The segment polarity phenotype of Drosophila involves differential tendencies toward transformation and cell death

The midbrain-hindbrain phenotype of Wnt-1-/Wnt-1- mice results from stepwise deletion of engrailed-expressing cells by 9.5 days postcoitum

Mice homozygous for null alleles of the putative signaling molecule Wnt-1 have a reproducible phenotype: loss of the midbrain and adjacent cerebellar component of the metencephalon. By examining embryonic expression of the mouse engrailed (En) genes, from 8.0 to 9.5 days postcoitum, we demonstrate that Wnt-1 primarily regulates midbrain development. The midbrain itself is required for normal development of the metencephalon. Thus, the observed neonatal phenotype is explained by a series of early events, within 48 hr of neural plate induction, that leads to a complete loss of En domains in the anterior central nervous system. Wnt-1 and a related gene, Wnt-3a, are coexpressed from early somite stages in dorsal aspects of the myelencephalon and spinal cord. We suggest that functional redundancy between these two genes accounts for the lack of a caudal central nervous system phenotype.

Use of a yeast site-specific recombinase to generate embryonic mosaics in Drosophila

An efficient method for generating embryonic mosaics using a yeast site-specific recombinase (FLP), under the control of a heat shock promoter, is described. FLP-recombinase can promote mitotic exchange between homologous chromosomes that contain FRT (FLP Recombination Target) sequences. To demonstrate the efficiency of FLP-recombinase to generate embryonic mosaics, clones of the recessive and cell autonomous mutation armadillo (arm), detected by their ability to differentiate ectopic denticles in the naked cuticle of each abdominal segment, have been induced. We have analyzed the parameters of FLP-recombinase induced embryonic mitotic recombination and have demonstrated that clones can be efficiently induced during the postblastoderm mitotic divisions. We discuss applications of this technique for the analyses of the roles of various mutations during embryonic patterning.

Repression of the Drosophila proliferating-cell nuclear antigen gene promoter by zerknüllt protein

A 631-bp fragment containing the 5'-flanking region of the Drosophila melanogaster proliferating-cell nuclear antigen (PCNA) gene was placed upstream of the chloramphenicol acetyltransferase (CAT) gene of a CAT vector. A transient expression assay of CAT activity in Drosophila Kc cells transfected with this plasmid and a set of 5'-deletion derivatives revealed that the promoter function resided within a 192-bp region (-168 to +24 with respect to the transcription initiation site). Cotransfection with a zerknüllt (zen)-expressing plasmid specifically repressed CAT expression. However, cotransfection with expression plasmids for a nonfunctional zen mutation, even-skipped, or bicoid showed no significant effect on CAT expression. RNase protection analysis revealed that the repression by zen was at the transcription step. The target sequence of zen was mapped within the 34-bp region (-119 to -86) of the PCNA gene promoter, even though it lacked zen protein-binding sites. Transgenic flies carrying the PCNA gene regulatory region (-607 to +137 or -168 to +137) fused with lacZ were established. When these flies were crossed with the zen mutant, ectopic expression of lacZ was observed in the dorsal region of gastrulating embryos carrying the transgene with either construct. These results indicate that zen indirectly represses PCNA gene expression, probably by regulating the expression of some transcription factor(s) that binds to the PCNA gene promoter.

Repression of the Drosophila proliferating-cell nuclear antigen gene promoter by zerknüllt protein

A 631-bp fragment containing the 5'-flanking region of the Drosophila melanogaster proliferating-cell nuclear antigen (PCNA) gene was placed upstream of the chloramphenicol acetyltransferase (CAT) gene of a CAT vector. A transient expression assay of CAT activity in Drosophila Kc cells transfected with this plasmid and a set of 5'-deletion derivatives revealed that the promoter function resided within a 192-bp region (-168 to +24 with respect to the transcription initiation site). Cotransfection with a zerknüllt (zen)-expressing plasmid specifically repressed CAT expression. However, cotransfection with expression plasmids for a nonfunctional zen mutation, even-skipped, or bicoid showed no significant effect on CAT expression. RNase protection analysis revealed that the repression by zen was at the transcription step. The target sequence of zen was mapped within the 34-bp region (-119 to -86) of the PCNA gene promoter, even though it lacked zen protein-binding sites. Transgenic flies carrying the PCNA gene regulatory region (-607 to +137 or -168 to +137) fused with lacZ were established. When these flies were crossed with the zen mutant, ectopic expression of lacZ was observed in the dorsal region of gastrulating embryos carrying the transgene with either construct. These results indicate that zen indirectly represses PCNA gene expression, probably by regulating the expression of some transcription factor(s) that binds to the PCNA gene promoter.

Interactions between segment polarity genes and the generation of the segmental pattern in Drosophila

Although mutations in the segment polarity genes wingless, engrailed, hedgehog, gooseberry and cubitus-interruptusD all affect the region of naked cuticle within each segment of the Drosophila larva, subtle phenotypic differences suggest that these genes play different roles in segmental patterning. In this paper, the regulative interactions between these genes are analysed. They have revealed that the products of most of these genes accomplish more than one function during embryogenesis. Whereas early on a positive feed-back loop involving wg, en and hh maintains the expression of wg and en in the extremes of each parasegment, later on wg and en become independent from each other. en appears to regulate the expression of hh and ptc, while wg depends on gsb and ciD.

