Incorporation of H3-thymidine into the oocytes of a sterlet in the early meiotic prophase]

DNA synthesis in meiotic oocytes of the sterlet (A. ruthenus) has been studied during early prophase stages using H3-thymidine. The pattern of H3-thymidine incorporation is similar to that in oocytes of Amphibia and Osteichthyes. In the oogonia as well as in the leptotene and zygotene oocytes, the label is predominantly localized over chromosomes. An intensive incorporation of H3-thymidine into the material of the heterochromatic "cap" has been observed during pachytene. Thus, the main synthesis of extra DNA in the sterlet oocytes occurs during pachytene. No DNA in synthesized by the diplotene oocytes.     

Oogenesis of Tilapia mossambica. I. Oogonia and meiotic prophase oocytes

Using light and electron microscopy and autoradiography, the morphology and synthesis of DNA, RNA and proteins in oogonia and early meiotic prophase oocytes in Tilaria mossabique were studied. According to dimensions and morphological features observed it is possible to distinguish between two groups of oogonia: large oogonia corresponding to type A spermatogonia of mammals, and small actively dividing oogonia, located in groups and identical to type B spermatogonia. The morphology of oogonia and of the early meiotic prophase oocytes well compares with the pattern described for other species of bony fishes. In the cytoplasm of these cells dense bodies, nuage-material, free ribosomes, large mitochondria with lamellar cristae and Golgi cisterns are available. In the oocyte nuclei at zygotene and pahytene stages 3H-thymidine incorporation was seen mainly into the nucleolus-associated chromatin. Besides, the formation of a heterochromatin cape and the synaptonemal complex was observed. Incorporation of 3H-uridine and 3H-leucine in the nuclei of these cells was very poor.     

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     

THE OOGONIA OF MACROALGA UNDARIA PINNATIFIDA ARE ALKALINE‐PHOSPHATASE POSITIVE AND CONTAIN GERMINAL BODY‐LIKE STRUCTURES1

It was observed that in the female gametophyte of Undaria pinnatifida (Harv.) Suringar (Phaeophyta, Laminariales) gametangial initials and maturing oogonia demonstrated different levels of alkaline‐phosphatase activity (APA). The oogonia exhibited a higher level of APA than in its initials. Electron‐dense granular ovoid structures ～0.5–0.6 μm were present in the cytoplasm of oogonia. These inclusions were not membrane bound and do not appear to be associated with any particular organelles. The number of the inclusions was 1 to 2 in a single section of the cell. In essential details, the specific APA and subcellular germinal body‐like structure of the developing female gamete in U. pinnatifida were very similar to those in metazoan oocytes.     

Oogenesis in the Polychaete Dipolydora commensalis

Oocytes of the polychaete Dipolydora commensalis develop in the gonad, in close contact with the wall of the genital blood vessel, up to the late stages of vitellogenesis. At the blood vessel wall, between the neighboring vitellogenic oocytes, and sometimes on the apical surface of the oocytes, there are flattened follicular cells. However, no continuous, well-expressed gonad envelope is found. Oogenesis is asynchronous. Gametes at all developmental stages, from oogonia to late vitellogenic oocytes, occur in the gonad. Dividing oogonia vary from 6 to 10 m in diameter. RNA, proteins, glycogen, and lipids accumulate in the oocytes during vitellogenesis. The breakdown of the oocyte germ vesicle occurs in the gonad. Before spawning, gametes accumulate in the coelom and reach 80–90 m in diameter, at which point a new generation appears in the gonad.     

Development of germ cells in the ovaries of human fetuses in the early periods]

Histological methods were used for studying 30 ovaries of early human embryos from 7 to 11 weeks of development. It was shown that in the process of development of the ovary the number of mitotically dividing oogonia decreased from 76% in 7-8 weeks to 41% in the period of 10-11 weeks. The mototic division of oogonia was characterized by high activity from 3,6% to 6,8%. However, as early as in the ovaries of 7-8 week embryos there occurred transition of a part of oogonia into oocytes of preleptotene stages which were characterized by processes of spiralization and despiralization of chromatin in the nuclei. The amount of such oocytes increases in the process of development of the embryo. The amount of oocytes at the stage of condensation of chromatin "prochromosomes" increases from 7,6% to 14,4%, the amount of oocytes at the stage of the following despiralization increased from 2,1% to 21% when comparing the ovaries of embryos of 7-8 and 10=11 weeks of development. The size of nucleoli was found to change in the period of preleptotene transformations in the oocyte nuclei. Photographs of the stages in question are presented made from histological and total preparations.     

