Hostname: page-component-77c89778f8-9q27g Total loading time: 0 Render date: 2024-07-22T03:27:26.095Z Has data issue: false hasContentIssue false
  • English
  • Français

The effect of absence of protozoa on rumen biohydrogenation and the fatty acid composition of lamb muscle

Published online by Cambridge University Press:  01 May 2007

David R. Yáñez-Ruiz ,
Selwyn Williams  and
Charles J. Newbold
David R. Yáñez-Ruiz*
Affiliation:
Institute of Rural Sciences, University of Wales Aberystwyth, Llanbadarn Campus, Aberystwyth, SY23 3AL, UK
Selwyn Williams
Affiliation:
Institute of Rural Sciences, University of Wales Aberystwyth, Llanbadarn Campus, Aberystwyth, SY23 3AL, UK
Charles J. Newbold*
Affiliation:
Institute of Rural Sciences, University of Wales Aberystwyth, Llanbadarn Campus, Aberystwyth, SY23 3AL, UK
*
*Corresponding author: Professor C. J. Newbold, fax +44 1970 611264, email cjn@aber.ac.uk
Rights & Permissions [Opens in a new window]

Abstract

The effects of the absence of protozoa in the rumen of lambs on animal growth, rumen fermentation, microbial diversity and fatty acid profiles in abomasal fluid and intramuscular fat were measured in ten control and ten protozoa-free (PF) lambs. PF lambs were prepared by isolating them from ewes within the first 24 h after birth. The PF and control lambs were kept for 4 months in two different fields and received a daily supplement of 250 g concentrate. The bacterial populations visualised by denaturing gradient gel electrophoresis differed between the two groups of animals and showed a higher bacterial diversity in control lambs than in PF lambs. Abomasal contents from control lambs contained higher concentrations of 22 : 5n-3 and 22 : 6n-3 and lower concentrations of vaccenic acid (trans-11–18 : 1) and 20 : 3n-6 than PF lambs. The rest of the fatty acids, including the conjugated linoleic acid (CLA) isomers, were present at the same concentrations in abomasal contents from both experimental groups. Fatty acid composition in intramuscular fat showed differences between the groups. PF lambs had higher proportions of 18 : 0, 18 : 3, trans-10, cis-12-CLA and total SFA than control lambs. Control lambs had higher proportions of cis-9–18 : 1, cis-9, cis-12–18 : 2, 20 : 3n-6, 22 : 6n-3 (DHA) and MUFA. In conclusion, rumen defaunation led to higher tissue levels of the trans-10, cis-12-CLA isomer and SFA and lower PUFA:SFA ratio and n-3 PUFA in lamb muscle.

Keywords

Conjugated linoleic acidProtozoaRumen biohydrogenationFatty acids
Type
Full Papers
Information
British Journal of Nutrition , Volume 97 , Issue 5 , May 2007 , pp. 938 - 948
Copyright
Copyright © The Authors 2007

Conjugated linoleic acid (CLA) is a collective term used to describe positional and geometric isomers of linoleic acid (cis-9, cis-12-18 : 2). Food products derived from ruminant animals are the major source of CLA in human diets. The main form of CLA, cis-9, trans-11–18 : 2 (c9, t11-CLA), can be produced directly by microbial hydrogenation in the rumen or by the enzyme stearoyl-CoA desaturase in the animal's tissues using vaccenic acid (VA; trans-11-18 : 1), formed in the rumen, as its substrate (Bauman et al. Reference Bauman, Baumgard, Corl and Griinari1999). Another important CLA isomer, trans-10, cis-12-18 : 2 (t10, c12-CLA) is also formed in the rumen. Some isomers of CLA have been associated with inhibition of some types of cancer (De la Torre et al. Reference De la Torre, Debiton, Durand, Chardigny, Berdeaux, Loreau, Barthomeuf, Bauchart and Gruffat2005), reductions in atherosclerosis (Toomey et al. Reference Toomey, Harhen, Roche, Fitzgerald and Belton2005), enhancement of the immune response (Zhang et al. Reference Zhang, Guo and Yuan2005) and body fat repartitioning (Blankson et al. Reference Blankson, Stakkestad, Fagertun, Thom, Wadstein and Gudmundsen2000). However, some experiments on laboratory animals appear to suggest that the t10, c12 isomer may have detrimental effects on health (Wahle et al. Reference Wahle, Heys and Rotondo2004).

Recently, it has been shown that the rumen protozoa have a higher content of CLA and VA than the rumen bacteria, suggesting that protozoa may make a significant contribution to VA and CLA flow from the rumen (Devillard et al. Reference Devillard, McIntosh, Newbold and Wallace2006). By using real-time PCR to quantify protozoal 18s rDNA genes we have observed that protozoal cells contain a significant proportion (40 %) of the CLA and VA reaching the duodenum of animals (Yáñez-Ruiz et al. Reference Yáñez-Ruiz, Scollan, Merry and Newbold2006). Studies on the effect of defaunation on lipid metabolism in the rumen are contradictory and not conclusive. In an early study Dawson & Kemp (Reference Dawson and Kemp1969) reported that biohydrogenation in ruminal digesta was only slightly decreased following the removal of protozoa from the rumen (defaunation) and the presence of protozoa was not necessary for biohydrogenation to occur. Klopfenstein et al. (Reference Klopfenstein, Purser and Tyznik1966) reported a decrease in 18 : 1 in blood in the absence of protozoa, which is not consistent with protozoa being a major source of 18 : 1 supply to the small intestine. More recently, Jouany & Lassalas (Reference Jouany and Lassalas2003) observed that CLA formation actually increased when protozoa were removed. However, no attempts have been made to look at the effect of the absence of protozoa on the CLA content of the ruminant product (milk or meat).

The present experiment was carried out to determine the effect of the absence of protozoa in the rumen of lambs on ruminal biohydrogenation, rumen microbial ecology and the fatty acid composition of lamb muscle.

Material and methods

Experimental design and animal management

Twenty crossbred lambs were used. Ten were taken from the ewes within the first 24 h of life and kept isolated from adult animals (protozoa-free (PF) group) and fed commercial milk replacer (Volac® Instant; Volac International Ltd, Royston, Herts, UK) while the other ten were left with the ewes (control group). Both groups were provided grass hay ad libitum and commercial concentrate supplemented with retinol (30 000 μg/kg), cholecalciferol (62·5 μg/kg), vitamin E (25 mg/kg) and Se (500 μg/kg) (Wynnstay LambMaster; Wynnstay plc, Llansantffraid, Powys, UK) and were weaned at 6 weeks. On week 7, animals in both groups were each given orally 7·5 ml of a mineral (14 g Ca/kg, 4·5 g P/kg, 150 mg Zn/kg, 108 mg Fe/kg, 50 mg Mn/kg, 2 mg Co/kg, 6·5 mg I/kg, 0·182 mg Se/kg) and vitamin (1800 retinol μg/kg, 30 μg/kg cholecalciferol/kg, 13·4 μg alphatocopherol/kg) supplement (Liquithrive; Agri Lloyd International Ltd, Leominster, Herefordshire, UK) and 1 mg diclazuril/kg body weight (Vecoxan®; Janssen Animal Health, Saunderton, Bucks, UK) as an anticoccidial treatment. This last treatment was then repeated at 4-week intervals three more times. Once weaned, at 6 weeks of age, the lambs grazed on two different pastures (predominantly perennial ryegrass) supplemented with a lamb commercial concentrate supplement (Wynnstay LambMaster; 250 g/head per d) for 4 months before slaughter. The main ingredients in the commercial concentrate were wheat, barley, sunflower, molasses, sugarbeet pulp, soya and mineral–vitamin mix. The fields were 7300 m2 and 4800 m2 for the control and PF groups, respectively. PF pasture had not been used by any ruminant in the 6 months before the experiment, ensuring no contamination by rumen protozoa. Animals were weighed every week to monitor weight gain. Electric fences were used to prevent grazing in an area of approximately 51 m2 in each experimental field in order to estimate daily grass intake (Stockdale & King, Reference Stockdale and King1983).

Sample collection

Samples of grass and concentrate were collected every week, pooled and frozen at − 20°C for chemical (ten subsamples) and fatty acid (five subsamples) analysis.

On week 11 of the grazing period an area of wool (50 mm × 50 mm) was clipped from the left hindquarters of each lamb. After 7 weeks the wool grown within these patches was clipped and packaged into paper bags. The wool and the bags were oven-dried overnight at 60°C and the dry weight of the wool produced was then calculated.

