Expression of activated MAP kinase in Xenopus laevis embryos: evaluating the roles of FGF and other signaling pathways in early induction and patterning.

FGF signaling has been implicated in germ layer formation and axial determination. An antibody specific for the activated form of mitogen-activated protein kinase (MAPK) was used to monitor FGF signaling in vivo during early Xenopus development. Activation of MAPK in young embryos is abolished by injection of a dominant negative FGF receptor (XFD) RNA, suggesting that MAPK is activated primarily by FGF in this context. A transition from cytoplasmic to nuclear localization of activated MAPK occurs in morula/blastula stage embryo animal and marginal zones coinciding with the proposed onset of mesodermal competence. Activated MAPK delineates the region of the dorsal marginal zone before blastopore formation and persists in this region during gastrulation, indicating an early role for FGF signaling in dorsal mesoderm. Activated MAPK was also found in posterior neural tissue from late gastrulation onward. Inhibition of FGF signaling does not block posterior neural gene expression (HoxB9) or activation of MAPK; however, inhibition of FGF signaling does cause a statistically significant decrease in the level of activated MAPK. These results point toward the involvement of other receptor tyrosine kinase signaling pathways in posterior neural patterning.

Altered retinoid signaling in the heads of small eye mouse embryos.

The vitamin A derivative retinoic acid (RA) is necessary for eye development, though its role in signaling within eye tissues is poorly understood. We investigated this question in two transgenic mouse strains carrying a retinoic acid response element (RARE) fused to beta-galactosidase that identify regions of the embryo expressing activated retinoic acid receptors. Retinoid signaling appears in the retina and lens ectoderm of wild-type embryos prior to neural tube closure, when lens induction is under way. To determine if there are interactions between retinoid signaling and the transcription factor Pax-6, also essential for lens development, we examined RARE transgene expression in Small eye (Sey) mice, which carry a Pax-6 mutation. Retinoid signaling in the eye, nose, and forebrain of Sey embryos is decreased, with the most severe effects in the developing lens. In Sey mice the lens anlage cannot respond to exogenous RA after E9, though it is responsive earlier; the retina and other neural ectoderm can respond to RA at any stage. In Sey mice the ability of presumptive lens and retina to produce and/or sequester RA is also decreased, as assayed with a retinoid-reporter cell line. These results implicate retinoid signaling in lens formation and show that RA signaling in the developing eye is dependent upon Pax-6.

The development of Xenopus tropicalis transgenic lines and their use in studying lens developmental timing in living embryos.

The generation of reporter lines for observing lens differentiation in vivo demonstrates a new strategy for embryological manipulation and allows us to address a long-standing question concerning the timing of the onset of differentiation. Xenopus tropicalis was used to make GFP reporter lines with (gamma)1-crystallin promoter elements directing GFP expression within the early lens. X. tropicalis is a close relative of X. laevis that shares the same ease of tissue manipulation with the added benefits of a diploid genome and faster life cycle. The efficiency of the Xenopus transgenic technique was improved in order to generate greater numbers of normal, adult transgenic animals and to facilitate in vivo analysis of the crystallin promoter. This transgene is transmitted through the germline, providing an accurate and consistent way to monitor lens differentiation. This line permitted us to distinguish models for how the onset of differentiation is controlled: by a process intrinsic to differentiating tissue or one dependent on external cues. This experiment would not have been feasible without the sensitivity and accuracy provided by the in vivo reporter. We find that, in specified lens ectoderm transplanted from neural tube stage donors to younger neural-plate-stage hosts, the onset of differentiation, as measured by expression of the crystallin/GFP transgene, is delayed by an average of 4.4 hours. When specified lens ectoderm is explanted into culture, the delay was an average of 16.3 hours relative to control embryos. These data suggest that the onset of differentiation in specified ectoderm can be altered by the environment and imply that this onset is normally controlled by external cues rather than by an intrinsic mechanism.

Gene activation during early stages of lens induction in Xenopus.

