Regulated replication of DNA microinjected into eggs of Xenopus laevis

Purified circular DNA of SV40 or polyoma virus has been injected into unfertilized eggs of Xenopus laevis. Injected DNA initiates and completes multiple rounds of semiconservative replication while observing cellular regulatory signals. Thus replication initiation of double-stranded templates is induced after the oocyte is matured in vitro by progesterone. Only one round of replication of injected DNA is observed in a single cell cycle. When protein synthesis is inhibited unreplicated molecules continue to initiate replication at an undiminished rate, but reinitiation on previously replicated molecules is completely and selectively abolished. The DNA sequence requirements for the replication of injected DNA have been investigated. A variety of procaryotic DNA molecules and circularized fragments of SV40 or polyoma DNA replicate, regardless of whether they contain the viral origin of DNA replication. These results suggest that a specialized DNA sequence is not essential for the initiation of semiconservative DNA replication in the Xenopus embryo, nor is a specialized sequence essential for the mechanism which prevents reinitiation on a molecule which has already replicated within a cell cycle. The possibility is discussed that viral origins of replication are not valid models for the eucaryotic chromosome but are adaptations for uncoupling viral replication from the mechanism which prevents reinitiation within a cell cycle.     

Persistence and replication of plasmid DNA microinjected into early embryos of Xenopus laevis

The persistence and replication of defined circular and linear plasmid DNA molecules microinjected into fertilized eggs of Xenopus laevis were analyzed. For all plasmids tested, a small fraction of microinjected circular molecules was replicated; however, the overall copy numbers of either free form I or form II molecules usually did not increase through blastulation. In contrast, extensive amplification of input DNA sequences was seen whenever the microinjected DNA was assembled into high molecular weight concatemers. Moreover, the appearance and subsequent replication of injected sequences in high molecular weight DNA were enhanced when linear (form III), rather than circular, molecules were microinjected. The injected form III DNA was rapidly converted into long linear concatemers. All possible orientations of monomeric molecules within the concatemers were observed although, on occasion, head-to-tail orientations were favored. Long linear concatemers were replicated very efficiently, irrespective of the sequence of the input DNA. Form I and form II DNA molecules were also formed in the embryo from microinjected form III DNA. A small fraction of these circular forms was replicated, although overall copy numbers did not increase significantly. Form III molecules that remained monomeric were not observed to be replicated at all within our limits of detection. In some batches of embryos, form I and form II DNA molecules were replicated to the extent that overall copy number increased. Even in these cases, however, the amplification of long linear concatemers of the input DNA sequences was more efficient.     

The midblastula transition defines the onset of Y RNA-dependent DNA replication in Xenopus laevis

Noncoding Y RNAs are essential for the initiation of chromosomal DNA replication in mammalian cell extracts, but their role in this process during early vertebrate development is unknown. Here, we use antisense morpholino nucleotides (MOs) to investigate Y RNA function in Xenopus laevis and zebrafish embryos. We show that embryos in which Y RNA function is inhibited by MOs develop normally until the midblastula transition (MBT) but then fail to replicate their DNA and die before gastrulation. Consistent with this observation, Y RNA function is not required for DNA replication in Xenopus egg extracts but is required for replication in a post-MBT cell line. Y RNAs do not bind chromatin in karyomeres before MBT, but they associate with interphase nuclei after MBT in an origin recognition complex (ORC)-dependent manner. Y RNA-specific MOs inhibit the association of Y RNAs with ORC, Cdt1, and HMGA1a proteins, suggesting that these molecular associations are essential for Y RNA function in DNA replication. The MBT is thus a transition point between Y RNA-independent and Y RNA-dependent control of vertebrate DNA replication. Our data suggest that in vertebrates Y RNAs function as a developmentally regulated layer of control over the evolutionarily conserved eukaryotic DNA replication machinery.     

Differential replication of circular DNA molecules co-injected into early Xenopus laevis embryos.

Replication of co-injected supercoiled DNA molecules in fertilized Xenopus eggs was monitored through the blastula stage of development. The extent of replication, as measured by 32P-dTMP incorporation into form I DNA, was directly proportional to the number of molecules, rather than the size, of the plasmid injected. Although only a small fraction of molecules of either template was replicated, incorporation was predominantly into full length daughter molecules. Over at least a 20-fold concentration range of microinjected DNA, injection of equal masses of DNA resulted in greater incorporation into the smaller form I DNA present in molar excess. The extent of incorporation into supercoiled DNA for a particular plasmid was apparently independent of the concentration of a second, co-injected plasmid. The relative extents of replication of co-injected supercoiled templates could be altered simply by changing the molar ratios of the templates.     

