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Effect of undegradable intake protein supplementation on urea kinetics and microbial use of recycled urea in steers consuming low-quality forage

Published online by Cambridge University Press:  23 May 2008

Tryon A. Wickersham
Affiliation:
Department of Animal Sciences and Industry, Kansas State University, Manhattan, KS 66506, USA
Evan C. Titgemeyer*
Affiliation:
Department of Animal Sciences and Industry, Kansas State University, Manhattan, KS 66506, USA
Robert C. Cochran
Affiliation:
Department of Animal Sciences and Industry, Kansas State University, Manhattan, KS 66506, USA
Erin E. Wickersham
Affiliation:
Department of Animal Sciences and Industry, Kansas State University, Manhattan, KS 66506, USA
*
*Corresponding author: Dr Evan C. Titgemeyer, fax +1 785 5325681, email [email protected]
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Abstract

We evaluated the effect of undegradable intake protein (UIP) on urea kinetics and microbial incorporation of urea-N in ruminally and duodenally fistulated steers (n 4; 319 kg) provided ad libitum access to grass hay in a 4 × 4 Latin square. Casein was continuously infused abomasally in amounts of 0, 62, 124 and 186 mg N/kg body weight per d to simulate provision of UIP. Periods were 13 d long with 7 d for adaptation and 6 d for collection. Jugular infusion of [15N15N]urea followed by determination of urinary enrichment of [15N15N]urea and [14N15N]urea was used to measure urea kinetics. Forage and N intake increased (quadratic, P < 0·02) with increasing UIP. Urea synthesis was 27·1, 49·9, 82·2 and 85·8 g urea-N/d for 0, 62, 124 and 186 diets, respectively (linear, P < 0·01). The proportion of urea synthesis that entered the gastrointestinal tract was 0·96 for steers receiving no UIP and decreased linearly (P = 0·05) to a low of 0·89 for steers receiving 186. The amount of urea entering the gastrointestinal tract was least for 0 (26·3) and increased (linear, P < 0·01) to 48·7, 77·2 and 76·6 g urea-N/d for 62, 124 and 186 diets, respectively. Microbial incorporation of recycled urea-N increased quadratically (P = 0·04) from 13·9 for 0 to 47·7 g N/d for 124. The proportion of microbial N derived from recycled urea increased (quadratic, P = 0·05) from 0·31 to 0·58 between 0 and 124 and dropped to 0·44 for 186 mg N/kg body weight per d. UIP increased intake of hay and provided a N source for ruminal microbes via urea recycling.

Type
Full Papers
Copyright
Copyright © The Authors 2008

Protein supplementation to cattle is recommended when there is insufficient ruminally available N (RAN) to allow for adequate microbial activity for use of fermentable organic matter (OM). The ability of undegradable intake protein (UIP), provided by either forage or supplement, to provide RAN via urea recycling is not considered by many current feeding systems. For example, Level 1 of the National Research Council's Nutrient Requirements of Beef Cattle (1) recommends feeding cattle 130 g degradable intake protein (DIP)/kg total digestible nutrients, giving no credit for the possible contribution of N to the RAN pool from the recycling of N originally supplied as UIP. Ultimately, this leads to an underestimation of RAN when the diet contains significant amounts of UIP. For example, when bermudagrass hay was fed to steers, there was no improvement in forage use when protein was supplemented(Reference Mathis, Cochran, Heldt, Woods, Abdelgadir, Olson, Titgemeyer and Vanzant2), although the DIP to digestible OM ratio predicted inadequate amounts of RAN(1). The authors(Reference Mathis, Cochran, Heldt, Woods, Abdelgadir, Olson, Titgemeyer and Vanzant2) attributed the lack of response to the UIP in the hay providing RAN through recycling of urea to the rumen. Furthermore, Level 2 of the National Research Council's Nutrient Requirements of Beef Cattle (1) bases its estimate of urea recycling to the rumen solely on the percentage of crude protein in the diet. This assumes that urea recycling is not influenced by protein degradability.

When DIP is supplemented, increases in ruminal ammonia concentration are apparent, but there are only small increases in ruminal ammonia concentration with UIP supplementation(Reference Bandyk, Cochran, Wickersham, Titgemeyer, Farmer and Higgins3, Reference Wickersham, Cochran, Titgemeyer, Farmer, Klevesahl, Arroquy, Johnson and Gnad4). However, UIP supplementation increases plasma urea concentrations similarly to DIP supplementation(Reference Bandyk, Cochran, Wickersham, Titgemeyer, Farmer and Higgins3, Reference Wickersham, Cochran, Titgemeyer, Farmer, Klevesahl, Arroquy, Johnson and Gnad4). The combination of lower ruminal ammonia concentrations and similar plasma urea concentrations with UIP supplementation relative to DIP supplementation would be expected to lead to greater urea recycling to the rumen with UIP supplementation(Reference Kennedy and Milligan5).

Given the increasing availability of byproducts containing large amounts of UIP (e.g. distiller's grains), knowledge of the contribution of N recycling to RAN will aid appropriate incorporation of byproducts into supplementation strategies. Previous research has demonstrated that UIP is effective, although less so than DIP, in stimulating intake and digestion of low-quality forage(Reference Bandyk, Cochran, Wickersham, Titgemeyer, Farmer and Higgins3, Reference Wickersham, Cochran, Titgemeyer, Farmer, Klevesahl, Arroquy, Johnson and Gnad4). The mode of action of this increase in intake has not been completely defined. A portion of the response may be due to improved protein status of the animal(Reference Egan and Moir6), but much evidence points to the role N recycling plays in stimulating intake; ruminal ammonia and plasma urea concentrations both increase when supplemental UIP is provided. By accounting for urea-recycling mechanisms, we can better predict the contribution of UIP to RAN, which will allow more accurate prediction of animal response to supplemental protein. The objective of the present study was to determine the effect of supplemental UIP on urea kinetics and the microbial incorporation of recycled urea-N.

