Animals and experimental design

Experimental procedures were approved by the Central Animal Testing Committee, The Netherlands, and the Animal Welfare Body of Wageningen University (2017.W-0073.003). Fifteen (seven males and eight females) neutered 1-year-old domestic shorthair cats with an initial body weight between 3·6 and 5·2 kg were utilised from the feline unit of the research facility Carus (Department of Animal Sciences, Wageningen University, Wageningen, The Netherlands). The body condition score ranged between 5 and 8 on a scale of 1 (anorexic) to 9 (obese)^{(Reference Laflamme24)}. The cats were group-housed but fed individually (08.00, 11.00, 14.00 and 17.00 h) to maintain stable body weight and were weighed twice weekly. During collection periods, cats were housed in metabolic cages (0·80 × 1·00 × 0·75 m) fitted with a litter tray, and each group had 2 × 1 h of socialisation and play per day in the hallway of the facility. The group rooms were temperature-controlled (20°C) and maintained on a 12:12 h light–dark cycle. Enrichment in group rooms included scratching posts, hammocks and toys. Cats had free access to water and were cared for daily by animal caretakers and the trial leader. The trial leader was aware of the group allocation during the conduct of the experiment, the outcome assessment and the data analysis.

The cats were offered one-quarter of a mouse at several time points before the actual start of the trial to test their acceptance. One cat did not accept the mouse and was, therefore, excluded from the study. Fifteen cats were assigned to two groups according to body weight and sex resulting in a mean body weight of 4·5 (sd 0·4) kg for the cats fed MM (n 8) and 4·4 (sd 0·7) kg for the cats fed WM (WM; n 7). All participating cats were first individually fed a commercial extruded dry cat food (EXT) for 16 d with faecal samples collected during the final 3 d for microbiota analysis and to create a baseline for faecal fermentative end-product concentrations (EXT preMM; EXT preWM). The study had a parallel design with one feeding period. After 10 d of feeding MM and WM, total faeces and urine were collected for 5 consecutive days (postMM; postWM). Afterwards, urine was collected on day 15 to determine baseline for ¹⁵N values as on day 16, ¹⁵N-glycine (50·0 mg/ml; 5·0 mg/kg BW)^{(Reference Russell, Lobley and Millward25)} was included in the diets to gain insight into gastric emptying with urine collected for 48 h post ¹⁵N-glycine administration. Fresh faeces (within 15 min of defecation) for microbiota analyses were collected from day 16 to 19.

Diets

The extruded dry cat food was a commercial diet (Table 1). Specific pathogen-free mice, with an age range of 8 weeks to 12 months old, were obtained from Envigo (Envigo) and stored frozen until 30 min before feeding when they were thawed in a plastic bag in boiled water (water boiler) until they were defrosted. Mice were either minced in a blender or left whole receiving a midline incision to improve acceptability. The estimated metabolisable energy (ME) of mice was calculated using Atwater factors where ME (kJ/100 g DM) = 16·7 × crude protein (CP) + 35·6 × crude fat (EE) + 16·7 × nitrogen-free extract (NFE)⁽²⁶⁾ with the latter determined as 100 – moisture – CP – EE – crude fibre – crude ash (all in % of DM). Food intake and leftovers were weighed every feeding time. The amount of food offered to individual cats was adjusted when the cat gained or lost more than 1 % of body weight.

Table 1. Analysed chemical composition, amino acid composition and metabolisable energy content of the extruded dry cat food (EXT) and mice used in the experiment

EXT, extruded dry cat food; aNDF, amylase-treated neutral detergent fibre; ME, metabolisable energy; NFE, nitrogen-free extract.

* Perfect fit^TM adult 1+ rich in chicken (Mars Petcare Inc); ingredients: dried poultry protein (incl. 21 % chicken), wheat, greaves protein, soya protein, oils and fats (incl. 0,4 % sunflower oil), soya meal, rice (4 %), dried cereal protein, hydrolysed liver, minerals, cellulose, and dry algae.

