The ascidian pigmented sensory organs: structures and developmental programs.

The recent advances on ascidian pigment sensory organ development and function represent a fascinating platform to get insight on the basic programs of chordate eye formation. This review aims to summarize current knowledge, at the structural and molecular levels, on the two main building blocks of ascidian light sensory organ, i.e. pigment cells and photoreceptor cells. The unique features of these structures (e.g., simplicity and well characterized cell lineage) are indeed making it possible to dissect the developmental programs at single cell resolution and will soon provide a panel of molecular tools to be exploited for a deep developmental and comparative-evolutionary analysis.

The transcription factor snail controls epithelial-mesenchymal transitions by repressing E-cadherin expression.

The Snail family of transcription factors has previously been implicated in the differentiation of epithelial cells into mesenchymal cells (epithelial-mesenchymal transitions) during embryonic development. Epithelial-mesenchymal transitions are also determinants of the progression of carcinomas, occurring concomitantly with the cellular acquisition of migratory properties following downregulation of expression of the adhesion protein E-cadherin. Here we show that mouse Snail is a strong repressor of transcription of the E-cadherin gene. Epithelial cells that ectopically express Snail adopt a fibroblastoid phenotype and acquire tumorigenic and invasive properties. Endogenous Snail protein is present in invasive mouse and human carcinoma cell lines and tumours in which E-cadherin expression has been lost. Therefore, the same molecules are used to trigger epithelial-mesenchymal transitions during embryonic development and in tumour progression. Snail may thus be considered as a marker for malignancy, opening up new avenues for the design of specific anti-invasive drugs.

Characterization of a MADS FLOWERING LOCUS C-LIKE (MFL) sequence in Cichorium intybus: a comparative study of CiMFL and AtFLC reveals homologies and divergences in gene function.

In Arabidopsis thaliana, the ability to flower is mainly related to a floral repressor, FLOWERING LOCUS C (FLC), which is regulated through the vernalization pathway. The genes controlling the vernalization pathway seem to be only partially conserved in dicots other than the Brassicaceae. Cichorium intybus (chicory) is a biennial species belonging to the Asteraceae family, and it shows an obligate vernalization requirement for flowering. Cichorium intybus MADS (MCM1, Agamous, Deficiens, SRF) FLC-like (CiMFL) sequences were isolated in C. intybus by RT-PCR and their expression patterns characterized during plant development and in response to vernalization. The biological function of CiMFL was analysed by complementation of A. thaliana FRIGIDA (AtFRI);flc3. Resetting of MFL expression after vernalization was analysed during microsporogenesis. Before vernalization, CiMFL is mainly expressed in the axils of young leaves. Vernalization induced CiMFL down-regulation under a long-day photoperiod but not under a short-day photoperiod. Furthermore, together with a decrease in CiMFL transcripts, cold conditions induced changes in the morphology of the shoot apical meristem and in the transition to flowering. The biological function of CiMFL was found not to be conserved. Our results show that the regulation of CiMFL expression in time and space and in relation to environmental conditions is only partially conserved with respect to FLC isolated from A. thaliana. A model for flowering repression by CiMFL is proposed.

Cell movements during vertebrate development: integrated tissue behaviour versus individual cell migration.

Cell migration during development is fundamental to the establishment of the embryonic architecture. Depending on the context, cells may move either as integrated sheets of tissue or individually. Recently, molecules that are involved in both these types of cell behaviour have been identified, helping us to understand developmental processes as important as gastrulation and neural crest formation, and ultimately, the morphogenetic movements that shape the embryo.

PLAUF binding to the 3'UTR of the H3.3 histone transcript affects mRNA stability.

