Effects of Supplemental Glutamine on Growth Performance, Plasma Parameters and LPS-induced Immune Response of Weaned Barrows after Castration

Article information

Asian-Australas J Anim Sci.. 2012;25(5):674-681
Publication date (electronic) : 2012 May 01
doi : https://doi.org/10.5713/ajas.2011.11359
1Kaohsiung Animal Propagation Station, Livestock Research Institute, COA, Pingtung 912, Taiwan
2Department of Animal Science, National Chung Hsing University, Taichung 402, Taiwan.
3Department of Biotechnology, Ming Dao University, Changhau 523, Taiwan.
4Animal Technology Institute Taiwan, P.O. box 23, Chunan, Miaoli 350, Taiwan.
*Corresponding Author: B. Yu. Tel: +886-4-22860799, Fax: +886-4-22860265, E-mail: byu@dragon.nchu.edu.tw
Received 2011 October 11; Revised 2012 February 06; Accepted 2011 December 10.

Abstract

Two experiments were conducted to investigate the effects of supplemental glutamine on growth performance, plasma parameters and LPS-induced immune response of weaned barrows after castration. In experiment 1, forty-eight weaned male piglets were used and fed maize and soybean meal diets supplemented with 0 (Control) or 2% L-Gln (Gln+) for 25 days. The results indicated that the Gln+ group tended to increase average daily gain compared to control in stages of days 7 to 14 and 0 to 25. The Gln+ had significantly better feed efficiency than the control group did during days 14 to 25 and 0 to 25. The plasma blood urea nitrogen and alkaline phosphatase contents of Gln+ group were higher than those of the control group on day 14 post-weaning. In experiment 2, sixteen weaned male piglets were injected with E. coli K88+ lipopolysaccharide (LPS) on day 14 post-weaning. The results showed that the Gln+ group had lower concentrations of plasma adrenocorticotrophic hormone and cortisol than the control group on day 14 pre-LPS challenge. In addition, Gln+ group had higher plasma IgG concentration than the control group for pre- or post-LPS challenged on day 14 post-weaning. In summary, dietary supplementation of Gln was able to alleviate the stressful condition and inflammation associated with castration in weaned barrows, and to improve their immunity and growth performance in the early starter stage.

INTRODUCTION

Inadequate nutrient intake after weaning often damages the intestinal villi and contributes to the poor growth of weanling pigs (Pluske et al., 1997). Amino acids (glutamine (Gln) and arginine) and polysaccharide from Chinese herbs/Chitosan are an energy source and act immunologically; the intestinal mucosa are quantitatively more important in the abrupt change of weaning (Kong et al., 2007; Guo et al., 2008; Liu et al., 2008; Yin et al., 2008; Han et al., 2009; Yao et al., 2011).

Dietary Gln is metabolized by the small intestine and essentially all Gln within the body is synthesized de novo through the action of Gln synthetase. The major sites of net Gln synthesis are lungs, adipose tissue, skeletal muscle and liver (Hall et al., 1996; Holecek, 2002). It is also the most abundant free AA found in the blood of animals and in sow milk (Wu and Knabe, 1994).

Glutamine provides energy to rapidly dividing cells, such as intestinal epithelial cells, activates lymphocytes and is regarded as a conditionally essential AA (Ardawi and Newsholme, 1983; Wu et al., 1995; Komatsu et al., 2007; Li et al., 2007). Glutamine is known to stimulate protein synthesis in intestinal epithelial cells via activating the mammalian target of the rapamycin signaling pathway (Wu et al., 2011). In addition, a key intermediate in L-glutamine catabolism, alpha-ketoglutarate, could inhibit glutamine degradation and enhance protein synthesis in intestinal porcine epithelial cells (Yao et al., 2011). The requirement of Gln increased especially under certain physiological stresses such as weaning, castration and infection, which cannot be countered by endogenous synthesis (Lacey and Wilmore, 1990; Hall et al., 1996; Newsholme, 2001). Previous reports revealed that Gln reduces the susceptibility to infections and enhances the recovery of wounds for patients (Newsholme, 2001; Wilmore, 2001). In the swine industry, castration is usually carried out at 2 to 5 weeks of age without any anesthesia or analgesia, which results in painful and great stress to the barrows. Therefore, castrated barrows normally have an impaired growth performance than the gilts during the period immediately after the castration (Bruininx et al., 2001). Alleviation of the stress associated with castration can definitely minimize the economic losses. The objective of the present study was to investigate the effects of dietary supplementation of Gln on growth performance, plasma parameters and LPS-induced immune response of weaned barrows after castration.

