Animals

Twelve male and nine female (all neutered) adult Labrador retrievers (n 21, average age 4·9 years, range 3–8 years) were used in this study. The number of dogs was determined using simulation analyses based on variance estimates of F¹³CO₂ from an unpublished IAAO study (Gray et al.) to provide a 95 % CI for the breakpoint concentration of methionine within 25 % of the mean with 90 % power. Dogs were housed in purpose-built, environmentally enriched housing at the WALTHAM Centre for Pet Nutrition. They interacted with other dogs within their sampling group and other, non-study dogs, but interaction with other study dogs was avoided to prevent any isotopic contamination. On IAAO sampling days, dogs were isolated from other animals to prevent coprophagia. Dogs were habituated to all trial procedures before the start of the study. The trial took place between January and June.

Diets

A semi-purified base diet was used to have consistency in the nutritional composition, minimising complex matrix effects while manipulating the methionine content. Nine diets (manufactured by ssniff Speziäldiaten GmbH) were nutritionally complete apart from methionine and formulated for dogs with an energy requirements of 397·48 kJ/kg^0·75, iso-energetic and iso-nitrogenous (see online Supplementary Tables S1 and S2 for formulation and nutritional profile analysis). The nine diets differed in methionine content: 0, 0·3, 0·6, 0·9, 1·2, 1·5, 1·8, 2·1 and 2·4 g/4184 kJ (analysed values 0, 0·31, 0·60, 0·97, 1·30, 1·61, 1·83, 2·15 and 2·47 g/4184 kJ, respectively). These values were selected to have four diets above and four diets below the methionine inclusion level of 1·16 g/4184 kJ (the NRC minimum recommended allowance adjusted to a maintenance energy requirement of 397·48 kJ/kg^0·75). To provide an acceptable consistency for consumption, the powdered diet was hydrated (15 %, w/w) immediately before offering to the dog. All diets were offered in amounts to maintain individual energy requirements, with BW and body condition score assessed weekly.

Study design

Each dog received each test diet in a randomised order. Dogs had at least 5 d washout between each test diet assessment, where they were offered Royal Canin Medium Adult (single batch, nutritionally complete) at 100 % maintenance energy requirement (see online Supplementary Table S3 for proximate analysis). For each test diet, dogs received the test diet for 2 d (four meals/d) prior to the assay day (day 3). On the 3rd day, dogs were fed to their maintenance energy requirement (based on intake in the week prior) distributed across eight equal aliquots (given at hourly intervals). Isotope (described below) was added from meal 4 onwards (Fig. 1). Two groups of dogs were fed the incorrect diet on one study day, and so for the diet containing 1·2 g/4184 kJ only fifteen dogs’ data were analysed.

Fig. 1.

Schematic of indicator amino acid oxidation study day detailing timing of meals, breath sampling and [¹³C]phenylalanine supplementation.

Isotope tracer addition

The first three meals were used to obtain a baseline measure of breath ¹³CO₂ enrichment (i.e. no isotope added). Breath samples were taken immediately before feeding meal 3 and meal 4. In meal 4, a priming dose of 3 mg/kg BW ¹³C-Phe (Cambridge Isotope Laboratories) was added when the meal was hydrated. Further doses (2 mg/kg BW) were given in meals 5, 6, 7 and 8. Subsequent to meal 3, breath samples were taken at 30-min intervals, just prior to, and 30 min after, each meal (Fig. 1).

Sample collection and analysis

Breath samples were collected using a veterinary respiratory mask connected to a breath collection bag (Quintron, QT00830-P). Approximately 12 ml of breath was syringed from the bags and injected into a vacutainer, two vacutainers were collected for each breath sample. The samples were then run on a Continuous Flow Isotope Ratio Mass Spectrometer (CF-IRMS AP2003, Analytical Precision) to determine the delta ¹³C.