The daily herbage intake was calculated using the difference between the grass growth in the isolated area compared with that in the grazed field over a 9-week period. Grass growth was measured in the grazed and fenced areas after the 9-week period using random sampling with a 1 m2 quadrat, which was thrown randomly ten times in the restricted area and thirty times in the grazed area. Quadrats were cut to ground level, dried at 100°C for 24 h, for the conversion to DM mass.

On the day of slaughter animals were transported 30 miles to a commercial slaughter facility (Hamer International Ltd, Llanidloes, Powys, UK) then weighed and slaughtered within 2 h. Animals were fasted overnight before slaughter. At slaughter samples from the rumen, abomasum and tail muscle (sacrocaudalis ventralis lateralis) were collected, kept in ice, pH of rumen content measured and samples frozen at − 20°C within 1 h. After slaughter, cold carcass weight was recorded. In order to have enough intramuscular fat to extract and accurately detect the different fatty acids by GC, muscle and abomasal samples (5 g) were pooled from pairs of animals. Thus five samples per group were analysed and not ten.

Samples of rumen fluid from defaunated lambs were examined by light microscopy (40 × ) to confirm the absence of protozoa.

Chemical and molecular analysis

Ash and, by mass difference, organic matter in samples of herbage and concentrate were analysed by combusting the ground samples at 550°C for 6 h in a muffle furnace. Total N was determined by a micro-Kjeldahl technique using ‘kjeltec’ equipment (Foss UK Ltd, Warrington, Cheshire, UK). Neutral-detergent fibre and acid-detergent fibre analysis was performed by the sequential procedure of van Soest & Mason (Reference van Soest and Mason1991), using the Ankom200/220 fibre analyser (Ankom, 2000). Neutral-detergent fibre was assayed with sodium sulfite and without α-amylase. Neutral-detergent fibre and acid-detergent fibre were expressed without residual ash.

The fatty acids in the grasses and concentrate were measured using the one-step extraction–transesterification procedure described by Sukhija & Palmquist (Reference Sukhija and Palmquist1988). Abomasal fatty acids were obtained by direct hydrolysis at 60°C, with added internal standard (100 μl methyl ester C21, 15 mg/ml CHCl3), in 5 m-KOH in aqueous methanol. Potassium carboxylates were converted into fatty acids by the addition of 10 ml 0·5 m-H2SO4 and methylated using 5 % (w/w) HCl in methanol at 50°C (Kramer & Zhou, Reference Kramer and Zhou2001). Total intramuscular muscle lipids were extracted as described by Folch et al. (Reference Folch, Lees and Sloane Stanley1957) and saponified and methylated as described for abomasal fatty acids.

After saponification and methylation, methyl esters of fatty acids were recovered in 5 ml hexane and quantified by GC on a CP-Select chemically bonded for FAME column (100 m × 0·25 mm internal diameter; Varian Inc., Palo Alto, CA, USA) with ultra-high-purity He carrier gas at a flow rate of 7 ml/min. Injector and detector temperatures were 250 and 255°C, respectively. The splitting ratio to the flame ionisation detector was 1:80. The oven temperature schedule for abomasal samples was: 70°C for 1 min; increase to 100°C at 5°C/min; constant 100°C for 2 min; increase to 175°C at 10°C/min; constant 175°C for 34 min; increase to 225°C at 4°C/min; constant 225°C for 22 min. The total run time was 85 min. The oven temperature schedule for muscle samples was: 100°C for 0 min; increase to 175°C at 20°C/min; constant 175°C for 25 min; increase to 204°C at 2°C/min; increase to 230°C at 10°C/min and hold for 2 min; increase to 240°C at 20°C/min and hold for 8 min. The total run time was 60 min. Individual fatty acids were quantified by reference to the internal standard and using external standards: c9, t11-18 : 2; t10, c12–18 : 2; trans-11–18 : 1 (Matreya, Pleasant Gap, PA, USA) and standard mixture of 37 FAME (Supelco, Poole, Dorset, UK). Data from abomasum and muscle samples were calculated as normalised area percentages of fatty acids.

Volatile fatty acids in rumen liquor were determined by HPLC (Rooke et al. Reference Rooke, Alison and Borman Armstrong1990). Ammonia-N concentration was determined by a colorimetric method (Weatherburn, Reference Weatherburn1967).

Molecular analysis on rumen samples

DNA was extracted from frozen rumen samples using a QIAamp® DNA Stool Mini Kit (Qiagen Ltd, Crawley, West Sussex, UK) following the manufacturer's instructions.

Denaturing gradient gel electrophoresis (DGGE) was used to compare bacterial diversity between rumen samples for each experimental animal. Approximately 200 bp of the 16S rDNA gene were amplified using the primers: forward 5′-CCGCCGCGCGCGGCGGGCGGGGCGGGGGCACGGGGGGCTACGGGAGGCAGCAG-3′; reverse 5′-ATTACCGCGGCTGCTGG-3′ (Nubel et al. Reference Nubel, Engelen, Felske, Snaidr, Wieshuber, Amann, Ludwing and Backhaus1996). Use of a GC-clamp has been shown to help obtain a better profile on the denaturing gel (Muyzer et al. Reference Muyzer, de Waal and Uitterlinden1993). PCR was performed using the following steps: one cycle (94°C for 4 min); twenty-five cycles (94°C for 1 min, 55°C for 1 min, 72°C for 1 min); one cycle (94°C for 1 min, 55°C for 1 min, 72°C for 10 min). The size of amplicon was confirmed by electrophoresis on a 2·5 % agarose gel, visualised after staining with ethidium bromide.

DGGE was performed in a C.B.S. Scientific® system (C.B.S. Scientific, Inc., Del Mar, CA, USA). Gels contained 40–60 % denaturant gradient in 8 % acrylamide gels and were run at 130 V, 200 mA and 250 W for 16 h at 60°C. DNA was visualised by silver staining with DNA Silver Staining Kit (Amersham Biosciences, Uppsala, Sweden). Gels were scanned using a GS-800 Calibrated Imaging Densitometer (BioRad, Hercules, CA, USA). Scanned DGGE images were analysed with Quantity One® Software (BioRad) by scoring for the presence or absence of bands at different positions in each lane. DGGE banding profiles were compared by using similarity trees. Each band position present in the gel was binary coded for its presence or absence within a lane and each lane was compared by using a similarity matrix (Regensbogenova et al. Reference Regensbogenova, Pristas, Javorsky Hackstein, Newbold and McEwan2004). Trees were constructed by using the NEIGHBOUR program (PHYLIP version 3·6; Felsenstein, Reference Felsenstein2002).

Protozoal rDNA concentration was determined using the real-time PCR assay developed by Sylvester et al. (Reference Sylvester, Karnati, Yu, Morrrison and Firkins2004, Reference Sylvester, Karnati, Yu, Newbold and Firkins2005), using the ciliate-specific primers: forward -5′-GCTTTCGWTGGTAGTGTATT-3′-; reverse -5′-CTTGCCCTCYAATCGTWCT-3′-. A no-template (sterile distilled water) negative control was loaded on each plate run to screen for possible contamination and dimer formation and to set the background fluorescence for plate normalisation. The extracted DNA from washed protozoal solutions from all ruminal samples (Williams & Coleman, Reference Williams and Coleman1992), after DNA quantification, was diluted to generate the necessary standard curves. Real-time PCR was performed using a DNA Engine Opticon® System, PTC-200 DNA Engine™ Cycler (MJ Research, Braintree, Essex, UK). DNA extract (1 μl) was added to amplification reactions (50 μl) containing 50 pmol of each primer, 25 μl of SYBR® Green JumpStart™ Taq ReadyMix™ (Sigma, Poole, Dorset, UK) containing 20 mm-tri(hydroxymethyl)-aminomethane-HCl (pH 8·3), 100 mm-KCl, 7 mm-MgCl2, 0·4 mm each dNTP, stabilisers, Taq DNA polymerase (0·05 unit/μl), JumpStart Taq, antibody and SYBR Green I. Cycling conditions were 94°C for 4 min; forty-five cycles of 94°C for 30 s, 54°C for 30 s, 72°C for 1 min; and a final extension of 72°C for 6 min. Fluorescence readings were taken after each extension step, and a final melting analysis was obtained by slow heating with 0·1°C/s increment from 65 to 95°C, with fluorescence collection at 0·1°C intervals. The threshold cycle (i.e. the amplification cycle in which product formation exceeds background fluorescence) of each standard dilution was determined during the exponential phase of amplification and regressed against the logarithm (base 10) of known protozoal DNA standard. All post-run data analyses were performed using MJ Research Opticon Monitor Software (version 1·06; Waltham, MA, USA).

