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9-Hydroxyoctadecadienoic acid

March 16, 2024

9-Hydroxyoctadecadienoic acid (or 9-HODE) has been used in the literature to designate either or both of two stereoisomer metabolites of the essential fatty acid, linoleic acid: 9(S)-hydroxy-10(E),12(Z)-octadecadienoic acid (9(S)-HODE) and 9(R)-hydroxy-10(E),12(Z)-octadecadienoic acid (9(R)-HODE); these two metabolites differ in having their hydroxy residues in the S or R configurations, respectively. The accompanying figure gives the structure for 9(S)-HETE. Two other 9-hydroxy linoleic acid derivatives occur in nature, the 10E,12E isomers of 9(S)-HODE and 9(R)-HODE viz., 9(S)-hydroxy-10E,12E-octadecadienoic acid (9(S)-EE-HODE) and 9(R)-hydroxy-10E,12E-octadecadienoic acid (13(R)-EE-HODE); these two derivatives have their double bond at carbon 12 in the E or trans configuration as opposed to the Z or cis configuration. The four 9-HODE isomers, particularly under conditions of oxidative stress, may form together in cells and tissues; they have overlapping but not identical biological activities and significances. Because many studies have not distinguished between the S and R stereoisomers and, particularly in identifying tissue levels, the two EE isomers, 9-HODE is used here when the isomer studied is unclear.

9-Hydroxyoctadecadienoic acid
Names
Preferred IUPAC name
(9S,10E,12Z)-9-Hydroxyoctadeca-10,12-dienoic acid
Other names
  • α-Dimorphecolic acid
  • 9-hydroxy-10(E),12(Z)-octadecadienoic acid
Identifiers
  • 73543-67-6 Y
3D model (JSmol)
  • Interactive image
ChemSpider
  • 4472255
ECHA InfoCard 100.230.886
  • 5312830
UNII
  • 42KE04U9BM Y
  • DTXSID20868260
  • InChI=1S/C18H32O3/c1-2-3-4-5-6-8-11-14-17(19)15-12-9-7-10-13-16-18(20)21/h6,8,11,14,17,19H,2-5,7,9-10,12-13,15-16H2,1H3,(H,20,21)/b8-6-,14-11+/t17-/m1/s1 COPY
    Key: NPDSHTNEKLQQIJ-UINYOVNOSA-N
  • CCCCC/C=C\C=C\[C@H](CCCCCCCC(=O)O)O
Properties
C18H32O3
Molar mass 296.451 g·mol−1
Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa).

A similar set of 13-Hydroxyoctadecadienoic acid (13-HODE) metabolites (13(S)-HODE), 13(R)-HODE, 13(S)-EE-HODE), and 13(R)-EE-HODE) also occurs naturally and, again particularly under conditions of oxidative stress, may form concurrently with 9-HODEs; these 13-HODEs also have overlapping and complementary but not identical activities with the 9-HODEs. Some recent studies measuring HODE levels in tissue have lumped the four 9-HODEs and four 13-HODEs together to report only on total HODEs (tHODEs): tHODEs have been proposed to be markers for certain human disease. Other recent studies have lumped together the 9-(S), 9(R), 13 (S)-, and 13(R)-HODE along with the two ketone metabolites of these HODEs, 9-oxoODE (9-oxo-10(E),12(Z)-octadecadienoic acid) and 13-oxoODE, reporting only on total OXLAMs (oxidized linoleic acid metabolites); the OXLAMs have been implicated in working together to signal for pain perception.

