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13-Hydroxyoctadecadienoic acid

January 01, 1970

13-Hydroxyoctadecadienoic acid (13-HODE) is the commonly used term for 13(S)-hydroxy-9Z,11E-octadecadienoic acid (13(S)-HODE). The production of 13(S)-HODE is often accompanied by the production of its stereoisomer, 13(R)-hydroxy-9Z,11E-octadecadienoic acid (13(R)-HODE). The adjacent figure gives the structure for the (S) stereoisomer of 13-HODE. Two other naturally occurring 13-HODEs that may accompany the production of 13(S)-HODE are its cis-trans (i.e., 9E,11E) isomers viz., 13(S)-hydroxy-9E,11E-octadecadienoic acid (13(S)-EE-HODE) and 13(R)-hydroxy-9E,11E-octadecadienoic acid (13(R)-EE-HODE). Studies credit 13(S)-HODE with a range of clinically relevant bioactivities; recent studies have assigned activities to 13(R)-HODE that differ from those of 13(S)-HODE; and other studies have proposed that one or more of these HODEs mediate physiological and pathological responses, are markers of various human diseases, and/or contribute to the progression of certain diseases in humans. Since, however, many studies on the identification, quantification, and actions of 13(S)-HODE in cells and tissues have employed methods that did not distinguish between these isomers, 13-HODE is used here when the actual isomer studied is unclear.

13-Hydroxyoctadecadienoic acid
Names
Preferred IUPAC name
(9Z,11E,13S)-13-Hydroxyoctadeca-9,11-dienoic acid
Other names
13(S)-HODE, 13S-HODE
Identifiers
  • 29623-28-7 Y
  • 9Z,11E,13S: 5204-88-6
  • 9Z,11E,13R: 10219-69-9
3D model (JSmol)
  • 9E,11E: Interactive image
  • 9Z,11E,13S: Interactive image
  • 9Z,11E,13R: Interactive image
ChEBI
  • CHEBI:137495
  • 9Z,11E,13S: CHEBI:34154
ChEMBL
  • 9Z,11E,13S: ChEMBL451721
ChemSpider
  • 4947055
KEGG
  • 9Z,11E,13R: C14762
  • 9E,11E: 5282948
  • 9Z,11E,13S: 6443013
  • 9Z,11E,13R: 13723970
UNII
  • 53CYY2A5PM Y
  • InChI=1S/C18H32O3/c1-2-3-11-14-17(19)15-12-9-7-5-4-6-8-10-13-16-18(20)21/h7,9,12,15,17,19H,2-6,8,10-11,13-14,16H2,1H3,(H,20,21)/b9-7-,15-12+/t17-/m0/s1
    Key: HNICUWMFWZBIFP-IRQZEAMPSA-N
  • 9Z,11E,13R: InChI=1S/C18H32O3/c1-2-3-11-14-17(19)15-12-9-7-5-4-6-8-10-13-16-18(20)21/h7,9,12,15,17,19H,2-6,8,10-11,13-14,16H2,1H3,(H,20,21)/b9-7-,15-12+/t17-/m1/s1
  • 9E,11E: CCCCCC(/C=C/C=C/CCCCCCCC(=O)O)O
  • 9Z,11E,13S: CCCCC[C@@H](/C=C/C=C\CCCCCCCC(=O)O)O
  • 9Z,11E,13R: CCCCC[C@H](/C=C/C=C\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 9-Hydroxyoctadecadienoic acid (9-HODE) metabolites (i.e., 9(S)-HODE), 9(R)-HODE, 9(S)-EE-HODE), and 9(R)-EE-HODE) occurs naturally and particularly under conditions of oxidative stress forms concurrently with the 13-HODEs; the 9-HODEs have overlapping and complementary but not identical activities with the 13-HODEs. Some recent studies measuring HODE levels in tissue have lumped the four 9-HODEs with the four 13-HODEs to report only on total HODEs (tHODEs). tHODEs have been proposed to be markers for certain human diseases. Other studies have lumped together the 9-(S), 9(R), 13 (S)-, and 13(R)-HODEs along with the two ketone metabolites of these HODEs, 13-oxoODE (13-oxo-9Z,12E-octadecadienoic acid) and 9-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 13-HODEs edit

15-Lipoxygenase 1 edit

15-lipoxygenase 1 (ALOX15), while best known for converting the 20 carbon polyunsaturated fatty acid, arachidonic acid, into a series of 15-hydroxylated arachidonic acid metabolites (see 15-hydroxyicosatetraenoic acid), actually prefers as its substrate the 18 carbon polyunsaturated fatty acid, linoleic acid, over arachidonic acid, converting it to 13-hydroperoxy-9Z,11E-octadecadienoic acid (13-HpODE).[1][2] The enzyme acts in a highly stereospecific manner, forming 13(S)-hydroperoxy-9Z,11E-octadecadienoic acid (13(S)-HpODE) but comparatively little or no 13(R)-hydroperoxy-9Z,11E-octadecadienoic acid (13(R)-HpODE) -.[3][4] In cells, 13(S)-HpODE is rapidly reduced by peroxidases to 13(S)-HODE.[1][5] ALOX15 is fully capable of metabolizing the linoleic acid that is bound to phospholipid[6] or cholesterol[7] to form 13(S)-HpODE-bound phospholipids and cholesterol that are rapidly converted to their corresponding 13(S)-HODE-bound products.

