Morphodynamics of ovarian follicles during oogenesis in mice

In the mouse, oogonia enter the prophase of the first meiotic division and differentiate into oocyte while developing in the fetal ovary. Shortly after birth, all oocytes are arrested in the dictyate stage of late prophase in the developing follicles; a small number of follicles reach the ovulatory...

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Veröffentlicht in:	Microscopy research and technique 2006-06, Vol.69 (6), p.427-435
Hauptverfasser:	Sato, Eimei, Kimura, Naoko, Yokoo, Masaki, Miyake, Yuko, Ikeda, Joh-E
Format:	Artikel
Sprache:	eng
Schlagworte:	angiogenesis Animals apoptosis atresia Cell Differentiation cumulus-oocyte complex Cytokines - metabolism EGF Female follicle development glycosaminoglycans Glycosaminoglycans - metabolism Mice oocyte Oocytes - cytology Oocytes - ultrastructure Oogenesis - physiology Ovarian Follicle - cytology Ovarian Follicle - physiology Ovarian Follicle - ultrastructure ovary Ovary - cytology Ovary - ultrastructure TNF-α
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creator	Sato, Eimei Kimura, Naoko Yokoo, Masaki Miyake, Yuko Ikeda, Joh-E
description	In the mouse, oogonia enter the prophase of the first meiotic division and differentiate into oocyte while developing in the fetal ovary. Shortly after birth, all oocytes are arrested in the dictyate stage of late prophase in the developing follicles; a small number of follicles reach the ovulatory stage; the rest are lost by apoptosis. The resumption of meiotic division and nuclear progression to metaphase II (oocyte maturation) occur in the ovulatory follicles. In this article we review recent morphological data that have clarified how cytokines and glycosaminoglycans (GAGs) are involved in mouse follicular development, atresia, and maturation during oogenesis, as exogenous/endogenous factors. (1) Microvascular networks and angiogenic factors (epidermal growth factor; GAGs) are deeply involved in selective mouse oocyte growth beyond ∼20–30 μm in diameter. (2) Gonadotropin‐inducible neuronal apoptosis inhibitory protein may indirectly affect oocyte survival as a result of the inhibition of apoptotic granulosa‐cell death during folliculogenesis. (3) The pattern of oocyte degeneration depends on follicle and oocyte developmental stages, and follicle stimulating hormone accelerates the process of degeneration of oocytes. (4) The process of degeneration of mouse oocytes/eggs is modulated by tumor necrosis factor‐α that is accumulated in the expanded cumulus during oocyte maturation. (5) A colloidal iron‐positive substance was detected in the intercellular spaces of follicular tissue, especially in the cumulus mass. Cells located where the cumulus mass and granulosa cell layer interwound became enlarged during the resumption of oocyte meiosis. Colloidal iron‐positive substances accumulated extensively within the intercellular spaces of the enlarged cells. Microsc. Res. Tech., 2006. © 2006 Wiley‐Liss, Inc.
doi_str_mv	10.1002/jemt.20302
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(3) The pattern of oocyte degeneration depends on follicle and oocyte developmental stages, and follicle stimulating hormone accelerates the process of degeneration of oocytes. (4) The process of degeneration of mouse oocytes/eggs is modulated by tumor necrosis factor‐α that is accumulated in the expanded cumulus during oocyte maturation. (5) A colloidal iron‐positive substance was detected in the intercellular spaces of follicular tissue, especially in the cumulus mass. Cells located where the cumulus mass and granulosa cell layer interwound became enlarged during the resumption of oocyte meiosis. Colloidal iron‐positive substances accumulated extensively within the intercellular spaces of the enlarged cells. Microsc. Res. 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Res. Tech</addtitle><description>In the mouse, oogonia enter the prophase of the first meiotic division and differentiate into oocyte while developing in the fetal ovary. Shortly after birth, all oocytes are arrested in the dictyate stage of late prophase in the developing follicles; a small number of follicles reach the ovulatory stage; the rest are lost by apoptosis. The resumption of meiotic division and nuclear progression to metaphase II (oocyte maturation) occur in the ovulatory follicles. In this article we review recent morphological data that have clarified how cytokines and glycosaminoglycans (GAGs) are involved in mouse follicular development, atresia, and maturation during oogenesis, as exogenous/endogenous factors. (1) Microvascular networks and angiogenic factors (epidermal growth factor; GAGs) are deeply involved in selective mouse oocyte growth beyond ∼20–30 μm in diameter. (2) Gonadotropin‐inducible neuronal apoptosis inhibitory protein may indirectly affect oocyte survival as a result of the inhibition of apoptotic granulosa‐cell death during folliculogenesis. (3) The pattern of oocyte degeneration depends on follicle and oocyte developmental stages, and follicle stimulating hormone accelerates the process of degeneration of oocytes. (4) The process of degeneration of mouse oocytes/eggs is modulated by tumor necrosis factor‐α that is accumulated in the expanded cumulus during oocyte maturation. (5) A colloidal iron‐positive substance was detected in the intercellular spaces of follicular tissue, especially in the cumulus mass. Cells located where the cumulus mass and granulosa cell layer interwound became enlarged during the resumption of oocyte meiosis. Colloidal iron‐positive substances accumulated extensively within the intercellular spaces of the enlarged cells. Microsc. Res. 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Res. Tech</addtitle><date>2006-06</date><risdate>2006</risdate><volume>69</volume><issue>6</issue><spage>427</spage><epage>435</epage><pages>427-435</pages><issn>1059-910X</issn><eissn>1097-0029</eissn><abstract>In the mouse, oogonia enter the prophase of the first meiotic division and differentiate into oocyte while developing in the fetal ovary. Shortly after birth, all oocytes are arrested in the dictyate stage of late prophase in the developing follicles; a small number of follicles reach the ovulatory stage; the rest are lost by apoptosis. The resumption of meiotic division and nuclear progression to metaphase II (oocyte maturation) occur in the ovulatory follicles. In this article we review recent morphological data that have clarified how cytokines and glycosaminoglycans (GAGs) are involved in mouse follicular development, atresia, and maturation during oogenesis, as exogenous/endogenous factors. (1) Microvascular networks and angiogenic factors (epidermal growth factor; GAGs) are deeply involved in selective mouse oocyte growth beyond ∼20–30 μm in diameter. (2) Gonadotropin‐inducible neuronal apoptosis inhibitory protein may indirectly affect oocyte survival as a result of the inhibition of apoptotic granulosa‐cell death during folliculogenesis. (3) The pattern of oocyte degeneration depends on follicle and oocyte developmental stages, and follicle stimulating hormone accelerates the process of degeneration of oocytes. (4) The process of degeneration of mouse oocytes/eggs is modulated by tumor necrosis factor‐α that is accumulated in the expanded cumulus during oocyte maturation. (5) A colloidal iron‐positive substance was detected in the intercellular spaces of follicular tissue, especially in the cumulus mass. Cells located where the cumulus mass and granulosa cell layer interwound became enlarged during the resumption of oocyte meiosis. 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subjects	angiogenesis Animals apoptosis atresia Cell Differentiation cumulus-oocyte complex Cytokines - metabolism EGF Female follicle development glycosaminoglycans Glycosaminoglycans - metabolism Mice oocyte Oocytes - cytology Oocytes - ultrastructure Oogenesis - physiology Ovarian Follicle - cytology Ovarian Follicle - physiology Ovarian Follicle - ultrastructure ovary Ovary - cytology Ovary - ultrastructure TNF-α
title	Morphodynamics of ovarian follicles during oogenesis in mice
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