Vol 53, No 5 (2019)

Blood is extremely important for a multicellular organism: it connects all organs and tissues, supplies them with nutrients and oxygen, removes carbon dioxide and metabolic products, maintains homeostasis, and provides protection against infections. That is why studies on blood have always drawn a great deal of attention. In ancient times, it was believed that the soul was in the blood and that it sometimes “sank into the stomach.” Initially, the study of blood was limited to morphological methods, to which physiological and cellular research were added in the twentieth century. With their help, researchers established that mature blood cells are formed from a rare population of hematopoietic stem cells (HSCs), which are located in the bone marrow. The development of molecular biology methods and their combination with classical physiological ones allowed a breakthrough in understanding the structure of the hematopoietic system, which changed our understanding not only of hematopoiesis but also about the nature of adult stem cells. This review describes the molecular assays used in experimental hematology, and how their application has gradually been expanding our knowledge of blood formation and continues to provide new information about it.

Skin wound healing is subject to an intricate regulation, involves many cell populations and molecular mediators, and is one of the key mechanisms that ensures the barrier functions of the skin and the maintenance of body homeostasis. The efficiency of this process is largely determined by the balance of proinflammatory and proregenerative signals, which are mediated by cytokines. The review summarizes the latest data on the role of proinflammatory cytokines, mainly tumor necrosis factor (TNF), interleukin 6 (IL-6), interleukin 1 (IL-1), and interferons (IFNs), in skin wound healing, including those obtained with the use of genome editing techniques and methods of reverse genetics to establish relevant animal models. The roles that proinflammatory cytokines play at various stages of skin regeneration are discussed for both normal state and systemic pathologies, such as diabetes. Promising approaches to treating poorly healing wounds are summarized.

Interleukin-33 (IL-33) belongs to the IL-1 cytokine family and acts as a danger signal. IL-33 is released from stressed or necrotic cells. Initially, IL-33 was described as an inducer of the humoral immune response, which activated Th2 cells and mast cells involved in modulating inflammation and allergic reactions. In addition, IL-33 acts as a stimulator of the Th1, NK, and CD8T cells, which induce a cytotoxic immune response against intracellular pathogens. It was recently discovered that this cytokine is involved in the development of cancer by performing both pro- and antitumor functions. IL-33 can directly affect tumor cells and provokes their proliferation, survival, and metastasis. Moreover, IL-33 stimulates carcinogenesis by remodeling the tumor microenvironment and inducing angiogenesis, thus contributing to the generation of immunosuppressive conditions. At the same time, IL-33 causes tumor infiltration with cytotoxic CD8 T lymphocytes and natural killers, which leads to cytolysis-mediated cancer cell death. This review describes the versatile role of the IL-33/ST2 cascade in the development of experimental and clinical tumors. In addition, we discuss the prospects for the application of IL-33 and ST2 as diagnostic biomarkers and targets for cancer immunotherapy.

Recently, much attention has been drawn to unraveling the mechanisms of neurodegenerative and neuroinflammatory disease pathogenesis. A special role in the development of neuropathologies is assigned to the interaction of the nervous and the immune systems. Microglia are the cells of the immune system that function as resident macrophages of the central nervous system (CNS) and are involved in the development of CNS, as well as in homeostatic interactions. Impaired microglia can contribute to neuroinflammation and neurodegeneration. With the help of genome editing technologies, the main paradigms in the development and functions of microglia have been addressed. At the same time, an understanding of the mechanisms of regulation of microglia in normal and pathological conditions is necessary to create an effective therapy aimed at treating various neurological diseases. This review focuses on recent findings on the origin of microglia, its regulatory role in the central nervous system, as well as its contribution to the development of neuroinflammation.

