Lipid Supplement in the Cultural Condition Facilitates the Porcine iPSC Derivation through cAMP/PKA/CREB Signal Pathway

Large numbers of lipids exist in the porcine oocytes and early embryos and have the positive effects on their development, suggesting that the lipids may play an important role in pluripotency establishment and maintenance in pigs. However, the effects of lipids and their metabolites, such as fatty acids on reprogramming and the pluripotency gene expression of porcine-induced pluripotent stem cells (iPSCs), are unclear. Here, we generated the porcine iPSCs that resemble the mouse embryonic stem cells (ESCs) under lipid and fatty-acid-enriched cultural conditions (supplement of AlbuMAX). These porcine iPSCs show positive for the ESCs pluripotency markers and have the differentiation abilities to all three germ layers, and importantly, have the capability of aggregation into the inner cell mass (ICM) of porcine blastocysts. We further confirmed that lipid and fatty acid enriched condition can promote the cell proliferation and improve reprogramming efficiency by elevating cAMP levels. Interestingly, this lipids supplement promotes mesenchymal–epithelial transition (MET) through the cAMP/PKA/CREB signal pathway and upregulates the E-cadherin expression during porcine somatic cell reprogramming. The lipids supplement also makes a contribution to lipid droplets accumulation in the porcine iPSCs that resemble porcine preimplantation embryos. These findings may facilitate understanding of the lipid metabolism in porcine iPSCs and lay the foundation of bona fide porcine embryonic stem cell derivation.


Introduction
Induced pluripotent stem cells (iPSCs) could be derived from somatic cell by the expression of transcription factors including OCT4, SOX2, KLF4 and c-MYC [1,2]. The iPSCs has become an alternative resource of stem cells for biomedical research and stem cell therapy, without using embryos. Compared with mouse and other model animals, pigs share similarities with human physiology, anatomy and metabolism [3]. Generation of porcine iPSCs may make up for the disadvantages of human iPSCs, such as the limits of in vivo experiment due to ethical issues [4,5]. Thus, the pig could

The iPSCs Have Pluripotency, Differentiation Potential and Embryo Aggregation Abilities
The LpiPSCs that were morphologically similar to mouse ESCs were domed and three-dimensional ( Figure 2A). In order to examine the pluripotency of LpiPSCs, we performed the AP staining and immunofluorescent staining. These piPSC lines were cultured for more than 10 passages before characterization. The results showed that LpiPSCs were AP-positive ( Figure 2B) and expressed pluripotency markers, such as OCT4, SOX2, SSEA-1 and NANOG ( Figure 2C). Additionally, in vitro differentiation experiment indicated that LpiPSCs were able to form embryoid bodies (EBs) and differentiate into three germ-layers including endoderm, mesoderm and ectoderm ( Figure 2D). In vivo experiment showed that teratoma, which contained three germ-layer cells, could be formed after injection of LpiPSCs in immunodeficient mice ( Figure 2E). These results indicate that LpiPSCs have differentiation abilities in vitro and in vivo.
To test the capability of aggregation of LpiPSCs into porcine embryos, we injected LpiPSCs into porcine parthenogenetic embryos at the eight-cell stage and examined when embryos developed to the blastocyst stage. The results indicated that LpiPSCs with green fluorescence incorporated into inner cell masses (ICM) of porcine embryos ( Figure 2F). Cross-species chimeric mouse embryos at E8.5-E10.5 developmental stages were generated following injection of naïve human ESCs into mouse morulas [17]. In our work, LpiPSCs were aggregated with two mouse embryos without zona pellucida at the eight-cell stage in microwells ( Figure S1A). The reconstructed blastocysts contained LpiPSCs with green fluorescence, indicating that iPSCs were incorporated into mouse blastocysts ( Figure S1B). After transplantation of reconstructed embryos into the pseudopregnant mouse, no green fluorescence was detected at E13.5 mouse embryos ( Figure S1C). These results suggest that the LpiPSCs have embryonic aggregation ability but it is limited for further in vivo development to full term.