15-lipoxygenase 2 edit

15-lipoxygenase type 2 (ALOX15B) strongly prefers arachidonic acid over linoleic acid and in consequence is relatively poor in metabolizing linoleic acid to 13(S)-HpODE (which is then converted to 13(S)-HODE) compared to 15-lipoxygenase 1;[8] nonetheless, it can contribute to the production of these metabolites.[2][9]

Cyclooxygenases 1 and 2 edit

Cyclooxygenase 1 (COX-1) and cyclooxygenase 2 (COX-2) metabolize linoleic acid to 13(S)-HODE with COX-2 exhibiting a higher preference for linoleic acid and therefore producing far more of this product than its COX-1 counterpart;[10] consequently, COX-2 appears to be the principle COX making 13(S)-HODE in cells expressing both enzymes.[11] Concurrently with their production of 13(S)-HODE, these enzymes also produce smaller amounts of 9(R)-HODE.[12][11]

Cytochrome P450 edit

Cytochrome P450 microsomal enzymes metabolize linoleic acid to a mixture of 13-HODEs and 9-HODEs; these reactions produce racemic mixtures in which the R stereoisomer predominates, for instance by a R/S ratio of 80%/20% for both 13-HODE and 9-HODE in human liver microsomes.[13][14][15]

Free radical and singlet oxygen oxidations edit

Oxidative stress in cells and tissues produces Free radical and singlet oxygen oxidations of linoleic acid to generate 13-HpODEs, 9-HpODEs, 13-HODEs, and 9-HODEs; these non-enzymatic reactions produce or are suspected but not proven to produce approximately equal amounts of their S and R stereoisomers.[16][17][18] Free radical oxidations of linoleic acid also produce 13-EE-HODE, 9-hydroxy-10E,12-E-octadecadienoic acid, 9-hydroxy-10E,12-Z-octadecadienoic acid, and 11-hydroxy-9Z,12Z-octadecadienoic acid while singlet oxygen attacks on linoleic acid produce (presumably) racemic mixtures of 9-hydroxy-10E,12-Z-octadecadienoic acid, 10-hydroxy-8E,12Z-octadecadienoic acid, and 12-hydroxy-9Z-13-E-octadecadienoic acid.[19] 4-Hydroxynonenal (i.e. 4-hydroxy-2E-nonenal or HNE) is also a peroxidation product of 13-HpODE.[20] Since oxidative stress commonly produces both free radicals and singlet oxygen, most or all of these products may form together in tissues undergoing oxidative stress. Free radical and singlet oxygen oxidations of linoleic acid produce a similar set of 13-HODE metabolites (see 9-Hydroxyoctadecadienoic acid). Studies attribute these oxidations to be major contributors to 13-HODE production in tissues undergoing oxidative stress including in humans sites of inflammation, steatohepatitis, cardiovascular disease-related atheroma plaques, neurodegenerative disease, etc. (see oxidative stress).[21][19]

Metabolism of 13(S)-HODE edit

Like most polyunsaturated fatty acids and mono-hydroxyl polyunsaturated fatty acids, 13(S)-HODE is rapidly and quantitatively incorporated into phospholipids;[22] the levels of 13(S)-HODE esterified to the sn-2 position of phosphatidylcholine, phosphatidylinositol, and phosphatidylethanolamine in human psoriasis lesions are significantly lower than those in normal skin; this chain shortening pathway may be responsible for inactivating 13(S)-HODE.[23] 13(S)-HODE is also metabolized by peroxisome-dependent β-oxidations to chain-shortened 16-carbon, 14-carbon, and 12-carbon products which are released from the cell;[24] this chain-shortening pathway may serve to inactive and dispose of 13(S)-HODE.

13(S)-HODE is oxidized to 13-oxo-9Z,11E-octadecadienoic acid (13-oxo-HODE or 13-oxoODE) by a NAD+-dependent 13-HODE dehydrogenase, the protein for which has been partially purified from rat colon.[25][26][27] The formation of 13-oxo-ODE may represent the first step in 13(S)-HODEs peroxisome-dependent chain shortening but 13-oxo-ODE has its own areas of biological importance: it accumulates in tissues,[28][29] is bioactive,[30][31] and may have clinically relevance as a marker for[32][33] and potential contributor to[33] human disease. 13-Oxo-ODE itself may react with glutathione in a non-enzymatic Michael reaction or a glutathione transferase-dependent reaction to form 13-oxo-ODE products containing an 11 trans double bound and glutathione attached to carbon 9 in a mixture of S and R diastereomers; these two diastereomers are major metabolites of 13(S)-HODE in cultured HT-29 human colon cancer cells.[34] Colonic mucosal explants from Sprague-Dawley rats and human colon cancer HT29 cells add glutathione to 13-oxo-ODE in a Michael reaction to form 13-oxo-9-glutatione-11(E)-octadecenoic acid; this conjugation reaction appears to be enzymatic and mediated by a glutathione transferase.[35][36] Since this conjugate may be rapidly exported from the cell and has not yet been characterized for biological activity, it is not clear if this transferase reaction serves any function beyond removing 13-oxo-ODE from the cell to limit its activity.[34]

Activities edit

Stimulation of peroxisome proliferator-activated receptors edit

13-HODE, 13-oxoODE, and 13-EE-HODE (along with their 9-HODE counterparts) directly activate peroxisome proliferator-activated receptor gamma (PPARγ).[37][38][39] 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.[37] 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.[40]

Stimulation of TRPV1 receptor edit

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[41] 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).

Stimulation of GPR132 receptor edit

13(S)-HpODE, and 13(S)-HODE directly activate human (but not mouse) GPR132 (G protein coupled receptor 132, also termed G2A) in Chinese hamster ovary cells made to express these receptors; they are, however, far weaker GPR132 activators than 9(S)-HpODE or 9(S)-HODE.[42][43] GPR132 was initially described as a pH sensing receptor; the role(s) of 13(S)-HpODE and 13(S)-HODE as well as 9(S)-HpODE, 9(S)HODE, and a series or GPR132-activating arachidonic acid hydroxy metabolites (i.e. HETEs) in activating G2A under the physiological and pathological conditions in which G2A is implicated (see GPR132 for a lists 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.

