Association of rumen ciliate populations with plant particles in vitro

Seven known species of rumen ciliates and mixedEntodinium spp. showed association with plant particles in rumen fluid in vitro. Association was greater with fresh particles than with hay, and substantially decreased when the water-soluble components of the particles were removed, suggesting that the water-soluble components may be responsible for the association. The association was rapid and maximal between 5 and 35 min (depending on the ciliate species) after exposure to the particles, and involved major transfers of ciliate populations and biomass from the liquid phase to the solid phase of the system. The most rapid and largest population transfers to the particles from the rumen fluid were shown by the holotrich ciliates, where transfers of up to 97% of the population were recorded. Association with plant particles by all species examined occurred within the pH range 5.5–7.5, and decreased with time when the particles were incubated in rumen contents in vivo. The ciliate biomass transferring from the liquid to the solid phase varied with the composition of the ciliate population.     

Rumen Fungi and Forage Fiber Degradation

The role of anaerobic rumen fungi in in vitro forage fiber degradation was determined in a two forage × two inoculum source × five treatment factorial design. Forages used as substrates for rumen microorganisms were Coastal bermuda grass and alfalfa; inoculum sources were rumen fluid samples from a steer fed Coastal bermuda grass hay or alfalfa hay; treatments were whole rumen fluid (WRF), WRF plus streptomycin (0.2 mg/ml of rumen fluid) and penicillin (1.25 mg/ml of fluid), WRF plus cycloheximide (0.5 mg/ml of fluid), WRF plus streptomycin, penicillin, and cycloheximide, and McDougall buffer. Populations of fungi as shown by sporangial development were greater on bermuda grass leaves than on alfalfa leaflets regardless of inoculum source. However, endogenous fungal populations were greater from the alfalfa hay inoculum. Cycloheximide inhibited the fungi, whereas streptomycin and penicillin, which inhibit bacterial populations, resulted in an increase in numbers of sporangia in the alfalfa inoculum, suggesting an interaction between bacteria and fungi. Bacteria (i.e., WRF plus cycloheximide) were equal to the total population in degrading dry matter, neutral-detergent fiber (NDF), acid-detergent fiber (ADF), and cellulose for both inocula and both forages. Degradation of dry matter, NDF, ADF, and cellulose by anaerobic fungi (i.e., WRF plus streptomycin and penicillin) was less than that due to the total population or bacteria alone. However, NDF, ADF, and cellulose digestion was 1.3, 2.4, and 7.9 percentage units higher, respectively, for bermuda grass substrate with the alfalfa versus bermuda grass inoculum, suggesting a slight benefit by rumen fungi. No substantial loss of lignin (72% H₂SO₄ method) occurred due to fungal degradation. The most active fiber-digesting population in the rumen was the bacteria, even when streptomycin and penicillin treatment resulted in an increase in rumen fungi over untreated WRF. The development of large numbers of sporangia on fiber may not indicate a substantial role as digesters of forage.     

Detection and Capturing of <Superscript>14</Superscript>C Radioactively-Labeled Small Subunit rRNA from Mixed Microbial Communities of a Microbial Mat Using Magnetic Beads

Carbon cycling in the hypersaline microbial mats from Chiprana Lake, Spain is primarily dependent on phototrophic microorganisms with the ability to fix CO₂ into organics that can be further utilized by aerobic as well as anaerobic heterotrophic bacteria. Here, mat pieces were incubated in seawater amended with ¹⁴C sodium bicarbonate and the incorporation of the radiocarbon in the small subunit ribosomal RNA (SSU rRNA) of mat organisms was followed using scintillation counter and autoradiography. Different domains of SSU rRNA were separated from the total RNA by means of streptavidin-coated magnetic beads and biotin-labeled oligonucleotide probes. The ¹⁴C label was detected in isolated RNA by both scintillation counter and autoradiography, however the latter technique was less sensitive. Using scintillation counter, the radiolabel incorporation increased with time with a maximum rate of 0.18 Bq ng⁻¹ detected after 25 days. The bacterial SSU rRNA could be captured using the magnetic beads, however the hybridization efficiency was around 20%. The captured RNA was radioactively labeled, which could be mainly due to the fixation of radiocarbon by phototrophic organisms. In conclusion, the incubation of microbial mats in the presence of radiolabeled bicarbonate leads to the incorporation of the ¹⁴C label into RNA molecules through photosynthesis and this label can be detected using scintillation counter. The used approach could be useful in studying the fate of fixed carbon and its uptake by other microorganisms in complex microbial mats, particularly when species-specific probes are used and the hybridization efficiency and RNA yield are further optimized.     