The iPSCs Have Pluripotency, Differentiation Potential and Embryo Aggregation Abilities
The LpiPSCs that were morphologically similar to mouse ESCs were domed and three-dimensional ( Figure 2A). In order to examine the pluripotency of LpiPSCs, we performed the AP staining and immunofluorescent staining. These piPSC lines were cultured for more than 10 passages before characterization. The results showed that LpiPSCs were AP-positive ( Figure 2B) and expressed pluripotency markers, such as OCT4, SOX2, SSEA-1 and NANOG ( Figure 2C). Additionally, in vitro differentiation experiment indicated that LpiPSCs were able to form embryoid bodies (EBs) and differentiate into three germ-layers including endoderm, mesoderm and ectoderm ( Figure 2D). In vivo experiment showed that teratoma, which contained three germ-layer cells, could be formed after injection of LpiPSCs in immunodeficient mice ( Figure 2E). These results indicate that LpiPSCs have differentiation abilities in vitro and in vivo.
To test the capability of aggregation of LpiPSCs into porcine embryos, we injected LpiPSCs into porcine parthenogenetic embryos at the eight-cell stage and examined when embryos developed to the blastocyst stage. The results indicated that LpiPSCs with green fluorescence incorporated into inner cell masses (ICM) of porcine embryos ( Figure 2F). Cross-species chimeric mouse embryos at E8.5-E10.5 developmental stages were generated following injection of naïve human ESCs into mouse morulas [17]. In our work, LpiPSCs were aggregated with two mouse embryos without zona pellucida at the eight-cell stage in microwells ( Figure S1A). The reconstructed blastocysts contained LpiPSCs with green fluorescence, indicating that iPSCs were incorporated into mouse blastocysts ( Figure S1B). After transplantation of reconstructed embryos into the pseudopregnant mouse, no green fluorescence was detected at E13.5 mouse embryos ( Figure S1C). These results suggest that the LpiPSCs have embryonic aggregation ability but it is limited for further in vivo development to full term.

AlbuMAX Promotes iPSCs Proliferation
As shown in AP staining during reprogramming, more AP-positive cells were in LpiPSCs than the control. Therefore, AlbuMAX may promote cell proliferation. In order to confirm it, we performed the Bromodeoxyuridine (5-bromo-2'-deoxyuridine, BrdU) immunofluorescent staining

AlbuMAX Promotes iPSCs Proliferation
As shown in AP staining during reprogramming, more AP-positive cells were in LpiPSCs than the control. Therefore, AlbuMAX may promote cell proliferation. In order to confirm it, we performed the Bromodeoxyuridine (5-bromo-2'-deoxyuridine, BrdU) immunofluorescent staining

AlbuMAX Promotes iPSCs Proliferation
As shown in AP staining during reprogramming, more AP-positive cells were in LpiPSCs than the control. Therefore, AlbuMAX may promote cell proliferation. In order to confirm it, we performed the Bromodeoxyuridine (5-bromo-2'-deoxyuridine, BrdU) immunofluorescent staining and flow cytometry analysis of BrdU positive cells in iPSCs. The results revealed that a lot of BrdU positive cells existed in LpiPSCs. The proportions were 35.31% ( Figure 3A,B). As a control, 26.28% of BrdU positive cells were detectable ( Figure 3A,B). Quantitative RT-PCR showed that genes related with cell cycle including Cdc2, Ccnc, Cdc20 and Ccna2 were highly expressed in LpiPSCs ( Figure 3C). These findings suggest that AlbuMAX improved the PEF reprogramming efficiency through promoting cell proliferation. A high proliferation rate was a key factor for mouse and human iPSCs generation [18,19].  Figure 3A,B). As a control, 26.28% of BrdU positive cells were detectable ( Figure 3A,B). Quantitative RT-PCR showed that genes related with cell cycle including Cdc2, Ccnc, Cdc20 and Ccna2 were highly expressed in LpiPSCs ( Figure  3C). These findings suggest that AlbuMAX improved the PEF reprogramming efficiency through promoting cell proliferation. A high proliferation rate was a key factor for mouse and human iPSCs generation [18,19]. During reprogramming, Nanog and EpCAM expression levels increased as compared to the control group ( Figure S2B) while expression levels of pluripotency genes, such as Oct4, Sox2, Sall4, Cdh1 and Esrrb, were not obviously elevated ( Figure S2B). As per previous reports, the exogenous pluripotency genes were not silenced and not reduced completely ( Figure S2A), suggesting more During reprogramming, Nanog and EpCAM expression levels increased as compared to the control group ( Figure S2B) while expression levels of pluripotency genes, such as Oct4, Sox2, Sall4, Cdh1 and Esrrb, were not obviously elevated ( Figure S2B). As per previous reports, the exogenous pluripotency genes were not silenced and not reduced completely ( Figure S2A), suggesting more experimentation can be done to explore the detail mechanisms. By contrast, when porcine iPSCs derived in medium without AlbuMAX were cultured in the AlbuMAX medium for three and six passages respectively, the endogenous genes were not changed significantly ( Figure S2C). These results demonstrate that lipids supplement mainly promotes cell proliferation to improve the efficiency of the porcine iPSCs reprogramming.

