Definition and biological significance of the major histocompatibility system (MHS) in man and animals

Reproductive immunology in viviparous mammals: evolutionary paradox of interactions among immune mechanisms and autologous or allogeneic gametes and semiallogeneic foetuses

Literally, reproductive immunology was born in bovine on-farm reproduction where seminal experiments intended for developing methods for embryo transfer in cattle were performed. Actually, these experiments led to two of major concepts and fundamental principles of reproductive immunology using the bovine species as a model for biomedical research, namely the concept of acquired immunological tolerance and the paradox of the semiallogeneic bovine foetus whereby such organism can develop within an immunologically competent host. Peter Medawar, a scientist who together with Frank Macfarlande Burnet shared the 1960 Nobel Prize in physiology or medicine for discovery of acquired immunological tolerance, while studying dizygotic cattle twins, thereby giving birth to reproductive immunology. Also, these findings significantly influenced development of organ transplants and showed that using farm animals as models for studying transplantation immunology had general relevance for mammalian biology and health including those of humans. However, the interest for further research of the fascinating maternal immune influences on pregnancy and perinatal outcomes and of the prevention and treatment of immunologically mediated reproductive disorders in viviparous mammals of veterinary relevance by veterinary immunologists and reproductive clinicians have been very scarce regarding the application of nonspecific immunomodulatory agents for prevention and treatment of subfertility and infertility in pigs and cattle, but still broadening knowledge in this area and hold great potential for improving such therapy in the future. The aim of the current overview is to provide up-to-date information and explaining/translating relevant immunology phenomena into veterinary practice for specialists and scientists/clinicians in reproduction of animals.

Major histocompatibility complex antigens in normal, acanthotic and neoplastic ovine skin: an association been tumor invasiveness and low level MHC class I expression

The distribution and density of ovine MHC class I and class II antigens in normal, acanthotic and malignantly transformed ovine skin was investigated using monoclonal antibodies and an immunoperoxidase technique. The subjects were sheep that had been exposed to high levels of sunlight for more than 6 years. The expression of MHC class II antigens in the plasma membrane of cells within the normal epidermis was restricted to basally located dendritic and mononuclear cells. Normal keratinocytes did not express MHC class II antigens. However, we observed low levels of intracellular MHC class II expression in both acanthotic and neoplastic keratinocytes. Expression of MHC class I antigens was variable in normal and acanthotic epithelium; it was usually present, but of low intensity in very early ovine squamous cell carcinoma and was increased in small, but morphologically typical, tumors. Tumors originating on the nose, which are more invasive than those on the ear, were found to express significantly less MHC class I (P < 0.05). Thus, an association between tumor invasiveness and low level expression of MHC class I was apparent. This may have diagnostic value and highlights a mechanism by which neoplastic cells may evade immune surveillance by T cells.

Function and regulation of lymphocyte-mediated immune responses: relevance to bovine mastitis

Bovine mastitis is one of the most costly diseases to the dairy industry. Prospects for effective vaccines are limited by the variety of microorganisms capable of causing mastitis. An understanding of the physiologic and immunologic factors controlling the susceptibility of the cow to disease will lead to more rational approaches to prevention and control. In this paper, we describe the basic components of the immune system, drawing upon information derived from studies with rodents and humans. Some of these findings have been confirmed in the bovine and other domestic species, and it is likely that further study will reveal additional similarities between the immune systems of laboratory animals, humans, and domestic animals. Some important differences have already been identified, such as altered lymphocyte circulation patterns in ruminant versus non-ruminant species. These differences are discussed. We describe the structural and functional properties of major histocompatibility complex antigens and their role in regulation of immune responses. Finally, we discuss the consequences of antigen-induced activation of T-lymphocytes and the role of these cells in response to disease-causing microorganisms.

