Pattern formation in the imaginal discs of a temperature-sensitive cell-lethal mutant of Drosophila melanogaster

To explore the effects of cell death on pattern formation in the developing imaginal discs of Drosophila melanogaster, I have isolated a number of cell-autonomous temperature-sensitive lethal mutants. Sex-linked temperature-sensitive lethals were screened for cell-autonomy by scoring the survival of lethal-bearing clones in genetic mosaics. The mutant with the strongest effect on clone viability gave rise to a high frequency of structural deficiencies and duplications in the derivatives of the eye-antennal discs, when subjected to pulse-treatments at the nonpermissive temperature during the late second and third instars. The patterns produced were nonrandom, with some structures showing a tendency to become deficient, and others a tendency to duplicate. Duplicated structures were only found in heads in which other structures were missing. Genetic tests identified the lethal as a point mutation at the suppressor-of-forked locus. Recombination, and complementation tests with a small duplication of this region showed that a second mutational lesion is in all probability not involved in the generation of abnormal patterns in the imaginal discs. It is therefore proposed that the cell-lethal action of the mutant is sufficient to account for phenotypic effects described. According to this hypothesis, cell death primarily causes deficiencies, and duplications occur as a response of the discs to injury. In agreement with this, it was found that in gynandromorphs, pattern duplications can be found in wild-type tissue in the presence of lethal tissue in the same disc. Thus, a cell-autonomous lethal may affect the process of pattern formation in a nonautonomous way.     

The use of cell lethal mutations in the study of Drosophila development

Cell-lethal mutations are currently being used to study the role of cell death in the development of normal and mutant phenotypes, and in highly detailed studies of pattern formation. Histological studies of certain “position-specific” cell-lethals suggest that programmed cell death may be important in the development of normal imaginal discs, and that many mutations may be producing an abnormal phenotype by amplifying this normal process. Somatic mosaic studies using temperature-sensitive cell-lethals have provided much information about the development of pattern duplications, including the number of cells involved, their growth rate, and compartmentalization during duplication. Further work in this area may, when combined with genetic analyses of the loci involved, reveal much about the nature of the processes controlling pattern determination and differentiation.     

Isolation of temperature sensitive mutations blocking clone development inDrosophila melanogaster,and the effects of a temperature sensitive cell lethal mutation on pattern formation in imaginal discs

Summary A method of isolating temperature-sensitive (ts) mutations blocking clone development, based on the analysis of twin spots produced by X-ray induced somatic recombination is reported. From this screen 10 ts mutations were recovered which caused an absence of the lethal-bearing clone at the restrictive temperature. Eight of these mutations were analyzed. Seven proved to be autonomous ts cell lethals and one was an autonomous ts mutation which reversibly affected cell division and growth of imaginal disc cells and growth of larval cells. The effects on development of one of the cell lethal mutations,l(1)ts-504, are described. Heat pulses (29°C) 24–72 hrs long caused a high frequency (up to 90%) of morphologically abnormal animals. The abnormalities observed were of two major kinds: deficiencies and duplications of imaginal disc derivatives. In addition, alterations of tarsal segmentations occurred. Heat pulses to larvae also delayed pupariation and eclosion by as much as four days. In general, longer pulses led to a greater delay in pupariation and eclosion and a higher frequency of deficiencies and duplications than shorter pulses. Exposure to restrictive temperature early in larval development delayed pupariation and resulted in mostly normal animals; exposure during the second and early third larval instar also delayed pupariation and led to a high frequency of duplications; exposure later in larval life, i.e. mid and late third larval instar, caused no delay in pupariation but led to a high frequency of deficiencies. These results can be explained by the occurrence of areas of cell death, which can be seen in the imaginal discs of larvae exposed to restrictive temperature by staining with trypan blue. This conclusion is further supported by the observation in gynandromorphs of duplications of female nonmutant tissue. These results are discussed in relation to current theories of pattern formation.     

Retrotransposon-induced ectopic expression of the Om(2D) gene causes the eye-specific Om(M) phenotype in Drosophila ananassae

Optic morphology (Om) mutations in Drosophila ananassae map to at least 22 loci, which are scattered throughout the genome. Om mutations are all semidominant, neomorphic, nonpleiotropic, and associated with the insertion of a retrotransposon, tom. We have found that the Om(2D) gene encodes a novel protein containing histidine/proline repeats, and is ubiquitously expressed during embryogenesis. The Om(2D) RNA is not detected in wild-type eye imaginal discs, but is abundantly found in the center of the eye discs of Om(2D) mutants, where excessive cell death occurs. D. melanogaster flies transformed with the Om(2D) cDNA under control of the hsp70 promoter display abnormal eye morphology when heat-shocked at the third larval instar stage. These results suggest that the Om(2D) gene is not normally expressed in the eye imaginal discs, but its ectopic expression, induced by the tom element, in the eye disc of third instar larvae results in defects in adult eye morphology.     

