MGYS00000629: An integrated multi-omics approach reveals the effects of supplementing grass or grass hay with vitamin E on the rumen microbiome and its function

An integrated multi-omics approach reveals the effects of supplementing grass or grass hay with vitamin E on the rumen microbiome and its function

Biome, Causing climate change, CC relation type, Host-associated, Mammals, Methane emission reducing diet, Methane production, Mitigating climate change, Related phenomenon

Description
Rumen function is generally sub-optimal leading to losses in the form of methane and nitrogen. Analysis of the rumen microbiome is thus important to understand underlying microbial activity under different feeding strategies. This study investigated the effect of forage conservation method and vitamin E supplementation on rumen function using the rumen simulation technique (Rusitec). Dietary treatments consisted of ryegrass (GRA) or ryegrass hay (HAY) supplemented with 20% concentrate containing zero or 50 IU/d vitamin E, as ?-tocopheryl acetate, according to a 2?2 factorial design. Forage conservation method did not substantially change the nutrient composition but had a profound impact on the structure and diversity of the main rumen microbial communities. HAY diets promoted a more complex bacterial community (+38 OTUs) dominated by Firmicutes. This adaptation, together with increased rumen protozoa levels and greater diversity in the bacterial and methanogen communities, led to greater fibre degradation (+12%) in HAY diets, but also to greater proteolysis (+15%) than observed with GRA diets. Inter-species H transfer between fibrolytic bacteria, protozoa and methanogens was greater in HAY diets, which resulted in higher metabolic H recovery and ultimately higher methane emissions (+35%). On the contrary, GRA diets promoted more simplified methanogen and bacterial communities. This bacterial community was dominated by Bacteroidetes and Lactobacillus, thus lactate formation may have acted as an alternative H sink in GRA diets. Moreover the structure of the bacterial community with GRA diets was highly correlated with N utilization, and GRA diets promoted greater bacterial growth and microbial protein synthesis (+16%), as well as a more efficient microbial protein synthesis (+22%). A dose-response experiment using batch cultures revealed that ?-tocopheryl acetate was more effective than ?-tocopherol in improving rumen fermentation, moreover a high vitamin E dose (500 IU/L) had a negative impact on rumen function. This improvement consisted of a small increase in feed degradability (+8%), possibly as a result of the antioxidant properties of vitamin E which led to higher bacterial and protozoal levels. Moreover, vitamin E supplementation promoted substantial changes in the methanogen community suggesting that some methanogen species are particularly sensitive to oxidative stresses. Our findings suggested that when possible grass should be fed instead of grass hay, in order to improve rumen function and to decrease the environmental impact of livestock agriculture.

Related Publications

Pubmed Record 27375609

Abstract Text
Rumen function is generally suboptimal leading to losses in methane and nitrogen. Analysis of the rumen microbiome is thus important to understanding the underlying microbial activity under different feeding strategies. This study investigated the effect of forage conservation method and vitamin E supplementation on rumen function using a rumen simulation technique. Ryegrass (GRA) or ryegrass hay (HAY) was supplemented with 20% concentrate containing zero or 50 IU/d vitamin E, as Alfa-tocopheryl acetate, according to a 2 x 2 factorial design. The forage conservation method did not substantially change the nutrient composition but had a profound impact on the structure and diversity of the rumen microbiome. HAY diets promoted a more complex bacterial community (+38 OTUs) dominated by Firmicutes. This bacterial adaptation, together with increased rumen protozoa levels and methanogen diversity, was associated with greater fiber disappearance (+12%) in HAY diets, but also with greater rumen true N degradability (+7%) than GRA diets. HAY diets also had a higher metabolic H recovery and methane production (+35%) suggesting more efficient inter-species H transfer between bacteria, protozoa and methanogens. Contrarily, GRA diets promoted more simplified methanogen and bacterial communities, which were dominated by Bacteroidetes and Lactobacillus, thus lactate formation may have acted as an alternative H sink in GRA diets. Moreover the structure of the bacterial community with GRA diets was highly correlated with N utilization, and GRA diets promoted greater bacterial growth and microbial protein synthesis (+16%), as well as a more efficient microbial protein synthesis (+22%). A dose-response experiment using batch cultures revealed that vitamin E supplementation increased rumen fermentation in terms of total VFA and gas production, with protozoal activity higher when supplying Alfa-tocopheryl acetate vs. Alfa-tocopherol. Moreover, Alfa-tocopheryl acetate promoted a small increase in feed degradability (+8%), possibly as a result of its antioxidant properties which led to higher bacterial and protozoal levels. Vitamin E supplementation also modified the levels of some methanogen species indicating that they may be particularly sensitive to oxidative stresses. Our findings suggested that when possible, grass should be fed instead of grass hay, in order to improve rumen function and to decrease the environmental impact of livestock agriculture.