AlbuMAX Contributes to Lipid Droplets Accumulation
Quantitative RT-PCR showed that genes associated with signaling pathways including fatty acid biosynthesis (i.e., Prkaa2), transport (i.e., Fabp5) and metabolism (i.e., Acadcl, Acadsb) were up-regulated significantly in LpiPSCs ( Figure 4A), which were similar to that in porcine pre-implantation embryos [4]. These results suggest that the culture system containing AlbuMAX could increase fatty acid metabolism of porcine iPSCs, as well as, the patterns of fatty acid metabolism-related gene expression and metabolic characteristics in LpiPSCs are similar to that in the porcine early embryos. In order to test lipid droplets content, iPSCs were stained with Nile Red that could specifically stain lipid droplets in cells and then analyzed by flow cytometry. Flow cytometry analysis of lipid droplets content showed that the fluorescent signal of Nile Red in LpiPSCs was higher than the control ( Figure 4B), indicating that AlbuMAX facilitated lipid droplets accumulation in the porcine iPSCs. experimentation can be done to explore the detail mechanisms. By contrast, when porcine iPSCs derived in medium without AlbuMAX were cultured in the AlbuMAX medium for three and six passages respectively, the endogenous genes were not changed significantly ( Figure S2C). These results demonstrate that lipids supplement mainly promotes cell proliferation to improve the efficiency of the porcine iPSCs reprogramming.

AlbuMAX Contributes to Lipid Droplets Accumulation
Quantitative RT-PCR showed that genes associated with signaling pathways including fatty acid biosynthesis (i.e., Prkaa2), transport (i.e., Fabp5) and metabolism (i.e., Acadcl, Acadsb) were up-regulated significantly in LpiPSCs ( Figure 4A), which were similar to that in porcine pre-implantation embryos [4]. These results suggest that the culture system containing AlbuMAX could increase fatty acid metabolism of porcine iPSCs, as well as, the patterns of fatty acid metabolism-related gene expression and metabolic characteristics in LpiPSCs are similar to that in the porcine early embryos. In order to test lipid droplets content, iPSCs were stained with Nile Red that could specifically stain lipid droplets in cells and then analyzed by flow cytometry. Flow cytometry analysis of lipid droplets content showed that the fluorescent signal of Nile Red in LpiPSCs was higher than the control ( Figure 4B), indicating that AlbuMAX facilitated lipid droplets accumulation in the porcine iPSCs.

AlbuMAX Promotes MET During the Reprogramming of Fibroblasts
MET was known as the first barrier in the reprogramming process [20] and occurred after PEF infected with pluripotency factors [21]. To test whether AlbuMAX participate in the MET, we added AlbuMAX at different stages of reprogramming, such as at the early stage (Day 3-4), at the middle stage (Day 5-6) and at the late stage (Day 7-8). More cells with morphology change were in the AlbuMAX group than the control, as black circles indicated ( Figure 5A). AP-positive colonies in the AlbuMAX medium were more than in the control at the early, middle and late stages ( Figure 5B and 5C). In addition, quantitative RT-PCR revealed that MET markers including E-cadherin and EpCAM were upregulated significantly at different stages ( Figure 5D), demonstrating that AlbuMAX promoted expression of genes associated with MET. The data indicated that fatty acid metabolism play an important role in the whole process of reprogramming.