Experimental methods

Four duodenally and ruminally fistulated Angus × Hereford steers (average initial body weight (BW) 319 (sd 17) kg) were used in a 4 × 4 balanced Latin square to evaluate the effect of increasing amounts of supplemental UIP on urea kinetics and recycled urea-N use by ruminal microbes in steers consuming low-quality forage. All data from one steer for one period (i.e. one observation) were lost due to problems not related to treatment. The experimental protocol was approved by the Institutional Animal Care and Use Committee at Kansas State University. Steers were provided ad libitum access to fresh water and a trace mineral/salt block (composition: ≥ 96·0 % NaCl, 0·16 % Fe, 0·40 % Zn, 0·32 % Mn, 0·01 % I, 0·04 % Cu, 0·004 % Co; American Stockman, Overland Park, KS, USA) while being offered tallgrass-prairie hay (i.e. native pasture dominated by big bluestem (Andropogon gerardii), indiangrass (Sorghastrum nutans), little bluestem (Schizachyrium scoparium) and switchgrass (Panicum virgatum)) at 06.30 hours each day (Table 1) at 130 % of average voluntary intake for the preceding 4 d.

Table 1 Chemical composition of grass hay and casein (g/kg DM)

Treatments were one of four amounts (0, 62, 124 and 186 mg N/kg BW per d) of casein (Alanate 180, New Zealand Milk Products Inc., Santa Rosa, CA, USA; Table 1) continuously infused abomasally, via infusion lines passed through the rumen cannula and the reticulo-omasal orifice and anchored in the abomasum with a 10 cm rubber flange. The allotted amount of casein for each treatment was dissolved daily by mixing the casein with 4·5 litres of deionized water for 20 h. Steers receiving no supplement were infused with 4·5 litres deionized water/d. Infusions into the abomasum were accomplished using a peristaltic-pump and polyvinyl chloride tubing. Casein was selected as the supplemental UIP because of its high protein content and high intestinal digestibility. The highest amount of supplemental UIP (186 mg N/kg BW per d) was close to the DIP requirement for maximum forage use(Reference Wickersham, Cochran, Titgemeyer, Farmer, Klevesahl, Arroquy, Johnson and Gnad4).

Experimental procedures used general methodologies and adaptation periods validated by Wickersham(Reference Wickersham7). Experimental periods were 13 d long, with 7 d for adaptation to treatments and 6 d for collection. For the first 4 d of adaptation, steers were housed in individual pens (1·5 × 3·1 m) and tethered to the front of the pen to prevent removal of the abomasal infusion lines. For the remainder of the adaptation and throughout the collection period, steers were placed in metabolism crates to facilitate the total collection of acidified urine and faeces and the jugular infusion of [15N15N]urea. Metabolism crates were designed such that urine was collected into a funnel directly beneath the mid portion of the steer and subsequently was diverted into a bucket using gravity, whereas faeces were collected in a pan placed directly behind the steer.

On day 9 at 16.00 hours an indwelling catheter was placed in the jugular vein of each steer to infuse [15N15N]urea for the determination of urea kinetics. The catheter was inserted on the evening prior to the start of infusions so that infusions would minimize disturbances in the animals' routine. The [15N15N]urea solution was prepared by combining 1·20 g [15N15N]urea (99·7 % [15N15N]urea; Medical Isotopes Inc., Pelham, NH, USA) with 1 litre of sterile saline solution (9 g/l NaCl), and then it was filter sterilized (0·22 μm filter unit; Sterivex, Millipore Corporation, Billeric, MA, USA). Saline solution was infused continuously to prevent blockage of the catheter from the time the catheter was placed until 06.00 hours on day 10 when infusion of the [15N15N]urea solution began. The [15N15N]urea solution was continuously infused until the end of the experimental period at approximately 4 ml/h, which delivered 0·154 mmol urea-N/h, using a syringe infusion pump (Harvard Apparatus, South Natick, MA, USA). Total collections of urine and faeces from day 9 were used to determine background enrichments of 15N. Total collections of urine and faeces from day 12 were used to measure enrichments for calculating urea kinetics. On day 13, rumen fluid samples were collected by suction strainer (19 mm diameter, 1·5 mm mesh) just before feeding (0 h) and at 4, 8, 12, 16 and 20 h after feeding. Ruminal fluid (4 ml) from each collection was combined with 1 ml 1 m-HCl and frozen for ammonia and SCFA analysis. On day 13, whole ruminal contents (1 kg) and duodenal samples (300 ml) were collected prior to feeding (0 h) and at 4, 8, 12, 16 and 20 h after feeding to determine duodenal flows and incorporation of recycled urea-N into microbial protein. To isolate ruminal bacteria from the whole ruminal contents, 0·5 litres 9 g/l NaCl solution was added immediately after the sample was collected, then it was blended (5 min; Waring Commercial Blender, Waring Commercial, Torrington, CT, USA) and strained through two layers of cheesecloth. The liquid fraction was immediately frozen and the material remaining in the cheesecloth was placed in the rumen. Blood was collected from the jugular vein opposite the catheter into heparinized Vacutainer tubes (Becton Dickinson, Franklin Lakes, NJ, USA) 12 h after feeding on day 13. Samples were placed in ice water immediately after collection and centrifuged at 5000 g for 15 min within 1 h after collection. Plasma was frozen for subsequent determination of plasma urea-N concentration.

