Dietary intake of broiler breeder hens during the laying period affects amino acid and fatty acid profiles in eggs

Li, Feng; Yang, Yi; Yang, Xue; Shan, Mingxu; Gao, Xiang; Zhang, Yuanyuan; Hu, Jingwei; Shan, Anshan

doi:10.1590/rbz4820180292

ABSTRACT

The objective of this study was to evaluate the effects of maternal dietary intake on the amino acid and fatty acid contents in eggs during the laying period. An experiment with a 2×2 factorial design was conducted with two maternal dietary intake levels (100 and 75% of dietary intake recommended by the Chinese Ministry of Agriculture) and two broiler lines (fat and lean line). A total of 384 hens of fat line and 384 hens of lean line at 23 weeks of age were included in the experiment. Each line was randomly divided into two treatments (n = 192 in each treatment, with 12 replications), and each replication included 16 birds. The treatments were LN (lean line and normal maternal dietary intake, n = 192), LL (lean line and low maternal dietary intake, n = 192), FN (fat line and normal maternal dietary intake, n = 192), and FL (fat line and low maternal dietary intake, n = 192). The amino acid and fatty acid contents in eggs were tested (50 weeks of age). The fat line had higher levels of arginine, aspartic acid, glycine, histidine, leucine, methionine, and threonine in the egg albumen than the lean line. Low maternal dietary intake increased the cystine deposition in egg yolks. There were interactions between maternal dietary intake and line on the deposition of trans-oleic acid, docosanoic acid, and total fatty acid in egg yolks. Low maternal dietary intake increased the deposition of tetradecenoic and linolenic acids and the ratio of total polyunsaturated fatty acids to total saturated fatty acid in egg yolks but decreased the deposition of docosanoic acid. Maternal dietary intake and line affect the amino acid and fatty acid profiles in eggs.

Keywords:
egg albumen; egg yolk; fat line; feed intake; lean line

Introduction

Birds rely entirely on the egg nutrition to sustain life in the initial stage of development. Embryonic development is affected by many factors, including egg nutrition, temperature, and humidity (Dymond et al., 2013Dymond, J.; Vinyard, B.; Nicholson, A. D.; French, N. A. and Bakst, M. R. 2013. Short periods of incubation during egg storage increase hatchability and chick quality in long-stored broiler eggs. Poultry Science 92:2977-2987. https://doi.org/10.3382/ps.2012-02816
https://doi.org/10.3382/ps.2012-02816... ; Noiva et al., 2014Noiva, R. M.; Menezes, A. C. and Peleteiro, M. C. 2014. Influence of temperature and humidity manipulation on chicken embryonic development. BMC Veterinary Research 10:234. https://doi.org/10.1186/s12917-014-0234-3
https://doi.org/10.1186/s12917-014-0234-... ; Yildirim and Yetisir, 2004Yildirim, I. and Yetisir, R. 2004. Effects of different hatcher temperatures on hatching traits of broiler embryos during the last five days of incubation. South African Journal of Animal Science 34:211-216.). Previous reports have indicated that the changes in egg nutrition affect the embryonic development and health (Bhattacharyya et al., 2018Bhattacharyya, A.; Majumdar, S.; Bhanja, S. K.; Mandal, A. B. and Kadam, M. 2018. Effect of maternal dietary manipulation and in ovo injection of nutrients on the hatchability indices, post-hatch growth, feed consumption, feed conversion ratio and immunocompetence traits of turkey poults. Journal of Applied Animal Research 46:287-294. https://doi.org/10.1080/09712119.2017.1296843
https://doi.org/10.1080/09712119.2017.12... ; Kermanshahi et al., 2017Kermanshahi, H.; Golian, A.; Emami, N. K.; Daneshmand, A.; Tabari, D. G. and Ibrahim, S. A. 2017. Effects of in ovo injection of threonine on hatchability, intestinal morphology, and somatic attributes in Japanese quail (Coturnix japonica). Journal of Applied Animal Research 45:437-441. https://doi.org/10.1080/09712119.2016.1206902
https://doi.org/10.1080/09712119.2016.12... ). Other researchers have shown that restricting maternal nutrition affects the development of embryos (Prezotto et al., 2016Prezotto, L. D.; Camacho, L. E.; Lemley, C. O.; Keomanivong, F. E.; Caton, J. S.; Vonnahme, K. A. and Swanson, K. C. 2016. Nutrient restriction and realimentation in beef cows during early and mid-gestation and maternal and fetal hepatic and small intestinal in vitro oxygen consumption. Animal 10:829-837. https://doi.org/10.1017/S1751731115002645
https://doi.org/10.1017/S175173111500264... ; Raja et al., 2016Raja, J. S.; Hoffman, M. L.; Govoni, K. E.; Zinn, S. A. and Reed, S. A. 2016. Restricted maternal nutrition alters myogenic regulatory factor expression in satellite cells of ovine offspring. Animal 10:1200-1203. https://doi.org/10.1017/S1751731116000070
https://doi.org/10.1017/S175173111600007... ). In addition, Bhanja et al. (2015)Bhanja, S. K.; Hotowy, A.; Mehra, M.; Sawosz, E.; Pineda, L.; Vadalasetty, K. P.; Kurantowicz, N. and Chwalibog, A. 2015. In ovo administration of silver nanoparticles and/or amino acids influence metabolism and immune gene expression in chicken embryos. International Journal of Molecular Sciences 16:9484-9503. https://doi.org/10.3390/ijms16059484
https://doi.org/10.3390/ijms16059484... reported that silver nanoparticles and amino acid complexes can act as potential agents to enhance innate and adaptive immunity in chickens. Al-Daraji et al. (2012)Al-Daraji, H. J.; Al-Mashadani, A. A.; Al-Hayani, W. K.; Al-Hassani, A. S. and Mirza, H. A. 2012. Effect of in ovo injection with L-arginine on productive and physiological traits of Japanese quail. South African Journal of Animal Science 42:139-145. https://doi.org/10.4314/sajas.v42i2.6
https://doi.org/10.4314/sajas.v42i2.6... reported that the inoculation of different levels of L-Arginine into eggs improves the productive and physiological performance of quail. Moreover, L-Leucine used in ovo injection to increase the prenatal metabolic rate and lipid metabolism (Han et al., 2018Han, G.; Yang, H.; Bungo, T.; Ikeda, H.; Wang, Y.; Nguyen L. T. N.; Eltahan, H. M.; Furuse, M. and Chowdhury, V. S. 2018. In ovo L-leucine administration stimulates lipid metabolisms in heat-exposed male, but not female, chicks to afford thermotolerance. Journal of Thermal Biology 71:74-82.).