Monoclonal antibodies to sheep MHC class I and class II molecules: biochemical characterization of three class I gene products and four distinct subpopulations of class II molecules

The availability of a panel of monoclonal antibodies to sheep MHC class I and class II gene products has allowed for the first time an assessment of the relative complexity of the sheep MHC. By using four monoclonal antibodies to MHC class I, and seven monoclonal antibodies to MHC class II molecules together with one-dimensional SDS-PAGE, sequential immunoprecipitation and 2-dimensional gel analysis, three class I gene products and four distinct subsets of class II molecules have been identified. Sheep class I molecules showed heterogeneity on 2-dimensional gels and as in mouse and man, represented the products of at least three different non-allelic class I genes. Interestingly, the sheep beta 2 microglobulin molecule also displayed heterogeneity, consistent with either two primary gene products or allelic variation. Four sheep class II monoclonal antibodies identified distinct, non-overlapping subsets of sheep class II molecules of Mr 32-36 K (alpha chain) and 25-28 K (beta chain). These class II molecules were co-expressed on sheep B lymphocytes and represented the primary products of different sheep MHC class II genes. The class II molecules within three of these subsets displayed allelic polymorphism essentially restricted to their beta polypeptides, while the fourth subset of class II molecules showed allelic variation in both their alpha and beta polypeptides. The results of this study represent the first evidence for gene duplication and heterogeneity within the sheep MHC. The identification of three primary class I gene products and four distinct subsets of class II molecules suggests three class I loci and up to four distinct class II subregions within the sheep MHC. Potentially large numbers of allelic variants of these different gene products may be expressed in normal sheep.

Characterization of species and strains of Theileria

A variety of methods is now available for characterizing species and strains of Theileria. For many practical purposes involving field control of theileriosis, characterization on a broad basis may be sufficient, but in other areas much more precise characterization is required. Such precision can be usefully exploited only when cloned parasite populations are involved, and methods to improve parasite characterization and parasite cloning should be developed concurrently. The current methods of immunization against theileriosis involve the use of live parasite populations which are generally poorly defined and, in addition, have the capacity to undergo biological change (by selection, mutation or genetic recombination) within hosts and vectors. Such changes may be difficult to define and identify, but could have profound effects on immunization strategies. Improved methods of parasite characterization and selection, which are now becoming available, will enable parasite stocks for immunization to be identified and selected more precisely, and any biological changes that occur can be monitored. Improved methods of parasite characterization will also open the way to a better understanding of Theileria genetics and the mechanisms of heritability, which appear to differ in some fundamental ways from patterns of Mendelian inheritance. Controlled matings between selected and defined populations of parasites can be envisaged, with the aim of producing hybrid parasites for immunization. In addition, the prospects of modifying the theilerial genome by genetic manipulation become very real: transfection vectors tailored by restriction enzymes could be used to insert or modify gene sequences to develop parasites with appropriate sets of characters. It may also be possible to identify parasite genes which trigger the cytotoxic response which is so important in immunity (Eugui and Emery, 1981; Emery et al., 1981; Preston et al., 1983). Such genes might then be transfected into bovine host lymphocytes to generate immunity against the whole parasite (Iams, 1985). The gene products which are responsible for stimulating immune responses could also be synthesized artificially and used for vaccination. Methods of characterizing Theileria range from Giemsa's staining to DNA hybridization; all have a role to play, and by judicious selection of appropriate methods for particular circumstances, it is becoming possible to characterize theilerial parasites very precisely. Improved methods of characterization can, in turn, lead to a better understanding of parasite biology and to the development of improved methods of immunization and control.

Revised classification of the DLA loci by serological studies

Peripheral blood mononuclear cells from DLA typed dogs were treated with rabbit-anti-dog-beta 2-microglobulin and subsequently with goat-anti-rabbit-immunoglobulin in order to aggregate the DLA class I molecules on the cell membrane (lysostrip). Utilizing a panel of 70 defined DLA-A and DLA-B antisera, lymphocytes treated in this way showed resistance to complement dependent lysis with monospecific DLA-A sera only, whereas reactivity of DLA-B antisera was not blocked; on the contrary, complete lympholysis with each DLA-B antiserum was recognized. Thus, the DLA-B antigens, evidently not associated with beta 2-microglobulin, are designated as candidates for class II gene products. The different reactions of DLA-C antisera after lysostrip did not allow a precise assignment of this antigen series as yet.