Dominant Maternal-Effect Mutations of DROSOPHILA MELANOGASTER Causing the Production of Double-Abdomen Embryos

Dominant mutations at two loci, BicaudalC (BicC ) and BicaudalD (BicD), cause heterozygous females to produce double-abdomen embryos. These mutations cause the production of embryos with a range of defects extending from the anterior end of the differentiated embryo. The same array of defective embryos is caused by mutations at either locus and is similar to that produced by the original mutation at bicaudal (bic). The array of defective embryos suggests that these mutations cause the loss of positional values from the anterior end of the embryo, associated with a duplication of the posterior end if too few positional values remain. BicaudalD mutations appear to be antimorphic, gain-of-function mutations, whereas BicaudalC mutations are likely to be hypomorphic or amorphic mutations. Mutations at all these loci (bic, BicC and BicD) act as mutual enhancers of each other, and a number of other maternal-effect mutations also act to either enhance or suppress the expression of these dominant bicaudal mutations.     

Different requirements for l(1)giant in two embryonic domains of Drosophila melanogaster

L(1)giant is a zygotic lethal mutation which affects the embryonic development of both the labial/thoracic segments and a subset of posterior abdominal segments. Using antibodies specific for proteins encoded by several Drosophila genes to identify the compartmental origin of the defects, we show that the requirement of giant activity is different in these two embryonic domains. Anteriorly, the posterior compartment of the labial segment is missing at the blastoderm stage. Posteriorly, cells are specifically deleted by cell death within the anterior compartments of abdominal segments 5–7 during germ band elongation. In mature embryos, posterior compartment structures of the peripheral nervous system of A5–7 are fused. In addition to a different pattern of defect in the two parts of the embryo, the kind of action appears different. Anteriorly, giant resembles a gap mutation in that a particular region is missing from the blastoderm fate map, whereas in the abdominal domain, giant affects the development of anterior compartment-specific structures.     

The influence of segmental compartmentalisation on the development of the larval peripheral nervous system in Drosophila melanogaster

Summary The peripheral nervous system of embryos homozygous for prd, ftz, en and bxd was examined for defects and transformations in the segment-specific pattern of sensilla and peripheral nerves. This analysis permitted me to assign a distinct subset of sensilla to any of the three genetically and morphologically defined compartments s, a and p of each segment. In the wild-type embryonic segments, sensory axons deriving from sensilla of different compartments form a part of the common peripheral nerves. In the composite segments of prd and ftz mutant embryos, subsets of sensilla of two neighbouring segments are combined. Nevertheless, the axons of sensilla of different segmental identity are able to fasciculate and to form afferent nerves, which connect in an apparently normal fashion to the central nervous system. It is concluded that in the Drosophila embryo compartmental and segmental identity of sensory organs has no influence on the trajectories of sensory axons.     

Scanning electron microscopic analysis of spontaneous and UV-induced abnormal segment patterns in Chironomus samoensis (Diptera,Chironomidae)

Summary The embryonic body pattern of Chironomus samoensis, as well as other chironomids, can be altered dramatically by irradiating their eggs with ultraviolet light (UV). Anterior UV irradiation leads to the formation of double abdomen embryos whose anterior segments are replaced by posterior segments with reversed polarity. Most double abdomens are symmetrical showing a mirror image duplication of the posterior six or seven segments. However, in some cases the anterior end of the double abdomen is shorter, and comprises fewer segments, than its posterior counterpart. These asymmetries range from moderate to extreme. They involve the juxtaposition, at the plane of polarity reversal, of disparate segments. The same range of symmetrical and asymmetrical double abdomens is also formed spontaneously in an apparently mutant strain of C. samoensis. There are striking similarities between this natural variant and the Drosophila melanogaster mutant bicaudal which are also discussed with respect to models of embryonic pattern formation.     

Pattern formation in fragmented eggs of the short germ insect Schistocerca gregaria

Summary The effect of transverse fragmentation on the segment pattern of the short germ embryo of the locust Schistocerca gregaria has been investigated at two stages subsequent to the formation of the germ anlage. Following fragmentation both anterior and posterior partial embryos were observed, although rarely in a single egg. Anterior partial patterns usually terminated with a segment visible at the time of fragmentation or with the next segment due to appear. Posterior partial patterns began with a wide range of segments depending on the level of fragmentation.Anterior and posterior partial patterns developing in a single egg were usually not complementary and the segments missing sometimes included some segments visible when the embryo was fragmented. Non-complementary patterns resulted following fragmentation in all regions, while complementary patterns only occurred after fragmentation in the visibly-segmented region.The results suggest that following fragmentation isolated posterior portions of the embryo continue to form segments, while isolated anterior regions usually do not. This effect could result from variable damage to an existing pattern of unequally-sized segment primordia, or from the disruption of a process of sequential segmentation in the elongating posterior region of the embryo. The results are broadly compatible with the progress zone model proposed by Summerbell et al. (1973).     