Plasmalogens of microbial communities associated with barley straw and clover in the rumen

Abstract: Microbial plasmalogen aldehydes (detected as dimethyl acetals, DMA) have been used to compare microbial populations associated with clover and barley straw incubated in nylon mesh bags in the rumen of a cow. The results suggest that the populations involved in the digestion of these substrates differ substantially and that population changes occur as digestion proceeds: these conclusions were supported by electron-microscopic observations. Analysis of DMA suggested that populations associated with the particles of straw and clover differed more markedly than the corresponding populations in the liquid phase. When straw was pre-incubated with the rumen cellulolytic bacterium Ruminococcus flavefaciens strain 17, the DMA characteristic of this bacterium were present at increased levels during subsequent incubation of the straw in the rumen, though the R. flavefaciens DMA tended to contribute a smaller proportion of the total DMA as the incubation time in the rumen was increased from 24 to 72h.     

Effects of preservation procedures of rumen inoculum on in vitro microbial diversity and fermentation

Sheep rumen contents were used as inoculum for an in vitro semi-continuous incubation system to study whether preservation method affects microbial fermentation pattern. Rumen fluid was filtered and either used immediately as inoculum (CTL) or dispensed into 110 mm × 16 mm tubes, that were stored refrigerated at 6 °C for 4 h (REF) or frozen at ?20 °C (FRZ), frozen in liquid N (FLN) or added with 0.04 glycerol and frozen in liquid N (FGL) for 48 h. Frozen inocula were thawed at 39 °C for 2 min before use (16 ml per bottle). Two 24 h incubations with four bottles per treatment were completed. The microbial utilisation of added glycerol after thawing in FGL increased total gas production (P<0.05) and 24 h volatile fatty acid (VFA) production (P<0.05), and also increased propionate and butyrate proportions at the expense of acetate. The other freezing inocula (i.e., FLN and FRZ) reduced the rate of gas production (as ml/g dry matter per hour), compared with CTL in the first 2 and 4 h of incubation (P<0.05), but this was compensated by increased fermentation at 8 and 12 h, respectively. Differences in gas production did not manifest a different VFA pattern at either 6 or 24 h incubation. Bacterial diversity was slightly affected by the preservation process, and the similarity index between untreated inocula and the 24 h incubated CTL samples was 0.690–0.724. Similarity between bacterial communities in FRZ and FLN with that in CTL after incubation was 0.678. The freezing preservation method of rumen inocula for subsequent in vitro gas production studies does not affect microbial fermentation pattern or bacterial biodiversity, provided that processing is rapid enough by using a high surface to volume ratio. Freezing in liquid N is more appropriate than at ?20 °C.     

An in vitro evaluation of browser and grazer fermentation efficiency and microbiota using European moose spring and summer foods

Evolutionary morphological and physiological differences between browsers and grazers contribute to species‐specific digestion efficiency of food resources. Rumen microbial community structure of browsers is supposedly adapted to characteristic nutrient composition of the diet source. If this assumption is correct, domesticated ruminants, or grazers, are poor model animals for assessing the nutritional value of food consumed by browsing game species. In this study, typical spring and summer foods of the European moose (Alces alces) were combined with rumen fluid collected from both dairy cows (Bos taurus) and from moose, with the aim of comparing fermentation efficiency and microbial community composition. The nutritional value of the food resources was characterized by chemical analysis and advanced in vitro measurements. The study also addressed whether or not feed evaluation based on in vitro techniques with cattle rumen fluid as inoculum could be a practical alternative when evaluating the nutritional value of plants consumed by wild browsers. Our results suggest that the fermentation characteristics of moose spring and summer food are partly host‐specific and related to the contribution of the bacterial phyla Firmicutes and Bacteriodetes to the rumen microbial community. Host‐specific adaptations of the ruminal microbial community structure could be explained from the evolutionary adaptations related to feeding habitats and morphophysiological differences between browsers and grazers. However, the observed overall differences in microbial community structure could not be related to ruminal digestion parameters measured in vitro. The in vitro evaluation of digestion efficiency reveals that equal amounts of methane were produced across all feed samples regardless of whether the ruminal fluid was from moose or dairy cow. The results of this study suggested that the nutritional value of browsers' spring and summer food can be predicted using rumen fluid from domesticated grazers as inoculum in in vitro assessments of extent of digestion when excluding samples of the white water lily root, but not of fermentation characteristics as indicated by the proportions of individual fermentation fatty acids to the total of volatile fatty acids.     

