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.     

Changing rates of DNA and RNA synthesis in Drosophila embryos

Rates of DNA and RNA synthesis during Drosophila embryogenesis were measured by labeling octane-treated embryos with [¹⁴C]thymidine and [³H]uridine. Radioactivity incorporated per hour was converted to rates of synthesis using measurements of the pool-specific activity during the labeling periods. The rate of DNA synthesis during early embryogenesis increases to a maximum at 6 hr after oviposition and then decreases sharply. Measured rates of DNA synthesis were used to calculate that the total amount of DNA per embryo doubles every 18 min at blastoderm, every 70–80 min during gastrulation, and less than once every 7 hr at later stages. The rate of RNA accumulation per embryo increases continuously during the first 14 hr of embryogenesis. The rate of nuclear RNA synthesis per diploid amount of DNA, however, decreases fivefold between blastoderm and primary organogenesis. The cytoplasmic poly(A)⁺ RNA synthesized by blastoderm embryos associates rapidly with polysomes. The relatively high rate of synthesis of polysomal poly(A)⁺ RNA per nucleus at blastoderm allows the small number of nuclei present at blastoderm to make a significant quantitative contribution to the informational RNA active in the early embryo. At the end of blastoderm, approximately 14% of the mRNA being translated in the embryo has been synthesized after fertilization.     

Post-transcriptional regulation of protein synthesis in Ilyanassa embryos and isolated polar lobes

The experimental removal of the polar lobe, an anucleate cytoplasmic protrusion formed in preparation for the first cleavage, from the egg of Ilyanassa obsoleta results in grossly abnormal embryonic development. In experiments reported here normal and delobed embryos, as well as isolated polar lobes, were incubated with [³⁵S]methionine for 4 hr beginning at the completion of the first cleavage or 21 hr later during epiboly. Proteins were extracted and examined by fluorography after resolution by two-dimensional polyacrylamide gel electrophoresis. In normal embryos the synthesis of several proteins begins or ends between the two stages investigated. In isolated polar lobes a subset of these developmental changes in protein synthesis occurs, indicating that the regulation of these events is independent of concomitant nuclear activity and probably involves selective regulation of the translation of mRNA stored in the eggs. The patterns of protein synthesis in normal embryos and delobed embryos are qualitatively extremely similar, though quantitative differences are also observed. No proteins can be detected which are synthesized exclusively in polar lobes.     

Replication of mitochondrial DNA in the early development of Misgurnus fossilis

Mitochondria isolated from Misgurnus fossilis embryos at various developmental stages were incubated with ³H-dTTP in vitro and the incorporation into mtDNA was determined. It has been found that the rate of mtDNA labeling increases exponentially with a doubling time of 7 hr from 0.01 pmole of ³H-dTMP/mg protein/hr in mitochondria from unfertilized eggs to 0.4 pmoles of ³H-dTMP/mg protein/hr in mitochondria of 35 hr embryos. The pool of intramitochondrial dTTP decreases 2.5 times during the first 10 hr after fertilization, then remains practically constant up to 35 hr of development. The rate of exogenous ³H-dTTP incorporation into the acid soluble pool of isolated mitochondria at two stages is approximately proportional to the pool size. Thus identical specific activities of ³H-dTTP inside mitochondria would be obtained even with pools of different sizes. We conclude that the increase of ³H-dTMP incorporation into mtDNA in development reflects genuine activation of mtDNA synthesis. As early as 6 hr after fertilization the bulk of the label incorporated into mtDNA is found in the fraction associated with covalently closed molecules. This pattern of labeling characteristic for replicating mtDNA is maintained throughout early development. In contrast such preferential label incorporation into the closed circular fraction was not found with mitochondria of unfertilized eggs. Closed mtDNA from unfertilized eggs contains not more than 1% of molecules with D-loops. In 35 hr embryos the corresponding value is equal to about 4%. Activation of mtDNA replication in embryogenesis is probably due to the activation of mechanisms responsible for the generation of primers for replication. DNA polymerase activity solubilized from mitochondria remains unchanged in the course of embryogenesis.     

Rates of synthesis of major classes of RNA in Drosophila embryos.

