RSPO1/β-catenin signaling pathway regulates oogonia differentiation and entry into meiosis in the mouse fetal ovary

Differentiation of germ cells into male gonocytes or female oocytes is a central event in sexual reproduction. Proliferation and differentiation of fetal germ cells depend on the sex of the embryo. In male mouse embryos, germ cell proliferation is regulated by the RNA helicase Mouse Vasa homolog gene and factors synthesized by the somatic Sertoli cells promote gonocyte differentiation. In the female, ovarian differentiation requires activation of the WNT/β-catenin signaling pathway in the somatic cells by the secreted protein RSPO1. Using mouse models, we now show that Rspo1 also activates the WNT/β-catenin signaling pathway in germ cells. In XX Rspo1(-/-) gonads, germ cell proliferation, expression of the early meiotic marker Stra8, and entry into meiosis are all impaired. In these gonads, impaired entry into meiosis and germ cell sex reversal occur prior to detectable Sertoli cell differentiation, suggesting that β-catenin signaling acts within the germ cells to promote oogonial differentiation and entry into meiosis. Our results demonstrate that RSPO1/β-catenin signaling is involved in meiosis in fetal germ cells and contributes to the cellular decision of germ cells to differentiate into oocyte or sperm.     

Nutritional regulation of late meiotic events in Saccharomyces cerevisiae through a pathway distinct from initiation.

The IME1 gene is essential for initiation of meiosis in the yeast Saccharomyces cerevisiae, although it is not required for growth. Here we report that in stationary-phase cultures containing low concentration of glucose, cells overexpressing IME1 undergo the early meiotic events, including DNA replication, commitment to recombination, and synaptonemal complex formation and dissolution. In contrast, later meiotic events, such as chromosome segregation, commitment to meiosis, and spore formation, do not occur. Thus, nutrients can repress the late stages of meiosis independently of their block of initiation. Cells arrested at this midpoint in meiosis are relatively stable and can resume meiotic differentiation if transferred to sporulation conditions. Resumption of meiosis does not require repression of IME1 expression, since IME1 RNA levels stay high after transfer of the arrested cells to sporulation medium. These results suggest that meiosis in S. cerevisiae is a paradigm of a differentiation pathway regulated by signal transduction at both early and late stages.     

Meiotic chromosome missegregation during apyrene meiosis in the gypsy moth,Lymantria dispar,is preceded by an aberrant prophase I

The gypsy moth, Lymantria dispar, produces two structurally and genetically distinct types of spermatozoa. The eupyrene spermatozoa are genetically haploid and structurally typical. The apyrene spermatozoa are anucleate and structurally different from eupyrene spermatozoa. To understand further the events contributing to meiotic chromosome missegregation in apyrene spermatocytes, we examined the progression of meiosis in these cells with respect to their eupyrene counterparts. Chromosomal bouquet formation and fusion of nucleolar organizing regions are disrupted in apyrene nuclei. In addition, the chromatin of apyrene nuclei is prematurely and extremely condensed compared with that of eupyrene nuclei. An antibody to the conserved synaptonemal complex protein 3 (SCP3) labeled eupyrene pachytene chromosomes, but not apyrene pachytene chromosomes. In addition, apyrene meiotic spindles are missing a subset of microtubules, which likely include kinetochore microtubules. Because the condensation behavior of meiotic chromatin in apyrene spermatocytes deviates from that of eupyrene spermatocytes, we examined the appearance and distribution of the phosphorylated form of histone H3, but no significant differences in histone H3 phosphorylation were found between apyrene and eupyrene spermatocytes. We argue that because a pachytene checkpoint is not initiated in apyrene spermatocytes, this system may provide a way to understand better the underlying biochemical connections between pairing, recombination, synapsis, kinetochore assembly and segregation of chromosomes during meiosis in a higher eukaryote.     

