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Addition of arginine and leucine to low or normal protein diets: performance, carcass characteristics and intramuscular fat of finishing pigs

Published: October 5, 2017
By: Núria Tous 1, Rosil Lizardo 1, Borja Vilà 1, Marina Gispert 2, Maria Font-i-Furnols 2, and Enric Esteve-Garcia 1. / 1 IRTA, Animal Nutrition and Health Program, Mas de Bover, Ctra. de Reus-El Morell Km 4.5. 43120 Constantí, Tarragona, Spain; 2 IRTA, Product Quality Program, Finca Camps i Armet. 17121 Monells, Girona, Spain.
Summary

The effect of dietary crude protein (CP) reduction, supplementation with arginine or leucine on intramuscular fat (IMF) content was evaluated in (Landrace × Duroc) × Pietrain pigs. One-hundred and eight barrows (67 ± 4 kg) were assigned to six diets (n=6 pens of 3 pigs each): four normal CP diets containing 16% CP from 60 to 90 kg and 13% CP from 90 to 115 kg live weight (normal protein; normal protein high Arg, normal protein high Leu or normal protein high Arg and Leu) and two low CP diets containing 14% CP from 60 to 90 kg and 11.8% CP from 90 to 115 kg live weight (with or without supplementation of both amino acids). The high Leu and Arg diets were supplemented to obtain ratios of standard ileal digestible Leu/Lys and Arg/Lys of 4 and 2, respectively. While feed to gain ratio tended to increase (p<0.05), final weight (p<0.01), average daily feed intake (ADFI) (p<0.05) and average daily gain (ADG) (p<0.01) were reduced in animals fed low-protein diets supplemented with Arg and Leu compared to the ones fed low-protein diet unsupplemented. Marbling and IMF content in loin were reduced when Arg was supplemented (p<0.05) in normal protein diets. Supplementing these diets with Arg also reduced belly weight (p<0.01) and increased lean meat percentage (p<0.05). Contrary to the initial hypothesis, reduction of CP or dietary supplementation with Leu had no effect on IMF content and supplementation with Arg reduced it.

Additional key words: amino acid; branched chain amino acids antagonism; meat quality; loin depth; marbling; subcutaneous fat.

Abbreviations used: ADFI (average daily feed intake); ADG (average daily gain); Arg (arginine); BCAA (branched chain amino acids); CP (crude protein); FGR (feed to gain ratio); IMF (intramuscular fat); Leu (leucine); LM (Longissimus muscle); LP (low protein); LPAL (low protein plus arginine and leucine); NIT (near infrared transmittance); NP (normal crude protein); NPA (normal crude protein plus arginine); NPAL (normal crude protein plus arginine and leucine); NPL (normal crude protein plus leucine); SM (Semimembranosus muscle).

Authors’ contributions: Conceived and designed the experiments: NT, RL, BV and EEG. Performed the experiments and contributed reagents/materials/analysis tools: NT, MG and MFF. Analyzed the data: NT and EEG. Wrote the paper: NT, RL, BV, MG, MFF and EEG.

Citation: Tous, N.; Lizardo, R.; Vilà, B.; Gispert, M.; Font-i-Furnols, M.; Esteve-Garcia, E. (2016). Addition of arginine and leucine to low or normal protein diets: performance, carcass characteristics and intramuscular fat of finishing pigs. Spanish Journal of Agricultural Research, Volume 14, Issue 4, e0605. http://dx.doi.org/10.5424/sjar/2016144-9351.

Received: 25 Jan 2016. Accepted: 28 Sep 2016.

