Tuberculosis (TB), an infectious disease caused by Mycobacterium tuberculosis (M.tb), remains a leading public health problem in most parts of the world. Despite the discovery of the bacilli over 100 years ago, there are still many unanswered questions about the host resistance to TB. Although one third of the world's population is infected with virulent M.tb, no more than 5-10% develop active disease within their lifetime. A lot of studies suggest that host genetic factors determine the outcome of M.tb-host interactions, however, specific genes and polymorphisms that govern the development of TB are not completely understood. Strong evidence exists for genes encoding pattern recognition receptors (TLR, CD14), C-type lectins, cytokines/chemokines and their receptors (IFN-γ, TNF-α, IL-12, IL-10, MCP-1, MMP-1), major histocompatibility complex (MHC) molecules, vitamin D receptor (VDR), and proton-coupled divalent metal ion transporters (SLC11A1). Polymorphisms in these genes have a diverse influence on the susceptibility to or protection against TB among particular families, ethnicities and races. In this paper, we review recent discoveries in genetic studies and correlate these findings with their influence on TB susceptibility.
Immunological memory is a key feature of adaptive immunity. It provides the organism with long-lived and robust protection against infection. The important question is whether cyclophosphamide (CP), as immunosuppressive agent used in cancer therapy and in some autoimmune diseases, may act on the memory T-cell population. We investigated the effect of CP on the percentage of central memory T cells (T) and effector memory T cells (T) in the mouse model of CP-induced immunosuppression (8-10-week-old male C57BL/6 mice CP treated for 7 days at the daily dose of 50 μg/g body weight [bw], manifested the best immunosuppression status, as compared to lower doses of CP: 10 or 20 μg/g bw). The CP induced a significant decrease in the percentage of CD8 (T), compared to nonimmunosuppressed mice. This effect was not observed in the case of CD4 T population. The percentage of gated T with CD4 and CD8 phenotype was significantly decreased in CP-treated mice, as compared to the control ones. Taken together, the above data indicate that CP-induced immunosuppression in mice leads to a reduction in the abundance of central memory cells possessing preferentially CD8 phenotype as well as to a reduction in the percentage of effector memory cells (splenocytes both CD4 and CD8), compared to the cells from nonimmunosuppressed mice. These findings in mice described in this article may contribute to the understanding of the complexity of the immunological responses in humans and extend research on the impact of the CP model of immunosuppression in mice and memory T-cell populations.
Immunosuppression is a condition characterized by weakened or inhibited immune response. It occurred both in humoral and cellular response. This is related to the variable levels of deficiency for each antibody class (IgG, IgM, IgA) and a decrease in the number and function of immune cells, mainly T cells which results in the inhibition of cytokine production, signaling transduction and clonal expansion. Immunosuppressive therapy is used in many fields of medicine, such as transplantology, oncology, autoimmune disorders. Immunosuppression can be induced in several ways, by the surgical resection of the organs of the immune system, physical methods using X-rays or chemical methods using pharmacological agents. The most common way to induce immunosuppression is the administration of immunosuppressive drugs, amongst others: glucocorticoids, cytostatic drugs, immunophilin-binding agents, monoclonal antibodies. Unfortunately, the desired therapeutic effects of immunosuppression may be accompanied by a number of side effects associated with both impaired immunity (susceptibility to infections, including those caused by opportunistic microorganisms), toxic effects on the tissues (nephrotoxicity, neurotoxicity), or with a direct impact on the processes of malignancy. This harmful influence can be limited by the modification of the existing drugs, looking for new ones or developing new methods for the controlled kinetics of releasing the immunosuppressive pharmaceuticals. The personalization of immunosuppressant treatment according to genetic/genomic characteristics of individual patient represents the quite innovative look into the issue of immunosuppression.
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