Mitochondrial morphology in human fetal and adult female germ cells

doi:10.1093/humrep/15.suppl_2.129

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Human Reproduction, Vol. 15, No. suppl_2, pp. 129-147, 2000
© 2000 European Society of Human Reproduction and Embryology

Mitochondrial morphology in human fetal and adult female germ cells

Pietro M. Motta¹^,3, Stefania A. Nottola¹, Sayoko Makabe² and Rosemarie Heyn¹

¹ Department of Anatomy, University of Rome ‘La Sapienza’ Rome 00161, Italy ² Department of Obstetrics and Gynecology, Toho University Tokyo 143, Japan

Correspondence: ³To whom correspondence should be addressed at: Department of Anatomy, Faculty of Medicine, Via A.Borelli 50,I–00161 Rome, Italy. E-mail: motta{at}uniromal.it

The aim of this study has been to observe, by electron microscopy,the morphological changes affecting mitochondria and associatedorganelles in the human female germ cell during oogenesis, maturationand fertilization. In the primordial germ cell (PGC), roundedmitochondria with a pale matrix and small vesicular cristaeare disposed near the nucleus and significantly increase innumber during PGC migration and settlement in the gonadal ridge,where they differentiate into oogonia. In these early stagesof mammalian oogenesis, aggregates of mitochondria are typicallyclustered around or in close relationship with the nuage. Inoocytes at early prophase stage, mitochondria proliferate whilealigned along the outer surface of the nuclear membrane, containa more dense matrix than before, and have lamellar cristae.Oocytes of primordial and primary follicles mostly contain roundor irregular mitochondria whose matrix has become very light.These mitochondria show typical parallel, arched cristae, andare clustered near the nucleus with other organelles formingthe Balbiani's vitelline body. When follicles grow, the mitochondriaof the oocytes become even more numerous and are dispersed inthe ooplasm. Both paranuclear accumulation and subsequent dispersionof mitochondria in the cytoplasm are likely to be regulatedby microtubules. By ovulation, mitochondria are the most prominentorganelles in the ooplasm. They form voluminous aggregates withsmooth endoplasmic reticulum (SER) tubules and vesicles. Thesemitochondrial–SER aggregates (M–SER) and the mitochondrial–vesiclecomplexes (MV) could be involved in the production of a reservoirof substances or membranes anticipating subsequent fertilizationand early embryogenesis. Just after fertilization, the mitochondriaof the oocyte undergo a further substantial change in size,shape, and microtopography. In the pronuclear zygote, mitochondriaconcentrate around the pronuclei. During the first embryoniccleavage divisions, round or oval mitochondria with a densematrix and few arched cristae are gradually replaced by elongatedones with a less dense matrix and numerous transverse cristae.A progressive reduction in size and number of M–SER aggregatesand MV complexes also occurs. In summary, oocyte mitochondriashow dynamic morphological changes as they increase in numberand populate different cell domains within the oocyte. Theyform complex relationships with other cell organelles, accordingto the different energetic -metabolic needs of the cell duringdifferentiation, maturation, and fertilization, and are ultimatelyinherited by the developing embryo, where they eventually assumea more typical somatic cell form.

Key words: embryo/germ cell/mitochondria/oocyte/ultrastructure

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