1. Introduction
Manganese (Mn) is an indispensable trace element, necessary for the normal development and activity of tissues [
1]. It is an important component of enzymes involved in growth, carbohydrate and lipid metabolism, and blood clotting [
2,
3]. Earlier study has shown that dietary Mn is essential for the prevention of the deformity of the tibiae and metatarsi of chickens [
4]. Numerous recent studies have proved that Mn plays an important role in immune function [
5], meat quality [
6] and reproductive performance of broilers [
2]. Due to the low Mn content in corn–soybean meal diets [
7] used in production and the inefficient intestinal absorption of Mn in broilers [
8], it is necessary to supplement diets with Mn [
2]. It is also known that exposure to excessive Mn is related to severe damage to the liver, lungs and the reproductive and immune systems in broilers [
9]. All the foregoing indicates the need for optimizing supplemental provision of Mn to broilers.
As the very important strain of broilers, the yellow-feathered broiler is famous for the great meat quality. Nowadays, the production of yellow-feathered broilers has been approximately 4 billion annually, almost same as white-feathered broilers. Work from this group optimized supplemental Mn for yellow-feathered breeder hens during the peak period of laying at 90 to 135 mg/kg [
10], while the nutritional requirements of yellow-feathered broilers during growth to market size remains incomplete. In the current study, a hypothesis was formulated that dietary supplemental Mn affected the growth performance, tibial development, immune function and meat quality of yellow-feathered broilers in dose-dependence, and diets with different supplementations of Mn were used to determine the optimized dietary supplemental Mn for yellow-feathered broilers. The results will provide a rational recommendation for the appropriate dietary nutrient levels for yellow-feathered broilers.
2. Material and Methods
2.1. Experimental Design
Chinese yellow-feathered male broilers (Lingnan, rapidly growing yellow-feathered broilers) were used to assess effects of supplemental level of Mn during starter, grower and finisher phases of growth.
Starter phase (d 1 to 21): 1920 hatchlings were randomly divided into 8 groups, 6 replicates per treatment, 40 birds per replicate, and birds were fed a basal diet (16 mg/kg Mn) supplemented with 0, 20, 40, 60, 80, 100, 120 or 140 mg/kg Mn (MnSO4).
Grower phase (d 22 to 42): 1,440 broilers were raised during the starter phase on a diet containing 20 mg/kg Mn (to reduce Mn deposition in organs) then allocated to the same 8 supplemental treatments, each with 6 replicates of 30 birds; the basal grower diet contained 17 mg/kg Mn. Broilers were supplemented with the same levels of Mn as above.
Finisher phase (d 43 to 63): Broilers that had previously received diets containing 80 mg/kg Mn at the starter phase (the current recommendation for starter phase) and 20 mg/kg Mn at the grower phase (to reduce Mn deposition in organs) were used. Birds at 43 d (n = 800) were randomly assigned to the 8 supplemental Mn treatments as before, using a basal diet containing 14 mg/kg Mn; each treatment consisted of 5 replicates of 20 broilers.
2.2. Experimental Diets and Chicken Husbandry
The diets were formulated as Chinese Feeding Standard of Chicken recommended [
11], with the exception of Mn. Details of ingredient composition and calculated nutrient contents of basal diets were given (
Table 1). The Mn concentration in basal diets was determined as described previously [
12] and is showed in
Table 2. In brief, diets were weighed and digested with HNO
3 and HClO
4, and Mn concentration was determined by inductively coupled argon plasma spectroscopy [
12].
Water and diets were provided ad libitum throughout. The room temperature was kept at 32 to 34 °C at the first 3 days and reduced to a final temperature of 26 °C (2 °C per week). The light cycle was 24L:0D from d 1 to d 2, 23L:1D from d 3 to d 10, and 18L:6D from d 11 with incandescent bulbs. Birds were raised in floor pens with wood shavings litter, and the stocking density was 0.20, 0.27, and 0.40 m2/bird during the three phases of growth, respectively.
2.3. Measurement of Growth Performance and Carcass Traits
Birds were weighed at the beginning and end of each 3-wk growth phase on a per replicate basis. The final body weight, average daily gain, average daily feed intake and feed/gain ratio were calculated as previously described [
13].
At the end of each phase, 2 birds close to average BW per replicate were deprived of feed overnight and weighed immediately prior to slaughter. The birds were electrically stunned and exsanguinated. The spleen, thymus and bursa of Fabricius were dissected, blotted and weighed. The relative weight of immune organs was calculated. Relative weight = the immune organ weight/live weight × 100%.