Ether-induced segmentation disturbances in Drosophila melanogaster

Summary Drosophila embryos, exposed to ether between 1 and 4 h after oviposition, develop defects ranging from the complete lack of segmentation to isolated gaps in single segments. Between these extremes are varying extents of incomplete and abnormal segmentation. On the basis of both their temporal and spatial characteristics, five major phenotype classes may be distinguished: headless — unsegmented or incompletely segmented anteriorly; gap — interruptions of segmentation not obviously periodic; alternating segment gaps — interruptions with double segment periodicities; fused segments; and short segments — truncations with single segment periodicities. Many defects resemble known mutant phenotypes. The disturbances in segmentation are predominantly global and frequently accompanied by alterations in segment specification, such that the segments obtained show no resemblance to the normal homologues. These features, together with the distinctive spatiotemporal characteristics of the defects, all point to segmentation as a dynamic process. The regular spacing of the segments and the fact that the entire range of defects is inducible by ether are further consistent with the hypothesis that at least part of the segmentation process may consist of physicochemical reactions coordinated over the whole body. The relationship between our data and data from genetic and other analyses are briefly discussed.     

Sensory neurons and peripheral pathways in Drosophila embryos

Summary The thoracic and abdominal segments of the Drosophila embryo contain 373 neurons innervating external sensory structures and 162 neurons innervating chordotonal organs. These neurons are arranged in ventral, lateral and dorsal clusters within each segment, in a highly invariant pattern. Two fascicles are formed in each segment as the sensory axons grow ventrally towards the CNS and meet motor axons growing dorsally from the CNS. In all but the last segment, the anterior fascicle is contributed by the dorsal and lateral neurons, while the posterior one is formed by the ventral neurons. Five distinct segmental patterns are described, corresponding to (1) the prothorax, (2) the other two thoracic segments, (3) the first seven abdominal segments, (4) the eighth and (5) the ninth (and possibly the tenth) abdominal segments.The publisher regrets that two companion papers unfortunately were published out of sequence. The present paper should have preceded the paper entitled The sense organs in the Drosophila larva and their relation to the embryonic pattern of sensory neurons, which appeared in Volume 195, Number 4 of the journal (pp 222–228)     

Function of trans-acting genes of theachaete-scute complex in sensory organ patterning in the mesonotum ofDrosophila

Summary Cell-cell interactions play a fundamental role in the differentiation of nervous elements in constant patterns, both during embryogenesis and imaginal development. In this paper we analyse the role of genes of theachaete-scute andEnhancer of split complexes, plus the genesextramacrochaetae, Notch, Delta, andHairless in the patterning of sensory elements in the mesonotum ofDrosophila. The phenotypes of different alleles of these genes, including lethals in genetic mosaics, reveal their participation in two processes, the singling out from epidermal cells of sensory organ mother cells and their subsequent differentiation. Studies of allelic combinations of different genes lead to a model of the genetic interactions involved in the processes of pattern formation. In this model, theachaete-scute complex plays a central role, determining sensory organ mother cells and preventing neighbouring cells from following the same developmental pathway.     

A cell arrangement specific to thoracic ganglia in the central nervous system of theDrosophila embryo: Its behaviour in homoeotic mutants

Summary We describe a set of cells in the central nervous system of theDrosophila embryo which are restricted to the thoracic ganglia in the wildtype. Taking these cells as indication of thoracic identity, we find that the ventral cord of embryos homozygous mutant for different bithorax functions and for Polycomb undergoes homoeotic transformations equivalent to those observed in the larval cuticle.     

The segment polarity gene costal-2 in Drosophila. I. The organization of both primary and secondary embryonic fields may be affected

A series of loss of function alleles at the costal-2 locus is described. Embryos mutant for lethal alleles that are derived from a mutant female germ line display polarity defects on the larval segments. A posterior part of the segmental denticle belt is missing and in its place is a mirror-image duplication of the anterior part including the segment boundary. Maternally rescued embryos are lethal but have normal morphology. Hypomorphic alleles escape to adults that display pattern duplications on the wings and halteres. Dominant gain of function alleles at the Costal-1 locus are also described and data are presented that argue that these are neomorphic and act in trans to impair functioning of costal-2. Some wild-type isoalleles of costal-2 are particularly sensitive to interference from Costal-1 mutations and different combinations of these alleles with Costal-1 can lead to embryos in which the primary embryonic field is disrupted (bicaudal phenotype) and adults with pattern duplications on the anterior compartment of most body segments.     

