Mitogen-activated protein kinase and neural specification in Xenopus

We have investigated the activity and function of mitogen-activated protein kinase (MAPK) during neural specification in Xenopus. Ectodermal MAPK activity increased between late blastula and midgastrula stages. At midgastrula, MAPK activity in both newly induced neural ectoderm and ectoderm overexpressing the anterior neural inducer noggin was 5-fold higher than in uninduced ectoderm. Overexpression of MAPK phosphatase-1 (MKP-1) in ectoderm inhibited MAPK activity and prevented neurectoderm-specific gene expression when the ectoderm was recombined with dorsal mesoderm or treated with fibroblast growth factor (FGF). Neurectoderm-specific gene expression was observed, however, in ectoderm overexpressing both noggin and MKP-1. To evaluate the role of MAPK in posterior regionalization, ectodermal isolates were treated with increasing concentrations of FGF and assayed for MAPK activity and neurectoderm-specific gene expression. Although induction of posterior neural ectoderm by FGF was accompanied by an elevation of MAPK activity, relative MAPK activity associated with posterior neural fate was no higher than that of ectoderm specified to adopt an anterior neural fate. Thus, increasingly posterior neural fates are not correlated with quantitative increases in MAPK activity. Because MAPK has been shown to down-regulate Smad1, MAPK may disrupt bone morphogenetic protein 4 (BMP-4) signaling during neural specification. Our results suggest that MAPK plays an essential role in the establishment of neural fate in vivo.

Cooperative effects of growth factors involved in the induction of hematopoietic mesoderm

Hematopoietic induction occurs on the ventral side of Xenopus gastrulae and is thought to be triggered by the growth factor bone morphogenetic protein 4 (BMP-4). To characterize this process, we developed a quantitative and sensitive assay for the induction of erythroid cells from totipotent ectoderm of the embryo. When high doses of BMP-4 were used in this explant assay, few erythroid cells were detected. In contrast, large numbers of differentiated erythroid cells were induced when ectoderm was treated with BMP-4 and the mesoderm inducers, activin, or fibroblast growth factor (FGF). Ectopic expression of GATA-1 also induced abundant erythroid cells in ectoderm treated with bFGF. This induction of erythroid cells by GATA-1 was blocked by coexpression with a dominant negative BMP-4 receptor, showing that GATA-1 requires the BMP signaling cascade to function. These results suggest that BMP-4 requires mesoderm induction to generate a program of gene expression, which regulates the specification of hematopoietic mesoderm by GATA factors.

Assessing the roles of glutamatergic and cholinergic synaptic drive in the control of fictive swimming frequency in young Xenopus tadpoles

This paper investigates the proposal that the frequency of the swimming central pattern generator in young Xenopus tadpoles is partly determined by the population of glutamatergic premotor interneurons active on each cycle. During fictive swimming spinal neurons also receive cholinergic and electrotonic excitation from motoneurons. As frequency changes during swimming we make two predictions: first, since most motoneurons fire very reliably at all frequencies, the electrotonic and nicotinic drive from motoneurons should remain constant, and second, when swimming frequency decreases, the glutamatergic drive should decrease as the number of active premotor excitatory interneurons decreases. We have tested these predictions by measuring the excitatory synaptic drive to motoneurons as frequency changes during fictive swimming. The components of synaptic drive were revealed by the local microperfusion of strychnine together with different excitatory antagonists. After blocking the nicotinic acetylcholine receptor, the mainly glutamatergic excitatory synaptic drive still changed with frequency. However, when glutamate receptors or all chemical transmission was blocked, excitation did not change with frequency. Our predictions are confirmed, suggesting that premotor excitatory interneurons are a major factor in frequency control in the tadpole central pattern generator and that motoneurons provide a stable background excitation.

