Sequence and developmental expression of mRNA coding for a gap junction protein in Xenopus.

Cloned complementary DNAs representing the complete coding sequence for an embryonic gap junction protein in the frog Xenopus laevis have been isolated and sequenced. The cDNAs hybridize with an RNA of 1.5 kb that is first detected in gastrulating embryos and accumulates throughout gastrulation and neurulation. By the tailbud stage, the highest abundance of the transcript is found in the region containing ventroposterior endoderm and the rudiment of the liver. In the adult, transcripts are present in the lungs, alimentary tract organs, and kidneys, but are not detected in the brain, heart, body wall and skeletal muscles, spleen, or ovary. The gene encoding this embryonic gap junction protein is present in only one or a few copies in the frog genome. In vitro translation of RNA synthesized from the cDNA template produces a 30-kD protein, as predicted by the coding sequence. This product has extensive sequence similarity to mammalian gap junction proteins in its putative transmembrane and extracellular domains, but has diverged substantially in two of its intracellular domains.

Differential regulation of the levels of three gap junction mRNAs in Xenopus embryos.

Xenopus mRNAs that potentially encode gap junction proteins in the oocyte and early embryo have been identified by low-stringency screening of cDNA libraries with cloned mammalian gap junction cDNAs. The levels of these mRNAs show strikingly different temporal regulation and tissue distribution. Using a nomenclature designed to stress important structural similarities of distinct gap junction gene products, the deduced polypeptides have been designated the Xenopus alpha 1 and alpha 2 gap junction proteins. The alpha 2 gap junction mRNA is a maternal transcript that disappears by the late gastrula stage. It is not detected in any organ of the adult except the ovary, and resides primarily, if not exclusively, in the oocytes and early embryos. The alpha 1 gap junction mRNA appears during organogenesis, and is detected in RNA from a wide variety of organs. It is also found in full-grown oocytes, but is rapidly degraded upon oocyte maturation, both in vivo and in vitro. The alpha 1 and alpha 2 mRNAs encode proteins with different degrees of amino acid sequence similarity to the predominant gap junction subunit of the mammalian heart (connexin 43). Together with our earlier report of a mid-embryonic (beta 1) gap junction mRNA, the results suggest that intercellular communication during oocyte growth and postfertilization development is a complex phenomenon involving the coordinated regulation of several genes.

Connexin40, a component of gap junctions in vascular endothelium, is restricted in its ability to interact with other connexins.

The cellular distribution of connexin40 (Cx40), a newly cloned gap junction structural protein, was examined by immunofluorescence microscopy using two different specific anti-peptide antibodies. Cx40 was detected in the endothelium of muscular as well as elastic arteries in a punctate pattern consistent with the known distribution of gap junctions. However, it was not detected in other cells of the vascular wall. By contrast, Cx43, another connexin present in the cardiovascular system, was not detected in endothelial cells of muscular arteries but was abundant in the myocardium and aortic smooth muscle. We have tested the ability of these connexins to interact functionally. Cx40 was functionally expressed in pairs of Xenopus oocytes and induced the formation of intercellular channels with unique voltage dependence. Unexpectedly, communication did not occur when oocytes expressing Cx40 were paired with those expressing Cx43, although each could interact with a different connexin, Cx37, to form gap junction channels in paired oocytes. These findings indicate that establishment of intercellular communication can be spatially regulated by the selective expression of different connexins and suggest a mechanism that may operate to control the extent of communication between cells.

Over-expression of FoxM1 stimulates cyclin B1 expression.

FoxM1 (previously named WIN, HFH-11 or Trident) is a Forkhead box (Fox) transcription factor widely expressed in proliferating cells. Various findings, including a recent analysis of FoxM1 knockout mice, suggest that FoxM1 is required for normal S-M coupling during cell cycle progression. To study the regulatory role of FoxM1 and its downstream regulatory targets, three stably transfected HeLa lines that display doxycycline (dox)-inducible FoxM1 expression were established. Over-expression of FoxM1 by dox induction facilitates growth recovery from serum starvation. Quantitation of cyclin B1 and D1 levels using flow cytometric, Western and Northern analyses reveals that elevated FoxM1 levels lead to stimulation of cyclin B1 but not cyclin D1 expression. Transient reporter assays in the dox-inducible lines and upon co-transfection with a constitutive FoxM1 expression plasmid suggest that FoxM1 can activate the cyclin B1 promoter.

