The origin of urinary aromatic compounds excreted by ruminants. 2. The metabolism of phenolic cinnamic acids to benzoic acid.
TLDR
It is concluded that rumen microbial metabolism of dietary phenolic cinnamic acids to 3-phenylpropionic acid followed by its absorption and oxidation in the body tissues is responsible for the greater part of the benzoic and cinnic acids found in ruminant urine.Abstract:
1. The extent to which phenolic derivatives of benzoic acid (seven); of phenylacetic acid (one); of 3-phenylpropionic acid (one) and of cinnamic acid (six) served as precursors of the urinary benzoic acid excreted by sheep was determined after administration as continuous drips via rumen or abomasal cannulas. 2. Phenolic derivatives of benzoic or of phenylacetic acid were not dehydroxylated to yield aromatic acids following administration via either route. 3. Rumen infusion of phenolic derivatives of both 3-phenylpropionic and cinnamic acids gave enhanced rumen concentrations of 3-phenylpropionic acid with negligible amounts of benzoic acid. Between 63 and 106% of the 2-, 3- or 4-hydroxy acids, of the 3,4-dihydroxy acids or of the 3-methoxy, 4-hydroxy acids infused were excreted in the urine as benzoic acid and a variable proportion, characteristic of the individual animal, of up to 20% of the dose as cinnamic acid. 4. Abomasal infusion of monohydroxy 3-phenylpropionic and cinnamic acids did not yield urinary benzoic acid increments. However, between 11 and 34% of abomasally-infused disubstituted phenolic cinnamic acids infused were excreted in the urine as benzoic acid due, it is postulated, to entero-hepatic circulation and microbial metabolism of the infused acids in the large intestine. 5. It is concluded that rumen microbial metabolism of dietary phenolic cinnamic acids to 3-phenylpropionic acid followed by its absorption and oxidation in the body tissues is responsible for the greater part of the benzoic and cinnamic acids found in ruminant urine.read more
Citations
More filters
Journal ArticleDOI
Antinutritional factors in foods for livestock
TL;DR: In this paper, the authors classified the anti-nutritional factors in livestock foods into four groups based on their effects on livestock: (i) affecting protein utilization and depressing digestion (protease inhibitors, tannins, saponins, lectins, etc.), (ii) metal ion scavengers (oxalates, phytates, gossypol pigments, glucosinolates), (iii) antivitamins, and (iv) those which cannot be put in the above categories (mycotoxins, mimosine, cyanogens,
Journal ArticleDOI
Hydroxycinnamic acids in the digestive tract of livestock and humans
Andrew Chesson,Gordon J Provan,Wendy R. Russell,Lorraine Scobbie,Anthony J. Richardson,Colin S. Stewart +5 more
TL;DR: In the rumen, rapid hydrogenation of p-coumaric, ferulic and caffeic acids, followed by dehydroxylation at C4 and more slowly at C3 yields 3-phenylpropionic acid, the major metabolite in rats where relatively little chain-shortening occurs.
Journal ArticleDOI
Changing perceptions of the effect of plant phenolics on nutrient supply in the ruminant
TL;DR: The diverse effects of plant phenolics on nutrient flow probably result from the balance between adverse effects on some organisms and the rate at which they are degraded or inactivated by other organisms, and improved animal performance can likely be obtained by manipulation of rumen microbial metabolism.
Journal ArticleDOI
Anti-inflammatory implications of the microbial transformation of dietary phenolic compounds.
Wendy R. Russell,Lorraine Scobbie,Andrew Chesson,Anthony J. Richardson,Colin S. Stewart,Sylvia H. Duncan,Janice E. Drew,Garry G. Duthie +7 more
TL;DR: The resultant metabolites had differing effects on prostanoid production ranging from a slight increase to a significant reduction in magnitude, suggesting that the microbial transformation of dietary compounds will have important inflammatory implications in the chemoprevention of colon cancer.
Book ChapterDOI
Phenolic Acids in Soils and their Influence on Plant Growth and Soil Microbial Processes
R. D. Hartley,D. C. Whitehead +1 more
TL;DR: Phenolic compounds of low molecular weight, particularly p-hydroxybenzoic, vanillic, p-coumaric and ferulic acids, are of widespread occurrence in soils and occur mainly but not entirely in chemically-bound forms as discussed by the authors.
References
More filters
Book
Human intestinal flora
B. S. Drasar,M. J. Hill +1 more
TL;DR: As one of the part of book categories, human intestinal flora always becomes the most wanted book.
Journal ArticleDOI
Phenolic Acids in Oats, Wheat, Sorghum, and Corn Residues and Their Phytotoxicity1
W. D. Guenzi,T. M. McCalla +1 more
TL;DR: In this article, five phenolic acids, ferulic, p-coumaric, syringic, vanillic, and p-hydroxybenzoic, were quantitatively estimated in corn, wheat, sorghum, and oats residues.
Journal ArticleDOI
p‐Coumaric and ferulic acid components of cell walls of ryegrass and their relationships with lignin and digestibility
TL;DR: In this article, cell walls, isolated from vegetative Italian ryegrass, pre-and post-flowering perennial ry egregrass and the faeces of sheep fed the herb, were treated with alkali and the liberated p-coumaric acid (PCA), ferulic acid (FA) and vanillin estimated.
Related Papers (5)
Syntrophococcus sucromutans sp.nov.gen.nov. uses carbohydrates as electron donors and formate, methoxymonobenzenoids or Methanobrevibacter as electron acceptor systems
Lee R. Krumholz,Marvin P. Bryant +1 more