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Review: Impact of protein and energy supply on the fate of amino acids from absorption to milk protein in dairy cows

Published online by Cambridge University Press:  06 February 2020

H. Lapierre*
Affiliation:
Agriculture and Agri-Food Canada, 2000 College Street, Sherbrooke, QuébecJ1M 0C8, Canada
R. Martineau
Affiliation:
Département des sciences animales, Université Laval, 2425 rue de l’Agriculture, Québec, QCG1V 0A6, Canada
M. D. Hanigan
Affiliation:
Department of Dairy Science, Virginia Polytechnic Institute and State University, 175 West Campus Drive, Blacksburg, VA24061, USA
H. J. van Lingen
Affiliation:
Department of Animal Science, University of California, One Shields Avenue, Davis, CA95616USA
E. Kebreab
Affiliation:
Department of Animal Science, University of California, One Shields Avenue, Davis, CA95616USA
J. W. Spek
Affiliation:
Wageningen Livestock Research, De Elst 1, Wageningen6708 WD, The Netherlands
D. R. Ouellet
Affiliation:
Agriculture and Agri-Food Canada, 2000 College Street, Sherbrooke, QuébecJ1M 0C8, Canada

Abstract

Making dairy farming more cost-effective and reducing nitrogen environmental pollution could be reached through a reduced input of dietary protein, provided productivity is not compromised. This could be achieved through balancing dairy rations for essential amino acids (EAA) rather than their aggregate, the metabolizable protein (MP). This review revisits the estimations of the major true protein secretions in dairy cows, milk protein yield (MPY), metabolic fecal protein (MFP), endogenous urinary loss and scurf and associated AA composition. The combined efficiency with which MP (EffMP) or EAA (EffAA) is used to support protein secretions is calculated as the sum of true protein secretions (MPY + MFP + scurf) divided by the net supply (adjusted to remove the endogenous urinary excretion: MPadj and AAadj). Using the proposed protein and AA secretions, EffMP and EffAA were predicted through meta-analyses (807 treatment means) and validated using an independent database (129 treatment means). The effects of MPadj or AAadj, plus digestible energy intake (DEI), days in milk (DIM) and parity (primiparous v. multiparous), were significant in all models. Models using (MPadj, MPadj × MPadj, DEI and DEI × DEI) or (MPadj/DEI and MPadj/DEI × MPadj/DEI) had similar corrected Akaike’s information criterion, but the model using MPadj/DEI performed better in the validation database. A model that also included this ratio was, therefore, used to fitting equations to predict EffAA. These equations predicted well EffAA in the validation database except for Arg which had a strong slope bias. Predictions of MPY from predicted EffMP based on MPadj/DEI, MPadj/DEI × MPadj/DEI, DIM and parity yielded a better fit than direct predictions of MPY based on MPadj, MPadj × MPadj, DEI, DIM and parity. Predictions of MPY based on each EffAA yielded fairly similar results among AA. It is proposed to ponder the mean of MPY predictions obtained from each EffAA by the lowest prediction to retain the potential limitation from AA with the shortest supply. Overall, the revisited estimations of endogenous urinary excretion and MFP, revised AA composition of protein secretions and inclusion of a variable combined EffAA (based on AAadj/DEI, AAadj/DEI × Aadj/DEI, DIM and parity) offer the potential to improve predictions of MPY, identify which AA are potentially in short supply and, therefore, improve the AA balance of dairy rations.

Type
Review Article
Copyright
© Her Majesty the Queen in Right of Canada, as represented by the Minister of Agriculture and Agri-Food Canada 2020.

Implications

To improve the formulation of dairy rations, allowing a reduction of crude protein intake, feeding costs and nitrogen excretion into the environment, the current review proposed revisited estimations of daily true protein secretions in dairy cows and associated amino acid composition. A good prediction of milk protein yield was obtained using the predicted combined variable efficiency of utilization of absorbed amino acids based on the ratio of absorbed amino acids/digestible energy intake, days in milk and parity. This approach could help to identify which amino acids are in short supply and, therefore, improve the amino acid balance of dairy rations.

Introduction

With an overall objective of increasing the sustainability of dairy farms, optimizing the efficiency of utilization of protein without compromising productivity becomes a must for dairy nutritionists. Emphasis is often put on the poor efficiency of utilization of N by dairy cows to produce milk protein (milk N/N intake) averaging, for example, 24.7 ± 4.1% and 27.7 ± 3.6% in 736 North American and 998 North European treatment means, respectively (Huhtanen and Hristov, Reference Huhtanen and Hristov2009). However, human-edible feed conversion efficiency (heFCE), calculated as the ratio of human-edible output/human-edible input, has been proposed to better evaluate the contribution of animal production to the human food chain (e.g. Wilkinson, Reference Wilkinson2011; Ertl et al., Reference Ertl, Klocker, Hörtenhuber, Knaus and Zollitsch2015). In this context and considering protein, Wilkinson (Reference Wilkinson2011) concluded that dairy cows were offering the most efficient animal production system in the United Kingdom; Ertl et al. (Reference Ertl, Klocker, Hörtenhuber, Knaus and Zollitsch2015) reported heFCE for protein varying from 0.5 to slightly more than 2.0 in commercial dairy farms in Austria, whereas Broderick (Reference Broderick2018) calculated heFCE varying between 1.4 and 2.1, depending of the production context from different countries. Therefore, dairy cows can make a valuable contribution to the human food chain with a high heFCE for protein.

Improving the overall efficiency of N utilization still remains, however, a target due to its dual impact on reducing both feeding cost and environmental impact. Dijkstra et al. (Reference Dijkstra, Reynolds, Kebreab, Bannink, Ellis, France, Van Vuuren, Oltjen, Kebreab and Lapierre2013a) suggested that focusing on an optimal supply of rumen-degradable protein and optimizing the efficiency of utilization of absorbed amino acids (AA) for milk protein synthesis would be the potential strategies available for improving N efficiency. To improve AA recommendations for dairy rations, three major points need to be tackled: (1) quantify the net supply of AA; (2) assess the fate of absorbed AA (for which functions are they used for?) and (3) determine with which efficiency the absorbed AA are used to support the identified functions.

The current review focuses on the two latter points: revisiting true protein (TP) secretions and associated AA secretions and identifying the major factors affecting the efficiency of utilization of absorbed AA (EffAA). We will also evaluate if predicted efficiency of utilization of metabolizable protein (MP) supply and EffAA are sufficiently robust to predict milk true protein yield (MPY). To simplify the review, only secretions and not accretions are included in AA demand: the cows are, therefore, considered at constant body weight (BW) and not in gestation.

Updates of true protein and amino acid secretions

To follow the fate of absorbed AA, the quantification of AA secreted into milk protein but also on AA ‘lost’ by the cow in endogenous secretions found in scurf, urine and feces is required. These endogenous AA losses as MPY remove AA irreversibly from the free AA pool. On a net basis, these exported AA need to be replaced on a timely basis by a minimal equivalent flow of digested AA: this predicted ‘replacement’ constitutes the basis of MP and AA recommendations which are calculated as the sum of secretions divided by an efficiency of utilization of absorbed MP or AA to support different identified secretions.

Scurf

True protein secretion

In most of the formulation models, the equation from Swanson (Reference Swanson1977) predicting net crude protein (CP) requirement for scurf is used:

(1)$${\rm{CP\, scur}}{{\rm{f}}_{{\rm{secretion}}}}\left( {\rm g/day} \right) = 0.2{\rm{ }} \times {\rm{ B}}{{\rm{W}}^{0.60}}$$

Swanson’s prediction was retained but adjusted to take into account that not all CP is TP:

(2)$${\rm{TP\, scur}}{{\rm{f}}_{{\rm{secretion}}}}\left( {{\rm{g/day}}} \right) = 0.2{\rm{ }} \times {\rm{ B}}{{\rm{W}}^{0.60}} \times {\rm{ }}0.86{\rm{ }} = {\rm{ }}0.17{\rm{ }} \times {\rm{ B}}{{\rm{W}}^{0.60}}$$

where 0.86 represents the TP/CP ratio of scurf, based on its AA composition, detailed below, and total N content; here and throughout the text, BW is in kg.

Amino acids

The secretion of AA into scurf is obtained by multiplying TP scurfsecretion by its AA composition, estimated using the head, hide, feet and tail composition reported by Williams (Reference Williams1978) and van Amburgh et al. (Reference Van Amburgh, Collao-Saenz, Higgs, Ross, Recktenwald, Raffrenato, Chase, Overton, Mills and Foskolos2015). The mean from these studies, corrected for incomplete recovery of AA with 24-h hydrolyses (Lapierre et al., Reference Lapierre, Binggeli, Sok, Pellerin and Ouellet2019), is reported on a TP basis in Table 1.

(3)$${\rm{AA\, scur}}{{\rm{f}}_{{\rm{secretion}}}}\left( {{\rm{g/day}}} \right){\rm{ }} = {\rm{ }}0.17{\rm{ }} \times {\rm{ B}}{{\rm{W}}^{0.60}} \times {\rm{ }}\left[ {{\rm{A}}{{\rm{A}}_{{\rm{corr}} - {\rm{Scurf}}}}} \right]/100$$

where (AAcorr–Scurf) is in g AA/100 g TP.

Table 1 Amino acid (AA) composition of protein secretions used in the calculation of efficiency of utilization of AA in lactating dairy cows

1 g AAcorr: AA composition corrected to account for incomplete recovery of AA with 24-h hydrolysis; TP = true protein.

2 g AAcalc: AA composition calculated from the primary structure of the reference protein of each family; see text for details.

