decapentaplegic and wingless are regulated by eyes absent and eyegone and interact to direct the pattern of retinal differentiation in the eye disc.

Signaling by the secreted hedgehog, decapentaplegic and wingless proteins organizes the pattern of photoreceptor differentiation within the Drosophila eye imaginal disc; hedgehog and decapentaplegic are required for differentiation to initiate at the posterior margin and progress across the disc, while wingless prevents it from initiating at the lateral margins. Our analysis of these interactions has shown that initiation requires both the presence of decapentaplegic and the absence of wingless, which inhibits photoreceptor differentiation downstream of the reception of the decapentaplegic signal. However, wingless is unable to inhibit differentiation driven by activation of the epidermal growth factor receptor pathway. The effect of wingless is subject to regional variations in control, as the anterior margin of the disc is insensitive to wingless inhibition. The eyes absent and eyegone genes encode members of a group of nuclear proteins required to specify the fate of the eye imaginal disc. We show that both eyes absent and eyegone are required for normal activation of decapentaplegic expression at the posterior and lateral margins of the disc, and repression of wingless expression in presumptive retinal tissue. The requirement for eyegone can be alleviated by inhibition of the wingless signaling pathway, suggesting that eyegone promotes eye development primarily by repressing wingless. These results provide a link between the early specification and later differentiation of the eye disc.

u-shaped encodes a zinc finger protein that regulates the proneural genes achaete and scute during the formation of bristles in Drosophila.

The pattern of the large sensory bristles on the notum of Drosophila arises as a consequence of the expression of the achaete and scute genes. The gene u-shaped encodes a novel zinc finger that acts as a transregulator of achaete and scute in the dorsal region of the notum. Viable hypomorphic u-shaped mutants display additional dorsocentral and scutellar bristles that result from overexpression of achaete and scute. In contrast, overexpression of u-shaped causes a loss of achaete-scute expression and consequently a loss of dorsal bristles. The effects on the dorsocentral bristles appear to be mediated through the enhancer sequences that regulate achaete and scute at this site. The effects of u-shaped mutants are similar to those of a class of dominant alleles of the gene pannier with which they display allele-specific interactions, suggesting that the products of both genes cooperate in the regulation of achaete and scute. A study of the sites at which the dorsocentral bristles arise in mosaic u-shaped nota, suggests that the levels of the u-shaped protein are crucial for the precise positioning of the precursors of these bristles.

Genes of the Enhancer of split and achaete-scute complexes are required for a regulatory loop between Notch and Delta during lateral signalling in Drosophila.

Like the neuroblasts of the central nervous system, sensory organ precursors of the peripheral nervous system of the Drosophila thorax arise as single spaced cells. However, groups of cells initially have neural potential as visualized by the expression of the proneural genes achaete and scute. A class of genes, known as the 'neurogenic genes', function to restrict the proportion of cells that differentiate as sensory organ precursors. They mediate cell communication between the competent cells by means of an inhibitory signal, Delta, that is transduced through the Notch receptor and results in a cessation of achaete-scute activity. Here we show that mutation of either the bHLH-encoding genes of the Enhancer of split complex (E(spl)-C) or groucho, like Notch or Delta mutants, cause an overproduction of sensory organ precursors at the expense of epidermis. The mutant cells behave antonomously suggesting that the corresponding gene products are required for reception of the inhibitory signal. Epistasis experiments place both E(spl)-C bHLH-encoding genes and groucho downstream of Notch and upstream of achaete and scute, consistent with the idea that they are part of the Notch signalling cascade. Since all competent cells produce both the receptor and its ligand, it was postulated that Notch and Delta are linked within each cell by a feedback loop. We show, that, like mutant Notch cells, cells mutant for E(spl)-C bHLH-encoding genes or groucho inhibit neighbouring wild-type cells causing them to adopt the epidermal fate. This inhibition requires the genes of the achaete-scute complex (AS-C) which must therefore regulate the signal Delta. Thus there is a regulatory loop between Notch and Delta that is under the transcriptional control of the E(spl)-C and AS-C genes.

Drosophila shaggy kinase and rat glycogen synthase kinase-3 have conserved activities and act downstream of Notch.

During neurogenesis in Drosophila, groups of equipotential, neurally competent cells choose between epidermal and neural fates. Notch, a phylogenetically conserved transmembrane protein, may act as a receptor in a lateral signalling pathway in which a single neural precursor is chosen from each group and the neural fate of the other cells is inhibited, causing them to differentiate into epidermis. Possible intracellular transduction events mediating signals from Notch are, however, unknown. shaggy is also required for the lateral signal and encodes serine/threonine protein kinases with homology to the glycogen synthase kinase-3 (GSK-3) enzymes that act in signal transduction pathways in vertebrates. We report here that, in transgenic flies, GSK-3 beta can substitute for shaggy, and we also present a study of epistatic relationships between shaggy and gain and loss of function alleles of Notch. The results indicate that shaggy/GSK-3 is part of a signalling pathway downstream of Notch.