MATERIALS AND METHODS

Animals and management

The animal feeding protocol of this research was approved by the Animal Care and Use Committee of Kaohsiung propagation station, Livestock Research Institute, Council of Agriculture, involving 64 crossbred (Landrace×Yorkshire×Duroc) weaned at 28±2 days of age and initial body weight was approximately 7.0 kg per pig from the commercial piglet farm. All male piglets were fed with a commercial mash diet during the 3 day adaptation period. The pigs were raised in a nursery house with concrete floor. Each pen contained a self feeder and a nipple water cooler. Mash feed and water were provided for ad libitum during the entire experimental period. The average temperature during the experiment was 26.3°C. All of the piglets were castrated on day 7 post-weaning by the same technician to avoid stress due to different sill between surgeons. The castration procedure was completed within 2 min per piglet.

Experimental design

In experiment 1, 48 weaned male piglets were randomly allocated into 12 pens for two dietary treatments with supplemented with 0 (Control) or 2% L-Gln supplemented diet (Gln+). The control starter diet was maize-soybean meal diet formulated according to the NRC (1998) standard (Table 1). Pigs were weighed individually at day 0 (initial of the trial), 7, 14 and 25 (end of the trial). Feed intake was recorded by period, days 0 to 14 and days 15 to 25. Blood samples of two pigs randomly selected from each pen were taken via the vena cava puncture at day 0, 7, 14 and 25 of the experimental period. Blood samples were centrifuged at 2,000×g for 20 min at 4°C, and the plasma was separated and stored at −20°C until the analysis of the biochemical parameters. On d 14, four piglets from each treatment were randomly selected after weighing and blood collection, sacrificed and the intestinal morphology was measured as described below. In experiment 2, 16 male piglets were randomly divided into 2 groups (4 piglets/pen, 2 pens/group) after weaning. The experimental dietary treatment and castration procedure was similar to experiment 1. On d 14, all of the piglets received an intramuscular injection of E. coli K88+ lipopolysaccharide (LPS, serotype 055:B5, Sigma Chemical, St Louis, MO) at 25 μg/kg body weight. Rectal temperatures and blood samples were taken on d 7 (before castration) and d 14 (before and at 4 h after LPS challenge) post-weaning. Blood samples and plasma preparation were the same as mentioned above. The plasma was stored at −20°C for subsequent analysis of stress-related hormones (adrenocorticotrophic hormone (ACTH) and cortisol), IgG and cytokines (TNF-α, IL-1β and IL-10).

Ingredient composition and calculated values of starter dieta

Small intestinal morphology

Four 4-cm segments from the front section (one-tenth), middle section (a half) and last section (nine-tenth) of the small intestine representing duodenum, jejunum and ileum, respectively, were taken for histological measurement. These samples were first rinsed with 0.1 M phosphate buffered saline (PBS) at pH 7.2, and then fixed with 10% neutral formaldehyde. After 24 h, the samples were removed from the fixative, cut into 1 cm2 sections (two per location) and stored in fresh fixative. They were then embedded in paraffin, sectioned at 6 μm thickness and stained with hematoxylin and eosin for a light microscopy examination. The villous height (VH), crypt depth (CD), and the muscular layer thickness were measured based on 15 apparently intact villi from each section according to the procedure described by Yu et al. (1999).

Plasma biochemical parameters

The concentrations of blood urea nitrogen (BUN), creatinine, glucose, and alkaline phosphatase (ALP) activity were measured by an automatic biochemical analyzer (Automatic Analyzer, HITACHI 7150. Tokyo, Japan). The concentrations of ACTH and cortisol were determined by chemiluminescent immunoassay (Immulite Chemiluminescent immunoassay; DPC, Los Angeles, CA) (Webel et al., 1997).

Plasma IgG and cytokines

The plasma concentrations of total IgG and cytokines (TNF-α, IL-1β and IL-10) were measured by commercially available ELISA kits (R&D Systems, Inc., Minneapolis, MN) according to the manufacturer’s instructions. Plasma samples were diluted (1:100,000 for IgG; 1:1 or 1:10 for cytokines) and analyzed in duplicate.

Statistical analysis

Data were analyzed by SAS programs (1999). Unpaired Student’s t-test was used to determine differences between treatments, and p<0.05 was considered as statistically significant; p<0.1 was considered as a trend.