Endogenous urinary

True protein secretion

Most formulation models predict endogenous urinary daily protein losses according to Swanson (Reference Swanson1977), at 2.75 g/BW0.50. To better quantify the AA required to cover this loss, a literature review was conducted to quantify the composition of urinary N. Force is to admit that literature is scarce on that domain in dairy cattle (Dijkstra et al., Reference Dijkstra, Oenema, van Groenigen, Spek, van Vuuren and Bannink2013b). The major N metabolites in endogenous urinary N losses are: urea synthesized from endogenous sources, endogenous purine derivative (PD), creatinine and creatine, hippuric acid and 3-methyl-His. Therefore, endogenous N urinary loss is not a protein secretion per se. From studies with low CP dietary intake, daily excretion of endogenous urea has been quantified as 10 mg N/BW per day (Hutchinson and Morris, Reference Hutchinson and Morris1936; Biddle et al., Reference Biddle, Evans and Trout1975; Marini and Van Amburgh, Reference Marini and Van Amburgh2005; Wickersham et al., Reference Wickersham, Titgemeyer, Cochran, Wickersham and Gnad2008a and Reference Wickersham, Titgemeyer, Cochran, Wickersham and Mooref2008b). To predict creatinine excretion, a database using exclusive dairy breeds, with growing and mature animals (111 treatment means from 24 publications from 1979 to 2015: Supplementary Material S1) was built. Urinary excretion of creatinine was regressed to 25.5 mg creatinine/BW per day, representing 9.46 ± 0.157 mg N/BW per day. Creatine excretion was evaluated as 0.37 that of creatinine (Blaxter and Wood, Reference Blaxter and Wood1951; Nehring et al., Reference Nehring, Zelck and Schiemann1965; Bristow et al., Reference Bristow, Whitehead and Cockburn1992). Urinary excretion of endogenous PD was assumed to average 27.1 mg N/BW0.75 per day (483 µmol/BW0.75: reviews from Tas and Susenbeth, Reference Tas and Susenbeth2007; Fujihara and Shem, Reference Fujihara and Shem2011). Daily urinary excretion of 3-methyl-His (µmol) was evaluated at 50.4 + 3.54 × BW (Harris and Milne, Reference Harris and Milne1981).

Using the database from Spek et al. (Reference Spek, Dijkstra, van Duinkerken, Hendriks and Bannink2013), the ‘measured’ endogenous urinary N excretion was calculated as non-urea urinary excretion plus endogenous urea (predicted as described above) minus estimation of PD derived from absorbed microbial protein (Chen and Gomes, Reference Chen and Gomes1992). The sum of predictions described above represented 54% of the ‘measured’ endogenous urinary N excretion. As previously mentioned, hippuric acid is another N metabolite excreted in urine. Hippuric acid is formed in the liver to detoxify benzoic acid originating from rumen fermentation of dietary phenolic compounds. Although this excretion cannot be purely defined as ‘endogenous’, it has probably been included in previous predictions of endogenous urinary N excretion. When determined, it averaged 25.7% of non-urea N urinary excretion (Nehring et al., Reference Nehring, Zelck and Schiemann1965; Bristow et al., Reference Bristow, Whitehead and Cockburn1992; Kool et al., Reference Kool, Hoffland, Hummelink and van Groenigen2006). Including hippuric acid to the ‘endogenous’ urinary excretion, the calculated v. ‘measured’ values from Spek’s database were not different (29.3 ± 4.5 v. 33.4 ± 15.4 g N/day), but there was a strong slope bias. The potential hippuric acid excretion was best related, in the database, to the proportion of urea N in urinary N excretion. Using this relationship to evaluate hippuric acid excretion, the calculated endogenous urinary N excretion averaged 33.2 ± 11.2 g N/day compared with 33.4 g N/day for the 84 treatment means ‘measured’ as described above. Although smaller, there remained a slope bias that could not be corrected, indicating an important gap in our knowledge on the composition of urinary N excretion. Besides hippuric acid, most of the estimations of urinary excretion were based on BW, and the sum of endogenous urinary N excretions was expressed relative to BW, averaging 53 mg N/BW (or 0.053 g N/BW) per day. Using a totally different approach, the prediction of daily endogenous urinary N loss averages 50 mg N/BW in the formulation model of the Institut National de Recherche Agronomique (INRA, 2018), very similar to our prediction and roughly twice as large as the Swanson (Reference Swanson1977) prediction. As these compounds are expressed in g N/day, there is no need to convert from CP to TP. Therefore,

(4)$${\rm{TP\, endogenous\, urinar}}{{\rm{y}}_{{\rm{secretion}}}}\left( {{\rm{g/day}}} \right){\rm{ }} = {\rm{ }}0.33{\rm{ }} \times {\rm{ BW}}$$

where 0.33 is derived from 0.053 × 6.25.

Amino acid composition

The reason for revisiting endogenous urinary excretion was to identify which AA were upstream of these urinary excretions. After the examination of metabolic pathways yielding each of these urinary excreted compounds, only endogenous urea and 3-methyl-His excretions require a direct input of essential AA (EAA), if we exclude Arg from true EAA. Indeed, endogenous PD are synthesized from Asp, Gln and Gly; creatine and creatinine from Arg and Gly (it requires S-adenosyl Met, but as for other metabolic pathways, this does not represent a net Met requirement); and hippuric acid is synthesized from Gly. Endogenous urea excretion is assumed to have a revisited whole empty body AA composition (Williams, Reference Williams1978; Rohr and Lebzien, Reference Rohr and Lebzien1991; Ainslie et al., Reference Ainslie, Fox, Perry, Ketchen and Barry1993; Van Amburgh et al., Reference Van Amburgh, Collao-Saenz, Higgs, Ross, Recktenwald, Raffrenato, Chase, Overton, Mills and Foskolos2015); the mean of these studies, corrected for incomplete recovery of AA with 24-h hydrolyses, is reported on a TP basis in Table 1. Therefore, to determine AA secretion in endogenous urinary N output, we need first to calculate endogenous urea excretion,

(5)$${\rm{TP\, endogenous\, urinary \hyphen ure}}{{\rm{a}}_{{\rm{secretion}}}}\left( {{\rm{g/day}}} \right){\rm{ }} = {\rm{ }}0.0625{\rm{ }} \times {\rm{ BW}},$$

where 0.0625 was derived from 0.010 g N/day × 6.25; and multiply this secretion by the corresponding AAcorr composition, assumed to be that of whole empty body (Table 1).

(6)$${\rm{AA\, endogenous\, urinar}}{{\rm{y}}_{{\rm{secretion}}}}\left( {{\rm{g/day}}} \right){\rm{ }} = 0.0625{\rm{ }} \times {\rm{ BW }} \times {\rm{ }}\left[ {{\rm{A}}{{\rm{A}}_{{\rm{corr}} - {\rm{WholeEmptyBody}}}}} \right]/100$$

where (AAcorr–WholeEmptyBody) is in g AA/100 g TP.

To complete the estimation of His excretion in endogenous urinary loss, 3-methyl His urinary excretion, as described above (mg His/day = 7.82 + 0.55 × BW), needs to be added. And finally, to complete the estimation of contribution of Arg to urinary N excretion, we need to include its contribution to creatinine and creatine, that is, 0.052 × BW g Arg/day.

Metabolic fecal protein secretion

True protein secretion

This is certainly protein secretion with the largest discrepancy in its prediction varying, for example, between 337 and 621 g/day for a cow eating 23 kg/day of a 16.5% CP diet when predicted with five formulation models (Lapierre et al., Reference Lapierre, Larsen, Sauvant, Van Amburgh and Van Duinkerken2018). Reasons for this high discrepancy are inherent to the difficulty in performing its measurements and to the ambiguous definition of MFP. First, the determination of MFP in ruminants cannot be done as simply as in monogastrics where MFP is measured in animals fed an N-free diet. Predictions of MFP in ruminants have been based on regressing intake of digestible CP on CP intake with the negative intercept estimated as MFP, averaging, for example, 34, 33 and 29 g CP/kg DM intake (DMI) in earlier studies (Holter and Reid, Reference Holter and Reid1959; Waldo and Glenn, Reference Waldo and Glenn1984) comparable to 32 and 27 g CP/kg DMI reported in more recent studies (Jonker et al., Reference Jonker, Kohn and Erdman1998; Kauffman and St-Pierre, Reference Kauffman and St-Pierre2001). In a meta-analysis using 65 growing-finishing cattle studies (291 treatment means) and 43 dairy cow studies (164 treatment means), Marini et al. (Reference Marini, Fox and Murphy2008) obtained an intercept of 30 g CP/kg DMI when ignoring the multidimensionality of the relationship with other parameters. Predictions of MFP have also been calculated subtracting predicted undigested feed N from fecal N when animals were fed low CP diets (29.4 g CP/kg DMI; Swanson, Reference Swanson1977). However, it has been demonstrated that MFP losses are related more closely to feces output than to feed intake (Swanson, Reference Swanson1977): for this reason, some formulation models have based their estimation of MFP on indigestible DM (CNCPS; Fox et al., Reference Fox, Tedeschi, Tylutki, Russell, Van Amburgh, Chase, Pell and Overton2004) or the outflow of organic matter from the digestive tract (NorFor, 2011; INRA, 2018). However, because of the uncertainty related to the estimation of DM digestibility, the National Research Council (2001) predicted MFP based on DMI.