Retrotransposon-induced ectopic expression of the Om(2D) gene causes the eye-specific Om(M) phenotype in Drosophila ananassae

Optic morphology (Om) mutations in Drosophila ananassae map to at least 22 loci, which are scattered throughout the genome. Om mutations are all semidominant, neomorphic, nonpleiotropic, and associated with the insertion of a retrotransposon, tom. We have found that the Om(2D) gene encodes a novel protein containing histidine/proline repeats, and is ubiquitously expressed during embryogenesis. The Om(2D) RNA is not detected in wild-type eye imaginal discs, but is abundantly found in the center of the eye discs of Om(2D) mutants, where excessive cell death occurs. D. melanogaster flies transformed with the Om(2D) cDNA under control of the hsp70 promoter display abnormal eye morphology when heat-shocked at the third larval instar stage. These results suggest that the Om(2D) gene is not normally expressed in the eye imaginal discs, but its ectopic expression, induced by the tom element, in the eye disc of third instar larvae results in defects in adult eye morphology.     

Phenotypic and Molecular Characterization of Ser(d), a Dominant Allele of the Drosophila Gene Serrate

The Drosophila gene Serrate (Ser) encodes a transmembrane protein with 14 epidermal growth factor--like repeats in its extracellular domain, which is required for the control of cell proliferation and pattern formation during wing development. Flies hetero- or homozygous for the dominant mutation Ser(D) exhibit scalloping of the wing margin due to cell death during pupal stages. Ser(D) is associated with an insertion of the transposable element Tirant in the 3' untranslated region of the gene, resulting in the truncation of the Ser RNA, thereby eliminating putative RNA degradation signals located further downstream. This leads to increased stability of Ser RNA and higher levels of Serrate protein. In wing discs of wild-type third instar larvae, the Serrate protein exhibits a complex expression pattern, including a strong stripe dorsal and a weaker stripe ventral to the prospective wing margin. Wing discs of Ser(D) third instar larvae exhibit additional Serrate protein expression in the edge zone of the future wing margin, where it is normally not detectable. In these cells expression of wing margin specific genes, such as cut and wingless, is repressed. By using the yeast Gal4 system to induce locally restricted ectopic expression of Serrate in the edge zone of the prospective wing margin, we can reproduce all aspects of the Ser(D) wing phenotype, that is, repression of wing margin--specific genes, scalloping of the wing margin and enhancement of the Notch haplo-insufficiency wing phenotype. This suggests that expression of the Serrate protein in the cells of the edge zone of the wing margin, where it is normally absent, interferes with the proper development of the margin.     

Study of temperature-sensitive mutations in the virilis group of Drosophila. 4. Phenogenetics of a temperature-sensitive mutation affecting the development of imaginal discs in Drosophila virilis Sturt]

The phenogenetics of a new temperature-sensitive mutation diskless-ts (dl-ts, 2nd chromosome) has been studied in D. virilis. The rearing of larvae from the 1st instar at the temperature 31 degrees resulted in the complete or partial arrest of the development of imaginal discs and, consequently, the death of larvae prior to the pupation, at the prepupa stage. The change of temperature from 25 to 31 degrees during the second half of development in the 3rd instar affects the differentiation of imaginal discs. Some organs differentiate completely or partially (eyes, wings, legs) whereas the rest do not develop at all. The sensitive period embraces the whole larval development till the beginning of pupation.     

Mosaic: a position-effect variegation eye-color mutant in the mosquito Anopheles gambiae

The Mosaic (Mos) mutation, isolated in the F1 of 60Co-irradiated mosquitoes, confers variegated eye color to third and fourth instar larvae, pupae, and adults of the mosquito Anopheles gambiae. Mos is recessive in wild pink eye (p+) individuals, but is dominant and confers areas of wild-type pigment in mutant pink eye backgrounds. Mos is located 14.4 cM from pink eye on the X chromosome and is associated with a duplication of division 2B euchromatin that has been inserted into division 6 heterochromatin. Various combinations of Mos, pink eye alleles, and the autosomal mutation red eye were produced. In all cases, the darker pigmented regions of the eye in Mos individuals show the phenotypic interactions expected if the phenotype of those regions is due to expression of a p+ allele. Expression of Mos is suppressed by rearing larvae at 32 degrees C relative to 22 degrees C. All of these characteristics are consistent with Mos being a duplicated wild copy of the pink eye gene undergoing position-effect variegation.     

