Role for PADI6 in securing the mRNA-MSY2 complex to the oocyte cytoplasmic lattices

The oocyte cytoplasmic lattices (CPLs) have long been predicted to function as a storage form for the maternal contribution of ribosomes to the early embryo. Our previous studies have demonstrated that ribosomal component S6 is stored in the oocyte CPLs and peptidylarginine deiminase 6 (PADI6) is critical for CPLs formation. Additionally, we found that depletion of PADI6 reduced de novo protein synthesis prior to the maternal-to-embryonic transition, therefore causing embryos to arrest at the 2-cell stage. Here, we present evidence further supporting the association of ribosomes with the CPLs by demonstrating that rRNAs are dramatically decreased in Padi6 KO oocytes. We also show that the abundance and localization of mRNAs is affected upon PADI6 depletion, suggesting that mRNAs are very possibly associated with CPLs. Consistent with this observation, the amount of the major RNA binding protein, MSY2, that is associated with the insoluble fraction of the oocytes after Triton X-100 extraction is also markedly decreased in the Padi6 KO oocytes. Furthermore, treatment of the oocytes with RNase A followed by Triton X-100 extraction severely impairs the localization of PADI6 and MSY2 in oocytes. These results indicate that mRNAs, possibly in a complex with MSY2 and PADI6, are bound in the CPLs and may play a role in securing the mRNA-MSY2 complex to the CPLs.     

Potential Role for MATER in Cytoplasmic Lattice Formation in Murine Oocytes

Background

Mater and Padi6 are maternal effect genes that are first expressed during oocyte growth and are required for embryonic development beyond the two-cell stage in the mouse. We have recently found that PADI6 localizes to, and is required for the formation of, abundant fibrillar Triton X-100 (Triton) insoluble structures termed the oocyte cytoplasmic lattices (CPLs). Given their similar expression profiles and mutant mouse phenotypes, we have been testing the hypothesis that MATER also plays a role in CPL formation and/or function.

Methodology/Findings

Herein, we show that PADI6 and MATER co-localize throughout the oocyte cytoplasm following Triton extraction, suggesting that MATER co-localizes with PADI6 at the CPLs. Additionally, the solubility of PADI6 was dramatically increased in Mater^tm/tm oocytes following Triton extraction, suggesting that MATER is involved in CPL nucleation. This prediction is supported by transmission electron microscopic analysis of Mater^+/+ and Mater^tm/tm germinal vesicle stage oocytes which illustrated that volume fraction of CPLs was reduced by 90% in Mater^tm/tm oocytes compared to Mater^+/+ oocytes.

Conclusions

Taken together, these results suggest that, similar to PADI6, MATER is also required for CPL formation. Given that PADI6 and MATER are essential for female fertility, these results not only strengthen the hypothesis that the lattices play a critical role in mediating events during the oocyte-to-embryo transition but also increase our understanding of the molecular nature of the CPLs.     

Subcellular localization of cytoplasmic lattice-associated proteins is dependent upon fixation and processing procedures

We and others have recently demonstrated by immuno-EM and mutation analysis that two oocyte-restricted maternal effect genes, PADI6 and MATER, localize, in part, to the oocyte cytoplasmic lattices (CPLs). During these ongoing studies, however, we found that the localization of these factors by confocal immunofluorescence (IF) analysis can vary dramatically depending upon how the oocytes and embryos are processed, with the localization pattern sometimes appearing more uniformly cytoplasmic while at other times appearing to be primarily cortical. We set out to better understand this differential staining pattern by testing a range of IF protocol parameters, changing mainly time and temperature conditions of the primary antibody solution incubation, as well as fixation methods. We found by confocal IF whole mount analysis that PADI6 and MATER localization in germinal vesicle stage oocytes is mainly cytoplasmic when the oocytes are fixed and then incubated with primary antibodies at room temperature for 1 hour, while the localization of these factors is largely limited to the cortex when the oocytes are fixed and incubated in primary antibody at 4 °C overnight. We then probed sections of fixed/embedded ovaries and isolated two-cell embryos with specific antibodies and found that, under these conditions, PADI6 and MATER were again primarily cytoplasmically localized, although the staining for these factors is slightly more cortical at the two-cell stage. Taken together, our results suggest that the localization of CPL-associated proteins by confocal IF is particularly affected by processing conditions. Further, based on our current observations, it appears that PADI6 and MATER are primarily distributed throughout the cytoplasm as opposed to the oocyte subcortex.     

