Effect of Sunflower and Marine Oils on Ruminal Microbiota, In vitro Fermentation and Digesta Fatty Acid Profile

Effect of Sunflower and Marine Oils on Ruminal Microbiota, In vitro Fermentation and Digesta Fatty Acid Profile

This study using the rumen simulation technique (RUSITEC) investigated the changes in the ruminal microbiota and anaerobic fermentation in response to the addition of different lipid supplements to a ruminant diet. A basal diet with no oil added was the control, and the treatment diets were suppleme...

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Published in:Frontiers in microbiology Vol. 8; p. 1124
Main Authors: Vargas, Julio E, Andrés, Sonia, Snelling, Timothy J, López-Ferreras, Lorena, Yáñez-Ruíz, David R, García-Estrada, Carlos, López, Secundino
Format: Journal Article
Language:English
Published: Switzerland Frontiers Media S.A 20-06-2017
Subjects:
ANALYSIS
CLOSTRIDIUM-PROTEOCLASTICUM
DIETARY
dietary fats
DIVERSITY
FATTENING LAMBS
FISH-OIL
LACTATING DAIRY-COWS
LINOLEIC-ACID
LIPID-METABOLISM
METHANE PRODUCTION
microbial community composition
Microbiology
Microbiology in the medical area
Mikrobiologi inom det medicinska området
qPCR
REAL-TIME PCR
RUMEN BACTERIAL COMMUNITY
rumen microbiota
Rusitec fermenters
TRFLP
microbial community composition
TRFLP
qPCR
dietary fats
Rusitec fermenters
rumen microbiota
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Summary:This study using the rumen simulation technique (RUSITEC) investigated the changes in the ruminal microbiota and anaerobic fermentation in response to the addition of different lipid supplements to a ruminant diet. A basal diet with no oil added was the control, and the treatment diets were supplemented with sunflower oil (2%) only, or sunflower oil (2%) in combination with fish oil (1%) or algae oil (1%). Four fermentation units were used per treatment. RUSITEC fermenters were inoculated with rumen digesta. Substrate degradation, fermentation end-products (volatile fatty acids, lactate, gas, methane, and ammonia), and microbial protein synthesis were determined. Fatty acid profiles and microbial community composition were evaluated in digesta samples. Numbers of representative bacterial species and microbial groups were determined using qPCR. Microbial composition and diversity were based on T-RFLP spectra. The addition of oils had no effect on substrate degradation or microbial protein synthesis. Differences among diets in neutral detergent fiber degradation were not significant ( = 0.132), but the contrast comparing oil-supplemented diets with the control was significant ( = 0.039). Methane production was reduced ( < 0.05) with all oil supplements. Propionate production was increased when diets containing oil were fermented. Compared with the control, the addition of algae oil decreased the percentage C18:3 9 12 15 in rumen digesta, and that of C18:2 9 11 was increased when the control diet was supplemented with any oil. Marine oils decreased the hydrogenation of C18 unsaturated fatty acids. Microbial diversity was not affected by oil supplementation. Cluster analysis showed that diets with additional fish or algae oils formed a group separated from the sunflower oil diet. Supplementation with marine oils decreased the numbers of producers of stearic acid, and affected the numbers of protozoa, methanogens, and , but not total bacteria. In conclusion, there is a potential to manipulate the rumen fermentation and microbiota with the addition of sunflower, fish or algae oils to ruminant diets at appropriate concentrations. Specifically, supplementation of ruminant mixed rations with marine oils will reduce methane production, the acetate to propionate ratio and the fatty acid hydrogenation in the rumen.
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This article was submitted to Systems Microbiology, a section of the journal Frontiers in Microbiology
Edited by: Antonio Faciola, University of Nevada, Reno, United States
Reviewed by: Timothy Hackmann, University of Florida, United States; Gwinyai Chibisa, University of Idaho, United States
ISSN:1664-302X
1664-302X
DOI:10.3389/fmicb.2017.01124