Egg nutrition is derived entirely from the mother bird. Some reports have indicated that maternal nutrition changed nutritional composition and characteristics of eggs, which could affect the embryonic development. Many researchers have shown that egg components are affected by dietary components and nutrition level of hens (Güçlü et al., 2008Güçlü, B.; Uyanık, F. and İşcan, K. 2008. Effects of dietary oil sources on egg quality, fatty acid composition of eggs and blood lipids in laying quail. South African Journal of Animal Science 38:91-100.; Li et al., 2011Li, F.; Xu, L. M.; Shan, A. S.; Hu, J. W.; Zhang, Y. Y. and Li, Y. H. 2011. Effect of daily feed intake in laying period on laying performance, egg quality and egg composition of genetically fat and lean lines of chickens. British Poultry Science 52:163-168. https://doi.org/10.1080/00071668.2011.559455
https://doi.org/10.1080/00071668.2011.55... ). Our previous work illustrates that the interactions between daily feed intake of hens during the laying period and genotype (fat and lean lines) on egg production, egg weight, percentage yolk, yolk:albumen ratio, and yolk cholesterol content are significant (Li et al., 2011Li, F.; Xu, L. M.; Shan, A. S.; Hu, J. W.; Zhang, Y. Y. and Li, Y. H. 2011. Effect of daily feed intake in laying period on laying performance, egg quality and egg composition of genetically fat and lean lines of chickens. British Poultry Science 52:163-168. https://doi.org/10.1080/00071668.2011.559455
https://doi.org/10.1080/00071668.2011.55... ). Maternal feed restriction decreases egg weight and increases egg production, egg-shape index, and cholesterol content of yolk significantly (Li et al., 2011Li, F.; Xu, L. M.; Shan, A. S.; Hu, J. W.; Zhang, Y. Y. and Li, Y. H. 2011. Effect of daily feed intake in laying period on laying performance, egg quality and egg composition of genetically fat and lean lines of chickens. British Poultry Science 52:163-168. https://doi.org/10.1080/00071668.2011.559455
https://doi.org/10.1080/00071668.2011.55... ). Lima et al. (2007)Lima, R. C.; Fuentes, M. F. F.; Freitas, E. R.; Sucupira, F. S.; Moreira, R. F. and Braz, N. M. 2007. Farelo de coco na ração de poedeiras comerciais: digestibilidade dos nutrientes, desempenho e qualidade dos ovos. Revista Brasileira de Zootecnia 36:1340-1346. https://doi.org/10.1590/S1516-35982007000600016
https://doi.org/10.1590/S1516-3598200700... reported that different dietary components can affect the characteristics of eggs of commercial laying hens. Besides, Trindade Neto et al. (2011)Trindade Neto, M. A.; Pacheco, B. H. C.; Albuquerque, R. and Schammass, E. A. 2011. Lysine and zinc chelate in diets for brown laying hens: effects on egg production and composition. Revista Brasileira de Zootecnia 40:377-384. https://doi.org/10.1590/S1516-35982011000200020
https://doi.org/10.1590/S1516-3598201100... showed that increasing dietary lysine concentration can reduce the protein content and increase the composition of lipids in eggs. Corduk and Sarica (2008)Corduk, M. and Sarica, S. 2008. Effects of L-carnitine in layer diets containing different fat sources and energy levels on hen performance and egg quality. South African Journal of Animal Science 38:260-270. showed that dietary metabolizable energy (ME) levels or fat sources in layer diets significantly affect egg quality parameters. In addition, different dietary oils or fat sources can affect the fatty acid profile, and no negative effects have been found on the performance of hens, total fat content of eggs, or egg quality (King et al., 2012King, E.; Hugo, A.; De Witt, F.; Van der Merwe, H. and Fair, M. 2012. Effect of dietary fat source on fatty acid profile and lipid oxidation of eggs. South African Journal of Animal Science 42:503-506.). Moreover, during embryonic and post-hatching periods, the antioxidant capacity of progeny can be improved by the inclusion of vitamin E, selenium (Se), or methionine (Met) in the maternal diet (Zhao et al., 2010Zhao, L. Y.; Xu, S. Q.; Zhao, R. Q.; Peng, Z. Q. and Pan, X. J. 2010. Effects of selenium and methionine supplementation of breeder hen diets on selenium concentration and oxidative stability of lipids in the thigh muscles of progeny. Journal of Food Science 74:C569-C574. https://doi.org/10.1111/j.1750-3841.2009.01296.x
https://doi.org/10.1111/j.1750-3841.2009... ; Surai et al., 2016Surai, P. F.; Fisinin, V. I. and Karadas, F. 2016. Antioxidant systems in chick embryo development. Part 1. Vitamin E, carotenoids and selenium. Animal Nutrition 2:1-11. https://doi.org/10.1016/j.aninu.2016.01.001
https://doi.org/10.1016/j.aninu.2016.01.... ).

Our previous research showed that low maternal dietary intake affects the embryonic development process, changes the gene expression of myostatin and myogenin (Li et al., 2013Li, F.; Shan, A. S.; Hu, J. W.; Zheng, Y. B.; Xu, L. M. and Chen, Z. H. 2013. Changes to daily feed intake during the laying period alters embryonic MSTN and MYOG gene expression in genetically fat and lean lines of chickens. British Poultry Science 54:728-737. https://doi.org/10.1080/00071668.2013.853868
https://doi.org/10.1080/00071668.2013.85... ), and decreases birth weight of offspring (Li et al., 2019Li, F., Shan, M. X.; Gao, X; Yang, Y.; Yang, X.; Zhang, Y. Y.; Hu, J.W.; Shan, A. S. and Cheng, B. J. 2019. Effects of nutrition restriction of fat-and lean line broiler breeder hens during the laying period on offspring performance, blood biochemical parameters, and hormone levels. Domestic Animal Endocrinology 68:73-82. https://doi.org/10.1016/j.domaniend.2019.01.007
https://doi.org/10.1016/j.domaniend.2019... ). Although a series of changes in egg weight, egg shape index, and cholesterol content of yolks were found (Li et al., 2011Li, F.; Xu, L. M.; Shan, A. S.; Hu, J. W.; Zhang, Y. Y. and Li, Y. H. 2011. Effect of daily feed intake in laying period on laying performance, egg quality and egg composition of genetically fat and lean lines of chickens. British Poultry Science 52:163-168. https://doi.org/10.1080/00071668.2011.559455
https://doi.org/10.1080/00071668.2011.55... ), the effects of maternal nutrition restriction on the fatty acid profile and amino acid profile of eggs, which might affect the embryonic development process and offspring growth, were not clear. We hypothesize that maternal nutrition can affect the amino acids and fatty acids of eggs, which are important nutrients for embryonic development during the hatching period. To better indicate the maternal effects, two broiler lines (fat and lean), differing based on abdominal fat percentage, were used to evaluate the effects of two maternal dietary intake levels on the fatty acid and amino acid profiles in eggs in this study.

Material and Methods

This study was approved by the Animal Care and Use Committee (case no. 09/2011) and was performed in Harbin, Heilongjiang Province, China (45°75'07" E longitude, 126°73'39" N latitude, and 126 m altitude).