Involvement in mitochondria degradation edit

In the maturation of the red blood cell lineage (see erythropoiesis) from mitochondria-bearing reticulocytes to mature mitochondria-free erythrocytes in rabbits, the mitochondria accumulate phospholipid-bound 13(S)-HODE in their membranes due to the action of a lipoxygenase which (in rabbits, mice, and other sub-primate vertebrates) directly metabolizes linoleic acid-bound phospholipid to 13(S)-HpODE-bound phospholipid which is rapidly reduced to 13(S)-HODE-bound phospholipid.[44] It is suggested that the accumulation of phospholipid-bound 13(S)-HpODE and/or 13(S)-HODE is a critical step in rendering mitochondria more permeable thereby triggering their degradation and thence maturation to erythrocytes.[44][45] However, functional inactivation of the phospholipid-attacking lipoxygenase gene in mice does not cause major defects in erythropoiesis.[46] It is suggested that mitochondrial degradation proceeds through at least two redundant pathways besides that triggered by lipoxygenase-dependent formation of 13(S)-HpODE- and 13(S)-HODE-bound phospholipids viz., mitochondrial digestion by autophagy and mitochondrial exocytosis.[47] In all events, formation of 13(S)-HODE bound to phospholipid in mitochondrial membranes is one pathway by which they become more permeable and thereby subject to degradation and, as consequence of their release of deleterious elements, to cause cell injury.[48]

Stimulation of blood leukocytes edit

13-HODE (and 9-HODE) are moderately strong stimulators of the directed migration (i.e. chemotaxis) of cow and human neutrophils in vitro[49] whereas 13(R)-HODE (and 9(R)-HODE, and 9(S)-HODE) are weak stimulators of the in vitro directed migration of the human cytotoxic and potentially tissue-injuring lymphocytes, i.e. natural killer cells.[50] These effects may contribute to the pro-inflammatory and tissue-injuring actions ascribed to 13-HODEs (and 9-HODEs).

Involvement in human diseases edit

Atherosclerosis edit

In atherosclerosis, an underlying cause of Coronary artery disease and strokes, atheromatous plaques accumulate in the vascular tunica intima thereby narrowing blood vessel size and decreasing blood flow. In an animal model and in humans 13-HODE (primarily esterified to cholesterol, phospholipids, and possibly other lipids) is a dominant component of these plaques.[51][52][53][54] Since these studies found that early into the progression of the plaques, 13-HODE consisted primarily of the S stereoisomer while more mature plaques contained equal amounts of S and R stereoisomers, it was suggested that 15-LOX-1 contributes to early accumulation while cytochrome and/or free radical pathways contributes to the later accumulation of the plaques. Further studies suggest that 13(S)-HODE contributes to plaque formation by activating the transcription factor, PPARγ (13(R)-HODE lacks this ability[55]), which in turn stimulates the production of two receptors on the surface of macrophages resident in the plaques, 1) CD36, a scavenger receptor for oxidized low density lipoproteins, native lipoproteins, oxidized phospholipids, and long-chain fatty acids, and 2) adipocyte protein 2 (aP2), a fatty acid binding protein; this may cause macrophages to increase their uptake of these lipids, transition to lipid-laden foam cells, and thereby increase plaque size.[56] The 13(S)-HODE/PPARγ axis also causes macrophages to self-destruct by activating apoptosis-inducing pathways;, this effect may also contribute to increases in plaque size.[57] These studies suggest that 13-HODE-producing metabolic pathways,[56] PPARγ,[56][57] CD36,[58] and aP2[59] may be therapeutic targets for treating atherosclerosis-related diseases. Indeed, Statins, which are known to suppress cholesterol synthesis by inhibiting an enzyme in the cholesterol synthesis pathway, 3-hydroxy-3-methyl-glutaryl-CoA reductase HMG-CoA reductase, are widely used to prevent atherosclerosis and atherosclerosis-related diseases. Statins also inhibit PPARγ in human macrophages, vascular endothelial cells, and smooth muscle cells; this action may contribute to their anti-atherogenic effect.[60]

Asthma edit

In guinea pigs, 13(S)-HODE, when injected intravenously, causes a narrowing of lung airways and, when inhaled as an aerosol, mimics the asthmatic hypersensitivity to agents that cause bronchoconstriction by increasing airway narrowing responses to methacholine and histamine.[61] In a mouse model of allergen-induced asthma, 13-HODE levels are elevated,[62] in the latter mouse model, the injection of antibody directed against 13(S)-HODE reduced many of the pathological and physiological features of asthma.[48] mouse forced to overexpress in lung the mouse enzyme (12/15-lipoxygenase) that metabolizes linoleic acid to 13(S)-HODE exhibited elevated levels of this metabolite in lung as well as various pathological and physiological features of asthma,[62] and the instillation of 13(S)HODE replicated many of these features of asthma,[48] In the mouse model of asthma and in the human disease, epithelial cells of lung airways show various pathological changes including disruption of their mitochondria[48][62][63] 13(S)-HODE causes similar disruptive changes in the mitochondria of cultured Beas 2B human airway epithelial cells.[48] Furthermore, humans with asthma exhibit increased levels of 13-HODE in their blood, sputum, and washings form their lung alveola (i.e. bronchoalveolar lavage fluid of BAL) and human eosinophils, which are implicated in contributing to human asthma, metabolize linoleic acid to 13-HODE (and 9-HODE) to a far greater extent than any other type of leukocyte.[64] The mechanism responsible for 13-HODE's impact on airway epithelial cells may involve its activation of the TRPV1 receptor (see previous section on TRPV1): this receptor is highly expressed in mouse and human airway epithelial cells and in Beas 2B human airway epithelial cells and, furthermore, suppression of TRPV1 expression as well as a TPRV1 receptor inhibitor (capsazepan) block mouse airway responses to 13(S)-HODE.[48] While much further work is needed, these pre-clinical studies allow that 13(S)-HODE, made at least in part by eosinophils and operating through TRPV1, may be responsible for the airways damage which occurs in the more severe forms of asthma and that pharmacological inhibitors of TRPV1 may eventually proved to be useful additions to the treatment of asthma.

