The two origins of hemocytes in Drosophila

As in many other organisms, the blood of Drosophila consists of several types of hemocytes, which originate from the mesoderm. By lineage analyses of transplanted cells, we specified two separate anlagen that give rise to different populations of hemocytes: embryonic hemocytes and lymph gland hemocytes. The anlage of the embryonic hemocytes is restricted to a region within the head mesoderm between 70 and 80% egg length. In contrast to all other mesodermal cells, the cells of this anlage are already determined as hemocytes at the blastoderm stage. Unexpectedly, these hemocytes do not degenerate during late larval stages, but have the capacity to persist through metamorphosis and are still detectable in the adult fly. A second anlage, which gives rise to additional hemocytes at the onset of metamorphosis, is located within the thoracic mesoderm at 50 to 53% egg length. After transplantation within this region, clones were detected in the larval lymph glands. Labeled hemocytes are released by the lymph glands not before the late third larval instar. The anlage of these lymph gland-derived hemocytes is not determined at the blastoderm stage, as indicated by the overlap of clones with other tissues. Our analyses reveal that the hemocytes of pupae and adult flies consist of a mixture of embryonic hemocytes and lymph gland-derived hemocytes, originating from two distinct anlagen that are determined at different stages of development.

Mapping and identification of essential gene functions on the X chromosome of Drosophila

The Drosophila melanogaster genome consists of four chromosomes that contain 165 Mb of DNA, 120 Mb of which are euchromatic. The two Drosophila Genome Projects, in collaboration with Celera Genomics Systems, have sequenced the genome, complementing the previously established physical and genetic maps. In addition, the Berkeley Drosophila Genome Project has undertaken large-scale functional analysis based on mutagenesis by transposable P element insertions into autosomes. Here, we present a large-scale P element insertion screen for vital gene functions and a BAC tiling map for the X chromosome. A collection of 501 X-chromosomal P element insertion lines was used to map essential genes cytogenetically and to establish short sequence tags (STSs) linking the insertion sites to the genome. The distribution of the P element integration sites, the identified genes and transcription units as well as the expression patterns of the P-element-tagged enhancers is described and discussed.

The formation of syncytia within the visceral musculature of the Drosophila midgut is dependent on duf, sns and mbc

The visceral musculature of the Drosophila midgut consists of an inner layer of circular and an outer layer of longitudinal muscles. Here, we show that the circular muscles are organised as binucleate syncytia that persist through metamorphosis. At stage 11, prior to the onset of the fusion processes, we detected two classes of myoblasts within the visceral trunk mesoderm. One class expresses the founder-cell marker rP298-LacZ in a one- to two-cells-wide strip along the ventralmost part of the visceral mesoderm, whereas the adjacent two to three cell rows are characterised by the expression of Sticks-and-stones (SNS). During the process of cell fusion at stage 12 SNS expression decreases within the newly formed syncytia that spread out dorsally over the midgut. At both margins of the visceral band several cells remain unfused and continue to express SNS. Additional rP298-LacZ-expressing cells arise from the posterior tip of the mesoderm, migrate anteriorly and eventually fuse with the remaining SNS-expressing cells, generating the longitudinal muscles. Thus, although previous studies proposed a separate primordium for the longitudinal musculature located at the posteriormost part of the mesoderm anlage, our cell lineage analyses as well as our morphological observations reveal that a second population of cells originates from the trunk mesoderm. Mutations of genes that are involved in somatic myoblast fusion, such as sns, dumbfounded (duf) or myoblast city (mbc), also cause severe defects within the visceral musculature. The circular muscles are highly unorganised while the longitudinal muscles are almost absent. Thus the fusion process seems to be essential for a proper visceral myogenesis. Our results provide strong evidence that the founder-cell hypothesis also applies to visceral myogenesis, employing the same genetic components as are used in the somatic myoblast fusion processes.

The segmentation gene Krüppel of Drosophila melanogaster has homeotic properties

In Drosophila hindgut, Malpighian tubules and posterior midgut develop from the most posterior region of the blastoderm. One of the genes that influences the differentiation of the Malpighian tubules is Krüppel (Kr), a segmentation gene of the gap class. Kr homozygous embryos lack thoracic and abdominal segments and, depending on the allele, develop nearly normal Malpighian tubules or do not differentiate them at all. In the wild type, injection of horseradish peroxidase (HRP) into cells of the early gastrula at various posterior positions results in labeling of hindgut (93%), Malpighian tubules (46%), and posterior midgut (20%). Malpighian tubules were labeled only in combination with hindgut. In Kr1 homozygous embryos that lack Malpighian tubules, the label was restricted to hindgut (84%) and posterior midgut (24%). Because we could not find significant cell death in the posterior region of Kr1 embryos, we counted the cell nuclei in the hindguts of wild-type and mutant embryos. The results show that the hindgut in Kr1 embryos contains those cells that would differentiate into Malpighian tubules in wild type. Therefore, we conclude that the Krüppel gene exhibits a homeotic function in addition to its role as a segmentation gene and is involved in separating hindgut and Malpighian tubule cells and in the elongation process as well.

