Özet

Inactivation of mTor: A Tool to Investigate Meiotic Progression and Translational Control During Bovine Oocyte Maturation

Published: September 24, 2015

Özet

The protocol presented here describes the inhibition of the Ser/Thr kinase mTor during IVM of bovine oocytes. This approach can facilitate the investigation of meiotic progression and translational control. It also contributes to the definition of developmental competence and the improvement of IVM conditions.

Abstract

Although routinely used in breeding programs, in vitro maturation (IVM) of bovine oocytes and in vitro production (IVP) of embryos are nevertheless still the subject of basic research owing to suboptimal IVM conditions and variations in the developmental competence of the starting oocytes. In the present study we provide a method to inhibit the Ser/Thr kinase mTor during IVM using two independent inhibitors, Torin2 and Rapamycin. Both substances have different effects on meiotic progression and translational control and may allow discrimination between the mTorC1 and mTorC2 complex functions. The effects of the inhibitors are monitored by inspection of the chromatin configuration using aceto-orcein-staining as well as Western blotting and immunohistochemical analysis of the phosphorylation state of the translational repressor 4E-BP1, which is a prominent mTor target. Whereas Torin2 arrests bovine oocytes in the M I stage and inhibits 4E-BP1 phosphorylation, Rapamycin inhibits asymmetric division and does not influence 4E-BP1. Investigations utilizing these reactions can provide deeper insights into the regulatory events involved in meiotic maturation. Moreover, special focus can be placed on the temporal and spatial regulation of translational control. Such findings can contribute to the definition of the developmental competence of oocytes and to an improvement of IVM conditions.

Introduction

Fully grown bovine oocytes (arrested at prophase I; germinal vesicle -GV- stage) resume meiosis spontaneously when they are released from their follicles and transferred to a suitable culture medium. Previous investigations using the application of different inhibitors to in vitro culture media1, 2 revealed that activation of protein kinases and de novo protein synthesis trigger the maturation of mammalian oocytes and arrest them in metaphase II (M II), the stage suitable for fertilization. In the present study we describe a method to inhibit the Ser/Thr kinase mTorduring IVM of bovine oocytes. This approach might provide deeper insights into the complex processes involved in the regulation of protein synthesis in the context of meiotic maturation (transition from GV-stage to M II), because mTor links the phosphorylation of specific factors directly to translational control3, 4.

The focus on the investigation of translational control reflects the importance of this process; fully grown oocytes are transcriptionally silent and protein synthesis relies on the activation of stored, dormant mRNAs5. In this context, mTor plays a predominant role. The kinase directly phosphorylates and inactivates repressors of the mRNA cap-binding protein eIF4E, the so-called 4E-binding proteins (4E-BP1-3), and thereby allows the formation of the 5´-mRNA-cap binding complex eIF4F (composed of eIF4E, the scaffold protein eIF4G and the RNA helicase eIF4A). Together with other factors it also stimulates ribosome binding and translation initiation6.

mTor, however, exists as two complexes: mTorC1 and mTorC2. Each complex is composed of different major regulators, differs in sensitivity to Rapamycin and has different cellular targets7. The major regulator of mTorC1, Raptor (regulatory-associated protein of mTOR), phosphorylates components of the translational machinery, namely ribosomal proteins (for instance RPS6 at Ser235/36) and the translational repressor 4E-BP1 (at Thr37/46/65/70). The major regulator of mTorC2, Rictor (Rapamycin-insensitive companion of mTOR), is Rapamycin- resistant and phosphorylates Akt (PKB) which in turn phosphorylates mTorC1. Preliminary investigations in bovine oocytes during IVM revealed different transient activities of mTorC1 and mTorC2 during IVM. In the GV-stage of oocytes the mTorC2 is active3 ; it is inactivated in the course of IVM. In contrast, mTorC1 shows the opposite behavior3. These results correspond with findings showing that 4E-BP1 phosphorylation is lower in the GV-stage, continuously increases during IVM, and is highest in the M II stage8, 9.