We have been successful in labeling to high specific activity (3 × 10⁵ dpm/μg) the RNA synthesized by large numbers of Drosophila embryos. Embryos of various developmental stages were rendered permeable with octane and labeled with [³H]uridine for 1 hr. At each stage the total dpm incorporated into RNA and the specific activity of the UTP pool were measured and used to calculate the absolute rate of RNA synthesis per embryo. This rate increases during embryonic development, from 1 pmole UTP/hr at 2 hr after oviposition to 6 pmoles UTP/hr at 15 hr. The rates of synthesis of nuclear and cytoplasmic poly(A)^? and poly(A)⁺ RNAs were determined by analyzing the fractionated RNAs from each stage by sucrose gradient sedimentation. There is a significant activation of nuclear RNA synthesis at the blastoderm stage (approximately 2 hr after oviposition). After blastoderm, the rates of synthesis of nuclear and cytoplasmic poly(A)^? and poly(A)⁺ RNA per embryo increase continuously; the rate of synthesis of each of these classes per nucleus, however, remains fairly constant. After making corrections for turnover during the labeling period, we find that the rates of synthesis of the major classes of RNA per nucleus at the gastrula stage are: cytoplasmic poly(A)⁺ RNA, 0.06 fg/nucleus-min; hnRNA, 0.86 fg/nucleus-min; and ribosomal RNA, 0.46 fg/nucleus-min. These rates are compared to rates of RNA synthesis in sea urchin embryos.     

Program of early development in the mammal: changes in patterns and absolute rates of tubulin and total protein synthesis during oogenesis and early embryogenesis in the mouse.

The absolute rates of total protein synthesis and tubulin synthesis during oogenesis and early embryogenesis in the mouse have been determined by measuring specific activities of the endogenous methionine pool and rates of incorporation of [³⁵S]methionine into total protein and tubulin. The absolute rate of protein synthesis decreases from 43 to 33 pg/hr/oocyte during meiotic maturation, while the size of the endogenous methionine pool remains essentially unchanged at 65 fmole/oocyte (R. M. Schultz, M. J. LaMarca, and P. M. Wassarman, 1978, Proc. Nat. Acad. Sci. USA,75, 4160). The one-cell mouse embryo synthesizes protein at a rate of 45 pg/hr/embryo, so that fertilization is accompanied by about a 40% increase in the absolute rate of total protein synthesis. The eight-cell compacted embryo synthesizes protein at the rate of 51 pg/hr/embryo. The size of the endogenous methionine pool increases dramatically during early embryogenesis, from 74 fmole in the unfertilized ovum to 137 and 222 fmole in the one-cell embryo and eight-cell compacted embryo, respectively. Tubulin is one of the major proteins synthesized by the mouse oocyte and embryo since the absolute rate of tubulin synthesis is, on the average, 1.3% that of total protein synthesis. The absolute rate of tubulin synthesis decreases from 0.61 to 0.36 pg/hr/oocyte during meiotic maturation and then increases to 0.60 pg/hr/embryo in the one-cell embryo and to 0.66 pg/hr/embryo in the eight-cell compacted embryo. During meiotic maturation and early embryogenesis the direction and magnitude of changes in the rate of tubulin synthesis closely parallel those of total protein synthesis. Although equimolar amounts of tubulin subunits are present in microtubules, the ratio of the absolute rate of synthesis of the β subunit to that of the α subunit is about 2.0 throughout meiotic maturation and early embryogenesis.High-resolution two-dimensional gel electrophoretic analysis of [³⁵S]methionine-labeled proteins reveals that many of the newly synthesized proteins that first appear during meiotic maturation of the oocyte continue to be synthesized in the one-cell embryo. Nearly all of the proteins synthesized in the one-cell embryo are also synthesized in the unfertilized ovum, although some changes in the pattern of protein synthesis are associated with fertilization. Therefore, the developmental program for early embryogenesis in the mouse appears to be activated during meiotic maturation of the oocyte. These results are compared with those obtained using oocytes and embryos from nonmammalian animal species.     

