The importance of methanogens associated with ciliate protozoa in ruminal methane production in vitro

The importance of methanogenic bacteria associated with ciliate protozoa was estimated either by removing protozoa from whole rumen fluid (using defaunated rumen fluid to correct for the effects of centrifugation on bacteria) or by isolating the protozoa. Rumen fluid was withdrawn from sheep inoculated with either Polyplastron multivesiculatum , a co-culture of Isotricha prostoma plus Entodinium spp. or a mixed type B fauna of Entodinium, Eudiplodinium and Epidinium spp. Methanogenesis was highest in rumen fluid containing a mixed protozoal population of the following genera: Entodinium, Eudiplodinium and Epidinium , was lower in defaunated rumen fluid and lowest in rumen fluid containing either I. prostoma plus Entodinium or P. multivesiculatum . Methanogenic bacteria associated with rumen ciliates were apparently responsible for between 9 and 25% of methanogenesis in rumen fluid.     

Hydrolysis of Fraction 1 leaf protein and casein by rumen entodiniomorphid protozoa

Cell-free extracts of fourteen individual species of rumen ciliate protozoa and of mixed rumen ciliates degraded Fraction 1 leaf protein. For Entodinium caudatum and Eudiplodinium maggii the optimum pH was 3·2. The maximum rates of proteolysis (in µmol acid soluble-tyrosine formed/mg protein/h) were 0·16 to 5·7 with protozoa grown in vivo and 0·38 to 6·4 with protozoa grown in vitro. The highest rates were obtained with Entodinium caudatum and E. simplex and the lowest with the cellulolytic species grown in vivo. K _m values (mg/ml) ranged from 0·42 to 19 with protozoa grown in vivo and 0·35 to 13·3 with protozoa grown in vitro. All single species (with one exception) whether grown in vivo or in vitro degraded Fraction 1 leaf protein faster (1·4 to 21 times) than casein. Partial inhibition of the activity of Entodinium caudatum was obtained with pepstatin and N-ethylmaleimide and almost complete inhibition with leupeptin suggesting the presence of 'carboxyl' and 'thiol' enzymes.     

The uptake and utilization of Entodinium caudatum, bacteria, free amino acids and glucose by the rumen ciliate Entodinium bursa

C oleman , G.S. & H all , F.J. 1984. The uptake and utilization of Entodinium caudatum , bacteria, free amino acids and glucose by the rumen ciliate Entodinium bursa. Journal of Applied Bacteriology 56 , 283–294.
Washed suspensions of Entodinium bursa were incubated anaerobically with Entodinium caudatum , ten species of bacteria and a yeast. The rate of uptake and digestion of these micro-organisms was investigated. Protozoa grown in vivo did not engulf Proteus mirabilis or Klebsiella aerogenes but rapidly took up Bacillus mega-terium, Selenomonas ruminantium, Torulopsis glabrata and Streptococcus bouis , although only the last was digested with release of soluble material into the medium. Protozoa grown in vitro engulfed each of the bacteria tested, taking up Megasphaera elsdenii and i>Proteus mirabilis most rapidly. Individual bacterial species and mixed rumen bacteria were engulfed more rapidly (up to 20 times) by protozoa grown in vivo than those grown in vitro , although the latter digested over 80% of the B. megaterium, Escherichia coli and P. mirabilis taken up. Labelled Ent. caudatum was extensively digested after engulfment by Ent. bursa . Some of the digestion products were released into the medium but individual amino acids were transferred as such from Ent. caudatum protein to Ent. bursa protein. Engulfed bacteria and polysaccharide granules were transferred intact from one protozoon to the other. Free amino acids were also taken up intact from the medium into protozoal protein but there was little biosynthesis of amino acids from glucose. When available for engulfment Ent. caudatum was quantitatively a much more valuable source of amino acids for protein synthesis by Ent. bursa than free amino acids or bacteria.     