Pathways making 9-HODEs edit

Cyclooxygenases 1 and 2 edit

The enzymes cyclooxygenase 1 (COX-1) and cyclooxygenase 2 (COX-2), which are best known for metabolizing arachidonic acid to prostaglandins, are also able to metabolize linoleic acid predominantly to 9(R)-hydroperoxy-10(E),12(Z)-octadecadienoic acid (i.e. 9(R)-HpODE)-HODE) and lesser amounts of 9(S)-hydroperoxy-10(E),12(Z)-octadecadienoic acid (i.e. 9(S)-HpODE); in cells and tissues, the two hydroperoxy metabolites are rapidly reduce to 9(R)-HODE and 9(S)-HODE, respectively.[1][2][3] COX-2 exhibits a greater preference for linoleic acid than does Cox-1 and is therefore credited with producing most of these products in cells expressing both COX enzymes.[2] The COXs also metabolize linoleic acid to 13(S)-hydroperoxy-octadecadionoic acid (13(S)-HpODE and lesser amounts of 13(R)-hydroperoxy-octadecadienoic acid (13(R)-HpODE, which are then rapidly reduced to 13(S)-HODE) and 13(R)-HODE; the two enzymes therefore metabolize linoleic acid predominantly to the R stereoisomer of 9-HODE and (S) stereoisomer of 13-HODE with the 13-HODE products predominating over the 9-HODE products.[1][2][4]

Cytochrome P450 edit

Cytochrome P450 microsomal enzymes metabolize linoleic acid to a mixture of 9(S)-HpODE and 9(R)-HpODE which are subsequently reduced to their corresponding hydroxy products; these reactions produce racemic mixtures in which the R stereoisomer predominates, for instance by a R/S ratio of 80%/20% in human liver microsomes.[5][6][7] In cells and tissues, the cytochrome enzymes concurrently metabolize linoleic acid to 13(S)-HpODE and 13(R)-HpODE which are reduced to 13(S)-HODE and 13(R)-HODE in an R/S ratio similar to than of the 9-HODES, i.e. 80%/20%.[6]

Free-radical and singlet-oxygen oxidations edit

Oxidative stress in cells and tissues produces Free-radical-induced and singlet-oxygen-induced oxidations of linoleic acid to generate the various racemic mixtures of 9-HpODE and 9-HODE in non-enzymatic reactions that produce, or are suspected but not proven to produce, approximately equal amounts of their S and R stereoisomers.[8][9][10] These oxidations are credited with being the major contributors to 9-HODE and 13-HODE isomer production in tissues undergoing oxidative stress such as occurs in any tissue suffering inadequate blood flow, inflammation, or other serious insult, in liver steatohepatitis, in the atheroma plaques of cardiovascular disease, in nerve tissues of neurodegenerative diseases, and in the various tissues compromised by diabetes (see oxidative stress).[11][12] Free-radical oxidation of linoleic acid produces racemic mixtures of 9-HODE and 9-EE-HODE; singlet-oxygen attack on linoleic acid produces (presumably) racemic mixtures of 9-HODE, 10-hydroxy-8E,12Z-octadecadienoic acid, and 12-hydroxy-9Z-13-E-octadecadienoic acid.[13][12] Since free-radical-induced and singlet-oxygen-induced oxidations of linoleic acid produce a similar set of 13-HODE metabolites (see 13-Hydroxyoctadecadienoic acid), since both free radicals and singlet oxygen attack not only free linoleic acid but also linoleic acid bound to phospholipids, glycerides, cholesterol, and other lipids, and since free-radical and singlet-oxygen reactions may occur together, oxygen-stressed tissues often contain an array of free and lipid-bound 9-HODE and 13-HODE products. For example, laboratory studies find that 9-HODE and 9-EE-HODE (along with their 13-HODE counterparts) are found in the phospholipid and cholesterol components of low-density lipoproteins that have been oxidized by human monocytes; the reaction appears due to the in situ free-radical- and/or superoxide-induced oxidation of the lipoproteins.[14]

Mouse 8(S)-lipoxygenase edit

The murine homolog of human 15(S)-lipoxygenase-2 (ALOX15B), 8(S)-lipoxygenase, while preferring arachidonic acid over linoleic acid, metabolizes linoleic acid predominantly to (9(S)-HpODE, which in tissues and cells is rapidly reduced to 9(S)-HODE.[15][16] However, ALOX15B, similar to human 15-lipoxygenase-1 (ALOX15), metabolizes linoleic acid to 13(S)-HODE but not to 9(S)-HODEs.[17][18]