† aNDF and crude fibre are techniques developed to quantify plant fibre, not animal fibre.

‡ The average of the values calculated by Atwater factors where ME (kJ/100 g DM) = 16·7 × % crude protein + 35·6 × % crude fat + 16·7 × % nitrogen-free extract. NFE was determined as 100 – % moisture – % crude protein – % crude fat – % crude fibre – % crude ash.

§ Not available.

Sample collection

The extruded dry cat food was subsampled, and sixteen defrosted mice were minced in a blender, freeze-dried (ScanVac CoolSafe^TM freeze-dryer) and ground over a 1-mm mill (Retsch ZM 200). The cats were acclimated to modified plastic litter boxes consisting of two identical, close-fitted trays positioned to slightly sloping to one corner to ensure complete collection of faeces and urine. The top tray contained a series of small holes at the lowest point and was filled with about 200 g of polyethylene grains (diameter 2 to 4 mm). The bottom tray contained 5 ml of 2M HCl to acidify urine immediately after voiding. Specific gravity was determined by collecting a small amount of urine present in the top tray. The litter boxes were checked every 15 min, and urine was then collected and stored at −20°C. Afterwards, urine was freeze-dried for determining the gross energy (GE) and stable isotope analyses. For the latter, subsamples of approximately 1·0 mg were weighed on a microbalance XP56 (Mettler-Toledo S.A.) into 8 × 5 mm tin capsules (Interchrom).

Fresh faecal pH was immediately determined after collection by sticking a pH probe directly in the core of the faeces at two different sites (within 15 min of defecation; pH meter WTW 340i, Geotech). The faecal samples were weighed and scored on a five-point visual scale where 1 is classified as ‘bullet like’ and 5 as ‘entire liquid stool’^{(Reference Moxham27)} and stored at −20°C. To subsample the faecal samples, they were placed overnight in a refrigerator (4°C). For NH₃, SCFA and biogenic amines (BA), subsamples of approximately 1·0 g were added to pre-weighed 15 ml of screw cap tubes (Sarstedt AG & Co. KG). One ml of 10 % TCA (for NH₃) or 1 ml of 0·1 M phosphoric acid (for SCFA) was added to the screw cap tubes. The contents of the tubes were vigorously mixed, weighed and stored at −20°C. For the determination of DM and the volatile organic compounds, approximately 1·0 g of subsample was added to a pre-weighed, 2-ml safe-lock tube (Eppendorf AG) and stored at −20°C (DM) or −80°C. Fresh faecal samples for microbiota analysis were immediately flash-frozen in liquid N₂ and stored at −80°C until DNA extraction.

Chemical analyses

Diets and faeces were analysed for DM and ash by drying to a constant weight at 103°C (EXT) or by lyophilisation (mice and faeces) and combustion at 550°C, respectively. Nitrogen was determined by the Kjeldahl method⁽²⁸⁾ with CP calculated as N × 6·25, and crude fat was determined by pre-hydrolysis according to the Soxhlet method⁽²⁹⁾. Crude fibre was analysed by acid-alkali digestion⁽³⁰⁾. A protease step (Megazyme; Subtilisin A from Bacillus licheniformis; 50 mg/ml) preceded the analyses of amylase-treated neutral detergent fibre (aNDF)⁽³¹⁾ because of samples having a high protein content. Both fibre analyses are developed to quantify plant fibre. Therefore, an underrepresentation of animal fibre is expected with these techniques^{(Reference D’Hooghe, Cools and Muñoz Saravia32)}. Analysis of amino acids of the diets (Table 1) was done by Feed & Food Quality (FFQ) with their in-house method based on EC 152/2009 (L54/23) for the oxidation and hydrolysis. The ultra-HPLC was according to the Waters ACCQ-tag method with pre-column derivatisation. Tryptophan was determined according to EC 152/2009 (L54/32). Dietary, faecal and urinary GE were determined using a Flash 2000 Elemental Analyzer (Thermo Fisher Scientific).