2.4. Measurement of Tibial Charcteristics
Two pairs of tibias of the birds dissected above were collected for analyses. Tibias were cleaned from all adherent tissues. For the left tibia, the bone breaking strength was determined with a materials tester (Instron 4411, Instron Corporation, Grove City, PA, USA), as described by Wang et al. [
10]. For the right tibia, it was blotted dry with paper towels and then weighted; the length and diameter were measured with a caliper; the mineral density was measured with an X-ray osteodensitometer (Lunar Prodigy, General Electric Company, Fairfield, CT). Tibias (2 g) were ashed at 600 °C to constant weight (less than 0.5 mg before and after incineration) [
14], and the content of Mn in bone ash was measured using inductively coupled argon plasma spectroscopy, according to the method described previously [
12].
2.5. Determination of Meat Quality
Breast muscles (the whole left
pectoralis major) of the chosen birds were collected and kept at 4 °C. Shear force 45 min post-mortem, and drip loss 24 h post-mortem was determined as previously described [
13]. In brief, muscle samples were cut, weighed and placed in a plastic bag filled with air in 4 °C for 24 h. The drip loss was determined: drip loss = (weight
24h − weight
0h)/weight
24h * 100% [
13]. The muscles were cooked to an internal temperature of 70 °C. After cooling to room temperature, segments 1 cm
2 were cut perpendicular to the fiber orientation of the muscle then 10 sections about 3 cm thick were cut parallel to the fiber orientation to determine the shear force [
13].
2.6. Statistical Analysis
A replicate (pen for the determination of growth performance and bird for other indicators) served as the experimental unit. The effects of Mn supplementation were analyzed by a one-way ANOVA procedure (SPSS Inc., Chicago, IL, USA). Means were separated by Duncan’s multiple range test. Where appropriate, polynomial regressions were fitted to test for linear and quadratic effects in response to Mn supplementation [
15]. When a significant quadratic component was demonstrated (
p < 0.05), regression analyses were used to estimate supplemental Mn optimization (the maximum response from a quadratic model).
4. Discussion
Manganese takes a crucial part in biological processes, including the metabolism of lipid, protein, and carbohydrate [
16]. Several studies showed that Mn improved the growth performance of broilers. Ross 708 male broilers fed corn–soy diets with elevated levels of Mn at 80, 120 or 160 mg/kg had improved feed conversion ratio [
17]. Manganese at 45 to 130 mg/kg significantly increased the BW of broilers from 1 to 49 d [
7]. For the Gushi Broiler, another Chinese yellow-feathered strain, the highest weight gain was obtained when chicks received 90 mg/kg dietary Mn [
18]. The effects of supplemental Mn on the performance of broilers were inconsistent, however, and several studies failed to demonstrate any beneficial effects of supplemented Mn on BW or F/G [
19,
20]. The current study with yellow-feathered broilers showed that supplemental Mn improved the growth performance during the starter and grower phase broilers but was without effect on that during the finisher phase. Considering growth performance, supplementation with 120 and 54 mg/kg was optimal for yellow-feathered broilers at the starter and grower phases, achieving the lowest F/G or highest ADG, respectively.
Manganese has been proved to be important in supporting normal immune functions in broilers [
21]. The present study indicated that there were benefits of supplemental Mn on thymic relative weights at both 42 d and 63 d. A previous study showed that the supplementation of 75 to 100 mg/kg Mn (to basal diets containing 23.3 to 26.4 mg/kg Mn) of chickens enhanced the humoral immune response and increased antibody titers against Newcastle disease virus [
19], and for broilers, Mn supplementation also enhanced the antibody titer to sheep red blood cells and improved the cell immunity of basophil sensitization to plant lectins [
5,
16]. The reason for Mn improving immunity may be from its contribution to activity of Mn superoxide dismutase (MnSOD) [
22], which is vital for the integrity of macrophages [
19], as MnSOD interacts with heterophils and macrophages through plasma membrane cells which act in the immune response [
21]. This effect of Mn in yellow-feathered broilers needs further study because supplemental Mn in mice enhanced phagocytosis of macrophages and natural killer cells by increasing IFN-γ [
16] and increased gene expression of
IFN-γ,
IL-1β,
IL-6, and
IL-8 in rat microglia and human monocyte-derived macrophages [
16,
23]. On the other hand, excessive Mn accumulated in the immune organs of birds exposed to high Mn and disturbed the balance of the microelements and induced immune suppression at the molecular level [
9]. Exposure to Mn particles in vitro was suggested to adversely affect the adaptive cellular response in viral-induced IFN-γ production [
24]. In the current research, optimal levels of supplemental Mn for the thymic index of yellow-feathered broilers were 94 and 110 mg/kg during the grower and finisher phases, achieving the most relative weight of the thymus.