Calculations of intake, digestion and N balance were made from observations on days 8–12. Feed and ort samples were collected on days 8–11 to correspond with faecal and urine samples collected on days 9–12. Duodenal flows were based on samples from day 13 with acid- detergent insoluble ash (ADIA) serving as an internal marker. Hay was sampled as it was being fed with 400 g hay retained each day for later analysis. Orts were removed at 06.00 hours and approximately 200 g were retained for analysis. Faecal bins and urine buckets were removed and contents weighed at 06.15 hours daily. Faeces collected over each 24 h period were thoroughly mixed, and 3 % was sampled and frozen ( − 20°C) for subsequent analysis. Urine collected over each 24 h period was thoroughly mixed and 2 % was retained as a sample and subsequently frozen ( − 20°C). Urine pH was maintained below 3 by adding 400 ml 6 m-HCl to urine containers prior to collection.

Laboratory analyses

Partial DM of hay, ort and faecal (used for faecal output determination) samples was determined by drying at 55°C for 96 h in a forced-air oven. Duodenal samples were frozen and lyophilized. Subsequently, all dried samples were ground with a Wiley mill to pass a 1 mm screen. Hay and casein samples collected during the measurement phase were pooled across days on an equal weight basis. Ort and faecal samples were composited by steer across days for each period on a proportional basis. Hay, supplement, ort, faecal and duodenal samples were dried for 24 h at 105°C in a forced-air oven to determine DM and then combusted for 8 h at 450°C in a muffle furnace for OM determination. N content of hay, casein, wet faeces, urine and duodenal digesta was determined by total combustion (Nitrogen Analyzer Model FP-2000; Leco Corporation, St. Joseph, MI, USA). Crude protein was calculated as N × 6·25. All hay, ort, faecal and duodenal samples were analysed for neutral-detergent fibre and acid-detergent fibre with the ANKOM-Fiber Analyzer (ANKOM-Technology, Fairport, NY, USA) with sodium sulphite and amylase omitted and without correction for residual ash. To determine ADIA of hay, ort, faecal and duodenal samples, the ANKOM bags containing the acid-detergent fibre residues were combusted for 8 h at 450°C in a muffle furnace. Dry faecal and duodenal samples were analysed for 15N using a stable isotope elemental analyser (Thermofinnigan Delta Plus; Thermo Electron Corporation, Waltham, MA, USA). To isolate ruminal bacteria, samples of ruminal contents were thawed and feed particles were removed from the sample by centrifugation at 500 g for 20 min. Supernatants were then centrifuged at 20 000 g for 20 min to pellet the bacteria. The pellet was resuspended with 9 g/l NaCl and centrifuged at 20 000 g for 20 min. The bacterial pellets were frozen and lyophilized. Bacteria were analysed for 15N enrichment.

For determination of urea kinetics, urinary urea and ammonia concentrations were determined on urine samples collected on days 9 and 12 colorimetrically with an auto-analyser (Technicon Analyzer II; Technicon Industrial Systems, Buffalo Grove, IL, USA) using the methods of Marsh et al. (Reference Marsh, Fingerhut and Miller8) and Broderick & Kang(Reference Broderick and Kang9). To remove ammonia from the urine samples initially, 2 ml Dowex 50W-X8 ion exchange resin 100–200 mesh, H+ form (Sigma Chemical Co., St. Louis, MO, USA) was mixed with 10 ml urine, vortexed for 15 s and allowed to stand for 15 min. From the tube, 31 μmol urea was pipetted on to a column containing 2 ml Dowex resin to remove any remaining ammonia, and the effluent was discarded. Deionized water (20 ml) was added to the column, and the effluent was discarded(Reference Read, Harrison and Halliday10). An additional 10 ml deionized water was added to the column, and the effluent was retained. Urea and ammonia concentrations of the retained effluent were determined as previously described. If no ammonia was present, then 3 μmol urea were transferred into an Exetainer tube (Labco International, Houston, TX, USA), and the sample was brought to 4 ml with deionized water and subsequently frozen. If ammonia was present, the initial step of mixing the urine with the Dowex resin was repeated until no ammonia was present in the final effluent. To prepare samples for Hoffman degradation, He was bubbled through the samples for approximately 10 min, capped and quickly frozen in liquid N2. After freezing, 0·5 ml hypobromite (27 g bromine/100 ml 40 % (w/w) NaOH) was added and the lid screwed on(Reference Volk and Jackson11). With the tube remaining in liquid N2, a vacuum pump was used to remove the gas from the head space and He was added; this process was repeated three times. After the final addition of He, the Exetainer was removed from liquid N2 and allowed to thaw at room temperature. The thawed sample was then placed in a 60°C water-bath for 15 min to allow the Hoffman degradation reaction to occur rapidly. Samples were then analysed for 28N2, 29N2 and 30N2 using a stable isotope gas bench (Thermofinnigan Delta Plus).

Ruminal SCFA were determined by GLC as described by Vanzant & Cochran(Reference Vanzant and Cochran12). Colorimetric determinations of ruminal ammonia(Reference Broderick and Kang9) and plasma urea(Reference Marsh, Fingerhut and Miller8) were made using an auto-analyser (Technicon Analyzer II).

Calculations

Urea kinetics were calculated as outlined by Lobley et al. (Reference Lobley, Bremner and Zuur13) and include correction (0·56 %) for non-monomolecular reactions during the Hoffman degradation. This correction was based on standards analysed at the same urea concentration (0·75 mm) as the samples and was lower than the correction factor (4·68 %) reported by Lobley et al. (Reference Lobley, Bremner and Zuur13). The difference between the correction factors can be accounted for by the fact that our urea concentration was much lower (0·75 v. 9 mm) than theirs and is supported by the observed reduction in non-monomolecular reactions as urea concentration decreases(Reference Marini and Attene-Ramos14). Duodenal flow was calculated by dividing faecal ADIA output (g/d) by the ADIA concentration of duodenal digesta. Bacterial N flow was calculated by multiplying duodenal N flow by the ratio of duodenal 15N enrichment to bacterial 15N enrichment. The flow of bacterial N derived from recycled urea-N was calculated by multiplying bacterial N flow by the ratio of bacterial 15N enrichment to urinary 15N enrichment. Urinary 15N enrichment was determined by converting the urinary urea enrichment measurements used to determine urea kinetics to total 15N enrichment. UIP flow was determined by subtracting bacterial N flow from total duodenal N flow, and there was no correction for the contribution of endogenous N flow.