Total bacterial rDNA concentration in rumen samples was measured by real-time PCR using the primers designed by Maeda et al. (Reference Maeda, Fujimoto, Haruki, Maeda, Kokeguchi, Petelin, Arai, Tanimoto, Nishimura and Takashiba2003) to target the conserved region on the 16S rDNA: forward 5′-GTGSTGCAYGGYTGTCGTCA-3′, reverse 5′-ACGTCRTCCMCACCTTCCTC-3′. DNA extract (1 μl) was added to amplification reactions (50 μl), containing 20 pmol of each primer, 25 μl of SYBR® Green JumpStart™ Taq ReadyMix™ (Sigma) containing 20 mm-tri(hydroxymethyl)-aminomethane-HCl (pH 8·3), 100 mm-KCl, 7 mm-MgCl2, 0·4 mm each dNTP, stabilisers, Taq DNA polymerase (0·05 unit/μl), JumpStart Taq, antibody and SYBR Green I. Cycling conditions were 95°C for 5 min, forty cycles of 95°C for 15 s, 61°C for 1 min and 72°C for 30 s. Fluorescence readings, melting analysis and standard analyses were performed as described earlier for the protozoal assay. A bacterial rDNA standard curve was generated from DNA extracted from a mix (equal volumes) of 24 h cultures of the following rumen bacterial strains all grown on Hobson's medium 2 (Stewart et al. Reference Stewart, Flint, Bryant, Hobson and Stewart1997): Prevotella ruminicola 23, Butyrivibrio fibrisolvens SH13, Ruminococcus albus SY3, Prevotella albensis M384, Clostridium sticklandii 12 662, Peptostreptococcus anaerobius 27 337, R. flavefaciens Fd1, Mitsuokella multiacidus 46/5, Selenomonas ruminantium 2388, Lachnospira multipara D15d, Veillonela parvula L59, Prevotella bryantii B14, Prevotella brevis GA33, Lactobacillus casei LB17, C. aminophilum 49 906, Streptococcus bovis ES1 and Megasphera elsdenii J1, all obtained from the Rowett Research Institute's (Aberdeen, UK) culture collection. The DNA concentration of the bacterial standard was determined by fluorescence following the bisbenzimide–DNA assay described by Labarca & Paigen (Reference Labarca and Paigen1980).

Calculations and statistical analysis

Species richness on DGGE gels was calculated as the mean numbers of bands present. The Shannon's diversity index (proportional abundance of species in a community) was determined according to Marrugan (Reference Marrugan1988): H' = − SUM (pi × * ln(pi)), where the proportion of single bands (i) relative to the total number of bands (pi) is calculated, and then multiplied by the natural logarithm of this proportion (lnpi). The resulting product is summed across species and multiplied by − 1.

Data were subjected to ANOVA (Genstat 7; Lawes Agricultural Trust, Rothamsted Experimental Station, Harpenden, Herts, UK) with absence of protozoa as the sole treatment effect.

Results

The rumen of PF lambs remained free of protozoa during the experiment as neither protozoa nor protozoal DNA was found in their rumen at slaughter.

Diet composition

The chemical composition of the grasses and concentrate are presented in Table 1. The composition of the two grasses (field control and field PF) was very similar, although the control grass contained more DM and contained a relatively higher amount of organic matter and structural carbohydrates (acid-detergent fibre and neutral-detergent fibre). Fatty acid analysis revealed very similar profiles between both grasses with a high content of linolenic and palmitic acids whereas the experimental concentrate contained high levels of palmitic, stearic and oleic acids.

Table 1 Chemical composition and fatty acid profile of grasses and concentrate (g/kg dry matter) (Mean values with their standard errors)

* Control grass v. protozoa-free grass.

sem values for n 10 for chemical composition and n 5 for fatty acid profile.

Grass intake and animal growth

PF lambs had numerically a slightly higher grass intake over the 9 weeks of measurement (Table 2). As the values represented a whole group measurement and not individual animal intakes we were not able to perform any statistical analysis. We assume that concentrate intake was the same in both groups as there were no refusals and it was served in long feeding troughs (total length 3 m) with enough space for each lamb to have access. Assuming equal concentrate intakes, total daily DM intake would be 837 and 893 g DM for the control and PF groups, respectively. Live-weight gain and final live weight at slaughter (Table 2) values did not differ between the experimental groups. Wool growth was greater (P < 0·05) in PF lambs than in control lambs.

Table 2 Effect of the absence of protozoa on production parameters and carcass characteristics (Mean values with their standard errors)

* sem values for n 10.

Ruminal fermentation and microbial ecosystem

Rumen pH did not differ between samples taken from control and PF lambs (Table 3). However, ammonia concentrations were significantly affected by the absence of protozoa, with 2·5-fold decrease concentrations in PF animals. Ruminal volatile fatty acid concentration and composition differed between control and PF lambs; butyrate molar proportions decreased in PF lambs compared with control lambs, whose rumen content had higher total volatile fatty acid concentrations than PF lambs. As we expected, no protozoal DNA was detected in PF lambs whereas rumen samples from control animals had 2·21 μg protozoal DNA/ml. Total bacteria DNA quantified by real-time PCR targeting 16S bacterial rDNA did not differ between the experimental groups.

Table 3 Effect of the absence of protozoa on ruminal fermentation and microbial numbers (Mean values with their standard errors)

ND, not detected.

* sem values for n 10.

Fig. 1 shows the DGGE image and the dendrogram derived from the cluster analysis. Rumen content from control and PF animals had a different bacterial species distribution, as the banding profiles were clearly clustered into two different groups, representing control and PF lambs. The two groups showed no more than 50 % similarity in banding patterns, whilst within groups similarity was between 75 and 80 %. Additionally, PF lambs had a lower average total number of bands (40·7 (sd 4·8) v. 54·5 (sd 5·0) for PF and control lambs, respectively) and lower diversity (Shannon index: 3·99 v. 4·22 for PF and control lambs, respectively). The present results suggest that, even though total bacterial numbers were similar, the distribution of the different bacterial groups was changed due to the lack of protozoa.

Fig. 1 Denaturing gradient gel electrophoresis of rumen bacterial 16S rDNA from control (C) and protozoa-free (PF) lambs and dendrogram derived after cluster analysis (unweighted pair group method with arithmetic mean; UPGMA) of banding profiles. The scaled bar indicates percentage similarity coefficients.

Abomasal and intramuscular fatty acid composition

The fatty acid compositions of both abomasal and intramuscular fat samples are shown in Table 4. Abomasal contents from control lambs had lower concentrations of trans-11–18 : 1 and higher of 20 : 3n-6, 22 : 5n-3, 22 : 6n-3 and total PUFA than PF lambs. The rest of the fatty acids, including the CLA isomers, were present at the same concentrations in abomasal contents from both experimental groups.

Table 4 Effect of the absence of protozoa on fatty acid composition (proportion (× 100) of total fatty acids) of abomasal content and sacrocaudalis ventralis lateralis intramuscular fat (Mean values with their standard errors)

PF, protozoa-free.

* sem values for n 5.

Sum of 14 : 0, 16 : 0 and 18 : 0.

Sum of 16 : 1, trans-11-18 : 1 and cis-9-18 : 1.

§ Sum of 18 : 2n-6, 18 : 3n-3, cis-9, trans-11-18 : 2, trans-10, cis-12–18 : 2, 20 : 3n-6, 20 : 4n-6, 20 : 5n-3, 22 : 5n-3 and 22 : 6n-3.

The total lipid in tail muscle samples was 24·2 and 27·3 mg lipid/g muscle (wet weight) for control and PF groups, respectively (P = 0·403; sed 4·93). Fatty acid concentrations in intramuscular fat showed differences between the groups. PF lambs had higher proportion of 18 : 0, 18 : 3n-3, t10, c12-CLA and total SFA than control lambs. The other CLA isomer analysed in the present study (c9, t11) was present in higher concentrations than the t10, c12 and did not differ between groups. On the other hand, control lambs had higher proportion of cis-9-18 : 1, cis-9, cis-12–18 : 2, 20 : 3n-6, 22 : 6n-3 and MUFA.

Overall the PUFA:SFA ratios in fatty acids detected in intramuscular fat in the present study were 0·39 and 0·28 for control and PF groups, respectively.