Negative regulation of Jun/AP-1: conserved function of glycogen synthase kinase 3 and the Drosophila kinase shaggy.

Transcription factor AP-1 is constituted by the products of the various fos and jun genes. AP-1 activity is modulated by second messengers and appears to involve post-translational modifications of Fos and Jun. It has been shown that phosphorylation mediated by glycogen synthase kinase 3 (GSK-3) is involved in negative regulation of c-Jun DNA-binding function in vitro. Here we show that two forms of GSK-3 function to decrease the DNA-binding activity as well as the transcriptional activation elicited by c-Jun in vivo. Similarly, the other members of the jun family, JunB, JunD and v-Jun, are negatively regulated by GSK-3 in vivo, although to a slightly lesser extent than c-Jun. We have also tested the proteins encoded by the Drosophila shaggy gene (sgg) in our assays. The sgg proteins share homology with the mammalian GSK-3 and appear to be important for the normal segregation of bristle precursor cells in the imaginal epithelium in Drosophila. Here we show that the products of the sgg gene can also function as negative regulators of Jun/AP-1.

Functional significance of a family of protein kinases encoded at the shaggy locus in Drosophila.

The characterization of the structurally complex gene shaggy is presented. This gene encodes multiple proteins with putative serine/threonine kinase activity thought to be involved in signal transduction mechanisms that take place during several patterning events throughout Drosophila development. The gene comprises two transcription units that give rise to 10 transcripts and five different proteins with a common kinase catalytic domain and overlapping patterns of expression during development. Mutational analysis of shaggy defines a single complementation group, lethality of which is associated with the loss of two major shaggy proteins. These studies allow the first definition of a true null allele. Two proteins may fulfill maternal requirements. Phenotypes of flies expressing individual shaggy proteins revealed that although there is some redundancy between the different forms they do not all carry out identical functions in vivo. However, under experimental conditions, a single form of the protein was able to carry out all known requirements. This protein probably also functions as part of a signal transduction cascade in the imaginal neuroepithelium, where cells have to choose between epidermal and neural fates.

A dual role for the protein kinase shaggy in the repression of achaete-scute.

achaete and scute are expressed in a spatially restricted pattern and provide neural potential to cells. The domains of expression depend partly on extramacrochaetae whose product is itself spatially restricted and acts as a negative post-translational regulator of achaete and scute. The protein kinase shaggy also represses achaete and scute at many sites but may act via intermediate transcription factors. However shaggy and extramacrochaetae act synergistically and molecular studies suggest that they may be part of the same pathway. shaggy is functionally homologous to the mammalian glycogen synthase kinase-3 and analogy with the known physiology of this enzyme, suggests that this function of shaggy may result from the "constitutive" activity. At the site where a single neural precursor will develop, achaete and scute are initially expressed in a group of equivalent cells. The genes Notch and Delta are part of a lateral signal required to single out one precursor cell and to silence achaete and scute expression in the other cells. shaggy is required downstream of Notch for transduction of the inhibitory signal. This second role of shaggy may be due to modulation of enzymatic activity during signalling.

An early embryonic product of the gene shaggy encodes a serine/threonine protein kinase related to the CDC28/cdc2+ subfamily.

The product(s) of the gene shaggy (sgg) is required for seemingly unrelated events during the development of Drosophila melanogaster. In embryos, maternal and zygotically derived sgg products are required initially to construct a normal syncytial blastoderm and later for normal segmentation. Furthermore, in mutant animals a process of intercellular communication that is required for the segregation of the neural and epidermal lineage during the formation of the central nervous system and the adult peripheral nervous system is disrupted. Here we describe a transcription unit of approximately 40 kb lying within the cloned chromosomal interval 3B1, and provide evidence that it encodes the sgg+ function. Of seven developmentally regulated transcripts that are partially generated by alternative splicing, two seem to be responsible for early sgg activity. Sequence analysis of corresponding cDNA(s) predicts a protein of 514 amino acids with a canonical catalytic domain found in serine/threonine specific protein kinases, linked to an unusual region rich in Gly, Ala and Ser. A search for homologies as well as a comparative study of the kinase catalytic domain with that of other proteins, revealed that the protein kinase domain of sgg is distantly related to the members of the CDC28/cdc2+ subfamily of protein kinases, all of which play cardinal roles in the regulation of the yeast and mammalian cell cycles. Ubiquitous expression of sgg transcripts was found during embryonic stages. A possible role of the sgg protein in a signal transduction pathway necessary for intercellular communication at different stages of development is discussed.

