Interferon synthesis in the early post-implantation mouse embryo

Abstract. A qualitative bioassay was adapted and used to determine the ability of the early post-implantation mouse embryo to synthesise interferon. Interferon production was not seen in any embryo tissue in the absence of an inducer and could only be detected in virus-induced tissue from the early 7th day of development. This induced interferon synthesis was initially confined to the trophoblast of the early 7th day embryo. It was then found in tissues of both trophoblast and inner cell mass origin in the early 8th day, and subsequently, in derivatives of the embryonic ectoderm in the 13th-day embryo.     

Interferon synthesis in the early post-implantation mouse embryo

A qualitative bioassay was adapted and used to determine the ability of the early post-implantation mouse embryo to synthesise interferon. Interferon production was not seen in any embryo tissue in the absence of an inducer and could only be detected in virus-induced tissue from the early 7th day of development. This induced interferon synthesis was initially confined to the trophoblast of the early 7th day embryo. It was then found in tissues of both trophoblast and inner cell mass origin in the early 8th day, and subsequently, in derivatives of the embryonic ectoderm in the 13th-day embryo.     

SPARC synthesis in pre-implantation and early post-implantation mouse embryos

Summary SPARC (secreted protein acidic and rich in cysteine), also known as osteonectin and BM-40, is a secreted protein associated with a variety of embryonic and adult tissue and cell types, including placenta, parietal and visceral endoderm, certain epithelia (e.g. gut, skin, glandular epithelia), and regions of active chondrogenesis and osteogenesis. Although much is known concerning the tissue distribution of this protein, neither the time and location of its initial appearance nor its functions during embryogenesis have been clearly established. We identified the location of SPARC on two-dimensional protein gels. By using two-dimensional gel analysis of both pre- and post-implantation stage mouse embryos, we find that SPARC is initially synthesized between 3.5 and 4.5 days of embryogenesis. This is the earliest time during development at which synthesis of SPARC has been demonstrated. Inner cell masses isolated from 4.5 day blastocysts synthesize SPARC indicating that either primitive ectoderm, primitive endoderm, or both produce this protein. SPARC synthesis is also detectable in isolated trophoblast vesicles. Thus, SPARC is synthesized not only in placenta, parietal endoderm, and visceral endoderm, but in the precursors of these tissues as well. Examination of 7.5 day embryos reveals that SPARC is synthesized in isolated parietal yolk sac and in whole extraembryonic and embryonic regions. Relative to other proteins, synthesis of SPARC was most prevalent in the parietal yolk sac. The possible implications of SPARC synthesis as early as 4.5 days are discussed.     

Proteins of Developing Rice Embryos As Characterized by Twodimensional Gel Electrophoresis

Developmental changes of rice (Oryza sativa, subsp, japonica) in embryonic proteins during embryogenesis were investigated by modified two-dimensionalpolyacrylamide gel electrophoresis. The results indicated that there were apparently differences in the embryonic proteins between the embryos at 7th and 13th day after anthesis. Some proteins only appeared in the embryos al 7th day, disappearing at 13th day. Then some new proteinsappeared at 21th day embryos, which were different from that disappeared during differentiation. In concomitant with the completion of embryo differentiation, the number of acidic proteins decreased, while the basic ones showed an increasing trend. Itwas also found that in the 7th day embryos, there were a higher relative percent ofembryonic protein spots in the region of higher molecular weight, while in the 13thday there were higher relative percent of ones in the region of lower molecular weight.The electrophoretic pattern of rice germ lectin (RGL) showed that the synthesis ofRGL was associated with embryo differentiation. According to these results, we propose that some of embryonic proteins which areonly found at early stage of embryogenesis may be important factors for the regulationof embryo differentiation. Although the function of these proteins is still an openquestion, these specific proteins, at least, represent an excellent mark for plant embryodifferentiation.     