Growth and Immunologic Studies on the Culture Forms of Trypanosoma lewisi*

SYNOPSIS. Culture forms of Trypanosoma lewisi grown at 27 C in a diphasic blood agar medium resemble in structure the stage found in the invertebrate host. Cultures inoculated with approximately 1 × 10⁶ trypanosomes/ml attain maximum populations of 2–7 × 10⁷ organisms/ml after 5–6 days of incubation. The stationary phase persists 6–15 days. The decline of the population is of relatively long duration with approximately 1 × 10⁶ viable organisms/ml present after 90 days. Variations in growth were attributed to the preparation of defibrinated heated rabbit blood incorporated into the culture medium. With inocula of 3.0 × 10⁵ trypanosomes/ml there was a lag in growth not observed with larger inocula. Trypanosomes incubated at elevated temperatures had altered growth curves compared to organisms at 27 C. Agitation of cultures did not affect the growth or stationary phases, but hastened the population decline. Heated and unheated 5% (v/v) normal rat serum incorporated in the liquid phase of the medium altered the growth of the organisms. Heated serum caused a decrease in the population and an extended lag phase. The effects on growth were more marked with unheated serum suggesting that both heat-stable and labile components affect growth. Antisera from rats injected with live culture forms included in the liquid phase inhibited, while antisera from rats 24 days after infection with the blood stream forms had no effect on the growth of the culture forms. Antisera from rabbits immunized with sonicates of culture forms also altered the growth of the organisms in culture. Rabbit antisera prepared by immunization with sonicates of dividing and non-dividing blood stream forms had no effect on the in vitro growth. Antisera from animals immunized with rat blood and culture medium were also without effect. The immunologic implications of the data are considered and discussed.     

Microbial colonisation of tannin-rich tropical plants: Interplay between degradability,methane production and tannin disappearance in the rumen

Condensed tannins in plants are found free and attached to protein and fibre but it is not known whether these fractions influence rumen degradation and microbial colonisation. This study explored the rumen degradation of tropical tannin-rich plants and the relationship between the disappearance of free and bound condensed tannin fractions and microbial communities colonising plant particles using in situ and in vitro experiments. Leaves from Calliandra calothyrsus, Gliricidia sepium, and Leucaena leucocephala, pods from Acacia nilotica and the leaves of two agricultural by-products: Manihot esculenta and Musa spp. were incubated in situ in the rumen of three dairy cows to determine their degradability for up to 96 h. Tannin disappearance was determined at 24 h of incubation, and adherent microbial communities were examined at 3 and 12 h of incubation using a metataxonomic approach. An in vitro approach was also used to assess the effects of these plants on rumen fermentation parameters. All plants contained more than 100 g/kg of condensed tannins with a large proportion (32–61%) bound to proteins. Calliandra calothyrsus had the highest concentration of condensed tannins at 361 g/kg, whereas Acacia nilotica was particularly rich in hydrolysable tannins (350 g/kg). Free condensed tannins from all plants completely disappeared after 24-h incubation in the rumen. Disappearance of protein-bound condensed tannins was variable with values ranging from 93% for Gliricidia sepium to 21% for Acacia nilotica. In contrast, fibre-bound condensed tannin disappearance averaged ～ 82% and did not vary between plants. Disappearance of bound fractions of condensed tannins was not associated with the degradability of plant fractions. The presence of tannins interfered with the microbial colonisation of plants. Each plant had distinct bacterial and archaeal communities after 3 and 12 h of incubation in the rumen and distinct protozoal communities at 3 h. Adherent communities in tannin-rich plants had a lower relative abundance of fibrolytic microbes, notably Fibrobacter spp. whereas, archaea diversity was reduced in high-tannin-containing Calliandra calothyrsus and Acacia nilotica at 12 h of incubation. Concurrently, in vitro methane production was lower for Calliandra calothyrsus, Acacia nilotica and Leucaena leucocephala although for the latter total volatile fatty acids production was not affected and was similar to control. Here, we show that the total amount of hydrolysable and condensed tannins contained in a plant govern the interaction with rumen microbes affecting degradability and fermentation. The effect of protein- and fibre-bound condensed tannins on degradability is less important.     

