Effects of Plant Extracts on Microbial Population, Methane Emission and Ruminal Fermentation Characteristics in In vitro
Article information
Abstract
This study was conducted to evaluate effects of plant extracts on methanogenesis and rumen microbial diversity in in vitro. Plant extracts (Artemisia princeps var. Orientalis; Wormwood, Allium sativum for. Pekinense; Garlic, Allium cepa; Onion, Zingiber officinale; Ginger, Citrus unshiu; Mandarin orange, Lonicera japonica; Honeysuckle) were obtained from the Plant Extract Bank at Korea Research Institute of Bioscience and Biotechnology. The rumen fluid was collected before morning feeding from a fistulated Holstein cow fed timothy and commercial concentrate (TDN; 73.5%, crude protein; 19%, crude fat; 3%, crude fiber; 12%, crude ash; 10%, Ca; 0.8%, P; 1.2%) in the ratio of 3 to 2. The 30 ml of mixture, comprising McDougall buffer and rumen liquor in the ratio of 4 to 1, was dispensed anaerobically into serum bottles containing 0.3 g of timothy substrate and plant extracts (1% of total volume, respectively) filled with O2-free N2 gas and capped with a rubber stopper. The serum bottles were held in a shaking incubator at 39°C for 24 h. Total gas production in all plant extracts was higher (p<0.05) than that of the control, and total gas production of ginger extract was highest (p<0.05). The methane emission was highest (p<0.05) at control, but lowest (p<0.05) at garlic extract which was reduced to about 20% of methane emission (40.2 vs 32.5 ml/g DM). Other plant extracts also resulted in a decrease in methane emissions (wormwood; 8%, onion; 16%, ginger; 16.7%, mandarin orange; 12%, honeysuckle; 12.2%). Total VFAs concentration and pH were not influenced by the addition of plant extracts. Acetate to propionate ratios from garlic and ginger extracts addition samples were lower (p<0.05, 3.36 and 3.38 vs 3.53) than that of the control. Real-time PCR indicted that the ciliate-associated methanogen population in all added plant extracts decreased more than that of the control, while the fibrolytic bacteria population increased. In particular, the F. succinogens community in added wormwood, garlic, mandarin orange and honeysuckle extracts increased more than that of the others. The addition of onion extract increased R. albus diversity, while other extracts did not influence the R. albus community. The R. flavefaciens population in added wormwood and garlic extracts decreased, while other extracts increased its abundance compared to the control. In conclusion, the results indicated that the plant extracts used in the experiment could be promising feed additives to decrease methane gas emission from ruminant animals while improving ruminal fermentation.
INTRODUCTION
Global warming, which results in an increase in the earth’s atmospheric temperature, is purported to cause climate change leading to the exacerbation of extreme weather events and the frequency of their occurrence. The increase of greenhouse gases in the atmosphere, in particular methane, has been the focus of a study in global warming (IPPC, 2007), as its contribution is 23 times more potent than carbon dioxide. It was estimated that livestock produced 18% of all global greenhouse gas emission, greater than all forms of transportation combined. Through their unique digestive process, ruminants emit methane during enteric fermentation and account for approximately 15% of total methane emission (Takahashi et al., 2005). In addition, methane emission represents a loss of carbon sources from the rumen, leading to an unproductive use of dietary energy, and results in the substantial loss of up to 12% of the dietary energy intake (Johnson et al., 1995). Various approaches, such as selection of rumen micro-organisms through the elimination of protozoa, the inoculation of exogenous bacterial strains and vaccination against methanogenic micro-organisms, have been studied with the aim of reducing methane emission of digestive origin. Plant extracts as new feed additives have led to the interest in new, safe and inexpensive ways to reduce methane emission from ruminants. Many plant extracts included tannin and saponin have been studied as possible modifiers of rumen fermentation in order to decrease methanogenesis (Patra et al., 2010). In previous laboratory studies, different plants and additives were extracted with various solvents (methanol, ethanol and boiling water), and the effect on methane emission and ruminal fermentation in in vitro was observed. Patra et al. (2010) suggested that in vitro fermentation might be affected by the dosage of extract as well as the extract solvents. Plants belonging to Compositate and Liliaceae families had a large influence in decreasing methane emission in a previous study.
The objectives of this study were to screen effects of representative plant extracts with known antioxidant properties, as sources of anti-microbial activity for manipulating microbial families within the ruminal ecosystem and to evaluate effects of these plant extracts on methane emission and ruminal fermentation in in vitro.
MATERIALS AND METHODS
In vitro incubation
Animal
A fistulated Holstein cow of 500 kg body weight was used as a donor of rumen fluid. Timothy and commercial concentrate (TDN; 73.5%, crude protein; 19%, crude fat; 3%, crude fiber; 12%, crude ash; 10%, Ca; 0.8%, P; 1.2%, AMINOTEK, CJ feeds) in the ratio of 3 to 2 were fed at 2% of body weight twice a day. Water and mineral-vitamin block were allowed ad libitum.