Gene amplification in the oocytes of dytiscid water beetles

A conspicuous mass of extrachromosomal DNA (Giardina's body) is found in oogonia and oocytes of Dytiscid water beetles. Since in older oocytes this DNA is associated with numerous nucleoli, it seemed probable that the ovary might contain extra copies of the genes for ribosomal RNA (rRNA). This hypothesis has been confirmed by centrifugation and molecular hybridization studies. —In Dytiscus marginalis and Colymbetes fuscus a high density satellite DNA is found in somatic cells and in sperm. Hybridization experiments show that all of the rDNA, i.e., those sequences complementary to rRNA, are located in this satellite, although quantitatively they make up only a small fraction of the satellite. In both species the DNA isolated from ovariole tips is enriched with respect to the satellite. A parallel enrichment of the rDNA has been shown in ovariole tips of Colymbetes, but for technical reasons has not been examined in Dytiscus. —The following model is proposed. In somatic cells and sperm the rDNA is part of an extensive region of high density DNA in one or more chromosomes. In oogonia and oocytes the entire high density region is replicated extrachromosomally and appears cytologically as Giardina's body.     

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.     

Dominant distribution of mitochondrial DNA from recipient oocytes in bovine embryos and offspring after nuclear transfer

In the process of nuclear transfer, heteroplasmic sources of mitochondrial DNA from a donor cell and a recipient oocyte are mixed in the cytoplasm of the reconstituted embryo. The distribution of mitochondrial DNA heteroplasmy in nuclear transfer bovine embryos and resultant offspring was investigated by measuring polymorphism in the displacement loop region of mitochondrial DNA using PCR-mediated single-strand conformation polymorphism. Most offspring (20 of 21 calves) from recipient oocytes of undefined mitochondrial DNA genotypes showed different genotypes from the mitochondrial DNA of donor cells. The single calf that was an exception showed heteroplasmy, including the donor mitochondrial DNA genotype. Six cloned calves were produced from oocytes of a defined mitochondrial DNA genotype. All of these clonal members and various tissues showed only the mitochondrial DNA genotype derived from the oocyte. The mitochondrial DNA from donor cells appeared to be eliminated during early embryonic development; it gradually decreased at the early cleavage stages and was hardly detectable by the blastocyst stage. These results indicate that the genotype of mitochondrial DNA from recipient oocytes may become the dominant category of mitochondrial DNA in calves resulting from nuclear transfer.     

Ovarian intercellular bridges in Dermacentor andersoni stiles (Acari : Ixodidae)

Intercellular bridges are present between oogonia and between oocytes of nymphs and newly molted and fasting adult Dermacentor andersoni Stiles. During these stages there is synchronous development of oogonia and oocytes. These bridges are unique both in their degree of development and in possessing narrow, elongated invaginations of the plasma membrane around both bases. Dictyosomes are frequently present in close proximity to bridge bases and vesicles are often noted in bridges between oocytes of adults. Bridges between oogonia infrequently contain cisternae of smooth endoplasmic reticulum.     

Effects of Hoechst 33342 staining and ultraviolet irradiation on mitochondrial distribution and DNA copy number in porcine oocytes and preimplantation embryos

Hoechst 33342 (H342), in combination with ultraviolet (UV) irradiation, is frequently used to aid or confirm the enucleation of porcine oocytes in somatic cell nuclear transfer programs. The exposure of oocytes to H342 and UV irradiation has a deleterious effect on the development of in vitro‐fertilized porcine oocytes, with increasing exposure to UV irradiation (up to 30 sec) having more drastic effects. It has been hypothesized that this decrease in embryonic development could be due to damage to the mitochondrial DNA (mtDNA). To investigate this hypothesis, we analyzed the mitochondrial distribution and DNA copy number of in vitro‐matured porcine oocytes exposed to H342/UV and the subsequent embryonic development compared with the mitochondrial distribution and DNA copy number of in vivo‐derived oocytes and embryos. Using quantitative, real‐time polymerase chain reaction (qPCR) protocols to analyze mtDNA and confocal laser scanning microscopy with MitoTracker Deep Red to determine mitochondrial distribution, we demonstrated that the simultaneous exposure of in vitro‐matured porcine oocytes to H342 staining and UV irradiation is associated with reduced oocyte developmental competence and abnormal mitochondrial distribution in the resulting cleaved embryos. In addition, 2‐ to 4‐cell embryos derived from oocytes exposed to H342/UV showed a significant decrease in mtDNA copy number. These results should be considered when H342/UV procedure is used during nuclear transfer in recipient porcine oocytes. Mol. Reprod. Dev. 79: 651–663, 2012. © 2012 Wiley Periodicals, Inc.     

