Mutations Affecting Functions of the Drosophila Gene Glued

Glued mutations in Drosophila comprise an essential complementation group with complex developmental effects. The original Glued mutation (Gl) has dominant nonlethal effects in heterozygous flies, principally on the morphogenesis of the visual system. Gl also has a recessive lethal effect early in development. Mutations that reverse the dominant visual effects of Gl (GlR mutations) were induced by gamma-radiation or by insertions of the transposable P element. The GlR(G) mutations induced by gamma-radiation do not reverse the lethal effect of Gl; these appear to be null mutations, some of which (and possibly all) delete segments of the Glued region. The GlR(P) mutations induced by insertion of the P element also reverse concomitantly a recessive lethal effect of Gl, suggesting that both the recessive and dominant effects are controlled by the same gene. The reversal of a lethal effect of Gl by the P element is remarkable, since it indicates that an essential gene function can be restored by insertion of unrelated DNA. Another class of lethal Glued mutations was induced in the normal Gl+ strain by ethyl methanesulfonate (EMS). The EMS mutations belong to the same essential complementation group as Gl, but do not have the strong dominant effects of Gl on the visual system. The GlR(P) mutations provide a molecular marker for the Glued gene, which was used to map the gene to the 70C2 band of chromosome 3L by in situ hybridization of a P element probe to polytene chromosomes from the GlR(P) strains and also to isolate clones of Glued genomic DNA for molecular studies of the normal gene and the various Glued mutations.     

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.     

The p150(Glued) CAP-Gly domain regulates initiation of retrograde transport at synaptic termini

p150(Glued) is the major subunit of dynactin, a complex that functions with dynein in minus-end-directed microtubule transport. Mutations within the p150(Glued) CAP-Gly microtubule-binding domain cause neurodegenerative diseases through an unclear mechanism. A p150(Glued) motor neuron degenerative disease-associated mutation introduced into the Drosophila Glued locus generates a partial loss-of-function allele (Gl(G38S)) with impaired neurotransmitter release and adult-onset locomotor dysfunction. Disruption of the p150(Glued) CAP-Gly domain in neurons causes a specific disruption of vesicle trafficking at?terminal boutons (TBs), the distal-most ends of synapses. Gl(G38S) larvae accumulate endosomes along with dynein and kinesin motor proteins within swollen TBs, and genetic analyses show that kinesin and p150(Glued) function cooperatively at TBs to coordinate transport. Therefore, the p150(Glued) CAP-Gly domain regulates dynein-mediated retrograde transport at synaptic termini, and this function of dynactin is disrupted by a mutation that causes motor?neuron disease.     

Neural development in an imaginal disc mutant of Drosophila melanogaster

The neural phenotype of an imaginal disc degenerate mutant l(1)d deg-3 was studied in histological sections. The mutant larvae showed severe abnormalities in the imaginal neural development. Gynandromorphs, which are composed of genetically mutant and nonmutant cells, were generated and analyzed as late larvae. The results of mosaic analysis were consistent with l(1)d deg-3 gene acting autonomously in the imaginal disc and imaginal neural cells. The optic lobe development patterns observed in the larval mosaics provided evidence for an eye disc-optic lobe interaction during the late third instar larval stage.     

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.     

Postembryonic changes in the optic primordia and optic bud in the flesh fly Sarcophaga ruficornis fabr. (Diptera: Sarcophagidae)

Differentiation of the optic lobe anlagen begin in the brain of second instar. Each is an elongated disc of cortical cells placed on the dorsolateral border of each protocerebrum. In the late second instar the disc elongates and its two ends bend inwards which gradually separate from the central region, thus giving three imaginal discs. The protocerebral neuropile extends into these discs and medulla interna and externa are formed. The rudiments of compound eyes (cephalic complex) appear in the early laid larva. These are attached with the brain and pharyngeal wall separately. The posterior portion of cephalic complex (optic bud), after establishing a nervous association with the central optic lobe anlage (lamina ganglionaris), forms the compound eye. Ech optic bud is attached to the brain by a non-nervous stalk. The epiblast cells of the optic bud do not migrate into the brain and the lamina is formed by the proliferation of the central imaginal disc. The reorientation of the optic lobe anlagen starts in the late third instar and the medulla interna divides into two unequal lobes. In 2 day pupa the nerve fibres from the lamina travel into the optic stalk and the optic nerve is formed. The epiblast cells of the optic bud differentiate to form a peripheral epithelial layer which becomes pigmented and gets apposed to the lateral boundary of the brain. The central epiblast cells of the optic bud form several ommatidia. The optic nerve degenerates gradually and various components of the compound eye are formed by the epiblast cells. Chiasm internum is present but chiasm externum is absent.     