HORMONAL CONTROL OF OOCYTE MATURATION IN ARENICOLA MARINA L. (ANNELIDA, POLYCHAETA) II. MATURATION AND FERTILIZATION

In Arenicola marina (Annelida, Polychacta) the oocytes arc arrested in the first prophase stage of meiosis until spawning. Oocyte maturation is under hormonal control: when incubated in vitro in a brain extract oocytes proceed to the first metaphase at which they remain arrested until fertilization. The prophase arrested oocytes can neither be fertilized nor parthcnogenetically activated by ionophore A23187 or 1 M glycerol. On the contrary the metaphase-arrested oocytes can be fertilized and parthenogenetically activated. Fertilizability thus appears during maturation; it seems to be linked to microvilli retraction. A study of spermatozoa "capacitation" and oocyte fertilization or activation is reported. A scanning electron microscope study of early contact and penetration of spermatozoa is presented.     

The Arabidopsis-mei2-like genes play a role in meiosis and vegetative growth in Arabidopsis

The Arabidopsis-mei2-Like (AML) genes comprise a five-member gene family related to the mei2 gene, which is a master regulator of meiosis in Schizosaccharomyces pombe and encodes an RNA binding protein. We have analyzed the AML genes to assess their role in plant meiosis and development. All five AML genes were expressed in both vegetative and reproductive tissues. Analysis of AML1-AML5 expression at the cellular level indicated a closely similar expression pattern. In the inflorescence, expression was concentrated in the shoot apical meristem, young buds, and reproductive organ primordia. Within the reproductive organs, strong expression was observed in meiocytes and developing gametes. Functional analysis using RNA interference (RNAi) and combinations of insertion alleles revealed a role for the AML genes in meiosis, with RNAi lines and specific multiple mutant combinations displaying sterility and a range of defects in meiotic chromosome behavior. Defects in seedling growth were also observed at low penetrance. These results indicate that the AML genes play a role in meiosis as well as in vegetative growth and reveal conservation in the genetic mechanisms controlling meiosis in yeast and plants.     

C. elegans CPB-3 interacts with DAZ-1 and functions in multiple steps of germline development

Cytoplasmic polyadenylation element-binding proteins (CPEBs) are well-conserved RNA-binding proteins, which regulate mRNA translation mainly through control of poly(A) elongation. Here, we show that CPB-3, one of the four CPEB homologs in C. elegans, positively regulates multiple aspects of oocyte production. CPB-3 protein was highly expressed in early meiotic regions of the hermaphrodite gonad. Worms deficient in cpb-3 were apparently impaired in germ cell proliferation and differentiation including sperm/oocyte switching and progression of female meiosis. We also show that cpb-3 is likely to promote the meiotic entry in parallel with gld-3, a component of one of the redundant but essential genetic pathways for the entry to and progression through meiosis. Taken together, CPEB appears to have a conserved role in the early phase of meiosis and in the sperm/oocyte specification, in addition to its reported function during meiotic progression.     

The Caenorhabditis elegans SCC-3 homologue is required for meiotic synapsis and for proper chromosome disjunction in mitosis and meiosis

The product of the Caenorhabditis elegans ORF F18E2.3 is homologous to the cohesin component Scc3p. By antibody staining the product of F18E2.3 is found in interphase and early meiotic nuclei. At pachytene it localizes to the axes of meiotic chromosomes but is no longer detectable on chromatin later in meiosis or in mitoses. Depletion of the gene product by RNAi results in aberrant mitoses and meioses. In meiosis, homologous pairing is defective during early meiotic prophase and at diakinesis there occur univalents consisting of loosely connected sister chromatids or completely separated sisters. The recombination protein RAD-51 accumulates in nuclear foci at higher numbers during meiotic prophase and disappears later than in wild-type worms, suggesting a defect in the repair of meiotic double-stranded DNA breaks. Embryos showing nuclei of variable size and anaphase bridges, indicative of mitotic segregation defects, are frequently observed. In the most severely affected gonads, nuclear morphology cannot be related to any specific stage. The cytological localization and the consequences of the lack of the protein indicate that C. elegans SCC-3 is essential for sister chromatid cohesion both in mitosis and in meiosis.     

