The function of the nuclear envelope in nuclear protein accumulation.

The mechanism by which proteins accumulate in the cell nucleus is not yet known. Two alternative mechanisms are discussed here: (a) selective unidirectional entry of karyophilic proteins through the nuclear pores, and (b) free diffusion of all proteins through the nuclear pores and specific binding of nuclear proteins to nondiffusible components of the nucleoplasm. We present experiments designed to distinguish between these alternatives. After mechanical injury of the Xenopus oocyte nuclear envelope, nuclear proteins were detected in the cytoplasm by immunohistochemical methods. In a second approach, nuclei from X. borealis oocytes were isolated under oil, the nuclear envelopes were removed, and the pure nucleoplasm was injected into the vegetal pole of X. laevis oocytes. With immunohistochemical methods, it was found that each of five nuclear proteins rapidly diffuses out of the injected nucleoplasm into the surrounding cytoplasm. The subsequent transport and accumulation in the intact host nucleus could be shown for the nuclear protein N1 with the aid of a species-specific mAb that reacts only with X. borealis N1. Purified and iodinated nucleoplasmin was injected into the cytoplasm of Xenopus oocytes and its uptake into the nucleus was studied by biochemical methods.

Immunological localization of a major karyoskeletal protein in nucleoli of oocytes and somatic cells of Xenopus laevis.

Oocyte nuclei of Xenopus laevis contain two major karyoskeletal proteins characterized by their resistance to extractions in high salt buffers and the detergent Triton X-100, i.e. a polypeptide of 68,000 mol wt which is located in the core complex-lamina structure and a polypeptide of 145,000 mol wt enriched in nucleolar fractions. Both proteins are also different by tryptic peptide maps and immunological determinants. Mouse antibodies were raised against insoluble karyoskeletal proteins from Xenopus oocytes and analyzed by immunoblotting procedures. Affinity purified antibodies were prepared using antigens bound to nitrocellulose paper. In immunofluorescence microscopy of Xenopus oocytes purified antibodies against the polypeptide of 145,000 mol wt showed strong staining of nucleoli, with higher concentration in the nucleolar cortex, and of smaller nucleoplasmic bodies. In various other cells including hepatocytes, Sertoli cells, spermatogonia, and cultured kidney epithelial cells antibody staining was localized in small subnucleolar granules. The results support the conclusion that this "insoluble" protein is a major nucleus-specific protein which is specifically associated with--and characteristic of--nucleoli and certain nucleolus-related nuclear bodies. It represents the first case of a positive localization of a karyoskeletal protein in the nuclear interior, i.e. away from the pore complex-lamina structure of the nuclear cortex.

Enzyme from calf thymus degrading the RNA moiety of DNA-RNA Hybrids: effect on DNA-dependent RNA polymerase.

An enzyme present in extracts from calf thymus degrades specifically the RNA moiety of DNA-RNA hybrids. Other nucleic acids, such as single- or double-stranded DNA and single- or double-stranded RNA, are not affected to a comparable degree. If prepared free of the hybrid-degrading enzyme, RNA polymerase from calf thymus shows a fivefold increase in activity on denatured DNA as compared to native DNA.

Bottle cell formation in relation to mesodermal patterning in the Xenopus embryo.

The appearance of bottle cells at the dorsal vegetal/marginal boundary of Xenopus embryos marks the onset of blastopore formation. The conditions leading to this epithelial activity were investigated by inducing bottle cells ectopically in the animal region with VegT or different members of the transforming growth factor (TGF)-beta family. Morphological studies on the ectopic bottle cells indicate their close similarity to the endogenous bottle cells at the dorsal blastopore lip. The subepithelial cells of the induced animal region express mesodermal genes in a pattern reminiscent to that observed on the dorsal lip. Relating this expression pattern to the position of the ectopic bottle cells leads to the conclusion that bottle cells form in regions of high TGF-beta signalling. The specific inhibitory effects of cerberus on ectopically induced bottle cells revealed that nodal related growth factors are the intrinsic signals that elicit bottle cell formation in the normal embryo. In addition, fibroblast growth factor signalling is an essential precondition for this epithelial response as it is for mesoderm formation. We conclude that bottle cell formation in the epithelial layer of the gastrula is closely linked to mesodermal patterning in the subepithelial tissues.