Discussion

Rumen defaunation can be achieved by different methods, one of which consists of separating the young animals from their dam after birth and preventing contact with adult animals, being the one used in our work (Abou Akkada & El Shazly, Reference Abou Akkada and El Shazly1964). The literature and the present results confirm that this method allows the rumen to be naturally contaminated with strictly anaerobic bacteria and is also reliable at stopping protozoa developing in the rumen (Williams & Coleman, Reference Coleman1992).

Grass intake and animal growth

In the present experiment PF lambs had a higher daily live animal weight and carcass yield than control lambs. Published results on the effects of eliminating rumen protozoa on animal growth and wool production are contradictory (Veira, Reference Veira1986; Coleman, Reference Coleman1988). In agreement with the present results, several authors (Demeyer et al. Reference Demeyer, Van Nevel and Van de Voorde1982; Bird & Leng, Reference Bird and Leng1984; Van Nevel et al. Reference Van Nevel, Demeyer and Van de Voorde1985; Santra & Karim, Reference Santra and Karim2002) have shown that exclusion of protozoa from the rumen has a beneficial effect on the growth rate, wool growth and feed conversion efficiency in animals under certain feeding conditions. However, some reports have concluded that protozoa are an essential component of the microbial ecosystem in the rumen, and their exclusion has a harmful effect on the productivity of the host (Eadi & Gill, Reference Eadie and Gill1971; Ramprasad & Raghacan, Reference Ramprasad and Raghacan1981). It is, however, clear that selective retention of protozoa in the rumen and the engulfment and digestion of bacteria by protozoa in the rumen increases the recycling of microbial N therein (Koenig et al. Reference Koenig, Newbold, McIntosh and Rode2000). Thus, removing protozoa from the rumen causes an increase in bacterial and total N flows to the duodenum (Ushida et al. Reference Ushida, Jouany and Thivend1986; Ivan et al. Reference Ivan, Neill, Foster, Alimon, Rode and Entz2000, Reference Ivan, Koening, Morgavi, Rode, Newbold and Entz2006). This is manifested in the present experiment by the numerically higher wool growth; wool growth might be an indication of total flow of microbial protein to the duodenum because wool growth is often limited by the sulfur-containing amino acids which are high in microbial protein formed in the rumen (McNabb et al. Reference McNabb, Waghorn, Barry and Shelton1993). The only published paper (Van Nevel et al. Reference Van Nevel, Demeyer and Van de Voorde1985) on the effect of the absence of protozoa on carcass composition found a trend towards more meat and less fat in the carcass of defaunated lambs, but this was not significant.

Ruminal fermentation and microbial ecosystem

Previous studies have found that defaunation had no effect on rumen pH when diets were rich in cell-wall carbohydrates (Collombier, Reference Collombier1981), which is in agreement with the present results. However, ammonia concentrations were significantly affected by the absence of protozoa. With the exception of the results published by Demeyer et al. (Reference Demeyer, Van Nevel and Van de Voorde1982), all authors agree that by defaunating the rumen the NH3-N concentration is greatly decreased (Jouany et al. Reference Jouany, Demeyer and Grain1988), mainly due to a reduction in breakdown of bacterial proteins and lower N recycling in the rumen (Koenig et al. Reference Koenig, Newbold, McIntosh and Rode2000).

The lower butyrate molar proportion observed in PF lambs compared with control is commonly associated with a decreased ruminal fauna (Sutton et al. Reference Sutton, Knight, McAllan and Smith1983; Williams & Coleman, Reference Williams and Coleman1992). Many authors have reported that defaunation frequently results in an increase in the molar proportion of propionic acid (Jouany et al. Reference Jouany, Demeyer and Grain1988); however, we found no effect, with similar acetate:propionate ratios in the experimental groups. The decreased concentrations of iso-butyrate may be indicative of decreased proteolysis (Wolin et al. Reference Wolin, Miller, Stewart, Hobson and Stewart1997). Our observations suggest that defaunation had no effect on total bacterial numbers, which differs from the majority of the experiments carried out on the effect of defaunation (Hsu et al. Reference Hsu, Fahey, Berger, Mackie and Menden1991). However, most of these measurements were made over a short time period. Williams & Withers (Reference Williams and Withers1990) reported that in the medium to long term, bacterial numbers in the rumen of defaunated sheep tended to decrease to the original values observed before defaunation.

Despite there being no effect on total bacterial numbers, DGGE 16S rDNA banding profiles showed different bacterial populations in PF and control lambs. Previous studies have reported that defaunation causes an increase in Gram-negative rod-type bacteria (Kurihara et al. Reference Kurihara, Eadie, Hobson and Mann1968), of amylolytic bacteria (Kurihara et al. Reference Kurihara, Takechi and Shibata1978) and modifications in the balance between cellulolytic bacteria (Whitelaw et al. Reference Whitelaw, Eadie, Mann and Reid1972). More recently, Ozutsumi et al. (Reference Ozutsumi, Tajima, Takenaka and Itabashi2005) observed different bacterial communities in faunated and defaunated cattle by using 16S rDNA clone libraries. In the former study 151 sequences from faunated animals were classified into 98 operational taxonomic units, while the 161 sequences from defaunated animals were classified into 72 operational taxonomic units. However, for complex microbiomes such as those in the rumen or soil, it is estimated that thousands to ten of thousands clones are required for more robust comparison (Dunbar et al. Reference Dunbar, Barns, Ticknor and Kuske2002). In addition, only about twenty to twenty-two clones per animal were sequenced, which limits inter-animal variation. The DNA fingerprint technique used in the present study (PCR-DGGE), although less detailed in terms of bacterial phylogeny, ensures a broader analysis of the bacterial community in comparison with 16S rDNA libraries with limited number of sequences and confirmed the higher bacterial diversity reported by Ozutsumi et al. (Reference Ozutsumi, Tajima, Takenaka and Itabashi2005) in faunated animals compared with defaunated animals and showed that the differences are consistent amongst animals. The effect of the absence of protozoa in different bacterial numbers may be explained by the preferential uptake of specific groups of bacteria by protozoa. Coleman (Reference Coleman1964, Reference Coleman1986) showed that Selenomonas ruminantium and B. fibrisolvens were taken up and digested at faster rates than other bacteria by Entodinium caudatum. Kurihara et al. (Reference Kurihara, Takechi and Shibata1978) found a significant increase in Megasphera numbers in the rumen after defaunation. However, we found that eliminating protozoa from the rumen leads to lower bacterial diversity and the disappearance of some bacterial groups compared with faunated animals. That might be explained by the close metabolic relationship between protozoa and some groups of bacteria, in addition to methanogens, found to be attached to protozoa (Vogels et al. Reference Vogels, Hoppe and Stumm1980; Bonhomme, Reference Bonhomme1990).

Abomasal and intramuscular fatty acid composition

Tail muscle samples were taken from the carcass in the present study to study muscle fatty composition to enable carcasses to be sold. Although most of the published work studying the fatty acid composition of intramuscular fat used longissimus dorsi muscle as a reference, there is evidence that differences in the fatty acid composition (in percentage terms) of the intramuscular fat is very small between different esqueletic muscles (Enser et al. Reference Enser, Hallet, Hewitt, Fursey, Wood and Harrington1998). In the former work the authors did not find major differences in the fatty composition of three esqueletic muscles from different parts of the carcass (triceps branchi, longissumus dorsi and gluteobiceps) from lambs fed grass. Intramuscular fat is metabolically very active in all esqueletic muscles compared with perineal and subcutaneous adipocytes (Gardan et al. Reference Gardan, Gondret and Louveau2006), and that could explain the similarity between different muscles in the body.

Ruminant fats are among the richest natural dietary source of CLA, in particular the c9, t11 and t10, c12 isomers (Chin et al. Reference Chin, Liu, Storkson, Ha and Pariza1992). Both isomers are produced as a result of the partial biohydrogenation of linoleic and linolenic acid in the rumen by ruminal micro-organisms (Harfoot & Hazlewood, Reference Harfoot, Hazlewood, Hobson and Stewart1997). Although, biohydrogenation in the rumen has been considered only in terms of bacterial activity, recent observations have suggested that rumen protozoa may play an important role given the high concentration in VA and CLA in protozoa compared with bacteria (Devillard et al. Reference Devillard, McIntosh, Newbold and Wallace2006). Indeed, by using real-time PCR to quantify rumen protozoa (Sylvester et al. Reference Sylvester, Karnati, Yu, Newbold and Firkins2005), we have estimated that protozoa accounted for between 30 and 43 % of CLA and 40 % of the VA reaching the duodenum (Yáñez-Ruiz et al. Reference Yáñez-Ruiz, Scollan, Merry and Newbold2006).

