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C-Phycocyanin supplementation during in vitro maturation enhances pre-implantation developmental competence of parthenogenetic and cloned embryos in pigs
Accepted Manuscript C-Phycocyanin supplementation during in vitro maturation enhances pre-implantation developmental competence of parthenogenetic and cloned embryos in pigs Shuang Liang, Jing Guo, Yong Xun Jin, Bao Yuan, Jia-Bao Zhang, Nam-Hyung Kim PII:
S0093-691X(17)30420-X
DOI:
10.1016/j.theriogenology.2017.09.001
Reference:
THE 14248
To appear in:
Theriogenology
Received Date: 29 June 2017 Revised Date:
30 August 2017
Accepted Date: 1 September 2017
Please cite this article as: Liang S, Guo J, Jin YX, Yuan B, Zhang J-B, Kim N-H, C-Phycocyanin supplementation during in vitro maturation enhances pre-implantation developmental competence of parthenogenetic and cloned embryos in pigs, Theriogenology (2017), doi: 10.1016/ j.theriogenology.2017.09.001. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.
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Revised
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C-Phycocyanin supplementation during in vitro maturation enhances
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pre-implantation developmental competence of parthenogenetic and cloned
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embryos in pigs
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Shuang Liang a, b, Jing Guo b, Yong Xun Jin a, Bao Yuan a, Jia-Bao Zhang a* &
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Nam-Hyung Kima, b*
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a
Department of Laboratory Animal Center, College of Animal Sciences, Jilin University,
Changchun, 130062, China. b
Department of Animal Science, Chungbuk National University, Cheongju, Chungbuk,
361-763, Republic of Korea.
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*Corresponding author: Nam-Hyung Kim and Jia-Bao Zhang.
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E-mail addresses: [email protected] (N.-H. Kim) and [email protected] (J.-B. Zhang).
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ABSTRACT
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C-Phycocyanin (C-PC), a protein from green microalgae, has been suggested to possess
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various biological activities, including antioxidant and free radical scavenging properties. The
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aim of the current study was to explore the effects of C-PC on the maturation of porcine
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oocytes and subsequent developmental competence after parthenogenetic activation and
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somatic cell nuclear transfer (SCNT) as well as the underlying mechanisms. There was no
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significant improvement in nuclear maturation rates between the control and C-PC
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supplementation groups (1, 3, 5, 10 µg/mL). However, supplementation of 5 µg/mL C-PC in
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the maturation medium significantly increased blastocyst formation and hatching rates after
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parthenogenetic activation (59.6 ± 3.6% and 33.0 ± 2.6% vs. 49.8 ± 3.5% and 27.4 ± 2.4%,
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respectively). In addition, the presence of C-PC during the maturation period significantly
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improved blastocyst formation rates and total cell numbers after SCNT (24.8 ± 1.9% and 42.2
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± 3.3 vs. 21.6 ± 2.2% and 39.5 ± 3.4, respectively) compared to the control group.
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Furthermore, cellular proliferation and the expression of pluripotency-related genes (SOX2
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and NANOG) were increased in cloned blastocysts derived from the C-PC supplemented
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group. Importantly, C-PC supplementation during maturation not only improved cumulus
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expansion and increased the expression of cumulus expansion-related genes (HAS2, PTX3,
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and PTGS2), but also enhanced antioxidant capacity, improved mitochondria function, and
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decreased cathepsin B activity in porcine oocytes. These results demonstrate that C-PC may
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be useful for improving porcine oocyte quality and subsequent developmental competence in
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embryos.
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Keywords: In vitro maturation, C-phycocyanin, Porcine oocyte, Parthenogenetic activation,
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Somatic cell nuclear transfer
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1. Introduction Somatic cell nuclear transfer (SCNT) is a useful technology with applications in
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transgenic animals, preserving species, stem cell research, and regenerative medicine. During
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SCNT, the nucleus of a somatic cell is transferred into a healthy enucleated metaphase II (MII)
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stage oocyte to generate a new individual compatible with the somatic cell donor [1]. It has
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been suggested that pigs share several characteristics with humans, and generating genetic
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modifications in pigs using SCNT technology may be an excellent model for biomedical
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studies and xenotransplantation [2, 3]. Many studies have attempted to improve the success
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rate of producing porcine cloned embryos in vitro [4-6]. However, compared with embryos
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derived from oocytes matured in vivo, the developmental competence of embryos derived
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from oocytes matured in vitro remains low [7, 8].
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Many factors affect the efficiency of generating cloned pigs with SCNT technology [9,
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10]. Among these factors, oocyte quality is the most important factor affecting the
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developmental competence of cloned embryos [11, 12]. Oocyte maturation is a complex
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process that includes nuclear and cytoplasmic maturation [13]. Any errors in this process can
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lead to the failure of further embryonic development [14]. Therefore, high-quality or
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developmentally competent oocytes are vital for fertilization and embryo development. In
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general, oocyte quality and developmental competence are obtained during follicular
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development under in vivo conditions [15]. When oocytes are liberated from their follicles,
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they can undergo spontaneous meiotic resumption under in vivo condition and become
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arrested in the MII stage of meiosis [16, 17]. Previous studies showed that incomplete nuclear
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maturation and cytoplasmic maturation of in vitro matured pigs oocytes explains the lower
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efficiency of embryo development in vitro [4, 18-20]. Many stressors, such as medium
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composition or culture conditions, affect the developmental competence and quality of in
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vitro matured porcine oocytes during in vitro maturation (IVM) [21-24]. To improve the
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quality of in vitro matured porcine oocytes, which undergo complete nuclear maturation and
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cytoplasmic maturation, several studies have focused on improving the efficiency of the IVM
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system via supplementation and/or the use of chemically defined media [25-28].
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ACCEPTED MANUSCRIPT C-phycocyanin (C-PC) is a biliprotein present in blue green algae, such as Spirulina
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platensis, which shows potential biological activities [29]. An increasing number of studies
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has suggested that C-PC can be used as a dietary supplement in food because of its
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anti-microbial, anti-inflammatory, neuroprotective, and hepatoprotective effects [30-32].
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C-PC is also a potential therapeutic agent for oxidative stress-induced disease [33]. Moreover,
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C-PC can prevent early signs of osteoarthritis caused by compressive stress and attenuate
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H2O2-induced oxidative stress [34]. A recent study showed that C-PC administration to
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D-galactose-induced
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effects and prevented oocyte fragmentation and aneuploidy by maintaining cytoskeletal
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integrity [35].
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aging mice significantly increased litter size through its antioxidant
The biological activities and physiological functions of C-PC for curing diseases are
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well documented. However, information on the effects of C-PC on livestock oocyte
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maturation and their subsequent embryonic development is lacking. Therefore, the objective
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of the present study was to investigate the effect of C-PC supplementation of maturation
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medium on porcine oocyte maturation and subsequent embryonic development after
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parthenogenetic activation (PA) and SCNT. We compared blastocyst formation and quality,
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oocyte nuclear maturation, cumulus expansion degree and relative gene expression (HAS2,
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PTX3, and PTGS2), intracellular levels reactive oxygen species (ROS), and glutathione
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(GSH), total antioxidant capacity (TAC), superoxide dismutase (SOD) activity, cathepsin B
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activity, and mitochondria function in porcine oocytes.
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2. Material and Methods
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This study was approved by the Ethics Committee of Chungbuk National University,
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Korea and conducted in accordance with institutional guidelines. All chemicals used in this
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study were purchased from Sigma Chemical Co. (Sigma, St. Louis, MO, USA) unless stated
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otherwise.
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2.1 Porcine oocyte collection and in vitro maturation (IVM)
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to the laboratory in sterile saline containing 75 µg/mL penicillin G and 50 µg/mL
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streptomycin sulfate at 35–37°C within 2 h in an insulated flask. Cumulus-oocyte complexes
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(COCs) were aspirated from antral follicles and collected under a stereo microscope. The
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COCs were washed three times in Tyrode's Lactate HEPES medium. Oocytes were only
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selected for further experiments if they had a homogeneous ooplasm and were surrounded by
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a minimum of three layers of cumulus cells. The COCs were cultured in tissue culture
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medium 199 (TCM-199, Invitrogen, Carlsbad, CA, USA) supplemented with 10% (v/v)
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porcine follicular fluid, 1 µg/mL insulin, 75 µg/mL kanamycin, 0.91 mM Na pyruvate, 10
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ng/mL epidermal growth factor, 0.5 µg/mL follicle stimulating hormone, and 0.5 µg/mL
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luteinizing hormone for 42 h at 38.5°C in an atmosphere containing 5% CO2 at 100%
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humidity. Oocyte maturation was performed by culturing approximately 50 COCs in 500 µL
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of maturation medium in 4-well dishes containing various concentrations of C-PC (0, 1, 3, 5,
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10 µg/mL) during the entire maturation period. Before use, C-PC was dissolved in maturation
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medium to prepare a stock solution and stored in the dark at -20°C.