Pre-MBT patterning of early gene regulation in Xenopus: the role of the cortical rotation and mesoderm induction.

Patterning events that occur before the mid-blastula transition (MBT) and that organize the spatial pattern of gene expression in the animal hemisphere have been analyzed in Xenopus embryos. We present evidence that genes that play a role in dorsoventral specification display different modes of activation. Using early blastomere explants (16-128-cell stage) cultured until gastrula stages, we demonstrate by RT-PCR analysis that the expression of goosecoid (gsc), wnt-8 and brachyury (bra) is dependent on mesoderm induction. In contrast, nodal-related 3 (nr3) and siamois (sia) are expressed in a manner that is independent of mesoderm induction, however their spatially correct activation does require cortical rotation. The pattern of sia and nr3 expression reveals that the animal half of the 16-cell embryo is already distinctly polarized along the dorsoventral axis as a result of rearrangement of the egg structure during cortical rotation. Similar to the antagonistic activity between the ventral and the dorsal mesoderm, the ventral animal blastomeres can attenuate the expression of nr3 and sia in dorsal animal blastomeres. Our data suggest that no Nieuwkoop center activity at the blastula stage is required for the activation of nr3 and sia in vivo.

A beta 1-integrin associated alpha-chain is differentially expressed during Xenopus embryogenesis.

The antigen of mAb 2F10 was identified as a Xenopus beta 1-integrin associated alpha-chain by the criteria (1) that it coprecipitates with anti beta 1-antibody, (2) that it changes molecular mass upon reduction in a way that is characteristic for integrin alpha-chains and (3) that it is present on cell membranes. This alpha-chain, termed alpha 2F10, is found in small amounts in the pregastrula stages of Xenopus development and accumulates thereafter in the embryo, alpha 2F10 can be detected by immunofluorescence first at stage 17 of embryogenesis on the cell membranes of the sensorial layer of the ectoderm, the notochord and the endoderm. This characteristic pattern of distribution is maintained throughout the following embryonic stages. Timed explanation experiments indicate that all cells of the pregastrula have the potency to express alpha 2F10. This potency becomes successively restricted during gastrulation to yield the ultimate pattern of expression.

Maturation induced internalization of beta 1-integrin by Xenopus oocytes and formation of the maternal integrin pool.

A pool of beta 1-integrin, ready to be inserted into the cleavage membranes, is present in the cytoplasm of the Xenopus egg, while its plasma membrane is devoid of this membrane protein (Gawantka et al., 1992). The underlying mechanisms that lead to this specific pattern of beta 1-integrin distribution in the egg have been investigated. beta 1-Integrin is present on the oocyte membrane throughout oogenesis. During maturation the oocyte membrane is cleared of beta 1-integrin via internalization of the protein by the oocyte. Synthesis of beta 1-integrin precursor is stimulated moderately in the maturing oocyte. At the same time processing of the precursor into the mature form of beta 1-integrin and its complexing with a putative alpha-chain is greatly accelerated. This way a maternal integrin pool accumulates in the mature oocyte. It is localized in conspicuous yolk free patches which contain large amounts of endoplasmic reticulum, Golgi complexes and smooth vesicles. We suggest that membrane vesicles harbouring the beta 1-integrin are generated in these cytoplasmic regions and that this store of vesicles provides the material source for the rapid membrane formation during cleavage.

A paired oocyte adhesion assay reveals the homophilic binding properties of the Xenopus maternal cadherins, XB/U- and EP-cadherin.