Introduction
One of the characteristics that influence the quality of meat as perceived by the consumer is the amount of intramuscular fat (IMF), which is located within the structure of muscle. In terms of taste, IMF is well correlated with pork acceptability. The threshold level of IMF needed for optimal eating quality of pork proposed is between 2.2 and 3.4% (Font-i-Furnols et al., 2012). In the last decades, the trend in pig production has been to increase the carcass lean content, reduce carcass fat, and the end result is that IMF content has decreased. Some studies indicate that for some modern genotypes IMF can be as low as 1% (Channon et al., 2001). One of the challenges for nutritionists is to increase the level of IMF without increasing backfat or impairing the animal growth.
It has been reported that supplementing pig diets with leucine (Leu) (Hyun et al., 2003, 2007) or arginine (Arg) could increase IMF (Tan et al., 2009; Ma et al., 2010). Leucine as a branched-chain amino acid (BCAA) is essential and therefore must be continuously available for protein synthesis. Although most of articles evaluating the excess dietary Leu in pigs have concentrated on the interaction of Leu with the other BCAA (valine and isoleucine) and its effects on growth performance (Morales et al., 2015), Leu may also promote global protein synthesis, insulin release and inhibit protein degradation (Harris et al., 2004). Leucine as a keto-acid may also further undergo oxidative decarboxylation to produce acyl-CoA derivatives and enter tricarboxylic acid cycle, promoting fatty acid synthesis. Therefore, the proper Leu concentration is critically important for maintaining body protein levels beyond simply the need of this essential amino acid for protein synthesis (Harris et al., 2004). Arginine is a semi-essential amino acid, some studies have demonstrated that dietary Arg may stimulate protein synthesis in young (Yao et al., 2008) and in adult pigs and at the same time reduce fat deposition in fattening pigs (He et al., 2009). These effects may be due to the role of Arg in regulating the metabolism of energy substrates (fatty acids, glucose, amino acids) partly through production of nitric oxide (NO). Nitric oxide increases fatty acid oxidation, decreases triacylglycerides synthesis and increases the basal lipolysis (Jobgen et al., 2006). However, Tan et al. (2011) suggested that dietary L-arginine supplementation differentially regulates expression of lipid-metabolic genes in porcine adipose tissue and skeletal muscle, favouring lipogenesis in muscle but lipolysis in adipose tissue. Therefore, it can be hypothesised that increasing the level of Arg and Leu in pig diets may increase the IMF content and consequently the acceptability of meat for consumers. However, data is not consistent throughout the literature. Hyun et al. (2007) only found an increase of IMF in the diets with a low level of Lys (0.5%) but no effect was observed when Lys was added at 0.7%. Madeira et al. (2014) did not find an alteration on IMF content in (Duroc × Pietrain) × (Large White × Landrace) fed reduced protein supplemented with Leu. Go et al. (2012) and Madeira et al. (2014, 2015) did not find effect of Arg on IMF.
Furthermore, in a previous study, using Duroc × Landrace pigs, reduction of the level of dietary protein maintaining the levels of Lys as the ones in the control diet or reduction of dietary Lys maintaining the levels of protein as the ones in the control diet resulted in an increase of IMF, while when both parameters protein and Lys were reduced IMF was not affected (Tous et al., 2014). Wood et al. (2004) found that a low protein diet slowed growth and increased neutral lipid fatty acid concentrations in Longissimus (LM) and Psoas muscles in the two modern breeds compared with two traditional genotypes. Hence, there are genotypic differences regarding the effects of dietary protein level on IMF.
The first objective of the current study was to evaluate whether the addition of Arg or Leu to low or normal protein diets would increase the IMF content on LM of pigs. The second objective was to determine if the reduction of dietary crude protein (CP) would increase IMF without negatively affecting growth performance and other carcass traits in a leaner genotype ([Landrace × Duroc] × Pietrain) than the one used in our previous study (Duroc × Landrace crossbreed; Tous et al., 2014).
 
Material and methods
The experiment was conducted in compliance with the Spanish guidelines (BOE, 2007) for human care and use of animals in research and the protocol was approved by the Ethical Animal Committee of Institut de Recerca i Tecnologia Agroalimentàries (IRTA, Spain).
 
Animals and diets
One hundred and eight 67 ± 4 kg live weight (Landrace × Duroc) × Pietrain barrows chosen from a larger group were blocked by weight balancing the effect of litter within the block, and were housed in the same farm in adjacent pens with 3 pigs per pen (6 pens per treatment). Pigs within blocks were randomly assigned to one of the six dietary treatments up to slaughter at approximately 115 ± 7 kg live weight (56 or 70 days). The six treatments differed in the CP, Arg and Leu content: normal CP (NP), normal CP diet + Arg (NPA), normal CP diet + Leu (NPL), normal CP diet + Arg + Leu (NPAL), low CP diet (LP), low CP + Arg + Leu (LPAL). The high Leu and Arg diets were supplemented to obtain ratios of standardized ileal digestible Leu/Lys and Arg/Lys of 4 and 2, respectively. Glutamic acid, a non-essential amino acid, replaced the additions of the different amino acids to maintain constant levels of nitrogen and protein in the diets (Table 1). The level of dietary protein in the normal protein diets was in accordance to requirements (NRC, 1998). Low-protein diets were first formulated based on the normal protein diet (with the supplementation of both Arg and Leu) but reducing level of protein as much as possible maintaining Lys and the minimum requirements for the essential amino acid to Lys ratios although the supplementation with Arg and Leu in LPAL diet. In order to obtain isonitrogenous diets, the inclusion of amino acids (Arg, Leu and glutamic acid) in the diets was adjusted. Diets were based on maize and soybean meal 44%. Net energy was calculated according to Sauvant et al. (2004). All diets had a calculated net energy content of 10.0 MJ/kg (Table 2). Lglutamic acid (Ajinomoto, Mesnil-Saint-Nicaise, France), L-leucine (Ajinomoto, Limeira-SP, Brazil) and L-arginine (Ajinomoto, Morodomi-Cho Saga, Japan) had a purity greater than 98.5%. During the experimental period, pigs received the diets for ad libitum consumption and had free access to water.
Addition of arginine and leucine to low or normal protein diets: performance, carcass characteristics and intramuscular fat of finishing pigs - Image 1
Pigs were selected on two different days (50 animals day 56: NP=10; NPA=9; NPL=10; NPAL=7; LP=12; LPAL=2; and 58 animals day 70: NP=8; NPA=9; NPL=8; NPAL=11; LP=6; LPAL=16) in order that all animals had similar final body weight 48 h before slaughter (115 ± 7 kg live weight). It was not possible to select the same number of pigs per treatment for each day of slaughter because pigs fed the LPAL treatment grew more slowly. Individual body weights were determined at the beginning of the trial (67 ± 4 kg live weight), on day 21 (88 ± 3 kg live weight), and before the first shipment of animals to the slaughterhouse (day 56; 107 ± 7 kg live weight). The average daily feed intake, average daily gain and feed efficiency were calculated until the day before the first shipment of the pigs to the abattoir (day 56). However, pigs that did not reach the weight the first day were fed with the same previous diet until they reached slaughter weight.
 