Basal carbon dioxide production (sodium bicarbonate analysis)

Oral dosing of ¹³C-sodium bicarbonate (NaH¹³CO₃) was used to calculate CO₂ production rate, based on the methodology of Larsson et al. ^{(Reference Larsson, Junghans and Tauson24)}. CO₂ production rate was measured at the beginning and end of the study, an average of these two points to calculate basal CO₂ production rate for each dog.

Atom percent and atom percent excess calculation

Atom percent (AP) and AP excess (APE) were calculated from the delta ¹³C values, where R is the ratio of ¹³C:¹²C of the international Pee Dee belemnite standard (R 0·0112372) using the following respective equations:

$${\rm{AP}} = 100/({\rm{ }}1/\left( {\left( {\left( {{\rm{delt}}{{\rm{a}}^{13}}C/1000} \right) + 1} \right) \times R} \right) + 1)$$

$${\rm{APE}} = {\rm{AP}}_{{\rm{sample}}} - {\rm{AP}}_{\rm{Baseline}}$$

Carbon dioxide production rate and retention factor calculation

The CO₂ production rate (RCO₂) and bicarbonate retention factor (RF) were calculated using the following equations, where D represents the tracer dose administered, AUC represents AUC (sodium bicarbonate analysis) and A represents abundance of ¹³CO₂ (parts per million) in expired breath samples:

$${\rm{RCO}}_2 = \left(D/{\rm{AUC}}\right) \times {\rm{RF}}$$

$${\rm{RF}} = \left( {{\rm{A}} \times {\rm{RCO}}_2} \right)/D$$

F¹³CO₂ calculation

The rate of appearance of ¹³CO₂ in the breath (F¹³CO₂) (µmol/kg per h) was calculated using the following equation:

$${\rm F}^{13}{\rm CO}_2 = \left( {\rm RCO}_2 \times {\rm ECO}_2 \times 44\cdot6 \times 60 \right)/\left( {\rm BW} \times 0\cdot82 \times 100 \right)$$

where ECO₂ is the ¹³CO₂ enrichment in expired breath at isotopic steady state (APE), and BW is the body weight (kg) of the dogs. The constants 44·6 and 60 convert FCO₂ into µmol/h. The factor 100 changes APE to a fraction. The factor 0·82 was used to account for the retention of ¹³CO₂ in the bicarbonate pool of the body in the fed state (RF).

Calculation of the breakpoint (mean methionine requirement)

F¹³CO₂ was analysed using a mixed-effects breakpoint regression model^{(Reference Davison25)}. Using a mixed-effects model accounts for the correlation between repeated measures within each dog, thus random effects of dog were fitted, with a random y-intercept and random slope variances estimated. The breakpoint analysis modelled two regression slopes, one before the breakpoint and one after the breakpoint, where the slope after the breakpoint was forced to have a slope of zero. The model is defined by:

$${y_{id}} = {\beta _0} + {\beta _1} \times \left( {{\rm{BP - }}{{\rm{x}}_{{\rm{id}}}}} \right) \times I\,\left( {{x_{id}}{\rm{ < BP}}} \right){\rm{ + b}}{{\rm{0}}_{\rm{i}}}{\rm{ + }}\,{\rm{b}}{{\rm{1}}_{{\rm{id}}}}{\rm{ + }}\,{\varepsilon _{{\rm{id}}}},$$

where i = 1… no. of dogs, d = 1… no. of diets, BP is the breakpoint and so the estimated mean methionine requirement, x _id is the dth diet on the ith dog, I(x _id < BP) = 1 if x _id < BP or 0 otherwise, I(x _id ≥ BP) = 0 if x _id < BP or 1 otherwise, β ₀ = F¹³CO₂ value at the breakpoint, –β ₁ is the slope when x _id < BP, b0_i is the random intercept of the ith dog (normally distributed), b1_id is the random slope of ith dog when x _id < BP (normally distributed) and ε _id is the independently normally distributed random errors.