Cancer edit

Colon cancer edit

Familial adenomatous polyposis is a syndrome that includes the propensity to develop colorectal cancer (and other cancers) due to the inheritance of defective mutations in either the APC (adenomatous polyposis coli) or MUTYH gene. These mutations lead to several abnormalities in the regulation of the growth of colon epithelial cells that ultimately lead to the development of intestinal polyps which have a high risk of turning cancerous.[65] One of the abnormalities found in the APC disease is progressive reductions in 15-lipoxygenase 1 along with its product, 13-HODE (presumed but not unambiguously shown to be the S stereoisomer) as the colon disease advances from polyp to malignant stages; 15-HETE, 5-lipoxygenase, 12-lipoxygenase, and 15-lipoxygenase-2, and selected metabolites of the latter lipoxygenases show no such association.[66][67][68] Similarly selective reductions in 15-lipoxygenase 1 and 13-HODE occur in non-hereditary colon cancer.[69][70][66] 13(S)-HODE inhibits the proliferation and causes the death (apoptosis) of cultured human colon cancer cells.[55][69][71][70] Animal model studies also find that the 15-lipoxygenase 1 / 13-HODE axis inhibits the development of drug-induced colon cancer as well as the growth of human colon cancer cell explants.[67] These results suggest that 15-lipoxygenase 1 and its 13(S)-HODE product are factors in promoting genetically-associated and -non-associated colon cancers; they function by contributing to the suppression of the development and/or growth of this cancer and when reduced or absent allow its unrestrained, malignant growth.

Breast cancer edit

13(S)-HODE stimulates the proliferation of human MCF-7 estrogen receptor positive and MBA-MD-231 estrogen receptor negative human breast cancer cell lines (see List of breast cancer cell lines) in culture);[72] its production appears necessary for epidermal growth factor and tumor growth factor α to stimulate cultured BT-20 human breast cancer cells to proliferate[73] and for human breast cancer xenografts to grow in mice.;[74] and among a series of 10 polyunsaturated fatty acid metabolites quantified in human breast cancer tissue, only 13-HODE (stereoisomer not defined) was significantly elevated in rapidly growing, compared to slower growing, cancers.[72] The results of these studies suggest that 13(S)-HODE may act to promote the growth of breast cancer in humans.

Prostate cancer edit

15-LOX 1 is overexpressed in prostate cancerous compared to non-cancerous prostate tissue and the levels of its expression in cultured various human prostate cancer cell lines correlates positively with their rates of proliferation and increases the proliferation response of prostate cancer cells to epidermal growth factor and insulin-like growth factor 1); its levels in human prostate cancer tissues also correlates positively with the cancers' severity as judged by the cancers' Gleason score; and overexpressed 15-LOX 1 appears to not only increase prostate cancer cell proliferation, but also promotes its cell survival by stimulating production and of insulin-like growth factor 1 and possibly altering the Bcl-2 pathway of cellular apoptosis as well as increases prostate tumor vascularization and thereby metastasis by stimulating production of vascular endothelial growth factor. These 15-LOX 1 effects appear due to the enzyme's production of 13(S)-HODE.[75][76][77] The 15-LOX 1/13(S)-HODE axis also promotes the growth of prostate cancer in various animal models.[78][79] In one animal model the pro-growth effects of 15-LOX 1 were altered by dietary targeting: increases in dietary linoleic acid, an omega-6 fatty acid, promoted while increases in dietary stearidonic acid, an omega-3 fatty acid reduced the growth of human prostate cancer explants.[80] These effects could be due to the ability of the linoleic acid diet to increase the production of the 15-Lox 1 metabolite, 13-HODE,[80] and the ability of the stearidonic acid to increase the production of docosahexaenoic acid and the 15-LOX-1 metabolites of docosahexaenoic acid, 17S-hydroperoxy-docosa-hexa-4Z,7Z,10Z,13 Z,15E,19Z-enoate(17-HpDHA, 17S-hydroxy-docosahexa-4Z,7Z,10Z,13Z,15E,19Z-enoate(17-HDHA), 10S,17S-dihydroxy-docosahexa-4Z,7Z,11E,13Z,15E,19Z-enoate(10,17-diHDHA, protectin DX), and 7S,17S-dihydroxy-docsahexa-4Z,8E,10Z,13Z,15E,19Z-enoate(7,17-diHDHA, protectin D5), all of which are inhibitors of cultured human prostate cancer cell proliferation.[81][82][83]

Markers for disease edit

13-HODE levels are elevated, compared to appropriate controls, in the low density lipoproteins isolated from individuals with rheumatoid arthritis,[84] in the high-density lipoprotein fraction of patients with diabetes,[85] in the serum of individuals with polycystic kidney disease.[86] or chronic pancreatitis,[87] and in the plasma of individuals with alcoholic and non-alcoholic steatohepatitis.[88][89] The level of total HODEs, which includes various 13-HODE and 9-HODE isomers, are elevated in the plasma and erythrocytes of patients with Alzheimer's disease and in the plasma but not erythrocytes of patients with vascular dementia compared to normal volunteers.[90] See 9-hydroxyoctadecadienoic acid section on 9-HODEs as markers of disease involving oxidative stress for further details. 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.[21][91][92][19] HODE markers may find usefulness as markers of specific disease, type of disease, and/or progression of disease when combined with other disease markers.[19][93]

