Effect of Liquorice extract on in vitro rumen fermentation parameters of diets containing different levels of concentrate

Document Type : Research Paper

Authors

1 Department of Animal Science- Faculty of Agriculture- Ilam University

2 Associate Professor- Department of Animal Science- Faculty of Agriculture- Ilam University

3 Department of Animal Science, Chahatmahal Bakhtiari Agricultural and Natural Resources Research and Education Center

4 Department of Animal Science, University of Zanjan

5 Assistant Professor- Department of Animal Science- Faculty of Agriculture- Ilam University

Abstract

Introduction: Plants produce an enormous array of phytochemicals arising from various biosynthetic pathways. More than 200,000 defined structures of phytochemicals have been recognized. The growing concerns over bacterial resistance to antibiotics and chemical residues in animal derived foods have led to use phytochemicals as alternatives to antibiotics, other chemotherapeutic agents, and chemical and growth promoting antibiotic feed additives. Phytochemicals exhibit antibacterial, antiviral and antifungal activities against a wide range of pathogenic and non-pathogenic microorganisms. The antimicrobial properties of phytochemicals are being explored to utilize as feed additives in livestock production system (Patra 2012). One of the plant secondary metabolites which researchers recently focus on beneficial effects is saponins. Saponin-containing plants and their extracts by suppressing the bacteriolytic activity of rumen ciliate protozoa could enhance total microbial protein flow from the rumen. Saponins also have selective antibacterial effects which may prove useful in, for example, controlling starch digestion (Wallace et al 2002). Extract of licorice root can be used to manipulate rumen fermentation due to its saponin content. To date, there are limited research on the effect of plant phytochemicals on ruminal microbial fermentation at low pH. Most research studied the effects of plant phytochemicals on high-forage diets at pH > 6.2. The effects of plant extracts on ruminal microbial fermentation are pH-dependent.Microbial populations and ruminal fermentation conditions in cattle fed high-concentrate diets may be very different from cattle fed high-forage diets, because of the type of substrate being fermented or the resulting pH. Therefore, the search for additives that will help to replace ionophores in high concentrate diets needs to be tested in a high-concentrate and low-pH environment. It was hypothesized that extract of licorice root could exert some antimicrobial activities in low pH. Hence, the objective of this experiment was to study the effect of Licorice extract on in vitro gas production parameters, pH, volatile fatty acids (VFA), N- ammonia concentration and protozoa populations in diets containing different levels of concentrate to forage ratio.
Material and Methods: Dried licorice extract obtained from Zagros Company (Kermanshah). Two experimental diets with different forage to concentrate ratio (40 to 60% or 60 to 40 %) were formulated. Licorice extract was added to diets at three levels, 1 or 2 and or 3 milligram /liter of incubation media. The saponin content of Licorice extract was 134.75 mg/g of dired licorice extract. For in vitro gas production, rumen fluid was taken from two rumen fistulated Kordish rams. For measuring gas production, 200 mg of experimental diets with four levels of licorice extract (0, 1, 2 and 3 mg/L incubation medium) were incubated with 40 ml of buffered-rumen fluid for 120 hours. The cumulative produced gas was recorded at different times of incubation and gas production parameters were fitted with Blummel et al equation (2003). Organic matter digestibility (OMD) was estimated after 24 hours of incubation (Menke and Steingass 1988). N-ammonia concentration was measured based Broderickand Kang (1980). Rumen protozoa were identified according to the method of Dehority (2003). After 24 incubation, 5 ml of buffered rumen fluid was pipetted into a screw-capped test tube containing 5 ml of formalin. Thereafter, two drops of brilliant green dye (2 g brilliant green and 2 ml glacial acetic diluted to 100 ml with distilled water) were added to the test tube, mixed thoroughly and allowed to stand overnight at room temperature. Total and differential counts of protozoa were made with five replications. In vitro rumen concentration of volatile fatty acids (VFA) was measured by gas chromatography (Ottenstein and Bartley 1971). All in vitro gas production trials were carried out in three runs. Rumen fermentation parameters, protozoa population and organic matter digestibility date were analyzed in a factorial arrangement based on a completely randomized design and gas production data were analyzed in a factorial arrangement based on a complete randomized block design using Proc GLM of SAS software. The differences among treatments were evaluated using Tukey adjustment when the overall F-test was P ≤ 0.05. Trends were declared when 0.05 < P ≤ 0.10.
Results and Discussion: The results showed that the interaction of diets and licorice extract levels were not significant on in vitro gas production, rate of gas production, estimated organic matter digestibility N-ammonia concentration, pH, total protozoa population, Entodinium, Epidinium, Diplodinium, Eudiplodinium and Isotricha population and in vitro ruminal concentrations of total VFA, acetate, propionate, butyrate, isobutyrate, valerate and isovalerate. The effect of diets on gas production (P≤0.05) and estimated OMD (p < 0.01) was significant and high concentrate diets in compare to low concentrate diets had greater gas production and greater estimated OMD. Inconsistent to these results, adding saponin to diet containing low level of concentrate decreased gas production (Yogianto et al 2014) and adding saponin to diet containing high level of concentrate increased gas production (Aazami et al 2013). Furthermore, high concentrate diet in compare to low concentrate diet had lower organic matter diegestability (Yogianto et al 2014). Diets containing high concentrate had lower acetate and greater isovalerate concentrations (p < 0.01). Addition of licorice extract reduced estimated OMD and total protozoa population and Entodinium population (p < 0.01) and tended to increase total VFA concentration (P=0.09) and to decrease isovalrate concentration (P=0.06).
Conclusion: Based on this study, it is concluded that different levels of licorice extract had no effect on fermentation parameters of diets containing different concentrate: forage ratios. Further studies are necessary to determine the effectiveness of saponin-containing plants extracts on rumen microbial fermentation and digestion kinetics.

