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Unified theory of human and animals aging. Bioenergy concept aging as a disease. Алексей Фёдорович ФитинЧитать онлайн книгу.

Unified theory of human and animals aging. Bioenergy concept aging as a disease - Алексей Фёдорович Фитин


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and regeneration due to slow axonal vesicular transport, the speed which is much less than the blood flow velocity. The speed of vesicular transport in the axon reaches 20–50 cm / day, and the blood flow rate is in the range from 0.03 cm / sec in the capillaries to 40 cm / sec in the aorta.

      Thus, the rate of vesicular axonal transport of mitochondria and enzymes accumulated in the Golgi apparatus and is 50–70000 times less than the rate of transport of nutrients by the circulatory system. This difference predetermines the limiting stage of the regeneration process of axons damaged in one way or another, which is from 2 to 5 mm per day. I came to the conclusion, that it is the energetics of these unique neurons that can be a limiting factor in their effective work and the regeneration of their offshoots. And since the energetics of a neuron is based on oxidative phosphorylation, I came to the preliminary conclusion that only oxygen can be the initial limiting factor in the work of these unique neurons. Later it turned out that the weakest point of these neurons are the terminal areas of axons farthest from the cell nucleus and from the Golgi apparatus, on which receptors are localized and which are capable of regeneration after physiological degeneration.

      1.1 Etiology of Aging

      The death of the body is the inevitable outcome of the disease of aging. When assessing the dynamics of aging, two indicators are important – the average indicator and the indicator of the maximum life expectancy.

      Searching for the stages of pathogenesis that limit a long and healthy life, I came to the conclusion that the indicator of the maximum or species life expectancy is associated with physiological aging (senescence) and depends on the only unique internal pathogenic factor – oxygen deficiency in organs and tissues and is determined by specific (per unit mass of body weight per unit of time) by the rate of formation of carriers of free energy: adenosine triphosphoric acid (ATP), reduced forms of nicotinamide-adenine dinucleotides (NADH, NADPH), reduced forms of flavine-adenine dinucleotide (FAD) and acetyl-coenzyme A (acetyl-CoA).[1]

      Indicator of maximum life expectancy has not changed over the centuries and therefore is a species-specific feature. At the same time, the partial pressure of oxygen in different organs and tissues differs significantly, and therefore the levels of hypoxia, normoxia and hyperoxia for each organ and each tissue are unique [7].

      Max Rubner first drew attention to the limitation of the maximum life span for the species of warm-blooded animals, while studying the energy characteristics of animals under resting conditions. More on this in the second part of the review.

      Specific rates of synthesis of energy carriers, in turn, are determined not only by the partial pressure of oxygen in organs and tissues, but also by the specific content of mitochondria in cells, which catalyze the main process of synthesis of carriers of free energy – oxidative phosphorylation.

      In a number of cells (stem, tumor) and tissues (embryonic tissue, fetus and «cambial» tissues of stem cell niches), in which aerobic glycolysis and the pentose phosphate cycle make a significant contribution to the production of free energy carriers, the amount of enzymes of these metabolic pathways present in cells also determines the specific rates of synthesis of free energy carriers.

      Thus, the indicator of the maximum or species life expectancy of organisms is determined by the specific rates of synthesis of free energy carriers (per gram of tissues and organs per unit of time): ATP, NADH, NADPH, FMN, FADH2, Acetyl-CoA.

      The parameter limiting the indicator of the maximum life span of a species, according to my proposed bioenergetic Concept of aging, is the specific rate (per kilogram of body weight) of the formation of carriers of free energy, which depends on the content in cells and activity of mitochondria that carry out oxidative phosphorylation of ADP and reduction of NAD+.

      The indicator of the average life expectancy is associated with pathological or premature aging, and just like the indicator of the maximum life expectancy depends on the oxygen concentration in organs and tissues, but, at the same time, it is determined not by the rates of formation of carriers of free energy, but the rates of their expenditure.

      Pathological aging is accelerated by the influence of numerous factors of a biological, chemical and physical nature, which is realized through a unified process of consumption of deficient oxygen or free energy, both on the work of the body’s safety systems (detoxification systems; immunity systems; stress response systems and supply systems a high level of selectivity of enzymes of matrix synthesis of DNA, RNA and protein, as well as a system for correcting errors made by these enzymes), as well as to overcome metabolic chaos in the form of diseases caused by infections, poisoning, distress and mutations, if the power of energy dependent security systems the body was not enough.

      All expenditure of free energy by the body can be divided into two categories. The first is associated with the expenditure of free energy to maintain the basic vital functions, without which life is impossible, and which includes the costs of growth, development, reproduction, functioning, adaptation to small changes in the surrounding and internal environment of the body (costs for the constantly ongoing process of changing enzymatic patterns in cells and for the response to eustress), on maintaining body temperature and creating physiological endogenous reserves of nutrients for the smooth functioning of the body. The listed costs of energy are in a competitive relationship.

      For example, the more free energy is spent on adaptation or on reproduction, the less it remains for other functions and the lower the indicator of the maximum life span of the species (see the example of the Shrew in the second part of the review). Another example – long-lived mutants of roundworms – soil nematodes Caenorhabditis elegans for the age-1 or daf-23 gene, encoding the catalytic subunit of phosphatidylinositol-3-kinase, localized in the signal transduction chain from the insulin-like growth factor, were characterized by either complete sterility, or fewer offspring and a high level of embryonic mortality.

      I hope that the high energy consumption of the above basic vital functions is obvious to the reader, perhaps, except for the cost of adaptation. In this regard, I will briefly dwell on the mechanism of one of the most energy-consuming life processes – the adaptation of an organism to changes in its internal environment. The process of adaptation underlies the pathogenesis of aging as the longest chronic disease. This is not about the global (strategic) and slow process of adaptation of organisms to environmental conditions for many generations, which underlies the evolution of species and affects the changes in genes, but about the constantly going "every minute" adaptation of the organism to the continuous changes of the organism itself, manifested at the epigenetic level, without changing the genes themselves.

      Such operational adaptation is expressed both in a change in the activity of enzymes due to a change in their content in cells, and in a change in their lists (patterns). It is impossible to constantly keep in the cells of this or that organ or tissue the entire set of necessary enzymes for all occasions. A large number of enzymes are classified as inducible and their amount in a cell can vary significantly depending on the situation. The relatively short half-life of many enzymes – from several tens of minutes to a day, indicates both the high rate of change of enzymatic “communities” (patterns) of the cell, and the significant expenditure of free energy, which goes both for synthesis and for degradation proteins. When I first drew attention to the high rate of protein turnover in the cell, I could not understand for a long time the reason for the high degree of cell wastefulness in terms of the expenditure of always deficient free energy.

      Indeed, the ribosomal synthesis of only one peptide bond at a cost of 2 kcal/mol is accompanied by the consumption of four high-energy compounds (ATP, pyrophosphate and 2 GTP), with a total cost of 30 kcal/mol. In addition, the intracellular transport of protein to its workplace and folding of the protein into the working conformation also requires considerable additional energy consumption. The highest energy cost is characteristic of proteins delivered by energy-dependent vesicular transport over huge distances from the body of neurons along axons.

      Only now, considering the energy costs underlying the life of cells and the organism as a whole, I realized the high cost of adaptation to the changing conditions of the internal environment of the organism. An example is the activation of the synthesis of a


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Free energy or Gibbs-Helmholtz energy – part of the internal energy of molecules that can be converted into work during reactions.

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