In vitro metabolism of phenylalanine by ruminal bacteria,protozoa, and their mixture

An in vitro study was conducted to examine the metabolism of phenylalanine (Phe) by mixed rumen bacteria (B), mixed rumen protozoa (P), and a combination of the two (BP). Rumen microorganisms were collected from fistulated goats fed lucerne cubes (Medicago sativa) and a concentrated mixture twice a day. Microbial suspensions were anaerobically incubated at 39 degrees C for 12 h. Phe and some other related compounds in both supernatants and microbial hydrolysates of the incubations were analysed by HPLC. The net degradation rate (&mgr;mol/g microbial nitrogen) of Phe in B was about 1.5-fold higher than that in P. Phe was converted mainly into phenylacetic acid (PAA) and unknown compound(s) that presumably involved tyrosine in B, P, and BP during the 12 h incubation period. Small amounts of benzoic acid (BZA), and traces of phenylpropionic acid (PPR) and phenyllactic acid (PLA) were also produced from Phe. PAA production in B was found to be higher than that in P, whereas it was significantly higher in BP. Although BZA production was less than one-tenth that of PAA production, it was higher in P than in B and BP. PPR was detected in both B and BP, but not in P. PLA was detected only in B. The production of unknown compound(s) was higher in B than in P and BP.     

Aromatic amino acid biosynthesis and production of related compounds from p-hydroxyphenylpyruvic acid by rumen bacteria,protozoa and their mixture

Summary. Aromatic amino acid biosynthesis and production of related compounds from p-hydroxyphenylpyruvic acid (HPY) by mixed rumen bacteria (B), protozoa (P), and their mixture (BP) in an in vitro system were quantitatively investigated. Microbial suspensions prepared from mature, fistulated goats fed Lucerne (Medicago sativa) cubes and a concentrate mixture were anaerobically incubated at 39°C for 12 h. Tyrosine (Tyr), phenylalanine (Phe), tryptophan (Trp) and other related compounds in both supernatants and hydrolyzates of all incubations were analyzed by HPLC. Large amounts of Tyr (27.0, 47.0 and 50.8% of disappeared HPY in B, P and BP, respectively) were produced from 1 mM HPY during a 12-h incubation period. The formation of Tyr in P was 1.8 and 1.6 times higher than those in B and BP, respectively. Appreciable amounts of Phe (3–12% of the disappeared HPY) and Trp (2–10% of the disappeared HPY) were also produced from HPY in B, P, and BP. Phe synthesis in B and P was almost similar but Trp synthesis in B was 1.8 times higher than that in P. The biosynthesis of both Phe and Trp from HPY in BP was higher than those in B plus P. A large amount of p-hydroxyphenylacetic acid (about 45% of the disappeared HPY) was produced from HPY in B which was 1.9 times higher than that in P. p-Hydroxybenzoic acid produced from HPY in P was 1.6 times higher than that in B. Considerable amounts of phenylpropionic acid, phenyllactic acid, and phenylpyruvic acid (2–6% of the disappeared HPY) were produced only in B. Received March 21, 2001 Accepted July 4, 2001     

Studies on the production of conjugated linoleic acid from linoleic and vaccenic acids by mixed rumen protozoa

The conversion of β-myrcene to the furanoid flavour compound perillene by Pleurotus ostreatus was investigated using trideutero β-myrcene, trideutero α-(Z)-acaridiol and non-labeled 1,2- and 3,10-epoxy-β-myrcene, α,α-acarilactol, and perillene as substrates. Myrcene diols were formed from the cleavage of myrcene epoxides, but only α-(Z)-acaridiol, a 1,4-butanediol derivative most likely generated through a base-catalysed epoxide opening, was a suitable precursor of perillene. Once formed, this key intermediate was rapidly oxidised and the resulting cyclic lactol was dehydrated to yield perillene. Bioconversion of the supplemented perillene to α,α-acariolide indicated that perillene was another intermediate of the pathway and prone to further oxidative degradation. The data suggest that the fungus converted the cytotoxic β-myrcene in its environment into a metabolically useable carbon source along this route.     