Investigation on the “In vitro” degradation of zearalenone in rumen fluid

Ruminal zearalenone (ZEA) degradation in “in vitro” digestion was examined in different variants using the Hohenheimer Gas Test. First, the mycotoxin degradation was measured using squeezed rumen fluid from solid digesta of the dorsal sack and free rumen fluid from the ventral sack, respectively. Then free rumen, fluid of the ventral sac was used with addition of concentrate and mixtures of concentrate with sun-flower oil and starch, respectively. Within 24 hours ZEA was degraded down to 63% and 49% of the initial concentration when incubated with solid and fluid rumen digesta, respectively. Using additives and rumen fluid concentrate for incubation, concentrate, concentrate with oil and concentrate with starch, respectively, a reduction of ZEA to 46, 56 and 37% of the initial toxin concentration was observed. Presented at the 26^th Mykotoxin-Workshop in Herrsching, Germany, May 17–19 2004 Financial support: German Academic Exchange Service (approval of a grant) and Famy Foundation     

Grass cells ingested by ruminants undergo autolysis which differs from senescence: implications for grass breeding targets and livestock production

It is widely believed that the initial degradation of proteins contained in grazed forage is mediated by rumen micro‐organisms, but the authors’ recent work suggests that the plant cells themselves contribute to their own demise. In the present study the responses of Lolium perenne leaves to the rumen environment were investigated by using an in vitro system which simulates the main stresses of the rumen but from which rumen micro‐organisms were excluded. Degradation of leaf protein and the accumulation of amino acids in tissue and bathing medium occurred over a time‐scale that is relevant to rumen function, and in a near 1 : 1 ratio. Significant loss of nuclear material was observed after 6 h incubation and chloroplasts became morphologically more spherical as the incubation progressed. In situ localization suggested that ribulose 1,5 bisphosphate carboxylase/oxygenase was broken down within chloroplasts which from cytology were judged to be intact. We conclude from these data that plant metabolism may play a significant role in breaking down plant proteins within relatively intact organelles in the rumen. The determinations of chlorophyll content and cell viability revealed that the plant processes occurring in the simulated rumen were similar but not identical to those of natural senescence.     

Biosynthesis of Threonine from Homoserine by Mixed Rumen Microorganisms: An In Vitro Study

The biosynthesis of threonine (Thr) by using the main biosynthetic pathway involving homoserine (Hser) was quantitatively investigated by mixed rumen bacteria (B), protozoa (P), and their mixture (BP) in an in vitro system. Rumen contents were collected from fistulated goats to prepare the microbial suspensions and were incubated anaerobically at 39°C for 12 h with or without Hser (2 mm) as a substrate. Thr and other related compounds produced in both the supernatants and hydrolysates of the incubation were analyzed by HPLC. During a 12-h incubation period, 84.2%, 58.1%, and 92.0% of Hser disappeared in B, P, and BP suspensions, respectively. Rumen bacteria and the mixture of rumen bacteria and protozoa were demonstrated for the first time to produce Thr from Hser, and the production of Thr from Hser in BP (371.9 and 297.2 μmol/g MN) (MN, microbial nitrogen) was about 13.0% and 9.1% higher than that in B alone (329.2 and 272.5 μmol/g MN) during 6- and 12-h incubations, respectively. On the other hand, mixed rumen protozoa were unable to synthesize Thr from Hser. Other metabolites produced from Hser were found to be glycine (Gly) and 2-aminobutyric acid (2AB) in B and BP. In P, Gly and 2AB were not found. The results mentioned above indicated the abilities of rumen bacteria and the mixture of rumen bacteria and protozoa to synthesize Thr de novo from Hser and appeared as first-time report. Received: 24 May 2000/Accepted: 4 August 2000     

In vitro method for determining the ruminal degradation rate of rapeseed meal protein using N isotope labelled ammonia nitrogen