The δ¹⁵N isotope values were measured at the University of New Mexico Center for Stable Isotopes (Albuquerque, USA). The samples were combusted in a Costech 4010 elemental analyser (Costech) coupled to a Thermo Scientific Delta V mass spectrometer (Thermo Scientific). Reference material was atmospheric N₂ for N.

For the determination of NH₃ and SCFA, the subsamples were thawed, mixed and centrifuged at 14 000 rpm for 5 min at room temperature (Centrifuge Hereaus Megafuge 40R). Ammonia and SCFA concentrations were determined as described in Eertink et al. ^{(Reference Eertink, Wood and Pellikaan33)}. BA were determined as described in Saarinen^{(Reference Saarinen34)}. In brief, sample material (1·0 g) was added in a 15-ml falcon tube and shaken on maximum speed for 15 min with 2 ml of extraction solution (2 % sulphosalicyl acid dehydrate in 0·1 M HCl) for the extruded diet (EXT) faecal samples and 5 ml for the mice diet faecal samples. Afterwards, 0·5 ml of supernatant was transferred to 1·5 ml of Eppendorf cup together with 0·5 ml of internal standard solution (Heptylamine), mixed on a Vortex mixer, placed in an ice-bath for 15 min and centrifuged for 10 min (14 000 rpm; 18°C). The supernatant was pipetted for derivatisation with dansyl chloride. After derivatisation, 1·0 ml of supernatant was pipetted in vials. The vials were placed in the autosampler, and 30 µl was injected on the column (Agilent 5 TC-C18 250 × 4·6 mm) of the HPLC (Sykam S5200 analyser, Sykam GmbH). Detection took place by a fluorescent detector with an excitation at 250 nm and emission at 540 nm (RF-20A, SerCoLab). The faecal DM content was used to calculate SCFA, NH₃ and BA content in the original faeces. The volatile organic compounds phenol, x-cresol and indole were analysed as described in Vossen et al.^{(Reference Vossen, Goethals and De Vrieze35)}. There were a few alterations made to this method, that is, 0·5 g of faecal sample was used, there was no internal standard added and the solid phase micro-extraction fibre was exposed to each sample for 40 min at 38·5°C. The compounds were identified by comparing the chromatograms with the National Institute of Standard and Technology Mass Spectral Library (version 2.0, 2005) and retention time matching with external standards (phenol, x-cresol and indole). The data were obtained by expressing the relative area of specific quantifications ions for phenol, x-cresol and indole (respectively m/z 94, 107 and 117). The detection limit was set at 1 × 10⁴. We report x-cresol as p-cresol.

Calculations

When urine is collected with modified cat litter boxes containing polyethylene grains, some inevitable losses of urine occurs. Therefore, we measured the difference in volume and weight between a known amount of urine added to the litter box and the amount that was recovered. This was repeated twelve times, and the following linear regression was derived to calculate the amount of voided urine:

$${\rm{y}} = {\rm{1}} \cdot {\rm{1395}}\,{\rm{x}}\, + {\rm{3\cdot8523}}$$

where y = urine (ml) voided and x = urine (ml) collected and 4·2 < x < 44·0 ml.

The amino acids (AA) were calculated as a proportion of the sum of all AA (g /100 g AA) because of the large difference in DM% between EXT and mice.

GE (MJ/kg) was calculated after using the Flash 2000 Elemental Analyzer with the equation 0·3491 × C (weight percentage, wt%) + 1·1783 × H (wt%) + 0·1005 × S (wt%) − 0·0151 × N (wt%) − 0·1034 × O (wt%) − 0·0211 × ash (wt%)^{(Reference Obernberger and Thek36)}. The Flash 2000 Elemental Analyzer does not generate a value for O. Therefore, O + ash was calculated as 100 – H – N – S. Then, an average was calculated when the outcome of this calculation was presumed as O and when it was presumed as ash.