Acquisition of developmental autonomy in the equatorial region of the Xenopus embryo.

This paper describes a continuing effort to define the location and mode of action of morphogenetic determinants which direct the development of dorsal body axis structures in embryos of the frog Xenopus laevis. Earlier results demonstrated that presumptive endodermal cells in one vegetal quadrant of the 64-cell embryo can, under certain experimental conditions, induce partial or complete body axis formation by progeny of adjacent equatorial cells. (R.L. Gimlich and J.C. Gerhart, 1984, Dev. Biol. 104, 117-130). I have now assessed the importance of other blastomeres for embryonic axis formation in a series of transplantation experiments using cells from the equatorial level of the 32-cell embryo. The transplant recipients were embryos which had been irradiated with ultraviolet light before first cleavage. Without transplantation, embryos failed to develop the dorsal structures of the embryonic body axis. However, cells of these recipients were competent to respond to inductive signals from transplanted tissue and to participate in normal embryogenesis. Dorsal equatorial cells, but not their lateral or ventral counterparts, often caused partial or complete body axis development in irradiated recipients, and themselves formed much of the notochord and some prechordal and somitic mesoderm. These are the same structures that they would have formed in the normal donor. Thus, the dorsal equatorial blastomeres were often at least partially autonomous in developing according to their prospective fates. In addition, they induced progeny of neighboring host cells to contribute to the axial mesoderm and to form most of the central nervous system. The frequency with which such transplants caused complete axis formation in irradiated hosts increased when they were made at later and later cleavage stages. In contrast, the inductive activity of vegetal cells remained the same or declined during the cleavage period. These and other results suggest that the egg cytoplasmic region containing "axial determinants" is distributed to both endodermal and mesodermal precursors in the dorsal-most quadrant of the early blastula.

Cytoplasmic localization and chordamesoderm induction in the frog embryo.

The experiments described here were designed to reveal the distribution in the frog early embryo of components which are sufficient for specification of the dorsal structures of the embryonic body axis. The approach was to allow cleavage planes to divide the embryo into various well-defined regions and to transplant cells from each region into recipient embryos which would otherwise fail to form axial structures. Partial or complete body axis development could then be scored by the use of external criteria or histological methods. Recipients were embryos which had been irradiated before first cleavage with ultraviolet light on the vegetal surface. Irradiated embryos display a well-characterized set of deficiencies in the dorsal structures of the body axis, but their development can be 'rescued' toward normalcy in several ways. In particular, transplantation of certain small groups of blastomeres from the normal 32- to 64-cell embryo into irradiated recipients was sufficient to cause partial or complete axis development. Cell groups which could cause rescue were located in the vegetal and equatorial levels of one quadrant of the normal embryo--the quadrant centered on the future dorsal midline. Clonal marking analysis showed that the vegetal-most cells of this quadrant contribute primarily to endodermal structures in normal development. In rescued recipient embryos, these cells also contributed only to the endoderm; the dorsal mesoderm and central nervous system were formed exclusively by host cells which originated near the transplant. Rescue could also result from transplantation of equatorial cells from the dorsal quadrant of the normal embryo. As in normal development, these cells formed primarily the chordamesoderm of the rescued embryo. Host cells were induced to contribute the somitic mesoderm, central nervous system, and other structures which would have been missing but for the presence of the transplanted cells. The frequency and degree of rescue caused by equatorial and vegetal transplants is variable. This was explained by the discovery that the location of components needed for rescue varies among individual embryos without regard to the positions of cleavage planes. This was true even when donor embryos were selected on the basis of a precisely regular pattern of cleavage. In such selected embryos, particular blastomeres make a predictable contribution of progeny to the body axis. Thus it may be that the positions of components which can cause axis formation vary without exact regard to the fate map of prospective areas. The implications of this for the study of cytoplasmic localization in the early embryo are discussed.(ABSTRACT TRUNCATED AT 400 WORDS)

Lithium-induced teratogenesis in frog embryos prevented by a polyphosphoinositide cycle intermediate or a diacylglycerol analog.

