Ruminal bacteria and protozoa composition, digestibility, and amino acid profile determined by multiple hydrolysis times

Fessenden, S.W.; Hackmann, Timothy J.; Ross, Deborah; Foskolos, Andreas; Amburgh, M.E. Van

doi:10.3168/jds.2016-12531

Cited by 15 publications

(25 citation statements)

References 46 publications

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“…These are the classical patterns reported, for example, in goat milk by Rutherfurd et al (2008) and in rumen microorganisms by Fessenden et al (2017). During examination of the results obtained from the equation proposed by Robel and Crane (1972) and used by others (e.g., Darragh et al, 1996;Rutherfurd et al, 2008; Fessenden et al, 2017), we observed that the loss rate from the hydrolysate was negative for the AA, still showing an increment of their concentration after 24 h of hydrolysis. Although this negative loss rate gives a good mathematical fit to the data, it does not apply to its initial representation in the model, which should be the proportion of state B (i.e., in the pool of AA in the hydrolysate) being degraded.…”

Section: Resultssupporting

confidence: 73%

“…We excluded the max/24h ratio of Ser and Thr because, as discussed above, these 2 AA presented a significant loss before the 24-h measurements. The very low ratio of A 0 /24h compared with max/24h for the BCAA indicates that the current nonlinear model does not apply well to these AA Average of the current study, Darragh et al (1996), Rutherfurd et al (2008), and Fessenden et al (2017).…”

Section: Resultsmentioning

confidence: 63%

“…A third ratio reported in the literature was also used: the ratio of the true AA concentrations deter-mined based on the DNA sequence of a purified protein on the concentrations measured after a 24-h hydrolysis (gene/24h). In addition to the original work of Robel and Crane (1972) and the current study, the A 0 /24h ratios were estimated in egg white lysozyme (Darragh et al, 1996), goat milk formulation (Rutherfurd et al, 2008), and rumen microorganisms (Fessenden et al, 2017). The max/24h ratios were determined in wheat (Kohler and Palter, 1967), pig diet and digesta (Rowan et al, 1992), and different soybean products (Albin et al, 2000).…”

Section: Resultsmentioning

confidence: 88%

“…As previously mentioned, it has been known for a long time that acidlabile AA like Ser and Thr are partially destroyed after their release from the protein during a 24-h hydrolysis (Rees, 1946). Accordingly, when multiple time hydrolyses have been conducted, Ser and Thr are the AA with a positive and high loss rate (e.g., Darragh et al, 1996;Fessenden et al, 2017). Besides Ser and Thr, only Met had a positive loss rate across all the proteins with an average of 24 h to reach its maximal concentration.…”

Section: Resultsmentioning

confidence: 99%

“…Rumen fluid-associated bacteria (FAB) and particleassociated bacteria (PAB) were isolated according to Reynal and Broderick (2005), except that 2 layers of cheese cloth were used initially to separate the FAB and PAB and that the low speed centrifugations were at 500 × g rather than 1,000. Protozoa were extracted according to Fessenden et al (2017). Formalin was not used on bacteria or protozoa samples.…”

Section: Methodsmentioning

confidence: 99%

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Estimation of correction factors to determine the true amino acid concentration of protein after a 24-hour hydrolysis

Lapierre

Binggeli

Sok

et al. 2019

Journal of Dairy Science

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Although it has been acknowledged for a long time that a single period of hydrolysis, normally 21 to 24 h, is not the optimal time for most of the AA, a single period is routinely used due to time and cost constraints. As models to balance dairy rations for proteins are evolving toward balancing for AA, it becomes critical to improve the predictions of AA supply from digested proteins. Our objective was to develop correction factors that could systematically be applied to AA concentrations obtained after a 24-h hydrolysis of proteins to account for incomplete recovery and therefore determine their true AA composition. Thirteen substrates were selected to represent different types of proteins commonly used to estimate the supply of AA in ration formulation models: feed ingredients (grass silage, corn silage, soybean meal, canola meal, high-protein corn dried distillers grains, and wheat dried distillers grains plus solubles), 16-h rumen residues (soybean meal and canola meal), digesta (duodenal digesta and feces), and rumen microorganisms (fluid-associated bacteria, particle-associated bacteria and protozoa). Each protein was hydrolyzed in 6 N HCl for multiple hydrolysis times: 13 (2, 4, 8, 12, 18, 21, 24, 30, 48, 72, 96, 120, and 168 h) for feed ingredients, rumen residues, and digesta, and 9 (2, 4, 8, 18, 24, 30, 48, 96, and 168 h) for rumen microorganisms; all analyses were conducted in triplicate. Using nonlinear regression, the AA composition in the protein before the hydrolysis (A 0 ) was derived for each AA in each protein. Two ratios were calculated as potential correction factors: A 0 /24-h concentration (A 0 /24h) and the maximal concentration/24-h concentration (max/24h). Both ratios were tested to determine if the type of proteins was affecting them. The ratios A 0 /24h were not affected by the type of proteins, whereas the ratios max/24h were also not affected by the type of proteins except for 3 nonessential AA (Ala, Glu, and Gly). In an attempt to propose correction factors, our results were combined with results from the literature reporting ratios A 0 /24h, ratios max/24h, or the ratio of the AA composition calculated from gene structure/24 h. The correction factors proposed for individual AA varied from 1.02 (Asp) to 1.12 (Thr). For the essential AA, the highest ratios were obtained, as expected, for the branched-chain AA and Thr. Formulation programs balancing dairy rations for essential AA would need to acknowledge the incomplete recovery of AA when obtained from 24-h hydrolysis and include correction factors, specific for each AA, but the same across different types of proteins, to correctly estimate the true AA supply to dairy cows.

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