Apparent total tract digestibility values (%) were calculated using the equation: ((nutrient intake (g/d) − faecal nutrient output (g/d))/nutrient intake (g/d)) × 100. Dietary ME (kJ/kg) was calculated with data from individual cats utilising the equation ME = ((GE of food consumed (kJ/d) - GE of faeces collected (kJ/d)) - GE of urine collected (kJ/d))/amount of food consumed (kg/d).

The MUET of δ¹⁵N was calculated as an alteration on the calculation for the faecal mean retention time of Thielemans et al. ^{(Reference Thielemans, François and Bodart37)}:

$${\rm{MUET}}\,{\rm{(h)}} = \sum {{\rm{t}}_{\rm{i}}}\,{{\rm{C}}_{\rm{i}}}\,{\rm{\Delta}}{{\rm{t}}_{\rm{i}}}{\rm{/}}\sum {{\rm{C}}_{\rm{i}}}\,{\rm{\Delta}} {{\rm{t}}_{\rm{i}}}$$

where t_i is the average time between the collection time of sample i and that of sample i-1, C_i is the marker concentration in sample i, and Δt_i is the interval between t_i and t_i-1.

Histamine and pyrrolidine were not included in the calculation of total BA because several values were non-detectable when cats ate MM (histamine: n 2; pyrrolidine: n 3) and when cats ate WM (histamine: n 5; pyrrolidine n 1).

Molecular analysis

DNA extraction was performed with the Qiagen DNeasy®PowerLyzer® PowerSoil® Kit (ref 12855-100). The concentration of the DNA was measured using the Nanodrop ND-1000 spectrophotometer (Nanodrop Technologie). Ten µl genomic DNA extract was send out to LGC genomics GmbH where the 16S rRNA gene V3-V4 hypervariable region was amplified as described in Van Landuyt et al.^{(Reference Van Landuyt, Cimmino and Dumolin38)}. The PCR mix included 1 µl of 10× diluted DNA extract, 15 pmol of both the forward primer 341F 5’- NNNNNNNNNTCCTACGGGNGGCWGCAG and reverse primer 785R 5’- NNNNNNNNNNTGACTACHVGGGTATCTAAKCC^{(Reference Klindworth, Pruesse and Schweer39)} in 20 µl volume of MyTaq buffer containing 1·5 units MyTaq DNA polymerase (Bioline), and 2 µl of BioStab II PCR Enhancer (Sigma-Aldrich). For each sample, the forward and reverse primers had the same unique 10-nt barcode sequence. PCR were carried out for 30 cycles using the following parameters: 2 min 96°C pre-denaturation; 96°C for 15 s, 50°C for 30 s and 70°C for 90 s.

DNA concentration of amplicons of interest were determined by gel electrophoresis. Next, about 20 ng of amplicon DNA of each sample was pooled for up to forty-eight samples carrying different barcodes. The amplicon pools were purified with one volume of AMPure XP beads (Agencourt) to remove primer dimer and other small mispriming products, followed by an additional purification on MinElute columns (Qiagen). Finally, about 100 ng of each purified amplicon pool DNA was used to construct Illumina libraries by means of adaptor ligation using the Ovation Rapid DR Multiplex System 1-96 (NuGEN). Illumina libraries were pooled, and size was selected by preparative gel electrophoresis. Sequencing was performed on an Illumina MiSeq using v3 Chemistry (Illumina).

