Hostname: page-component-78c5997874-94fs2 Total loading time: 0 Render date: 2024-11-04T19:23:35.422Z Has data issue: false hasContentIssue false

Differences in plasma metabolomics between sows fed dl-methionine and its hydroxy analogue reveal a strong association of milk composition and neonatal growth with maternal methionine nutrition

Published online by Cambridge University Press:  02 February 2015

Xiaoling Zhang
Affiliation:
Key Laboratory for Animal Disease-Resistance Nutrition of China Ministry of Education, Animal Nutrition Institute, Sichuan Agricultural University, Ya'an625014, People's Republic of China
Hao Li
Affiliation:
Key Laboratory for Animal Disease-Resistance Nutrition of China Ministry of Education, Animal Nutrition Institute, Sichuan Agricultural University, Ya'an625014, People's Republic of China
Guangmang Liu
Affiliation:
Key Laboratory for Animal Disease-Resistance Nutrition of China Ministry of Education, Animal Nutrition Institute, Sichuan Agricultural University, Ya'an625014, People's Republic of China
Haifeng Wan
Affiliation:
Key Laboratory for Animal Disease-Resistance Nutrition of China Ministry of Education, Animal Nutrition Institute, Sichuan Agricultural University, Ya'an625014, People's Republic of China
Yves Mercier
Affiliation:
Adisseo France SAS, CERN, Commentry, France
Caimei Wu
Affiliation:
Key Laboratory for Animal Disease-Resistance Nutrition of China Ministry of Education, Animal Nutrition Institute, Sichuan Agricultural University, Ya'an625014, People's Republic of China
Xiuqun Wu
Affiliation:
Key Laboratory for Animal Disease-Resistance Nutrition of China Ministry of Education, Animal Nutrition Institute, Sichuan Agricultural University, Ya'an625014, People's Republic of China
Lianqiang Che
Affiliation:
Key Laboratory for Animal Disease-Resistance Nutrition of China Ministry of Education, Animal Nutrition Institute, Sichuan Agricultural University, Ya'an625014, People's Republic of China
Yan Lin
Affiliation:
Key Laboratory for Animal Disease-Resistance Nutrition of China Ministry of Education, Animal Nutrition Institute, Sichuan Agricultural University, Ya'an625014, People's Republic of China
Shengyu Xu
Affiliation:
Key Laboratory for Animal Disease-Resistance Nutrition of China Ministry of Education, Animal Nutrition Institute, Sichuan Agricultural University, Ya'an625014, People's Republic of China
Gang Tian
Affiliation:
Key Laboratory for Animal Disease-Resistance Nutrition of China Ministry of Education, Animal Nutrition Institute, Sichuan Agricultural University, Ya'an625014, People's Republic of China
Daiwen Chen
Affiliation:
Key Laboratory for Animal Disease-Resistance Nutrition of China Ministry of Education, Animal Nutrition Institute, Sichuan Agricultural University, Ya'an625014, People's Republic of China
De Wu
Affiliation:
Key Laboratory for Animal Disease-Resistance Nutrition of China Ministry of Education, Animal Nutrition Institute, Sichuan Agricultural University, Ya'an625014, People's Republic of China
Zhengfeng Fang*
Affiliation:
Key Laboratory for Animal Disease-Resistance Nutrition of China Ministry of Education, Animal Nutrition Institute, Sichuan Agricultural University, Ya'an625014, People's Republic of China
*
*Corresponding author: Professor Z. Fang, fax +86 28 86290920, email [email protected]
Rights & Permissions [Opens in a new window]

Abstract

The aim of the present study was to determine whether increased consumption of methionine as dl-methionine (DLM) or its hydroxy analogue dl-2-hydroxy-4-methylthiobutanoic acid (HMTBA) could benefit milk synthesis and neonatal growth. For this purpose, eighteen cross-bred (Landrace × Yorkshire) primiparous sows were fed a control (CON), DLM or HMTBA diet (n 6 per diet) from 0 to 14 d post-partum. At postnatal day 14, piglets in the HMTBA group had higher body weight (P= 0·02) than those in the CON group, tended (P= 0·07) to be higher than those in the DLM group, and had higher (P< 0·05) mRNA abundance of jejunal fatty acid-binding protein 2, intestinal than those in the CON and DLM groups. Compared with the CON diet-fed sows, milk protein, non-fat solid, and lysine, histidine and ornithine concentrations decreased in the DLM diet-fed sows (P< 0·05), and milk fat, lactose, and cysteine and taurine concentrations increased in the HMTBA diet-fed sows (P< 0·05). Plasma homocysteine and urea N concentrations that averaged across time were increased (P< 0·05) in sows fed the DLM diet compared with those fed the CON diet. Metabolomic results based on 1H NMR spectroscopy revealed that consumption of the HMTBA and DLM diets increased (P< 0·05) both sow plasma methionine and valine levels; however, consumption of the DLM diet led to lower (P< 0·05) plasma levels of lysine, tyrosine, glucose and acetate and higher (P< 0·05) plasma levels of citrate, lactate, formate, glycerol, myo-inositol and N-acetyl glycoprotein in sows. Collectively, neonatal growth and milk synthesis were regulated by dietary methionine levels and sources, which resulted in marked alterations in amino acid, lipid and glycogen metabolism.

Type
Full Papers
Copyright
Copyright © The Authors 2015 

The sulphur amino acids (SAA), methionine, homocysteine and cysteine play an important role in human and animal nutrition and health( Reference Fang, Yao and Zhang 1 , Reference Shoveller, Stoll and Ball 2 ). Recent studies have shown that adequate amounts of SAA are necessary for intestinal health and normal growth of neonates( Reference Bauchart-Thevret, Stoll and Chang 3 , Reference Bauchart-Thevret, Stoll and Chacko 4 ). However, previous research that analysed the amino acids (AA) profile in sow milk has suggested that supply of methionine in the diet may not match the requirements of growing neonates. Interestingly, concentrations of a majority of AA including lysine, leucine, arginine and valine in sow milk increase as the lactation period advances from 5 to 19 d post-partum( Reference Daza, Riopérez and Centeno 5 ). In contrast, no significant variations between lactation periods were observed in relation to the concentrations of several AA, especially methionine and threonine, in sow milk( Reference Daza, Riopérez and Centeno 5 ). Studies in piglets using isotope tracers have indicated that roughly one-third of dietary intake of essential AA including lysine, leucine and phenylalanine is consumed in first-pass metabolism by the intestine, and that AA catabolism by intestinal mucosal cells is quantitatively greater than AA incorporation into mucosal protein( Reference Stoll, Henry and Reeds 6 ). Further in vitro studies have indicated that 50–70 % of leucine, 25 % of methionine, threonine and proline, and 15 % of lysine and arginine are utilised for bacterial protein synthesis( Reference Dai, Li and Xi 7 ). Given that nutrients are first consumed by the intestine, the extensive metabolism of dietary essential AA by the intestine( Reference Stoll, Henry and Reeds 6 ) or commensal intestinal bacteria( Reference Dai, Li and Xi 7 ) may result in a decrease in their availability for protein synthesis in other tissues such as the mammary glands. In support of this notion, milk protein synthesis in dairy cows has been shown to increase more by jugular infusion of AA than by post-ruminal infusion of AA, indicating a significant decrease in dietary AA metabolism by the intestine and thus an increase in AA availability for delivery to the mammary glands( Reference Schei, Danfær and Boman 8 ).