HORMONAL CONTROL OF OOCYTE MATURATION IN ARENICOLA MARINA L. (ANNELIDA, POLYCHAETA) I. MORPHOLOGICAL STUDY OF OOCYTE MATURATION

In Arenicola marina (Annelida, Polychaeta) the oocytes are arrested in the first prophase stage of mciosis until spawning. Oocyte maturation is under hormonal control: when incubated in vitro in a brain extract oocytes reach the first metaphase at which they remain arrested until fertilization. The meiosis reinitiating substance induces numerous morphological changes in the oocytes: general (shape), cortical (microvilli retraction, plasma membrane flattening), cytoplasmic (cortical granules repartition) and nuclear modifications (germinal vesicle breakdown, chromosome condensation, formation of a meiotic maturation spindle). A kinetic study of these morphological modifications has been performed.     

Effects of spermatozoa during in vitro meiosis progression in the porcine germinal vesicle oocytes

We have investigated the effect of co-culture with porcine spermatozoa on in vitro maturation of porcine germinal vesicle (GV) oocytes before fertilization. Most oocytes were arrested at the first prophase of meiosis when oocytes were cultured in TCM 199 alone, but the proportion of oocytes that reached metaphase II was significantly elevated by co-incubation with spermatozoa in vitro. The oocyte maturation effect was observed with intact and parts of spermatozoa (head and tail) collected from adult swine (regardless of source). However, gonocytes from the newborn porcine testis were not able to enhance in vitro maturation of porcine germinal vesicle oocytes. Interestingly, the oocyte maturation effect by spermatozoa was not decreased with heat treatment, but the maturation effect of oocyte treatment disappeared with exposure to detergent in sperm suspension. Porcine spermatozoa were also observed to stimulate meiosis of oocytes, which was maintained at meiotic arrest using dibutyryl cyclic AMP or forskolin. The study suggests that (i) membrane of porcine spermatozoa contains a substance(s) that can enhance in vitro maturation of oocytes prior to fertilization, (ii) the putative meiosis-enhancing substance(s) of spermatozoa from adult testes retains the oocyte maturation effect during transportation of spermatozoa through epididymis, and (iii) the putative meiosis-enhancing substance(s) is able to overcome the inhibitory effect of dibutyryl cyclic AMP or forskolin by inducing germinal vesicle breakdown of porcine cumulus-oocyte complexes maintained in meiotic arrest.     

Trichinella spiralis: behavior, structure, and biochemistry of larvae following exposure to components of the host enteric environment

Four layers are present on the surface of infective larvae of Trichinella spiralis isolated from host muscle in pepsin-HCl. Trypsin treatment of pepsin-HCl isolated worms caused partial degradation and removal of large patches of the two outer surface layers. Following exposure to bile, only traces of the outer layers remained on the worms surface. These changes in the worm surface were accompanied by a shift from Type I behavior, typical of pepsin-HCl isolated larvae, to Type II behavior, (snakelike) following exposure to either trypsin or bile. Worm behavior was also temperature dependent. Type I behavior was typical of worms maintained at room temperature regardless of treatment, while Type II behavior displayed by worms held at 37 C was treatment dependent. The absorption of in vitro glucose or beta-methyl-D-glucoside was lowest in pepsin-HCl isolated first stage infective larvae, significantly higher in trypsin treated worms and greatest in worms following exposure to bile. Sugar uptake by worms isolated from the host small intestine after 1 hr of enteral infection was similar to that seen in worms isolated from host muscle in pepsin-HCl. Sugar uptake in vitro in worms 2 hr following enteral infection was similar to worms following exposure to bile. The highest levels of sugar absorption in vitro occurred in worms which had resided in the small intestine for 3 hr. The lowest rates of incorporation of label into worm tissues was seen in 1 hr enteral and pepsin-HCl isolated worms. Infective larvae treated with trypsin or bile incorporated significantly greater amounts of label than the two former groups. The highest levels of incorporation of label into worm tissues was seen in 3 hr enteral worms. These findings support the view that trypsin, bile, and temperature serve as environmental cues which lead to alteration of the parasite's behavioral and nutritional status.     