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January 01, 1970
hydroxyoctadecadienoic, acid, hode, commonly, used, term, hydroxy, octadecadienoic, acid, hode, production, hode, often, accompanied, production, stereoisomer, hydroxy, octadecadienoic, acid, hode, adjacent, figure, gives, structure, stereoisomer, hode, other,. 13 Hydroxyoctadecadienoic acid 13 HODE is the commonly used term for 13 S hydroxy 9Z 11E octadecadienoic acid 13 S HODE The production of 13 S HODE is often accompanied by the production of its stereoisomer 13 R hydroxy 9Z 11E octadecadienoic acid 13 R HODE The adjacent figure gives the structure for the S stereoisomer of 13 HODE Two other naturally occurring 13 HODEs that may accompany the production of 13 S HODE are its cis trans i e 9E 11E isomers viz 13 S hydroxy 9E 11E octadecadienoic acid 13 S EE HODE and 13 R hydroxy 9E 11E octadecadienoic acid 13 R EE HODE Studies credit 13 S HODE with a range of clinically relevant bioactivities recent studies have assigned activities to 13 R HODE that differ from those of 13 S HODE and other studies have proposed that one or more of these HODEs mediate physiological and pathological responses are markers of various human diseases and or contribute to the progression of certain diseases in humans Since however many studies on the identification quantification and actions of 13 S HODE in cells and tissues have employed methods that did not distinguish between these isomers 13 HODE is used here when the actual isomer studied is unclear 13 Hydroxyoctadecadienoic acid Names Preferred IUPAC name 9Z 11E 13S 13 Hydroxyoctadeca 9 11 dienoic acid Other names 13 S HODE 13S HODE Identifiers CAS Number 29623 28 7 Y9Z 11E 13S 5204 88 69Z 11E 13R 10219 69 9 3D model JSmol 9E 11E Interactive image9Z 11E 13S Interactive image9Z 11E 13R Interactive image ChEBI CHEBI 1374959Z 11E 13S CHEBI 34154 ChEMBL 9Z 11E 13S ChEMBL451721 ChemSpider 4947055 KEGG 9Z 11E 13R C14762 PubChem CID 9E 11E 52829489Z 11E 13S 64430139Z 11E 13R 13723970 UNII 53CYY2A5PM Y InChI InChI 1S C18H32O3 c1 2 3 11 14 17 19 15 12 9 7 5 4 6 8 10 13 16 18 20 21 h7 9 12 15 17 19H 2 6 8 10 11 13 14 16H2 1H3 H 20 21 b9 7 15 12 t17 m0 s1Key HNICUWMFWZBIFP IRQZEAMPSA N9Z 11E 13R InChI 1S C18H32O3 c1 2 3 11 14 17 19 15 12 9 7 5 4 6 8 10 13 16 18 20 21 h7 9 12 15 17 19H 2 6 8 10 11 13 14 16H2 1H3 H 20 21 b9 7 15 12 t17 m1 s1 SMILES 9E 11E CCCCCC C C C C CCCCCCCC O O O9Z 11E 13S CCCCC C H C C C C CCCCCCCC O O O9Z 11E 13R CCCCC C H C C C C CCCCCCCC O O O Properties Chemical formula C 18H 32O 3 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 Infobox references A similar set of 9 Hydroxyoctadecadienoic acid 9 HODE metabolites i e 9 S HODE 9 R HODE 9 S EE HODE and 9 R EE HODE occurs naturally and particularly under conditions of oxidative stress forms concurrently with the 13 HODEs the 9 HODEs have overlapping and complementary but not identical activities with the 13 HODEs Some recent studies measuring HODE levels in tissue have lumped the four 9 HODEs with the four 13 HODEs to report only on total HODEs tHODEs tHODEs have been proposed to be markers for certain human diseases Other studies have lumped together the 9 S 9 R 13 S and 13 R HODEs along with the two ketone metabolites of these HODEs 13 oxoODE 13 oxo 9Z 12E octadecadienoic acid and 9 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 13 HODEs 1 1 15 Lipoxygenase 1 1 2 15 lipoxygenase 2 1 3 Cyclooxygenases 1 and 2 1 4 Cytochrome P450 1 5 Free radical and singlet oxygen oxidations 2 Metabolism of 13 S HODE 3 Activities 3 1 Stimulation of peroxisome proliferator activated receptors 3 2 Stimulation of TRPV1 receptor 3 3 Stimulation of GPR132 receptor 3 4 Involvement in mitochondria degradation 3 5 Stimulation of blood leukocytes 4 Involvement in human diseases 4 1 Atherosclerosis 4 2 Asthma 4 3 Cancer 4 3 1 Colon cancer 4 3 2 Breast cancer 4 3 3 Prostate cancer 4 4 Markers for disease 5 ReferencesPathways making 13 HODEs edit15 Lipoxygenase 1 edit 15 lipoxygenase 1 ALOX15 while best known for converting the 20 carbon polyunsaturated fatty acid arachidonic acid into a series of 15 hydroxylated arachidonic acid metabolites see 15 hydroxyicosatetraenoic acid actually prefers as its substrate the 18 carbon polyunsaturated fatty acid linoleic acid over arachidonic acid converting it to 13 hydroperoxy 9Z 11E octadecadienoic acid 13 HpODE 1 2 The enzyme acts in a highly stereospecific manner forming 13 S hydroperoxy 9Z 11E octadecadienoic acid 13 S HpODE but comparatively little or no 13 R hydroperoxy 9Z 11E octadecadienoic acid 13 R HpODE 3 4 In cells 13 S HpODE is rapidly reduced by peroxidases to 13 S HODE 1 5 ALOX15 is fully capable of metabolizing the linoleic acid that is bound to phospholipid 6 or cholesterol 7 to form 13 S HpODE bound phospholipids and cholesterol that are rapidly converted to their corresponding 13 S HODE bound products 15 lipoxygenase 2 edit 15 lipoxygenase type 2 ALOX15B strongly prefers arachidonic acid over linoleic acid and in consequence is relatively poor in metabolizing linoleic acid to 13 S HpODE which is then converted to 13 S HODE compared to 15 lipoxygenase 1 8 nonetheless it can contribute to the production of these metabolites 2 9 Cyclooxygenases 1 and 2 edit Cyclooxygenase 1 COX 1 and cyclooxygenase 2 COX 2 metabolize linoleic acid to 13 S HODE with COX 2 exhibiting a higher preference for linoleic acid and therefore producing far more of this product than its COX 1 counterpart 10 consequently COX 2 appears to be the principle COX making 13 S HODE in cells expressing both enzymes 11 Concurrently with their production of 13 S HODE these enzymes also produce smaller amounts of 9 R HODE 12 11 Cytochrome P450 edit Cytochrome P450 microsomal enzymes metabolize linoleic acid to a mixture of 13 HODEs and 9 HODEs these reactions produce racemic mixtures in which the R stereoisomer predominates for instance by a R S ratio of 80 20 for both 13 HODE and 9 HODE in human liver microsomes 13 14 15 Free radical and singlet oxygen oxidations edit Oxidative stress in cells and tissues produces Free radical and singlet oxygen oxidations of linoleic acid to generate 13 HpODEs 9 HpODEs 13 HODEs and 9 HODEs these non