Effect of insulin on in vitro fermentation activity of microrganism community of rumen ciliate Entodinium caudatum culture

The influence of insulin (17.4 nmol l-1) on total gas and methane production, the concentration of total and individual fatty acids and dry matter degradability was investigated in the rumen ciliate culture of Entodinium caudatum. The experimental groups consisted of control group (without insulin) and two groups with insulin application--single shot and long-term application (over 30 days). Fermentation activity of each experimental group was observed on two subgroups: whole protozoan culture (protozoa plus bacteria) and bacterial fraction (bacteria without protozoa). Long-term application of insulin significantly increased methane production and DM degradability in the whole protozoan culture. Total VFA concentration was significantly increased by long-term as well as single-dose application of insulin (by 255% and 158%, respectively). The growth of the protozoa was not influenced by insulin treatments. It can be concluded that the fermentation activity of the community of the rumen ciliate Entodinium caudatum culture was marked stimulated by application of insulin.     

Rumen protozoal diversity in the Spanish ibex (Capra pyrenaica hispanica) as compared with domestic goats (Capra hircus)

Rumen protozoal diversity in the Spanish ibex (SI) was studied in males (n=4), females (n=7) and young (n=4) from the Maestrazgo (Spain) and contrasted with domestic goats (n=3; DG) of the same region. There were no differences among SI types in protozoal concentration or in the number of protozoal species. Only protozoa from the genus Entodinium were observed in SI (seven species), the highest numbers corresponding to E. damae, E. ovibos and E. parvum. DG harboured threefold more species than SI. Nine to 10 Entodinium spp. were observed, but E. ovibos was absent from the rumen of DG, and E. damae was in only one animal. E. caudatum (caudatum, dubardi and lobospinosum morphotypes) occurred in the highest percentage, and E. dubardi, E. exiguum and E. parvum were quite abundant. Four genera of the subfamily Diplodiniinae and the genera Isotricha and Dasytricha from the family Isotrichidae were detected in DG. Epidinium (two DG) and Ophryoscolex (one DG) were also observed. Denaturing gradient gel electrophoresis analysis agreed with microscopic classification, showing up to 8 and 16 bands in SI and DG samples, respectively. The three DG clustered together (similarity index over 0.84), and separately from SI (similarity index over 0.86), with only 0.58 similarity between host species.     

The uptake and utilization of Entodinium caudatum, bacteria, free amino acids and glucose by the rumen ciliate Entodinium bursa

Washed suspensions of Entodinium bursa were incubated anaerobically with Entodinium caudatum, ten species of bacteria and a yeast. The rate of uptake and digestion of these micro-organisms was investigated. Protozoa grown in vivo did not engulf Proteus mirabilis or Klebsiella aerogenes but rapidly took up Bacillus megaterium. Selenomonas ruminantium, Torulopsis glabrata and Streptococcus bovis, although only the last was digested with release of soluble material into the medium. Protozoa grown in vitro engulfed each of the bacteria tested, taking up Megasphaera elsdenii and Proteus mirabilis most rapidly. Individual bacterial species and mixed rumen bacteria were engulfed more rapidly (up to 20 times) by protozoa grown in vivo than those grown in vitro, although the latter digested over 80% of the B. megaterium, Escherichia coli and P. mirabilis taken up. Labelled Ent. caudatum was extensively digested after engulfment by Ent. bursa. Some of the digestion products were released into the medium but individual amino acids were transferred as such from Ent. caudatum protein to Ent. bursa protein. Engulfed bacteria and polysaccharide granules were transferred intact from one protozoon to the other. Free amino acids were also taken up intact from the medium into protozoal protein but there was little biosynthesis of amino acids from glucose. When available for engulfment Ent. caudatum was quantitatively a much more valuable source of amino acids for protein synthesis by Ent. bursa than free amino acids or bacteria.     

