Quantitative changes in total RNA, total poly(A), and ribosomes in early mouse embryos

To obtain information on the amounts and major classes of RNA stored in the mouse egg and accumulated during cleavage, we determined the contents of total RNA, total poly(A), and ribosomes from the 1-cell stage to blastocyst. Using purified RNA for assay, we obtained an RNA content of 0.35 ng in the unfertilized egg, 0.24 ng in 2-cell, 0.69 ng in 8- to 16-cell, and 1.47 ng in early bastocyst (32 cells). As derived from EM morphometry, the number of ribosomes accounts for 60–70% of the total RNA content at all these stages; the marked increase in ribosomal number during cleavage is attributable entirely to new synthesis. Hybridization with [³H]poly(U) in solution yielded a poly(A) content of 0.7 pg for the unfertilized egg and 0.83 pg for the 1-cell embryo. The poly(A) content dropped sharply, to 0.26 pg per embryo, by the late 2-cell stage and increased to 0.44 pg in 8- to 16-cell embryos and 1.42 pg in early blastocysts. Hybridization in situ gave a similar pattern and also revealed a heavy labeling of embryo nuclei from the 2-cell onward but very little, if any, labeling of the pronuclei of 1-cell embryos, suggesting an absence, or low level, of poly(A)+ RNA synthesis at the 1-cell but an active synthesis at the 2-cell and later stages. These findings and other available evidence(e.g., R. Bachvarova and V. De Leon, 1980, Develop. Biol.74, 1–8) suggest that the mouse embryo inherits a large supply of maternal mRNA but that the bulk of this RNA is eliminated in the 2-cell embryo. In situ hybridization was used to study the relative concentration of poly(A) in ovarian oocytes. In growing oocytes, the cytoplasmic concentration of poly(A) remains about the same, suggesting that the accumulation of poly(A)+ RNA is proportional to oocyte growth. The poly(A) content declines about twofold between the time of completion of oocyte growth and fertilization. The germinal vesicle continues to be labeled up to the time of ovulation, raising the possibility that poly(A)+ RNA synthesis (and presumably turnover) occurs in fully grown oocytes.     

Postfertilization Poly(A) · Protein Complex Formation on Sea Urchin Maternal Messenger RNA

A two-fold increase in polyadenylate [poly(A)] content occurs between fertilization and the two-cell stage in sea urchin zygotes. In this report the role of this cytoplasmic polyadenylation process in the provision of binding sites for poly(A)-associated proteins during early development of Lytechinus pictus is evaluated. Protein-associated poly(A) sequences, from ribonuclease-treated, post-mitochondrial supernatants of various developmental stages, were collected by nitrocellulose filtration and quantified by ³H-poly(U) complex formation. The proportion of protein-associated poly(A) rose from about 27% to about 60% of the total poly(A), on a nucleotide basis, during the period between fertilization and the eight-cell stage. However, the actual increase in number of poly(A) sequences associated with protein was more extensive, about 2.5-fold, since protein-associated poly(A) sequences average about 45 nucleotides longer than free poly(A). The protein-associated poly(A) of eggs and zygotes is found in two types of protease-sensitive complexes which sediment at 8–12 S and 15–20 S. The 8–12 S complex appears to be selectively increased in amount following fertilization. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of the poly(A) protein complex fraction indicates the presence of 87,000 and 130,000 molecular weight polypeptides in both eggs and zygotes. It is concluded that quantitative, but not qualitative, alterations in the proportion of protein-associated poly(A) accompanies post-fertilization cytoplasmic polyadenylation in sea urchin zygotes. The attachment of specific proteins to the 3'terminus of maternal RNAs may be involved in their subsequent activities during early embryogenesis.     

Multiple sequence elements and a maternal mRNA product control cdk2 RNA polyadenylation and translation during early Xenopus development.

