Effects of Dietary Lycopene Supplementation on Plasma Lipid Profile, Lipid Peroxidation and Antioxidant Defense System in Feedlot Bamei Lamb

Article information

Asian-Australas J Anim Sci. 2015;28(7):958-965
*Corresponding Author: Hailing Luo. Tel: +86-10-62734597, Fax: +86-10-62734597, E-mail: luohailing@cau.edu.cn
State Key Laboratory of Animal Nutrition, College of Animal Science and Technology, China Agricultural University, Beijing 100193, China
Received 2014 November 20; Revised 2015 February 02; Accepted 2015 February 15.

Abstract

Lycopene, a red non-provitamin A carotenoid, mainly presenting in tomato and tomato byproducts, has the highest antioxidant activity among carotenoids because of its high number of conjugated double bonds. The objective of this study was to investigate the effect of lycopene supplementation in the diet on plasma lipid profile, lipid peroxidation and antioxidant defense system in feedlot lamb. Twenty-eight Bamei male lambs (90 days old) were divided into four groups and fed a basal diet (LP0, 40:60 roughage: concentrate) or the basal diet supplemented with 50, 100, and 200 mg/kg lycopene. After 120 days of feeding, all lambs were slaughtered and sampled. Dietary lycopene supplementation significantly reduced the levels of plasma total cholesterol (p<0.05, linearly), total triglycerides (TG, p<0.05) and low-density lipoprotein cholesterol (LDL-C, p<0.05), as well as atherogenic index (p<0.001), whereas no change was observed in high-density lipoprotein cholesterol (p>0.05). The levels of TG (p<0.001) and LDL-C (p<0.001) were decreased with the feeding time extension, and both showed a linear trend (p<0.01). Malondialdehyde level in plasma and liver decreased linearly with the increase of lycopene inclusion levels (p<0.01). Dietary lycopene intake linearly increased the plasma antioxidant vitamin E level (p<0.001), total antioxidant capacity (T-AOC, p<0.05), and activities of catalase (CAT, p<0.01), glutathione peroxidase (GSH-Px, p<0.05) and superoxide dismutase (SOD, p<0.05). The plasma T-AOC and activities of GSH-Px and SOD decreased with the extension of the feeding time. In liver, dietary lycopene inclusion showed similar antioxidant effects with respect to activities of CAT (p<0.05, linearly) and SOD (p<0.001, linearly). Therefore, it was concluded that lycopene supplementation improved the antioxidant status of the lamb and optimized the plasma lipid profile, the dosage of 200 mg lycopene/kg feed might be desirable for growing lambs to prevent environment stress and maintain normal physiological metabolism.

INTRODUCTION

There is an increase in the demand for lamb in China as people seek more protein and more diverse diets. Industrial agriculture based on large-scale monoculture is gradually becoming the dominant system of modern sheep farming, which implies that animals will face a variety of psychological and environmental stresses and consequent health risks. Due to cost and practicality, dietary modifications of ruminants are preferable to other methods of improving production and health. Recent studies have shown that diets enriched with antioxidant substances can be used to attenuate the negative effects of environmental stress, as the detrimental effects of environmental stress could be partly due to induction of oxidative stress (Bollengier-Lee et al., 1998; Seven et al., 2010; Chauhan et al., 2014).

Lycopene, a carotenoid antioxidant without provitamin-A activity, has recently received considerable scientific interest. Lycopene can provide a protection against damage caused by reactive oxygen species (ROS) (Di-Mascio et al., 1989; Jain et al., 1999), and thus prevent damage to cells and tissues as well as ameliorating genetic problems (Atish and Anil, 2013). Studies have showed that lycopene consumption has a cardioprotection effect in humans and animals (Arab and Steck, 2000; Rissanen, 2006) by up-regulating the redox status such as improving antioxidant enzyme activities and antioxidant vitamin contents (Luo and Wu, 2011), and optimizing the plasma lipid profile (Sahin et. al., 2006a; Upaganlawar and Balaraman, 2012). To our knowledge, the majority of lycopene-related studies have focused on humans and rodents (Jain et al., 1999; Atish and Anil, 2013; Aydin et al., 2013), while the cardioprotection and antioxidative effects exerted by lycopene have not previously been investigated in sheep.