Bacterial Ingestion by the Rumen Ciliates Entodinium and Diplodinium

SYNOPSIS. In cattle fed a high-starch diet, species of Entodinium and Diplodinium ingested associated ruminal bacteria. Stained preparations of diluted rumen contents showed Entodinium caudatum, E. minimum, E. dubardi , (syn. E. simplex ), E. longinucleatum, E. bursa, E. nanellum, E. exiguum , and E. vorax contained gram-positive diplococci. Starch grains with adherent gram-positive diplococci were observed within Entodinium spp. Diplodinium ecaudatum forma ecaudatum, D. ecaudatum forma caudatum, D. neglectum and an unidentified species of Diplodinium also ingested ruminal diplococci. Bacteria were isolated from mixed species of Entodinium by washing and culturing the protozoa in a starch feed-extract agar medium. The strains isolated from the ciliates were gram-positive diplococci, 0.8 times 1–1.5 μm, which attached themselves to starch granules and were able to digest the starch. Conclusive evidence of bacterial ingestion by the oligotrichs was obtained by providing the bacterial cultures to Entodinium species ( E. dubardi and E. minimum ) which had been starved 24 hr. Gram-stained preparations showed the ciliates readily ingested the bacteria. The amylolytic cocci utilized by Entodinium spp. were identified as Streptococcus bovis.     

The aminoethylphosphonate-containing lipids of rumen protozoa

1. A method is presented for identifying and estimating the aminoethylphosphonate (ciliatine)-containing phospholipids in a complex mixture. 2. Evidence was obtained that the phospholipids of a pure culture of Entodinium caudatum and a mixed rumen protozoa sample contain diglyceride ciliatine, and a plasmalogen ciliatine was detected in the latter. 3. A ninhydrin-positive sphingolipid was isolated from rumen protozoa. Although chromatographically homogeneous on silica gel it contains two components, which were provisionally identified as ceramide ciliatine and ceramide phosphorylethanolamine. 4. A detailed phospholipid analysis of E. caudatum and rumen protozoa is presented. They contain no phosphatidylserine or cardiolipin, but an unidentified phosphoglyceride containing a zwitterionic amino acid is present.     

Development and validation of a real-time PCR method to quantify rumen protozoa and examination of variability between entodinium populations in sheep offered a hay-based diet

PCR and real-time PCR primers for the 18S rRNA gene of rumen protozoa (Entodinium and Dasytricha spp.) were designed, and their specificities were tested against a range of rumen microbes and protozoal groups. External standards were prepared from DNA extracts of a rumen matrix containing known numbers and species of protozoa. The efficiency of PCR (epsilon) was calculated following amplification of serial dilutions of each standard and was used to calculate the numbers of protozoa in each sample collected; serial dilutions of DNA were used similarly to calculate PCR efficiency. Species of Entodinium, the most prevalent of the rumen protozoa, were enumerated in rumen samples collected from 100 1-year-old merino wethers by microscopy and real-time PCR. Both the counts developed by the real-time PCR method and microscopic counts were accurate and repeatable, with a strong correlation between them (R2= 0.8), particularly when the PCR efficiency was close to optimal (i.e., two copies per cycle). The advantages and disadvantages of each procedure are discussed. Entodinium represented on average 98% of the total protozoa, and populations within the same sheep were relatively stable, but greater variation occurred between different sheep (10(0) and 10(6) entodinia per gram of rumen contents). With this inherent variability, it was estimated that, to detect a statistically significant (P = 0.05) 20% change in Entodinium populations, 52 sheep per treatment group would be required.     

The 3' untranslated region of messages in the rumen protozoan Entodinium caudatum

The 3' untranslated regions of a number of cDNAs from the rumen protozoal species Entodinium caudatum were studied with a view to characterising their preference for stop codons, general length, nucleotide composition and polyadenylation signals. Unlike a number of ciliates, Entodinium caudatum uses UAA as a stop codon, rather than as a codon for glutamine. In addition, the 3' untranslated region of the message is generally less than 100 nucleotides in length, extremely A+T rich, and does not appear to utilise any of the conventional polyadenylation signals described in other organisms.     