Various studies have demonstrated that little CLA flows out of the rumen (Duckett et al. Reference Duckett, Andrae and Owens2002; Sackmann et al. Reference Sackmann, Duckett, Gillis, Realini, Parks and Eggelston2003), although this is the first intermediate in the biohydrogenation of linoleic acid (Harfoot & Hazlewood, Reference Harfoot, Hazlewood, Hobson and Stewart1997). The flow of VA to the duodenum was more than twenty times greater than CLA in steers fed typical finishing diets (Duckett et al. Reference Duckett, Andrae and Owens2002; Sackmann et al. Reference Sackmann, Duckett, Gillis, Realini, Parks and Eggelston2003). Thus, the key to increasing the CLA content of animal tissues may be to produce CLA using the Δ9 desaturase enzyme in the animals tissue which has been shown to be important for accumulation of c9, t11-CLA in milk (Griinari et al. Reference Griinari, Corl, Lacy, Chouinard, Nurmela and Bauman2000). Thus, the higher VA content found in the abomasum of PF lambs could explain the numerically higher c9, t11-CLA synthesis and deposition in the muscle observed in the present study. This higher VA production is in agreement with lower 18 : 2 concentration as a result of an increase in the biohydrogenation of 18 : 2 to 18 : 1 and 18 : 0, suggesting that a shift in the biohydrogenation pathway has occurred in PF lambs compared with control lambs. However, meat fat from control lambs had higher VA concentrations, which could represent an advantage over PF lambs, considering that about 20 % of the dietary VA is desaturated to c9, t11-CLA in the human liver (Turpeinen et al. Reference Turpeinen, Mutanen, Aro, Salminen, Basu, Palmquist and Griinari2002). Early work (Klopfenstein et al. Reference Klopfenstein, Purser and Tyznik1966; Lough, Reference Lough1968) studied the effect of defaunation on lipid metabolism and indicated that 16 : 0, 16 : 1 and 18 : 0 levels in plasma were unchanged after defaunation; however, the plasma concentrations of 18 : 3 and 18 : 2 were increased in defaunated animals, whereas 18 : 1 concentrations fell. These results might indicate that dietary fatty acids are hydrogenated more effectively when ciliate protozoa are present in the rumen, which does not agree with our observations. Different ruminal bacteria groups involved in biohydrogenation have been described. Two complementary groups are believed to be involved: group A biohydrogenate long-chain unsaturated fatty acids to VA whereas group B bacteria biohydrogenate VA to stearic acid (Kemp & Lander, Reference Kemp and Lander1984; Harfoot & Hazlewood, Reference Harfoot, Hazlewood, Hobson and Stewart1997). B. fibrisolvens from group A hydrogenates linoleic acid to c9, t11-CLA and VA and Fusocillus from group B completes the hydrogenation of VA to stearic acid. More recently, Van de Vossenberg & Joblin (Reference Van de Vossenberg and Joblin2003) isolated from a grazing cow a bacterium phylogenetically close to B. hungatei which could form stearate from linoleic acid. As noted earlier, it has been previously shown that B. fibrisolvens are taken up and digested at faster rates than other bacteria by E. caudatum (Coleman, Reference Coleman1986). Thus it seems possible that in the absence of protozoa B. fibrisolvens numbers increased, hence the higher VA production, but that the complete hydrogenation to stearic acid was not enhanced. In any case, because of the complexity of the number of different species involved in biohydrogenation and CLA synthesis (Ogawa et al. Reference Ogawa, Kishino, Ando, Sugimoto, Mihara and Shimizu2005), changes in biohydrogenation pathways might not be explained by changes in the numbers of only two or three bacterial species.

The fatty acid composition of sacrocaudalis ventralis lateralis intramuscular fat agrees with values obtained in abomasal contents, even though we did not measured absolute fatty acid flows from the rumen. The fatty acids 16 : 0, 18 : 0 and cis-9–18 : 1 make up the greatest proportion of the fatty acids in the muscle, which is in agreement with other work carried out with grazing lambs (Enser et al. Reference Enser, Hallet, Hewitt, Fursey, Wood and Harrington1998; Rowe et al. Reference Rowe, Macedo, Visentainer, Souza and Matsushita1999). As might be expected from grass-fed animals, significant proportions of n-3 PUFA were also observed, although not at the levels reported by others (Díaz et al. Reference Díaz, Álvarez and De la Fuente2005), probably due to the concentrate supplement given to the experimental animals which contributed to increase n-6 PUFA intake. With regards to intramuscular fat content, the fact that there was no difference between groups rules out the possibility of explaining some differences in fatty acids due to changes in phospholipid and neutral lipids (Raes et al. Reference Raes, De Smet and Demeyer2004). From the present results, it seems that keeping protozoa in the rumen is beneficial for human health in terms of obtaining a higher PUFA:SFA ratio in ruminant meat. In addition, control lambs had higher levels of 22 : 6n-3, a fatty acid that has been associated with reduction in the thrombotic tendency of blood and a lower risk of heart disease (Department of Health, 1994).

The proportions observed for the main CLA isomer (c9, t11) are in the same range of those found by others in lamb meat (Wachira et al. Reference Wachira, Sinclair, Wilkinson, Enser, Wood and Fisher2002; Cooper et al. Reference Cooper, Sinclair, Wilkinson, Hallet, Enser and Wood2004) and are higher than values reported for lambs fed on concentrate diets (Aurousseau et al. Reference Aurousseau, Bauchart, Calichon, Micol and Priolo2004). Although only a few papers report the t10, c12-CLA content in lamb muscles, our values observed for the PF lambs appear to be slightly higher than those published (Bolte et al. Reference Bolte, Hess, Means, Moss and Rule2002). The three-fold rise observed in t10, c12-CLA in PF lambs compared with control lambs is of the same order to that achieved by Boles et al. (Reference Boles, Kott, Hatfield, Bergman and Flynn2005) in lambs after supplementing the basal diet with 6 % of safflower oil. This increase is in agreement with Jouany & Lassalas (Reference Jouany and Lassalas2003) who observed, in vitro, that three times more t10, c12-CLA was produced in vessels inoculated with rumen fluid from defaunated animals compared with those inoculated with rumen fluid from faunated animals. They suggested that defaunating activates certain isomerisation reactions and pushes biohydrogenation pathways towards trans, trans and t10, c12 isomer production. Interestingly, Kim et al. (Reference Kim, Liu, Rychlik and Russell2002) identified a strain of Megasphaera elsdenii (YJ-4) capable of producing t10, c12-CLA, whilst Kurihara et al. (Reference Kurihara, Takechi and Shibata1978) showed a ten-fold increase in Megasphera after defaunation, which could explain the higher production of this isomer observed in PF lambs. A number of recent observations using individual isomers in animals and human subjects seem to suggest that some CLA isomers, particularly the t10, c12 isomer, may elicit detrimental effects on human health (Medina et al. Reference Medina, Horn, Keim, Havel, Benito, Kelley, Nelson and Erickson2000; Riserus et al. Reference Riserus, Berglund and Vessby2001, Roche et al. Reference Roche, Noone, Sewter, Mc Bennett, Savage, Gibney, O'Rahilly and Vidal-Puig2002) although no detrimental effects on health have been reported for the more commonly employed 50:50 mixtures of the two main isomers of CLA or the most abundant c9, t11 isomer (Wahle et al. Reference Wahle, Heys and Rotondo2004). The present results show a higher concentration of the t10, c12 isomer in muscle from PF animals which, if the deleterious effects of this isomer are confirmed, suggests that defaunating the rumen might not be desirable in terms of producing a diet for optimal human health.