Slaughter conditions
Pigs were transported to the IRTA experimental abattoir (2 h) on 2 different days (day 56 or 70) and they underwent approximately 16 h of fasting time before slaughter, with free access to water. Pigs were weighed and slaughtered minimizing the stress using standard ante-mortem procedures and stunned with 85% CO2 for 120 s using CO2 Dip Lift (Butina, Alps, Copenhagen, Denmark). Once carcasses were eviscerated, they were split longitudinally and weighed within 45 min (blooming time). Perirenal fat and liver were also separately weighed.
Addition of arginine and leucine to low or normal protein diets: performance, carcass characteristics and intramuscular fat of finishing pigs - Image 2
Carcass quality measurements
Fat and muscle thickness were measured with the Fat-O-Meat’er probe (Carometec A/S, Herlev, Denmark) between the third and the fourth last ribs at 6 cm off the midline. From these measurements, lean meat percentage was calculated using the Spanish official equation (Lean meat (%) = 66.91 – 0.895 * backfat thickness + 0.144 * muscle depth; Font-i-Furnols & Gispert, 2009). In addition, backfat thickness at the last rib at 6 cm off the midline and between the third and the fourth lumbar vertebrae at 8 cm off the midline were determined with the same probe. The minimum fat thickness over the Gluteus medius muscle and fat thickness in the cranial position of the first lumbar vertebrae and in the shoulder at the level of first rib were measured with a ruler over the carcass midline.
After carcass refrigeration at 3 °C for 24 h, carcasses were weighed. Carcass length was measured as the distance between the recess of the first rib and the anterior edge of the symphysis pubic and loin length as the distance from the atlas bone to the first lumbar vertebrae. Then, the left side of each carcass was cut following a simplified European reference method (Walstra & Merkus, 1995). The primary cuts obtained were: ham (included hind shank and hind foot), loin, belly (included the ventral part of the belly and jowl), shoulder (with front shank, front foot and neck), tenderloin and head (with cheek). Each cut was weighed and their proportion with respect to cold carcass weight was calculated. Furthermore, the Semimembranosus muscle (SM) was separated from the ham and the LM and subcutaneous fat (with skin) from the loin, and their respective weights were recorded. The LM was stored at 4 °C for 24 h. Then, the LM samples were ground using a food processor (Robot-Coupe Blixer 3, Montceau les Mines, France), and a 90 g subsample was used to determine the IMF content using the Infratec 1265 Meat Analyzer (Foss Tecator AB, Hoganas, Sweden) equipment, based on near infrared transmittance (NIT) (Gispert et al., 1997, 2010).
Muscle pH was measured in the left carcass side using a Crison portable meter (Crison, Barcelona, Spain) equipped with a Xerolyte electrode in the LM at the last rib level and in SM muscles at 45 min (pH45) and at 24 h (pHu) postmortem. Electrical conductivity was measured in the carcass using a probe (Pork Quality Meter-Kombi, Aichach, Germany) also at the last rib level in the LM and SM muscles at 24 h postmortem. Instrumental colour (CIE, 1976) was measured at 24 h postmortem at the level of the last rib on a cross section of the LM after 15 min of blooming time with a colorimeter (using D65 as illuminant and standard observer of 10°; CR-400 Minolta Co., Osaka, Japan), and luminosity (L*), redness (a*) and yellowness (b*) were recorded. Subjective marbling (NPPC, 2000) measurements in LM samples were obtained from the cut lean surface of each chop on a scale of 1 to 5 (1 being low and 5 being high). Drip loss was obtained from the LM according the methodology described by Rasmussen & Andersson (1996).
 
Statistical methods
A preliminary statistical evaluation was performed using GLM procedure of SAS (SAS, Inst. Inc., Cary, NC, USA) with initial weight as covariable for growth performance. Final weight was also included as covariable for some backfat measurements (backfat thickness on the last rib, minimum fat thickness over the Gluteus medius muscle and lean meat percentage). Pen was considered the experimental unit for all variables (6 replicates per treatment). The LPAL treatment presented a large standard deviation compared to the other treatments for all variables measured, indicating that variance was not homogeneous for all treatments. Consequently, it was eliminated from the overall data set. A Student t-test for not homogeneous variances was conducted to compare the LP and LPAL treatments. For the five remaining dietary treatments (NP, NPA, NPL, NPAL, and LP), the different variables studied were analyzed by two way ANOVA in a 2 by 2 plus one design (comparison of low protein versus normal protein diet and the effect of supplementation of Arg and Leu in normal protein diets as a 2 × 2 factorial design) with 6 blocks corresponding to body weight and location within the house. Differences among treatment means were investigated with a set of contrasts in four different comparisons: NP + NPAL vs. NPA + NPL (evaluating interaction between Arg and Leu: Int), NPA + NPAL vs. NP + NPL (evaluating the effect of supplementing arginine: Arg), NPL + NPAL vs. NP + NPA (evaluating the effect of supplementing leucine: Leu) and NP vs. LP (evaluating the effect of reducing dietary CP: Prot). Differences were considered significant at p<0.05 and p<0.1 was considered as trend.
 
