Effect of Protein Fractionation and Buffer Solubility of Forage Sources on In Vitro Fermentation Characteristics, Degradability and Gas Production

Jin, Guang Lin; Shinekhuu, Judder; Qin, Wei-Ze; Kim, Jong-Kyu; Ju, J.G.; Suh, Seong-Won; Song, Mi Kyoung

doi:10.5333/kgfs.2012.32.1.59

Cited by 6 publications

(9 citation statements)

References 17 publications

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“…The strong relationship between total gas production and EDDM has been previously reported (Jin et al, 2012). Regardless of defaunation, more gas was produced from forages than from cellulose (Table 4).…”

Section: Discussionsupporting

confidence: 74%

“…Furthermore, ryegrass showed similar results in comparison with cellulose, and seemed to be more potent in increasing total VFA concentration than both rice straw and tall fescue. This might be associated with the relatively low degree of lignification and high buffer solubility in ryegrass (Jin et al, 2012). It can be indicated that degradation of ryegrass is less limited by lignin and more rapidly available for rumen microbes, contribution to more VFA production.…”

Section: Discussionmentioning

confidence: 99%

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Effect of Defaunation on In Vitro Fermentation Characteristics and Methane Emission When Incubated with Forages

Qin¹,

Choi²,

Lee³

et al. 2013

Journal of The Korean Society of Grassland and Forage Science

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An in vitro study was conducted to determine the effects of defaunation (removal of protozoa) and forage sources (rice straw, ryegrass and tall fescue) on ruminal fermentation characteristics, methane (CH4) production and degradation by rumen microbes. Sodium lauryl sulfate, as a defaunation reagent, was added into the mixed culture solution to remove ruminal protozoa at a concentration of 0.375 mg/ml. Pure cellulose (0.64 g, Sigma, C8002) and three forage sources were incubated in the bottle of culture solution of mixed rumen microbes (faunation) or defaunation for up to 24 h. The concentration of ammonia-N was high under condition of defaunation compared to that from faunation in all incubations (p<0.001). Total VFA concentration was increased at 3, 6 and 12 h (p<0.05~p<0.01) but was decreased at 24 h incubation (p<0.001) under condition of defaunation. Defaunation decreased acetate (p<0.001) and butyrate (p<0.001) proportions at 6, 12 and 24 h incubation times, but increased propionate (p<0.001) proportion at all incubation times for forages. Effective degradability of dry matter was decreased by defaunation (p<0.001). Defaunation not only decreased total gas (p<0.001) and CO2 (p<0.01~0.001) production at 12 and 24 h incubations, but reduced CH4 production (p<0.001) at all incubation times for all forages. The CH4 production, regardless of defaunation, in order of forage sources were rice straw > tall fescue > ryegrass > cellulose (p<0.001) up to 24 h incubation. (Key words : Defaunation, Forages, Effective degradability, Total gas, Methane emission). INTRODUCTIONThe forages make up a large proportion of the diet in ruminant production systems. The feeding of forages as energy sources to ruminants is highly depended on rumen fermentation of the fiber such as cellulose and hemicelluloses by rumen microbes (Wina et al., 2006). Rumen protozoa are metabolically active and serve a multifunctional role in metabolizing dietary nutrients through several ways (Morgavi et al., 2010). Protozoa are well known to secrete hydrolytic enzymes (Coleman, 1986) and positively contributed to 20% of fiber degradation (Dijkstra and Tamminga, 1995). In addition to their role in fiber degradation, rumen protozoa are positively related to methane (CH4) production in the rumen. Finlay et al. (1994) described a symbiotic relationship of ruminal ciliate protozoa with methanogens, which has been proved to allow an interspecies H2 transfer from ciliate protozoa to methanogens for CH4 synthesis, and the symbiotic methanogens associated with rumen ciliate protozoa may account for 37% of the total CH4 production. Some studies have shown that defuanation (removal of protozoa in the rumen) decreased CH4 production up to 10.8% (Kreuzer et al., 1986) or 24.1% (Morgavi et al., 2008) when the cattle were fed forage diets. Furthermore, it is well known that ruminants fed forage-based diets produce more CH4 than those fed high level of concentrate diets (Johnson et al, 2000).Since CH4 emission from ruminants has increasingly caused widesprea...

