The uptake and metabolism of bacteria, amino acids, glucose and starch by the spined and spineless forms of the rumen ciliate Entodinium caudatum

Spined and spineless forms of Entodinium caudatum were obtained by growth in vivo in the presence and absence, respectively, of Entodinium bursa. Washed suspensions of both forms engulfed all the bacteria tested although the spined form took them up 1.3 to 1.9 times more rapidly per unit volume of protozoon than did the spineless form. Buytrivibrio fibrisolvens and Selenomonas ruminantium were rapidly digested by the spined form after engulfment. Free amino acids were taken up on average 3.1 times and glucose approximately 60 times faster per unit volume of protozoon by the spined form. Limited amounts of protein were synthesized by the spined form from glucose and starch but engulfed bacteria and, to a lesser extent, free amino acids were probably the prinicpal sources of protein for growth of both forms.     

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.     

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.     

Growth Factors of Bacterial Origin for the Culture of the Rumen Oligotrich Protozoon, Entodinium caudatum

Attempts were made to develop an artificial medium suitable for axenic culture of Entodinium caudatum. Agnotobiotic cultures of the protozoon were established as stock cultures for testing the suitability of various growth media. A cell-free extract of mixed bacteria isolated from the rumen was shown to contain one or more growth factors for the protozoon when supplied with activated charcoal as a carrier. The medium (CYSE medium), which supported the growth of the protozoon in the presence of 50 μg/ml each of penicillin and chloramphenicol, consisted of activated charcoal (20 mg), heat-treated yeast (Y) (80 mg), 13%β-sitosterol-coated rice starch (S) (120 mg), and cell-free extract of rumen bacteria (1 ml) in 40 ml buffer solution. When culturing the protozoon, the CYSE medium was supplemented daily with 20 mg each of Y and S and half of the medium was replaced with fresh medium once every 5 d. The possible use of this method to establish an axenic culture of E. caudatum is discussed.     

Electron microscopy of the rumen ciliate Entodinium caudatum, with special reference to the engulfment of bacteria and other particulate matter

A study in the electron microscope of thin sections of the rumen ciliate Entodinium caudatum was undertaken in an attempt to elucidate the mode of engulfment of particulate matter. This protozoon engulfed bacteria, polystyrene latex particles and olive oil into membrane-lined vesicles in the protozoal endoplasm. Particles of palladium black were also taken up into the endoplasm, but due to the toxic nature of this material it was not possible to demonstrate vesicle formation with certainty. The initial uptake of bacteria may be into large sacs containing many organisms which were subsequently taken into the endoplasm in vesicles that contained only one bacterium each. The evidence obtained in this investigation has been used to distinguish between two different mechanisms for the digestion of bacteria and utilization of the amino acids from the bacterial protein for the synthesis of protozoal protein.     

Phospholipid biosynthesis in the anaerobic protozoon Entodinium caudatum.

1. The anaerobic rumen protozoon Entodinium caudatum was incubated either intact or with various radioactive precursors of phospholipids after ultrasonication. 2. Pulse-chase experiments showed a rapid turnover of phosphatidylinositol and much slower turnovers of phosphatidylethanolamine and phosphatidylcholine. 3. E. caudatum imbibed choline very rapidly; this was immediately and exclusively converted into phosphatidylcholine which was shown by radioautography after 10 min to be distributed throughout the cell membranes. 4. Phosphatidylcholine was synthesized through a phosphorylcholine-CDP-choline pathway, the methylation or base-exchange pathways not being present. 5. Under suitable conditions [Me-14C]choline can be substantially (50-60%) converted into CDP-choline by sonicated E. caudatum and this provides an excellent method of preparing this biosynthetic intermediary. 6. [2-14C]Ethanolamine was taken up much less readily than choline. The former was incorporated into phosphatidylethanolamine by the CDP-ethanolamine pathway. 7. Doubly labelled [32P]phosphatidyl[2-3H]ethanolamine was converted into ceramide phosphorylethanolamine and N-(1-carboxyethyl)phosphatidyl-ethanolamine, without change in the isotopic ratio. Ceramide phosphoryl [2-14C]-ethanolamine was converted into phsophatidylethanolamine. 8. Palmitic acid, oleic acid and linoleic acid were taken by E. caudatum cells and incorporated into phospholipids. By contrast, although stearic acid was taken up it was hardly incorporated into phospholipids.     