Biohydrogenation of linoleic acid by rumen fungi compared with rumen bacteria

AIMS: To investigate biohydrogenation of linoleic acid by rumen fungi compared with rumen bacteria, and to identify the fungus with the fastest biohydrogenation rate. METHODS AND RESULTS: Biohydrogenation of linoleic acid by mixed rumen fungi and mixed rumen bacteria were compared in vitro. With mixed rumen bacteria, all biohydrogenation reactions were finished within 100 min of incubation and the end product of biohydrogenation was stearic acid. With mixed rumen fungi, biohydrogenation proceeded more slowly over a 24-h period. Conjugated linoleic acid (CLA; cis-9, trans-11 C18 : 2) was an intermediate product, and vaccenic acid (VA; trans-11 C18 : 1) was the end product of biohydrogenation. Fourteen pure fungal isolates were tested for biohydrogenation rate. DNA sequencing showed that the isolate with the fastest rate belonged to the Orpinomyces genus. CONCLUSIONS: It is concluded that rumen fungi have the ability to biohydrogenate linoleic acid, but biohydrogenation is slower in rumen fungi than in rumen bacteria. The end product of fungal biohydrogenation is VA, as for group A rumen bacteria. Orpinomyces is the most active biohydrogenating fungus. SIGNIFICANCE AND IMPACT OF THE STUDY: This is the first study to demonstrate that rumen fungi can biohydrogenate fatty acids. Fungi could influence CLA content of ruminant products.     

Degradation of tryptophan and related indolic compounds by ruminal bacteria,protozoa and their mixture in vitro

Summary.  In vitro experiments were conducted to examine the degradation of d- and l-isomers of tryptophan (Trp) and 10 related indolic compounds by mixed rumen bacteria (B), protozoa (P) and a combination of the two (BP). The analyses were carried out by HPLC. d-Trp (1.0 mM) was not degraded by rumen microorganisms during the 24-h incubation period. The net degradation of 1 mM l-Trp was 46.5%, 8.7% and 80.0% by B, P and BP suspensions, respectively. Trp was degraded into indoleacetic acid, indolelactic acid and indole by rumen bacteria and protozoa, and into skatole, p-cresol and indolepropionic acid by rumen bacteria only. Of them, indoleacetic acid was the major product of Trp found in B (15.4%) and P (3.1%), and skatole in BP (43.2%). This is the first report of the production of indolelactic acid and p-cresol from Trp by rumen microbes. Starch, d-glucose, salinomycin and monensin inhibited the production of skatole and indole from Trp, and skatole from indoleacetic acid by rumen bacteria. Received August 2, 2001 Accepted June 21, 2002 Published online November 14, 2002 Acknowledgements The authors are extremely grateful to Dr. H. Ogawa, Professor, the University of Tokyo and Dr. T. Hasegawa, Associate Professor, Miyazaki University, for inserting a permanent fistula in goats. The present study was financially supported by research grants from Kyowa Hakko Kogyo Co. Ltd. and Daiichi Seiyaku Co., Japan. Nazimuddin Mohammed thanks the Ministry of Education, Science, Sports and Culture of Japan (Monbusho) for the award of a research studentship from 1996. Authors' address: Dr. Nazimuddin Mohammed, Laboratory of Agricultural Production Technology, Faculty of Agriculture, Field Science Center, Tokyo University of Agriculture and Technology, Saiwai-cho 3-5-8, Fuchu-shi, Tokyo 183-8509, Japan     

Effects of salinomycin and vitamin B(6) on the in vitro synthesis of lysine from the stereoisomers of 2,6-diaminopimelic acid by mixed rumen protozoa,bacteria, and their mixture

