in birds whose food has been withheld and were probably due to the pattern of food intake imposed by the experimental protocol. It is concluded that the metabolic differences between infected and pair-fed birds are of doubtful significance.

Thyroid function in relation to trimethylamine oxidation in immature domestic fowl fed on rapeseed meal

1. Two groups of 12-week-old female chicks were selected for their ability to oxidise 14C-trimethylamine (TMA) after being fed on a diet containing 100 g high-glucosinolate rapeseed meal (RSM)/kg for 14 d. A third group (control) was fed on a rapeseed-free diet. Measurements of thyroid activity and hepatic TMA activity were made after a further week on the diets. 2. After feeding RSM, hepatic TMA oxidase oxidase was very low (P less than 0.001) in one group (sensitive) but was unaffected in the other group (resistant). Thyroid size was increased in both groups receiving RSM but was larger (P less than 0.001) in sensitive birds. 3. Plasma half life of thyroxine (T4) and its metabolite clearance rate were not affected by feeding RSM; thyroidal secretion was reduced (P less than 0.05) to the same extent in both groups. 4. Plasma concentration of triiodothyronine was decreased in both groups after feeding RSM (P less than 0.05); plasma T4 concentration was increased (P less than 0.05) only in sensitive birds. 5. The results indicate that the short-term depression of TMA oxidation in birds sensitive to RSM is not mediated by the thyroid.

Estimation of thyroidal radioiodide clearance in the domestic fowl (Gallus domesticus)

A method for estimating thyroidal clearance of radioiodide from the blood plasma of the domestic fowl is described. It differed from published methods in a number of ways. (1) It utilized total thyroid radioiodide concentration (IT) and did not require the use of goitrogens or the separation of free and protein-bound components. (2) Radioiodide was injected intravenously rather than by other routes. (3) Plasma radioiodide concentration (IB) was determined from several serial samples from each bird rather than once only. (4) The method allowed the clearance constant (kappa; microliter/min per mg) to be estimated for individual birds, rather than from groups, thereby enabling effective replication for comparative experiments. The constant was estimated from the model dIT/dt = kappaIB, measurements being made within 120 min after injection to ensure that exit of radioiodide from the thyroid was negligible. The improved method resulted in estimates of clearance constants which agreed well with published findings.

Changes in the peripheral blood leucocyte populations following an injection of corticotrophin in the immature chicken

Three-week-old chickens were given an injection of corticotrophin (ACTH) (30 iu/kg) and changes in the plasma concentration of corticosterone and the numbers of peripheral blood leucocytes (PBL) were determined over a 32 hour period. Plasma corticosterone concentration increased to a peak after two hours but was within the normal range after eight hours. The PBL response was biphasic, a leucopenia after one hour and a marked leucocytosis between four and 12 hours after injection of ACTH. The leucopenia, caused by a reduction in the number of circulating lymphocytes, was significant at one and two hours; the leucocytosis was caused by a large increase in the number of polymorphonuclear cells. There were no consistent changes in the numbers of basophils, eosinophils or large mononuclear cells.

The effect of an injection of corticotrophin on plasma concentrations of corticosterone, growth hormone and prolactin in two strains of domestic fowl

1. Three-week-old Light Sussex (LS) and Rhode Island Red (RIR) chicks were injected with long-acting corticotrophin (ACTH: 30 IU/kg) and the plasma concentrations of corticosterone, growth hormone (GH) and prolactin were determined over a 6-h period. Plasma concentrations of corticosterone and growth hormone were also measured after an injection of corticosterone (500 microgram/kg). 2. The resting plasma concentration of corticosterone in LS was less than that in RIR birds. The increase elicited by ACTH was smaller in LS but, since it was maintained for longer, the plasma corticosterone response was at least 18% larger than that in RIR birds. 3. Plasma GH concentration was decreased after an injection of ACTH in both strains but the decrease lasted longer in the LS chicks. 4. Plasma prolactin concentration was unaffected by ACTH. 5. After intra-abdominal injection of corticosterone, plasma GH concentration was depressed in both strains. It is concluded that ACTH-induced depression of plasma GH and growth is mediated by corticosterone.

Effect of daily injections of ACTH on growth and on the adrenal and lymphoid tissues of two strains of immature fowls

1. The effects of daily injections of ACTH (30 IU/kg) or physiological saline on growth and on adrenal and lymphoid tissues of Rhode Island Red (RIR) and Light Sussex (LS) chickens were compared at 1, 2 and 3 weeks of age. 2. Saline injections retarded skeletal growth in both strains during the 1st week but only affected weight gain in LS birds. 3. Injections of ACTH depressed growth rate, caused adrenal enlargement and deplenished adrenal cholesterol to the same extent in both strains. 4. ACTH caused a greater reduction in bursal size in RIR than in LS birds. Spleen size was reduced by ACTH only in RIR birds. 5. At 2 and 3 weeks the plasma concentrations of corticosterone of RIR birds were greater than those of LS birds. Plasma corticosterone concentrations were within the normal range 24 h after the last injection of ACTH in both strains. 6. Plasma concentrations of growth hormone was unaffected by ACTH treatment in RIR birds, but it was increased in LS birds after 3 weeks of treatment.