Statistical analyses

Intake, digestion, N balance, urea kinetics, duodenal flows and plasma urea-N concentration were analysed using the MIXED procedure of SAS System for Windows Release 8.1 (SAS Institute Inc., Cary, NC, USA). Terms in the model were treatment and period with steer included as a random term. Fermentation profile variables were analysed using the MIXED procedure of SAS. Terms in the model were treatment, period, hour, and hour × treatment with steer and treatment × period × steer included as random terms. The repeated term was hour with treatment × steer serving as the subject. Compound symmetry was used for the covariance structure. Orthogonal polynomial contrasts (linear, quadratic and cubic) were used to partition treatment sums of squares.

Results

Forage OM and total OM intake increased quadratically (P = 0·02; Table 2) in response to supplemental UIP, whereas total digestible OM intake (TDOMI) increased linearly (P < 0·01). True ruminal OM digestion and ruminal neutral- detergent fibre digestion were not significantly impacted by increasing UIP supplementation. Similarly, total tract digestibilities of OM and neutral-detergent fibre were not impacted by increasing UIP. By design, intake of N increased with supplemental UIP (linear, P < 0·01). Correspondingly, faecal and urinary N excretion increased (linear, P ≤ 0·03) with UIP supplementation. absorption increased (linear, P < 0·01) with increasing UIP supplementation. Retention of N increased (linear, P < 0·01) from 3·4 g N/d for 0 mg N/kg BW per d to 37·8 g N/d for 186 mg N/kg BW per d. Retention of N as a fraction of N intake also increased linearly (P = 0·02) in response to UIP.

Table 2 Effects of undegradable intake protein supplementation on intake, digestion and nitrogen balance of steers fed grass hay*

* For details of procedures, see Experimental methods.

For n 3.

Urinary urea-N excretion, both as an amount per day and as a fraction of urinary N excretion, increased with UIP supplementation (linear, P < 0·01; Table 3). Urinary ammonia was not impacted by treatment. Urea production increased linearly (P < 0·01) with increasing delivery of supplemental UIP. The amount of urea entering the gut increased linearly (P < 0·01) with increasing UIP supplementation; however, gut entry as a fraction of urea production decreased linearly (P = 0·05). The amount and fraction of urea that entered the gut and was subsequently returned to the ornithine cycle was increased (linear, P < 0·01) by increasing UIP. Faecal excretion of recycled urea-N increased (quadratic, P = 0·05) with increasing UIP supplementation. Faecal excretion of recycled urea-N as a fraction of gut entry was not impacted by UIP provision. Provision of supplemental UIP tended to increase (quadratic, P = 0·06) anabolic use of recycled urea-N above that of steers receiving no UIP. Anabolic use of recycled urea-N as a fraction of gut entry decreased (linear, P < 0·01) with increasing supplemental UIP.

Table 3 Effects of undegradable intake protein supplementation on urea excretion, ammonia excretion and urea kinetics in steers fed grass hay*

* For details of procedures, see Experimental methods.

For n 3.

Duodenal N flow, microbial N flow and UIP flow increased (linear, P ≤ 0·01; Table 4) with increasing provision of supplemental protein. Incorporation of recycled urea-N by ruminal microbes was increased (quadratic, P = 0·04) by supplemental UIP. The fraction of total microbial N from recycled urea-N increased quadratically (P = 0·05) with increasing levels of supplemental UIP. The fraction of urea production and of urea entering the gut that was incorporated into microbial N was not significantly impacted by supplemental UIP. Microbial efficiency was not significantly altered by UIP supplementation. Plasma urea-N concentration was linearly (P < 0·01; Table 5) increased by supplemental UIP.

Table 4 Effects of undegradable intake protein supplementation on duodenal nitrogen flows and recycled urea-nitrogen incorporation into microbial nitrogen in steers fed grass hay*

MNU, microbial N from recycled urea; OM, organic matter; TDOMI, total digestible organic matter intake.

* For details of procedures, see Experimental methods.

For n 3.

Microbial N flowing to the duodenum per kg of truly digested OM.

§ Microbial N flowing to the duodenum per kg of TDOMI.

Table 5 Effects of undegradable intake protein supplementation on plasma urea-nitrogen concentration and ruminal fermentation characteristics in steers consuming grass hay*

* For details of procedures, see Experimental methods.

For n 3.

The treatment × time interaction was significant for ruminal ammonia, but the interaction was largely due to the magnitude of the difference that existed between treatments at different times rather than to changes in treatment rankings (data not shown). Therefore, to facilitate discussion, only treatment means are presented. Ruminal ammonia concentration increased linearly (P < 0·01; Table 5) with increasing supplemental protein, but the magnitude of the increase was small, from 0·08 to 0·55 mm for 0 and 186 mg N/kg BW per d, respectively. Concentrations of SCFA linearly (P < 0·01) increased with increasing UIP supplementation. The molar proportions of acetate, butyrate and valerate were not altered by UIP provision. Propionate proportion was increased quadratically (P = 0·01) and isobutyrate and isovalerate were linearly (P < 0·01) decreased with supplemental UIP. There was a significant treatment × time interaction for valerate, but data are not shown because the magnitude of the differences were small (all treatments at all time-points ranged between 0·28 and 0·40 molar percentage) and deemed not biologically important. Ruminal pH was linearly (P < 0·01) decreased by supplemental UIP.

