• 한국가금학회지
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• 제30권4호
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• pp.289-299
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• 2003

본 연구에서는 ${\omega}$-6 및 ${\omega}$-3계 지방산을 함유한 유지의 첨가비율을 달리한 실험사료를 어린 병아리에서 급여했을 때 면연 기관의 지방산조성에 미치는 영향을 조사하였다. 5개의 처리구에 각 처리당 3반복을 두고 총 75수의 1일령 수평아리를 공시하였다. 옥수수유(CO)와 들깨유(PO)를 중량비로 각각 8%+0%, , 6%+2%, 4%+4%, 2%+6%, 0%+8% 수준으로 첨가한 반정제 실험 사료를 7주간 급여하였다. 실험 종료시 증체량 및 사료섭취량은 처리 간에 큰 차이가 보이지 않았으며 체중 100g당 간장 중량 및 면역 기관 중량에서도 유의한 차이가 인정되지 않았다. 면역조직 내 지방산 조성은 EPA와 AA(arachidonic acid)를 포함하여 섭취한 사료 지방산의 조성을 잘 반영하는 경향을 보였는데, 면역기관 간에 그 정도에 차이가 있었다. 들깨유의 첨가수준이 증가함에 따라 linoleie acid LA)의 비율이 점진적으로 감소하였고 반면 a-linolenic acid(LNA) 비율은 현저하게 증가하는 경향이었다. 흉선에는 .LA와 LNA의 함량이 다른 조직보다 현저히 더 많아서 섭취하는 지방산의 조성이 가장 잘 반영되었다. 비장 조직에는 HPA 및 AA 농도와 EPA/LNA, AA/LA의 비율이 다른 조직에 비해 현저히 더 높았는데 이는 비장이 LA나 LNA로부터 AA나 EPA로 전환하는 능력이 높음을 의미한다. 실험사료 급여후 2, 4주후에 조사된 anti-BSA 항체가 유의한 차이는 인정되지 않았으나 CO 8%구에 비해 PO를 첨가한 모든 구에서 더 많이 생성되는 경향이 관찰되었고 특히 PO를 6% 및 8% 첨가한 실험구에서 20~30%나 더 높아졌다. 결론적으로 섭취하는 지방산 조성에 따라 면역기관내 모든 지방산 조성이 변하였으며, 면역기관에 따라 그 반응정도가 달라지는 것이 관찰되었다. 이는 eicosanoids 합성에도 영향을 미칠 수 있기 때문에 가금에서 질병에 대한 면역력 향상이라는 관점에서 앞으로 더 세밀한 연구가 필요하다.

• Journal of Microbiology and Biotechnology
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• 제28권3호
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• pp.349-356
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• 2018

Asterias amurensis is a marine organism that causes damage to the fishing industry worldwide; however, it has been considered a promising source of functional components. The present study aimed to investigate the immune-enhancing effects of fatty acids from three organs of A. amurensis on murine macrophages (RAW 264.7 cells). A. amurensis fatty acids boosted production of immune-associated factors such as nitric oxide (NO) and prostaglandin E2 in RAW 264.7 cells. A. amurensis fatty acids also enhanced the expression of critical immune-associated genes, including iNOS, $TNF-{\alpha}$, $IL-1{\beta}$, and IL-6, as well as COX-2. Western blotting showed that A. amurensis fatty acids stimulated the $NF-{\kappa}B$ and MAPK pathways by phosphorylation of $NF-{\kappa}B$ p-65, p38, ERK1/2, and JNK. A. amurensis fatty acids from different tissues resulted in different levels of $NF-{\kappa}B$ and MAPK phosphorylation in RAW 264.7 cells. The results increase our understanding of how A. amurensis fatty acids boost immunity in a physiological system, as a potential functional material.

• 한국응용과학기술학회지
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• 제16권1호
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• pp.45-57
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• 1999

This study was designed to examine the effect of ${\omega}-3$ fatty acid, linlenic acid, EPA, DHA on serum lipid and cytokines of male rats(Sprague-Dawley). Animals of 3 groups were administrated perilla oil, salmoon oil, and tuna oil of 0.4 $m{\ell}/day$ for 8 weeks respectively. These oils were used for a source of linolenic acid, EPA and DHA. ${\omega}-3$ polyunsaturated fatty acid decreases significantly body weight, serum $PGE_2$ content and serum cytokines content of the rat, and increases internal organs weight, specially liver weight and serum HDL-cholesterol level of the rat. In the results, authors propose to use perilla oil for source of effective ${\omega}-3$ poly-unsaturated fatty acid(linolenic acid) to Prevent cardiovascular and immune diseases.

• Animal Bioscience
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• 제35권10호
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• pp.1461-1478
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• 2022

The maintenance of poultry gut health is complex depending on the intricate balance among diet, the commensal microbiota, and the mucosa, including the gut epithelium and the superimposing mucus layer. Changes in microflora composition and abundance can confer beneficial or detrimental effects on fowl. Antibiotics have devastating impacts on altering the landscape of gut microbiota, which further leads to antibiotic resistance or spread the pathogenic populations. By eliciting the landscape of gut microbiota, strategies should be made to break down the regulatory signals of pathogenic bacteria. The optional strategy of conferring dietary fibers (DFs) can be used to counterbalance the gut microbiota. DFs are the non-starch carbohydrates indigestible by host endogenous enzymes but can be fermented by symbiotic microbiota to produce short-chain fatty acids (SCFAs). This is one of the primary modes through which the gut microbiota interacts and communicate with the host. The majority of SCFAs are produced in the large intestine (particularly in the caecum), where they are taken up by the enterocytes or transported through portal vein circulation into the bloodstream. Recent shreds of evidence have elucidated that SCFAs affect the gut and modulate the tissues and organs either by activating G-protein-coupled receptors or affecting epigenetic modifications in the genome through inducing histone acetylase activities and inhibiting histone deacetylases. Thus, in this way, SCFAs vastly influence poultry health by promoting energy regulation, mucosal integrity, immune homeostasis, and immune maturation. In this review article, we will focus on DFs, which directly interact with gut microbes and lead to the production of SCFAs. Further, we will discuss the current molecular mechanisms of how SCFAs are generated, transported, and modulated the pro-and anti-inflammatory immune responses against pathogens and host physiology and gut health.