An in vitro method based on observations of ¹⁴N and ¹⁵N isotope fluxes between ammonia N and non-ammonia (NAN) pools was established to study the ruminal degradation rate of rapeseed meal protein. Feed protein equal to 125 mg of N/l was incubated in the presence of rumen fluid, mineral buffer, and a carbohydrate mixture formulated to provide a constant supply of fermentable energy over the entire incubation period. The ammonia N was labelled with the ¹⁵N isotope, and the incubations were carried out for 0, 0.5, 1, 1.5, 2, 3, 4, 5, 6, 8, and 10 h. A model with six pools was used to estimate the rate of protein degradation to ammonia N and the rate of microbial N synthesis from ammonia N. The parameter values were adjusted based on the sizes of the ammonia ¹⁴N, ammonia ¹⁵N, ¹⁴NAN, and ¹⁵NAN pools observed at different time points over the incubation period. The rate of rapeseed meal N degradation was 0.06/h (0.028 standard deviation between runs), and the predicted effective protein degradability was 0.38 (0.122 standard deviation between runs). The current approach seemed appropriate for determining microbial N synthesis from ammonia N, but measurement of the direct incorporation of amino acids into microbial N may be required to adequately characterize the metabolic events involved in ruminal protein degradation.     

Effects of monolaurin on ruminal methanogens and selected bacterial species from cattle, as determined with the rumen simulation technique

Before being able to implement effective ruminal methane mitigation strategies via feed supplementation, the assessment of side effects on ruminal fermentation and rumen microbial populations is indispensable. In this respect we investigated the effects of monolaurin, a methane-mitigating lipid, on methanogens and important carbohydrate-degrading bacteria present in ruminal fluid of dairy cattle in continuous culture employing the rumen simulation technique. In six experimental runs, each lasting for 10 days, four diets with different carbohydrate composition, based on hay, maize, wheat and a maize-wheat mixture, either remained non-supplemented or were supplemented with monolaurin and incubated in a ruminal-fluid buffer mixture. Incubation liquid samples from days 6 to 10 of incubation were analyzed with relative quantitative polymerase chain reaction (qPCR) of 16S rRNA genes to assess monolaurin-induced shifts in specific rumen microbial populations in relation to the corresponding non-supplemented diets. Monolaurin completely inhibited Fibrobacter succinogenes in all diets while the response of the other cellulolytic bacteria varied in dependence of the diet. Megasphaera elsdenii remained unaffected by monolaurin in the two diets containing maize, but was slightly stimulated by monolaurin with the wheat and largely with the hay diet. The supply of monolaurin suppressed Methanomicrobiales below the detection limit with all diets, whereas relative 16S rRNA gene copy numbers of Methanobacteriales increased by 7-fold with monolaurin in case of the hay diet. Total Archaea were decreased by up to over 90%, but this was significant only for the wheat containing diets. Thus, monolaurin exerted variable effects mediated by unknown mechanisms on important ruminal microbes involved in carbohydrate degradation, along with its suppression of methane formation. The applicability of monolaurin for methane mitigation in ruminants thus depends on the extent to which adverse effects on carbohydrate-degrading bacteria actually impair the supply of digested carbohydrates to the animal.     

In Vitro Catabolism of Histidine by Mixed Rumen Bacteriaand Protozoa

An in vitro study was conducted to examine the metabolism of histidine (His) by mixed rumen bacteria (B), mixed rumen protozoa (P), and a combination of the two (BP). Rumen microorganisms were collected from fistulated goats fed with lucerne cubes (Medicago sativa) and a concentrate mixture twice a day. Microbial suspensions were anaerobically incubated with or without 2 mm each of His, or histamine (HTM), or 1 mm urocanic acid (URA) at 39°C for 12 h. His and other related compounds in both supernatant and microbial hydrolysates were analyzed by HPLC. After 6- and 12-h incubations, the net degradation of His was 26.1% and 51.7% in B, 13.5% and 20.9% in P, and 21.7% and 46.0% in BP, respectively. The rate of the net degradation of His in B (98.0 μmol/g microbial nitrogen/h) was about 2.6 times higher than that of P during a 12-h incubation period. His was found to be degraded into urocanic acid (URA), imidazolelactic acid (ImLA), imidazoleacetic acid (ImAA), and histamine (HTM). Of these degraded His was mainly converted into URA in all microbial suspensions. The production of ImLA and ImAA was higher in B than in P suspensions, whereas the production of HTM was higher in P than in B suspensions. From these results, the existence of diverse catabolic routes of His in rumen microorganisms was indicated. Received: 23 May 2000 / Accepted: 31 July 2000     

The ability of the rumen protozoan <Emphasis Type="Italic">Eudiplodinium maggii</Emphasis> to utilize chitin

