[Problems of specific prevention of African swine fever].

This review presents the current state of the problem of development and application of the specific prevention of African swine fever (ASF) with a brief description of its etiology and pathogenesis. The unique nature of the ASF virus (ASFV) determines some limitations and the complexity of solving the problem of vaccine development. Such situation stimulated the development of highly specific diagnostic methods for rapid and accurate detection of the ASFV. In this regard, results of studies, including our own, concerning the comparative analysis of the genome of vaccine and virulent strains of the ASFV, as well as immunodiagnostic approaches to determine causes of high virulence and low protective activity of the ASFV, are briefly presented. Special attention is given to the issue related to the development of safe and effective vaccines against ASF. In this context disadvantages and possible advantages of live attenuated (LAV) and recombinant (RV) vaccines are considered in details. Results of recent studies on the assessment of the immunogenicity of genetically modified vaccines (GMV) which developed in various laboratories around the world are presented. The obtained data indicate that ASF vaccination is currently the most promising measure to stop the spread of this disease in our country and in the world, however, previous experience with ASF vaccination has revealed some problems in its development and application. The significant contribution of foreign researchers to the study of the basics of virulence of this pathogen and the study of its genes functions are noted. The possible further expansion of ASF in Europe and Asia in bordering Russia territories, as well as the established fact of the persistence of ASFV in wild boar population indicate a constant threat of its re-introduction into our country. In conclusion, the importance of developing a safe effective vaccine against ASF and the assessing of the possible risks of creating the artificial sources of the infection in nature as a result of its use is emphasized.

[Characterization of B1-cells during experimental leukomogenesis.]

BACKGROUND: Bovine leukemia causes a significant polyclonal expansion of CD5+, IgM+ B lymphocytes, known as persistent lymphocytosis (PL), in approximately 30% of infected cattle. However, it is not yet clear what happens to this subpopulation of B cells in the early period of infection of animals. PURPOSE: Quantitative characterization of IgM+ and CD5+ B cells during the immune response, which can provide important information on the mechanisms of lymphocyte priming in BLV infection. MATERIAL AND METHODS: The experiment used BLV-negative calves of black-motley breed at the age of 8 months (n = 11). Animals (n = 8) were intravenously injected with blood of a BLV-positive cow. Control calves (n = 3) were injected with saline. Studies were performed before and after infection on days 5, 7, 14, 21, 28 and 65 of the immune response. The determination of the number of B-lymphocytes in the blood was carried out by the method of immunoperoxidase staining based on monoclonal antibodies to IgM, CD5. RESULTS: As a result of the studies, it was found that the level of CD5+ B cells increases on the 14th day of the primary immune response, characterized by polyclonal proliferation of CD5+ B cells, which are the primary target for BLV. Our research data confirm that in the lymphocytes of experimentally infected cattle, surface aggregation of IgM and CD5 molecules on B-lymphocytes is absent. DISCUSSION: It is known that the wave-like nature of IgM synthesis, which was shown in previous studies, depends on a subpopulation of B1 cells. After 7 days of the immune response, IgM+ and CD5+ cells do not correlate, which shows their functional difference. The increase in CD5+ cells is probably not associated with B cells, but with T cells differentiating under the influence of the virus. CONCLUSIONS: A subset of B1 cells is the primary target of cattle leukemia virus. The 65th day of the immune response is characterized by the expansion of IgM+ B cells, a decrease in the number of CD5+ cells and a uniform distribution of receptors around the perimeter of the cells.

[Detection of specific antibodies of classes G and M to bovine leukemia virus in the blood serum.]

INTRODUCTION: Bovine leukemia is a widespread infection worldwide, the causative agent of which is the bovine leukemia virus (BLV) in structural structure and functional features similar to human T-cell leukemia virus (HTLV-1 and HTLV-2) and It is considered as an actual medical and social problem. The study of the immune response in experimentally infected calves at an early stage of the disease development, synthesis of specific antibodies of classes G and M (IgG and IgM), diagnostic informativeness of detection of IgM in cattle leukemia is relevant and determines the purpose of this study. MATERIAL AND METHODS: Samples of blood and serum of cattle: animals experimentally infected with VLCRS, patients with cattle leukemia; control negative; specific to heterologous pathogens of cattle diseases. Indirect and sandwich variant enzyme-linked immunosorbent assay (ELISA); commercial ELISA kits (IDEXX, USA; Hema LLC, FKP Kursk Biofactory Firm BIOK, Russia) for the detection of specific IgG and IgM for BLV in the agar gel immunodiffusion reaction (RID). RESULTS: The humoral immune response develops shortly after infection - by 1-8 weeks. IgM are detected starting from the 3rd day, and IgG from the 7th day after infection. Up to 97% of coincidence of positive results in RID and indirect variant of TF ELISA based on monoclonal antibodies to cattle IgM (IgMbovine) were found. DISCUSSION: The dynamics of the synthesis of antibodies of classes M and G to the glycoprotein gp 51 BLV has a dosedependent wave-like character, is consistent with the levels of increase / decrease in the absolute and relative number of leukocytes / blood lymphocytes of infected calves. FINDINGS: Serum specific IgM was detected starting 3 days after infection with BLV. Early detection of IgM in serum of cattle can be used as an additional test for the detection of sick animals.