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Colony-stimulating factors (CSF) are intriguing molecules, which are glycoproteins that control the production and even some functions of granulocytes and macrophages, the immune cells that are primarily responsible for protecting the body against infections. While their presence was suspected in the early part of the 20th century, it was only in 1965 that researchers observed the growth of white blood cells in colonies derived from one single cell each, called the precursor or progenitor cells.
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The colonies consisted of growing granulocytes. Their growth was in direct proportion to the presence of some factor called, for the time, colony-stimulating factor, or CSF. Today these factors are known to be of immense significance in the treatment of low white blood cell levels following chemotherapy in cancer patients.
There are four separate CSFs which have separate modes of actions, and are found in small amounts in tissue. They are called:
The first ones to be purified were GM-CSF and M-CSF in 1977, followed by IL-3 and G-CSF, from rats. Soon after, human CSFs were purified using human tumor cell lines. Still later, molecular biology techniques were successful in producing cloned cDNAs for all the four molecules in the couple of years from 1984 to 1986. They are produced in very minute amounts, except in the presence of infections or endotoxins, or other foreign antigens, when the level shoots up a thousand times within the span of a few hours.
The exception is M-CSF which is more stable. Overall, the CSFs are very responsive to external stimuli and able to regulate the rate of proliferation of blood cells. They act on specific receptors present on granulocytes and monocyte-macrophage cells, stimulating them to mature from progenitor cells to mature cells. This causes them to leave the blood stream and enter the cells via binding to the receptors, following which they are broken down.
The CSFs are essential to allow all blood cells in the granulocyte and monocyte series to divide, both the progenitor cells and their progeny. An S-shaped curve reflects the way in which these cells respond to CSF, with shorter cell cycles leading to faster cell division.
Again, they cause increased proliferation at each new turn of the reproduction wheel, and prevent apoptosis (programmed cell death). Thus, they are also necessary to the survival of hemopoietic cells. Each CSF acts on specific cell populations predominantly, such as G-CSF acting to produce 75% of granulocytes in normal conditions.
On the other hand, GM-CSF acts to promote the functions of mature cells rather than their formation per se.
M-CSF is required both to form and to mature macrophages, but also for tooth eruption and for successful gestations.
IL-3 is involved in responses to parasites involving mast cells and basophils, in the form of type IV hypersensitivity reactions.
All of them also act in harmony to regulate blood formation both in health and in disease, promoting or inhibiting the actions of each other to produce the right mix of cells and functions.
CSFs also promote faster maturation and improved survival as well as higher grades of function of mature cells. Along with stem cell factor, CSFs can promote the division of the earliest blood-forming cells. They also are capable of producing maturation in leukemic cell lines and may decide which way blood cell precursors mature, in the granulocyte or macrophage series, based upon events observed in the laboratory. They can also promote cell function in mature cells, including chemotaxis, oxidative events involved in cell metabolism, antibody-dependent phagocytosis and microbial killing.
Early research showed that the prior administration of CSF could enhance immunity in patients on chemotherapy if given before exposure to infections. However, excessively high levels of these molecules caused serious and life-threatening inflammation of many organs including the lung, muscles and bowel, itching of the skin refractory to treatment, and paralysis with rapid mortality, in mouse experiments using different CSFs.
The finding that GM-CSF and IL-3 are necessary for the division and survival of leukemic cells, and may even act as oncogenes to transform blood cells into leukemic cells, may mean that cell division must be imbalanced to favor the excessive and autonomous formation of one series of blood-forming cells, along with its gaining the power to stimulate its own growth through the secretion of these CSFs.