Developmental modulation of protein synthesis in Drosophila primary embryonic cell cultures

The patterns of proteins synthesized during embryonic development in Drosophila melanogaster have been examined by two-dimensional gel electrophoresis. Primary cell cultures prepared from donor embryos synchronized to ± 1 hr were labeled with [³⁵S]methionine at 5, 11.5, 14.5, and 26 hr after oviposition. Of approximately 400 to 500 proteins detected, the synthesis of about 50 is developmentally modulated. The greatest number of changes in the synthesis of stage-specific proteins occurs at 11.5 and 14.5 hr after oviposition, periods just prior to and during the times of the greatest overt morphological and biochemical changes. At 11.5 hr, 35 stage-specific proteins are synthesized, including 19 that are not present at the previous stage examined. At 14.5 hr, 34 stage-specific proteins can be detected, including 11 newly synthesized proteins. However, 12 proteins from the previous stage are no longer synthesized. At the completion of embryonic differentiation, at 26 hr, no new proteins are synthesized and the synthesis of many present in earlier stages has decreased or stopped. Comparison of patterns of embryonic proteins to those synthesized by two Drosophila continuous cell lines reveals that the majority of proteins are common to all. However, only about 40% of the embryonic stage-specific proteins are present in either cell line. In addition, there are several proteins unique to each cell line that are not observed in any of the embryonic stages.     

Ribosomal protein mRNAs increase dramatically during Xenopus development

The amount of messenger RNA per microgram of rRNA increases three- to fourfold during Xenopus early development. This increase is the same when measured by stimulation of in vitro protein synthesis or by poly(U) hybridization. The increase in mRNA per embryo therefore is approximately six- to eightfold since the ribosome content doubles between fertilization and the stage 41 tadpole. The amount of ribosomal protein mRNA, as assayed by in vitro protein synthesis, also increases dramatically during early development. This increase is much more pronounced than the general increase in mRNA content, i.e., there is a dramatic increase in the abundance as well as the amount of the ribosomal protein mRNA. Since ribosomal protein mRNAs are predominantly small mRNAs, the increase in ribosomal protein mRNA abundance contributes to the general decrease in the average size of pA⁺ RNA that occurs during early development in Xenopus.     

The program of protein synthesis during the development of the micromere-primary mesenchyme cell line in the sea urchin embryo

Changes in the pattern of protein synthesis were analyzed during the in vitro development of the micromere-primary mesenchyme cell line of the sea urchin embryo. Micromeres were isolated and cultured from 16-cell stage embryos, and primary mesenchyme cells were isolated and cultured from early gastrulae. Both cell isolates developed normally in culture with about the same timing as their in situ counterparts in control embryos. Newly synthesized proteins were labeled with [³H]valine at several stages of development and were analyzed by two-dimensional polyacrylamide gel electrophoresis and fluorgraphy. The electrophoretic pattern of labeled proteins changed dramatically during development. More than half of the analyzed proteins underwent qualitative or quantitative changes in their relative rates of valine incorporation and these changes were highly specific to this cell line. Almost all of the changes were initiated prior to gastrulation and many prior to hatching. The highest frequency of changes in the micromere pattern of protein synthesis occurred between hatching and the start of gastrulation. This peak of activity coincided with the normal time of ingression of the primary mesenchyme and preceded the differentiation of spicules by more than 30 hr. Most of the observed changes were characterized as either decreases in the synthesis of proteins that showed maximum incorporation at the 16-cell stage or increases in the synthesis of proteins that showed maxima in the fully differentiated cells. Very few proteins exhibited transient synthetic maxima at intermediate stages. Thus, the program of protein synthesis associated with the development of micromeres consists largely of a switch in emphasis from early to late proteins, with the primary time of switching being between hatching and the onset of gastrulation.     

DNA-dependent RNA polymerase activities during embryogenesis in the bug, Oncopeltus fasciatus

Using α-amanitin to inhibit polymerase II activity in intact nuclei from Oncopeltus embryos, it is demonstrated that there is no difference in relative amounts of α-amanitin-resistant (Form I) and α-amanitin-sensitive (Form II) polymerases at two stages of embryonic development (70 and 140 hr), although the total polymerase activity is considerably higher at the earlier stage. However the RNA made under these circumstances (presumably due to Form I activity) appears to be, as expected, largely ribosomal.When the RNA polymerase activities are solubilized and separated, there is a substantially higher level of Form I activity in 70-hr embryos over that in 140-hr embryos. It is suggested that this high level of polymerase activity is correlated directly with the high level of ribosomal RNA synthesis at this stage.     