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Section: Discussionsupporting

confidence: 74%

Section: Discussionmentioning

confidence: 99%

Effect of Defaunation on In Vitro Fermentation Characteristics and Methane Emission When Incubated with Forages

Qin¹,

Choi²,

Lee³

et al. 2013

Journal of The Korean Society of Grassland and Forage Science

Self Cite

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“…Table 1). 이것은 기존 연구에서 보고된 각 단백질의 N 분획과 전체적으로 유사하였으나 (Licitra et al, 1996;Jin, 2011;Choi, 2015), 채종박의 경우 B 2 fraction이 A와 B 1 fraction보다 다소 높게 나타났다. .…”

Section: Cncps Fraction별 대표사료 선정unclassified

Changes in ruminal fermentation and blood metabolism in steers fed low protein TMR with protein fraction-enriched feeds

Choi¹

2016

Korean Journal of Agricultural Science

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Four ruminally cannulated Holstein steers (BW 482.9 ± 8.10 kg), fed low protein TMR (CP 11.7%) as a basal diet, were used to investigate changes in rumen fermentation and blood metabolism according to protein fraction, cornell net carbohydrates and protein system (CNCPS), and enriched feeds. The steers, arranged in a 4 × 4 Latin square design, consumed TMR only (control), TMR supplemented with rapeseed meal (AB1), soybean meal (B2), and perilla meal (B3C), respectively. The protein feeds were substituted for 23.0% of CP in TMR. Ruminal pH, ammonia-N, and volatile fatty acids (VFA) in rumen digesta, sampled through ruminal cannula at 1 h-interval after the morning feeding, were analyzed. For plasma metabolites analysis, blood was sampled via the jugular vein after the rumen digesta sampling. Different N fraction-enriched protein feeds did not affect (p > 0.05) mean ruminal pH except AB1 being numerically lower 1 -3 h post-feeding than the other groups. Mean ammonia-N was statistically (p < 0.05) higher for AB1 than for the other groups, but VFA did not differ among the groups. Blood urea nitrogen was statistically (p < 0.05) higher for B2 than for the other groups, which was rather unclear due to relatively low ruminal ammonia-N. This indicates that additional studies on relationships between dietary N fractions and ruminant metabolism according to different levels of CP in a basal diet should be required.

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“…단백질 fraction별 대표사료를 선정하기 위해 기존의 문 헌을 통해 후보사료를 1차 검색 후 그 중 fraction별 함유량 이 높고 국내에 사용되고 있는 사료로 선발하였다 (Choi, 2003;Choi et al, 2015;Jin, 2011;Licitra et al, 1996).…”

Section: Cncps Fraction별 대표사료 선정unclassified

“…(Table 1). 이것은 기존 연구에 서 보고된 각 단백질의 N 분획과 전체적으로 유사하였다 (Choi, 2003;Jin, 2011;Licitra et al, 1996) Treatments were TMR only (control), TMR with rapeseed meal (AB1), TMR with soybean meal (B2) and TMR with perilla meal (B3C), respectively. b) Standard error of the mean.…”

Section: Cncps Fraction별 대표사료 선정mentioning

confidence: 99%

Effects of CNCPS fraction-enriched proteins on ruminal fermentation and plasma metabolites in holstein steers fed TMR containing low protein

Choi

2015

Korean Journal of Agricultural Science

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: Four ruminally cannulated Holstein steers (BW 401.0 ± 2.22 kg) fed TMR containing low protein (CP 9.63 %) as a basal diet were used to investigate the effects of cornell net carbohydrates and protein system (CNCPS) fraction enriched protein feeds on rumen fermentation and blood metabolites. The steers used in a 4 × 4 Latin square design consumed TMR only (control), TMR with rapeseed meal (AB1), TMR with soybean meal (B2) and TMR with perilla meal (B3C), respectively. The protein feeds were substituted for 30 % crude protein of TMR intake. For measuring ruminal pH, ammonia-N and volatile fatty acids (VFA), ruminal digesta was sampled through ruminal cannula at 1 h-interval after the afternoon feeding. Blood was sampled via the jugular vein after the ruminal digesta sampling. Different CNCPS fraction-enriched proteins did not affect (p>0.05) ruminal pH except B3C being numerically low compared with the other groups. Ammonia-N and VFA were not significantly different among the experimental groups. Numerically low ammonia-N appeared in the steers fed rapeseed meal even though it contained high soluble N composition (A and B1 fractions). The discrepancy is unclear; however this may be related to low protein level in the diet and/or low DM intake. Blood metabolites were not significantly affected by the protein substitution except for blood urea nitrogen that was significantly (p<0.05) increased.

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Effect of Protein Fractionation and Buffer Solubility of Forage Sources on In Vitro Fermentation Characteristics, Degradability and Gas Production

Cited by 6 publications

References 17 publications

Effect of Defaunation on In Vitro Fermentation Characteristics and Methane Emission When Incubated with Forages

Effect of Defaunation on In Vitro Fermentation Characteristics and Methane Emission When Incubated with Forages

Changes in ruminal fermentation and blood metabolism in steers fed low protein TMR with protein fraction-enriched feeds

Effects of CNCPS fraction-enriched proteins on ruminal fermentation and plasma metabolites in holstein steers fed TMR containing low protein

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