The effect of enzymes on release of trace

Full text

Turn on search term navigation

* Research

* Open Access

The effect of enzymes on release of trace elements in feedstuffs based on in vitro digestion model for monogastric livestock

* Xiaonan Yu1,

* Jianan Han1,

* Haiyun Li1,

* Yiwei Zhang1 and

* Jie Feng1Email author

Journal of Animal Science and Biotechnology2018 9:73

https://doi.org/10.1186/s40104-018-0289-2

* Received: 24 May 2018

* Accepted: 23 August 2018

* Published: 15 October 2018

Abstract

Background

This experiment was conducted to study the effect of different feed enzymes (phytase, xylanase, β-glucanase) on release rate of trace elements (Fe, Cu, Mn and Zn) in 6 commonly used feedstuffs (corn, wheat, barley, soybean meal, wheat bran, wheat middlings) by using an in vitro model, simulating the digestive processes in stomach for 2 h and then in small intestine for 6 h at 39 °C.

Results

Phytase raised (P < 0.05) the release rate of Cu and Zn in corn, Cu, Zn and Mn in wheat, Cu in barley, Cu, Zn and Mn in soybean meal, Zn, Fe in wheat bran and Zn, Fe, Mn in wheat middlings. The release rate of various trace elements in feedstuffs was increased after xylanase addition. Compared with the control group, the release rate of soluble Cu in corn, wheat, barley and soybean meal, soluble Zn in corn, wheat and wheat middlings and soluble of Mn in corn, wheat, barley and wheat bran increased (P < 0.05) after xylanase treatment. After the treatment of β-glucanase, the release rate of soluble Cu in corn, wheat and wheat bran, soluble Fe in barley, soybean meal and wheat bran and soluble Mn in corn and wheat bran all increased (P < 0.05) compared with the control group. In each feedstuff, after corresponding enzyme treatment, the contents of phytic acid, xylan and β-glucan were significantly lower than those of the control group (P < 0.05).

Conclusions

Results showed that bound trace elements in feedstuffs can be released by feed enzymes. It may be necessary to take the trace elements in feedstuffs into account in the actual feed preparation including feed enzymes.

Keywords

* Feedstuffs

* Feed enzymes

* In vitro model

* Release rate

* Trace elements

Background

Trace elements are essential nutrients for animal growth. They play critical roles in various biochemical processes and functions and consequently, are generally supplemented as inorganic forms in the livestock diets [1]. The bioavailability of inorganic trace elements such as Cu and Zn is low, about 7%~ 15% and 5%~ 10%, respectively, in monogastric animals, which result in a large amount of trace elements (more than 95%) being excreted in feces and urine [2–4] to eventually reach ground water and soil. After years of manure spreading for agriculture purposes, trace elements may accumulate in soil at toxic levels, the feed and food plants grown on the metal-contaminated soil will also be polluted, thus bring potential threats to animals and people [4].

Feedstuffs contain a certain amount of trace elements, while often be ignored when configured in the actual feed formulation. This may result from the exist of anti-nutritional factors such as phytic acid and non-starch polysaccharides in feedstuffs, which affect the bioavailability of the trace elements [5–7]. Therefore, study on improving the release rate of trace elements in feedstuffs is of great significance on reducing the supplementation of exogenous trace elements in feed and the emission of them in animals’ feces or urine, thus saving feed costs and protecting environment.

Recently enzyme preparations such as phytase and NSP enzymes have been widely applied in feed industry to hydrolyze corresponding anti-nutritional factors and then improve nutrient digestion and absorption efficiency, for instance, the application of phytase could improve the utilization rate of Ca and P [8–11]. NSP enzyme such as xylanase and β-glucanase can increase apparent ileal digestibility of DM, CP, GE, AA and other nutrients [12–15]. According to the anti-nutritional factors’ binding capacity for trace elements in feedstuffs and reported effects of these enzymes, the release of trace elements in feedstuffs could be promoted by these feed additives. However, few studies have been reported on investigating whether these enzymes could release trace elements from feedstuffs while improving the digestion and utilization efficiency of other nutrients. Thus, this research was conducted to study the effect of different feed enzymes (phytase, xylanase, β-glucanase) on release rate of trace elements (Fe, Cu, Mn and Zn) in 6 commonly used feedstuffs (corn, wheat, barley, soybean meal, wheat bran, wheat middlings) using an in vitro model.

Methods

Feedstuffs

There were six different commonly used feedstuffs (corn, wheat, barley, soybean meal, wheat bran and wheat middlings) and each with 6 batches (n = 6). All 36 feedstuff samples were crushed and segregated by 40 mesh sieve.

Determination of trace elements in feedstuffs

Determination of Fe, Cu, Mn and Zn content in feedstuffs was done according to the national standard GB/T 13885–2003 [16]. Briefly, measured every element’s standard solution, reagent blank and test sample respectively by atomic absorption spectrometer (Thermo Scientific ICE 3300), read the concentration of the elements in the sample according to the standard curve. Measured 3 times for each sample and average. Contents of Cu, Zn, Fe and Mn of each sample are listed in Table 1.