AlbuMAX Promotes MET During the Reprogramming of Fibroblasts
MET was known as the first barrier in the reprogramming process [20] and occurred after PEF infected with pluripotency factors [21]. To test whether AlbuMAX participate in the MET, we added AlbuMAX at different stages of reprogramming, such as at the early stage (Day 3-4), at the middle stage (Day 5-6) and at the late stage (Day 7-8). More cells with morphology change were in the AlbuMAX group than the control, as black circles indicated ( Figure 5A). AP-positive colonies in the AlbuMAX medium were more than in the control at the early, middle and late stages ( Figure 5B,C). In addition, quantitative RT-PCR revealed that MET markers including E-cadherin and EpCAM were upregulated significantly at different stages ( Figure 5D), demonstrating that AlbuMAX promoted expression of genes associated with MET. The data indicated that fatty acid metabolism play an important role in the whole process of reprogramming.

AlbuMAX Enhances Reprogramming via Activating cAMP/PKA/CREB Signaling Pathway
Multiple fatty acids and phospholipids are the agonists of G-protein-coupled receptors (GPCRs), such as both sphingosine-1-phosphate and lysophosphatidic acid, which may activate the downstream cAMP/PKA signaling pathway [22]. We hypothesize that the cAMP/PKA pathway is active in LpiPSCs and AlbuMAX may activate the signaling pathway. To confirm the hypothesis, we examined cAMP levels after treatment of PEF in the AlbuMAX medium. The results showed that cAMP levels in PEF after treatment for 4-6 h were more than twice in the control group, which were similar to that after treatment with cAMP activator Forskolin ( Figure 6A). Western blot assay also indicated that the phosphorylation levels of CREB and activating transcription factor (ATF) that are transcription factors downstream of cAMP/PKA pathway elevated after AlbuMAX incubation ( Figure 6B). These data demonstrate AlubMAX could activate the cAMP/PKA signaling pathway during porcine PEF reprogramming into iPSCs.
Transcription factor CREB contains conserved binding sites in the regulatory regions of E-cadherin promoter. Therefore, we constructed a luciferase reporter and the mutation vector of E-cadherin promoter containing CREB binding sites ( Figure 6C). The luciferase activity assay showed that luciferase expression levels following supplementation with AlbuMAX in the medium were

AlbuMAX Enhances Reprogramming via Activating cAMP/PKA/CREB Signaling Pathway
Multiple fatty acids and phospholipids are the agonists of G-protein-coupled receptors (GPCRs), such as both sphingosine-1-phosphate and lysophosphatidic acid, which may activate the downstream cAMP/PKA signaling pathway [22]. We hypothesize that the cAMP/PKA pathway is active in LpiPSCs and AlbuMAX may activate the signaling pathway. To confirm the hypothesis, we examined cAMP levels after treatment of PEF in the AlbuMAX medium. The results showed that cAMP levels in PEF after treatment for 4-6 h were more than twice in the control group, which were similar to that after treatment with cAMP activator Forskolin ( Figure 6A). Western blot assay also indicated that the phosphorylation levels of CREB and activating transcription factor (ATF) that are transcription factors downstream of cAMP/PKA pathway elevated after AlbuMAX incubation ( Figure 6B). These data demonstrate AlubMAX could activate the cAMP/PKA signaling pathway during porcine PEF reprogramming into iPSCs. added in the cell culture systems After which E-cadherin positive cells decreased from 1.32% to 0.35% ( Figure 6D). E-cadherin expression also downregulated significantly via quantitative RT-PCR detection ( Figure 6E). To test the PEF reprogramming efficiency in the culture conditions including PKA inhibitor, AP staining was performed, showing that AP-positive colonies were reduced significantly ( Figure 6F). These results indicate that AlbuMAX is impeded by inhibiting cAMP/PKA signaling pathway.  Transcription factor CREB contains conserved binding sites in the regulatory regions of E-cadherin promoter. Therefore, we constructed a luciferase reporter and the mutation vector of E-cadherin promoter containing CREB binding sites ( Figure 6C). The luciferase activity assay showed that luciferase expression levels following supplementation with AlbuMAX in the medium were significantly more elevated than the control, while the luciferase levels of mutation treated with AlbuMAX did not increase much more than the control group ( Figure 6C). These data demonstrate that AlbuMAX could activate CREB which binds to E-cadherin promoter regulatory regions and then regulate E-cadherin expression.
To further confirm the cAMP/PKA signaling pathway play a role, the PKA inhibitor H-89 was added in the cell culture systems After which E-cadherin positive cells decreased from 1.32% to 0.35% ( Figure 6D). E-cadherin expression also downregulated significantly via quantitative RT-PCR detection ( Figure 6E). To test the PEF reprogramming efficiency in the culture conditions including PKA inhibitor, AP staining was performed, showing that AP-positive colonies were reduced significantly ( Figure 6F). These results indicate that AlbuMAX is impeded by inhibiting cAMP/PKA signaling pathway.
Taken together, AlbuMAX acts as the GPCRs' agonist and mainly participates in the reprogramming through cAMP/PKA signaling pathway. AlbuMAX upregulates cAMP levels, as well as, PKA improves CREB phosphorylation levels and then CREB binds to regulatory regions of E-cadherin to promote E-cadherin expression. MET process is enhanced and reprogramming efficiency is thus improved, as shown in the model (Figure 7). Taken together, AlbuMAX acts as the GPCRs' agonist and mainly participates in the reprogramming through cAMP/PKA signaling pathway. AlbuMAX upregulates cAMP levels, as well as, PKA improves CREB phosphorylation levels and then CREB binds to regulatory regions of E-cadherin to promote E-cadherin expression. MET process is enhanced and reprogramming efficiency is thus improved, as shown in the model (Figure 7).