Discussion

Intake of low-quality forage responded less in the present study, as a percentage of control, than when the same levels of casein were ruminally supplemented to cattle consuming similar forage(Reference Wickersham7). Work using similar forages has shown that UIP supplemented at levels near 124 mg N/kg BW per d led to increases in TDOMI that were about two-thirds as great as observed when the same level DIP was supplemented(Reference Bandyk, Cochran, Wickersham, Titgemeyer, Farmer and Higgins3, Reference Wickersham, Cochran, Titgemeyer, Farmer, Klevesahl, Arroquy, Johnson and Gnad4). They attributed the increases in intake to increased RAN and a possible alleviation of metabolic discomfort with the improvement in protein status. Provision of post-ruminal N as either casein or urea stimulated intake of low-quality forage in sheep(Reference Egan and Moir6, Reference Egan15), although the mechanism of each increase was hypothesized to be different. They observed an increase in digestion rate with urea, but not with casein, leading them to conclude that casein was acting as a chemoregulator, whereas urea was increasing intake via N recycling mechanisms. Garza et al. (Reference Garza, Owens and Welty16) also observed increases in low-quality forage intake in cattle with provision of either casein or urea post-ruminally. It is also possible that bioactive peptides in casein impacted gut motility(Reference Daniel, Vohwinkel and Rehner17Reference Froetschel19) and subsequently intake. We attribute the increase in forage intake in the present study predominantly to the increased RAN supply from recycled urea and the subsequent improvement in ruminal fermentation of the forage.

Supplemental UIP did not affect either ruminal or total tract neutral-detergent fibre digestion, which is similar to the lack of effect on digestion of neutral-detergent fibre observed by Bandyk et al. (Reference Bandyk, Cochran, Wickersham, Titgemeyer, Farmer and Higgins3) and Wickersham et al. (Reference Wickersham, Cochran, Titgemeyer, Farmer, Klevesahl, Arroquy, Johnson and Gnad4) when casein was provided abomasally to steers. In contrast, Egan & Moir(Reference Egan and Moir6) observed a numerical decrease in DM digestion in sheep supplemented with UIP as casein when compared to control or post-ruminal urea provision. Garza et al. (Reference Garza, Owens and Welty16) observed greater ruminal DM digestibility when steers were supplemented with either casein or urea post-ruminally compared to control. Digestibility in the present study was likely not improved, in spite of greater microbial activity, because passage increases along with intake in response to higher levels of RAN(Reference Köster, Cochran, Titgemeyer, Vanzant, Abdelgadir and St. Jean20, Reference Olson, Cochran, Jones, Vanzant, Titgemeyer and Johnson21).

In general, N retention of cattle fed low-quality forage is improved in response to supplemental protein(Reference Wickersham7, Reference Hunter and Siebert22, Reference Hennessy and Nolan23), but the specific response to supplemental UIP has not been documented. The levels of N retention (3·4–37·8 g N/d) in the present study are similar to previous observations of cattle consuming low-quality forage and supplemented with protein. Hennessy & Nolan(Reference Hennessy and Nolan23) observed N retention of 3·6 g N/d when cattle were fed subtropical grass and not supplemented, and when supplemented (100 mg N/kg BW per d) cattle retained 15·6 g N/d. Supplementation of similar levels of casein as DIP led to a linear increase in N retention from − 2·7 to 35·2 g N/d(Reference Wickersham7), which is very similar to the response when UIP was supplemented. In the current study, growth of steers was likely more limited by energy supply than by protein supply, and, thus, the increases in N retention with UIP provision likely resulted from increases in energy supply rather than from the direct increases in protein supply. The provision of UIP not only increased the energy supply by directly providing a source of digestible amino acids that could be catabolized and used as a source of energy, but also by increasing forage intake as a result of N from the UIP being recycled to the rumen as urea. The entry of urea-N into the gut increases energy intake by stimulating ruminal fermentation and increasing forage intake and TDOMI, which is in accordance with the work of Egan & Moir(Reference Egan and Moir6) and Egan(Reference Egan15).

Supplemental UIP increased urinary N excretion linearly (P < 0·03), but the magnitude of the increase in urinary N excretion was less than the observations of Archibeque et al. (Reference Archibeque, Burns and Huntington24) and Marini & Van Amburgh(Reference Marini and Van Amburgh25) when N intake was increased. Hunter & Siebert(Reference Hunter and Siebert22) also reported that supplementation with cottonseed meal resulted in only small increases in urinary N excretion. Faecal excretion of N increased somewhat more than urinary N excretion in response to supplementation, which is also in accordance with the observations of Hunter & Siebert(Reference Hunter and Siebert22) and Wickersham(Reference Wickersham7). Increased N intake in some other work did not increase faecal N excretion(Reference Archibeque, Burns and Huntington24Reference Archibeque, Burns and Huntington26). Faecal N excretion in the present study was increased with provision of increasing amounts of N because microbial growth (ruminal microbial N that is indigestible in the intestine, intestinally synthesized microbial N that is directly excreted in faeces, or both) and forage intake were increased, both of which increase the excretion of N in the faeces. Concomitantly, urinary N was not greatly increased because additions of N to our diet were largely used either directly by the steers for protein deposition or conserved by the animal through urea recycling mechanisms and subsequently incorporated into microbial N, which could contribute to both faecal and retained N.