In the experiment, two divergent broiler lines were used: lean and fat lines, which have been selected since 1996 according to abdominal fat percentage, very low deposition of lipoprotein in the plasma, and body weight (Wang et al., 2009Wang, H.; Wang, Q.; Wang, S.; Hu, G. and Li, H. 2009. Comparative analysis of body fat traits and serum biochemical parameters between broiler lines divergently selected for abdominal fat content. Journal of Northeast Agricultural University 40:76-80.). A 2×2 factorial design was used to research the effects of two maternal dietary intake levels (100 and 75% maternal dietary intake recommended by the Chinese Ministry of Agriculture [CMOA, 2004CMOA - Chinese Ministry of Agriculture. 2004. Feeding standard of chicken. Agricultural industry standard, Chinese Ministry of Agriculture, China, NY/T 33.]) and two broiler lines (fat and lean) on the deposition of amino acids and fatty acids in eggs. Nine hundred one-day-old female birds of fat and lean lines (450 birds of each) were used. The birds were reared in stairstep cages from birth to 23 weeks. At 23 weeks old, 768 females (lean line, n = 384; fat line, n = 384) were randomly selected and assigned to four treatments. Each line was divided into two treatments (n = 192 in each treatment, with 12 replications). Sixteen birds allocated into eight adjoining metal cages consisted of a replicate, and two birds were housed in a cage $(48 \times 34 \times 39 cm)$ . The treatments were LN (lean line with normal maternal dietary intake, n = 192), LL (lean line with low maternal dietary intake, n = 192), FN (fat line with normal maternal dietary intake, n = 192), and FL (fat line with low maternal dietary intake, n = 192). The initial weight did not significantly differ among individual birds (means: $2.55 \times 10^{3} - 2.56 \times 10^{3} g$ ; pooled SEM: 9.13 g).

From one day to 24 weeks of age, all birds were supplied with the same diet [0-6 weeks: 12.10 MJ ME/kg, 179 g crude protein (CP)/kg, and 10.6 g Ca/kg; 7-18 weeks: 11.82 MJ ME/kg, 147 g CP/kg, and 9.1 g Ca/kg; and 19-24 weeks: 11.61 MJ ME/kg, 161 g CP/kg, and 20.8 g Ca/kg]. After 24 weeks, the birds in all treatments were fed a corn-soy-based diet (Table 1). From 27 (5% of laying rate) to 50 weeks of age, the daily feed allocations of the LN and FN treatments (Table 2) were the same as the maternal dietary intake (MDIR) recommended by the Chinese Ministry of Agriculture (CMOA, 2004CMOA - Chinese Ministry of Agriculture. 2004. Feeding standard of chicken. Agricultural industry standard, Chinese Ministry of Agriculture, China, NY/T 33.), and the daily allocations of the LL and FL treatments were reduced to 75% of MDIR. To alleviate or reduce chronic stress and hunger, feed was given twice a day at 08:00 and 16:00 h. There was no residual feed each time. Therefore, the feed supply was equal to the maternal dietary intake. Water was given ad libitum during the experimental period. Artificial and natural light were used during the photoperiod: the artificial light was used from 10 days to 29 weeks; a combination of natural and artificial light was used after 29 weeks; from 10 days to 20 weeks, the day length was 8 h; then, from 21 weeks to 29 weeks, it was increased by an average of half an hour per week from 12 h per day up to a maximum of 16 h per day, after which was maintained at 16 h per day. The house temperature was maintained at 20±2 °C.

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Table 1
Composition of the basal diets of fat-line and lean-line hens

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Table 2
Feed allocations of fat-line and lean-line hens from 27 to 58 weeks of age¹ 1 Based on the Feeding Standard for Chickens (CMOA, 2004).

Three eggs were randomly selected from each replicate at 16:00 h on the last day of the 50th week of age. The eggs were weighed and broken. Extractions of 100-400 mg albumen and 400-600 mg yolk were used to determine the amino acid levels via the hydrochloric acid hydrolysis method. The external standard curve of amino acids was drawn by the relationship between the concentration and peak area of amino acid (Figure 1). An amino acid analyzer (L-8800 Hitachi Automatic Amino Acid Analyzer, Tokyo, Japan) was used. The length of the ion-exchange column (Hitachi HPLC Packed Column, Hitachi High-Tech Science Corp., Tokyo, Japan) was 4.6×60 mm. A subsample of 0.5 g well-mixed egg yolk from the same egg used for amino acid determination was weighed and used to determine the fatty acid level via the fatty acid methylation method. Fatty acid methyl esters were analyzed with a Shimadzu GC-2010 gas chromatograph (Shimadzu Scientific Instrument, Inc., Columbia, MD, USA) installed with an SPTM-2560 fused silica capillary column (100 m × 0.25 mm × 0.2 µm film thickness) of Supelco (Sigma-Aldrich, St. Louis, MO, USA), for which a standard with 37 fatty acid methyl esters is available (Supelco F.A.M.E. Mix C4-C24, catalog no. 47885-U). The external standard curve of fatty acids was drawn by the relationship between the concentration and peak area of fatty acid (Figure 2).

Figure 1
External standard curve of amino acids.

Figure 2
External standard curve of fatty acids.

The hydrochloric acid hydrolysis method was used to determine the amino acid level. The sample was sent to the bottom of a hydrolysis tube, and 6-8 mL of 6 mol/L hydrochloric acid was added to the hydrolysis tube. Each hydrolysis tube was filled with nitrogen, the inner plug was inserted, and the tube was covered with a screw cap. The tubes were placed in an oven at 110 ℃ for 22-24 h. After hydrolysis, the tubes were left to cool. The liquid in each tube was well shaken, filtered using filter paper (11×11 cm), and set to 50 mL in a volumetric flask with double-distilled water. The hydrolysis tube was washed more than three times with double-distilled water to ensure that the amino acid salts did not remain in the hydrolysis tube or filter paper. Then, 1 mL liquid was removed from the volumetric flask into a plastic centrifuge tube and concentrated in vacuo for 4-6 h with a lyophilizer to dryness. Subsequently, 1 mL of 0.02 mol/L hydrochloric acid was added to the centrifuge tube. The tube was well shaken and centrifuged at 14,000 rpm for 15 min with a centrifuge (Anke TDL-60B, Anting Scientific Instrument Factory, Shanghai, China). Then, 0.8 mL supernatant was filtered through a 0.22 nm filter membrane into a vial. The vial was placed on an amino acid analyzer (L-8800 Hitachi Automatic Amino Acid Analyzer, Tokyo, Japan). The length of the ion-exchange column (Hitachi HPLC Packed Column, Hitachi High-Tech Science Corp., Tokyo, Japan) was 4.6×60 mm; the resin was 2622#; the temperature of the reaction column was 135 ℃; the temperature of the separation column was 57 ℃; the flow rate of the buffer was 0.4 mL/min; the column pressure was 7.0-7.3 MPa; the flow rate of the ninhydrin was 0.35 mL/min; and the column pressure was 0.7-0.8 MPa.

