Figures
Abstract
The trials were conducted to assess the effects of long-term feeding with phytase transgenic corn (PTC) to hens on laying performance and egg quality, and investigate the fate of transgenic DNA and protein in digesta, blood, tissues, and eggs. Fifty-week old laying hens (n = 144) were fed with a diet containing 62.4% PTC or non-transgenic isogenic control corn (CC) for 16 weeks. We observed that feeding PTC to laying hens had no adverse effect on laying performance or egg quality (P>0.05) except on yolk color (P<0.05). Transgenic phyA2 gene and protein were rapidly degraded in the digestive tract and were not detected in blood, heart, liver, spleen, kidney, breast muscle, and eggs of laying hens fed with diet containing PTC. It was concluded that performance of hens fed diets containing PTC, as measured by egg production and egg quality, was similar to that of hens fed diets formulated with CC. There was no evidence of phyA2 gene or protein translocation to the blood, tissues, and eggs of laying hens.
Citation: Ma Q, Gao C, Zhang J, Zhao L, Hao W, Ji C (2013) Detection of Transgenic and Endogenous Plant DNA Fragments and Proteins in the Digesta, Blood, Tissues, and Eggs of Laying Hens Fed with Phytase Transgenic Corn. PLoS ONE 8(4): e61138. https://doi.org/10.1371/journal.pone.0061138
Editor: Marinus F. W. te Pas, Wageningen UR Livestock Research, The Netherlands
Received: September 9, 2012; Accepted: March 5, 2013; Published: April 8, 2013
Copyright: © 2013 Ma et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Funding: This work was financed by the Genetically Modified Organisms Evaluation Major Projects (No. 2009ZX08011-005B-01), Yangtz River Scholar and Innovation Research Team Development Program (NO. IRT0945), China Agriculture Research System (CARS-41-K15), and China Agriculture Research System-Beijing Team for Poultry Industry. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Competing interests: The authors have declared that no competing interests exist.
Introduction
Phosphorus (P) is one of the essential mineral elements for all living organisms. However, there is fairly low content of available P in plant-sourced feed ingredients. About 80% of P in cereal plants, including corn is stored as phytate-P [1]. Phytate bound P is poorly utilized by monogastric animals, due to low levels of phytase activity in their digestive tracts [2]. As a consequence, inorganic P is added to diet to meet the P requirement by animals, which leads to the excretion of non-utilizable portion of dietary P and consequent environmental pollution [3]. Exogenous microbial phytase supplementation in low-P diets has been considered to be one of the most effective ways to reduce P output [4]. However, this approach is associated with high production costs for microbial phytase and requirement of special care in feed processing, which limits its extensive commercial use in diet [5].
The cultivation area for genetically modified (GM) plants has increased 94-fold under the demands for more efficient agriculture since 1996, reaching 160 million hectares worldwide in 2011 [6]. In 2011, 88% of the corn, 90% of the cotton, and 94% of the soybeans planted in the United States were GM [7]. Advances in agricultural biotechnology have enabled the production of transgenic plants expressing microbial-derived phytase in tobacco seeds [8], soybean [9], and canola [10]. Recently, an Aspergillus niger derived phytase expressed in the endosperm of corn was developed by the Chinese Academy of Agricultural Science [11]. As an innovative way of delivering microbial phytase to non-ruminants for better utilization of phytate-bound P, phytase transgenic corn (PTC) will allow animal feed producers to eliminate the purchasing for phytase and corn separately, and eliminate the need for mixing the two ingredients together. This saves time, machinery, and labor for animal feed producers. The PTC has been demonstrated by our lab to improve P utilization in poultry fed P-deficient diets [12].
Compared with conventional corn, corn expressing a microbial-derived gene may have more potential for future development [11]. However, since the increasing feeding with GM plants to meat, milk and egg producing animals, safety concerns have been raised with respect to potential adverse effects on animals and humans health [13]–[18]. Consumer-concerned GM plants may pose a perceived risk to health, development of toxicity or the transfer of the recombinant DNA and proteins from diet to livestock and livestock derived products that are consumed by humans.
To our knowledge, no research has been conducted to evaluate the safety of PTC in animals. Therefore, the objectives of this study were to: 1) explore the effects of 16 weeks of long-term feeding with PTC compared with an isogenic parent line corn on laying performance and egg quality, and 2) assess the fate of recombinant DNA and protein in the gastrointestinal tract (GIT) and verify the possible transfer to blood, tissues, and eggs of laying hens after consumption of GM corn.