RESULTS

Growth performance in experiment 1

Glutamine supplementation on growth performance of weaned piglets is shown in Table 2. There were no significant differences in initial body weight between treatments; however, the body weight of Gln+ group tended to be higher than the control at d 25 post-weaning. The ADG was compared based on different stages (0 to 7, 7 to 14, 0 to 14, 14 to 25 and 0 to 25 d) of growth. The Gln+ group had trended to increase ADG compared to the control on days 7 to 14 and days 0 to 25. In general, the feed intakes in all stages did not differ between treatments. However, the Gln+ group had significantly higher G/F than the control group during the 14 to 25 day and 0 to 25 day periods.

Effect of glutamine supplementation on growth performance of weaned piglets

Small intestinal morphology in experiment 1

Table 3 presents the small intestinal morphological criteria observed on d 14. There were no differences in villous height, crypt depth and VH/CD ratio between treatments at day 14 post-weaning. However, in comparison with the control, dietary supplementation of Gln significantly increased the muscular layer thickness in the jejunum and ileum.

Effect of glutamine supplementation on the intestinal morphology of weaned piglets on day 14 post-weaninga

Plasma biochemical parameters in experiment 1

For all the plasma biochemical parameters, there was no significant difference due to weaning (d 0 and d 7 post-weaning) (Table 4). The Gln+ group showed a trend toward higher BUN and total protein concentrations on d 7, and BUN and ALP activity showed a significantly higher than control group on d 14. However, no differences in all plasma parameters between the groups were observed on d 25.

Effect of glutamine supplementation on the plasma biochemical parameters of weaned pigletsa

Plasma stress-related hormones and rectal temperature in experiment 2

The concentration of plasma stress-related hormones (ACTH and cortisol) and rectal temperature of pigs in experiment 2 are shown in Table 5. The rectal temperature and the concentrations of ACTH and cortisol were no different between the groups before castration on d 7 post-weaning. In contrast, the Gln+ barrows had significantly lower concentrations of ACTH and cortisol when compared to control barrows on d 14 post-weaning before LPS challenge. When the pigs were challenged with LPS, the plasma level of ACTH and cortisol dramatically increased, but no difference was found between treatments 4 h later. Nevertheless, the rectal temperature of the control group was significantly higher than the Gln+ group after LPS challenge.

Effect of glutamine supplementation on the plasma stress-related hormones and rectal temperature of barrows with LPS challengea

Responses of plasma IgG and cytokines after the LPS challenge in experiment 2

In experiment 2, the plasma concentrations of IgG and cytokines (TNF-α, IL-1β and IL-10) on d 14 post-weaning are shown in Table 6. There were no significant differences in plasma concentrations of IgG and cytokines between groups on d 7 (before castration, data not shown). On d 14, before the LPS challenge, the plasma IgG concentration in Gln+ group was significantly higher than that of the control; however, the plasma TNF-α in Gln+ group exhibited no significant effects compared to the control (p = 0.113). After the LPS challenge, the concentrations of IgG appeared to decline in all treatments, but the Gln+ group was significantly higher than the control. For the cytokines, although no differences were found between groups after the LPS challenge, the concentrations of TNF-α, IL-1β and IL-10 increased in the treatments compared to the pre-challenged status.

Effect of glutamine supplementation on the plasma IgG and cytokine profiles of barrows with LPS challenge on d 14 post-weaninga

DISCUSSION

The growth performance of weaned castrated piglets is usually inferior to that of the gilts during the early stage after castration, even though the castration is done as early as 3 days of age (Bruininx et al., 2001). Castration of male piglets without anesthesia or analgesia induces a strong activation of the pituitary-adrenocortical axis, so that the piglets are under acute pain and stress (Prunier et al., 2005). Under stress or inflammation, animals elevate the pro-inflammatory cytokine concentrations in plasma, leading to depressed feed intake and growth performance (Le Floc’h et al., 2004). In the current study, the Gln+ group (2% Gln supplementation) had trended to increase ADG compared to the control at days 7 to 14 and days 0 to 25. These results may suggest that dietary Gln supplementation alleviates the piglets suffering from pain and stress due to castration and improves their growth performance.