Cytoplasmic poly(A) elongation is one mechanism that regulates translational recruitment of maternal mRNA in early development. In Xenopus laevis, poly(A) elongation is controlled by two cis elements in the 3' untranslated regions of responsive mRNAs: the hexanucleotide AAUAAA and a U-rich structure with the general sequence UUUUUAAU, which is referred to as the cytoplasmic polyadenylation element (CPE). B4 RNA, which contains these sequences, is polyadenylated during oocyte maturation and maintains a poly(A) tail in early embryos. However, cdk2 RNA, which also contains these sequences, is polyadenylated during maturation but deadenylated after fertilization. This suggests that cis-acting elements in cdk2 RNA signal the removal of the poly(A) tail at this time. By using poly(A) RNA-injected eggs, we showed that two elements which reside 5' of the CPE and 3' of the hexanucleotide act synergistically to promote embryonic deadenylation of this RNA. When an identical RNA lacking a poly(A) tail was injected, these sequences also prevented poly(A) addition. When fused to CAT RNA, the cdk2 3' untranslated region, which contains these elements, as well as the CPE and the hexanucleotide, promoted poly(A) addition and enhanced chloramphenicol acetyltransferase activity during maturation, as well as repression of these events after fertilization. Incubation of fertilized eggs with cycloheximide prevented the embryonic inhibition of cdk2 RNA polyadenylation but did not affect the robust polyadenylation of B4 RNA. This suggests that a maternal mRNA, whose translation occurs only after fertilization, is necessary for the cdk2 deadenylation or inhibition of RNA polyadenylation. This was further suggested when poly(A)+ RNA isolated from two-cell embryos was injected into oocytes that were then allowed to mature. Such oocytes became deficient for cdk2 RNA polyadenylation but remained proficient for B4 RNA polyadenylation. These data show that CPE function is developmentally regulated by multiple sequences and factors.     

Nuclear penetration and stimulation of nucleic acids synthesis by poly(A)-poly(U) in mammalian cells

The rapid penetration of poly(A)-poly(U) into cell nuclei is shown by radioautography, by recovery of acid-precipitable material from isolated nuclei and by sucrose gradient centrifugation of nuclear lysates. The majority of poly(A)-poly(U) remains intact in the nuclei for at least h. This penetration is increased 20-fold by pretreatment of the cells with DEAE Dextran. In cells treated with DEAE Dextran, DNA and RNA syntheses are stimulated by poly(A)-poly(U) from the time the polymer complex is added and for at least h.     

U2 small nuclear RNA localization and expression during bovine preimplantation development.

This study describes the localization of the U2 small nuclear RNA (snRNA) and the major U snRNA group ribonucleoproteins (snRNPs) during bovine preimplantation development. In vitro maturation, fertilization, and oviductal epithelial cell coculture methods were employed to produce several developmental series totalling over 2,000 preimplantation-stage bovine oocytes and embryos. These oocytes and preimplantation embryos were processed for in situ hybridization, immunofluorescence and Northern blotting methods. The U2 snRNA and the major U group snRNPS were localized initially over the germinal vesicle (GV) of preovulatory oocytes but following GV breakdown were released throughout the ooplasm. They subsequently reassociated with both pronuclei during fertilization. From the two-cell to the blastocyst stages, the U2 snRNA and U snRNPs were localized to the interphase nucleus of each blastomere. The levels of U2 snRNA throughout bovine preimplantation development were determined by probing a Northern blot containing total RNA isolated from the following preimplantation bovine embryo stages: one to two cell, eight to 16 cell, early morula (greater than 32 cell), and late morula/early blastocysts. The levels of U2 snRNA remained constant between the one-cell and eight- to 16-cell bovine embryo stages but increased 4.4-fold between the eight- to 16-cell stage and the late morula/early blastocyst stages. The results suggest that a maternal pool of snRNAs is maintained in mammalian preimplantation embryos regardless of the duration of maternal control of development.     