Metabolism edit

Like most unsaturated fatty acids, the 9-HODEs formed in cells are incorporated into cellular phospholipids principally at the sn-2 position of the phospholipid (see Phospholipase A2);[19][20] since, however, the linoleic acid bound to cellular phospholipids is susceptible to non-enzymatic peroxidation and free-radical attack,[21][22][23] the 9-HODEs in cellular phospholipids may also derive more directly from in-situ oxidation. 9-HODE esterified to the sn-2 position of phosphatidylserine is subject to be released as free 9-HODE by the action of cytosol (see phospholipase A2 section on cPLA2) and therefore may serve as a storage pool that is mobilized by cell stimulation.[23]

9-HODE may be further metabolized to 9-oxo-10(E),12(Z)-octadecadienoic acid (9-oxoODE or 9-oxo-ODE), possibly by the same hydroxy-fatty-acid dehydrogenase which metabolizes other hydroxy fatty acids, such as 13-HODE, to their oxo derivatives.[24]

Direct actions edit

9-HODE, 9-oxoODE, and 9-EE-HODE (along with their 13-HODE counterparts) directly activate peroxisome proliferator-activated receptor gamma (PPARγ).[25][26][27] This activation appears responsible for the ability of 13-HODE (and 9-HODE) to induce the transcription of PPARγ-inducible genes in human monocytes as well as to stimulate the maturation of these cells to macrophages.[25] 13(S)-HODE (and 9(S)-HODE) also stimulate the activation of peroxisome proliferator-activated receptor beta (PPARβ) in a model cell system; 13-HODE (and 9-HODE) are also proposed to contribute to the ability of oxidized low-density lipoprotein (LDL) to activate PPARβl: LDL containing phospholipid-bound 13-HODE (and 9-HODE) is taken up by the cell and then acted on by phospholipases to release the HODEs which in turn directly activate PPARβl.[28]

13(S)-HODE, 13(R)-HODE and 13-oxoODE, along with their 9-HODE counterparts, also act on cells through TRPV1. TRPV1 is the transient receptor potential cation channel subfamily V member 1 receptor (also termed capsaicin receptor or vanilloid receptor 1). These 6 HODEs, dubbed, oxidized linoleic acid metabolites (OXLAMs), individually but also and possibly to a greater extent when acting together, stimulate TRPV1-dependent responses in rodent neurons, rodent and human bronchial epithelial cells, and in model cells made to express rodent or human TRPV1. This stimulation appears due to a direct interaction of these agents on TRPV1 although reports disagree on the potencies of the (OXLAMs) with, for example, the most potent OXLAM, 9(S)-HODE, requiring at least 10 micromoles/liter[29] or a more physiological concentration of 10 nanomoles/liter[30] to activate TRPV1 in rodent neurons. The OXLAM-TRPV1 interaction is credited with mediating pain sensation in rodents (see below).

9(S)-HODE and with progressively lesser potencies 9(S)-HpODE, a racemic mixture of 9-HODE, 13(S)-HpODE, and 13(S)-HODE directly activate human (but not mouse) GPR132 (i.e. G protein coupled receptor 132 or G2A) in Chinese hamster ovary cells made to express these receptors; 9(S)-HODE was also a more potent stimulator of human G2A than a series of mono-hydroxy arachidonic acid metabolites.[31][32] GPR132 was initially described as a pH sensing receptor; the role(s) of 9-HODEs as well as other linoleic and arachidonic acid metabolites in activating GPR132 under the physiological and pathological conditions in which it is implicated to be involved(see (see GPR132 for a listing of these conditions) have not yet been determined. This determination, as it might apply to humans, is made difficult by the inability of these HODEs to activate rodent GPR132 and therefore to be analyzed in rodent models.