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2.2 PA, SCNT, and embryo culture
For PA, matured oocytes were parthenogenetically activated by two direct-current (DC)
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pulses of 120 V/mm for 60 µs in 300 mM mannitol containing 0.1 mM CaCl2, 0.05 mM
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MgSO4, 0.01% polyvinyl alcohol (PVA) (w/v), and 0.5 mM HEPES.
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For SCNT, porcine fetal fibroblasts were used as nuclear donors and cultured as
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previously described [36]. Oocytes were enucleated by aspirating the polar body and
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metaphase chromosomes in a small amount (<15% of the oocyte volume) of cytoplasm using
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a 25-µm beveled glass pipette (Humagen, Charlottesville, VA, USA). After enucleation using
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a fine injecting pipette, a single donor cell was inserted into the perivitelline space of the
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enucleated oocyte. Membrane fusion was induced by applying an alternating current field of
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2 V cycling at 1 MHz for 2 s, followed by a DC pulse of 200 V/mm for 20 µs, using a cell
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fusion generator (LF201; Nepa Gene, Chiba, Japan). Following fusion, the reconstructed
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embryos were placed in bicarbonate-buffered porcine zygote medium 5 (PZM-5) containing
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0.4 mg/mL bovine serum albumin (BSA) for 1 h prior to activation. Activation was
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performed by applying DC pulses of 150 V/mm for 100 µs in 297 mM mannitol containing
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0.1 mM CaCl2, 0.05 mM MgSO4, 0.01% PVA (w/v), and 0.5 mM HEPES. The activated oocytes or reconstructed embryos were cultured in bicarbonate-buffered
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PZM-5 containing 4 mg/mL BSA and 7.5 µg/mL cytochalasin B for 3 h to suppress extrusion
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of the pseudo-second polar body. Next, the activated oocytes or reconstructed embryos were
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thoroughly washed and cultured in bicarbonate-buffered PZM-5 supplemented with 4 mg/mL
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BSA for 7 days at 38.5°C in an atmosphere containing 5% CO2 at 100% humidity without
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changing the medium. The development of activated oocytes or reconstructed embryos into
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blastocysts was examined at 7 days after activation. To count total cell numbers, blastocysts
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were stained with 10 µg/mL Hoechst 33342 for 15 min, mounted on glass slides, and
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examined under a fluorescence microscope (IX70, Olympus, Tokyo, Japan).
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2.3 5-Bromo-2′-deoxyuridine (BrdU) analysis
Cell proliferation was assessed by performing a BrdU assay [37]. Blastocysts were
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incubated with 100 µM BrdU in a humidified atmosphere of 5% CO2 at 38.5°C for 6 h. These
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blastocysts were washed three times with Dulbecco's phosphate-buffered saline (PBS)
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containing 0.05% Tween 20 (PBS-T), fixed in ice-cold methanol for 20 min, and
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permeabilized with 0.2% Triton X-100 for 2 min. The blastocysts were then washed with
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PBS-T and treated with 2 N HCl at room temperature for 30 min. Next, the blastocysts were
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washed and incubated with a mouse anti-BrdU monoclonal antibody (Sigma; B2531) diluted
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1:10 at 4°C overnight. After washing with 0.1% BSA prepared in PBS, the blastocysts were
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incubated with a rabbit anti-mouse IgG Alexa Fluor 568-conjugated polyclonal antibody
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(1:200; Cat: A-11061; Invitrogen) at room temperature for 1 h. After extensive washing with
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PBS-T, embryos were counterstained with 10 µg/mL Hoechst 33342 for 15 min, mounted on
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glass slides, and examined under a confocal laser scanning microscope (LSM 510 and 710
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META, Zeiss, Oberkochen, Germany). Proliferating cells in blastocysts were counted using
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NIH Image J software (National Institutes of Health, Bethesda, MD, USA).
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2.4 Real-time quantitative RT-PCR analysis Total RNA was extracted from cumulus cells from the control and C-PC groups using a
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Dynabeads mRNA Direct Kit (Invitrogen) according to the manufacturer’s instructions.
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First-strand cDNA was synthesized by reverse transcription of mRNA using the Oligo (dT)
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primer and SuperScript TM III reverse transcriptase (Invitrogen). Real-time RT-PCR was
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performed with SYBR Green, a fluorophore that binds to double-stranded DNA, in a final
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reaction volume of 20 µL using a CFX96 touch real-time RT-PCR detection system (Bio-Rad,
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Hercules, CA, USA). Finally, gene expression was quantified using the 2-△△Ct method, with
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normalization to the mRNA expression of GAPDH. The PCR primers used to amplify each
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gene are listed in Supplementary Table 1.
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2.5 Detection of intracellular ROS and GSH levels
To determine intracellular ROS levels, oocytes were incubated for 15 min in PBS containing 0.1% PVA (PBS-PVA) medium and 10
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diacetate. To detect intracellular GSH levels, the oocytes were incubated for 30 min in
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PBS-PVA medium containing 10 µM 4-chloromethyl-6,8-difluoro-7-hydroxycoumarin dye.
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Fluorescence signals were captured as TIFF files using a digital camera (DP72; Olympus)
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connected to a fluorescence microscope. The same procedures were used for all groups of
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oocytes, including incubation, rinsing, and imaging. NIH Image J software was used to
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analyze the fluorescence intensities of the oocytes.
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2.6 Measurement of TAC and SOD activity
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To measure TAC, 100 oocytes in each group were washed three times with cold PBS
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prior to lysis. Oocytes were lysed by sonication in cold PBS and centrifuged at 10,000 ×g for
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10 min at 4°C; the supernatant was retained for analysis. To measure SOD activity, 100
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oocytes in each group were placed in 500 µL cold 1X lysis buffer (10 mM Tris, PH 7.5, 150
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mM NaCl, 0.1 mM EDTA), lysed by sonication, and centrifuged at 1200 rpm for 10 min. The
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supernatant was assayed for CAT activity (STA-360-T, Cell Biolabs, San Diego, CA, USA)
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and SOD activity (STA-340-T, Cell Biolabs) using commercial assay kits according to the
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manufacturer’s instructions.
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2.7 Mitochondrial membrane potential (∆Ψm) assay To measure ∆Ψm, oocytes were washed three times with PBS-PVA and incubated in in
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5,5′,6,6′-tetrachloro-1,1′,3,3′-tetraethyl-imidacarbocyanine iodide (JC-1; Invitrogen) for 30
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min. ∆Ψm was calculated as the ratio of red florescence (corresponding to activated
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mitochondria; J-aggregates) to green fluorescence (corresponding to less active mitochondria;
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J-monomers) [38]. Fluorescence signals were captured as a TIFF file using a digital camera
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connected to a fluorescence microscope. The fluorescence intensity of the images were
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processed and measured using NIH Image J software.
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2.8 Cathepsin B activity assays
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Intracellular cathepsin B activity was detected using a commercial Magic red cathepsin
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B assay kit (Immunochemistry Technologies, LLC, Bloomington, MN, USA) according to
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the manufacturer’s protocol. Briefly, oocytes were incubated in 500 µL PBS-PVA, with 2 µL
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reaction mix for 20 min at 38.5°C in a humidified atmosphere of 5% CO2. The fluorescence
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signals were captured as a TIFF file using a digital camera connected to a fluorescence
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microscope. NIH Image J software was used to analyze the fluorescence intensities of the
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oocytes.
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2.9 Statistical analysis
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All data were subjected to arcsine transformation prior to statistical analysis and
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presented as the mean ± SEM. Comparisons of data between groups were performed with
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Student's t test. All statistical analysis was performed using the software package GraphPad
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Prism (version 6.01; GraphPad, Inc., La Jolla, CA, USA). p < 0.05 was considered
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statistically significant.
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3. Results
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3.1 Effects of C-PC supplementation during maturation period on polar body extrusion (PBE)
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and developmental competence of pig oocytes We first evaluated the effects of different concentrations (0, 1, 3, 5, 10 µg/mL) of C-PC on
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the PBE of porcine oocytes. The PBE rate was determined after 42 h of IVM and the results
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are shown in Fig. 1A and B. The rate of PBE ranged from 83.3 ± 2.3% to 87.1 ± 2.4% and did
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not differ significantly between the control group and C-PC-supplemented groups (p > 0.05).
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We further investigated the development of porcine oocyte PA after IVM. As shown in Fig.
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1C and D, there was a significant increase in blastocyst formation and the hatching rates in
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the 5 µg/mL C-PC supplementation group compared to in the control group (59.6 ± 3.6% and
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33.0 ± 2.6% vs. 49.8 ± 3.5% and 27.4 ± 2.4%, respectively; p < 0.05). No significant
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differences in blastocyst formation and hatching rates were observed among the control and 0,
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1, 3, and 10 µg/mL supplementation groups. These results revealed 5 µg/mL as the optimal
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concentration; hence, this was used in the subsequent experiments.