Mouse oocytes and early embryos express multiple histone H1 subtypes

Oocytes and embryos of many species, including mammals, contain a unique linker (H1) histone, termed H1oo in mammals. It is uncertain, however, whether other H1 histones also contribute to the linker histone complement of these cells. Using immunofluorescence and radiolabeling, we have examined whether histone H10, which frequently accumulates in the chromatin of nondividing cells, and the somatic subtypes of H1 are present in mouse oocytes and early embryos. We report that oocytes and embryos contain mRNA encoding H10. A polymerase chain reaction-based test indicated that the poly(A) tail did not lengthen during meiotic maturation, although it did so beginning at the four-cell stage. Antibodies raised against histone H10 stained the nucleus of wild-type prophase-arrested oocytes but not of mice lacking the H10 gene. Following fertilization, H10 was detected in the nuclei of two-cell embryos and less strongly at the four-cell stage. No signal was detected in H10 -/- embryos. Radiolabeling revealed that species comigrating with the somatic H1 subtypes H1a and H1c were synthesized in maturing oocytes and in one- and two-cell embryos. Beginning at the four-cell stage in both wild-type and H10 -/- embryos, species comigrating with subtypes H1b, H1d, and H1e were additionally synthesized. These results establish that histone H10 constitutes a portion of the linker histone complement in oocytes and early embryos and that changes in the pattern of somatic H1 synthesis occur during early embryonic development. Taken together with previous results, these findings suggest that multiple H1 subtypes are present on oocyte chromatin and that following fertilization changes in the histone H1 complement accompany the establishment of regulated embryonic gene expression.     

SEBOX is essential for early embryogenesis at the two-cell stage in the mouse

Previously, we found high levels of skin-embryo-brain-oocyte homeobox (Sebox) gene expression in germinal vesicle (GV)-stage oocytes. The objective of the present study was to determine the role played by SEBOX in oocyte maturation and early embryogenesis using RNA interference (RNAi). Microinjection of Sebox double-stranded RNA into GV oocytes resulted in a marked decrease in Sebox mRNA and protein expression. However, Sebox RNAi affects neither oocyte maturation rate nor morphological characteristics, including spindle and chromosomal organization of metaphase II oocytes. In addition, Sebox RNAi had no discernible effect on the activities of M-phase promoting factor or mitogen-activated protein kinase. In contrast, microinjection of Sebox double-stranded RNA into pronuclear-stage embryos resulted in holding embryo development at the two-cell (84.9%) and the four- and eight-cell (15.1%) stages. We concluded that Sebox is a new addition to maternal effect genes that produced and stored in oocytes and function in preimplantation embryo development.     

小鼠母源因子对早期胚胎发育的影响

在脊椎动物中发育过程中,卵母细胞要经历MII期停滞、受精、早期胚胎发育的启动、胚胎基因组的转录激活、并指导完成个体的发育过程。同时,核移植过程中,分化的细胞核在去核的卵母细胞中能够重编程到胚胎早期的状态并能完成个体的发育过程。在这些发育过程中母源因子都发挥了极其的重要作用。在小鼠胚胎发育研究中发现,小鼠的基因组激活发生在2细胞期,这一时期标志着合子的发育由卵母细胞控制向胚胎控制的过渡,期间发生一系列复杂的生化过程。体外培养的小鼠的胚胎的发育阻断也易发生的2细胞时期。因此对卵母细胞及早期胚胎母源因子的研究,将有利于了解早期体外培养胚胎和克隆胚胎发育失败的原因,为提高体外培养和克隆胚胎发育的成功率提供理论的基础。     

