Effects of Medium Chain Fatty Acids on Intestinal Health of Monogastric Animals.

Medium-chain fatty acids (MCFAs) are the main form of Medium Chain Triglycerides (MCTs) utilized by monogastric animals. MCFAs can be directly absorbed and supply rapid energy to promote the renewal and repair of intestinal epithelial cells, maintain the integrity of intestinal mucosal barrier function, and reduce inflammation and stress. In our review, we pay more attention to the role of MCFAs on intestinal microbiota and mucosa immunity to explore MCFA's positive effect. It was found that MCFAs and their esterified forms can decrease pathogens while increasing probiotics. In addition, being recognized via specific receptors, MCFAs are capable of alleviating inflammation to a certain extent by regulating inflammation and immune-related pathways. MCFAs may also have a certain value to relieve intestinal allergy and inflammatory bowel disease (IBD). Unknown mechanism of various MCFA characteristics still causes dilemmas in the application, thus MCFAs are used generally in limited dosages and combined with short-chain organic acids (SOAs) to attain ideal results. We hope that further studies will provide guidance for the practical use of MCFAs in animal feed.

Antibacterial activity of sphingoid bases and fatty acids against Gram-positive and Gram-negative bacteria.

There is growing evidence that the role of lipids in innate immunity is more important than previously realized. How lipids interact with bacteria to achieve a level of protection, however, is still poorly understood. To begin to address the mechanisms of antibacterial activity, we determined MICs and minimum bactericidal concentrations (MBCs) of lipids common to the skin and oral cavity--the sphingoid bases D-sphingosine, phytosphingosine, and dihydrosphingosine and the fatty acids sapienic acid and lauric acid--against four Gram-negative bacteria and seven Gram-positive bacteria. Exact Kruskal-Wallis tests of these values showed differences among lipid treatments (P < 0.0001) for each bacterial species except Serratia marcescens and Pseudomonas aeruginosa. D-sphingosine (MBC range, 0.3 to 19.6 µg/ml), dihydrosphingosine (MBC range, 0.6 to 39.1 µg/ml), and phytosphingosine (MBC range, 3.3 to 62.5 µg/ml) were active against all bacteria except S. marcescens and P. aeruginosa (MBC > 500 µg/ml). Sapienic acid (MBC range, 31.3 to 375.0 µg/ml) was active against Streptococcus sanguinis, Streptococcus mitis, and Fusobacterium nucleatum but not active against Escherichia coli, Staphylococcus aureus, S. marcescens, P. aeruginosa, Corynebacterium bovis, Corynebacterium striatum, and Corynebacterium jeikeium (MBC > 500 µg/ml). Lauric acid (MBC range, 6.8 to 375.0 µg/ml) was active against all bacteria except E. coli, S. marcescens, and P. aeruginosa (MBC > 500 µg/ml). Complete killing was achieved as early as 0.5 h for some lipids but took as long as 24 h for others. Hence, sphingoid bases and fatty acids have different antibacterial activities and may have potential for prophylactic or therapeutic intervention in infection.

Sebum free fatty acids enhance the innate immune defense of human sebocytes by upregulating beta-defensin-2 expression.

Various sebum free fatty acids (FFAs) have shown antibacterial activity against a broad range of gram-positive bacteria, resulting in the suggestion that they are accountable, at least partially, for the direct antimicrobial activity of the skin surface. In this study, we examined the effects of sebum FFAs on the antimicrobial peptide (AMP)-mediated innate immune defense of human sebocytes. Incubation of lauric acid, palmitic acid, or oleic acid (OA) with human sebocytes dramatically enhanced their expression of human beta-defensin (hBD)-2, one of the predominant AMPs found in the skin, whereas remarkable increases in hBD-1, hBD-3, and human cathelicidin LL-37 were not observed. Secreted hBD-2 was detectable by western blotting in the supernatant of sebocyte culture incubated with each FFA, but not with a vehicle control. The supernatant of FFA-incubated sebocyte culture showed antimicrobial activity against Propionibacterium acnes, whereas the enhanced antimicrobial activity of human sebocytes was neutralized by anti-hBD-2 IgG. In addition, the FFA-induced hBD-2 expression was suppressed by blocking the cluster of differentiation (CD)36 fatty acid translocase on the surface of sebocytes with anti-human CD36 IgG or blocking the NF-kappaB signaling pathway with BMS-345541, a highly selective inhibitor of inhibitory kappaB kinase. These data suggest that sebum FFAs upregulate the expression of hBD-2 in human sebocytes, which may enhance the disinfecting activity of the human sebaceous gland. The FFA-induced upregulation of hBD-2 is facilitated by CD36-mediated FFA uptake and NF-kappaB-mediated transactivation. The upregulation of mouse beta-defensin 4, a mouse ortholog for hBD-2, was also observed in the hair follicle sebaceous glands of mouse ear skin after an epicutaneous application of OA, the most hBD-2-inducible FFA tested. This report highlights the potential of using FFAs as a multifunctional antimicrobial therapy agent for acne vulgaris treatment; FFAs may provide direct antibacterial activities against P. acnes and enhance the skin's innate antibacterial defense by inducing the expression of hBD-2 in sebocytes as well.

