Ethical approval

All procedures involving animal handling and treatment were approved by the institutional ethics committee of the University of Veterinary Medicine Vienna and the national authority according to paragraph 26 of Law for Animal Experiments, Tierversuchsgesetz – TVG (GZ BMWF-68.205/0051-II/3b/2013).

Animals

Seven castrated male pigs (Large White; initial body weight 54·8 (sd 3·4) kg; age 3–4 months) were obtained from the university research pig farm (University of Veterinary Medicine Vienna) 1 week prior to ileal cannulation. Pigs were housed in individual metabolism pens (1·0 × 1·2 m) with Plexiglass walls for visual contact in an environmentally controlled room (21 ± 1°C)⁽Reference Newman, Zebeli and Velde¹³⁾. Each pen was equipped with a single-space feeder and a nipple drinker for ad libitum access to demineralised water. Pens were cleaned daily with water and faeces were removed several times daily. Health status of pigs was monitored daily throughout the experiment. Pigs were surgically fitted with a simple T-cannula (tubus 9 cm, foot 9 cm, inner diameter 2·0 cm, outer diameter 2·3 cm; LKT – Laboratorium für Kunststofftechnik GmbH), inserted at the distal ileum to allow for the collection of ileal digesta⁽Reference Newman, Zebeli and Velde¹³⁾. Post-surgery, the skin around the cannula was cleaned with lukewarm water at least twice daily, treated with a skin-protecting paste (Stomahesive Paste, Convatec), and foam material was placed between the retaining ring and the skin to absorb any leaking digesta to prevent erythema⁽Reference Metzler, Mosenthin and Baumgärtel¹⁴⁾. Post-surgery, pigs were allowed a 9-d recovery period, where feed amounts were gradually increased until reaching pre-surgery levels. Upon completion of the experiment, pigs were sedated (Narketan, 10 ml/kg body weight (Ketamine HCl; Vétoquinol AG) and Stresnil, 3 ml/kg body weight (Azaperone; Biokema SA)) and euthanised by intracardiac injection of T61 (10 ml/kg; Embutramide; MSD Animal Health).

Experimental design, diets and feeding

Prior to the start of the experiment, pigs were fed a commercial cereal-based grower diet (metabolisable energy 13·4 MJ/kg; crude protein 16·8 % as-fed basis)^{(Reference Newman, Petri and Grüll9)}. Following recovery, pigs were randomly allotted to one of two dietary treatments according to a complete crossover design with two 16-d replicate periods (online Supplementary Fig. S1). This provided a total of seven observations per dietary treatment. Each replicate period consisted of 10-d adaptation to diets, followed by 3-d collection of faeces and 3-d collection of ileal digesta. The advantage of using a crossover design is that it requires a smaller sample size than a parallel design, without compromising the level of statistical power and precision, which is helpful when using an ileal cannulation model. Nevertheless, it may be advisable to include a washout period in order to avoid carryover effects from one to the other experimental period, especially as the effect of short-term feeding of TGS on the intestinal passage rate, nutrient flow and microbiota composition was investigated in the present study. We did not include a washout period due to the increasing risk of growth-related losses of cannulae with progressing time from the surgery, and maturational changes in the intestinal microbiota with increasing age of the pig. In order to balance for simple first-order carryover effects of one treatment into the following treatment period, the diets were randomised among pigs in both replicate batches.

The two experimental diets were formulated to meet or exceed current recommendations for nutrient requirements of growing pigs⁽¹⁵⁾ and only differed in the starch component (Table 1). The starch component of the control (CON) diet was a rapidly digestible waxy maize starch (Agrana Research and Innovation Center GmbH), whereas in the TGS diet, 50 % of the native waxy maize starch was replaced by TGS (Agrana Research and Innovation Center GmbH)⁽Reference Newman, Petri and Grüll^9, Reference Metzler-Zebeli, Newman and Grüll¹⁶⁾. As described before⁽Reference Newman, Petri and Grüll^9, Reference Metzler-Zebeli, Newman and Grüll¹⁶⁾, acid-catalysed transglycosylation of the native waxy maize starch was used to produce TGS. This process rearranged the glycosidic bonds in the native waxy maize starch, resulting in eight types of glycosydic bonds: α(1,2), α(1,3), α(1,4), α(1,6), β(1,2), β(1,3), β(1,4), and β(1,6)-glycosidic bonds and a total dietary fibre content of 50 % in the final TGS product (method 2009.01)⁽¹⁷⁾. Daily feed allowances were estimated to correspond to approximately three times the estimated energy required for maintenance⁽¹⁵⁾, which were divided into two equal meals that were fed at 08.00 and 16.00 hours as a mash and mixed with water at a ratio of about 2:1. Potential feed spillage and leftovers in feeding bowls were collected after feeding.