Dopamine D2 receptor-mediated modulation of rod-cone coupling in the Xenopus retina

We studied the responses of rod photoreceptors that were elicited with light flashes or sinusoidally modulated light by using intracellular recording. Dark-adapted Xenopus rod photoreceptors responded to sinusoidally modulated green lights at temporal frequencies between 1 Hz and 4 Hz. In normal Ringer's solution, 57% of the rods tested could follow red lights that were matched for equal rod absorbance to frequencies >5 Hz, indicating an input from red-sensitive cones. Quinpirole (10 microM), a D2 dopamine agonist, increased rod-cone coupling, whereas spiperone (5 microM), a selective D2 antagonist, completely suppressed it. D1 dopamine ligands were without effect. Neurobiotin that was injected into single rods diffused into neighboring rods and cones in quinpirole-treated retinas but only diffused into rods in spiperone-treated retinas. A subpopulation of rods (ca. 10% total rods) received a very strong cone input, which quickened the kinetics of their responses to red flashes and greatly increased the bandpass of their responses to sinusoidally modulated light. Based on electron microscopic examination, which showed that rod-rod and cone-cone gap junctions are common, whereas rod-cone junctions are relatively rare, we postulate that cone signals enter the rod network through a minority of rods with strong cone connections, from which the cone signal is further distributed in the rod network. A semiquantitative model of coupling, based on measures of gap-junction size and distribution and estimates of their conductance and open times, provides support for this assumption. The same network would permit rod signals to reach cones.

beta-TrCP is a negative regulator of Wnt/beta-catenin signaling pathway and dorsal axis formation in Xenopus embryos

The Wnt/beta-catenin signaling pathway is responsible for the establishment of dorsoventral axis of Xenopus embryos. The recent finding of the F-box/WD40-repeat protein slimb in Drosophila, whose loss-of-function mutation causes ectopic activation of wingless signaling (Jiang, J., Struhl, G., 1998. Nature 391, 493-496), led us to examine the role of its vertebrate homolog betaTrCp in the Wnt/beta-catenin signaling and dorsal axis formation in Xenopus embryos. Co-injection of betaTrCp mRNA diminished Xwnt8 mRNA-induced axis formation and expression of Siamois and Xnr3, suggesting that betaTrCP is a negative regulator of the Wnt/beta-catenin signaling pathway. An mRNA for a betaTrCp mutant construct (DeltaF), which lacked the F-box domain, induced an ectopic axis and expression of Siamois and Xnr3. Because this activity of DeltaF was suppressed by co-injection of DeltaF TrCP mRNA, DeltaF likely acts in a dominant negative fashion. The activity of DeltaF was diminished by C-cadherin, glycogen synthase kinase 3 and Axin, but not by a dominant negative dishevelled. These results suggest that betaTrCp can act as a negative regulator of dorsal axis formation in Xenopus embryos.

Timing and mechanisms of mesodermal and neural determination revealed by secondary embryo formation in Cynops and Xenopus

We examined the timing and mechanisms of mesodermal and neural determination in Cynops, using the secondary embryo induced by transplantation of the prechordal endomesoderm. Two unique approaches were used: one was to observe gastrulation movements induced by the graft, and the other to measure the volumes of formed tissues. Transplanted graft pulled host animal cap cells inside to form a new notochord and other mesoderm of the secondary embryo, showing determination of mesoderm during gastrulation. The graft attained a certain width beneath the host ectoderm and moved near to the animal pole of the host by late gastrula, and a neural plate, which had a similar width to the graft, was formed covering the graft. The volume of neural tissues of the secondary embryo at tail-bud stages was about half that of the normal embryo, while the volumes of notochord were comparable in each case. These data suggest that prechordal endomesoderm, rather than notochord, determines the limit of neural plate in the overlying ectoderm. Similar dorsal grafts were transplanted at early gastrula in Xenopus but did not form well developed secondary embryos, demonstrating that the timing and mechanisms of mesoderm formation in Xenopus are different from those in Cynops.