However, the values obtained from the methods described above are not strictly a measure of loss of true protein from endogenous origin. Indeed, it was already raised at the beginning of the 1980s that these estimations of MFP included bacteria and bacterial debris (Swanson, Reference Swanson and Owens1982) and then the question ‘Is the source of bacteria primarily waste N rather than a metabolic cost to the animal?’ was raised (question from Trenkle: Swanson, Reference Swanson and Owens1982). Indeed, the metabolic demand for MFP should be only derived from endogenous secretions originating directly from AA (either from arterial supply and small intestinal digestion) and not from urea recycled into microbial protein. Therefore, NRC (2001), recognizing that a part of this fecal material contains undigested ruminal microbial CP, assumed that 50% of indigestible microbial protein appears in the feces and should be excluded from initial MFP prediction.

To improve the estimation of endogenous secretions through the gut in dairy cows, Ouellet et al. (Reference Ouellet, Demers, Zuur, Lobley, Seoane, Nolan and Lapierre2002 and Reference Ouellet, Berthiaume, Holtrop, Lobley, Martineau and Lapierre2010) adapted an isotopic dilution approach used in pigs (e.g. Lien et al., Reference Lien, Sauer, Mosenthin, Souffrant and Dugan1997) and sheep (Sandek et al., Reference Sandek, Krawielitzki, Kowalczyk, Kreienbring, Schoenhusen, Gabel, Zebrowska, Hagemeister and Voigt2001). This approach allowed the development of a model delineating the contribution of undigested rumen bacteria synthesized from endogenous secretions or from urea to fecal N, thus allowing the exclusion of the latter from MFP. Because endogenous proteins have multiple origins (saliva, gastric juices, bile, pancreatic secretions, sloughed epithelial cells and mucin: Tamminga et al., Reference Tamminga, Schulze, Van Bruchem and Huisman1995), it is a challenge to determine the isotopic enrichment of the precursor pool when using a dilution approach. Values obtained using the enrichment of the mucosa as representative of endogenous secretions have been retained for this revision. Furthermore, the metabolic cost of the loss of undigested endogenous secretion across the upper gut should be measured at the ileum, because the endogenous secretions flowing out of the small intestine and disappearing across the hindgut do not result in absorbed AA. Endogenous fecal loss was, therefore, adjusted using a factor of 1.13, representing the ratio of ileal endogenous flow divided by fecal endogenous flow, measured in dairy cows (Ouellet et al., Reference Ouellet, Valkeners, Holtrop, Lobley and Lapierre2007). Therefore, the prediction of endogenous ileal flow calculated using the enrichment of gut mucosa was retained as a basis for the estimation of MFP, averaging 14.9 g CP/kg DMI (Lapierre et al., Reference Lapierre, Lobley, Ouellet, Doepel and Pacheco2007).

Although MFP is calculated relative to DMI, as discussed above, it has been recognized that the driving force of MFP should be indigestible DM (Swanson, Reference Swanson1977). However, because of the uncertainties associated with estimating DM digestibility, we propose to still use DMI as a basis to predict MFP, but to include the neutral detergent fiber of the ration (NDF, %DM) based on Marini et al. (Reference Marini, Fox and Murphy2008) regression of total tract digestibility of N v. N content of the diet. This inclusion will partially account for diet DM digestibility. The Marini equation also included a carbohydrate fermentation rate (fast, medium or none), but for practical purposes and to remove subjectivity, the average of three values was used to derive the final equation. Therefore, the equation of Marini et al. (Reference Marini, Fox and Murphy2008) was adjusted to yield the value mentioned above at 14.9 g CP/kg DMI for cows fed diets at 36% NDF (in the rations in Ouellet et al., Reference Ouellet, Demers, Zuur, Lobley, Seoane, Nolan and Lapierre2002, Reference Ouellet, Valkeners, Holtrop, Lobley and Lapierre2007 and Reference Ouellet, Berthiaume, Holtrop, Lobley, Martineau and Lapierre2010). In addition, endogenous secretions occurring across the hindgut also create a demand on AA as demonstrated in pigs (Zhu et al., Reference Zhu, Lapierre, Rademacher, de Lange and Ball2003). Based on observations in sheep (Sandek et al., Reference Sandek, Krawielitzki, Kowalczyk, Kreienbring, Schoenhusen, Gabel, Zebrowska, Hagemeister and Voigt2001), this demand was estimated as 60% of N ileal flow of small intestinal endogenous secretion, the latter averaging 5.1 g CP/kg DMI in dairy cows (Ouellet et al., Reference Ouellet, Valkeners, Holtrop, Lobley and Lapierre2007). Due to the scarcity of data on the exact origin of this hindgut N, it is assumed that half of this input originated from endogenous proteins and the other half from urea. Therefore, the estimation of MFP excretion (g CP/day) = (11.62 + 0.134 ×NDF%DM) × DMI. Note that we keep the term metabolic fecal protein, although the small intestinal loss was truly predicted at the ileum. Based on its AA composition, detailed below, and N content, a ratio of 0.73 for TP/CP of MFP is calculated and

(7)$${\rm{TP\, MF}}{{\rm{P}}_{{\rm{secretion}}}}\left( {{\rm{g/day}}} \right) = \left( {8.5{\rm{ }} + {\rm{ }}0.1{\rm{ }} \times {\rm{ ND}}{{\rm{F}}_{{\rm{\% DM}}}}} \right) \times {\rm{DMI}}$$

where NDF%DM is the percentage of NDF in the ration; here and throughouot the text, DMI is in kg/day.

Amino acid composition

The AA composition of MFP is based on the AA composition of ruminal and abomasal isolates from Ørskov et al. (Reference Ørskov, McLeod and Kyle1986) and the endogenous flow at the ileum in pigs (Jansman et al., Reference Jansman, Smink, Van Leeuwen and Rademacher2002), assuming that 70% of MFP is from undigested endogenous duodenal flow and the remaining 30% from the intestine (Ouellet et al., Reference Ouellet, Demers, Zuur, Lobley, Seoane, Nolan and Lapierre2002 and Reference Ouellet, Berthiaume, Holtrop, Lobley, Martineau and Lapierre2010). The averaged composition corrected for incomplete recovery of AA with 24-h hydrolyses is reported on a TP basis in Table 1. Therefore, individual AA secretion in MFP is calculated as:

(8)$${\rm{AA}}\,{\rm{MF}}{{\rm{P}}_{{\rm{secretion}}}}({\rm{g}}/{\rm{day}}) = [(8.5 + 0.1 \times {\rm{ND}}{{\rm{F}}_{{\rm{\% DM}}}}) \times {\rm{DMI}}] \times [{\rm{A}}{{\rm{A}}_{{\rm{corr}} - {\rm{MFP}}}}]/100$$

where (AAcorr–MFP) is in g AA/100 g TP.

Milk

True protein secretion

Milk true protein secretion is certainly the most accurate measurement of export protein to make. The factor used to convert the measured milk N concentration into CP varies between 6.34 and 6.39. Based on the AA composition of milk protein, 6.34 would be the best factor (Karman and van Boekel, Reference Karman and van Boekel1986; authors’ calculations), but using different factors only has a limited impact on the estimation of MPY, smaller than 1%. Similar to other protein secretions, it has to be expressed as TP. If the TP/CP ratio is not known, NPN content of milk is assumed to be 4.9% (DePeters and Cant, Reference DePeters and Cant1992).

Amino acid composition

Although critical in the definition of AA requirements, milk AA composition has not been recently investigated. Indeed, early studies reported (1) that the EAA composition of milk produced from cows fed urea and ammonium N as the sole source of N differed by <3% from the EAA composition of milk from control cows (Syvaöja and Virtanen, Reference Syvaöja and Virtanen1965), and (2) that a change in the forage–grain ratio of the ration did not alter the AA composition of milk (Featherston et al., Reference Featherston, Frazeur, Hill, Noller and Parmelee1964). From these observations, it has been assumed that the AA composition of milk protein is fairly constant, and this dogma has not been really challenged. Therefore, milk AA composition is still assumed to be constant, although this issue might need to be re-addressed with improved techniques to measure AA concentration. The same approach as that used in Swaisgood (Reference Swaisgood and Jensen1995) has been adopted to determine the AA composition of milk TP. Milk AA composition has been calculated based on the primary structure of reference protein of each family as detailed by Farrell et al. (Reference Farrell, Jimenez-Flores, Bleck, Brown, Butler, Creamer, Hicks, Hollar, Ng-Kwai-Hang and Swaisgood2004). Based on the distribution of milk proteins reported in 15 manuscripts published between 1980 and 2012 (Supplementary Material S2), protein fractions in milk TP were assumed to be 82.4% casein (as a percentage of total protein: 35.2% αs1-casein; 7.6% αs2-casein; 30.9% β-casein; 8.7% κ-casein) and 17.6% whey (as a percentage of total protein: 3.7% α-lactalbumin; 10.5% β-lactoglobulin; 1.04% albumin; 1.64% IgG1; 0.21% IgG2; 0.04% IgA; 0.33% IgM; 0.21% lactoferrin). The AA composition of milk protein calculated using this procedure is presented in Table 1. Therefore, individual AA secretion in milk protein is calculated as:

(9)$${\rm{AA}}\,{\rm{Mil}}{{\rm{k}}_{{\rm{secretion}}}}({\rm{g}}/{\rm{day}}) = {\rm{MPY}}({\rm{g}}/{\rm{day}}) \times [{\rm{A}}{{\rm{A}}_{{\rm{calc}} - {\rm{Milk}}}}]/100$$

where AAcalc-Milk is in g/100 g TP.

Using this approach for milk, there is no need to do any correction for potential loss due to an incomplete recovery with hydrolyses. Due to the high diversity of proteins included in other types of secretions, an approach similar to milk protein cannot be used for these former proteins; therefore, the only way to obtain their AA composition is by hydrolysis. To correctly sum the AA in protein secretions, we used corrected AA concentrations for all protein secretions and calculated AA concentrations for milk.