Bioinformatics (16S rRNA gene profiling)

Read assembly and clean-up was largely derived from the MiSeq SOP described by the Schloss lab^{(Reference Schloss, Gevers and Westcott40,Reference Kozich, Westcott and Baxter41)} . In brief, mothur (v.1.42.3) was used to assemble reads into contigs, perform alignment-based quality filtering (alignment to the mothur-reconstructed SILVA SEED alignment, v. 138.1), remove chimeras (vsearch v2·13·0), assign taxonomy using a naive Bayesian classifier^{(Reference Wang, Garrity and Tiedje42)} and SILVA NR v138.1 and cluster contigs into operational taxonomic units (OTU) at 97 % sequence similarity. All sequences that were classified as Eukaryota, Archaea, Chloroplasts or Mitochondria and those that could not be classified at all were removed. For each out, representative sequences were picked as the most abundant sequence within that OTU and singletons were removed prior to further data analyses.

Statistical analyses

Based on a power analysis, a sample size of n 8 cats per group was found to be sufficient (Settings: Power = 0·8; α = 0·05/2 (to correct for multiple testing); d = 1·75 (based on the study of Depauw et al. ^{(Reference Depauw, Hesta and Whitehouse-Tedd16)}); two-sample t test; conducted in R 4.0.3. using the pwr package). The power analysis was based on the significant difference in indole values after cheetahs had consumed two different diets in Depauw et al. ^{(Reference Depauw, Hesta and Whitehouse-Tedd16)}. The effect size d (i.e. difference between the means divided by the pooled standard deviation) was found to be 1·75. The outcome parameters can be grouped in apparent total tract digestibility, MUET, microbial composition and fermentation products, each with their unique statistical characteristics. All statistical analyses and graph visualisations were conducted in RStudio v3.6.3 and v.4.2.0 (faecal microbiota), using packages vegan v.2.6.2, microbiome v.1.18.0, phyloseq v.1.40.0 and ggplot2 v3.3.6. To compare the difference in food intake, faecal characteristics, apparent total tract digestibility and urine characteristics between WM and MM treatment, a linear regression was performed using lm function of the stats-package. To analyse the effect of both treatment (WM v. MM) and the difference between the baseline period (EXT preMM; EXT preWM) and the experimental period (postMM; postWM), a linear mixed model was used including both treatment and period and with cat as random factor using the lmer-function in the lmerTest-package^{(Reference Kuznetsova, Brockhoff and Christensen43)}.

Alpha diversity indices (Richness (observed OTU), Shannon, InvSimpson) were calculated on OTU after normalisation by scaling with ranked subsampling (SRS)^{(Reference Beule and Karlovsky44)} at 35 688 sequences per sample. Differences in α diversity measures were further assessed by Kruskal–Wallis and pairwise Wilcoxon tests with Benjamini–Hochberg standard false discovery rate (FDR-BH) correction for multiple testing and significance threshold at P < 0·05.

Beta diversity was assessed using Bray–Curtis dissimilarities and visualised using principal coordinate analysis plots. permutational multivariate analysis of variance (PERMANOVA) was used to identify significant differences between the four groups (EXT preMM, EXT preWM, postMM and postWM). All PERMANOVA analyses were run with VEGAN function adonis with 1000 permutations. Pairwise group comparisons were assessed with the function pairwise.adonis, and P-values were adjusted with the false discovery rate correction.

For taxonomic composition and differential abundance analyses, OTU assigned to phyla and family whose relative median abundance was ≤ 1 % were removed from further analyses. Differences in taxonomic profiles at phylum and family level between the four groups were analysed by Kruskal–Wallis and pairwise Wilcoxon tests with FDR-BH correction and significance threshold at P _adj < 0·05.

Linear discriminant analysis effect size (LEfSe) was used to estimate which microbiome attributes differ significantly between cats fed MM (postMM) v WM (postWM). The Galaxy implementation of LEfSe with default options was used, including a threshold of 2·0 for the logarithmic linear discriminant analysis score for discriminate features. Differential abundance of OTU between EXT preMM and postMM, EXT preWM and WM, and postMM and postWM was determined with DESeq2 v.1.36.0. Original count data were used after filtering rows with fewer than five counts over the entire row and using the parametric Wald test in DESeq2 with alpha = 0·01.