Keywords

References

Aazami MH, Tahmasbi A, Naseryan AA and Valizadeh R, 2013.Effect of incremental levels of saponins on in vitro gas production. Pp. 333-337. Second national conference of livestock and poultry management. Shahid Bahonar University. Kerman, Iran. (In Persian).
Aguerre MJ, Wattiaux MA, Powell JM, Broderick GA and Arndt C, 2011. Effect of forage to concentrate ratio in dairy cow diets on emission of methane, carbon dioxide, and ammonia, lactation performance, and manure excretion. Journal of Dairy Science 94: 3081-3039.
Beauchemin KA, Kreuzer M, O'Mara F and McAllister TA, 2008. Nutritional management forenteric methane abatement. Animal Production Science 48:21-27.
Benchaar C and Greathead H, 2011. Essential oils and opportunities to mitigate enteric methane emissions from ruminants. Animal Feed Science and Technology 166: 338– 355.
Benchaar C, Petit HV, Berthiaume R, Ouellet DR, Chiquette J and Chouinard PY, 2007. Effects of essential oils on digestion, ruminal fermentation, rumen microbial populations, milk production, and milk composition in dairy cows fed alfalfa silage or corn silage. Journal of Dairy Science 90: 886–897.
Blummel M, Karsli A and Russell JR, 2003. Influence of diet on growth yields of rumen micro-organisms in vitro and in vivo: influence on growth yield of variable carbon fluxes to fermentation products. British Journal of Nutrition 90: 625-634.
Bodas R, López S, Fernández M, García-González R, Rodríguez AB, Wallace RJ and González JS, 2008. In vitro screening of the potential of numerous plant species as antimethanogenic feed additives for ruminants. Animal Feed Science Technology 145: 245-258.
Broderick GA and JH Kang, 1980. Automated simultaneous determination of ammonia and total amino acids in ruminal fluid and in vitro media. Journal of Dairy Science 63: 64-75.
Busquet M, Calsamiglia S, Ferret A and Kamel C, 2006. Plant extracts affect in vitro rumen microbial fermentation. Journal of Dairy Science 89: 761-771.
Cardozo PW,  Calsamiglia S,  Ferret A and  Kamel C, 2005. Screening for the effects of natural plant extracts at different pH on in vitro rumen microbial fermentation of a high-concentrate diet for beef cattle. Journal of Animal Science, 83: 2572-2579.
Dehority BA, 2003. Rumen Microbiology. British Library Cataloguing in Publication Data. First published.
Dehority BA, 1978. Specificity of rumen ciliate protozoa in cattle and sheep. Journal of Protozoology 25: 509-513.
D'Mello JPF, 2000. Farm animal metabolism and nutrition. CABI Publishing, Wallingford, 438 pp.
Glauert AM, Dingle JT and Lucy JA, 1962. Action of saponin on biological membranes. Nature 196: 953-955.
Hassan SM, Byrd JA Cartwright LA and Bailey CA, 2010. Hemolytic and antimicrobial activities differ among saponin-rich extracts from guar, quillaja, yucca, and soybean. Applied Biochemistry Biotechnology. 162: 1008-1017.
Hart KJ, Ruiz DRY, Duva SM, McEwan NR and Newbold CJ, 2008. Plant extracts to manipulate rumen fermentation. Animal Feed Science and Technology 14: 78–35.
Hristov AN, Ivan M, Neill L and McAllister TA, 2003. Evaluation of several potential bioactive agents for reducing protozoal activity in vitro. Animal Feed Science and Technology 105: 163-184.