Identification of the Xenopus laevis homolog of Saccharomyces cerevisiae DNA2 and its role in DNA replication

The DNA2 gene of Saccharomyces cerevisiae is essential for growth and appears to be required for a late stage of chromosomal DNA replication. S. cerevisiae Dna2p (ScDna2p) is a DNA helicase and also a nuclease. We have cloned and sequenced the homologous gene from Xenopus (Xenopus Dna2). Xenopus Dna2p (XDna2p) is 32% identical to ScDna2p, and the similarity extends over the entire length, including but not limited to the five conserved helicase motifs. XDna2p is even more closely related (60% identical) to a partial human cDNA. The Xenopus Dna2 (XDna2) gene was able to complement an S. cerevisiae dna2-1 mutant strain for growth at the nonpermissive temperature, suggesting that XDna2p is a functional as well as a structural homolog of the yeast protein. Recombinant XDna2p was expressed in insect cells and purified. Like the ScDna2p purified from yeast, it is a single-stranded DNA endonuclease and a DNA-dependent ATPase, suggesting that both of these activities are part of the essential function of Dna2p. However, unlike ScDna2p from yeast, recombinant XDna2p showed no DNA helicase activity. When XDna2 was immunodepleted from interphase egg extracts, chromosomal DNA replication was almost completely inhibited. From the size of the residually synthesized DNA from the XDna2-depleted egg extracts, it seems that initiation of DNA replication may be impaired. This interpretation is also supported by the normal DNA replication of M13 single-stranded DNA in the XDna2-depleted egg extracts.     

Nuclear proteins of quiescent Xenopus laevis cells inhibit DNA replication in intact and permeabilized nuclei

Quiescent cells from adult vertebrate liver and contact-inhibited or serum-deprived tissue cultures are active metabolically but do not carry out nuclear DNA replication and cell division. Replication of intact nuclei isolated from either quiescent Xenopus liver or cultured Xenopus A6 cells in quiescence was barely detectable in interphase extracts of Xenopus laevis eggs, although Xenopus sperm chromatin was replicated with approximately 100% efficiency in the same extracts. Permeabilization of nuclei from quiescent Xenopus liver or cultured Xenopus epithelial A6 cells did not facilitate efficient replication in egg extracts. Moreover, replication of Xenopus sperm chromatin in egg extracts was strongly inhibited by a soluble extract of isolated Xenopus liver nuclei; in contrast, complementary-strand synthesis on single-stranded DNA templates in egg extracts was not affected. Inhibition was specific to endogenous molecules localized preferentially in quiescent as opposed to proliferating cell nuclei, and was not due to suppression of cdk2 kinase activity. Extracts of Xenopus liver nuclei also inhibited growth of sperm nuclei formed in egg extracts. However, the rate and extent of decondensation of sperm chromatin in egg extracts were not affected. The formation of prereplication centers detected by anti-RP-A antibody was not affected by extracts of liver nuclei, but formation of active replication foci was blocked by the same extracts. Inhibition of DNA replication was alleviated when liver nuclear extracts were added to metaphase egg extracts before or immediately after Ca++ ion-induced transition to interphase. A plausible interpretation of our data is that endogenous inhibitors of DNA replication play an important role in establishing and maintaining a quiescent state in Xenopus cells, both in vivo and in cultured cells, perhaps by negatively regulating positive modulators of the replication machinery.     

Embryonic wound healing by apical contraction and ingression in Xenopus laevis

We have characterized excisional wounds in the animal cap of early embryos of the frog Xenopus laevis and found that these wounds close accompanied by three distinct processes: (1) the assembly of an actin purse-string in the epithelial cells at the wound margin, (2) contraction and ingression of exposed deep cells, and (3) protrusive activity of epithelial cells at the margin. Microsurgical manipulation allowing fine control over the area and depth of the wound combined with videomicroscopy and confocal analysis enabled us to describe the kinematics and challenge the mechanics of the closing wound. Full closure typically occurs only when the deep, mesenchymal cell-layer of the ectoderm is left intact; in contrast, when deep cells are removed along with the superficial, epithelial cell-layer of the ectoderm, wounds do not close. Actin localizes to the superficial epithelial cell-layer at the wound margin immediately after wounding and forms a contiguous "purse-string" in those cells within 15 min. However, manipulation and closure kinematics of shaped wounds and microsurgical cuts made through the purse-string rule out a major force-generating role for the purse-string. Further analysis of the cell behaviors within the wound show that deep, mesenchymal cells contract their apical surfaces and ingress from the exposed surface. High resolution time-lapse sequences of cells at the leading edge of the wound show that these cells undergo protrusive activity only during the final phases of wound closure as the ectoderm reseals. We propose that assembly of the actin purse-string works to organize and maintain the epithelial sheet at the wound margin, that contraction and ingression of deep cells pulls the wound margins together, and that protrusive activity of epithelial cells at the wound margin reseals the ectoderm and re-establishes tissue integrity during wound healing in the Xenopus embryonic ectoderm.     