Several stages in the lens determination process have been defined, though it is not known which gene products control these events. At mid-gastrula stages in Xenopus, ectoderm is transiently competent to respond to lens-inducing signals. Between late gastrula and neural tube stages, the presumptive lens ectoderm acquires a lens-forming bias, becomes specified to form lens and begins differentiation. Several genes have been identified, either by expression pattern, mutant phenotype or involvement in crystallin gene regulation, that may play a role in lens bias and specification, and we focus on these roles here. Fate mapping shows that the transcriptional regulators Otx-2, Pax-6 and Sox-3 are expressed in the presumptive lens ectoderm prior to lens differentiation. Otx-2 appears first, followed by Pax-6, during the stages of lens bias (late neural plate stages); expression of Sox-3 follows neural tube closure and lens specification. We also demonstrate the expression of these genes in competent ectoderm transplanted to the lens-forming region. Expression of these genes is maintained or activated preferentially in ectoderm in response to the anterior head environment. Finally, we examined activation of these genes in response to early and late lens-inducing signals. Activation of Otx-2, Pax-6 and Sox-3 in competent ectoderm occurs in response to the early inducing tissue, the anterior neural plate. Since Sox-3 is activated following neural tube closure, we tested its dependence on the later inducing tissue, the optic vesicle, which contacts lens ectoderm at this stage. Sox-3 is not expressed in lens ectoderm, nor does a lens form, when the optic vesicle anlage is removed at late neural plate stages. Expression of these genes demarcates patterning events preceding differentiation and is tightly coupled to particular phases of lens induction.

Anteroposterior neural tissue specification by activin-induced mesoderm.

The transforming growth factor beta superfamily member, activin, is able to induce mesodermal tissues in animal cap explants from Xenopus laevis blastula stage embryos. Activin can act like a morphogen of the dorsoventral axis in that lower doses induce more ventral, and higher doses more dorsal, tissue types. Activin has also previously been reported to induce neural tissues in animal caps. From cell mixing experiments it was inferred that this might be an indirect effect of induced mesoderm signaling to uninduced ectoderm. Here we demonstrate directly that neural tissues do indeed arise by the action of induced mesoderm on uninduced ectoderm. Dorsal mesoderm is itself subdivided into posterior and anterior domains in vivo, but this had not been demonstrated for induced mesoderm. We therefore tested whether different concentrations of activin recreate these different anteroposterior properties as well. We show that the anteroposterior positional value of induced mesoderm, including its neuroinductive properties, depends on the dose of activin applied to the mesoderm, with lower doses inducing more posterior and higher doses giving more anterior markers. We discuss the implications of these results for patterning signals and the relationship between anteroposterior and dorsoventral axes.

Dorsal-ventral patterning during neural induction in Xenopus: assessment of spinal cord regionalization with xHB9, a marker for the motor neuron region.

While the role of the notochord and floor plate in patterning the dorsal-ventral (D/V) axis of the neural tube is clearly established, relatively little is known about the earliest stages of D/V regionalization. In an effort to examine more closely the initial, preneural plate stages of regionalization along the prospective D/V neural axis, we have performed a series of explant experiments employing xHB9, a novel marker of the motor neuron region in Xenopus. Using tissue recombinants and Keller explants we show that direct mesodermal contact is both necessary and sufficient for the initial induction of xHB9 in the motor neuron region. We also show that presumptive neural plate explants removed as early as midgastrulation and cultured in isolation are already specified to express xHB9 but do so in an inappropriate spatial pattern while identical explants are specified to express the floor plate marker vhh-1 with correct spatial patterning. Our data suggest that, in addition to floor plate signaling, continued interactions with the underlying mesoderm through neural tube stages are essential for proper spatial patterning of the motor neuron region.

Neural induction and antero-posterior patterning in the amphibian embryo: past, present and future.

Neural induction and patterning in competent ectoderm occurs during gastrula and early neurula stages in response to signals from dorsal mesoderm. The earliest views of antero-posterior (A-P) patterning were modified beginning in the 1930s, as complexities concerning the timing of the pattern-forming process and potential sources of the patterning signals were revealed. In the 1950s and 1960s several different models for A-P patterning were proposed, all of which, however, bear a number of similarities, including a two-component system for generating A-P axial information in the embryo. Early attempts to identify neural-inducing molecules were largely unsuccessful due to technical limitations in biochemical analyses and concerns about assaying neural responses. The advent of modern molecular genetic technology has permitted more precise tests of a number of classic observations about the timing of A-P patterning and the sources of patterning signals. While some early observations have been confirmed, a number of new concepts have emerged in recent years, particularly concerning the source of patterning signals in the embryo. Striking progress has been made in identifying putative neural-inducing molecules, and recent experiments have begun to suggest how these might contribute to A-P patterning. While the successes in recent years have been revealing, many of the classic issues concerning neural induction and patterning remain essentially as they were when first defined many decades ago. The power of modern molecular genetics, however, should permit many of these issues to be significantly clarified in the decades to come.