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3.2 C-PC supplementation during maturation period improves porcine SCNT embryo
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development
We next assayed whether C-PC supplementation during the maturation period improved
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the developmental competence of porcine SCNT embryos. The analysis of in vitro SCNT
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embryo developmental competence revealed that C-PC supplementation during the
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maturation period significantly improved the developmental potency of IVM oocytes. As
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shown in Fig. 2, the frequency of blastocyst formation and number of blastocyst cells were
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significantly increased in the C-PC group (24.8 ± 1.9% and 42.2 ± 3.3, respectively)
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compared to in the control group (21.6 ± 2.2% and 39.5 ± 3.4, respectively, p < 0.05). We
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further evaluated the cellular proliferative capacity in these SCNT embryos using the BrdU
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assay. We found that the percentage of BrdU-positive cells in blastocysts derived from mature
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COCs in the C-PC group was significantly higher than that in the control group (Fig. 3A and
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B; p < 0.05). Consistent with this result, expression of the pluripotency markers SOX2 and
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NANOG was increased significantly in blastocysts obtained from C-PC-supplemented COCs
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than those in the control group (Fig. 3C and D; p < 0.05).
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3.3 Effects of C-PC supplementation during maturation period on cumulus expansion in
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porcine COCs Cumulus expansion is necessary for oocyte maturation and is routinely employed IVM as a
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gross indicator of oocyte quality [39]. Therefore, we evaluated the effects of C-PC
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supplementation during the maturation period on cumulus expansion, followed by an analysis
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of the degree of cumulus cell expansion and expression of genes related to cumulus
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expansion genes (HAS2, PTX3, and PTGS2). As shown in Fig. 4A, C-PC supplementation
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during the maturation period significantly increased the proportion of COCs exhibiting
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complete cumulus expansion (degree 4, p < 0.05). However, other degree of cumulus cell
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expansion did not differ significantly between the C-PC-supplemented COC group and
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control group (p > 0.05). We also observed increased expression of cumulus
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expansion-related genes (HAS2, PTX3 and PTGS2) after C-PC supplementation during the
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maturation period (Fig. 4B; p < 0.05). These results suggest that C-PC supplementation
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during the maturation period improves cumulus expansion in porcine COCs.
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3.4 Effects of C-PC supplementation during maturation period on intracellular ROS and
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GSH level in porcine oocytes
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Because C-PC has antioxidant properties, we hypothesized that C-PC increases the
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resistance of embryos to oxidative stress. Therefore, we evaluated the effects of C-PC
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supplementation during the maturation period on intracellular ROS and GSH levels in
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porcine after IVM. As shown in Fig. 5A, significantly lower intracellular ROS levels were
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observed in the C-PC supplementation group during the maturation period (p < 0.05). The
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intracellular GSH level was significantly increased in the C-PC-supplemented group
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compared to in the control group (p < 0.05; Fig. 5B). In addition, we evaluated SOD activity
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and TAC in porcine after IVM. SOD activity was significantly increased in the
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C-PC-supplemented group compared to in the control group (p < 0.05; Fig. 5C). Similarly,
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TAC was significantly increased in the C-PC-supplemented group compared to in the control
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group (p < 0.05; Fig. 5D).
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3.5 Effects of C-PC supplementation during maturation period on mitochondria function in
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porcine oocytes Mitochondria in mammalian cells have a major effect on the production of cellular energy.
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To further explore the mechanism by which C-PC supplementation during the maturation
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period improves the developmental potential of porcine oocytes, ∆Ψm was evaluated.
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Representative images of mitochondrial ∆Ψm are shown in Fig. 7A. The average value of
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∆Ψm (Fig. 7B) in oocytes significantly increased upon C-PC supplementation during the
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maturation period (p < 0.05).
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3.6 Effects of C-PC supplementation during maturation period on cathepsin B activity in
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porcine oocytes
To further analyze the influence of C-PC supplementation during the maturation period on
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the quality of porcine oocytes, we evaluated cathepsin B activity in oocytes after IVM. As
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shown in Fig. 6A and B, matured oocytes derived from the supplemented group showed
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significantly decreased cathepsin B activity compared to the control group (p < 0.05).
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4. Discussion In the present study, we investigated whether supplementation of C-PC during the IVM
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period improves porcine oocyte quality and pre-implantation embryo development after PA
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and SCNT. This study revealed that C-PC enhanced the developmental potential of porcine
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oocytes when supplemented during the IVM period. Moreover, we found that C-PC
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supplementation during the IVM period improved the developmental competence of PA and
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SCNT embryos. Importantly, C-PC decreased intracellular ROS levels, increased intracellular
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GSH levels, improved mitochondria function, and decreased intracellular cathepsin B activity
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during the IVM period, suggesting that C-PC promotes porcine oocyte cytoplasm maturation.
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This is the first study showing that C-PC is correlated with porcine oocyte quality and
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subsequent embryo developmental competence after PA and SCNT.
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Oocyte quality, including nuclear and cytoplasm maturation, is an important determinant
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of embryo developmental competence [40]. Cloned embryos can be produced using in vivo or
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in vitro matured oocytes [41, 42]. However, oocytes matured in vitro frequently exhibit low
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quality, including incomplete nuclear and cytoplasmic maturation, compared to in vivo
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matured oocytes [43]. A previous study suggested that the decreased quality of porcine
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oocytes influences both pre-implantation cloned embryonic development and fetal
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development [44]. Therefore, enhancing oocyte quality is very important for the
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developmental ability of embryos produced by SCNT. In the present study, we found that the
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proportion of PA embryos undergoing blastocyst formation and hatching significantly
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increased when the IVM medium was supplemented with 5 µg/mL C-PC. However,
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unexpectedly, C-PC supplementation during the IVM period did not affect porcine oocyte
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PBE. Further analyses revealed that C-PC supplementation during the IVM period clearly
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improved SCNT embryo development and the quality of these embryos as indicated by total
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cell numbers, cellular proliferation, and pluripotency gene expression in blastocysts. These
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results highlight the positive effect of C-PC supplementation during the IVM period on the
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developmental competence of PA and SCNT embryos.
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During oocyte maturation, cumulus cell expansion is necessary for oocyte maturation
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and the acquisition of developmental competence by releasing and mediating signals to
ACCEPTED MANUSCRIPT oocytes [45, 46]. The degree of cumulus expansion is routinely evaluating during IVM as a
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gross indicator of oocyte maturation and the outcome of embryo in vitro culture [35].
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Cumulus expansion may play a role as a structural component of expanded cumuli and
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molecular signals regulating oocyte maturation [47]. The oocytes with high fertilizing
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capacity and developing competence have been attributed to expansion of cumulus cell [48].
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In the current study, supplementation with C-PC during the IVM period dramatically
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increased cumulus expansion of porcine cumulus cells and expression of expansion-related
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transcripts in cumulus cells (HAS2, PTX3, and PTGS2). Therefore, C-PC supplementation
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during the IVM period improves the developmental competence of PA and SCNT embryos in
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part by affecting porcine cumulus cell expansion.
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Oxidative stress is characterized by overproduction of free radicals, which can disrupt
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the balance of ROS and antioxidants under normal physiological conditions. ROS levels
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within an optimal range is required for normal cell metabolism, while excessive ROS
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generation may negatively influence cell membranes, protein synthesis, and lipid metabolism
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[49]. It has been demonstrated that high ROS levels in oocytes are detrimental to oocyte
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maturation and fertilization and impair embryo development [38]. The maturation status of
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oocyte cytoplasm plays an important role in successful embryonic genome activation at the
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onset of embryonic development by regulating reprogramming gene expression [50]. Porcine
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oocytes are particularly sensitive to damage caused by ROS because of the high lipid
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concentrations in the cytoplasm [51]. Therefore, suppression or removal of excess ROS using
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antioxidants may improve porcine oocyte quality and subsequently embryo development.
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Supplementation of antioxidants during the IVM period has been shown to influence oocyte
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maturation and embryo development [52]. It had been suggested that supplementation with
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antioxidants in IVM medium, such as β-mercaptoethanol and L-carnitine, improves SCNT
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embryonic development [53] [54]. This may be because of increased transcription factor
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expression, which stimulates nuclear reprogramming. Therefore, we hypothesized that C-PC
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affects porcine oocyte maturation by regulating oxidative stress-induced impairments. We
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found that IVM media supplemented with 5 µg/mL C-PC effectively decreased intracellular
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ROS levels in mature oocytes. A previous study suggested that supplementation of C-PC can
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effectively prevent H2O2-induced oxidative stress and early signs of osteoarthritis [34]. In
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addition, C-PC can protect and repair the ischemic brain via improved antioxidative,
349
neurotrophic,
350
doxorubicin-induced oxidative stress and apoptosis in cardiomyocytes [56]. Therefore, C-PC
351
reduces ROS levels in oocytes during the IVM period, thus improving porcine oocyte quality
352
and enhancing subsequent embryo developmental competence after PA and SCNT. This
353
explains why C-PC affect porcine cumulus cell expansion may occur through decreased
354
oxygen tension in close proximity to the oocyte as a result of active cumulus cell metabolism
355
[57].
anti-inflammatory
mechanisms
[55].