Table 1

The content of Cu, Zn, Fe, Mn and anti-nutritional factors in feedstuffs

Feedstuffs

Batch

Cu, mg/kg

Zn, mg/kg

Fe, mg/kg

Mn, mg/kg

Phytic acid, g/100 g

Xylan, g/100 g

β-glucan, g/100 g

Corn

3.06

15.23

67.98

20.32

1.35

6.14

0.13

3.11

14.98

65.65

18.98

1.15

6.20

0.18

3.02

15.65

51.65

19.12

1.45

6.23

0.21

3.09

15.74

69.98

16.98

1.39

6.15

0.10

3.04

16.57

72.92

20.16

1.27

6.27

0.14

3.55

15.22

18.56

19.24

1.37

6.16

0.12

Wheat

7.06

37.98

87.65

52.65

1.52

7.89

0.97

7.12

40.23

90.23

49.65

1.37

8.47

0.73

7.03

39.98

88.98

53.65

1.48

7.29

0.68

7.05

38.32

89.98

55.65

1.46

8.72

0.81

7.20

30.41

86.16

48.59

1.33

7.84

0.85

7.31

41.54

95.64

60.43

1.41

7.93

0.82

Barley

6.12

32.32

62.12

36.65

1.38

5.47

4.34

5.98

33.32

61.98

34.32

1.74

5.69

4.19

6.06

29.65

59.32

32.65

1.53

6.37

4.24

9.11

31.02

60.98

35.98

1.24

5.83

4.56

5.56

17.85

59.01

39.69

1.62

5.15

4.16

7.38

34.32

62.27

30.00

1.47

5.73

4.35

Soybean meal

16.65

64.65

187.65

77.65

2.57

6.20

7.12

17.98

63.98

194.32

80.32

2.48

5.76

6.48

18.65

61.98

188.98

74.98

2.03

5.99

6.82

16.98

64.65

179.98

76.98

1.96

6.14

6.73

22.18

69.55

171.73

85.30

2.16

6.03

7.52

15.49

43.69

122.26

53.22

2.04

5.89

6.21

Wheat bran

12.98

75.32

231.32

154.32

3.73

19.84

13.62

13.12

73.65

209.98

159.32

3.10

19.07

14.76

13.06

73.49

213.32

152.32

3.27

20.73

13.79

13.03

74.19

221.46

149.98

4.42

21.56

13.97

13.21

75.76

209.76

160.10

3.85

18.69

14.25

13.64

74.59

242.48

144.18

3.77

20.48

14.00

Wheat middlings

13.12

84.98

105.32

106.65

2.41

18.05

20.01

12.98

91.32

99.98

110.32

2.46

18.17

20.37

12.89

82.98

112.32

102.65

2.61

17.84

19.64

13.09

85.65

106.65

111.45

2.32

19.47

21.58

13.77

90.92

115.41

171.93

2.55

17.03

18.23

10.87

68.51

100.49

102.35

2.39

17.92

19.85

Determination of anti-nutritional factors in feedstuffs

The determination of phytic acid content in feedstuffs was according to the “Standard determination of phytic acid in food” [17]. Xylan and glucan contents in all samples were determined according to the Laboratory Analytical Procedure of “Determination of Structural Carbohydrates and Lignin in Biomass” (Version 2012) from National Renewable Energy Laboratory (NREL) [18]. Contents of anti-nutritional factors of each sample are listed in Table 1.

Digestion of feedstuffs based on the in vitro model

In vitro digestion was done according to S. Boisen’s method [19, 20], can be divided into two steps including the simulated stomach and the small intestine digestion.

Simulated stomach digestion

For each sample, accurately weighed 12 copies of 3.0000 ± 0.0010 g finely crushed material into twelve 100 mL conical flasks. Divided them into 4 different treatment: 1) Phytase group: added 0.3 mL phosphate buffer (0.1 mol/L, pH 6.0) containing 300 μg phytase (5,000 U/g, Sun HY) to the sample; 2) Xylanase group: add 0.3 mL phosphate buffer (0.1 mol/L, pH 6.0) containing 75 μg xylanase (40,000 U/g, Sun HY) to the sample; 3) β-glucanase: add 0.3 mL phosphate buffer (0.1 mol/L, pH 6.0) containing 180 μg β-glucanase (5,000 U/g, Sun HY) to the sample; 4) Control: add 0.3 mL phosphate buffer (0.1 mol/L, pH 6.0) without enzyme to the sample. The amount of enzyme added was based on the product specification which meets the actual production requirement. Each flask was added 25 mL phosphate buffer (0.1 mol/L, pH 6.0) and a magnetic rob and kept magnetic stirring for 1 min, then the pH of the mixture was adjusted to 2.0 by adding HCl (1 mol/L). After 1 mL of pepsin solution containing 25 mg pepsin (3,000 NFU/mg, Ameresco No.0685) and 0.5 mL chloramphenicol ethanol solution added, digested in the water bath (SHJ - A6) at 39 °C for 2 h and stirring slowly and continuously to simulate feed digestion in the stomach.

