Genetic analysis of metamorphic and premetamorphic Xenopus ciliary marginal zone.

A major event affecting the eye during amphibian metamorphosis is an asymmetrical growth of the ventrotemporal portion of the retina compared with its dorsonasal counterpart. This event is due to an increased proliferation of the precursors of the ventral ciliary marginal zone (CMZ). Here, we analyze the expression patterns of several key homeobox genes implicated in eye development (Xrx1, Xvax2, Xsix3, Xpax6, Xchx10, Xotx2) to understand whether they are active at the time in which the metamorphic changes of the retina occur. We also analyze their expression patterns in the ventral and dorsal CMZ and compare them with bromodeoxyuridine incorporation in the CMZ. Our results suggest that the metamorphic CMZ maintains the functional subdivisions described during embryonic development. Moreover, we find that genes involved in proliferation and cell type determination of the embryonic retina are actively transcribed in the proliferating CMZ, thus indicating a potential regulatory role for these genes in the metamorphic retina.

Cloning and expression of noz1, a zebrafish zinc finger gene related to Drosophila nocA.

We report the isolation of noz1, a novel zebrafish zinc finger gene which displays sequence similarity to Drosophila nocA. noz1 transcripts are detected at the shield stage within the germ ring and excluded from the most dorsal region. By the end of gastrulation, noz1 is expressed in the presumptive hindbrain and spinal cord as well as in the forming tailbud. During somitogenesis noz1 shows a dynamic expression in the midbrain-hindbrain boundary, hindbrain and spinal cord. This results, at 24 hpf, in a graded expression with the highest level in rhombomeres 2 and 3, and the lowest in the spinal cord. Expression analysis in swirl and chordino mutants as well as in retinoic acid treated embryos indicate that noz1 is activated by BMP antagonists and neural posteriorizing signals.

Homeobox genes in the genetic control of eye development.

Vertebrate eye formation is a complex process which involves early specification of the prospective eye territory, induction events, patterning along the polarity axes and regional specification, to bring about the proper morphogenetic movements, cell proliferation, cell differentiation and neural connections allowing visual function. The molecular machinery underlying such complex developmental events is presently under an intense research scrutiny and many associated genetic factors have been isolated and characterized. These studies produced striking knowledge in the field, especially with respect to uncovering the role of key genes and their possible evolutionary conservation. Presently, a major task is to define the complex interactions connecting the multiplicity of molecular players that regulate eye development. We recently identified two homeobox genes, Xrx1 and Xvax2, and studied their function by using the Xenopus embryo as a developmental model system. Xrx1 and Xvax2 control key aspects of eye development. In particular, Xrx1 appears to play a role in the early specification of anterior neural regions fated to give rise to retina and forebrain structures, and in promoting cell proliferation within these territories. On the other hand, Xvax2 is involved in regulating the eye proximo-distal and/or dorsoventral polarity, and the morphogenetic movements taking place during formation of the optic stalk and cup. Here we review the experimental results addressing the roles of Xrx1 and Xvax2 and their vertebrate orthologues, and discuss their relationship with other molecules also playing a related function in eye development.

A homeobox gene, vax2, controls the patterning of the eye dorsoventral axis.

We have identified a transcription factor specifically expressed in the developing vertebrate eye. We named this gene vax2 because of the high degree of sequence similarity to the recently described vax1. Both in the human and mouse genomes, vax2 is localized in the vicinity of the emx1 gene. This mapping assignment, together with the previously reported colocalization of Vax1 and Emx2 in mouse, indicates that the vax and the emx genes may be organized in clusters. vax2 has a remarkable expression domain confined to the ventral portion of the prospective neural retina in mouse, human, and Xenopus. The overexpression of either the frog Xvax2 or the human VAX2 in Xenopus embryos leads to an aberrant eye phenotype and, in particular, determines a ventralizing effect on the developing eye. The expression domain of the transcription factor Xpax2, normally confined to the ventral developing retina, extends to the dorsal region of the retina after overexpression of vax2. On the other hand, the expression of Xvent2, a molecular marker of the dorsal retina, is strongly reduced. Furthermore, vax2 overexpression induces a striking expansion of the optic stalk, a structure deriving from the ventralmost region of the eye vesicle. Altogether, these data indicate that vax2 plays a crucial role in eye development and, in particular, in the specification of the ventral optic vesicle.