Swimming kinematics and respiratory behaviour of Xenopus laevis larvae raised in altered gravity

We examined the respiratory behaviours and swimming kinematics of Xenopus laevis tadpoles hatched in microgravity (Space Shuttle), simulated microgravity (clinostat) and hypergravity (3 g centrifuge). All observations were made in the normal 1 g environment. Previous research has shown that X. laevis raised in microgravity exhibit abnormalities in their lungs and vestibular system upon return to 1 g. The tadpoles raised in true microgravity exhibited a significantly lower tailbeat frequency than onboard 1 g centrifuge controls on the day of landing (day0), but this behaviour normalized within 9 days. The two groups did not differ significantly in buccal pumping rates. Altered buoyancy in the space-flight microgravity tadpoles was indicated by an increased swimming angle on the day after landing (day1). Tadpoles raised in simulated microgravity differed to a greater extent in swimming behaviours from their 1 g controls. The tadpoles raised in hypergravity showed no substantive effects on the development of swimming or respiratory behaviours, except swimming angle. Together, these results show that microgravity has a transient effect on the development of locomotion in X. laevis tadpoles, most notably on swimming angle, indicative of stunted lung development. On the basis of the behaviours we studied, there is no indication of neuromuscular retardation in amphibians associated with embryogenesis in microgravity.

Fluorescence microscopy of calcium and synaptic vesicle dynamics during synapse formation in tissue culture

The signal transduction process involved in the development of the nerve terminal is an intriguing question in developmental neurobiology. During the formation of the neuromuscular junction, presynaptic development is induced by growth cone's contact with the target muscle cell. Fluorescence microscopy with specific markers has made it possible to follow signalling events during this process. By using fluorescent calcium indicators, such as fura-2 and fluo-3, we found that a rise in intracellular calcium is elicited in the growth cone upon its contact with a target, and this calcium signal can also be elicited by local application of basic fibroblast growth factor. To monitor the clustering of synaptic vesicles in response to target contact, the fluorescent vesicular probe FMl-43 was used. With this probe, we observed that packets of synaptic vesicle are already present along the length of naïve neurite, which has not encountered its synaptic target. The activity-dependent loading of FMl-43 indicates that these packets can undergo exocytosis and endocytosis upon depolarization. Time-lapse recording showed that these packets are quite mobile. Upon target contact, synaptic vesicles become clustered and immobilized at the contact site. The methodology and instrumentation used in these studies are described in this article.

Conserved Spätzle/Toll signaling in dorsoventral patterning of Xenopus embryos

The Spätzle/Toll signaling pathway controls ventral axis formation in Drosophila by generating a gradient of nuclear Dorsal protein. Dorsal controls the downstream regulators dpp and sog, whose patterning functions are conserved between insects and vertebrates. Although there is no experimental evidence that the upstream events are conserved as well, we set out to ask if a vertebrate embryo can respond to maternal components of the fly Dorsal pathway. Here we demonstrate a dorsalizing activity for the heterologous Easter, Spätzle and Toll proteins in UV-ventralized Xenopus embryos, which is inhibited by a co-injected dominant Cactus variant. We conclude that the Dorsal signaling pathway is a component of the conserved dorsoventral (d/v) patterning system in bilateria.

Ion channels and the control of swimming in the Xenopus embryo

The Xenopus embryo has been well studied and the circuitry underlying motor pattern generation largely elucidated. We have extended this analysis by determining the roles of individual voltage- and ligand-gated ion channels in controlling the motor pattern for swimming and two mechanisms that control rundown of this pattern. Xenopus embryo spinal neurons possess at least six classes of ion channel: a fast Na+ channel; a mixture of kinetically similar Ca2+ channels; a fast K+ channel; a slow K+ channel; a Na(+)-dependent K+ channel; and a slowly activating Ca2(+)-dependent K+ channel. The roles of the voltage-gated currents in determining neuronal firing properties and operation of the locomotor circuitry have been examined both pharmacologically and in realistic computer simulations. Model neurons fire repetitively in response to current injection. The Ca2+ current seems essential for repetitive firing. The fast K+ current appears mainly to control spike width, whereas the slow K+ current exerts a powerful influence on repetitive firing. These predictions from the model have been confirmed by the use of specific pharmacological blockers of the fast and slow K+ currents. Both the model network and the real spinal locomotor circuit appear to tolerate a wide variation in the relative strengths of the component synapses but are very sensitive to the magnitudes of the voltage-gated currents. In particular the slow K+ current, despite being a small component of the total outward current, plays a critical role in stabilizing the motor pattern. Like many other rhythmic motor patterns, swimming in the Xenopus embryo is episodic; it undergoes run-down and self-termination even in the absence of sensory inputs. The slow Ca2(+)-dependent K+ current appears to play a role in the self-termination of swimming. However, intrinsic modulation mediated by the release of ATP and production of adenosine in the extracellular space appears to be a very powerful determinant of run-down of the motor pattern.