The segment polarity gene armadillo encodes a functionally modular protein that is the Drosophila homolog of human plakoglobin

The Drosophila segment polarity gene armadillo is required for pattern formation within embryonic segments and imaginal discs. We have found that armadillo is highly conserved during evolution; it is 63% identical to human plakoglobin, a protein found in adhesive junctions joining epithelial and other cells. We have examined arm protein localization in a number of larval tissues and found that arm protein accumulation within cells shares many features with the accumulation of plakoglobin. We have compared the phenotype and molecular lesions responsible for the different arm mutations. Surprisingly, severely truncated proteins retain some function; the degree of function is strictly correlated with the length of the truncated protein, suggesting that the internally repetitive arm protein is modular in function. We present a possible model for the cellular role of arm.

Spatial expression of the Drosophila segment polarity gene armadillo is posttranscriptionally regulated by wingless

armadillo (arm) is one of a group of Drosophila segment polarity genes that are required for normal patterning within the embryonic segment. Although arm RNA is uniformly distributed in embryos, arm protein accumulates at higher levels in regions that contain wingless, another segment polarity gene which encodes a secreted protein that regulates patterning via cell-cell communication. These local increases in arm protein require wingless activity, and mutations that alter wingless distribution produce corresponding changes in the arm protein pattern. These results suggest that wingless regulates accumulation of arm protein by a posttranscriptional mechanism. Two other segment polarity genes, porcupine and dishevelled, are required for this effect. We also show that arm protein is closely associated with the plasma membrane in virtually all cell types and often colocalizes with F-actin.

The orthodenticle gene is regulated by bicoid and torso and specifies Drosophila head development

In the Drosophila embryo, cell fate along the anterior-posterior axis is determined by maternally expressed genes. The activity of the bicoid (bcd) gene is required for the development of larval head and thoracic structures, and that of maternal torso (tor) for the development of the unsegmented region of the head (acron). In contrast to the case of thoracic and abdominal segmentation, the hierarchy of zygotically expressed genes controlling head development has not been clearly defined. The bcd protein, which is expressed in a gradient, activates zygotic expression of the gap gene hunchback (hb), but hb alone is not sufficient to specify head development. Driever et al. proposed that at least one other bcd-activated gene controls the development of head regions anterior to the hb domain. We report here that the homeobox gene orthodenticle (otd), which is involved in head development, could be such a gene. We also show that otd expression responds to the activity of the maternal tor gene at the anterior pole of the embryo.

Mutations in the Drosophila gene extradenticle affect the way specific homeo domain proteins regulate segmental identity

We characterized a gene, extradenticle, which seems to interact with a specific subset of Drosophila homeo domain proteins, possibly affecting their target specificity. This interpretation is based on an examination of the zygotic and maternal effect phenotypes of extradenticle mutations. In embryos with reduced levels of extradenticle gene product, anterior and posterior segmental transformations occur. Segmental identity in Drosophila is mediated by the products of the Antennapedia and bithorax complexes. These homeo domain proteins are thought to regulate different target genes specifically in each segment, resulting in different morphologies. extradenticle alters segmental identity without affecting the pattern of expression of homeotic genes. Genetic tests demonstrate that in extradenticle mutants, the homeotic proteins are functional and act in their normal segmental domains, yet segmental identities are altered. Even when homeotic proteins are ectopically expressed under the control of a heterologous promoter, extradenticle mutations affect their consequences. Thus, in the absence of sufficient extradenticle product, altered segmental morphology results from alteration of the functional consequences of specific homeo domain proteins, possibly through alterations in their target gene specificity. extradenticle is also expressed maternally. Complete removal of extradenticle, maternally and zygotically, leads to specific alterations in segmentation, many of which result from failure to maintain the expression of the homeo domain protein engrailed.

Multiple functions of a Drosophila homeotic gene, zeste-white 3, during segmentation and neurogenesis

Lack of both maternal and zygotic gene activity at the zeste-white 3 (zw3) locus causes severe developmental transformations. Embryos derived from germ cells that lack zw3+ gene activity die during embryogenesis and have a phenotype that is similar to that of embryos mutant for the segment polarity gene naked (nkd). In both nkd and germ line clone-derived zw3 embryos the pattern elements derived from the anterior-most part of each segment, the denticle belts, are deleted. Similar abnormal patterns of the zygotically expressed genes engrailed and Ultrabithorax are detected in both mutants, suggesting that the two genes are involved in the same developmental process. Additionally, the induction of clones of zw3 mutant cells in imaginal discs causes homeotic transformations of noninnervated hair cells into innervated sensory bristles. The multiple roles of zw3 during development and its possible interactions with the zygotic gene nkd are discussed.