enzymatic reactions produce or are suspected but not proven to produce approximately equal amounts of their S and R stereoisomers 16 17 18 Free radical oxidations of linoleic acid also produce 13 EE HODE 9 hydroxy 10E 12 E octadecadienoic acid 9 hydroxy 10E 12 Z octadecadienoic acid and 11 hydroxy 9Z 12Z octadecadienoic acid while singlet oxygen attacks on linoleic acid produce presumably racemic mixtures of 9 hydroxy 10E 12 Z octadecadienoic acid 10 hydroxy 8E 12Z octadecadienoic acid and 12 hydroxy 9Z 13 E octadecadienoic acid 19 4 Hydroxynonenal i e 4 hydroxy 2E nonenal or HNE is also a peroxidation product of 13 HpODE 20 Since oxidative stress commonly produces both free radicals and singlet oxygen most or all of these products may form together in tissues undergoing oxidative stress Free radical and singlet oxygen oxidations of linoleic acid produce a similar set of 13 HODE metabolites see 9 Hydroxyoctadecadienoic acid Studies attribute these oxidations to be major contributors to 13 HODE production in tissues undergoing oxidative stress including in humans sites of inflammation steatohepatitis cardiovascular disease related atheroma plaques neurodegenerative disease etc see oxidative stress 21 19 Metabolism of 13 S HODE editLike most polyunsaturated fatty acids and mono hydroxyl polyunsaturated fatty acids 13 S HODE is rapidly and quantitatively incorporated into phospholipids 22 the levels of 13 S HODE esterified to the sn 2 position of phosphatidylcholine phosphatidylinositol and phosphatidylethanolamine in human psoriasis lesions are significantly lower than those in normal skin this chain shortening pathway may be responsible for inactivating 13 S HODE 23 13 S HODE is also metabolized by peroxisome dependent b oxidations to chain shortened 16 carbon 14 carbon and 12 carbon products which are released from the cell 24 this chain shortening pathway may serve to inactive and dispose of 13 S HODE 13 S HODE is oxidized to 13 oxo 9Z 11E octadecadienoic acid 13 oxo HODE or 13 oxoODE by a NAD dependent 13 HODE dehydrogenase the protein for which has been partially purified from rat colon 25 26 27 The formation of 13 oxo ODE may represent the first step in 13 S HODEs peroxisome dependent chain shortening but 13 oxo ODE has its own areas of biological importance it accumulates in tissues 28 29 is bioactive 30 31 and may have clinically relevance as a marker for 32 33 and potential contributor to 33 human disease 13 Oxo ODE itself may react with glutathione in a non enzymatic Michael reaction or a glutathione transferase dependent reaction to form 13 oxo ODE products containing an 11 trans double bound and glutathione attached to carbon 9 in a mixture of S and R diastereomers these two diastereomers are major metabolites of 13 S HODE in cultured HT 29 human colon cancer cells 34 Colonic mucosal explants from Sprague Dawley rats and human colon cancer HT29 cells add glutathione to 13 oxo ODE in a Michael reaction to form 13 oxo 9 glutatione 11 E octadecenoic acid this conjugation reaction appears to be enzymatic and mediated by a glutathione transferase 35 36 Since this conjugate may be rapidly exported from the cell and has not yet been characterized for biological activity it is not clear if this transferase reaction serves any function beyond removing 13 oxo ODE from the cell to limit its activity 34 Activities editStimulation of peroxisome proliferator activated receptors edit 13 HODE 13 oxoODE and 13 EE HODE along with their 9 HODE counterparts directly activate peroxisome proliferator activated receptor gamma PPARg 37 38 39 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 37 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 40 Stimulation of TRPV1 receptor edit 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 41 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 Stimulation of GPR132 receptor edit 13 S HpODE and 13 S HODE directly activate human but not mouse GPR132 G protein coupled receptor 132 also termed G2A in Chinese hamster ovary cells made to express these receptors they are however far weaker GPR132 activators than 9 S HpODE or 9 S HODE 42 43 GPR132 was initially described as a pH sensing receptor the role s of 13 S HpODE and 13 S HODE as well as 9 S HpODE 9 S HODE and a series or GPR132 activating arachidonic acid hydroxy metabolites i e HETEs in activating G2A under the physiological and pathological conditions in which G2A is implicated see GPR132 for a lists 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 Involvement in mitochondria degradation edit In the maturation of the red blood cell lineage see erythropoiesis from mitochondria bearing reticulocytes to mature mitochondria free erythrocytes in rabbits the mitochondria accumulate phospholipid bound 13 S HODE in their membranes due to the action of a lipoxygenase which in rabbits mice and other sub primate vertebrates directly metabolizes linoleic acid bound phospholipid to 13 S HpODE bound phospholipid which is rapidly reduced to 13 S HODE bound phospholipid 44 It is suggested that the accumulation of phospholipid bound 13 S HpODE and or 13 S HODE is a critical step in rendering mitochondria more permeable thereby triggering their degradation and thence maturation to erythrocytes 44 45 However functional inactivation of the phospholipid attacking lipoxygenase gene in mice does not cause major defects in erythropoiesis 46 It is suggested that mitochondrial degradation proceeds through at least two redundant pathways besides that triggered by lipoxygenase dependent formation of 13 S HpODE and 13 S HODE bound phospholipids viz mitochondrial digestion by autophagy and mitochondrial exocytosis 47 In all events formation of 13 S HODE bound to phospholipid in mitochondrial membranes is one pathway by which they become more permeable and thereby subject to degradation and as consequence of their release of deleterious elements to cause cell injury 48 Stimulation of blood leukocytes edit 13 HODE and 9 HODE are moderately strong stimulators of the directed migration i e chemotaxis of cow and human neutrophils in vitro 49 whereas 13 R HODE and 9 R HODE and 9 S HODE are weak stimulators of the in vitro directed migration of