Spatial and temporal relationships between cell death and tissue overgrowth in imaginal wing disks of the Drosophila mutant l(3)c43hs1

The temperature-sensitive mutant l(3)c43hs1 is lethal at the restrictive temperature late in the last larval instar and has wing disks that show excessive growth when larvae are reared at 25 degrees C. Such mutant disks give rise to defective wings showing duplications and deficiencies. Abnormal folding patterns are localized to the region between the wing pouch and the area where adepithelial cells are found; the disks retain an epithelial morphology. Apoptotic cell death is distributed throughout the wing disks without any obvious concentration of dead cells in a specific area. Cell death is seen as early as 12 hr after a shift to the restrictive temperature. Temperature shift experiments also show that cell death precedes the onset of overgrowth, but since the spatial distribution of death is not localized to the regions of abnormal folds, it is unlikely that cell death and overgrowth are causally related.     

The Ade6-M26 Mutation of Schizosaccharomyces Pombe Increases the Frequency of Crossing over

The ade6-M26 mutation of Schizosaccharomyces pombe increases conversion frequency in comparison with the nearby mutation ade6-M375. In order to investigate the effect of ade6-M26 on crossover frequency, heteroallelic ade6 duplications were constructed by integration of plasmids carrying the marker gene ura4. One ade6 gene carries either of the mutations M26 or M375 while the other ade6 copy carries the L469 mutation in both duplications. The duplication with ade6-M26 yields Ade(+) recombinants at significantly higher frequencies in meiosis, but not in mitosis. Tetrad analysis and physical characterization of spore clones from recombination tetrads demonstrate that conversions, unequal crossovers and intrachromatid exchanges occur at higher frequencies but with unaltered proportions among them. The conversion events show a pronounced bias when M26 is involved: they take place preferentially at the M26 allele. Thus the ade6-M26 mutation not only enhances conversion frequency as demonstrated before, but also crossover frequency. It displays the properties expected for a preferred site of initiation of general meiotic recombination. The duplications also yielded new information on ectopic recombination in S. pombe: ectopic crossovers occur in the duplications at much higher frequency than among naturally dispersed homologous sequences.     

The determination of aldehyde oxidase activity patterns in the wing discs of Drosophila melanogaster

Summary The pattern of aldehyde oxidase (AO) activity was determined in wing discs of Drosophila melanogaster larvae homozygous for the mutants apt ⁷³ⁿ, Beaded, and vestigial (vg) in order to determine if reduction in field size in the pouch could be related to alterations of the wild-type AO pattern, as suggested by the Kauffman (1978) hypothesis. The pattern in wild-type discs was resolved into six areas for comparison with mutant discs. vg discs developed at 25° C showed restriction of the pattern into a small area on the anterior side of the disc, and comparison of vg and wild-type prepupal wings allowed positive identification of the AO pattern elements which remained. AO patterns in vg wing discs grown at 27°, 29°, and 31° C were progressively more complete and similar to wild-type, reflecting the reduction in cell death in discs grown at higher temperatures. These results show that cell loss during the third instar in vg development at 25° C is responsible for the alteration of the AO pattern, rather than field size reduction, and that determination of the pattern must take place much earlier than the time of its first appearance during the third larval instar, and before cell death in vg discs begins. Thus mutants acting at earlier stages will be necessary for further tests of the Kauffman hypothesis.     

Drosophila nemo promotes eye specification directed by the retinal determination gene network

Drosophila nemo (nmo) is the founding member of the Nemo-like kinase (Nlk) family of serine-threonine kinases. Previous work has characterized nmo's role in planar cell polarity during ommatidial patterning. Here we examine an earlier role for nmo in eye formation through interactions with the retinal determination gene network (RDGN). nmo is dynamically expressed in second and third instar eye imaginal discs, suggesting additional roles in patterning of the eyes, ocelli, and antennae. We utilized genetic approaches to investigate Nmo's role in determining eye fate. nmo genetically interacts with the retinal determination factors Eyeless (Ey), Eyes Absent (Eya), and Dachshund (Dac). Loss of nmo rescues ey and eya mutant phenotypes, and heterozygosity for eya modifies the nmo eye phenotype. Reducing nmo also rescues small-eye defects induced by misexpression of ey and eya in early eye development. nmo can potentiate RDGN-mediated eye formation in ectopic eye induction assays. Moreover, elevated Nmo alone can respecify presumptive head cells to an eye fate by inducing ectopic expression of dac and eya. Together, our genetic analyses reveal that nmo promotes normal and ectopic eye development directed by the RDGN.     