The ability was determined of the rumen ciliate Eudiplodinium maggii to utilize chitin from fungal cell wall. Cultivation experiments shoved that the population concentration (number of ciliates in vitro) was positively correlated with chitin doses. Cell extract prepared from the bacteria-free ciliates degraded colloidal chitin releasing 2.0 μmol reducing sugar per mg protein per h. End products of this reaction were chitotriose and N-acetylglucosamine. Incubation of the bacteria-free ciliates with chitin resulted in an increase in the concentration of acetic, propionic and butyric acids in the incubation medium. The production rate of total volatile fatty acids (VFA) by ciliates incubated with and without chitin was 45.0 and 30.5 pmol VFA per protozoan, respectively, the molar proportion of particular acids remaining unchanged.     

The effect of rumen ciliates on chitinolytic activity,chitin content and the number of fungal zoospores in the rumen fluid of sheep

The objective of this study was to investigate the effect of selected protozoa on the degradation and concentration of chitin and the numbers of fungal zoospores in the rumen fluid of sheep. Three adult ewes were fed a hay-concentrate diet, defaunated, then monofaunated with Entodinium caudatum or Diploplastron affine alone and refaunated with natural rumen fauna. The average density of the protozoa population varied from 6.1 · 10⁴ (D. affine) to 42.2 · 10⁴ cells/ml rumen fluid (natural rumen fauna). The inoculation of protozoa in the rumen of defaunated sheep increased the total activity of chitinolytic enzymes from 2.9 to 3.6 μmol N-acetylglucosamine/g dry matter (DM) of rumen fluid per min, the chitin concentration from 6.3 to 7.2 mg/g DM of rumen fluid and the number of fungal zoospores from 8.1 to 10.9 · 10⁵ cells/ml rumen fluid. All examined indices showed diurnal variations. Ciliate population density was highest immediately prior to feeding and lowest at 4 h thereafter. The opposite effects were observed for the numbers of fungal zoospores, the chitin concentration and chitinolytic activity. Furthermore, it was found that chitin from zoospores may account for up to 95% of total microbial chitin in the rumen fluid of sheep. In summary, the examined ciliate species showed the ability of chitin degradation as well as a positive influence on the development of the ruminal fungal population.     

In situ analysis of oxygen consumption and diffusive transport in high‐temperature acidic iron‐oxide microbial mats

The role of dissolved oxygen as a principal electron acceptor for microbial metabolism was investigated within Fe(III)‐oxide microbial mats that form in acidic geothermal springs of Yellowstone National Park (USA). Specific goals of the study were to measure and model dissolved oxygen profiles within high‐temperature (65–75°C) acidic (pH = 2.7–3.8) Fe(III)‐oxide microbial mats, and correlate the abundance of aerobic, iron‐oxidizing Metallosphaera yellowstonensis organisms and mRNA gene expression levels to Fe(II)‐oxidizing habitats shown to consume oxygen. In situ oxygen microprofiles were obtained perpendicular to the direction of convective flow across the aqueous phase/Fe(III)‐oxide microbial mat interface using oxygen microsensors. Dissolved oxygen concentrations dropped from ～ 50–60 μM in the bulk‐fluid/mat surface to below detection (< 0.3 μM) at a depth of ～ 700 μm (～ 10% of the total mat depth). Net areal oxygen fluxes into the microbial mats were estimated to range from 1.4–1.6 × 10^?4 μmol cm^?2 s^?1. Dimensionless parameters were used to model dissolved oxygen profiles and establish that mass transfer rates limit the oxygen consumption. A zone of higher dissolved oxygen at the mat surface promotes Fe(III)‐oxide biomineralization, which was supported using molecular analysis of Metallosphaera yellowstonensis 16S rRNA gene copy numbers and mRNA expression of haem Cu oxidases (FoxA) associated with Fe(II)‐oxidation.     

