Irradiated Non-replicative Lactic Acid Bacteria Preserve Metabolic Activity While Exhibiting Diverse Immune Modulation.

In the recent years, safety concerns regarding the administration of probiotics led to an increased interest in developing inactivated probiotics, also called "paraprobiotics". Gamma irradiation represents a promising tool that can be used to produce safe paraprobiotics by inhibiting replication while preserving the structure, the metabolic activity, and the immunogenicity of bacteria. In this study, we evaluated the ability of four strains of lactic acid bacteria (LAB: Lacticaseibacillus casei, Lactobacillus acidophilus, Lactiplantibacillus plantarum, and Lacticaseibacillus paracasei) in preserving the metabolic activity and the immune modulation of swine porcine peripheral blood mononuclear cells, after gamma irradiation or heat inactivation. Our results show that all four strains retained the metabolic activity following gamma irradiation but not after heat inactivation. In terms of immune-modulatory capacity, irradiated L. acidophilus and Lc. paracasei were able to maintain an overall gene expression pattern similar to their live state, as heat inactivation did with Lc. casei. Moreover, we show that the two inactivation methods applied to the same strain can induce an opposed expression of key genes involved in pro-inflammatory response (e.g., IFNα and interleukin-6 for Lc. casei), whereas gamma irradiation of L. acidophilus and Lc. paracasei was able to induce a downregulation of the anti-inflammatory TGFß. Taken together, our data show that immune modulation can be impacted not only by different inactivation methods but also by the strain of LAB selected. This study highlights that gamma irradiation harbors the potential to produce safe non-replicative metabolically active LAB and identifies immunomodulatory capacities that may be applied as vaccine adjuvants.

Low Dose Gamma Irradiation of Trypanosoma evansi Parasites Identifies Molecular Changes That Occur to Repair Radiation Damage and Gene Transcripts That May Be Involved in Establishing Disease in Mice Post-Irradiation.

The protozoan parasite Trypanosoma evansi is responsible for causing surra in a variety of mammalian hosts and is spread by many vectors over a wide geographical area making it an ideal target for irradiation as a tool to study the initial events that occur during infection. Parasites irradiated at the representative doses 100Gy, 140Gy, and 200Gy were used to inoculate BALB/c mice revealing that parasites irradiated at 200Gy were unable to establish disease in all mice. Cytokine analysis of mice inoculated with 200Gy of irradiated parasites showed significantly lower levels of interleukins when compared to mice inoculated with non-irradiated and 100Gy irradiated parasites. Irradiation also differentially affected the abundance of gene transcripts in a dose-dependent trend measured at 6- and 20-hours post-irradiation with 234, 325, and 484 gene transcripts affected 6 hours post-irradiation for 100Gy-, 140Gy- and 200Gy-irradiated parasites, respectively. At 20 hours post-irradiation, 422, 381, and 457 gene transcripts were affected by irradiation at 100Gy, 140Gy, and 200Gy, respectively. A gene ontology (GO) term analysis was carried out for the three representative doses at 6 hours and 20 hours post-irradiation revealing different processes occurring at 20 hours when compared to 6 hours for 100Gy irradiation. The top ten most significant processes had a negative Z score. These processes fall in significance at 140Gy and even further at 200Gy, revealing that they were least likely to occur at 200Gy, and thus may have been responsible for infection in mice by 100Gy and 140Gy irradiated parasites. When looking at 100Gy irradiated parasites 20 hours post-irradiation processes with a positive Z score, we identified genes that were involved in multiple processes and compared their fold change values at 6 hours and 20 hours. We present these genes as possibly necessary for repair from irradiation damage at 6 hours and suggestive of being involved in the establishment of disease in mice at 20 hours post-irradiation. A potential strategy using this information to develop a whole parasite vaccine is also postulated.

Advances in Irradiated Livestock Vaccine Research and Production Addressing the Unmet Needs for Farmers and Veterinary Services in FAO/IAEA Member States.

The Animal Production and Health section (APH) of the Joint FAO/IAEA Centre of Nuclear Techniques in Food and Agriculture at the International Atomic Energy Agency has over the last 58 years provided technical and scientific support to more than 100 countries through co-ordinated research activities and technical co-operation projects in peaceful uses of nuclear technologies. A key component of this support has been the development of irradiated vaccines targeting diseases that are endemic to participating countries. APH laboratories has over the last decade developed new techniques and has put in place a framework that allows researchers from participating member states to develop relevant vaccines targeting local diseases while using irradiation as a tool for improving livestock resources.

Development and evaluation of a real-time PCR panel for the detection of 20 immune markers in cattle and sheep.