Mutant Drosophila embryos in which all cells adopt a neural fate.

In the Drosophila embryo, early developmental decisions lead to all cells adopting one of several initial fates, such as those characteristic of the germ layers. The central nervous system is formed subsequently from the neurogenic region of the ectoderm, in which progenitor cells of the neuroblasts and ventral epidermis are intermingled. Two classes of genes govern the segregation of neuroblasts and peripheral sensory organs. The pro-neural class of genes, for example, the achaete-scute complex, participates in the initial decision to make each uniquely positioned neuroblast or sensory organ, but are initially expressed in groups of cells. The segregation of a neuroblast or sensory organ from an equivalent group of equipotential cells involves a mechanism of lateral inhibition whereby the future epidermal cells are prevented from engaging in the primary dominant neural fate. In the absence of this inhibitory signal, all cells of the group will become neural by default. The neurogenic class of genes is thought to mediate these cell interactions. Here we report that cells in embryos mutant for shaggy which are unable to adopt any of the early initial fates, instead develop neural characteristics.

[Esophagoplasty in caustic stenosis in children. Apropos of 28 cases]. / Les oesophagoplasties pour sténose caustique chez l'enfant. A propos de 28 cas.

28 cases of oesophagectomy for caustic stenosis in children are reported. The authors discuss the technical modalities and the evolution of ideas, especially the importance of the oesophagectomy, in front of the risk of a secondary cancerisation. This severe complication becomes accentuated with the years and prescribes in children more systematic oesophagectomy concomitant or secondary to the oesophagoplasty.

Changes in the chromatin structure of Drosophila glue genes accompany developmental cessation of transcription in wild type and transformed strains.

Three Drosophila salivary gland glue genes show a dramatic transition in their DNAse I hypersensitive sites during the short period between the late third instar and the white prepupa, which correlates with the cessation of their transcription. In culture cells, where the genes are inactive, there is a chromatin configuration similar to that of prepupal salivary glands. In two transformed fly strains where the sgs3 gene is active at new chromosomal sites, including one in which 2.6 kb of sgs3 upstream sequences have been inverted, the same DNAase I hypersensitive sites and developmental transitions are seen over the same DNA regions. These results, together with the analysis of transformants carrying rearranged sgs3 genes, suggest that there is at least one distal DNAase I hypersensitive site associated with an element of regulation which may be exchanged between sgs genes.

Remote regulatory sequences of the Drosophila glue gene sgs3 as revealed by P-element transformation.

We have examined the transcriptional activity of the Formosa sgs3 glue gene reinserted in the Drosophila genome in transposons containing various arrangements of its natural flanking sequences. The shortest transposons, retaining 127 bp of 5' sequence show no (or very rare) expression. Constructs with up to 1.4 kb of 5' sequence show tissue- and stage-specific accumulation of transcripts, but at severely reduced levels when compared with the resident sgs3 glue gene. To obtain wild-type levels of transcripts, sequences contained in the next 1.3 kb are necessary. At least one regulatory element defined by these experiments is bi-directional. Our results show that marked P-element transformation vectors can be used to analyze regulatory elements of linked genes.

The normal developmental regulation of a cloned sgs3 'glue' gene chromosomally integrated in Drosophila melanogaster by P element transformation.

A 7-kb genomic segment containing the coding sequence for the Drosophila melanogaster Formosa variant of salivary gland secretion protein 3 (sgs3) has been inserted into the snw y, bw, st strain of D. melanogaster using the P transformation vector p.6.1. The inserted sequence codes for a shorter RNA which can be distinguished from that of the host gene. The amount of RNA, and its stage- and tissue-specific synthesis is identical to that of the host gene, which suggests that all the cis-acting regulatory DNA sequences for this gene are contained within this 7-kb segment.

Vectors containing a prokaryotic dihydrofolate reductase gene transform Drosophila cells to methotrexate-resistance.

Transformed Drosophila Kc cell lines, resistant to methotrexate, an inhibitor of de novo purine and pyrimidine synthesis, have been obtained by calcium phosphate transfection of plasmids containing a sequence coding for a methotrexate-resistant dihydrofolate reductase enzyme (DHFR). The introduced DNA is stably maintained in the cells as head-to-tail multimeric structures of the initial DNA sequence even after several months of culture in the presence of the selective agent. The introduced sequences are present at a high copy number in the transformed cells and express cytoplasmic RNAs transcribed from the DHFR gene.