Similarity of proteins synthesized by isolated blastomeres of early sea urchin embryos

The 16-cell sea urchin embryo has blastomeres of three distinct size classes: micromeres, mesomeres, and macromeres. Each class is already restricted in its developmental fate, micromeres being committed to formation of primary mesenchyme cells. The three classes of blastomeres were isolated in high purity and incubated in [³⁵S]methionine until the next cleavage. Nearly all the radioactive protein was solubilized and subjected to two-dimensional electrophoresis according to O'Farrell. Of approximately 1000 spots resolved, there are no qualitative differences among the three blastomeres. When embryos were labeled between the first and fourth cleavages and blastomeres then isolated, no qualitative differences in protein synthesis were observed. Moreover, there are very few changes when unfertilized eggs are compared to 16-cell embryos. Thus cellular determination during embryonic development is not accompanied by qualitative changes in the distribution within the embryo of abundantly synthesized proteins, virtually all of which are coded for by sequences present in the egg.     

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.     

Teratoid Tumors Derived from Mouse Embryos Grown in an Immunologically Privileged Site

Mouse early embryos and embryo fragments were transplanted into an immunologically privileged site, consisting of a glass cylinder previously implanted under the skin of adult mice in order to test their tumor producing potential, in allogeneic adult recipients. The highest yield of tumors was obtained upon transplantation of 6 1/2 day old embryos in toto. i.e., including the embryonic and extraembryonic areas. Histological examination showed teratomas composed of differentiated tissues derived from the three germ layers containing isolated foci of undifferentiated cells and nodules of trophoblast giant cells. Areas exhibiting the histological appearance of yolk sac carcinoma were also observed. Transplantation of the whole 6 1/2 day old egg cylinder, including the ectoplacental cone, and the isolated embryonic area produced a lower incidence of teratomas with a reduced variety of differentiated tissues. No yolk sac carcinoma was found in these grafts. The ectoplacental cone of 6 1/2 day embryos produced no tumors. Grafts of genital ridges from 12 1/2 day embryos gave rise to teratomas with well differentiated tissues of embryonic and extraembryonic origin. Areas ressembling yolk sac carcinoma were also observed. The life span of trophoblastic giant cells within the glass cylinder was significantly longer than in other experimental systems.     

Development of separated germ layers of rodent embryos on ectopic sites: a reappraisal.

The method of separation of germ layers of rodent embryos by treating the embryonic shields with proteolytic enzymes and by microsurgery with the subsequent transplantation to ectopic sites has helped to gain a more detailed insight into what is going on during gastrulation in mammals. The space under the kidney capsule of adult animals seems to be the most appropriate ectopic site for transplantation of early postimplantation rat embryos or separated germ layers. After transplantation the grafts develop into teratomas whose complex histological structure reflects the initial developmental capacities of the graft. At the pre-primitive streak and the early primitive streak stages the primitive ectoderm differentiates into tissue derivatives of all three definitive germ layers, often in complex organotypic combinations. This is indirect evidence that all cells of the embryonic body originate from the primitive embryonic ectoderm. Halves of the primitive ectoderm obtained by a longitudinal or transverse cut through the egg cylinder give the same result. At the head fold stage the capacity for differentiation of the ectoderm is restricted to ectodermal and mesodermal derivatives. One day before gastrulation the isolated primitive ectoderm is not able to differentiate as renal isograft. The mesoderm isolated at the head fold stage and at later stages when its segmentation occurs, differentiates almost exclusively into the brown adipose tissue. The embryonic endoderm differentiates only in combination with the mesoderm. After transplantation the embryonic ectoderm loses its epithelial organization and breaks up into a mass of mesenchyme-like cells in which epithelial structures subsequently appear and differentiate in a way reminiscent of the reaggregation of cells in mixed cell suspension in vitro.     

