Wilhelm Gerner

Porcine T lymphocytes and NK cells - an update.

Natural killer (NK) cells represent an important cell population of the innate immune system with the ability to attack spontaneously pathogen-infected and malignant body cells as well as to produce immune-regulatory cytokines. T lymphocytes belong to the adaptive immune system and perform a wide array of functions in immune regulation, inflammation and protective immune responses. In this review we summarize the current knowledge about the phenotype and functional characteristics of these two cell populations in swine. Porcine NK cells can be distinguished from T cells by the complex phenotype perforin+ CD3(-)CD4(-)CD5(-)CD6(-)CD8alpha+CD8beta(-)CD11b+CD16+. Investigations so far show that these cells have the capacity to lyse virus-infected target cells and respond to various regulatory cytokines. Such cytokines can induce interferon-gamma (IFN-gamma) production in porcine NK cells, as well as the up-regulation of effector/activation molecules like perforin and CD25. Porcine T cells can be divided into a number of subpopulations, including a prominent fraction of T cells expressing T-cell receptors (TCR) with gammadelta-chains. Like TCR-alphabeta T cells, these TCR-gammadelta T cells can express CD8alpha and MHC class II, two molecules which in swine seem to be correlated with an activation status of T cells. Functional properties of these cells seem to include cytolytic activity as well as antigen presentation; however, both aspects require further investigation. Like in other species, TCR-alphabeta T cells in swine comprise MHC class-I restricted cytolytic T cells, T-helper cells and recently identified regulatory T cells. We summarize data on the phenotype and function of these cells including memory cell formation. Current knowledge suggests that MHC class-I restricted cytolytic T cells can be identified by the expression of CD8alphabeta heterodimers. T-helper cells express CD4 as well as other activation-related markers, including CD8alpha, MHC class II and CD45RC. Porcine regulatory T cells have a phenotype similar to that of mouse and humans: CD4+CD25+Foxp3+. First results indicate that these cells can suppress proliferation of other T cells and produce IL-10. Finally, the abundant expression of swine-specific activation markers CD8alpha and MHC class II on T cells and NK cells is discussed in more detail.

Establishment and characterization of a novel canine B-cell line derived from a spontaneously occurring diffuse large cell lymphoma

Cell lines derived from spontaneous tumors serve as a research tool for cancer cell biology and new anti-cancer drug development. Isolation and propagation of canine lymphoma cell lines is difficult, thus only a few are available. Now we have established a new B-cell lymphoma cell line CLBL-1 from a dog with confirmed stage IV diffuse large cell lymphoma. Immunophenotyping of these CLBL-1 cells showed positive staining for CD11a, CD79alphacy, CD45, CD45RA, MHC II and cells were negative for CD3, CD4, CD5, CD8, CD11d, CD14, CD21, CD34, CD56 and T-cell receptor-gammadelta (TCR-gammadelta). PCR analysis for TCR-gamma and immunoglobulin heavy chain (IgH) gene rearrangements yielded a monoclonal result for the IgH gene. Furthermore, the clonality of IgH gene rearrangement was confirmed by sequencing of 16 positive bacterial clones. As canine lymphoma resembles non-Hodgkins lymphoma (NHL) in humans in many respects, this new cell line, will promote translational and comparative lymphoma research in humans and dogs.

The porcine innate immune system: an update.

Abstract Over the last few years, we have seen an increasing interest and demand for pigs in biomedical research. Domestic pigs (Sus scrofa domesticus) are closely related to humans in terms of their anatomy, genetics, and physiology, and often are the model of choice for the assessment of novel vaccines and therapeutics in a preclinical stage. However, the pig as a model has much more to offer, and can serve as a model for many biomedical applications including aging research, medical imaging, and pharmaceutical studies to name a few. In this review, we will provide an overview of the innate immune system in pigs, describe its anatomical and physiological key features, and discuss the key players involved. In particular, we compare the porcine innate immune system to that of humans, and emphasize on the importance of the pig as model for human disease.

Detection of Foxp3 protein expression in porcine T lymphocytes.