The role of nutrition in creation of the eye imaginal disc and initiation of metamorphosis in Manduca sexta

With the exception of the wing imaginal discs, the imaginal discs of Manduca sexta are not formed until early in the final larval instar. An early step in the development of these late-forming imaginal discs from the imaginal primordia appears to be an irreversible commitment to form pupal cuticle at the next molt. Similar to pupal commitment in other tissues at later stages, activation of broad expression is correlated with pupal commitment in the adult eye primordia. Feeding is required during the final larval instar for activation of broad expression in the eye primordia, and dietary sugar is the specific nutritional cue required. Dietary protein is also necessary during this time to initiate the proliferative program and growth of the eye imaginal disc. Although the hemolymph titer of juvenile hormone normally decreases to low levels early in the final larval instar, eye disc development begins even if the juvenile hormone titer is artificially maintained at high levels. Instead, creation of the late-forming imaginal discs in Manduca appears to be controlled by unidentified endocrine factors whose activation is regulated by the nutritional state of the animal.     

A clonal analysis of pattern duplication in a temperature-sensitive cell-lethal mutant of Drosophila melanogaster

Clonal analysis was used to determine the numbers of cells involved in the initiation and growth of pattern duplications in mesothoracic legs that result from a 29°C treatment of a cell-lethal mutant. The frequency, size, and location of clones induced before, during, and after the 29°C treatment were analyzed. The results indicate that duplications arise from a small number of cells. These cells become committed to form the duplicate within 48 hr after the end of the 29°C treatment and begin rapid growth at about the same time. The cell number and growth rate of newly initiated duplicate legs are remarkably similar to those of normal leg discs at early stages in development, supporting the hypothesis that pattern duplicates develop by a reiteration of normal growth processes.     

Alterations in the cell cycle of Drosophila imaginal disc cells precede metamorphosis

Flow cytometric analyses of imaginal disc and brain nuclei of Drosophila melanogaster have been made throughout the third larval instar. In wing, haltere, and leg discs the proportion of cells in the G₂M phase of the cell cycle (tetraploid cells) increases with larval age. In contrast, in the eye disc and in brain the proportion of tetraploid cells, already low at the outset of the instar, declines further. Measurement of growth rates for disc and brain tissue during the same developmental period was carried out by the cell counting procedure of Martin (1982). Our results are consistent with the conclusion that imaginal discs grow exponentially with an apparent doubling time of 5–10 hr from the resumption of cell division (in the first or second larval instar) until about 95 hr, when the apparent doubling time increases. Cell numbers increase until at least 5 hr after formation of white prepupae (122 hr), but during the preceding 10 hr the rate of increase is low. Thus, for wing and leg discs, but not for the eye disc and brain, the declining growth rate is associated with an increase in the proportions of tetraploid cells. In conjunction with cell counts and flow cytometry, fluorometric determination of disc DNA content at 112 hr indicated that the diploid DNA content of imaginal disc nuclei is 0.45 pg.     

In-Vivo Imaging of the Drosophila Wing Imaginal Disc over Time: Novel Insights on Growth and Boundary Formation

In developmental biology, the sequence of gene induction and pattern formation is best studied over time as an organism develops. However, in the model system of Drosophila larvae this oftentimes proves difficult due to limitations in imaging capabilities. Using the larval wing imaginal disc, we show that both overall growth, as well as the creation of patterns such as the distinction between the anterior(A) and posterior(P) compartments and the dorsal(D) and ventral(V) compartments can be studied directly by imaging the wing disc as it develops inside a larva. Imaged larvae develop normally, as can be seen by the overall growth curve of the wing disc. Yet, the fact that we can follow the development of individual discs through time provides the opportunity to simultaneously assess individual variability. We for instance find that growth rates can vary greatly over time. In addition, we observe that mechanical forces act on the wing disc within the larva at times when there is an increase in growth rates. Moreover, we observe that A/P boundary formation follows the established sequence and a smooth boundary is present from the first larval instar on. The division of the wing disc into a dorsal and a ventral compartment, on the other hand, develops quite differently. Contrary to expectation, the specification of the dorsal compartment starts with only one or two cells in the second larval instar and a smooth boundary is not formed until the third larval instar.     