Based on plasma urea N, lysine and threonine have been identified to be the first- and second-limiting AA, respectively, in maize–soyabean diets of lactating sows( Reference Soltwedel, Easter and Pettigrew 9 ). However, studies on sows implanted with catheters in a carotid artery and the main mammary vein have indicated that AA needed for milk synthesis is defined by the maximal uptake of plasma AA by porcine mammary glands( Reference Guan, Bequette and Ku 10 ). It has been observed in piglets that the extensive metabolism of dietary AA by the intestine makes the net portal balance of methionine (48 % intake) and threonine (38 % intake) greatly lower than that of lysine (65 % intake); therefore, it has been proposed that methionine and threonine rather than lysine are the limiting AA for extra-intestinal protein synthesis( Reference Stoll, Henry and Reeds 6 ). In support of this view, milk synthesis in lactating sows and high-producing dairy cows has been shown to increase by an increased inclusion of dietary threonine( Reference Bojčuková and Krátký 11 ) and jugular-infused methionine( Reference Appuhamy, Knapp and Becvar 12 ), respectively. Further studies on mammary epithelial cells and tissues have indicated that both methionine and threonine are the limiting substrates for protein synthesis in the mammary glands; however, methionine is also a potential regulator of milk protein synthesis( Reference Appuhamy, Knoebel and Nayananjalie 13 ). Taken together, these studies have indicated the considerable importance of adequate methionine availability for the mammary glands to sustain milk production.

However, because homocysteine, the intermediate compound of methionine in the trans-methylation cycle, is toxic to humans and animals, methionine is considered to be the most toxic AA( Reference Benevenga and Steele 14 ). This may have discouraged the attempts to increase methionine availability for extra-intestinal tissues by increasing methionine consumption. Remarkably, previous studies in ducks( Reference Xie, Hou and Huang 15 ) have found that consumption of the methionine hydroxy analogue, dl-2-hydroxy-4-methylthiobutanoic acid (HMTBA), resulted in less plasma homocysteine consumption compared with equimolar dl-methionine (DLM) consumption. Moreover, our recent studies conducted in piglets have indicated that HMTBA may be less extensively lost compared with DLM when they are absorbed from the lumen into the portal blood( Reference Fang, Yao and Zhang 1 , Reference Fang, Luo and Qi 16 Reference Fang, Huang and Luo 18 ). It appears that the potential less toxicity and higher extra-intestinal availability of HMTBA relative to DLM may provide a promising implication for HMTBA utilisation in lactating animals. Studies in pigs may be beneficial for our understanding in human lactation, as pigs and humans have similar anatomic and physiological characteristics including the cardiovascular, urinary, integumentary and digestive systems( Reference Swindle, Makin and Herron 19 ). The aim of the present study was to determine how neonatal pigs respond to increased consumption of methionine as DLM or HMTBA by lactating sows, and we hypothesised that supplemental dietary methionine sources could result in the changes in sow plasma metabolite concentrations and thus affect milk synthesis and neonatal pig growth.

Materials and methods

Animals and diets

The protocol of the present study was approved by the Animal Care and Use Committee of Animal Nutrition Institute, Sichuan Agricultural University, and carried out in accordance with the National Research Council's Guide for the Care and Use of Laboratory Animals. In the present experiment, eighteen pregnant cross-bred (Landrace × Yorkshire) primiparous sows artificially inseminated with mixed semen from two Duroc boars were used. On day 110 of gestation, sows were moved into farrowing crates (2·1 m × 0·7 m) with an area (2·1 m × 0·6 m) for newborn pigs on each side of the crate in an environmentally regulated farrowing house. Temperature in the farrowing house was maintained at 20 ± 1°C, and heat lamps provided supplemental heat to the piglets. All sows were fed the control (CON) diet until farrowing. During farrowing, six sows continued to receive the CON diet, and the other sows were fed the DLM or HMTBA diet, with six sows per diet. The CON diet was formulated based on the nutrition requirement of lactating sows as recommended by the National Research Council (1998)( 20 ) (Table 1). According to the National Research Council (1998), in the ideal AA profile for lactating sows, dietary ratios of methionine and methionine+cystine to lysine were 26:100 and 48:100, respectively. In contrast, Dourmad et al. ( Reference Dourmad, Étienne and Valancogne 21 ) recommended dietary ratios of methionine and methionine+cystine to lysine to be 30:100 and 60:100, respectively, which means that compared with the recommendation of the National Research Council (1998), dietary ratios of methionine and methionine+cystine to lysine have been found to be increased by 15 and 25 %, respectively. In the present study, the CON diet was formulated to contain methionine and lysine at 0·25 and 0·97 %, respectively, and the dietary ratio of methionine:lysine (26:100) was the same as that recommended by the National Research Council (1998). Accordingly, the percentage of dietary methionine+cystine in the CON diet was up to 0·53 %, at 25 % of which, namely, 1·34 kg DLM (99 %) and 1·51 kg HMTBA (88 %) were added to 1000·05 kg of the CON diet at the expense of maize to form the DLM and HMTBA diets, respectively. The time span of farrowing between the sows was within 3 d. At day 0 post-partum, the backfat thickness of sows was 11·06 (sd 2·04), 11·17 (sd 2·87) and 12·83 (sd 1·96) mm for the CON, DLM and HMTBA treatments, respectively, and the body weight of sows was 155·68 (sd 17·82), 145·27 (sd 22·85) and 154·80 (sd 13·78) kg for the CON, DLM and HMTBA treatments, respectively. Within 12 h of farrowing, all litters were standardised based on the number and body weight of piglets so that there were ten piglets per sow, and the average body weight (CV < 3·0 %) of piglets was 1·42 (sd 0·02), 1·42 (sd 0·03) and 1·44 (sd 0·04) kg for the CON, DLM and HMTBA treatments, respectively. Sows had free access to diets and water throughout the experimental period.

Table 1 Ingredients and composition of the control (CON) diet of sows*

CP, crude protein.

* The dl-methionine (DLM) and dl-2-hydroxy-4-methylthiobutanoic acid (HMTBA) diets were prepared by adding 1·34 kg DLM (99 %) and 1·51 kg HMTBA (88 %), respectively, to 1000·05 kg of the CON diet at the expense of maize. Each diet (per kg) contained 14 200 kJ digestible energy.

The compositional values were calculated from the tabulated values of the National Research Council (1998)( 20 ).

Provided per kg of diet: retinol, 3600 mg; vitamin D3, 70 mg; vitamin E, 100 mg; menadione, 3·5 mg; thiamin, 3·5 mg; riboflavin, 8·5 mg; niacin, 35 mg; d-pantothenic acid, 21 mg; vitamin B6, 3·5 mg; vitamin B12, 35 mg; d-biotin, 420 mg; folic acid, 2·5 mg.

§ Provided per kg of diet: Cu, 10 mg; Fe, 120 mg; Mn, 30 mg; Zn, 80 mg; I, 0·21 mg; Se, 0·23 mg; antioxidant, 100 mg; anti-mould additive, 500 mg.

Collection of blood, milk and tissue samples

At 30 min before the initiation of the morning meal, following an overnight period of feed withdrawal, blood samples (10 ml) from each sow at days 7 and 14 post-partum were collected from the superior vena cava into heparinised tubes and immediately centrifuged for 10 min at 4000 rpm and 4°C. Supernatants were divided into four subsamples and stored at − 80°C until analysis. Milk samples (20 ml) from each sow were also collected at day 14 post-partum before the morning meal as described previously( Reference Daza, Riopérez and Centeno 5 ). Briefly, piglets were separated from their dams for 90 min initially, and then 10 IU (20 mg) of oxytocin (a nonapeptide; 1 IU of oxytocin is equivalent to about 2 mg of pure peptide) were injected into the ear vein of each sow, and the functional pectoral and inguinal glands were milked manually to collect milk samples, which were stored at − 20°C until analysis. At postnatal day 14, one piglet with an average body weight of the litter was selected from each litter for collecting intestinal samples as described previously( Reference Benevenga and Steele 14 ). Briefly, the intestine was rapidly excised from the ligament of Treitz to the ileo-caecal valve, freed of its mesenteric fat and rinsed in ice-cold saline. Measuring from the ligament of Treitz, a 2 cm section of tissue was removed, snap-frozen in liquid N2 and stored at − 80°C for subsequent RNA isolation.

Measurement of sow and piglet performance

Body weight and backfat thickness of each sow were determined before the morning meal at days 0 and 14 post-partum. Backfat thickness was measured at 65 mm left side of the dorsal midline at the last rib level using ultrasound (Renco Lean-Meater). Feed intake of each sow was recorded daily. Body weight of piglets was determined before the morning meal at postnatal days 0, 7 and 14.

