Emerin expression in early development of Xenopus laevis

Emerin is an integral protein of the inner nuclear membrane in the majority of differentiated vertebrate cells. In humans, deficiency of emerin causes a progressive muscular dystrophy of the Emery-Dreifuss type. The physiological role of emerin is poorly understood. By screening and sequencing of EST clones we have identified two emerin homologues in Xenopus laevis, Xemerin1 and Xemerin2. Xemerins share with mammalian emerins the N-terminal LEM domain and a single transmembrane domain at the C-terminus. As shown by immunoblot analysis with Xemerin-specific antibodies, both proteins have an apparent molecular mass of 24 kDa but differ in their isoelectric points. Xemerin1 and Xemerin2 proteins are not detectable in oocytes nor during early embryogenesis. Protein expression is first found at stage 43 and persists in somatic cells. However, RT-PCR and Northern blot analysis show Xemerin mRNAs of approximately 4.0 kb to be present in oocytes and throughout embryogenesis. During embryogenesis the level of Xemerin mRNAs increases at stage 22 and is particularly abundant in mesodermal and neuro-ectodermal regions of the embryo. These data provide the necessary background to further investigate the role of emerin in nuclear envelope assembly, gene expression and organ development of X. laevis as a model organism.     

Regulated gene expression of hyaluronan synthases during Xenopus laevis development

Here reported is the developmental gene expression pattern of the three known vertebrate hyaluronan synthases (XHas1, XHas2 and XHas3) and a comparative analysis of their mRNAs spatio-temporal distribution during Xenopus laevis development. We found that while XHas2 shows a steady-state expression from gastrula to late tailbud stage, XHas1 is mainly present in the early phases of development while XHas3 is predominantly transcribed in tailbud embryos. XHas1, XHas2 and XHas3 show distinct tissue expression patterns. In particular, XHas1 is localized in ectodermal derivatives and in cranial neural crest cells, whereas XHas2 is mainly found in mesoderm-derived structures and in trunk neural crest cells. Moreover, the expression pattern of XHas2 overlaps that of MyoD in cells committed to a muscle fate. Unlike the other hyaluronan synthases, XHas3 mRNA distribution is very restricted. In particular, XHas3 is expressed in the otic vesicles and closely follows the inner ear development. In conclusion, XHas1, XHas2 and XHas3 mRNAs have distinct and never overlapping spatial expression domains, which would suggest that these three enzymes may play different roles during embryogenesis.     

Transforming growth factor-beta5 expression during early development of Xenopus laevis

Members of the transforming growth factor-beta (TGF-beta) superfamily play various roles during development in both vertebrates and invertebrates. Two isoforms, TGF-beta2 and -beta5, have been isolated from Xenopus laevis. We describe here the localization of TGF-beta5 mRNA in early embryos of X. laevis, assessed by whole-mount in situ hybridization. The first detectable expression of TGF-beta5 was seen in the stage 14 embryo at the posterior tip of notochord, which continued to later stages, accompanied by the expression in bilateral regions of posterior wall in the tail region next to the notochord. At later stages, transient expression was seen in the cement gland (around stage 21) and in the somites (stages 24-27). In addition, expression was present in the branchial arches (stage 29-36) and olfactory placodes (stage 36).     

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.     

Expression analysis of the peroxiredoxin gene family during early development in Xenopus laevis

Development in the frog, Xenopus laevis, requires the utilization of yolk glyco-lipo-proteins in a temporally- and spatially-dependent manner. The metabolism of the yolk produces hydrogen peroxide (H₂O₂), a potent reactive oxygen species (ROS). Peroxiredoxins (prdxs) are a family of six anti-oxidant enzymes that, amongst other roles, reduce H₂O₂. Prdxs reduce H₂O₂ through a thiol-redox reaction at conserved cysteine residues which results in the creation of disulfide bonds. Recently the thiol-redox reaction of Prdxs has also been implicated in several cell signaling systems. Here we report the cloning and expression patterns during development of six peroxiredoxin homologs from the frog X. laevis. Sequence analysis confirmed their identity as well as their evolutionary relationship with peroxiredoxins from several other species. Using RT-PCR and in situ hybridization analysis we have shown that there is early and robust expression of all six homologs during development. All six X. laevis peroxiredoxins are expressed in neural regions including the brain, eyes, as well as the somites. Different expression patterns for each peroxiredoxin are also observed in the pronephric region, including the proximal and distal tubules. Expression of several peroxiredoxins was also observed in the blood precursors and the olfactory placode. These results suggest important roles for all six peroxiredoxins during early development. These roles may be restricted to their functions as anti-oxidant enzymes, but may also be related to their emerging roles in redox signaling.     