Efficiency of utilization of metabolizable protein and amino acids

Variable efficiency

It is recognized that the efficiency of utilization of MP (EffMP) to support MPY is not fixed. Indeed, the marginal recovery of abomasal casein infusions averaged 21%, ranging from −5% to 45% in seven studies (Hanigan et al., Reference Hanigan, Cant, Weakley and Beckett1998), far below the traditional fixed efficiency of lactation of 65% to 67%. More recently, the marginal recovery of 81 comparisons of MPY response to post-rumen casein infusions averaged 24%, and was negatively related to the MP balance of control treatment (Martineau et al., Reference Martineau, Ouellet, Kebreab, White and Lapierre2017). A similar trend is observed when variation in MP supply is achieved through a dietary change. For example, Metcalf et al. (Reference Metcalf, Mansbridge, Blake, Oldham and Newbold2008) reported that the efficiency of lactation decreased from 77% to 50% when MP supply varied from 25% below to 25% above requirements, the efficiency for maintenance requirement assumed to be fixed.

In addition to MP supply per se, energy supply also has an impact on EffMP. Increments in MPY have been observed in response to post-ruminal supply of energy, either as glucose (Vanhatalo et al., Reference Vanhatalo, Varvikko and Huhtanen2003a; Nichols et al., Reference Nichols, Kim, Carson, Metcalf, Cant and Doelman2016), propionate (Raggio et al., Reference Raggio, Lobley, Berthiaume, Pellerin, Allard, Dubreuil and Lapierre2007) or dietary rumen-inert fat (Nichols et al., Reference Nichols, Bannink, Pacheco, van Valenberg, Dijkstra and van Laar2018), although not always (e.g. Clark et al., Reference Clark, Spires, Derrig and Bennink1977; Vanhatalo et al., Reference Vanhatalo, Varvikko and Huhtanen2003b). Obviously, MPY increment in response to increased post-rumen energy supply (no effect on MP supply) increased EffMP. Using 825 treatment means, Daniel et al. (Reference Daniel, Friggens, Chapoutot, Van Laar and Sauvant2016) concluded that both MP and net energy of lactation (NEL) supplies increased MPY, the effects being additive, as observed in most of the individual studies where the interaction was tested. Only the study of Brun-Lafleur et al. (Reference Brun-Lafleur, Delaby, Husson and Faverdin2010) reported a protein × energy interaction with a very targeted experimental design.

Therefore, there was enough evidence of the good use of a variable EffMP, related to both MP and energy supplies. Currently, NorFor (2011) and the DVE/OEB (Van Duinkerken et al., Reference Van Duinkerken, Blok, Bannink, Cone, Dijkstra, Van Vuuren and Tamminga2011) system are using a fixed efficiency for maintenance and a variable efficiency for lactation. Although not estimating directly EffMP, INRA (2018) is using MP and NEL supplies to predict MPY, thereby introducing a variable EffMP for non-productive and lactation functions. Introducing a variable EffMP in the formulation models was yielding a better prediction of MPY in response to variations in MP and/or energy supply than the use of a fixed EffMP, still in use in most current North American models (Lapierre et al., Reference Lapierre, Larsen, Sauvant, Van Amburgh and Van Duinkerken2018).

Combined efficiency

Based on the observed metabolism of AA across tissues, it has been proposed to use a single EffAA, different for each AA but identical for all the protein functions (Lapierre et al., Reference Lapierre, Lobley, Ouellet, Doepel and Pacheco2007). The reason for this suggestion is that EAA catabolism does not occur at the site of protein synthesis or protein secretion but does occur in the organ(s) where appropriate enzymes are present (Lobley and Lapierre, Reference Lobley, Lapierre, Souffrant and Metges2003). For example, mammary uptake of Group 2 AA (Ile, Leu, Lys and Val) is in excess of MPY and the excess increases with MP supply; in contrast, Group 1 AA (His, Met, Phe+Tyr and Trp) net mammary uptake is almost equivalent to their secretion into milk protein (Lapierre et al., Reference Lapierre, Lobley, Doepel, Raggio, Rulquin and Lemosquet2012). Therefore, it is proposed to use a single EffMP and EffAA (one for each EAA) for all the protein functions, except endogenous urinary loss. The latter represents end-products of metabolic pathways, and an efficiency of 1.0 should be used (Sauvant et al., Reference Sauvant, Catalapiedra-Hijar, Delaby, Daniel, Faverdin and Nozière2015). Sauvant et al. (Reference Sauvant, Catalapiedra-Hijar, Delaby, Daniel, Faverdin and Nozière2015) reported that EffMP was better predicted when the same efficiency was assigned to all protein functions rather than a fixed efficiency for the non-productive functions and a variable efficiency for lactation.

With the objective of balancing dairy rations on an AA basis rather than MP basis, we developed equations to predict EffMP and EffAA in relation to MP or AA and energy supplies, which has not been done yet. Variable EffAA has already been proposed, but solely related to AA supply (Doepel et al., Reference Doepel, Pacheco, Kennelly, Hanigan, López and Lapierre2004).

Calculation of efficiency

MP supply and AA net digestible flow were calculated as the sum of digestible flow from rumen-undegraded protein (RUP) flow and microbial protein; endogenous duodenal flow was not included. The model of White et al. (Reference White, Kononoff and Firkins2017) was used to predict RUP flows, with the AA composition of RUP assumed to be the AA composition of feed ingredients; the equation from Roman-Garcia et al. (Reference Roman-Garcia, White and Firkins2016) was used to predict microbial N, with an adjustment proposed by Myers et al. (Reference Myers, Lapierre, White, Tran, Kononoff, Martineau, Weiss and Hanigan2018), converted to microbial true protein assuming 16% N, and using the TP/CP (82.4%) ratio and the AA composition from Sok et al. (Reference Sok, Ouellet, Firkins, Pellerin and Lapierre2017).

Using the supplies and secretions described above, the combined EffMP or EffAA was calculated as follows:

(10)$${\rm{Ef}}{{\rm{f}}_{{\rm{MP}}}} = ({\rm{TP}}\,{\rm{scur}}{{\rm{f}}_{{\rm{secretion}}}} + {\rm{TP}}\,{\rm{MF}}{{\rm{P}}_{{\rm{secretion}}}} + {\rm{MPY}})/{\rm{MP}}\,{\rm{suppl}}{{\rm{y}}_{{\rm{adj}}}}$$

where MP supplyadj = MP supply – TP endogenous urinarysecretion and

(11)$${\rm{Ef}}{{\rm{f}}_{{\rm{AA}}}} = ({\rm{AA}}\,{\rm{scur}}{{\rm{f}}_{{\rm{secretion }}}} + {\rm{AA}}\,{\rm{MF}}{{\rm{P}}_{{\rm{secretion }}}} + {\rm{AA}}\,{\rm{Mil}}{{\rm{k}}_{{\rm{secretion}}}})/{\rm{AA}}\,{\rm{net}}\,{\rm{digestible}}\,{\rm{flo}}{{\rm{w}}_{{\rm{adj}}}}$$

where AA net digestible flowadj = AA net digestible flow – AA endogenous urinarysecretion. In the text, MP supplyadj will be referred to as MPadj, and AA net digestible flowadj as AAadj.

Prediction of efficiency

Databases

The calculations described above were applied to two databases, one used for the development of models, and the second for their validation. The developmental database included 208 publications (807 treatment means) and was an extension of the database used by Roman-Garcia et al. (Reference Roman-Garcia, White and Firkins2016) with studies added to offer a wider range of AA supply. An independent validation database was also built, including 32 publications (129 treatment means). The summary statistics of developmental and validation databases are presented in Tables 2 and 3, respectively. Publications included in the developmental database and in the validation database are listed in Supplementary Material S3. In both databases, studies have been coded to look specifically at the increment of MP supply. The relationship between MPY and MP supply depicts the overall meta-design (Figure 1).

Table 2 Summary statistics of the developmental database (n = 807) from studies conducted in lactating dairy cows

MP = metabolizable protein; MPadj = metabolizable protein supply minus endogenous urinary loss; DE = digestible energy.

Table 3 Summary statistics of the validation database (n = 129) from studies conducted in lactating dairy cows

MP = metabolizable protein; MPadj = metabolizable protein supply minus endogenous urinary loss; DE = digestible energy.

Figure 1 Relationship between milk true protein yield and metabolizable protein (MP) supply in lactating dairy cows in the developmental and validation databases.

Statistics

Models predicting EffMP were developed using variables that were strong predictors of the sum of protein secretions when tested individually: MPadj, digestible energy intake (DEI), days in milk (DIM) and parity (primiparous v. multiparous). Digestible energy was used because metabolizable energy requires the estimation of urinary N, unknown until the efficiency is predicted, and net energy requires, in addition, the quantification of MPY: both are unknown that we are trying to predict. Digestible energy was predicted based on nutrient digestibility (Daley et al., Reference Daley, Armentano, Kononoff, Prestegaard and Hanigan2018; de Souza et al., Reference de Souza, Tempelman, Allen, Weiss, Bernard and VandeHaar2018). Models tested the linear and quadratic effects of (1) MPadj, (2) MPadj and DEI and (3) MPadj/DEI; DIM and parity were tested in all models.