X-chromosome heteromorphism and appearance of meiosis in the rat fetal ovary

Fetal rat oogenesis was examined attempting to test the hypothesis that two functional X chromosomes are required for the onset of meiosis. The presence of a Barr body in germ cells was considered to be evidence for one inactive X chromosome and the detection of leptotene oocytes as the criterion for the establishment of meiotic prophase. It was found that on Day 16 of gestation, 3.9% of the germ cells were leptotene oocytes, but the incidence of Barr body-positive oogonia persisted at 9.9%. On Day 17, the leptotene oocytes had increased to 26.6% and the Barr body-positive oogonia had decreased to 3.5%. It was concluded that X-chromosome reactivation, though occurring at some time during the onset of meiosis, was not the initiating event.     

Expression of activin subunits and receptors in the developing human ovary: activin A promotes germ cell survival and proliferation before primordial follicle formation

The formation of the essential functional unit of the ovary, the primordial follicle, occurs during fetal life in humans. Factors regulating oogonial proliferation and interaction with somatic cells before primordial follicle formation are largely unknown. We have investigated the expression, localisation and functional effects of activin and its receptors in the human fetal ovary at 14-21 weeks gestation. Expression of mRNA for the activin betaA and betaB subunits and the activin receptors ActRIIA and ActRIIB was demonstrated by RT-PCR. Expression of betaA mRNA increased 2-fold across the gestational range examined. Activin subunits and receptors were localised by immunohistochemistry. The betaA subunit was expressed by oogonia, and the betaB subunit and activin receptors were expressed by both oogonia and somatic cells. BetaA expression was increased in larger oogonia at later gestations, but was low in oocytes within newly formed primordial follicles. Treatment of ovary fragments with activin A in vitro increased both the number of oogonia present and oogonial proliferation, as detected by bromodeoxyuridine (BrdU) incorporation. These data indicate that activin may be involved in the autocrine and paracrine regulation of germ cell proliferation in the human ovary during the crucial period of development leading up to primordial follicle formation.     

Cytophotometric and autoradiographic evidence for functional apomixis in a gynogenetic fish,Poecilia formosa and its related,triploid unisexuals

Summary Amounts of DNA in individual Feulgen-stained nuclei from squash preparations of ovaries and testes from wild-caught and laboratory-reared stocks of Poecilia spp. were determined with an integrating microdensitometer. The DNA content of primary spermatocytes (4C) at zygotene, pachytene, or at metaphase I (3.3–3.4 pg) was approximately twice that found in secondary spermatocytes (2C) and four times that found for young spermatids (1C). Rarely, mature sperm were found with 2C DNA amounts. Nuclei from follicular epithelium and oogonia from both bisexual and diploid unisexual fish contained about 1.6–1.7 pg DNA; whereas, the DNA content of primary oocyte nuclei was about 3.5–3.7 pg DNA, indicating that just one cycle of chromosomal replication had occurred in these cells during the period of DNA synthesis before the visible onset of meiotic prophase. Similar results were obtained for triploid unisexuals whose 6C primary oocyte nuclei contained 5.0–5.1 pg DNA, which was twice the DNA content of 3C oogonia and follicular epithelial cells (2.4–2.5 pg DNA). Autoradiographic studies, designed to monitor the incorporation of ³H-thymidine by oogonia and primary oocytes in vivo and in vitro, also showed that there is no additional synthesis of DNA during the course of meiotic prophase in these unisexual fish. Therefore, we conclude that apomixis, not endoreduplication, is the cytological basis of reproduction in Poecilia formosa and its related, triploid biotypes.     

A LIGHT- AND ELECTRON-MICROSCOPIC STUDY OF PRIMARY HETEROGENEITY IN THE EGGS OF TWO BROWN ALGAE

The mature eggs of Zonaria farlowii and Dictyota binghamiae exhibit a distinctively symmetrical arrangement of organelles. In mature oogonia plastids occur in two groups in the central region of the cell and vacuoles of several types are arranged in peripheral layers. Before the mature egg is released, an amorphous “mucilage layer” developes inside the wall of the oogonium. After fertilization the plastids become uniformly distributed. When the eggs of Zonaria develop parthenogenetically the primary heterogeneity is retained. The symmetrical arrangement of membranes seen in the oocytes of these plants may represent an organizing system that influences cytodifferentiation and perhaps subsequent embryology.     