Structural modifications induced by the mtDBP-C protein in the replication origin of Xenopus laevis mitochondrial DNA

The structure of the non-coding region of Xenopus laevis mitochondrial DNA has been studied by electron microscopy analysis of DNA molecules end-labelled with streptavidin-ferritin. We have shown that the effect of a protein modifying the shape of the DNA double-helix can be studied and precisely located by this method. It was found that the non-coding region contains curved segments and that the mitochondrial protein mtDBP-C preferentially enhances the curvature of the promoters-replication origin region.     

Differential compartmentalization of plasmid DNA microinjected into Xenopus laevis embryos relates to replication efficiency.

Circular plasmid DNA molecules and linear concatemers formed from the same plasmid exhibit strikingly different fates following microinjection into Xenopus laevis embryos. In this report, we prove quantitatively that only a minority of small, circular DNA molecules were replicated (mean = 14%) from fertilization through the blastula stage of development. At all concentrations tested, very few molecules (approximately 1%) underwent more than one round of DNA synthesis within these multiple cell cycles. In addition, unlike endogenous chromatin, the majority of circular templates became resistant to cleavage by micrococcal nuclease. The extent of nuclease resistance was similar for both replicated and unreplicated templates. Sequestration of circular molecules within a membranous compartment (pseudonucleus), rather than the formation of nucleosomes with abnormal size or spacing, apparently conferred the nuclease resistance. In contrast, most linearly concatenated DNA molecules (derived from end-to-end joining of microinjected monomeric plasmid DNA) underwent at least two rounds of DNA replication during this same period. Linear concatemers also exhibited micrococcal nuclease digestion patterns similar to those seen for endogenous chromatin yet, as judged by their failure to persist in later stages of embryogenesis, were likely to be replicated and maintained extrachromosomally. We propose, therefore, that template size and conformation determine the efficiency of replication of microinjected plasmid DNA by directing DNA to a particular compartment within the cell following injection. Template-dependent compartmentalization may result from differential localization within endogenous nuclei versus extranuclear compartments or from supramolecular assembly processes that depend on template configuration (e.g., association with nuclear matrix or nuclear envelope).     

Tetracycline-regulated gene expression switch in Xenopus laevis

Xenopus is a well-characterized model system for the investigation of biological processes at the molecular, cellular, and developmental level. The successful application of a rapid and reliable method for transgenic approaches in Xenopus has led to renewed interest in this system. We have explored the applicability of tetracycline-regulated gene expression, first described by Gossen and Bujard in 1992, to the Xenopus system. By optimizing conditions, tetracycline repressor induced expression of a luciferase reporter gene was readily and reproducibly achieved in both the Xenopus oocyte and developing embryo. This high level of expression was effectively abrogated by addition of low levels of tetracycline. The significance of this newly defined system for studies of chromatin dynamics and developmental processes is discussed.     

Mitochondria DNA synthesis in oocytes of Xenopus laevis

The process of attachment was studied in primary mouse kidney epithelial cell cultures by means of reflexion contrast microscopy, a method developed for studying the cell membrane-substrate relationship. The first in a series of events is simple adherence to the substrate, called close contact. This phenomenon is associated with the greatest extension of lamellar cytoplasm and the fewest number of cell nuclei/unit area. The nuclei of such cells are in close contact with the bottom portion of the cell membrane. Approx. 24 h after planting, as the cultures become more crowded, cells develop a different kind of attachment to the substrate—focal contacts—that are correlated with a decrease in lamellar cytoplasm. Cells detached from the substrate after close contact formation readily reattach, while cells detached after formation of focal contacts do not reattach. After incubation for periods greater than 5 days, the dense cultures degenerate and cells lose their attachment to the glass surface.     