Segmental organisation of the tail region in the embryo of Drosophila melanogaster

Summary The segmental organisation of the tail region in the embryo of Drosophila melanogaster, which is defined here as the epidermal region posterior to the boundary between abdominal segments A7 and A8, has been investigated by means of ultraviolet (UV) laser fate-mapping and phenotypic analysis of embryonic mutants that alter the segmental pattern of the larval cuticle. Wild-type embryos were irradiated in the presumptive tail region with a UV- laser microbeam of 20 m diameter at the blastoderm stage. The ensuing defects were scored in the cuticle pattern of the tail region of the first-instar larva, which is described in detail in this paper. The spatial distribution of defect frequencies was used to construct a blastoderm fate-map of the cuticle structures of the larval tail region. The segmental origin of the larval tail structures was inferred from the phenotypic analysis of segmentation and homoeotic mutants, which revealed pattern repetition throughout the embryonic tail region corresponding to four segment anlagen, A8 to A11, and a non-segmental telson. These data enabled the transformation of the blastoderm fate-map of cuticle structures into a map of tail segment anlagen. The tail anlage occupies about 10% of the egg length (EL), bounded by segment A7 anteriorly at 20% EL and by the proctodaeum posteriorly at 10% EL, as measured from the posterior pole. The anlagen of segments A8 and A9 appear to be narrow dorso-ventral strips of blastoderm cells similar to the anlagen of the trunk segments, whereas the anlagen of A10 and A11 are smaller and produce fewer pattern elements. The telson is represented in the cuticle by the tuft which derives from a very dorsal posterior position. The antero-posterior axis of the entire tail anlage appears curved upward posteriorly. Differences in the mode of development between tail and trunk segments are discussed, as are similarities of larval and imaginal tail development in Drosophila. Comparison with tail development in other insects suggests that, during evolution, the transition from semi-long-germ to long-germ development modified the organisation of the tail region without affecting its primary subdivision into metameric units.     

Cell degeneration and elimination in the imaginal wing disc,caused by the mutationsvestigial andUltravestigial ofDrosophila melanogaster

Summary The mutationsvestigial (vg; recessive) andUltravestigial (vg ^U; dominant) ofDrosophila melanogaster give rise to identical mutant adult phenotypes in which much of the cases this results from cell death in the presumptive wing margin of the wing disc in the third larval instar, but the process of cell degeneration is quite different in the two mutants. Invg cell death occurs continuously throughout the third larval instar, while invg ^U it occurs only in the early third instar. Cells fragment and some of the fragments condense, becoming electron dense (apoptosis). Both condensed and ultrastructurally normal cell fragments are extruded to the basal side of thevg disc epithelium. They accumulate under the basal lamina in the wing pouch area until they are phagocytosed by blood cells entering the wing pouch during the six hours following pupariation. Fragments are not extruded from thevg ^U epithelium but are apparently phagocytosed by neighboring epithelial cells. The basal lamina undergoes mophological changes following pupariation and is phagocytosed by blood cells in both wild-type andvestigial, but investigial the degenerated cell fragments are also engulfed by the same blood cells.     

Pair-rule and gap gene mutants in the flour beetle Tribolium castaneum

 Early pattern formation in the Drosophila embryo occurs in a syncytial blastoderm where communication between nuclei is unimpeded by cell walls. During the development of other insects, similar gene expression patterns are generated in a cellular environment. In Tribolium, for instance, pair-rule stripes are transiently expressed near the posterior end of the growing germ band. To elucidate how pattern formation in such a situation deviates from that of Drosophila, functional data about the genes involved are essential. In a genetic screen for Tribolium mutants affecting the larval cuticle pattern, we isolated 4 mutants (from a total of 30) which disrupt segmentation in the thorax and abdomen. Two of these mutants display clear pair-rule phenotypes. This demonstrates that not only the expression, but also the function of pair-rule genes in this short-germ insect is in principle similar to Drosophila. The other two mutants appear to identify gap genes. They provide the first evidence for the involvement of gap genes in abdominal segmentation of short-germ embryos. However, significant differences between the phenotypes of these mutants and those of known Drosophila gap mutants exist which indicates that evolutionary changes occurred in either the regulation or action of these genes. Received: 8 May 1998 / Accepted: 17 June 1998     