Defining intermediate stages in cell determination: acquisition of a lens-forming bias in head ectoderm during lens determination.

Cell determination in vertebrates requires integration of many events, although the mechanisms controlling the different stages in this process are poorly understood. While studies of lens determination have helped define some of these stages, we know very little about the intermediate steps involved in the commitment of ectoderm to lens formation. Lens determination begins during gastrulation when ectoderm is briefly competent to respond to lens-inducing signals and progresses to a point, at the neural tube stage, when the presumptive lens ectoderm is specified. Between these two stages important regulatory genes are activated in the presumptive lens ectoderm, including the transcription factor Pax-6, and transplantation experiments presented here suggest that the presumptive lens ectoderm is becoming "biased" toward lens formation. We show that competent ectoderm from Xenopus laevis embryos forms well-differentiated lenses in most cases when transplanted to the presumptive lens area of neural plate stage hosts, where the lens-inductive environment is strong. When placed into later, neural tube stage hosts, optimally competent ectoderm does form small lenses in about half the cases, but the overall response is much weaker. Even in this weakly inducing environment, however, lens ectoderm that is part way through the inductive process (at the neural plate stage) is shown to have a lens-forming bias, since it forms well differentiated lenses in nearly all cases. While we find that ectoderm surrounding the lens-forming area at neural plate stages does not have a lens-forming bias, non-lens head ectoderm at the neural tube stage does, suggesting that a large region of head ectoderm is biased during neurulation. Using Rana palustris embryos, a species used in the earliest lens induction studies, we were also able to show that the optic vesicle can induce lenses in non-lens head ectoderm at neural tube stages. These results lead us to refine the definition of lens cell determination and provide a context that should allow clarification of determination mechanisms.

Lens induction in axolotls: comparison with inductive signaling mechanisms in Xenopus laevis.

Amphibian lens induction is an embryonic process whose broad outlines are conserved between anurans and urodeles; however, it has been argued that some aspects of this process differ significantly between even closely related species. Classical embryologists concluded that in some species direct contact between the optic vesicle and ectoderm was both necessary and sufficient to induce the ectoderm to form a lens, while in other species tissues other than the optic vesicle induce lens formation. Recent studies of lens induction in Xenopus have argued that lens induction may be more conserved evolutionarily than was previously thought and that the different conclusions reached in the classical literature may be due more to experimental methodology than to actual differences in the process of lens induction. We have tested this hypothesis by examining the timing of lens induction in the axolotl and the ability of various tissues to induce lenses in explant cultures. We find that, despite the evolutionary divergence between Xenopus and Ambystoma, the mechanism of lens specification is substantially similar in the two species. These results support the hypothesis that the mechanism of lens induction is evolutionarily conserved among amphibians.

Inductive processes leading to inner ear formation during Xenopus development.

This study examines the spatial and temporal attributes of inner ear induction in Xenopus embryos. These results are compared to recent experiments concerning lens induction to assess whether head sensory structures share common ontogenetic features. Ectoderm from different regions and stages was transplanted to the presumptive ear region of hosts of either early (neural plate) or late (neural tube) stages. Explants of the presumptive ear ectoderm were also taken from embryos at these stages to establish the time of otic ectoderm specification. We find that ectodermal competence for otic vesicle formation extends through neural plate stages, far longer than for lens formation. Otic vesicle specification occurs substantially earlier, at neural plate stages, than lens specification. Competent ectoderm forms otic vesicles in a high fraction of cases when exposed to the ear-inducing environment of either neural plate stages or neural tube stages, a result which contrasts with lens induction where the neural tube stage embryo provides a much weaker inducing environment than earlier stages. Otic vesicles induced in neural tube stage hosts are primarily in contact with presumptive hindbrain, suggesting that this neural tissue may be sufficient for otic vesicle induction. These studies reveal overall similarities between lens and inner ear induction, but sufficient differences to propose that some facets of determination of these sensory tissues may occur by independent mechanisms and not via a common developmental state.