Biological and clinical relevancy edit

As markers of disease involving oxidative stress edit

Various measurements of tissue and blood levels of reactive oxygen species have been used as markers of diseases in which these species are generated and may contribute to tissue injury and systemic disturbances; examples of such diseases include a wide range of neurological, cardiovascular, infectious, autoimmune, and genetic diseases (see oxidative stress). HODEs measurements have been evaluated as markers for many of these oxygen-stress-related diseases. These measurements commonly use saponification methods to release HODEs bound by acylation to other molecules; they therefore measure not only free HODEs but also HODEs acylated to phospholipids, glycerides, cholesterol, and other lipids.

Studies find that 1) 9(S)-HODE (and 13(S)-HODE) levels are elevated in the plasma of older patients with early-stage cataracts compared to non-cataract subjects; 2) 9-HODE (and 13-HODE) are increased in the low density lipoproteins of patients with rheumatoid arthritis compared to healthy subjects as well as in the destructive but not normal bone tissue of the rheumatoid arthritic patients; 3) total HODEs (includes 9-HODE and 13-HODE stereoisomers) are higher in the plasma and liver of patients with hepatitis C and hepatitis B chronic viral infections as well as in the plasma and red blood cells of patients with Alzheimer's disease compared to healthy subjects; 4) 9-HODE and 9-oxoODE (as well as 13-HODE and 13-oxo-ODE) levels were elevated in the serum and/or pancreatic secretions of patients with pancreatitis compared to control subjects; 5) levels of the hydroperoxy precursors to 9-HODE and 13-HODE are elevated in the plasma and/or red blood cells of patients with Alzheimer's disease, atherosclerosis, diabetes, diabetic nephritis, non-alcoholic steatohepatitis, and alcoholic steatohepatitis compared to healthy subjects.[33][34][35][36][37][38][39] These studies suggest that high levels of the HODEs may be useful to indicate the presence and progression of the cited diseases. Since, however, the absolute values of HODEs found in different studies vary greatly, since HODE levels vary with dietary linoleic acid intake, since HODEs may form during the processing of tissues, and since abnormal HODE levels are not linked to a specific disease, the use of these metabolites as markers has not attained clinical usefulness.[11][37][40][12] HODE markers may find usefulness as markers of specific disease, type of disease, and/or progression of disease when combined with other disease markers.[12][41]

As mediators of oxidative-stress-related diseases edit

Some of the studies cited above have suggested that 9-HODEs, 13-HODEs, their hydroperoxy counterparts, and/or their oxo counterparts contribute mechanistically to these oxidative-stress-related diseases. That is, the free radical oxidation of linoleic acid makes these products which then proceed to contribute to the tissue injury, DNA damage, and/or systemic dysfunctions that characterize the diseases.[42][43][44][45][46] Furthermore, certain of these HODE-related products may serve as signals to activate pathways that combat the reactive oxygen species and in this and other ways the oxidative stress. It remains unclear whether or not the HODEs and their counterparts promote, dampen, or merely reflect oxidative-stress-related diseases.

As mediators of pain perception edit

9(S)-HODE, 9(R)-HODE, and 9-oxoODE, along with the other OXLAMs, appear to act through the TRPV1 receptor (see above section on Direct actions) mediate the perception of acute and chronic pain induced by heat, UV light, and inflammation in the skin of rodents.[30][47][48][49][50] These studies propose that the OXLAM-TRPV1 circuit (with 9(S)-HODE being the most potent TRPV1-activating OXLAM) similarly contributes to the perception of pain in humans.

As contributors to atherosclerosis edit

9-HODEs, 13-HODEs, and low density lipoprotein which has been oxidized so that it contains HODEs stimulate the expression of interleukin 1β mRNA in and its extracellular release from human peripheral blood monocyte-derived macrophages; interleukin 1β is implicated in the proliferation of smooth muscle cells that occurs in atherosclerosis and contributes to blood vessel narrowing.[51]