Models were developed using the rma.mv function from the metafor package in R. Potential outlying and influential observations and studies were detected using the rstandard, the rstudent and the cook.distance functions in the metafor package. All relationships were graphed and evaluated using the ggplot function of the ggplot2 package for R (Wickham, Reference Wickham2016). Using the rma.mv function of metafor, the hierarchy of studies, as a random effect, was taken into account. For example, two or more different studies could be reported in the same experiment; therefore, data were fitted to a three-level mixed-effect meta-regression model. To weigh data by √N, the V argument was set to zero and the R argument was used to specify a known matrix, that is, diag(1/developmental_database$Nexp0.5), with an unknown multiplicative variance component which was then estimated by metafor (Viechtbauer, Reference Viechtbauer2018). Unbiased estimates of fixed effects and valid estimates of SE were obtained using the robust function in the metafor package with publication as the clustering variable. The use of robust function does not change the weight matrix but only affects the way the variance–covariance matrix of the fixed effects and downstream SE and P values are computed (Viechtbauer, Reference Viechtbauer2017a and Reference Viechtbauer2017b). Model performance was evaluated using RMSE and root mean squared prediction error (RMSPE) for the development and validation databases as a percentage of the observed mean. Mean bias and slope bias, which are two MSE decomposition terms, were also computed and expressed as a percentage of MSE (Theil, Reference Theil1966; Bibby and Toutenburg, Reference Bibby and Toutenburg1978). Concordance correlation coefficients (CCC; Lin, 1989 and Reference Lin1992) and the corrected Akaike’s information criterion (AICc; Hurvich and Tsai, Reference Hurvich and Tsai1993) are also reported. Ideal models are those with RMSE closest to 0, CCC closest to 1, mean and slope biases closest to 0, and smallest AICc.

Factors affecting efficiency

We initially tested the models using MPadj as a surrogate of individual AAadj to delineate which model(s) would yield the best goodness of fit. Three models are reported in Table 4: EffMP as a function of MPadj and its squared term (equation 12); the latter plus DEI and its squared term (equation 13); and the ratio of MPadj/DEI and its squared term (equation 14); DIM and parity were significant in the three models. The inclusion of DEI, either as an independent term (equation 13) or as a ratio with MPadj (equation 14), improved the goodness of fit compared with MP terms alone (Figure 2), as shown by a substantial reduction of AICc, a large decrease in slope bias in both the developmental and validation databases and an increased CCC (Table 4). The improvement of the relationship of EffMP with MPadj/DEI compared with MPadj can also be visually appreciated in Figure 3. This agrees with a better prediction of MPY when energy supply is included in the model than based only on MP supply (Doepel et al., Reference Doepel, Pacheco, Kennelly, Hanigan, López and Lapierre2004) or with a final model which includes both protein and energy supplies (Daniel et al., Reference Daniel, Friggens, Chapoutot, Van Laar and Sauvant2016). Although equation (13) yielded a slightly lower AICc than equation (14), in the validation database, the slope bias was larger with the former equation and CCC was lower. Currently, two European systems, the DVE/OEB (Van Duinkerken et al., Reference Van Duinkerken, Blok, Bannink, Cone, Dijkstra, Van Vuuren and Tamminga2011) and NorFor (2011), are using the ratio of MP/NEL available for milk to predict the efficiency of lactation and MPY; Sauvant et al. (Reference Sauvant, Catalapiedra-Hijar, Delaby, Daniel, Faverdin and Nozière2015) estimated that EffMP was better related to MP/DMI than MP/NEL. Another main advantage of using the ratio is the practicality of transferring results to ‘cows of the future’ eating more and producing more than cows from the studies included in the current review. In theory, predictive equations should be used within the range of values of predictors used for their development. Even if cows in commercial farms are eating more than observations in the developmental database, the ratio MPadj/DEI remains within the limits of current observations, whereas MPadj and DEI of high-producing dairy cows are already higher than the maxima observed in the developmental database. Therefore, we decided to use MPadj/DEI as the driving force of EffMP and apply the same concept to individual AAadj. Results for EffAA, equations (15) to (24), are presented in Table 5. All estimates were highly significant (P < 0.01) for all variables except parity (P < 0.05). Globally, the trends were very similar for the estimation of EffAA compared with EffMP, that is, very low mean and slope bias in the developmental database and a mean bias of ±5% MSE in the validation database. In both databases, His and Trp were used with the highest efficiency, and Phe and Thr with the lowest. Values are in the same range as previously reported for combined efficiency (Lapierre et al., Reference Lapierre, Lobley, Ouellet, Doepel and Pacheco2007; Van Amburgh et al., Reference Van Amburgh, Collao-Saenz, Higgs, Ross, Recktenwald, Raffrenato, Chase, Overton, Mills and Foskolos2015) except for Arg being much higher and Lys and Met being lower. The large difference for Arg is due to the change in the prediction of AA in endogenous urinary loss: the current proposition involves an important loss of Arg related to creatine and creatinine urinary excretion decreasing substantially Argadj. Also, Arg displayed high CCC but had a large slope bias in the validation database, probably related to the uncertainty of its true supply due to unknown and unaccounted supply from de novo synthesis. In fact, for this reason, although given for a comparison, the current estimates for Arg should not be used. It is also important to note that the current estimates could only be used to predict efficiency until the minimal predicted efficiency is reached according to the quadratic function: after that threshold ratio of AAadj/DEI, the function will not apply. These threshold ratios are in AAadj/DEI (g/MJ): 0.31, 0.67, 1.23, 0.92, 0.32, 0.82, 0.58, 0.15 and 0.73 for His, Ile, Leu, Lys, Met, Phe, Thr, Trp and Val, respectively. In the validation database, only one treatment mean was higher than the threshold ratio for His at 0.32, whereas the ratios were all lower than the threshold values in the validation database.

Table 4 Models of efficiency of utilization of metabolizable protein (MP)1 in lactating dairy cows

AICc = corrected Akaike’s information criterion; CCC = concordance correlation coefficient; RMSPE = root mean squared prediction error.

1 Efficiency of utilization of MP = (true protein secretion in milk + scurf + metabolic fecal protein)/MPadj × 100.

2 MPadj (kg/d): metabolizable protein supply minus endogenous urinary loss; DEI (MJ/d): digestible energy intake; DIM: days in milk; parity (1 = primiparous; 0 = multiparous).

Figure 2 Observed (•) and residual (▴) values of efficiency of utilization of metabolizable protein in the function of efficiency predicted according to equations (12), (13) and (14) (see text for details of the equations) in lactating dairy cows in the validation database.

Figure 3 Relationship between efficiency of utilization of metabolizable protein (MP) and MP adjusted (MP supply minus endogenous urinary loss) or the ratio of MP adjusted/digestible energy (DE) intake in lactating dairy cows in the developmental database. Efficiency is calculated as (true protein in milk + scurf + metabolic fecal)/MP adjusted.

Table 5 Models of efficiency of utilization of individual amino acids (AA)1 in lactating dairy cows

CCC = concordance correlation coefficient; RMSPE = root mean squared prediction error.

1 Efficiency of utilization of AA = (AA secretion in milk + scurf + metabolic fecal protein)/AAadj × 100.

2 AAadj (g/d): net flow of digestible AA supply minus endogenous urinary loss; DEI (MJ/d): digestible energy intake; DIM: days in milk; parity (1 = primiparous; 0 = multiparous); all estimates were significant: P < 0.01 for all parameters except parity where P < 0.05.

Degree of significance = $P ≤ 0.10; *P ≤ 0.05; ***P ≤ 0.001.

Efficiency of utilization and prediction of milk true protein yield

The ultimate goal in the estimation of EffMP and EffAA is the prediction of MPY which was calculated either as:

(25)$${\rm{MPY}} = {\rm{M}}{{\rm{P}}_{{\rm{adj}}}} \times {\rm{ Ef}}{{\rm{f}}_{{\rm{MP}}}} - {\rm{ }}\left( {{\rm{TP\, scur}}{{\rm{f}}_{{\rm{secretion}}}} + {\rm{TP MF}}{{\rm{P}}_{{\rm{secretion}}}}} \right)$$

or

(26)$${\eqalign{\rm{MPY}} = ({\rm{A}}{{\rm{A}}_{{\rm{adj}}}} \times {\rm{Ef}}{{\rm{f}}_{{\rm{AA}}}} - ({\rm{AA}}\,{\rm{scur}}{{\rm{f}}_{{\rm{secretion}}}} + {\rm{AA}}\,{\rm{MF}}{{\rm{P}}_{{\rm{secretion}}}}))/[{\rm{A}}{{\rm{A}}_{{\rm{calc}} - {\rm{Milk}}}}] \times 100$$

First it appeared clearly that the prediction of EffMP based solely on MPadj (equation 12) predicts MPY with a low CCC in both databases (Table 6). As observed for the prediction of the efficiencies themselves, adding DEI to MP into the prediction equations greatly improved the predictions of MPY. Adding DEI as an independent variable (equation 13) improved CCC; slope bias contributed to a greater proportion of the total prediction error, but the total error decreased in the validation database (Table 6). Finally, the equation, including the ratio MPadj/DEI, provided the best goodness of fit in the two databases, with the highest CCC. For a comparison, a model was developed to predict the sum of protein secretions (MPY + MFP + scurf) directly from MPadj, MPadj × MPadj, DEI, DIM and parity; MPY was then calculated as predicted protein secretions minus (MFP + scurf). The equation is:

(27)$${\rm{Protein\, secretions}} = 160{\rm{ }}\left( { \pm 79} \right) + 381\left( { \pm 74} \right) \times {\rm{M}}{{\rm{P}}_{{\rm{adj}}}} -74\left( { \pm 19} \right) \times {\rm{M}}{{\rm{P}}_{{\rm{adj}}}} \times {\rm{M}}{{\rm{P}}_{{\rm{adj}}}} + 2.49\left( { \pm 0.22} \right) \times {\rm{DEI}} - 0.6\left( { \pm 0.1} \right) \times {\rm{DIM}}-100\left( { \pm 21} \right) \times {\rm{parity}}\left( {1 = {\rm{primiparous}},0 = {\rm{multiparous}}} \right)$$

Table 6 Predicted milk true protein yield (MPY, g/d) based on estimates of the efficiency of utilization of metabolizable protein (EffMP) or predicted directly in lactating dairy cows

CCC = concordance correlation coefficient; RMSPE = root mean squared prediction error.

