Mannose: A Potential Selection System for Genetic Transformation of Annatto

The aim of the present work was to evaluate the feasibility of mannose as a selection system for the future genetic transformation of annatto (Bixa orellana L.). Hypocotyl segments, inverted hypocotyls and immature zygotic embryos were inoculated onto a Murashige and Skoog's medium supplemented with B5 vitamins, 87.6 mM sucrose and mannose in different combinations, 2.8 g dm^?3 Phytagel®, and 4.56 μM zeatin (organogenesis) or 2.26 μM 2,4-dichlorophenoxyacetic acid and 4.52 μM kinetin (somatic embryogenesis). Annatto explants did not regenerate on medium with mannose as the only carbon source when inverted hypocotyls and immature zygotic embryos were used. However, organogenesis (5 % frequency) occurred exclusively in hypocotyl-derived explants nearest to the crown (collar) of the seedlings. No further shoot development was achieved. Therefore the substitution of sucrose by mannose inhibited both organogenesis and embryogenesis, and thus the employment of mannose could constitute an alternative selective agent in protocols for genetic transformation of this species.     

Knockdown of SPARC leads to decreased cell-cell adhesion and lens cataracts during post-gastrula development in Xenopus laevis

SPARC is a multifunctional matricellular glycoprotein with complex, transient tissue distribution during embryonic development. In Xenopus laevis embryos, zygotic activation of SPARC is first detected during late gastrulation, undergoing rapid changes in its spatiotemporal distribution throughout organogenesis. Injections of anti-sense Xenopus SPARC morpholinos (XSMOs) into 2- and 4-cell embryos led to a dose-dependent dissociation of embryos during neurula and tailbud stages of development. Animal cap explants derived from XSMO-injected embryos also dissociated, resulting in the formation of amorphous ciliated microspheres. At low doses of XSMOs, lens cataracts were formed, phenocopying that observed in Sparc-null mice. At XSMOs concentrations that did not result in a loss of axial tissue integrity, adhesion between myotomes at intersomitic borders was compromised with a reduction in SPARC concentration. The combined data suggest a critical requirement for SPARC during post-gastrula development in Xenopus embryos and that SPARC, directly or indirectly, promotes cell?Ccell adhesion in vivo.     

Development of preimplantation rabbit embryos in vivo and in vitro

Qualitative patterns of protein synthesis in preimplantation rabbit embryos grown in vivo and in vitro were examined by SDS polyacrylamide gel electrophoresis followed by autoradiography. The results demonstrate that (1) most qualitative changes in the pattern of protein synthesis occur during cleavage, (2) the blastocyst period of development is characterized by a remarkably uniform and constant pattern of protein synthesis, and (3) the qualitative pattern of protein synthesis in embryos cultured in vitro from the 1-cell to the blastocyst stage is essentially identical to the pattern of protein synthesis in embryos grown to a comparable stage in vivo.These results indicate that no “special” maternal factors, such as uterine proteins, are required in vitro either for the qualitative changes in the pattern of protein synthesis during cleavage, or for the initial expression of a pattern of protein synthesis characteristic of the entire blastocyst period. From these studies we conclude that, once fertilized, the rabbit egg proceeds through cleavage and blastocyst formation on its own endogenous developmental program.     

A correlative study of experimentally changed first cleavage and Janus development in the trunk of Platynereis dumerilii (Annelida,Polychaeta)

Summary Among zygotes of Platynereis dumerilii treated with cytochalasin B (CCB) prior to first cleavage, a wide variety of developmental effects were observed. One effect is a delay in the first cleavage. Treated embryos may skip the first or even more than one cleavage cycle and become multinucleated. Once these eggs start cleaving their cleavage plane takes the same position as in synchronously fertilized controls. Accordingly, the first cleavage in embryos having skipped the first normal cleavage cycle is meridional and equal, but their second cleavage is equatorial as in the third cleavage in controls. None of the embryos that were observed to skip early cleavages showed normal organogenesis, but developed into vesicle-shaped embryos with little cytological differentiation. Another effect of CCB treatment is altered blastomere size in those embryos which begin cleaving in synchrony with controls. While the majority of treated embryos followed a normal cleavage pattern, i.e. they cleaved at the right time and inequally, some of them cleaved equally or almost equally (adequally). Most of these embryos showed cleavage defects in subsequent cleavage cycles and became abnormal vesicle-shaped embryos. However, some of these embryos cleaving on schedule and equally or adequally developed into juvenile worms showing complete duplication of urites and parapodial rows (0.3% of all treated eggs) and are described as Janus duplicitates. This means that the occurrence of duplicitates and geometrically altered first cleavage patterns are correlated phenomena. The character and origin of the duplications and the consequences for dorsoventral polarity are discussed.     