The homophilic nature of cadherin-mediated cell-cell adhesion provides an organism with the opportunity of altering the adhesive capabilities of its cells by selectively modulating the expression of different cadherin types. Differential cadherin expression is of major importance in regulating the cell rearrangements involved in the processes which shape tissues and organs during embryogenesis. The pregastrula embryo of Xenopus laevis expresses two maternally supplied cadherins: XB/U-cadherin and EP-cadherin. Since these two proteins are almost 92% identical at the amino acid level, it was unclear whether heterophilic interactions between them were possible. Different functional roles can only be ascribed to the two cadherins if the possibility of heterophilic binding between them can be excluded. We describe a simple and straightforward assay which can be used to assess interactions between adhesion molecules. A combination of antisense oligonucleotide and enzyme treatments eliminates endogenous cadherins in Xenopus oocytes and subsequent injection of a specific mRNA yields oocytes carrying only one or the other cadherin. After removal of the vitelline membranes, two oocytes expressing the appropriate cadherins will adhere to one another when they are placed in close contact. By scoring for adhesion in homotypic and heterotypic pairings, we demonstrate that XB/U-cadherin and EP-cadherin do not interact with one another.

Beta-catenin translocation into nuclei demarcates the dorsalizing centers in frog and fish embryos.

The question of how dorsal-ventral polarity is established in vertebrates is central to our understanding of their early development. Several lines of evidence suggest that wnt-signaling is involved in the induction of dorsal-specific gene expression in the Spemann Organizer of amphibians. Here, we show that beta-catenin, acting as a component of the wnt-pathway, transiently accumulates in nuclei on the dorsal side of Xenopus and zebrafish blastulae. The spatially restricted nuclear translocation of beta-catenin precedes the expression of dorsal-specific genes. In experimentally ventralized frog embryos the dorsal ventral pattern of beta-catenin nuclear staining is abolished; in contrast, embryos hyperdorsalized by Li-ions or by injection of Xwnt8 mRNA exhibit an enhanced nuclear accumulation of beta-catenin. The results show that translocation of beta-catenin into nuclei in the wake of wnt-signaling is an early step in the establishment of the dorsal-ventral axis in frog and fish embryos.

Tight junction biogenesis in the early Xenopus embryo.

Tight junctions (TJs) perform a critical role in the transport functions and morphogenetic activity of the primary epithelium formed during Xenopus cleavage. Biogenesis of these junctions was studied by immunolocalization of TJ-associated proteins (cingulin, ZO-1 and occludin) and by an in vivo biotin diffusion assay. Using fertilized eggs synchronized during the first division cycle, we found that membrane assembly of the TJ initiated at the animal pole towards the end of zygote cytokinesis and involved sequential incorporation of components in the order cingulin, ZO-1 and occludin. The three constituents appeared to be recruited from maternal stores and were targeted to the nascent TJ site by different pathways. TJ protein assembly was focused precisely to the border between the oolemma-derived apical membrane and newly-inserted basolateral membrane generated during cytokinesis and culminated in the formation of functional TJs in the two-cell embryo, which maintained a diffusion barrier. New membrane formation and the generation of cell surface polarity therefore precede initiation of TJ formation. Moreover, assembly of TJ marker protein precisely at the apical-basolateral membrane boundary was preserved in the complete absence of intercellular contacts and adhesion. Thus, the mechanism of TJ biogenesis in the Xenopus early embryo relies on intrinsic cues of a cell autonomous mechanism. These data reveal a distinction between Xenopus and mammalian early embryos in the origin and mechanisms of epithelial cell polarization and TJ formation during cleavage of the egg.

Integrin alpha 5 during early development of Xenopus laevis.

The full length sequence of the Xenopus integrin alpha 5 subunit is reported. Analysis of cloned cDNA fragments reveals that alternative polyadenylation of alpha 5 mRNA occurs in the embryo. Furthermore, a variant form of the alpha 5 mRNA is expressed which encodes an integrin alpha 5 subunit with a truncated cytoplasmic domain. Integrin alpha 5 mRNA and protein are expressed in oocytes, eggs and throughout development. Spatial expression of alpha 5 mRNAs is first detected by whole mount in situ hybridization in presumptive neural crest cells and in the somitic mesoderm from the midgastrula stage onwards. In contrast, the alpha 5 protein is present on newly formed plasma membranes beginning at first cleavage. During neurulation, the integrin alpha 5 subunit disappears from the outer layer of the ectoderm, the notochord and the neural tube and accumulates in the sensorial layer of the ectoderm, the somites and the neural crest cells. These results provide evidence for the position specific regulation of alpha subunit expression in early vertebrate embryos.