Simulated small intestine digestion

After the process of simulated digestion in the stomach, added 10 mL phosphate buffer (0.2 mol/L, pH 6.8) and then adjusted pH to 6.8 by HCl (1 mol/L) or NaOH (1 mol/L). Finally added a magnetic rob and 1 mL the pancreatin solution containing 50 mg porcine pancreatin (≥4 UPS,Sigma No.P-l750) were added into the mixture. Digested for 6 h in water bath (SHJ - A6) at 39 °C, stirring slowly and constantly to simulate feed digestion in the small intestine.

After digestion, filtrated the digestive production through 0.45 μm filter membrane. Supernatant and the residue were collected separately after filtration.

Determination of trace elements in the supernatant

Put the supernatant in 250 mL conical flask with plug, added 25 mL mixed acid (nitric acid: perchloric acid = 4:1, volume ratio), soaked overnight, and then kept heating until the digestive solution became colorless and transparent or slightly yellow. After cooling, diluted the digested product with 1% nitric acid solution to 50 mL. Determination of trace elements content in the supernatant was done according to the national standard GB/T 13885–2003 [16] as described above.

Determination of anti-nutritional factors in feedstuffs after digestion

The contents of phytic acid, xylan and β-glucan in feedstuffs after digestion were determined according to the determination of anti-nutritional factors in feedstuffs as described above.

Data calculation

The release rate of trace elements in feedstuffs were calculated by the following formula:

Release rate (%) = Cs / CT × 100%,

where Cs is the soluble trace element content which calculated by measured value in the supernatant and CT is the corresponding total trace element content.

The hydrolysis rate of anti-nutritional factors were calculated by the following formula:

Hydrolysis rate (%) =100% –AD / AF × 100%,

where AD is the and AF is the anti-nutritional factors content after digestion, AF is the corresponding anti-nutritional factors in feedstuffs .

Statistical analysis

The release rate of trace elements and the content of anti-nutritional factors in the feedstuffs after digestion in the feedstuffs after digestion are presented as mean ± standard deviation (SD). Means between groups were compared by one-way analysis of variance and Scheffe’s post-hoc test or non-parameter Kruskal-Wallis test (SPSS software, version 21). P < 0.05 was considered significant.

Results

The release rate of trace elements in corn

The release rate of trace elements after enzyme treatment in corn are shown in Table 2. The release rate of Cu in the phytase group, the xylanase group and the β-glucanase group was 50.94%, 28.97% and 30.92% higher, respectively than in the control group (P < 0.05). The release rate of Zn in phytase and xylanase groups were higher than the control group (P < 0.05). Xylanase and β-glucanase raised the release rate of Mn.

Table 2

The release rate of trace elements in corn

Trace elements

Control group

Enzyme preparation

Phytase

Xylanase

β-glucanase

Cu, %

40.09 ± 11.95c

91.03 ± 4.61a

69.06 ± 6.88b

71.01 ± 8.79b

Zn, %

60.09 ± 3.39b

90.42 ± 5.96a

90.63 ± 8.84a

64.78 ± 6.19b

Fe, %

43.95 ± 8.19

53.70 ± 2.92

50.58 ± 7.88

55.31 ± 5.15

Mn, %

13.12 ± 3.23c

17.67 ± 1.98c

30.35 ± 2.53b

68.52 ± 4.70a

a,b,cMeans values within a row not sharing a common letter differ significantly (P < 0.05)

The release rate of trace elements in wheat

The release rate of trace elements in wheat treated by enzyme preparations are shown in Table 3. The three enzyme preparations had a significant effect on the release of Cu in wheat (P < 0.05) and phytase and xylanase increased the release rate of Zn and Mn (P < 0.05).

Table 3

The release rate of trace elements in wheat

Trace elements

Control group

Enzyme preparation

Phytase

Xylanase

β-glucanase

Cu, %

19.61 ± 1.92d

52.99 ± 3.99b

64.88 ± 3.32a

32.02 ± 4.62c

Zn, %

7.48 ± 1.66b

30.62 ± 2.59a

33.66 ± 4.14a

11.38 ± 2.79b

Fe, %

10.90 ± 0.49c

36.49 ± 3.17b

50.42 ± 2.24a

11.52 ± 0.41c

Mn, %

20.68 ± 4.16b

46.35 ± 2.47a

43.32 ± 4.38a

14.99 ± 3.27b

a,b,c,dMeans values within a row not sharing a common letter differ significantly (P < 0.05)

The release rate of trace elements in barley

As can be seen from Table 4, the release rate of Cu in the phytase group and the xylanase group increased by 11.57% and 11.96% respectively (P < 0.05) compared with the control group. Treatment with β-glucanase increased the release rate of Fe (P < 0.05) and xylanase promote the release of Mn in barley (P < 0.05).