Properties of cells from inverted embryos ofXenopus laevis investigated by scanning electron microscopy

Summary Xenopus embryos held inverted from the one cell stage show a partial reversal of the pattern of cleavage: the blastocoel forms towards the new upper pole, and the non-pigmented cells forming the blastocoel roof are smaller than normal endoderm cells. Two properties of the cells from inverted embryos have been studied: their capacity to form cilia when cultured for 48 h, normally a property of ectoderm cells; and their scanning electron microscopical appearance when isolated and cultured for shorter periods, which differs for normal ectoderm and endoderm cells. Groups of the upper, non-pigmented cells from inverted embryos do not form cilia in a longerterm culture, whereas groups of the lower, pigmented cells do. In contrast, the scanning electron microscopical appearance of the upper, non-pigmented cells of inverted embryos is more like that of normal ectoderm cells; the appearance of lower, pigmented cells is more like that of normal endoderm. Thus the determination to form cilia is not reversed by inversion, whereas the control of cell morphology is.     

Insemination of immature sea urchin (Arbacia punctulata) eggs

Nuclei from osmotically opened erythrocytes and erythroblasts were injected into nucleated or enucleated Xenopus laevis eggs. Although the cleavage pattern of the recipient eggs which started to divide was normal in about half of the cases, nuclei from erythrocytes injected into nucleated or enucleated eggs never promoted development beyond the early gastrula stage. In contrast, nuclei from osmotically opened erythroblasts injected into enucleated eggs promoted development to early tadpole stages (stages 29–36). Frequently, injection of osmotically broken erythroblasts injected into nonenucleated eggs gave rise to triploid larvae which all died at roughly the same early tadpole stages (29–36). Surprisingly, development did not proceed to the stage of advanced organogenesis (stages 44–47), which is easily reached by gynogenetic haploids: The presence of the haploid genome derived from the egg pronucleus did not significantly improve the developmental capacity. Embryos obtained by single injection of erythrocyte nuclei into nucleated eggs were unable to pass the gastrula stage. To invalidate the interpretation that the observed arrest in development was related to nuclear damage during injection of the recipient eggs, single unbroken erythrocytes and unbroken erythroblasts were transferred into nucleated and enucleated eggs. No cleavage was observed in both classes of eggs injected with unbroken erythrocytes. In contrast, erythroblasts were found to induce cleavage in the recipient eggs at a frequency of about 11%. To ascertain that the nucleus of unbroken erythroblasts participated in development, the 1-nucleolar marker was used. Diploid embryos with only one nucleolus present were found following injection of unbroken erythroblasts into enucleated eggs from 2nu females. Triploid 2nu embryos were detected following injection of (diploid) 1nu erythroblasts into nonenucleated eggs from 2nu females. The most advanced development stages reached by these embryos did not, however, differ from the best results found in the first class of experiments: Nuclei from erythroblasts injected undamaged into nucleated or enucleated eggs never developed into a normal tadpole. Serial transfer experiments were performed using normally gastrulating embryos which had developed, following the injection of 1nu unbroken erythroblasts into recipient eggs. These donors for serial transfer experiments were checked for the presence of the 1nu marker. In addition they had passed through a normally cleaving eight-cell stage. No improvement in developmental capacity as compared to first transfer experiments could be found.     