Role of Xrx1 in Xenopus eye and anterior brain development.

The anteriormost part of the neural plate is fated to give rise to the retina and anterior brain regions. In Xenopus, this territory is initially included within the expression domain of the bicoid-class homeobox gene Xotx2 but very soon, at the beginning of neurulation, it becomes devoid of Xotx2 transcripts in spatiotemporal concomitance with the transcriptional activation of the paired-like homeobox gene Xrx1. By use of gain- and loss-of-function approaches, we have studied the role played by Xrx1 in the anterior neural plate and its interactions with other anterior homeobox genes. We find that, at early neurula stage Xrx1 is able to repress Xotx2 expression, thus first defining the retina-diencephalon territory in the anterior neural plate. Overexpression studies indicate that Xrx1 possesses a proliferative activity that is coupled with the specification of anterior fate. Expression of a Xrx1 dominant repressor construct (Xrx1-EnR) results in a severe impairment of eye and anterior brain development. Analysis of several brain markers in early Xrx1-EnR-injected embryos reveals that anterior deletions are preceded by a reduction of anterior gene expression domains in the neural plate. Accordingly, expression of anterior markers is abolished or decreased in animal caps coinjected with the neural inducer chordin and the Xrx1-EnR construct. The lack of expansion of mid-hindbrain markers, and the increase of apoptosis in the anterior neural plate after Xrx1-EnR injection, indicate that anterior deletions result from an early loss of anterior neural plate territories rather than posteriorization of the neuroectoderm. Altogether, these data suggest that Xrx1 plays a role in assigning anterior and proliferative properties to the rostralmost part of the neural plate, thus being required for eye and anterior brain development.

Anteroposterior patterning by mutual repression of orthodenticle and caudal-type transcription factors.

Members of the Otx (orthodenticle) and Cdx (caudal) families of homeodomain transcription factors are expressed in similar embryonic regions in all animal groups and have been shown to be directly involved in anteroposterior patterning in a number of species. In the amphibian Xenopus laevis, the Otx family gene Xotx2 and the Cdx family gene Xcad3 are both expressed within the early dorsal organizer. We show that they have mutually repressive activities, suggesting that they play a crucial role in the early regionalization of the organizer into anterior and posterior territories. Xotx2 can act both as an activator and repressor of gene expression depending on context. A form of Xotx2 that acts exclusively as a repressor (OtxEn-R) was made by fusing the Xotx2 homeodomain to the Drosophila melanogaster engrailed transcriptional repressor domain. Overexpression of this protein in vivo indicates that OtxEn-R antagonizes the activating function of endogenous Xotx2 for anterior marker genes such as XCG and goosecoid but retains the ability to repress the expression of posterior markers such as Xcad3 and Xbra. OtxEn-R overexpression causes a severe derangement of anterior development, resulting in the loss of cement gland, eyes, stomodeal opening, and pharynx. The specification and development of anterior neural structures is dramatically abnormal up to and including the isthmic signaling center at the midbrain/hindbrain junction. This study provides good evidence that Xenopus Otx2 is required for normal head patterning and the process of anterior neural specification. We propose that a mutually antagonistic relationship between Otx and Cdx factors is a basic aspect of anteroposterior patterning in all vertebrates.

Activating and repressing signals in head development: the role of Xotx1 and Xotx2.

