In vitro investigation of the effect of dairy propionibacteria on rumen pH, lactic acid and volatile fatty acids

Luo, Jianbiao; Ranadheera, Chaminda Senaka; King, Stuart; Evans, Craig A.; Baines, Susan

doi:10.1016/s2095-3119(16)61556-3

Cited by 12 publications

(8 citation statements)

References 28 publications

(39 reference statements)

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“…Caproiciproducens and Clostridium sensu stricto 12 are also significantly correlated with Acetobacter ( Supplementary Table S6 ), a genus characterized as an acetic acid producer ( Cleenwerck et al, 2002 ). Acidipropionibacterium, an apparent lactic utilizing bacteria ( Luo et al, 2017 ; Candry et al, 2020 ), correlated with Lactobacillus .…”

Section: Resultsmentioning

confidence: 97%

Mixed Acid Fermentation of Carbohydrate-Rich Dairy Manure Hydrolysate

Ingle

Fortney

Walters

et al. 2021

Front. Bioeng. Biotechnol.

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Dairy manure (DM) is an abundant agricultural residue that is largely composed of lignocellulosic biomass. The aim of this study was to investigate if carbon derived from DM fibers can be recovered as medium-chain fatty acids (MCFAs), which are mixed culture fermentation products of economic interest. DM fibers were subjected to combinations of physical, enzymatic, chemical, and thermochemical pretreatments to evaluate the possibility of producing carbohydrate-rich hydrolysates suitable for microbial fermentation by mixed cultures. Among the pretreatments tested, decrystalization dilute acid pretreatment (DCDA) produced the highest concentrations of glucose and xylose, and was selected for further experiments. Bioreactors fed DCDA hydrolysate were operated. Acetic acid and butyric acid comprised the majority of end products during operation of the bioreactors. MCFAs were transiently produced at a maximum concentration of 0.17 mg CODMCFAs/mg CODTotal. Analyses of the microbial communities in the bioreactors suggest that lactic acid bacteria, Megasphaera, and Caproiciproducens were involved in MCFA and C4 production during DCDA hydrolysate metabolism.

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Section: Resultsmentioning

confidence: 97%

Mixed Acid Fermentation of Carbohydrate-Rich Dairy Manure Hydrolysate

Ingle

Fortney

Walters

et al. 2021

Front. Bioeng. Biotechnol.

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“…For the same reason, it seems unlikely that the increase in propionate observed when feeding P169 is produced by the strain P169 itself, since the recovery for this strain was 10 6 CFU per mL or lower (Peng et al, 2011). However, Luo et al (2017) showed that propionate can be formed by PAB at high rates and we cannot rule out that P169 could have produced propionate more rapidly in vivo than in vitro, as a result of the stimulation of natural microbial inhabitants of the rumen.…”

Section: Effects On Production Of Volatile Fatty Acids and Methanementioning

confidence: 85%

“…Previous studies found that PAB strains could increase rumen propionate levels (as a proportion of the total VFA) and lower levels of acetate in vivo (Stein et al, 2006;Raeth-Knight et al, 2007;Weiss et al, 2008) and in vitro (Akay & Dado, 2001;Alazzeh et al, 2013), suggesting that PAB could significantly contribute to rumen fermentation. Luo et al (2017) showed that PAB can degrade lactate in the rumen fluid in vitro. In experiments 1 and 2, the molar ratios of acetate to propionate in the controls were 4.0 and 4.6, respectively.…”

Section: Effects On Production Of Volatile Fatty Acids and Methanementioning

confidence: 99%

Propionic acid bacteria enhance ruminal feed degradation and reduce methane production in vitro

Chen

Harstad

McAllister

et al. 2020

Acta Agriculturae Scandinavica, Section A — Animal Science

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Thirty-one strains of propionic acid bacteria were screened for their effects on methane production and volatile fatty acid concentrations using in vitro assays of rumen fluid from Norwegian dairy cows and a grass silage-concentrate mixture as substrate. Nine of 31 strains were further analysed for effects on substrate degradation. Propionic acid bacteria led to reductions of up to 20% in methane production. Seven strains stimulated volatile fatty acid production, and in their presence in vitro substrate degradation tended to increase (P < .10). Most consistent results were found with Propionibacterium thoenii T159, which reduced methane production by 20% and caused 8% and 21% overall increases in substrate degradation and total volatile acid production, respectively (P < .05). Concomitant beneficial effects of a reduction in methane emissions and an increase in feed degradation suggest that this strain may be a promising tool for improving the productive performance of dairy cows.