Control of ribosomal protein synthesis during wheat embryo imbibition

Dry wheat embryos contain large quantities of ribosomes, synthesized and assembled during embryogenesis. When messenger RNA isolated from dry embryos is translated, in vitro, a significant proportion of the total translation products (approx. 10%) is identifiable as ribosomal proteins, by electrophoresis in two distinct two-dimensional polyacrylamide gel electrophoretic systems. When germinating embryos are labelled with [³⁵S]methionine, during the first 24 h of imbibition, the appearance of newly synthesized ribosomal proteins in the cytosolic fraction is barely detectable. However, this low level (< 1% of total cytosolic protein synthesis) of observed ribosomal protein synthesis is not correlated with a correspondingly low level of ribosomal protein mRNA. Ribosomal proteins constitute at least 10% of the products of translation, in vitro, of mRNA isolated from germinating wheat embryos. Ribosomal proteins are also conspicuous products of translation when polyribosomes isolated from imbibing embryos are used to direct protein synthesis in a cell-free ‘run-off’ system, and newly synthesized ribosomal proteins can be detected in the nuclei isolated from germinating embryos. It is proposed that their absence from the cytosolic fraction is a consequence of post-translational regulatory events.     

Spatial and temporal distribution of Patched-related protein in the Drosophila embryo

Patched-related (Ptr) encodes a protein with 12 potential transmembrane domains and a sterol-sensing domain that is closely related in predicted topology and domain organization to Patched, the canonical receptor of the Hedgehog pathway. Here we describe the production of an antibody specific for Drosophila Ptr and analyse its spatial and temporal distribution in the embryo. We find that at early developmental stages Ptr is predominantly localized at cell periphery but later on it becomes strongly and almost exclusively expressed in hemocytes. Interestingly Ptr null mutant embryos died without hatching. Our findings suggest that Ptr plays an essential function in Drosophila development, perhaps as a new receptor of embryonic hemocytes.     

Polar lobe specific regulation of translation in embryos of Ilyanassa obsoleta.

Comparisons of the patterns of synthesis of ¹⁴C-labeled proteins of normal embryos of Ilyanassa with the patterns of synthesis of ³H-labeled proteins of embryos from which the polar lobes had been removed at the trefoil stage were made by coelectrophoresis on polyacrylamide disc gels. Controls utilizing biochemical and morphological markers were performed to assure that normal and delobed embryos were developing at equivalent rates. The expression of significant differences in the patterns of protein synthesis were found between normal and delobed embryos, and these differences were not dependent upon concomitant RNA synthesis. These differences were observable as early as after only 24 hr of development, although organogenesis does not begin until much later in development. Therefore, the observed differences probably reflect determininative events. The results support the hypothesis that the developmental determinants of the polar lobe may include specific, preformed mRNA sequences, or specific regulators of translation.     

Polyadenylic acid-containing of rna in unfertilized and fertilized eggs of the rabbit.

Molecular hybridization between ³H-polyuridylic acid and unlabeled RNA prepared from unfertilized rabbit eggs and 10-h postfertilization stage rabbit embryos has been used to measure the amount and subcellular localization of adenylated maternal RNA. The results reported indicate that there is poly (A)-containing RNA (putative messenger RNA) in unfertilized rabbit eggs. The amount of poly (A) in the RNA in rabbit eggs does not increase immediately after fertilization and is located primarily in the ribosomal fraction of the cell. The rate of protein synthesis in fertilized eggs is insensitive to α-amanitin at concentrations which inhibit RNA synthesis. These results suggest that maternal mRNA makes an important contribution to protein synthesis in early stages of cleavage in the rabbit embryo.     

