Catabolism: Difference between revisions
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:''For the related metabolic process, see [[anabolism]].'' | :''For the related metabolic process, see [[anabolism]].'' | ||
'''Catabolism''' (Greek: καταβολισμός) is the metabolic process that breaks down molecules into smaller units. It is made up of degradative chemical reactions in the living cell. Large polymeric molecules ([[polysaccharide]]s, [[nucleic acid]]s and [[protein]]s) are processed into their constituent monomeric units (i.e. [[monosaccharide]]s, [[nucleotide]]s and [[amino acid]]s, respectively). | '''Catabolism''' (Greek: καταβολισμός) is the metabolic process that breaks down molecules into smaller units. It is made up of degradative chemical reactions in the living cell. Large polymeric molecules ([[polysaccharide]]s, [[nucleic acid]]s and [[protein]]s) are processed into their constituent monomeric units (i.e. [[monosaccharide]]s, [[nucleotide]]s and [[amino acid]]s, respectively). Those monomers can be further degraded into simpler molecules for production of energy. | ||
Cells use [[monomers]] to construct new [[polymeric]] molecules and disassemble them to simple cellular metabolites (lactic acid, acetic acid, carbon dioxide, ammonia, urea, etc.). The creation of cellular metabolites is an [[oxidation]] process involving a release of chemical free energy, not all of which is lost as heat, but some of which is partially conserved through the coupled synthesis of [[adenosine triphosphate]]. The [[hydrolysis]] of this compound is subsequently used to drive almost every energy-requiring reaction in the cell. Catabolism provides the chemical energy necessary for the maintenance of the living cell. Examples of catabolic processes include breakdown of muscle protein in order to use amino acids as [[substrate (biochemistry)|substrate]]s for [[gluconeogenesis]] and breakdown of [[fat]] in [[adipose]] to [[fatty acid]]s. | Cells use [[monomers]] to construct new [[polymeric]] molecules and disassemble them to simple cellular metabolites (lactic acid, acetic acid, carbon dioxide, ammonia, urea, etc.). The creation of cellular metabolites is an [[oxidation]] process involving a release of chemical free energy, not all of which is lost as heat, but some of which is partially conserved through the coupled synthesis of [[adenosine triphosphate]]. The [[hydrolysis]] of this compound is subsequently used to drive almost every energy-requiring reaction in the cell. Catabolism provides the chemical energy necessary for the maintenance of the living cell. Examples of catabolic processes include breakdown of muscle protein in order to use amino acids as [[substrate (biochemistry)|substrate]]s for [[gluconeogenesis]] and breakdown of [[fat]] in [[adipose]] to [[fatty acid]]s. | ||
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Because it is counterproductive to have anabolic and catabolic processes occurring in cells simultaneously, there are many signals that switch on anabolic processes while switching off catabolic processes and vice versa. Most of the known signals are [[hormone]]s and the molecules involved in metabolism itself. [[Endocrinologist]]s have traditionally classified many of the hormones as [[anabolic]] or catabolic. | Because it is counterproductive to have anabolic and catabolic processes occurring in cells simultaneously, there are many signals that switch on anabolic processes while switching off catabolic processes and vice versa. Most of the known signals are [[hormone]]s and the molecules involved in metabolism itself. [[Endocrinologist]]s have traditionally classified many of the hormones as [[anabolic]] or catabolic. | ||
==Classic Catabolic Hormones== | ==Classic Catabolic Hormones== | ||
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*[[Cytokine]]s | *[[Cytokine]]s | ||
Newer hormones associated with the balance of the catabolic and anabolic states include | Newer hormones associated with the balance of the catabolic and anabolic states include | ||
*[[Orexin]] | *[[Orexin]] (also known as [[Hypocretin]]) | ||
*[[Melatonin]] | *[[Melatonin]] | ||
Latest revision as of 02:03, 2 June 2009
- For the related metabolic process, see anabolism.
Catabolism (Greek: καταβολισμός) is the metabolic process that breaks down molecules into smaller units. It is made up of degradative chemical reactions in the living cell. Large polymeric molecules (polysaccharides, nucleic acids and proteins) are processed into their constituent monomeric units (i.e. monosaccharides, nucleotides and amino acids, respectively). Those monomers can be further degraded into simpler molecules for production of energy.
Cells use monomers to construct new polymeric molecules and disassemble them to simple cellular metabolites (lactic acid, acetic acid, carbon dioxide, ammonia, urea, etc.). The creation of cellular metabolites is an oxidation process involving a release of chemical free energy, not all of which is lost as heat, but some of which is partially conserved through the coupled synthesis of adenosine triphosphate. The hydrolysis of this compound is subsequently used to drive almost every energy-requiring reaction in the cell. Catabolism provides the chemical energy necessary for the maintenance of the living cell. Examples of catabolic processes include breakdown of muscle protein in order to use amino acids as substrates for gluconeogenesis and breakdown of fat in adipose to fatty acids.
Because it is counterproductive to have anabolic and catabolic processes occurring in cells simultaneously, there are many signals that switch on anabolic processes while switching off catabolic processes and vice versa. 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.
Classic Catabolic Hormones
- Cortisol
- Glucagon
- Adrenalin(e) and other catecholamines
- Cytokines
Newer hormones associated with the balance of the catabolic and anabolic states include
- Orexin (also known as Hypocretin)
- Melatonin