Rumen fluid
The rumen fluid was collected from the fistulated Holstein cow before morning feeding. Rumen samples were collected in a bottle, previously kept warm and filled with O2 free-CO2 gas, carried to the laboratory, and filtered through four layers of cheesecloth before mixing with buffer maintained at 39°C and under O2-free N2 gas.
Plant extracts
Plant extracts were obtained from Plant Extract Bank (PEB) at the Korea Research Institute of Bioscience and Biotechnology. Plants were collected from fields in Korea (Table 1). Each plant was cut into small pieces and dried naturally under shade. Plants were extracted by using methanol (MeOH), and stored at −20°C until use. Stock solution (20 mg/ml) of the extract was prepared in DMSO (Dimethyl sulfoxide).
In vitro incubation
Rumen liquor was filtered through four layers of cheesecloth before mixing with buffer maintained at 39°C. The 30 ml of rumen fluid-buffer mixture, comprising McDougall buffer and rumen liquor in the ratio of 4 to 1, was dispensed anaerobically into serum bottles, filled with O2-free N2 gas, containing 0.3 g of tomothy substrate and plant extracts (1% of total volume, respectively), and then capped with a rubber stopper. The serum bottles were held in a shaking incubator (HBS-201SL, HANBAEK, Korea) at 39°C for 24 h.
Analyses
Total gas production was measured by the assay of Theodorou et al. (1994). A detachable pressure transducer and a digital readout voltmeter (Laurel Electronics, Inc., CA, USA) were used to measure the headspace gas pressure of fermenting cultures. For the total gas production measurement, the transducer was modified in such a way that it could be linked to the inlet of a disposable Luer-lock three-way stopcock (Theodorou, 1994). Gas pressure in the headspace was read from the display unit after insertion of a hypodermic syringe needle through the butyl rubber stopper above the culture medium. The headspace gas in the serum bottle was collected for analysing the composition of gas, especially methane and carbon dioxide. Methane and carbon dioxide were analysed by the gas chromatography (GC-2010, Shimadzu, Japan) equipped with column (Shincarbon ST. 50/80, Shimadzu, Japan). The incubated inoculum was subsampled for the analysis of pH (Mettle-Toledo, CH/MP220), volatile fatty acid (VFA) concentration and total DNA extraction. VFA analysis was performed with a gas chromatography (GC-2010, Shimadzu, Japan) as described by Erwin et al. (1961).
DNA extraction, PCR primers and Real-time PCR
DNA extraction
TissueLyser (Retsch; QIAGEN, Valencia, CA, USA), a high-speed reciprocal shaker which retains samples in screw-capped tubes containing silica beads, was used for DNA extraction. Total nucleic acid was extracted from the incubated rumen samples by using the modified bead-beating protocol with the QIAamp DNA mini kit (250) (QIAGEN, USA). For samples, a 1.0 ml aliquot was taken from the 30 ml incubated mixture using a wide bore pipette so as to ensure a homogenous sample containing fluid and digesta. Nucleic acid concentrations were measured by using a NanoDrop Spectrophotometer (ND-1000, USA).
PCR primers
The PCR primer sets used in this study for amplification of general bacteria, Fibrobacter succinogenes, Ruminococcus albus, Ruminococcus flavefaciens, methanogenic archaea and ciliate-associated methanogens were the same as referenced by Denman and McSweeney (2006), Tajima et al. (2001), Koike et al. (2001), Luton at al. (2002) and Medlin et al. (1998), respectively as shown in Table 2.
Real-time PCR
PCR assays for enumeration of ciliate-associated methanogens and cellulolytic bacterial species were performed according to the methods described by Denman and McSweeney (2006) and Denman et al. (2007) on a Rotor-Gene Real-Time PCR Machine (Crobett life science, Australia) using the iQ SYBR Green Supermix (Bio-Rad Inc., USA). The values of cycle threshold (Ct) after real-time PCR were used to determine fold change (number of fold difference) of different microbial populations relative to the control without extract and plant extracts treatment. Abundance of these microbes were expressed by the equation: relative quantification = 2−ΔCT (Target)−ΔCT(Control), where Ct represents threshold cycle. All quantative (q) PCR reaction mixtures (final volume of 25 μl) contained forward and reverse primers, the iQ SYBR Green Supermix and DNA template ranging from 10 ng to 100 ng. A negative control without the template DNA was used in every qPCR assay for each primer. The PCR amplification of the target DNA, included the annealing and the extension temperature, was conducted following the references in Table 2.
Statistical analysis
Data were analyzed using the general linear model (GLM) procedure of the Statistical Analysis System Institute, Inc. (SAS, 2002). Differences among means were tested for significance using Duncan’s multiple range test of SAS (2002).