Abdominal B-type Hox gene expression in Xenopus laevis

Previously, we reported a zebrafish iroquois gene, ziro3, and its expression during early embryogenesis (Mech. Dev. 87 (1999) 165). In the present study, we have isolated two novel zebrafish iroquois genes, ziro1 and ziro5, homologs of mouse Irx1 and mouse Irx5, respectively. The expression of both genes is initiated in dorsal neuroectoderm and mesoderm during gastrulation. Later, their expression appears in the central nervous system (CNS), excluding the telencephalon and most of the diencephalon. ziro1 expression is complementary to that of ziro3 in the notochord and later in the gut. In contrast, ziro5 expression mostly overlaps with that of ziro3. Interestingly, all three iroquois zebrafish genes are expressed in the notochord while only Irx3 is active in the mouse notochord. Their expression in later stages of embryogenesis was also compared.     

Modulation of Na,K-ATPase expression during early development of Xenopus laevis.

In amphibian and mammalian systems, regulation of Na+ transport via the Na,K-ATPase plays an important role in distinct developmental processes such as blastocoele formation and neurulation. In this study, we have followed the Na,K-ATPase activity, the biosynthesis, and the cellular accumulation of catalytic alpha-subunits after fertilization of Xenopus laevis eggs up to neurula formation. Our data show that Na,K-ATPase activity increases significantly between stages 4 and 6 and again between stages 13 and 24. The four-fold rise in Na,K-ATPase activity during blastocoele formation is not mediated by an increased cellular pool of alpha-subunits. On the other hand, a five-fold increase of the biosynthesis rate around midblastula precedes a progressive accumulation up to neurula stage mainly of alpha 1-subunits and to a lesser extent of a second alpha-immunoreactive species. In contrast, newly synthesized glycoproteinic beta 1-subunits of Na,K-ATPase cannot be detected up to late neurula. These data indicate that (1) upregulation of Na,K-ATPase activity during blastocoele and neurula formation are mediated by different regulation mechanisms and (2) alpha- and possibly beta-isoforms are expressed in a developmentally regulated fashion during early Xenopus development.     

Deep cytoplasmic rearrangements during early development in Xenopus laevis

The egg of the frog Xenopus is cylindrically symmetrical about its animal-vegetal axis before fertilization. Midway through the first cell cycle, the yolky subcortical cytoplasm rotates 30 degrees relative to the cortex and plasma membrane, usually toward the side of the sperm entry point. Dorsal embryonic structures always develop on the side away from which the cytoplasm moves. Details of the deep cytoplasmic movements associated with the cortical rotation were studied in eggs vitally stained during oogenesis with a yolk platelet-specific fluorescent dye. During the first cell cycle, eggs labelled in this way develop a complicated swirl of cytoplasm in the animal hemisphere. This pattern is most prominent on the side away from which the vegetal yolk moves, and thus correlates in position with the prospective dorsal side of the embryo. Although the pattern is initially most evident near the egg's equator or marginal zone, extensive rearrangements associated with cleavage furrowing (cytoplasmic ingression) relocate portions of the swirl to vegetal blastomeres on the prospective dorsal side.     

Cell cycle transition in early embryonic development of Xenopus laevis

This article reviews cell cycle changes that occur during midblastula transition (MBT) in Xenopus laevis based on research carried out in the authors' laboratory. Blastomeres dissociated from the animal cap of blastulae, as well as those in an intact embryo, divide synchronously with a constant cell cycle duration in vitro, up to the 12th cell cycle regardless of their cell sizes. During this synchronous cleavage, cell sizes of blastomeres become variable because of repeated unequal cleavage. After the 12th cell cycle blastomeres require contact with an appropriate protein substrate to continue cell division. When nucleocytoplasmic (N/C) ratios of blastomeres reach a critical value during the 13th cycle, their cell cycle durations lengthen in proportion to the reciprocal of cell surface areas, and cell divisions become asynchronous due to variations in cell sizes. The same changes occur in haploid blastomeres with a delay of one cell cycle. Thus, post-MBT cell cycle control becomes dependent not only on the N/C relation but also on cell surface activities of blastomeres. Unlike cell cycle durations of pre-MBT blastomeres, which show monomodal frequency distributions with a peak at about 30 min, those of post-MBT blastomeres show polymodal frequency distributions with peaks at multiples of about 30 min, suggesting 'quantisement' of the cell cycle. Thus, we hypothesised that MPF is produced periodically during its unit cycle with 30 min period, but it titrates, and is neutralized by, an inhibitor contained in the nucleus in a quantity proportional to the genome size; however, when all of the inhibitor has been titrated, excess MPF during the last cycle triggers mitosis. At MBT, cell cycle checkpoint mechanisms begin to operate. While the operation of S phase checkpoint to monitor DNA replication is initiated by N/C relation, the initiation of M phase checkpoint operation to monitor chromosome segregation at mitosis is regulated by an age-dependent mechanism.