Xotx1 and Xotx2 are two Xenopus homologues of the Drosophila orthodenticle gene that are specifically expressed in presumptive head regions that do not undergo convergent extension movements during gastrulation. We studied the function of Xotx1 and compared it with that of Xotx2. Ectopic expression of each of the two genes has similar effects in impairing trunk and tail development. Experimental evidence suggests that posterior deficiencies observed in microinjected embryos are due to negative interference with convergent extension movements. Transplantations of putative tail-forming regions showed that, while Xotx1 overexpression inhibits tail organizer activity, Xotx2 overexpression is able to turn a tail organizer into a head organizer. Finally, Xotx1 and Xotx2 are activated by factors involved in head formation and repressed by a posteriorizing signal like retinoic acid. Taken together, these data suggest that Xotx genes are involved in head-organizing activity. They also suggest that the head organizer may act not only stimulating the formation of anterior regions, but also repressing the formation of posterior structures.

Xrx1, a novel Xenopus homeobox gene expressed during eye and pineal gland development.

We have isolated a novel Xenopus homeobox gene, Xrx1, belonging to the paired-like class of homeobox genes. Xrx1 is expressed in the anterior neural plate, and subsequently in the neural structures of the developing eye (neural retina and pigmented epithelium), and in other forebrain structures deriving from the anterior neural plate: in the pineal gland, throughout its development, in the diencephalon floor and in the hypophysis. Its rostral limit of expression corresponds to the chiasmatic ridge, which some authors consider as the anteriormost limit of the neural tube: thus, Xrx1 may represent one of the most anteriorly expressed homeobox genes reported to date. Moreover, its expression in organs implicated in the establishment of circadian rhythms, may suggest for Xrx1 a role in the genetic control of this function. Finally, analysis of Xrx1 expression in embryos subjected to various treatments, or microinjected with different dorsalizing agents (noggin, Xwnt-8), suggests that vertical inductive signals leading to head morphogenesis are required to activate Xrx1.

Xotx genes in the developing brain of Xenopus laevis.

The vertebrate Otx gene family is related to otd, a gene contributing to head development in Drosophila. We previously reported on the expression of Xotx2 gene, homologous to the murine Otx2 gene, during early Xenopus development. In the present paper we report an extensive analysis of the expression pattern of Xotx2 during later stages of development and also the cloning and developmental expression of two additional Otx Xenopus genes, Xotx1 and Xotx4. These latter two genes bear a good degree of homology to murine Otx1, higher for Xotx1 than for Xotx4. Both these genes are expressed in the forebrain and midbrain regions and their developmental patterns of expression are very similar, although not perfectly superimposable. Spatial and temporal expression patterns of the three Xotx genes suggest that they may be involved in the early subdivision of the rostral brain, providing antero-posterior positional information within the most anterior districts of the neuraxis. The three Xotx genes are expressed in all the developing sense organs of the head, eyes, olfactory system and otic vesicles. By in situ hybridization the earliest detectable expression is found in anterior mesendoderm for Xotx2, and in presumptive anterior neuroectoderm for Xotx1 and Xotx4. In addition, we examined whether Xotx1 is expressed in exogastrulae, finding that Xotx1 expression can be activated in the apparent absence of vertical signals of neural induction.

The Xenopus homologue of Otx2 is a maternal homeobox gene that demarcates and specifies anterior body regions.