Live-cell Imaging and Quantitative Analysis of Embryonic Epithelial Cells in Xenopus laevis

Embryonic epithelial cells serve as an ideal model to study morphogenesis where multi-cellular tissues undergo changes in their geometry, such as changes in cell surface area and cell height, and where cells undergo mitosis and migrate. Furthermore, epithelial cells can also regulate morphogenetic movements in adjacent tissues¹. A traditional method to study epithelial cells and tissues involve chemical fixation and histological methods to determine cell morphology or localization of particular proteins of interest. These approaches continue to be useful and provide "snapshots" of cell shapes and tissue architecture, however, much remains to be understood about how cells acquire specific shapes, how various proteins move or localize to specific positions, and what paths cells follow toward their final differentiated fate. High resolution live imaging complements traditional methods and also allows more direct investigation into the dynamic cellular processes involved in the formation, maintenance, and morphogenesis of multicellular epithelial sheets. Here we demonstrate experimental methods from the isolation of animal cap tissues from Xenopus laevis embryos to confocal imaging of epithelial cells and simple measurement approaches that together can augment molecular and cellular studies of epithelial morphogenesis.Download video file.^{(77M, mp4)}     

Bleomycin-induced DNA damage and repair in Xenopus laevis and Xenopus tropicalis

Microgel cell electrophoresis has been used with various species to measure breakage of DNA and DNA repair following exposure to the radiomimetic antibiotic, bleomycin. With humans, a high degree of DNA damage is considered to be predictive of cancer susceptibility. Non-isogeneic Xenopus laevis, the South African clawed toad, rarely develop spontaneous or induced cancers. Here, we investigate bleomycin-induced DNA damage and repair in splenic lymphocytes of this species to test consistency with cancer predictability. As X. laevis is pseudotetraploid in nature, while Xenopus tropicalis is diploid, we additionally explore the effect of polyploidy on DNA damage and repair in these vertebrates. The results show that higher doses of bleomycin are required to induce comparable levels of DNA damage in both Xenopus species, than in humans. X. tropicalis, the diploid, is more bleomycin-sensitive than is X. laevis. Additionally, repair rates of damaged DNA of X. laevis lymphocytes are more rapid than those of X. tropicalis, although both are hours slower than human leukocytes. While no data exist on cancer susceptibility in X. tropicalis, the results suggest greater susceptibility to cancer than X. laevis, but less than in humans. Thus, polyploidy serves as a protection against DNA damage and allows more rapid repair.     

Differential expression of two cadherins in Xenopus laevis

Using a cadherin fraction from Xenopus tissue culture cells as an immunogen, two monoclonal antibodies were obtained that allowed the characterization of two distinct cadherins in the Xenopus embryo. The two cadherins differ in molecular weight, in their time of appearance during development and in their spatial pattern of expression. One of the antigens was identified as E-cadherin. It appears in the embryonic ectoderm during gastrulation when epidermal differentiation commences and it disappears from the neural plate area upon neural induction. The second antigen could not be allocated to any of the known cadherin subtypes and was termed U-cadherin. It is present in the egg and becomes deposited in newly formed inner cell membranes during cleavage, the outer apical membranes of the embryo remaining devoid of the cadherin throughout development. U-cadherin is found on membranes of all cells up to the late neurula stages. A conspicuous polarized expression of the antigen on the membranes of individual inner cells suggests its participation in the segregation of cell layers and organ anlagen. These findings are discussed in the context of current hypotheses on the role of cadherins in establishing the spatial structure of the embryo.     

Developmental expression of Shisa-2 in Xenopus laevis

Shisa is an antagonist of Wnt and FGF signaling, that functions cell autonomously in the endoplasmic reticulum (ER) to inhibit the post-translational maturation of Wnt and FGF receptors. In this paper we report the isolation of a second Xenopus shisa gene (Xshisa-2). Xenopus Shisa-2 shows 30.7% identity to Xshisa. RT-PCR analysis indicated that Xshisa-2 mRNA is present throughout early development and shows an increased expression during neurula and tailbud stages. At neurula stages Xenopus shisa-2 is initially expressed in the presomitic paraxial mesoderm and later in the developing somites. The expression profiles and pattern of Xshisa and Xshisa-2 differ significantly. During gastrulation only Xshisa mRNA is present in the Spemann-Mangold organizer and later on becomes restricted to the neuroectoderm and the prechordal plate.