Xenopus gamma-crystallin gene expression: evidence that the gamma-crystallin gene family is transcribed in lens and nonlens tissues.

Crystallins, the major gene products of the lens, accumulate to high levels during the differentiation of the vertebrate lens. Although crystallins were traditionally thought to be lens specific, it has recently been shown that some are also expressed at very low levels in nonlens tissues. We have examined the embryonic expression pattern of gamma-crystallins, the most abundant crystallins of the embryonic lens in Xenopus laevis. The expression profile of five Xenopus gamma-crystallin genes mirrors the pattern of lens differentiation in X. laevis, exhibiting on average a 100-fold increase between tailbud and tadpole stages. Four of these genes are also ubiquitously expressed outside the lens at a very low level, the first demonstration of nonlens expression of any gamma-crystallin gene; expression of the remaining gene was not detected outside the head region, thus suggesting that there may be two classes of gamma-crystallin genes in X. laevis. Predictions regarding control mechanisms responsible for this dual mode of expression are discussed. This study raises the question of whether any crystallin, on stringent examination, will be found exclusively in the lens.

Characterization of Xenopus laevis gamma-crystallin-encoding genes.

In order to gain insight into crystallin (Cry)-encoding gene (cry) evolution and developmental function, we have determined the gene structure and sequence of several Xenopus laevis gamma-cry. These encode the most abundant Cry in the embryonic lens. Four of the X. laevis gamma-cry, which are part of a multigene family, were isolated from a X. laevis genomic library and demonstrated to have the same gene structure as gamma-cry from other vertebrates, thereby providing further evidence that the split between beta and gamma members of the beta gamma cry family occurred relatively early in evolution. Sequence comparisons indicate that these X. laevis genes share 88-90% nucleotide sequence identity in the protein coding regions, which is slightly higher than the identity observed between gamma-cry of other species. The 5' upstream regions of X. laevis gamma-cry contain a few short stretches of homology and one putative promoter element conserved among all cry genes but lack other regions common to gamma-cry promoters from other organisms. The deduced amino acid sequences of all four genes and one cDNA suggest that the structure of X. laevis gamma-Cry is highly conserved with that of other vertebrate gamma-Cry, as deduced from the known three-dimensional structure of bovine gamma B Cry.

A Xenopus homebox gene defines dorsal-ventral domains in the developing brain.

One of the distinguishing features of vertebrate development is the elaboration of the anterior neural plate into forebrain and midbrain, yet little is known about the early tissue interactions that regulate pattern formation in this region or the genes that mediate these interactions. As an initial step toward analyzing the process of regionalization in the anterior-most region of the brain, we have screened an anterior neural cDNA library for homeobox clones and have identified one which we have called XeNK-2 (Xenopus NK-2) because of its homology to the NK-2 family of homeobox genes. From neurula stages, when XeNK-2 is first detectable, through hatching stages, XeNK-2 mRNA is expressed primarily in the anterior region of the brain. By swimming tadpole stages, XeNK-2 expression resolves into a set of bands positioned at the forebrain-midbrain and the midbrain-hindbrain boundaries, after which XeNK-2 transcripts are no longer detectable. In addition to localized expression along the anterior-posterior axis, XeNK-2 may also play a role in the process of regionalization along the dorsal-ventral axis of the developing brain. At all stages examined, XeNK-2 mRNA is restricted to a pair of stripes that are bilaterally symmetrical in the ventral-lateral region of the brain. To begin to identify the tissue interactions that are required for the proper spatial and temporal localization of XeNK-2, we have performed a series of explant experiments. Consistent with earlier work showing that the A/P axis is not fixed at mid-gastrula stages, we show that XeNK-2 expression is activated when assayed in gastrula stage explants taken from any region along the entire A/P axis and that the tissue interactions necessary to localize XeNK-2 along the A/P axis are not completed until later neurula stages.

Interphotoreceptor retinoid-binding protein (IRBP), a major 124 kDa glycoprotein in the interphotoreceptor matrix of Xenopus laevis. Characterization, molecular cloning and biosynthesis.

