Insights into regulation of the mammalian cell cycle from studies on spermatogenesis using genetic approaches in animal models

The genetic hierarchy controlling mitosis and especially meiosis during gamete formation is not well understood, even in less complicated systems such as the yeasts. Meiotic divisions are obviously restricted to germ line cells and as such likely require mechanisms of cell cycle control that do not function and may not exist in somatic cells. While male and female germ cells have stages of cell cycle regulation in common, the timing of these events and the stage of development at which these events occur differ in the two sexes. Understanding the genetic program controlling the mitotic and meiotic divisions of the germ line represents a unique opportunity for providing insight into cell cycle control in vivo. Elucidating the key control points and proteins may also enhance our understanding of the etiology of infertility and provide new directions for contraception.     

The cytology of paedogenesis in the gall midgeMycophila speyeri

In paedogenetically developing female eggs of the gall midgeMycophila speyeri only one equational meiotic division occurs. The primary cleavage nucleus contains 29 chromosomes. In the fourth cleavage division 23 chromosomes are eliminated from the future somatic nuclei while the primordial germ-line nucleus keeps the high chromosome number.—The paedogenetic development of male eggs begins with two meiotic divisions. The egg nucleus with 14 or 15 chromosomes fuses with two, sometimes only one, somatic nuclei (2n=6) of maternal origin (regulation). Thus the primary cleavage nucleus contains 26 or 27 chromosomes, sometimes only 20 or 21. Elimination in cleavage divisions V and VI leeds to somatic nuclei with 3 chromosomes while the primordial germ-line nucleus keeps the high chromosome number.—Differences between male and female eggs and the evolution of regulation in gall midges are discussed.     

Die Zytologie der bisexuellen und parthenogenetischen Fortpflanzung von Heteropeza pygmaea Winnertz,einer Gallmücke mit pädogenetischer Vermehrung

Heteropeza pygmaea (syn. Oligarces paradoxus) can reproduce as larvae by paedogenesis or as imagines (Fig. 1). The eggs of imagines may develop after fertilization or parthenogenetically. The fertilized eggs give rise to female larvae, which develop into mother-larvae with female offspring (Weibchenmütter). Only a few of the larvae which hatch from unfertilized eggs become motherlarvae with female offspring; the others die. Spermatogenesis is aberrant, as it is in all gall midges studied to date. The primary spermatocyte contains 53 or 63 chromosomes. The meiotic divisions give rise to two sperms each of which contains only 7 chromosomes (Figs. 5–11). The eggs of the imago are composed of the oocyte and the nurse-cell chamber. In addition to the oocyte nucleus and the nurse-cell nuclei there are three other nuclei in the eggs (Figs. 15–17). They are called small nuclei (kleine Kerne). In prometaphase stages of the first cleavage division it could be seen that these nuclei contain about 10 chromosomes. Therefore it is assumed that these nuclei originate from the soma of the mother-larva. The chromosome number of the primary oocyte is approximately 66. The oocyte completes two meiotic divisions. The reduced egg nucleus contains approximately 33 chromosomes. The polar body-nuclei degenerate during the first cleavage divisions. The fertilized egg contains 2–3 sperms. The primary cleavage nucleus is formed by the egg nucleus and usually all of the sperm nuclei and the small nuclei (Figs. 21–29). The most frequent chromosome numbers in the primary cleavage nuclei are about 77 and 67. The first and the second cleavage divisions are normal. A first elimination occurs in the 3rd, 4th, and 5th cleavage division (Fig. 30). All except 6 chromosomes are eliminated from the future somatic nuclei. Following a second elimination (Figs. 33, 34), the future somatic nuclei contain 5 chromosomes. No elimination occurs in the divisions of the germ line nucleus. In eggs which develop parthenogenetically the primary cleavage nucleus is formed by the egg nucleus and 2–3 small nuclei. It's chromosome number is therefore about 53 or 63. After two eliminations, which are similar to the ones which occur in fertilized eggs, the soma contains 5 chromosomes. The somatic nuclei of male larvae which arrise by paedogenesis contain 5 chromosomes; while the somatic nuclei of female larvae of paedogenetic origin contain 10 chromosomes. It was therefore assumed earlier that sex was determined by haploidy or diploidy. But the above results show that larvae from fertilized as well as from unfertilized eggs of imagines have 5 chromosomes in the soma, but are females, and the female paedogenetic offspring of larvae from unfertilized eggs have either 5 or 10 chromosomes in their somatic cells. Therefore sex determination is not by haploidy-diploidy but by some other, unknown, mechanism. The cytological events associated with paedogenetic, bisexual, and parthenogenetic reproduction in Heteropeza pygmaea are compared (Fig. 37). The occurrence and meaning of the small nuclei which are found in the eggs of most gall midges are discussed. It has been shown here that these nuclei function to restore the chromosome number in fertilized eggs; it is suggested that they function similarity in certain other gall midges. Consideration of the mode of restoration of the germ-line chromosome number leads to the conclusion that in Heteropeza few, if any, of the chromosomes are limited to the germ-line, i.e. can never occur in somatic cells (p. 124).     