The ultrastructure of germinal beds in the ovary of Gerrhonotus coeruleus (Reptilia: Anguidae)

A study of ovarian structure in adult Alligator Lizards (Gerrhonotus coeruleus) was conducted by light microscopy and transmission electron microscopy. Particular attention was directed to characterizing the ultrastructure of germ-line cells, prior to follicle formation. General ovarian structure in this lizard is similar to that of other lizards. The paired organs are hollow, thin-walled sacs containing follicles in roughly 3 to 4 size classes. Ovarian germinal tissue consists of oogonia (diploid cells which divide mitotically) and oocytes (meiotic cells), intermixed with ovarian surface epithelial cells. Germ cells reside in two dorsal patches of epithelium per ovary (germinal beds), as is common in lizards. Oogonia in interphase show a highly dispersed chromatin pattern. Within oogonia cytoplasm, Golgi complexes are scarce, rough endoplasmic reticulum is absent, and lipid droplets are rare. Ribosomes are scattered in small clusters. Small, round vesicles are common in all oogonia; glycogen-like granules are present in some. Mitochondria form a juxtanuclear mass within which groups of several mitochondria surround a dense granule. “Nuage” granules also are found unassociated with mitochondria. Oocytes are present in stages of meiotic prophase up to diplotene. Synaptinemal complexes are seen in several (pachytene) cells. The cytoplasm of oocytes differs from that of oogonia in that mitochondria do not form groups, and nuage and glycogen are absent, whereas small round vesicles and large irregular vesicles are common. The ultrastructural similarities in germ cells of a reptile as compared to those of other vertebrates strengthens the notion that germ-line cells possess (or lack) qualities related to the undifferentiated state of these cells.     

Two progenitor cells for human oogonia inferred from pedigree data and the X-inactivation imprinting model of the fragile-X syndrome.

Laird has proposed that the human fragile-X syndrome is caused by abnormal chromosome imprinting. The analysis presented here supports and extends this proposal. Using published pedigrees that include DNA polymorphism (RFLP) data, we establish that the states of the fragile-X mutation termed "imprinted" and "nonimprinted" usually can be distinguished by the level of cytogenetic expression of the fragile-X chromosome. This information is then used to assess the state of the fragile-X allele in carrier progeny of individual women who inherited a nonimprinted fragile-X chromosome. From this assessment, an estimate is made of the frequency, in individual women, of primary oocytes with an imprinted fragile-X chromosome. The results of this analysis provide additional support for the specific model in which chromosome imprinting occurs in a female in, on average, half of her primary oocytes. This is the expected frequency if X-chromosome inactivation is the initial step in the imprinting of the mutant fragile-X allele. Moreover, this analysis suggests a biological explanation for peculiarities of fragile-X inheritance described by others as "clustering" and the "Sherman paradox." We interpret these peculiarities as consequences of a very small number of oogonial progenitor cells. Two progenitor cells for oogonia is the best integer estimate of the number of such cells at the time of the initial event that leads to chromosome imprinting.     

Mitochondrial DNA copy number in bovine oocytes and somatic cells

Restriction endonuclease analysis and direct nucleotide sequencing of bovine mitochondrial DNA have revealed a high apparent rate of sequence divergence between maternally related individuals. One possible mechanism that would account for the high rate involves nonuniform amplification and/or segregation of mitochondrial DNA during development of the oocyte. We report here experiments which quantitate the amount of mitochondrial DNA in the bovine oocyte as compared to bovine somatic cells. Total DNA was isolated from purified oocytes, separated by agarose gel electrophoresis, and immobilized on nitrocellulose filters. Hybridization with the complete mitochondrial DNA genome or cloned mitochondrial DNA restriction fragments revealed a 100-fold increase in oocyte mitochondrial DNA as compared to somatic cells. Developing oocytes contained about 4.5 pg or 2.6 × 10⁵ copies per cell, whereas primary bovine tissue culture cells contained 0.045 pg or 2.6 × 10³ copies per cell. These experiments demonstrate directly the amplification of mitochondrial DNA in mammalian oocytes and are consistent with models which could generate mitochondrial DNA polymorphisms by unequal amplification of mitochondrial genomes within an animal.     

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.