Chronology and dynamics of the development of female genital organs of cattle fetuses

The chronology and dynamics of the female germ cell development, of the mitotic activity of oogonia, and of the chromosome rearrangements at prophase I of meiosis have been quantitatively estimated in 30 cow embryos and foetuses at the age of 1.5 to 9 months. The sexual differentiation of the gonads was shown in a 1.5 month old embryo. The oocytes at the stages of preleptotene chromosome condensation and decondensation occurred in the 1.5 month old embryos and their maximum number was observed in the 2-5 month old foetuses. The leptotene oocytes were found in the 2-2.5 month old foetuses. The transition to zygotene and pachytene was also recorded in the 2-2.5 month old foetuses but their maximum number was observed in the 4-6 month old foetuses; their number was reduced to single oocytes thereafter. The first diplotene oocytes appeared in the 3 month old foetuses but the active transition of the oocytes to diplotene was observed after four months of development. The formation of a layer of follicle cells takes place around the diplotene oocytes. The vast majority of degenerating germ cells are the oocytes in zygotene-pachytene and in diplotene. The population of germ cells is formed by the mitotic division of oogonia in the cow foetuses, mainly at the age of 1.5 to 4 months of development.     

From primordial germ cell to primordial follicle: mammalian female germ cell development

In mammals, the final number of oocytes available for reproduction of the next generation is defined at birth. Establishment of this oocyte pool is essential for fertility. Mammalian primordial germ cells form and migrate to the gonad during embryonic development. After arriving at the gonad, the germ cells are called oogonia and develop in clusters of cells called germ line cysts or oocyte nests. Subsequently, the oogonia enter meiosis and become oocytes. The oocyte nests break apart into individual cells and become packaged into primordial follicles. During this time, only a subset of oocytes ultimately survive and the remaining immature eggs die by programmed cell death. This phase of oocyte differentiation is poorly understood but molecules and mechanisms that regulate oocyte development are beginning to be identified. This review focuses on these early stages of female germ cell development.     

Details of the female and male pathway of the Keimbahn determined by enzyme histochemical and autoradiographic studies

Autoradiographic studies and the use of enzyme histochemistry have revealed that early germ line cells (female and male PGC, oogonia, prediplotene oocytes and prospermatogonia) as well as the more advanced germ cells (diplotene oocytes, spermatogonia, spermatocytes and spermatids) show specific patterns of their DNA and RNA synthesis and their enzymatic equipment. The female and male germ lines show similar kinetics up to the arise of oocytes and T prospermatogonia (T for transitional), the final products of a first limited multiplication process of primitive gonia. In former studies we supposed that oocytes and T prospermatogonia are the first exponents of the female and male pathway of the germ line (Hilscher and Hilscher, 1989a). Recently, it could be shown--using the reverse PLM method in slides of plastic embedded material--that the first differences between female and male GC can already be stated at the end of the first proliferation wave of oogonia and multiplying prospermatogonia; that means even before the existence of oocytes and T prospermatogonia (Hilscher and Hilscher, 1989b). Oogonia and M prospermatogonia (M for multiplying) are equipped both with only one active X chromosome. While oocytes traverse the prediplotene stages of meiotic prophase T prospermatogonia prepare for a second extensive proliferation process: spermatogenesis. Oocytes in meiosis are provided with two active X chromosomes, T prospermatogonia possess only one, and the presence of the Y chromosome is not vital for them. However, the Y chromosome is required for the normal course of spermatogenesis characterized by a stock of stem cells, that are responsible for the continuous production of male gamets. The mammalian oocyte--similar as that of insects and amphibia but to a lower degree--acts as pre-embryo.     

