Survival of photoreceptor neurons in the compound eye of Drosophila depends on connections with the optic ganglia.

The importance of retinal innervation for the normal development of the optic ganglia in Drosophila is well documented. However, little is known about retrograde effects of the optic lobe on the adult photoreceptor cells (R-cells). We addressed this question by examining the survival of R-cells in mutant flies where R-cells do not connect to the brain. Although imaginal R-cells develop normally in the absence of connections to the optic lobes, we find that their continued survival requires these connections. Genetic mosaic studies with the disconnected (disco) mutation demonstrate that survival of R-cells does not depend on the genotype of the eye, but is correlated with the presence of connections to the optic ganglia. These results suggest the existence of retrograde interactions in the Drosophila visual system reminiscent of trophic interactions found in vertebrates.     

Giant lens, a gene involved in cell determination and axon guidance in the visual system of Drosophila melanogaster.

Mutations in the Drosophila gene giant lens (gil) affect ommatidial development, photoreceptor axon guidance and optic lobe development. We have cloned the gene using an enhancer trap line. Molecular analysis of gil suggests that it encodes a secreted protein with an epidermal-growth-factor-like motif. We have generated mutations at the gil locus by imprecise excision of the enhancer trap P-element. In the absence of gil, additional photoreceptors develop at the expense of pigment cells, suggesting an involvement of gil in cell determination during eye development. In addition, gil mutants show drastic effects on photoreceptor axon guidance and optic lobe development. In wildtype flies, photoreceptor axons grow from the eye disc through the optic stalk into the larval brain hemisphere, where retinal innervation is required for the normal development of the lamina and distal medulla. The projection pattern of these axons in the developing lamina and medulla is highly regular and reproducible. In gil, photoreceptor axons enter the larval brain but fail to establish proper connections in the lamina or medulla. We propose that gil encodes a new type of signalling molecule involved in the process of axon pathfinding and cell determination in the visual system of Drosophila.     

Blackpatch, a neural degeneration mutation that interacts with the Notch locus in Drosophila.

We have identified a gene in Drosophila melanogaster that is involved in the development of the adult eye and optic lobe of the brain and that interacts with facet alleles at the Notch locus. We have named this locus Blackpatch (Bpt). Mutant alleles of Bpt produce a variety of abnormal phenotypes in the presence of facet alleles. These phenotypes include neural degeneration in the eye and in the optic lobe of the adult brain that begins 60 hr after pupariation and produces a dark, necrotic eye spot in the adult eye. Other phenotypes include recessive embryonic lethality, pharate adult lethality, and premature adult death. We have isolated and characterized 10 Bpt alleles, all of which yield the neural eye/brain degeneration phenotype in individuals who are also homozygous or hemizygous for facet mutations. Only some of the facet alleles interact with Bpt. Bpt mutations also interact with the split mutation but do not interact with other types of Notch mutation. Somatic mosaic analysis and imaginal disc transplantation experiments suggest that the optic lobe of the brain may be the focus of Bpt action. We conclude that the Notch and Bpt genes have important functions during the interaction between the retina and the optic lobe of the brain.     

Regulation of Drosophila neural development by a putative secreted protein

The Drosophila strawberry (sty) locus was isolated by P-element insertion mutagenesis in a screen for mutations affecting eye development. Analysis of the mutant phenotype and the putative expression pattern of the sty gene suggested that it has multiple functions. Mutations in the sty gene lead to irregular spacing of ommatidia, an increase in the number of photoreceptor cells, as well as abnormal axonal projections to the lamina and disrupted structure of the optic lobes in the adult fly. The sty mutation also causes abnormal head involution, a change in a number of sensilla in the antennomaxillary complex in the embryonic stage and abnormal morphogenesis of the maxillary palp and wings in later stages. We examined the presumptive expression of the sty gene during development by histochemical staining for lacZ expression from enhancer trap elements inserted within the sty gene. During embryogenesis, expression of lacZ showed a segmental pattern in the ectoderm and in the nervous system. In the eye imaginal discs, lacZ was expressed in photoreceptor cells beginning a few rows posterior to the morphogenetic furrow. The lacZ was also expressed in the wing disc. In the adult, lacZ was expressed in the retina and lamina. We cloned the sty gene by P-element tagging and found that it encodes a putative secreted protein containing a cysteine-rich region similar to the epidermal growth factor (EGF) repeat. On the basis of the loss of functional phenotype, the expression pattern and the predicted structure of its product, we propose that sty encodes a diffusible protein acting as a signal involved in lateral inhibition within the developing nervous system and also as a factor involved either directly or indirectly in axonal guidance and optic lobe development.     