An in vitro study was conducted to examine the effects of salinomycin (SL) and vitamin B(6) (pyridoxine hydrochloride) (B(6)) on the production of lysine from the three stereoisomers of 2,6-diaminopimelic acid (DAP-SI) by mixed rumen protozoa (P), mixed rumen bacteria (B), and their mixture (PB). P, B, and PB were isolated from the rumen of goats given a concentrate mixture and lucerne cubes, separately incubated for 12 h with and without DAP-SI (5 mM) as a substrate and SL (5 &mgr;g/ml) and/or B(6) (10 &mgr;g/ml) as additives. In P suspensions, SL and B(6) reduced the amount of DAP-SI by 2.1 times (p<0.001, where p is probability) and 19.9% (p<0.05), respectively, and also increased the production of lysine by 2.4 times (p<0.001) and 26.8% (p <0.05), respectively, during 12 h incubation. In B suspensions, the reductions of DAP-SI with a single addition of SL or B(6) were 8.5% (p<0.001) and 2.7%, respectively, and lysine production increased by 54.3 and 32.9% (p<0.001), respectively, during 12 h incubation. In PB suspensions, the reductions of DAP-SI were 21.9 and 11.7% (p<0.001) with a single addition of SL or B(6), respectively, and the production of lysine increased by 81.4 and 39.4% (p<0.001), respectively, during 12 h incubation. When SL and B(6) were added together to the P, B, and PB suspensions, lysine production further increased by 12.3, 21.3, and 12.4% more than the cases of adding SL only during 12 h incubation, respectively. SL and B(6) were demonstrated to enhance the production of lysine from DAP-SI by mixed rumen protozoa, mixed rumen bacteria and their mixture in this study.     

Tryptophan biosynthesis and production of other related compounds from indolepyruvic acid by mixed ruminal bacteria,protozoa, and their mixture in vitro

Tryptophan (Trp) biosynthesis and the production of other related compounds by mixed ruminal bacteria (B), protozoa (P), and their mixture (BP) in an in vitro system were quantitatively investigated by using 1 mM of indole-3-pyruvic acid (IPA) as substrate. Ruminal microorganisms were anaerobically incubated at 39 degrees C for 12 h. Trp and other related compounds in both the supernatants and the microbial hydrolyzates of the incubation were analyzed by HPLC. As a whole, about 334, 440, and 436 &mgr;M of Trp were produced from IPA in 12 h by B, P, and BP suspensions, respectively. In the B suspension, a greater portion of synthesized Trp (242 &mgr;M) from IPA was accumulated as free form in the medium, whereas a large amount of Trp (92 &mgr;M) was incorporated into cell protein in a 12-h incubation. On the other hand, in the P suspension, a large amount of Trp (475 &mgr;M) from IPA was also found as free form in the supernatant in a 12-h incubation. Protozoa did not incorporate Trp into cell protein, but they liberated endogenous Trp (34 &mgr;M) into the medium. The net productions of Trp from IPA were 344.3 and 447.7 &mgr;mol/g of microbial nitrogen in 12 h by B and P suspensions, respectively. The ability of P to synthesize Trp from IPA was about 30% higher than that of B in 12 h. Trp produced from IPA by B, P, and BP suspensions were simultaneously degraded into its related compounds, and among them, indoleacetic acid (IAA) was a major product found in all microbial suspensions. Productions of IAA were 124, 25, and 99 &mgr;M from IPA in 12 h by B, P, and BP suspensions, respectively. The formation of indolelactic acid (ILA) from IPA was observed for the first time in all microbial suspensions, and it was about 84, 24, and 54 &mgr;M in 12 h by B, P, and BP, respectively. Higher IAA and ILA productions were observed in B when compared with P. A small amount of skatole (SKT) (26 &mgr;M) was produced from IPA in B, whereas a sizable amount of SKT (38 &mgr;M) was found in BP after a 12-h incubation. p-Cresol (CRL) was also produced from IPA by both B (43 &mgr;M) and BP (65 &mgr;M) suspensions in 12 h, and this is also the first discovery to show the formation of CRL from IPA by B and BP suspensions. BP suspension was more active to produce both SKT and CRL from IPA, though P suspension has no ability to produce either SKT or CRL from IPA during a 12-h incubation.     