Materials and Methods
1. Ethics Statement
The protocol reviewed and approved by the Animal Care and Use Committee of China Agricultural University. All procedures were carried out in strict accordance with the recommendations in the Guide for Guidelines for Experimental Animals of the Ministry of Science and Technology (Beijing, China), and all efforts were made to minimize suffering.
2. Corn and diets
One non-transgenic isogenic control corn (CC) and PTC (Beijing, China) were grown, harvested, and stored under the same environmental conditions. To avoid any possibility of contamination, corns harvested from CC and PTC were strictly separated. Nutrient and energy content of both corn varieties have been reported by our previous study [12].
To prevent contamination during diet preparation, the control diet was mixed before the transgenic diet, both as single batches. The instruments were cleaned using dedicated equipment before, between, and after batches. Each diet was assessed by Polymerase Chain Reaction (PCR) to confirm the absence (in control) or presence (in transgenic diet) of the phyA2 transgenic gene.
All diets were analyzed for nutrients levels (Table 1) as previously described by Gao et al. [12]. Phytase activity in diet was determined according to the method reported by Engelen et al. [19]. One phytase activity unit (FTU) is defined as the quantity of enzyme that releases 1 µmol of inorganic P per min from 1.5 mM sodium phytate at pH 5.5 at 37°C. The two treatment diets were formulated to contain adequate concentrations of all nutrients required for laying hens according to the National Research Council [20].
3. Animal housing and management
One hundred and forty-four 50-week-old healthy Hy-Line Brown laying hens (BW = 1.80±0.10 kg), the mean egg production of 85.15±3.29%, were randomly allocated to two dietary treatments. Each treatment had 8 replicates, and each replicate had 3 stainless steel suspended cages (Yanbei Group, Beijing, China) with 3 hens per cage, all fed from a single feeder per cage. The cage size was 45 cm×45 cm×45 cm. Two experimental diets contained corn (62.4%) either from CC or PTC. Prior to the feeding trial, all the birds were fed the CC diet (Table 1) for 2 weeks. After this adaptation period, the birds were fed the CC or PTC diet, respectively, for 16 weeks. The hens were housed in a completely enclosed, mechanically ventilated building, where they were maintained on a 16-h light schedule and allowed ad libitum access to experimental diets and water. Room temperature was maintained at 25±2°C.
4. Performance and egg quality measurement
From week 1 to week 16, egg weight and egg production were recorded in replicates at 2:30 p.m. every day. Feed intake was recorded weekly, and feed conversion was calculated. Mortality was recorded daily. On week 16, five eggs from each replicate were collected and the yolk color, albumen height, and Haugh units were measured with the Egg Multi Tester EMT-5200 (Robotmation Co. Ltd., Tokyo, Japan). Eggs were tested on EggShell Thickness Gauge (Robotmation Co. Ltd., Tokyo, Japan) to determine eggshell thickness. Eggshell strength was measured with EggShell Force Gauge (Robotmation Co. Ltd., Tokyo, Japan). The egg shape index was measured with the FHK egg shape determinator (Fujihira Industry Co., Tokyo, Japan).
5. Blood, intestinal, organ and eggs sampling
On week 16, one laying hen from each replicate with similar live weight was selected for blood collection. Five milliliters of blood was obtained via wing vein into a sterile tube with EDTA (for DNA extraction).
After weighting, one bird from each replicate was sacrificed to allow bleeding and was then hung upside down for 3 min. The last meal was administered 2 h prior to sacrifice. To avoid accidental cross-contamination, the birds fed CC were sacrificed first, followed by birds fed PTC. All the surgical instruments were disinfected with 75% ethanol solution between animal. New disposable gloves were used for each sample. Immediately following sacrifice, the tissues of heart, liver, spleen, kidneys, and breast muscle were excised, trimmed of any superficial fat or blood clots and collected.
Samples of gut contents were collected in the following order: rectal, cecal, ileum, jejunum, duodenal, gizzard, and crop. This order was followed because the target genes and proteins to be detected were assumed to be more concentrated toward the oral cavity because of the degradation activity of the digestive process [21]. In this way, accidental cross-contamination among different guts was avoided. The samples were collected in separate sterile tubes, placed on ice, and stored at −80°C until analysis.
At the end of the study, five eggs were randomly collected from each replicate. All the eggs were stored at 4°C for DNA and protein extraction.