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.     

Genetic analysis of mutations at the Glued locus and interacting loci in Drosophila melanogaster

A genetic analysis of the dominant mutation Glued that perturbs the development of the normal axonal architecture of the fly's visual system was undertaken. Ten new alleles at this locus were identified and characterized. Two complementation groups that were identified failed to complement the original allele, suggesting that it is a double mutant or that it resides at a complex locus. Several of the new alleles display visual-system abnormalities similar to those of the original mutation. Seven of the eight members of one complementation group are embryonic/early larval lethals, like the original mutation. The other allele in this group is temperature sensitive. Homozygous mutant adults exhibit a temperature-sensitive female sterile phenotype. Unsuccessful attempts to recover genetic mosaics carrying clones of cells homozygous for some of these mutations revealed that they are either essential for the viability of individual cells or that they affect some other fundamental cellular function, such as mitosis or the ability to participate in tissue level organization, which prevents them from being recovered in adult mosaics. This also indicates that these mutations do not specifically affect neural cells. A number of X-ray- and EMS-induced partial and complete phenotypic "revertants" of the original allele have also been isolated as material for a comparative analysis of visual system development. All "revertants" that alter the abnormal eye phenotype towards the wild type have similar impact on the organization of the optic lobe.     

Genetical analysis of visual system disorganizer (vid), a new gene involved in normal development of eye and optic lobe of the brain in Drosophila melanogaster

A neuroanatomical screening of a collection of P-element mutagenized flies has been carried out with the aim of finding new mutants affecting the optic lobe of the adult brain in Drosophila melanogaster. We have identified a new gene that is involved in the development of the adult axon array in the optic ganglia and in the ommatidia assembly. We have named this locus visual system disorganizer (vid). Reversional mutagenesis demonstrated that the vid mutant was the result of a P-element insertion in the Drosophila genome and allowed us to generate independent alleles, some of which resulted in semilethality, like the vid original mutant, while the others were completely lethal. A genetic somatic mosaic analysis indicated that the vid gene is required in the eye for its normal development by inductive effects. This analysis also suggests an inductive effect of the vid gene on the distal portion of the optic lobe, particularly the lamina and the first optic chiasma. Moreover, the absence of mutant phenotype in the proximal region of the optic ganglia, including the medulla, the second optic chiasma, and the lobula complex underlying mosaic eyes, is suggestive of an autonomously acting mechanism of the vid gene in the optic lobe. The complete or partial lethality generated by different mutations at the vid locus suggests that this gene's role may not be limited to the visual system, but may also affect a vital function during Drosophila development.     

The compound eye of Parnara guttata (Insecta,Lepidoptera, Hesperiidae): Fine structure of the ommatidium

Summary The fine structure of an ommatidium of a skipper butterfly, Parnara guttata, has been studied using the electron microscope. Each ommatidium has nine retinula cells, which were classified into three groups: two distal, six medial and one basal retinula cells. The rhabdomeres of the distal retinula cells are localized in the distal part of the rhabdom, while those of the six medial retinula cells appear throughout most of the rhabdom. The rhabdomere of the basal retinula cell occupies only the basal part of the rhabdom. The rhabdomeres of four medial cells are constructed of parallel microvilli, while fan-like microvilli form the rhabdomeres of other two medial retinula cells. The distal and basal retinula cells have rhabdomeres consisting of both parallel and fan-like microvilli. This is the first time the construction of the rhabdomeres of the distal and basal retinula cells has been described in such fine detail for a skipper butterfly. Nine retinula cell axons of each ommatidium extend to the first neuropile of the optic lobe, the lamina ganglionaris. No difference was found in the number of retinula cells of an ommatidium or the shape of the rhabdom between the dorsal and ventral regions of the compound eye.     