Program of early development in the mammal: changes in the patterns and absolute rates of tubulin and total protein synthesis during oocyte growth in the mouse

Oocytes at several stages of growth have been isolated by enzymatic digestion and/or physical disruption of ovaries excised from juvenile and adult mice. The absolute rates of total protein synthesis and tubulin synthesis in these isolated oocytes were determined by measuring sizes of the endogenous methionine pool and apparent rates of incorporation of [³⁵S]methionine into total protein and tubulin using methods described previously (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). The size of the endogenous methionine pool increases approximately 350-fold during oocyte growth, from 0.16 fmole in nongrowing oocytes (12 μm) to 56 fmole in fully grown oocytes (85 μm). Since the volume of mouse oocytes also increases about 350-fold during growth, the concentration of intracellular free methionine remains constant at approximately 170 μM. The absolute rate of protein synthesis increases from 1.1 to 41.8 pg/hr/oocyte for nongrowing and fully grown mouse oocytes, respectively. Since this represents about a 38-fold increase in the absolute rate of protein synthesis, the rate of synthesis per picoliter of cytoplasm actually decreases nearly 10-fold during oocyte growth. These measurements indicate that the growing mouse oocyte itself is capable of synthesizing only about 50% of the protein found in fully grown oocytes. Tubulin is one of the major proteins synthesized by growing mouse oocytes since the absolute rate of tubulin synthesis is, on the average, 1.8% of total protein synthesis. The absolute rate of tubulin synthesis increases from 0.4 to 0.6 pg/hr/oocyte as the oocyte grows from 40 to 85 μm in diameter. However, overall, the percentage of total protein synthesis devoted to the synthesis of tubulin actually declines somewhat during this phase of growth, from 2 to 1.5%. Although equimolar amounts of tubulin subunits are present in microtubules, the ratio of absolute rate of synthesis of the β subunit to that of the α subunit varies from 1.3 to 2.0 throughout oocyte growth. High-resolution two-dimensional gel electrophoretic analyses of [³⁵S]methionine-labeled proteins reveal that many changes take place in the pattern of protein synthesis during oocyte growth.     

Cytochemical studies on the protamine-type protein transition in sperm nuclei after fertilization and the early embryonic histones of Urechis caupo.

Cytochemical staining characteristics of nuclear histones during postfertilization maturation division and various early embryonic stages in Urechis have been studied. The transition of protamine-type protein to adult histones in the sperm nucleus is accomplished by 15 min after entrance into the egg cytoplasm. Newly synthesized egg proteins migrate into enlarging male and female pronuclei after this transition, followed by pronuclear DNA synthesis and fusion. The shift from protamine-type protein to adult histones, which occurs in the absence of RNA synthesis during the postfertilization maturation division of the egg, may be one of the processes involved in the normal structural reorganization of chromosomes. Such a reorganization is likely to be a prerequisite for chromosome replication and mitosis. No qualitative differences are detected in the stainability of histones of unfertilized eggs and embryos at the cleavage and later stages of development.     

Fertilization of sea urchin eggs is accompanied by 40 S ribosomal subunit phosphorylation

After fertilization of sea urchin (Arbacia punctulata) eggs, there is a single prominent alteration in the pattern of protein phosphorylation. In eggs preloaded with ³²PO₄, a 31,000 M_r protein (rp31) becomes labeled within 4 min of sperm addition. A new steady-state level of rp31 labeling is achieved by 11 min. The rate of protein synthesis in sea urchin zygotes also increases at 8–10 min after fertilization. Protein rp31 corresponds to mammalian ribosomal S6 because it cosediments with 40 S subunits on high salt-sucrose gradients, it is similar to the mammalian protein in M_r and charge, and it becomes phosphorylated during an increase in protein synthesis. The specific activity of phosphorylated rp31 (relative to rRNA) is similar between free 80 S monosomes and polysomes, indicating that rp31 phosphorylation is not sufficient for ribosomal activity. A phosphatase, highly specific for rp31, is present in extracts of eggs and very early embryos. This phosphatase becomes inactive at about the same time that the degree of labeling of rp31 increases in embryos. Evidently a control system that maintains a low level of rp31 phosphorylation is active in sea urchin eggs. Inactivation of this system shortly after fertilization leads to the accumulation of phosphorylated ribosomes.