The model was fitted by allowing the breakpoint to vary from minimum + 0·5 to the maximum – 0·5 methionine contents offered, with 1000 breakpoints fitted in total. The Akaike information criterion of the fitted models conditional upon the breakpoint was then minimised. This maximised the profile log likelihood for the breakpoint, giving the best fitting model and associated breakpoint. We calculated 95 % CI for the breakpoint using the profile log likelihood, with the lower and upper limits set at the models with an Akaike information criterion equal to the minimised + χ ₁^{2(Reference Hayamizu, Kato and Hattori26)}.

The breakpoint analyses were performed in R version 3.0.2⁽²⁷⁾ using the lme4 library^{(Reference Pinheiro, Bates and DebRoy28)}.

Animals

Adult Labrador retrievers (n 52) were used in this study (average age 5·2 years, range 2·3–8·2 years at start of study). One dog was removed from the study at week 8 (n 51) and another at week 16 (n 50) for reasons unrelated to the study. Data from dogs removed from the study were included in the analysis up to the point they were removed from the study. Dogs were housed and exercised with other dogs in their dietary group throughout the whole trial. Dogs were habituated to all trial procedures in accordance with WALTHAM welfare and ethical principles. The trial took place between January and October.

Diets

To remain consistent with the IAAO study, all diets were semi-purified (ssniff Speziäldiaten Gmbh) and produced in a pelleted format (2·5 cm), differing in methionine and cystine content to maintain total SAA (see online Supplementary Tables S4 and S5 for formulation and nutritional profile analysis). control diet (control diet) contained 1·37 g/4184 kJ methionine; the breakpoint diet (test diet 1) 0·55 g/4184 kJ methionine and the upper 95 % CL diet (test diet 2) contained 0·71 g/4184 kJ methionine. All diets were iso-energetic and iso-nitrogenous (via alanine) and nutritionally complete⁽¹⁹⁾, except for the reduced level of methionine in test diets (total SAA content being maintained by the addition of dietary cystine). Diets were fed at 100 % of individual maintenance energy requirement, estimated from 28 d of pre-feeding the control diet to maintain a stable BW and body condition score using the SHAPE scoring system. Food was provided in one meal (80 % ration) at 08.30 hours and the remaining 20 % provided as treats throughout the day (all fed by 16.00 hours).

Diet analysis and protein digestibility

All diets underwent full nutritional analysis (online Supplementary Table S5 (Eurofins)). The pelleted diets used in the longitudinal study were used to determine protein digestibility. A mixed breed panel (n 8) was fed study diets for 9 d, faeces collections were made on days 7–9 and samples were analysed for protein digestibility (Mars Petcare Europe Central Laboratory).

Study design

The primary objective of the study was to determine whether a reduction in dietary methionine intake would result in a physiologically meaningful change in plasma methionine concentrations between the test and control diets. Canine plasma methionine can differ by at least 20 % between dogs fed nutritionally complete diets^{(Reference Delaney, Kass and Rogers29)}. Sample size analyses by simulation were performed using methionine data derived from an unpublished results (Gray et al.) using a standard diet to inform estimates of the within and between dog variability. The method estimated that seventeen dogs per group were needed to detect a 20 % change in methionine with at least 90 % power using a test level of 5 %.

All dogs were fed the control diet (1·37 g/4184 kJ) for 4 weeks at the beginning of the study, all dogs then had a baseline sample taken before being randomised to one of three dietary groups balanced for age and sex. Group 1 remained on the control diet. Group 2 (IAAO Breakpoint) transitioned to test diet 1 (0·55 g/4184 kJ) and Group 3 (upper 95 % IAAO CL) transitioned to test diet 2 (0·71 g/4184 kJ) for 32 weeks. Fasted blood and urine samples were taken every 8 weeks (weeks 8, 16, 24 and 32). To minimise scavenging of bile/SAA derivatives, all dogs were monitored 24 h/d for 1 week prior to blood sampling to ensure all faeces samples were collected immediately and the dogs did not practice coprophagia. BW and body condition score were assessed weekly.