Evidence That the Mechanism of Prenatal Germ Cell Death in the Mouse Is Apoptosis

Using fluorescence-activated cell sorting combined with fluorescence microscopy the mechanism of embryonic germ cell death in the mouse has been shown to be apoptosis. Primordial germ cells (PGCs) from embryos at specific developmental stages have been analyzed, and cells with apoptotic morphology have been isolated by cell sorting. In the female, apoptotic oogonia at Day 13 and apoptotic oocytes at Days 15 and 17 were found. In the male, apoptotic cells were seen on Day 13 through Day 17. Apoptotic germ cells were not detected at Day 12 (combined male and female PGCs). Examination of sorted cells by fluorescence microscopy and by light microscopic analysis after alkaline phosphatase staining confirmed that the cells are apoptotic germ cells. Electron microscopy further confirmed that cells showing the morphological characteristics of apoptosis are present.     

Sex chromosome elimination,X chromosome inactivation and reactivation in the southern brown bandicoot Isoodon obesulus (Marsupialia: Peramelidae)

Cytogenetic studies have shown that bandicoots (family Peramelidae) eliminate one X chromosome in females and the Y chromosome in males from some somatic tissues at different stages during development. The discovery of a polymorphism for X-linked phosphoglycerate kinase (PGK-1) in a population of Isoodon obesulus from Mount Gambier, South Australia, has allowed us to answer a number of long standing questions relating to the parental source of the eliminated X chromosome, X chromosome inactivation and reactivation in somatic and germ cells of female bandicoots. We have found no evidence of paternal PGK-1 allele expression in a wide range of somatic tissues and cell types from known female heterozygotes. We conclude that paternal X chromosome inactivation occurs in bandicoots as in other marsupial groups and that it is the paternally derived X chromosome that is eliminated from some cell types of females. The absence of PGK-1 paternal activity in somatic cells allowed us to examine the state of X chromosome activity in germ cells. Electrophoresis of germ cells from different aged pouch young heterozygotes showed only maternal allele expression in oogonia whereas an additional paternally derived band was observed in pre-dictyate oocytes. We conclude that reactivation of the inactive X chromosome occurs around the onset of meiosis in female bandicoots. As in other mammals, late replication is a common feature of the Y chromosome in male and the inactive X chromosome in female bandicoots. The basis of sex chromosome loss is still not known; however later timing of DNA synthesis is involved. Our finding that the paternally derived X chromosome is eliminated in females suggests that late DNA replication may provide the imprint for paternal X inactivation and the elimination of sex chromosomes in bandicoots.     

Immunocytochemical evidence for methylation of the inactive X chromosome in human fetal oogonia

The state of DNA methylation of the X chromosomes of human interphase oogonia from a 46,XX and a 46,XX/47,XXX fetus at 17 weeks of gestation was tested immunocytochemically with an antibody to 5-methylcytosine (5MeC). Of 1637 oogonial nuclei from the 46,XX fetal ovary, 313 (19.1%) contained Barr bodies, of which 93.6% were positive for 5MeC. Of 1780 oogonia from the 46,XX/47,XXX fetus 327 (18.4%) contained Barr bodies; 175 oogonia had one Barr body and 152 had two. Of the single Barr bodies 145 (82.8%) had positive 5MeC reaction product. Of the 152 oogonia from the XXX line, 97 (63.8%) had positive 5MeC on both Barr bodies, 35 (23%) had one positive and one negative, and 20 (13.1%) had no product on either Barr body. This immunocytochemical evidence supports the hypothesis that the DNA of the inactive X-chromosome of the human 17-week gestation oogonium is methylated.     

The role of the rete ovarii in meiosis and follicle formation in the cat, mink and ferret.

Ovarian morphology was studied from the inception of meiosis in the cat, mink and ferret. It was shown that "open connections", allowing cellular contact, existed between the intra-ovarian rete cords and the groups of germ cells as well as between the surface epithelium and the germ cells. The germ cells in the innermost part of the cortex and lying in contact with the rete cells were those which were the first to enter meiotic prophase. Later, the more peripheral oogonia transformed to oocytes. The first follicular formations occurred at the innermost part of the cortex. The granulosa cell layers were in open connection with the intra-ovarian rete cords. In the mink and ferret, a certain part of the rete system at the hilus differentiated into the hilar rete body. In all animals, the extra-ovarian rete cells were actively secreting. It is proposed that the rete system interacts with the cortex, initiating the start of meiosis and that the rete cells as well as cells of the surface epithelium contribute to the granulosa cell layer.     