Hu WL, Liu JX, Ye JA, Wu YM and Guo YQ, 2005. Effect of tea saponin on rumen fermentation in vitro. Animal Feed Science and Technology 120: 333-339.
Hussain I and Cheeke PR, 1995. Effect of dietary Yucca schidigera extract on rumen and blood profiles of steers fed concentrate- or roughage-based diets. Animal Feed Science and Technology 51: 231-242.
Jiménez-Peralta FS, Salem AZM, Mejia-Hernández P, González-Ronquillo M, Albarrán-Portillo B, Rojo-Rubio R and Tinoco-Jaramillo JL, 2011. Influence of individual and mixed extracts of two tree species on in vitro gas production kinetics of a high concentrate diet fed to growing lambs.Journal of Livestock Science 136: 192-200.
Klita PT, Mathison GW, Fenton TW and Hardin RT, 1996. Effects of alfalfa root saponins on digestive function in sheep.Journal of Animal Science 74: 1144-1156.
Makkar HPS, Becker K, Abel H, Pawelzik E, 1999. Nutrient contents, rumen protein degradability and anti -nutritional factors in some colour and white flowering cultivars of Vicia faba beans. Journal of Science of Food and Agriculture 75:511-520.
Manatbay B, Cheng Y, Mao S and Zhu W, 2014. Effect of gynosaponin on rumen in vitro methanogenesis under different forage-concentrate ratios. Asian Australian Journal of Animal Science 27: 1088-1097.
Mao HL, Wang JK, Zhou YY and Liu JX, 2010. Effect of addition of tea saponins and soybean oil on methane production in the rumen of growing lambs. Journal of Livestock Science129: 56-62.
McDougallEI, 1947. The composition and output of sheep saliva. Institute of Animal Pathology. University of Cambridge.
McIntosh FM, Williams P, Losa R, Wallace RJ, Beever DA and Newbold CJ, 2003. Effects of essential oils on ruminal microorganisms and their protein metabolism. Applied and Environmental Microbiology 69: 5011–5014.
Menke KH and Steingass H, 1988. Estimation of the energetic feed value obtained from chemical analysis and in vitro gas production using rumen fluid. Animal Research and Development 28: 7-55.
Mirzaei-Alamouti H, Razavian M, Masoumi R and Salmani Zavieh V, 2017. Effect of monension and plant extract on rumen and blood metabolites and gene expression of the urea transporter gene in the rumen epithelium of fattening lambs. Journal of Animal Sciences Researches 27(3): 161-174. (In Persian).
Mohaghi MM, Tahmasebi A, Valizadeh R, Naserian A, 2013.Determination of fermentation process of diet containing different levels of saponin and acid tannic under in vitro condition. Iranian Journal of Animal Science Research: 5: 39-47. (In Persian).
Mohaghi MM, Tahmasebi A, Valizadeh R, Naserian A, Kazemi M and Eskandari Torbagha A, 2018. Effect of different levels of saponin on the nutrient content, fermentation parameters, rumen protozoan population and blood parameters in Baluchi sheep. Journal of Animal Science 117: 241-256. (In Persian).
Nasri, S, Ben Salem H, Vasta V, Abidi S, Makkar HPS and Priolo A, 2011. Effect of increasing levels of Quillajasaponaria on digestion, growth and meat quality of Barbarine lamb. Animal Feed Science and Technology 164: 71-78.