Discussion
Porcine oocytes and embryos at early stages contain a lot of lipids including triglyceride, cholesterol, free fatty acids and phospholipids, wherein the content is higher than that of the mouse, bovine and ovine oocytes [9]. Lipids facilitate oocyte maturation, embryo development and cell proliferation [14,23,24]. Lipids may thus contribute to the generation of porcine iPSCs. However, lipids in porcine oocytes are complicated and the metabolites could be transformed. As a result, it is difficult to confirm what kind of lipid has a function. Therefore, AlbuMAX containing triglyceride, cholesterol, free fatty acids and phospholipids could simulate the lipid niche in porcine oocytes and early embryos well. In our study, we identify AlbuMAX that motivates PEF reprogramming. The porcine iPSCs derived from PEF in AlbuMAX medium were pluripotent and had differentiation ability and embryo aggregation ability.
Early studies demonstrated that a high proliferation rate was important for cell reprogramming in both mouse and human [18,19]. Our study suggested that acceleration of cell cycle progression and enhancement of cell proliferation were also required for porcine iPSCs generation.
Promotion of MET process significantly enhances reprogramming [25]. Overexpression of MET marker E-cadherin based on the traditional transcription factors promoted MET and as a result improves reprogramming. E-cadherin could even replace Oct4 to induce mouse somatic cell reprogramming [26]. E-cadherin-mediated cell-cell contact is also critical for induced pluripotent stem cell generation. Knockdown E-cadherin reduced reprogramming efficiency [27]. One notable finding in our work is that AlbuMAX works in PEF reprogramming through upregulating E-cadherin and promoting MET. High performance liquid chromatography analysis demonstrates that ingredients of AlbuMAX are albumin and lipids including triglyceride, cholesterol, free fatty acids and phospholipids. Lipids but not albumin in AlbuMAX are responsible for stimulating ESCs renewal [15]. Phospholipids that are GPCRs agonists but not free fatty acids promotes ESCs renewal [15,22]. Triglyceride works primarily as an energy substance and cholesterol is the main ingredient of cell membrane. Therefore, phospholipids in AlbuMAX may play leading roles in stimulating the MET process via elevating cAMP levels and then activating downstream transcription factors through PKA pathway.