Regulation of cytoplasmic dynein function in vivo by the Drosophila Glued complex

The Drosophila Glued gene product shares sequence homology with the p150 component of vertebrate dynactin. Dynactin is a multiprotein complex that stimulates cytoplasmic dynein-mediated vesicle motility in vitro. In this report, we present biochemical, cytological, and genetic evidence that demonstrates a functional similarity between the Drosophila Glued complex and vertebrate dynactin. We show that, similar to the vertebrate homologues in dynactin, the Glued polypeptides are components of a 20S complex. Our biochemical studies further reveal differential expression of the Glued polypeptides, all of which copurify as microtubule-associated proteins. In our analysis of the Glued polypeptides encoded by the dominant mutation, Glued, we identify a truncated polypeptide that fails to assemble into the wild-type 20S complex, but retains the ability to copurify with microtubules. The spatial and temporal distribution of the Glued complex during oogenesis is shown by immunocytochemistry methods to be identical to the pattern previously described for cytoplasmic dynein. Significantly, the pattern of Glued distribution in oogenesis is dependent on dynein function, as well as several other gene products known to be required for proper dynein localization. In genetic complementation studies, we find that certain mutations in the cytoplasmic dynein heavy chain gene Dhc64C act as dominant suppressors or enhancers of the rough eye phenotype of the dominant Glued mutation. Furthermore, we show that a mutation that was previously isolated as a suppressor of the Glued mutation is an allele of Dhc64C. Together with the observed dependency of Glued localization on dynein function, these genetic interactions demonstrate a functional association between the Drosophila dynein motor and Glued complexes.     

Heterozygous Mutation of Drosophila Opa1 Causes the Development of Multiple Organ Abnormalities in an Age-Dependent and Organ-Specific Manner

Optic Atrophy 1 (OPA1) is a ubiquitously expressed dynamin-like GTPase in the inner mitochondrial membrane. It plays important roles in mitochondrial fusion, apoptosis, reactive oxygen species (ROS) and ATP production. Mutations of OPA1 result in autosomal dominant optic atrophy (DOA). The molecular mechanisms by which link OPA1 mutations and DOA are not fully understood. Recently, we created a Drosophila model to study the pathogenesis of optic atrophy. Heterozygous mutation of Drosophila OPA1 (dOpa1) by P-element insertion results in no obvious morphological abnormalities, whereas homozygous mutation is embryonic lethal. In eye-specific somatic clones, homozygous mutation of dOpa1 causes rough (mispatterning) and glossy (decreased lens deposition) eye phenotypes in adult Drosophila. In humans, heterozygous mutations in OPA1 have been associated with mitochondrial dysfunction, which is predicted to affect multiple organs. In this study, we demonstrated that heterozygous dOpa1 mutation perturbs the visual function and an ERG profile of the Drosophila compound eye. We independently showed that antioxidants delayed the onset of mutant phenotypes in ERG and improved larval vision function in phototaxis assay. Furthermore, heterozygous dOpa1 mutation also caused decreased heart rate, increased heart arrhythmia, and poor tolerance to stress induced by electrical pacing. However, antioxidants had no effects on the dysfunctional heart of heterozygous dOpa1 mutants. Under stress, heterozygous dOpa1 mutations caused reduced escape response, suggesting abnormal function of the skeletal muscles. Our results suggest that heterozygous mutation of dOpa1 shows organ-specific pathogenesis and is associated with multiple organ abnormalities in an age-dependent and organ-specific manner.     