FlyMove--a new way to look at development of Drosophila

Development of any organism requires a complex interplay of genes to orchestrate the many movements needed to build up an embryo. Previously, work on Drosophila melanogaster has provided important insights that are often applicable in other systems. But developmental processes, which take place in space and time, are difficult to convey in textbooks. Here, we introduce FlyMove (http://flymove.uni-muenster.de), a new database combining movies, animated schemata, interactive "modules" and pictures that will greatly facilitate the understanding of Drosophila development.

A new approach reveals syncytia within the visceral musculature ofDrosophila melanogaster

In order to reveal syncytia within the visceral musculature of Drosophila melanogaster, we have combined the GAL4/UAS system with the single-cell transplantation technique. After transplantation of single cells from UAS-GFP donor embryos into ubiquitously GAL4-expressing recipients, the expression of the reporter gene was exclusively activated in syncytia containing both donor- and recipient-derived nuclei. In the first trial, we tested the system in the larval somatic musculature, which is already known to consist of syncytia. By this means we could show that most of the larval somatic muscles are generated by clonally non-related cells. Moreover, using this approach we were able to detect syncytia within the visceral musculature – a tissue that has previously been described as consisting of mononuclear cells. Both the longitudinal visceral musculature of the midgut and the circular musculature of the hindgut consist of syncytia and persist through metamorphosis. This novel application of the transplantation technique might be a powerful tool to trace syncytia in any organism using the GAL4/UAS system.

FlyView, a Drosophila image database, and other Drosophila databases

FlyView is an image database for Drosophila development and genetics, particularly for gene-expression patterns. Thousands of enhancer-trap lines have now been isolated by different methods, particularly by using a variety of transposons with the resulting flies being kept in a great many laboratories. We are collecting pictures of expression patterns of all lines that are available for use by Drosophila researchers and now offer about 1800 images of about 350 enhancer-trap lines in FlyView. This article also summarizes information on the other main Drosophila resources: FlyBase-the main Drosophila database, Flybrain, an online atlas and database of the Drosophila nervous system, and Interactive Fly, a cyberspace guide to Drosophila genes and their roles in development.Copyright 1997 Academic Press Limited Copyright 1997Academic Press Limited

Cell lineage of larval and imaginal thoracic anlagen cells of Drosophila melanogaster, as revealed by single-cell transplantations

We have analyzed the cell lineage of larval and imaginal cells in the thoracic ectoderm of the early embryo of Drosophila melanogaster, by homotopic transplantation of single cells in the region of 50–60% egg length. Single cells were isolated prior to transplantation in an in vitro solution. The donors were ‘enhancer-trap’ lines in which the nuclei of all larval and imaginal cells exhibit a uniformly intense expression of the lacZ gene of E. coli. The transplantations were carried out from the blastoderm to the early gastrula stage, as a rule immediately after the onset of gastrulation (stage 6). It was found that at this time the cells of the thoracic ectoderm are not yet committed to form larval or imaginal structures, as indicated by the presence of clones overlapping all structures formed by the thoracic ectoderm, i.e. the nervous system, the larval epidermis, the tracheae and the imaginal discs. The average size of pure epidermal clones was five cells. In clones overlapping either other larval tissues or imaginal discs, the average number of epidermal cells was between three and four. The mean relative clone size was 1/5 of the size of the total structure for leg imaginal discs and 1/7 for the wing imaginal disc. We therefore infer that the precursors for the leg discs and wing disc on one side together number 22 cells in the blastoderm or early gastrula stage. These cells eventually give rise not only to precursors of the imaginal discs but usually also to larval epidermal and nervous-system cells, because most of the imaginal disc clones (80%) overlap larval tissue. The transplantations were not precisely homotopic; the fact that up to 10 cells were removed from the donor essentially rules out exact homotopy between donor and host sites, because a segment anlage is only about three cells wide. Nevertheless, the clones developed completely normal tissue together with the recipient cells. Although the clones have the capacity to extend over different ectodermal tissues and can include both imaginal discs in a given segment, no clones were found that clearly crossed larval or imaginal segment boundaries. We propose a model in which the segregation of the cells that are to differentiate into the imaginal tissues does not occur until the second postblastodermal mitosis