C-PC
also
ameliorated
SC
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and
GSH is an important antioxidant found in mammalian cells and functions as a scavenger
357
of ROS [58]. Intracellular GSH are used to predict cytoplasmic maturation in porcine oocytes
358
[21]. In vivo matured oocytes exhibit higher GSH and developmental competence than in
359
vitro matured oocytes [59, 60]. Therefore, increasing the intracellular GSH level can protect
360
oocytes from oxidative damage and increase cytoplasmic maturation. A previous study
361
suggested that supplementation of antioxidants during IVM influences oocyte maturation and
362
improves its developmental potency by increasing intracellular GSH levels. In the present
363
study, inclusion of 5 µg/mL C-PC in the IVM media significantly improved intracellular
364
GSH levels. SOD is an effective defense enzyme that catalyzes the dismutation of superoxide
365
anions into H2O2. A previous study showed that C-PC restores SOD and GSH-Px activities in
366
CCl4-induced damaged livers and increases GSH level [61]. Furthermore, an imbalance
367
between TAC and increased ROS levels surrounding the embryo may lead to oxidative stress
368
[62, 63]. In the present study, we found that C-PC supplementation during the IVM period
369
effectively increased the TAC and activity of SOD in porcine oocytes. Therefore, C-PC
370
supplemented during the maturation period promotes cytoplasmic maturation of oocytes,
371
which may be because increased intracellular GSH levels contribute to higher embryonic
372
development following PA and SCNT.
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373
Mitochondria are major producers of ROS and ATP, which influence oocyte
374
developmental potential and are associated with fertilization and embryonic development
375
[64]. ∆Ψm is commonly used as an indicator of mitochondrial function in oocytes [65] and is
ACCEPTED MANUSCRIPT the driving force behind ATP production [66]. A previous study showed that C-PC restored
377
oxalate-induced decreases in ATP levels in MDCK cells [67]. In addition, C-PC can prevents
378
cisplatin-induced mitochondrial dysfunction and oxidative stress [68]. In the current study,
379
we found that supplementation of C-CP during the IVM period led to increased ∆Ψm in
380
porcine oocytes. It does not seem likely that C-CP improves porcine oocyte quality by
381
improving mitochondrial function. Cathepsin B is a lysosomal cysteine proteinase in normal
382
cells and tissues and plays an important role in intracellular proteolysis [69]. Recent studies
383
have shown that cathepsin B activity is a marker of poor-quality oocytes and embryos, which
384
is associated with low developmental competence [62, 63]. In the present study, the
385
decreased cathepsin B activity in porcine oocytes further revealed that C-CP supplementation
386
during the IVM period positively affected porcine quality.
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376
In conclusion, our results suggest that C-PC supplementation during the IVM period has
388
beneficial effects on porcine oocytes maturation, particularly cytoplasm maturation, and
389
subsequent developmental competence of embryos produced from PA and SCNT. These
390
findings will be useful for improving the efficiency of producing SCNT embryos in pig.
391
However, additional studies should examine these factors in fertilized embryos.
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Acknowledgements
This study was supported by a grant from the Next-Generation BioGreen 21 Program (PJ011126), Rural Development Administration (RDA), Republic of Korea.
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Additional Information
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Competing Interests: The authors declare that they have no competing interests.
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Figure legends
568
Fig. 1. Effects of C-PC treatment during in vitro maturation at different concentrations on
569
porcine oocyte polar body extrusion (PBE) and subsequent in vitro developmental
570
competence of parthenogenetic embryos. (A) Representative fluorescent images of metaphase
571
II (MII) stage oocyte with an extruded polar body. Blue: DNA; Green: α-tubulin (B) PBE rate.
572
(C) Blastocyst formation rate. (D) Blastocyst hatching rate. The numbers of embryos
573
examined in each experimental group are shown in the bar.
574
differences are represented with different letters (p < 0.05). Data are expressed as the mean ±
575
SEM from at least three separate experiments. Scale bar = 20 µm.
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567
Statistically significant
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a, b
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Fig. 2. Effects of C-PC treatment during in vitro maturation on the developmental
578
competence of porcine cloned embryo. (A) Blastocyst formation was examined at day 7. (B)
579
Blastocyst rate. (C) Total cell number in each blastocyst. The numbers of embryos examined
580
in each experimental group are shown in the bar.
581
represented with different letters (p < 0.05). Data are expressed as the mean ± SEM from at
582
least three separate experiments. Scale bar = 100 µm.
Statistically significant differences are
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a, b
583
Fig. 3. Effect of C-PC treatment during in vitro maturation on expression of genes related to
585
cell proliferation, apoptosis, pluripotency, and apoptosis in porcine cloned embryo. (A)
586
Immunofluorescence staining of BrdU in porcine cloned embryo at blastocyst stage. (B)
587
Percentages
588
pluripotency-related genes in blastocyst. The numbers of embryos examined in each
589
experimental group are shown in the bar.
590
represented with different letters (p < 0.05). Data are expressed as the mean ± SEM from at
591
least three separate experiments. Scale bar = 20 µm.
BrdU-positive
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of
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cells
in
blastocyst.
a, b
(C)
Relative
expression
of
Statistically significant differences are
592 593
Fig. 4. Effect of C-PC treatment during in vitro maturation on cumulus cell expansion and
594
relative gene expression in porcine cumulus cell. (A) The degree of cumulus expansion in
595
porcine cumulus oocyte complexes. (B) Cumulus expansion-related genes in porcine cumulus
ACCEPTED MANUSCRIPT a, b
596
cell.
Statistically significant differences are represented with different letters (p < 0.05).
597
Data are expressed as the mean ± SEM from at least three separate experiments.
598
Fig. 5. Effect of C-PC treatment during in vitro maturation on ROS and GSH levels, total
600
antioxidant capacity (TAC), and superoxide dismutase (SOD) activity in porcine oocytes.
601
Intracellular ROS (A) and GSH (B) levels. (C) TCA. (D) SOD activity. The numbers of
602
embryos examined in each experimental group are shown in the bar.
603
significant differences are represented with different letters (p < 0.05). Data are expressed as
604
the mean ± SEM from at least three separate experiments.
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599
Statistically
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a, b
605
Fig. 6. Effect of C-PC treatment during in vitro maturation on mitochondrial membrane
607
potential (∆Ψm) in porcine oocytes. (A) Representative fluorescent images of 5,5′,6,
608
6′-tetrachloro-1,1′,3,3′-tetraethyl-imidacarbocyanine iodide (JC-1) staining in MII stage
609
oocytes. (B) Quantification of fluorescence intensity of JC-1. The numbers of embryos
610
examined in each experimental group are shown in the bar.
611
differences are represented with different letters (p < 0.05). Data are expressed as the mean ±
612
SEM from at least three separate experiments. Scale bar = 50 µm.
a, b
Statistically significant
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Fig. 7. Effect of C-PC treatment during in vitro maturation on cathepsin B activity in porcine
615
oocytes. (A) Representative fluorescent images showing cathepsin B activity in MII stage
616
oocytes. Red: Cathepsin B. (B) Quantification of fluorescence intensity of intracellular
617
cathepsin B activity. The numbers of embryos examined in each experimental group are
618
shown in the bar.
619
(p < 0.05). Data are expressed as the mean ± SEM from at least three separate experiments.
620
Scale bar = 50 µm.
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a, b
Statistically significant differences are represented with different letters
ACCEPTED MANUSCRIPT Table 1. Primer sequences used in real-time RT-PCR
Primer sequence (5’-3’) F: CCCCGCCCTATGACTTCT
POU5F1
60 R: TAGGAGCTTGGCAAATTGTTC F: CGCAGACCTACATGAACG 60 R: TCGGACTTGACCACTGAG F: CTCTCCTCTTCCTTCCTC
60
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NANONG
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SOX2
Product Size (bp)
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Gene
Annealing Temperature (°C)
269
103
139
R: CTTCTGCTTCTTGACTGG
F: AGTTTATGGGCAGCCAATGTAGTT HAS2
60
101
60
185
60
194
60
117
R: GCACTTGGACCGAGCTGTGT F: GCACTTGGACCGAGCTGTGT PTX3
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R: GCTATCCTCTCCAACAAGTGA F: ACAGGGCCATGGGGTGGACT PTGS2
R: CCACGGCAAAGCGGAGGTGT F: TTCCACGGCACAGTCAAG
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GAPDH
R: ATACTCAGCACCAGCATCG
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F, forward; R, reverse.
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B
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A
Blue: DNA; Green: α-tubulin
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C
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A
Control
C-CP
B
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C
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DNA
Brdu
Merge
B
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C-PC
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Control
A
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C
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B
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A
B
C
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A
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D
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Light
JC-1 green
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B
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C-CP
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Control
A
JC-1 red
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Control
C-CP
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A
Red: Cathepsin B
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B
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Highlights •
C-Phycocyanin significantly
supplementation increased
the
during
in
developmental
vitro
maturation
competence
of
period porcine
parthenogenetic and cloned embryos. C-Phycocyanin enhanced antioxidant capacity, improved mitochondria
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•
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function, and decreased cathepsin B activity in porcine oocytes.