In P. lividus sea urchin the H3.3 histone variant is coded by an mRNA characterized by a long 3'UTR containing ARE (AU-Rich element) motifs. RNA stability assays performed in rabbit reticulocyte lysate showed that such 3'UTR affects the degradation rate of the transcripts. In fact, chimeric molecules containing the 3'UTR of H3.3 transcript, ligated to the coding region of the rabbit beta-globin transcript, were unstable whereas chimeric molecules containing mainly the coding region of the H3.3 transcript were stable as the wild-type globin mRNA. Three proteins (45kDa, 32kDa and 25kDa) that bind specifically the 3'UTR have been revealed in the whole protein extracts of embryos at different stages of development. PLAUF, a P. lividus RNA-binding protein similar to human and rodent AUF1 proteins, was identified as the 32kDa factor using anti-PLAUF antibody in Western blot and supershift mobility assays. Moreover the recombinant GST-PLAUF protein specifically binds part of the H3.3 3'UTR and in vitro affects the half-life of the transcript. In addition in situ hybridization experiments demonstrated that PLAUF and H3.3 histone mRNAs co-localize in embryos at different stages of development. In conclusion all the reported results suggest that PLAUF can bind in vivo the 3'UTR of the H3.3 histone mRNA and plays some role in the stability of the mRNA.

The increasing complexity of the Snail gene superfamily in metazoan evolution.

The Snail family of zinc-finger transcription factors is involved not only in the development of vertebrate and invertebrate embryos, but also in tumour progression. Following the identification of eight new members, we have analysed the evolutionary history of these genes and found that they constitute a superfamily that groups two independent families, Snail and Scratch. We propose that the duplication of an ancestral gene at the time of the metazoan radiation (1000-500 Myr ago) gave rise to Snail and Scratch, and that independent duplications in protostomes and deuterostomes led to the present situation. We discuss the implications of the distinct duplication events on the acquisition of new functions.

Identification and developmental expression of Ci-msxb: a novel homologue of Drosophila msh gene in Ciona intestinalis.

We report the cloning and expression pattern of Ci-msxb the second Ciona intestinalis homeobox gene homologue to the Drosophila muscle segment homeobox (msh) gene. Northern blot analysis showed that transcripts appeared at gastrula stage, peaked in the early tailbud and decreased during the tailed stages. Whole mount in situ hybridization showed that the Ci-msxb expression first is detected at 110 cell-stage in the blastomeres that are precursors of different tissue (muscle, spinal cord, endodermal strand, brain, mesenchyme, pigmented cells and primordial pharynx). Transcript level declined in mesoderm cells after the completion of gastrulation, but mRNAs were still present in the folding neural plate during neurulation and in the pigmented cells. Later, at larval stage, transcripts were present around the otolith and ocellus, in a restricted part of the nervous system and in the primordial pharynx; the gene expression was conserved after metamorphosis in the juvenile.

Isolation of cDNA clones encoding DNA methyltransferase of sea urchin P. lividus: expression during embryonic development.

A full-length cDNA, encoding a DNA (cytosine-5)-methyltransferase (DNA MTase), has been assembled from a series of overlapping cDNA clones isolated from P. lividus sea urchin embryo cDNA libraries. The cDNA contains 103 bp 5'-UTR, 4839 bp open reading frame corresponding to a 1612 amino acids (aa) protein and 2240 bp 3'-UTR including a terminal 18-bp poly(A) tail. Both the cDNA and the encoded protein are the longest so far reported for DNA MTases. The protein shows five distinct and sequential regions of identity with the other animal DNA MTases, with values of identity from zero to 80%. Northern blot analyses reveal a single RNA band of about 7.5 kb in length showing a highly regulated concentration pattern during development with peak value at the four blastomere stage.

DNA (cytosine-5) methyltransferase turnover and cellular localization in developing Paracentrotus lividus sea urchin embryo.

The turnover and localization of the enzyme DNA (cytosine-5) methyltransferase (Dnmt1) were studied during Paracentrotus lividus sea urchin embryo development using antibody preparations against the NH(2) and COOH-terminal regions of the molecule. The antibodies reveal, by Western blots and whole-mount analyses, that the enzyme is differently required during embryonic development. The changeover point is at blastula stage, where a proteolytic mechanism hydrolyses the enzyme present in all embryonic cells by removing a peptide of about 45 kDa from the amino terminal region of the 190 kDa enzyme initially synthesized on maternal transcripts. The resulting 145 kDa enzyme shows modified catalytic properties, different antibody reactivity and is rapidly destroyed in the few hours before gastrulation. At more advanced stages of development the enzyme is newly synthesized but only in particular cell types, among which neurons. The data show that Dnmt1 is removed from embryonic cells before gastrulation to be synthesized again at different levels in different cell types, indicating that the concentration of Dnmt1 is critical for the various differentiated cells of the developing sea urchin embryo.