Results
Growth performance
A trend in the interaction between dietary Arg and Leu was observed in animals fed normal protein diets for final weight and average daily gain (ADG) (p=0.083 and p=0.072, respectively; Table 3). Animals fed normal protein diets supplemented with Arg or Leu tended to have a greater final weight and ADG compared to animals fed normal protein diet or normal protein diet supplemented with both amino acids Arg and Leu. When both Arg and Leu were added in excess in normal protein diet final body weight and ADG were similar to normal protein diet without amino acid supplementation.
The reduction of dietary protein did not affect growth performance compared to normal protein diets. However, the addition of both amino acids Arg and Leu in the low protein diet reduced final weight (p=0.006), average daily feed intake (ADFI) (p=0.020) and ADG (p=0.001) and reduced gain to feed ratio (p=0.040) compared to low protein diet.
 
Carcass
characteristics A trend in the interaction between Arg and Leu was observed in muscle depth between the third and the fourth last ribs (p=0.070; Table 4), as it tended to be increased in normal protein diets supplemented with Arg or Leu with respect to the normal protein diet but it was not changed in normal protein diet supplemented with both Arg and Leu. The other variables measured were not affected by the interaction between Arg and Leu. A trend to reduce backfat thickness (p=0.059) between the third and the fourth last ribs and an increase of lean meat percentage (p=0.046) was observed by effect of Arg supplementation compared to normal protein diet and the normal protein diet supplemented with Leu. The supplementation of diets with Leu (NP and NPA vs. NPL and NPAL) reduced the length of the loin (p=0.041). Reduction of dietary protein level (NP vs. LP) tended to increase carcass yield (p=0.089). Animals fed the low protein diets supplemented with Arg and Leu had a lower body weight at the end of the trial, carcass length (p=0.018 and p=0.006, respectively) and tended to reduce carcass yield (p=0.071) compared to the ones fed low protein diet (LP vs. LPAL). Considering the LSMEANS adjusted for the covariable body weight (data not shown in Table 4), backfat thickness tended to be increased on the last rib and on the fist lumbar vertebrae (14.3 vs 16.9 p=0.096 and 19.6 vs 22.7 p=0.061, respectively) and muscle depth was decreased (p=0.011) and the lean meat percentage tended to be reduced (60.2 vs 57.7 p=0.072) by effect of supplementing diets with a reduced level of protein with Arg and Leu compared to animals fed the low protein diet.
Addition of arginine and leucine to low or normal protein diets: performance, carcass characteristics and intramuscular fat of finishing pigs - Image 3
Addition of arginine and leucine to low or normal protein diets: performance, carcass characteristics and intramuscular fat of finishing pigs - Image 4
Meat quality traits Meat quality traits were not affected by the interaction between dietary Arg and Leu levels (Table 5). Addition of Arg (NPA and NPAL) produced a reduction of IMF content (p=0.033), marbling (p=0.041), meat lightness (L*, p=0.028) and yellowness (b*, p=0.045) with respect to the normal protein diet or the normal protein diet supplemented with Leu (NP and NPL). Electrical conductivity and drip loss in LM increased (p=0.035 and p=0.013, respectively) and redness tended to increase (a*, p=0.051) in animals fed normal protein diets supplemented with Leu (NP and NPA vs. NPL and NPAL). The IMF content or marbling was not affected by the supplementation of normal protein diet with Leu or the reduction of dietary protein. Lightness (L*, p=0.032) and yellowness (b*, p=0.045) were reduced in meat from animals fed the low protein diet (NP vs. LP). A reduction of pH at 45 min (p=0.044) in LM, a trend to reduce pH at 45 min in SM (p=0.058), a pH reduction at 24 h in SM (p=0.011), an increase of meat redness (a*, p=0.022) and a trend to increase conductivity in LM (p=0.097) was observed in low protein diets supplemented with both Arg and Leu compared to the unsupplemented low protein diets. Intramuscular fat content and marbling were not affected by supplementing low protein diets with Arg and Leu.
 
Weight of carcass cuts, liver and perirenal fat
A trend in the interaction between Leu and Arg (p=0.092; Table 6) was found for liver weight which tended to be reduced in normal protein diets supplemented with Arg or Leu (NPA or NPL) but no difference was observed when both amino acids Arg and Leu were added to normal protein diet (NPAL) compared to those of NP diet. Supplementation of normal protein diets with Arg (NPA and NPAL vs. NP and NPL) tended to increase shoulder weight (p=0.095) and significantly reduced (p=0.003) the belly weight (cut with a greater fat content). The weight of the different carcass cuts was not affected by the dietary supplementation of Leu. Reduction of dietary CP (LP vs. NP) tended to reduce belly weight (p=0.086) and tended to increase tenderloin weight (p=0.052). The weight of belly was also significantly reduced in animals fed low protein diets supplemented with Arg and Leu (p=0.039) compared to the ones fed unsupplemented diets.
 
