1. Introduction
Phosphorus (P) is an essential and vital nutrient that is well expressed in the components used in the formulation of feed for poultry production, mainly soybean meal or maize. Nevertheless, two-thirds of the total phosphate content in plant seeds is stored as phytate P and excreted without being digested [
1,
2]. Phosphorus phytate is poorly absorbed in the gastrointestinal tract of monogastric animals and can additionally negatively affect the digestibility of other nutrients and poultry performance due to its anti-nutritional impact [
3,
4]. Although sources of inorganic P, such as dicalcium phosphate, can be added to poultry diets, this will increase the amount of released P in the manure. Contamination of water with excessive P leads to its eutrophication and subsequent enrichment of surface water with phytonutrients, which is considered a form of pollution [
5]. This problem has motivated scientists to search for suitable ways to decrease the quantity of P excreted in poultry waste, and among these solutions is including phytase in the diet.
In the past few decades, the development of exogenous phytases has been considered one of the most significant findings in poultry nutrition. Exogenous phytases can eliminate the anti-nutritional effect of phytate, allow for better use of P and calcium (Ca), enhance nutrient digestibility, and reduce environmental pollution by P by reducing its excretion in manure [
6,
7]. Dietary supplementation with exogenous phytases can reduce the required amount of non-phytic P. This elevates the amount of hydrolyzed phytate P available to birds by hydrolyzing the phosphodiester bonds of phytates [
8]. Phytases are classified into two subclasses, 3-phytase or 6-phytase, based on the position of the first hydrolyzed phosphate group on the myo-inositol ring [
9]. They can also be organized as bacterial or fungal depending on their industrial production process or the microorganisms used as gene donors [
10]. Commercially, several types of phytase are available; some are derived from fungi such as
Aspergillus niger and
A. ficum, which are generally 3-phytase (EC 3.1.3.8), and others are derived from the bacterium
Escherichia coli or the fungi
Peniphoralycii and
Trichodermareesei, which are 6-phytases (EC 3.1.3.26) [
10,
11]. Furthermore, the microbial physicochemical and catalytic properties of phytases can differ [
12], which can affect P release and subsequently affect the productive and reproductive performance of laying hens. The catalytic properties of phytases differ based on their type: 3-phytases begin the degradation of phytate at position 3, while 6-phytases initiate the release of phosphate radicals in the C6 position of myo-inositol hexaphosphate [
10,
11]. Moreover, phytase sources may have different characteristics, such as thermal stability, resistance to degradation in the gastrointestinal tract, and pH required for optimal activity [
12], which in turn affect the in vivo efficiency of phytase products. In order to assess the efficacy of the new phytases, ongoing studies are required.
To our knowledge, few studies have investigated the impact of bacterial or fungal phytases on laying hens. Therefore, this experiment aims to evaluate the impact of bacterial or fungal phytase sources on productive efficiency, egg quality, biochemical blood indices, and ovary formation in layers.
2. Materials and Methods
2.1. Ethical Statement
This study was conducted under the approval of the Ethics Committee of the Local Experimental Animals Treatment Committee and operated following the guidelines of Kafrelsheik University, Egypt (number 4/2016EC).
2.2. Birds and Experimental Diets
For the experiment, 360 Bovans brown hens (42 weeks of age, 86% egg production) were caged (105 × 65 × 50 cm
3 (length × width × height)) in an open-sided building, divided into 4 experimental groups, each with 15 replicates (6 hens/replicate) and under a 16:8 h light:dark lighting regimen with the same environmental management conditions (temperature, moisture, ventilation). Each cage was equipped with stainless steel nipple drinkers providing drinking water ad libitum. Feed in mash form was also offered ad libitum and the ambient temperature ranged between 24 and 27 °C. The first treatment group was fed the basal diet, which contained 4.6 g/kg available P, as control; the second, third, and fourth treatment groups were fed diets that included 3.2 g/kg available P, supplemented with 5000 FTU/kg diet of bacterial phytase (Quantum
TM Blue 5G, AB-Vista, Plantation, FL, USA), fungal phytase (VemoZyme
® F 5000 NTP, VEMO 99 Ltd., Sofia, Bulgaria), or fungal phytase (Yemzim
® FZ100, OrbaBiokimya, Istanbul, Turkey). The first phytase source was derived from
E. coli (6-phytase; EC 3.1.3.26), while the second and third phytase sources were derived from Aspergillus niger (3-phytase; EC 3.1.3.8) and Trichodermareesei (6-phytase; EC 3.1.3.26), respectively. Each phytase source contained 5000 phytase units (FTU)/kg as described by the manufacturer’s manual, moreover, the three enzymes are thermally stable and the activity recover more than 100% in mash feed 95–99% in pelleted feed; the single unit corresponds to the enzyme quantity needed to liberate 1 μmol of inorganic P from 5.1 mM sodium phytate/minute at 37 °C and pH 5.5 [
13]. The composition of the experimental diet is presented in
Table 1. Diets were determined to follow the guidelines for Bovans brown layers [
14].