Analysis of the signaling activities of localization mutants of beta-catenin during axis specification in Xenopus

In Xenopus embryos, beta-catenin has been shown to be both necessary and sufficient for the establishment of dorsal cell fates. This signaling activity is thought to depend on the binding of beta-catenin to members of the Lef/Tcf family of transcription factors and the regulation of gene expression by this complex. To test whether beta-catenin must accumulate in nuclei to establish dorsal cell fate, we constructed various localization mutants that restrict beta-catenin to either the plasma membrane, the cytosol, or the nucleus. When overexpressed in Xenopus embryos, the proteins localize as predicted, but surprisingly all forms induce an ectopic axis, indicative of inducing dorsal cell fates. Given this unexpected result, we focused on the membrane-tethered form of beta-catenin to resolve the apparent discrepancy between its membrane localization and the hypothesized role of nuclear beta-catenin in establishing dorsal cell fate. We demonstrate that overexpression of membrane-tethered beta-catenin elevates the level of free endogenous beta-catenin, which subsequently accumulates in nuclei. Consistent with the hypothesis that it is this pool of non-membrane-associated beta-catenin that signals in the presence of membrane-tethered beta-catenin, overexpression of cadherin, which binds free beta-catenin, blocks the axis-inducing activity of membrane- tethered beta-catenin. The mechanism by which ectopic membrane-tethered beta-catenin increases the level of endogenous beta-catenin likely involves competition for the adenomatous polyposis coli (APC) protein, which in other systems has been shown to play a role in degradation of beta-catenin. Consistent with this hypothesis, membrane-tethered beta-catenin coimmunoprecipitates with APC and relocalizes APC to the membrane in cells. Similar results are observed with ectopic plakoglobin, casting doubt on a normal role for plakoglobin in axis specification and indicating that ectopic proteins that interact with APC can artifactually elevate the level of endogenous beta-catenin, likely by interfering with its degradation. These results highlight the difficulty in interpreting the activity of an ectopic protein when it is assayed in a background containing the endogenous protein. We next investigated whether the ability of beta-catenin to interact with potential protein partners in the cell may normally be regulated by phosphorylation. Compared with nonphosphorylated beta-catenin, beta-catenin phosphorylated by glycogen synthase kinase-3 preferentially associates with microsomal fractions expressing the cytoplasmic region of N-cadherin. These results suggest that protein-protein interactions of beta-catenin can be influenced by its state of phosphorylation, in addition to prior evidence that this phosphorylation modulates the stability of beta-catenin.

The beta subunit of CKII negatively regulates Xenopus oocyte maturation

CKII (formerly known as casein kinase II) is a ubiquitously expressed enzyme that plays an important role in regulating cell growth and differentiation. The beta subunit of CKII (CKIIbeta) is not catalytic but forms heterotetramers with the catalytic subunit alpha to generate an alpha2beta2 holoenzyme. In Xenopus oocytes, CKIIbeta also associates with another serine/threonine kinase, Mos. As a key regulator of meiosis, Mos is necessary and sufficient to initiate oocyte maturation. We have previously shown that the binding of CKIIbeta to Mos represses Mos-mediated mitogen-activated protein kinase (MAPK) activation and that the ectopic expression of CKIIbeta inhibits progesterone-induced Xenopus oocyte maturation. We have now used an antisense oligonucleotide technique to reduce the endogenous CKIIbeta protein level in Xenopus oocytes, and we find that oocytes with a reduced content of CKIIbeta are more sensitive to low doses of progesterone and show accelerated MAPK activation and germinal vesicle breakdown. Furthermore, ectopic expression of a Mos-binding fragment of CKIIbeta suppressed the effect of antisense oligonucleotide. These results suggest that the endogenous CKIIbeta normally sets a threshold level for Mos protein, which must be exceeded for Mos to activate the MAPK signaling pathway and induce oocyte maturation.