Analysis of milk composition

For milk composition analysis, frozen milk samples were thawed at 4°C, and then 10 ml of each sample were used for the analysis of milk fat, lactose, protein and non-fat solid contents using an ultrasonic milk analyser (MILKYWAY-CP2; Hangzhou Simple Technology Company, Limited). Milk fat, lactose, protein and non-fat solid contents were automatically calculated based on the changes in ultrasonic propagation parameters such as velocity and amplitude of ultrasonic pulse emitted and received after travelling through the milk( Reference Wang, Liu and Zhou 22 ).

Analysis of plasma urea nitrogen and milk amino acids

Frozen plasma and milk samples were thawed at 4°C, and 1 ml of each sample and 2·5 ml of 7·5 % (w/v) TCA solution were mixed thoroughly and centrifuged at 12 000  g and 4°C for 15 min. Then, the supernatant fluid was collected, and AA and urea N concentrations were determined by ion-exchange chromatography using an L8800 high-speed AA analyser (Hitachi), as described previously( Reference Fang, Luo and Qi 16 ).

Analysis of plasma homocysteine concentration

Plasma homocysteine concentration was determined using a homocysteine detection kit (Jiancheng Bioengineering Limited), according to the manufacturer's instructions, and the assay principle was based on the method of enzymatic cycling, as described previously( Reference Roberts and Roberts 23 ). Briefly, oxidised homocysteine was first reduced to free homocysteine, which then reacts with a co-substrate, S-adenosyl-l-methionine, catalysed by homocysteine S-methyltransferase. The co-substrate conversion product was amplified by coupled enzymatic cycling reactions. The homocysteine level in the sample was indirectly proportional to the rate of the absorbance of NADH conversion to NAD+ and was measured at 340 nm.

RNA extraction and real-time PCR

Jejunal tissue samples were used to detect the expression of genes related to the intestinal transport of dietary nutrients. The detected genes included apoA-IV (APOA4) and fatty acid-binding protein 2 (FABP2), intestinal. Total RNA was extracted from the frozen samples using the RNAiso Plus reagent (TaKaRa Corporation), according to the manufacturer's specifications. Concentration of RNA in the samples was quantified using a DU-800 nucleic and protein detector (Beckman Coulter, Inc.) at an optical density (OD) of 260 nm, and the ratio of OD260:OD280 between 1·8 and 2·0 was acceptable. Integrity of RNA was verified by electrophoresis on a 1 % agarose gel stained with ethidium bromide. Real-time PCR was performed using the SYBR Green method and the ABI 7900HT Sequence Detection System (Applied Biosystems). Briefly, first-strand complementary DNA were synthesised from 1 μg of total RNA as described previously( Reference Fang, Luo and Qi 16 ). The thermal cycling parameters were as follows: 95°C for 30 s, followed by forty cycles at 95°C for 15 s and 60°C for 34 s, and finally followed by the dissociation step at 95°C for 15 s, 60°C for 1 min and 95°C for 15 s. To confirm the specific amplification, melt curve analysis was performed, and PCR products were also detected on ethidium bromide-stained 2 % agarose gel after electrophoresis using Tris–acetate–EDTA buffer. The nucleotide primer sequences of 18S RNA (forward, 5′-GACTCAACACGGGAAACCTCAC-3′; reverse, 5′-ATCGCTCCACCAACTAAGAACG-3′), APOA4 (forward, 5′-GTGGCTACTGTGATGTGGGACTAC-3′; reverse, 5′-CCAAGTTTGTCCTGGAAGAGAGTG-3′) and FABP2 (forward, 5′-TACAGCCTCGCAGACGGAAC-3′; reverse, 5′-CCTCTTGGCTTCTACTCCTTCATAC-3′) used for the real-time PCR were designed based on the mRNA sequences in pigs (accession no. NR_046261.1, NM_214388.1 and NM_001031780.1 for the 18S RNA, APOA4 and FABP2, respectively), and synthesised by Chengdu Tiantai Biological Company. These primers were designed to flank known or putative introns, thus preventing the amplification of any contaminating genomic DNA. The relative mRNA abundances of the detected genes in the jejunum samples were calculated using the $$2^{ - \Delta \Delta C _{t}} $$ method( Reference Livak and Schmittgen 24 ), and all data were normalised with 18S RNA in the same samples.

NMR spectroscopy

Plasma samples were prepared by mixing 200 μl of plasma with 400 μl of saline containing 50 % 2H2O (for field-frequency lock purposes). The proton NMR spectra of plasma were recorded at 298 K using a Bruker Avance DRX-600 spectrometer (Bruker BioSpin) operating at a 1H frequency of 600·11 MHz with a triple-resonance, high-resolution probe. A water-presaturated Carr–Purcell–Meiboom–Gill pulse sequence (recycle delay − 90° − (τ − 180° − τ)n− acquisition) was used to attenuate NMR signals from macromolecules. The spin–spin relaxation delay (2) of 200 ms was employed. Typically, a 90° pulse was set to 10·0 μs, and thirty-two transients were collected into 32k data points for each spectrum with a spectral width of 20 parts per million. For assignment purposes, five two-dimensional NMR spectra were acquired for the selected samples: 1H–1H J-resolved spectroscopy; 1H–1H correlation spectroscopy; 1H–1H total correlation spectroscopy; 1H–13C heteronuclear single-quantum coherence spectroscopy; 1H–13C heteronuclear multiple-bond correlation spectroscopy.

NMR spectral processes

Free induction decays were multiplied by an exponential window function with a 1 Hz line-broadening factor before Fourier transformation. All NMR spectra were initially phase-adjusted, and then the baseline was corrected using Mestrenova 7.0 software (Mestrelab Research SL). Chemical shift was referenced to the peak of the methyl proton of l-lactate at δ 1·33.

NMR spectra (δ 0·5–9·5) were integrated into regions of 0·002 parts per million wide using Mestrenova 7.0 software (Mestrelab Research SL). Regions distorted by imperfect water saturation were discarded as well as the regions containing urea signals. These regions are δ 4·47–5·18, δ 5·5–6·0 and δ 4·28–4·45. Subsequently, each integral region was normalised to the total sum of all the integral regions for each spectrum before pattern recognition analyses.

Statistical analysis

Data are presented as means and standard deviations. For comparisons of backfat thickness, body weight and concentrations of plasma homocysteine and urea N among the dietary treatment groups, a repeated-measures ANOVA (version 8.1, SAS Institute, Inc.) was performed with time as the repeated-measure effect. Differences in the means of milk composition and mRNA abundance were analysed by one-way ANOVA followed by Fisher's least significant difference test. Multivariate data analysis was carried out on the normalised NMR datasets with the software package SIMCA-P+ (version 11.0; Umetrics). Principal component analysis was performed to show an overview of intrinsic similarity/dissimilarity within the dataset. The orthogonal projection to latent structure discriminant analysis (OPLS-DA) was further carried out using the unit-variance scaled NMR data as the X-matrix and class information as the Y-matrix( Reference Trygg and Wold 25 ). The quality of the model was assessed by the parameters R 2 X, representing the total explained variations for the X-matrix, and Q 2, indicating model predictability. The models were validated by two methods: a cross-validation method( Reference Cloarec, Dumas and Trygg 26 ) and a permutation test( Reference Lindgren, Hansen and Karcher 27 ). The models were interpreted by coefficient-coded loading plots. The loadings were back-transformed in Excel (Microsoft) and plotted with colour-coded absolute coefficient values (|r|) of the variables in MATLAB (version 7.1; The Mathworks Inc.)( Reference Cloarec, Dumas and Trygg 26 ). The coefficient plot indicated the significance of variables (resonances) that contributed to the differentiation of classes of interest. The significant discriminatory metabolites were indicated by the red colour, whereas no significance was indicated by the blue colour. In the present study, appropriate correlation coefficients were used as the cut-off values (depending on the number of animals used) for statistical significance based on the significance of discrimination at the level of P< 0·05; such significance was determined according to Pearson's product–moment correlation coefficient test( Reference Cloarec, Dumas and Trygg 26 ). P≤ 0·05 was considered significant, and P< 0·10 was considered to have a tendency towards difference.