However, mTorC1 and C2 both respond to the active site inhibitor Torin210 and might have other (yet unknown) targets. Candidates are meiotic spindle-forming or regulatory proteins, since mTor associates with meiotic spindles during chromatin segregation.

From a practical point of view, it should be noted that in vitro systems yield only 30-40 % transferable embryos in the bovine species 11. The causes for this could be suboptimal in vitro conditions and/or differences in the developmental competence of the starting oocytes which occur despite their selection from follicles of a defined size. However, detailed investigations of meiotic maturation on a molecular level can contribute to the optimization of IVM systems. Furthermore, oocytes might be selected according to their developmental competence, for instance by IVM systems under inhibitory conditions (see discussion). Hence, in the procedure presented here, we used two independent mTor inhibitors, Torin2 and Rapamycin, which resulted in different chromatin statuses and differential phosphorylation of 4E-BP1. Interestingly, approximately 20 % of the oocytes overcame the Torin2 block and might thus be candidates which possess a high developmental competence.

Protocol

All experiments were performed in accordance with the guidelines of the local ethics committee (Landesamt für Landwirtschaft, Lebensmittelsicherheit und Fischerei, Mecklenburg-Vorpommern, Germany). The ovaries were obtained from a commercial slaughterhouse. The remaining carcass was used for meat production. 1. Solutions to be prepared. Prepare PBS for gaining oocytes by weighing Glucose (500 mg), Pyruvate (18 mg), Penicillin (10 mg), Streptomycin (20 mg), Heparin (5.6 mg) and…

Representative Results

Source of oocytes, in vitro maturation and mTor inhibition Figure 1 illustrates the collection of cumulus oocyte complexes (COCs) and the analysis of the chromatin configuration. Only healthy ovaries (Figure 1A) obtained from a local slaughterhouse were used as oocyte sources. COCswere aspirated from follicles sized 4-8 mm (Figure 1B). Only COCs with compact layers of cumulus cells (Figure 1C) were used fo…

Discussion

In vitro maturation (IVM) of bovine oocytes is an important technique because it is an integral part of the in vitro production of embryos in specific breeding programs. However, a critical limitation is the fact that no method exists to assess the developmental competence of fully grown oocytes directly after follicular release. Furthermore, when the chromatin status of bovine oocytes is analyzed morphologically, more than 90 % have reached the M II stage after 24 h of IVM under standard conditions1. However, transfera…

Açıklamalar

The authors have nothing to disclose.

Acknowledgements

Manuela Kreißelmeier and Sophia Mayer were scholarship holders of the Dr. Dr. Karl-Eibl-Stiftung. We wish to thank Gesine Krüger and Petra Reckling for excellent technical assistance.