Discussion
The current study was performed to evaluate if the reduction of dietary protein level below requirements (NRC, 1998) has the same effect on IMF than in the previous study (Tous et al., 2014) with a different crossbreed (Duroc × Landrace vs. Duroc × Landrace sows crossed with a Pietrain boar) in which IMF was expected to be lower. Therefore, the control diet had a protein level according to NRC's (1998) requirements (16% during the growing period and 13% during the fattening period) and the low protein diet had a level below these requirements (14% during the growing period and 11.8% during the fattening period). In order to avoid the protein × Lys interaction observed in a previous study (Tous et al., 2014) the level of Lys was kept constant between the different diets. In the current study, although diets were based on maize which has lower protein content than barley, the level of dietary protein could not be as low as in the previous study because diets were supplemented with two different amino acids (Arg and Leu). The levels of supplementation with Arg and Leu were selected based on studies in which supplementation of Arg and Leu increased IMF content (Hyun et al., 2003, 2007; Tan et al., 2009; Ma et al., 2010). In all studies, diets were also based on maize, and in the case of Hyun et al. (2003 and 2007) the basal Leu level was similar to that of our study. These levels were considered not toxic (Baker, 1989). In order to avoid the animal weight effect all animals were slaughtered at similar body weight, although animals fed the low protein diets supplemented with Arg and Leu had a lower body weight at the end of the trial. Therefore, the differences obtained for carcass characteristics, meat quality and carcass cuts between animals fed LP diet and the ones fed LPAL may be attributed to the difference in final body weight.
Performance of the animals in the current study could be considered adequate, according to the standard of the farm and the crossbreed used. The reduction of ADFI, ADG, final weight and the trend to increase feed to gain ratio (FGR) observed in animals fed low protein diets supplemented with Arg and Leu may be explained by an antagonism between Leu and other branched chain amino acids (BCAA). When Leu is in excess, isoleucine and valine may become limiting and depress performance, as Leu increases activity of enzymes involved in BCAA catabolism (Oestmer & Handson, 1973). The growth depression may occur despite the fact that the levels of isoleucine and valine were in excess of the ratios proposed by Chung & Baker (1992). Hyun et al. (2003) reported a reduction of ADG in Duroc × Yorkshire pigs when Leu (2%) was supplemented in the diet, as in the low protein diet supplemented with Arg and Leu in the current experiment. In the experiment of Hyun et al. (2003) the level of Lys in the control and experimental diet was the same (0.79%) but, contrary to our study, the Leu supplemented diet had a higher CP concentration (15.4%) compared with the control (14.1%). The same authors did not find significant modifications of the growth performance in PIC line 327 × C22 pigs fed finishing diets supplemented diets with 1, 2, 3% Leu (Hyun et al., 2007) at two different levels of Lys (0.5% or 0.7%) but the level of dietary CP was not constant between diets. Tan et al. (2009) found an increase of ADG and a trend to reduce FGR of pigs when 1% Arg was added to the diet. Ma et al. (2010) and Go et al. (2012) did not find differences in performance of pigs fed diets supplemented with 1 % Arg compared to their respective control diets containing the same Lys and CP levels. The study of Madeira et al. (2014) reported that supplementation with Leu reduced the ADFI and that animals fed reduced dietary protein diets had a lower ADG and a higher FGR which may be caused by a deficiency in Lys, as Lys content was lower compared with the control diet. Therefore, the differences observed between studies could be explained because dietary protein, Lys and the genotype of the pigs were different.
Addition of arginine and leucine to low or normal protein diets: performance, carcass characteristics and intramuscular fat of finishing pigs - Image 5
One of the variables most related to meat acceptability for consumers is the IMF content (Font-i-Furnols et al., 2012). In our previous study, when protein was reduced and the dietary Lys was the same as the control, or when dietary Lys level was reduced but the percentage of dietary protein was the same as the control, the IMF content in LM and SM increased (Tous et al., 2014). In the present study, the reduction of dietary protein did not affect IMF content in LM. Supplementation of normal protein diet with Leu did not affect IMF and Arg supplementation reduced IMF and marbling in LM contrary to our hypothesis. These results are in contrast with previous studies which had shown an increase of IMF when Leu (Hyun et al., 2003, 2007) and Arg (Tan et al., 2009; Ma et al., 2010) were supplemented to pig diets, but in agreement with others (Go et al., 2012; Madeira et al., 2014, 2015) that found no effect of Arg supplementation on IMF. Hyun et al. (2007) found that the increase of IMF content was dependent of the level of dietary Lys, as Leu enhanced IMF content in LM when was combined with dietary low Lys but not with high dietary Lys. In a similar study performed with (Duroc × Pietrain) × (Large White × Landrace) boars, diet supplementation with 1% of Arg or 2% of Leu had no effect on the IMF content in LM, while the reduction of dietary protein increased it (Madeira et al., 2014). The difference between the studies of Madeira et al. (2014) and Tous et al. (2014) is that in the study of Madeira et al. (2014) the level of Lys in the low protein diet was reduced compared with the normal