Graded effect of tailless on posterior gut development: molecular basis of an allelic series of a nuclear receptor gene

By marking cells of early gastrula stage embryos, we showed that in embryos mutant for a strong tll allele the fate map is shifted posteriorly and the hindgut anlage is deleted. We therefore used aspects of hindgut development to characterize the phenotype of new and previously described tll alleles. In embryos mutant for the various alleles, relative levels of blastoderm expression of Trg (T-related gene, required to establish the hindgut) and of mature hindgut size were determined; the results of these assays correlated with each other. Of the alleles that map to the sequence encoding the Tailless nuclear receptor protein, all (four) affect the zinc fingers of the DNA binding domain; surprisingly, substitutions of highly conserved residues allow a range of activities as detected by our bioassays.

Adepithelial cells in Drosophila melanogaster: origin and cell lineage

We have analysed the cell lineage relationships between larval and imaginal mesodermal primordia at the blastoderm stage by homotopic single cell transplantations. The primordia of adepithelial cells, the precursors of adult thoracic muscles, are restricted to the region from 50 to 65% egg length within the ventrally located mesodermal anlage. Clones of adepithelial cells always show a common cell lineage with larval muscles and in some cases additionally with larval fat body. This proves that at the blastoderm stage the determination of larval vs. imaginal mesodermal primordia has not yet taken place. Larval somatic muscle clones, in contrast to clones in the ectoderm, can overlap several segments, whereas clones of adepithelial cells are always restricted to imaginal discs of one segment.

Fate map and cell lineage relationships of thoracic and abdominal mesodermal anlagen in Drosophila melanogaster

We have examined the cell lineage of larval and imaginal precursors of the mesodermal anlage between 10% and 60% egg length (EL) by homotopic single-cell transplantations at the blastoderm stage. Clones in the larval somatic muscles and in the fat body were derived from transplantations everywhere between 10% and 60% EL along the ventral side of the embryo. Clones frequently overlap these tissues and can extend over a maximum of four segments in the larval somatic muscles or over two morphologically-distinct parts in the fat body. Clones in the gonadal mesoderm overlap with other mesodermal derivatives and exhibit different mitotic behaviour in the two sexes. We present a blastoderm fate map for the fat body, the larval somatic muscles and the gonadal mesoderm. Clones in the imaginal muscle precursors of the abdomen, as well as of the thorax, always show a common cell lineage with larval somatic muscles and partly with other mesodermal tissues. These clones of imaginal derivatives are always found within a single segment, while the overlapping clone parts in the larval somatic muscles can label up to three segments.

Localization of thoracic imaginal-disc precursor cells in the early embryo of Drosophila melanogaster

Our previous cell lineage analysis of the thoracic disc primordia of Drosophila showed that at the blastoderm and early gastrula stage, cells are not yet committed to form either larval or imaginal tissue (Meise and Janning, 1993). We have now refined our studies on the cell lineage and have mapped the imaginal primordia in the thoracic region. Homotopic transplantations of single cells within the thoracic region of blastoderm and early gastrula stages show that the precursor cells of thoracic imaginal discs are locally restricted to a small lateral area of the thoracic region. Clones labelling leg discs frequently included the Keilin's organs. Heterotopic transplantations along the dorsoventral axis indicate that cells within the thoracic region are not yet committed with respect to larval or imaginal tissue, their fate being dependent on the position where the transplanted cell had been deposited. On the other hand, cells taken from the abdominal anlagen and transplanted into the region of thoracic disc primordia could not participate in the formation of imaginal discs. This shows that, in contrast to the dorsoventral axis, determinative events had separated primordia along the anterior-posterior axis.

Larval and imaginal pathways in early development of Drosophila

In holometabolous development, higher insects have two different life forms, the larva and the imago. Both larval and imaginal cells are derived from cells of the blastoderm stage. After the final embryonic wave of mitosis, however, only the imaginal cells remain diploid, proliferate massively and do not differentiate until metamorphosis. The separation of these two pathways was described by many authors as a fundamental process that must take place at a very early stage of development, most probably the blastoderm stage. Mainly by using single cell transplantations at the blastoderm or early gastrula stages, respectively, we found common cell lineages between larval and imaginal structures by clones overlapping in the ectoderm (i.e. larval epidermal cells and imaginal discs within a segment, or larval and imaginal salivary gland cells), the mesoderm (i.e. larval somatic muscles and adepithelial cells), and the endoderm (i.e. larval and imaginal midgut cells). From these findings we conclude that it seems to be a principle in Drosophila embryogenesis that the separation of larval and imaginal pathways is postponed to a later developmental stage.