Eicosapentaenoic acid


Eicosapentaenoic acid is an omega−3 fatty acid. In physiological literature, it is given the name 20:5. It also has the trivial name timnodonic acid. In chemical structure, EPA is a carboxylic acid with a 20-carbon chain and five cis double bonds; the first double bond is located at the third carbon from the omega end.
EPA is a polyunsaturated fatty acid that acts as a precursor for prostaglandin-3, thromboxane-3, and leukotriene-5 eicosanoids. EPA is both a precursor and the hydrolytic breakdown product of eicosapentaenoyl ethanolamide. Although studies of fish oil supplements, which contain both docosahexaenoic acid and EPA, have failed to support claims of preventing heart attacks or strokes, a recent multi-year study of Vascepa, a prescription drug containing only EPA, was shown to reduce heart attack, stroke, and cardiovascular death by 25% relative to a placebo in those with statin-resistant hypertriglyceridemia.

Forms

Commercially available dietary supplements are most often derived from fish oil and are typically delivered in the triglyceride, ethyl ester, or phospholipid form of EPA. There is debate among supplement manufacturers about the relative advantages and disadvantages of the different forms. One form found naturally in algae, the polar lipid form, has been shown to have improved bioavailability over the ethyl ester or triglyceride form. Similarly, DHA or EPA in the lysophosphatidylcholine form was found to be more efficient than triglyceride and phosphatidylcholines in a 2020 study.
BaseEPA
Ethyl esterEPA ethyl ester
Lysophosphatidylcholine LPC-EPA, or lysoPC-EPA
Phosphatidylcholine EPA-PC
Phospholipid EPA-PL
Triglyceride or triacylglycerol EPA-TG, or EPA-TAG
Re-esterified triglyceride, or re-esterified triacylglycerol EPA rTG, or r-TAG

Biosynthesis

Aerobic eukaryote pathway

Aerobic eukaryotes, specifically microalgae, mosses, fungi, and most animals, perform biosynthesis of EPA usually as a series of desaturation and elongation reactions, catalyzed by the sequential action of desaturase and elongase enzymes. This pathway, originally identified in Thraustochytrium, applies to these groups:
  1. a desaturation at the sixth carbon of alpha-linolenic acid by a Δ6 desaturase to produce stearidonic acid,
  2. elongation of the stearidonic acid by a Δ6 elongase to produce eicosatetraenoic acid,
  3. desaturation at the fifth carbon of eicosatetraenoic acid by a Δ5 desaturase to produce eicosapentaenoic acid,

    Polyketide synthase pathway

Marine bacteria and the microalgae Schizochytrium use an anerobic polyketide synthase pathway to synthesize DHA. The PKS pathway includes six enzymes namely, 3-ketoacyl synthase, 2 ketoacyl-ACP-reductase, dehydrase, enoyl reductase, dehydratase/2-trans 3-cos isomerase, dehydratase/2-trans, and 2-cis isomerase. The biosynthesis of EPA varies in marine species, but most of the marine species' ability to convert C18 PUFA to LC-PUFA is dependent on the fatty acyl desaturase and elongase enzymes. The molecule basis of the enzymes will dictate where the double bond is formed on the resulting molecule.
The proposed polyketide synthesis pathway of EPA in Shewanella is a repetitive reaction of reduction, dehydration, and condensation that uses acetyl-CoA and malonyl-CoA as building blocks. The mechanism of α-linolenic acid to EPA involves the condensation of malonyl-CoA to the pre-existing α-linolenic acid by KS. The resulting structure is converted by NADPH dependent reductase, KR, to form an intermediate that is dehydrated by the DH enzyme. The final step is the NADPH-dependent reduction of a double bond in trans-2-enoyl-ACP via ER enzyme activity. The process is repeated to form EPA.

Clinical significance

The US National Institute of Health's MedlinePlus lists medical conditions for which EPA is known or thought to be an effective treatment. Most of these involve its ability to lower inflammation.
Intake of large doses of long-chain omega−3 fatty acids as prescription drugs or dietary supplements are generally required to achieve significant lowering of triglycerides, and at those doses the effects can be significant.
Dietary supplements containing EPA and DHA lower triglycerides in a dose dependent manner; however, DHA appears to raise low-density lipoprotein and LDL-C values, while EPA does not. This effect has been seen in several meta-analyses that combined hundreds of individual clinical trials in which both EPA and DHA were part of a high dose omega−3 supplement, but it is when EPA and DHA are given separately that the difference can be seen clearly.
Ordinary consumers commonly obtain EPA and DHA from foods such as fatty fish, fish oil dietary supplements, and less commonly from algae oil supplements in which the omega−3 doses are lower than those in clinical experiments.
Omega−3 fatty acids, particularly EPA, have been studied for their effect on autistic spectrum disorder. Some have theorized that, since omega−3 fatty acid levels may be low in children with autism, supplementation might lead to an improvement in symptoms. Well-controlled studies have shown no statistically significant improvement in symptoms as a result of high-dose omega−3 supplementation.
In addition, studies have shown that omega−3 fatty acids may be useful for treating depression.
EPA and DHA ethyl esters may be absorbed less well, thus work less well, when taken on an empty stomach or with a low-fat meal.