The fatty acid methylation method was used to determine the fatty acid level. A sample of 0.5 g well-mixed egg yolk from the same egg used for the amino acid determination was weighed into a centrifuge tube with a plug. Then, 1.5 mL ultra-pure water was added and shaken. Heptanoic acid (0.5 mL, 17:0) internal standard solution (5 mg/mL), 2.5 mL methanol, and 2.5 mL chloroform were then added and vortexed for 5 min. Two hours later, the mixture was centrifuged at 4200 rpm for 5 min. Then, 1 mL of the chloroform layer was moved into a screw-capped glass tube and dried in a block heater under a stream of nitrogen. The dried lipids were resolubilized in 2 mL of sodium methoxide solution. The tubes were heated in a water bath at 50 ℃ for 30 min. When cooled, 3 mL of a hydrochloric acid-methanol solution was added, mixed, sealed, and heated in a water bath at 90 ℃ for 60 min. When cooled, 1 mL double distilled water and 1.5 mL hexane were added. The sample was mixed and allowed to separate. The hexane (upper) layer was filtered through anhydrous sodium sulfate into a vial for analysis. Fatty acid methyl esters were analyzed with a Shimadzu GC-2010 gas chromatograph (Shimadzu Scientific Instrument, Inc., Columbia, MD, USA) installed with an SPTM-2560 fused silica capillary column (100 m × 0.25 mm × 0.2 µm film thickness) of Supelco (Sigma-Aldrich, St. Louis, MO, USA), for which a standard with 37 fatty acid methyl esters is available (Supelco F.A.M.E. Mix C4-C24, catalog no. 47885-U). The chromatography conditions were as follows: 240 ℃ injector temperature; 240 ℃ detector temperature; helium as the carrier gas at a flow rate of 1.04 mL/min, 1:50 split ratio; and temperature program set to 170 ℃ for 30 min, followed by an increase of 1.5 ℃/min to 200 ℃ maintained for 20 min, and then an increase of 5 ℃/min to 220 ℃ maintained for 15 min. Peaks were identiﬁed by comparison of retention times with those of the corresponding standards.

Total trait values were analyzed by ANOVA using PROC MIXED of SAS (Statistical Analysis System, version 9.1) for a randomized complete block with a factorial arrangement of treatments. The factorial treatment arrangement consisted of two maternal dietary intake levels and two broiler lines. Maternal dietary intake and lines were fixed effects and blocks were random effects. The following formula was used to calculate the value of amino acid content in the samples:

Yij = (Wij \times 2.5) / Wj,

in which Yij = amino acid content in the sample (mg/g), Wij = weight of amino acid measured by the amino acid analyzer, and Wj = sample weight.

The following formula was used to calculate the value of fatty acid content in the samples:

Y i j = ((F i \times W s j \times A i j) / A s j) \times 1000 / W j,

in which Yij = fatty acid content (mg/g), Fi = correction factor, Wsj = weight of internal standard mixed with the sample, Aij = peak area of fatty acid, Asj = peak area of internal standard, Wj = sample weight, and $(Fi \times Wsj \times Aij) / Asj = fatty acid weight in the sample$ . In total, 37 mixed external standards contained the internal standard. Fi was calculated using the external standard curve. The calculation formula for Fi is as follows: $Fi = (Wi/Ws) / (Ai/As)$ , in which Wi = weight of fatty acid in external standards, Ws = weight of internal standard in external standards, Ai = peak area of fatty acid in the external standard curve, and As = the peak area of internal standard in the external standard curve.

The following model was used to analyze the data:

Yijk = μ + α i + β j + (α β) ij + Pk + ε ijk,

in which Yijk = value of an individual sample from each egg of each replicate, μ = overall mean, αi = maternal dietary intake effect, βj = line effect, (αβ)ij = interaction between maternal dietary intake and line, Pk = effect of block, and εijk = error component. If differences in treatment means were detected by ANOVA, Duncan's multiple range test was applied to separate means. A significance level of P≤0.05 was used for analysis.

Results

The main amino acids in egg albumen were glycine (Gly), alanine (Ala), aspartic (Asp), glutamic acid (Glu), and leucine (Leu) (Table 3). Cysteine (Cys) had the lowest levels in the albumen. There was no significant interaction between maternal dietary intake and line on the deposition of amino acids in egg albumen. There were significant differences (P<0.05) between the lines in the deposition of Arg, Asp, Gly, histidine (His), Leu, Met, and threonine (Thr) in egg albumen, and the fat line had higher deposition (P<0.05) of the above amino acids in albumen than the lean line.

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Table 3
Effect of maternal dietary intake on the deposition of amino acids in egg albumen of fat-line and lean-line hens (mg/g of egg albumen [fresh samples])¹ 1 n = 36/treatment.

The main amino acids in the egg yolks were Gly, Ala, Asp, Glu, Leu, Lysine (Lys), and proline (Table 4). The least abundant amino acid in egg yolk was Cys. There was no significant interaction between maternal dietary intake and line on the deposition of amino acids in egg yolks. There was no significant difference between the lines in the deposition of amino acids in yolks. Low maternal dietary intake significantly increased (P<0.05) the deposition of Cys in egg yolks. Moreover, low maternal dietary intake significantly increased (P<0.05) the deposition of amino acids (Met and tyrosine) were not included) in the yolks of the fat line, but there were no significant effects on those of the lean line.

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Table 4
Effect of maternal dietary intake on the deposition of amino acids in egg yolks of fat-line and lean-line hens (mg/g of egg yolk [fresh samples])¹ 1 n = 36/treatment.

The fatty acids in egg yolks were mainly composed of palmitic (16:0), palmitoleic (16:1), stearic (18:0), oleic (18:1n-9c), and linoleic (18:2n-6c) (Table 5). The deposition of 18:1n-9c in yolks was the highest. There were significant interactions (P<0.05) between maternal dietary intake and line on the deposition of trans-oleic acid (18:1n-9t), docosanoic acid (22:0), and total fatty acid (TFA) in egg yolks. Furthermore, there was a significant difference (P<0.01) between the two lines in the deposition of heneicosanoic acid (21:0) in egg yolk. In LN and FN, there was a significant difference (P<0.05) between the two lines in the deposition of 22:0 in egg yolks. Besides, in LL and FL, there was a significant difference (P<0.05) between the two lines in the deposition of 18:1n-9t, 22:0, and TFA in egg yolks. Low maternal dietary intake significantly increased the deposition of 14:1, linolenic acid (18:3n-6), and the ratio of total polyunsaturated fatty acids (PUFA) to total saturated fatty acids (SFA) in egg yolk (P<0.05), but it decreased the deposition of 22:0 (P<0.05). In terms of the fat line, low maternal dietary intake significantly increased the deposition of 18:1n9t (P<0.05).

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Table 5
Effect of maternal dietary intake on the deposition of fatty acids in egg yolks of fat-line and lean-line hens (mg/g of egg yolk [fresh samples])¹ 1 n = 36/treatment.