Discussion
Porcine oocytes and embryos at early stages contain a lot of lipids including triglyceride, cholesterol, free fatty acids and phospholipids, wherein the content is higher than that of the mouse, bovine and ovine oocytes [9]. Lipids facilitate oocyte maturation, embryo development and cell proliferation [14,23,24]. Lipids may thus contribute to the generation of porcine iPSCs. However, lipids in porcine oocytes are complicated and the metabolites could be transformed. As a result, it is difficult to confirm what kind of lipid has a function. Therefore, AlbuMAX containing triglyceride, cholesterol, free fatty acids and phospholipids could simulate the lipid niche in porcine oocytes and early embryos well. In our study, we identify AlbuMAX that motivates PEF reprogramming. The porcine iPSCs derived from PEF in AlbuMAX medium were pluripotent and had differentiation ability and embryo aggregation ability.
Early studies demonstrated that a high proliferation rate was important for cell reprogramming in both mouse and human [18,19]. Our study suggested that acceleration of cell cycle progression and enhancement of cell proliferation were also required for porcine iPSCs generation.
Promotion of MET process significantly enhances reprogramming [25]. Overexpression of MET marker E-cadherin based on the traditional transcription factors promoted MET and as a result improves reprogramming. E-cadherin could even replace Oct4 to induce mouse somatic cell reprogramming [26]. E-cadherin-mediated cell-cell contact is also critical for induced pluripotent stem cell generation. Knockdown E-cadherin reduced reprogramming efficiency [27]. One notable finding in our work is that AlbuMAX works in PEF reprogramming through upregulating E-cadherin and promoting MET. High performance liquid chromatography analysis demonstrates that ingredients of AlbuMAX are albumin and lipids including triglyceride, cholesterol, free fatty acids and phospholipids. Lipids but not albumin in AlbuMAX are responsible for stimulating ESCs renewal [15]. Phospholipids that are GPCRs agonists but not free fatty acids promotes ESCs renewal [15,22]. Triglyceride works primarily as an energy substance and cholesterol is the main ingredient of cell membrane. Therefore, phospholipids in AlbuMAX may play leading roles in stimulating the MET process via elevating cAMP levels and then activating downstream transcription factors through PKA pathway.
Taken together, AlbuMAX added in cell medium had positive effects on iPSCs generation. Despite the fact AlbuMAX could facilitate reprogramming in a pig, endogenous pluripotency genes were inadequate to support porcine iPSCs maintenance and exogenous genes were still expressed to maintain iPSCs pluripotency. Key pluripotency regulators in porcine iPSCs may be different from conventional reprogramming factors and culture conditions in mouse and human iPSCs. Optimal induced factors, chemical compounds and cytokines supplemented in culture systems need to be explored so as to find the methods of activating endogenous pluripotency genes and then silencing exogenous genes during porcine somatic reprogramming.

Animal Experiments
Immunodeficient mice were purchased from Vital River Laboratories (Beijing, China) and used for the teratoma assay. The animal study proposal (Approved code: SKLAB-2013-04-01, 1 April 2013) in this study were approved by the Animal Care and Use Committee of China Agricultural University.

Generation of Porcine iPSCs and Cell Culture
Retroviral virus vectors (pMXs vector) separately carrying porcine Oct4, Sox2, Klf4 and c-Myc were used to generate iPSCs. The viral production was performed as the method described [28]. Retroviruses were used to infect PEF containing Actin-ZsGreen for 12 h. Cells were passaged and seeded on the mitomycin-treated mouse embryonic fibroblasts (also called feeder cells) following two rounds of infection. Then the medium was changed to reprogramming medium on the second day. The medium was changed every two days. The efficiency of PEF reprogramming was evaluated by AP staining. Colonies were picked up at about Day 30.
For embryoid body formation, the iPSCs were digested and maintained in the medium mentioned above removal of human LIF, 2i (CHIR99021 and PD0325901) and AlbuMAX on a shaker (40 r/min) in a CO 2 incubator.