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.     

In vitro determination of generation times for Entodinium exiguum, Ophryoscolex purkynjei and Eudiplodinium maggii

ABSTRACT. Most previously reported generation times for rumen ciliate protozoa are longer than would be required to prevent their being flushed out of the rumen. In an earlier study from this lab, using a sequential transfer procedure, generation times between 12 and 13 h were determined for both Epidinium caudatum and Entodinium caudatum . This would permit these species to be maintained in a rumen with a fluid volume turnover rate as rapid as twice a day. In this study, generation times were estimated for Entodinium exiguum (13.2 h), Eudiplodinium maggii (26.8 h), and Ophryoscolex purkynjei (29 h), by sequential transfer at both 12 and 24 h time periods. The generation time for E. exiguum is lower than reported for this and other Entodinium species as determined by logarithmic growth from a small inoculum, but similar to that obtained for Ent. caudatum using sequential transfer. Eudiplodinium maggii and O. purkynjei generation times are similar to previous estimates of 24- and 24–48 h, respectively. However, it was observed that after an adaptation period of 36 to 48 h (generally 3–4 transfers) cell concentrations decreased and generation times were markedly decreased, i.e. 12.2 h for Ent. exiguum , 15.0 h for E. maggii and 12.8 h for O. purkynjei . In a separate study, varying both the concentration of Epidinium and the quantity of substrate fed per cell had no effect on generation time.     

A cryopreservation procedure for the rumen protozoon Entodinium caudatum: estimation of its viability by fluorescence microscopy

AIMS: To study the viability of a culture of the rumen protozoon Entodinium caudatum after a cryopreservation procedure by a fluorescence microscopy staining method. METHODS AND RESULTS: Fluorescence method is based on the different colour of cells depending on their membrane integrity. When the temperature effect was studied either by fluorescence or motility, the techniques were correlated (r = 0.727) and their slopes and intercepts were not different (P > 0.05). However, motility showed a higher variation coefficient (0.40 vs 0.12). There were no differences between cooling rates at cryopreservation (1 and 4 degrees C min-1) at 38, 15 or 5 degrees C, nor after thawing. CONCLUSIONS: Fluorescence staining is more accurate than motility for assessing protozoal viability. Viability after thawing was 0.50, and the number of viable cells per 250 microl straw was 320 and 420 for 1 and 4 degrees C min-1. SIGNIFICANCE AND IMPACT OF THE STUDY: This cryopreservation procedure seems to ensure culture recovery for E. caudatum.     

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.     

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.     

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.     

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.     

The metabolism of starch, glucose, amino acids, purines, pyrimidines and bacteria by the rumen ciliate Polyplastron multivesiculatum.

The large rumen ciliate protozoon Polyplastron multivesiculatum grown in vitro engulfed a wide range of bacteria (from a population density of 10(9) bacteria ml(-1)) at a rate of 1500 to 137000 bacteria h(-1) protozoon(-1). No evidence was found for the preferential engulfment of bacteria of rumen origin. Except for Proteus mirabilis none of the bacteria were digested with the liberation of soluble materials into the medium. Glucose and amino acids were taken up rapidly by P. multivesiculatum compared with the rate of uptake by Entodinium caudatam. Glucose was incorporated into protozoal polysaccharide and into bacteria associated with the protozoa and was used for the synthesis of a wide range of amino acids. Evidence showed that bacteria and free amino acids at the concentrations found in the rumen could supply the protein requirements of the protozoa for division at least once each day.     