RESULTS AND DISCUSSION
Ruminal fermentation characteristics
The in vitro total gas production, methane emission and carbon dioxide production are shown in Table 3. Total gas production in all plant extracts was significantly higher (p<0.05) than that of the control, and total gas production from ginger extract was the highest (p<0.05). The methane emission was shown to be the highest (p<0.05) in control samples, and lowest (p<0.05) observed in samples containing garlic extract with a reduction of approximately 20% of methane emission. Other plant extracts also led to a decrease in methane emission. This finding is in agreement with García-González et al. (2008) who reported that bulbs of Allium sativum (garlic) led to a decrease greater than 20% in both the concentration of methane and in total methane production. Kamra et al. (2008) found that Allium sativum (garlic) extract decreased methane production by more than 25%. Carbon dioxide production in added ginger extract was highest, whereas that of garlic extract was lowest. Total VFAs concentration and pH were not significantly influenced by the addition of plant extracts. However, total VFAs concentration in added mandarin orange extract was highest while that of onion extract was lowest. The ratio of acetate to propionate in added garlic and ginger extracts was significantly lower (p<0.05) than that of the control (Table 4). Methane emission in the rumen is closely related to the a:p ratio, and the decreased methane emission led to a higher molar proportion of propionate and low a:p ratio (Nellet et al., 1997; Mitsumori et al., 2008). The formation of propionate from succinate would result in a lower availability of H2 for the methanogenesis. It indicated that the antimicrobial properties of these plant extracts might influence methanogenesis, resulting in a reduction in methane emission.
Microbial population in rumen
Culture-independent molecular techniques were used as tools to obtain information regarding microbial communities without cultivation (Tajima et al., 2001; Denman et al., 2006). Molecular assays, DNA hybridization, real-time PCR, denaturing gradient gel electrophoresis (DGGE) and other techniques have been used to study the quantitative and phylogenetic changes of microbial groups in a ruminal environment. The ciliate-associated methanogen populations were affected by all plant extracts as shown in Figure 1 and were decreased more than that of the control. These findings agreed with other research studies where ciliate-associated methanogen populations were decreased by addition of garlic (Amagase et al., 2001; Patra et al., 2010), ginger (Patra et al., 2006; Sirohi et al., 2009), mandarin orange (Kamra et al., 2008; Tanaka et al., 2010) and honeysuckle extracts (in the present experiment). In the present study, the supplementation of garlic and ginger extracts is speculated to have decreased the protozoa population resulting in reduction of methane emission in the rumen (Table 3) and thus inhibiting methanogenesis (Figure 1). Zhang et al. (2011) reported that the addition of ginger powder affected the ruminal microbial fermentation in an in vivo experiment. Effects of plant extracts on the population of major fibrolytic microorganisms, Fibrobacter succinogens, Ruminococcus albus and Ruminococcus flavefaciens, are shown in Figure 2, Figure 3 and Figure 4, respectively. The F. succinogens population in all added plant extracts was shown to have an increasing tendency. In particular, the F. succinogens community with the addition of wormwood, garlic, mandarin orange and honeysuckle extracts increased to a greater extent than that of others (Figure 2). The R. albus diversity in added onion extract increased, while other extracts did not influence the R. albus community (Figure 3), and the R. flavefaciens population decreased with the addition of wormwood and garlic extracts, but compared to the control increased with the addition of other extracts (Figure 4). Fiamegos et al. (2011) reported that wormwood (Artemisia absinthium) extracts had a strong antimicrobial activity, particularly against gram-positive pathogenic bacteria. Garlic (Allium sativum) and Onion (Allium cepa) has a wide spectrum of antibacterial activity against gram-negative and gram-positive bacteria such as Bacillus subtilis, Salmonella, and E. coli, which has been linked to the presence of a number of small terpenoid and phenolic compounds (Reuter et al., 1996; Wanapat et al., 2008). Muetzel (2003) reported that the growth of F. succinogenes and R. flavefaciens was not affected by the addition of Sesbania pachycarpa leaves containing saponins to inhibit R. albus in vitro. Lonicera japonica (Honeysuckle), which contains a poisonous compound like saponins, toxic alkaloids and tannins, showed similar results against bacteria.
In conclusion, Plant extracts (Artemisia princeps var. Orientalis; Wormwood, Allium sativum for. Pekinense; Garlic, Allium cepa; Onion, Zingiber officinale; Ginger, Citrus unshiu; Mandarin orange, Lonicera japonica; Honeysuckle) were shown to have properties to decrease methanogenesis and may have the potential possibility for use as additives for ruminants without adversely affecting ruminal fermentation. The results indicated that the plant extracts used in the experiment could be promising feed additives to decrease methane emission from ruminants while improving ruminal fermentation.
ACKNOWLEDGEMENTS
E. T. Kim was supported by a scholarship from the BK21 Program, the Ministry of Education, Science and Technology, Korea.