2.3. Performance
At the beginning (42 weeks old) and the end (54 weeks old) of the experiment, the body weight (BW) of birds was recorded. Eggs were collected daily, weighed individually, and used for all experimental periods to measure mean egg weight. Egg mass was determined by multiplying the production of eggs (% hens/day) by the egg weights. Daily feed intake (FI) was assessed on a cage basis, and the overall feed conversion ratio (FCR) was evaluated as kg of feed per kg of eggs.
2.4. Egg Quality
Egg and eggshell quality criteria including egg weight, length, and width, shell thickness, yolk width, thick and thin albumin width, yolk height, egg white height, yolk weight, egg white weight, yolk color, and shell weight were measured at 42 and 54 weeks. From each test, 30 eggs laid between 08:00 and 12:00 were randomly chosen. Eggs were individually weighed and split on the Egg Quality Measure (EQM) plate measuring stand and the albumin height was determined. The strength of the yolk color was measured and reported using the Roche yolk fan color process. Eggshells were cleaned of any adhering albumin to determine shell weight, and the membrane was eliminated; eggshells were then dried at 37 °C for 1 h and their weight was measured as a percentage of the entire egg. An assessment of egg consistency was carried out on individual eggs, equivalent to the estimated egg weight.
2.5. Reproductive Morphological Measurements
One bird per replicate was weighed and slaughtered at the end of the experiment. The weight of internal organs and morphology of the reproductive system were evaluated. The weight of liver, gizzard, spleen, and abdominal fat was assessed. The ovary and oviduct were also weighed, and the overall length of the oviduct was measured. The relative weight and length of oviduct portions (including vagina, uterus, isthmus, magnum, and infundibulum) were calculated [
15].
2.6. Serum Biochemical Parameters
Blood samples were collected and centrifuged for 30 min at 3000 g, and samples for serum constituent measurements were stored at −20 °C. The quantities of total cholesterol, high-density lipoprotein (HDL), albumin, total protein, aspartate aminotransferase (AST), alanine aminotransferase (ALT), Ca, P, and glucose were analyzed spectrophotometrically (Unico UV-2000; SpectraLab Scientific Inc., San marcos, CA, USA) at a wavelength of 545 nm [
16] using a commercial kit (Egyptian Company for Biotechnology, Cairo, Egypt). Triglyceride concentration was measured (Wako Chemicals, Richmond, VA, USA) and used as a marker of circulating low-density lipoprotein (LDL), which is an accurate and simple method to estimate the LDL production and reproductive status of domestic fowl [
17].
2.7. Yolk Chemical Analysis
Yolk cholesterol was established in fat extracted from the yolk with a mixture of methanol and chloroform (1:2 vol:vol) [
18,
19]. Malondialdehyde (MDA) content of the yolk was determined colorimetrically, as described by Saleh et al. [
20]. Yolk concentrations of calcium and phosphorus were evaluated by the mineral measurement method [
21].
2.8. Data Analysis
The collected data were analyzed using the general linear model (GLM) procedure in SAS (v 9.4; SAS Institute, 2016, Gary, CA, USA). The significance of differences of means was tested using Tukey’s test, and all differences were considered significant at p < 0.05.
4. Discussion
The beneficial role of bacterial and fungal phytases in alleviating the negative impact of dietary P deficiency in poultry has been well documented [
10,
22]. This study proposes that phytase can hydrolyze phosphoester bonds of phytates and release nutrients, which improves their utilization. The results of the present study revealed no significant gaps in productivity efficiency between layers fed the control diet and those fed diets with low available P fortified with bacterial and fungal phytases, which appears to support the conclusions of previous studies. Our findings follow those of Shet et al. [
23], Tischler et al. [
24], and Żyła et al. [
25], who described that dietary addition of exogenous phytases at 250, 300, and 500 FTU/kg feed with normal or low levels of available P had no effect on egg number, FI, and FCR. On the contrary, Jalal and Scheideler [
26] reported that feeding on a low 0.01% non-phytate P diet supplemented with commercial phytase (250 and 300 FTU/kg) improved the FI, FCR, and egg mass of layers. Moreover, in the present study, we found that no discrepancies between bacterial and fungal phytase sources were noticed. Yan et al. [
27], Sands et al. [
28], and Stahl et al. [
29] showed comparable results in young pigs, broilers, and aged laying hens and explained that these findings were due to improper gastrointestinal pH, elaborating the potential catalytic differences among phytase sources. Additionally, it has been stated that changes in the gastrointestinal maturation of laying hens that occur as the birds get older may affect the potential activity of bacterial and fungal phytases [
30,
31].