Oocyte-specific expression of Gpr3 is required for the maintenance of meiotic arrest in mouse oocytes

The maintenance of meiotic prophase arrest in mouse oocytes within fully grown follicles, prior to the surge of luteinizing hormone (LH) that triggers meiotic resumption, depends on a high level of cAMP within the oocyte. cAMP is produced within the oocyte, at least in large part, by the G(s)-linked G-protein-coupled receptor, GPR3. Gpr3 is localized in the mouse oocyte but is also present throughout the follicle. To investigate whether Gpr3 in the follicle cells contributes to the maintenance of meiotic arrest, RNA interference (RNAi) was used to reduce the amount of Gpr3 RNA within follicle-enclosed oocytes. Follicle-enclosed oocytes injected with small interfering double-stranded RNA (siRNA) targeting Gpr3, but not control siRNAs, stimulated the resumption of meiosis in the majority of oocytes following a 3-day culture period. Reduction of RNA was specific for Gpr3 because an unrelated gene was not reduced by microinjection of siRNA. Meiotic resumption was stimulated in isolated oocytes injected with the same siRNA and cultured for 1 to 2 days, but at a much lower rate than in follicle-enclosed oocytes that could be cultured for longer. These results demonstrate that GPR3 specifically in the oocyte, rather than in the follicle cells, is responsible for maintenance of meiotic arrest in mouse oocytes. Furthermore, the method developed here for specifically reducing RNA in follicle-enclosed oocytes, which can be cultured for a sufficient time to reduce the level of endogenous protein, should be generally useful for targeting a wide range of other proteins that may be involved in meiotic arrest, the resumption of meiosis, fertilization, or early embryonic development.     

Reducing CYP51 inhibits follicle-stimulating hormone induced resumption of mouse oocyte meiosis in vitro

Meiosis activating sterol, produced directly by lanosterol 14-α-demethylase (CYP51) during cholesterol biosynthesis, has been shown to promote the initiation of oocyte meiosis. However, the physiological significance of CYP51 action on oocyte meiosis in response to gonadotrophins’ induction remained to be further explored. Herein, we analyzed the role of CYP51 in gonadotrophin-induced in vitro oocyte maturation via RNA interference (RNAi). We showed that although both luteinizing hormone (LH) and follicle-stimulating hormone (FSH) significantly induced meiotic resumption in follicle-enclosed oocytes (FEOs), the effect of LH on oocyte meiosis resumption in FEOs was weaker than FSH. Moreover, both FSH and LH were able to upregulate CYP51 expression in cultured follicular granulosa cells when examined at 8 h or 12 h posttreatments, respectively. Interestingly, whereas knockdown of CYP51 expression via small interference RNA (siRNA) moderately blocked (23% reduction at 24 h) FSH-induced oocyte maturation [43% germinal vesicle breakdown (GVBD) rate in RNAi vs. 66% in control, P < 0.05] in FEOs, similar treatments showed no apparent effects on LH-induced FEO meiotic maturation (58% GVBD rate in RNAi vs. 63% in control, P > 0.05). Moreover, the results in a cumulus-enclosed oocytes (CEOs) model showed that approximately 30% of FSH-induced CEOs’ meiotic resumption was blocked upon CYP51 knockdown by siRNAs. These findings suggest that FSH, partially at least, employs CYP51, and therefore the MAS pathway, to initiate oocyte meiosis.     

Syntheses of nucleic acids during spermatogenesis in Nereis diversicolor (annelida polychaeta): a quantitative autoradiographic study

The development of DNA and RNA synthesis in the germ cell population was studied after a 3H-thymidine or 3H-uridine pulse at each stage of spermatogenesis. The autoradiographic results show that the first sign (after 3 days in vitro) of cellular changes is an increase in RNA synthesis which reaches a maximum at day 5. DNA replication (premeiotic S phase) occurred at day 7, then cells entered meiotic prophase (day 9). Meiotic divisions and spermiogenesis occurred after 11 days. Silver grain counts permit the conclusion that RNA synthesis is clearly higher during premeiotic interphase (days 3-7) than during spermatogonial proliferation (day 0). It appears therefore that male meiotic differentiation in Nereidae is accompanied by increased RNA synthesis.     