S0093-691X(17)30420-X
DOI:
10.1016/j.theriogenology.2017.09.001
Reference:
THE 14248
To appear in:
Theriogenology
Received Date: 29 June 2017 Revised Date:
30 August 2017
Accepted Date: 1 September 2017
Please cite this article as: Liang S, Guo J, Jin YX, Yuan B, Zhang J-B, Kim N-H, C-Phycocyanin supplementation during in vitro maturation enhances pre-implantation developmental competence of parthenogenetic and cloned embryos in pigs, Theriogenology (2017), doi: 10.1016/ j.theriogenology.2017.09.001. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.
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Revised
2
C-Phycocyanin supplementation during in vitro maturation enhances
3
pre-implantation developmental competence of parthenogenetic and cloned
4
embryos in pigs
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1
5
Shuang Liang a, b, Jing Guo b, Yong Xun Jin a, Bao Yuan a, Jia-Bao Zhang a* &
7
Nam-Hyung Kima, b*
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11 12 13 14 15
a
Department of Laboratory Animal Center, College of Animal Sciences, Jilin University,
Changchun, 130062, China. b
Department of Animal Science, Chungbuk National University, Cheongju, Chungbuk,
361-763, Republic of Korea.
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*Corresponding author: Nam-Hyung Kim and Jia-Bao Zhang.
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E-mail addresses: [email protected] (N.-H. Kim) and [email protected] (J.-B. Zhang).
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ABSTRACT
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C-Phycocyanin (C-PC), a protein from green microalgae, has been suggested to possess
20
various biological activities, including antioxidant and free radical scavenging properties. The
21
aim of the current study was to explore the effects of C-PC on the maturation of porcine
22
oocytes and subsequent developmental competence after parthenogenetic activation and
23
somatic cell nuclear transfer (SCNT) as well as the underlying mechanisms. There was no
24
significant improvement in nuclear maturation rates between the control and C-PC
25
supplementation groups (1, 3, 5, 10 µg/mL). However, supplementation of 5 µg/mL C-PC in
26
the maturation medium significantly increased blastocyst formation and hatching rates after
27
parthenogenetic activation (59.6 ± 3.6% and 33.0 ± 2.6% vs. 49.8 ± 3.5% and 27.4 ± 2.4%,
28
respectively). In addition, the presence of C-PC during the maturation period significantly
29
improved blastocyst formation rates and total cell numbers after SCNT (24.8 ± 1.9% and 42.2
30
± 3.3 vs. 21.6 ± 2.2% and 39.5 ± 3.4, respectively) compared to the control group.
31
Furthermore, cellular proliferation and the expression of pluripotency-related genes (SOX2
32
and NANOG) were increased in cloned blastocysts derived from the C-PC supplemented
33
group. Importantly, C-PC supplementation during maturation not only improved cumulus
34
expansion and increased the expression of cumulus expansion-related genes (HAS2, PTX3,
35
and PTGS2), but also enhanced antioxidant capacity, improved mitochondria function, and
36
decreased cathepsin B activity in porcine oocytes. These results demonstrate that C-PC may
37
be useful for improving porcine oocyte quality and subsequent developmental competence in
38
embryos.
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Keywords: In vitro maturation, C-phycocyanin, Porcine oocyte, Parthenogenetic activation,
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Somatic cell nuclear transfer
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1. Introduction Somatic cell nuclear transfer (SCNT) is a useful technology with applications in
44
transgenic animals, preserving species, stem cell research, and regenerative medicine. During
45
SCNT, the nucleus of a somatic cell is transferred into a healthy enucleated metaphase II (MII)
46
stage oocyte to generate a new individual compatible with the somatic cell donor [1]. It has
47
been suggested that pigs share several characteristics with humans, and generating genetic
48
modifications in pigs using SCNT technology may be an excellent model for biomedical
49
studies and xenotransplantation [2, 3]. Many studies have attempted to improve the success
50
rate of producing porcine cloned embryos in vitro [4-6]. However, compared with embryos
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derived from oocytes matured in vivo, the developmental competence of embryos derived
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from oocytes matured in vitro remains low [7, 8].
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Many factors affect the efficiency of generating cloned pigs with SCNT technology [9,
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10]. Among these factors, oocyte quality is the most important factor affecting the
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developmental competence of cloned embryos [11, 12]. Oocyte maturation is a complex
56
process that includes nuclear and cytoplasmic maturation [13]. Any errors in this process can
57
lead to the failure of further embryonic development [14]. Therefore, high-quality or
58
developmentally competent oocytes are vital for fertilization and embryo development. In
59
general, oocyte quality and developmental competence are obtained during follicular
60
development under in vivo conditions [15]. When oocytes are liberated from their follicles,
61
they can undergo spontaneous meiotic resumption under in vivo condition and become
62
arrested in the MII stage of meiosis [16, 17]. Previous studies showed that incomplete nuclear
63
maturation and cytoplasmic maturation of in vitro matured pigs oocytes explains the lower
64
efficiency of embryo development in vitro [4, 18-20]. Many stressors, such as medium
65
composition or culture conditions, affect the developmental competence and quality of in
66
vitro matured porcine oocytes during in vitro maturation (IVM) [21-24]. To improve the
67
quality of in vitro matured porcine oocytes, which undergo complete nuclear maturation and
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cytoplasmic maturation, several studies have focused on improving the efficiency of the IVM
69
system via supplementation and/or the use of chemically defined media [25-28].
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ACCEPTED MANUSCRIPT C-phycocyanin (C-PC) is a biliprotein present in blue green algae, such as Spirulina
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platensis, which shows potential biological activities [29]. An increasing number of studies
72
has suggested that C-PC can be used as a dietary supplement in food because of its
73
anti-microbial, anti-inflammatory, neuroprotective, and hepatoprotective effects [30-32].
74
C-PC is also a potential therapeutic agent for oxidative stress-induced disease [33]. Moreover,
75
C-PC can prevent early signs of osteoarthritis caused by compressive stress and attenuate
76
H2O2-induced oxidative stress [34]. A recent study showed that C-PC administration to
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D-galactose-induced
78
effects and prevented oocyte fragmentation and aneuploidy by maintaining cytoskeletal
79
integrity [35].
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aging mice significantly increased litter size through its antioxidant
The biological activities and physiological functions of C-PC for curing diseases are
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well documented. However, information on the effects of C-PC on livestock oocyte
82
maturation and their subsequent embryonic development is lacking. Therefore, the objective
83
of the present study was to investigate the effect of C-PC supplementation of maturation
84
medium on porcine oocyte maturation and subsequent embryonic development after
85
parthenogenetic activation (PA) and SCNT. We compared blastocyst formation and quality,
86
oocyte nuclear maturation, cumulus expansion degree and relative gene expression (HAS2,
87
PTX3, and PTGS2), intracellular levels reactive oxygen species (ROS), and glutathione
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(GSH), total antioxidant capacity (TAC), superoxide dismutase (SOD) activity, cathepsin B
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activity, and mitochondria function in porcine oocytes.
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2. Material and Methods
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This study was approved by the Ethics Committee of Chungbuk National University,
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Korea and conducted in accordance with institutional guidelines. All chemicals used in this
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study were purchased from Sigma Chemical Co. (Sigma, St. Louis, MO, USA) unless stated
95
otherwise.
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2.1 Porcine oocyte collection and in vitro maturation (IVM)
ACCEPTED MANUSCRIPT Ovaries were obtained from slaughtered sows at a local slaughterhouse and transported
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to the laboratory in sterile saline containing 75 µg/mL penicillin G and 50 µg/mL
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streptomycin sulfate at 35–37°C within 2 h in an insulated flask. Cumulus-oocyte complexes
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(COCs) were aspirated from antral follicles and collected under a stereo microscope. The
102
COCs were washed three times in Tyrode's Lactate HEPES medium. Oocytes were only
103
selected for further experiments if they had a homogeneous ooplasm and were surrounded by
104
a minimum of three layers of cumulus cells. The COCs were cultured in tissue culture
105
medium 199 (TCM-199, Invitrogen, Carlsbad, CA, USA) supplemented with 10% (v/v)
106
porcine follicular fluid, 1 µg/mL insulin, 75 µg/mL kanamycin, 0.91 mM Na pyruvate, 10
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ng/mL epidermal growth factor, 0.5 µg/mL follicle stimulating hormone, and 0.5 µg/mL
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luteinizing hormone for 42 h at 38.5°C in an atmosphere containing 5% CO2 at 100%
109
humidity. Oocyte maturation was performed by culturing approximately 50 COCs in 500 µL
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of maturation medium in 4-well dishes containing various concentrations of C-PC (0, 1, 3, 5,
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10 µg/mL) during the entire maturation period. Before use, C-PC was dissolved in maturation
112
medium to prepare a stock solution and stored in the dark at -20°C.
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2.2 PA, SCNT, and embryo culture
For PA, matured oocytes were parthenogenetically activated by two direct-current (DC)
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pulses of 120 V/mm for 60 µs in 300 mM mannitol containing 0.1 mM CaCl2, 0.05 mM
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MgSO4, 0.01% polyvinyl alcohol (PVA) (w/v), and 0.5 mM HEPES.