1 Equations detailed in the text; MPY = EffMP × MPadj – (scurf true protein + metabolic fecal true protein); MPadj (kg/d): metabolizable protein supply minus endogenous urinary loss.

2 Equation detailed in the text.

The squared term of DEI was not significant (P = 0.93). Predictions from this model are detailed in Table 6 and are not as good as those obtained when EffMP was predicted with equation (14). Moreover, a strong slope bias was observed in the validation database. Inclusion of the ratio MPadj/NEL supply in predictive models of EffMP to predict MPY also yielded the best predictions when different formulation models were compared (Lapierre et al., Reference Lapierre, Larsen, Sauvant, Van Amburgh and Van Duinkerken2018). Therefore, predicted EffAA from equations (15) to (24), for each EAA, were used to predict MPY (Table 7). All AA are yielding fairly similar predictions of MPY except Arg. A comparison between observed and predicted MPY was also made using several combinations to explore the impact of individual EffAA. Five combinations, all excluding predictions from Arg, are presented in Table 7, which are: the lowest of MPY predicted from EffAA (MinAA), the mean of nine MPY predicted from EffAA (MeanAA), the mean of MinAA and MeanAA (MinMeanAA) and the mean of estimations from His, Lys and Met (HLM). All predictions provided good fitness with observed MPY, and this is probably one of the limitations of the database and current work actually available. Although we extended the database from Roman-Garcia et al. (Reference Roman-Garcia, White and Firkins2016), trying to increase the number of studies where the supply of only one AA was changed at the time, in most of the studies variations of AA supply were achieved through a change in protein supply which affected simultaneously the supply of all AA. MinAA might be too severe, as the efficiency of a single AA might be maximized if only this one is in short supply (e.g. Lapierre and Ouellet, Reference Lapierre and Ouellet2015). Until we have further development, MinMeanAA might be a prudent option as it ponders an average predicted MPY with the prediction from AA most probably in shortest supply. By doing so, it would certainly be fortuitous to verify which AA is yielding the lowest prediction as this might provide a tool to identify the AA with the shortest supply relative to estimated requirements.

Table 7 Prediction of milk true protein yield (MPY, g/day) based on estimates of the efficiency of utilization of amino acids (EffAA) in lactating dairy cows

CCC = concordance correlation coefficient; RMSPE = root mean squared prediction error.

1 MPY = (Effaa × AAadj – (AA in scurf + AA in metabolic fecal))/concentration of AA in milk × 100; AAadj (g/d): net flow of digestible AA supply minus endogenous urinary loss.

2 Min: minimum predicted MPY; mean: average predicted MPY; max: maximum predicted MPY; HLM: average predicted MPY from His, Lys and Met; Arg predicted MPY excluded from all the combinations.

Conclusion

The development of a factorial approach to balance dairy rations for individual EAA is moving forward with improvement of the quantification of proteins exported out of the animal and their respective AA composition. The major net utilization of EAA supports secretion into MFP and MPY, with a limited contribution to endogenous urinary and scurf secretions. To this net utilization, an inefficiency (100 – efficiency) needs to be added: EffMP and EffAA are positively related to energy supply and negatively related to MPadj or AAadj. And finally, the predictions of EffMP and EffAA can be used successfully to predict MPY. Although the concepts derived in the current study can probably be extended to most of the models used to balance dairy rations, it has to be noted that the current figures only apply when using the assumptions as presented. Also, although protein accretion from growth in cows from first parity is acknowledged because parity (primiparous v. multiparous) was included in the model, other changes in protein mass, either through gain or loss of BW or gestation, were not accounted for. Finally, studies where the supply of a single EAA is changed incrementally are currently lacking to really fine-tune our estimations of individual EAA recommendations in dairy rations.

Acknowledgements

The salary of R Martineau was supported in main part by Agriculture and Agri-Food Canada, and by additional contributions from Dairy Farmers of Canada, the Canadian Dairy Network and the Canadian Dairy Commission under the Agri-Science Clusters Initiative. HJ van Lingen and E Kebreab acknowledge financial support from the Sesnon Endowed Chair Program of the University of California, Davis. Part of this review article is an update of a presentation given in an extension conference and published as an extension paper (Lapierre et al., Reference Lapierre, Ouellet, Martineau and Spek2016).

H. Lapierre 0000-0002-1162-7226

Declaration of interest

There is no potential conflicts of interest.

Ethics statement

None.

Software and data repository resources

None.

Supplementary material

To view supplementary material for this article, please visit https://doi.org/10.1017/S1751731119003173