The establishment of a panel of immune markers is of paramount importance to understand the different transcription patterns of infectious diseases in livestock. The array of commercially available immunological assays for cattle and sheep is currently limited, due to the lack of antibodies for these species. Even though SYBR Green based real time quantitative PCR (qPCR) is the most commonly used method to study cytokine transcription in ruminants, a lack of standardization impairs its implementation in the study of different ruminant diseases. In order to obtain reliable qPCR results, several variables need to be considered: choice of reference genes for optimal normalization, variation of annealing temperature among primer sets, and assay specificity and sensitivity. In this study, we developed and validated a panel of immune markers in bovine and ovine samples using SYBR Green based qPCR in a cost-effective way with multiple primer sets optimised to amplify at a common thermal cycling temperature. Twenty primer sets were designed to quantify immune markers (IL-1b, IL-2, IL-4, IL-5, IL-6, IL-10, IL-12, IL-13, IL-15, IL-18, IL-23, TNF-α, IFN-γ, IFN-α, Ki-67, NFkB-65, TLR-3, TLR-4, TLR-8 and Rig-1) in ovine and bovine templates. For optimal normalization and selection of suitable reference genes, primer sets that measure the transcription of five reference genes were also included in the panel. The amplification efficiency, linearity and specificity was validated for all target genes. Optimal amplification conditions were achieved in both ovine and bovine samples for all gene targets, with the exception of Ki67. Relative quantification studies were performed on ovine and bovine mRNA obtained from sheep peripheral blood mononuclear cells (PBMCs) stimulated with three different treatments (PMA/Ionomycin, Concanavalin A (Con A) and pokeweed mitogen (PWM)). Pokeweed and ConA efficiently induced gene transcription of most of the targeted genes, while PMA/Ionomycin showed a weaker induction. Finally, we further assessed usability of our panel by running it on bovine monocyte derived dendritic cells (MoDCs) stimulated with different vaccines. Results confirmed the induction of a specific pro-inflammatory gene transcription pattern by rabies vaccine, which resembles the one occurring during viral infection. Altogether, we validated the efficiency and usability of an extended real-time PCR panel that gives the possibility to rapidly measure a broad spectrum of ovine and bovine immune markers by using a single set of reagents and protocol thus representing a valid and cost-effective tool for research purposes.

Individuals with HIV-1 Subtype C Infection and Cryptococcal Meningitis Exhibit Viral Genetic Intermixing of HIV-1 Between Plasma and Cerebrospinal Fluid and a High Prevalence of CXCR4-Using Variants.

The genotypic properties of human immunodeficiency virus type 1 (HIV-1) subtype C in individuals presenting with cryptococcal meningitis (CM) are not well established. Employing single-genome amplification as well as bulk PCR, cloning and sequencing strategies, we evaluated the genetic properties of HIV-1 subtype C env in 16 antiretroviral therapy-naive study participants with CM. Eleven of the 16 participants had matched blood plasma and cerebrospinal fluid (CSF) evaluated, with the rest having either a plasma or CSF sample evaluated. Before antiretroviral therapy initiation, matched plasma and CSF-derived env sequences of all 11 participants displayed genetic intermixing between the two compartments. Overall, 7 of the 16 (∼43.8%) participants harbored CXCR4-using variants in plasma and/or CSF, according to coreceptor usage prediction algorithms. This study suggests that HIV-1 subtype C genetic intermixing between peripheral blood and the central nervous system is common in individuals presenting with CM, and that CXCR4 usage is present in one or both compartments in approximately 44% of individuals.

Bovine monocyte derived dendritic cell based assay for measuring vaccine immunogenicity in vitro.

During both human and animal vaccine development phases, animal testing is necessary to demonstrate vaccine efficacy. Since the number of antigen candidates for testing is usually large when developing a potential vaccine, it is too costly, time consuming and would involve higher risks to carry out selection using in vivo models. The currently available in vitro assays that measure immunogenicity do not adequately reproduce the in vivo state and this is especially true for vaccine research in livestock species. With this in mind, we have developed a bovine monocyte derived dendritic cell (MODC)s based assay to prime CD4 and CD8 lymphocytes in order to investigate vaccine immunogenicity in vitro. MODCs were generated, pulsed with diphtheria toxoid (DT) and co-cultured with lymphocytes for priming. Immunogenicity was measured through antigen recall when antigen pulsed MODC were re-introduced to the co-culture and proliferation of CD4 and CD8 positive lymphocytes were quantified using expressed Ki-67. Having developed the protocol for the assay, we then employed two licenced vaccines against blue tongue virus and rabies virus to validate the assay. Our results show the ability of the assay to satisfactorily measure immunogenicity in cattle. The assay could be used to identify antigens that induce CD4 and CD8 T cell responses prior to embarking on in vivo experiments and can also be used for the quality control of established vaccines in vaccine production facilities as a supplement for in vivo experiments.

Trypanosoma brucei brucei oligopeptidase B null mutants display increased prolyl oligopeptidase-like activity.

African trypanosomosis is a parasitic disease in man and animals caused by protozoan parasites of the genus Trypanosoma. Nagana, the cattle form of the disease, is caused by Trypanosoma congolense, Trypanosoma vivax and Trypanosoma brucei brucei. An option for developing vaccines and chemotherapeutic agents against trypanosomosis is to target pathogenic factors released by the parasite during infection, namely an "anti-disease" approach. One such pathogenic factor is oligopeptidase B (TbOPB), a trypanosome peptidase that hydrolyses Arg/Lys containing peptides smaller than 30 amino acid residues and is suspected to be involved in the hormonal deregulation associated with the disease. To better understand the role TbOPB plays in parasite physiology and host pathogenesis, oligopeptidase B null mutant parasites (Δopb) were generated in the T. b. brucei Lister 427 strain. Δopb Trypanosoma brucei parasites grew at a significantly faster rate in vitro, and were as virulent as wild type strains during infection in mice. Immunohistopatholgy of infected mouse testes revealed Δopb parasites in extra vascular regions showing that TbOPB is not involved in assisting T. brucei parasites to cross microvascular endothelial cells. Gelatine gel analysis of Δopb null mutants showed an increase in discrete cysteine peptidase activities when compared to wild type strains. Enzymatic activity assays were carried out to identify how closely related oligopeptidases are affected by TbOPB gene deletion. A significant increase of T. brucei prolyl oligopeptidase (TbPOP) activity was observed, but no concomitant increase in TbPOP protein levels, suggesting that a POP-like enzyme might compensate for a loss in OPB activity in Δopb null mutants.