A great quantity of by-products, mainly tomato peel and seeds, are generated by the tomato industry in Bayannaoer area of the autonomous province of Inner Mongolia, which is the second largest tomato planting and processing base after Xinjiang province. As an alterative solution for reducing the burden on environment, the agro-industrial byproducts are locally used as supplements in small ruminant diets and lambs on this diet perform very well in terms of growth and health. Tomato seeds and peel residues contain a great variety of biologically active substances, principally lycopene (Calvo et al., 2008), so whether the lycopene plays a positive role in the good effects of the byproduct is still not elucidated in sheep.

The objective of this study was, therefore, to investigate the effects of different levels of dietary tomato lycopene supplementation on plasma lipid profile, lipid peroxidation and antioxidant defense systems in feedlot Bamei lambs.

MATERIALS AND METHODS

The feeding trial was conducted at Fuchuan sheep farm, Bayannaoer city, Inner Mongolia, China (40°59′47″ N latitude and 107°34′50″ E longitude). The experiment lasted for 120 days, beginning on May 28, 2013 and ending on September 24, 2013. The climate of the location is classified as temperate continental monsoon climate. Maximum environmental temperatures registered throughout the experiment varied from 22°C to 36°C. The experiment was approved by the Institutional Animal Care Committee of China Agricultural University with the criteria in the Guide for the Care of Laboratory Animals (Beijing, China).

Animals and diets

Twenty-eight Bamei male lambs (a meat-type sheep developed in 2007) with average age of 3 months±10 days, an average initial live weight of 19.34±2.21 kg and the same genetic background were equally assigned, on the basis of body weight, into 4 dietary treatments of 7 animals each. All animals were kept in individual pens (2.5×1 m2) with sand bedding in an open-side barn, with a roof but without walls. All lambs were placed on the sunny side of shed in a line across the lateral direction and they were allowed visual contact with each other and had ad libitum access to water. The experimental period lasted 120 days and was preceded by an adaption period of two weeks.

Food grade lycopene powder (10.84% lycopene) was produced by Shanxi Sciphar Hi-tech Industry Co., Ltd, Xi’an, China. The control group (LP0) was fed a basal diet without lycopene supplementation. The other three groups were fed the basal diet with dietary lycopene supplementation at levels of 50 (LP50), 100 (LP100), and 200 (LP200) mg lycopene/kg feed, respectively. The ingredients and chemical composition of the basal diet, which was formulated according to NRC (2007), are shown in Table 1. The feed samples destined for chemical analyses were taken at the beginning, in the middle and at the end of the experimental period, then were pooled and analyzed in triplicate for crude protein (AOAC, 2000), neutral detergent fiber fractions and acid detergent fiber fractions (Van Soest et al., 1991). Gross energy content was measured using an adiabatic bomb calorimeter (Parr 1261, Parr Instrument Company, Moline, IL, USA). The crude fat was determined by extracting the sample with petroleum ether using an automatic soxhlet extractor (Gerhardt Analytical Systems, Konigswinter, Germany). During the trial, each lamb was fed twice daily at 6:00 and 17:00. Orts were recorded daily.

Ingredients and chemical composition of the basal diet fed to the lambs1

Sample preparation

At day 30, 60, 90, and 120 of the trial period, 10 mL blood was taken from jugular vein of each lamb into heparin sodium tube (vacuum blood collection) at 6:00 AM prior to the morning feeding, and then immediately centrifuged at 3,000 r/m for 10 min at 4°C to obtain plasma. The plasma was divided into aliquots for storage at −20°C till analysis.

At the end of 120-day feeding trial, sheep were fasted overnight with free access to water and slaughtered in the local abattoir using Halal methods (Sen et al., 2006). The liver was sampled and stored at −80°C till analysis.

Analytical procedure

Concentrations of total cholesterol (TC), high-density lipoprotein cholesterol (HDL-C), low-density lipoprotein cholesterol (LDL-C) and total triglycerides (TG) in plasma were measured enzymatically on an automatic analyzer (Hitachi 7600, Tokyo, Japan); Atherogenic index (AI) was estimated using the formula of AI = (TC − HDL)/HDL.