Targeted expression of the signaling molecule decapentaplegic induces pattern duplications and growth alterations in Drosophila wings.

In the wing imaginal disc, the decapentaplegic (dpp) gene is expressed in a stripe of anterior cells near the anterior-posterior compartment boundary, and it is required solely in these cells for the entire disc to develop. In some viable segment polarity mutants, alterations in dpp expression have been demonstrated that correlate with changes in wing morphology. To test the hypothesis that the abnormal patterns of dpp expression are responsible directly for the mutant phenotypes, we have expressed dpp in ectopic places in wing imaginal discs, and we have found that dpp is able to cause overgrowth and pattern duplications in both anterior and posterior compartments of the wing disc. The alterations of the anterior compartment are strikingly similar to those observed in some viable segment polarity mutants. Thus, ectopic dpp alone can account for the phenotype of these mutants. We also show that ectopic expression of the segment polarity gene hedgehog (hh) gives similar morphological changes and activates dpp expression in the anterior compartment. This strongly suggests that the organizating activity of hh is mediated by dpp. We propose that the expression of dpp near the anterior-posterior compartment boundary is directed by the interaction between patched and hh, and that dpp itself could act as a general organizer of the patterning in the wing imaginal disc.     

The morphology, physiology, and neural projections of supernumerary compound eyes in Drosophila melanogaster

Supernumerary compound eyes in Drosophila melanogaster produced by the extra eye (ee) mutation were analyzed with regard to their morphology, physiology, and neural projections. Electron and light microscopy revealed that large extra eyes often possess the normal complement of compound-eye cell types and that these cells usually have standard fine structure. In addition, the array of photoreceptor cell rhabdomeres within individual supernumerary ommatidia is standardly trapezoidal, and ommatidial subpopulations having mirror-image configurations of their rhabdomeric trapezoids are separated by an equator in extra eyes. Light stimulation of supernumerary eyes can elicit photoreceptor depolarization potentials as evidenced by electroretinographic recordings from them. In addition, extra-eye photoreceptor cells have a functional pupillary response to light stimulation. Although the supernumerary eyes can be functionally and anatomically standard, examination of serial, silver-stained sections of extra-eye heads has shown that their photoreceptor axons seldom innervate the brain. This situation obtains even in a case in which the normal, ipsilateral compound eye was removed by the eyeless mutation. In contrast, rare supernumerary antennae occasionally found in ee stocks have receptor cells whose axons innervate ventral brain. In addition to duplications of cuticular epithelia, extra glial cells, muscle fibers, and ocellar interneurons are sometimes found in extra-eye bearing flies. Discussion of these results focuses on a polarity guidance hypothesis which models the growth of adult photoreceptor axons into the brain during normal development.     

bicaudal encodes the Drosophila beta NAC homolog, a component of the ribosomal translational machinery*

bicaudal was the first Drosophila mutation identified as producing mirror-image pattern duplications along the anteroposterior axis of the embryo. However the mutation has been little studied due to its low penetrance and suppressibility. We undertook cloning of the bicaudal locus together with studies of the mutation's effects on key elements of the posterior embryonic patterning pathway. Our mapping studies place the bicaudal mutation within a approximately 2 kb region, 3' to the protein coding sequence of the Drosophila homolog of beta NAC, a subunit of Nascent polypeptide Associated Complex (NAC). Genomic DNA encoding beta NAC completely rescues the bicaudal phenotype. The lethal phenotype of Enhancer of Bicaudal, E(Bic), a mutation hypothesized to affect the bicaudal locus, is also completely rescued by the beta NAC locus. We further demonstrate that the E(Bic) mutation is caused by a P element insertion into the transcribed region of the beta NAC gene. NAC is among the first ribosome-associated entities to bind the nascent polypeptide after peptide bond formation. In contrast to other bicaudal-embryo-producing mutations, bicaudal leads to ectopic translation of mRNA for the posterior determinant nanos, without affecting the localization of mRNA for its upstream regulator, oskar, in the embryo. These findings suggest that repression of nanos mRNA translation occurs on the ribosome and involves a role for beta NAC.