Die Entstehung multipler Oocytennukleolen aus akzessorischen DNS-Körpern bei Gryllus domesticus

The early stages of female and male germ cells have been investigated in Feulgen squash preparations, in unfixed state with phase contrast optics and in the electron microscope. The DNA axes of the ring-shaped multiple nucleoli in the growing oocytes of Gryllus arise from compact DNA bodies which are found in oogonia of young larvae and in oocytes prior to the growth period. The nuclei of the early oogonia contain several little DNA bodies whereas young oocytes at leptotene, zygotene and pachytene have only one body which is bigger than at earlier stages (Pig. 3). At metaphase and anaphase during oogonial mitosis the DNA body has a filamentous shape distinguishable from the compact chromosomes (Fig. 5). In oogonia as well as at leptotene and zygotene stages, nucleoli are produced in the peripheral, uncoiled parts of each DNA body whereas the compact interior is completely free of nucleolar material (Figs. 4, 12). At pachytene, the whole DNA body begins to despiralize, and single DNA strands are released into the nucleoplasm. These strands form hundreds of multiple nucleoli which finally are dispersed in the germinal vesicle (Fig. 11). — Incorporation studies with radio-active thymidine have shown that DNA synthesis in the DNA body is not synchronous with the S-phase of the chromosomes (Fig. 7). — The DNA body is an own formation distinct from the sex chromosomes (in contrast to the opinion of Sotelo and Wettstein, 1964). Although the positive heteropycnotic X-chromosome in the germ cells of the male cricket is very similar to the DNA body of the female (Fig. 8), there is no regular contact between sex chromosome and nucleolus neither in spermatogonia nor in spermatocytes (Figs. 9, 14). In all probability, the site of the nucleolar organizer is autosomal. — It is suggested that the amplification of the nucleolar genes in Gryllus oocytes results in an accumulation of ribosomal RNA for use during the early cleavage stages of the embryo     

Ovarian responses to undernutrition in pregnant ewes,USA

In most mammals oogonia proliferate by mitosis and begin meiotic development during fetal life. Previous studies indicated that there is a delay in the progression to the first stage of meiotic arrest in germ cells of female fetuses of undernourished ewes. We report that underfeeding (50% NRC requirement beginning on Day 28 of pregnancy) provokes an increase in oxidative base lesions within DNA of mid-gestational (Day 78) fetal oogonia; this condition was associated with up-regulation of the tumor suppressor/cell-cycle arrest modulator p53, antiapoptotic factor Bcl-2, and base-excision repair polymerase β. Fetal ovarian weights and germ cell concentrations were not altered by nutrient deprivation. Ovaries of ewes on control diets (100% NRC) contained more tertiary follicles than their restricted counterparts; however, peripheral venous estradiol-17β was not different between groups. There was no effect of treatment on p53 accumulation in maternal oocytes. Luteal structure-function was not perturbed by undernutrition. No fetal losses were attributed to the dietary restriction. It is proposed that DNA of interphase fetal oogonia is vulnerable to oxidative insults perpetrated by a nutritional stress to the dam, and that multiple/integrated adaptive molecular response mechanisms of cell-cycle inhibition (providing the time required for base repairs) and survival hence sustain the genomic integrity and population stability of the germline.     