References

Ainslie, SJ, Fox, DG, Perry, TC, Ketchen, DJ and Barry, MC 1993. Predicting amino acid adequacy of diets fed to Holstein steers. Journal of Animal Science 71, 13121319.CrossRefGoogle ScholarPubMed
Bibby, J and Toutenburg, H 1978. Improved estimation and prediction. Journal of Applied Mathematics 58, 4549.Google Scholar
Biddle, GN, Evans, JL and Trout, JR 1975. Labile nitrogen reserves and plasma nitrogen fractions in growing cattle. Journal of Nutrition 105, 15841591.CrossRefGoogle ScholarPubMed
Blaxter, KL and Wood, WA 1951. The nutrition of the young Ayrshire calf. I. The endogenous nitrogen and basal energy metabolism of the calf. British Journal of Nutrition 5, 1125.CrossRefGoogle Scholar
Bristow, AW, Whitehead, DC and Cockburn, JE 1992. Nitrogenous constituents in the urine of cattle, sheep and goats. Journal of the Science of Food and Agriculture 59, 387394.CrossRefGoogle Scholar
Broderick, GA 2018. Review: Optimizing ruminant conversion of feed protein to human food protein. Animal 12, 17221734.CrossRefGoogle ScholarPubMed
Brun-Lafleur, L, Delaby, L, Husson, F and Faverdin, P 2010. Predicting energy × protein interaction on milk yield and milk composition in dairy cows. Journal of Dairy Science 93, 41284143.CrossRefGoogle ScholarPubMed
Chen, XB and Gomes, MJ 1992. Estimation of microbial protein supply to sheep and cattle based on urinary excretion of purine derivatives: an overview of the technical details. International Feed Resources Unit, Rowett Research Institute, Aberdeen, UK.Google Scholar
Clark, H, Spires, HR, Derrig, RG and Bennink, MR 1977. Milk production, nitrogen utilization and glucose synthesis in lactating cows infused postruminally with sodium caseinate and glucose. The Journal of Nutrition 107, 631644.CrossRefGoogle ScholarPubMed
Daley, VL, Armentano, LE, Kononoff, PJ, Prestegaard, JM and Hanigan, MD 2018. Fatty acid digestion in dairy cows fed different fat sources: a meta-analytic approach. Journal of Dairy Science 101 (suppl. 2), 304.Google Scholar
Daniel, JB, Friggens, NC, Chapoutot, P, Van Laar, H and Sauvant, D 2016. Milk yield and milk composition responses to change in predicted net energy and metabolizable protein: a meta-analysis. Animal 10, 19751985.CrossRefGoogle ScholarPubMed
DePeters, EJ and Cant, JP 1992. Nutritional factors influencing the nitrogen composition of bovine milk: a review. Journal of Dairy Science 75, 20432070.CrossRefGoogle ScholarPubMed
de Souza, RA, Tempelman, RJ, Allen, MS, Weiss, WP, Bernard, JK and VandeHaar, MJ 2018. Predicting nutrient digestibility in high-producing dairy cows. Journal of Dairy Science 101, 11231135.CrossRefGoogle ScholarPubMed
Dijkstra, J, Oenema, O, van Groenigen, JW, Spek, JW, van Vuuren, AM and Bannink, A 2013b. Diet effects on urine composition of cattle and N2O emissions. Animal 7, 292302.CrossRefGoogle ScholarPubMed
Dijkstra, J, Reynolds, CK, Kebreab, E, Bannink, A, Ellis, JL, France, J and Van Vuuren, AM 2013a. Challenges in ruminant nutrition: towards minimal nitrogen losses in cattle. In Energy and protein metabolism and nutrition in sustainable animal production (ed. Oltjen, JW, Kebreab, E and Lapierre, H), pp. 4758. Wageningen Academic Publishers, Wageningen, The Netherlands.CrossRefGoogle Scholar
Doepel, L, Pacheco, D, Kennelly, JJ, Hanigan, MD, López, IF and Lapierre, H 2004. Milk protein synthesis as a function of amino acid supply. Journal of Dairy Science 87, 12791297.CrossRefGoogle ScholarPubMed
Ertl, P, Klocker, H, Hörtenhuber, S, Knaus, W and Zollitsch, W 2015. The net contribution of dairy production to human food supply: the case of Austrian dairy farms. Agricultural Systems 137, 119125.CrossRefGoogle Scholar
Farrell, HMJ, Jimenez-Flores, R, Bleck, GT, Brown, EM, Butler, JE, Creamer, LK, Hicks, CL, Hollar, CM, Ng-Kwai-Hang, KF and Swaisgood, HE 2004. Nomenclature of the proteins of cows’ milk - Sixth revision. Journal of Dairy Science 87, 16411674.CrossRefGoogle ScholarPubMed
Featherston, WR, Frazeur, DR, Hill, DL, Noller, CH and Parmelee, CE 1964. Constancy of amino acid composition of cow’s milk protein under changing ration. Journal of Dairy Science 47, 14171418.CrossRefGoogle Scholar
Fox, DG, Tedeschi, LO, Tylutki, TP, Russell, JB, Van Amburgh, ME, Chase, LE, Pell, AN and Overton, TR 2004. The Cornell Net carbohydrate and protein system model for evaluating herd nutrition and nutrient excretion. Animal Feed Science and Technology 112, 2978.CrossRefGoogle Scholar
Fujihara, T and Shem, MN 2011. Metabolism of microbial nitrogen in ruminants with special reference to nucleic acids. Animal Science Journal 82, 198208.CrossRefGoogle ScholarPubMed
Hanigan, MD, Cant, JP, Weakley, DC and Beckett, JL 1998. An evaluation of postabsorptive protein and amino acid metabolism in the lactating dairy cow. Journal of Dairy Science 81, 33853401.CrossRefGoogle ScholarPubMed
Harris, CI and Milne, G 1981. The urinary excretion of N-methyl histidine by cattle: validation as an index of muscle protein breakdown. British Journal of Nutrition 45, 411.CrossRefGoogle Scholar
Holter, JA and Reid, JT 1959. Relationship between the concentrations of crude protein and apparently digestible protein in forages. Journal of Animal Science 18, 13391349.CrossRefGoogle Scholar
Huhtanen, P and Hristov, AN 2009. A meta-analysis of the effects of dietary protein concentration and degradability on milk protein yield and milk N efficiency in dairy cows. Journal of Dairy Science 92, 32223232.CrossRefGoogle Scholar
Hurvich, CM and Tsai, CL 1993. A corrected akaike information criterion for vector autoregressive model selection. Journal of Time Series Analysis 14, 271279.CrossRefGoogle Scholar
Hutchinson, JC and Morris, S 1936. The digestibility of dietary protein in the ruminant: the digestibility of protein following a prolonged fast, with a detailed study of the nitrogen metabolism. Biochemical Journal 30, 16951704.CrossRefGoogle ScholarPubMed
Institut National de Recherche Agronomique (INRA) 2018. Feeding system for ruminants. Wageningen Academic Publishers, Wageningen, The Netherlands.Google Scholar
Jansman, AJM, Smink, W, Van Leeuwen, P and Rademacher, M 2002. Evaluation through literature data of the amount and amino acid composition of basal endogenous crude protein at the terminal ileum of pigs. Animal Feed Science and Technology 98, 4960.CrossRefGoogle Scholar
Jonker, JS, Kohn, RA and Erdman, RA 1998. Using milk urea nitrogen to predict nitrogen excretion and utilization efficiency in lactating dairy cows. Journal of Dairy Science 81, 26812692.CrossRefGoogle ScholarPubMed
Karman, AH and van Boekel, AJS 1986. Evaluation of the Kjeldahl factor for conversion of the nitrogen content of milk and milk products to protein content. Netherlands Milk and Dairy Journal 40, 315336.Google Scholar
Kauffman, AJ and St-Pierre, NR 2001. The relationship of milk urea nitrogen to urine nitrogen excretion in Holstein and Jersey cows. Journal of Dairy Science 84, 22842294.CrossRefGoogle ScholarPubMed
Kool, DM, Hoffland, E, Hummelink, EWJ and van Groenigen, JW 2006. Increased hippuric acid content of urine can reduce soil N2O fluxes. Soil Biology and Biochemistry 38, 10211027.CrossRefGoogle Scholar
Lapierre, H, Binggeli, S, Sok, M, Pellerin, D and Ouellet, DR 2019. Estimation of correction factors to determine the true amino acid concentration of protein after a 24-hour hydrolysis. Journal of Dairy Science 102, 12051212.CrossRefGoogle ScholarPubMed
Lapierre, H, Larsen, M, Sauvant, D, Van Amburgh, ME and Van Duinkerken, G 2018. Review: Converting nutritional knowledge into feeding practices: a case study comparing different protein feeding systems for dairy cows. Animal 12, S457S466.CrossRefGoogle ScholarPubMed
Lapierre, H, Lobley, GE, Doepel, L, Raggio, G, Rulquin, H and Lemosquet, S 2012. Triennial lactation symposium: mammary metabolism of amino acids in dairy cows. Journal of Animal Science 90, 17081721.CrossRefGoogle ScholarPubMed
Lapierre, H, Lobley, GE, Ouellet, DR, Doepel, L and Pacheco, D 2007. Amino acid requirements for lactating dairy cows: reconciling predictive models and biology. In Proceedings of the 69th Cornell Nutrition Conference for Feed Manufacturers, 23–25 October 2007, Syracuse, NY, USA, pp. 3959.Google Scholar
Lapierre, H and Ouellet, DR 2015. How the efficiency of utilization of histidine varies with supply in dairy cows. Journal of Dairy Science 98 (suppl. 2), 609.Google Scholar
Lapierre, H, Ouellet, DR, Martineau, R and Spek, JW 2016. Key roles of amino acids in cow performance and metabolism – considerations for defining amino acid requirement. In Proceedings of the 78th Cornell Nutrition Conference for Feed Manufacturers, 18–20 October 2016, Syracuse, NY, USA, pp. 205219.Google Scholar
Lien, KA, Sauer, WC, Mosenthin, R, Souffrant, WB and Dugan, MER 1997. Evaluation of the 15N-isotope dilution technique for determining the recovery of endogenous protein in ileal digestion of pigs: effect of dilution in the precursor pool for endogenous nitrogen secretion. Journal of Animal Science 75, 148158.CrossRefGoogle ScholarPubMed
Lin, LI-K 1989. A concordance correlation coefficient to evaluate reproducibility. Biometrics 45, 255268.CrossRefGoogle ScholarPubMed
Lin, LI-K 1992. Assay validation using the concordance correlation coefficient. Biometrics 48, 599604.CrossRefGoogle Scholar
Lobley, GE and Lapierre, H 2003. Post-absorptive metabolism of amino acids. In Progress in research on energy and protein metabolism (ed. Souffrant, WB and Metges, CC), pp. 737756, Wageningen Academic Publishers, Wageningen, The Netherlands.Google Scholar
Marini, JC, Fox, DG and Murphy, MR 2008. Nitrogen transactions along the gastrointestinal tract of cattle: a meta-analytical approach. Journal of Animal Science 86, 660679.CrossRefGoogle ScholarPubMed
Marini, JC and Van Amburgh, ME 2005. Partition of nitrogen excretion in urine and the feces of holstein replacement heifers. Journal of Dairy Science 88, 17781784.CrossRefGoogle ScholarPubMed
Martineau, R, Ouellet, DR, Kebreab, E, White, RR and Lapierre, H 2017. Relationships between postruminal casein infusion and milk production, and concentrations of plasma amino acids and blood urea in dairy cows: a multilevel mixed-effects meta-analysis. Journal of Dairy Science 100, 80538071.CrossRefGoogle ScholarPubMed
Metcalf, JA, Mansbridge, RJ, Blake, JS, Oldham, JD and Newbold, JR 2008. The efficiency of conversion of metabolisable protein into milk true protein over a range of metabolisable protein intakes. Animal 2, 11931202.CrossRefGoogle Scholar
Myers, AJ, Lapierre, H, White, RR, Tran, H, Kononoff, PJ, Martineau, R, Weiss, WP and Hanigan, MD 2018. Predictions of rumen outflow of amino acids in dairy cattle. Journal of Dairy Science 101 (suppl. 2), 410.Google Scholar
National Research Council 2001. Nutrient requirements of dairy cattle. 7th revised edition. Natl. Acad. Sci., Washington, DC, USA.Google Scholar
Nehring, K, Zelck, U and Schiemann, R 1965. Über die zusammensetzung des harns an organischen inhaltsstoffen bei rindern, schafen und schweinen. Archiv für Tierernaehrung 15, 4552.CrossRefGoogle Scholar
Nichols, K, Bannink, A, Pacheco, S, van Valenberg, HJ, Dijkstra, J and van Laar, H 2018. Feed and nitrogen efficiency are affected differently but milk lactose production is stimulated equally when isoenergetic protein and fat is supplemented in lactating dairy cow diets. Journal of Dairy Science 101, 78577870.CrossRefGoogle ScholarPubMed
Nichols, K, Kim, JJM, Carson, M, Metcalf, JA, Cant, JP and Doelman, J 2016. Glucose supplementation stimulates peripheral branched-chain amino acid catabolism in lactating dairy cows during essential amino acid infusions. Journal of Dairy Science 99, 11451160.CrossRefGoogle ScholarPubMed
NorFor 2011. The Nordic feed evaluation system. Wageningen Academic Publishers, Wageningen, The Netherlands.Google Scholar
Ørskov, ER, McLeod, NA and Kyle, DJ 1986. Flow of nitrogen from the rumen and abomasum in cattle and sheep given protein-free nutrients by intragastric infusion. British Journal of Nutrition 56, 241248.CrossRefGoogle ScholarPubMed
Ouellet, DR, Berthiaume, R, Holtrop, G, Lobley, GE, Martineau, R and Lapierre, H 2010. Effect of method of conservation of timothy on endogenous nitrogen flows in lactating dairy cows. Journal of Dairy Science 93, 42524261.CrossRefGoogle ScholarPubMed
Ouellet, DR, Demers, M, Zuur, G, Lobley, GE, Seoane, JR, Nolan, JV and Lapierre, H 2002. Effect of dietary fiber on endogenous nitrogen flows in lactating dairy cows. Journal of Dairy Science 85, 30133025.CrossRefGoogle ScholarPubMed
Ouellet, DR, Valkeners, D, Holtrop, G, Lobley, GE and Lapierre, H 2007. Contribution of endogenous secretions and urea recycling to nitrogen metabolism. In Proceedings of the 69th Cornell Nutrition Conference for Feed Manufacturers, 23–25 October 2007, Syracuse, NY, USA, pp. 124.Google Scholar
Raggio, G, Lobley, GE, Berthiaume, R, Pellerin, D, Allard, G, Dubreuil, P and Lapierre, H 2007. Effect of protein supply on hepatic synthesis of plasma and constitutive proteins in lactating dairy cows. Journal of Dairy Science 90, 352359.CrossRefGoogle ScholarPubMed
Rohr, K and Lebzien, P 1991. Present knowledge of amino acid requirements for maintenance and production. Paper pesented at the 6th International Symposium on Protein Metabolism and Nutrition, 9–14 June 1991, Herning, Denmark, pp. 127137.Google Scholar
Roman-Garcia, Y, White, RR and Firkins, JL 2016. Meta-analysis of postruminal microbial nitrogen flows in dairy cattle. I. Derivation of equations. Journal of Dairy Science 99, 79187931.CrossRefGoogle Scholar
Sandek, A, Krawielitzki, K, Kowalczyk, J, Kreienbring, F, Schoenhusen, U, Gabel, M, Zebrowska, T, Hagemeister, H and Voigt, J 2001. Studies on N-metabolism in different gastrointestinal sections of sheep using the digesta exchange technique. 2. Passage of endogenous nitrogen. Journal of Animal & Feed Sciences 10, 605618.CrossRefGoogle Scholar
Sauvant, D, Catalapiedra-Hijar, G, Delaby, L, Daniel, J-B, Faverdin, P and Nozière, P 2015. Actualisation des besoins protéiques des ruminants et détermination des réponses des femelles laitières aux apports de protéines digestibles dans l’intestin (PDI). INRA Productions Animales 28, 347368.CrossRefGoogle Scholar
Sok, M, Ouellet, DR, Firkins, JL, Pellerin, D and Lapierre, H 2017. Amino acid composition of rumen bacteria and protozoa in cattle. Journal of Dairy Science 100, 52415249.CrossRefGoogle ScholarPubMed
Spek, JW, Dijkstra, J, van Duinkerken, G, Hendriks, WH and Bannink, A 2013. Prediction of urinary nitrogen and urinary urea nitrogen excretion by lactating dairy cattle in northwestern Europe and North America: a meta-analysis. Journal of Dairy Science 96, 43104322.CrossRefGoogle ScholarPubMed
Swaisgood, HE 1995. Protein and amino acid composition of bovine milk. In Handbook of Milk Composition (ed. Jensen, RG), pp. 464472. Academic Press, London, UK.CrossRefGoogle Scholar
Swanson, EW 1977. Factors for computing requirements of protein for maintenance of cattle. Journal of Dairy Science 60, 15831593.CrossRefGoogle Scholar
Swanson, EW 1982. Estimation of metabolic protein requirements to cover unavoidable losses of endogenous nitrogen in maintenance of cattle. Paper presented at the Symposium Protein Requirements for Cattle (ed. Owens, FN), 19–21 November 1980, Oklahoma State University, Stillwater, OK, USA, pp. 183197.Google Scholar
Syvaöja, E-L and Virtanen, AI 1965. Fractionation of milk proteins, especially of milk produced on protein-free feed with urea and ammonium salt as the sole source of nitrogen. Enzymologia 29, 205219.Google ScholarPubMed
Tamminga, S, Schulze, H, Van Bruchem, J and Huisman, J 1995. The nutritional significance of endogenous N-losses along the gastro-intestinal tract of farm animals. Archiv fur Tierernahrung 48, 922.CrossRefGoogle ScholarPubMed
Tas, BM and Susenbeth, A 2007. Urinary purine derivates excretion as an indicator of in vivo microbial N flow in cattle: a review. Livestock Science 111, 181192.CrossRefGoogle Scholar
Theil, H 1966. Measuring the accuracy of point predictions. In Applied economic forecasting, pp. 1436. North Holland Publishing Company, Amsterdam, The Netherlands.Google Scholar
Van Amburgh, ME, Collao-Saenz, EA, Higgs, RJ, Ross, DA, Recktenwald, EB, Raffrenato, E, Chase, LE, Overton, TR, Mills, JK and Foskolos, A 2015. The Cornell Net carbohydrate and protein system: updates to the model and evaluation of version 6.5. Journal of Dairy Science 98, 63616380.CrossRefGoogle ScholarPubMed
Van Duinkerken, G, Blok, MC, Bannink, A, Cone, JW, Dijkstra, J, Van Vuuren, AM and Tamminga, S 2011. Update of the Dutch protein evaluation system for ruminants: the DVE/OEB2010 system. Journal of Agricultural Science 149, 351367.CrossRefGoogle Scholar
Vanhatalo, A, Varvikko, T and Huhtanen, P 2003a. Effects of casein and glucose on responses of cows fed diets based on restrictively fermented grass silage. Journal of Dairy Science 86, 32603270.CrossRefGoogle ScholarPubMed
Vanhatalo, A, Varvikko, T and Huhtanen, P 2003b. Effects of various glucogenic sources on production and metabolic responses of dairy cows fed grass silage-based diets. Journal of Dairy Science 86, 32493259.CrossRefGoogle ScholarPubMed
Viechtbauer, W 2017a. [R-meta] Multilevel meta-analysis using metafor. Retrieved on 01 August 2018 from https://stat.ethz.ch/pipermail/r-sig-meta-analysis/2017-August/000174.html.Google Scholar
Viechtbauer, W 2017b. [R-meta] Multilevel meta-analysis using metafor. Compute (cluster) robust test and confidence intervals for ‘rma’ objects. Retrieved on 30 January 2018 from https://www.rdocumentation.org/packages/metafor/versions/1.9-9/topics/robust.Google Scholar
Viechtbauer, W 2018. [R-meta] Weighing factors in rma.mv corresponding to those used in lmer. Retrieved on 01 August 2018 from https://stat.ethz.ch/pipermail/r-sig-meta-analysis/2018-March/000731.html.Google Scholar
Waldo, DR and Glenn, BP 1984. Comparison of new protein systems for lactating dairy cows. Journal of Dairy Science 67, 11151133.CrossRefGoogle Scholar
White, RR, Kononoff, PJ and Firkins, JL 2017. Technical note: methodological and feed factors affecting prediction of ruminal degradability and intestinal digestibility of essential amino acids. Journal of Dairy Science 100, 19461950.CrossRefGoogle ScholarPubMed
Wickersham, TA, Titgemeyer, EC, Cochran, RC, Wickersham, EE and Gnad, DP 2008a. Effect of rumen-degradable intake protein supplementation on urea kinetics and microbial use of recycled urea in steers consuming low-quality forage. Journal of Animal Science 86, 30793088.CrossRefGoogle ScholarPubMed
Wickersham, TA, Titgemeyer, EC, Cochran, RC, Wickersham, EE and Mooref, ES 2008b. Effect of frequency and amount of rumen-degradable intake protein supplementation on urea kinetics and microbial use of recycled urea in steers consuming low-quality forage. Journal of Animal Science 86, 30893099.CrossRefGoogle ScholarPubMed
Wickham, H 2016. ggplot2: elegant graphics for data analysis, 2nd edition. Springer International Publishing AG, Switzerland.CrossRefGoogle Scholar
Wilkinson, JM 2011. Re-defining efficiency of feed use by livestock. Animal 5, 10141022.CrossRefGoogle ScholarPubMed
Williams, AP 1978. The amino acids, collagen and mineral composition of preruminant calves. The Journal of Agricultural Science 90, 617624.CrossRefGoogle Scholar
Zhu, CL, Lapierre, H, Rademacher, M and de Lange, CFM 2003. Pectin infusion into the caecum reduces the utilization of threonine intake for body protein deposition and urea flux in growing pigs. In Proceedings of the 9th International Symposium on Digestive Physiology in Pigs, Volume 2 (ed. Ball, RO), 14–17 May 2003, Banff, AB, Canada, pp. 346348.Google Scholar
Figure 0