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For SCNT, porcine fetal fibroblasts were used as nuclear donors and cultured as
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previously described [36]. Oocytes were enucleated by aspirating the polar body and
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metaphase chromosomes in a small amount (<15% of the oocyte volume) of cytoplasm using
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a 25-µm beveled glass pipette (Humagen, Charlottesville, VA, USA). After enucleation using
122
a fine injecting pipette, a single donor cell was inserted into the perivitelline space of the
123
enucleated oocyte. Membrane fusion was induced by applying an alternating current field of
124
2 V cycling at 1 MHz for 2 s, followed by a DC pulse of 200 V/mm for 20 µs, using a cell
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fusion generator (LF201; Nepa Gene, Chiba, Japan). Following fusion, the reconstructed
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embryos were placed in bicarbonate-buffered porcine zygote medium 5 (PZM-5) containing
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0.4 mg/mL bovine serum albumin (BSA) for 1 h prior to activation. Activation was
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performed by applying DC pulses of 150 V/mm for 100 µs in 297 mM mannitol containing
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0.1 mM CaCl2, 0.05 mM MgSO4, 0.01% PVA (w/v), and 0.5 mM HEPES. The activated oocytes or reconstructed embryos were cultured in bicarbonate-buffered
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PZM-5 containing 4 mg/mL BSA and 7.5 µg/mL cytochalasin B for 3 h to suppress extrusion
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of the pseudo-second polar body. Next, the activated oocytes or reconstructed embryos were
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thoroughly washed and cultured in bicarbonate-buffered PZM-5 supplemented with 4 mg/mL
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BSA for 7 days at 38.5°C in an atmosphere containing 5% CO2 at 100% humidity without
135
changing the medium. The development of activated oocytes or reconstructed embryos into
136
blastocysts was examined at 7 days after activation. To count total cell numbers, blastocysts
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were stained with 10 µg/mL Hoechst 33342 for 15 min, mounted on glass slides, and
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examined under a fluorescence microscope (IX70, Olympus, Tokyo, Japan).
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2.3 5-Bromo-2′-deoxyuridine (BrdU) analysis
Cell proliferation was assessed by performing a BrdU assay [37]. Blastocysts were
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incubated with 100 µM BrdU in a humidified atmosphere of 5% CO2 at 38.5°C for 6 h. These
143
blastocysts were washed three times with Dulbecco's phosphate-buffered saline (PBS)
144
containing 0.05% Tween 20 (PBS-T), fixed in ice-cold methanol for 20 min, and
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permeabilized with 0.2% Triton X-100 for 2 min. The blastocysts were then washed with
146
PBS-T and treated with 2 N HCl at room temperature for 30 min. Next, the blastocysts were
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washed and incubated with a mouse anti-BrdU monoclonal antibody (Sigma; B2531) diluted
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1:10 at 4°C overnight. After washing with 0.1% BSA prepared in PBS, the blastocysts were
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incubated with a rabbit anti-mouse IgG Alexa Fluor 568-conjugated polyclonal antibody
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(1:200; Cat: A-11061; Invitrogen) at room temperature for 1 h. After extensive washing with
151
PBS-T, embryos were counterstained with 10 µg/mL Hoechst 33342 for 15 min, mounted on
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glass slides, and examined under a confocal laser scanning microscope (LSM 510 and 710
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META, Zeiss, Oberkochen, Germany). Proliferating cells in blastocysts were counted using
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NIH Image J software (National Institutes of Health, Bethesda, MD, USA).
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2.4 Real-time quantitative RT-PCR analysis Total RNA was extracted from cumulus cells from the control and C-PC groups using a
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Dynabeads mRNA Direct Kit (Invitrogen) according to the manufacturer’s instructions.
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First-strand cDNA was synthesized by reverse transcription of mRNA using the Oligo (dT)
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primer and SuperScript TM III reverse transcriptase (Invitrogen). Real-time RT-PCR was
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performed with SYBR Green, a fluorophore that binds to double-stranded DNA, in a final
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reaction volume of 20 µL using a CFX96 touch real-time RT-PCR detection system (Bio-Rad,
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Hercules, CA, USA). Finally, gene expression was quantified using the 2-△△Ct method, with
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normalization to the mRNA expression of GAPDH. The PCR primers used to amplify each
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gene are listed in Supplementary Table 1.
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2.5 Detection of intracellular ROS and GSH levels
To determine intracellular ROS levels, oocytes were incubated for 15 min in PBS containing 0.1% PVA (PBS-PVA) medium and 10
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diacetate. To detect intracellular GSH levels, the oocytes were incubated for 30 min in
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PBS-PVA medium containing 10 µM 4-chloromethyl-6,8-difluoro-7-hydroxycoumarin dye.
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Fluorescence signals were captured as TIFF files using a digital camera (DP72; Olympus)
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connected to a fluorescence microscope. The same procedures were used for all groups of
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oocytes, including incubation, rinsing, and imaging. NIH Image J software was used to
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analyze the fluorescence intensities of the oocytes.
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2.6 Measurement of TAC and SOD activity
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To measure TAC, 100 oocytes in each group were washed three times with cold PBS
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prior to lysis. Oocytes were lysed by sonication in cold PBS and centrifuged at 10,000 ×g for
180
10 min at 4°C; the supernatant was retained for analysis. To measure SOD activity, 100
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oocytes in each group were placed in 500 µL cold 1X lysis buffer (10 mM Tris, PH 7.5, 150
182
mM NaCl, 0.1 mM EDTA), lysed by sonication, and centrifuged at 1200 rpm for 10 min. The
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supernatant was assayed for CAT activity (STA-360-T, Cell Biolabs, San Diego, CA, USA)
184
and SOD activity (STA-340-T, Cell Biolabs) using commercial assay kits according to the
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manufacturer’s instructions.
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2.7 Mitochondrial membrane potential (∆Ψm) assay To measure ∆Ψm, oocytes were washed three times with PBS-PVA and incubated in in
188
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5,5′,6,6′-tetrachloro-1,1′,3,3′-tetraethyl-imidacarbocyanine iodide (JC-1; Invitrogen) for 30
191
min. ∆Ψm was calculated as the ratio of red florescence (corresponding to activated
192
mitochondria; J-aggregates) to green fluorescence (corresponding to less active mitochondria;
193
J-monomers) [38]. Fluorescence signals were captured as a TIFF file using a digital camera
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connected to a fluorescence microscope. The fluorescence intensity of the images were
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processed and measured using NIH Image J software.
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2.8 Cathepsin B activity assays
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Intracellular cathepsin B activity was detected using a commercial Magic red cathepsin
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B assay kit (Immunochemistry Technologies, LLC, Bloomington, MN, USA) according to
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the manufacturer’s protocol. Briefly, oocytes were incubated in 500 µL PBS-PVA, with 2 µL
201
reaction mix for 20 min at 38.5°C in a humidified atmosphere of 5% CO2. The fluorescence
202
signals were captured as a TIFF file using a digital camera connected to a fluorescence
203
microscope. NIH Image J software was used to analyze the fluorescence intensities of the
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oocytes.
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2.9 Statistical analysis
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All data were subjected to arcsine transformation prior to statistical analysis and
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presented as the mean ± SEM. Comparisons of data between groups were performed with
209
Student's t test. All statistical analysis was performed using the software package GraphPad
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Prism (version 6.01; GraphPad, Inc., La Jolla, CA, USA). p < 0.05 was considered
211
statistically significant.
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3. Results
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3.1 Effects of C-PC supplementation during maturation period on polar body extrusion (PBE)
215
and developmental competence of pig oocytes We first evaluated the effects of different concentrations (0, 1, 3, 5, 10 µg/mL) of C-PC on
217
the PBE of porcine oocytes. The PBE rate was determined after 42 h of IVM and the results
218
are shown in Fig. 1A and B. The rate of PBE ranged from 83.3 ± 2.3% to 87.1 ± 2.4% and did
219
not differ significantly between the control group and C-PC-supplemented groups (p > 0.05).
220
We further investigated the development of porcine oocyte PA after IVM. As shown in Fig.
221
1C and D, there was a significant increase in blastocyst formation and the hatching rates in
222
the 5 µg/mL C-PC supplementation group compared to in the control group (59.6 ± 3.6% and
223
33.0 ± 2.6% vs. 49.8 ± 3.5% and 27.4 ± 2.4%, respectively; p < 0.05). No significant
224
differences in blastocyst formation and hatching rates were observed among the control and 0,
225
1, 3, and 10 µg/mL supplementation groups. These results revealed 5 µg/mL as the optimal
226
concentration; hence, this was used in the subsequent experiments.
