Double lipoxygenation of polyunsaturated fatty acids of nutritional interest.

Double lipoxygenation of polyunsaturated fatty acids having at least three methylene-interrupted double bonds can be made by two lipoxygenases, e.g. 5- and 12-LOX, or 15-LOX only, followed by reduction of the hydroperoxide products through the glutathione peroxidase action. Several biological activities have been reported for such a double 15-LOX product of docosahexaenoic acid, called protectin DX to differentiate it from protectin D1, a stereo and geometric isomer described for its potent anti-inflammatory potential. The geometric characteristic of the double lipoxygenase products is the conjugated triene E,Z,E (trans,cis,trans), which appears crucial in their biological activities. A focus is also done on single lipoxygenation of mono-hydroxylated products first made by aspirin-treated cyclooxygenase-2. The resulting (R,S)-diOH, E,Z,E conjugated trienes, instead of the (S,S)-diOH isomer in case of double lipoxygenation, seem to be even more active for some biological effects, making biologically relevant the single lipoxygenation in aspirin-treated situations.

Functional fluxolipidomics of polyunsaturated fatty acids and oxygenated metabolites in the blood vessel compartment.

Synthesis of bioactive oxygenated metabolites of polyunsaturated fatty acids and their degradation or transformation products are made through multiple enzyme processes. The kinetics of the enzymes responsible for the different steps are known to be quite diverse, although not precisely determined. The location of the metabolites biosynthesis is diverse as well. Also, the biological effects of the primary and secondary products, and their biological life span are often completely different. Consequently, phenotypes of cells in response to these bioactive lipid mediators must then depend on their concentrations at a given time. This demands a fluxolipidomics approach that can be defined as a mediator lipidomics, with all measurements done as a function of time and biological compartments. This review points out what is known, even qualitatively, in the blood vascular compartment for arachidonic acid metabolites and number of other metabolites from polyunsaturated fatty acids of nutritional value. The functional consequences are especially taken into consideration.

Biological properties of a DHA-containing structured phospholipid (AceDoPC) to target the brain.

1-acetyl,2-docosahexaenoyl-glycerophosphocholine (AceDoPC) has been made to prevent docosahexaenoyl (DHA) to move to the sn-1 position as it rapidly does when present in 1-lyso,2-docosahexaenoyl-GPC (lysoPC-DHA), an efficient DHA transporter to the brain. When incubated with human blood, AceDoPC behaves closer to lysoPC-DHA than PC-DHA in terms of binding to plasma albumin and lipoproteins, and DHA incorporation into platelets and red cells. In addition, AceDoPC prevents more efficiently the deleterious effects of the experimental stroke in rats than does unesterified DHA. Also, AceDoPC inhibits platelet-activating factor-induced human blood platelet aggregation. Overall, AceDoPC might act as an efficient DHA transporter to the brain, and as a neuro-protective agent by itself.

Effects of oxidative stress on adiponectin secretion and lactate production in 3T3-L1 adipocytes.

Obesity is an increasing nutritional disorder in developed countries, and oxidative stress has been identified as a key factor in numerous pathologies such as diabetes, inflammation, and atherosclerosis, which are favored by obesity. The objective of the present study was to investigate the effects of oxidative stress in 3T3-L1 adipose cells on two parameters involved in metabolic complications associated with obesity, namely adiponectin secretion and lactate production. Differentiated 3T3-L1 adipose cells were exposed to increasing concentrations of glucose oxidase. 4-Hydroxynonenal (4-HNE), a relevant lipid peroxidation by-product which may affect several metabolic processes in making covalent adducts with various molecules; adiponectin secretion; and lactate production were measured in response to glucose oxidase exposure. Results show an inhibition of adiponectin mRNA expression by glucose oxidase and a significant inverse correlation between 4-HNE formation and adiponectin secretion. Furthermore, 4-HNE alone inhibits adiponectin production by 3T3-L1. On the other hand, glucose oxidase and 4-HNE significantly stimulated lactate production by 3T3-L1 adipocytes. These results demonstrate that adipose cells are highly sensitive to oxidative stress, with subsequent decreased adiponectin secretion and increased lactate production, two events involved in the development of insulin resistance.

Aldehydes from n-6 fatty acid peroxidation. Effects on aminophospholipids.