Regulatory T cells (Tregs) are potent regulators of various immune reactions. Due to the lack of Treg-specific markers their analysis had often been challenging until the discovery of the transcription factor Forkhead-box p3 (Foxp3) which serves as this highly demanded marker. So far, antibodies staining human and murine Foxp3 have been developed. This study describes the analysis of four commercially available anti-Foxp3 antibodies for reactivity with their specific antigen in cells derived from porcine lymphoid tissues. One out of the four antibodies showed selective reactivity with porcine CD25(+) T lymphocytes. The intracellular antigen was expressed on a small subset of CD25(dim) cells and the majority of the CD25(high) positive T-cell subpopulation. Intracellular antigen positive cells showed a heterogeneous expression of other leukocyte differentiation antigens. The majority belonged to the CD4(+)CD8(+) T-lymphocyte subpopulation, but were also found in the CD4(+)CD8(-) subpopulation. Another small minority was included in the CD4(-)CD8(+) T-lymphocyte subpopulation. Additionally, a small fraction of the putative Foxp3(+) cells showed an expression of MHC-II molecules. These staining patterns in three and four colour flow cytometry analyses indicated that the cells detected by a rat anti-mouse/rat-Foxp3 antibody expressed the porcine Foxp3. The expression of the putative Foxp3 protein in distinct leukocyte subsets was confirmed by molecular analysis of Foxp3 mRNA expression. Using Western blot analysis specific protein bands could only be detected in fractions that also exhibited the corresponding Foxp3 mRNA expression. These experiments also revealed that the antibody recognized a single chain protein with a molecular mass of about 45kDA similar to Foxp3 described for other species. In summary, these data strongly indicate the reactivity of this antibody with porcine Foxp3. Thereby, this rat anti-mouse/rat Foxp3 antibody presents a powerful tool for the identification of porcine regulatory T cells.

Phenotypic maturation of porcine NK- and T-cell subsets

Detailed information concerning the development of the immune system in young pigs is still rudimental. In the present study, we analyzed changes in phenotype and absolute numbers of natural killer cells, γδ T cells, T helper cells, regulatory T cells and cytolytic T cells in the blood of pigs from birth to six months of age. For each lymphocyte subpopulation, a combination of lineage and differentiation markers was investigated by six-color flow cytometry. Major findings were: (i) absolute numbers of γδ T cells strongly increased from birth until 19-25 weeks of age, indicating an important role for these cells during adolescence; (ii) phenotype of T helper cells changed over time from CD8α(-)SLA-DR(-)CD27(+) towards CD8α(+)SLA-DR(+)CD27(-) but CD45RC(-) T helper cells were found immediately after birth, therefore questioning the role of this marker for the identification of T-helper memory cells; (iii) for cytolytic T cells, putative phenotypes for early effector (CD3(+)CD8αβ(+)perforin(+)CD27(dim)) and late effector or memory cells (CD3(+)CD8αβ(+)perforin(+)CD27(-)) could be identified.

Coronavirus nsp6 proteins generate autophagosomes from the endoplasmic reticulum via an omegasome intermediate

Autophagy is a cellular response to starvation which generates autophagosomes to carry cellular organelles and long-lived proteins to lysosomes for degradation. Degradation through autophagy can provide an innate defence against virus infection, or conversely autophagosomes can promote infection by facilitating assembly of replicase proteins. We demonstrate that the avian coronavirus, Infectious Bronchitis Virus (IBV) activates autophagy. A screen of individual IBV non-structural proteins (nsps) showed that autophagy was activated by IBV nsp6. This property was shared with nsp6 of mammalian coronaviruses Mouse Hepatitis Virus, and Severe Acute Respiratory Syndrome Virus, and the equivalent nsp5-7 of the arterivirus Porcine Reproductive and Respiratory Syndrome Virus. These multiple-spanning transmembrane proteins located to the endoplasmic reticulum (ER) where they generated Atg5 and LC3II-positive vesicles, and vesicle formation was dependent on Atg5 and class III PI3 kinase. The vesicles recruited double FYVE-domain containing protein (DFCP) indicating localised concentration of phosphatidylinositol 3 phosphate, and therefore shared many features with omegasomes formed from the ER in response to starvation. Omegasomes induced by viral nsp6 matured into autophagosomes that delivered LC3 to lysosomes and therefore recruited and recycled the proteins needed for autophagosome nucleation, expansion, cellular trafficking and delivery of cargo to lysosomes. The coronavirus nsp6 proteins activated omegasome and autophagosome formation independently of starvation, but activation did not involve direct inhibition of mTOR signalling, activation of sirtuin1 or induction of ER stress.

Changes in lymphocyte populations in suckling piglets during primary infections with Isospora suis.