The concentrations of Vitamin E and Vitamin A in plasma were determined by high performance liquid chromatography (HPLC), following precipitation of proteins by ethanol and extraction of the supernatant in hexane. The hexane layer was transferred to a test tube and evaporated to dryness in a 60°C water bath under a stream of nitrogen gas. The residue was re-dissolved immediately in 0.5 mL of methanol and transferred to an amber glass vial equipped with screw cap and PTFE/rubber septa. Samples were analyzed by normal phase HPLC (Dikma Diamonsil-C18, 250×4.6 mm, 5 μm, 100Å ) fitted with variable wavelength ultraviolet detector (Agilent Series 1200, Santa Clara, CA, USA). The mobile phase was methanol: water (98:2, v/v) at a constant flow rate of 1 mL/min. The injection volume was 20 μL. The detection wavelength was set to 230 nm and 265 nm for vitamin E and vitamin A respectively. Results were presented in mg/L.

Malondialdehyde (MDA) level of lipid peroxides, total antioxidant capacity (T-AOC), and activities of catalase (CAT), glutathione peroxidase (GSH-Px) and superoxide dismutase (SOD) in plasma and liver were determined using commercially available assay kits (Institute of Biological Engineering of Nanjing Jianchen, Nanjing, China). Liver homogenates were centrifuged at 2,500 r/m for 10 min at 4°C to remove crude fractions, and the resulting supernatants were used for the determination of enzymatic activities by spectrophotometric methods using a spectrophotometer (UV-1800PC, Shanghai mapada instruments Co., Ltd., Shanghai, China). All of the assays followed the instructions of the kits. Liver protein was measured by the method of coomassie brilliant blue and detected at 595 nm. The MDA level was presented in nmol/mL in plasma or nmol/mg protein in liver, and the enzyme activity was presented in unit/mL plasma or unit/mg protein.

Statistical analyses

Blood parameters data of lipid profile and antioxidant enzymes were analyzed using repeated measures of general linear model (GLM) in IBM SPSS Statistics 21.0 (Statistical Product and Service Solutions, IBM Corporation, New York, NY, USA), which consists of diet treatment, sampling time and treatment×sampling time interaction. Means were separated using least significant difference and presented as means±standard error in tabular form. When the interaction was not significant but the main effects of treatment and/or sampling time were significant, difference among all means was tested separately with least significant difference multiple-range tests. Statistical significance was declared at p≤0.05.

The content of plasma vitamins and activities of liver antioxidant enzymes were subjected to GLM procedures of SPSS. Differences among means were tested by least significant difference comparisons. Orthogonal polynomial contrasts were used to examine the linear effects of increasing levels of lycopene in the diet. In the orthogonal polynomial analysis, coefficients were corrected because of unequal spacing of treatments. A value of p≤0.05 was used to indicate statistical significance.

RESULTS

Plasma lipids profile

The effects of varying levels of dietary lycopene supplementation and sampling time on plasma lipid profile in sheep are presented in Table 2. The levels of plasma TC (p<0.01), TG (p<0.05) and LDL-C (p<0.05) were reduced in lycopene-supplemted groups, compared to the control group, and the level of TC showed a significant linear trend (p<0.05) with the increasing of lycopene levels. Compared to the control group, there was a significant decrease in AI (p<0.001) as the decrease of plasma TC and the numerical increment of HDL-C level in lycopene treatments, although no treatment effect was observed in HDL-C level (p>0.05). The levels of TG (p<0.01) and LDL-C (p<0.001) were decreased with the feeding time extension, and both showed a linear trend (p<0.01). There was no interaction in plasma lipid profile between treatment and sampling time.

Effects of varying levels of dietary lycopene supplementation and sampling time on plasma lipid profile in feedlot sheep

Lipid peroxidation

In Table 3, plasma MDA level was significantly affected by treatment and sampling time, in which dietary lycopene decreased the concentration of plasma MDA (p<0.001), while sampling time showed the reverse pattern with the extension of the feeding time (p<0.05, linearly). In liver, dietary lycopene had the same positive effect for MDA as that in plasma (p<0.01), especially for LP200 treatment, significantly lower than the LP0 and LP50 treatments.

