Experiment I

A total of thirty-six barrows (initial BW 18·6 (se 0·70) kg) were blocked by time in two equal groups of eighteen pigs and randomly assigned to dietary treatments. Dietary treatments were arranged in a 3 × 2 factorial randomised complete block design with two main factors: (1) three levels of dietary SAA allowance (1·0, 2·4 or 3·6 g/d, representing 15, 37 and 55 %, respectively, of established SAA requirements for maximum growth for pigs of this BW^{( 16 )}) and (2) ISS (ISS −  v. ISS+). A total of three soya protein isolate and maize starch-based diets were formulated, in which SAA were among the first-limiting AA (diets 1 to 3; Table 1). The dietary SAA levels were achieved by altering the ratio of maize starch:soya protein isolate, which contains relatively low levels of SAA (Table 1). The ratios of essential AA:SAA in soya protein exceed the recommendations given by Wang & Fuller⁽ Reference Wang and Fuller ^{17 )} and the National Research Council^{( 16 )} by 20 % (Table 1). The diets were calculated to contain 5·0 MJ/kg of metabolisable energy. The diets were fortified with vitamins and minerals to surpass the requirements recommended by the National Research Council (Table 1)^{( 16 )}. Titanium dioxide (0·1 % TiO₂; Sigma-Aldrich Limited) was included in all the diets as an indigestible marker for determining ileal digestibility of nutrients. Pigs were fed equal meals twice per d at 08.00 and 16.00 hours. Daily feed allowance was restricted to 800 g/d, resulting in daily metabolisable energy intakes of 12·0 MJ/d, to ensure constant energy intake levels across all the dietary treatments. Water intake was restricted to 2·5 litres/d to avoid water spillage and contamination of urine. A 5 d pre-ISS N balance was conducted to establish the PD of individual pigs as influenced by the SAA intake levels (n 12). At the end of the pre-ISS N-balance period, pigs at each SAA dietary level were injected intramuscularly with either lipopolysaccharide (LPS) (n 8; ISS+) or the same volume of a sterile saline solution (n 4; ISS − ). ISS was induced by an intramuscular repeated injection of increasing doses of Escherichia coli LPS every 48 h for 7 d. The initial dosage of 60 μg/kg BW was increased by 12 % at subsequent injections to avoid LPS tolerance⁽ Reference Deitch ^{18 )}. Subsequently, two consecutive N-balances (lasting 3 and 4 d, respectively) were conducted to monitor the pattern of PD during ISS.

Table 1 Ingredient composition and analysed nutrient contents of the experimental diets

SAA, sulphur amino acids.

* Provided the following amounts of vitamins and trace minerals (per kg of diet): vitamin A (as retinyl acetate), 4·1 mg; vitamin D₃ (as cholecalciferol), 0·03 mg; vitamin E (as dl-α-tocopherol acetate), 48 mg; vitamin K (as menadione), 3 mg; pantothenic acid, 180 mg; riboflavin, 6 mg; choline, 600 mg; folic acid, 2·4 mg; niacin, 30 mg; thiamin, 18 mg; pyridoxine, 1·8 mg; vitamin B₁₂, 0·03 mg; biotin, 0·24 mg; Cu (as CuSO4·5H₂O), 18 mg; Fe (as FeSO₄), 120 mg; Mn (as MnO₂), 124 mg; Zn (as ZnO), 126 mg; Se (as Na₂SeO₃), 0·36 mg; I (as KI), 0·6 mg (DSM Nutritional Products Canada, Inc.).

† Calculated value, MJ/kg.

Experiment II

A total of twenty-four barrows (initial BW 23·4 (se 0·43) kg) were blocked by time in two equal groups of twelve pigs and randomly assigned to dietary treatments. Dietary treatments were arranged in a 2 × 2 factorial randomised complete block design with the following factors: (1) two levels of dietary SAA allowance (4·0 or 5·0 g/d, representing 61 and 77 %, respectively, of established SAA requirements for maximum growth for pigs of this BW^{( 16 )} and (2) ISS (ISS −  v. ISS+). Compositions of the experimental diets are presented in Table 1 (diets 4 and 5). The same principles were used for diet formulation as in Expt I, with the exception of using a soyabean meal as the sole source of dietary AA in Expt II. As per Expt I, a 5 d pre-ISS N-balance period (n 12 at each dietary SAA level) was followed by two N-balance periods during ISS. At the end of the first N-balance period, half of the pigs (n 6) at each dietary SAA level were injected intramuscularly with either LPS or the same volume of a saline solution, as described in Expt I.