Tissue-restricted expression of thrombomodulin in the placenta rescues thrombomodulin-deficient mice from early lethality and reveals a secondary developmental block

The endothelial cell surface receptor thrombomodulin (TM) inhibits blood coagulation by forming a complex with thrombin, which then converts protein C into the natural anticoagulant, activated protein C. In mice, a loss of TM function causes embryonic lethality at day 8.5 p.c. (post coitum) before establishment of a functional cardiovascular system. At this developmental stage, TM is expressed in the developing vasculature of the embryo proper, as well as in non-endothelial cells of the early placenta, giant trophoblast and parietal endoderm. Here, we show that reconstitution of TM expression in extraembryonic tissue by aggregation of tetraploid wild-type embryos with TM-null embryonic stem cells rescues TM-null embryos from early lethality. TM-null tetraploid embryos develop normally during midgestation, but encounter a secondary developmental block between days 12.5 and 16.5 p.c. Embryos lacking TM develop lethal consumptive coagulopathy during this period, and no live embryos are retrieved at term. Morphogenesis of embryonic blood vessels and other organs appears normal before E15. These findings demonstrate a dual role of TM in development, and that a loss of TM function disrupts mouse embryogenesis at two different stages. These two functions of TM are exerted in two distinct tissues: expression of TM in non-endothelial extraembryonic tissues is required for proper function of the early placenta, while the absence of TM from embryonic blood vessel endothelium causes lethal consumptive coagulopathy.     

Qualitative patterns of protein synthesis in the preimplantation mouse embryo: I. Normal pregnancy

Qualitative patterns of protein synthesis in preimplantation mouse embryos were examined by SDS-polyacrylamide-gel electrophoresis followed by autoradiography. The results demonstrate that the qualitative pattern of protein synthesis in newly fertilized eggs (day 1) is very similar to the protein pattern obtained from ovulated, unfertilized eggs. By late day 1 or early day 2, most of these “maternal” proteins are no longer being synthesized by the embryo, and many new autoradiographic bands are apparent. The most intriguing aspect of this study is the observation that all major changes in the qualitative pattern of protein synthesis take place between fertilization and the four- to eight-cell stage (day 3). From early day 3 onward, the qualitative pattern of protein synthesis remains essentially unchanged.Many of the major autoradiographic bands observed in mouse embryos from the four- to eight-cell stage and onward are also observed in protein patterns obtained from blastocyst-stage rabbit embryos. The changing patterns of protein synthesis revealed in this study occur before any gross differentiation of the embryos is evident (delineation of the inner cell mass and trophoblast) and before a marked increase in the relative rate of incorporation of l-[³⁵S]methionine takes place. However, the qualitative changes in the pattern of protein synthesis do coincide with a period of extensive fine structural differentiation.     

Mice lacking HSP90beta fail to develop a placental labyrinth

The 90 kDa heat-shock proteins (HSP90s) play important roles during stress situations as general chaperones and under physiological conditions in the conformational activation of specific protein substrates. Vertebrates express two cytosolic HSP90s (HSP90alpha and HSP90beta) ubiquitously. We have mutated the Hsp90beta gene in murine embryonic stem cells and generated Hsp90beta mutant mice. Heterozygous animals were phenotypically normal. Interestingly, homozygous embryos developed normally until embryonic day 9.0/9.5. Then, although Hsp90beta is expressed ubiquitously, they exhibited phenotypic abnormalities restricted to the placenta. The mutant concepti failed to form a fetal placental labyrinth and died a day later. Fusion between the allantois and the chorionic plate occurred, allantoic blood vessels invaded the chorion, but then did not expand. Mutant trophoblast cells failed to differentiate into trilaminar labyrinthine trophoblast. Despite conspicuous similarities between HSP90alpha and HSP90beta at the molecular level, our data suggest that HSP90beta has a key role in placenta development that cannot be performed by the endogenous HSP90alpha alone. Analysis of chimeric concepti consisting of mutant embryos and tetraploid embryos or ES cells revealed that wild-type allantois was able to induce mutant trophoblast to differentiate. In contrast, trophoblast wild type at the Hsp90beta locus was unable to differentiate when in contact with mutant allantois. Therefore, the primary defect caused by the Hsp90beta mutation resided in the allantois. The allantois mesoderm is thought to induce trophoblast differentiation. Our results show that Hsp90beta is a necessary component of this induction process.     