Table 1 Amino acid (AA) composition of protein secretions used in the calculation of efficiency of utilization of AA in lactating dairy cows

Figure 1

Table 2 Summary statistics of the developmental database (n = 807) from studies conducted in lactating dairy cows

Figure 2

Table 3 Summary statistics of the validation database (n = 129) from studies conducted in lactating dairy cows

Figure 3

Figure 1 Relationship between milk true protein yield and metabolizable protein (MP) supply in lactating dairy cows in the developmental and validation databases.

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Table 4 Models of efficiency of utilization of metabolizable protein (MP)1 in lactating dairy cows

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Figure 2 Observed (•) and residual (▴) values of efficiency of utilization of metabolizable protein in the function of efficiency predicted according to equations (12), (13) and (14) (see text for details of the equations) in lactating dairy cows in the validation database.

Figure 6

Figure 3 Relationship between efficiency of utilization of metabolizable protein (MP) and MP adjusted (MP supply minus endogenous urinary loss) or the ratio of MP adjusted/digestible energy (DE) intake in lactating dairy cows in the developmental database. Efficiency is calculated as (true protein in milk + scurf + metabolic fecal)/MP adjusted.

Figure 7

Table 5 Models of efficiency of utilization of individual amino acids (AA)1 in lactating dairy cows

Figure 8

Table 6 Predicted milk true protein yield (MPY, g/d) based on estimates of the efficiency of utilization of metabolizable protein (EffMP) or predicted directly in lactating dairy cows

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Table 7 Prediction of milk true protein yield (MPY, g/day) based on estimates of the efficiency of utilization of amino acids (EffAA) in lactating dairy cows

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