Cleavage pattern and survivin expression in porcine embryos by somatic cell nuclear transfer

Mammalian embryos produced in vitro show a high rate of early developmental failure. Numerous somatic cell nuclear transfer (SCNT) embryos undergo arrest and show abnormal gene expression in the early developmental stages. The purpose of this study was to analyze porcine SCNT embryo development and investigate the cause of porcine SCNT embryo arrest. The temporal cleavage pattern of porcine SCNT embryos was analyzed first, and the blastocyst origin at early developmental stage was identified. To investigate markers of arrest in the cleavage patterns of preimplantation SCNT embryos, the expression of survivin—the smallest member of the inhibitor of apoptosis (IAP) gene family, which suppresses apoptosis and regulates cell division—was compared between embryos showing normal cleavage and arrested embryos.A total of 511 SCNT embryos were used for cleavage pattern analysis. Twenty-four hours post activation (hpa), embryos were classified into five groups based on the cleavage stage as follows; 1-cell, 2-cell, 4-cell, 8-cell and fragmentation (frag). In addition, 48 hpa embryos were more strictly classified into 15 groups based on the cleavage stage of 24 hpa; 1-1 cell (24 hpa-48 hpa), 1-2 cell, 1-4 cell, 1-8 cell, 1 cell-frag, 2-2 cell, 2-4 cell, 2-8 cell, 2 cell-frag, 4-4 cell, 4-8 cell, 4 cell-frag, 8-8 cell, 8 cell-frag, and frag-frag. These groups were cultured until 7 d post activation, and were evaluated for blastocyst formation. At 24 hpa, the proportion of 2-cell stage was significantly higher (44.5%) than those in the other cleavage stages (1-cell: 13.4%; 4-cell: 17.9%; 8-cell: 10.3%; and frag: 13.9%). At 48 hpa, the proportion of embryos in the 2-4 cell stage was significantly higher (32.4%) than those in the other cleavage stages (2-8 cell: 8.2%; 4-8 cell: 12.1%; and frag-frag: 13.9%). Some embryos arrested at 48 hpa (1-1 cell: 5.8%; 2-2 cell: 2.8%; 4-4 cell: 3.8%; 8-8 cell: 6.5%; and total arrested embryos: 18.9%). Blastocyst formation rates were higher in 2-4 cell cleavage group (20.2%) than in other groups. SCNT embryos in 2-4 cell stage showed stable developmental competence. In addition, we investigated survivin expression in porcine SCNT embryos during the early developmental stages. The levels of survivin mRNA in 2-cell, 4-cell stage SCNT embryos were significantly higher than those of arrested embryos. Survivin protein expression showed a similar pattern to that of survivin mRNA. Normally cleaving embryos showed higher survivin protein expression levels than arrested embryos. These observations suggested that 2-4 cell cleaving embryos at 48 hpa have high developmental competence, and that embryonic arrest, which may be influenced by survivin expression in porcine SCNT embryos.     

Proteomic analysis reveals CCT is a target of Fragile X mental retardation protein regulation in Drosophila

Fragile X mental retardation protein (FMRP) is an RNA-binding protein that is required for the translational regulation of specific target mRNAs. Loss of FMRP causes Fragile X syndrome (FXS), the most common form of inherited mental retardation in humans. Understanding the basis for FXS has been limited because few in vivo targets of FMRP have been identified and mechanisms for how FMRP regulates physiological targets are unclear. We have previously demonstrated that Drosophila FMRP (dFMRP) is required in early embryos for cleavage furrow formation. In an effort to identify new targets of dFMRP-dependent regulation and new effectors of cleavage furrow formation, we used two-dimensional difference gel electrophoresis and mass spectrometry to identify proteins that are misexpressed in dfmr1 mutant embryos. Of the 28 proteins identified, we have identified three subunits of the Chaperonin containing TCP-1 (CCT) complex as new direct targets of dFMRP-dependent regulation. Furthermore, we found that the septin Peanut, a known effector of cleavage, is a likely conserved substrate of fly CCT and is mislocalized in both cct and in dfmr1 mutant embryos. Based on these results we propose that dFMRP-dependent regulation of CCT subunits is required for cleavage furrow formation and that at least one of its substrates is affected in dfmr1− embryos suggesting that dFMRP-dependent regulation of CCT contributes to the cleavage furrow formation phenotype.     

Morphogenesis in Long-term Maintained Immature Embryo-derived Callus of Wheat (Triticum aestivum L) - Histological Evidence for Both Somatic Embryogenesis and Organogenesis

Callus induced from immature embryos of wheat cv Kharchia 65 on Murashige and Skoog’s medium containing 2.5 mg l¹ 2,4-D was maintained In the regenerable state by subculturing every 5-6 weeks on medium supplemented with 2,4-D (2.5 mg l^-1) and proline (10 mg l^-1). Addition of proline helped maintain morphogenic competence for over four years. The regenerating callus was analysed histologically about one year after first induction. Both somatic embryogenesis and shoot organogenesis were seen in the same callus tissue that contained typical stages of somatic embryoid development and evidence for the de novo shoot bud formation.     

