Dietary Fish Oil Substitution Alters the Eicosanoid Profile in Ankle Joints of Mice During Lyme Infection

Overview

Journal J Nutr

Publisher Elsevier

Specialty Nutritional Sciences

Date 2012 Jun 15

PMID 22695969

Citations 7

Authors

Darren S Dumlao

Anna M Cunningham

Laura E Wax

Paul C Norris

Jennifer Hughes Hanks

Rachel Halpin

Kawasi M Lett

Victoria A Blaho

William J Mitchell

Kevin L Fritsche

Edward A Dennis

Charles R Brown

Affiliations

Soon will be listed here.

Abstract

Dietary ingestion of (n-3) PUFA alters the production of eicosanoids and can suppress chronic inflammatory and autoimmune diseases. The extent of changes in eicosanoid production during an infection of mice fed a diet high in (n-3) PUFA, however, has not, to our knowledge, been reported. We fed mice a diet containing either 18% by weight soybean oil (SO) or a mixture with fish oil (FO), FO:SO (4:1 ratio), for 2 wk and then infected them with Borrelia burgdorferi. We used an MS-based lipidomics approach and quantified changes in eicosanoid production during Lyme arthritis development over 21 d. B. burgdorferi infection induced a robust production of prostanoids, mono-hydroxylated metabolites, and epoxide-containing metabolites, with 103 eicosanoids detected of the 139 monitored. In addition to temporal and compositional changes in the eicosanoid profile, dietary FO substitution increased the accumulation of 15-deoxy PGJ(2), an antiinflammatory metabolite derived from arachidonic acid. Chiral analysis of the mono-hydroxylated metabolites revealed they were generated from primarily nonenzymatic mechanisms. Although dietary FO substitution reduced the production of inflammatory (n-6) fatty acid-derived eicosanoids, no change in the host inflammatory response or development of disease was detected.

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