257 DETECTION OF MICROTUBULES BY POLARIZED LIGHT MICROSCOPY IN SHEEP AND GOAT OOCYTES
J. N. Caamaño A , M. Catalá B , R. Romaguera B , C. Diez A , M. Muñoz A , D. Martín A , R. Morató B , S. Carrocera A , T. Mogas B , M. T. Paramio B and E. Gomez AA SERIDA, Gijón, Asturias, Spain;
B Universidad Autónoma de Barcelona, Barcelona, Cataluña, Spain
Reproduction, Fertility and Development 23(1) 226-227 https://doi.org/10.1071/RDv23n1Ab257
Published: 7 December 2010
Abstract
The meiotic spindle in the oocyte is composed of microtubules and plays a key role in normal chromosome alignment and segregation during meiosis. In oocytes from farm animals, the meiotic spindle cannot be detected by conventional light microscopy due to the characteristic of their cytoplasm. Conventional methods to image the meiotic spindle rely on fixation of the oocytes. Polarized light microscopy (PLM) allows noninvasive evaluation of the meiotic spindle of metaphase oocytes. The aim of this study was to assess the efficiency of polarized light microscopy to detect microtubule-polymerized protein within in vitro matured prepubertal sheep and goat oocytes. We carried out 2 studies. In the first one, cumulus–oocyte complexes from slaughterhouse sheep ovaries were matured in vitro for 27 h. After in vitro maturation, oocytes (n = 77) were denuded of cumulus cells and placed individually in 10-μL drops of TCM-199-HEPES-BSA in a glass Petri dish. Polarized light microscopy was used to detect the presence of polymerized protein, which could be associated with the forming of a meiotic spindle. To confirm the presence of the polymerized protein and the meiotic spindle, each individual oocyte was subjected to immunostaining and chromatin detection as described by (Morató et al. 2008 Mol. Reprod. Dev. 75, 191–201). The experiment was replicated 4 times. The correlation analysis was performed using the Proc Corr procedure of SAS. There was a positive correlation (r = 0.87; P < 0.001) between the signal obtained by PLM and the presence of microtubule-polymerized protein as confirmed by immunostaining. A positive PLM signal was detected in 87.0% of the oocytes, and 69.0% of the oocytes reached the metaphase II (MII) stage after in vitro maturation. A barrel-shaped spindle was observed in 77.3% of the MII oocytes. In the second study, we performed a similar experiment but used goat oocytes. A total of 78 oocytes were used, and PLM and immunostaining were performed in each individual oocyte as it was described with sheep oocytes. There was also a positive correlation (r = 1; P < 0.001) between the signal obtained by PLM and the presence of microtubule-polymerized protein. A positive PLM signal was detected in 98.7% of the oocytes, and 80.7% of the oocytes reached the MII stage after in vitro maturation. A barrel-shaped spindle was observed in 92.0% of the MII oocytes. These results indicate that PLM is an efficient system to detect polymerized protein in in vitro matured sheep and goat oocytes.
This work was supported by the following grant: INIA: RZ2007-00013-00-00. M. Muñoz and D. Martín are sponsored by RYC08-03454 and PTA2007-0268-I, respectively.