Body weight and body temperature

BW was measured at the beginning and end of each N-balance period. Eye temperature (Expt I) or rectal temperature (Expt II) was monitored daily. Thermography of eye was performed using an IR camera (ThermaCam™ SC2000; FLIRSystems, Inc.⁽ Reference Montanholi, Odongo and Swanson ^{19 ,} Reference Hughes, Patterson and Thornton ^{20 )}). The camera was calibrated each day for room temperature and relative humidity⁽ Reference Montanholi, Odongo and Swanson ^{19 )}. The emissivity value was set at 0·98 according to the camera manufacturer's recommendation for biological tissues. Multiple IR pictures were taken approximately 0·8 m from the right eye and the best pictures, in terms of focus and precision, were selected for interpretation. The IR pictures were interpreted using ThermaCam™ Researcher 2001 software (FLIR Systems AB). An average of the best three pictures was taken and used for further analysis and interpretation. Due to the unavailability of the IR camera in Expt II, rectal temperature was measured⁽ Reference Hughes, Patterson and Thornton ^{20 )}.

Nitrogen balance

Urine was collected quantitatively and sampled daily as described by Zhu et al. ⁽ Reference Zhu, Rademacher and de Lange ^{21 )}. Urine was collected in tared bottles, containing a sufficient amount of 5 m-HCl to maintain a pH below 2·5. Faeces were collected twice daily and stored in sealed plastic bags at − 20°C until further processing. At the end of each N-balance period, faeces were thawed, pooled for each pig, homogenised using a Hobart mixer (Hobart Corporation) and kept in sealed plastic bags at − 20°C until further processing. Wasted feed, including vomit, was collected quantitatively using feed wastage trays, pooled for each pig and N-balance period, oven dried at 60°C, left overnight and then weighed to derive the actual daily N intake.

Blood collection and processing

Blood samples were taken by retro-orbital sinus bleeding at the end of the last N-balance period. For complete blood cell counts, blood was collected in tubes containing EDTA (BD Vacutainer; BD) kept on ice and analysed within 2 h after collection. For measuring serum albumin and haptoglobin levels, blood samples were collected in a serum tube containing clot activator (BD Vacutainer), left at room temperature for 1 h, centrifuged at 1500  g and stored at − 20°C. For determining plasma fibrinogen levels, blood samples was collected in tubes containing sodium citrate (BD Vacutainer), centrifuged immediately for 10 min at 1500  g at 4°C and stored at − 20°C.

Apparent ileal digestibility of nutrients and organ weights

The slaughter technique was used to measure the apparent ileal digestibility (AID) of nutrients⁽ Reference Low ^{22 )}. Between 6 and 7 h, after the morning meal and immediately after euthanasia, a ventral abdominal incision was made, spleen and liver were removed, rinsed with physiological saline, blotted dry and weighed. The last 100 cm of the small intestine was then isolated and clamped to prevent digesta movement. The ileum was then excised and the ileal digesta were gently expelled, collected and stored at − 20°C until further processing.

Chemical analysis

Blood levels of acute-phase proteins and complete blood cell counts were determined at the Animal Health Laboratory of the University of Guelph. Serum albumin and haptoglobin levels were analysed using a Roche cobas c501 biochemistry analyser (Roche Diagnostics)⁽ Reference Doumas, Watson and Biggs ^{23 ,} Reference Makimura and Suzuki ^{24 )}. Plasma fibrinogen was quantified using a KC4 Delta semi-automatic coagulation analyser (Trinity Biotech) and a TirinitClot kit (TriniCLOT™ Fibrinogen; Trinity Biotech). Complete blood count was performed using the ADIVA 120 Hematology System (Siemens Healthcare Diagnostics, Inc.).

Faecal samples along with ileal digesta and dietary samples were freeze-dried, ground and thoroughly mixed before analysis. TiO₂ and DM were determined according to the standard Association of Official Analytical Chemists procedures^{( 25 )}. N contents of the faeces and urine were measured using a LECO FP-428 Nitrogen Determinator combustion instrument (LECO Corporation) and analysed according to the standard Association of Official Analytical Chemists procedures^{( 25 )}. Ileal digesta and dietary N contents were determined by LECO FP-2000 (LECO Corporation) at the laboratory of Evonik Degussa GmbH. Gross energy of the dietary and ileal digesta samples was determined as suggested by Widyaratne & Zijlstra⁽ Reference Widyaratne and Zijlstra ^{26 )} using an IKA oxygen bomb calorimeter (model C 5003; IKA GmbH & Company KG).

