Segment-Specific Functional Responses of Swine Intestine to Time-Restricted Feeding Regime

Nanjing Agricultural University Animal Care and Use Committee (Nanjing, China) (Approval#SYXK2019-0066) authorized the present research. All manipulations related to animals were carried out according to China Laboratory Animal Guideline for Ethical Review of Animal Welfare (GB/T 35892-2018) [15].

Twelve healthy growing crossbred (Duroc × Landrace × Yorkshire) pigs with an average bodyweight of 56.29 kg were employed in this study. Pigs were randomly (random number table method) divided into FA group and TRF group with each group having 6 replicates (1 pig/pen). The FA group had free access to feed, whereas the TRF pigs were fed ad libitum within 07:00–08:00, 12:00–13:00, and 17:00–18:00, respectively (Figure 1). The same commercial pellet feed was formulated according to the NRC (2012) [16]. Feed formulation is shown in Table S1. All pigs were raised in individual pens under recommended feeding conditions. The experiment lasted for 3 weeks. All pigs were weighed and then euthanized by CO₂ asphyxiation to collect the tissues, mucosa, and digesta samples from the digestive tract. The jejunum was harvested starting from the duodenojejunal flexure and ending at the jejunoileal junction. The entire colon was collected from the ileocecal valve to the distal end of the descending colon. After detaching the mesentery, the intestines were stretched to collect and homogenize the digesta for analysis. The length and weight of the jejunum and colon were measured respectively. A 20 cm middle section of the intestine was cut and cleaned with saline. Mucosal samples were collected by scraping the inner surface with a glass slide.

The tissue indices of the jejunum and colon were calculated using Formula (1): (1) T i s s u e i n d e x = ( % ) w e i g h t o f i n t e s t i n a l s e g m e n t × 100 l i v e b o d y w e i g h t

To evaluate the apparent total tract digestibility (ATTD) of proximate nutrients, chromic oxide (Cr₂O₃) was utilized as an indigestible marker. During the final week of the trial, experimental pigs were administered diets supplemented with 0.3% Cr₂O₃. Fecal samples were collected over three consecutive days preceding the conclusion of the experiment. Fresh fecal matter was promptly stored at −20 °C to prevent degradation prior to analysis. Both feed and dried, finely ground fecal samples were analyzed in duplicate for their crude protein (CP), ether extract (EE), crude fiber (CF), crude ash (Ash), and chromium (Cr) content. All nutrient analyses adhered to official methods of AOAC (2000): Ash (method 920.153), CP (method 981.10), EE (method 922.06), and CF (Method 978.10). Nitrogen (N) content was determined using a Kjeldahl nitrogen analyzer (Foss8400, FOSS, Hillerød, Denmark), with CP calculated as N × 6.25. CF was analyzed utilizing an Ankom fiber analyzer (Ankom 200 fiber Analyzer, Ankom Technology, Macedon, NY, USA), and EE was measured using a Soxhlet extractor (Soxtec-2055, FOSS, Eden Prairie, MN, USA).

The concentration of Cr was quantified using a colorimetric method with a spectrophotometer (UV-1201, Shimadzu, Kyoto, Japan), in accordance with AOAC 974.25 and our previous method [17]. Samples underwent digestion in a mixture of concentrated nitric acid (HNO₃) and perchloric acid (HClO₄) on a hotplate within a fume hood. Digestion continued until dense white fumes emerged and the digestate exhibited a deep red coloration. Following cooling, the digestate was diluted to the desired volume with deionized water. The ATTD was calculated using Equation (2):(2)ATTD (%)=[1−(Nutrient_feed×Cr2O3_feces)/(Nutrient_feces×Cr2O3_feed)]×100 where

Nutrient_feed = Concentration of the nutrient (CP, EE, CF, Ash) in the feed.

Nutrient_feces = Concentration of the nutrient in the feces.

Cr₂O₃_feed = Concentration of Cr₂O₃ in the feed.

Cr₂O₃_feces = Concentration of Cr₂O₃ in the feces.

The analysis of digestive enzyme activities was conducted on stomach and ileum digesta, which were collected immediately following euthanasia. These samples were subsequently snap-frozen in liquid nitrogen. Samples were homogenized in PBS at a ratio of 1:9 (w/v) and centrifuged at 10,000× g for 15 min at 4 °C. Enzyme activities of pepsin (A080-1-1), chymotrypsin (A080-3-1), lipase (A054-2-1), amylase (C016-1-2), maltase (A082-3-1), and sucrase (A082-2-1) in the supernatants were quantified using commercial assay kits in accordance with the manufacturer's protocols (Jiancheng Bioengineering Institute, Nanjing, China). Six samples per treatment were analyzed, with two technical repeats per each sample. The enzyme activities were analyzed and were expressed as units per gram of protein (U/g protein), with protein concentration determined using the Bradford method.