Table 1. Ingredients and chemical composition of the control (CON) diet and transglycosylated starch (TGS) diet

* Agrana Research and Innovation Center GmbH.

† FibreCell (Agromed Austria GmbH).

‡ Provided per kg of complete diet (GARANT GmbH): 4800 µg of vitamin A, 50 µg of vitamin D₃, 125 mg of vitamin E, 2·0 mg of vitamin B₁, 6·0 mg of vitamin B₂, 3·0 mg of vitamin B₆, 0·03 mg of vitamin B₁₂, 3·0 mg of vitamin K₃, 30 mg of niacin, 15·0 mg of pantothenic acid, 900 mg of choline chloride, 0·15 mg of biotin, 1·5 mg of folic acid, 200 mg of vitamin C, 4·6 g of Ca, 2·3 g as digestible P, 2·4 g as Na, 2·0 g of Cl, 3·2 g K, 1·0 g Mg, 50 mg of Mn (as MnO), 100 mg of Zn (as ZnSO₄), 120 mg of Fe (as FeSO₄), 15·6 mg of Cu (as CuSO₄), 0·5 mg of Se (as Na₂SeO₃), 1·9 mg of iodine (as Ca(IO₃)₂).

§ Total starch in the CON diet determined by enzymatic spectrophotometric assay (R-Biopharm), and in the TGS diet by perchloric acid treatment of samples and measurement of resulting glucose using HPLC⁽¹⁵⁾.

Sample collection and digesta flow marker application

In each of the two experimental periods, fresh faecal samples were collected from slatted flooring and tray beneath the cage on experimental days 11–13 (online Supplementary Fig. S1) via grab sampling⁽Reference Newman, Zebeli and Velde¹³⁾. Subsamples of freshly defecated faeces were immediately frozen at −80°C for the analysis of faecal microbiota and at −20°C for SCFA. The remaining faecal samples were stored at −20°C for proximate nutrient analysis. Ileal digesta samples were collected on days 14 and 15 between 08.00 and 18.00 hours into 10 × 4 cm plastic bags that were attached to the barrel of each cannula using rubber bands. Each bag contained 4 ml of 2·5 m formic acid to minimise bacterial fermentation. Full bags were removed, or at least every 30 min. Ileal digesta samples were collected without formic acid for bacterial microbiota, SCFA and lactate analyses at 11.00 and 14.00 hours. Subsamples for bacterial microbiota were immediately frozen at −80°C, and subsamples for SCFA and lactate were stored at 4°C until digesta samples from both time-points were obtained. Then, digesta was pooled by pig, homogenised and frozen at −20°C for later analysis. On day 16 of each experimental run, 40 ml of liquid marker (chromium-ethylenediaminetetraacetic acid, Cr-EDTA) and 1 g of solid marker (Yb₂O₃) were mixed into the morning meal⁽Reference Newman, Zebeli and Velde¹³⁾. Ileal digesta samples were collected postprandially at 0, 30, 90, 120, 180, 240, 300, 360, 420 and 480 min. As ileal digesta flow can be irregular, the actual collection times were recorded.