Microinjection of LiCl into prospective ventral blastomeres of the 32-cell Xenopus embryo gives rise to duplication of dorsoanterior structures such as the notochord, neural tube, eyes, and cement gland. We report here that this teratogenic effect of Li+ is prevented by coinjection of equimolar myo-inositol, an intermediate of the polyphosphoinositide cycle. In contrast, epi-inositol, a nonbiological positional isomer of inositol not employed in this cycle, is ineffective at rescuing Li+-injected embryos. Treatment of embryos at stage 7 with the tumor promoter, phorbol myristate acetate (an analog of the polyphosphoinositide cycle-derived second messenger, diacylglycerol), also prevents dorsoanterior duplication of Li+ embryos, while the nontransforming analog, phorbol myristate acetate-4-O-methyl ether, is without effect. Both of these rescuing agents are without obvious effects on development when administered alone (i.e., without Li+). Li+-selective microelectrode measurements demonstrate that intracellular Li+ levels are identical when Li+ is injected with or without myo-inositol. Clonal analysis shows that blastomeres injected with Li+ plus myo-inositol make a normal contribution of progeny to the later embryo. Because Li+ is a well-established inhibitor of the polyphosphoinositide cycle and can thereby have profound effects on cellular myo-inositol and diacylglycerol levels, these observations concerning inositol-mediated rescue suggest a role for altered polyphosphoinositide cycle activity in lithium-induced teratogenesis.

Cell lineage and the induction of second nervous systems in amphibian development.

The amphibian nervous system has long been thought to arise from within a large (greater than 10(3) population of dorsal ectodermal cells, that would otherwise differentiate only as epidermis, as a result of inductive signals from underlying dorsal mesoderm at gastrulation. It has recently been claimed, however, that small cell groups are set aside much earlier in amphibian development, as the sole founders of particular portions or 'compartments' of the body plan. This would imply a dramatic re-interpretation of classical experiments where a second dorsal blastoporal lip, grafted to the ventral side of a gastrula containing 10,000 or more cells, causes there the development of a second central nervous system (CNS) in host tissue. We show that such surgically induced second nervous systems are made by host cells which have lineages separate from those that contribute to the original CNS from the 32-cell stage. Thus neural induction can occur as traditionally supposed, by assignment of ectodermal cell fate in relation to dorsal mesoderm during gastrulation. We discuss the implications of this for the recent proposals about early compartmentation in vertebrate development.

Improved fluorescent compounds for tracing cell lineage.

In this note simple methods for the synthesis of several new fluorescent cell lineage tracers are described. These are fluorescent dextrans with average molecular weights of approximately 11 X 10(3), and with one or more fluorophore molecules covalently coupled to each dextran chain. These fluorescent dextrans are brighter than commercially obtainable products, and can be microinjected using either air-pressure injection or iontophoresis. They are long-lasting and have a uniform distribution in the cytoplasm of embryonic cells, clearly revealing very fine cell extensions such as cilia, axons, and filipodia. A method is also described for covalently attaching free amino groups to fluorescent dextran to make the tracers cofixable with cellular constituents by aldehyde treatment. Fluorescent dextran-amine tracers allow embryonic cell lineages to be studied in fixed, permeabilized, or sectioned embryos.

Early cellular interactions promote embryonic axis formation in Xenopus laevis.

We have attempted to define the location and mode of action of axial determinants in the egg of Xenopus laevis. To this end, we transplanted small numbers of blastomeres from normal 64-cell stage embryos into synchronous recipient embryos which had been irradiated with ultraviolet light prior to first cleavage. Without transplantation, such embryos fail to develop dorsal structures of the embryonic body axis. We found that one to three blastomeres transplanted from the vegetal-most octet of cells can effect complete or partial rescue of of axis development in a recipient, provided that the donor cells derive from the quadrant just under the prospective dorsal marginal region. These same cells, when transplanted into the ventral vegetal quadrant of a normal 64-cell embryo, cause the formation of a complete second body axis. In contrast, other cells from the vegetal octet of normal donors fail to cause axis formation. When the rescuing donor cells are labeled with a lineage-restricted fluorescent marker, we find that their progeny do not contribute to the axial structures of the recipient. Progeny of the transplanted cells are found below the level of the blastopore in the early gastrula and eventually give rise to portions of the gut, as is their fate in normal development. These results, in agreement with those of Nieuwkoop (P.D. Nieuwkoop, 1977, Curr. Top. Dev. Biol. 11, 115-132), imply that the dorsal-most vegetal cells of the 64-cell embryo receive from the egg cytoplasm a set of determinants enabling them to induce neighboring cells to undertake axis formation. We discuss the relationship between axis induction in rescued irradiated embryos and axis determining processes in normal embryogenesis.