Studies on the possibility of histidine biosynthesis from histidinol, imidazolepyruvic acid, imidazoleacetic acid, and imidazolelactic acid by mixed ruminal bacteria, protozoa, and their mixture in vitro

The possibility of histidine (His) synthesis using a main biosynthetic pathway involving histidinol (HDL) and also the recycling capability of imidazolic compounds such as imidazolepyruvic acid (ImPA), imidazoleacetic acid (ImAA), and imidazolelactic acid (ImLA) to produce His were investigated using mixed ruminal bacteria (B), protozoa (P), and a mixture of both (BP) in an in vitro system. Rumen microorganisms were anaerobically incubated at 39 degrees C for 18 h with or without each substrate (2 mM) mentioned. His and other related compounds produced in both the supernatants and hydrolyzates of the incubation were analyzed by high-performance liquid chromatography. B, P, and BP suspensions failed to show His synthesizing ability when incubated with HDL. His was synthesized from ImPA by B, P, and BP. Expressed in units "per gram of microbial nitrogen (MN)", ImPA disappearance was greatest in B (72.7 micromol/g MN per hour), followed by BP (33.13 micromol/g MN per hour) and then P (18.6 micromol/g MN per hour) for the 18-h incubation period. The production of His from ImPA in B (240.0, 275.9, and 261.2 micromol/g MN in 6, 12, and 18 h incubation, respectively) was about 3.5 times higher than that in P (67.3, 83.8, and 72.7 micromol/g MN in 6, 12, and 18 h incubation, respectively). Other metabolites produced from ImPA were ImLA, ImAA, histamine (HTM), and urocanic acid (URA), found in all microbial suspensions. ImLA as a substrate remained without diminution in all microbial suspensions. Although ImAA was found to be degraded to a small extent (3.4-6.3%) only after 18 h incubation, neither His nor other metabolites were detected on the chromatograms. These results have been demonstrated for the first time in rumen microorganisms and suggest that His may be an essential amino acid for rumen microorganisms.     

Synthesis of phenylalanine and production of other related compounds from phenylpyruvic acid and phenylacetic acid by ruminal bacteria,protozoa, and their mixture in vitro

Phenylalanine (Phe) synthesis and the production of other related compounds by mixed ruminal bacteria (B), protozoa (P), and a combination of the two mixture (BP) in an in vitro system were quantitatively investigated using phenylpyruvic acid (PPY) and phenylacetic acid (PAA) as substrates. Rumen microorganisms were collected from fistulated goats fed lucerne cubes (Medicago sativa) and a concentrated mixture twice a day. Microbial suspensions were anaerobically incubated at 39 degrees C for 12 h. Phe and some other related compounds in both supernatants and microbial hydrolysates of the incubations were analysed by HPLC. A large quantity of Phe was produced from both PPY and PAA not only in B but also in P. In B suspensions, free Phe also accumulated in the medium only when PPY was used as a substrate. The ability of B to synthesize Phe from both PPY and PAA (expressed as unit 'per microbial nitrogen') was 5.1 and 24.8% higher than P, respectively. Phe production from PPY in B and P was 43.5 and 55.2% higher than that from PAA. Large amounts of PAA (17-27%) were produced from PPY in all microbial suspension and production amounts were similar in B and P. Small amounts of benzoic acid (BZA) were produced from PPY and PAA in B, P, and BP, and higher BZA production was observed in P as compared to B. Phenylpropionic acid (PPR) was produced in B from both PPY and PAA, but not in P or BP. A trace amount of phenyllactic acid (PLA) was detected only from PPY in B. Higher concentrations of an unknown compound from PPY and PAA were found to be accumulated in the body protein of B and also in the medium of P, and production of the compound from both PPY and PAA was also higher in B than P.     

Effects of salinomycin and vitamin B(6) on in vitro metabolism of phenylalanine and its related compounds by ruminal bacteria,protozoa and their mixture