As noted before, PUFA:SFA ratios of the fatty acids detected in intramuscular fat in the present study were 0·39 and 0·28 for control and PF groups, respectively. Chalupa & Kutches (Reference Chalupa and Kutches1968) believed that the increased levels of oleic and linoleic acids in the milk of animals with depressed milk fat tests were attributable to the virtual absence of protozoa in the rumen of these cattle. Investigations with pure isomers have shown that t10, c12-CLA is a potent inhibitor of milk fat synthesis (Bauman & Griinari, Reference Bauman and Griinari2003), which could explain the relationship between absence of protozoa and milk fat depression reported by Chalupa & Kutches (Reference Chalupa and Kutches1968). In contrast, Abaza et al. (Reference Abaza, Abou Akkada and El Shazly1975) found a decrease in SFA levels in the plasma of sheep lacking protozoa compared with faunated animals. Protozoa rapidly engulf chloroplasts released from plant cells (Hall et al. Reference Hall, West and Coleman1974) and possibly as a result the fatty acids of rumen protozoa are less saturated (between 22 and 35 % of the fatty acids present as 18 : 1, 18 : 2 or 18 : 3) compared with bacteria (between 7 and 25 % of the fatty acids present as 18 : 1, 18 : 2 or 18 : 3) (Harfoot & Hazlewood, Reference Harfoot, Hazlewood, Hobson and Stewart1997). Girard & Hawke (Reference Girard and Hawke1978) estimated that 20–25 % of the linoleic acid in the rumen of a cow receiving a hay diet was present in the lipids of the relatively small Isotricha population (103–104 cells/ml). Different diets and means of providing forages (grazing, silage, hay) will lead to differing levels of chloroplast entering the rumen and hence a possible different role of protozoa. Based on the present results, it might be speculated that unsaturated dietary fatty acids may be partially protected from biohydrogenation by incorporation into structural phospholipids of protozoa. Given that protozoa make up approximately half of the rumen biomass (Jouany, Reference Jouany1995), this suggests that ciliate protozoa represent a major pool of unsaturated fatty acids in the rumen as a result of their storage capacity. This is supported by our recent results (Yáñez-Ruiz et al. Reference Yáñez-Ruiz, Scollan, Merry and Newbold2006) which show that protozoa make a greater contribution to the flow of unsaturated fatty acids from the rumen (30–50 % of the fatty acids entering the duodenum of protozoal origin) than to the flow of SFA (10–20 %).

In conclusion, the elimination of protozoa from the rumen leads not only to greater animal lamb growth, but also to changes in bacterial populations and in the biohydrogenation pathways, which results in more VA being produced in the rumen and less PUFA, more SFA and t10, c12-CLA in intramuscular fat, which is not desirable from a human health perspective. More research needs to be undertaken on the effect of rumen protozoa in animals fed different types of diets with different lipid sources to confirm such a hypothesis.

Acknowledgements

The authors acknowledge expert analytical advice from Dr Susan Girwood, and Evita Gonzalez and Dr Stephane Duval for technical assistance. D. R. Y.-R. gratefully acknowledges the receipt of a research contract from the European Commission (Marie Curie Programme RUMENOMICS 010972).