Sex-specific telomere redistribution and synapsis initiation in cattle oogenesis

The process of homolog pairing is well characterised in meiosis of male mammals, but much less information is available from female meiosis. We have therefore studied telomere dynamics by FISH and synapsis formation by immunostaining of synaptonemal complex proteins (SCP3, SCP1) on ovarian sections from 15 bovine fetuses, which covered the entire female prophase I. Telomeres displayed a dispersed intranuclear distribution in oogonia and relocated to the nuclear periphery during the preleptotene stage. Tight telomere clustering (bouquet formation) coincided with synapsis initiation at the leptotene/zygotene transition. Clustering of telomeres persisted during zygotene and even into the pachytene stage in a subset of nuclei, while it was absent in diplotene/dictyotene stage nuclei. Thus, the bouquet stage in the bovine female lasts significantly longer than in the male. Further, we observed that synapsis in the female initiated both terminally and interstitially in earliest zygotene stage oocytes, which contrasts with the predominantly terminal synapsis initiation in early zygotene spermatocytes of the bovine male. Altogether, our data disclose a sex-specific difference in telomere dynamics and synapsis initiation patterns in male and female bovine germ cells that may be related to the sex-specific differences in recombination rates observed in this and other mammalian species.     

Electron microscopic study of the differentiation and development of trophocytes and oocytes in Gerris najas (Heteroptera).

The differentiation of oogonia and oocytes, and of trophocytes, from undifferentiated germ line cells has been studied in Gerris najas, a pond skater, from the fourth instar to the adult animal. For the first time criteria have been obtained which allow the distinction between poorly differentiated early oogonia and nurse cells. The most important criteria are the size, shape, and structure of nuclei and mucleoli. This is consistent with the different function of these cell types, which is primarily a different nuclear function: meiosis in the oocytes, and RNA synthesis to support the trophic core and the oocytes in the trophocytes.     

Ovaries of Tubificinae (Clitellata, Naididae) resemble ovary cords found in Hirudinea (Clitellata)

The ultrastructure of the ovaries and oogenesis was studied in three species of three genera of Tubificinae. The paired ovaries are small, conically shaped structures, connected to the intersegmental septum between segments X and XI by their narrow end. The ovaries are composed of syncytial cysts of germ cells interconnected by stable cytoplasmic bridges (ring canals) and surrounded by follicular cells. The architecture of the germ-line cysts is exactly the same as in all clitellate annelids studied to date, i.e. each cell in a cyst has only one ring canal connecting it to the central, anuclear cytoplasmic mass, the cytophore. The ovaries found in all of the species studied seem to be meroistic, i.e. the ultimate fate of germ cells within a cyst is different, and the majority of cells withdraw from meiosis and become nurse cells; the rest continue meiosis, gather macromolecules, cell organelles and storage material, and become oocytes. The ovaries are polarized; their narrow end contains mitotically dividing oogonia and germ cells entering the meiosis prophase; whereas within the middle and basal parts, nurse cells, a prominent cytophore and growing oocytes occur. During late previtellogenesis/early vitellogenesis, the oocytes detach from the cytophore and float in the coelom; they are usually enveloped by the peritoneal epithelium and associated with blood vessels. Generally, the organization of ovaries in all of the Tubificinae species studied resembles the polarized ovary cords found within the ovisacs of some Euhirudinea. The organization of ovaries and the course of oogenesis between the genera studied and other clitellate annelids are compared. Finally, it is suggested that germ-line cysts formation and the meroistic mode of oogenesis may be a primary character for all Clitellata.     

Meiosis-inducing and meiosis-preventing effects of sex steroid hormones on hamster fetal ovaries in organ culture

Day 11 to day 15 p.c. female gonads were cultured for 6-8 days in chemically-defined media. In day 11 and day 12 p.c. ovaries grown in a non-hormonal medium, the germ cells were unable to enter meiosis; they were retained at a stage of oogonia or more frequently at a preleptotene stage. Ovaries of the same ages cultured in an estradiol-containing medium showed germ cells progressing through meiotic prophase in a way close to that in ovaries of equivalent age in vivo. That was the case of the germ cells in day 13 to day 15 p.c. ovaries maintained in a non-hormonal medium. In a testosterone-containing medium, the germ cells in day 13 and day 14 p.c. ovaries were prevented from entering meiosis; by contrast, those in day 15 p.c. ovaries underwent meiotic prophase normally. These results indicated that each of both hormones was able to exert its corresponding (meiosis-inducing or meiosis-preventing) effect before a definite critical time of ovarian development. The possibility is suggested that the germ cell differentiation in the female and male gonads in vivo would also depend on estrogens or androgens precociously synthesized in the gonads or supplied from other organs via the fetal blood.     