Suppression of IgE antibody response by the fatty acid-modified antigen.

Ovalbumin (OA) of hens was chemically coupled with fatty acids (lauric acid, myristic acid, palmitic acid and stearic acid). These hydrophobically modified antigens were unable to react with mouse antiserum against native OA and were incapable of eliciting primary and secondary anti-OA antibody responses in BALB/c mice. Preadministration of these modified antigens, especially of palmitoyl OA (OA-pal), suppressed both primary and secondary anti-OA IgE antibody responses without affecting IgG antibody production. Administration of OA-pal after the primary immunization resulted in a rapid decrease of the ongoing anti-OA IgE antibody production and inhibited the anamnestic anti-OA IgE antibody response upon subsequent immunization with OA. The passive transfer of spleen cells from OA-pal-treated animals with OA-primed spleen cells suppressed the adoptive secondary anti-OA IgE antibody response in irradiated recipients. The suppressive effect was abrogated by treatment with an anti-T-cell antiserum indicating that suppressor T cells were primed by administration of hydrophobically modified antigens.

Immunogenic properties of soluble antigens or whole cells of Brucella abortus strain 45/20 associated with immunoadjuvants. I. Soluble antigens.

A purified protein derivative-live preparation of Brucella abortus strain 45/20 was tested for immunogenic properties either alone, after lipid conjugation, or in association with defined adjuvants. The adjuvants were trehalose dimycolate (cord factor), isolated from wax D of mycobacteria and murmyl dipeptide (N-acetyl-muramyl-L-alamyl-D-isoglutamine), a synthetic glycopeptide analog of peptidoglycan subunits found in many bacterial cell walls and wax D of mycobacteria. Guinea pigs were intradermally inoculated with a single injection of the vaccine preparations eight weeks before intramuscular challenge with B. abortus, strain 2308. None of the purified protein derivative-like preparations were as effective in the prevention of splenic infections with B. abortus as were killed whole cells of strain 45/20 in Freund's complete adjuvant. Whole cells in Freund's complete adjuvant were able to reduce mean colony counts by 97% (P = 0.02), while purified protein derivative-like vaccines were able to reduce mean colony counts by only 32 to 61% as compared to control animals. Results suggest that purified protein derivative-like preparations have limited immunogenic properties under present test conditions.

Induction of cell-mediated immunity to chemically modified antigens in guinea pigs. I. Characterization of the immune response to lipid-conjugated protein antigens.

Bovine serum albumin (BSA) conjugated with a lipid, dodecanoic acid, is capable of inducing strong delayed-type hypersensitivity (DTH) in guinea pigs. This paper reports experiments on the nature and specificity of this hypersensitivity. The response to lipid-conjugated BSA (L-BSA) was found to be classical DTH, as evidenced by its ability to be transferred passively by immune cells, but not by serum. In addition, special histologic examination of skin test sites demonstrated the characteristics of DTH rather than cutaneous basophil hypersensitivity. Similar results were obtained when lipid-conjugated purified protein derivative of tubercle bacilli (L-PPD) was used. The increased immunogenicity of L-BSA was not caused by the presence of protein aggregates, but seemed to be related to the hydrophobic nature of the conjugated side chains. A series of cross-reacting serum albumins was used for a study of the specificity of the antibody and DTH responses to BSA. It was found that the degree of enhancement of immunogenicity for DTH caused by lipid conjugation varied for different antigenic determinants on BSA.

Induction of cell-mediated immunity to chemically modified antigens in guinea pigs. II. The interaction between lipid-conjugated antigens, macrophages, and T lymphocytes.

Protein antigens covalently conjugated with lipid groups (dodecanoic acid) have previously been shown to stimulate strong delayed-type hypersensitivity (DTH) without the aid of adjuvants. The present experiments show that lipid-conjugated bovine serum albumin (L-BSA) is taken up in vitro by macrophages (Mpsi) 25- to 50-fold more than unconjugated BSA or aminidated BSA, neither of which induces DTH. Macrophages that take up 125I-labeled L-BSA in vitro stimulate DTH even more efficiently, when injected into syngeneic guinea pigs, than does soluble L-BSA. Tracer studies on the fate of radiolabeled BSA and L-BSA showed that much more L-BSA than BSA was retained by draining lymph nodes. Autoradiography demonstrated that 125I-L-BSA is rapidly taken up by Mpsi in the medullary sinuses of the lymph nodes. Some of this antigen is then transported into the paracortex, a region in which T lymphocytes predominate. The capacity of lipophilic antigens to stimulate cell-mediated immune responses may be caused by their increased uptake by Mpsi, resulting in more efficient presentation to immunocompetent T lymphocytes. The anatomical site of this Mpsi-T cell interaction may be within the sinusoids or paracortex of the draining lymph nodes.