Effect of varying levels of dietary lycopene on plasma and liver malondialdehyde (MDA) levels in feedlot sheep

Antioxidant defense system

As shown in Figure 1, plasma vitamin E level was largely increased with the increase of lycopene supplementation levels in the diets after supplementation for 120 days (p<0.001). The mean level of vitamin E increased linearly by 130% from LP0 treatment to LP200 treatment (p<0.001). No significant difference was observed among the treatments with respect to content of vitamin A (p>0.05).

Figure 1

Effect of different dietary lycopene levels on plasma vitamin A and vitamin E levels in feedlot Bamei sheep. Values with different letters are highly significantly different (p<0.01). Vertical bars are standard deviations. LP, lycopene; LP0 = No LP; LP50, 50 mg LP/kg feed; LP100, 100 mg LP/kg feed; LP200, 200 mg LP/kg feed.

Effects of varying levels of dietary lycopene on T-AOC and antioxidant enzymes activities in plasma and liver are presented in Table 4 and 5, respectively. In Table 4, dietary lycopene intake linearly increased the plasma T-AOC (p<0.05), although no significant difference was found among all treatments (p>0.05). The activities of GSH-Px (p<0.05), CAT (p<0.01) and SOD (p<0.05) in lycopene-supplemented groups were all increased linearly, especially in LP100 and LP200 treatments, compared to the control group. As for sampling time, the activities of plasma T-AOC, GSH-Px, and SOD were decreased with the extension of the feeding time (Table 4). There was no variation for liver T-AOC and GSH-Px activity among the four treatment groups (Table 5). Similar to the situation in plasma, activities of liver CAT (p<0.05) and SOD (p<0.001) were linearly increased with the increase in dietary lycopene supplementation levels (Table 5), especially significantly in LP200 treatments, compared to LP0 group.

Effects of varying levels of dietary lycopene and sampling time on plasma T-AOC and antioxidant enzymes activities in sheep

Effect of varying levels of dietary lycopene on liver T-AOC and antioxidant enzymes activities (nmol/mg protein) in feedlot sheep

DISCUSSION

Sheep in intensive farming system are frequently exposed to a variety of stressors, including environmental and psychological ones. In the present study, our experiment was conducted in summer and the average maximum temperature was 29°C (extreme temperatures reached 36°C in July and August). Experimental animals were exposed to the sun from 9:30 am to 5:00 pm because the roof of the shed was 3 meters high and the animals were arranged on the sunny side of the barn. Sheep tend to be less susceptible to heat stress than other animal species such as swine and cattle due to the presence of the wool cover (Marai, 2007). We observed that the lambs were panting at the daytime. In addition, all lambs were kept in individual pens and they were observed to become very vocal and agitated when separated from their flock mates, which posed a great psychological or emotional distress as sheep are flock animals and strongly gregarious (Nowak et al., 2008). Both factors above are stressors for lambs and they are associated with increased ROS production (Mujahid et al., 2005; Wang et al., 2007; Sahin et al., 2011). Superfluous ROS induced by stress can disturb the balance between oxidant and antioxidant systems. Thus lambs need to be supplemented with adequate antioxidant by diets to improve the antioxidant status. Herbal antioxidants were shown to have the ability to scavenge excessive free radicals in vivo and thus affect antioxidant defense in sheep (Nieto et al., 2010; Ortuno et al., 2014). In our experiment, we examined the effects of lycopene supplementation on antioxidant defense enzymes like SOD, GSH-Px, and CAT and non-enzymes such as vitamins A and E. The results showed significant increasing tendencies for these enzymes activities and the content of antioxidant vitamin E, which demonstrated an improvement in antioxidant status of the sheep as a result of the supplementation with lycopene. Lycopene is the single most potent natural carotenoid oxygen quencher (Di-Mascio et al., 1989; Rao and Agarwal, 1999; Agarwal and Rao, 2000). It can inactivate hydrogen peroxide and nitrogen dioxide (Bohm et al., 1995). Because of the lack of studies regarding lycopene as dietary supplement in ruminant animals, the results of the present experiment are not comparable with literature. However, the positive impacts of lycopene supplementation on antioxidant status are in agreement with previous studies done in other animal species such as rat, poultry and fish (Breinholt et al., 2000; Sahin et al., 2006a; 2014). In sheep, Sgorlon et al. (2006) had confirmed that tomato pomace, containing 1.3% lycopene, was able to counterbalance oxidative stress in sheep by inducing specific transcriptional activity of genes involved in oxidant defenses. We previously found that dry matter intake had a linear increase with an increased addition of lycopene (p<0.05), which were 943, 989, 1,055, and 1,023 g/d for LP0, LP50, LP100, and LP200 groups respectively. The average daily weight gain increased by 8.54%, 12.20%, and 7.32% in LP50, LP100 and LP200 treatments, respectively, compared to LP0 group (unpublished data), also implying that lycopene supplementation seems to ameliorate the stress suffered by lambs. In addition, the observed decrease in activities of the antioxidant enzymes (T-AOC, GSH-Px, and SOD) with the extension of the feeding time suggests a lower oxidative status in lambs, the reason for which might be that animal gradually adapted to the stress and thus their anti-stress capability correspondingly enhanced with the growth.