4-Hydroxy-nonenal (4-HNE) is a major by-product of n-6 fatty acid peroxidation. It has been described to covalently bind biomolecules expressing primary amine, especially the Lys residues in proteins. Low-density lipoproteins (LDL) are well-described macromolecules to be modified by 4-HNE, making them available to scavenger receptors on macrophages. Those macrophages then become foam cells and play an active role in atherogenesis. This paper reports on the covalent binding of 4-HNE to phosphatidylethanolamine (PE), a major aminophospholipid in biological membranes. In contrast, phosphatidylserine (PS) is virtually not modified by 4-HNE. One stable adduct, the Michael adduct PE/4-HNE is a poor substrate of secreted phospholipase A(2) and is not cleaved by phospholipase D. Plasmalogen PE, an important subclass of PE, is covalently modified by 4-HNE as well, but appears to be further degraded on its sn-1 position, the alkenyl chain, which might alter the antioxidant potential of the molecule. An aldehyde homologous to 4-HNE has been characterized as a breakdown product of 12-hydroperoxyeicosatetraenoic acid (12-HpETE) and named 4-hydroxy-2E,6Z-dodecadienal (4-HDDE). This compound as well as 4-HNE was detected in human plasma. Finally, 4-HDDE appears almost 3-fold more active than 4-HNE to make covalent adducts with PE. We conclude that 4-HNE and 4-HDDE are two biologically relevant markers of n-6 fatty acid peroxidation that may alter the phospholipid-dependent cell signaling.

Formation of highly reactive gamma-ketoaldehydes (neuroketals) as products of the neuroprostane pathway.

Neuroprostanes are prostaglandin-like compounds produced by free radical-induced peroxidation of docosahexaenoic acid, which is highly enriched in the brain. We previously described the formation of highly reactive gamma-ketoaldehydes (isoketals) as products of the isoprostane pathway of free radical-induced peroxidation of arachidonic acid. We therefore explored whether isoketal-like compounds (neuroketals) are also formed via the neuroprostane pathway. Utilizing mass spectrometric analyses, neuroketals were found to be formed in abundance in vitro during oxidation of docosahexaenoic acid and were formed in greater abundance than isoketals during co-oxidation of docosahexaenoic and arachidonic acid. Neuroketals were shown to rapidly adduct to lysine, forming lactam and Schiff base adducts. Neuroketal lysyl-lactam protein adducts were detected in nonoxidized rat brain synaptosomes at a level of 0.09 ng/mg of protein, which increased 19-fold following oxidation in vitro. Neuroketal lysyl-lactam protein adducts were also detected in vivo in normal human brain at a level of 9.9 +/- 3.7 ng/g of brain tissue. These studies identify a new class of highly reactive molecules that may participate in the formation of protein adducts and protein-protein cross-links in neurodegenerative diseases and contribute to the injurious effects of other oxidative pathologies in the brain.

The retinitis pigmentosa GTPase regulator (RPGR) interacts with novel transport-like proteins in the outer segments of rod photoreceptors.

Mutations in the retinitis pigmentosa GTPase regulator (RPGR) gene cause X-linked retinitis pigmentosa type 3 (RP3), a severe, progressive and degenerative retinal dystrophy eventually leading to complete blindness. RPGR is ubiquitously expressed, yet mutations in the RPGR gene lead to a retina-restricted phenotype. To date, all RP3 associated missense mutations that have been identified are located in the RCC1-homologous domain (RHD) of RPGR. To investigate the molecular pathogenesis of RP3, we screened retinal yeast two-hybrid libraries with the RHD of RPGR. We identified several alternatively spliced gene products, some with retina-restricted expression, that interact specifically with RPGR in vivo and in vitro. Thus, these proteins were named RPGR-interacting protein 1 (RPGRIP1) isoforms. They contain a C-terminal RPGR-interacting domain and stretches of variable coiled-coil domains homologous to proteins involved in vesicular trafficking. The interaction between RPGR and RPGRIP1 isoforms was impaired in vivo by RP3-associated mutations in RPGR. Moreover, RPGR and RPGRIP1 co-localize in the outer segment of rod photoreceptors, which is in full agreement with the retinitis pigmentosa phenotype observed in RP3 patients. The localization of RPGRIP1 at 14q11 makes it a strong candidate gene for RP16. These results provide a clue for the retina-specific pathogenesis in RP3, and hint towards the involvement of RPGR and RPGRIP1 in mediating vesicular transport-associated processes.