Results

Porcine performance

At day 14 post-partum, backfat thickness (11·72 (sd 2·05), 10·83 (sd 3·07) and 14·22 (sd 3·66) mm for the CON, DLM and HMTBA treatments, respectively) and body weight (155·47 (sd 12·80), 141·73 (sd 19·60) and 153·00 (sd 15·33) kg for the CON, DLM and HMTBA treatments, respectively) of sows did not differ (P>0·10) among the dietary treatment groups. The total feed consumption (69·08 (sd 10·00), 63·95 (sd 13·18) and 66·34 (sd 10·98) kg for the CON, DLM and HMTBA treatments, respectively) and daily digestible energy intake as a percentage of metabolic body weight (1590·96 (sd 196·82), 1572·71 (sd 229·45) and 1544·80 (sd 195·68) kJ for the CON, DLM and HMTBA treatments, respectively) were also not different (P>0·10) among the dietary treatment groups during the experimental phase. However, the body weight of suckling piglets at postnatal day 14 in the HMTBA group was higher (P= 0·02) than that in the CON group and tended (P= 0·07) to be higher than that in the DLM group (Table 2).

Table 2 Body weight (kg) of piglets at postnatal days 0, 7 and 14 (Mean values and standard deviations, n 6)

CON, control; DLM, dl-methionine; HMTBA, dl-2-hydroxy-4-methylthiobutanoic acid.

a,b,c,dMean values with unlike superscript letters were significantly different (P< 0·05).

* Mean value tended to be different from that of the HMTBA group (P< 0·10).

Plasma homocysteine and urea nitrogen concentrations

There was no effect of time (P>0·10) for plasma homocysteine and urea N concentrations. Plasma homocysteine (11·68 (sd 1·70) v. 9·49 (sd 1·58) μmol/l) and urea N (4836 (sd 852) v. 3898 (sd 453) μmol/l) concentrations that averaged across time were higher (P< 0·05) in the DLM-fed sows than in the CON-fed sows. Plasma urea N concentration that averaged across time was also higher (P< 0·05) in the DLM-fed sows than in the HMTBA-fed sows (4171 (sd 622) μmol/l). However, neither plasma homocysteine (10·28 (sd 1·87) μmol/l) nor urea N concentration that averaged across time was different (P>0·10) between the HMTBA-fed and CON-fed sows.

Milk amino acid concentrations

Table 3 presents milk AA concentrations in sows fed the CON, DLM or HMTBA diet at day 14 post-partum. Milk lysine concentration in the DLM-fed sows was lower (P< 0·05) than that in the CON-fed sows and tended (P< 0·10) to be lower than that in the HMTBA-fed sows. Milk histidine concentration was lower (P< 0·05) in the DLM-fed sows than in the CON-fed and HMTBA-fed sows. The DLM-fed sows also had lower (P< 0·05) ornithine concentration than the CON-fed sows. The HMTBA-fed sows had higher taurine (P< 0·05) concentration, but lower (P< 0·05) alanine concentration than the CON-fed sows. Milk cysteine concentration was higher (P< 0·05) in the HMTBA-fed sows than in the CON-fed and DLM-fed sows.

Table 3 Effects of diets supplemented with dl-methionine (DLM) or dl-2-hydroxy-4-methylthiobutanoic acid (HMTBA) on milk amino acid concentrations (μmol/l) in sows at day 14 post-partum (Mean values and standard deviations, n 6)

CON, control.

a,bMean values with unlike superscript letters were significantly different (P< 0·05).

* Mean value tended to be different from that of the HMTBA group (P< 0·10).

Milk fat, lactose, protein and non-fat solid contents

Milk fat and lactose contents were higher (P< 0·05) in the HMTBA-fed sows than in the CON-fed and DLM-fed sows, whereas milk protein and non-fat solid contents were lower (P< 0·05) in the DLM-fed sows than in the CON-fed and HMTBA-fed sows at 14 d post-partum (Fig. 1).

Fig. 1 Fat, protein, non-fat solid (NFS) and lactose contents in the milk of sows fed the control (), dl-methionine () and dl-2-hydroxy-4-methylthiobutanoic acid () diets at day 14 post-partum. Values are means (n 6), with standard deviations represented by vertical bars. a,bMean values with unlike letters were significantly different (P< 0·05).

mRNA abundance of genes related to intestinal nutrient transport

Fig. 2 shows the mRNA abundance of genes related to nutrient transport in the jejunum of 14-d-old suckling piglets. The mRNA abundance of the APAO4 gene was not different (P>0·10) among the dietary treatment groups. However, the mRNA abundance of FABP2 was higher (P< 0·05) in piglets reared by the HMTBA-fed sows than in those reared by the CON-fed and DLM-fed sows.

Fig. 2 mRNA abundance of genes related to nutrient transport in the jejunum of 14-d-old suckling piglets reared by sows fed the control (), dl-methionine () and dl-2-hydroxy-4-methylthiobutanoic acid () diets. Values are means (n 6), with standard deviations represented by vertical bars. a,bMean values with unlike letters were significantly different (P< 0·05). APOA4, apoA-IV; FABP2, fatty acid-binding protein 2.

Multivariate data analysis of NMR datasets

Principal component analysis was initially performed on the spectral data, and two principal components were calculated for the six dietary treatment groups, with 35·3 and 27·1 % of the total variation being explained by principal components 1 and 2, respectively. The principal component analysis (Fig. 3(A)) showed that separations were absent in the plasma metabolic profiles at 7 and 14 d post-partum from the respective groups. Therefore, the respective groups of sows at 7 and 14 d post-partum were merged to represent the CON, DLM and HMTBA groups, respectively (i.e. CON-day 7+CON-day 14 = CON; DLM-day 7+DLM-day 14 = DLM; HMTBA-day 7+HMTBA-day 14 = HMTBA). Projection to latent structure with discriminant analysis of the plasma spectra from the CON, DLM and HMTBA groups was performed, and the score plots (Fig. 3(B)–(D)) clearly showed two clusters corresponding to the two groups of different dietary regimens, respectively. To further identify the important plasma metabolic changes induced by the different dietary regimens, the metabolic profiles of sows from different dietary treatment groups were compared using the OPLS-DA strategy. The corresponding coefficient loading plots showed that the plasma levels of allantoin, citrate, creatinine, formate, glycerol, lactate, methionine, myo-inositol, N-acetyl glycoprotein and valine were higher (P< 0·05), whereas those of acetate, lysine, tyrosine and glucose were lower (P< 0·05) in the DLM group than in the CON group (Fig. 4(A) and Table 4). The corresponding coefficient loading plots also showed that the plasma levels of acetate, dimethylamine (DMA), methionine and valine were higher (P< 0·05) in the HMTBA group than in the CON group (Fig. 4(B) and Table 4). Multivariate data analysis showed that the plasma levels of acetate, leucine, isoleucine, lysine, tyrosine, valine and glucose were higher (P< 0·05), but those of alanine, glutamate, glutamine, lactate and N-acetyl glycoprotein were lower (P< 0·05) in the HMTBA group than in the DLM group (Fig. 4(C) and Table 4).

Fig. 3 (A) Principal component analysis (PC1 and PC2) and (B–D) projection to latent structure discriminant analysis score plots based on 1H NMR spectra of plasma obtained from different dietary treatment groups. CON, control; DLM, dl-methionine; HMTBA, dl-2-hydroxy-4-methylthiobutanoic acid; t[1], Principal component 1 of principal component analysis score plot; t[2], principal component 2 of principal component analysis score plot. (A) , CON-day 7 (d7); , CON-day 14 (d14); , DLM-d7; , DLM-d14; , HMTBA-d7; , HMTBA-d14. R 2 X= 62·4 %, Q 2= 0·538. (B) , CON; , DLM. R 2 X= 40·5 %, R 2 Y= 0·993, Q 2= 0·529. (C) , CON; , HMTBA. R 2 X= 38·6 %, R 2 Y= 0·992, Q 2= 0·741. (D) , DLM; , HMTBA. R 2 X= 32·1 %, R 2 Y= 0·998, Q 2= 0·452.