Patterning the ascidian nervous system: structure, expression and transgenic analysis of the CiHox3 gene.

Hox genes play a fundamental role in the establishment of chordate body plan, especially in the anteroposterior patterning of the nervous system. Particularly interesting are the anterior groups of Hox genes (Hox1-Hox4) since their expression is coupled to the control of regional identity in the anterior regions of the nervous system, where the highest structural diversity is observed. Ascidians, among chordates, are considered a good model to investigate evolution of Hox gene, organisation, regulation and function. We report here the cloning and the expression pattern of CiHox3, a Ciona intestinalis anterior Hox gene homologous to the paralogy group 3 genes. In situ hybridization at the larva stage revealed that CiHox3 expression was restricted to the visceral ganglion of the central nervous system. The presence of a sharp posterior boundary and the absence of transcript in mesodermal tissues are distinctive features of CiHox3 expression when compared to the paralogy group 3 in other chordates. We have investigated the regulatory elements underlying CiHox3 neural-specific expression and, using transgenic analysis, we were able to isolate an 80 bp enhancer responsible of CiHox3 activation in the central nervous system (CNS). A comparative study between mouse and Ciona Hox3 promoters demonstrated that divergent mechanisms are involved in the regulation of these genes in vertebrates and ascidians.

Developmental regulation and tissue-specific localization of calmodulin mRNA in the protochordate Ciona intestinalis.

A full-length cDNA encoding a highly conserved calmodulin was isolated from a cDNA library prepared from hatched larvae of the ascidian Ciona intestinalis. Sequence analysis has identified a 447 b.p. open reading frame, encoding a putative protein of 149 amino acid residues, with a predicted molecular weight of 16.8 kDa, showing 85-98% identity to known calmodulins. Northern blot analysis revealed a single transcript of about 0.8 kb in length, which was maternally expressed and progressively increased during development, until late tail-bud stage. Whole-mount in situ hybridizations, carried out on embryos at different stages of development, showed that starting from the neurula stage, the C. intestinalis calmodulin (Ci-CaM) expression became restricted to the neuroectoderm and that in larvae it was specifically detected in the nervous system.

A new role for E12/E47 in the repression of E-cadherin expression and epithelial-mesenchymal transitions.

Down-regulation of E-cadherin expression is a determinant of tumor cell invasiveness, an event frequently associated with epithelial-mesenchymal transitions. Here we show that the mouse E12/E47 basic helix-loop-helix transcription factor (the E2A gene product) acts as a repressor of E-cadherin expression and triggers epithelial-mesenchymal transitions. The mouse E47 factor was isolated in a one-hybrid system designed to isolate repressors of the mouse E-cadherin promoter. Epithelial cells ectopically expressing E47 adopt a fibroblastic phenotype and acquire tumorigenic and migratory/invasive properties, concomitant with the suppression of E-cadherin expression. Suppression of E-cadherin expression under stable or inducible expression of E47 in epithelial cells occurs at the transcriptional level and is dependent on the E-boxes of the E-cadherin promoter. Interestingly, analysis of endogenous E2A expression in murine and human cell lines illustrated its presence in E-cadherin-deficient, invasive carcinoma cells but its absence from epithelial cell lines. This expression pattern is consistent with that observed in early mouse embryos, where E2A mRNA is absent from epithelia but strongly expressed in the mesoderm. These results implicate E12/E47 as a repressor of E-cadherin expression during both development and tumor progression and indicate its involvement in the acquisition and/or maintenance of the mesenchymal phenotype.