6. DNA extraction
Extreme caution was taken during DNA extraction and PCR to avoid cross-contamination. The samples derived from birds fed with CC or PTC was processed in two different places. Pestles, mortars, homogenizer, and place of work were carefully cleaned before every new sample. New disposable gloves were used for each sample.
6.1 Corn and diets.
The CC, PTC and diets were prepared by finely grinding in liquid nitrogen using clean, sterile pestles and mortars. DNA from the ground material was extracted using a DNeasy plant Mini Kit (Qiagen GmbH, Hilden, Germany) according to the manufacturer's protocols.
6.2 Intestinal contents.
The samples of the undigested contents of the rectal, cecal, ileum, jejunum, duodenal, gizzard and crop were prepared by finely grinding in liquid nitrogen using clean, sterile pestles and mortars. Genomic DNA from intestinal contents was isolated with the QIAamp DNA Stool Mini Kit (Qiagen GmbH, Hilden, Germany) according to the manufacturer's protocols.
6.3 Blood and tissues.
All tissues and blood were defrosted, and then parts of tissues were taken by cutting out an internal portion of the tissue with a clean scalpel blade. DNA from bird tissues and blood was extracted using the DNeasy Blood & Tissue Kit (Qiagen GmbH, Hilden, Germany) according to the manufacturer's protocols, respectively.
6.4 Eggs.
Eggs were disinfected with 75% ethanol before being cracked. The content of the five eggs from each replicate was homogenized at 10,000 rpm for 1 min using a disperser (Ultra-Turrax model T25, IKA Werke, Staufen, Germany) on ice. Genomic DNA from eggs was extracted according to the method reported by Herman [22] using the DNeasy Blood & Tissue Kit (Qiagen GmbH, Hilden, Germany).
7. PCR analysis
In the PCR studies, a corn specific invertase gene ivr (226 bp) was used as the positive control to identify maize DNA [23], and a foreign gene phyA2 (678 bp) inserted into the PTC was used to monitor transgenic DNA [11]. In addition, the DNA extracts from digesta, blood, tissues, and eggs were analyzed by PCR for a 396 bp region of the chicken ovalbumin (ov) gene to ensure the quality and suitability of the extracted DNA for PCR analysis [24]. Three pairs targeting ivr, phyA2 and ov genes were obtained from Invitrogen (Beijing, China), respectively. The primers and PCR conditions used for the detection of ivr, phyA2 and ov genes are outlined in Table 2.
The PCR products were separated on a 1.5% agarose gels in 1×TBE (89 mM Tris, pH 8.4; 89 mM boric acid; 2 mM EDTA) and were visualized by ethidium bromide staining (Cowin Biotech, Beijing, China). The gel images were digitally captured using AlphaImager TM 2200 & 1220 Documentation & Analysis Systems (Alpha Innotech Corporation, San Leandro, CA).
8. Western blot analysis
Prior to protein extraction, all the samples were prepared by finely grinding in liquid nitrogen using clean, sterile pestles and mortars. Proteins were extracted from corns, diets and digesta using plant protein extraction reagent (Cowin Biotech, Beijing, China) and 5 µL PMSF (Sigma-Aldrich). The tissues were homogenized in 500 µL tissue protein extraction reagent (Cowin Biotech, Beijing, China) and 5 µL PMSF (Sigma-Aldrich). Supernatants were transferred into fresh tubes for SDS-PAGE and western blotting analysis. Protein concentration was determined by the BCA assay (Pierce Biotechnology, Rockford, IL, USA).
Protein samples were separated by 10% sodium dodecyl sulphate–polyacrylamide gel electrophoresis kit (SDS-PAGE gel kit; Cowin Biotech, Beijing, China) and then transferred to nitrocellulose membranes (Bio-Rad, USA). The blot was probed with a polyclonal antibody raised in rabbits against the yeast-expressed phyA2 protein [11]. Purification and characterization of the phyA2 protein followed the procedure as described elsewhere [11], [25]. The antibody was diluted by 2,000× for western blot analysis. The goat anti-rabbit IgG labeled with alkaline phosphatase (LI-COR Bioscience, Lincoln, NE, USA) were used as the second antibody.
Results
1. Effect of long-term feeding PTC on laying performance and egg quality
There were no adverse effects of feeding PTC on the laying performance and egg quality (P>0.05) of laying hens except on yolk color (Table 3). The yolk color was significantly decreased in the treatment fed with GM-maize diet (P<0.05) (Table 3).