An in vitro study was conducted to examine the effects of salinomycin (SL) and vitamin B(6) (B(6)) on the production of phenylalanine (Phe) from phenylpyruvic acid (PPY) and phenylacetic acid (PAA) and of PAA from Phe and PPY by mixed rumen bacteria (B), mixed rumen protozoa (P) and their mixture (BP). Rumen microorganisms were collected from fistulated goats fed lucerne cubes (Medicago sativa) and a concentrate mixture (3 : 1) twice a day. Microbial suspensions were anaerobically incubated at 39 degrees C for 12 h. Phe and some other related compounds in both supernatants and microbial hydrolysates of the incubations were analyzed by HPLC. When PPY was used as a substrate, it completely disappeared without additives and converted mainly to Phe and PAA on the average by 396 and 178, 440 and 189, and 439 and 147 &mgr;M in B, P and BP, respectively, during the 12 h incubation period. The rate of disappearance showed no significant differences between the microbial suspensions with and without SL and B(6) during the incubation period. The production of Phe from PPY with SL was enhanced (p<0.05) by 40, 20 and 19% in B, P and BP, respectively, while PAA production from PPY with SL was inhibited (p<0.05) by 35, 37 and 38% in B, P and BP, respectively, during the 12 h incubation period. On the other hand, with B(6), the production of Phe and PAA from PPY tended to be enhanced by 14 and 17, 9 and 11, and 7 and 22% in B, P and BP, respectively, during the 12 h incubation period. When PAA added as a substrate was incubated in the incubation medium without any additives, it disappeared by 483, 462 and 507 &mgr;M and converted mainly to Phe on the average by 231, 244 and 248 &mgr;M in B, P and BP, respectively. The disappearance of PAA with SL was inhibited (p<0.05) by 16, 15 and 20%, in B, P and BP, respectively, whereas the disappearance of PAA with B6 was almost the same as that without B(6) in B and BP suspensions but tended to be enhanced by more than 9% in P suspensions during the 12 h incubation period. The production of Phe from PAA with SL tended to be inhibited by 12, 11 and 8% in B, P and BP, respectively, during the 6 h incubation period, but the inhibition was weakened during the 12 h incubation period, whereas Phe production from PAA with B(6) tended to be enhanced by 13, 16 and 8% in B, P and BP, respectively. When Phe was added as a substrate, the net Phe disappearance without additives was 549, 365 and 842 &mgr;M and converted mainly to PAA on the average by 254, 205 and 461 &mgr;M in B, P and BP, respectively. The net disappearance of Phe with SL was inhibited (p<0.05) by 38, 28 and 46%, whereas the net disappearance of Phe with B(6) was enhanced (p<0.05) by 9, 8 and 7% in B, P and BP, respectively. The production of PAA from Phe with SL was inhibited (p<0.05) by 73, 54 and 76% in B, P and BP, respectively. On the other hand, with B(6), PAA production from Phe was enhanced (p<0.05) by 19, 18 and 20% in B, P and BP, respectively. Based on these results, it seems that SL inhibited Phe disappearance and enhanced the synthesis of Phe from PPY, though not from PAA, and accumulated free Phe in the medium, whereas B(6) also enhanced Phe synthesis both from PPY and PAA, which could provide additional amino N for animals.     

Glycoside hydrolases of rumen bacteria and protozoa

Sixteen strains of rumen bacteria and 21 protozoal preparations were screened for glycoside hydrolase and phosphatase activity, using 22 nitrophenyl glycoside substrates. The range and level of bacterial enzyme activities were species dependent, although, the glycosidases associated with plant cell wall breakdown were most active in the cellulolytic and hemicellulolytic species. Alkaline phosphatase occurred widely in the organisms examined, but was most active in the twoBacteroides ruminicola strains.A wide range of enzyme activities was also detected in the holotrich and Entodiniomorphid ciliates isolated from the rumen or cultured in vitro. The glycosidases involved in cellulose and hemicellulose breakdown were detected in all of the protozoa examined, and, with the exception ofEntodinium spp., were most active in the Entodiniomorphid protozoa; -l-arabinofuranosidase, an essential hemicellulolytic glycoside hydrolase, was particularly active in this latter group of ciliates.     

Interactions between rumen bacteria and ciliate protozoa in their attachment to barley straw

The attachment of ¹⁴C-choline-labelled mixed rumen protozoa to barley straw in vitro was not significantly affected when bacteria prepared from rumen fluid were added to the incubation mixture. There was similarly little effect on protozoal attachment when the straw had already been colonized by a bacterial population for 24 h. In contrast, it was deduced from measurements of enzyme activities associated with straw that bacterial attachment was reduced if protozoa were present. Bacteria that had colonized the straw for 25 h beforehand were less susceptible to predation by protozoa.     