The function and mechanism of convergent extension during gastrulation of Xenopus laevis.

The processes thought to function in Xenopus gastrulation include bottle cell formation, migration of cells on the roof of the blastocoel, and autonomous convergent extension of the circumblastoporal region. A review of recent and classical results shows that only the last accounts for the bulk of the tissue displacement of gastrulation, including spreading of the marginal zone toward the blastopore, involution of the marginal zone, and closure of the blastopore. Microsurgical manipulation and explantation studies, analysed by time-lapse video and cine microscopy, shows that the dorsal circumblastoporal region contains two regions which show either autonomous or semiautonomous convergent extension. The dorsal involuting marginal zone (IMZ) undergoes convergence (narrowing) and extension (lengthening) after its involution, beginning at the midgastrula stage and continuing through neurulation, such that it simultaneously extends posteriorly across the yolk plug and narrows the blastoporal circumference. Concurrently, the corresponding region of the overlying non-involuting marginal zone (NIMZ) begins a complementary convergent extension, but at a greater rate, which spreads vegetally to occupy surface area vacated by the IMZ. Tissue recombination experiments show that the deep cells of the dorsal IMZ bring about convergent extension. Labelling of small populations of these cells with a cell lineage tracer shows that convergent extension involves intercalation of deep cells to form a longer, narrower array. Direct time-lapse video and cine micrography of deep cells in cultured explants show that convergent extension involves radial and circumferential intercalation. Removal of the entire blastocoel roof of the early gastrula, including all or part of the NIMZ, shows that convergent extension of the IMZ alone can bring about its involution and blastopore closure. The role of convergent extension in gastrulation of other amphibians and other metazoans and its significance to related problems in early development are discussed.

Expression of a dominant negative inhibitor of intercellular communication in the early Xenopus embryo causes delamination and extrusion of cells.

A chimeric construct, termed 3243H7, composed of fused portions of the rat gap junction proteins connexin32 (Cx32) and connexin43 (Cx43) has been shown to have selective dominant inhibitory activity when tested in the Xenopus oocyte pair system. Co-injection of mRNA coding for 3243H7 together with mRNAs coding for Cx32 or Cx43 completely blocked the development of channel conductances, while the construct was ineffective at blocking intercellular channel assembly when coinjected with rat connexin37 (Cx37). Injection of 3243H7 into the right anterodorsal blastomere of 8-cell-stage Xenopus embryos resulted in disadhesion and delamination of the resultant clone of cells evident by embryonic stage 8; a substantial number, although not all, of the progeny of the injected cell were eliminated from the embryo by stage 12. A second construct, 3243H8, differing from 3243H7 in the relative position of the middle splice, had no dominant negative activity in the oocyte pair assay, nor any detectable effects on Xenopus development, even when injected at four-fold higher concentrations. The 3243H7-induced embryonic defects could be rescued by coinjection of Cx37 with 3243H7. A blastomere reaggregation assay was used to demonstrate that a depression of dye-transfer could be detected in 3243H7-injected cells as early as stage 7; Lucifer yellow injections into single cells also demonstrated that injection of 3243H7 resulted in a block of intercellular communication. These experiments indicate that maintenance of embryonic cell adhesion with concomitant positional information requires gap junction-mediated intercellular communication.

Localization and induction in early development of Xenopus.

Our experimental results, as well as those of others, lead us to suggest the following steps in the dorsalization and axialization of the Xenopus egg and embryo: the sperm aster determines the direction of rotation of the cortex relative to the deeper cytoplasm (endoplasm); the rotation of the cortex activates latent dorsalizing-axializing agents in the vegetal hemisphere. The extent of rotation determines the amount of activation. The direction of rotation determines the location of the activated agents. The activated agents determine the level of mesoderm-inducing activity of the vegetal cells cleaved from that cytoplasmic region. The level of inducing activity determines at least the time at which marginal zone cells will begin gastrulation movements. The time of its initiation of gastrulation may determine how anterior and dorsal a particular marginal zone cell can become.