Mitogen-activated protein kinase and cyclin B/Cdc2 phosphorylate Xenopus nuclear factor 7 (xnf7) in extracts from mature oocytes. Implications for regulation of xnf7 subcellular localization

Xenopus nuclear factor 7 (xnf7) is a maternally expressed putative transcription factor that exhibits phosphorylation-dependent changes in subcellular localization during early Xenopus development. Xnf7 is localized to the germinal vesicle (nucleus) of immature oocytes in a hypophosphorylated state. Xnf7 is phosphorylated during oocyte maturation and released to the cytoplasm. The protein is retained in the cytoplasm during early embryonic cleavage stages but returns to nuclei at the mid-blastula transition. Xnf7 is phosphorylated at two sites during oocyte maturation, designated P1, consisting of one threonine at position 103, and P2, consisting of three clustered threonines at positions 209, 212, and 218. Phosphorylation of both sites is important in regulating xnf7 localization. The P1 site can be phosphorylated by cyclin B/Cdc2 in vitro. To further understand the mechanisms regulating subcellular localization of xnf7 during early development, kinases capable of catalyzing phosphorylation of the P2 site were purified from mature oocyte extracts. We found that mitogen-activated protein kinase phosphorylated Thr212 and cyclin B/Cdc2 phosphorylated Thr 209 and Thr212. No other kinase in mature oocyte extracts phosphorylated the xnf7 P2 site to a significant extent. These results implicate mitogen-activated protein kinase and cyclin B/Cdc2 in regulating xnf7 localization during oocyte maturation. This also suggests that localization of xnf7 may be regulated by multiple kinase activation pathways.

Cell-cell signalling: frog frizbees

The recent discovery that Frizzled proteins are receptor for Wnts has been quickly followed by the identification of a secreted protein, Frzb, that is related to Frizzled, expressed by the Spemann organizer in frog embryos and can bind to and antagonize Wnt developmental signalling molecules.

The EphA4 and EphB1 receptor tyrosine kinases and ephrin-B2 ligand regulate targeted migration of branchial neural crest cells

BACKGROUND

During vertebrate head development, neural crest cells migrate from hindbrain segments to specific branchial arches, where they differentiate into distinct patterns of skeletal structures. The rostrocaudal identity of branchial neural crest cells appears to be specified prior to migration, so it is important that they are targeted to the correct destination. In Xenopus embryos, branchial neural crest cells segregate into four streams that are adjacent during early stages of migration. It is not known what restricts the intermingling of these migrating cell populations and targets them to specific branchial arches. Here, we investigated the role of Eph receptors and ephrins-mediators of cell-contact-dependent interactions that have been implicated in neuronal pathfinding-in this targeted migration.

RESULTS

Xenopus EphA4 and EphB1 are expressed in migrating neural crest cells and mesoderm of the third arch, and third plus fourth arches, respectively. The ephrin-B2 ligand, which interacts with these receptors, is expressed in the adjacent second arch neural crest and mesoderm. Using truncated receptors, we show that the inhibition of EphA4/EphB1 function leads to abnormal migration of third arch neural crest cells into second and fourth arch territories. Furthermore, ectopic activation of these receptors by overexpression of ephrin-B2 leads to scattering of third arch neural crest cells into adjacent regions. Similar disruptions occur when the expression of ephrin-B2 or truncated receptors is targeted to the neural crest.

CONCLUSIONS

These data indicate that the complementary expression of EphA4/EphB1 receptors and ephrin-B2 is involved in restricting the intermingling of third and second arch neural crest and in targeting third arch neural crest to the correct destination. Together with previous work showing that Eph receptors and ligands mediate neuronal growth cone repulsion, our findings suggest that similar mechanisms are used for neural crest and axon pathfinding.