Lower than 2% Gln supplementation may not enhance the performance of piglets. Zou et al. (2006) discovered that pigs supplemented with 1% Gln had a 12% lower feed/gain ratio during the first ten days after weaning. Wu et al. (1996) showed that 0.2 to 1.0% Gln supplementation did not have any significant effects on the daily feed intake, daily gain and gain/feed during the first week post-weaning. Moreover, Lee et al. (2003) also found that the 1.5% Gln supplementation did not affect the feed intake, ADG, and gain/feed of pigs weaned on 21 days of age. However, Alverdy (1990) showed that dietary provision of 2% Gln was essential for the maintenance of gut-associated lymphoid tissues and for the secretary IgA synthesis by small intestine, thereby preventing TNFα-induced bacterial translocation from lumen of gut into the circulatory system. Dietary supplementation with 2% Gln increased the survival of mice to bacterial challenges (Adjei et al., 1994) and improved tumor-directed NK cell cytotoxic activity in rats (Shewchuk et al., 1997). Therefore, 2% Gln supplementation was chosen in the current study. The improvement growth performance of weaned piglets by Gln supplementation may be attributed to the maintenance of intestinal villous function and morphology and the increasing ability in intestinal absorption (Liu et al., 2002; Yi et al., 2005). In the present study, the villous morphology in various intestinal segments of villous height and crypt depth were not affected by Gln supplementation, but did increase the muscular layer thickness in the jejunum and ileum (Table 3). We speculated that Gln may facilitate mucosal protein synthesis in the gut and promote the growth of intestinal muscular layer (Coëffier et al., 2003; Le Bacquer et al., 2003).

In the plasma BUN level, the Gln supplemented piglets had higher plasma BUN levels than the control piglets did after 7 days and 14 days post-weaning, respectively. Zou et al. (2006) suggested that higher level of blood BUN in weaned piglets may be a consequence of deficient nutrient supply with increasing protein catabolism, causing N losses to occur. One percentage of Gln supplement diet corrected these negative effects and decreased serum BUN concentration to some extent because Gln provides precursors of several kinds of amino acids and promotes protein synthesis (Yu et al., 2002). Currently, a higher supplementary level could suggest that excess provision might lead to an imbalance of amino acids, elevated catabolism and blood BUN concentration (Holecek, 2002). The Gln requirement for weaned male piglets might be in dynamic rapidly transient status; therefore, 2% of Gln supplementation may be adequate for requirement initially and over provision in the late stages (d 25 post-weaning). The results demonstrated that increasing the Gln supplement up to 2% obtained a positive growth perform effect, but elevated the BUN and increased the risk of metabolic imbalance of amino acids.

Both Gln and glucose are major sources of energy for enterocytes of piglets (Posho et al., 1994). It suggests that Gln can exert a “sparing effect” by reducing glucose contribution to the total ATP turnover (Posho et al., 1994). However, no difference was found in plasma glucose between treatments at each stage of post-weaning. The pain and stress associated with castration peaked between 30 and 60 min after the operation, and were reflected in the plasma cortisol concentration, which returned to the baseline level within 3 h (Prunier et al., 2005). The plasma ALP activity in Gln+ pigs was significantly higher than that of control pigs after two weeks of weaning. It is possible that higher dietary Gln can increase the ALP activity of barrows and facilitate the recovery of injured tissues.

The subsequent development of cortisol or ACTH concentration in barrows remained unclear. In this study, the ACTH and cortisol were higher than those of the barrows on d 7 after castration; moreover, Gln+ group was significantly lower than the control group without LPS, challenged on the d 14 post-weaning. We speculate that more pain or stress might exist in barrows after castration, and Gln could alleviate the stressful condition. Recently, research on molecular mechanisms has revealed that dietary Gln supplementation would increase the intestinal expression (120 to 124%) of genes that are necessary for cell growth and removal of oxidants, while reducing (34 to 75%) the expression of genes that promote oxidative stress (Wang et al., 2008). The results suggested that Gln supplementation may improve the intestinal oxidative-defense capacity and result in lower plasma stress-related hormones.

The significantly higher concentration of plasma IgG in the Gln+ group pre- and post- LPS challenged at d 14 post-weaning indicated that male piglets could possess stronger anti-stress capacity to cope with the invasive organisms. Although the increase of IgG contents in weaned piglets after treatment cannot directly indicate biological significance, Yu et al. (2002) reported that dietary supplementation of 1% Gln was able to increase serum IgG level and to neutralize antibody titers of foot and mouth disease (FMD) in LPS-challenged weaned piglets. Thus, they speculated that Gln might play a role in enhancing the immune system especially in the humoral immunity of piglets. Similar results also showed that dietary 1% Gln supplementation could improve growth performance, facilitate the health of the GI tract, and increase the concentrations of sera IgG and IgA in chickens (Bartell and Batal, 2007).