Table 4

The release rate of trace elements in barley

Trace elements

Control group

Enzyme preparation

Phytase

Xylanase

β-glucanase

Cu, %

25.85 ± 3.84b

37.42 ± 7.59a

37.81 ± 4.53a

30.19 ± 3.31ab

Zn, %

11.91 ± 1.86

20.18 ± 2.18

20.71 ± 3.12

18.99 ± 2.68

Fe, %

31.05 ± 1.56b

32.45 ± 2.27ab

33.14 ± 2.00ab

41.38 ± 4.98a

Mn, %

42.26 ± 5.22b

47.45 ± 2.30ab

54.70 ± 6.54a

50.00 ± 4.60ab

a,bMeans values within a row not sharing a common letter differ significantly (P < 0.05)

The release rate of trace elements in soybean meal

Table 5 presents the release rate of trace elements in enzyme-treated soybean meal. The release rate of Cu in the phytase group and xylanase group were significantly higher than in the control group (P < 0.05), while Fe release rate was higher in the β-glucanase group. Phytase raised the release rate of Zn and Mn (P < 0.05).

Table 5

The release rate of trace elements in soybean meal

Trace elements

Control group

Enzyme preparation

Phytase

Xylanase

β-glucanase

Cu, %

60.60 ± 5.79c

85.91 ± 8.25ab

91.06 ± 6.05a

74.08 ± 7.07bc

Zn, %

53.75 ± 7.34b

65.00 ± 3.42a

60.81 ± 4.49b

56.19 ± 4.95b

Fe, %

27.37 ± 2.48b

32.45 ± 2.27ab

31.61 ± 1.61b

33.23 ± 4.06a

Mn, %

15.57 ± 1.68b

21.07 ± 0.94a

16.73 ± 1.14b

17.34 ± 1.90b

a,b,cMeans values within a row not sharing a common letter differ significantly (P < 0.05)

The release rate of trace elements in wheat bran

As shown in Table 6, all enzyme preparations could significantly increase the release rate of Mn (P < 0.05). Compared with the control group, the release rate of Fe in phytase group and β-glucanase group increased by 11.33% and 6.72% respectively (P < 0.05), the release rate of Zn in phytase group increased by 48.82% (P < 0.05) and the release rate of Cu in β-glucanase group increased by 57.00% (P < 0.05).

Table 6

The release rate of trace elements in wheat bran

Trace elements

Control group

Enzyme preparation

Phytase

Xylanase

β-glucanase

Cu, %

19.10 ± 1.34b

56.35 ± 4.13ab

46.15 ± 1.75bc

67.92 ± 5.54a

Zn, %

5.29 ± 0.70b

62.29 ± 3.63a

33.65 ± 2.33ab

12.09 ± 0.83ab

Fe, %

11.33 ± 1.51b

21.66 ± 2.55a

13.19 ± 2.02b

18.05 ± 0.54a

Mn, %

6.83 ± 1.11c

28.74 ± 1.80a

13.97 ± 1.57b

14.98 ± 1.60b

a,b,cMeans values within a row not sharing a common letter differ significantly (P < 0.05)

The release rate of trace elements in wheat middlings

The release rate in wheat middlings after being treated by enzyme preparations are listed in Table 7. Compared with the control group, xylanase raised the release rate of Zn (P < 0.05) and phytase raised the release rate of Zn, Fe and Mn (P < 0.05).

Table 7

The release rate of trace elements in wheat middlings

Trace elements

Control group

Enzyme preparation

Phytase

Xylanase

β-glucanase

Cu, %

33.77 ± 1.44

35.69 ± 4.45

35.73 ± 2.10

38.83 ± 3.36

Zn, %

11.48 ± 1.42c

24.11 ± 3.08a

16.98 ± 1.67b

12.57 ± 0.68c

Fe, %

29.66 ± 1.36b

34.28 ± 3.09a

33.12 ± 2.06b

31.73 ± 2.27b

Mn, %

20.64 ± 0.92b

29.87 ± 1.73a

20.80 ± 1.52b

19.07 ± 1.60b

a,b,cMeans values within a row not sharing a common letter differ significantly (P < 0.05)

The digestion of anti-nutritional factors in feedstuffs

Figure 1 presents the digestion of anti-nutritional factors in feedstuffs. Figure 1a-c present the contents of phytic acid, xylan and β-glucan in feedstuffs after digestion respectively and Fig. 1d presents the hydrolysis rate of anti-nutritional factors after corresponding enzyme treatment. In each feedstuff, after corresponding enzyme treatment, the contents of phytic acid, xylan and β-glucan were significantly lower than those of the control group (P < 0.05). In corn, wheat, barley, soybean meal, wheat bran and wheat middlings, the phytic acid content of the phytase group was 58.41%, 66.42%, 58.88%, 64.20%, 49.52% and 52.23% lower than that of the control group, respectively (P < 0.05). Compared with the control group, treatment with xylanase reduced the xylan content in corn, wheat, barley, soybean meal, wheat bran and wheat middlings by 61.99%, 51.45%, 59.75%, 58.24%, 49.93% and 50.15%, respectively. The β-glucan content of the β-glucanase group in these feedstuffs decreased by 60.61%, 46.18%, 57.18%, 48.79%, 45.05% and 42.39% respectively compared with the control group. The hydrolysis rate of phytic acid in corn, wheat, barley, soybean meal, wheat bran and wheat middlings is 62.93%, 76.45%, 67.05%, 70.26%, 61.92% and 61.35%, respectively, xylan is 65.07%, 59.60%, 63.21%, 61.80%, 56.07% and 55.50%, respectively, and β-glucan is 65.22%, 53.07%, 62.53%, 50.89%, 50.80% and 49.18%, respectively.