A molecular phylogeny of the bivalve mollusks

A phylogenetic reconstruction based on 506 nucleotides near the 5' end of the 18S subunit of ribosomal DNA (rDNA) in 2 gastropod, 3 chiton and 28 bivalve mollusks supported the monophyly and sister group relationship of the subclasses Heterodonta and Palaeoheterodonta but could not confidently establish either the monophyly or the phylogenetic relationships of the morphologically well defined subclasses Pteriomorphia, Protobranchia, and Anomalodesmata. When both gastropods and chitons were included in the analysis, one or the other invariably emerged within Bivalvia. Some evidence indicates that this apparent polyphyly may be the consequence of unequal rates of evolution and of rapid changes in the protobranch and anomalodesmatan lineages. The taxa usually included in Pteriomorpha emerge as a grade rather than a clade, although in a sequence that differs from morphologically based phylogenies.

Effects of neuroamines and divalent cations on cloned and mutated ATP-gated channels

Sensitivities to dopamine, 5-hydroxytryptamine, Zn2+ and Cd2+ were studied in P2X1, P2X2, P2X3 and P2X4 purinoceptors and mutants of P2X2 purinoceptors expressed in Xenopus oocytes. Dopamine (10 and 100 microM) and 5-hydroxytryptamine (1 to 100 microM) enhanced the inward current activated by extracellular ATP through P2X2 and P2X4 purinoceptors. Zn2+ (1 to 100 microM) and Cd2+ (10 microM to 1 microM) enhanced the current through P2X2 purinoceptors. As for P2X4 purinoceptors, the ATP-activated current was, however, enhanced after the washout of Zn2+ (100 microM) or Cd2+ (1 mM). Three mutants of P2X2 purinoceptors were constructed by substituting negatively charged amino-acid residues. The magnitude of the enhancement by Zn2+, Cd2+ and dopamine was attenuated when Asp221 was replaced by histidine. The results suggest that dopamine, Zn2+ and Cd2+ require some common motif for the current enhancement.

Activin signalling has a necessary function in Xenopus early development

The first signalling event in Xenopus development is the mesoderm-forming (or Nieuwkoop) induction, starting three hours after fertilization [1]. Two prime candidates for the molecule that mediates this signalling are activin [2] and Vg1 [3], both members of the transforming growth factor beta (TGFbeta) family. Because genetic methods are not available for amphibian studies, 'dominant-negative' truncated receptors have been used in studying signalling molecules such as the receptors for fibroblast and platelet-derived growth factors (FGF and PDGF) [4] [5]. The truncated receptors bind to, and prevent signalling from, endogenous receptors. Activin is a potent mesoderm inducer in vitro, and the severe phenotype obtained using a dominant-negative activin receptor in Xenopus [6], coupled with evidence from fish [7], suggested that activin is essential for development. However, a dominant-negative receptor for activin blocked the activity of other TGFbeta family members in Xenopus, most notably Vg1 [8], and activin 'knock-out' mice are essentially wild-type in phenotype [7]; these two findings cast doubt on the idea of a function for activin in early development. We have designed a new receptor construct which can selectively block the function of activin but not of Vg1, and we have used it to show that activin has an essential role in vivo in Xenopus early development. We conclude that activin, or a close relative that has yet to be described, is required for normal development.

Neuropharmacology: a part for purines in pattern generation

Purinergic transmission has been found to play a key role in the neural control of rhythmic swimming behaviour in Xenopus embryos: it may have similar importance in other vertebrate motor behaviours.

XKCM1: a Xenopus kinesin-related protein that regulates microtubule dynamics during mitotic spindle assembly

We isolated a cDNA clone encoding a kinesin-related protein, which we named XKCM1. Antibodies to XKCM1 stain mitotic centromeres and spindle poles. Immunodepletion and antibody addition experiments in an in vitro spindle assembly assay show that XKCM1 is required for both establishment and maintenance of mitotic spindles. The structures that form in the absence of XKCM1 contain abnormally long microtubules. This long microtubule defect can be rescued by the addition of purified XKCM1 protein. Analysis of microtubule dynamics in a clarified mitotic extract reveals that loss of XKCM1 function causes a 4-fold suppression in the catastrophe frequency. XKCM1 thus exhibits a novel activity for a kinesin-related protein by promoting microtubule depolymerization during mitotic spindle assembly.