the human cytotoxic and potentially tissue injuring lymphocytes i e natural killer cells 50 These effects may contribute to the pro inflammatory and tissue injuring actions ascribed to 13 HODEs and 9 HODEs Involvement in human diseases editAtherosclerosis edit In atherosclerosis an underlying cause of Coronary artery disease and strokes atheromatous plaques accumulate in the vascular tunica intima thereby narrowing blood vessel size and decreasing blood flow In an animal model and in humans 13 HODE primarily esterified to cholesterol phospholipids and possibly other lipids is a dominant component of these plaques 51 52 53 54 Since these studies found that early into the progression of the plaques 13 HODE consisted primarily of the S stereoisomer while more mature plaques contained equal amounts of S and R stereoisomers it was suggested that 15 LOX 1 contributes to early accumulation while cytochrome and or free radical pathways contributes to the later accumulation of the plaques Further studies suggest that 13 S HODE contributes to plaque formation by activating the transcription factor PPARg 13 R HODE lacks this ability 55 which in turn stimulates the production of two receptors on the surface of macrophages resident in the plaques 1 CD36 a scavenger receptor for oxidized low density lipoproteins native lipoproteins oxidized phospholipids and long chain fatty acids and 2 adipocyte protein 2 aP2 a fatty acid binding protein this may cause macrophages to increase their uptake of these lipids transition to lipid laden foam cells and thereby increase plaque size 56 The 13 S HODE PPARg axis also causes macrophages to self destruct by activating apoptosis inducing pathways this effect may also contribute to increases in plaque size 57 These studies suggest that 13 HODE producing metabolic pathways 56 PPARg 56 57 CD36 58 and aP2 59 may be therapeutic targets for treating atherosclerosis related diseases Indeed Statins which are known to suppress cholesterol synthesis by inhibiting an enzyme in the cholesterol synthesis pathway 3 hydroxy 3 methyl glutaryl CoA reductase HMG CoA reductase are widely used to prevent atherosclerosis and atherosclerosis related diseases Statins also inhibit PPARg in human macrophages vascular endothelial cells and smooth muscle cells this action may contribute to their anti atherogenic effect 60 Asthma edit In guinea pigs 13 S HODE when injected intravenously causes a narrowing of lung airways and when inhaled as an aerosol mimics the asthmatic hypersensitivity to agents that cause bronchoconstriction by increasing airway narrowing responses to methacholine and histamine 61 In a mouse model of allergen induced asthma 13 HODE levels are elevated 62 in the latter mouse model the injection of antibody directed against 13 S HODE reduced many of the pathological and physiological features of asthma 48 mouse forced to overexpress in lung the mouse enzyme 12 15 lipoxygenase that metabolizes linoleic acid to 13 S HODE exhibited elevated levels of this metabolite in lung as well as various pathological and physiological features of asthma 62 and the instillation of 13 S HODE replicated many of these features of asthma 48 In the mouse model of asthma and in the human disease epithelial cells of lung airways show various pathological changes including disruption of their mitochondria 48 62 63 13 S HODE causes similar disruptive changes in the mitochondria of cultured Beas 2B human airway epithelial cells 48 Furthermore humans with asthma exhibit increased levels of 13 HODE in their blood sputum and washings form their lung alveola i e bronchoalveolar lavage fluid of BAL and human eosinophils which are implicated in contributing to human asthma metabolize linoleic acid to 13 HODE and 9 HODE to a far greater extent than any other type of leukocyte 64 The mechanism responsible for 13 HODE s impact on airway epithelial cells may involve its activation of the TRPV1 receptor see previous section on TRPV1 this receptor is highly expressed in mouse and human airway epithelial cells and in Beas 2B human airway epithelial cells and furthermore suppression of TRPV1 expression as well as a TPRV1 receptor inhibitor capsazepan block mouse airway responses to 13 S HODE 48 While much further work is needed these pre clinical studies allow that 13 S HODE made at least in part by eosinophils and operating through TRPV1 may be responsible for the airways damage which occurs in the more severe forms of asthma and that pharmacological inhibitors of TRPV1 may eventually proved to be useful additions to the treatment of asthma Cancer edit Colon cancer edit Familial adenomatous polyposis is a syndrome that includes the propensity to develop colorectal cancer and other cancers due to the inheritance of defective mutations in either the APC adenomatous polyposis coli or MUTYH gene These mutations lead to several abnormalities in the regulation of the growth of colon epithelial cells that ultimately lead to the development of intestinal polyps which have a high risk of turning cancerous 65 One of the abnormalities found in the APC disease is progressive reductions in 15 lipoxygenase 1 along with its product 13 HODE presumed but not unambiguously shown to be the S stereoisomer as the colon disease advances from polyp to malignant stages 15 HETE 5 lipoxygenase 12 lipoxygenase and 15 lipoxygenase 2 and selected metabolites of the latter lipoxygenases show no such association 66 67 68 Similarly selective reductions in 15 lipoxygenase 1 and 13 HODE occur in non hereditary colon cancer 69 70 66 13 S HODE inhibits the proliferation and causes the death apoptosis of cultured human colon cancer cells 55 69 71 70 Animal model studies also find that the 15 lipoxygenase 1 13 HODE axis inhibits the development of drug induced colon cancer as well as the growth of human colon cancer cell explants 67 These results suggest that 15 lipoxygenase 1 and its 13 S HODE product are factors in promoting genetically associated and non associated colon cancers they function by contributing to the suppression of the development and or growth of this cancer and when reduced or absent allow its unrestrained malignant growth Breast cancer edit 13 