Fig. 4 Orthogonal projection to latent structure discriminant analysis score plots (A–C) derived from 1H NMR spectra of plasma and corresponding coefficient loading plots (D–F) obtained from different dietary treatment groups. The colour map shows the significance of metabolite variations between the two classes of peaks. Peaks in the positive direction indicate metabolites that are more abundant in the groups in the positive direction of the first principal component. Consequently, metabolites that are more abundant in the groups in the negative direction of the first principal component are presented as peaks in the negative direction. Ace, acetate; Ala, alanine; All, allantoin; Cit, citrate; Cn, creatinine; DMA, dimethylamine; For, formate; G, glycerol; Glc, glucose; Gln, glutamine; Glu, glutamate; Ile, isoleucine; Lac, lactate; Leu, leucine; Lys, lysine; m-I, myo-inositol; Met, methionine; NAG, N-acetyl glycoprotein; Tyr, tyrosine; Val, valine. CON, control; DLM, dl-methionine; HMTBA, dl-2-hydroxy-4-methylthiobutanoic acid; ppm, parts per million; t[1]P, principal component 1 of orthogonal projection to latent structure discriminant analysis score plot; t[2]O, principal component 2 of orthogonal projection to latent structure discriminant analysis score plot. (A) , CON; , DLM. R 2 X= 21·5 %, Q 2= 0·229. (B) , CON; , HMTBA. R 2 X= 18·9 %, Q 2= − 0·159. (C) , DLM; , HMTBA. R 2 X= 18·5 %, Q 2= 0·309.

Table 4 Orthogonal projection to latent structure discriminant analysis coefficients derived from the NMR data of metabolites in plasma obtained from the different dietary treatment groups*

DLM, dl-methionine; CON, control; HMTBA, dl-2-hydroxy-4-methylthiobutanoic acid.

* Assignments of plasma metabolites in pigs are shown in Table 5.

In the Correlation coefficient column, positive and negative signs indicate positive and negative correlations in concentrations, respectively. The correlation coefficient of |r|>0·553 was used as the cut-off value for statistical significance based on the significance of discrimination at the level of P= 0·05 and df = 11. ‘–’ represents the correlation coefficient of |r| < 0·553.

Table 5 Assignments of plasma metabolites in pigs*

* Chemical shift was referenced to the methyl group of lactate at δ 1·33.

Multiplicity: s, singlet; d, doublet; t, triplet; q, quartet; m, multiplet; dd, double of doubles.

Discussion

The main objective of the present study was to determine the metabolic mechanisms of milk synthesis in response to increased consumption of methionine as DLM or its hydroxy analogue HMTBA. As reported previously in the literature, conducting experimental trials using the sow as a model represents several challenges. First, given that lactation performance of sows was, to a great extent, affected by feed intake( Reference Kruse, Traulsen and Krieter 28 ), which negatively correlates with body fatness at parturition( Reference Eissen, Kanis and Kemp 29 ), backfat thickness at day 0 post-partum was the first consideration in the grouping of sows in the present study. Second, previous work has shown that sows have limited ability to support mammary growth and milk production, especially during the first lactation period when feed intake is usually inadequate( Reference Kim, Hurley and Wu 30 ), which indicates the importance of uniform parity in the evaluation of performance responses to dietary treatments. To minimise the potential effect of sow status on lactation performance, only the first-parity sows with similar genetic background and body weight were used in the study. Third, evidence shows that litter size is also an important factor that influences maternal tissue protein mobilisation and nutrient requirements during lactation( Reference Kim and Easter 31 ). Thus, all litters were standardised, as described previously( Reference Kusina, Pettigrew and Sower 32 ), to ten pigs per sow throughout the experimental period. Based on the aforementioned control, we found no statistical difference in both total feed consumption and energy intake per metabolic body weight among diets. This may allow us to discuss the difference in lactation performance in association with dietary treatments, specifically methionine levels and sources.

A particularly important finding was that increased consumption of methionine as HMTBA not only increased methionine availability for extra-intestinal tissues, but also had no effect on lysine availability, which was decreased by DLM consumption. This may be explained by the difference in the chemical nature and absorption site of methionine sources. Lysine and methionine have been reported to share the B0,+ and b0,+ transport systems in the mammalian intestine( Reference Bröer 33 ), and an earlier study( Reference Hagihira, Lin and Samiy 34 ) has indicated mutual inhibition occurring among lysine, methionine, cystine, ornithine and arginine when transported across the intestinal epithelium. Moreover, a down-regulation effect of l-methionine on these transporters has been reported in broiler chickens, and decreased lysine uptake has been found to be concomitant with reduced methionine transport( Reference Soriano-García, Torras-Llort and Moretó 35 ). In contrast, HMTBA is an organic acid until it is converted to l-methionine, which provides a biochemical basis for the absorption of HMTBA in the upper gastrointestinal tract( Reference Dibner and Buttin 36 ). Consistent with this notion, previous studies in broilers( Reference Richards, Atwell and Vazquez-Anon 37 ) have indicated that HMTBA absorption occurs primarily in the proximal gastrointestinal tract before the small intestine. The transporter mediating HMTBA transport across the apical membrane of cell monolayers is monocarboxylate transporter 1( Reference Martín-Venegas, Rodríguez-Lagunas and Geraert 38 ). Recent studies in pigs( Reference Jendza, Geraert and Ragland 39 ) have further revealed that absorption of HMTBA is complete by the end of the duodenum. Moreover, diffusion into cells represents a major route of organic acid uptake and occurs most rapidly at low pH when more of the acid will be protonated and lipophilic( Reference Walter and Gutknecht 40 ), which provides further support for the highly efficient absorption of HMTBA in the upper gastrointestinal tract. Taken together, the highly efficient absorption of HMTBA as an organic acid has two effects, namely increasing methionine availability for extra-intestinal tissues without compromising lysine availability.

Lysine is often considered to be the first-limiting AA for lactating sows sustaining milk synthesis( Reference Soltwedel, Easter and Pettigrew 9 ). Further studies have shown that milk protein synthesis is affected by plasma AA availability( Reference Guan, Bequette and Ku 10 , Reference Guan, Bequette and Calder 41 , Reference Guan, Pettigrew and Ku 42 ). With these in mind, the lower plasma lysine level may explain the lower milk protein synthesis in the DLM-fed sows than in the CON-fed and HMTBA-fed sows. The increased levels of the tricarboxylic acid cycle intermediate, citrate, in the DLM-fed sows might be associated with the mobilisation of body fat and muscle tissues. In support of this view, there was extensive muscle degradation in the DLM-fed sows as evidenced by elevated plasma alanine and urea N levels( Reference Fang, Huang and Luo 18 ). In addition, the HMTBA-fed sows had relatively lower plasma glutamate and glutamine levels than the DLM-fed sows, which is in agreement with our previous studies in piglets( Reference Fang, Luo and Qi 16 ). Glutamate and glutamine are major fuels for the gut( Reference Janeczko, Stoll and Chang 43 ). Increased glutamate and glutamine catabolism following HMTBA consumption may spare essential AA as an energy source for the intestine and thus improve their extra-intestinal availability as evaluated by the net portal balance( Reference Fang, Luo and Qi 16 , Reference Fang, Huang and Luo 18 ). In the present study, there were also higher leucine, isoleucine and valine levels in the plasma of the HMTBA-fed sows than those of the DLM-fed sows, which may be a result of their enhanced net portal balance as observed in our previous studies( Reference Fang, Luo and Qi 16 ). Given that leucine and isoleucine play a central role in the activation of mammalian target of rapamycin signalling, which is a control point of protein synthesis, higher leucine and isoleucine levels in plasma may provide further explanation for the higher protein level in the milk of the HMTBA-fed sows than that of the DLM-fed sows.