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March 16, 2024
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This article may be confusing or unclear to readers Please help clarify the article There might be a discussion about this on the talk page August 2015 Learn how and when to remove this template message 9 Hydroxyoctadecadienoic acid or 9 HODE has been used in the literature to designate either or both of two stereoisomer metabolites of the essential fatty acid linoleic acid 9 S hydroxy 10 E 12 Z octadecadienoic acid 9 S HODE and 9 R hydroxy 10 E 12 Z octadecadienoic acid 9 R HODE these two metabolites differ in having their hydroxy residues in the S or R configurations respectively The accompanying figure gives the structure for 9 S HETE Two other 9 hydroxy linoleic acid derivatives occur in nature the 10E 12E isomers of 9 S HODE and 9 R HODE viz 9 S hydroxy 10E 12E octadecadienoic acid 9 S EE HODE and 9 R hydroxy 10E 12E octadecadienoic acid 13 R EE HODE these two derivatives have their double bond at carbon 12 in the E or trans configuration as opposed to the Z or cis configuration The four 9 HODE isomers particularly under conditions of oxidative stress may form together in cells and tissues they have overlapping but not identical biological activities and significances Because many studies have not distinguished between the S and R stereoisomers and particularly in identifying tissue levels the two EE isomers 9 HODE is used here when the isomer studied is unclear 9 Hydroxyoctadecadienoic acid NamesPreferred IUPAC name 9S 10E 12Z 9 Hydroxyoctadeca 10 12 dienoic acidOther names a Dimorphecolic acid9 hydroxy 10 E 12 Z octadecadienoic acidIdentifiersCAS Number 73543 67 6 Y3D model JSmol Interactive imageChemSpider 4472255ECHA InfoCard 100 230 886PubChem CID 5312830UNII 42KE04U9BM YCompTox Dashboard EPA DTXSID20868260InChI InChI 1S C18H32O3 c1 2 3 4 5 6 8 11 14 17 19 15 12 9 7 10 13 16 18 20 21 h6 8 11 14 17 19H 2 5 7 9 10 12 13 15 16H2 1H3 H 20 21 b8 6 14 11 t17 m1 s1 COPYKey NPDSHTNEKLQQIJ UINYOVNOSA NSMILES CCCCC C C C C C H CCCCCCCC O O OPropertiesChemical formula C 18H 32O 3Molar mass 296 451 g mol 1Except where otherwise noted data are given for materials in their standard state at 25 C 77 F 100 kPa Infobox references A similar set of 13 Hydroxyoctadecadienoic acid 13 HODE metabolites 13 S HODE 13 R HODE 13 S EE HODE and 13 R EE HODE also occurs naturally and again particularly under conditions of oxidative stress may form concurrently with 9 HODEs these 13 HODEs also have overlapping and complementary but not identical activities with the 9 HODEs Some recent studies measuring HODE levels in tissue have lumped the four 9 HODEs and four 13 HODEs together to report only on total HODEs tHODEs tHODEs have been proposed to be markers for certain human disease Other recent studies have lumped together the 9 S 9 R 13 S and 13 R HODE along with the two ketone metabolites of these HODEs 9 oxoODE 9 oxo 10 E 12 Z octadecadienoic acid and 13 oxoODE reporting only on total OXLAMs oxidized linoleic acid metabolites the OXLAMs have been implicated in working together to signal for pain perception Contents 1 Pathways making 9 HODEs 1 1 Cyclooxygenases 1 and 2 1 2 Cytochrome P450 1 3 Free radical and singlet oxygen oxidations 1 4 Mouse 8 S lipoxygenase 2 Metabolism 3 Direct actions 4 Biological and clinical relevancy 4 1 As markers of disease involving oxidative stress 4 2 As mediators of oxidative stress related diseases 4 3 As mediators of pain perception 4 4 As contributors to atherosclerosis 5 ReferencesPathways making 9 HODEs editCyclooxygenases 1 and 2 edit The enzymes cyclooxygenase 1 COX 1 and cyclooxygenase 2 COX 2 which are best known for metabolizing arachidonic acid to prostaglandins are also able to metabolize linoleic acid predominantly to 9 R hydroperoxy 10 E 12 Z octadecadienoic acid i e 9 R HpODE HODE and lesser amounts of 9 S hydroperoxy 10 E 12 Z octadecadienoic acid i e 9 S HpODE in cells and tissues the two hydroperoxy metabolites are rapidly reduce to 9 R HODE and 9 S HODE respectively 1 2 3 COX 2 