Metabolism of aflatoxin, ochratoxin, zearalenone, and three trichothecenes by intact rumen fluid, rumen protozoa, and rumen bacteria

The effect of rumen microbes on six mycotoxins (aflatoxin B1, ochratoxin A, zearalenone, T-2 toxin, diacetoxyscirpenol, and deoxynivalenol ) considered to be health risks for domestic animals was investigated. The mycotoxins were incubated with intact rumen fluid or fractions of rumen protozoa and bacteria from sheep and cattle in the presence or absence of milled feed. Rumen fluid had no effect on aflatoxin B1 and deoxynivalenol . The remaining four mycotoxins were all metabolized, and protozoa were more active than bacteria. Metabolism of ochratoxin A, zearalenone, and diacetoxyscirpenol was moderately or slightly inhibited by addition of milled feed in vitro. The capacity of rumen fluid to degrade ochratoxin A decreased after feeding, but this activity was gradually restored by the next feeding time. Ochratoxin A was cleaved to ochratoxin alpha and phenylalanine; zearalenone was reduced to alpha-zearalenol and to a lesser degree to beta-zearalenol; diacetoxyscirpenol and T-2 toxin were deacetylated to monoacetoxyscirpenol and HT-2 toxin, respectively. Feeding of 5 ppm (5 mg/kg) of ochratoxin A to sheep revealed 14 ppb (14 ng/ml) of ochratoxin A and ochratoxin alpha in rumen fluid after 1 h, but neither was detected in the blood. Whether such conversions in the rumen fluid may be considered as a first line of defense against toxic compounds present in the diet is briefly discussed.     

In vitro production of lysine from 2,2'-diaminopimelic acid by rumen protozoa.

Rumen protozoa can produce lysine from free 2,2'-diaminopimelic acid (DAP). However, the quantitative importance of this transformation has been disputed; lysine contents of protozoal incubation supernatants reported by Onodera & Kandatsu and Masson & Ling show a 26-fold difference. The in vitro experimental methods of both groups were compared to determine the causes of this difference. Lysine production was proportional to DAP concentration. Results with rumen protozoa from sheep or goats were similar. The incubation medium and deproteinizing procedure of the Welsh group gave a two-fold increase in lysine production compared with Japanese protocols. Omissions of rice starch from protozoal incubations slightly increased lysine production, whereas omissions of antibacterial agents resulted in varying, yet relatively small changes. The greatest cause of the difference was the number of rumen protozoa incubated. When this factor was taken into account, the difference in the maximum rates of lysine production between the Welsh and Japanese groups was only three-fold, namely 4.5 versus 15.0 nmol lysine/10(5) protozoa/h. Adding other amino acids to the incubations suggested that DAP uptake by rumen protozoa may occur via transport system ASC. The importance of DAP metabolism by protozoa as a source of lysine for ruminant host animals is discussed.     

In vitro metabolism of 2,2'-diaminopimelic acid from gram-positive and gram-negative bacterial cells by ruminal protozoa and bacteria

Bacillus megaterium GW1 and Escherichia coli W7-M5 were specifically radiolabeled with 2,2'-diamino[G-3H]pimelic acid [( 3H]DAP) as models of gram-positive and gram-negative bacteria, respectively. These radiolabeled bacterial mutants were incubated alone (control) and with mixed ruminal bacteria or protozoa, and the metabolic processes, rates, and patterns of radiolabeled products released from them were studied. Control incubations revealed an inherent difference between the two substrates; gram-positive supernatants consistently contained 5% radioactivity, whereas even at 0 h, those from the gram-negative mutant released 22%. Incubations with ruminal microorganisms showed that the two mutants were metabolized differently and that protozoa were the major effectors of their metabolism. Protozoa exhibited differential rates of engulfment (150 B. megaterium GW1 and 4,290 E. coli W7-M5 organisms per protozoan per h), and they extensively degraded [3H]DAP-labeled B. megaterium GW1 at rates up to nine times greater than those of ruminal bacteria. By contrast, [3H]DAP-labeled E. coli W7-M5 degradation by either ruminal bacteria or ruminal protozoa was more limited. These fundamental differences in the metabolism of the two mutants, especially by ruminal protozoa, were reflected in the patterns and rates of radiolabeled metabolites produced; many were rapidly released from [3H]DAP-labeled B. megaterium GW1, whereas few were slowly released from [3H]DAP-labeled E. coli W7-M5. Most radiolabeled products derived from [3H]DAP-labeled B. megaterium GW1 were peptides of bacterial peptidoglycan origin. The ruminal metabolism of DAP-containing gram-positive and gram-negative bacteria, even with the same peptidoglycan chemotype, is thus likely to be profoundly different.(ABSTRACT TRUNCATED AT 250 WORDS)     