Changes in protein synthetic activity in early Drosophila embryos mutant for the segmentation gene Krüppel

We have identified early embryo proteins related to the segmentation gene Krüppel by [35S]methionine pulse labelling and two-dimensional gel electrophoresis. Protein synthesis differences shared by homozygous embryos of two Krüppel alleles when compared to heterozygous and wild-type embryos are reported. The study was extended to syncytial blastoderm stages by pulse labelling and gel analysis of single embryos, using Krüppel-specific proteins from gastrula stages as molecular markers for identifying homozygous Krüppel embryos. Localized expression of interesting proteins was examined in embryo fragments. The earliest differences detected at nuclear migration stages showed unregulated synthesis in mutant embryos of two proteins that have stage specific synthesis in normal embryos. At the cellular blastoderm stage one protein was not synthesized and two proteins showed apparent shifts in isoelectric point in mutant embryos. Differences observed in older embryos included additional proteins with shifted isoelectric points and a number of qualitative and quantitative changes in protein synthesis. Five of the proteins with altered rates of synthesis in mutant embryos showed localized synthesis in normal embryos. The early effects observed are consistent with the hypothesis that the Krüppel product can be a negative or positive regulator of expression of other loci, while blastoderm and gastrula stage shifts in isoelectric point indicate that a secondary effect of Krüppel function may involve post-translational modification of proteins.     

Localized synthesis of specific proteins during oogenesis and early embryogenesis inDrosophila melanogaster

Summary Protein synthesis in egg follicles and blastoderm embryos ofDrosophila melanogaster has been studied by means of two-dimensional gel electrophoresis. Up to 400 polypeptide spots have been resolved on autoradiographs. Stage 10 follicles (for stages see King, 1970) were labelled in vitro for 10 to 60 min with³⁵S-methionine and cut with tungsten needles into an anterior fragment containing the nurse cells and a posterior fragment containing the oocyte and follicle cells. The nurse cells were found to synthesize a complex pattern of proteins. At least two proteins were detected only in nurse cells but not in the oocyte even after a one hour labelling period. Nurse cells isolated from stages 9, 10 and 12 follicles were shown to synthesize stage specific patterns of proteins. Several proteins are synthesized in posterior fragments of stage 10 follicles but not in anterior fragments. These proteins are only found in follicle cells. No oocyte specific proteins have been detected. Striking differences between the protein patterns of anterior and posterior fragments persist until the nurse cells degenerate. In mature stage 14 follicles, labelled in vivo, no significant differences in the protein patterns of isolated anterior and posterior fragments could be detected; this may be due to technical limitations. At the blastoderm stage localized synthesis of specific proteins becomes detectable again. When blastoderm embryos, labelled in vivo, are cut with tungsten needles and the cells are isolated from anterior and posterior halves, differences become apparent. The pole cells located at the posterior pole are highly active in protein synthesis and contribute several specific proteins which are found exclusively in the posterior region of the embryo. In this study synthesis of specific proteins could only be demonstrated at those developmental stages which are characterized by the presence of different cell types within the egg chamber, while no differences were detected when stage 14 follicles were cut and anterior and posterior fragments analyzed separately. The differences in the pattern of protein synthesis by pole cells and blastoderm cells indicate that even the earliest stages of determination are reflected by marked changes at the biochemical level.     