Two-step freezing procedure for cryopreservation of rumen ciliates,an effective tool for creation of a frozen rumen protozoa bank

The present study aimed at the long-term storage of rumen protozoa as living cells in liquid nitrogen. The two-step or interrupted slow freezing procedure was used to cryopreserve six of the dominant species of rumen ciliates isolated from monofaunated animals, Dasytricha ruminantium, Entodinium caudatum, Epidinium ecaudatum caudatum, Eudiplodinium maggii, Isotricha prostoma, and Polyplastron multivesiculatum. We optimized the first step in the interrupted slow freezing procedure, from the extracellular ice nucleation temperature to the holding temperature, and studied the effects of the cooling rates on survival. In addition to the nature of the cryoprotectant (dimethyl sulfoxide), the equilibration temperature and equilibration time (25 degrees C and 5 min, respectively), and the holding time at subzero temperature (45 min) recommended previously (S. Kisidayová, J. Microbiol. Methods 22:185-192, 1995), we found that a holding temperature of -30 degrees C, a cooling rate from extracellular ice nucleation temperature to holding temperature of between 1.2 degrees C/min and 2.5 degrees C/min, depending on the ciliate, and rumen juice as the freezing and thawing medium markedly improved the survival rate. Survival rates determined after 2 weeks in liquid nitrogen were 100% for Isotricha, 98% for Dasytricha, 85% for Epidinium, 79% for Polyplastron, 63% for Eudiplodinium, and 60% for Entodinium. They were not significantly modified after a period of 1 year in liquid nitrogen. Four of the five ciliate species cryopreserved for 8 months in liquid nitrogen successfully colonized the rumen when inoculated into defaunated animals. These results have made it possible to set up a bank of cryopreserved rumen protozoa.     

Effect of pH on viability of Entodinium caudatum, Entodinium exiguum, Epidinium caudatum, and Ophryoscolex purkynjei in vitro

Cultures of Entodinium caudatum, Entodinium exiguum, Epidinium caudatum, and Ophryoscolex purkynjei were grown and transferred in poorly buffered media prepared using different concentrations of sodium bicarbonate and a nitrogen gas phase. By transferring every 12 or 24 h, culture pH was gradually decreased until the protozoa disappeared. The cultures were transferred by placing half of the culture into an equal volume of fresh medium, resulting in pH fluctuations similar to those in the rumen, resulting from fermentation, eating, and saliva production. All four species appeared to maintain their concentrations around pH 5.8, but numbers decreased as pH values fell below 5.6. The four species were similar in that they all survived above pH 5.3. These results differ from previous reports in which Entodinium species appeared to be more tolerant to low pH than all other species of rumen ciliates. No adaptation to low pH was observed in Epidinium caudatum cultures after recovery from pH 5.4 medium containing only one or two viable cells.     

Preliminary study on the requirements of Entodinium exiguum and E. caudatum for live or dead bacteria when cultured in vitro

Whether live bacteria are required to culture the rumen protozoa Entodinium exiguum and E. caudatum in vitro was studied. Treatments were protozoa plus antibiotics (PA), PA plus autoclaved bacteria (PAB) or protozoa plus live bacteria (PLB). Generation times at 24 h were 22.8 and 31.0 h for E. exiguum and E. caudatum. Protozoal concentrations were unaffected by the absence of bacteria up to 48 h. After 72 h, E. exiguum, concentrations were higher in PLB than PA or PAB. With E. caudatum differences between PLB and PA were only observed at 96 h. Thus, a requirement for live bacteria appears to be manifested in culture periods longer than 48 (E. exiguum) and 72 (E. caudatum) h. Although differences between PLB and PAB indicate a metabolic dependence for bacteria or a long-term antibiotic effect, non-significant differences between PAB and PA suggest that the effect is also related to a nutritive bacterial contribution.     

Effect of nisin on two cultures of rumen ciliates

The effect of nisin (in the form of Nisaplin) was determined using two species of rumen ciliate protozoa in vitro, on their co-culture bacterial population, and volatile fatty acid concentration. Nisaplin did not affect the in vitro growth of Entodinium caudatum at concentrations of 50-400 mg/L during short-term treatment (5 d). Long-term application (30 d) of Nisaplin (100 mg/L) significantly decreased growth of the Epidinium ecaudatum forma caudatum et ecaudatum but not growth of E. caudatum. Nisaplin moderately supported the growth of E. caudatum after omission of wheat gluten (source of amino acids for protozoan growth). An inhibition of Gram-positive facultative anaerobic bacterial population in the protozoan cultures (lactobacilli, enterococci, staphylococci and amylolytic streptococci) was observed during long-term Nisaplin treatment. The concentration of volatile fatty acids significantly increased during the long-term Nisaplin treatment of both cultures. The propionate concentration in the mixture of volatile fatty acids was nearly twice higher on the account of the decreased concentration (from 74 to 63%) of acetate.     