The concentrations of carbon (starch and cellulose) and nitrogen (total protein and NH3-N) in colonic digesta were measured [12]. Starch and cellulose were assessed using Solarbio Detection Kits BC0700 and BC4280 (Beijing, China), respectively. Total protein was measured with Solarbio Detection Kit PC0010 via the Coomassie brilliant blue G-250 method, whereas NH3-N levels were determined using a colorimetric method based on our previous work [12].

Total RNA from jejunal and colonic mucosal samples were extracted with an RNA extraction kit (Tiangen BioTech Co., Ltd., Beijing, China). RNA sample concentration and integrity were assessed with a Nanodrop spectrophotometer (NanoDrop Technologies, Wilmington, NC, USA). RNA sequencing was conducted following cDNA library construction and sequencing on the Illumina HiSeq 2500 platform (Illumina, San Diego, CA, USA). The paired-end raw reads were submitted to the NCBI Sequence Read Archive (SRA) under accession number PRJNA1126326. Raw data were filtered to eliminate low-quality reads (Q20 ≤ 20), poly-N stretches (>5% N), and adaptor-only reads using WipeAdapter.pl (v.1.0.1) and Fastq (v.1.0.0) filter scripts [18]. Clean reads were then aligned to the pig reference genome (Sus scrofa 11.1) with TopHat (version 2.1.1), and gene expression levels were quantified using FPKM method. DEGs between the FA and TRF groups were identified using DESeq2, with criteria of |fold change| ≥ 1.5 and p value < 0.05 [19]. Gene ontology (GO) biological process and Kyoto Encyclopedia of Genes and Genomes (KEGG) enrichment and pathway analysis were conducted [20]. More details were described in our previously published articles [2].

The statistical significance of differences in intestinal segment length, tissue indices, the ATTD of proximate nutrients, colonic nutrient substrates, and digestive enzyme activities between the two groups were calculated by t-test (two-tailed) (IBM SPSS Statistics for Windows, Version 21.0) and R software (version 4.1.0). Differences were considered significant at p < 0.05, and a tendency was considered at 0.05 ≤ p < 0.1. Data visualization was performed with GraphPad Prism (version 8, GraphPad Software, San Diego, CA, USA), Cytoscape (Cytoscape-3.7.2), with built-in plugin ClueGO (version 2.5.8).

In the present study, the feeding regime shift had no significant impact on tissue indices of either the jejunum (p = 0.80) or colon (p = 0.72) nor on the length of the colon (p = 0.19). However, the TRF pattern tended to enhance the length of the jejunum (p = 0.07, Table 1).

Using the exogenous indicator method, we found that TRF significantly increased the ATTD of CP (increased by 18.9%, p = 0.045), whereas it exerted no significant effects on the ATTD of ash (p = 0.20), EE (p = 0.99) or CF (p = 0.71) compared with the FA group (Figure 2).

Compared to the control group, TRF exerted no significant effect on pepsin activity (p = 0.13) in the stomach (Figure 3). In the ileum, TRF significantly decreased the activities of amylase (p < 0.01), sucrase (p < 0.01), and lipase (p < 0.01), whereas maltase (p = 0.12) and chymotrypsin (p = 0.33) activities remained unaffected (Figure 3). Furthermore, TRF significantly increased trypsin and lipase activities in the pancreas and increased amylase, maltase, and lipase activities in the duodenum; detailed data (Figure S1) for pancreatic and duodenal enzymes have been previously reported [2].

Colonic nutrient substrates reflect, to some extent, the digestive efficiency in the small intestine and microbial metabolic activity in the large intestine. These substrates may influence systemic host metabolism via the microbiota–gut–brain axis. Our findings revealed that TRF significantly reduced colonic carbohydrate substrates, particularly starch (p = 0.02) and cellulose (p = 0.04) levels, whereas it exerted minimal effects on nitrogenous substrates total protein (p = 0.23) and NH3-N (p = 0.70) (Figure 4).

In the jejunum, a total of 55.93 Gb data were obtained, with an average of 6.54 Gb data per sample. The percentage of Q30 bases was greater than 92.69%, indicating reliable sequencing quality. These clean data were then mapped to the swine reference genome, resulting in mapping rates of 93.82%~94.52% (). After splice prediction analysis, gene structure optimization analysis, and novel gene discovery based on the mapped genes, a total of 2033 novel genes were discovered. Among these novel genes, 1076 had functional annotations. In total, up to 13,493 genes were identified. Table S2