Temperature-dependent differences in community structure of bacteria involved in degradation of petroleum hydrocarbons under sulfate-reducing conditions

Aim: The aim of this study was to characterize the microbial community involved in anaerobic degradation of petroleum hydrocarbon under low‐ and moderate‐temperature conditions. Methods and Results: Sulfate‐reducing enrichment cultures growing on crude oil and p‐xylene were established at low and moderate temperatures. Bacterial community structures of the cultures were characterized by 16S rRNA gene‐based analysis and organisms responsible for degradation of p‐xylene were investigated by analysis of the bamA gene, involved in anaerobic degradation of aromatic compounds. The PCR‐denaturing gradient gel electrophoresis analysis indicated significant differences in microbial community structures among the cultures, depending on the temperatures of incubation. Difference depending on the temperatures was also observed in the cloning analysis of the bamA gene performed on the p‐xylene‐degrading enrichment cultures. Majority of clones detected in the culture of moderate temperature were related to Desulfosarcina ovata, whereas more diverse bamA gene sequences were obtained from the culture incubated at low temperature. Conclusions: Temperature‐dependent differences in microbial community were demonstrated by the analyses of two genes. It was suggested that sulfate‐reducing bacteria of phylogenetically different groups might be involved in the degradation of petroleum hydrocarbons in different temperature environments. Significance and Impact of the Study: This study is the first report of p‐xylene‐degrading sulfate‐reducing enrichment culture at low temperature. The results of the experiments at low temperature were distinctly different from those reported in previous studies performed at moderate temperatures.     

Ruminal degradability of 15N labelled ribonucleic acid in grass

The ruminal degradation of RNA in rye grass (Lolium perenne) was studied using the bag method. A non-lactating cow (BW 550?kg) fitted with a rumen cannula was used and fed twice daily at maintenance level with a chopped grass hay-based ration containing 30% ground barley. Rye grass, labelled during growth by fertilization with ¹⁵N₂-urea (9.5 atom% ¹⁵N, 20?g N/m²), was cut at seven stages of growth and maturity and freeze-dried. RNA-N represented 6 to 17% of total N. Labelled grass samples (milled to 5.0?mm screen, 5.0?±?0.1?g DM) were incubated in polyester bags (100?×?200?mm, pore size 50?μm) in the rumen for periods of 1, 3, 6, 9, 12, 24, and 48?h. Data of N and RNA disappearances from the bags were fitted to an exponential equation to estimate parameters of degradation. The effective degradability of RNA in the rumen averaged 90?±?4%, for N it was 11% units lower (P?R ²?=?0.92). Degradability of RNA (R ²?=?0.96) and N (R ²?=?0.93) decreased with increasing fibre content of grass. Increasing the fibre content by 1% diminished the degradability of RNA and N by 1.1% units and 2.4% units, respectively (P????1, a model calculation indicates that about 9 to 19% of duodenal RNA are of dietary origin in animals fed grass. This should be taken into account for the calculation of microbial N on the basis of RNA as marker.     

Influence of natural magnesium sources on the in vitro fermentation and protozoan population in the rumen fluid collected from sheep

The objective of this experiment was to determine the effect of two types of caustic calcinated magnesite (caustic magnesite (CM) and Agromag (AG)) upon the end products of in vitro fermentation (total gas, methane, total and individual fatty acids, and VFA) and protozoan population in the rumen fluid collected from sheep. Both magnesium additives (CM and AG) as natural products in the dose of 0.01 g were added to the fermentation bottles containing rumen inoculum from sheep and different substrates. Meadow hay (MH), wheat straw (WS), amorphous cellulose (AC) and barley grain (BG) were used as substrates and incubated with the buffered rumen fluid using an in vitro gas measuring technique during 72 h of incubation. The rumen protozoa, Entodinium spp., Trichostomatids and large Entodiniomorphids and the total protozoan concentration were counted after 24 h of incubation. The methane production was significantly decreased with CM or AG, respectively, by 58 or 62% (MH), by 65% (WS), by 52% (AC) and by 58% (BG). The total VFA concentration was significantly lower compared to control for CM plus MH, WS, AC, BG and AG plus WS. The total VFA concentration was significantly higher compared to control for AG plus AC. The effect of the both additives on ciliate population was not uniform and depended on the substrates used and protozoan type. Ciliate population was significantly increased in Entodinium spp. (AG plus BG) and Diploplastron affinae (CM or AG plus BG) compared to control. Tested additives significantly decreased population of Entodinium spp. (AG plus MH or AC), Dasytricha ruminantium (AG plus AC), Ophryoscolex c. tricoronatus, Eremoplastron dilobum and Polyplastron multivesiculatum (CM or AG plus BG). It can be concluded that both natural magnesium sources influenced rumen fermentation patterns and protozoan population in vitro depending on the type of the substrate used; therefore, the relative efficacy of individual tested additive cannot be determined from these experiments. In vivo experiments are required in future.