On d 14 post-weaning (d 7 post-castrated), dietary Gln supplementation had somewhat modulated the expression of plasma TNF-α; the Gln+ piglets seemed to have lower levels of inflammation after weaning and castration. In the response of the LPS challenge, the significant elevation of rectal temperature indicated that the inflammatory response of pigs had been induced, and the extent of fever was milder in Gln+ group (Table 5). The production of plasma pro-inflammatory cytokines peaked 2 to 4 h after LPS challenge in piglets and returned to normal levels within 12 h (Webel et al., 1997). In the present study, the concentrations of plasma cytokines in all groups obviously increased 4 h post-challenged, but they did not statistically differ between treatments (Table 6). Similar results were reported, that dietary supplementation of Gln and nucleotides did not affect the concentration of serum TNF-α in piglets challenged with LPS (Yu et al., 2002). It was speculated that under such a high dose of LPS challenge, the cytokines were acutely produced by macrophages and monocytes of piglets to modulate the inflammation. In short, dietary supplementation of Gln might not powerfully affect the plasma cytokine profiles during the short period of LPS challenge in our current study even if Gln could inhibit over-expression of pro-inflammatory genes in rats (Fillmann et al., 2007). Furthermore, the effect of Gln on the regulation of systemic inflammation suggested that it could be applied potentially to the inflammatory diseases (Singleton and Wischmeyer, 2008).

CONCLUSIONS

Dietary supplementation of 2% Gln was able to alleviate the stressful condition and inflammation associated with castration in weaned barrows, and to improve their immunity and growth performance in the early starter stage.

ACKNOWLEDGEMENTS

The authors would like to thank the Council of Agriculture of the Republic of China for supporting the research and the Ajinomoto Co. Inc. (Tokyo, Japan) for their generous gift of L-glutamine.