Discussion

Egg composition, especially the content of amino acids and fatty acids, is critical for the development of an embryo. Egg composition is mainly affected by age, feeding, and variety (Hammershøj and Johansen, 2016Hammershøj, M. and Johansen, N. F. 2016. The effect of grass and herbs in organic egg production on egg fatty acid composition, egg yolk colour and sensory properties. Livestock Science 194:37-43. https://doi.org/10.1016/j.livsci.2016.11.001
https://doi.org/10.1016/j.livsci.2016.11... ). In this experiment, lines might have affected the development of hatching offspring. There were significant differences between the lines in the deposition of many amino acids in albumen, such as Arg, Asp, Gly, His, Leu, Met, and Thr, which might affect the development of hatching offspring. However, no differences in the total deposition in albumen were found between the lines. Furthermore, there was no significant difference between lines in the deposition in yolks. In addition, research by Yin et al. (1996)Yin, Q.; Han, Y. and Zhang, Z. Y. 1996. Studies on the requirements and models of essential amino acids and protein in the peak for laying hens. Journal of Northeast Agricultural University. showed that Met could affect the development of hatching offspring. These results indicated that selecting divergently for abdominal fat did not change the total deposition level of amino acids in egg albumen and yolks, despite the difference in abdominal fat percentage (4.28% in the fat line and 1.22% in the lean line) at seven weeks of age (Wang et al., 2009Wang, H.; Wang, Q.; Wang, S.; Hu, G. and Li, H. 2009. Comparative analysis of body fat traits and serum biochemical parameters between broiler lines divergently selected for abdominal fat content. Journal of Northeast Agricultural University 40:76-80.).

In terms of fatty acid deposition, this selection for abdominal fat also caused no significant differences between the lines. A significant line effect on the deposition of 21:0 in egg yolk was found. Moreover, in LL and FL, there were significant differences between the lines in the deposition of 18:1n-9t, 22:0, and TFA. In terms of LN and FN, there was a significant difference between the lines in the deposition of 22:0. These results may be related to abdominal fat percentage.

The contents of amino and fatty acids in maternity are very important for the development of the embryo and are related to their deposition in eggs. Studying the changes in amino and fatty acids in eggs laid by hens with different maternal dietary intake levels may help to explain the nutritional mechanism controlling embryonic development through maternal nutrition. Under healthy circumstances, maternal blood, body tissues, and eggs are in a state of dynamic equilibrium. Generally, the amino acids in the embryo are derived from the decomposition of the small intestine and the maternal dietary intake (Heo et al., 2015Heo, J. M.; Woyengo, T. A.; Kahindi, R. K.; Kiarie, E.; Maiti, P. K. and Nyachoti, C. M. 2015. Ileal amino acid digestibility in egg from hyperimmunized-hens fed to weaned pigs and piglet response to diets contain egg products. Animal Feed Science and Technology 204:52-61. https://doi.org/10.1016/j.anifeedsci.2015.03.006
https://doi.org/10.1016/j.anifeedsci.201... ). Amino acids in the feed are absorbed into the blood. The amino acids are fed directly into the fallopian tube and ovaries. The content of amino acids deposited in egg yolk and albumen by feeding is approximately 15-20% of the total amount (Salter et al., 1971Salter, D. N.; Coates, M. E. and Westgarth, D. R. 1971. Studies on the incorporation of 14C-labelled amino acids into egg proteins. British Poultry Science 12:483-498. https://doi.org/10.1080/00071667108415904
https://doi.org/10.1080/0007166710841590... ). Therefore, the proportions of amino acids in eggs should be similar to the proportions of amino acids in the hen.

Lysine, Met, and Thr are the essential amino acids. With adequate maternal dietary intake of amino acids, this dynamic balance can be maintained. At this time, hen egg yield and egg production may be maintained at a high level. With insufficient maternal dietary intake of amino acids, body tissues in hens will be broken down to meet the amino acid needs of laying eggs (Yin et al., 1996Yin, Q.; Han, Y. and Zhang, Z. Y. 1996. Studies on the requirements and models of essential amino acids and protein in the peak for laying hens. Journal of Northeast Agricultural University.). This situation would destroy the dynamic equilibrium and probably cause weight loss in the hens.

In this experiment, low maternal dietary intake significantly increased the deposition of 17 amino acids in egg yolks. Different levels of protein in the diet had little effect on the protein content and chemical composition of egg. When the protein level in the diet rose from 8 to 13%, the amino acid content and amino acid ratio in the egg did not change significantly (Yin et al., 1996Yin, Q.; Han, Y. and Zhang, Z. Y. 1996. Studies on the requirements and models of essential amino acids and protein in the peak for laying hens. Journal of Northeast Agricultural University.). However, the protein content in eggs increased when the protein level in the diet rose from 11 to 16% (Babatunde and Fetuga, 1976Babatunde, G. M. and Fetuga, B. L. 1976. Effects of protein levels in the diets of layers on the egg production rate and the chemical composition of poultry eggs in the tropics. Journal of the Science of Food and Agriculture 27:454-462. https://doi.org/10.1002/jsfa.2740270512
https://doi.org/10.1002/jsfa.2740270512... ). Similar to the findings of Yin et al. (1996)Yin, Q.; Han, Y. and Zhang, Z. Y. 1996. Studies on the requirements and models of essential amino acids and protein in the peak for laying hens. Journal of Northeast Agricultural University., low maternal dietary intake did not significantly change the amounts of 17 amino acids in egg albumen and yolk in this experiment (except Cys in yolk).

Dietary factors can affect the deposition of amino acids in eggs. Nimalaratne et al. (2011)Nimalaratne, C.; Lopes-Lutz, D.; Schieber, A. and Wu, J. 2011. Free aromatic amino acids in egg yolk show antioxidant properties. Food Chemistry 129:155-161. https://doi.org/10.1016/j.foodchem.2011.04.058
https://doi.org/10.1016/j.foodchem.2011.... reported a significant difference in the deposition of amino acids of egg yolks between two groups whose hens were fed two different diets. These effects are mainly related to the source of amino acids in the feed. The addition of free Met or Cys to the diet of hens had no effect on the Met or Cys content of the egg (Csonka et al., 1947Csonka, F. A.; Denton, C. A. and Ringel, S. J. 1947. The methionine and cystine content of hen's eggs. The Journal of Biological Chemistry 169:259-265.; Carvalho et al., 2018Carvalho, T. S. M.; Sousa, L. S.; Nogueira, F. A.; Vaz, D. P.; Saldanha, M. M.; Triginelli, M. V.; Pinto, M. F. V. S.; Baiao, N. C. and Lara, L. J. C. 2018. Digestible methionine+cysteine in the diet of commercial layers and its influence on the performance, quality, and amino acid profile of eggs and economic evaluation. Poultry Science 97:2044-2052. https://doi.org/10.3382/ps/pey036
https://doi.org/10.3382/ps/pey036... ), but those in peptide bondage could increase their level in yolk (Csonka, 1950Csonka, F. A. 1950. Nitrogen, methionine and cystine content of hen's eggs. Their distribution in the egg white and yolk. The Journal of Nutrition 42:443-451. https://doi.org/10.1093/jn/42.3.443
https://doi.org/10.1093/jn/42.3.443... ).