Principal component analysis (PCA) revealed a distinct transcriptomic pattern in response to the altered feeding pattern (Figure 5A). A total of 1339 DEGs were identified (Figure 5B). There were 462 genes up-regulated and 877 genes down-regulated. The DEGs with the greatest changes in expression were NR1H4 (farnesoid X receptor, p = 9.61 × 10⁻⁶), DDX58 (ATP-dependent RNA helicase DDX58, p = 8.57 × 10⁻⁵), GPRL15 (G protein-coupled receptor 15, p < 0.001), TMEM252 (transmembrane protein 252, p = 0.0042), CUBN (cubilin, p = 0.028), NOL4 (nucleolar protein 4 like, p < 0.001), SPTLC3 (serine palmitoyltransferase, p = 9.51 × 10⁻⁵), GSDME (gasdermin-E isoform X1, p = 8.26 × 10⁻⁷), PKP1 (plakophilin 1, p = 3.97 × 10⁻⁴), TMIGD1 (transmembrane and immunoglobulin domain-containing protein 1, p = 9.66 × 10⁻⁵), FABP6 (fatty acid-binding protein 6, p = 2.50 × 10⁻⁷), and SLC10A2 (solute carrier family 10 member 2, p = 2.81 × 10⁻⁷). DEGs were mainly associated with 215 GO terms (Figure 5C).

The most enriched biological process GO terms were cell migration and biological adhesion. The most enriched molecular function GO terms were cell adhesion molecule binding, protein tyrosine kinase activity, serine hydrolase activity, serine-type peptidase activity, endopeptidase activity, metalloendopeptidase activity, and collagen binding. KEGG analysis suggested that these DEGs were mainly enriched in 43 KEGG pathways. The most enriched KEGG pathways (Figure 5D) were focal adhesion, ECM–receptor interaction, protein digestion and absorption, complement and coagulation cascades, and axon guidance. Of note, SLC1A1 (Solute Carrier Family 1 Member 1, p = 0.003), SLC38A2 (Solute carrier family 38 member 2, p = 0.047), SLC7A8 (Solute carrier family 7 member 8, p = 0.049), SLC8A1 (Solute carrier family 8 member 1, p = 0.014), and XPNPEP2 (X—Prolyl aminopeptidase 2, p = 0.023), which are closely related to the digestion and absorption of protein, were significantly altered by the TRF regime.

In the colon, 59.16 Gb data were obtained after quality control, with an average of 6.80 Gb data per sample. The percentage of Q30 bases was 92.73%. The mapping rates ranged from 93.57% to 94.69%. A total of 2291 novel genes (1130 with functional annotations) were identified (Table S2). The PCA results of the TRF and FA groups failed to clearly distinguish the two groups (Figure 6A). From the volcano plot (Figure 6B), among these 13,858 genes, there were 268 mRNAs which were significantly altered (175 up-regulated and 93 down-regulated). The most significantly down-regulated DEGs with maximal fold change were FAM53C (family with sequence similarity 53 member C, p = 2.18 × 10⁻³), G6PC (glucose-6-phosphatase, p = 0.031), DMGDH (dimethylglycine dehydrogenase, p = 0.081), and PGLYRP2 (peptidoglycan recognition protein, p = 0.005), whereas the most significantly up-regulated DEGs were LYNX1 (Ly6/neurotoxin 1, p = 0.001), EFCAB7 (EF-hand calcium-binding domain-containing protein 7, p = 0.013), PKP1 (Plakophilin 1, p = 0.034), and DCAF5 (DDB1-and CUL4-associated factor 5, p = 2.06 × 10⁻⁶). Further, the GO pathway enrichment plot (Figure 6C) revealed that the altered genes were mainly related to 127 GO terms.

The most enriched biological process GO terms were microtubule-based movement regulation, regulation of cilium movement, heart development, multicellular organismal reproductive process, and monosaccharide transmembrane transport. The most enriched cell components GO terms were the intrinsic component of plasma membrane, sperm flagellum, 9 + 2 motile cilium, postsynaptic specialization, and extracellular organelle. The most enriched molecular functions GO terms were glycosaminoglycan binding, signaling adaptor activity, CCR chemokine receptor binding, cadherin binding, protein tyrosine kinase binding, and transferring pentosyl groups. KEGG analysis revealed that the DEGs were mainly related to starch and sucrose metabolism, pyrimidine metabolism, axon guidance, pertussis, gap junction, and circadian entrainment plot (Figure 6D).

Comparatively, five times more DEGs were identified in the jejunum than in the colon (1339 vs. 268, Figure 7A). Of these genes, only 62 DEGs were shared between the jejunum and the colon. These genes were mainly enriched in KEGG pathways related to axon guidance, which might implicate the bidirectional interaction between the gut and the brain [21]. In the jejunum, 462 genes were up-regulated and 877 were down-regulated, whereas in the colon, 175 genes were up-regulated and 93 genes were down-regulated (Figure 7B). The significantly changed genes were primarily related to KEGG pathways related to physiological processes, pathological processes, and nutrient metabolism (Figure 7C). Notably, DEGs in the jejunum were mainly related to the digestion and absorption of protein, whereas DEGs in the colon were primarily related to pyrimidine metabolism and starch and sucrose metabolism pathways.