Quantifying urea kinetics and the incorporation of recycled urea-N into ruminal microbial N with increasing provision of UIP were the primary objectives of the present study. Production of urea increases as N intake increases(Reference Wickersham7, Reference Cocimano and Leng27, Reference Bunting, Boling and MacKown28). Urea production as a fraction of N intake was 0·54 when no supplemental protein was provided. When supplemental protein was provided as UIP, urea production as a fraction of N intake averaged 0·74. In contrast, urea production as a fraction of N intake was 0·46 when supplemental DIP was provided(Reference Wickersham7). In further contrast to the present study, urea production as a fraction of N intake in dairy heifers averaged 0·27(Reference Marini and Van Amburgh25) and in steers consuming different grasses it averaged 0·28(Reference Archibeque, Burns and Huntington24) and 0·43(Reference Archibeque, Burns and Huntington26). Hennessy & Nolan(Reference Hennessy and Nolan23) reported urea productions as fractions of N intakes of 0·62 and 0·53 for supplemented and unsupplemented steers, respectively. Urea production as a fraction of N intake in the present study was higher than other studies because N was provided in a different form, UIP v. DIP. The present observation is, in part, supported by the numerically greater plasma urea-N concentrations observed by Bandyk et al. (Reference Bandyk, Cochran, Wickersham, Titgemeyer, Farmer and Higgins3) and Wickersham et al. (Reference Wickersham, Cochran, Titgemeyer, Farmer, Klevesahl, Arroquy, Johnson and Gnad4) when equal amounts of casein were supplied as UIP v. DIP in cattle consuming low-quality forage. Their reported differences in plasma urea-N concentrations existed despite significantly greater ruminal ammonia concentrations in both studies when casein was supplied as DIP v. UIP. These differences between UIP and DIP occurred for two reasons: (1) when UIP was supplemented, microbes did not have first access to the N, which prevented formation of indigestible microbial residues or of products (e.g. purines) for which the end-point of metabolism does not involve urea synthesis (the difference between the present study and Wickersham(Reference Wickersham7) with DIP supplementation), and (2) energy availability (i.e. forage intake) did not increase as rapidly as metabolizable protein supply resulting in the catabolism of the excess amino acids with the subsequent production of urea which could be recycled to the gut.

Urea can be excreted in the urine or be recycled to the gastrointestinal tract (gut entry). Urinary urea excretion was increased with provision of increasing amounts of UIP, in accordance with observations(Reference Wickersham7) where increasing DIP provision augmented urinary urea excretion, but fractional urinary excretion was only 0·11 of production at the highest level of supplementation. The low urinary urea excretion despite increased urea production indicates the remarkable ability of cattle to conserve N through urea recycling mechanisms in the face of a severe N deficiency. Hennessy & Nolan(Reference Hennessy and Nolan23) and Thornton(Reference Thornton29) also reported low excretions of urinary urea: 0·41 and 1·6 g urea-N/d when cattle were fed carpet grass hay (49 g crude protein/kg DM) or oat straw (19 g crude protein/kg DM), respectively. When sheep were fed low-quality forage, the fraction of urinary N from urea was 0·35(Reference McIntyre30). Using a higher-quality forage (88 g crude protein/kg DM), Archibeque et al. (Reference Archibeque, Burns and Huntington24) reported that 0·32–0·55 of urinary N excretion was urea. Archibeque et al. (Reference Archibeque, Burns and Huntington26) reported that 0·66–0·77 of urinary N excretion was as urea-N for steers fed tall fescue hay.

Gut entry of urea as a fraction of urea production in the present study ranged from 0·97 to 0·89, decreasing with UIP supplementation. Urea transfer to the gut at the low levels of supplementation was nearly as high as reported by Wickersham(Reference Wickersham7) when low levels of DIP were supplemented. Gut entry of urea increased with increasing provision of supplemental protein, but urea transferred to the gut as a fraction of N intake was greater when steers were supplemented with UIP (current study, 0·69) rather than DIP(Reference Wickersham7) (0·45). This likely was because urea production represented a greater proportion of intake when UIP rather than DIP was supplemented, because most of the urea production was recycled to the gut in both studies. Similar to the observations of the present study, high fractional transfers of urea production to the gut (0·84 and 0·87) have previously been reported Archibeque et al. (Reference Archibeque, Burns and Huntington24) and Marini & Van Amburgh(Reference Marini and Van Amburgh25). Additionally, Hennessy & Nolan(Reference Hennessy and Nolan23) reported fractional transfers of urea to the gut of 0·79 and 0·97 in supplemented and unsupplemented steers, respectively. The present study demonstrates that in the face of a RAN deficiency, UIP supplementation can provide a substantial amount of N to the rumen by increasing urea recycling. The low ruminal ammonia concentrations for all treatments and the increase in microbial protein flow in the face of increasing recycled urea in response to UIP supplementation demonstrate the ability of ruminal microbes to utilize the recycled N efficiently under the present experimental conditions.

In the present study, anabolic use of urea (g N/d) tended to increase (quadratic, P = 0·06) with increasing amounts of supplemental UIP. The difference between the present study and the work of Lobley et al. (Reference Lobley, Bremner and Zuur13) and Marini & Van Amburgh(Reference Marini and Van Amburgh25) is that in the present study provision of additional N stimulated microbial activity by providing RAN and thereby increased the intake of fermentable OM. The same stimulation of microbes occurred with DIP supplementation(Reference Wickersham7) except, with DIP supplementation, as more N became available for N recycling, the demand for N from recycling was diminished because of the direct provision of RAN as DIP.

Microbial incorporation of recycled urea-N increased quadratically with increasing supplemental UIP. In contrast, when increasing amounts of DIP were provided, microbial incorporation of recycled urea-N increased linearly(Reference Wickersham7). Marini & Van Amburgh(Reference Marini and Van Amburgh25) observed a decrease in microbial incorporation of recycled urea-N as N intake increased in dairy heifers. The fraction of total microbial N derived from microbial incorporation of recycled urea-N also increased quadratically (P = 0·05) in response to increasing UIP in the present study. In contrast, with DIP supplementation(Reference Wickersham7) there was no change in the fraction of total microbial N derived from recycled urea-N (average of 0·28). Similar to those observations, Neutze et al. (Reference Neutze, Kellaway and Faichney31) observed that, in sheep fed alkali-treated wheat straw and supplemented with urea, the fraction of microbial N derived from recycled urea-N was 0·12 and 0·31 for supplemented and unsupplemented sheep, respectively. In cattle fed a low-protein diet, Bunting et al. (Reference Bunting, Boling and MacKown28) found that recycled urea-N contributed 0·40 of microbial N. The quadratic response of microbial incorporation of recycled urea-N in the present study is explained by the plateauing of TDOMI, urea production and gut entry of urea when UIP supplementation increased from 124 to 186 mg N/kg BW per d. Between 0 and 124 mg N/kg BW per d, microbial incorporation of recycled urea-N increased by the equivalent of 0·87 of the UIP dose.