References

Adjei AA, Matsumoto Y, Oku T, Hiroi Y, Yamamoto S. 1994;Dietary arginine and glutamine combination improves survival in septic mice. Nutr Res 14:1591–1599.
Alverdy JC. 1990;Glutamine supplemented diets on immunology of the gut. J Parenter Enter Nutr 14:109S–113S.
Ardawi MSM, Newsholme EA. 1983;Glutamine metabolism in lymphocytes of the rat. Biochem J 212:835–842.
Bartell SM, Batal AB. 2007;The effect of supplemental glutamine on growth performance, development of the gastrointestinal tract, and humoral immune response of broilers. Poult Sci 86:1940–1947.
Bruininx EM, van der Peet-Schwering CM, Schrama JW, Vereijken PF, Vesseur PC, Everts H, den Hartog LA, Beynen AC. 2001;Individually measured feed intake characteristics and growth performance of group-housed weanling pigs: Effects of sex, initial body weight, and body weight distribution within groups. J Anim Sci 79:301–308.
Coëffier M, Claeyssens S, Hecketsweiler B, Lavoinne A, Ducrotte P, Dechelotte P. 2003;Enteral glutamine stimulates protein synthesis and decreases ubiquitin mRNA level in human gut mucosa. Am J Physiol Gastrointest Liver Physiol 285:G266–273.
Fillmann H, Kretzmann NA, San-Miguel B, Llesuy S, Marroni N, Gonzalez-Gallego J, Tunon MJ. 2007;Glutamine inhibits over-expression of pro-inflammatory genes and down-regulates the nuclear factor kappaB pathway in an experimental model of colitis in the rat. Toxicology 236:217–226.
Guo GL, Liu YL, Fan W, Han J, Hou YQ, Yin YL, Zhu HL, Ding BY, Shi JX, Lu J, Wang HR, Chao J, Qu YH. 2008;Effects of Achyranthes Bidentata polysaccharide on growth performance, immunological, adrenal, and somatotropic responses of weaned pigs challenged with escherichia coli lipopolysaccharide. Asian-Aust J Anim Sci 21:1189–1195.
Hall JC, Hell K, McCaulet R. 1996;Glutamine. Br J Surg 83:305–321.
Han J, Liu YL, Fan W, Chao J, Hou YQ, Yin YL, Zhu HL, Meng GQ, Che ZQ. 2008;Dietary L-arginine supplementation alleviates immunosuppression induced by cyclophosphamide in weaned pigs. Amino Acids 37:643–651.
Holecek M. 2002;Relation between glutamine, branched-chain amino acids, and protein metabolism. Nutrition 18:130–133.
Komatsu W, Mawatari K, Miura Y, Yagasaki K. 2007;Restoration by dietary glutamine of reduced tumor necrosis factor production in a low-protein-diet-fed rat model. Biosci Biotechnol Biochem 71:352–357.
Kong XF, Zhang YZ, Yin YL, Wu GY, Zhou HJ, Tan ZL, Yang F, Bo MJ, Huang RL, Li TJ, Geng MM. 2009;Chinese yam polysaccharide enhances growth performance and cellular immune response in weanling rats. J Sci Food Agric 89:2039–2044.
Lacey JM, Wilmore DW. 1990;Is glutamine a conditionally essential amino acid? Nutr Rev 48:297–309.
Le Bacquer OL, Laboisse C, Darmaun D. 2003;Glutamine preserves protein synthesis and paracellular permeability in Caco-2 cells submitted to “luminal fasting”. Am J Physiol Gastrointest Liver Physiol 285:G128–136.
Le Floc’h NL, Melchior D, Obled C. 2004;Modifications of protein and amino acid metabolism during inflammation and immune system activation. Livest Prod Sci 87:37–45.
Lee DN, Cheng YH, Wu FY, Sato H, Shinzato I, Cheng SP, Yen HT. 2003;Effect of dietary glutamine supplement on performance and intestinal morphology of weaned pigs. Asian-Aust J Anim Sci 16:1770–1776.
Li P, Yin YL, Li D, Kim SW, Wu G. 2007;Amino acids and immune function. Br J Nutr 98:237–252.
Liu T, Peng J, Xiong Y, Zhou S, Cheng X. 2002;Effects of dietary glutamine and glutamate supplementation on small intestinal structure, active absorption and DNA, RNA concentrations in skeletal muscle tissue of weaned piglets during d 28 to 42 of age. Asian-Aust J Anim Sci 15:238–242.
Liu YL, Huang JJ, Hou YQ, Zhu HL, Zhao SJ, Ding BY, Yin YL, Yi GF, Shi JX, Fan W. 2008;Dietary arginine supplementation alleviates intestinal mucosal disruption induced by Escherichia coli lipopolysaccharide in weaned pigs. Br J Nutr 100:552–560.
National Research Council. 1998. Nutrient requirements of swine 10th Rev Edth ed. National Academy Press. Washington, DC, USA:
Newsholme P. 2001;Why is L-glutamine metabolism important to cells of the immune system in health, postinjury, surgery or infection. J Nutr 131:2515S–2522S.
Pluske JR, Hampson DJ, Williams IH. 1997;Factors influencing the structure and function of the small intestine in the weaned pig: a view. Livest Prod Sci 51:215–236.
Posho L, Darcy-Vrillon B, Blachier F, Duee P. 1994;The contribution of glucose and glutamine to energy metabolism in newborn pig enterocytes. J Nutr Biochem 5:284–290.
Prunier A, Mounier AM, Hay M. 2005;Effects of castration, tooth resection, or tail docking on plasma metabolites and stress hormones in young pigs. J Anim Sci 83:216–222.
SAS. 1999. SAS/STAT user’s guide, Release 6.11 Ed SAS Inst Inc. Cary, NC, USA:
Shewchuk LD, Baracos VE, Field CJ. 1997;Dietary L-glutamine supplementation reduces growth of the Morris hepatoma 7777 in exercise-trained and sedentary rats. J Nutr 127:158–166.
Singleton KD, Wischmeyer PE. 2008;Glutamine attenuates inflammation and NF-κB activation via Cullin-1 deneddylation. Biochem Biophys Res Commun 373:445–449.
Webel DM, Finck BN, Baker DH, Johnson RW. 1997;Time course of increased plasma cytokines, cortisol, and urea nitrogen in pigs following intraperitoneal injection of lipopolysaccharide. J Anim Sci 75:1514–1520.
Wilmore DW. 2001;The effect of glutamine supplementation in patients following elective surgery and accidental injury. J Nutr 131:2543S–2549S.
Wu G, Knabe DA. 1994;Free and protein-bound amino acids in sow’s colostrum and milk. J Nutr 124:415–424.
Wu G, Knabe DA, Yan W, Flynn NE. 1995;Glutamine and glucose metabolism in enterocytes of the neonatal pig. Am J Physiol 268:R334–R342.
Wu G, Meier SA, Knabe DA. 1996;Dietary glutamine supplementation prevents jejunal atrophy in weaned pigs. J Nutr 126:2578–2584.
Wu G, Bazer FW, Johnson GA. 2011;Important roles for L-glutamine in swine nutrition and production. J Anim Sci 89:2017–2030.
Yao K, Yin Y, Li X, Xi P, Wang J, Lei J, Hou Y, Wu G. 2011;Alpha-ketoglutarate inhibits glutamine degradation and enhances protein synthesis in intestinal porcine epithelial cells. Amino Acid in press. 10.1007/s00726-011-1060-6.
Yi GF, Carroll JA, Allee GL, Gaines AM, Kendall DC, Usry JL, Toride Y, Izuru S. 2005;Effect of glutamine and spray-dried plasma on growth performance, small intestinal morphology, and immune responses of Escherichia coli K88+-challenged weaned pigs. J Anim Sci 83:634–643.
Yin YL, Tang ZR, Sun ZH, Liu ZQ, Li TJ, Huang RL, Ruan Z, Deng ZY, Gao B, Chen LX, Wu GY, Kim SW. 2008;Effect of galacto-mannan-oligosaccharides or chitosan supplementation on cytoimmunity and humoral immunity response in early-weaned piglets. Asian-Aust J Anim Sci 21:723–731.
Yu B, Tsen HY, Chiou PWS. 1999;Caecal culture enhance performance and prevents Salmonella infection in broilers. J Appl Poult Res 8:195–204.
Yu IT, Wu JF, Yang PC, Liu CY, Lee DN, Yen HT. 2002;Roles of glutamine and nucleotides in combination in growth, immune responses and FMD antibody titres of weaned pigs. Anim Sci 75:379–385.
Zou XT, Zheng GH, Fang XJ, Jiang JF. 2006;Effects of glutamine on growth performance of weanling piglets. Czech J Anim Sci 51:444–448.