exhibits a greater preference for linoleic acid than does Cox 1 and is therefore credited with producing most of these products in cells expressing both COX enzymes 2 The COXs also metabolize linoleic acid to 13 S hydroperoxy octadecadionoic acid 13 S HpODE and lesser amounts of 13 R hydroperoxy octadecadienoic acid 13 R HpODE which are then rapidly reduced to 13 S HODE and 13 R HODE the two enzymes therefore metabolize linoleic acid predominantly to the R stereoisomer of 9 HODE and S stereoisomer of 13 HODE with the 13 HODE products predominating over the 9 HODE products 1 2 4 Cytochrome P450 edit Cytochrome P450 microsomal enzymes metabolize linoleic acid to a mixture of 9 S HpODE and 9 R HpODE which are subsequently reduced to their corresponding hydroxy products these reactions produce racemic mixtures in which the R stereoisomer predominates for instance by a R S ratio of 80 20 in human liver microsomes 5 6 7 In cells and tissues the cytochrome enzymes concurrently metabolize linoleic acid to 13 S HpODE and 13 R HpODE which are reduced to 13 S HODE and 13 R HODE in an R S ratio similar to than of the 9 HODES i e 80 20 6 Free radical and singlet oxygen oxidations edit Oxidative stress in cells and tissues produces Free radical induced and singlet oxygen induced oxidations of linoleic acid to generate the various racemic mixtures of 9 HpODE and 9 HODE in non enzymatic reactions that produce or are suspected but not proven to produce approximately equal amounts of their S and R stereoisomers 8 9 10 These oxidations are credited with being the major contributors to 9 HODE and 13 HODE isomer production in tissues undergoing oxidative stress such as occurs in any tissue suffering inadequate blood flow inflammation or other serious insult in liver steatohepatitis in the atheroma plaques of cardiovascular disease in nerve tissues of neurodegenerative diseases and in the various tissues compromised by diabetes see oxidative stress 11 12 Free radical oxidation of linoleic acid produces racemic mixtures of 9 HODE and 9 EE HODE singlet oxygen attack on linoleic acid produces presumably racemic mixtures of 9 HODE 10 hydroxy 8E 12Z octadecadienoic acid and 12 hydroxy 9Z 13 E octadecadienoic acid 13 12 Since free radical induced and singlet oxygen induced oxidations of linoleic acid produce a similar set of 13 HODE metabolites see 13 Hydroxyoctadecadienoic acid since both free radicals and singlet oxygen attack not only free linoleic acid but also linoleic acid bound to phospholipids glycerides cholesterol and other lipids and since free radical and singlet oxygen reactions may occur together oxygen stressed tissues often contain an array of free and lipid bound 9 HODE and 13 HODE products For example laboratory studies find that 9 HODE and 9 EE HODE along with their 13 HODE counterparts are found in the phospholipid and cholesterol components of low density lipoproteins that have been oxidized by human monocytes the reaction appears due to the in situ free radical and or superoxide induced oxidation of the lipoproteins 14 Mouse 8 S lipoxygenase edit The murine homolog of human 15 S lipoxygenase 2 ALOX15B 8 S lipoxygenase while preferring arachidonic acid over linoleic acid metabolizes linoleic acid predominantly to 9 S HpODE which in tissues and cells is rapidly reduced to 9 S HODE 15 16 However ALOX15B similar to human 15 lipoxygenase 1 ALOX15 metabolizes linoleic acid to 13 S HODE but not to 9 S HODEs 17 18 Metabolism editLike most unsaturated fatty acids the 9 HODEs formed in cells are incorporated into cellular phospholipids principally at the sn 2 position of the phospholipid see Phospholipase A2 19 20 since however the linoleic acid bound to cellular phospholipids is susceptible to non enzymatic peroxidation and free radical attack 21 22 23 the 9 HODEs in cellular phospholipids may also derive more directly from in situ oxidation 9 HODE esterified to the sn 2 position of phosphatidylserine is subject to be released as free 9 HODE by the action of cytosol see phospholipase A2 section on cPLA2 and therefore may serve as a storage pool that