Blood sample preparation

Whole-blood samples (EDTA) were centrifuged and plasma collected in aliquots and frozen at –80°C until analysis, unless otherwise stated.

Plasma amino acid analysis

Sample processing buffer (5 % SSA + 500 µmol/l norleucine + d-glucosaminic acid) was added 1:1 to plasma, mixed using a Vortex Whirlimixer and allowed to incubate at room temperature for 20 min. Sample was then centrifuged at 7000RCF, for 5 min at 4°C. Supernatant was then removed and filtered with a Whatman Mini-Uniprep Syringeless 0·2 µm filter, aliquoted and frozen at –80°C for later analysis. Samples were analysed in duplicate on the Biochrom 30+ analyser (Biochrom).

Plasma choline, betaine and dimethylglycine analysis

Plasma (50 µl) was combined with 20 µl of internal standard working solution (2·0 mg/l D9 choline chloride and 2·5 mg/l D11 betaine), to standardise the results from the sample, and 200 µl of acetonitrile for protein precipitation. The resulting solution was mixed with a Vortex Whirlimixer before being centrifuged for 10 min at 7000RCF. The supernatant was filtered and 50 µl transferred to a culture tube, where 2·45 ml acetonitrile:water solution (85:15) was added and the resulting 50× diluted solution was vortexed and filtered through a 0·2 µm syringe filter. From this, 5 µl was injected in duplicate. The analysis was carried out by a coupled chromatograph and MS (Agilent 1290 UPLC and Agilent 6460c Mass Spectrometer) at 30°C for a total of 6 min (Talbot & Coffey, unpublished results).

Plasma homocysteine analyses

Plasma (50 µl) combined with 20 µl of internal standard working solution (containing 20 mmdl-homocysteine-3, 3, 3″, 3″, 4, 4, 4″, 4″-D) and 20 µl of dithiothreitol (500 mm) to reduce the homocystine to homocysteine so all homocysteine present was measured. The sample was then mixed using a Vortex Whirlimixer and left to stand for 15 min before the addition of acetonitrile (200 µl). It was vortexed, left to settle and vortexed again, followed by being centrifuged at 7000RCF for 10 min. The supernatant was filtered through a 0·2 µm PVDF filter, by syringe filter into a HPLC autosampler vial and analysis was carried out with a coupled chromatograph and MS (Agilent 1290 UPLC and Agilent 6460c Mass Spectrometer) at 30°C for a total of 6 min (Talbot & Coffey, unpublished results) with each sample being injected into the instrument twice. This process was carried out in duplicate to get a number of replicates to give the total amount of homocysteine within each sample.

Plasma S-adenosylmethionine and S-adenosylhomocysteine

Plasma (300 µl) was acidified at point of collection with 30 µl 1m acetic acid to prevent SAM degradation^{(Reference Kirsch, Knapp and Geisel30)} and vortexed for 5 s, plasma was then snap-frozen and placed in storage at –80°C until analysis. SAM and SAH analysis (Center of Metabolomics at the Baylor Scott & White Research Institute) was conducted for control diet and test diet 1 at 0, 16 and 32 weeks of the study.

Whole-blood taurine analysis

Whole blood (200 µl) was aliquoted into three Eppendorf tubes and frozen at –20°C. To lyse erythrocytes, samples were subjected to two freeze/thaw cycles. After the final thaw, sterile water was added to a dilution of 1:4 to lyse the cells further. Sampling processing buffer (5 % SSA, 500 µmol/l norleucine and d-glucosaminic acid made up in lithium loading buffer) was added at a 1:2 dilution in order for analysis to be normalised, positively charge the AA and also deproteinise the sample. The sample was mixed using a Vortex and incubated at room temperature for 20 min, before being centrifuged for 5 min at 4°C at 7000RCF. Supernatant was removed and transferred to a Whatman Mini-Uniprep Syringeless 0·2 µm filter vial to filter the sample. The final sample was at a 1:8 dilution and was injected into the instrument in duplicate. The analysis was carried out using a Biochrom 30+ Analyser (Biochrom).