Fig. 1 Fig. 1

Fig. 1

The digestion of anti-nutritional factors in feedstuffs. Values are means ± SD (n = 6). a, b and c present the phytic acid, xylan and β-glucan contents in feedstuffs after digestion respectively, d presents the hydrolysis rate of anti-nutritional factors after corresponding enzyme treatment. In each feedstuff, after corresponding enzyme treatment, the contents of phytic acid, xylan and β-glucan were significantly lower than those of the control group (P < 0.05)

Discussion

Plant-based feedstuffs contain various kinds of anti-nutritional factors such as phytic acid, xylan, β-glucan, which affect the digestive utilization of nutrients for livestocks. The amount of anti-nutritional factors differs among feedstuffs [5, 6].

Phytic acid, commonly called phytate, also known as inositol hexaphosphate (IP6). It is a strong chelator, which can chelating divalent and trivalent metal ions to form insoluble precipitate, thereby affecting the absorption of these elements. Several reports confirmed that phytase hydrolyze phytate and then release trace elements like Cu and Fe, making them more available to animals. Shelton et al. [21] reported that digestive utilization of Zn, Fe and Mn in pigs have been improved after supplementing diets with phytase. Revy et al. [22] had compared the bioavailability of Zn when piglets were fed with three different diets, basic rations (32 mg/kg Zn) with 20 mg/kg organic zinc, or inorganic zinc or 1,200 U/kg phytase and showed that phytase greatly improved the intestinal bioavailability of Zn and promote effective utilization of Ca, P, Mg, Fe and Cu. In another study [23], it was reported that phytase supplementation of diet increased Zn and Cu bioavailability significantly. Kim et al. [24] found that use of phytase can significantly improve the iron status of piglets and thus reduce adverse performance due to iron deficiency. The results of previous in vivo studies are consistent with the present in vitro one, where phytase greatly raised the release rate of Cu and Zn in corn, Cu, Zn and Mn in wheat, Cu in barley, Cu, Zn and Mn in soybean meal, Zn, Fe in wheat bran, Zn, Fe, Mn in wheat middlings. These results implied that phytic acid can not only inhibit the absorption of Ca and P, but also made it hard for monogastric livestock to absorb trace elements. The results of our research also suggested that phytic acid binds more strongly to Cu and Zn in these feedstuffs. According to the results of the digestion of phytic acid in feedstuffs (Fig. 1a and Fig. 1d) and the results above, it can be speculated that the digestion of phytic acid promotes the release of trace elements in feedstuffs. Therefore, phytic acid may be one of the main anti-nutritional factors which affect the release of trace elements in these feedstuffs.

Xylan is also called the Arab xylan, mainly consisted of Arab sugar and xylose [25]. Xylan constitutes most of cell wall NSP in corn, wheat and barley. Researches showed that the utilization rate of nutrients will be lower when livestocks are fed with excessive feedstuffs containing much xylan such as corn, wheat, barley, bran and so on, which resulted from the anti-nutritional effect of xylan that played the role by improving livestocks’ intestinal chyme viscosity, slowing down the movement speed of chyme in the digestive tract and changing the morphology of digestive tract [26–28]. In addition, as one of the NSP, xylan could easily form complexes with minerals by electrostatic interactions. It will be deprotonated at around neutral pH, and therefore ions like Ca2+, Fe2+ and Zn2+ will interact with the negative charged groups [29]. Xylanase supplementation of diets has been reported to improve the nutrient digestibility such as GE, AA, P, and Ca [30–33]. There is also an in vitro study showing that adding xylanase can release chelated zinc and iron in pearl millet grain [7].Our data showed that the release rate of various trace elements in feedstuffs had been increased after xylanase addition. Compared with the control group, after xylanase treatment, the release rate of Cu in corn, wheat, barley and soybean meal, the release rate of Zn in corn, wheat and wheat middlings and the release rate of Mn in corn, wheat, barley and wheat bran all increased significantly (P < 0.05). These findings suggest that xylan is one of the main anti-nutritional factors to bind Cu, Zn and Mn in cereal feed and its byproducts. Besides, xylanase performs better in increasing the release rate of trace elements in corn, wheat and barley. Based on our study on the digestion of xylan in feedstuffs (Fig. 1b and Fig. 1d), xylanase performs well on xylan digestibility in corn, wheat and barley. It could be inferred from the results above that xylan mainly affect the release of Cu, Zn and Mn in corn, wheat and barley.