Meiotic weakness: the first division

Cell division is probably the most dramatic event in the life of a cell : the entire genetic material has to be equally distributed into the two daughter cells. Segregation errors have severe consequences and lead to either cell death or the generation of aneuploid cells and may cause the formation of tumors or tumor promoting mutations in somatic cells. In meiosis, they provoke the generation of aneuploid embryos and/or spontaneous abortions. Trisomies in humans, such as trisomy 21, are due to the missegregation of one chromosome in the first meiotic division in the oocyte. This review deals with the molecular mechanisms regulating the two meiotic divisions required for the generation of female haploid germ cells. Here we focus mainly on spindle assembly, and cell cycle regulation especially during the first meiotic division in mouse oocytes (excellent reviews have been written on the peculiar aspects of cell cycle regulation in meiosis II, such as the CSF arrest).     

Germ line and oogenesis during paedogenetic reproduction inHeteropeza pygmaea Winnertz (Diptera: Cecidomyiidae)

The germ line during paedogenetic reproduction in the gall midgeHeteropeza pygmaea was followed cell generation by cell generation. There are altogether 8 or 9 successive divisions during one paedogenetic cycle, and all descendants of the primordial germ cell develop into occytes, while the trophocytes are of somatic origin. In the cytological race studied (from southern Finland) the germ-line cells possess 58 chromosomes, the somatic number being 10.     

Nuclear division and migration during early embryogenesis of Bradysia tritici coquillet (syn. Sciara ocellaris) (diptera : Sciaridae)

Nuclear division and migration of cleavage nuclei in the embryos of Bradysia tritici (Diptera : Sciaridae) have been studied by light microscopy and nuclear staining. There are 8 cleavage cycles up to the syncytial blastoderm stage (4.5 hr), and during the 11th cycle cellularization begins (6.5 hr). The first 3 divisions take about 30 min each. During the 5th and 6th cycles, the maximum rate of division is reached (12 min/cycle at 22°C). After pole cell formation, the duration of the following mitotic cycles increases progressively. During nuclear migration, the presumptive germ line nuclei reach the egg cortex first, followed by anterior somatic nuclei and finally, posterior somatic nuclei reach the egg cortex. Possibly as a result of this region-specific nuclear migration, nuclear divisions become parasynchronous after 3 hr of embryogenesis (4th cycle). Several mitotic cycles later, between the 8th and 10th cycle in different embryos, X-chromosome elimination in somatic nuclei begins at the anterior egg pole and progresses in anteroposterior direction. Our observations suggest that the observed region-specific differences may be due to the activity of localized factors in the egg that control migration and nuclear cycle of the somatic nuclei.     