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“…Higher lactic acid in rumen fluid trigger lactic acid utilizer growth. Some lactic acid utilizer such as Megasphaera elsdenii and Propionibacterium will consume lactic acid, leading to increased production of propionic acid (Seo et al, 2010;Luo et al, 2017). Increased propionic acid after inoculation of L. plantarum also reported by Weinberg et al (2003).…”

Section: Resultsmentioning

confidence: 93%

Survival of Lactobacillus plantarumU40 on the in vitro rumen fermentation quantified with real-time PCR

Astuti

Widyastuti

Wina³

et al. 2018

J. Indonesian Trop. Anim. Agric.

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ABSTRAKTujuan dari penelitian ini adalah untuk menganalisa daya tahan L. plantarumU40 menggunakan real-time PCR dalam fermentasi rumen in vitro. Desain penelitian yang digunakan adalah Rancangan Acak Kelompok dengan 3 perlakuan dan 4 ulangan. Perlakuan yang diberikan adalah kontrol, inokulasi dengan L. plantarumU40 danL. plantarumU40 + glukosa. Perlakuan dengan inokulasi menghasilkan populasi L. plantarumU40 yang lebih tinggi. Setelah 8 jam inkubasi, pemberian glukosa cenderung menurunkan populasi L. plantarum U40. Perlakuan kontrol menghasilkan populasi L. plantarum U40 yang paling rendah selama fermentasi in vitro.Inokulasi L. plantarum U40meningkatkan populasi Bakteri Asam Laktat secara signifikan (P<0.05) sampai dengan 12 jam inkubasi dibandingkan dengan kontrol. Perlakuan kontrol mempunyai pH yang paling tinggi selama masa inkubasi. Penambahan glukosa secara signifikan (P<0.05) menurunkan pH rumen pada akhir inkubasi (24 jam) (6.30), dibandinkgkan dengan kontrol (6.85).Inokulasi dengan L. plantarumU40 + glukosa secara signifikan (P<0.05) meningkatkan asam propionat, menurunkan asam asetat serta nisbah A/P dibanding perlakuan lainnya.Lactobacillus plantarum U40 tanpa penambahan glukosa tidak memberikan efek terhadap produksi propionat secara signifikan. Dapat disimpulkan bahwa Lactobacillus plantarumU40 dapat bertahan hidup di dalam rumen serta mengubah fermentasi rumen ketika glukosa ditambahkan sebagai sumber karbon. Kata kunci: Lactobacillus plantarumU40, daya tahan, glukosa,fermentasi rumen, quantitative real-time PCR ABSTRACTThe objective of this study was to evaluate the survival of L. plantarumU40 quantified with realtime PCR during in vitro rumen fermentation. The experiment was arranged in a randomized block design with 3 treatments and 4 replications. Treatments were control, rumen fermentation inoculated with L. plantarumU40and L. plantarumU40 + glucose solution. Population of L. plantarum U40 was higher at inoculation treatment. After 8 hours incubation, glucose addition tended to decrease L. plantarum U40 population. Control treatment showed lowest population of L. plantarum U40 along in 184 J.Indonesian Trop.Anim.Agric. 43(2):184-192, June 2018 vitro fermentation compared with other treatment. Inoculation of L. plantarumU40 significantly (p<0.05) increased population of LAB until 12 hours incubation compared with control. Control treatment had highest pH at all incubation time. Glucose addition significantly (P<0.05) decreased final rumen pH (24 hours) (6.30), compared with control treatment (6.85). Inoculation of L. plantarum U40 with glucose addition significantly (P<0.05)increased propionic acid, decreased acetic acid and A/P ratio compared with other treatments. Lactobacillus plantarum U40 without glucose addition did not affect propionic acid production significantly. As conclusion, Lactobacillus plantarum U40 can survive in rumen fluid and changes rumen fermentation when glucose is added as carbon source.

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In vitro investigation of the effect of dairy propionibacteria on rumen pH, lactic acid and volatile fatty acids

Cited by 12 publications

References 28 publications

Mixed Acid Fermentation of Carbohydrate-Rich Dairy Manure Hydrolysate

Mixed Acid Fermentation of Carbohydrate-Rich Dairy Manure Hydrolysate

Propionic acid bacteria enhance ruminal feed degradation and reduce methane production in vitro

Survival of Lactobacillus plantarumU40 on the in vitro rumen fermentation quantified with real-time PCR

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