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3.2 C-PC supplementation during maturation period improves porcine SCNT embryo
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development
We next assayed whether C-PC supplementation during the maturation period improved
231
the developmental competence of porcine SCNT embryos. The analysis of in vitro SCNT
232
embryo developmental competence revealed that C-PC supplementation during the
233
maturation period significantly improved the developmental potency of IVM oocytes. As
234
shown in Fig. 2, the frequency of blastocyst formation and number of blastocyst cells were
235
significantly increased in the C-PC group (24.8 ± 1.9% and 42.2 ± 3.3, respectively)
236
compared to in the control group (21.6 ± 2.2% and 39.5 ± 3.4, respectively, p < 0.05). We
237
further evaluated the cellular proliferative capacity in these SCNT embryos using the BrdU
238
assay. We found that the percentage of BrdU-positive cells in blastocysts derived from mature
239
COCs in the C-PC group was significantly higher than that in the control group (Fig. 3A and
240
B; p < 0.05). Consistent with this result, expression of the pluripotency markers SOX2 and
241
NANOG was increased significantly in blastocysts obtained from C-PC-supplemented COCs
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than those in the control group (Fig. 3C and D; p < 0.05).
243 244
3.3 Effects of C-PC supplementation during maturation period on cumulus expansion in
245
porcine COCs Cumulus expansion is necessary for oocyte maturation and is routinely employed IVM as a
247
gross indicator of oocyte quality [39]. Therefore, we evaluated the effects of C-PC
248
supplementation during the maturation period on cumulus expansion, followed by an analysis
249
of the degree of cumulus cell expansion and expression of genes related to cumulus
250
expansion genes (HAS2, PTX3, and PTGS2). As shown in Fig. 4A, C-PC supplementation
251
during the maturation period significantly increased the proportion of COCs exhibiting
252
complete cumulus expansion (degree 4, p < 0.05). However, other degree of cumulus cell
253
expansion did not differ significantly between the C-PC-supplemented COC group and
254
control group (p > 0.05). We also observed increased expression of cumulus
255
expansion-related genes (HAS2, PTX3 and PTGS2) after C-PC supplementation during the
256
maturation period (Fig. 4B; p < 0.05). These results suggest that C-PC supplementation
257
during the maturation period improves cumulus expansion in porcine COCs.
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3.4 Effects of C-PC supplementation during maturation period on intracellular ROS and
260
GSH level in porcine oocytes
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Because C-PC has antioxidant properties, we hypothesized that C-PC increases the
262
resistance of embryos to oxidative stress. Therefore, we evaluated the effects of C-PC
263
supplementation during the maturation period on intracellular ROS and GSH levels in
264
porcine after IVM. As shown in Fig. 5A, significantly lower intracellular ROS levels were
265
observed in the C-PC supplementation group during the maturation period (p < 0.05). The
266
intracellular GSH level was significantly increased in the C-PC-supplemented group
267
compared to in the control group (p < 0.05; Fig. 5B). In addition, we evaluated SOD activity
268
and TAC in porcine after IVM. SOD activity was significantly increased in the
269
C-PC-supplemented group compared to in the control group (p < 0.05; Fig. 5C). Similarly,
270
TAC was significantly increased in the C-PC-supplemented group compared to in the control
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group (p < 0.05; Fig. 5D).
272 273
3.5 Effects of C-PC supplementation during maturation period on mitochondria function in
274
porcine oocytes Mitochondria in mammalian cells have a major effect on the production of cellular energy.
276
To further explore the mechanism by which C-PC supplementation during the maturation
277
period improves the developmental potential of porcine oocytes, ∆Ψm was evaluated.
278
Representative images of mitochondrial ∆Ψm are shown in Fig. 7A. The average value of
279
∆Ψm (Fig. 7B) in oocytes significantly increased upon C-PC supplementation during the
280
maturation period (p < 0.05).
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3.6 Effects of C-PC supplementation during maturation period on cathepsin B activity in
283
porcine oocytes
To further analyze the influence of C-PC supplementation during the maturation period on
285
the quality of porcine oocytes, we evaluated cathepsin B activity in oocytes after IVM. As
286
shown in Fig. 6A and B, matured oocytes derived from the supplemented group showed
287
significantly decreased cathepsin B activity compared to the control group (p < 0.05).
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4. Discussion In the present study, we investigated whether supplementation of C-PC during the IVM
291
period improves porcine oocyte quality and pre-implantation embryo development after PA
292
and SCNT. This study revealed that C-PC enhanced the developmental potential of porcine
293
oocytes when supplemented during the IVM period. Moreover, we found that C-PC
294
supplementation during the IVM period improved the developmental competence of PA and
295
SCNT embryos. Importantly, C-PC decreased intracellular ROS levels, increased intracellular
296
GSH levels, improved mitochondria function, and decreased intracellular cathepsin B activity
297
during the IVM period, suggesting that C-PC promotes porcine oocyte cytoplasm maturation.
298
This is the first study showing that C-PC is correlated with porcine oocyte quality and
299
subsequent embryo developmental competence after PA and SCNT.
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Oocyte quality, including nuclear and cytoplasm maturation, is an important determinant
301
of embryo developmental competence [40]. Cloned embryos can be produced using in vivo or
302
in vitro matured oocytes [41, 42]. However, oocytes matured in vitro frequently exhibit low
303
quality, including incomplete nuclear and cytoplasmic maturation, compared to in vivo
304
matured oocytes [43]. A previous study suggested that the decreased quality of porcine
305
oocytes influences both pre-implantation cloned embryonic development and fetal
306
development [44]. Therefore, enhancing oocyte quality is very important for the
307
developmental ability of embryos produced by SCNT. In the present study, we found that the
308
proportion of PA embryos undergoing blastocyst formation and hatching significantly
309
increased when the IVM medium was supplemented with 5 µg/mL C-PC. However,
310
unexpectedly, C-PC supplementation during the IVM period did not affect porcine oocyte
311
PBE. Further analyses revealed that C-PC supplementation during the IVM period clearly
312
improved SCNT embryo development and the quality of these embryos as indicated by total
313
cell numbers, cellular proliferation, and pluripotency gene expression in blastocysts. These
314
results highlight the positive effect of C-PC supplementation during the IVM period on the
315
developmental competence of PA and SCNT embryos.
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During oocyte maturation, cumulus cell expansion is necessary for oocyte maturation
317
and the acquisition of developmental competence by releasing and mediating signals to
ACCEPTED MANUSCRIPT oocytes [45, 46]. The degree of cumulus expansion is routinely evaluating during IVM as a
319
gross indicator of oocyte maturation and the outcome of embryo in vitro culture [35].
320
Cumulus expansion may play a role as a structural component of expanded cumuli and
321
molecular signals regulating oocyte maturation [47]. The oocytes with high fertilizing
322
capacity and developing competence have been attributed to expansion of cumulus cell [48].
323
In the current study, supplementation with C-PC during the IVM period dramatically
324
increased cumulus expansion of porcine cumulus cells and expression of expansion-related
325
transcripts in cumulus cells (HAS2, PTX3, and PTGS2). Therefore, C-PC supplementation
326
during the IVM period improves the developmental competence of PA and SCNT embryos in
327
part by affecting porcine cumulus cell expansion.
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Oxidative stress is characterized by overproduction of free radicals, which can disrupt
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the balance of ROS and antioxidants under normal physiological conditions. ROS levels
330
within an optimal range is required for normal cell metabolism, while excessive ROS
331
generation may negatively influence cell membranes, protein synthesis, and lipid metabolism
332
[49]. It has been demonstrated that high ROS levels in oocytes are detrimental to oocyte
333
maturation and fertilization and impair embryo development [38]. The maturation status of
334
oocyte cytoplasm plays an important role in successful embryonic genome activation at the
335
onset of embryonic development by regulating reprogramming gene expression [50]. Porcine
336
oocytes are particularly sensitive to damage caused by ROS because of the high lipid
337
concentrations in the cytoplasm [51]. Therefore, suppression or removal of excess ROS using
338
antioxidants may improve porcine oocyte quality and subsequently embryo development.
339
Supplementation of antioxidants during the IVM period has been shown to influence oocyte
340
maturation and embryo development [52]. It had been suggested that supplementation with
341
antioxidants in IVM medium, such as β-mercaptoethanol and L-carnitine, improves SCNT
342
embryonic development [53] [54]. This may be because of increased transcription factor
343
expression, which stimulates nuclear reprogramming. Therefore, we hypothesized that C-PC
344
affects porcine oocyte maturation by regulating oxidative stress-induced impairments. We
345
found that IVM media supplemented with 5 µg/mL C-PC effectively decreased intracellular
346
ROS levels in mature oocytes. A previous study suggested that supplementation of C-PC can
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effectively prevent H2O2-induced oxidative stress and early signs of osteoarthritis [34]. In
348
addition, C-PC can protect and repair the ischemic brain via improved antioxidative,
349
neurotrophic,
350
doxorubicin-induced oxidative stress and apoptosis in cardiomyocytes [56]. Therefore, C-PC
351
reduces ROS levels in oocytes during the IVM period, thus improving porcine oocyte quality
352
and enhancing subsequent embryo developmental competence after PA and SCNT. This
353
explains why C-PC affect porcine cumulus cell expansion may occur through decreased
354
oxygen tension in close proximity to the oocyte as a result of active cumulus cell metabolism
355
[57].
anti-inflammatory
mechanisms
[55].