2. Transgenic phyA2 gene detection in digesta, blood, tissues, and eggs of laying hens
PCR studies were used to find genes from corn, diets, digesta, blood, tissues, and eggs, either endogenous gene such as the corn specific invertase gene (ivr), specific poultry gene (ov), or transgenic fragments (phyA2). All the corn and diet samples were positive for ivr gene, while the transgenic phyA2 gene was only detected in PTC and PTC based diet (Figure 1). The ivr gene was also detected in all of the gastrointestinal sectors taken from both the CC and PTC-fed laying hens (Figure 2), while the phyA2 gene was only detected in upper GIT digest of laying hens fed with the PTC based diets (Table 4). Further down the GIT, the endogenous maize gene was detected in a relatively high frequency in along the length of the GIT in both the CC and PTC-fed laying hens (duodenum, 87.5% and 75%; jejunum, 87.5%; ileum, 75%; cecum, 62.5 and 50%; rectum, 62.5 and 50%, respectively) (Table 5). The phyA2 gene was not detected in duodenum digesta and the lower GIT of PTC-fed laying hens. The endogenous poultry gene (ov) was also detected in all digesta of laying hens fed CC or PTC based diet except in jejunum digesta non-GM maize-fed (87.5%) (Table 5).
(a) The endogenous gene (226 bp) of corn for ivr (left), (b) The exogenous gene (678 bp) of PTC for phyA2 (right). Arrows indicate the expected length of PCR products. M = marker; Lanes 1 = CC; lanes 2 = PTC; Lanes 3 = CC diet; lanes 4 = PTC diet; − = negative control (no DNA).
(a) The endogenous gene (226 bp) of corn for ivr (left), (b) The exogenous gene (678 bp) of PTC for phyA2 (right). Arrows indicate the expected length of PCR products. M = marker; lanes 1 to 8 CC-fed laying hens (control); lanes 9 to 16 = PTC-fed laying hens; + = positive (GM corn), and − = negative control (no DNA). C = crop contents, G = gizzard contents, D = duodenal contents, J = jejunum contents, I = ileum contents, CE = cecal contents, and R = rectal contents.
No transgenic phyA2 gene fragments were detected in the blood, heart, liver, spleen, kidneys, breast muscle, and examined eggs (Table 5). However, as expected, all of the blood, tissue (Figure 3) and egg (Figure 4) samples were positive for the endogenous (ov) poultry gene in both the CC and PTC-fed group.
(a) The endogenous gene (396 bp) of poultry for ov (left), (b) The exogenous gene (678 bp) of PTC for phyA2 (right). Arrows indicate the expected length of PCR products. M = marker; Lanes 1∼6 = blood, heart, liver, spleen, kidney, breast muscle of CC-fed laying hens (control); lanes 7∼12 = blood, heart, liver, spleen, kidney, breast muscle of PTC-fed laying hens; − = negative control (no DNA).
(a) The endogenous gene (396 bp) of poultry for ov (left), (b) The exogenous gene (678 bp) of PTC for phyA2 (right). Arrows indicate the expected length of PCR products. M = marker; lanes 1 = CC-fed laying hens (control); lanes 2 = PTC-fed laying hens; + = positive (GM corn), and − = negative control (no DNA).
3. The phyA2 protein detection in digesta, blood, tissues, and eggs of laying hens
No phyA2 protein was detected in CC and CC diets, while the phyA2 protein was detected in all PTC and PTC diets (Figure 5). Likewise, no phyA2 protein was detected in all of the GIT digesta of laying hens fed CC based diet (Figure 6). The phyA2 protein was, however, detected in the 100% of crop samples and 87.5% of gizzard samples taken from PTC-fed laying hens (Table 6). Further down the GIT, the phyA2 protein was also detected in the lower gastrointestinal tract of PTC-fed laying hens, but only in the duodenal and jejunum samples (37.5% and 12.5%, respectively) and at a lower frequency than in the gizzard samples (Table 6).
Lane 1, control corn (CC); lane 2, phytase transgenic corn (PTC); lane 3, CC diet; lane 4, PTC diet.
“+” Positive control (GM corn); lane 1, crop contents; lane 2, gizzard contents; lane 3, duodenal contents; lane 4, jejunum contents; lane 5, ileum contents; lane 6, cecal contents; lane 7, rectal contents.
No phyA2 protein was detected in the blood, heart, liver, spleen, kidneys, breast muscle (Figure 7), and eggs (Figure 8) of laying hens fed either CC or PTC based diets (Table 6).