Sine Oculis Is a Homeobox Gene Required for Drosophila Visual System Development

The so(mda) (sine oculis-medusa) mutant is the result of a P element insertion at position 43C on the second chromosome. so(mda) causes aberrant development of the larval photoreceptor (Bolwig's) organ and the optic lobe primordium in the embryo. Later in development, adult photoreceptors fail to project axons into the optic ganglion. Consequently optic lobe development is aborted and photoreceptor cells show age-dependent retinal degeneration. The so gene was isolated and characterized. The gene encodes a homeodomain protein expressed in the optic lobe primordium and Bolwig's organ of embryos, in the developing adult visual system of larvae, and in photoreceptor cells and optic lobes of adults. In addition, the SO product is found at invagination sites during embryonic development: at the stomadeal invagination, the cephalic furrow, and at segmental boundaries. The mutant so(mda) allele causes severe reduction of SO embryonic expression but maintains adult visual system expression. Ubiquitous expression of the SO gene product in 4-8-hr embryos rescues all so(mda) mutant abnormalities, including the adult phenotypes. Thus, all deficits in adult visual system development and function result from failure to properly express the so gene during embryonic development. This analysis shows that the homeodomain containing SO gene product is involved in the specification of the larval and adult visual system development during embryogenesis.     

A genetic analysis of visual system development in Drosophilia melanogaster.

The eyes and optic lobes of adult Drosophila melanogaster comprise a highly organized system of interconnected neurons. The eye and optic lobe primordia are physically separate during the embryonic and larval stages of development, and these tissues do not come into contact until the third larval instar, as a consequence of axons growing from the receptor cells of the developing eyes to the primordial optic lobes. After this contact, the axons of the eyes arrange themselves into their complex and orderly adult pattern. Simultaneously, the optic lobe cells begin elaborating axons which organize into their precise adult array. One question posed by this system is: Does cellular pattern formation in either the eyes or optic lobes depend on eye-brain interactions, or do the two tissues organize autonomously? To answer this question, mutations were found which cause abnormal ommatidial array in the eyes and which also perturb the normal adult axon array in the optic lobes. By means of X ray-induced somatic recombination and by genetically controlled mitotic chromosome loss (gynandromorph formation), flies mosaic for genotypically mutant and normal tissue were constructed. Analysis of the neuronal array in mosaic flies in which eye and optic lobe tissue differed genotypically showed that the axon array phenotype of the optic lobe depends on the genotype of the eye tissue innervating that lobe, while the eye phenotype does not depend on optic lobe genotype. Thus, the axonal organization of the D. melanogaster optic lobe has been shown to depend on the transmission of information from the eyes to the optic lobes.     

Hypomorphic Mutations in the Larval Photokinesis a (Lpha) Gene Have Stage-Specific Effects on Visual System Function in Drosophila Melanogaster

Of the many genes that are expressed in the visual system of Drosophila melanogaster adults, some affect larval vision. However, with the exception of one X-linked mutation, no genes that have larval-specific effects on visual system structure or function have previously been reported. We describe the isolation and characterization of two mutant alleles that define the larval photokinesis A (lphA) gene, one allele of which is associated with a P-element insertion at cytogenetic locus 8E1-10. Larvae that express lphA mutations are, like normal animals, negatively photokinetic, but they are less responsive to white light than lphA+ controls. Larvae that are heterozygous in trans for a mutant lphA allele and a deficiency that uncovers the lphA locus are blind, which indicates that the mutant allele is hypomorphic. lphA larvae respond normally to odorants and taste stimuli. Moreover, the lphA mutations do not affect adult flies' fast phototaxis or visually driven aspects of male sexual behavior, and electroretinograms recorded from the compound eyes of lphA/deficiency heterozygotes and lphA(1)/lphA(2) females are normal. These observations suggest that the lphA gene affects a larval-specific aspect of visual system function.     

Mutations in a steroid hormone-regulated gene disrupt the metamorphosis of the central nervous system in Drosophila

The actions of steroid hormones on vertebrate and invertebrate nervous systems include alterations in neuronal architecture, regulation of neuronal differentiation, and programmed cell death. In particular, central nervous system (CNS) metamorphosis in insects requires a precise pattern of exposure to the steroid molting hormone 20-hydroxyecdysone (ecdysterone). To test whether the effects of steroid hormones on the insect nervous system are due to changes in patterns of gene expression, we examined Drosophila mutants of the ecdysterone-regulated locus, the Broad Complex (BR-C). This report documents aspects of CNS reorganization which are dependent on BR-C function. During wild-type metamorphosis, CNS components undergo dramatic morphogenetic movements relative to each other and to the body wall. These movements, in particular, the separation of the subesophageal ganglion from the thoracic ganglion, the positioning of the developing visual system, and the fusion of right and left brain hemispheres, are deranged in BR-C mutants. In addition, a subset of mutants shows disorganization of optic lobe neuropil, both within and among optic lobe ganglia. Optic lobe disorganization is found in mutants of the br and l(1)2Bc complementation groups, but not in those of the rbp complementation group. This suggests that the three complementation groups of this complex locus represent distinct but overlapping functions necessary for normal CNS reorganization. This study demonstrates that ecdysterone-regulated gene expression is essential for CNS metamorphosis, illustrating the utility of Drosophila as a model system for investigating the genetic basis of steroid hormone action on the nervous system.     