Poly(A) length,cytoplasmic adenylation and synthesis of poly(A)+ RNA in early mouse embryos

The poly(A) content of early mouse embryos fluctuates widely: after a transient increase in the one-cell embryo, there is a 70% drop in the two-cell and an approximately fivefold increase between the two-cell and early blastocyst stages (L. Pikó and K. B. Clegg, 1982, Dev. Biol.89, 362–378). To shed light on the significance of these changes, we analyzed the size distribution of total poly(A) from embryos at different stages of development by gel electrophoresis and hybridization with [³H]poly(U). The number-average size of poly(A) tracts varies only slightly, from 61 to 77 nucleotides, indicating that the changes in poly(A) content are due primarily to changes in the number of poly(A) sequences, i.e., the number of poly(A)+ mRNA. From these data, the number of poly(A)+ mRNA can be estimated as follows: ovulated egg, 1.7 × 10⁷; one-cell embryo, 2.4 × 10⁷; late two-cell, 0.7 × 10⁷; late eight-cell, 1.3 × 10⁷; and early blastocyst, 3.4 × 10⁷. These results suggest the elimination of the bulk of maternal poly(A)+ mRNA at the two-cell stage, to be replaced by newly synthesized mRNA derived from the embryonic genome. To study the synthesis of poly(A)+ mRNA, we cultured mouse embryos in vitro with [³H]adenosine and analyzed the labeled poly(A)+ RNA as to molecular size, length of the poly(A) tail, and relative distribution of label in poly(A) vs internal locations. We observed an active incorporation of label into large-molecular-weight (average size about 2 kb) poly(A)+ RNA at all stages from the one-cell to the blastocyst. However, in the one-cell embryo, about 70% of the label was localized in the poly(A) tail, suggesting cytoplasmic polyadenylation, and only about 30% was localized in the remainder of the molecule, suggesting the complete new synthesis of a small amount of poly(A)+ RNA. Differences in the size distribution of the labeled poly(A) as compared with the total poly(A) in the one-cell embryo indicate that the labeling is not due to a general turnover of poly(A) tails, but rather to the polyadenylation of previously nonpolyadenylated, stored RNA. Significant new synthesis of poly(A)+ RNA is evident from the two-cell stage onward and most likely accounts for the sharp rise in the number of poly(A)+ RNA molecules by the early blastocyst stage.     

Differential accumulation and localization of maternal poly(A)-containing RNA during early development of the ascidian,Styela

The regional distribution of poly(A)⁺ RNA was examined in sections of Styela oocytes and fertilized eggs by in situ hybridization with [³H]poly(U). The nucleus and cytoplasm of previtellogenic oocytes contain equivalent densities of [³H]poly(U) binding sites. The concentration of these sites is reduced in the cytoplasm, but not the nucleus, during vitellogenesis. Consequently, the germinal vesicle (GV) plasm of mature oocytes is characterized by an eightfold elevation in [³H]poly(U) binding activity relative to the surrounding cytoplasm. The distinctive cytoplasmic regions of the mature oocyte do not exhibit differential concentrations of [³H]poly(U) binding sites. Following fertilization which triggers GV breakdown, meiosis, and ooplasmic segregation, the high density of [³H]poly(U) binding sites characteristic of the GV plasm is conserved in the basophilic cytoplasm during its extensive migration and eventual accumulation in the animal hemisphere of the egg. The insensitivity of the [³H]poly(U) binding sites of the basophilic cytoplasm to actinomycin D suggests that they are of maternal origin. It is concluded that maternal poly(A)⁺ RNA is subject to differential accumulation in the GV plasm and its derivative ooplasm during the early development of Styela.     

Accumulation and Spatial Distribution of Poly(A)+RNA in Oocytes and Early Embryos of Drosophila melanogaster

We describe the accumulation and distribution of poly (A)⁺RNA during oogenesis and early embryogenesis as revealed by in situ hybridization with a radio-labeled poly (U) probe. The amount of poly (A)⁺RNA in nurse cell cytoplasm continuously increased untill mid-vitellogenic stage (st. 10), then decreased with the rapid increase of poly (A)⁺RNA in the oocyte (st. 11). The localization of poly (A)⁺RNA at stage 10 was in the anterior region of the oocyte, where it is connected by cytoplasmic bridge to the nurse cells. These observations indicate that most of the poly (A)⁺RNA synthesized in the nurse cells is transferred to the oocyte through the cytoplasmic bridges at stage 10–11. During the remainder of oogenesis (st. 11–14) and during preblastodermal embryogenesis, poly (A)⁺RNA was evenly distributed over the cytoplasm of oocytes and embryos. At blastoderm stage, poly(A)⁺RNA became concentrated in the peripheral region of embryos. Though the somatic nuclei of the blastoderm contained a detectable amount of poly (A)⁺ RNA, the pole cell nuclei did not. The cytoplasmic RNA visualised by acridine orange staining and the poly (A)⁺RNA detected by hybridization with [³H]poly (U) exhibited identical distributions during oogenesis and early embryogenesis. These observations provide a basis to assess the unique distributions of specific RNA sequences involved in early development.     