Article information Continued

Table 1

Ingredient composition and calculated values of starter dieta

Ingredient (%) Starter diet
Maize, dent yellow 49.05
Soybean meal, solvent, 44% of CP 23.70
Dried skim milk 16.00
Whey 5.00
Soybean oil 1.00
Dicalcium phosphate 1.60
Limestone, pulverized 0.80
Salt 0.50
Vitamin premixb 0.10
Mineral premixc 0.15
Choline chloride, 50% 0.10
Maize starch 2.00
Calculated values (%)
 Crude protein 20.30
 Digestible energy (kcal) 3,450.00
 Calcium 0.75
 Total phosphorus 0.65
 Lysine 1.17
a

Gln+treatment diet used 2% of glutamine to replace maize.

b

Supplied the following vitamins per kg of diet: Vitamin A, 6,000 IU; vitamin D3, 800 IU; vitamin E, 20 mg; vitamin K3, 4 mg; vitamin B2, 4 mg; vitamin B6, 1 mg; vitamin B12, 0.02 mg; Niacin, 30 mg; calcium pantothenate, 16 mg; folic acid, 0.6 mg; biotin, 0.01 mg; choline chloride, 50 mg.

c

Supplied the following minerals per kg of diet: Fe, 140 mg; Cu, 7 mg; Mn, 20 mg; Zn, 120 mg; I, 0.45 mg.

Table 2

Effect of glutamine supplementation on growth performance of weaned piglets

Item Control Gln+ SEMc p value
Mean body weight (kg)
 0 da 8.18 8.13 0.21 0.878
 7 da 9.16 9.11 0.25 0.893
 14 da 10.96 11.34 0.34 0.412
 25 db 15.02 16.27 0.51 0.100
Mean daily gain (kg)
 0–7 da 0.14 0.14 0.02 0.993
 7–14 da,* 0.27 0.32 0.02 0.061
 0–14da 0.20 0.23 0.01 0.169
 14–25b 0.41 0.44 0.03 0.287
 0–25b,* 0.29 0.33 0.02 0.097
Daily feed intake (kg)
 0–14 0.37 0.38 0.02 0.604
 14–25 0.78 0.77 0.05 0.955
 0–25 0.54 0.54 0.03 0.867
Feed efficiency (G/F)
 0–14* 0.54 0.63 0.03 0.099
 14–25** 0.52 0.58 0.02 0.022
 0–25** 0.53 0.61 0.02 0.033
a,b

Mean value is obtained from 24 and 14 piglets, respectively.

c

Standard error of means.

*

Means in the treatments are numerically different (p<0.1).

**

Means in the treatments are different significantly (p<0.05).

Table 3

Effect of glutamine supplementation on the intestinal morphology of weaned piglets on day 14 post-weaninga

Item Control Gln+ SEMb p value
Duodenum
 Villous height (μm) 377 450 40 0.248
 Crypt depth (μm) 329 343 34 0.783
 VH/CD value 1.22 1.42 0.27 0.621
 Muscular thickness (μm) 444 460 57 0.854
Jejunum
 Villous height (μm) 394 445 32 0.206
 Crypt depth (μm) 242 312 29 0.119
 VH/CD value 1.73 1.48 0.19 0.409
 Muscular thickness (μm)* 245 336 25 0.046
Ileum
 Villous height (μm) 319 358 19 0.155
 Crypt depth (μm) 209 216 14 0.757
 VH/CD value 1.59 1.75 0.17 0.536
 Muscular thickness (μm)* 451 736 67 0.024
*

Means in the treatments are different significantly (p<0.05).

a

Values of intestinal morphology assay are means of 12 pigs per treatment.

b

Standard error of means.