Tissue-Specific and Complex Complementation Patterns in the Punch Locus of DROSOPHILA MELANOGASTER

Mutations in the Punch locus result in loss of GTP cyclohydrolase activity, but all mutations do not affect the enzyme in the same way. There are at least three classes of Punch mutations. One class results in a dominant eye color, recessive lethal phenotype. A second class of mutations also causes a recessive lethal phenotype, but heterozygous mutants have normal eye color. They show loss of GTP cyclohydrolase function in all tissues where activity can be measured. Alleles comprising a third class are recessive eye color mutations that are homozygous viable. Individuals with this third type of mutation show loss of enzyme activity in the eye, but show normal or near-normal activity elsewhere. In order to examine the organization and function of this locus further, we have performed interallelic complementation tests on 25 Punch mutations, monitoring viability and enzyme activity in prepupae and adults. Most allele combinations are lethal. Those that complement do so in ways that are tissue-or stage-specific and unpredictable. Tests of mutants with tissue-specific phenotypes and of individuals mutant for complementing Punch lethal alleles lead us to conclude that Punch is a complex locus, both with respect to its organization and to its products.     

Missense mutation and hexanucleotide duplication in the PAX2 gene in two unrelated families with renal-coloboma syndrome (MIM 120330)

We present a family with autosomal-dominant inheritance of renal insufficiency caused by renal hypoplasia in six individuals. In all affected individuals, signs of optic disk dysplasia were detected, but most patients were asymptomatic. A heterozygous missense mutation in the PAX2 gene causing a Gly75 to Ser substitution was present in all affected individuals. A second, unrelated patient presented with ocular complaints related to optic disk dysplasia, and had a history of vesico-ureteral reflux. A heterozygous hexanucleotide duplication in the PAX2 gene was detected leading to the duplication of GluThr at positions 74 and 75. The mutations in these two families are the first mutations in the PAX2 gene that do not lead to a truncated protein. Mechanistically, these mutations are expected to result in abnormal folding of the PAX2 protein. These observations further expand the spectrum of clinical features associated with PAX2 mutations, and suggest that a distinct genetic disorder can be identified in patients with renal dysplasia through a careful eye examination. As the ocular manifestations in this syndrome are variable anomalies of retinal and optic disk dysplasia, we prefer the term “papillo-renal syndrome”. Received: 29 January 1998 / Accepted: 25 March 1998     

The superposition eye of Cloeon dipterum: The organization of the lamina ganglionaris

Summary The lamina ganglionaris of the superposition eye of Cloeon dipterum is composed of separate optic cartridges arranged in a hexagonal pattern. Each optic cartridge consists of one central, radially branched monopolar cell (Li) surrounded by a crown of seven retinula cell terminals and two more unilaterally branched monopolar cells (La1/La2) situated close together outside the cartridge. Projections to neighbouring cartridges have not been observed.In most cases, synaptic contacts could be seen between a presynaptic retinula cell and more than two other postsynaptic profiles, which belong to monopolar cells or sometimes to glial cells.Seven retinula cell fibers of one ommatidium pass in a bundle through the basement membrane, run into their respective cartridges without changing orientation and terminate at approximately equal levels in the lamina. Long visual fibers with endings in the medulla are not visible in the superposition eye lamina, but are present in the lateral apposition eye. The relationship between the behaviour of the animal, optic mechanisms of the superposition eye and the structure of the lamina is discussed.     

Postembryonic development of serotonin-immunoreactive neurons in the central nervous system of the blowfly,Calliphora erythrocephala