β-glucan, like xylan, is also a member of NSP. It is present in most cereals and is particularly prevalent in barley and oats. β-glucan consists of a linear chain of glucose monomers linked by β-1-3 and β-1-4 linkages in different ratios [34, 35]. The effects of β-glucan on the absorption of nutrients for livestocks is mainly through the following four aspects: 1) β-glucan encrusting the cell wall and can bind the nutrients in the cell. 2) Its hydrophilicity cause the increase of water layer’s thickness on the intestinal mucosal surface. 3) Due to the presence of β-1-3 linkages, the microfibrils in β-glucan are more tightly packed together, giving them higher solubility than cellulose. Its solubility and considerable length can easily lead to the increase of intestinal viscosity, thus decrease the diffusion rate of enzyme and nutrients and impede well mix of them. 4) It increases chyme viscosity, slow down their movement, thus produce harmful microorganisms and acidic substance which greatly reduce enzymes’ effects [27, 36–38]. In addition, similar to the effect of xylan on electrostatic interactions, it can interact electrostatically with ions like Ca2+, Fe2+, Zn2+ to lower the efficiency of utilization. β-glucanase can crack β-glucan into small molecule and force β-glucan to lose hydrophilicity and thus reduce the viscosity of intestinal contents to improve absorption of nutrition in livestocks. Besides, β-glucanase will release intracellular nutrition by degrading the cell wall. In this study, after the treatment of β-glucanase, the release rate of soluble Cu in corn, wheat and wheat bran, the release rate of Fe in barley, soybean meal and wheat bran, the release rate of Mn in corn and wheat bran all increased significantly compared with the control group (P < 0.05). The results showed that β-glucan affect the release of Cu, Fe and Mn in these feedstuffs. Our data also indicated that β-glucanase had better impact on the release of trace elements in corn and wheat bran. After β-glucanase treatment, compared with the control group, the digestion of β-glucan of the β-glucanase group increased in all these feedstuffs (P < 0.05). According to the results above, we may infer that β-glucan mainly affect the release of trace elements in corn and wheat bran.

Conclusion

Anti-nutritional factors like phytate, xylan and β-glucan could inhibit digestion and absorption of trace elements, corresponding enzyme treatment could digest the anti-nutritional factors in conventional feedstuffs and thus release a certain amount of trace elements. Phytase performs better on the release of Cu and Zn in feedstuffs, xylanase has good effect on releasing Cu, Zn and Mn in cereal feed, β-glucanase improve the release rate of Cu, Fe and Mn and it performs better on corn and wheat bran.

Abbreviations

AA:

Amino acid

ANFs:

Anti-nutritional factors

CP:

Crude protein

DM:

Dry matter

GE:

Gross energy

NSP:

Non-starch polysaccharide

Declarations

Acknowledgements

We are grateful to Linjun Chen, Haoxuan Ding and Guohua Wang for the assistance with the digestion process, to Bojing Liu and Xinyang Dong for assistance with the measurement of trace elements and anti-nutritional factors. Moreover, we thank ZheJiang Kesheng Feed Stock Co., LTD for providing the feedstuffs.

Funding

This research was financially supported by the National Key R&D Program of China (No. 2016YFD0501201), National Natural Sciences Foundation of China (No. 31472102, No.31772607), and Zhejiang Provincial Key Science Project (No. 2015C03006).

Availability of data and materials

The datasets generated and/or analysed during the current study are available from the corresponding author on reasonable request.

Authors’ contributions

JF designed the research. XY, JH, HL and YZ collected data and samples. XY, JH and HL prepared the reagent and conducted the feedstuffs digestion. XY, JH and HL measured the contents of race elements and anti-nutritional factors. XY analyzed data and wrote the original draft. JF reviewed and edited the paper. All authors read and approved the final manuscript.

Ethics approval and consent to participate

Not applicable.

Consent for publication

Not applicable.

Competing interests

The authors declare that they have no competing interests.

Open AccessThis article is distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution, and reproduction in any medium, provided you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. The Creative Commons Public Domain Dedication waiver (http://creativecommons.org/publicdomain/zero/1.0/) applies to the data made available in this article, unless otherwise stated.

Authors’ Affiliations

(1)

Key Laboratory of Animal Nutrition & Feed Science, College of Animal Science, Zhejiang University, Hangzhou, 310012, People’s Republic of China

References

Hostetler CE, Kincaid RL, Mirando MA. The role of essential trace elements in embryonic and fetal development in livestock. Vet J. 2003;166:125–39.View ArticleGoogle Scholar

Cang L, Wang YJ, Zhou DM, Dong YH. Heavy metal pollution in poultry and livestock feeds and manures under intensive farming in Jiangsu Province. China J Environ Sci. 2004;03:371–4.Google Scholar

Li Y, Chen T. Concentrations of additive arsenic in Beijing pig feeds and the residues in pig manure. Resour Conserv Recy. 2005;45:356–67.View ArticleGoogle Scholar