In the present calculation of microbial incorporation of recycled urea-N, all of the 15N appearing at the duodenum was attributed to incorporation of recycled urea-N. In contrast, Ouellet et al. (Reference Ouellet, Demers, Zuur, Lobley, Seoane, Nolan and Lapierre32) reported that endogenous secretions other than urea accounted for 13 % of duodenal N flow and that half of this N was found in microbial N. It is probable in the present study that a portion of the non-urea endogenous secretions would be labelled with 15N, which would inflate our measures of microbial incorporation of recycled urea-N, although differences between our steers fed low-protein diets and their dairy cows fed diets with 17·5 % crude protein would preclude extrapolation of their observations to the present data. In the model used by Ouellet et al. (Reference Ouellet, Demers, Zuur, Lobley, Seoane, Nolan and Lapierre32) they assumed that 0·12 of the microbial N was derived from urea-N, which is much less than the fraction of microbial N from recycled urea-N in the present study (0·31–0·58), and the length of their 15N infusion was much longer than ours (200 v. 96 h), which would increase the enrichment of the endogenous secretions. Further work would be required to determine how much 15N appears as endogenous N other than urea.

The contribution of recycled urea-N to meeting ruminal N requirements was increased as UIP provision increased up to 124 mg N/kg BW per d. Although UIP did not lead to increases in forage intake as large as expected for DIP, it did increase the energy and metabolizable protein supplied to the animal. If protein supplements that are high in UIP are cheaper than protein supplements high in DIP, there is an opportunity to utilize the UIP-containing supplements to increase ruminal N supply. The present study provides information that can be incorporated into feeding recommendations that will better account for the contributions of UIP to meeting ruminal N requirements.

Acknowledgements

This paper is contribution number 07-287-J from the Kansas Agricultural Experiment Station, Manhattan. Financial support of this research was provided by the Kansas Agricultural Experiment Station. The authors are unaware of any biases or conflicts of interest that may have prejudiced interpretation or presentation of results. T. A. W., E. C. T. and R. C. C. were responsible for developing the original hypothesis, selecting the appropriate experimental design and methodologies, data analysis, and data interpretation. T. A. W. and E. E. W. were responsible for animal care, implementation of the experimental protocol, sample processing and handling, and data processing. All authors contributed to development of the manuscript. The authors gratefully acknowledge Dr Roxane Fagan at North Carolina State University for her assistance in analysing 15N-enriched samples and Cheryl Armendariz at Kansas State University for her assistance in the laboratory.