Haploinsufficiency of Bcl-x leads to male-specific defects in fetal germ cells: differential regulation of germ cell apoptosis between the sexes

In germ cells, the function of which is to form the next generation, apoptotic cell death occurs during development, as in the case of somatic cells. In this study, we show that Bcl-x knockout heterozygous (Bcl-x(+/-)) mice exhibit severe defects in male germ cells during development. A substantial increase in apoptosis of male germ cells occurs at around embryonic day 13.5 (E13.5) in Bcl-x(+/-) embryos, leading to hypoplasia of postnatal testes and reduced fertility. On the other hand, female germ cells at the same stages do not show discernible differences between wild-type and Bcl-x(+/-) embryos. This phenotype of Bcl-x haploinsufficiency shows that regulation of apoptosis becomes different between the sexes at around the onset of sex differentiation. Through this study, we found that, in wild-type embryos, (1) apoptosis is much more frequent (approximately 10 times) in the male than in female germ cells, and (2) expression of Bcl-xL, but not that of Bax, is higher in female than in male germ cells, at around E13.5. Male fetal germ cells, cultured with gonadal somatic cells in vitro, showed higher frequencies of apoptosis than those cultured without gonadal somatic cells. On the other hand, in the absence of gonadal somatic cells, both male and female fetal germ cells in vitro showed similar frequencies of apoptosis to female fetal germ cells in vivo. Therefore, male germ cell apoptosis, of which the default pathway is similar to that of the female, is likely to be influenced by male gonadal environments.     

Cytokinesis in plant male meiosis

In somatic cell division, cytokinesis is the final step of the cell cycle and physically divides the mother cytoplasm into two daughter cells. In the meiotic cell division, however, pollen mother cells (PMCs) undergo two successive nuclear divisions without an intervening S-phase and consequently generate four haploid daughter nuclei out of one parental cell. In line with this, the physical separation of meiotic nuclei does not follow the conventional cytokinesis pathway, but instead is mediated by alternative processes, including polar-based phragmoplast outgrowth and RMA-mediated cell wall positioning. In this review, we outline the different cytological mechanisms of cell plate formation operating in different types of PMCs and additionally focus on some important features associated with male meiotic cytokinesis, including cytoskeletal dynamics and callose deposition. We also provide an up-to-date overview of the main molecular actors involved in PMC wall formation and additionally highlight some recent advances on the effect of cold stress on meiotic cytokinesis in plants.     

Vasa and the germ line lineage in a colonial urochordate

Germ cell sequestering in Animalia is enlightened by either, launching true germ line along epigenetic or preformistic modes of development, or by somatic embryogenesis, where no true germ line is set aside. The research on germ line-somatic tissue segregation is of special relevancy to colonial organisms like botryllid ascidians that reconstruct, on a weekly basis, completely new sets of male and female gonads in newly formed somatic tissues. By sequencing and evaluating expression patterns of BS-Vasa, the Botryllus schlosseri orthologue of Vasa, in sexually mature and asexual colonies during blastogenesis, we have demonstrated that the BS-Vasa mRNA and protein are not expressed exclusively in germ cell lineages, but appeared in cells repeatedly emerging de novo in the colony, independently of its sexual state. In addition, we recorded an immediate Vasa response to cellular stress (UV irradiation) indicating additional functions to its germ line assignments. To confirm germ lineage exclusivity, we examined the expression of three more stem cell markers (BS-Pl10, Bl-piwi and Oct4). Vasa co-expression with Pl10 and Oct4 was detected in germ line derivatives and with Bl-piwi in somatic tissues. Presumptive primordial germ cells (PGC-like cells), that are Vasa⁺/Pl10⁺/Oct4⁺ and 6-12 μm in diameter, were first detected in wrapped-tail embryos, in oozooids, in sexual/asexual colonies, within a newly identified PGC niche termed as ‘budlet niche’, and in circulating blood borne cells, indicating epigenetic embryogenesis. Alternatively, BS-Vasa co-expression with piwi orthologue, an omnipresent bona fide stemness flag, in non germ line cell populations, may indicate germ cell neogenesis (somatic embryogenesis) in B. schlosseri. Both alternatives are not necessarily mutually exclusive.     