Summary The postembryonic development of serotonin-immunoreactive (5-HTi) neurons was studied in the optic lobe of the blowfly. In the adult fly there are 24 5-HTi neurons invading each optic lobe. The perikarya of two of these neurons are situated in the dorso-caudal part of the protocerebrum (LBO-5HT neurons; large bilateral optic lobe 5-HTi neurons). The cell bodies of the remaining 22 neurons are located anteriorly at the medial base of the medulla (2 innervating the lobula, LO-5HT neurons; and 20 neurons innervating the medulla, ME-5HT neurons). The two central neurons (LBO-5HT neurons) are derived from metamorphosing larval neurons, while the ME- and LO-5HT neurons are imaginai optic lobe neurons differentiating during pupal development.The 5-HTi neurons of the optic lobe seem to have different ancestors. The LBO-5HT neurons are probably derived from segmental protocerebral neuroblasts, whereas the ME-and LO-5HT neurons are most likely derived from the inner optic anlage. The first 5-HTi fibers to reach the imaginal optic lobes are seen in the late third instar larva and are derived from the LBO-5HT neurons. The first ME- and LO-5HT neurons become immunoreactive at 24 h (10%) pupal development. At about 96 h (40%) of pupal development all the 5-HTi neurons of the optic lobes have differentiated and attained their basic adult morphology. The further development mainly entails increase in volume of arborizations and number of finer processes. The differentiation and outgrowth of 5-HTi processes follows that of, e.g., columnar neurons in the optic lobe neuropils. Hence, 5-HTi processes invade neuropil relatively late in the differentiation of the optic lobe.     

Golgi and genetic mosaic analyses of visual system mutants in Drosophila melanogaster

We have used a Golgi staining procedure in Drosophila melanogaster to examine the structure of individual neurons in the visual systems of the Canton-S wild-type strain, of flies expressing mutations at the Glued, rough, glass, and uneven loci, all of which affect the organization of the visual system, and of genetic mosaics involving the Glued and uneven loci. We have found that the structure of the neurons studied in the wild type is quite similar to that reported for other diptera and that the mutants studied evidence a variety of abnormalities in neuronal morphology, each mutant being characterized by a different spectrum of aberrations. The genetic mosaic analysis of the Glued and uneven loci showed that the structure of individual neurons in the optic lobes is profoundly influenced by the genotype of the cells projecting to that region from the compound eye but that the final form attained by a neuron is not solely controlled by that factor.     

Patterns of growth and tract formation during the early development of secondary lineages in the Drosophila larval brain

The Drosophila brain consists of a relatively small number of invariant, genetically determined lineages which provide a model to study the relationship between gene function and neuronal architecture. In following this long‐term goal, we reconstruct the morphology (projection pattern and connectivity) and gene expression patterns of brain lineages throughout development. In this article, we focus on the secondary phase of lineage morphogenesis, from the reactivation of neuroblast proliferation in the first larval instar to the time when proliferation ends and secondary axon tracts have fully extended in the late third larval instar. We have reconstructed the location and projection of secondary lineages at close (4 h) intervals and produced a detailed map in the form of confocal z‐projections and digital three‐dimensional models of all lineages at successive larval stages. Based on these reconstructions, we could compare the spatio‐temporal pattern of axon formation and morphogenetic movements of different lineages in normal brain development. In addition to wild type, we reconstructed lineage morphology in two mutant conditions. (1) Expressing the construct UAS‐p35 which rescues programmed cell death we could systematically determine which lineages normally lose hemilineages to apoptosis. (2) so‐Gal4‐driven expression of dominant‐negative EGFR ablated the optic lobe, which allowed us to conclude that the global centrifugal movement normally affecting the cell bodies of lateral lineages in the late larva is causally related to the expansion of the optic lobe, and that the central pattern of axonal projections of these lineages is independent of the presence or absence of the optic lobe. © 2015 Wiley Periodicals, Inc. Develop Neurobiol 76: 434–451, 2016     

Variability and the nature of the insect electroretinogram

A study was made of the electroretinogram (ERG) waveform of over eighty species of diurnal Lepidoptera. In all, the two major components were found to be a cornea-negative potential originating in the retinula cells, and a cornea-positive component originating deep in the retina. These components can be shown to be physiologically independent of each other on the basis of the selective action of drugs, various inorganic ions, etc. They are different from each other in terms of flicker fusion frequency, latency, spectral sensitivity, and the effect of light adaptation. It is proposed that the cornea-positive component originates in the eccentric retinula cell, located close to the basement membrane. These cells appear to function as a photopic photoreceptor. The nature of the response of such cells varies as a result of small shifts in inorganic (Na⁺) ion concentration, thereby accounting for the observed variability of the insect ERG. It is suggested that such cells are associated with inhibitory events occurring in the optic lobe.