protein diet but it was not in the study of Tous et al. (2014). This difference between the low protein diets in the experiments suggests that the level of Lys instead of the level of protein may be responsible for the increase of IMF as previously suggested by Madeira et al. (2013) in ( Large White × Landrace) × (Large White × Pietrain) boars. Some studies evidenced the increase of IMF by dietary protein restriction is mediated through Lys deficiency (Madeira et al., 2013, 2014, 2015; Katsumata, 2011) as Tous et al. (2014) found an interaction between these two parameters. Go et al. (2012) did not observe an increase of IMF in pigs fed diets supplemented with 1% Arg when the level of Lys in the control and the experimental diet was similar (0.76 and 0.75 g / 100 g of diet, respectively), although they attributed the lack of response to the duration of the treatment or high BW at the beginning of the trial (from 80 to 110 kg live weight). Taking into account these considerations the supplementation of Arg and Leu may be only effective increasing IMF when the level of Lys in the diet is below the dietary requirement for pigs, or because low Lys and not Arg or Leu supplementation is the responsible of the increase on IMF. The difference observed between the current and the previous experiment with the Duroc x Landrace crossbreed (Tous et al., 2014), suggests that the genetic origin may also influence the changes on IMF and fat deposition as affected by dietary factors. In the study of Tous et al. (2014), the lean meat percentage of pigs fed the control diet was 50% while in the current study it was 57.3%, and in the current study the muscle depth was 10 mm higher and backfat thickness was 5 to 7 mm lower in all measurements compared with the previous study. Additionally, in the previous trial, animals fed the control diet presented an IMF of 2.38% and the animals fed the low-protein diet presented an IMF of 2.68%. In the current trial, although not significant, the animals fed the low-protein diet presented a lower IMF content in LM than the control diet (2.23 for NP vs 1.99% for LP). The differences in lean meat percentage between crossbreeds may explain, at least in part, the differences observed between these two studies. Wood et al. (2013) reported that feeding a regime for pigs with a lean genotype (Large White × Landrace) which provided a low protein diet but with the same intake of essential amino acids as pigs fed a control diet produced carcasses similar in fat content but higher content of IMF in LM, while feeding a reduced protein diet without maintaining the levels of essential amino acids, produced fatter pigs and increased IMF in LM and SM. In the studies of Wood et al. (2013) and Tous et al. (2014) the genotype did not include Pietrain sires, while in the study of Maderia et al. (2014) and in the current study, the genotype included Pietrain sires. Therefore, it could be hypothesized that some genes associated with the Pietrain breed may inhibit the response of IMF to certain nutrients in the diet. Further studies are required to confirm the hypothesis that Pietrain sires are less prone to increase IMF due to dietary modification.
Addition of arginine and leucine to low or normal protein diets: performance, carcass characteristics and intramuscular fat of finishing pigs - Image 6
Dietary supplementation with Arg increased lean meat percentage and reduced belly weight in relation carcass weight (cut with a high content of fat). These results together with the trend to reduce fatness in the 3rd-4th last ribs and the reduction of IMF and marbling, suggests a reduction of the whole animal fatness in animals fed diets supplemented with Arg. He et al. (2009) also found that dietary Arg supplementation decreased fat deposition and increased protein accretion in pigs. These results are opposite to those of Tan et al. (2009, 2011), showing higher lipogenesis and high fat deposition in muscle, but higher lipolisis and a reduction of total carcass fat in pigs fed diets supplemented with Arg, due to differential regulation of lipid-metabolic genes in adipose tissue and skeletal muscle. Ma et al. (2010) did not find differences due to Arg supplementation in carcass fat depth or meat percentage. Supplementation with Leu did not affect carcass backfat thickness or carcass lean meat percentage in agreement with Hyun et al. (2007), although Hyun et al. (2003) found a reduction of backfat on the last lumbar vertebrae and a trend to increase LM area when Leu was supplemented. Reduction of dietary protein did not affect carcass backfat thickness or carcass lean meat percentage in contrast to the results obtained in the previous study (Tous et al., 2014). The same reasons (Lys, genotype and cereal source in the diet) as stated previously for IMF might explain the differences observed between studies.
Although some differences were observed for conductivity and colour measurements by the effect of the dietary treatments, these differences were too small in magnitude to change the classification of meat as pale soft and exudative (PSE) or dark firm and dry (DFD). In the studies of Hyun et al. (2003, 2007), Madeira et al. (2014) and Ma et al. (2015) these variables were not significantly affected either.
In conclusion, in the conditions of the current study, and contrary to the initial hypothesis, reduction of crude protein or dietary supplementation with leucine had no effect on intramuscular fat content while supplementation with arginine reduced it. Furthermore, arginine seems to reduce whole animal fatness and increase the lean content. Attention must be paid when leucine and arginine are added in low crude protein diets as they impaired performance, possibly due to an antagonism between leucine and the other branched chain fatty acids.
 