Cell degeneration in the developing optic lobes of the sine oculis and small-optic-lobes mutants of Drosophila melanogaster

In the small-optic-lobes (sol) and sine oculis (so) mutants of Drosophila melanogaster extensive cell death occurs in the optic lobes during the first half of pupal development. Gynandromorph flies show that the sol mutation acts primarily on cells of the medulla cortex. Degeneration of medullar ganglion cells occurs at an early stage of cellular differentiation, when their axons have not yet participated in the formation of the second optic chiasma. The so gene, on the other hand, acts on the eye anlagen. The analysis of chimeric flies demonstrates that degeneration in the optic lobes of so flies is a consequence of eye reduction. At the level of the second optic chiasma extensive axonal degeneration can be observed in the mutant. Neurons seem to die after their failure to establish a sufficient number of functional contacts. In sol;so double mutants, the mutational effects are cumulative causing complete degeneration of columnar cell types in pupae without any eye anlage. The tiny rudiments of the optic lobes in eyeless double mutants still contain tangential neurons of the medulla and of the lobula complex. The central brain is reduced in size due to the missing visual fibers, however, its overall appearance is surprisingly normal.     

DPKQDFMRFamide expression is similar in two distantly related Drosophila species

Drosophila melanogaster DPKQDFMRFamide was isolated and its expression reported. Distribution of DPKQDFMRFamide immunoreactivity is now described in Drosophila virilis. DPKQDFMRFamide antibody stained a cell in the subesophageal ganglion in embryo. DPKQDFMRFamide antibody stained cells in the superior protocerebrum, subesophageal ganglion, thoracic ganglia, and an abdominal ganglion in larva, pupa, and adult. DPKQDFMRFamide antibody stained an additional pair of cells in the optic lobe and a cell in the lateral protocerebrum in adult. Structure identity and similar distribution of DPKQDFMRFamide in D. virilis and D. melanogaster, two distantly related Drosophila species, suggests an important and conserved activity for the peptide.     

Developmental analysis of the facets, a group of intronic mutations at the Notch locus of Drosophila melanogaster that affect postembryonic development

The activity of the Notch locus of Drosophila melanogaster during embryogenesis is necessary for the correct segregation of neural from epidermal lineages. The action of Notch is not confined to embryogenesis but is also essential for normal development during the postembryonic stages. Its action is pleiotropic, as revealed by the existence of several classes of mutations which affect various imaginal structures. Here, we examine a group of six recessive mutations, the facets (fa, fa3, fag, fag-2, fafx and fasw), which affect eye and optic lobe morphology and have been previously shown to be associated with the insertion of transposable elements into an intronic region of Notch. Using both somatic recombination and gynandromorph analysis, we find that their behavior in a mosaic analysis is not identical. While in the majority of alleles abnormal Notch function in the retina is sufficient to induce optic lobe abnormalities, in the case of fag-2, a considerable number of individuals having mosaic retinas exhibit normal optic lobe structure. All the facet alleles appear to behave in a cell-autonomous manner. A developmental analysis of the eye and optic lobe defects associated with the facet mutations support the contention that Notch may be involved not only in the formation of certain structures but also in their maintenance.     

Organization of local interneurons in optic glomeruli of the dipterous visual system and comparisons with the antennal lobes

The lateral protocerebrum of the fly's brain is composed of a system of optic glomeruli, the organization of which compares to that of antennal lobe glomeruli. Each optic glomerulus receives converging axon terminals from a unique ensemble of optic lobe output neurons. Glomeruli are interconnected by systems of spiking and nonspiking local interneurons that are morphologically similar to diffuse and polarized local interneurons in the antennal lobes. GABA-like immunoreactive processes richly supply optic glomeruli, which are also invaded by processes originating from the midbrain and subesophageal ganglia. These arrangements support the suggestion that circuits amongst optic glomeruli refine and elaborate visual information carried by optic lobe outputs, relaying data to long-axoned neurons that extend to other parts of the central nervous system including thoracic ganglia. The representation in optic glomeruli of other modalities suggests that gating of visual information by other sensory inputs, a phenomenon documented from the recordings of descending neurons, could occur before the descending neuron dendrites. The present results demonstrate that future studies must consider the roles of other senses in visual processing.     