Isospora suis, a common intestinal parasite of piglets, causes neonatal porcine coccidiosis, which results in reduced and uneven weaning weights and economic losses in pig production. Nevertheless, there are no detailed studies available on the immune response to I. suis. The aim of this study was to carry out phenotypical characterization of lymphocytes during primary infections on day 3 after birth. Infected and noninfected piglets were investigated between days 7 and 16 after birth. Lymphocytes from the blood, spleen and mesenteric lymph nodes (flow cytometry) and of the jejunal mucosa (immunohistochemistry) were analysed. A decrease in T cells, especially with the phenotype of resting T‐helper cells, T‐cell receptor‐γδ‐T cells, and regulatory T cells in the blood, spleen and mesenteric lymph nodes was noticeable. An increase in cells with the phenotype of natural killer cells in the spleen of infected animals was found, and the subset of TcR‐γδ‐T cells was strongly increased in the gut mucosa. Our findings suggest an accelerated migration of those cells into the gut. This study provides a strong indication for the involvement of adaptive and innate immune response mechanisms in the primary immune response to I. suis, especially of TcR‐γδ‐T cells as a linkage between innate and adaptive immunity.

NKp46 expression discriminates porcine NK cells with different functional properties

So far little is known about natural killer (NK) cells in the pig due to the lack of NK cell‐specific markers. In this study, we identified the activating receptor NKp46 (CD335) in swine with newly developed monoclonal antibodies (mAbs) for more detailed studies on NK cells in this species. The NKp46 mAbs showed a specific reactivity with a distinct population of perforin+CD2+CD3−CD8α+CD16+ lymphocytes. In spleen and liver, an additional subset of CD8αdim/− lymphocytes with increased NKp46 expression was observed. Surprisingly, we could identify NKp46− cells with an NK cell phenotype in all animals analyzed. These lymphocytes showed comparable cytolytic activity against xenogeneic and allogeneic target cells as NKp46+ NK cells. In contrast, NKp46+ NK cells produced several fold higher levels of interferon‐γ (IFN‐γ) than the NKp46− cells after cytokine stimulation. Furthermore, an activation‐dependent induction of NKp46 expression in formerly NKp46− cells after stimulation with interleukin‐2 (IL‐2), IL‐12, and IL‐18 could be shown. In summary, our data indicate that NKp46 is not expressed by all porcine NK cells and that NKp46 discriminates porcine NK cells differing in regard to cytokine production, which challenges the paradigm of NKp46 as a comprehensive marker for NK cells across different mammalian species.

Expression of vascular endothelial growth factor and its receptors in canine lymphoma.

Vascular endothelial growth factor (VEGF) stimulates endothelial cell proliferation and has a pivotal role in tumour angiogenesis. The expression of VEGF and its receptors VEGFR-1 and VEGFR-2 was examined immunohistochemically in 43 specimens of canine lymphoma and in six normal lymph nodes. Western blotting and reverse transcriptase polymerase chain reaction (RT-PCR) were performed to detect VEGF protein and mRNA, respectively. VEGF protein was expressed by 60% of the tumours with diffuse cytoplasmic labelling of the neoplastic cells. Endothelial cells, macrophages and plasma cells were also immunolabelled. VEGFR-1 was expressed by variable numbers of neoplastic cells in 54% of lymphoma specimens. VEGFR-1 was also expressed by macrophages, plasma cells, reticulum cells, and vascular endothelial cells. Macrophages and lymphocytes in germinal centres of normal lymph nodes were also immunoreactive with anti-VEGF and VEGFR-1. Most tumours did not express VEGFR-2 but in 7% of sections there was focal labelling of neoplastic and endothelial cells, with a cytoplasmic and perinuclear pattern. The observed variability in expression of VEGF and its receptors probably relates to the fact that lymphoma is a heterogeneous lymphoproliferative tumour. Individual differences in VEGF and VEGFR expression must be taken into account when VEGF and VEGFR-targeted approaches for anti-angiogenic therapy are considered in dogs.

Porcine CD27: identification, expression and functional aspects in lymphocyte subsets in swine.

Up to now for Swine Workshop Cluster 2 (SWC2) the orthologous human CD molecule was unknown. By use of the SWC2-specific mAb b30c7 and a retroviral cDNA expression library derived from stimulated porcine peripheral blood mononuclear cells we could identify SWC2 as porcine CD27. Phenotypic analyses of lymphocytes isolated from blood and lymphatic organs revealed that mature T cells in thymus and T cells in the periphery with a naïve phenotype were CD27(+). However, within CD8α(+) T helper and CD8α(+) γδ T cells also CD27(-) cells were present, indicating a down-regulation after antigen contact in vivo. B cells lacked CD27 expression, whereas NK cells expressed intermediate levels. Furthermore, plate-bound mAb b30c7 showed a costimulatory capacity on CD3-activated T cells for proliferation, IFN-γ and TNF-α production. Hence, our data indicate an important role of porcine CD27 for T-cell differentiation and activation as described for humans and mice.