Acknowledgements
Crystalline amino acids for the study were kindly provided by Indukern, S.A. (Barcelona, Spain).
 
Funding: MICINN, Spain (AGL2007-65898-C02-02); N. Tous was a recipient of an INIA (Madrid, Spain) scholarship.
Competing interests: The authors have declared that no competing interests exist.

This article was originally published in Spanish Journal of Agricultural Research 14(4), e0605, 11 pages (2016) eISSN: 2171-9292 http://dx.doi.org/10.5424/sjar/2016144-9351. This is an Open Access article distributed under the terms of the Creative Commons Attribution (CC-by) Spain 3.0 License.
 
References
Baker DH, 1989. Amino acid nutrition of pigs and poultry. In: Recent advances in animal nutrition; Haresign W, Cole DJA (eds.). pp: 245-260. http://dx.doi.org/10.1016/B978- 0-408-04149-2.50017-9.
BOE, 2007. Ley 32/2007 de 7 de Noviembre para el cuidado de los animales, en su explotación, transporte, experimentación y sacrificio. Boletín Oficial del Estado 268: 45914-45920.
Channon HA, Reynolds J, Baud S, 2001. Identifying pathways to ensure acceptable eating quality of pork. Progress Report, Pig Research and Development Corporation, DV 136/1385, Canberra, Australia. Chung TK, Baker DH, 1992. Ideal amino acid pattern for 10-kg pigs. J Anim Sci 70: 3102-3111. http://dx.doi. org/10.2527/1992.70103102x.
CIE, 1976. Colorimetry, 2nd ed. Commission International de l’Eclairage Publ. No. 15.2, Vienna, Austria. Font-i-Furnols M, Gispert M, 2009. Comparison of different devices for predicting the lean meat percentage of pig carcasses. Meat Sci 83: 443-446. http://dx.doi.org/10.1016/j. meatsci.2009.06.018.
Font-i-Furnols M, Tous N, Esteve-Garcia E, Gispert M, 2012. Do all the consumers accept marbling in the same way? The relationship between eating and visual acceptability of pork with different intramuscular fat content. Meat Sci 91: 448-453. http://dx.doi.org/10.1016/j.meatsci.2012.02.030.
Gispert M, Valero A, Oliver MA, Diestre A, 1997. Associated problems with pig carcasses to much lean. Eurocarne 61: 27-32.
Gispert M, Oliver MA, Velarde A, Suarez P, Perez J, Fonti-Furnols M, 2010. Carcass and meat quality characteristics of immunocastrated male, surgically castrated male, entire male and female pigs. Meat Sci 85: 664-670. http:// dx.doi.org/10.1016/j.meatsci.2010.03.021.
Go G, Wu G, Silvey DT, Choi S, Li X, Smith SB, 2012. Lipid metabolism in pigs fed supplemental conjugated linoleic acid and/or dietary arginine. Amino Acids 43: 1713-1726. http://dx.doi.org/10.1007/s00726-012-1255-5.
Harris RA, Joshi M, Jeoung NH, 2004. Mechanisms responsible for regulation of branched-chain amino acid catabolism. Biochem Biophys Res Commun 313: 391-396. http:// dx.doi.org/10.1016/j.bbrc.2003.11.007.
He Q, Kong X, Wu G, Ren P, Tang H, Hao F, Huang R, Li T, Tan B, Li P et al., 2009. Metabolic analysis of the response of growing pigs to dietary L-arginine supplementation. Amino Acids 37: 199-208. http://dx.doi. org/10.1007/s00726-008-0192-9.
Hyun Y, Ellis M, McKeith FK, Baker DH, 2003. Effect of dietary leucine level on growth performance, and carcass and meat quality in finishing pigs. Can J Anim Sci 83: 315-318. http://dx.doi.org/10.4141/A02-035.
Hyun Y, Kim JD, Ellis M, Peterson BA, Baker DH, McKeith FK, 2007. Effect of dietary leucine and lysine levels on intramuscular fat content in finishing pigs. Can J Anim Sci 87: 303-306. http://dx.doi.org/10.4141/CJAS06042.
Jobgen WS, Fried SK, Fu WJ, Meininger CJ, Wu G, 2006. Regulatory role for the arginine-nitric oxide pathway in metabolism of energy substrates. J Nutr Biochem 17: 571- 588. http://dx.doi.org/10.1016/j.jnutbio.2005.12.001.
Katsumata M, 2011. Promotion of intramuscular fat accumulation in porcine muscle by nutritional regulation. Anim Sci J 82: 17-25. http://dx.doi.org/10.1111/j.1740-0929.2010.00844.x.
Ma X, Lin Y, Jiang Z, Zheng C, Zhou G, Yu D, Cao T, Wang J, Chen F, 2010. Dietary arginine supplementation enhances antioxidative capacity and improves meat quality of finishing pigs. Amino Acids 38: 95-102. http://dx.doi. org/10.1007/s00726-008-0213-8.
Ma X, Zheng C, Hu Y, Wang L, Yang X, Jiang Z, 2015. Dietary L-arginine supplementation affects skeletal longissimus muscle proteome in finishing pigs. Plos One 10: e0117294. http://dx.doi.org/10.1371/journal.pone.0117294.