Metabolism of aflatoxin, ochratoxin, zearalenone, and three trichothecenes by intact rumen fluid, rumen protozoa, and rumen bacteria.

The effect of rumen microbes on six mycotoxins (aflatoxin B1, ochratoxin A, zearalenone, T-2 toxin, diacetoxyscirpenol, and deoxynivalenol ) considered to be health risks for domestic animals was investigated. The mycotoxins were incubated with intact rumen fluid or fractions of rumen protozoa and bacteria from sheep and cattle in the presence or absence of milled feed. Rumen fluid had no effect on aflatoxin B1 and deoxynivalenol . The remaining four mycotoxins were all metabolized, and protozoa were more active than bacteria. Metabolism of ochratoxin A, zearalenone, and diacetoxyscirpenol was moderately or slightly inhibited by addition of milled feed in vitro. The capacity of rumen fluid to degrade ochratoxin A decreased after feeding, but this activity was gradually restored by the next feeding time. Ochratoxin A was cleaved to ochratoxin alpha and phenylalanine; zearalenone was reduced to alpha-zearalenol and to a lesser degree to beta-zearalenol; diacetoxyscirpenol and T-2 toxin were deacetylated to monoacetoxyscirpenol and HT-2 toxin, respectively. Feeding of 5 ppm (5 mg/kg) of ochratoxin A to sheep revealed 14 ppb (14 ng/ml) of ochratoxin A and ochratoxin alpha in rumen fluid after 1 h, but neither was detected in the blood. Whether such conversions in the rumen fluid may be considered as a first line of defense against toxic compounds present in the diet is briefly discussed.     

Role of the protozoan Isotricha prostoma, liquid-, and solid-associated bacteria in rumen biohydrogenation of linoleic acid

From the simultaneous accumulation of hydrogenation intermediates and the disappearance of Isotricha prostoma after algae supplementation, we suggested a role of this ciliate and/or its associated bacteria in rumen biohydrogenation of unsaturated fatty acids. The experiments described here evaluated the role of I. prostoma and/or its associated endogenous and exogenous bacteria in rumen biohydrogenation of C18:2n-6 and its main intermediates CLA c9t11 and C18:1t11. Fractions of I. prostoma and associated bacteria, obtained by sedimentation of rumen fluid sampled from a monofaunated sheep, were used untreated, treated with antibiotics or sonicated to discriminate between the activity of I. prostoma and its associated bacteria, the protozoan or the bacteria, respectively. Incubations were performed in triplicate during 6 h with unesterified C18:2n-6, CLA c9t11 or C18:1t11 (400 μg/ml) and 0.1 g glucose/cellobiose (1/1, w/w). I. prostoma did not hydrogenate C18:2n-6 or its intermediates whereas bacteria associated with I. prostoma converted a limited amount of C18:2n-6 and CLA c9t11 to trans monoenes. C18:1t11 was not hydrogenated by either I. prostoma or its associated bacteria but was isomerized to C18:1c9. A phylogenetic analysis of clones originating from Butyrivibrio-specific PCR product was performed. This indicated that 71% of the clones from the endogenous and exogenous community clustered in close relationship with Lachnospira pectinoschiza. Additionally, the biohydrogenation activity of solid-associated bacteria (SAB) and liquid-associated bacteria (LAB) was examined and compared with the activity of the non-fractioned I. prostoma monofaunated rumen fluid (LAB + SAB). Both SAB and LAB were involved in rumen biohydrogenation of C18:2n-6. SAB fractions performed the full hydrogenation reaction to C18:0 while C18:1 fatty acids, predominantly C18:1t10 and C18:1t11, accumulated in the LAB fractions. SAB and LAB sequence analyses were mainly related to the genera Butyrivibrio and Pseudobutyrivibrio with 12% of the SAB clones closely related to the C18:0 producing B. proteoclasticus branch. In conclusion, this work suggests that I. prostoma and its associated bacteria play no role in C18:2n-6 biohydrogenation, while LAB convert C18:2n-6 to a wide range of C18:1 fatty acids and SAB produce C18:0, the end product of rumen lipid metabolism.     