In this research, similarly, 0.08% free Met was added to the diet. Therefore, more free Met was taken in the normal dietary intake group, but there was no increase of Met in the yolk. Csonka (1950)Csonka, F. A. 1950. Nitrogen, methionine and cystine content of hen's eggs. Their distribution in the egg white and yolk. The Journal of Nutrition 42:443-451. https://doi.org/10.1093/jn/42.3.443
https://doi.org/10.1093/jn/42.3.443... reported that the Cys:Met ratio increases in the egg yolk during the low protein dietary regimen. In this experiment, low maternal dietary intake increased the deposition of Cys in egg yolks. This was most probably due to the low maternal dietary intake that improved the conversion of Cys from hens to eggs. In the case of low protein intake, Cys is deposited more efficiently in the yolk. Further research is needed to understand the mechanism of the change in the amount of Cys in egg yolk caused by maternal low protein intake.

In this experiment, low maternal dietary intake increased the deposition of most amino acids in egg yolks of the fat line but did not affect those amino acids of the lean line. Usually, the amino acid content in egg yolks is affected by egg yolk weight and fatty acid content. These results may be related to the mobilization and deposition of fatty acids in the fat line.

Chickens are an oviparous animal. Chicken embryonic development is carried out in a closed environment, and the environment can protect the embryo from many external factors. These characteristics make this animal of particular value to biologists in many aspects of research.

The energy and nutrients needed for the development of chicken embryos are mainly provided by the nutrients stored in the eggs. Egg yolk provides 90% of the energy needed for embryonic development in the form of fatty acids (Haron et al., 2017Haron, A.; Dahan, Y.; Shinder, D. and Druyan, S. 2017. Physiological effects of hypoxic conditions during the plateau period on the chicken embryo. Comparative Biochemistry and Physiology Part A: Molecular & Integrative Physiology 203:32-39. https://doi.org/10.1016/j.cbpa.2016.08.015
https://doi.org/10.1016/j.cbpa.2016.08.0... ). Whether polar or neutral fatty acids, the fatty acids most absorbed by the embryo were 16:0, 16:1, 18:0, 18:1n-9c, and 18:2n-6c, followed by 14:1, 17:0, 18:1n-9t, 18:3n-6, and 20:3n-6.

Unsaturated fatty acids (UFA) can promote growth, eliminate free radicals, reduce blood cholesterol, and improve blood rheology and microcirculation (Cobos et al., 2000Cobos, A.; Veiga, A. and Dı́az, O. 2000. Chemical and fatty acid composition of meat and liver of wild ducks (Anas platyrhynchos). Food Chemistry 68:77-79. https://doi.org/10.1016/S0308-8146(99)00164-8
https://doi.org/10.1016/S0308-8146(99)00... ). The 18:1n9c and 18:3n6 are essential amino acids for birds. These amino acids can promote metabolism and prevent certain diseases. In this experiment, low maternal dietary intake significantly increased the deposition of 14:1 and 18:3n-6. However, in terms of 18:2n-6c, there was no significant difference between the two different maternal dietary intakes.

Dietary fatty acid composition can affect the fatty acid composition in egg yolks, which may affect the embryonic development and hatching rate (Kraisoon et al., 2018Kraisoon, A.; Navanukraw, C.; Inthamonee, W. and Bunma, T. 2018. Embryonic development, luteal size and blood flow area, and concentrations of PGF2α metabolite in dairy cows fed a diet enriched in polysaturated or polyunsaturated fatty acid. Animal Reproduction Science 195:291-301. https://doi.org/10.1016/j.anireprosci.2018.06.007
https://doi.org/10.1016/j.anireprosci.20... ). The fatty acid 16:0 in the diet can increase the level of 18:1n-9c in the egg yolk and the level of 18:2n-6c in the embryo, which meet the requirements of embryonic growth and hatching. Adding corn oil, 16:0, 18:1n-9c, or 18:2n-6c to the basal diet could increase the hatchability and reduce embryo mortality at the later stages of hatching (Vilchez et al., 1990Vilchez, C.; Touchburn, S. P.; Chavez, E. R. and Chan, C. W. 1990. The influence of supplemental corn oil and free fatty acids on the reproductive performance of Japanese quail (Coturnix coturnix japonica). Poultry Science 69:1533-1538. https://doi.org/10.3382/ps.0691533
https://doi.org/10.3382/ps.0691533... ). Supplementation with 16:0 could improve the growth of egg yolk, and corn oil could increase the content of 18:2n-6c in eggs, which has been shown to increase embryonic survival and hatching and alter fat metabolism of the offspring (Vilchez et al., 1990Vilchez, C.; Touchburn, S. P.; Chavez, E. R. and Chan, C. W. 1990. The influence of supplemental corn oil and free fatty acids on the reproductive performance of Japanese quail (Coturnix coturnix japonica). Poultry Science 69:1533-1538. https://doi.org/10.3382/ps.0691533
https://doi.org/10.3382/ps.0691533... ; Vilchez et al., 1992Vilchez, C.; Touchburn, S. P.; Chavez, E. R. and Chan, C. W. 1992. Effect of feeding palmitic, oleic, and linoleic acids to Japanese quail hens (Coturnix coturnix japonica). 2. Maternal diets and stage of incubation on the lipid metabolism of quail embryos. Poultry Science 71:1032-1042. https://doi.org/10.3382/ps.0711032
https://doi.org/10.3382/ps.0711032... ). These studies show that different proportions of fatty acids in the diet can influence the ratio of fatty acids in eggs and embryonic development.

From the aspect of feed intake, free fatty acids and very-low deposition lipoprotein in serum could be increased by low maternal dietary intake, which shows that a low maternal dietary intake severely affects lipid metabolism in broilers (Zhan et al., 2007Zhan, X. A.; Wang, M.; Ren, H.; Zhao, R. Q.; Li, J. X. and Tan, Z. L. 2007. Effect of early feed restriction on metabolic programming and compensatory growth in broiler chickens. Poultry Science 86:654-660. https://doi.org/10.1093/ps/86.4.654
https://doi.org/10.1093/ps/86.4.654... ). Moreover, according to Li et al. (2018)Li, F.; Mou, S. Y.; Liu, Y.; Jiang, D.; Wang, C.; Chen, Y. L.; Ren, H. L. and Xu, L. M. 2018. Maternal dietary energy levels affected the lipid deposition of offspring embryos at the end of the laying period of broiler breeder hens. Italian Journal of Animal Science 17:180-183. https://doi.org/10.1080/1828051X.2017.1345665
https://doi.org/10.1080/1828051X.2017.13... , a low maternal dietary energy level could improve serum low-deposition lipoprotein-cholesterol level and affect lipid metabolism in embryos. These changes in lipid metabolism (fatty acid compositions in plasma) were caused by changes in fatty acid deposition in yolk, and changes in fatty acid deposition were caused by maternal dietary intake. Similarly, we also found that reducing the dietary intake of hens can cause changes in fatty acid patterns. In our experiments, low maternal dietary intake increased the levels of certain UFA in yolks and the ratio of total PUFA to total SFA, which might affect the development of embryos.

Conclusions

There are significant interactions between feed intake and line on the deposition of some kinds of fatty acids in egg yolks. The fat line has higher deposition of several kinds of amino acids in the albumen than the lean line. Low maternal dietary intake increases the deposition of cystine in egg yolk and changes the fatty acid profiles of egg yolk.