“+” Positive control (GM corn); non-transgenic group: lane 1, blood; lane 3, heart; lane 5, liver; lane 7, spleen; lane 9, kidney; lane 11, breast muscle. Transgenic group: lane 2, blood; lane 4, heart; lane 6, liver; lane 8, spleen; lane 10, kidney; lane 12, breast muscle.
“+” Positive control (GM corn); lane 1, non-transgenic group; lane 2, transgenic group.
Discussion
1. Effects of long-term feeding with PTC on laying performance and egg quality
The PTC was modified to improve the utilization of phytate-P derived from plant feedstuffs and decrease P excretion in feces [11]. Our previous study demonstrated that, the PTC used in the study has a higher phytase and fat contents, lower phytate contents than the CC [12]. No difference was observed in amino acid values between the PTC and CC [12]. The present results strongly suggest that there are no significant effects of the treatment in the measured growth performance parameters of feed intake, feed conversion efficiency, or mortality. This finding agrees with the results of previous studies that have confirmed laying hen performance is not affected by GM plants as compared to their conventional counterpart [26], [27]. Comparative studies [28], [29] with broilers fed GM maize and its isogenic non-GM varieties also showed that there were no adverse effects on the growth performance parameters. Likewise, no significant difference in growth performance parameters of pigs [30], steers [31], cows [32], fishes [33], or rats [34] receiving a non-GM diet or a GM plant-based diet has also been reported.
The egg quality also showed no statistically significant differences in egg shape index, shell thickness, eggshell strength, albumen height, and Haugh unit between laying hens consuming diets produced with PTC and CC. These results are consistent with laying hens feeding trials [27], [35], [36], which demonstrated similar egg quality between groups of laying hens fed diets with non-GM or GM maize. Although a decrease in yolk color was observed in PTC group compared with the control diet group, it may be explained by the higher levels of lutein in CC than in PTC (11.69 vs. 6.43 mg/kg). This is because yolk color is primarily contributed by the contents of lutein and carotene in diet [37].
In common with numerous researches, it indicates that PTC prepared from GM had no unintended effects on production traits and egg quality of laying hens as compared to CC.
2. Transgenic phyA2 gene detection in digesta, blood, tissues, and eggs of laying hens
2.1 Digesta samples.
DNA is the basic substance of all life and nearly all food or feed contains DNA. During the consumption of feed or food, DNA is sensitive to the digestive enzymes and gastric acid, and most of DNA is broken into subunits in digestive tract. Although all DNA, transgenic or not, is sensitive to the digestive processes, the DNA stability may be different in animals GIT [38], [39]. In this study, the degradation of ivr gene was detected to investigate whether the DNA degradability of a GM plant showed any difference compared with an unmodified plant. PCR data showed that ivr recovery, calculated as percentage of positives over all the samples, was recovered with high efficiency in all of the gastrointestinal sectors of non-GM and GM groups. No significant effect of two different diets (transgenic and non-transgenic) was observed on the ivr recovery throughout the GIT. However, the detection of the phyA2 genes in the digesta of PTC-fed laying hens decreased during passage through the GIT from 100% recovery in the crop and gizzard to undetectable in the small intestine and rectum. Similar findings have been reported by Chambers et al. [38], who demonstrated that transgenic gene was detected in the crop and gizzard but not in distal GIT of chickens fed GM maize. Therefore, the transgenic phyA2 genes appeared to be rapidly degraded as it passes through animals' GIT. These genetic materials were probably too degraded to allow amplification of such size of sequences in GIT of laying hens [15], [17]. Moreover, the phyA2 gene fragments could not be found probably due to their rare occurrence compared with ivr genes in the GIT.
Only strong positive signals for the phyA2 gene were detected in the PTC, PTC based diet and some digesta samples in GM group and no positive signals for control group. This indicates that cross-contamination between the two group could be excluded.
2.2 Blood, tissues and eggs samples.
Even though the phyA2 gene is rapidly degraded in GIT in this study, it seems possible that the DNA could be protected against degradation by certain dietary compounds in the upper GIT [40]. The possibility that DNA fragments were transported from bloodstream through GIT epithelia to host organism or eggs cannot be eliminated. In ileostomists small bowel, for example, DNA survives long enough to be capable of transforming a human GIT microflora [41]. Likewise, Nemeth et al. [42] and Sharma et al. [43] found that DNA fragments can cross the intestinal barrier and be detected in animal tissues and products.