is mobilized by cell stimulation 23 9 HODE may be further metabolized to 9 oxo 10 E 12 Z octadecadienoic acid 9 oxoODE or 9 oxo ODE possibly by the same hydroxy fatty acid dehydrogenase which metabolizes other hydroxy fatty acids such as 13 HODE to their oxo derivatives 24 Direct actions edit9 HODE 9 oxoODE and 9 EE HODE along with their 13 HODE counterparts directly activate peroxisome proliferator activated receptor gamma PPARg 25 26 27 This activation appears responsible for the ability of 13 HODE and 9 HODE to induce the transcription of PPARg inducible genes in human monocytes as well as to stimulate the maturation of these cells to macrophages 25 13 S HODE and 9 S HODE also stimulate the activation of peroxisome proliferator activated receptor beta PPARb in a model cell system 13 HODE and 9 HODE are also proposed to contribute to the ability of oxidized low density lipoprotein LDL to activate PPARbl LDL containing phospholipid bound 13 HODE and 9 HODE is taken up by the cell and then acted on by phospholipases to release the HODEs which in turn directly activate PPARbl 28 13 S HODE 13 R HODE and 13 oxoODE along with their 9 HODE counterparts also act on cells through TRPV1 TRPV1 is the transient receptor potential cation channel subfamily V member 1 receptor also termed capsaicin receptor or vanilloid receptor 1 These 6 HODEs dubbed oxidized linoleic acid metabolites OXLAMs individually but also and possibly to a greater extent when acting together stimulate TRPV1 dependent responses in rodent neurons rodent and human bronchial epithelial cells and in model cells made to express rodent or human TRPV1 This stimulation appears due to a direct interaction of these agents on TRPV1 although reports disagree on the potencies of the OXLAMs with for example the most potent OXLAM 9 S HODE requiring at least 10 micromoles liter 29 or a more physiological concentration of 10 nanomoles liter 30 to activate TRPV1 in rodent neurons The OXLAM TRPV1 interaction is credited with mediating pain sensation in rodents see below 9 S HODE and with progressively lesser potencies 9 S HpODE a racemic mixture of 9 HODE 13 S HpODE and 13 S HODE directly activate human but not mouse GPR132 i e G protein coupled receptor 132 or G2A in Chinese hamster ovary cells made to express these receptors 9 S HODE was also a more potent stimulator of human G2A than a series of mono hydroxy arachidonic acid metabolites 31 32 GPR132 was initially described as a pH sensing receptor the role s of 9 HODEs as well as other linoleic and arachidonic acid metabolites in activating GPR132 under the physiological and pathological conditions in which it is implicated to be involved see see GPR132 for a listing of these conditions have not yet been determined This determination as it might apply to humans is made difficult by the inability of these HODEs to activate rodent GPR132 and therefore to be analyzed in rodent models Biological and clinical relevancy editAs markers of disease involving oxidative stress edit Various measurements of tissue and blood levels of reactive oxygen species have been used as markers of diseases in which these species are generated and may contribute to tissue injury and systemic disturbances examples of such diseases include a wide range of neurological cardiovascular infectious autoimmune and genetic diseases see oxidative stress HODEs measurements have been evaluated as markers for many of these oxygen stress related diseases These measurements commonly use saponification methods to release HODEs bound by acylation to other molecules they therefore measure not only free HODEs but also HODEs acylated to phospholipids glycerides cholesterol and other lipids Studies find that 1 9 S HODE and 13 S HODE levels are elevated in the plasma of older patients with early stage cataracts compared to non cataract subjects 2 9 HODE and 13 HODE are increased in the low density lipoproteins of patients with rheumatoid arthritis compared to healthy subjects as well as in the destructive but not normal bone tissue of the rheumatoid arthritic patients 3 total HODEs