Acknowledgments

We thank the Poultry Breeding Group of the College of Animal Science and Technology of the Northeast Agricultural University for providing the birds. This study was supported by the Education Department Research Program of Heilongjiang Province [12531006].

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Publication Dates

Publication in this collection
12 Sept 2019
Date of issue
2019

History

Received
15 Dec 2018
Accepted
03 Apr 2019

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] Al-Daraji, H. J.; Al-Mashadani, A. A.; Al-Hayani, W. K.; Al-Hassani, A. S. and Mirza, H. A. 2012. Effect of in ovo injection with L-arginine on productive and physiological traits of Japanese quail. South African Journal of Animal Science 42:139-145. https://doi.org/10.4314/sajas.v42i2.6
» https://doi.org/10.4314/sajas.v42i2.6

[2] Babatunde, G. M. and Fetuga, B. L. 1976. Effects of protein levels in the diets of layers on the egg production rate and the chemical composition of poultry eggs in the tropics. Journal of the Science of Food and Agriculture 27:454-462. https://doi.org/10.1002/jsfa.2740270512
» https://doi.org/10.1002/jsfa.2740270512

[3] Bhanja, S. K.; Hotowy, A.; Mehra, M.; Sawosz, E.; Pineda, L.; Vadalasetty, K. P.; Kurantowicz, N. and Chwalibog, A. 2015. In ovo administration of silver nanoparticles and/or amino acids influence metabolism and immune gene expression in chicken embryos. International Journal of Molecular Sciences 16:9484-9503. https://doi.org/10.3390/ijms16059484
» https://doi.org/10.3390/ijms16059484

[4] Bhattacharyya, A.; Majumdar, S.; Bhanja, S. K.; Mandal, A. B. and Kadam, M. 2018. Effect of maternal dietary manipulation and in ovo injection of nutrients on the hatchability indices, post-hatch growth, feed consumption, feed conversion ratio and immunocompetence traits of turkey poults. Journal of Applied Animal Research 46:287-294. https://doi.org/10.1080/09712119.2017.1296843
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Item		1 to 6 weeks	7 to 18 weeks	19 to 24 weeks	24 to 50 weeks
Ingredient (g/kg)
	Corn	678.5	731.9	686.2	628.8
	Soybean meal	282.0	196.5	231.8	235.0
	Soybean oil	4.0	0.0	0.0	0.0
	Fish meal	0.0	0.0	4.0	30.0
	Rice hulls	0.0	39.0	11.3	0.0
	Salt	1.5	2.0	3.0	3.0
	CaHPO₄	17.0	15.0	20.0	16.0
	Limestone	12.5	10.6	38.5	82.0
	DL-methionine	0.2	0.7	0.8	0.8
	L-lysine	0.0	0.0	0.2	0.2
	Choline chloride	1.0	1.0	1.0	1.0
	Vitamin premix¹ 1 Vitamin premix provided per kilogram of diet: vitamin A, 12,000 IU; cholecalciferol, 2400 IU; vitamin E, 30 IU; riboflavin, 9 mg; pantothenic acid, 12 mg; niacin, 35 mg; cobalamin, 12 µg; biotin, 0.2 mg; folic acid, 1.5 mg; thiamine, 2.0 mg; pyridoxine, 4.5 mg.	0.3	0.3	0.2	0.2
	Mineral premix² 2 Mineral premix provided per kilogram of diet: Fe, 80 mg; Zn, 80 mg; Mn, 100 mg; I, 1.0 mg; Cu, 8 mg; Se, 0.30 mg.	3.0	3.0	3.0	3.0
Nutrient composition³ 3 Calculated values.
	Metabolizable energy (MJ/kg)	12.10	11.82	11.61	11.64
	Crude protein	179.0	147.0	161.0	170.9
	Arginine	12.0	9.3	10.5	11.4
	Histidine	4.9	4.0	4.4	4.8
	Isoleucine	7.4	5.9	6.6	7.2
	Leucine	16.0	13.6	14.6	15.4
	Lysine	9.2	7.0	8.2	9.2
	Methionine	3.0	3.1	3.4	4.1
	Cystine	3.0	2.5	2.7	2.8
	Phenylalanine	8.7	7.1	7.8	8.3
	Tyrosine	6.2	5.2	5.6	6.0
	Threonine	6.8	5.5	6.1	6.7
	Tryptophan	2.0	1.6	1.8	1.9
	Valine	8.3	6.7	7.4	8.0
	Octadecadienoic	16.4	17.1	16.3	15.1
	Calcium	10.6	9.1	20.8	34.9
	Phosphorus	7.5	6.6	8.0	6.5
	Available phosphorus	4.6	4.0	5.3	4.9
	Ether extract	33.7	30.3	29.5	30.2
	Crude fiber	32.2	45.6	34.4	28.4
	Ash	25.4	28.6	25.3	25.8
	Neutral detergent fiber	105.5	99.2	99.5	94.2
	Acid detergent fiber	48.1	41.6	43.5	42.1
	Starch	440.7	471.6	443.9	407.5

Age (weeks)	Feed allocation (g/bird/day)
Age (weeks)	Normal maternal dietary intake	Low maternal dietary intake
27	150.0	112.6
29	170.0	127.6
33	167.0	125.4
43	163.0	122.4
58	156.0	117.0

Amino acid	Lean line	Fat line	Normal intake	Low intake	Lean line		Fat line		Pooled SEM	P-value
Amino acid	Lean line	Fat line	Normal intake	Low intake	Normal intake	Low intake	Normal intake	Low intake	Pooled SEM	Line	Feed intake	Line × intake
Alanine	10.04	10.59	10.32	10.31	10.05	10.04	10.59	10.58	0.515	NS	NS	NS
Arginine	5.88b	6.23a	6.05	6.06	5.87	5.90	6.24	6.22	0.234	0.042	NS	NS
Aspartic acid	9.07b	9.55a	9.28	9.33	9.02	9.11	9.55	9.55	0.335	0.047	NS	NS
Cystine	0.97	1.03	1.01	1.00	0.98	0.97	1.04	1.03	0.050	NS	NS	NS
Glutamic acid	10.02	10.49	10.22	10.28	9.96	10.07	10.48	10.49	0.364	NS	NS	NS
Glycine	11.41b	12.05a	11.70	11.75	11.35	11.46	12.05	12.04	0.440	0.044	NS	NS
Histidine	2.40b	2.55a	2.46	2.50	2.39	2.42	2.53	2.57	0.096	0.033	NS	NS
Isoleucine	5.23	5.50	5.34	5.39	5.20	5.27	5.49	5.51	0.197	NS	NS	NS
Leucine	8.26b	8.70a	8.45	8.50	8.21	8.31	8.70	8.70	0.287	0.034	NS	NS
Lysine	7.39	7.70	7.53	7.56	7.36	7.43	7.71	7.69	0.292	NS	NS	NS
Methionine	3.77b	4.03a	3.91	3.89	3.74	3.79	4.08	3.99	0.172	0.031	NS	NS
Phenylalanine	6.21	6.53	6.37	6.37	6.19	6.23	6.54	6.51	0.268	NS	NS	NS
Proline	7.28	7.69	7.52	7.46	7.31	7.26	7.72	7.65	0.379	NS	NS	NS
Serine	4.44	4.63	4.52	4.55	4.41	4.48	4.63	4.63	0.148	NS	NS	NS
Threonine	5.39b	5.67a	5.52	5.54	5.36	5.43	5.68	5.66	0.184	0.038	NS	NS
Tyrosine	4.99	5.32	5.20	5.11	5.04	4.93	5.35	5.30	0.401	NS	NS	NS
Valine	6.26	6.61	6.41	6.47	6.22	6.30	6.59	6.63	0.266	NS	NS	NS
Total	115.64	121.83	118.57	118.90	115.27	116.02	121.88	121.79	4.760	NS	NS	NS