The escape of the mink embryo from obligate diapause

The obligate embryonic diapause that characterizes gestation in mink engenders a developmental arrest at the blastocyst stage. The characteristics of escape from obligate diapause were investigated in embryos reactivated by treatment of the dams with exogenous prolactin. Protein and DNA synthesis showed marked increases within 72 h after the reinitiation of development, and embryo diameter increased thereafter. Trophoblast cells from embryos at Day 5 after activation proliferated more readily in vitro than trophoblasts from diapause or from Day 9 after activation, while in Day 9 embryos, cells from the inner cell mass (ICM) replicated comparatively more readily in vitro. There was evidence of expression of fibroblast growth factor-4 (FGF4) in both diapause and activated embryos and in ICM, but not the trophoblast. FGF receptor-2 was present in embryos from Day 5 after reactivation in both trophoblast and ICM cell lines. Trophoblast cell lines established from mink embryos proliferated in culture in the presence of FGF4 with a doubling time of 1.4 days, while in its absence, the doubling time was 4.0 days. We conclude that, during reinitiation of embryogenesis in the mink after diapause, embryo growth is characterized by gradual increases in protein synthesis, accompanied by mitosis of the trophoblast and ICM. There appears to be a pattern of differential proliferation between cells derived from these embryonic compartments, with the trophoblast phase of replication occurring mainly in the early reactivation phase, while the ICM proliferates more rapidly nearer to the time of implantation.     

Study of nucleic acid synthesis in rat embryos in relation to phase-specific characteristics of teratogenic effect of chloridine]

The maximal rate of incorporation of 32P-phosphate, 14C-formate and 14C-thymidine in DNA was recorded on the 13th day of development in the rat embryos and that of 14C-formate and 32P-phosphate in RNA and nucleotides of the acid-soluble fraction on the 12th day. The maximal incorporation of 14C-formate was recorded later: on the 15-16th days. Chloridin inhibited the incorporation of 14C-formate in DNA at all developmental stages, irrespective of the sensitivity of embryos to its teratogenic effect. The period of the maximal rate of DNA synthesis coincides with that of highest teratogenic activity of the drug. A suggestion is put forward to the effect that quantitative differences in the intensity of DNA synthesis at different stages of organgenesis provide one of the main causes of differential sensitivity of embryos to the teratogenic effect of inhibitors of nucleic acid synthesis.     

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.     

In vitro study of the fusion products and cell hybrids of mouse oocytes, zygotes and blastomeres

Several variants of mouse embryos were received by polyethylene glycol-induced fusion of ovulated oocytes, blastomeres from various developmental stages, zygotes and their fragments. Cytological analysis and observation in culture have been carried out. The nuclear dynamics during the process of fusion, onset of mitosis in fusion products, their cleavage and initial morphogenetic processes in developing embryos have been followed. The possibility of directed constitution of embryos with varying quantitative and qualitative combination of nuclei and cytoplasm is, thus, shown. Some aspects of application of these models in studying the controlling mechanisms of early embryogenesis are considered.     

Differential expression of nuclear lamin proteins during chicken development

By immunocytochemistry, quantitative immunoblotting, and two-dimensional gel electrophoresis, we have analyzed the distribution of nuclear lamin proteins during chicken embryonic development. Whereas no qualitative differences in the patterns of expression of lamins A, B1, and B2 were observed during gametogenesis in either the female or the male germ line, profound changes in the composition of the nuclear lamina occurred during the development of somatic tissues. Most unexpectedly, early chicken embryos were found to contain little if any lamin A, although they contained substantial amounts of lamins B1 and B2. During embryonic development, lamin A became increasingly prominent, whereas the amounts of lamin B1 decreased in many tissues. Interestingly, the extent and the developmental timing of these changes displayed pronounced tissue-specific variations. Lamin B2 was expressed in fairly constant amounts in all cell types investigated (except for pachytene-stage germ cells). These results have implications for the purported functional specializations of individual lamin proteins. In addition, they suggest that alterations in the composition of the nuclear lamina may be important for the establishment of cell- or tissue-specific differences in nuclear architecture.