References

Abaza, MA, Abou Akkada, AR & El Shazly, K (1975) Effect of rumen protozoa on dietary lipid in sheep. J Agric Sci 85, 135143.CrossRefGoogle Scholar
Abou Akkada, AR & El Shazly, K (1964) Effect of absence or presence of rumen ciliate protozoa on some blood components, nitrogen retention and digestibility of food constituents in lambs. J Agric Sci 64, 251255.CrossRefGoogle Scholar
Ankom (2000) Procedures for fibre and in vitro analysis. Accessed 14 December 2000.http://www.ankom.com.Google Scholar
Aurousseau, B, Bauchart, D, Calichon, E, Micol, D & Priolo, A (2004) Effect of grass or concentrate feeding systems and rate of growth on triglyceride and phospholipids and their fatty acids in the M. longissimus thoracis of lambs. Meat Sci 66, 531541.CrossRefGoogle ScholarPubMed
Bauman, DE & Griinari, JM (2003) Nutritional regulation of milk fat synthesis. Annu Rev Nutr 23, 203227.CrossRefGoogle ScholarPubMed
Bauman, DEL, Baumgard, BA, Corl, BA & Griinari, JM (1999) Biosynthesis of conjugated linoleic acids in ruminants. Proc Am Soc Anim Sci, Accessed 1 September 2002.http://www.asas.org/jas/symposia/proceedings/0937.pdf.Google Scholar
Bird, SH & Leng, RA (1984) Further studies on the effects of the presence or absence of protozoa in the rumen of live-weight gain and wool growth of sheep. Br J Nutr 52, 607611.CrossRefGoogle ScholarPubMed
Blankson, H, Stakkestad, JA, Fagertun, H, Thom, E, Wadstein, J & Gudmundsen, O (2000) Conjugated linoleic acid reduces body fat mass in overweight and obese humans. J Nutr 130, 29432948.Google ScholarPubMed
Boles, JA, Kott, RW, Hatfield, PG, Bergman, JW & Flynn, CR (2005) Supplemental safflower oil affects the fatty acid profile, including conjugated linoleic acid, of lamb. J Anim Sci 83, 21752181.CrossRefGoogle ScholarPubMed
Bolte, MR, Hess, BW, Means, WJ, Moss, GE & Rule, DC (2002) Feeding lambs high-oleate or high-linoleate safflower seeds differentially influences carcass fatty acid composition. J Anim Sci 80, 609616.CrossRefGoogle ScholarPubMed
Bonhomme, A (1990) Rumen ciliates: their metabolism and relationship with bacteria and their hosts. Anim Feed Sci Technol 30, 203266.CrossRefGoogle Scholar
Chalupa, A & Kutches, AJ (1968) Biohydrogenation of linoleic 1-C14 acid by rumen protozoa. J Anim Sci 27, 15021508.CrossRefGoogle Scholar
Chin, SF, Liu, W, Storkson, JM, Ha, YL & Pariza, WM (1992) Dietary sources of conjugated dienoic isomers of linoleic acid, a newly recognized class of anticarcinogens. J Food Compos Anal 5, 185197.CrossRefGoogle Scholar
Coleman, GS (1964) The metabolism of Escherichia coli and other bacteria by Entodinium caudatum. J Gen Microbiol 47, 449464.CrossRefGoogle Scholar
Coleman, GS (1986) The metabolism of rumen ciliate protozoa. FEMS Microbiol Rev 39, 321344.CrossRefGoogle Scholar
Coleman, GS (1988) The importance of rumen ciliate protozoa in the growth and metabolism of the host ruminant. Int J Anim Sci 3, 7595.Google Scholar
Collombier, J (1981) Contribution à l'étude du role des protozoaires cilies du rumen dans l'apport d'azote microbien entrant dans le duodenum du ruminant (Contribution to the study of the role of rumen ciliate protozoa in the microbial nitrogen contribution entering the duodenum of ruminants). PhD Thesis, Université Clermont-Ferrand II.Google Scholar
Cooper, SL, Sinclair, LA, Wilkinson, RG, Hallet, KG, Enser, M & Wood, JD (2004) Manipulation of the n-3 polyunsaturated fatty acid content of muscle and adipose tissue in lambs. J Anim Sci 82, 14611470.CrossRefGoogle ScholarPubMed
Dawson, RMC & Kemp, P (1969) The effect of defaunation on the phospholipids and on the hydrogenation of unsaturated fatty acids in the rumen. Biochem J 115, 351352.CrossRefGoogle ScholarPubMed
De la Torre, A, Debiton, E, Durand, D, Chardigny, JM, Berdeaux, O, Loreau, O, Barthomeuf, C, Bauchart, D & Gruffat, D (2005) Conjugated linoleic acid isomers and their conjugated derivatives inhibit growth of human cancer cell lines. Anticancer Res 25, 39433949.Google ScholarPubMed
Demeyer, DI, Van Nevel, CJ & Van de Voorde, G (1982) The effect of defaunation on the growth of lambs fed three urea-containing diets. Arch Tierernähr 32, 595604.CrossRefGoogle Scholar
Department of Health (1994) Nutritional Aspects of Cardiovascular Disease. Report on Health and Social Subjects no. 46. London: H.M. Stationery Office.Google Scholar
Devillard, E, McIntosh, FM, Newbold, CJ & Wallace, RJ (2006) Rumen ciliate protozoa contain high concentrations of conjugated linoleic acids and vaccenic acid, yet do not hydrogenate linoleic acid or desaturate stearic acid. Br J Nutr 96, 697704.Google ScholarPubMed
Díaz, MT, Álvarez, I, De la Fuente, J, et al. (2005) Fatty acid composition of meat from typical lamb production systems of Spain. United Kingdom, Germany and Uruguay. Meat Sci 71, 256263.CrossRefGoogle ScholarPubMed
Duckett, SK, Andrae, JG & Owens, FN (2002) Effect of high-oil corn or added corn oil on ruminal biohydrogenation of fatty acids and conjugated linoleic acid formation in beef steers fed finishing diets. J Anim Sci 80, 33533360.CrossRefGoogle ScholarPubMed
Dunbar, J, Barns, SM, Ticknor, LO & Kuske, CR (2002) Empirical and theoretical bacterial diversity in four Arizona soils. Appl Environ Microbiol 68, 30353045.CrossRefGoogle ScholarPubMed
Eadie, JM & Gill, JC (1971) The effect of the absence of rumen ciliate protozoa on growing lambs fed on a roughage-concentrate diet. Br J Nutr 26, 155167.CrossRefGoogle ScholarPubMed
Enser, M, Hallet, K, Hewitt, B, Fursey, GAJ, Wood, JD & Harrington, G (1998) Fatty acid composition of UK beef anf lamb muscle in relation to production system and implications for human nutrition. Meat Sci 49, 329341.CrossRefGoogle Scholar
Felsenstein, F (2002) PHYLIP (Phylogeny Inference Package) version 3·6a. Seattle: University of Washington.Google Scholar
Folch, J, Lees, M & Sloane Stanley, GH (1957) A simple method for the isolation and purification of lipides from animal tissues. J Biol Chem 226, 497509.CrossRefGoogle ScholarPubMed
Gardan, D, Gondret, F & Louveau, I (2006) Lipid metabolism and secretory function of porcine intramuscular adipocytes compared with subcutaneous and perineal adipocytes. Am J Physiol 291, E372E380.Google Scholar
Girard, V & Hawke, JC (1978) The role of holotrichs in the metabolism of dietary linoleic acid in the rumen. Biochim Biophys Acta 528, 404413.Google Scholar
Griinari, JM, Corl, BA, Lacy, SH, Chouinard, PY, Nurmela, KV & Bauman, DE (2000) Conjugated linoleic acid is synthesized endogenously in lactating dairy cows by Δ9-desaturase. J Nutr 130, 22852291.CrossRefGoogle Scholar
Hall, FJ, West, J & Coleman, GS (1974) Fine structural studies on the digestion of chloroplasts in the rumen ciliate Entodinium caudatum. Tissue Cell 6, 243253.CrossRefGoogle ScholarPubMed
Harfoot, GC & Hazlewood, GP (1997) Lipid metabolism in the rumen. In The Rumen Microbial Ecosystem, pp. 383425 [Hobson, PN and Stewart, CS, editors]. London: Blackie Academic and Professional.Google Scholar
Hsu, JT, Fahey, GC, Berger, LL, Mackie, RI & Menden, NR (1991) Manipulation of nitrogen digestion by sheep using defaunation and various nitrogen supplementation regimes. J Anim Sci 69, 12901297.CrossRefGoogle Scholar
Ivan, M, Koening, KM, Morgavi, DP, Rode, LM, Newbold, CJ & Entz, T (2006) Duodenal flow and digestibility in fauna-free sheep and in sheep monofauntaed with Entodinium caudatum or Polypastron multivesiculatum. Br J Nutr 95, 469476.CrossRefGoogle ScholarPubMed
Ivan, M, Neill, L, Foster, R, Alimon, R, Rode, LM & Entz, T (2000) Effects of Isotricha, Dasytricha, Entodinium, and total fauna on ruminal fermentation and duodenal flow in wethers fed different diets. J Dairy Sci 83, 776787.CrossRefGoogle ScholarPubMed
Jouany, JP (1995) Effect of rumen protozoa on nitrogen utilization by ruminants. J Nutr 1335S1346S.Google Scholar
Jouany, JP & Lassalas, B (2003) Effect of rumen protozoa on biohydrogenation of polyunsaturated fatty acids. In Proceedings of the International Conference on the Molecular Biology and Biotechnology of Ciliates and Anaerobic Protozoa, p. 94. Nijmegen, The Netherlands: University of Nijmegen.Google Scholar
Jouany, JP, Demeyer, DI & Grain, J (1988) Effect of defaunating the rumen. Anim Feed Sci Technol 21, 229265.CrossRefGoogle Scholar
Kemp, P & Lander, DJ (1984) Hydrogenation in vitro of α-linolenic acid to stearic acid by mixed rumen bacteria. J Gen Microbiol 130, 527533.Google Scholar
Kim, YJ, Liu, RM, Rychlik, JL & Russell, JB (2002) The enrichment of a ruminal bacterium (Megasphaera elsdenii YJ-4) that produces the trans-10, cis-12 isomer of conjugated linoleic acid. J Appl Microbiol 92, 976982.CrossRefGoogle ScholarPubMed
Klopfenstein, TJ, Purser, DB & Tyznik, WJ (1966) Effects of defaunation on feed digestibility, rumen metabolism and blood metabolites. J Anim Sci 25, 765–773.CrossRefGoogle ScholarPubMed
Koenig, KM, Newbold, CJ, McIntosh, FM & Rode, LM (2000) Effects of protozoa on bacterial nitrogen recycling in the rumen. J Anim Sci 78, 24312445.CrossRefGoogle ScholarPubMed
Kramer, JKG & Zhou, JQ (2001) Conjugated linoleic acid and octadecenoic acids: extraction and isolation of lipids. Eur J Lipid Sci Technol 103, 594–600.3.0.CO;2-R>CrossRefGoogle Scholar
Kurihara, Y, Eadie, JM, Hobson, PN & Mann, SO (1968) Relationship between bacteria and ciliate protozoa in the sheep rumen. J Gen Microbiol 51, 267–288.CrossRefGoogle ScholarPubMed
Kurihara, Y, Takechi, T & Shibata, F (1978) Relationship between bacteria and ciliate protozoa in the rumen of sheep fed on a purified diet. J Agric Sci 90, 373381.CrossRefGoogle Scholar
Labarca, C & Paigen, K (1980) A simple, rapid, and sensitive DNA assay procedure. Anal Biochem 102, 344–352.CrossRefGoogle ScholarPubMed