Requirement of successive protein syntheses for the progress of meiosis in Blepharisma

Germ nuclei of Blepharisma japonicum begin meiosis within a few hours when cells of complementary mating types conjugate. We synchronized the onset of conjugation and treated cells in different stages of meiosis with 10 micrograms/ml cycloheximide which strongly inhibits protein synthesis in this ciliate. Cycloheximide arrested meiosis at six stages: I, between pairing of cells and swelling of germ nuclei; II, leptotene; III, zygotene; IV, pachytene; XI, interkinesis; XII, prometaphase II. Five of these arrests were reversible. Puromycin (250-500 micrograms/ml) also inhibited the progress of meiosis, though to lesser extents. We propose that the progression of meiosis of B. japonicum requires at least six proteins which are synthesized sequentially during meiosis.     

Differential expression of vasa homologue gene in the germ cells during oogenesis and spermatogenesis in a teleost fish, tilapia, Oreochromis niloticus

Vas (a Drosophila vasa homologue) gene expression pattern in germ cells during oogenesis and spermatogenesis was examined using all genetic females and males of a teleost fish, tilapia. Primordial germ cells (PGC) reach the gonadal anlagen 3 days after hatching (7 days after fertilization), the time when the gonadal anlagen was first formed. Prior to meiosis, no differences in vas RNA are observed in male and female germ cells. In the ovary, vas is expressed strongly in oogonia to diplotene oocytes and becomes localized as patches in auxocytes and then strong signals are uniformly distributed in the cytoplasm of previtellogenic oocytes, followed by a decrease from vitellogenic to postvitellogenic oocytes. In the testis, vas signals are strong in spermatogonia and decrease in early primary spermatocytes. No vas RNA expression is evident in either diplotene primary spermatocytes, secondary spermatocytes, spermatids or spermatozoa. The observed differences in vas RNA expression suggest a differential function of vas in the regulation of meiotic progression of female and male germ cells.     

Comparative aspects of the effects of radiation during oogenesis

Primordial germ cells, which are relatively resistant to radiation administered prior or during migration, become sensitive during sex differentiation of the gonad. Sensitivity increases to a maximum during the peak “wave” of mitosis in oogonia, and especially during the final premeiotic division. The oocyte subsequently becomes increasingly resistant to radiation as it progresses from leptotene to pachytene, after which sensitivity increases with the onset of the period of arrested development (diplotene or dictyate stage).     

Early preantral mouse follicle in vitro maturation: oocyte growth, meiotic maturation and granulosa-cell proliferation

Mechanically isolated early preantral mouse follicles were cultured singly for 16 d and fully grown oocytes were obtained from these follicles. We then compared in vitro and in vivo follicle growth by trypsinising the follicles and counting their cell numbers in a Neubauer-counting chamber and recording the diameter and meiotic status of oocytes under an inverted microscope. As long as the granulosa cells were within the basal membrane, proliferation was slow. From Day 6, when granulosa cells had broken through the basal membrane, the proliferation rate progressed up to Day 10 and decreased thereafter to approximately 12,000 cells per culture droplet. Incorporation of BrdU revealed that proliferating cells were evenly distributed throughout the follicle until antrum formation. As granulosa cell differentiation progressed, proliferation of mural-granulosa cells ceased, while cells around the oocytes continued dividing. Oocyte diameter increased discontinuously in relation to follicle remodelling. During the first growth phase, diameters increased from 56.5 (+/- 4.4 microns) to 67 (+/- 4.1 microns) until the onset of antral-like cavity formation. The last growth phase started after Day 10, and by Day 14 oocyte diameters were not significantly different from those of 26-d-old in vivo control oocytes. The potential to resume meiosis after mechanical removal of granulosa cells was first reached on Day 8; thereafter, removal of the corona showed that all oocytes cultured with FSH remained arrested at the GV stage up to Day 16. After Day 8, approximately 70% of all oocytes underwent GVBD as a result of granulosa-cell removal, but only 23% of these reached MII after 24 h. The in vivo controls reached a comparable GVBD rate (66%) when the granulosa was removed, but most of the oocytes (82%) underwent first polar body extrusion 24 h later. These results suggest that although oocyte diameters after IVM are not different from those of the controls, culture conditions are not yet adequate to support complete meiotic maturation.     