Quantitative RT-PCR
Total RNA was extracted using a Qiagen RNeasy mini RNA kit (Qiagen, San Diego, CA, USA) and then reverse-transcribed by Oligo-dT primer and M-MLV Reverse Transcriptase (Promega, Fitchburg, WI, USA). The cDNAs were used for quantitative RT-PCR analysis with LightCycler 480 SYBR Green I Master Kit (Roche, Basel, Switzerland). The data was analyzed using the comparative CT method.
The primers were as bellows:

Alkaline Phosphatase Staining and Immunofluorescence Staining
The alkaline phosphatase (AP) staining was performed using an Alkaline Phosphatase Detection Kit (Millipore, Temecula, CA, USA) according to the manufacturer's instructions.
For lipid droplets staining using Nile Red (Sigma, N-1142). The cells were fixed with 4% PFA for 20 min at room temperature and washed three times with Dulbecco's Phosphate Buffered Saline (DPBS) and then incubated with 5 ng/ml Nile Red for 5 min at room temperature.

Flow Cytometry Analysis
For flow cytometry analysis, single cells after digestion of colonies with Tryple were stained with primary antibody and secondary antibody for 1 h, respectively. These cells were then washed three times with DPBS and filtered through a 40-µm falcon. Fluorescence activated Cell Sorting (FACS) analysis was performed using the Moflo-XDP (Beckman, Indianapolis, IN, USA).

Teratoma Formation Assay
For teratoma formation, the porcine iPSCs (2 × 10 7 ) were subcutaneously injected into the BALB/c nude mice. After two months, teratoma were harvested for histological analysis by hematoxylin and eosin (H&E) staining. For H&E staining, nuclei were stained with the alum hematoxylin and eosinophilic structures were stained with eosin.

Parthenogenetic Embryo Injection
The maturation and parthenogenetic activation (PA) of porcine oocytes were performed as described [30]. Embryos at eight-cell stage were selected for the injection assay. About 15-20 porcine iPSCs were injected into every embryo by micromanipulation. The injected embryos were then transferred into the Porcine Zygote Medium-3 (PZM-3) for 3-4 days. The numbers of blastocysts and chimeric blastocysts were then analyzed.

Western Blot
Cells were washed in cold DPBS and then lysed in sodium dodecyl sulfate (SDS) sample buffer on ice for 30 min. After centrifugation at 10,000× g for 15 min (4 • C), supernatant was collected. The protein concentration of samples was measured using the BCA Protein Assay Kit (Beyotime). The samples were boiled at 99 • C for 5 min and were transferred on ice. The denatured protein samples were used for Sodium dodecyl sulfate polyacrylamide gel electrophoresis and then transferred to polyvinylidene fluoride (PVDF) membranes. The PVDF membranes were in 5% nonfat milk for blocking and probed overnight at 4 • C with primary antibodies. Secondary antibodies were then probed for 1 h at room temperature. Protein bands were finally detected by SuperSignal West Dura Extended Duration Substrate (Thermo Scientific, Waltham, MA, USA).

Detection of cAMP Levels
The cAMP levels of cells were detected using the cAMP-Glo assay kit according to the protocol (Promega). Cells were treated with an agonist or in the induction buffer for the desired length of time and then lysis buffer was added. The plate was incubated with shaking for 15 min. The cAMP detection solution was prepared and added to all wells, mixed and incubated for 20 min. Kinase-Glo ® reagents were supplemented into all reactions and incubated for 10 min. The luminescence measurement values were used to calculate the cAMP concentration according to the kit manual.

The Luciferase Reporter Construction and Luciferase Activity Analysis
CREB binding cites in the E-cadherin promoter were synthesized directly as shown below: Top chain tcgagACTCTGTCTCAGTTATTTTTCCCTCGTCAAGAGCCATCTGAAGGAGAGGCa Bottom chain agcttGCCTCTCCTTCAGATGGCTCTTGACGAGGGAAAAATAACTGAGACAGAGTc Bases in lower-case were the cohesive ends. Bases in upper-case were the binding sites. In mutation vector construction, mutation cites were designed in the primers and mutation vectors were amplified by rolling circle amplification. CGTAC were transformed to CTGCA in mutation vectors.
The primers were shown as below: Forward AGTTATTTTTCCCTCTGCAAGAGCCATCT Reverse AGATGGCTCTTGCAGAGGGAAAAATAACT Luciferase activity analysis was performed following cell transfection 24 h using the Dual-Glo Luciferase Assay System (Promega).