A morphological and developmental study of Drosophila embryos ligated during nuclear multiplication

In the Drosophila embryo, determination is established at the cellular blastoderm and a mosaic type development is observed after this time. Before the blastoderm stage, however, development is not of the mosaic type, as ligation during the nuclear multiplication stage causes a change in the spatial organization of the larval pattern. An aberration in determination leads to an increase in segment size, an increase in the number of cells per segment, and a decrease in segment number. This abnormal determination of blastoderm cells has also been demonstrated experimentally by marking corresponding regions of the blastoderm in ligated (posterior fragments only) and nonligated embryos. When the blastoderms of nonligated and ligated embryos are punctured at the same site, ligated embryos produce larvae with damage in segments posterior to the segments damaged in larvae from nonligated embryos. Ultrastructurally, no abnormalities were observed in the plasma membrane at the time of ligation or later in blastoderm cells which formed in the ligation area of these embryos. Evidence from this study, as well as other sources, indicates that determination of segmentation is under maternal control.     

Region-specific defects in l(1)giant embryos of Drosophila melanogaster

Lack of zygotic expression of the l(1)giant locus (l(1)gt;3A1), produces embryos with defects in abdominal A5, 6, and 7 and within the head. Scanning electron microscopy at the time of segment formation reveals two regions of defects in the segmentation pattern: anteriorly the labial lobe and thoracic segments T1 and T2 are fused; posteriorly, abdominal segments A5-7 are disrupted. The mature embryo shows incomplete head involution and defects within A5-7; fusion of T1 and T2 is no longer observed. Localized cell death within neural and mesodermal tissues is observed at 7 hr of development; later ventral ganglia, A5-7, are missing. Double-mutant analyses of l(1)gt with maternal effect lethal mutations and mutations that generate homeotic, segment number, gap, or segment polarity phenotypes indicate that normal activity of l(1)gt is required for differentiation of two embryonic domains: one corresponding to labial, T1 and T2 segments, and the second corresponding to abdominal segments 5, 6, and 7.     

Use of a cytoplasmically localised P-lacZ fusion to identify cell shapes by enhancer trapping inDrosophila

Summary The N-terminal 125 amino acids of theDrosophila P element transposase are necessary and sufficient for the nuclear localisation of a hybridlacZ gene product in most cell types of theDrosophila embryo. A P-lacZ enhancer-trap element lacking these residues is of use in visualizing the shapes of P-lacZ-expressing cells.     

Change of the crossing-over frequency inDrosophila during selection for resistance to temperature fluctuations

Significant differences among cage populations ofDrosophila in the dynamics of linkage disequilibrium for marker locib, cn andvg of chromosome 2 have been found at optimum and extreme temperatures. Fifteen generations of selection under extreme conditions considerably increased recombination frequency in thecn-vg region and over the whole of theb-vg interval. From the data obtained it is inferred that recombination-promoting alleles with intermediate expression in the heterozygous state are responsible for these changes.     

Maternal-effect mutations altering the anterior-posterior pattern of the Drosophila embryo

Summary Mutations in seven different maternal-effect loci on the second chromosome of Drosophila melanogaster all cause alterations in the anterior-posterior pattern of the embryo. Mutations in torso (tor) and trunk (trk) delete the anterior- and posterior-most structures of the embryo. At the same time they shift cellular fates which are normally found in the subterminal regions of the embryo towards the poles. Mutations in vasa (vas), valois (vls), staufen (stau) and tudor (tud) cause two embryonic defects. For one they result in absence of polar plasm, polar granules and pole cells in all eggs produced by mutant females. Secondly, embryos developing inside such eggs show deletions of abdominal segments. In addition, embryos derived from staufen mothers lack anterior head structures, embryos derived from valois mothers frequently fail to cellularize properly. Mutations in exuperantia (exu) cause deletions of anterior head structures, similar to torso, trunk and staufen. However in exu, these head structures are replaced by an inverted posterior end which comprises posterior midgut, proctodeal region, and often malpighian tubules.The effects of all mutations can be traced back to the beginning stages of gastrulation, indicating that the alterations in cellular fates have probably taken place by that time. Analysis of embryos derived from double mutant mothers suggests that these three phenotypic groups of mutants interfere with three different, independent pathways. All three pathways seem to act additively on the system which specifies anterior-posterior cellular fates within the egg.