S6 phosphorylation is regulated at multiple levels in Xenopus laevis oocytes

It is known that the 40s ribosomal protein S6 undergoes a dramatic increase in its level of phosphorylation during Xenopus oocyte meiotic maturation in response to progesterone stimulation. During prophase arrest, the majority of S6 has 0 moles phosphate per mole protein; this increases to 4-5 moles phosphate per mole protein by the time of germinal vesicle breakdown (GVBD). Our in vitro and in vivo studies indicate that the accumulation of phosphate on S6 is the net result of a 4-5-fold increase in S6 kinase activity and a 30-50% decrease in the rate of dephosphorylation and/or turnover of phosphate groups on S6 in maturing oocytes. In addition, the level of phosphorylation of S6 on 80s monosomes injected into non-hormone-stimulated oocytes was unexpectedly high. This indicates that the S6 kinase/phosphatase ratio in prophase arrested oocytes is higher than anticipated from previous studies. This observation implies that the majority of the oocyte ribosomes may be sequestered from any S6 kinase during meiotic prophase. Furthermore, these observations suggest that a portion of the increased accumulation of phosphate on S6 may be the result of increased accessibility of the ribosomes to S6 kinase during oocyte meiotic maturation.     

Program of early development in the mammal: Changes in absolute rates of synthesis of ribosomal proteins during oogenesis and early embryogenesis in the mouse

The absolute rates of synthesis of specific ribosomal proteins have been determined during growth and meiotic maturation of mouse oocytes, as well as during early embryogenesis in the mouse. These measurements were made possible by the development of a high-resolution twodimensional gel electrophoresis procedure capable of resolving basic proteins with isoelectric points between 9.1 and 10.2. Mouse ribosomal proteins were separated on such gels and observed rates of incorporation of [³⁵S]methionine into each of 12 representative ribosomal proteins were converted into absolute rates of synthesis (femtograms or moles synthesized/hour/oocyte or embryo) by using previously determined values for the absolute rates of total protein synthesis in mouse oocytes and embryos (R. M. Schultz, M. J. LaMarca, and P. M. Wassarman, 1978,Proc. Nat. Acad. Sci. USA,75, 4160;R. M. Schultz, G. E. Letourneau, and P. M. Wassarman, 1979,Develop. Biol.,68, 341–359). Ribosomal proteins were synthesized at all stages of oogenesis and early embryogenesis examined and, while equimolar amounts of ribosomal proteins were found in ribosomes, they were always synthesized in nonequimolar amounts during development. Rates of synthesis of individual ribosomal proteins differed from each other by more than an order of magnitude in some cases. Synthesis of ribosomal proteins accounted for 1.5, 1.5, and 1.1% of total protein synthesis during growth of the oocyte, in the fully grown oocyte, and in the unfertilized egg, respectively. During meiotic maturation of mouse oocytes the absolute rate of synthesis of ribosomal proteins decreased about 40%, from 620 to 370 fg/hr/cell, as compared to a 23% decrease in the rate of total protein synthesis during the same period. On the other hand, during early embryogenesis the absolute rates of synthesis of each of the 12 ribosomal proteins examined increased substantially as compared with those of the unfertilized egg, such that at the eight-cell stage of embryogenesis synthesis of ribosomal proteins (4.17 pg/hr/embryo) accounted for about 8.1% of the total protein synthesis in the embryo. Consequently, while the absolute rate of total protein synthesis increased about 1.5-fold during development from an unfertilized mouse egg to an eight-cell compacted embryo, the absolute rate of ribosomal protein synthesis increased more than 11-fold during the same period. These results seem to reflect the differences reported for the patterns of ribosomal RNA synthesis during early development of mammalian, as compared to nonmammalian, animal species. The results are compared with those obtained using oocytes and embryos fromXenopus laevis.     

Embryonic poly(A)-binding protein is differently expressed and interacts with the messenger RNAs in the mouse oocytes and early embryos