AA analyses of the feed and digesta samples were performed at the laboratory of Evonik Degussa GmbH. AA contents in the dietary and ileal digesta samples were determined by ion-exchange chromatography with post-column derivatisation with ninhydrin. Before protein hydrolyses, AA were oxidised with performic acid, which was neutralised with sodium metabisulphite⁽ Reference Llames and Fontanie ^{27 )}. The samples were hydrolysed with 6 m-HCl for 24 h at 110°C. AA were quantified with the internal standard method by measuring the absorption of reaction products with ninhydrin at 570 nm.

Calculations

The AID of crude protein (CP; N × 6·25), AA and gross energy were calculated using the indicator method and TiO₂ as an indigestible marker. Standardised ileal digestibility (SID) of AA was estimated as described by Stein et al. ⁽ Reference Stein, Fuller and Moughan ^{28 )}. The basal endogenous loss of each AA was calculated using the profile of basal endogenous AA in growing pigs as described by Jansman et al. ⁽ Reference Jansman, Sminka and van Leeuwena ^{29 )}.

SID SAA intake was calculated as follows:

$$\begin{eqnarray} SID\,SAA\,intake\,(g/d) = (SID\,SAA/100)\times (SAA_{diet}\times DMI), \end{eqnarray}$$ $$

where SID SAA is the SID of SAA (%) and SAA_diet and DMI are dietary SAA contents (g/kg DM) and DM intake (kg/d), respectively.

Whole-body PD (N retention × 6·25) was calculated as described by Zhu et al. ⁽ Reference Zhu, Rademacher and de Lange ^{21 )}. Faecal protein digestibility was measured, using TiO₂ as an indigestible marker, to compute faecal N excretion from dietary N intake.

Linear-plateau (broken-line) regression models were used to relate PD (g/d) to SID SAA intake (g/d) and to estimate the cross-over point of dietary SAA intakes required to just reach plateau or maximum PD in ISS+ and ISS −  pigs⁽ Reference Robbins, Saxton and Southern ^{30 )}.

At dietary SAA intakes below the cross-over point, the following linear regression model was used to estimate maintenance SID SAA requirements and the partial efficiency of SAA utilisation for PD:

$$\begin{eqnarray} PD\,(g/d) = a + b \times (SID\,SAA\ intake). \end{eqnarray}$$ $$

The regression coefficients a and b were used to estimate maintenance SID SAA requirements (g/d), i.e. SID AA intake when PD equals zero, calculated as − a/b. The regression coefficient b (g PD/g SID SAA intake) represents the partial efficiency of the utilisation of SID SAA intake for PD⁽ Reference Baker, Becker and Norton ^{31 )}.

Statistical analyses

Statistical analyses were carried out using SAS software version 9.1 (SAS Institute, Inc.). One-time observations such as final BW, organ weights, plasma acute-phase protein concentrations and measures of digestibility were analysed using a factorial randomised complete block design (PROC MIXED) with dietary SAA allowance (D; three and two levels in Expt I and II, respectively), ISS (ISS −  v. ISS+), interaction between D and ISS (D × ISS) and group of pigs (block) as fixed effects and pig within D and ISS as the random effect. Results for body temperature, PD and SID SAA intake were analysed separately for the two experiments as repeated measurements across the N-balance periods in a factorial randomised complete block design. This model included D, ISS, D × ISS, N-balance periods and block as fixed effects and pig within D and ISS as the random effect. Due to the sequential nature of the observations on each animal, a compound symmetry structure that yielded the model with the best fit was identified, according to the Akaike and Bayesian information criteria⁽ Reference Burnham and Anderson ^{32 )}. Values are reported as least-square means with their standard errors. The differences in the efficiency of SAA utilisation for PD (slopes) as well as SAA requirements for maintenance between the ISS −  and ISS+ pigs were tested using the regression procedure (PROC REG). Treatment effects were considered significant at P≤ 0·05. A tendency towards a significant difference between treatment means was also considered at P≤ 0·10.