includes 9 HODE and 13 HODE stereoisomers are higher in the plasma and liver of patients with hepatitis C and hepatitis B chronic viral infections as well as in the plasma and red blood cells of patients with Alzheimer s disease compared to healthy subjects 4 9 HODE and 9 oxoODE as well as 13 HODE and 13 oxo ODE levels were elevated in the serum and or pancreatic secretions of patients with pancreatitis compared to control subjects 5 levels of the hydroperoxy precursors to 9 HODE and 13 HODE are elevated in the plasma and or red blood cells of patients with Alzheimer s disease atherosclerosis diabetes diabetic nephritis non alcoholic steatohepatitis and alcoholic steatohepatitis compared to healthy subjects 33 34 35 36 37 38 39 These studies suggest that high levels of the HODEs may be useful to indicate the presence and progression of the cited diseases Since however the absolute values of HODEs found in different studies vary greatly since HODE levels vary with dietary linoleic acid intake since HODEs may form during the processing of tissues and since abnormal HODE levels are not linked to a specific disease the use of these metabolites as markers has not attained clinical usefulness 11 37 40 12 HODE markers may find usefulness as markers of specific disease type of disease and or progression of disease when combined with other disease markers 12 41 As mediators of oxidative stress related diseases edit Some of the studies cited above have suggested that 9 HODEs 13 HODEs their hydroperoxy counterparts and or their oxo counterparts contribute mechanistically to these oxidative stress related diseases That is the free radical oxidation of linoleic acid makes these products which then proceed to contribute to the tissue injury DNA damage and or systemic dysfunctions that characterize the diseases 42 43 44 45 46 Furthermore certain of these HODE related products may serve as signals to activate pathways that combat the reactive oxygen species and in this and other ways the oxidative stress It remains unclear whether or not the HODEs and their counterparts promote dampen or merely reflect oxidative stress related diseases As mediators of pain perception edit 9 S HODE 9 R HODE and 9 oxoODE along with the other OXLAMs appear to act through the TRPV1 receptor see above section on Direct actions mediate the perception of acute and chronic pain induced by heat UV light and inflammation in the skin of rodents 30 47 48 49 50 These studies propose that the OXLAM TRPV1 circuit with 9 S HODE being the most potent TRPV1 activating OXLAM similarly contributes to the perception of pain in humans As contributors to atherosclerosis edit 9 HODEs 13 HODEs and low density lipoprotein which has been oxidized so that it contains HODEs stimulate the expression of interleukin 1b mRNA in and its extracellular release from human peripheral blood monocyte derived macrophages interleukin 1b is implicated in the proliferation of smooth muscle cells that occurs in atherosclerosis and contributes to blood vessel narrowing 51 References edit a b J Biol Chem 1995 Aug 18 270 33 19330 6 a b c J Invest Dermatol 1996 Nov 107 5 726 32 rch Biochem Biophys 1998 Jan 15 349 2 376 80 Prostaglandins 1989 Aug 38 2 203 14 Arch Biochem Biophys 1984 Aug 15 233 1 80 7 a b Biochim Biophys Acta 1993 Feb 24 1166 2 3 258 63 Ruparel Shivani Green Dustin Chen Paul Hargreaves Kenneth M 2012 The Cytochrome P450 Inhibitor Ketoconazole Inhibits Oxidized Linoleic Acid Metabolite Mediated Peripheral Inflammatory Pain Molecular Pain 8 1744 8069 8 73 doi 10 1186 1744 8069 8 73 PMC 3488501 PMID 23006841 Prog Lipid Res 1984 23 4 197 221 Biochim Biophys Acta 1998 May 20 1392 1 23 40 Chem Res Toxicol 2005 Feb 18 2 349 56 a b Ramsden Christopher E Ringel Amit 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JNEUROSCI 3993 14 2015 PMC 4452557 PMID 26041925 J Biol Chem 1992 Jul 15 267 20 14183 8 Retrieved from https en wikipedia org w index php title 9 Hydroxyoctadecadienoic acid amp oldid 1189311423, wikipedia, wiki, book, books, library,

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