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The concept of electronically-activated species as messengers in both normal metabolism and in pathogenesis goes back to the 19th century. For example, the biological pigment ] is a stable free radical. ] noted that white blue-eyed cats are usually deaf and that this combination might be related to some defect in neuronal development secondary to the absence of melanin pigment. In a similar manner, it has been known for centuries that radical-generating ] such as intraocular ] and ] may produce massive vitreous fibrosis (scarring) as they oxidize. We now know that ] likely play a key role in fibrocyte activation.{{Fact|date=May 2009}} The concept of electronically-activated species as messengers in both normal metabolism and in pathogenesis goes back to the 19th century. For example, the biological pigment ] is a stable free radical. ] noted that white blue-eyed cats are usually deaf and that this combination might be related to some defect in neuronal development secondary to the absence of melanin pigment. In a similar manner, it has been known for centuries that radical-generating ] such as intraocular ] and ] may produce massive vitreous fibrosis (scarring) as they oxidize. We now know that ] likely play a key role in fibrocyte activation.{{Fact|date=May 2009}}


The "Adrenochrome Hypothesis" of ] and ] for the causation of ] involves the radical oxidation of the neurotransmitter ] to the psychoactive compound ]. The "Adrenochrome Hypothesis" of ] and ] for the causation of ] involves the radical oxidation of the neurotransmitter ] and other ]s to the psychoactive compound ].


The first modern statement of the hypothesis appears to be that of Proctor<ref>{{cite journal |author=Proctor P |title=Electron-transfer factors in psychosis and dyskinesia |journal=Physiol. Chem. Phys. |volume=4 |issue=4 |pages=349–60 |year=1972 |pmid=4680784 |url=http://www.nitrone.com/72rev.htm}}</ref>, who at a subsequent congress of free radical investigators in 1979 generalized it to suggest that " ....active oxygen metabolites act as specific intermediary transmitter substances for a variety of biological processes including inflammation, fibrosis, and possibly, neurotransmission.." and " One explanation for this data is that various active oxygen species ( or such products as hydroperoxides ) may act as specific transmitter substances....". This was formally published in a review in 1984 . The next reference seems to be Bochner and coworkers<ref>{{cite journal |author=Bochner BR, Lee PC, Wilson SW, Cutler CW, Ames BN |title=AppppA and related adenylylated nucleotides are synthesized as a consequence of oxidation stress |journal=Cell |volume=37 |issue=1 |pages=225–32 |year=1984 |month=May |pmid=6373012 |url=http://linkinghub.elsevier.com/retrieve/pii/0092-8674(84)90318-0}}</ref>. The first modern statement of the hypothesis appears to be that of Proctor<ref>{{cite journal |author=Proctor P |title=Electron-transfer factors in psychosis and dyskinesia |journal=Physiol. Chem. Phys. |volume=4 |issue=4 |pages=349–60 |year=1972 |pmid=4680784 |url=http://www.nitrone.com/72rev.htm}}</ref>, who at a subsequent congress of free radical investigators in 1979 generalized it to suggest that " ....active oxygen metabolites act as specific intermediary transmitter substances for a variety of biological processes including inflammation, fibrosis, and possibly, neurotransmission.." and " One explanation for this data is that various active oxygen species ( or such products as hydroperoxides ) may act as specific transmitter substances....". This was formally published in a review in 1984 . The next reference seems to be Bochner and coworkers<ref>{{cite journal |author=Bochner BR, Lee PC, Wilson SW, Cutler CW, Ames BN |title=AppppA and related adenylylated nucleotides are synthesized as a consequence of oxidation stress |journal=Cell |volume=37 |issue=1 |pages=225–32 |year=1984 |month=May |pmid=6373012 |url=http://linkinghub.elsevier.com/retrieve/pii/0092-8674(84)90318-0}}</ref>.

Revision as of 19:30, 30 May 2010

Redox signaling is the process wherein free radicals, reactive oxygen species (ROS), and other electronically-activated species act as messengers in biological systems.