Highly efficient galvanotaxis apparatus for cleaning and concentrating rumen ciliates

Galvanotaxis was shown to be an efficient method for cleaning and concentrating rumen ciliate protozoa whose harvesting (centrifugation of large volumes of in vitro cultures followed by repeated washing of the sediment to remove plant debris) is time consuming. We suggested the use of a new galvanotaxis apparatus (a small-capacity two-way glass stopcock) to improve cell yield in concentrating the rumen ciliate protozoa and cleaning them from impurities. Migration of the ciliates (Entodinium caudatum, Entodinium furca monolobum and Diploplastron affine) into the cathode compartment under different electric currents (0, 5, 10, and 15 mA) and intervals (5, 10, 20, and 30 min) was evaluated. The lethal current level was 20 mA. Cell yield was 9-81%, depending on ciliate species, migration time and current. The migration time significantly affected both E. caudatum and D. affine. The electric current-migration time interplay was shown to be significant in both E. caudatum and D. affine. The advantages and disadvantages of the tested apparatus were determined; the two-way glass stopcock was very convenient for both cleaning and concentrating rumen ciliate in vitro cultures by galvanotaxis.     

Why does the establishment of the starch preferring<Emphasis Type="Italic">Entodinium caudatum</Emphasis> in the rumen decrease the numbers of the fibrolytic ciliate<Emphasis Type="Italic">Eudiplodinium maggii</Emphasis>?

The effect of the establishment of Entodinium caudatum on the population of Eudiplodinium maggii was examined in the rumen of three sheep fed a hay/ground barley diet. The cell concentration of E. maggii were 15.9-38.5 and 11.7-12.4 x 10(3) cells per g of the rumen contents in the absence and presence of E. caudatum, respectively. Microscopic analysis showed that starch was the only material engulfed by eudiplodinia irrespective of the time after feeding and the presence or absence of E. caudatum. Up to 82-93% of individuals contained starch grains when E. maggii was the only ciliate species in the rumen; the proportion was 70-77% after entodinia had been established. The largest quantity of starch engulfed by E. maggii ciliates was 12.4-19.0 and 6.7-7.6 mg per 100 mg protozoal dry mass in the absence and presence of entodinia, respectively. No visible engulfment of hay was observed in vivo in spite of the fact that hay particles up to 42 microns in length were dominating in rumen fluid. Ingestion of fresh particles of hay separated from the rumen digesta was found when they were added in the proportion of 1 g per 40 mL suspension of ciliates. No preferential intake of starch was observed when E. maggii ciliates were incubated in vitro with a mixture of hay and barley starch. It is suggested that competition for starch between the two ciliate species was responsible for the drop in the numbers of E. maggii. This could result from a too low concentration of small particles of hay in the rumen fluid.     

The rate of uptake and metabolism of starch grains and cellulose particles by Entodinium species, Eudiplodinium maggii, some other entodiniomorphid protozoa and natural protozoal populations taken from the ovine rumen.