A second important finding was that the acetate level was increased by HMTBA consumption, but decreased by DLM consumption. Our previous studies have found that there is more than 3-fold acetate production in the distal small intestine of the HMTBA-fed pigs than that in the DLM-fed pigs( Reference Fang, Luo and Qi 16 ), which may provide an explanation for the higher plasma acetate concentration observed in the HMTBA-fed sows. There is evidence that the lactating sow can utilise acetate as a carbon source for fatty acid synthesis( Reference Pettigrew, Gill and France 44 ). The increased availability of acetate may increase milk fat synthesis through the contribution of the carbon source. In support of this view, the HMTBA-fed sows showed higher fat concentration in milk than the CON- and DLM-fed sows. In addition, physiological concentrations of SCFA, particularly acetate, have been shown to exert a promoting effect on blood flow( Reference Kvietys and Granger 45 ), which may facilitate the transportation of nutrients from the lumen into the portal blood and from the blood into the tissues as shown in previous studies( Reference Fang, Luo and Qi 16 , Reference Guan, Stoll and Lu 46 ). It appears that the potential increase in the blood flow of the HMTBA-fed sows may also contribute to increased milk synthesis. Increased piglet body weight and milk lactose level, which positively correlates with milk yield( Reference Shahbazkia, Aminlari and Tavasoli 47 ) provided evidence for increased milk synthesis in the HMTBA-fed sows.

The availability of glucose is considered to be essential for overall milk synthesis and is particularly important for milk fat synthesis. Besides providing the carbon source, glucose is also used for generating reducing equivalents and producing glycerol molecules required for fatty acid synthesis( Reference Luick and Kleiber 48 ). The decreased glucose level in plasma provided further explanation for the lower fat level in the milk of the DLM-fed sows. Beyond the increased milk fat content, enhanced milk concentrations of free SAA including cysteine and taurine were observed in the HMTBA-fed sows. Taurine and cystine have been reported( Reference Wu and Knabe 49 ) to be the most abundant milk free AA and the least abundant milk protein-bound AA, respectively. In this regard, increased SAA supply may provide further explanation for the improved growth of neonatal pigs reared by the HMTBA diet-fed sows. In addition, consistent with previous studies( Reference Wang, Chen and Li 50 ), we observed the intestinal mRNA expression of APOA4 and FABP2, which are thought to participate in the uptake, intracellular metabolism and/or transport of long-chain fatty acids( Reference Wang, Chen and Li 50 , Reference Lu, Yao and Meng 51 ). Piglets reared by the HMTBA-fed sows had up-regulated FABP2 expression, which might be due to these piglets receiving more milk fat for transport and metabolism by the intestine.

A third important finding was that plasma homocysteine and creatinine levels were increased following DLM consumption, but an increased level of DMA, the hydrolysis product of asymmetric dimethylarginine (ADMA), was observed in the HMTBA-fed sows rather than in the DLM-fed sows. This higher DMA concentration suggested that more amount of ADMA was degraded in the HMTBA-fed sows. Given that ADMA is an endogenous inhibitor of NO synthesis, the presumed lower level of ADMA in the HMTBA-fed sows might lead to increased NO synthesis, which, in turn, affected the blood flow and thus promoted milk synthesis, as discussed previously. Moreover, ADMA has been shown to have a strong association with cardiovascular incident risk and mortality risk( Reference Shi, Ni and Zhou 52 Reference Young, Terrin and Wang 54 ). The hydrolysis of ADMA to DMA is, therefore, considered to be a detoxification pathway. It has been reported that 90 % of ADMA is metabolised by dimethylarginine dimethylaminohydrolase (DDAH), the enzyme responsible for the breakdown of ADMA( Reference Atamer, Ecder and Atamer 55 ). A dose-dependent reduction in DDAH activity by homocysteine has been observed in previous studies( Reference Stühlinger, Tsao and Her 56 ). Therefore, it has been inferred that the higher homocysteine level increased the inhibition of DDAH activity and thus decreased the hydrolysis of ADMA to DMA, which may explain that the DMA level was higher in the HMTBA-fed sows than in the CON-fed sows, but was not different between the DLM-fed and CON-fed sows. In support of this view, studies in humans have shown that acute elevation of homocysteine level by oral methionine loading stimulates the formation of ADMA. Moreover, growing evidence indicates that the ADMA level is positively correlated with homocysteine and creatinine levels( Reference Atamer, Ecder and Atamer 55 ). It would appear that higher homocysteine and creatinine levels are indicative of increased production of ADMA following DLM consumption. Given that enhanced plasma levels of homocysteine as well as ADMA( Reference Shi, Ni and Zhou 52 Reference Young, Terrin and Wang 54 ) are strongly associated with CVD in adults( Reference Stipanuk 57 ) and with an increased risk of stroke in infants( Reference Hogeveen, Blom and van Amerongen 58 ) and children( Reference van Beynum, Smeitink and den Heijer 59 ), HMTBA may have particular health implications for animals and humans, which warrants further studies.

In summary, increased maternal consumption of methionine as HMTBA contributed to neonatal growth and milk synthesis, which was metabolically associated with elevated methionine, valine and acetate availability for delivery to the mammary glands, neither compromising lysine and glucose availability nor increasing homocysteine accumulation. These observations offered novel insights into the mechanisms of SAA metabolism and milk synthesis regulated by methionine sources, which may have important nutrition and health implications for animals and humans.

Acknowledgements

The authors acknowledge the financial support from the Rhodimet Research Grant from Adisseo France SAS, Briand, Antony Cedex, France, the National Natural Science Foundation of China (30901042), and Sichuan Province Science Foundation for Fostering Youths Talents (2011JQ0015). The authors thank BIOTREE for technical assistance in the data analysis.

The authors' contributions are as follows: Z. F., D. W. and D. C. designed the study; H. L., H. W., X. Z., C. W., X. W., L. C., Y. L., S. X. and G. T. performed the study; X. Z., Z. F., G. L., Y. M. and H. L. analysed the data and wrote the paper.

The authors declare that there is a potential conflict of interest, given that Y. M. is an employee of Adisseo (one of the financial supporters of the present study).