Stress can disturb the balance between the production of ROS and antioxidant systems and results in oxidative injury such as lipid peroxidation (Sahin et al., 2014). Lipid peroxides and their products can cause damage to membrane-bound enzymes and other macromolecules, including DNA, and have been implicated in several disease processes (Sahin et al, 2006b; 2008). In the present study, the contents of plasma and liver MDA showed a significantly decrease trend in a linear manner with the increase of lycopene supplement levels. MDA is one of the most frequently used indicators of lipid peroxidation associated with oxidative stress (Aksu et al., 2010). The decrease in plasma and liver MDA levels could be due to the ability of lycopene to affect antioxidant defense system. Similar to our results, Sahin et al. (2006; 2008; and 2014) reported that quail and rainbow trout supplemented with lycopene had a significant reduction in MDA values in serum and liver.

Antioxidant properties of lycopene were thought to be primarily responsible for its biological effects (Sahin et al, 2006a; 2011; 2014), which may be important in the prevention from chronic diseases associated with oxidative stress such as cardiovascular diseases. Studies have provided evidence in support of the protective effect of lycopene on a favorable lipid profile (Sahin et al., 2006a; Napolitano et al., 2007; Ried and Fakler, 2011). In the present study, our data showed that the plasma TC, TG, and LDL-C levels (p<0.05) were reduced in lycopene supplemented groups, compared to the control group, meanwhile, the values of TG (p<0.01) and LDL-C maintained a decreased trend with the feeding time extension, which demonstrated the cardioprotection effect of lycopene in sheep. Amarenco et al. (2007; 2008) reported that free radicals were excessively generated in all living organisms as a result of increased metabolic activities induced by the stress and were presumed to trigger degenerative diseases like atherosclerosis, which is positively correlated with serum LDL-C and inversely correlated with HDL-C. Stress exposure also increases the levels of blood TC and TG and supplementation of antioxidants decreases these elevated levels (Sahin et al., 2006a; Marai, 2007). Similar effects of different antioxidants on the lipid metabolism have been reported (Oshima et al., 1996). To the best of our knowledge, this is the first study to evaluate the effect of lycopene supplementation on blood lipid parameters measured in sheep. Fuhrman et al. (1997) demonstrated that tomato lycopene, when used as dietary supplement at 60 mg/d, significantly decreased plasma LDL-C and TG concentration without affecting HDL-C in macrophages. Likewise, Silaste et al. (2007) found that the average plasma TC and LDL-cholesterol were reduced by 5.9% and 12.9%, respectively, in healthy normocholesterolemic adults after high daily dietary intake of tomato juice and ketchup for a period of 3 weeks, without any change in the concentrations of HDL-cholesterol and triglycerides. In addition to its antioxidant properties, lycopene has been proposed to reduce cholesterol levels by its suppression of cholesterol synthesis, increase of LDL degradation, and inhibition of the hydroxy-methyl-glutaryl-coenzyme, a (HMGCoA)-reductase enzyme (Fuhrman et al., 1997), which needs to be further investigated in sheep. In our experiment, we speculated that the positive effect on lipid metabolism for lycopene could be related to the antioxidative effect of lycopene, reflected by higher vitamin E levels and antioxidant enzyme activities as well as lower MDA concentration in lycopene-supplemented groups.