The modern era of research in immunology is characterized by an unprecedented level of detail about structural characteristics of the immune system and the regulation of activities of its numerous components, which function together as a whole distributed-parameter system. Mathematical modeling provides an analytical tool to describe, analyze, and predict the dynamics of immune responses by applying a reductionist approach. In modern systems immunology and mathematical immunology as a new interdisciplinary field, a great challenge is to formulate the mathematical models of the human immune system that reflect the level achieved in understanding its structure and describe the processes that sustain its function. To this end, a systematic development of multiscale mathematical models has to be advanced. An appropriate methodology should consider (1) the intracellular processes of immune cell fate regulation, (2) the population dynamics of immune cells in various organs, and (3) systemic immunophysiological processes in the whole host organism. Main studies aimed at modeling the intracellular regulatory networks are reviewed in the context of multiscale mathematical modelling. The processes considered determine the regulation of the immune cell fate, including activation, division, differentiation, apoptosis, and migration. Because of the complexity and high dimensionality of the regulatory networks, identifying the parsimonious descriptions of signaling pathways and regulatory loops is a pressing problem of modern mathematical immunology.

Lymphocyte phosphatase-associated phosphoprotein (LPAP) is a small transmembrane protein that is found in lymphocytes and is tightly associated with the phosphatase CD45. The function of LPAP is still unknown. Studies of the LPAP interactome may reveal new details of how C45 and lymphocyte signaling in general are regulated. LPAP binding partners were sought using coimmunoprecipitation coupled with mass spectrometry, stabilization of protein complexes with chemical crosslinkers, and Blue Native electrophoresis. In addition to CD45, several proteins were identified as LPAP partners, including CD71, CD98, cytoskeletal proteins, the amino acid transporter SLC1A4, and the cell signaling component HS1. It was confirmed that more than 70% of LPAP molecules were bound with CD45 in a 1 : 1 complex. The effect of CD45 on LPAP was studied in CEM and Jurkat cells with a CD45 knockout. The LPAP levels in the cells were 10% of the level in wild-type cells. In the absence of CD45, LPAP phosphorylation at Ser-153 and Ser-163 was not affected, whereas phosphorylation at Ser-99 and Ser-172 decreased significantly. Based on the results, CD45 was assumed to play a role in regulating LPAP expression and phosphorylation status.

It is time to celebrate the 125th anniversary of the first successful attempt to develop and use a specific high-titer antitoxic serum for treating diphtheria, a deadly infectious disease. This was followed by major advances in passive immunotherapy 75 years ago (production of pooled human IgG for subcutaneous injection) and 50 years ago (widespread technology for producing immunoglobulin preparations for intravenous administration). More than 200 tons of pooled human IgG are produced per year worldwide. The preparation is used primarily for IgG substitution in patients with primary and secondary immunodeficiencies, as well as for an immunomodulating treatment of a growing number of autoimmune and inflammatory diseases. These preparations contain the pooled IgG antibody repertoire of a large population of healthy plasma donors. This repertoire includes antibodies that neutralize pathogens and their factors of virulence, anti-idiotypic antibodies, and antibodies to other foreign and own proteins, as well as to carbohydrate antigens. Naturally polyspecific antibodies that are present in all healthy individuals play an important role as a first-line defense against bacteria and viruses. After exposure to protein-modifying agents, some IgG molecules can acquire the ability to bind novel structurally unrelated antigens. This phenomenon is referred to as induced polyspecificity. The list of these protein-modifying molecules was shown to include low-pH buffers, free heme, pro-oxidative ferrous ions, reactive oxygen species, etc. Such modified antibody preparations may have a therapeutic potential, since their administration to animals with experimental sepsis or aseptic systemic response syndromes significantly improved survival rates, while the same dose of the native preparation had no effect. We also hypothesize that the aggressive protein-modifying molecules released in sites of inflammation and tissue damage could also modify the antigen-binding behavior of surface immunoglobulin B cell receptors and the structurally related T cell receptors. This “specificity editing” of both types of receptors may play a major role in the body’s defense mechanisms.