Controlled X‐chromosome dynamics defines meiotic potential of female mouse in vitro germ cells

The mammalian germline is characterized by extensive epigenetic reprogramming during its development into functional eggs and sperm. Specifically, the epigenome requires resetting before parental marks can be established and transmitted to the next generation. In the female germline, X‐chromosome inactivation and reactivation are among the most prominent epigenetic reprogramming events, yet very little is known about their kinetics and biological function. Here, we investigate X‐inactivation and reactivation dynamics using a tailor‐made in vitro system of primordial germ cell‐like cell (PGCLC) differentiation from mouse embryonic stem cells. We find that X‐inactivation in PGCLCs in vitro and in germ cell‐competent epiblast cells in vivo is moderate compared to somatic cells, and frequently characterized by escaping genes. X‐inactivation is followed by step‐wise X‐reactivation, which is mostly completed during meiotic prophase I. Furthermore, we find that PGCLCs which fail to undergo X‐inactivation or reactivate too rapidly display impaired meiotic potential. Thus, our data reveal fine‐tuned X‐chromosome remodelling as a critical feature of female germ cell development towards meiosis and oogenesis.     

Probing spermatogenesis in Drosophila with P-element enhancer detectors.

Formation of motile sperm in Drosophila melanogaster requires the coordination of processes such as stem cell division, mitotic and meiotic control and structural reorganization of a cell. Proper execution of spermatogenesis entails the differentiation of cells derived from two distinct embryonic lineages, the germ line and the somatic mesoderm. Through an analysis of homozygous viable and fertile enhancer detector lines, we have identified molecular markers for the different cell types present in testes. Some lines label germ cells or somatic cyst cells in a stage-specific manner during their differentiation program. These expression patterns reveal transient identities for the cyst cells that had not been previously recognized by morphological criteria. A marker line labels early stages of male but not female germ cell differentiation and proves useful in the analysis of germ line sex-determination. Other lines label the hub of somatic cells around which germ line stem cells are anchored. By analyzing the fate of the somatic hub in an agametic background, we show that the germ line plays some role in directing its size and its position in the testis. We also describe how marker lines enable us to identify presumptive cells in the embryonic gonadal mesoderm before they give rise to morphologically distinct cell types. Finally, this collection of marker lines will allow the characterization of genes expressed either in the germ line or in the soma during spermatogenesis.     

Histone macroH2A1.2 is concentrated in the XY-body by the early pachytene stage of spermatogenesis

The pairing of sex chromosomes during meiosis in male mammals is associated with ongoing heterochromatinization and X inactivation. This process occurs in a specific area of the nucleus that can be discerned morphologically: the sex vesicle or XY-body. In contrast to X inactivation in the somatic cells of female mammals the reasons for X inactivation in the male germline remain obscure. We have recently demonstrated that the inactive X chromosome in somatic cells of female mammals is marked by a high concentration of histone macroH2A. Here we investigate X inactivation in the meiotic cells of the male germline. We demonstrate here that macroH2A1.2 is present in the nuclei of germ cells starting first with localization that is largely, if not exclusively, to the developing XY-body in early pachytene spermatocytes. Our results suggest that inactivation of sex chromosomes in the male germ cell includes a major alteration of the nucleosomal structure.     

Characterization of male meiotic germ cell-specific antigen (Meg 1) by monoclonal antibody TRA 369 in mice.