The rates of engulfment and breakdown of starch grains and cellulose particles and of the rate of synthesis of amylopectin from cellulose by individual species of entodiniomorphid protozoa (grown in vivo and in vitro) and incubated anaerobically in vitro were studied. Rates of starch uptake varied from 2.3 to 770 micrograms/mg protozoal protein/min; the lowest was found with Diploplastron affine and the highest with Entodinium spp. on initial incubation with starch grains. The rate of starch breakdown varied from 0.49 to 8.6 micrograms/mg protein/min; the rate was dependent on the initial starch concentration inside the protozoa. Eudiplodinium maggii engulfed cellulose particles more rapidly (2-7 times) than rice starch grains and digested the cellulose at rates of 10 to 16.5 micrograms/mg protein/min. In a mixture of starch grains and cellulose particles, it engulfed the latter at 1.35 to 25 times the rate of the former. Eudiplodinium maggii and Epidinium caudatum, but not Entodinium spp. or Dip. affine, synthesized an amylopectin-like material from cellulose at rates of 0.4 to 4.75 micrograms/mg protein/min. If these reactions occur in the rumen in vivo, up to 9 g of amylopectin could be synthesized from cellulose each day by the entodiniomorphid protozoa.     

Methanogenesis in rumen ciliate cultures ofEntodinium caudatum andEpidinium ecaudatum after long-term cultivation in a chemically defined medium

The methanogenic activity in the presence of Entodinium caudatum and Epidinium ecaudatum was well preserved after long-term cultivation. Microscopic observation revealed that methane production in the presence of E. caudatum was probably caused by their intracellular methanogenic activity, while methane production in the presence of E. ecaudatum f caudatum et ecaudatum could be attributed to both the methanogenic bacterial fraction of their external surface and their intracellular activity. Methane production per protozoan cell of E. caudatum and E. ecaudatum was 2.1 nmol per cell per d and 6.0 nmol per cell per d, respectively. E. caudatum was responsible for almost the entire methane production in the culture. The activity of free methanogens constituted approximately 50% of the total methane production in the E. ecaudatum culture. Decrease of digestibility of substrates and differences in the fermentation end products accompanied the inhibition of methanogenesis in both cultures by penicillin G, streptomycin, chloramphenicol, 2-bromoethanesulfonate, and pyromellitic diimide. E. caudatum appeared to be more sensitive than E. ecaudatum to the compounds tested. Hydrogen recoveries based on both volatile fatty acids and methane production suggested that the methanogenic population appeared not to be fully able to consume hydrogen produced in the protozoan cultures. The culture conditions tested were found to be suitable for experiments on the relationship between rumen ciliates and rumen bacteria.     

Rumen Ciliate Protozoa of the Blue Duiker (Cephalophus monticola), with Observations on Morphological Variation Lines Within the Species Entodinium dubardi

ABSTRACT. Protozoal concentrations were determined in rumen and cecal contents of 20 blue duikers ( Cephalophus monticola ). Ten animals of each sex were fed either a high concentrate or high roughage diet. Rumen protozoa were present in 19 of the 20 animals and concentrations ranged from 4.5 to 33.7 × 10⁶ per g of rumen contents. At the higher concentrations, protozoal cells equaled between 30–40% of the total rumen contents volume. No protozoa were found in cecal contents. Weight of rumen contents was higher in females than in males ( P < 0.01), and rumen protozoa concentrations were higher in males ( P < 0.05) and in those animals fed the high concentrate diet ( P < 0.05). All the protozoa were identified as belonging to a single species, Entodinium dubardi . However, an average of about 30% of the E. dubardi cells varied from the typical morphology of this species. These cells appeared to be on variation lines leading toward 7–10 other non-caudate species of Entodinium . The present data were used to evaluate and discuss the concept of variation lines within E. dubardi .     

The cultivation of the rumen ciliate Entodinium bursa in the presence of Entodinium caudatum.

The rumen ciliate protozoon Entodinium bursa has been grown in vitro in the presence of bacteria and Entodinium caudatum for over a year at population densities of 100 to 200 ml-1. The medium contained potassium phosphate, prepared fresh rumen fluid, cysteine, wholemeal flour (or rice starch), dried grass and a culture of the spineless form of Entodinium caudatum. Entodinium bursa has an obligate requirement for this protozoon and died within 48 h in its absence. During growth from a 2% inoculum, the mean generation time of E. bursa was 6 h. Entodinium bursa engulfed 1-5 to 2-5 E. caudatum organisms h-1, and when E. caudatum was in excess it developed caudal spines for the first time in 17 years; these spined forms were engulfed much less readily than the spineless organisms.