Chemical analysis

Prior to chemical analyses, ileal and faecal subsamples for proximate nutrient analysis were lyophilised (Gamma 2–20; Martin Christ Gefriertrocknungsanlagen GmbH). Ileal, faecal and diet samples were homogenised and ground through a 0·5-mm screen (GRINDOMIX GM200; Retsch GmbH). Diets and freeze-dried ileal digesta and faeces were analysed for DM, crude ash, crude protein (N × 6·25 by the Kjeldahl method), Ca and P⁽Reference Naumann and Basler¹⁸⁾. Gross energy of diets, digesta and faeces was measured using an isoperibolic bomb calorimeter (C200; IKA-Werke GmbH and Co. KG), with benzoic acid as calibration standard⁽Reference Naumann and Basler¹⁸⁾. The total starch content of the CON diet was determined via the UV method (Enzymatic BioAnalysis; R-Biopharm) using a spectrophotometer (DR 2800; Hach Lange GmbH), whereas to measure total starch content of the TGS diet, soluble TGS was leached out of the samples and treated with perchloric acid⁽Reference Newman, Zebeli and Eberspächer⁸⁾. Thereafter, the resulting glucose was measured using HPLC (Ultimate 3000; Thermo Fisher Scientific) equipped with an Aminex HPX-87H separation column and a Refratomax 520 detector. The starch content in ileal digesta and faeces was measured accordingly. Titanium dioxide was measured spectrophotometrically (Hitachi U-3000; Metrohm INULA GmbH) at 405 nm in feed, faeces and ileal digesta after Kjeldahl extraction⁽Reference Khol-Parisini, Humer and Sizmaz¹⁹⁾, whereas commercially available kits (Megazyme K-DLATE) were used to determine d- and l-lactate concentrations in fresh ileal digesta and faecal samples. Concentrations of SCFA in fresh ileal digesta and faecal samples were analysed using gas chromatography⁽Reference Newman, Zebeli and Velde¹³⁾. The pH in fresh ileal digesta and faeces was determined using a Beckman ϕ63 pH meter (Beckman Coulter).

Passage rate marker analysis

Inductively coupled plasma mass spectrometry was applied to determine Cr and Yb as previously described⁽Reference Newman, Zebeli and Velde¹³⁾. The measurements were performed on a double-focusing sector field instrument (Finnigan ELEMENT2; Thermo Electron Corporation) equipped with a CETAC ASX-520 autosampler (CETAC Technologies) using 50 mg of lyophilised ileal digesta. The digesta were weighed into 10 ml glass tubes and digested with 2 ml 65 % nitric acid (60 min at 95°C). Thereafter, the solutions were transferred into clean and pre-weighted 50 ml tubes of polypropylene, filled up to 50 g on a laboratory balance and shaken. After sedimentation, the solutions were diluted 1:100 with 0·5 % (v/v) nitric acid, and 20 µg/l Sc, 10 µg/l In and 10 µg/l Tl were added as internal standards. The following nuclides were measured in medium-resolution mode, R_s = 4000, 10 % valley definition ³¹P, ⁴⁴Ca, ⁴⁵Sc, ⁵²Cr, ¹⁷³Yb and ²⁰⁵Tl. Quantitative analysis of the samples was performed by external calibration.

The excretion curves of ileal markers, including Yb₂O₃ as a solid marker and Cr-EDTA as a liquid marker, were fitted to a two-compartment kinetics model, implemented in the NLIN procedure (iterative Marquardt method) of SAS (version 9.4, SAS Institute. Inc.) as described before⁽Reference Newman, Zebeli and Velde^13, Reference Zebeli, Tafaj and Weber²⁰⁾. These models estimate the fractional passage rates from two compartments (slow (k_S) and fast (k_F), where k_S represents passage out of the stomach; and k_F, passage out of the small intestine), including a time delay. The time delay indicates the time lapse between pulse dosing and the first appearance of markers in ileal digesta (or transit time due to displacement flow of digesta, in minutes). The time lapse between pulse dosing and the reach of peak ileal marker excretion was considered as the time of peak flow (minutes). Maximum total mean retention time (TMRT) was calculated as the sum of maximum mean retention times in the stomach (GMRT = 1/k_S) and small intestine (SMRT = 1/k_F), including the time delay.