Cleavage pattern in embryos of Haliotis tuberculata (Archaeogastropoda) and gastropod phylogeny

The early cleavage pattern in embryos of the archaeogastropod Haliotis tuberculata strongly resembles the cleavage pattern of the archaeogastropods Trochus and Patella. It typically deviates from the cleavage patterns found in embryos of more advanced Archaeogastropoda, Caenogastropoda (the majority of the meso- and neogastropods), and Euthyneura (opisthobranch and pulmonate gastropods). It is assumed that the cleavage pattern found in Haliotis, Trochus, and Patella represents the ancestral pattern. A regular pattern of heterochronic changes in the succession of the formation of the larval trochoblasts and the stem cell of the adult mesoderm can be observed from the more primitive Archaeogastropoda to the more advanced Euthyneura. This observation strengthens the idea that the early cleavage pattern contains significant phyletic information. © 1993 Wiley-Liss, Inc.     

Development of cell surface activity and cell surface adhesiveness in early embryos of the newt,Cynops pyrrhogaster

The development of cell surface activity and adhesiveness was examined in relation to cleavage number in early embryos of the newt, Cynops pyrrhogaster. Both large hyaline bleb formation and surface adhesiveness to substratum were manifested in presumptive ectodermal cells isolated from embryos after the eleventh cleavage (mid-blastula stage). Scanning electron microscopy of the inner surface of the blastocoelic wall (presumptive ectodermal cell layer) revealed the formation of large blebs after the eleventh cleavage. Treatment with alcian blue and lanthanum nitrate demonstrated the accumulation of an extracellular matrix (ECM) on the surface of large blebs.     

Degeneration pattern in somatic embryos of <Emphasis Type="Italic">Pinus sylvestris</Emphasis> L.

Somatic embryos can be used for propagating forest trees vegetatively, which is of great importance for capturing the genetic gain in breeding programs. However, many economically important Pinus species are difficult or impossible to propagate via somatic embryogenesis. In order to get a better understanding of the difficulties to propagate Pinus species via somatic embryogenesis, we are studying the developmental pathway of somatic embryos in different cell lines. In a previous study, we showed that the morphology of early somatic embryos in Scots pine (Pinus sylvestris) differs between cell lines giving rise to normal or abnormal cotyledonary embryos. In this study, we have compared the proliferation and degeneration pattern of early and late embryos in a normal and abnormal cell line. In both cell lines, a high frequency of the embryos degenerated. Among the degenerating embryos, two main degeneration patterns could be distinguished. In the normal cell line, the embryos degenerated similar to how the subordinate embryos are degraded in the seed. In the abnormal cell line, the degeneration of the embryos resulted in a continuous loop of embryo degeneration and differentiation of new embryos. We observed a similar degeneration pattern when embryogenic tissue was initiated from megagametophytes containing zygotic embryos at the stage of cleavage polyembryony. Based on our results, we suggest that the degeneration pattern in abnormal cell lines starts during initiation of embryogenic cultures.     

Changes in Protein Synthesis upon Cytokinin-Mediated Adventitious Bud Induction and during Seedling Development in Norway Spruce, Picea abies

A pulse-treatment of embryos of Picea abies (L.) Karst with cytokinin efficiently and reproducibly induces the coordinate de novo formation of bud primordia from subepidermal cells. The cytokinin treatment also affects the germinative development of the embryo; chloroplast maturation is delayed, and cell elongation is completely suppressed. We have analyzed the protein patterns in developing spruce embryos with the aim of identifying proteins which are differentially synthesized during early bud-differentiation and germination. In addition to a set of major seed storage proteins and a large set of constitutively synthesized proteins, we distinguish two sets of proteins that showed different patterns of synthesis in relation to germination. One was synthesized at high rates during germination, and the second set during post-germinative seedling development. Twenty-two proteins were differentially synthesized in the bud-induced versus the germinating embryos. Interestingly, all 22 belonged to either the germination phase-abundant or the seedling protein sets, whereas the constitutively synthesized proteins were unaffected by the treatment. Proteins synthesized exclusively in bud-induced embryos were not found. In total, the bud-induction treatment caused a maintenance of a protein synthesis pattern typical for the germination phase in the nontreated embryos, and the de novo formation of buds was not preceded by a major change in gene expression in the tissue.     