The embryonic poly(A)-binding protein (EPAB) functions in the translational regulation of the maternal messenger RNAs (mRNAs) required during oocyte maturation, fertilization, and early embryo development. Since there is no antibody specific to mammalian EPAB protein, all studies related to the Epab gene could be performed at the mRNA levels except for the investigations in the Xenopus. In this study, we have produced an EPAB-specific antibody. When we examined its expressional distribution in the mouse gonadal and somatic tissues, the EPAB protein was found to be expressed only in the mouse ovary and testis tissues, but it is undetectable level in the somatic tissues including stomach, liver, heart, small intestine, and kidney. Additionally, the spatial and temporal expression patterns of the EPAB and poly(A)-binding protein cytoplasmic 1 (PABPC1) proteins were analyzed in the mouse germinal vesicle (GV) and metaphase II (MII) oocytes, one-cell, and two-cell embryos. While EPAB expression gradually decreased from GV oocytes to two-cell embryos, the PABPC1 protein level progressively increased from GV oocytes to one-cell embryos and remarkably declined in the two-cell embryos ( P < 0.05). We have also described herein that the EPAB protein interacted with Epab, Pabpc1, Ccnb1, Gdf9, and Bmp15 mRNAs dependent upon the developmental stages of the mouse oocytes and early embryos. As a result, we have first produced an EPAB-specific antibody and characterized its expression patterns and interacting mRNAs in the mouse oocytes and early embryos. The findings suggest that EPAB in cooperation with PABPC1 implicate in the translational control of maternal mRNAs during oogenesis and early embryo development.     

Stored and polysomal ribosomes of mouse ova

RNP particles of ovulated mouse ova, labeled by exposure of growing oocytes to [³H]uridine, were displayed on sucrose gradients. Under standard salt conditions, radioactivity was observed coinciding with liver ribosomal subunits, monomers, and polysomes. The RNA from each region of the gradient was isolated and was found to contain the expected species of labeled 18S and/or 28S ribosomal RNA. Heterogeneous RNP particles were widely distributed in the gradient. From data on RNase sensitivity and resistance to dissociation in high salt, it was estimated that 20–25% of the total ribosomes were in polysomes. No difference in the distribution was observed when ribosomes were labeled in the early or late growth phase of the oocyte. The evidence suggested that the nonpolysomal subunits and monomers were unable to form a high salt-stable complex in the presence of poly(U) and factors for protein synthesis. Thus, the bulk of the ribosomes are inactive in protein synthesis in ovulated ova and are apparently stored for use in embryonic development.     

Protein-Synthesizing Machinery in the Growing Oocyte of the Cyclic Mouse

A quantitative ultrastructural evaluation of the oocyte ribosomal population was carried out during the oocyte growth, bearing in mind that this period of the mouse oogenesis displays the greatest activity of ribosomal RNA synthesis.
At the onset of growth almost 3/4 of the oocyte ribosomes exist as singles, these become polysomal ribosomes as growth progresses. At the same time the number of ribosomes increases. Once the major growth period has elapsed, the number of ribosomes starts to decrease just when lattice-like structures exhibiting a periodic organization begin to accumulate in the oocyte cytoplasmic matrix.
Evidence, like the particulate organization of these lattices, the size of their particles, its digestion by RNase, and the time of the lattice appearance, together with data reported by several authors, allows one to suggest that near the end of the oocyte growth a great part of the ribosomes are stored in the lattices to be used during early development.     

Phosphorylation-dependent interaction of tyrosine 3-monooxygenase/tryptophan 5-monooxygenase activation protein (YWHA) with PADI6 following oocyte maturation in mice

Proteins in the tyrosine 3-monooxygenase/tryptophan 5-monooxygenase activation protein family (YWHA; also known as 14-3-3) are involved in the regulation of many intracellular processes. We have examined the interaction of YWHA with peptidylarginine deiminase type VI (PADI6), an abundant protein in mammalian oocytes, eggs, and early embryos. Peptidylarginine deiminases catalyze the posttranslational modification of peptidylarginine to citrulline. PADI6 is associated with oocyte cytoplasmic sheets, and PADI6-deficient mice are infertile because of disruption of development beyond the two-cell stage. We found that PADI6 undergoes a dramatic developmental change in phosphorylation during oocyte maturation. This change in phosphorylation is linked to an interaction of PADI6 with YWHA in the mature egg. Recombinant glutathione S-transferase YWHA pull-down experiments and transgenic tandem affinity purification with liquid chromatography-mass spectrometry demonstrate a binding interaction between YWHA and PADI6 in mature eggs. YWHA proteins modulate or complement intracellular events involving phosphorylation-dependent switching or protein modification. These results indicate that phosphorylation and/or YWHA binding may serve as a means of intracellular PADI6 regulation.     