DNA isolation, Illumina MiSeq sequencing and bioinformatics analysis

The PowerSoil DNA isolation kit (MoBio Laboratories) was used to extract total DNA from 250 mg of the homogenised ileal digesta and faecal samples. Modifications included an additional heating step (70°C for 10 min) between mixing the digesta samples with C1 buffer and bead beating for proper lysis of bacteria⁽Reference Metzler-Zebeli, Lawlor and Magowan²¹⁾. DNA concentration was measured using the Qubit double-stranded DNA HS assay kit (Life Technologies) on the Qubit 2.0 fluorometer (Life Technologies). The 16S rRNA gene PCRs, library preparation and sequencing on an Illumina MiSeq sequencing v2 platform (Illumina Inc.) were performed with Microsynth as described previously⁽Reference Newman, Petri and Grüll⁹⁾. The V3–V5 hypervariable regions of bacterial 16S rRNA genes were amplified using the primers 357F-HMP (5′-CCTACGGGAGGCAGCAG-3′) and 926R-HMP (5′-CCGTCAATTCMTTTRAGT-3′) to produce an amplicon size of approximately 523 bp (Peterson et al., 2009). Libraries were constructed by ligating sequencing adapters and indices onto purified PCR products using the Nextera XT sample preparation kit (Illumina Inc.). Equimolar quantities of each library were pooled and sequenced using a 300-bp read length paired-end protocol. After sequencing, the overlapping paired-end reads were de-multiplexed, trimmed of Illumina adaptor residuals using cutadapt (https://cutadapt.readthedocs.io/en/stable/) and stitched using USEARCH (drive5/com) with Microsynth.

The merged FASTQ sequences were analysed using QIIME (Quantitative Insights Into Microbial Ecology) software package, version 1.9.1⁽Reference Caporaso, Kuczynski and Stombaugh²²⁾. After quality trimming of stitched reads using a quality threshold of q > 20, the UCHIME method using the 64-bit version of USEARCH (drive5.com)⁽Reference Edgar^23, Reference Edgar, Haas and Clemente²⁴⁾ and the GOLD database (drive5.com) were used to screen for and exclude chimeric sequences. Open-reference operational taxonomic unit (OTU) picking was performed at 97 % similarity level using UCLUST⁽Reference Edgar²³⁾, and taxonomy was assigned against the Greengenes database (gg_13_8; http://qiime.org/home_static/dataFiles.html). Rare OTUs with less than ten sequences were removed. The raw sequence reads were uploaded to the NCBI Bioproject databank (PRJNA514964).

Differences in hit count abundances of bacterial genera were assessed using the R package ‘DESeq2’ (version 1.14.1)⁽Reference Love, Huber and Anders^25, Reference Huber, Carey and Gentleman²⁶⁾. The ‘DESeq’ function within the DESeq2 package was used to test for differentially abundant taxa by dietary starch. In using this function, data were normalised to the size factors of the libraries and dispersion estimation. Specifically, this function models raw counts using a negative binomial distribution and adjusts internally for ‘size factors’ that normalise for differences in sequencing depth between sample libraries. We also pre-filtered the dataset to keep only features that have at least ten reads total using the R command in DESeq2 ‘rowSums(counts(deseq_data)) ≥ 10’ to remove low-count taxa. DESeq2 default settings were used to replace and filter for count outliers. Differential taxa abundance between treatments was identified using the ‘Wald’ test⁽Reference Love, Huber and Anders²⁵⁾. Data were listed as normalised read counts per feature. The correction of P values relating to the taxonomic profiles was performed using the Benjamini–Hochberg false discovery rate (FDR)⁽Reference Benjamini and Hochberg²⁷⁾.To account for multiple comparisons, we considered a type I error rate of ≤0·05 and a FDR-adjusted P value (q value) ≤0·10 as significant. Mean counts for each dietary starch were computed using the DESeq function within the DESeq2 package. Statistical assessment of dissimilarity matrices (Bray–Curtis) derived from ileal and faecal OTU data was performed using the ‘adonis2’ function (PERMANOVA) and visualised in two-dimensional non-metric multidimensional scaling (NMDS) ordination plots obtained with the ‘metaMDS’ function in the vegan R package (version 2.5.2)⁽Reference Oksanen, Blanchet and Friendly²⁸⁾. Alpha diversity measurements were also performed by means of the vegan R package.