CONCLUSION

In conclusion, the present study showed that lycopene supplementation improved plasma and liver antioxidant capacities in feedlot Bamei lambs during summer. In addition, it reduced lipid peroxidation and improved the lipid profile, thus offering an effective strategy to decrease the risk of developing diseases related to oxidative stress. Based on the data in lipid profile, MDA and antioxidant defense system in the present study, the level of 200 mg/kg lycopene in the diet is recommended for growing lambs to counter environment stress and keep normal physiological metabolism.

ACKNOWLEDGMENTS

The authors wish to express their gratitude to Dr. Elaine Grings (South Dakota State University) for her comments and corrections on this manuscript. This research was supported by projects of the China Agricultural Ministry (CARS-39 and 200903060). We appreciate the assistance of Kun Liu and Zhaoyun Zuo in obtaining the samples.

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Figure 1

Effect of different dietary lycopene levels on plasma vitamin A and vitamin E levels in feedlot Bamei sheep. Values with different letters are highly significantly different (p<0.01). Vertical bars are standard deviations. LP, lycopene; LP0 = No LP; LP50, 50 mg LP/kg feed; LP100, 100 mg LP/kg feed; LP200, 200 mg LP/kg feed.

Table 1

Ingredients and chemical composition of the basal diet fed to the lambs1

Items Basal diet
Ingredients (%, as fed basis)
 Chinese wildrye grass hay, ground 32
 Alfalfa hay, ground 8
 Corn 34
 Soybean meal 8.9
 Dried distilled grain solubles 9.0
 Wheat bran 5.5
 Salt 0.5
 Limestone 0.3
 Dicalcium phosphate 0.5
 Sodium bicarbonate 0.3
 Minerals and vitamin premix2 1.0
Chemical composition (%, as-fed basis)
 Dry matter 91.7
 Gross energy (MJ/kg) 15.98
 Crude protein 13.93
 Crude fat 2.51
 Neutral detergent fiber 35.98
 Acid detergent fiber 17.89
1

Experimental diets were supplemented with 0, 50, 100, and 200 mg lycopene/1 kg basal diet.

2

Per kilogram of diet: 23 mg Fe, 28 mg Zn, 17 mg Mn, 6 mg Cu, 0.04 mg I, 0.2 mg Se, 0.1 mg Co, 3,700 IU vitamin A, 1,000 mg vitamin D3, 60 IU vitamin E.

Table 2

Effects of varying levels of dietary lycopene supplementation and sampling time on plasma lipid profile in feedlot sheep

TC (mmol/L) TG (mmol/L) HDL-C (mmol/L) LDL-C (mmol/L) AI1
LP2
 LP0 1.68±0.09a 0.64±0.02a 0.59±0.03 0.61±0.04a 2.00±0.20a
 LP50 1.36±0.06b 0.60±0.01ab 0.61±0.03 0.51±0.04ab 1.27±0.07b
 LP100 1.44±0.06b 0.61±0.01ab 0.65±0.04 0.51±0.03ab 1.24±0.08b
 LP200 1.39±0.04b 0.59±0.01b 0.66±0.03 0.48±0.04b 1.16±0.11b
Time3
 Day 30 1.49±0.07 0.66±0.02a 0.67±0.02 0.63±0.03a 1.27±0.14
 Day 60 1.36±0.07 0.60±0.01b 0.58±.03 0.56±0.03a 1.46±0.16
 Day 90 1.42±0.08 0.57±0.01b 0.60±.04 0.45±0.04b 1.42±0.13
 Day 120 1.61±0.09 0.59±0.01b 0.65±0.04 0.46±0.03b 1.54±0.15
Statistical significance
 LP ** * NS * ***
 Time NS *** NS *** NS
 LP×time NS NS NS NS NS
 Linear
 LP * NS NS NS NS
 Time NS ** NS *** NS

TC, total cholesterol; TG, total triglyceride; HDL-C, high density lipoprotein-cholesterol; LDL-C, low density lipoprotein-cholesterol; AI, atherogenic index ; LP, lycopene; NS, not significant.

1

AI = (TC-HDL)/HDL.

2

LP0, no LP; LP50, 50 mg LP/kg feed; LP100, 100 mg LP/kg feed; LP200, 200 mg LP/kg feed.