Table 4

Effect of glutamine supplementation on the plasma biochemical parameters of weaned pigletsa

Item Control Gln+ SEMb p value
Day 0 post-weaning
 Creatinine (mg/dl) 1.00 1.07 0.04 0.220
 BUN (mg/dl) 5.5 5.9 0.5 0.579
 Total protein (g/dl) 4.9 5.1 0.1 0.155
 Glucose (mg/dl) 132.0 131.0 4.0 0.963
 Alkinine phosphatase (IU/L) 9.8 12.1 2.1 0.439
Day 7 post-weaning (pre-castration)
 Creatinine (mg/dl) 0.93 0.89 0.03 0.413
 BUN (mg/dl)* 12.5 14.9 0.9 0.064
 Total protein (g/dl)* 4.8 5.1 0.1 0.094
 Glucose (mg/dl) 112.0 115.0 3.6 0.539
 Alkinine phosphatase (IU/L) 5.9 6.2 1.2 0.840
Day 14 post-weaning
 Creatinine (mg/dl) 0.79 0.80 0.04 0.892
 BUN (mg/dl)** 10.0 13.0 0.6 0.003
 Total protein (g/dl) 4.8 4.9 0.1 0.431
 Glucose (mg/dl) 117.0 110.0 3.3 0.206
 Alkinine phosphatase (IU/L)** 4.7 14.6 1.4 0.001
Day 25 post-weaning
 Creatinine (mg/dl) 0.77 0.69 0.03 0.126
 BUN (mg/dl) 10.2 9.7 0.6 0.589
 Total protein (g/dl) 5.2 5.2 0.2 0.926
 Glucose (mg/dl) 115.0 114.0 3.1 0.928
 Alkinine phosphatase (IU/L) 8.2 6.4 1.1 0.234
*

Means in the treatments are numerically different (p<0.1).

**

Means in the treatments are different significantly (p<0.05).

a

Values of plasma biochemical parameters are means of 12 pigs per treatment.

b

Standard error of means.

Table 5

Effect of glutamine supplementation on the plasma stress-related hormones and rectal temperature of barrows with LPS challengea

Item Control Gln+ SEMb p value
Day 7 post-weaning (Pre-castration)
 Rectal temperature (°C) 40.0 40.1 0.1 0.659
 ACTH (pg/ml) 27.1 24.7 5.3 0.642
 Cortisol (μg/dl) 2.9 2.6 0.4 0.727
Day 14 post-weaning
 Pre-LPS challenge
  Rectal temperature (°C) 40.0 39.9 0.1 0.489
  ACTH (pg/ml)* 81.3 44.1 12.1 0.044
  Cortisol (μg/dl)* 6.1 3.2 0.6 0.003
 Post-LPS challenge
  Rectal temperature (°C)* 41.4 41.0 0.1 0.025
  ACTH (pg/ml) 142.9 134.2 33.1 0.854
  Cortisol (μg/dl) 8.5 10.3 1.4 0.355
*

Means in the treatments are different significantly (p<0.05).

a

Values of plasma stress-related hormones and rectal temperature are means of 8 pigs per treatment.

b

Standard error of means.

Table 6

Effect of glutamine supplementation on the plasma IgG and cytokine profiles of barrows with LPS challenge on d 14 post-weaninga

Item Control Gln+ SEMb p value
Day 14 post-weaning (Pre-LPS)
 IgG (mg/ml)* 13.1 20.5 1.3 0.002
 TNF-α (pg/ml) 983 668 108 0.113
 IL-1β (pg/ml) 527 415 85 0.524
 IL-10 (pg/ml) 1,059 950 82 0.453
Day 14 post-weaning (Post-LPS)
 IgG (mg/ml)* 11.7 15.6 1.0 0.011
 TNF-α (pg/ml) 1,674 1,317 177 0.332
 IL-1β (pg/ml) 751 607 121 0.536
 IL-10 (pg/ml) 1,704 1,431 172 0.415
*

Means in the treatments are different significantly (p<0.05).

a

Values of plasma IgG and cytokine profiles are means of 8 pigs per treatment.

b

Standard error of means.