In addition, sparse partial least squares (sPLS) and relevance network analysis were performed using the package ‘mixOmics’ in R⁽Reference Lê Cao, Costello and Lakis^29, Reference Rohart, Gautier and Singh³⁰⁾ to integrate data of genera (0·01 % of all reads) and fermentation metabolites, including digesta DM content and pH with nutrient flow and digesta retention parameters in ileal and faecal samples, in order to identify dependencies among the data. The ‘network’ function calculated a similarity measure between X and Y variables in a pairwise manner. In the graphs, each X and Y variable corresponds to a node, whereas the edges display the associations between the nodes. The size of the nodes is arbitrary, depending on the name of the variable.

In order to further understand ileal and faecal networking, multi-group supervised DIABLO N-integration was performed to identify the key features and their relations among each other, also by means of the package ‘mixOmics’ (version 6.3)⁽Reference Rohart, Gautier and Singh³⁰⁾ in R studio (version 1.1.456). Supervised multi-group sPLS-discriminant analysis (sPLS-DA) was used to integrate the datasets of relative abundances of genera, fermentation metabolites including digesta DM content and pH, and nutrient flow in order to classify and select key features from each dataset. Tuning of sPLS-DA parameters was performed using the ‘tune’ function to identify the most influential genera, fermentation metabolites and nutrients in digesta or faeces with the lowest possible error rate – finally selecting ten genera, five fermentation metabolites and four nutrient genes each for components 1 and 2, respectively. In doing so, the ‘tune’ function returns a set of ‘keepX’ values for each dataset that shows the best predictive performance for all the components in the model, while simultaneously performing repeated leave-one-out cross-validation using the function ‘nrepeat’⁽Reference Rohart, Gautier and Singh³⁰⁾. The assessment of the performance of the final model by cross-validation showed the lowest possible error rate of, on average, 35 and 27 % for components 1 and 2, respectively, for ileal datasets. For ileal datasets, cross-validation of the final model revealed the lowest possible error rate of, on average, 5·4 and 3·1 % for components 1 and 2, respectively.

Calculations and statistical analysis

The amounts of DM protein, ash, starch (g/kg DM intake) and gross energy (MJ/kg DM intake) remaining at the distal ileum and excreted in faeces and post-ileal disappearance were calculated as previously reported⁽Reference Newman, Zebeli and Velde¹³⁾:

Amount remaining at the terminal ileum or faeces (g or MJ/kg DM intake) = (concentration of dietary constituent in digesta/faeces × (TiO₂ in diet/TiO₂ in digesta/faeces))

Post-ileal disappearance (g or MJ/kg DM intake) = amount remaining at terminal ileum – amount excreted in faeces

A power test analysis estimated according to Kononoff & Hanford⁽Reference Kononoff and Hanford³¹⁾ and based on previous data for similar variables, such as intestinal microbiota composition and digestibility⁽Reference Newman, Zebeli and Velde^13, Reference Regmi, Metzler-Zebeli and Gänzle³²⁾, using the SAS software was performed to identify the minimum number of observations (n 6) required for the present pig experiment to reject the null hypothesis if this was false. Due to the missing washout period, all parameters, including ileal and faecal bacterial taxa and microbial metabolites, ileal digesta and faecal characteristics, passage rate, as well as ileal flow, hindgut disappearance and faecal excretion of nutrients, were analysed for potential carryover effects using a linear model and the MIXED procedure in SAS. This mixed model included the fixed effects of the sequence of feeding the diets, diet and replicate batch. The estimates showed that CON/TGS v. TGS/CON sequences had no significant impact on the data. Moreover, data of passage rate, ileal flow, hindgut disappearance and faecal excretion of nutrients, pH, SCFA and lactate were analysed for normality using the Shapiro–Wilk test and outlier in SAS. ANOVA was performed using the MIXED procedure of SAS to compare the effects of TGS and CON diets with pig as the experimental unit. The model included the fixed effect of diet and the random effect of block. Degrees of freedom were approximated using the Kenward–Rogers method (ddfm = kr). Pairwise comparisons among least square means were performed using the Tukey–Kramer test. Results are expressed as least square means with their standard error of the mean, and P < 0·05 and 0·05 < P ≤ 0·10 were defined as significance and trend, respectively.