Urinary taurine analysis

Urine samples were snap-frozen after collection using dry ice and transferred to a –80°C freezer until ready for analysis. Samples were thawed on the day of analysis and diluted with sample diluent (5 % SSA (Sigma) and loading buffer (Biochrom)), one part urine to five parts sample diluent. Sample processing buffer was added at a 1:2 dilution, mixed with a Vortex mixer and left at room temperature for 20 min. The sample was centrifuged for 5 min at 4°C and 7000RCF. Supernatant was removed and filtered using a Whatman Mini-Uniprep Syringeless 0·2 µl filter vial. Samples with a final dilution of 1:12 were then run on the Biochrom 30+ Analyser (Biochrom).

Urinary creatinine

Urine samples were stored at 4°C after collection until analysis, at which point the samples were centrifuged at 2000RCF for 5 min at 4°C. Urine was then analysed on an AU480 Analyser (Beckman Coulter).

Plasma biochemistry and creatine kinase

Whole-blood samples (EDTA) were centrifuged for 10 min at 4°C at 2000RCF. The plasma was removed and transferred into 2·5 ml sample cups. Samples were then run on the AU480 Chemistry Analyser (Beckman Coulter), analysed parameters include total protein, albumin, phosphate, alkaline phosphatase, alanine aminotransferase, aspartate aminotransferase, Ca, cholesterol, urea, creatinine, TAG, glucose and creatine kinase. Further parameters measured were lipidaemia/turbidity, icterus and haemolysis as an internal test to ensure no photometric interference was present within the plasma.

Plasma N-terminal pro B-type natriuretic peptide

Plasma samples were packed frozen on dry ice and shipped overnight to a reference laboratory for analysis (IDEXX Laboratories).

Statistics

The primary response variable was plasma methionine. Secondary supportive response variables were plasma choline, betaine, dimethylglycine (DMG), homocysteine, SAM and SAH. Additional recorded measures included whole-blood taurine, plasma taurine, urinary taurine, clinical health measures (plasma NT proBNP (IDEXX) and biochemistry) and daily energy intake (calculated from the amount of diet offered minus left after meal and energy density of the diet).

For each response measured, linear mixed model analyses (restricted maximum likelihood) were used to allow for repeated measures on each dog over time. Specifically, where there were technical repeats for a measure at each time point, random effects of week nested in dog were used, but where only single measurements were available at each time point a random effect of dog was used. Categorical fixed effects of diet, week and their interaction were used.

Distributional assumptions were checked to ensure robustness of the statistical models by performing residual checks (e.g. for randomness and constant variance). Residuals were found to have increasing variability for a number of measures (homocysteine, choline and betaine); therefore, these measures were log₁₀ transformed prior to analyses.

As plasma methionine was the only primary measure, an overall test level of 5 % was used. Secondary measures were also tested against a test level of 5 % as they were supportive. Planned contrasts investigated the changes from week 0 (baseline) to weeks 8, 16, 24 and 32 within each diet and the differences between each diet at each week. Family wise adjustments were made for the number of comparisons to maintain the overall test level at 5 % for each measure. Accordingly, means, differences in means or fold changes of means (where log₁₀ transformation was necessary) are reported with 95 % family wise CI.

Analyses were performed in R version 3.2.4 using libraries nlme ^{(Reference Pinheiro, Bates and DebRoy28)} for linear mixed effects models, multcomp ^{(Reference Hothorn, Bretz and Westfall31)} for simultaneous inference of planned contrasts and ggplot2 ^{(Reference Wickham32)} for figures.