We have demonstrated that the neural retina of Xenopus laevis secretes into the extracellular matrix surrounding the inner and outer segments of its photoreceptors a glycoprotein containing hydrophobic domains conserved in mammalian interphotoreceptor retinoid-binding proteins (IRBPs). The soluble extract of the interphotoreceptor matrix contains a 124 kDa protein that cross-reacts with anti-bovine IRBP immunoglobulins. In vitro [3H]fucose incorporation studies combined with in vivo light and electron microscopic autoradiographic analysis, showed that the IRBP-like glycoprotein is synthesized by the neural retina and secreted into the interphotoreceptor matrix. A 1.2 kb Xenopus IRBP cDNA was isolated by screening a stage 42 (swimming tadpole) lambda Zap II library with a human IRBP cDNA under low-stringency conditions. The cDNA hybridizes with a 4.2 kb mRNA in adult Xenopus neural retina, tadpole heads as well as a less-abundant mRNA of the same size in brain. During development, IRBP and opsin mRNA expression correlates with photoreceptor differentiation. The translated amino acid sequence of the Xenopus IRBP clone has an overall 70% identity with the fourth repeat of the human protein. Sequence alignment with the four repeats of human IRBP showed three highly conserved regions, rich in hydrophobic residues. This focal conservation predicts domains important to the protein's function, which presumably is to facilitate the exchange of 11-cis retinal and all-trans retinol between the pigment epithelium and photoreceptors, and to the transport of fatty acids through the hydrophilic interphotoreceptor matrix.

Early opsin expression in Xenopus embryos precedes photoreceptor differentiation.

The visual pigment which serves as the first step in the phototransduction cycle in vertebrate rod cells consists of a retinal chromophore which is linked to the transmembrane protein, opsin. Opsin genes have been isolated from a number of different organisms and studies have shown opsin to be developmentally regulated with both mRNA and protein expression associated with the morphological differentiation of photoreceptor cells. Due to its potential utility as a marker for rod photoreceptor determination in studies of retinal tissue interactions, and because no amphibian opsin genes have as yet been cloned, we isolated cDNA clones of the Xenopus laevis opsin gene. Sequence analysis shows that within the coding region Xenopus opsin shares a high degree of identity with other rod opsin genes, except at the C-terminal where it more closely resembles the mammalian color opsins. A developmental analysis, on the other hand, reveals that Xenopus opsin transcripts are detectable in a retina-specific fashion early in retinal development. Using in situ hybridization we find that Xenopus opsin mRNA is initially restricted to a few isolated cells in the presumptive photoreceptor layer which express the gene at relatively high levels. This suggests that rod photoreceptor determination occurs in single cells, and that the mechanisms controlling opsin expression in Xenopus are initiated well before any evidence of morphological differentiation.

Embryonic lens induction: shedding light on vertebrate tissue determination.

The principle of embryonic induction was defined by early studies of lens determination, and because of the relative simplicity of the developing lens and its interaction with presumptive retinal tissue it has been a favored system for examining mechanisms of induction. Recent studies have led to substantial alterations of the classic model for this process, introducing several elements that significantly refine our view of vertebrate tissue determination.

Vertebrate eye development.

Vertebrate eye determination is mediated by a series of inductive interactions that have now been more precisely defined with the use of regional markers. Analyses of the genes responsible for eye mutations and the cloning of genes delimiting spatial domains within the developing eye have begun to elucidate the molecular basis of this process.

A labile period in the determination of the anterior-posterior axis during early neural development in Xenopus.

The process by which the vertebrate central nervous system acquires its regional properties remains a central problem in developmental biology. It is generally argued that at early gastrula stages the dorsal mesoderm possesses precise anterior-posterior positional information, which is subsequently imparted to the overlying ectoderm. However, using regionally specific gene probes to monitor regional responses in Xenopus embryos, we find that anterior-posterior properties are not fixed until early neurula stages. During gastrulation the regional inducing capacities of the dorsal mesoderm as well as the regional responses of the presumptive neural ectoderm are activated along the entire anterior-posterior axis when these properties are assayed in recombinant and explant experiments, respectively. Restriction of regional inducing capacity in the mesoderm and responsiveness in the neural ectoderm occur only at neural plate stages.