References

1 Fang, Z, Yao, K, Zhang, X, et al. (2010) Nutrition and health relevant regulation of intestinal sulfur amino acid metabolism. Amino acids 39, 633640.CrossRefGoogle ScholarPubMed
2 Shoveller, AK, Stoll, B, Ball, RO, et al. (2005) Nutritional and functional importance of intestinal sulfur amino acid metabolism. J Nutr 135, 16091612.CrossRefGoogle ScholarPubMed
3 Bauchart-Thevret, C, Stoll, B, Chang, X, et al. (2008) Sulfur amino acids are necessary for normal intestinal mucosal growth in neonatal piglets. FASEB J 22, 896.1.CrossRefGoogle Scholar
4 Bauchart-Thevret, C, Stoll, B, Chacko, S, et al. (2009) Sulfur amino acid deficiency upregulates intestinal methionine cycle activity and suppresses epithelial growth in neonatal pigs. Am J Physiol Endocrinol Metab 296, E1239E1250.CrossRefGoogle ScholarPubMed
5 Daza, A, Riopérez, J & Centeno, C (2004) Short Communication. Changes in the composition of sows' milk between days 5 to 26 of lactation. Span J Agric Res 2, 333336.CrossRefGoogle Scholar
6 Stoll, B, Henry, J, Reeds, PJ, et al. (1998) Catabolism dominates the first-pass intestinal metabolism of dietary essential amino acids in milk protein-fed piglets. J Nutr 128, 606614.CrossRefGoogle ScholarPubMed
7 Dai, ZL, Li, XL, Xi, PB, et al. (2012) Metabolism of select amino acids in bacteria from the pig small intestine. Amino Acids 42, 15971608.CrossRefGoogle ScholarPubMed
8 Schei, I, Danfær, A, Boman, I, et al. (2007) Post-ruminal or intravenous infusions of carbohydrates or amino acids to dairy cows 1. Early lactation. Animal 1, 501514.CrossRefGoogle ScholarPubMed
9 Soltwedel, KT, Easter, RA & Pettigrew, JW (2006) Evaluation of the order of limitation of lysine, threonine, and valine, as determined by plasma urea nitrogen, in corn–soybean meal diets of lactating sows with high body weight loss. J Anim Sci 84, 17341741.CrossRefGoogle ScholarPubMed
10 Guan, X, Bequette, BJ, Ku, PK, et al. (2004) The amino acid need for milk synthesis is defined by the maximal uptake of plasma amino acids by porcine mammary glands. J Nutr 134, 21822190.CrossRefGoogle ScholarPubMed
11 Bojčuková, J & Krátký, F (2006) Influence of various lysine and threonine levels in feed mixtures for lactating sows on milk quality and piglet growth. Czech J Anim Sci 51, 2430.CrossRefGoogle Scholar
12 Appuhamy, J, Knapp, J, Becvar, O, et al. (2011) Effects of jugular-infused lysine, methionine, and branched-chain amino acids on milk protein synthesis in high-producing dairy cows. J Dairy Sci 94, 19521960.CrossRefGoogle ScholarPubMed
13 Appuhamy, JA, Knoebel, NA, Nayananjalie, WA, et al. (2012) Isoleucine and leucine independently regulate mTOR signaling and protein synthesis in MAC-T cells and bovine mammary tissue slices. J Nutr 142, 484491.CrossRefGoogle ScholarPubMed
14 Benevenga, N & Steele, R (1984) Adverse effects of excessive consumption of amino acids. Annu Rev Nutr 4, 157181.CrossRefGoogle ScholarPubMed
15 Xie, M, Hou, S, Huang, W, et al. (2007) Effect of excess methionine and methionine hydroxy analogue on growth performance and plasma homocysteine of growing Pekin ducks. Poult Sci 86, 19951999.CrossRefGoogle ScholarPubMed
16 Fang, Z, Luo, J, Qi, Z, et al. (2009) Effects of 2-hydroxy-4-methylthiobutyrate on portal plasma flow and net portal appearance of amino acids in piglets. Amino acids 36, 501509.CrossRefGoogle ScholarPubMed
17 Fang, Z, Luo, H, Wei, H, et al. (2010) Methionine metabolism in piglets fed dl-methionine or its hydroxy analogue was affected by distribution of enzymes oxidizing these sources to keto-methionine. J Agric Food Chem 58, 20082014.CrossRefGoogle ScholarPubMed
18 Fang, Z, Huang, F, Luo, J, et al. (2010) Effects of dl-2-hydroxy-4-methylthiobutyrate on the first-pass intestinal metabolism of dietary methionine and its extra-intestinal availability. Br J Nutr 103, 643651.CrossRefGoogle ScholarPubMed
19 Swindle, MM, Makin, A, Herron, AJ, et al. (2012) Swine as models in biomedical research and toxicology testing. Vet Pathol 49, 344356.CrossRefGoogle ScholarPubMed
20 National Research Council (1998) Requirements of Swine, 10th ed. Washington, DC: National Academic Press.Google Scholar
21 Dourmad, J-Y, Étienne, M, Valancogne, A, et al. (2008) InraPorc: a model and decision support tool for the nutrition of sows. Anim Feed Sci Technol 143, 372386.CrossRefGoogle Scholar
22 Wang, YB, Liu, DH, Zhou, XH, et al. (2003) Effect of applying ultrasonic milk analyzer for detecting composition of cow milk adulterated with table salt and sugar. J Zhejiang University (Agric Life Sci) 29, 671674.Google Scholar
23 Roberts, RF & Roberts, WL (2004) Performance characteristics of a recombinant enzymatic cycling assay for quantification of total homocysteine in serum or plasma. Clin Chim Acta 344, 9599.CrossRefGoogle ScholarPubMed
24 Livak, KJ & Schmittgen, TD (2001) Analysis of relative gene expression data using real-time quantitative PCR and the $$2^{ - \Delta \Delta C _{t}} $$ method. Methods 25, 402408.CrossRefGoogle ScholarPubMed
25 Trygg, J & Wold, S (2002) Orthogonal projections to latent structures (O-PLS). J Chemom 16, 119128.CrossRefGoogle Scholar
26 Cloarec, O, Dumas, ME, Trygg, J, et al. (2005) Evaluation of the orthogonal projection on latent structure model limitations caused by chemical shift variability and improved visualization of biomarker changes in 1H NMR spectroscopic metabonomic studies. Anal Chem 77, 517526.CrossRefGoogle ScholarPubMed
27 Lindgren, F, Hansen, B, Karcher, W, et al. (1996) Model validation by permutation tests: applications to variable selection. J Chemom 10, 521532.3.0.CO;2-J>CrossRefGoogle Scholar
28 Kruse, S, Traulsen, I & Krieter, J (2011) Analysis of water, feed intake and performance of lactating sows. Livest Sci 135, 177183.CrossRefGoogle Scholar
29 Eissen, J, Kanis, E & Kemp, B (2000) Sow factors affecting voluntary feed intake during lactation. Livest Prod Sci 64, 147165.CrossRefGoogle Scholar
30 Kim, S, Hurley, W, Wu, G, et al. (2009) Ideal amino acid balance for sows during gestation and lactation. J Anim Sci 87, E123E132.CrossRefGoogle ScholarPubMed
31 Kim, S & Easter, R (2001) Nutrient mobilization from body tissues as influenced by litter size in lactating sows. J Anim Sci 79, 21792186.CrossRefGoogle ScholarPubMed
32 Kusina, J, Pettigrew, J, Sower, A, et al. (1999) Effect of protein intake during gestation and lactation on the lactational performance of primiparous sows. J Anim Sci 77, 931941.CrossRefGoogle ScholarPubMed
33 Bröer, S (2008) Amino acid transport across mammalian intestinal and renal epithelia. Physiol Rev 88, 249286.CrossRefGoogle ScholarPubMed
34 Hagihira, H, Lin, E, Samiy, A, et al. (1961) Active transport of lysine, ornithine, arginine and cystine by the intestine. Biochem Biophys Res Commun 4, 478481.CrossRefGoogle ScholarPubMed
35 Soriano-García, JF, Torras-Llort, M, Moretó, M, et al. (1999) Regulation of l-methionine and l-lysine uptake in chicken jejunal brush-border membrane by dietary methionine. Am J Physiol Regul Integr Comp Physiol 277, R1654R1661.CrossRefGoogle ScholarPubMed
36 Dibner, J & Buttin, P (2002) Use of organic acids as a model to study the impact of gut microflora on nutrition and metabolism. J Appl Poult Res 11, 453463.CrossRefGoogle Scholar
37 Richards, J, Atwell, C, Vazquez-Anon, M, et al. (2005) Comparative in vitro and in vivo absorption of 2-hydroxy-4 (methylthio) butanoic acid and methionine in the broiler chicken. Poult Sci 84, 13971405.CrossRefGoogle Scholar
38 Martín-Venegas, R, Rodríguez-Lagunas, M, Geraert, P, et al. (2007) Monocarboxylate transporter 1 mediates dl-2-hydroxy-(4-methylthio) butanoic acid transport across the apical membrane of Caco-2 cell monolayers. J Nutr 137, 4954.CrossRefGoogle ScholarPubMed
39 Jendza, J, Geraert, P, Ragland, D, et al. (2011) The site of intestinal disappearance of dl-methionine and methionine hydroxy analog differs in pigs. J Anim Sci 89, 13851391.CrossRefGoogle ScholarPubMed
40 Walter, A & Gutknecht, J (1984) Monocarboxylic acid permeation through lipid bilayer membranes. J Membr Biol 77, 255264.CrossRefGoogle ScholarPubMed
41 Guan, X, Bequette, BJ, Calder, G, et al. (2002) Amino acid availability affects amino acid flux and protein metabolism in the porcine mammary gland. J Nutr 132, 12241234.Google ScholarPubMed
42 Guan, X, Pettigrew, J, Ku, P, et al. (2004) Dietary protein concentration affects plasma arteriovenous difference of amino acids across the porcine mammary gland. J Anim Sci 82, 29532963.CrossRefGoogle ScholarPubMed
43 Janeczko, MJ, Stoll, B, Chang, X, et al. (2007) Extensive gut metabolism limits the intestinal absorption of excessive supplemental dietary glutamate loads in infant pigs. J Nutr 137, 23842390.CrossRefGoogle ScholarPubMed
44 Pettigrew, J, Gill, M, France, J, et al. (1992) A mathematical integration of energy and amino acid metabolism of lactating sows. J Anim Sci 70, 37423761.CrossRefGoogle ScholarPubMed
45 Kvietys, P & Granger, D (1981) Effect of volatile fatty acids on blood flow and oxygen uptake by the dog colon. Gastroenterology 80, 962969.CrossRefGoogle ScholarPubMed
46 Guan, X, Stoll, B, Lu, X, et al. (2003) GLP-2-mediated up-regulation of intestinal blood flow and glucose uptake is nitric oxide-dependent in TPN-fed piglets. Gastroenterology 125, 136147.CrossRefGoogle ScholarPubMed
47 Shahbazkia, HR, Aminlari, M, Tavasoli, A, et al. (2010) Associations among milk production traits and glycosylated haemoglobin in dairy cattle; importance of lactose synthesis potential. Vet Res Commun 34, 19.CrossRefGoogle ScholarPubMed
48 Luick, JR & Kleiber, M (1961) Quantitative importance of plasma glucose for synthesis of milk fat glycerol. Am J Physiol 200, 13271329.CrossRefGoogle ScholarPubMed
49 Wu, G & Knabe, DA (1994) Free and protein-bound amino acids in sow's colostrum and milk. J Nutr 124, 415424.CrossRefGoogle ScholarPubMed
50 Wang, J, Chen, L, Li, P, et al. (2008) Gene expression is altered in piglet small intestine by weaning and dietary glutamine supplementation. J Nutr 138, 10251032.CrossRefGoogle ScholarPubMed
51 Lu, S, Yao, Y, Meng, S, et al. (2002) Overexpression of apolipoprotein A-IV enhances lipid transport in newborn swine intestinal epithelial cells. J Biol Chem 277, 3192931937.CrossRefGoogle ScholarPubMed
52 Shi, B, Ni, Z, Zhou, W, et al. (2010) Circulating levels of asymmetric dimethylarginine are an independent risk factor for left ventricular hypertrophy and predict cardiovascular events in pre-dialysis patients with chronic kidney disease. Eur J Intern Med 21, 444448.CrossRefGoogle ScholarPubMed
53 Abedini, S, Meinitzer, A, Holme, I, et al. (2009) Asymmetrical dimethylarginine is associated with renal and cardiovascular outcomes and all-cause mortality in renal transplant recipients. Kidney Int 77, 4450.CrossRefGoogle Scholar
54 Young, JM, Terrin, N, Wang, X, et al. (2009) Asymmetric dimethylarginine and mortality in stages 3 to 4 chronic kidney disease. Clin J Am Soc Nephrol 4, 11151120.CrossRefGoogle ScholarPubMed
55 Atamer, A, Ecder, SA, Atamer, Y, et al. (2012) The effects of asymmetric dimethylarginine (ADMA), nitric oxide (NO) and homocysteine (Hcy) on progression of mild chronic kidney disease (CKD): relationship between clinical and biochemical parameters In Chronic Kidney Disease, pp. 197–208 [M Gööz, editor]. Rijeka, Croatia: InTech.Google Scholar
56 Stühlinger, MC, Tsao, PS, Her, J-H, et al. (2001) Homocysteine impairs the nitric oxide synthase pathway role of asymmetric dimethylarginine. Circulation 104, 25692575.CrossRefGoogle ScholarPubMed
57 Stipanuk, MH (2004) Sulfur amino acid metabolism: pathways for production and removal of homocysteine and cysteine. Annu Rev Nutr 24, 539577.CrossRefGoogle ScholarPubMed
58 Hogeveen, M, Blom, HJ, van Amerongen, M, et al. (2002) Hyperhomocysteinemia as risk factor for ischemic and hemorrhagic stroke in newborn infants. J Pediatr 141, 429431.CrossRefGoogle ScholarPubMed
59 van Beynum, IM, Smeitink, JAM, den Heijer, M, et al. (1999) Hyperhomocysteinemia: a risk factor for ischemic stroke in children. Circulation 99, 20702072.CrossRefGoogle ScholarPubMed
Figure 0