Nourian Soror MA, Khazarian A and Moeni MM, 2016. Effects of ethanol and acetone extracts of Glycyrrhiza glabra root on ruminal fermentation parameters, methane production and goat protozoa population. Animal production 4: 729-740. (In Persian).
NRC, 2001.Nutrient Requirements of Dairy Cattle. 7th ed. National Academy Press, Washington, DC, USA.
Oloomi H and Hassibi N, 2012. Evaluation of the content of secondary metabolites of Licorice root in some natural habitats of Kerman province. Medicinal plants. 41: 137-144. (In Persian).
Ottenstein DM and Bartley DA, 1971. Separation of free acids C2-C5 in diluted aqueous solution column technology. Journal of Chromatographic Science 9: 673-681.
Patra AK and Saxena J, 2009a. Dietary phytochemicals as rumen modifiers: A review of the effects on microbial populations. Antonie van Leeuwenhoek 96: 363-375.
Patra AK and Saxena J, 2009b. The effect and mode of action of saponins on the microbial population and fermentation in the rumen and ruminant production. Nutrition Research Reviews 22: 204-219.
Patra AK. 2012. Dietary Phytochemicalsand Microbes. Spriger, New York, USA.
Patra AK and Yu Z. 2015. Effects of adaptation of in vitro rumen culture to garlic oil, nitrate, and saponin and their combinations on methanogenesis, fermentation, and abundances and diversity of microbial populations. Frontiers in Microbiology: 6:1-11.
Patra AK and Yu Z. 2013. Effects of vanillin, quillaja saponin, and essential oils on in vitro fermentation and protein-degrading microorganisms of the rumen. Applied Microbiology and Biotechnology: 98(2):897-905.
Ramos-Morales E, Rossi G, Cattin M, Jones E, Braganca R and Newbold CJ, 2018. The effect of an isoflavonid-rich liquorice extract on fermentation, methanogenesis and the microbiome in the rumen simulation technique. FEMS Microbiology Ecology 94: 1-11.
Suharti S, Astuti DA, Wina E and Toharmat T, 2011. Rumen microbial population in the in vitro fermentation of different ratios of forage and concentrate in the presence of whole Lerak (Sapindus rarak) fruit extract. Journal of Animal Science 8: 1086 – 1091.
Takahashi J, Nwenya B, Santoso B, Sar C, Umetsu K, Kishimoto T, Nishizaki K, kimura K and Hamamoto O, 2005. Mitigation of methane emission and energy recycling in animal agricultural systems. Asian-Australian Journal of Animal Science 18: 1199-12080.
Wallace RJ, McEwan NR, McIntosh FM, Teferedegne B and Newbold CJ, 2002. Natural products as manipulators of rumen fermentation. Asian Australasian Journal of Animal Science 15: 1458-1468.
Wang Y, McAllister TA, Newbold CJ, Rode LM, Cheeke PR and Cheng KJ, 1998. Effect of Yucca schidigera extract on fermentation and degradation of steroidal saponins in the rumen simulation technique (RUSITEC). Animal Feed Science and Technology 74: 143-153.
Yogianto, Sudarman A, Wina E and Jayanegara A, 2014. Supplementation effects of tannin and saponin extracts to diets with different forage to concentrate ratio on in vitro rumen fermentation and methanogenesis. Journal of the Indonesian Tropical Animal Agriculture 39: 144-151.
Animal Science Research
Volume 30, Issue 4
March 2021
Pages 27-39

Files

History

  • Receive Date: 10 July 2019
  • Revise Date: 16 March 2020
  • Accept Date: 14 March 2021

Share

How to cite

Statistics