Mn is essential for normal bone development in young chicks. Manganese is absorbed from the intestinal lumen [
25] into the hepatic portal vein and the bulk of the Mn accumulates in bone [
26]. Receiving 30 to 120 mg/kg dietary Mn induced an increase in tibial Mn content of cockerel chicks [
20], and the plasma [
27], hepatic, renal, and tibial [
17,
28] contents were higher in Mn-supplemented broilers than those in controls. Similarly, Mn content in the tibia of yellow-feathered broilers in all three phases examined here were obviously responsive to increasing levels of supplemental Mn. It is worth noting that the optimal levels of Mn to obtain the highest Mn content in tibia are 198 and 162 mg/kg for broilers during the starter and grower phases; however, in that situation, the dietary Mn level was considered to be too high so as to have negative influence on growth or health of broilers. Therefore, Mn content in the tibia is not suitable to be used as a sensitive indicator to evaluate the optimal level of supplemental Mn.
Dietary Mn is known to have profound effects on the skeleton. Manganese insufficiencies resulted in malformation of the epiphyseal plate of the tibia [
29], an enlargement of the intertarsal joint, and either twisting or shortening of the tibia [
4,
8]; furthermore, Mn deficiency is also related to osteoporosis [
8], and Mn-deficient diets lead to decreased ash content and length of leg bones in chicks [
30]. It was found here that dietary supplementation with Mn improved tibial parameters during all the growth phases. Similarly, broilers fed Mn at 160 mg/kg exhibited improved tibial breaking strength [
17]. It has been demonstrated that manganese is involved in bone regulation through many paths. Mangnese is important in the synthesis of mucopolysaccharides [
2,
4,
5,
26] which are major constituents of bone extracellular matrixes and central to the development of the physical problems [
30]. Manganese also participates through its contribution to enzyme activity within metabolic pathways involved in the formation of the skeletal system [
31]. Oliveira et al. [
31] suggested that improvements in the concentrations of Mn used as components of metalloenzymes are necessary for the synthesis of connective tissue. In addition, Mn played a significant role in the vitality of osteoblasts by regulating relative mRNA expression levels of
RANKL (receptor activator of nuclear factor κB ligand) and
OPG (osteoprotegerin), thus affected the normal development of the tibia [
8]. It is worth noting that excessive Mn may impair the absorption of other minerals and is related to severe damage to the physiological process of broilers [
7,
9]. In the current research, the bone density of broilers in the starter phase significantly decreased when supplemented with 140 mg/kg, indicating that 140 mg/kg might be excessive for broilers in the starter phase. The present study indicated that 52, 60, and 68 mg/kg supplemental Mn met the requirements of yellow-feathered broilers for bone density at the three growth phases.
In the current study, supplemental Mn did not affect the drip loss and shear force of breast muscle, which was similar with the research of Lu et al. [
32]. For color attributes, the L* and b* value of breast muscle were influenced by dietary Mn supplementation. Yang et al. [
3] suggested optimal dietary Mn supplementation was important for improving the muscle quality variables of chickens and 40 mg/kg additional Mn decreased L* value in breast muscle. Lu et al. [
6] also showed that Mn decreased b* value of leg muscle and influenced pH in breast muscle of Arbor Acres male broilers. An important factor contributing to reduced meat quality is lipid oxidation [
32]. Manganese is a component of MnSOD, the primary antioxidant enzyme protecting cells from oxidative stress, enhancing the antioxidant ability of scavenging excessive reactive oxygen species (ROS) and reducing lipid peroxidation in broilers [
33]. It was suggested that supplemental Mn might improve the meat quality of the yellow-feathered broilers studied here, probably by affecting MnSOD activities and reducing the content of malondialdehyde, an indicator reflecting the extent of lipid oxidation in meat, as noted by Lu et al. [
32] and Zhang et al. [
34]. For further study of Mn on the meat quality of yellow-feathered broilers, pH value and indicators for color attributes in muscles of birds post mortem should be considered.