Molecular differentiation of the rabbit ovum. II. During the preimplantation development of in vivo and in vitro matured oocytes

The developmental capacity of in vitro matured rabbit oocytes was assessed after transfer to inseminated, ovariectomized recipients such that fertilization and preimplantation development occurred in vivo. The results demonstrate that of the total number of transferred oocytes (1) 75% were fertilized, (2) 50% underwent cleavage, and (3) 13% developed into expanded blastocysts. By light microscopic criteria, embryos recovered at representative stages of preimplantation development were morphologically indistinguishable from embryos recovered at comparable stages from normally mated animals. Autoradiographs produced by high resolution, two-dimensional polyacrylamide gel electrophoresis demonstrated that changes in the pattern of polypeptide synthesis during the preimplantation stages were directly and entirely comparable for embryos derived either from normally mated animals or from in vivo or in vitro matured and transferred oocytes. Up to approximately the eight-cell stage, the translational patterns indicate the progressive disappearance of numerous oocyte-characteristic polypeptides from the autoradiographs as well as the appearance of some new species of polypeptides. Between the eight-cell and early blastocyst period, extensive and complex changes (qualitative and quantitative) occur in the patterns, whereas, in contrast, the phase of blastocyst growth and expansion that occurs during the latter portion of the preimplantation period is characterized by a fairly uniform and constant translational pattern.     

Cell Lineage of the Ilyanassa Embryo: Evolutionary Acceleration of Regional Differentiation during Early Development

Cell lineage studies in mollusk embryos have documented numerous variations on the lophotrochozoan theme of spiral cleavage. In the experimentally tractable embryo of the mud snail Ilyanassa, cell lineage has previously been described only up to the 29-cell stage. Here I provide a chronology of cell divisions in Ilyanassa to the stage of 84 cells (about 16 hours after first cleavage at 23°C), and show spatial arrangements of identified nuclei at stages ranging from 27 to 84 cells. During this period the spiral cleavage pattern gives way to a bilaterally symmetric, dorsoventrally polarized pattern of mitotic timing and geometry. At the same time, the mesentoblast cell 4d rapidly proliferates to form twelve cells lying deep to the dorsal ectoderm. The onset of epiboly coincides with a period of mitotic quiescence throughout the ectoderm. As in other gastropod embryos, cell cycle lengths vary widely and predictably according to cell identity, and many of the longest cell cycles occur in small daughters of highly asymmetric divisions. While Ilyanassa shares many features of embryonic cell lineage with two other caenogastropod genera, Crepidula and Bithynia, it is distinguished by a general tendency toward earlier and more pronounced diversification of cell division pattern along axes of later differential growth.     

小鼠孤雌胚与体内正常胚H3K27三甲基化模式的差异

为了考察小鼠(Mus musculus)孤雌激活胚胎H3K27三甲基化模式与体内正常胚胎之间的差异,以及曲古抑菌素A(TSA)对孤雌胚H3K27三甲基化水平的影响,探究表观遗传修饰对孤雌胚胎发育的作用。首先,用H3K27me3特异性抗体对MⅡ期卵母细胞染色,利用激光共聚焦对其荧光强度进行检测,结果发现该时期的甲基化荧光强度相对较低。接着,采用同样的方法对小鼠孤雌胚胎和体内正常胚胎植入前各时期的H3K27me3模式进行比较,结果显示,从2-细胞到囊胚期孤雌组呈现逐渐升高的趋势,与体内组变化趋势完全相反,且总体平均荧光强度较体内组普遍偏低。孤雌胚胎经TSA处理后,处理组和未处理组在前三个时期虽然没有显著性差异(P0.05),但是处理之后的H3K27三甲基化水平有所提高,囊胚期与未处理组相比有显著性差异(P0.05)。以上结果表明,小鼠孤雌胚胎的H3K27三甲基化模式与体内胚胎之间存在着巨大的差异,这可能是造成孤雌胚胎发育能力差的重要原因之一。TSA处理对H3K27me3模式造成了一定的影响,使体外培养环境有所改善,这可能对提高孤雌胚胎发育能力具有一定的意义。