Appearance of RNA with a specific size class of poly(A) in oocytes and eggs in HCG-stimulated Xenopus laevis females

Using a 3H-poly(U) binding technique, poly(A) content has been measured in Xenopus laevis eggs consisting of two groups: one was obtained from females 12 to 16 hr after a single injection of human chorionic gonadotropin (HCG) (designated "unstimulated" eggs), and the other was obtained one week later from the same females by the second injection of the hormone ("stimulated" eggs). The stimulated egg contained about a 1.2-fold larger amount of poly(A) than the unstimulated one. Gel electrophoresis has revealed that this slight but reproducible increase in the poly(A) content was due to the production of a specific size class of poly(A) (i.e., about 80 nucleotides long). This poly(A) was also detectable in the oocytes obtained one week after a single injection but not in those from uninjected females. Poly(A)+RNA was analyzed by sucrose density gradient centrifugation, and it has been shown that most of the 80 nucleotide-long poly(A) sequences in the stimulated eggs were associated with RNA whose size distribution was less heterogeneous than, and hence distinguishable from, that of the bulk poly(A)+RNA. The possibility is discussed that HCG hormone may stimulate the synthesis of a specific class of poly(A)+RNA in smaller oocytes, which may not normally take place to a significant extent during maturation.     

Nuclear reprogramming in nuclear transplant rabbit embryos

The first six genetically verified nuclear transplant rabbits have been produced in this study. Individual eight-cell stage embryo blastomeres were transferred and fused with enucleated mature oocytes of which six full-term offspring were produced out of 164 manipulated eggs. The following efficiency rates were determined for the nuclear transplantation procedure: chromosomal removal from oocytes, 92%; fusion rate, 84%; activation rate, 46%; embryo transfer rate, 27%. Additional reasons for the low efficiency rate of nuclear transplant embryos may include limited development due to aging in recipient oocytes and asynchronous transfers of manipulated embryos to recipient females. The successful development to term may have been due to the ability of the mature oocyte to reprogram the eight-cell stage nuclei. The number of cells in blastocysts derived from isolated eight-cell blastomeres (18 +/- .08) was lower than that of nonmanipulated pronuclear (106 +/- 5.1) and nuclear transplant embryos derived from eight-cell stage nuclei (91 +/- 10.2) (p less than 0.001). This evidence along with the significant amount of nuclear swelling in nuclear transplant embryos and a delay in the time of blastocyst formation indicate that nuclear reprogramming had taken place in these embryos. Successful nuclear reprogramming indicates that serial transfers could result in the expanded multiplication of mammalian embryos.     

Calmodulin synthesis and accumulation during oogenesis and maturation of Xenopus laevis oocytes

The calmodulin levels in stage 6 Xenopus oocytes averaged 89 +/- 24 (SD) ng/oocyte and had largely accumulated by stage 3 of oogenesis. From stage 3 to early stage 6, calmodulin levels did not increase further. However, in large stage 6 oocytes (greater than 1.25 mm diam) calmodulin levels again rose to a level as high as 121 ng/oocyte. Calmodulin levels did not change during the maturation of stage 6 oocytes and the results of measurements on animal and vegetal oocyte halves from control and mature oocytes showed no evidence of a redistribution of calmodulin during maturation. Measurements of calmodulin synthesis in stages 1 and 2 oocytes, stage 4 oocytes, and stage 6 oocytes indicated that calmodulin was being synthesized continuously during oogenesis and that the rate of synthesis increased during oogenesis. In stage 1 and 2 oocytes (combined), the synthesis rate was 3.5 pg/hr/oocyte; in stage 4 oocytes it was 48 pg/hr/oocyte, and in large stage 6 oocytes the rate had increased to 160 pg/hr/oocyte. These changes in the rates of synthesis were discussed as they relate to the pattern of calmodulin accumulation during oogenesis.