Amino acid	Lean line	Fat line	Normal intake	Low intake	Lean line		Fat line		Pooled SEM	P value
Amino acid	Lean line	Fat line	Normal intake	Low intake	Normal intake	Low intake	Normal intake	Low intake	Pooled SEM	Line	Feed intake	Line × intake
Alanine	11.70	11.83	11.53	12.00	11.79	11.60	11.26	12.40	0.566	NS	NS	NS
Arginine	10.22	10.34	10.06	10.50	10.27	10.17	9.86	10.82	0.419	NS	NS	NS
Aspartic acid	11.47	11.44	11.25	11.67	11.55	11.39	10.95	11.94	0.433	NS	NS	NS
Cystine	1.02	1.00	0.98b	1.04a	1.01	1.03	0.95	1.05	0.040	NS	0.033	NS
Glutamic acid	12.26	12.07	11.93	12.39	12.31	12.20	11.56	12.58	0.461	NS	NS	NS
Glycine	13.47	13.50	13.20	13.78	13.52	13.43	12.88	14.13	0.542	NS	NS	NS
Histidine	3.59	3.60	3.50	3.69	3.60	3.58	3.41	3.79	0.148	NS	NS	NS
Isoleucine	7.41	7.48	7.28	7.60	7.45	7.37	7.12	7.84	0.285	NS	NS	NS
Leucine	12.09	12.10	11.84	12.34	12.12	12.05	11.57	12.63	0.442	NS	NS	NS
Lysine	10.98	11.06	10.79	11.26	11.03	10.93	10.54	11.58	0.462	NS	NS	NS
Methionine	3.47	3.46	3.41	3.52	3.50	3.43	3.32	3.60	0.151	NS	NS	NS
Phenylalanine	6.26	6.20	6.07	6.40	6.23	6.29	5.90	6.50	0.244	NS	NS	NS
Proline	11.09	11.34	10.99	11.43	11.15	11.03	10.83	11.84	0.474	NS	NS	NS
Serine	7.27	7.27	7.12	7.41	7.30	7.23	6.95	7.60	0.279	NS	NS	NS
Threonine	8.23	8.23	8.05	8.40	8.26	8.20	7.85	8.60	0.305	NS	NS	NS
Tyrosine	6.87	7.36	7.09	7.13	7.04	6.69	7.15	7.58	0.548	NS	NS	NS
Valine	7.66	7.69	7.47	7.89	7.66	7.66	7.27	8.11	0.325	NS	NS	NS
Total	155.29	155.95	152.45	158.80	156.00	154.58	148.90	163.01	6.250	NS	NS	NS

Fatty acid	Lean line	Fat line	Normal line	Low line	Lean line		Fat line		Pooled SEM	P value
Fatty acid	Lean line	Fat line	Normal line	Low line	Normal intake	Low intake	Normal intake	Low intake	Pooled SEM	Line	Feed intake	Line × intake
Tetradecenoic (14:1)	0.21	0.24	0.20b	0.25a	0.20	0.22	0.19	0.29	0.039	NS	0.047	NS
Palmitic (16:0)	82.31	83.79	84.48	81.62	85.72	78.89	83.23	84.35	3.384	NS	NS	NS
Palmitoleic (16:1)	10.37	10.79	10.43	10.73	10.95	9.80	9.91	11.66	1.242	NS	NS	NS
Heptadecanoic (17:0)	4.58	4.92	4.58	4.91	4.31	4.84	4.86	4.98	0.280	NS	NS	NS
Stearic (18:0)	24.88	26.07	26.20	24.74	26.36	23.39	26.04	26.10	1.065	NS	NS	NS
Trans oleic acid (18:1n-9t)	0.35	0.40	0.37	0.38	0.38ab	0.32b	0.36b	0.45a	0.039	NS	NS	0.009
Oleic acid (18:1n-9c)	134.96	140.75	138.72	136.99	142.34	127.57	135.09	146.41	10.877	NS	NS	NS
Linoleic (18:2n-6c)	40.28	42.62	39.19	43.71	39.65	40.92	38.72	46.51	4.005	NS	NS	NS
Linolenic (18:3n-6)	0.36	0.36	0.33b	0.39a	0.35	0.37	0.32	0.41	0.029	NS	0.012	NS
Heneicosanoic acid (21:0)	0.06b	0.09a	0.07	0.08	0.06	0.06	0.09	0.10	0.014	0.002	NS	NS
Docosanoic (22:0)	0.11	0.11	0.12a	0.09b	0.15a	0.07c	0.10bc	0.12ab	0.020	NS	0.033	0.002
Eicosatrienoic (20:3n-6)	0.49	0.50	0.46	0.52	0.49	0.48	0.44	0.56	0.051	NS	NS	NS
∑ TFA² 2 Total fatty acids=16:0+17:0+18:0+21:0+22:0+14:1+16:1+1 8:1n-9t+18:1n-9c+18:2n-6c+18:3n-6+20:3n-6.	314.61	326.44	320.87	320.19	326.90ab	302.34b	314.84ab	338.05a	16.663	NS	NS	0.049
∑ SFA³ 3 Saturated fatty acids=16:0+17:0+18:0+21:0+22:0.	113.47	116.56	117.02	113.01	118.20	108.75	115.85	117.27	4.287	NS	NS	NS
∑ MUFA⁴ 4 Monounsaturated fatty acids=14:1+16:1+18:1n-9t+18:1n-9c.	146.74	153.02	150.59	149.17	154.75	138.73	146.42	159.62	11.107	NS	NS	NS
∑ PUFA⁵ 5 Polyunsaturated fatty acids=18:2n-6c+18:3n-6+20:3n-6.	54.40	56.87	53.26	58.01	53.95	54.86	52.57	61.16	4.256	NS	NS	NS
∑ n-6	47.44	49.91	46.30	51.06	46.92	47.97	45.68	54.15	4.150	NS	NS	NS
∑ n-3	6.66	6.65	6.65	6.65	6.74	6.58	6.56	6.73	0.391	NS	NS	NS
∑ PUFA:∑ SFA ratio	4.80	4.89	4.55b	5.15a	4.54	5.07	4.56	5.23	0.343	NS	0.020	NS