References

1National Research Council (1996) Nutrient Requirements of Beef Cattle, 7th rev. ed.Washington, DC: National Academy Press.Google Scholar
2Mathis, CP, Cochran, RC, Heldt, JS, Woods, BC, Abdelgadir, IEO, Olson, KC, Titgemeyer, EC & Vanzant, ES (2000) Effects of supplemental degradable intake protein on utilization of medium- to low-quality forages. J Anim Sci 78, 224232.CrossRefGoogle ScholarPubMed
3Bandyk, CA, Cochran, RC, Wickersham, TA, Titgemeyer, EC, Farmer, CG & Higgins, JJ (2001) Effect of ruminal vs postruminal administration of degradable protein utilization of low-quality forage by beef steers. J Anim Sci 79, 225231.CrossRefGoogle ScholarPubMed
4Wickersham, TA, Cochran, RC, Titgemeyer, EC, Farmer, CG, Klevesahl, EA, Arroquy, JI, Johnson, DE & Gnad, DP (2004) Effect of postruminal protein supply on the response to ruminal protein supplementation in beef steers fed a low-quality grass hay. Anim Feed Sci Tech 115, 1936.CrossRefGoogle Scholar
5Kennedy, PM & Milligan, LP (1980) The degradation and utilization of endogenous urea in the gastrointestinal tract of ruminants: a review. Can J Anim Sci 60, 205221.CrossRefGoogle Scholar
6Egan, AR & Moir, RJ (1965) Nutritional status and intake regulation in sheep. I. Effects of duodenally infused single doses of casein, urea, and propionate upon voluntary intake of a low-protein roughage by sheep. Aust J Agric Res 16, 437449.CrossRefGoogle Scholar
7Wickersham, TA (2006) Effect of supplemental protein on nitrogen recycling in beef cattle consuming low-quality forage. PhD Thesis, Kansas State University.Google Scholar
8Marsh, WH, Fingerhut, B & Miller, H (1965) Automated and manual direct methods for the determination of blood urea. Clin Chem 11, 624627.CrossRefGoogle ScholarPubMed
9Broderick, GA & Kang, JH (1980) Automated simultaneous determination of ammonia and total amino acids in ruminal fluid and in vitro media. J Dairy Sci 63, 6475.CrossRefGoogle ScholarPubMed
10Read, WW, Harrison, RA & Halliday, D (1982) A resin-based method for the preparation of molecular nitrogen for 15N analysis from urinary and plasma components. Anal Biochem 123, 249254.CrossRefGoogle ScholarPubMed
11Volk, RJ & Jackson, WA (1979) Preparing nitrogen gas for nitrogen-15 analysis. Anal Chem 51, 463464.CrossRefGoogle Scholar
12Vanzant, ES & Cochran, RC (1994) Performance and forage utilization by beef cattle receiving increasing amounts of alfalfa hay as a supplement to low-quality, tallgrass-prairie forage. J Anim Sci 72, 10591067.CrossRefGoogle Scholar
13Lobley, GE, Bremner, DM & Zuur, G (2000) Effects of diet quality on urea fates in sheep assessed by a refined, non-invasive [15N15N]-urea kinetics. Br J Nutr 84, 459468.CrossRefGoogle ScholarPubMed
14Marini, JC & Attene-Ramos, MS (2006) An improved analytical method for the determination of urea nitrogen isotopomers in biological sample utilizing continuous flow isotope ratio mass spectrometry. Rapid Commun Mass Spectrom 20, 37363740.CrossRefGoogle ScholarPubMed
15Egan, AR (1965) Nutritional status and intake regulation in sheep. II. The influence of sustained duodenal infusions of casein or urea upon voluntary intake of low-protein roughages by sheep. Aust J Agric Res 16, 451462.CrossRefGoogle Scholar
16Garza, JD, Owens, FN & Welty, S (1991) Effect of postruminal protein infusion on feed intake and utilization of low quality hay by beef steers. Okla Agric Exp Sta Res Rep MP-134, 106113.Google Scholar
17Daniel, H, Vohwinkel, M & Rehner, G (1990) Effect of casein and β-casomorphins on gastrointestinal motility in rats. J Nutr 120, 252257.CrossRefGoogle ScholarPubMed
18Kil, SL & Froetschel, MA (1994) Involvement of opioid peptides from casein on reticular motility and digesta passage in steers. J Dairy Sci 77, 111123.CrossRefGoogle ScholarPubMed
19Froetschel, MA (1996) Bioactive peptides in digesta that regulate gastrointestinal function and intake. J Anim Sci 74, 25002508.CrossRefGoogle ScholarPubMed
20Köster, HH, Cochran, RC, Titgemeyer, EC, Vanzant, ES, Abdelgadir, I & St. Jean, G (1996) Effect of increasing degradable intake protein on intake and digestion of low-quality, tallgrass-prairie forage by beef cows. J Anim Sci 74, 24732481.CrossRefGoogle ScholarPubMed
21Olson, KC, Cochran, RC, Jones, TJ, Vanzant, ES, Titgemeyer, EC & Johnson, DE (1999) Effects of ruminal administration of supplemental degradable intake protein and starch on utilization of low-quality warm season grass hay by beef steers. J Anim Sci 77, 10161025.CrossRefGoogle ScholarPubMed
22Hunter, RA & Siebert, BD (1980) The utilization of spear grass (Heteropogon contortus). IV. The nature and flow of digesta in cattle fed on spear grass alone and with protein or nitrogen or sulfur. Aust J Agric Res 31, 10371047.CrossRefGoogle Scholar
23Hennessy, DW & Nolan, JV (1988) Nitrogen kinetics in cattle fed a mature subtropical grass hay with and without protein meal supplementation. Aust J Agric Res 39, 11351150.CrossRefGoogle Scholar
24Archibeque, SL, Burns, JC & Huntington, GB (2001) Urea flux in beef steers: effects of forage species and nitrogen fertilization. J Anim Sci 79, 19371943.CrossRefGoogle ScholarPubMed
25Marini, JC & Van Amburgh, ME (2003) Nitrogen metabolism and recycling in Holstein heifers. J Anim Sci 81, 545552.CrossRefGoogle ScholarPubMed
26Archibeque, SL, Burns, JC & Huntington, GB (2002) Nitrogen metabolism of beef steers fed endophyte-free tall fescue hay: effects of ruminally protected methionine supplementation. J Anim Sci 80, 13441351.CrossRefGoogle ScholarPubMed
27Cocimano, MR & Leng, RA (1967) Metabolism of urea in sheep. Br J Nutr 21, 353371.CrossRefGoogle ScholarPubMed
28Bunting, LD, Boling, JA & MacKown, CT (1989) Effect of dietary protein level on nitrogen metabolism in the growing bovine: I. Nitrogen recycling and intestinal protein supply in calves. J Anim Sci 67, 810819.CrossRefGoogle ScholarPubMed
29Thornton, RF (1970) Factors affecting the urinary excretion of urea nitrogen in cattle II. The plasma urea nitrogen concentration. Aust J Agric Res 21, 145152.CrossRefGoogle Scholar
30McIntyre, KH (1971) The effects of continuous intravenous and intraruminal infusion of urea on nitrogen metabolism in sheep. Aust J Agric Res 22, 429441.CrossRefGoogle Scholar
31Neutze, SA, Kellaway, RC & Faichney, GJ (1986) Kinetics of nitrogen transfer across the rumen wall of sheep given a low-protein roughage. Br J Nutr 56, 497507.CrossRefGoogle Scholar
32Ouellet, DR, Demers, M, Zuur, G, Lobley, GE, Seoane, JR, Nolan, JV & Lapierre, H (2002) Effect of dietary fiber on endogenous nitrogen flows in lactating dairy cows. J Dairy Sci 85, 30133025.CrossRefGoogle ScholarPubMed
Figure 0

Table 1 Chemical composition of grass hay and casein (g/kg DM)

Figure 1

Table 2 Effects of undegradable intake protein supplementation on intake, digestion and nitrogen balance of steers fed grass hay*

Figure 2

Table 3 Effects of undegradable intake protein supplementation on urea excretion, ammonia excretion and urea kinetics in steers fed grass hay*

Figure 3

Table 4 Effects of undegradable intake protein supplementation on duodenal nitrogen flows and recycled urea-nitrogen incorporation into microbial nitrogen in steers fed grass hay*

Figure 4

Table 5 Effects of undegradable intake protein supplementation on plasma urea-nitrogen concentration and ruminal fermentation characteristics in steers consuming grass hay*