Differentiation of mouse primordial germ cells into female or male germ cells.

Mouse primordial germ cells (PGCs) migrate from the base of the allantois to the genital ridge. They proliferate both during migration and after their arrival, until initiation of the sex-differentiation of fetal gonads. Then, PGCs enter into the prophase of the first meiotic division in the ovary to become oocytes, while those in the testis become mitotically arrested to become prospermatogonia. Growth regulation of mouse PGCs has been studied by culturing them on feeder cells. They show a limited period of proliferation in vitro and go into growth arrest, which is in good correlation with their developmental changes in vivo. However, in the presence of multiple growth signals, PGCs can restart rapid proliferation and transform into pluripotent embryonic germ (EG) cells. Observation of ectopic germ cells and studies of reaggregate cultures suggested that both male and female PGCs show cell-autonomous entry into meiosis and differentiation into oocytes if they were set apart from the male gonadal environments. Recently, we developed a two-dimensional dispersed culture system in which we can examine transition from the mitotic PGCs into the leptotene stage of the first meiotic division. Such entry into meiosis seems to be programmed in PGCs before reaching the genital ridges and unless it is inhibited by putative signals from the testicular somatic cells.     

Hormonal regulation of spermatogenesis and spermiogenesis

Normal testicular function is dependent upon hormones acting through endocrine and paracrine pathways both in vivo and in vitro. Sertoli cells provide factors necessary for the successful progression of spermatogonia into spermatozoa. Sertoli cells have receptors for follicle stimulating hormone (FSH) and testosterone which are the main hormonal regulators of spermatogenesis. Hormones such as testosterone, FSH and luteinizing hormone (LH) are known to influence the germ cell fate. Their removal induces germ cell apoptosis. Proteins of the Bcl-2 family provide one signaling pathway which appears to be essential for male germ cell homeostasis. In addition to paracrine signals, germ cells also depend upon signals derived from Sertoli by direct membrane contact. Somatostatin is a regulatory peptide playing a role in the regulation of the proliferation of the male gametes. Activin A, follistatin and FSH play a role in germ cell maturation during the period when gonocytes resume mitosis to form the spermatogonial stem cells and differentiating germ cell populations. In vitro cultures systems have provided evidence that spermatogonia in advance stage of differentiation have specific regulatory mechanisms that control their fate. This review article provides an overview of the literature concerning the hormonal pathways regulating spermatogenesis.     

同一居群韭莲不同植株减数分裂行为差异的遗传分析

对韭莲(2n=48)小孢子母细胞减数分裂及小孢子发育进行研究。结果显示同一居群植株的减数分裂行为存在明显差异。多数韭莲植株小孢子母细胞减数分裂存在少量落后染色体、微核等现象,平均每株中具有异常分离行为的母细胞占14.02%,小孢子发育正常,但花粉无活力。并首次从减数分裂后期Ⅰ的特殊的细胞学形态证明韭莲是臂内倒位杂合体。而少数植株韭莲的小孢子母细胞减数分裂极其紊乱,后期Ⅰ出现多极分离、大量落后染色体,小孢子母细胞减数分裂总异常分离高达94.3%。四分孢子期多分孢子体高达73.4%。分析认为:前者减数分裂行为异常的原因主要由染色体结构变异所致,而后者的原因除染色体结构变异外,还可能与控制纺锤体形成的基因突变有关。     

哺乳动物精子发生中减数分裂的起始

生殖细胞的发生、增殖和分化是生命科学领域研究的重要课题之一. 生殖是所有动物赖以生存的基础,精子发生是完成繁殖所必须经历的过程,其最终目的是源源不断地产生单倍体精子.精子发生过程本身是一个复杂特殊的细胞增殖与分化过程,其中减数分裂是精子发生最重要的步骤,但关于减数分裂如何精确起始的分子机制仍知之甚少.已有报道发现,维甲酸（RA）调控Stra8可能是哺乳动物减数分裂起始的机制之一,Nanos2、Boule对RA-Stra8通路具有重要的调控作用. 本文对哺乳动物精子发生中减数分裂起始的相关研究进展进行综述.