To better understand the differences in cytoskeletal organization between in vivo (IVO) and in vitro (IVM) matured oocytes, we analyzed remodeling of the centrosome-microtubule complex in IVO and IVM mouse oocytes. Fluorescence imaging revealed dramatic differences in meiotic spindle assembly and organization between these two populations. Metaphase spindles at both meiosis I (M-I) and meiosis II (M-II) in IVO oocytes were compact, displayed focused spindle poles with distinct gamma-tubulin foci, and were composed of acetylated microtubules. In contrast, IVM oocytes exhibited barrel-shaped spindles with fewer acetylated microtubules and gamma-tubulin diffusely distributed throughout the spindle proper. With respect to meiotic progression, IVO oocytes were more synchronous in the rate and extent of anaphase to telophase of M-I and first polar body emission than were IVM counterparts. Furthermore, IVO oocytes showed a twofold increase in cytoplasmic microtubule organizing centers (MTOCs), and constitutive MTOC proteins (gamma-tubulin and pericentrin) were excluded from the first polar body. Inclusion of MTOC constitutive proteins in the polar body and diminished number of cytoplasmic MTOCs was observed in IVM oocytes. These findings were corroborated in IVO oocytes obtained from naturally ovulated and spontaneously cycling mice and highlight a fundamental distinction in the spatial and temporal regulation of microtubule dynamics between IVO and IVM oocytes
Understanding the physiology underlying the complex dialog between the oocyte and its surrounding somatic cells within the ovarian follicle has been crucial in defining optimal procedures for the development of clinical approaches in ART for women suffering from infertility and ovarian dysfunction. Recent studies have implicated oocyte-secreted factors like growth differentiation factor 9 (GDF-9) and bone morphogenetic protein 15 (BMP-15), members of the transforming growth factor-beta (TGFβ) superfamily, as potent regulators of folliculogenesis and ovulation. These two factors act as biologically active heterodimers or as homodimers in a synergistic cooperation. Through autocrine and paracrine mechanisms, the GDF-9 and BMP-15 system has been shown to regulate growth, differentiation, and function of granulosa and thecal cells during follicular development playing a vital role in oocyte development, ovulation, fertilization, and embryonic competence. The present mini-review provides an overview of recent findings relating GDF-9 and BMP-15 as fundamental factors implicated in the regulation of ovarian function and discusses their potential role as markers of oocyte quality in women.
The results emphasize the importance of coupling MT remodeling and cell cycle components during oocyte maturation to achieve a balanced coordination of nuclear and cytoplasmic maturation that under physiological conditions occurs within the first 5 h of LH stimulation.
Mammalian oocytes acquire a series of competencies during follicular development that play critical roles at fertilization and subsequent stages of preimplantation embryonic development. These competencies involve remodelling of chromatin and the cytoskeleton in the oocyte at critical stages of folliculogenesis when gametes and somatic cells communicate by paracrine and junctional mechanisms. While the detailed steps involved in bi-directional signalling between oocytes and granulosa cells remain unknown, studies from mice bearing targeted deletions in essential 'communication' genes reveal selective disturbances in oocyte maturation competencies that compromise the oocyte's developmental potential. Recent data are reviewed that illustrate the general principle that competencies acquired at sequential stages of oogenesis are manifest during oocyte growth, maturation, or following fertilization. The recognition that oocyte-specific genes are called into play at key developmental transitions in mammalian embryogenesis emphasizes the importance of monitoring genetic and epigenetic determinants when using current assisted reproductive technologies manipulations.
Polarity is an important aspect of oogenesis and early development for many animal groups, but only recently it has become relevant to the study of mammals. Mammalian oocyte development occurs through tight coordination and interaction between all ovarian structures. In fact, bi-directional communication between the oocyte and its companion granulosa cells (GC) in the ovarian follicle seems essential for GC proliferation, differentiation, and production of a functional female gamete. The transzonal projections (TZP), which are specialized extensions from granulosa cells that terminate on the oolema after crossing the zona pellucida, are major structural components necessary for oocyte-GC interaction. Granulosa cell polarity seems to be a necessary requisite for appropriate function of TZP, and the role of FSH as modulator of a polarized phenotype on GC is discussed. This article also discusses oocyte polarity with special reference to the partial loss of polarity that occurs during in-vitro oocyte maturation and possible implications in the modulation of oocyte competencies. Cytoskeletal markers that may account for oocyte quality were defined and found to be distinct in in-vivo and in-vitro matured oocytes. Implications of partial loss of oocyte polarity during in-vitro maturation, reflected by distinct distribution of these markers, are further discussed. It is also proposed that expression of both somatic and germ cell polarity in the ovarian follicle will ultimately determine acquisition of meiotic, fertilization and developmental competences by the oocyte.
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