C-PC
also
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GSH is an important antioxidant found in mammalian cells and functions as a scavenger
357
of ROS [58]. Intracellular GSH are used to predict cytoplasmic maturation in porcine oocytes
358
[21]. In vivo matured oocytes exhibit higher GSH and developmental competence than in
359
vitro matured oocytes [59, 60]. Therefore, increasing the intracellular GSH level can protect
360
oocytes from oxidative damage and increase cytoplasmic maturation. A previous study
361
suggested that supplementation of antioxidants during IVM influences oocyte maturation and
362
improves its developmental potency by increasing intracellular GSH levels. In the present
363
study, inclusion of 5 µg/mL C-PC in the IVM media significantly improved intracellular
364
GSH levels. SOD is an effective defense enzyme that catalyzes the dismutation of superoxide
365
anions into H2O2. A previous study showed that C-PC restores SOD and GSH-Px activities in
366
CCl4-induced damaged livers and increases GSH level [61]. Furthermore, an imbalance
367
between TAC and increased ROS levels surrounding the embryo may lead to oxidative stress
368
[62, 63]. In the present study, we found that C-PC supplementation during the IVM period
369
effectively increased the TAC and activity of SOD in porcine oocytes. Therefore, C-PC
370
supplemented during the maturation period promotes cytoplasmic maturation of oocytes,
371
which may be because increased intracellular GSH levels contribute to higher embryonic
372
development following PA and SCNT.
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Mitochondria are major producers of ROS and ATP, which influence oocyte
374
developmental potential and are associated with fertilization and embryonic development
375
[64]. ∆Ψm is commonly used as an indicator of mitochondrial function in oocytes [65] and is
ACCEPTED MANUSCRIPT the driving force behind ATP production [66]. A previous study showed that C-PC restored
377
oxalate-induced decreases in ATP levels in MDCK cells [67]. In addition, C-PC can prevents
378
cisplatin-induced mitochondrial dysfunction and oxidative stress [68]. In the current study,
379
we found that supplementation of C-CP during the IVM period led to increased ∆Ψm in
380
porcine oocytes. It does not seem likely that C-CP improves porcine oocyte quality by
381
improving mitochondrial function. Cathepsin B is a lysosomal cysteine proteinase in normal
382
cells and tissues and plays an important role in intracellular proteolysis [69]. Recent studies
383
have shown that cathepsin B activity is a marker of poor-quality oocytes and embryos, which
384
is associated with low developmental competence [62, 63]. In the present study, the
385
decreased cathepsin B activity in porcine oocytes further revealed that C-CP supplementation
386
during the IVM period positively affected porcine quality.
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In conclusion, our results suggest that C-PC supplementation during the IVM period has
388
beneficial effects on porcine oocytes maturation, particularly cytoplasm maturation, and
389
subsequent developmental competence of embryos produced from PA and SCNT. These
390
findings will be useful for improving the efficiency of producing SCNT embryos in pig.
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However, additional studies should examine these factors in fertilized embryos.
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Acknowledgements
This study was supported by a grant from the Next-Generation BioGreen 21 Program (PJ011126), Rural Development Administration (RDA), Republic of Korea.
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Additional Information
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Competing Interests: The authors declare that they have no competing interests.
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Figure legends
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Fig. 1. Effects of C-PC treatment during in vitro maturation at different concentrations on
569
porcine oocyte polar body extrusion (PBE) and subsequent in vitro developmental
570
competence of parthenogenetic embryos. (A) Representative fluorescent images of metaphase
571
II (MII) stage oocyte with an extruded polar body. Blue: DNA; Green: α-tubulin (B) PBE rate.
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(C) Blastocyst formation rate. (D) Blastocyst hatching rate. The numbers of embryos
573
examined in each experimental group are shown in the bar.
574
differences are represented with different letters (p < 0.05). Data are expressed as the mean ±
575
SEM from at least three separate experiments. Scale bar = 20 µm.
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Statistically significant
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a, b
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Fig. 2. Effects of C-PC treatment during in vitro maturation on the developmental
578
competence of porcine cloned embryo. (A) Blastocyst formation was examined at day 7. (B)
579
Blastocyst rate. (C) Total cell number in each blastocyst. The numbers of embryos examined
580
in each experimental group are shown in the bar.
581
represented with different letters (p < 0.05). Data are expressed as the mean ± SEM from at
582
least three separate experiments. Scale bar = 100 µm.
Statistically significant differences are
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a, b
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Fig. 3. Effect of C-PC treatment during in vitro maturation on expression of genes related to
585
cell proliferation, apoptosis, pluripotency, and apoptosis in porcine cloned embryo. (A)
586
Immunofluorescence staining of BrdU in porcine cloned embryo at blastocyst stage. (B)
587
Percentages
588
pluripotency-related genes in blastocyst. The numbers of embryos examined in each
589
experimental group are shown in the bar.
590
represented with different letters (p < 0.05). Data are expressed as the mean ± SEM from at
591
least three separate experiments. Scale bar = 20 µm.
BrdU-positive
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of
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cells
in
blastocyst.
a, b
(C)
Relative
expression
of
Statistically significant differences are
592 593
Fig. 4. Effect of C-PC treatment during in vitro maturation on cumulus cell expansion and
594
relative gene expression in porcine cumulus cell. (A) The degree of cumulus expansion in
595
porcine cumulus oocyte complexes. (B) Cumulus expansion-related genes in porcine cumulus
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596
cell.
Statistically significant differences are represented with different letters (p < 0.05).
597
Data are expressed as the mean ± SEM from at least three separate experiments.
598
Fig. 5. Effect of C-PC treatment during in vitro maturation on ROS and GSH levels, total
600
antioxidant capacity (TAC), and superoxide dismutase (SOD) activity in porcine oocytes.
601
Intracellular ROS (A) and GSH (B) levels. (C) TCA. (D) SOD activity. The numbers of
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embryos examined in each experimental group are shown in the bar.
603
significant differences are represented with different letters (p < 0.05). Data are expressed as
604
the mean ± SEM from at least three separate experiments.
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Statistically
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a, b
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Fig. 6. Effect of C-PC treatment during in vitro maturation on mitochondrial membrane
607
potential (∆Ψm) in porcine oocytes. (A) Representative fluorescent images of 5,5′,6,
608
6′-tetrachloro-1,1′,3,3′-tetraethyl-imidacarbocyanine iodide (JC-1) staining in MII stage
609
oocytes. (B) Quantification of fluorescence intensity of JC-1. The numbers of embryos
610
examined in each experimental group are shown in the bar.
611
differences are represented with different letters (p < 0.05). Data are expressed as the mean ±
612
SEM from at least three separate experiments. Scale bar = 50 µm.
a, b
Statistically significant
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Fig. 7. Effect of C-PC treatment during in vitro maturation on cathepsin B activity in porcine
615
oocytes. (A) Representative fluorescent images showing cathepsin B activity in MII stage
616
oocytes. Red: Cathepsin B. (B) Quantification of fluorescence intensity of intracellular
617
cathepsin B activity. The numbers of embryos examined in each experimental group are
618
shown in the bar.
619
(p < 0.05). Data are expressed as the mean ± SEM from at least three separate experiments.
620
Scale bar = 50 µm.
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a, b
Statistically significant differences are represented with different letters
ACCEPTED MANUSCRIPT Table 1. Primer sequences used in real-time RT-PCR
Primer sequence (5’-3’) F: CCCCGCCCTATGACTTCT
POU5F1
60 R: TAGGAGCTTGGCAAATTGTTC F: CGCAGACCTACATGAACG 60 R: TCGGACTTGACCACTGAG F: CTCTCCTCTTCCTTCCTC
60
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NANONG
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SOX2
Product Size (bp)
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Gene
Annealing Temperature (°C)
269
103
139
R: CTTCTGCTTCTTGACTGG
F: AGTTTATGGGCAGCCAATGTAGTT HAS2
60
101
60
185
60
194
60
117
R: GCACTTGGACCGAGCTGTGT F: GCACTTGGACCGAGCTGTGT PTX3
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R: GCTATCCTCTCCAACAAGTGA F: ACAGGGCCATGGGGTGGACT PTGS2
R: CCACGGCAAAGCGGAGGTGT F: TTCCACGGCACAGTCAAG
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GAPDH
R: ATACTCAGCACCAGCATCG
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F, forward; R, reverse.
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B
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A
Blue: DNA; Green: α-tubulin
D
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C
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A
Control
C-CP
B
AC C
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C
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DNA
Brdu
Merge
B
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C-PC
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Control
A
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C
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B
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A
B
C
SC
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A
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D
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Light
JC-1 green
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B
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C-CP
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Control
A
JC-1 red
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Control
C-CP
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A
Red: Cathepsin B
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B
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Highlights •
C-Phycocyanin significantly
supplementation increased
the
during
in
developmental
vitro
maturation
competence
of
period porcine
parthenogenetic and cloned embryos. C-Phycocyanin enhanced antioxidant capacity, improved mitochondria
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•
AC C
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function, and decreased cathepsin B activity in porcine oocytes.