Analysis of visual system development in Drosophila melanogaster: mutations at the Glued locus

We have analyzed several aspects of the development of flies carrying mutations at the Glued locus. Optic lobe abnormalities in individuals heterozygous for the original Glued allele were previously shown to result from an action of this mutation in the retinula cells. We have estimated when the functioning of this gene or its product is required for normal visual system development by using genetic mosaicism induced by somatic recombination and temperature shifts of a temperature-sensitive mutation at this locus. Both methods point to a period in the mid-third instar, suggesting that early events in the formation of ommatidia and/or late events in the program of retinal cells are affected. Application of a new histological stain for developing axons indicates that individuals heterozygous for Glued exhibit abnormalities in the retinula fiber projection by the late third instar. Thus, the adult phenotype is not solely the result of later cellular degeneration or rearrangement. Beneath M+ Gl+ clones which encompass the entire eye were found optic lobe abnormalities with features not seen in either other mosaics or Gl heterozygotes. The possibility that these abnormalities result from temporal asynchrony in the development of eye and and optic lobe in these individuals is discussed and the results of attempts to test this hypothesis are presented.     

果蝇新型碱性磷酸酶相关基因CG6236的敲除及表型分析

碱性磷酸酶广泛存在于人体各器官中,其水平异常与一系列疾病有关,但其在发育中的具体作用机制尚不明确。该文以果蝇为模式生物,研究一个新型碱性磷酸酶样蛋白基因CG6236在发育中的功能。利用P-因子介导的不精确剪切获得CG6236缺失突变体果蝇品系,发现CG6236纯合突变体半致死,存活的幼虫及成蝇腹部出现黑色素瘤样表型。在细胞中表达CG6236融合蛋白,发现其定位于细胞质中。另外,缺失或过表达CG6236均不影响Wingless和Hedgehog信号通路。综上,该研究首次获得CG6236基因缺失突变和转基因果蝇品系,并观察了缺失CG6236果蝇的表型,为进一步阐明基因CG6236的功能及作用机制奠定了基础。     

The brain tumor gene negatively regulates neural progenitor cell proliferation in the larval central brain of Drosophila

Brain development in Drosophila is characterized by two neurogenic periods, one during embryogenesis and a second during larval life. Although much is known about embryonic neurogenesis, little is known about the genetic control of postembryonic brain development. Here we use mosaic analysis with a repressible cell marker (MARCM) to study the role of the brain tumor (brat) gene in neural proliferation control and tumour suppression in postembryonic brain development of Drosophila. Our findings indicate that overproliferation in brat mutants is due to loss of proliferation control in the larval central brain and not in the optic lobe. Clonal analysis indicates that the brat mutation affects cell proliferation in a cell-autonomous manner and cell cycle marker expression shows that cells of brat mutant clones show uncontrolled proliferation, which persists into adulthood. Analysis of the expression of molecular markers, which characterize cell types in wild-type neural lineages, indicates that brat mutant clones comprise an excessive number of cells, which have molecular features of undifferentiated progenitor cells that lack nuclear Prospero (Pros). pros mutant clones phenocopy brat mutant clones in the larval central brain, and targeted expression of wild-type pros in brat mutant clones promotes cell cycle exit and differentiation of brat mutant cells, thereby abrogating brain tumour formation. Taken together, our results provide evidence that the tumour suppressor brat negatively regulates cell proliferation during larval central brain development of Drosophila, and suggest that Prospero acts as a key downstream effector of brat in cell fate specification and proliferation control.     

Morewright (Mwr), a New Meiotic Mutant of Drosophila Melanogaster Affecting Nonexchange Chromosome Segregation

A new meiotic mutation, morewright (mwr) was identified by screening for new mutations that act as dominant enhancers of the dosage-sensitive Drosophila melanogaster female meiotic mutant, nod(DTW). mwr is a recessive meiotic mutant, specifically impairing the segregation of nonexchange chromosomes. Cytological evidence suggests that the meitoic defect in mwr/mwr females is in homologue recognition because the chromosomes appear to be misaligned on an intact spindle. The mwr mutation was recovered during a screen of random P-element insertions on a chromosome with a single insertion located at 50C. The P-element insertion is a recessive female-sterile mutation. While excision of the P element from the mwr-bearing chromosome partially relieves the female sterility, the excisions retain the dominant nod(DTW)-enhancing activity. The mwr meiotic phenotype maps very close to the female-sterile P insertion. Thus the mwr locus appears to encode a function required for partner recognition in meiosis, although its relationship to the neighboring female-sterile mutation remains to be elucidated.