A study of X chromosome regulation during oogenesis in the mouse

Mature oocytes of mammals, in contrast to somatic cells, have two active X chromosomes. This situation might arise through either of two possible mechanisms. The germ line might be differentiated from somatic cells prior to X inactivation. Alternatively, an X chromosome in germ cells would be reactivated after prior inactivation. This paper presents data compatible with reactivation of the X in germ cells. X-linked enzymes were compared in oocytes of XX and XO fetal mice. The activity of G6PD is similar in the two classes of cells at early meiotic stages, but an $\text{XX}\text{XO}$ ratio of 2:1 is approached at later times; this suggests reactivation of the G6PD locus. For HPRT, a 2:1 ratio is observed at all meiotic stages. HPRT shows a large increase in enzyme activity during early meiosis, while G6PD does not. Synthesis of this enzyme at early meiotic stages probably accounts for differences between these data and those obtained for G6PD, and places the time of X reactivation at the entry to meiosis.     

Germ cell kinetics in the neonatal rabbit testis

Summary Germ cells in the developing rabbit testis were found to undergo several distinct changes in the first two weeks after birth. Mitotic activity, which had been high in the late fetal period, reached a peak on the day before birth, then diminished steadily and ceased entirely after five days of age. Extensive germ cell degeneration occurred in the first week after birth resulting in accumulation of pools of degenerating germ cells in the central portions of the seminiferous cords. Following shortly after the peak of mitotic activity, germ cells at various stages of preleptotene could be found in squash preparations. This corresponded to the time when germ cells in the rabbit ovary enter and proceed through meiotic prophase. There was no evidence of entry into leptotene or later stages of meiosis in the neonatal testis. The findings suggest that a similar stimulus for entry into meiosis may exist in both sexes, but a blockage occurs in the male.Technical assistance was provided by Margaret Randolph and David Knibbs     

Cytogenetic analysis of reconstituted one-cell mouse embryos derived from nuclear transfer of fetal male germ cells.

Micromanipulation techniques were used to produce reconstituted one-cell mouse embryos after the fusion of fetal male germ cells 15.5 day post coitum with enucleated secondary oocytes. At this stage of development, male fetal germ cells are arrested at G1 of mitotic interphase. Two distinct populations of germ cells, differing in size and ploidy, were isolated from the genital ridge of a mid-term fetus. Oocytes that had received male germ cells from the population of smaller (mononuclear) germ cells developed as diploid one-cell reconstituted embryos. When the same procedures were used to produce reconstituted one-cell embryos using male fetal germ cells from a population of larger (multinucleate) cells, they exhibited ploidy of either 4x, 6x or 8x at metaphase of the first cell division. Although most reconstituted embryos (90 and 96%) developed to the two-cell stage, the proportion of embryos receiving small germ cells developed to blastocysts was much higher (62%) than that receiving large germ cells (4%). These studies indicate that not all fetal germ cells are diploid before the onset of meiosis and have identified procedures to produce reconstituted embryos from fetal germ cells that do not carry genome or chromosome anomalies.