Madeira MS, Costa P, Alfaia CM, Lopes PA, Bessa RJB, Lemos JPC, Prates JAM, 2013. The increased intramuscular fat promoted by dietary lysine restriction in lean but not in fatty pig genotypes improves pork sensory attributes. J Anim Sci 91: 3177-3187. http://dx.doi.org/10.2527/ jas.2012-5424.
Madeira MS, Alfaia CM, Costa P, Lopes PA, Lemos JPC, Bessa RJB, Prates JAM, 2014. The combination of arginine and leucine supplementation of reduced crude protein diets for boars increases eating quality of pork. J Anim Sci 92: 2030-6876. http://dx.doi.org/10.2527/jas.2013- 6876.
Madeira MS, Alfaia CM, Costa P, Lopes PA, Martins SV, Lemos JPC, Moreira O, Santos-Silva J, Bessa RJB, Prates JAM, 2015. Effect of betaine and arginine in lysine-deficient diets on growth, carcass traits, and pork quality. J Anim Sci 93: 4721-4733. http://dx.doi.org/10.2527/ jas.2015-9117.
Morales A, Arce N, Cota M, Buenabad L, Avelar E, Htoo JK, Cervantes M, 2015. Effect of dietary excess of branchedchain amino acids on performance and serum concentrations of amino acids in growing pigs. J Anim Physiol Anim Nutr 100 (1): 39-45. http://dx.doi.org/10.1111/ jpn.12327.
NPPC, 2000. Composition and quality assessment procedures. National Pork Producers Council, Des Moines, IA, USA. NRC, 1998. Nutrient requirements of swine, 10th revised edn. National Academies Press, Washington, DC, USA. Oestmer GA, Handson LE, 1973. Leucine-isoleucine interrelationship in young pigs. J Anim Sci 36: 674-678. http:// dx.doi.org/10.2527/jas1973.364674x.
Rasmussen AJ, Andersson M, 1996. New method for determination of drip loss in pork muscles. Proc. 42nd Int Cong of Meat Sci and Technol, Lillehammer (Norway), Set 1-6. pp: 286-287.
Sauvant D, Perez JM, Tran G, 2004. Tables de composition et de valeur nutritive des matières premières destinées aux animaux d’élevage. INRA ed., Paris. Tan B, Yin Y, Liu Z, Li X, Xu H, Kong X, Huang R, Tang W, Shinzato I, Smith SB, Wu G, 2009. Dietary L-arginine supplementation increases muscle gain and reduces body fat mass in growing-finishing pigs. Amino Acids 37: 169- 175. http://dx.doi.org/10.1007/s00726-008-0148-0.
Tan B, Yin Y, Liu Z, Tang W, Xu H, Kong X, Li X, Yao K, Gu W, Smith SB, Wu G, 2011. Dietary L-arginine supplementation differentially regulates expression of lipidmetabolic genes in porcine adipose tissue and skeletal muscle. J Nutr Biochem 22: 441-445. http://dx.doi. org/10.1016/j.jnutbio.2010.03.012.
Tous N, Lizardo R, Vilà B, Gispert M, Font-i-Furnols M, EsteveGarcia E, 2014. Effect of reducing dietary protein and lysine on growth performance, carcass characteristics, intramuscular fat, and fatty acid profile of finishing barrows. J Anim Sci 92: 129-140. http://dx.doi.org/10.2527/jas.2012-6222.
Walstra P, Merkus GSM, 1995. Procedure for assessment of the lean meat percentage as a consequence of the new EU reference dissection method in pig carcass classification. Research Institute for Animal Science and Health Research Branch, Zeist, The Netherlands, 22 pp.
Wood JD, Nute GR, Richardson RI, Whittington FM, Southwood O, Plastow G, Mansbridge R, Da Costa N, Chang KC, 2004. Effects of breed, diet and muscle on fat deposition and eating quality in pigs. Meat Sci 67: 651-667. http://dx.doi.org/10.1016/j.meatsci.2004.01.007.
Wood JD, Lambe NR, Walling WA, Whitney H, Jagge, S, Fullarton PJ, Bayntun J, Hallett K, Bünger L, 2013. Effects of low protein diets on pigs with a lean genotype. 1. Carcass composition measured by dissection and muscle fatty acid composition. Meat Sci 95: 123-128. http://dx. doi.org/10.1016/j.meatsci.2013.03.001.
Yao K, Deng D, Liu ZQ, Li TJ, Huang RL, Chu WY, Tan BE, Wang W, Wu G, Yin YL, 2008. Dietary arginine supplementation increases intracellular mTOR signaling activity in skeletal muscle of neonatal pigs. J Nutr 138: 867-872.
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Authors:
Rosil Lizardo
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Borja Vila
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Marina Gispert Martinell
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Maria M. Font-i-Furnols
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Enric Esteve-Garcia
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