We have identified a male meiotic germ cell-specific antigen (Meg 1) with monoclonal antibody (mAb) TRA 369 in mice. The Meg 1 antigen was strongly expressed in specific steps of meiotic germ cells from pachytene spermatocyte to early spermatid, and not in other germ cells or somatic cells. Immunohistochemical examination revealed that the antigen was localized to the cytoplasm and was not distributed in the nucleus or on the cell surface. This antigen was demonstrated to have a molecular weight of 93 kDa and an isoelectric point of 5.2 by Western blotting. This molecule was first detected in the testis of 13-day-old mouse when pachytene spermatocytes first appeared. Thus this is a differentiation-specific antigen in male meiotic germ cells, and mAb TRA 369 is a useful tool to study the regulation of germ cell differentiation and to define germ cell development in a molecular level.     

Mutagen effects on rat seminiferous tubules in vitro: induction of meiotic micronuclei by adriamycin

Mutagen effect on male germ cells can be analyzed by micronucleus induction during meiotic divisions. These can be followed in vitro by culturing seminiferous tubular segments from stages of the epithelial cycle that contain late pachytene and diakinetic primary spermatocytes. We studied the formation of micronuclei in this test system using adriamycin as a model mutagen. Micronuclei were induced in a dose-dependent manner at concentrations of 1-10 ng/ml that were far below the dose that caused morphologically or biochemically detectable cytotoxic effects. The meiotic micronucleus induction in vitro is a potentially sensitive test system of male germ cell mutagenesis.     

Misexpression of cyclin D1 in embryonic germ cells promotes testicular teratoma initiation

Testicular teratomas result from anomalies in embryonic germ cell development. In the 129 family of inbred mouse strains, teratomas arise during the same developmental period that male germ cells normally enter G1/G0 mitotic arrest and female germ cells initiate meiosis (the mitotic:meiotic switch). Dysregulation of this switch associates with teratoma susceptibility and involves three germ cell developmental abnormalities seemingly critical for tumor initiation: delayed G1/G0 mitotic arrest, retention of pluripotency, and misexpression of genes normally restricted to embryonic female and adult male germ cells. One misexpressed gene, cyclin D1 (Ccnd1), is a known regulator of cell cycle progression and an oncogene in many tissues. Here, we investigated whether Ccnd1 misexpression in embryonic germ cells is a determinant of teratoma susceptibility in mice. We found that CCND1 localizes to teratoma-susceptible germ cells that fail to enter G1/G0 arrest during the mitotic:meiotic switch and is the only D-type cyclin misexpressed during this critical developmental time frame. We discovered that Ccnd1 deficiency in teratoma-susceptible mice significantly reduced teratoma incidence and suppressed the germ cell proliferation and pluripotency abnormalities associated with tumor initiation. Importantly, Ccnd1 expression was dispensable for somatic cell development and male germ cell specification and maturation in tumor-susceptible mice, implying that the mechanisms by which Ccnd1 deficiency reduced teratoma incidence were germ cell autonomous and specific to tumorigenesis. We conclude that misexpression of Ccnd1 in male germ cells is a key component of a larger pro-proliferative program that disrupts the mitotic:meiotic switch and predisposes 129 inbred mice to testicular teratocarcinogenesis.     

The symbiotically essential cbb(3)-type oxidase of Bradyrhizobium japonicum is a proton pump

The male germ line stem cell is the only cell type in the adult that can contribute genes to the next generation and is characterized by postnatal proliferation. It has not been determined whether this cell population can be used to deliberately introduce genetic modification into the germ line to generate transgenic animals or whether human somatic cell gene therapy has the potential to accidentally introduce permanent genetic changes into a patient's germ line. Here we report that several techniques can be used to achieve both in vitro and in vivo gene transfer into mouse male germ line stem cells using a retroviral vector. Expression of a retrovirally delivered reporter lacZ transgene in male germ line stem cells and differentiated germ cells persisted in the testis for more than 6 months. At least one in 300 stem cells could be infected. The experiments demonstrate a system to introduce genes directly into the male germ line and also provide a method to address the potential of human somatic cell gene therapy DNA constructs to enter a patient's germ line.