Chary NS, Kamala CT, Raj DSS. Assessing risk of heavy metals from consuming food grown on sewage irrigated soils and food chain transfer. Ecotox Environ Safe. 2008;69:513–24.View ArticleGoogle Scholar

Elke H, Karl S. Fermentation of food and feed: a technology for efficient utilization of macro and trace elements in monogastrics. J Trace Elem Med Bio. 2016;37:69–77.View ArticleGoogle Scholar

Raes K, Knockaert D, Struijs K, Van CJ. Role of processing on bioaccessibility of minerals: influence of localization of minerals and antinutritional factors in the plant. Trends Food Sci Tech. 2014;37:32–41.View ArticleGoogle Scholar

Lestienne I, Caporiccio B, Besançon P, Rochette I, Trèche S. Relative contribution of phytates, fibers, and tannins to low iron and zinc in vitro solubility in pearl millet (Pennisetum glaucum) flour and grain fractions. J Agric Food Chem. 2005;21:8342–8.View ArticleGoogle Scholar

Tiwari SP, Gendley MK, Pathak AK, Gupta R. Influence of an enzyme cocktail and phytase individually or in combination in Ven cobb broiler chickens. Brit Poult Sci. 2010;51:92–100.View ArticleGoogle Scholar

Selle PH, Ravindran V. Microbial phytase in poultry nutrition. Anim Feed Sci Tech. 2007;135:1–41.View ArticleGoogle Scholar

Gonzálezvega JC, Walk CL, Stein HH. Effects of microbial phytase on apparent and standardized total tract digestibility of calcium in calcium supplements fed to growing pigs. J Anim Sci. 2015;93:2255–64.View ArticleGoogle Scholar

Letourneau-Montminy MP, Jondreville C, Sauvant D, Narcy A. Meta- analysis of phosphorus utilization by growing pigs: effect of dietary phosphorus, calcium and exogenous phytase. Animal. 2012;6:1590–600.View ArticleGoogle Scholar

Owusu-Asiedu A, Kiarie E, Peron A, Woyengo TA, Simmins PH, Nyachoti CM. Growth performance and nutrient digestibilities in nursery pigs receiving varying doses of xylanase and beta-glucanase blend in pelleted wheat-and barley-based diets. J Anim Sci. 2012;90:92–4.View ArticleGoogle Scholar

Kerr BJ, Shurson GC. Strategies to improve fiber utilization in swine. J Anim Sci Biotechnol. 2013;4:11–23.View ArticleGoogle Scholar

Clarke LC, Sweeney T, Curley E, Gath V, Duffy SK, Vigors S, et al. Effect of β-glucanase and β-xylanase enzyme supplemented barley diets on nutrient digestibility, growth performance and expression of intestinal nutrient transporter genes in finisher pigs. Anim Feed Sci Tech. 2018;238:98–110.View ArticleGoogle Scholar

Yin YL, Baidoo SK, Jin LZ, Liu YG, Schulze H, Simmins PH. The effect of different carbohydrase and protease supplementation on apparent (ileal and overall) digestibility of nutrients of five hulless barley varieties in young pigs. Livest Prod Sci. 2001;71:109–20.View ArticleGoogle Scholar

GB/T 13885–2003/ISO 6869:2000, Animal feeding stuffs-Determination of the contents of calcium, copper, Iron, magnesium, manganese, potassium, sodium and zinc-Method using atomic absorption spectrometry(In Chinese).Google Scholar

GB 5009.153–2016. Standard determination of phytic acid in food(In Chinese).Google Scholar

Sluiter A, Hames B, Ruiz R, Scarlata C, Sluiter J, Templeton D, Crocker D. Determination of Structural Carbohydrates and Lignin in Biomass. In: Laboratory analytical procedure. National Renewable Laboratory, NREL/ TP-510-42618, USA; 2012.Google Scholar

Boisen S, Fernandez JA. Prediction of the apparent ileal digestibility of protein and amino acids in feedstuffs and feed mixtures for pigs by in vitro analyses. Anim Feed Sci Tech. 1995;51:29–43.View ArticleGoogle Scholar

Boisen S, Fernandez JA. Prediction of the total tract digestibility of energy in feedstuffs and pig diets by in vitro analyses. Anim Feed Sci Tech. 1997;68:277–86.View ArticleGoogle Scholar

Shelton JL, LeMieux FM, Southern LL, Bidner TD. Effect of microbial phytase addition with or without the trace mineral premix in nursery, growing. and finishing pig diets J Anim Sci. 2005;83:376–85.PubMedGoogle Scholar

Revy PS, Jondreville C, Dourmad JY, Nys Y. Effect of zinc supplemented as either an organic or an inorganic source and of microbial phytase on zinc and other minerals utilisation by weanling pigs. Anim Feed Sci Tech. 2004;16:93–112.View ArticleGoogle Scholar

Adebiyi OA, Ologhobo AD, Agboola AS. Effects of microbial phytase supplementation on mineral composition of tibia and mineral utilization in broiler fed maize-based diets. Int J Poult Sci. 2009;8:570–3.View ArticleGoogle Scholar