In this study, we analyzed the blood and tissues such as heart, liver, spleen, kidneys and breast muscle of laying hens to demonstrate the absorption of gene fragments into the host organism. Moreover, DNA traceability was tested on genomic DNA from total eggs. In all bird blood, tissues and eggs to a PCR assays for the poultry specific ovalbumin (ov) gene was successfully amplified, assuring the suitability of the extraction and amplify ability of DNA. In contrast, no transgenic gene (phyA2) or maize specific gene (ivr) was detected in any of bird blood, tissues and eggs samples of the non-GM and GM group. This finding is consistent with numerous studies investigating the fate of transgenic DNA in animal blood or tissues [44], [45], [46], [47]. A rapid degradation throughout the GIT takes place [48], which might account for the absence of recombinant DNA in blood or tissues after feed intake.
Similar to the finding reported by Aeschbacher et al. [26], transgenic plant DNA was not detected in the eggs of laying hens. A possible explanation for this observation is that the eggs contain only a small amount of DNA [26]. Consequently, the low number of copies of gene may also hinder to trace a possible transfer of recombinant DNA into the eggs.
3. The phyA2 protein detection in digesta, blood, tissue, and eggs of laying hens
3.1 Digesta samples.
The phyA2 protein was detected in 100% of crop samples, 87.5% of gizzard samples, 37.5% duodenum samples and 12.5% jejunum samples taken from PTC-fed laying hens. Similar to the findings documented by Ash et al. [49], the detection of recombinant protein in the digesta of GM soybean-fed laying hens decreased during passage through the GIT from 100% recovery in the diet to undetectable in the feces. The possible explanation for the degradation of recombinant protein could be the enzymatic proteolysis and microbial in stomach and small intestine. However, Chowdhury et al. [44] reported that high levels of Cry1Ab protein were detected in rectal digesta of pigs, which was ascribed to incomplete degradation of recombinant protein in the GIT of pigs. This may reflect differences in the physiology of the GIT of avian and pigs. Birds have a gizzard where the surface area of the feed may be increased by grinding, which may further expose protein both to acid and to GIT proteolytic enzymes. In addition, susceptibility of the phytase protein to proteolytic cleavage and pH in the crop and gizzard [50], resulted in the drastic degradation of phytase protein in the crop and gizzard.
The discrepancy in detection frequencies between the transgenic gene and protein at similar sites along the GIT has also been reported by Walsh et al. [15], [17]. The authors observed that the chance of detection of transgenic genes is lower than the protein detection frequency further down the GIT (ileal, cecum, and colon). The use of primers with shorter expected fragment lengths increased transgenic gene detection frequency may account for the discrepancies observed in detection frequencies between the transgenic gene and protein in GIT [44], [51]. In the future, it is most likely that these transgenic genes or proteins can be detected at very low concentrations with improved methods.
3.2 Blood, tissues and eggs samples.
Similar to previous findings [15], [52], recombinant protein was not detected in the blood or any animal tissue samples. Moreover, our finding that no phyA2 protein was detected in the eggs is consistent with studies demonstrating that no transgenic CP4 EPSPS protein were found in the whole egg or albumin of laying hens receiving GM diets [48]. This is not surprising, considering that the transgenic genes were also undetectable in blood, tissues and eggs of laying hens. The genetic material was probably degraded by proteolytic enzymes in GIT, making them beyond the level of detection in the tissues and blood of laying hens. To date, no studies have reported the discovery of recombinant protein in blood, tissues, eggs or milk derived from animals fed GM-based diets.
In conclusion, the results obtained from long-term feeding with PTC to laying hens indicate that no adverse effects on laying performance and egg quality. Transgenic phyA2 gene and protein were detected in GIT digesta but can be rapidly degraded before excreted to the environment. There was no evidence of phyA2 gene or protein translocation to blood, tissues or, eggs of laying hens.
Acknowledgments
The authors would like to thank Prof. Xugang Luo for his technical assistance. We also acknowledge Prof. Dale Buck Hales and Dr. Da Chen for their assistance with the manuscript.
Author Contributions
Conceived and designed the experiments: QGM CQG CJ. Performed the experiments: CQG JYZ LHZ. Analyzed the data: CQG JYZ. Contributed reagents/materials/analysis tools: QGM CQG JYZ LHZ WBH CJ. Wrote the paper: CQG QGM CJ. Read and approved the final manuscript: CJ QGM CQG JYZ LHZ WBH.
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