The catabolism of phosphatidylethanolamine by the rumen protozoon Entodinium caudatum and its conversion into the N-(1-carboxyethyl) derivative

1. The N-(2-hydroxyethyl)alanine esterified to phosphatidic acid in anaerobic ciliate rumen protozoa has the l configuration. 2. Labelling experiments with Entodinium caudatum cultures using [(32)P]P(i) [2-(14)C]ethanolamine and (32)P- and (14)C-labelled phosphatidylethanolamine show that phosphatidylethanolamine is the direct lipid precursor of the N-(2-hydroxyethyl)alanine-containing phospholipid. 3. Labelling experiments with [(14)C]starch, [(14)C]lactate and [(14)C]pyruvate with E. caudatum cultures indicate that a three-carbon glycolytic intermediate is probably the precursor of the N-(1-carboxyethyl) grouping which substitutes on the amino group of phosphatidylethanolamine. 4. [(32)P]phosphatidylethanolamine is catabolized by E. caudatum forming initially glycerylphosphorylethanolamine and subsequently glycerophosphate and P(i). A little phosphorylethanolamine formed may possibly arise from bacterial enzymes ingested by the protozoa.     

An NAD(+)-dependent glutamate dehydrogenase cloned from the ruminal ciliate protozoan, Entodinium caudatum

An NAD(+)-dependent glutamate dehydrogenase (GDH; EC 1.4.1.24) was cloned from the ruminal ciliate protozoan, Entodinium caudatum. The gene had high sequence similarity to GDH genes from the Bacteroides (class)--a class of bacteria which is highly represented in the rumen. When expressed in Escherichia coli the enzyme had a high affinity for ammonia and alpha-ketoglutarate (apparent K(m) of 2.33 and 0.71 mM, respectively) and a low affinity for glutamate (apparent K(m) of 98 mM). GDH activity and GDH mRNA concentration were increased by incubating washed E. caudatum cells with ammonia and antibiotics. These results suggest that the GDH is an anabolic enzyme catalysing the assimilation of ammonia by E. caudatum in the rumen and that the gene was probably acquired by lateral gene transfer from a ruminal bacterium.     

The Uptake and Utilization of Bacteria, Amino Acids and Carbohydrate by the Rumen Ciliate Entodinium longinucleatum in Relation to the Sources of Amino Acids for Protein Synthesis

Entodinium longinucleatum grown in vitro in the presence of bacteria engulfed a wide range of bacterial species at rates of 130–3400 bacteria/h/protozoon (from suspensions of 10 bacteria/ml), but showed a preference for Klebsiella aerogenes and Proteus mirabilis which occurred in the growth medium. Some of the bacteria were digested with release of soluble material into the medium. Free amino acids were incorporated by the protozoa in the presence of chloramphenicol at rates of 5·4–15·1 nmol/h/10⁶ protozoa and approximately 40% of the amino acid-carbon was incorporated into protein. There was no appreciable synthesis of protozoal protein from carbohydrate. Evidence was obtained that the protozoa obtained the amino acids required for growth largely from engulfed bacteria.     

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 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.     

Phylogeny of the Rumen Ciliates Entodinium, Epidinium and Polyplastron (Litostomatea: Entodiniomorphida) Inferred from Small Subunit Ribosomal RNA Sequences

ABSTRACT. Three complete 18S ribosomal RNA gene sequences from the rumen ciliates, Entodinium coudatum (1,639 bp), Epidinium caudarum (1,638 bp), and Polyplastron multivesiculatum (1,640 bp) were determined and confrimed in the opposite direction. Trees produced using maximum parsimony and distance-matrix methods (lest squares and neighbour-joining). with strong bootstrap support, depict the rumen ciliates as a monophyletic group, Entodinium caudatum is the earliest branching rumen ciliate. However, Entodiniwn simplex does not pair with En. caudatum , but rather with Polyplastron multivesiculatum. Signature sequences for these rumen ciliates reveal that the published SSrRNA gene sequence from En. simplex is in fact a Polyoplastron species. The free-living haptorian ciliates, Loxophyllum, Homalozoon and Spathidium (Subclass Hoptoria), are monophyletic and are the sister group to the rumen cilates. The litostomes (class Litostomatea), consisting of the haptorians and the rumen ciliates, are also a monophyletic group.