Protein-synthesizing machinery in the growing oocyte of the cyclic mouse. A quantitative electron microscopic study

A quantitative ultrastructural evaluation of the oocyte ribosomal population was carried out during the oocyte growth, bearing in mind that this period of the mouse oogenesis displays the greatest activity of ribosomal RNA synthesis. At the onset of growth almost 3/4 of the oocyte ribosomes exist as singles, these become polysomal ribosomes as growth progresses. At the same time the number of ribosomes increases. Once the major growth period has elapsed, the number of ribosomes starts to decrease just when lattice-like structures exhibiting a periodic organization begin to accumulate in the oocyte cytoplasmic matrix. Evidence, like the particulate organization of these lattices, the size of their particles, its digestion by RNase, and the time of the lattice appearance, together with data reported by several authors, allows one to suggest that near the end of the oocyte growth a great part of the ribosomes are stored in the lattices to be used during early development.     

The role of autophagy during the oocyte-to-embryo transition

After fertilization, the maternal proteins stored in oocytes are degraded and new proteins encoded by the zygotic genome are synthesized. Although several proteins are degraded by the ubiquitin-proteasome system, the mechanism underlying the dynamic protein turnover during this process remains largely unknown. We recently reported that autophagy plays a critical role during preimplantation embryonic development. We found that the level of autophagy was low in unfertilized oocytes; however, autophagy was activated shortly after fertilization. The function of autophagy was further analyzed using oocyte-specific Atg5 (autophagy-related 5) knockout mice. Atg5-null oocytes could develop if they were fertilized with wild-type sperm, but could not develop beyond the four- and eight-cell stages if they were fertilized with Atg5-null sperm. Furthermore, protein synthesis rates were reduced in the autophagy-deficient embryos. We have previously reported that Atg5-null oocytes derived from Atg5+/- mice, which should contain maternally inherited Atg5 protein in the oocyte, were able to produce Atg5-/- neonates, emphasizing the specific importance of autophagy during very early embryogenesis. Thus, the degradation of maternal factors by autophagy is essential for preimplantation development in mammals.

Addendum to: Tsukamoto S, Kuma A, Murakami M, Kishi C, Yamamoto A, Mizushima N. Autophagy is essential for preimplantation development of mouse embryos. Science 2008; 321:117-20.     

The role of autophagy during the oocyte-to-embryo transition

After fertilization, the maternal proteins stored in oocytes are degraded and new proteins encoded by the zygotic genome are synthesized. Although several proteins are degraded by the ubiquitin-proteasome system, the mechanism underlying the dynamic protein turnover during this process remains largely unknown. We recently reported that autophagy plays a critical role during preimplantation embryonic development. We found that the level of autophagy was low in unfertilized oocytes; however, autophagy was activated shortly after fertilization. The function of autophagy was further analyzed using oocyte-specific Atg5 (autophagy-related 5) knockout mice. Atg5-null oocytes could develop if they were fertilized with wild-type sperm, but could not develop beyond the four- and eight-cell stages if they were fertilized with Atg5-null sperm. Furthermore, protein synthesis rates were reduced in the autophagy-deficient embryos. We have previously reported that Atg5-null oocytes derived from Atg5(+/-) mice, which should contain maternally inherited Atg5 protein in the oocyte, were able to produce Atg5(-/-) neonates, emphasizing the specific importance of autophagy during very early embryogenesis. Thus, the degradation of maternal factors by autophagy is essential for preimplantation development in mammals.     