Kim JC, Wilcock P, Bedford MR. Iron status of piglets and impact of phytase superdosing on iron physiology: a review. Anim Feed Sci Tech. 2018;235:8–14.View ArticleGoogle Scholar

Saulnier L, Guillon F, Chateigner-Boutin AL. Cell wall deposition and metabolism in wheat grain. J Cereal Sci. 2012;56:91–108.View ArticleGoogle Scholar

Jaworski NW, Lærke HN, Bach Knudsen KE, Stein HH. Carbohydrate composition and in vitro digestibility of dry matter and nonstarch polysaccharides in corn, sorghum, and wheat and coproducts from these grains. J Anim Sci. 2015;93:1103–13.View ArticleGoogle Scholar

Bedford MR. Mechanism of action and potential environmental benefits from the use of feed enzymes. Anim Feed Sci Tech. 1995;53:145–55.View ArticleGoogle Scholar

Gutierrez NA, Serão NVL, Kerr BJ, Zijlstra RT, Patience JF. Relationships among dietary fiber components and the digestibility of energy, dietary fiber, and amino acids and energy content of nine corn coproducts fed to growing pigs. J Anim Sci. 2014;92:4505–17.View ArticleGoogle Scholar

Debon SJJ, Tester RF. In vitro binding of calcium, iron and zinc by non-starch polysaccharides. Food Chem. 2001;73:401–10.View ArticleGoogle Scholar

Diebold G, Mosenthin R, Piepho HP, Sauer WC. Effect of supplementation of xylanase and phospholipase to a wheat-based diet for weanling pigs on nutrient digestibility and concentrations of microbial metabolites in ileal digesta and feces. J Anim Sci. 2004;82:2647–56.View ArticleGoogle Scholar

Pedersen MB, Yu S, Arent S, Dalsgaard S, Bach Knudsen KE, Lærke HN. Xylanase increased the ileal digestibility of nonstarch polysaccharides and concentration of low molecular weight nondigestible carbohydrates in pigs fed high levels of wheat distillers dried grains with solubles. J Anim Sci. 2015;93:2885–93.View ArticleGoogle Scholar

Nortey TN, Patience JF, Sands JS, Trottier NL, Zijlstra RT. Effects of xylanase supplementation on the apparent digestibility and digestible content of energy, amino acids, phosphorus, and calcium in wheat and wheat by- products from dry milling fed to grower pigs. J Anim Sci. 2008;86:3450–64.View ArticleGoogle Scholar

Woyengo TA, Sands JS, Guenter W, Nyachoti CM. Nutrient digestibility and performance responses of growing pigs fed phytase-and xylanase- supplemented wheat-based diets. J Anim Sci. 2008;86:848–57.View ArticleGoogle Scholar

Fry SC, Nesselrode BHWA, Miller JG, Mewburn BR. Mixed-linkage (1-3,1-4)-β-d-glucan is a major hemicellulose of Equisetum (horsetail) cell walls. New Phytol. 2008;179:104–15.View ArticleGoogle Scholar

Sørensen I, Pettolino FA, Wilson SM, Doblin MS, Johansen B, Bacic A, Willats WGT. Mixed-linkage (1,3;1,4)-β -D-glucan is not unique to the poales and is an abundant component of Equisetum arvense cell walls. Plant J. 2008;54:510–21.View ArticleGoogle Scholar

Burton RA, Fincher GB. (1,3:1,4)-β-D-glucans in cell walls of the poaceae, lower plants and funghi: a tale of two linkages. Mol Plant. 2009;2:873–82.View ArticleGoogle Scholar

Masey O’Neill HV, Smith JA, Bedford MR. Multicarbohydrase enzymes for non-ruminants. Asian-Australas J Anim Sci. 2014;27:290–301.View ArticleGoogle Scholar

Wang L, Newman RK, Newman CW, Hofer PJ. Barley beta-glucans alter intestinal viscosity and reduce plasma cholesterol concentrations in chicks. J Nutr. 1992;122:2292–7.View ArticleGoogle Scholar

Word count: 5763

Show less

Copyright © 2018. This work is licensed under http://creativecommons.org/licenses/by/4.0/ (the “License”). Notwithstanding the ProQuest Terms and Conditions, you may use this content in accordance with the terms of the License.

Abstract

Translate

Background

Results

Conclusions

Details

Title

The effect of enzymes on release of trace elements in feedstuffs based on in vitro digestion model for monogastric livestock

Author

Yu, Xiaonan; Han, Jianan; Li, Haiyun; Zhang, Yiwei; Feng, Jie

Publication year

2018

Publication date

2018

Publisher

BioMed Central

ISSN

16749782

e-ISSN

20491891

Source type

Scholarly Journal

Language of publication

English

DOI

https://doi.org/10.1186/s40104-018-0289-2

ProQuest document ID

2122283606

The effect of enzymes on release of trace elements in feedstuffs based on in vitro digestion model for monogastric livestock

Jump to:

Full text

Abstract

Details

Suggested sources