Xenopus cadherins: the maternal pool comprises distinguishable members of the family.

Three maternal cadherins have been reported to occur in the pregastrula Xenopus embryo. EP- and XB-cadherin are distinguished by their distinct cDNA sequences. U-cadherin has been characterized by its reaction with a specific monoclonal antibody (mAb 6D5). Thus far, lack of specific probes that discriminate between these molecules has prevented their identification as distinct cadherins. We now demonstrate by means of RNase protection assays that both EP- and XB-cadherin mRNAs are present in oocytes and mature eggs. By use of the Xenopus cadherin proteins expressed in mammalian cell lines, we find that mAb 6D5 crossreacts with XB-cadherin, but not with EP-cadherin. The major fraction of the maternal cadherins does not contain the 6D5 epitope and probably represents EP-cadherin. A minor fraction carries the 6D5 epitope indicative for the XB- and U-type of cadherins. We have termed this fraction XB/U-cadherin. The function of maternal cadherins was examined by in vitro cell adhesion assays. A newly developed antiserum with a broad specificity for various Xenopus cadherins efficiently blocks all calcium dependent cell adhesion in the early embryo. We conclude that the maternal cadherins play a central role in interblastomere adhesion in the early embryo and comprise at least two discrete cadherin forms, EP- and XB/U-cadherin.

Cloning of the Xenopus integrin alpha(v) subunit and analysis of its distribution during early development.

One striking feature of the integrin alpha(v) subunit is its ability to associate with at least five different beta subunits (beta1, beta3, beta5, beta6 and beta8) to form functional receptors. These receptors are involved in diverse biological processes, such as differentiation, cell adhesion and migration. Here we report the cloning of the Xenopus homolog of the integrin alpha(v) subunit. Integrin alpha(v) mRNA and protein are maternally supplied and present throughout development. During gastrulation and neurulation alpha(v) protein appears on cell membranes of all three germ layers. In tailbud stage embryos great amounts of the alpha(v) protein can be observed in the inner layer of the ectoderm and in the endothelial cells lining the pharynx and gut.

A new method to prepare sections from amphibian embryos for immunohistology.

The method involves impregnation of fixed embryos with a solution of plexiglass. The solvent is evaporated slowly. Blocks of plexiglass containing the specimen are thus formed. Sections (1-2 microns) are stretched and attached by an unconvential method. Immunohistological techniques allow antigen localization in a combination of high resolution, excellent quality of the sections and low background.

Planar polarity in the ciliated epidermis of Xenopus embryos.

The coordinated orientation of ciliary beat in the larval epidermis of amphibians, evident in an organized streamline pattern, suggests a planar polarity of the epithelium, i.e., a polarity within the plane of the cell sheet. It has been proposed that the direction of ciliary beat is determined at mid gastrula by a gradient of a diffusible factor produced by the mesoderm. To analyze whether ectoderm in isolation can establish a uniform direction of ciliary beat, and at what stage its polarity is specified in the embryo, ectoderm of Xenopus laevis embryos of different stages was cultured in vitro on substrates. On concanavalin A, ectoderm isolated at early gastrula stages, i.e., prior to any contact with mesoderm, can autonomously coordinate the direction of ciliary beat, at least in small regions. A uniform planar polarity is expressed by ectoderm explanted from the early mid gastrula onward. On fibronectin, which promotes migration, the direction of movement correlates well with the direction of ciliary beat, and directional migration can even override the inherent polarity specified prior to explantation. Embryos which lack dorsal mesoderm nevertheless develop a highly organized streamline pattern, excluding a strict requirement for dorsal mesoderm for the determination of planar polarity. However, in spite of the early specification of planar polarity found for isolated tissue, rotated ectodermal transplants in situ can readjust their polarity in accordance with that of the host.

Development of the lateral line system in Xenopus laevis. II. Cell multiplication and organ formation in the supraorbital system.