Egg quality characteristics of hens fed diets with low available P and microbial phytases were not different than those fed diets with normal available P. However, eggshell quality criteria (thickness and weight) were improved in treated layers compared to controls. Inconsistency was noticed in the results of egg quality criteria as affected by dietary phytase supplementation. On the one hand, Mohammed et al. [
32] reported that supplementation with phytase in layers’ diets had no significant effect on egg quality measurements. Lucky et al. [
33], Panda et al. [
34], and Cabuk et al. [
35] noted no changes in eggshell weight and thickness with various dietary phytase levels. On the other hand, it has been stated that low levels of Ca and available P in diets without phytase supplementation reduced eggshell weight [
36,
37]. Liu et al. [
38] demonstrated that eggshell thickness was improved by dietary supplementation with Ca, P, and phytase. Furthermore, as reported by Żyła et al. [
39], Hughes et al. [
40], and Jalal and Scheideler [
26], dietary phytase was effective in enhancing eggshell quality when laying hens received diets with inadequate non-phytate P. The increased eggshell quality may be attributed to increased nutrient digestibility associated with phytase supplementation and better utilization of P by hens [
27].
Reproductive morphology measurements were not influenced by feeding on diets with low available P complemented with bacterial or fungal phytase sources. No previous investigations evaluated the impact of microbial phytases on oviduct and ovarian morphology. The potential role of microbial phytases in maintaining reproductive system morphology in hens fed diets with low available P could be through their ability to reduce endogenous amino acid flow, enhance the availability of dietary energy, and enhance the digestibility of protein, phosphorus, and amino acids [
41]. Microbial phytases can also dephosphorylate insoluble phytate salts and liberate minerals such as Zn, Mn, Fe, Cu, and Mg [
42,
43], which might be involved in regulating the development of the oviduct and ovary in layers [
15]. Xie et al. [
44] confirmed this assumption and documented that Mn has a vital role in regulating hormones that participate in egg production and ovarian development in broiler breeder hens.
Dietary inclusion of bacterial or fungal phytases increased serum and yolk levels of P compared to the control. These data are in agreement with those of Yan et al. [
27], who noticed an elevation in serum Ca and P values of layers fed diets with phytase and found that these levels were positively correlated with nutrient digestibility. Rama-Rao et al. [
45] also reported a linear increase in serum P in response to phytase addition. In contrast, serum Ca was not elevated linearly, which might be attributed to the antagonistic impact of serum P and Ca. On the contrary, no significant differences in the P and Ca contents of egg yolk were noticed with phytase addition [
46]. Moreover, Viveros et al. [
47] and Sebastian et al. [
48] documented that phytase supplementation of low non-phytate P diets reduced plasma Ca and increased plasma P levels. The increased serum Ca and P levels can be attributed to the ability of microbial phytases to dephosphorylate phosphoester bonds of phytates and insoluble phytate salts and release P [
42,
43]. Moreover, it has been reported that feeding on low P diets led to elevate plasma levels of ionized Ca [
49]. Generally, numerous factors can affect Ca and P metabolism and deposition in the egg yolk, such as the age and genetic line of the birds and their physiological status.
In the present study, cholesterol concentration in egg yolk was reduced in groups with microbial phytase supplementation. Our results are in line with those of Saleh [
50], who reported that the content of total cholesterol in egg yolk was decreased by dietary supplementation with bacterial phytase in low P diets. Furthermore, Żyła et al. [
39] also reported that yolk cholesterol was reduced in Hi-sex laying hens fed diets with phytase. The authors suggested that the increased content of unsaturated fatty acids in egg yolk by phytase inclusion might be the cause of the reduction in cholesterol. However, this finding requires more detailed research, mainly because similar reductions in probiotics have been observed [
19,
51,
52,
53,
54], and probiotics are known to have the ability to produce phytase [
55,
56].