Catabolism - Related Links
Open Access Articles- Top Results for Catabolism
Journal of Clinical & Cellular ImmunologyGlycolytic Metabolism is Differentially Coupled to Proliferative Potential and Morphodynamic Capacity in RAW 264.7 and Mafb/C-Maf Deficient Macrophage
Oral Health and Dental ManagementEx vivo Yeast-Decontamination of Denture by H2O2/Iodide/Lactoperoxidase System: Need to Overpass the Microbial H2O2 Catabolism
Journal of Novel PhysiotherapiesPassive Cycling Limits Myofibrillar Protein Catabolism in Unconscious Patients: A Pilot Study
- For the related metabolic process, see anabolism.
Catabolism (from Greek κάτω kato, "downward" and βάλλειν ballein, "to throw") is the set of metabolic pathways that breaks down molecules into smaller units to release energy. Catabolism breaks down large molecules (such as polysaccharides, lipids, nucleic acids and proteins) into smaller units (such as monosaccharides, fatty acids, nucleotides, and amino acids, respectively). As molecules such as polysaccharides, proteins, and nucleic acids comprise long chains of these small monomer units (mono = one + mer = part), the large molecules are called polymers (poly = many).
Cells use the monomers released from breaking down polymers to either construct new polymer molecules, or degrade the monomers further to simple waste products, releasing energy. Cellular wastes include lactic acid, acetic acid, carbon dioxide, ammonia, and urea. The creation of these wastes is usually an oxidation process involving a release of chemical free energy, some of which is lost as heat, but the rest of which is used to drive the synthesis of adenosine triphosphate (ATP). This molecule acts as a way for the cell to transfer the energy released by catabolism to the energy-requiring reactions that make up anabolism. (Catabolism is seen as destructive metabolism and anabolism as constructive metabolism). Catabolism therefore provides the chemical energy necessary for the maintenance and growth of cells. Examples of catabolic processes include glycolysis, the citric acid cycle, the breakdown of muscle protein in order to use amino acids as substrates for gluconeogenesis, the breakdown of fat in adipose tissue to fatty acids, and oxidative deamination of neurotransmitters by monoamine oxidase.
There are many signals that control catabolism. Most of the known signals are hormones and the molecules involved in metabolism itself. Endocrinologists have traditionally classified many of the hormones as anabolic or catabolic, depending on which part of metabolism they stimulate. The so-called classic catabolic hormones known since the early 20th century are cortisol, glucagon, and adrenaline (and other catecholamines). In recent decades, many more hormones with at least some catabolic effects have been discovered, including cytokines, orexin (also known as hypocretin), and melatonin.
Many of these catabolic hormones express an anti-catabolic effect in muscle tissue. One study found that the administration of epinephrine (adrenaline) had an anti-proteolytic effect, and in fact suppressed catabolism rather than promoted it. Another study found that catecholamines in general (the main ones being, epinephrine, norepinephrine and dopamine), greatly decreased the rate of muscle catabolism.
- Dehydration synthesis
- Nocturnal post absorptive catabolism
- de Bolster, M.W.G. (1997). "Glossary of Terms Used in Bioinorganic Chemistry: Catabolism". International Union of Pure and Applied Chemistry. Retrieved 2007-10-30.
- Fryburg, DA; Gelfand, RA; Jahn, LA; Oliveras, D; Sherwin, RS; Sacca, L; Barrett, EJ (1995). "Effects of epinephrine on human muscle glucose and protein metabolism". American Journal of Physiology - Endocrinology and Metabolism 268 (1): E55–9. PMID 7840182.
- Navegantes, Luiz Carlos C.; Resano, Neusa M. Z.; Migliorini, Renato H.; Kettelhut, Ísis C. (2001). "Catecholamines inhibit Ca2+-dependent proteolysis in rat skeletal muscle through β2-adrenoceptors and cAMP". American Journal of Physiology - Endocrinology and Metabolism 281 (3): E449–54. PMID 11500299.