3

Time means sampling time at day 30, 60, 90, and 120 of feeding.

a,b

Means with different small letters within LP or time in the same column are significantly different (p<0.05).

*

p<0.05;

**

p<0.01;

***

p<0.001.

Table 3

Effect of varying levels of dietary lycopene on plasma and liver malondialdehyde (MDA) levels in feedlot sheep

Items MDA

Plasma (nmol/mL) Liver (nmol/mg protein)
Treatment1
 LP0 3.83±0.32a 2.91±0.33a
 LP50 2.45±0.19b 2.70±0.32ab
 LP100 2.59±0.15b 1.81±0.14bc
 LP200 2.68±0.22b 1. 48±0.14c
 p-value *** **
 Linear ** **
Time2
 Day 30 2.05±0.13b
 Day 60 3.38±0.34a
 Day 90 2.93± 0.26a
 Day 120 3.21±0.14a
 p-value **
 Linear *

LP, lycopene.

1

LP0, no LP; LP50, 50 mg LP/kg feed; LP100, 100 mg LP/kg feed; LP200, 200 mg LP/kg feed.

2

Time means sampling time at day 30, 60, 90 and 120 of feeding.

a,b

Means with different small letters in the same row are significantly different (p<0.05).

*

p<0.05;

**

p<0.01;

***

p<0.001.

Table 4

Effects of varying levels of dietary lycopene and sampling time on plasma T-AOC and antioxidant enzymes activities in sheep

T-AOC CAT GSH-Px SOD
LP1
 LP0 17.87±0.68 9.51±0.49b 131.12±7.97b 68.13±5.58a
 LP50 19.40±0.86 10.70±0.64ab 154.19±7.31ab 81.89±4.41b
 LP100 20.53±1.14 12.25±0.51a 158.25±9.84ab 85.16±5.34b
 LP200 20.71±1.15 12.04±0.69a 180.02±12.72a 84.91±5.40b
Time3
 Day 30 22.42±0.80a 11.47±0.68 180.85±13.31a 91.74±2.29a
 Day 60 20.42±1.07ab 11.21±0.54 154.02±8.15ab 88.77±4.20a
 Day 90 18.17±1.05b 10.64±0.41 133.37±9.71b 81.29±4.44a
 Day 120 17.50±0.63b 11.06±0.76 155.34±6.44ab 58.29±6.31b
Statistical significance
 LP NS ** ** *
 Time ** NS * ***
 LP×time NS NS NS NS
Linear
 LP * ** * *
 Time *** NS NS ***

T-AOC, total antioxidant capacity; CAT, catalase; GSH-Px, glutathione peroxidase; SOD, superoxide dismutase; LP, lycopene; NS, not significant.

1

LP0, no LP; LP50, 50 mg LP/kg feed; LP100, 100 mg LP/kg feed; LP200, 200 mg LP/kg feed.

2

Time means sampling time at day 30, 60, 90, and 120 of feeding.

a,b

Means with different small letters within LP or Time in the same column are significantly different (p<0.05).

*

p<0.05;

**

p<0.01;

***

p<0.001.

Table 5

Effect of varying levels of dietary lycopene on liver T-AOC and antioxidant enzymes activities (nmol/mg protein) in feedlot sheep

Variables Treatment1 p value Linear

LP0 LP50 LP100 LP200
T-AOC 1.48±0.31 1.37±0.10 1.56±0.07 1.77±0.13 NS NS
CAT 62.09±2.56 70.72±4.92 73.37±3.82 75.89±3.56 NS *
GSH-Px 336.12±25.19 338.29±33.26 350.08±12.64 345.74±20.13 NS NS
SOD 40.47±0.62b 40.16±2.38b 48.13±1.79ab 54.86±3.76a ** ***

LP, lycopene; T-AOC, total antioxidant capacity; NS, not significant; CAT, catalase; GSH-Px, glutathione peroxidase; SOD, superoxide dismutase.

1

LP0, no LP; LP50, 50 mg LP/kg feed; LP100, 100 mg LP/kg feed; LP200, 200 mg LP/kg feed.

a,b

Means with different small letters in the same row are significantly different (p<0.05).

*

p<0.05;

**

p<0.01;

***

p<0.001.