In this paper we study Xotx2, a Xenopus homeobox gene related to orthodenticle, a gene expressed in the developing head of Drosophila. The murine cognate, Otx2, is first expressed in the entire epiblast of prestreak embryos and later in very anterior regions of late-gastrulae, including the neuroectoderm of presumptive fore- and mid-brain. In Xenopus, RNase protection experiments reveal that Xotx2 is expressed at low levels throughout early development from unfertilized egg to late blastula, when its expression level significantly increases. Whole-mount in situ hybridization shows a localized expression in the dorsal region of the marginal zone at stage 9.5. At stage 10.25 Xotx2 is expressed in dorsal bottle cells and in cells of the dorsal deep zone fated to give rise to prechordal mesendoderm, suggesting a role in the specification of very anterior structures. In stage 10.5 gastrulae, Xotx2 transcripts start to be detectable also in presumptive anterior neuroectoderm, where they persist in subsequent stages. Various treatments of early embryos cause a general reorganization of Xotx2 expression. In particular, retinoic acid treatment essentially abolishes Xotx2 expression in neuroectoderm. Microinjection of Xotx2 mRNA in 1-, 2- and 4-cell stage embryos causes the appearance of secondary cement glands and partial secondary axes in embryos with reduced trunk and tail structures. The presence of the Xotx2 homeodomain is required to produce these effects. In particular, this homeodomain contains a specific lysine residue at position 9 of the recognition helix. Microinjected transcripts of Xotx2 constructs containing a homeodomain where this lysine is substituted by a glutamine or a glutamic acid residue fail to cause these effects.

RNA binding properties and evolutionary conservation of the Xenopus multifinger protein Xfin.

Xfin is a Xenopus zinc finger protein which is expressed in the cytoplasm of the oocyte and throughout embryogenesis, as well as in the cytoplasm of some specific and highly differentiated cell types (De Lucchini et al., Mech. Dev. 36, 31-40, 1991). In this paper we present a characterization of some structural features of the protein and of its nucleic acid binding properties. We found that Xfin is a phosphoprotein, is present in the soluble fraction of the cytoplasm, and is actively phosphorylated in cytosolic extracts. Several putative phosphorylation sites are present in the cDNA-derived protein sequence, mostly located at specific positions within the Zn-fingers. In an in vitro assay a fusion protein containing part of the finger region of Xfin exhibits specific binding to a poly (G) RNA homopolymer, while it does not bind DNA. The RNA binding activity of the protein is significantly enhanced by phosphorylation. A putative Xfin homolog, which appears to be evolutionarily conserved with regard to size, cytoplasmic expression and antigenic specificity, is present in representatives of five Vertebrate classes. Taken together, these results may suggest that, by virtue of its RNA binding activity modulated through phosphorylation, Xfin could serve some evolutionarily conserved function in post-transcriptional regulation processes.

Changes in 7SL RNA conformation during the signal recognition particle cycle.

The structure of 7SL RNA has been probed by chemical modification followed by primer extension, using four substrates: (i) naked 7SL RNA; (ii) free signal recognition particle (SRP); (iii) polysome bound SRP; and (iv) membrane bound SRP. Decreasing sensitivity to chemical modification between these different substrates suggests regions on 7SL RNA that: bind proteins associated with SRP might interact with ribosomes; and are protected by binding to membranes. Other areas increase in chemical sensitivity, exemplified by a tertiary interaction present in naked 7SL RNA but not in free SRP. Such changes suggest that 7SL RNA changes its conformation during the SRP cycle. These conformational changes could be a necessary component to move through the SRP cycle from one stage to the next.

Extra-ribosomal spacer sequences in Triturus.

We show that, in Triturus vulgaris meridionalis, sequences homologous to the rDNA "non-transcribed" spacer (NTS) are clustered at chromosomal loci where they are not associated with 18 S or 28 S rDNA genes: these sequences are referred to as the extra-ribosomal spacer sequences. Genomic clones containing such extra-ribosomal spacer sequences have been isolated. As shown by restriction mapping, these clones appear to consist mostly of repetitive BamHI fragments that are, in turn, internally repetitious and highly homologous to each other. The structure of the clones was confirmed by nucleotide sequence analysis, which also demonstrates the high degree of conservation between the BamHI elements and the homologous NTS sequences. An intriguing 12 base-pair homology between the extra-ribosomal spacer sequences and a Xenopus NTS enhancer sequence is reported. The possibility that a repetitive octanucleotide motif found within the BamHI elements could act as a recombination hotspot by virtue of its similarity with the Escherichia coli chi sequence is discussed.