Cell multiplication was studied during development of the supraorbital lateral line system in Xenopus laevis. The increase in cell number is biphasic. The first phase extends from the beginning of primordial elongation to the end of primary organ formation. Cell number increases linearly during this interval. Throughout this phase, a constant number of cells is in S phase of the cell cycle at a given time, despite a more than 10-fold increase in total cell number. After their formation, the number of the primary organs remains essentially constant. The individual primary organs are not clones of cells. Different organs grow at different rates, and become more and more heterogeneous in size. The second phase which is correlated with accessory organ formation is characterized by an elevated growth rate. This phase was not studied in detail. If developing larvae are starved, growth is normal up to completion of the first growth phase but is arrested at this point. The frequency distribution of the sizes of such growth-arrested organs approximates a binominal distribution. From its characteristics, a detailed model of cell proliferation and organ formation can be deduced: cell multiplication occurs through asymmetrically dividing stem cells, which become allocated to the forming organs at random and go through a fixed number of cell divisions.

Development of the lateral line system in Xenopus laevis. I. Normal development and cell movement in the supraorbital system.

During development of Xenopus laevis, the supraorbital lateral line system (i.e. the parietal and supraorbital lines of organs and the anterior auditory group of organs) is all derived from a single primordium located in the ear region of the epidermis. The primordium elongates first by active movement along the dorsal margin of the eye. Individual primary organs are then formed by progressive fragmentation of the streak-like primordium. After fragmentation, passive displacement of the organs due to skin growth seems to play the main role in altering the arrangement of the line system. Transplantation experiments confirmed that non-placodal epidermal cells are not incorporated into the developing system. The active elongation of the primordium is due to cell multiplication, and not due to cell rearrangement or change in cell shape or size. Cell multiplication is not confined to a growth zone, but dividing cells are randomly distributed throughout the primordium. All cells of a primordium have to change position during its elongation.

Two-dimensional gel analysis of the fate of oocyte nuclear proteins in the development of Xenopus laevis.

The amphibian oocyte nucleus is thought to provide a maternal store of protein required in embryogenesis. The fate of germinal vesicle proteins has been studied by comparing polypeptide patterns of oocytes, embryos, and several adult organs of Xenopus laevis on two-dimensional gels. A combination of silver staining and fluorography of radiolabeled protein on gels was used to analyze maternal and newly synthesized polypeptides in embryogenesis. Comparison of protein patterns was facilitated and corroborated by application of monoclonal antibodies against several germinal vesicle proteins. These were characterized by immunoblotting from two-dimensional gels, and polypeptides of identical structure were recognized in oocyte nuclei, embryos, and tadpoles. The following conclusions were drawn: (1) Almost all prevalent germinal vesicle proteins can be continuously traced in embryos up to swimming tadpole stages, although their patterns of new synthesis are greatly different, some are not radiolabeled in the embryo but solely provided by the maternal store. (2) Many of the polypeptides occurring in oocyte nuclei are also found in one or several organs of the adult. (3) Tissue specificities of germinal vesicle proteins, previously detected by immunocytochemistry with monoclonal antibodies, could be confirmed by independent biochemical methods. (4) As has been previously shown by immunohistological methods, oocyte nuclear antigens are shed into the cytoplasm of the maturing egg, and are reaccumulated in the nuclei of the embryonic cells, each at a characteristic developmental stage. These shifts between intracellular compartments are not accompanied by a change of the covalent structure of the antigen.

On the activity of RNA polymerase B in lysates from Ehrlich ascites cells.

Transcription by endogenous RNA polymerase B in lysates of Ehrlich ascites cells was investigated. The enzyme exhibits two salt optima at 0.025 M and at 0.3 M (NH4)2SO4 respectively. Preincubation of the cells with the nucleoside analogue 5,6-dichloro-1-beta-D-ribofuranosylbenzimidazole results in an inactivation of the polymerase molecules active under condition of low salt. This indicates two functional states of the enzyme in vivo. Initiations of RNA chains by polymerase B do not occur in vitro as judged by the incorporation of [beta-32P]GTP. Thus the two functional states seem to be both elongating polymerase molecules. Polymerase B does not occur in the lysates in a state ready to initiate on an exogenous template, in contrast to polymerase A and C which do occur in free form. Pretreatment with dichlororibofuranosylbenzimidazole in vivo does not result in an accumulation of free polymerase B.