History

The concept of electronically-activated species as messengers in both normal metabolism and in pathogenesis goes back to the 19th century. For example, the biological pigment melanin is a stable free radical. Charles Darwin noted that white blue-eyed cats are usually deaf and that this combination might be related to some defect in neuronal development secondary to the absence of melanin pigment. In a similar manner, it has been known for centuries that radical-generating transition-series metals such as intraocular copper and iron may produce massive vitreous fibrosis (scarring) as they oxidize. We now know that reactive oxygen species likely play a key role in fibrocyte activation.

The "Adrenochrome Hypothesis" of Abram Hoffer and Humphry Osmond for the causation of schizophrenia involves the radical oxidation of the neurotransmitter epinephrine and other catecholamines to the psychoactive compound adrenochrome.

The first modern statement of the hypothesis appears to be that of Proctor, who at a subsequent congress of free radical investigators in 1979 generalized it to suggest that " ....active oxygen metabolites act as specific intermediary transmitter substances for a variety of biological processes including inflammation, fibrosis, and possibly, neurotransmission.." and " One explanation for this data is that various active oxygen species ( or such products as hydroperoxides ) may act as specific transmitter substances....". This was formally published in a review in 1984 . The next reference seems to be Bochner and coworkers.

Progress in biochemistry has enabled us to improve our understanding of redox signaling in general: usually extracellular environment is more oxidized than intracellular. This results in proteins and segments thereof that are exposed to the extracellular environment to form disulfide bridges between cysteine amino acid residues. This way, complementary surfaces have the ability to maintain a covalent bond that stabilizes structure. This is important to extracellular proteins, as they are constantly exposed to a variety of proteases, capable of degrading especially easily proteins with loose conformation. Inside the cell, on the contrary, mildly reducing conditions usually predominate. Cysteine residues are not involved in the formation of disulfide bonds, unless intracellular redox balance is tilted toward oxidant stress. The formation of disulfide bonds is capable of altering both conformation and activity of a number of enzymes, most notably of phosphatases. These enzymes usually restrict the activity of protein kinases (protein phosphorylases). Inactivation of a specific phosphatase by oxidant stress results in prolonged activity for the kinases that it controls in a specific cell type. Prolonged activity of specific kinases, in a cell, means that particular intracellular signal cascades are increasingly activated. Such alterations in the intracellular signal cascades, which proceed through successive phosphorylations of particular kinases that operate on a pathway, culminate in phosphorylation of proteins in many cell compartments, such as mitochondria or nucleus. This modification of specific regulatory proteins can result in a number of changes, ranging from ionic signals to wide alterations in patterns of gene expression. As a consequence, a cell may change its rate of proliferation, or die, depending on the signal networks that it operates. An intracellular oscillation of oxidant levels has been previously experimentally linked to maintenance of the rate of cell proliferation. As an example, when chelating redox-active iron present in the endosomal/lysosomal compartment of cultured epithelial cell line HeLa with the iron chelator desferrioxamine, cell proliferation is inhibited.

External links

References

  1. Proctor P (1972). "Electron-transfer factors in psychosis and dyskinesia". Physiol. Chem. Phys. 4 (4): 349–60. PMID 4680784.
  2. Bochner BR, Lee PC, Wilson SW, Cutler CW, Ames BN (1984). "AppppA and related adenylylated nucleotides are synthesized as a consequence of oxidation stress". Cell. 37 (1): 225–32. PMID 6373012. {{cite journal}}: Unknown parameter |month= ignored (help)CS1 maint: multiple names: authors list (link)
  3. Irani K, Xia Y, Zweier JL; et al. (1997). "Mitogenic signaling mediated by oxidants in Ras-transformed fibroblasts". Science. 275 (5306): 1649–52. PMID 9054359. {{cite journal}}: Explicit use of et al. in: |author= (help); Unknown parameter |month= ignored (help)CS1 maint: multiple names: authors list (link)
  4. Doulias PT, Christoforidis S, Brunk UT, Galaris D (2003). "Endosomal and lysosomal effects of desferrioxamine: protection of [[ HeLa ]] cells from hydrogen peroxide-induced DNA damage and induction of cell-cycle arrest". Free Radic. Biol. Med. 35 (7): 719–28. PMID 14583336. {{cite journal}}: URL–wikilink conflict (help); Unknown parameter |month= ignored (help)CS1 maint: multiple names: authors list (link).
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