Materials

PBS Dulbecco wCa2+ wMg2+ Biochrom AG L1815 For gaining of the COC and denudation
D-(+)-Glucose Sigma G5400-250G Supplement to PBS Dulbecco
Sodium pyruvate Sigma P3662-25G Supplement to PBS Dulbecco
Penicillin G sodium salt Sigma P3032-25 MU Supplement to PBS Dulbecco
Streptomycin sulfate salt Sigma S1277-50G Supplement to PBS Dulbecco
Heparin sodium salt Sigma H3149-25 KU Supplement to PBS Dulbecco
Bovine serum albumin Sigma A9647-10G Supplement to PBS Dulbecco
Sodium bicarbonate (NaHCO3) Sigma S4019-500G Supplement to PBS Dulbecco
Gentamicin sulfate salt Sigma G3632-250MG Component of TCM medium
TCM-199 Hepes Modification Sigma M2520-1L Component of TCM medium
Sodium chloride (NaCl) Sigma S5886-500G Component of 0.9% NaCl solution
Rapamycin Cell Signaling Technology (CST) 9904 S m-Tor-inhibitor
Dimethyl sulfoxide (DMSO) Serva 39757.01 Used as solubilizer for Rapamycin and Torin 2
Torin 2 R&D Systems 4248/10 m-Tor-inhibitor
Phosphat Buffered Saline Tablets (PBS) Sigma P-4417 for PBS-präparation
Tween 20 Serva 39796.01 permeabilization buffer
Roti-Immuno-Block Roth T144.1 Blockingsolution+Lsg.für AK
Triton X100 Serva 37240 permeabilization buffer
Hepes Serva 25245 permeabilization buffer
Albumin Fraktion V(biotinfrei) Roth 0163.3 permeabilization buffer
D(+)-Saccharose Roth 4621.1 permeabilization buffer
Nacl Roth 3957.1 permeabilization buffer
MgCl2x6 H2O Sigma M2393 permeabilization buffer
Paraformaldehyde Sigma P-6148 Fixation
Kaisers Glyceringelatine Merck 109,242 cover oocytes
Alex-Fluor  546F(ab)2 fragment goat anti rabbit IgG( H+L) MOBITEC A11071 secondary antibody fluorecent labeled
SYBR Green nucleic acid gel stain Invitrogen S7563 DNA staining
4E-BP1 CST 9452 primary antibody
p4E-BP1 Thr37/46 CST 2855 primary antibody
anti rabbit IgG-HRP CST 7074 secondary antiboday HRP labelled
ECL prime GE healthcare RPN2232 WB detection
Fluid filter Infufil 0,2µm 5,7 cm2 Fresenius Kabi 2909702 Used for sterile filtration
Pipette pipetman P10 0,1-10µl Gilson Used for transferring denudated oocytes and embryos and volumina of 0,1-10µl
Pipette Reference 10-100µl Eppendorf 4920000059 Used for transferring COC and volumina of 10-100µl and for denudation
Pipette Reference 100-1000µl Eppendorf 4920000083 Used for transferring volumina of 100-1000µl
Micro-classic pipette controller Brand 25900 Used for transferring COC  
Micropipettes intraMark 20µl Brand 708718 Used for transferring COC
Safe-lock tubes 0,5 ml Eppendorf 0030 121.570 Used to store volumina up to 0,5 ml
Polypropylene centrifuge tube with conical base 50 ml, 30,0/115mm Greiner 210261 Used for the aspirated fluid to sediment
Pasteur pipette 7 ml VWR 612-1681 Used for transferring the sediment to screened Petri dishes
Germ count dish with vents 90/16 mm Greiner 633175 Used for searching the COC
Petri dish with vents 35/10 mm Greiner 627102 Used for medium preparation, washing the COC
Petri dish with vents 60/15 mm Greiner 628102 Used for medium preparation
Multidish 4 wells Thermo Scientific 176740 Used for washing the COC, for COC maturation, embryo culture and for denudation of the oocytes
Tissue culture dish 35/10 mm, 4 compartments Greiner 627170 Used for washing the COC  
Microscope slides 76x26x1mm Thermo Scientific AB00000112E For fast morphological inspection by Aceto-Orcein-staining
Microscope cover glasses, 18×18 mm VWR ECN 631-1567 For fast morphological inspection by Aceto-Orcein-staining
Needle 18G x 1 1/2"  1,2 x 40 mm BD Microlance REF 304622 For medium preparation
Incubator inc108med with CO2 control Memmert 84198998 Used for in vitro maturation
Universal oven model UNB 200 Memmert 84193990 Used for medium preparation
Control unit HAT 400 W1, 72VA 470 x 263 mm Minitube 12055/0400 Used for keeping the cells warm in the course of treatment
confocal laser scanning microscope, phase contrast microscope  Zeiss Model: LSM 5 PASCAL Axiovert 200 M Morphological and immuno-histochemical analysis of oocytes

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Bu Makaleden Alıntı Yapın
Kreißelmeier, M., Mayer, S., Wrenzycki, C., Pöhland, R., Tomek, W. Inactivation of mTor: A Tool to Investigate Meiotic Progression and Translational Control During Bovine Oocyte Maturation. J. Vis. Exp. (Pending Publication), e53689, doi: (2015).

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