S HODE stimulates the proliferation of human MCF 7 estrogen receptor positive and MBA MD 231 estrogen receptor negative human breast cancer cell lines see List of breast cancer cell lines in culture 72 its production appears necessary for epidermal growth factor and tumor growth factor a to stimulate cultured BT 20 human breast cancer cells to proliferate 73 and for human breast cancer xenografts to grow in mice 74 and among a series of 10 polyunsaturated fatty acid metabolites quantified in human breast cancer tissue only 13 HODE stereoisomer not defined was significantly elevated in rapidly growing compared to slower growing cancers 72 The results of these studies suggest that 13 S HODE may act to promote the growth of breast cancer in humans Prostate cancer edit 15 LOX 1 is overexpressed in prostate cancerous compared to non cancerous prostate tissue and the levels of its expression in cultured various human prostate cancer cell lines correlates positively with their rates of proliferation and increases the proliferation response of prostate cancer cells to epidermal growth factor and insulin like growth factor 1 its levels in human prostate cancer tissues also correlates positively with the cancers severity as judged by the cancers Gleason score and overexpressed 15 LOX 1 appears to not only increase prostate cancer cell proliferation but also promotes its cell survival by stimulating production and of insulin like growth factor 1 and possibly altering the Bcl 2 pathway of cellular apoptosis as well as increases prostate tumor vascularization and thereby metastasis by stimulating production of vascular endothelial growth factor These 15 LOX 1 effects appear due to the enzyme s production of 13 S HODE 75 76 77 The 15 LOX 1 13 S HODE axis also promotes the growth of prostate cancer in various animal models 78 79 In one animal model the pro growth effects of 15 LOX 1 were altered by dietary targeting increases in dietary linoleic acid an omega 6 fatty acid promoted while increases in dietary stearidonic acid an omega 3 fatty acid reduced the growth of human prostate cancer explants 80 These effects could be due to the ability of the linoleic acid diet to increase the production of the 15 Lox 1 metabolite 13 HODE 80 and the ability of the stearidonic acid to increase the production of docosahexaenoic acid and the 15 LOX 1 metabolites of docosahexaenoic acid 17S hydroperoxy docosa hexa 4Z 7Z 10Z 13 Z 15E 19Z enoate 17 HpDHA 17S hydroxy docosahexa 4Z 7Z 10Z 13Z 15E 19Z enoate 17 HDHA 10S 17S dihydroxy docosahexa 4Z 7Z 11E 13Z 15E 19Z enoate 10 17 diHDHA protectin DX and 7S 17S dihydroxy docsahexa 4Z 8E 10Z 13Z 15E 19Z enoate 7 17 diHDHA protectin D5 all of which are inhibitors of cultured human prostate cancer cell proliferation 81 82 83 Markers for disease edit 13 HODE levels are elevated compared to appropriate controls in the low density lipoproteins isolated from individuals with rheumatoid arthritis 84 in the high density lipoprotein fraction of patients with diabetes 85 in the serum of individuals with polycystic kidney disease 86 or chronic pancreatitis 87 and in the plasma of individuals with alcoholic and non alcoholic steatohepatitis 88 89 The level of total HODEs which includes various 13 HODE and 9 HODE isomers are elevated in the plasma and erythrocytes of patients with Alzheimer s disease and in the plasma but not erythrocytes of patients with vascular dementia compared to normal volunteers 90 See 9 hydroxyoctadecadienoic acid section on 9 HODEs as markers of disease involving oxidative stress for further details 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 21 91 92 19 HODE markers may find usefulness as markers of specific disease type of disease and or progression of disease when combined with other disease markers 19 93 References edit a b Soberman R J Harper T W Betteridge D Lewis R A Austen K F 1985 Characterization and separation of the arachidonic acid 5 lipoxygenase and linoleic acid omega 6 lipoxygenase arachidonic acid 15 lipoxygenase of human polymorphonuclear leukocytes The Journal of Biological Chemistry 260 7 4508 15 doi 10 1016 S0021 9258 18 89293 6 PMID 3920219 a b Wecksler Aaron T Kenyon Victor Deschamps Joshua D Holman Theodore R 2008 Substrate Specificity Changes for Human Reticulocyte and Epithelial 15 Lipoxygenases Reveal Allosteric Product Regulation Biochemistry 47 28 7364 75 doi 10 1021 bi800550n PMC 2603187 PMID 18570379 Reinaud O Delaforge M Boucher J L Rocchiccioli F Mansuy D 1989 Oxidative metabolism of linoleic acid by human leukocytes Biochemical and Biophysical Research Communications 161 2 883 91 doi 10 1016 0006 291X 89 92682 X PMID 2735926 Kuhn Hartmut Barnett Jim Grunberger Dorit Baecker Preston Chow Joan Nguyen Binh Bursztyn Pettegrew Hela Chan Hardy Sigal Elliott 1993 Overexpression purification and characterization of human recombinant 15 lipoxygenase Biochimica et Biophysica Acta BBA Lipids and Lipid Metabolism 1169 1 80 89 doi 10 1016 0005 2760 93 90085 N PMID 8334154 Kuhn Hartmut Walther Matthias Kuban Ralf Jurgen 2002 Mammalian arachidonate 15 lipoxygenases Prostaglandins amp Other Lipid Mediators 68 69 263 290 doi 10 1016 S0090 6980 02 00035 7 PMID 12432923 Burri L Hoem N Banni S Berge K 2012 Marine Omega 3 Phospholipids Metabolism and Biological Activities International Journal of Molecular Sciences 13 11 15401 15419 doi 10 3390 ijms131115401 PMC 3509649 PMID 23203133 Cholesterol at the U S National Library of Medicine Medical Subject Headings MeSH Brash A R Boeglin W E Chang M S 1997 Discovery of a second 15S lipoxygenase in humans Proceedings of the National Academy of Sciences 94 12 6148 52 Bibcode 1997PNAS 94 6148B doi 10 1073 pnas 94 12 6148 PMC 21017 PMID 9177185 Wecksler Aaron T Kenyon Victor Garcia Natalie K Deschamps Joshua D Van Der Donk Wilfred A Holman Theodore R 2009 Kinetic and Structural Investigations of the Allosteric Site in Human Epithelial 15 Lipoxygenase 2 Biochemistry 48 36 8721 30 doi 10 1021 bi9009242 PMC 2746553 PMID 19645454 Laneuville O Breuer D K Xu N Huang Z H Gage D A Watson J T Lagarde M Dewitt D L Smith W L 1995 Fatty acid substrate specificities of human 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