Table 1 Ingredients and composition of the control (CON) diet of sows*

Figure 1

Table 2 Body weight (kg) of piglets at postnatal days 0, 7 and 14 (Mean values and standard deviations, n 6)

Figure 2

Table 3 Effects of diets supplemented with dl-methionine (DLM) or dl-2-hydroxy-4-methylthiobutanoic acid (HMTBA) on milk amino acid concentrations (μmol/l) in sows at day 14 post-partum (Mean values and standard deviations, n 6)

Figure 3

Fig. 1 Fat, protein, non-fat solid (NFS) and lactose contents in the milk of sows fed the control (), dl-methionine () and dl-2-hydroxy-4-methylthiobutanoic acid () diets at day 14 post-partum. Values are means (n 6), with standard deviations represented by vertical bars. a,bMean values with unlike letters were significantly different (P< 0·05).

Figure 4

Fig. 2 mRNA abundance of genes related to nutrient transport in the jejunum of 14-d-old suckling piglets reared by sows fed the control (), dl-methionine () and dl-2-hydroxy-4-methylthiobutanoic acid () diets. Values are means (n 6), with standard deviations represented by vertical bars. a,bMean values with unlike letters were significantly different (P< 0·05). APOA4, apoA-IV; FABP2, fatty acid-binding protein 2.

Figure 5

Fig. 3 (A) Principal component analysis (PC1 and PC2) and (B–D) projection to latent structure discriminant analysis score plots based on 1H NMR spectra of plasma obtained from different dietary treatment groups. CON, control; DLM, dl-methionine; HMTBA, dl-2-hydroxy-4-methylthiobutanoic acid; t[1], Principal component 1 of principal component analysis score plot; t[2], principal component 2 of principal component analysis score plot. (A) , CON-day 7 (d7); , CON-day 14 (d14); , DLM-d7; , DLM-d14; , HMTBA-d7; , HMTBA-d14. R2X= 62·4 %, Q2= 0·538. (B) , CON; , DLM. R2X= 40·5 %, R2Y= 0·993, Q2= 0·529. (C) , CON; , HMTBA. R2X= 38·6 %, R2Y= 0·992, Q2= 0·741. (D) , DLM; , HMTBA. R2X= 32·1 %, R2Y= 0·998, Q2= 0·452.

Figure 6

Fig. 4 Orthogonal projection to latent structure discriminant analysis score plots (A–C) derived from 1H NMR spectra of plasma and corresponding coefficient loading plots (D–F) obtained from different dietary treatment groups. The colour map shows the significance of metabolite variations between the two classes of peaks. Peaks in the positive direction indicate metabolites that are more abundant in the groups in the positive direction of the first principal component. Consequently, metabolites that are more abundant in the groups in the negative direction of the first principal component are presented as peaks in the negative direction. Ace, acetate; Ala, alanine; All, allantoin; Cit, citrate; Cn, creatinine; DMA, dimethylamine; For, formate; G, glycerol; Glc, glucose; Gln, glutamine; Glu, glutamate; Ile, isoleucine; Lac, lactate; Leu, leucine; Lys, lysine; m-I, myo-inositol; Met, methionine; NAG, N-acetyl glycoprotein; Tyr, tyrosine; Val, valine. CON, control; DLM, dl-methionine; HMTBA, dl-2-hydroxy-4-methylthiobutanoic acid; ppm, parts per million; t[1]P, principal component 1 of orthogonal projection to latent structure discriminant analysis score plot; t[2]O, principal component 2 of orthogonal projection to latent structure discriminant analysis score plot. (A) , CON; , DLM. R2X= 21·5 %, Q2= 0·229. (B) , CON; , HMTBA. R2X= 18·9 %, Q2= − 0·159. (C) , DLM; , HMTBA. R2X= 18·5 %, Q2= 0·309.

Figure 7

Table 4 Orthogonal projection to latent structure discriminant analysis coefficients derived from the NMR data of metabolites in plasma obtained from the different dietary treatment groups*

Figure 8

Table 5 Assignments of plasma metabolites in pigs*