Pathogenesis of cancer - Сергей Алексеевич Шалин
1. Class II — pluripotent progenitor cell of the ancestor of myelopoiesis, common to 4 lineages (CFU-GEMMeg) with subsequent development in the direction of the Monocytic lineage.
2. Class III — unipotent progenitor cell of the monocytes (CFU-M). It must be emphasized that genotypic changes in nuclear DNA occur according to a recessive trait, therefore these changes do not manifest themselves in any way in the red bone marrow.
During the process of differentiation, genotypic changes are laid down in the genetic apparatus of the future Monocyte, which morphologically will not differ from a normal bone marrow cell. The acquisition of genotypic changes in nuclear DNA for a Monocyte is not decisive in the possibility of transformation into a malignant stem cell, because it can divide, mature, differentiate, transform into cells of the microenvironment, and transform into a Macrophage. And although irreversible genotypic changes are an absolute necessity for transformation into a malignant stem cell, this is completely insufficient. Genotypic changes in the DNA of the Monocyte nucleus will wait patiently until optimal conditions arise for their manifestation, and then the “nascent” descendants — malignant stem cells — will dominate the host organism.
For the “birth” of a malignant stem cell, subsequent growth and development of the malignant process, “super conditions” are required, creating an isolated state of the progenitor cell from the influence of the body. These conditions can be called a “pre-tumor” bed in pathologically altered local tissues against the background of pre-tumor diseases of the macroorganism. A “pretumor” bed can be an isolated microcavity, the formation of which during chronic inflammation is a natural process. However, it is not at all necessary that the formed isolated microcavity will become the place where the “birth” of a malignant stem cell will occur. Formation of an isolated microcavity: during the process of inflammation, small blood clots and dead tissue are reabsorbed. Large tissue defects resulting from fibrinous-necrotic inflammation are replaced by scar tissue. Small defects that occur between cells within the stroma first become lumens and then turn into microcavities. In response to tissue damage and under the influence of pathogenetic inflammatory factors, pluripotent poorly differentiated connective tissue cells, called “peripheral blood fibrocytes” or fibroblast-like cells, migrate from the bloodstream. Their immunophenotypic characteristics, combined with the ability to give rise to representatives of fibroplastic cell differential, suggest that they are multipotent mesenchymal stromal cells (MMSCs), constantly circulating in the blood in small quantities. It is these fibroblast-like cells that participate in the formation of the insulating shell of the microcavity, which acts as a “graveyard” for dead cells. Due to chemotaxis, a certain number of Monocytes enter an isolated microcavity, because not all of them are subsequently transformed into a malignant stem cell, but the transformation process never occurs from single cells. Once in an isolated microcavity, the Monocyte finds itself surrounded by an aggressive oxygen-free environment. He develops structural changes in the cell membrane and chemical changes in the cytoplasm — epigenetic changes. A tissue monocyte appears, which has genotypic and epigenetic changes — this is the potential precursor cell of the primary malignant stem cell of solid tumors. Such a Monocyte remains outwardly normal as long as it is in interphase, but as soon as it begins Mitosis, all changes will become obvious and manifest themselves. It is known that each Monocyte in tissues turns into an organ- and tissue-specific Macrophage during the process of transformation. Transformation is a series of cell divisions during which its phenotypic changes occur sequentially under the influence of the microenvironment. A monocyte, having genotypic and epigenetic changes, attempts to transform into a Macrophage (macrophage blast, promacrophage, tissue macrophage) and begins the process of mitosis, during which a return to the embryonic state occurs. However, after mitosis, the level of genotypic changes appears, as a result of which a block of differentiation of daughter cells occurs and transformation, during which the nature of genotypic changes in nuclear DNA appears. As a result, an unstable active system is “born” — a malignant stem cell, which has retained many of the basic abilities and capabilities of the mother cell — the tissue Monocyte, which has not completely left the embryonic state and acquires new abilities of its new life: the possibility of uncontrolled division, autonomous regulation, immortality of the population, etc. A malignant stem cell is a proliferating somatic cell that has a certain level of potency, which corresponds to the level at which genotypic changes occurred in the bone marrow cell during hematopoiesis:
1. If