Proteomic profiling of murine oocyte maturation

In an effort to better understand oocyte function, we utilized two-dimensional (2D) electrophoresis and mass spectrometry to identify proteins that are differentially expressed during murine oocyte maturation. Proteins from 500 germinal vesicle (GV) and metaphase II-(MII) arrested oocytes were extracted, resolved on 2D electrophoretic gels, and stained with silver. Analysis of the gels indicated that 12 proteins appeared to be differentially expressed between the GV and MII stage. These proteins were then cored from the 2D gels and identified by mass spectrometry as: transforming acidic coiled-coil protein 3 (TACC3), heat shock protein 105 (HSP105), programmed cell death six-interacting protein (PDCD6IP), stress-inducible phosphoprotein (STI1), importin alpha2, adenylsuccinate synthase (ADDS), nudix, spindlin, lipocalin, lysozyme, translationally controlled tumor protein (TCTP), and nucleoplasmin 2 (NPM2). Interestingly, PDCD6IP, importin alpha2, spindlin, and NPM2 appear slightly larger in mass and more acidic on the MII oocyte gel compared to the GV oocyte gel, suggesting that they may be post-translationally modified during oocyte maturation. Given NPM2 is an oocyte-restricted protein, we chose to further investigate its properties during oocyte maturation and preimplantation development. Real-Time RT-PCR showed that NPM2 mRNA levels rapidly decline at fertilization. Indirect immunofluorescence analysis showed that, with the exception of cortical localization in MII-arrested oocytes, NPM2 is localized to the nucleus of both GV stage oocytes and all stages of preimplantation embryos. We then performed one-dimensional (1D) western blot analysis of mouse oocytes and preimplantation embryos and found that, as implicated by the 2D gel comparison, NPM2 undergoes a phosphatase-sensitive electrophoretic mobility shift during the GV to MII transition. The slower migrating NPM2 form is also present in pronuclear embryos but by the two-cell stage, the majority of NPM2 exists as the faster migrating form, which persists to the blastocyst stage.     

Quantification of cyclin B1 and p34(cdc2) in bovine cumulus-oocyte complexes and expression mapping of genes involved in the cell cycle by complementary DNA macroarrays

Although high amounts of cyclin B1 mRNA are present in bovine oocytes arrested at the germinal vesicle (GV) stage, the protein is not detectable. Furthermore, there is a depletion of the stored cyclin B1 mRNA in the oocyte as follicular growth progresses. To assess the effect of follicular growth on the accumulation of M-phase promoting factor (MPF) components, mRNA and protein levels of cyclin B1 and p34(cdc2) were measured in GV oocytes collected from diverse follicle size groups (<2 mm, 3-5 mm, and >6 mm). Because oocytes collected from very small follicles have high levels of cyclin B1 mRNA, the onset of its accumulation in the oocytes was evaluated by in situ hybridization of fetal ovaries. Also, a comparative expression map of cell cycle-related genes expressed in the oocyte and cumulus cells was established using nylon-based cDNA arrays, which allowed the detection of 35 different genes transcribed mostly in oocytes. Both components of the pre-MPF complex were expressed at the mRNA level in GV oocytes, whereas p34(cdc2) was the only pre-MPF protein detected at that stage, thus indicating that meiosis resumption in bovine oocytes is differentially regulated as compared with other mammals, and meiosis resumption seems to be regulated by the translation of cyclin B1 mRNA.     

Changes in zinc,copper and metallothionein contents during oocyte growth and early development of the teleost Danio rerio (zebrafish)

In the present report, we investigated zinc, copper and metallothionein (MT) contents in zebrafish oocytes and embryos. Our results demonstrate that the metal content increases during oocytes maturation. Zinc increases from 30 ng/oocyte (stage-1 oocytes) to 100 ng/oocyte (stage-3 oocytes); copper varied from 1 ng/oocyte (stage-1 oocytes) to 3.5 ng/oocyte (stage-3 oocytes). During embryogenesis, zinc and copper contents dramatically increase after fertilisation around the 512-cells stage, then slowly decrease until the mid-gastrula stage. During oocyte growth, the changes in the MT level are proportional to metal content, whereas during embryogenesis the pattern of MT accumulation does not parallel that of the two metals. Indeed, the maternal pool of MT decreases steadily during the early stages of the development until the gastrula stage. We have examined the effect of cadmium on the expression of MT during zebrafish development. After cadmium exposure, MT content increases in embryos at the blastula stage, whereas no induction occurs in embryos at the gastrula stage. However, pre-treatment of embryos at the gastrula stage with 5-aza-2'-deoxycytidine induces MT synthesis following exposure to cadmium. These observations show that changes in metal levels are not correlated to MT content in the embryo, whereas DNA methylation is one of the factors regulating MT expression.