Lough, AK (1968) Component of fatty acids of plasma lipids of lambs with and without rumen ciliate protozoa. Proc Nutr Soc 27, 30A–31A.Google Scholar
McNabb, WC, Waghorn, GC, Barry, TN & Shelton, ID (1993) The effect of condensed tannins in Lotus pedunculatus on the digestion and metabolism of methionine, cystine and inorganic sulphur in sheep. Br J Nutr 70, 647661.CrossRefGoogle ScholarPubMed
Maeda, H, Fujimoto, C, Haruki, Y, Maeda, T, Kokeguchi, S, Petelin, M, Arai, H, Tanimoto, I, Nishimura, F & Takashiba, S (2003) Quantitative real-time PCR using TaqMan and SYBR Green for Actinobacillus actinomycetemcomitans, Porphyromonas gingivalis, Prevotella intermedia, tetQ gene and total bacteria. FEMS Immunol Med Microbiol 39, 81–86.CrossRefGoogle ScholarPubMed
Marrugan, A (1988) Ecological Diversity and its Measurement. London: Chapman and Hall.Google Scholar
Medina, EA, Horn, WF, Keim, NL, Havel, PJ, Benito, P, Kelley, DS, Nelson, GJ & Erickson, KL (2000) Conjugated linoleic acid supplementation in humans: effects on circulating leptin concentrations and appetite. Lipids 35, 783788.CrossRefGoogle ScholarPubMed
Muyzer, G, de Waal, EC & Uitterlinden, GA (1993) Profiling of complex populations by denaturing gradient gel electrophoresis of polymerase chain reaction-amplified genes coding for 16S rRNA. App Environ Microbiol 59, 695–700.CrossRefGoogle ScholarPubMed
Nubel, U, Engelen, B, Felske, A, Snaidr, J, Wieshuber, A, Amann, RI, Ludwing, W & Backhaus, H (1996) Sequence heterogeneities of genes encoding 16S rRNAs in Paenibacillus polymyxa detected by temperature gradient gel electrophoresis. J Bacteriol 178, 56365643.CrossRefGoogle ScholarPubMed
Ogawa, J, Kishino, S, Ando, A, Sugimoto, S, Mihara, K & Shimizu, S (2005) Production of conjugated fatty acids by lactic acid bacteria. J Biosci Bioeng 100, 355–364.CrossRefGoogle ScholarPubMed
Ozutsumi, Y, Tajima, K, Takenaka, A & Itabashi, H (2005) The effect of protozoa on the composition of rumen bacteria in cattle using 16S rRNA gene clone libraries. Biosci Biotechnol Biochem 69, 499506.CrossRefGoogle ScholarPubMed
Raes, K, De Smet, S & Demeyer, D (2004) Effect of dietary fatty acids on incorporation of long chain polyunsaturated fatty acids and conjugated linoleic acid in lamb, beef and pork meat: a review. Anim Feed Sci Technol 113, 199–221.CrossRefGoogle Scholar
Ramprasad, J & Raghacan, GV (1981) Note of the growth rate and body composition of faunated and defaunated lambs. Indian J Anim Sci 51, 570572.Google Scholar
Regensbogenova, MP, Pristas, P, Javorsky Hackstein, JHP, Newbold, CJ & McEwan, N (2004) Assessment of ciliates in the sheep rumen by DGGE. Lett Appl Microbiol 39, 144–147.CrossRefGoogle ScholarPubMed
Riserus, U, Berglund, L & Vessby, B (2001) Conjugated linoleic acid (CLA) reduced abdominal adipose tissue in obese middle-aged men with signs of the metabolic syndrome: a randomised controlled trial. Int J Obes 25, 11291135.CrossRefGoogle ScholarPubMed
Roche, HM, Noone, E, Sewter, C, Mc Bennett, S, Savage, D, Gibney, MJ, O'Rahilly, S & Vidal-Puig, AJ (2002) Isomer-dependent metabolic effects of conjugated linoleic acid: insights from molecular markers sterol regulatory element-binding protein-1c and LXRα. Diabetes 51, 20372044.CrossRefGoogle ScholarPubMed
Rooke, JA, Alison, J & Borman Armstrong, DG (1990) The effect of inoculation with Lactobacillus plantarum on fermentation in laboratory silos of herbage low in water-soluble carbohydrate. Grass Forage Sci 45, 143–152.CrossRefGoogle Scholar
Rowe, A, Macedo, FA, Visentainer, JV, Souza, NE & Matsushita, M (1999) Muscle composition and fatty acid profile in lambs fattened in drylot or pasture. Meat Sci 51, 283288.CrossRefGoogle ScholarPubMed
Sackmann, JR, Duckett, SK, Gillis, MH, Realini, CE, Parks, AH & Eggelston, RB (2003) Effects of forage and sunflower oil levels on ruminal biohydrogenation of fatty acids and conjugated linoleic acid formation in beef steers fed finishing diets. J Anim Sci 81, 31743181.CrossRefGoogle ScholarPubMed
Santra, A & Karim, SA (2002) Influence of ciliate protozoa on biochemical changes and hydrolytic enzyme profile in the rumen ecosystem. J Appl Microbiol 92, 801–811.CrossRefGoogle ScholarPubMed
Stewart, CS, Flint, HJ & Bryant, MP (1997) The rumen bacteria. In The Rumen Microbial Ecosystem, pp. 10–72 [Hobson, PN and Stewart, CS, editors]. London: Blackie Academic and Professional.CrossRefGoogle Scholar
Stockdale, CR & King, KR (1983) A comparison of two techniques used to estimate the herbage intake of lactating dairy cows in a grazing environment. J Agric Sci 100, 227230.CrossRefGoogle Scholar
Sukhija, PS & Palmquist, DL (1988) Rapid method for determination of total fatty acid content and composition of feedstuffs and feces. J Agric Food Chem 36, 12021206.CrossRefGoogle Scholar
Sutton, JD, Knight, R, McAllan, AB & Smith, RH (1983) Digestion and synthesis in the rumen of sheep given diets supplemented with free and protected oils. Br J Nutr 49, 419–432.CrossRefGoogle ScholarPubMed
Sylvester, JT, Karnati, SK, Yu, Z, Morrrison, M & Firkins, JL (2004) Development of an assay to quantify ciliate protozoal biomass in cows using real-time PCR. J Nutr 134, 33783384.CrossRefGoogle ScholarPubMed
Sylvester, JT, Karnati, SK, Yu, Z, Newbold, CJ & Firkins, JL (2005) Evaluation of a real time PCR assay quantifying the ruminal pool size and duodenal flow of protozoal nitrogen. J Dairy Sci 88, 2083–2095.CrossRefGoogle ScholarPubMed
Toomey, S, Harhen, B, Roche, HM, Fitzgerald, D & Belton, O (2005) Profound resolution of early atherosclerosis with conjugated linoleic acid. Atherosclerosis 20, 232–238.Google Scholar
Turpeinen, AM, Mutanen, M, Aro, A, Salminen, I, Basu, S, Palmquist, DL & Griinari, JM (2002) Bioconversion of vaccenic acid to conjugated linoleic acid by humans. Am J Clin Nutr 76, 504510.CrossRefGoogle ScholarPubMed
Ushida, K, Jouany, JP & Thivend, P (1986) Role of protozoa in nitrogen digestion in sheep given two isonitrogenous diets. Br J Nutr 56, 407–419.CrossRefGoogle ScholarPubMed
Van de Vossenberg, JLCM & Joblin, KN (2003) Biohydrogenation of C18 unsaturated fatty acids to stearic acid by a strain of Butyrivibrio hungatei from the bovine rumen. Lett App Microbiol 37, 424428.CrossRefGoogle ScholarPubMed
Van Nevel, CJ, Demeyer, DI & Van de Voorde, G (1985) Effect of defaunating the rumen on growth and carcass composition of lambs. Arch Anim Nutr 35, 331–337.Google ScholarPubMed
van Soest, PJ & Mason, VC (1991) The influence of the Maillard reaction upon the nutritive value of fibrous feeds. Animal Feed Sci Technol 32, 45–53.CrossRefGoogle Scholar
Veira, DM (1986) The role of ciliate protozoa in nutrition of the ruminant. J Anim Sci 63, 15471560.CrossRefGoogle ScholarPubMed
Vogels, GD, Hoppe, WF & Stumm, CK (1980) Association of methahanogenic bacteria with rumen ciliates. Appl Environ Microbiol 40, 608–612.CrossRefGoogle ScholarPubMed
Wachira, AM, Sinclair, LA, Wilkinson, RG, Enser, M, Wood, JD & Fisher, V (2002) Effects of dietary fat source and breed on the carcass composition n-3 polyunsaturaed fatty acid and conjugated linoleic acid content of sheep meat and adipose tissue. Br J Nutr 88, 697709.CrossRefGoogle Scholar
Wahle, WJK, Heys, SD & Rotondo, D (2004) Conjugated linoleic acids: are they beneficial or detrimental to health? Prog Lipid Res 43, 553–587.CrossRefGoogle ScholarPubMed
Weatherburn, MW (1967) Phenol hypochlorite reaction for determination of ammonia. Anal Chem 89, 971974.CrossRefGoogle Scholar
Whitelaw, FG, Eadie, JM, Mann, SO & Reid, RS (1972) Some effects of rumen ciliate protozoa in cattle given restricted amounts of barley diet. Br J Nutr 27, 425–437.CrossRefGoogle ScholarPubMed
Williams, AG & Coleman, GS (1992) The Rumen Protozoa. New York: Springer-Verlag.CrossRefGoogle Scholar
Williams, AG & Withers, SE (1990) Effect of ciliate protozoa on the activity of polysaccharide-degrading enzymes and fibre breakdown in the rumen ecosystem. J App Bacteriol 70, 144–155.CrossRefGoogle Scholar
Wolin, MJ, Miller, TL & Stewart, CS (1997) Microbe-microbe interactions. In The Rumen Microbial Ecosystem, pp. 467491 [Hobson, PN and Stewart, CS, editors]. London: Blackie Academic and Professional.CrossRefGoogle Scholar
Yáñez-Ruiz, DR, Scollan, ND, Merry, RJ & Newbold, CJ (2006) Contribution of rumen protozoa to duodenal flow of nitrogen, conjugated linoleic acid and trans-vaccenic acid in steers fed silages differing in their water-soluble carbohydrate content. Br J Nutr 96, 861869.CrossRefGoogle ScholarPubMed
Zhang, H, Guo, Y & Yuan, J (2005) Conjugated linoleic acid enhanced the immune function in broiler chicks. Br J Nutr 94, 746–752.CrossRefGoogle ScholarPubMed
Figure 0

Table 1 Chemical composition and fatty acid profile of grasses and concentrate (g/kg dry matter) (Mean values with their standard errors)

Figure 1

Table 2 Effect of the absence of protozoa on production parameters and carcass characteristics (Mean values with their standard errors)

Figure 2

Table 3 Effect of the absence of protozoa on ruminal fermentation and microbial numbers (Mean values with their standard errors)

Figure 3

Fig. 1 Denaturing gradient gel electrophoresis of rumen bacterial 16S rDNA from control (C) and protozoa-free (PF) lambs and dendrogram derived after cluster analysis (unweighted pair group method with arithmetic mean; UPGMA) of banding profiles. The scaled bar indicates percentage similarity coefficients.

Figure 4

Table 4 Effect of the absence of protozoa on fatty acid composition (proportion (× 100) of total fatty acids) of abomasal content and sacrocaudalis ventralis lateralis intramuscular fat (Mean values with their standard errors)