The role of holotrichs in the metabolism of dietary linoleic acid in the rumen

The uptake and metabolism of linoleic acid by rumen holotrichs (mainly Isotricha prostoma and I. intestinalis) has been examined in in vitro infusion experiments. Maximum absorption and metabolism of [1-14C]linoleate by 2 . 10(6) Isotricha suspended in 100 ml buffer was obtained using an infusion rate of 1.6 mg linoleate/h. After 90 min, 84% of the added substrate was recovered within the cells, mainly as free fatty acid or phospholipid. There was a rapid incorporation of radioactivity into phospholipid, mainly phosphatidylcholine, at the commencement of linoleate infusion but no further incorporation after about 40 min. The presence of bacteria during incubations, in approximately the same Isotricha/bacteria ratio as found in the rumen, reduced the uptake of linoleate and the accumulation of free fatty acid by holotrichs but the incorporation into phospholipid remained similar to that obtained in the absence of bacteria. Very little biohydrogenation of linoleic acid occurred in incubations with holotrichs alone. Bacterial suspensions converted linoleic acid to mainly trans monoene and a small amount of stearic acid, but in incubations containing both bacteria and holotrichs, both stearic acid and trans monoene were major products. Using the latter mixed culture, about 20% of the added [1-14C]linoleic acid was present in holotrich phospholipid of which 62% remained as octadecadienoic acid. The Isotricha population was 3 . 10(3)--2 . 10(4)/ml rumen fluid and it contributed about 23% of the linoleic acid in the rumen of a cow on a hay diet.     

Inhibition by 1,10-phenanthroline of the breakdown of peptides by rumen bacteria and protozoa

The rate of peptide breakdown in the rumen frequently exceeds the rate at which the amino acids released can be used for microbial growth. The final step in this often wasteful process involves the cleavage of dipeptides. The main rumen bacterial species with high dipeptidase activity, Prevotella ruminicola, Fibrobacter succinogenes, Lachnospira multipara and Megasphaera elsdenii , had activities which were inhibited >95% by 1,10-phenanthroline, a chelator of divalent metal ions and metalloprotease inhibitor. Dipeptidase activity in digesta taken from the rumen of sheep decreased by 33% in the presence of 1,10-phenanthroline, while mixed bacteria from the same samples were inhibited by 80% and the activity of mixed protozoa decreased by only 15%. Thus a substantial amount of dipeptide breakdown appears to be due to ciliate protozoa in the mixed population. Extensive washing of the protozoa increased the sensitivity of protozoal dipeptidase activity to 1,10-phenanthroline, suggesting that protozoa too have a metallo-dipeptidase activity but that it is normally protected from inhibition by 1,10-phenanthroline. Breakdown of the pentapeptide, Ala₅, was also inhibited 27% by 1,10-phenanthroline in the mixed population, and when Trypticase, a pancreatic casein hydrolysate containing a mixture of oligopeptides, dipeptides and amino acids, was incubated with rumen fluid, the production of ammonia and free amino groups was inhibited 71% by 1,10-phenanthroline. It was concluded that metal ion chelation inhibits oligopeptidase and dipeptidase activities of rumen micro-organisms and may be a means of controlling ammonia production from peptides in the rumen.