Lin Liu1, David L Keefe. 1. Department of Obstetrics and Gynecology, Brown University, Women and Infants Hospital, Providence, RI 02905, USA.
Abstract
BACKGROUND: The senescence-accelerated mouse (SAM) has been shown to exhibit ageing-associated mitochondrial dysfunction and oxidative stress, and early decline in fertility. METHODS: We compared meiotic progression of germinal vesicle oocytes between young (2-3 months) and old (10-14 months) SAM mice using triple immunostaining and fluorescence microscopy as well as Pol-Scope imaging. RESULTS: At 8-9 h of in-vitro maturation (IVM), most young SAM oocytes (86%, 32/37) were at meiosis I (MI) stage, with chromosomes aligned in the mid-region of MI spindles, whereas disrupted MI spindles and/or chromosome misalignments (45%, 18/40) and a few oocytes (20%, 8/40) with abnormal MII spindles were found in old SAM oocytes. At 15-17 h of IVM, old SAM oocytes, despite errors at MI stage, extruded a first polar body at an incidence of 88% (n = 85), which did not differ from that (92%, n = 106) of young SAM oocytes. However, oocytes from old SAM (64%, 32/50) showed aberrant MII, with chromosome misalignment and dispersal, in contrast to normal MII in most young SAM oocytes (87%, 65/75), showing chromosome alignment at the metaphase plate of MII spindles. Moreover, Pol-Scope imaging non-invasively detected disrupted or absent visible spindles and possibly aberrant chromosome alignment. CONCLUSIONS: Spindle disruption and/or chromosome misalignments at both MI and MII are associated with maternal ageing in the SAM mouse. Our findings also suggest that meiotic division lacks a competent checkpoint for spindle integrity and chromosome alignment during reproductive ageing-associated oocyte senescence.
BACKGROUND: The senescence-accelerated mouse (SAM) has been shown to exhibit ageing-associated mitochondrial dysfunction and oxidative stress, and early decline in fertility. METHODS: We compared meiotic progression of germinal vesicle oocytes between young (2-3 months) and old (10-14 months) SAM mice using triple immunostaining and fluorescence microscopy as well as Pol-Scope imaging. RESULTS: At 8-9 h of in-vitro maturation (IVM), most young SAM oocytes (86%, 32/37) were at meiosis I (MI) stage, with chromosomes aligned in the mid-region of MI spindles, whereas disrupted MI spindles and/or chromosome misalignments (45%, 18/40) and a few oocytes (20%, 8/40) with abnormal MII spindles were found in old SAM oocytes. At 15-17 h of IVM, old SAM oocytes, despite errors at MI stage, extruded a first polar body at an incidence of 88% (n = 85), which did not differ from that (92%, n = 106) of young SAM oocytes. However, oocytes from old SAM (64%, 32/50) showed aberrant MII, with chromosome misalignment and dispersal, in contrast to normal MII in most young SAM oocytes (87%, 65/75), showing chromosome alignment at the metaphase plate of MII spindles. Moreover, Pol-Scope imaging non-invasively detected disrupted or absent visible spindles and possibly aberrant chromosome alignment. CONCLUSIONS: Spindle disruption and/or chromosome misalignments at both MI and MII are associated with maternal ageing in the SAM mouse. Our findings also suggest that meiotic division lacks a competent checkpoint for spindle integrity and chromosome alignment during reproductive ageing-associated oocyte senescence.
Authors: Yong Cheng; Kai Wang; Lori D Kellam; Young S Lee; Cheng-Guang Liang; Zhiming Han; Namdori R Mtango; Keith E Latham Journal: Biol Reprod Date: 2008-12-10 Impact factor: 4.285